/* ************************************************************************ * Copyright (c) 2020-2021 Advanced Micro Devices, Inc. * ************************************************************************ */ #pragma once #include "clientcommon.hpp" #include "lapack_host_reference.hpp" #include "norm.hpp" #include "rocsolver.hpp" #include "rocsolver_arguments.hpp" #include "rocsolver_test.hpp" template void geql2_geqlf_checkBadArgs(const rocblas_handle handle, const rocblas_int m, const rocblas_int n, T dA, const rocblas_int lda, const rocblas_stride stA, U dIpiv, const rocblas_stride stP, const rocblas_int bc) { // handle EXPECT_ROCBLAS_STATUS( rocsolver_geql2_geqlf(STRIDED, GEQLF, nullptr, m, n, dA, lda, stA, dIpiv, stP, bc), rocblas_status_invalid_handle); // values // N/A // sizes (only check batch_count if applicable) if(STRIDED) EXPECT_ROCBLAS_STATUS( rocsolver_geql2_geqlf(STRIDED, GEQLF, handle, m, n, dA, lda, stA, dIpiv, stP, -1), rocblas_status_invalid_size); // pointers EXPECT_ROCBLAS_STATUS( rocsolver_geql2_geqlf(STRIDED, GEQLF, handle, m, n, (T) nullptr, lda, stA, dIpiv, stP, bc), rocblas_status_invalid_pointer); EXPECT_ROCBLAS_STATUS( rocsolver_geql2_geqlf(STRIDED, GEQLF, handle, m, n, dA, lda, stA, (U) nullptr, stP, bc), rocblas_status_invalid_pointer); // quick return with invalid pointers EXPECT_ROCBLAS_STATUS(rocsolver_geql2_geqlf(STRIDED, GEQLF, handle, 0, n, (T) nullptr, lda, stA, (U) nullptr, stP, bc), rocblas_status_success); EXPECT_ROCBLAS_STATUS(rocsolver_geql2_geqlf(STRIDED, GEQLF, handle, m, 0, (T) nullptr, lda, stA, (U) nullptr, stP, bc), rocblas_status_success); // quick return with zero batch_count if applicable if(STRIDED) EXPECT_ROCBLAS_STATUS( rocsolver_geql2_geqlf(STRIDED, GEQLF, handle, m, n, dA, lda, stA, dIpiv, stP, 0), rocblas_status_success); } template void testing_geql2_geqlf_bad_arg() { // safe arguments rocblas_local_handle handle; rocblas_int m = 1; rocblas_int n = 1; rocblas_int lda = 1; rocblas_stride stA = 1; rocblas_stride stP = 1; rocblas_int bc = 1; if(BATCHED) { // memory allocations device_batch_vector dA(1, 1, 1); device_strided_batch_vector dIpiv(1, 1, 1, 1); CHECK_HIP_ERROR(dA.memcheck()); CHECK_HIP_ERROR(dIpiv.memcheck()); // check bad arguments geql2_geqlf_checkBadArgs(handle, m, n, dA.data(), lda, stA, dIpiv.data(), stP, bc); } else { // memory allocations device_strided_batch_vector dA(1, 1, 1, 1); device_strided_batch_vector dIpiv(1, 1, 1, 1); CHECK_HIP_ERROR(dA.memcheck()); CHECK_HIP_ERROR(dIpiv.memcheck()); // check bad arguments geql2_geqlf_checkBadArgs(handle, m, n, dA.data(), lda, stA, dIpiv.data(), stP, bc); } } template void geql2_geqlf_initData(const rocblas_handle handle, const rocblas_int m, const rocblas_int n, Td& dA, const rocblas_int lda, const rocblas_stride stA, Ud& dIpiv, const rocblas_stride stP, const rocblas_int bc, Th& hA, Uh& hIpiv) { if(CPU) { rocblas_init(hA, true); // scale A to avoid singularities for(rocblas_int b = 0; b < bc; ++b) { for(rocblas_int i = 0; i < m; i++) { for(rocblas_int j = 0; j < n; j++) { if(m - i == n - j) hA[b][i + j * lda] += 400; else hA[b][i + j * lda] -= 4; } } } } if(GPU) { // now copy to the GPU CHECK_HIP_ERROR(dA.transfer_from(hA)); } } template void geql2_geqlf_getError(const rocblas_handle handle, const rocblas_int m, const rocblas_int n, Td& dA, const rocblas_int lda, const rocblas_stride stA, Ud& dIpiv, const rocblas_stride stP, const rocblas_int bc, Th& hA, Th& hARes, Uh& hIpiv, double* max_err) { std::vector hW(n); // input data initialization geql2_geqlf_initData(handle, m, n, dA, lda, stA, dIpiv, stP, bc, hA, hIpiv); // execute computations // GPU lapack CHECK_ROCBLAS_ERROR(rocsolver_geql2_geqlf(STRIDED, GEQLF, handle, m, n, dA.data(), lda, stA, dIpiv.data(), stP, bc)); CHECK_HIP_ERROR(hARes.transfer_from(dA)); // CPU lapack for(rocblas_int b = 0; b < bc; ++b) { GEQLF ? cblas_geqlf(m, n, hA[b], lda, hIpiv[b], hW.data(), n) : cblas_geql2(m, n, hA[b], lda, hIpiv[b], hW.data()); } // error is ||hA - hARes|| / ||hA|| (ideally ||QL - Qres Lres|| / ||QL||) // (THIS DOES NOT ACCOUNT FOR NUMERICAL REPRODUCIBILITY ISSUES. // IT MIGHT BE REVISITED IN THE FUTURE) // using frobenius norm double err; *max_err = 0; for(rocblas_int b = 0; b < bc; ++b) { err = norm_error('F', m, n, lda, hA[b], hARes[b]); *max_err = err > *max_err ? err : *max_err; } } template void geql2_geqlf_getPerfData(const rocblas_handle handle, const rocblas_int m, const rocblas_int n, Td& dA, const rocblas_int lda, const rocblas_stride stA, Ud& dIpiv, const rocblas_stride stP, const rocblas_int bc, Th& hA, Uh& hIpiv, double* gpu_time_used, double* cpu_time_used, const rocblas_int hot_calls, const int profile, const bool perf) { std::vector hW(n); if(!perf) { geql2_geqlf_initData(handle, m, n, dA, lda, stA, dIpiv, stP, bc, hA, hIpiv); // cpu-lapack performance (only if not in perf mode) *cpu_time_used = get_time_us_no_sync(); for(rocblas_int b = 0; b < bc; ++b) { GEQLF ? cblas_geqlf(m, n, hA[b], lda, hIpiv[b], hW.data(), n) : cblas_geql2(m, n, hA[b], lda, hIpiv[b], hW.data()); } *cpu_time_used = get_time_us_no_sync() - *cpu_time_used; } geql2_geqlf_initData(handle, m, n, dA, lda, stA, dIpiv, stP, bc, hA, hIpiv); // cold calls for(int iter = 0; iter < 2; iter++) { geql2_geqlf_initData(handle, m, n, dA, lda, stA, dIpiv, stP, bc, hA, hIpiv); CHECK_ROCBLAS_ERROR(rocsolver_geql2_geqlf(STRIDED, GEQLF, handle, m, n, dA.data(), lda, stA, dIpiv.data(), stP, bc)); } // gpu-lapack performance hipStream_t stream; CHECK_ROCBLAS_ERROR(rocblas_get_stream(handle, &stream)); double start; if(profile > 0) { rocsolver_log_set_layer_mode(rocblas_layer_mode_log_profile); rocsolver_log_set_max_levels(profile); } for(rocblas_int iter = 0; iter < hot_calls; iter++) { geql2_geqlf_initData(handle, m, n, dA, lda, stA, dIpiv, stP, bc, hA, hIpiv); start = get_time_us_sync(stream); rocsolver_geql2_geqlf(STRIDED, GEQLF, handle, m, n, dA.data(), lda, stA, dIpiv.data(), stP, bc); *gpu_time_used += get_time_us_sync(stream) - start; } *gpu_time_used /= hot_calls; } template void testing_geql2_geqlf(Arguments& argus) { // get arguments rocblas_local_handle handle; rocblas_int m = argus.get("m"); rocblas_int n = argus.get("n", m); rocblas_int lda = argus.get("lda", m); rocblas_stride stA = argus.get("strideA", lda * n); rocblas_stride stP = argus.get("strideP", min(m, n)); rocblas_int bc = argus.batch_count; rocblas_int hot_calls = argus.iters; rocblas_stride stARes = (argus.unit_check || argus.norm_check) ? stA : 0; // check non-supported values // N/A // determine sizes size_t size_A = size_t(lda) * n; size_t size_P = size_t(min(m, n)); double max_error = 0, gpu_time_used = 0, cpu_time_used = 0; size_t size_ARes = (argus.unit_check || argus.norm_check) ? size_A : 0; // check invalid sizes bool invalid_size = (m < 0 || n < 0 || lda < m || bc < 0); if(invalid_size) { if(BATCHED) EXPECT_ROCBLAS_STATUS(rocsolver_geql2_geqlf(STRIDED, GEQLF, handle, m, n, (T* const*)nullptr, lda, stA, (T*)nullptr, stP, bc), rocblas_status_invalid_size); else EXPECT_ROCBLAS_STATUS(rocsolver_geql2_geqlf(STRIDED, GEQLF, handle, m, n, (T*)nullptr, lda, stA, (T*)nullptr, stP, bc), rocblas_status_invalid_size); if(argus.timing) rocsolver_bench_inform(inform_invalid_size); return; } // memory size query is necessary if(argus.mem_query || !USE_ROCBLAS_REALLOC_ON_DEMAND) { CHECK_ROCBLAS_ERROR(rocblas_start_device_memory_size_query(handle)); if(BATCHED) CHECK_ALLOC_QUERY(rocsolver_geql2_geqlf(STRIDED, GEQLF, handle, m, n, (T* const*)nullptr, lda, stA, (T*)nullptr, stP, bc)); else CHECK_ALLOC_QUERY(rocsolver_geql2_geqlf(STRIDED, GEQLF, handle, m, n, (T*)nullptr, lda, stA, (T*)nullptr, stP, bc)); size_t size; CHECK_ROCBLAS_ERROR(rocblas_stop_device_memory_size_query(handle, &size)); if(argus.mem_query) { rocsolver_bench_inform(inform_mem_query, size); return; } CHECK_ROCBLAS_ERROR(rocblas_set_device_memory_size(handle, size)); } if(BATCHED) { // memory allocations host_batch_vector hA(size_A, 1, bc); host_batch_vector hARes(size_ARes, 1, bc); host_strided_batch_vector hIpiv(size_P, 1, stP, bc); device_batch_vector dA(size_A, 1, bc); device_strided_batch_vector dIpiv(size_P, 1, stP, bc); if(size_A) CHECK_HIP_ERROR(dA.memcheck()); if(size_P) CHECK_HIP_ERROR(dIpiv.memcheck()); // check quick return if(m == 0 || n == 0 || bc == 0) { EXPECT_ROCBLAS_STATUS(rocsolver_geql2_geqlf(STRIDED, GEQLF, handle, m, n, dA.data(), lda, stA, dIpiv.data(), stP, bc), rocblas_status_success); if(argus.timing) rocsolver_bench_inform(inform_quick_return); return; } // check computations if(argus.unit_check || argus.norm_check) geql2_geqlf_getError(handle, m, n, dA, lda, stA, dIpiv, stP, bc, hA, hARes, hIpiv, &max_error); // collect performance data if(argus.timing) geql2_geqlf_getPerfData(handle, m, n, dA, lda, stA, dIpiv, stP, bc, hA, hIpiv, &gpu_time_used, &cpu_time_used, hot_calls, argus.profile, argus.perf); } else { // memory allocations host_strided_batch_vector hA(size_A, 1, stA, bc); host_strided_batch_vector hARes(size_ARes, 1, stARes, bc); host_strided_batch_vector hIpiv(size_P, 1, stP, bc); device_strided_batch_vector dA(size_A, 1, stA, bc); device_strided_batch_vector dIpiv(size_P, 1, stP, bc); if(size_A) CHECK_HIP_ERROR(dA.memcheck()); if(size_P) CHECK_HIP_ERROR(dIpiv.memcheck()); // check quick return if(m == 0 || n == 0 || bc == 0) { EXPECT_ROCBLAS_STATUS(rocsolver_geql2_geqlf(STRIDED, GEQLF, handle, m, n, dA.data(), lda, stA, dIpiv.data(), stP, bc), rocblas_status_success); if(argus.timing) rocsolver_bench_inform(inform_quick_return); return; } // check computations if(argus.unit_check || argus.norm_check) geql2_geqlf_getError(handle, m, n, dA, lda, stA, dIpiv, stP, bc, hA, hARes, hIpiv, &max_error); // collect performance data if(argus.timing) geql2_geqlf_getPerfData(handle, m, n, dA, lda, stA, dIpiv, stP, bc, hA, hIpiv, &gpu_time_used, &cpu_time_used, hot_calls, argus.profile, argus.perf); } // validate results for rocsolver-test // using m * machine_precision as tolerance // (for possibly singular of ill-conditioned matrices we could use m*min(m,n)) if(argus.unit_check) ROCSOLVER_TEST_CHECK(T, max_error, m); // output results for rocsolver-bench if(argus.timing) { if(!argus.perf) { rocsolver_bench_header("Arguments:"); if(BATCHED) { rocsolver_bench_output("m", "n", "lda", "strideP", "batch_c"); rocsolver_bench_output(m, n, lda, stP, bc); } else if(STRIDED) { rocsolver_bench_output("m", "n", "lda", "strideA", "strideP", "batch_c"); rocsolver_bench_output(m, n, lda, stA, stP, bc); } else { rocsolver_bench_output("m", "n", "lda"); rocsolver_bench_output(m, n, lda); } rocsolver_bench_header("Results:"); if(argus.norm_check) { rocsolver_bench_output("cpu_time", "gpu_time", "error"); rocsolver_bench_output(cpu_time_used, gpu_time_used, max_error); } else { rocsolver_bench_output("cpu_time", "gpu_time"); rocsolver_bench_output(cpu_time_used, gpu_time_used); } rocsolver_bench_endl(); } else { if(argus.norm_check) rocsolver_bench_output(gpu_time_used, max_error); else rocsolver_bench_output(gpu_time_used); } } // ensure all arguments were consumed argus.validate_consumed(); }