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/* ************************************************************************
* Copyright (C) 2021 Advanced Micro Devices, Inc. All rights Reserved.
*
* 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.
*
* ************************************************************************ */
#include "testing_spsm_csr.hpp"
#include <hipsparse.h>
struct M_N_K_alpha
{
int M;
int N;
int K;
double alpha;
};
typedef std::tuple<M_N_K_alpha,
hipsparseOperation_t,
hipsparseOperation_t,
hipsparseOrder_t,
hipsparseOrder_t,
hipsparseIndexBase_t,
hipsparseDiagType_t,
hipsparseFillMode_t,
hipsparseSpSMAlg_t>
spsm_csr_tuple;
typedef std::tuple<M_N_K_alpha,
hipsparseOperation_t,
hipsparseOperation_t,
hipsparseOrder_t,
hipsparseOrder_t,
hipsparseIndexBase_t,
hipsparseDiagType_t,
hipsparseFillMode_t,
hipsparseSpSMAlg_t,
std::string>
spsm_csr_bin_tuple;
M_N_K_alpha spsm_csr_M_N_K_alpha_range[] = {{50, 50, 22, 2.0}};
hipsparseOperation_t spsm_csr_transA_range[] = {HIPSPARSE_OPERATION_NON_TRANSPOSE};
hipsparseOperation_t spsm_csr_transB_range[] = {HIPSPARSE_OPERATION_NON_TRANSPOSE};
hipsparseOrder_t spsm_csr_orderB_range[] = {HIPSPARSE_ORDER_COL, HIPSPARSE_ORDER_ROW};
hipsparseOrder_t spsm_csr_orderC_range[] = {HIPSPARSE_ORDER_COL, HIPSPARSE_ORDER_ROW};
hipsparseIndexBase_t spsm_csr_idxbase_range[] = {HIPSPARSE_INDEX_BASE_ZERO};
hipsparseDiagType_t spsm_csr_diag_type_range[] = {HIPSPARSE_DIAG_TYPE_NON_UNIT};
hipsparseFillMode_t spsm_csr_fill_mode_range[]
= {HIPSPARSE_FILL_MODE_LOWER, HIPSPARSE_FILL_MODE_UPPER};
hipsparseSpSMAlg_t spsm_csr_alg_range[] = {HIPSPARSE_SPSM_ALG_DEFAULT};
std::string spsm_csr_bin[] = {"nos1.bin", "nos3.bin", "nos5.bin", "scircuit.bin"};
class parameterized_spsm_csr : public testing::TestWithParam<spsm_csr_tuple>
{
protected:
parameterized_spsm_csr() {}
virtual ~parameterized_spsm_csr() {}
virtual void SetUp() {}
virtual void TearDown() {}
};
class parameterized_spsm_csr_bin : public testing::TestWithParam<spsm_csr_bin_tuple>
{
protected:
parameterized_spsm_csr_bin() {}
virtual ~parameterized_spsm_csr_bin() {}
virtual void SetUp() {}
virtual void TearDown() {}
};
Arguments setup_spsm_csr_arguments(spsm_csr_tuple tup)
{
Arguments arg;
arg.M = std::get<0>(tup).M;
arg.N = std::get<0>(tup).N;
arg.K = std::get<0>(tup).K;
arg.alpha = std::get<0>(tup).alpha;
arg.transA = std::get<1>(tup);
arg.transB = std::get<2>(tup);
arg.orderB = std::get<3>(tup);
arg.orderC = std::get<4>(tup);
arg.baseA = std::get<5>(tup);
arg.diag_type = std::get<6>(tup);
arg.fill_mode = std::get<7>(tup);
arg.spsm_alg = std::get<8>(tup);
arg.timing = 0;
return arg;
}
Arguments setup_spsm_csr_arguments(spsm_csr_bin_tuple tup)
{
Arguments arg;
arg.K = std::get<0>(tup).K;
arg.alpha = std::get<0>(tup).alpha;
arg.transA = std::get<1>(tup);
arg.transB = std::get<2>(tup);
arg.orderB = std::get<3>(tup);
arg.orderC = std::get<4>(tup);
arg.baseA = std::get<5>(tup);
arg.diag_type = std::get<6>(tup);
arg.fill_mode = std::get<7>(tup);
arg.spsm_alg = std::get<8>(tup);
arg.timing = 0;
// Determine absolute path of test matrix
std::string bin_file = std::get<9>(tup);
// Matrices are stored at the same path in matrices directory
arg.filename = get_filename(bin_file);
return arg;
}
#if(!defined(CUDART_VERSION) || CUDART_VERSION >= 11010)
TEST(spsm_csr_bad_arg, spsm_csr_float)
{
testing_spsm_csr_bad_arg();
}
TEST_P(parameterized_spsm_csr, spsm_csr_i32_float)
{
Arguments arg = setup_spsm_csr_arguments(GetParam());
SKIP_IF_DEBIANNOTFOUND(arg);
hipsparseStatus_t status = testing_spsm_csr<int32_t, int32_t, float>(arg);
EXPECT_EQ(status, HIPSPARSE_STATUS_SUCCESS);
}
TEST_P(parameterized_spsm_csr, spsm_csr_i64_double)
{
Arguments arg = setup_spsm_csr_arguments(GetParam());
SKIP_IF_DEBIANNOTFOUND(arg);
hipsparseStatus_t status = testing_spsm_csr<int64_t, int64_t, double>(arg);
EXPECT_EQ(status, HIPSPARSE_STATUS_SUCCESS);
}
TEST_P(parameterized_spsm_csr, spsm_csr_i32_float_complex)
{
Arguments arg = setup_spsm_csr_arguments(GetParam());
SKIP_IF_DEBIANNOTFOUND(arg);
hipsparseStatus_t status = testing_spsm_csr<int32_t, int32_t, hipComplex>(arg);
EXPECT_EQ(status, HIPSPARSE_STATUS_SUCCESS);
}
TEST_P(parameterized_spsm_csr, spsm_csr_i64_double_complex)
{
Arguments arg = setup_spsm_csr_arguments(GetParam());
SKIP_IF_DEBIANNOTFOUND(arg);
hipsparseStatus_t status = testing_spsm_csr<int64_t, int64_t, hipDoubleComplex>(arg);
EXPECT_EQ(status, HIPSPARSE_STATUS_SUCCESS);
}
TEST_P(parameterized_spsm_csr_bin, spsm_csr_bin_i32_float)
{
Arguments arg = setup_spsm_csr_arguments(GetParam());
SKIP_IF_DEBIANNOTFOUND(arg);
hipsparseStatus_t status = testing_spsm_csr<int32_t, int32_t, float>(arg);
EXPECT_EQ(status, HIPSPARSE_STATUS_SUCCESS);
}
TEST_P(parameterized_spsm_csr_bin, spsm_csr_bin_i64_double)
{
Arguments arg = setup_spsm_csr_arguments(GetParam());
SKIP_IF_DEBIANNOTFOUND(arg);
hipsparseStatus_t status = testing_spsm_csr<int64_t, int64_t, double>(arg);
EXPECT_EQ(status, HIPSPARSE_STATUS_SUCCESS);
}
INSTANTIATE_TEST_SUITE_P(spsm_csr,
parameterized_spsm_csr,
testing::Combine(testing::ValuesIn(spsm_csr_M_N_K_alpha_range),
testing::ValuesIn(spsm_csr_transA_range),
testing::ValuesIn(spsm_csr_transB_range),
testing::ValuesIn(spsm_csr_orderB_range),
testing::ValuesIn(spsm_csr_orderC_range),
testing::ValuesIn(spsm_csr_idxbase_range),
testing::ValuesIn(spsm_csr_diag_type_range),
testing::ValuesIn(spsm_csr_fill_mode_range),
testing::ValuesIn(spsm_csr_alg_range)));
INSTANTIATE_TEST_SUITE_P(spsm_csr_bin,
parameterized_spsm_csr_bin,
testing::Combine(testing::ValuesIn(spsm_csr_M_N_K_alpha_range),
testing::ValuesIn(spsm_csr_transA_range),
testing::ValuesIn(spsm_csr_transB_range),
testing::ValuesIn(spsm_csr_orderB_range),
testing::ValuesIn(spsm_csr_orderC_range),
testing::ValuesIn(spsm_csr_idxbase_range),
testing::ValuesIn(spsm_csr_diag_type_range),
testing::ValuesIn(spsm_csr_fill_mode_range),
testing::ValuesIn(spsm_csr_alg_range),
testing::ValuesIn(spsm_csr_bin)));
#endif
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