* Copyright (c) 2025 Huawei Technologies Co., Ltd.
* This program is free software, you can redistribute it and/or modify it under the terms and conditions of
* CANN Open Software License Agreement Version 2.0 (the "License").
* Please refer to the License for details. You may not use this file except in compliance with the License.
* THIS SOFTWARE IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OF ANY KIND, EITHER EXPRESS OR IMPLIED,
* INCLUDING BUT NOT LIMITED TO NON-INFRINGEMENT, MERCHANTABILITY, OR FITNESS FOR A PARTICULAR PURPOSE.
* See LICENSE in the root of the software repository for the full text of the License.
*/
#include <vector>
#include <array>
#include "gtest/gtest.h"
#include "../../../op_api/aclnn_addcdiv.h"
#include "op_api_ut_common/op_api_ut.h"
#include "op_api_ut_common/scalar_desc.h"
#include "op_api_ut_common/tensor_desc.h"
#include "op_api_ut_common/inner/types.h"
#include "opdev/platform.h"
using namespace std;
using namespace op;
class l2_addcdiv_test : public testing::Test {
protected:
static void SetUpTestCase()
{
cout << "addcdiv_test SetUp" << endl;
}
static void TearDownTestCase()
{
cout << "addcdiv_test TearDown" << endl;
}
};
TEST_F(l2_addcdiv_test, case_1)
{
auto input = TensorDesc({3, 3}, ACL_FLOAT, ACL_FORMAT_ND).ValueRange(-1, 1);
auto tensor1 = TensorDesc({3, 3}, ACL_FLOAT, ACL_FORMAT_ND).ValueRange(-1, 1);
auto tensor2 = TensorDesc({3, 3}, ACL_FLOAT, ACL_FORMAT_ND).ValueRange(-1, 1);
auto out = TensorDesc({3, 3}, ACL_FLOAT, ACL_FORMAT_ND);
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACL_SUCCESS);
}
TEST_F(l2_addcdiv_test, case_2)
{
auto input = nullptr;
auto tensor1 = TensorDesc({3}, ACL_FLOAT, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{4, 4, 4});
auto tensor2 = TensorDesc({3}, ACL_FLOAT, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 1, 1});
auto out = TensorDesc({3}, ACL_FLOAT, ACL_FORMAT_ND);
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACLNN_ERR_PARAM_NULLPTR);
}
TEST_F(l2_addcdiv_test, case_3)
{
auto input = TensorDesc({3}, ACL_FLOAT, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 2, 3});
auto tensor1 = nullptr;
auto tensor2 = TensorDesc({3}, ACL_FLOAT, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 1, 1});
auto out = TensorDesc({3}, ACL_FLOAT, ACL_FORMAT_ND);
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACLNN_ERR_PARAM_NULLPTR);
}
TEST_F(l2_addcdiv_test, case_4)
{
auto input = TensorDesc({3}, ACL_FLOAT, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 2, 3});
auto tensor1 = TensorDesc({3}, ACL_FLOAT, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 1, 1});
auto tensor2 = nullptr;
auto out = TensorDesc({3}, ACL_FLOAT, ACL_FORMAT_ND);
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACLNN_ERR_PARAM_NULLPTR);
}
TEST_F(l2_addcdiv_test, case_5)
{
auto input = TensorDesc({3}, ACL_FLOAT, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 2, 3});
auto tensor1 = TensorDesc({3}, ACL_FLOAT, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 1, 1});
auto tensor2 = TensorDesc({3}, ACL_FLOAT, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 1, 1});
auto out = TensorDesc({3}, ACL_FLOAT, ACL_FORMAT_ND);
auto scalar = nullptr;
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACLNN_ERR_PARAM_NULLPTR);
}
TEST_F(l2_addcdiv_test, case_6)
{
auto input = TensorDesc({3}, ACL_FLOAT, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 2, 3});
auto tensor1 = TensorDesc({3}, ACL_FLOAT, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 1, 1});
auto tensor2 = TensorDesc({3}, ACL_FLOAT, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 1, 1});
auto out = nullptr;
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACLNN_ERR_PARAM_NULLPTR);
}
TEST_F(l2_addcdiv_test, case_7)
{
auto input = TensorDesc({3}, ACL_FLOAT, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 2, 3});
auto tensor1 = TensorDesc({3}, ACL_DT_UNDEFINED, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{4, 4, 4});
auto tensor2 = TensorDesc({3}, ACL_FLOAT, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 1, 1});
auto out = TensorDesc({3}, ACL_FLOAT, ACL_FORMAT_ND);
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACLNN_ERR_PARAM_INVALID);
}
TEST_F(l2_addcdiv_test, case_8)
{
auto input = TensorDesc({3}, ACL_DT_UNDEFINED, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 2, 3});
auto tensor1 = TensorDesc({3}, ACL_FLOAT, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{4, 4, 4});
auto tensor2 = TensorDesc({3}, ACL_FLOAT, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 1, 1});
auto out = TensorDesc({3}, ACL_FLOAT, ACL_FORMAT_ND);
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACLNN_ERR_PARAM_INVALID);
}
TEST_F(l2_addcdiv_test, case_9)
{
auto input = TensorDesc({3}, ACL_FLOAT, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 2, 3});
auto tensor1 = TensorDesc({3}, ACL_FLOAT, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{4, 4, 4});
auto tensor2 = TensorDesc({3}, ACL_FLOAT, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 1, 1});
auto out = TensorDesc({3}, ACL_INT64, ACL_FORMAT_ND);
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACLNN_ERR_PARAM_INVALID);
}
TEST_F(l2_addcdiv_test, case_10)
{
auto input = TensorDesc({3, 3, 3, 3, 3, 3, 3, 3, 3}, ACL_FLOAT, ACL_FORMAT_NCDHW);
auto tensor1 = TensorDesc({3, 3, 3, 3, 3, 3, 3, 3, 3}, ACL_FLOAT, ACL_FORMAT_NCDHW);
auto tensor2 = TensorDesc({3, 3, 3, 3, 3, 3, 3, 3, 3}, ACL_FLOAT, ACL_FORMAT_NCDHW);
auto out = TensorDesc({3, 3, 3, 3, 3, 3, 3, 3, 3}, ACL_FLOAT, ACL_FORMAT_NCDHW);
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACLNN_ERR_PARAM_INVALID);
}
TEST_F(l2_addcdiv_test, case_11)
{
auto input = TensorDesc({4, 2, 3}, ACL_FLOAT, ACL_FORMAT_ND);
auto tensor1 = TensorDesc({4, 3}, ACL_FLOAT, ACL_FORMAT_ND);
auto tensor2 = TensorDesc({2, 3}, ACL_FLOAT, ACL_FORMAT_ND);
auto out = TensorDesc({4, 2, 3}, ACL_FLOAT, ACL_FORMAT_ND);
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACLNN_ERR_PARAM_INVALID);
}
TEST_F(l2_addcdiv_test, case_12)
{
auto input = TensorDesc({4, 2, 3}, ACL_FLOAT, ACL_FORMAT_ND);
auto tensor1 = TensorDesc({4, 3}, ACL_FLOAT, ACL_FORMAT_ND);
auto tensor2 = TensorDesc({3}, ACL_FLOAT, ACL_FORMAT_ND);
auto out = TensorDesc({4, 2, 3}, ACL_FLOAT, ACL_FORMAT_ND);
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACLNN_ERR_PARAM_INVALID);
}
TEST_F(l2_addcdiv_test, case_13)
{
auto input = TensorDesc({4, 2, 3}, ACL_FLOAT, ACL_FORMAT_ND);
auto tensor1 = TensorDesc({4, 3}, ACL_FLOAT, ACL_FORMAT_ND);
auto tensor2 = TensorDesc({3}, ACL_FLOAT, ACL_FORMAT_ND);
auto out = TensorDesc({4, 2, 3}, ACL_FLOAT, ACL_FORMAT_ND);
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACLNN_ERR_PARAM_INVALID);
}
TEST_F(l2_addcdiv_test, case_14)
{
auto input = TensorDesc({4, 1, 3}, ACL_FLOAT, ACL_FORMAT_ND);
auto tensor1 = TensorDesc({4, 0, 3}, ACL_FLOAT, ACL_FORMAT_ND);
auto tensor2 = TensorDesc({3}, ACL_FLOAT, ACL_FORMAT_ND);
auto out = TensorDesc({4, 0, 3}, ACL_FLOAT, ACL_FORMAT_ND);
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACL_SUCCESS);
}
TEST_F(l2_addcdiv_test, case_16)
{
auto input = TensorDesc({3}, ACL_FLOAT16, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 2, 3});
auto tensor1 = TensorDesc({3}, ACL_FLOAT16, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{4, 4, 4});
auto tensor2 = TensorDesc({3}, ACL_FLOAT16, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 1, 1});
auto out = TensorDesc({3}, ACL_FLOAT16, ACL_FORMAT_ND);
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACL_SUCCESS);
}
TEST_F(l2_addcdiv_test, case_17)
{
auto input = TensorDesc({3}, ACL_BF16, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 2, 3});
auto tensor1 = TensorDesc({3}, ACL_BF16, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{4, 4, 4});
auto tensor2 = TensorDesc({3}, ACL_BF16, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 1, 1});
auto out = TensorDesc({3}, ACL_BF16, ACL_FORMAT_ND);
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
if (GetCurrentPlatformInfo().GetSocVersion() == SocVersion::ASCEND910B) {
EXPECT_EQ(aclRet, ACL_SUCCESS);
} else {
EXPECT_EQ(aclRet, ACLNN_ERR_PARAM_INVALID);
}
}
TEST_F(l2_addcdiv_test, case_18)
{
auto input = TensorDesc({3}, ACL_INT32, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 2, 3});
auto tensor1 = TensorDesc({3}, ACL_INT32, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{4, 4, 4});
auto tensor2 = TensorDesc({3}, ACL_INT32, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 1, 1});
auto out = TensorDesc({3}, ACL_INT32, ACL_FORMAT_ND);
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACLNN_ERR_PARAM_INVALID);
}
TEST_F(l2_addcdiv_test, case_20)
{
auto input = TensorDesc({3}, ACL_INT16, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 2, 3});
auto tensor1 = TensorDesc({3}, ACL_INT16, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{4, 4, 4});
auto tensor2 = TensorDesc({3}, ACL_INT16, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 1, 1});
auto out = TensorDesc({3}, ACL_INT16, ACL_FORMAT_ND);
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACLNN_ERR_PARAM_INVALID);
}
TEST_F(l2_addcdiv_test, case_21)
{
auto input = TensorDesc({3}, ACL_INT8, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 2, 3});
auto tensor1 = TensorDesc({3}, ACL_INT8, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{4, 4, 4});
auto tensor2 = TensorDesc({3}, ACL_INT8, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 1, 1});
auto out = TensorDesc({3}, ACL_INT8, ACL_FORMAT_ND);
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACLNN_ERR_PARAM_INVALID);
}
TEST_F(l2_addcdiv_test, case_22)
{
auto input = TensorDesc({3}, ACL_UINT8, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 2, 3});
auto tensor1 = TensorDesc({3}, ACL_UINT8, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{4, 4, 4});
auto tensor2 = TensorDesc({3}, ACL_UINT8, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 1, 1});
auto out = TensorDesc({3}, ACL_UINT8, ACL_FORMAT_ND);
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACLNN_ERR_PARAM_INVALID);
}
TEST_F(l2_addcdiv_test, case_23)
{
auto input = TensorDesc({3}, ACL_BOOL, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 2, 3});
auto tensor1 = TensorDesc({3}, ACL_BOOL, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{4, 4, 4});
auto tensor2 = TensorDesc({3}, ACL_BOOL, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 1, 1});
auto out = TensorDesc({3}, ACL_BOOL, ACL_FORMAT_ND);
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACLNN_ERR_PARAM_INVALID);
}
TEST_F(l2_addcdiv_test, case_24)
{
auto input = TensorDesc({3}, ACL_COMPLEX64, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 2, 3});
auto tensor1 = TensorDesc({3}, ACL_COMPLEX64, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{4, 4, 4});
auto tensor2 = TensorDesc({3}, ACL_COMPLEX64, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 1, 1});
auto out = TensorDesc({3}, ACL_COMPLEX64, ACL_FORMAT_ND);
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACLNN_ERR_PARAM_INVALID);
}
TEST_F(l2_addcdiv_test, case_25)
{
auto input = TensorDesc({3}, ACL_COMPLEX128, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 2, 3});
auto tensor1 = TensorDesc({3}, ACL_COMPLEX128, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{4, 4, 4});
auto tensor2 = TensorDesc({3}, ACL_COMPLEX128, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 1, 1});
auto out = TensorDesc({3}, ACL_COMPLEX128, ACL_FORMAT_ND);
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACLNN_ERR_PARAM_INVALID);
}
TEST_F(l2_addcdiv_test, case_26)
{
auto input = TensorDesc({3}, ACL_DT_UNDEFINED, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 2, 3});
auto tensor1 = TensorDesc({3}, ACL_DT_UNDEFINED, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{4, 4, 4});
auto tensor2 = TensorDesc({3}, ACL_DT_UNDEFINED, ACL_FORMAT_ND).ValueRange(0, 10).Value(vector<float>{1, 1, 1});
auto out = TensorDesc({3}, ACL_DT_UNDEFINED, ACL_FORMAT_ND);
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACLNN_ERR_PARAM_INVALID);
}
TEST_F(l2_addcdiv_test, case_27)
{
auto input = TensorDesc({3, 3, 3, 3}, ACL_FLOAT, ACL_FORMAT_NCHW);
auto tensor1 = TensorDesc({3, 3, 3, 3}, ACL_FLOAT, ACL_FORMAT_NCHW);
auto tensor2 = TensorDesc({3, 3, 3, 3}, ACL_FLOAT, ACL_FORMAT_NCHW);
auto out = TensorDesc({3, 3, 3, 3}, ACL_FLOAT, ACL_FORMAT_NCHW);
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACLNN_SUCCESS);
}
TEST_F(l2_addcdiv_test, case_28)
{
auto input = TensorDesc({3, 3, 3, 3}, ACL_FLOAT, ACL_FORMAT_NHWC);
auto tensor1 = TensorDesc({3, 3, 3, 3}, ACL_FLOAT, ACL_FORMAT_NHWC);
auto tensor2 = TensorDesc({3, 3, 3, 3}, ACL_FLOAT, ACL_FORMAT_NHWC);
auto out = TensorDesc({3, 3, 3, 3}, ACL_FLOAT, ACL_FORMAT_NHWC);
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACLNN_SUCCESS);
}
TEST_F(l2_addcdiv_test, case_29)
{
auto input = TensorDesc({3, 3, 3, 3}, ACL_FLOAT, ACL_FORMAT_HWCN);
auto tensor1 = TensorDesc({3, 3, 3, 3}, ACL_FLOAT, ACL_FORMAT_HWCN);
auto tensor2 = TensorDesc({3, 3, 3, 3}, ACL_FLOAT, ACL_FORMAT_HWCN);
auto out = TensorDesc({3, 3, 3, 3}, ACL_FLOAT, ACL_FORMAT_HWCN);
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACLNN_SUCCESS);
}
TEST_F(l2_addcdiv_test, case_30)
{
auto input = TensorDesc({3, 3, 3, 3, 3}, ACL_FLOAT, ACL_FORMAT_NDHWC);
auto tensor1 = TensorDesc({3, 3, 3, 3, 3}, ACL_FLOAT, ACL_FORMAT_NDHWC);
auto tensor2 = TensorDesc({3, 3, 3, 3, 3}, ACL_FLOAT, ACL_FORMAT_NDHWC);
auto out = TensorDesc({3, 3, 3, 3, 3}, ACL_FLOAT, ACL_FORMAT_NDHWC);
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACLNN_SUCCESS);
}
TEST_F(l2_addcdiv_test, case_31)
{
auto input = TensorDesc({3, 3, 3, 3, 3}, ACL_FLOAT, ACL_FORMAT_NCDHW);
auto tensor1 = TensorDesc({3, 3, 3, 3, 3}, ACL_FLOAT, ACL_FORMAT_NCDHW);
auto tensor2 = TensorDesc({3, 3, 3, 3, 3}, ACL_FLOAT, ACL_FORMAT_NCDHW);
auto out = TensorDesc({3, 3, 3, 3, 3}, ACL_FLOAT, ACL_FORMAT_NCDHW);
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACLNN_SUCCESS);
}
TEST_F(l2_addcdiv_test, l2_addcdiv_test_case_32_Test)
{
auto input = TensorDesc({2, 4}, ACL_FLOAT, ACL_FORMAT_NCDHW, {1, 2}, 0, {4, 2});
auto tensor1 = TensorDesc({2, 4}, ACL_FLOAT, ACL_FORMAT_NCDHW, {1, 2}, 0, {4, 2});
auto tensor2 = TensorDesc({2, 4}, ACL_FLOAT, ACL_FORMAT_NCDHW, {1, 2}, 0, {4, 2});
auto out = TensorDesc({2, 4}, ACL_FLOAT, ACL_FORMAT_NCDHW);
auto scalar = ScalarDesc(1.0f);
auto ut = OP_API_UT(aclnnAddcdiv, INPUT(input, tensor1, tensor2, scalar), OUTPUT(out));
uint64_t workspaceSize = 0;
aclnnStatus aclRet = ut.TestGetWorkspaceSize(&workspaceSize);
EXPECT_EQ(aclRet, ACLNN_SUCCESS);
}
