* 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 <gtest/gtest.h>
#include "kernel_operator.h"
using namespace AscendC;
enum TestMode {
NORMAL_MODE,
CAL_MODE,
BUF_MODE,
BUF_CAL_MODE
};
class TEST_FMOD : public testing::Test {
protected:
void SetUp()
{
AscendC::SetGCoreType(2);
}
void TearDown()
{
AscendC::SetGCoreType(0);
}
};
template <typename T>
void MainVecFmodDemo(__gm__ uint8_t *__restrict__ dstGm, __gm__ uint8_t *__restrict__ src0Gm,
__gm__ uint8_t *__restrict__ src1Gm, uint32_t dataSize, TestMode testMode)
{
TPipe tpipe;
GlobalTensor<T> input0Global;
GlobalTensor<T> input1Global;
GlobalTensor<T> outputGlobal;
input0Global.SetGlobalBuffer(reinterpret_cast<__gm__ T *>(src0Gm), dataSize);
input1Global.SetGlobalBuffer(reinterpret_cast<__gm__ T *>(src1Gm), dataSize);
outputGlobal.SetGlobalBuffer(reinterpret_cast<__gm__ T *>(dstGm), dataSize);
TBuf<TPosition::VECCALC> tbuf1;
tpipe.InitBuffer(tbuf1, dataSize * sizeof(T));
LocalTensor<T> input0Local = tbuf1.Get<T>();
TBuf<TPosition::VECCALC> tbuf2;
tpipe.InitBuffer(tbuf2, dataSize * sizeof(T));
LocalTensor<T> input1Local = tbuf2.Get<T>();
TBuf<TPosition::VECCALC> tbuf3;
tpipe.InitBuffer(tbuf3, dataSize * sizeof(T));
LocalTensor<T> outputLocal = tbuf3.Get<T>();
DataCopy(input0Local, input0Global, dataSize);
DataCopy(input1Local, input1Global, dataSize);
SetFlag<HardEvent::MTE2_V>(EVENT_ID0);
WaitFlag<HardEvent::MTE2_V>(EVENT_ID0);
if (testMode == NORMAL_MODE) {
Fmod<T>(outputLocal, input0Local, input1Local);
} else if (testMode == CAL_MODE) {
Fmod<T>(outputLocal, input0Local, input1Local, dataSize);
} else {
TBuf<TPosition::VECCALC> tbuf4;
if (sizeof(T) == sizeof(float)) {
tpipe.InitBuffer(tbuf4, dataSize * sizeof(float));
} else {
tpipe.InitBuffer(tbuf4, dataSize * sizeof(float) * 4);
}
LocalTensor<uint8_t> tmpLocal = tbuf4.Get<uint8_t>();
if (testMode == BUF_MODE) {
Fmod<T>(outputLocal, input0Local, input1Local, tmpLocal);
} else if (testMode == BUF_CAL_MODE) {
Fmod<T>(outputLocal, input0Local, input1Local, tmpLocal, dataSize);
}
}
SetFlag<HardEvent::V_MTE3>(EVENT_ID0);
WaitFlag<HardEvent::V_MTE3>(EVENT_ID0);
DataCopy(outputGlobal, outputLocal, dataSize);
PipeBarrier<PIPE_ALL>();
}
#define VEC_FMOD_LEVEL2_TESTCASE(DATA_TYPE, TEST_MODE, DATA_SIZE) \
TEST_F(TEST_FMOD, Fmod##DATA_TYPE##TEST_MODE##DATA_SIZE##Case) \
{ \
uint32_t dataSize = DATA_SIZE; \
uint8_t input0Gm[dataSize * sizeof(DATA_TYPE)] = {0}; \
uint8_t input1Gm[dataSize * sizeof(DATA_TYPE)] = {0}; \
uint8_t outputGm[dataSize * sizeof(DATA_TYPE)] = {0}; \
\
MainVecFmodDemo<DATA_TYPE>(outputGm, input0Gm, input1Gm , dataSize, TEST_MODE); \
\
for (uint32_t i = 0; i < dataSize; i++) { \
EXPECT_EQ(outputGm[i], 0x00); \
} \
}
VEC_FMOD_LEVEL2_TESTCASE(float, NORMAL_MODE, 256);
VEC_FMOD_LEVEL2_TESTCASE(float, CAL_MODE, 256);
VEC_FMOD_LEVEL2_TESTCASE(float, BUF_MODE, 256);
VEC_FMOD_LEVEL2_TESTCASE(float, BUF_CAL_MODE, 256);
VEC_FMOD_LEVEL2_TESTCASE(half, NORMAL_MODE, 256);
VEC_FMOD_LEVEL2_TESTCASE(half, CAL_MODE, 256);
VEC_FMOD_LEVEL2_TESTCASE(half, BUF_MODE, 256);
VEC_FMOD_LEVEL2_TESTCASE(half, BUF_CAL_MODE, 256);
