* 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"
#include "kernel_utils.h"
using namespace std;
using namespace AscendC;
enum TestMode {
CAL_MODE,
BUF_CAL_MODE
};
template<typename DstT, typename SrcT, int32_t calCount, int32_t dataSize, TestMode mode>
class KernelIsNan {
public:
__aicore__ inline KernelIsNan()
{}
__aicore__ inline void Init(GM_ADDR dst_gm, GM_ADDR src_gm)
{
srcSize = dataSize;
dstSize = dataSize;
src_global.SetGlobalBuffer(reinterpret_cast<__gm__ SrcT *>(src_gm), srcSize);
dst_global.SetGlobalBuffer(reinterpret_cast<__gm__ DstT *>(dst_gm), dstSize);
pipe.InitBuffer(inQueue, 1, dataSize * sizeof(SrcT));
pipe.InitBuffer(outQueue, 1, dataSize * sizeof(DstT));
mask = calCount;
}
__aicore__ inline void Process()
{
AscendCUtils::SetOverflow(1);
CopyIn();
Compute();
CopyOut();
AscendCUtils::SetOverflow(0);
}
private:
__aicore__ inline void CopyIn()
{
LocalTensor<SrcT> srcLocal = inQueue.AllocTensor<SrcT>();
DataCopy(srcLocal, src_global, srcSize);
inQueue.EnQue(srcLocal);
}
__aicore__ inline void Compute()
{
LocalTensor<SrcT> srcLocal = inQueue.DeQue<SrcT>();
if constexpr (mode == CAL_MODE) {
if constexpr (std::is_same_v<DstT, bool>) {
LocalTensor<DstT> dstLocal = outQueue.AllocTensor<DstT>();
Duplicate((LocalTensor<int8_t> &)dstLocal, (int8_t)0, dataSize);
IsNan(dstLocal, srcLocal, calCount);
outQueue.EnQue(dstLocal);
} else {
LocalTensor<DstT> dstLocal = outQueue.AllocTensor<DstT>();
Duplicate(dstLocal, (DstT)0, dataSize);
IsNan(dstLocal, srcLocal, calCount);
outQueue.EnQue(dstLocal);
}
} else {
TBuf<TPosition::VECCALC> tbuf;
if constexpr (sizeof(SrcT) == sizeof(float)) {
pipe.InitBuffer(tbuf, dataSize * sizeof(float));
} else {
pipe.InitBuffer(tbuf, dataSize * sizeof(float) * 4);
}
LocalTensor<uint8_t> tmpLocal = tbuf.Get<uint8_t>();
if constexpr (std::is_same_v<DstT, bool>) {
LocalTensor<DstT> dstLocal = outQueue.AllocTensor<DstT>();
Duplicate((LocalTensor<int8_t> &)dstLocal, (int8_t)0, dataSize);
IsNan(dstLocal, srcLocal, tmpLocal, calCount);
outQueue.EnQue(dstLocal);
} else {
LocalTensor<DstT> dstLocal = outQueue.AllocTensor<DstT>();
Duplicate(dstLocal, (DstT)0, dataSize);
IsNan(dstLocal, srcLocal, tmpLocal, calCount);
outQueue.EnQue(dstLocal);
}
}
inQueue.FreeTensor(srcLocal);
}
__aicore__ inline void CopyOut()
{
LocalTensor<DstT> dstLocal = outQueue.DeQue<DstT>();
DataCopy(dst_global, dstLocal, dataSize);
outQueue.FreeTensor(dstLocal);
}
private:
GlobalTensor<SrcT> src_global;
GlobalTensor<DstT> dst_global;
TPipe pipe;
TQue<TPosition::VECIN, 1> inQueue;
TQue<TPosition::VECOUT, 1> outQueue;
uint32_t srcSize = 0;
uint32_t dstSize = 0;
uint32_t mask;
};
struct IsNanParams {
void (*CalFunc)();
};
template<typename DstT, typename SrcT, int32_t calCount, int32_t dataSize, TestMode mode>
void RunCase() {
int src_byte_size = sizeof(SrcT);
int dst_byte_size = sizeof(DstT);
uint8_t dstGm[calCount * dst_byte_size] = {0};
uint8_t srcGm[calCount * src_byte_size] = {0};
KernelIsNan<DstT, SrcT, calCount, dataSize, mode> op;
op.Init(dstGm, srcGm);
op.Process();
}
class IsNanTestsuite : public testing::TestWithParam<IsNanParams> {
protected:
void SetUp() {}
void TearDown() {}
};
INSTANTIATE_TEST_CASE_P(TEST_OPEARATION_ADVANCE_API_ISINF, IsNanTestsuite,
::testing::Values(
IsNanParams { RunCase<float, float, 1024, 1024, CAL_MODE> },
IsNanParams { RunCase<float, float, 1023, 1024, CAL_MODE> },
IsNanParams { RunCase<float, float, 512, 1024, CAL_MODE> },
IsNanParams { RunCase<float, float, 1, 1024, CAL_MODE> },
IsNanParams { RunCase<bool, float, 1024, 1024, CAL_MODE> },
IsNanParams { RunCase<bool, float, 1023, 1024, CAL_MODE> },
IsNanParams { RunCase<bool, float, 512, 1024, CAL_MODE> },
IsNanParams { RunCase<bool, float, 1, 1024, CAL_MODE> },
IsNanParams { RunCase<half, half, 1024, 1024, CAL_MODE> },
IsNanParams { RunCase<half, half, 1023, 1024, CAL_MODE> },
IsNanParams { RunCase<half, half, 512, 1024, CAL_MODE> },
IsNanParams { RunCase<half, half, 1, 1024, CAL_MODE> },
IsNanParams { RunCase<bool, half, 1024, 1024, CAL_MODE> },
IsNanParams { RunCase<bool, half, 1023, 1024, CAL_MODE> },
IsNanParams { RunCase<bool, half, 512, 1024, CAL_MODE> },
IsNanParams { RunCase<bool, half, 1, 1024, CAL_MODE> },
IsNanParams { RunCase<float, float, 1024, 1024, BUF_CAL_MODE> },
IsNanParams { RunCase<float, float, 1023, 1024, BUF_CAL_MODE> },
IsNanParams { RunCase<float, float, 512, 1024, BUF_CAL_MODE> },
IsNanParams { RunCase<float, float, 1, 1024, BUF_CAL_MODE> },
IsNanParams { RunCase<bool, float, 1024, 1024, BUF_CAL_MODE> },
IsNanParams { RunCase<bool, float, 1023, 1024, BUF_CAL_MODE> },
IsNanParams { RunCase<bool, float, 512, 1024, BUF_CAL_MODE> },
IsNanParams { RunCase<bool, float, 1, 1024, BUF_CAL_MODE> },
IsNanParams { RunCase<half, half, 1024, 1024, BUF_CAL_MODE> },
IsNanParams { RunCase<half, half, 1023, 1024, BUF_CAL_MODE> },
IsNanParams { RunCase<half, half, 512, 1024, BUF_CAL_MODE> },
IsNanParams { RunCase<half, half, 1, 1024, BUF_CAL_MODE> },
IsNanParams { RunCase<bool, half, 1024, 1024, BUF_CAL_MODE> },
IsNanParams { RunCase<bool, half, 1023, 1024, BUF_CAL_MODE> },
IsNanParams { RunCase<bool, half, 512, 1024, BUF_CAL_MODE> },
IsNanParams { RunCase<bool, half, 1, 1024, BUF_CAL_MODE> }
)
);
TEST_P(IsNanTestsuite, IsNanTestCase)
{
auto param = GetParam();
param.CalFunc();
}
