* 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>
#define private public
#define protected public
#include "kernel_operator.h"
#include "kernel_utils.h"
namespace AscendC {
template <typename InputDataType, typename OutputDataType, bool WithOffset = true>
class AntiQuantTest {
public:
__aicore__ inline AntiQuantTest() {}
__aicore__ inline void Init(GM_ADDR dstGm, GM_ADDR srcGm, GM_ADDR offsetGm, GM_ADDR scaleGm,
uint32_t elementCountOfInput, uint32_t elementCountOfOffset, uint32_t tmpBufferSize)
{
m_elementCountOfInput = elementCountOfInput;
m_elementCountOfOffset = elementCountOfOffset;
m_dstGlobal.SetGlobalBuffer((__gm__ OutputDataType*)dstGm);
m_srcGlobal.SetGlobalBuffer((__gm__ InputDataType*)srcGm);
m_offsetGlobal.SetGlobalBuffer((__gm__ OutputDataType*)offsetGm);
m_scaleGlobal.SetGlobalBuffer((__gm__ OutputDataType*)scaleGm);
m_pipe.InitBuffer(m_queInSrc, 1, elementCountOfInput * sizeof(InputDataType));
m_pipe.InitBuffer(m_queInOffset, 1, elementCountOfOffset * sizeof(OutputDataType));
m_pipe.InitBuffer(m_queInScale, 1, elementCountOfOffset * sizeof(OutputDataType));
m_pipe.InitBuffer(m_queOut, 1, elementCountOfInput * sizeof(OutputDataType));
m_pipe.InitBuffer(m_queTmp, 1, tmpBufferSize);
}
__aicore__ inline void Process()
{
CopyIn();
Compute();
CopyOut();
}
private:
__aicore__ inline void CopyIn()
{
LocalTensor<InputDataType> srcLocal = m_queInSrc.AllocTensor<InputDataType>();
DataCopy(srcLocal, m_srcGlobal, m_elementCountOfInput);
m_queInSrc.EnQue(srcLocal);
LocalTensor<OutputDataType> offsetLocal = m_queInOffset.AllocTensor<OutputDataType>();
DataCopy(offsetLocal, m_offsetGlobal, m_elementCountOfOffset);
m_queInOffset.EnQue(offsetLocal);
LocalTensor<OutputDataType> scaleLocal = m_queInScale.AllocTensor<OutputDataType>();
DataCopy(scaleLocal, m_scaleGlobal, m_elementCountOfOffset);
m_queInScale.EnQue(scaleLocal);
}
__aicore__ inline void Compute()
{
LocalTensor<InputDataType> srcLocal = m_queInSrc.DeQue<InputDataType>();
LocalTensor<OutputDataType> offsetLocal = m_queInOffset.DeQue<OutputDataType>();
LocalTensor<OutputDataType> scaleLocal = m_queInScale.DeQue<OutputDataType>();
LocalTensor<OutputDataType> dstLocal = m_queOut.AllocTensor<OutputDataType>();
LocalTensor<uint8_t> sharedTmpBuffer = m_queTmp.AllocTensor<uint8_t>();
AntiQuantShapeInfo shapeInfo{static_cast<uint32_t>(1), static_cast<uint32_t>(m_elementCountOfOffset),
static_cast<uint32_t>(1), static_cast<uint32_t>(m_elementCountOfOffset)};
if constexpr(WithOffset) {
AscendAntiQuant<InputDataType, OutputDataType, false>(dstLocal, srcLocal, offsetLocal, scaleLocal,
sharedTmpBuffer, m_elementCountOfInput / m_elementCountOfOffset, shapeInfo);
} else {
AscendAntiQuant<InputDataType, OutputDataType, false>(dstLocal, srcLocal, scaleLocal,
sharedTmpBuffer, m_elementCountOfInput / m_elementCountOfOffset, shapeInfo);
}
m_queInSrc.FreeTensor(srcLocal);
m_queInOffset.FreeTensor(offsetLocal);
m_queInScale.FreeTensor(scaleLocal);
m_queTmp.FreeTensor(sharedTmpBuffer);
m_queOut.EnQue(dstLocal);
}
__aicore__ inline void CopyOut()
{
LocalTensor<OutputDataType> dstLocal = m_queOut.DeQue<OutputDataType>();
DataCopy(m_dstGlobal, dstLocal, m_elementCountOfInput);
m_queOut.FreeTensor(dstLocal);
}
private:
TPipe m_pipe;
TQue<TPosition::VECIN, 1> m_queInSrc;
TQue<TPosition::VECIN, 1> m_queInOffset;
TQue<TPosition::VECIN, 1> m_queInScale;
TQue<TPosition::VECOUT, 1> m_queTmp;
TQue<TPosition::VECOUT, 1> m_queOut;
GlobalTensor<OutputDataType> m_dstGlobal;
GlobalTensor<InputDataType> m_srcGlobal;
GlobalTensor<OutputDataType> m_offsetGlobal;
GlobalTensor<OutputDataType> m_scaleGlobal;
uint32_t m_elementCountOfInput;
uint32_t m_elementCountOfOffset;
};
}
template <typename InputDataType, typename OutputDataType, bool WithOffset = true>
__global__ __aicore__ void testAntiQuant(GM_ADDR dst, GM_ADDR src, GM_ADDR offset, GM_ADDR scale,
uint32_t elementCountOfInput, uint32_t elementCountOfOffset, uint32_t tmpBufferSize)
{
AscendC::AntiQuantTest<InputDataType, OutputDataType, WithOffset> op;
op.Init(dst, src, offset, scale, elementCountOfInput, elementCountOfOffset, tmpBufferSize);
op.Process();
}
struct antiquantParams {
uint32_t elementCountOfInput;
uint32_t elementCountOfOffset;
uint32_t tmpBufferSize;
void (*cal_func)(GM_ADDR, GM_ADDR, GM_ADDR, GM_ADDR, uint32_t, uint32_t, uint32_t);
};
class AntiquantTestsuite : public testing::Test,
public testing::WithParamInterface<antiquantParams> {
protected:
void SetUp() {
AscendC::SetGCoreType(2);
}
void TearDown() {
AscendC::SetGCoreType(0);
}
};
INSTANTIATE_TEST_CASE_P(TEST_OPEARATION_ANTIQUANT, AntiquantTestsuite,
::testing::Values(
antiquantParams { 2048, 64, 1024, testAntiQuant<int8_t, half>},
antiquantParams { 2048, 64, 81920, testAntiQuant<int8_t, half>},
antiquantParams { 5888, 256, 81920, testAntiQuant<int8_t, half>},
antiquantParams { 12288, 96, 81920, testAntiQuant<int8_t, half>}
));
TEST_P(AntiquantTestsuite, testAntiquant)
{
auto param = GetParam();
uint8_t srcGm[param.elementCountOfInput] = {0};
uint8_t offsetGm[param.elementCountOfOffset * sizeof(half)] = {0};
uint8_t scaleGm[param.elementCountOfOffset * sizeof(half)] = {0};
uint8_t dstGm[param.elementCountOfInput * sizeof(half)] = {0};
param.cal_func(dstGm, srcGm, offsetGm, scaleGm,
param.elementCountOfInput, param.elementCountOfOffset, param.tmpBufferSize);
for (int32_t i = 0; i < param.elementCountOfInput; i++) {
EXPECT_EQ(dstGm[i], 0x00);
}
}
