本文分享自華爲雲社區《Ascend C 自定義PRelu算子》,作者: jackwangcumt。
1 PRelu算子概述
PReLU是 Parametric Rectified Linear Unit的縮寫,首次由何凱明團隊提出,和LeakyReLU非常類似,是Relu的改進版本,在幾乎沒有增加額外參數的前提下既可以提升模型的擬合能力,又能減小過擬合風險。PReLU的數學表達式我們可以參考pytorch中PReLU的描述(https://pytorch.org/docs/2.1/generated/torch.nn.PReLU.html#prelu):
2 Ascend C自定義算子
基於Ascend C進行自定義算子開發之前,需要成功基於昇騰設備安裝相關的驅動、固件以及開發者套件。我之前安裝的開發者套件版本過低,編譯運行官方的Sample部分示例會報錯,因此,需要重新安裝一個8.0新版本,依次用root執行如下命令:
# 卸載 cann-toolkit_7.0.RC1 root@atlas500ai:/home/kzroot/mysoft# ./Ascend-cann-toolkit_7.0.RC1_linux-aarch64.run --uninstall # 清空遺留文件 rm -rf /usr/local/Ascend/ascend-toolkit/* # 安裝 cann-toolkit_8.0.RC1.alpha002 ./Ascend-cann-toolkit_8.0.RC1.alpha002_linux-aarch64.run --install --install-for-all --quiet #安裝依賴protobuf pip3 install protobuf==3.20.0
在一個目錄下新建單算子工程描述文件 PReluCustom.json ,內容參考如下:
[
{
"op": "PReluCustom",
"language": "cpp",
"input_desc": [
{
"name": "x",
"param_type": "required",
"format": [
"ND"
],
"type": [
"float"
]
}
],
"output_desc": [
{
"name": "y",
"param_type": "required",
"format": [
"ND"
],
"type": [
"float"
]
}
],
"attr": [
{
"name": "alpha",
"param_type": "optional",
"type": "float",
"default_value": "0.002"
}
]
}
]
用開發者套件中內置的算子工程生成工具msopgen ,通過描述文件自動生成單算子工程代碼目錄:
/usr/local/Ascend/ascend-toolkit/8.0.RC1.alpha002/python/site-packages/bin/msopgen gen -i ./PReluCustom.json -c ai_core-Ascend310P3 -lan cpp -out ./PReluCustom
執行成功後,會基於C++語言生成單算子工程代碼目錄PReluCustom,其中包含的CMakePresets.json文件,有幾個重要的配置項,特別是開發者套件安裝的路徑ASCEND_CANN_PACKAGE_PATH,需要根據本地情況進行修改,我這裏是 /usr/local/Ascend/ascend-toolkit/latest 否則會出現編譯錯誤,我這裏修改的部分代碼如下:
{
"version": 1,
"cmakeMinimumRequired": {
"major": 3,
"minor": 19,
"patch": 0
},
"configurePresets": [
{
"name": "default",
"displayName": "Default Config",
"description": "Default build using Unix Makefiles generator",
"generator": "Unix Makefiles",
"binaryDir": "${sourceDir}/build_out",
"cacheVariables": {
"CMAKE_BUILD_TYPE": {
"type": "STRING",
"value": "Release"
},
"ENABLE_SOURCE_PACKAGE": {
"type": "BOOL",
"value": "True"
},
"ENABLE_BINARY_PACKAGE": {
"type": "BOOL",
"value": "True"
},
"ASCEND_COMPUTE_UNIT": {
"type": "STRING",
"value": "ascend310p"
},
"ENABLE_TEST": {
"type": "BOOL",
"value": "True"
},
"vendor_name": {
"type": "STRING",
"value": "customize"
},
"ASCEND_CANN_PACKAGE_PATH": {
"type": "PATH",
"value": "/usr/local/Ascend/ascend-toolkit/latest"
},
"ASCEND_PYTHON_EXECUTABLE": {
"type": "STRING",
"value": "python3"
},
"CMAKE_INSTALL_PREFIX": {
"type": "PATH",
"value": "${sourceDir}/build_out"
},
"ENABLE_CROSS_COMPILE": {
"type": "BOOL",
"value": "False"
},
"CMAKE_CROSS_PLATFORM_COMPILER": {
"type": "PATH",
"value": "/usr/bin/aarch64-linux-gnu-g++"
}
}
}
]
}
其中的vendor_name 可以根據自己的情況進行修改,默認的算子部署後會放於customize 目錄下,這裏可以修改,比如改成jackwangcumt。而且單算子工程每次部署會進行覆蓋,因此,這裏需要注意一下。生成的p_relu_custom.cpp文件,重點的算子計算爲:
__aicore__ inline void Compute(int32_t progress)
{
// deque input tensors from VECIN queue
LocalTensor<float> xLocal = inQueueX.DeQue<float>();
LocalTensor<float> yLocal = outQueueY.AllocTensor<float>();
LocalTensor<float> tmpTensor1 = tmpBuffer1.Get<float>();
float inputVal = 0.0;
Maxs(tmpTensor1, xLocal, inputVal, this->tileLength); // x >= 0 --> x
// x < 0
Mins(xLocal, xLocal, inputVal, this->tileLength);
Muls(xLocal, xLocal, this->alpha, this->tileLength);
Add(yLocal, xLocal, tmpTensor1, this->tileLength);
outQueueY.EnQue<float>(yLocal);
// free input tensors for reuse
inQueueX.FreeTensor(xLocal);
}
這裏通過內置的原生算子來分別處理輸入x<0和x>=0兩個部分的數據處理,再通過Add將兩個部分合並,得到最終的數據。在op_host目錄下的p_relu_custom_tiling.h代碼如下所示:
#include "register/tilingdata_base.h"
namespace optiling {
BEGIN_TILING_DATA_DEF(TilingData)
TILING_DATA_FIELD_DEF(uint32_t, totalLength);
TILING_DATA_FIELD_DEF(uint32_t, tileNum);
TILING_DATA_FIELD_DEF(float, alpha);
END_TILING_DATA_DEF;
REGISTER_TILING_DATA_CLASS(PReluCustom, TilingData)
}
p_relu_custom.cpp 核心代碼如下所示:
#include "p_relu_custom_tiling.h"
#include "register/op_def_registry.h"
namespace optiling {
const uint32_t BLOCK_DIM = 8;
const uint32_t TILE_NUM = 16 ; // 這個數可能影響測試是否通過
static ge::graphStatus TilingFunc(gert::TilingContext* context)
{
TilingData tiling;
uint32_t totalLength = context->GetInputTensor(0)->GetShapeSize();
const gert::RuntimeAttrs *attrs = context->GetAttrs();
const float *alpha = attrs->GetAttrPointer<float>(0);
context->SetBlockDim(BLOCK_DIM);
tiling.set_totalLength(totalLength);
tiling.set_tileNum(TILE_NUM);
tiling.set_alpha(*alpha);
tiling.SaveToBuffer(context->GetRawTilingData()->GetData(), context->GetRawTilingData()->GetCapacity());
context->GetRawTilingData()->SetDataSize(tiling.GetDataSize());
size_t *currentWorkspace = context->GetWorkspaceSizes(1);
currentWorkspace[0] = 0;
return ge::GRAPH_SUCCESS;
}
}
namespace ge {
static ge::graphStatus InferShape(gert::InferShapeContext* context)
{
const gert::Shape* x1_shape = context->GetInputShape(0);
gert::Shape* y_shape = context->GetOutputShape(0);
*y_shape = *x1_shape;
return GRAPH_SUCCESS;
}
}
namespace ops {
class PReluCustom : public OpDef {
public:
explicit PReluCustom(const char* name) : OpDef(name)
{
this->Input("x")
.ParamType(REQUIRED)
.DataType({ge::DT_FLOAT})
.Format({ge::FORMAT_ND})
.UnknownShapeFormat({ge::FORMAT_ND});
this->Output("y")
.ParamType(REQUIRED)
.DataType({ge::DT_FLOAT})
.Format({ge::FORMAT_ND})
.UnknownShapeFormat({ge::FORMAT_ND});
this->Attr("alpha").AttrType(OPTIONAL).Float(0.002);
this->SetInferShape(ge::InferShape);
this->AICore()
.SetTiling(optiling::TilingFunc);
this->AICore().AddConfig("ascend310p");
}
};
OP_ADD(PReluCustom);
}
執行如下命令,編譯算子工程:
root@atlas500ai:/home/kzroot/mysoft/myAscendC/PReluSample/PReluCustom# bash build.sh
Self-extractable archive "custom_opp_ubuntu_aarch64.run" successfully created. 則表明編譯成功。執行如下命令進行算子部署:
PReluCustom# ./build_out/custom_opp_ubuntu_aarch64.run
3 Ascend C自定義算子驗證
基於Ascend C 自定義算子需要進行正確性驗證,這裏新建一個AclNNInvocation目錄(可以參考官方示例中的相關內容),目錄結構如下所示:
其中的gen_data.py用於生成測試的輸入和輸出數據,verity_result.py用於驗證精度。gen_data.py內容如下所示:
import numpy as np
import os
def gen_golden_data_simple():
alpha = np.array(0.002, dtype=np.float32)
input_x = np.random.uniform(-100, 100, [8, 200, 1024]).astype(np.float32)
golden = np.where(input_x >= 0, input_x, input_x * alpha).astype(np.float32)
os.system("mkdir -p input")
os.system("mkdir -p output")
input_x.tofile("./input/input_x.bin")
golden.tofile("./output/golden.bin")
if __name__ == "__main__":
gen_golden_data_simple()
src目錄下的CMakeLists.txt有一個環境變量可能需要修改,即 set(CUST_PKG_PATH "${INC_PATH}/opp/vendors/customize/op_api") ,默認是不需要修改的,他需要和vendor_name一致。執行如下命令進行測試:
PReluSample/AclNNInvocation# bash run.sh
