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paddlepaddle--paddle/test/cpp_extension/mix_relu_and_extension.cc
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2026-07-13 12:40:42 +08:00

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// Copyright (c) 2023 PaddlePaddle Authors. All Rights Reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#include <iostream>
#include <vector>
#include "custom_power.h" // NOLINT
#include "paddle/extension.h"
#define CHECK_CPU_INPUT(x) \
PADDLE_ENFORCE_EQ( \
x.is_cpu(), true, common::errors::Fatal(#x " must be a CPU Tensor."))
template <typename data_t>
void relu_cpu_forward_kernel(const data_t* x_data,
data_t* out_data,
int64_t x_numel) {
PADDLE_ENFORCE_NE(
x_data, nullptr, common::errors::Fatal("x_data is nullptr."));
PADDLE_ENFORCE_NE(
out_data, nullptr, common::errors::Fatal("out_data is nullptr."));
for (int64_t i = 0; i < x_numel; ++i) {
out_data[i] = std::max(static_cast<data_t>(0.), x_data[i]);
}
}
template <typename data_t>
void relu_cpu_backward_kernel(const data_t* grad_out_data,
const data_t* out_data,
data_t* grad_x_data,
int64_t out_numel) {
for (int64_t i = 0; i < out_numel; ++i) {
grad_x_data[i] =
grad_out_data[i] * (out_data[i] > static_cast<data_t>(0) ? 1. : 0.);
}
}
template <typename data_t>
void relu_cpu_double_backward_kernel(const data_t* out_data,
const data_t* ddx_data,
data_t* ddout_data,
int64_t ddout_numel) {
for (int64_t i = 0; i < ddout_numel; ++i) {
ddout_data[i] =
ddx_data[i] * (out_data[i] > static_cast<data_t>(0) ? 1. : 0.);
}
}
std::vector<paddle::Tensor> relu_cpu_forward(const paddle::Tensor& x) {
CHECK_CPU_INPUT(x);
auto out = paddle::empty_like(x);
PD_DISPATCH_FLOATING_TYPES(
x.type(), "relu_cpu_forward", ([&] {
relu_cpu_forward_kernel<data_t>(
x.data<data_t>(), out.data<data_t>(), x.numel());
}));
return {out};
}
std::vector<paddle::Tensor> relu_cpu_backward(const paddle::Tensor& x,
const paddle::Tensor& out,
const paddle::Tensor& grad_out) {
auto grad_x = paddle::empty_like(x);
PD_DISPATCH_FLOATING_TYPES(out.type(), "relu_cpu_backward", ([&] {
relu_cpu_backward_kernel<data_t>(
grad_out.data<data_t>(),
out.data<data_t>(),
grad_x.data<data_t>(),
out.size());
}));
return {grad_x};
}
std::vector<paddle::Tensor> relu_cpu_double_backward(
const paddle::Tensor& out, const paddle::Tensor& ddx) {
CHECK_CPU_INPUT(out);
CHECK_CPU_INPUT(ddx);
auto ddout = paddle::empty(out.shape(), out.dtype(), out.place());
PD_DISPATCH_FLOATING_TYPES(out.type(), "relu_cpu_double_backward", ([&] {
relu_cpu_double_backward_kernel<data_t>(
out.data<data_t>(),
ddx.data<data_t>(),
ddout.mutable_data<data_t>(out.place()),
ddout.size());
}));
return {ddout};
}
std::vector<paddle::Tensor> ReluForward(const paddle::Tensor& x) {
if (x.is_cpu()) {
return relu_cpu_forward(x);
} else {
PD_THROW("Not implemented.");
}
}
std::vector<paddle::Tensor> ReluBackward(const paddle::Tensor& x,
const paddle::Tensor& out,
const paddle::Tensor& grad_out) {
if (x.is_cpu()) {
return relu_cpu_backward(x, out, grad_out);
} else {
PD_THROW("Not implemented.");
}
}
std::vector<paddle::Tensor> ReluDoubleBackward(const paddle::Tensor& out,
const paddle::Tensor& ddx) {
if (out.is_cpu()) {
return relu_cpu_double_backward(out, ddx);
} else {
PD_THROW("Not implemented.");
}
}
std::vector<std::vector<int64_t>> ReluDoubleBackwardInferShape(
const std::vector<int64_t>& out_shape,
const std::vector<int64_t>& ddx_shape) {
return {out_shape};
}
PD_BUILD_OP(custom_relu)
.Inputs({"X"})
.Outputs({"Out"})
.SetKernelFn(PD_KERNEL(ReluForward));
PD_BUILD_GRAD_OP(custom_relu)
.Inputs({"X", "Out", paddle::Grad("Out")})
.Outputs({paddle::Grad("X")})
.SetKernelFn(PD_KERNEL(ReluBackward));
PD_BUILD_DOUBLE_GRAD_OP(custom_relu)
.Inputs({"Out", paddle::Grad(paddle::Grad("X"))})
.Outputs({paddle::Grad(paddle::Grad("Out"))})
.SetKernelFn(PD_KERNEL(ReluDoubleBackward))
.SetInferShapeFn(PD_INFER_SHAPE(ReluDoubleBackwardInferShape));
// Extension with tensor operator overloading
paddle::Tensor custom_sub2(paddle::Tensor x, paddle::Tensor y) {
return paddle::exp(x) - paddle::exp(y);
}
// Extension with tensor operator overloading
paddle::Tensor custom_add2(const paddle::Tensor& x, const paddle::Tensor& y) {
return paddle::exp(x) + paddle::exp(y);
}
PYBIND11_MODULE(mix_relu_extension, m) {
m.def("custom_add2", &custom_add2, "exp(x) + exp(y)");
m.def("custom_sub2", &custom_sub2, "exp(x) - exp(y)");
}