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// Copyright (c) 2022 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 "paddle/phi/kernels/gelu_grad_kernel.h"
#include <algorithm>
#include <cmath>
#include "glog/logging.h"
#include "paddle/phi/backends/cpu/cpu_context.h"
#include "paddle/phi/core/kernel_registry.h"
#include "paddle/phi/kernels/funcs/blas/blas.h"
#include "paddle/phi/kernels/funcs/blas/blas_impl.h"
#include "paddle/phi/kernels/funcs/eigen/common.h"
#include "paddle/phi/kernels/funcs/eigen/eigen_function.h"
#include "paddle/phi/kernels/gelu_kernel.h"
namespace phi {
template <typename T>
struct GeluGradFunctor {
template <typename Device, typename X, typename dOut, typename dX>
void operator()(Device d, X x, dOut dout, dX dx, bool approximate) const {
if (approximate) {
if (std::is_same<T, dtype::float16>::value) {
VLOG(4) << "cast from float16 to float before computing";
auto casted_x = x.template cast<float>();
auto casted_dout = dout.template cast<float>();
const float kAlpha = static_cast<float>(M_2_SQRTPI * M_SQRT1_2);
const float kBeta =
kAlpha * static_cast<float>(GELU_CONSTANT) * static_cast<float>(3);
const auto y =
(kAlpha *
((static_cast<float>(GELU_CONSTANT) * casted_x.cube()) + casted_x))
.tanh();
dx.device(d) = (static_cast<float>(0.5) * casted_dout *
(static_cast<float>(1) + y +
(casted_x - casted_x * y.square()) *
(kAlpha + kBeta * casted_x.square())))
.template cast<T>();
} else {
const T kAlpha = static_cast<T>(M_2_SQRTPI * M_SQRT1_2);
const T kBeta =
kAlpha * static_cast<T>(GELU_CONSTANT) * static_cast<T>(3);
const auto y =
(kAlpha * ((static_cast<T>(GELU_CONSTANT) * x.cube()) + x)).tanh();
dx.device(d) = static_cast<T>(0.5) * dout *
(static_cast<T>(1) + y +
(x - x * y.square()) * (kAlpha + kBeta * x.square()));
}
} else {
#if defined(PADDLE_WITH_MKLML) && !defined(_WIN32) && !defined(__APPLE__) && \
!defined(__OSX__) && !defined(PADDLE_WITH_CUDA) && \
!defined(PADDLE_WITH_HIP)
auto x_data = x.data();
auto dx_data = dx.data();
auto dout_data = dout.data();
int n = std::min(x.size(), dx.size());
auto first = static_cast<T*>(std::malloc(n * sizeof(T)));
std::memset(first, 0, n * sizeof(T));
auto second = static_cast<T*>(std::malloc(n * sizeof(T)));
std::memset(second, 0, n * sizeof(T));
// first = (0.5 * (1 + erf(x / sqrt(2))))
funcs::CBlas<T>::AXPY(n, static_cast<T>(M_SQRT1_2), x_data, 1, first, 1);
funcs::CBlas<T>::VMERF(n, first, first, VML_LA);
for (int i = 0; i < n; i++) {
first[i] += static_cast<T>(1);
}
funcs::CBlas<T>::SCAL(n, static_cast<T>(0.5), first, 1);
// second = (0.5 * 2/sqrt(pi) * 1/sqrt(2) * x * exp(-0.5 * x^2))
funcs::CBlas<T>::VSQUARE(n, x_data, second);
funcs::CBlas<T>::SCAL(n, -static_cast<T>(0.5), second, 1);
funcs::CBlas<T>::VEXP(n, second, second);
funcs::CBlas<T>::VMUL(n, x_data, second, second);
funcs::CBlas<T>::SCAL(
n, static_cast<T>(0.5 * M_2_SQRTPI * M_SQRT1_2), second, 1);
// dx = dout * (first + second);
funcs::CBlas<T>::VADD(n, first, second, first);
funcs::CBlas<T>::VMUL(n, dout_data, first, dx_data);
std::free(first);
std::free(second);
#else
// gelu_grad(x) = dout * 0.5 * (1 + erf(x / sqrt(2)) + x * sqrt(2 / pi) *
// exp(- x^2 / 2)
if (std::is_same<T, dtype::float16>::value) {
VLOG(4) << "cast from float16 to float before computing";
auto casted_x = x.template cast<float>();
auto casted_dout = dout.template cast<float>();
auto first = static_cast<float>(0.5) *
(static_cast<float>(1) +
((casted_x * static_cast<float>(M_SQRT1_2)).erf()));
auto second = static_cast<float>(0.5 * M_2_SQRTPI * M_SQRT1_2) *
casted_x *
(-static_cast<float>(0.5) * casted_x.square()).exp();
dx.device(d) = (casted_dout * (first + second)).template cast<T>();
} else {
auto first =
static_cast<T>(0.5) *
(static_cast<T>(1) + ((x * static_cast<T>(M_SQRT1_2)).erf()));
auto second = static_cast<T>(0.5 * M_2_SQRTPI * M_SQRT1_2) * x *
(-static_cast<T>(0.5) * x.square()).exp();
dx.device(d) = dout * (first + second);
}
#endif
}
}
};
template <typename T, typename Context>
void GeluGradKernel(const Context& dev_ctx,
const DenseTensor& x,
const DenseTensor& out_grad,
bool approximate,
DenseTensor* x_grad) {
dev_ctx.template Alloc<T>(x_grad);
if (x_grad && x_grad->numel() == 0) {
return;
}
auto eigen_x = EigenVector<T>::Flatten(x);
auto eigen_out_grad = EigenVector<T>::Flatten(out_grad);
auto eigen_x_grad = EigenVector<T>::Flatten(*x_grad);
auto& dev = *dev_ctx.eigen_device();
GeluGradFunctor<T> functor;
functor(dev, eigen_x, eigen_out_grad, eigen_x_grad, approximate);
}
} // namespace phi
PD_REGISTER_KERNEL(
gelu_grad, CPU, ALL_LAYOUT, phi::GeluGradKernel, float, double) {}