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Feature/op fusion (#12240)

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# Operator fusion
Fusing multiple operators together is an important method to optimize the program execution, particularly for GPU or other specialized accelerators. An obvious benefit is to avoid the overhead of saving the intermediate result back into global memory.
There are generally two ways to fuse operators, fusing directly connected operators and fusing non directly connected operators. The first method is mainly used by [NNVM Compiler](https://github.com/dmlc/tvm/) and [XLA](https://www.tensorflow.org/performance/xla/). The second method is mainly used by Dynet and TensorFlow Fold to do auto-batching. The principle of fusing operator is according to some rules to combine multiple operations into one, for example, `Y = X * W` and `Z = Y + B` can be fused to `Z = X * W + B`, and `Y1 = X1 * W` and `Y2 = X2 * W` can be fused to `[Y1;Y2] = [X1;X2] * W`. In order to get a short-term profit, we decided to try to manually specify these rules.
## Challenge
The challenge of fusing operators is:
- how to make the rules.
- how to implement these rules efficiently.
### How to make the rules?
The problem of determining the best single location for a fusion operator is an NP-hard combinatorial problem. After analysis the operators of the DL model, we found there are two group of operators can be fused explicitly, one is the simple and adjacent operations, for example, `tmp = x + y` and `z = Relu(tmp)`, and the other is the operators that have the same function, for example, a serials of `SGD` or `Momentum`. They usually appear in the model in a large number. So we should think about how to fuse them separately first.
### How to implement these rules efficiently?
#### How to fuse the adjacent operations efficiently?
Here we use a template function to represent the fused operations. The pros of using a template function are that it is simple and efficient, and the cons are that it is not easy to expand, and it can only be used to express some simple operations. So taking into account our current needs, the template function is more appropriate.
#### How to fuse the operators that have the same function efficiently?
We take SGD operator as an example, the training model may have hundreds of parameters and correspondingly have the same number of SGD operators. The expression(`w = w - lr*w_g`) of those operators is the same, so during of training, the executor will execute this expression hundreds time in CPU or other specialized accelerators. If we can fuse them and make the address of all `w` and all `w_g` continuous respectively, we only need execute one time. For some accelerators, the time of launching kernel is not neglected, so the time of hundreds of times of launching and executing kernel may be larger than launching and executing only once. There usually are many operators that similar to `SGD` in the DL model, such as `AllReduce` and `FC`.
/* Copyright (c) 2018 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 <string>
#include <vector>
#include "paddle/fluid/operators/fused_elemwise_activation_op.h"
namespace paddle {
namespace operators {
class FusedElemwiseActivationOp : public framework::OperatorWithKernel {
public:
using framework::OperatorWithKernel::OperatorWithKernel;
void InferShape(framework::InferShapeContext *ctx) const override {
PADDLE_ENFORCE(
ctx->HasInput("X"),
"Input(X) of FusedElemwiseActivationOp op should not be null.");
PADDLE_ENFORCE(
ctx->HasInput("Y"),
"Input(Y) of FusedElemwiseActivationOp op should not be null.");
PADDLE_ENFORCE(
ctx->HasOutput("Out"),
"Output(Out) of FusedElemwiseActivationOp op should not be null.");
auto x_dim = ctx->GetInputDim("X");
auto y_dim = ctx->GetInputDim("Y");
PADDLE_ENFORCE_GE(x_dim.size(), y_dim.size(),
"Rank of first input must >= rank of second input.");
ctx->SetOutputDim("Out", x_dim);
ctx->ShareLoD("X", /*->*/ "Out");
}
protected:
framework::OpKernelType GetExpectedKernelType(
const framework::ExecutionContext &ctx) const override {
PADDLE_ENFORCE_EQ(ctx.Input<framework::Tensor>("X")->type(),
ctx.Input<framework::Tensor>("Y")->type(),
"The element's type of input should be the same.");
auto input_data_type =
framework::ToDataType(ctx.Input<framework::Tensor>("X")->type());
return framework::OpKernelType(input_data_type, ctx.GetPlace());
}
};
class FusedElemwiseActivationMaker : public framework::OpProtoAndCheckerMaker {
public:
void Make() override {
AddInput("X", "(vector<Tensor>)");
AddInput("Y", "(vector<Tensor>)");
AddOutput("Out", "vector<Tensor>");
AddAttr<int>("axis",
"axis is used by elementwise_op, the default value is -1.")
.SetDefault(-1);
AddAttr<float>("scale",
"scale is used by scale_op, the default value is 0.0.")
.SetDefault(0.0);
AddAttr<bool>("recomputation",
"Whether to recompute the Out."
"fused_elemwise_activation_grad has two methods to get the "
"dx and dy, one "
"is to use the 'Out', and the other is not to use it. "
"The former method will save the time of recomputing the "
"'Out', but it must occupy the memory to store the 'out'. "
"While, the later method can avoid occupying the memory, "
"but it must recompute the 'Out'. The default value is true.")
.SetDefault(true);
AddAttr<std::vector<std::string>>("functor_list",
"The functors that should be fused.")
.AddCustomChecker([&](const std::vector<std::string> &functor_list) {
PADDLE_ENFORCE(ValidCheck(functor_list));
});
AddComment(R"DOC(
FusedElemwiseActivation Operator.
At present, FusedElemwiseActivation only supports Two kinds of compound
operators (elementwise_op and activation_op):
Z = Binary(X, Unary(Y))
Z = Unary(Binary(X, Y))
The attributions of activation_op can be get from fused_elemwise_activation_op's
attributions. functor_list records the functors to be fused, for example
"scale,elementwise_add".
)DOC");
}
private:
bool ValidCheck(const std::vector<std::string> &functors) {
std::unordered_set<std::string> unary_fun = {"scale", "relu"};
std::unordered_set<std::string> binary_fun = {"elementwise_add"};
std::string unary_fun_str;
if (binary_fun.count(functors[0])) {
unary_fun_str = functors[1];
} else if (binary_fun.count(functors[1])) {
unary_fun_str = functors[0];
} else {
PADDLE_THROW("%s and %s are not included in fused_list.", functors[0],
functors[1]);
}
PADDLE_ENFORCE_EQ(unary_fun.count(unary_fun_str), 1,
"%s is not included in fused_list.", unary_fun_str);
return true;
}
};
class FusedElemwiseActivationGradMaker
: public framework::SingleGradOpDescMaker {
public:
using framework::SingleGradOpDescMaker::SingleGradOpDescMaker;
protected:
std::unique_ptr<framework::OpDesc> Apply() const override {
auto *op_desc_ptr = new framework::OpDesc();
op_desc_ptr->SetType(this->ForwardOpType() + "_grad");
for (auto &input_param : this->InputNames()) {
op_desc_ptr->SetInput(input_param, this->Input(input_param));
op_desc_ptr->SetOutput(framework::GradVarName(input_param),
this->InputGrad(input_param, true));
}
for (auto &output_param : this->OutputNames()) {
op_desc_ptr->SetInput(output_param, this->Output(output_param));
op_desc_ptr->SetInput(framework::GradVarName(output_param),
this->OutputGrad(output_param));
}
op_desc_ptr->SetAttrMap(this->Attrs());
std::vector<std::string> functor_names =
boost::get<std::vector<std::string>>(
op_desc_ptr->GetAttr("functor_list"));
functor_names[0] += "_grad";
functor_names[1] += "_grad";
op_desc_ptr->SetAttr("functor_list", functor_names);
return std::unique_ptr<framework::OpDesc>(op_desc_ptr);
}
};
class FusedElemwiseActivationOpGrad : public framework::OperatorWithKernel {
public:
using framework::OperatorWithKernel::OperatorWithKernel;
void InferShape(framework::InferShapeContext *ctx) const override {
PADDLE_ENFORCE(ctx->HasInput("X"), "Input(X) should not be null");
PADDLE_ENFORCE(ctx->HasInput("Y"), "Input(Y) should not be null");
PADDLE_ENFORCE(ctx->HasInput(framework::GradVarName("Out")),
"Input(Out@GRAD) should not be null");
auto x_dims = ctx->GetInputDim("X");
auto y_dims = ctx->GetInputDim("Y");
auto out_dims = ctx->GetInputDim(framework::GradVarName("Out"));
PADDLE_ENFORCE_GE(x_dims.size(), y_dims.size(),
"Rank of first input must >= rank of second input.");
auto x_grad_name = framework::GradVarName("X");
auto y_grad_name = framework::GradVarName("Y");
if (ctx->HasOutput(x_grad_name)) {
ctx->SetOutputDim(x_grad_name, x_dims);
}
if (ctx->HasOutput(y_grad_name)) {
ctx->SetOutputDim(y_grad_name, y_dims);
}
}
protected:
framework::OpKernelType GetExpectedKernelType(
const framework::ExecutionContext &ctx) const override {
auto input_data_type_index = ctx.Input<framework::Tensor>("X")->type();
PADDLE_ENFORCE_EQ(input_data_type_index,
ctx.Input<framework::Tensor>("Y")->type(),
"The element's type of input should be the same.");
PADDLE_ENFORCE_EQ(
input_data_type_index,
ctx.Input<framework::Tensor>(framework::GradVarName("Out"))->type(),
"The element's type of input should be the same.");
auto input_data_type = framework::ToDataType(input_data_type_index);
return framework::OpKernelType(input_data_type, ctx.GetPlace());
}
};
} // namespace operators
} // namespace paddle
namespace ops = paddle::operators;
REGISTER_OPERATOR(fused_elemwise_activation, ops::FusedElemwiseActivationOp,
ops::FusedElemwiseActivationMaker,
ops::FusedElemwiseActivationGradMaker);
REGISTER_OPERATOR(fused_elemwise_activation_grad,
ops::FusedElemwiseActivationOpGrad);
REGISTER_OP_CPU_KERNEL(
fused_elemwise_activation,
ops::FusedElemwiseActivationKernel<paddle::platform::CPUDeviceContext,
float>,
ops::FusedElemwiseActivationKernel<paddle::platform::CPUDeviceContext,
double>);
REGISTER_OP_CPU_KERNEL(
fused_elemwise_activation_grad,
ops::FusedElemwiseActivationGradKernel<paddle::platform::CPUDeviceContext,
float>,
ops::FusedElemwiseActivationGradKernel<paddle::platform::CPUDeviceContext,
double>);
/* Copyright (c) 2018 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/fluid/operators/fused_elemwise_activation_op.h"
namespace ops = paddle::operators;
REGISTER_OP_CUDA_KERNEL(
fused_elemwise_activation,
ops::FusedElemwiseActivationKernel<paddle::platform::CUDADeviceContext,
float>,
ops::FusedElemwiseActivationKernel<paddle::platform::CUDADeviceContext,
double>);
REGISTER_OP_CUDA_KERNEL(
fused_elemwise_activation_grad,
ops::FusedElemwiseActivationGradKernel<paddle::platform::CUDADeviceContext,
float>,
ops::FusedElemwiseActivationGradKernel<paddle::platform::CUDADeviceContext,
double>);
/* Copyright (c) 2018 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. */
#pragma once
#include <string>
#include <vector>
#include "paddle/fluid/framework/op_desc.h"
#include "paddle/fluid/framework/op_registry.h"
#include "paddle/fluid/operators/detail/safe_ref.h"
#include "paddle/fluid/operators/elementwise_op_function.h"
#include "paddle/fluid/operators/math/functors.h"
namespace math = paddle::operators::math;
namespace paddle {
namespace operators {
// CompoundFunctors
// For example: Z = Binary(X, Unary(Y))
template <typename T, typename BinaryFun, typename UnaryFun>
struct BinaryCompoundFunctor {
BinaryCompoundFunctor(const BinaryFun &binary_fun, const UnaryFun &unary_fun)
: binary_fun_(binary_fun), unary_fun_(unary_fun) {}
inline HOSTDEVICE T operator()(T x, T y) {
return binary_fun_(x, unary_fun_(y));
}
private:
BinaryFun binary_fun_;
UnaryFun unary_fun_;
};
// For example: Z = Unary(Binary(X, Y))
template <typename T, typename UnaryFun, typename BinaryFun>
struct UnaryCompoundFunctor {
UnaryCompoundFunctor(const UnaryFun &unary_fun, const BinaryFun &binary_fun)
: unary_fun_(unary_fun), binary_fun_(binary_fun) {}
inline HOSTDEVICE T operator()(T x, T y) {
return unary_fun_(binary_fun_(x, y));
}
private:
UnaryFun unary_fun_;
BinaryFun binary_fun_;
};
// FIXME(zcd): DBinaryFun and DUnaryFun have to method to get
// the dx, one is to use the 'out', and the other is not to use it.
// the former method will save the time of recomputing the
// 'out', but it must occupy the memory to store the 'out'.
// While the later method can avoid occupying this memory,
// but it must recompute the 'out'.
template <typename T, typename DBinaryFun, typename UnaryFun,
bool Recomputation = true>
struct BinaryCompoundGradDxFunctor {
BinaryCompoundGradDxFunctor(const DBinaryFun &d_binary_fun,
const UnaryFun &unary_fun)
: d_binary_fun_(d_binary_fun), unary_fun_(unary_fun) {}
inline HOSTDEVICE T operator()(T x, T y, T out, T dout) {
if (Recomputation) {
return dout * d_binary_fun_(x, unary_fun_(y));
} else {
return dout * d_binary_fun_(x, unary_fun_(y), out);
}
}
private:
DBinaryFun d_binary_fun_;
UnaryFun unary_fun_;
};
template <typename T, typename DBinaryFun, typename UnaryFun,
typename DUnaryFun, bool Recomputation = true>
struct BinaryCompoundGradDyFunctor {
BinaryCompoundGradDyFunctor(const DBinaryFun &d_binary_fun,
const UnaryFun &unary_fun,
const DUnaryFun &d_unary_fun)
: d_binary_fun_(d_binary_fun),
unary_fun_(unary_fun),
d_unary_fun_(d_unary_fun) {}
inline HOSTDEVICE T operator()(T x, T y, T out, T dout) {
if (Recomputation) {
return dout * d_binary_fun_(unary_fun_(y), x) * d_unary_fun_(y);
} else {
return dout * d_binary_fun_(unary_fun_(y), x, out) * d_unary_fun_(y);
}
}
private:
DBinaryFun d_binary_fun_;
UnaryFun unary_fun_;
DUnaryFun d_unary_fun_;
};
template <typename T, typename DUnaryFun, typename BinaryFun,
typename DBinaryFun, bool Recomputation = true>
struct UnaryCompoundGradDxFunctor {
UnaryCompoundGradDxFunctor(const DUnaryFun &d_unary_fun,
const BinaryFun &binary_fun,
const DBinaryFun &d_binary_fun)
: d_unary_fun_(d_unary_fun),
binary_fun_(binary_fun),
d_binary_fun_(d_binary_fun) {}
inline HOSTDEVICE T operator()(T x, T y, T out, T dout) {
T base;
if (Recomputation) {
base = dout * d_unary_fun_(binary_fun_(x, y));
} else {
base = dout * d_unary_fun_(binary_fun_(x, y), out);
}
return base * d_binary_fun_(x, y);
}
private:
DUnaryFun d_unary_fun_;
BinaryFun binary_fun_;
DBinaryFun d_binary_fun_;
};
template <typename T, typename DUnaryFun, typename BinaryFun,
typename DBinaryFun, bool Recomputation = true>
struct UnaryCompoundGradDyFunctor {
UnaryCompoundGradDyFunctor(const DUnaryFun &d_unary_fun,
const BinaryFun &binary_fun,
const DBinaryFun &d_binary_fun)
: d_unary_fun_(d_unary_fun),
binary_fun_(binary_fun),
d_binary_fun_(d_binary_fun) {}
inline HOSTDEVICE T operator()(T x, T y, T out, T dout) {
T base;
if (Recomputation) {
base = dout * d_unary_fun_(binary_fun_(x, y));
} else {
base = dout * d_unary_fun_(binary_fun_(x, y), out);
}
return base * d_binary_fun_(y, x);
}
private:
DUnaryFun d_unary_fun_;
BinaryFun binary_fun_;
DBinaryFun d_binary_fun_;
};
template <typename DeviceContext, typename T, typename BinaryFunctor,
typename UnaryFunctor>
static void RunBinaryCompoundFunctor(const framework::ExecutionContext &ctx,
const BinaryFunctor &binary_functor,
const UnaryFunctor &unary_functor,
const framework::Tensor *in_x,
const framework::Tensor *in_y,
framework::Tensor *output) {
int axis = ctx.Attr<int>("axis");
using BinaryCompoundFunctor =
BinaryCompoundFunctor<T, BinaryFunctor, UnaryFunctor>;
ElementwiseComputeEx<BinaryCompoundFunctor, DeviceContext, T>(
ctx, in_x, in_y, axis,
BinaryCompoundFunctor(binary_functor, unary_functor), output);
}
template <typename DeviceContext, typename T, typename UnaryFunctor,
typename BinaryFunctor>
static void RunUnaryCompoundFunctors(const framework::ExecutionContext &ctx,
const UnaryFunctor &unary_functor,
const BinaryFunctor &binary_functor,
const framework::Tensor *in_x,
const framework::Tensor *in_y,
framework::Tensor *output) {
int axis = ctx.Attr<int>("axis");
using UnaryCompoundFunctor =
UnaryCompoundFunctor<T, UnaryFunctor, BinaryFunctor>;
ElementwiseComputeEx<UnaryCompoundFunctor, DeviceContext, T>(
ctx, in_x, in_y, axis,
UnaryCompoundFunctor(unary_functor, binary_functor), output);
}
template <typename DeviceContext, typename T, typename BinaryGradFunctor,
typename UnaryFunctor, typename UnaryGradFunctor,
bool Recomputation = true>
static void RunBinaryCompoundGradFunctors(
const framework::ExecutionContext &ctx,
const BinaryGradFunctor &binary_grad_functor,
const UnaryFunctor &unary_functor,
const UnaryGradFunctor &unary_grad_functor, const framework::Tensor *in_x,
const framework::Tensor *in_y, const framework::Tensor *in_out,
const framework::Tensor *in_out_grad, framework::Tensor *x_grad,
framework::Tensor *y_grad) {
int axis = ctx.Attr<int>("axis");
using BinaryCompoundDxFunctor =
BinaryCompoundGradDxFunctor<T, BinaryGradFunctor, UnaryFunctor,
Recomputation>;
using BinaryCompoundDyFunctor =
BinaryCompoundGradDyFunctor<T, BinaryGradFunctor, UnaryFunctor,
UnaryGradFunctor, Recomputation>;
ElemwiseGradCompute<DeviceContext, T, BinaryCompoundDxFunctor,
BinaryCompoundDyFunctor>(
ctx, *in_x, *in_y, *in_out, *in_out_grad, axis, x_grad, y_grad,
BinaryCompoundDxFunctor(binary_grad_functor, unary_functor),
BinaryCompoundDyFunctor(binary_grad_functor, unary_functor,
unary_grad_functor));
}
template <typename DeviceContext, typename T, typename UnaryGradFunctor,
typename BinaryFunctor, typename BinaryGradFunctor,
bool Recomputation = true>
static void RunUnaryCompoundGradFunctors(
const framework::ExecutionContext &ctx,
const UnaryGradFunctor &unary_grad_functor,
const BinaryFunctor &binary_functor,
const BinaryGradFunctor &binary_grad_functor, const framework::Tensor *in_x,
const framework::Tensor *in_y, const framework::Tensor *in_out,
const framework::Tensor *in_out_grad, framework::Tensor *x_grad,
framework::Tensor *y_grad) {
int axis = ctx.Attr<int>("axis");
using UnaryCompoundDxFunctor =
UnaryCompoundGradDxFunctor<T, UnaryGradFunctor, BinaryFunctor,
BinaryGradFunctor, Recomputation>;
using UnaryCompoundDyFunctor =
UnaryCompoundGradDyFunctor<T, UnaryGradFunctor, BinaryFunctor,
BinaryGradFunctor, Recomputation>;
ElemwiseGradCompute<DeviceContext, T, UnaryCompoundDxFunctor,
UnaryCompoundDyFunctor>(
ctx, *in_x, *in_y, *in_out, *in_out_grad, axis, x_grad, y_grad,
UnaryCompoundDxFunctor(unary_grad_functor, binary_functor,
binary_grad_functor),
UnaryCompoundDyFunctor(unary_grad_functor, binary_functor,
binary_grad_functor));
}
template <typename DeviceContext, typename T>
static void RunFunctors(const framework::ExecutionContext &ctx,
const framework::Tensor *in_x,
const framework::Tensor *in_y,
framework::Tensor *output) {
auto &functors = ctx.Attr<std::vector<std::string>>("functor_list");
auto funcs_str = functors[0] + "," + functors[1];
// TODO(zcd): The following code can be refined.
if (funcs_str == "elementwise_add,scale") {
// Z = Binary(X, Unary(Y))
T scale = static_cast<T>(ctx.Attr<float>("scale"));
RunBinaryCompoundFunctor<DeviceContext, T, math::AddFunctor<T>,
math::ScaleFunctor<T>>(
ctx, math::AddFunctor<T>(), math::ScaleFunctor<T>(scale), in_x, in_y,
output);
} else if (funcs_str == "scale,elementwise_add") {
// Z = Unary(Binary(X, Y))
T scale = static_cast<T>(ctx.Attr<float>("scale"));
RunUnaryCompoundFunctors<DeviceContext, T, math::ScaleFunctor<T>,
math::AddFunctor<T>>(
ctx, math::ScaleFunctor<T>(scale), math::AddFunctor<T>(), in_x, in_y,
output);
} else if (funcs_str == "elementwise_add,relu") {
RunBinaryCompoundFunctor<DeviceContext, T, math::AddFunctor<T>,
math::ReluFunctor<T>>(
ctx, math::AddFunctor<T>(), math::ReluFunctor<T>(), in_x, in_y, output);
} else if (funcs_str == "relu,elementwise_add") {
RunUnaryCompoundFunctors<DeviceContext, T, math::ReluFunctor<T>,
math::AddFunctor<T>>(
ctx, math::ReluFunctor<T>(), math::AddFunctor<T>(), in_x, in_y, output);
} else {
PADDLE_THROW("%s has not been implemented.", funcs_str);
}
}
template <typename DeviceContext, typename T>
static void RunGradFunctors(const framework::ExecutionContext &ctx,
const framework::Tensor *in_x,
const framework::Tensor *in_y,
const framework::Tensor *in_out,
const framework::Tensor *in_out_grad,
framework::Tensor *x_grad,
framework::Tensor *y_grad) {
auto &functors = ctx.Attr<std::vector<std::string>>("functor_list");
auto funcs_str = functors[0] + "," + functors[1];
bool recomputation = ctx.Attr<bool>("recomputation");
// TODO(zcd): The following code can be refined. for example, use registion
if (funcs_str == "elementwise_add_grad,scale_grad") {
// The backward of Z = Binary(X, Unary(Y))
T scale = static_cast<T>(ctx.Attr<float>("scale"));
if (recomputation) {
RunBinaryCompoundGradFunctors<DeviceContext, T, math::AddGradFunctor<T>,
math::ScaleFunctor<T>,
math::ScaleGradFunctor<T>, true>(
ctx, math::AddGradFunctor<T>(), math::ScaleFunctor<T>(scale),
math::ScaleGradFunctor<T>(scale), in_x, in_y, in_out, in_out_grad,
x_grad, y_grad);
} else {
RunBinaryCompoundGradFunctors<DeviceContext, T, math::AddGradFunctor<T>,
math::ScaleFunctor<T>,
math::ScaleGradFunctor<T>, false>(
ctx, math::AddGradFunctor<T>(), math::ScaleFunctor<T>(scale),
math::ScaleGradFunctor<T>(scale), in_x, in_y, in_out, in_out_grad,
x_grad, y_grad);
}
} else if (funcs_str == "scale_grad,elementwise_add_grad") {
// The backward of Z = Unary(Binary(X, Y))
T scale = static_cast<T>(ctx.Attr<float>("scale"));
if (recomputation) {
RunUnaryCompoundGradFunctors<DeviceContext, T, math::ScaleGradFunctor<T>,
math::AddFunctor<T>, math::AddGradFunctor<T>,
true>(ctx, math::ScaleGradFunctor<T>(scale),
math::AddFunctor<T>(),
math::AddGradFunctor<T>(), in_x, in_y,
in_out, in_out_grad, x_grad, y_grad);
} else {
RunUnaryCompoundGradFunctors<DeviceContext, T, math::ScaleGradFunctor<T>,
math::AddFunctor<T>, math::AddGradFunctor<T>,
false>(ctx, math::ScaleGradFunctor<T>(scale),
math::AddFunctor<T>(),
math::AddGradFunctor<T>(), in_x, in_y,
in_out, in_out_grad, x_grad, y_grad);
}
} else if (funcs_str == "elementwise_add_grad,relu_grad") {
if (recomputation) {
RunBinaryCompoundGradFunctors<DeviceContext, T, math::AddGradFunctor<T>,
math::ReluFunctor<T>,
math::ReluGradFunctor<T>, true>(
ctx, math::AddGradFunctor<T>(), math::ReluFunctor<T>(),
math::ReluGradFunctor<T>(), in_x, in_y, in_out, in_out_grad, x_grad,
y_grad);
} else {
RunBinaryCompoundGradFunctors<DeviceContext, T, math::AddGradFunctor<T>,
math::ReluFunctor<T>,
math::ReluGradFunctor<T>, false>(
ctx, math::AddGradFunctor<T>(), math::ReluFunctor<T>(),
math::ReluGradFunctor<T>(), in_x, in_y, in_out, in_out_grad, x_grad,
y_grad);
}
} else if (funcs_str == "relu_grad,elementwise_add_grad") {
if (recomputation) {
RunUnaryCompoundGradFunctors<DeviceContext, T, math::ReluGradFunctor<T>,
math::AddFunctor<T>, math::AddGradFunctor<T>,
true>(ctx, math::ReluGradFunctor<T>(),
math::AddFunctor<T>(),
math::AddGradFunctor<T>(), in_x, in_y,
in_out, in_out_grad, x_grad, y_grad);
} else {
RunUnaryCompoundGradFunctors<DeviceContext, T, math::ReluGradFunctor<T>,
math::AddFunctor<T>, math::AddGradFunctor<T>,
false>(ctx, math::ReluGradFunctor<T>(),
math::AddFunctor<T>(),
math::AddGradFunctor<T>(), in_x, in_y,
in_out, in_out_grad, x_grad, y_grad);
}
} else {
PADDLE_THROW("%s has not been implemented.", funcs_str);
}
}
template <typename DeviceContext, typename T>
class FusedElemwiseActivationKernel : public framework::OpKernel<T> {
public:
void Compute(const framework::ExecutionContext &ctx) const override {
auto &in_x = detail::Ref(ctx.Input<framework::Tensor>("X"),
"Cannot get input tensor %s, variable name = %s",
"X", ctx.op().Input("X"));
auto &in_y = detail::Ref(ctx.Input<framework::Tensor>("Y"),
"Cannot get input tensor %s, variable name = %s",
"Y", ctx.op().Input("Y"));
auto &output = detail::Ref(ctx.Output<framework::Tensor>("Out"),
"Cannot get input tensor %s, variable name = %s",
"Out", ctx.op().Output("Out"));
RunFunctors<DeviceContext, T>(ctx, &in_x, &in_y, &output);
}
};
template <typename DeviceContext, typename T>
class FusedElemwiseActivationGradKernel : public framework::OpKernel<T> {
public:
void Compute(const framework::ExecutionContext &ctx) const override {
auto &in_x = detail::Ref(ctx.Input<framework::Tensor>("X"),
"Cannot get input tensor %s, variable name = %s",
"X", ctx.op().Input("X"));
auto &in_y = detail::Ref(ctx.Input<framework::Tensor>("Y"),
"Cannot get input tensor %s, variable name = %s",
"Y", ctx.op().Input("Y"));
auto &in_out = detail::Ref(ctx.Input<framework::Tensor>("Out"),
"Cannot get input tensor %s, variable name = %s",
"Out", ctx.op().Input("Out"));
auto &in_out_grad =
detail::Ref(ctx.Input<framework::Tensor>(framework::GradVarName("Out")),
"Cannot get input tensor %s, variable name = %s",
framework::GradVarName("Out"),
ctx.op().Input(framework::GradVarName("Out")));
framework::Tensor *x_grad =
ctx.Output<framework::Tensor>(framework::GradVarName("X"));
framework::Tensor *y_grad =
ctx.Output<framework::Tensor>(framework::GradVarName("Y"));
RunGradFunctors<DeviceContext, T>(ctx, &in_x, &in_y, &in_out, &in_out_grad,
x_grad, y_grad);
}
};
} // namespace operators
} // namespace paddle
/* Copyright (c) 2018 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. */
#pragma once
namespace paddle {
namespace operators {
namespace math {
// AddFunctor
template <typename T>
struct AddFunctor {
// out = x + y;
inline HOSTDEVICE T operator()(T x, T y) { return x + y; }
};
template <typename T>
struct AddGradFunctor {
inline HOSTDEVICE T operator()(T x, T y) { return 1; }
inline HOSTDEVICE T operator()(T x, T y, T out) const { return 1; }
};
template <typename T>
struct ScaleFunctor {
explicit ScaleFunctor(const T coeff) : coeff_(coeff) {}
inline HOSTDEVICE T operator()(T ele) { return ele * coeff_; }
private:
T coeff_;
};
template <typename T>
struct ScaleGradFunctor {
explicit ScaleGradFunctor(T coeff) : coeff_(coeff) {}
inline HOSTDEVICE T operator()(T x) { return coeff_; }
inline HOSTDEVICE T operator()(T x, T out) { return coeff_; }
private:
T coeff_;
};
template <typename T>
struct ReluFunctor {
inline HOSTDEVICE T operator()(T x) { return x * (x > 0); }
};
template <typename T>
struct ReluGradFunctor {
inline HOSTDEVICE T operator()(T x) { return x > 0 ? 1 : 0; }
inline HOSTDEVICE T operator()(T x, T out) { return x > 0 ? 1 : 0; }
};
} // namespace math
} // namespace operators
} // namespace paddle
......@@ -313,9 +313,9 @@ class TestAbs(OpTest):
self.init_dtype()
x = np.random.uniform(-1, 1, [4, 4]).astype(self.dtype)
# Because we set delta = 0.005 in caculating numeric gradient,
# Because we set delta = 0.005 in calculating numeric gradient,
# if x is too small, such as 0.002, x_neg will be -0.003
# x_pos will be 0.007, so the numeric gradient is unaccurate.
# x_pos will be 0.007, so the numeric gradient is inaccurate.
# we should avoid this
x[np.abs(x) < 0.005] = 0.02
out = np.abs(x)
......
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