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paddlepaddle--paddle/paddle/phi/kernels/impl/ftrl_kernel_impl.h
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// Copyright (c) 2024 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 "paddle/phi/core/dense_tensor.h"
#include "paddle/phi/core/kernel_registry.h"
#include "paddle/phi/kernels/funcs/eigen/common.h"
#include "paddle/phi/kernels/funcs/for_range.h"
#include "paddle/phi/kernels/funcs/selected_rows_functor.h"
namespace phi {
template <typename T>
class SparseFTRLFunctor {
private:
const T* g_;
const T* p_;
const T* s_acc_;
const T* l_acc_;
const T* lr_;
const T l1_;
const T l2_;
const T lr_power_;
const int64_t* rows_;
const int64_t row_numel_;
T* p_out_;
T* s_acc_out_;
T* l_acc_out_;
public:
SparseFTRLFunctor(const T* g,
const T* p,
const T* s_acc,
const T* lr,
const T l1,
const T l2,
const T lr_power,
const int64_t* rows,
int64_t row_numel,
T* p_out,
T* s_acc_out,
T* l_acc_out)
: g_(g),
p_(p),
s_acc_(s_acc),
lr_(lr),
l1_(l1),
l2_(l2),
lr_power_(lr_power),
rows_(rows),
row_numel_(row_numel),
p_out_(p_out),
s_acc_out_(s_acc_out),
l_acc_out_(l_acc_out) {}
inline HOSTDEVICE void operator()(size_t i) {
auto j = rows_[i / row_numel_] * row_numel_ + i % row_numel_;
const T g = g_[i];
const T p = p_[j];
const T s_acc = s_acc_[j];
const T lr = lr_[0];
auto new_acc = s_acc + g * g;
if (lr_power_ == static_cast<T>(-0.5)) {
l_acc_out_[j] += g - (std::sqrt(new_acc) - std::sqrt(s_acc)) / lr * p;
} else {
l_acc_out_[j] +=
g - (std::pow(new_acc, -lr_power_) - std::pow(s_acc, -lr_power_)) /
lr * p;
}
auto l_acc = l_acc_out_[j];
if (std::fabs(l_acc) > l1_) {
auto x = -l_acc;
if (l_acc >= static_cast<T>(0)) {
x += l1_;
} else {
x -= l1_;
}
auto y = static_cast<T>(2) * l2_;
if (lr_power_ == static_cast<T>(-0.5)) {
y += std::sqrt(new_acc) / lr;
} else {
y += std::pow(new_acc, -lr_power_) / lr;
}
auto pre_shrink = x / y;
p_out_[j] = pre_shrink;
} else {
p_out_[j] = static_cast<T>(0);
}
s_acc_out_[j] += g * g;
}
};
template <typename T, typename Context>
void FTRLOpKernel(const Context& dev_ctx,
const DenseTensor& param,
const DenseTensor& squared_accumulator,
const DenseTensor& linear_accumulator,
const DenseTensor& grad_in,
const DenseTensor& learning_rate,
float l1_in,
float l2_in,
float lr_power_in,
DenseTensor* param_out,
DenseTensor* squared_accum_out,
DenseTensor* linear_accum_out) {
auto* lr_in = &learning_rate;
auto* param_in = &param;
auto* sq_accum_in = &squared_accumulator;
auto* lin_accum_in = &linear_accumulator;
auto* sq_accum_out = squared_accum_out;
auto* lin_accum_out = linear_accum_out;
dev_ctx.template Alloc<T>(param_out);
dev_ctx.template Alloc<T>(sq_accum_out);
dev_ctx.template Alloc<T>(lin_accum_out);
auto l1 = static_cast<T>(l1_in) + static_cast<T>(1e-10);
auto l2 = static_cast<T>(l2_in) + static_cast<T>(1e-10);
auto lr_power = static_cast<T>(lr_power_in);
auto grad = &grad_in;
auto g = EigenVector<T>::Flatten(*grad);
auto p = EigenVector<T>::Flatten(*param_in);
auto sq_accum = EigenVector<T>::Flatten(*sq_accum_in);
auto lin_accum = EigenVector<T>::Flatten(*lin_accum_in);
auto lr = EigenVector<T>::Flatten(*lr_in);
auto p_out = EigenVector<T>::Flatten(*param_out);
auto s_acc_out = EigenVector<T>::Flatten(*sq_accum_out);
auto l_acc_out = EigenVector<T>::Flatten(*lin_accum_out);
auto& place = *dev_ctx.eigen_device();
Eigen::DSizes<int, 1> grad_dsize(grad->numel());
auto new_accum = sq_accum + g * g;
// Special case for lr_power = -0.5
if (lr_power == static_cast<T>(-0.5)) {
l_acc_out.device(place) =
lin_accum + g -
((new_accum.sqrt() - sq_accum.sqrt()) / lr.broadcast(grad_dsize)) * p;
} else {
l_acc_out.device(place) =
lin_accum + g -
((new_accum.pow(-lr_power) - sq_accum.pow(-lr_power)) /
lr.broadcast(grad_dsize)) *
p;
}
auto x = (l_acc_out.constant(l1) * l_acc_out.sign() - l_acc_out);
if (lr_power == static_cast<T>(-0.5)) {
auto y = (new_accum.sqrt() / lr.broadcast(grad_dsize)) +
l_acc_out.constant(static_cast<T>(2) * l2);
auto pre_shrink = x / y;
p_out.device(place) =
(l_acc_out.abs() > l_acc_out.constant(l1))
.select(pre_shrink, p.constant(static_cast<T>(0)));
} else {
auto y = (new_accum.pow(-lr_power) / lr.broadcast(grad_dsize)) +
l_acc_out.constant(static_cast<T>(2) * l2);
auto pre_shrink = x / y;
p_out.device(place) =
(l_acc_out.abs() > l_acc_out.constant(l1))
.select(pre_shrink, p.constant(static_cast<T>(0)));
}
s_acc_out.device(place) = sq_accum + g * g;
}
} // namespace phi