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paddlepaddle--paddle/paddle/phi/kernels/funcs/dropout_impl.cu.h
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2026-07-13 12:40:42 +08:00

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/* Copyright (c) 2021 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>
#ifdef PADDLE_WITH_CUDA
#include <cuda.h>
#include <curand_kernel.h>
#endif
#ifdef PADDLE_WITH_HIP
#include <hip/hip_runtime.h>
#include <hiprand_kernel.h>
#endif
#include "paddle/phi/kernels/funcs/dropout_impl_util.h"
#include "paddle/phi/backends/gpu/cuda/cuda_graph_with_memory_pool.h"
#include "paddle/phi/backends/gpu/gpu_launch_config.h"
#include "paddle/phi/kernels/funcs/broadcast_function.h"
#include "paddle/phi/kernels/funcs/distribution_helper.h"
#include "paddle/phi/kernels/funcs/functors.h"
#include "paddle/phi/kernels/primitive/compute_primitives.h"
#include "paddle/phi/kernels/primitive/datamover_primitives.h"
#include "paddle/phi/kernels/scale_kernel.h"
namespace phi {
namespace funcs {
template <typename T>
struct DstFunctor {
using MT = typename MPTypeTrait<T>::Type;
HOSTDEVICE inline DstFunctor(const float retain_prob,
const bool is_upscale_in_train,
const int64_t num)
: retain_prob_(retain_prob),
is_upscale_in_train_(is_upscale_in_train),
num_(num) {
factor = static_cast<MT>(1.0f / retain_prob_);
}
HOSTDEVICE inline T operator()(const T src_val, const uint8_t mask) const {
for (int i = 0; i < num_; i++) {
if (mask == static_cast<uint8_t>(1)) {
return is_upscale_in_train_
? static_cast<T>(static_cast<MT>(src_val) * factor)
: static_cast<T>(src_val);
} else {
return static_cast<T>(0);
}
}
}
private:
const float retain_prob_;
const bool is_upscale_in_train_;
const int64_t num_;
MT factor;
};
template <typename T>
struct MaskFunctor {
explicit MaskFunctor(const float retain_prob) : retain_prob_(retain_prob) {}
HOSTDEVICE inline void operator()(T* dst, const float* rand, int num) const {
static constexpr int kCount =
funcs::uniform_distribution<float>::kReturnsCount;
// 0 ~ kCount - 1 is dst, kCount ~ 2 * kCount - 1 is mask
#pragma unroll
for (int i = 0; i < kCount; i++) {
dst[i] = rand[i] < retain_prob_ ? static_cast<T>(1) : static_cast<T>(0);
}
}
private:
float retain_prob_;
};
template <typename T>
struct DstMaskFunctor {
using MT = typename MPTypeTrait<T>::Type;
HOSTDEVICE inline DstMaskFunctor(const float retain_prob,
const bool is_upscale_in_train)
: retain_prob_(retain_prob), is_upscale_in_train_(is_upscale_in_train) {
factor = static_cast<MT>(1.0f / retain_prob_);
}
HOSTDEVICE inline void operator()(T* dst,
const T* src_val,
const float* rand,
int num) const {
static constexpr int kCount =
funcs::uniform_distribution<float>::kReturnsCount;
// 0 ~ kCount - 1 is dst, kCount ~ 2 * kCount - 1 is mask
#pragma unroll
for (int i = 0; i < kCount; i++) {
if (rand[i] < retain_prob_) {
dst[i] = is_upscale_in_train_
? static_cast<T>(static_cast<MT>(src_val[i]) * factor)
: static_cast<T>(src_val[i]);
dst[i + kCount] = static_cast<T>(1);
} else {
dst[i] = static_cast<T>(0);
dst[i + kCount] = dst[i];
}
}
}
private:
MT factor;
float retain_prob_;
bool is_upscale_in_train_;
};
template <typename T>
__global__ void VectorizedRandomGenerator(
unsigned int
identifier, /* This is used to relate kernel to cudaGraph nodes*/
const size_t n,
uint64_t seed,
const float dropout_prob,
const T* src,
uint8_t* mask,
T* dst,
bool is_upscale_in_train,
uint64_t increment,
size_t main_offset) {
size_t idx = static_cast<size_t>(BLOCK_ID_X * BLOCK_NUM_X);
static constexpr int kCount =
funcs::uniform_distribution<float>::kReturnsCount;
size_t stride = BLOCK_NUM_X * GRID_NUM_X * kCount;
#ifdef PADDLE_WITH_HIP
hiprandStatePhilox4_32_10_t state;
hiprand_init(seed, idx + THREAD_ID_X, increment, &state);
using SType = hiprandStatePhilox4_32_10_t;
#else
curandStatePhilox4_32_10_t state;
curand_init(seed, idx + THREAD_ID_X, increment, &state);
using SType = curandStatePhilox4_32_10_t;
#endif
T dst_mask[kCount *
2]; // 0 ~ kCount - 1 : dst, kCount ~ 2 * kCount - 1: mask
float rands[kCount];
uint8_t mask_result[kCount];
using Rand = funcs::uniform_distribution<float>;
using Cast = kps::IdentityFunctor<T>;
int deal_size = BLOCK_NUM_X * kCount;
size_t fix = idx * kCount;
auto dst_functor =
DstMaskFunctor<T>(1.0f - dropout_prob, is_upscale_in_train);
for (; fix < main_offset; fix += stride) {
kps::ReadData<T, kCount, 1, false>(&dst_mask[0], src + fix, deal_size);
kps::ElementwiseRandom<SType, float, kCount, Rand>(
&rands[0], Rand(), &state);
// dst
kps::OperatorTernary<T, float, T, DstMaskFunctor<T>>(
&dst_mask[0], &dst_mask[0], &rands[0], dst_functor, kCount);
kps::WriteData<T, kCount, 1, false>(dst + fix, &dst_mask[0], deal_size);
// mask
kps::ElementwiseUnary<T, uint8_t, kCount, 1, Cast>(
&mask_result[0], &dst_mask[kCount], Cast());
kps::WriteData<uint8_t, kCount, 1, false>(
mask + fix, &mask_result[0], deal_size);
}
int remainder = n - fix;
if (remainder > 0) {
kps::ReadData<T, kCount, 1, true>(&dst_mask[0], src + fix, remainder);
kps::ElementwiseRandom<SType, float, kCount, Rand>(
&rands[0], Rand(), &state);
// dst
kps::OperatorTernary<T, float, T, DstMaskFunctor<T>>(
&dst_mask[0], &dst_mask[0], &rands[0], dst_functor, kCount);
kps::WriteData<T, kCount, 1, true>(dst + fix, &dst_mask[0], remainder);
// mask
kps::ElementwiseUnary<T, uint8_t, kCount, 1, Cast>(
&mask_result[0], &dst_mask[kCount], Cast());
kps::WriteData<uint8_t, kCount, 1, true>(
mask + fix, &mask_result[0], remainder);
}
}
template <typename T>
__global__ void VectorizedGeneratorMask(const size_t n,
uint64_t seed,
const float dropout_prob,
const T* src,
uint8_t* mask,
uint64_t increment,
size_t main_offset,
MaskFunctor<T> mask_functor,
const uint64_t* seed_ptr) {
// Vectorized Generate Mask
// kCount is 4 for curand_uniform4 is used
if (seed_ptr) seed = seed_ptr[0];
constexpr int kCount = funcs::uniform_distribution<float>::kReturnsCount;
size_t idx = static_cast<size_t>(BLOCK_ID_X * BLOCK_NUM_X);
size_t stride = BLOCK_NUM_X * GRID_NUM_X * kCount;
#ifdef PADDLE_WITH_HIP
hiprandStatePhilox4_32_10_t state;
hiprand_init(seed, idx + THREAD_ID_X, increment, &state);
using SType = hiprandStatePhilox4_32_10_t;
#else
curandStatePhilox4_32_10_t state;
curand_init(seed, idx + THREAD_ID_X, increment, &state);
using SType = curandStatePhilox4_32_10_t;
#endif
T dst_mask[kCount]; // 0 ~ kCount - 1 : dst, kCount ~ 2 * kCount - 1: mask
float rands[kCount];
uint8_t mask_result[kCount];
using Rand = funcs::uniform_distribution<float>;
using Cast = kps::IdentityFunctor<T>;
int deal_size = BLOCK_NUM_X * kCount;
size_t fix = idx * kCount;
for (; fix < main_offset; fix += stride) {
kps::ReadData<T, kCount, 1, false>(&dst_mask[0], src + fix, deal_size);
kps::ElementwiseRandom<SType, float, kCount, Rand>(
&rands[0], Rand(), &state);
// dst
kps::OperatorBinary<float, T, MaskFunctor<T>>(
&dst_mask[0], &rands[0], mask_functor, kCount);
// mask
kps::ElementwiseUnary<T, uint8_t, kCount, 1, Cast>(
&mask_result[0], &dst_mask[0], Cast());
kps::WriteData<uint8_t, kCount, 1, false>(
mask + fix, &mask_result[0], deal_size);
}
int remainder = n - fix;
if (remainder > 0) {
kps::ReadData<T, kCount, 1, true>(&dst_mask[0], src + fix, remainder);
kps::ElementwiseRandom<SType, float, kCount, Rand>(
&rands[0], Rand(), &state);
// dst
kps::OperatorBinary<float, T, MaskFunctor<T>>(
&dst_mask[0], &rands[0], mask_functor, kCount);
// mask
kps::ElementwiseUnary<T, uint8_t, kCount, 1, Cast>(
&mask_result[0], &dst_mask[0], Cast());
kps::WriteData<uint8_t, kCount, 1, true>(
mask + fix, &mask_result[0], remainder);
}
}
template <typename T>
void DropoutFwGPUKernelDriver(
const GPUContext& dev_ctx,
bool is_test,
float dropout_prob,
bool upscale_in_train,
bool is_fix_seed,
int seed_val,
const DenseTensor& x,
const DenseTensor* seed,
DenseTensor* mask,
DenseTensor* y,
bool is_dropout_nd = false,
const std::vector<int>& axis = std::vector<int>()) {
int64_t x_numel = x.numel();
auto stream = dev_ctx.stream();
auto* x_data = x.data<T>();
auto* y_data = y->data<T>();
if (!is_test && mask) {
auto* mask_data = mask->data<uint8_t>();
size_t size = common::product(mask->dims());
if (dropout_prob == 1.0f) {
#ifdef PADDLE_WITH_HIP
PADDLE_ENFORCE_GPU_SUCCESS(
hipMemsetAsync(y_data, 0, x_numel * sizeof(T), stream));
PADDLE_ENFORCE_GPU_SUCCESS(
hipMemsetAsync(mask_data, 0, x_numel * sizeof(*mask_data), stream));
#else
PADDLE_ENFORCE_GPU_SUCCESS(
cudaMemsetAsync(y_data, 0, x_numel * sizeof(T), stream));
PADDLE_ENFORCE_GPU_SUCCESS(
cudaMemsetAsync(mask_data, 0, x_numel * sizeof(*mask_data), stream));
#endif
return;
}
uint64_t seed_data;
uint64_t increment;
// VectorizedRandomGenerator use curand_uniform4, so kVecSize is 4;
constexpr int kVecSize = funcs::uniform_distribution<float>::kReturnsCount;
size_t grid_size;
size_t block_size;
size_t offset;
if (funcs::IsDeterministicRNG()) {
auto cfg = funcs::GetDeterministicRNGConfig(x_numel, kVecSize);
grid_size = cfg.grid_size;
block_size = cfg.block_size;
offset = cfg.increment;
} else {
auto gpu_config =
phi::backends::gpu::GetGpuLaunchConfig1D(dev_ctx, x_numel, kVecSize);
grid_size = gpu_config.GetGridSize();
block_size = gpu_config.GetBlockSize();
int64_t device_id = dev_ctx.GetPlace().GetDeviceId();
const auto& prop = phi::backends::gpu::GetDeviceProperties(device_id);
size_t max_grid_size = prop.maxThreadsPerMultiProcessor *
prop.multiProcessorCount / block_size;
grid_size = std::min(grid_size, max_grid_size);
offset =
((x_numel - 1) / (grid_size * block_size * kVecSize) + 1) * kVecSize;
}
size_t main_offset =
size / (block_size * kVecSize) * (block_size * kVecSize);
if (is_dropout_nd) {
auto mask_functor = MaskFunctor<T>(1.0f - dropout_prob);
bool copy_in_kernel = GetSeedDataAndIncrement(dev_ctx,
seed,
is_fix_seed,
seed_val,
offset,
&seed_data,
&increment,
true);
const uint64_t* seed_ptr =
copy_in_kernel ? seed->data<uint64_t>() : nullptr;
VectorizedGeneratorMask<T>
<<<grid_size, block_size, 0, stream>>>(size,
seed_data,
dropout_prob,
x_data,
mask_data,
increment,
main_offset,
mask_functor,
seed_ptr);
auto dst_functor =
DstFunctor<T>(1.0f - dropout_prob, upscale_in_train, x_numel);
std::vector<const DenseTensor*> ins = {&x, mask};
std::vector<DenseTensor*> outs = {y};
funcs::BroadcastKernel<T>(dev_ctx, ins, &outs, dst_functor);
} else {
bool copy_in_kernel = GetSeedDataAndIncrement(
dev_ctx, seed, is_fix_seed, seed_val, offset, &seed_data, &increment);
const GPUContext* dev_ctx_p = &dev_ctx;
auto gen_cuda = dev_ctx.GetGenerator();
auto state_index = gen_cuda->GetStateIndex();
phi::backends::gpu::CUDAGraphNodeLauncher::parameterSetter_t
parameterSetter = [offset, dev_ctx_p, state_index, is_fix_seed](
phi::backends::gpu::gpuKernelParams& params) {
if (!is_fix_seed) {
// we assume seed is null pointer
// seed copy to cpu is meaningless here
auto gen_cuda = dev_ctx_p->GetGenerator();
// ensure the generator use correct state index
gen_cuda->SetStateIndex(state_index);
uint64_t seed, increment;
std::tie(seed, increment) = gen_cuda->IncrementOffset(offset);
params.As<uint64_t>(2) = seed;
params.As<uint64_t>(8) = increment;
VLOG(10) << "CUDA_GRAPH seed = " << seed
<< ", increment = " << increment;
}
};
phi::backends::gpu::CUDAGraphNodeLauncher::gpuKernelCallback_t
cudaKernelCallback = [=](unsigned int id) {
void* functionPtr =
reinterpret_cast<void*>(&(VectorizedRandomGenerator<T>));
#ifdef PADDLE_WITH_HIP
hipFunction_t cudaFunc =
reinterpret_cast<hipFunction_t>(functionPtr);
#else
cudaFunction_t cudaFunc;
PADDLE_ENFORCE_GPU_SUCCESS(
cudaGetFuncBySymbol(&cudaFunc, functionPtr));
#endif
VLOG(10) << "[cudaKernelCallback] cudaFunc = " << cudaFunc
<< " functionPtr = " << functionPtr;
VectorizedRandomGenerator<T>
<<<grid_size, block_size, 0, stream>>>(id,
size,
seed_data,
dropout_prob,
x_data,
mask_data,
y_data,
upscale_in_train,
increment,
main_offset);
return cudaFunc;
};
phi::backends::gpu::CUDAGraphNodeLauncher::Instance().KernelNodeLaunch(
parameterSetter, cudaKernelCallback);
VLOG(10) << "NON_CUDA_GRAPH seed = " << seed_data
<< ", increment = " << increment;
}
} else {
if (upscale_in_train) {
// y = x
phi::Copy(dev_ctx, x, dev_ctx.GetPlace(), false, y);
} else {
using MT = typename MPTypeTrait<T>::Type;
MT factor = static_cast<MT>(1.0f - dropout_prob);
// y = factor * x
phi::ScaleKernel<T, GPUContext>(dev_ctx, x, factor, 0.0f, false, y);
}
}
}
template <typename T>
struct CudaDropoutGradFunctor {
using MT = typename MPTypeTrait<T>::Type;
explicit CudaDropoutGradFunctor(const MT factor) : factor_(factor) {}
__device__ __forceinline__ T operator()(const T dout,
const uint8_t mask) const {
return static_cast<T>(static_cast<MT>(dout) * static_cast<MT>(mask) *
factor_);
}
private:
MT factor_;
};
template <typename T>
void DropoutGradGPUKernelDriver(const GPUContext& dev_ctx,
bool is_test,
float dropout_prob,
bool upscale_in_train,
const DenseTensor& grad_y,
const DenseTensor& mask,
DenseTensor* grad_x,
bool is_dropout_nd = false) {
using MT = typename MPTypeTrait<T>::Type;
auto stream = dev_ctx.stream();
if (is_test) {
MT factor = static_cast<MT>(upscale_in_train ? 1.0f : 1.0f - dropout_prob);
// y = factor * x
phi::ScaleKernel<T, GPUContext>(
dev_ctx, grad_y, factor, 0.0f, false, grad_x);
} else {
if (upscale_in_train && dropout_prob == 1.0f) {
#ifdef PADDLE_WITH_HIP
hipMemset(grad_x->data<T>(), 0, grad_x->numel() * sizeof(T));
#else
cudaMemset(grad_x->data<T>(), 0, grad_x->numel() * sizeof(T));
#endif
} else {
MT factor = upscale_in_train
? static_cast<MT>(1.0f / (1.0f - dropout_prob))
: static_cast<MT>(1.0f);
std::vector<const DenseTensor*> ins = {&grad_y, &mask};
std::vector<DenseTensor*> outs = {grad_x};
if (is_dropout_nd) {
funcs::BroadcastKernel<T>(
dev_ctx, ins, &outs, CudaDropoutGradFunctor<T>(factor));
} else {
funcs::ElementwiseKernel<T>(
dev_ctx, ins, &outs, CudaDropoutGradFunctor<T>(factor));
}
}
}
}
} // namespace funcs
} // namespace phi