// 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/embedding_grad_kernel.h" #include "paddle/phi/kernels/funcs/embedding_util.h" #include "paddle/fluid/memory/memcpy.h" #include "paddle/phi/backends/gpu/gpu_context.h" #include "paddle/phi/common/data_type.h" #include "paddle/phi/core/kernel_registry.h" #include "paddle/phi/kernels/funcs/eigen/common.h" #include "paddle/fluid/framework/mixed_vector.h" #include "paddle/fluid/platform/device/gpu/gpu_primitives.h" namespace phi { template __global__ void InputTypeConvert(const InT* in_ids, const int64_t K, OutT* out_ids) { for (int i = 0; i < K; i++) { out_ids[i] = static_cast(in_ids[i]); } } template __global__ void EmbeddingGrad(T* table, const T* output, const IdT* ids, const int64_t N, const int64_t K, const int64_t D) { int idx = threadIdx.x; int idy = blockIdx.x + threadIdx.y * gridDim.x; while (idy < K) { auto id = static_cast(ids[idy]); const T* out = output + idy * D; T* tab = table + id * D; #ifdef PADDLE_WITH_CUDA paddle::platform::VectorizedAtomicAddPerBlock(D, idx, blockDim.x, out, tab); #else for (int i = idx; i < D; i += blockDim.x) { paddle::platform::CudaAtomicAdd(&tab[i], out[i]); } #endif idy += blockDim.y * gridDim.x; } } template struct EmbeddingGradCUDAFunctor { EmbeddingGradCUDAFunctor(const Context& dev_ctx, const DenseTensor& input, const DenseTensor& weight, const DenseTensor& out_grad, int64_t padding_idx, DenseTensor* weight_grad) : dev_ctx_(dev_ctx), input_(input), weight_(weight), out_grad_(out_grad), padding_idx_(padding_idx), weight_grad_(weight_grad) {} template void apply() { // Since paddings are not trainable and fixed in forward, the gradient of // paddings makes no sense and we don't deal with it in backward. { auto d_output_t = out_grad_; auto d_table_t = weight_grad_; int N = weight_grad_->dims()[0]; int D = weight_grad_->dims()[1]; int K = input_.numel(); const T* d_output = d_output_t.template data(); const auto* ids = input_.template data(); T* d_table = dev_ctx_.template Alloc(d_table_t); #ifdef PADDLE_WITH_HIP PADDLE_ENFORCE_GPU_SUCCESS( hipMemsetAsync(d_table, 0, N * D * sizeof(T), dev_ctx_.stream())); #else PADDLE_ENFORCE_GPU_SUCCESS( cudaMemsetAsync(d_table, 0, N * D * sizeof(T), dev_ctx_.stream())); #endif const int gridx = 2 * dev_ctx_.GetSMCount(); dim3 threads(128, 8); dim3 grids(gridx, 1); EmbeddingGrad<<>>( d_table, d_output, ids, N, K, D); } } private: const phi::GPUContext& dev_ctx_; const DenseTensor& input_; const DenseTensor& weight_; const DenseTensor& out_grad_; int64_t padding_idx_; DenseTensor* weight_grad_; }; template void EmbeddingGradKernel(const Context& ctx, const DenseTensor& input, const DenseTensor& weight, const DenseTensor& out_grad, int64_t padding_idx, DenseTensor* weight_grad) { EmbeddingGradCUDAFunctor functor( ctx, input, weight, out_grad, padding_idx, weight_grad); if (input.dtype() == phi::DataType::INT32) { functor.template apply(); } else if (input.dtype() == phi::DataType::INT64) { functor.template apply(); } else { PADDLE_THROW(phi::errors::Unimplemented( "emebdding input only support int32 and int64")); } } template struct EmbeddingSparseGradCUDAFunctor { EmbeddingSparseGradCUDAFunctor(const Context& dev_ctx, const DenseTensor& input, const DenseTensor& weight, const DenseTensor& out_grad, int64_t padding_idx, SelectedRows* weight_grad) : dev_ctx_(dev_ctx), input_(input), weight_(weight), out_grad_(out_grad), padding_idx_(padding_idx), weight_grad_(weight_grad) {} template void apply() { // Since paddings are not trainable and fixed in forward, the gradient of // paddings makes no sense and we don't deal with it in backward. const auto* ids_data = input_.template data(); auto* d_table = weight_grad_; auto* table = &weight_; auto* d_output = &out_grad_; int64_t ids_num = input_.numel(); dim3 threads(128, 8); dim3 grids(8, 1); auto stream = dev_ctx_.stream(); paddle::framework::Vector new_rows; new_rows.resize(ids_num); auto gpu_place = dev_ctx_.GetPlace(); paddle::framework::MixVector mixv_new_rows(&new_rows); if (!std::is_same::value) { InputTypeConvert<<>>( ids_data, ids_num, mixv_new_rows.MutableData(gpu_place)); } else { paddle::memory::Copy(gpu_place, mixv_new_rows.CUDAMutableData(gpu_place), gpu_place, ids_data, ids_num * sizeof(int64_t), stream); } mixv_new_rows.CopyToCPU(); d_table->set_rows(new_rows); auto* d_table_value = d_table->mutable_value(); d_table_value->Resize({ids_num, table->dims()[1]}); dev_ctx_.template Alloc(d_table_value); auto* d_table_data = d_table_value->template data(); auto* d_output_data = d_output->template data(); auto d_output_dims = d_output->dims(); auto d_output_dims_2d = phi::flatten_to_2d(d_output_dims, d_output_dims.size() - 1); PADDLE_ENFORCE_EQ(d_table_value->dims(), d_output_dims_2d, phi::errors::InvalidArgument( "ShapeError: The shape of lookup_table@Grad and " "output@Grad should be same. " "But received lookup_table@Grad's shape = [%s], " "output@Grad's shape = [%s].", d_table_value->dims(), d_output_dims_2d)); paddle::memory::Copy(gpu_place, d_table_data, gpu_place, d_output_data, d_output->numel() * sizeof(T), stream); } private: const phi::GPUContext& dev_ctx_; const DenseTensor& input_; const DenseTensor& weight_; const DenseTensor& out_grad_; int64_t padding_idx_; SelectedRows* weight_grad_; }; template void EmbeddingSparseGradKernel(const Context& ctx, const DenseTensor& input, const DenseTensor& weight, const DenseTensor& out_grad, int64_t padding_idx, SelectedRows* weight_grad) { EmbeddingSparseGradCUDAFunctor functor( ctx, input, weight, out_grad, padding_idx, weight_grad); if (input.dtype() == phi::DataType::INT32) { functor.template apply(); } else if (input.dtype() == phi::DataType::INT64) { functor.template apply(); } else { PADDLE_THROW(phi::errors::Unimplemented( "emebdding input only support int32 and int64")); } } } // namespace phi PD_REGISTER_KERNEL(embedding_grad, GPU, ALL_LAYOUT, phi::EmbeddingGradKernel, float, double, phi::dtype::float16) {} PD_REGISTER_KERNEL(embedding_sparse_grad, GPU, ALL_LAYOUT, phi::EmbeddingSparseGradKernel, float, double, phi::dtype::float16) {}