/* Copyright (c) 2016 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 #include #include "paddle/fluid/operators/math/math_function.h" #include "paddle/fluid/operators/math/selected_rows_functor.h" #include "paddle/fluid/platform/cuda_primitives.h" #include "paddle/fluid/platform/float16.h" namespace paddle { namespace operators { namespace math { template struct SelectedRowsAdd { void operator()(const platform::CUDADeviceContext& context, const framework::SelectedRows& input1, const framework::SelectedRows& input2, framework::SelectedRows* output) { auto in1_height = input1.height(); PADDLE_ENFORCE_EQ(in1_height, input2.height()); output->set_height(in1_height); framework::Vector in1_rows(input1.rows()); auto& in2_rows = input2.rows(); std::vector out_rows; out_rows.reserve(in1_rows.size() + in2_rows.size()); // concat rows out_rows.insert(out_rows.end(), in1_rows.begin(), in1_rows.end()); out_rows.insert(out_rows.end(), in2_rows.begin(), in2_rows.end()); output->set_rows(out_rows); auto* out_value = output->mutable_value(); auto& in1_value = input1.value(); auto& in2_value = input2.value(); auto in1_row_numel = in1_value.numel() / in1_rows.size(); PADDLE_ENFORCE_EQ(in1_row_numel, in2_value.numel() / in2_rows.size()); PADDLE_ENFORCE_EQ(in1_row_numel, out_value->numel() / out_rows.size()); auto* out_data = out_value->data(); auto* in1_data = in1_value.data(); auto in1_place = input1.place(); PADDLE_ENFORCE(platform::is_gpu_place(in1_place)); auto in2_place = input2.place(); PADDLE_ENFORCE(platform::is_gpu_place(in2_place)); auto out_place = context.GetPlace(); PADDLE_ENFORCE(platform::is_gpu_place(out_place)); memory::Copy(boost::get(out_place), out_data, boost::get(in1_place), in1_data, in1_value.numel() * sizeof(T), context.stream()); auto* in2_data = in2_value.data(); memory::Copy(boost::get(out_place), out_data + in1_value.numel(), boost::get(in2_place), in2_data, in2_value.numel() * sizeof(T), context.stream()); } }; template struct SelectedRowsAdd; template struct SelectedRowsAdd; namespace { template __global__ void SelectedRowsAddTensorKernel(const T* selected_rows, const int64_t* rows, T* tensor_out, int64_t row_numel) { const int ty = blockIdx.x; int tid = threadIdx.x; selected_rows += ty * row_numel; tensor_out += rows[ty] * row_numel; for (int index = tid; index < row_numel; index += block_size) { // Since index in rows of SelectedRows can be duplicate, we can not use // tensor_out[index] += selected_rows[index]; Instead, we have to use // AtomicAdd to avoid concurrent write error. paddle::platform::CudaAtomicAdd(tensor_out + index, selected_rows[index]); } } } // namespace template struct SelectedRowsAddTensor { void operator()(const platform::CUDADeviceContext& context, const framework::SelectedRows& input1, const framework::Tensor& input2, framework::Tensor* output) { auto in1_height = input1.height(); auto in2_dims = input2.dims(); auto out_dims = output->dims(); PADDLE_ENFORCE_EQ(in1_height, in2_dims[0]); PADDLE_ENFORCE_EQ(in1_height, out_dims[0]); auto& in1_value = input1.value(); auto& in1_rows = input1.rows(); int64_t in1_row_numel = in1_value.numel() / in1_rows.size(); PADDLE_ENFORCE_EQ(in1_row_numel, input2.numel() / in1_height); PADDLE_ENFORCE_EQ(in1_row_numel, output->numel() / in1_height); auto* in1_data = in1_value.data(); auto* in2_data = input2.data(); auto* out_data = output->data(); SetConstant functor; functor(context, output, static_cast(0)); const int block_size = 256; dim3 threads(block_size, 1); dim3 grid(in1_rows.size(), 1); SelectedRowsAddTensorKernel< T, block_size><<>>( in1_data, in1_rows.CUDAData(context.GetPlace()), out_data, in1_row_numel); auto out_eigen = framework::EigenVector::Flatten(*output); auto in2_eigen = framework::EigenVector::Flatten(input2); out_eigen.device(*context.eigen_device()) = out_eigen + in2_eigen; } }; template struct SelectedRowsAddTensor; template struct SelectedRowsAddTensor; template struct SelectedRowsAdd; template struct SelectedRowsAddTensor; template struct SelectedRowsAddTo { void operator()(const platform::CUDADeviceContext& context, const framework::SelectedRows& input1, const int64_t input2_offset, framework::SelectedRows* input2) { auto in1_height = input1.height(); PADDLE_ENFORCE_EQ(in1_height, input2->height()); auto& in1_rows = input1.rows(); auto& in2_rows = *(input2->mutable_rows()); auto& in1_value = input1.value(); auto* in2_value = input2->mutable_value(); // concat rows if (in1_rows.size()) { in2_rows.Extend(in1_rows.begin(), in1_rows.end()); } auto in1_place = input1.place(); PADDLE_ENFORCE(platform::is_gpu_place(in1_place)); auto in2_place = input2->place(); PADDLE_ENFORCE(platform::is_gpu_place(in2_place)); auto* in1_data = in1_value.data(); auto* in2_data = in2_value->data(); memory::Copy(boost::get(in2_place), in2_data + input2_offset, boost::get(in1_place), in1_data, in1_value.numel() * sizeof(T), context.stream()); } }; template struct SelectedRowsAddTo; template struct SelectedRowsAddTo; template struct SelectedRowsAddTo; template struct SelectedRowsAddTo; template struct SelectedRowsAddTo; namespace { template __global__ void SelectedRowsAddToTensorKernel(const T* selected_rows, const int64_t* rows, T* tensor_out, int64_t row_numel) { const int ty = blockIdx.x; int tid = threadIdx.x; selected_rows += ty * row_numel; tensor_out += rows[ty] * row_numel; for (int index = tid; index < row_numel; index += block_size) { // Since index in rows of SelectedRows can be duplicate, we have to use // Atomic Operation to avoid concurrent write error. paddle::platform::CudaAtomicAdd(tensor_out + index, selected_rows[index]); } } } // namespace template struct SelectedRowsAddToTensor { void operator()(const platform::CUDADeviceContext& context, const framework::SelectedRows& input1, framework::Tensor* input2) { auto in1_height = input1.height(); auto in2_dims = input2->dims(); PADDLE_ENFORCE_EQ(in1_height, in2_dims[0]); auto& in1_value = input1.value(); auto& in1_rows = input1.rows(); int64_t in1_row_numel = in1_value.numel() / in1_rows.size(); PADDLE_ENFORCE_EQ(in1_row_numel, input2->numel() / in1_height); auto* in1_data = in1_value.data(); auto* in2_data = input2->data(); const int block_size = 256; dim3 threads(block_size, 1); dim3 grid(in1_rows.size(), 1); SelectedRowsAddToTensorKernel< T, block_size><<>>( in1_data, in1_rows.CUDAData(context.GetPlace()), in2_data, in1_row_numel); } }; template struct SelectedRowsAddToTensor; template struct SelectedRowsAddToTensor; template struct SelectedRowsAddToTensor; template struct SelectedRowsAddToTensor; template struct SelectedRowsAddToTensor; namespace scatter { template __global__ void MergeAddKernel(const T* input, const int64_t* input_rows, T* out, const int64_t* out_rows, size_t out_rows_size, int64_t row_numel) { const int ty = blockIdx.x; int tid = threadIdx.x; __shared__ size_t out_idx; if (tid == 0) { for (size_t i = 0; i < out_rows_size; i++) { if (input_rows[ty] == out_rows[i]) { out_idx = i; } } } __syncthreads(); input += ty * row_numel; out += out_idx * row_numel; for (int index = tid; index < row_numel; index += block_size) { paddle::platform::CudaAtomicAdd(out + index, input[index]); } } template struct MergeAdd { framework::SelectedRows operator()(const platform::CUDADeviceContext& context, const framework::SelectedRows& input, const bool sorted_result = false) { framework::SelectedRows out; (*this)(context, input, &out); return out; } void operator()(const platform::CUDADeviceContext& context, const framework::SelectedRows& input, framework::SelectedRows* output, const bool sorted_result = false) { framework::Vector input_rows(input.rows()); if (input_rows.size() == 0) { return; } framework::SelectedRows& out = *output; std::set row_set(input_rows.begin(), input_rows.end()); std::vector merge_rows_cpu(row_set.begin(), row_set.end()); framework::Vector merge_rows(merge_rows_cpu); auto input_width = input.value().dims()[1]; out.set_rows(merge_rows); out.set_height(input.height()); out.mutable_value()->mutable_data( framework::make_ddim( {static_cast(merge_rows.size()), input_width}), context.GetPlace()); math::SetConstant constant_functor; constant_functor(context, out.mutable_value(), static_cast(0)); auto* out_data = out.mutable_value()->data(); auto* input_data = input.value().data(); const int block_size = 256; dim3 threads(block_size, 1); dim3 grid1(input_rows.size(), 1); MergeAddKernel<<>>( input_data, input_rows.CUDAData(context.GetPlace()), out_data, out.mutable_rows()->CUDAMutableData(context.GetPlace()), out.rows().size(), input_width); } void operator()(const platform::CUDADeviceContext& context, const std::vector& inputs, framework::SelectedRows* output, const bool sorted_result = false) { if (inputs.size() == 0) { VLOG(3) << "no input! return"; return; } const framework::SelectedRows* has_value_input = nullptr; for (auto* in : inputs) { if (in->rows().size() > 0) { has_value_input = in; break; } } if (has_value_input == nullptr) { VLOG(3) << "no input has value! just return" << std::endl; return; } auto input_width = has_value_input->value().dims()[1]; auto input_height = has_value_input->height(); framework::SelectedRows& out = *output; std::set merged_row_set; for (auto* input : inputs) { if (input->rows().size() == 0) { continue; } PADDLE_ENFORCE_EQ(input_width, input->value().dims()[1], "all input should have same " "dimension except for the first one"); PADDLE_ENFORCE_EQ(input_height, input->height(), "all input should have same height"); merged_row_set.insert(input->rows().begin(), input->rows().end()); } std::vector merge_rows_cpu(merged_row_set.begin(), merged_row_set.end()); framework::Vector merge_rows(merge_rows_cpu); out.set_rows(merge_rows); out.set_height(input_height); out.mutable_value()->mutable_data( framework::make_ddim( {static_cast(merge_rows.size()), input_width}), context.GetPlace()); math::SetConstant constant_functor; constant_functor(context, out.mutable_value(), static_cast(0)); auto* out_data = out.mutable_value()->data(); const int block_size = 256; dim3 threads(block_size, 1); for (auto* input : inputs) { if (input->rows().size() == 0) { continue; } auto* input_data = input->value().data(); auto& input_rows = input->rows(); dim3 grid1(input_rows.size(), 1); MergeAddKernel<<>>( input_data, input_rows.CUDAData(context.GetPlace()), out_data, out.mutable_rows()->CUDAMutableData(context.GetPlace()), out.rows().size(), input_width); } } }; template struct MergeAdd; template struct MergeAdd; template struct MergeAdd; template struct MergeAdd; template struct MergeAdd; template __global__ void UpdateToTensorKernel(const T* selected_rows, const int64_t* rows, const ScatterOps& op, T* tensor_out, int64_t row_numel) { const int ty = blockIdx.x; int tid = threadIdx.x; selected_rows += ty * row_numel; tensor_out += rows[ty] * row_numel; // FIXME(typhoonzero): use macro fix the below messy code. switch (op) { case ScatterOps::ASSIGN: for (int index = tid; index < row_numel; index += block_size) { tensor_out[index] = selected_rows[index]; } break; case ScatterOps::ADD: for (int index = tid; index < row_numel; index += block_size) { tensor_out[index] += selected_rows[index]; } break; case ScatterOps::SUB: for (int index = tid; index < row_numel; index += block_size) { tensor_out[index] -= selected_rows[index]; } break; case ScatterOps::SUBBY: for (int index = tid; index < row_numel; index += block_size) { tensor_out[index] = selected_rows[index] - tensor_out[index]; } break; case ScatterOps::MUL: for (int index = tid; index < row_numel; index += block_size) { tensor_out[index] *= selected_rows[index]; } break; case ScatterOps::DIV: for (int index = tid; index < row_numel; index += block_size) { tensor_out[index] /= selected_rows[index]; } break; case ScatterOps::DIVBY: for (int index = tid; index < row_numel; index += block_size) { tensor_out[index] = selected_rows[index] / tensor_out[index]; } break; } } template struct UpdateToTensor { void operator()(const platform::CUDADeviceContext& context, const ScatterOps& op, const framework::SelectedRows& input1, framework::Tensor* input2) { // NOTE: Use SelectedRowsAddToTensor for better performance // no additional MergeAdd called. MergeAdd merge_func; auto merged_in1 = merge_func(context, input1); auto in1_height = merged_in1.height(); auto in2_dims = input2->dims(); PADDLE_ENFORCE_EQ(in1_height, in2_dims[0]); auto& in1_value = merged_in1.value(); auto& in1_rows = merged_in1.rows(); int64_t in1_row_numel = in1_value.numel() / in1_rows.size(); PADDLE_ENFORCE_EQ(in1_row_numel, input2->numel() / in1_height); auto* in1_data = in1_value.template data(); auto* in2_data = input2->data(); dim3 threads(platform::PADDLE_CUDA_NUM_THREADS, 1); dim3 grid(in1_rows.size(), 1); UpdateToTensorKernel<<< grid, threads, 0, context.stream()>>>(in1_data, in1_rows.cuda_data(), op, in2_data, in1_row_numel); } }; } // namespace scatter } // namespace math } // namespace operators } // namespace paddle