/* Copyright (c) 2019 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 #include #include "math/math_function.h" #include "paddle/fluid/framework/tensor.h" #include "paddle/fluid/platform/cuda_primitives.h" #include "paddle/fluid/platform/place.h" namespace paddle { namespace operators { using Tensor = framework::Tensor; #define CUDA_1D_KERNEL_LOOP(i, n) \ for (int i = blockIdx.x * blockDim.x + threadIdx.x; i < (n); \ i += blockDim.x * gridDim.x) template __global__ void ScatterInitCUDAKernel(const IndexT* indices, T* output, size_t index_size, size_t slice_size, bool overwrite) { CUDA_1D_KERNEL_LOOP(i, index_size * slice_size) { int indices_i = i / slice_size; int slice_i = i - indices_i * slice_size; // offset inside the slice IndexT scatter_i = indices[indices_i]; IndexT out_i = scatter_i * slice_size + slice_i; *(output + out_i) = static_cast(0); } } template __global__ void ScatterCUDAKernel(const T* params, const IndexT* indices, T* output, size_t index_size, size_t slice_size, bool overwrite) { CUDA_1D_KERNEL_LOOP(i, index_size * slice_size) { int indices_i = i / slice_size; int slice_i = i - indices_i * slice_size; // offset inside the slice IndexT scatter_i = indices[indices_i]; IndexT out_i = scatter_i * slice_size + slice_i; if (overwrite) { *(output + out_i) = *(params + i); } else { paddle::platform::CudaAtomicAdd(output + out_i, *(params + i)); } } } template __global__ void ScatterNdCUDAKernel(const T* update, const IndexT* indices, T* output, const int* output_dims, size_t remain_size, size_t slice_size, size_t end_size) { CUDA_1D_KERNEL_LOOP(i, remain_size * slice_size) { int indices_i = i / slice_size; int slice_i = i - indices_i * slice_size; // offset inside the slice IndexT gather_i = 0; int64_t temp = slice_size; for (int64_t j = end_size - 1; j >= 0; --j) { IndexT index_value = indices[indices_i * end_size + j]; gather_i += (index_value * temp); temp *= output_dims[j]; } IndexT output_i = gather_i + slice_i; paddle::platform::CudaAtomicAdd(output + output_i, *(update + i)); } } /** * A thin wrapper on gpu tensor * Return a new updated tensor from source tensor, scatter-assigned according to * index * input[src]: type-T source Tensor * input[index]: type-IndexT index Tensor (1-D) * return: output tensor */ template void GPUScatterAssign(const framework::ExecutionContext& context, const Tensor& src, const Tensor& index, Tensor* output, bool overwrite = true) { // check index of shape 1-D const auto& ctx = context.device_context(); if (index.dims().size() == 2) { PADDLE_ENFORCE_EQ(index.dims()[1], 1, "index.dims()[1] should be 1 when index.dims().size() == " "2 in scatter_op."); } else { PADDLE_ENFORCE_EQ(index.dims().size(), 1, "index.dims().size() should be 1 or 2 in scatter_op."); } int index_size = index.dims()[0]; auto src_dims = src.dims(); framework::DDim output_dims(src_dims); output_dims[0] = index_size; // slice size int slice_size = 1; for (int i = 1; i < src_dims.size(); ++i) slice_size *= src_dims[i]; const T* p_src = src.data(); const IndexT* p_index = index.data(); T* p_output = output->data(); const size_t& slice_bytes = slice_size * sizeof(T); // set block and grid num int block = 512; int n = slice_size * index_size; int grid = (n + block - 1) / block; // if not overwrite mode, init data if (!overwrite) { ScatterInitCUDAKernel<<< grid, block, 0, reinterpret_cast(ctx).stream()>>>( p_index, p_output, index_size, slice_size, overwrite); } ScatterCUDAKernel<<< grid, block, 0, reinterpret_cast(ctx).stream()>>>( p_src, p_index, p_output, index_size, slice_size, overwrite); } template void GPUScatterNdAdd(const framework::ExecutionContext& context, const Tensor& update, const Tensor& index, Tensor* output) { auto index_dims = index.dims(); auto index_dims_size = index_dims.size(); auto output_dims = output->dims(); auto output_dims_size = output_dims.size(); const T* p_update = update.data(); const IndexT* p_index = index.data(); T* p_output = output->data(); // final dim int64_t end_size = index_dims[index_dims_size - 1]; // remain dim auto remain_ddim = framework::slice_ddim(index_dims, 0, index_dims_size - 1); int64_t remain_numel = framework::product(remain_ddim); // slice size int64_t slice_size = 1; for (int64_t i = end_size; i < output_dims_size; ++i) { slice_size *= output_dims[i]; } const size_t slice_bytes = slice_size * sizeof(T); // put output_dims int CUDA // gplace and cplace const auto& ctx = context.template device_context(); const auto gplace = boost::get(ctx.GetPlace()); auto cplace = platform::CPUPlace(); std::vector v_output_dims(output_dims_size); for (int i = 0; i < output_dims_size; ++i) { v_output_dims[i] = static_cast(output_dims[i]); } auto& dev_ctx = context.cuda_device_context(); auto& allocator = platform::DeviceTemporaryAllocator::Instance().Get(dev_ctx); int bytes = output_dims_size * sizeof(int); auto output_dims_ptr = allocator.Allocate(bytes); int* g_output_dims = reinterpret_cast(output_dims_ptr->ptr()); memory::Copy(gplace, g_output_dims, cplace, v_output_dims.data(), bytes, ctx.stream()); int block = 512; int n = slice_size * remain_numel; int grid = (n + block - 1) / block; ScatterNdCUDAKernel<<< grid, block, 0, reinterpret_cast(ctx).stream()>>>( p_update, p_index, p_output, g_output_dims, remain_numel, slice_size, end_size); } } // namespace operators } // namespace paddle