/* Copyright (c) 2016 PaddlePaddle Authors. All Rights Reserve. 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/framework/lod_tensor.h" #include "paddle/operators/math/im2col.h" #include "paddle/operators/math/math_function.h" namespace paddle { namespace operators { namespace math { using Tensor = framework::Tensor; using LoDTensor = framework::LoDTensor; /* * \brief Context projection concatenates features in adjacent time-steps in * a sequence. The i-th row of the output is the concatenation of * context_length rows of the input. The context_length rows are the * consecutive rows from the i+shift_start row. * ContextProjectGradFunctor is the inverse process of ContextProjectFunctor. * * \param in Input data. * \param Shape The shape of Input data: * [mini-batch, input_hidden_size]. * * \param padding_data Padding data. * \param Shape The shape of Padding data: * [up_pad + down_pad, input_hidden_size]. * * \param col Col data. * \param Shape The shape of Col data: * [mini-batch, context_length * input_hidden_size]. * * For a mini-batch of 2 variable lengths sentences, containing 3, and 1 * time-steps: * * Assumed input (X) is a [4, M, N] float LoDTensor, and X->lod()[0] = [0, 3, * 4]. * Besides, for the sake of simplicity, we assume M=1 and N=2. * * X = [[a1, a2; * b1, b2; * c1, c2] * [d1, d2]] * * This is to say that input (X) has 4 words and the dimension of each word * representation is 2. * * - Case1: * If context_start is -1 and padding_trainable is false, we use zero to pad * instead of learned weight to pad, * and the context_length is 3, the output (Out) is: * * Out =[[0, 0, a1, a2, b1, b2; * a1, a2, b1, b2, c1, c2; * b1, b2, c1, c2, 0, 0 ] * [0, 0, d1, d2, 0, 0 ]] * * - Case2: * If context_start is -1 and padding_trainable is true, we use learned weight * to pad, * and the context_length is 3, the output (Out) is: * * Out = [[w1, w2, a1, a2, b1, b2; * a1, a2, b1, b2, c1, c2; * b1, b2, c1, c2, w3, w4] * [w1, w2, d1, d2, w3, w4]] * */ template class ContextProjectFunctor { public: void operator()(const platform::DeviceContext& context, const LoDTensor& in, const Tensor& padding_data, Tensor& col, bool padding_trainable, int context_start, int context_length, int context_stride, int up_pad, int down_pad) { auto lod_level_0 = in.lod()[0]; math::Im2ColFunctor im2col_ocf; if (platform::is_gpu_place(context.GetPlace())) { LOG(INFO) << "========= gpu =========="; } int input_row_begin, input_row_end; int sequence_height, sequence_width; sequence_width = in.dims()[1]; for (int i = 0; i < static_cast(lod_level_0.size()) - 1; ++i) { input_row_begin = (context_start > 0) ? static_cast(lod_level_0[i]) + context_start : static_cast(lod_level_0[i]); input_row_end = static_cast(lod_level_0[i + 1]); Tensor out_t = col.Slice(static_cast(lod_level_0[i]), static_cast(lod_level_0[i + 1])); sequence_height = static_cast(out_t.dims()[0]); if (input_row_begin < input_row_end) { Tensor in_t = in.Slice(input_row_begin, input_row_end); std::vector output_shape( {sequence_height, 1, 1, context_length, sequence_width}); // output_height, output_width, // input_channels, filter_height, filter_width out_t.Resize(framework::make_ddim(output_shape)); std::vector input_shape( {1, input_row_end - input_row_begin, sequence_width}); // input_channels, input_height, input_width in_t.Resize(framework::make_ddim(input_shape)); im2col_ocf(context, in_t, out_t, /*stride_height*/ context_stride, /*stride_width*/ 1, up_pad, down_pad, 0, 0); out_t.Resize({sequence_height, context_length * sequence_width}); } } if (padding_trainable) { for (int i = 0; i < static_cast(lod_level_0.size()) - 1; ++i) { Tensor out_t = col.Slice(static_cast(lod_level_0[i]), static_cast(lod_level_0[i + 1])); sequence_height = static_cast(out_t.dims()[0]); // add up trainable data out_t.Resize({sequence_height * context_length, sequence_width}); if (up_pad > 0) { // add up pad int padding_rows = std::min( up_pad, static_cast(lod_level_0[i + 1] - lod_level_0[i])); for (int k = 0; k < padding_rows; ++k) { int padding_size = k + context_length < up_pad ? context_length : up_pad - k; Tensor out_t_sub = out_t.Slice(k * context_length, k * context_length + padding_size); Tensor w_sub = padding_data.Slice(k, k + padding_size); out_t_sub.CopyFrom(w_sub, context.GetPlace(), context); } } if (down_pad > 0) { // add down pad int down_pad_begin_row = std::max(0, (sequence_height - context_start - context_length) + 1) + 1; int padding_begin = std::max(0, context_start - sequence_height); int padding_size = sequence_height - context_start >= context_length ? 1 : context_length - (sequence_height - context_start); if (context_start >= sequence_height) padding_size = context_length; int padding_idx = padding_begin; for (int t = 0; t + down_pad_begin_row <= sequence_height; ++t, ++padding_size) { if (context_start >= sequence_height) padding_size = context_length; if (padding_size > context_length) { padding_size = context_length; padding_idx++; } if (padding_begin > 0 || sequence_height == context_start) padding_idx = padding_begin + t; Tensor out_t_sub = out_t.Slice( (down_pad_begin_row + t) * context_length - padding_size, (down_pad_begin_row + t) * context_length); Tensor w_sub = padding_data.Slice( up_pad + padding_idx, up_pad + padding_idx + padding_size); out_t_sub.CopyFrom(w_sub, context.GetPlace(), context); } } out_t.Resize({sequence_height, context_length * sequence_width}); } } } }; template class ContextProjectGradFunctor { public: void operator()(const platform::DeviceContext& context, LoDTensor& in, Tensor& padding_data, Tensor& col, bool padding_trainable, int context_start, int context_length, int context_stride, int up_pad, int down_pad, bool input_grad, bool pad_grad) { auto lod_level_0 = in.lod()[0]; math::Col2ImFunctor col2im_ocf; int input_row_begin, input_row_end; int sequence_height, sequence_width; sequence_width = in.dims()[1]; if (input_grad) { for (int i = 0; i < static_cast(lod_level_0.size()) - 1; ++i) { input_row_begin = (context_start > 0) ? static_cast(lod_level_0[i]) + context_start : static_cast(lod_level_0[i]); input_row_end = static_cast(lod_level_0[i + 1]); Tensor out_t = col.Slice(static_cast(lod_level_0[i]), static_cast(lod_level_0[i + 1])); sequence_height = static_cast(out_t.dims()[0]); if (input_row_begin < input_row_end) { Tensor in_t = in.Slice(input_row_begin, input_row_end); std::vector output_shape( {sequence_height, 1, 1, context_length, sequence_width}); // output_height, output_width, // input_channels, filter_height, filter_width out_t.Resize(framework::make_ddim(output_shape)); std::vector input_shape( {1, input_row_end - input_row_begin, sequence_width}); // input_channels, input_height, input_width in_t.Resize(framework::make_ddim(input_shape)); col2im_ocf(context, in_t, out_t, /*stride_height*/ context_stride, /*stride_width*/ 1, up_pad, down_pad, 0, 0); out_t.Resize({sequence_height, context_length * sequence_width}); } } } if (pad_grad) { if (padding_trainable) { for (int i = 0; i < static_cast(lod_level_0.size()) - 1; ++i) { Tensor out_t = col.Slice(static_cast(lod_level_0[i]), static_cast(lod_level_0[i + 1])); sequence_height = static_cast(out_t.dims()[0]); out_t.Resize({sequence_height * context_length, sequence_width}); if (up_pad > 0) { int padding_rows = std::min( up_pad, static_cast(lod_level_0[i + 1] - lod_level_0[i])); for (int k = 0; k < padding_rows; ++k) { int padding_size = k + context_length < up_pad ? context_length : up_pad - k; Tensor out_t_sub = out_t.Slice(k * context_length, k * context_length + padding_size); Tensor w_sub = padding_data.Slice(k, k + padding_size); axpy(context, w_sub.numel(), static_cast(1), out_t_sub.data(), w_sub.data()); } } if (down_pad > 0) { int down_pad_begin_row = std::max( 0, (sequence_height - context_start - context_length) + 1) + 1; int padding_begin = std::max(0, context_start - sequence_height); int padding_size = sequence_height - context_start >= context_length ? 1 : context_length - (sequence_height - context_start); if (context_start >= sequence_height) padding_size = context_length; int padding_idx = padding_begin; for (int t = 0; t + down_pad_begin_row <= sequence_height; ++t, ++padding_size) { if (context_start >= sequence_height) padding_size = context_length; if (padding_size > context_length) { padding_size = context_length; padding_idx++; } if (padding_begin > 0 || sequence_height == context_start) padding_idx = padding_begin + t; Tensor out_t_sub = out_t.Slice( (down_pad_begin_row + t) * context_length - padding_size, (down_pad_begin_row + t) * context_length); Tensor w_sub = padding_data.Slice( up_pad + padding_idx, up_pad + padding_idx + padding_size); axpy(context, w_sub.numel(), static_cast(1), out_t_sub.data(), w_sub.data()); } } out_t.Resize({sequence_height, context_length * sequence_width}); } } } } }; } // namespace math } // namespace operators } // namespace paddle