185 lines
6.5 KiB
C++
185 lines
6.5 KiB
C++
// Copyright (c) 2022 PaddlePaddle Authors. All Rights Reserved.
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//
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// Licensed under the Apache License, Version 2.0 (the "License");
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// you may not use this file except in compliance with the License.
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// You may obtain a copy of the License at
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//
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// http://www.apache.org/licenses/LICENSE-2.0
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//
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the License is distributed on an "AS IS" BASIS,
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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// See the License for the specific language governing permissions and
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// limitations under the License.
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#pragma once
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#include "paddle/phi/kernels/conv_kernel.h"
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#include "paddle/phi/kernels/cpu/conv_util.h"
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#include "paddle/phi/kernels/full_kernel.h"
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#include "paddle/phi/kernels/funcs/batch_norm_utils.h"
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#include "paddle/phi/kernels/funcs/blas/blas.h"
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#include "paddle/phi/kernels/funcs/im2col.h"
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#include "paddle/phi/kernels/funcs/math_function.h"
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#include "paddle/phi/kernels/funcs/vol2col.h"
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namespace phi {
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template <typename T, typename Context>
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void ConvKernelImpl(const Context& dev_ctx,
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const DenseTensor& input,
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const DenseTensor& filter,
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const std::vector<int>& strides,
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const std::vector<int>& paddings,
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const std::string& padding_algorithm,
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int groups,
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const std::vector<int>& dilations,
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const std::string& data_format,
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DenseTensor* output) {
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std::vector<int> paddings_ = paddings;
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std::vector<int> dilations_ = dilations;
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DenseTensor filter_ = filter;
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if (input.numel() == 0 || filter.numel() == 0) {
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Full<T, Context>(dev_ctx, output->dims(), 0, output);
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return;
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}
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// The filter will be reshaped in the calculations,
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// so here use an assignment operation,
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// that avoids modifying the variable in the Scope.
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dev_ctx.template Alloc<T>(output);
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const bool channel_last = (data_format == "NHWC" || data_format == "NDHWC");
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DenseTensor transformed_input(input.type());
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DenseTensor transformed_output(output->type());
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if (channel_last) {
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ResizeToChannelFirst<Context, T>(dev_ctx, &input, &transformed_input);
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TransToChannelFirst<Context, T>(dev_ctx, &input, &transformed_input);
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ResizeToChannelFirst<Context, T>(dev_ctx, output, &transformed_output);
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} else {
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transformed_input = input;
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transformed_output = *output;
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}
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// update padding and dilation
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auto trans_in_dims = transformed_input.dims();
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auto filter_dims = filter.dims();
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DDim in_data_dims = slice_ddim(trans_in_dims, 2, trans_in_dims.size());
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DDim filter_data_dims = slice_ddim(filter_dims, 2, filter_dims.size());
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std::vector<int> ksize = vectorize<int>(filter_data_dims);
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UpdatePaddingAndDilation(
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&paddings_, &dilations_, padding_algorithm, in_data_dims, strides, ksize);
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const int64_t batch_size = transformed_input.dims()[0];
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// filter_shape_vec:
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// {k_o, k_i, k_h, k_w} or {k_o, k_i, k_d, k_h, k_w}
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std::vector<int64_t> filter_shape_vec(vectorize(filter.dims()));
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// output_shape_vec:
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// {o_n, o_c, o_h, o_w} or {o_n, o_c, o_d, o_h, o_w}
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std::vector<int64_t> output_shape_vec(vectorize(transformed_output.dims()));
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// use col_shape in the im2col calculation
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// col_shape_vec:
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// {i_c/g, k_h, k_w, o_h, o_w} or {i_c/g, k_d, k_h, k_w,
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// o_d,o_h, o_w}
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size_t data_dim = filter_shape_vec.size() - 2;
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std::vector<int64_t> col_shape_vec(1 + 2 * data_dim);
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col_shape_vec[0] = trans_in_dims[1] / groups;
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for (size_t j = 0; j < data_dim; ++j) {
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col_shape_vec[j + 1] = filter_shape_vec[j + 2];
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col_shape_vec[j + 1 + data_dim] = output_shape_vec[j + 2];
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}
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DDim col_shape(make_ddim(col_shape_vec));
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// use col_matrix_shape in the gemm calculation
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// size:
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// (i_c/g * k_h * k_w, o_h * o_w) or (i_c/g * k_d * k_h * k_w, o_d * o_h *
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// o_w)
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DDim col_matrix_shape = flatten_to_2d(col_shape, data_dim);
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bool is_expand = IsExpand(filter_shape_vec, strides, paddings_, dilations_);
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DenseTensor col;
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// col_matrix shares the same piece of data with col,
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// but will be reshaped into a two-dimensional matrix shape
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// to call the matrix multiplication interface.
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DenseTensor col_matrix;
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if (is_expand) {
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// col = dev_ctx.AllocateTmpTensor<T, Context>(col_shape, dev_ctx);
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col.Resize(col_shape);
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dev_ctx.template Alloc<T>(&col);
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col_matrix.ShareDataWith(col);
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col_matrix.Resize(col_matrix_shape);
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}
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DDim in_matrix_shape =
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slice_ddim(transformed_input.dims(), 1, transformed_input.dims().size());
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DDim filter_matrix_shape = {filter.dims()[0],
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filter.numel() / filter.dims()[0]};
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filter_.Resize(filter_matrix_shape);
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DDim output_matrix_shape = {
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transformed_output.dims()[1],
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transformed_output.numel() /
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(transformed_output.dims()[0] * transformed_output.dims()[1])};
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// convolution operator: im2col(or vol2col) + gemm
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int64_t in_step = transformed_input.dims()[1] / groups;
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int64_t out_step = transformed_output.dims()[1] / groups;
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funcs::Im2ColFunctor<funcs::ColFormat::CFO, Context, T> im2col;
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funcs::Vol2ColFunctor<Context, T> vol2col;
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auto blas = funcs::GetBlas<Context, T>(dev_ctx);
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for (int64_t i = 0; i < batch_size; i++) {
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DenseTensor in_batch =
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transformed_input.Slice(i, i + 1).Resize(in_matrix_shape);
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DenseTensor out_batch =
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transformed_output.Slice(i, i + 1).Resize(output_matrix_shape);
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for (int g = 0; g < groups; g++) {
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DenseTensor in_slice = in_batch.Slice(g * in_step, (g + 1) * in_step);
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if (!is_expand) {
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col.ShareDataWith(in_slice);
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col_matrix.ShareDataWith(col);
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col_matrix.Resize(col_matrix_shape);
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} else if (data_dim == 2U) {
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im2col(dev_ctx,
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in_slice,
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dilations_,
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strides,
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std::vector<int>{
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paddings_[0], paddings_[2], paddings_[1], paddings_[3]},
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&col);
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} else if (data_dim == 3U) {
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vol2col(dev_ctx, in_slice, dilations_, strides, paddings_, &col);
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}
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// gemm
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DenseTensor out_slice = out_batch.Slice(g * out_step, (g + 1) * out_step);
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DenseTensor filter_slice =
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filter_.Slice(g * out_step, (g + 1) * out_step);
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blas.MatMul(
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filter_slice, false, col_matrix, false, T(1.0), &out_slice, T(0.0));
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}
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}
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if (channel_last) {
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TransToChannelLast<Context, T>(dev_ctx, &transformed_output, output);
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}
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}
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} // namespace phi
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