/* Copyright (c) 2018 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 "framework/program/program-optimize/program_optimize.h" #include #include "framework/program/program-optimize/fusion_op_register.h" namespace paddle_mobile { namespace framework { std::shared_ptr ProgramOptimize::FusionOptimize( std::shared_ptr ori_des, bool add_split) { // ProgramDesc *optimize_program = new ProgramDesc(*ori_des); std::shared_ptr optimize_program = std::make_shared(*ori_des); current_block_ = optimize_program->Blocks().size(); for (int i = 0; i < optimize_program->Blocks().size(); ++i) { std::unordered_map> output_nodes; std::unordered_map>> type_map; std::vector> nodes; std::shared_ptr begin_node; auto block = optimize_program->Block(i); // DLOG << " ops size: " << block->Ops().size(); for (int j = 0; j < block->Ops().size(); ++j) { auto op = block->Ops()[j]; auto op_type = op->Type(); if (op_input_output_key.find(op->Type()) == op_input_output_key.end()) { LOG(kLOG_ERROR) << "has not support op return null " << " op type: " << op->Type(); return nullptr; } std::shared_ptr node = std::make_shared(op); nodes.push_back(node); // type_map[op->Type()].push_back(node); if (j == 0) { begin_node = node; } auto input_keys = op_input_output_key.at(op->Type()).first; for (auto input_key : input_keys) { auto op_inputs = op->Input(input_key); for (int l = 0; l < op_inputs.size(); ++l) { std::string input_key = op_inputs[l]; if (output_nodes.find(input_key) != output_nodes.end()) { auto input_node = output_nodes[input_key]; *input_node > node; } } } auto output_keys = op_input_output_key.at(op_type).second; for (auto output_key : output_keys) { auto op_outputs = op->Output(output_key); for (int k = 0; k < op_outputs.size(); ++k) { output_nodes[op_outputs[k]] = node; } } } for (auto ®isted : FusionOpRegister::Instance()->Matchers()) { std::string fusion_type = registed->Type(); std::shared_ptr matcher = registed; auto match_vector = type_map[matcher->BeginType()]; for (auto &match_node : match_vector) { auto depth = matcher->BeginNode().Depth(); auto sub_node = match_node->To(depth); // DLOG << " sub node: " << *sub_node; if (*sub_node == matcher->BeginNode()) { // DLOG << " match success " << " fusion node: \n" << // matcher->BeginNode() << "\nsub node: \n" << *sub_node; // DLOG << "match node\n"<< *match_node; std::vector> removed_nodes; matcher->FolderNodes(match_node.get(), &removed_nodes); for (int j = 0; j < removed_nodes.size(); ++j) { auto removed_node = removed_nodes[j]; auto removed_ite = std::find(nodes.begin(), nodes.end(), removed_node); nodes.erase(removed_ite); } } } } std::vector> op_descs; if (add_split) { GenerateOps(&op_descs, begin_node.get(), add_split); } else { for (int m = 0; m < nodes.size(); ++m) { auto &node = nodes[m]; op_descs.push_back(node->op_desc_); } } block->ops_ = op_descs; } for (int m = 0; m < new_blocks_.size(); ++m) { std::shared_ptr new_block = new_blocks_[m]; new_block->index_ = m + ori_des->blocks_.size(); optimize_program->blocks_.push_back(new_block); } return optimize_program; } void ProgramOptimize::GenerateOps( std::vector> *op_desc, Node *input_node, Node *current_node) { if (current_node->inputs_.size() > 1 && input_node != current_node->inputs_.back()) { DLOG << " current type " << current_node->type_; DLOG << " inputs size of current node > 0 "; for (int i = 0; i < current_node->inputs_.size(); ++i) { DLOG << " input i: " << current_node->inputs_[i]->type_; } return; } else if (current_node->inputs_.size() > 1 && input_node == current_node->inputs_.back()) { op_desc->push_back(current_node->op_desc_); } else { op_desc->push_back(current_node->op_desc_); } for (int i = 0; i < current_node->outputs_.size(); ++i) { auto &output = current_node->outputs_[i]; GenerateOps(op_desc, current_node, output.get()); } } void ProgramOptimize::GenerateOps( std::vector> *op_desc, Node *input_node, Node *current_node, bool adding_thread, int thread_num, std::shared_ptr new_block) { if (current_node->outputs_.size() > 1) { adding_thread = false; } bool can_add_split = false; // 如果当前节点有多个输出 并且 只有当前节点对应的 op_desc_ 输出数为 1 时支持 if (current_node->outputs_.size() > 1 && op_input_output_key[current_node->op_desc_->type_].second.size() == 1) { can_add_split = true; // 遍历当前节点的 output 节点 for (const auto &output : current_node->outputs_) { // 不支持 output 有多个 output 的情况 if (output->outputs_.size() > 1) { DLOG << "don't support multi output of output"; can_add_split = false; break; } //与节点关联的 OpDesc std::shared_ptr &op_desc = output->op_desc_; //获取这个 op 的 inputs key 和 outputs key auto inputs_and_outputs = op_input_output_key[op_desc->type_]; //判断现在 是否存在这个 op //判断这个 output 和 input key 的 size 等于 1 if (op_input_output_key.find(op_desc->type_) != op_input_output_key.end() && inputs_and_outputs.first.size() == 1 && inputs_and_outputs.second.size() == 1) { auto inputs_of_output = op_desc->Input(inputs_and_outputs.first[0]); auto outputs_of_output = op_desc->Output(inputs_and_outputs.second[0]); // 判断一下, 如果输入和输出没有同名, 是支持的 for (int i = 0; i < inputs_of_output.size(); ++i) { std::string input_of_output = inputs_of_output[i]; for (int j = 0; j < outputs_of_output.size(); ++j) { std::string output_of_output = outputs_of_output[j]; if (input_of_output == output_of_output) { DLOG << "output的 output 包含 input" << input_of_output; can_add_split = false; break; } } } } else { // 如果模型中包含没有的 op, 则不支持添加 split DLOG << "找不到 这个 op 类型: " << output->op_desc_->type_; can_add_split = false; } } } if (current_node->inputs_.size() > 1 && input_node != current_node->inputs_.back()) { return; } else if (current_node->inputs_.size() > 1 && input_node == current_node->inputs_.back()) { new_block.reset(); adding_thread = false; op_desc->push_back(current_node->op_desc_); } else { if (new_block.get() && adding_thread) { new_block->ops_.push_back(current_node->op_desc_); } else { op_desc->push_back(current_node->op_desc_); } } if (adding_thread) { Attribute attr; attr.Set(thread_num); current_node->op_desc_->attrs_["thread"] = attr; } if (can_add_split) { new_block = std::make_shared(); new_block->multi_thread_ = true; new_block->index_ = current_block_; new_blocks_.push_back(new_block); adding_thread = true; std::shared_ptr split_op_desc = std::make_shared(); split_op_desc->type_ = G_OP_TYPE_SPLIT; auto outputs = current_node->op_desc_->Output( op_input_output_key[current_node->op_desc_->Type()].second[0]); split_op_desc->inputs_ = { {op_input_output_key[G_OP_TYPE_SPLIT].first[0], outputs}}; auto &split_outputs = split_op_desc->outputs_[op_input_output_key[G_OP_TYPE_SPLIT].second[0]]; for (const auto &output : current_node->outputs_) { split_outputs.push_back(outputs[0]); } Attribute attr; attr.Set(current_block_); split_op_desc->attrs_["block_id"] = attr; op_desc->push_back(split_op_desc); current_block_++; } for (int i = 0; i < current_node->outputs_.size(); ++i) { auto &output = current_node->outputs_[i]; if (can_add_split) { GenerateOps(op_desc, current_node, output.get(), adding_thread, i, new_block); } else { GenerateOps(op_desc, current_node, output.get(), adding_thread, thread_num, new_block); } } } void ProgramOptimize::GenerateOps( std::vector> *op_descs, Node *begin_node, bool can_add_split) { // std::vector> *op_desc, // Node *input_node, Node *current_node, bool adding_thread, int // thread_num if (can_add_split) { this->GenerateOps(op_descs, begin_node, begin_node, false, -1, nullptr); } else { this->GenerateOps(op_descs, begin_node, begin_node); } } } // namespace framework } // namespace paddle_mobile