/* 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 "paddle/fluid/framework/ir/graph_helper.h" #include #include #include #include #include #include DEFINE_string(print_sub_graph_dir, "", "FLAGS_print_sub_graph_dir is used " "to print the nodes of sub_graphs."); namespace paddle { namespace framework { namespace ir { namespace { void SortHelper( const std::map> &adj_list, ir::Node *node, std::unordered_set *visited, std::vector *ret) { visited->insert(node); for (auto adj : adj_list.at(node)) { if (visited->find(adj) == visited->end()) { SortHelper(adj_list, adj, visited, ret); } } VLOG(30) << "topology sort insert: " << node->Name() << reinterpret_cast(node) << " input " << node->inputs.size(); ret->push_back(node); } bool HasCircleHelper( ir::Node *node, const std::map> &adj_list, std::unordered_set *visited, std::unordered_set *in_trace) { if (visited->find(node) == visited->end()) { visited->insert(node); in_trace->insert(node); for (ir::Node *in : adj_list.at(node)) { if (visited->find(in) == visited->end() && HasCircleHelper(in, adj_list, visited, in_trace)) { return true; } else if (in_trace->find(in) != in_trace->end()) { return true; } } } in_trace->erase(node); return false; } bool HasCircleInternal( const std::map> &adj_list) { std::unordered_set visited; std::unordered_set in_trace; for (auto &adj : adj_list) { if (HasCircleHelper(adj.first, adj_list, &visited, &in_trace)) { return true; } } return false; } } // namespace bool HasCircle(const Graph &graph) { return HasCircleInternal(BuildOperationAdjList(graph)); } std::vector TopologySortOperations(const Graph &graph) { std::map> adj_list = BuildOperationAdjList(graph); PADDLE_ENFORCE(!HasCircleInternal(adj_list)); std::unordered_set visited; std::vector ret; for (auto adj : adj_list) { if (visited.find(adj.first) == visited.end()) { SortHelper(adj_list, adj.first, &visited, &ret); } } return ret; } std::map> BuildOperationAdjList( const Graph &graph) { std::map> adj_list; for (auto &n : graph.Nodes()) { if (n->NodeType() != ir::Node::Type::kOperation) continue; if (adj_list.find(n) == adj_list.end()) { adj_list[n] = std::unordered_set(); } for (auto &var : n->inputs) { for (auto &adj_n : var->inputs) { PADDLE_ENFORCE(adj_n->NodeType() == ir::Node::Type::kOperation); VLOG(40) << "adj " << adj_n->Name() << reinterpret_cast(adj_n) << " -> " << n->Name() << reinterpret_cast(n) << " via " << var->Name() << reinterpret_cast(var); adj_list[n].insert(adj_n); } } } return adj_list; } size_t GraphNum(const Graph &graph) { std::unordered_set nodes = graph.Nodes(); std::unordered_set visited_nodes; visited_nodes.reserve(nodes.size()); std::deque q_nodes; std::vector> graph_nodes; std::unordered_set g_nodes; // q_set used to record records in the queue. std::unordered_set q_set; size_t graph_count = 0; auto traverse_nodes = [&visited_nodes, &q_nodes, &q_set](const std::vector &nodes) { for (auto n : nodes) { if (visited_nodes.count(n) == 0 && q_set.count(n) == 0) { q_nodes.push_back(n); q_set.insert(n); } } }; while (visited_nodes.size() != nodes.size()) { if (!q_nodes.empty()) { auto cur_node = q_nodes.front(); q_nodes.pop_front(); q_set.erase(cur_node); visited_nodes.insert(cur_node); g_nodes.insert(cur_node); traverse_nodes(cur_node->inputs); traverse_nodes(cur_node->outputs); } else { ++graph_count; if (g_nodes.size()) { graph_nodes.emplace_back(g_nodes); } g_nodes.clear(); for (auto &n : nodes) { if (visited_nodes.count(n) == 0) { q_nodes.push_back(n); q_set.insert(n); break; } } } } if (g_nodes.size()) { graph_nodes.emplace_back(g_nodes); } if (FLAGS_print_sub_graph_dir.size()) { if (graph_nodes.size() > 1) { std::stringstream out; for (auto &g_n : graph_nodes) { out << "graph_nodes: " << g_n.size() << "\n"; } out << "\n\n"; for (auto &g_n : graph_nodes) { out << "graph_nodes: " << g_n.size(); for (auto &node : g_n) { out << "\nNode: " << node->Name() << " in ["; for (auto &n : node->inputs) { out << n->Name() << ", "; } out << "], out["; for (auto &n : node->outputs) { out << n->Name() << ", "; } out << "]"; } out << "\n\n\n"; } std::unique_ptr fout( new std::ofstream(FLAGS_print_sub_graph_dir)); PADDLE_ENFORCE(fout->good()); *fout << out.str(); } } return graph_count; } } // namespace ir } // namespace framework } // namespace paddle