/** * \file graph.C * This file is part of LyX, the document processor. * Licence details can be found in the file COPYING. * * \author Dekel Tsur * * Full author contact details are available in file CREDITS */ #include "graph.h" #include "format.h" #include #include using std::queue; using std::vector; int Graph::bfs_init(int s, bool clear_visited) { if (s < 0) return s; Q_ = std::queue(); if (clear_visited) fill(visited_.begin(), visited_.end(), false); if (visited_[s] == false) { Q_.push(s); visited_[s] = true; } return s; } vector const Graph::getReachableTo(int target, bool clear_visited) { vector result; int const s = bfs_init(target, clear_visited); if (s < 0) return result; while (!Q_.empty()) { int const i = Q_.front(); Q_.pop(); if (i != s || formats.get(target).name() != "lyx") { result.push_back(i); } vector::iterator it = vertices_[i].in_vertices.begin(); vector::iterator end = vertices_[i].in_vertices.end(); for (; it != end; ++it) { if (!visited_[*it]) { visited_[*it] = true; Q_.push(*it); } } } return result; } vector const Graph::getReachable(int from, bool only_viewable, bool clear_visited) { vector result; if (bfs_init(from, clear_visited) < 0) return result; while (!Q_.empty()) { int const i = Q_.front(); Q_.pop(); Format const & format = formats.get(i); if (format.name() == "lyx") continue; if (!only_viewable || !format.viewer().empty() || format.isChildFormat()) result.push_back(i); vector::const_iterator cit = vertices_[i].out_vertices.begin(); vector::const_iterator end = vertices_[i].out_vertices.end(); for (; cit != end; ++cit) if (!visited_[*cit]) { visited_[*cit] = true; Q_.push(*cit); } } return result; } bool Graph::isReachable(int from, int to) { if (from == to) return true; int const s = bfs_init(from); if (s < 0 || to < 0) return false; while (!Q_.empty()) { int const i = Q_.front(); Q_.pop(); if (i == to) return true; vector::const_iterator cit = vertices_[i].out_vertices.begin(); vector::const_iterator end = vertices_[i].out_vertices.end(); for (; cit != end; ++cit) { if (!visited_[*cit]) { visited_[*cit] = true; Q_.push(*cit); } } } return false; } Graph::EdgePath const Graph::getPath(int from, int t) { EdgePath path; if (from == t) return path; int const s = bfs_init(from); if (s < 0 || t < 0) return path; vector prev_edge(formats.size()); vector prev_vertex(formats.size()); bool found = false; while (!Q_.empty()) { int const i = Q_.front(); Q_.pop(); if (i == t) { found = true; break; } vector::const_iterator beg = vertices_[i].out_vertices.begin(); vector::const_iterator cit = beg; vector::const_iterator end = vertices_[i].out_vertices.end(); for (; cit != end; ++cit) if (!visited_[*cit]) { int const j = *cit; visited_[j] = true; Q_.push(j); int const k = cit - beg; prev_edge[j] = vertices_[i].out_edges[k]; prev_vertex[j] = i; } } if (!found) return path; while (t != s) { path.push_back(prev_edge[t]); t = prev_vertex[t]; } reverse(path.begin(), path.end()); return path; } void Graph::init(int size) { vertices_ = vector(size); visited_.resize(size); numedges_ = 0; } void Graph::addEdge(int s, int t) { vertices_[t].in_vertices.push_back(s); vertices_[s].out_vertices.push_back(t); vertices_[s].out_edges.push_back(numedges_++); } vector Graph::vertices_;