1 /* -*- mode: C++; indent-tabs-mode: nil; -*-
3 * This file is a part of LEMON, a generic C++ optimization library.
5 * Copyright (C) 2003-2009
6 * Egervary Jeno Kombinatorikus Optimalizalasi Kutatocsoport
7 * (Egervary Research Group on Combinatorial Optimization, EGRES).
9 * Permission to use, modify and distribute this software is granted
10 * provided that this copyright notice appears in all copies. For
11 * precise terms see the accompanying LICENSE file.
13 * This software is provided "AS IS" with no warranty of any kind,
14 * express or implied, and with no claim as to its suitability for any
19 #ifndef LEMON_PLANARITY_H
20 #define LEMON_PLANARITY_H
24 /// \brief Planarity checking, embedding, drawing and coloring
29 #include <lemon/dfs.h>
30 #include <lemon/bfs.h>
31 #include <lemon/radix_sort.h>
32 #include <lemon/maps.h>
33 #include <lemon/path.h>
34 #include <lemon/bucket_heap.h>
35 #include <lemon/adaptors.h>
36 #include <lemon/edge_set.h>
37 #include <lemon/color.h>
38 #include <lemon/dim2.h>
42 namespace _planarity_bits {
44 template <typename Graph>
45 struct PlanarityVisitor : DfsVisitor<Graph> {
47 TEMPLATE_GRAPH_TYPEDEFS(Graph);
49 typedef typename Graph::template NodeMap<Arc> PredMap;
51 typedef typename Graph::template EdgeMap<bool> TreeMap;
53 typedef typename Graph::template NodeMap<int> OrderMap;
54 typedef std::vector<Node> OrderList;
56 typedef typename Graph::template NodeMap<int> LowMap;
57 typedef typename Graph::template NodeMap<int> AncestorMap;
59 PlanarityVisitor(const Graph& graph,
60 PredMap& pred_map, TreeMap& tree_map,
61 OrderMap& order_map, OrderList& order_list,
62 AncestorMap& ancestor_map, LowMap& low_map)
63 : _graph(graph), _pred_map(pred_map), _tree_map(tree_map),
64 _order_map(order_map), _order_list(order_list),
65 _ancestor_map(ancestor_map), _low_map(low_map) {}
67 void reach(const Node& node) {
68 _order_map[node] = _order_list.size();
69 _low_map[node] = _order_list.size();
70 _ancestor_map[node] = _order_list.size();
71 _order_list.push_back(node);
74 void discover(const Arc& arc) {
75 Node source = _graph.source(arc);
76 Node target = _graph.target(arc);
78 _tree_map[arc] = true;
79 _pred_map[target] = arc;
82 void examine(const Arc& arc) {
83 Node source = _graph.source(arc);
84 Node target = _graph.target(arc);
86 if (_order_map[target] < _order_map[source] && !_tree_map[arc]) {
87 if (_low_map[source] > _order_map[target]) {
88 _low_map[source] = _order_map[target];
90 if (_ancestor_map[source] > _order_map[target]) {
91 _ancestor_map[source] = _order_map[target];
96 void backtrack(const Arc& arc) {
97 Node source = _graph.source(arc);
98 Node target = _graph.target(arc);
100 if (_low_map[source] > _low_map[target]) {
101 _low_map[source] = _low_map[target];
108 OrderMap& _order_map;
109 OrderList& _order_list;
110 AncestorMap& _ancestor_map;
114 template <typename Graph, bool embedding = true>
115 struct NodeDataNode {
118 typename Graph::Arc first;
122 template <typename Graph>
123 struct NodeDataNode<Graph, false> {
128 template <typename Graph>
129 struct ChildListNode {
130 typedef typename Graph::Node Node;
135 template <typename Graph>
137 typename Graph::Arc prev, next;
140 template <typename Graph>
141 class PlanarityChecking {
144 TEMPLATE_GRAPH_TYPEDEFS(Graph);
150 typedef typename Graph::template NodeMap<Arc> PredMap;
152 typedef typename Graph::template EdgeMap<bool> TreeMap;
154 typedef typename Graph::template NodeMap<int> OrderMap;
155 typedef std::vector<Node> OrderList;
157 typedef typename Graph::template NodeMap<int> LowMap;
158 typedef typename Graph::template NodeMap<int> AncestorMap;
160 typedef _planarity_bits::NodeDataNode<Graph> NodeDataNode;
161 typedef std::vector<NodeDataNode> NodeData;
163 typedef _planarity_bits::ChildListNode<Graph> ChildListNode;
164 typedef typename Graph::template NodeMap<ChildListNode> ChildLists;
166 typedef typename Graph::template NodeMap<std::list<int> > MergeRoots;
168 typedef typename Graph::template NodeMap<bool> EmbedArc;
172 PlanarityChecking(const Graph& graph) : _graph(graph) {}
175 typedef _planarity_bits::PlanarityVisitor<Graph> Visitor;
177 PredMap pred_map(_graph, INVALID);
178 TreeMap tree_map(_graph, false);
180 OrderMap order_map(_graph, -1);
181 OrderList order_list;
183 AncestorMap ancestor_map(_graph, -1);
184 LowMap low_map(_graph, -1);
186 Visitor visitor(_graph, pred_map, tree_map,
187 order_map, order_list, ancestor_map, low_map);
188 DfsVisit<Graph, Visitor> visit(_graph, visitor);
191 ChildLists child_lists(_graph);
192 createChildLists(tree_map, order_map, low_map, child_lists);
194 NodeData node_data(2 * order_list.size());
196 EmbedArc embed_arc(_graph, false);
198 MergeRoots merge_roots(_graph);
200 for (int i = order_list.size() - 1; i >= 0; --i) {
202 Node node = order_list[i];
205 for (OutArcIt e(_graph, node); e != INVALID; ++e) {
206 Node target = _graph.target(e);
208 if (order_map[source] < order_map[target] && tree_map[e]) {
209 initFace(target, node_data, order_map, order_list);
213 for (OutArcIt e(_graph, node); e != INVALID; ++e) {
214 Node target = _graph.target(e);
216 if (order_map[source] < order_map[target] && !tree_map[e]) {
217 embed_arc[target] = true;
218 walkUp(target, source, i, pred_map, low_map,
219 order_map, order_list, node_data, merge_roots);
223 for (typename MergeRoots::Value::iterator it =
224 merge_roots[node].begin();
225 it != merge_roots[node].end(); ++it) {
227 walkDown(rn, i, node_data, order_list, child_lists,
228 ancestor_map, low_map, embed_arc, merge_roots);
230 merge_roots[node].clear();
232 for (OutArcIt e(_graph, node); e != INVALID; ++e) {
233 Node target = _graph.target(e);
235 if (order_map[source] < order_map[target] && !tree_map[e]) {
236 if (embed_arc[target]) {
248 void createChildLists(const TreeMap& tree_map, const OrderMap& order_map,
249 const LowMap& low_map, ChildLists& child_lists) {
251 for (NodeIt n(_graph); n != INVALID; ++n) {
254 std::vector<Node> targets;
255 for (OutArcIt e(_graph, n); e != INVALID; ++e) {
256 Node target = _graph.target(e);
258 if (order_map[source] < order_map[target] && tree_map[e]) {
259 targets.push_back(target);
263 if (targets.size() == 0) {
264 child_lists[source].first = INVALID;
265 } else if (targets.size() == 1) {
266 child_lists[source].first = targets[0];
267 child_lists[targets[0]].prev = INVALID;
268 child_lists[targets[0]].next = INVALID;
270 radixSort(targets.begin(), targets.end(), mapToFunctor(low_map));
271 for (int i = 1; i < int(targets.size()); ++i) {
272 child_lists[targets[i]].prev = targets[i - 1];
273 child_lists[targets[i - 1]].next = targets[i];
275 child_lists[targets.back()].next = INVALID;
276 child_lists[targets.front()].prev = INVALID;
277 child_lists[source].first = targets.front();
282 void walkUp(const Node& node, Node root, int rorder,
283 const PredMap& pred_map, const LowMap& low_map,
284 const OrderMap& order_map, const OrderList& order_list,
285 NodeData& node_data, MergeRoots& merge_roots) {
290 na = nb = order_map[node];
291 da = true; db = false;
295 if (node_data[na].visited == rorder) break;
296 if (node_data[nb].visited == rorder) break;
298 node_data[na].visited = rorder;
299 node_data[nb].visited = rorder;
303 if (na >= int(order_list.size())) {
305 } else if (nb >= int(order_list.size())) {
312 nn = da ? node_data[na].prev : node_data[na].next;
313 da = node_data[nn].prev != na;
316 nn = db ? node_data[nb].prev : node_data[nb].next;
317 db = node_data[nn].prev != nb;
322 Node rep = order_list[rn - order_list.size()];
323 Node parent = _graph.source(pred_map[rep]);
325 if (low_map[rep] < rorder) {
326 merge_roots[parent].push_back(rn);
328 merge_roots[parent].push_front(rn);
331 if (parent != root) {
332 na = nb = order_map[parent];
333 da = true; db = false;
341 void walkDown(int rn, int rorder, NodeData& node_data,
342 OrderList& order_list, ChildLists& child_lists,
343 AncestorMap& ancestor_map, LowMap& low_map,
344 EmbedArc& embed_arc, MergeRoots& merge_roots) {
346 std::vector<std::pair<int, bool> > merge_stack;
348 for (int di = 0; di < 2; ++di) {
351 int n = rd ? node_data[rn].next : node_data[rn].prev;
355 Node node = order_list[n];
357 if (embed_arc[node]) {
359 // Merging components on the critical path
360 while (!merge_stack.empty()) {
363 int cn = merge_stack.back().first;
364 bool cd = merge_stack.back().second;
365 merge_stack.pop_back();
367 // Parent of component
368 int dn = merge_stack.back().first;
369 bool dd = merge_stack.back().second;
370 merge_stack.pop_back();
372 Node parent = order_list[dn];
374 // Erasing from merge_roots
375 merge_roots[parent].pop_front();
377 Node child = order_list[cn - order_list.size()];
379 // Erasing from child_lists
380 if (child_lists[child].prev != INVALID) {
381 child_lists[child_lists[child].prev].next =
382 child_lists[child].next;
384 child_lists[parent].first = child_lists[child].next;
387 if (child_lists[child].next != INVALID) {
388 child_lists[child_lists[child].next].prev =
389 child_lists[child].prev;
392 // Merging external faces
395 cn = cd ? node_data[cn].prev : node_data[cn].next;
396 cd = node_data[cn].next == en;
400 if (cd) node_data[cn].next = dn; else node_data[cn].prev = dn;
401 if (dd) node_data[dn].prev = cn; else node_data[dn].next = cn;
405 bool d = pn == node_data[n].prev;
407 if (node_data[n].prev == node_data[n].next &&
408 node_data[n].inverted) {
412 // Embedding arc into external face
413 if (rd) node_data[rn].next = n; else node_data[rn].prev = n;
414 if (d) node_data[n].prev = rn; else node_data[n].next = rn;
417 embed_arc[order_list[n]] = false;
420 if (!merge_roots[node].empty()) {
422 bool d = pn == node_data[n].prev;
424 merge_stack.push_back(std::make_pair(n, d));
426 int rn = merge_roots[node].front();
428 int xn = node_data[rn].next;
429 Node xnode = order_list[xn];
431 int yn = node_data[rn].prev;
432 Node ynode = order_list[yn];
435 if (!external(xnode, rorder, child_lists,
436 ancestor_map, low_map)) {
438 } else if (!external(ynode, rorder, child_lists,
439 ancestor_map, low_map)) {
441 } else if (pertinent(xnode, embed_arc, merge_roots)) {
447 merge_stack.push_back(std::make_pair(rn, rd));
452 } else if (!external(node, rorder, child_lists,
453 ancestor_map, low_map)) {
454 int nn = (node_data[n].next != pn ?
455 node_data[n].next : node_data[n].prev);
457 bool nd = n == node_data[nn].prev;
459 if (nd) node_data[nn].prev = pn;
460 else node_data[nn].next = pn;
462 if (n == node_data[pn].prev) node_data[pn].prev = nn;
463 else node_data[pn].next = nn;
465 node_data[nn].inverted =
466 (node_data[nn].prev == node_data[nn].next && nd != rd);
474 if (!merge_stack.empty() || n == rn) {
480 void initFace(const Node& node, NodeData& node_data,
481 const OrderMap& order_map, const OrderList& order_list) {
482 int n = order_map[node];
483 int rn = n + order_list.size();
485 node_data[n].next = node_data[n].prev = rn;
486 node_data[rn].next = node_data[rn].prev = n;
488 node_data[n].visited = order_list.size();
489 node_data[rn].visited = order_list.size();
493 bool external(const Node& node, int rorder,
494 ChildLists& child_lists, AncestorMap& ancestor_map,
496 Node child = child_lists[node].first;
498 if (child != INVALID) {
499 if (low_map[child] < rorder) return true;
502 if (ancestor_map[node] < rorder) return true;
507 bool pertinent(const Node& node, const EmbedArc& embed_arc,
508 const MergeRoots& merge_roots) {
509 return !merge_roots[node].empty() || embed_arc[node];
518 /// \brief Planarity checking of an undirected simple graph
520 /// This function implements the Boyer-Myrvold algorithm for
521 /// planarity checking of an undirected simple graph. It is a simplified
522 /// version of the PlanarEmbedding algorithm class because neither
523 /// the embedding nor the Kuratowski subdivisons are computed.
524 template <typename GR>
525 bool checkPlanarity(const GR& graph) {
526 _planarity_bits::PlanarityChecking<GR> pc(graph);
532 /// \brief Planar embedding of an undirected simple graph
534 /// This class implements the Boyer-Myrvold algorithm for planar
535 /// embedding of an undirected simple graph. The planar embedding is an
536 /// ordering of the outgoing edges of the nodes, which is a possible
537 /// configuration to draw the graph in the plane. If there is not
538 /// such ordering then the graph contains a K<sub>5</sub> (full graph
539 /// with 5 nodes) or a K<sub>3,3</sub> (complete bipartite graph on
540 /// 3 Red and 3 Blue nodes) subdivision.
542 /// The current implementation calculates either an embedding or a
543 /// Kuratowski subdivision. The running time of the algorithm is O(n).
545 /// \see PlanarDrawing, checkPlanarity()
546 template <typename Graph>
547 class PlanarEmbedding {
550 TEMPLATE_GRAPH_TYPEDEFS(Graph);
553 typename Graph::template ArcMap<Arc> _embedding;
555 typename Graph::template EdgeMap<bool> _kuratowski;
559 typedef typename Graph::template NodeMap<Arc> PredMap;
561 typedef typename Graph::template EdgeMap<bool> TreeMap;
563 typedef typename Graph::template NodeMap<int> OrderMap;
564 typedef std::vector<Node> OrderList;
566 typedef typename Graph::template NodeMap<int> LowMap;
567 typedef typename Graph::template NodeMap<int> AncestorMap;
569 typedef _planarity_bits::NodeDataNode<Graph> NodeDataNode;
570 typedef std::vector<NodeDataNode> NodeData;
572 typedef _planarity_bits::ChildListNode<Graph> ChildListNode;
573 typedef typename Graph::template NodeMap<ChildListNode> ChildLists;
575 typedef typename Graph::template NodeMap<std::list<int> > MergeRoots;
577 typedef typename Graph::template NodeMap<Arc> EmbedArc;
579 typedef _planarity_bits::ArcListNode<Graph> ArcListNode;
580 typedef typename Graph::template ArcMap<ArcListNode> ArcLists;
582 typedef typename Graph::template NodeMap<bool> FlipMap;
584 typedef typename Graph::template NodeMap<int> TypeMap;
586 enum IsolatorNodeType {
589 ROOT = 10, PERTINENT = 11,
595 /// \brief The map type for storing the embedding
597 /// The map type for storing the embedding.
598 /// \see embeddingMap()
599 typedef typename Graph::template ArcMap<Arc> EmbeddingMap;
601 /// \brief Constructor
604 /// \pre The graph must be simple, i.e. it should not
605 /// contain parallel or loop arcs.
606 PlanarEmbedding(const Graph& graph)
607 : _graph(graph), _embedding(_graph), _kuratowski(graph, false) {}
609 /// \brief Run the algorithm.
611 /// This function runs the algorithm.
612 /// \param kuratowski If this parameter is set to \c false, then the
613 /// algorithm does not compute a Kuratowski subdivision.
614 /// \return \c true if the graph is planar.
615 bool run(bool kuratowski = true) {
616 typedef _planarity_bits::PlanarityVisitor<Graph> Visitor;
618 PredMap pred_map(_graph, INVALID);
619 TreeMap tree_map(_graph, false);
621 OrderMap order_map(_graph, -1);
622 OrderList order_list;
624 AncestorMap ancestor_map(_graph, -1);
625 LowMap low_map(_graph, -1);
627 Visitor visitor(_graph, pred_map, tree_map,
628 order_map, order_list, ancestor_map, low_map);
629 DfsVisit<Graph, Visitor> visit(_graph, visitor);
632 ChildLists child_lists(_graph);
633 createChildLists(tree_map, order_map, low_map, child_lists);
635 NodeData node_data(2 * order_list.size());
637 EmbedArc embed_arc(_graph, INVALID);
639 MergeRoots merge_roots(_graph);
641 ArcLists arc_lists(_graph);
643 FlipMap flip_map(_graph, false);
645 for (int i = order_list.size() - 1; i >= 0; --i) {
647 Node node = order_list[i];
649 node_data[i].first = INVALID;
652 for (OutArcIt e(_graph, node); e != INVALID; ++e) {
653 Node target = _graph.target(e);
655 if (order_map[source] < order_map[target] && tree_map[e]) {
656 initFace(target, arc_lists, node_data,
657 pred_map, order_map, order_list);
661 for (OutArcIt e(_graph, node); e != INVALID; ++e) {
662 Node target = _graph.target(e);
664 if (order_map[source] < order_map[target] && !tree_map[e]) {
665 embed_arc[target] = e;
666 walkUp(target, source, i, pred_map, low_map,
667 order_map, order_list, node_data, merge_roots);
671 for (typename MergeRoots::Value::iterator it =
672 merge_roots[node].begin(); it != merge_roots[node].end(); ++it) {
674 walkDown(rn, i, node_data, arc_lists, flip_map, order_list,
675 child_lists, ancestor_map, low_map, embed_arc, merge_roots);
677 merge_roots[node].clear();
679 for (OutArcIt e(_graph, node); e != INVALID; ++e) {
680 Node target = _graph.target(e);
682 if (order_map[source] < order_map[target] && !tree_map[e]) {
683 if (embed_arc[target] != INVALID) {
685 isolateKuratowski(e, node_data, arc_lists, flip_map,
686 order_map, order_list, pred_map, child_lists,
687 ancestor_map, low_map,
688 embed_arc, merge_roots);
696 for (int i = 0; i < int(order_list.size()); ++i) {
698 mergeRemainingFaces(order_list[i], node_data, order_list, order_map,
699 child_lists, arc_lists);
700 storeEmbedding(order_list[i], node_data, order_map, pred_map,
701 arc_lists, flip_map);
707 /// \brief Give back the successor of an arc
709 /// This function gives back the successor of an arc. It makes
710 /// possible to query the cyclic order of the outgoing arcs from
712 Arc next(const Arc& arc) const {
713 return _embedding[arc];
716 /// \brief Give back the calculated embedding map
718 /// This function gives back the calculated embedding map, which
719 /// contains the successor of each arc in the cyclic order of the
720 /// outgoing arcs of its source node.
721 const EmbeddingMap& embeddingMap() const {
725 /// \brief Give back \c true if the given edge is in the Kuratowski
728 /// This function gives back \c true if the given edge is in the found
729 /// Kuratowski subdivision.
730 /// \pre The \c run() function must be called with \c true parameter
731 /// before using this function.
732 bool kuratowski(const Edge& edge) const {
733 return _kuratowski[edge];
738 void createChildLists(const TreeMap& tree_map, const OrderMap& order_map,
739 const LowMap& low_map, ChildLists& child_lists) {
741 for (NodeIt n(_graph); n != INVALID; ++n) {
744 std::vector<Node> targets;
745 for (OutArcIt e(_graph, n); e != INVALID; ++e) {
746 Node target = _graph.target(e);
748 if (order_map[source] < order_map[target] && tree_map[e]) {
749 targets.push_back(target);
753 if (targets.size() == 0) {
754 child_lists[source].first = INVALID;
755 } else if (targets.size() == 1) {
756 child_lists[source].first = targets[0];
757 child_lists[targets[0]].prev = INVALID;
758 child_lists[targets[0]].next = INVALID;
760 radixSort(targets.begin(), targets.end(), mapToFunctor(low_map));
761 for (int i = 1; i < int(targets.size()); ++i) {
762 child_lists[targets[i]].prev = targets[i - 1];
763 child_lists[targets[i - 1]].next = targets[i];
765 child_lists[targets.back()].next = INVALID;
766 child_lists[targets.front()].prev = INVALID;
767 child_lists[source].first = targets.front();
772 void walkUp(const Node& node, Node root, int rorder,
773 const PredMap& pred_map, const LowMap& low_map,
774 const OrderMap& order_map, const OrderList& order_list,
775 NodeData& node_data, MergeRoots& merge_roots) {
780 na = nb = order_map[node];
781 da = true; db = false;
785 if (node_data[na].visited == rorder) break;
786 if (node_data[nb].visited == rorder) break;
788 node_data[na].visited = rorder;
789 node_data[nb].visited = rorder;
793 if (na >= int(order_list.size())) {
795 } else if (nb >= int(order_list.size())) {
802 nn = da ? node_data[na].prev : node_data[na].next;
803 da = node_data[nn].prev != na;
806 nn = db ? node_data[nb].prev : node_data[nb].next;
807 db = node_data[nn].prev != nb;
812 Node rep = order_list[rn - order_list.size()];
813 Node parent = _graph.source(pred_map[rep]);
815 if (low_map[rep] < rorder) {
816 merge_roots[parent].push_back(rn);
818 merge_roots[parent].push_front(rn);
821 if (parent != root) {
822 na = nb = order_map[parent];
823 da = true; db = false;
831 void walkDown(int rn, int rorder, NodeData& node_data,
832 ArcLists& arc_lists, FlipMap& flip_map,
833 OrderList& order_list, ChildLists& child_lists,
834 AncestorMap& ancestor_map, LowMap& low_map,
835 EmbedArc& embed_arc, MergeRoots& merge_roots) {
837 std::vector<std::pair<int, bool> > merge_stack;
839 for (int di = 0; di < 2; ++di) {
842 int n = rd ? node_data[rn].next : node_data[rn].prev;
846 Node node = order_list[n];
848 if (embed_arc[node] != INVALID) {
850 // Merging components on the critical path
851 while (!merge_stack.empty()) {
854 int cn = merge_stack.back().first;
855 bool cd = merge_stack.back().second;
856 merge_stack.pop_back();
858 // Parent of component
859 int dn = merge_stack.back().first;
860 bool dd = merge_stack.back().second;
861 merge_stack.pop_back();
863 Node parent = order_list[dn];
865 // Erasing from merge_roots
866 merge_roots[parent].pop_front();
868 Node child = order_list[cn - order_list.size()];
870 // Erasing from child_lists
871 if (child_lists[child].prev != INVALID) {
872 child_lists[child_lists[child].prev].next =
873 child_lists[child].next;
875 child_lists[parent].first = child_lists[child].next;
878 if (child_lists[child].next != INVALID) {
879 child_lists[child_lists[child].next].prev =
880 child_lists[child].prev;
883 // Merging arcs + flipping
884 Arc de = node_data[dn].first;
885 Arc ce = node_data[cn].first;
887 flip_map[order_list[cn - order_list.size()]] = cd != dd;
889 std::swap(arc_lists[ce].prev, arc_lists[ce].next);
890 ce = arc_lists[ce].prev;
891 std::swap(arc_lists[ce].prev, arc_lists[ce].next);
895 Arc dne = arc_lists[de].next;
896 Arc cne = arc_lists[ce].next;
898 arc_lists[de].next = cne;
899 arc_lists[ce].next = dne;
901 arc_lists[dne].prev = ce;
902 arc_lists[cne].prev = de;
906 node_data[dn].first = ce;
909 // Merging external faces
912 cn = cd ? node_data[cn].prev : node_data[cn].next;
913 cd = node_data[cn].next == en;
915 if (node_data[cn].prev == node_data[cn].next &&
916 node_data[cn].inverted) {
921 if (cd) node_data[cn].next = dn; else node_data[cn].prev = dn;
922 if (dd) node_data[dn].prev = cn; else node_data[dn].next = cn;
926 bool d = pn == node_data[n].prev;
928 if (node_data[n].prev == node_data[n].next &&
929 node_data[n].inverted) {
935 Arc arc = embed_arc[node];
936 Arc re = node_data[rn].first;
938 arc_lists[arc_lists[re].next].prev = arc;
939 arc_lists[arc].next = arc_lists[re].next;
940 arc_lists[arc].prev = re;
941 arc_lists[re].next = arc;
944 node_data[rn].first = arc;
947 Arc rev = _graph.oppositeArc(arc);
948 Arc e = node_data[n].first;
950 arc_lists[arc_lists[e].next].prev = rev;
951 arc_lists[rev].next = arc_lists[e].next;
952 arc_lists[rev].prev = e;
953 arc_lists[e].next = rev;
956 node_data[n].first = rev;
961 // Embedding arc into external face
962 if (rd) node_data[rn].next = n; else node_data[rn].prev = n;
963 if (d) node_data[n].prev = rn; else node_data[n].next = rn;
966 embed_arc[order_list[n]] = INVALID;
969 if (!merge_roots[node].empty()) {
971 bool d = pn == node_data[n].prev;
972 if (node_data[n].prev == node_data[n].next &&
973 node_data[n].inverted) {
977 merge_stack.push_back(std::make_pair(n, d));
979 int rn = merge_roots[node].front();
981 int xn = node_data[rn].next;
982 Node xnode = order_list[xn];
984 int yn = node_data[rn].prev;
985 Node ynode = order_list[yn];
988 if (!external(xnode, rorder, child_lists, ancestor_map, low_map)) {
990 } else if (!external(ynode, rorder, child_lists,
991 ancestor_map, low_map)) {
993 } else if (pertinent(xnode, embed_arc, merge_roots)) {
999 merge_stack.push_back(std::make_pair(rn, rd));
1004 } else if (!external(node, rorder, child_lists,
1005 ancestor_map, low_map)) {
1006 int nn = (node_data[n].next != pn ?
1007 node_data[n].next : node_data[n].prev);
1009 bool nd = n == node_data[nn].prev;
1011 if (nd) node_data[nn].prev = pn;
1012 else node_data[nn].next = pn;
1014 if (n == node_data[pn].prev) node_data[pn].prev = nn;
1015 else node_data[pn].next = nn;
1017 node_data[nn].inverted =
1018 (node_data[nn].prev == node_data[nn].next && nd != rd);
1026 if (!merge_stack.empty() || n == rn) {
1032 void initFace(const Node& node, ArcLists& arc_lists,
1033 NodeData& node_data, const PredMap& pred_map,
1034 const OrderMap& order_map, const OrderList& order_list) {
1035 int n = order_map[node];
1036 int rn = n + order_list.size();
1038 node_data[n].next = node_data[n].prev = rn;
1039 node_data[rn].next = node_data[rn].prev = n;
1041 node_data[n].visited = order_list.size();
1042 node_data[rn].visited = order_list.size();
1044 node_data[n].inverted = false;
1045 node_data[rn].inverted = false;
1047 Arc arc = pred_map[node];
1048 Arc rev = _graph.oppositeArc(arc);
1050 node_data[rn].first = arc;
1051 node_data[n].first = rev;
1053 arc_lists[arc].prev = arc;
1054 arc_lists[arc].next = arc;
1056 arc_lists[rev].prev = rev;
1057 arc_lists[rev].next = rev;
1061 void mergeRemainingFaces(const Node& node, NodeData& node_data,
1062 OrderList& order_list, OrderMap& order_map,
1063 ChildLists& child_lists, ArcLists& arc_lists) {
1064 while (child_lists[node].first != INVALID) {
1065 int dd = order_map[node];
1066 Node child = child_lists[node].first;
1067 int cd = order_map[child] + order_list.size();
1068 child_lists[node].first = child_lists[child].next;
1070 Arc de = node_data[dd].first;
1071 Arc ce = node_data[cd].first;
1073 if (de != INVALID) {
1074 Arc dne = arc_lists[de].next;
1075 Arc cne = arc_lists[ce].next;
1077 arc_lists[de].next = cne;
1078 arc_lists[ce].next = dne;
1080 arc_lists[dne].prev = ce;
1081 arc_lists[cne].prev = de;
1084 node_data[dd].first = ce;
1089 void storeEmbedding(const Node& node, NodeData& node_data,
1090 OrderMap& order_map, PredMap& pred_map,
1091 ArcLists& arc_lists, FlipMap& flip_map) {
1093 if (node_data[order_map[node]].first == INVALID) return;
1095 if (pred_map[node] != INVALID) {
1096 Node source = _graph.source(pred_map[node]);
1097 flip_map[node] = flip_map[node] != flip_map[source];
1100 Arc first = node_data[order_map[node]].first;
1103 Arc arc = flip_map[node] ?
1104 arc_lists[prev].prev : arc_lists[prev].next;
1106 _embedding[prev] = arc;
1108 while (arc != first) {
1109 Arc next = arc_lists[arc].prev == prev ?
1110 arc_lists[arc].next : arc_lists[arc].prev;
1111 prev = arc; arc = next;
1112 _embedding[prev] = arc;
1117 bool external(const Node& node, int rorder,
1118 ChildLists& child_lists, AncestorMap& ancestor_map,
1120 Node child = child_lists[node].first;
1122 if (child != INVALID) {
1123 if (low_map[child] < rorder) return true;
1126 if (ancestor_map[node] < rorder) return true;
1131 bool pertinent(const Node& node, const EmbedArc& embed_arc,
1132 const MergeRoots& merge_roots) {
1133 return !merge_roots[node].empty() || embed_arc[node] != INVALID;
1136 int lowPoint(const Node& node, OrderMap& order_map, ChildLists& child_lists,
1137 AncestorMap& ancestor_map, LowMap& low_map) {
1140 Node child = child_lists[node].first;
1142 if (child != INVALID) {
1143 low_point = low_map[child];
1145 low_point = order_map[node];
1148 if (low_point > ancestor_map[node]) {
1149 low_point = ancestor_map[node];
1155 int findComponentRoot(Node root, Node node, ChildLists& child_lists,
1156 OrderMap& order_map, OrderList& order_list) {
1158 int order = order_map[root];
1159 int norder = order_map[node];
1161 Node child = child_lists[root].first;
1162 while (child != INVALID) {
1163 int corder = order_map[child];
1164 if (corder > order && corder < norder) {
1167 child = child_lists[child].next;
1169 return order + order_list.size();
1172 Node findPertinent(Node node, OrderMap& order_map, NodeData& node_data,
1173 EmbedArc& embed_arc, MergeRoots& merge_roots) {
1174 Node wnode =_graph.target(node_data[order_map[node]].first);
1175 while (!pertinent(wnode, embed_arc, merge_roots)) {
1176 wnode = _graph.target(node_data[order_map[wnode]].first);
1182 Node findExternal(Node node, int rorder, OrderMap& order_map,
1183 ChildLists& child_lists, AncestorMap& ancestor_map,
1184 LowMap& low_map, NodeData& node_data) {
1185 Node wnode =_graph.target(node_data[order_map[node]].first);
1186 while (!external(wnode, rorder, child_lists, ancestor_map, low_map)) {
1187 wnode = _graph.target(node_data[order_map[wnode]].first);
1192 void markCommonPath(Node node, int rorder, Node& wnode, Node& znode,
1193 OrderList& order_list, OrderMap& order_map,
1194 NodeData& node_data, ArcLists& arc_lists,
1195 EmbedArc& embed_arc, MergeRoots& merge_roots,
1196 ChildLists& child_lists, AncestorMap& ancestor_map,
1200 Node pred = INVALID;
1204 bool pert = pertinent(cnode, embed_arc, merge_roots);
1205 bool ext = external(cnode, rorder, child_lists, ancestor_map, low_map);
1208 if (!merge_roots[cnode].empty()) {
1209 int cn = merge_roots[cnode].back();
1211 if (low_map[order_list[cn - order_list.size()]] < rorder) {
1212 Arc arc = node_data[cn].first;
1213 _kuratowski.set(arc, true);
1216 cnode = _graph.target(arc);
1221 wnode = znode = cnode;
1227 while (!external(cnode, rorder, child_lists, ancestor_map, low_map)) {
1228 Arc arc = node_data[order_map[cnode]].first;
1230 if (_graph.target(arc) == pred) {
1231 arc = arc_lists[arc].next;
1233 _kuratowski.set(arc, true);
1235 Node next = _graph.target(arc);
1236 pred = cnode; cnode = next;
1245 while (!pertinent(cnode, embed_arc, merge_roots)) {
1246 Arc arc = node_data[order_map[cnode]].first;
1248 if (_graph.target(arc) == pred) {
1249 arc = arc_lists[arc].next;
1251 _kuratowski.set(arc, true);
1253 Node next = _graph.target(arc);
1254 pred = cnode; cnode = next;
1261 Arc arc = node_data[order_map[cnode]].first;
1263 if (_graph.target(arc) == pred) {
1264 arc = arc_lists[arc].next;
1266 _kuratowski.set(arc, true);
1268 Node next = _graph.target(arc);
1269 pred = cnode; cnode = next;
1276 void orientComponent(Node root, int rn, OrderMap& order_map,
1277 PredMap& pred_map, NodeData& node_data,
1278 ArcLists& arc_lists, FlipMap& flip_map,
1279 TypeMap& type_map) {
1280 node_data[order_map[root]].first = node_data[rn].first;
1283 std::vector<Node> st, qu;
1286 while (!st.empty()) {
1287 Node node = st.back();
1291 Arc arc = node_data[order_map[node]].first;
1293 if (type_map[_graph.target(arc)] == 0) {
1294 st.push_back(_graph.target(arc));
1295 type_map[_graph.target(arc)] = 1;
1298 Arc last = arc, pred = arc;
1299 arc = arc_lists[arc].next;
1300 while (arc != last) {
1302 if (type_map[_graph.target(arc)] == 0) {
1303 st.push_back(_graph.target(arc));
1304 type_map[_graph.target(arc)] = 1;
1307 Arc next = arc_lists[arc].next != pred ?
1308 arc_lists[arc].next : arc_lists[arc].prev;
1309 pred = arc; arc = next;
1315 flip_map[root] = false;
1317 for (int i = 1; i < int(qu.size()); ++i) {
1321 while (type_map[node] != 2) {
1324 node = _graph.source(pred_map[node]);
1327 bool flip = flip_map[node];
1329 while (!st.empty()) {
1333 flip_map[node] = flip != flip_map[node];
1334 flip = flip_map[node];
1337 Arc arc = node_data[order_map[node]].first;
1338 std::swap(arc_lists[arc].prev, arc_lists[arc].next);
1339 arc = arc_lists[arc].prev;
1340 std::swap(arc_lists[arc].prev, arc_lists[arc].next);
1341 node_data[order_map[node]].first = arc;
1346 for (int i = 0; i < int(qu.size()); ++i) {
1348 Arc arc = node_data[order_map[qu[i]]].first;
1349 Arc last = arc, pred = arc;
1351 arc = arc_lists[arc].next;
1352 while (arc != last) {
1354 if (arc_lists[arc].next == pred) {
1355 std::swap(arc_lists[arc].next, arc_lists[arc].prev);
1357 pred = arc; arc = arc_lists[arc].next;
1363 void setFaceFlags(Node root, Node wnode, Node ynode, Node xnode,
1364 OrderMap& order_map, NodeData& node_data,
1365 TypeMap& type_map) {
1366 Node node = _graph.target(node_data[order_map[root]].first);
1368 while (node != ynode) {
1369 type_map[node] = HIGHY;
1370 node = _graph.target(node_data[order_map[node]].first);
1373 while (node != wnode) {
1374 type_map[node] = LOWY;
1375 node = _graph.target(node_data[order_map[node]].first);
1378 node = _graph.target(node_data[order_map[wnode]].first);
1380 while (node != xnode) {
1381 type_map[node] = LOWX;
1382 node = _graph.target(node_data[order_map[node]].first);
1384 type_map[node] = LOWX;
1386 node = _graph.target(node_data[order_map[xnode]].first);
1387 while (node != root) {
1388 type_map[node] = HIGHX;
1389 node = _graph.target(node_data[order_map[node]].first);
1392 type_map[wnode] = PERTINENT;
1393 type_map[root] = ROOT;
1396 void findInternalPath(std::vector<Arc>& ipath,
1397 Node wnode, Node root, TypeMap& type_map,
1398 OrderMap& order_map, NodeData& node_data,
1399 ArcLists& arc_lists) {
1400 std::vector<Arc> st;
1404 while (node != root) {
1405 Arc arc = arc_lists[node_data[order_map[node]].first].next;
1407 node = _graph.target(arc);
1411 Arc arc = st.back();
1412 if (type_map[_graph.target(arc)] == LOWX ||
1413 type_map[_graph.target(arc)] == HIGHX) {
1416 if (type_map[_graph.target(arc)] == 2) {
1417 type_map[_graph.target(arc)] = 3;
1419 arc = arc_lists[_graph.oppositeArc(arc)].next;
1423 arc = arc_lists[arc].next;
1425 while (_graph.oppositeArc(arc) == st.back()) {
1428 arc = arc_lists[arc].next;
1434 for (int i = 0; i < int(st.size()); ++i) {
1435 if (type_map[_graph.target(st[i])] != LOWY &&
1436 type_map[_graph.target(st[i])] != HIGHY) {
1437 for (; i < int(st.size()); ++i) {
1438 ipath.push_back(st[i]);
1444 void setInternalFlags(std::vector<Arc>& ipath, TypeMap& type_map) {
1445 for (int i = 1; i < int(ipath.size()); ++i) {
1446 type_map[_graph.source(ipath[i])] = INTERNAL;
1450 void findPilePath(std::vector<Arc>& ppath,
1451 Node root, TypeMap& type_map, OrderMap& order_map,
1452 NodeData& node_data, ArcLists& arc_lists) {
1453 std::vector<Arc> st;
1455 st.push_back(_graph.oppositeArc(node_data[order_map[root]].first));
1456 st.push_back(node_data[order_map[root]].first);
1458 while (st.size() > 1) {
1459 Arc arc = st.back();
1460 if (type_map[_graph.target(arc)] == INTERNAL) {
1463 if (type_map[_graph.target(arc)] == 3) {
1464 type_map[_graph.target(arc)] = 4;
1466 arc = arc_lists[_graph.oppositeArc(arc)].next;
1470 arc = arc_lists[arc].next;
1472 while (!st.empty() && _graph.oppositeArc(arc) == st.back()) {
1475 arc = arc_lists[arc].next;
1481 for (int i = 1; i < int(st.size()); ++i) {
1482 ppath.push_back(st[i]);
1487 int markExternalPath(Node node, OrderMap& order_map,
1488 ChildLists& child_lists, PredMap& pred_map,
1489 AncestorMap& ancestor_map, LowMap& low_map) {
1490 int lp = lowPoint(node, order_map, child_lists,
1491 ancestor_map, low_map);
1493 if (ancestor_map[node] != lp) {
1494 node = child_lists[node].first;
1495 _kuratowski[pred_map[node]] = true;
1497 while (ancestor_map[node] != lp) {
1498 for (OutArcIt e(_graph, node); e != INVALID; ++e) {
1499 Node tnode = _graph.target(e);
1500 if (order_map[tnode] > order_map[node] && low_map[tnode] == lp) {
1502 _kuratowski[e] = true;
1509 for (OutArcIt e(_graph, node); e != INVALID; ++e) {
1510 if (order_map[_graph.target(e)] == lp) {
1511 _kuratowski[e] = true;
1519 void markPertinentPath(Node node, OrderMap& order_map,
1520 NodeData& node_data, ArcLists& arc_lists,
1521 EmbedArc& embed_arc, MergeRoots& merge_roots) {
1522 while (embed_arc[node] == INVALID) {
1523 int n = merge_roots[node].front();
1524 Arc arc = node_data[n].first;
1526 _kuratowski.set(arc, true);
1529 node = _graph.target(arc);
1530 while (!pertinent(node, embed_arc, merge_roots)) {
1531 arc = node_data[order_map[node]].first;
1532 if (_graph.target(arc) == pred) {
1533 arc = arc_lists[arc].next;
1535 _kuratowski.set(arc, true);
1537 node = _graph.target(arc);
1540 _kuratowski.set(embed_arc[node], true);
1543 void markPredPath(Node node, Node snode, PredMap& pred_map) {
1544 while (node != snode) {
1545 _kuratowski.set(pred_map[node], true);
1546 node = _graph.source(pred_map[node]);
1550 void markFacePath(Node ynode, Node xnode,
1551 OrderMap& order_map, NodeData& node_data) {
1552 Arc arc = node_data[order_map[ynode]].first;
1553 Node node = _graph.target(arc);
1554 _kuratowski.set(arc, true);
1556 while (node != xnode) {
1557 arc = node_data[order_map[node]].first;
1558 _kuratowski.set(arc, true);
1559 node = _graph.target(arc);
1563 void markInternalPath(std::vector<Arc>& path) {
1564 for (int i = 0; i < int(path.size()); ++i) {
1565 _kuratowski.set(path[i], true);
1569 void markPilePath(std::vector<Arc>& path) {
1570 for (int i = 0; i < int(path.size()); ++i) {
1571 _kuratowski.set(path[i], true);
1575 void isolateKuratowski(Arc arc, NodeData& node_data,
1576 ArcLists& arc_lists, FlipMap& flip_map,
1577 OrderMap& order_map, OrderList& order_list,
1578 PredMap& pred_map, ChildLists& child_lists,
1579 AncestorMap& ancestor_map, LowMap& low_map,
1580 EmbedArc& embed_arc, MergeRoots& merge_roots) {
1582 Node root = _graph.source(arc);
1583 Node enode = _graph.target(arc);
1585 int rorder = order_map[root];
1587 TypeMap type_map(_graph, 0);
1589 int rn = findComponentRoot(root, enode, child_lists,
1590 order_map, order_list);
1592 Node xnode = order_list[node_data[rn].next];
1593 Node ynode = order_list[node_data[rn].prev];
1597 while (!merge_roots[xnode].empty() || !merge_roots[ynode].empty()) {
1599 if (!merge_roots[xnode].empty()) {
1601 rn = merge_roots[xnode].front();
1604 rn = merge_roots[ynode].front();
1607 xnode = order_list[node_data[rn].next];
1608 ynode = order_list[node_data[rn].prev];
1611 if (root != _graph.source(arc)) {
1612 orientComponent(root, rn, order_map, pred_map,
1613 node_data, arc_lists, flip_map, type_map);
1614 markFacePath(root, root, order_map, node_data);
1615 int xlp = markExternalPath(xnode, order_map, child_lists,
1616 pred_map, ancestor_map, low_map);
1617 int ylp = markExternalPath(ynode, order_map, child_lists,
1618 pred_map, ancestor_map, low_map);
1619 markPredPath(root, order_list[xlp < ylp ? xlp : ylp], pred_map);
1620 Node lwnode = findPertinent(ynode, order_map, node_data,
1621 embed_arc, merge_roots);
1623 markPertinentPath(lwnode, order_map, node_data, arc_lists,
1624 embed_arc, merge_roots);
1630 orientComponent(root, rn, order_map, pred_map,
1631 node_data, arc_lists, flip_map, type_map);
1633 Node wnode = findPertinent(ynode, order_map, node_data,
1634 embed_arc, merge_roots);
1635 setFaceFlags(root, wnode, ynode, xnode, order_map, node_data, type_map);
1639 if (!merge_roots[wnode].empty()) {
1640 int cn = merge_roots[wnode].back();
1641 Node rep = order_list[cn - order_list.size()];
1642 if (low_map[rep] < rorder) {
1643 markFacePath(root, root, order_map, node_data);
1644 int xlp = markExternalPath(xnode, order_map, child_lists,
1645 pred_map, ancestor_map, low_map);
1646 int ylp = markExternalPath(ynode, order_map, child_lists,
1647 pred_map, ancestor_map, low_map);
1649 Node lwnode, lznode;
1650 markCommonPath(wnode, rorder, lwnode, lznode, order_list,
1651 order_map, node_data, arc_lists, embed_arc,
1652 merge_roots, child_lists, ancestor_map, low_map);
1654 markPertinentPath(lwnode, order_map, node_data, arc_lists,
1655 embed_arc, merge_roots);
1656 int zlp = markExternalPath(lznode, order_map, child_lists,
1657 pred_map, ancestor_map, low_map);
1659 int minlp = xlp < ylp ? xlp : ylp;
1660 if (zlp < minlp) minlp = zlp;
1662 int maxlp = xlp > ylp ? xlp : ylp;
1663 if (zlp > maxlp) maxlp = zlp;
1665 markPredPath(order_list[maxlp], order_list[minlp], pred_map);
1671 Node pxnode, pynode;
1672 std::vector<Arc> ipath;
1673 findInternalPath(ipath, wnode, root, type_map, order_map,
1674 node_data, arc_lists);
1675 setInternalFlags(ipath, type_map);
1676 pynode = _graph.source(ipath.front());
1677 pxnode = _graph.target(ipath.back());
1679 wnode = findPertinent(pynode, order_map, node_data,
1680 embed_arc, merge_roots);
1684 if (type_map[_graph.source(ipath.front())] == HIGHY) {
1685 if (type_map[_graph.target(ipath.back())] == HIGHX) {
1686 markFacePath(xnode, pxnode, order_map, node_data);
1688 markFacePath(root, xnode, order_map, node_data);
1689 markPertinentPath(wnode, order_map, node_data, arc_lists,
1690 embed_arc, merge_roots);
1691 markInternalPath(ipath);
1692 int xlp = markExternalPath(xnode, order_map, child_lists,
1693 pred_map, ancestor_map, low_map);
1694 int ylp = markExternalPath(ynode, order_map, child_lists,
1695 pred_map, ancestor_map, low_map);
1696 markPredPath(root, order_list[xlp < ylp ? xlp : ylp], pred_map);
1700 if (type_map[_graph.target(ipath.back())] == HIGHX) {
1701 markFacePath(ynode, root, order_map, node_data);
1702 markPertinentPath(wnode, order_map, node_data, arc_lists,
1703 embed_arc, merge_roots);
1704 markInternalPath(ipath);
1705 int xlp = markExternalPath(xnode, order_map, child_lists,
1706 pred_map, ancestor_map, low_map);
1707 int ylp = markExternalPath(ynode, order_map, child_lists,
1708 pred_map, ancestor_map, low_map);
1709 markPredPath(root, order_list[xlp < ylp ? xlp : ylp], pred_map);
1714 std::vector<Arc> ppath;
1715 findPilePath(ppath, root, type_map, order_map, node_data, arc_lists);
1718 if (!ppath.empty()) {
1719 markFacePath(ynode, xnode, order_map, node_data);
1720 markPertinentPath(wnode, order_map, node_data, arc_lists,
1721 embed_arc, merge_roots);
1722 markPilePath(ppath);
1723 markInternalPath(ipath);
1724 int xlp = markExternalPath(xnode, order_map, child_lists,
1725 pred_map, ancestor_map, low_map);
1726 int ylp = markExternalPath(ynode, order_map, child_lists,
1727 pred_map, ancestor_map, low_map);
1728 markPredPath(root, order_list[xlp < ylp ? xlp : ylp], pred_map);
1735 if (!external(wnode, rorder, child_lists, ancestor_map, low_map)) {
1736 Node znode = findExternal(pynode, rorder, order_map,
1737 child_lists, ancestor_map,
1738 low_map, node_data);
1740 if (type_map[znode] == LOWY) {
1741 markFacePath(root, xnode, order_map, node_data);
1742 markPertinentPath(wnode, order_map, node_data, arc_lists,
1743 embed_arc, merge_roots);
1744 markInternalPath(ipath);
1745 int xlp = markExternalPath(xnode, order_map, child_lists,
1746 pred_map, ancestor_map, low_map);
1747 int zlp = markExternalPath(znode, order_map, child_lists,
1748 pred_map, ancestor_map, low_map);
1749 markPredPath(root, order_list[xlp < zlp ? xlp : zlp], pred_map);
1751 markFacePath(ynode, root, order_map, node_data);
1752 markPertinentPath(wnode, order_map, node_data, arc_lists,
1753 embed_arc, merge_roots);
1754 markInternalPath(ipath);
1755 int ylp = markExternalPath(ynode, order_map, child_lists,
1756 pred_map, ancestor_map, low_map);
1757 int zlp = markExternalPath(znode, order_map, child_lists,
1758 pred_map, ancestor_map, low_map);
1759 markPredPath(root, order_list[ylp < zlp ? ylp : zlp], pred_map);
1764 int xlp = markExternalPath(xnode, order_map, child_lists,
1765 pred_map, ancestor_map, low_map);
1766 int ylp = markExternalPath(ynode, order_map, child_lists,
1767 pred_map, ancestor_map, low_map);
1768 int wlp = markExternalPath(wnode, order_map, child_lists,
1769 pred_map, ancestor_map, low_map);
1771 if (wlp > xlp && wlp > ylp) {
1772 markFacePath(root, root, order_map, node_data);
1773 markPredPath(root, order_list[xlp < ylp ? xlp : ylp], pred_map);
1777 markInternalPath(ipath);
1778 markPertinentPath(wnode, order_map, node_data, arc_lists,
1779 embed_arc, merge_roots);
1781 if (xlp > ylp && xlp > wlp) {
1782 markFacePath(root, pynode, order_map, node_data);
1783 markFacePath(wnode, xnode, order_map, node_data);
1784 markPredPath(root, order_list[ylp < wlp ? ylp : wlp], pred_map);
1788 if (ylp > xlp && ylp > wlp) {
1789 markFacePath(pxnode, root, order_map, node_data);
1790 markFacePath(ynode, wnode, order_map, node_data);
1791 markPredPath(root, order_list[xlp < wlp ? xlp : wlp], pred_map);
1795 if (pynode != ynode) {
1796 markFacePath(pxnode, wnode, order_map, node_data);
1798 int minlp = xlp < ylp ? xlp : ylp;
1799 if (wlp < minlp) minlp = wlp;
1801 int maxlp = xlp > ylp ? xlp : ylp;
1802 if (wlp > maxlp) maxlp = wlp;
1804 markPredPath(order_list[maxlp], order_list[minlp], pred_map);
1808 if (pxnode != xnode) {
1809 markFacePath(wnode, pynode, order_map, node_data);
1811 int minlp = xlp < ylp ? xlp : ylp;
1812 if (wlp < minlp) minlp = wlp;
1814 int maxlp = xlp > ylp ? xlp : ylp;
1815 if (wlp > maxlp) maxlp = wlp;
1817 markPredPath(order_list[maxlp], order_list[minlp], pred_map);
1821 markFacePath(root, root, order_map, node_data);
1822 int minlp = xlp < ylp ? xlp : ylp;
1823 if (wlp < minlp) minlp = wlp;
1824 markPredPath(root, order_list[minlp], pred_map);
1832 namespace _planarity_bits {
1834 template <typename Graph, typename EmbeddingMap>
1835 void makeConnected(Graph& graph, EmbeddingMap& embedding) {
1836 DfsVisitor<Graph> null_visitor;
1837 DfsVisit<Graph, DfsVisitor<Graph> > dfs(graph, null_visitor);
1840 typename Graph::Node u = INVALID;
1841 for (typename Graph::NodeIt n(graph); n != INVALID; ++n) {
1842 if (!dfs.reached(n)) {
1848 typename Graph::Node v = n;
1850 typename Graph::Arc ue = typename Graph::OutArcIt(graph, u);
1851 typename Graph::Arc ve = typename Graph::OutArcIt(graph, v);
1853 typename Graph::Arc e = graph.direct(graph.addEdge(u, v), true);
1855 if (ue != INVALID) {
1856 embedding[e] = embedding[ue];
1862 if (ve != INVALID) {
1863 embedding[graph.oppositeArc(e)] = embedding[ve];
1864 embedding[ve] = graph.oppositeArc(e);
1866 embedding[graph.oppositeArc(e)] = graph.oppositeArc(e);
1873 template <typename Graph, typename EmbeddingMap>
1874 void makeBiNodeConnected(Graph& graph, EmbeddingMap& embedding) {
1875 typename Graph::template ArcMap<bool> processed(graph);
1877 std::vector<typename Graph::Arc> arcs;
1878 for (typename Graph::ArcIt e(graph); e != INVALID; ++e) {
1882 IterableBoolMap<Graph, typename Graph::Node> visited(graph, false);
1884 for (int i = 0; i < int(arcs.size()); ++i) {
1885 typename Graph::Arc pp = arcs[i];
1886 if (processed[pp]) continue;
1888 typename Graph::Arc e = embedding[graph.oppositeArc(pp)];
1889 processed[e] = true;
1890 visited.set(graph.source(e), true);
1892 typename Graph::Arc p = e, l = e;
1893 e = embedding[graph.oppositeArc(e)];
1896 processed[e] = true;
1898 if (visited[graph.source(e)]) {
1900 typename Graph::Arc n =
1901 graph.direct(graph.addEdge(graph.source(p),
1902 graph.target(e)), true);
1904 embedding[graph.oppositeArc(pp)] = n;
1906 embedding[graph.oppositeArc(n)] =
1907 embedding[graph.oppositeArc(e)];
1908 embedding[graph.oppositeArc(e)] =
1909 graph.oppositeArc(n);
1912 e = embedding[graph.oppositeArc(n)];
1914 visited.set(graph.source(e), true);
1917 e = embedding[graph.oppositeArc(e)];
1920 visited.setAll(false);
1925 template <typename Graph, typename EmbeddingMap>
1926 void makeMaxPlanar(Graph& graph, EmbeddingMap& embedding) {
1928 typename Graph::template NodeMap<int> degree(graph);
1930 for (typename Graph::NodeIt n(graph); n != INVALID; ++n) {
1931 degree[n] = countIncEdges(graph, n);
1934 typename Graph::template ArcMap<bool> processed(graph);
1935 IterableBoolMap<Graph, typename Graph::Node> visited(graph, false);
1937 std::vector<typename Graph::Arc> arcs;
1938 for (typename Graph::ArcIt e(graph); e != INVALID; ++e) {
1942 for (int i = 0; i < int(arcs.size()); ++i) {
1943 typename Graph::Arc e = arcs[i];
1945 if (processed[e]) continue;
1946 processed[e] = true;
1948 typename Graph::Arc mine = e;
1949 int mind = degree[graph.source(e)];
1953 typename Graph::Arc l = e;
1954 e = embedding[graph.oppositeArc(e)];
1956 processed[e] = true;
1960 if (degree[graph.source(e)] < mind) {
1962 mind = degree[graph.source(e)];
1965 e = embedding[graph.oppositeArc(e)];
1968 if (face_size < 4) {
1972 typename Graph::Node s = graph.source(mine);
1973 for (typename Graph::OutArcIt e(graph, s); e != INVALID; ++e) {
1974 visited.set(graph.target(e), true);
1977 typename Graph::Arc oppe = INVALID;
1979 e = embedding[graph.oppositeArc(mine)];
1980 e = embedding[graph.oppositeArc(e)];
1981 while (graph.target(e) != s) {
1982 if (visited[graph.source(e)]) {
1986 e = embedding[graph.oppositeArc(e)];
1988 visited.setAll(false);
1990 if (oppe == INVALID) {
1992 e = embedding[graph.oppositeArc(mine)];
1993 typename Graph::Arc pn = mine, p = e;
1995 e = embedding[graph.oppositeArc(e)];
1996 while (graph.target(e) != s) {
1997 typename Graph::Arc n =
1998 graph.direct(graph.addEdge(s, graph.source(e)), true);
2001 embedding[graph.oppositeArc(n)] = e;
2002 embedding[graph.oppositeArc(p)] = graph.oppositeArc(n);
2007 e = embedding[graph.oppositeArc(e)];
2010 embedding[graph.oppositeArc(e)] = pn;
2014 mine = embedding[graph.oppositeArc(mine)];
2015 s = graph.source(mine);
2016 oppe = embedding[graph.oppositeArc(oppe)];
2017 typename Graph::Node t = graph.source(oppe);
2019 typename Graph::Arc ce = graph.direct(graph.addEdge(s, t), true);
2020 embedding[ce] = mine;
2021 embedding[graph.oppositeArc(ce)] = oppe;
2023 typename Graph::Arc pn = ce, p = oppe;
2024 e = embedding[graph.oppositeArc(oppe)];
2025 while (graph.target(e) != s) {
2026 typename Graph::Arc n =
2027 graph.direct(graph.addEdge(s, graph.source(e)), true);
2030 embedding[graph.oppositeArc(n)] = e;
2031 embedding[graph.oppositeArc(p)] = graph.oppositeArc(n);
2036 e = embedding[graph.oppositeArc(e)];
2039 embedding[graph.oppositeArc(e)] = pn;
2041 pn = graph.oppositeArc(ce), p = mine;
2042 e = embedding[graph.oppositeArc(mine)];
2043 while (graph.target(e) != t) {
2044 typename Graph::Arc n =
2045 graph.direct(graph.addEdge(t, graph.source(e)), true);
2048 embedding[graph.oppositeArc(n)] = e;
2049 embedding[graph.oppositeArc(p)] = graph.oppositeArc(n);
2054 e = embedding[graph.oppositeArc(e)];
2057 embedding[graph.oppositeArc(e)] = pn;
2066 /// \brief Schnyder's planar drawing algorithm
2068 /// The planar drawing algorithm calculates positions for the nodes
2069 /// in the plane. These coordinates satisfy that if the edges are
2070 /// represented with straight lines, then they will not intersect
2073 /// Scnyder's algorithm embeds the graph on an \c (n-2)x(n-2) size grid,
2074 /// i.e. each node will be located in the \c [0..n-2]x[0..n-2] square.
2075 /// The time complexity of the algorithm is O(n).
2077 /// \see PlanarEmbedding
2078 template <typename Graph>
2079 class PlanarDrawing {
2082 TEMPLATE_GRAPH_TYPEDEFS(Graph);
2084 /// \brief The point type for storing coordinates
2085 typedef dim2::Point<int> Point;
2086 /// \brief The map type for storing the coordinates of the nodes
2087 typedef typename Graph::template NodeMap<Point> PointMap;
2090 /// \brief Constructor
2093 /// \pre The graph must be simple, i.e. it should not
2094 /// contain parallel or loop arcs.
2095 PlanarDrawing(const Graph& graph)
2096 : _graph(graph), _point_map(graph) {}
2100 template <typename AuxGraph, typename AuxEmbeddingMap>
2101 void drawing(const AuxGraph& graph,
2102 const AuxEmbeddingMap& next,
2103 PointMap& point_map) {
2104 TEMPLATE_GRAPH_TYPEDEFS(AuxGraph);
2106 typename AuxGraph::template ArcMap<Arc> prev(graph);
2108 for (NodeIt n(graph); n != INVALID; ++n) {
2109 Arc e = OutArcIt(graph, n);
2122 Node anode, bnode, cnode;
2125 Arc e = ArcIt(graph);
2126 anode = graph.source(e);
2127 bnode = graph.target(e);
2128 cnode = graph.target(next[graph.oppositeArc(e)]);
2131 IterableBoolMap<AuxGraph, Node> proper(graph, false);
2132 typename AuxGraph::template NodeMap<int> conn(graph, -1);
2134 conn[anode] = conn[bnode] = -2;
2136 for (OutArcIt e(graph, anode); e != INVALID; ++e) {
2137 Node m = graph.target(e);
2138 if (conn[m] == -1) {
2144 for (OutArcIt e(graph, bnode); e != INVALID; ++e) {
2145 Node m = graph.target(e);
2146 if (conn[m] == -1) {
2148 } else if (conn[m] != -2) {
2150 Arc pe = graph.oppositeArc(e);
2151 if (conn[graph.target(next[pe])] == -2) {
2154 if (conn[graph.target(prev[pe])] == -2) {
2158 proper.set(m, conn[m] == 1);
2164 typename AuxGraph::template ArcMap<int> angle(graph, -1);
2166 while (proper.trueNum() != 0) {
2167 Node n = typename IterableBoolMap<AuxGraph, Node>::TrueIt(proper);
2168 proper.set(n, false);
2171 for (OutArcIt e(graph, n); e != INVALID; ++e) {
2172 Node m = graph.target(e);
2173 if (conn[m] == -1) {
2175 } else if (conn[m] != -2) {
2177 Arc pe = graph.oppositeArc(e);
2178 if (conn[graph.target(next[pe])] == -2) {
2181 if (conn[graph.target(prev[pe])] == -2) {
2185 proper.set(m, conn[m] == 1);
2190 Arc e = OutArcIt(graph, n);
2196 if (conn[graph.target(e)] == -2 && conn[graph.target(p)] == -2) {
2199 f = next[graph.oppositeArc(f)];
2201 f = next[graph.oppositeArc(f)];
2209 if (conn[graph.target(e)] == -2 && conn[graph.target(p)] == -2) {
2212 f = next[graph.oppositeArc(f)];
2214 f = next[graph.oppositeArc(f)];
2220 typename AuxGraph::template NodeMap<Node> apred(graph, INVALID);
2221 typename AuxGraph::template NodeMap<Node> bpred(graph, INVALID);
2222 typename AuxGraph::template NodeMap<Node> cpred(graph, INVALID);
2224 typename AuxGraph::template NodeMap<int> apredid(graph, -1);
2225 typename AuxGraph::template NodeMap<int> bpredid(graph, -1);
2226 typename AuxGraph::template NodeMap<int> cpredid(graph, -1);
2228 for (ArcIt e(graph); e != INVALID; ++e) {
2229 if (angle[e] == angle[next[e]]) {
2232 apred[graph.target(e)] = graph.source(e);
2233 apredid[graph.target(e)] = graph.id(graph.source(e));
2236 bpred[graph.target(e)] = graph.source(e);
2237 bpredid[graph.target(e)] = graph.id(graph.source(e));
2240 cpred[graph.target(e)] = graph.source(e);
2241 cpredid[graph.target(e)] = graph.id(graph.source(e));
2247 cpred[anode] = INVALID;
2248 cpred[bnode] = INVALID;
2250 std::vector<Node> aorder, border, corder;
2253 typename AuxGraph::template NodeMap<bool> processed(graph, false);
2254 std::vector<Node> st;
2255 for (NodeIt n(graph); n != INVALID; ++n) {
2256 if (!processed[n] && n != bnode && n != cnode) {
2258 processed[n] = true;
2260 while (m != INVALID && !processed[m]) {
2262 processed[m] = true;
2265 while (!st.empty()) {
2266 aorder.push_back(st.back());
2274 typename AuxGraph::template NodeMap<bool> processed(graph, false);
2275 std::vector<Node> st;
2276 for (NodeIt n(graph); n != INVALID; ++n) {
2277 if (!processed[n] && n != cnode && n != anode) {
2279 processed[n] = true;
2281 while (m != INVALID && !processed[m]) {
2283 processed[m] = true;
2286 while (!st.empty()) {
2287 border.push_back(st.back());
2295 typename AuxGraph::template NodeMap<bool> processed(graph, false);
2296 std::vector<Node> st;
2297 for (NodeIt n(graph); n != INVALID; ++n) {
2298 if (!processed[n] && n != anode && n != bnode) {
2300 processed[n] = true;
2302 while (m != INVALID && !processed[m]) {
2304 processed[m] = true;
2307 while (!st.empty()) {
2308 corder.push_back(st.back());
2315 typename AuxGraph::template NodeMap<int> atree(graph, 0);
2316 for (int i = aorder.size() - 1; i >= 0; --i) {
2319 for (OutArcIt e(graph, n); e != INVALID; ++e) {
2320 if (apred[graph.target(e)] == n) {
2321 atree[n] += atree[graph.target(e)];
2326 typename AuxGraph::template NodeMap<int> btree(graph, 0);
2327 for (int i = border.size() - 1; i >= 0; --i) {
2330 for (OutArcIt e(graph, n); e != INVALID; ++e) {
2331 if (bpred[graph.target(e)] == n) {
2332 btree[n] += btree[graph.target(e)];
2337 typename AuxGraph::template NodeMap<int> apath(graph, 0);
2338 apath[bnode] = apath[cnode] = 1;
2339 typename AuxGraph::template NodeMap<int> apath_btree(graph, 0);
2340 apath_btree[bnode] = btree[bnode];
2341 for (int i = 1; i < int(aorder.size()); ++i) {
2343 apath[n] = apath[apred[n]] + 1;
2344 apath_btree[n] = btree[n] + apath_btree[apred[n]];
2347 typename AuxGraph::template NodeMap<int> bpath_atree(graph, 0);
2348 bpath_atree[anode] = atree[anode];
2349 for (int i = 1; i < int(border.size()); ++i) {
2351 bpath_atree[n] = atree[n] + bpath_atree[bpred[n]];
2354 typename AuxGraph::template NodeMap<int> cpath(graph, 0);
2355 cpath[anode] = cpath[bnode] = 1;
2356 typename AuxGraph::template NodeMap<int> cpath_atree(graph, 0);
2357 cpath_atree[anode] = atree[anode];
2358 typename AuxGraph::template NodeMap<int> cpath_btree(graph, 0);
2359 cpath_btree[bnode] = btree[bnode];
2360 for (int i = 1; i < int(corder.size()); ++i) {
2362 cpath[n] = cpath[cpred[n]] + 1;
2363 cpath_atree[n] = atree[n] + cpath_atree[cpred[n]];
2364 cpath_btree[n] = btree[n] + cpath_btree[cpred[n]];
2367 typename AuxGraph::template NodeMap<int> third(graph);
2368 for (NodeIt n(graph); n != INVALID; ++n) {
2370 bpath_atree[n] + cpath_atree[n] - atree[n] - cpath[n] + 1;
2372 cpath_btree[n] + apath_btree[n] - btree[n] - apath[n] + 1;
2379 /// \brief Calculate the node positions
2381 /// This function calculates the node positions on the plane.
2382 /// \return \c true if the graph is planar.
2384 PlanarEmbedding<Graph> pe(_graph);
2385 if (!pe.run()) return false;
2391 /// \brief Calculate the node positions according to a
2392 /// combinatorical embedding
2394 /// This function calculates the node positions on the plane.
2395 /// The given \c embedding map should contain a valid combinatorical
2396 /// embedding, i.e. a valid cyclic order of the arcs.
2397 /// It can be computed using PlanarEmbedding.
2398 template <typename EmbeddingMap>
2399 void run(const EmbeddingMap& embedding) {
2400 typedef SmartEdgeSet<Graph> AuxGraph;
2402 if (3 * countNodes(_graph) - 6 == countEdges(_graph)) {
2403 drawing(_graph, embedding, _point_map);
2407 AuxGraph aux_graph(_graph);
2408 typename AuxGraph::template ArcMap<typename AuxGraph::Arc>
2409 aux_embedding(aux_graph);
2413 typename Graph::template EdgeMap<typename AuxGraph::Edge>
2416 for (EdgeIt e(_graph); e != INVALID; ++e) {
2417 ref[e] = aux_graph.addEdge(_graph.u(e), _graph.v(e));
2420 for (EdgeIt e(_graph); e != INVALID; ++e) {
2421 Arc ee = embedding[_graph.direct(e, true)];
2422 aux_embedding[aux_graph.direct(ref[e], true)] =
2423 aux_graph.direct(ref[ee], _graph.direction(ee));
2424 ee = embedding[_graph.direct(e, false)];
2425 aux_embedding[aux_graph.direct(ref[e], false)] =
2426 aux_graph.direct(ref[ee], _graph.direction(ee));
2429 _planarity_bits::makeConnected(aux_graph, aux_embedding);
2430 _planarity_bits::makeBiNodeConnected(aux_graph, aux_embedding);
2431 _planarity_bits::makeMaxPlanar(aux_graph, aux_embedding);
2432 drawing(aux_graph, aux_embedding, _point_map);
2435 /// \brief The coordinate of the given node
2437 /// This function returns the coordinate of the given node.
2438 Point operator[](const Node& node) const {
2439 return _point_map[node];
2442 /// \brief Return the grid embedding in a node map
2444 /// This function returns the grid embedding in a node map of
2445 /// \c dim2::Point<int> coordinates.
2446 const PointMap& coords() const {
2452 const Graph& _graph;
2453 PointMap _point_map;
2457 namespace _planarity_bits {
2459 template <typename ColorMap>
2462 typedef typename ColorMap::Key Key;
2465 KempeFilter(const ColorMap& color_map,
2466 const typename ColorMap::Value& first,
2467 const typename ColorMap::Value& second)
2468 : _color_map(color_map), _first(first), _second(second) {}
2470 Value operator[](const Key& key) const {
2471 return _color_map[key] == _first || _color_map[key] == _second;
2475 const ColorMap& _color_map;
2476 typename ColorMap::Value _first, _second;
2482 /// \brief Coloring planar graphs
2484 /// The graph coloring problem is the coloring of the graph nodes
2485 /// so that there are no adjacent nodes with the same color. The
2486 /// planar graphs can always be colored with four colors, which is
2487 /// proved by Appel and Haken. Their proofs provide a quadratic
2488 /// time algorithm for four coloring, but it could not be used to
2489 /// implement an efficient algorithm. The five and six coloring can be
2490 /// made in linear time, but in this class, the five coloring has
2491 /// quadratic worst case time complexity. The two coloring (if
2492 /// possible) is solvable with a graph search algorithm and it is
2493 /// implemented in \ref bipartitePartitions() function in LEMON. To
2494 /// decide whether a planar graph is three colorable is NP-complete.
2496 /// This class contains member functions for calculate colorings
2497 /// with five and six colors. The six coloring algorithm is a simple
2498 /// greedy coloring on the backward minimum outgoing order of nodes.
2499 /// This order can be computed by selecting the node with least
2500 /// outgoing arcs to unprocessed nodes in each phase. This order
2501 /// guarantees that when a node is chosen for coloring it has at
2502 /// most five already colored adjacents. The five coloring algorithm
2503 /// use the same method, but if the greedy approach fails to color
2504 /// with five colors, i.e. the node has five already different
2505 /// colored neighbours, it swaps the colors in one of the connected
2506 /// two colored sets with the Kempe recoloring method.
2507 template <typename Graph>
2508 class PlanarColoring {
2511 TEMPLATE_GRAPH_TYPEDEFS(Graph);
2513 /// \brief The map type for storing color indices
2514 typedef typename Graph::template NodeMap<int> IndexMap;
2515 /// \brief The map type for storing colors
2517 /// The map type for storing colors.
2518 /// \see Palette, Color
2519 typedef ComposeMap<Palette, IndexMap> ColorMap;
2521 /// \brief Constructor
2524 /// \pre The graph must be simple, i.e. it should not
2525 /// contain parallel or loop arcs.
2526 PlanarColoring(const Graph& graph)
2527 : _graph(graph), _color_map(graph), _palette(0) {
2528 _palette.add(Color(1,0,0));
2529 _palette.add(Color(0,1,0));
2530 _palette.add(Color(0,0,1));
2531 _palette.add(Color(1,1,0));
2532 _palette.add(Color(1,0,1));
2533 _palette.add(Color(0,1,1));
2536 /// \brief Return the node map of color indices
2538 /// This function returns the node map of color indices. The values are
2539 /// in the range \c [0..4] or \c [0..5] according to the coloring method.
2540 IndexMap colorIndexMap() const {
2544 /// \brief Return the node map of colors
2546 /// This function returns the node map of colors. The values are among
2547 /// five or six distinct \ref lemon::Color "colors".
2548 ColorMap colorMap() const {
2549 return composeMap(_palette, _color_map);
2552 /// \brief Return the color index of the node
2554 /// This function returns the color index of the given node. The value is
2555 /// in the range \c [0..4] or \c [0..5] according to the coloring method.
2556 int colorIndex(const Node& node) const {
2557 return _color_map[node];
2560 /// \brief Return the color of the node
2562 /// This function returns the color of the given node. The value is among
2563 /// five or six distinct \ref lemon::Color "colors".
2564 Color color(const Node& node) const {
2565 return _palette[_color_map[node]];
2569 /// \brief Calculate a coloring with at most six colors
2571 /// This function calculates a coloring with at most six colors. The time
2572 /// complexity of this variant is linear in the size of the graph.
2573 /// \return \c true if the algorithm could color the graph with six colors.
2574 /// If the algorithm fails, then the graph is not planar.
2575 /// \note This function can return \c true if the graph is not
2576 /// planar, but it can be colored with at most six colors.
2577 bool runSixColoring() {
2579 typename Graph::template NodeMap<int> heap_index(_graph, -1);
2580 BucketHeap<typename Graph::template NodeMap<int> > heap(heap_index);
2582 for (NodeIt n(_graph); n != INVALID; ++n) {
2584 heap.push(n, countOutArcs(_graph, n));
2587 std::vector<Node> order;
2589 while (!heap.empty()) {
2590 Node n = heap.top();
2594 for (OutArcIt e(_graph, n); e != INVALID; ++e) {
2595 Node t = _graph.runningNode(e);
2596 if (_color_map[t] == -2) {
2597 heap.decrease(t, heap[t] - 1);
2602 for (int i = order.size() - 1; i >= 0; --i) {
2603 std::vector<bool> forbidden(6, false);
2604 for (OutArcIt e(_graph, order[i]); e != INVALID; ++e) {
2605 Node t = _graph.runningNode(e);
2606 if (_color_map[t] != -1) {
2607 forbidden[_color_map[t]] = true;
2610 for (int k = 0; k < 6; ++k) {
2611 if (!forbidden[k]) {
2612 _color_map[order[i]] = k;
2616 if (_color_map[order[i]] == -1) {
2625 bool recolor(const Node& u, const Node& v) {
2626 int ucolor = _color_map[u];
2627 int vcolor = _color_map[v];
2628 typedef _planarity_bits::KempeFilter<IndexMap> KempeFilter;
2629 KempeFilter filter(_color_map, ucolor, vcolor);
2631 typedef FilterNodes<const Graph, const KempeFilter> KempeGraph;
2632 KempeGraph kempe_graph(_graph, filter);
2634 std::vector<Node> comp;
2635 Bfs<KempeGraph> bfs(kempe_graph);
2638 while (!bfs.emptyQueue()) {
2639 Node n = bfs.nextNode();
2640 if (n == v) return false;
2642 bfs.processNextNode();
2645 int scolor = ucolor + vcolor;
2646 for (int i = 0; i < static_cast<int>(comp.size()); ++i) {
2647 _color_map[comp[i]] = scolor - _color_map[comp[i]];
2653 template <typename EmbeddingMap>
2654 void kempeRecoloring(const Node& node, const EmbeddingMap& embedding) {
2655 std::vector<Node> nodes;
2658 for (Arc e = OutArcIt(_graph, node); e != INVALID; e = embedding[e]) {
2659 Node t = _graph.target(e);
2660 if (_color_map[t] != -1) {
2662 if (nodes.size() == 4) break;
2666 int color = _color_map[nodes[0]];
2667 if (recolor(nodes[0], nodes[2])) {
2668 _color_map[node] = color;
2670 color = _color_map[nodes[1]];
2671 recolor(nodes[1], nodes[3]);
2672 _color_map[node] = color;
2678 /// \brief Calculate a coloring with at most five colors
2680 /// This function calculates a coloring with at most five
2681 /// colors. The worst case time complexity of this variant is
2682 /// quadratic in the size of the graph.
2683 /// \param embedding This map should contain a valid combinatorical
2684 /// embedding, i.e. a valid cyclic order of the arcs.
2685 /// It can be computed using PlanarEmbedding.
2686 template <typename EmbeddingMap>
2687 void runFiveColoring(const EmbeddingMap& embedding) {
2689 typename Graph::template NodeMap<int> heap_index(_graph, -1);
2690 BucketHeap<typename Graph::template NodeMap<int> > heap(heap_index);
2692 for (NodeIt n(_graph); n != INVALID; ++n) {
2694 heap.push(n, countOutArcs(_graph, n));
2697 std::vector<Node> order;
2699 while (!heap.empty()) {
2700 Node n = heap.top();
2704 for (OutArcIt e(_graph, n); e != INVALID; ++e) {
2705 Node t = _graph.runningNode(e);
2706 if (_color_map[t] == -2) {
2707 heap.decrease(t, heap[t] - 1);
2712 for (int i = order.size() - 1; i >= 0; --i) {
2713 std::vector<bool> forbidden(5, false);
2714 for (OutArcIt e(_graph, order[i]); e != INVALID; ++e) {
2715 Node t = _graph.runningNode(e);
2716 if (_color_map[t] != -1) {
2717 forbidden[_color_map[t]] = true;
2720 for (int k = 0; k < 5; ++k) {
2721 if (!forbidden[k]) {
2722 _color_map[order[i]] = k;
2726 if (_color_map[order[i]] == -1) {
2727 kempeRecoloring(order[i], embedding);
2732 /// \brief Calculate a coloring with at most five colors
2734 /// This function calculates a coloring with at most five
2735 /// colors. The worst case time complexity of this variant is
2736 /// quadratic in the size of the graph.
2737 /// \return \c true if the graph is planar.
2738 bool runFiveColoring() {
2739 PlanarEmbedding<Graph> pe(_graph);
2740 if (!pe.run()) return false;
2742 runFiveColoring(pe.embeddingMap());
2748 const Graph& _graph;
2749 IndexMap _color_map;