lemon-0.x: lemon/planarity.h@611ced85018b (annotated)

deba@2480	1	/* -- C++ --
deba@2480	2	*
deba@2480	3	* This file is a part of LEMON, a generic C++ optimization library
deba@2480	4	*
alpar@2553	5	* Copyright (C) 2003-2008
deba@2480	6	* Egervary Jeno Kombinatorikus Optimalizalasi Kutatocsoport
deba@2480	7	* (Egervary Research Group on Combinatorial Optimization, EGRES).
deba@2480	8	*
deba@2480	9	* Permission to use, modify and distribute this software is granted
deba@2480	10	* provided that this copyright notice appears in all copies. For
deba@2480	11	* precise terms see the accompanying LICENSE file.
deba@2480	12	*
deba@2480	13	* This software is provided "AS IS" with no warranty of any kind,
deba@2480	14	* express or implied, and with no claim as to its suitability for any
deba@2480	15	* purpose.
deba@2480	16	*
deba@2480	17	*/
alpar@2553	18
deba@2480	19	#ifndef LEMON_PLANARITY_H
deba@2480	20	#define LEMON_PLANARITY_H
deba@2480	21
deba@2499	22	/// \ingroup planar
deba@2480	23	/// \file
deba@2508	24	/// \brief Planarity checking, embedding, drawing and coloring
deba@2480	25
deba@2480	26	#include <vector>
deba@2480	27	#include <list>
deba@2480	28
deba@2480	29	#include <lemon/dfs.h>
deba@2508	30	#include <lemon/bfs.h>
deba@2480	31	#include <lemon/radix_sort.h>
deba@2480	32	#include <lemon/maps.h>
deba@2480	33	#include <lemon/path.h>
deba@2499	34	#include <lemon/iterable_maps.h>
deba@2499	35	#include <lemon/edge_set.h>
deba@2508	36	#include <lemon/bucket_heap.h>
deba@2508	37	#include <lemon/ugraph_adaptor.h>
deba@2508	38	#include <lemon/color.h>
deba@2480	39
deba@2480	40
deba@2480	41	namespace lemon {
deba@2480	42
deba@2480	43	namespace _planarity_bits {
deba@2480	44
deba@2480	45	template <typename UGraph>
deba@2480	46	struct PlanarityVisitor : DfsVisitor<UGraph> {
deba@2480	47
deba@2480	48	typedef typename UGraph::Node Node;
deba@2480	49	typedef typename UGraph::Edge Edge;
deba@2480	50
deba@2480	51	typedef typename UGraph::template NodeMap<Edge> PredMap;
deba@2480	52
deba@2480	53	typedef typename UGraph::template UEdgeMap<bool> TreeMap;
deba@2480	54
deba@2480	55	typedef typename UGraph::template NodeMap<int> OrderMap;
deba@2480	56	typedef std::vector<Node> OrderList;
deba@2480	57
deba@2480	58	typedef typename UGraph::template NodeMap<int> LowMap;
deba@2480	59	typedef typename UGraph::template NodeMap<int> AncestorMap;
deba@2480	60
deba@2480	61	PlanarityVisitor(const UGraph& ugraph,
deba@2480	62	PredMap& pred_map, TreeMap& tree_map,
deba@2480	63	OrderMap& order_map, OrderList& order_list,
deba@2480	64	AncestorMap& ancestor_map, LowMap& low_map)
deba@2480	65	: _ugraph(ugraph), _pred_map(pred_map), _tree_map(tree_map),
deba@2480	66	_order_map(order_map), _order_list(order_list),
deba@2480	67	_ancestor_map(ancestor_map), _low_map(low_map) {}
deba@2480	68
deba@2480	69	void reach(const Node& node) {
deba@2480	70	_order_map[node] = _order_list.size();
deba@2480	71	_low_map[node] = _order_list.size();
deba@2480	72	_ancestor_map[node] = _order_list.size();
deba@2480	73	_order_list.push_back(node);
deba@2480	74	}
deba@2480	75
deba@2480	76	void discover(const Edge& edge) {
deba@2480	77	Node source = _ugraph.source(edge);
deba@2480	78	Node target = _ugraph.target(edge);
deba@2480	79
deba@2480	80	_tree_map[edge] = true;
deba@2480	81	_pred_map[target] = edge;
deba@2480	82	}
deba@2480	83
deba@2480	84	void examine(const Edge& edge) {
deba@2480	85	Node source = _ugraph.source(edge);
deba@2480	86	Node target = _ugraph.target(edge);
deba@2480	87
deba@2480	88	if (_order_map[target] < _order_map[source] && !_tree_map[edge]) {
deba@2480	89	if (_low_map[source] > _order_map[target]) {
deba@2480	90	_low_map[source] = _order_map[target];
deba@2480	91	}
deba@2480	92	if (_ancestor_map[source] > _order_map[target]) {
deba@2480	93	_ancestor_map[source] = _order_map[target];
deba@2480	94	}
deba@2480	95	}
deba@2480	96	}
deba@2480	97
deba@2480	98	void backtrack(const Edge& edge) {
deba@2480	99	Node source = _ugraph.source(edge);
deba@2480	100	Node target = _ugraph.target(edge);
deba@2480	101
deba@2480	102	if (_low_map[source] > _low_map[target]) {
deba@2480	103	_low_map[source] = _low_map[target];
deba@2480	104	}
deba@2480	105	}
deba@2480	106
deba@2480	107	const UGraph& _ugraph;
deba@2480	108	PredMap& _pred_map;
deba@2480	109	TreeMap& _tree_map;
deba@2480	110	OrderMap& _order_map;
deba@2480	111	OrderList& _order_list;
deba@2480	112	AncestorMap& _ancestor_map;
deba@2480	113	LowMap& _low_map;
deba@2480	114	};
deba@2480	115
deba@2480	116	template <typename UGraph, bool embedding = true>
deba@2480	117	struct NodeDataNode {
deba@2480	118	int prev, next;
deba@2480	119	int visited;
deba@2480	120	typename UGraph::Edge first;
deba@2480	121	bool inverted;
deba@2480	122	};
deba@2480	123
deba@2480	124	template <typename UGraph>
deba@2480	125	struct NodeDataNode<UGraph, false> {
deba@2480	126	int prev, next;
deba@2480	127	int visited;
deba@2480	128	};
deba@2480	129
deba@2480	130	template <typename UGraph>
deba@2480	131	struct ChildListNode {
deba@2480	132	typedef typename UGraph::Node Node;
deba@2480	133	Node first;
deba@2480	134	Node prev, next;
deba@2480	135	};
deba@2480	136
deba@2480	137	template <typename UGraph>
deba@2480	138	struct EdgeListNode {
deba@2480	139	typename UGraph::Edge prev, next;
deba@2480	140	};
deba@2480	141
deba@2480	142	}
deba@2480	143
deba@2499	144	/// \ingroup planar
deba@2480	145	///
deba@2480	146	/// \brief Planarity checking of an undirected simple graph
deba@2480	147	///
deba@2499	148	/// This class implements the Boyer-Myrvold algorithm for planarity
deba@2480	149	/// checking of an undirected graph. This class is a simplified
deba@2480	150	/// version of the PlanarEmbedding algorithm class, and it does
deba@2480	151	/// provide neither embedding nor kuratowski subdivisons.
deba@2480	152	template <typename UGraph>
deba@2480	153	class PlanarityChecking {
deba@2480	154	private:
deba@2480	155
deba@2499	156	UGRAPH_TYPEDEFS(typename UGraph);
deba@2480	157
deba@2480	158	const UGraph& _ugraph;
deba@2480	159
deba@2480	160	private:
deba@2480	161
deba@2480	162	typedef typename UGraph::template NodeMap<Edge> PredMap;
deba@2480	163
deba@2480	164	typedef typename UGraph::template UEdgeMap<bool> TreeMap;
deba@2480	165
deba@2480	166	typedef typename UGraph::template NodeMap<int> OrderMap;
deba@2480	167	typedef std::vector<Node> OrderList;
deba@2480	168
deba@2480	169	typedef typename UGraph::template NodeMap<int> LowMap;
deba@2480	170	typedef typename UGraph::template NodeMap<int> AncestorMap;
deba@2480	171
deba@2480	172	typedef _planarity_bits::NodeDataNode<UGraph> NodeDataNode;
deba@2480	173	typedef std::vector<NodeDataNode> NodeData;
deba@2480	174
deba@2480	175	typedef _planarity_bits::ChildListNode<UGraph> ChildListNode;
deba@2480	176	typedef typename UGraph::template NodeMap<ChildListNode> ChildLists;
deba@2480	177
deba@2480	178	typedef typename UGraph::template NodeMap<std::list<int> > MergeRoots;
deba@2480	179
deba@2480	180	typedef typename UGraph::template NodeMap<bool> EmbedEdge;
deba@2480	181
deba@2480	182	public:
deba@2480	183
deba@2480	184	/// \brief Constructor
deba@2480	185	///
deba@2480	186	/// \warining The graph should be simple, i.e. parallel and loop edge
deba@2480	187	/// free.
deba@2480	188	PlanarityChecking(const UGraph& ugraph) : _ugraph(ugraph) {}
deba@2480	189
deba@2480	190	/// \brief Runs the algorithm.
deba@2480	191	///
deba@2480	192	/// Runs the algorithm.
deba@2480	193	/// \return %True when the graph is planar.
deba@2481	194	bool run() {
deba@2480	195	typedef _planarity_bits::PlanarityVisitor<UGraph> Visitor;
deba@2480	196
deba@2480	197	PredMap pred_map(_ugraph, INVALID);
deba@2480	198	TreeMap tree_map(_ugraph, false);
deba@2480	199
deba@2480	200	OrderMap order_map(_ugraph, -1);
deba@2480	201	OrderList order_list;
deba@2480	202
deba@2480	203	AncestorMap ancestor_map(_ugraph, -1);
deba@2480	204	LowMap low_map(_ugraph, -1);
deba@2480	205
deba@2480	206	Visitor visitor(_ugraph, pred_map, tree_map,
deba@2480	207	order_map, order_list, ancestor_map, low_map);
deba@2480	208	DfsVisit<UGraph, Visitor> visit(_ugraph, visitor);
deba@2480	209	visit.run();
deba@2480	210
deba@2480	211	ChildLists child_lists(_ugraph);
deba@2480	212	createChildLists(tree_map, order_map, low_map, child_lists);
deba@2480	213
deba@2480	214	NodeData node_data(2 * order_list.size());
deba@2480	215
deba@2480	216	EmbedEdge embed_edge(_ugraph, false);
deba@2480	217
deba@2480	218	MergeRoots merge_roots(_ugraph);
deba@2480	219
deba@2480	220	for (int i = order_list.size() - 1; i >= 0; --i) {
deba@2480	221
deba@2480	222	Node node = order_list[i];
deba@2480	223
deba@2480	224	Node source = node;
deba@2480	225	for (OutEdgeIt e(_ugraph, node); e != INVALID; ++e) {
deba@2480	226	Node target = _ugraph.target(e);
deba@2480	227
deba@2480	228	if (order_map[source] < order_map[target] && tree_map[e]) {
deba@2481	229	initFace(target, node_data, order_map, order_list);
deba@2480	230	}
deba@2480	231	}
deba@2480	232
deba@2480	233	for (OutEdgeIt e(_ugraph, node); e != INVALID; ++e) {
deba@2480	234	Node target = _ugraph.target(e);
deba@2480	235
deba@2480	236	if (order_map[source] < order_map[target] && !tree_map[e]) {
deba@2480	237	embed_edge[target] = true;
deba@2480	238	walkUp(target, source, i, pred_map, low_map,
deba@2480	239	order_map, order_list, node_data, merge_roots);
deba@2480	240	}
deba@2480	241	}
deba@2480	242
deba@2480	243	for (typename MergeRoots::Value::iterator it =
deba@2480	244	merge_roots[node].begin(); it != merge_roots[node].end(); ++it) {
deba@2480	245	int rn = *it;
deba@2480	246	walkDown(rn, i, node_data, order_list, child_lists,
deba@2480	247	ancestor_map, low_map, embed_edge, merge_roots);
deba@2480	248	}
deba@2480	249	merge_roots[node].clear();
deba@2480	250
deba@2480	251	for (OutEdgeIt e(_ugraph, node); e != INVALID; ++e) {
deba@2480	252	Node target = _ugraph.target(e);
deba@2480	253
deba@2480	254	if (order_map[source] < order_map[target] && !tree_map[e]) {
deba@2480	255	if (embed_edge[target]) {
deba@2480	256	return false;
deba@2480	257	}
deba@2480	258	}
deba@2480	259	}
deba@2480	260	}
deba@2480	261
deba@2480	262	return true;
deba@2480	263	}
deba@2480	264
deba@2480	265	private:
deba@2480	266
deba@2480	267	void createChildLists(const TreeMap& tree_map, const OrderMap& order_map,
deba@2480	268	const LowMap& low_map, ChildLists& child_lists) {
deba@2480	269
deba@2480	270	for (NodeIt n(_ugraph); n != INVALID; ++n) {
deba@2480	271	Node source = n;
deba@2480	272
deba@2480	273	std::vector<Node> targets;
deba@2480	274	for (OutEdgeIt e(_ugraph, n); e != INVALID; ++e) {
deba@2480	275	Node target = _ugraph.target(e);
deba@2480	276
deba@2480	277	if (order_map[source] < order_map[target] && tree_map[e]) {
deba@2480	278	targets.push_back(target);
deba@2480	279	}
deba@2480	280	}
deba@2480	281
deba@2480	282	if (targets.size() == 0) {
deba@2480	283	child_lists[source].first = INVALID;
deba@2480	284	} else if (targets.size() == 1) {
deba@2480	285	child_lists[source].first = targets[0];
deba@2480	286	child_lists[targets[0]].prev = INVALID;
deba@2480	287	child_lists[targets[0]].next = INVALID;
deba@2480	288	} else {
deba@2480	289	radixSort(targets.begin(), targets.end(), mapFunctor(low_map));
deba@2480	290	for (int i = 1; i < int(targets.size()); ++i) {
deba@2480	291	child_lists[targets[i]].prev = targets[i - 1];
deba@2480	292	child_lists[targets[i - 1]].next = targets[i];
deba@2480	293	}
deba@2480	294	child_lists[targets.back()].next = INVALID;
deba@2480	295	child_lists[targets.front()].prev = INVALID;
deba@2480	296	child_lists[source].first = targets.front();
deba@2480	297	}
deba@2480	298	}
deba@2480	299	}
deba@2480	300
deba@2480	301	void walkUp(const Node& node, Node root, int rorder,
deba@2480	302	const PredMap& pred_map, const LowMap& low_map,
deba@2480	303	const OrderMap& order_map, const OrderList& order_list,
deba@2480	304	NodeData& node_data, MergeRoots& merge_roots) {
deba@2480	305
deba@2480	306	int na, nb;
deba@2480	307	bool da, db;
deba@2480	308
deba@2480	309	na = nb = order_map[node];
deba@2480	310	da = true; db = false;
deba@2480	311
deba@2480	312	while (true) {
deba@2480	313
deba@2480	314	if (node_data[na].visited == rorder) break;
deba@2480	315	if (node_data[nb].visited == rorder) break;
deba@2480	316
deba@2480	317	node_data[na].visited = rorder;
deba@2480	318	node_data[nb].visited = rorder;
deba@2480	319
deba@2480	320	int rn = -1;
deba@2480	321
deba@2480	322	if (na >= int(order_list.size())) {
deba@2480	323	rn = na;
deba@2480	324	} else if (nb >= int(order_list.size())) {
deba@2480	325	rn = nb;
deba@2480	326	}
deba@2480	327
deba@2480	328	if (rn == -1) {
deba@2480	329	int nn;
deba@2480	330
deba@2480	331	nn = da ? node_data[na].prev : node_data[na].next;
deba@2480	332	da = node_data[nn].prev != na;
deba@2480	333	na = nn;
deba@2480	334
deba@2480	335	nn = db ? node_data[nb].prev : node_data[nb].next;
deba@2480	336	db = node_data[nn].prev != nb;
deba@2480	337	nb = nn;
deba@2480	338
deba@2480	339	} else {
deba@2480	340
deba@2480	341	Node rep = order_list[rn - order_list.size()];
deba@2480	342	Node parent = _ugraph.source(pred_map[rep]);
deba@2480	343
deba@2480	344	if (low_map[rep] < rorder) {
deba@2480	345	merge_roots[parent].push_back(rn);
deba@2480	346	} else {
deba@2480	347	merge_roots[parent].push_front(rn);
deba@2480	348	}
deba@2480	349
deba@2480	350	if (parent != root) {
deba@2480	351	na = nb = order_map[parent];
deba@2480	352	da = true; db = false;
deba@2480	353	} else {
deba@2480	354	break;
deba@2480	355	}
deba@2480	356	}
deba@2480	357	}
deba@2480	358	}
deba@2480	359
deba@2480	360	void walkDown(int rn, int rorder, NodeData& node_data,
deba@2480	361	OrderList& order_list, ChildLists& child_lists,
deba@2480	362	AncestorMap& ancestor_map, LowMap& low_map,
deba@2480	363	EmbedEdge& embed_edge, MergeRoots& merge_roots) {
deba@2480	364
deba@2480	365	std::vector<std::pair<int, bool> > merge_stack;
deba@2480	366
deba@2480	367	for (int di = 0; di < 2; ++di) {
deba@2480	368	bool rd = di == 0;
deba@2480	369	int pn = rn;
deba@2480	370	int n = rd ? node_data[rn].next : node_data[rn].prev;
deba@2480	371
deba@2480	372	while (n != rn) {
deba@2480	373
deba@2480	374	Node node = order_list[n];
deba@2480	375
deba@2480	376	if (embed_edge[node]) {
deba@2480	377
deba@2480	378	// Merging components on the critical path
deba@2480	379	while (!merge_stack.empty()) {
deba@2480	380
deba@2480	381	// Component root
deba@2480	382	int cn = merge_stack.back().first;
deba@2480	383	bool cd = merge_stack.back().second;
deba@2480	384	merge_stack.pop_back();
deba@2480	385
deba@2480	386	// Parent of component
deba@2480	387	int dn = merge_stack.back().first;
deba@2480	388	bool dd = merge_stack.back().second;
deba@2480	389	merge_stack.pop_back();
deba@2480	390
deba@2480	391	Node parent = order_list[dn];
deba@2480	392
deba@2480	393	// Erasing from merge_roots
deba@2480	394	merge_roots[parent].pop_front();
deba@2480	395
deba@2480	396	Node child = order_list[cn - order_list.size()];
deba@2480	397
deba@2480	398	// Erasing from child_lists
deba@2480	399	if (child_lists[child].prev != INVALID) {
deba@2480	400	child_lists[child_lists[child].prev].next =
deba@2480	401	child_lists[child].next;
deba@2480	402	} else {
deba@2480	403	child_lists[parent].first = child_lists[child].next;
deba@2480	404	}
deba@2480	405
deba@2480	406	if (child_lists[child].next != INVALID) {
deba@2480	407	child_lists[child_lists[child].next].prev =
deba@2480	408	child_lists[child].prev;
deba@2480	409	}
deba@2480	410
deba@2480	411	// Merging external faces
deba@2480	412	{
deba@2480	413	int en = cn;
deba@2480	414	cn = cd ? node_data[cn].prev : node_data[cn].next;
deba@2480	415	cd = node_data[cn].next == en;
deba@2480	416
deba@2480	417	}
deba@2480	418
deba@2480	419	if (cd) node_data[cn].next = dn; else node_data[cn].prev = dn;
deba@2480	420	if (dd) node_data[dn].prev = cn; else node_data[dn].next = cn;
deba@2480	421
deba@2480	422	}
deba@2480	423
deba@2480	424	bool d = pn == node_data[n].prev;
deba@2480	425
deba@2480	426	if (node_data[n].prev == node_data[n].next &&
deba@2480	427	node_data[n].inverted) {
deba@2480	428	d = !d;
deba@2480	429	}
deba@2480	430
deba@2480	431	// Embedding edge into external face
deba@2480	432	if (rd) node_data[rn].next = n; else node_data[rn].prev = n;
deba@2480	433	if (d) node_data[n].prev = rn; else node_data[n].next = rn;
deba@2480	434	pn = rn;
deba@2480	435
deba@2480	436	embed_edge[order_list[n]] = false;
deba@2480	437	}
deba@2480	438
deba@2480	439	if (!merge_roots[node].empty()) {
deba@2480	440
deba@2480	441	bool d = pn == node_data[n].prev;
deba@2480	442
deba@2480	443	merge_stack.push_back(std::make_pair(n, d));
deba@2480	444
deba@2480	445	int rn = merge_roots[node].front();
deba@2480	446
deba@2480	447	int xn = node_data[rn].next;
deba@2480	448	Node xnode = order_list[xn];
deba@2480	449
deba@2480	450	int yn = node_data[rn].prev;
deba@2480	451	Node ynode = order_list[yn];
deba@2480	452
deba@2480	453	bool rd;
deba@2480	454	if (!external(xnode, rorder, child_lists, ancestor_map, low_map)) {
deba@2480	455	rd = true;
deba@2480	456	} else if (!external(ynode, rorder, child_lists,
deba@2480	457	ancestor_map, low_map)) {
deba@2480	458	rd = false;
deba@2480	459	} else if (pertinent(xnode, embed_edge, merge_roots)) {
deba@2480	460	rd = true;
deba@2480	461	} else {
deba@2480	462	rd = false;
deba@2480	463	}
deba@2480	464
deba@2480	465	merge_stack.push_back(std::make_pair(rn, rd));
deba@2480	466
deba@2480	467	pn = rn;
deba@2480	468	n = rd ? xn : yn;
deba@2480	469
deba@2480	470	} else if (!external(node, rorder, child_lists,
deba@2480	471	ancestor_map, low_map)) {
deba@2480	472	int nn = (node_data[n].next != pn ?
deba@2480	473	node_data[n].next : node_data[n].prev);
deba@2480	474
deba@2480	475	bool nd = n == node_data[nn].prev;
deba@2480	476
deba@2480	477	if (nd) node_data[nn].prev = pn;
deba@2480	478	else node_data[nn].next = pn;
deba@2480	479
deba@2480	480	if (n == node_data[pn].prev) node_data[pn].prev = nn;
deba@2480	481	else node_data[pn].next = nn;
deba@2480	482
deba@2480	483	node_data[nn].inverted =
deba@2480	484	(node_data[nn].prev == node_data[nn].next && nd != rd);
deba@2480	485
deba@2480	486	n = nn;
deba@2480	487	}
deba@2480	488	else break;
deba@2480	489
deba@2480	490	}
deba@2480	491
deba@2480	492	if (!merge_stack.empty() \|\| n == rn) {
deba@2480	493	break;
deba@2480	494	}
deba@2480	495	}
deba@2480	496	}
deba@2480	497
deba@2480	498	void initFace(const Node& node, NodeData& node_data,
deba@2481	499	const OrderMap& order_map, const OrderList& order_list) {
deba@2480	500	int n = order_map[node];
deba@2480	501	int rn = n + order_list.size();
deba@2480	502
deba@2480	503	node_data[n].next = node_data[n].prev = rn;
deba@2480	504	node_data[rn].next = node_data[rn].prev = n;
deba@2480	505
deba@2480	506	node_data[n].visited = order_list.size();
deba@2480	507	node_data[rn].visited = order_list.size();
deba@2480	508
deba@2480	509	}
deba@2480	510
deba@2480	511	bool external(const Node& node, int rorder,
deba@2480	512	ChildLists& child_lists, AncestorMap& ancestor_map,
deba@2480	513	LowMap& low_map) {
deba@2480	514	Node child = child_lists[node].first;
deba@2480	515
deba@2480	516	if (child != INVALID) {
deba@2480	517	if (low_map[child] < rorder) return true;
deba@2480	518	}
deba@2480	519
deba@2480	520	if (ancestor_map[node] < rorder) return true;
deba@2480	521
deba@2480	522	return false;
deba@2480	523	}
deba@2480	524
deba@2480	525	bool pertinent(const Node& node, const EmbedEdge& embed_edge,
deba@2480	526	const MergeRoots& merge_roots) {
deba@2480	527	return !merge_roots[node].empty() \|\| embed_edge[node];
deba@2480	528	}
deba@2480	529
deba@2480	530	};
deba@2480	531
deba@2499	532	/// \ingroup planar
deba@2480	533	///
deba@2480	534	/// \brief Planar embedding of an undirected simple graph
deba@2480	535	///
deba@2480	536	/// This class implements the Boyer-Myrvold algorithm for planar
deba@2480	537	/// embedding of an undirected graph. The planar embeding is an
deba@2480	538	/// ordering of the outgoing edges in each node, which is a possible
deba@2480	539	/// configuration to draw the graph in the plane. If there is not
deba@2480	540	/// such ordering then the graph contains a \f$ K_5 \f$ (full graph
deba@2480	541	/// with 5 nodes) or an \f$ K_{3,3} \f$ (complete bipartite graph on
deba@2480	542	/// 3 ANode and 3 BNode) subdivision.
deba@2480	543	///
deba@2480	544	/// The current implementation calculates an embedding or an
deba@2480	545	/// Kuratowski subdivision if the graph is not planar. The running
deba@2480	546	/// time of the algorithm is \f$ O(n) \f$.
deba@2480	547	template <typename UGraph>
deba@2480	548	class PlanarEmbedding {
deba@2480	549	private:
deba@2480	550
deba@2499	551	UGRAPH_TYPEDEFS(typename UGraph);
deba@2480	552
deba@2480	553	const UGraph& _ugraph;
deba@2480	554	typename UGraph::template EdgeMap<Edge> _embedding;
deba@2480	555
deba@2480	556	typename UGraph::template UEdgeMap<bool> _kuratowski;
deba@2480	557
deba@2480	558	private:
deba@2480	559
deba@2480	560	typedef typename UGraph::template NodeMap<Edge> PredMap;
deba@2480	561
deba@2480	562	typedef typename UGraph::template UEdgeMap<bool> TreeMap;
deba@2480	563
deba@2480	564	typedef typename UGraph::template NodeMap<int> OrderMap;
deba@2480	565	typedef std::vector<Node> OrderList;
deba@2480	566
deba@2480	567	typedef typename UGraph::template NodeMap<int> LowMap;
deba@2480	568	typedef typename UGraph::template NodeMap<int> AncestorMap;
deba@2480	569
deba@2480	570	typedef _planarity_bits::NodeDataNode<UGraph> NodeDataNode;
deba@2480	571	typedef std::vector<NodeDataNode> NodeData;
deba@2480	572
deba@2480	573	typedef _planarity_bits::ChildListNode<UGraph> ChildListNode;
deba@2480	574	typedef typename UGraph::template NodeMap<ChildListNode> ChildLists;
deba@2480	575
deba@2480	576	typedef typename UGraph::template NodeMap<std::list<int> > MergeRoots;
deba@2480	577
deba@2480	578	typedef typename UGraph::template NodeMap<Edge> EmbedEdge;
deba@2480	579
deba@2480	580	typedef _planarity_bits::EdgeListNode<UGraph> EdgeListNode;
deba@2480	581	typedef typename UGraph::template EdgeMap<EdgeListNode> EdgeLists;
deba@2480	582
deba@2480	583	typedef typename UGraph::template NodeMap<bool> FlipMap;
deba@2480	584
deba@2480	585	typedef typename UGraph::template NodeMap<int> TypeMap;
deba@2480	586
deba@2480	587	enum IsolatorNodeType {
deba@2480	588	HIGHX = 6, LOWX = 7,
deba@2480	589	HIGHY = 8, LOWY = 9,
deba@2480	590	ROOT = 10, PERTINENT = 11,
deba@2480	591	INTERNAL = 12
deba@2480	592	};
deba@2480	593
deba@2480	594	public:
deba@2480	595
deba@2499	596	/// \brief The map for store of embedding
deba@2499	597	typedef typename UGraph::template EdgeMap<Edge> EmbeddingMap;
deba@2499	598
deba@2480	599	/// \brief Constructor
deba@2480	600	///
deba@2480	601	/// \warining The graph should be simple, i.e. parallel and loop edge
deba@2480	602	/// free.
deba@2480	603	PlanarEmbedding(const UGraph& ugraph)
deba@2480	604	: _ugraph(ugraph), _embedding(_ugraph), _kuratowski(ugraph, false) {}
deba@2480	605
deba@2480	606	/// \brief Runs the algorithm.
deba@2480	607	///
deba@2480	608	/// Runs the algorithm.
deba@2480	609	/// \param kuratowski If the parameter is false, then the
deba@2480	610	/// algorithm does not calculate the isolate Kuratowski
deba@2480	611	/// subdivisions.
deba@2480	612	///\return %True when the graph is planar.
deba@2480	613	bool run(bool kuratowski = true) {
deba@2480	614	typedef _planarity_bits::PlanarityVisitor<UGraph> Visitor;
deba@2480	615
deba@2480	616	PredMap pred_map(_ugraph, INVALID);
deba@2480	617	TreeMap tree_map(_ugraph, false);
deba@2480	618
deba@2480	619	OrderMap order_map(_ugraph, -1);
deba@2480	620	OrderList order_list;
deba@2480	621
deba@2480	622	AncestorMap ancestor_map(_ugraph, -1);
deba@2480	623	LowMap low_map(_ugraph, -1);
deba@2480	624
deba@2480	625	Visitor visitor(_ugraph, pred_map, tree_map,
deba@2480	626	order_map, order_list, ancestor_map, low_map);
deba@2480	627	DfsVisit<UGraph, Visitor> visit(_ugraph, visitor);
deba@2480	628	visit.run();
deba@2480	629
deba@2480	630	ChildLists child_lists(_ugraph);
deba@2480	631	createChildLists(tree_map, order_map, low_map, child_lists);
deba@2480	632
deba@2480	633	NodeData node_data(2 * order_list.size());
deba@2480	634
deba@2480	635	EmbedEdge embed_edge(_ugraph, INVALID);
deba@2480	636
deba@2480	637	MergeRoots merge_roots(_ugraph);
deba@2480	638
deba@2480	639	EdgeLists edge_lists(_ugraph);
deba@2480	640
deba@2480	641	FlipMap flip_map(_ugraph, false);
deba@2480	642
deba@2480	643	for (int i = order_list.size() - 1; i >= 0; --i) {
deba@2480	644
deba@2480	645	Node node = order_list[i];
deba@2480	646
deba@2480	647	node_data[i].first = INVALID;
deba@2480	648
deba@2480	649	Node source = node;
deba@2480	650	for (OutEdgeIt e(_ugraph, node); e != INVALID; ++e) {
deba@2480	651	Node target = _ugraph.target(e);
deba@2480	652
deba@2480	653	if (order_map[source] < order_map[target] && tree_map[e]) {
deba@2480	654	initFace(target, edge_lists, node_data,
deba@2480	655	pred_map, order_map, order_list);
deba@2480	656	}
deba@2480	657	}
deba@2480	658
deba@2480	659	for (OutEdgeIt e(_ugraph, node); e != INVALID; ++e) {
deba@2480	660	Node target = _ugraph.target(e);
deba@2480	661
deba@2480	662	if (order_map[source] < order_map[target] && !tree_map[e]) {
deba@2480	663	embed_edge[target] = e;
deba@2480	664	walkUp(target, source, i, pred_map, low_map,
deba@2480	665	order_map, order_list, node_data, merge_roots);
deba@2480	666	}
deba@2480	667	}
deba@2480	668
deba@2480	669	for (typename MergeRoots::Value::iterator it =
deba@2480	670	merge_roots[node].begin(); it != merge_roots[node].end(); ++it) {
deba@2480	671	int rn = *it;
deba@2480	672	walkDown(rn, i, node_data, edge_lists, flip_map, order_list,
deba@2480	673	child_lists, ancestor_map, low_map, embed_edge, merge_roots);
deba@2480	674	}
deba@2480	675	merge_roots[node].clear();
deba@2480	676
deba@2480	677	for (OutEdgeIt e(_ugraph, node); e != INVALID; ++e) {
deba@2480	678	Node target = _ugraph.target(e);
deba@2480	679
deba@2480	680	if (order_map[source] < order_map[target] && !tree_map[e]) {
deba@2480	681	if (embed_edge[target] != INVALID) {
deba@2480	682	if (kuratowski) {
deba@2480	683	isolateKuratowski(e, node_data, edge_lists, flip_map,
deba@2480	684	order_map, order_list, pred_map, child_lists,
deba@2480	685	ancestor_map, low_map,
deba@2480	686	embed_edge, merge_roots);
deba@2480	687	}
deba@2480	688	return false;
deba@2480	689	}
deba@2480	690	}
deba@2480	691	}
deba@2480	692	}
deba@2480	693
deba@2480	694	for (int i = 0; i < int(order_list.size()); ++i) {
deba@2480	695
deba@2480	696	mergeRemainingFaces(order_list[i], node_data, order_list, order_map,
deba@2480	697	child_lists, edge_lists);
deba@2480	698	storeEmbedding(order_list[i], node_data, order_map, pred_map,
deba@2480	699	edge_lists, flip_map);
deba@2480	700	}
deba@2480	701
deba@2480	702	return true;
deba@2480	703	}
deba@2480	704
deba@2480	705	/// \brief Gives back the successor of an edge
deba@2480	706	///
deba@2480	707	/// Gives back the successor of an edge. This function makes
deba@2480	708	/// possible to query the cyclic order of the outgoing edges from
deba@2480	709	/// a node.
deba@2480	710	Edge next(const Edge& edge) const {
deba@2480	711	return _embedding[edge];
deba@2480	712	}
deba@2480	713
deba@2499	714	/// \brief Gives back the calculated embedding map
deba@2499	715	///
deba@2499	716	/// The returned map contains the successor of each edge in the
deba@2499	717	/// graph.
deba@2499	718	const EmbeddingMap& embedding() const {
deba@2499	719	return _embedding;
deba@2499	720	}
deba@2499	721
deba@2480	722	/// \brief Gives back true when the undirected edge is in the
deba@2480	723	/// kuratowski subdivision
deba@2480	724	///
deba@2480	725	/// Gives back true when the undirected edge is in the kuratowski
deba@2480	726	/// subdivision
deba@2480	727	bool kuratowski(const UEdge& uedge) {
deba@2480	728	return _kuratowski[uedge];
deba@2480	729	}
deba@2480	730
deba@2480	731	private:
deba@2480	732
deba@2480	733	void createChildLists(const TreeMap& tree_map, const OrderMap& order_map,
deba@2480	734	const LowMap& low_map, ChildLists& child_lists) {
deba@2480	735
deba@2480	736	for (NodeIt n(_ugraph); n != INVALID; ++n) {
deba@2480	737	Node source = n;
deba@2480	738
deba@2480	739	std::vector<Node> targets;
deba@2480	740	for (OutEdgeIt e(_ugraph, n); e != INVALID; ++e) {
deba@2480	741	Node target = _ugraph.target(e);
deba@2480	742
deba@2480	743	if (order_map[source] < order_map[target] && tree_map[e]) {
deba@2480	744	targets.push_back(target);
deba@2480	745	}
deba@2480	746	}
deba@2480	747
deba@2480	748	if (targets.size() == 0) {
deba@2480	749	child_lists[source].first = INVALID;
deba@2480	750	} else if (targets.size() == 1) {
deba@2480	751	child_lists[source].first = targets[0];
deba@2480	752	child_lists[targets[0]].prev = INVALID;
deba@2480	753	child_lists[targets[0]].next = INVALID;
deba@2480	754	} else {
deba@2480	755	radixSort(targets.begin(), targets.end(), mapFunctor(low_map));
deba@2480	756	for (int i = 1; i < int(targets.size()); ++i) {
deba@2480	757	child_lists[targets[i]].prev = targets[i - 1];
deba@2480	758	child_lists[targets[i - 1]].next = targets[i];
deba@2480	759	}
deba@2480	760	child_lists[targets.back()].next = INVALID;
deba@2480	761	child_lists[targets.front()].prev = INVALID;
deba@2480	762	child_lists[source].first = targets.front();
deba@2480	763	}
deba@2480	764	}
deba@2480	765	}
deba@2480	766
deba@2480	767	void walkUp(const Node& node, Node root, int rorder,
deba@2480	768	const PredMap& pred_map, const LowMap& low_map,
deba@2480	769	const OrderMap& order_map, const OrderList& order_list,
deba@2480	770	NodeData& node_data, MergeRoots& merge_roots) {
deba@2480	771
deba@2480	772	int na, nb;
deba@2480	773	bool da, db;
deba@2480	774
deba@2480	775	na = nb = order_map[node];
deba@2480	776	da = true; db = false;
deba@2480	777
deba@2480	778	while (true) {
deba@2480	779
deba@2480	780	if (node_data[na].visited == rorder) break;
deba@2480	781	if (node_data[nb].visited == rorder) break;
deba@2480	782
deba@2480	783	node_data[na].visited = rorder;
deba@2480	784	node_data[nb].visited = rorder;
deba@2480	785
deba@2480	786	int rn = -1;
deba@2480	787
deba@2480	788	if (na >= int(order_list.size())) {
deba@2480	789	rn = na;
deba@2480	790	} else if (nb >= int(order_list.size())) {
deba@2480	791	rn = nb;
deba@2480	792	}
deba@2480	793
deba@2480	794	if (rn == -1) {
deba@2480	795	int nn;
deba@2480	796
deba@2480	797	nn = da ? node_data[na].prev : node_data[na].next;
deba@2480	798	da = node_data[nn].prev != na;
deba@2480	799	na = nn;
deba@2480	800
deba@2480	801	nn = db ? node_data[nb].prev : node_data[nb].next;
deba@2480	802	db = node_data[nn].prev != nb;
deba@2480	803	nb = nn;
deba@2480	804
deba@2480	805	} else {
deba@2480	806
deba@2480	807	Node rep = order_list[rn - order_list.size()];
deba@2480	808	Node parent = _ugraph.source(pred_map[rep]);
deba@2480	809
deba@2480	810	if (low_map[rep] < rorder) {
deba@2480	811	merge_roots[parent].push_back(rn);
deba@2480	812	} else {
deba@2480	813	merge_roots[parent].push_front(rn);
deba@2480	814	}
deba@2480	815
deba@2480	816	if (parent != root) {
deba@2480	817	na = nb = order_map[parent];
deba@2480	818	da = true; db = false;
deba@2480	819	} else {
deba@2480	820	break;
deba@2480	821	}
deba@2480	822	}
deba@2480	823	}
deba@2480	824	}
deba@2480	825
deba@2480	826	void walkDown(int rn, int rorder, NodeData& node_data,
deba@2480	827	EdgeLists& edge_lists, FlipMap& flip_map,
deba@2480	828	OrderList& order_list, ChildLists& child_lists,
deba@2480	829	AncestorMap& ancestor_map, LowMap& low_map,
deba@2480	830	EmbedEdge& embed_edge, MergeRoots& merge_roots) {
deba@2480	831
deba@2480	832	std::vector<std::pair<int, bool> > merge_stack;
deba@2480	833
deba@2480	834	for (int di = 0; di < 2; ++di) {
deba@2480	835	bool rd = di == 0;
deba@2480	836	int pn = rn;
deba@2480	837	int n = rd ? node_data[rn].next : node_data[rn].prev;
deba@2480	838
deba@2480	839	while (n != rn) {
deba@2480	840
deba@2480	841	Node node = order_list[n];
deba@2480	842
deba@2480	843	if (embed_edge[node] != INVALID) {
deba@2480	844
deba@2480	845	// Merging components on the critical path
deba@2480	846	while (!merge_stack.empty()) {
deba@2480	847
deba@2480	848	// Component root
deba@2480	849	int cn = merge_stack.back().first;
deba@2480	850	bool cd = merge_stack.back().second;
deba@2480	851	merge_stack.pop_back();
deba@2480	852
deba@2480	853	// Parent of component
deba@2480	854	int dn = merge_stack.back().first;
deba@2480	855	bool dd = merge_stack.back().second;
deba@2480	856	merge_stack.pop_back();
deba@2480	857
deba@2480	858	Node parent = order_list[dn];
deba@2480	859
deba@2480	860	// Erasing from merge_roots
deba@2480	861	merge_roots[parent].pop_front();
deba@2480	862
deba@2480	863	Node child = order_list[cn - order_list.size()];
deba@2480	864
deba@2480	865	// Erasing from child_lists
deba@2480	866	if (child_lists[child].prev != INVALID) {
deba@2480	867	child_lists[child_lists[child].prev].next =
deba@2480	868	child_lists[child].next;
deba@2480	869	} else {
deba@2480	870	child_lists[parent].first = child_lists[child].next;
deba@2480	871	}
deba@2480	872
deba@2480	873	if (child_lists[child].next != INVALID) {
deba@2480	874	child_lists[child_lists[child].next].prev =
deba@2480	875	child_lists[child].prev;
deba@2480	876	}
deba@2480	877
deba@2480	878	// Merging edges + flipping
deba@2480	879	Edge de = node_data[dn].first;
deba@2480	880	Edge ce = node_data[cn].first;
deba@2480	881
deba@2480	882	flip_map[order_list[cn - order_list.size()]] = cd != dd;
deba@2480	883	if (cd != dd) {
deba@2480	884	std::swap(edge_lists[ce].prev, edge_lists[ce].next);
deba@2480	885	ce = edge_lists[ce].prev;
deba@2480	886	std::swap(edge_lists[ce].prev, edge_lists[ce].next);
deba@2480	887	}
deba@2480	888
deba@2480	889	{
deba@2480	890	Edge dne = edge_lists[de].next;
deba@2480	891	Edge cne = edge_lists[ce].next;
deba@2480	892
deba@2480	893	edge_lists[de].next = cne;
deba@2480	894	edge_lists[ce].next = dne;
deba@2480	895
deba@2480	896	edge_lists[dne].prev = ce;
deba@2480	897	edge_lists[cne].prev = de;
deba@2480	898	}
deba@2480	899
deba@2480	900	if (dd) {
deba@2480	901	node_data[dn].first = ce;
deba@2480	902	}
deba@2480	903
deba@2480	904	// Merging external faces
deba@2480	905	{
deba@2480	906	int en = cn;
deba@2480	907	cn = cd ? node_data[cn].prev : node_data[cn].next;
deba@2480	908	cd = node_data[cn].next == en;
deba@2480	909
deba@2480	910	if (node_data[cn].prev == node_data[cn].next &&
deba@2480	911	node_data[cn].inverted) {
deba@2480	912	cd = !cd;
deba@2480	913	}
deba@2480	914	}
deba@2480	915
deba@2480	916	if (cd) node_data[cn].next = dn; else node_data[cn].prev = dn;
deba@2480	917	if (dd) node_data[dn].prev = cn; else node_data[dn].next = cn;
deba@2480	918
deba@2480	919	}
deba@2480	920
deba@2480	921	bool d = pn == node_data[n].prev;
deba@2480	922
deba@2480	923	if (node_data[n].prev == node_data[n].next &&
deba@2480	924	node_data[n].inverted) {
deba@2480	925	d = !d;
deba@2480	926	}
deba@2480	927
deba@2480	928	// Add new edge
deba@2480	929	{
deba@2480	930	Edge edge = embed_edge[node];
deba@2480	931	Edge re = node_data[rn].first;
deba@2480	932
deba@2480	933	edge_lists[edge_lists[re].next].prev = edge;
deba@2480	934	edge_lists[edge].next = edge_lists[re].next;
deba@2480	935	edge_lists[edge].prev = re;
deba@2480	936	edge_lists[re].next = edge;
deba@2480	937
deba@2480	938	if (!rd) {
deba@2480	939	node_data[rn].first = edge;
deba@2480	940	}
deba@2480	941
deba@2480	942	Edge rev = _ugraph.oppositeEdge(edge);
deba@2480	943	Edge e = node_data[n].first;
deba@2480	944
deba@2480	945	edge_lists[edge_lists[e].next].prev = rev;
deba@2480	946	edge_lists[rev].next = edge_lists[e].next;
deba@2480	947	edge_lists[rev].prev = e;
deba@2480	948	edge_lists[e].next = rev;
deba@2480	949
deba@2480	950	if (d) {
deba@2480	951	node_data[n].first = rev;
deba@2480	952	}
deba@2480	953
deba@2480	954	}
deba@2480	955
deba@2480	956	// Embedding edge into external face
deba@2480	957	if (rd) node_data[rn].next = n; else node_data[rn].prev = n;
deba@2480	958	if (d) node_data[n].prev = rn; else node_data[n].next = rn;
deba@2480	959	pn = rn;
deba@2480	960
deba@2480	961	embed_edge[order_list[n]] = INVALID;
deba@2480	962	}
deba@2480	963
deba@2480	964	if (!merge_roots[node].empty()) {
deba@2480	965
deba@2480	966	bool d = pn == node_data[n].prev;
deba@2480	967	if (node_data[n].prev == node_data[n].next &&
deba@2480	968	node_data[n].inverted) {
deba@2480	969	d = !d;
deba@2480	970	}
deba@2480	971
deba@2480	972	merge_stack.push_back(std::make_pair(n, d));
deba@2480	973
deba@2480	974	int rn = merge_roots[node].front();
deba@2480	975
deba@2480	976	int xn = node_data[rn].next;
deba@2480	977	Node xnode = order_list[xn];
deba@2480	978
deba@2480	979	int yn = node_data[rn].prev;
deba@2480	980	Node ynode = order_list[yn];
deba@2480	981
deba@2480	982	bool rd;
deba@2480	983	if (!external(xnode, rorder, child_lists, ancestor_map, low_map)) {
deba@2480	984	rd = true;
deba@2480	985	} else if (!external(ynode, rorder, child_lists,
deba@2480	986	ancestor_map, low_map)) {
deba@2480	987	rd = false;
deba@2480	988	} else if (pertinent(xnode, embed_edge, merge_roots)) {
deba@2480	989	rd = true;
deba@2480	990	} else {
deba@2480	991	rd = false;
deba@2480	992	}
deba@2480	993
deba@2480	994	merge_stack.push_back(std::make_pair(rn, rd));
deba@2480	995
deba@2480	996	pn = rn;
deba@2480	997	n = rd ? xn : yn;
deba@2480	998
deba@2480	999	} else if (!external(node, rorder, child_lists,
deba@2480	1000	ancestor_map, low_map)) {
deba@2480	1001	int nn = (node_data[n].next != pn ?
deba@2480	1002	node_data[n].next : node_data[n].prev);
deba@2480	1003
deba@2480	1004	bool nd = n == node_data[nn].prev;
deba@2480	1005
deba@2480	1006	if (nd) node_data[nn].prev = pn;
deba@2480	1007	else node_data[nn].next = pn;
deba@2480	1008
deba@2480	1009	if (n == node_data[pn].prev) node_data[pn].prev = nn;
deba@2480	1010	else node_data[pn].next = nn;
deba@2480	1011
deba@2480	1012	node_data[nn].inverted =
deba@2480	1013	(node_data[nn].prev == node_data[nn].next && nd != rd);
deba@2480	1014
deba@2480	1015	n = nn;
deba@2480	1016	}
deba@2480	1017	else break;
deba@2480	1018
deba@2480	1019	}
deba@2480	1020
deba@2480	1021	if (!merge_stack.empty() \|\| n == rn) {
deba@2480	1022	break;
deba@2480	1023	}
deba@2480	1024	}
deba@2480	1025	}
deba@2480	1026
deba@2480	1027	void initFace(const Node& node, EdgeLists& edge_lists,
deba@2480	1028	NodeData& node_data, const PredMap& pred_map,
deba@2480	1029	const OrderMap& order_map, const OrderList& order_list) {
deba@2480	1030	int n = order_map[node];
deba@2480	1031	int rn = n + order_list.size();
deba@2480	1032
deba@2480	1033	node_data[n].next = node_data[n].prev = rn;
deba@2480	1034	node_data[rn].next = node_data[rn].prev = n;
deba@2480	1035
deba@2480	1036	node_data[n].visited = order_list.size();
deba@2480	1037	node_data[rn].visited = order_list.size();
deba@2480	1038
deba@2480	1039	node_data[n].inverted = false;
deba@2480	1040	node_data[rn].inverted = false;
deba@2480	1041
deba@2480	1042	Edge edge = pred_map[node];
deba@2480	1043	Edge rev = _ugraph.oppositeEdge(edge);
deba@2480	1044
deba@2480	1045	node_data[rn].first = edge;
deba@2480	1046	node_data[n].first = rev;
deba@2480	1047
deba@2480	1048	edge_lists[edge].prev = edge;
deba@2480	1049	edge_lists[edge].next = edge;
deba@2480	1050
deba@2480	1051	edge_lists[rev].prev = rev;
deba@2480	1052	edge_lists[rev].next = rev;
deba@2480	1053
deba@2480	1054	}
deba@2480	1055
deba@2480	1056	void mergeRemainingFaces(const Node& node, NodeData& node_data,
deba@2480	1057	OrderList& order_list, OrderMap& order_map,
deba@2480	1058	ChildLists& child_lists, EdgeLists& edge_lists) {
deba@2480	1059	while (child_lists[node].first != INVALID) {
deba@2480	1060	int dd = order_map[node];
deba@2480	1061	Node child = child_lists[node].first;
deba@2480	1062	int cd = order_map[child] + order_list.size();
deba@2480	1063	child_lists[node].first = child_lists[child].next;
deba@2480	1064
deba@2480	1065	Edge de = node_data[dd].first;
deba@2480	1066	Edge ce = node_data[cd].first;
deba@2480	1067
deba@2480	1068	if (de != INVALID) {
deba@2480	1069	Edge dne = edge_lists[de].next;
deba@2480	1070	Edge cne = edge_lists[ce].next;
deba@2480	1071
deba@2480	1072	edge_lists[de].next = cne;
deba@2480	1073	edge_lists[ce].next = dne;
deba@2480	1074
deba@2480	1075	edge_lists[dne].prev = ce;
deba@2480	1076	edge_lists[cne].prev = de;
deba@2480	1077	}
deba@2480	1078
deba@2480	1079	node_data[dd].first = ce;
deba@2480	1080
deba@2480	1081	}
deba@2480	1082	}
deba@2480	1083
deba@2480	1084	void storeEmbedding(const Node& node, NodeData& node_data,
deba@2480	1085	OrderMap& order_map, PredMap& pred_map,
deba@2480	1086	EdgeLists& edge_lists, FlipMap& flip_map) {
deba@2480	1087
deba@2480	1088	if (node_data[order_map[node]].first == INVALID) return;
deba@2480	1089
deba@2480	1090	if (pred_map[node] != INVALID) {
deba@2480	1091	Node source = _ugraph.source(pred_map[node]);
deba@2480	1092	flip_map[node] = flip_map[node] != flip_map[source];
deba@2480	1093	}
deba@2480	1094
deba@2480	1095	Edge first = node_data[order_map[node]].first;
deba@2480	1096	Edge prev = first;
deba@2480	1097
deba@2480	1098	Edge edge = flip_map[node] ?
deba@2480	1099	edge_lists[prev].prev : edge_lists[prev].next;
deba@2480	1100
deba@2480	1101	_embedding[prev] = edge;
deba@2480	1102
deba@2480	1103	while (edge != first) {
deba@2480	1104	Edge next = edge_lists[edge].prev == prev ?
deba@2480	1105	edge_lists[edge].next : edge_lists[edge].prev;
deba@2480	1106	prev = edge; edge = next;
deba@2480	1107	_embedding[prev] = edge;
deba@2480	1108	}
deba@2480	1109	}
deba@2480	1110
deba@2480	1111
deba@2480	1112	bool external(const Node& node, int rorder,
deba@2480	1113	ChildLists& child_lists, AncestorMap& ancestor_map,
deba@2480	1114	LowMap& low_map) {
deba@2480	1115	Node child = child_lists[node].first;
deba@2480	1116
deba@2480	1117	if (child != INVALID) {
deba@2480	1118	if (low_map[child] < rorder) return true;
deba@2480	1119	}
deba@2480	1120
deba@2480	1121	if (ancestor_map[node] < rorder) return true;
deba@2480	1122
deba@2480	1123	return false;
deba@2480	1124	}
deba@2480	1125
deba@2480	1126	bool pertinent(const Node& node, const EmbedEdge& embed_edge,
deba@2480	1127	const MergeRoots& merge_roots) {
deba@2480	1128	return !merge_roots[node].empty() \|\| embed_edge[node] != INVALID;
deba@2480	1129	}
deba@2480	1130
deba@2480	1131	int lowPoint(const Node& node, OrderMap& order_map, ChildLists& child_lists,
deba@2480	1132	AncestorMap& ancestor_map, LowMap& low_map) {
deba@2480	1133	int low_point;
deba@2480	1134
deba@2480	1135	Node child = child_lists[node].first;
deba@2480	1136
deba@2480	1137	if (child != INVALID) {
deba@2480	1138	low_point = low_map[child];
deba@2480	1139	} else {
deba@2480	1140	low_point = order_map[node];
deba@2480	1141	}
deba@2480	1142
deba@2480	1143	if (low_point > ancestor_map[node]) {
deba@2480	1144	low_point = ancestor_map[node];
deba@2480	1145	}
deba@2480	1146
deba@2480	1147	return low_point;
deba@2480	1148	}
deba@2480	1149
deba@2480	1150	int findComponentRoot(Node root, Node node, ChildLists& child_lists,
deba@2480	1151	OrderMap& order_map, OrderList& order_list) {
deba@2480	1152
deba@2480	1153	int order = order_map[root];
deba@2480	1154	int norder = order_map[node];
deba@2480	1155
deba@2480	1156	Node child = child_lists[root].first;
deba@2480	1157	while (child != INVALID) {
deba@2480	1158	int corder = order_map[child];
deba@2480	1159	if (corder > order && corder < norder) {
deba@2480	1160	order = corder;
deba@2480	1161	}
deba@2480	1162	child = child_lists[child].next;
deba@2480	1163	}
deba@2480	1164	return order + order_list.size();
deba@2480	1165	}
deba@2480	1166
deba@2480	1167	Node findPertinent(Node node, OrderMap& order_map, NodeData& node_data,
deba@2480	1168	EmbedEdge& embed_edge, MergeRoots& merge_roots) {
deba@2480	1169	Node wnode =_ugraph.target(node_data[order_map[node]].first);
deba@2480	1170	while (!pertinent(wnode, embed_edge, merge_roots)) {
deba@2480	1171	wnode = _ugraph.target(node_data[order_map[wnode]].first);
deba@2480	1172	}
deba@2480	1173	return wnode;
deba@2480	1174	}
deba@2480	1175
deba@2480	1176
deba@2480	1177	Node findExternal(Node node, int rorder, OrderMap& order_map,
deba@2480	1178	ChildLists& child_lists, AncestorMap& ancestor_map,
deba@2480	1179	LowMap& low_map, NodeData& node_data) {
deba@2480	1180	Node wnode =_ugraph.target(node_data[order_map[node]].first);
deba@2480	1181	while (!external(wnode, rorder, child_lists, ancestor_map, low_map)) {
deba@2480	1182	wnode = _ugraph.target(node_data[order_map[wnode]].first);
deba@2480	1183	}
deba@2480	1184	return wnode;
deba@2480	1185	}
deba@2480	1186
deba@2480	1187	void markCommonPath(Node node, int rorder, Node& wnode, Node& znode,
deba@2480	1188	OrderList& order_list, OrderMap& order_map,
deba@2480	1189	NodeData& node_data, EdgeLists& edge_lists,
deba@2480	1190	EmbedEdge& embed_edge, MergeRoots& merge_roots,
deba@2480	1191	ChildLists& child_lists, AncestorMap& ancestor_map,
deba@2480	1192	LowMap& low_map) {
deba@2480	1193
deba@2480	1194	Node cnode = node;
deba@2480	1195	Node pred = INVALID;
deba@2480	1196
deba@2480	1197	while (true) {
deba@2480	1198
deba@2480	1199	bool pert = pertinent(cnode, embed_edge, merge_roots);
deba@2480	1200	bool ext = external(cnode, rorder, child_lists, ancestor_map, low_map);
deba@2480	1201
deba@2480	1202	if (pert && ext) {
deba@2480	1203	if (!merge_roots[cnode].empty()) {
deba@2480	1204	int cn = merge_roots[cnode].back();
deba@2480	1205
deba@2480	1206	if (low_map[order_list[cn - order_list.size()]] < rorder) {
deba@2480	1207	Edge edge = node_data[cn].first;
deba@2480	1208	_kuratowski.set(edge, true);
deba@2480	1209
deba@2480	1210	pred = cnode;
deba@2480	1211	cnode = _ugraph.target(edge);
deba@2480	1212
deba@2480	1213	continue;
deba@2480	1214	}
deba@2480	1215	}
deba@2480	1216	wnode = znode = cnode;
deba@2480	1217	return;
deba@2480	1218
deba@2480	1219	} else if (pert) {
deba@2480	1220	wnode = cnode;
deba@2480	1221
deba@2480	1222	while (!external(cnode, rorder, child_lists, ancestor_map, low_map)) {
deba@2480	1223	Edge edge = node_data[order_map[cnode]].first;
deba@2480	1224
deba@2480	1225	if (_ugraph.target(edge) == pred) {
deba@2480	1226	edge = edge_lists[edge].next;
deba@2480	1227	}
deba@2480	1228	_kuratowski.set(edge, true);
deba@2480	1229
deba@2480	1230	Node next = _ugraph.target(edge);
deba@2480	1231	pred = cnode; cnode = next;
deba@2480	1232	}
deba@2480	1233
deba@2480	1234	znode = cnode;
deba@2480	1235	return;
deba@2480	1236
deba@2480	1237	} else if (ext) {
deba@2480	1238	znode = cnode;
deba@2480	1239
deba@2480	1240	while (!pertinent(cnode, embed_edge, merge_roots)) {
deba@2480	1241	Edge edge = node_data[order_map[cnode]].first;
deba@2480	1242
deba@2480	1243	if (_ugraph.target(edge) == pred) {
deba@2480	1244	edge = edge_lists[edge].next;
deba@2480	1245	}
deba@2480	1246	_kuratowski.set(edge, true);
deba@2480	1247
deba@2480	1248	Node next = _ugraph.target(edge);
deba@2480	1249	pred = cnode; cnode = next;
deba@2480	1250	}
deba@2480	1251
deba@2480	1252	wnode = cnode;
deba@2480	1253	return;
deba@2480	1254
deba@2480	1255	} else {
deba@2480	1256	Edge edge = node_data[order_map[cnode]].first;
deba@2480	1257
deba@2480	1258	if (_ugraph.target(edge) == pred) {
deba@2480	1259	edge = edge_lists[edge].next;
deba@2480	1260	}
deba@2480	1261	_kuratowski.set(edge, true);
deba@2480	1262
deba@2480	1263	Node next = _ugraph.target(edge);
deba@2480	1264	pred = cnode; cnode = next;
deba@2480	1265	}
deba@2480	1266
deba@2480	1267	}
deba@2480	1268
deba@2480	1269	}
deba@2480	1270
deba@2480	1271	void orientComponent(Node root, int rn, OrderMap& order_map,
deba@2480	1272	PredMap& pred_map, NodeData& node_data,
deba@2480	1273	EdgeLists& edge_lists, FlipMap& flip_map,
deba@2480	1274	TypeMap& type_map) {
deba@2480	1275	node_data[order_map[root]].first = node_data[rn].first;
deba@2480	1276	type_map[root] = 1;
deba@2480	1277
deba@2480	1278	std::vector<Node> st, qu;
deba@2480	1279
deba@2480	1280	st.push_back(root);
deba@2480	1281	while (!st.empty()) {
deba@2480	1282	Node node = st.back();
deba@2480	1283	st.pop_back();
deba@2480	1284	qu.push_back(node);
deba@2480	1285
deba@2480	1286	Edge edge = node_data[order_map[node]].first;
deba@2480	1287
deba@2480	1288	if (type_map[_ugraph.target(edge)] == 0) {
deba@2480	1289	st.push_back(_ugraph.target(edge));
deba@2480	1290	type_map[_ugraph.target(edge)] = 1;
deba@2480	1291	}
deba@2480	1292
deba@2480	1293	Edge last = edge, pred = edge;
deba@2480	1294	edge = edge_lists[edge].next;
deba@2480	1295	while (edge != last) {
deba@2480	1296
deba@2480	1297	if (type_map[_ugraph.target(edge)] == 0) {
deba@2480	1298	st.push_back(_ugraph.target(edge));
deba@2480	1299	type_map[_ugraph.target(edge)] = 1;
deba@2480	1300	}
deba@2480	1301
deba@2480	1302	Edge next = edge_lists[edge].next != pred ?
deba@2480	1303	edge_lists[edge].next : edge_lists[edge].prev;
deba@2480	1304	pred = edge; edge = next;
deba@2480	1305	}
deba@2480	1306
deba@2480	1307	}
deba@2480	1308
deba@2480	1309	type_map[root] = 2;
deba@2480	1310	flip_map[root] = false;
deba@2480	1311
deba@2480	1312	for (int i = 1; i < int(qu.size()); ++i) {
deba@2480	1313
deba@2480	1314	Node node = qu[i];
deba@2480	1315
deba@2480	1316	while (type_map[node] != 2) {
deba@2480	1317	st.push_back(node);
deba@2480	1318	type_map[node] = 2;
deba@2480	1319	node = _ugraph.source(pred_map[node]);
deba@2480	1320	}
deba@2480	1321
deba@2480	1322	bool flip = flip_map[node];
deba@2480	1323
deba@2480	1324	while (!st.empty()) {
deba@2480	1325	node = st.back();
deba@2480	1326	st.pop_back();
deba@2480	1327
deba@2480	1328	flip_map[node] = flip != flip_map[node];
deba@2480	1329	flip = flip_map[node];
deba@2480	1330
deba@2480	1331	if (flip) {
deba@2480	1332	Edge edge = node_data[order_map[node]].first;
deba@2480	1333	std::swap(edge_lists[edge].prev, edge_lists[edge].next);
deba@2480	1334	edge = edge_lists[edge].prev;
deba@2480	1335	std::swap(edge_lists[edge].prev, edge_lists[edge].next);
deba@2480	1336	node_data[order_map[node]].first = edge;
deba@2480	1337	}
deba@2480	1338	}
deba@2480	1339	}
deba@2480	1340
deba@2480	1341	for (int i = 0; i < int(qu.size()); ++i) {
deba@2480	1342
deba@2480	1343	Edge edge = node_data[order_map[qu[i]]].first;
deba@2480	1344	Edge last = edge, pred = edge;
deba@2480	1345
deba@2480	1346	edge = edge_lists[edge].next;
deba@2480	1347	while (edge != last) {
deba@2480	1348
deba@2480	1349	if (edge_lists[edge].next == pred) {
deba@2480	1350	std::swap(edge_lists[edge].next, edge_lists[edge].prev);
deba@2480	1351	}
deba@2480	1352	pred = edge; edge = edge_lists[edge].next;
deba@2480	1353	}
deba@2480	1354
deba@2480	1355	}
deba@2480	1356	}
deba@2480	1357
deba@2480	1358	void setFaceFlags(Node root, Node wnode, Node ynode, Node xnode,
deba@2480	1359	OrderMap& order_map, NodeData& node_data,
deba@2480	1360	TypeMap& type_map) {
deba@2480	1361	Node node = _ugraph.target(node_data[order_map[root]].first);
deba@2480	1362
deba@2480	1363	while (node != ynode) {
deba@2480	1364	type_map[node] = HIGHY;
deba@2480	1365	node = _ugraph.target(node_data[order_map[node]].first);
deba@2480	1366	}
deba@2480	1367
deba@2480	1368	while (node != wnode) {
deba@2480	1369	type_map[node] = LOWY;
deba@2480	1370	node = _ugraph.target(node_data[order_map[node]].first);
deba@2480	1371	}
deba@2480	1372
deba@2480	1373	node = _ugraph.target(node_data[order_map[wnode]].first);
deba@2480	1374
deba@2480	1375	while (node != xnode) {
deba@2480	1376	type_map[node] = LOWX;
deba@2480	1377	node = _ugraph.target(node_data[order_map[node]].first);
deba@2480	1378	}
deba@2480	1379	type_map[node] = LOWX;
deba@2480	1380
deba@2480	1381	node = _ugraph.target(node_data[order_map[xnode]].first);
deba@2480	1382	while (node != root) {
deba@2480	1383	type_map[node] = HIGHX;
deba@2480	1384	node = _ugraph.target(node_data[order_map[node]].first);
deba@2480	1385	}
deba@2480	1386
deba@2480	1387	type_map[wnode] = PERTINENT;
deba@2480	1388	type_map[root] = ROOT;
deba@2480	1389	}
deba@2480	1390
deba@2480	1391	void findInternalPath(std::vector<Edge>& ipath,
deba@2480	1392	Node wnode, Node root, TypeMap& type_map,
deba@2480	1393	OrderMap& order_map, NodeData& node_data,
deba@2480	1394	EdgeLists& edge_lists) {
deba@2480	1395	std::vector<Edge> st;
deba@2480	1396
deba@2480	1397	Node node = wnode;
deba@2480	1398
deba@2480	1399	while (node != root) {
deba@2480	1400	Edge edge = edge_lists[node_data[order_map[node]].first].next;
deba@2480	1401	st.push_back(edge);
deba@2480	1402	node = _ugraph.target(edge);
deba@2480	1403	}
deba@2480	1404
deba@2480	1405	while (true) {
deba@2480	1406	Edge edge = st.back();
deba@2480	1407	if (type_map[_ugraph.target(edge)] == LOWX \|\|
deba@2480	1408	type_map[_ugraph.target(edge)] == HIGHX) {
deba@2480	1409	break;
deba@2480	1410	}
deba@2480	1411	if (type_map[_ugraph.target(edge)] == 2) {
deba@2480	1412	type_map[_ugraph.target(edge)] = 3;
deba@2480	1413
deba@2480	1414	edge = edge_lists[_ugraph.oppositeEdge(edge)].next;
deba@2480	1415	st.push_back(edge);
deba@2480	1416	} else {
deba@2480	1417	st.pop_back();
deba@2480	1418	edge = edge_lists[edge].next;
deba@2480	1419
deba@2480	1420	while (_ugraph.oppositeEdge(edge) == st.back()) {
deba@2480	1421	edge = st.back();
deba@2480	1422	st.pop_back();
deba@2480	1423	edge = edge_lists[edge].next;
deba@2480	1424	}
deba@2480	1425	st.push_back(edge);
deba@2480	1426	}
deba@2480	1427	}
deba@2480	1428
deba@2480	1429	for (int i = 0; i < int(st.size()); ++i) {
deba@2480	1430	if (type_map[_ugraph.target(st[i])] != LOWY &&
deba@2480	1431	type_map[_ugraph.target(st[i])] != HIGHY) {
deba@2480	1432	for (; i < int(st.size()); ++i) {
deba@2480	1433	ipath.push_back(st[i]);
deba@2480	1434	}
deba@2480	1435	}
deba@2480	1436	}
deba@2480	1437	}
deba@2480	1438
deba@2480	1439	void setInternalFlags(std::vector<Edge>& ipath, TypeMap& type_map) {
deba@2480	1440	for (int i = 1; i < int(ipath.size()); ++i) {
deba@2480	1441	type_map[_ugraph.source(ipath[i])] = INTERNAL;
deba@2480	1442	}
deba@2480	1443	}
deba@2480	1444
deba@2480	1445	void findPilePath(std::vector<Edge>& ppath,
deba@2480	1446	Node root, TypeMap& type_map, OrderMap& order_map,
deba@2480	1447	NodeData& node_data, EdgeLists& edge_lists) {
deba@2480	1448	std::vector<Edge> st;
deba@2480	1449
deba@2480	1450	st.push_back(_ugraph.oppositeEdge(node_data[order_map[root]].first));
deba@2480	1451	st.push_back(node_data[order_map[root]].first);
deba@2480	1452
deba@2480	1453	while (st.size() > 1) {
deba@2480	1454	Edge edge = st.back();
deba@2480	1455	if (type_map[_ugraph.target(edge)] == INTERNAL) {
deba@2480	1456	break;
deba@2480	1457	}
deba@2480	1458	if (type_map[_ugraph.target(edge)] == 3) {
deba@2480	1459	type_map[_ugraph.target(edge)] = 4;
deba@2480	1460
deba@2480	1461	edge = edge_lists[_ugraph.oppositeEdge(edge)].next;
deba@2480	1462	st.push_back(edge);
deba@2480	1463	} else {
deba@2480	1464	st.pop_back();
deba@2480	1465	edge = edge_lists[edge].next;
deba@2480	1466
deba@2480	1467	while (!st.empty() && _ugraph.oppositeEdge(edge) == st.back()) {
deba@2480	1468	edge = st.back();
deba@2480	1469	st.pop_back();
deba@2480	1470	edge = edge_lists[edge].next;
deba@2480	1471	}
deba@2480	1472	st.push_back(edge);
deba@2480	1473	}
deba@2480	1474	}
deba@2480	1475
deba@2480	1476	for (int i = 1; i < int(st.size()); ++i) {
deba@2480	1477	ppath.push_back(st[i]);
deba@2480	1478	}
deba@2480	1479	}
deba@2480	1480
deba@2480	1481
deba@2480	1482	int markExternalPath(Node node, OrderMap& order_map,
deba@2480	1483	ChildLists& child_lists, PredMap& pred_map,
deba@2480	1484	AncestorMap& ancestor_map, LowMap& low_map) {
deba@2480	1485	int lp = lowPoint(node, order_map, child_lists,
deba@2480	1486	ancestor_map, low_map);
deba@2480	1487
deba@2480	1488	if (ancestor_map[node] != lp) {
deba@2480	1489	node = child_lists[node].first;
deba@2480	1490	_kuratowski[pred_map[node]] = true;
deba@2480	1491
deba@2480	1492	while (ancestor_map[node] != lp) {
deba@2480	1493	for (OutEdgeIt e(_ugraph, node); e != INVALID; ++e) {
deba@2480	1494	Node tnode = _ugraph.target(e);
deba@2480	1495	if (order_map[tnode] > order_map[node] && low_map[tnode] == lp) {
deba@2480	1496	node = tnode;
deba@2480	1497	_kuratowski[e] = true;
deba@2480	1498	break;
deba@2480	1499	}
deba@2480	1500	}
deba@2480	1501	}
deba@2480	1502	}
deba@2480	1503
deba@2480	1504	for (OutEdgeIt e(_ugraph, node); e != INVALID; ++e) {
deba@2480	1505	if (order_map[_ugraph.target(e)] == lp) {
deba@2480	1506	_kuratowski[e] = true;
deba@2480	1507	break;
deba@2480	1508	}
deba@2480	1509	}
deba@2480	1510
deba@2480	1511	return lp;
deba@2480	1512	}
deba@2480	1513
deba@2480	1514	void markPertinentPath(Node node, OrderMap& order_map,
deba@2480	1515	NodeData& node_data, EdgeLists& edge_lists,
deba@2480	1516	EmbedEdge& embed_edge, MergeRoots& merge_roots) {
deba@2480	1517	while (embed_edge[node] == INVALID) {
deba@2480	1518	int n = merge_roots[node].front();
deba@2480	1519	Edge edge = node_data[n].first;
deba@2480	1520
deba@2480	1521	_kuratowski.set(edge, true);
deba@2480	1522
deba@2480	1523	Node pred = node;
deba@2480	1524	node = _ugraph.target(edge);
deba@2480	1525	while (!pertinent(node, embed_edge, merge_roots)) {
deba@2480	1526	edge = node_data[order_map[node]].first;
deba@2480	1527	if (_ugraph.target(edge) == pred) {
deba@2480	1528	edge = edge_lists[edge].next;
deba@2480	1529	}
deba@2480	1530	_kuratowski.set(edge, true);
deba@2480	1531	pred = node;
deba@2480	1532	node = _ugraph.target(edge);
deba@2480	1533	}
deba@2480	1534	}
deba@2480	1535	_kuratowski.set(embed_edge[node], true);
deba@2480	1536	}
deba@2480	1537
deba@2480	1538	void markPredPath(Node node, Node snode, PredMap& pred_map) {
deba@2480	1539	while (node != snode) {
deba@2480	1540	_kuratowski.set(pred_map[node], true);
deba@2480	1541	node = _ugraph.source(pred_map[node]);
deba@2480	1542	}
deba@2480	1543	}
deba@2480	1544
deba@2480	1545	void markFacePath(Node ynode, Node xnode,
deba@2480	1546	OrderMap& order_map, NodeData& node_data) {
deba@2480	1547	Edge edge = node_data[order_map[ynode]].first;
deba@2480	1548	Node node = _ugraph.target(edge);
deba@2480	1549	_kuratowski.set(edge, true);
deba@2480	1550
deba@2480	1551	while (node != xnode) {
deba@2480	1552	edge = node_data[order_map[node]].first;
deba@2480	1553	_kuratowski.set(edge, true);
deba@2480	1554	node = _ugraph.target(edge);
deba@2480	1555	}
deba@2480	1556	}
deba@2480	1557
deba@2480	1558	void markInternalPath(std::vector<Edge>& path) {
deba@2480	1559	for (int i = 0; i < int(path.size()); ++i) {
deba@2480	1560	_kuratowski.set(path[i], true);
deba@2480	1561	}
deba@2480	1562	}
deba@2480	1563
deba@2480	1564	void markPilePath(std::vector<Edge>& path) {
deba@2480	1565	for (int i = 0; i < int(path.size()); ++i) {
deba@2480	1566	_kuratowski.set(path[i], true);
deba@2480	1567	}
deba@2480	1568	}
deba@2480	1569
deba@2480	1570	void isolateKuratowski(Edge edge, NodeData& node_data,
deba@2480	1571	EdgeLists& edge_lists, FlipMap& flip_map,
deba@2480	1572	OrderMap& order_map, OrderList& order_list,
deba@2480	1573	PredMap& pred_map, ChildLists& child_lists,
deba@2480	1574	AncestorMap& ancestor_map, LowMap& low_map,
deba@2480	1575	EmbedEdge& embed_edge, MergeRoots& merge_roots) {
deba@2480	1576
deba@2480	1577	Node root = _ugraph.source(edge);
deba@2480	1578	Node enode = _ugraph.target(edge);
deba@2480	1579
deba@2480	1580	int rorder = order_map[root];
deba@2480	1581
deba@2480	1582	TypeMap type_map(_ugraph, 0);
deba@2480	1583
deba@2480	1584	int rn = findComponentRoot(root, enode, child_lists,
deba@2480	1585	order_map, order_list);
deba@2480	1586
deba@2480	1587	Node xnode = order_list[node_data[rn].next];
deba@2480	1588	Node ynode = order_list[node_data[rn].prev];
deba@2480	1589
deba@2480	1590	// Minor-A
deba@2480	1591	{
deba@2480	1592	while (!merge_roots[xnode].empty() \|\| !merge_roots[ynode].empty()) {
deba@2480	1593
deba@2480	1594	if (!merge_roots[xnode].empty()) {
deba@2480	1595	root = xnode;
deba@2480	1596	rn = merge_roots[xnode].front();
deba@2480	1597	} else {
deba@2480	1598	root = ynode;
deba@2480	1599	rn = merge_roots[ynode].front();
deba@2480	1600	}
deba@2480	1601
deba@2480	1602	xnode = order_list[node_data[rn].next];
deba@2480	1603	ynode = order_list[node_data[rn].prev];
deba@2480	1604	}
deba@2480	1605
deba@2480	1606	if (root != _ugraph.source(edge)) {
deba@2480	1607	orientComponent(root, rn, order_map, pred_map,
deba@2480	1608	node_data, edge_lists, flip_map, type_map);
deba@2480	1609	markFacePath(root, root, order_map, node_data);
deba@2480	1610	int xlp = markExternalPath(xnode, order_map, child_lists,
deba@2480	1611	pred_map, ancestor_map, low_map);
deba@2480	1612	int ylp = markExternalPath(ynode, order_map, child_lists,
deba@2480	1613	pred_map, ancestor_map, low_map);
deba@2480	1614	markPredPath(root, order_list[xlp < ylp ? xlp : ylp], pred_map);
deba@2480	1615	Node lwnode = findPertinent(ynode, order_map, node_data,
deba@2480	1616	embed_edge, merge_roots);
deba@2480	1617
deba@2480	1618	markPertinentPath(lwnode, order_map, node_data, edge_lists,
deba@2480	1619	embed_edge, merge_roots);
deba@2480	1620
deba@2480	1621	return;
deba@2480	1622	}
deba@2480	1623	}
deba@2480	1624
deba@2480	1625	orientComponent(root, rn, order_map, pred_map,
deba@2480	1626	node_data, edge_lists, flip_map, type_map);
deba@2480	1627
deba@2480	1628	Node wnode = findPertinent(ynode, order_map, node_data,
deba@2480	1629	embed_edge, merge_roots);
deba@2480	1630	setFaceFlags(root, wnode, ynode, xnode, order_map, node_data, type_map);
deba@2480	1631
deba@2480	1632
deba@2480	1633	//Minor-B
deba@2480	1634	if (!merge_roots[wnode].empty()) {
deba@2480	1635	int cn = merge_roots[wnode].back();
deba@2480	1636	Node rep = order_list[cn - order_list.size()];
deba@2480	1637	if (low_map[rep] < rorder) {
deba@2480	1638	markFacePath(root, root, order_map, node_data);
deba@2480	1639	int xlp = markExternalPath(xnode, order_map, child_lists,
deba@2480	1640	pred_map, ancestor_map, low_map);
deba@2480	1641	int ylp = markExternalPath(ynode, order_map, child_lists,
deba@2480	1642	pred_map, ancestor_map, low_map);
deba@2480	1643
deba@2480	1644	Node lwnode, lznode;
deba@2480	1645	markCommonPath(wnode, rorder, lwnode, lznode, order_list,
deba@2480	1646	order_map, node_data, edge_lists, embed_edge,
deba@2480	1647	merge_roots, child_lists, ancestor_map, low_map);
deba@2480	1648
deba@2480	1649	markPertinentPath(lwnode, order_map, node_data, edge_lists,
deba@2480	1650	embed_edge, merge_roots);
deba@2480	1651	int zlp = markExternalPath(lznode, order_map, child_lists,
deba@2480	1652	pred_map, ancestor_map, low_map);
deba@2480	1653
deba@2480	1654	int minlp = xlp < ylp ? xlp : ylp;
deba@2480	1655	if (zlp < minlp) minlp = zlp;
deba@2480	1656
deba@2480	1657	int maxlp = xlp > ylp ? xlp : ylp;
deba@2480	1658	if (zlp > maxlp) maxlp = zlp;
deba@2480	1659
deba@2480	1660	markPredPath(order_list[maxlp], order_list[minlp], pred_map);
deba@2480	1661
deba@2480	1662	return;
deba@2480	1663	}
deba@2480	1664	}
deba@2480	1665
deba@2480	1666	Node pxnode, pynode;
deba@2480	1667	std::vector<Edge> ipath;
deba@2480	1668	findInternalPath(ipath, wnode, root, type_map, order_map,
deba@2480	1669	node_data, edge_lists);
deba@2480	1670	setInternalFlags(ipath, type_map);
deba@2480	1671	pynode = _ugraph.source(ipath.front());
deba@2480	1672	pxnode = _ugraph.target(ipath.back());
deba@2480	1673
deba@2480	1674	wnode = findPertinent(pynode, order_map, node_data,
deba@2480	1675	embed_edge, merge_roots);
deba@2480	1676
deba@2480	1677	// Minor-C
deba@2480	1678	{
deba@2480	1679	if (type_map[_ugraph.source(ipath.front())] == HIGHY) {
deba@2480	1680	if (type_map[_ugraph.target(ipath.back())] == HIGHX) {
deba@2480	1681	markFacePath(xnode, pxnode, order_map, node_data);
deba@2480	1682	}
deba@2480	1683	markFacePath(root, xnode, order_map, node_data);
deba@2480	1684	markPertinentPath(wnode, order_map, node_data, edge_lists,
deba@2480	1685	embed_edge, merge_roots);
deba@2480	1686	markInternalPath(ipath);
deba@2480	1687	int xlp = markExternalPath(xnode, order_map, child_lists,
deba@2480	1688	pred_map, ancestor_map, low_map);
deba@2480	1689	int ylp = markExternalPath(ynode, order_map, child_lists,
deba@2480	1690	pred_map, ancestor_map, low_map);
deba@2480	1691	markPredPath(root, order_list[xlp < ylp ? xlp : ylp], pred_map);
deba@2480	1692	return;
deba@2480	1693	}
deba@2480	1694
deba@2480	1695	if (type_map[_ugraph.target(ipath.back())] == HIGHX) {
deba@2480	1696	markFacePath(ynode, root, order_map, node_data);
deba@2480	1697	markPertinentPath(wnode, order_map, node_data, edge_lists,
deba@2480	1698	embed_edge, merge_roots);
deba@2480	1699	markInternalPath(ipath);
deba@2480	1700	int xlp = markExternalPath(xnode, order_map, child_lists,
deba@2480	1701	pred_map, ancestor_map, low_map);
deba@2480	1702	int ylp = markExternalPath(ynode, order_map, child_lists,
deba@2480	1703	pred_map, ancestor_map, low_map);
deba@2480	1704	markPredPath(root, order_list[xlp < ylp ? xlp : ylp], pred_map);
deba@2480	1705	return;
deba@2480	1706	}
deba@2480	1707	}
deba@2480	1708
deba@2480	1709	std::vector<Edge> ppath;
deba@2480	1710	findPilePath(ppath, root, type_map, order_map, node_data, edge_lists);
deba@2480	1711
deba@2480	1712	// Minor-D
deba@2480	1713	if (!ppath.empty()) {
deba@2480	1714	markFacePath(ynode, xnode, order_map, node_data);
deba@2480	1715	markPertinentPath(wnode, order_map, node_data, edge_lists,
deba@2480	1716	embed_edge, merge_roots);
deba@2480	1717	markPilePath(ppath);
deba@2480	1718	markInternalPath(ipath);
deba@2480	1719	int xlp = markExternalPath(xnode, order_map, child_lists,
deba@2480	1720	pred_map, ancestor_map, low_map);
deba@2480	1721	int ylp = markExternalPath(ynode, order_map, child_lists,
deba@2480	1722	pred_map, ancestor_map, low_map);
deba@2480	1723	markPredPath(root, order_list[xlp < ylp ? xlp : ylp], pred_map);
deba@2480	1724	return;
deba@2480	1725	}
deba@2480	1726
deba@2480	1727	// Minor-E*
deba@2480	1728	{
deba@2480	1729
deba@2480	1730	if (!external(wnode, rorder, child_lists, ancestor_map, low_map)) {
deba@2480	1731	Node znode = findExternal(pynode, rorder, order_map,
deba@2480	1732	child_lists, ancestor_map,
deba@2480	1733	low_map, node_data);
deba@2480	1734
deba@2480	1735	if (type_map[znode] == LOWY) {
deba@2480	1736	markFacePath(root, xnode, order_map, node_data);
deba@2480	1737	markPertinentPath(wnode, order_map, node_data, edge_lists,
deba@2480	1738	embed_edge, merge_roots);
deba@2480	1739	markInternalPath(ipath);
deba@2480	1740	int xlp = markExternalPath(xnode, order_map, child_lists,
deba@2480	1741	pred_map, ancestor_map, low_map);
deba@2480	1742	int zlp = markExternalPath(znode, order_map, child_lists,
deba@2480	1743	pred_map, ancestor_map, low_map);
deba@2480	1744	markPredPath(root, order_list[xlp < zlp ? xlp : zlp], pred_map);
deba@2480	1745	} else {
deba@2480	1746	markFacePath(ynode, root, order_map, node_data);
deba@2480	1747	markPertinentPath(wnode, order_map, node_data, edge_lists,
deba@2480	1748	embed_edge, merge_roots);
deba@2480	1749	markInternalPath(ipath);
deba@2480	1750	int ylp = markExternalPath(ynode, order_map, child_lists,
deba@2480	1751	pred_map, ancestor_map, low_map);
deba@2480	1752	int zlp = markExternalPath(znode, order_map, child_lists,
deba@2480	1753	pred_map, ancestor_map, low_map);
deba@2480	1754	markPredPath(root, order_list[ylp < zlp ? ylp : zlp], pred_map);
deba@2480	1755	}
deba@2480	1756	return;
deba@2480	1757	}
deba@2480	1758
deba@2480	1759	int xlp = markExternalPath(xnode, order_map, child_lists,
deba@2480	1760	pred_map, ancestor_map, low_map);
deba@2480	1761	int ylp = markExternalPath(ynode, order_map, child_lists,
deba@2480	1762	pred_map, ancestor_map, low_map);
deba@2480	1763	int wlp = markExternalPath(wnode, order_map, child_lists,
deba@2480	1764	pred_map, ancestor_map, low_map);
deba@2480	1765
deba@2480	1766	if (wlp > xlp && wlp > ylp) {
deba@2480	1767	markFacePath(root, root, order_map, node_data);
deba@2480	1768	markPredPath(root, order_list[xlp < ylp ? xlp : ylp], pred_map);
deba@2480	1769	return;
deba@2480	1770	}
deba@2480	1771
deba@2480	1772	markInternalPath(ipath);
deba@2480	1773	markPertinentPath(wnode, order_map, node_data, edge_lists,
deba@2480	1774	embed_edge, merge_roots);
deba@2480	1775
deba@2480	1776	if (xlp > ylp && xlp > wlp) {
deba@2480	1777	markFacePath(root, pynode, order_map, node_data);
deba@2480	1778	markFacePath(wnode, xnode, order_map, node_data);
deba@2480	1779	markPredPath(root, order_list[ylp < wlp ? ylp : wlp], pred_map);
deba@2480	1780	return;
deba@2480	1781	}
deba@2480	1782
deba@2480	1783	if (ylp > xlp && ylp > wlp) {
deba@2480	1784	markFacePath(pxnode, root, order_map, node_data);
deba@2480	1785	markFacePath(ynode, wnode, order_map, node_data);
deba@2480	1786	markPredPath(root, order_list[xlp < wlp ? xlp : wlp], pred_map);
deba@2480	1787	return;
deba@2480	1788	}
deba@2480	1789
deba@2480	1790	if (pynode != ynode) {
deba@2480	1791	markFacePath(pxnode, wnode, order_map, node_data);
deba@2480	1792
deba@2480	1793	int minlp = xlp < ylp ? xlp : ylp;
deba@2480	1794	if (wlp < minlp) minlp = wlp;
deba@2480	1795
deba@2480	1796	int maxlp = xlp > ylp ? xlp : ylp;
deba@2480	1797	if (wlp > maxlp) maxlp = wlp;
deba@2480	1798
deba@2480	1799	markPredPath(order_list[maxlp], order_list[minlp], pred_map);
deba@2480	1800	return;
deba@2480	1801	}
deba@2480	1802
deba@2480	1803	if (pxnode != xnode) {
deba@2480	1804	markFacePath(wnode, pynode, order_map, node_data);
deba@2480	1805
deba@2480	1806	int minlp = xlp < ylp ? xlp : ylp;
deba@2480	1807	if (wlp < minlp) minlp = wlp;
deba@2480	1808
deba@2480	1809	int maxlp = xlp > ylp ? xlp : ylp;
deba@2480	1810	if (wlp > maxlp) maxlp = wlp;
deba@2480	1811
deba@2480	1812	markPredPath(order_list[maxlp], order_list[minlp], pred_map);
deba@2480	1813	return;
deba@2480	1814	}
deba@2480	1815
deba@2480	1816	markFacePath(root, root, order_map, node_data);
deba@2480	1817	int minlp = xlp < ylp ? xlp : ylp;
deba@2480	1818	if (wlp < minlp) minlp = wlp;
deba@2480	1819	markPredPath(root, order_list[minlp], pred_map);
deba@2480	1820	return;
deba@2480	1821	}
deba@2480	1822
deba@2480	1823	}
deba@2480	1824
deba@2480	1825	};
deba@2480	1826
deba@2499	1827	namespace _planarity_bits {
deba@2499	1828
deba@2499	1829	template <typename UGraph, typename EmbeddingMap>
deba@2499	1830	void makeConnected(UGraph& ugraph, EmbeddingMap& embedding) {
deba@2499	1831	DfsVisitor<UGraph> null_visitor;
deba@2499	1832	DfsVisit<UGraph, DfsVisitor<UGraph> > dfs(ugraph, null_visitor);
deba@2499	1833	dfs.init();
deba@2499	1834
deba@2499	1835	typename UGraph::Node u = INVALID;
deba@2499	1836	for (typename UGraph::NodeIt n(ugraph); n != INVALID; ++n) {
deba@2499	1837	if (!dfs.reached(n)) {
deba@2499	1838	dfs.addSource(n);
deba@2499	1839	dfs.start();
deba@2499	1840	if (u == INVALID) {
deba@2499	1841	u = n;
deba@2499	1842	} else {
deba@2499	1843	typename UGraph::Node v = n;
deba@2499	1844
deba@2499	1845	typename UGraph::Edge ue = typename UGraph::OutEdgeIt(ugraph, u);
deba@2499	1846	typename UGraph::Edge ve = typename UGraph::OutEdgeIt(ugraph, v);
deba@2499	1847
deba@2499	1848	typename UGraph::Edge e = ugraph.direct(ugraph.addEdge(u, v), true);
deba@2499	1849
deba@2499	1850	if (ue != INVALID) {
deba@2499	1851	embedding[e] = embedding[ue];
deba@2499	1852	embedding[ue] = e;
deba@2499	1853	} else {
deba@2499	1854	embedding[e] = e;
deba@2499	1855	}
deba@2499	1856
deba@2499	1857	if (ve != INVALID) {
deba@2499	1858	embedding[ugraph.oppositeEdge(e)] = embedding[ve];
deba@2499	1859	embedding[ve] = ugraph.oppositeEdge(e);
deba@2499	1860	} else {
deba@2499	1861	embedding[ugraph.oppositeEdge(e)] = ugraph.oppositeEdge(e);
deba@2499	1862	}
deba@2499	1863	}
deba@2499	1864	}
deba@2499	1865	}
deba@2499	1866	}
deba@2499	1867
deba@2499	1868	template <typename UGraph, typename EmbeddingMap>
deba@2499	1869	void makeBiNodeConnected(UGraph& ugraph, EmbeddingMap& embedding) {
deba@2499	1870	typename UGraph::template EdgeMap<bool> processed(ugraph);
deba@2499	1871
deba@2499	1872	std::vector<typename UGraph::Edge> edges;
deba@2499	1873	for (typename UGraph::EdgeIt e(ugraph); e != INVALID; ++e) {
deba@2499	1874	edges.push_back(e);
deba@2499	1875	}
deba@2499	1876
deba@2499	1877	IterableBoolMap<UGraph, typename UGraph::Node> visited(ugraph, false);
deba@2499	1878
deba@2499	1879	for (int i = 0; i < int(edges.size()); ++i) {
deba@2499	1880	typename UGraph::Edge pp = edges[i];
deba@2499	1881	if (processed[pp]) continue;
deba@2499	1882
deba@2499	1883	typename UGraph::Edge e = embedding[ugraph.oppositeEdge(pp)];
deba@2499	1884	processed[e] = true;
deba@2499	1885	visited.set(ugraph.source(e), true);
deba@2499	1886
deba@2499	1887	typename UGraph::Edge p = e, l = e;
deba@2499	1888	e = embedding[ugraph.oppositeEdge(e)];
deba@2499	1889
deba@2499	1890	while (e != l) {
deba@2499	1891	processed[e] = true;
deba@2499	1892
deba@2499	1893	if (visited[ugraph.source(e)]) {
deba@2499	1894
deba@2499	1895	typename UGraph::Edge n =
deba@2499	1896	ugraph.direct(ugraph.addEdge(ugraph.source(p),
deba@2499	1897	ugraph.target(e)), true);
deba@2499	1898	embedding[n] = p;
deba@2499	1899	embedding[ugraph.oppositeEdge(pp)] = n;
deba@2499	1900
deba@2499	1901	embedding[ugraph.oppositeEdge(n)] =
deba@2499	1902	embedding[ugraph.oppositeEdge(e)];
deba@2499	1903	embedding[ugraph.oppositeEdge(e)] =
deba@2499	1904	ugraph.oppositeEdge(n);
deba@2499	1905
deba@2499	1906	p = n;
deba@2499	1907	e = embedding[ugraph.oppositeEdge(n)];
deba@2499	1908	} else {
deba@2499	1909	visited.set(ugraph.source(e), true);
deba@2499	1910	pp = p;
deba@2499	1911	p = e;
deba@2499	1912	e = embedding[ugraph.oppositeEdge(e)];
deba@2499	1913	}
deba@2499	1914	}
deba@2499	1915	visited.setAll(false);
deba@2499	1916	}
deba@2499	1917	}
deba@2499	1918
deba@2499	1919
deba@2499	1920	template <typename UGraph, typename EmbeddingMap>
deba@2499	1921	void makeMaxPlanar(UGraph& ugraph, EmbeddingMap& embedding) {
deba@2499	1922
deba@2499	1923	typename UGraph::template NodeMap<int> degree(ugraph);
deba@2499	1924
deba@2499	1925	for (typename UGraph::NodeIt n(ugraph); n != INVALID; ++n) {
deba@2499	1926	degree[n] = countIncEdges(ugraph, n);
deba@2499	1927	}
deba@2499	1928
deba@2499	1929	typename UGraph::template EdgeMap<bool> processed(ugraph);
deba@2499	1930	IterableBoolMap<UGraph, typename UGraph::Node> visited(ugraph, false);
deba@2499	1931
deba@2499	1932	std::vector<typename UGraph::Edge> edges;
deba@2499	1933	for (typename UGraph::EdgeIt e(ugraph); e != INVALID; ++e) {
deba@2499	1934	edges.push_back(e);
deba@2499	1935	}
deba@2499	1936
deba@2499	1937	for (int i = 0; i < int(edges.size()); ++i) {
deba@2499	1938	typename UGraph::Edge e = edges[i];
deba@2499	1939
deba@2499	1940	if (processed[e]) continue;
deba@2499	1941	processed[e] = true;
deba@2499	1942
deba@2499	1943	typename UGraph::Edge mine = e;
deba@2499	1944	int mind = degree[ugraph.source(e)];
deba@2499	1945
deba@2499	1946	int face_size = 1;
deba@2499	1947
deba@2499	1948	typename UGraph::Edge l = e;
deba@2499	1949	e = embedding[ugraph.oppositeEdge(e)];
deba@2499	1950	while (l != e) {
deba@2499	1951	processed[e] = true;
deba@2499	1952
deba@2499	1953	++face_size;
deba@2499	1954
deba@2499	1955	if (degree[ugraph.source(e)] < mind) {
deba@2499	1956	mine = e;
deba@2499	1957	mind = degree[ugraph.source(e)];
deba@2499	1958	}
deba@2499	1959
deba@2499	1960	e = embedding[ugraph.oppositeEdge(e)];
deba@2499	1961	}
deba@2499	1962
deba@2499	1963	if (face_size < 4) {
deba@2499	1964	continue;
deba@2499	1965	}
deba@2499	1966
deba@2499	1967	typename UGraph::Node s = ugraph.source(mine);
deba@2499	1968	for (typename UGraph::OutEdgeIt e(ugraph, s); e != INVALID; ++e) {
deba@2499	1969	visited.set(ugraph.target(e), true);
deba@2499	1970	}
deba@2499	1971
deba@2499	1972	typename UGraph::Edge oppe = INVALID;
deba@2499	1973
deba@2499	1974	e = embedding[ugraph.oppositeEdge(mine)];
deba@2499	1975	e = embedding[ugraph.oppositeEdge(e)];
deba@2499	1976	while (ugraph.target(e) != s) {
deba@2499	1977	if (visited[ugraph.source(e)]) {
deba@2499	1978	oppe = e;
deba@2499	1979	break;
deba@2499	1980	}
deba@2499	1981	e = embedding[ugraph.oppositeEdge(e)];
deba@2499	1982	}
deba@2499	1983	visited.setAll(false);
deba@2499	1984
deba@2499	1985	if (oppe == INVALID) {
deba@2499	1986
deba@2499	1987	e = embedding[ugraph.oppositeEdge(mine)];
deba@2499	1988	typename UGraph::Edge pn = mine, p = e;
deba@2499	1989
deba@2499	1990	e = embedding[ugraph.oppositeEdge(e)];
deba@2499	1991	while (ugraph.target(e) != s) {
deba@2499	1992	typename UGraph::Edge n =
deba@2499	1993	ugraph.direct(ugraph.addEdge(s, ugraph.source(e)), true);
deba@2499	1994
deba@2499	1995	embedding[n] = pn;
deba@2499	1996	embedding[ugraph.oppositeEdge(n)] = e;
deba@2499	1997	embedding[ugraph.oppositeEdge(p)] = ugraph.oppositeEdge(n);
deba@2499	1998
deba@2499	1999	pn = n;
deba@2499	2000
deba@2499	2001	p = e;
deba@2499	2002	e = embedding[ugraph.oppositeEdge(e)];
deba@2499	2003	}
deba@2499	2004
deba@2499	2005	embedding[ugraph.oppositeEdge(e)] = pn;
deba@2499	2006
deba@2499	2007	} else {
deba@2499	2008
deba@2499	2009	mine = embedding[ugraph.oppositeEdge(mine)];
deba@2499	2010	s = ugraph.source(mine);
deba@2499	2011	oppe = embedding[ugraph.oppositeEdge(oppe)];
deba@2499	2012	typename UGraph::Node t = ugraph.source(oppe);
deba@2499	2013
deba@2499	2014	typename UGraph::Edge ce = ugraph.direct(ugraph.addEdge(s, t), true);
deba@2499	2015	embedding[ce] = mine;
deba@2499	2016	embedding[ugraph.oppositeEdge(ce)] = oppe;
deba@2499	2017
deba@2499	2018	typename UGraph::Edge pn = ce, p = oppe;
deba@2499	2019	e = embedding[ugraph.oppositeEdge(oppe)];
deba@2499	2020	while (ugraph.target(e) != s) {
deba@2499	2021	typename UGraph::Edge n =
deba@2499	2022	ugraph.direct(ugraph.addEdge(s, ugraph.source(e)), true);
deba@2499	2023
deba@2499	2024	embedding[n] = pn;
deba@2499	2025	embedding[ugraph.oppositeEdge(n)] = e;
deba@2499	2026	embedding[ugraph.oppositeEdge(p)] = ugraph.oppositeEdge(n);
deba@2499	2027
deba@2499	2028	pn = n;
deba@2499	2029
deba@2499	2030	p = e;
deba@2499	2031	e = embedding[ugraph.oppositeEdge(e)];
deba@2499	2032
deba@2499	2033	}
deba@2499	2034	embedding[ugraph.oppositeEdge(e)] = pn;
deba@2499	2035
deba@2499	2036	pn = ugraph.oppositeEdge(ce), p = mine;
deba@2499	2037	e = embedding[ugraph.oppositeEdge(mine)];
deba@2499	2038	while (ugraph.target(e) != t) {
deba@2499	2039	typename UGraph::Edge n =
deba@2499	2040	ugraph.direct(ugraph.addEdge(t, ugraph.source(e)), true);
deba@2499	2041
deba@2499	2042	embedding[n] = pn;
deba@2499	2043	embedding[ugraph.oppositeEdge(n)] = e;
deba@2499	2044	embedding[ugraph.oppositeEdge(p)] = ugraph.oppositeEdge(n);
deba@2499	2045
deba@2499	2046	pn = n;
deba@2499	2047
deba@2499	2048	p = e;
deba@2499	2049	e = embedding[ugraph.oppositeEdge(e)];
deba@2499	2050
deba@2499	2051	}
deba@2499	2052	embedding[ugraph.oppositeEdge(e)] = pn;
deba@2499	2053	}
deba@2499	2054	}
deba@2499	2055	}
deba@2499	2056
deba@2499	2057	}
deba@2499	2058
deba@2500	2059	/// \ingroup planar
deba@2500	2060	///
deba@2499	2061	/// \brief Schnyder's planar drawing algorithms
deba@2499	2062	///
deba@2499	2063	/// The planar drawing algorithm calculates location for each node
deba@2499	2064	/// in the plane, which coordinates satisfies that if each edge is
deba@2499	2065	/// represented with a straight line then the edges will not
deba@2499	2066	/// intersect each other.
deba@2499	2067	///
deba@2499	2068	/// Scnyder's algorithm embeds the graph on \c (n-2,n-2) size grid,
deba@2499	2069	/// ie. each node will be located in the \c [0,n-2]x[0,n-2] square.
deba@2499	2070	/// The time complexity of the algorithm is O(n).
deba@2499	2071	template <typename UGraph>
deba@2499	2072	class PlanarDrawing {
deba@2499	2073	public:
deba@2499	2074
deba@2499	2075	UGRAPH_TYPEDEFS(typename UGraph);
deba@2499	2076
deba@2499	2077	/// \brief The point type for store coordinates
deba@2499	2078	typedef dim2::Point<int> Point;
deba@2499	2079	/// \brief The map type for store coordinates
deba@2499	2080	typedef typename UGraph::template NodeMap<Point> PointMap;
deba@2499	2081
deba@2499	2082
deba@2499	2083	/// \brief Constructor
deba@2499	2084	///
deba@2499	2085	/// Constructor
deba@2499	2086	/// \pre The ugraph should be simple, ie. loop and parallel edge free.
deba@2499	2087	PlanarDrawing(const UGraph& ugraph)
deba@2499	2088	: _ugraph(ugraph), _point_map(ugraph) {}
deba@2499	2089
deba@2499	2090	private:
deba@2499	2091
deba@2499	2092	template <typename AuxUGraph, typename AuxEmbeddingMap>
deba@2499	2093	void drawing(const AuxUGraph& ugraph,
deba@2499	2094	const AuxEmbeddingMap& next,
deba@2499	2095	PointMap& point_map) {
deba@2499	2096	UGRAPH_TYPEDEFS(typename AuxUGraph);
deba@2499	2097
deba@2499	2098	typename AuxUGraph::template EdgeMap<Edge> prev(ugraph);
deba@2499	2099
deba@2499	2100	for (NodeIt n(ugraph); n != INVALID; ++n) {
deba@2499	2101	Edge e = OutEdgeIt(ugraph, n);
deba@2499	2102
deba@2499	2103	Edge p = e, l = e;
deba@2499	2104
deba@2499	2105	e = next[e];
deba@2499	2106	while (e != l) {
deba@2499	2107	prev[e] = p;
deba@2499	2108	p = e;
deba@2499	2109	e = next[e];
deba@2499	2110	}
deba@2499	2111	prev[e] = p;
deba@2499	2112	}
deba@2499	2113
deba@2499	2114	Node anode, bnode, cnode;
deba@2499	2115
deba@2499	2116	{
deba@2499	2117	Edge e = EdgeIt(ugraph);
deba@2499	2118	anode = ugraph.source(e);
deba@2499	2119	bnode = ugraph.target(e);
deba@2499	2120	cnode = ugraph.target(next[ugraph.oppositeEdge(e)]);
deba@2499	2121	}
deba@2499	2122
deba@2499	2123	IterableBoolMap<AuxUGraph, Node> proper(ugraph, false);
deba@2499	2124	typename AuxUGraph::template NodeMap<int> conn(ugraph, -1);
deba@2499	2125
deba@2499	2126	conn[anode] = conn[bnode] = -2;
deba@2499	2127	{
deba@2499	2128	for (OutEdgeIt e(ugraph, anode); e != INVALID; ++e) {
deba@2499	2129	Node m = ugraph.target(e);
deba@2499	2130	if (conn[m] == -1) {
deba@2499	2131	conn[m] = 1;
deba@2499	2132	}
deba@2499	2133	}
deba@2499	2134	conn[cnode] = 2;
deba@2499	2135
deba@2499	2136	for (OutEdgeIt e(ugraph, bnode); e != INVALID; ++e) {
deba@2499	2137	Node m = ugraph.target(e);
deba@2499	2138	if (conn[m] == -1) {
deba@2499	2139	conn[m] = 1;
deba@2499	2140	} else if (conn[m] != -2) {
deba@2499	2141	conn[m] += 1;
deba@2499	2142	Edge pe = ugraph.oppositeEdge(e);
deba@2499	2143	if (conn[ugraph.target(next[pe])] == -2) {
deba@2499	2144	conn[m] -= 1;
deba@2499	2145	}
deba@2499	2146	if (conn[ugraph.target(prev[pe])] == -2) {
deba@2499	2147	conn[m] -= 1;
deba@2499	2148	}
deba@2499	2149
deba@2499	2150	proper.set(m, conn[m] == 1);
deba@2499	2151	}
deba@2499	2152	}
deba@2499	2153	}
deba@2499	2154
deba@2499	2155
deba@2499	2156	typename AuxUGraph::template EdgeMap<int> angle(ugraph, -1);
deba@2499	2157
deba@2499	2158	while (proper.trueNum() != 0) {
deba@2499	2159	Node n = typename IterableBoolMap<AuxUGraph, Node>::TrueIt(proper);
deba@2499	2160	proper.set(n, false);
deba@2499	2161	conn[n] = -2;
deba@2499	2162
deba@2499	2163	for (OutEdgeIt e(ugraph, n); e != INVALID; ++e) {
deba@2499	2164	Node m = ugraph.target(e);
deba@2499	2165	if (conn[m] == -1) {
deba@2499	2166	conn[m] = 1;
deba@2499	2167	} else if (conn[m] != -2) {
deba@2499	2168	conn[m] += 1;
deba@2499	2169	Edge pe = ugraph.oppositeEdge(e);
deba@2499	2170	if (conn[ugraph.target(next[pe])] == -2) {
deba@2499	2171	conn[m] -= 1;
deba@2499	2172	}
deba@2499	2173	if (conn[ugraph.target(prev[pe])] == -2) {
deba@2499	2174	conn[m] -= 1;
deba@2499	2175	}
deba@2499	2176
deba@2499	2177	proper.set(m, conn[m] == 1);
deba@2499	2178	}
deba@2499	2179	}
deba@2499	2180
deba@2499	2181	{
deba@2499	2182	Edge e = OutEdgeIt(ugraph, n);
deba@2499	2183	Edge p = e, l = e;
deba@2499	2184
deba@2499	2185	e = next[e];
deba@2499	2186	while (e != l) {
deba@2499	2187
deba@2499	2188	if (conn[ugraph.target(e)] == -2 && conn[ugraph.target(p)] == -2) {
deba@2499	2189	Edge f = e;
deba@2499	2190	angle[f] = 0;
deba@2499	2191	f = next[ugraph.oppositeEdge(f)];
deba@2499	2192	angle[f] = 1;
deba@2499	2193	f = next[ugraph.oppositeEdge(f)];
deba@2499	2194	angle[f] = 2;
deba@2499	2195	}
deba@2499	2196
deba@2499	2197	p = e;
deba@2499	2198	e = next[e];
deba@2499	2199	}
deba@2499	2200
deba@2499	2201	if (conn[ugraph.target(e)] == -2 && conn[ugraph.target(p)] == -2) {
deba@2499	2202	Edge f = e;
deba@2499	2203	angle[f] = 0;
deba@2499	2204	f = next[ugraph.oppositeEdge(f)];
deba@2499	2205	angle[f] = 1;
deba@2499	2206	f = next[ugraph.oppositeEdge(f)];
deba@2499	2207	angle[f] = 2;
deba@2499	2208	}
deba@2499	2209	}
deba@2499	2210	}
deba@2499	2211
deba@2499	2212	typename AuxUGraph::template NodeMap<Node> apred(ugraph, INVALID);
deba@2499	2213	typename AuxUGraph::template NodeMap<Node> bpred(ugraph, INVALID);
deba@2499	2214	typename AuxUGraph::template NodeMap<Node> cpred(ugraph, INVALID);
deba@2499	2215
deba@2499	2216	typename AuxUGraph::template NodeMap<int> apredid(ugraph, -1);
deba@2499	2217	typename AuxUGraph::template NodeMap<int> bpredid(ugraph, -1);
deba@2499	2218	typename AuxUGraph::template NodeMap<int> cpredid(ugraph, -1);
deba@2499	2219
deba@2499	2220	for (EdgeIt e(ugraph); e != INVALID; ++e) {
deba@2499	2221	if (angle[e] == angle[next[e]]) {
deba@2499	2222	switch (angle[e]) {
deba@2499	2223	case 2:
deba@2499	2224	apred[ugraph.target(e)] = ugraph.source(e);
deba@2499	2225	apredid[ugraph.target(e)] = ugraph.id(ugraph.source(e));
deba@2499	2226	break;
deba@2499	2227	case 1:
deba@2499	2228	bpred[ugraph.target(e)] = ugraph.source(e);
deba@2499	2229	bpredid[ugraph.target(e)] = ugraph.id(ugraph.source(e));
deba@2499	2230	break;
deba@2499	2231	case 0:
deba@2499	2232	cpred[ugraph.target(e)] = ugraph.source(e);
deba@2499	2233	cpredid[ugraph.target(e)] = ugraph.id(ugraph.source(e));
deba@2499	2234	break;
deba@2499	2235	}
deba@2499	2236	}
deba@2499	2237	}
deba@2499	2238
deba@2499	2239	cpred[anode] = INVALID;
deba@2499	2240	cpred[bnode] = INVALID;
deba@2499	2241
deba@2499	2242	std::vector<Node> aorder, border, corder;
deba@2499	2243
deba@2499	2244	{
deba@2499	2245	typename AuxUGraph::template NodeMap<bool> processed(ugraph, false);
deba@2499	2246	std::vector<Node> st;
deba@2499	2247	for (NodeIt n(ugraph); n != INVALID; ++n) {
deba@2499	2248	if (!processed[n] && n != bnode && n != cnode) {
deba@2499	2249	st.push_back(n);
deba@2499	2250	processed[n] = true;
deba@2499	2251	Node m = apred[n];
deba@2499	2252	while (m != INVALID && !processed[m]) {
deba@2499	2253	st.push_back(m);
deba@2499	2254	processed[m] = true;
deba@2499	2255	m = apred[m];
deba@2499	2256	}
deba@2499	2257	while (!st.empty()) {
deba@2499	2258	aorder.push_back(st.back());
deba@2499	2259	st.pop_back();
deba@2499	2260	}
deba@2499	2261	}
deba@2499	2262	}
deba@2499	2263	}
deba@2499	2264
deba@2499	2265	{
deba@2499	2266	typename AuxUGraph::template NodeMap<bool> processed(ugraph, false);
deba@2499	2267	std::vector<Node> st;
deba@2499	2268	for (NodeIt n(ugraph); n != INVALID; ++n) {
deba@2499	2269	if (!processed[n] && n != cnode && n != anode) {
deba@2499	2270	st.push_back(n);
deba@2499	2271	processed[n] = true;
deba@2499	2272	Node m = bpred[n];
deba@2499	2273	while (m != INVALID && !processed[m]) {
deba@2499	2274	st.push_back(m);
deba@2499	2275	processed[m] = true;
deba@2499	2276	m = bpred[m];
deba@2499	2277	}
deba@2499	2278	while (!st.empty()) {
deba@2499	2279	border.push_back(st.back());
deba@2499	2280	st.pop_back();
deba@2499	2281	}
deba@2499	2282	}
deba@2499	2283	}
deba@2499	2284	}
deba@2499	2285
deba@2499	2286	{
deba@2499	2287	typename AuxUGraph::template NodeMap<bool> processed(ugraph, false);
deba@2499	2288	std::vector<Node> st;
deba@2499	2289	for (NodeIt n(ugraph); n != INVALID; ++n) {
deba@2499	2290	if (!processed[n] && n != anode && n != bnode) {
deba@2499	2291	st.push_back(n);
deba@2499	2292	processed[n] = true;
deba@2499	2293	Node m = cpred[n];
deba@2499	2294	while (m != INVALID && !processed[m]) {
deba@2499	2295	st.push_back(m);
deba@2499	2296	processed[m] = true;
deba@2499	2297	m = cpred[m];
deba@2499	2298	}
deba@2499	2299	while (!st.empty()) {
deba@2499	2300	corder.push_back(st.back());
deba@2499	2301	st.pop_back();
deba@2499	2302	}
deba@2499	2303	}
deba@2499	2304	}
deba@2499	2305	}
deba@2499	2306
deba@2499	2307	typename AuxUGraph::template NodeMap<int> atree(ugraph, 0);
deba@2499	2308	for (int i = aorder.size() - 1; i >= 0; --i) {
deba@2499	2309	Node n = aorder[i];
deba@2499	2310	atree[n] = 1;
deba@2499	2311	for (OutEdgeIt e(ugraph, n); e != INVALID; ++e) {
deba@2499	2312	if (apred[ugraph.target(e)] == n) {
deba@2499	2313	atree[n] += atree[ugraph.target(e)];
deba@2499	2314	}
deba@2499	2315	}
deba@2499	2316	}
deba@2499	2317
deba@2499	2318	typename AuxUGraph::template NodeMap<int> btree(ugraph, 0);
deba@2499	2319	for (int i = border.size() - 1; i >= 0; --i) {
deba@2499	2320	Node n = border[i];
deba@2499	2321	btree[n] = 1;
deba@2499	2322	for (OutEdgeIt e(ugraph, n); e != INVALID; ++e) {
deba@2499	2323	if (bpred[ugraph.target(e)] == n) {
deba@2499	2324	btree[n] += btree[ugraph.target(e)];
deba@2499	2325	}
deba@2499	2326	}
deba@2499	2327	}
deba@2499	2328
deba@2499	2329	typename AuxUGraph::template NodeMap<int> apath(ugraph, 0);
deba@2499	2330	apath[bnode] = apath[cnode] = 1;
deba@2499	2331	typename AuxUGraph::template NodeMap<int> apath_btree(ugraph, 0);
deba@2499	2332	apath_btree[bnode] = btree[bnode];
deba@2499	2333	for (int i = 1; i < int(aorder.size()); ++i) {
deba@2499	2334	Node n = aorder[i];
deba@2499	2335	apath[n] = apath[apred[n]] + 1;
deba@2499	2336	apath_btree[n] = btree[n] + apath_btree[apred[n]];
deba@2499	2337	}
deba@2499	2338
deba@2499	2339	typename AuxUGraph::template NodeMap<int> bpath_atree(ugraph, 0);
deba@2499	2340	bpath_atree[anode] = atree[anode];
deba@2499	2341	for (int i = 1; i < int(border.size()); ++i) {
deba@2499	2342	Node n = border[i];
deba@2499	2343	bpath_atree[n] = atree[n] + bpath_atree[bpred[n]];
deba@2499	2344	}
deba@2499	2345
deba@2499	2346	typename AuxUGraph::template NodeMap<int> cpath(ugraph, 0);
deba@2499	2347	cpath[anode] = cpath[bnode] = 1;
deba@2499	2348	typename AuxUGraph::template NodeMap<int> cpath_atree(ugraph, 0);
deba@2499	2349	cpath_atree[anode] = atree[anode];
deba@2499	2350	typename AuxUGraph::template NodeMap<int> cpath_btree(ugraph, 0);
deba@2499	2351	cpath_btree[bnode] = btree[bnode];
deba@2499	2352	for (int i = 1; i < int(corder.size()); ++i) {
deba@2499	2353	Node n = corder[i];
deba@2499	2354	cpath[n] = cpath[cpred[n]] + 1;
deba@2499	2355	cpath_atree[n] = atree[n] + cpath_atree[cpred[n]];
deba@2499	2356	cpath_btree[n] = btree[n] + cpath_btree[cpred[n]];
deba@2499	2357	}
deba@2499	2358
deba@2499	2359	typename AuxUGraph::template NodeMap<int> third(ugraph);
deba@2499	2360	for (NodeIt n(ugraph); n != INVALID; ++n) {
deba@2499	2361	point_map[n].x =
deba@2499	2362	bpath_atree[n] + cpath_atree[n] - atree[n] - cpath[n] + 1;
deba@2499	2363	point_map[n].y =
deba@2499	2364	cpath_btree[n] + apath_btree[n] - btree[n] - apath[n] + 1;
deba@2499	2365	}
deba@2499	2366
deba@2499	2367	}
deba@2499	2368
deba@2499	2369	public:
deba@2499	2370
deba@2499	2371	/// \brief Calculates the node locations
deba@2499	2372	///
deba@2499	2373	/// This function calculates the node locations.
deba@2499	2374	bool run() {
deba@2499	2375	PlanarEmbedding<UGraph> pe(_ugraph);
deba@2499	2376	if (!pe.run()) return false;
deba@2499	2377
deba@2499	2378	run(pe);
deba@2499	2379	return true;
deba@2499	2380	}
deba@2499	2381
deba@2499	2382	/// \brief Calculates the node locations according to a
deba@2499	2383	/// combinatorical embedding
deba@2499	2384	///
deba@2499	2385	/// This function calculates the node locations. The \c embedding
deba@2499	2386	/// parameter should contain a valid combinatorical embedding, ie.
deba@2499	2387	/// a valid cyclic order of the edges.
deba@2499	2388	template <typename EmbeddingMap>
deba@2499	2389	void run(const EmbeddingMap& embedding) {
deba@2499	2390	typedef SmartUEdgeSet<UGraph> AuxUGraph;
deba@2499	2391
deba@2499	2392	if (3 * countNodes(_ugraph) - 6 == countUEdges(_ugraph)) {
deba@2499	2393	drawing(_ugraph, embedding, _point_map);
deba@2499	2394	return;
deba@2499	2395	}
deba@2499	2396
deba@2499	2397	AuxUGraph aux_ugraph(_ugraph);
deba@2499	2398	typename AuxUGraph::template EdgeMap<typename AuxUGraph::Edge>
deba@2499	2399	aux_embedding(aux_ugraph);
deba@2499	2400
deba@2499	2401	{
deba@2499	2402
deba@2499	2403	typename UGraph::template UEdgeMap<typename AuxUGraph::UEdge>
deba@2499	2404	ref(_ugraph);
deba@2499	2405
deba@2499	2406	for (UEdgeIt e(_ugraph); e != INVALID; ++e) {
deba@2499	2407	ref[e] = aux_ugraph.addEdge(_ugraph.source(e), _ugraph.target(e));
deba@2499	2408	}
deba@2499	2409
deba@2499	2410	for (UEdgeIt e(_ugraph); e != INVALID; ++e) {
deba@2499	2411	Edge ee = embedding[_ugraph.direct(e, true)];
deba@2499	2412	aux_embedding[aux_ugraph.direct(ref[e], true)] =
deba@2499	2413	aux_ugraph.direct(ref[ee], _ugraph.direction(ee));
deba@2499	2414	ee = embedding[_ugraph.direct(e, false)];
deba@2499	2415	aux_embedding[aux_ugraph.direct(ref[e], false)] =
deba@2499	2416	aux_ugraph.direct(ref[ee], _ugraph.direction(ee));
deba@2499	2417	}
deba@2499	2418	}
deba@2499	2419	_planarity_bits::makeConnected(aux_ugraph, aux_embedding);
deba@2499	2420	_planarity_bits::makeBiNodeConnected(aux_ugraph, aux_embedding);
deba@2499	2421	_planarity_bits::makeMaxPlanar(aux_ugraph, aux_embedding);
deba@2499	2422	drawing(aux_ugraph, aux_embedding, _point_map);
deba@2499	2423	}
deba@2499	2424
deba@2499	2425	/// \brief The coordinate of the given node
deba@2499	2426	///
deba@2499	2427	/// The coordinate of the given node.
deba@2499	2428	Point operator[](const Node& node) {
deba@2499	2429	return _point_map[node];
deba@2499	2430	}
deba@2499	2431
deba@2499	2432	/// \brief Returns the grid embedding in a \e NodeMap.
deba@2499	2433	///
deba@2499	2434	/// Returns the grid embedding in a \e NodeMap of \c dim2::Point<int> .
deba@2499	2435	const PointMap& coords() const {
deba@2499	2436	return _point_map;
deba@2499	2437	}
deba@2499	2438
deba@2499	2439	private:
deba@2499	2440
deba@2499	2441	const UGraph& _ugraph;
deba@2499	2442	PointMap _point_map;
deba@2499	2443
deba@2499	2444	};
deba@2499	2445
deba@2508	2446	namespace _planarity_bits {
deba@2508	2447
deba@2508	2448	template <typename ColorMap>
deba@2508	2449	class KempeFilter {
deba@2508	2450	public:
deba@2508	2451	typedef typename ColorMap::Key Key;
deba@2508	2452	typedef bool Value;
deba@2508	2453
deba@2508	2454	KempeFilter(const ColorMap& color_map,
deba@2508	2455	const typename ColorMap::Value& first,
deba@2508	2456	const typename ColorMap::Value& second)
deba@2508	2457	: _color_map(color_map), _first(first), _second(second) {}
deba@2508	2458
deba@2508	2459	Value operator[](const Key& key) const {
deba@2508	2460	return _color_map[key] == _first \|\| _color_map[key] == _second;
deba@2508	2461	}
deba@2508	2462
deba@2508	2463	private:
deba@2508	2464	const ColorMap& _color_map;
deba@2508	2465	typename ColorMap::Value _first, _second;
deba@2508	2466	};
deba@2508	2467	}
deba@2508	2468
deba@2508	2469	/// \ingroup planar
deba@2508	2470	///
deba@2508	2471	/// \brief Coloring planar graphs
deba@2508	2472	///
deba@2508	2473	/// The graph coloring problem is the coloring of the graph nodes
deba@2508	2474	/// such way that there are not adjacent nodes with the same
deba@2508	2475	/// color. The planar graphs can be always colored with four colors,
deba@2508	2476	/// it is proved by Appel and Haken and their proofs provide a
deba@2508	2477	/// quadratic time algorithm for four coloring, but it could not be
deba@2508	2478	/// used to implement efficient algorithm. The five and six coloring
deba@2508	2479	/// can be made in linear time, but in this class the five coloring
deba@2508	2480	/// has quadratic worst case time complexity. The two coloring (if
deba@2508	2481	/// possible) is solvable with a graph search algorithm and it is
deba@2508	2482	/// implemented in \ref bipartitePartitions() function in Lemon. To
deba@2508	2483	/// decide whether the planar graph is three colorable is
deba@2508	2484	/// NP-complete.
deba@2508	2485	///
deba@2508	2486	/// This class contains member functions for calculate colorings
deba@2508	2487	/// with five and six colors. The six coloring algorithm is a simple
deba@2508	2488	/// greedy coloring on the backward minimum outgoing order of nodes.
deba@2508	2489	/// This order can be computed such way, that in each phase the node
deba@2508	2490	/// with least outgoing edges to unprocessed nodes is choosen. This
deba@2508	2491	/// order guarantees that at the time of coloring of a node it has
deba@2508	2492	/// at most five already colored adjacents. The five coloring
deba@2508	2493	/// algorithm works in the same way, but if the greedy approach
deba@2508	2494	/// fails to color with five color, ie. the node has five already
deba@2508	2495	/// different colored neighbours, it swaps the colors in one
deba@2508	2496	/// connected two colored set with the Kempe recoloring method.
deba@2508	2497	template <typename UGraph>
deba@2508	2498	class PlanarColoring {
deba@2508	2499	public:
deba@2508	2500
deba@2508	2501	UGRAPH_TYPEDEFS(typename UGraph);
deba@2508	2502
deba@2508	2503	/// \brief The map type for store color indexes
deba@2508	2504	typedef typename UGraph::template NodeMap<int> IndexMap;
deba@2508	2505	/// \brief The map type for store colors
deba@2508	2506	typedef ComposeMap<Palette, IndexMap> ColorMap;
deba@2508	2507
deba@2508	2508	/// \brief Constructor
deba@2508	2509	///
deba@2508	2510	/// Constructor
deba@2508	2511	/// \pre The ugraph should be simple, ie. loop and parallel edge free.
deba@2508	2512	PlanarColoring(const UGraph& ugraph)
deba@2508	2513	: _ugraph(ugraph), _color_map(ugraph), _palette(0) {
deba@2508	2514	_palette.add(Color(1,0,0));
deba@2508	2515	_palette.add(Color(0,1,0));
deba@2508	2516	_palette.add(Color(0,0,1));
deba@2508	2517	_palette.add(Color(1,1,0));
deba@2508	2518	_palette.add(Color(1,0,1));
deba@2508	2519	_palette.add(Color(0,1,1));
deba@2508	2520	}
deba@2508	2521
deba@2508	2522	/// \brief Returns the \e NodeMap of color indexes
deba@2508	2523	///
deba@2508	2524	/// Returns the \e NodeMap of color indexes. The values are in the
deba@2508	2525	/// range \c [0..4] or \c [0..5] according to the five coloring or
deba@2508	2526	/// six coloring.
deba@2508	2527	IndexMap colorIndexMap() const {
deba@2508	2528	return _color_map;
deba@2508	2529	}
deba@2508	2530
deba@2508	2531	/// \brief Returns the \e NodeMap of colors
deba@2508	2532	///
deba@2508	2533	/// Returns the \e NodeMap of colors. The values are five or six
deba@2508	2534	/// distinct \ref lemon::Color "colors".
deba@2508	2535	ColorMap colorMap() const {
deba@2508	2536	return composeMap(_palette, _color_map);
deba@2508	2537	}
deba@2508	2538
deba@2508	2539	/// \brief Returns the color index of the node
deba@2508	2540	///
deba@2508	2541	/// Returns the color index of the node. The values are in the
deba@2508	2542	/// range \c [0..4] or \c [0..5] according to the five coloring or
deba@2508	2543	/// six coloring.
deba@2508	2544	int colorIndex(const Node& node) const {
deba@2508	2545	return _color_map[node];
deba@2508	2546	}
deba@2508	2547
deba@2508	2548	/// \brief Returns the color of the node
deba@2508	2549	///
deba@2508	2550	/// Returns the color of the node. The values are five or six
deba@2508	2551	/// distinct \ref lemon::Color "colors".
deba@2598	2552	Color color(const Node& node) const {
deba@2508	2553	return _palette[_color_map[node]];
deba@2508	2554	}
deba@2508	2555
deba@2508	2556
deba@2508	2557	/// \brief Calculates a coloring with at most six colors
deba@2508	2558	///
deba@2508	2559	/// This function calculates a coloring with at most six colors. The time
deba@2508	2560	/// complexity of this variant is linear in the size of the graph.
deba@2508	2561	/// \return %True when the algorithm could color the graph with six color.
deba@2508	2562	/// If the algorithm fails, then the graph could not be planar.
deba@2508	2563	bool runSixColoring() {
deba@2508	2564
deba@2508	2565	typename UGraph::template NodeMap<int> heap_index(_ugraph, -1);
deba@2508	2566	BucketHeap<typename UGraph::template NodeMap<int> > heap(heap_index);
deba@2508	2567
deba@2508	2568	for (NodeIt n(_ugraph); n != INVALID; ++n) {
deba@2508	2569	_color_map[n] = -2;
deba@2508	2570	heap.push(n, countOutEdges(_ugraph, n));
deba@2508	2571	}
deba@2508	2572
deba@2508	2573	std::vector<Node> order;
deba@2508	2574
deba@2508	2575	while (!heap.empty()) {
deba@2508	2576	Node n = heap.top();
deba@2508	2577	heap.pop();
deba@2508	2578	_color_map[n] = -1;
deba@2508	2579	order.push_back(n);
deba@2508	2580	for (OutEdgeIt e(_ugraph, n); e != INVALID; ++e) {
deba@2508	2581	Node t = _ugraph.runningNode(e);
deba@2508	2582	if (_color_map[t] == -2) {
deba@2508	2583	heap.decrease(t, heap[t] - 1);
deba@2508	2584	}
deba@2508	2585	}
deba@2508	2586	}
deba@2508	2587
deba@2508	2588	for (int i = order.size() - 1; i >= 0; --i) {
deba@2508	2589	std::vector<bool> forbidden(6, false);
deba@2508	2590	for (OutEdgeIt e(_ugraph, order[i]); e != INVALID; ++e) {
deba@2508	2591	Node t = _ugraph.runningNode(e);
deba@2508	2592	if (_color_map[t] != -1) {
deba@2508	2593	forbidden[_color_map[t]] = true;
deba@2508	2594	}
deba@2508	2595	}
deba@2508	2596	for (int k = 0; k < 6; ++k) {
deba@2508	2597	if (!forbidden[k]) {
deba@2508	2598	_color_map[order[i]] = k;
deba@2508	2599	break;
deba@2508	2600	}
deba@2508	2601	}
deba@2508	2602	if (_color_map[order[i]] == -1) {
deba@2508	2603	return false;
deba@2508	2604	}
deba@2508	2605	}
deba@2508	2606	return true;
deba@2508	2607	}
deba@2508	2608
deba@2508	2609	private:
deba@2508	2610
deba@2508	2611	bool recolor(const Node& u, const Node& v) {
deba@2508	2612	int ucolor = _color_map[u];
deba@2508	2613	int vcolor = _color_map[v];
deba@2508	2614	typedef _planarity_bits::KempeFilter<IndexMap> KempeFilter;
deba@2508	2615	KempeFilter filter(_color_map, ucolor, vcolor);
deba@2508	2616
deba@2508	2617	typedef NodeSubUGraphAdaptor<const UGraph, const KempeFilter> KempeUGraph;
deba@2508	2618	KempeUGraph kempe_ugraph(_ugraph, filter);
deba@2508	2619
deba@2508	2620	std::vector<Node> comp;
deba@2508	2621	Bfs<KempeUGraph> bfs(kempe_ugraph);
deba@2508	2622	bfs.init();
deba@2508	2623	bfs.addSource(u);
deba@2508	2624	while (!bfs.emptyQueue()) {
deba@2508	2625	Node n = bfs.nextNode();
deba@2508	2626	if (n == v) return false;
deba@2508	2627	comp.push_back(n);
deba@2508	2628	bfs.processNextNode();
deba@2508	2629	}
deba@2508	2630
deba@2508	2631	int scolor = ucolor + vcolor;
deba@2508	2632	for (int i = 0; i < static_cast<int>(comp.size()); ++i) {
deba@2508	2633	_color_map[comp[i]] = scolor - _color_map[comp[i]];
deba@2508	2634	}
deba@2508	2635
deba@2508	2636	return true;
deba@2508	2637	}
deba@2508	2638
deba@2508	2639	template <typename EmbeddingMap>
deba@2508	2640	void kempeRecoloring(const Node& node, const EmbeddingMap& embedding) {
deba@2508	2641	std::vector<Node> nodes;
deba@2508	2642	nodes.reserve(4);
deba@2508	2643
deba@2508	2644	for (Edge e = OutEdgeIt(_ugraph, node); e != INVALID; e = embedding[e]) {
deba@2508	2645	Node t = _ugraph.target(e);
deba@2508	2646	if (_color_map[t] != -1) {
deba@2508	2647	nodes.push_back(t);
deba@2508	2648	if (nodes.size() == 4) break;
deba@2508	2649	}
deba@2508	2650	}
deba@2508	2651
deba@2508	2652	int color = _color_map[nodes[0]];
deba@2508	2653	if (recolor(nodes[0], nodes[2])) {
deba@2508	2654	_color_map[node] = color;
deba@2508	2655	} else {
deba@2508	2656	color = _color_map[nodes[1]];
deba@2508	2657	recolor(nodes[1], nodes[3]);
deba@2508	2658	_color_map[node] = color;
deba@2508	2659	}
deba@2508	2660	}
deba@2508	2661
deba@2508	2662	public:
deba@2508	2663
deba@2508	2664	/// \brief Calculates a coloring with at most five colors
deba@2508	2665	///
deba@2508	2666	/// This function calculates a coloring with at most five
deba@2598	2667	/// colors. The worst case time complexity of this variant is
deba@2508	2668	/// quadratic in the size of the graph.
deba@2508	2669	template <typename EmbeddingMap>
deba@2508	2670	void runFiveColoring(const EmbeddingMap& embedding) {
deba@2508	2671
deba@2508	2672	typename UGraph::template NodeMap<int> heap_index(_ugraph, -1);
deba@2508	2673	BucketHeap<typename UGraph::template NodeMap<int> > heap(heap_index);
deba@2508	2674
deba@2508	2675	for (NodeIt n(_ugraph); n != INVALID; ++n) {
deba@2508	2676	_color_map[n] = -2;
deba@2508	2677	heap.push(n, countOutEdges(_ugraph, n));
deba@2508	2678	}
deba@2508	2679
deba@2508	2680	std::vector<Node> order;
deba@2508	2681
deba@2508	2682	while (!heap.empty()) {
deba@2508	2683	Node n = heap.top();
deba@2508	2684	heap.pop();
deba@2508	2685	_color_map[n] = -1;
deba@2508	2686	order.push_back(n);
deba@2508	2687	for (OutEdgeIt e(_ugraph, n); e != INVALID; ++e) {
deba@2508	2688	Node t = _ugraph.runningNode(e);
deba@2508	2689	if (_color_map[t] == -2) {
deba@2508	2690	heap.decrease(t, heap[t] - 1);
deba@2508	2691	}
deba@2508	2692	}
deba@2508	2693	}
deba@2508	2694
deba@2508	2695	for (int i = order.size() - 1; i >= 0; --i) {
deba@2508	2696	std::vector<bool> forbidden(5, false);
deba@2508	2697	for (OutEdgeIt e(_ugraph, order[i]); e != INVALID; ++e) {
deba@2508	2698	Node t = _ugraph.runningNode(e);
deba@2508	2699	if (_color_map[t] != -1) {
deba@2508	2700	forbidden[_color_map[t]] = true;
deba@2508	2701	}
deba@2508	2702	}
deba@2508	2703	for (int k = 0; k < 5; ++k) {
deba@2508	2704	if (!forbidden[k]) {
deba@2508	2705	_color_map[order[i]] = k;
deba@2508	2706	break;
deba@2508	2707	}
deba@2508	2708	}
deba@2508	2709	if (_color_map[order[i]] == -1) {
deba@2508	2710	kempeRecoloring(order[i], embedding);
deba@2508	2711	}
deba@2508	2712	}
deba@2508	2713	}
deba@2508	2714
deba@2508	2715	/// \brief Calculates a coloring with at most five colors
deba@2508	2716	///
deba@2508	2717	/// This function calculates a coloring with at most five
deba@2508	2718	/// colors. The worst case time complexity of this variant is
deba@2508	2719	/// quadratic in the size of the graph, but it most cases it does
deba@2508	2720	/// not have to use Kempe recoloring method, in this case it is
deba@2508	2721	/// equivalent with the runSixColoring() algorithm.
deba@2508	2722	/// \return %True when the graph is planar.
deba@2508	2723	bool runFiveColoring() {
deba@2508	2724	PlanarEmbedding<UGraph> pe(_ugraph);
deba@2508	2725	if (!pe.run()) return false;
deba@2508	2726
deba@2508	2727	runFiveColoring(pe.embeddingMap());
deba@2508	2728	return true;
deba@2508	2729	}
deba@2508	2730
deba@2508	2731	private:
deba@2508	2732
deba@2508	2733	const UGraph& _ugraph;
deba@2508	2734	IndexMap _color_map;
deba@2508	2735	Palette _palette;
deba@2508	2736	};
deba@2508	2737
deba@2480	2738	}
deba@2480	2739
deba@2480	2740	#endif

author	convert-repo
	Thu, 04 Mar 2010 19:34:55 +0000
changeset 2659	611ced85018b
parent 2553	bfced05fa852
permissions	-rw-r--r--