deba@2084
|
1 |
/* -*- C++ -*-
|
deba@2084
|
2 |
*
|
deba@2084
|
3 |
* This file is a part of LEMON, a generic C++ optimization library
|
deba@2084
|
4 |
*
|
deba@2084
|
5 |
* Copyright (C) 2003-2006
|
deba@2084
|
6 |
* Egervary Jeno Kombinatorikus Optimalizalasi Kutatocsoport
|
deba@2084
|
7 |
* (Egervary Research Group on Combinatorial Optimization, EGRES).
|
deba@2084
|
8 |
*
|
deba@2084
|
9 |
* Permission to use, modify and distribute this software is granted
|
deba@2084
|
10 |
* provided that this copyright notice appears in all copies. For
|
deba@2084
|
11 |
* precise terms see the accompanying LICENSE file.
|
deba@2084
|
12 |
*
|
deba@2084
|
13 |
* This software is provided "AS IS" with no warranty of any kind,
|
deba@2084
|
14 |
* express or implied, and with no claim as to its suitability for any
|
deba@2084
|
15 |
* purpose.
|
deba@2084
|
16 |
*
|
deba@2084
|
17 |
*/
|
deba@2084
|
18 |
|
deba@2084
|
19 |
/// \ingroup demos
|
deba@2084
|
20 |
/// \file
|
deba@2084
|
21 |
/// \brief Node and edge disjoint paths in directed graph.
|
deba@2084
|
22 |
///
|
deba@2084
|
23 |
/// This demo program calculates how many edge disjoint and node disjoint
|
deba@2084
|
24 |
/// paths are in a directed graph between a source and a target node.
|
deba@2084
|
25 |
/// The edge disjoint paths can be computed with a flow algorithm,
|
deba@2084
|
26 |
/// in this example we use the Preflow algorithm class. To get the node
|
deba@2084
|
27 |
/// disjoint paths we should first adapt the graph with the SplitGraphAdaptor
|
deba@2084
|
28 |
/// and just then calculate the flow.
|
deba@2084
|
29 |
///
|
deba@2084
|
30 |
/// \include disjoint_paths_demo.cc
|
deba@2084
|
31 |
|
deba@2084
|
32 |
#include <iostream>
|
deba@2084
|
33 |
|
deba@2084
|
34 |
#include <lemon/smart_graph.h>
|
deba@2084
|
35 |
#include <lemon/graph_adaptor.h>
|
deba@2084
|
36 |
#include <lemon/graph_reader.h>
|
deba@2084
|
37 |
#include <lemon/preflow.h>
|
deba@2084
|
38 |
#include <lemon/graph_to_eps.h>
|
deba@2084
|
39 |
|
deba@2084
|
40 |
using namespace lemon;
|
deba@2084
|
41 |
using namespace std;
|
deba@2084
|
42 |
|
deba@2084
|
43 |
Color color(bool b) {
|
alpar@2174
|
44 |
return b ? RED : BLACK;
|
deba@2084
|
45 |
}
|
deba@2084
|
46 |
|
deba@2084
|
47 |
int main() {
|
deba@2084
|
48 |
cout << "This program calculates the number " <<
|
deba@2084
|
49 |
"of disjoint paths in a graph" << endl;
|
deba@2084
|
50 |
cout << "The graph is read from the disjoint_paths_demo.lgf file" << endl;
|
deba@2084
|
51 |
typedef SmartGraph Graph;
|
deba@2084
|
52 |
|
deba@2084
|
53 |
Graph graph;
|
deba@2084
|
54 |
|
alpar@2207
|
55 |
Graph::NodeMap<dim2::Point<double> > coords(graph);
|
deba@2084
|
56 |
Graph::Node source, target;
|
deba@2084
|
57 |
GraphReader<Graph>("disjoint_paths_demo.lgf", graph).
|
deba@2084
|
58 |
readNodeMap("coords", coords).
|
deba@2084
|
59 |
readNode("source", source).readNode("target", target).run();
|
deba@2084
|
60 |
|
deba@2084
|
61 |
typedef ConstMap<Graph::Edge, int> Capacity;
|
deba@2084
|
62 |
Capacity capacity(1);
|
deba@2084
|
63 |
|
deba@2084
|
64 |
Graph::EdgeMap<int> flow(graph);
|
deba@2084
|
65 |
|
deba@2084
|
66 |
Preflow<Graph, int, Capacity> preflow(graph, source, target, capacity, flow);
|
deba@2084
|
67 |
|
deba@2084
|
68 |
preflow.run();
|
deba@2084
|
69 |
|
deba@2084
|
70 |
cout << "Number of edge disjoint paths: " << preflow.flowValue() << endl;
|
deba@2084
|
71 |
|
deba@2084
|
72 |
graphToEps(graph, "edge_disjoint_paths.eps").
|
deba@2084
|
73 |
title("edge disjoint path").copyright("(C) 2006 LEMON Project").drawArrows().
|
deba@2084
|
74 |
edgeColors(composeMap(functorMap(color), flow)).
|
deba@2084
|
75 |
coords(coords).autoNodeScale().run();
|
deba@2084
|
76 |
|
deba@2084
|
77 |
|
deba@2084
|
78 |
cout << "The paths are written into edge_disjoint_paths.eps" << endl;
|
deba@2084
|
79 |
|
deba@2084
|
80 |
typedef SplitGraphAdaptor<SmartGraph> SGraph;
|
deba@2084
|
81 |
|
deba@2084
|
82 |
SGraph sgraph(graph);
|
deba@2084
|
83 |
|
deba@2084
|
84 |
typedef ConstMap<SGraph::Edge, int> SCapacity;
|
deba@2084
|
85 |
SCapacity scapacity(1);
|
deba@2084
|
86 |
|
deba@2084
|
87 |
SGraph::EdgeMap<int> sflow(sgraph);
|
deba@2084
|
88 |
|
deba@2084
|
89 |
Preflow<SGraph, int, SCapacity> spreflow(sgraph, SGraph::outNode(source),
|
deba@2084
|
90 |
SGraph::inNode(target),
|
deba@2084
|
91 |
scapacity, sflow);
|
deba@2084
|
92 |
|
deba@2084
|
93 |
spreflow.run();
|
deba@2084
|
94 |
|
deba@2084
|
95 |
cout << "Number of node disjoint paths: " << spreflow.flowValue() << endl;
|
deba@2084
|
96 |
|
deba@2084
|
97 |
|
deba@2084
|
98 |
graphToEps(sgraph, "node_disjoint_paths.eps").
|
deba@2084
|
99 |
title("node disjoint path").copyright("(C) 2006 LEMON Project").drawArrows().
|
deba@2084
|
100 |
edgeColors(composeMap(functorMap(color), sflow)).
|
alpar@2207
|
101 |
coords(SGraph::combinedNodeMap(coords,
|
alpar@2207
|
102 |
shiftMap(coords,
|
alpar@2207
|
103 |
dim2::Point<double>(5, 0)))).
|
deba@2084
|
104 |
autoNodeScale().run();
|
deba@2084
|
105 |
|
deba@2084
|
106 |
cout << "The paths are written into node_disjoint_paths.eps" << endl;
|
deba@2084
|
107 |
|
deba@2084
|
108 |
return 0;
|
deba@2084
|
109 |
}
|