COIN-OR::LEMON - Graph Library

source: lemon-0.x/src/work/marci/leda/comparison.cc @ 651:a56e043aeab1

Last change on this file since 651:a56e043aeab1 was 648:8c13444bccf6, checked in by marci, 21 years ago

for_each fix

File size: 4.7 KB
Line 
1// -*- c++ -*-
2#include <iostream>
3#include <fstream>
4#include <vector>
5#include <cstdlib>
6
7#include <LEDA/graph.h>
8#include <LEDA/mcb_matching.h>
9#include <LEDA/list.h>
10#include <LEDA/graph_gen.h>
11
12#include <leda_graph_wrapper.h>
13#include <sage_graph.h>
14//#include <smart_graph.h>
15//#include <dimacs.h>
16#include <hugo/time_measure.h>
17#include <hugo/for_each_macros.h>
18#include <hugo/graph_wrapper.h>
19#include <bipartite_graph_wrapper.h>
20#include <hugo/maps.h>
21#include <max_flow.h>
22
23/**
24 * Inicializalja a veletlenszamgeneratort.
25 * Figyelem, ez nem jo igazi random szamokhoz,
26 * erre ne bizzad a titkaidat!
27 */
28void random_init()
29{
30        unsigned int seed = getpid();
31        seed |= seed << 15;
32        seed ^= time(0);
33
34        srand(seed);
35}
36
37/**
38 * Egy veletlen int-et ad vissza 0 es m-1 kozott.
39 */
40int random(int m)
41{
42  return int( double(m) * rand() / (RAND_MAX + 1.0) );
43}
44
45using namespace hugo;
46
47int main() {
48  //for leda graph
49  leda::graph lg;
50  //lg.make_undirected();
51  typedef LedaGraphWrapper<leda::graph> Graph;
52  Graph g(lg);
53
54  //for UndirSageGraph
55  //typedef UndirSageGraph Graph;
56  //Graph g;
57
58  typedef Graph::Node Node;
59  typedef Graph::NodeIt NodeIt;
60  typedef Graph::Edge Edge;
61  typedef Graph::EdgeIt EdgeIt;
62  typedef Graph::OutEdgeIt OutEdgeIt;
63
64  std::vector<Graph::Node> s_nodes;
65  std::vector<Graph::Node> t_nodes;
66
67  int a;
68  std::cout << "number of nodes in the first color class=";
69  std::cin >> a;
70  int b;
71  std::cout << "number of nodes in the second color class=";
72  std::cin >> b;
73  int m;
74  std::cout << "number of edges=";
75  std::cin >> m;
76  int k;
77  std::cout << "A bipartite graph is a random group graph if the color classes \nA and B are partitiones to A_0, A_1, ..., A_{k-1} and B_0, B_1, ..., B_{k-1} \nas equally as possible \nand the edges from A_i goes to A_{i-1 mod k} and A_{i+1 mod k}.\n";
78  std::cout << "number of groups in LEDA random group graph=";
79  std::cin >> k;
80  std::cout << std::endl;
81 
82  leda_list<leda_node> lS;
83  leda_list<leda_node> lT;
84  random_bigraph(lg, a, b, m, lS, lT, k);
85
86  Graph::NodeMap<int> ref_map(g, -1);
87  IterableBoolMap< Graph::NodeMap<int> > bipartite_map(ref_map);
88
89  //generating leda random group graph
90  leda_node ln;
91  forall(ln, lS) bipartite_map.insert(ln, false);
92  forall(ln, lT) bipartite_map.insert(ln, true);
93
94  //making bipartite graph
95  typedef BipartiteGraphWrapper<Graph> BGW;
96  BGW bgw(g, bipartite_map);
97
98
99  //st-wrapper
100  typedef stGraphWrapper<BGW> stGW;
101  stGW stgw(bgw);
102  ConstMap<stGW::Edge, int> const1map(1);
103  stGW::EdgeMap<int> flow(stgw);
104
105  Timer ts;
106
107  ts.reset();
108  FOR_EACH_LOC(stGW::EdgeIt, e, stgw) flow.set(e, 0);
109  MaxFlow<stGW, int, ConstMap<stGW::Edge, int>, stGW::EdgeMap<int> >
110    max_flow_test(stgw, stgw.S_NODE, stgw.T_NODE, const1map, flow/*, true*/);
111  max_flow_test.run();
112  std::cout << "HUGO max matching algorithm based on preflow." << std::endl
113            << "Size of matching: "
114            << max_flow_test.flowValue() << std::endl;
115  std::cout << "elapsed time: " << ts << std::endl << std::endl;
116
117  ts.reset(); 
118  leda_list<leda_edge> ml=MAX_CARD_BIPARTITE_MATCHING(lg);
119  std::cout << "LEDA max matching algorithm." << std::endl
120            << "Size of matching: "
121            << ml.size() << std::endl;
122  std::cout << "elapsed time: " << ts << std::endl << std::endl;
123
124//   ts.reset();
125//   FOR_EACH_LOC(stGW::EdgeIt, e, stgw) flow.set(e, 0);
126//   typedef SageGraph MutableGraph;
127//   while (max_flow_test.augmentOnBlockingFlow<MutableGraph>()) { }
128//   std::cout << "HUGO max matching algorithm based on blocking flow augmentation."
129//          << std::endl << "Matching size: "
130//          << max_flow_test.flowValue() << std::endl;
131//   std::cout << "elapsed time: " << ts << std::endl << std::endl;
132
133  {
134  SageGraph hg;
135  SageGraph::Node s=hg.addNode(); 
136  SageGraph::Node t=hg.addNode();
137  BGW::NodeMap<SageGraph::Node> b_s_nodes(bgw); 
138  BGW::NodeMap<SageGraph::Node> b_t_nodes(bgw);
139 
140  FOR_EACH_INC_LOC(BGW::ClassNodeIt, n, bgw, BGW::S_CLASS) {
141    b_s_nodes.set(n, hg.addNode());
142    hg.addEdge(s, b_s_nodes[n]);
143  }
144  FOR_EACH_INC_LOC(BGW::ClassNodeIt, n, bgw, BGW::T_CLASS) {
145    b_t_nodes.set(n, hg.addNode());
146    hg.addEdge(b_t_nodes[n], t);
147  }
148
149  FOR_EACH_LOC(BGW::EdgeIt, e, bgw)
150    hg.addEdge(b_s_nodes[bgw.tail(e)], b_t_nodes[bgw.head(e)]);
151
152  ConstMap<SageGraph::Edge, int> cm(1);
153  SageGraph::EdgeMap<int> flow(hg); //0
154 
155  Timer ts;
156
157  ts.reset();
158  MaxFlow<SageGraph, int, ConstMap<SageGraph::Edge, int>,
159    SageGraph::EdgeMap<int> >
160    max_flow_test(hg, s, t, cm, flow);
161  max_flow_test.run();
162  std::cout << "HUGO max matching algorithm on SageGraph by copying the graph, based on preflow."
163            << std::endl
164            << "Size of matching: "
165            << max_flow_test.flowValue() << std::endl;
166  std::cout << "elapsed time: " << ts << std::endl << std::endl;
167  }
168
169  return 0;
170}
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