outil/src/HypergraphLib_FindCycles.cpp

#include "gestionversion.h"
#include "HypergraphLib_platform.h"

#include "HypergraphLib_FindCycles.h"
#include "HypergraphLib_Node.h"
#include "HypergraphLib_Arc.h"
#include "HypergraphLib_Graph.h"
#include <algorithm>
#include <iostream>

#undef DEBUG

namespace HypergraphLib {

    int find_n( std::vector < Node * > & __depthFirstSearchNodes, Node *__n)
    {
        for (unsigned i=0; i<__depthFirstSearchNodes.size(); i++)
            if (__depthFirstSearchNodes[i] == __n)
                return i;
        return -1;
    }

    int find_n( std::vector < Arc * > & __depthFirstSearchArcs, Arc *__a)
    {
        for (unsigned i=0; i<__depthFirstSearchArcs.size(); i++)
            if (__depthFirstSearchArcs[i] == __a)
                return i;
        return -1;
    }

    /**
     * returns :
     * -2 if the cycle does not exist
     * -1 if the cycle exist
     * j if the cycle at index j is longer than the new one
     */

    int does_cycle_already_exist( const std::vector < std::vector < Node * > > & cycles, const std::vector < Node * > & cycle)
    {
        for (unsigned i = 0; i < cycles.size(); i++)
            {
                for (unsigned j=0; j<cycles[i].size(); j++)
                    {
                        std::vector < Node * >::const_iterator it = std::find(cycle.begin(), cycle.end(), cycles[i][j]);
                        if (it == cycle.end())
                            goto not_equal_cycles;
                    }
                if (cycles[i].size() == cycle.size())
                    {
#ifdef DEBUG                    
                        std::cout << "Cycle \"";
                        for (int j=0; j<cycle.size(); j++)
                            std::cout << cycle[j]->Id() << ", ";
                        std::cout << "\" matches cycle ";
                        for (int j=0; j<cycles[i].size(); j++)
                            std::cout << cycles[i][j]->Id() << ", ";           
                        std::cout << std::endl;
#endif
                    }
                else if (cycles[i].size() > cycle.size())               
                    {
#ifdef DEBUG            
                        std::cout << "the candidate cycle \"";
                        for (int j=0; j<cycle.size(); j++)
                            std::cout << cycle[j]->Id() << ", ";
                        std::cout << "\" is shorter than the cycle \"";
                        for (int j=0; j<cycles[i].size(); j++)
                            std::cout << cycles[i][j]->Id() << ", "; 
                        std::cout << "\"";             
                        std::cout << std::endl;
#endif
                        return i;                       
                    }
                else 
                    {
#ifdef DEBUG            
                        std::cout << "the candidate cycle \"";
                        for (int j=0; j<cycle.size(); j++)
                            std::cout << cycle[j]->Id() << ", ";
                        std::cout << "\" is longer than the cycle \"";
                        for (int j=0; j<cycles[i].size(); j++)
                            std::cout << cycles[i][j]->Id() << ", "; 
                        std::cout << "\"";             
                        std::cout << std::endl; 
#endif          
                    }
                return -1;
not_equal_cycles:
                continue;
            }
#ifdef DEBUG            
                std::cout << "Cycle \"";
                for (int j=0; j<cycle.size(); j++)
                    std::cout << cycle[j]->Id() << ", ";                
                std::cout << "\" is a new cycle "<< std::endl;
#endif
                
        return -2;
    }

    void
    dfsCycle(Node *__n, std::vector < Node * > & __depthFirstSearchNodes, std::vector< Arc * > & __depthFirstSearchArcs, std::vector < std::vector < Node * > > & cycles )
    {
        std::set < Node * > adj;
        __n->AdjacentNodes( adj );
        std::vector<Node*>::iterator  it3;

        //int pos_n;
        if (__depthFirstSearchNodes.size() == 0)
            __depthFirstSearchNodes.push_back(__n);

        for ( Node::MultimapArcsById::iterator itIncidentArcs = __n->IncidentArcs().begin();
              itIncidentArcs != __n->IncidentArcs().end();
              itIncidentArcs++ )
            {
                Arc * incidentArc = itIncidentArcs->second;
                for ( Arc::MultimapNodesById::iterator itAdjNodes = incidentArc->Nodes().begin();
                      itAdjNodes != incidentArc->Nodes().end();
                      itAdjNodes++)
                    {
                        Node * adjNode = itAdjNodes->second;
                        std::vector < Node * > tempPath = __depthFirstSearchNodes;
                        std::vector < Arc * > tempPathArcs = __depthFirstSearchArcs;

                        if (__n->Owner()->IsCycle(tempPath))
                            {
                                //std::vector < Node * > cycle;
                                //for (int i=0; i<tempPath.size(); i++)
                                //    cycle.push_back(tempPath[i]);
                                int is_cycle_exists = does_cycle_already_exist(cycles, tempPath);
                                // if the cycle does not exists
                                if (is_cycle_exists == -2)
                                    cycles.push_back(tempPath);
                                // if a shorter cycle exists : replace the long cycle with the short cycle
                                if (is_cycle_exists > 0)
                                    {
                                        cycles [is_cycle_exists] = tempPath;
                                    }
                                //tempPath = __depthFirstSearchNodes;
                            }
                        else if ( find_n(__depthFirstSearchNodes, adjNode) == -1 && find_n(__depthFirstSearchArcs, incidentArc) == -1)
                            {
                                tempPath.push_back(adjNode);
                                tempPathArcs.push_back(incidentArc);
                                dfsCycle (adjNode, tempPath, tempPathArcs, cycles);
                            }
                    }
            }
    }

    
    void
    FindCycles(Graph * __G, std::vector < std::vector < Node * > > & cycles)
    {
        std::vector < Node * > depthFirstSearchNodes;
        std::vector < Arc * > depthFirstSearchArcs;

        GRAPH_FOR_EACH_NODE_CONST(__G, startNode)
        {
            depthFirstSearchNodes.clear();
            dfsCycle (startNode->second, depthFirstSearchNodes, depthFirstSearchArcs, cycles);
        }
    }
}

Revision:	253
Committed:	Tue Jul 13 19:40:46 2010 UTC (14 years, 10 months ago) by francois
File size:	4990 byte(s)
Error occurred while calculating annotation data.
Log Message:	changement de hiearchie et utilisation de ccmake + mise a jour
#	Content
1	#include "gestionversion.h"
2	#include "HypergraphLib_platform.h"
3
4	#include "HypergraphLib_FindCycles.h"
5	#include "HypergraphLib_Node.h"
6	#include "HypergraphLib_Arc.h"
7	#include "HypergraphLib_Graph.h"
8	#include <algorithm>
9	#include <iostream>
10
11	#undef DEBUG
12
13	namespace HypergraphLib {
14
15	int find_n( std::vector < Node * > & __depthFirstSearchNodes, Node *__n)
16	{
17	for (unsigned i=0; i<__depthFirstSearchNodes.size(); i++)
18	if (__depthFirstSearchNodes[i] == __n)
19	return i;
20	return -1;
21	}
22
23	int find_n( std::vector < Arc * > & __depthFirstSearchArcs, Arc *__a)
24	{
25	for (unsigned i=0; i<__depthFirstSearchArcs.size(); i++)
26	if (__depthFirstSearchArcs[i] == __a)
27	return i;
28	return -1;
29	}
30
31	/**
32	* returns :
33	* -2 if the cycle does not exist
34	* -1 if the cycle exist
35	* j if the cycle at index j is longer than the new one
36	*/
37
38	int does_cycle_already_exist( const std::vector < std::vector < Node * > > & cycles, const std::vector < Node * > & cycle)
39	{
40	for (unsigned i = 0; i < cycles.size(); i++)
41	{
42	for (unsigned j=0; j<cycles[i].size(); j++)
43	{
44	std::vector < Node * >::const_iterator it = std::find(cycle.begin(), cycle.end(), cycles[i][j]);
45	if (it == cycle.end())
46	goto not_equal_cycles;
47	}
48	if (cycles[i].size() == cycle.size())
49	{
50	#ifdef DEBUG
51	std::cout << "Cycle \"";
52	for (int j=0; j<cycle.size(); j++)
53	std::cout << cycle[j]->Id() << ", ";
54	std::cout << "\" matches cycle ";
55	for (int j=0; j<cycles[i].size(); j++)
56	std::cout << cycles[i][j]->Id() << ", ";
57	std::cout << std::endl;
58	#endif
59	}
60	else if (cycles[i].size() > cycle.size())
61	{
62	#ifdef DEBUG
63	std::cout << "the candidate cycle \"";
64	for (int j=0; j<cycle.size(); j++)
65	std::cout << cycle[j]->Id() << ", ";
66	std::cout << "\" is shorter than the cycle \"";
67	for (int j=0; j<cycles[i].size(); j++)
68	std::cout << cycles[i][j]->Id() << ", ";
69	std::cout << "\"";
70	std::cout << std::endl;
71	#endif
72	return i;
73	}
74	else
75	{
76	#ifdef DEBUG
77	std::cout << "the candidate cycle \"";
78	for (int j=0; j<cycle.size(); j++)
79	std::cout << cycle[j]->Id() << ", ";
80	std::cout << "\" is longer than the cycle \"";
81	for (int j=0; j<cycles[i].size(); j++)
82	std::cout << cycles[i][j]->Id() << ", ";
83	std::cout << "\"";
84	std::cout << std::endl;
85	#endif
86	}
87	return -1;
88	not_equal_cycles:
89	continue;
90	}
91	#ifdef DEBUG
92	std::cout << "Cycle \"";
93	for (int j=0; j<cycle.size(); j++)
94	std::cout << cycle[j]->Id() << ", ";
95	std::cout << "\" is a new cycle "<< std::endl;
96	#endif
97
98	return -2;
99	}
100
101	void
102	dfsCycle(Node __n, std::vector < Node > & __depthFirstSearchNodes, std::vector< Arc * > & __depthFirstSearchArcs, std::vector < std::vector < Node * > > & cycles )
103	{
104	std::set < Node * > adj;
105	__n->AdjacentNodes( adj );
106	std::vector<Node*>::iterator it3;
107
108	//int pos_n;
109	if (__depthFirstSearchNodes.size() == 0)
110	__depthFirstSearchNodes.push_back(__n);
111
112	for ( Node::MultimapArcsById::iterator itIncidentArcs = __n->IncidentArcs().begin();
113	itIncidentArcs != __n->IncidentArcs().end();
114	itIncidentArcs++ )
115	{
116	Arc * incidentArc = itIncidentArcs->second;
117	for ( Arc::MultimapNodesById::iterator itAdjNodes = incidentArc->Nodes().begin();
118	itAdjNodes != incidentArc->Nodes().end();
119	itAdjNodes++)
120	{
121	Node * adjNode = itAdjNodes->second;
122	std::vector < Node * > tempPath = __depthFirstSearchNodes;
123	std::vector < Arc * > tempPathArcs = __depthFirstSearchArcs;
124
125	if (__n->Owner()->IsCycle(tempPath))
126	{
127	//std::vector < Node * > cycle;
128	//for (int i=0; i<tempPath.size(); i++)
129	// cycle.push_back(tempPath[i]);
130	int is_cycle_exists = does_cycle_already_exist(cycles, tempPath);
131	// if the cycle does not exists
132	if (is_cycle_exists == -2)
133	cycles.push_back(tempPath);
134	// if a shorter cycle exists : replace the long cycle with the short cycle
135	if (is_cycle_exists > 0)
136	{
137	cycles [is_cycle_exists] = tempPath;
138	}
139	//tempPath = __depthFirstSearchNodes;
140	}
141	else if ( find_n(__depthFirstSearchNodes, adjNode) == -1 && find_n(__depthFirstSearchArcs, incidentArc) == -1)
142	{
143	tempPath.push_back(adjNode);
144	tempPathArcs.push_back(incidentArc);
145	dfsCycle (adjNode, tempPath, tempPathArcs, cycles);
146	}
147	}
148	}
149	}
150
151
152	void
153	FindCycles(Graph * __G, std::vector < std::vector < Node * > > & cycles)
154	{
155	std::vector < Node * > depthFirstSearchNodes;
156	std::vector < Arc * > depthFirstSearchArcs;
157
158	GRAPH_FOR_EACH_NODE_CONST(__G, startNode)
159	{
160	depthFirstSearchNodes.clear();
161	dfsCycle (startNode->second, depthFirstSearchNodes, depthFirstSearchArcs, cycles);
162	}
163	}
164	}
165