/**
* \brief Set the ordering of edges around n according to their order in v.
*/
void GraphStorage::setEdgeOrder(const node n, const std::vector<edge> &v ) {
if (v.empty()) return;
MutableContainer<int> isEle;
isEle.setAll(0);
for (std::vector<edge>::const_iterator it=v.begin(); it!=v.end(); ++it) {
isEle.add(it->id, 1);
}
std::vector<edge>::const_iterator it2=v.begin();
EdgeVector& currentOrder = nodes[n.id].edges;
for (unsigned int i=0; i<currentOrder.size(); ++i) {
if ( isEle.get(currentOrder[i].id)>0 ) {
isEle.add(currentOrder[i].id, -1);
currentOrder[i] = *it2;
++it2;
}
}
}
PosibErr<void> itemize (ParmString s, MutableContainer & d) {
ItemizeTokenizer els(s);
ItemizeItem li;
while (li = els.next(), li.name != 0) {
switch (li.action) {
case '+':
RET_ON_ERR(d.add(li.name));
break;
case '-':
RET_ON_ERR(d.remove(li.name));
break;
case '!':
RET_ON_ERR(d.clear());
break;
default:
abort();
}
}
return no_err;
}
bool run() {
result->setAllNodeValue(0.0);
result->setAllEdgeValue(0.0);
bool directed = false;
bool norm = false;
if ( dataSet!=NULL ) {
dataSet->get("directed",directed);
dataSet->get("norm", norm);
}
//Metric is 0 in this case
if(graph->numberOfNodes()<=2) return true;
Iterator<node> *it = graph->getNodes();
unsigned int count = 0;
while(it->hasNext()) {
if (pluginProgress->progress(count++,graph->numberOfNodes())!=TLP_CONTINUE) break;
node s = it->next();
stack<node> S;
TLP_HASH_MAP<node, list<node> > P;
MutableContainer<int> sigma;
sigma.setAll(0);
sigma.set(s.id,1);
MutableContainer<int> d;
d.setAll(-1);
d.set(s.id, 0);
queue<node> Q;
Q.push(s);
while(!Q.empty()) {
node v = Q.front();
Q.pop();
S.push(v);
Iterator<node> *it2;
if (directed)
it2 = graph->getOutNodes(v);
else
it2 = graph->getInOutNodes(v);
while (it2->hasNext()) {
node w = it2->next();
if (d.get(w.id)<0) {
Q.push(w);
d.set(w.id, d.get(v.id)+1);
}
if (d.get(w.id) == d.get(v.id)+1) {
sigma.add(w.id, sigma.get(v.id));
P[w].push_back(v);
}
}
delete it2;
}
MutableContainer<double> delta;
delta.setAll(0.0);
while(!S.empty()) {
node w = S.top();
S.pop();
list<node>::const_iterator itn = P[w].begin();
for (; itn!=P[w].end(); ++itn) {
node v = *itn;
delta.add(v.id, (double(sigma.get(v.id)) / double(sigma.get(w.id)) * (1.0 + delta.get(w.id))));
edge e = graph->existEdge(v,w,directed);
if(e.isValid())
result->setEdgeValue(e, result->getEdgeValue(e) + double(sigma.get(v.id)) / double(sigma.get(w.id)) * (1.0 + delta.get(w.id)));
}
if (w != s) result->setNodeValue(w, result->getNodeValue(w) + delta.get(w.id));
}
}
delete it;
//Normalization
if(norm || !directed) {
double n = graph->numberOfNodes();
it = graph->getNodes();
while(it->hasNext()) {
node s = it->next();
//In the undirected case, the metric must be divided by two, then
if(norm)
result->setNodeValue(s,result->getNodeValue(s)/((n-1.0)*(n-2.0)));
if(!directed)
result->setNodeValue(s,result->getNodeValue(s)/2.0);
}
delete it;
Iterator<edge> *itE = graph->getEdges();
while(itE->hasNext()) {
edge e = itE->next();
if(norm)
result->setEdgeValue(e,4.0*result->getEdgeValue(e)/(n*n));
if(!directed)
result->setEdgeValue(e,result->getEdgeValue(e)/(2.0));
}
delete itE;
}
return pluginProgress->state()!=TLP_CANCEL;
}
/*
* Algebric criteria to check the plane map...
*/
bool PlanarityTestImpl::isPlanarEmbedding(Graph *sG) {
int n = sG->numberOfNodes();
if (n == 1)
return true;
int m = sG->numberOfEdges();
unsigned int count = 0;
MutableContainer<char> considered;
MutableContainer<bool> sens;
considered.setAll(0);
sens.setAll(false);
int fc = 0;
// displayMap(sG);
for (int k=0; k<2; ++k) {
Iterator<edge> *it = sG->getEdges();
while (it->hasNext()) {
edge e = it->next();
if (considered.get(e.id)<2) {
count = 0;
// cerr << "Face : " << fc << " start edge:" << e.id << endl;
edge e1 = e;
node n, n_tmp;
if (sens.get(e.id))
n = sG->target(e1);
else
n = sG->source(e1);
// cerr << "-(" << e1.id << ")->" << n.id << flush;
n_tmp = n;
do {
considered.add(e1.id, 1);
EdgeMapIterator it(sG, e1, n);
e1 = it.next();
n = sG->opposite(e1,n);
if (sG->source(e1) == n)
sens.set(e1.id,true);
// cerr << "-(" << e1.id << ")->" << n.id << flush;
++count;
if (count > sG->numberOfEdges() +1) break;
}
while ((e1 != e)||(n != n_tmp));
fc++;
// cerr << endl;
}
}
delete it;
}
if (fc != m - n + 2) {
//cerr << __PRETTY_FUNCTION__ << " : not ok :( nb faces :" << fc << "!=" << m - n +2 << endl;
return false;
}
return true;
}
