private void init(Graph<V, E> g, Set<V> vertexSet, Set<E> edgeSet) {
// create a map between vertex value to its order(1st,2nd,etc)
// "CAT"=1 "DOG"=2 "RHINO"=3
this.mapVertexToOrder = new HashMap<V, Integer>(vertexSet.size());
int counter = 0;
for (V vertex : vertexSet) {
mapVertexToOrder.put(vertex, new Integer(counter));
counter++;
}
// create a friendlier representation of an edge
// by order, like 2nd->3rd instead of B->A
// use the map to convert vertex to order
// on directed graph, edge A->B must be (A,B)
// on undirected graph, edge A-B can be (A,B) or (B,A)
this.labelsEdgesSet = new HashSet<LabelsEdge>(edgeSet.size());
for (E edge : edgeSet) {
V sourceVertex = g.getEdgeSource(edge);
Integer sourceOrder = mapVertexToOrder.get(sourceVertex);
int sourceLabel = sourceOrder.intValue();
int targetLabel = (mapVertexToOrder.get(g.getEdgeTarget(edge))).intValue();
LabelsEdge lablesEdge = new LabelsEdge(sourceLabel, targetLabel);
this.labelsEdgesSet.add(lablesEdge);
if (g instanceof UndirectedGraph<?, ?>) {
LabelsEdge oppositeEdge = new LabelsEdge(targetLabel, sourceLabel);
this.labelsEdgesSet.add(oppositeEdge);
}
}
}
/**
* Compute the unique decomposition of the input graph G (atoms of G). Implementation of algorithm
* Atoms as described in Berry et al. (2010), DOI:10.3390/a3020197, <a
* href="http://www.mdpi.com/1999-4893/3/2/197">http://www.mdpi.com/1999-4893/3/2/197</a>
*/
private void computeAtoms() {
if (chordalGraph == null) {
computeMinimalTriangulation();
}
separators = new HashSet<>();
// initialize g' as subgraph of graph (same vertices and edges)
UndirectedGraph<V, E> gprime = copyAsSimpleGraph(graph);
// initialize h' as subgraph of chordalGraph (same vertices and edges)
UndirectedGraph<V, E> hprime = copyAsSimpleGraph(chordalGraph);
atoms = new HashSet<>();
Iterator<V> iterator = meo.descendingIterator();
while (iterator.hasNext()) {
V v = iterator.next();
if (generators.contains(v)) {
Set<V> separator = new HashSet<>(Graphs.neighborListOf(hprime, v));
if (isClique(graph, separator)) {
if (separator.size() > 0) {
if (separators.contains(separator)) {
fullComponentCount.put(separator, fullComponentCount.get(separator) + 1);
} else {
fullComponentCount.put(separator, 2);
separators.add(separator);
}
}
UndirectedGraph<V, E> tmpGraph = copyAsSimpleGraph(gprime);
tmpGraph.removeAllVertices(separator);
ConnectivityInspector<V, E> con = new ConnectivityInspector<>(tmpGraph);
if (con.isGraphConnected()) {
throw new RuntimeException("separator did not separate the graph");
}
for (Set<V> component : con.connectedSets()) {
if (component.contains(v)) {
gprime.removeAllVertices(component);
component.addAll(separator);
atoms.add(new HashSet<>(component));
assert (component.size() > 0);
break;
}
}
}
}
hprime.removeVertex(v);
}
if (gprime.vertexSet().size() > 0) {
atoms.add(new HashSet<>(gprime.vertexSet()));
}
}
/**
* Finds the vertex set for the subgraph of all cycles.
*
* @return set of all vertices which participate in at least one cycle in this graph
*/
public Set<V> findCycles() {
// ProbeIterator can't be used to handle this case,
// so use StrongConnectivityInspector instead.
StrongConnectivityInspector<V, E> inspector = new StrongConnectivityInspector<V, E>(graph);
List<Set<V>> components = inspector.stronglyConnectedSets();
// A vertex participates in a cycle if either of the following is
// true: (a) it is in a component whose size is greater than 1
// or (b) it is a self-loop
Set<V> set = new HashSet<V>();
for (Set<V> component : components) {
if (component.size() > 1) {
// cycle
set.addAll(component);
} else {
V v = component.iterator().next();
if (graph.containsEdge(v, v)) {
// self-loop
set.add(v);
}
}
}
return set;
}
/**
* @param vertexNumber the number which identifies the vertex v in this order.
* @return the identifying numbers of all vertices which are connected to v by an edge incoming to
* v.
*/
public int[] getInEdges(int vertexNumber) {
if (cacheEdges && (incomingEdges[vertexNumber] != null)) {
return incomingEdges[vertexNumber];
}
V v = getVertex(vertexNumber);
Set<E> edgeSet;
if (graph instanceof DirectedGraph<?, ?>) {
edgeSet = ((DirectedGraph<V, E>) graph).incomingEdgesOf(v);
} else {
edgeSet = graph.edgesOf(v);
}
int[] vertexArray = new int[edgeSet.size()];
int i = 0;
for (E edge : edgeSet) {
V source = graph.getEdgeSource(edge), target = graph.getEdgeTarget(edge);
vertexArray[i++] = mapVertexToOrder.get(source.equals(v) ? target : source);
}
if (cacheEdges) {
incomingEdges[vertexNumber] = vertexArray;
}
return vertexArray;
}
/**
* .
*
* @return
*/
public int edgeCount() {
return vertexEdges.size();
}
public int outDegreeOf(V vertex) {
Set<E> res = outgoingEdgesOf(vertex);
return res.size();
}
public int inDegreeOf(V vertex) {
Set<E> res = incomingEdgesOf(vertex);
return res.size();
}
