/** @see Graph#getAllEdges(Object, Object) */
public Set<E> getAllEdges(V sourceVertex, V targetVertex) {
Set<E> edges = null;
if (containsVertex(sourceVertex) && containsVertex(targetVertex)) {
edges = new ArrayUnenforcedSet<E>();
Iterator<E> iter = getEdgeContainer(sourceVertex).vertexEdges.iterator();
while (iter.hasNext()) {
E e = iter.next();
boolean equalStraight =
sourceVertex.equals(getEdgeSource(e)) && targetVertex.equals(getEdgeTarget(e));
boolean equalInverted =
sourceVertex.equals(getEdgeTarget(e)) && targetVertex.equals(getEdgeSource(e));
if (equalStraight || equalInverted) {
edges.add(e);
}
}
}
return edges;
}
private void markPath(V v, V child, V stem, Set<V> blossom) {
while (!contracted.get(v).equals(stem)) {
blossom.add(contracted.get(v));
blossom.add(contracted.get(match.get(v)));
path.put(v, child);
child = match.get(v);
v = path.get(match.get(v));
}
}
public Set<E> getAllEdges(V sourceVertex, V targetVertex) {
Set<E> res = new HashSet<E>();
if (g1.containsVertex(sourceVertex) && g1.containsVertex(targetVertex)) {
res.addAll(g1.getAllEdges(sourceVertex, targetVertex));
}
if (g2.containsVertex(sourceVertex) && g2.containsVertex(targetVertex)) {
res.addAll(g2.getAllEdges(sourceVertex, targetVertex));
}
return Collections.unmodifiableSet(res);
}
public Set<E> outgoingEdgesOf(V vertex) {
Set<E> res = new HashSet<E>();
if (getG1().containsVertex(vertex)) {
res.addAll(getG1().outgoingEdgesOf(vertex));
}
if (getG2().containsVertex(vertex)) {
res.addAll(getG2().outgoingEdgesOf(vertex));
}
return Collections.unmodifiableSet(res);
}
public Set<E> edgesOf(V vertex) {
Set<E> res = new HashSet<E>();
if (g1.containsVertex(vertex)) {
res.addAll(g1.edgesOf(vertex));
}
if (g2.containsVertex(vertex)) {
res.addAll(g2.edgesOf(vertex));
}
return Collections.unmodifiableSet(res);
}
private V lowestCommonAncestor(V a, V b) {
Set<V> seen = new HashSet<>();
for (; ; ) {
a = contracted.get(a);
seen.add(a);
if (!match.containsKey(a)) {
break;
}
a = path.get(match.get(a));
}
for (; ; ) {
b = contracted.get(b);
if (seen.contains(b)) {
return b;
}
b = path.get(match.get(b));
}
}
/** @see Graph#getAllEdges(Object, Object) */
public Set<E> getAllEdges(V sourceVertex, V targetVertex) {
Set<E> edges = null;
if (containsVertex(sourceVertex) && containsVertex(targetVertex)) {
edges = new ArrayUnenforcedSet<E>();
DirectedEdgeContainer<V, E> ec = getEdgeContainer(sourceVertex);
Iterator<E> iter = ec.outgoing.iterator();
while (iter.hasNext()) {
E e = iter.next();
if (getEdgeTarget(e).equals(targetVertex)) {
edges.add(e);
}
}
}
return edges;
}
/** @see Graph#edgesOf(Object) */
public Set<E> edgesOf(V vertex) {
ArrayUnenforcedSet<E> inAndOut = new ArrayUnenforcedSet<E>(getEdgeContainer(vertex).incoming);
inAndOut.addAll(getEdgeContainer(vertex).outgoing);
// we have two copies for each self-loop - remove one of them.
if (allowingLoops) {
Set<E> loops = getAllEdges(vertex, vertex);
for (int i = 0; i < inAndOut.size(); ) {
Object e = inAndOut.get(i);
if (loops.contains(e)) {
inAndOut.remove(i);
loops.remove(e); // so we remove it only once
} else {
i++;
}
}
}
return Collections.unmodifiableSet(inAndOut);
}
/**
* Runs the algorithm on the input graph and returns the match edge set.
*
* @return set of Edges
*/
private Set<E> findMatch() {
Set<E> result = new ArrayUnenforcedSet<>();
match = new HashMap<>();
path = new HashMap<>();
contracted = new HashMap<>();
for (V i : graph.vertexSet()) {
// Any augmenting path should start with _exposed_ vertex
// (vertex may not escape match-set being added once)
if (!match.containsKey(i)) {
// Match is maximal iff graph G contains no more augmenting paths
V v = findPath(i);
while (v != null) {
V pv = path.get(v);
V ppv = match.get(pv);
match.put(v, pv);
match.put(pv, v);
v = ppv;
}
}
}
Set<V> seen = new HashSet<>();
graph
.vertexSet()
.stream()
.filter(v -> !seen.contains(v) && match.containsKey(v))
.forEach(
v -> {
seen.add(v);
seen.add(match.get(v));
result.add(graph.getEdge(v, match.get(v)));
});
return result;
}
/**
* .
*
* @return
*/
public int edgeCount() {
return vertexEdges.size();
}
/**
* .
*
* @param e
*/
public void addEdge(EE e) {
vertexEdges.add(e);
}
/**
* .
*
* @param e
*/
public void removeOutgoingEdge(EE e) {
outgoing.remove(e);
}
/**
* .
*
* @param e
*/
public void removeIncomingEdge(EE e) {
incoming.remove(e);
}
public Set<V> vertexSet() {
Set<V> res = new HashSet<V>();
res.addAll(g1.vertexSet());
res.addAll(g2.vertexSet());
return Collections.unmodifiableSet(res);
}
/**
* .
*
* @param e
*/
public void addIncomingEdge(EE e) {
incoming.add(e);
}
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();
}
/**
* .
*
* @param e
*/
public void removeEdge(EE e) {
vertexEdges.remove(e);
}
/**
* .
*
* @param e
*/
public void addOutgoingEdge(EE e) {
outgoing.add(e);
}
public Set<E> edgeSet() {
Set<E> res = new HashSet<E>();
res.addAll(g1.edgeSet());
res.addAll(g2.edgeSet());
return Collections.unmodifiableSet(res);
}
private V findPath(V root) {
Set<V> used = new HashSet<>();
Queue<V> q = new ArrayDeque<>();
// Expand graph back from its contracted state
path.clear();
contracted.clear();
graph.vertexSet().forEach(vertex -> contracted.put(vertex, vertex));
used.add(root);
q.add(root);
while (!q.isEmpty()) {
V v = q.remove();
for (E e : graph.edgesOf(v)) {
V to = graph.getEdgeSource(e);
if (to.equals(v)) {
to = graph.getEdgeTarget(e);
}
if ((contracted.get(v).equals(contracted.get(to))) || to.equals(match.get(v))) {
continue;
}
// Check whether we've hit a 'blossom'
if ((to.equals(root)) || ((match.containsKey(to)) && (path.containsKey(match.get(to))))) {
V stem = lowestCommonAncestor(v, to);
Set<V> blossom = new HashSet<>();
markPath(v, to, stem, blossom);
markPath(to, v, stem, blossom);
graph
.vertexSet()
.stream()
.filter(i -> contracted.containsKey(i) && blossom.contains(contracted.get(i)))
.forEach(
i -> {
contracted.put(i, stem);
if (!used.contains(i)) {
used.add(i);
q.add(i);
}
});
// Check whether we've had hit a loop (of even length (!) presumably)
} else if (!path.containsKey(to)) {
path.put(to, v);
if (!match.containsKey(to)) {
return to;
}
to = match.get(to);
used.add(to);
q.add(to);
}
}
}
return null;
}
