/**
* Convenience method, returns the two outgoing from the node the edge points to that does not
* lead to where the edge comes from
*/
private Edge[] otherEdges(Edge e) {
Iterator it = e.pointsTo().getEdges();
LinkedList ll = new LinkedList();
while (it.hasNext()) {
Edge next = (Edge) it.next();
if (e.getBackEdge() != next) ll.add(next);
}
if (ll.size() == 0) return null; // we are looking at a leaf
return (Edge[]) ll.toArray(new Edge[0]);
}
public void removeEdge(final Edge e) {
adjacency.get(e.getFirst()).remove(e);
adjacency.get(e.getSecond()).remove(e.getBackEdge());
}
/** Specified in Node */
protected Node makeBinary(Collection newedges, Edge[] edgemapping, Node caller) {
// O(n) each edge is visited 1 time in the first part
// In the second part an upper bound of the total number
// of runs through the while-loop is O(n) (number of edges).
Iterator it = edges.iterator();
Edge e1, e2, newedge1, newedge2, next;
InnerNode thiscopy = new InnerNode();
Node tmp;
// first part (recursion)
while (it.hasNext()) { // Invoke recursively //Like the copy-method
next = (Edge) it.next();
if (next.to != caller) {
tmp = next.to.makeBinary(newedges, edgemapping, this);
e1 = thiscopy.addNeighbour(tmp);
e2 = tmp.addNeighbour(thiscopy);
e1.backedge = e2;
e2.backedge = e1;
edgemapping[next.getId()] = e1;
edgemapping[next.getBackEdge().getId()] = e2;
}
}
// second part (fixing degree with a while-loop)
while ((thiscopy.edges.size() > 2 && caller != null)
|| thiscopy.edges.size() > 3) { // not binary
// System.out.println(thiscopy+" has "+thiscopy.edges.size()+" edges");
it = thiscopy.edges.iterator();
e1 =
(Edge)
it.next(); // 1 //Save two outgoing edges (e1 and e2) for binarification
if (e1.to == caller) e1 = (Edge) it.next(); // 1 or 2
it.remove(); // Remove this edge from the edge list, see why below **
e2 = (Edge) it.next(); // 2 or 3
if (e2.to == caller)
e2 =
(Edge)
it
.next(); // 3 //since edges.size() >=4 I can get three elements out without
// problems
it.remove(); // Remove this edge from the edge list, see why below **
// e1 and e2 are two outgoing edges that does not lead back to the caller
InnerNode newnode = new InnerNode(); // Make a new node to attach e1 and e2 to
newedge1 = thiscopy.addNeighbour(newnode); // attach this node to the new node
newedge2 = newnode.addNeighbour(thiscopy); // and vice versa
newedge1.backedge = newedge2;
newedge2.backedge = newedge1;
newedges.add(newedge1); // Since these edges are new edges, add them to the collection
newedges.add(newedge2);
// Now instead of using removeNeighbour and that stuff, we use a 'hack'. We change the
// endpoint of the
// edges between 'e1' and 'thiscopy' to 'e1' and 'newnode', and 'e2' and 'thiscopy' to 'e2'
// and 'newnode' respectively.
// This way any new edge already added to the newedges-collection is still valid.
e1.from = newnode; // change the endpoints
e2.from = newnode;
e1.getBackEdge().to = newnode; //
e2.getBackEdge().to = newnode;
// now we need to remove e1 and e2 from this nodes edgelist and add them to newnode's edge
// list, but we
// already did half of that above **
newnode.edges.add(e1);
newnode.edges.add(e2); // the other half well done.
// For each run of this while-loop one neighbour is added and two are removed, hence it must
// terminate.
}
return thiscopy;
}