private boolean applyAfterDirectedNodeRemoval(Update u) {
DirectedNode node = (DirectedNode) ((NodeRemoval) u).getNode();
int min = Integer.MAX_VALUE;
int max = 0;
HashMap<Integer, LinkedList<DirectedNode>> order = new HashMap<>();
for (IElement ie : node.getIncomingEdges()) {
DirectedEdge e = (DirectedEdge) ie;
DirectedNode n = e.getSrc();
if (richClub.containsKey(n.getOutDegree() + 1)
&& richClub.get(n.getOutDegree() + 1).contains(n)) {
this.edgesBetweenRichClub--;
min = Math.min(min, n.getOutDegree());
max = Math.max(max, n.getOutDegree());
richClub.get(n.getOutDegree() + 1).remove(n);
if (richClub.get(n.getOutDegree() + 1).isEmpty()) {
richClub.remove(n.getOutDegree() + 1);
}
if (richClub.containsKey(n.getOutDegree())) {
richClub.get(n.getOutDegree()).add(n);
} else {
richClub.put(n.getOutDegree(), new LinkedList<Node>());
richClub.get(n.getOutDegree()).add(n);
}
if (order.containsKey(n.getOutDegree())) {
order.get(n.getOutDegree()).add(n);
} else {
order.put(n.getOutDegree(), new LinkedList<DirectedNode>());
order.get(n.getOutDegree()).add(n);
}
} else if (nodesSortedByDegree.containsKey(n.getOutDegree() + 1)
&& nodesSortedByDegree.get(n.getOutDegree() + 1).contains(n)) {
nodesSortedByDegree.get(n.getOutDegree() + 1).remove(n);
if (nodesSortedByDegree.get(n.getOutDegree() + 1).isEmpty()) {
nodesSortedByDegree.remove(n.getOutDegree() + 1);
}
if (nodesSortedByDegree.containsKey(n.getOutDegree())) {
nodesSortedByDegree.get(n.getOutDegree()).add(n);
} else {
nodesSortedByDegree.put(n.getOutDegree(), new LinkedList<Node>());
nodesSortedByDegree.get(n.getOutDegree()).add(n);
}
} else {
System.out.println("f**k");
}
}
for (int i = min; i <= max; i++) {
boolean f = false;
if (f) {
break;
}
if (!order.containsKey(i)) {
continue;
}
for (DirectedNode n1 : order.get(i)) {
int big = getBiggest();
if (i >= big) {
f = true;
break;
}
// changes for firstNode of Rest
DirectedNode firstNode = (DirectedNode) this.nodesSortedByDegree.get(big).removeFirst();
if (this.nodesSortedByDegree.get(firstNode.getOutDegree()).isEmpty()) {
this.nodesSortedByDegree.remove(firstNode.getOutDegree());
}
addToRichClub(firstNode);
// Changes for src node for richclub
this.richClub.get(i).remove(n1);
if (this.richClub.get(i).isEmpty()) {
this.richClub.remove(i);
}
addNodeToRest(n1);
// calculate changes for richclub connectivity
for (IElement ie : n1.getEdges()) {
DirectedEdge edge = (DirectedEdge) ie;
DirectedNode n2 = (DirectedNode) edge.getDifferingNode(n1);
if (this.richClub.containsKey(n2.getOutDegree())
&& this.richClub.get(n2.getOutDegree()).contains(n2)) {
this.edgesBetweenRichClub--;
}
}
for (IElement ie : firstNode.getEdges()) {
DirectedEdge edge = (DirectedEdge) ie;
DirectedNode n2 = (DirectedNode) edge.getDifferingNode(firstNode);
if (this.richClub.containsKey(n2.getOutDegree())
&& this.richClub.get(n2.getOutDegree()).contains(n2)) {
this.edgesBetweenRichClub++;
}
}
}
}
if (this.richClub.containsKey(node.getOutDegree())
&& this.richClub.get(node.getOutDegree()).contains(node)) {
int degree = ((DirectedNode) node).getOutDegree();
// changes for firstNode of Rest
DirectedNode firstNode =
(DirectedNode) this.nodesSortedByDegree.get(getBiggest()).removeFirst();
if (this.nodesSortedByDegree.get(firstNode.getOutDegree()).isEmpty()) {
this.nodesSortedByDegree.remove(firstNode.getOutDegree());
}
addToRichClub(firstNode);
// Changes for src node for richclub
this.richClub.get(degree).remove(node);
if (this.richClub.get(degree).isEmpty()) {
this.richClub.remove(degree);
}
// calculate changes for richclub connectivity
for (IElement ie : node.getOutgoingEdges()) {
DirectedEdge edge = (DirectedEdge) ie;
DirectedNode n2 = (DirectedNode) edge.getDifferingNode(node);
if (this.richClub.containsKey(n2.getOutDegree())
&& this.richClub.get(n2.getOutDegree()).contains(n2)) {
this.edgesBetweenRichClub--;
}
}
for (IElement ie : firstNode.getEdges()) {
DirectedEdge edge = (DirectedEdge) ie;
DirectedNode n2 = (DirectedNode) edge.getDifferingNode(firstNode);
if (this.richClub.containsKey(n2.getOutDegree())
&& this.richClub.get(n2.getOutDegree()).contains(n2)) {
this.edgesBetweenRichClub++;
}
}
} else {
int degree = ((DirectedNode) node).getOutDegree();
this.nodesSortedByDegree.get(degree).remove(node);
if (this.nodesSortedByDegree.get(degree).isEmpty()) {
this.nodesSortedByDegree.remove(degree);
}
}
return true;
}
private void directedDelete(DirectedNode r, DirectedEdge e) {
HashMap<Node, Node> parent = this.parents.get(r);
HashMap<Node, Integer> height = this.heights.get(r);
DirectedNode src = e.getSrc();
DirectedNode dst = e.getDst();
// if the source or dst or edge is not in tree do nothing
if (height.get(src) == Integer.MAX_VALUE
|| height.get(dst) == Integer.MAX_VALUE
|| dst.equals(r)
|| !parent.get(dst).equals(src)) {
return;
}
// Queues and data structure for tree change
HashSet<DirectedNode> uncertain = new HashSet<DirectedNode>();
HashSet<DirectedNode> changed = new HashSet<DirectedNode>();
PriorityQueue<QueueElement<DirectedNode>> q = new PriorityQueue<QueueElement<DirectedNode>>();
q.add(new QueueElement<DirectedNode>(dst, height.get(dst)));
uncertain.add(dst);
parent.remove(dst);
while (!q.isEmpty()) {
QueueElement<DirectedNode> qE = q.poll();
DirectedNode w = qE.e;
int key = qE.distance;
// find the new shortest path
int dist = Integer.MAX_VALUE;
ArrayList<DirectedNode> minSettled = new ArrayList<DirectedNode>();
ArrayList<DirectedNode> min = new ArrayList<DirectedNode>();
for (IElement iEgde : w.getIncomingEdges()) {
DirectedWeightedEdge edge = (DirectedWeightedEdge) iEgde;
IntWeight eWeight = (IntWeight) edge.getWeight();
DirectedNode z = edge.getSrc();
if (changed.contains(z) || height.get(z) == Integer.MAX_VALUE) {
continue;
}
if (height.get(z) + (int) eWeight.getWeight() < dist) {
min.clear();
minSettled.clear();
min.add(z);
if (!uncertain.contains(z)) minSettled.add(z);
dist = height.get(z) + (int) eWeight.getWeight();
continue;
}
if (height.get(z) + (int) eWeight.getWeight() == dist) {
min.add(z);
if (!uncertain.contains(z)) minSettled.add(z);
continue;
}
}
boolean noPossibleNeighbour =
(key >= breakLoop && dist > breakLoop)
|| (min.isEmpty() && (!uncertain.contains(w) || (key == dist)));
// no neighbour found
if (noPossibleNeighbour) {
if (height.get(w) != Integer.MAX_VALUE) apsp.decr(height.get(w));
height.put(w, Integer.MAX_VALUE);
parent.remove(w);
continue;
}
if (uncertain.contains(w)) {
if (key == dist) {
if (minSettled.isEmpty()) {
parent.put(w, min.get(0));
} else {
parent.put(w, minSettled.get(0));
}
if (height.get(w) != Integer.MAX_VALUE) apsp.decr(height.get(w));
apsp.incr(dist);
height.put(w, dist);
for (IElement iEgde : w.getOutgoingEdges()) {
DirectedWeightedEdge edge = (DirectedWeightedEdge) iEgde;
IntWeight iEdgeWeight = (IntWeight) edge.getWeight();
DirectedNode z = edge.getDst();
if (height.get(z) > dist + (int) iEdgeWeight.getWeight()) {
q.remove(new QueueElement<DirectedNode>(z, dist + (int) iEdgeWeight.getWeight()));
q.add(new QueueElement<DirectedNode>(z, dist + (int) iEdgeWeight.getWeight()));
}
}
} else {
changed.add(w);
q.add(new QueueElement<DirectedNode>(w, dist));
uncertain.remove(w);
for (IElement iEgde : w.getOutgoingEdges()) {
DirectedEdge edge = (DirectedEdge) iEgde;
DirectedNode z = edge.getDst();
if (parent.get(z) == w) {
parent.remove(z);
uncertain.add(z);
q.add(new QueueElement<DirectedNode>(z, height.get(z)));
}
}
}
continue;
}
if (dist > key) {
q.add(new QueueElement<DirectedNode>(w, dist));
continue;
}
if (minSettled.isEmpty()) {
parent.put(w, min.get(0));
} else {
parent.put(w, minSettled.get(0));
}
changed.remove(w);
if (height.get(w) != Integer.MAX_VALUE) apsp.decr(height.get(w));
apsp.incr(dist);
height.put(w, dist);
for (IElement iEgde : w.getOutgoingEdges()) {
DirectedWeightedEdge edge = (DirectedWeightedEdge) iEgde;
IntWeight eWeight = (IntWeight) edge.getWeight();
DirectedNode z = edge.getDst();
if (height.get(z) > dist + (int) eWeight.getWeight()) {
q.remove(new QueueElement<DirectedNode>(z, dist + (int) eWeight.getWeight()));
q.add(new QueueElement<DirectedNode>(z, dist + (int) eWeight.getWeight()));
}
}
}
}
