I am trying to implement the above community detection algorithm in Java, and while I have access to C++ code, and the original paper - I can't make it work at all. My major issue is that I don't understand the purpose of the code - i.e. how the algorithm works. In practical terms, my code gets stuck in what seems to be an infinite loop at `mergeBestQ`

, the list `heap`

seems to be getting larger on each iteration (as I would expect from the code), but the value of `topQ`

is always returning the same value.

The graph I am testing this on is quite large (300,000 nodes, 650,000 edges). The original code I am using for my implementation is from the SNAP library (https://github.com/snap-stanford/snap/blob/master/snap-core/cmty.cpp). What would be great is if someone could explain to me the intuition of the algorithm, it seems to be initially setting each node to be in it's own community, then recording the modularity value (whatever that is) of each pair of connected nodes in the graph, then finding the pair of nodes which have the highest modularity and moving them to the same community. In addition, if someone could provide some mid level pseudo code, that would be great. Here is my implementation thus far, I have tried to keep it in one file for the sake of brevity, however CommunityGraph and CommunityNode are elsewhere (should not be required). Graph maintain a list of all nodes and each node maintains a list of its connections to other nodes. When running it never gets past the line `while(this.mergeBestQ()){}`

UPDATE - found several bugs in my code after a thorough review. The code now completes VERY quickly, but doesnt fully implement the algorithm, for example of the 300,000 nodes in the graph, it states there are approximately 299,000 communities (i.e. roughly 1 node per community). I have listed the updated code below. /// Clauset-Newman-Moore community detection method. /// At every step two communities that contribute maximum positive value to global modularity are merged. /// See: Finding community structure in very large networks, A. Clauset, M.E.J. Newman, C. Moore, 2004 public class CNMMCommunityMetric implements CommunityMetric{ private static class DoubleIntInt implements Comparable{ public double val1; public int val2; public int val3; DoubleIntInt(double val1, int val2, int val3){ this.val1 = val1; this.val2 = val2; this.val3 = val3; }

```
@Override
public int compareTo(DoubleIntInt o) {
//int this_sum = this.val2 + this.val3;
//int oth_sum = o.val2 + o.val3;
if(this.equals(o)){
return 0;
}
else if(val1 < o.val1 || (val1 == o.val1 && val2 < o.val2) || (val1 == o.val1 && val2 == o.val2 && val3 < o.val3)){
return 1;
}
else{
return -1;
}
//return this.val1 < o.val1 ? 1 : (this.val1 > o.val1 ? -1 : this_sum - oth_sum);
}
@Override
public boolean equals(Object o){
return this.val2 == ((DoubleIntInt)o).val2 && this.val3 == ((DoubleIntInt)o).val3;
}
@Override
public int hashCode() {
int hash = 3;
hash = 79 * hash + this.val2;
hash = 79 * hash + this.val3;
return hash;
}
}
private static class CommunityData {
double DegFrac;
TIntDoubleHashMap nodeToQ = new TIntDoubleHashMap();
int maxQId;
CommunityData(){
maxQId = -1;
}
CommunityData(double nodeDegFrac, int outDeg){
DegFrac = nodeDegFrac;
maxQId = -1;
}
void addQ(int NId, double Q) {
nodeToQ.put(NId, Q);
if (maxQId == -1 || nodeToQ.get(maxQId) < Q) {
maxQId = NId;
}
}
void updateMaxQ() {
maxQId=-1;
int[] nodeIDs = nodeToQ.keys();
double maxQ = nodeToQ.get(maxQId);
for(int i = 0; i < nodeIDs.length; i++){
int id = nodeIDs[i];
if(maxQId == -1 || maxQ < nodeToQ.get(id)){
maxQId = id;
maxQ = nodeToQ.get(maxQId);
}
}
}
void delLink(int K) {
int NId=getMxQNId();
nodeToQ.remove(K);
if (NId == K) {
updateMaxQ();
}
}
int getMxQNId() {
return maxQId;
}
double getMxQ() {
return nodeToQ.get(maxQId);
}
};
private TIntObjectHashMap<CommunityData> communityData = new TIntObjectHashMap<CommunityData>();
private TreeSet<DoubleIntInt> heap = new TreeSet<DoubleIntInt>();
private HashMap<DoubleIntInt,DoubleIntInt> set = new HashMap<DoubleIntInt,DoubleIntInt>();
private double Q = 0.0;
private UnionFind uf = new UnionFind();
@Override
public double getCommunities(CommunityGraph graph) {
init(graph);
//CNMMCommunityMetric metric = new CNMMCommunityMetric();
//metric.getCommunities(graph);
// maximize modularity
while (this.mergeBestQ(graph)) {
}
// reconstruct communities
HashMap<Integer, ArrayList<Integer>> IdCmtyH = new HashMap<Integer, ArrayList<Integer>>();
Iterator<CommunityNode> ns = graph.getNodes();
int community = 0;
TIntIntHashMap communities = new TIntIntHashMap();
while(ns.hasNext()){
CommunityNode n = ns.next();
int r = uf.find(n);
if(!communities.contains(r)){
communities.put(r, community++);
}
n.setCommunity(communities.get(r));
}
System.exit(0);
return this.Q;
}
private void init(Graph graph) {
double M = 0.5/graph.getEdgesList().size();
Iterator<Node> ns = graph.getNodes();
while(ns.hasNext()){
Node n = ns.next();
uf.add(n);
int edges = n.getEdgesList().size();
if(edges == 0){
continue;
}
CommunityData dat = new CommunityData(M * edges, edges);
communityData.put(n.getId(), dat);
Iterator<Edge> es = n.getConnections();
while(es.hasNext()){
Edge e = es.next();
Node dest = e.getStart() == n ? e.getEnd() : e.getStart();
double dstMod = 2 * M * (1.0 - edges * dest.getEdgesList().size() * M);//(1 / (2 * M)) - ((n.getEdgesList().size() * dest.getEdgesList().size()) / ((2 * M) * (2 * M)));// * (1.0 - edges * dest.getEdgesList().size() * M);
dat.addQ(dest.getId(), dstMod);
}
Q += -1.0 * (edges*M) * (edges*M);
if(n.getId() < dat.getMxQNId()){
addToHeap(createEdge(dat.getMxQ(), n.getId(), dat.getMxQNId()));
}
}
}
void addToHeap(DoubleIntInt o){
heap.add(o);
}
DoubleIntInt createEdge(double val1, int val2, int val3){
DoubleIntInt n = new DoubleIntInt(val1, val2, val3);
if(set.containsKey(n)){
DoubleIntInt n1 = set.get(n);
heap.remove(n1);
if(n1.val1 < val1){
n1.val1 = val1;
}
n = n1;
}
else{
set.put(n, n);
}
return n;
}
void removeFromHeap(Collection<DoubleIntInt> col, DoubleIntInt o){
//set.remove(o);
col.remove(o);
}
DoubleIntInt findMxQEdge() {
while (true) {
if (heap.isEmpty()) {
break;
}
DoubleIntInt topQ = heap.first();
removeFromHeap(heap, topQ);
//heap.remove(topQ);
if (!communityData.containsKey(topQ.val2) || ! communityData.containsKey(topQ.val3)) {
continue;
}
if (topQ.val1 != communityData.get(topQ.val2).getMxQ() && topQ.val1 != communityData.get(topQ.val3).getMxQ()) {
continue;
}
return topQ;
}
return new DoubleIntInt(-1.0, -1, -1);
}
boolean mergeBestQ(Graph graph) {
DoubleIntInt topQ = findMxQEdge();
if (topQ.val1 <= 0.0) {
return false;
}
// joint communities
int i = topQ.val3;
int j = topQ.val2;
uf.union(i, j);
Q += topQ.val1;
CommunityData datJ = communityData.get(j);
CommunityData datI = communityData.get(i);
datI.delLink(j);
datJ.delLink(i);
int[] datJData = datJ.nodeToQ.keys();
for(int _k = 0; _k < datJData.length; _k++){
int k = datJData[_k];
CommunityData datK = communityData.get(k);
double newQ = datJ.nodeToQ.get(k);
//if(datJ.nodeToQ.containsKey(i)){
// newQ = datJ.nodeToQ.get(i);
//}
if (datI.nodeToQ.containsKey(k)) {
newQ = newQ + datI.nodeToQ.get(k);
datK.delLink(i);
} // K connected to I and J
else {
newQ = newQ - 2 * datI.DegFrac * datK.DegFrac;
} // K connected to J not I
datJ.addQ(k, newQ);
datK.addQ(j, newQ);
addToHeap(createEdge(newQ, Math.min(j, k), Math.max(j, k)));
}
int[] datIData = datI.nodeToQ.keys();
for(int _k = 0; _k < datIData.length; _k++){
int k = datIData[_k];
if (!datJ.nodeToQ.containsKey(k)) { // K connected to I not J
CommunityData datK = communityData.get(k);
double newQ = datI.nodeToQ.get(k) - 2 * datJ.DegFrac * datK.DegFrac;
datJ.addQ(k, newQ);
datK.delLink(i);
datK.addQ(j, newQ);
addToHeap(createEdge(newQ, Math.min(j, k), Math.max(j, k)));
}
}
datJ.DegFrac += datI.DegFrac;
if (datJ.nodeToQ.isEmpty()) {
communityData.remove(j);
} // isolated community (done)
communityData.remove(i);
return true;
}
}
```

UPDATE:the currently listed code is fairly quick, and has half the memory usage compared to the "quickest" solution, while only being ~5% slower. the difference is in the use of hashmap + treest vs priority queue, and ensuring only a single object for a given i, j pair exists at any time.