Hi I have been trying to implement the DBSCAN algorithm for Neo4j, but am running into serious performance bottlenecks. I'll describe the implementation then ask for help.

I discretized the possible epsilon values and put counts of the number of neighbors under each discretization in each node in order to be able to retrieve all of the core nodes in one query.

```
START a = node(*)
WHERE a.rel<cutoff threshold>! >= {minp}
RETURN a
```

This part is fast, the part that isn't fast is the follow up query :

```
START a = node({i})
SET a.label<cutoff threshold>_<minpoints> = {clust}
WITH a
MATCH a -[:'|'.join(<valid distance relations>)]- (x)
WHERE not(has(x.label<cutoff threshold>_<minpoints>))
WITH x
SET x.label<cutoff threshold>_<minpoints>={clust}
RETURN x
```

I then pick a core node to start from, and as long as there are still core node neighbors, run the above query to label their neighbors.

I think the problem is that my graph has very different levels of sparsity - starting from only weak similarity it is almost fully connected, with ~50M relations between ~10k nodes, whereas at strong similarity there are as few as ~20k relations between ~10k nodes (or fewer). No matter what, it is always REALLY slow. What is the best way for me to handle this? Is it to index on relationship type and starting node? I haven't been able to find any resources on this problem, and surprisingly there isn't already an implementation since this is a pretty standard graph algorithm. I could use scikit.learn but then I would be restricted to in-memory distance matricies only :(