# Graph Algorithm / Disjoint Set

I am trying to solve this problem but unable to do it fast.

In short - we have a graph (directed) and we want to find out from which node (a set of nodes to select from is given) we can visit the most nodes. A straightforward implementation will be to run DFS/BFS from every node and see how many we can visit. But that it too slow as there are over 5000 nodes in the graph. Running 5000 BFS/DFS will be take very long time.

On the other hand I also get a feeling that this problem may have something to do with Disjoint Set data structure? But I am unable to formulate it that way as in my disjoint set implementation some of the mentioned rules.

Can someone give a hint as to how to approach this problem?

-
The problem you describe here is a lot more general to the problem you linked to. – Niklas B. Mar 17 '14 at 17:58
@Niklas - Sorry I didn't get it ! The explanation that I gave is just what I came up with to solve it but it's giving TLE straightaway. Do you think Amit's description is correct? – VVV Mar 17 '14 at 18:14
@Dukeling - Ok will modify it. – VVV Mar 17 '14 at 18:15
@VVV: amit's answer assumes a general graph, while the graph in the problem is a DAG. Also, amit's algorithm has a straightforward O(k(n + m)) implementation which you said was too slow. The problem doesn't say how large k can get, which is pretty bad. – Niklas B. Mar 17 '14 at 18:27
Thanks Niklas, can you elaborate on Amit's step 3? I have written my understanding below the answer. Also I did manage to implement the Dominating set algorithm for social advertising problem, even thought it took me 11 attempts and 5 hours :-). – VVV Mar 17 '14 at 18:32

1. Find Strongly Connected Components (SCC) using Tarjan's algorithm (O(V+E)), and create the SCC graph.
2. Topologically sort the resulting SCC graph (it is a DAG).
3. From last to first, find the number of nodes reachable from each component.
4. Choose a node which is in a SCC that can reach maximal number of nodes.

Step 3 - elaboration:

(For clarification reasons I will denote a vertex in the original graph as 'node', and a vertex in the SCC graph as 'vertex').

In step 3 you want to find the number of nodes that are reachable from each vertex of your SCC. This can be done by explicitly finding this set, or by finding only the number of nodes:

1. Explicitly finding the set of nodes reachable from each vertex:
This is pretty much straight forward, each vertex has an associated set of nodes, and you need to find the set associated to each vertex by doing a union on all edges on your SCC graph leading from the current vertex.
2. Using inclusion/exclusion to find the number of nodes reachable:
Inclusion/exclusion is a technique used to count size of union of sets where the sets might have repeats in them. For example, if you have 2 sets, the size of their union is `|A|+|B|- |A[intersection]B|`.
For 3 sets A,B,C: `|A|+|B|+|C|-|A[intersrction]B| - |A[intersection]C| - |B[intersection]C + |A[intersection]B[intersection]C|`
(and so on)
Using inclusion/exclusion - the sets are the previous nodes, and the intersections are based on 2 different vertices that will later link themselves to the same vertex.
-
Here's another idea: instead of sorting and calculating the number of reachable vertices in reverse topological order, you could just keep track of the number of vertices in each SCC, then for each DAG in the DAG forest of SCCs sum up all those values and chose a vertex from the sink of the DAG with the highest number of vertices in it. Not asymptotically faster, but maybe a bit harder to get wrong. – G. Bach Mar 17 '14 at 14:47
@amit: Sorry even after thinking about some more time, I can't see how inclusion/exclusion would help. If you have outdegree > log (n+m), this will take more time than a single DFS, or did I miss something? Uniting sets via merge-by-rank is probably the way to go, but it seems like we need persistent search trees for that – Niklas B. Mar 17 '14 at 18:31
@NiklasB. Inclusion/exclusion will be `O(m^2)`, and explicit sets will be O(n*m) to my understanding - per vertex, where `n` is the number of nodes in the original graph and `m` is the number of vertices in the SCC graph. The inclusion exclusion needs to go over at most all links in the SCC graph from the current vertex to the end, which is O(m^2) worst case, and for each such link the computation done is O(1). However, note that this graph is likely to be much smaller than the original and the worst case is not very likely in average case. (continue in next comment) – amit Mar 17 '14 at 18:56
Let's assume that the node that has k nodes after it has in average k/2 edges (can modify for any other k). Assuming uniform distribution, the mean distance from this node will also be k/2. This yields to the fact that each of these have k/4 edges. By continuing it, you get k/2+k/4+...+1 < k, and the number of vertices you need to go over is O(m) according to this analysis, which in turn will lead to O(m*n) total computation time. Much better than O(n^3) provided by BFS from each node. – amit Mar 17 '14 at 18:57
In the problem the graph is a DAG, so m = n with your notation. I have to admit I don't see how you are going to achieve O(n^2), since the only method that I know to apply inclusion/exclusion here is exponential to the outdegree of the node we are currently looking at (I would have to look at every subset of adjacent neighbors). Also the worst case will most definitely occur somewhere in the test cases – Niklas B. Mar 17 '14 at 19:00