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This is an interview question that I recently found on Internet:

How would you find the degree of separation between two person on Facebook? Discuss different ideas, algorithms, and trade-offs. (Definition of degree of saparation: http://en.wikipedia.org/wiki/Six_degrees_of_separation)

Here's what I think about it:

The candidate algorithms that I can think of are: breadth-first search(BFS), depth-first search(DFS), depth-limited search(DLS), iterative-deepening search(IDS).

First, DFS should be taken of consideration. It is very likely that even when the two persons are connected (i.e. degree of separation = 1), the algorithm may keep searching along a wrong path for a long time.

BFS is guaranteed to find the minimum degree of separation (since the graph is not weighted). Assume the max branching factor is b and the actual degree of separation between two target persons is d, both time complexity and space complexity would be O(b^d).

Since the max possible degree of separation is unknown (although it should not be too higher than 6), it may not be a good idea to use DLS. However, IDS seems to be a better idea than BFS - it's time complexity is also O(b^d) (although the actual time cost a bit higher than BFS due to repeated visiting of intermediate nodes), while its space complexity is O(bd), which is a lot better than O(b^d).

After all, I would choose IDS. Is that an acceptable answer in an interview? Did I mid any mistake in the above inference? Or are there any better solutions that I missed?

Thanks in advance.

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2 Answers 2

up vote 4 down vote accepted

A better solution might be to start a BFS from both nodes simultaneously. Something like the following pseudo-code:

nodes1 = (A);
nodes2 = (B);
d = 1;
loop {
    nodes1 = successors(nodes1);
    if (intersects(nodes1, nodes2)) {
        return d;
    }
    d += 1;
    nodes2 = successors(nodes2);
    if (intersects(nodes2, nodes1)) {
        return d;
    }
    d += 1;
}

The time complexity of this algorithm is about O(m ^ (d/2)) where m is the maximum degree of all nodes and d is the maximum distance. Compared to a simple BFS with O(m ^ d), this can be a lot faster in large graphs.

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I haven't thought about bidirectional search before. Thanks for mention that. –  quantumrose Mar 11 '13 at 1:32

If you're looking for the degree of separation between two specific people, I'd use Dijkstra's algorithm, which will find the shortest paths from a chosen source to all reachable nodes.

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1  
What is the difference between Dijkstra's algorithm and BFS quantumrose describes if the edges are unweighted? –  angelatlarge Mar 9 '13 at 22:42
    
Probably nothing. But an interviewer asking this question is likely looking to see if the candidate has a basic knowledge of graph algorithms, i.e. if "dijkstra" and "prim" can roll easily off the tongue. –  phs Mar 9 '13 at 22:44
    
Maybe A* also then? –  angelatlarge Mar 9 '13 at 22:46
    
@angelatlarge if use A*, how to find a appropriate heuristic? –  quantumrose Mar 9 '13 at 22:53
3  
Fair question. In Facebook, I'd consider a combination of educational institutions, places worked at, hobbies/interests, maybe geographic locations, and maybe familial relations. It seems reasonable that you are likelier to find fewer degrees of separation by going through people with common interests. Specifically, if I start with person A and try to find the mindistance to person B, I should first search through people who have more in common with B. Though now that I think about it, this is not correct: you will have to search everything to ensure you have the shortest distance anyway. –  angelatlarge Mar 9 '13 at 22:59

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