# Efficient way for finding the nodes having maximum degree of separation in a connected graph

I am working on a graph library.It has to have a function which finds the two nodes which are most separated i.e they maximum number of the minimum number of nodes required to traverse before reaching the target node from the source node.

One naive way would be to calculate the degree of separation from each node to all other node and repeat the same for every node.

The complexity of this turns out to be `O(n^2)`.

Any better solution to this problem ?

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The complexity of your approach is O(n*m), not the one you state. –  Ivaylo Strandjev Jan 15 '13 at 10:57
@IvayloStrandjev : there are n nodes and you need to check its degree of separation from every other vertex. This will be done for all n vertices.hence n^2. –  jairaj Jan 15 '13 at 11:01
@jairaj How do you manage to compute the degree of separation in O(1)? –  Khaur Jan 15 '13 at 11:02
@Khaur: Agreed its not order of 1 but would be very less ,in fact equal to number of nodes in the path.Assuming (en.wikipedia.org/wiki/Six_degrees_of_separation) six degrees of separation to be true it will be at most 6, a constant which can well be neglected. –  jairaj Jan 15 '13 at 11:05
@Dukeling The OP refers to degree of separation, i.e. unit cost for edges. There is no need for Dijkstra's algorithm, a simple BFS (`O(|E|)`) is sufficient. –  Khaur Jan 15 '13 at 13:10

Use Floyd-Warshall algorithm to find all pairs shortest path. Then iterate through results and find one with the longest path.

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Without any assumptions on the graph, Floyd-Warshall is the way to go.

If your graph is sparse (i.e. it has a relatively few edges by node, or `|E|<<|N|^2`), then Johnson is likely to be faster.

With unit edge weight (which seems to be your case), a naïve approach by computing the furthest node (with BFS) for each node leads to `O(|N|.|E|)`. This can probably be improved further, but I don't see a way right now.

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For completeness, Floyd-Warshall does assume that there are no negative cycles in the graph, but this is a rare case, and IMO mentioning it in the answer would have reduced its clarity. –  Khaur Jan 15 '13 at 13:28
@Kaganar I did notice it if you read my answer thoroughly, that's why I posted a new answer even though an existing one was suggesting Floyd-Warshall already. –  Khaur Jan 15 '13 at 16:44