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If you have a graph, and need to find the diameter of it (which is the maximum distance between two nodes), how can you do it in O(log v * (v + e)) complexity.

Wikipedia says you can do this using Dijkstra's algorithm with a binary heap. But I don't understand how this works. Can someone explain please?

Or show a pseudocode?

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Dijkstra's algorithm won't find the diameter of the graph; it will just find the distance from some node to each other node in the graph. Is there a resource you have that says that you can use Dijkstra's to do this? –  templatetypedef Mar 26 '13 at 20:03
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cs.stackexchange.com/questions/194/… –  omega Mar 26 '13 at 20:07
    
Nothing in the link says that you should use Dijkstra's to do this. –  templatetypedef Mar 26 '13 at 20:12
    
oh ok, but is there a way to do this in O(log n * (n + e) complexity? –  omega Mar 26 '13 at 20:14
    
Is are the edges weighted? –  MAK Mar 26 '13 at 20:59

7 Answers 7

For a general Graph G=(V,E) there is no O(log V * (V + E)) time complexity algorithm known for computing the diameter. The current best solution is O(V*V*V), e.g., by computing all shortest Paths with Floyd Warshall's Algorithm. For sparse Graphs, i.e. when E is in o(N*N), Johnson's Algorithm gives you with O(V*V*log(V)+V*E) a better time complexity.

If your graph has certain properties like acyclic (Tree) you can get better.

So the bad news is, the Dijkstra won't be enough in the general case...

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First you will need to find the convex hull of the graph (finding it which is O(nh), where h is number of nodes on hull). The points of diameter will lie on the convex hull and thus the problem will reduce to finding the farthest points in h points. Hence, total order will be O(nh+h*h).

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I think the question was related to an abstract graph. Your answer relates to a number of points in the plain and to find the maximum distance between them, which is not the same. For example, the abstract graph does not have to meet the triangle inequality. Also, the total order of your algorithm will be O(nh+hh) which is less then O(nh^3). –  eci Sep 18 '13 at 7:49

I know I'm a year late to the thread, but I don't believe any of these answers are correct. OP mentioned in the comments that the edges are unweighted; in this case, the best algorithm runs in $O(n^{\omega}) \log n$ time (where $\omega$ is the exponent for matrix multiplication; currently upper bounded at $2.373$ by Virginia Williams).

The algorithm exploits the following property of unweighted graphs. Let $A$ be the adjacency matrix of the graph with an added self-loop for each node. Then $(A^k)_{ij}$ is nonzero iff $d(i, j) \le k$. We can use this fact to find the graph diameter by computing $\log n$ values of $A^k$.

Here's how the algorithm works: let $A$ be the adjacency matrix of the graph with an added self loop for each node. Set $M_0 = A$. While $M_k$ contains at least one zero, compute $M_{k+1} = M_{k}^2$.

Eventually, you find a matrix $M_{K}$ with all nonzero entries. We know that $K \le \log n$ by the property discussed above; therefore, we have performed matrix multiplication only $O(\log n)$ times so far. We can now continue by binary searching between $M_{K} = A^{2^K}$ and $M_{K-1} = A^{2^{K-1}}$. Set $B = M_{K-1}$ as follows.

Set DIAMETER = $2^{k-1}$. For $i = (K-2 \dots 0)$, perform the following test:

Multiply $B$ by $M_{i}$ and check the resulting matrix for zeroes. If we find any zeroes, then set $B$ to this matrix product, and add $2^i$ to DIAMETER. Otherwise, do nothing.

Finally, return DIAMETER.

As a minor implementation detail, it might be necessary to set all nonzero entries in a matrix to $1$ after each matrix multiplication is performed, so that the values don't get too large and unwieldy to write down in a small amount of time.

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Nice approach. A few minor points: (1) I think that there can still be zero entries in B after i reaches 0, and in that case the diameter is 2^K (i.e. the original squaring loop happened to find the smallest diameter). (2) You could use bitwise AND and OR instead of multiplication and addition respectively to ensure that cell values don't get unwieldy. (3) After log2(n) squarings of the adjacency matrix, either all entries are nonzero or the graph was not connected in the first place. –  j_random_hacker Feb 19 at 12:58

Boost BGL has a small extended deque class named "rcm_queue" with which the eccentricity of a vertex can be found by a simple breadth first search, meaning a complexity of O(E).

http://www.boost.org/doc/libs/1_54_0/boost/graph/detail/sparse_ordering.hpp

As the diameter can be calculated by going over the eccentricity of all vertices, one can calculate the diameter of a graph with a complexity of O(V*E).

Especially for a very sparse graph with a deg(G) <<< V, I didn't find anything with better runtime.

I didn't look into the Floyd Warshall algorithm. I was just dealing with a graph with > 5.000.000 vertices but with a highest degree of any vertex of less than 15 and thought, this should probably outperform an algorithm with V*V*log(V) complexity.

EDIT

For sure, this only works with an undirected graph and not negative weighted (or even unweighted only? I'm not sure atm)

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Actually, if the graph is extremely large, you will need to use Dijkstra's algorithm in order to find the shortest distance. So it depends on how many nodes the OP's graph has.

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As eci mentioned, one of the solutions is to use the Floyd-Warshall algorithm. If you need the code for it, a C++ version of it can be found here.

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This can only happen with an unweighted graph. Where bfs gives shortest path tree in o(v+e) and you repeat the same for v sources.

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This does not provide an answer to the question. To critique or request clarification from an author, leave a comment below their post - you can always comment on your own posts, and once you have sufficient reputation you will be able to comment on any post. –  Adam S Jul 17 '14 at 16:27
    
BFS definitely does not work in o(v + e) (what are v and e anyway?). O(V + E) yes. But then Dijkstra's algorithm is also O(V + E) and works on weighted graphs, so there is no difference. And remember there is still V vertices, so how do you expect to reduce it to the log(V) factor? (-1) –  Jan Hudec Oct 24 '14 at 15:04

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