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I tried googling it up, but nothing of value pops up.

The graph:

  • is undirected.
  • is represented as directed graph with double edges.
  • may contain edges with negative weights.

I know I can use Bellman-Ford to solve this in the directed case, but with undirected edges it will just return single edges (2-cycles) as its output. I need to find a cycle of size > 2.

Also, the algorithm is supposed to have run-time complexity O(V*E) and memory complexity O(V).

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"My method that uses Ford-Bellman algorithm doesn't work (obviously) as it returns single edges" This is not at all obvious, so please elaborate. Bellman-Ford can definitely be used to solve this problem. –  Niklas B. Mar 18 '14 at 17:45
    
I don't have access to that function. It doesn't work properly for undirected graphs and I should either make my own similar method or use another algorithm. I tried with a sheet of paper and I can't see how can it work. I got stuck when two vertices kinda "pointed" at each other and were lowering weight every iteration. –  lavsprat Mar 18 '14 at 17:48
    
Your space-time constraints seem impossible. –  Jan Dvorak Mar 18 '14 at 17:54
    
"I don't have access to that function" You seem to have to point out what you are allowed and what you are not allowed to do. Bellman-Ford can do it and it is most definitely the intended solution –  Niklas B. Mar 18 '14 at 17:57
    
@JanDvorak Those are exactly the Bellman-Ford bounds. Not sure why that seems impossible to you –  Niklas B. Mar 18 '14 at 17:58

1 Answer 1

Looking at the algorithm in http://en.wikipedia.org/wiki/Bellman%E2%80%93Ford_algorithm, in step 2 you consider using every edge (u, v) to to find a shorter path to v and, if you see an improvement, you record it by setting predecessor[v] = u. This means that at each stage you know the predecessor of each node - so you can eliminate length two cycles by checking that predecessor[u] != v before you set predecessor[v] = u.

By eliminating these cycles you change the invariant of the induction - at each stage you are now finding the shortest route to u from s with at most i edges which does not include any length 2 cycles.

A cycle of length 3 or greater reachable from the source should still show up - the check for negative cycles looks for apparent improvements after you should have found every shortest path for lengths up to that necessary to visit every vertex.

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Unfortunately, your solution doesn't work. Take a look at THIS. Pink one is my starting point, blue numbers represent edges' weights, green arrows point at vertices' predecessors. –  lavsprat Mar 19 '14 at 14:06
    
@lavsprat You need an extra round to detect cycles, and you didn't check whether the relaxation you made would create a length-2 cycle. –  David Eisenstat Mar 19 '14 at 15:36
    
I agree with David, and note that this follows the Wikipedia algorithm, except that I should have pointed out that the check to avoid 2-cycles needs to go into their step (3) as well as their step (2). I believe that the total number of rounds is the same with and without 2-cycle checking because for every undirected graph with a -ve cycle you can construct a directed graph without 2-cycles but with the same -ve cycle and the same timing for cycle detection by allowing only the directions needed to create and observe the cycle. –  mcdowella Mar 19 '14 at 19:55

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