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I've successfully implemented Bellman-Ford to find the distance of the shortest path when edges have negative weights/distances. I've not been able to get it to return all shortest paths (when there are ties for shortest). I managed to get all shortest paths (between a given pair of nodes) with Dijkstra. Is this possible with Bellman-Ford? (just want to know if I'm wasting my time trying)

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Mathematically, I'm not sure this is possible. If all of the edges have cost zero, for example, there are infinitely many possible shortest paths that you can take. Do you want shortest acyclic paths? –  templatetypedef Jul 6 '12 at 21:48
    
Yes, sorry, should have specified that. I'd like to find all shortest acyclic paths between two nodes. –  user1507844 Jul 6 '12 at 21:58

1 Answer 1

up vote 4 down vote accepted

If you alter the second step of the Bellman-Ford algorithm a little bit you can achieve something very similar:

for i from 1 to size(vertices)-1:
   for each edge uv in edges: // uv is the edge from u to v
       u := uv.source
       v := uv.destination
       if u.distance + uv.weight < v.distance:
           v.distance := u.distance + uv.weight
           v.predecessor[] := u
       else if u.distance + uv.weight == v.distance:
           if u not in v.predecessor:
               v.predecessor += u

where v.predecessor is a list of vertices. If the new distance of v equals a path which isn't included yet include the new predecessor.

In order to print all shortest paths you could use something like

procedure printPaths(vertex current, vertex start, list used, string path):
    if current == start:
        print start.id + " -> " + path
    else:
        for each edge ve in current.predecessors:
            if ve.start not in used:
                printPaths(ve.start,start, used + ve.start, ve.start.id + " -> " + path)

Use printPaths(stop,start,stop,stop.id) in order to print all paths.

Note: It is possible to exclude if u not in v.predecessor then v.predecessor += u from the modified algorithm if you remove duplicate elements after the algorithm has finished.

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Thank you that was very helpful. I actually had managed to to do everything except the recursive printPaths procedure, which is really quite simple after looking at it. Is there a way to print all the paths without recursion? In a more general sense, is it always possible to use a loop instead of recursion? –  user1507844 Jul 7 '12 at 11:05
    
Yes, but it's tricky to keep track of used since this is a backtracking algorithm. If you want to create a iterative version you would have to manipulate the used list somehow without creating a infinite loop. There are some crude solutions, for example build a queue[0,...,n-1], where queue[i] contains all possible predecessors of the i level (queue[0] := [stop]) and use a n-dimensional multiindex I to iterate over the queue. But you would have to check whether the current set I is valid. Since you're only using acyclic paths you can then use a list of vertex sets for used. –  Zeta Jul 7 '12 at 12:50

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