Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I made a slight modification to Bellman-Ford so that it only does "useful" relaxes. That is, relaxations that meant d(v) was updated.

define Relax(u, v):
 if d(v) > d(u) + w(u,v)         //w(u,v) = weight of edge u->v
    d(v) = d(u) + w(u,v)

INIT // our usual initialization.
Queue Q
Q ← s // Q holds vertices whose d(v) values have been updated recently.
While (Q not empty)
  u ← Frontof(Q);
  for each neighbor v of u
    Relax(u, v)

    if d(v) was updated by Relax and v not in the Q  //Here's where we're a bit smarter
        ADD v to End of Q.                           //since we add to Q if 
                                                     //the relaxation changed d(v)

Now, if all shortest paths have at most k arcs. Then the worst-case runtime is O(V*k) since we only go through k arcs in this smart version. This is a bit faster than the original O(V*E) since |k| < |E|

Can anyone please tell me of a type of graph for which this improved version is no better than the original Bellman-Ford algorithm? That is, for which the best-case performance is O(V*E)

share|improve this question

1 Answer 1

Consider the graph where all edges have negative weight. In this graph, vertex u will be added to Q multiple times if it has multiple incomming edges.

The statement |k| < |E| is incorect: if there is a negative loop in graph, then k is infinite

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.