In a Weighted Directed Graph G (with positive weights), with n vertex and m edges, we want to calculate the shortest path from vertex 1 to other vertexes. we use 1-dimensional array D[1..n], and D[1]=0 and others filled with +infinity. for updating the array we just permit to use Realx(u, v)

if D[v] > D[u] + W(u, v) then D(v):=D(u)+W(u,v) 

in which W(u, v) is the weight of u-->v edge. how many time we must call the Relax function to ensure that for each vertex u, D[u] be equals to length of shortest path from vertex 1 to u.

Solution: i think this is Bellman-Ford and m*n times we must call.

In Dijkstra and Bellman-Ford and others, we have Relax function. How do we detect which of them?

Cited from CLRS Book:

The algorithms in this chapter differ in how many times they relax each edge and the order in which they relax edges. Dijkstra’s algorithm and the shortest-paths algorithm for directed acyclic graphs relax each edge exactly once. The Bellman-Ford algorithm relaxes each edge |V|-1 times.

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  • Until it stops changing – stark Feb 18 '15 at 18:29
  • Dear @stark, it means m*n, m+n, m or n? – Ali Movagher Feb 18 '15 at 18:30
  • @JuniorCompressor, why you remove your answer? – Ali Movagher Feb 21 '15 at 5:25
  • Can you explain more about the problem? How do we detect which of them? I don't get what you mean here? – Pham Trung Feb 23 '15 at 11:22
  • 2
    "How do we detect which of them?" I have no idea what this question means, and no idea why five people have upvoted this. – David Eisenstat Feb 23 '15 at 12:26

For Bellman-Ford and Dijkstra algorithm, we will use same relax function, but the main different is, how many times the relax function is being called, in each algorithm.

For Bellman-Ford:

for i from 1 to size(vertices)-1:
       for each edge (u, v) with weight w in edges:

So, relax function will be called exactly n - 1 times for each edges.

For Dijkstra:

while Q is not empty:
      u ← vertex in Q with min dist[u]  // Source node in first case
      remove u from Q 

      for each edge(u,v) of u:           // where v is still in Q.

      end for
end while

In this case, relax function will be called once for each edge, when its starting vertex is processed.

Summary: Bellman-Ford's algorithm, the number of relax function call is m*n, and Dijkstra's algorithm, the number of call is m, with m is number of edges, and n is number of vertices.

Note: code is taken and modified from Wikipedia to bring you clearer view of using relax function

  • please mention that if we just use relax with for loop, the only is Bellman ... – Ali Movagher Feb 25 '15 at 8:49
  • No, you didnt mentioned, if we just use only Relax function, this algorithm is bellman-ford and minimum is M*N. – Ali Movagher Feb 25 '15 at 10:31
  • @AliMovagher done! – Pham Trung Feb 25 '15 at 10:44
  • ِDijkstra always terminates after |E| relaxations not 2*|E| – Ali Movagher Feb 25 '15 at 12:16
  • @AliMovagher O(|E|) doesn't mean it is |E|, please read this and this – Pham Trung Feb 25 '15 at 12:50

We should iterate over each edge n - 1 times:

for step <- 0 ... n - 1:
    for edge <- edges
  1. It is necessary: imagine a chain with n vertices. We need to make exactly n - 1 steps to reach the last.

  2. It is sufficient: there no cycle in an optimal path, and the longest simple path contains at most n - 1 edges.

So the answer is (n - 1) * m is want to simply iterate over the distance array and make changes(yes, it is Ford-Bellman's algorithm).

However, if another algorithm is used(for instance, Dijkstra's), the number of calls to the relax function is less(namely, m).

So it depends on details of the algorithm we are using.

  • i think it's say, positive weights, two of them can be used. and because it's say, from one vertex to all other vertex Dijkstra cannot used? am i wrong? – Ali Movagher Feb 18 '15 at 18:49
  • @AliMovagher Dijkstra's algorithm can be used to find shortest paths from one vertex to all other vertices. – kraskevich Feb 18 '15 at 18:50
  • when we want to choose the best option between m*n, m+n, m or n, which of them is best? – Ali Movagher Feb 18 '15 at 18:57
  • @AliMovagher m seems to be the best(in a sense that it is the smallest sufficient number of relax calls). – kraskevich Feb 18 '15 at 19:05
  • i think there is a tricky point in this question, just on of this algorithm should be considered.... – Ali Movagher Feb 19 '15 at 8:51

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