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.

`How do we detect which of them?`

I don't get what you mean here? – Pham Trung Feb 23 '15 at 11:22