# Shortest path with one skippable edge

I have this problem: "Shortest path with one skippable edge. Given an edge-weighted digraph, design an `E*log(V)` algorithm to find a shortest path from `s` to `t` where you can change the weight of any one edge to zero. Assume the edge weights are nonnegative."

I don't understand what they want me to do. What does it mean to change the weight to zero? I think that I can change any edge in any shortest path to zero and it will still be the shortest.

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"I think that I can change any edge in any shortest path to zero and it will still be the shortest." - Imagine a single edge that attaches the start to the finish, with weight 9999999. –  BlueRaja - Danny Pflughoeft Apr 30 '13 at 6:14
What do you mean? If I have a shortest path and change this huge edge to zero, this edge will become the new shortest path? –  Graduate Apr 30 '13 at 6:26
Yes, that is exactly what I mean. So the problem is not as simple as "find the shortest path and remove the longest edge that's a part of it." Nor is it as simple as removing the longest edge on the graph. I'd have to take some time to think about how to solve this. –  BlueRaja - Danny Pflughoeft Apr 30 '13 at 8:12

First use Dijkstra to find the legth S(v) of shortset path from s to v for every v. Then use Dijkstra to find the legth T(v) of shortset path from v to t for every v. Then for every edge (v, w) consider path from s to t through (v, w) and its length S(v) + T(w) if you change weight of (v, w) to 0. Finally, choose te minimum :)

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The problem is simple.

Suppose that you have a shortest path with one skippable edge, p = v1,...,vi,vi+1,...,vm and (vi,vi+1) is a skipped edge
Obviously, a path(v1,...,vi) is a shortest path between v1 and vi
and a path(vi+1,...,vm) is a shortest path between vi+1 and vm
Define d(x,y) as the length of the shortest path between node x and node y
you can simply find d(s,x) and d(x,t) for all node x by dijkstra algorithm and now we have to choose the skipped edge one by one. In other words, the length of the shortest path with one skippable edge is

min( d(s,u) + d(v,t) ) for all edge (u,v) in the graph

and the time complexity is O(E log V) because of Dijkstra Algorithm

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Though the other answer was first and says the same thing, this one is much better explained. +1! –  BlueRaja - Danny Pflughoeft Apr 30 '13 at 15:59

The previous answers seem to suppose that Dijkstra gives the shortest distance from every vertex to every vertex, but this is not the case.

If you execute Dijkstra only once, starting from s, you have the shortest path from s to every vertex.

To find the shortest distance from every vertex to t, it is necessary to execute Dijkstra again starting from t after reversing every edge of the graph.

The complete solution is:

1) Execute Dijkstra on the graph G starting from s to obtain the shortest distance T(v) between s and any v.

2) Reverse all the edges to obtain the reversed graph G'

3) Execute Dijkstra on the graph G' starting from t to obtain the shortest distance R(v) between t and any v.

4) The one to skip is the edge e(v1 --> v2) for which T(v1) + R(v2) is minimum.

5) The path to follow is a concatenation of the shortest path between s and v1 given by the first Dijkstra and the shortest path between v2 and t given by the second Dijkstra.

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