# Dijkstra for longest path in a DAG

I am trying to find out if it is possible to use Dijkstra's algorithm to find the longest path in a directed acyclic path. I know that it is not possible to find the longest path with Dijkstra in a general graph, because of negative cost cycles. But it should work in a DAG, I think. Through Google I found a lot of conflicting sources. Some say it works in a dag and some say it does not work, but I didn't find a proof or a counter example. Can someone point me to a proof or a counter example?

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looks like it works, if i look at this approach Longest path problem, but you arent convinced? –  yosukesabai Nov 6 '11 at 13:21
@yosukesabai The algorithm you point to is not the Dijkstra Algorithm. –  punkyduck Nov 10 '11 at 15:16

The only requirement is not to have negative cycles. If you don't have the cycles, then you can remap negative ones by adding the highest absolute value from the negative weights to all the weights. That way you will lose the negative wights, as all the weight will be equal or grater than zero. So too sum up the only thing to worry is not having a negative cycle.

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This will skew the length of paths, since a negative cycle implies negative infinity as a distance to any node that can be reached via the cycle, while afterwards every distance is non-negative. Also the number of edges in the path will then dominate its length, which clearly isnt the intention when edges can have weights. –  G. Bach Feb 5 '13 at 16:16

I thought about the problem and I think it is not possible in general. Being acyclic is not enough, I think.

For example:

We want to go from a to c in this dag.

``````a - > b - > c
|           /\
v           |
d - - - - -
``````

d-c has length 4

a-d has length 1

all others have length 2

If you just replace the min function with a max function, the algorithm will lead to a-b-c but the longest path is a-d-c.

I found two special cases where you can use Dijkstra for calculating the longest path:

1. The graph is not only directed acyclic, but also acyclic if you remove the directions. In other words: It is a tree. Because in a tree the longest path is also the shortest path.
2. The graph has only negative weights. Then you can use max instead of min to find the longest path. BUT this works only if the weights are really negative. If you just invert positive weights it will not work.
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Actually for (2) you cannot have negative weights else it's like trying to simply look for the maximum (inverting the comparison). You need to find a value at least equal to the maximum weight, and then for each weight: weight = max_weight - weight. Then a normal Dijkstra will return you the longest path. Just do path_length*max_weight - dist to get that distance. –  Wernight Mar 9 '13 at 0:08

There're three possible ways to apply Dijkstra, NONE of them will work:
1.Directly use “max” operations instead of “min” operations.
2.Convert all positive weights to be negative. Then find the shortest path.
3.Give a very large positive number M. If the weight of an edge is w, now M-w is used to replace w. Then find the shortest path.

For DAG, critical path method will work:
1: Find a topological ordering.
2: Find the critical path.
see [Horowitz 1995] E. Howowitz, S. Sahni and D. Metha, Fundamentals of Data Structures in C++, Computer Science Press, New York, 1995

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I suggest you modify the Dijkstra's algorithm to take the inverted value of the edge weight. Because the graph is acyclic, the algorithm will not enter an endless loop, using the negative weights to keep optimising. What is more, now positive weights become negative, but, again, there are no cycles. This will work even if the graph is undirected, provided that you disallow reinsertion of visited nodes (i.e., stop the endless jumping between two nodes, because adding negative value will always be better).

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