# why Dijkstra's algo does not work for negative weight edges

Can somebody tell me why Dijkstra's algorithm for single source shortest path assumes that the edges must be non-negative. I am talking about only edges not the negative weight cycles.

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Recall that in Dijkstra's algorithm, once a vertex is marked as "closed" (and out of the open set) - the algorithm found the shortest path to it, and will never have to develop this node again - it assumes the path developed to this path is the shortest.

But with negative weights - it might not be true. For example:

``````       A
/ \
/   \
/     \
5       2
/         \
B--(-10)-->C

V={A,B,C} ; E = {(A,C,2), (A,B,5), (B,C,-10)}
``````

Dijkstra from A will first develop C, and will later fail to find `A->B->C`

EDIT a bit deeper explanation:

Note that this is important, because in each relaxation step, the algorithm assumes the "cost" to the "closed" nodes is indeed minimal, and thus the node that will next be selected is also minimal.

The idea of it is: If we have a vertex in open such that its cost is minimal - by adding any positive number to any vertex - the minimality will never change.
Without the constraint on positive numbers - the above assumption is not true.

Since we do "know" each vertex which was "closed" is minimal - we can safely do the relaxation step - without "looking back". If we do need to "look back" - Bellman-Ford offers a recursive-like (DP) solution of doing so.

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Sorry but I'm not getting any error. First `A->B` will 5 and `A->C` will 2. Then `B->C` will `-5`. So the value of `C` will be `-5` same as bellman-ford. How is this not giving the right answer? –  tintinmj May 23 '14 at 7:02
@tintinmj first, Dijkstra will "close" node `A` with value of 0. Then, it will look on the minimal valued node, `B` is 5 and `C` is 2. The minimal is `C`, so it will close `C` with value 2 and will never look back, when later `B` is closed, it cannot modify the value of `C`, since it is already "closed". –  amit May 23 '14 at 8:33

Dijkstra's algorithm assumes paths can only become 'heavier', so that if you have a path from A to B with a weight of 3, and a path from A to C with a weight of 3, there's no way you can add an edge and get from A to B through C with a weight of less than 3.

This assumption makes the algorithm faster than algorithms that have to take negative weights into account.

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Try Dijkstra on this graph to see what is happening:

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Sorry but I'm not getting any error. First `A->B` will `1` and `A->C` will `100`. Then `B->D` will `2`. Then `C->D` will `-4900`. So the value of `D` will be `-4900` same as bellman-ford. How is this not giving the right answer? –  tintinmj May 22 '14 at 23:11
@tintinmj If you have an outgoing edge from D, it will get visited before D's distance is decreased and hence not updated after it is. This will then result in an error for sure. If you consider D's 2 as the final distance already after scanning outgoing edges, even this graph results in an error. –  Christian Schnorr Jul 16 '14 at 14:46

Correctness of Dijkstra's algorithm:

We have 2 sets of vertices at any step of the algorithm. Set A consists of the vertices to which we have computed the shortest paths. Set B consists of the remaining vertices.

Inductive Hypothesis: At each step we will assume that all previous iterations are correct.

Inductive Step: When we add a vertex V to the set A and set the distance to be dist[V], we must prove that this distance is optimal. If this is not optimal then there must be some other path to the vertex V that is of shorter length.

Suppose this some other path goes through some vertex X.

Now, since dist[V] <= dist[X] , therefore any other path to V will be atleast dist[V] length, unless the graph has negative edge lengths.

Thus for dijkstra's algorithm to work, the edge weights must be non negative.

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