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# How to determine a dependency graph solution is correct

I created a class that takes a directed graph, a vertex in that graph, and outputs an acceptable sequence of vertices to lead to that vertex.

e.g.

• A->B
• A->C
• B->D
• C->D

The two possible sequences for vertex D are:

• A->B->C->D
• A->C->B->D

Now, I need to design a test to determine if a solution my program gives is correct.

Any ideas?

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You could use an algorithm based on Cyclomatic Complexity to calculate the number of paths that should be found, which would be a good sanity check - esp if you have a very big graph, getting exactly the right number of paths would be reassuring (though not obviously a guarantee that the paths themselves are correct!). It is broadly speaking the number of edges minus the number of nodes - you'll see the nuances on that wikipedia page.

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Your problem is quite common. There are essentially two similar and easy ways to deal with it:

• put the sequences of nodes in a set and check the set size and whether it contains all the sequences

• sort the sequences according to some known algorithm (e.g. by comparing one node after another). Now the order is always the same.

In Java this would mean:

• implement `equals` and `hashCode` for the sequence of nodes (if this is something like `List<Node>`, implement `equals` and `hashCode` for `Node` instead) and put them in `HashSet`. Then simply check if the set has correct size and contains both paths.

• make the sequence of nodes `Comparable` and sort them. Then the order is always known and fixed. In your case simply compare corresponding nodes one after another.

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This seems to be assuming I know the solution beforehand. I need to be able to put an extremely complex graph in, and have the solution checked specifically via the test. Any ideas for that? – Jeff Aug 18 '11 at 6:37