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I am looking for a way to perform a topological sorting on a given directed unweighted graph, that contains cycles. The result should not only contain the ordering of vertices, but also the set of edges, that are violated by the given ordering. This set of edges shall be minimal.

As my input graph is potentially large, I cannot use an exponential time algorithm. If it's impossible to compute an optimal solution in polynomial time, what heuristic would be reasonable for the given problem?

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Is this not feedback arc set? You can get the order by topologically sorting the residual DAG. –  David Eisenstat Jun 17 '13 at 13:13
Also do you want a minimal solution (each and every removed arc would complete a cycle in the DAG) or a minimum solution (as few arcs removed as possible)? –  David Eisenstat Jun 17 '13 at 13:39
@DavidEisenstat actually I don't care too much if it's one arc more or less, I simply have to handle them separately. If some algorithm takes twice the runtime and only finds a solution with few arcs less, it won't be economical. The problem seems to be feedback arc set, but that's NP hard in this case, so we'll need an approximation. –  orsg Jun 17 '13 at 14:16

2 Answers 2

up vote 4 down vote accepted

Eades, Lin, and Smyth proposed A fast and effective heuristic for the feedback arc set problem. The article is behind a paywall (sorry), but the idea is pretty simple.

There’s an algorithm for topological sorting that builds the vertex order by selecting a vertex with no incoming arcs, recursing on the graph minus the vertex, and prepending that vertex to the order. (I’m describing the algorithm recursively, but you don’t have to implement it that way.) The Eades–Lin–Smyth algorithm looks also for vertices with no outgoing arcs and appends them. Of course, it can happen that all vertices have incoming and outgoing arcs. In this case, select the vertex with the highest differential between incoming and outgoing. There is undoubtedly room for experimentation here.

The algorithms with provable worst-case behavior are based on linear programming and graph cuts. These are neat, but the guarantees are less than ideal (log^2 n or log n log log n times as many arcs as needed), and I suspect that efficient implementations would be quite a project.

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(I'm unfortunately writing a separate answer for what is essentially just a comment to David Eisenstat's answer, as I don't have enough points to comment.)

The Eades, Lynn, and Smith paper is freely available at citeseer.

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