# Directed maximum weighted bipartite matching allowing sharing of start/end vertices

Let G (U u V, E) be a weighted directed bipartite graph (i.e. U and V are the two sets of nodes of the bipartite graph and E contains directed weighted edges from U to V or from V to U). Here is an example:

In this case:

``````U = {A,B,C}
V = {D,E,F}
E = {(A->E,7), (B->D,1), (C->E,3), (F->A,9)}
``````

Definition: DirectionalMatching (I made up this term just to make things clearer): set of directed edges that may share the start or end vertices. That is, if U->V and U'->V' both belong to a DirectionalMatching then V /= U' and V' /= U but it may be that U = U' or V = V'.

My question: How to efficiently find a DirectionalMatching, as defined above, for a bipartite directional weighted graph which maximizes the sum of the weights of its edges?

By efficiently, I mean polynomial complexity or faster, I already know how to implement a naive brute force approach.

In the example above the maximum weighted DirectionalMatching is: {F->A,C->E,B->D}, with a value of 13.

Formally demonstrating the equivalence of this problem to any other well known problem in graph theory would also be valuable.

Thanks!

Note 1: This question is based on Maximum weighted bipartite matching _with_ directed edges but with the extra relaxation that it is allowed for edges in the matching to share the origin or destination. Since that relaxation makes a big difference, I created an independent question.

Note 2: This is a maximum weight matching. Cardinality (how many edges are present) and the number of vertices covered by the matching is irrelevant for a correct result. Only the maximum weight matters.

Note 2: During my research to solve the problem I found this paper, I think it would be helpful to others trying to find a solution: Alternating cycles and paths in edge-coloured multigraphs: a survey

Note 3: In case it helps, you can also think of the graph as its equivalent 2-edge coloured undirected bipartite multigraph. The problem formulation would then turn into: Find the set of edges without colour-alternating paths or cycles which has maximum weight sum.

Note 4: I suspect that the problem might be NP-hard, but I am not that experienced with reductions so I haven't managed to prove it yet.

Yet another example:

4 vertices: `{u1, u2}` `{v1, v2}`

4 edges: `{u1->v1, u1->v2, u2->v1, v2->u2}`

Then, regardless of their weights, `u1->v2` and `v2->u2` cannot be in the same DirectionalMatching, neither can `v2->u2` and `u2->v1`. However `u1->v1` and `u1->v2` can, and so can `u1->v1` and `u2->v1`.

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Is only me, or does this definition allows us to connect every nodes from the left to every nodes from the right, and it still will be "directional matching"? –  K. Bulatov Feb 12 '13 at 13:26
Indeed, that would be a directional matching –  fons Feb 12 '13 at 13:32
what's the problem then? so let's take all the edges from left to right and from right to left 8) we can't take any more (there are none), so it will maximize the sum. –  K. Bulatov Feb 12 '13 at 13:45
@K.Bulatov No, that is not a solution, please read the definition of Directional Matching carefully. For instance A->E cannot appear in the same matching as F->A –  fons Feb 12 '13 at 14:14
Wouldn't the maximum be at {F->A,C->E,B->D} where it is 13? –  cyon Feb 12 '13 at 15:46

Define a new undirected graph `G'` from `G` as follows.

1. `G'` has a node `(A, B)` with weight `w` for each directed edge `(A, B)` with weight `w` in `G`
2. `G'` has undirected edge `((A, B),(B, C))` if (A, B) and (B, C) are both directed edges in G

http://en.wikipedia.org/wiki/Line_graph#Line_digraphs

Now find a maximal (weighted) independent vertex set in `G'`.

http://en.wikipedia.org/wiki/Vertex_independent_set

## Edit: stuff after this point only works if all of the edge weights are the same - when the edge weights have different values its a more difficult problem (google "maximum weight independent vertex set" for possible algorithms)

Typically this would be an NP-hard problem. However, `G'` is a bipartite graph -- it contains only even cycles. Finding the maximal (weighted) independent vertex set in a bipartite graph is not NP-hard.

The algorithm you will run on `G'` is as follows.

1. Find the connected components of `G'`, say `H_1, H_2, ..., H_k`
2. For each `H_i` do a 2-coloring (say red and blue) of the nodes. The cookbook approach here is to do a depth-first search on `H_i` alternating colors. A simple approach would be to color each vertex in `H_i` based on whether the corresponding edge in `G` goes from `U` to `V` (red) or from `V` to `U` (blue).
3. The two options for which nodes to select from `H_i` are either all the red nodes or all the blue nodes. Choose the colored node set with higher weight. For example, the red node set has weight equal to `H_i.nodes.where(node => node.color == red).sum(node => node.w)`. Call the higher-weight node set `N_i`.
4. Your maximal weighted independent vertex set is now `union(N_1, N_2, ..., N_k)`.

Since each vertex in `G'` corresponds to one of the directed edges in `G`, you have your maximal DirectionalMatching.

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Wow, as simple as modelling the problem with the line graph instead. Skiena is right, again: Design Graphs not Algorithms!!! I haven't checked the whole solution yet (it's really late here) but I will do it first thing tomorrow (it looks like you are getting the bounty though :)). –  fons Feb 20 '13 at 22:41
Yeah, the section you referenced in that book summarizes pretty much exactly what I did in this answer: (1) transform the graph, (2) apply known algorithm (with a slight modification). Let me know how it works out for you. –  Timothy Shields Feb 20 '13 at 23:02
I haven't had time to check it yet (I am having a busy day). But since this is the only promising answer (well, from my perspective until I confirm it) and the bounty is ending in 1 hour .... it's yours. –  fons Feb 21 '13 at 12:12
For step 2, isn't the coloring straightforward since G' is bipartite? Just use blue (red) for the nodes created from edges from U to V and red (blue) for the nodes created from V to U. I don't see why a depth-first search is required. –  fons Feb 23 '13 at 2:08
I have an example that I dont understand how this will solve: `U={A,C,E}` `V={B,D}` and `E={(A->B,10), (B->C,1), (C->D,1), (D->E,10)}`. I would expect maximum value be 20, but with a 2-coloring it ends up with 11? –  viblo Feb 25 '13 at 22:29

This problem can be solved in polynomial time using the Hungarian Algorithm. The "proof" by Vor above is wrong.

The method of structuring the problem for the above example is as follows:

``````   D E F
A  # 7 9
B  1 # #
C  # 3 #
``````

where "#" means negative infinity. You then resolve the matrix using the Hungarian algorithm to determine the maximum matching. You can multiply the numbers by -1 if you want to find a minimum matching.

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How would you adapt the Hungarian Algorithm to this case which includes: 1) directed edges, and 2) the possibility for edges in the solution to share vertices? –  mhum Feb 19 '13 at 19:13
The fact that the edges are directed is irrelevant. If a vertex connects to multiple vertices then that results in multiple possible weightings. For example, in my example above A has two weightings, but B and C only one. You could just as well have edges between every single vertex, which would result in a full matrix with no "#" values. –  Tyler Durden Feb 19 '13 at 19:20
That is exactly correct. It is not a bipartite matching. The asker has specifically said that they are looking for something they have termed a "Directional Matching" (not a standard term), defined above in the question. The graph itself is defined as bipartite, but the requested solutions are not bipartite matchings, as far as I can tell. –  mhum Feb 19 '13 at 19:52
Ok, well in this case, I guess what you are saying is that {E->A,F->A} is considered as a single "directional matching" with a value of 16, however, this is still impossible because if you do this match, then how do you match B/C to just D, you can't. It is not really clear what the objective is, if it is not a 1-to-1 matching. I mean if you are allowing any so called "match", why not match everything (which is exactly what your "solution" above does, including all 4 edges)? –  Tyler Durden Feb 19 '13 at 20:22
Yes, in the modified case I stated, I think the solution would be to select all edges. The thing which prevents this from always being the solution is the idea that if A->B and B->C, you can't select both A->B and B->C to be in a solution since the head of one edge intersects the tail of another edge. "Matching" is perhaps an inapt term here. I think the asker is requesting a set of directed edges such that there are no heads overlapping any tails. –  mhum Feb 19 '13 at 20:28