I know various algorithms to compute the maximum weighted matching of **weighted, undirected** bipartite graphs (i.e. the assignment problem):

For instance ... The Hungarian Algorithm, Bellman-Ford or even the Blossom algorithm (which works for general, i.e. not bipartite, graphs).

However, how can I compute the maximum weighted matching if the edges of the bipartite graph are **weighted and directed**?

I would appreciate pointers to algorithms with polinomial complexity or prior transformations to make the graph undirected so that I could apply any of the aforementioned algorithms.

**Edit:** note that the matching should maximize the weight of the edges, that's why having directed edges makes a difference (A->B can have a totally different weight than B->A).

Admittedly, if I was maximizing cardinality, the directed edges wouldn't make a difference and I could apply any of the well-known algorithms to maximize cardinality: Hopcroft–Karp, Maximum Network Flow ....

**Edit 2**: Since *matching* is a term normally applied to undirected graphs, let me clarify what I exactly mean by *matching* in this question: *a set of directed edges that do not share start or end vertices*. More formally, if U->V and U'->V' are part of the matching, then V /= U' and V' /= U.