I need an algorithm to (efficiently) solve a problem that has come up in some diagramming software that I am writing.
I have two sets of nodes, N and M. Each node n0 in N has 0 to M connections to a unique (for n0) node in M. These sets of nodes are to be arranged on two parallel horizontal lines, with the N nodes in the line above the M nodes. The connections will be drawn as straight lines from N to M.
What I need to do is to rearrange the N and M nodes within their horizontal lines, to minimize crossings. Is their any way to do this that is more efficient than just naively enumerating all possible arrangements, which is O(N!*M!)? (actually, its considerably worse than that, since each connection has to be checked for crossing also).
References to relevant literature are welcome also, though an explanation as to why its relevant is desired.
As has been pointed out, in the general case this could be considered a bipartite graph (the sets N and M) planarization algorithm. However, this specific problem is considerably more restricted than that (which I hope can make it faster) and is required to produce additional information (which may make it slower), as follows:
the diagram's restrictions are that the connections must be drawn as straight lines from N to M. In graph theory, this practically means that the connections cannot go behind the nodes in N or M, only between them. Thus, the 2x2 case with four connectors can be planarized in the general Bipartite graph case, but cannot in the case of my diagram.
The additional information, is that if it cannot be planarized, I still need a minimal-crossing solution (or close to it). Generally, minimal-crossing algorithims are significantly different from those that only planarize.