Counting and Enumerating Crossing-free Geometric Graphs

Abstract

We describe a framework for counting and enumerating various types of crossing-free geometric graphs on a planar point set. The framework generalizes ideas of Alvarez and Seidel, who used them to count triangulations in time O(2nn2) where n is the number of points. The main idea is to reduce the problem of counting geometric graphs to counting source-sink paths in a directed acyclic graph. The following new results will emerge. The number of all crossing-free geometric graphs can be computed in time O(cnn4) for some c < 2.83929. The number of crossing-free convex partitions can be computed in time O(2nn4). The number of crossing-free perfect matchings can be computed in time O(2nn4). The number of convex subdivisions can be computed in time O(2nn4). The number of crossing-free spanning trees can be computed in time O(cnn4) for some c < 7.04313. The number of crossing-free spanning cycles can be computed in time O(cnn4) for some c < 5.61804. With the same bounds on the running time we can construct data structures which allow fast enumeration of the respective classes. For example, after O(2nn4) time of preprocessing we can enumerate the set of all crossing-free perfect matchings using polynomial time per enumerated object. For crossing-free perfect matchings and convex partitions we further obtain enumeration algorithms where the time delay for each (in particular, the first) output is bounded by a polynomial in n. All described algorithms are comparatively simple, both in terms of their analysis and implementation.