The Complexity of Counting Eulerian Tours in 4-Regular Graphs

Abstract

We investigate the complexity of counting Eulerian tours ( #ET) and its variations from two perspectives---the complexity of exact counting and the complexity w.r.t. approximation-preserving reductions (AP-reductions MR2044886). We prove that #ET is #P-complete even for planar 4-regular graphs. A closely related problem is that of counting A-trails ( #A-trails) in graphs with rotational embedding schemes (so called maps). Kotzig MR0248043 showed that #A-trails can be computed in polynomial time for 4-regular plane graphs (embedding in the plane is equivalent to giving a rotational embedding scheme). We show that for 4-regular maps the problem is #P-hard. Moreover, we show that from the approximation viewpoint #A-trails in 4-regular maps captures the essence of #ET, that is, we give an AP-reduction from #ET in general graphs to #A-trails in 4-regular maps. The reduction uses a fast mixing result for a card shuffling problem MR2023023. In order to understand whether # A-trails in 4-regular maps can AP-reduce to # ET in 4-regular graphs, we investigate a problem in which transitions in vertices are weighted (this generalizes both # A-trails and # ET). In the 4-regular case we show that A-trails can be used to simulate any vertex weights and provide evidence that ET can simulate only a limited set of vertex weights.