Approximating partition functions of bounded-degree Boolean counting Constraint Satisfaction Problems

Abstract

We study the complexity of approximate counting Constraint Satisfaction Problems (#CSPs) in a bounded degree setting. Specifically, given a Boolean constraint language and a degree bound , we study the complexity of #CSP(), which is the problem of counting satisfying assignments to CSP instances with constraints from and whose variables can appear at most times. Our main result shows that: (i) if every function in is affine, then #CSP() is in FP for all , (ii) otherwise, if every function in is in a class called IM2, then for all sufficiently large , #CSP() is equivalent under approximation-preserving (AP) reductions to the counting problem #BIS (the problem of counting independent sets in bipartite graphs) (iii) otherwise, for all sufficiently large , it is NP-hard to approximate the number of satisfying assignments of an instance of #CSP(), even within an exponential factor. Our result extends previous results, which apply only in the so-called "conservative" case.