Solving MaxSAT and #SAT on structured CNF formulas
Abstract
In this paper we propose a structural parameter of CNF formulas and use it to identify instances of weighted MaxSAT and #SAT that can be solved in polynomial time. Given a CNF formula we say that a set of clauses is precisely satisfiable if there is some complete assignment satisfying these clauses only. Let the ps-value of the formula be the number of precisely satisfiable sets of clauses. Applying the notion of branch decompositions to CNF formulas and using ps-value as cut function, we define the ps-width of a formula. For a formula given with a decomposition of polynomial ps-width we show dynamic programming algorithms solving weighted MaxSAT and #SAT in polynomial time. Combining with results of 'Belmonte and Vatshelle, Graph classes with structured neighborhoods and algorithmic applications, Theor. Comput. Sci. 511: 54-65 (2013)' we get polynomial-time algorithms solving weighted MaxSAT and #SAT for some classes of structured CNF formulas. For example, we get algorithms for formulas of clauses and variables and size , if has a linear ordering of the variables and clauses such that for any variable occurring in clause , if appears before then any variable between them also occurs in , and if appears before then occurs also in any clause between them. Note that the class of incidence graphs of such formulas do not have bounded clique-width.
Cite
@article{arxiv.1402.6485,
title = {Solving MaxSAT and #SAT on structured CNF formulas},
author = {Sigve Hortemo Sæther and Jan Arne Telle and Martin Vatshelle},
journal= {arXiv preprint arXiv:1402.6485},
year = {2014}
}