Parameterizing the quantification of CMSO: model checking on minor-closed graph classes
Abstract
Given a graph and a vertex set , the annotated treewidth tw of in is the maximum treewidth of an -rooted minor of , i.e., a minor where the model of each vertex of contains some vertex of . That way, tw can be seen as a measure of the contribution of to the tree-decomposability of . We introduce the logic CMSO/tw as the fragment of monadic second-order logic on graphs obtained by restricting set quantification to sets of bounded annotated treewidth. We prove the following Algorithmic Meta-Theorem (AMT): for every non-trivial minor-closed graph class, model checking for CMSO/tw formulas can be done in quadratic time. Our proof works for the more general CMSO/tw+dp logic, that is CMSO/tw enhanced by disjoint-path predicates. Our AMT can be seen as an extension of Courcelle's theorem to minor-closed graph classes where the bounded-treewidth condition in the input graph is replaced by the bounded-treewidth quantification in the formulas. Our results yield, as special cases, all known AMTs whose combinatorial restriction is non-trivial minor-closedness.
Cite
@article{arxiv.2406.18465,
title = {Parameterizing the quantification of CMSO: model checking on minor-closed graph classes},
author = {Ignasi Sau and Giannos Stamoulis and Dimitrios M. Thilikos},
journal= {arXiv preprint arXiv:2406.18465},
year = {2024}
}