Width Parameterizations for Knot-free Vertex Deletion on Digraphs
Abstract
A knot in a directed graph is a strongly connected subgraph of with at least two vertices, such that no vertex in is an in-neighbor of a vertex in . Knots are important graph structures, because they characterize the existence of deadlocks in a classical distributed computation model, the so-called OR-model. Deadlock detection is correlated with the recognition of knot-free graphs as well as deadlock resolution is closely related to the {\sc Knot-Free Vertex Deletion (KFVD)} problem, which consists of determining whether an input graph has a subset of size at most such that contains no knot. In this paper we focus on graph width measure parameterizations for {\sc KFVD}. First, we show that: (i) {\sc KFVD} parameterized by the size of the solution is W[1]-hard even when , the length of a longest directed path of the input graph, as well as , its Kenny-width, are bounded by constants, and we remark that {\sc KFVD} is para-NP-hard even considering many directed width measures as parameters, but in FPT when parameterized by clique-width; (ii) {\sc KFVD} can be solved in time , but assuming ETH it cannot be solved in , where is the treewidth of the underlying undirected graph. Finally, since the size of a minimum directed feedback vertex set () is an upper bound for the size of a minimum knot-free vertex deletion set, we investigate parameterization by and we show that (iii) {\sc KFVD} can be solved in FPT-time parameterized by either or ; and it admits a Turing kernel by the distance to a DAG having an Hamiltonian path.
Cite
@article{arxiv.1910.01783,
title = {Width Parameterizations for Knot-free Vertex Deletion on Digraphs},
author = {Stéphane Bessy and Marin Bougeret and Alan D. A. Carneiro and Fábio Protti and Uéverton S. Souza},
journal= {arXiv preprint arXiv:1910.01783},
year = {2019}
}
Comments
An extended abstract of this paper was published in IPEC 2019