Weighted Clique and Independent Set in Edge-Distant Hereditary Graphs

Abstract

In this work, we investigate the algorithmic aspects of two natural extensions of hereditary classes: the edge-apex class and the edge-add class, recently introduced by Singh and Sivaraman. These are defined as the graph classes obtained by at most one edge deletion or one non-edge addition, respectively, from a hereditary class G. Building on earlier results showing that both classes remain hereditary and admit finite forbidden induced subgraph characterizations whenever G does, we focus on the Weighted Maximum Clique Problem (WMCP) and the Weighted Maximum Independent Set Problem (WMISP). We first present algorithms for WMCP and WMISP on both the edge-apex and edge-add classes of hereditary graph classes. Extending this framework, we introduce the notion of the G-edge distance of a graph G, denoted by ξG(G), which quantifies how far G is from the class G in terms of the minimum number of edge deletions or non-edge additions needed to transform it into a member of G. By parameterizing with respect to this distance, we show that both WMCP and WMISP can be solved in O*(2k) time on graphs whose G-edge distance is k, provided these problems admit polynomial-time algorithms within the class G. This result extends earlier algorithmic characterizations of the single edge-apex and edge-add classes to the more general setting of k-edge-distant graphs. By combining our general results with known properties of transitive graphs, we show that WMCP and WMISP can be solved in O*(2k) time for graphs with transitive-edge distance k.