Directed Reachability-Preserving Minimum Edge Cut: Approximation and Planar Hardness

Abstract

We study a directed version of the three-terminal reachability-preserving minimum edge cut problem. Given a directed graph G=(V,A) with arc costs and terminals s1,s2,t, the one-way directed RPMEC problem asks for a minimum-cost set of arcs whose deletion preserves the reachability s1 s2 while destroying the reachability s1 t. We first give a path--cut formulation in terms of a rooted directed cut function. Using a root-linear approximation for the associated polymatroid, we obtain an O( r)-approximation, where r is the number of relevant vertices with positive singleton cut value. In particular this gives an O( n)-approximation in general directed graphs. For acyclic directed graphs, we give an additional singleton-length algorithm and obtain an O(\ r,h\) guarantee, where h is the maximum number of relevant vertices on an s1-s2 path. Finally, we prove that directed planar RPMEC is NP-hard, even on acyclic planar digraphs with nonnegative costs, by reducing from independent set on cubic planar graphs through a finite-bimodal directed node-cut construction and a planar node-to-edge split.