Almost-Optimal Approximation Algorithms for Global Minimum Cut in Directed Graphs

Abstract

We develop new (1+ε)-approximation algorithms for finding the global minimum edge-cut in a directed edge-weighted graph, and for finding the global minimum vertex-cut in a directed vertex-weighted graph. Our algorithms are randomized, and have a running time of O(m1+o(1)/ε) on any m-edge n-vertex input graph, assuming all edge/vertex weights are polynomially-bounded. In particular, for any constant ε>0, our algorithms have an almost-optimal running time of O(m1+o(1)). The fastest previously-known running time for this setting, due to (Cen et al., FOCS 2021), is O(\n2/ε2,m1+o(1)n\) for Minimum Edge-Cut, and O(n2/ε2) for Minimum Vertex-Cut. Our results further extend to the rooted variants of the Minimum Edge-Cut and Minimum Vertex-Cut problems, where the algorithm is additionally given a root vertex r, and the goal is to find a minimum-weight cut separating any vertex from the root r. In terms of techniques, we build upon and extend a framework that was recently introduced by (Chuzhoy et al., SODA 2026) for solving the Minimum Vertex-Cut problem in unweighted directed graphs. Additionally, in order to obtain our result for the Global Minimum Vertex-Cut problem, we develop a novel black-box reduction from this problem to its rooted variant. Prior to our work, such reductions were only known for more restricted settings, such as when all vertex-weights are unit.

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