Near-Linear Time Approximations for Cut Problems via Fair Cuts

Abstract

We introduce the notion of fair cuts as an approach to leverage approximate (s,t)-mincut (equivalently (s,t)-maxflow) algorithms in undirected graphs to obtain near-linear time approximation algorithms for several cut problems. Informally, for any α≥ 1, an α-fair (s,t)-cut is an (s,t)-cut such that there exists an (s,t)-flow that uses 1/α fraction of the capacity of every edge in the cut. (So, any α-fair cut is also an α-approximate mincut, but not vice-versa.) We give an algorithm for (1+ε)-fair (s,t)-cut in O(m)-time, thereby matching the best runtime for (1+ε)-approximate (s,t)-mincut [Peng, SODA '16]. We then demonstrate the power of this approach by showing that this result almost immediately leads to several applications: - the first nearly-linear time (1+ε)-approximation algorithm that computes all-pairs maxflow values (by constructing an approximate Gomory-Hu tree). Prior to our work, such a result was not known even for the special case of Steiner mincut [Dinitz and Vainstein, STOC '94; Cole and Hariharan, STOC '03]; - the first almost-linear-work subpolynomial-depth parallel algorithms for computing (1+ε)-approximations for all-pairs maxflow values (again via an approximate Gomory-Hu tree) in unweighted graphs; - the first near-linear time expander decomposition algorithm that works even when the expansion parameter is polynomially small; this subsumes previous incomparable algorithms [Nanongkai and Saranurak, FOCS '17; Wulff-Nilsen, FOCS '17; Saranurak and Wang, SODA '19].