Combinatorial Maximum Flow via Weighted Push-Relabel on Shortcut Graphs
Abstract
We give a combinatorial algorithm for computing exact maximum flows in directed graphs with n vertices and edge capacities from \1,…,U\ in O(n2 U) time, which is near-optimal on dense graphs. This shaves an no(1) factor from the recent result of [Bernstein-Blikstad-Saranurak-Tu FOCS'24] and, more importantly, greatly simplifies their algorithm. We believe that ours is by a significant margin the simplest of all algorithms that go beyond O(mn) time in general graphs. To highlight this relative simplicity, we provide a full implementation of the algorithm in C++. The only randomized component of our work is the cut-matching game. Via existing tools, we show how to derandomize it for vertex-capacitated max flow and obtain a deterministic O(n2) time algorithm. This marks the first deterministic near-linear time algorithm for this problem (or even for the special case of bipartite matching) in any density regime.
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