A simple deterministic near-linear time approximation scheme for transshipment with arbitrary positive edge costs

Abstract

We describe a simple deterministic near-linear time approximation scheme for uncapacitated minimum cost flow in undirected graphs with real edge weights, a problem also known as transshipment. Specifically, our algorithm takes as input a (connected) undirected graph G = (V, E), vertex demands b ∈ RV such that Σv ∈ V b(v) = 0, positive edge costs c ∈ R>0E, and a parameter > 0. In O(-2 m O(1) n) time, it returns a flow f such that the net flow out of each vertex is equal to the vertex's demand and the cost of the flow is within a (1 + ) factor of optimal. Our algorithm is combinatorial and has no running time dependency on the demands or edge costs. With the exception of a recent result presented at STOC 2022 for polynomially bounded edge weights, all almost- and near-linear time approximation schemes for transshipment relied on randomization to embed the problem instance into low-dimensional space. Our algorithm instead deterministically approximates the cost of routing decisions that would be made if the input were subject to a random tree embedding. To avoid computing the (n2) vertex-vertex distances that an approximation of this kind suggests, we also take advantage of the clustering method used in the well-known Thorup-Zwick distance oracle.