Minimum Cost Flow in the CONGEST Model
Abstract
We consider the CONGEST model on a network with nodes, edges, diameter , and integer costs and capacities bounded by . In this paper, we show how to find an exact solution to the minimum cost flow problem in rounds, improving the state of the art algorithm with running time [Forster et al. FOCS 2021], which only holds for the special case of unit capacity graphs. For certain graphs, we achieve even better results. In particular, for planar graphs, expander graphs, -genus graphs, -treewidth graphs, and excluded-minor graphs our algorithm takes rounds. We obtain this result by combining recent results on Laplacian solvers in the CONGEST model [Forster et al. FOCS 2021, Anagnostides et al. DISC 2022] with a CONGEST implementation of the LP solver of Lee and Sidford [FOCS 2014], and finally show that we can round the approximate solution to an exact solution. Our algorithm solves certain linear programs, that generalize minimum cost flow, up to additive error in rounds.
Cite
@article{arxiv.2304.01600,
title = {Minimum Cost Flow in the CONGEST Model},
author = {Tijn de Vos},
journal= {arXiv preprint arXiv:2304.01600},
year = {2023}
}
Comments
To be presented at the ACM Symposium on Principles of Distributed Computing (PODC 2023) as brief announcement and at the 30th International Colloquium on Strucutural Information and Communication Complexity (SIROCCO 2023) as full paper