Faster Min-Cost Flow and Approximate Tree Decomposition on Bounded Treewidth Graphs
Abstract
We present an algorithm for min-cost flow in graphs with vertices and edges, given a tree decomposition of width and size , and polynomially bounded, integral edge capacities and costs, running in time. This improves upon the previous fastest algorithm in this setting achieved by the bounded-treewidth linear program solver by [Dong-Lee-Ye,21] and [Gu-Song,22], which runs in time, where is the matrix multiplication exponent. Our approach leverages recent advances in structured linear program solvers and robust interior point methods (IPM). For general graphs where treewidth is trivially bounded by , the algorithm runs in time, which is the best-known result without using the Lee-Sidford barrier or IPM, demonstrating the surprising power of robust interior point methods. As a corollary, we obtain a time algorithm to compute a tree decomposition of width , given a graph with edges.
Cite
@article{arxiv.2308.14727,
title = {Faster Min-Cost Flow and Approximate Tree Decomposition on Bounded Treewidth Graphs},
author = {Sally Dong and Guanghao Ye},
journal= {arXiv preprint arXiv:2308.14727},
year = {2024}
}
Comments
15 pages, to appear at ESA 2024