Cut-Equivalent Trees are Optimal for Min-Cut QueriesDownload PDFOpen Website

Amir Abboud, Robert Krauthgamer, Ohad Trabelsi

2020 (modified: 17 Sept 2021)FOCS 2020Readers: Everyone
Abstract: Min-Cut queries are fundamental: Preprocess an undirected edge-weighted graph, to quickly report a minimum-weight cut that separates a query pair of nodes s, t. The best data structure known for this problem simply builds a cut-equivalent tree, discovered 60 years ago by Gomory and Hu, who also showed how to construct it using n-1 minimum st-cut computations. Using state-of-the-art algorithms for minimum st-cut (Lee and Sidford, FOCS 2014), one can construct the tree in time ~O(mn <sup xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">3/2</sup> ), which is also the preprocessing time of the data structure. (Throughout, we focus on polynomially-bounded edge weights, noting that faster algorithms are known for small/ u nit edge weights, and use n and m for the number of nodes and edges in the graph.) Our main result shows the following equivalence: Cut-equivalent trees can be constructed in near-linear time if and only if there is a data structure for Min-Cut queries with near-linear preprocessing time and polylogarithmic (amortized) query time, and even if the queries are restricted to a fixed source. That is, equivalent trees are an essentially optimal solution for Min-Cut queries. This equivalence holds even for every minor-closed family of graphs, such as bounded-treewidth graphs, for which a two-decade old data structure (Arikati, Chaudhuri, and Zaroliagis, J. Algorithms 1998) implies the first near-linear time construction of cut-equivalent trees. Moreover, unlike all previous techniques for constructing cut-equivalent trees, ours is robust to relying on approximation algorithms. In particular, using the almost-linear time algorithm for ( 1+ε)-approximate minimum st-cut (Kelner, Lee, Orecchia, and Sidford, SODA 2014), we can construct a ( 1+ε)-approximate flow-equivalent tree (which is a slightly weaker notion) in time n <sup xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">2+o(1)</sup> . This leads to the first ( 1+ε)-approximation for All-Pairs Max-Flow that runs in time n <sup xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">2+o(1)</sup> , and matches the output size almost-optimally.
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