Distributed Verification and Hardness of Distributed Approximation

TL;DR

This paper systematically studies the verification problem in distributed networks, establishing tight lower bounds on verification time and deriving strong unconditional hardness results for distributed approximation of fundamental problems like MST and shortest paths.

Contribution

It provides almost tight lower bounds for distributed verification problems and introduces new unconditional hardness results for distributed approximation of classical optimization problems.

Findings

Almost tight lower bounds for verification of connectivity, spanning subgraphs, and cuts.

Unconditional lower bounds on the hardness of distributed approximation for MST, shortest paths, and min cut.

Improves and subsumes previous bounds for MST approximation and computation.

Abstract

We study the {\em verification} problem in distributed networks, stated as follows. Let $H$ be a subgraph of a network $G$ where each vertex of $G$ knows which edges incident on it are in $H$. We would like to verify whether $H$ has some properties, e.g., if it is a tree or if it is connected. We would like to perform this verification in a decentralized fashion via a distributed algorithm. The time complexity of verification is measured as the number of rounds of distributed communication. In this paper we initiate a systematic study of distributed verification, and give almost tight lower bounds on the running time of distributed verification algorithms for many fundamental problems such as connectivity, spanning connected subgraph, and $s-t$ cut verification. We then show applications of these results in deriving strong unconditional time lower bounds on the {\em hardness of distributed approximation} for many classical optimization problems including minimum spanning tree, shortest paths, and minimum cut. Many of these results are the first non-trivial lower bounds for both exact and approximate distributed computation and they resolve previous open questions. Moreover, our unconditional lower bound of approximating minimum spanning tree (MST) subsumes and improves upon the previous hardness of approximation bound of Elkin [STOC 2004] as well as the lower bound for (exact) MST computation of Peleg and Rubinovich [FOCS 1999]. Our result implies that there can be no distributed approximation algorithm for MST that is significantly faster than the current exact algorithm, for {\em any} approximation factor. Our lower bound proofs show an interesting connection between communication complexity and distributed computing which turns out to be useful in establishing the time complexity of exact and approximate distributed computation of many problems.