# Distributed Exact Shortest Paths in Sublinear Time

**Authors:** Michael Elkin

arXiv: 1703.01939 · 2017-05-02

## TL;DR

This paper presents sublinear-time distributed algorithms for exact shortest paths in graphs, significantly improving over classical methods and addressing longstanding open problems in distributed computing.

## Contribution

It introduces the first sublinear-time distributed algorithms for exact shortest paths and the first complexity-guaranteed algorithm for the semi-streaming model.

## Key findings

- Achieves sublinear time for single-source shortest paths when D = o(n/ log^2 n)
- Provides a sublinear-time algorithm for all-pairs shortest paths
- Develops the first non-trivial complexity guarantees in the semi-streaming model

## Abstract

The distributed single-source shortest paths problem is one of the most fundamental and central problems in the message-passing distributed computing. Classical Bellman-Ford algorithm solves it in $O(n)$ time, where $n$ is the number of vertices in the input graph $G$. Peleg and Rubinovich (FOCS'99) showed a lower bound of $\tilde{\Omega}(D + \sqrt{n})$ for this problem, where $D$ is the hop-diameter of $G$.   Whether or not this problem can be solved in $o(n)$ time when $D$ is relatively small is a major notorious open question. Despite intensive research \cite{LP13,N14,HKN15,EN16,BKKL16} that yielded near-optimal algorithms for the approximate variant of this problem, no progress was reported for the original problem.   In this paper we answer this question in the affirmative. We devise an algorithm that requires $O((n \log n)^{5/6})$ time, for $D = O(\sqrt{n \log n})$, and $O(D^{1/3} \cdot (n \log n)^{2/3})$ time, for larger $D$. This running time is sublinear in $n$ in almost the entire range of parameters, specifically, for $D = o(n/\log^2 n)$. For the all-pairs shortest paths problem, our algorithm requires $O(n^{5/3} \log^{2/3} n)$ time, regardless of the value of $D$.   We also devise the first algorithm with non-trivial complexity guarantees for computing exact shortest paths in the multipass semi-streaming model of computation.   From the technical viewpoint, our algorithm computes a hopset $G"$ of a skeleton graph $G'$ of $G$ without first computing $G'$ itself. We then conduct a Bellman-Ford exploration in $G' \cup G"$, while computing the required edges of $G'$ on the fly. As a result, our algorithm computes exactly those edges of $G'$ that it really needs, rather than computing approximately the entire $G'$.

## Full text

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## References

43 references — full list in the complete paper: https://tomesphere.com/paper/1703.01939/full.md

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Source: https://tomesphere.com/paper/1703.01939