English

Fast Distributed Algorithms for Connectivity and MST in Large Graphs

Distributed, Parallel, and Cluster Computing 2016-07-07 v3 Data Structures and Algorithms

Abstract

Motivated by the increasing need to understand the algorithmic foundations of distributed large-scale graph computations, we study a number of fundamental graph problems in a message-passing model for distributed computing where k2k \geq 2 machines jointly perform computations on graphs with nn nodes (typically, nkn \gg k). The input graph is assumed to be initially randomly partitioned among the kk machines, a common implementation in many real-world systems. Communication is point-to-point, and the goal is to minimize the number of communication rounds of the computation. Our main result is an (almost) optimal distributed randomized algorithm for graph connectivity. Our algorithm runs in O~(n/k2)\tilde{O}(n/k^2) rounds (O~\tilde{O} notation hides a \polylog(n)\poly\log(n) factor and an additive \polylog(n)\poly\log(n) term). This improves over the best previously known bound of O~(n/k)\tilde{O}(n/k) [Klauck et al., SODA 2015], and is optimal (up to a polylogarithmic factor) in view of an existing lower bound of Ω~(n/k2)\tilde{\Omega}(n/k^2). Our improved algorithm uses a bunch of techniques, including linear graph sketching, that prove useful in the design of efficient distributed graph algorithms. Using the connectivity algorithm as a building block, we then present fast randomized algorithms for computing minimum spanning trees, (approximate) min-cuts, and for many graph verification problems. All these algorithms take O~(n/k2)\tilde{O}(n/k^2) rounds, and are optimal up to polylogarithmic factors. We also show an almost matching lower bound of Ω~(n/k2)\tilde{\Omega}(n/k^2) rounds for many graph verification problems by leveraging lower bounds in random-partition communication complexity.

Keywords

Cite

@article{arxiv.1503.02353,
  title  = {Fast Distributed Algorithms for Connectivity and MST in Large Graphs},
  author = {Gopal Pandurangan and Peter Robinson and Michele Scquizzato},
  journal= {arXiv preprint arXiv:1503.02353},
  year   = {2016}
}
R2 v1 2026-06-22T08:47:09.814Z