Sublogarithmic Distributed Algorithms for Lov\'asz Local lemma, and the Complexity Hierarchy

Abstract

Locally Checkable Labeling (LCL) problems include essentially all the classic problems of LOCAL distributed algorithms. In a recent enlightening revelation, Chang and Pettie [arXiv 1704.06297] showed that any LCL (on bounded degree graphs) that has an o( n)-round randomized algorithm can be solved in TLLL(n) rounds, which is the randomized complexity of solving (a relaxed variant of) the Lov\'asz Local Lemma (LLL) on bounded degree n-node graphs. Currently, the best known upper bound on TLLL(n) is O( n), by Chung, Pettie, and Su [PODC'14], while the best known lower bound is ( n), by Brandt et al. [STOC'16]. Chang and Pettie conjectured that there should be an O( n)-round algorithm. Making the first step of progress towards this conjecture, and providing a significant improvement on the algorithm of Chung et al. [PODC'14], we prove that TLLL(n)= 2O( n). Thus, any o( n)-round randomized distributed algorithm for any LCL problem on bounded degree graphs can be automatically sped up to run in 2O( n) rounds. Using this improvement and a number of other ideas, we also improve the complexity of a number of graph coloring problems (in arbitrary degree graphs) from the O( n)-round results of Chung, Pettie and Su [PODC'14] to 2O( n). These problems include defective coloring, frugal coloring, and list vertex-coloring.