Locally-iterative (+1)-Coloring in Sublinear (in ) Rounds

Abstract

Distributed graph coloring is one of the most extensively studied problems in distributed computing. There is a canonical family of distributed graph coloring algorithms known as the locally-iterative coloring algorithms, first formalized in the seminal work of [Szegedy and Vishwanathan, STOC'93]. In such algorithms, every vertex iteratively updates its own color according to a predetermined function of the current coloring of its local neighborhood. Due to the simplicity and naturalness of its framework, locally-iterative coloring algorithms are of great significance both in theory and practice. In this paper, we give a locally-iterative (+1)-coloring algorithm with O(3/4)+*n running time. This is the first locally-iterative (+1)-coloring algorithm with sublinear-in- running time, and answers the main open question raised in a recent breakthrough [Barenboim, Elkin, and Goldberg, JACM'21]. A key component of our algorithm is a locally-iterative procedure that transforms an O(2)-coloring to a (+O(3/4))-coloring in o() time. Inside this procedure we work on special proper colorings that encode (arb)defective colorings, and reduce the number of used colors quadratically in a locally-iterative fashion. As a main application of our result, we also give a self-stabilizing distributed algorithm for (+1)-coloring with O(3/4)+*n stabilization time. To the best of our knowledge, this is the first self-stabilizing algorithm for (+1)-coloring with sublinear-in- stabilization time.

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