Deterministic Distributed Vertex Coloring: Simpler, Faster, and without Network Decomposition

Abstract

We present a simple deterministic distributed algorithm that computes a (+1)-vertex coloring in O(2 · n) rounds. The algorithm can be implemented with O( n)-bit messages. The algorithm can also be extended to the more general (degree+1)-list coloring problem. Obtaining a polylogarithmic-time deterministic algorithm for (+1)-vertex coloring had remained a central open question in the area of distributed graph algorithms since the 1980s, until a recent network decomposition algorithm of Rozhon and Ghaffari [STOC'20]. The current state of the art is based on an improved variant of their decomposition, which leads to an O(5 n)-round algorithm for (+1)-vertex coloring. Our coloring algorithm is completely different and considerably simpler and faster. It solves the coloring problem in a direct way, without using network decomposition, by gradually rounding a certain fractional color assignment until reaching an integral color assignments. Moreover, via the approach of Chang, Li, and Pettie [STOC'18], this improved deterministic algorithm also leads to an improvement in the complexity of randomized algorithms for (+1)-coloring, now reaching the bound of O(3 n) rounds. As a further application, we also provide faster deterministic distributed algorithms for the following variants of the vertex coloring problem. In graphs of arboricity a, we show that a (2+ε)a-vertex coloring can be computed in O(3 a· n) rounds. We also show that for ≥ 3, a -coloring of a -colorable graph G can be computed in O(2 ·2 n) rounds.