New Classes of Distributed Time Complexity

Abstract

A number of recent papers -- e.g. Brandt et al. (STOC 2016), Chang et al. (FOCS 2016), Ghaffari & Su (SODA 2017), Brandt et al. (PODC 2017), and Chang & Pettie (FOCS 2017) -- have advanced our understanding of one of the most fundamental questions in theory of distributed computing: what are the possible time complexity classes of LCL problems in the LOCAL model? In essence, we have a graph problem in which a solution can be verified by checking all radius-O(1) neighbourhoods, and the question is what is the smallest T such that a solution can be computed so that each node chooses its own output based on its radius-T neighbourhood. Here T is the distributed time complexity of . The time complexity classes for deterministic algorithms in bounded-degree graphs that are known to exist by prior work are (1), (* n), ( n), (n1/k), and (n). It is also known that there are two gaps: one between ω(1) and o( * n), and another between ω(* n) and o( n). It has been conjectured that many more gaps exist, and that the overall time hierarchy is relatively simple -- indeed, this is known to be the case in restricted graph families such as cycles and grids. We show that the picture is much more diverse than previously expected. We present a general technique for engineering LCL problems with numerous different deterministic time complexities, including (αn) for any α1, 2(αn) for any α 1, and (nα) for any α <1/2 in the high end of the complexity spectrum, and (α* n) for any α 1, 2(α* n) for any α 1, and ((* n)α) for any α 1 in the low end; here α is a positive rational number.