Node and Edge Averaged Complexities of Local Graph Problems

Abstract

The node-averaged complexity of a distributed algorithm running on a graph G=(V,E) is the average over the times at which the nodes V of G finish their computation and commit to their outputs. We study the node-averaged complexity for some distributed symmetry breaking problems and provide the following results (among others): - The randomized node-averaged complexity of computing a maximal independent set (MIS) in n-node graphs of maximum degree is at least (\, n n\). This bound is obtained by a novel adaptation of the well-known KMW lower bound [JACM'16]. As a side result, we obtain the same lower bound for the worst-case randomized round complexity for computing an MIS in trees -- this essentially answers open problem 11.15 in the book of Barenboim and Elkin and resolves the complexity of MIS on trees up to an O( n) factor. We also show that, (2,2)-ruling sets, which are a minimal relaxation of MIS, have O(1) randomized node-averaged complexity. - For maximal matching, we show that while the randomized node-averaged complexity is (\, n n\), the randomized edge-averaged complexity is O(1). Further, we show that the deterministic edge-averaged complexity of maximal matching is O(2 + * n) and the deterministic node-averaged complexity of maximal matching is O(3 + * n). - Finally, we consider the problem of computing a sinkless orientation of a graph. The deterministic worst-case complexity of the problem is known to be ( n), even on bounded-degree graphs. We show that the problem can be solved deterministically with node-averaged complexity O(* n), while keeping the worst-case complexity in O( n).