Distributed Maximal Matching and Maximal Independent Set on Hypergraphs

Abstract

We investigate the distributed complexity of maximal matching and maximal independent set (MIS) in hypergraphs in the LOCAL model. A maximal matching of a hypergraph H=(VH,EH) is a maximal disjoint set M⊂eq EH of hyperedges and an MIS S⊂eq VH is a maximal set of nodes such that no hyperedge is fully contained in S. Both problems can be solved by a simple sequential greedy algorithm, which can be implemented naively in O( r + * n) rounds, where is the maximum degree, r is the rank, and n is the number of nodes. We show that for maximal matching, this naive algorithm is optimal in the following sense. Any deterministic algorithm for solving the problem requires (\ r, r n\) rounds, and any randomized one requires (\ r, r n\) rounds. Hence, for any algorithm with a complexity of the form O(f(, r) + g(n)), we have f(, r) ∈ ( r) if g(n) is not too large, and in particular if g(n) = * n (which is the optimal asymptotic dependency on n due to Linial's lower bound [FOCS'87]). Our lower bound proof is based on the round elimination framework, and its structure is inspired by a new round elimination fixed point that we give for the -vertex coloring problem in hypergraphs. For the MIS problem on hypergraphs, we show that for r, there are significant improvements over the naive O( r + * n)-round algorithm. We give two deterministic algorithms for the problem. We show that a hypergraph MIS can be computed in O(2· r + · r· * r + * n) rounds. We further show that at the cost of a worse dependency on , the dependency on r can be removed almost entirely, by giving an algorithm with complexity O()·* r + O(* n).

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