Maximum Matching in Two, Three, and a Few More Passes Over Graph Streams

Abstract

We consider the maximum matching problem in the semi-streaming model formalized by Feigenbaum, Kannan, McGregor, Suri, and Zhang that is inspired by giant graphs of today. As our main result, we give a two-pass (1/2 + 1/16)-approximation algorithm for triangle-free graphs and a two-pass (1/2 + 1/32)-approximation algorithm for general graphs; these improve the approximation ratios of 1/2 + 1/52 for bipartite graphs and 1/2 + 1/140 for general graphs by Konrad, Magniez, and Mathieu. In three passes, we achieve approximation ratios of 1/2 + 1/10 for triangle-free graphs and 1/2 + 1/19.753 for general graphs. We also give a multi-pass algorithm where we bound the number of passes precisely---we give a (2/3 -)-approximation algorithm that uses 2/(3) passes for triangle-free graphs and 4/(3) passes for general graphs. Our algorithms are simple and combinatorial, use O(n n) space, and have O(1) update time per edge. For general graphs, our multi-pass algorithm improves the best known deterministic algorithms in terms of the number of passes: --Ahn and Guha give a (2/3 - )-approximation algorithm that uses O((1/)/2) passes, whereas our (2/3 - )-approximation algorithm uses 4/(3) passes; --they also give a (1-)-approximation algorithm that uses O( n · poly(1/)) passes, where n is the number of vertices of the input graph; although our algorithm is (2/3 - )-approximation, our number of passes do not depend on n. Earlier multi-pass algorithms either have a large constant inside big-O notation for the number of passes or the constant cannot be determined due to the involved analysis, so our multi-pass algorithm should use much fewer passes for approximation ratios bounded slightly below 2/3.