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|Title:||Work-efficient parallel union-find|
Kun Lung Wu
IBM Thomas J. Watson Research Center
University of Massachusetts Amherst
Iowa State University
|Citation:||Concurrency Computation. Vol.30, No.4 (2018)|
|Abstract:||Copyright © 2017 John Wiley & Sons, Ltd. The incremental graph connectivity (IGC) problem is to maintain a data structure that can quickly answer whether two given vertices in a graph are connected, while allowing more edges to be added to the graph. IGC is a fundamental problem and can be solved efficiently in the sequential setting using a solution to the classical union-find problem. However, sequential solutions are not sufficient to handle modern-day large, rapidly-changing graphs where edge updates arrive at a very high rate. We present the first shared-memory parallel data structure for union-find (equivalently, IGC) that is both provably work-efficient (ie, performs no more work than the best sequential counterpart) and has polylogarithmic parallel depth. We also present a simpler algorithm with slightly worse theoretical properties, but which is easier to implement and has good practical performance. Our experiments on large graph streams with various degree distributions show that it has good practical performance, capable of processing hundreds of millions of edges per second using a 20-core machine.|
|Appears in Collections:||Scopus 2018|
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