Near-optimal Distributed Triangle Enumeration via Expander Decompositions

IF 2.3 2区计算机科学 Q2 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE Journal of the ACM Pub Date : 2021-05-13 DOI:10.1145/3446330

Yi-Jun Chang, S. Pettie, Thatchaphol Saranurak, Hengjie Zhang

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引用次数: 13

Abstract

We present improved distributed algorithms for variants of the triangle finding problem in the

model. We show that triangle detection, counting, and enumeration can be solved in

rounds using expander decompositions . This matches the triangle enumeration lower bound of

by Izumi and Le Gall [PODC’17] and Pandurangan, Robinson, and Scquizzato [SPAA’18], which holds even in the

model. The previous upper bounds for triangle detection and enumeration in

were

and

, respectively, due to Izumi and Le Gall [PODC’17]. An

-expander decomposition of a graph

is a clustering of the vertices

such that (i) each cluster

induces a subgraph with conductance at least

and (ii) the number of inter-cluster edges is at most

. We show that an

-expander decomposition with

can be constructed in

rounds for any

and positive integer

. For example, a

-expander decomposition only requires

rounds to compute, which is optimal up to subpolynomial factors, and a

-expander decomposition can be computed in

rounds, for any arbitrarily small constant

. Our triangle finding algorithms are based on the following generic framework using expander decompositions, which is of independent interest. We first construct an expander decomposition. For each cluster, we simulate

algorithms with small overhead by applying the expander routing algorithm due to Ghaffari, Kuhn, and Su [PODC’17] Finally, we deal with inter-cluster edges using recursive calls.

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基于扩展器分解的近最优分布三角枚举

我们提出了改进的分布式算法来解决模型中三角形查找问题的变体。我们证明了三角形检测、计数和枚举可以使用扩展器分解在轮询中解决。这与Izumi和Le Gall [PODC ' 17]以及Pandurangan、Robinson和Scquizzato [SPAA ' 18]的三角枚举下界相吻合，即使在模型中也成立。由于Izumi和Le Gall [PODC ' 17]，之前的三角形检测和枚举上界分别为和。图的扩展分解是顶点的聚类，使得(i)每个聚类诱导出一个电导最少且(ii)簇间边数最多的子图。我们证明了对于任意的-展开式分解都可以被构造为整数一个正整数。例如，-展开器分解只需要计算轮数，这是最优的次多项式因子，对于任意小的常数，展开分解都可以以轮为单位计算。我们的三角查找算法基于以下使用扩展器分解的通用框架，这是独立的兴趣。我们首先构造一个展开器分解。对于每个集群，我们通过应用基于Ghaffari、Kuhn和Su [PODC ' 17]的扩展路由算法来模拟开销较小的算法。最后，我们使用递归调用处理集群间边缘。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of the ACM 工程技术-计算机：理论方法

CiteScore

7.50

自引率

0.00%

发文量

审稿时长

3 months

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