局部图问题的节点和边平均复杂度

IF 1.3 4区 计算机科学 Q3 COMPUTER SCIENCE, THEORY & METHODS
Alkida Balliu, Mohsen Ghaffari, Fabian Kuhn, Dennis Olivetti
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引用次数: 4

摘要

我们继续最近开始的关于分布式图算法的分布式节点平均复杂度的工作。运行在图\(G=(V,E)\)上的分布式算法的节点平均复杂度是节点V (G)完成计算并提交其输出的时间的平均值。我们研究了一些中心分布对称破缺问题的节点平均复杂性,并提供了以下结果(其中包括)。作为我们的主要结果,我们证明了在最大度\(\Delta \)的n节点图中计算最大独立集(MIS)的随机节点平均复杂度至少为\(\Omega \big (\min \big \{\frac{\log \Delta }{\log \log \Delta },\sqrt{\frac{\log n}{\log \log n}}\big \}\big )\)。这个边界是由Kuhn, Moscibroda和Wattenhofer [JACM ' 16]对众所周知的下界进行了新的改编得到的。作为一个副产品,我们得到了计算树状管理信息系统的最坏情况随机轮复杂度也是\(\Omega \big (\min \big \{\frac{\log \Delta }{\log \log \Delta },\sqrt{\frac{\log n}{\log \log n}}\big \}\big )\)——这基本上回答了巴伦博伊姆和埃尔金书中的开放问题11.15,并将树状管理信息系统的复杂度解决到\(O(\sqrt{\log \log n})\)因子。我们还表明,也许令人惊讶的是,对于(2,2)-统治集问题,MIS的最小松弛(与(2,1)-统治集问题相同)将随机节点平均复杂度降低到O(1)。对于最大匹配,我们证明了随机节点平均复杂度为\(\Omega \big (\min \big \{\frac{\log \Delta }{\log \log \Delta },\sqrt{\frac{\log n}{\log \log n}}\big \}\big )\),随机边平均复杂度为O(1)。进一步证明了最大匹配的确定性边平均复杂度为\(O(\log ^2\Delta + \log ^* n)\),最大匹配的确定性节点平均复杂度为\(O(\log ^3\Delta + \log ^* n)\)。最后,我们考虑了图的无下沉方向的计算问题。已知问题的确定性最坏情况复杂度为\(\Theta (\log n)\),即使在有界度图上也是如此。我们证明了这个问题可以用节点平均复杂度\(O(\log ^* n)\)确定性地解决,同时保持最坏情况的复杂度\(O(\log n)\)。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Node and edge averaged complexities of local graph problems

Node and edge averaged complexities of local graph problems

We continue the recently started line of work on the distributed node-averaged complexity of distributed graph algorithms. 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 of the central distributed symmetry breaking problems and provide the following results (among others). As our main result, we show that the randomized node-averaged complexity of computing a maximal independent set (MIS) in n-node graphs of maximum degree \(\Delta \) is at least \(\Omega \big (\min \big \{\frac{\log \Delta }{\log \log \Delta },\sqrt{\frac{\log n}{\log \log n}}\big \}\big )\). This bound is obtained by a novel adaptation of the well-known lower bound by Kuhn, Moscibroda, and Wattenhofer [JACM’16]. As a side result, we obtain that the worst-case randomized round complexity for computing an MIS in trees is also \(\Omega \big (\min \big \{\frac{\log \Delta }{\log \log \Delta },\sqrt{\frac{\log n}{\log \log n}}\big \}\big )\)—this essentially answers open problem 11.15 in the book by Barenboim and Elkin and resolves the complexity of MIS on trees up to an \(O(\sqrt{\log \log n})\) factor. We also show that, perhaps surprisingly, a minimal relaxation of MIS, which is the same as (2, 1)-ruling set, to the (2, 2)-ruling set problem drops the randomized node-averaged complexity to O(1). For maximal matching, we show that while the randomized node-averaged complexity is \(\Omega \big (\min \big \{\frac{\log \Delta }{\log \log \Delta },\sqrt{\frac{\log n}{\log \log n}}\big \}\big )\), the randomized edge-averaged complexity is O(1). Further, we show that the deterministic edge-averaged complexity of maximal matching is \(O(\log ^2\Delta + \log ^* n)\) and the deterministic node-averaged complexity of maximal matching is \(O(\log ^3\Delta + \log ^* n)\). 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 \(\Theta (\log n)\), even on bounded-degree graphs. We show that the problem can be solved deterministically with node-averaged complexity \(O(\log ^* n)\), while keeping the worst-case complexity in \(O(\log n)\).

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来源期刊
Distributed Computing
Distributed Computing 工程技术-计算机:理论方法
CiteScore
3.20
自引率
0.00%
发文量
24
审稿时长
>12 weeks
期刊介绍: The international journal Distributed Computing provides a forum for original and significant contributions to the theory, design, specification and implementation of distributed systems. Topics covered by the journal include but are not limited to: design and analysis of distributed algorithms; multiprocessor and multi-core architectures and algorithms; synchronization protocols and concurrent programming; distributed operating systems and middleware; fault-tolerance, reliability and availability; architectures and protocols for communication networks and peer-to-peer systems; security in distributed computing, cryptographic protocols; mobile, sensor, and ad hoc networks; internet applications; concurrency theory; specification, semantics, verification, and testing of distributed systems. In general, only original papers will be considered. By virtue of submitting a manuscript to the journal, the authors attest that it has not been published or submitted simultaneously for publication elsewhere. However, papers previously presented in conference proceedings may be submitted in enhanced form. If a paper has appeared previously, in any form, the authors must clearly indicate this and provide an account of the differences between the previously appeared form and the submission.
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