On the complexity of local distributed graph problems

M. Ghaffari, F. Kuhn, Yannic Maus
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引用次数: 127

Abstract

This paper is centered on the complexity of graph problems in the well-studied LOCAL model of distributed computing, introduced by Linial [FOCS '87]. It is widely known that for many of the classic distributed graph problems (including maximal independent set (MIS) and (Δ+1)-vertex coloring), the randomized complexity is at most polylogarithmic in the size n of the network, while the best deterministic complexity is typically 2O(√logn). Understanding and potentially narrowing down this exponential gap is considered to be one of the central long-standing open questions in the area of distributed graph algorithms. We investigate the problem by introducing a complexity-theoretic framework that allows us to shed some light on the role of randomness in the LOCAL model. We define the SLOCAL model as a sequential version of the LOCAL model. Our framework allows us to prove completeness results with respect to the class of problems which can be solved efficiently in the SLOCAL model, implying that if any of the complete problems can be solved deterministically in logn rounds in the LOCAL model, we can deterministically solve all efficient SLOCAL-problems (including MIS and (Δ+1)-coloring) in logn rounds in the LOCAL model. Perhaps most surprisingly, we show that a rather rudimentary looking graph coloring problem is complete in the above sense: Color the nodes of a graph with colors red and blue such that each node of sufficiently large polylogarithmic degree has at least one neighbor of each color. The problem admits a trivial zero-round randomized solution. The result can be viewed as showing that the only obstacle to getting efficient determinstic algorithms in the LOCAL model is an efficient algorithm to approximately round fractional values into integer values. In addition, our formal framework also allows us to develop polylogarithmic-time randomized distributed algorithms in a simpler way. As a result, we provide a polylog-time distributed approximation scheme for arbitrary distributed covering and packing integer linear programs.
局部分布图问题的复杂性
本文主要关注Linial [FOCS '87]引入的分布式计算的LOCAL模型中图问题的复杂性。众所周知,对于许多经典的分布式图问题(包括最大独立集(MIS)和(Δ+1)顶点着色),随机复杂度在网络的大小n中最多是多对数的,而最佳确定性复杂度通常是20(√logn)。理解并潜在地缩小这种指数差距被认为是分布式图算法领域长期存在的核心开放问题之一。我们通过引入一个复杂性理论框架来研究这个问题,该框架使我们能够阐明随机性在局部模型中的作用。我们将SLOCAL模型定义为LOCAL模型的顺序版本。我们的框架允许我们证明关于可以在SLOCAL模型中有效解决的问题类别的完备性结果,这意味着如果任何一个完整问题可以在LOCAL模型中在logn轮中确定性地解决,我们可以在LOCAL模型中在logn轮中确定性地解决所有有效的SLOCAL问题(包括MIS和(Δ+1)-coloring)。也许最令人惊讶的是,我们展示了一个相当基本的图着色问题在上面的意义上是完整的:用红色和蓝色给图的节点着色,使得每个足够大的多对数度的节点至少有一个每种颜色的邻居。这个问题允许一个平凡的零轮随机解。结果表明,在LOCAL模型中获得有效的确定性算法的唯一障碍是将分数值近似四舍五入为整数值的有效算法。此外,我们的正式框架还允许我们以更简单的方式开发多对数时间随机分布算法。因此,我们为任意分布覆盖和填充整数线性规划提供了一个多时间分布逼近格式。
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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