An Automatic Speedup Theorem for Distributed Problems

Proceedings of the 2019 ACM Symposium on Principles of Distributed Computing Pub Date : 2019-02-26 DOI:10.1145/3293611.3331611

S. Brandt

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引用次数: 43

Abstract

Recently, Brandt et al.\ [STOC'16] proved a lower bound for the distributed Lovász Local Lemma, which has been conjectured to be tight for sufficiently relaxed LLL criteria by Chang and Pettie [FOCS'17]. At the heart of their result lies a speedup technique that, for graphs of girth at least 2t+2, transforms any t-round algorithm for one specific LLL problem into a (t-1)-round algorithm for the same problem. We substantially improve on this technique by showing that such a speedup exists for any locally checkable problem ¶i, with the difference that the problem ¶i_1 the inferred (t-1)-round algorithm solves is not (necessarily) the same problem as ¶i. Our speedup is automatic in the sense that there is a fixed procedure that transforms a description for ¶i into a description for ¶i_1 and reversible in the sense that any (t-1)-round algorithm for ¶i_1 can be transformed into a t-round algorithm for ¶i. In particular, for any locally checkable problem ¶i with exact deterministic time complexity T(n, Δ) łeq t on graphs with n nodes, maximum node degree Δ, and girth at least 2t+2, there is a sequence of problems ¶i_1, ¶i_2, \dots with time complexities T(n, Δ)-1, T(n, Δ)-2, \dots, that can be inferred from ¶i. As a first application of our generalized speedup, we solve a long-standing open problem of Naor and Stockmeyer [STOC'93]: we show that weak 2-coloring in odd-degree graphs cannot be solved in o(łog^* Δ) rounds, thereby providing a matching lower bound to their upper bound.

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分布式问题的自动加速定理

最近，Brandt等人[STOC'16]证明了分布式Lovász局部引理的下界，而Chang和Pettie [FOCS'17]已经推测该下界对于充分放松的LLL准则是紧的。他们的结果的核心在于一种加速技术，对于周长至少为2t+2的图，该技术可以将任何用于特定LLL问题的t-round算法转换为用于相同问题的(t-1)-round算法。我们通过展示任何局部可检查问题¶i都存在这样的加速，从而大大改进了这种技术，不同之处在于，推断的(t-1)轮算法解决的问题¶i_1(不一定)与¶i是相同的问题。我们的加速是自动的，因为有一个固定的过程将¶i的描述转换为¶i_1的描述，并且在某种意义上是可逆的，因为任何用于¶i_1的(t-1)轮算法都可以转换为用于¶i的t-轮算法。特别地，对于任何具有精确确定性时间复杂度T(n， Δ) łeq T的局部可检查问题¶i，在具有n个节点，最大节点度Δ，且周长至少为2t+2的图上，存在一系列具有时间复杂度T(n， Δ)-1, T(n， Δ)-2， \dots的问题¶i_1，¶i_2， \dots，可以从¶i推断出来。作为我们的广义加速的第一个应用，我们解决了Naor和Stockmeyer [STOC'93]的一个长期开放问题:我们证明了奇次图中的弱2-着色不能在o(łog^* Δ)轮内解决，从而提供了一个与它们的上界匹配的下界。

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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Proceedings of the 2019 ACM Symposium on Principles of Distributed Computing

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