Improved Bounds for Distributed Load Balancing

Proceedings of the ... International Symposium on High Performance Distributed Computing Pub Date : 2020-08-10 DOI:10.4230/LIPIcs.DISC.2020.1

Sepehr Assadi, A. Bernstein, Zachary Langley

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引用次数: 7

Abstract

In the load balancing problem, the input is an $n$-vertex bipartite graph $G = (C \cup S, E)$ and a positive weight for each client $c \in C$. The algorithm must assign each client $c \in C$ to an adjacent server $s \in S$. The load of a server is then the weighted sum of all the clients assigned to it. The goal is to compute an assignment that minimizes some function of the server loads, typically either the maximum server load (i.e., the $\ell_{\infty}$-norm) or the $\ell_p$-norm of the server loads. We study load balancing in the distributed setting. There are two existing results in the CONGEST model. Czygrinow et al. [DISC 2012] showed a 2-approximation for unweighted clients with round-complexity $O(\Delta^5)$, where $\Delta$ is the maximum degree of the input graph. Halldorsson et al. [SPAA 2015] showed an $O(\log{n}/\log\log{n})$-approximation for unweighted clients and $O(\log^2\!{n}/\log\log{n})$-approximation for weighted clients with round-complexity polylog$(n)$. In this paper, we show the first distributed algorithms to compute an $O(1)$-approximation to the load balancing problem in polylog$(n)$ rounds. In the CONGEST model, we give an $O(1)$-approximation algorithm in polylog$(n)$ rounds for unweighted clients. For weighted clients, the approximation ratio is $O(\log{n})$. In the less constrained LOCAL model, we give an $O(1)$-approximation algorithm for weighted clients in polylog$(n)$ rounds. Our approach also has implications for the standard sequential setting in which we obtain the first $O(1)$-approximation for this problem that runs in near-linear time. A 2-approximation is already known, but it requires solving a linear program and is hence much slower. Finally, we note that all of our results simultaneously approximate all $\ell_p$-norms, including the $\ell_{\infty}$-norm.

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改进的分布式负载平衡边界

在负载平衡问题中，输入是一个$n$ -顶点二部图$G = (C \cup S, E)$和每个客户端的正权$c \in C$。该算法必须将每个客户端$c \in C$分配给相邻的服务器$s \in S$。服务器的负载是分配给它的所有客户机的加权和。目标是计算一个分配，使服务器负载的某些功能最小化，通常是最大服务器负载(即$\ell_{\infty}$ -norm)或服务器负载的$\ell_p$ -norm。我们研究了分布式环境下的负载均衡。在CONGEST模型中有两个现有的结果。Czygrinow等人[DISC 2012]展示了具有循环复杂度$O(\Delta^5)$的未加权客户端的2近似，其中$\Delta$是输入图的最大程度。Halldorsson等人[SPAA 2015]用循环复杂度多元对数$(n)$显示了未加权客户端的$O(\log{n}/\log\log{n})$ -近似和加权客户端的$O(\log^2\!{n}/\log\log{n})$ -近似。在本文中，我们展示了第一个分布式算法来计算polylog $(n)$轮中负载平衡问题的$O(1)$ -近似。在CONGEST模型中，对于未加权的客户端，我们给出了在polylog $(n)$轮中的$O(1)$ -近似算法。对于加权客户端，近似比率为$O(\log{n})$。在约束较少的LOCAL模型中，我们给出了polylog $(n)$轮中加权客户端的$O(1)$ -逼近算法。我们的方法也适用于标准顺序设置，在该设置中，我们获得了该问题在近线性时间内运行的第一个$O(1)$ -近似。2近似是已知的，但它需要求解线性程序，因此要慢得多。最后，我们注意到我们所有的结果同时近似所有$\ell_p$ -范数，包括$\ell_{\infty}$ -范数。

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 ... International Symposium on High Performance Distributed Computing

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