An Efficient LP Rounding Scheme for Replica Placement

2020 IEEE High Performance Extreme Computing Conference (HPEC) Pub Date : 2020-09-22 DOI:10.1109/HPEC43674.2020.9286163

Zhihui Du, Sen Zhang, David A. Bader, Jingkun Hu

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Abstract

Large fault-tolerant network systems with high Quality of Service (QoS) guarantee are critical in many real world applications and entail diverse replica placement problems. In this paper, the replica placement problem in terms of minimizing the replica placement cost subject to both QoS and fault-tolerant constraints is formulated as a binary integer linear programming problem first and then relaxed as a linear programming problem. Given the optimal fractional linear programming solution, we propose a two-step rounding algorithm to obtain its integer solution. In the first step, a half rounding algorithm is used to simplify the problem. In the second step, a cheapest amortized cost rounding algorithm uses a novel metric, named amortized cost, to make locally optimal rounding decision for the remaining vertices independently. Furthermore, a conflict resolution algorithm is presented to tackle the situations when different vertices make conflicting rounding decisions. Finally, we prove that the proposed two-step rounding algorithm has a 2-approximation ratio when the additional conflict cost meets a given constraint.

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一种用于副本放置的高效LP舍入方案

具有高服务质量(QoS)保证的大型容错网络系统在许多实际应用中是至关重要的，并且会带来各种副本放置问题。本文首先将在QoS和容错约束下最小化副本放置成本的副本放置问题表述为二进制整数线性规划问题，然后将其松弛为线性规划问题。在给定分数阶线性规划最优解的情况下，提出了一种求整数解的两步舍入算法。第一步，采用半舍入算法对问题进行简化。在第二步中，最便宜的平摊代价舍入算法使用一种新的度量，称为平摊代价，对剩余的顶点独立地做出局部最优舍入决策。在此基础上，提出了一种解决不同顶点舍入决策冲突的冲突解决算法。最后，我们证明了当附加冲突代价满足给定约束条件时，所提出的两步舍入算法具有2-近似比。

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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2020 IEEE High Performance Extreme Computing Conference (HPEC)

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