The RESET and MARC techniques, with application to multiserver-job analysis

IF 1 4区计算机科学 Q4 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE

Performance Evaluation Pub Date : 2023-10-11 DOI:10.1016/j.peva.2023.102378

Isaac Grosof, Yige Hong, Mor Harchol-Balter, Alan Scheller-Wolf

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引用次数: 0

Abstract

Multiserver-job (MSJ) systems, where jobs need to run concurrently across many servers, are increasingly common in practice. The default service ordering in many settings is First-Come First-Served (FCFS) service. Virtually all theoretical work on MSJ FCFS models focuses on characterizing the stability region, with almost nothing known about mean response time.

We derive the first explicit characterization of mean response time in the MSJ FCFS system. Our formula characterizes mean response time up to an additive constant, which becomes negligible as arrival rate approaches throughput, and allows for general phase-type job durations.

We derive our result by utilizing two key techniques: REduction to Saturated for Expected Time (RESET) and MArkovian Relative Completions (MARC).

Using our novel RESET technique, we reduce the problem of characterizing mean response time in the MSJ FCFS system to an M/M/1 with Markovian service rate (MMSR). The Markov chain controlling the service rate is based on the saturated system, a simpler closed system which is far more analytically tractable.

Unfortunately, the MMSR has no explicit characterization of mean response time. We therefore use our novel MARC technique to give the first explicit characterization of mean response time in the MMSR, again up to constant additive error. We specifically introduce the concept of “relative completions,” which is the cornerstone of our MARC technique.

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RESET和MARC技术，以及在多服务器作业分析中的应用

多服务器作业(MSJ)系统在实践中越来越普遍，其中作业需要在许多服务器上并发运行。在许多设置中，默认的服务顺序是先到先得(FCFS)服务。实际上，所有关于MSJ FCFS模型的理论工作都集中在描述稳定区域上，对平均响应时间几乎一无所知。我们首次导出了MSJ FCFS系统中平均响应时间的显式表征。我们的公式将平均响应时间描述为一个可加常数，当到达率接近吞吐量时，该常数可以忽略不计，并允许一般阶段类型的工作持续时间。我们通过使用两种关键技术得出了我们的结果:预期时间饱和还原(RESET)和马尔可夫相对完井(MARC)。利用我们新颖的RESET技术，我们将MSJ FCFS系统的平均响应时间表征问题降低到具有马尔可夫服务率(MMSR)的M/M/1。控制服务率的马尔可夫链基于饱和系统，这是一种更简单的封闭系统，更易于分析处理。不幸的是，MMSR没有明确的平均响应时间表征。因此，我们使用新颖的MARC技术给出了MMSR中平均响应时间的第一个明确表征，再次达到恒定的加性误差。我们特别介绍了“相对补全”的概念，这是MARC技术的基石。

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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来源期刊

Performance Evaluation 工程技术-计算机：理论方法

CiteScore

3.10

自引率

0.00%

发文量

审稿时长

24 days

期刊介绍： Performance Evaluation functions as a leading journal in the area of modeling, measurement, and evaluation of performance aspects of computing and communication systems. As such, it aims to present a balanced and complete view of the entire Performance Evaluation profession. Hence, the journal is interested in papers that focus on one or more of the following dimensions: -Define new performance evaluation tools, including measurement and monitoring tools as well as modeling and analytic techniques -Provide new insights into the performance of computing and communication systems -Introduce new application areas where performance evaluation tools can play an important role and creative new uses for performance evaluation tools. More specifically, common application areas of interest include the performance of: -Resource allocation and control methods and algorithms (e.g. routing and flow control in networks, bandwidth allocation, processor scheduling, memory management) -System architecture, design and implementation -Cognitive radio -VANETs -Social networks and media -Energy efficient ICT -Energy harvesting -Data centers -Data centric networks -System reliability -System tuning and capacity planning -Wireless and sensor networks -Autonomic and self-organizing systems -Embedded systems -Network science