Component-distinguishable Co-location and Resource Reclamation for High-throughput Computing

IF 2 4区计算机科学 Q2 COMPUTER SCIENCE, THEORY & METHODS ACM Transactions on Computer Systems Pub Date : 2023-11-18 DOI:10.1145/3630006

Laiping Zhao, Yushuai Cui, Yanan Yang, Xiaobo Zhou, Tie Qiu, Keqiu Li, Yungang Bao

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Abstract

Cloud service providers improve resource utilization by co-locating latency-critical (LC) workloads with best-effort batch (BE) jobs in datacenters. However, they usually treat multi-component LCs as monolithic applications and treat BEs as ”second-class citizens” when allocating resources to them. Neglecting the inconsistent interference tolerance abilities of LC components and the inconsistent preemption loss of BE workloads can result in missed co-location opportunities for higher throughput.

We present Rhythm, a co-location controller that deploys workloads and reclaims resources rhythmically for maximizing the system throughput while guaranteeing LC service’s tail latency requirement. The key idea is to differentiate the BE throughput launched with each LC component, that is, components with higher interference tolerance can be deployed together with more BE jobs. It also assigns different reclamation priority values to BEs by evaluating their preemption losses into a multi-level reclamation queue. We implement and evaluate Rhythm using workloads in the form of containerized processes and microservices. Experimental results show that it can improve the system throughput by 47.3%, CPU utilization by 38.6%, and memory bandwidth utilization by 45.4% while guaranteeing the tail latency requirement.

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面向高吞吐量计算的组件可区分的协同定位和资源回收

云服务提供商通过将延迟关键型(LC)工作负载与尽力而为的批处理(BE)作业放在数据中心中，从而提高资源利用率。然而，他们通常将多组件lc视为整体应用程序，并在为它们分配资源时将BEs视为“二等公民”。忽略LC组件的不一致的干扰容忍能力和BE工作负载的不一致的抢占损失可能会导致错过更高吞吐量的共址机会。我们提出了一种协同位置控制器Rhythm，它可以有节奏地部署工作负载和回收资源，以最大限度地提高系统吞吐量，同时保证LC服务的尾部延迟要求。关键思想是区分每个LC组件启动的BE吞吐量，即具有更高干扰容限的组件可以与更多的BE作业一起部署。它还通过评估BEs在多级回收队列中的抢占损失，为它们分配不同的回收优先级值。我们使用容器化流程和微服务形式的工作负载来实现和评估Rhythm。实验结果表明，在保证尾部延迟要求的情况下，该方法可将系统吞吐量提高47.3%，CPU利用率提高38.6%，内存带宽利用率提高45.4%。

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来源期刊

ACM Transactions on Computer Systems 工程技术-计算机：理论方法

CiteScore

4.00

自引率

0.00%

发文量

审稿时长

1 months

期刊介绍： ACM Transactions on Computer Systems (TOCS) presents research and development results on the design, implementation, analysis, evaluation, and use of computer systems and systems software. The term "computer systems" is interpreted broadly and includes operating systems, systems architecture and hardware, distributed systems, optimizing compilers, and the interaction between systems and computer networks. Articles appearing in TOCS will tend either to present new techniques and concepts, or to report on experiences and experiments with actual systems. Insights useful to system designers, builders, and users will be emphasized. TOCS publishes research and technical papers, both short and long. It includes technical correspondence to permit commentary on technical topics and on previously published papers.