解决在云中执行大规模计算集群的挑战

2018 18th IEEE/ACM International Symposium on Cluster, Cloud and Grid Computing (CCGRID) Pub Date : 2018-05-01 DOI:10.1109/CCGRID.2018.00040

Brandon Posey, Christopher Gropp, Boyd Wilson, Boyd McGeachie, S. Padhi, Alexander Herzog, A. Apon

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引用次数: 7

摘要

研究时间的一个主要限制可能是缺乏可用的计算资源。根据资源的容量，当资源需求量很大时，执行具有数十万个作业的应用程序套件可能需要数周时间。我们描述了如何利用Amazon Web Services (AWS)动态地提供超过一百万核的大规模高性能计算集群。我们将讨论与使用商业云资源创建如此大规模集群相关的权衡、挑战和解决方案。我们利用我们的大规模集群研究了一个由多个数据集上的消息传递并行主题建模作业组成的参数扫描工作流。在峰值时，我们在近50,000个实例中实现了1,119,196个vcpu的同时核心计数，并且能够在单个AWS区域中利用AWS Spot实例在两小时内执行近50万个作业。我们针对挑战和权衡的解决方案广泛应用于其他商业云上类似集群的生命周期管理。

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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Addressing the Challenges of Executing a Massive Computational Cluster in the Cloud

A major limitation for time-to-science can be the lack of available computing resources. Depending on the capacity of resources, executing an application suite with hundreds of thousands of jobs can take weeks when resources are in high demand. We describe how we dynamically provision a large scale high performance computing cluster of more than one million cores utilizing Amazon Web Services (AWS). We discuss the trade-offs, challenges, and solutions associated with creating such a large scale cluster with commercial cloud resources. We utilize our large scale cluster to study a parameter sweep workflow composed of message-passing parallel topic modeling jobs on multiple datasets. At peak, we achieve a simultaneous core count of 1,119,196 vCPUs across nearly 50,000 instances, and are able to execute almost half a million jobs within two hours utilizing AWS Spot Instances in a single AWS region. Our solutions to the challenges and trade-offs have broad application to the lifecycle management of similar clusters on other commercial clouds.

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来源期刊

2018 18th IEEE/ACM International Symposium on Cluster, Cloud and Grid Computing (CCGRID)

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