Invasive computing in HPC with X10

X10 '13 Pub Date : 2013-06-20 DOI:10.1145/2481268.2481274

H. Bungartz, C. Riesinger, Martin Schreiber, G. Snelting, Andreas Zwinkau

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引用次数: 14

Abstract

High performance computing with thousands of cores relies on distributed memory due to memory consistency reasons. The resource management on such systems usually relies on static assignment of resources at the start of each application. Such a static scheduling is incapable of starting applications with required resources being used by others since a reduction of resources assigned to applications without stopping them is not possible. This lack of dynamic adaptive scheduling leads to idling resources until the remaining amount of requested resources gets available. Additionally, applications with changing resource requirements lead to idling or less efficiently used resources. The invasive computing paradigm suggests dynamic resource scheduling and applications able to dynamically adapt to changing resource requirements. As a case study, we developed an invasive resource manager as well as a multigrid with dynamically changing resource demands. Such a multigrid has changing scalability behavior during its execution and requires data migration upon reallocation due to distributed memory systems. To counteract the additional complexity introduced by the additional interfaces, e. g. for data migration, we use the X10 programming language for improved programmability. Our results show improved application throughput and the dynamic adaptivity. In addition, we show our extension for the distributed arrays of X10 to support data migration.

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X10在HPC中的侵入性计算

由于内存一致性的原因，数千核的高性能计算依赖于分布式内存。此类系统上的资源管理通常依赖于每个应用程序开始时的静态资源分配。这种静态调度无法启动其他应用程序正在使用所需资源的应用程序，因为不可能在不停止应用程序的情况下减少分配给应用程序的资源。缺乏动态自适应调度会导致资源闲置，直到剩余的请求资源可用为止。此外，资源需求不断变化的应用程序会导致资源闲置或使用效率降低。侵入式计算范式建议动态资源调度和应用程序能够动态适应不断变化的资源需求。作为一个案例研究，我们开发了一个侵入式资源管理器以及一个具有动态变化资源需求的多网格。这种多网格在执行过程中具有不断变化的可伸缩性行为，并且由于分布式内存系统，需要在重新分配时进行数据迁移。为了抵消额外接口(例如数据迁移)带来的额外复杂性，我们使用X10编程语言来改进可编程性。结果表明，该方法提高了应用程序的吞吐量和动态适应性。此外，我们还展示了用于支持数据迁移的X10分布式数组的扩展。

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

X10 '13

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