Semi-Static and Dynamic Load Balancing for Asynchronous Hurricane Storm Surge Simulations

2018 IEEE/ACM Parallel Applications Workshop, Alternatives To MPI (PAW-ATM) Pub Date : 2018-11-01 DOI:10.1109/PAW-ATM.2018.00010

Maximilian H. Bremer, J. Bachan, Cy P. Chan

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引用次数: 6

Abstract

The performance of hurricane storm surge simulations is critical to forecast and mitigate the deadly effects of hurricane landfall. Supercomputers play a key role to run these simulations quickly; however, disruptive changes in future computer architectures will require adapting simulators to maintain high performance, such as increasing asynchrony and improving load balance. We introduce two new multi-constraint, fully asynchronous load balancers and a new discrete-event simulator (DGSim) that is able to natively model the execution of task-based hurricane simulations based on efficient one-sided, active message-based communication protocols. We calibrate and validate DGSim, use it to compare the algorithms' load balancing capabilities and task migration costs under many parameterizations, saving of over 5,000x core-hours compared to running the application code directly. Our load balancing algorithms achieve a performance improvement of up to 56 percent over the original static balancer and up to 97 percent of the optimal speed-up.

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异步飓风风暴潮模拟的半静态和动态负载平衡

飓风风暴潮模拟的性能对预测和减轻飓风登陆的致命影响至关重要。超级计算机在快速运行这些模拟中起着关键作用;然而，未来计算机体系结构的颠覆性变化将需要调整模拟器以保持高性能，例如增加异步性和改善负载平衡。我们介绍了两个新的多约束、全异步负载平衡器和一个新的离散事件模拟器(DGSim)，它能够基于高效的单侧、主动的基于消息的通信协议，对基于任务的飓风模拟的执行进行本地建模。我们校准和验证了DGSim，用它来比较算法的负载平衡能力和许多参数化下的任务迁移成本，与直接运行应用程序代码相比，节省了超过5000倍的核心小时。我们的负载平衡算法比原来的静态平衡器实现了高达56%的性能改进和高达97%的最佳加速。

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

2018 IEEE/ACM Parallel Applications Workshop, Alternatives To MPI (PAW-ATM)

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