Modeling the Impact of Checkpoints on Next-Generation Systems

24th IEEE Conference on Mass Storage Systems and Technologies (MSST 2007) Pub Date : 2007-09-24 DOI:10.1109/MSST.2007.24

R. Oldfield, Sarala Arunagiri, P. Teller, Seetharami R. Seelam, Maria Ruiz Varela, R. Riesen, P. Roth

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引用次数: 142

Abstract

The next generation of capability-class, massively parallel processing (MPP) systems is expected to have hundreds of thousands of processors. For application-driven, periodic checkpoint operations, the state-of-the-art does not provide a solution that scales to next-generation systems. We demonstrate this by using mathematical modeling to compute a lower bound of the impact of these approaches on the performance of applications executed on three massive-scale, in-production, DOE systems and a theoretical petaflop system. We also adapt the model to investigate a proposed optimization that makes use of "lightweight" storage architectures and overlay networks to overcome the storage system bottleneck. Our results indicate that (1) as we approach the scale of next-generation systems, traditional checkpoint/restart approaches will increasingly impact application performance, accounting for over 50% of total application execution time; (2) although our alternative approach improves performance, it has limitations of its own; and (3) there is a critical need for new approaches to fault tolerance that allow continuous computing with minimal impact on application scalability.

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模拟检查点对下一代系统的影响

下一代功能级大规模并行处理(MPP)系统预计将拥有数十万个处理器。对于应用程序驱动的周期性检查点操作，最先进的技术并没有提供可扩展到下一代系统的解决方案。我们通过使用数学建模来计算这些方法对在三个大规模生产的DOE系统和一个理论上的petaflop系统上执行的应用程序性能的影响的下界来证明这一点。我们还对该模型进行了调整，以研究一种利用“轻量级”存储架构和覆盖网络来克服存储系统瓶颈的建议优化。我们的研究结果表明:(1)当我们接近下一代系统的规模时，传统的检查点/重启方法将越来越多地影响应用程序的性能，占应用程序总执行时间的50%以上;(2)虽然我们的替代方法提高了性能，但它有其自身的局限性;(3)迫切需要新的容错方法，以允许在对应用程序可伸缩性影响最小的情况下进行连续计算。

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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24th IEEE Conference on Mass Storage Systems and Technologies (MSST 2007)

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