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Checkpointing Strategies for Shared High-Performance Computing Platforms

Abstract : Input/output (I/O) from various sources often contend for scarcely available bandwidth. For example, checkpoint/restart (CR) protocols can help to ensure application progress in failure-prone environments. However, CR I/O alongside an application's normal, requisite I/O can increase I/O contention and might negatively impact performance. In this work, we consider different aspects (system-level scheduling policies and hardware) that optimize the overall performance of concurrently executing CR-based applications that share I/O resources. We provide a theoretical model and derive a set of necessary constraints to minimize the global waste on a given platform. Our results demonstrate that Young/Daly's optimal checkpoint interval, despite providing a sensible metric for a single, undisturbed application, is not sufficient to optimally address resource contention at scale. We show that by combining optimal checkpointing periods with contention-aware system-level I/O scheduling strategies, we can significantly improve overall application performance and maximize the platform throughput. Finally, we evaluate how specialized hardware, namely burst buffers, may help to mitigate the I/O contention problem. Overall, these results provide critical analysis and direct guidance on how to design efficient, CR ready, large -scale platforms without a large investment in the I/O subsystem.
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Submitted on : Thursday, September 30, 2021 - 4:43:49 PM
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Thomas Herault, Yves Robert, Aurelien Bouteiller, Arnold Arnold, Kurt Ferreira, et al.. Checkpointing Strategies for Shared High-Performance Computing Platforms. International Journal of Networking and Computing, Higashi Hiroshima : Dept. of Computer Engineering, Hiroshima University, 2019, 9 (1), pp.28-52. ⟨10.15803/ijnc.9.1_28⟩. ⟨hal-03360248⟩



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