Modeling and simulating multiple failure masking enabled by local recovery for stencil-based applications at extreme scales

Marc Gamell; Keita Teranishi; Jackson Mayo; Hemanth Kolla; Michael A. Heroux; Jacqueline Chen; Manish Parashar

doi:10.1109/TPDS.2017.2696538

Modeling and simulating multiple failure masking enabled by local recovery for stencil-based applications at extreme scales

Marc Gamell
, Keita Teranishi
, Jackson Mayo
, Hemanth Kolla
, Michael A. Heroux
, Jacqueline Chen
, Manish Parashar

Research output: Contribution to journal › Article › peer-review

12 Scopus citations

Abstract

Obtaining multi-process hard failure resilience at the application level is a key challenge that must be overcome before the promise of exascale can be fully realized. Previous work has shown that online global recovery can dramatically reduce the overhead of failures when compared to the more traditional approach of terminating the job and restarting it from the last stored checkpoint. If online recovery is performed in a local manner further scalability is enabled, not only due to the intrinsic lower costs of recovering locally, but also due to derived effects when using some application types. In this paper we model one such effect, namely multiple failure masking, that manifests when running Stencil parallel computations on an environment when failures are recovered locally. First, the delay propagation shape of one or multiple failures recovered locally is modeled to enable several analyses of the probability of different levels of failure masking under certain Stencil application behaviors. Our results indicate that failure masking is an extremely desirable effect at scale which manifestation is more evident and beneficial as the machine size or the failure rate increase.

Original language	English
Article number	7908967
Pages (from-to)	2881-2895
Number of pages	15
Journal	IEEE Transactions on Parallel and Distributed Systems
Volume	28
Issue number	10
DOIs	https://doi.org/10.1109/TPDS.2017.2696538
State	Published - Oct 1 2017
Externally published	Yes

Funding

The authors would like to thank Josep Gamell and Robert Clay for interesting discussions related to this work. The research presented in this work is supported in part by National Science Foundation (NSF) via grants numbers ACI 1339036, ACI 1310283, CNS 1305375, and DMS 1228203, by the Office of Advanced Scientific Computing Research, Office of Science, of the US Department of Energy through the SciDAC Institute for Scalable Data Management, Analysis and Visualization (SDAV) under award number DE-SC0007455, RSVP award via subcontract number 4000126989 from UT Battelle, the ASCR and FES Partnership for Edge Physics Simulations (EPSI) under award number DE-FG02-06ER54857, and the ExaCT Combustion CoDesign Center via subcontract number 4000110839 from UT Battelle. The research at Rutgers was conducted as part of the Rutgers Discovery Informatics Institute (RDI2). Sandia National Laboratories is a multimission laboratory managed and operated by National Technology and Engineering Solutions of Sandia, LLC., a wholly owned subsidiary of Honeywell International, Inc., for the U.S. Department of Energy’s National Nuclear Security Administration under contract DE-NA0003525.

Keywords

Parallel processing
failure masking
fault tolerance
modeling
resilience
stencil computation

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10.1109/TPDS.2017.2696538

Cite this

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title = "Modeling and simulating multiple failure masking enabled by local recovery for stencil-based applications at extreme scales",

abstract = "Obtaining multi-process hard failure resilience at the application level is a key challenge that must be overcome before the promise of exascale can be fully realized. Previous work has shown that online global recovery can dramatically reduce the overhead of failures when compared to the more traditional approach of terminating the job and restarting it from the last stored checkpoint. If online recovery is performed in a local manner further scalability is enabled, not only due to the intrinsic lower costs of recovering locally, but also due to derived effects when using some application types. In this paper we model one such effect, namely multiple failure masking, that manifests when running Stencil parallel computations on an environment when failures are recovered locally. First, the delay propagation shape of one or multiple failures recovered locally is modeled to enable several analyses of the probability of different levels of failure masking under certain Stencil application behaviors. Our results indicate that failure masking is an extremely desirable effect at scale which manifestation is more evident and beneficial as the machine size or the failure rate increase.",

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Modeling and simulating multiple failure masking enabled by local recovery for stencil-based applications at extreme scales

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