FMI:用于快速透明恢复的容错消息接口

Kento Sato, A. Moody, K. Mohror, T. Gamblin, B. Supinski, N. Maruyama, S. Matsuoka
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引用次数: 27

摘要

未来拥有更多组件的超级计算机将实现更大、更高保真度的模拟,但代价是更高的故障率。传统的减轻故障的方法,例如并行文件系统的检查点/重新启动(C/R),会产生很大的开销。在未来的极端规模系统中,传统的C/R不太可能在下一次故障发生之前恢复失败的应用程序。为了解决这个问题,我们提出了容错消息传递接口(FMI),它支持极低延迟的恢复。FMI使用可生存的通信运行时以及快速的内存C/R和动态节点分配来实现这一点。FMI提供了类似于MPI的消息传递语义,但是使用FMI编写的应用程序可以运行失败。FMI运行时软件处理容错,包括检查指向应用程序状态、重新启动失败的进程以及在需要时分配额外的节点。我们的测试表明,FMI运行时具有与MPI相似的无故障性能,但FMI仅产生28%的开销,并且故障间隔时间非常高,为1分钟。
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FMI: Fault Tolerant Messaging Interface for Fast and Transparent Recovery
Future supercomputers built with more components will enable larger, higher-fidelity simulations, but at the cost of higher failure rates. Traditional approaches to mitigating failures, such as checkpoint/restart (C/R) to a parallel file system incur large overheads. On future, extreme-scale systems, it is unlikely that traditional C/R will recover a failed application before the next failure occurs. To address this problem, we present the Fault Tolerant Messaging Interface (FMI), which enables extremely low-latency recovery. FMI accomplishes this using a survivable communication runtime coupled with fast, in-memory C/R, and dynamic node allocation. FMI provides message-passing semantics similar to MPI, but applications written using FMI can run through failures. The FMI runtime software handles fault tolerance, including check pointing application state, restarting failed processes, and allocating additional nodes when needed. Our tests show that FMI runs with similar failure-free performance as MPI, but FMI incurs only a 28% overhead with a very high mean time between failures of 1 minute.
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