用于运行时MPI死锁检测的分布式等待状态跟踪

2013 SC - International Conference for High Performance Computing, Networking, Storage and Analysis (SC) Pub Date : 2013-11-17 DOI:10.1145/2503210.2503237

Tobias Hilbrich, B. Supinski, W. Nagel, Joachim Protze, C. Baier, Matthias S. Müller

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引用次数: 17

摘要

广泛使用的消息传递接口(Message Passing Interface, MPI)具有多种通信功能，容易出现使用错误。运行时错误检测工具有助于消除这些错误。我们开发MUST作为这样一个工具，它提供了各种各样的自动正确性检查。除了死锁检测之外，它的正确性检查可以在分布式模式下运行。这种限制适用于使用集中检测算法或超时方法的各种工具。为了提供可扩展和分布式死锁检测，并详细了解死锁情况，我们提出了一个用于制定分布式算法的MPI阻塞条件模型。该算法在MUST中实现了可扩展的MPI死锁检测。多达4,096个过程的压力测试证明了我们方法的可扩展性。最后，复杂基准套件的开销结果表明，在2,048个进程时，运行时平均增加了34%。

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Distributed wait state tracking for runtime MPI deadlock detection

The widely used Message Passing Interface (MPI) with its multitude of communication functions is prone to usage errors. Runtime error detection tools aid in the removal of these errors. We develop MUST as one such tool that provides a wide variety of automatic correctness checks. Its correctness checks can be run in a distributed mode, except for its deadlock detection. This limitation applies to a wide range of tools that either use centralized detection algorithms or a timeout approach. In order to provide scalable and distributed deadlock detection with detailed insight into deadlock situations, we propose a model for MPI blocking conditions that we use to formulate a distributed algorithm. This algorithm implements scalable MPI deadlock detection in MUST. Stress tests at up to 4,096 processes demonstrate the scalability of our approach. Finally, overhead results for a complex benchmark suite demonstrate an average runtime increase of 34% at 2,048 processes.

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来源期刊

2013 SC - International Conference for High Performance Computing, Networking, Storage and Analysis (SC)

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