Task Bench: A Parameterized Benchmark for Evaluating Parallel Runtime Performance

SC20: International Conference for High Performance Computing, Networking, Storage and Analysis Pub Date : 2019-08-15 DOI:10.1109/SC41405.2020.00066

Elliott Slaughter, Wei Wu, Yuankun Fu, Legend Brandenburg, N. Garcia, Wilhem Kautz, Emily Marx, Kaleb S. Morris, Wonchan Lee, Qinglei Cao, G. Bosilca, S. Mirchandaney, Sean Treichler, P. McCormick, A. Aiken

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引用次数: 34

Abstract

We present Task Bench, a parameterized benchmark designed to explore the performance of distributed programming systems under a variety of application scenarios. Task Bench dramatically lowers the barrier to benchmarking and comparing multiple programming systems by making the implementation for a given system orthogonal to the benchmarks themselves: every benchmark constructed with Task Bench runs on every Task Bench implementation. Furthermore, Task Bench’s parameterization enables a wide variety of benchmark scenarios that distill the key characteristics of larger applications.To assess the effectiveness and overheads of the tested systems, we introduce a novel metric, minimum effective task granularity (METG). We conduct a comprehensive study with 15 programming systems on up to 256 Haswell nodes of the Cori supercomputer. Running at scale, 100$\mu$s-long tasks are the finest granularity that any system runs efficiently with current technologies. We also study each system’s scalability, ability to hide communication and mitigate load imbalance.

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任务工作台:用于评估并行运行时性能的参数化基准

我们提出Task Bench，这是一个参数化基准，旨在探索分布式编程系统在各种应用场景下的性能。Task Bench通过使给定系统的实现与基准测试本身正交，极大地降低了基准测试和比较多个编程系统的障碍:用Task Bench构建的每个基准测试都运行在每个Task Bench实现上。此外，Task Bench的参数化支持各种各样的基准测试场景，这些场景可以提炼出大型应用程序的关键特征。为了评估被测试系统的有效性和开销，我们引入了一个新的度量，最小有效任务粒度(METG)。我们在Cori超级计算机的多达256个Haswell节点上对15个编程系统进行了全面的研究。在规模上运行，100$\mu$s长的任务是当前技术下任何系统有效运行的最细粒度。我们还研究了每个系统的可扩展性、隐藏通信和减轻负载不平衡的能力。

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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SC20: International Conference for High Performance Computing, Networking, Storage and Analysis

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