Integrating OpenMP into the Charm++ Programming Model

Proceedings of the Third International Workshop on Extreme Scale Programming Models and Middleware Pub Date : 2017-11-12 DOI:10.1145/3152041.3152085

Seonmyeong Bak, Harshitha Menon, Sam White, M. Diener, L. Kalé

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引用次数: 5

Abstract

The recent trend of rapid increase in the number of cores per chip has resulted in vast amounts of on-node parallelism. These high core counts result in hardware variability that introduces imbalance. Applications are also becoming more complex themselves, resulting in dynamic load imbalance. Load imbalance of any kind can result in loss of performance and decrease in system utilization. In this paper, we propose a new integrated runtime system that adds OpenMP shared-memory parallelism to the Charm++ distributed programming model to improve load balancing on distributed systems. Our proposal utilizes an infrequent periodic assignment of work to cores based on load measurement, in combination with tasks created via OpenMP's parallel loop construct from each core to handle load imbalance. We demonstrate the benefits of using this integrated runtime system on the LLNL ASC proxy application Lassen, achieving speedups of 50% over runs without any load balancing and 10% over existing distributed-memory-only balancing schemes in Charm++.

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将OpenMP集成到Charm++编程模型中

最近每个芯片的核心数量快速增加的趋势导致了大量的节点上并行性。这些高核数导致硬件可变性，从而导致不平衡。应用程序本身也变得越来越复杂，导致动态负载不平衡。任何类型的负载不平衡都可能导致性能损失和系统利用率下降。在本文中，我们提出了一个新的集成运行时系统，该系统将OpenMP共享内存并行性添加到Charm++分布式编程模型中，以改善分布式系统的负载平衡。我们的建议利用基于负载测量的不频繁的周期性工作分配给内核，并结合通过OpenMP的并行循环构造从每个内核创建的任务来处理负载不平衡。我们展示了在LLNL ASC代理应用程序Lassen上使用这个集成的运行时系统的好处，在没有任何负载平衡的情况下，运行速度提高了50%，在Charm++中比现有的仅分配内存的平衡方案提高了10%。

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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Proceedings of the Third International Workshop on Extreme Scale Programming Models and Middleware

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