Scalable MiniMD Design with Hybrid MPI and OpenSHMEM

International Conference on Partitioned Global Address Space Programming Models Pub Date : 2014-10-06 DOI:10.1145/2676870.2676893

Mingzhe Li, Jian Lin, Xiaoyi Lu, Khaled Hamidouche, K. Tomko, D. Panda

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引用次数: 12

Abstract

The MPI programming model has been widely used for scientific applications. The emergence of Partitioned Global Address Space (PGAS) programming models presents an alternative approach to improve programmability. With the global data view and lightweight communication operations, PGAS has the potential to increase the performance of scientific applications at scale. However, since the PGAS models are emerging, it is unlikely that entire applications will be re-written with them. Instead, unified communication runtimes have paved the way for a new class of hybrid applications that can leverage the benefits of both MPI and PGAS models. In this paper, we re-design an existing MPI based scientific mini-application (MiniMD) with MPI and OpenSHMEM programming models. We propose two alternative designs using MPI and OpenSHMEM programming models and compare performance and scalability of those designs with the original MPI-based implementation. Our performance evaluations using MVAPICH2-X (Unified MPI+PGAS Communication Runtime over InfiniBand) show a 17% reduction in total execution time, compared to existing MPI-based design with 1,024 cores.

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混合MPI和OpenSHMEM的可扩展最小化设计

MPI规划模型已广泛应用于科学领域。分区全局地址空间(PGAS)编程模型的出现为提高可编程性提供了另一种方法。凭借全局数据视图和轻量级通信操作，PGAS具有大规模提高科学应用性能的潜力。然而，由于PGAS模型正在出现，因此不太可能用它们重写整个应用程序。相反，统一通信运行时为一类新的混合应用程序铺平了道路，这些应用程序可以利用MPI和PGAS模型的优势。在本文中，我们利用MPI和OpenSHMEM编程模型重新设计了一个现有的基于MPI的科学小应用程序(MiniMD)。我们提出了使用MPI和OpenSHMEM编程模型的两种替代设计，并将这些设计与原始基于MPI的实现的性能和可扩展性进行了比较。我们使用MVAPICH2-X(基于InfiniBand的统一MPI+PGAS通信运行时)进行的性能评估显示，与现有基于1,024核MPI的设计相比，总执行时间减少了17%。

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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International Conference on Partitioned Global Address Space Programming Models

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