未来互联的应用探索

2013 IEEE International Symposium on Parallel & Distributed Processing, Workshops and Phd Forum Pub Date : 2013-05-20 DOI:10.1109/IPDPSW.2013.60

R. Barrett, C. Vaughan, S. Hammond, D. Roweth

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引用次数: 2

摘要

二十多年来，在并行处理架构上实现计算科学和工程应用程序的可移植性能的主要方法是批量同步并行编程模型。代码开发人员出于性能考虑而尽量减少传输的消息数量，通常会努力通过聚合策略来增加每条消息的大小。新兴的和未来的架构，特别是那些以Exascale能力为目标的架构，为重新访问这种方法提供了动力和能力。在本文中，我们探索了大规模复杂多物理场应用和代表其行为的代理的背景下的替代配置，并展示了随着处理器数量的增加而具有一些重要优势的结果。

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Application Explorations for Future Interconnects

For over two decades the dominant means for enabling portable performance of computational science and engineering applications on parallel processing architectures has been the bulk-synchronous parallel programming model. Code developers, motivated by performance considerations to minimize the number of messages transmitted, have typically strived to increase the size of each message through aggregation strategies. Emerging and future architectures, especially those seen as targeting Exascale capabilities, provide motivation and capabilities for revisiting this approach. In this paper we explore alternative configurations within the context of a large-scale complex multi-physics application and a proxy that represents its behavior, presenting results that demonstrate some important advantages as the number of processors increases in scale.

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2013 IEEE International Symposium on Parallel & Distributed Processing, Workshops and Phd Forum

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