Overcoming the Scalability Challenges of Epidemic Simulations on Blue Waters

2014 IEEE 28th International Parallel and Distributed Processing Symposium Pub Date : 2014-05-19 DOI:10.1109/IPDPS.2014.83

Jae-Seung Yeom, A. Bhatele, K. Bisset, Eric J. Bohm, Abhishek K. Gupta, L. Kalé, M. Marathe, Dimitrios S. Nikolopoulos, M. Schulz, Lukasz Wesolowski

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引用次数: 43

Abstract

Modeling dynamical systems represents an important application class covering a wide range of disciplines including but not limited to biology, chemistry, finance, national security, and health care. Such applications typically involve large-scale, irregular graph processing, which makes them difficult to scale due to the evolutionary nature of their workload, irregular communication and load imbalance. EpiSimdemics is such an application simulating epidemic diffusion in extremely large and realistic social contact networks. It implements a graph-based system that captures dynamics among co-evolving entities. This paper presents an implementation of EpiSimdemics in Charm++ that enables future research by social, biological and computational scientists at unprecedented data and system scales. We present new methods for application-specific processing of graph data and demonstrate the effectiveness of these methods on a Cray XE6, specifically NCSA's Blue Waters system.

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克服蓝色水域流行病模拟的可扩展性挑战

动态系统建模是一门重要的应用课程，涵盖了广泛的学科，包括但不限于生物、化学、金融、国家安全和卫生保健。这类应用程序通常涉及大规模、不规则的图形处理，由于其工作负载的演化性质、不规则的通信和负载不平衡，这使得它们难以扩展。episimdemic就是这样一个应用程序，它可以模拟流行病在超大的现实社会接触网络中的传播。它实现了一个基于图的系统，可以捕获共同进化实体之间的动态。本文介绍了episimdemic在Charm++中的实现，使社会、生物和计算科学家能够在前所未有的数据和系统规模上进行未来的研究。我们提出了针对特定应用程序处理图形数据的新方法，并在Cray XE6上演示了这些方法的有效性，特别是NCSA的Blue Waters系统。

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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2014 IEEE 28th International Parallel and Distributed Processing Symposium

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