在stampede的Xeon和Xeon Phi处理器上优化PCIT算法，以更快地发现生物网络

Proceedings of the Conference on Extreme Science and Engineering Discovery Environment: Gateway to Discovery Pub Date : 2013-07-22 DOI:10.1145/2484762.2484794

L. Koesterke, K. Milfeld, M. Vaughn, D. Stanzione, J. Koltes, N. Weeks, J. Reecy

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引用次数: 16

摘要

PCIT方法是检测网络间相互作用的重要技术。PCIT算法已被用于生物学领域，以推断遗传网络、全基因组关联研究和其他类似问题中的复杂调控机制和相互作用。在这项工作中，PCIT算法重新实现了并行，矢量，I/O，内存和指令优化，适用于当今的多核和多核架构。新代码的改进和性能针对Stampede超级计算机的处理器体系结构，但也将使其他体系结构受益。Stampede系统由英特尔至强E5处理器基础系统和由英特尔至强Phi协处理器组成的创新组件组成。给出了Xeon和Xeon Phi处理器的优化结果和分析。

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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Optimizing the PCIT algorithm on stampede's Xeon and Xeon Phi processors for faster discovery of biological networks

The PCIT method is an important technique for detecting interactions between networks. The PCIT algorithm has been used in the biological context to infer complex regulatory mechanisms and interactions in genetic networks, in genome wide association studies, and in other similar problems. In this work, the PCIT algorithm is re-implemented with exemplary parallel, vector, I/O, memory and instruction optimizations for today's multi- and many-core architectures. The evolution and performance of the new code targets the processor architectures of the Stampede supercomputer, but will also benefit other architectures. The Stampede system consists of an Intel Xeon E5 processor base system with an innovative component comprised of Intel Xeon Phi Coprocessors. Optimized results and an analysis are presented for both the Xeon and the Xeon Phi.

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Proceedings of the Conference on Extreme Science and Engineering Discovery Environment: Gateway to Discovery

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