Exploring power behaviors and trade-offs of in-situ data analytics

2013 SC - International Conference for High Performance Computing, Networking, Storage and Analysis (SC) Pub Date : 2013-11-17 DOI:10.1145/2503210.2503303

Marc Gamell, I. Rodero, M. Parashar, Janine Bennett, H. Kolla, Jacqueline H. Chen, P. Bremer, Aaditya G. Landge, A. Gyulassy, P. McCormick, S. Pakin, Valerio Pascucci, S. Klasky

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引用次数: 52

Abstract

As scientific applications target exascale, challenges related to data and energy are becoming dominating concerns. For example, coupled simulation workflows are increasingly adopting in-situ data processing and analysis techniques to address costs and overheads due to data movement and I/O. However it is also critical to understand these overheads and associated trade-offs from an energy perspective. The goal of this paper is exploring data-related energy/performance trade-offs for end-to-end simulation workflows running at scale on current high-end computing systems. Specifically, this paper presents: (1) an analysis of the data-related behaviors of a combustion simulation workflow with an insitu data analytics pipeline, running on the Titan system at ORNL; (2) a power model based on system power and data exchange patterns, which is empirically validated; and (3) the use of the model to characterize the energy behavior of the workflow and to explore energy/performance tradeoffs on current as well as emerging systems.

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探索电力行为和就地数据分析的权衡

随着科学应用的目标是百亿亿级，与数据和能源相关的挑战正成为人们关注的主要问题。例如，耦合仿真工作流越来越多地采用原位数据处理和分析技术来解决由于数据移动和I/O而产生的成本和开销。然而，从能源的角度理解这些开销和相关的权衡也是至关重要的。本文的目标是探索在当前高端计算系统上大规模运行的端到端模拟工作流中与数据相关的能量/性能权衡。具体而言，本文提出:(1)在ORNL的Titan系统上，利用现场数据分析管道对燃烧模拟工作流的数据相关行为进行了分析;(2)基于系统功率和数据交换模式的功率模型，并进行了实证验证;(3)使用该模型来表征工作流的能源行为，并探索当前以及新兴系统的能源/性能权衡。

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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2013 SC - International Conference for High Performance Computing, Networking, Storage and Analysis (SC)

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