VEF3 Traces: Towards a Complete Framework for Modelling Network Workloads for Exascale Systems

2018 IEEE 4th International Workshop on High-Performance Interconnection Networks in the Exascale and Big-Data Era (HiPINEB) Pub Date : 2018-02-01 DOI:10.1109/HiPINEB.2018.00013

Javier Cano-Cano, Francisco J. Andújar, F. J. Alfaro, J. L. Sánchez

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引用次数: 1

Abstract

To meet the expected performance requirements of applications running on future exascale systems, the number of processing nodes included in such systems will have to increase and, according to the current trend, also the number of cores in each node. In these systems, the networks, both off- and on-chip, interconnecting these nodes and cores inside nodes, respectively, will have to be much more efficient than current ones. In order to develop and research on interconnection networks, simulation is the most common technique used. Simulators traditionally have used synthetic traffic as network workload which does not represent the network workload that real applications generate. The use of application communication trace files is a best strategy for this purpose. In this paper, we extend an existing tool including functionality related to communication within each node. In this way, the tool will allow interconnection network simulators to model traffic due to all the communications generated in the exascale systems.

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VEF3跟踪:为百亿亿级系统建模网络工作负载的完整框架

为了满足在未来百亿亿级系统上运行的应用程序的预期性能要求，这些系统中包含的处理节点的数量必须增加，并且根据当前的趋势，每个节点中的核心数量也必须增加。在这些系统中，分别连接这些节点和节点内部核心的片外和片上网络必须比目前的网络效率高得多。为了开发和研究互连网络，仿真是最常用的技术。模拟器传统上使用合成流量作为网络工作负载，这并不代表实际应用程序产生的网络工作负载。使用应用程序通信跟踪文件是实现此目的的最佳策略。在本文中，我们扩展了一个现有的工具，包括与每个节点内通信相关的功能。通过这种方式，该工具将允许互连网络模拟器模拟由于百亿亿级系统中产生的所有通信而产生的流量。

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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2018 IEEE 4th International Workshop on High-Performance Interconnection Networks in the Exascale and Big-Data Era (HiPINEB)

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