在HPC认知模拟中，分解是可能的吗?

2021 IEEE/ACM Workshop on Machine Learning in High Performance Computing Environments (MLHPC) Pub Date : 2021-11-01 DOI:10.1109/mlhpc54614.2021.00014

Michael R. Wyatt, Valen Yamamoto, Zoë Tosi, I. Karlin, B. V. Essen

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引用次数: 2

摘要

认知模拟(Cognitive simulation, CogSim)是高性能计算科学探索和科学机器学习(scientific machine learning, SciML)中一个重要的新兴工作流程。CogSim的一个具有挑战性的工作负载是用计算循环“内部”的快速、可学习的代理模型替换复杂物理模拟中的一个组件。这种循环内推理的执行特别具有挑战性，因为它需要跨多个可能的目标模型进行频繁的推理，可能在模拟的关键路径上(延迟限制)，受到来自多个MPI等级的请求的影响，并且每个请求通常包含少量样本。在本文中，我们探索了使用大型的、专用的深度学习/人工智能加速器，这些加速器是从计算节点分解出来的，用于此CogSim工作负载。我们比较了在领导级HPC系统上使用这些加速器与节点本地GPU加速器的权衡。

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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Is Disaggregation possible for HPC Cognitive Simulation?

Cognitive simulation (CogSim) is an important and emerging workflow for HPC scientific exploration and scientific machine learning (SciML). One challenging workload for CogSim is the replacement of one component in a complex physical simulation with a fast, learned, surrogate model that is “inside” of the computational loop. The execution of this in-the-loop inference is particularly challenging because it requires frequent inference across multiple possible target models, can be on the simulation’s critical path (latency bound), is subject to requests from multiple MPI ranks, and typically contains a small number of samples per request. In this paper we explore the use of large, dedicated Deep Learning / AI accelerators that are disaggregated from compute nodes for this CogSim workload. We compare the trade-offs of using these accelerators versus the node-local GPU accelerators on leadership-class HPC systems.

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2021 IEEE/ACM Workshop on Machine Learning in High Performance Computing Environments (MLHPC)

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