Understanding Permanent Hardware Failures in Deep Learning Training Accelerator Systems

Yi He, Yanjing Li
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Abstract

Hardware failures pose critical threats to deep neural network (DNN) training workloads, and the urgency of tackling this challenge (known as the Silent Data Corruption challenge in a broader context) has been raised widely by the industry. Based on industry reports, a large number of the failures observed in real systems are permanent hardware failures in logic. However, there is a very limited understanding of the effects that these failures can impose on DNN training workloads. In this paper, we present the first resilience study on this subject, focusing on deep learning (DL) training accelerator systems. We developed a fault injection framework to accurately simulate the effects of permanent faults, and conducted 100K fault injection experiments. Our results provide the fundamental understanding on how logic permanent hardware failures affect training workloads and eventually generate unexpected training outcomes. Based on this new knowledge, we developed efficient software-based detection and recovery techniques to mitigate logic permanent hardware failures that are likely to generate unexpected outcomes. Evaluation on Google Cloud TPUs shows that our techniques are effective and practical: they require 15−25 lines of code change, and introduce 0.004%−0.025% performance/energy overhead for various representative neural network models.
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理解深度学习训练加速器系统中的永久性硬件故障
硬件故障对深度神经网络(DNN)训练工作负载构成严重威胁,解决这一挑战(在更广泛的背景下被称为无声数据损坏挑战)的紧迫性已被业界广泛提出。根据行业报告,在实际系统中观察到的大量故障都是逻辑上的永久性硬件故障。然而,对于这些故障对DNN训练工作量的影响,人们的理解非常有限。在本文中,我们提出了关于这一主题的第一个弹性研究,重点是深度学习(DL)训练加速器系统。开发了断层注入框架,准确模拟永久断层的影响,并进行了100K次断层注入实验。我们的结果提供了对逻辑永久性硬件故障如何影响训练工作负载并最终产生意外训练结果的基本理解。基于这些新知识,我们开发了高效的基于软件的检测和恢复技术,以减轻可能产生意外结果的逻辑永久性硬件故障。在Google Cloud tpu上的评估表明,我们的技术是有效和实用的:它们需要15 - 25行代码更改,并为各种代表性神经网络模型引入0.004% - 0.025%的性能/能量开销。
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