Explaining cache SER anomaly using DUE AVF measurement

HPCA - 16 2010 The Sixteenth International Symposium on High-Performance Computer Architecture Pub Date : 2010-04-01 DOI:10.1109/HPCA.2010.5416629

Arijit Biswas, C. Recchia, Shubhendu S. Mukherjee, V. Ambrose, L. Chan, A. Jaleel, A. Papathanasiou, M. Plaster, N. Seifert

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引用次数: 25

Abstract

We have discovered that processors can experience a super-linear increase in detected unrecoverable errors (DUE) when the write-back L2 cache is doubled in size. This paper explains how an increase in the cache tag's Architectural Vulnerability Factor or AVF caused such a super-linear increase in the DUE rate. AVF expresses the fraction of faults that become user-visible errors. Our hypothesis is that this increase in AVF is caused by a super-linear increase in “dirty” data residence times in the L2 cache. Using proton beam irradiation, we measured the DUE rates from the write-back cache tags and analyzed the data to show that our hypothesis holds. We utilized a combination of simulation and measurements to help develop and prove this hypothesis. Our investigation reveals two methods by which dirty line residency causes super-linear increases in the L2 cache tag's AVF. One is a reduction in the miss rates as we move to the larger cache part, resulting in fewer evictions of data required for architecturally correct execution. The second is the occurrence of strided cache access patterns, which cause a significant increase in the “dirty” residency times of cache lines without increasing the cache miss rate.

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利用DUE AVF测量解释缓存SER异常

我们发现，当回写L2缓存的大小增加一倍时，处理器检测到的不可恢复错误(DUE)可能会出现超线性增长。本文解释了缓存标签的架构漏洞因子或AVF的增加如何导致DUE率的超线性增加。AVF表示成为用户可见错误的故障的比例。我们的假设是，AVF的增加是由L2缓存中“脏”数据停留时间的超线性增加引起的。使用质子束辐照，我们测量了回写缓存标签的DUE率，并分析了数据，以表明我们的假设成立。我们利用模拟和测量相结合来帮助发展和证明这一假设。我们的调查揭示了两种方法，其中脏线驻留导致L2缓存标签的AVF超线性增加。一个是当我们移动到更大的缓存部分时，丢失率降低了，从而减少了体系结构正确执行所需的数据清除。第二种是跨行缓存访问模式的出现，这会导致缓存线的“脏”驻留时间显著增加，而不会增加缓存丢失率。

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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HPCA - 16 2010 The Sixteenth International Symposium on High-Performance Computer Architecture

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