C-Mine: Data Mining of Logic Common Cases for Improved Timing Error Resilience with Energy Efficiency

ACM Trans. Design Autom. Electr. Syst. Pub Date : 2017-11-29 DOI:10.1145/3144534

Chen-Hsuan Lin, Lu Wan, Deming Chen

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引用次数: 1

Abstract

The better-than-worst-case (BTW) design methodology can achieve higher circuit energy efficiency, performance, or reliability by allowing timing errors for rare cases and rectifying them with error correction mechanisms. Therefore, the performance of BTW design heavily depends on the correctness of common cases, which are frequent input patterns in a workload. However, most existing methods do not provide sufficiently scalable solutions and also overlook the whole picture of the design. Thus, we propose a new technique, common-case mining method (C-Mine), which combines two scalable techniques, data mining and Boolean satisfiability (SAT) solving, to overcome these limitations. Data mining can efficiently extract patterns from an enormous dataset, and SAT solving is famous for its scalable verification. In this article, we present two versions of C-Mine, C-Mine-DCT and C-Mine-APR, which aim at faster runtime and better energy saving, respectively. The experimental results show that, compared to a recent publication, C-Mine-DCT can achieve compatible performance with an additional 8% energy savings and 54x speedup for bigger benchmarks on average. Furthermore, C-Mine-APR can achieve up to 13% more energy saving than C-Mine-DCT while confronting designs with more common cases.

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C-Mine:基于能效的提高时序误差弹性的逻辑通用案例的数据挖掘

优于最坏情况(BTW)的设计方法可以实现更高的电路能源效率，性能，或可靠性，通过允许在罕见情况下的时间误差和纠错机制来纠正它们。因此，BTW设计的性能在很大程度上取决于常见情况的正确性，这些情况是工作负载中经常出现的输入模式。然而，大多数现有的方法不能提供足够的可伸缩的解决方案，而且还忽略了设计的全貌。因此，我们提出了一种新的技术，共案例挖掘方法(C-Mine)，它结合了两种可扩展的技术，数据挖掘和布尔可满足性(SAT)求解，以克服这些限制。数据挖掘可以有效地从庞大的数据集中提取模式，而SAT求解以其可扩展的验证而闻名。在本文中，我们提出了两个版本的C-Mine, C-Mine- dct和C-Mine- apr，它们分别以更快的运行速度和更好的节能为目标。实验结果表明，与最近发表的一篇文章相比，C-Mine-DCT可以实现兼容的性能，在更大的基准测试中平均节省8%的能源和54倍的加速。此外，在面对更常见情况的设计时，C-Mine-APR可以比C-Mine-DCT节省高达13%的能源。

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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来源期刊

ACM Trans. Design Autom. Electr. Syst.

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