FaultHound:基于值-位置的软容错

Nitin, I. Pomeranz, T. N. Vijaykumar
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引用次数: 8

摘要

随着CMOS的持续扩展,软误差敏感性日益受到关注。以前的工作探讨了软容错的硬件和软件的全冗余和部分冗余方案。然而,全冗余方案带来高性能和能源开销,而部分冗余方案实现低覆盖率。一项最初的研究,称为基于扰动的故障筛选(PBFS),探索利用值局域性来提供软故障的提示,每当一个值落在其邻域之外。PBFS采用位掩码过滤器捕获值邻域。然而,PBFS实现了低覆盖率;直接提高覆盖率会导致高误报率,以及性能和能源开销。本文提出了一种基于值-位置的软容错方案FaultHound,该方案采用五种机制来解决PBFS的局限性:(1)通过过滤器表的反向组织对过滤器进行聚类,以加强学习并降低误报率;(2)忽略多次误报的错误位的学习方案,进一步降低误报率;(3)采用轻量级前导重放方案代替完全回滚,以减少剩余误报的性能和能量损失;(4)区分重命名错误(需要回滚而不是重放恢复)和误报的简单方案,以避免不必要的回滚惩罚;(5)一种避免回滚的检测方案,用于重播不包括的负载存储队列。通过模拟,我们表明,虽然PBFS在高性能开销(97%)下实现了低覆盖率(30%)或高假阳性率(8%),但FaultHound在较低的性能和能量开销(10%和25%)下实现了更高的覆盖率(75%)和较低的假阳性率(3%)。
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FaultHound: Value-locality-based soft-fault tolerance
Soft error susceptibility is a growing concern with continued CMOS scaling. Previous work explores full- and partial-redundancy schemes in hardware and software for soft-fault tolerance. However, full-redundancy schemes incur high performance and energy overheads whereas partial-redundancy schemes achieve low coverage. An initial study, called Perturbation Based Fault Screening (PBFS), explores exploiting value locality to provide hints of soft faults whenever a value falls outside its neighborhood. PBFS employs bit-mask filters to capture value neighborhoods. However, PBFS achieves low coverage; straightforwardly improving the coverage results in high false-positive rates, and performance and energy overheads. We propose FaultHound, a value-locality-based soft-fault tolerance scheme, which employs five mechanisms to address PBFS's limitations: (1) a scheme to cluster the filters via an inverted organization of the filter tables to reinforce learning and reduce the false-positive rates; (2) a learning scheme for ignoring the delinquent bit positions that raise repeated false alarms, to reduce further the false-positive rate; (3) a light-weight predecessor replay scheme instead of a full rollback to reduce the performance and energy penalty of the remaining false positives; (4) a simple scheme to distinguish rename faults, which require rollback instead of replay for recovery, from false positives to avoid unnecessary rollback penalty; and (5) a detection scheme, which avoids rollback, for the load-store queue which is not covered by our replay. Using simulations, we show that while PBFS achieves either low coverage (30%), or high false-positive rates (8%) with high performance overheads (97%), FaultHound achieves higher coverage (75%) and lower false-positive rates (3%) with lower performance and energy overheads (10% and 25%).
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