用于低开销在线测试的编译器辅助方法

2013 International Conference on Embedded Computer Systems: Architectures, Modeling, and Simulation (SAMOS) Pub Date : 2013-07-15 DOI:10.1109/SAMOS.2013.6621126

G. Nazarian, R. M. Seepers, C. Strydis, G. Gaydadjiev

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引用次数: 2

摘要

由于暂态故障率的增加，可靠性已成为现代系统设计的重要标准。通常用于解决这个问题的硬件容错技术引入了很高的设计成本。作为替代方案，基于编译器断言的软件签名监控(SM)方案是一种有效的控制流错误检测方法。现有的SM技术不考虑导致不必要开销的特定于应用程序的信息。在本文中，使用编译时控制流图(CFG)拓扑分析将最适合的断言放置在汇编代码的最佳位置，以减少开销。我们对代表性工作负载的评估显示，故障覆盖的增加与开销接近的基于断言的控制流校正(ACFC)，这是开销最低的方法。与ACFC相比，我们的技术(平均)在相同代码大小的开销下，故障覆盖率提高了17%，性能开销提高了5%，功耗降低了3%。

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Compiler-aided methodology for low overhead on-line testing

Reliability is emerging as an important design criterion in modern systems due to increasing transient fault rates. Hardware fault-tolerance techniques, commonly used to address this, introduce high design costs. As alternative, software Signature-Monitoring (SM) schemes based on compiler assertions are an efficient method for control-flow-error detection. Existing SM techniques do not consider application-specific-information causing unnecessary overheads. In this paper, compile-time Control-Flow-Graph (CFG) topology analysis is used to place best-suited assertions at optimal locations of the assembly code to reduce overheads. Our evaluation with representative workloads shows fault-coverage increase with overheads close to Assertion-based Control-Flow Correction (ACFC), the method with lowest overhead. Compared to ACFC, our technique improves (on average) fault coverage by 17%, performance overhead by 5% and power-consumption by 3% with equal code-size overhead.

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来源期刊

2013 International Conference on Embedded Computer Systems: Architectures, Modeling, and Simulation (SAMOS)

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