Handling mixed-criticality in SoC-based real-time embedded systems

International Conference on Embedded Software Pub Date : 2009-10-12 DOI:10.1145/1629335.1629367

R. Pellizzoni, P. Meredith, Min-Young Nam, Mu Sun, M. Caccamo, L. Sha

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引用次数: 79

Abstract

System-on-Chip (SoC) is a promising paradigm to implement safety-critical embedded systems, but it poses significant challenges from a design and verification point of view. In particular, in a mixed-criticality system, low criticality applications must be prevented from interfering with high criticality ones. In this paper, we introduce a new design methodology for SoC that provides strong isolation guarantees to applications with different criticalities. A set of certificates describing the assumed application behavior is extracted from a functional Architectural Analysis and Design Language (AADL) specification. Our tools then automatically generate hardware wrappers that enforce at run-time the behavior described by the certificates. In particular, we employ run-time monitoring to formally check all data communication in the system, and we enforce timing reservations for both computation and communication resources. Verification is greatly simplified because certificates are much simpler than the components used to implement low-criticality applications. The effectiveness of our methodology is proven on a case study consisting of a medical pacemaker.

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处理基于soc的实时嵌入式系统中的混合临界性

片上系统(SoC)是实现安全关键型嵌入式系统的一个很有前途的范例，但从设计和验证的角度来看，它提出了重大挑战。特别是在混合临界系统中，必须防止低临界应用干扰高临界应用。在本文中，我们介绍了一种新的SoC设计方法，该方法为具有不同临界性的应用提供了强大的隔离保证。一组描述假定应用程序行为的证书是从功能性架构分析和设计语言(AADL)规范中提取出来的。然后，我们的工具自动生成硬件包装器，在运行时强制执行证书所描述的行为。特别是，我们使用运行时监控来正式检查系统中的所有数据通信，并对计算资源和通信资源强制进行时间预留。验证被大大简化了，因为证书比用于实现低临界应用程序的组件要简单得多。我们的方法的有效性证明了一个案例研究组成的医疗起搏器。

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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International Conference on Embedded Software

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