Non-intrusive Software-Implemented Fault Injection in Embedded Systems

Abstract

Critical embedded systems, like those used in avionics or automotive, have strong dependability requirements and most of them must face with fault tolerance. One of the methods typically used to validate fault tolerance mechanisms is fault injection. The idea is to study the behavior of the system in presence of faults in order to determine whether the system behaves properly or not. Software-implemented fault injection (SWIFI) techniques enable fault injection to be performed by software. Although interesting, major drawbacks of existing SWIFI techniques are the temporal and the spatial overheads they induced in the systems under study. The reduction of these overheads is thus crucial, in order to be confident on the results and conclusions of a SWIFI experiment. This paper focuses on this problem. It proposes a new non-intrusive SWIFI technique for injecting faults in embedded (system-on-chip) applications. The technique exploits the features of a standard debugging interface for embedded systems, called Nexus, in order to inject faults without temporal overhead. Then, Nexus features are also exploited in order to observe, without spatial intrusion, the behavior of the target system in presence of the injected faults. In other words, the embedded system under study can be controlled (for injecting faults) and observed (for tracing its behavior) without customizing its original structure or altering its normal execution. Since based on Nexus, the technique has also the benefit of being applicable to any Nexus-compliant system. In order to illustrate the potentials of the approach, we use an automotive embedded control unit application as a case study. Some preliminary results obtained from the experiments performed are also discussed.