Estimating Maximum Error Impact in Dynamic Data-driven Applications for Resource-aware Adaption of Software-based Fault-Tolerance (1608.06103v1)

Abstract: The rise of transient faults in modern hardware requires system designers to consider errors occurring at runtime. Both hardware- and software-based error handling must be deployed to meet application reliability requirements. The level of required reliability can vary for system components and depend on input and state, so that a selective use of resilience methods is advised, especially for resource-constrained platforms as found in embedded systems. If an error occurring at runtime can be classified as having negligible or tolerable impact, less effort can be spent on correcting it. As the actual impact of an error is often dependent on the state of a system at time of occurrence, it can not be determined precisely for highly dynamic workloads in data-driven applications. We present a concept to estimate error propagation in sets of tasks with variable data dependencies. This allows for a coarse grained analysis of the impact a failed task may have on the overall output. As an application example, we demonstrate our method for a typical dynamic embedded application, namely a decoder for the H.264 video format.