Abstract

The 'optimal' (in some sense) amount of time used for (or the optimal number of times) retrying an instruction upon detection of an error in a computing system is usually determined under the assumption that the system is composed of a single module, within which all fault activities are confined until some module-replacement action is taken. However, a computing system is usually composed of at least three modules, namely, CPU, memory, and I/O, and the execution of an instruction often requires the cooperation of two or more modules. It is thus more realistic to consider the fault activities in multiple-module systems. In this paper, we first relax the single-module assumption and model the fault activities in a multiple-module system as a Markov process. We apply the randomization method to decompose the continuous-time Markov chain into a discrete-time Markov chain subordinated to a Poisson process. Using this decomposition, we can derive several interesting measures, such as (1) the conditional probability of successful retry given a retry period and the fact that a non-permanent fault has occurred, (2) the mean time-to-system recovery, and (3) the distribution of the time until which all modules in the system enter a fault-free state. All the measures derived are used to determine, along with the parameters characterizing fault activities and costs of recovery techniques, (a) whether or not retry should be used as a first-step recovery means upon detection of an error, and (b) the best retry period or number of retries that satisfies a given criterion, e.g., a specific probability of successful retry.

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