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On model checking data-independent systems with arrays without reset

Published online by Cambridge University Press:  12 August 2004

R. S. LAZIĆ
Affiliation:
Department of Computer Science, University of Warwick, Coventry CV4 7AL, UK (e-mail: [email protected])
T. C. NEWCOMB
Affiliation:
Oxford University Computing Laboratory, Wolfson Buildings, Parks Road, Oxford OX1 3QD, UK (e-mail: [email protected], [email protected])
A. W. ROSCOE
Affiliation:
Oxford University Computing Laboratory, Wolfson Buildings, Parks Road, Oxford OX1 3QD, UK (e-mail: [email protected], [email protected])

Abstract

A system is data-independent with respect to a data type $X$ iff the operations it can perform on values of type $X$ are restricted to just equality testing. The system may also store, input and output values of type $X$. We study model checking of systems which are data-independent with respect to two distinct type variables $X$ and $Y$, and may in addition use arrays with indices from $X$ and values from $Y$. Our main interest is the following parameterised model-checking problem: whether a given program satisfies a given temporal-logic formula for all non-empty finite instances of $X$ and $Y$. Initially, we consider instead the abstraction where $X$ and $Y$ are infinite and where partial functions with finite domains are used to model arrays. Using a translation to data-independent systems without arrays, we show that the $\mu$-calculus model-checking problem is decidable for these systems. From this result, we can deduce properties of all systems with finite instances of $X$ and $Y$. We show that there is a procedure for the above parameterised model-checking problem of the universal fragment of the $\mu$-calculus, such that it always terminates but may give false negatives. We also deduce that the parameterised model-checking problem of the universal disjunction-free fragment of the $\mu$-calculus is decidable. Practical motivations for model checking data-independent systems with arrays include verification of memory and cache systems, where $X$ is the type of memory addresses, and $Y$ the type of storable values. As an example we verify a fault-tolerant memory interface over a set of unreliable memories.

Type
Regular Papers
Copyright
© 2004 Cambridge University Press

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Footnotes

This work was funded in part by the EPSRC standard research grant ‘Exploiting data independence’, GR/M32900. The first author is affiliated to the Mathematical Institute, Belgrade, and was supported partly by a grant from the Intel Corporation, a Junior Research Fellowship from Christ Church, Oxford, and previously by a scholarship from Hajrija & Boris Vukobrat and Copechim France SA. The second author was funded in part by QinetiQ Malvern. The third author was funded in part by the US ONR.