Parametrizing Reads-From Equivalence for Predictive Monitoring

Abstract

Predictive runtime monitoring asks whether an execution σ of a concurrent program can be used to soundly predict the existence of a reordering of σ that satisfies a property . Its effectiveness and efficiency depend on two factors: (a) the complexity of , and (b) the expressive power of the reorderings considered. At one extreme, allowing all reorderings induced by reads-from equivalence makes predictive monitoring intractable, even for simple properties such as data races. At the other extreme, restricting to commutativity-based reorderings (Mazurkiewicz trace equivalence) yields efficient algorithms for simple properties, but remains intractable for general regular specifications and offers limited predictive power. We address this tradeoff via parametrization. We introduce sliced reorderings and their generalization, k-sliced reorderings. Informally, is a k-sliced reordering of σ if σ can be partitioned into k+1 ordered subsequences whose concatenation yields , while preserving program order and reads-from constraints. Our results are twofold. First, k-sliced reorderings form a strictly increasing hierarchy that converges to reads-from equivalence as k grows. Second, for any fixed k, predictive monitoring modulo k-sliced reorderings against any regular specification admits a constant-space streaming algorithm. Together, these results establish k-sliced reorderings as a principled alternative to existing equivalences, enabling a uniform parametrized framework where expressive power can be systematically traded off against computational cost.