Abstract
We introduce a framework for the verification of protocols involving a distinguished machine (referred to as a leader) orchestrating the operation of an arbitrary number of identical machines (referred to as followers) in a network. At the core of our framework is a high-level formalism capturing the operation of these types of machines together with their network interactions. We show that this formalism automatically translates to a tractable form of first-order temporal logic. Checking whether a protocol specified in our formalism satisfies a desired property (expressible in temporal logic) then amounts to checking whether the protocol’s translation in first-order temporal logic entails that property. Many different types of protocols used in practice, such as cache coherence, atomic commitment, consensus, and synchronization protocols, fit within our framework. First-order temporal logic also facilitates parameterized verification by enabling us to model such protocols abstractly without referring to individual machines.
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