Litcius/Paper detail

Trillium: Higher-Order Concurrent and Distributed Separation Logic for Intensional Refinement

Amin Timany, Simon Oddershede Gregersen, Léo Stefanesco, Jonas Kastberg Hinrichsen, Léon Gondelman, Abel Nieto, Lars Birkedal

2024Proceedings of the ACM on Programming Languages11 citationsDOIOpen Access PDF

Abstract

Expressive state-of-the-art separation logics rely on step-indexing to model semantically complex features and to support modular reasoning about imperative higher-order concurrent and distributed programs. Stepindexing comes, however, with an inherent cost: it restricts the adequacy theorem of program logics to a fairly simple class of safety properties. In this paper, we explore if and how intensional refinement is a viable methodology for strengthening higher-order concurrent (and distributed) separation logic to prove non-trivial safety and liveness properties. Specifically, we introduce Trillium, a language-agnostic separation logic framework for showing intensional refinement relations between traces of a program and a model. We instantiate Trillium with a concurrent language and develop Fairis, a concurrent separation logic, that we use to show liveness properties of concurrent programs under fair scheduling assumptions through a fair liveness-preserving refinement of a model. We also instantiate Trillium with a distributed language and obtain an extension of Aneris, a distributed separation logic, which we use to show refinement relations between distributed systems and TLA + models.

Topics & Concepts

LivenessSeparation logicComputer scienceProgramming languageSearch engine indexingSeparation of concernsExtension (predicate logic)Theoretical computer scienceArtificial intelligenceSoftwareDistributed systems and fault toleranceFormal Methods in VerificationSoftware System Performance and Reliability