A Cut-Free Sequent Calculus for the Analysis of Finite-Trace Properties in Concurrent Systems

We address the problem of identifying a proof-theoretic framework that enables a compositional analysis of finite-trace properties in concurrent systems, with a particular focus on those specified via prefix-closure. To this end, we investigate the interaction of a prefix-closure operator and its residual (with respect to set-theoretic inclusion) with language intersection, union, and concatenation, and introduce the variety of closure $\ell$-monoids as a minimal algebraic abstraction of finite-trace properties to be conveniently described within an analytic proof system. Closure $\ell$-monoids are division-free reducts of distributive residuated lattices equipped with a forward diamond/backward box residuated pair of unary modal operators, where the diamond is a topological closure operator satisfying $\Diamond(x \cdot y) \leq \Diamond x \cdot \Diamond y$. As a logical counterpart to these structures, we present $\mathsf{LMC}$, a Gentzen-style system based on the division-free fragment of the Distributive Full Lambek Calculus. In $\mathsf{LMC}$, structural terms are built from formulas using Belnap-style structural operators for monoid multiplication, meet, and diamond. The rules for the modalities and the structural diamond are taken from Moortgat's system $\mathsf{NL}(\Diamond)$. We show that the calculus is sound and complete with respect to the variety of closure $\ell$-monoids and that it admits cut elimination.