A Current Logical Framework: The Propositional Fragment

Watkins, Kevin; Cervesato, Iliano; Pfenning, Frank; Walker, David

doi:10.21236/ada418510

Cited by 4 publications

References 23 publications

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ILC: A Foundation for Automated Reasoning About Pointer Programs

Jia

Walker

2006

Programming Languages and Systems

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Abstract. This paper shows how to use Girard's intuitionistic linear logic extended with a classical sublogic to reason about pointer programs. More specifically, first, the paper defines the proof theory for ILC (Intuitionistic Linear logic with Constraints) and shows it is well-defined via a proof of cut elimination. Second, inspired by prior work of O'Hearn, Reynolds, and Yang, the paper explains how to interpret linear logical formulas as descriptions of a program store. Third, this paper defines a simple imperative programming language with mutable references and arrays and gives verification condition generation rules that produce assertions in ILC. Finally, we identify a fragment of ILC, ILC − , that is both decidable and closed under generation of verification conditions. Since verification condition generation is syntax-directed, we obtain a decidable procedure for checking properties of pointer programs.

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ILC: A Foundation for Automated Reasoning About Pointer Programs

Jia

Walker

2006

Programming Languages and Systems

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Subformula Linking for Intuitionistic Logic with Application to Type Theory

Chaudhuri

2021

Automated Deduction – CADE 28

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Subformula linking is an interactive theorem proving technique that was initially proposed for (classical) linear logic. It is based on truth and context preserving rewrites of a conjecture that are triggered by a user indicating links between subformulas, which can be done by direct manipulation, without the need of tactics or proof languages. The system guarantees that a true conjecture can always be rewritten to a known, usually trivial, theorem. In this work, we extend subformula linking to intuitionistic first-order logic with simply typed lambda-terms as the term language of this logic. We then use a well known embedding of intuitionistic type theory into this logic to demonstrate one way to extend linking to type theory.

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