Synthesis from Assume-Guarantee Contracts using Skolemized Proofs of Realizability
October 19, 2016 Β· Declared Dead Β· π arXiv.org
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Authors
Andreas Katis, Grigory Fedyukovich, Andrew Gacek, John Backes, Arie Gurfinkel, Michael W. Whalen
arXiv ID
1610.05867
Category
cs.SE: Software Engineering
Cross-listed
cs.LO
Citations
8
Venue
arXiv.org
Last Checked
4 months ago
Abstract
The realizability problem in requirements engineering is to determine the existence of an implementation that meets the given formal requirements. A step forward after realizability is proven, is to construct such an implementation automatically, and thus solve the problem of program synthesis. In this paper, we propose a novel approach to pro- gram synthesis guided by k-inductive proofs of realizability of assume- guarantee contracts constructed from safety properties. The proof of re- alizability is performed over a set of forall-exists formulas, and synthesis is per- formed by extracting Skolem functions witnessing the existential quan- tification. These Skolem functions can then be combined into an imple- mentation. Our approach is implemented in the JSyn tool which con- structs Skolem functions from a contract written in a variant of the Lus- tre programming language and then compiles the Skolem functions into a C language implementation. For a variety of benchmark models that already contained hand-written implementations, we are able to identify the usability and effectiveness of the synthesized counterparts, assuming a component-based verification framework.
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