Constraint solving for finite model finding in SMT solvers-Reference-Cited by-同舟云学术

Constraint solving for finite model finding in SMT solvers

Published:2017-06-28 Issue:4 Volume:17 Page:516-558
ISSN:1471-0684
Container-title:Theory and Practice of Logic Programming
language:en
Short-container-title:Theory and Practice of Logic Programming

Author:

REYNOLDS ANDREW,TINELLI CESARE,BARRETT CLARK

Abstract

AbstractSatisfiability modulo theories (SMT) solvers have been used successfully as reasoning engines for automated verification and other applications based on automated reasoning. Current techniques for dealing with quantified formulas in SMT are generally incomplete, forcing SMT solvers to report “unknown” when they fail to prove the unsatisfiability of a formula with quantifiers. This inability to return counter models limits their usefulness in applications that produce queries involving quantified formulas. In this paper, we reduce these limitations by integrating finite model finding techniques based on constraint solving into the architecture used by modern SMT solvers. This approach is made possible by a novel solver for cardinality constraints, as well as techniques for on-demand instantiation of quantified formulas. Experiments show that our approach is competitive with the state of the art in SMT, and orthogonal to approaches in automated theorem proving.

Publisher

Cambridge University Press (CUP)

Subject

Artificial Intelligence,Computational Theory and Mathematics,Hardware and Architecture,Theoretical Computer Science,Software

Reference38 articles.

1. Déharbe D. , Fontaine P. , Merz S. and Paleo B. W. 2011. Exploiting symmetry in SMT problems. In Proc. of CADE-23, Lecture Notes in Computer Science, vol. 6803. Springer, 222–236.

2. McCune W. 1994. A Davis–Putnam Program and its Application to Finite First-Order Model Search: Quasigroup Existence Problems. Technical Report, Argonne National Laboratory.

3. Zhang J. and Zhang H. 1995. SEM: A system for enumerating models. In Proc. of IJCAI'95, 298–303.

4. Krstić S. and Goel A. 2007. Architecting solvers for SAT modulo theories: Nelson-Oppen with DPLL. In Proc. of FroCoS'07, Lecture Notes in Computer Science, vol. 4720. Springer, 1–27.