Counterexample-guided abstraction refinement for symbolic model checking-Reference-Cited by-同舟云学术

Counterexample-guided abstraction refinement for symbolic model checking

Published:2003-09 Issue:5 Volume:50 Page:752-794
ISSN:0004-5411
Container-title:Journal of the ACM
language:en
Short-container-title:J. ACM

Author:

Clarke Edmund¹,Grumberg Orna²,Jha Somesh³,Lu Yuan⁴,Veith Helmut⁵

Affiliation:

1. Carnegie Mellon University, Pittsburgh, Pennsylvania

2. The Technion, Haifa, Israel

3. University of Wisconsin, Madison, Wisconsin

4. Broadcom Co., San Jose, California

5. Vienna University of Technology, Wien, Austria

Abstract

The state explosion problem remains a major hurdle in applying symbolic model checking to large hardware designs. State space abstraction, having been essential for verifying designs of industrial complexity, is typically a manual process, requiring considerable creativity and insight.In this article, we present an automatic iterative abstraction-refinement methodology that extends symbolic model checking. In our method, the initial abstract model is generated by an automatic analysis of the control structures in the program to be verified. Abstract models may admit erroneous (or "spurious") counterexamples. We devise new symbolic techniques that analyze such counterexamples and refine the abstract model correspondingly. We describe aSMV, a prototype implementation of our methodology in NuSMV. Practical experiments including a large Fujitsu IP core design with about 500 latches and 10000 lines of SMV code confirm the effectiveness of our approach.

Publisher

Association for Computing Machinery (ACM)

Subject

Artificial Intelligence,Hardware and Architecture,Information Systems,Control and Systems Engineering,Software

Link

https://dl.acm.org/doi/pdf/10.1145/876638.876643

Reference80 articles.

1. Abdulla P. A. Annichini A. Bensalem S. Bouajjani A. Habermehl P. and Lakhnech Y. 1999. Verification of infinite-state systems by combining abstraction and reachability analysis. In Computer-Aided Verification (CAV).]] Abdulla P. A. Annichini A. Bensalem S. Bouajjani A. Habermehl P. and Lakhnech Y. 1999. Verification of infinite-state systems by combining abstraction and reachability analysis. In Computer-Aided Verification (CAV).]]

2. Balarin F. and Sangiovanni-Vincentelli A. L. 1993. An iterative approach to language containment. In Computer-Aided Verification (CAV).]] Balarin F. and Sangiovanni-Vincentelli A. L. 1993. An iterative approach to language containment. In Computer-Aided Verification (CAV).]]

3. Free Bits, PCPs, and Nonapproximability---Towards Tight Results

4. Bensalem S. Bouajjani A. Loiseaux C. and Sifakis J. 1992. Property preserving simulations. In Computer-Aided Verification (CAV).]] Bensalem S. Bouajjani A. Loiseaux C. and Sifakis J. 1992. Property preserving simulations. In Computer-Aided Verification (CAV).]]

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