From RTL to silicon: the case for automated debug
Proceedings of the 16th Asia and South Pacific Design Automation Conference
Debugging with dominance: on-the-fly RTL debug solution implications
Proceedings of the International Conference on Computer-Aided Design
Non-solution implications using reverse domination in a modern SAT-based debugging environment
DATE '12 Proceedings of the Conference on Design, Automation and Test in Europe
| Hi-index | 14.98 |
Formal CAD tools operate on mathematical models describing the sequential behavior of a VLSI design. With the growing size and state-space of modern digital hardware designs, the conciseness of this mathematical model is of paramount importance in extending the scalability of those tools, provided that the compression does not come at the cost of reduced performance. Quantified Boolean Formula satisfiability (QBF) is a powerful generalization of Boolean satisfiability (SAT). It also belongs to the same complexity class as many CAD problems dealing with sequential circuits, which makes it a natural candidate for encoding such problems. This work proposes a succinct QBF encoding for modeling sequential circuit behavior. The encoding is parametrized and further compression is achieved using time-frame windowing. Comprehensive hardware constructions are used to illustrate the proposed encodings. Three notable CAD problems, namely bounded model checking, design debugging and sequential test pattern generation, are encoded as QBF instances to demonstrate the robustness and practicality of the proposed approach. Extensive experiments on OpenCore circuits show memory reductions in the order of 90 percent and demonstrate competitive runtimes compared to state-of-the-art SAT techniques. Furthermore, the number of solved instances is increased by 16 percent. Admittedly, this work encourages further research in the use of QBF in CAD for VLSI.