4 research outputs found
Loop Analysis by Quantification over Iterations
We present a framework to analyze and verify programs containing loops by using a first-order language of so-called extended expressions. This language can express both functional and temporal properties of loops. We prove soundness and completeness of our framework and use our approach to automate the tasks of partial correctness verification, termination analysis and invariant generation. For doing so, we express the loop semantics as a set of first-order properties over extended expressions and use theorem provers and/or SMT solvers to reason about these properties. Our approach supports full first-order reasoning, including proving program properties with alternation of quantifiers. Our work is implemented in the tool QuIt and successfully evaluated on benchmarks coming from software verification
Counterexample-Guided Prophecy for Model Checking Modulo the Theory of Arrays
We develop a framework for model checking infinite-state systems by
automatically augmenting them with auxiliary variables, enabling
quantifier-free induction proofs for systems that would otherwise require
quantified invariants. We combine this mechanism with a counterexample-guided
abstraction refinement scheme for the theory of arrays. Our framework can thus,
in many cases, reduce inductive reasoning with quantifiers and arrays to
quantifier-free and array-free reasoning. We evaluate the approach on a wide
set of benchmarks from the literature. The results show that our implementation
often outperforms state-of-the-art tools, demonstrating its practical
potential.Comment: 23 pages, 1 figure, 1 table, extended version of paper to be
published in International Conference on Tools and Algorithms for the
Construction and Analysis of Systems 202