English

Using Dynamic Analysis to Generate Disjunctive Invariants

Software Engineering 2019-04-17 v1 Programming Languages

Abstract

Program invariants are important for defect detection, program verification, and program repair. However, existing techniques have limited support for important classes of invariants such as disjunctions, which express the semantics of conditional statements. We propose a method for generating disjunctive invariants over numerical domains, which are inexpressible using classical convex polyhedra. Using dynamic analysis and reformulating the problem in non-standard "max-plus" and "min-plus" algebras, our method constructs hulls over program trace points. Critically, we introduce and infer a weak class of such invariants that balances expressive power against the computational cost of generating nonconvex shapes in high dimensions. Existing dynamic inference techniques often generate spurious invariants that fit some program traces but do not generalize. With the insight that generating dynamic invariants is easy, we propose to verify these invariants statically using k-inductive SMT theorem proving which allows us to validate invariants that are not classically inductive. Results on difficult kernels involving nonlinear arithmetic and abstract arrays suggest that this hybrid approach efficiently generates and proves correct program invariants.

Keywords

Cite

@article{arxiv.1904.07463,
  title  = {Using Dynamic Analysis to Generate Disjunctive Invariants},
  author = {ThanhVu Nguyen and Deepak Kapur and Westley Weimer and Stephanie Forrest},
  journal= {arXiv preprint arXiv:1904.07463},
  year   = {2019}
}

Comments

appear in ICSE 2014

R2 v1 2026-06-23T08:40:50.702Z