English

Proving LTL Properties of Bitvector Programs and Decompiled Binaries (Extended)

Programming Languages 2021-08-31 v2 Formal Languages and Automata Theory Software Engineering Systems and Control Systems and Control

Abstract

There is increasing interest in applying verification tools to programs that have bitvector operations (eg., binaries). SMT solvers, which serve as a foundation for these tools, have thus increased support for bitvector reasoning through bit-blasting and linear arithmetic approximations. In this paper we show that similar linear arithmetic approximation of bitvector operations can be done at the source level through transformations. Specifically, we introduce new paths that over-approximate bitvector operations with linear conditions/constraints, increasing branching but allowing us to better exploit the well-developed integer reasoning and interpolation of verification tools. We show that, for reachability of bitvector programs, increased branching incurs negligible overhead yet, when combined with integer interpolation optimizations, enables more programs to be verified. We further show this exploitation of integer interpolation in the common case also enables competitive termination verification of bitvector programs and leads to the first effective technique for LTL verification of bitvector programs. Finally, we provide an in-depth case study of decompiled ("lifted") binary programs, which emulate X86 execution through frequent use of bitvector operations. We present a new tool DarkSea, the first tool capable of verifying reachability, termination, and LTL of lifted binaries.

Keywords

Cite

@article{arxiv.2105.05159,
  title  = {Proving LTL Properties of Bitvector Programs and Decompiled Binaries (Extended)},
  author = {Yuandong Cyrus Liu and Chengbin Pang and Daniel Dietsch and Eric Koskinen and Ton-Chanh Le and Georgios Portokalidis and Jun Xu},
  journal= {arXiv preprint arXiv:2105.05159},
  year   = {2021}
}

Comments

39 pages(including Appendix), 10 tables, 4 Postscript figures, accepted to APLAS 2021

R2 v1 2026-06-24T01:59:50.480Z