English

Exploiting Binary Floating-Point Representations for Constraint Propagation: The Complete Unabridged Version

Artificial Intelligence 2015-08-03 v4 Software Engineering

Abstract

Floating-point computations are quickly finding their way in the design of safety- and mission-critical systems, despite the fact that designing floating-point algorithms is significantly more difficult than designing integer algorithms. For this reason, verification and validation of floating-point computations is a hot research topic. An important verification technique, especially in some industrial sectors, is testing. However, generating test data for floating-point intensive programs proved to be a challenging problem. Existing approaches usually resort to random or search-based test data generation, but without symbolic reasoning it is almost impossible to generate test inputs that execute complex paths controlled by floating-point computations. Moreover, as constraint solvers over the reals or the rationals do not natively support the handling of rounding errors, the need arises for efficient constraint solvers over floating-point domains. In this paper, we present and fully justify improved algorithms for the propagation of arithmetic IEEE 754 binary floating-point constraints. The key point of these algorithms is a generalization of an idea by B. Marre and C. Michel that exploits a property of the representation of floating-point numbers.

Keywords

Cite

@article{arxiv.1308.3847,
  title  = {Exploiting Binary Floating-Point Representations for Constraint Propagation: The Complete Unabridged Version},
  author = {Roberto Bagnara and Matthieu Carlier and Roberta Gori and Arnaud Gotlieb},
  journal= {arXiv preprint arXiv:1308.3847},
  year   = {2015}
}

Comments

51 pages, 3 figures, 1 table, 1 listing

R2 v1 2026-06-22T01:10:59.599Z