Project description
Reliable and effective combinatorial optimisation
In combinatorial optimisation, the challenge lies in devising efficient methods to find solutions to complex problems. These problems often involve intricate decision-making processes and can be so-called NP-hard or worse, making them computationally demanding. While existing tools have made significant progress in solving such problems, ensuring their reliability remains a crucial concern. In this context, the ERC-funded CertiFOX project aims to guarantee 100 % certainty in solving problems correctly. Leveraging proof logging breakthroughs, it focuses on providing end-to-end correctness guarantees relative to user-specified problems. This advancement promises significant impacts, facilitating debugging, auditability and rigorous evaluation of algorithmic enhancements. Overall, CertiFOX aims to pave the way for a future of combinatorial optimisation software development that is reliable and effective.
Objective
The field of combinatorial optimization is concerned with developing generic tools that take a declarative problem description and automatically compute an optimal solution to it. Often, users specify their problem in a high-level, human-understandable formal language. This specification is first translated into a low-level specification a solver understands and subsequently solved. Thanks to tremendous progress in solving technology, we can now solve a wide variety of NP-hard (or worse) problems in practice. Moreover, these tools are increasingly used in real-life applications, including high-value and life-affecting decisions. Therefore, it is of utmost importance that they be completely reliable. The central objective of this proposal is to develop methodologies and tools with which we can guarantee with 100% certainty that the right problem has been solved correctly.
To achieve this ambitious objective, I will build on recent breakthroughs in proof logging, where solvers do not just output an answer, but also a proof (or certificate) of correctness. However, a major limitation of current techniques is that correctness is not proven relative to the human-understandable specification written by the user, but relative to the low-level translation that the solver receives, meaning that there is no guarantee that the solver is solving the original problem. In this project, I will investigate end-to-end guarantees of correctness. When successful, this will have a major impact on the way combinatorial optimization software is developed, evaluated, and used: the proofs produced will enable (1) debugging, since proofs contain detailed information about where bugs occurred, (2) auditability, since proofs can be stored and checked by an independent third party, and even (3) rigorous evaluation of algorithmic improvements (I, for instance, have first-hand experience of winning a solver competition due to a bug that would have been caught easily using proof logging).
Fields of science
Keywords
Programme(s)
- HORIZON.1.1 - European Research Council (ERC) Main Programme
Funding Scheme
HORIZON-ERC - HORIZON ERC GrantsHost institution
1050 Bruxelles / Brussel
Belgium