Automatic constraint satisfaction problem

Abstract

We study constraint satisfaction problems (CSPs) where the constraint languages are defined by finite automata, giving rise to automata-based CSPs. The key notion is the concept of Automatic Constraint Satisfaction Problem (AutCSP), where constraint languages and instances are specified by finite automata. The AutCSP captures infinite yet finitely describable sets of relations, enabling concise representations of complex constraints. Studying the complexity of the AutCSPs illustrates the interplay between classical CSPs, automata, and logic, sharpening the boundary between tractable and intractable constraints. We show that checking whether an operation is a polymorphism of such a language can be done in polynomial time. Building on this, we establish several complexity classification results for the AutCSP. In particular, we prove that Schaefer's Dichotomy Theorem extends to the AutCSP over the Boolean domain, and we provide algorithms that decide tractability of some classes of AutCSPs over arbitrary finite domains via automatic polymorphisms. An important part of our work is that our polynomial-time algorithms run on AutCSP instances that can be exponentially more succinct than their standard CSP counterparts.