Hereditary First-Order Model Checking

Many computational problems can be modelled as the class of all finite relational structures $\mathbb A$ that satisfy a fixed first-order sentence $\phi$ hereditarily, i.e., we require that every substructure of $\mathbb A$ satisfies $\phi$. In this case, we say that the class is in HerFO. The problems in HerFO are always in coNP, and sometimes coNP-complete. HerFO also contains many interesting computational problems in P, including many constraint satisfaction problems (CSPs). We show that HerFO captures the class of complements of CSPs for reducts of finitely bounded structures, i.e., every such CSP is polynomial-time equivalent to the complement of a problem in HerFO. However, we also prove that HerFO does not have the full computational power of coNP: there are problems in coNP that are not polynomial-time equivalent to a problem in HerFO, unless E=NE. Another main result is a description of the quantifier-prefixes for $\phi$ such that hereditarily checking $\phi$ is in P; we show that for every other quantifier-prefix there exists a formula $\phi$ with this prefix such that hereditarily checking $\phi$ is coNP-complete.