Toward a Uniform Algorithm and Uniform Reduction for Constraint Problems

Abstract

We develop a unified framework to characterize the power of higher-level algorithms for the constraint satisfaction problem (CSP), such as k-consistency, the Sherali-Adams LP hierarchy, and the affine IP hierarchy. As a result, solvability of a fixed-template CSP or, more generally, a Promise CSP by a given level is shown to depend only on the polymorphism minion of the template. Similarly, we obtain a minion-theoretic description of k-consistency reductions between Promise CSPs. We introduce a new hierarchy of SDP-like vector relaxations with vectors over Zp in which orthogonality is imposed on k-tuples of vectors. Surprisingly, this relaxation turns out to be equivalent to the k-th level of the AIP-Zp relaxation. We show that it solves the CSP of the dihedral group D4, the smallest CSP that fools the singleton BLP+AIP algorithm. Using this vector representation, we further show that the p-th level of the Zp relaxation solves linear equations modulo p2.