Algorithmic Universality, Low-Degree Polynomials, and Max-Cut in Sparse Random Graphs

Universality, namely distributional invariance, is a well-known property for many random structures. For example it is known to hold for a broad range of variational problems with random input. Much less is known about the universality of the performance of specific algorithms for solving such variational problems. Namely, do algorithms tuned to specific variational tasks produce the same asymptotic answer regardless of the underlying distribution? In this paper we show that the answer is yes for a class of models, which includes spin glass models and constraint satisfaction problems on sparse graphs, provided that an algorithm can be coded as a low-degree polynomial (LDP). We illustrate this specifically for the case of the Max-Cut problem in sparse Erd\"os-R\'enyi graph $\mathbb{G}(n, d/n)$. We use the fact that the Approximate Message Passing (AMP) algorithm, which is an effective algorithm for finding near-ground state of the Sherrington-Kirkpatrick (SK) model, is well approximated by an LDP. We then establish our main universality result: the performance of the LDP based algorithms exhibiting certain connectivity property, is the same in the mean-field (SK) and in the random graph $\mathbb{G}(n, d/n)$ setting, up to an appropriate rescaling. The main technical challenge which we address in this paper is showing that the output of the LDP algorithm on $\mathbb{G}(n, d/n)$ is truly discrete, namely it is close to the set of points in the binary cube.