English

Cubic Goldreich-Levin

Data Structures and Algorithms 2022-11-21 v2

Abstract

In this paper, we give a cubic Goldreich-Levin algorithm which makes polynomially-many queries to a function f ⁣:FpnCf \colon \mathbb F_p^n \to \mathbb C and produces a decomposition of ff as a sum of cubic phases and a small error term. This is a natural higher-order generalization of the classical Goldreich-Levin algorithm. The classical (linear) Goldreich-Levin algorithm has wide-ranging applications in learning theory, coding theory and the construction of pseudorandom generators in cryptography, as well as being closely related to Fourier analysis. Higher-order Goldreich-Levin algorithms on the other hand involve central problems in higher-order Fourier analysis, namely the inverse theory of the Gowers UkU^k norms, which are well-studied in additive combinatorics. The only known result in this direction prior to this work is the quadratic Goldreich-Levin theorem, proved by Tulsiani and Wolf in 2011. The main step of their result involves an algorithmic version of the U3U^3 inverse theorem. More complications appear in the inverse theory of the U4U^4 and higher norms. Our cubic Goldreich-Levin algorithm is based on algorithmizing recent work by Gowers and Mili\'cevi\'c who proved new quantitative bounds for the U4U^4 inverse theorem. Our cubic Goldreich-Levin algorithm is constructed from two main tools: an algorithmic U4U^4 inverse theorem and an arithmetic decomposition result in the style of the Frieze-Kannan graph regularity lemma. As one application of our main theorem we solve the problem of self-correction for cubic Reed-Muller codes beyond the list decoding radius. Additionally we give a purely combinatorial result: an improvement of the quantitative bounds on the U4U^4 inverse theorem.

Cite

@article{arxiv.2207.13281,
  title  = {Cubic Goldreich-Levin},
  author = {Dain Kim and Anqi Li and Jonathan Tidor},
  journal= {arXiv preprint arXiv:2207.13281},
  year   = {2022}
}

Comments

51 pages

R2 v1 2026-06-25T01:15:43.999Z