Optimal Proximity Gap for Folded Reed--Solomon Codes via Subspace Designs

Abstract

A collection of sets satisfies a (δ,)-proximity gap with respect to some property if for every set in the collection, either (i) all members of the set are δ-close to the property in (relative) Hamming distance, or (ii) only a small -fraction of members are δ-close to the property. In a seminal work, Ben-Sasson et al.\ showed that the collection of affine subspaces exhibits a (δ,)-proximity gap with respect to the property of being Reed--Solomon (RS) codewords with δ up to the so-called Johnson bound for list decoding. Their technique relies on the Guruswami--Sudan list decoding algorithm for RS codes, which is guaranteed to work in the Johnson bound regime. Folded Reed--Solomon (FRS) codes are known to achieve the optimal list decoding radius δ, a regime known as capacity. Moreover, a rich line of list decoding algorithms was developed for FRS codes. It is then natural to ask if FRS codes can be shown to exhibit an analogous (δ,)-proximity gap, but up to the so-called optimal capacity regime. We answer this question in the affirmative (and the framework naturally applies more generally to suitable subspace-design codes). An additional motivation to understand proximity gaps for FRS codes is the recent results [BCDZ'25] showing that they exhibit properties similar to random linear codes, which were previously shown to be related to properties of RS codes with random evaluation points in [LMS'25], as well as codes over constant-size alphabet based on AEL [JS'25].