Limitations to Computing Quadratic Functions on Reed-Solomon Encoded Data

We study the problem of low-bandwidth non-linear computation on Reed-Solomon encoded data. Given an $[n,k]$ Reed-Solomon encoding of a message vector $\vec{f} \in \mathbb{F}_q^k$, and a polynomial $g \in \mathbb{F}_q[X_1, X_2, \ldots, X_k]$, a user wishing to evaluate $g(\vec{f})$ is given local query access to each codeword symbol. The query response is allowed to be the output of an arbitrary function evaluated locally on the codeword symbol, and the user's aim is to minimize the total information downloaded in order to compute $g(\vec{f})$. We show that when $k=2$ and $q = p^e$ for odd $e$ and prime $p$ satisfying $p\equiv 3 \mod 4$, then any scheme that evaluates the quadratic monomial $g(X_1, X_2) := X_1 X_2$ must download at least $2\lceil \log_2(q-1) \rceil - 3$ bits of information. Compare this with the straightforward scheme of Reed-Solomon interpolation which recovers $\vec{f}$ in its entirety, which downloads $2 \lceil \log_2(q) \rceil$ bits. Our result shows that dimension-2 Reed-Solomon codes do not admit any meaningful low-bandwidth scheme for the evaluation of quadratic functions over the encoded data. This contrasts sharply with prior work for low-bandwidth evaluation of linear functions $g(\vec{f})$ over Reed-Solomon encoded data, for which it is possible to substantially improve upon the naive bound of $k \lceil \log_2(q) \rceil$ bits.