Paper 2021/470
Upslices, Downslices, and Secret-Sharing with Complexity of $1.5^n$
Benny Applebaum and Oded Nir
Abstract
A secret-sharing scheme allows to distribute a secret $s$ among $n$ parties such that only some predefined ``authorized'' sets of parties can reconstruct the secret, and all other ``unauthorized'' sets learn nothing about $s$. The collection of authorized/unauthorized sets can be captured by a monotone function $f:\{0,1\}^n\rightarrow \{0,1\}$. In this paper, we focus on monotone functions that all their min-terms are sets of size $a$, and on their duals -- monotone functions whose max-terms are of size $b$. We refer to these classes as $(a,n)$-upslices and $(b,n)$-downslices, and note that these natural families correspond to monotone $a$-regular DNFs and monotone $(n-b)$-regular CNFs. We derive the following results. 1. (General downslices) Every downslice can be realized with total share size of $1.5^{n+o(n)}<2^{0.585 n}$. Since every monotone function can be cheaply decomposed into $n$ downslices, we obtain a similar result for general access structures improving the previously known $2^{0.637n+o(n)}$ complexity of Applebaum, Beimel, Nir and Peter (STOC 2020). We also achieve a minor improvement in the exponent of linear secrets sharing schemes. 2. (Random mixture of upslices) Following Beimel and Farras (TCC 2020) who studied the complexity of random DNFs with constant-size terms, we consider the following general distribution $F$ over monotone DNFs: For each width value $a\in [n]$, uniformly sample $k_a$ monotone terms of size $a$, where $k=(k_1,\ldots,k_n)$ is an arbitrary vector of non-negative integers. We show that, except with exponentially small probability, $F$ can be realized with share size of $2^{0.5 n+o(n)}$ and can be linearly realized with an exponent strictly smaller than $2/3$. Our proof also provides a candidate distribution for ``exponentially-hard'' access structure. We use our results to explore connections between several seemingly unrelated questions about the complexity of secret-sharing schemes such as worst-case vs. average-case, linear vs. non-linear and primal vs. dual access structures. We prove that, in at least one of these settings, there is a significant gap in secret-sharing complexity.
Metadata
- Available format(s)
- Publication info
- Preprint. MINOR revision.
- Keywords
- Secret SharingInformation Theoretic Cryptography
- Contact author(s)
-
odednir123 @ gmail com
benny applebaum @ gmail com - History
- 2021-04-12: received
- Short URL
- https://ia.cr/2021/470
- License
-
CC BY
BibTeX
@misc{cryptoeprint:2021/470, author = {Benny Applebaum and Oded Nir}, title = {Upslices, Downslices, and Secret-Sharing with Complexity of $1.5^n$}, howpublished = {Cryptology {ePrint} Archive, Paper 2021/470}, year = {2021}, url = {https://eprint.iacr.org/2021/470} }