Hardness of Range Avoidance and Remote Point for Restricted Circuits via Cryptography

Author(s)

Chen, Yilei; Li, Jiatu

Abstract

A recent line of research has introduced a systematic approach to exploring the complexity of explicit construction problems through the use of meta-problems, namely, the range avoidance problem (abbrev. Avoid) and the remote point problem (abbrev. ). The upper and lower bounds for these meta problems provide a unified perspective on the complexity of specific explicit construction problems that were previously studied independently. An interesting question largely unaddressed by previous works is whether we can show hardness of Avoid and RPP for simple circuits, such as low-depth circuits. In this paper, we demonstrate, under plausible cryptographic assumptions, that both the range avoidance problem and the remote point problem cannot be efficiently solved by nondeterministic search algorithms, even when the input circuits are as simple as constant-depth circuits. This extends a hardness result established by Ilango, Li, and Williams (STOC’23) against deterministic algorithms employing witness encryption for NP, where the inputs to Avoid are general Boolean circuits. Our primary technical contribution is a novel construction of witness encryption inspired by public-key encryption for certain promise language in NP that is unlikely to be NP-complete. We introduce a generic approach to transform a public-key encryption scheme with particular properties into a witness encryption scheme for a promise language related to the initial public-key encryption scheme. Based on this translation and variants of standard lattice-based or coding-based PKE schemes, we obtain, under plausible assumption, a provably secure witness encryption scheme for some promise language in NP-coNP/poly. Additionally, we show that our constructions of witness encryption are plausibly secure against nondeterministic adversaries under a generalized notion of security in the spirit of Rudich’s super-bits (RANDOM’97), which is crucial for demonstrating the hardness of Avoid and RPP against nondeterministic algorithms.

Description

STOC ’24, June 24–28, 2024, Vancouver, BC, Canada

Date issued

2024-06-10

URI

https://hdl.handle.net/1721.1/155704

Department

Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory

Journal

STOC 2024: Proceedings of the 56th Annual ACM Symposium on Theory of Computing

Publisher

ACM

Citation

Chen, Yilei and Li, Jiatu. 2024. "Hardness of Range Avoidance and Remote Point for Restricted Circuits via Cryptography." STOC 2024: Proceedings of the 56th Annual ACM Symposium on Theory of Computing.

Version: Final published version

ISBN

979-8-4007-0383-6