Hardness of Range Avoidance and Proof Complexity Generators from Demi-Bits
Abstract
Given a circuit with , the *range avoidance* problem () asks to output a string that is not in the range of . Besides its profound connection to circuit complexity and explicit construction problems, this problem is also related to the existence of *proof complexity generators* -- circuits where but for every , it is infeasible to prove the statement "" in a given propositional proof system. This paper connects these two problems with the existence of *demi-bits generators*, a fundamental cryptographic primitive against nondeterministic adversaries introduced by Rudich (RANDOM '97). We show that the existence of demi-bits generators implies is hard for nondeterministic algorithms. This resolves an open problem raised by Chen and Li (STOC '24). Furthermore, assuming the demi-hardness of certain LPN-style generators or Goldreich' PRG, we prove the hardness of even when the instances are constant-degree polynomials over . We show that the dual weak pigeonhole principle is unprovable in Cook's theory under the existence of demi-bits generators secure against , thereby separating Jerabek's theory from . We transform demi-bits generators to proof complexity generators that are *pseudo-surjective* with nearly optimal parameters. Our constructions build on the recent breakthroughs on the hardness of by Ilango, Li, and Williams (STOC '23) and Chen and Li (STOC '24). We use *randomness extractors* to significantly simplify the construction and the proof.
Keywords
Cite
@article{arxiv.2511.14061,
title = {Hardness of Range Avoidance and Proof Complexity Generators from Demi-Bits},
author = {Hanlin Ren and Yichuan Wang and Yan Zhong},
journal= {arXiv preprint arXiv:2511.14061},
year = {2026}
}
Comments
ITCS 2026. Abstract shortened due to constraints