English

A Meta-Complexity Characterization of Quantum Cryptography

Cryptography and Security 2024-10-08 v1 Computational Complexity Quantum Physics

Abstract

We prove the first meta-complexity characterization of a quantum cryptographic primitive. We show that one-way puzzles exist if and only if there is some quantum samplable distribution of binary strings over which it is hard to approximate Kolmogorov complexity. Therefore, we characterize one-way puzzles by the average-case hardness of a uncomputable problem. This brings to the quantum setting a recent line of work that characterizes classical cryptography with the average-case hardness of a meta-complexity problem, initiated by Liu and Pass. Moreover, since the average-case hardness of Kolmogorov complexity over classically polynomial-time samplable distributions characterizes one-way functions, this result poses one-way puzzles as a natural generalization of one-way functions to the quantum setting. Furthermore, our equivalence goes through probability estimation, giving us the additional equivalence that one-way puzzles exist if and only if there is a quantum samplable distribution over which probability estimation is hard. We also observe that the oracle worlds of defined by Kretschmer et. al. rule out any relativizing characterization of one-way puzzles by the hardness of a problem in NP or QMA, which means that it may not be possible with current techniques to characterize one-way puzzles with another meta-complexity problem.

Keywords

Cite

@article{arxiv.2410.04984,
  title  = {A Meta-Complexity Characterization of Quantum Cryptography},
  author = {Bruno P. Cavalar and Eli Goldin and Matthew Gray and Peter Hall},
  journal= {arXiv preprint arXiv:2410.04984},
  year   = {2024}
}

Comments

26 pages

R2 v1 2026-06-28T19:11:03.571Z