English

Lattice Problems Beyond Polynomial Time

Computational Complexity 2022-11-22 v1 Cryptography and Security Data Structures and Algorithms

Abstract

We study the complexity of lattice problems in a world where algorithms, reductions, and protocols can run in superpolynomial time, revisiting four foundational results: two worst-case to average-case reductions and two protocols. We also show a novel protocol. 1. We prove that secret-key cryptography exists if O~(n)\widetilde{O}(\sqrt{n})-approximate SVP is hard for 2εn2^{\varepsilon n}-time algorithms. I.e., we extend to our setting (Micciancio and Regev's improved version of) Ajtai's celebrated polynomial-time worst-case to average-case reduction from O~(n)\widetilde{O}(n)-approximate SVP to SIS. 2. We prove that public-key cryptography exists if O~(n)\widetilde{O}(n)-approximate SVP is hard for 2εn2^{\varepsilon n}-time algorithms. This extends to our setting Regev's celebrated polynomial-time worst-case to average-case reduction from O~(n1.5)\widetilde{O}(n^{1.5})-approximate SVP to LWE. In fact, Regev's reduction is quantum, but ours is classical, generalizing Peikert's polynomial-time classical reduction from O~(n2)\widetilde{O}(n^2)-approximate SVP. 3. We show a 2εn2^{\varepsilon n}-time coAM protocol for O(1)O(1)-approximate CVP, generalizing the celebrated polynomial-time protocol for O(n/logn)O(\sqrt{n/\log n})-CVP due to Goldreich and Goldwasser. These results show complexity-theoretic barriers to extending the recent line of fine-grained hardness results for CVP and SVP to larger approximation factors. (This result also extends to arbitrary norms.) 4. We show a 2εn2^{\varepsilon n}-time co-non-deterministic protocol for O(logn)O(\sqrt{\log n})-approximate SVP, generalizing the (also celebrated!) polynomial-time protocol for O(n)O(\sqrt{n})-CVP due to Aharonov and Regev. 5. We give a novel coMA protocol for O(1)O(1)-approximate CVP with a 2εn2^{\varepsilon n}-time verifier. All of the results described above are special cases of more general theorems that achieve time-approximation factor tradeoffs.

Keywords

Cite

@article{arxiv.2211.11693,
  title  = {Lattice Problems Beyond Polynomial Time},
  author = {Divesh Aggarwal and Huck Bennett and Zvika Brakerski and Alexander Golovnev and Rajendra Kumar and Zeyong Li and Spencer Peters and Noah Stephens-Davidowitz and Vinod Vaikuntanathan},
  journal= {arXiv preprint arXiv:2211.11693},
  year   = {2022}
}
R2 v1 2026-06-28T06:23:58.632Z