Deterministic Hardness of Approximation of Unique-SVP and GapSVP in p norms for p>2
Abstract
We establish deterministic hardness of approximation results for the Shortest Vector Problem in p norm (SVPp) and for Unique-SVP (uSVPp) for all p > 2. Previously, no deterministic hardness results were known, except for ∞. For every p > 2, we prove constant-ratio hardness: no polynomial-time algorithm approximates SVPp or uSVPp within a ratio of 2 - o(1), assuming 3SAT DTIME(2O(n2/3 n)), and, Unambiguous-3SAT DTIME(2O(n2/3 n)). We also show that for any > 0 there exists p > 2 such that for every p p: no polynomial-time algorithm approximates SVPp within a ratio of 2( n)1- , assuming NP DTIME(n( n)); and within a ratio of n1/((n)), assuming NP SUBEXP. This improves upon [Haviv, Regev, Theory of Computing 2012], which obtained similar inapproximation ratios under randomized reductions. We obtain analogous results for uSVPp under the assumptions Unambiguous-3SAT ⊂eq DTIME(n( n)) and Unambiguous-3SAT ⊂eq SUBEXP, improving the previously known 1+o(1) [Stephens-Davidowitz, Approx 2016]. Strengthening the hardness of uSVP has direct cryptographic impact. By the reduction of Lyubashevsky and Micciancio [Lyubashevsky, Micciancio, CRYPTO 2009], hardness for γ-uSVPp carries over to 1γ-BDDp (Bounded Distance Decoding). Thus, understanding the hardness of uSVP improves worst-case guarantees for two core problems that underpin security in lattice-based cryptography.
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