Improved Hardness of BDD and SVP Under Gap-(S)ETH

Abstract

We show improved fine-grained hardness of two key lattice problems in the p norm: Bounded Distance Decoding to within an α factor of the minimum distance (BDDp, α) and the (decisional) γ-approximate Shortest Vector Problem (SVPp,γ), assuming variants of the Gap (Strong) Exponential Time Hypothesis (Gap-(S)ETH). Specifically, we show: 1. For all p ∈ [1, ∞), there is no 2o(n)-time algorithm for BDDp, α for any constant α > αkn, where αkn = 2-ckn and ckn is the 2 kissing-number constant, assuming ckn > 0 and that non-uniform Gap-ETH holds. 2. For all p ∈ [1, ∞), there is no 2o(n)-time algorithm for BDDp, α for any constant α > αp, where αp is explicit and satisfies αp = 1 for 1 ≤ p ≤ 2, αp < 1 for all p > 2, and αp 1/2 as p ∞, unless randomized Gap-ETH is false. 3. For all p ∈ [1, ∞) 2 Z and all C > 1, there is no 2n/C-time algorithm for BDDp, α for any constant α > αp, C, where αp, C is explicit and satisfies αp, C 1 as C ∞ for any fixed p ∈ [1, ∞), assuming ckn > 0 and that non-uniform Gap-SETH holds. 4. For all p > p0 ≈ 2.1397, p 2Z, and all C > Cp, there is no 2n/C-time algorithm for SVPp, γ for some constant γ > 1, where Cp > 1 is explicit and satisfies Cp 1 as p ∞, unless randomized Gap-SETH is false.