Recovery Reductions in the Random Noise Model via Group Theory: Insights into NP-Complete and Fine-Grained Problems

We introduce and initiate the study of a new model of reductions called the random noise model. In this model, the truth table $T_f$ of the function $f$ is corrupted on a randomly chosen $\delta$-fraction of instances. A randomized algorithm $A$ is a $\left(t, \delta, 1-\varepsilon\right)$-recovery reduction for $f$ if: 1. With probability $1-\varepsilon$ over the choice of $\delta$-fraction corruptions, given access to the corrupted truth table, the algorithm $A$ computes $f(\phi)$ correctly with probability at least $2/3$ on every input $\phi$. 2. The algorithm $A$ runs in time $O(t)$. We believe this model, which is a natural relaxation of average-case complexity, both has practical motivations and is mathematically interesting. Pointing towards this, we show the existence of robust deterministic polynomial-time recovery reductions with the highest tolerable noise level for many of the canonical NP-complete problems - SAT, kSAT, kCSP, CLIQUE and more. Our recovery reductions are optimal for non-adaptive algorithms under complexity-theoretic assumptions. Notably, all our recovery reductions follow as corollaries of one black box algorithm based on group theory and permutation group algorithms. This suggests that recovery reductions in the random noise model are important to the study of the structure of NP-completeness. Furthermore, we establish recovery reductions with optimal parameters for Orthogonal Vectors and Parity $k$-Clique problems. These problems exhibit structural similarities to NP-complete problems, with Orthogonal Vectors admitting a $2^{0.5n}$-time reduction from kSAT on $n$ variables and Parity $k$-Clique, a subexponential-time reduction from 3SAT. This further highlights the relevance of our model to the study of NP-completeness.