English

Superpolynomial Lower Bounds for Decision Tree Learning and Testing

Computational Complexity 2022-10-13 v1 Data Structures and Algorithms Machine Learning

Abstract

We establish new hardness results for decision tree optimization problems, adding to a line of work that dates back to Hyafil and Rivest in 1976. We prove, under randomized ETH, superpolynomial lower bounds for two basic problems: given an explicit representation of a function ff and a generator for a distribution D\mathcal{D}, construct a small decision tree approximator for ff under D\mathcal{D}, and decide if there is a small decision tree approximator for ff under D\mathcal{D}. Our results imply new lower bounds for distribution-free PAC learning and testing of decision trees, settings in which the algorithm only has restricted access to ff and D\mathcal{D}. Specifically, we show: nn-variable size-ss decision trees cannot be properly PAC learned in time nO~(loglogs)n^{\tilde{O}(\log\log s)}, and depth-dd decision trees cannot be tested in time exp(dO(1))\exp(d^{\,O(1)}). For learning, the previous best lower bound only ruled out poly(n)\text{poly}(n)-time algorithms (Alekhnovich, Braverman, Feldman, Klivans, and Pitassi, 2009). For testing, recent work gives similar though incomparable bounds in the setting where ff is random and D\mathcal{D} is nonexplicit (Blais, Ferreira Pinto Jr., and Harms, 2021). Assuming a plausible conjecture on the hardness of Set-Cover, we show our lower bound for learning decision trees can be improved to nΩ(logs)n^{\Omega(\log s)}, matching the best known upper bound of nO(logs)n^{O(\log s)} due to Ehrenfeucht and Haussler (1989). We obtain our results within a unified framework that leverages recent progress in two lines of work: the inapproximability of Set-Cover and XOR lemmas for query complexity. Our framework is versatile and yields results for related concept classes such as juntas and DNF formulas.

Keywords

Cite

@article{arxiv.2210.06375,
  title  = {Superpolynomial Lower Bounds for Decision Tree Learning and Testing},
  author = {Caleb Koch and Carmen Strassle and Li-Yang Tan},
  journal= {arXiv preprint arXiv:2210.06375},
  year   = {2022}
}

Comments

44 pages, 5 figures. SODA 2023

R2 v1 2026-06-28T03:27:56.669Z