Abstract
For many computational problems involving randomness, intricate geometric features of the solution space have been used to rigorously rule out powerful classes of algorithms. This is often accomplished through the lens of the multi Overlap Gap Property (m-OGP), a rigorous barrier against algorithms exhibiting input stability. In this paper, we focus on the algorithmic tractability of two models: (i) discrepancy minimization, and (ii) the symmetric binary perceptron (SBP), a random constraint satisfaction problem as well as a toy model of a single-layer neural network. Our first focus is on the limits of online algorithms. By establishing and leveraging a novel geometrical barrier, we obtain sharp hardness guarantees against online algorithms for both the SBP and discrepancy minimization. Our results match the best known algorithmic guarantees, up to constant factors. Our second focus is on efficiently finding a constant discrepancy solution, given a random matrix M ∈ RM×n. In a smooth setting, where the entries of M are i.i.d. standard normal, we establish the presence of m-OGP for n = Θ(M log M). Consequently, we rule out the class of stable algorithms at this value. These results give the first rigorous evidence towards Altschuler and Niles-Weed (2022, Conjecture 1). Our methods use the intricate geometry of the solution space to prove tight hardness results for online algorithms. The barrier we establish is a novel variant of the m-OGP. Furthermore, it regards m-tuples of solutions with respect to correlated instances, with growing values of m, m = ω(1). Importantly, our results rule out online algorithms succeeding even with an exponentially small probability.
Original language | English (US) |
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Pages (from-to) | 3231-3263 |
Number of pages | 33 |
Journal | Proceedings of Machine Learning Research |
Volume | 195 |
State | Published - 2023 |
Externally published | Yes |
Event | 36th Annual Conference on Learning Theory, COLT 2023 - Bangalore, India Duration: Jul 12 2023 → Jul 15 2023 |
Keywords
- Binary perceptron
- Discrepancy
- overlap gap property
- statistical-to-computational gap
ASJC Scopus subject areas
- Artificial Intelligence
- Software
- Control and Systems Engineering
- Statistics and Probability