English

On efficiently computable functions, deep networks and sparse compositionality

Machine Learning 2025-10-15 v1

Abstract

We show that \emph{efficient Turing computability} at any fixed input/output precision implies the existence of \emph{compositionally sparse} (bounded-fan-in, polynomial-size) DAG representations and of corresponding neural approximants achieving the target precision. Concretely: if f:[0,1]dRmf:[0,1]^d\to\R^m is computable in time polynomial in the bit-depths, then for every pair of precisions (n,mout)(n,m_{\mathrm{out}}) there exists a bounded-fan-in Boolean circuit of size and depth \poly(n+mout)\poly(n+m_{\mathrm{out}}) computing the discretized map; replacing each gate by a constant-size neural emulator yields a deep network of size/depth \poly(n+mout)\poly(n+m_{\mathrm{out}}) that achieves accuracy ε=2mout\varepsilon=2^{-m_{\mathrm{out}}}. We also relate these constructions to compositional approximation rates \cite{MhaskarPoggio2016b,poggio_deep_shallow_2017,Poggio2017,Poggio2023HowDS} and to optimization viewed as hierarchical search over sparse structures.

Keywords

Cite

@article{arxiv.2510.11942,
  title  = {On efficiently computable functions, deep networks and sparse compositionality},
  author = {Tomaso Poggio},
  journal= {arXiv preprint arXiv:2510.11942},
  year   = {2025}
}
R2 v1 2026-07-01T06:35:00.998Z