English

Improved Algorithms for Solving Polynomial Systems over GF(2) by Multiple Parity-Counting

Data Structures and Algorithms 2020-07-17 v2

Abstract

We consider the problem of finding a solution to a multivariate polynomial equation system of degree dd in nn variables over F2\mathbb{F}_2. For d=2d=2, the best-known algorithm for the problem is by Bardet et al. [J. Complexity, 2013] and was shown to run in time O(20.792n)O(2^{0.792n}) under assumptions that were experimentally found to hold for random equation systems. The best-known worst-case algorithm for the problem is due to Bj\"{o}rklund et al. [ICALP'19]. It runs in time O(20.804n)O(2^{0.804n}) for d=2d = 2 and O(2(11/(2.7d))n)O(2^{(1 - 1/(2.7d))n}) for d>2d > 2. In this paper, we devise a worst-case algorithm that improves the one by Bj\"{o}rklund et al. It runs in time O(20.6943n)O(2^{0.6943n}) (or O(1.6181n)O(1.6181^n)) for d=2d = 2 and O(2(11/(2d))n)O(2^{(1 - 1/(2d))n}) for d>2d > 2. Our algorithm thus outperforms all known worst-case algorithms, as well as ones analyzed for random equation systems. We also devise a second algorithm that outputs all solutions to a polynomial system and has similar complexity to the first (provided that the number of solutions is not too large). A central idea in the work of Bj\"{o}rklund et al. was to reduce the problem of finding a solution to a polynomial system over F2\mathbb{F}_2 to the problem of counting the parity of all solutions. A parity-counting instance was then reduced to many smaller parity-counting instances. Our main observation is that these smaller instances are related and can be solved more efficiently by a new algorithm to a problem which we call multiple parity-counting.

Keywords

Cite

@article{arxiv.2005.04800,
  title  = {Improved Algorithms for Solving Polynomial Systems over GF(2) by Multiple Parity-Counting},
  author = {Itai Dinur},
  journal= {arXiv preprint arXiv:2005.04800},
  year   = {2020}
}

Comments

Several (mostly small) changes

R2 v1 2026-06-23T15:26:32.428Z