English

An Algebraic Attack on Rank Metric Code-Based Cryptosystems

Cryptography and Security 2021-03-05 v2

Abstract

The Rank metric decoding problem is the main problem considered in cryptography based on codes in the rank metric. Very efficient schemes based on this problem or quasi-cyclic versions of it have been proposed recently, such as those in the submissions ROLLO and RQC currently at the second round of the NIST Post-Quantum Cryptography Standardization Process. While combinatorial attacks on this problem have been extensively studied and seem now well understood, the situation is not as satisfactory for algebraic attacks, for which previous work essentially suggested that they were ineffective for cryptographic parameters. In this paper, starting from Ourivski and Johansson's algebraic modelling of the problem into a system of polynomial equations, we show how to augment this system with easily computed equations so that the augmented system is solved much faster via Groebner bases. This happens because the augmented system has solving degree rr, r+1r+1 or r+2r+2 depending on the parameters, where rr is the rank weight, which we show by extending results from Verbel et al. (PQCrypto 2019) on systems arising from the MinRank problem; with target rank rr, Verbel et al. lower the solving degree to r+2r+2, and even less for some favorable instances that they call superdetermined. We give complexity bounds for this approach as well as practical timings of an implementation using Magma. This improves upon the previously known complexity estimates for both Groebner basis and (non-quantum) combinatorial approaches, and for example leads to an attack in 200 bits on ROLLO-I-256 whose claimed security was 256 bits.

Keywords

Cite

@article{arxiv.1910.00810,
  title  = {An Algebraic Attack on Rank Metric Code-Based Cryptosystems},
  author = {Magali Bardet and Pierre Briaud and Maxime Bros and Philippe Gaborit and Vincent Neiger and Olivier Ruatta and Jean-Pierre Tillich},
  journal= {arXiv preprint arXiv:1910.00810},
  year   = {2021}
}

Comments

Eurocrypt 2020

R2 v1 2026-06-23T11:32:27.617Z