Code-based cryptography

From PQC WIKI
Revision as of 23:36, 12 May 2021 by Admin (talk | contribs) (1 revision imported)
(diff) ← Older revision | Latest revision (diff) | Newer revision → (diff)

Code-based Problems

1. Syndrome Decoding

SDP – Syndrome Decoding [1]

Let be positive integers. A distribution is sampled by choosing and where , and ouputing .

PROBLEM. Search-SDP

Given a vector , , and a positive interger .
Goal. Find vector such that and .


PROBLEM. Decisional-SDP

Goal. Distinguish with a non-negligible advantage between samples from the SD distribution and samples from the uniform distribution over .


RSD – Rank Syndrome Decoding

Let be positive integers. A distribution is sampled by choosing and where , and ouputing .

PROBLEM. Search-RSD

Given a vector , , and a positive interger .
Goal. Find vector such that and .


PROBLEM. Decisional-RSD

Goal. Distinguish with a non-negligible advantage between samples from distribution and samples from the uniform distribution over .


RELATED PAPERS

An Algebraic Attack on Rank Metric Code-Based Cryptosystems
Magali Bardet and Pierre Briaud and Maxime Bros and Philippe Gaborit and Vincent Neiger and Olivier Ruatta and Jean-Pierre Tillich.
arXiv, 2019.

New Technique for Decoding Codes in the Rank Metric and Its Cryptography Applications
A. V. Ourivski and T. Johansson.
Problems of Information Transmission, 2002.

On the complexity of the Rank Syndrome Decoding problem
Philippe Gaborit and Olivier Ruatta and Julien Schrek.
arXiv, 2013.


Ideal RSD – Ideal Rank Syndrome Decoding[2]

Let be an irreducilbe polynomial of degree and be positive integers. Let be the set of parity-check matrices under systematic form of ideal codes of type . The IRSD distribution is sampled by choosing uniformly at random a matrix H from , a vector from such that and, and ouputing .

PROBLEM. Search Ideal RSD

Given be an irreducilbe polynomial of degree and be positive integers. Given a random parity check matrix under systematic form of ideal codes and .
Goal. Find from such that and, and ouputing .


PROBLEM. Decisional Ideal RSD

Given be an irreducilbe polynomial of degree and be positive integers. Let be the set of parity-check matrices under systematic form of ideal codes of type .
Goal. Distinguish with a non-negligible advantage between samples from distribution and samples from the uniform distribution over .


QC-SDP – Quasi-Cyclic Syndrome Decoding

DEFINITION. Quasi-cyclic code (QC) [3]

A linear code of length is a QC code of order and index if is generated by parity-check matrix where is an circulant matrix.


PROBLEM. Search QC-SDP

Given a set of matrices , a positive integer and a vector . Define as the circulant matrix generated by .
Goal. Find vector with and .


2. Ideal LRPC – Ideal Low Rank Parity Check

The definition of the Low Rank Parity Check[4] (LRPC) codes was proposed by Gaborit, Murat, Ruatta, and Zémor in 2013.

DEFINITION. Low Rank Parity Check codes (LRPC)

A LRPC code of rank , length and dimension over is a code where it has a parity-check matrix . The coefficients of generate a sub-vector space of of small dimension .


DEFINITION. Ideal Low Rank Parity Check codes (Ideal LRPC)[5]

Let be a sub-vector space of a small dimension of , two vectors of of support and a polynomial of degree . Let The code with parity-check matrix is an ideal LRPC code of type .


PROBLEM. Decisional Ideal LRPC[5]

Given a polynomial of degree and a vector
Goal. Distinguish an ideal code with the parity-check matrix generated by is a random linear code or if it is an ideal LRPC code of weight .

Submissions in NIST

PKE/KEM
(19 schemes)
BIG QUAKE
BIKE
Classic McEliece
DAGS
Edon-K
HQC
LAKE
LEDAkem
LEDApkc
Lepton
LOCKER
McNie
NTS-KEM
ROLLO
Ouroboros-R
QC-MDPC KEM
Ramstake
RLCE-KEM
RQC
Signatures
(3 schemes)
pqsigRM
RaCoSS
RankSign

References

GENERAL
  1. On the inherent intractability of certain coding problems
    Berlekamp, E. and McEliece, R. and van Tilborg, H..
    in IEEE Transactions on Information Theory, vol. 24, no. 3, pp. 384-386, May 1978..
  2. Low rank parity check codes and their application to cryptography
    Carlos Aguilar Melchor, Nicolas Aragon, Slim Bettaieb, Loïc Bidoux, Olivier Blazy, Jean-Christophe Deneuville, Philippe Gaborit, Adrien Hauteville, • Alain Couvreur.
    NIST submission.
  3. Reducing Key Length of the McEliece Cryptosystem
    Berger, Thierry P. and Cayrel, Pierre-Louis and Gaborit, Philippe and Otmani, Ayoub..
    AFRICACRYPT '09., 2009.
  4. Low rank parity check codes and their application to cryptography
    Philippe Gaborit, Gaétan Murat, Olivier Ruatta, Gilles Zemor..
    Proceedings of the Workshop on Coding and Cryptography WCC., 2013.
  5. 5.0 5.1 Low rank parity check codes and their application to cryptography
    Carlos Aguilar Melchor, Nicolas Aragon, Slim Bettaieb, Loïc Bidoux, Olivier Blazy, Jean-Christophe Deneuville, Philippe Gaborit, Adrien Hauteville, Olivier Ruatta, Jean-Pierre Tillich, Gilles Zémor.
    NIST submission.

Cite error: <ref> tag with name "MTSB13" defined in <references> is not used in prior text.