An Algorithmic Reduction Theory for Binary Codes: LLL and More

Thomas Debris-Alazard; Leo Ducas; Wessel P.J. Van Woerden

doi:10.1109/TIT.2022.3143620

An Algorithmic Reduction Theory for Binary Codes: LLL and More

Thomas Debris-Alazard
, Leo Ducas
, Wessel P.J. Van Woerden

Research output: Contribution to journal › Article › peer-review

Abstract

In this article, we propose an adaptation of the algorithmic reduction theory of lattices to binary codes. This includes the celebrated LLL algorithm (Lenstra, Lenstra, Lovasz, 1982), as well as adaptations of associated algorithms such as the Nearest Plane Algorithm of Babai (1986). Interestingly, the adaptation of LLL to binary codes can be interpreted as an algorithmic version of the bound of Griesmer (1960) on the minimal distance of a code. Using these algorithms, we demonstrate - both with a heuristic analysis and in practice - a small polynomial speed-up over the Information-Set Decoding algorithm of Lee and Brickell (1988) for random binary codes. This appears to be the first such speed-up that is not based on a time-memory trade-off. The above speed-up should be read as a very preliminary example of the potential of a reduction theory for codes, for example in cryptanalysis.

Original language	English
Pages (from-to)	3426-3444
Number of pages	19
Journal	IEEE Transactions on Information Theory
Volume	68
Issue number	5
DOIs	https://doi.org/10.1109/TIT.2022.3143620
Publication status	Published - 1 May 2022
Externally published	Yes

Keywords

Codes
LLL
cryptanalysis
information set decoding
lattices

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10.1109/TIT.2022.3143620

Cite this

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title = "An Algorithmic Reduction Theory for Binary Codes: LLL and More",

abstract = "In this article, we propose an adaptation of the algorithmic reduction theory of lattices to binary codes. This includes the celebrated LLL algorithm (Lenstra, Lenstra, Lovasz, 1982), as well as adaptations of associated algorithms such as the Nearest Plane Algorithm of Babai (1986). Interestingly, the adaptation of LLL to binary codes can be interpreted as an algorithmic version of the bound of Griesmer (1960) on the minimal distance of a code. Using these algorithms, we demonstrate - both with a heuristic analysis and in practice - a small polynomial speed-up over the Information-Set Decoding algorithm of Lee and Brickell (1988) for random binary codes. This appears to be the first such speed-up that is not based on a time-memory trade-off. The above speed-up should be read as a very preliminary example of the potential of a reduction theory for codes, for example in cryptanalysis.",

keywords = "Codes, LLL, cryptanalysis, information set decoding, lattices",

author = "Thomas Debris-Alazard and Leo Ducas and \{Van Woerden\}, \{Wessel P.J.\}",

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AU - Debris-Alazard, Thomas

AU - Ducas, Leo

AU - Van Woerden, Wessel P.J.

PY - 2022/5/1

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N2 - In this article, we propose an adaptation of the algorithmic reduction theory of lattices to binary codes. This includes the celebrated LLL algorithm (Lenstra, Lenstra, Lovasz, 1982), as well as adaptations of associated algorithms such as the Nearest Plane Algorithm of Babai (1986). Interestingly, the adaptation of LLL to binary codes can be interpreted as an algorithmic version of the bound of Griesmer (1960) on the minimal distance of a code. Using these algorithms, we demonstrate - both with a heuristic analysis and in practice - a small polynomial speed-up over the Information-Set Decoding algorithm of Lee and Brickell (1988) for random binary codes. This appears to be the first such speed-up that is not based on a time-memory trade-off. The above speed-up should be read as a very preliminary example of the potential of a reduction theory for codes, for example in cryptanalysis.

AB - In this article, we propose an adaptation of the algorithmic reduction theory of lattices to binary codes. This includes the celebrated LLL algorithm (Lenstra, Lenstra, Lovasz, 1982), as well as adaptations of associated algorithms such as the Nearest Plane Algorithm of Babai (1986). Interestingly, the adaptation of LLL to binary codes can be interpreted as an algorithmic version of the bound of Griesmer (1960) on the minimal distance of a code. Using these algorithms, we demonstrate - both with a heuristic analysis and in practice - a small polynomial speed-up over the Information-Set Decoding algorithm of Lee and Brickell (1988) for random binary codes. This appears to be the first such speed-up that is not based on a time-memory trade-off. The above speed-up should be read as a very preliminary example of the potential of a reduction theory for codes, for example in cryptanalysis.

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KW - cryptanalysis

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KW - lattices

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An Algorithmic Reduction Theory for Binary Codes: LLL and More

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