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General | |
---|---|

Designers | Praveen Gauravaram, Lars Knudsen, Krystian Matusiewicz, Florian Mendel, Christian Rechberger, Martin Schläffer, and Søren S. Thomsen |

Related to | AES |

Certification | SHA-3 finalist |

Detail | |

Digest sizes |
arbitrary (from 8 to 512 bits in 8-bit steps)^{[1]} |

Rounds | 10 (digest size 8-256) or 14 (digest size 264-512) |

Speed | 21.4 cpb on Core 2 for 224/256 bit digest; 30.1 cpb for 384/512 bit digest. |

Best public cryptanalysis | |

Collision attack on 5 rounds^{[2]} |

**Grøstl** is a cryptographic hash function submitted to the NIST hash function competition by Praveen Gauravaram, Lars Knudsen, Krystian Matusiewicz, Florian Mendel, Christian Rechberger, Martin Schläffer, and Søren S. Thomsen. Grøstl was chosen as one of the five finalists of the competition. It uses the same S-box as AES in a custom construction. The authors claim speeds of up to 21.4 cycles per byte on an Intel Core 2 Duo.

According to the submission document, the name "Grøstl" is a multilingual play-on-words, referring to an Austrian dish that is very similar to hash (food).

Like other hash functions in the MD5/SHA family, Grøstl divides the input into blocks and iteratively computes *h _{i}* =

The compression function *f* is based on a pair of 256- or 512-bit permutation functions *P* and *Q*, and is defined as:

*f*(*h*,*m*) =*P*(*h*⊕*m*) ⊕*Q*(*m*) ⊕*h*

The permutation functions *P* and *Q* are heavily based on the Rijndael (AES) block cipher, but operate on 8×8 or 8×16 arrays of bytes, rather than 4×4. Like AES, each round consists of four operations:

- AddRoundKey (the Grøstl round keys are fixed, but differ between P and Q)
- SubBytes (this uses the Rijndael S-box, allowing sharing with AES implementations)
- ShiftBytes (expanded compared to AES, this also differs between P and Q, and 512- and 1024-bit versions)
- MixColumns (using an 8×8 matrix rather than Rijndael's 4×4)

Unlike Rijndael, all rounds are identical and there is no final AddRoundKey operation. 10 rounds are recommended for the 512-bit permutation, and 14 rounds for the 1024-bit version.

The final double-width hash receives a final output transformation of

- Ω(
*h*) =*h*⊕*P*(*h*)

and is then truncated to the desired width. This is equivalent to applying a final iteration of the compression function using an all-zero message block *m*, followed by a (cryptographically insignificant) exclusive-or with the fixed constant *Q*(0).

Hash values of empty string.

Grøstl-224("") 0x f2e180fb5947be964cd584e22e496242c6a329c577fc4ce8c36d34c3 Grøstl-256("") 0x 1a52d11d550039be16107f9c58db9ebcc417f16f736adb2502567119f0083467 Grøstl-384("") 0x ac353c1095ace21439251007862d6c62f829ddbe6de4f78e68d310a9205a736d8b11d99bffe448f57a1cfa2934f044a5 Grøstl-512("") 0x 6d3ad29d279110eef3adbd66de2a0345a77baede1557f5d099fce0c03d6dc2ba8e6d4a6633dfbd66053c20faa87d1a11f39a7fbe4a6c2f009801370308fc4ad8

Even a small change in the message will (with overwhelming probability) result in a mostly different hash, due to the avalanche effect. For example, adding a period to the end of the sentence:

Grøstl-256("The quick brown fox jumps over the lazy dog") 0x 8c7ad62eb26a21297bc39c2d7293b4bd4d3399fa8afab29e970471739e28b301 Grøstl-256("The quick brown fox jumps over the lazy dog.") 0x f48290b1bcacee406a0429b993adb8fb3d065f4b09cbcdb464a631d4a0080aaf

**^**Praveen Gauravaram, Lars R. Knudsen, Krystian Matusiewicz, Florian Mendel, Christian Rechberger, Martin Schläffer, and Søren S. Thomsen (2011-03-02),*Grøstl - a SHA-3 candidate*(PDF)**^**Mendel, Florian; Rijmen, Vincent; Schläffer, Martin (2014-04-30), "Collision Attack on 5 Rounds of Grøstl",*Cryptology ePrint Archive*, Report 2014/305

- The Grøstl web site
- VHDL source code developed by the Cryptographic Engineering Research Group (CERG) at George Mason University

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