BLAKE (hash function)

BLAKE is a cryptographic hash function based on Daniel J. Bernstein's ChaCha stream cipher, but a permuted copy of the input block, XORed with round constants, is added before each ChaCha round. Like SHA-2, there are two variants differing in the word size. ChaCha operates on a 4×4 array of words. BLAKE repeatedly combines an 8-word hash value with 16 message words, truncating the ChaCha result to obtain the next hash value. BLAKE-256 and BLAKE-224 use 32-bit words and produce digest sizes of 256 bits and 224 bits, respectively, while BLAKE-512 and BLAKE-384 use 64-bit words and produce digest sizes of 512 bits and 384 bits, respectively.

The BLAKE2 hash function, based on BLAKE, was announced in 2012. The BLAKE3 hash function, based on BLAKE2, was announced in 2020.

History
BLAKE was submitted to the NIST hash function competition by Jean-Philippe Aumasson, Luca Henzen, Willi Meier, and Raphael C.-W. Phan. In 2008, there were 51 entries. BLAKE made it to the final round consisting of five candidates but lost to Keccak in 2012, which was selected for the SHA-3 algorithm.

Algorithm
Like SHA-2, BLAKE comes in two variants: one that uses 32-bit words, used for computing hashes up to 256 bits long, and one that uses 64-bit words, used for computing hashes up to 512 bits long. The core block transformation combines 16 words of input with 16 working variables, but only 8 words (256 or 512 bits) are preserved between blocks.

It uses a table of 16 constant words (the leading 512 or 1024 bits of the fractional part of π), and a table of 10 16-element permutations: σ[0] = 0  1  2  3  4  5  6  7  8  9 10 11 12 13 14 15 σ[1] = 14 10 4  8  9 15 13  6  1 12  0  2 11  7  5  3 σ[2] = 11 8 12  0  5  2 15 13 10 14  3  6  7  1  9  4 σ[3] = 7  9  3  1 13 12 11 14  2  6  5 10  4  0 15  8 σ[4] = 9  0  5  7  2  4 10 15 14  1 11 12  6  8  3 13 σ[5] = 2 12  6 10  0 11  8  3  4 13  7  5 15 14  1  9 σ[6] = 12 5  1 15 14 13  4 10  0  7  6  3  9  2  8 11 σ[7] = 13 11 7 14 12  1  3  9  5  0 15  4  8  6  2 10 σ[8] = 6 15 14  9 11  3  0  8 12  2 13  7  1  4 10  5 σ[9] = 10 2  8  4  7  6  1  5 15 11  9 14  3 12 13  0

The core operation, equivalent to ChaCha's quarter round, operates on a 4-word column or diagonal, which is combined with 2 words of message   and two constant words. It is performed 8 times per full round: j ← σ[r%10][2×i]           // Index computations k ← σ[r%10][2×i+1] a ← a + b + (m[j] ⊕ n[k])  // Step 1 (with input) d ← (d ⊕ a) >>> 16 c ← c + d                  // Step 2 (no input) b ← (b ⊕ c) >>> 12 a ← a + b + (m[k] ⊕ n[j])  // Step 3 (with input) d ← (d ⊕ a) >>> 8 c ← c + d                  // Step 4 (no input) b ← (b ⊕ c) >>> 7 In the above,  is the round number (0–13), and   varies from 0 to 7.

The differences from the ChaCha quarter-round function are: "BLAKE reuses the permutation of the ChaCha stream cipher with rotations done in the opposite directions. Some have suspected an advanced optimization, but in fact it originates from a typo in the original BLAKE specifications", Jean-Philippe Aumasson explains in his "Crypto Dictionary".
 * The addition of the message words has been added.
 * The rotation directions have been reversed.

The 64-bit version (which does not exist in ChaCha) is identical, but the rotation amounts are 32, 25, 16 and 11, respectively, and the number of rounds is increased to 16.

Tweaks
Throughout the NIST hash function competition, entrants are permitted to "tweak" their algorithms to address issues that are discovered. Changes that have been made to BLAKE are: the number of rounds was increased from 10/14 to 14/16. This is to be more conservative about security while still being fast.

Example digests
Hash values of an empty string:

BLAKE-224("") = 7dc5313b1c04512a174bd6503b89607aecbee0903d40a8a569c94eed BLAKE-256("") = 716f6e863f744b9ac22c97ec7b76ea5f5908bc5b2f67c61510bfc4751384ea7a BLAKE-384("") = c6cbd89c926ab525c242e6621f2f5fa73aa4afe3d9e24aed727faaadd6af38b620bdb623dd2b4788b1c8086984af8706 BLAKE-512("") = a8cfbbd73726062df0c6864dda65defe58ef0cc52a5625090fa17601e1eecd1b628e94f396ae402a00acc9eab77b4d4c2e852aaaa25a636d80af3fc7913ef5b8

Changing a single bit causes each bit in the output to change with 50% probability, demonstrating an avalanche effect:

BLAKE-512("The quick brown fox jumps over the lazy dog") = 1f7e26f63b6ad25a0896fd978fd050a1766391d2fd0471a77afb975e5034b7ad2d9ccf8dfb47abbbe656e1b82fbc634ba42ce186e8dc5e1ce09a885d41f43451 BLAKE-512("The quick brown fox jumps over the lazy dof") = a701c2a1f9baabd8b1db6b75aee096900276f0b86dc15d247ecc03937b370324a16a4ffc0c3a85cd63229cfa15c15f4ba6d46ae2e849ed6335e9ff43b764198a

(In this example 266 matching bits out of 512 is about 52% due to the random nature of the avalanche.)

BLAKE2
BLAKE2 is a cryptographic hash function based on BLAKE, created by Jean-Philippe Aumasson, Samuel Neves, Zooko Wilcox-O'Hearn, and Christian Winnerlein. The design goal was to replace the widely used, but broken, MD5 and SHA-1 algorithms in applications requiring high performance in software. BLAKE2 was announced on December 21, 2012. A reference implementation is available under CC0, the OpenSSL License, and the Apache License 2.0.

BLAKE2b is faster than MD5, SHA-1, SHA-2, and SHA-3, on 64-bit x86-64 and ARM architectures. BLAKE2 provides better security than SHA-2 and similar to that of SHA-3: immunity to length extension, indifferentiability from a random oracle, etc.

BLAKE2 removes addition of constants to message words from BLAKE round function, changes two rotation constants, simplifies padding, adds parameter block that is XOR'ed with initialization vectors, and reduces the number of rounds from 16 to 12 for BLAKE2b (successor of BLAKE-512), and from 14 to 10 for BLAKE2s (successor of BLAKE-256).

BLAKE2 supports keying, salting, personalization, and hash tree modes, and can output digests from 1 up to 64 bytes for BLAKE2b, or up to 32 bytes for BLAKE2s. There are also parallel versions designed for increased performance on multi-core processors; BLAKE2bp (4-way parallel) and BLAKE2sp (8-way parallel).

BLAKE2X is a family of extendable-output functions (XOFs). Whereas BLAKE2 is limited to 64-byte digests, BLAKE2X allows for digests of up to 256 GiB. BLAKE2X is itself not an instance of a hash function, and must be based on an actual BLAKE2 instance. An example of a BLAKE2X instance could be BLAKE2Xb16MiB, which would be a BLAKE2X version based on BLAKE2b producing 16,777,216-byte digests (or exactly 16 MiB, hence the name of such an instance).

BLAKE2b and BLAKE2s are specified in RFC 7693. Optional features using the parameter block (salting, personalized hashes, tree hashing, et cetera), are not specified, and thus neither is support for BLAKE2bp, BLAKE2sp, or BLAKE2X.

Initialization vector
BLAKE2b uses an initialization vector that is the same as the IV used by SHA-512. These values are transparently obtained by taking the first 64 bits of the fractional parts of the positive square roots of the first eight prime numbers.

IV0 = 0x6a09e667f3bcc908  // Frac(sqrt(2)) IV1 = 0xbb67ae8584caa73b  // Frac(sqrt(3)) IV2 = 0x3c6ef372fe94f82b  // Frac(sqrt(5)) IV3 = 0xa54ff53a5f1d36f1  // Frac(sqrt(7)) IV4 = 0x510e527fade682d1  // Frac(sqrt(11)) IV5 = 0x9b05688c2b3e6c1f  // Frac(sqrt(13)) IV6 = 0x1f83d9abfb41bd6b  // Frac(sqrt(17)) IV7 = 0x5be0cd19137e2179  // Frac(sqrt(19))

BLAKE2b algorithm
Pseudocode for the BLAKE2b algorithm. The BLAKE2b algorithm uses 8-byte (UInt64) words, and 128-byte chunks. Algorithm BLAKE2b Input: M                              Message to be hashed cbMessageLen: Number, (0..2128) Length of the message in bytes Key                            Optional 0..64 byte key cbKeyLen: Number, (0..64)      Length of optional key in bytes cbHashLen: Number, (1..64)     Desired hash length in bytes Output: Hash                           Hash of cbHashLen bytes Initialize State vector h with IV h0..7 ← IV0..7 Mix key size (cbKeyLen) and desired hash length (cbHashLen) into h0 h0 ← h0 xor 0x0101kknn where kk is Key Length (in bytes) nn is Desired Hash Length (in bytes) Each time we Compress we record how many bytes have been compressed cBytesCompressed ← 0 cBytesRemaining ← cbMessageLen If there was a key supplied (i.e. cbKeyLen > 0) then pad with trailing zeros to make it 128-bytes (i.e. 16 words)  and prepend it to the message M if (cbKeyLen > 0) then M ← Pad(Key, 128) || M      cBytesRemaining ← cBytesRemaining + 128 end if Compress whole 128-byte chunks of the message, except the last chunk while (cBytesRemaining > 128) do chunk ← get next 128 bytes of message M cBytesCompressed ← cBytesCompressed + 128 increase count of bytes that have been compressed cBytesRemaining ← cBytesRemaining  - 128  decrease count of bytes in M remaining to be processed h ← Compress(h, chunk, cBytesCompressed, false) false ⇒ this is not the last chunk end while Compress the final bytes from M chunk ← get next 128 bytes of message M We will get cBytesRemaining bytes (i.e. 0..128 bytes) cBytesCompressed ← cBytesCompressed+cBytesRemaining The actual number of bytes leftover in M chunk ← Pad(chunk, 128) If M was empty, then we will still compress a final chunk of zeros h ← Compress(h, chunk, cBytesCompressed, true) true ⇒ this is the last chunk Result ← first cbHashLen bytes of little endian state vector h End Algorithm BLAKE2b

Compress
The Compress function takes a full 128-byte chunk of the input message and mixes it into the ongoing state array:

Function Compress Input: h                     Persistent state vector chunk                 128-byte (16 double word) chunk of message to compress t: Number, 0..2128    Count of bytes that have been fed into the Compression IsLastBlock: Boolean  Indicates if this is the final round of compression Output: h                     Updated persistent state vector Setup local work vector V V0..7 ← h0..7  First eight items are copied from persistent state vector h V8..15 ← IV0..7 Remaining eight items are initialized from the IV Mix the 128-bit counter t into V12:V13 V12 ← V12 xor Lo(t)   Lo 64-bits of UInt128 t V13 ← V13 xor Hi(t)   Hi 64-bits of UInt128 t If this is the last block then invert all the bits in V14 if IsLastBlock then V14 ← V14 xor 0xFFFFFFFFFFFFFFFF Treat each 128-byte message chunk as sixteen 8-byte (64-bit) words m m0..15 ← chunk Twelve rounds of cryptographic message mixing for i from 0 to 11 do Select message mixing schedule for this round. BLAKE2b uses 12 rounds, while SIGMA has only 10 entries. S0..15 ← SIGMA[i mod 10]  Rounds 10 and 11 use SIGMA[0] and SIGMA[1] respectively Mix(V0, V4, V8, V12, m[S0], m[S1]) Mix(V1, V5, V9, V13, m[S2], m[S3]) Mix(V2, V6, V10, V14, m[S4], m[S5]) Mix(V3, V7, V11, V15, m[S6], m[S7]) Mix(V0, V5, V10, V15, m[S8], m[S9]) Mix(V1, V6, V11, V12, m[S10], m[S11]) Mix(V2, V7, V8, V13, m[S12], m[S13]) Mix(V3, V4, V9, V14, m[S14], m[S15]) end for Mix the upper and lower halves of V into ongoing state vector h h0..7 ← h0..7 xor V0..7 h0..7 ← h0..7 xor V8..15 Result ← h End Function Compress

Mix
The Mix function is called by the Compress function, and mixes two 8-byte words from the message into the hash state. In most implementations this function would be written inline, or as an inlined function.

Function Mix Inputs: Va, Vb, Vc, Vd      four 8-byte word entries from the work vector V x, y               two 8-byte word entries from padded message m Output: Va, Vb, Vc, Vd      the modified versions of Va, Vb, Vc, Vd Va ← Va + Vb + x         with input Vd ← (Vd xor Va) rotateright 32 Vc ← Vc + Vd             no input Vb ← (Vb xor Vc) rotateright 24 Va ← Va + Vb + y         with input Vd ← (Vd xor Va) rotateright 16 Vc ← Vc + Vd             no input Vb ← (Vb xor Vc) rotateright 63 Result ← Va, Vb, Vc, Vd End Function Mix

Example digests
Hash values of an empty string:

BLAKE2s-224("") = 1fa1291e65248b37b3433475b2a0dd63d54a11ecc4e3e034e7bc1ef4 BLAKE2s-256("") = 69217a3079908094e11121d042354a7c1f55b6482ca1a51e1b250dfd1ed0eef9 BLAKE2b-384("") = b32811423377f52d7862286ee1a72ee540524380fda1724a6f25d7978c6fd3244a6caf0498812673c5e05ef583825100 BLAKE2b-512("") = 786a02f742015903c6c6fd852552d272912f4740e15847618a86e217f71f5419d25e1031afee585313896444934eb04b903a685b1448b755d56f701afe9be2ce

Changing a single bit causes each bit in the output to change with 50% probability, demonstrating an avalanche effect:

BLAKE2b-512("The quick brown fox jumps over the lazy dog") = a8add4bdddfd93e4877d2746e62817b116364a1fa7bc148d95090bc7333b3673f82401cf7aa2e4cb1ecd90296e3f14cb5413f8ed77be73045b13914cdcd6a918 BLAKE2b-512("The quick brown fox jumps over the lazy dof") = ab6b007747d8068c02e25a6008db8a77c218d94f3b40d2291a7dc8a62090a744c082ea27af01521a102e42f480a31e9844053f456b4b41e8aa78bbe5c12957bb

Users of BLAKE2

 * Argon2, the winner of the Password Hashing Competition, uses BLAKE2b
 * Chef's Habitat deployment system uses BLAKE2b for package signing
 * FreeBSD Ports package management tool uses BLAKE2b
 * GNU Core Utilities implements BLAKE2b in its b2sum command
 * IPFS allows use of BLAKE2b for tree hashing
 * librsync uses BLAKE2b
 * Noise (cryptographic protocol), which is used in WhatsApp includes BLAKE2 as an option.
 * RAR archive format version 5 supports an optional 256-bit BLAKE2sp file checksum instead of the default 32-bit CRC32; it was implemented in WinRAR v5+
 * 7-Zip (in order to support the RAR archive format version 5 ) can generate the BLAKE2sp signature for each file in the Explorer shell via "CRC SHA" context menu, and choosing '*'
 * rmlint uses BLAKE2b for duplicate file detection
 * WireGuard uses BLAKE2s for hashing
 * Zcash, a cryptocurrency, uses BLAKE2b in the Equihash proof of work, and as a key derivation function
 * NANO, a cryptocurrency, uses BLAKE2b in the proof of work, for hashing digital signatures and as a key derivation function
 * Polkadot, a multi-chain blockchain uses BLAKE2b as its hashing algorithm.
 * Kadena (cryptocurrency), a scalable proof of work blockchain that uses Blake2s_256 as its hashing algorithm.
 * PCI Vault, uses BLAKE2b as its hashing algorithm for the purpose of PCI compliant PCD tokenization.
 * Ergo, a cryptocurrency, uses BLAKE2b256 as a subroutine of its hashing algorithm called Autolykos.
 * Linux kernel, version 5.17 replaced SHA-1 with BLAKE2s for hashing the entropy pool in the random number generator.
 * Open Network for Digital Commerce, a Government of India initiative, uses BLAKE-512 to sign API requests.
 * checksum, a Windows file hashing program has Blake2s as one of its algorithms

Implementations
In addition to the reference implementation, the following cryptography libraries provide implementations of BLAKE2:


 * Botan
 * Bouncy Castle
 * Crypto++
 * Libgcrypt
 * libsodium
 * OpenSSL
 * wolfSSL

BLAKE3
BLAKE3 is a cryptographic hash function based on Bao and BLAKE2, created by Jack O'Connor, Jean-Philippe Aumasson, Samuel Neves, and Zooko Wilcox-O'Hearn. It was announced on January 9, 2020, at Real World Crypto.

BLAKE3 is a single algorithm with many desirable features (parallelism, XOF, KDF, PRF and MAC), in contrast to BLAKE and BLAKE2, which are algorithm families with multiple variants. BLAKE3 has a binary tree structure, so it supports a practically unlimited degree of parallelism (both SIMD and multithreading) given long enough input. The official Rust and C implementations are dual-licensed as public domain (CC0) and the Apache License.

BLAKE3 is designed to be as fast as possible. It is consistently a few times faster than BLAKE2. The BLAKE3 compression function is closely based on that of BLAKE2s, with the biggest difference being that the number of rounds is reduced from 10 to 7, a change based on the assumption that current cryptography is too conservative. In addition to providing parallelism, the Merkle tree format also allows for verified streaming (on-the-fly verifying) and incremental updates.