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purpose_string
BLAKE3/reference_impl/reference_impl.rs
Jack O'Connor 320affafc1 rename the "context string" to the "purpose string" 
Apart from being pretty ambiguous in general, the term "context string"
has the specific problem that it isn't clear whether it should be
describing the input or the output. In fact, it's quite important that
it describes the output, because the whole point is to domain-separate
different outputs that derive from the *same* input. To make that
clearer, rename the "context string" to the "purpose string" in
documentation.
2021-02-28 20:05:40 -05:00

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Rust
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//! This is the reference implementation of BLAKE3. It is used for testing and
//! as a readable example of the algorithms involved. Section 5.1 of [the BLAKE3
//! spec](https://github.com/BLAKE3-team/BLAKE3-specs/blob/master/blake3.pdf)
//! discusses this implementation. You can render docs for this implementation
//! by running `cargo doc --open` in this directory.
//!
//! # Example
//!
//! ```
//! let mut hasher = reference_impl::Hasher::new();
//! hasher.update(b"abc");
//! hasher.update(b"def");
//! let mut hash = [0; 32];
//! hasher.finalize(&mut hash);
//! let mut extended_hash = [0; 500];
//! hasher.finalize(&mut extended_hash);
//! assert_eq!(hash, extended_hash[..32]);
//! ```
use core::cmp::min;
use core::convert::TryInto;
const OUT_LEN: usize = 32;
const KEY_LEN: usize = 32;
const BLOCK_LEN: usize = 64;
const CHUNK_LEN: usize = 1024;
const CHUNK_START: u32 = 1 << 0;
const CHUNK_END: u32 = 1 << 1;
const PARENT: u32 = 1 << 2;
const ROOT: u32 = 1 << 3;
const KEYED_HASH: u32 = 1 << 4;
const DERIVE_KEY_CONTEXT: u32 = 1 << 5;
const DERIVE_KEY_MATERIAL: u32 = 1 << 6;
const IV: [u32; 8] = [
0x6A09E667, 0xBB67AE85, 0x3C6EF372, 0xA54FF53A, 0x510E527F, 0x9B05688C, 0x1F83D9AB, 0x5BE0CD19,
];
const MSG_PERMUTATION: [usize; 16] = [2, 6, 3, 10, 7, 0, 4, 13, 1, 11, 12, 5, 9, 14, 15, 8];
// The mixing function, G, which mixes either a column or a diagonal.
fn g(state: &mut [u32; 16], a: usize, b: usize, c: usize, d: usize, mx: u32, my: u32) {
state[a] = state[a].wrapping_add(state[b]).wrapping_add(mx);
state[d] = (state[d] ^ state[a]).rotate_right(16);
state[c] = state[c].wrapping_add(state[d]);
state[b] = (state[b] ^ state[c]).rotate_right(12);
state[a] = state[a].wrapping_add(state[b]).wrapping_add(my);
state[d] = (state[d] ^ state[a]).rotate_right(8);
state[c] = state[c].wrapping_add(state[d]);
state[b] = (state[b] ^ state[c]).rotate_right(7);
}
fn round(state: &mut [u32; 16], m: &[u32; 16]) {
// Mix the columns.
g(state, 0, 4, 8, 12, m[0], m[1]);
g(state, 1, 5, 9, 13, m[2], m[3]);
g(state, 2, 6, 10, 14, m[4], m[5]);
g(state, 3, 7, 11, 15, m[6], m[7]);
// Mix the diagonals.
g(state, 0, 5, 10, 15, m[8], m[9]);
g(state, 1, 6, 11, 12, m[10], m[11]);
g(state, 2, 7, 8, 13, m[12], m[13]);
g(state, 3, 4, 9, 14, m[14], m[15]);
}
fn permute(m: &mut [u32; 16]) {
let mut permuted = [0; 16];
for i in 0..16 {
permuted[i] = m[MSG_PERMUTATION[i]];
}
*m = permuted;
}
fn compress(
chaining_value: &[u32; 8],
block_words: &[u32; 16],
counter: u64,
block_len: u32,
flags: u32,
) -> [u32; 16] {
let mut state = [
chaining_value[0],
chaining_value[1],
chaining_value[2],
chaining_value[3],
chaining_value[4],
chaining_value[5],
chaining_value[6],
chaining_value[7],
IV[0],
IV[1],
IV[2],
IV[3],
counter as u32,
(counter >> 32) as u32,
block_len,
flags,
];
let mut block = *block_words;
round(&mut state, &block); // round 1
permute(&mut block);
round(&mut state, &block); // round 2
permute(&mut block);
round(&mut state, &block); // round 3
permute(&mut block);
round(&mut state, &block); // round 4
permute(&mut block);
round(&mut state, &block); // round 5
permute(&mut block);
round(&mut state, &block); // round 6
permute(&mut block);
round(&mut state, &block); // round 7
for i in 0..8 {
state[i] ^= state[i + 8];
state[i + 8] ^= chaining_value[i];
}
state
}
fn first_8_words(compression_output: [u32; 16]) -> [u32; 8] {
compression_output[0..8].try_into().unwrap()
}
fn words_from_little_endian_bytes(bytes: &[u8], words: &mut [u32]) {
for (bytes_block, word) in bytes.chunks_exact(4).zip(words.iter_mut()) {
*word = u32::from_le_bytes(bytes_block.try_into().unwrap());
}
}
// Each chunk or parent node can produce either an 8-word chaining value or, by
// setting the ROOT flag, any number of final output bytes. The Output struct
// captures the state just prior to choosing between those two possibilities.
struct Output {
input_chaining_value: [u32; 8],
block_words: [u32; 16],
counter: u64,
block_len: u32,
flags: u32,
}
impl Output {
fn chaining_value(&self) -> [u32; 8] {
first_8_words(compress(
&self.input_chaining_value,
&self.block_words,
self.counter,
self.block_len,
self.flags,
))
}
fn root_output_bytes(&self, out_slice: &mut [u8]) {
let mut output_block_counter = 0;
for out_block in out_slice.chunks_mut(2 * OUT_LEN) {
let words = compress(
&self.input_chaining_value,
&self.block_words,
output_block_counter,
self.block_len,
self.flags | ROOT,
);
// The output length might not be a multiple of 4.
for (word, out_word) in words.iter().zip(out_block.chunks_mut(4)) {
out_word.copy_from_slice(&word.to_le_bytes()[..out_word.len()]);
}
output_block_counter += 1;
}
}
}
struct ChunkState {
chaining_value: [u32; 8],
chunk_counter: u64,
block: [u8; BLOCK_LEN],
block_len: u8,
blocks_compressed: u8,
flags: u32,
}
impl ChunkState {
fn new(key: [u32; 8], chunk_counter: u64, flags: u32) -> Self {
Self {
chaining_value: key,
chunk_counter,
block: [0; BLOCK_LEN],
block_len: 0,
blocks_compressed: 0,
flags,
}
}
fn len(&self) -> usize {
BLOCK_LEN * self.blocks_compressed as usize + self.block_len as usize
}
fn start_flag(&self) -> u32 {
if self.blocks_compressed == 0 {
CHUNK_START
} else {
0
}
}
fn update(&mut self, mut input: &[u8]) {
while !input.is_empty() {
// If the block buffer is full, compress it and clear it. More
// input is coming, so this compression is not CHUNK_END.
if self.block_len as usize == BLOCK_LEN {
let mut block_words = [0; 16];
words_from_little_endian_bytes(&self.block, &mut block_words);
self.chaining_value = first_8_words(compress(
&self.chaining_value,
&block_words,
self.chunk_counter,
BLOCK_LEN as u32,
self.flags | self.start_flag(),
));
self.blocks_compressed += 1;
self.block = [0; BLOCK_LEN];
self.block_len = 0;
}
// Copy input bytes into the block buffer.
let want = BLOCK_LEN - self.block_len as usize;
let take = min(want, input.len());
self.block[self.block_len as usize..][..take].copy_from_slice(&input[..take]);
self.block_len += take as u8;
input = &input[take..];
}
}
fn output(&self) -> Output {
let mut block_words = [0; 16];
words_from_little_endian_bytes(&self.block, &mut block_words);
Output {
input_chaining_value: self.chaining_value,
block_words,
block_len: self.block_len as u32,
counter: self.chunk_counter,
flags: self.flags | self.start_flag() | CHUNK_END,
}
}
}
fn parent_output(
left_child_cv: [u32; 8],
right_child_cv: [u32; 8],
key: [u32; 8],
flags: u32,
) -> Output {
let mut block_words = [0; 16];
block_words[..8].copy_from_slice(&left_child_cv);
block_words[8..].copy_from_slice(&right_child_cv);
Output {
input_chaining_value: key,
block_words,
counter: 0, // Always 0 for parent nodes.
block_len: BLOCK_LEN as u32, // Always BLOCK_LEN (64) for parent nodes.
flags: PARENT | flags,
}
}
fn parent_cv(
left_child_cv: [u32; 8],
right_child_cv: [u32; 8],
key: [u32; 8],
flags: u32,
) -> [u32; 8] {
parent_output(left_child_cv, right_child_cv, key, flags).chaining_value()
}
/// An incremental hasher that can accept any number of writes.
pub struct Hasher {
chunk_state: ChunkState,
key: [u32; 8],
cv_stack: [[u32; 8]; 54], // Space for 54 subtree chaining values:
cv_stack_len: u8, // 2^54 * CHUNK_LEN = 2^64
flags: u32,
}
impl Hasher {
fn new_internal(key: [u32; 8], flags: u32) -> Self {
Self {
chunk_state: ChunkState::new(key, 0, flags),
key,
cv_stack: [[0; 8]; 54],
cv_stack_len: 0,
flags,
}
}
/// Construct a new `Hasher` for the regular hash function.
pub fn new() -> Self {
Self::new_internal(IV, 0)
}
/// Construct a new `Hasher` for the keyed hash function.
pub fn new_keyed(key: &[u8; KEY_LEN]) -> Self {
let mut key_words = [0; 8];
words_from_little_endian_bytes(key, &mut key_words);
Self::new_internal(key_words, KEYED_HASH)
}
/// Construct a new `Hasher` for the key derivation function. The purpose
/// string should be hardcoded, globally unique, and application-specific.
pub fn new_derive_key(purpose: &str) -> Self {
let mut purpose_hasher = Self::new_internal(IV, DERIVE_KEY_CONTEXT);
purpose_hasher.update(purpose.as_bytes());
let mut purpose_key = [0; KEY_LEN];
purpose_hasher.finalize(&mut purpose_key);
let mut purpose_key_words = [0; 8];
words_from_little_endian_bytes(&purpose_key, &mut purpose_key_words);
Self::new_internal(purpose_key_words, DERIVE_KEY_MATERIAL)
}
fn push_stack(&mut self, cv: [u32; 8]) {
self.cv_stack[self.cv_stack_len as usize] = cv;
self.cv_stack_len += 1;
}
fn pop_stack(&mut self) -> [u32; 8] {
self.cv_stack_len -= 1;
self.cv_stack[self.cv_stack_len as usize]
}
// Section 5.1.2 of the BLAKE3 spec explains this algorithm in more detail.
fn add_chunk_chaining_value(&mut self, mut new_cv: [u32; 8], mut total_chunks: u64) {
// This chunk might complete some subtrees. For each completed subtree,
// its left child will be the current top entry in the CV stack, and
// its right child will be the current value of `new_cv`. Pop each left
// child off the stack, merge it with `new_cv`, and overwrite `new_cv`
// with the result. After all these merges, push the final value of
// `new_cv` onto the stack. The number of completed subtrees is given
// by the number of trailing 0-bits in the new total number of chunks.
while total_chunks & 1 == 0 {
new_cv = parent_cv(self.pop_stack(), new_cv, self.key, self.flags);
total_chunks >>= 1;
}
self.push_stack(new_cv);
}
/// Add input to the hash state. This can be called any number of times.
pub fn update(&mut self, mut input: &[u8]) {
while !input.is_empty() {
// If the current chunk is complete, finalize it and reset the
// chunk state. More input is coming, so this chunk is not ROOT.
if self.chunk_state.len() == CHUNK_LEN {
let chunk_cv = self.chunk_state.output().chaining_value();
let total_chunks = self.chunk_state.chunk_counter + 1;
self.add_chunk_chaining_value(chunk_cv, total_chunks);
self.chunk_state = ChunkState::new(self.key, total_chunks, self.flags);
}
// Compress input bytes into the current chunk state.
let want = CHUNK_LEN - self.chunk_state.len();
let take = min(want, input.len());
self.chunk_state.update(&input[..take]);
input = &input[take..];
}
}
/// Finalize the hash and write any number of output bytes.
pub fn finalize(&self, out_slice: &mut [u8]) {
// Starting with the Output from the current chunk, compute all the
// parent chaining values along the right edge of the tree, until we
// have the root Output.
let mut output = self.chunk_state.output();
let mut parent_nodes_remaining = self.cv_stack_len as usize;
while parent_nodes_remaining > 0 {
parent_nodes_remaining -= 1;
output = parent_output(
self.cv_stack[parent_nodes_remaining],
output.chaining_value(),
self.key,
self.flags,
);
}
output.root_output_bytes(out_slice);
}
}
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