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Diffstat (limited to 'vendor/twox-hash/src/xxh3.rs')
-rw-r--r-- | vendor/twox-hash/src/xxh3.rs | 1666 |
1 files changed, 1666 insertions, 0 deletions
diff --git a/vendor/twox-hash/src/xxh3.rs b/vendor/twox-hash/src/xxh3.rs new file mode 100644 index 000000000..0ffc54189 --- /dev/null +++ b/vendor/twox-hash/src/xxh3.rs @@ -0,0 +1,1666 @@ +//! The in-progress XXH3 algorithm. +//! +//! Please read [the notes in original implementation][warning] to +//! learn about when to use these algorithms. Specifically, the +//! version of code this crate reproduces says: +//! +//! > The algorithm is currently in development, meaning its return +//! values might still change in future versions. However, the API +//! is stable, and can be used in production, typically for +//! generation of ephemeral hashes (produced and consumed in same +//! session). +//! +//! [warning]: https://github.com/Cyan4973/xxHash#new-hash-algorithms + +use alloc::vec::Vec; + +use core::convert::TryInto; +use core::hash::Hasher; +use core::mem; +use core::ops::{Deref, DerefMut}; +use core::slice; + +#[cfg(target_arch = "x86")] +use core::arch::x86::*; +#[cfg(target_arch = "x86_64")] +use core::arch::x86_64::*; + +use cfg_if::cfg_if; +use static_assertions::{const_assert, const_assert_eq}; + +#[cfg(feature = "serialize")] +use serde::{Deserialize, Serialize}; + +use crate::sixty_four::{ + PRIME_1 as PRIME64_1, PRIME_2 as PRIME64_2, PRIME_3 as PRIME64_3, PRIME_4 as PRIME64_4, + PRIME_5 as PRIME64_5, +}; +use crate::thirty_two::{PRIME_1 as PRIME32_1, PRIME_2 as PRIME32_2, PRIME_3 as PRIME32_3}; + +#[cfg(feature = "std")] +pub use crate::std_support::xxh3::{RandomHashBuilder128, RandomHashBuilder64}; + +#[inline(always)] +pub fn hash64(data: &[u8]) -> u64 { + hash64_with_seed(data, 0) +} + +#[inline(always)] +pub fn hash64_with_seed(data: &[u8], seed: u64) -> u64 { + let len = data.len(); + + if len <= 16 { + hash_len_0to16_64bits(data, len, &SECRET, seed) + } else if len <= 128 { + hash_len_17to128_64bits(data, len, &SECRET, seed) + } else if len <= MIDSIZE_MAX { + hash_len_129to240_64bits(data, len, &SECRET, seed) + } else { + hash_long_64bits_with_seed(data, len, seed) + } +} + +#[inline(always)] +pub fn hash64_with_secret(data: &[u8], secret: &[u8]) -> u64 { + debug_assert!(secret.len() >= SECRET_SIZE_MIN); + + let len = data.len(); + + if len <= 16 { + hash_len_0to16_64bits(data, len, secret, 0) + } else if len <= 128 { + hash_len_17to128_64bits(data, len, secret, 0) + } else if len <= MIDSIZE_MAX { + hash_len_129to240_64bits(data, len, secret, 0) + } else { + hash_long_64bits_with_secret(data, len, secret) + } +} + +#[inline(always)] +pub fn hash128(data: &[u8]) -> u128 { + hash128_with_seed(data, 0) +} + +#[inline(always)] +pub fn hash128_with_seed(data: &[u8], seed: u64) -> u128 { + let len = data.len(); + + if len <= 16 { + hash_len_0to16_128bits(data, len, &SECRET, seed) + } else if len <= 128 { + hash_len_17to128_128bits(data, len, &SECRET, seed) + } else if len <= MIDSIZE_MAX { + hash_len_129to240_128bits(data, len, &SECRET, seed) + } else { + hash_long_128bits_with_seed(data, len, seed) + } +} + +#[inline(always)] +pub fn hash128_with_secret(data: &[u8], secret: &[u8]) -> u128 { + debug_assert!(secret.len() >= SECRET_SIZE_MIN); + + let len = data.len(); + + if len <= 16 { + hash_len_0to16_128bits(data, len, secret, 0) + } else if len <= 128 { + hash_len_17to128_128bits(data, len, secret, 0) + } else if len <= MIDSIZE_MAX { + hash_len_129to240_128bits(data, len, secret, 0) + } else { + hash_long_128bits_with_secret(data, len, secret) + } +} + +/// Calculates the 64-bit hash. +#[cfg_attr(feature = "serialize", derive(Deserialize, Serialize))] +#[derive(Clone, Default)] +pub struct Hash64(State); + +impl Hash64 { + pub fn with_seed(seed: u64) -> Self { + Self(State::with_seed(seed)) + } + + pub fn with_secret<S: Into<Vec<u8>>>(secret: S) -> Self { + Self(State::with_secret(secret)) + } +} + +impl Hasher for Hash64 { + #[inline(always)] + fn finish(&self) -> u64 { + self.0.digest64() + } + + #[inline(always)] + fn write(&mut self, bytes: &[u8]) { + self.0.update(bytes, AccWidth::Acc64Bits) + } +} + +/// Calculates the 128-bit hash. +#[cfg_attr(feature = "serialize", derive(Deserialize, Serialize))] +#[derive(Clone, Default)] +pub struct Hash128(State); + +impl Hash128 { + pub fn with_seed(seed: u64) -> Self { + Self(State::with_seed(seed)) + } + + pub fn with_secret<S: Into<Vec<u8>>>(secret: S) -> Self { + Self(State::with_secret(secret)) + } +} + +impl Hasher for Hash128 { + #[inline(always)] + fn finish(&self) -> u64 { + self.0.digest128() as u64 + } + + #[inline(always)] + fn write(&mut self, bytes: &[u8]) { + self.0.update(bytes, AccWidth::Acc128Bits) + } +} + +pub trait HasherExt: Hasher { + fn finish_ext(&self) -> u128; +} + +impl HasherExt for Hash128 { + #[inline(always)] + fn finish_ext(&self) -> u128 { + self.0.digest128() + } +} + +/* ========================================== + * XXH3 default settings + * ========================================== */ + +const SECRET_DEFAULT_SIZE: usize = 192; +const SECRET_SIZE_MIN: usize = 136; + +const SECRET: Secret = Secret([ + 0xb8, 0xfe, 0x6c, 0x39, 0x23, 0xa4, 0x4b, 0xbe, 0x7c, 0x01, 0x81, 0x2c, 0xf7, 0x21, 0xad, 0x1c, + 0xde, 0xd4, 0x6d, 0xe9, 0x83, 0x90, 0x97, 0xdb, 0x72, 0x40, 0xa4, 0xa4, 0xb7, 0xb3, 0x67, 0x1f, + 0xcb, 0x79, 0xe6, 0x4e, 0xcc, 0xc0, 0xe5, 0x78, 0x82, 0x5a, 0xd0, 0x7d, 0xcc, 0xff, 0x72, 0x21, + 0xb8, 0x08, 0x46, 0x74, 0xf7, 0x43, 0x24, 0x8e, 0xe0, 0x35, 0x90, 0xe6, 0x81, 0x3a, 0x26, 0x4c, + 0x3c, 0x28, 0x52, 0xbb, 0x91, 0xc3, 0x00, 0xcb, 0x88, 0xd0, 0x65, 0x8b, 0x1b, 0x53, 0x2e, 0xa3, + 0x71, 0x64, 0x48, 0x97, 0xa2, 0x0d, 0xf9, 0x4e, 0x38, 0x19, 0xef, 0x46, 0xa9, 0xde, 0xac, 0xd8, + 0xa8, 0xfa, 0x76, 0x3f, 0xe3, 0x9c, 0x34, 0x3f, 0xf9, 0xdc, 0xbb, 0xc7, 0xc7, 0x0b, 0x4f, 0x1d, + 0x8a, 0x51, 0xe0, 0x4b, 0xcd, 0xb4, 0x59, 0x31, 0xc8, 0x9f, 0x7e, 0xc9, 0xd9, 0x78, 0x73, 0x64, + 0xea, 0xc5, 0xac, 0x83, 0x34, 0xd3, 0xeb, 0xc3, 0xc5, 0x81, 0xa0, 0xff, 0xfa, 0x13, 0x63, 0xeb, + 0x17, 0x0d, 0xdd, 0x51, 0xb7, 0xf0, 0xda, 0x49, 0xd3, 0x16, 0x55, 0x26, 0x29, 0xd4, 0x68, 0x9e, + 0x2b, 0x16, 0xbe, 0x58, 0x7d, 0x47, 0xa1, 0xfc, 0x8f, 0xf8, 0xb8, 0xd1, 0x7a, 0xd0, 0x31, 0xce, + 0x45, 0xcb, 0x3a, 0x8f, 0x95, 0x16, 0x04, 0x28, 0xaf, 0xd7, 0xfb, 0xca, 0xbb, 0x4b, 0x40, 0x7e, +]); + +#[repr(align(64))] +#[derive(Clone)] +struct Secret([u8; SECRET_DEFAULT_SIZE]); + +const_assert_eq!(mem::size_of::<Secret>() % 16, 0); + +impl Default for Secret { + #[inline(always)] + fn default() -> Self { + SECRET + } +} + +impl Deref for Secret { + type Target = [u8]; + + #[inline(always)] + fn deref(&self) -> &Self::Target { + &self.0[..] + } +} + +cfg_if! { + if #[cfg(feature = "serialize")] { + impl Serialize for Secret { + fn serialize<S>(&self, serializer: S) -> Result<S::Ok, S::Error> + where + S: serde::Serializer, + { + serializer.serialize_bytes(self) + } + } + + impl<'de> Deserialize<'de> for Secret { + fn deserialize<D>(deserializer: D) -> Result<Secret, D::Error> + where + D: serde::Deserializer<'de>, + { + deserializer.deserialize_bytes(SecretVisitor) + } + } + + struct SecretVisitor; + + impl<'de> serde::de::Visitor<'de> for SecretVisitor { + type Value = Secret; + + fn expecting(&self, formatter: &mut core::fmt::Formatter) -> core::fmt::Result { + formatter.write_str("secret with a bytes array") + } + + fn visit_bytes<E>(self, v: &[u8]) -> Result<Self::Value, E> + where + E: serde::de::Error, + { + if v.len() == SECRET_DEFAULT_SIZE { + let mut secret = [0; SECRET_DEFAULT_SIZE]; + + secret.copy_from_slice(v); + + Ok(Secret(secret)) + } else { + Err(E::custom("incomplete secret data")) + } + } + } + } +} + +impl Secret { + #[inline(always)] + pub fn with_seed(seed: u64) -> Self { + let mut secret = [0; SECRET_DEFAULT_SIZE]; + + for off in (0..SECRET_DEFAULT_SIZE).step_by(16) { + secret[off..].write_u64_le(SECRET[off..].read_u64_le().wrapping_add(seed)); + secret[off + 8..].write_u64_le(SECRET[off + 8..].read_u64_le().wrapping_sub(seed)); + } + + Secret(secret) + } +} + +cfg_if! { + if #[cfg(target_feature = "avx2")] { + #[repr(align(32))] + #[cfg_attr(feature = "serialize", derive(Deserialize, Serialize))] + #[derive(Clone)] + struct Acc([u64; ACC_NB]); + } else if #[cfg(target_feature = "sse2")] { + #[repr(align(16))] + #[cfg_attr(feature = "serialize", derive(Deserialize, Serialize))] + #[derive(Clone)] + struct Acc([u64; ACC_NB]); + } else { + #[repr(align(8))] + #[cfg_attr(feature = "serialize", derive(Deserialize, Serialize))] + #[derive(Clone)] + struct Acc([u64; ACC_NB]); + } +} + +const ACC_SIZE: usize = mem::size_of::<Acc>(); + +const_assert_eq!(ACC_SIZE, 64); + +impl Default for Acc { + #[inline(always)] + fn default() -> Self { + Acc([ + u64::from(PRIME32_3), + PRIME64_1, + PRIME64_2, + PRIME64_3, + PRIME64_4, + u64::from(PRIME32_2), + PRIME64_5, + u64::from(PRIME32_1), + ]) + } +} + +impl Deref for Acc { + type Target = [u64]; + + #[inline(always)] + fn deref(&self) -> &Self::Target { + &self.0 + } +} + +impl DerefMut for Acc { + #[inline(always)] + fn deref_mut(&mut self) -> &mut Self::Target { + &mut self.0 + } +} + +trait Buf { + fn read_u32_le(&self) -> u32; + + fn read_u64_le(&self) -> u64; +} + +trait BufMut { + fn write_u32_le(&mut self, n: u32); + + fn write_u64_le(&mut self, n: u64); +} + +impl Buf for [u8] { + #[inline(always)] + fn read_u32_le(&self) -> u32 { + let buf = &self[..mem::size_of::<u32>()]; + u32::from_le_bytes(buf.try_into().unwrap()) + } + + #[inline(always)] + fn read_u64_le(&self) -> u64 { + let buf = &self[..mem::size_of::<u64>()]; + u64::from_le_bytes(buf.try_into().unwrap()) + } +} + +impl BufMut for [u8] { + #[inline(always)] + fn write_u32_le(&mut self, n: u32) { + self[..mem::size_of::<u32>()].copy_from_slice(&n.to_le_bytes()[..]); + } + + #[inline(always)] + fn write_u64_le(&mut self, n: u64) { + self[..mem::size_of::<u64>()].copy_from_slice(&n.to_le_bytes()[..]); + } +} + +/* ========================================== + * Short keys + * ========================================== */ + +#[inline(always)] +fn hash_len_0to16_64bits(data: &[u8], len: usize, key: &[u8], seed: u64) -> u64 { + debug_assert!(len <= 16); + + if len > 8 { + hash_len_9to16_64bits(data, len, key, seed) + } else if len >= 4 { + hash_len_4to8_64bits(data, len, key, seed) + } else if len > 0 { + hash_len_1to3_64bits(data, len, key, seed) + } else { + 0 + } +} + +#[inline(always)] +fn hash_len_9to16_64bits(data: &[u8], len: usize, key: &[u8], seed: u64) -> u64 { + debug_assert!((9..=16).contains(&len)); + + let ll1 = data.read_u64_le() ^ key.read_u64_le().wrapping_add(seed); + let ll2 = data[len - 8..].read_u64_le() ^ key[8..].read_u64_le().wrapping_sub(seed); + let acc = (len as u64) + .wrapping_add(ll1) + .wrapping_add(ll2) + .wrapping_add(mul128_fold64(ll1, ll2)); + + avalanche(acc) +} + +#[inline(always)] +fn hash_len_4to8_64bits(data: &[u8], len: usize, key: &[u8], seed: u64) -> u64 { + debug_assert!((4..=8).contains(&len)); + + let in1 = u64::from(data.read_u32_le()); + let in2 = u64::from(data[len - 4..].read_u32_le()); + let in64 = in1.wrapping_add(in2 << 32); + let keyed = in64 ^ key.read_u64_le().wrapping_add(seed); + let mix64 = + (len as u64).wrapping_add((keyed ^ (keyed >> 51)).wrapping_mul(u64::from(PRIME32_1))); + + avalanche((mix64 ^ (mix64 >> 47)).wrapping_mul(PRIME64_2)) +} + +#[inline(always)] +fn hash_len_1to3_64bits(data: &[u8], len: usize, key: &[u8], seed: u64) -> u64 { + debug_assert!((1..=3).contains(&len)); + + let c1 = u32::from(data[0]); + let c2 = u32::from(data[len >> 1]); + let c3 = u32::from(data[len - 1]); + let combined = c1 + (c2 << 8) + (c3 << 16) + ((len as u32) << 24); + let keyed = u64::from(combined) ^ u64::from(key.read_u32_le()).wrapping_add(seed); + let mixed = keyed.wrapping_mul(PRIME64_1); + + avalanche(mixed) +} + +#[inline(always)] +fn hash_len_17to128_64bits(data: &[u8], len: usize, secret: &[u8], seed: u64) -> u64 { + debug_assert!((17..=128).contains(&len)); + debug_assert!(secret.len() >= SECRET_SIZE_MIN); + + let mut acc = PRIME64_1.wrapping_mul(len as u64); + + if len > 32 { + if len > 64 { + if len > 96 { + acc = acc + .wrapping_add(mix_16bytes(&data[48..], &secret[96..], seed)) + .wrapping_add(mix_16bytes(&data[len - 64..], &secret[112..], seed)); + } + acc = acc + .wrapping_add(mix_16bytes(&data[32..], &secret[64..], seed)) + .wrapping_add(mix_16bytes(&data[len - 48..], &secret[80..], seed)); + } + + acc = acc + .wrapping_add(mix_16bytes(&data[16..], &secret[32..], seed)) + .wrapping_add(mix_16bytes(&data[len - 32..], &secret[48..], seed)); + } + + acc = acc + .wrapping_add(mix_16bytes(data, secret, seed)) + .wrapping_add(mix_16bytes(&data[len - 16..], &secret[16..], seed)); + + avalanche(acc) +} + +const MIDSIZE_MAX: usize = 240; +const MIDSIZE_STARTOFFSET: usize = 3; +const MIDSIZE_LASTOFFSET: usize = 17; + +#[inline(always)] +fn hash_len_129to240_64bits(data: &[u8], len: usize, secret: &[u8], seed: u64) -> u64 { + debug_assert!((129..=MIDSIZE_MAX).contains(&len)); + debug_assert!(secret.len() >= SECRET_SIZE_MIN); + + let acc = (len as u64).wrapping_mul(PRIME64_1); + let acc = (0..8).fold(acc, |acc, i| { + acc.wrapping_add(mix_16bytes(&data[16 * i..], &secret[16 * i..], seed)) + }); + let acc = avalanche(acc); + + let nb_rounds = len / 16; + debug_assert!(nb_rounds >= 8); + + let acc = (8..nb_rounds).fold(acc, |acc, i| { + acc.wrapping_add(mix_16bytes( + &data[16 * i..], + &secret[16 * (i - 8) + MIDSIZE_STARTOFFSET..], + seed, + )) + }); + + avalanche(acc.wrapping_add(mix_16bytes( + &data[len - 16..], + &secret[SECRET_SIZE_MIN - MIDSIZE_LASTOFFSET..], + seed, + ))) +} + +/* ========================================== + * Long keys + * ========================================== */ + +const STRIPE_LEN: usize = 64; +const SECRET_CONSUME_RATE: usize = 8; // nb of secret bytes consumed at each accumulation +const SECRET_MERGEACCS_START: usize = 11; // do not align on 8, so that secret is different from accumulator +const SECRET_LASTACC_START: usize = 7; // do not align on 8, so that secret is different from scrambler +const ACC_NB: usize = STRIPE_LEN / mem::size_of::<u64>(); + +#[derive(Debug, Clone, Copy, PartialEq)] +pub(crate) enum AccWidth { + Acc64Bits, + Acc128Bits, +} + +#[inline(always)] +fn hash_long_64bits_with_default_secret(data: &[u8], len: usize) -> u64 { + hash_long_internal(data, len, &SECRET) +} + +#[inline(always)] +fn hash_long_64bits_with_secret(data: &[u8], len: usize, secret: &[u8]) -> u64 { + hash_long_internal(data, len, secret) +} + +/// Generate a custom key, based on alteration of default kSecret with the seed, +/// and then use this key for long mode hashing. +/// +/// This operation is decently fast but nonetheless costs a little bit of time. +/// Try to avoid it whenever possible (typically when `seed.is_none()`). +#[inline(always)] +fn hash_long_64bits_with_seed(data: &[u8], len: usize, seed: u64) -> u64 { + if seed == 0 { + hash_long_64bits_with_default_secret(data, len) + } else { + let secret = Secret::with_seed(seed); + + hash_long_internal(data, len, &secret) + } +} + +#[inline(always)] +fn hash_long_internal(data: &[u8], len: usize, secret: &[u8]) -> u64 { + let mut acc = Acc::default(); + + hash_long_internal_loop(&mut acc, data, len, secret, AccWidth::Acc64Bits); + + merge_accs( + &acc, + &secret[SECRET_MERGEACCS_START..], + (len as u64).wrapping_mul(PRIME64_1), + ) +} + +#[inline(always)] +fn hash_long_internal_loop( + acc: &mut [u64], + data: &[u8], + len: usize, + secret: &[u8], + acc_width: AccWidth, +) { + let secret_len = secret.len(); + let nb_rounds = (secret_len - STRIPE_LEN) / SECRET_CONSUME_RATE; + let block_len = STRIPE_LEN * nb_rounds; + + debug_assert!(secret_len >= SECRET_SIZE_MIN); + + let mut chunks = data.chunks_exact(block_len); + + for chunk in &mut chunks { + accumulate(acc, chunk, secret, nb_rounds, acc_width); + unsafe { + scramble_acc(acc, &secret[secret_len - STRIPE_LEN..]); + } + } + + /* last partial block */ + debug_assert!(len > STRIPE_LEN); + + let nb_stripes = (len % block_len) / STRIPE_LEN; + + debug_assert!(nb_stripes < (secret_len / SECRET_CONSUME_RATE)); + + accumulate(acc, chunks.remainder(), secret, nb_stripes, acc_width); + + /* last stripe */ + if (len & (STRIPE_LEN - 1)) != 0 { + unsafe { + accumulate512( + acc, + &data[len - STRIPE_LEN..], + &secret[secret_len - STRIPE_LEN - SECRET_LASTACC_START..], + acc_width, + ); + } + } +} + +#[inline(always)] +fn accumulate(acc: &mut [u64], data: &[u8], secret: &[u8], nb_stripes: usize, acc_width: AccWidth) { + for n in 0..nb_stripes { + unsafe { + accumulate512( + acc, + &data[n * STRIPE_LEN..], + &secret[n * SECRET_CONSUME_RATE..], + acc_width, + ); + } + } +} + +#[inline(always)] +const fn _mm_shuffle(z: u32, y: u32, x: u32, w: u32) -> i32 { + ((z << 6) | (y << 4) | (x << 2) | w) as i32 +} + +#[cfg(target_feature = "avx2")] +mod avx2 { + use super::*; + + #[target_feature(enable = "avx2")] + pub(crate) unsafe fn accumulate512( + acc: &mut [u64], + data: &[u8], + keys: &[u8], + acc_width: AccWidth, + ) { + let xacc = acc.as_mut_ptr() as *mut __m256i; + let xdata = data.as_ptr() as *const __m256i; + let xkey = keys.as_ptr() as *const __m256i; + + for i in 0..STRIPE_LEN / mem::size_of::<__m256i>() { + let d = _mm256_loadu_si256(xdata.add(i)); + let k = _mm256_loadu_si256(xkey.add(i)); + let dk = _mm256_xor_si256(d, k); // uint32 dk[8] = {d0+k0, d1+k1, d2+k2, d3+k3, ...} + let mul = _mm256_mul_epu32(dk, _mm256_shuffle_epi32(dk, 0x31)); // uint64 res[4] = {dk0*dk1, dk2*dk3, ...} + + xacc.add(i).write(if acc_width == AccWidth::Acc128Bits { + let dswap = _mm256_shuffle_epi32(d, _mm_shuffle(1, 0, 3, 2)); + let add = _mm256_add_epi64(xacc.add(i).read(), dswap); + _mm256_add_epi64(mul, add) + } else { + let add = _mm256_add_epi64(xacc.add(i).read(), d); + _mm256_add_epi64(mul, add) + }) + } + } + + #[target_feature(enable = "avx2")] + pub unsafe fn scramble_acc(acc: &mut [u64], key: &[u8]) { + let xacc = acc.as_mut_ptr() as *mut __m256i; + let xkey = key.as_ptr() as *const __m256i; + let prime32 = _mm256_set1_epi32(PRIME32_1 as i32); + + for i in 0..STRIPE_LEN / mem::size_of::<__m256i>() { + let data = xacc.add(i).read(); + let shifted = _mm256_srli_epi64(data, 47); + let data = _mm256_xor_si256(data, shifted); + + let k = _mm256_loadu_si256(xkey.add(i)); + let dk = _mm256_xor_si256(data, k); /* U32 dk[4] = {d0+k0, d1+k1, d2+k2, d3+k3} */ + let dk1 = _mm256_mul_epu32(dk, prime32); + + let d2 = _mm256_shuffle_epi32(dk, 0x31); + let dk2 = _mm256_mul_epu32(d2, prime32); + let dk2h = _mm256_slli_epi64(dk2, 32); + + xacc.add(i).write(_mm256_add_epi64(dk1, dk2h)); + } + } +} + +#[cfg(all(target_feature = "sse2", not(target_feature = "avx2")))] +mod sse2 { + use super::*; + + #[target_feature(enable = "sse2")] + #[allow(clippy::cast_ptr_alignment)] + pub(crate) unsafe fn accumulate512( + acc: &mut [u64], + data: &[u8], + keys: &[u8], + acc_width: AccWidth, + ) { + let xacc = acc.as_mut_ptr() as *mut __m128i; + let xdata = data.as_ptr() as *const __m128i; + let xkey = keys.as_ptr() as *const __m128i; + + for i in 0..STRIPE_LEN / mem::size_of::<__m128i>() { + let d = _mm_loadu_si128(xdata.add(i)); + let k = _mm_loadu_si128(xkey.add(i)); + let dk = _mm_xor_si128(d, k); // uint32 dk[4] = {d0+k0, d1+k1, d2+k2, d3+k3} */ + let mul = _mm_mul_epu32(dk, _mm_shuffle_epi32(dk, 0x31)); // uint64 res[4] = {dk0*dk1, dk2*dk3, ...} */ + xacc.add(i).write(if acc_width == AccWidth::Acc128Bits { + let dswap = _mm_shuffle_epi32(d, _mm_shuffle(1, 0, 3, 2)); + let add = _mm_add_epi64(xacc.add(i).read(), dswap); + _mm_add_epi64(mul, add) + } else { + let add = _mm_add_epi64(xacc.add(i).read(), d); + _mm_add_epi64(mul, add) + }) + } + } + + #[target_feature(enable = "sse2")] + #[allow(clippy::cast_ptr_alignment)] + pub unsafe fn scramble_acc(acc: &mut [u64], key: &[u8]) { + let xacc = acc.as_mut_ptr() as *mut __m128i; + let xkey = key.as_ptr() as *const __m128i; + let prime32 = _mm_set1_epi32(PRIME32_1 as i32); + + for i in 0..STRIPE_LEN / mem::size_of::<__m128i>() { + let data = xacc.add(i).read(); + let shifted = _mm_srli_epi64(data, 47); + let data = _mm_xor_si128(data, shifted); + + let k = _mm_loadu_si128(xkey.add(i)); + let dk = _mm_xor_si128(data, k); + + let dk1 = _mm_mul_epu32(dk, prime32); + + let d2 = _mm_shuffle_epi32(dk, 0x31); + let dk2 = _mm_mul_epu32(d2, prime32); + let dk2h = _mm_slli_epi64(dk2, 32); + + xacc.add(i).write(_mm_add_epi64(dk1, dk2h)); + } + } +} + +#[cfg(not(any(target_feature = "avx2", target_feature = "sse2")))] +mod generic { + use super::*; + + #[inline(always)] + pub(crate) unsafe fn accumulate512( + acc: &mut [u64], + data: &[u8], + key: &[u8], + acc_width: AccWidth, + ) { + for i in (0..ACC_NB).step_by(2) { + let in1 = data[8 * i..].read_u64_le(); + let in2 = data[8 * (i + 1)..].read_u64_le(); + let key1 = key[8 * i..].read_u64_le(); + let key2 = key[8 * (i + 1)..].read_u64_le(); + let data_key1 = key1 ^ in1; + let data_key2 = key2 ^ in2; + acc[i] = acc[i].wrapping_add(mul32_to64(data_key1, data_key1 >> 32)); + acc[i + 1] = acc[i + 1].wrapping_add(mul32_to64(data_key2, data_key2 >> 32)); + + if acc_width == AccWidth::Acc128Bits { + acc[i] = acc[i].wrapping_add(in2); + acc[i + 1] = acc[i + 1].wrapping_add(in1); + } else { + acc[i] = acc[i].wrapping_add(in1); + acc[i + 1] = acc[i + 1].wrapping_add(in2); + } + } + } + + #[inline(always)] + fn mul32_to64(a: u64, b: u64) -> u64 { + (a & 0xFFFFFFFF).wrapping_mul(b & 0xFFFFFFFF) + } + + #[inline(always)] + pub unsafe fn scramble_acc(acc: &mut [u64], key: &[u8]) { + for i in 0..ACC_NB { + let key64 = key[8 * i..].read_u64_le(); + let mut acc64 = acc[i]; + acc64 ^= acc64 >> 47; + acc64 ^= key64; + acc64 = acc64.wrapping_mul(u64::from(PRIME32_1)); + acc[i] = acc64; + } + } +} + +cfg_if! { + if #[cfg(target_feature = "avx2")] { + use avx2::{accumulate512, scramble_acc}; + } else if #[cfg(target_feature = "sse2")] { + use sse2::{accumulate512, scramble_acc}; + } else { + use generic::{accumulate512, scramble_acc}; + } +} + +#[inline(always)] +fn merge_accs(acc: &[u64], secret: &[u8], start: u64) -> u64 { + avalanche( + start + .wrapping_add(mix2accs(acc, secret)) + .wrapping_add(mix2accs(&acc[2..], &secret[16..])) + .wrapping_add(mix2accs(&acc[4..], &secret[32..])) + .wrapping_add(mix2accs(&acc[6..], &secret[48..])), + ) +} + +#[inline(always)] +fn mix2accs(acc: &[u64], secret: &[u8]) -> u64 { + mul128_fold64( + acc[0] ^ secret.read_u64_le(), + acc[1] ^ secret[8..].read_u64_le(), + ) +} + +#[inline(always)] +fn mix_16bytes(data: &[u8], key: &[u8], seed: u64) -> u64 { + let ll1 = data.read_u64_le(); + let ll2 = data[8..].read_u64_le(); + + mul128_fold64( + ll1 ^ key.read_u64_le().wrapping_add(seed), + ll2 ^ key[8..].read_u64_le().wrapping_sub(seed), + ) +} + +#[inline(always)] +fn mul128_fold64(ll1: u64, ll2: u64) -> u64 { + let lll = u128::from(ll1).wrapping_mul(u128::from(ll2)); + + (lll as u64) ^ ((lll >> 64) as u64) +} + +#[inline(always)] +fn avalanche(mut h64: u64) -> u64 { + h64 ^= h64 >> 37; + h64 = h64.wrapping_mul(PRIME64_3); + h64 ^ (h64 >> 32) +} + +/* === XXH3 streaming === */ + +const INTERNAL_BUFFER_SIZE: usize = 256; +const INTERNAL_BUFFER_STRIPES: usize = INTERNAL_BUFFER_SIZE / STRIPE_LEN; + +const_assert!(INTERNAL_BUFFER_SIZE >= MIDSIZE_MAX); +const_assert_eq!(INTERNAL_BUFFER_SIZE % STRIPE_LEN, 0); + +#[repr(align(64))] +#[cfg_attr(feature = "serialize", derive(Deserialize, Serialize))] +#[derive(Clone)] +struct State { + acc: Acc, + secret: With, + buf: Vec<u8>, + seed: u64, + total_len: usize, + nb_stripes_so_far: usize, +} + +#[cfg_attr(feature = "serialize", derive(Deserialize, Serialize))] +#[derive(Clone)] +enum With { + Default(Secret), + Custom(Secret), + Ref(Vec<u8>), +} + +impl Deref for With { + type Target = [u8]; + + fn deref(&self) -> &Self::Target { + match self { + With::Default(secret) | With::Custom(secret) => &secret.0[..], + With::Ref(secret) => secret, + } + } +} + +impl Default for State { + fn default() -> Self { + Self::new(0, With::Default(Secret::default())) + } +} + +impl State { + fn new(seed: u64, secret: With) -> Self { + State { + acc: Acc::default(), + secret, + buf: Vec::with_capacity(INTERNAL_BUFFER_SIZE), + seed, + total_len: 0, + nb_stripes_so_far: 0, + } + } + + fn with_seed(seed: u64) -> Self { + Self::new(seed, With::Custom(Secret::with_seed(seed))) + } + + fn with_secret<S: Into<Vec<u8>>>(secret: S) -> State { + let secret = secret.into(); + + debug_assert!(secret.len() >= SECRET_SIZE_MIN); + + Self::new(0, With::Ref(secret)) + } + + #[inline(always)] + fn secret_limit(&self) -> usize { + self.secret.len() - STRIPE_LEN + } + + #[inline(always)] + fn nb_stripes_per_block(&self) -> usize { + self.secret_limit() / SECRET_CONSUME_RATE + } + + #[inline(always)] + fn update(&mut self, mut input: &[u8], acc_width: AccWidth) { + let len = input.len(); + + if len == 0 { + return; + } + + self.total_len += len; + + if self.buf.len() + len <= self.buf.capacity() { + self.buf.extend_from_slice(input); + return; + } + + let nb_stripes_per_block = self.nb_stripes_per_block(); + let secret_limit = self.secret_limit(); + + if !self.buf.is_empty() { + // some data within internal buffer: fill then consume it + let (load, rest) = input.split_at(self.buf.capacity() - self.buf.len()); + self.buf.extend_from_slice(load); + input = rest; + self.nb_stripes_so_far = consume_stripes( + &mut self.acc, + self.nb_stripes_so_far, + nb_stripes_per_block, + &self.buf, + INTERNAL_BUFFER_STRIPES, + &self.secret, + secret_limit, + acc_width, + ); + self.buf.clear(); + } + + // consume input by full buffer quantities + let mut chunks = input.chunks_exact(INTERNAL_BUFFER_SIZE); + + for chunk in &mut chunks { + self.nb_stripes_so_far = consume_stripes( + &mut self.acc, + self.nb_stripes_so_far, + nb_stripes_per_block, + chunk, + INTERNAL_BUFFER_STRIPES, + &self.secret, + secret_limit, + acc_width, + ); + } + + // some remaining input data : buffer it + self.buf.extend_from_slice(chunks.remainder()) + } + + #[inline(always)] + fn digest_long(&self, acc_width: AccWidth) -> Acc { + let mut acc = self.acc.clone(); + let secret_limit = self.secret_limit(); + + if self.buf.len() >= STRIPE_LEN { + // digest locally, state remains unaltered, and can continue ingesting more data afterwards + let total_nb_stripes = self.buf.len() / STRIPE_LEN; + let _nb_stripes_so_far = consume_stripes( + &mut acc, + self.nb_stripes_so_far, + self.nb_stripes_per_block(), + &self.buf, + total_nb_stripes, + &self.secret, + secret_limit, + acc_width, + ); + if (self.buf.len() % STRIPE_LEN) != 0 { + unsafe { + accumulate512( + &mut acc, + &self.buf[self.buf.len() - STRIPE_LEN..], + &self.secret[secret_limit - SECRET_LASTACC_START..], + acc_width, + ); + } + } + } else if !self.buf.is_empty() { + // one last stripe + let mut last_stripe = [0u8; STRIPE_LEN]; + let catchup_size = STRIPE_LEN - self.buf.len(); + + last_stripe[..catchup_size].copy_from_slice(unsafe { + slice::from_raw_parts( + self.buf.as_ptr().add(self.buf.capacity() - catchup_size), + catchup_size, + ) + }); + last_stripe[catchup_size..].copy_from_slice(&self.buf); + + unsafe { + accumulate512( + &mut acc, + &last_stripe[..], + &self.secret[secret_limit - SECRET_LASTACC_START..], + acc_width, + ); + } + } + + acc + } + + #[inline(always)] + fn digest64(&self) -> u64 { + if self.total_len > MIDSIZE_MAX { + let acc = self.digest_long(AccWidth::Acc64Bits); + + merge_accs( + &acc, + &self.secret[SECRET_MERGEACCS_START..], + (self.total_len as u64).wrapping_mul(PRIME64_1), + ) + } else if self.seed != 0 { + hash64_with_seed(&self.buf, self.seed) + } else { + hash64_with_secret(&self.buf, &self.secret[..self.secret_limit() + STRIPE_LEN]) + } + } + + #[inline(always)] + fn digest128(&self) -> u128 { + let secret_limit = self.secret_limit(); + + if self.total_len > MIDSIZE_MAX { + let acc = self.digest_long(AccWidth::Acc128Bits); + + debug_assert!(secret_limit + STRIPE_LEN >= ACC_SIZE + SECRET_MERGEACCS_START); + + let total_len = self.total_len as u64; + + let low64 = merge_accs( + &acc, + &self.secret[SECRET_MERGEACCS_START..], + total_len.wrapping_mul(PRIME64_1), + ); + let high64 = merge_accs( + &acc, + &self.secret[secret_limit + STRIPE_LEN - ACC_SIZE - SECRET_MERGEACCS_START..], + !total_len.wrapping_mul(PRIME64_2), + ); + + u128::from(low64) + (u128::from(high64) << 64) + } else if self.seed != 0 { + hash128_with_seed(&self.buf, self.seed) + } else { + hash128_with_secret(&self.buf, &self.secret[..secret_limit + STRIPE_LEN]) + } + } +} + +#[inline(always)] +#[allow(clippy::too_many_arguments)] +fn consume_stripes( + acc: &mut [u64], + nb_stripes_so_far: usize, + nb_stripes_per_block: usize, + data: &[u8], + total_stripes: usize, + secret: &[u8], + secret_limit: usize, + acc_width: AccWidth, +) -> usize { + debug_assert!(nb_stripes_so_far < nb_stripes_per_block); + + if nb_stripes_per_block - nb_stripes_so_far <= total_stripes { + let nb_stripes = nb_stripes_per_block - nb_stripes_so_far; + + accumulate( + acc, + data, + &secret[nb_stripes_so_far * SECRET_CONSUME_RATE..], + nb_stripes, + acc_width, + ); + unsafe { + scramble_acc(acc, &secret[secret_limit..]); + } + accumulate( + acc, + &data[nb_stripes * STRIPE_LEN..], + secret, + total_stripes - nb_stripes, + acc_width, + ); + + total_stripes - nb_stripes + } else { + accumulate( + acc, + data, + &secret[nb_stripes_so_far * SECRET_CONSUME_RATE..], + total_stripes, + acc_width, + ); + + nb_stripes_so_far + total_stripes + } +} + +/* ========================================== + * XXH3 128 bits (=> XXH128) + * ========================================== */ + +#[inline(always)] +fn hash_len_0to16_128bits(data: &[u8], len: usize, secret: &[u8], seed: u64) -> u128 { + debug_assert!(len <= 16); + + if len > 8 { + hash_len_9to16_128bits(data, len, secret, seed) + } else if len >= 4 { + hash_len_4to8_128bits(data, len, secret, seed) + } else if len > 0 { + hash_len_1to3_128bits(data, len, secret, seed) + } else { + 0 + } +} + +#[inline(always)] +fn hash_len_1to3_128bits(data: &[u8], len: usize, key: &[u8], seed: u64) -> u128 { + debug_assert!((1..=3).contains(&len)); + + let c1 = u32::from(data[0]); + let c2 = u32::from(data[len >> 1]); + let c3 = u32::from(data[len - 1]); + let combinedl = c1 + (c2 << 8) + (c3 << 16) + ((len as u32) << 24); + let combinedh = combinedl.swap_bytes(); + let keyedl = u64::from(combinedl) ^ u64::from(key.read_u32_le()).wrapping_add(seed); + let keyedh = u64::from(combinedh) ^ u64::from(key[4..].read_u32_le()).wrapping_sub(seed); + let mixedl = keyedl.wrapping_mul(PRIME64_1); + let mixedh = keyedh.wrapping_mul(PRIME64_2); + + u128::from(avalanche(mixedl)) + (u128::from(avalanche(mixedh)) << 64) +} + +#[inline(always)] +fn hash_len_4to8_128bits(data: &[u8], len: usize, key: &[u8], seed: u64) -> u128 { + debug_assert!((4..=8).contains(&len)); + + let in1 = u64::from(data.read_u32_le()); + let in2 = u64::from(data[len - 4..].read_u32_le()); + let in64l = in1.wrapping_add(in2 << 32); + let in64h = in64l.swap_bytes(); + let keyedl = in64l ^ key.read_u64_le().wrapping_add(seed); + let keyedh = in64h ^ key[8..].read_u64_le().wrapping_sub(seed); + let mix64l1 = + (len as u64).wrapping_add((keyedl ^ (keyedl >> 51)).wrapping_mul(u64::from(PRIME32_1))); + let mix64l2 = (mix64l1 ^ (mix64l1 >> 47)).wrapping_mul(PRIME64_2); + let mix64h1 = (keyedh ^ (keyedh >> 47)) + .wrapping_mul(PRIME64_1) + .wrapping_sub(len as u64); + let mix64h2 = (mix64h1 ^ (mix64h1 >> 43)).wrapping_mul(PRIME64_4); + + u128::from(avalanche(mix64l2)) + (u128::from(avalanche(mix64h2)) << 64) +} + +#[inline(always)] +fn hash_len_9to16_128bits(data: &[u8], len: usize, key: &[u8], seed: u64) -> u128 { + debug_assert!((9..=16).contains(&len)); + + let ll1 = data.read_u64_le() ^ key.read_u64_le().wrapping_add(seed); + let ll2 = data[len - 8..].read_u64_le() ^ key[8..].read_u64_le().wrapping_sub(seed); + let inlow = ll1 ^ ll2; + + let m128 = u128::from(inlow).wrapping_mul(u128::from(PRIME64_1)); + let high64 = ((m128 >> 64) as u64).wrapping_add(ll2.wrapping_mul(PRIME64_1)); + let low64 = (m128 as u64) ^ (high64 >> 32); + + let h128 = u128::from(low64).wrapping_mul(u128::from(PRIME64_2)); + let high64 = ((h128 >> 64) as u64).wrapping_add(high64.wrapping_mul(PRIME64_2)); + let low64 = h128 as u64; + + u128::from(avalanche(low64)) + (u128::from(avalanche(high64)) << 64) +} + +#[inline(always)] +fn hash_len_17to128_128bits(data: &[u8], len: usize, secret: &[u8], seed: u64) -> u128 { + debug_assert!((17..=128).contains(&len)); + debug_assert!(secret.len() >= SECRET_SIZE_MIN); + + let mut acc1 = PRIME64_1.wrapping_mul(len as u64); + let mut acc2 = 0u64; + + if len > 32 { + if len > 64 { + if len > 96 { + acc1 = acc1.wrapping_add(mix_16bytes(&data[48..], &secret[96..], seed)); + acc2 = acc2.wrapping_add(mix_16bytes(&data[len - 64..], &secret[112..], seed)); + } + acc1 = acc1.wrapping_add(mix_16bytes(&data[32..], &secret[64..], seed)); + acc2 = acc2.wrapping_add(mix_16bytes(&data[len - 48..], &secret[80..], seed)); + } + + acc1 = acc1.wrapping_add(mix_16bytes(&data[16..], &secret[32..], seed)); + acc2 = acc2.wrapping_add(mix_16bytes(&data[len - 32..], &secret[48..], seed)); + } + + acc1 = acc1.wrapping_add(mix_16bytes(data, secret, seed)); + acc2 = acc2.wrapping_add(mix_16bytes(&data[len - 16..], &secret[16..], seed)); + + let low64 = acc1.wrapping_add(acc2); + let high64 = acc1 + .wrapping_mul(PRIME64_1) + .wrapping_add(acc2.wrapping_mul(PRIME64_4)) + .wrapping_add((len as u64).wrapping_sub(seed).wrapping_mul(PRIME64_2)); + + u128::from(avalanche(low64)) + (u128::from(0u64.wrapping_sub(avalanche(high64))) << 64) +} + +#[inline(always)] +fn hash_len_129to240_128bits(data: &[u8], len: usize, secret: &[u8], seed: u64) -> u128 { + debug_assert!((129..=MIDSIZE_MAX).contains(&len)); + debug_assert!(secret.len() >= SECRET_SIZE_MIN); + + let acc1 = (len as u64).wrapping_mul(PRIME64_1); + let acc2 = 0u64; + + let (acc1, acc2) = (0..4).fold((acc1, acc2), |(acc1, acc2), i| { + ( + acc1.wrapping_add(mix_16bytes(&data[32 * i..], &secret[32 * i..], seed)), + acc2.wrapping_add(mix_16bytes( + &data[32 * i + 16..], + &secret[32 * i + 16..], + 0u64.wrapping_sub(seed), + )), + ) + }); + let acc1 = avalanche(acc1); + let acc2 = avalanche(acc2); + + let nb_rounds = len / 32; + debug_assert!(nb_rounds >= 4); + + let (acc1, acc2) = (4..nb_rounds).fold((acc1, acc2), |(acc1, acc2), i| { + ( + acc1.wrapping_add(mix_16bytes( + &data[32 * i..], + &secret[32 * (i - 4) + MIDSIZE_STARTOFFSET..], + seed, + )), + acc2.wrapping_add(mix_16bytes( + &data[32 * i + 16..], + &secret[32 * (i - 4) + 16 + MIDSIZE_STARTOFFSET..], + 0u64.wrapping_sub(seed), + )), + ) + }); + + // last bytes + let acc1 = acc1.wrapping_add(mix_16bytes( + &data[len - 16..], + &secret[SECRET_SIZE_MIN - MIDSIZE_LASTOFFSET..], + seed, + )); + let acc2 = acc2.wrapping_add(mix_16bytes( + &data[len - 32..], + &secret[SECRET_SIZE_MIN - MIDSIZE_LASTOFFSET - 16..], + 0u64.wrapping_sub(seed), + )); + + let low64 = acc1.wrapping_add(acc2); + let high64 = acc1 + .wrapping_mul(PRIME64_1) + .wrapping_add(acc2.wrapping_mul(PRIME64_4)) + .wrapping_add((len as u64).wrapping_sub(seed).wrapping_mul(PRIME64_2)); + + u128::from(avalanche(low64)) + (u128::from(0u64.wrapping_sub(avalanche(high64))) << 64) +} + +#[inline] +fn hash_long_128bits_with_default_secret(data: &[u8], len: usize) -> u128 { + hash_long_128bits_internal(data, len, &SECRET) +} + +#[inline] +fn hash_long_128bits_with_secret(data: &[u8], len: usize, secret: &[u8]) -> u128 { + hash_long_128bits_internal(data, len, secret) +} + +#[inline] +fn hash_long_128bits_with_seed(data: &[u8], len: usize, seed: u64) -> u128 { + if seed == 0 { + hash_long_128bits_with_default_secret(data, len) + } else { + let secret = Secret::with_seed(seed); + + hash_long_128bits_internal(data, len, &secret) + } +} + +#[inline(always)] +fn hash_long_128bits_internal(data: &[u8], len: usize, secret: &[u8]) -> u128 { + let mut acc = Acc::default(); + + hash_long_internal_loop(&mut acc, data, len, secret, AccWidth::Acc128Bits); + + debug_assert!(secret.len() >= acc.len() + SECRET_MERGEACCS_START); + + let low64 = merge_accs( + &acc, + &secret[SECRET_MERGEACCS_START..], + (len as u64).wrapping_mul(PRIME64_1), + ); + let high64 = merge_accs( + &acc, + &secret[secret.len() - ACC_SIZE - SECRET_MERGEACCS_START..], + !(len as u64).wrapping_mul(PRIME64_2), + ); + + u128::from(low64) + (u128::from(high64) << 64) +} + +/* === XXH3 128-bit streaming === */ + +/* all the functions are actually the same as for 64-bit streaming variant, +just the reset one is different (different initial acc values for 0,5,6,7), +and near the end of the digest function */ + +#[cfg(test)] +mod tests { + use alloc::vec; + + use super::*; + + const PRIME: u64 = 2654435761; + const PRIME64: u64 = 11400714785074694797; + const SANITY_BUFFER_SIZE: usize = 2243; + + fn sanity_buffer() -> [u8; SANITY_BUFFER_SIZE] { + let mut buf = [0; SANITY_BUFFER_SIZE]; + let mut byte_gen: u64 = PRIME; + + for b in buf.iter_mut() { + *b = (byte_gen >> 56) as u8; + byte_gen = byte_gen.wrapping_mul(PRIME64); + } + + buf + } + + #[test] + fn hash_64bits_sanity_check() { + let buf = sanity_buffer(); + + let test_cases = vec![ + (&[][..], 0, 0), /* zero-length hash is always 0 */ + (&[][..], PRIME64, 0), + (&buf[..1], 0, 0x7198D737CFE7F386), /* 1 - 3 */ + (&buf[..1], PRIME64, 0xB70252DB7161C2BD), /* 1 - 3 */ + (&buf[..6], 0, 0x22CBF5F3E1F6257C), /* 4 - 8 */ + (&buf[..6], PRIME64, 0x6398631C12AB94CE), /* 4 - 8 */ + (&buf[..12], 0, 0xD5361CCEEBB5A0CC), /* 9 - 16 */ + (&buf[..12], PRIME64, 0xC4C125E75A808C3D), /* 9 - 16 */ + (&buf[..24], 0, 0x46796F3F78B20F6B), /* 17 - 32 */ + (&buf[..24], PRIME64, 0x60171A7CD0A44C10), /* 17 - 32 */ + (&buf[..48], 0, 0xD8D4D3590D136E11), /* 33 - 64 */ + (&buf[..48], PRIME64, 0x05441F2AEC2A1296), /* 33 - 64 */ + (&buf[..80], 0, 0xA1DC8ADB3145B86A), /* 65 - 96 */ + (&buf[..80], PRIME64, 0xC9D55256965B7093), /* 65 - 96 */ + (&buf[..112], 0, 0xE43E5717A61D3759), /* 97 -128 */ + (&buf[..112], PRIME64, 0x5A5F89A3FECE44A5), /* 97 -128 */ + (&buf[..195], 0, 0x6F747739CBAC22A5), /* 129-240 */ + (&buf[..195], PRIME64, 0x33368E23C7F95810), /* 129-240 */ + (&buf[..403], 0, 0x4834389B15D981E8), /* one block, last stripe is overlapping */ + (&buf[..403], PRIME64, 0x85CE5DFFC7B07C87), /* one block, last stripe is overlapping */ + (&buf[..512], 0, 0x6A1B982631F059A8), /* one block, finishing at stripe boundary */ + (&buf[..512], PRIME64, 0x10086868CF0ADC99), /* one block, finishing at stripe boundary */ + (&buf[..2048], 0, 0xEFEFD4449323CDD4), /* 2 blocks, finishing at block boundary */ + (&buf[..2048], PRIME64, 0x01C85E405ECA3F6E), /* 2 blocks, finishing at block boundary */ + (&buf[..2240], 0, 0x998C0437486672C7), /* 3 blocks, finishing at stripe boundary */ + (&buf[..2240], PRIME64, 0x4ED38056B87ABC7F), /* 3 blocks, finishing at stripe boundary */ + (&buf[..2243], 0, 0xA559D20581D742D3), /* 3 blocks, last stripe is overlapping */ + (&buf[..2243], PRIME64, 0x96E051AB57F21FC8), /* 3 blocks, last stripe is overlapping */ + ]; + + for (buf, seed, result) in test_cases { + { + let hash = hash64_with_seed(buf, seed); + + assert_eq!( + hash, + result, + "hash64_with_seed(&buf[..{}], seed={}) failed, got 0x{:X}, expected 0x{:X}", + buf.len(), + seed, + hash, + result + ); + } + + // streaming API test + + // single ingestio + { + let mut hasher = Hash64::with_seed(seed); + hasher.write(buf); + let hash = hasher.finish(); + + assert_eq!( + hash, + result, + "Hash64::update(&buf[..{}]) with seed={} failed, got 0x{:X}, expected 0x{:X}", + buf.len(), + seed, + hash, + result + ); + } + + if buf.len() > 3 { + // 2 ingestions + let mut hasher = Hash64::with_seed(seed); + hasher.write(&buf[..3]); + hasher.write(&buf[3..]); + let hash = hasher.finish(); + + assert_eq!( + hash, + result, + "Hash64::update(&buf[..3], &buf[3..{}]) with seed={} failed, got 0x{:X}, expected 0x{:X}", + buf.len(), + seed, + hash, + result + ); + } + + // byte by byte ingestion + { + let mut hasher = Hash64::with_seed(seed); + + for chunk in buf.chunks(1) { + hasher.write(chunk); + } + + let hash = hasher.finish(); + + assert_eq!( + hash, + result, + "Hash64::update(&buf[..{}].chunks(1)) with seed={} failed, got 0x{:X}, expected 0x{:X}", + buf.len(), + seed, + hash, + result + ); + } + } + } + + #[test] + fn hash_64bits_with_secret_sanity_check() { + let buf = sanity_buffer(); + let secret = &buf[7..7 + SECRET_SIZE_MIN + 11]; + + let test_cases = vec![ + (&[][..], secret, 0), /* zero-length hash is always 0 */ + (&buf[..1], secret, 0x7F69735D618DB3F0), /* 1 - 3 */ + (&buf[..6], secret, 0xBFCC7CB1B3554DCE), /* 6 - 8 */ + (&buf[..12], secret, 0x8C50DC90AC9206FC), /* 9 - 16 */ + (&buf[..24], secret, 0x1CD2C2EE9B9A0928), /* 17 - 32 */ + (&buf[..48], secret, 0xA785256D9D65D514), /* 33 - 64 */ + (&buf[..80], secret, 0x6F3053360D21BBB7), /* 65 - 96 */ + (&buf[..112], secret, 0x560E82D25684154C), /* 97 -128 */ + (&buf[..195], secret, 0xBA5BDDBC5A767B11), /* 129-240 */ + (&buf[..403], secret, 0xFC3911BBA656DB58), /* one block, last stripe is overlapping */ + (&buf[..512], secret, 0x306137DD875741F1), /* one block, finishing at stripe boundary */ + (&buf[..2048], secret, 0x2836B83880AD3C0C), /* > one block, at least one scrambling */ + (&buf[..2243], secret, 0x3446E248A00CB44A), /* > one block, at least one scrambling, last stripe unaligned */ + ]; + + for (buf, secret, result) in test_cases { + { + let hash = hash64_with_secret(buf, secret); + + assert_eq!( + hash, + result, + "hash64_with_secret(&buf[..{}], secret) failed, got 0x{:X}, expected 0x{:X}", + buf.len(), + hash, + result + ); + } + + // streaming API test + + // single ingestio + { + let mut hasher = Hash64::with_secret(secret); + hasher.write(buf); + let hash = hasher.finish(); + + assert_eq!( + hash, + result, + "Hash64::update(&buf[..{}]) with secret failed, got 0x{:X}, expected 0x{:X}", + buf.len(), + hash, + result + ); + } + + // byte by byte ingestion + { + let mut hasher = Hash64::with_secret(secret); + + for chunk in buf.chunks(1) { + hasher.write(chunk); + } + + let hash = hasher.finish(); + + assert_eq!( + hash, + result, + "Hash64::update(&buf[..{}].chunks(1)) with secret failed, got 0x{:X}, expected 0x{:X}", + buf.len(), + hash, + result + ); + } + } + } + + #[test] + fn hash_128bits_sanity_check() { + let buf = sanity_buffer(); + + let test_cases = vec![ + (&[][..], 0, 0u64, 0u64), /* zero-length hash is { seed, -seed } by default */ + (&[][..], PRIME, 0, 0), + (&buf[..1], 0, 0x7198D737CFE7F386, 0x3EE70EA338F3F1E8), /* 1-3 */ + (&buf[..1], PRIME, 0x8E05996EC27C0F46, 0x90DFC659A8BDCC0C), /* 1-3 */ + (&buf[..6], 0, 0x22CBF5F3E1F6257C, 0xD4E6C2B94FFC3BFA), /* 4-8 */ + (&buf[..6], PRIME, 0x97B28D3079F8541F, 0xEFC0B954298E6555), /* 4-8 */ + (&buf[..12], 0, 0x0E0CD01F05AC2F0D, 0x2B55C95951070D4B), /* 9-16 */ + (&buf[..12], PRIME, 0xA9DE561CA04CDF37, 0x609E31FDC00A43C9), /* 9-16 */ + (&buf[..24], 0, 0x46796F3F78B20F6B, 0x58FF55C3926C13FA), /* 17-32 */ + (&buf[..24], PRIME, 0x30D5C4E9EB415C55, 0x8868344B3A4645D0), /* 17-32 */ + (&buf[..48], 0, 0xD8D4D3590D136E11, 0x5527A42843020A62), /* 33-64 */ + (&buf[..48], PRIME, 0x1D8834E1A5407A1C, 0x44375B9FB060F541), /* 33-64 */ + (&buf[..81], 0, 0x4B9B448ED8DFD3DD, 0xE805A6D1A43D70E5), /* 65-96 */ + (&buf[..81], PRIME, 0xD2D6B075945617BA, 0xE58BE5736F6E7550), /* 65-96 */ + (&buf[..103], 0, 0xC5A9F97B29EFA44E, 0x254DB7BE881E125C), /* 97-128 */ + (&buf[..103], PRIME, 0xFA2086367CDB177F, 0x0AEDEA68C988B0C0), /* 97-128 */ + (&buf[..192], 0, 0xC3142FDDD9102A3F, 0x06F1747E77185F97), /* 129-240 */ + (&buf[..192], PRIME, 0xA89F07B35987540F, 0xCF1B35FB2C557F54), /* 129-240 */ + (&buf[..222], 0, 0xA61AC4EB3295F86B, 0x33FA7B7598C28A07), /* 129-240 */ + (&buf[..222], PRIME, 0x54135EB88AD8B75E, 0xBC45CE6AE50BCF53), /* 129-240 */ + (&buf[..403], 0, 0xB0C48E6D18E9D084, 0xB16FC17E992FF45D), /* one block, last stripe is overlapping */ + (&buf[..403], PRIME64, 0x0A1D320C9520871D, 0xCE11CB376EC93252), /* one block, last stripe is overlapping */ + (&buf[..512], 0, 0xA03428558AC97327, 0x4ECF51281BA406F7), /* one block, finishing at stripe boundary */ + (&buf[..512], PRIME64, 0xAF67A482D6C893F2, 0x1382D92F25B84D90), /* one block, finishing at stripe boundary */ + (&buf[..2048], 0, 0x21901B416B3B9863, 0x212AF8E6326F01E0), /* two blocks, finishing at block boundary */ + (&buf[..2048], PRIME, 0xBDBB2282577DADEC, 0xF78CDDC2C9A9A692), /* two blocks, finishing at block boundary */ + (&buf[..2240], 0, 0x00AD52FA9385B6FE, 0xC705BAD3356CE302), /* two blocks, ends at stripe boundary */ + (&buf[..2240], PRIME, 0x10FD0072EC68BFAA, 0xE1312F3458817F15), /* two blocks, ends at stripe boundary */ + (&buf[..2237], 0, 0x970C91411533862C, 0x4BBD06FF7BFF0AB1), /* two blocks, ends at stripe boundary */ + (&buf[..2237], PRIME, 0xD80282846D814431, 0x14EBB157B84D9785), /* two blocks, ends at stripe boundary */ + ]; + + for (buf, seed, lo, hi) in test_cases { + let result = u128::from(lo) + (u128::from(hi) << 64); + + { + let hash = hash128_with_seed(buf, seed); + + assert_eq!( + hash, + result, + "hash128_with_seed(&buf[..{}], seed={}) failed, got 0x{:X}, expected 0x{:X}", + buf.len(), + seed, + hash, + result + ); + } + + // streaming API test + + // single ingestio + { + let mut hasher = Hash128::with_seed(seed); + hasher.write(buf); + let hash = hasher.finish_ext(); + + assert_eq!( + hash, + result, + "Hash128::update(&buf[..{}]) with seed={} failed, got 0x{:X}, expected 0x{:X}", + buf.len(), + seed, + hash, + result + ); + } + + if buf.len() > 3 { + // 2 ingestions + let mut hasher = Hash128::with_seed(seed); + hasher.write(&buf[..3]); + hasher.write(&buf[3..]); + let hash = hasher.finish_ext(); + + assert_eq!( + hash, + result, + "Hash64::update(&buf[..3], &buf[3..{}]) with seed={} failed, got 0x{:X}, expected 0x{:X}", + buf.len(), + seed, + hash, + result + ); + } + + // byte by byte ingestion + { + let mut hasher = Hash128::with_seed(seed); + + for chunk in buf.chunks(1) { + hasher.write(chunk); + } + + let hash = hasher.finish_ext(); + + assert_eq!( + hash, + result, + "Hash64::update(&buf[..{}].chunks(1)) with seed={} failed, got 0x{:X}, expected 0x{:X}", + buf.len(), + seed, + hash, + result + ); + } + } + } +} |