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//! SHA-512 `x86`/`x86_64` backend
#![allow(clippy::many_single_char_names)]
use core::mem::size_of;
#[cfg(target_arch = "x86")]
use core::arch::x86::*;
#[cfg(target_arch = "x86_64")]
use core::arch::x86_64::*;
use crate::consts::K64;
cpufeatures::new!(avx2_cpuid, "avx2");
pub fn compress(state: &mut [u64; 8], blocks: &[[u8; 128]]) {
// after stabilization
if avx2_cpuid::get() {
unsafe {
sha512_compress_x86_64_avx2(state, blocks);
}
} else {
super::soft::compress(state, blocks);
}
}
#[target_feature(enable = "avx2")]
unsafe fn sha512_compress_x86_64_avx2(state: &mut [u64; 8], blocks: &[[u8; 128]]) {
let mut start_block = 0;
if blocks.len() & 0b1 != 0 {
sha512_compress_x86_64_avx(state, &blocks[0]);
start_block += 1;
}
let mut ms: MsgSchedule = [_mm_setzero_si128(); 8];
let mut t2: RoundStates = [_mm_setzero_si128(); 40];
let mut x = [_mm256_setzero_si256(); 8];
for i in (start_block..blocks.len()).step_by(2) {
load_data_avx2(&mut x, &mut ms, &mut t2, blocks.as_ptr().add(i) as *const _);
// First block
let mut current_state = *state;
rounds_0_63_avx2(&mut current_state, &mut x, &mut ms, &mut t2);
rounds_64_79(&mut current_state, &ms);
accumulate_state(state, ¤t_state);
// Second block
current_state = *state;
process_second_block(&mut current_state, &t2);
accumulate_state(state, ¤t_state);
}
}
#[inline(always)]
unsafe fn sha512_compress_x86_64_avx(state: &mut [u64; 8], block: &[u8; 128]) {
let mut ms = [_mm_setzero_si128(); 8];
let mut x = [_mm_setzero_si128(); 8];
// Reduced to single iteration
let mut current_state = *state;
load_data_avx(&mut x, &mut ms, block.as_ptr() as *const _);
rounds_0_63_avx(&mut current_state, &mut x, &mut ms);
rounds_64_79(&mut current_state, &ms);
accumulate_state(state, ¤t_state);
}
#[inline(always)]
unsafe fn load_data_avx(x: &mut [__m128i; 8], ms: &mut MsgSchedule, data: *const __m128i) {
#[allow(non_snake_case)]
let MASK = _mm_setr_epi32(0x04050607, 0x00010203, 0x0c0d0e0f, 0x08090a0b);
macro_rules! unrolled_iterations {
($($i:literal),*) => {$(
x[$i] = _mm_loadu_si128(data.add($i) as *const _);
x[$i] = _mm_shuffle_epi8(x[$i], MASK);
let y = _mm_add_epi64(
x[$i],
_mm_loadu_si128(&K64[2 * $i] as *const u64 as *const _),
);
ms[$i] = y;
)*};
}
unrolled_iterations!(0, 1, 2, 3, 4, 5, 6, 7);
}
#[inline(always)]
unsafe fn load_data_avx2(
x: &mut [__m256i; 8],
ms: &mut MsgSchedule,
t2: &mut RoundStates,
data: *const __m128i,
) {
#[allow(non_snake_case)]
let MASK = _mm256_set_epi64x(
0x0809_0A0B_0C0D_0E0F_i64,
0x0001_0203_0405_0607_i64,
0x0809_0A0B_0C0D_0E0F_i64,
0x0001_0203_0405_0607_i64,
);
macro_rules! unrolled_iterations {
($($i:literal),*) => {$(
x[$i] = _mm256_insertf128_si256(x[$i], _mm_loadu_si128(data.add(8 + $i) as *const _), 1);
x[$i] = _mm256_insertf128_si256(x[$i], _mm_loadu_si128(data.add($i) as *const _), 0);
x[$i] = _mm256_shuffle_epi8(x[$i], MASK);
let t = _mm_loadu_si128(K64.as_ptr().add($i * 2) as *const u64 as *const _);
let y = _mm256_add_epi64(x[$i], _mm256_set_m128i(t, t));
ms[$i] = _mm256_extracti128_si256(y, 0);
t2[$i] = _mm256_extracti128_si256(y, 1);
)*};
}
unrolled_iterations!(0, 1, 2, 3, 4, 5, 6, 7);
}
#[inline(always)]
unsafe fn rounds_0_63_avx(current_state: &mut State, x: &mut [__m128i; 8], ms: &mut MsgSchedule) {
let mut k64_idx: usize = SHA512_BLOCK_WORDS_NUM;
for _ in 0..4 {
for j in 0..8 {
let k64 = _mm_loadu_si128(&K64[k64_idx] as *const u64 as *const _);
let y = sha512_update_x_avx(x, k64);
{
let ms = cast_ms(ms);
sha_round(current_state, ms[2 * j]);
sha_round(current_state, ms[2 * j + 1]);
}
ms[j] = y;
k64_idx += 2;
}
}
}
#[inline(always)]
unsafe fn rounds_0_63_avx2(
current_state: &mut State,
x: &mut [__m256i; 8],
ms: &mut MsgSchedule,
t2: &mut RoundStates,
) {
let mut k64x4_idx: usize = SHA512_BLOCK_WORDS_NUM;
for i in 1..5 {
for j in 0..8 {
let t = _mm_loadu_si128(K64.as_ptr().add(k64x4_idx) as *const u64 as *const _);
let y = sha512_update_x_avx2(x, _mm256_set_m128i(t, t));
{
let ms = cast_ms(ms);
sha_round(current_state, ms[2 * j]);
sha_round(current_state, ms[2 * j + 1]);
}
ms[j] = _mm256_extracti128_si256(y, 0);
t2[8 * i + j] = _mm256_extracti128_si256(y, 1);
k64x4_idx += 2;
}
}
}
#[inline(always)]
fn rounds_64_79(current_state: &mut State, ms: &MsgSchedule) {
let ms = cast_ms(ms);
for i in 64..80 {
sha_round(current_state, ms[i & 0xf]);
}
}
#[inline(always)]
fn process_second_block(current_state: &mut State, t2: &RoundStates) {
for t2 in cast_rs(t2).iter() {
sha_round(current_state, *t2);
}
}
#[inline(always)]
fn sha_round(s: &mut State, x: u64) {
macro_rules! big_sigma0 {
($a:expr) => {
$a.rotate_right(28) ^ $a.rotate_right(34) ^ $a.rotate_right(39)
};
}
macro_rules! big_sigma1 {
($a:expr) => {
$a.rotate_right(14) ^ $a.rotate_right(18) ^ $a.rotate_right(41)
};
}
macro_rules! bool3ary_202 {
($a:expr, $b:expr, $c:expr) => {
$c ^ ($a & ($b ^ $c))
};
} // Choose, MD5F, SHA1C
macro_rules! bool3ary_232 {
($a:expr, $b:expr, $c:expr) => {
($a & $b) ^ ($a & $c) ^ ($b & $c)
};
} // Majority, SHA1M
macro_rules! rotate_state {
($s:ident) => {{
let tmp = $s[7];
$s[7] = $s[6];
$s[6] = $s[5];
$s[5] = $s[4];
$s[4] = $s[3];
$s[3] = $s[2];
$s[2] = $s[1];
$s[1] = $s[0];
$s[0] = tmp;
}};
}
let t = x
.wrapping_add(s[7])
.wrapping_add(big_sigma1!(s[4]))
.wrapping_add(bool3ary_202!(s[4], s[5], s[6]));
s[7] = t
.wrapping_add(big_sigma0!(s[0]))
.wrapping_add(bool3ary_232!(s[0], s[1], s[2]));
s[3] = s[3].wrapping_add(t);
rotate_state!(s);
}
#[inline(always)]
fn accumulate_state(dst: &mut State, src: &State) {
for i in 0..SHA512_HASH_WORDS_NUM {
dst[i] = dst[i].wrapping_add(src[i]);
}
}
macro_rules! fn_sha512_update_x {
($name:ident, $ty:ident, {
ADD64 = $ADD64:ident,
ALIGNR8 = $ALIGNR8:ident,
SRL64 = $SRL64:ident,
SLL64 = $SLL64:ident,
XOR = $XOR:ident,
}) => {
unsafe fn $name(x: &mut [$ty; 8], k64: $ty) -> $ty {
// q[2:1]
let mut t0 = $ALIGNR8(x[1], x[0], 8);
// q[10:9]
let mut t3 = $ALIGNR8(x[5], x[4], 8);
// q[2:1] >> s0[0]
let mut t2 = $SRL64(t0, 1);
// q[1:0] + q[10:9]
x[0] = $ADD64(x[0], t3);
// q[2:1] >> s0[2]
t3 = $SRL64(t0, 7);
// q[2:1] << (64 - s0[1])
let mut t1 = $SLL64(t0, 64 - 8);
// (q[2:1] >> s0[2]) ^
// (q[2:1] >> s0[0])
t0 = $XOR(t3, t2);
// q[2:1] >> s0[1]
t2 = $SRL64(t2, 8 - 1);
// (q[2:1] >> s0[2]) ^
// (q[2:1] >> s0[0]) ^
// q[2:1] << (64 - s0[1])
t0 = $XOR(t0, t1);
// q[2:1] << (64 - s0[0])
t1 = $SLL64(t1, 8 - 1);
// sigma1(q[2:1])
t0 = $XOR(t0, t2);
t0 = $XOR(t0, t1);
// q[15:14] >> s1[2]
t3 = $SRL64(x[7], 6);
// q[15:14] >> (64 - s1[1])
t2 = $SLL64(x[7], 64 - 61);
// q[1:0] + sigma0(q[2:1])
x[0] = $ADD64(x[0], t0);
// q[15:14] >> s1[0]
t1 = $SRL64(x[7], 19);
// q[15:14] >> s1[2] ^
// q[15:14] >> (64 - s1[1])
t3 = $XOR(t3, t2);
// q[15:14] >> (64 - s1[0])
t2 = $SLL64(t2, 61 - 19);
// q[15:14] >> s1[2] ^
// q[15:14] >> (64 - s1[1] ^
// q[15:14] >> s1[0]
t3 = $XOR(t3, t1);
// q[15:14] >> s1[1]
t1 = $SRL64(t1, 61 - 19);
// sigma1(q[15:14])
t3 = $XOR(t3, t2);
t3 = $XOR(t3, t1);
// q[1:0] + q[10:9] + sigma1(q[15:14]) + sigma0(q[2:1])
x[0] = $ADD64(x[0], t3);
// rotate
let temp = x[0];
x[0] = x[1];
x[1] = x[2];
x[2] = x[3];
x[3] = x[4];
x[4] = x[5];
x[5] = x[6];
x[6] = x[7];
x[7] = temp;
$ADD64(x[7], k64)
}
};
}
fn_sha512_update_x!(sha512_update_x_avx, __m128i, {
ADD64 = _mm_add_epi64,
ALIGNR8 = _mm_alignr_epi8,
SRL64 = _mm_srli_epi64,
SLL64 = _mm_slli_epi64,
XOR = _mm_xor_si128,
});
fn_sha512_update_x!(sha512_update_x_avx2, __m256i, {
ADD64 = _mm256_add_epi64,
ALIGNR8 = _mm256_alignr_epi8,
SRL64 = _mm256_srli_epi64,
SLL64 = _mm256_slli_epi64,
XOR = _mm256_xor_si256,
});
#[inline(always)]
fn cast_ms(ms: &MsgSchedule) -> &[u64; SHA512_BLOCK_WORDS_NUM] {
unsafe { &*(ms as *const MsgSchedule as *const _) }
}
#[inline(always)]
fn cast_rs(rs: &RoundStates) -> &[u64; SHA512_ROUNDS_NUM] {
unsafe { &*(rs as *const RoundStates as *const _) }
}
type State = [u64; SHA512_HASH_WORDS_NUM];
type MsgSchedule = [__m128i; SHA512_BLOCK_WORDS_NUM / 2];
type RoundStates = [__m128i; SHA512_ROUNDS_NUM / 2];
const SHA512_BLOCK_BYTE_LEN: usize = 128;
const SHA512_ROUNDS_NUM: usize = 80;
const SHA512_HASH_BYTE_LEN: usize = 64;
const SHA512_HASH_WORDS_NUM: usize = SHA512_HASH_BYTE_LEN / size_of::<u64>();
const SHA512_BLOCK_WORDS_NUM: usize = SHA512_BLOCK_BYTE_LEN / size_of::<u64>();