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#![allow(clippy::many_single_char_names)]
use super::BLOCK_SIZE;
use core::convert::TryInto;
const K: [u32; 4] = [0x5A827999, 0x6ED9EBA1, 0x8F1BBCDC, 0xCA62C1D6];
#[inline(always)]
fn add(a: [u32; 4], b: [u32; 4]) -> [u32; 4] {
[
a[0].wrapping_add(b[0]),
a[1].wrapping_add(b[1]),
a[2].wrapping_add(b[2]),
a[3].wrapping_add(b[3]),
]
}
#[inline(always)]
fn xor(a: [u32; 4], b: [u32; 4]) -> [u32; 4] {
[a[0] ^ b[0], a[1] ^ b[1], a[2] ^ b[2], a[3] ^ b[3]]
}
#[inline]
pub fn sha1_first_add(e: u32, w0: [u32; 4]) -> [u32; 4] {
let [a, b, c, d] = w0;
[e.wrapping_add(a), b, c, d]
}
fn sha1msg1(a: [u32; 4], b: [u32; 4]) -> [u32; 4] {
let [_, _, w2, w3] = a;
let [w4, w5, _, _] = b;
[a[0] ^ w2, a[1] ^ w3, a[2] ^ w4, a[3] ^ w5]
}
fn sha1msg2(a: [u32; 4], b: [u32; 4]) -> [u32; 4] {
let [x0, x1, x2, x3] = a;
let [_, w13, w14, w15] = b;
let w16 = (x0 ^ w13).rotate_left(1);
let w17 = (x1 ^ w14).rotate_left(1);
let w18 = (x2 ^ w15).rotate_left(1);
let w19 = (x3 ^ w16).rotate_left(1);
[w16, w17, w18, w19]
}
#[inline]
fn sha1_first_half(abcd: [u32; 4], msg: [u32; 4]) -> [u32; 4] {
sha1_first_add(abcd[0].rotate_left(30), msg)
}
fn sha1_digest_round_x4(abcd: [u32; 4], work: [u32; 4], i: i8) -> [u32; 4] {
match i {
0 => sha1rnds4c(abcd, add(work, [K[0]; 4])),
1 => sha1rnds4p(abcd, add(work, [K[1]; 4])),
2 => sha1rnds4m(abcd, add(work, [K[2]; 4])),
3 => sha1rnds4p(abcd, add(work, [K[3]; 4])),
_ => unreachable!("unknown icosaround index"),
}
}
fn sha1rnds4c(abcd: [u32; 4], msg: [u32; 4]) -> [u32; 4] {
let [mut a, mut b, mut c, mut d] = abcd;
let [t, u, v, w] = msg;
let mut e = 0u32;
macro_rules! bool3ary_202 {
($a:expr, $b:expr, $c:expr) => {
$c ^ ($a & ($b ^ $c))
};
} // Choose, MD5F, SHA1C
e = e
.wrapping_add(a.rotate_left(5))
.wrapping_add(bool3ary_202!(b, c, d))
.wrapping_add(t);
b = b.rotate_left(30);
d = d
.wrapping_add(e.rotate_left(5))
.wrapping_add(bool3ary_202!(a, b, c))
.wrapping_add(u);
a = a.rotate_left(30);
c = c
.wrapping_add(d.rotate_left(5))
.wrapping_add(bool3ary_202!(e, a, b))
.wrapping_add(v);
e = e.rotate_left(30);
b = b
.wrapping_add(c.rotate_left(5))
.wrapping_add(bool3ary_202!(d, e, a))
.wrapping_add(w);
d = d.rotate_left(30);
[b, c, d, e]
}
fn sha1rnds4p(abcd: [u32; 4], msg: [u32; 4]) -> [u32; 4] {
let [mut a, mut b, mut c, mut d] = abcd;
let [t, u, v, w] = msg;
let mut e = 0u32;
macro_rules! bool3ary_150 {
($a:expr, $b:expr, $c:expr) => {
$a ^ $b ^ $c
};
} // Parity, XOR, MD5H, SHA1P
e = e
.wrapping_add(a.rotate_left(5))
.wrapping_add(bool3ary_150!(b, c, d))
.wrapping_add(t);
b = b.rotate_left(30);
d = d
.wrapping_add(e.rotate_left(5))
.wrapping_add(bool3ary_150!(a, b, c))
.wrapping_add(u);
a = a.rotate_left(30);
c = c
.wrapping_add(d.rotate_left(5))
.wrapping_add(bool3ary_150!(e, a, b))
.wrapping_add(v);
e = e.rotate_left(30);
b = b
.wrapping_add(c.rotate_left(5))
.wrapping_add(bool3ary_150!(d, e, a))
.wrapping_add(w);
d = d.rotate_left(30);
[b, c, d, e]
}
fn sha1rnds4m(abcd: [u32; 4], msg: [u32; 4]) -> [u32; 4] {
let [mut a, mut b, mut c, mut d] = abcd;
let [t, u, v, w] = msg;
let mut e = 0u32;
macro_rules! bool3ary_232 {
($a:expr, $b:expr, $c:expr) => {
($a & $b) ^ ($a & $c) ^ ($b & $c)
};
} // Majority, SHA1M
e = e
.wrapping_add(a.rotate_left(5))
.wrapping_add(bool3ary_232!(b, c, d))
.wrapping_add(t);
b = b.rotate_left(30);
d = d
.wrapping_add(e.rotate_left(5))
.wrapping_add(bool3ary_232!(a, b, c))
.wrapping_add(u);
a = a.rotate_left(30);
c = c
.wrapping_add(d.rotate_left(5))
.wrapping_add(bool3ary_232!(e, a, b))
.wrapping_add(v);
e = e.rotate_left(30);
b = b
.wrapping_add(c.rotate_left(5))
.wrapping_add(bool3ary_232!(d, e, a))
.wrapping_add(w);
d = d.rotate_left(30);
[b, c, d, e]
}
macro_rules! rounds4 {
($h0:ident, $h1:ident, $wk:expr, $i:expr) => {
sha1_digest_round_x4($h0, sha1_first_half($h1, $wk), $i)
};
}
macro_rules! schedule {
($v0:expr, $v1:expr, $v2:expr, $v3:expr) => {
sha1msg2(xor(sha1msg1($v0, $v1), $v2), $v3)
};
}
macro_rules! schedule_rounds4 {
(
$h0:ident, $h1:ident,
$w0:expr, $w1:expr, $w2:expr, $w3:expr, $w4:expr,
$i:expr
) => {
$w4 = schedule!($w0, $w1, $w2, $w3);
$h1 = rounds4!($h0, $h1, $w4, $i);
};
}
#[inline(always)]
fn sha1_digest_block_u32(state: &mut [u32; 5], block: &[u32; 16]) {
let mut w0 = [block[0], block[1], block[2], block[3]];
let mut w1 = [block[4], block[5], block[6], block[7]];
let mut w2 = [block[8], block[9], block[10], block[11]];
let mut w3 = [block[12], block[13], block[14], block[15]];
#[allow(clippy::needless_late_init)]
let mut w4;
let mut h0 = [state[0], state[1], state[2], state[3]];
let mut h1 = sha1_first_add(state[4], w0);
// Rounds 0..20
h1 = sha1_digest_round_x4(h0, h1, 0);
h0 = rounds4!(h1, h0, w1, 0);
h1 = rounds4!(h0, h1, w2, 0);
h0 = rounds4!(h1, h0, w3, 0);
schedule_rounds4!(h0, h1, w0, w1, w2, w3, w4, 0);
// Rounds 20..40
schedule_rounds4!(h1, h0, w1, w2, w3, w4, w0, 1);
schedule_rounds4!(h0, h1, w2, w3, w4, w0, w1, 1);
schedule_rounds4!(h1, h0, w3, w4, w0, w1, w2, 1);
schedule_rounds4!(h0, h1, w4, w0, w1, w2, w3, 1);
schedule_rounds4!(h1, h0, w0, w1, w2, w3, w4, 1);
// Rounds 40..60
schedule_rounds4!(h0, h1, w1, w2, w3, w4, w0, 2);
schedule_rounds4!(h1, h0, w2, w3, w4, w0, w1, 2);
schedule_rounds4!(h0, h1, w3, w4, w0, w1, w2, 2);
schedule_rounds4!(h1, h0, w4, w0, w1, w2, w3, 2);
schedule_rounds4!(h0, h1, w0, w1, w2, w3, w4, 2);
// Rounds 60..80
schedule_rounds4!(h1, h0, w1, w2, w3, w4, w0, 3);
schedule_rounds4!(h0, h1, w2, w3, w4, w0, w1, 3);
schedule_rounds4!(h1, h0, w3, w4, w0, w1, w2, 3);
schedule_rounds4!(h0, h1, w4, w0, w1, w2, w3, 3);
schedule_rounds4!(h1, h0, w0, w1, w2, w3, w4, 3);
let e = h1[0].rotate_left(30);
let [a, b, c, d] = h0;
state[0] = state[0].wrapping_add(a);
state[1] = state[1].wrapping_add(b);
state[2] = state[2].wrapping_add(c);
state[3] = state[3].wrapping_add(d);
state[4] = state[4].wrapping_add(e);
}
pub fn compress(state: &mut [u32; 5], blocks: &[[u8; BLOCK_SIZE]]) {
let mut block_u32 = [0u32; BLOCK_SIZE / 4];
// since LLVM can't properly use aliasing yet it will make
// unnecessary state stores without this copy
let mut state_cpy = *state;
for block in blocks.iter() {
for (o, chunk) in block_u32.iter_mut().zip(block.chunks_exact(4)) {
*o = u32::from_be_bytes(chunk.try_into().unwrap());
}
sha1_digest_block_u32(&mut state_cpy, &block_u32);
}
*state = state_cpy;
}