rust-bitcoin-unsafe-fast/hashes/src/cmp.rs

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//! Useful comparison functions.
/// Compare two slices for equality in fixed time. Panics if the slices are of non-equal length.
///
/// This works by XOR'ing each byte of the two inputs together and keeping an OR counter of the
/// results.
///
/// Instead of doing fancy bit twiddling to try to outsmart the compiler and prevent early exits,
/// which is not guaranteed to remain stable as compilers get ever smarter, we take the hit of
/// writing each intermediate value to memory with a volatile write and then re-reading it with a
/// volatile read. This should remain stable across compiler upgrades, but is much slower.
///
/// As of rust 1.31.0 disassembly looks completely within reason for this, see
/// <https://godbolt.org/z/mMbGQv>.
pub fn fixed_time_eq(a: &[u8], b: &[u8]) -> bool {
assert!(a.len() == b.len());
let count = a.len();
let lhs = &a[..count];
let rhs = &b[..count];
let mut r: u8 = 0;
for i in 0..count {
let mut rs = unsafe { core::ptr::read_volatile(&r) };
rs |= lhs[i] ^ rhs[i];
unsafe {
core::ptr::write_volatile(&mut r, rs);
}
}
{
let mut t = unsafe { core::ptr::read_volatile(&r) };
t |= t >> 4;
unsafe {
core::ptr::write_volatile(&mut r, t);
}
}
{
let mut t = unsafe { core::ptr::read_volatile(&r) };
t |= t >> 2;
unsafe {
core::ptr::write_volatile(&mut r, t);
}
}
{
let mut t = unsafe { core::ptr::read_volatile(&r) };
t |= t >> 1;
unsafe {
core::ptr::write_volatile(&mut r, t);
}
}
unsafe { (::core::ptr::read_volatile(&r) & 1) == 0 }
}
#[test]
fn eq_test() {
assert!(fixed_time_eq(&[0b00000000], &[0b00000000]));
assert!(fixed_time_eq(&[0b00000001], &[0b00000001]));
assert!(fixed_time_eq(&[0b00000010], &[0b00000010]));
assert!(fixed_time_eq(&[0b00000100], &[0b00000100]));
assert!(fixed_time_eq(&[0b00001000], &[0b00001000]));
assert!(fixed_time_eq(&[0b00010000], &[0b00010000]));
assert!(fixed_time_eq(&[0b00100000], &[0b00100000]));
assert!(fixed_time_eq(&[0b01000000], &[0b01000000]));
assert!(fixed_time_eq(&[0b10000000], &[0b10000000]));
assert!(fixed_time_eq(&[0b11111111], &[0b11111111]));
assert!(!fixed_time_eq(&[0b00000001], &[0b00000000]));
assert!(!fixed_time_eq(&[0b00000001], &[0b11111111]));
assert!(!fixed_time_eq(&[0b00000010], &[0b00000000]));
assert!(!fixed_time_eq(&[0b00000010], &[0b11111111]));
assert!(!fixed_time_eq(&[0b00000100], &[0b00000000]));
assert!(!fixed_time_eq(&[0b00000100], &[0b11111111]));
assert!(!fixed_time_eq(&[0b00001000], &[0b00000000]));
assert!(!fixed_time_eq(&[0b00001000], &[0b11111111]));
assert!(!fixed_time_eq(&[0b00010000], &[0b00000000]));
assert!(!fixed_time_eq(&[0b00010000], &[0b11111111]));
assert!(!fixed_time_eq(&[0b00100000], &[0b00000000]));
assert!(!fixed_time_eq(&[0b00100000], &[0b11111111]));
assert!(!fixed_time_eq(&[0b01000000], &[0b00000000]));
assert!(!fixed_time_eq(&[0b01000000], &[0b11111111]));
assert!(!fixed_time_eq(&[0b10000000], &[0b00000000]));
assert!(!fixed_time_eq(&[0b10000000], &[0b11111111]));
assert!(fixed_time_eq(&[0b00000000, 0b00000000], &[0b00000000, 0b00000000]));
assert!(!fixed_time_eq(&[0b00000001, 0b00000000], &[0b00000000, 0b00000000]));
assert!(!fixed_time_eq(&[0b00000000, 0b00000001], &[0b00000000, 0b00000000]));
assert!(!fixed_time_eq(&[0b00000000, 0b00000000], &[0b00000001, 0b00000000]));
assert!(!fixed_time_eq(&[0b00000000, 0b00000000], &[0b00000001, 0b00000001]));
}
#[cfg(bench)]
mod benches {
use test::Bencher;
use crate::cmp::fixed_time_eq;
use crate::{sha256, sha512, Hash};
#[bench]
fn bench_32b_constant_time_cmp_ne(bh: &mut Bencher) {
let hash_a = sha256::Hash::hash(&[0; 1]);
let hash_b = sha256::Hash::hash(&[1; 1]);
bh.iter(|| fixed_time_eq(&hash_a[..], &hash_b[..]))
}
#[bench]
fn bench_32b_slice_cmp_ne(bh: &mut Bencher) {
let hash_a = sha256::Hash::hash(&[0; 1]);
let hash_b = sha256::Hash::hash(&[1; 1]);
bh.iter(|| &hash_a[..] == &hash_b[..])
}
#[bench]
fn bench_32b_constant_time_cmp_eq(bh: &mut Bencher) {
let hash_a = sha256::Hash::hash(&[0; 1]);
let hash_b = sha256::Hash::hash(&[0; 1]);
bh.iter(|| fixed_time_eq(&hash_a[..], &hash_b[..]))
}
#[bench]
fn bench_32b_slice_cmp_eq(bh: &mut Bencher) {
let hash_a = sha256::Hash::hash(&[0; 1]);
let hash_b = sha256::Hash::hash(&[0; 1]);
bh.iter(|| &hash_a[..] == &hash_b[..])
}
#[bench]
fn bench_64b_constant_time_cmp_ne(bh: &mut Bencher) {
let hash_a = sha512::Hash::hash(&[0; 1]);
let hash_b = sha512::Hash::hash(&[1; 1]);
bh.iter(|| fixed_time_eq(&hash_a[..], &hash_b[..]))
}
#[bench]
fn bench_64b_slice_cmp_ne(bh: &mut Bencher) {
let hash_a = sha512::Hash::hash(&[0; 1]);
let hash_b = sha512::Hash::hash(&[1; 1]);
bh.iter(|| &hash_a[..] == &hash_b[..])
}
#[bench]
fn bench_64b_constant_time_cmp_eq(bh: &mut Bencher) {
let hash_a = sha512::Hash::hash(&[0; 1]);
let hash_b = sha512::Hash::hash(&[0; 1]);
bh.iter(|| fixed_time_eq(&hash_a[..], &hash_b[..]))
}
#[bench]
fn bench_64b_slice_cmp_eq(bh: &mut Bencher) {
let hash_a = sha512::Hash::hash(&[0; 1]);
let hash_b = sha512::Hash::hash(&[0; 1]);
bh.iter(|| &hash_a[..] == &hash_b[..])
}
}