From: Matt Corallo Date: Sun, 3 Mar 2024 14:23:39 +0000 (+0000) Subject: Add a relatively simple mostly-const-fn bigint math implementation X-Git-Tag: v0.5.4~31 X-Git-Url: http://git.bitcoin.ninja/?a=commitdiff_plain;h=9bfff3609162efcca02310d4d9231054b6d824fd;p=dnssec-prover Add a relatively simple mostly-const-fn bigint math implementation While `ring` is great, it struggles with platform support and has a fairly involved dependency tree due to its reliance on C backends. Further, while the `RustCrypto` org tries to stick to Rust, in doing so it takes on more (unnecessary) dependencies and has a particularly unusable MSRV policy. Finally, its contributor base has historically not been particularly friendly. Thus, sadly, there's not really a good option for doing RSA validation using a third-party crate. Instead, in the next commit we'll go our own way and add an in-crate RSA validator. This takes the first step, adding a bigint implementation that works up to 4096 bits (the longest allowed RSA keys in the DNS). Sadly, once we get to EC math we'll really want most of our math operations to be const fns, which provides some additional limits. Absent a better way to do subslicing on rustc 1.63, this commit introduces a dependency on the `const_slice_from_raw_parts` feature, which appears to work fine on 1.63 with `RUSTC_BOOTSTRAP=1` set, and was stabilized in 1.64. --- diff --git a/Cargo.toml b/Cargo.toml index 9a762de..7dd5d41 100644 --- a/Cargo.toml +++ b/Cargo.toml @@ -26,6 +26,9 @@ bitcoin_hashes = { version = "0.14", default-features = false, optional = true } hex_lit = { version = "0.1", default-features = false, features = ["rust_v_1_46"], optional = true } tokio_crate = { package = "tokio", version = "1.0", default-features = false, optional = true } +[target.'cfg(fuzzing)'.dependencies] +ibig = { version = "0.3", optional = true } + [dev-dependencies] hex-conservative = { version = "0.1", default-features = false, features = ["alloc"] } base64 = "0.21" diff --git a/fuzz/Cargo.toml b/fuzz/Cargo.toml index b8869bd..74a5929 100644 --- a/fuzz/Cargo.toml +++ b/fuzz/Cargo.toml @@ -18,7 +18,7 @@ libfuzzer_fuzz = ["libfuzzer-sys"] stdin_fuzz = [] [dependencies] -dnssec-prover = { path = "../", features = ["validation", "std", "build_server"] } +dnssec-prover = { path = "../", features = ["validation", "std", "build_server", "ibig"] } afl = { version = "0.12", optional = true } honggfuzz = { version = "0.5", optional = true, default-features = false } @@ -52,3 +52,7 @@ path = "src/parse_stream_validate.rs" [[bin]] name = "fuzz_builder" path = "src/fuzz_builder.rs" + +[[bin]] +name = "bigint_math" +path = "src/bigint_math.rs" diff --git a/fuzz/src/bigint_math.rs b/fuzz/src/bigint_math.rs new file mode 100644 index 0000000..6de807f --- /dev/null +++ b/fuzz/src/bigint_math.rs @@ -0,0 +1,68 @@ +// This file is Copyright its original authors, visible in version control +// history. +// +// This file is licensed under the Apache License, Version 2.0 or the MIT license +// , at your option. +// You may not use this file except in accordance with one or both of these +// licenses. + +#![cfg_attr(feature = "libfuzzer_fuzz", no_main)] + +#[cfg(not(fuzzing))] +compile_error!("Fuzz targets need cfg=fuzzing"); + +extern crate dnssec_prover; +use dnssec_prover::crypto::bigint::fuzz_math; + +#[cfg(feature = "afl")] +#[macro_use] extern crate afl; +#[cfg(feature = "afl")] +fn main() { + fuzz!(|data| { + fuzz_math(data); + }); +} + +#[cfg(feature = "honggfuzz")] +#[macro_use] extern crate honggfuzz; +#[cfg(feature = "honggfuzz")] +fn main() { + loop { + fuzz!(|data| { + fuzz_math(data); + }); + } +} + +#[cfg(feature = "libfuzzer_fuzz")] +#[macro_use] extern crate libfuzzer_sys; +#[cfg(feature = "libfuzzer_fuzz")] +fuzz_target!(|data: &[u8]| { + fuzz_math(data); +}); + +#[cfg(feature = "stdin_fuzz")] +fn main() { + use std::io::Read; + + let mut data = Vec::with_capacity(8192); + std::io::stdin().read_to_end(&mut data).unwrap(); + fuzz_math(&data); +} + +#[test] +fn run_test_cases() { + use std::fs; + use std::io::Read; + + if let Ok(tests) = fs::read_dir("test_cases/bigint_math") { + for test in tests { + let mut data: Vec = Vec::new(); + let path = test.unwrap().path(); + fs::File::open(&path).unwrap().read_to_end(&mut data).unwrap(); + + fuzz_math(&data); + } + } +} diff --git a/src/crypto/bigint.rs b/src/crypto/bigint.rs new file mode 100644 index 0000000..62beef4 --- /dev/null +++ b/src/crypto/bigint.rs @@ -0,0 +1,902 @@ +//! Simple variable-time big integer implementation + +use alloc::vec::Vec; + +const WORD_COUNT_4096: usize = 4096 / 64; + +// RFC 5702 indicates RSA keys can be up to 4096 bits +#[derive(Clone, Debug, PartialEq, Eq, PartialOrd, Ord)] +pub(super) struct U4096([u64; WORD_COUNT_4096]); + +macro_rules! debug_unwrap { ($v: expr) => { { + let v = $v; + debug_assert!(v.is_ok()); + match v { + Ok(r) => r, + Err(e) => return Err(e), + } +} } } + +// Various const versions of existing slice utilities +/// Const version of `&a[start..end]` +const fn const_subslice<'a, T>(a: &'a [T], start: usize, end: usize) -> &'a [T] { + assert!(start <= a.len()); + assert!(end <= a.len()); + assert!(end >= start); + let mut startptr = a.as_ptr(); + startptr = unsafe { startptr.add(start) }; + let len = end - start; + // The docs for from_raw_parts do not mention any requirements that the pointer be valid if the + // length is zero, aside from requiring proper alignment (which is met here). Thus, + // one-past-the-end should be an acceptable pointer for a 0-length slice. + unsafe { alloc::slice::from_raw_parts(startptr, len) } +} + +/// Const version of `dest[dest_start..dest_end].copy_from_slice(source)` +/// +/// Once `const_mut_refs` is stable we can convert this to a function +macro_rules! copy_from_slice { + ($dest: ident, $dest_start: expr, $dest_end: expr, $source: ident) => { { + let dest_start = $dest_start; + let dest_end = $dest_end; + assert!(dest_start <= $dest.len()); + assert!(dest_end <= $dest.len()); + assert!(dest_end >= dest_start); + assert!(dest_end - dest_start == $source.len()); + let mut i = 0; + while i < $source.len() { + $dest[i + dest_start] = $source[i]; + i += 1; + } + } } +} + +/// Const version of a > b +const fn slice_greater_than(a: &[u64], b: &[u64]) -> bool { + debug_assert!(a.len() == b.len()); + let len = if a.len() <= b.len() { a.len() } else { b.len() }; + let mut i = 0; + while i < len { + if a[i] > b[i] { return true; } + else if a[i] < b[i] { return false; } + i += 1; + } + false // Equal +} + +/// Const version of a == b +const fn slice_equal(a: &[u64], b: &[u64]) -> bool { + debug_assert!(a.len() == b.len()); + let len = if a.len() <= b.len() { a.len() } else { b.len() }; + let mut i = 0; + while i < len { + if a[i] != b[i] { return false; } + i += 1; + } + true +} + +/// Adds one in-place, returning an overflow flag, in which case one out-of-bounds high bit is +/// implicitly included in the result. +/// +/// Once `const_mut_refs` is stable we can convert this to a function +macro_rules! add_one { ($a: ident) => { { + let len = $a.len(); + let mut i = 0; + let mut res = true; + while i < len { + let (v, carry) = $a[len - 1 - i].overflowing_add(1); + $a[len - 1 - i] = v; + if !carry { res = false; break; } + i += 1; + } + res +} } } + +/// Negates the given u64 slice. +/// +/// Once `const_mut_refs` is stable we can convert this to a function +macro_rules! negate { ($v: ident) => { { + let mut i = 0; + while i < $v.len() { + $v[i] ^= 0xffff_ffff_ffff_ffff; + i += 1; + } + let overflow = add_one!($v); + debug_assert!(!overflow); +} } } + +/// Doubles in-place, returning an overflow flag, in which case one out-of-bounds high bit is +/// implicitly included in the result. +/// +/// Once `const_mut_refs` is stable we can convert this to a function +macro_rules! double { ($a: ident) => { { + { let _: &[u64] = &$a; } // Force type resolution + let len = $a.len(); + let mut carry = false; + let mut i = 0; + while i < len { + let mut next_carry = ($a[len - 1 - i] & (1 << 63)) != 0; + let (v, next_carry_2) = ($a[len - 1 - i] << 1).overflowing_add(carry as u64); + $a[len - 1 - i] = v; + debug_assert!(!next_carry || !next_carry_2); + next_carry |= next_carry_2; + carry = next_carry; + i += 1; + } + carry +} } } + +macro_rules! define_add { ($name: ident, $len: expr) => { + /// Adds two $len-64-bit integers together, returning a new $len-64-bit integer and an overflow + /// bit, with the same semantics as the std [`u64::overflowing_add`] method. + const fn $name(a: &[u64], b: &[u64]) -> ([u64; $len], bool) { + debug_assert!(a.len() == $len); + debug_assert!(b.len() == $len); + let mut r = [0; $len]; + let mut carry = false; + let mut i = 0; + while i < $len { + let pos = $len - 1 - i; + let (v, mut new_carry) = a[pos].overflowing_add(b[pos]); + let (v2, new_new_carry) = v.overflowing_add(carry as u64); + new_carry |= new_new_carry; + r[pos] = v2; + carry = new_carry; + i += 1; + } + (r, carry) + } +} } + +define_add!(add_2, 2); +define_add!(add_4, 4); +define_add!(add_8, 8); +define_add!(add_16, 16); +define_add!(add_32, 32); +define_add!(add_64, 64); +define_add!(add_128, 128); + +macro_rules! define_sub { ($name: ident, $len: expr) => { + /// Subtracts the `b` $len-64-bit integer from the `a` $len-64-bit integer, returning a new + /// $len-64-bit integer and an overflow bit, with the same semantics as the std + /// [`u64::overflowing_sub`] method. + const fn $name(a: &[u64], b: &[u64]) -> ([u64; $len], bool) { + debug_assert!(a.len() == $len); + debug_assert!(b.len() == $len); + let mut r = [0; $len]; + let mut carry = false; + let mut i = 0; + while i < $len { + let pos = $len - 1 - i; + let (v, mut new_carry) = a[pos].overflowing_sub(b[pos]); + let (v2, new_new_carry) = v.overflowing_sub(carry as u64); + new_carry |= new_new_carry; + r[pos] = v2; + carry = new_carry; + i += 1; + } + (r, carry) + } +} } + +define_sub!(sub_2, 2); +define_sub!(sub_4, 4); +define_sub!(sub_8, 8); +define_sub!(sub_16, 16); +define_sub!(sub_32, 32); +define_sub!(sub_64, 64); +#[cfg(debug_assertions)] +define_sub!(sub_128, 128); + +/// Multiplies two 128-bit integers together, returning a new 256-bit integer. +/// +/// This is the base case for our multiplication, taking advantage of Rust's native 128-bit int +/// types to do multiplication (potentially) natively. +const fn mul_2(a: &[u64], b: &[u64]) -> [u64; 4] { + debug_assert!(a.len() == 2); + debug_assert!(b.len() == 2); + + // Gradeschool multiplication is way faster here. + let (a0, a1) = (a[0] as u128, a[1] as u128); + let (b0, b1) = (b[0] as u128, b[1] as u128); + let z2 = a0 * b0; + let z1i = a0 * b1; + let z1j = b0 * a1; + let (z1, i_carry) = z1i.overflowing_add(z1j); + let z0 = a1 * b1; + + let z2a = ((z2 >> 64) & 0xffff_ffff_ffff_ffff) as u64; + let z1a = ((z1 >> 64) & 0xffff_ffff_ffff_ffff) as u64; + let z0a = ((z0 >> 64) & 0xffff_ffff_ffff_ffff) as u64; + let z2b = (z2 & 0xffff_ffff_ffff_ffff) as u64; + let z1b = (z1 & 0xffff_ffff_ffff_ffff) as u64; + let z0b = (z0 & 0xffff_ffff_ffff_ffff) as u64; + + let l = z0b; + let (k, j_carry) = z0a.overflowing_add(z1b); + let (mut j, mut second_i_carry) = z1a.overflowing_add(z2b); + + let new_i_carry; + (j, new_i_carry) = j.overflowing_add(j_carry as u64); + debug_assert!(!second_i_carry || !new_i_carry); + second_i_carry |= new_i_carry; + + let mut i = z2a; + let mut spurious_overflow; + (i, spurious_overflow) = i.overflowing_add(i_carry as u64); + debug_assert!(!spurious_overflow); + (i, spurious_overflow) = i.overflowing_add(second_i_carry as u64); + debug_assert!(!spurious_overflow); + + [i, j, k, l] +} + +macro_rules! define_mul { ($name: ident, $len: expr, $submul: ident, $add: ident, $subadd: ident, $sub: ident, $subsub: ident) => { + /// Multiplies two $len-64-bit integers together, returning a new $len*2-64-bit integer. + const fn $name(a: &[u64], b: &[u64]) -> [u64; $len * 2] { + // We could probably get a bit faster doing gradeschool multiplication for some smaller + // sizes, but its easier to just have one variable-length multiplication, so we do + // Karatsuba always here. + debug_assert!(a.len() == $len); + debug_assert!(b.len() == $len); + + let a0 = const_subslice(a, 0, $len / 2); + let a1 = const_subslice(a, $len / 2, $len); + let b0 = const_subslice(b, 0, $len / 2); + let b1 = const_subslice(b, $len / 2, $len); + + let z2 = $submul(a0, b0); + let z0 = $submul(a1, b1); + + let (z1a_max, z1a_min, z1a_sign) = + if slice_greater_than(&a1, &a0) { (a1, a0, true) } else { (a0, a1, false) }; + let (z1b_max, z1b_min, z1b_sign) = + if slice_greater_than(&b1, &b0) { (b1, b0, true) } else { (b0, b1, false) }; + + let z1a = $subsub(z1a_max, z1a_min); + debug_assert!(!z1a.1); + let z1b = $subsub(z1b_max, z1b_min); + debug_assert!(!z1b.1); + let z1m_sign = z1a_sign == z1b_sign; + + let z1m = $submul(&z1a.0, &z1b.0); + let z1n = $add(&z0, &z2); + let mut z1_carry = z1n.1; + let z1 = if z1m_sign { + let r = $sub(&z1n.0, &z1m); + if r.1 { z1_carry ^= true; } + r.0 + } else { + let r = $add(&z1n.0, &z1m); + if r.1 { z1_carry = true; } + r.0 + }; + + let l = const_subslice(&z0, $len / 2, $len); + let (k, j_carry) = $subadd(const_subslice(&z0, 0, $len / 2), const_subslice(&z1, $len / 2, $len)); + let (mut j, mut i_carry) = $subadd(const_subslice(&z1, 0, $len / 2), const_subslice(&z2, $len / 2, $len)); + if j_carry { + let new_i_carry = add_one!(j); + debug_assert!(!i_carry || !new_i_carry); + i_carry |= new_i_carry; + } + let mut i = [0; $len / 2]; + let i_source = const_subslice(&z2, 0, $len / 2); + copy_from_slice!(i, 0, $len / 2, i_source); + if i_carry { + let spurious_carry = add_one!(i); + debug_assert!(!spurious_carry); + } + if z1_carry { + let spurious_carry = add_one!(i); + debug_assert!(!spurious_carry); + } + + let mut res = [0; $len * 2]; + copy_from_slice!(res, $len * 2 * 0 / 4, $len * 2 * 1 / 4, i); + copy_from_slice!(res, $len * 2 * 1 / 4, $len * 2 * 2 / 4, j); + copy_from_slice!(res, $len * 2 * 2 / 4, $len * 2 * 3 / 4, k); + copy_from_slice!(res, $len * 2 * 3 / 4, $len * 2 * 4 / 4, l); + res + } +} } + +define_mul!(mul_4, 4, mul_2, add_4, add_2, sub_4, sub_2); +define_mul!(mul_8, 8, mul_4, add_8, add_4, sub_8, sub_4); +define_mul!(mul_16, 16, mul_8, add_16, add_8, sub_16, sub_8); +define_mul!(mul_32, 32, mul_16, add_32, add_16, sub_32, sub_16); +define_mul!(mul_64, 64, mul_32, add_64, add_32, sub_64, sub_32); + + +/// Squares a 128-bit integer, returning a new 256-bit integer. +/// +/// This is the base case for our squaring, taking advantage of Rust's native 128-bit int +/// types to do multiplication (potentially) natively. +const fn sqr_2(a: &[u64]) -> [u64; 4] { + debug_assert!(a.len() == 2); + + let (a0, a1) = (a[0] as u128, a[1] as u128); + let z2 = a0 * a0; + let mut z1 = a0 * a1; + let i_carry = z1 & (1u128 << 127) != 0; + z1 <<= 1; + let z0 = a1 * a1; + + let z2a = ((z2 >> 64) & 0xffff_ffff_ffff_ffff) as u64; + let z1a = ((z1 >> 64) & 0xffff_ffff_ffff_ffff) as u64; + let z0a = ((z0 >> 64) & 0xffff_ffff_ffff_ffff) as u64; + let z2b = (z2 & 0xffff_ffff_ffff_ffff) as u64; + let z1b = (z1 & 0xffff_ffff_ffff_ffff) as u64; + let z0b = (z0 & 0xffff_ffff_ffff_ffff) as u64; + + let l = z0b; + let (k, j_carry) = z0a.overflowing_add(z1b); + let (mut j, mut second_i_carry) = z1a.overflowing_add(z2b); + + let new_i_carry; + (j, new_i_carry) = j.overflowing_add(j_carry as u64); + debug_assert!(!second_i_carry || !new_i_carry); + second_i_carry |= new_i_carry; + + let mut i = z2a; + let mut spurious_overflow; + (i, spurious_overflow) = i.overflowing_add(i_carry as u64); + debug_assert!(!spurious_overflow); + (i, spurious_overflow) = i.overflowing_add(second_i_carry as u64); + debug_assert!(!spurious_overflow); + + [i, j, k, l] +} + +macro_rules! define_sqr { ($name: ident, $len: expr, $submul: ident, $subsqr: ident, $subadd: ident) => { + /// Squares a $len-64-bit integers, returning a new $len*2-64-bit integer. + const fn $name(a: &[u64]) -> [u64; $len * 2] { + debug_assert!(a.len() == $len); + + let hi = const_subslice(a, 0, $len / 2); + let lo = const_subslice(a, $len / 2, $len); + + let v0 = $subsqr(lo); + let mut v1 = $submul(hi, lo); + let i_carry = double!(v1); + let v2 = $subsqr(hi); + + let l = const_subslice(&v0, $len / 2, $len); + let (k, j_carry) = $subadd(const_subslice(&v0, 0, $len / 2), const_subslice(&v1, $len / 2, $len)); + let (mut j, mut i_carry_2) = $subadd(const_subslice(&v1, 0, $len / 2), const_subslice(&v2, $len / 2, $len)); + + let mut i = [0; $len / 2]; + let i_source = const_subslice(&v2, 0, $len / 2); + copy_from_slice!(i, 0, $len / 2, i_source); + + if j_carry { + let new_i_carry = add_one!(j); + debug_assert!(!i_carry_2 || !new_i_carry); + i_carry_2 |= new_i_carry; + } + if i_carry { + let spurious_carry = add_one!(i); + debug_assert!(!spurious_carry); + } + if i_carry_2 { + let spurious_carry = add_one!(i); + debug_assert!(!spurious_carry); + } + + let mut res = [0; $len * 2]; + copy_from_slice!(res, $len * 2 * 0 / 4, $len * 2 * 1 / 4, i); + copy_from_slice!(res, $len * 2 * 1 / 4, $len * 2 * 2 / 4, j); + copy_from_slice!(res, $len * 2 * 2 / 4, $len * 2 * 3 / 4, k); + copy_from_slice!(res, $len * 2 * 3 / 4, $len * 2 * 4 / 4, l); + res + } +} } + +define_sqr!(sqr_4, 4, mul_2, sqr_2, add_2); +define_sqr!(sqr_8, 8, mul_4, sqr_4, add_4); +define_sqr!(sqr_16, 16, mul_8, sqr_8, add_8); +define_sqr!(sqr_32, 32, mul_16, sqr_16, add_16); +define_sqr!(sqr_64, 64, mul_32, sqr_32, add_32); + +#[cfg(fuzzing)] +macro_rules! dummy_pre_push { ($name: ident, $len: expr) => {} } +macro_rules! vec_pre_push { ($name: ident, $len: expr) => { $name.push([0; $len]); } } + +macro_rules! define_div_rem { ($name: ident, $len: expr, $sub: ident, $heap_init: expr, $pre_push: ident $(, $const_opt: tt)?) => { + /// Divides two $len-64-bit integers, `a` by `b`, returning the quotient and remainder + /// + /// Fails iff `b` is zero. + $($const_opt)? fn $name(a: &[u64; $len], b: &[u64; $len]) -> Result<([u64; $len], [u64; $len]), ()> { + if slice_equal(b, &[0; $len]) { return Err(()); } + + let mut b_pow = *b; + let mut pow2s = $heap_init; + let mut pow2s_count = 0; + while slice_greater_than(a, &b_pow) { + $pre_push!(pow2s, $len); + pow2s[pow2s_count] = b_pow; + pow2s_count += 1; + let double_overflow = double!(b_pow); + if double_overflow { break; } + } + let mut quot = [0; $len]; + let mut rem = *a; + let mut pow2 = pow2s_count as isize - 1; + while pow2 >= 0 { + let b_pow = pow2s[pow2 as usize]; + let overflow = double!(quot); + debug_assert!(!overflow); + if slice_greater_than(&rem, &b_pow) { + let (r, carry) = $sub(&rem, &b_pow); + debug_assert!(!carry); + rem = r; + quot[$len - 1] |= 1; + } + pow2 -= 1; + } + if slice_equal(&rem, b) { + let overflow = add_one!(quot); + debug_assert!(!overflow); + Ok((quot, [0; $len])) + } else { + Ok((quot, rem)) + } + } +} } + +#[cfg(fuzzing)] +define_div_rem!(div_rem_2, 2, sub_2, [[0; 2]; 2 * 64], dummy_pre_push, const); +#[cfg(fuzzing)] +define_div_rem!(div_rem_4, 4, sub_4, [[0; 4]; 4 * 64], dummy_pre_push, const); // Uses 8 KiB of stack +#[cfg(fuzzing)] +define_div_rem!(div_rem_8, 8, sub_8, [[0; 8]; 8 * 64], dummy_pre_push, const); // Uses 32 KiB of stack! +define_div_rem!(div_rem_64, 64, sub_64, Vec::new(), vec_pre_push); // Uses up to 2 MiB of heap +#[cfg(debug_assertions)] +define_div_rem!(div_rem_128, 128, sub_128, Vec::new(), vec_pre_push); // Uses up to 8 MiB of heap + +impl U4096 { + /// Constructs a new [`U4096`] from a variable number of big-endian bytes. + pub(super) fn from_be_bytes(bytes: &[u8]) -> Result { + if bytes.len() > 4096/8 { return Err(()); } + let u64s = (bytes.len() + 7) / 8; + let mut res = [0; WORD_COUNT_4096]; + for i in 0..u64s { + let mut b = [0; 8]; + let pos = (u64s - i) * 8; + let start = bytes.len().saturating_sub(pos); + let end = bytes.len() + 8 - pos; + b[8 + start - end..].copy_from_slice(&bytes[start..end]); + res[i + WORD_COUNT_4096 - u64s] = u64::from_be_bytes(b); + } + Ok(U4096(res)) + } + + /// Naively multiplies `self` * `b` mod `m`, returning a new [`U4096`]. + /// + /// Fails iff m is 0 or self or b are greater than m. + #[cfg(debug_assertions)] + fn mulmod_naive(&self, b: &U4096, m: &U4096) -> Result { + if m.0 == [0; WORD_COUNT_4096] { return Err(()); } + if self > m || b > m { return Err(()); } + + let mul = mul_64(&self.0, &b.0); + + let mut m_zeros = [0; 128]; + m_zeros[WORD_COUNT_4096..].copy_from_slice(&m.0); + let (_, rem) = div_rem_128(&mul, &m_zeros)?; + let mut res = [0; WORD_COUNT_4096]; + debug_assert_eq!(&rem[..WORD_COUNT_4096], &[0; WORD_COUNT_4096]); + res.copy_from_slice(&rem[WORD_COUNT_4096..]); + Ok(U4096(res)) + } + + /// Calculates `self` ^ `exp` mod `m`, returning a new [`U4096`]. + /// + /// Fails iff m is 0, even, or self or b are greater than m. + pub(super) fn expmod_odd_mod(&self, mut exp: u32, m: &U4096) -> Result { + #![allow(non_camel_case_types)] + + if m.0 == [0; WORD_COUNT_4096] { return Err(()); } + if m.0[WORD_COUNT_4096 - 1] & 1 == 0 { return Err(()); } + if self > m { return Err(()); } + + let mut t = [0; WORD_COUNT_4096]; + if &m.0[..WORD_COUNT_4096 - 1] == &[0; WORD_COUNT_4096 - 1] && m.0[WORD_COUNT_4096 - 1] == 1 { + return Ok(U4096(t)); + } + t[WORD_COUNT_4096 - 1] = 1; + if exp == 0 { return Ok(U4096(t)); } + + // Because m is not even, using 2^4096 as the Montgomery R value is always safe - it is + // guaranteed to be co-prime with any non-even integer. + + type mul_ty = fn(&[u64], &[u64]) -> [u64; WORD_COUNT_4096 * 2]; + type sqr_ty = fn(&[u64]) -> [u64; WORD_COUNT_4096 * 2]; + type add_double_ty = fn(&[u64], &[u64]) -> ([u64; WORD_COUNT_4096 * 2], bool); + type sub_ty = fn(&[u64], &[u64]) -> ([u64; WORD_COUNT_4096], bool); + let (word_count, log_bits, mul, sqr, add_double, sub) = + if m.0[..WORD_COUNT_4096 / 2] == [0; WORD_COUNT_4096 / 2] { + if m.0[..WORD_COUNT_4096 * 3 / 4] == [0; WORD_COUNT_4096 * 3 / 4] { + fn mul_16_subarr(a: &[u64], b: &[u64]) -> [u64; WORD_COUNT_4096 * 2] { + debug_assert_eq!(a.len(), WORD_COUNT_4096); + debug_assert_eq!(b.len(), WORD_COUNT_4096); + debug_assert_eq!(&a[..WORD_COUNT_4096 * 3 / 4], &[0; WORD_COUNT_4096 * 3 / 4]); + debug_assert_eq!(&b[..WORD_COUNT_4096 * 3 / 4], &[0; WORD_COUNT_4096 * 3 / 4]); + let mut res = [0; WORD_COUNT_4096 * 2]; + res[WORD_COUNT_4096 + WORD_COUNT_4096 / 2..].copy_from_slice( + &mul_16(&a[WORD_COUNT_4096 * 3 / 4..], &b[WORD_COUNT_4096 * 3 / 4..])); + res + } + fn sqr_16_subarr(a: &[u64]) -> [u64; WORD_COUNT_4096 * 2] { + debug_assert_eq!(a.len(), WORD_COUNT_4096); + debug_assert_eq!(&a[..WORD_COUNT_4096 * 3 / 4], &[0; WORD_COUNT_4096 * 3 / 4]); + let mut res = [0; WORD_COUNT_4096 * 2]; + res[WORD_COUNT_4096 + WORD_COUNT_4096 / 2..].copy_from_slice( + &sqr_16(&a[WORD_COUNT_4096 * 3 / 4..])); + res + } + fn add_32_subarr(a: &[u64], b: &[u64]) -> ([u64; WORD_COUNT_4096 * 2], bool) { + debug_assert_eq!(a.len(), WORD_COUNT_4096 * 2); + debug_assert_eq!(b.len(), WORD_COUNT_4096 * 2); + debug_assert_eq!(&a[..WORD_COUNT_4096 * 3 / 2], &[0; WORD_COUNT_4096 * 3 / 2]); + debug_assert_eq!(&b[..WORD_COUNT_4096 * 3 / 2], &[0; WORD_COUNT_4096 * 3 / 2]); + let (add, overflow) = add_32(&a[WORD_COUNT_4096 * 3 / 2..], &b[WORD_COUNT_4096 * 3 / 2..]); + let mut res = [0; WORD_COUNT_4096 * 2]; + res[WORD_COUNT_4096 * 3 / 2..].copy_from_slice(&add); + (res, overflow) + } + fn sub_16_subarr(a: &[u64], b: &[u64]) -> ([u64; WORD_COUNT_4096], bool) { + debug_assert_eq!(a.len(), WORD_COUNT_4096); + debug_assert_eq!(b.len(), WORD_COUNT_4096); + debug_assert_eq!(&a[..WORD_COUNT_4096 * 3 / 4], &[0; WORD_COUNT_4096 * 3 / 4]); + debug_assert_eq!(&b[..WORD_COUNT_4096 * 3 / 4], &[0; WORD_COUNT_4096 * 3 / 4]); + let (sub, underflow) = sub_16(&a[WORD_COUNT_4096 * 3 / 4..], &b[WORD_COUNT_4096 * 3 / 4..]); + let mut res = [0; WORD_COUNT_4096]; + res[WORD_COUNT_4096 * 3 / 4..].copy_from_slice(&sub); + (res, underflow) + } + (16, 10, mul_16_subarr as mul_ty, sqr_16_subarr as sqr_ty, add_32_subarr as add_double_ty, sub_16_subarr as sub_ty) + } else { + fn mul_32_subarr(a: &[u64], b: &[u64]) -> [u64; WORD_COUNT_4096 * 2] { + debug_assert_eq!(a.len(), WORD_COUNT_4096); + debug_assert_eq!(b.len(), WORD_COUNT_4096); + debug_assert_eq!(&a[..WORD_COUNT_4096 / 2], &[0; WORD_COUNT_4096 / 2]); + debug_assert_eq!(&b[..WORD_COUNT_4096 / 2], &[0; WORD_COUNT_4096 / 2]); + let mut res = [0; WORD_COUNT_4096 * 2]; + res[WORD_COUNT_4096..].copy_from_slice( + &mul_32(&a[WORD_COUNT_4096 / 2..], &b[WORD_COUNT_4096 / 2..])); + res + } + fn sqr_32_subarr(a: &[u64]) -> [u64; WORD_COUNT_4096 * 2] { + debug_assert_eq!(a.len(), WORD_COUNT_4096); + debug_assert_eq!(&a[..WORD_COUNT_4096 / 2], &[0; WORD_COUNT_4096 / 2]); + let mut res = [0; WORD_COUNT_4096 * 2]; + res[WORD_COUNT_4096..].copy_from_slice( + &sqr_32(&a[WORD_COUNT_4096 / 2..])); + res + } + fn add_64_subarr(a: &[u64], b: &[u64]) -> ([u64; WORD_COUNT_4096 * 2], bool) { + debug_assert_eq!(a.len(), WORD_COUNT_4096 * 2); + debug_assert_eq!(b.len(), WORD_COUNT_4096 * 2); + debug_assert_eq!(&a[..WORD_COUNT_4096], &[0; WORD_COUNT_4096]); + debug_assert_eq!(&b[..WORD_COUNT_4096], &[0; WORD_COUNT_4096]); + let (add, overflow) = add_64(&a[WORD_COUNT_4096..], &b[WORD_COUNT_4096..]); + let mut res = [0; WORD_COUNT_4096 * 2]; + res[WORD_COUNT_4096..].copy_from_slice(&add); + (res, overflow) + } + fn sub_32_subarr(a: &[u64], b: &[u64]) -> ([u64; WORD_COUNT_4096], bool) { + debug_assert_eq!(a.len(), WORD_COUNT_4096); + debug_assert_eq!(b.len(), WORD_COUNT_4096); + debug_assert_eq!(&a[..WORD_COUNT_4096 / 2], &[0; WORD_COUNT_4096 / 2]); + debug_assert_eq!(&b[..WORD_COUNT_4096 / 2], &[0; WORD_COUNT_4096 / 2]); + let (sub, underflow) = sub_32(&a[WORD_COUNT_4096 / 2..], &b[WORD_COUNT_4096 / 2..]); + let mut res = [0; WORD_COUNT_4096]; + res[WORD_COUNT_4096 / 2..].copy_from_slice(&sub); + (res, underflow) + } + (32, 11, mul_32_subarr as mul_ty, sqr_32_subarr as sqr_ty, add_64_subarr as add_double_ty, sub_32_subarr as sub_ty) + } + } else { + (64, 12, mul_64 as mul_ty, sqr_64 as sqr_ty, add_128 as add_double_ty, sub_64 as sub_ty) + }; + + let mut r = [0; WORD_COUNT_4096 * 2]; + r[WORD_COUNT_4096 * 2 - word_count - 1] = 1; + + let mut m_inv_pos = [0; WORD_COUNT_4096]; + m_inv_pos[WORD_COUNT_4096 - 1] = 1; + let mut two = [0; WORD_COUNT_4096]; + two[WORD_COUNT_4096 - 1] = 2; + for _ in 0..log_bits { + let mut m_m_inv = mul(&m_inv_pos, &m.0); + m_m_inv[..WORD_COUNT_4096 * 2 - word_count].fill(0); + let m_inv = mul(&sub(&two, &m_m_inv[WORD_COUNT_4096..]).0, &m_inv_pos); + m_inv_pos[WORD_COUNT_4096 - word_count..].copy_from_slice(&m_inv[WORD_COUNT_4096 * 2 - word_count..]); + } + m_inv_pos[..WORD_COUNT_4096 - word_count].fill(0); + + // We want the negative modular inverse of m mod R, so subtract m_inv from R. + let mut m_inv = m_inv_pos; + negate!(m_inv); + m_inv[..WORD_COUNT_4096 - word_count].fill(0); + debug_assert_eq!(&mul(&m_inv, &m.0)[WORD_COUNT_4096 * 2 - word_count..], + // R - 1 == -1 % R + &[0xffff_ffff_ffff_ffff; WORD_COUNT_4096][WORD_COUNT_4096 - word_count..]); + + debug_assert_eq!(&m_inv[..WORD_COUNT_4096 - word_count], &[0; WORD_COUNT_4096][..WORD_COUNT_4096 - word_count]); + + let mont_reduction = |mu: [u64; WORD_COUNT_4096 * 2]| -> [u64; WORD_COUNT_4096] { + debug_assert_eq!(&mu[..WORD_COUNT_4096 * 2 - word_count * 2], + &[0; WORD_COUNT_4096 * 2][..WORD_COUNT_4096 * 2 - word_count * 2]); + let mut mu_mod_r = [0; WORD_COUNT_4096]; + mu_mod_r[WORD_COUNT_4096 - word_count..].copy_from_slice(&mu[WORD_COUNT_4096 * 2 - word_count..]); + let mut v = mul(&mu_mod_r, &m_inv); + v[..WORD_COUNT_4096 * 2 - word_count].fill(0); // mod R + let t0 = mul(&v[WORD_COUNT_4096..], &m.0); + let (t1, t1_extra_bit) = add_double(&t0, &mu); + let mut t1_on_r = [0; WORD_COUNT_4096]; + debug_assert_eq!(&t1[WORD_COUNT_4096 * 2 - word_count..], &[0; WORD_COUNT_4096][WORD_COUNT_4096 - word_count..], + "t1 should be divisible by r"); + t1_on_r[WORD_COUNT_4096 - word_count..].copy_from_slice(&t1[WORD_COUNT_4096 * 2 - word_count * 2..WORD_COUNT_4096 * 2 - word_count]); + if t1_extra_bit || t1_on_r >= m.0 { + let underflow; + (t1_on_r, underflow) = sub(&t1_on_r, &m.0); + debug_assert_eq!(t1_extra_bit, underflow); + } + t1_on_r + }; + + // Calculate R^2 mod m as ((2^DOUBLES * R) mod m)^(log_bits - LOG2_DOUBLES) mod R + let mut r_minus_one = [0xffff_ffff_ffff_ffffu64; WORD_COUNT_4096]; + r_minus_one[..WORD_COUNT_4096 - word_count].fill(0); + // While we do a full div here, in general R should be less than 2x m (assuming the RSA + // modulus used its full bit range and is 1024, 2048, or 4096 bits), so it should be cheap. + // In cases with a nonstandard RSA modulus we may end up being pretty slow here, but we'll + // survive. + // If we ever find a problem with this we should reduce R to be tigher on m, as we're + // wasting extra bits of calculation if R is too far from m. + let (_, mut r_mod_m) = debug_unwrap!(div_rem_64(&r_minus_one, &m.0)); + let r_mod_m_overflow = add_one!(r_mod_m); + if r_mod_m_overflow || r_mod_m >= m.0 { + (r_mod_m, _) = sub_64(&r_mod_m, &m.0); + } + + let mut r2_mod_m: [u64; 64] = r_mod_m; + const DOUBLES: usize = 32; + const LOG2_DOUBLES: usize = 5; + + for _ in 0..DOUBLES { + let overflow = double!(r2_mod_m); + if overflow || r2_mod_m > m.0 { + (r2_mod_m, _) = sub_64(&r2_mod_m, &m.0); + } + } + for _ in 0..log_bits - LOG2_DOUBLES { + r2_mod_m = mont_reduction(sqr(&r2_mod_m)); + } + // Clear excess high bits + for (m_limb, r2_limb) in m.0.iter().zip(r2_mod_m.iter_mut()) { + let clear_bits = m_limb.leading_zeros(); + if clear_bits == 0 { break; } + *r2_limb &= !(0xffff_ffff_ffff_ffffu64 << (64 - clear_bits)); + if *m_limb != 0 { break; } + } + debug_assert!(r2_mod_m < m.0); + + // Calculate t * R and a * R as mont multiplications by R^2 mod m + let mut tr = mont_reduction(mul(&r2_mod_m, &t)); + let mut ar = mont_reduction(mul(&r2_mod_m, &self.0)); + + #[cfg(debug_assertions)] { + debug_assert_eq!(r2_mod_m, U4096(r_mod_m).mulmod_naive(&U4096(r_mod_m), &m).unwrap().0); + debug_assert_eq!(&tr, &U4096(t).mulmod_naive(&U4096(r_mod_m), &m).unwrap().0); + debug_assert_eq!(&ar, &self.mulmod_naive(&U4096(r_mod_m), &m).unwrap().0); + } + + while exp != 1 { + if exp % 2 == 1 { + tr = mont_reduction(mul(&tr, &ar)); + exp -= 1; + } + ar = mont_reduction(sqr(&ar)); + exp /= 2; + } + ar = mont_reduction(mul(&ar, &tr)); + let mut resr = [0; WORD_COUNT_4096 * 2]; + resr[WORD_COUNT_4096..].copy_from_slice(&ar); + Ok(U4096(mont_reduction(resr))) + } +} + +#[cfg(fuzzing)] +extern crate ibig; +#[cfg(fuzzing)] +/// Read some bytes and use them to test bigint math by comparing results against the `ibig` crate. +pub fn fuzz_math(input: &[u8]) { + if input.len() < 32 || input.len() % 16 != 0 { return; } + let split = core::cmp::min(input.len() / 2, 512); + let (a, b) = input.split_at(core::cmp::min(input.len() / 2, 512)); + let b = &b[..split]; + + let ai = ibig::UBig::from_be_bytes(&a); + let bi = ibig::UBig::from_be_bytes(&b); + + let mut a_u64s = Vec::with_capacity(split / 8); + for chunk in a.chunks(8) { + a_u64s.push(u64::from_be_bytes(chunk.try_into().unwrap())); + } + let mut b_u64s = Vec::with_capacity(split / 8); + for chunk in b.chunks(8) { + b_u64s.push(u64::from_be_bytes(chunk.try_into().unwrap())); + } + + macro_rules! test { ($mul: ident, $sqr: ident, $add: ident, $sub: ident, $div_rem: ident) => { + let res = $mul(&a_u64s, &b_u64s); + let mut res_bytes = Vec::with_capacity(input.len() / 2); + for i in res { + res_bytes.extend_from_slice(&i.to_be_bytes()); + } + assert_eq!(ibig::UBig::from_be_bytes(&res_bytes), ai.clone() * bi.clone()); + + debug_assert_eq!($mul(&a_u64s, &a_u64s), $sqr(&a_u64s)); + debug_assert_eq!($mul(&b_u64s, &b_u64s), $sqr(&b_u64s)); + + let (res, carry) = $add(&a_u64s, &b_u64s); + let mut res_bytes = Vec::with_capacity(input.len() / 2 + 1); + if carry { res_bytes.push(1); } else { res_bytes.push(0); } + for i in res { + res_bytes.extend_from_slice(&i.to_be_bytes()); + } + assert_eq!(ibig::UBig::from_be_bytes(&res_bytes), ai.clone() + bi.clone()); + + let mut add_u64s = a_u64s.clone(); + let carry = add_one!(add_u64s); + let mut res_bytes = Vec::with_capacity(input.len() / 2 + 1); + if carry { res_bytes.push(1); } else { res_bytes.push(0); } + for i in &add_u64s { + res_bytes.extend_from_slice(&i.to_be_bytes()); + } + assert_eq!(ibig::UBig::from_be_bytes(&res_bytes), ai.clone() + 1); + + let mut double_u64s = b_u64s.clone(); + let carry = double!(double_u64s); + let mut res_bytes = Vec::with_capacity(input.len() / 2 + 1); + if carry { res_bytes.push(1); } else { res_bytes.push(0); } + for i in &double_u64s { + res_bytes.extend_from_slice(&i.to_be_bytes()); + } + assert_eq!(ibig::UBig::from_be_bytes(&res_bytes), bi.clone() * 2); + + let (quot, rem) = if let Ok(res) = + $div_rem(&a_u64s[..].try_into().unwrap(), &b_u64s[..].try_into().unwrap()) { + res + } else { return }; + let mut quot_bytes = Vec::with_capacity(input.len() / 2); + for i in quot { + quot_bytes.extend_from_slice(&i.to_be_bytes()); + } + let mut rem_bytes = Vec::with_capacity(input.len() / 2); + for i in rem { + rem_bytes.extend_from_slice(&i.to_be_bytes()); + } + let (quoti, remi) = ibig::ops::DivRem::div_rem(ai.clone(), &bi); + assert_eq!(ibig::UBig::from_be_bytes("_bytes), quoti); + assert_eq!(ibig::UBig::from_be_bytes(&rem_bytes), remi); + } } + + if a_u64s.len() == 2 { + test!(mul_2, sqr_2, add_2, sub_2, div_rem_2); + } else if a_u64s.len() == 4 { + test!(mul_4, sqr_4, add_4, sub_4, div_rem_4); + } else if a_u64s.len() == 8 { + test!(mul_8, sqr_8, add_8, sub_8, div_rem_8); + } else if input.len() == 512*2 + 4 { + let mut e_bytes = [0; 4]; + e_bytes.copy_from_slice(&input[512 * 2..512 * 2 + 4]); + let e = u32::from_le_bytes(e_bytes); + let a = U4096::from_be_bytes(&a).unwrap(); + let b = U4096::from_be_bytes(&b).unwrap(); + + let res = if let Ok(r) = a.expmod_odd_mod(e, &b) { r } else { return }; + let mut res_bytes = Vec::with_capacity(512); + for i in res.0 { + res_bytes.extend_from_slice(&i.to_be_bytes()); + } + + let ring = ibig::modular::ModuloRing::new(&bi); + let ar = ring.from(ai.clone()); + assert_eq!(ar.pow(&e.into()).residue(), ibig::UBig::from_be_bytes(&res_bytes)); + } +} + +#[cfg(test)] +mod tests { + use super::*; + + #[test] + fn mul_min_simple_tests() { + let a = [1, 2]; + let b = [3, 4]; + let res = mul_2(&a, &b); + assert_eq!(res, [0, 3, 10, 8]); + + let a = [0x1bad_cafe_dead_beef, 2424]; + let b = [0x2bad_beef_dead_cafe, 4242]; + let res = mul_2(&a, &b); + assert_eq!(res, [340296855556511776, 15015369169016130186, 4248480538569992542, 10282608]); + + let a = [0xf6d9_f8eb_8b60_7a6d, 0x4b93_833e_2194_fc2e]; + let b = [0xfdab_0000_6952_8ab4, 0xd302_0000_8282_0000]; + let res = mul_2(&a, &b); + assert_eq!(res, [17625486516939878681, 18390748118453258282, 2695286104209847530, 1510594524414214144]); + + let a = [0x8b8b_8b8b_8b8b_8b8b, 0x8b8b_8b8b_8b8b_8b8b]; + let b = [0x8b8b_8b8b_8b8b_8b8b, 0x8b8b_8b8b_8b8b_8b8b]; + let res = mul_2(&a, &b); + assert_eq!(res, [5481115605507762349, 8230042173354675923, 16737530186064798, 15714555036048702841]); + + let a = [0x0000_0000_0000_0020, 0x002d_362c_005b_7753]; + let b = [0x0900_0000_0030_0003, 0xb708_00fe_0000_00cd]; + let res = mul_2(&a, &b); + assert_eq!(res, [1, 2306290405521702946, 17647397529888728169, 10271802099389861239]); + + let a = [0x0000_0000_7fff_ffff, 0xffff_ffff_0000_0000]; + let b = [0x0000_0800_0000_0000, 0x0000_1000_0000_00e1]; + let res = mul_2(&a, &b); + assert_eq!(res, [1024, 0, 483183816703, 18446743107341910016]); + + let a = [0xf6d9_f8eb_ebeb_eb6d, 0x4b93_83a0_bb35_0680]; + let b = [0xfd02_b9b9_b9b9_b9b9, 0xb9b9_b9b9_b9b9_b9b9]; + let res = mul_2(&a, &b); + assert_eq!(res, [17579814114991930107, 15033987447865175985, 488855932380801351, 5453318140933190272]); + + let a = [u64::MAX; 2]; + let b = [u64::MAX; 2]; + let res = mul_2(&a, &b); + assert_eq!(res, [18446744073709551615, 18446744073709551614, 0, 1]); + } + + #[test] + fn add_simple_tests() { + let a = [u64::MAX; 2]; + let b = [u64::MAX; 2]; + assert_eq!(add_2(&a, &b), ([18446744073709551615, 18446744073709551614], true)); + + let a = [0x1bad_cafe_dead_beef, 2424]; + let b = [0x2bad_beef_dead_cafe, 4242]; + assert_eq!(add_2(&a, &b), ([5141855058045667821, 6666], false)); + } + + #[test] + fn mul_4_simple_tests() { + let a = [1; 4]; + let b = [2; 4]; + assert_eq!(mul_4(&a, &b), + [0, 2, 4, 6, 8, 6, 4, 2]); + + let a = [0x1bad_cafe_dead_beef, 2424, 0x1bad_cafe_dead_beef, 2424]; + let b = [0x2bad_beef_dead_cafe, 4242, 0x2bad_beef_dead_cafe, 4242]; + assert_eq!(mul_4(&a, &b), + [340296855556511776, 15015369169016130186, 4929074249683016095, 11583994264332991364, + 8837257932696496860, 15015369169036695402, 4248480538569992542, 10282608]); + + let a = [u64::MAX; 4]; + let b = [u64::MAX; 4]; + assert_eq!(mul_4(&a, &b), + [18446744073709551615, 18446744073709551615, 18446744073709551615, + 18446744073709551614, 0, 0, 0, 1]); + } + + #[test] + fn double_simple_tests() { + let mut a = [0xfff5_b32d_01ff_0000, 0x00e7_e7e7_e7e7_e7e7]; + assert!(double!(a)); + assert_eq!(a, [18440945635998695424, 130551405668716494]); + + let mut a = [u64::MAX, u64::MAX]; + assert!(double!(a)); + assert_eq!(a, [18446744073709551615, 18446744073709551614]); + } +} diff --git a/src/crypto/mod.rs b/src/crypto/mod.rs index 4c501c8..06d13f2 100644 --- a/src/crypto/mod.rs +++ b/src/crypto/mod.rs @@ -19,4 +19,5 @@ //! does what we need without any unnecessary dependencies and with a very conservative MSRV //! policy. Thus we go ahead and use that for our hashing needs. +pub mod bigint; pub mod hash; diff --git a/src/http.rs b/src/http.rs index 51a6c20..ab162c9 100644 --- a/src/http.rs +++ b/src/http.rs @@ -2,6 +2,11 @@ #![deny(missing_docs)] +// const_slice_from_raw_parts was stabilized in 1.64, however we support building on 1.63 as well. +// Luckily, it seems to work fine in 1.63 with the feature flag (and RUSTC_BOOTSTRAP=1) enabled. +#![cfg_attr(feature = "validation", allow(stable_features))] +#![cfg_attr(feature = "validation", feature(const_slice_from_raw_parts))] + extern crate alloc; pub mod rr; diff --git a/src/lib.rs b/src/lib.rs index 6c9c577..f726320 100644 --- a/src/lib.rs +++ b/src/lib.rs @@ -24,21 +24,34 @@ //! * Finally, the crate can be built as a binary using the `build_server` feature, responding to //! queries over HTTP GET calls to `/dnssecproof?d=domain.name.&t=RecordType` with DNSSEC //! proofs. +//! +//! Note that this library's MSRV is 1.64 for normal building, however builds fine on 1.63 (and +//! possibly earlier) when `RUSTC_BOOTSTRAP=1` is set, as it relies on the +//! `const_slice_from_raw_parts` feature. #![deny(missing_docs)] #![deny(rustdoc::broken_intra_doc_links)] #![deny(rustdoc::private_intra_doc_links)] +// const_slice_from_raw_parts was stabilized in 1.64, however we support building on 1.63 as well. +// Luckily, it seems to work fine in 1.63 with the feature flag (and RUSTC_BOOTSTRAP=1) enabled. +#![allow(stable_features)] +#![feature(const_slice_from_raw_parts)] + #![cfg_attr(not(feature = "std"), no_std)] extern crate alloc; +#[cfg(feature = "validation")] +mod base32; + +#[cfg(all(feature = "validation", fuzzing))] +pub mod crypto; +#[cfg(all(feature = "validation", not(fuzzing)))] +mod crypto; + pub mod rr; pub mod ser; pub mod query; -#[cfg(feature = "validation")] -mod base32; -#[cfg(feature = "validation")] -mod crypto; #[cfg(feature = "validation")] pub mod validation; diff --git a/test.sh b/test.sh index 0da6120..9572653 100755 --- a/test.sh +++ b/test.sh @@ -1,5 +1,6 @@ #!/bin/sh set -eox +export RUSTC_BOOTSTRAP=1 cargo test --no-default-features cargo test cargo test --no-default-features --features std