serai/coins/bitcoin/src/crypto.rs
Luke Parker 79aff5d4c8
ff 0.13 (#269)
* Partial move to ff 0.13

It turns out the newly released k256 0.12 isn't on ff 0.13, preventing further
work at this time.

* Update all crates to work on ff 0.13

The provided curves still need to be expanded to fit the new API.

* Finish adding dalek-ff-group ff 0.13 constants

* Correct FieldElement::product definition

Also stops exporting macros.

* Test most new parts of ff 0.13

* Additionally test ff-group-tests with BLS12-381 and the pasta curves

We only tested curves from RustCrypto. Now we test a curve offered by zk-crypto,
the group behind ff/group, and the pasta curves, which is by Zcash (though
Zcash developers are also behind zk-crypto).

* Finish Ed448

Fully specifies all constants, passes all tests in ff-group-tests, and finishes moving to ff-0.13.

* Add RustCrypto/elliptic-curves to allowed git repos

Needed due to k256/p256 incorrectly defining product.

* Finish writing ff 0.13 tests

* Add additional comments to dalek

* Further comments

* Update ethereum-serai to ff 0.13
2023-03-28 04:38:01 -04:00

160 lines
4.4 KiB
Rust

use core::fmt::Debug;
use std::io;
use lazy_static::lazy_static;
use zeroize::Zeroizing;
use rand_core::{RngCore, CryptoRng};
use sha2::{Digest, Sha256};
use transcript::Transcript;
use secp256k1::schnorr::Signature;
use k256::{
elliptic_curve::{
ops::Reduce,
sec1::{Tag, ToEncodedPoint},
},
U256, Scalar, ProjectivePoint,
};
use frost::{
curve::{Ciphersuite, Secp256k1},
Participant, ThresholdKeys, ThresholdView, FrostError,
algorithm::{Hram as HramTrait, Algorithm, Schnorr as FrostSchnorr},
};
use bitcoin::XOnlyPublicKey;
/// Get the x coordinate of a non-infinity, even point. Panics on invalid input.
pub fn x(key: &ProjectivePoint) -> [u8; 32] {
let encoded = key.to_encoded_point(true);
assert_eq!(encoded.tag(), Tag::CompressedEvenY, "x coordinate of odd key");
(*encoded.x().expect("point at infinity")).into()
}
/// Convert a non-infinite even point to a XOnlyPublicKey. Panics on invalid input.
pub fn x_only(key: &ProjectivePoint) -> XOnlyPublicKey {
XOnlyPublicKey::from_slice(&x(key)).unwrap()
}
/// Make a point even by adding the generator until it is even. Returns the even point and the
/// amount of additions required.
pub fn make_even(mut key: ProjectivePoint) -> (ProjectivePoint, u64) {
let mut c = 0;
while key.to_encoded_point(true).tag() == Tag::CompressedOddY {
key += ProjectivePoint::GENERATOR;
c += 1;
}
(key, c)
}
/// A BIP-340 compatible HRAm for use with the modular-frost Schnorr Algorithm.
///
/// If passed an odd nonce, it will have the generator added until it is even.
#[derive(Clone, Copy, Debug)]
pub struct Hram {}
lazy_static! {
static ref TAG_HASH: [u8; 32] = Sha256::digest(b"BIP0340/challenge").into();
}
#[allow(non_snake_case)]
impl HramTrait<Secp256k1> for Hram {
fn hram(R: &ProjectivePoint, A: &ProjectivePoint, m: &[u8]) -> Scalar {
// Convert the nonce to be even
let (R, _) = make_even(*R);
let mut data = Sha256::new();
data.update(*TAG_HASH);
data.update(*TAG_HASH);
data.update(x(&R));
data.update(x(A));
data.update(m);
Scalar::reduce(U256::from_be_slice(&data.finalize()))
}
}
/// BIP-340 Schnorr signature algorithm.
///
/// This must be used with a ThresholdKeys whose group key is even. If it is odd, this will panic.
#[derive(Clone)]
pub struct Schnorr<T: Sync + Clone + Debug + Transcript>(FrostSchnorr<Secp256k1, T, Hram>);
impl<T: Sync + Clone + Debug + Transcript> Schnorr<T> {
/// Construct a Schnorr algorithm continuing the specified transcript.
pub fn new(transcript: T) -> Schnorr<T> {
Schnorr(FrostSchnorr::new(transcript))
}
}
impl<T: Sync + Clone + Debug + Transcript> Algorithm<Secp256k1> for Schnorr<T> {
type Transcript = T;
type Addendum = ();
type Signature = Signature;
fn transcript(&mut self) -> &mut Self::Transcript {
self.0.transcript()
}
fn nonces(&self) -> Vec<Vec<ProjectivePoint>> {
self.0.nonces()
}
fn preprocess_addendum<R: RngCore + CryptoRng>(
&mut self,
rng: &mut R,
keys: &ThresholdKeys<Secp256k1>,
) {
self.0.preprocess_addendum(rng, keys)
}
fn read_addendum<R: io::Read>(&self, reader: &mut R) -> io::Result<Self::Addendum> {
self.0.read_addendum(reader)
}
fn process_addendum(
&mut self,
view: &ThresholdView<Secp256k1>,
i: Participant,
addendum: (),
) -> Result<(), FrostError> {
self.0.process_addendum(view, i, addendum)
}
fn sign_share(
&mut self,
params: &ThresholdView<Secp256k1>,
nonce_sums: &[Vec<<Secp256k1 as Ciphersuite>::G>],
nonces: Vec<Zeroizing<<Secp256k1 as Ciphersuite>::F>>,
msg: &[u8],
) -> <Secp256k1 as Ciphersuite>::F {
self.0.sign_share(params, nonce_sums, nonces, msg)
}
#[must_use]
fn verify(
&self,
group_key: ProjectivePoint,
nonces: &[Vec<ProjectivePoint>],
sum: Scalar,
) -> Option<Self::Signature> {
self.0.verify(group_key, nonces, sum).map(|mut sig| {
// Make the R of the final signature even
let offset;
(sig.R, offset) = make_even(sig.R);
// s = r + cx. Since we added to the r, add to s
sig.s += Scalar::from(offset);
// Convert to a secp256k1 signature
Signature::from_slice(&sig.serialize()[1 ..]).unwrap()
})
}
fn verify_share(
&self,
verification_share: ProjectivePoint,
nonces: &[Vec<ProjectivePoint>],
share: Scalar,
) -> Result<Vec<(Scalar, ProjectivePoint)>, ()> {
self.0.verify_share(verification_share, nonces, share)
}
}