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Add tests for the premise of the Schnorr contract to the Schnorr crate
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commit
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6 changed files with 136 additions and 85 deletions
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@ -21,15 +21,16 @@ sha3 = { version = "0.10", default-features = false, features = ["std"] }
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group = { version = "0.13", default-features = false, features = ["alloc"] }
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k256 = { version = "^0.13.1", default-features = false, features = ["std", "arithmetic"] }
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alloy-sol-types = { version = "0.8", default-features = false }
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[build-dependencies]
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build-solidity-contracts = { path = "../build-contracts", version = "0.1" }
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[dev-dependencies]
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rand_core = { version = "0.6", default-features = false, features = ["std"] }
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k256 = { version = "^0.13.1", default-features = false, features = ["ecdsa"] }
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alloy-core = { version = "0.8", default-features = false }
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alloy-sol-types = { version = "0.8", default-features = false }
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alloy-simple-request-transport = { path = "../../../networks/ethereum/alloy-simple-request-transport", default-features = false }
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alloy-rpc-types-eth = { version = "0.3", default-features = false }
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@ -7,8 +7,9 @@ library Schnorr {
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uint256 constant private Q =
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0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEBAAEDCE6AF48A03BBFD25E8CD0364141;
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// We fix the key to have an even y coordinate to save a word when verifying
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// signatures. This is comparable to Bitcoin Taproot's encoding of keys
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// We fix the key to have:
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// 1) An even y-coordinate
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// 2) An x-coordinate < Q
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uint8 constant private KEY_PARITY = 27;
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// px := public key x-coordinate, where the public key has an even y-coordinate
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@ -27,11 +28,17 @@ library Schnorr {
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bytes32 sa = bytes32(Q - mulmod(uint256(s), uint256(px), Q));
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bytes32 ca = bytes32(Q - mulmod(uint256(c), uint256(px), Q));
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// For safety, we want each input to ecrecover to not be 0 (sa, px, ca)
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// The ecrecover precompile checks `r` and `s` (`px` and `ca`) are non-zero
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// That leaves us to check `sa` are non-zero
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if (sa == 0) return false;
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/*
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The ecrecover precompile checks `r` and `s` (`px` and `ca`) are non-zero,
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banning the two keys with zero for their x-coordinate and zero challenge.
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Each has negligible probability of occuring (assuming zero x-coordinates
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are even on-curve in the first place).
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`sa` is not checked to be non-zero yet it does not need to be. The inverse
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of it is never taken.
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*/
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address R = ecrecover(sa, KEY_PARITY, px, ca);
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// The ecrecover failed
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if (R == address(0)) return false;
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// Check the signature is correct by rebuilding the challenge
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@ -37,7 +37,13 @@ impl PublicKey {
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None?;
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}
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Some(PublicKey { A, x_coordinate: x_coordinate.into() })
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let x_coordinate: [u8; 32] = x_coordinate.into();
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// Returns None if the x-coordinate is 0
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// Such keys will never have their signatures able to be verified
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if x_coordinate == [0; 32] {
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None?;
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}
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Some(PublicKey { A, x_coordinate })
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}
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/// The point for this public key.
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@ -17,6 +17,8 @@ use alloy_node_bindings::{Anvil, AnvilInstance};
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use crate::{PublicKey, Signature};
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mod premise;
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#[expect(warnings)]
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#[expect(needless_pass_by_value)]
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#[expect(clippy::all)]
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111
networks/ethereum/schnorr/src/tests/premise.rs
Normal file
111
networks/ethereum/schnorr/src/tests/premise.rs
Normal file
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@ -0,0 +1,111 @@
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use rand_core::{RngCore, OsRng};
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use sha3::{Digest, Keccak256};
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use group::ff::{Field, PrimeField};
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use k256::{
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elliptic_curve::{ops::Reduce, point::AffineCoordinates, sec1::ToEncodedPoint},
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ecdsa::{
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self, hazmat::SignPrimitive, signature::hazmat::PrehashVerifier, SigningKey, VerifyingKey,
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},
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U256, Scalar, ProjectivePoint,
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};
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use alloy_core::primitives::Address;
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use crate::{PublicKey, Signature};
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// The ecrecover opcode, yet with if the y is odd replacing v
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fn ecrecover(message: Scalar, odd_y: bool, r: Scalar, s: Scalar) -> Option<[u8; 20]> {
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let sig = ecdsa::Signature::from_scalars(r, s).ok()?;
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let message: [u8; 32] = message.to_repr().into();
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alloy_core::primitives::Signature::from_signature_and_parity(
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sig,
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alloy_core::primitives::Parity::Parity(odd_y),
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)
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.ok()?
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.recover_address_from_prehash(&alloy_core::primitives::B256::from(message))
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.ok()
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.map(Into::into)
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}
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// Test ecrecover behaves as expected
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#[test]
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fn test_ecrecover() {
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let private = SigningKey::random(&mut OsRng);
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let public = VerifyingKey::from(&private);
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// Sign the signature
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const MESSAGE: &[u8] = b"Hello, World!";
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let (sig, recovery_id) = private
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.as_nonzero_scalar()
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.try_sign_prehashed(Scalar::random(&mut OsRng), &Keccak256::digest(MESSAGE))
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.unwrap();
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// Sanity check the signature verifies
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#[allow(clippy::unit_cmp)] // Intended to assert this wasn't changed to Result<bool>
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{
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assert_eq!(public.verify_prehash(&Keccak256::digest(MESSAGE), &sig).unwrap(), ());
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}
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// Perform the ecrecover
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assert_eq!(
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ecrecover(
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<Scalar as Reduce<U256>>::reduce_bytes(&Keccak256::digest(MESSAGE)),
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u8::from(recovery_id.unwrap().is_y_odd()) == 1,
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*sig.r(),
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*sig.s()
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)
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.unwrap(),
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Address::from_raw_public_key(&public.to_encoded_point(false).as_ref()[1 ..]),
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);
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}
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// Test that we can recover the nonce from a Schnorr signature via a call to ecrecover, the premise
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// of efficiently verifying Schnorr signatures in an Ethereum contract
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#[test]
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fn nonce_recovery_via_ecrecover() {
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let (key, public_key) = loop {
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let key = Scalar::random(&mut OsRng);
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if let Some(public_key) = PublicKey::new(ProjectivePoint::GENERATOR * key) {
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break (key, public_key);
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}
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};
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let nonce = Scalar::random(&mut OsRng);
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let R = ProjectivePoint::GENERATOR * nonce;
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let mut message = vec![0; 1 + usize::try_from(OsRng.next_u32() % 256).unwrap()];
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OsRng.fill_bytes(&mut message);
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let c = Signature::challenge(R, &public_key, &message);
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let s = nonce + (c * key);
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/*
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An ECDSA signature is `(r, s)` with `s = (H(m) + rx) / k`, where:
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- `m` is the message
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- `r` is the x-coordinate of the nonce, reduced into a scalar
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- `x` is the private key
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- `k` is the nonce
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We fix the recovery ID to be for the even key with an x-coordinate < the order. Accordingly,
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`kG = Point::from(Even, r)`. This enables recovering the public key via
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`((s Point::from(Even, r)) - H(m)G) / r`.
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We want to calculate `R` from `(c, s)` where `s = r + cx`. That means we need to calculate
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`sG - cX`.
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We can calculate `sG - cX` with `((s Point::from(Even, r)) - H(m)G) / r` if:
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- Latter `r` = `X.x`
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- Latter `s` = `c`
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- `H(m)` = former `s`
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This gets us to `(cX - sG) / X.x`. If we additionally scale the latter's `s, H(m)` values (the
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former's `c, s` values) by `X.x`, we get `cX - sG`. This just requires negating each to achieve
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`sG - cX`.
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*/
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let x_scalar = <Scalar as Reduce<U256>>::reduce_bytes(&public_key.point().to_affine().x());
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let sa = -(s * x_scalar);
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let ca = -(c * x_scalar);
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let q = ecrecover(sa, false, x_scalar, ca).unwrap();
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assert_eq!(q, Address::from_raw_public_key(&R.to_encoded_point(false).as_ref()[1 ..]));
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}
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@ -16,54 +16,6 @@ use frost::{
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use crate::{crypto::*, tests::key_gen};
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// The ecrecover opcode, yet with parity replacing v
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pub(crate) fn ecrecover(message: Scalar, odd_y: bool, r: Scalar, s: Scalar) -> Option<[u8; 20]> {
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let sig = ecdsa::Signature::from_scalars(r, s).ok()?;
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let message: [u8; 32] = message.to_repr().into();
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alloy_core::primitives::Signature::from_signature_and_parity(
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sig,
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alloy_core::primitives::Parity::Parity(odd_y),
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)
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.ok()?
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.recover_address_from_prehash(&alloy_core::primitives::B256::from(message))
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.ok()
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.map(Into::into)
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}
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#[test]
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fn test_ecrecover() {
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let private = SigningKey::random(&mut OsRng);
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let public = VerifyingKey::from(&private);
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// Sign the signature
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const MESSAGE: &[u8] = b"Hello, World!";
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let (sig, recovery_id) = private
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.as_nonzero_scalar()
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.try_sign_prehashed(
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<Secp256k1 as Ciphersuite>::F::random(&mut OsRng),
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&keccak256(MESSAGE).into(),
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)
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.unwrap();
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// Sanity check the signature verifies
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#[allow(clippy::unit_cmp)] // Intended to assert this wasn't changed to Result<bool>
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{
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assert_eq!(public.verify_prehash(&keccak256(MESSAGE), &sig).unwrap(), ());
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}
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// Perform the ecrecover
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assert_eq!(
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ecrecover(
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hash_to_scalar(MESSAGE),
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u8::from(recovery_id.unwrap().is_y_odd()) == 1,
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*sig.r(),
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*sig.s()
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)
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.unwrap(),
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address(&ProjectivePoint::from(public.as_affine()))
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);
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}
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// Run the sign test with the EthereumHram
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#[test]
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fn test_signing() {
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@ -75,31 +27,3 @@ fn test_signing() {
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let _sig =
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sign(&mut OsRng, &algo, keys.clone(), algorithm_machines(&mut OsRng, &algo, &keys), MESSAGE);
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}
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#[allow(non_snake_case)]
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pub fn preprocess_signature_for_ecrecover(
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R: ProjectivePoint,
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public_key: &PublicKey,
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m: &[u8],
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s: Scalar,
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) -> (Scalar, Scalar) {
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let c = EthereumHram::hram(&R, &public_key.A, m);
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let sa = -(s * public_key.px);
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let ca = -(c * public_key.px);
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(sa, ca)
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}
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#[test]
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fn test_ecrecover_hack() {
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let (keys, public_key) = key_gen();
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const MESSAGE: &[u8] = b"Hello, World!";
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let algo = IetfSchnorr::<Secp256k1, EthereumHram>::ietf();
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let sig =
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sign(&mut OsRng, &algo, keys.clone(), algorithm_machines(&mut OsRng, &algo, &keys), MESSAGE);
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let (sa, ca) = preprocess_signature_for_ecrecover(sig.R, &public_key, MESSAGE, sig.s);
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let q = ecrecover(sa, false, public_key.px, ca).unwrap();
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assert_eq!(q, address(&sig.R));
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}
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