#[cfg(feature = "serde")]
use crate::crypto::Ss58Codec;
use crate::crypto::{
CryptoBytes, DeriveError, DeriveJunction, Pair as TraitPair, SecretStringError,
};
#[cfg(feature = "full_crypto")]
use schnorrkel::signing_context;
use schnorrkel::{
derive::{ChainCode, Derivation, CHAIN_CODE_LENGTH},
ExpansionMode, Keypair, MiniSecretKey, PublicKey, SecretKey,
};
use sp_std::vec::Vec;
use crate::crypto::{CryptoType, CryptoTypeId, Derive, Public as TraitPublic, SignatureBytes};
use codec::{Decode, Encode, MaxEncodedLen};
use scale_info::TypeInfo;
use schnorrkel::keys::{MINI_SECRET_KEY_LENGTH, SECRET_KEY_LENGTH};
#[cfg(feature = "serde")]
use serde::{de, Deserialize, Deserializer, Serialize, Serializer};
#[cfg(feature = "std")]
use sp_runtime_interface::pass_by::PassByInner;
#[cfg(all(not(feature = "std"), feature = "serde"))]
use sp_std::alloc::{format, string::String};
const SIGNING_CTX: &[u8] = b"substrate";
pub const CRYPTO_ID: CryptoTypeId = CryptoTypeId(*b"sr25");
pub const PUBLIC_KEY_SERIALIZED_SIZE: usize = 32;
pub const SIGNATURE_SERIALIZED_SIZE: usize = 64;
#[doc(hidden)]
pub struct Sr25519Tag;
#[doc(hidden)]
pub struct Sr25519PublicTag;
pub type Public = CryptoBytes<PUBLIC_KEY_SERIALIZED_SIZE, Sr25519PublicTag>;
impl TraitPublic for Public {}
impl Derive for Public {
#[cfg(feature = "serde")]
fn derive<Iter: Iterator<Item = DeriveJunction>>(&self, path: Iter) -> Option<Public> {
let mut acc = PublicKey::from_bytes(self.as_ref()).ok()?;
for j in path {
match j {
DeriveJunction::Soft(cc) => acc = acc.derived_key_simple(ChainCode(cc), &[]).0,
DeriveJunction::Hard(_cc) => return None,
}
}
Some(Self::from(acc.to_bytes()))
}
}
#[cfg(feature = "std")]
impl std::str::FromStr for Public {
type Err = crate::crypto::PublicError;
fn from_str(s: &str) -> Result<Self, Self::Err> {
Self::from_ss58check(s)
}
}
#[cfg(feature = "std")]
impl std::fmt::Display for Public {
fn fmt(&self, f: &mut std::fmt::Formatter) -> std::fmt::Result {
write!(f, "{}", self.to_ss58check())
}
}
impl sp_std::fmt::Debug for Public {
#[cfg(feature = "std")]
fn fmt(&self, f: &mut sp_std::fmt::Formatter) -> sp_std::fmt::Result {
let s = self.to_ss58check();
write!(f, "{} ({}...)", crate::hexdisplay::HexDisplay::from(self.inner()), &s[0..8])
}
#[cfg(not(feature = "std"))]
fn fmt(&self, _: &mut sp_std::fmt::Formatter) -> sp_std::fmt::Result {
Ok(())
}
}
#[cfg(feature = "serde")]
impl Serialize for Public {
fn serialize<S>(&self, serializer: S) -> Result<S::Ok, S::Error>
where
S: Serializer,
{
serializer.serialize_str(&self.to_ss58check())
}
}
#[cfg(feature = "serde")]
impl<'de> Deserialize<'de> for Public {
fn deserialize<D>(deserializer: D) -> Result<Self, D::Error>
where
D: Deserializer<'de>,
{
Public::from_ss58check(&String::deserialize(deserializer)?)
.map_err(|e| de::Error::custom(format!("{:?}", e)))
}
}
pub type Signature = SignatureBytes<SIGNATURE_SERIALIZED_SIZE, Sr25519Tag>;
#[cfg(feature = "full_crypto")]
impl From<schnorrkel::Signature> for Signature {
fn from(s: schnorrkel::Signature) -> Signature {
Signature::from(s.to_bytes())
}
}
pub struct Pair(Keypair);
impl Clone for Pair {
fn clone(&self) -> Self {
Pair(schnorrkel::Keypair {
public: self.0.public,
secret: schnorrkel::SecretKey::from_bytes(&self.0.secret.to_bytes()[..])
.expect("key is always the correct size; qed"),
})
}
}
#[cfg(feature = "std")]
impl From<MiniSecretKey> for Pair {
fn from(sec: MiniSecretKey) -> Pair {
Pair(sec.expand_to_keypair(ExpansionMode::Ed25519))
}
}
#[cfg(feature = "std")]
impl From<SecretKey> for Pair {
fn from(sec: SecretKey) -> Pair {
Pair(Keypair::from(sec))
}
}
#[cfg(feature = "full_crypto")]
impl From<schnorrkel::Keypair> for Pair {
fn from(p: schnorrkel::Keypair) -> Pair {
Pair(p)
}
}
#[cfg(feature = "full_crypto")]
impl From<Pair> for schnorrkel::Keypair {
fn from(p: Pair) -> schnorrkel::Keypair {
p.0
}
}
#[cfg(feature = "full_crypto")]
impl AsRef<schnorrkel::Keypair> for Pair {
fn as_ref(&self) -> &schnorrkel::Keypair {
&self.0
}
}
fn derive_hard_junction(secret: &SecretKey, cc: &[u8; CHAIN_CODE_LENGTH]) -> MiniSecretKey {
secret.hard_derive_mini_secret_key(Some(ChainCode(*cc)), b"").0
}
type Seed = [u8; MINI_SECRET_KEY_LENGTH];
impl TraitPair for Pair {
type Public = Public;
type Seed = Seed;
type Signature = Signature;
fn public(&self) -> Public {
Public::from(self.0.public.to_bytes())
}
fn from_seed_slice(seed: &[u8]) -> Result<Pair, SecretStringError> {
match seed.len() {
MINI_SECRET_KEY_LENGTH => Ok(Pair(
MiniSecretKey::from_bytes(seed)
.map_err(|_| SecretStringError::InvalidSeed)?
.expand_to_keypair(ExpansionMode::Ed25519),
)),
SECRET_KEY_LENGTH => Ok(Pair(
SecretKey::from_bytes(seed)
.map_err(|_| SecretStringError::InvalidSeed)?
.to_keypair(),
)),
_ => Err(SecretStringError::InvalidSeedLength),
}
}
fn derive<Iter: Iterator<Item = DeriveJunction>>(
&self,
path: Iter,
seed: Option<Seed>,
) -> Result<(Pair, Option<Seed>), DeriveError> {
let seed = seed
.and_then(|s| MiniSecretKey::from_bytes(&s).ok())
.filter(|msk| msk.expand(ExpansionMode::Ed25519) == self.0.secret);
let init = self.0.secret.clone();
let (result, seed) = path.fold((init, seed), |(acc, acc_seed), j| match (j, acc_seed) {
(DeriveJunction::Soft(cc), _) => (acc.derived_key_simple(ChainCode(cc), &[]).0, None),
(DeriveJunction::Hard(cc), maybe_seed) => {
let seed = derive_hard_junction(&acc, &cc);
(seed.expand(ExpansionMode::Ed25519), maybe_seed.map(|_| seed))
},
});
Ok((Self(result.into()), seed.map(|s| MiniSecretKey::to_bytes(&s))))
}
#[cfg(feature = "full_crypto")]
fn sign(&self, message: &[u8]) -> Signature {
let context = signing_context(SIGNING_CTX);
self.0.sign(context.bytes(message)).into()
}
fn verify<M: AsRef<[u8]>>(sig: &Signature, message: M, pubkey: &Public) -> bool {
let Ok(signature) = schnorrkel::Signature::from_bytes(sig.as_ref()) else { return false };
let Ok(public) = PublicKey::from_bytes(pubkey.as_ref()) else { return false };
public.verify_simple(SIGNING_CTX, message.as_ref(), &signature).is_ok()
}
fn to_raw_vec(&self) -> Vec<u8> {
self.0.secret.to_bytes().to_vec()
}
}
#[cfg(feature = "std")]
impl Pair {
pub fn verify_deprecated<M: AsRef<[u8]>>(sig: &Signature, message: M, pubkey: &Public) -> bool {
match PublicKey::from_bytes(pubkey.as_ref()) {
Ok(pk) => pk
.verify_simple_preaudit_deprecated(SIGNING_CTX, message.as_ref(), &sig.0[..])
.is_ok(),
Err(_) => false,
}
}
}
impl CryptoType for Public {
type Pair = Pair;
}
impl CryptoType for Signature {
type Pair = Pair;
}
impl CryptoType for Pair {
type Pair = Pair;
}
pub mod vrf {
use super::*;
#[cfg(feature = "full_crypto")]
use crate::crypto::VrfSecret;
use crate::crypto::{VrfCrypto, VrfPublic};
use schnorrkel::{
errors::MultiSignatureStage,
vrf::{VRF_PREOUT_LENGTH, VRF_PROOF_LENGTH},
SignatureError,
};
const DEFAULT_EXTRA_DATA_LABEL: &[u8] = b"VRF";
#[derive(Clone)]
pub struct VrfTranscript(pub merlin::Transcript);
impl VrfTranscript {
pub fn new(label: &'static [u8], data: &[(&'static [u8], &[u8])]) -> Self {
let mut transcript = merlin::Transcript::new(label);
data.iter().for_each(|(l, b)| transcript.append_message(l, b));
VrfTranscript(transcript)
}
pub fn into_sign_data(self) -> VrfSignData {
self.into()
}
}
pub type VrfInput = VrfTranscript;
#[derive(Clone)]
pub struct VrfSignData {
pub(super) transcript: VrfTranscript,
pub(super) extra: Option<VrfTranscript>,
}
impl From<VrfInput> for VrfSignData {
fn from(transcript: VrfInput) -> Self {
VrfSignData { transcript, extra: None }
}
}
impl AsRef<VrfInput> for VrfSignData {
fn as_ref(&self) -> &VrfInput {
&self.transcript
}
}
impl VrfSignData {
pub fn new(input: VrfTranscript) -> Self {
input.into()
}
pub fn with_extra(mut self, extra: VrfTranscript) -> Self {
self.extra = Some(extra);
self
}
}
#[derive(Clone, Debug, PartialEq, Eq, Encode, Decode, MaxEncodedLen, TypeInfo)]
pub struct VrfSignature {
pub pre_output: VrfPreOutput,
pub proof: VrfProof,
}
#[derive(Clone, Debug, PartialEq, Eq)]
pub struct VrfPreOutput(pub schnorrkel::vrf::VRFPreOut);
impl Encode for VrfPreOutput {
fn encode(&self) -> Vec<u8> {
self.0.as_bytes().encode()
}
}
impl Decode for VrfPreOutput {
fn decode<R: codec::Input>(i: &mut R) -> Result<Self, codec::Error> {
let decoded = <[u8; VRF_PREOUT_LENGTH]>::decode(i)?;
Ok(Self(schnorrkel::vrf::VRFPreOut::from_bytes(&decoded).map_err(convert_error)?))
}
}
impl MaxEncodedLen for VrfPreOutput {
fn max_encoded_len() -> usize {
<[u8; VRF_PREOUT_LENGTH]>::max_encoded_len()
}
}
impl TypeInfo for VrfPreOutput {
type Identity = [u8; VRF_PREOUT_LENGTH];
fn type_info() -> scale_info::Type {
Self::Identity::type_info()
}
}
#[derive(Clone, Debug, PartialEq, Eq)]
pub struct VrfProof(pub schnorrkel::vrf::VRFProof);
impl Encode for VrfProof {
fn encode(&self) -> Vec<u8> {
self.0.to_bytes().encode()
}
}
impl Decode for VrfProof {
fn decode<R: codec::Input>(i: &mut R) -> Result<Self, codec::Error> {
let decoded = <[u8; VRF_PROOF_LENGTH]>::decode(i)?;
Ok(Self(schnorrkel::vrf::VRFProof::from_bytes(&decoded).map_err(convert_error)?))
}
}
impl MaxEncodedLen for VrfProof {
fn max_encoded_len() -> usize {
<[u8; VRF_PROOF_LENGTH]>::max_encoded_len()
}
}
impl TypeInfo for VrfProof {
type Identity = [u8; VRF_PROOF_LENGTH];
fn type_info() -> scale_info::Type {
Self::Identity::type_info()
}
}
#[cfg(feature = "full_crypto")]
impl VrfCrypto for Pair {
type VrfInput = VrfTranscript;
type VrfPreOutput = VrfPreOutput;
type VrfSignData = VrfSignData;
type VrfSignature = VrfSignature;
}
#[cfg(feature = "full_crypto")]
impl VrfSecret for Pair {
fn vrf_sign(&self, data: &Self::VrfSignData) -> Self::VrfSignature {
let inout = self.0.vrf_create_hash(data.transcript.0.clone());
let extra = data
.extra
.as_ref()
.map(|e| e.0.clone())
.unwrap_or_else(|| merlin::Transcript::new(DEFAULT_EXTRA_DATA_LABEL));
let proof = self.0.dleq_proove(extra, &inout, true).0;
VrfSignature { pre_output: VrfPreOutput(inout.to_preout()), proof: VrfProof(proof) }
}
fn vrf_pre_output(&self, input: &Self::VrfInput) -> Self::VrfPreOutput {
let pre_output = self.0.vrf_create_hash(input.0.clone()).to_preout();
VrfPreOutput(pre_output)
}
}
impl VrfCrypto for Public {
type VrfInput = VrfTranscript;
type VrfPreOutput = VrfPreOutput;
type VrfSignData = VrfSignData;
type VrfSignature = VrfSignature;
}
impl VrfPublic for Public {
fn vrf_verify(&self, data: &Self::VrfSignData, signature: &Self::VrfSignature) -> bool {
let do_verify = || {
let public = schnorrkel::PublicKey::from_bytes(&self.0)?;
let inout =
signature.pre_output.0.attach_input_hash(&public, data.transcript.0.clone())?;
let extra = data
.extra
.as_ref()
.map(|e| e.0.clone())
.unwrap_or_else(|| merlin::Transcript::new(DEFAULT_EXTRA_DATA_LABEL));
public.dleq_verify(extra, &inout, &signature.proof.0, true)
};
do_verify().is_ok()
}
}
fn convert_error(e: SignatureError) -> codec::Error {
use MultiSignatureStage::*;
use SignatureError::*;
match e {
EquationFalse => "Signature error: `EquationFalse`".into(),
PointDecompressionError => "Signature error: `PointDecompressionError`".into(),
ScalarFormatError => "Signature error: `ScalarFormatError`".into(),
NotMarkedSchnorrkel => "Signature error: `NotMarkedSchnorrkel`".into(),
BytesLengthError { .. } => "Signature error: `BytesLengthError`".into(),
InvalidKey => "Signature error: `InvalidKey`".into(),
MuSigAbsent { musig_stage: Commitment } =>
"Signature error: `MuSigAbsent` at stage `Commitment`".into(),
MuSigAbsent { musig_stage: Reveal } =>
"Signature error: `MuSigAbsent` at stage `Reveal`".into(),
MuSigAbsent { musig_stage: Cosignature } =>
"Signature error: `MuSigAbsent` at stage `Commitment`".into(),
MuSigInconsistent { musig_stage: Commitment, duplicate: true } =>
"Signature error: `MuSigInconsistent` at stage `Commitment` on duplicate".into(),
MuSigInconsistent { musig_stage: Commitment, duplicate: false } =>
"Signature error: `MuSigInconsistent` at stage `Commitment` on not duplicate".into(),
MuSigInconsistent { musig_stage: Reveal, duplicate: true } =>
"Signature error: `MuSigInconsistent` at stage `Reveal` on duplicate".into(),
MuSigInconsistent { musig_stage: Reveal, duplicate: false } =>
"Signature error: `MuSigInconsistent` at stage `Reveal` on not duplicate".into(),
MuSigInconsistent { musig_stage: Cosignature, duplicate: true } =>
"Signature error: `MuSigInconsistent` at stage `Cosignature` on duplicate".into(),
MuSigInconsistent { musig_stage: Cosignature, duplicate: false } =>
"Signature error: `MuSigInconsistent` at stage `Cosignature` on not duplicate"
.into(),
}
}
#[cfg(feature = "full_crypto")]
impl Pair {
pub fn make_bytes<const N: usize>(&self, context: &[u8], input: &VrfInput) -> [u8; N]
where
[u8; N]: Default,
{
let inout = self.0.vrf_create_hash(input.0.clone());
inout.make_bytes::<[u8; N]>(context)
}
}
impl Public {
pub fn make_bytes<const N: usize>(
&self,
context: &[u8],
input: &VrfInput,
pre_output: &VrfPreOutput,
) -> Result<[u8; N], codec::Error>
where
[u8; N]: Default,
{
let pubkey = schnorrkel::PublicKey::from_bytes(&self.0).map_err(convert_error)?;
let inout = pre_output
.0
.attach_input_hash(&pubkey, input.0.clone())
.map_err(convert_error)?;
Ok(inout.make_bytes::<[u8; N]>(context))
}
}
impl VrfPreOutput {
pub fn make_bytes<const N: usize>(
&self,
context: &[u8],
input: &VrfInput,
public: &Public,
) -> Result<[u8; N], codec::Error>
where
[u8; N]: Default,
{
public.make_bytes(context, input, self)
}
}
}
#[cfg(test)]
mod tests {
use super::{vrf::*, *};
use crate::{
crypto::{Ss58Codec, VrfPublic, VrfSecret, DEV_ADDRESS, DEV_PHRASE},
ByteArray as _,
};
use serde_json;
#[test]
fn derive_soft_known_pair_should_work() {
let pair = Pair::from_string(&format!("{}/Alice", DEV_PHRASE), None).unwrap();
let known = array_bytes::hex2bytes_unchecked(
"d6c71059dbbe9ad2b0ed3f289738b800836eb425544ce694825285b958ca755e",
);
assert_eq!(pair.public().to_raw_vec(), known);
}
#[test]
fn derive_hard_known_pair_should_work() {
let pair = Pair::from_string(&format!("{}//Alice", DEV_PHRASE), None).unwrap();
let known = array_bytes::hex2bytes_unchecked(
"d43593c715fdd31c61141abd04a99fd6822c8558854ccde39a5684e7a56da27d",
);
assert_eq!(pair.public().to_raw_vec(), known);
}
#[test]
fn verify_known_old_message_should_work() {
let public = Public::from_raw(array_bytes::hex2array_unchecked(
"b4bfa1f7a5166695eb75299fd1c4c03ea212871c342f2c5dfea0902b2c246918",
));
let signature = Signature::from_raw(array_bytes::hex2array_unchecked(
"5a9755f069939f45d96aaf125cf5ce7ba1db998686f87f2fb3cbdea922078741a73891ba265f70c31436e18a9acd14d189d73c12317ab6c313285cd938453202"
));
let message = b"Verifying that I am the owner of 5G9hQLdsKQswNPgB499DeA5PkFBbgkLPJWkkS6FAM6xGQ8xD. Hash: 221455a3\n";
assert!(Pair::verify_deprecated(&signature, &message[..], &public));
assert!(!Pair::verify(&signature, &message[..], &public));
}
#[test]
fn default_phrase_should_be_used() {
assert_eq!(
Pair::from_string("//Alice///password", None).unwrap().public(),
Pair::from_string(&format!("{}//Alice", DEV_PHRASE), Some("password"))
.unwrap()
.public(),
);
assert_eq!(
Pair::from_string(&format!("{}/Alice", DEV_PHRASE), None)
.as_ref()
.map(Pair::public),
Pair::from_string("/Alice", None).as_ref().map(Pair::public)
);
}
#[test]
fn default_address_should_be_used() {
assert_eq!(
Public::from_string(&format!("{}/Alice", DEV_ADDRESS)),
Public::from_string("/Alice")
);
}
#[test]
fn default_phrase_should_correspond_to_default_address() {
assert_eq!(
Pair::from_string(&format!("{}/Alice", DEV_PHRASE), None).unwrap().public(),
Public::from_string(&format!("{}/Alice", DEV_ADDRESS)).unwrap(),
);
assert_eq!(
Pair::from_string("/Alice", None).unwrap().public(),
Public::from_string("/Alice").unwrap()
);
}
#[test]
fn derive_soft_should_work() {
let pair = Pair::from_seed(&array_bytes::hex2array_unchecked(
"9d61b19deffd5a60ba844af492ec2cc44449c5697b326919703bac031cae7f60",
));
let derive_1 = pair.derive(Some(DeriveJunction::soft(1)).into_iter(), None).unwrap().0;
let derive_1b = pair.derive(Some(DeriveJunction::soft(1)).into_iter(), None).unwrap().0;
let derive_2 = pair.derive(Some(DeriveJunction::soft(2)).into_iter(), None).unwrap().0;
assert_eq!(derive_1.public(), derive_1b.public());
assert_ne!(derive_1.public(), derive_2.public());
}
#[test]
fn derive_hard_should_work() {
let pair = Pair::from_seed(&array_bytes::hex2array_unchecked(
"9d61b19deffd5a60ba844af492ec2cc44449c5697b326919703bac031cae7f60",
));
let derive_1 = pair.derive(Some(DeriveJunction::hard(1)).into_iter(), None).unwrap().0;
let derive_1b = pair.derive(Some(DeriveJunction::hard(1)).into_iter(), None).unwrap().0;
let derive_2 = pair.derive(Some(DeriveJunction::hard(2)).into_iter(), None).unwrap().0;
assert_eq!(derive_1.public(), derive_1b.public());
assert_ne!(derive_1.public(), derive_2.public());
}
#[test]
fn derive_soft_public_should_work() {
let pair = Pair::from_seed(&array_bytes::hex2array_unchecked(
"9d61b19deffd5a60ba844af492ec2cc44449c5697b326919703bac031cae7f60",
));
let path = Some(DeriveJunction::soft(1));
let pair_1 = pair.derive(path.into_iter(), None).unwrap().0;
let public_1 = pair.public().derive(path.into_iter()).unwrap();
assert_eq!(pair_1.public(), public_1);
}
#[test]
fn derive_hard_public_should_fail() {
let pair = Pair::from_seed(&array_bytes::hex2array_unchecked(
"9d61b19deffd5a60ba844af492ec2cc44449c5697b326919703bac031cae7f60",
));
let path = Some(DeriveJunction::hard(1));
assert!(pair.public().derive(path.into_iter()).is_none());
}
#[test]
fn sr_test_vector_should_work() {
let pair = Pair::from_seed(&array_bytes::hex2array_unchecked(
"9d61b19deffd5a60ba844af492ec2cc44449c5697b326919703bac031cae7f60",
));
let public = pair.public();
assert_eq!(
public,
Public::from_raw(array_bytes::hex2array_unchecked(
"44a996beb1eef7bdcab976ab6d2ca26104834164ecf28fb375600576fcc6eb0f"
))
);
let message = b"";
let signature = pair.sign(message);
assert!(Pair::verify(&signature, &message[..], &public));
}
#[test]
fn generate_with_phrase_should_be_recoverable_with_from_string() {
let (pair, phrase, seed) = Pair::generate_with_phrase(None);
let repair_seed = Pair::from_seed_slice(seed.as_ref()).expect("seed slice is valid");
assert_eq!(pair.public(), repair_seed.public());
assert_eq!(pair.to_raw_vec(), repair_seed.to_raw_vec());
let (repair_phrase, reseed) =
Pair::from_phrase(phrase.as_ref(), None).expect("seed slice is valid");
assert_eq!(seed, reseed);
assert_eq!(pair.public(), repair_phrase.public());
assert_eq!(pair.to_raw_vec(), repair_seed.to_raw_vec());
let repair_string = Pair::from_string(phrase.as_str(), None).expect("seed slice is valid");
assert_eq!(pair.public(), repair_string.public());
assert_eq!(pair.to_raw_vec(), repair_seed.to_raw_vec());
}
#[test]
fn generated_pair_should_work() {
let (pair, _) = Pair::generate();
let public = pair.public();
let message = b"Something important";
let signature = pair.sign(&message[..]);
assert!(Pair::verify(&signature, &message[..], &public));
}
#[test]
fn messed_signature_should_not_work() {
let (pair, _) = Pair::generate();
let public = pair.public();
let message = b"Signed payload";
let mut signature = pair.sign(&message[..]);
let bytes = &mut signature.0;
bytes[0] = !bytes[0];
bytes[2] = !bytes[2];
assert!(!Pair::verify(&signature, &message[..], &public));
}
#[test]
fn messed_message_should_not_work() {
let (pair, _) = Pair::generate();
let public = pair.public();
let message = b"Something important";
let signature = pair.sign(&message[..]);
assert!(!Pair::verify(&signature, &b"Something unimportant", &public));
}
#[test]
fn seeded_pair_should_work() {
let pair = Pair::from_seed(b"12345678901234567890123456789012");
let public = pair.public();
assert_eq!(
public,
Public::from_raw(array_bytes::hex2array_unchecked(
"741c08a06f41c596608f6774259bd9043304adfa5d3eea62760bd9be97634d63"
))
);
let message = array_bytes::hex2bytes_unchecked("2f8c6129d816cf51c374bc7f08c3e63ed156cf78aefb4a6550d97b87997977ee00000000000000000200d75a980182b10ab7d54bfed3c964073a0ee172f3daa62325af021a68f707511a4500000000000000");
let signature = pair.sign(&message[..]);
assert!(Pair::verify(&signature, &message[..], &public));
}
#[test]
fn ss58check_roundtrip_works() {
let (pair, _) = Pair::generate();
let public = pair.public();
let s = public.to_ss58check();
println!("Correct: {}", s);
let cmp = Public::from_ss58check(&s).unwrap();
assert_eq!(cmp, public);
}
#[test]
fn verify_from_old_wasm_works() {
let pk = Pair::from_seed(&array_bytes::hex2array_unchecked(
"0000000000000000000000000000000000000000000000000000000000000000",
));
let public = pk.public();
let js_signature = Signature::from_raw(array_bytes::hex2array_unchecked(
"28a854d54903e056f89581c691c1f7d2ff39f8f896c9e9c22475e60902cc2b3547199e0e91fa32902028f2ca2355e8cdd16cfe19ba5e8b658c94aa80f3b81a00"
));
assert!(Pair::verify_deprecated(&js_signature, b"SUBSTRATE", &public));
assert!(!Pair::verify(&js_signature, b"SUBSTRATE", &public));
}
#[test]
fn signature_serialization_works() {
let pair = Pair::from_seed(b"12345678901234567890123456789012");
let message = b"Something important";
let signature = pair.sign(&message[..]);
let serialized_signature = serde_json::to_string(&signature).unwrap();
assert_eq!(serialized_signature.len(), 130);
let signature = serde_json::from_str(&serialized_signature).unwrap();
assert!(Pair::verify(&signature, &message[..], &pair.public()));
}
#[test]
fn signature_serialization_doesnt_panic() {
fn deserialize_signature(text: &str) -> Result<Signature, serde_json::error::Error> {
serde_json::from_str(text)
}
assert!(deserialize_signature("Not valid json.").is_err());
assert!(deserialize_signature("\"Not an actual signature.\"").is_err());
assert!(deserialize_signature("\"abc123\"").is_err());
}
#[test]
fn vrf_sign_verify() {
let pair = Pair::from_seed(b"12345678901234567890123456789012");
let public = pair.public();
let data = VrfTranscript::new(b"label", &[(b"domain1", b"data1")]).into();
let signature = pair.vrf_sign(&data);
assert!(public.vrf_verify(&data, &signature));
}
#[test]
fn vrf_sign_verify_with_extra() {
let pair = Pair::from_seed(b"12345678901234567890123456789012");
let public = pair.public();
let extra = VrfTranscript::new(b"extra", &[(b"domain2", b"data2")]);
let data = VrfTranscript::new(b"label", &[(b"domain1", b"data1")])
.into_sign_data()
.with_extra(extra);
let signature = pair.vrf_sign(&data);
assert!(public.vrf_verify(&data, &signature));
}
#[test]
fn vrf_make_bytes_matches() {
let pair = Pair::from_seed(b"12345678901234567890123456789012");
let public = pair.public();
let ctx = b"vrfbytes";
let input = VrfTranscript::new(b"label", &[(b"domain1", b"data1")]);
let pre_output = pair.vrf_pre_output(&input);
let out1 = pair.make_bytes::<32>(ctx, &input);
let out2 = pre_output.make_bytes::<32>(ctx, &input, &public).unwrap();
assert_eq!(out1, out2);
let extra = VrfTranscript::new(b"extra", &[(b"domain2", b"data2")]);
let data = input.clone().into_sign_data().with_extra(extra);
let signature = pair.vrf_sign(&data);
assert!(public.vrf_verify(&data, &signature));
let out3 = public.make_bytes::<32>(ctx, &input, &signature.pre_output).unwrap();
assert_eq!(out2, out3);
}
#[test]
fn vrf_backend_compat() {
let pair = Pair::from_seed(b"12345678901234567890123456789012");
let public = pair.public();
let ctx = b"vrfbytes";
let input = VrfInput::new(b"label", &[(b"domain1", b"data1")]);
let extra = VrfTranscript::new(b"extra", &[(b"domain2", b"data2")]);
let data = input.clone().into_sign_data().with_extra(extra.clone());
let signature = pair.vrf_sign(&data);
assert!(public.vrf_verify(&data, &signature));
let out1 = pair.make_bytes::<32>(ctx, &input);
let out2 = public.make_bytes::<32>(ctx, &input, &signature.pre_output).unwrap();
assert_eq!(out1, out2);
let (inout, proof, _) = pair
.0
.vrf_sign_extra_after_check(input.0.clone(), |inout| {
let out3 = inout.make_bytes::<[u8; 32]>(ctx);
assert_eq!(out2, out3);
Some(extra.0.clone())
})
.unwrap();
let signature2 =
VrfSignature { pre_output: VrfPreOutput(inout.to_preout()), proof: VrfProof(proof) };
assert!(public.vrf_verify(&data, &signature2));
assert_eq!(signature.pre_output, signature2.pre_output);
}
}