// This file is part of Substrate. // Copyright (C) 2017-2022 Parity Technologies (UK) Ltd. // SPDX-License-Identifier: Apache-2.0 // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. //! Simple ECDSA secp256k1 API. use codec::{Decode, Encode, MaxEncodedLen}; use scale_info::TypeInfo; use sp_runtime_interface::pass_by::PassByInner; #[cfg(feature = "std")] use crate::crypto::Ss58Codec; use crate::crypto::{ ByteArray, CryptoType, CryptoTypeId, CryptoTypePublicPair, Derive, Public as TraitPublic, UncheckedFrom, }; #[cfg(feature = "full_crypto")] use crate::{ crypto::{DeriveJunction, Pair as TraitPair, SecretStringError}, hashing::blake2_256, }; #[cfg(feature = "std")] use bip39::{Language, Mnemonic, MnemonicType}; #[cfg(all(feature = "full_crypto", not(feature = "std")))] use secp256k1::Secp256k1; #[cfg(feature = "std")] use secp256k1::SECP256K1; #[cfg(feature = "full_crypto")] use secp256k1::{ ecdsa::{RecoverableSignature, RecoveryId}, Message, PublicKey, SecretKey, }; #[cfg(feature = "std")] use serde::{de, Deserialize, Deserializer, Serialize, Serializer}; #[cfg(feature = "full_crypto")] use sp_std::vec::Vec; /// An identifier used to match public keys against ecdsa keys pub const CRYPTO_ID: CryptoTypeId = CryptoTypeId(*b"ecds"); /// A secret seed (which is bytewise essentially equivalent to a SecretKey). /// /// We need it as a different type because `Seed` is expected to be AsRef<[u8]>. #[cfg(feature = "full_crypto")] type Seed = [u8; 32]; /// The ECDSA compressed public key. #[cfg_attr(feature = "full_crypto", derive(Hash))] #[derive( Clone, Copy, Encode, Decode, PassByInner, MaxEncodedLen, TypeInfo, Eq, PartialEq, PartialOrd, Ord, )] pub struct Public(pub [u8; 33]); impl Public { /// A new instance from the given 33-byte `data`. /// /// NOTE: No checking goes on to ensure this is a real public key. Only use it if /// you are certain that the array actually is a pubkey. GIGO! pub fn from_raw(data: [u8; 33]) -> Self { Self(data) } /// Create a new instance from the given full public key. /// /// This will convert the full public key into the compressed format. #[cfg(feature = "std")] pub fn from_full(full: &[u8]) -> Result { let pubkey = if full.len() == 64 { // Tag it as uncompressed public key. let mut tagged_full = [0u8; 65]; tagged_full[0] = 0x04; tagged_full[1..].copy_from_slice(full); secp256k1::PublicKey::from_slice(&tagged_full) } else { secp256k1::PublicKey::from_slice(full) }; pubkey.map(|k| Self(k.serialize())).map_err(|_| ()) } } impl ByteArray for Public { const LEN: usize = 33; } impl TraitPublic for Public { fn to_public_crypto_pair(&self) -> CryptoTypePublicPair { CryptoTypePublicPair(CRYPTO_ID, self.to_raw_vec()) } } impl From for CryptoTypePublicPair { fn from(key: Public) -> Self { (&key).into() } } impl From<&Public> for CryptoTypePublicPair { fn from(key: &Public) -> Self { CryptoTypePublicPair(CRYPTO_ID, key.to_raw_vec()) } } impl Derive for Public {} impl AsRef<[u8]> for Public { fn as_ref(&self) -> &[u8] { &self.0[..] } } impl AsMut<[u8]> for Public { fn as_mut(&mut self) -> &mut [u8] { &mut self.0[..] } } impl TryFrom<&[u8]> for Public { type Error = (); fn try_from(data: &[u8]) -> Result { if data.len() != Self::LEN { return Err(()) } let mut r = [0u8; Self::LEN]; r.copy_from_slice(data); Ok(Self::unchecked_from(r)) } } #[cfg(feature = "full_crypto")] impl From for Public { fn from(x: Pair) -> Self { x.public() } } impl UncheckedFrom<[u8; 33]> for Public { fn unchecked_from(x: [u8; 33]) -> Self { Public(x) } } #[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 std::fmt::Formatter) -> std::fmt::Result { let s = self.to_ss58check(); write!(f, "{} ({}...)", crate::hexdisplay::HexDisplay::from(&self.as_ref()), &s[0..8]) } #[cfg(not(feature = "std"))] fn fmt(&self, _: &mut sp_std::fmt::Formatter) -> sp_std::fmt::Result { Ok(()) } } #[cfg(feature = "std")] impl Serialize for Public { fn serialize(&self, serializer: S) -> Result where S: Serializer, { serializer.serialize_str(&self.to_ss58check()) } } #[cfg(feature = "std")] impl<'de> Deserialize<'de> for Public { fn deserialize(deserializer: D) -> Result where D: Deserializer<'de>, { Public::from_ss58check(&String::deserialize(deserializer)?) .map_err(|e| de::Error::custom(format!("{:?}", e))) } } /// A signature (a 512-bit value, plus 8 bits for recovery ID). #[cfg_attr(feature = "full_crypto", derive(Hash))] #[derive(Encode, Decode, MaxEncodedLen, PassByInner, TypeInfo, PartialEq, Eq)] pub struct Signature(pub [u8; 65]); impl TryFrom<&[u8]> for Signature { type Error = (); fn try_from(data: &[u8]) -> Result { if data.len() == 65 { let mut inner = [0u8; 65]; inner.copy_from_slice(data); Ok(Signature(inner)) } else { Err(()) } } } #[cfg(feature = "std")] impl Serialize for Signature { fn serialize(&self, serializer: S) -> Result where S: Serializer, { serializer.serialize_str(&array_bytes::bytes2hex("", self.as_ref())) } } #[cfg(feature = "std")] impl<'de> Deserialize<'de> for Signature { fn deserialize(deserializer: D) -> Result where D: Deserializer<'de>, { let signature_hex = array_bytes::hex2bytes(&String::deserialize(deserializer)?) .map_err(|e| de::Error::custom(format!("{:?}", e)))?; Signature::try_from(signature_hex.as_ref()) .map_err(|e| de::Error::custom(format!("{:?}", e))) } } impl Clone for Signature { fn clone(&self) -> Self { let mut r = [0u8; 65]; r.copy_from_slice(&self.0[..]); Signature(r) } } impl Default for Signature { fn default() -> Self { Signature([0u8; 65]) } } impl From for [u8; 65] { fn from(v: Signature) -> [u8; 65] { v.0 } } impl AsRef<[u8; 65]> for Signature { fn as_ref(&self) -> &[u8; 65] { &self.0 } } impl AsRef<[u8]> for Signature { fn as_ref(&self) -> &[u8] { &self.0[..] } } impl AsMut<[u8]> for Signature { fn as_mut(&mut self) -> &mut [u8] { &mut self.0[..] } } impl sp_std::fmt::Debug for Signature { #[cfg(feature = "std")] fn fmt(&self, f: &mut sp_std::fmt::Formatter) -> sp_std::fmt::Result { write!(f, "{}", crate::hexdisplay::HexDisplay::from(&self.0)) } #[cfg(not(feature = "std"))] fn fmt(&self, _: &mut sp_std::fmt::Formatter) -> sp_std::fmt::Result { Ok(()) } } impl UncheckedFrom<[u8; 65]> for Signature { fn unchecked_from(data: [u8; 65]) -> Signature { Signature(data) } } impl Signature { /// A new instance from the given 65-byte `data`. /// /// NOTE: No checking goes on to ensure this is a real signature. Only use it if /// you are certain that the array actually is a signature. GIGO! pub fn from_raw(data: [u8; 65]) -> Signature { Signature(data) } /// A new instance from the given slice that should be 65 bytes long. /// /// NOTE: No checking goes on to ensure this is a real signature. Only use it if /// you are certain that the array actually is a signature. GIGO! pub fn from_slice(data: &[u8]) -> Option { if data.len() != 65 { return None } let mut r = [0u8; 65]; r.copy_from_slice(data); Some(Signature(r)) } /// Recover the public key from this signature and a message. #[cfg(feature = "full_crypto")] pub fn recover>(&self, message: M) -> Option { self.recover_prehashed(&blake2_256(message.as_ref())) } /// Recover the public key from this signature and a pre-hashed message. #[cfg(feature = "full_crypto")] pub fn recover_prehashed(&self, message: &[u8; 32]) -> Option { let rid = RecoveryId::from_i32(self.0[64] as i32).ok()?; let sig = RecoverableSignature::from_compact(&self.0[..64], rid).ok()?; let message = Message::from_slice(message).expect("Message is 32 bytes; qed"); #[cfg(feature = "std")] let context = SECP256K1; #[cfg(not(feature = "std"))] let context = Secp256k1::verification_only(); context .recover_ecdsa(&message, &sig) .ok() .map(|pubkey| Public(pubkey.serialize())) } } #[cfg(feature = "full_crypto")] impl From for Signature { fn from(recsig: RecoverableSignature) -> Signature { let mut r = Self::default(); let (recid, sig) = recsig.serialize_compact(); r.0[..64].copy_from_slice(&sig); // This is safe due to the limited range of possible valid ids. r.0[64] = recid.to_i32() as u8; r } } /// Derive a single hard junction. #[cfg(feature = "full_crypto")] fn derive_hard_junction(secret_seed: &Seed, cc: &[u8; 32]) -> Seed { ("Secp256k1HDKD", secret_seed, cc).using_encoded(sp_core_hashing::blake2_256) } /// An error when deriving a key. #[cfg(feature = "full_crypto")] pub enum DeriveError { /// A soft key was found in the path (and is unsupported). SoftKeyInPath, } /// A key pair. #[cfg(feature = "full_crypto")] #[derive(Clone)] pub struct Pair { public: Public, secret: SecretKey, } #[cfg(feature = "full_crypto")] impl TraitPair for Pair { type Public = Public; type Seed = Seed; type Signature = Signature; type DeriveError = DeriveError; /// Generate new secure (random) key pair and provide the recovery phrase. /// /// You can recover the same key later with `from_phrase`. #[cfg(feature = "std")] fn generate_with_phrase(password: Option<&str>) -> (Pair, String, Seed) { let mnemonic = Mnemonic::new(MnemonicType::Words12, Language::English); let phrase = mnemonic.phrase(); let (pair, seed) = Self::from_phrase(phrase, password) .expect("All phrases generated by Mnemonic are valid; qed"); (pair, phrase.to_owned(), seed) } /// Generate key pair from given recovery phrase and password. #[cfg(feature = "std")] fn from_phrase( phrase: &str, password: Option<&str>, ) -> Result<(Pair, Seed), SecretStringError> { let big_seed = substrate_bip39::seed_from_entropy( Mnemonic::from_phrase(phrase, Language::English) .map_err(|_| SecretStringError::InvalidPhrase)? .entropy(), password.unwrap_or(""), ) .map_err(|_| SecretStringError::InvalidSeed)?; let mut seed = Seed::default(); seed.copy_from_slice(&big_seed[0..32]); Self::from_seed_slice(&big_seed[0..32]).map(|x| (x, seed)) } /// Make a new key pair from secret seed material. /// /// You should never need to use this; generate(), generate_with_phrase fn from_seed(seed: &Seed) -> Pair { Self::from_seed_slice(&seed[..]).expect("seed has valid length; qed") } /// Make a new key pair from secret seed material. The slice must be 32 bytes long or it /// will return `None`. /// /// You should never need to use this; generate(), generate_with_phrase fn from_seed_slice(seed_slice: &[u8]) -> Result { let secret = SecretKey::from_slice(seed_slice).map_err(|_| SecretStringError::InvalidSeedLength)?; #[cfg(feature = "std")] let context = SECP256K1; #[cfg(not(feature = "std"))] let context = Secp256k1::signing_only(); let public = PublicKey::from_secret_key(&context, &secret); let public = Public(public.serialize()); Ok(Pair { public, secret }) } /// Derive a child key from a series of given junctions. fn derive>( &self, path: Iter, _seed: Option, ) -> Result<(Pair, Option), DeriveError> { let mut acc = self.seed(); for j in path { match j { DeriveJunction::Soft(_cc) => return Err(DeriveError::SoftKeyInPath), DeriveJunction::Hard(cc) => acc = derive_hard_junction(&acc, &cc), } } Ok((Self::from_seed(&acc), Some(acc))) } /// Get the public key. fn public(&self) -> Public { self.public } /// Sign a message. fn sign(&self, message: &[u8]) -> Signature { self.sign_prehashed(&blake2_256(message)) } /// Verify a signature on a message. Returns true if the signature is good. fn verify>(sig: &Self::Signature, message: M, pubkey: &Self::Public) -> bool { match sig.recover(message) { Some(actual) => actual == *pubkey, None => false, } } /// Verify a signature on a message. Returns true if the signature is good. /// /// This doesn't use the type system to ensure that `sig` and `pubkey` are the correct /// size. Use it only if you're coming from byte buffers and need the speed. fn verify_weak, M: AsRef<[u8]>>(sig: &[u8], message: M, pubkey: P) -> bool { match Signature::from_slice(sig).and_then(|sig| sig.recover(message)) { Some(actual) => actual.as_ref() == pubkey.as_ref(), None => false, } } /// Return a vec filled with raw data. fn to_raw_vec(&self) -> Vec { self.seed().to_vec() } } #[cfg(feature = "full_crypto")] impl Pair { /// Get the seed for this key. pub fn seed(&self) -> Seed { self.secret.secret_bytes() } /// Exactly as `from_string` except that if no matches are found then, the the first 32 /// characters are taken (padded with spaces as necessary) and used as the MiniSecretKey. #[cfg(feature = "std")] pub fn from_legacy_string(s: &str, password_override: Option<&str>) -> Pair { Self::from_string(s, password_override).unwrap_or_else(|_| { let mut padded_seed: Seed = [b' '; 32]; let len = s.len().min(32); padded_seed[..len].copy_from_slice(&s.as_bytes()[..len]); Self::from_seed(&padded_seed) }) } /// Sign a pre-hashed message pub fn sign_prehashed(&self, message: &[u8; 32]) -> Signature { let message = Message::from_slice(message).expect("Message is 32 bytes; qed"); #[cfg(feature = "std")] let context = SECP256K1; #[cfg(not(feature = "std"))] let context = Secp256k1::signing_only(); context.sign_ecdsa_recoverable(&message, &self.secret).into() } /// Verify a signature on a pre-hashed message. Return `true` if the signature is valid /// and thus matches the given `public` key. pub fn verify_prehashed(sig: &Signature, message: &[u8; 32], public: &Public) -> bool { match sig.recover_prehashed(message) { Some(actual) => actual == *public, None => false, } } /// Verify a signature on a message. Returns true if the signature is good. /// Parses Signature using parse_overflowing_slice. #[deprecated(note = "please use `verify` instead")] pub fn verify_deprecated>(sig: &Signature, message: M, pubkey: &Public) -> bool { let message = libsecp256k1::Message::parse(&blake2_256(message.as_ref())); let parse_signature_overflowing = |x: [u8; 65]| { let sig = libsecp256k1::Signature::parse_overflowing_slice(&x[..64]).ok()?; let rid = libsecp256k1::RecoveryId::parse(x[64]).ok()?; Some((sig, rid)) }; let (sig, rid) = match parse_signature_overflowing(sig.0) { Some(sigri) => sigri, _ => return false, }; match libsecp256k1::recover(&message, &sig, &rid) { Ok(actual) => pubkey.0 == actual.serialize_compressed(), _ => false, } } } // The `secp256k1` backend doesn't implement cleanup for their private keys. // Currently we should take care of wiping the secret from memory. // NOTE: this solution is not effective when `Pair` is moved around memory. // The very same problem affects other cryptographic backends that are just using // `zeroize`for their secrets. #[cfg(feature = "full_crypto")] impl Drop for Pair { fn drop(&mut self) { let ptr = self.secret.as_mut_ptr(); for off in 0..self.secret.len() { unsafe { core::ptr::write_volatile(ptr.add(off), 0); } } } } impl CryptoType for Public { #[cfg(feature = "full_crypto")] type Pair = Pair; } impl CryptoType for Signature { #[cfg(feature = "full_crypto")] type Pair = Pair; } #[cfg(feature = "full_crypto")] impl CryptoType for Pair { type Pair = Pair; } #[cfg(test)] mod test { use super::*; use crate::crypto::{ set_default_ss58_version, PublicError, Ss58AddressFormat, Ss58AddressFormatRegistry, DEV_PHRASE, }; use serde_json; #[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(), ); } #[test] fn seed_and_derive_should_work() { let seed = array_bytes::hex2array_unchecked( "9d61b19deffd5a60ba844af492ec2cc44449c5697b326919703bac031cae7f60", ); let pair = Pair::from_seed(&seed); assert_eq!(pair.seed(), seed); let path = vec![DeriveJunction::Hard([0u8; 32])]; let derived = pair.derive(path.into_iter(), None).ok().unwrap(); assert_eq!( derived.0.seed(), array_bytes::hex2array_unchecked::<32>( "b8eefc4937200a8382d00050e050ced2d4ab72cc2ef1b061477afb51564fdd61" ) ); } #[test] fn test_vector_should_work() { let pair = Pair::from_seed(&array_bytes::hex2array_unchecked( "9d61b19deffd5a60ba844af492ec2cc44449c5697b326919703bac031cae7f60", )); let public = pair.public(); assert_eq!( public, Public::from_full( &array_bytes::hex2bytes_unchecked("8db55b05db86c0b1786ca49f095d76344c9e6056b2f02701a7e7f3c20aabfd913ebbe148dd17c56551a52952371071a6c604b3f3abe8f2c8fa742158ea6dd7d4"), ).unwrap(), ); let message = b""; let signature = array_bytes::hex2array_unchecked("3dde91174bd9359027be59a428b8146513df80a2a3c7eda2194f64de04a69ab97b753169e94db6ffd50921a2668a48b94ca11e3d32c1ff19cfe88890aa7e8f3c00"); let signature = Signature::from_raw(signature); assert!(pair.sign(&message[..]) == signature); assert!(Pair::verify(&signature, &message[..], &public)); } #[test] fn test_vector_by_string_should_work() { let pair = Pair::from_string( "0x9d61b19deffd5a60ba844af492ec2cc44449c5697b326919703bac031cae7f60", None, ) .unwrap(); let public = pair.public(); assert_eq!( public, Public::from_full( &array_bytes::hex2bytes_unchecked("8db55b05db86c0b1786ca49f095d76344c9e6056b2f02701a7e7f3c20aabfd913ebbe148dd17c56551a52952371071a6c604b3f3abe8f2c8fa742158ea6dd7d4"), ).unwrap(), ); let message = b""; let signature = array_bytes::hex2array_unchecked("3dde91174bd9359027be59a428b8146513df80a2a3c7eda2194f64de04a69ab97b753169e94db6ffd50921a2668a48b94ca11e3d32c1ff19cfe88890aa7e8f3c00"); let signature = Signature::from_raw(signature); assert!(pair.sign(&message[..]) == signature); assert!(Pair::verify(&signature, &message[..], &public)); } #[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)); assert!(!Pair::verify(&signature, b"Something else", &public)); } #[test] fn seeded_pair_should_work() { let pair = Pair::from_seed(b"12345678901234567890123456789012"); let public = pair.public(); assert_eq!( public, Public::from_full( &array_bytes::hex2bytes_unchecked("5676109c54b9a16d271abeb4954316a40a32bcce023ac14c8e26e958aa68fba995840f3de562156558efbfdac3f16af0065e5f66795f4dd8262a228ef8c6d813"), ).unwrap(), ); let message = array_bytes::hex2bytes_unchecked("2f8c6129d816cf51c374bc7f08c3e63ed156cf78aefb4a6550d97b87997977ee00000000000000000200d75a980182b10ab7d54bfed3c964073a0ee172f3daa62325af021a68f707511a4500000000000000"); let signature = pair.sign(&message[..]); println!("Correct signature: {:?}", signature); assert!(Pair::verify(&signature, &message[..], &public)); assert!(!Pair::verify(&signature, "Other message", &public)); } #[test] fn generate_with_phrase_recovery_possible() { let (pair1, phrase, _) = Pair::generate_with_phrase(None); let (pair2, _) = Pair::from_phrase(&phrase, None).unwrap(); assert_eq!(pair1.public(), pair2.public()); } #[test] fn generate_with_password_phrase_recovery_possible() { let (pair1, phrase, _) = Pair::generate_with_phrase(Some("password")); let (pair2, _) = Pair::from_phrase(&phrase, Some("password")).unwrap(); assert_eq!(pair1.public(), pair2.public()); } #[test] fn password_does_something() { let (pair1, phrase, _) = Pair::generate_with_phrase(Some("password")); let (pair2, _) = Pair::from_phrase(&phrase, None).unwrap(); assert_ne!(pair1.public(), pair2.public()); } #[test] fn ss58check_roundtrip_works() { let pair = Pair::from_seed(b"12345678901234567890123456789012"); 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 ss58check_format_check_works() { let pair = Pair::from_seed(b"12345678901234567890123456789012"); let public = pair.public(); let format = Ss58AddressFormatRegistry::Reserved46Account.into(); let s = public.to_ss58check_with_version(format); assert_eq!(Public::from_ss58check_with_version(&s), Err(PublicError::FormatNotAllowed)); } #[test] fn ss58check_full_roundtrip_works() { let pair = Pair::from_seed(b"12345678901234567890123456789012"); let public = pair.public(); let format = Ss58AddressFormatRegistry::PolkadotAccount.into(); let s = public.to_ss58check_with_version(format); let (k, f) = Public::from_ss58check_with_version(&s).unwrap(); assert_eq!(k, public); assert_eq!(f, format); let format = Ss58AddressFormat::custom(64); let s = public.to_ss58check_with_version(format); let (k, f) = Public::from_ss58check_with_version(&s).unwrap(); assert_eq!(k, public); assert_eq!(f, format); } #[test] fn ss58check_custom_format_works() { // We need to run this test in its own process to not interfere with other tests running in // parallel and also relying on the ss58 version. if std::env::var("RUN_CUSTOM_FORMAT_TEST") == Ok("1".into()) { use crate::crypto::Ss58AddressFormat; // temp save default format version let default_format = crate::crypto::default_ss58_version(); // set current ss58 version is custom "200" `Ss58AddressFormat::Custom(200)` set_default_ss58_version(Ss58AddressFormat::custom(200)); // custom addr encoded by version 200 let addr = "4pbsSkWcBaYoFHrKJZp5fDVUKbqSYD9dhZZGvpp3vQ5ysVs5ybV"; Public::from_ss58check(addr).unwrap(); set_default_ss58_version(default_format); // set current ss58 version to default version let addr = "KWAfgC2aRG5UVD6CpbPQXCx4YZZUhvWqqAJE6qcYc9Rtr6g5C"; Public::from_ss58check(addr).unwrap(); println!("CUSTOM_FORMAT_SUCCESSFUL"); } else { let executable = std::env::current_exe().unwrap(); let output = std::process::Command::new(executable) .env("RUN_CUSTOM_FORMAT_TEST", "1") .args(&["--nocapture", "ss58check_custom_format_works"]) .output() .unwrap(); let output = String::from_utf8(output.stdout).unwrap(); assert!(output.contains("CUSTOM_FORMAT_SUCCESSFUL")); } } #[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(); // Signature is 65 bytes, so 130 chars + 2 quote chars assert_eq!(serialized_signature.len(), 132); 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 { serde_json::from_str(text) } assert!(deserialize_signature("Not valid json.").is_err()); assert!(deserialize_signature("\"Not an actual signature.\"").is_err()); // Poorly-sized assert!(deserialize_signature("\"abc123\"").is_err()); } #[test] fn sign_prehashed_works() { let (pair, _, _) = Pair::generate_with_phrase(Some("password")); // `msg` shouldn't be mangled let msg = [0u8; 32]; let sig1 = pair.sign_prehashed(&msg); let sig2: Signature = { let message = Message::from_slice(&msg).unwrap(); SECP256K1.sign_ecdsa_recoverable(&message, &pair.secret).into() }; assert_eq!(sig1, sig2); // signature is actually different let sig2 = pair.sign(&msg); assert_ne!(sig1, sig2); // using pre-hashed `msg` works let msg = b"this should be hashed"; let sig1 = pair.sign_prehashed(&blake2_256(msg)); let sig2 = pair.sign(msg); assert_eq!(sig1, sig2); } #[test] fn verify_prehashed_works() { let (pair, _, _) = Pair::generate_with_phrase(Some("password")); // `msg` and `sig` match let msg = blake2_256(b"this should be hashed"); let sig = pair.sign_prehashed(&msg); assert!(Pair::verify_prehashed(&sig, &msg, &pair.public())); // `msg` and `sig` don't match let msg = blake2_256(b"this is a different message"); assert!(!Pair::verify_prehashed(&sig, &msg, &pair.public())); } #[test] fn recover_prehashed_works() { let (pair, _, _) = Pair::generate_with_phrase(Some("password")); // recovered key matches signing key let msg = blake2_256(b"this should be hashed"); let sig = pair.sign_prehashed(&msg); let key = sig.recover_prehashed(&msg).unwrap(); assert_eq!(pair.public(), key); // recovered key is useable assert!(Pair::verify_prehashed(&sig, &msg, &key)); // recovered key and signing key don't match let msg = blake2_256(b"this is a different message"); let key = sig.recover_prehashed(&msg).unwrap(); assert_ne!(pair.public(), key); } }