// Copyright 2015-2019 Parity Technologies (UK) Ltd. // This file is part of Parity Ethereum. // Parity Ethereum is free software: you can redistribute it and/or modify // it under the terms of the GNU General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // Parity Ethereum is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // You should have received a copy of the GNU General Public License // along with Parity Ethereum. If not, see . //! Extended keys use secret::Secret; use Public; use ethereum_types::H256; pub use self::derivation::Error as DerivationError; /// Represents label that can be stored as a part of key derivation pub trait Label { /// Length of the data that label occupies fn len() -> usize; /// Store label data to the key derivation sequence /// Must not use more than `len()` bytes from slice fn store(&self, target: &mut [u8]); } impl Label for u32 { fn len() -> usize { 4 } fn store(&self, target: &mut [u8]) { let bytes = self.to_be_bytes(); target[0..4].copy_from_slice(&bytes); } } /// Key derivation over generic label `T` pub enum Derivation { /// Soft key derivation (allow proof of parent) Soft(T), /// Hard key derivation (does not allow proof of parent) Hard(T), } impl From for Derivation { fn from(index: u32) -> Self { if index < (2 << 30) { Derivation::Soft(index) } else { Derivation::Hard(index) } } } impl Label for H256 { fn len() -> usize { 32 } fn store(&self, target: &mut [u8]) { (&mut target[0..32]).copy_from_slice(self.as_bytes()); } } /// Extended secret key, allows deterministic derivation of subsequent keys. pub struct ExtendedSecret { secret: Secret, chain_code: H256, } impl ExtendedSecret { /// New extended key from given secret and chain code. pub fn with_code(secret: Secret, chain_code: H256) -> ExtendedSecret { ExtendedSecret { secret: secret, chain_code: chain_code, } } /// New extended key from given secret with the random chain code. pub fn new_random(secret: Secret) -> ExtendedSecret { ExtendedSecret::with_code(secret, H256::random()) } /// New extended key from given secret. /// Chain code will be derived from the secret itself (in a deterministic way). pub fn new(secret: Secret) -> ExtendedSecret { let chain_code = derivation::chain_code(*secret); ExtendedSecret::with_code(secret, chain_code) } /// Derive new private key pub fn derive(&self, index: Derivation) -> ExtendedSecret where T: Label { let (derived_key, next_chain_code) = derivation::private(*self.secret, self.chain_code, index); let derived_secret = Secret::from(derived_key.0); ExtendedSecret::with_code(derived_secret, next_chain_code) } /// Private key component of the extended key. pub fn as_raw(&self) -> &Secret { &self.secret } } /// Extended public key, allows deterministic derivation of subsequent keys. pub struct ExtendedPublic { public: Public, chain_code: H256, } impl ExtendedPublic { /// New extended public key from known parent and chain code pub fn new(public: Public, chain_code: H256) -> Self { ExtendedPublic { public: public, chain_code: chain_code } } /// Create new extended public key from known secret pub fn from_secret(secret: &ExtendedSecret) -> Result { Ok( ExtendedPublic::new( derivation::point(**secret.as_raw())?, secret.chain_code.clone(), ) ) } /// Derive new public key /// Operation is defined only for index belongs [0..2^31) pub fn derive(&self, index: Derivation) -> Result where T: Label { let (derived_key, next_chain_code) = derivation::public(self.public, self.chain_code, index)?; Ok(ExtendedPublic::new(derived_key, next_chain_code)) } pub fn public(&self) -> &Public { &self.public } } pub struct ExtendedKeyPair { secret: ExtendedSecret, public: ExtendedPublic, } impl ExtendedKeyPair { pub fn new(secret: Secret) -> Self { let extended_secret = ExtendedSecret::new(secret); let extended_public = ExtendedPublic::from_secret(&extended_secret) .expect("Valid `Secret` always produces valid public; qed"); ExtendedKeyPair { secret: extended_secret, public: extended_public, } } pub fn with_code(secret: Secret, public: Public, chain_code: H256) -> Self { ExtendedKeyPair { secret: ExtendedSecret::with_code(secret, chain_code.clone()), public: ExtendedPublic::new(public, chain_code), } } pub fn with_secret(secret: Secret, chain_code: H256) -> Self { let extended_secret = ExtendedSecret::with_code(secret, chain_code); let extended_public = ExtendedPublic::from_secret(&extended_secret) .expect("Valid `Secret` always produces valid public; qed"); ExtendedKeyPair { secret: extended_secret, public: extended_public, } } pub fn with_seed(seed: &[u8]) -> Result { let (master_key, chain_code) = derivation::seed_pair(seed); Ok(ExtendedKeyPair::with_secret( Secret::from_unsafe_slice(master_key.as_bytes()).map_err(|_| DerivationError::InvalidSeed)?, chain_code, )) } pub fn secret(&self) -> &ExtendedSecret { &self.secret } pub fn public(&self) -> &ExtendedPublic { &self.public } pub fn derive(&self, index: Derivation) -> Result where T: Label { let derived = self.secret.derive(index); Ok(ExtendedKeyPair { public: ExtendedPublic::from_secret(&derived)?, secret: derived, }) } } // Derivation functions for private and public keys // Work is based on BIP0032 // https://github.com/bitcoin/bips/blob/master/bip-0032.mediawiki mod derivation { use parity_crypto::hmac; use ethereum_types::{BigEndianHash, U256, U512, H512, H256}; use secp256k1::key::{SecretKey, PublicKey}; use SECP256K1; use keccak; use math::curve_order; use super::{Label, Derivation}; use std::convert::TryInto; #[derive(Debug)] pub enum Error { InvalidHardenedUse, InvalidPoint, MissingIndex, InvalidSeed, } // Deterministic derivation of the key using secp256k1 elliptic curve. // Derivation can be either hardened or not. // For hardened derivation, pass u32 index at least 2^31 or custom Derivation::Hard(T) enum // // Can panic if passed `private_key` is not a valid secp256k1 private key // (outside of (0..curve_order()]) field pub fn private(private_key: H256, chain_code: H256, index: Derivation) -> (H256, H256) where T: Label { match index { Derivation::Soft(index) => private_soft(private_key, chain_code, index), Derivation::Hard(index) => private_hard(private_key, chain_code, index), } } fn hmac_pair(data: &[u8], private_key: H256, chain_code: H256) -> (H256, H256) { let private: U256 = private_key.into_uint(); // produces 512-bit derived hmac (I) let skey = hmac::SigKey::sha512(chain_code.as_bytes()); let i_512 = hmac::sign(&skey, &data[..]); // left most 256 bits are later added to original private key let hmac_key: U256 = H256::from_slice(&i_512[0..32]).into_uint(); // right most 256 bits are new chain code for later derivations let next_chain_code = H256::from_slice(&i_512[32..64]); let child_key = BigEndianHash::from_uint(&private_add(hmac_key, private)); (child_key, next_chain_code) } // Can panic if passed `private_key` is not a valid secp256k1 private key // (outside of (0..curve_order()]) field fn private_soft(private_key: H256, chain_code: H256, index: T) -> (H256, H256) where T: Label { let mut data = vec![0u8; 33 + T::len()]; let sec_private = SecretKey::from_slice(&SECP256K1, private_key.as_bytes()) .expect("Caller should provide valid private key"); let sec_public = PublicKey::from_secret_key(&SECP256K1, &sec_private) .expect("Caller should provide valid private key"); let public_serialized = sec_public.serialize_vec(&SECP256K1, true); // curve point (compressed public key) -- index // 0.33 -- 33..end data[0..33].copy_from_slice(&public_serialized); index.store(&mut data[33..]); hmac_pair(&data, private_key, chain_code) } // Deterministic derivation of the key using secp256k1 elliptic curve // This is hardened derivation and does not allow to associate // corresponding public keys of the original and derived private keys fn private_hard(private_key: H256, chain_code: H256, index: T) -> (H256, H256) where T: Label { let mut data: Vec = vec![0u8; 33 + T::len()]; let private: U256 = private_key.into_uint(); // 0x00 (padding) -- private_key -- index // 0 -- 1..33 -- 33..end private.to_big_endian(&mut data[1..33]); index.store(&mut data[33..(33 + T::len())]); hmac_pair(&data, private_key, chain_code) } fn private_add(k1: U256, k2: U256) -> U256 { let sum = U512::from(k1) + U512::from(k2); modulo(sum, curve_order()) } // todo: surely can be optimized fn modulo(u1: U512, u2: U256) -> U256 { let m = u1 % U512::from(u2); m.try_into().expect("U512 modulo U256 should fit into U256; qed") } pub fn public(public_key: H512, chain_code: H256, derivation: Derivation) -> Result<(H512, H256), Error> where T: Label { let index = match derivation { Derivation::Soft(index) => index, Derivation::Hard(_) => { return Err(Error::InvalidHardenedUse); } }; let mut public_sec_raw = [0u8; 65]; public_sec_raw[0] = 4; public_sec_raw[1..65].copy_from_slice(public_key.as_bytes()); let public_sec = PublicKey::from_slice(&SECP256K1, &public_sec_raw).map_err(|_| Error::InvalidPoint)?; let public_serialized = public_sec.serialize_vec(&SECP256K1, true); let mut data = vec![0u8; 33 + T::len()]; // curve point (compressed public key) -- index // 0.33 -- 33..end data[0..33].copy_from_slice(&public_serialized); index.store(&mut data[33..(33 + T::len())]); // HMAC512SHA produces [derived private(256); new chain code(256)] let skey = hmac::SigKey::sha512(chain_code.as_bytes()); let i_512 = hmac::sign(&skey, &data[..]); let new_private = H256::from_slice(&i_512[0..32]); let new_chain_code = H256::from_slice(&i_512[32..64]); // Generated private key can (extremely rarely) be out of secp256k1 key field if curve_order() <= new_private.into_uint() { return Err(Error::MissingIndex); } let new_private_sec = SecretKey::from_slice(&SECP256K1, new_private.as_bytes()) .expect("Private key belongs to the field [0..CURVE_ORDER) (checked above); So initializing can never fail; qed"); let mut new_public = PublicKey::from_secret_key(&SECP256K1, &new_private_sec) .expect("Valid private key produces valid public key"); // Adding two points on the elliptic curves (combining two public keys) new_public.add_assign(&SECP256K1, &public_sec) .expect("Addition of two valid points produce valid point"); let serialized = new_public.serialize_vec(&SECP256K1, false); Ok(( H512::from_slice(&serialized[1..65]), new_chain_code, )) } fn sha3(slc: &[u8]) -> H256 { keccak::Keccak256::keccak256(slc).into() } pub fn chain_code(secret: H256) -> H256 { // 10,000 rounds of sha3 let mut running_sha3 = sha3(secret.as_bytes()); for _ in 0..99999 { running_sha3 = sha3(running_sha3.as_bytes()); } running_sha3 } pub fn point(secret: H256) -> Result { let sec = SecretKey::from_slice(&SECP256K1, secret.as_bytes()) .map_err(|_| Error::InvalidPoint)?; let public_sec = PublicKey::from_secret_key(&SECP256K1, &sec) .map_err(|_| Error::InvalidPoint)?; let serialized = public_sec.serialize_vec(&SECP256K1, false); Ok(H512::from_slice(&serialized[1..65])) } pub fn seed_pair(seed: &[u8]) -> (H256, H256) { let skey = hmac::SigKey::sha512(b"Bitcoin seed"); let i_512 = hmac::sign(&skey, seed); let master_key = H256::from_slice(&i_512[0..32]); let chain_code = H256::from_slice(&i_512[32..64]); (master_key, chain_code) } } #[cfg(test)] mod tests { use super::{ExtendedSecret, ExtendedPublic, ExtendedKeyPair}; use secret::Secret; use std::str::FromStr; use ethereum_types::{H128, H256, H512}; use super::{derivation, Derivation}; fn master_chain_basic() -> (H256, H256) { let seed = H128::from_str("000102030405060708090a0b0c0d0e0f") .expect("Seed should be valid H128") .as_bytes() .to_vec(); derivation::seed_pair(&*seed) } fn test_extended(f: F, test_private: H256) where F: Fn(ExtendedSecret) -> ExtendedSecret { let (private_seed, chain_code) = master_chain_basic(); let extended_secret = ExtendedSecret::with_code(Secret::from(private_seed.0), chain_code); let derived = f(extended_secret); assert_eq!(**derived.as_raw(), test_private); } #[test] fn smoky() { let secret = Secret::from_str("a100df7a048e50ed308ea696dc600215098141cb391e9527329df289f9383f65").unwrap(); let extended_secret = ExtendedSecret::with_code(secret.clone(), H256::zero()); // hardened assert_eq!(&**extended_secret.as_raw(), &*secret); assert_eq!( **extended_secret.derive(2147483648.into()).as_raw(), H256::from_str("0927453daed47839608e414a3738dfad10aed17c459bbd9ab53f89b026c834b6").unwrap(), ); assert_eq!( **extended_secret.derive(2147483649.into()).as_raw(), H256::from_str("44238b6a29c6dcbe9b401364141ba11e2198c289a5fed243a1c11af35c19dc0f").unwrap(), ); // normal assert_eq!(**extended_secret.derive(0.into()).as_raw(), H256::from_str("bf6a74e3f7b36fc4c96a1e12f31abc817f9f5904f5a8fc27713163d1f0b713f6").unwrap()); assert_eq!(**extended_secret.derive(1.into()).as_raw(), H256::from_str("bd4fca9eb1f9c201e9448c1eecd66e302d68d4d313ce895b8c134f512205c1bc").unwrap()); assert_eq!(**extended_secret.derive(2.into()).as_raw(), H256::from_str("86932b542d6cab4d9c65490c7ef502d89ecc0e2a5f4852157649e3251e2a3268").unwrap()); let extended_public = ExtendedPublic::from_secret(&extended_secret).expect("Extended public should be created"); let derived_public = extended_public.derive(0.into()).expect("First derivation of public should succeed"); assert_eq!( *derived_public.public(), H512::from_str("f7b3244c96688f92372bfd4def26dc4151529747bab9f188a4ad34e141d47bd66522ff048bc6f19a0a4429b04318b1a8796c000265b4fa200dae5f6dda92dd94").unwrap(), ); let keypair = ExtendedKeyPair::with_secret( Secret::from_str("a100df7a048e50ed308ea696dc600215098141cb391e9527329df289f9383f65").unwrap(), H256::from_low_u64_be(64), ); assert_eq!( **keypair.derive(2147483648u32.into()).expect("Derivation of keypair should succeed").secret().as_raw(), H256::from_str("edef54414c03196557cf73774bc97a645c9a1df2164ed34f0c2a78d1375a930c").unwrap(), ); } #[test] fn h256_soft_match() { let secret = Secret::from_str("a100df7a048e50ed308ea696dc600215098141cb391e9527329df289f9383f65").unwrap(); let derivation_secret = H256::from_str("51eaf04f9dbbc1417dc97e789edd0c37ecda88bac490434e367ea81b71b7b015").unwrap(); let extended_secret = ExtendedSecret::with_code(secret.clone(), H256::zero()); let extended_public = ExtendedPublic::from_secret(&extended_secret).expect("Extended public should be created"); let derived_secret0 = extended_secret.derive(Derivation::Soft(derivation_secret)); let derived_public0 = extended_public.derive(Derivation::Soft(derivation_secret)).expect("First derivation of public should succeed"); let public_from_secret0 = ExtendedPublic::from_secret(&derived_secret0).expect("Extended public should be created"); assert_eq!(public_from_secret0.public(), derived_public0.public()); } #[test] fn h256_hard() { let secret = Secret::from_str("a100df7a048e50ed308ea696dc600215098141cb391e9527329df289f9383f65").unwrap(); let derivation_secret = H256::from_str("51eaf04f9dbbc1417dc97e789edd0c37ecda88bac490434e367ea81b71b7b015").unwrap(); let extended_secret = ExtendedSecret::with_code(secret.clone(), H256::from_low_u64_be(1)); assert_eq!( **extended_secret.derive(Derivation::Hard(derivation_secret)).as_raw(), H256::from_str("2bc2d696fb744d77ff813b4a1ef0ad64e1e5188b622c54ba917acc5ebc7c5486").unwrap(), ); } #[test] fn match_() { let secret = Secret::from_str("a100df7a048e50ed308ea696dc600215098141cb391e9527329df289f9383f65").unwrap(); let extended_secret = ExtendedSecret::with_code(secret.clone(), H256::from_low_u64_be(1)); let extended_public = ExtendedPublic::from_secret(&extended_secret).expect("Extended public should be created"); let derived_secret0 = extended_secret.derive(0.into()); let derived_public0 = extended_public.derive(0.into()).expect("First derivation of public should succeed"); let public_from_secret0 = ExtendedPublic::from_secret(&derived_secret0).expect("Extended public should be created"); assert_eq!(public_from_secret0.public(), derived_public0.public()); } #[test] fn test_seeds() { let seed = H128::from_str("000102030405060708090a0b0c0d0e0f") .expect("Seed should be valid H128") .as_bytes() .to_vec(); // private key from bitcoin test vector // xprv9wTYmMFdV23N2TdNG573QoEsfRrWKQgWeibmLntzniatZvR9BmLnvSxqu53Kw1UmYPxLgboyZQaXwTCg8MSY3H2EU4pWcQDnRnrVA1xe8fs let test_private = H256::from_str("e8f32e723decf4051aefac8e2c93c9c5b214313817cdb01a1494b917c8436b35") .expect("Private should be decoded ok"); let (private_seed, _) = derivation::seed_pair(&*seed); assert_eq!(private_seed, test_private); } #[test] fn test_vector_1() { // xprv9uHRZZhk6KAJC1avXpDAp4MDc3sQKNxDiPvvkX8Br5ngLNv1TxvUxt4cV1rGL5hj6KCesnDYUhd7oWgT11eZG7XnxHrnYeSvkzY7d2bhkJ7 // H(0) test_extended( |secret| secret.derive(2147483648.into()), H256::from_str("edb2e14f9ee77d26dd93b4ecede8d16ed408ce149b6cd80b0715a2d911a0afea") .expect("Private should be decoded ok") ); } #[test] fn test_vector_2() { // xprv9wTYmMFdV23N2TdNG573QoEsfRrWKQgWeibmLntzniatZvR9BmLnvSxqu53Kw1UmYPxLgboyZQaXwTCg8MSY3H2EU4pWcQDnRnrVA1xe8fs // H(0)/1 test_extended( |secret| secret.derive(2147483648.into()).derive(1.into()), H256::from_str("3c6cb8d0f6a264c91ea8b5030fadaa8e538b020f0a387421a12de9319dc93368") .expect("Private should be decoded ok") ); } }