// Written in 2014 by Andrew Poelstra // SPDX-License-Identifier: CC0-1.0 //! Bitcoin keys. //! //! This module provides keys used in Bitcoin that can be roundtrip //! (de)serialized. use crate::prelude::*; use core::{ops, str::FromStr}; use core::fmt::{self, Write}; use bitcoin_internals::write_err; pub use secp256k1::{self, Secp256k1, XOnlyPublicKey, KeyPair}; use crate::{base58, io}; use crate::network::constants::Network; use crate::hashes::{Hash, hash160, hex, hex::FromHex}; use crate::hash_types::{PubkeyHash, WPubkeyHash}; /// A key-related error. #[derive(Clone, PartialEq, Eq, PartialOrd, Ord, Hash, Debug)] #[non_exhaustive] pub enum Error { /// Base58 encoding error Base58(base58::Error), /// secp256k1-related error Secp256k1(secp256k1::Error), /// Invalid key prefix error InvalidKeyPrefix(u8), /// Hex decoding error Hex(hex::Error) } impl fmt::Display for Error { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { match *self { Error::Base58(ref e) => write_err!(f, "key base58 error"; e), Error::Secp256k1(ref e) => write_err!(f, "key secp256k1 error"; e), Error::InvalidKeyPrefix(ref b) => write!(f, "key prefix invalid: {}", b), Error::Hex(ref e) => write_err!(f, "key hex decoding error"; e) } } } #[cfg(feature = "std")] #[cfg_attr(docsrs, doc(cfg(feature = "std")))] impl std::error::Error for Error { fn source(&self) -> Option<&(dyn std::error::Error + 'static)> { use self::Error::*; match self { Base58(e) => Some(e), Secp256k1(e) => Some(e), InvalidKeyPrefix(_) => None, Hex(e) => Some(e), } } } #[doc(hidden)] impl From for Error { fn from(e: base58::Error) -> Error { Error::Base58(e) } } #[doc(hidden)] impl From for Error { fn from(e: secp256k1::Error) -> Error { Error::Secp256k1(e) } } #[doc(hidden)] impl From for Error { fn from(e: hex::Error) -> Self { Error::Hex(e) } } /// A Bitcoin ECDSA public key #[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)] pub struct PublicKey { /// Whether this public key should be serialized as compressed pub compressed: bool, /// The actual ECDSA key pub inner: secp256k1::PublicKey, } impl PublicKey { /// Constructs compressed ECDSA public key from the provided generic Secp256k1 public key pub fn new(key: secp256k1::PublicKey) -> PublicKey { PublicKey { compressed: true, inner: key, } } /// Constructs uncompressed (legacy) ECDSA public key from the provided generic Secp256k1 /// public key pub fn new_uncompressed(key: secp256k1::PublicKey) -> PublicKey { PublicKey { compressed: false, inner: key, } } fn with_serialized R>(&self, f: F) -> R { if self.compressed { f(&self.inner.serialize()) } else { f(&self.inner.serialize_uncompressed()) } } /// Returns bitcoin 160-bit hash of the public key pub fn pubkey_hash(&self) -> PubkeyHash { self.with_serialized(PubkeyHash::hash) } /// Returns bitcoin 160-bit hash of the public key for witness program pub fn wpubkey_hash(&self) -> Option { if self.compressed { Some(WPubkeyHash::from_inner( hash160::Hash::hash(&self.inner.serialize()).into_inner() )) } else { // We can't create witness pubkey hashes for an uncompressed // public keys None } } /// Write the public key into a writer pub fn write_into(&self, mut writer: W) -> Result<(), io::Error> { self.with_serialized(|bytes| writer.write_all(bytes)) } /// Read the public key from a reader /// /// This internally reads the first byte before reading the rest, so /// use of a `BufReader` is recommended. pub fn read_from(mut reader: R) -> Result { let mut bytes = [0; 65]; reader.read_exact(&mut bytes[0..1])?; let bytes = if bytes[0] < 4 { &mut bytes[..33] } else { &mut bytes[..65] }; reader.read_exact(&mut bytes[1..])?; Self::from_slice(bytes).map_err(|e| { // Need a static string for core2 #[cfg(feature = "std")] let reason = e; #[cfg(not(feature = "std"))] let reason = match e { Error::Base58(_) => "base58 error", Error::Secp256k1(_) => "secp256k1 error", Error::InvalidKeyPrefix(_) => "invalid key prefix", Error::Hex(_) => "hex decoding error" }; io::Error::new(io::ErrorKind::InvalidData, reason) }) } /// Serialize the public key to bytes pub fn to_bytes(self) -> Vec { let mut buf = Vec::new(); self.write_into(&mut buf).expect("vecs don't error"); buf } /// Serialize the public key into a `SortKey`. /// /// `SortKey` is not too useful by itself, but it can be used to sort a /// `[PublicKey]` slice using `sort_unstable_by_key`, `sort_by_cached_key`, /// `sort_by_key`, or any of the other `*_by_key` methods on slice. /// Pass the method into the sort method directly. (ie. `PublicKey::to_sort_key`) /// /// This method of sorting is in line with Bitcoin Core's implementation of /// sorting keys for output descriptors such as `sortedmulti()`. /// /// If every `PublicKey` in the slice is `compressed == true` then this will sort /// the keys in a /// [BIP67](https://github.com/bitcoin/bips/blob/master/bip-0067.mediawiki) /// compliant way. /// /// # Example: Using with `sort_unstable_by_key` /// /// ```rust /// use std::str::FromStr; /// use bitcoin::PublicKey; /// /// let pk = |s| PublicKey::from_str(s).unwrap(); /// /// let mut unsorted = [ /// pk("04c4b0bbb339aa236bff38dbe6a451e111972a7909a126bc424013cba2ec33bc38e98ac269ffe028345c31ac8d0a365f29c8f7e7cfccac72f84e1acd02bc554f35"), /// pk("038f47dcd43ba6d97fc9ed2e3bba09b175a45fac55f0683e8cf771e8ced4572354"), /// pk("028bde91b10013e08949a318018fedbd896534a549a278e220169ee2a36517c7aa"), /// pk("04c4b0bbb339aa236bff38dbe6a451e111972a7909a126bc424013cba2ec33bc3816753d96001fd7cba3ce5372f5c9a0d63708183033538d07b1e532fc43aaacfa"), /// pk("032b8324c93575034047a52e9bca05a46d8347046b91a032eff07d5de8d3f2730b"), /// pk("045d753414fa292ea5b8f56e39cfb6a0287b2546231a5cb05c4b14ab4b463d171f5128148985b23eccb1e2905374873b1f09b9487f47afa6b1f2b0083ac8b4f7e8"), /// pk("0234dd69c56c36a41230d573d68adeae0030c9bc0bf26f24d3e1b64c604d293c68"), /// ]; /// let sorted = [ /// // These first 4 keys are in a BIP67 compatible sorted order /// // (since they are compressed) /// pk("0234dd69c56c36a41230d573d68adeae0030c9bc0bf26f24d3e1b64c604d293c68"), /// pk("028bde91b10013e08949a318018fedbd896534a549a278e220169ee2a36517c7aa"), /// pk("032b8324c93575034047a52e9bca05a46d8347046b91a032eff07d5de8d3f2730b"), /// pk("038f47dcd43ba6d97fc9ed2e3bba09b175a45fac55f0683e8cf771e8ced4572354"), /// // Uncompressed keys are not BIP67 compliant, but are sorted /// // after compressed keys in Bitcoin Core using `sortedmulti()` /// pk("045d753414fa292ea5b8f56e39cfb6a0287b2546231a5cb05c4b14ab4b463d171f5128148985b23eccb1e2905374873b1f09b9487f47afa6b1f2b0083ac8b4f7e8"), /// pk("04c4b0bbb339aa236bff38dbe6a451e111972a7909a126bc424013cba2ec33bc3816753d96001fd7cba3ce5372f5c9a0d63708183033538d07b1e532fc43aaacfa"), /// pk("04c4b0bbb339aa236bff38dbe6a451e111972a7909a126bc424013cba2ec33bc38e98ac269ffe028345c31ac8d0a365f29c8f7e7cfccac72f84e1acd02bc554f35"), /// ]; /// /// unsorted.sort_unstable_by_key(|k| PublicKey::to_sort_key(*k)); /// /// assert_eq!(unsorted, sorted); /// ``` pub fn to_sort_key(self) -> SortKey { if self.compressed { let bytes = self.inner.serialize(); let mut res = [0; 32]; res[..].copy_from_slice(&bytes[1..33]); SortKey(bytes[0], res, [0; 32]) } else { let bytes = self.inner.serialize_uncompressed(); let mut res_left = [0; 32]; let mut res_right = [0; 32]; res_left[..].copy_from_slice(&bytes[1..33]); res_right[..].copy_from_slice(&bytes[33..65]); SortKey(bytes[0], res_left, res_right) } } /// Deserialize a public key from a slice pub fn from_slice(data: &[u8]) -> Result { let compressed = match data.len() { 33 => true, 65 => false, len => { return Err(base58::Error::InvalidLength(len).into()); }, }; if !compressed && data[0] != 0x04 { return Err(Error::InvalidKeyPrefix(data[0])) } Ok(PublicKey { compressed, inner: secp256k1::PublicKey::from_slice(data)?, }) } /// Computes the public key as supposed to be used with this secret pub fn from_private_key(secp: &Secp256k1, sk: &PrivateKey) -> PublicKey { sk.public_key(secp) } } /// An opaque return type for PublicKey::to_sort_key #[derive(Debug, Hash, PartialEq, Eq, PartialOrd, Ord, Clone, Copy)] pub struct SortKey(u8, [u8; 32], [u8; 32]); impl fmt::Display for PublicKey { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { // TODO: fast hex encoding self.with_serialized(|bytes| { for ch in bytes { write!(f, "{:02x}", ch)?; } Ok(()) }) } } impl FromStr for PublicKey { type Err = Error; fn from_str(s: &str) -> Result { match s.len() { 66 => PublicKey::from_slice(&<[u8; 33]>::from_hex(s)?), 130 => PublicKey::from_slice(&<[u8; 65]>::from_hex(s)?), len => Err(Error::Hex(hex::Error::InvalidLength(66, len))), } } } impl From for PubkeyHash { fn from(key: PublicKey) -> PubkeyHash { key.pubkey_hash() } } /// A Bitcoin ECDSA private key #[derive(Copy, Clone, PartialEq, Eq)] #[cfg_attr(feature = "std", derive(Debug))] pub struct PrivateKey { /// Whether this private key should be serialized as compressed pub compressed: bool, /// The network on which this key should be used pub network: Network, /// The actual ECDSA key pub inner: secp256k1::SecretKey, } impl PrivateKey { /// Constructs compressed ECDSA private key from the provided generic Secp256k1 private key /// and the specified network pub fn new(key: secp256k1::SecretKey, network: Network) -> PrivateKey { PrivateKey { compressed: true, network, inner: key, } } /// Constructs uncompressed (legacy) ECDSA private key from the provided generic Secp256k1 /// private key and the specified network pub fn new_uncompressed(key: secp256k1::SecretKey, network: Network) -> PrivateKey { PrivateKey { compressed: false, network, inner: key, } } /// Creates a public key from this private key pub fn public_key(&self, secp: &Secp256k1) -> PublicKey { PublicKey { compressed: self.compressed, inner: secp256k1::PublicKey::from_secret_key(secp, &self.inner) } } /// Serialize the private key to bytes pub fn to_bytes(self) -> Vec { self.inner[..].to_vec() } /// Deserialize a private key from a slice pub fn from_slice(data: &[u8], network: Network) -> Result { Ok(PrivateKey::new(secp256k1::SecretKey::from_slice(data)?, network)) } /// Format the private key to WIF format. pub fn fmt_wif(&self, fmt: &mut dyn fmt::Write) -> fmt::Result { let mut ret = [0; 34]; ret[0] = match self.network { Network::Bitcoin => 128, Network::Testnet | Network::Signet | Network::Regtest => 239, }; ret[1..33].copy_from_slice(&self.inner[..]); let privkey = if self.compressed { ret[33] = 1; base58::encode_check(&ret[..]) } else { base58::encode_check(&ret[..33]) }; fmt.write_str(&privkey) } /// Get WIF encoding of this private key. pub fn to_wif(self) -> String { let mut buf = String::new(); buf.write_fmt(format_args!("{}", self)).unwrap(); buf.shrink_to_fit(); buf } /// Parse WIF encoded private key. pub fn from_wif(wif: &str) -> Result { let data = base58::decode_check(wif)?; let compressed = match data.len() { 33 => false, 34 => true, _ => { return Err(Error::Base58(base58::Error::InvalidLength(data.len()))); } }; let network = match data[0] { 128 => Network::Bitcoin, 239 => Network::Testnet, x => { return Err(Error::Base58(base58::Error::InvalidAddressVersion(x))); } }; Ok(PrivateKey { compressed, network, inner: secp256k1::SecretKey::from_slice(&data[1..33])?, }) } } impl fmt::Display for PrivateKey { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { self.fmt_wif(f) } } #[cfg(not(feature = "std"))] impl fmt::Debug for PrivateKey { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { write!(f, "[private key data]") } } impl FromStr for PrivateKey { type Err = Error; fn from_str(s: &str) -> Result { PrivateKey::from_wif(s) } } impl ops::Index for PrivateKey { type Output = [u8]; fn index(&self, _: ops::RangeFull) -> &[u8] { &self.inner[..] } } #[cfg(feature = "serde")] #[cfg_attr(docsrs, doc(cfg(feature = "serde")))] impl serde::Serialize for PrivateKey { fn serialize(&self, s: S) -> Result { s.collect_str(self) } } #[cfg(feature = "serde")] #[cfg_attr(docsrs, doc(cfg(feature = "serde")))] impl<'de> serde::Deserialize<'de> for PrivateKey { fn deserialize>(d: D) -> Result { struct WifVisitor; impl<'de> serde::de::Visitor<'de> for WifVisitor { type Value = PrivateKey; fn expecting(&self, formatter: &mut core::fmt::Formatter) -> core::fmt::Result { formatter.write_str("an ASCII WIF string") } fn visit_bytes(self, v: &[u8]) -> Result where E: serde::de::Error, { if let Ok(s) = core::str::from_utf8(v) { PrivateKey::from_str(s).map_err(E::custom) } else { Err(E::invalid_value(::serde::de::Unexpected::Bytes(v), &self)) } } fn visit_str(self, v: &str) -> Result where E: serde::de::Error, { PrivateKey::from_str(v).map_err(E::custom) } } d.deserialize_str(WifVisitor) } } #[cfg(feature = "serde")] #[cfg_attr(docsrs, doc(cfg(feature = "serde")))] #[allow(clippy::collapsible_else_if)] // Aids readability. impl serde::Serialize for PublicKey { fn serialize(&self, s: S) -> Result { if s.is_human_readable() { s.collect_str(self) } else { self.with_serialized(|bytes| s.serialize_bytes(bytes)) } } } #[cfg(feature = "serde")] #[cfg_attr(docsrs, doc(cfg(feature = "serde")))] impl<'de> serde::Deserialize<'de> for PublicKey { fn deserialize>(d: D) -> Result { if d.is_human_readable() { struct HexVisitor; impl<'de> serde::de::Visitor<'de> for HexVisitor { type Value = PublicKey; fn expecting(&self, formatter: &mut core::fmt::Formatter) -> core::fmt::Result { formatter.write_str("an ASCII hex string") } fn visit_bytes(self, v: &[u8]) -> Result where E: serde::de::Error, { if let Ok(hex) = core::str::from_utf8(v) { PublicKey::from_str(hex).map_err(E::custom) } else { Err(E::invalid_value(::serde::de::Unexpected::Bytes(v), &self)) } } fn visit_str(self, v: &str) -> Result where E: serde::de::Error, { PublicKey::from_str(v).map_err(E::custom) } } d.deserialize_str(HexVisitor) } else { struct BytesVisitor; impl<'de> serde::de::Visitor<'de> for BytesVisitor { type Value = PublicKey; fn expecting(&self, formatter: &mut core::fmt::Formatter) -> core::fmt::Result { formatter.write_str("a bytestring") } fn visit_bytes(self, v: &[u8]) -> Result where E: serde::de::Error, { PublicKey::from_slice(v).map_err(E::custom) } } d.deserialize_bytes(BytesVisitor) } } } #[cfg(test)] mod tests { use crate::io; use super::{PrivateKey, PublicKey, SortKey}; use secp256k1::Secp256k1; use std::str::FromStr; use crate::hashes::hex::{FromHex, ToHex}; use crate::network::constants::Network::Testnet; use crate::network::constants::Network::Bitcoin; use crate::address::Address; #[test] fn test_key_derivation() { // testnet compressed let sk = PrivateKey::from_wif("cVt4o7BGAig1UXywgGSmARhxMdzP5qvQsxKkSsc1XEkw3tDTQFpy").unwrap(); assert_eq!(sk.network, Testnet); assert!(sk.compressed); assert_eq!(&sk.to_wif(), "cVt4o7BGAig1UXywgGSmARhxMdzP5qvQsxKkSsc1XEkw3tDTQFpy"); let secp = Secp256k1::new(); let pk = Address::p2pkh(&sk.public_key(&secp), sk.network); assert_eq!(&pk.to_string(), "mqwpxxvfv3QbM8PU8uBx2jaNt9btQqvQNx"); // test string conversion assert_eq!(&sk.to_string(), "cVt4o7BGAig1UXywgGSmARhxMdzP5qvQsxKkSsc1XEkw3tDTQFpy"); let sk_str = PrivateKey::from_str("cVt4o7BGAig1UXywgGSmARhxMdzP5qvQsxKkSsc1XEkw3tDTQFpy").unwrap(); assert_eq!(&sk.to_wif(), &sk_str.to_wif()); // mainnet uncompressed let sk = PrivateKey::from_wif("5JYkZjmN7PVMjJUfJWfRFwtuXTGB439XV6faajeHPAM9Z2PT2R3").unwrap(); assert_eq!(sk.network, Bitcoin); assert!(!sk.compressed); assert_eq!(&sk.to_wif(), "5JYkZjmN7PVMjJUfJWfRFwtuXTGB439XV6faajeHPAM9Z2PT2R3"); let secp = Secp256k1::new(); let mut pk = sk.public_key(&secp); assert!(!pk.compressed); assert_eq!(&pk.to_string(), "042e58afe51f9ed8ad3cc7897f634d881fdbe49a81564629ded8156bebd2ffd1af191923a2964c177f5b5923ae500fca49e99492d534aa3759d6b25a8bc971b133"); assert_eq!(pk, PublicKey::from_str("042e58afe51f9ed8ad3cc7897f634d881fdbe49a81564629ded8156bebd2ffd1af191923a2964c177f5b5923ae500fca49e99492d534aa3759d6b25a8bc971b133").unwrap()); let addr = Address::p2pkh(&pk, sk.network); assert_eq!(&addr.to_string(), "1GhQvF6dL8xa6wBxLnWmHcQsurx9RxiMc8"); pk.compressed = true; assert_eq!(&pk.to_string(), "032e58afe51f9ed8ad3cc7897f634d881fdbe49a81564629ded8156bebd2ffd1af"); assert_eq!(pk, PublicKey::from_str("032e58afe51f9ed8ad3cc7897f634d881fdbe49a81564629ded8156bebd2ffd1af").unwrap()); } #[test] fn test_pubkey_hash() { let pk = PublicKey::from_str("032e58afe51f9ed8ad3cc7897f634d881fdbe49a81564629ded8156bebd2ffd1af").unwrap(); let upk = PublicKey::from_str("042e58afe51f9ed8ad3cc7897f634d881fdbe49a81564629ded8156bebd2ffd1af191923a2964c177f5b5923ae500fca49e99492d534aa3759d6b25a8bc971b133").unwrap(); assert_eq!(pk.pubkey_hash().to_hex(), "9511aa27ef39bbfa4e4f3dd15f4d66ea57f475b4"); assert_eq!(upk.pubkey_hash().to_hex(), "ac2e7daf42d2c97418fd9f78af2de552bb9c6a7a"); } #[test] fn test_wpubkey_hash() { let pk = PublicKey::from_str("032e58afe51f9ed8ad3cc7897f634d881fdbe49a81564629ded8156bebd2ffd1af").unwrap(); let upk = PublicKey::from_str("042e58afe51f9ed8ad3cc7897f634d881fdbe49a81564629ded8156bebd2ffd1af191923a2964c177f5b5923ae500fca49e99492d534aa3759d6b25a8bc971b133").unwrap(); assert_eq!(pk.wpubkey_hash().unwrap().to_hex(), "9511aa27ef39bbfa4e4f3dd15f4d66ea57f475b4"); assert_eq!(upk.wpubkey_hash(), None); } #[cfg(feature = "serde")] #[test] fn test_key_serde() { use serde_test::{Configure, Token, assert_tokens}; static KEY_WIF: &str = "cVt4o7BGAig1UXywgGSmARhxMdzP5qvQsxKkSsc1XEkw3tDTQFpy"; static PK_STR: &str = "039b6347398505f5ec93826dc61c19f47c66c0283ee9be980e29ce325a0f4679ef"; static PK_STR_U: &str = "\ 04\ 9b6347398505f5ec93826dc61c19f47c66c0283ee9be980e29ce325a0f4679ef\ 87288ed73ce47fc4f5c79d19ebfa57da7cff3aff6e819e4ee971d86b5e61875d\ "; static PK_BYTES: [u8; 33] = [ 0x03, 0x9b, 0x63, 0x47, 0x39, 0x85, 0x05, 0xf5, 0xec, 0x93, 0x82, 0x6d, 0xc6, 0x1c, 0x19, 0xf4, 0x7c, 0x66, 0xc0, 0x28, 0x3e, 0xe9, 0xbe, 0x98, 0x0e, 0x29, 0xce, 0x32, 0x5a, 0x0f, 0x46, 0x79, 0xef, ]; static PK_BYTES_U: [u8; 65] = [ 0x04, 0x9b, 0x63, 0x47, 0x39, 0x85, 0x05, 0xf5, 0xec, 0x93, 0x82, 0x6d, 0xc6, 0x1c, 0x19, 0xf4, 0x7c, 0x66, 0xc0, 0x28, 0x3e, 0xe9, 0xbe, 0x98, 0x0e, 0x29, 0xce, 0x32, 0x5a, 0x0f, 0x46, 0x79, 0xef, 0x87, 0x28, 0x8e, 0xd7, 0x3c, 0xe4, 0x7f, 0xc4, 0xf5, 0xc7, 0x9d, 0x19, 0xeb, 0xfa, 0x57, 0xda, 0x7c, 0xff, 0x3a, 0xff, 0x6e, 0x81, 0x9e, 0x4e, 0xe9, 0x71, 0xd8, 0x6b, 0x5e, 0x61, 0x87, 0x5d, ]; let s = Secp256k1::new(); let sk = PrivateKey::from_str(KEY_WIF).unwrap(); let pk = PublicKey::from_private_key(&s, &sk); let pk_u = PublicKey { inner: pk.inner, compressed: false, }; assert_tokens(&sk, &[Token::BorrowedStr(KEY_WIF)]); assert_tokens(&pk.compact(), &[Token::BorrowedBytes(&PK_BYTES[..])]); assert_tokens(&pk.readable(), &[Token::BorrowedStr(PK_STR)]); assert_tokens(&pk_u.compact(), &[Token::BorrowedBytes(&PK_BYTES_U[..])]); assert_tokens(&pk_u.readable(), &[Token::BorrowedStr(PK_STR_U)]); } fn random_key(mut seed: u8) -> PublicKey { loop { let mut data = [0; 65]; for byte in &mut data[..] { *byte = seed; // totally a rng seed = seed.wrapping_mul(41).wrapping_add(43); } if data[0] % 2 == 0 { data[0] = 4; if let Ok(key) = PublicKey::from_slice(&data[..]) { return key; } } else { data[0] = 2 + (data[0] >> 7); if let Ok(key) = PublicKey::from_slice(&data[..33]) { return key; } } } } #[test] fn pubkey_read_write() { const N_KEYS: usize = 20; let keys: Vec<_> = (0..N_KEYS).map(|i| random_key(i as u8)).collect(); let mut v = vec![]; for k in &keys { k.write_into(&mut v).expect("writing into vec"); } let mut dec_keys = vec![]; let mut cursor = io::Cursor::new(&v); for _ in 0..N_KEYS { dec_keys.push(PublicKey::read_from(&mut cursor).expect("reading from vec")); } assert_eq!(keys, dec_keys); // sanity checks assert!(PublicKey::read_from(&mut cursor).is_err()); assert!(PublicKey::read_from(io::Cursor::new(&[])).is_err()); assert!(PublicKey::read_from(io::Cursor::new(&[0; 33][..])).is_err()); assert!(PublicKey::read_from(io::Cursor::new(&[2; 32][..])).is_err()); assert!(PublicKey::read_from(io::Cursor::new(&[0; 65][..])).is_err()); assert!(PublicKey::read_from(io::Cursor::new(&[4; 64][..])).is_err()); } #[test] fn pubkey_to_sort_key() { let key1 = PublicKey::from_str("02ff12471208c14bd580709cb2358d98975247d8765f92bc25eab3b2763ed605f8").unwrap(); let key2 = PublicKey { inner: key1.inner, compressed: false, }; let expected1 = SortKey( 2, <[u8; 32]>::from_hex( "ff12471208c14bd580709cb2358d98975247d8765f92bc25eab3b2763ed605f8", ).unwrap(), [0_u8; 32], ); let expected2 = SortKey( 4, <[u8; 32]>::from_hex( "ff12471208c14bd580709cb2358d98975247d8765f92bc25eab3b2763ed605f8", ).unwrap(), <[u8; 32]>::from_hex( "1794e7f3d5e420641a3bc690067df5541470c966cbca8c694bf39aa16d836918", ).unwrap(), ); assert_eq!(key1.to_sort_key(), expected1); assert_eq!(key2.to_sort_key(), expected2); } #[test] fn pubkey_sort() { struct Vector { input: Vec, expect: Vec, } let fmt = |v: Vec<_>| v.into_iter() .map(|s| PublicKey::from_str(s).unwrap()) .collect::>(); let vectors = vec![ // Start BIP67 vectors // Vector 1 Vector { input: fmt(vec![ "02ff12471208c14bd580709cb2358d98975247d8765f92bc25eab3b2763ed605f8", "02fe6f0a5a297eb38c391581c4413e084773ea23954d93f7753db7dc0adc188b2f", ]), expect: fmt(vec![ "02fe6f0a5a297eb38c391581c4413e084773ea23954d93f7753db7dc0adc188b2f", "02ff12471208c14bd580709cb2358d98975247d8765f92bc25eab3b2763ed605f8", ]), }, // Vector 2 (Already sorted, no action required) Vector { input: fmt(vec![ "02632b12f4ac5b1d1b72b2a3b508c19172de44f6f46bcee50ba33f3f9291e47ed0", "027735a29bae7780a9755fae7a1c4374c656ac6a69ea9f3697fda61bb99a4f3e77", "02e2cc6bd5f45edd43bebe7cb9b675f0ce9ed3efe613b177588290ad188d11b404", ]), expect: fmt(vec![ "02632b12f4ac5b1d1b72b2a3b508c19172de44f6f46bcee50ba33f3f9291e47ed0", "027735a29bae7780a9755fae7a1c4374c656ac6a69ea9f3697fda61bb99a4f3e77", "02e2cc6bd5f45edd43bebe7cb9b675f0ce9ed3efe613b177588290ad188d11b404", ]), }, // Vector 3 Vector { input: fmt(vec![ "030000000000000000000000000000000000004141414141414141414141414141", "020000000000000000000000000000000000004141414141414141414141414141", "020000000000000000000000000000000000004141414141414141414141414140", "030000000000000000000000000000000000004141414141414141414141414140", ]), expect: fmt(vec![ "020000000000000000000000000000000000004141414141414141414141414140", "020000000000000000000000000000000000004141414141414141414141414141", "030000000000000000000000000000000000004141414141414141414141414140", "030000000000000000000000000000000000004141414141414141414141414141", ]), }, // Vector 4: (from bitcore) Vector { input: fmt(vec![ "022df8750480ad5b26950b25c7ba79d3e37d75f640f8e5d9bcd5b150a0f85014da", "03e3818b65bcc73a7d64064106a859cc1a5a728c4345ff0b641209fba0d90de6e9", "021f2f6e1e50cb6a953935c3601284925decd3fd21bc445712576873fb8c6ebc18", ]), expect: fmt(vec![ "021f2f6e1e50cb6a953935c3601284925decd3fd21bc445712576873fb8c6ebc18", "022df8750480ad5b26950b25c7ba79d3e37d75f640f8e5d9bcd5b150a0f85014da", "03e3818b65bcc73a7d64064106a859cc1a5a728c4345ff0b641209fba0d90de6e9", ]), }, // Non-BIP67 vectors Vector { input: fmt(vec![ "02c690d642c1310f3a1ababad94e3930e4023c930ea472e7f37f660fe485263b88", "0234dd69c56c36a41230d573d68adeae0030c9bc0bf26f24d3e1b64c604d293c68", "041a181bd0e79974bd7ca552e09fc42ba9c3d5dbb3753741d6f0ab3015dbfd9a22d6b001a32f5f51ac6f2c0f35e73a6a62f59e848fa854d3d21f3f231594eeaa46", "032b8324c93575034047a52e9bca05a46d8347046b91a032eff07d5de8d3f2730b", "04c4b0bbb339aa236bff38dbe6a451e111972a7909a126bc424013cba2ec33bc3816753d96001fd7cba3ce5372f5c9a0d63708183033538d07b1e532fc43aaacfa", "028e1c947c8c0b8ed021088b8e981491ac7af2b8fabebea1abdb448424c8ed75b7", "045d753414fa292ea5b8f56e39cfb6a0287b2546231a5cb05c4b14ab4b463d171f5128148985b23eccb1e2905374873b1f09b9487f47afa6b1f2b0083ac8b4f7e8", "03004a8a3d242d7957c0b60fb7208d386fa6a0193aabd1f3f095ffd0ac097e447b", "04eb0db2d71ccbb0edd8fb35092cbcae2f7fa1f06d4c170804bf52007924b569a8d2d6f6bc8fd2b3caa3253fa1bb674443743bf7fb9f94f9c0b0831a252894cfa8", "04516cde23e14f2319423b7a4a7ae48b1dadceb5e9c123198d417d10895684c42eb05e210f90ccbc72448803a22312e3f122ff2939956ccef4f7316f836295ddd5", "038f47dcd43ba6d97fc9ed2e3bba09b175a45fac55f0683e8cf771e8ced4572354", "04c6bec3b07586a4b085a78cbb97e9bab6f1d3c9ebf299b65dec85213c5eacd44487de86017183120bb7ea3b6c6660c5037615fe1add2a73f800cbeeae22c60438", "03e1a1cfa9eaff604ae237b7af31ffe4c01be22eb96f3da0e62c5850dd4b4386c1", "028d3a2d9f1b1c5c75845944f93bc183ba23aecde53f1978b8aa1b77661be6114f", "028bde91b10013e08949a318018fedbd896534a549a278e220169ee2a36517c7aa", "04c4b0bbb339aa236bff38dbe6a451e111972a7909a126bc424013cba2ec33bc38e98ac269ffe028345c31ac8d0a365f29c8f7e7cfccac72f84e1acd02bc554f35", ]), expect: fmt(vec![ "0234dd69c56c36a41230d573d68adeae0030c9bc0bf26f24d3e1b64c604d293c68", "028bde91b10013e08949a318018fedbd896534a549a278e220169ee2a36517c7aa", "028d3a2d9f1b1c5c75845944f93bc183ba23aecde53f1978b8aa1b77661be6114f", "028e1c947c8c0b8ed021088b8e981491ac7af2b8fabebea1abdb448424c8ed75b7", "02c690d642c1310f3a1ababad94e3930e4023c930ea472e7f37f660fe485263b88", "03004a8a3d242d7957c0b60fb7208d386fa6a0193aabd1f3f095ffd0ac097e447b", "032b8324c93575034047a52e9bca05a46d8347046b91a032eff07d5de8d3f2730b", "038f47dcd43ba6d97fc9ed2e3bba09b175a45fac55f0683e8cf771e8ced4572354", "03e1a1cfa9eaff604ae237b7af31ffe4c01be22eb96f3da0e62c5850dd4b4386c1", "041a181bd0e79974bd7ca552e09fc42ba9c3d5dbb3753741d6f0ab3015dbfd9a22d6b001a32f5f51ac6f2c0f35e73a6a62f59e848fa854d3d21f3f231594eeaa46", "04516cde23e14f2319423b7a4a7ae48b1dadceb5e9c123198d417d10895684c42eb05e210f90ccbc72448803a22312e3f122ff2939956ccef4f7316f836295ddd5", "045d753414fa292ea5b8f56e39cfb6a0287b2546231a5cb05c4b14ab4b463d171f5128148985b23eccb1e2905374873b1f09b9487f47afa6b1f2b0083ac8b4f7e8", // These two pubkeys are mirrored. This helps verify the sort past the x value. "04c4b0bbb339aa236bff38dbe6a451e111972a7909a126bc424013cba2ec33bc3816753d96001fd7cba3ce5372f5c9a0d63708183033538d07b1e532fc43aaacfa", "04c4b0bbb339aa236bff38dbe6a451e111972a7909a126bc424013cba2ec33bc38e98ac269ffe028345c31ac8d0a365f29c8f7e7cfccac72f84e1acd02bc554f35", "04c6bec3b07586a4b085a78cbb97e9bab6f1d3c9ebf299b65dec85213c5eacd44487de86017183120bb7ea3b6c6660c5037615fe1add2a73f800cbeeae22c60438", "04eb0db2d71ccbb0edd8fb35092cbcae2f7fa1f06d4c170804bf52007924b569a8d2d6f6bc8fd2b3caa3253fa1bb674443743bf7fb9f94f9c0b0831a252894cfa8", ]), }, ]; for mut vector in vectors { vector.input.sort_by_cached_key(|k| PublicKey::to_sort_key(*k)); assert_eq!(vector.input, vector.expect); } } }