rust-bitcoin-unsafe-fast/bitcoin/src/address.rs

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// Written in 2014 by Andrew Poelstra <apoelstra@wpsoftware.net>
// SPDX-License-Identifier: CC0-1.0
//! Bitcoin addresses.
//!
//! Support for ordinary base58 Bitcoin addresses and private keys.
//!
//! # Example: creating a new address from a randomly-generated key pair
//!
//! ```rust
//! # #[cfg(feature = "rand-std")] {
//! use bitcoin::{Address, PublicKey, Network};
//! use bitcoin::secp256k1::{rand, Secp256k1};
//!
//! // Generate random key pair.
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//! let s = Secp256k1::new();
//! let public_key = PublicKey::new(s.generate_keypair(&mut rand::thread_rng()).1);
//!
//! // Generate pay-to-pubkey-hash address.
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//! let address = Address::p2pkh(&public_key, Network::Bitcoin);
//! # }
//! ```
//!
//! # Note: creating a new address requires the rand-std feature flag
//!
//! ```toml
//! bitcoin = { version = "...", features = ["rand-std"] }
//! ```
use core::convert::TryFrom;
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use core::fmt;
use core::marker::PhantomData;
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use core::str::FromStr;
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use bech32;
use bitcoin_internals::write_err;
use secp256k1::{Secp256k1, Verification, XOnlyPublicKey};
use crate::base58;
use crate::blockdata::constants::{
MAX_SCRIPT_ELEMENT_SIZE, PUBKEY_ADDRESS_PREFIX_MAIN, PUBKEY_ADDRESS_PREFIX_TEST,
SCRIPT_ADDRESS_PREFIX_MAIN, SCRIPT_ADDRESS_PREFIX_TEST,
};
use crate::blockdata::opcodes::all::*;
use crate::blockdata::script::Instruction;
use crate::blockdata::{opcodes, script};
use crate::crypto::key::PublicKey;
use crate::crypto::schnorr::{TapTweak, TweakedPublicKey, UntweakedPublicKey};
use crate::error::ParseIntError;
use crate::hash_types::{PubkeyHash, ScriptHash};
use crate::hashes::{sha256, Hash, HashEngine};
use crate::network::constants::Network;
use crate::prelude::*;
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use crate::taproot::TapNodeHash;
/// Address error.
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#[derive(Debug, PartialEq, Eq, Clone)]
#[non_exhaustive]
pub enum Error {
/// Base58 encoding error.
Base58(base58::Error),
/// Bech32 encoding error.
Bech32(bech32::Error),
/// The bech32 payload was empty.
EmptyBech32Payload,
/// The wrong checksum algorithm was used. See BIP-0350.
InvalidBech32Variant {
/// Bech32 variant that is required by the used Witness version.
expected: bech32::Variant,
/// The actual Bech32 variant encoded in the address representation.
found: bech32::Variant,
},
/// Script version must be 0 to 16 inclusive.
InvalidWitnessVersion(u8),
/// Unable to parse witness version from string.
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UnparsableWitnessVersion(ParseIntError),
/// Bitcoin script opcode does not match any known witness version, the script is malformed.
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MalformedWitnessVersion,
/// The witness program must be between 2 and 40 bytes in length.
InvalidWitnessProgramLength(usize),
/// A v0 witness program must be either of length 20 or 32.
InvalidSegwitV0ProgramLength(usize),
/// An uncompressed pubkey was used where it is not allowed.
UncompressedPubkey,
/// Address size more than 520 bytes is not allowed.
ExcessiveScriptSize,
/// Script is not a p2pkh, p2sh or witness program.
UnrecognizedScript,
/// Address type is either invalid or not supported in rust-bitcoin.
UnknownAddressType(String),
/// Address's network differs from required one.
NetworkValidation {
/// Network that was required.
required: Network,
/// Network on which the address was found to be valid.
found: Network
}
}
impl fmt::Display for Error {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
match *self {
Error::Base58(ref e) => write_err!(f, "base58 address encoding error"; e),
Error::Bech32(ref e) => write_err!(f, "bech32 address encoding error"; e),
Error::EmptyBech32Payload => write!(f, "the bech32 payload was empty"),
Error::InvalidBech32Variant { expected, found } => write!(f, "invalid bech32 checksum variant found {:?} when {:?} was expected", found, expected),
Error::InvalidWitnessVersion(v) => write!(f, "invalid witness script version: {}", v),
Error::UnparsableWitnessVersion(ref e) => write_err!(f, "incorrect format of a witness version byte"; e),
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Error::MalformedWitnessVersion => f.write_str("bitcoin script opcode does not match any known witness version, the script is malformed"),
Error::InvalidWitnessProgramLength(l) => write!(f, "the witness program must be between 2 and 40 bytes in length: length={}", l),
Error::InvalidSegwitV0ProgramLength(l) => write!(f, "a v0 witness program must be either of length 20 or 32 bytes: length={}", l),
Error::UncompressedPubkey => write!(f, "an uncompressed pubkey was used where it is not allowed"),
Error::ExcessiveScriptSize => write!(f, "script size exceed 520 bytes"),
Error::UnrecognizedScript => write!(f, "script is not a p2pkh, p2sh or witness program"),
Error::UnknownAddressType(ref s) => write!(f, "unknown address type: '{}' is either invalid or not supported in rust-bitcoin", s),
Error::NetworkValidation { required, found } => write!(f, "address's network {} is different from required {}", found, required),
}
}
}
#[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),
Bech32(e) => Some(e),
UnparsableWitnessVersion(e) => Some(e),
EmptyBech32Payload
| InvalidBech32Variant { .. }
| InvalidWitnessVersion(_)
| MalformedWitnessVersion
| InvalidWitnessProgramLength(_)
| InvalidSegwitV0ProgramLength(_)
| UncompressedPubkey
| ExcessiveScriptSize
| UnrecognizedScript
| UnknownAddressType(_)
| NetworkValidation { .. } => None,
}
}
}
#[doc(hidden)]
impl From<base58::Error> for Error {
fn from(e: base58::Error) -> Error { Error::Base58(e) }
}
#[doc(hidden)]
impl From<bech32::Error> for Error {
fn from(e: bech32::Error) -> Error { Error::Bech32(e) }
}
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/// The different types of addresses.
#[derive(Debug, Clone, Copy, PartialEq, Eq, PartialOrd, Ord, Hash)]
#[non_exhaustive]
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pub enum AddressType {
/// Pay to pubkey hash.
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P2pkh,
/// Pay to script hash.
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P2sh,
/// Pay to witness pubkey hash.
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P2wpkh,
/// Pay to witness script hash.
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P2wsh,
/// Pay to taproot.
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P2tr,
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}
impl fmt::Display for AddressType {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
f.write_str(match *self {
AddressType::P2pkh => "p2pkh",
AddressType::P2sh => "p2sh",
AddressType::P2wpkh => "p2wpkh",
AddressType::P2wsh => "p2wsh",
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AddressType::P2tr => "p2tr",
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})
}
}
impl FromStr for AddressType {
type Err = Error;
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fn from_str(s: &str) -> Result<Self, Self::Err> {
match s {
"p2pkh" => Ok(AddressType::P2pkh),
"p2sh" => Ok(AddressType::P2sh),
"p2wpkh" => Ok(AddressType::P2wpkh),
"p2wsh" => Ok(AddressType::P2wsh),
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"p2tr" => Ok(AddressType::P2tr),
_ => Err(Error::UnknownAddressType(s.to_owned())),
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}
}
}
/// Version of the witness program.
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///
/// Helps limit possible versions of the witness according to the specification. If a plain `u8`
/// type was used instead it would mean that the version may be > 16, which would be incorrect.
///
/// First byte of `scriptPubkey` in transaction output for transactions starting with opcodes
/// ranging from 0 to 16 (inclusive).
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#[derive(Clone, Copy, PartialEq, Eq, PartialOrd, Ord, Hash, Debug)]
#[repr(u8)]
pub enum WitnessVersion {
/// Initial version of witness program. Used for P2WPKH and P2WPK outputs
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V0 = 0,
/// Version of witness program used for Taproot P2TR outputs.
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V1 = 1,
/// Future (unsupported) version of witness program.
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V2 = 2,
/// Future (unsupported) version of witness program.
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V3 = 3,
/// Future (unsupported) version of witness program.
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V4 = 4,
/// Future (unsupported) version of witness program.
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V5 = 5,
/// Future (unsupported) version of witness program.
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V6 = 6,
/// Future (unsupported) version of witness program.
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V7 = 7,
/// Future (unsupported) version of witness program.
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V8 = 8,
/// Future (unsupported) version of witness program.
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V9 = 9,
/// Future (unsupported) version of witness program.
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V10 = 10,
/// Future (unsupported) version of witness program.
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V11 = 11,
/// Future (unsupported) version of witness program.
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V12 = 12,
/// Future (unsupported) version of witness program.
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V13 = 13,
/// Future (unsupported) version of witness program.
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V14 = 14,
/// Future (unsupported) version of witness program.
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V15 = 15,
/// Future (unsupported) version of witness program.
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V16 = 16,
}
/// Prints [`WitnessVersion`] number (from 0 to 16) as integer, without
/// any prefix or suffix.
impl fmt::Display for WitnessVersion {
fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { write!(f, "{}", *self as u8) }
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}
impl FromStr for WitnessVersion {
type Err = Error;
fn from_str(s: &str) -> Result<Self, Self::Err> {
let version: u8 = crate::parse::int(s).map_err(Error::UnparsableWitnessVersion)?;
WitnessVersion::try_from(version)
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}
}
impl WitnessVersion {
/// Returns integer version number representation for a given [`WitnessVersion`] value.
///
/// NB: this is not the same as an integer representation of the opcode signifying witness
/// version in bitcoin script. Thus, there is no function to directly convert witness version
/// into a byte since the conversion requires context (bitcoin script or just a version number).
pub fn to_num(self) -> u8 { self as u8 }
/// Determines the checksum variant. See BIP-0350 for specification.
pub fn bech32_variant(&self) -> bech32::Variant {
match self {
WitnessVersion::V0 => bech32::Variant::Bech32,
_ => bech32::Variant::Bech32m,
}
}
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}
impl TryFrom<bech32::u5> for WitnessVersion {
type Error = Error;
/// Converts 5-bit unsigned integer value matching single symbol from Bech32(m) address encoding
/// ([`bech32::u5`]) into [`WitnessVersion`] variant.
///
/// # Returns
/// Version of the Witness program.
///
/// # Errors
/// If the integer does not correspond to any witness version, errors with
/// [`Error::InvalidWitnessVersion`].
fn try_from(value: bech32::u5) -> Result<Self, Self::Error> { Self::try_from(value.to_u8()) }
}
impl TryFrom<u8> for WitnessVersion {
type Error = Error;
/// Converts an 8-bit unsigned integer value into [`WitnessVersion`] variant.
///
/// # Returns
/// Version of the Witness program.
///
/// # Errors
/// If the integer does not correspond to any witness version, errors with
/// [`Error::InvalidWitnessVersion`].
fn try_from(no: u8) -> Result<Self, Self::Error> {
use WitnessVersion::*;
Ok(match no {
0 => V0,
1 => V1,
2 => V2,
3 => V3,
4 => V4,
5 => V5,
6 => V6,
7 => V7,
8 => V8,
9 => V9,
10 => V10,
11 => V11,
12 => V12,
13 => V13,
14 => V14,
15 => V15,
16 => V16,
wrong => return Err(Error::InvalidWitnessVersion(wrong)),
})
}
}
impl TryFrom<opcodes::All> for WitnessVersion {
type Error = Error;
/// Converts bitcoin script opcode into [`WitnessVersion`] variant.
///
/// # Returns
/// Version of the Witness program (for opcodes in range of `OP_0`..`OP_16`).
///
/// # Errors
/// If the opcode does not correspond to any witness version, errors with
/// [`Error::MalformedWitnessVersion`].
fn try_from(opcode: opcodes::All) -> Result<Self, Self::Error> {
match opcode.to_u8() {
0 => Ok(WitnessVersion::V0),
version if version >= OP_PUSHNUM_1.to_u8() && version <= OP_PUSHNUM_16.to_u8() =>
WitnessVersion::try_from(version - OP_PUSHNUM_1.to_u8() + 1),
_ => Err(Error::MalformedWitnessVersion),
}
}
}
impl<'a> TryFrom<Instruction<'a>> for WitnessVersion {
type Error = Error;
/// Converts bitcoin script [`Instruction`] (parsed opcode) into [`WitnessVersion`] variant.
///
/// # Returns
/// Version of the Witness program for [`Instruction::Op`] and [`Instruction::PushBytes`] with
/// byte value within `1..=16` range.
///
/// # Errors
/// If the opcode does not correspond to any witness version, errors with
/// [`Error::MalformedWitnessVersion`] for the rest of opcodes.
fn try_from(instruction: Instruction) -> Result<Self, Self::Error> {
match instruction {
Instruction::Op(op) => WitnessVersion::try_from(op),
Instruction::PushBytes(bytes) if bytes.is_empty() => Ok(WitnessVersion::V0),
Instruction::PushBytes(_) => Err(Error::MalformedWitnessVersion),
}
}
}
impl From<WitnessVersion> for bech32::u5 {
/// Converts [`WitnessVersion`] instance into corresponding Bech32(m) u5-value ([`bech32::u5`]).
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fn from(version: WitnessVersion) -> Self {
bech32::u5::try_from_u8(version.to_num()).expect("WitnessVersion must be 0..=16")
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}
}
impl From<WitnessVersion> for opcodes::All {
/// Converts [`WitnessVersion`] instance into corresponding Bitcoin scriptopcode (`OP_0`..`OP_16`).
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fn from(version: WitnessVersion) -> opcodes::All {
match version {
WitnessVersion::V0 => OP_PUSHBYTES_0,
no => opcodes::All::from(OP_PUSHNUM_1.to_u8() + no.to_num() - 1),
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}
}
}
/// The method used to produce an address.
#[derive(Debug, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
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pub enum Payload {
/// P2PKH address.
PubkeyHash(PubkeyHash),
/// P2SH address.
ScriptHash(ScriptHash),
/// Segwit address.
WitnessProgram(WitnessProgram),
}
/// Witness program as defined in BIP141.
#[derive(Debug, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub struct WitnessProgram {
/// The witness program version.
version: WitnessVersion,
/// The witness program. (Between 2 and 40 bytes)
program: Vec<u8>,
}
impl WitnessProgram {
/// Creates a new witness program.
pub fn new(version: WitnessVersion, program: Vec<u8>) -> Result<Self, Error> {
if program.len() < 2 || program.len() > 40 {
return Err(Error::InvalidWitnessProgramLength(program.len()));
}
// Specific segwit v0 check. These addresses can never spend funds sent to them.
if version == WitnessVersion::V0 && (program.len() != 20 && program.len() != 32) {
return Err(Error::InvalidSegwitV0ProgramLength(program.len()));
}
Ok(WitnessProgram { version, program })
}
/// Returns the witness program version.
pub fn version(&self) -> WitnessVersion {
self.version
}
/// Returns the witness program.
pub fn program(&self) -> &[u8] {
&self.program
}
}
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impl Payload {
/// Constructs a [Payload] from an output script (`scriptPubkey`).
pub fn from_script(script: &script::Script) -> Result<Payload, Error> {
Ok(if script.is_p2pkh() {
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let mut hash_inner = [0u8; 20];
hash_inner.copy_from_slice(&script.as_bytes()[3..23]);
Payload::PubkeyHash(PubkeyHash::from_inner(hash_inner))
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} else if script.is_p2sh() {
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let mut hash_inner = [0u8; 20];
hash_inner.copy_from_slice(&script.as_bytes()[2..22]);
Payload::ScriptHash(ScriptHash::from_inner(hash_inner))
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} else if script.is_witness_program() {
let opcode = script.first_opcode().expect("witness_version guarantees len() > 4");
let witness_program = WitnessProgram::new(
WitnessVersion::try_from(opcode)?,
script.as_bytes()[2..].to_vec(),
)?;
Payload::WitnessProgram(witness_program)
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} else {
return Err(Error::UnrecognizedScript);
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})
}
/// Generates a script pubkey spending to this [Payload].
pub fn script_pubkey(&self) -> script::ScriptBuf {
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match *self {
Payload::PubkeyHash(ref hash) => script::ScriptBuf::new_p2pkh(hash),
Payload::ScriptHash(ref hash) => script::ScriptBuf::new_p2sh(hash),
Payload::WitnessProgram(ref prog) =>
script::ScriptBuf::new_witness_program(prog)
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}
}
/// Creates a pay to (compressed) public key hash payload from a public key
#[inline]
pub fn p2pkh(pk: &PublicKey) -> Payload { Payload::PubkeyHash(pk.pubkey_hash()) }
/// Creates a pay to script hash P2SH payload from a script
#[inline]
pub fn p2sh(script: &script::Script) -> Result<Payload, Error> {
if script.len() > MAX_SCRIPT_ELEMENT_SIZE {
return Err(Error::ExcessiveScriptSize);
}
Ok(Payload::ScriptHash(script.script_hash()))
}
/// Create a witness pay to public key payload from a public key
pub fn p2wpkh(pk: &PublicKey) -> Result<Payload, Error> {
let prog = WitnessProgram::new(
WitnessVersion::V0,
pk.wpubkey_hash().ok_or(Error::UncompressedPubkey)?.as_ref().to_vec()
)?;
Ok(Payload::WitnessProgram(prog))
}
/// Create a pay to script payload that embeds a witness pay to public key
pub fn p2shwpkh(pk: &PublicKey) -> Result<Payload, Error> {
let builder = script::Builder::new()
.push_int(0)
.push_slice(pk.wpubkey_hash().ok_or(Error::UncompressedPubkey)?.as_ref());
Ok(Payload::ScriptHash(builder.into_script().script_hash()))
}
/// Create a witness pay to script hash payload.
pub fn p2wsh(script: &script::Script) -> Payload {
let prog = WitnessProgram::new(
WitnessVersion::V0,
script.wscript_hash().as_ref().to_vec()
).expect("wscript_hash has len 32 compatible with segwitv0");
Payload::WitnessProgram(prog)
}
/// Create a pay to script payload that embeds a witness pay to script hash address
pub fn p2shwsh(script: &script::Script) -> Payload {
let ws =
script::Builder::new().push_int(0).push_slice(script.wscript_hash().as_ref()).into_script();
Payload::ScriptHash(ws.script_hash())
}
/// Create a pay to taproot payload from untweaked key
pub fn p2tr<C: Verification>(
secp: &Secp256k1<C>,
internal_key: UntweakedPublicKey,
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merkle_root: Option<TapNodeHash>,
) -> Payload {
let (output_key, _parity) = internal_key.tap_tweak(secp, merkle_root);
let prog = WitnessProgram::new(
WitnessVersion::V1,
output_key.to_inner().serialize().to_vec()
).expect("taproot output key has len 32 <= 40");
Payload::WitnessProgram(prog)
}
/// Create a pay to taproot payload from a pre-tweaked output key.
///
/// This method is not recommended for use and [Payload::p2tr()] should be used where possible.
pub fn p2tr_tweaked(output_key: TweakedPublicKey) -> Payload {
let prog = WitnessProgram::new(
WitnessVersion::V1,
output_key.to_inner().serialize().to_vec()
).expect("taproot output key has len 32 <= 40");
Payload::WitnessProgram(prog)
}
/// Returns a byte slice of the payload
pub fn as_bytes(&self) -> &[u8] {
match self {
Payload::ScriptHash(hash) => hash.as_ref(),
Payload::PubkeyHash(hash) => hash.as_ref(),
Payload::WitnessProgram(prog) => prog.program(),
}
}
}
/// A utility struct to encode an address payload with the given parameters.
/// This is a low-level utility struct. Consider using `Address` instead.
pub struct AddressEncoding<'a> {
/// The address payload to encode.
pub payload: &'a Payload,
/// base58 version byte for p2pkh payloads (e.g. 0x00 for "1..." addresses).
pub p2pkh_prefix: u8,
/// base58 version byte for p2sh payloads (e.g. 0x05 for "3..." addresses).
pub p2sh_prefix: u8,
/// hrp used in bech32 addresss (e.g. "bc" for "bc1..." addresses).
pub bech32_hrp: &'a str,
}
impl<'a> fmt::Display for AddressEncoding<'a> {
fn fmt(&self, fmt: &mut fmt::Formatter) -> fmt::Result {
match self.payload {
Payload::PubkeyHash(hash) => {
let mut prefixed = [0; 21];
prefixed[0] = self.p2pkh_prefix;
prefixed[1..].copy_from_slice(&hash[..]);
base58::encode_check_to_fmt(fmt, &prefixed[..])
}
Payload::ScriptHash(hash) => {
let mut prefixed = [0; 21];
prefixed[0] = self.p2sh_prefix;
prefixed[1..].copy_from_slice(&hash[..]);
base58::encode_check_to_fmt(fmt, &prefixed[..])
}
Payload::WitnessProgram(witness_prog) => {
let (version, prog) = (witness_prog.version(), witness_prog.program());
let mut upper_writer;
let writer = if fmt.alternate() {
upper_writer = UpperWriter(fmt);
&mut upper_writer as &mut dyn fmt::Write
} else {
fmt as &mut dyn fmt::Write
};
let mut bech32_writer =
bech32::Bech32Writer::new(self.bech32_hrp, version.bech32_variant(), writer)?;
bech32::WriteBase32::write_u5(&mut bech32_writer, version.into())?;
bech32::ToBase32::write_base32(&prog, &mut bech32_writer)
}
}
}
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}
mod sealed {
pub trait NetworkValidation {}
impl NetworkValidation for super::NetworkChecked {}
impl NetworkValidation for super::NetworkUnchecked {}
}
/// Marker of status of address's network validation. See section [*Parsing addresses*](Address#parsing-addresses)
/// on [`Address`] for details.
pub trait NetworkValidation: sealed::NetworkValidation {}
/// Marker that address's network has been successfully validated. See section [*Parsing addresses*](Address#parsing-addresses)
/// on [`Address`] for details.
#[derive(Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub enum NetworkChecked {}
/// Marker that address's network has not yet been validated. See section [*Parsing addresses*](Address#parsing-addresses)
/// on [`Address`] for details.
#[derive(Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub enum NetworkUnchecked {}
impl NetworkValidation for NetworkChecked {}
impl NetworkValidation for NetworkUnchecked {}
/// A Bitcoin address.
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///
/// ### Parsing addresses
///
/// When parsing string as an address, one has to pay attention to the network, on which the parsed
/// address is supposed to be valid. For the purpose of this validation, `Address` has
/// [`is_valid_for_network`](Address<NetworkUnchecked>::is_valid_for_network) method. In order to provide more safety,
/// enforced by compiler, `Address` also contains a special marker type, which indicates whether network of the parsed
/// address has been checked. This marker type will prevent from calling certain functions unless the network
/// verification has been successfully completed.
///
/// The result of parsing an address is `Address<NetworkUnchecked>` suggesting that network of the parsed address
/// has not yet been verified. To perform this verification, method [`require_network`](Address<NetworkUnchecked>::require_network)
/// can be called, providing network on which the address is supposed to be valid. If the verification succeeds,
/// `Address<NetworkChecked>` is returned.
///
/// The types `Address` and `Address<NetworkChecked>` are synonymous, i. e. they can be used interchangeably.
///
/// ```rust
/// use std::str::FromStr;
/// use bitcoin::{Address, Network};
/// use bitcoin::address::{NetworkUnchecked, NetworkChecked};
///
/// // variant 1
/// let address: Address<NetworkUnchecked> = "32iVBEu4dxkUQk9dJbZUiBiQdmypcEyJRf".parse().unwrap();
/// let address: Address<NetworkChecked> = address.require_network(Network::Bitcoin).unwrap();
///
/// // variant 2
/// let address: Address = Address::from_str("32iVBEu4dxkUQk9dJbZUiBiQdmypcEyJRf").unwrap()
/// .require_network(Network::Bitcoin).unwrap();
///
/// // variant 3
/// let address: Address<NetworkChecked> = "32iVBEu4dxkUQk9dJbZUiBiQdmypcEyJRf".parse::<Address<_>>()
/// .unwrap().require_network(Network::Bitcoin).unwrap();
/// ```
///
/// ### Formatting addresses
///
/// To format address into its textual representation, both `Debug` (for usage in programmer-facing,
/// debugging context) and `Display` (for user-facing output) can be used, with the following caveats:
///
/// 1. `Display` is implemented only for `Address<NetworkChecked>`:
///
/// ```
/// # use std::str::FromStr;
/// # use bitcoin::address::{Address, NetworkChecked};
/// let address: Address<NetworkChecked> = Address::from_str("132F25rTsvBdp9JzLLBHP5mvGY66i1xdiM")
/// .unwrap().assume_checked();
/// assert_eq!(address.to_string(), "132F25rTsvBdp9JzLLBHP5mvGY66i1xdiM");
/// ```
///
/// ```compile_fail
/// # use std::str::FromStr;
/// # use bitcoin::address::{Address, NetworkChecked};
/// let address: Address<NetworkUnchecked> = Address::from_str("132F25rTsvBdp9JzLLBHP5mvGY66i1xdiM")
/// .unwrap();
/// let s = address.to_string(); // does not compile
/// ```
///
/// 2. `Debug` on `Address<NetworkUnchecked>` does not produce clean address but address wrapped by
/// an indicator that its network has not been checked. This is to encourage programmer to properly
/// check the network and use `Display` in user-facing context.
///
/// ```
/// # use std::str::FromStr;
/// # use bitcoin::address::{Address, NetworkUnchecked};
/// let address: Address<NetworkUnchecked> = Address::from_str("132F25rTsvBdp9JzLLBHP5mvGY66i1xdiM")
/// .unwrap();
/// assert_eq!(format!("{:?}", address), "Address<NetworkUnchecked>(132F25rTsvBdp9JzLLBHP5mvGY66i1xdiM)");
/// ```
///
/// ```
/// # use std::str::FromStr;
/// # use bitcoin::address::{Address, NetworkChecked};
/// let address: Address<NetworkChecked> = Address::from_str("132F25rTsvBdp9JzLLBHP5mvGY66i1xdiM")
/// .unwrap().assume_checked();
/// assert_eq!(format!("{:?}", address), "132F25rTsvBdp9JzLLBHP5mvGY66i1xdiM");
/// ```
///
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/// ### Relevant BIPs
///
/// * [BIP13 - Address Format for pay-to-script-hash](https://github.com/bitcoin/bips/blob/master/bip-0013.mediawiki)
/// * [BIP16 - Pay to Script Hash](https://github.com/bitcoin/bips/blob/master/bip-0016.mediawiki)
/// * [BIP141 - Segregated Witness (Consensus layer)](https://github.com/bitcoin/bips/blob/master/bip-0141.mediawiki)
/// * [BIP142 - Address Format for Segregated Witness](https://github.com/bitcoin/bips/blob/master/bip-0142.mediawiki)
/// * [BIP341 - Taproot: SegWit version 1 spending rules](https://github.com/bitcoin/bips/blob/master/bip-0341.mediawiki)
/// * [BIP350 - Bech32m format for v1+ witness addresses](https://github.com/bitcoin/bips/blob/master/bip-0350.mediawiki)
#[derive(Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub struct Address<V = NetworkChecked>
where
V: NetworkValidation,
{
/// The type of the address.
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pub payload: Payload,
/// The network on which this address is usable.
pub network: Network,
/// Marker of the status of network validation.
_validation: PhantomData<V>,
}
#[cfg(feature = "serde")]
struct DisplayUnchecked<'a>(&'a Address<NetworkUnchecked>);
#[cfg(feature = "serde")]
impl fmt::Display for DisplayUnchecked<'_> {
fn fmt(&self, fmt: &mut fmt::Formatter) -> fmt::Result { self.0.fmt_internal(fmt) }
}
#[cfg(feature = "serde")]
crate::serde_utils::serde_string_serialize_impl!(Address, "a Bitcoin address");
#[cfg(feature = "serde")]
crate::serde_utils::serde_string_deserialize_impl!(Address<NetworkUnchecked>, "a Bitcoin address");
#[cfg(feature = "serde")]
impl serde::Serialize for Address<NetworkUnchecked> {
fn serialize<S>(&self, serializer: S) -> Result<S::Ok, S::Error>
where
S: serde::Serializer,
{
serializer.collect_str(&DisplayUnchecked(self))
}
}
/// Methods on [`Address`] that can be called on both `Address<NetworkChecked>` and
/// `Address<NetworkUnchecked>`.
impl<V: NetworkValidation> Address<V> {
/// Gets the address type of the address.
///
/// This method is publicly available as [`address_type`](Address<NetworkChecked>::address_type)
/// on `Address<NetworkChecked>` but internally can be called on `Address<NetworkUnchecked>` as
/// `address_type_internal`.
///
/// # Returns
/// None if unknown, non-standard or related to the future witness version.
fn address_type_internal(&self) -> Option<AddressType> {
match self.payload {
Payload::PubkeyHash(_) => Some(AddressType::P2pkh),
Payload::ScriptHash(_) => Some(AddressType::P2sh),
Payload::WitnessProgram(ref prog) => {
// BIP-141 p2wpkh or p2wsh addresses.
match prog.version() {
WitnessVersion::V0 => match prog.program().len() {
20 => Some(AddressType::P2wpkh),
32 => Some(AddressType::P2wsh),
_ => unreachable!("Address creation invariant violation: invalid program length")
},
WitnessVersion::V1 if prog.program().len() == 32 => Some(AddressType::P2tr),
_ => None,
}
}
}
}
/// Format the address for the usage by `Debug` and `Display` implementations.
fn fmt_internal(&self, fmt: &mut fmt::Formatter) -> fmt::Result {
let p2pkh_prefix = match self.network {
Network::Bitcoin => PUBKEY_ADDRESS_PREFIX_MAIN,
Network::Testnet | Network::Signet | Network::Regtest => PUBKEY_ADDRESS_PREFIX_TEST,
};
let p2sh_prefix = match self.network {
Network::Bitcoin => SCRIPT_ADDRESS_PREFIX_MAIN,
Network::Testnet | Network::Signet | Network::Regtest => SCRIPT_ADDRESS_PREFIX_TEST,
};
let bech32_hrp = match self.network {
Network::Bitcoin => "bc",
Network::Testnet | Network::Signet => "tb",
Network::Regtest => "bcrt",
};
let encoding =
AddressEncoding { payload: &self.payload, p2pkh_prefix, p2sh_prefix, bech32_hrp };
use fmt::Display;
encoding.fmt(fmt)
}
/// Create new address from given components, infering the network validation
/// marker type of the address.
#[inline]
pub fn new(network: Network, payload: Payload) -> Address<V> {
Address { network, payload, _validation: PhantomData }
}
}
/// Methods and functions that can be called only on `Address<NetworkChecked>`.
impl Address {
/// Creates a pay to (compressed) public key hash address from a public key.
///
/// This is the preferred non-witness type address.
#[inline]
pub fn p2pkh(pk: &PublicKey, network: Network) -> Address {
Address::new(network, Payload::p2pkh(pk))
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}
/// Creates a pay to script hash P2SH address from a script.
///
/// This address type was introduced with BIP16 and is the popular type to implement multi-sig
/// these days.
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#[inline]
pub fn p2sh(script: &script::Script, network: Network) -> Result<Address, Error> {
Ok(Address::new(network, Payload::p2sh(script)?))
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}
/// Creates a witness pay to public key address from a public key.
///
/// This is the native segwit address type for an output redeemable with a single signature.
///
/// # Errors
/// Will only return an error if an uncompressed public key is provided.
pub fn p2wpkh(pk: &PublicKey, network: Network) -> Result<Address, Error> {
Ok(Address::new(network, Payload::p2wpkh(pk)?))
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}
/// Creates a pay to script address that embeds a witness pay to public key.
///
/// This is a segwit address type that looks familiar (as p2sh) to legacy clients.
///
/// # Errors
/// Will only return an Error if an uncompressed public key is provided.
pub fn p2shwpkh(pk: &PublicKey, network: Network) -> Result<Address, Error> {
Ok(Address::new(network, Payload::p2shwpkh(pk)?))
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}
/// Creates a witness pay to script hash address.
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pub fn p2wsh(script: &script::Script, network: Network) -> Address {
Address::new(network, Payload::p2wsh(script))
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}
/// Creates a pay to script address that embeds a witness pay to script hash address.
///
/// This is a segwit address type that looks familiar (as p2sh) to legacy clients.
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pub fn p2shwsh(script: &script::Script, network: Network) -> Address {
Address::new(network, Payload::p2shwsh(script))
}
/// Creates a pay to taproot address from an untweaked key.
pub fn p2tr<C: Verification>(
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secp: &Secp256k1<C>,
internal_key: UntweakedPublicKey,
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merkle_root: Option<TapNodeHash>,
network: Network,
) -> Address {
Address::new(network, Payload::p2tr(secp, internal_key, merkle_root))
}
/// Creates a pay to taproot address from a pre-tweaked output key.
///
/// This method is not recommended for use, [`Address::p2tr()`] should be used where possible.
pub fn p2tr_tweaked(output_key: TweakedPublicKey, network: Network) -> Address {
Address::new(network, Payload::p2tr_tweaked(output_key))
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}
/// Gets the address type of the address.
///
/// # Returns
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/// None if unknown, non-standard or related to the future witness version.
#[inline]
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pub fn address_type(&self) -> Option<AddressType> {
self.address_type_internal()
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}
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/// Checks whether or not the address is following Bitcoin standardness rules when
/// *spending* from this address. *NOT* to be called by senders.
///
/// <details>
/// <summary>Spending Standardness</summary>
///
/// For forward compatibility, the senders must send to any [`Address`]. Receivers
/// can use this method to check whether or not they can spend from this address.
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///
/// SegWit addresses with unassigned witness versions or non-standard program sizes are
/// considered non-standard.
/// </details>
///
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pub fn is_spend_standard(&self) -> bool { self.address_type().is_some() }
/// Checks whether or not the address is following Bitcoin standardness rules.
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///
/// SegWit addresses with unassigned witness versions or non-standard program sizes are
/// considered non-standard.
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#[deprecated(since = "0.30.0", note = "Use Address::is_spend_standard instead")]
pub fn is_standard(&self) -> bool { self.address_type().is_some() }
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/// Constructs an [`Address`] from an output script (`scriptPubkey`).
pub fn from_script(script: &script::Script, network: Network) -> Result<Address, Error> {
Ok(Address::new(network, Payload::from_script(script)?))
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}
/// Generates a script pubkey spending to this address.
pub fn script_pubkey(&self) -> script::ScriptBuf { self.payload.script_pubkey() }
/// Creates a URI string *bitcoin:address* optimized to be encoded in QR codes.
///
/// If the address is bech32, both the schema and the address become uppercase.
/// If the address is base58, the schema is lowercase and the address is left mixed case.
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///
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/// Quoting BIP 173 "inside QR codes uppercase SHOULD be used, as those permit the use of
/// alphanumeric mode, which is 45% more compact than the normal byte mode."
pub fn to_qr_uri(&self) -> String {
let schema = match self.payload {
Payload::WitnessProgram { .. } => "BITCOIN",
_ => "bitcoin",
};
format!("{}:{:#}", schema, self)
}
/// Returns true if the given pubkey is directly related to the address payload.
///
/// This is determined by directly comparing the address payload with either the
/// hash of the given public key or the segwit redeem hash generated from the
/// given key. For taproot addresses, the supplied key is assumed to be tweaked
pub fn is_related_to_pubkey(&self, pubkey: &PublicKey) -> bool {
let pubkey_hash = pubkey.pubkey_hash();
let payload = self.payload.as_bytes();
let xonly_pubkey = XOnlyPublicKey::from(pubkey.inner);
(*pubkey_hash.as_ref() == *payload)
|| (xonly_pubkey.serialize() == *payload)
|| (*segwit_redeem_hash(&pubkey_hash).as_ref() == *payload)
}
/// Returns true if the supplied xonly public key can be used to derive the address.
///
/// This will only work for Taproot addresses. The Public Key is
/// assumed to have already been tweaked.
pub fn is_related_to_xonly_pubkey(&self, xonly_pubkey: &XOnlyPublicKey) -> bool {
let payload = self.payload.as_bytes();
payload == xonly_pubkey.serialize()
}
}
/// Methods that can be called only on `Address<NetworkUnchecked>`.
impl Address<NetworkUnchecked> {
/// Parsed addresses do not always have *one* network. The problem is that legacy testnet,
/// regtest and signet addresse use the same prefix instead of multiple different ones. When
/// parsing, such addresses are always assumed to be testnet addresses (the same is true for
/// bech32 signet addresses). So if one wants to check if an address belongs to a certain
/// network a simple comparison is not enough anymore. Instead this function can be used.
///
/// ```rust
/// use bitcoin::{Address, Network};
/// use bitcoin::address::NetworkUnchecked;
///
/// let address: Address<NetworkUnchecked> = "2N83imGV3gPwBzKJQvWJ7cRUY2SpUyU6A5e".parse().unwrap();
/// assert!(address.is_valid_for_network(Network::Testnet));
/// assert!(address.is_valid_for_network(Network::Regtest));
/// assert!(address.is_valid_for_network(Network::Signet));
///
/// assert_eq!(address.is_valid_for_network(Network::Bitcoin), false);
///
/// let address: Address<NetworkUnchecked> = "32iVBEu4dxkUQk9dJbZUiBiQdmypcEyJRf".parse().unwrap();
/// assert!(address.is_valid_for_network(Network::Bitcoin));
/// assert_eq!(address.is_valid_for_network(Network::Testnet), false);
/// ```
pub fn is_valid_for_network(&self, network: Network) -> bool {
let is_legacy = match self.address_type_internal() {
Some(AddressType::P2pkh) | Some(AddressType::P2sh) => true,
_ => false,
};
match (self.network, network) {
(a, b) if a == b => true,
(Network::Bitcoin, _) | (_, Network::Bitcoin) => false,
(Network::Regtest, _) | (_, Network::Regtest) if !is_legacy => false,
(Network::Testnet, _) | (Network::Regtest, _) | (Network::Signet, _) => true,
}
}
/// Checks whether network of this address is as required.
///
/// For details about this mechanism, see section [*Parsing addresses*](Address#parsing-addresses)
/// on [`Address`].
#[inline]
pub fn require_network(self, required: Network) -> Result<Address, Error> {
if self.is_valid_for_network(required) {
Ok(self.assume_checked())
} else {
Err(Error::NetworkValidation { found: self.network, required })
}
}
/// Marks, without any additional checks, network of this address as checked.
///
/// Improper use of this method may lead to loss of funds. Reader will most likely prefer
/// [`require_network`](Address<NetworkUnchecked>::require_network) as a safe variant.
/// For details about this mechanism, see section [*Parsing addresses*](Address#parsing-addresses)
/// on [`Address`].
#[inline]
pub fn assume_checked(self) -> Address {
Address::new(self.network, self.payload)
}
}
// Alternate formatting `{:#}` is used to return uppercase version of bech32 addresses which should
// be used in QR codes, see [`Address::to_qr_uri`].
impl fmt::Display for Address {
fn fmt(&self, fmt: &mut fmt::Formatter) -> fmt::Result { self.fmt_internal(fmt) }
}
impl fmt::Debug for Address {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { self.fmt_internal(f) }
}
impl fmt::Debug for Address<NetworkUnchecked> {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
write!(f, "Address<NetworkUnchecked>(")?;
self.fmt_internal(f)?;
write!(f, ")")
}
}
struct UpperWriter<W: fmt::Write>(W);
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impl<W: fmt::Write> fmt::Write for UpperWriter<W> {
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fn write_str(&mut self, s: &str) -> fmt::Result {
for c in s.chars() {
self.0.write_char(c.to_ascii_uppercase())?;
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}
Ok(())
}
}
/// Extracts the bech32 prefix.
///
/// # Returns
/// The input slice if no prefix is found.
fn find_bech32_prefix(bech32: &str) -> &str {
// Split at the last occurrence of the separator character '1'.
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match bech32.rfind('1') {
None => bech32,
Some(sep) => bech32.split_at(sep).0,
}
}
// Address can be parsed only with NetworkUnchecked.
impl FromStr for Address<NetworkUnchecked> {
type Err = Error;
fn from_str(s: &str) -> Result<Address<NetworkUnchecked>, Error> {
// try bech32
let bech32_network = match find_bech32_prefix(s) {
// note that upper or lowercase is allowed but NOT mixed case
"bc" | "BC" => Some(Network::Bitcoin),
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"tb" | "TB" => Some(Network::Testnet), // this may also be signet
"bcrt" | "BCRT" => Some(Network::Regtest),
_ => None,
};
if let Some(network) = bech32_network {
// decode as bech32
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let (_, payload, variant) = bech32::decode(s)?;
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if payload.is_empty() {
return Err(Error::EmptyBech32Payload);
}
// Get the script version and program (converted from 5-bit to 8-bit)
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let (version, program): (WitnessVersion, Vec<u8>) = {
let (v, p5) = payload.split_at(1);
(WitnessVersion::try_from(v[0])?, bech32::FromBase32::from_base32(p5)?)
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};
let witness_program = WitnessProgram::new(version, program)?;
// Encoding check
let expected = version.bech32_variant();
if expected != variant {
return Err(Error::InvalidBech32Variant { expected, found: variant });
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}
return Ok(Address::new(network, Payload::WitnessProgram(witness_program)));
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}
// Base58
if s.len() > 50 {
return Err(Error::Base58(base58::Error::InvalidLength(s.len() * 11 / 15)));
}
let data = base58::decode_check(s)?;
if data.len() != 21 {
return Err(Error::Base58(base58::Error::InvalidLength(data.len())));
}
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let (network, payload) = match data[0] {
PUBKEY_ADDRESS_PREFIX_MAIN =>
(Network::Bitcoin, Payload::PubkeyHash(PubkeyHash::from_slice(&data[1..]).unwrap())),
SCRIPT_ADDRESS_PREFIX_MAIN =>
(Network::Bitcoin, Payload::ScriptHash(ScriptHash::from_slice(&data[1..]).unwrap())),
PUBKEY_ADDRESS_PREFIX_TEST =>
(Network::Testnet, Payload::PubkeyHash(PubkeyHash::from_slice(&data[1..]).unwrap())),
SCRIPT_ADDRESS_PREFIX_TEST =>
(Network::Testnet, Payload::ScriptHash(ScriptHash::from_slice(&data[1..]).unwrap())),
x => return Err(Error::Base58(base58::Error::InvalidAddressVersion(x))),
};
Ok(Address::new(network, payload))
}
}
/// Convert a byte array of a pubkey hash into a segwit redeem hash
fn segwit_redeem_hash(pubkey_hash: &PubkeyHash) -> crate::hashes::hash160::Hash {
let mut sha_engine = sha256::Hash::engine();
sha_engine.input(&[0, 20]);
sha_engine.input(pubkey_hash.as_ref());
crate::hashes::hash160::Hash::from_engine(sha_engine)
}
#[cfg(test)]
mod tests {
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use core::str::FromStr;
use secp256k1::XOnlyPublicKey;
use super::*;
use crate::crypto::key::PublicKey;
use crate::internal_macros::{hex, hex_into, hex_script};
use crate::network::constants::Network::{Bitcoin, Testnet};
fn roundtrips(addr: &Address) {
assert_eq!(
Address::from_str(&addr.to_string()).unwrap().assume_checked(),
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*addr,
"string round-trip failed for {}",
addr,
);
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assert_eq!(
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Address::from_script(&addr.script_pubkey(), addr.network).as_ref(),
Ok(addr),
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"script round-trip failed for {}",
addr,
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);
#[cfg(feature = "serde")]
{
let ser = serde_json::to_string(addr).expect("failed to serialize address");
let back: Address<NetworkUnchecked> = serde_json::from_str(&ser).expect("failed to deserialize address");
assert_eq!(back.assume_checked(), *addr, "serde round-trip failed for {}", addr)
}
}
#[test]
fn test_p2pkh_address_58() {
let addr = Address::new(Bitcoin, Payload::PubkeyHash(hex_into!("162c5ea71c0b23f5b9022ef047c4a86470a5b070")));
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assert_eq!(
addr.script_pubkey(),
hex_script!("76a914162c5ea71c0b23f5b9022ef047c4a86470a5b07088ac")
);
assert_eq!(&addr.to_string(), "132F25rTsvBdp9JzLLBHP5mvGY66i1xdiM");
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assert_eq!(addr.address_type(), Some(AddressType::P2pkh));
roundtrips(&addr);
}
#[test]
fn test_p2pkh_from_key() {
let key = hex_into!("048d5141948c1702e8c95f438815794b87f706a8d4cd2bffad1dc1570971032c9b6042a0431ded2478b5c9cf2d81c124a5e57347a3c63ef0e7716cf54d613ba183");
let addr = Address::p2pkh(&key, Bitcoin);
assert_eq!(&addr.to_string(), "1QJVDzdqb1VpbDK7uDeyVXy9mR27CJiyhY");
let key = hex_into!("03df154ebfcf29d29cc10d5c2565018bce2d9edbab267c31d2caf44a63056cf99f");
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let addr = Address::p2pkh(&key, Testnet);
assert_eq!(&addr.to_string(), "mqkhEMH6NCeYjFybv7pvFC22MFeaNT9AQC");
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assert_eq!(addr.address_type(), Some(AddressType::P2pkh));
roundtrips(&addr);
}
#[test]
fn test_p2sh_address_58() {
let addr = Address::new(Bitcoin, Payload::ScriptHash(hex_into!("162c5ea71c0b23f5b9022ef047c4a86470a5b070")));
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assert_eq!(
addr.script_pubkey(),
hex_script!("a914162c5ea71c0b23f5b9022ef047c4a86470a5b07087")
);
assert_eq!(&addr.to_string(), "33iFwdLuRpW1uK1RTRqsoi8rR4NpDzk66k");
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assert_eq!(addr.address_type(), Some(AddressType::P2sh));
roundtrips(&addr);
}
#[test]
fn test_p2sh_parse() {
let script = hex_script!("552103a765fc35b3f210b95223846b36ef62a4e53e34e2925270c2c7906b92c9f718eb2103c327511374246759ec8d0b89fa6c6b23b33e11f92c5bc155409d86de0c79180121038cae7406af1f12f4786d820a1466eec7bc5785a1b5e4a387eca6d797753ef6db2103252bfb9dcaab0cd00353f2ac328954d791270203d66c2be8b430f115f451b8a12103e79412d42372c55dd336f2eb6eb639ef9d74a22041ba79382c74da2338fe58ad21035049459a4ebc00e876a9eef02e72a3e70202d3d1f591fc0dd542f93f642021f82102016f682920d9723c61b27f562eb530c926c00106004798b6471e8c52c60ee02057ae");
let addr = Address::p2sh(&script, Testnet).unwrap();
assert_eq!(&addr.to_string(), "2N3zXjbwdTcPsJiy8sUK9FhWJhqQCxA8Jjr");
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assert_eq!(addr.address_type(), Some(AddressType::P2sh));
roundtrips(&addr);
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}
#[test]
fn test_p2sh_parse_for_large_script() {
let script = hex_script!("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");
assert_eq!(Address::p2sh(&script, Testnet), Err(Error::ExcessiveScriptSize));
}
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#[test]
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fn test_p2wpkh() {
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// stolen from Bitcoin transaction: b3c8c2b6cfc335abbcb2c7823a8453f55d64b2b5125a9a61e8737230cdb8ce20
let mut key =
hex_into!("033bc8c83c52df5712229a2f72206d90192366c36428cb0c12b6af98324d97bfbc");
let addr = Address::p2wpkh(&key, Bitcoin).unwrap();
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assert_eq!(&addr.to_string(), "bc1qvzvkjn4q3nszqxrv3nraga2r822xjty3ykvkuw");
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assert_eq!(addr.address_type(), Some(AddressType::P2wpkh));
roundtrips(&addr);
// Test uncompressed pubkey
key.compressed = false;
assert_eq!(Address::p2wpkh(&key, Bitcoin), Err(Error::UncompressedPubkey));
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}
#[test]
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fn test_p2wsh() {
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// stolen from Bitcoin transaction 5df912fda4becb1c29e928bec8d64d93e9ba8efa9b5b405bd683c86fd2c65667
let script = hex_script!("52210375e00eb72e29da82b89367947f29ef34afb75e8654f6ea368e0acdfd92976b7c2103a1b26313f430c4b15bb1fdce663207659d8cac749a0e53d70eff01874496feff2103c96d495bfdd5ba4145e3e046fee45e84a8a48ad05bd8dbb395c011a32cf9f88053ae");
let addr = Address::p2wsh(&script, Bitcoin);
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assert_eq!(
&addr.to_string(),
"bc1qwqdg6squsna38e46795at95yu9atm8azzmyvckulcc7kytlcckxswvvzej"
);
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assert_eq!(addr.address_type(), Some(AddressType::P2wsh));
roundtrips(&addr);
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}
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#[test]
fn test_p2shwpkh() {
// stolen from Bitcoin transaction: ad3fd9c6b52e752ba21425435ff3dd361d6ac271531fc1d2144843a9f550ad01
let mut key =
hex_into!("026c468be64d22761c30cd2f12cbc7de255d592d7904b1bab07236897cc4c2e766");
let addr = Address::p2shwpkh(&key, Bitcoin).unwrap();
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assert_eq!(&addr.to_string(), "3QBRmWNqqBGme9er7fMkGqtZtp4gjMFxhE");
assert_eq!(addr.address_type(), Some(AddressType::P2sh));
roundtrips(&addr);
// Test uncompressed pubkey
key.compressed = false;
assert_eq!(Address::p2wpkh(&key, Bitcoin), Err(Error::UncompressedPubkey));
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}
#[test]
fn test_p2shwsh() {
// stolen from Bitcoin transaction f9ee2be4df05041d0e0a35d7caa3157495ca4f93b233234c9967b6901dacf7a9
let script = hex_script!("522103e5529d8eaa3d559903adb2e881eb06c86ac2574ffa503c45f4e942e2a693b33e2102e5f10fcdcdbab211e0af6a481f5532536ec61a5fdbf7183770cf8680fe729d8152ae");
let addr = Address::p2shwsh(&script, Bitcoin);
assert_eq!(&addr.to_string(), "36EqgNnsWW94SreZgBWc1ANC6wpFZwirHr");
assert_eq!(addr.address_type(), Some(AddressType::P2sh));
roundtrips(&addr);
}
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#[test]
fn test_non_existent_segwit_version() {
// 40-byte program
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let program = hex!(
"654f6ea368e0acdfd92976b7c2103a1b26313f430654f6ea368e0acdfd92976b7c2103a1b26313f4"
);
let witness_prog = WitnessProgram::new(WitnessVersion::V13, program).unwrap();
let addr = Address::new(Bitcoin, Payload::WitnessProgram(witness_prog));
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roundtrips(&addr);
}
#[test]
fn test_address_type() {
let addresses = [
("1QJVDzdqb1VpbDK7uDeyVXy9mR27CJiyhY", Some(AddressType::P2pkh)),
("33iFwdLuRpW1uK1RTRqsoi8rR4NpDzk66k", Some(AddressType::P2sh)),
("bc1qvzvkjn4q3nszqxrv3nraga2r822xjty3ykvkuw", Some(AddressType::P2wpkh)),
(
"bc1qwqdg6squsna38e46795at95yu9atm8azzmyvckulcc7kytlcckxswvvzej",
Some(AddressType::P2wsh),
),
(
"bc1p5cyxnuxmeuwuvkwfem96lqzszd02n6xdcjrs20cac6yqjjwudpxqkedrcr",
Some(AddressType::P2tr),
),
// Related to future extensions, addresses are valid but have no type
// segwit v1 and len != 32
("bc1pw508d6qejxtdg4y5r3zarvary0c5xw7kw508d6qejxtdg4y5r3zarvary0c5xw7kt5nd6y", None),
// segwit v2
("bc1zw508d6qejxtdg4y5r3zarvaryvaxxpcs", None),
];
for (address, expected_type) in &addresses {
let addr = Address::from_str(address)
.unwrap()
.require_network(Network::Bitcoin)
.expect("mainnet");
assert_eq!(&addr.address_type(), expected_type);
}
}
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#[test]
fn test_bip173_350_vectors() {
// Test vectors valid under both BIP-173 and BIP-350
let valid_vectors = [
("BC1QW508D6QEJXTDG4Y5R3ZARVARY0C5XW7KV8F3T4", "0014751e76e8199196d454941c45d1b3a323f1433bd6"),
("tb1qrp33g0q5c5txsp9arysrx4k6zdkfs4nce4xj0gdcccefvpysxf3q0sl5k7", "00201863143c14c5166804bd19203356da136c985678cd4d27a1b8c6329604903262"),
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("bc1pw508d6qejxtdg4y5r3zarvary0c5xw7kw508d6qejxtdg4y5r3zarvary0c5xw7kt5nd6y", "5128751e76e8199196d454941c45d1b3a323f1433bd6751e76e8199196d454941c45d1b3a323f1433bd6"),
("BC1SW50QGDZ25J", "6002751e"),
("bc1zw508d6qejxtdg4y5r3zarvaryvaxxpcs", "5210751e76e8199196d454941c45d1b3a323"),
("tb1qqqqqp399et2xygdj5xreqhjjvcmzhxw4aywxecjdzew6hylgvsesrxh6hy", "0020000000c4a5cad46221b2a187905e5266362b99d5e91c6ce24d165dab93e86433"),
("tb1pqqqqp399et2xygdj5xreqhjjvcmzhxw4aywxecjdzew6hylgvsesf3hn0c", "5120000000c4a5cad46221b2a187905e5266362b99d5e91c6ce24d165dab93e86433"),
("bc1p0xlxvlhemja6c4dqv22uapctqupfhlxm9h8z3k2e72q4k9hcz7vqzk5jj0", "512079be667ef9dcbbac55a06295ce870b07029bfcdb2dce28d959f2815b16f81798")
];
for vector in &valid_vectors {
let addr: Address = vector.0.parse::<Address<_>>().unwrap().assume_checked();
assert_eq!(&addr.script_pubkey().to_hex_string(), vector.1);
roundtrips(&addr);
}
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let invalid_vectors = [
// 1. BIP-350 test vectors
// Invalid human-readable part
"tc1p0xlxvlhemja6c4dqv22uapctqupfhlxm9h8z3k2e72q4k9hcz7vq5zuyut",
// Invalid checksums (Bech32 instead of Bech32m):
"bc1p0xlxvlhemja6c4dqv22uapctqupfhlxm9h8z3k2e72q4k9hcz7vqh2y7hd",
"tb1z0xlxvlhemja6c4dqv22uapctqupfhlxm9h8z3k2e72q4k9hcz7vqglt7rf",
"BC1S0XLXVLHEMJA6C4DQV22UAPCTQUPFHLXM9H8Z3K2E72Q4K9HCZ7VQ54WELL",
"bc1qw508d6qejxtdg4y5r3zarvary0c5xw7kemeawh",
"tb1q0xlxvlhemja6c4dqv22uapctqupfhlxm9h8z3k2e72q4k9hcz7vq24jc47",
// Invalid character in checksum
"bc1p38j9r5y49hruaue7wxjce0updqjuyyx0kh56v8s25huc6995vvpql3jow4",
// Invalid witness version
"BC130XLXVLHEMJA6C4DQV22UAPCTQUPFHLXM9H8Z3K2E72Q4K9HCZ7VQ7ZWS8R",
// Invalid program length (1 byte)
"bc1pw5dgrnzv",
// Invalid program length (41 bytes)
"bc1p0xlxvlhemja6c4dqv22uapctqupfhlxm9h8z3k2e72q4k9hcz7v8n0nx0muaewav253zgeav",
// Invalid program length for witness version 0 (per BIP141)
"BC1QR508D6QEJXTDG4Y5R3ZARVARYV98GJ9P",
// Mixed case
"tb1p0xlxvlhemja6c4dqv22uapctqupfhlxm9h8z3k2e72q4k9hcz7vq47Zagq",
// zero padding of more than 4 bits
"bc1p0xlxvlhemja6c4dqv22uapctqupfhlxm9h8z3k2e72q4k9hcz7v07qwwzcrf",
// Non-zero padding in 8-to-5 conversion
"tb1p0xlxvlhemja6c4dqv22uapctqupfhlxm9h8z3k2e72q4k9hcz7vpggkg4j",
// Empty data section
"bc1gmk9yu",
// 2. BIP-173 test vectors
// Invalid human-readable part
"tc1qw508d6qejxtdg4y5r3zarvary0c5xw7kg3g4ty",
// Invalid checksum
"bc1qw508d6qejxtdg4y5r3zarvary0c5xw7kv8f3t5",
// Invalid witness version
"BC13W508D6QEJXTDG4Y5R3ZARVARY0C5XW7KN40WF2",
// Invalid program length
"bc1rw5uspcuh",
// Invalid program length
"bc10w508d6qejxtdg4y5r3zarvary0c5xw7kw508d6qejxtdg4y5r3zarvary0c5xw7kw5rljs90",
// Invalid program length for witness version 0 (per BIP141)
"BC1QR508D6QEJXTDG4Y5R3ZARVARYV98GJ9P",
// Mixed case
"tb1qrp33g0q5c5txsp9arysrx4k6zdkfs4nce4xj0gdcccefvpysxf3q0sL5k7",
// zero padding of more than 4 bits
"bc1zw508d6qejxtdg4y5r3zarvaryvqyzf3du",
// Non-zero padding in 8-to-5 conversion
"tb1qrp33g0q5c5txsp9arysrx4k6zdkfs4nce4xj0gdcccefvpysxf3pjxtptv",
// Final test for empty data section is the same as above in BIP-350
// 3. BIP-173 valid test vectors obsolete by BIP-350
"bc1pw508d6qejxtdg4y5r3zarvary0c5xw7kw508d6qejxtdg4y5r3zarvary0c5xw7k7grplx",
"BC1SW50QA3JX3S",
"bc1zw508d6qejxtdg4y5r3zarvaryvg6kdaj",
];
for vector in &invalid_vectors {
assert!(vector.parse::<Address<_>>().is_err());
}
}
#[test]
#[cfg(feature = "serde")]
fn test_json_serialize() {
use serde_json;
let addr = Address::from_str("132F25rTsvBdp9JzLLBHP5mvGY66i1xdiM").unwrap().assume_checked();
let json = serde_json::to_value(&addr).unwrap();
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assert_eq!(
json,
serde_json::Value::String("132F25rTsvBdp9JzLLBHP5mvGY66i1xdiM".to_owned())
);
let into: Address = serde_json::from_value::<Address<_>>(json).unwrap().assume_checked();
assert_eq!(addr.to_string(), into.to_string());
assert_eq!(
into.script_pubkey(),
hex_script!("76a914162c5ea71c0b23f5b9022ef047c4a86470a5b07088ac")
);
let addr = Address::from_str("33iFwdLuRpW1uK1RTRqsoi8rR4NpDzk66k").unwrap().assume_checked();
let json = serde_json::to_value(&addr).unwrap();
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assert_eq!(
json,
serde_json::Value::String("33iFwdLuRpW1uK1RTRqsoi8rR4NpDzk66k".to_owned())
);
let into: Address = serde_json::from_value::<Address<_>>(json).unwrap().assume_checked();
assert_eq!(addr.to_string(), into.to_string());
assert_eq!(
into.script_pubkey(),
hex_script!("a914162c5ea71c0b23f5b9022ef047c4a86470a5b07087")
);
let addr: Address<NetworkUnchecked> =
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Address::from_str("tb1qrp33g0q5c5txsp9arysrx4k6zdkfs4nce4xj0gdcccefvpysxf3q0sl5k7")
.unwrap();
let json = serde_json::to_value(addr).unwrap();
assert_eq!(
json,
serde_json::Value::String(
"tb1qrp33g0q5c5txsp9arysrx4k6zdkfs4nce4xj0gdcccefvpysxf3q0sl5k7".to_owned()
)
);
let addr =
Address::from_str("tb1qrp33g0q5c5txsp9arysrx4k6zdkfs4nce4xj0gdcccefvpysxf3q0sl5k7")
.unwrap().assume_checked();
let json = serde_json::to_value(&addr).unwrap();
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assert_eq!(
json,
serde_json::Value::String(
"tb1qrp33g0q5c5txsp9arysrx4k6zdkfs4nce4xj0gdcccefvpysxf3q0sl5k7".to_owned()
)
);
let into: Address = serde_json::from_value::<Address<_>>(json).unwrap().assume_checked();
assert_eq!(addr.to_string(), into.to_string());
assert_eq!(
into.script_pubkey(),
hex_script!("00201863143c14c5166804bd19203356da136c985678cd4d27a1b8c6329604903262")
);
let addr = Address::from_str("bcrt1q2nfxmhd4n3c8834pj72xagvyr9gl57n5r94fsl").unwrap().assume_checked();
let json = serde_json::to_value(&addr).unwrap();
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assert_eq!(
json,
serde_json::Value::String("bcrt1q2nfxmhd4n3c8834pj72xagvyr9gl57n5r94fsl".to_owned())
);
let into: Address = serde_json::from_value::<Address<_>>(json).unwrap().assume_checked();
assert_eq!(addr.to_string(), into.to_string());
assert_eq!(
into.script_pubkey(),
hex_script!("001454d26dddb59c7073c6a197946ea1841951fa7a74")
);
}
#[test]
fn test_qr_string() {
for el in
["132F25rTsvBdp9JzLLBHP5mvGY66i1xdiM", "33iFwdLuRpW1uK1RTRqsoi8rR4NpDzk66k"].iter()
{
let addr = Address::from_str(el).unwrap().require_network(Network::Bitcoin).expect("mainnet");
assert_eq!(addr.to_qr_uri(), format!("bitcoin:{}", el));
}
for el in [
"bcrt1q2nfxmhd4n3c8834pj72xagvyr9gl57n5r94fsl",
"bc1qwqdg6squsna38e46795at95yu9atm8azzmyvckulcc7kytlcckxswvvzej",
]
.iter()
{
let addr = Address::from_str(el).unwrap().assume_checked();
assert_eq!(addr.to_qr_uri(), format!("BITCOIN:{}", el.to_ascii_uppercase()));
}
}
#[test]
fn test_valid_networks() {
let legacy_payload = &[
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Payload::PubkeyHash(PubkeyHash::all_zeros()),
Payload::ScriptHash(ScriptHash::all_zeros()),
];
let segwit_payload = (0..=16)
.map(|version| Payload::WitnessProgram(WitnessProgram::new(
WitnessVersion::try_from(version).unwrap(),
vec![0xab; 32], // Choose 32 to make test case valid for all witness versions(including v0)
).unwrap()))
.collect::<Vec<_>>();
const LEGACY_EQUIVALENCE_CLASSES: &[&[Network]] =
&[&[Network::Bitcoin], &[Network::Testnet, Network::Regtest, Network::Signet]];
const SEGWIT_EQUIVALENCE_CLASSES: &[&[Network]] =
&[&[Network::Bitcoin], &[Network::Regtest], &[Network::Testnet, Network::Signet]];
fn test_addr_type(payloads: &[Payload], equivalence_classes: &[&[Network]]) {
for pl in payloads {
for addr_net in equivalence_classes.iter().flat_map(|ec| ec.iter()) {
for valid_net in equivalence_classes
.iter()
.filter(|ec| ec.contains(addr_net))
.flat_map(|ec| ec.iter())
{
let addr = Address::new(*addr_net, pl.clone());
assert!(addr.is_valid_for_network(*valid_net));
}
for invalid_net in equivalence_classes
.iter()
.filter(|ec| !ec.contains(addr_net))
.flat_map(|ec| ec.iter())
{
let addr = Address::new(*addr_net, pl.clone());
assert!(!addr.is_valid_for_network(*invalid_net));
}
}
}
}
test_addr_type(legacy_payload, LEGACY_EQUIVALENCE_CLASSES);
test_addr_type(&segwit_payload, SEGWIT_EQUIVALENCE_CLASSES);
}
#[test]
fn p2tr_from_untweaked() {
//Test case from BIP-086
let internal_key = XOnlyPublicKey::from_str(
"cc8a4bc64d897bddc5fbc2f670f7a8ba0b386779106cf1223c6fc5d7cd6fc115",
)
.unwrap();
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let secp = Secp256k1::verification_only();
let address = Address::p2tr(&secp, internal_key, None, Network::Bitcoin);
assert_eq!(
address.to_string(),
"bc1p5cyxnuxmeuwuvkwfem96lqzszd02n6xdcjrs20cac6yqjjwudpxqkedrcr"
);
assert_eq!(address.address_type(), Some(AddressType::P2tr));
roundtrips(&address);
}
#[test]
fn test_is_related_to_pubkey_p2wpkh() {
let address_string = "bc1qhvd6suvqzjcu9pxjhrwhtrlj85ny3n2mqql5w4";
let address = Address::from_str(address_string)
.expect("address")
.require_network(Network::Bitcoin)
.expect("mainnet");
let pubkey_string = "0347ff3dacd07a1f43805ec6808e801505a6e18245178609972a68afbc2777ff2b";
let pubkey = PublicKey::from_str(pubkey_string).expect("pubkey");
let result = address.is_related_to_pubkey(&pubkey);
assert!(result);
let unused_pubkey = PublicKey::from_str(
"02ba604e6ad9d3864eda8dc41c62668514ef7d5417d3b6db46e45cc4533bff001c",
)
.expect("pubkey");
assert!(!address.is_related_to_pubkey(&unused_pubkey))
}
#[test]
fn test_is_related_to_pubkey_p2shwpkh() {
let address_string = "3EZQk4F8GURH5sqVMLTFisD17yNeKa7Dfs";
let address = Address::from_str(address_string)
.expect("address")
.require_network(Network::Bitcoin)
.expect("mainnet");
let pubkey_string = "0347ff3dacd07a1f43805ec6808e801505a6e18245178609972a68afbc2777ff2b";
let pubkey = PublicKey::from_str(pubkey_string).expect("pubkey");
let result = address.is_related_to_pubkey(&pubkey);
assert!(result);
let unused_pubkey = PublicKey::from_str(
"02ba604e6ad9d3864eda8dc41c62668514ef7d5417d3b6db46e45cc4533bff001c",
)
.expect("pubkey");
assert!(!address.is_related_to_pubkey(&unused_pubkey))
}
#[test]
fn test_is_related_to_pubkey_p2pkh() {
let address_string = "1J4LVanjHMu3JkXbVrahNuQCTGCRRgfWWx";
let address = Address::from_str(address_string)
.expect("address")
.require_network(Network::Bitcoin)
.expect("mainnet");
let pubkey_string = "0347ff3dacd07a1f43805ec6808e801505a6e18245178609972a68afbc2777ff2b";
let pubkey = PublicKey::from_str(pubkey_string).expect("pubkey");
let result = address.is_related_to_pubkey(&pubkey);
assert!(result);
let unused_pubkey = PublicKey::from_str(
"02ba604e6ad9d3864eda8dc41c62668514ef7d5417d3b6db46e45cc4533bff001c",
)
.expect("pubkey");
assert!(!address.is_related_to_pubkey(&unused_pubkey))
}
#[test]
fn test_is_related_to_pubkey_p2pkh_uncompressed_key() {
let address_string = "msvS7KzhReCDpQEJaV2hmGNvuQqVUDuC6p";
let address = Address::from_str(address_string)
.expect("address")
.require_network(Network::Testnet)
.expect("testnet");
let pubkey_string = "04e96e22004e3db93530de27ccddfdf1463975d2138ac018fc3e7ba1a2e5e0aad8e424d0b55e2436eb1d0dcd5cb2b8bcc6d53412c22f358de57803a6a655fbbd04";
let pubkey = PublicKey::from_str(pubkey_string).expect("pubkey");
let result = address.is_related_to_pubkey(&pubkey);
assert!(result);
let unused_pubkey = PublicKey::from_str(
"02ba604e6ad9d3864eda8dc41c62668514ef7d5417d3b6db46e45cc4533bff001c",
)
.expect("pubkey");
assert!(!address.is_related_to_pubkey(&unused_pubkey))
}
#[test]
fn test_is_related_to_pubkey_p2tr() {
let pubkey_string = "0347ff3dacd07a1f43805ec6808e801505a6e18245178609972a68afbc2777ff2b";
let pubkey = PublicKey::from_str(pubkey_string).expect("pubkey");
let xonly_pubkey = XOnlyPublicKey::from(pubkey.inner);
let tweaked_pubkey = TweakedPublicKey::dangerous_assume_tweaked(xonly_pubkey);
let address = Address::p2tr_tweaked(tweaked_pubkey, Network::Bitcoin);
assert_eq!(
address,
Address::from_str("bc1pgllnmtxs0g058qz7c6qgaqq4qknwrqj9z7rqn9e2dzhmcfmhlu4sfadf5e")
.expect("address")
.require_network(Network::Bitcoin)
.expect("mainnet")
);
let result = address.is_related_to_pubkey(&pubkey);
assert!(result);
let unused_pubkey = PublicKey::from_str(
"02ba604e6ad9d3864eda8dc41c62668514ef7d5417d3b6db46e45cc4533bff001c",
)
.expect("pubkey");
assert!(!address.is_related_to_pubkey(&unused_pubkey));
}
#[test]
fn test_is_related_to_xonly_pubkey() {
let pubkey_string = "0347ff3dacd07a1f43805ec6808e801505a6e18245178609972a68afbc2777ff2b";
let pubkey = PublicKey::from_str(pubkey_string).expect("pubkey");
let xonly_pubkey = XOnlyPublicKey::from(pubkey.inner);
let tweaked_pubkey = TweakedPublicKey::dangerous_assume_tweaked(xonly_pubkey);
let address = Address::p2tr_tweaked(tweaked_pubkey, Network::Bitcoin);
assert_eq!(
address,
Address::from_str("bc1pgllnmtxs0g058qz7c6qgaqq4qknwrqj9z7rqn9e2dzhmcfmhlu4sfadf5e")
.expect("address")
.require_network(Network::Bitcoin)
.expect("mainnet")
);
let result = address.is_related_to_xonly_pubkey(&xonly_pubkey);
assert!(result);
}
#[test]
fn test_fail_address_from_script() {
let bad_p2wpkh = hex_script!("0014dbc5b0a8f9d4353b4b54c3db48846bb15abfec");
let bad_p2wsh =
hex_script!("00202d4fa2eb233d008cc83206fa2f4f2e60199000f5b857a835e3172323385623");
let invalid_segwitv0_script = hex_script!("001161458e330389cd0437ee9fe3641d70cc18");
let expected = Err(Error::UnrecognizedScript);
assert_eq!(Address::from_script(&bad_p2wpkh, Network::Bitcoin), expected);
assert_eq!(Address::from_script(&bad_p2wsh, Network::Bitcoin), expected);
assert_eq!(
Address::from_script(&invalid_segwitv0_script, Network::Bitcoin),
Err(Error::InvalidSegwitV0ProgramLength(17))
);
}
#[test]
fn valid_address_parses_correctly() {
let addr = AddressType::from_str("p2tr").expect("false negative while parsing address");
assert_eq!(addr, AddressType::P2tr);
}
#[test]
fn invalid_address_parses_error() {
let got = AddressType::from_str("invalid");
let want = Err(Error::UnknownAddressType("invalid".to_string()));
assert_eq!(got, want);
}
}