757 lines
30 KiB
Rust
757 lines
30 KiB
Rust
//! Example of taproot PSBT workflow
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// We use the alias `alias bt='bitcoin-cli -regtest'` for brevity.
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// Step 0 - Wipe the `regtest` data directory to start from a clean slate.
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// Step 1 - Run `bitcoind -regtest -daemon` to start the daemon. Bitcoin Core 23.0+ is required.
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// Step 2 -
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// 2.1) Run `bt -named createwallet wallet_name=benefactor blank=true` to create a blank wallet with the name "benefactor"
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// 2.2) Run `bt -named createwallet wallet_name=beneficiary blank=true` to create a blank wallet with the name "beneficiary"
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// 2.3) Create the two aliases:
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// alias bt-benefactor='bitcoin-cli -regtest -rpcwallet=benefactor'
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// alias bt-beneficiary='bitcoin-cli -regtest -rpcwallet=beneficiary'
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//
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// 2.4) Import the example descriptors:
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// bt-benefactor importdescriptors '[
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// { "desc": "tr(tprv8ZgxMBicQKsPd4arFr7sKjSnKFDVMR2JHw9Y8L9nXN4kiok4u28LpHijEudH3mMYoL4pM5UL9Bgdz2M4Cy8EzfErmU9m86ZTw6hCzvFeTg7/86\'/1\'/0\'/1/*)#jzyeered", "active": true, "timestamp": "now", "internal": true },
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// { "desc": "tr(tprv8ZgxMBicQKsPd4arFr7sKjSnKFDVMR2JHw9Y8L9nXN4kiok4u28LpHijEudH3mMYoL4pM5UL9Bgdz2M4Cy8EzfErmU9m86ZTw6hCzvFeTg7/86\'/1\'/0\'/0/*)#rkpcykf4", "active": true, "timestamp": "now" }
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// ]'
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// bt-beneficiary importdescriptors '[
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// { "desc": "tr(tprv8ZgxMBicQKsPe72C5c3cugP8b7AzEuNjP4NSC17Dkpqk5kaAmsL6FHwPsVxPpURVqbNwdLAbNqi8Cvdq6nycDwYdKHDjDRYcsMzfshimAUq/86\'/1\'/0\'/1/*)#w4ehwx46", "active": true, "timestamp": "now", "internal": true },
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// { "desc": "tr(tprv8ZgxMBicQKsPe72C5c3cugP8b7AzEuNjP4NSC17Dkpqk5kaAmsL6FHwPsVxPpURVqbNwdLAbNqi8Cvdq6nycDwYdKHDjDRYcsMzfshimAUq/86\'/1\'/0\'/0/*)#lpuknn9z", "active": true, "timestamp": "now" }
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// ]'
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//
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// The xpriv and derivation path from the imported descriptors
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const BENEFACTOR_XPRIV_STR: &str = "tprv8ZgxMBicQKsPd4arFr7sKjSnKFDVMR2JHw9Y8L9nXN4kiok4u28LpHijEudH3mMYoL4pM5UL9Bgdz2M4Cy8EzfErmU9m86ZTw6hCzvFeTg7";
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const BENEFICIARY_XPRIV_STR: &str = "tprv8ZgxMBicQKsPe72C5c3cugP8b7AzEuNjP4NSC17Dkpqk5kaAmsL6FHwPsVxPpURVqbNwdLAbNqi8Cvdq6nycDwYdKHDjDRYcsMzfshimAUq";
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const BIP86_DERIVATION_PATH: &str = "m/86'/1'/0'/0/0";
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// Step 3 -
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// Run `bt generatetoaddress 103 $(bt-benefactor getnewaddress '' bech32m)` to generate 103 new blocks
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// with block reward being sent to a newly created P2TR address in the `benefactor` wallet.
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// This will leave us with 3 mature UTXOs that can be spent. Each will be used in a different example below.
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// Step 4 - Run `bt-benefactor listunspent` to display our three spendable UTXOs. Check that everything is the same as below
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// - otherwise modify it. The txids should be deterministic on regtest:
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const UTXO_SCRIPT_PUBKEY: &str =
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"5120be27fa8b1f5278faf82cab8da23e8761f8f9bd5d5ebebbb37e0e12a70d92dd16";
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const UTXO_PUBKEY: &str = "a6ac32163539c16b6b5dbbca01b725b8e8acaa5f821ba42c80e7940062140d19";
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const UTXO_MASTER_FINGERPRINT: &str = "e61b318f";
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const ABSOLUTE_FEES_IN_SATS: u64 = 1000;
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// UTXO_1 will be used for spending example 1
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const UTXO_1: P2trUtxo = P2trUtxo {
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txid: "a85d89b4666fed622281d3589474aa1f87971b54bd5d9c1899ed2e8e0447cc06",
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vout: 0,
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script_pubkey: UTXO_SCRIPT_PUBKEY,
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pubkey: UTXO_PUBKEY,
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master_fingerprint: UTXO_MASTER_FINGERPRINT,
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amount_in_sats: 50 * COIN_VALUE, // 50 BTC
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derivation_path: BIP86_DERIVATION_PATH,
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};
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// UTXO_2 will be used for spending example 2
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const UTXO_2: P2trUtxo = P2trUtxo {
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txid: "6f1c1df5862a67f4b6d1cde9a87e3c441b483ba6a140fbec2815f03aa3a5309d",
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vout: 0,
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script_pubkey: UTXO_SCRIPT_PUBKEY,
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pubkey: UTXO_PUBKEY,
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master_fingerprint: UTXO_MASTER_FINGERPRINT,
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amount_in_sats: 50 * COIN_VALUE,
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derivation_path: BIP86_DERIVATION_PATH,
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};
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// UTXO_3 will be used for spending example 3
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const UTXO_3: P2trUtxo = P2trUtxo {
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txid: "9795fed5aedca219244a396dfd7bce55c851274418383c3ab43530e3f74e5dcc",
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vout: 0,
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script_pubkey: UTXO_SCRIPT_PUBKEY,
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pubkey: UTXO_PUBKEY,
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master_fingerprint: UTXO_MASTER_FINGERPRINT,
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amount_in_sats: 50 * COIN_VALUE,
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derivation_path: BIP86_DERIVATION_PATH,
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};
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use std::collections::BTreeMap;
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use std::str::FromStr;
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use bitcoin::bip32::{ChildNumber, DerivationPath, ExtendedPrivKey, ExtendedPubKey, Fingerprint};
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use bitcoin::consensus::encode;
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use bitcoin::constants::COIN_VALUE;
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use bitcoin::hashes::hex::FromHex;
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use bitcoin::hashes::Hash;
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use bitcoin::key::XOnlyPublicKey;
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use bitcoin::opcodes::all::{OP_CHECKSIG, OP_CLTV, OP_DROP};
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use bitcoin::psbt::{self, Input, Output, Psbt, PsbtSighashType};
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use bitcoin::schnorr::{self, TapTweak};
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use bitcoin::secp256k1::{Message, Secp256k1};
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use bitcoin::sighash::{self, SchnorrSighashType, SighashCache};
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use bitcoin::taproot::{
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LeafVersion, TapLeafHash, TapSighashHash, TaprootBuilder, TaprootSpendInfo,
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};
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use bitcoin::{
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absolute, script, Address, Amount, OutPoint, ScriptBuf, Transaction, TxIn, TxOut, Txid, Witness,
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};
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fn main() -> Result<(), Box<dyn std::error::Error>> {
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let secp = Secp256k1::new();
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println!("\n----------------");
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println!("\nSTART EXAMPLE 1 - P2TR with a BIP86 commitment, signed with internal key\n");
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// Just some addresses for outputs from our wallets. Not really important.
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let to_address =
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Address::from_str("bcrt1p0p3rvwww0v9znrclp00uneq8ytre9kj922v8fxhnezm3mgsmn9usdxaefc")?;
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let change_address =
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Address::from_str("bcrt1pz449kexzydh2kaypatup5ultru3ej284t6eguhnkn6wkhswt0l7q3a7j76")?;
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let amount_to_send_in_sats = COIN_VALUE;
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let change_amount = UTXO_1
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.amount_in_sats
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.checked_sub(amount_to_send_in_sats)
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.and_then(|x| x.checked_sub(ABSOLUTE_FEES_IN_SATS))
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.ok_or("Fees more than input amount!")?;
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let tx_hex_string = encode::serialize_hex(&generate_bip86_key_spend_tx(
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&secp,
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// The master extended private key from the descriptor in step 4
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ExtendedPrivKey::from_str(BENEFACTOR_XPRIV_STR)?,
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// Set these fields with valid data for the UTXO from step 5 above
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UTXO_1,
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vec![
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TxOut { value: amount_to_send_in_sats, script_pubkey: to_address.script_pubkey() },
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TxOut { value: change_amount, script_pubkey: change_address.script_pubkey() },
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],
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)?);
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println!(
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"\nYou should now be able to broadcast the following transaction: \n\n{}",
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tx_hex_string
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);
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println!("\nEND EXAMPLE 1\n");
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println!("----------------\n");
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println!("START EXAMPLE 2 - Script path spending of inheritance UTXO\n");
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{
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let beneficiary =
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BeneficiaryWallet::new(ExtendedPrivKey::from_str(BENEFICIARY_XPRIV_STR)?)?;
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let mut benefactor = BenefactorWallet::new(
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ExtendedPrivKey::from_str(BENEFACTOR_XPRIV_STR)?,
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beneficiary.master_xpub(),
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)?;
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let (tx, psbt) = benefactor.create_inheritance_funding_tx(
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absolute::LockTime::from_height(1000).unwrap(),
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UTXO_2,
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)?;
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let tx_hex = encode::serialize_hex(&tx);
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println!("Inheritance funding tx hex:\n\n{}", tx_hex);
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// You can now broadcast the transaction hex:
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// bt sendrawtransaction ...
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//
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// And mine a block to confirm the transaction:
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// bt generatetoaddress 1 $(bt-benefactor getnewaddress '' 'bech32m')
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let spending_tx = beneficiary.spend_inheritance(
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psbt,
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absolute::LockTime::from_height(1000).unwrap(),
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to_address,
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)?;
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let spending_tx_hex = encode::serialize_hex(&spending_tx);
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println!("\nInheritance spending tx hex:\n\n{}", spending_tx_hex);
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// If you try to broadcast now, the transaction will be rejected as it is timelocked.
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// First mine 900 blocks so we're sure we are over the 1000 block locktime:
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// bt generatetoaddress 900 $(bt-benefactor getnewaddress '' 'bech32m')
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// Then broadcast the transaction with `bt sendrawtransaction ...`
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}
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println!("\nEND EXAMPLE 2\n");
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println!("----------------\n");
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println!("START EXAMPLE 3 - Key path spending of inheritance UTXO\n");
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{
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let beneficiary =
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BeneficiaryWallet::new(ExtendedPrivKey::from_str(BENEFICIARY_XPRIV_STR)?)?;
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let mut benefactor = BenefactorWallet::new(
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ExtendedPrivKey::from_str(BENEFACTOR_XPRIV_STR)?,
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beneficiary.master_xpub(),
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)?;
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let (tx, _) = benefactor.create_inheritance_funding_tx(
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absolute::LockTime::from_height(2000).unwrap(),
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UTXO_3,
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)?;
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let tx_hex = encode::serialize_hex(&tx);
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println!("Inheritance funding tx hex:\n\n{}", tx_hex);
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// You can now broadcast the transaction hex:
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// bt sendrawtransaction ...
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//
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// And mine a block to confirm the transaction:
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// bt generatetoaddress 1 $(bt-benefactor getnewaddress '' 'bech32m')
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// At some point we may want to extend the locktime further into the future for the beneficiary.
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// We can do this by "refreshing" the inheritance transaction as the benefactor. This effectively
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// spends the inheritance transaction via the key path of the taproot output, and is not encumbered
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// by the timelock so we can spend it immediately. We set up a new output similar to the first with
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// a locktime that is 'locktime_delta' blocks greater.
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let (tx, _) = benefactor.refresh_tx(1000)?;
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let tx_hex = encode::serialize_hex(&tx);
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println!("\nRefreshed inheritance tx hex:\n\n{}\n", tx_hex);
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println!("\nEND EXAMPLE 3\n");
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println!("----------------\n");
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}
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Ok(())
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}
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struct P2trUtxo<'a> {
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txid: &'a str,
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vout: u32,
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script_pubkey: &'a str,
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pubkey: &'a str,
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master_fingerprint: &'a str,
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amount_in_sats: u64,
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derivation_path: &'a str,
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}
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fn generate_bip86_key_spend_tx(
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secp: &secp256k1::Secp256k1<secp256k1::All>,
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master_xpriv: ExtendedPrivKey,
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input_utxo: P2trUtxo,
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outputs: Vec<TxOut>,
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) -> Result<Transaction, Box<dyn std::error::Error>> {
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let from_amount = input_utxo.amount_in_sats;
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let input_pubkey = XOnlyPublicKey::from_str(input_utxo.pubkey)?;
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// CREATOR + UPDATER
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let tx1 = Transaction {
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version: 2,
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lock_time: absolute::LockTime::ZERO,
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input: vec![TxIn {
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previous_output: OutPoint {
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txid: Txid::from_hex(input_utxo.txid)?,
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vout: input_utxo.vout,
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},
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script_sig: ScriptBuf::new(),
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sequence: bitcoin::Sequence(0xFFFFFFFF), // Ignore nSequence.
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witness: Witness::default(),
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}],
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output: outputs,
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};
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let mut psbt = Psbt::from_unsigned_tx(tx1)?;
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let mut origins = BTreeMap::new();
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origins.insert(
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input_pubkey,
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(
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vec![],
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(
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Fingerprint::from_str(input_utxo.master_fingerprint)?,
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DerivationPath::from_str(input_utxo.derivation_path)?,
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),
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),
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);
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let mut input = Input {
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witness_utxo: {
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let script_pubkey = ScriptBuf::from_hex(input_utxo.script_pubkey)
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.expect("failed to parse input utxo scriptPubkey");
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let amount = Amount::from_sat(from_amount);
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Some(TxOut { value: amount.to_sat(), script_pubkey })
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},
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tap_key_origins: origins,
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..Default::default()
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};
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let ty = PsbtSighashType::from_str("SIGHASH_ALL")?;
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input.sighash_type = Some(ty);
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input.tap_internal_key = Some(input_pubkey);
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psbt.inputs = vec![input];
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// SIGNER
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let unsigned_tx = psbt.unsigned_tx.clone();
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psbt.inputs.iter_mut().enumerate().try_for_each::<_, Result<(), Box<dyn std::error::Error>>>(
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|(vout, input)| {
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let hash_ty = input
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.sighash_type
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.and_then(|psbt_sighash_type| psbt_sighash_type.schnorr_hash_ty().ok())
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.unwrap_or(SchnorrSighashType::All);
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let hash = SighashCache::new(&unsigned_tx).taproot_key_spend_signature_hash(
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vout,
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&sighash::Prevouts::All(&[TxOut {
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value: from_amount,
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script_pubkey: ScriptBuf::from_str(input_utxo.script_pubkey)?,
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}]),
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hash_ty,
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)?;
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let (_, (_, derivation_path)) = input
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.tap_key_origins
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.get(&input.tap_internal_key.ok_or("Internal key missing in PSBT")?)
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.ok_or("Missing taproot key origin")?;
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let secret_key = master_xpriv.derive_priv(secp, &derivation_path)?.to_priv().inner;
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sign_psbt_schnorr(
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&secret_key,
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input.tap_internal_key.unwrap(),
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None,
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input,
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hash,
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hash_ty,
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secp,
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);
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Ok(())
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},
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)?;
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// FINALIZER
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psbt.inputs.iter_mut().for_each(|input| {
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let mut script_witness: Witness = Witness::new();
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script_witness.push(input.tap_key_sig.unwrap().to_vec());
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input.final_script_witness = Some(script_witness);
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// Clear all the data fields as per the spec.
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input.partial_sigs = BTreeMap::new();
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input.sighash_type = None;
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input.redeem_script = None;
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input.witness_script = None;
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input.bip32_derivation = BTreeMap::new();
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});
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// EXTRACTOR
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let tx = psbt.extract_tx();
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tx.verify(|_| {
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Some(TxOut {
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value: from_amount,
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script_pubkey: ScriptBuf::from_hex(input_utxo.script_pubkey).unwrap(),
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})
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})
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.expect("failed to verify transaction");
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Ok(tx)
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}
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/// A wallet that allows creating and spending from an inheritance directly via the key path for purposes
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/// of refreshing the inheritance timelock or changing other spending conditions.
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struct BenefactorWallet {
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master_xpriv: ExtendedPrivKey,
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beneficiary_xpub: ExtendedPubKey,
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current_spend_info: Option<TaprootSpendInfo>,
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next_psbt: Option<Psbt>,
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secp: Secp256k1<secp256k1::All>,
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next: ChildNumber,
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}
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impl BenefactorWallet {
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fn new(
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master_xpriv: ExtendedPrivKey,
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beneficiary_xpub: ExtendedPubKey,
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) -> Result<Self, Box<dyn std::error::Error>> {
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Ok(Self {
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master_xpriv,
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beneficiary_xpub,
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current_spend_info: None,
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next_psbt: None,
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secp: Secp256k1::new(),
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next: ChildNumber::from_normal_idx(0).expect("Zero is a valid child number"),
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})
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}
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fn time_lock_script(locktime: absolute::LockTime, beneficiary_key: XOnlyPublicKey) -> ScriptBuf {
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script::Builder::new()
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.push_int(locktime.to_consensus_u32() as i64)
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.push_opcode(OP_CLTV)
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.push_opcode(OP_DROP)
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.push_x_only_key(&beneficiary_key)
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.push_opcode(OP_CHECKSIG)
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.into_script()
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}
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fn create_inheritance_funding_tx(
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&mut self,
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lock_time: absolute::LockTime,
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input_utxo: P2trUtxo,
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) -> Result<(Transaction, Psbt), Box<dyn std::error::Error>> {
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if let ChildNumber::Normal { index } = self.next {
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if index > 0 && self.current_spend_info.is_some() {
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return Err("Transaction already exists, use refresh_inheritance_timelock to refresh the timelock".into());
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}
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}
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// We use some other derivation path in this example for our inheritance protocol. The important thing is to ensure
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// that we use an unhardened path so we can make use of xpubs.
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let derivation_path = DerivationPath::from_str(&format!("m/101/1/0/0/{}", self.next))?;
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let internal_keypair =
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self.master_xpriv.derive_priv(&self.secp, &derivation_path)?.to_keypair(&self.secp);
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let beneficiary_key =
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self.beneficiary_xpub.derive_pub(&self.secp, &derivation_path)?.to_x_only_pub();
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// Build up the leaf script and combine with internal key into a taproot commitment
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let script = Self::time_lock_script(lock_time, beneficiary_key);
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let leaf_hash = TapLeafHash::from_script(&script, LeafVersion::TapScript);
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let taproot_spend_info = TaprootBuilder::new()
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.add_leaf(0, script.clone())?
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.finalize(&self.secp, internal_keypair.x_only_public_key().0)
|
|
.expect("Should be finalizable");
|
|
self.current_spend_info = Some(taproot_spend_info.clone());
|
|
let script_pubkey = ScriptBuf::new_v1_p2tr(
|
|
&self.secp,
|
|
taproot_spend_info.internal_key(),
|
|
taproot_spend_info.merkle_root(),
|
|
);
|
|
let value = input_utxo.amount_in_sats - ABSOLUTE_FEES_IN_SATS;
|
|
|
|
// Spend a normal BIP86-like output as an input in our inheritance funding transaction
|
|
let tx = generate_bip86_key_spend_tx(
|
|
&self.secp,
|
|
self.master_xpriv,
|
|
input_utxo,
|
|
vec![TxOut { script_pubkey: script_pubkey.clone(), value }],
|
|
)?;
|
|
|
|
// CREATOR + UPDATER
|
|
let next_tx = Transaction {
|
|
version: 2,
|
|
lock_time,
|
|
input: vec![TxIn {
|
|
previous_output: OutPoint { txid: tx.txid(), vout: 0 },
|
|
script_sig: ScriptBuf::new(),
|
|
sequence: bitcoin::Sequence(0xFFFFFFFD), // enable locktime and opt-in RBF
|
|
witness: Witness::default(),
|
|
}],
|
|
output: vec![],
|
|
};
|
|
let mut next_psbt = Psbt::from_unsigned_tx(next_tx)?;
|
|
let mut origins = BTreeMap::new();
|
|
origins.insert(
|
|
beneficiary_key,
|
|
(vec![leaf_hash], (self.beneficiary_xpub.fingerprint(), derivation_path.clone())),
|
|
);
|
|
origins.insert(
|
|
internal_keypair.x_only_public_key().0,
|
|
(vec![], (self.master_xpriv.fingerprint(&self.secp), derivation_path)),
|
|
);
|
|
let ty = PsbtSighashType::from_str("SIGHASH_ALL")?;
|
|
let mut tap_scripts = BTreeMap::new();
|
|
tap_scripts.insert(
|
|
taproot_spend_info.control_block(&(script.clone(), LeafVersion::TapScript)).unwrap(),
|
|
(script, LeafVersion::TapScript),
|
|
);
|
|
|
|
let input = Input {
|
|
witness_utxo: {
|
|
let script_pubkey = script_pubkey;
|
|
let amount = Amount::from_sat(value);
|
|
|
|
Some(TxOut { value: amount.to_sat(), script_pubkey })
|
|
},
|
|
tap_key_origins: origins,
|
|
tap_merkle_root: taproot_spend_info.merkle_root(),
|
|
sighash_type: Some(ty),
|
|
tap_internal_key: Some(internal_keypair.x_only_public_key().0),
|
|
tap_scripts,
|
|
..Default::default()
|
|
};
|
|
|
|
next_psbt.inputs = vec![input];
|
|
self.next_psbt = Some(next_psbt.clone());
|
|
|
|
self.next.increment()?;
|
|
Ok((tx, next_psbt))
|
|
}
|
|
|
|
fn refresh_tx(
|
|
&mut self,
|
|
lock_time_delta: u32,
|
|
) -> Result<(Transaction, Psbt), Box<dyn std::error::Error>> {
|
|
if let Some(ref spend_info) = self.current_spend_info.clone() {
|
|
let mut psbt = self.next_psbt.clone().expect("Should have next_psbt");
|
|
let input = &mut psbt.inputs[0];
|
|
let input_value = input.witness_utxo.as_ref().unwrap().value;
|
|
let output_value = input_value - ABSOLUTE_FEES_IN_SATS;
|
|
|
|
// We use some other derivation path in this example for our inheritance protocol. The important thing is to ensure
|
|
// that we use an unhardened path so we can make use of xpubs.
|
|
let new_derivation_path =
|
|
DerivationPath::from_str(&format!("m/101/1/0/0/{}", self.next))?;
|
|
let new_internal_keypair = self
|
|
.master_xpriv
|
|
.derive_priv(&self.secp, &new_derivation_path)?
|
|
.to_keypair(&self.secp);
|
|
let beneficiary_key =
|
|
self.beneficiary_xpub.derive_pub(&self.secp, &new_derivation_path)?.to_x_only_pub();
|
|
|
|
// Build up the leaf script and combine with internal key into a taproot commitment
|
|
let lock_time = absolute::LockTime::from_height(
|
|
psbt.unsigned_tx.lock_time.to_consensus_u32() + lock_time_delta,
|
|
)
|
|
.unwrap();
|
|
let script = Self::time_lock_script(lock_time, beneficiary_key);
|
|
let leaf_hash = TapLeafHash::from_script(&script, LeafVersion::TapScript);
|
|
|
|
let taproot_spend_info = TaprootBuilder::new()
|
|
.add_leaf(0, script.clone())?
|
|
.finalize(&self.secp, new_internal_keypair.x_only_public_key().0)
|
|
.expect("Should be finalizable");
|
|
self.current_spend_info = Some(taproot_spend_info.clone());
|
|
let prevout_script_pubkey = input.witness_utxo.as_ref().unwrap().script_pubkey.clone();
|
|
let output_script_pubkey = ScriptBuf::new_v1_p2tr(
|
|
&self.secp,
|
|
taproot_spend_info.internal_key(),
|
|
taproot_spend_info.merkle_root(),
|
|
);
|
|
|
|
psbt.unsigned_tx.output =
|
|
vec![TxOut { script_pubkey: output_script_pubkey.clone(), value: output_value }];
|
|
psbt.outputs = vec![Output::default()];
|
|
psbt.unsigned_tx.lock_time = absolute::LockTime::ZERO;
|
|
|
|
let hash_ty = input
|
|
.sighash_type
|
|
.and_then(|psbt_sighash_type| psbt_sighash_type.schnorr_hash_ty().ok())
|
|
.unwrap_or(SchnorrSighashType::All);
|
|
let hash = SighashCache::new(&psbt.unsigned_tx).taproot_key_spend_signature_hash(
|
|
0,
|
|
&sighash::Prevouts::All(&[TxOut {
|
|
value: input_value,
|
|
script_pubkey: prevout_script_pubkey,
|
|
}]),
|
|
hash_ty,
|
|
)?;
|
|
|
|
{
|
|
let (_, (_, derivation_path)) = input
|
|
.tap_key_origins
|
|
.get(&input.tap_internal_key.ok_or("Internal key missing in PSBT")?)
|
|
.ok_or("Missing taproot key origin")?;
|
|
let secret_key =
|
|
self.master_xpriv.derive_priv(&self.secp, &derivation_path)?.to_priv().inner;
|
|
sign_psbt_schnorr(
|
|
&secret_key,
|
|
spend_info.internal_key(),
|
|
None,
|
|
input,
|
|
hash,
|
|
hash_ty,
|
|
&self.secp,
|
|
);
|
|
}
|
|
|
|
// FINALIZER
|
|
psbt.inputs.iter_mut().for_each(|input| {
|
|
let mut script_witness: Witness = Witness::new();
|
|
script_witness.push(input.tap_key_sig.unwrap().to_vec());
|
|
input.final_script_witness = Some(script_witness);
|
|
|
|
// Clear all the data fields as per the spec.
|
|
input.partial_sigs = BTreeMap::new();
|
|
input.sighash_type = None;
|
|
input.redeem_script = None;
|
|
input.witness_script = None;
|
|
input.bip32_derivation = BTreeMap::new();
|
|
});
|
|
|
|
// EXTRACTOR
|
|
let tx = psbt.extract_tx();
|
|
tx.verify(|_| {
|
|
Some(TxOut { value: input_value, script_pubkey: output_script_pubkey.clone() })
|
|
})
|
|
.expect("failed to verify transaction");
|
|
|
|
let next_tx = Transaction {
|
|
version: 2,
|
|
lock_time,
|
|
input: vec![TxIn {
|
|
previous_output: OutPoint { txid: tx.txid(), vout: 0 },
|
|
script_sig: ScriptBuf::new(),
|
|
sequence: bitcoin::Sequence(0xFFFFFFFD), // enable locktime and opt-in RBF
|
|
witness: Witness::default(),
|
|
}],
|
|
output: vec![],
|
|
};
|
|
let mut next_psbt = Psbt::from_unsigned_tx(next_tx)?;
|
|
let mut origins = BTreeMap::new();
|
|
origins.insert(
|
|
beneficiary_key,
|
|
(vec![leaf_hash], (self.beneficiary_xpub.fingerprint(), new_derivation_path)),
|
|
);
|
|
let ty = PsbtSighashType::from_str("SIGHASH_ALL")?;
|
|
let mut tap_scripts = BTreeMap::new();
|
|
tap_scripts.insert(
|
|
taproot_spend_info
|
|
.control_block(&(script.clone(), LeafVersion::TapScript))
|
|
.unwrap(),
|
|
(script, LeafVersion::TapScript),
|
|
);
|
|
|
|
let input = Input {
|
|
witness_utxo: {
|
|
let script_pubkey = output_script_pubkey;
|
|
let amount = Amount::from_sat(output_value);
|
|
|
|
Some(TxOut { value: amount.to_sat(), script_pubkey })
|
|
},
|
|
tap_key_origins: origins,
|
|
tap_merkle_root: taproot_spend_info.merkle_root(),
|
|
sighash_type: Some(ty),
|
|
tap_internal_key: Some(new_internal_keypair.x_only_public_key().0),
|
|
tap_scripts,
|
|
..Default::default()
|
|
};
|
|
|
|
next_psbt.inputs = vec![input];
|
|
self.next_psbt = Some(next_psbt.clone());
|
|
|
|
self.next.increment()?;
|
|
Ok((tx, next_psbt))
|
|
} else {
|
|
Err("No current_spend_info available. Create an inheritance tx first.".into())
|
|
}
|
|
}
|
|
}
|
|
|
|
/// A wallet that allows spending from an inheritance locked to a P2TR UTXO via a script path
|
|
/// after some expiry using CLTV.
|
|
struct BeneficiaryWallet {
|
|
master_xpriv: ExtendedPrivKey,
|
|
secp: secp256k1::Secp256k1<secp256k1::All>,
|
|
}
|
|
|
|
impl BeneficiaryWallet {
|
|
fn new(master_xpriv: ExtendedPrivKey) -> Result<Self, Box<dyn std::error::Error>> {
|
|
Ok(Self { master_xpriv, secp: Secp256k1::new() })
|
|
}
|
|
|
|
fn master_xpub(&self) -> ExtendedPubKey {
|
|
ExtendedPubKey::from_priv(&self.secp, &self.master_xpriv)
|
|
}
|
|
|
|
fn spend_inheritance(
|
|
&self,
|
|
mut psbt: Psbt,
|
|
lock_time: absolute::LockTime,
|
|
to_address: Address,
|
|
) -> Result<Transaction, Box<dyn std::error::Error>> {
|
|
let input_value = psbt.inputs[0].witness_utxo.as_ref().unwrap().value;
|
|
let input_script_pubkey =
|
|
psbt.inputs[0].witness_utxo.as_ref().unwrap().script_pubkey.clone();
|
|
psbt.unsigned_tx.lock_time = lock_time;
|
|
psbt.unsigned_tx.output = vec![TxOut {
|
|
script_pubkey: to_address.script_pubkey(),
|
|
value: input_value - ABSOLUTE_FEES_IN_SATS,
|
|
}];
|
|
psbt.outputs = vec![Output::default()];
|
|
let unsigned_tx = psbt.unsigned_tx.clone();
|
|
|
|
// SIGNER
|
|
for (x_only_pubkey, (leaf_hashes, (_, derivation_path))) in
|
|
&psbt.inputs[0].tap_key_origins.clone()
|
|
{
|
|
let secret_key =
|
|
self.master_xpriv.derive_priv(&self.secp, &derivation_path)?.to_priv().inner;
|
|
for lh in leaf_hashes {
|
|
let hash_ty = SchnorrSighashType::All;
|
|
let hash = SighashCache::new(&unsigned_tx).taproot_script_spend_signature_hash(
|
|
0,
|
|
&sighash::Prevouts::All(&[TxOut {
|
|
value: input_value,
|
|
script_pubkey: input_script_pubkey.clone(),
|
|
}]),
|
|
*lh,
|
|
hash_ty,
|
|
)?;
|
|
sign_psbt_schnorr(
|
|
&secret_key,
|
|
*x_only_pubkey,
|
|
Some(*lh),
|
|
&mut psbt.inputs[0],
|
|
hash,
|
|
hash_ty,
|
|
&self.secp,
|
|
);
|
|
}
|
|
}
|
|
|
|
// FINALIZER
|
|
psbt.inputs.iter_mut().for_each(|input| {
|
|
let mut script_witness: Witness = Witness::new();
|
|
for (_, signature) in input.tap_script_sigs.iter() {
|
|
script_witness.push(signature.to_vec());
|
|
}
|
|
for (control_block, (script, _)) in input.tap_scripts.iter() {
|
|
script_witness.push(script.to_bytes());
|
|
script_witness.push(control_block.serialize());
|
|
}
|
|
input.final_script_witness = Some(script_witness);
|
|
|
|
// Clear all the data fields as per the spec.
|
|
input.partial_sigs = BTreeMap::new();
|
|
input.sighash_type = None;
|
|
input.redeem_script = None;
|
|
input.witness_script = None;
|
|
input.bip32_derivation = BTreeMap::new();
|
|
input.tap_script_sigs = BTreeMap::new();
|
|
input.tap_scripts = BTreeMap::new();
|
|
input.tap_key_sig = None;
|
|
});
|
|
|
|
// EXTRACTOR
|
|
let tx = psbt.extract_tx();
|
|
tx.verify(|_| {
|
|
Some(TxOut { value: input_value, script_pubkey: input_script_pubkey.clone() })
|
|
})
|
|
.expect("failed to verify transaction");
|
|
|
|
Ok(tx)
|
|
}
|
|
}
|
|
|
|
// Lifted and modified from BDK at https://github.com/bitcoindevkit/bdk/blob/8fbe40a9181cc9e22cabfc04d57dac5d459da87d/src/wallet/signer.rs#L469-L503
|
|
|
|
// Bitcoin Dev Kit
|
|
// Written in 2020 by Alekos Filini <alekos.filini@gmail.com>
|
|
//
|
|
// Copyright (c) 2020-2021 Bitcoin Dev Kit Developers
|
|
//
|
|
// This file is licensed under the Apache License, Version 2.0 <LICENSE-APACHE
|
|
// or http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
|
|
// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your option.
|
|
// You may not use this file except in accordance with one or both of these
|
|
// licenses.
|
|
|
|
// Calling this with `leaf_hash` = `None` will sign for key-spend
|
|
fn sign_psbt_schnorr(
|
|
secret_key: &secp256k1::SecretKey,
|
|
pubkey: XOnlyPublicKey,
|
|
leaf_hash: Option<TapLeafHash>,
|
|
psbt_input: &mut psbt::Input,
|
|
hash: TapSighashHash,
|
|
hash_ty: SchnorrSighashType,
|
|
secp: &Secp256k1<secp256k1::All>,
|
|
) {
|
|
let keypair = secp256k1::KeyPair::from_seckey_slice(secp, secret_key.as_ref()).unwrap();
|
|
let keypair = match leaf_hash {
|
|
None => keypair.tap_tweak(secp, psbt_input.tap_merkle_root).to_inner(),
|
|
Some(_) => keypair, // no tweak for script spend
|
|
};
|
|
|
|
let sig = secp.sign_schnorr(&Message::from_slice(&hash.into_inner()[..]).unwrap(), &keypair);
|
|
|
|
let final_signature = schnorr::Signature { sig, hash_ty };
|
|
|
|
if let Some(lh) = leaf_hash {
|
|
psbt_input.tap_script_sigs.insert((pubkey, lh), final_signature);
|
|
} else {
|
|
psbt_input.tap_key_sig = Some(final_signature);
|
|
}
|
|
}
|