use ::bitcoin::{Transaction, Txid}; use anyhow::{anyhow, Result}; use ecdsa_fun::{ adaptor::{Adaptor, EncryptedSignature}, nonce::Deterministic, Signature, }; use rand::{CryptoRng, RngCore}; use serde::{Deserialize, Serialize}; use sha2::Sha256; use crate::{ bitcoin::{ self, current_epoch, timelocks::Timelock, wait_for_cancel_timelock_to_expire, BroadcastSignedTransaction, BuildTxLockPsbt, GetBlockHeight, GetRawTransaction, Network, TransactionBlockHeight, TxCancel, WatchForRawTransaction, }, monero, protocol::{alice, bob}, serde::monero_private_key, ExpiredTimelocks, }; #[derive(Clone, Debug, Deserialize, Serialize, PartialEq)] pub struct State0 { b: bitcoin::SecretKey, s_b: cross_curve_dleq::Scalar, v_b: monero::PrivateViewKey, #[serde(with = "::bitcoin::util::amount::serde::as_sat")] btc: bitcoin::Amount, xmr: monero::Amount, cancel_timelock: Timelock, punish_timelock: Timelock, refund_address: bitcoin::Address, min_monero_confirmations: u32, } impl State0 { pub fn new( rng: &mut R, btc: bitcoin::Amount, xmr: monero::Amount, cancel_timelock: Timelock, punish_timelock: Timelock, refund_address: bitcoin::Address, min_monero_confirmations: u32, ) -> Self { let b = bitcoin::SecretKey::new_random(rng); let s_b = cross_curve_dleq::Scalar::random(rng); let v_b = monero::PrivateViewKey::new_random(rng); Self { b, s_b, v_b, btc, xmr, cancel_timelock, punish_timelock, refund_address, min_monero_confirmations, } } pub fn next_message(&self, rng: &mut R) -> bob::Message0 { let dleq_proof_s_b = cross_curve_dleq::Proof::new(rng, &self.s_b); bob::Message0 { B: self.b.public(), S_b_monero: monero::PublicKey::from_private_key(&monero::PrivateKey { scalar: self.s_b.into_ed25519(), }), S_b_bitcoin: self.s_b.into_secp256k1().into(), dleq_proof_s_b, v_b: self.v_b, refund_address: self.refund_address.clone(), } } pub async fn receive(self, wallet: &W, msg: alice::Message0) -> anyhow::Result where W: BuildTxLockPsbt + Network, { msg.dleq_proof_s_a.verify( msg.S_a_bitcoin.clone().into(), msg.S_a_monero .point .decompress() .ok_or_else(|| anyhow!("S_a is not a monero curve point"))?, )?; let tx_lock = bitcoin::TxLock::new(wallet, self.btc, msg.A, self.b.public()).await?; let v = msg.v_a + self.v_b; Ok(State1 { A: msg.A, b: self.b, s_b: self.s_b, S_a_monero: msg.S_a_monero, S_a_bitcoin: msg.S_a_bitcoin, v, btc: self.btc, xmr: self.xmr, cancel_timelock: self.cancel_timelock, punish_timelock: self.punish_timelock, refund_address: self.refund_address, redeem_address: msg.redeem_address, punish_address: msg.punish_address, tx_lock, min_monero_confirmations: self.min_monero_confirmations, }) } } #[derive(Debug, Deserialize, Serialize)] pub struct State1 { A: bitcoin::PublicKey, b: bitcoin::SecretKey, s_b: cross_curve_dleq::Scalar, S_a_monero: monero::PublicKey, S_a_bitcoin: bitcoin::PublicKey, v: monero::PrivateViewKey, #[serde(with = "::bitcoin::util::amount::serde::as_sat")] btc: bitcoin::Amount, xmr: monero::Amount, cancel_timelock: Timelock, punish_timelock: Timelock, refund_address: bitcoin::Address, redeem_address: bitcoin::Address, punish_address: bitcoin::Address, tx_lock: bitcoin::TxLock, min_monero_confirmations: u32, } impl State1 { pub fn next_message(&self) -> bob::Message1 { bob::Message1 { tx_lock: self.tx_lock.clone(), } } pub fn receive(self, msg: alice::Message1) -> Result { let tx_cancel = TxCancel::new(&self.tx_lock, self.cancel_timelock, self.A, self.b.public()); let tx_refund = bitcoin::TxRefund::new(&tx_cancel, &self.refund_address); bitcoin::verify_sig(&self.A, &tx_cancel.digest(), &msg.tx_cancel_sig)?; bitcoin::verify_encsig( self.A, self.s_b.into_secp256k1().into(), &tx_refund.digest(), &msg.tx_refund_encsig, )?; Ok(State2 { A: self.A, b: self.b, s_b: self.s_b, S_a_monero: self.S_a_monero, S_a_bitcoin: self.S_a_bitcoin, v: self.v, btc: self.btc, xmr: self.xmr, cancel_timelock: self.cancel_timelock, punish_timelock: self.punish_timelock, refund_address: self.refund_address, redeem_address: self.redeem_address, punish_address: self.punish_address, tx_lock: self.tx_lock, tx_cancel_sig_a: msg.tx_cancel_sig, tx_refund_encsig: msg.tx_refund_encsig, min_monero_confirmations: self.min_monero_confirmations, }) } } #[derive(Debug, Clone, Deserialize, Serialize, PartialEq)] pub struct State2 { pub A: bitcoin::PublicKey, pub b: bitcoin::SecretKey, pub s_b: cross_curve_dleq::Scalar, pub S_a_monero: monero::PublicKey, pub S_a_bitcoin: bitcoin::PublicKey, pub v: monero::PrivateViewKey, #[serde(with = "::bitcoin::util::amount::serde::as_sat")] btc: bitcoin::Amount, pub xmr: monero::Amount, pub cancel_timelock: Timelock, pub punish_timelock: Timelock, pub refund_address: bitcoin::Address, pub redeem_address: bitcoin::Address, pub punish_address: bitcoin::Address, pub tx_lock: bitcoin::TxLock, pub tx_cancel_sig_a: Signature, pub tx_refund_encsig: EncryptedSignature, pub min_monero_confirmations: u32, } impl State2 { pub fn next_message(&self) -> bob::Message2 { let tx_cancel = TxCancel::new(&self.tx_lock, self.cancel_timelock, self.A, self.b.public()); let tx_cancel_sig = self.b.sign(tx_cancel.digest()); let tx_punish = bitcoin::TxPunish::new(&tx_cancel, &self.punish_address, self.punish_timelock); let tx_punish_sig = self.b.sign(tx_punish.digest()); bob::Message2 { tx_punish_sig, tx_cancel_sig, } } pub async fn lock_btc(self, bitcoin_wallet: &W) -> Result where W: bitcoin::SignTxLock + bitcoin::BroadcastSignedTransaction, { let signed_tx_lock = bitcoin_wallet.sign_tx_lock(self.tx_lock.clone()).await?; tracing::info!("{}", self.tx_lock.txid()); let _ = bitcoin_wallet .broadcast_signed_transaction(signed_tx_lock) .await?; Ok(State3 { A: self.A, b: self.b, s_b: self.s_b, S_a_monero: self.S_a_monero, S_a_bitcoin: self.S_a_bitcoin, v: self.v, btc: self.btc, xmr: self.xmr, cancel_timelock: self.cancel_timelock, punish_timelock: self.punish_timelock, refund_address: self.refund_address, redeem_address: self.redeem_address, punish_address: self.punish_address, tx_lock: self.tx_lock, tx_cancel_sig_a: self.tx_cancel_sig_a, tx_refund_encsig: self.tx_refund_encsig, min_monero_confirmations: self.min_monero_confirmations, }) } } #[derive(Clone, Debug, Serialize, Deserialize, PartialEq)] pub struct State3 { pub A: bitcoin::PublicKey, pub b: bitcoin::SecretKey, pub s_b: cross_curve_dleq::Scalar, S_a_monero: monero::PublicKey, S_a_bitcoin: bitcoin::PublicKey, v: monero::PrivateViewKey, #[serde(with = "::bitcoin::util::amount::serde::as_sat")] btc: bitcoin::Amount, xmr: monero::Amount, pub cancel_timelock: Timelock, punish_timelock: Timelock, pub refund_address: bitcoin::Address, redeem_address: bitcoin::Address, punish_address: bitcoin::Address, pub tx_lock: bitcoin::TxLock, pub tx_cancel_sig_a: Signature, pub tx_refund_encsig: EncryptedSignature, pub min_monero_confirmations: u32, } impl State3 { pub async fn watch_for_lock_xmr(self, xmr_wallet: &W, msg: alice::Message2) -> Result where W: monero::WatchForTransfer, { let S_b_monero = monero::PublicKey::from_private_key(&monero::PrivateKey::from_scalar( self.s_b.into_ed25519(), )); let S = self.S_a_monero + S_b_monero; xmr_wallet .watch_for_transfer( S, self.v.public(), msg.tx_lock_proof, self.xmr, self.min_monero_confirmations, ) .await?; Ok(State4 { A: self.A, b: self.b, s_b: self.s_b, S_a_monero: self.S_a_monero, S_a_bitcoin: self.S_a_bitcoin, v: self.v, btc: self.btc, xmr: self.xmr, cancel_timelock: self.cancel_timelock, punish_timelock: self.punish_timelock, refund_address: self.refund_address, redeem_address: self.redeem_address, punish_address: self.punish_address, tx_lock: self.tx_lock, tx_cancel_sig_a: self.tx_cancel_sig_a, tx_refund_encsig: self.tx_refund_encsig, }) } pub async fn wait_for_cancel_timelock_to_expire(&self, bitcoin_wallet: &W) -> Result<()> where W: WatchForRawTransaction + TransactionBlockHeight + GetBlockHeight, { wait_for_cancel_timelock_to_expire( bitcoin_wallet, self.cancel_timelock, self.tx_lock.txid(), ) .await } pub fn state4(&self) -> State4 { State4 { A: self.A, b: self.b.clone(), s_b: self.s_b, S_a_monero: self.S_a_monero, S_a_bitcoin: self.S_a_bitcoin, v: self.v, btc: self.btc, xmr: self.xmr, cancel_timelock: self.cancel_timelock, punish_timelock: self.punish_timelock, refund_address: self.refund_address.clone(), redeem_address: self.redeem_address.clone(), punish_address: self.punish_address.clone(), tx_lock: self.tx_lock.clone(), tx_cancel_sig_a: self.tx_cancel_sig_a.clone(), tx_refund_encsig: self.tx_refund_encsig.clone(), } } pub fn tx_lock_id(&self) -> bitcoin::Txid { self.tx_lock.txid() } pub async fn current_epoch(&self, bitcoin_wallet: &W) -> Result where W: WatchForRawTransaction + TransactionBlockHeight + GetBlockHeight, { current_epoch( bitcoin_wallet, self.cancel_timelock, self.punish_timelock, self.tx_lock.txid(), ) .await } } #[derive(Debug, Clone, Deserialize, Serialize, PartialEq)] pub struct State4 { pub A: bitcoin::PublicKey, pub b: bitcoin::SecretKey, pub s_b: cross_curve_dleq::Scalar, S_a_monero: monero::PublicKey, pub S_a_bitcoin: bitcoin::PublicKey, v: monero::PrivateViewKey, #[serde(with = "::bitcoin::util::amount::serde::as_sat")] btc: bitcoin::Amount, xmr: monero::Amount, pub cancel_timelock: Timelock, punish_timelock: Timelock, pub refund_address: bitcoin::Address, pub redeem_address: bitcoin::Address, punish_address: bitcoin::Address, pub tx_lock: bitcoin::TxLock, pub tx_cancel_sig_a: Signature, pub tx_refund_encsig: EncryptedSignature, } impl State4 { pub fn next_message(&self) -> bob::Message3 { let tx_redeem = bitcoin::TxRedeem::new(&self.tx_lock, &self.redeem_address); let tx_redeem_encsig = self.b.encsign(self.S_a_bitcoin, tx_redeem.digest()); bob::Message3 { tx_redeem_encsig } } pub fn tx_redeem_encsig(&self) -> EncryptedSignature { let tx_redeem = bitcoin::TxRedeem::new(&self.tx_lock, &self.redeem_address); self.b.encsign(self.S_a_bitcoin, tx_redeem.digest()) } pub async fn check_for_tx_cancel(&self, bitcoin_wallet: &W) -> Result where W: GetRawTransaction, { let tx_cancel = bitcoin::TxCancel::new(&self.tx_lock, self.cancel_timelock, self.A, self.b.public()); let sig_a = self.tx_cancel_sig_a.clone(); let sig_b = self.b.sign(tx_cancel.digest()); let tx_cancel = tx_cancel .clone() .add_signatures(&self.tx_lock, (self.A, sig_a), (self.b.public(), sig_b)) .expect( "sig_{a,b} to be valid signatures for tx_cancel", ); let tx = bitcoin_wallet.get_raw_transaction(tx_cancel.txid()).await?; Ok(tx) } pub async fn submit_tx_cancel(&self, bitcoin_wallet: &W) -> Result where W: BroadcastSignedTransaction, { let tx_cancel = bitcoin::TxCancel::new(&self.tx_lock, self.cancel_timelock, self.A, self.b.public()); let sig_a = self.tx_cancel_sig_a.clone(); let sig_b = self.b.sign(tx_cancel.digest()); let tx_cancel = tx_cancel .clone() .add_signatures(&self.tx_lock, (self.A, sig_a), (self.b.public(), sig_b)) .expect( "sig_{a,b} to be valid signatures for tx_cancel", ); let tx_id = bitcoin_wallet .broadcast_signed_transaction(tx_cancel) .await?; Ok(tx_id) } pub async fn watch_for_redeem_btc(&self, bitcoin_wallet: &W) -> Result where W: WatchForRawTransaction, { let tx_redeem = bitcoin::TxRedeem::new(&self.tx_lock, &self.redeem_address); let tx_redeem_encsig = self.b.encsign(self.S_a_bitcoin, tx_redeem.digest()); let tx_redeem_candidate = bitcoin_wallet .watch_for_raw_transaction(tx_redeem.txid()) .await; let tx_redeem_sig = tx_redeem.extract_signature_by_key(tx_redeem_candidate, self.b.public())?; let s_a = bitcoin::recover(self.S_a_bitcoin, tx_redeem_sig, tx_redeem_encsig)?; let s_a = monero::private_key_from_secp256k1_scalar(s_a.into()); Ok(State5 { A: self.A, b: self.b.clone(), s_a, s_b: self.s_b, S_a_monero: self.S_a_monero, S_a_bitcoin: self.S_a_bitcoin, v: self.v, btc: self.btc, xmr: self.xmr, cancel_timelock: self.cancel_timelock, punish_timelock: self.punish_timelock, refund_address: self.refund_address.clone(), redeem_address: self.redeem_address.clone(), punish_address: self.punish_address.clone(), tx_lock: self.tx_lock.clone(), tx_refund_encsig: self.tx_refund_encsig.clone(), tx_cancel_sig: self.tx_cancel_sig_a.clone(), }) } pub async fn wait_for_cancel_timelock_to_expire(&self, bitcoin_wallet: &W) -> Result<()> where W: WatchForRawTransaction + TransactionBlockHeight + GetBlockHeight, { wait_for_cancel_timelock_to_expire( bitcoin_wallet, self.cancel_timelock, self.tx_lock.txid(), ) .await } pub async fn expired_timelock(&self, bitcoin_wallet: &W) -> Result where W: WatchForRawTransaction + TransactionBlockHeight + GetBlockHeight, { current_epoch( bitcoin_wallet, self.cancel_timelock, self.punish_timelock, self.tx_lock.txid(), ) .await } pub async fn refund_btc( &self, bitcoin_wallet: &W, ) -> Result<()> { let tx_cancel = bitcoin::TxCancel::new(&self.tx_lock, self.cancel_timelock, self.A, self.b.public()); let tx_refund = bitcoin::TxRefund::new(&tx_cancel, &self.refund_address); { let sig_b = self.b.sign(tx_cancel.digest()); let sig_a = self.tx_cancel_sig_a.clone(); let signed_tx_cancel = tx_cancel.clone().add_signatures( &self.tx_lock, (self.A, sig_a), (self.b.public(), sig_b), )?; let _ = bitcoin_wallet .broadcast_signed_transaction(signed_tx_cancel) .await?; } { let adaptor = Adaptor::>::default(); let sig_b = self.b.sign(tx_refund.digest()); let sig_a = adaptor .decrypt_signature(&self.s_b.into_secp256k1(), self.tx_refund_encsig.clone()); let signed_tx_refund = tx_refund.add_signatures( &tx_cancel.clone(), (self.A, sig_a), (self.b.public(), sig_b), )?; let _ = bitcoin_wallet .broadcast_signed_transaction(signed_tx_refund) .await?; } Ok(()) } pub fn tx_lock_id(&self) -> bitcoin::Txid { self.tx_lock.txid() } } #[derive(Debug, Clone, Deserialize, Serialize, PartialEq)] pub struct State5 { A: bitcoin::PublicKey, pub b: bitcoin::SecretKey, #[serde(with = "monero_private_key")] s_a: monero::PrivateKey, pub s_b: cross_curve_dleq::Scalar, S_a_monero: monero::PublicKey, pub S_a_bitcoin: bitcoin::PublicKey, pub v: monero::PrivateViewKey, #[serde(with = "::bitcoin::util::amount::serde::as_sat")] btc: bitcoin::Amount, xmr: monero::Amount, cancel_timelock: Timelock, punish_timelock: Timelock, refund_address: bitcoin::Address, pub redeem_address: bitcoin::Address, punish_address: bitcoin::Address, pub tx_lock: bitcoin::TxLock, tx_refund_encsig: EncryptedSignature, tx_cancel_sig: Signature, } impl State5 { pub async fn claim_xmr(&self, monero_wallet: &W) -> Result<()> where W: monero::CreateWalletForOutput, { let s_b = monero::PrivateKey { scalar: self.s_b.into_ed25519(), }; let s = self.s_a + s_b; // NOTE: This actually generates and opens a new wallet, closing the currently // open one. monero_wallet .create_and_load_wallet_for_output(s, self.v) .await?; Ok(()) } pub fn tx_lock_id(&self) -> bitcoin::Txid { self.tx_lock.txid() } }