//! Run an XMR/BTC swap in the role of Bob. //! Bob holds BTC and wishes receive XMR. use anyhow::Result; use async_trait::async_trait; use futures::{ channel::mpsc::{Receiver, Sender}, StreamExt, }; use genawaiter::GeneratorState; use libp2p::{core::identity::Keypair, Multiaddr, NetworkBehaviour, PeerId}; use rand::rngs::OsRng; use std::{process, sync::Arc}; use tokio::sync::Mutex; use tracing::{debug, info}; mod amounts; mod message0; mod message1; mod message2; mod message3; use self::{amounts::*, message0::*, message1::*, message2::*, message3::*}; use crate::{ bitcoin, bitcoin::TX_LOCK_MINE_TIMEOUT, monero, network::{ peer_tracker::{self, PeerTracker}, transport, TokioExecutor, }, Cmd, Never, Rsp, SwapAmounts, PUNISH_TIMELOCK, REFUND_TIMELOCK, }; use xmr_btc::{ alice, bitcoin::{BroadcastSignedTransaction, EncryptedSignature, SignTxLock}, bob::{self, action_generator, ReceiveTransferProof, State0}, monero::CreateWalletForOutput, }; // FIXME: This whole function is horrible, needs total re-write. pub async fn swap( bitcoin_wallet: Arc, monero_wallet: Arc, btc: u64, addr: Multiaddr, mut cmd_tx: Sender, mut rsp_rx: Receiver, refund_address: ::bitcoin::Address, ) -> Result<()> { struct Network(Swarm); #[async_trait] impl ReceiveTransferProof for Network { async fn receive_transfer_proof(&mut self) -> monero::TransferProof { todo!() } } let mut swarm = new_swarm()?; libp2p::Swarm::dial_addr(&mut swarm, addr)?; let alice = match swarm.next().await { OutEvent::ConnectionEstablished(alice) => alice, other => panic!("unexpected event: {:?}", other), }; info!("Connection established."); swarm.request_amounts(alice.clone(), btc); let (btc, xmr) = match swarm.next().await { OutEvent::Amounts(amounts) => { debug!("Got amounts from Alice: {:?}", amounts); let cmd = Cmd::VerifyAmounts(amounts); cmd_tx.try_send(cmd)?; let response = rsp_rx.next().await; if response == Some(Rsp::Abort) { info!("Amounts no good, aborting ..."); process::exit(0); } info!("User verified amounts, continuing with swap ..."); (amounts.btc, amounts.xmr) } other => panic!("unexpected event: {:?}", other), }; // TODO: Pass this in using let rng = &mut OsRng; let state0 = State0::new( rng, btc, xmr, REFUND_TIMELOCK, PUNISH_TIMELOCK, refund_address, ); swarm.send_message0(alice.clone(), state0.next_message(rng)); let state1 = match swarm.next().await { OutEvent::Message0(msg) => state0.receive(bitcoin_wallet.as_ref(), msg).await?, other => panic!("unexpected event: {:?}", other), }; swarm.send_message1(alice.clone(), state1.next_message()); let state2 = match swarm.next().await { OutEvent::Message1(msg) => { state1.receive(msg)? // TODO: Same as above. } other => panic!("unexpected event: {:?}", other), }; swarm.send_message2(alice.clone(), state2.next_message()); info!("Handshake complete, we now have State2 for Bob."); let network = Arc::new(Mutex::new(Network(swarm))); let mut action_generator = action_generator( network.clone(), monero_wallet.clone(), bitcoin_wallet.clone(), state2, TX_LOCK_MINE_TIMEOUT, ); loop { let state = action_generator.async_resume().await; info!("resumed execution of bob generator, got: {:?}", state); match state { GeneratorState::Yielded(bob::Action::LockBtc(tx_lock)) => { let signed_tx_lock = bitcoin_wallet.sign_tx_lock(tx_lock).await?; let _ = bitcoin_wallet .broadcast_signed_transaction(signed_tx_lock) .await?; } GeneratorState::Yielded(bob::Action::SendBtcRedeemEncsig(tx_redeem_encsig)) => { let mut guard = network.as_ref().lock().await; guard.0.send_message3(alice.clone(), tx_redeem_encsig); } GeneratorState::Yielded(bob::Action::CreateXmrWalletForOutput { spend_key, view_key, }) => { monero_wallet .create_and_load_wallet_for_output(spend_key, view_key) .await?; } GeneratorState::Yielded(bob::Action::CancelBtc(tx_cancel)) => { let _ = bitcoin_wallet .broadcast_signed_transaction(tx_cancel) .await?; } GeneratorState::Yielded(bob::Action::RefundBtc(tx_refund)) => { let _ = bitcoin_wallet .broadcast_signed_transaction(tx_refund) .await?; } GeneratorState::Complete(()) => return Ok(()), } } } pub type Swarm = libp2p::Swarm; fn new_swarm() -> Result { let behaviour = Bob::default(); let local_key_pair = behaviour.identity(); let local_peer_id = behaviour.peer_id(); let transport = { #[cfg(feature = "tor")] { transport::build(local_key_pair, None)? } #[cfg(not(feature = "tor"))] { transport::build(local_key_pair)? } }; let swarm = libp2p::swarm::SwarmBuilder::new(transport, behaviour, local_peer_id.clone()) .executor(Box::new(TokioExecutor { handle: tokio::runtime::Handle::current(), })) .build(); info!("Initialized swarm with identity {}", local_peer_id); Ok(swarm) } #[allow(clippy::large_enum_variant)] #[derive(Debug)] pub enum OutEvent { ConnectionEstablished(PeerId), Amounts(SwapAmounts), Message0(alice::Message0), Message1(alice::Message1), Message2(alice::Message2), } impl From for OutEvent { fn from(event: peer_tracker::OutEvent) -> Self { match event { peer_tracker::OutEvent::ConnectionEstablished(id) => { OutEvent::ConnectionEstablished(id) } } } } impl From for OutEvent { fn from(event: amounts::OutEvent) -> Self { match event { amounts::OutEvent::Amounts(amounts) => OutEvent::Amounts(amounts), } } } impl From for OutEvent { fn from(event: message0::OutEvent) -> Self { match event { message0::OutEvent::Msg(msg) => OutEvent::Message0(msg), } } } impl From for OutEvent { fn from(event: message1::OutEvent) -> Self { match event { message1::OutEvent::Msg(msg) => OutEvent::Message1(msg), } } } impl From for OutEvent { fn from(event: message2::OutEvent) -> Self { match event { message2::OutEvent::Msg(msg) => OutEvent::Message2(msg), } } } impl From for OutEvent { fn from(_: Never) -> Self { panic!("not ever") } } /// A `NetworkBehaviour` that represents an XMR/BTC swap node as Bob. #[derive(NetworkBehaviour)] #[behaviour(out_event = "OutEvent", event_process = false)] #[allow(missing_debug_implementations)] pub struct Bob { pt: PeerTracker, amounts: Amounts, message0: Message0, message1: Message1, message2: Message2, message3: Message3, #[behaviour(ignore)] identity: Keypair, } impl Bob { pub fn identity(&self) -> Keypair { self.identity.clone() } pub fn peer_id(&self) -> PeerId { PeerId::from(self.identity.public()) } /// Sends a message to Alice to get current amounts based on `btc`. pub fn request_amounts(&mut self, alice: PeerId, btc: u64) { let btc = ::bitcoin::Amount::from_sat(btc); let _id = self.amounts.request_amounts(alice.clone(), btc); debug!("Requesting amounts from: {}", alice); } /// Sends Bob's first message to Alice. pub fn send_message0(&mut self, alice: PeerId, msg: bob::Message0) { self.message0.send(alice, msg) } /// Sends Bob's second message to Alice. pub fn send_message1(&mut self, alice: PeerId, msg: bob::Message1) { self.message1.send(alice, msg) } /// Sends Bob's third message to Alice. pub fn send_message2(&mut self, alice: PeerId, msg: bob::Message2) { self.message2.send(alice, msg) } /// Sends Bob's fourth message to Alice. pub fn send_message3(&mut self, alice: PeerId, tx_redeem_encsig: EncryptedSignature) { let msg = bob::Message3 { tx_redeem_encsig }; self.message3.send(alice, msg) } /// Returns Alice's peer id if we are connected. pub fn peer_id_of_alice(&self) -> Option { self.pt.counterparty_peer_id() } } impl Default for Bob { fn default() -> Bob { let identity = Keypair::generate_ed25519(); Self { pt: PeerTracker::default(), amounts: Amounts::default(), message0: Message0::default(), message1: Message1::default(), message2: Message2::default(), message3: Message3::default(), identity, } } }