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WIP: Test simplified swap execution

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This commit is contained in:
rishflab 2020-11-26 13:55:56 +11:00
parent dd07e2f882
commit ff7daf16f3
6 changed files with 552 additions and 4 deletions
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420
swap/src/alice.rs Normal file
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@ -0,0 +1,420 @@
//! Run an XMR/BTC swap in the role of Alice.
//! Alice holds XMR and wishes receive BTC.
use anyhow::Result;
use async_trait::async_trait;
use backoff::{backoff::Constant as ConstantBackoff, future::FutureOperation as _};
use genawaiter::GeneratorState;
use libp2p::{
core::{identity::Keypair, Multiaddr},
request_response::ResponseChannel,
NetworkBehaviour, PeerId,
};
use rand::rngs::OsRng;
use std::{sync::Arc, time::Duration};
use tokio::sync::Mutex;
use tracing::{debug, info, warn};
use uuid::Uuid;
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},
request_response::AliceToBob,
transport::SwapTransport,
TokioExecutor,
},
state,
storage::Database,
SwapAmounts, PUNISH_TIMELOCK, REFUND_TIMELOCK,
};
use xmr_btc::{
alice::{self, action_generator, Action, ReceiveBitcoinRedeemEncsig, State0},
bitcoin::BroadcastSignedTransaction,
bob,
monero::{CreateWalletForOutput, Transfer},
};
pub async fn swap(
bitcoin_wallet: Arc<bitcoin::Wallet>,
monero_wallet: Arc<monero::Wallet>,
db: Database,
listen: Multiaddr,
transport: SwapTransport,
behaviour: Alice,
) -> Result<()> {
struct Network(Arc<Mutex<Swarm>>);
// TODO: For retry, use `backoff::ExponentialBackoff` in production as opposed
// to `ConstantBackoff`.
#[async_trait]
impl ReceiveBitcoinRedeemEncsig for Network {
async fn receive_bitcoin_redeem_encsig(&mut self) -> bitcoin::EncryptedSignature {
#[derive(Debug)]
struct UnexpectedMessage;
let encsig = (|| async {
let mut guard = self.0.lock().await;
let encsig = match guard.next().await {
OutEvent::Message3(msg) => msg.tx_redeem_encsig,
other => {
warn!("Expected Bob's Bitcoin redeem encsig, got: {:?}", other);
return Err(backoff::Error::Transient(UnexpectedMessage));
}
};
Result::<_, backoff::Error<UnexpectedMessage>>::Ok(encsig)
})
.retry(ConstantBackoff::new(Duration::from_secs(1)))
.await
.expect("transient errors to be retried");
info!("Received Bitcoin redeem encsig");
encsig
}
}
let mut swarm = new_swarm(listen, transport, behaviour)?;
let message0: bob::Message0;
let mut state0: Option<alice::State0> = None;
let mut last_amounts: Option<SwapAmounts> = None;
// TODO: This loop is a neat idea for local development, as it allows us to keep
// Alice up and let Bob keep trying to connect, request amounts and/or send the
// first message of the handshake, but it comes at the cost of needing to handle
// mutable state, which has already been the source of a bug at one point. This
// is an obvious candidate for refactoring
loop {
match swarm.next().await {
OutEvent::ConnectionEstablished(bob) => {
info!("Connection established with: {}", bob);
}
OutEvent::Request(amounts::OutEvent::Btc { btc, channel }) => {
let amounts = calculate_amounts(btc);
last_amounts = Some(amounts);
swarm.send_amounts(channel, amounts);
let SwapAmounts { btc, xmr } = amounts;
let redeem_address = bitcoin_wallet.as_ref().new_address().await?;
let punish_address = redeem_address.clone();
// TODO: Pass this in using <R: RngCore + CryptoRng>
let rng = &mut OsRng;
let state = State0::new(
rng,
btc,
xmr,
REFUND_TIMELOCK,
PUNISH_TIMELOCK,
redeem_address,
punish_address,
);
info!("Commencing handshake");
swarm.set_state0(state.clone());
state0 = Some(state)
}
OutEvent::Message0(msg) => {
// We don't want Bob to be able to crash us by sending an out of
// order message. Keep looping if Bob has not requested amounts.
if last_amounts.is_some() {
// TODO: We should verify the amounts and notify Bob if they have changed.
message0 = msg;
break;
}
}
other => panic!("Unexpected event: {:?}", other),
};
}
let state1 = state0.expect("to be set").receive(message0)?;
let (state2, channel) = match swarm.next().await {
OutEvent::Message1 { msg, channel } => {
let state2 = state1.receive(msg);
(state2, channel)
}
other => panic!("Unexpected event: {:?}", other),
};
let msg = state2.next_message();
swarm.send_message1(channel, msg);
let state3 = match swarm.next().await {
OutEvent::Message2(msg) => state2.receive(msg)?,
other => panic!("Unexpected event: {:?}", other),
};
let swap_id = Uuid::new_v4();
db.insert_latest_state(swap_id, state::Alice::Handshaken(state3.clone()).into())
.await?;
info!("Handshake complete, we now have State3 for Alice.");
let network = Arc::new(Mutex::new(Network(unimplemented!())));
let mut action_generator = action_generator(
network,
bitcoin_wallet.clone(),
state3.clone(),
TX_LOCK_MINE_TIMEOUT,
);
loop {
let state = action_generator.async_resume().await;
tracing::info!("Resumed execution of generator, got: {:?}", state);
match state {
GeneratorState::Yielded(Action::LockXmr {
amount,
public_spend_key,
public_view_key,
}) => {
db.insert_latest_state(swap_id, state::Alice::BtcLocked(state3.clone()).into())
.await?;
let _ = monero_wallet
.transfer(public_spend_key, public_view_key, amount)
.await?;
db.insert_latest_state(swap_id, state::Alice::XmrLocked(state3.clone()).into())
.await?;
}
GeneratorState::Yielded(Action::RedeemBtc(tx)) => {
db.insert_latest_state(
swap_id,
state::Alice::BtcRedeemable {
state: state3.clone(),
redeem_tx: tx.clone(),
}
.into(),
)
.await?;
let _ = bitcoin_wallet.broadcast_signed_transaction(tx).await?;
}
GeneratorState::Yielded(Action::CancelBtc(tx)) => {
let _ = bitcoin_wallet.broadcast_signed_transaction(tx).await?;
}
GeneratorState::Yielded(Action::PunishBtc(tx)) => {
db.insert_latest_state(swap_id, state::Alice::BtcPunishable(state3.clone()).into())
.await?;
let _ = bitcoin_wallet.broadcast_signed_transaction(tx).await?;
}
GeneratorState::Yielded(Action::CreateMoneroWalletForOutput {
spend_key,
view_key,
}) => {
db.insert_latest_state(
swap_id,
state::Alice::BtcRefunded {
state: state3.clone(),
spend_key,
view_key,
}
.into(),
)
.await?;
monero_wallet
.create_and_load_wallet_for_output(spend_key, view_key)
.await?;
}
GeneratorState::Complete(()) => {
db.insert_latest_state(swap_id, state::Alice::SwapComplete.into())
.await?;
return Ok(());
}
}
}
}
pub type Swarm = libp2p::Swarm<Alice>;
fn new_swarm(listen: Multiaddr, transport: SwapTransport, behaviour: Alice) -> Result<Swarm> {
use anyhow::Context as _;
let local_peer_id = behaviour.peer_id();
let mut swarm = libp2p::swarm::SwarmBuilder::new(transport, behaviour, local_peer_id.clone())
.executor(Box::new(TokioExecutor {
handle: tokio::runtime::Handle::current(),
}))
.build();
Swarm::listen_on(&mut swarm, listen.clone())
.with_context(|| format!("Address is not supported: {:#}", listen))?;
tracing::info!("Initialized swarm: {}", local_peer_id);
Ok(swarm)
}
#[allow(clippy::large_enum_variant)]
#[derive(Debug)]
pub enum OutEvent {
ConnectionEstablished(PeerId),
Request(amounts::OutEvent), // Not-uniform with Bob on purpose, ready for adding Xmr event.
Message0(bob::Message0),
Message1 {
msg: bob::Message1,
channel: ResponseChannel<AliceToBob>,
},
Message2(bob::Message2),
Message3(bob::Message3),
}
impl From<peer_tracker::OutEvent> for OutEvent {
fn from(event: peer_tracker::OutEvent) -> Self {
match event {
peer_tracker::OutEvent::ConnectionEstablished(id) => {
OutEvent::ConnectionEstablished(id)
}
}
}
}
impl From<amounts::OutEvent> for OutEvent {
fn from(event: amounts::OutEvent) -> Self {
OutEvent::Request(event)
}
}
impl From<message0::OutEvent> for OutEvent {
fn from(event: message0::OutEvent) -> Self {
match event {
message0::OutEvent::Msg(msg) => OutEvent::Message0(msg),
}
}
}
impl From<message1::OutEvent> for OutEvent {
fn from(event: message1::OutEvent) -> Self {
match event {
message1::OutEvent::Msg { msg, channel } => OutEvent::Message1 { msg, channel },
}
}
}
impl From<message2::OutEvent> for OutEvent {
fn from(event: message2::OutEvent) -> Self {
match event {
message2::OutEvent::Msg { msg, .. } => OutEvent::Message2(msg),
}
}
}
impl From<message3::OutEvent> for OutEvent {
fn from(event: message3::OutEvent) -> Self {
match event {
message3::OutEvent::Msg(msg) => OutEvent::Message3(msg),
}
}
}
/// A `NetworkBehaviour` that represents an XMR/BTC swap node as Alice.
#[derive(NetworkBehaviour)]
#[behaviour(out_event = "OutEvent", event_process = false)]
#[allow(missing_debug_implementations)]
pub struct Alice {
pt: PeerTracker,
amounts: Amounts,
message0: Message0,
message1: Message1,
message2: Message2,
message3: Message3,
#[behaviour(ignore)]
identity: Keypair,
}
impl Alice {
pub fn identity(&self) -> Keypair {
self.identity.clone()
}
pub fn peer_id(&self) -> PeerId {
PeerId::from(self.identity.public())
}
/// Alice always sends her messages as a response to a request from Bob.
pub fn send_amounts(&mut self, channel: ResponseChannel<AliceToBob>, amounts: SwapAmounts) {
let msg = AliceToBob::Amounts(amounts);
self.amounts.send(channel, msg);
info!("Sent amounts response");
}
/// Message0 gets sent within the network layer using this state0.
pub fn set_state0(&mut self, state: State0) {
debug!("Set state 0");
let _ = self.message0.set_state(state);
}
/// Send Message1 to Bob in response to receiving his Message1.
pub fn send_message1(
&mut self,
channel: ResponseChannel<AliceToBob>,
msg: xmr_btc::alice::Message1,
) {
self.message1.send(channel, msg);
debug!("Sent Message1");
}
}
impl Default for Alice {
fn default() -> Self {
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,
}
}
}
fn calculate_amounts(btc: ::bitcoin::Amount) -> SwapAmounts {
// TODO: Get this from an exchange.
// This value corresponds to 100 XMR per BTC
const PICONERO_PER_SAT: u64 = 1_000_000;
let picos = btc.as_sat() * PICONERO_PER_SAT;
let xmr = monero::Amount::from_piconero(picos);
SwapAmounts { btc, xmr }
}
#[cfg(test)]
mod tests {
use super::*;
const ONE_BTC: u64 = 100_000_000;
const HUNDRED_XMR: u64 = 100_000_000_000_000;
#[test]
fn one_bitcoin_equals_a_hundred_moneroj() {
let btc = ::bitcoin::Amount::from_sat(ONE_BTC);
let want = monero::Amount::from_piconero(HUNDRED_XMR);
let SwapAmounts { xmr: got, .. } = calculate_amounts(btc);
assert_eq!(got, want);
}
}

12
swap/src/bin/simple_swap.rs
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@ -5,6 +5,7 @@ use swap::{
cli::Options,
storage::Database,
};
use uuid::Uuid;
#[tokio::main]
async fn main() -> Result<()> {
@ -19,7 +20,16 @@ async fn main() -> Result<()> {
match opt {
Options::Alice { .. } => {
simple_swap(bob_state, swarm, db, bitcoin_wallet, monero_wallet, rng).await?;
simple_swap(
bob_state,
swarm,
db,
bitcoin_wallet,
monero_wallet,
rng,
Uuid::new_v4(),
)
.await?;
}
Options::Recover { .. } => {
let _stored_state: BobState = unimplemented!("io.get_state(uuid)?");

2
swap/src/bob.rs
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@ -237,7 +237,7 @@ pub async fn swap(
pub type Swarm = libp2p::Swarm<Bob>;
fn new_swarm(transport: SwapTransport, behaviour: Bob) -> Result<Swarm> {
pub fn new_swarm(transport: SwapTransport, behaviour: Bob) -> Result<Swarm> {
let local_peer_id = behaviour.peer_id();
let swarm = libp2p::swarm::SwarmBuilder::new(transport, behaviour, local_peer_id.clone())

11
swap/src/bob_simple.rs
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@ -57,6 +57,7 @@ pub async fn simple_swap(
bitcoin_wallet: Arc<crate::bitcoin::Wallet>,
monero_wallet: Arc<crate::monero::Wallet>,
mut rng: OsRng,
swap_id: Uuid,
) -> Result<BobState> {
match state {
BobState::Started(mut cmd_tx, mut rsp_rx, btc, alice_peer_id) => {
@ -128,12 +129,14 @@ pub async fn simple_swap(
bitcoin_wallet,
monero_wallet,
rng,
swap_id,
)
.await
}
BobState::Negotiated(state2, alice_peer_id) => {
// Alice and Bob have exchanged info
let state3 = state2.lock_btc(bitcoin_wallet.as_ref()).await?;
// db.insert_latest_state(state);
simple_swap(
BobState::BtcLocked(state3, alice_peer_id),
swarm,
@ -141,6 +144,7 @@ pub async fn simple_swap(
bitcoin_wallet,
monero_wallet,
rng,
swap_id,
)
.await
}
@ -163,6 +167,7 @@ pub async fn simple_swap(
bitcoin_wallet,
monero_wallet,
rng,
swap_id,
)
.await
}
@ -184,6 +189,7 @@ pub async fn simple_swap(
bitcoin_wallet,
monero_wallet,
rng,
swap_id,
)
.await
}
@ -201,6 +207,7 @@ pub async fn simple_swap(
bitcoin_wallet,
monero_wallet,
rng,
swap_id,
)
.await
}
@ -217,7 +224,8 @@ pub async fn simple_swap(
db,
bitcoin_wallet,
monero_wallet,
rng,
rng,
swap_id
)
.await
@ -234,6 +242,7 @@ pub async fn simple_swap(
bitcoin_wallet,
monero_wallet,
rng,
swap_id,
)
.await
}

1
swap/src/lib.rs
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@ -1,6 +1,7 @@
use serde::{Deserialize, Serialize};
use std::fmt::{self, Display};
pub mod alice;
pub mod bitcoin;
pub mod bob;
pub mod bob_simple;

110
swap/tests/e2e.rs
View File

@ -2,10 +2,15 @@ use bitcoin_harness::Bitcoind;
use futures::{channel::mpsc, future::try_join};
use libp2p::Multiaddr;
use monero_harness::Monero;
use rand::rngs::OsRng;
use std::sync::Arc;
use swap::{alice, bob, network::transport::build, storage::Database};
use swap::{
alice, bob, bob::new_swarm, bob_simple, bob_simple::BobState, network::transport::build,
storage::Database,
};
use tempfile::tempdir;
use testcontainers::clients::Cli;
use uuid::Uuid;
use xmr_btc::bitcoin;
// NOTE: For some reason running these tests overflows the stack. In order to
@ -122,3 +127,106 @@ async fn swap() {
assert!(xmr_alice_final.as_piconero() <= xmr_alice - xmr);
assert_eq!(xmr_bob_final.as_piconero(), xmr_bob + xmr);
}
#[tokio::test]
async fn simple_swap_happy_path() {
use tracing_subscriber::util::SubscriberInitExt as _;
let _guard = tracing_subscriber::fmt()
.with_env_filter("swap=info,xmr_btc=info")
.with_ansi(false)
.set_default();
let alice_multiaddr: Multiaddr = "/ip4/127.0.0.1/tcp/9876"
.parse()
.expect("failed to parse Alice's address");
let cli = Cli::default();
let bitcoind = Bitcoind::new(&cli, "0.19.1").unwrap();
dbg!(&bitcoind.node_url);
let _ = bitcoind.init(5).await;
let btc = bitcoin::Amount::from_sat(1_000_000);
let btc_alice = bitcoin::Amount::ZERO;
let btc_bob = btc * 10;
// this xmr value matches the logic of alice::calculate_amounts i.e. btc *
// 10_000 * 100
let xmr = 1_000_000_000_000;
let xmr_alice = xmr * 10;
let xmr_bob = 0;
let alice_btc_wallet = Arc::new(
swap::bitcoin::Wallet::new("alice", bitcoind.node_url.clone())
.await
.unwrap(),
);
let bob_btc_wallet = Arc::new(
swap::bitcoin::Wallet::new("bob", bitcoind.node_url.clone())
.await
.unwrap(),
);
bitcoind
.mint(bob_btc_wallet.0.new_address().await.unwrap(), btc_bob)
.await
.unwrap();
let (monero, _container) =
Monero::new(&cli, None, vec!["alice".to_string(), "bob".to_string()])
.await
.unwrap();
monero
.init(vec![("alice", xmr_alice), ("bob", xmr_bob)])
.await
.unwrap();
let alice_xmr_wallet = Arc::new(swap::monero::Wallet(
monero.wallet("alice").unwrap().client(),
));
let bob_xmr_wallet = Arc::new(swap::monero::Wallet(monero.wallet("bob").unwrap().client()));
let alice_behaviour = alice::Alice::default();
let alice_transport = build(alice_behaviour.identity()).unwrap();
let db = Database::open(std::path::Path::new("../.swap-db/")).unwrap();
let alice_swap = todo!();
let db_dir = tempdir().unwrap();
let db = Database::open(db_dir.path()).unwrap();
let (cmd_tx, mut _cmd_rx) = mpsc::channel(1);
let (mut rsp_tx, rsp_rx) = mpsc::channel(1);
let bob_behaviour = bob::Bob::default();
let bob_transport = build(bob_behaviour.identity()).unwrap();
let bob_state = BobState::Started(cmd_tx, rsp_rx, btc_bob.as_sat(), alice_behaviour.peer_id());
let bob_swarm = new_swarm(bob_transport, bob_behaviour).unwrap();
let bob_swap = bob_simple::simple_swap(
bob_state,
bob_swarm,
db,
bob_btc_wallet.clone(),
bob_xmr_wallet.clone(),
OsRng,
Uuid::new_v4(),
);
// automate the verification step by accepting any amounts sent over by Alice
rsp_tx.try_send(swap::Rsp::VerifiedAmounts).unwrap();
try_join(alice_swap, bob_swap).await.unwrap();
let btc_alice_final = alice_btc_wallet.as_ref().balance().await.unwrap();
let btc_bob_final = bob_btc_wallet.as_ref().balance().await.unwrap();
let xmr_alice_final = alice_xmr_wallet.as_ref().get_balance().await.unwrap();
bob_xmr_wallet.as_ref().0.refresh().await.unwrap();
let xmr_bob_final = bob_xmr_wallet.as_ref().get_balance().await.unwrap();
assert_eq!(
btc_alice_final,
btc_alice + btc - bitcoin::Amount::from_sat(bitcoin::TX_FEE)
);
assert!(btc_bob_final <= btc_bob - btc);
assert!(xmr_alice_final.as_piconero() <= xmr_alice - xmr);
assert_eq!(xmr_bob_final.as_piconero(), xmr_bob + xmr);
}