-mod bitcoind_client;
+pub mod bitcoind_client;
mod cli;
mod convert;
mod disk;
use bitcoin_bech32::WitnessProgram;
use lightning::chain;
use lightning::chain::chaininterface::{BroadcasterInterface, ConfirmationTarget, FeeEstimator};
-use lightning::chain::chainmonitor::ChainMonitor;
+use lightning::chain::chainmonitor;
use lightning::chain::keysinterface::{InMemorySigner, KeysInterface, KeysManager};
use lightning::chain::transaction::OutPoint;
use lightning::chain::Filter;
use std::fs::File;
use std::io;
use std::io::Write;
+use std::ops::Deref;
use std::path::Path;
use std::sync::{Arc, Mutex};
-use std::thread;
use std::time::{Duration, SystemTime};
-use tokio::runtime::Runtime;
use tokio::sync::mpsc;
#[derive(PartialEq)]
>,
>;
-type ArcChainMonitor = ChainMonitor<
+type ChainMonitor = chainmonitor::ChainMonitor<
InMemorySigner,
Arc<dyn Filter>,
Arc<BitcoindClient>,
pub(crate) type PeerManager = SimpleArcPeerManager<
SocketDescriptor,
- ArcChainMonitor,
+ ChainMonitor,
BitcoindClient,
BitcoindClient,
dyn chain::Access,
>;
pub(crate) type ChannelManager =
- SimpleArcChannelManager<ArcChainMonitor, BitcoindClient, BitcoindClient, FilesystemLogger>;
+ SimpleArcChannelManager<ChainMonitor, BitcoindClient, BitcoindClient, FilesystemLogger>;
-fn handle_ldk_events(
+async fn handle_ldk_events(
peer_manager: Arc<PeerManager>, channel_manager: Arc<ChannelManager>,
- chain_monitor: Arc<ArcChainMonitor>, bitcoind_client: Arc<BitcoindClient>,
+ chain_monitor: Arc<ChainMonitor>, bitcoind_client: Arc<BitcoindClient>,
keys_manager: Arc<KeysManager>, payment_storage: PaymentInfoStorage, network: Network,
) {
let mut pending_txs: HashMap<OutPoint, Transaction> = HashMap::new();
.to_address();
let mut outputs = vec![HashMap::with_capacity(1)];
outputs[0].insert(addr, channel_value_satoshis as f64 / 100_000_000.0);
- let raw_tx = bitcoind_client.create_raw_transaction(outputs);
+ let raw_tx = bitcoind_client.create_raw_transaction(outputs).await;
// Have your wallet put the inputs into the transaction such that the output is
// satisfied.
- let funded_tx = bitcoind_client.fund_raw_transaction(raw_tx);
+ let funded_tx = bitcoind_client.fund_raw_transaction(raw_tx).await;
let change_output_position = funded_tx.changepos;
assert!(change_output_position == 0 || change_output_position == 1);
// Sign the final funding transaction and broadcast it.
- let signed_tx = bitcoind_client.sign_raw_transaction_with_wallet(funded_tx.hex);
+ let signed_tx =
+ bitcoind_client.sign_raw_transaction_with_wallet(funded_tx.hex).await;
assert_eq!(signed_tx.complete, true);
let final_tx: Transaction =
encode::deserialize(&hex_utils::to_vec(&signed_tx.hex).unwrap()).unwrap();
}
Event::PendingHTLCsForwardable { time_forwardable } => {
let forwarding_channel_manager = loop_channel_manager.clone();
- thread::spawn(move || {
+ tokio::spawn(async move {
let min = time_forwardable.as_secs();
let seconds_to_sleep = thread_rng().gen_range(min, min * 5);
- thread::sleep(Duration::new(seconds_to_sleep, 0));
+ tokio::time::sleep(Duration::from_secs(seconds_to_sleep)).await;
forwarding_channel_manager.process_pending_htlc_forwards();
});
}
Event::SpendableOutputs { outputs } => {
- let destination_address = bitcoind_client.get_new_address();
+ let destination_address = bitcoind_client.get_new_address().await;
let output_descriptors = &outputs.iter().map(|a| a).collect::<Vec<_>>();
let tx_feerate =
bitcoind_client.get_est_sat_per_1000_weight(ConfirmationTarget::Normal);
}
}
}
- thread::sleep(Duration::new(1, 0));
+ tokio::time::sleep(Duration::from_secs(1)).await;
}
}
-fn main() {
+#[tokio::main]
+pub async fn main() {
let args = match cli::parse_startup_args() {
Ok(user_args) => user_args,
Err(()) => return,
args.bitcoind_rpc_port,
args.bitcoind_rpc_username.clone(),
args.bitcoind_rpc_password.clone(),
- ) {
+ )
+ .await
+ {
Ok(client) => Arc::new(client),
Err(e) => {
println!("Failed to connect to bitcoind client: {}", e);
return;
}
};
- let mut bitcoind_rpc_client = bitcoind_client.get_new_rpc_client().unwrap();
// ## Setup
// Step 1: Initialize the FeeEstimator
let persister = Arc::new(FilesystemPersister::new(ldk_data_dir.clone()));
// Step 5: Initialize the ChainMonitor
- let chain_monitor: Arc<ArcChainMonitor> = Arc::new(ChainMonitor::new(
+ let chain_monitor: Arc<ChainMonitor> = Arc::new(chainmonitor::ChainMonitor::new(
None,
broadcaster.clone(),
logger.clone(),
} else {
let mut key = [0; 32];
thread_rng().fill_bytes(&mut key);
- let mut f = File::create(keys_seed_path).unwrap();
- f.write_all(&key).expect("Failed to write node keys seed to disk");
- f.sync_all().expect("Failed to sync node keys seed to disk");
+ match File::create(keys_seed_path.clone()) {
+ Ok(mut f) => {
+ f.write_all(&key).expect("Failed to write node keys seed to disk");
+ f.sync_all().expect("Failed to sync node keys seed to disk");
+ }
+ Err(e) => {
+ println!("ERROR: Unable to create keys seed file {}: {}", keys_seed_path, e);
+ return;
+ }
+ }
key
};
let cur = SystemTime::now().duration_since(SystemTime::UNIX_EPOCH).unwrap();
// Step 9: Initialize the ChannelManager
let user_config = UserConfig::default();
- let runtime = Runtime::new().unwrap();
let mut restarting_node = true;
let (channel_manager_blockhash, mut channel_manager) = {
if let Ok(mut f) = fs::File::open(format!("{}/manager", ldk_data_dir.clone())) {
} else {
// We're starting a fresh node.
restarting_node = false;
- let getinfo_resp = bitcoind_client.get_blockchain_info();
+ let getinfo_resp = bitcoind_client.get_blockchain_info().await;
+
let chain_params = ChainParameters {
network: args.network,
latest_hash: getinfo_resp.latest_blockhash,
));
}
chain_tip = Some(
- runtime
- .block_on(init::synchronize_listeners(
- &mut bitcoind_rpc_client,
- args.network,
- &mut cache,
- chain_listeners,
- ))
- .unwrap(),
+ init::synchronize_listeners(
+ &mut bitcoind_client.deref(),
+ args.network,
+ &mut cache,
+ chain_listeners,
+ )
+ .await
+ .unwrap(),
);
}
// We poll for events in handle_ldk_events(..) rather than waiting for them over the
// mpsc::channel, so we can leave the event receiver as unused.
- let (event_ntfn_sender, mut _event_ntfn_receiver) = mpsc::channel(2);
+ let (event_ntfn_sender, _event_ntfn_receiver) = mpsc::channel(2);
let peer_manager_connection_handler = peer_manager.clone();
let event_notifier = event_ntfn_sender.clone();
let listening_port = args.ldk_peer_listening_port;
- runtime.spawn(async move {
+ tokio::spawn(async move {
let listener = std::net::TcpListener::bind(format!("0.0.0.0:{}", listening_port)).unwrap();
loop {
let tcp_stream = listener.accept().unwrap().0;
// Step 17: Connect and Disconnect Blocks
if chain_tip.is_none() {
- chain_tip = Some(
- runtime.block_on(init::validate_best_block_header(&mut bitcoind_rpc_client)).unwrap(),
- );
+ chain_tip =
+ Some(init::validate_best_block_header(&mut bitcoind_client.deref()).await.unwrap());
}
let channel_manager_listener = channel_manager.clone();
let chain_monitor_listener = chain_monitor.clone();
+ let bitcoind_block_source = bitcoind_client.clone();
let network = args.network;
- runtime.spawn(async move {
- let chain_poller = poll::ChainPoller::new(&mut bitcoind_rpc_client, network);
+ tokio::spawn(async move {
+ let mut derefed = bitcoind_block_source.deref();
+ let chain_poller = poll::ChainPoller::new(&mut derefed, network);
let chain_listener = (chain_monitor_listener, channel_manager_listener);
let mut spv_client =
SpvClient::new(chain_tip.unwrap(), chain_poller, &mut cache, &chain_listener);
loop {
spv_client.poll_best_tip().await.unwrap();
- thread::sleep(Duration::new(1, 0));
+ tokio::time::sleep(Duration::from_secs(1)).await;
}
});
// Step 17 & 18: Initialize ChannelManager persistence & Once Per Minute: ChannelManager's
// timer_chan_freshness_every_min() and PeerManager's timer_tick_occurred
- let runtime_handle = runtime.handle();
let data_dir = ldk_data_dir.clone();
let persist_channel_manager_callback =
move |node: &ChannelManager| FilesystemPersister::persist_manager(data_dir.clone(), &*node);
);
let peer_manager_processor = peer_manager.clone();
- runtime_handle.spawn(async move {
+ tokio::spawn(async move {
loop {
peer_manager_processor.timer_tick_occurred();
- thread::sleep(Duration::new(60, 0));
+ tokio::time::sleep(Duration::from_secs(60)).await;
}
});
let keys_manager_listener = keys_manager.clone();
let payment_info: PaymentInfoStorage = Arc::new(Mutex::new(HashMap::new()));
let payment_info_for_events = payment_info.clone();
- let handle = runtime_handle.clone();
let network = args.network;
- thread::spawn(move || {
+ let bitcoind_rpc = bitcoind_client.clone();
+ tokio::spawn(async move {
handle_ldk_events(
peer_manager_event_listener,
channel_manager_event_listener,
chain_monitor_event_listener,
- bitcoind_client.clone(),
+ bitcoind_rpc,
keys_manager_listener,
payment_info_for_events,
network,
- );
+ )
+ .await;
});
// Reconnect to channel peers if possible.
match disk::read_channel_peer_data(Path::new(&peer_data_path)) {
Ok(mut info) => {
for (pubkey, peer_addr) in info.drain() {
- let _ = cli::connect_peer_if_necessary(
- pubkey,
- peer_addr,
- peer_manager.clone(),
- event_ntfn_sender.clone(),
- handle.clone(),
- );
+ for chan_info in channel_manager.list_channels() {
+ if pubkey == chan_info.remote_network_id {
+ let _ = cli::connect_peer_if_necessary(
+ pubkey,
+ peer_addr,
+ peer_manager.clone(),
+ event_ntfn_sender.clone(),
+ );
+ }
+ }
}
}
Err(e) => println!("ERROR: errored reading channel peer info from disk: {:?}", e),
event_ntfn_sender,
ldk_data_dir.clone(),
logger.clone(),
- handle,
args.network,
- );
+ )
+ .await;
}