2 pub mod bitcoind_client;
9 use crate::bitcoind_client::BitcoindClient;
10 use crate::disk::FilesystemLogger;
11 use bitcoin::blockdata::transaction::Transaction;
12 use bitcoin::consensus::encode;
13 use bitcoin::network::constants::Network;
14 use bitcoin::BlockHash;
15 use bitcoin_bech32::WitnessProgram;
16 use disk::{INBOUND_PAYMENTS_FNAME, OUTBOUND_PAYMENTS_FNAME};
17 use lightning::chain::{chainmonitor, ChannelMonitorUpdateStatus};
18 use lightning::chain::{Filter, Watch};
19 use lightning::events::bump_transaction::{BumpTransactionEventHandler, Wallet};
20 use lightning::events::{Event, PaymentFailureReason, PaymentPurpose};
21 use lightning::ln::channelmanager::{self, RecentPaymentDetails};
22 use lightning::ln::channelmanager::{
23 ChainParameters, ChannelManagerReadArgs, PaymentId, SimpleArcChannelManager,
25 use lightning::ln::msgs::DecodeError;
26 use lightning::ln::peer_handler::{IgnoringMessageHandler, MessageHandler, SimpleArcPeerManager};
27 use lightning::ln::{ChannelId, PaymentHash, PaymentPreimage, PaymentSecret};
28 use lightning::onion_message::{DefaultMessageRouter, SimpleArcOnionMessenger};
29 use lightning::routing::gossip;
30 use lightning::routing::gossip::{NodeId, P2PGossipSync};
31 use lightning::routing::router::DefaultRouter;
32 use lightning::routing::scoring::ProbabilisticScoringFeeParameters;
33 use lightning::sign::{EntropySource, InMemorySigner, KeysManager, SpendableOutputDescriptor};
34 use lightning::util::config::UserConfig;
35 use lightning::util::persist::{self, KVStore, MonitorUpdatingPersister};
36 use lightning::util::ser::{Readable, ReadableArgs, Writeable, Writer};
37 use lightning::{chain, impl_writeable_tlv_based, impl_writeable_tlv_based_enum};
38 use lightning_background_processor::{process_events_async, GossipSync};
39 use lightning_block_sync::init;
40 use lightning_block_sync::poll;
41 use lightning_block_sync::SpvClient;
42 use lightning_block_sync::UnboundedCache;
43 use lightning_net_tokio::SocketDescriptor;
44 use lightning_persister::fs_store::FilesystemStore;
45 use rand::{thread_rng, Rng};
46 use std::collections::hash_map::Entry;
47 use std::collections::HashMap;
48 use std::convert::TryInto;
55 use std::sync::atomic::{AtomicBool, Ordering};
56 use std::sync::{Arc, Mutex, RwLock};
57 use std::time::{Duration, SystemTime};
59 pub(crate) const PENDING_SPENDABLE_OUTPUT_DIR: &'static str = "pending_spendable_outputs";
61 #[derive(Copy, Clone)]
62 pub(crate) enum HTLCStatus {
68 impl_writeable_tlv_based_enum!(HTLCStatus,
74 pub(crate) struct MillisatAmount(Option<u64>);
76 impl fmt::Display for MillisatAmount {
77 fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
79 Some(amt) => write!(f, "{}", amt),
80 None => write!(f, "unknown"),
85 impl Readable for MillisatAmount {
86 fn read<R: io::Read>(r: &mut R) -> Result<Self, DecodeError> {
87 let amt: Option<u64> = Readable::read(r)?;
88 Ok(MillisatAmount(amt))
92 impl Writeable for MillisatAmount {
93 fn write<W: Writer>(&self, w: &mut W) -> Result<(), std::io::Error> {
98 pub(crate) struct PaymentInfo {
99 preimage: Option<PaymentPreimage>,
100 secret: Option<PaymentSecret>,
102 amt_msat: MillisatAmount,
105 impl_writeable_tlv_based!(PaymentInfo, {
106 (0, preimage, required),
107 (2, secret, required),
108 (4, status, required),
109 (6, amt_msat, required),
112 pub(crate) struct InboundPaymentInfoStorage {
113 payments: HashMap<PaymentHash, PaymentInfo>,
116 impl_writeable_tlv_based!(InboundPaymentInfoStorage, {
117 (0, payments, required),
120 pub(crate) struct OutboundPaymentInfoStorage {
121 payments: HashMap<PaymentId, PaymentInfo>,
124 impl_writeable_tlv_based!(OutboundPaymentInfoStorage, {
125 (0, payments, required),
128 type ChainMonitor = chainmonitor::ChainMonitor<
130 Arc<dyn Filter + Send + Sync>,
133 Arc<FilesystemLogger>,
135 MonitorUpdatingPersister<
136 Arc<FilesystemStore>,
137 Arc<FilesystemLogger>,
144 pub(crate) type GossipVerifier = lightning_block_sync::gossip::GossipVerifier<
145 lightning_block_sync::gossip::TokioSpawner,
146 Arc<lightning_block_sync::rpc::RpcClient>,
147 Arc<FilesystemLogger>,
151 IgnoringMessageHandler,
155 pub(crate) type PeerManager = SimpleArcPeerManager<
164 pub(crate) type ChannelManager =
165 SimpleArcChannelManager<ChainMonitor, BitcoindClient, BitcoindClient, FilesystemLogger>;
167 pub(crate) type NetworkGraph = gossip::NetworkGraph<Arc<FilesystemLogger>>;
169 type OnionMessenger =
170 SimpleArcOnionMessenger<ChainMonitor, BitcoindClient, BitcoindClient, FilesystemLogger>;
172 pub(crate) type BumpTxEventHandler = BumpTransactionEventHandler<
174 Arc<Wallet<Arc<BitcoindClient>, Arc<FilesystemLogger>>>,
176 Arc<FilesystemLogger>,
179 async fn handle_ldk_events(
180 channel_manager: &Arc<ChannelManager>, bitcoind_client: &BitcoindClient,
181 network_graph: &NetworkGraph, keys_manager: &KeysManager,
182 bump_tx_event_handler: &BumpTxEventHandler,
183 inbound_payments: Arc<Mutex<InboundPaymentInfoStorage>>,
184 outbound_payments: Arc<Mutex<OutboundPaymentInfoStorage>>, fs_store: &Arc<FilesystemStore>,
185 network: Network, event: Event,
188 Event::FundingGenerationReady {
189 temporary_channel_id,
190 counterparty_node_id,
191 channel_value_satoshis,
195 // Construct the raw transaction with one output, that is paid the amount of the
197 let addr = WitnessProgram::from_scriptpubkey(
200 Network::Bitcoin => bitcoin_bech32::constants::Network::Bitcoin,
201 Network::Testnet => bitcoin_bech32::constants::Network::Testnet,
202 Network::Regtest => bitcoin_bech32::constants::Network::Regtest,
203 Network::Signet => bitcoin_bech32::constants::Network::Signet,
206 .expect("Lightning funding tx should always be to a SegWit output")
208 let mut outputs = vec![HashMap::with_capacity(1)];
209 outputs[0].insert(addr, channel_value_satoshis as f64 / 100_000_000.0);
210 let raw_tx = bitcoind_client.create_raw_transaction(outputs).await;
212 // Have your wallet put the inputs into the transaction such that the output is
214 let funded_tx = bitcoind_client.fund_raw_transaction(raw_tx).await;
216 // Sign the final funding transaction and broadcast it.
217 let signed_tx = bitcoind_client.sign_raw_transaction_with_wallet(funded_tx.hex).await;
218 assert_eq!(signed_tx.complete, true);
219 let final_tx: Transaction =
220 encode::deserialize(&hex_utils::to_vec(&signed_tx.hex).unwrap()).unwrap();
221 // Give the funding transaction back to LDK for opening the channel.
223 .funding_transaction_generated(
224 &temporary_channel_id,
225 &counterparty_node_id,
231 "\nERROR: Channel went away before we could fund it. The peer disconnected or refused the channel.");
233 io::stdout().flush().unwrap();
236 Event::PaymentClaimable {
242 via_user_channel_id: _,
245 counterparty_skimmed_fee_msat: _,
248 "\nEVENT: received payment from payment hash {} of {} millisatoshis",
249 payment_hash, amount_msat,
252 io::stdout().flush().unwrap();
253 let payment_preimage = match purpose {
254 PaymentPurpose::InvoicePayment { payment_preimage, .. } => payment_preimage,
255 PaymentPurpose::SpontaneousPayment(preimage) => Some(preimage),
257 channel_manager.claim_funds(payment_preimage.unwrap());
259 Event::PaymentClaimed {
265 sender_intended_total_msat: _,
268 "\nEVENT: claimed payment from payment hash {} of {} millisatoshis",
269 payment_hash, amount_msat,
272 io::stdout().flush().unwrap();
273 let (payment_preimage, payment_secret) = match purpose {
274 PaymentPurpose::InvoicePayment { payment_preimage, payment_secret, .. } => {
275 (payment_preimage, Some(payment_secret))
277 PaymentPurpose::SpontaneousPayment(preimage) => (Some(preimage), None),
279 let mut inbound = inbound_payments.lock().unwrap();
280 match inbound.payments.entry(payment_hash) {
281 Entry::Occupied(mut e) => {
282 let payment = e.get_mut();
283 payment.status = HTLCStatus::Succeeded;
284 payment.preimage = payment_preimage;
285 payment.secret = payment_secret;
287 Entry::Vacant(e) => {
288 e.insert(PaymentInfo {
289 preimage: payment_preimage,
290 secret: payment_secret,
291 status: HTLCStatus::Succeeded,
292 amt_msat: MillisatAmount(Some(amount_msat)),
296 fs_store.write("", "", INBOUND_PAYMENTS_FNAME, &inbound.encode()).unwrap();
299 payment_preimage, payment_hash, fee_paid_msat, payment_id, ..
301 let mut outbound = outbound_payments.lock().unwrap();
302 for (id, payment) in outbound.payments.iter_mut() {
303 if *id == payment_id.unwrap() {
304 payment.preimage = Some(payment_preimage);
305 payment.status = HTLCStatus::Succeeded;
307 "\nEVENT: successfully sent payment of {} millisatoshis{} from \
308 payment hash {} with preimage {}",
310 if let Some(fee) = fee_paid_msat {
311 format!(" (fee {} msat)", fee)
319 io::stdout().flush().unwrap();
322 fs_store.write("", "", OUTBOUND_PAYMENTS_FNAME, &outbound.encode()).unwrap();
324 Event::OpenChannelRequest {
325 ref temporary_channel_id, ref counterparty_node_id, ..
327 let mut random_bytes = [0u8; 16];
328 random_bytes.copy_from_slice(&keys_manager.get_secure_random_bytes()[..16]);
329 let user_channel_id = u128::from_be_bytes(random_bytes);
330 let res = channel_manager.accept_inbound_channel(
331 temporary_channel_id,
332 counterparty_node_id,
336 if let Err(e) = res {
338 "\nEVENT: Failed to accept inbound channel ({}) from {}: {:?}",
339 temporary_channel_id,
340 hex_utils::hex_str(&counterparty_node_id.serialize()),
345 "\nEVENT: Accepted inbound channel ({}) from {}",
346 temporary_channel_id,
347 hex_utils::hex_str(&counterparty_node_id.serialize()),
351 io::stdout().flush().unwrap();
353 Event::PaymentPathSuccessful { .. } => {}
354 Event::PaymentPathFailed { .. } => {}
355 Event::ProbeSuccessful { .. } => {}
356 Event::ProbeFailed { .. } => {}
357 Event::PaymentFailed { payment_hash, reason, payment_id, .. } => {
359 "\nEVENT: Failed to send payment to payment hash {}: {:?}",
361 if let Some(r) = reason { r } else { PaymentFailureReason::RetriesExhausted }
364 io::stdout().flush().unwrap();
366 let mut outbound = outbound_payments.lock().unwrap();
367 if outbound.payments.contains_key(&payment_id) {
368 let payment = outbound.payments.get_mut(&payment_id).unwrap();
369 payment.status = HTLCStatus::Failed;
371 fs_store.write("", "", OUTBOUND_PAYMENTS_FNAME, &outbound.encode()).unwrap();
373 Event::InvoiceRequestFailed { payment_id } => {
374 print!("\nEVENT: Failed to request invoice to send payment with id {}", payment_id);
376 io::stdout().flush().unwrap();
378 let mut outbound = outbound_payments.lock().unwrap();
379 if outbound.payments.contains_key(&payment_id) {
380 let payment = outbound.payments.get_mut(&payment_id).unwrap();
381 payment.status = HTLCStatus::Failed;
383 fs_store.write("", "", OUTBOUND_PAYMENTS_FNAME, &outbound.encode()).unwrap();
385 Event::PaymentForwarded {
389 claim_from_onchain_tx,
390 outbound_amount_forwarded_msat,
392 let read_only_network_graph = network_graph.read_only();
393 let nodes = read_only_network_graph.nodes();
394 let channels = channel_manager.list_channels();
396 let node_str = |channel_id: &Option<ChannelId>| match channel_id {
397 None => String::new(),
398 Some(channel_id) => match channels.iter().find(|c| c.channel_id == *channel_id) {
399 None => String::new(),
401 match nodes.get(&NodeId::from_pubkey(&channel.counterparty.node_id)) {
402 None => "private node".to_string(),
403 Some(node) => match &node.announcement_info {
404 None => "unnamed node".to_string(),
405 Some(announcement) => {
406 format!("node {}", announcement.alias)
413 let channel_str = |channel_id: &Option<ChannelId>| {
415 .map(|channel_id| format!(" with channel {}", channel_id))
419 format!(" from {}{}", node_str(&prev_channel_id), channel_str(&prev_channel_id));
421 format!(" to {}{}", node_str(&next_channel_id), channel_str(&next_channel_id));
423 let from_onchain_str = if claim_from_onchain_tx {
424 "from onchain downstream claim"
426 "from HTLC fulfill message"
428 let amt_args = if let Some(v) = outbound_amount_forwarded_msat {
433 if let Some(fee_earned) = fee_earned_msat {
435 "\nEVENT: Forwarded payment for {} msat{}{}, earning {} msat {}",
436 amt_args, from_prev_str, to_next_str, fee_earned, from_onchain_str
440 "\nEVENT: Forwarded payment for {} msat{}{}, claiming onchain {}",
441 amt_args, from_prev_str, to_next_str, from_onchain_str
445 io::stdout().flush().unwrap();
447 Event::HTLCHandlingFailed { .. } => {}
448 Event::PendingHTLCsForwardable { time_forwardable } => {
449 let forwarding_channel_manager = channel_manager.clone();
450 let min = time_forwardable.as_millis() as u64;
451 tokio::spawn(async move {
452 let millis_to_sleep = thread_rng().gen_range(min, min * 5) as u64;
453 tokio::time::sleep(Duration::from_millis(millis_to_sleep)).await;
454 forwarding_channel_manager.process_pending_htlc_forwards();
457 Event::SpendableOutputs { outputs, channel_id: _ } => {
458 // SpendableOutputDescriptors, of which outputs is a vec of, are critical to keep track
459 // of! While a `StaticOutput` descriptor is just an output to a static, well-known key,
460 // other descriptors are not currently ever regenerated for you by LDK. Once we return
461 // from this method, the descriptor will be gone, and you may lose track of some funds.
463 // Here we simply persist them to disk, with a background task running which will try
464 // to spend them regularly (possibly duplicatively/RBF'ing them). These can just be
465 // treated as normal funds where possible - they are only spendable by us and there is
466 // no rush to claim them.
467 for output in outputs {
468 let key = hex_utils::hex_str(&keys_manager.get_secure_random_bytes());
469 // Note that if the type here changes our read code needs to change as well.
470 let output: SpendableOutputDescriptor = output;
471 fs_store.write(PENDING_SPENDABLE_OUTPUT_DIR, "", &key, &output.encode()).unwrap();
474 Event::ChannelPending { channel_id, counterparty_node_id, .. } => {
476 "\nEVENT: Channel {} with peer {} is pending awaiting funding lock-in!",
478 hex_utils::hex_str(&counterparty_node_id.serialize()),
481 io::stdout().flush().unwrap();
483 Event::ChannelReady {
486 ref counterparty_node_id,
490 "\nEVENT: Channel {} with peer {} is ready to be used!",
492 hex_utils::hex_str(&counterparty_node_id.serialize()),
495 io::stdout().flush().unwrap();
497 Event::ChannelClosed {
501 counterparty_node_id,
502 channel_capacity_sats: _,
505 "\nEVENT: Channel {} with counterparty {} closed due to: {:?}",
507 counterparty_node_id.map(|id| format!("{}", id)).unwrap_or("".to_owned()),
511 io::stdout().flush().unwrap();
513 Event::DiscardFunding { .. } => {
514 // A "real" node should probably "lock" the UTXOs spent in funding transactions until
515 // the funding transaction either confirms, or this event is generated.
517 Event::HTLCIntercepted { .. } => {}
518 Event::BumpTransaction(event) => bump_tx_event_handler.handle_event(&event),
522 async fn start_ldk() {
523 let args = match args::parse_startup_args() {
524 Ok(user_args) => user_args,
528 // Initialize the LDK data directory if necessary.
529 let ldk_data_dir = format!("{}/.ldk", args.ldk_storage_dir_path);
530 fs::create_dir_all(ldk_data_dir.clone()).unwrap();
533 // Step 1: Initialize the Logger
534 let logger = Arc::new(FilesystemLogger::new(ldk_data_dir.clone()));
536 // Initialize our bitcoind client.
537 let bitcoind_client = match BitcoindClient::new(
538 args.bitcoind_rpc_host.clone(),
539 args.bitcoind_rpc_port,
540 args.bitcoind_rpc_username.clone(),
541 args.bitcoind_rpc_password.clone(),
542 tokio::runtime::Handle::current(),
547 Ok(client) => Arc::new(client),
549 println!("Failed to connect to bitcoind client: {}", e);
554 // Check that the bitcoind we've connected to is running the network we expect
555 let bitcoind_chain = bitcoind_client.get_blockchain_info().await.chain;
557 != match args.network {
558 bitcoin::Network::Bitcoin => "main",
559 bitcoin::Network::Testnet => "test",
560 bitcoin::Network::Regtest => "regtest",
561 bitcoin::Network::Signet => "signet",
564 "Chain argument ({}) didn't match bitcoind chain ({})",
565 args.network, bitcoind_chain
570 // Step 2: Initialize the FeeEstimator
572 // BitcoindClient implements the FeeEstimator trait, so it'll act as our fee estimator.
573 let fee_estimator = bitcoind_client.clone();
575 // Step 3: Initialize the BroadcasterInterface
577 // BitcoindClient implements the BroadcasterInterface trait, so it'll act as our transaction
579 let broadcaster = bitcoind_client.clone();
581 // Step 4: Initialize the KeysManager
583 // The key seed that we use to derive the node privkey (that corresponds to the node pubkey) and
584 // other secret key material.
585 let keys_seed_path = format!("{}/keys_seed", ldk_data_dir.clone());
586 let keys_seed = if let Ok(seed) = fs::read(keys_seed_path.clone()) {
587 assert_eq!(seed.len(), 32);
588 let mut key = [0; 32];
589 key.copy_from_slice(&seed);
592 let mut key = [0; 32];
593 thread_rng().fill_bytes(&mut key);
594 match File::create(keys_seed_path.clone()) {
596 Write::write_all(&mut f, &key).expect("Failed to write node keys seed to disk");
597 f.sync_all().expect("Failed to sync node keys seed to disk");
600 println!("ERROR: Unable to create keys seed file {}: {}", keys_seed_path, e);
606 let cur = SystemTime::now().duration_since(SystemTime::UNIX_EPOCH).unwrap();
607 let keys_manager = Arc::new(KeysManager::new(&keys_seed, cur.as_secs(), cur.subsec_nanos()));
609 let bump_tx_event_handler = Arc::new(BumpTransactionEventHandler::new(
610 Arc::clone(&broadcaster),
611 Arc::new(Wallet::new(Arc::clone(&bitcoind_client), Arc::clone(&logger))),
612 Arc::clone(&keys_manager),
616 // Step 5: Initialize Persistence
617 let fs_store = Arc::new(FilesystemStore::new(ldk_data_dir.clone().into()));
618 let persister = Arc::new(MonitorUpdatingPersister::new(
619 Arc::clone(&fs_store),
622 Arc::clone(&keys_manager),
623 Arc::clone(&keys_manager),
625 // Alternatively, you can use the `FilesystemStore` as a `Persist` directly, at the cost of
626 // larger `ChannelMonitor` update writes (but no deletion or cleanup):
627 //let persister = Arc::clone(&fs_store);
629 // Step 6: Initialize the ChainMonitor
630 let chain_monitor: Arc<ChainMonitor> = Arc::new(chainmonitor::ChainMonitor::new(
632 Arc::clone(&broadcaster),
634 Arc::clone(&fee_estimator),
635 Arc::clone(&persister),
638 // Step 7: Read ChannelMonitor state from disk
639 let mut channelmonitors = persister
640 .read_all_channel_monitors_with_updates(&bitcoind_client, &bitcoind_client)
642 // If you are using the `FilesystemStore` as a `Persist` directly, use
643 // `lightning::util::persist::read_channel_monitors` like this:
644 //read_channel_monitors(Arc::clone(&persister), Arc::clone(&keys_manager), Arc::clone(&keys_manager)).unwrap();
646 // Step 8: Poll for the best chain tip, which may be used by the channel manager & spv client
647 let polled_chain_tip = init::validate_best_block_header(bitcoind_client.as_ref())
649 .expect("Failed to fetch best block header and best block");
651 // Step 9: Initialize routing ProbabilisticScorer
652 let network_graph_path = format!("{}/network_graph", ldk_data_dir.clone());
654 Arc::new(disk::read_network(Path::new(&network_graph_path), args.network, logger.clone()));
656 let scorer_path = format!("{}/scorer", ldk_data_dir.clone());
657 let scorer = Arc::new(RwLock::new(disk::read_scorer(
658 Path::new(&scorer_path),
659 Arc::clone(&network_graph),
663 // Step 10: Create Router
664 let scoring_fee_params = ProbabilisticScoringFeeParameters::default();
665 let router = Arc::new(DefaultRouter::new(
666 network_graph.clone(),
668 keys_manager.get_secure_random_bytes(),
673 // Step 11: Initialize the ChannelManager
674 let mut user_config = UserConfig::default();
675 user_config.channel_handshake_limits.force_announced_channel_preference = false;
676 user_config.channel_handshake_config.negotiate_anchors_zero_fee_htlc_tx = true;
677 user_config.manually_accept_inbound_channels = true;
678 let mut restarting_node = true;
679 let (channel_manager_blockhash, channel_manager) = {
680 if let Ok(mut f) = fs::File::open(format!("{}/manager", ldk_data_dir.clone())) {
681 let mut channel_monitor_mut_references = Vec::new();
682 for (_, channel_monitor) in channelmonitors.iter_mut() {
683 channel_monitor_mut_references.push(channel_monitor);
685 let read_args = ChannelManagerReadArgs::new(
686 keys_manager.clone(),
687 keys_manager.clone(),
688 keys_manager.clone(),
689 fee_estimator.clone(),
690 chain_monitor.clone(),
695 channel_monitor_mut_references,
697 <(BlockHash, ChannelManager)>::read(&mut f, read_args).unwrap()
699 // We're starting a fresh node.
700 restarting_node = false;
702 let polled_best_block = polled_chain_tip.to_best_block();
703 let polled_best_block_hash = polled_best_block.block_hash();
705 ChainParameters { network: args.network, best_block: polled_best_block };
706 let fresh_channel_manager = channelmanager::ChannelManager::new(
707 fee_estimator.clone(),
708 chain_monitor.clone(),
712 keys_manager.clone(),
713 keys_manager.clone(),
714 keys_manager.clone(),
717 cur.as_secs() as u32,
719 (polled_best_block_hash, fresh_channel_manager)
723 // Step 12: Sync ChannelMonitors and ChannelManager to chain tip
724 let mut chain_listener_channel_monitors = Vec::new();
725 let mut cache = UnboundedCache::new();
726 let chain_tip = if restarting_node {
727 let mut chain_listeners = vec![(
728 channel_manager_blockhash,
729 &channel_manager as &(dyn chain::Listen + Send + Sync),
732 for (blockhash, channel_monitor) in channelmonitors.drain(..) {
733 let outpoint = channel_monitor.get_funding_txo().0;
734 chain_listener_channel_monitors.push((
736 (channel_monitor, broadcaster.clone(), fee_estimator.clone(), logger.clone()),
741 for monitor_listener_info in chain_listener_channel_monitors.iter_mut() {
742 chain_listeners.push((
743 monitor_listener_info.0,
744 &monitor_listener_info.1 as &(dyn chain::Listen + Send + Sync),
748 init::synchronize_listeners(
749 bitcoind_client.as_ref(),
760 // Step 13: Give ChannelMonitors to ChainMonitor
761 for item in chain_listener_channel_monitors.drain(..) {
762 let channel_monitor = item.1 .0;
763 let funding_outpoint = item.2;
765 chain_monitor.watch_channel(funding_outpoint, channel_monitor),
766 Ok(ChannelMonitorUpdateStatus::Completed)
770 // Step 14: Optional: Initialize the P2PGossipSync
772 Arc::new(P2PGossipSync::new(Arc::clone(&network_graph), None, Arc::clone(&logger)));
774 // Step 15: Initialize the PeerManager
775 let channel_manager: Arc<ChannelManager> = Arc::new(channel_manager);
776 let onion_messenger: Arc<OnionMessenger> = Arc::new(OnionMessenger::new(
777 Arc::clone(&keys_manager),
778 Arc::clone(&keys_manager),
780 Arc::new(DefaultMessageRouter {}),
781 Arc::clone(&channel_manager),
782 IgnoringMessageHandler {},
784 let mut ephemeral_bytes = [0; 32];
785 let current_time = SystemTime::now().duration_since(SystemTime::UNIX_EPOCH).unwrap().as_secs();
786 rand::thread_rng().fill_bytes(&mut ephemeral_bytes);
787 let lightning_msg_handler = MessageHandler {
788 chan_handler: channel_manager.clone(),
789 route_handler: gossip_sync.clone(),
790 onion_message_handler: onion_messenger.clone(),
791 custom_message_handler: IgnoringMessageHandler {},
793 let peer_manager: Arc<PeerManager> = Arc::new(PeerManager::new(
794 lightning_msg_handler,
795 current_time.try_into().unwrap(),
798 Arc::clone(&keys_manager),
801 // Install a GossipVerifier in in the P2PGossipSync
802 let utxo_lookup = GossipVerifier::new(
803 Arc::clone(&bitcoind_client.bitcoind_rpc_client),
804 lightning_block_sync::gossip::TokioSpawner,
805 Arc::clone(&gossip_sync),
806 Arc::clone(&peer_manager),
808 gossip_sync.add_utxo_lookup(Some(utxo_lookup));
811 // Step 16: Initialize networking
813 let peer_manager_connection_handler = peer_manager.clone();
814 let listening_port = args.ldk_peer_listening_port;
815 let stop_listen_connect = Arc::new(AtomicBool::new(false));
816 let stop_listen = Arc::clone(&stop_listen_connect);
817 tokio::spawn(async move {
818 let listener = tokio::net::TcpListener::bind(format!("[::]:{}", listening_port))
820 .expect("Failed to bind to listen port - is something else already listening on it?");
822 let peer_mgr = peer_manager_connection_handler.clone();
823 let tcp_stream = listener.accept().await.unwrap().0;
824 if stop_listen.load(Ordering::Acquire) {
827 tokio::spawn(async move {
828 lightning_net_tokio::setup_inbound(
830 tcp_stream.into_std().unwrap(),
837 // Step 17: Connect and Disconnect Blocks
838 let channel_manager_listener = channel_manager.clone();
839 let chain_monitor_listener = chain_monitor.clone();
840 let bitcoind_block_source = bitcoind_client.clone();
841 let network = args.network;
842 tokio::spawn(async move {
843 let chain_poller = poll::ChainPoller::new(bitcoind_block_source.as_ref(), network);
844 let chain_listener = (chain_monitor_listener, channel_manager_listener);
845 let mut spv_client = SpvClient::new(chain_tip, chain_poller, &mut cache, &chain_listener);
847 spv_client.poll_best_tip().await.unwrap();
848 tokio::time::sleep(Duration::from_secs(1)).await;
852 let inbound_payments = Arc::new(Mutex::new(disk::read_inbound_payment_info(Path::new(
853 &format!("{}/{}", ldk_data_dir, INBOUND_PAYMENTS_FNAME),
855 let outbound_payments = Arc::new(Mutex::new(disk::read_outbound_payment_info(Path::new(
856 &format!("{}/{}", ldk_data_dir, OUTBOUND_PAYMENTS_FNAME),
858 let recent_payments_payment_ids = channel_manager
859 .list_recent_payments()
861 .filter_map(|p| match p {
862 RecentPaymentDetails::Pending { payment_id, .. } => Some(payment_id),
863 RecentPaymentDetails::Fulfilled { payment_id, .. } => Some(payment_id),
864 RecentPaymentDetails::Abandoned { payment_id, .. } => Some(payment_id),
865 RecentPaymentDetails::AwaitingInvoice { payment_id } => Some(payment_id),
867 .collect::<Vec<PaymentId>>();
868 for (payment_id, payment_info) in outbound_payments
873 .filter(|(_, i)| matches!(i.status, HTLCStatus::Pending))
875 if !recent_payments_payment_ids.contains(payment_id) {
876 payment_info.status = HTLCStatus::Failed;
880 .write("", "", OUTBOUND_PAYMENTS_FNAME, &outbound_payments.lock().unwrap().encode())
883 // Step 18: Handle LDK Events
884 let channel_manager_event_listener = Arc::clone(&channel_manager);
885 let bitcoind_client_event_listener = Arc::clone(&bitcoind_client);
886 let network_graph_event_listener = Arc::clone(&network_graph);
887 let keys_manager_event_listener = Arc::clone(&keys_manager);
888 let inbound_payments_event_listener = Arc::clone(&inbound_payments);
889 let outbound_payments_event_listener = Arc::clone(&outbound_payments);
890 let fs_store_event_listener = Arc::clone(&fs_store);
891 let network = args.network;
892 let event_handler = move |event: Event| {
893 let channel_manager_event_listener = Arc::clone(&channel_manager_event_listener);
894 let bitcoind_client_event_listener = Arc::clone(&bitcoind_client_event_listener);
895 let network_graph_event_listener = Arc::clone(&network_graph_event_listener);
896 let keys_manager_event_listener = Arc::clone(&keys_manager_event_listener);
897 let bump_tx_event_handler = Arc::clone(&bump_tx_event_handler);
898 let inbound_payments_event_listener = Arc::clone(&inbound_payments_event_listener);
899 let outbound_payments_event_listener = Arc::clone(&outbound_payments_event_listener);
900 let fs_store_event_listener = Arc::clone(&fs_store_event_listener);
903 &channel_manager_event_listener,
904 &bitcoind_client_event_listener,
905 &network_graph_event_listener,
906 &keys_manager_event_listener,
907 &bump_tx_event_handler,
908 inbound_payments_event_listener,
909 outbound_payments_event_listener,
910 &fs_store_event_listener,
918 // Step 19: Persist ChannelManager and NetworkGraph
919 let persister = Arc::new(FilesystemStore::new(ldk_data_dir.clone().into()));
921 // Step 20: Background Processing
922 let (bp_exit, bp_exit_check) = tokio::sync::watch::channel(());
923 let mut background_processor = tokio::spawn(process_events_async(
924 Arc::clone(&persister),
926 chain_monitor.clone(),
927 channel_manager.clone(),
928 GossipSync::p2p(gossip_sync.clone()),
929 peer_manager.clone(),
931 Some(scorer.clone()),
933 let mut bp_exit_fut_check = bp_exit_check.clone();
934 Box::pin(async move {
936 _ = tokio::time::sleep(t) => false,
937 _ = bp_exit_fut_check.changed() => true,
944 // Regularly reconnect to channel peers.
945 let connect_cm = Arc::clone(&channel_manager);
946 let connect_pm = Arc::clone(&peer_manager);
947 let peer_data_path = format!("{}/channel_peer_data", ldk_data_dir);
948 let stop_connect = Arc::clone(&stop_listen_connect);
949 tokio::spawn(async move {
950 let mut interval = tokio::time::interval(Duration::from_secs(1));
951 interval.set_missed_tick_behavior(tokio::time::MissedTickBehavior::Delay);
953 interval.tick().await;
954 match disk::read_channel_peer_data(Path::new(&peer_data_path)) {
956 let peers = connect_pm.get_peer_node_ids();
957 for node_id in connect_cm
960 .map(|chan| chan.counterparty.node_id)
961 .filter(|id| !peers.iter().any(|(pk, _)| id == pk))
963 if stop_connect.load(Ordering::Acquire) {
966 for (pubkey, peer_addr) in info.iter() {
967 if *pubkey == node_id {
968 let _ = cli::do_connect_peer(
971 Arc::clone(&connect_pm),
978 Err(e) => println!("ERROR: errored reading channel peer info from disk: {:?}", e),
983 // Regularly broadcast our node_announcement. This is only required (or possible) if we have
984 // some public channels.
985 let peer_man = Arc::clone(&peer_manager);
986 let chan_man = Arc::clone(&channel_manager);
987 let network = args.network;
988 tokio::spawn(async move {
989 // First wait a minute until we have some peers and maybe have opened a channel.
990 tokio::time::sleep(Duration::from_secs(60)).await;
991 // Then, update our announcement once an hour to keep it fresh but avoid unnecessary churn
992 // in the global gossip network.
993 let mut interval = tokio::time::interval(Duration::from_secs(3600));
995 interval.tick().await;
996 // Don't bother trying to announce if we don't have any public channls, though our
997 // peers should drop such an announcement anyway. Note that announcement may not
998 // propagate until we have a channel with 6+ confirmations.
999 if chan_man.list_channels().iter().any(|chan| chan.is_public) {
1000 peer_man.broadcast_node_announcement(
1002 args.ldk_announced_node_name,
1003 args.ldk_announced_listen_addr.clone(),
1009 tokio::spawn(sweep::periodic_sweep(
1010 ldk_data_dir.clone(),
1011 Arc::clone(&keys_manager),
1012 Arc::clone(&logger),
1013 Arc::clone(&persister),
1014 Arc::clone(&bitcoind_client),
1015 Arc::clone(&channel_manager),
1019 let cli_channel_manager = Arc::clone(&channel_manager);
1020 let cli_persister = Arc::clone(&persister);
1021 let cli_logger = Arc::clone(&logger);
1022 let cli_peer_manager = Arc::clone(&peer_manager);
1023 let cli_poll = tokio::task::spawn_blocking(move || {
1024 cli::poll_for_user_input(
1026 cli_channel_manager,
1039 // Exit if either CLI polling exits or the background processor exits (which shouldn't happen
1040 // unless we fail to write to the filesystem).
1041 let mut bg_res = Ok(Ok(()));
1044 bg_exit = &mut background_processor => {
1049 // Disconnect our peers and stop accepting new connections. This ensures we don't continue
1050 // updating our channel data after we've stopped the background processor.
1051 stop_listen_connect.store(true, Ordering::Release);
1052 peer_manager.disconnect_all_peers();
1054 if let Err(e) = bg_res {
1055 let persist_res = persister
1057 persist::CHANNEL_MANAGER_PERSISTENCE_PRIMARY_NAMESPACE,
1058 persist::CHANNEL_MANAGER_PERSISTENCE_SECONDARY_NAMESPACE,
1059 persist::CHANNEL_MANAGER_PERSISTENCE_KEY,
1060 &channel_manager.encode(),
1063 use lightning::util::logger::Logger;
1064 lightning::log_error!(
1066 "Last-ditch ChannelManager persistence result: {:?}",
1070 "ERR: background processing stopped with result {:?}, exiting.\n\
1071 Last-ditch ChannelManager persistence result {:?}",
1076 // Stop the background processor.
1077 if !bp_exit.is_closed() {
1078 bp_exit.send(()).unwrap();
1079 background_processor.await.unwrap().unwrap();
1084 pub async fn main() {
1085 #[cfg(not(target_os = "windows"))]
1087 // Catch Ctrl-C with a dummy signal handler.
1089 let mut new_action: libc::sigaction = core::mem::zeroed();
1090 let mut old_action: libc::sigaction = core::mem::zeroed();
1092 extern "C" fn dummy_handler(
1093 _: libc::c_int, _: *const libc::siginfo_t, _: *const libc::c_void,
1097 new_action.sa_sigaction = dummy_handler as libc::sighandler_t;
1098 new_action.sa_flags = libc::SA_SIGINFO;
1102 &new_action as *const libc::sigaction,
1103 &mut old_action as *mut libc::sigaction,