1 // This file is Copyright its original authors, visible in version control
4 // This file is licensed under the Apache License, Version 2.0 <LICENSE-APACHE
5 // or http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
6 // <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your option.
7 // You may not use this file except in accordance with one or both of these
10 //! Top level peer message handling and socket handling logic lives here.
12 //! Instead of actually servicing sockets ourselves we require that you implement the
13 //! SocketDescriptor interface and use that to receive actions which you should perform on the
14 //! socket, and call into PeerManager with bytes read from the socket. The PeerManager will then
15 //! call into the provided message handlers (probably a ChannelManager and P2PGossipSync) with
16 //! messages they should handle, and encoding/sending response messages.
18 use bitcoin::secp256k1::{self, Secp256k1, SecretKey, PublicKey};
20 use crate::chain::keysinterface::{KeysManager, NodeSigner, Recipient};
21 use crate::events::{MessageSendEvent, MessageSendEventsProvider, OnionMessageProvider};
22 use crate::ln::features::{InitFeatures, NodeFeatures};
24 use crate::ln::msgs::{ChannelMessageHandler, LightningError, NetAddress, OnionMessageHandler, RoutingMessageHandler};
25 use crate::ln::channelmanager::{SimpleArcChannelManager, SimpleRefChannelManager};
26 use crate::util::ser::{VecWriter, Writeable, Writer};
27 use crate::ln::peer_channel_encryptor::{PeerChannelEncryptor,NextNoiseStep};
29 use crate::ln::wire::Encode;
30 use crate::onion_message::{CustomOnionMessageContents, CustomOnionMessageHandler, SimpleArcOnionMessenger, SimpleRefOnionMessenger};
31 use crate::routing::gossip::{NetworkGraph, P2PGossipSync, NodeId, NodeAlias};
32 use crate::util::atomic_counter::AtomicCounter;
33 use crate::util::logger::Logger;
35 use crate::prelude::*;
37 use alloc::collections::LinkedList;
38 use crate::sync::{Arc, Mutex, MutexGuard, FairRwLock};
39 use core::sync::atomic::{AtomicBool, AtomicU32, Ordering};
40 use core::{cmp, hash, fmt, mem};
42 use core::convert::Infallible;
43 #[cfg(feature = "std")] use std::error;
45 use bitcoin::hashes::sha256::Hash as Sha256;
46 use bitcoin::hashes::sha256::HashEngine as Sha256Engine;
47 use bitcoin::hashes::{HashEngine, Hash};
49 /// A handler provided to [`PeerManager`] for reading and handling custom messages.
51 /// [BOLT 1] specifies a custom message type range for use with experimental or application-specific
52 /// messages. `CustomMessageHandler` allows for user-defined handling of such types. See the
53 /// [`lightning_custom_message`] crate for tools useful in composing more than one custom handler.
55 /// [BOLT 1]: https://github.com/lightning/bolts/blob/master/01-messaging.md
56 /// [`lightning_custom_message`]: https://docs.rs/lightning_custom_message/latest/lightning_custom_message
57 pub trait CustomMessageHandler: wire::CustomMessageReader {
58 /// Handles the given message sent from `sender_node_id`, possibly producing messages for
59 /// [`CustomMessageHandler::get_and_clear_pending_msg`] to return and thus for [`PeerManager`]
61 fn handle_custom_message(&self, msg: Self::CustomMessage, sender_node_id: &PublicKey) -> Result<(), LightningError>;
63 /// Returns the list of pending messages that were generated by the handler, clearing the list
64 /// in the process. Each message is paired with the node id of the intended recipient. If no
65 /// connection to the node exists, then the message is simply not sent.
66 fn get_and_clear_pending_msg(&self) -> Vec<(PublicKey, Self::CustomMessage)>;
69 /// A dummy struct which implements `RoutingMessageHandler` without storing any routing information
70 /// or doing any processing. You can provide one of these as the route_handler in a MessageHandler.
71 pub struct IgnoringMessageHandler{}
72 impl MessageSendEventsProvider for IgnoringMessageHandler {
73 fn get_and_clear_pending_msg_events(&self) -> Vec<MessageSendEvent> { Vec::new() }
75 impl RoutingMessageHandler for IgnoringMessageHandler {
76 fn handle_node_announcement(&self, _msg: &msgs::NodeAnnouncement) -> Result<bool, LightningError> { Ok(false) }
77 fn handle_channel_announcement(&self, _msg: &msgs::ChannelAnnouncement) -> Result<bool, LightningError> { Ok(false) }
78 fn handle_channel_update(&self, _msg: &msgs::ChannelUpdate) -> Result<bool, LightningError> { Ok(false) }
79 fn get_next_channel_announcement(&self, _starting_point: u64) ->
80 Option<(msgs::ChannelAnnouncement, Option<msgs::ChannelUpdate>, Option<msgs::ChannelUpdate>)> { None }
81 fn get_next_node_announcement(&self, _starting_point: Option<&NodeId>) -> Option<msgs::NodeAnnouncement> { None }
82 fn peer_connected(&self, _their_node_id: &PublicKey, _init: &msgs::Init, _inbound: bool) -> Result<(), ()> { Ok(()) }
83 fn handle_reply_channel_range(&self, _their_node_id: &PublicKey, _msg: msgs::ReplyChannelRange) -> Result<(), LightningError> { Ok(()) }
84 fn handle_reply_short_channel_ids_end(&self, _their_node_id: &PublicKey, _msg: msgs::ReplyShortChannelIdsEnd) -> Result<(), LightningError> { Ok(()) }
85 fn handle_query_channel_range(&self, _their_node_id: &PublicKey, _msg: msgs::QueryChannelRange) -> Result<(), LightningError> { Ok(()) }
86 fn handle_query_short_channel_ids(&self, _their_node_id: &PublicKey, _msg: msgs::QueryShortChannelIds) -> Result<(), LightningError> { Ok(()) }
87 fn provided_node_features(&self) -> NodeFeatures { NodeFeatures::empty() }
88 fn provided_init_features(&self, _their_node_id: &PublicKey) -> InitFeatures {
91 fn processing_queue_high(&self) -> bool { false }
93 impl OnionMessageProvider for IgnoringMessageHandler {
94 fn next_onion_message_for_peer(&self, _peer_node_id: PublicKey) -> Option<msgs::OnionMessage> { None }
96 impl OnionMessageHandler for IgnoringMessageHandler {
97 fn handle_onion_message(&self, _their_node_id: &PublicKey, _msg: &msgs::OnionMessage) {}
98 fn peer_connected(&self, _their_node_id: &PublicKey, _init: &msgs::Init, _inbound: bool) -> Result<(), ()> { Ok(()) }
99 fn peer_disconnected(&self, _their_node_id: &PublicKey) {}
100 fn provided_node_features(&self) -> NodeFeatures { NodeFeatures::empty() }
101 fn provided_init_features(&self, _their_node_id: &PublicKey) -> InitFeatures {
102 InitFeatures::empty()
105 impl CustomOnionMessageHandler for IgnoringMessageHandler {
106 type CustomMessage = Infallible;
107 fn handle_custom_message(&self, _msg: Infallible) {
108 // Since we always return `None` in the read the handle method should never be called.
111 fn read_custom_message<R: io::Read>(&self, _msg_type: u64, _buffer: &mut R) -> Result<Option<Infallible>, msgs::DecodeError> where Self: Sized {
116 impl CustomOnionMessageContents for Infallible {
117 fn tlv_type(&self) -> u64 { unreachable!(); }
120 impl Deref for IgnoringMessageHandler {
121 type Target = IgnoringMessageHandler;
122 fn deref(&self) -> &Self { self }
125 // Implement Type for Infallible, note that it cannot be constructed, and thus you can never call a
126 // method that takes self for it.
127 impl wire::Type for Infallible {
128 fn type_id(&self) -> u16 {
132 impl Writeable for Infallible {
133 fn write<W: Writer>(&self, _: &mut W) -> Result<(), io::Error> {
138 impl wire::CustomMessageReader for IgnoringMessageHandler {
139 type CustomMessage = Infallible;
140 fn read<R: io::Read>(&self, _message_type: u16, _buffer: &mut R) -> Result<Option<Self::CustomMessage>, msgs::DecodeError> {
145 impl CustomMessageHandler for IgnoringMessageHandler {
146 fn handle_custom_message(&self, _msg: Infallible, _sender_node_id: &PublicKey) -> Result<(), LightningError> {
147 // Since we always return `None` in the read the handle method should never be called.
151 fn get_and_clear_pending_msg(&self) -> Vec<(PublicKey, Self::CustomMessage)> { Vec::new() }
154 /// A dummy struct which implements `ChannelMessageHandler` without having any channels.
155 /// You can provide one of these as the route_handler in a MessageHandler.
156 pub struct ErroringMessageHandler {
157 message_queue: Mutex<Vec<MessageSendEvent>>
159 impl ErroringMessageHandler {
160 /// Constructs a new ErroringMessageHandler
161 pub fn new() -> Self {
162 Self { message_queue: Mutex::new(Vec::new()) }
164 fn push_error(&self, node_id: &PublicKey, channel_id: [u8; 32]) {
165 self.message_queue.lock().unwrap().push(MessageSendEvent::HandleError {
166 action: msgs::ErrorAction::SendErrorMessage {
167 msg: msgs::ErrorMessage { channel_id, data: "We do not support channel messages, sorry.".to_owned() },
169 node_id: node_id.clone(),
173 impl MessageSendEventsProvider for ErroringMessageHandler {
174 fn get_and_clear_pending_msg_events(&self) -> Vec<MessageSendEvent> {
175 let mut res = Vec::new();
176 mem::swap(&mut res, &mut self.message_queue.lock().unwrap());
180 impl ChannelMessageHandler for ErroringMessageHandler {
181 // Any messages which are related to a specific channel generate an error message to let the
182 // peer know we don't care about channels.
183 fn handle_open_channel(&self, their_node_id: &PublicKey, msg: &msgs::OpenChannel) {
184 ErroringMessageHandler::push_error(self, their_node_id, msg.temporary_channel_id);
186 fn handle_accept_channel(&self, their_node_id: &PublicKey, msg: &msgs::AcceptChannel) {
187 ErroringMessageHandler::push_error(self, their_node_id, msg.temporary_channel_id);
189 fn handle_funding_created(&self, their_node_id: &PublicKey, msg: &msgs::FundingCreated) {
190 ErroringMessageHandler::push_error(self, their_node_id, msg.temporary_channel_id);
192 fn handle_funding_signed(&self, their_node_id: &PublicKey, msg: &msgs::FundingSigned) {
193 ErroringMessageHandler::push_error(self, their_node_id, msg.channel_id);
195 fn handle_channel_ready(&self, their_node_id: &PublicKey, msg: &msgs::ChannelReady) {
196 ErroringMessageHandler::push_error(self, their_node_id, msg.channel_id);
198 fn handle_shutdown(&self, their_node_id: &PublicKey, msg: &msgs::Shutdown) {
199 ErroringMessageHandler::push_error(self, their_node_id, msg.channel_id);
201 fn handle_closing_signed(&self, their_node_id: &PublicKey, msg: &msgs::ClosingSigned) {
202 ErroringMessageHandler::push_error(self, their_node_id, msg.channel_id);
204 fn handle_update_add_htlc(&self, their_node_id: &PublicKey, msg: &msgs::UpdateAddHTLC) {
205 ErroringMessageHandler::push_error(self, their_node_id, msg.channel_id);
207 fn handle_update_fulfill_htlc(&self, their_node_id: &PublicKey, msg: &msgs::UpdateFulfillHTLC) {
208 ErroringMessageHandler::push_error(self, their_node_id, msg.channel_id);
210 fn handle_update_fail_htlc(&self, their_node_id: &PublicKey, msg: &msgs::UpdateFailHTLC) {
211 ErroringMessageHandler::push_error(self, their_node_id, msg.channel_id);
213 fn handle_update_fail_malformed_htlc(&self, their_node_id: &PublicKey, msg: &msgs::UpdateFailMalformedHTLC) {
214 ErroringMessageHandler::push_error(self, their_node_id, msg.channel_id);
216 fn handle_commitment_signed(&self, their_node_id: &PublicKey, msg: &msgs::CommitmentSigned) {
217 ErroringMessageHandler::push_error(self, their_node_id, msg.channel_id);
219 fn handle_revoke_and_ack(&self, their_node_id: &PublicKey, msg: &msgs::RevokeAndACK) {
220 ErroringMessageHandler::push_error(self, their_node_id, msg.channel_id);
222 fn handle_update_fee(&self, their_node_id: &PublicKey, msg: &msgs::UpdateFee) {
223 ErroringMessageHandler::push_error(self, their_node_id, msg.channel_id);
225 fn handle_announcement_signatures(&self, their_node_id: &PublicKey, msg: &msgs::AnnouncementSignatures) {
226 ErroringMessageHandler::push_error(self, their_node_id, msg.channel_id);
228 fn handle_channel_reestablish(&self, their_node_id: &PublicKey, msg: &msgs::ChannelReestablish) {
229 ErroringMessageHandler::push_error(self, their_node_id, msg.channel_id);
231 // msgs::ChannelUpdate does not contain the channel_id field, so we just drop them.
232 fn handle_channel_update(&self, _their_node_id: &PublicKey, _msg: &msgs::ChannelUpdate) {}
233 fn peer_disconnected(&self, _their_node_id: &PublicKey) {}
234 fn peer_connected(&self, _their_node_id: &PublicKey, _init: &msgs::Init, _inbound: bool) -> Result<(), ()> { Ok(()) }
235 fn handle_error(&self, _their_node_id: &PublicKey, _msg: &msgs::ErrorMessage) {}
236 fn provided_node_features(&self) -> NodeFeatures { NodeFeatures::empty() }
237 fn provided_init_features(&self, _their_node_id: &PublicKey) -> InitFeatures {
238 // Set a number of features which various nodes may require to talk to us. It's totally
239 // reasonable to indicate we "support" all kinds of channel features...we just reject all
241 let mut features = InitFeatures::empty();
242 features.set_data_loss_protect_optional();
243 features.set_upfront_shutdown_script_optional();
244 features.set_variable_length_onion_optional();
245 features.set_static_remote_key_optional();
246 features.set_payment_secret_optional();
247 features.set_basic_mpp_optional();
248 features.set_wumbo_optional();
249 features.set_shutdown_any_segwit_optional();
250 features.set_channel_type_optional();
251 features.set_scid_privacy_optional();
252 features.set_zero_conf_optional();
256 impl Deref for ErroringMessageHandler {
257 type Target = ErroringMessageHandler;
258 fn deref(&self) -> &Self { self }
261 /// Provides references to trait impls which handle different types of messages.
262 pub struct MessageHandler<CM: Deref, RM: Deref, OM: Deref, CustomM: Deref> where
263 CM::Target: ChannelMessageHandler,
264 RM::Target: RoutingMessageHandler,
265 OM::Target: OnionMessageHandler,
266 CustomM::Target: CustomMessageHandler,
268 /// A message handler which handles messages specific to channels. Usually this is just a
269 /// [`ChannelManager`] object or an [`ErroringMessageHandler`].
271 /// [`ChannelManager`]: crate::ln::channelmanager::ChannelManager
272 pub chan_handler: CM,
273 /// A message handler which handles messages updating our knowledge of the network channel
274 /// graph. Usually this is just a [`P2PGossipSync`] object or an [`IgnoringMessageHandler`].
276 /// [`P2PGossipSync`]: crate::routing::gossip::P2PGossipSync
277 pub route_handler: RM,
279 /// A message handler which handles onion messages. This should generally be an
280 /// [`OnionMessenger`], but can also be an [`IgnoringMessageHandler`].
282 /// [`OnionMessenger`]: crate::onion_message::OnionMessenger
283 pub onion_message_handler: OM,
285 /// A message handler which handles custom messages. The only LDK-provided implementation is
286 /// [`IgnoringMessageHandler`].
287 pub custom_message_handler: CustomM,
290 /// Provides an object which can be used to send data to and which uniquely identifies a connection
291 /// to a remote host. You will need to be able to generate multiple of these which meet Eq and
292 /// implement Hash to meet the PeerManager API.
294 /// For efficiency, [`Clone`] should be relatively cheap for this type.
296 /// Two descriptors may compare equal (by [`cmp::Eq`] and [`hash::Hash`]) as long as the original
297 /// has been disconnected, the [`PeerManager`] has been informed of the disconnection (either by it
298 /// having triggered the disconnection or a call to [`PeerManager::socket_disconnected`]), and no
299 /// further calls to the [`PeerManager`] related to the original socket occur. This allows you to
300 /// use a file descriptor for your SocketDescriptor directly, however for simplicity you may wish
301 /// to simply use another value which is guaranteed to be globally unique instead.
302 pub trait SocketDescriptor : cmp::Eq + hash::Hash + Clone {
303 /// Attempts to send some data from the given slice to the peer.
305 /// Returns the amount of data which was sent, possibly 0 if the socket has since disconnected.
306 /// Note that in the disconnected case, [`PeerManager::socket_disconnected`] must still be
307 /// called and further write attempts may occur until that time.
309 /// If the returned size is smaller than `data.len()`, a
310 /// [`PeerManager::write_buffer_space_avail`] call must be made the next time more data can be
311 /// written. Additionally, until a `send_data` event completes fully, no further
312 /// [`PeerManager::read_event`] calls should be made for the same peer! Because this is to
313 /// prevent denial-of-service issues, you should not read or buffer any data from the socket
316 /// If a [`PeerManager::read_event`] call on this descriptor had previously returned true
317 /// (indicating that read events should be paused to prevent DoS in the send buffer),
318 /// `resume_read` may be set indicating that read events on this descriptor should resume. A
319 /// `resume_read` of false carries no meaning, and should not cause any action.
320 fn send_data(&mut self, data: &[u8], resume_read: bool) -> usize;
321 /// Disconnect the socket pointed to by this SocketDescriptor.
323 /// You do *not* need to call [`PeerManager::socket_disconnected`] with this socket after this
324 /// call (doing so is a noop).
325 fn disconnect_socket(&mut self);
328 /// Error for PeerManager errors. If you get one of these, you must disconnect the socket and
329 /// generate no further read_event/write_buffer_space_avail/socket_disconnected calls for the
332 pub struct PeerHandleError { }
333 impl fmt::Debug for PeerHandleError {
334 fn fmt(&self, formatter: &mut fmt::Formatter) -> Result<(), fmt::Error> {
335 formatter.write_str("Peer Sent Invalid Data")
338 impl fmt::Display for PeerHandleError {
339 fn fmt(&self, formatter: &mut fmt::Formatter) -> Result<(), fmt::Error> {
340 formatter.write_str("Peer Sent Invalid Data")
344 #[cfg(feature = "std")]
345 impl error::Error for PeerHandleError {
346 fn description(&self) -> &str {
347 "Peer Sent Invalid Data"
351 enum InitSyncTracker{
353 ChannelsSyncing(u64),
354 NodesSyncing(NodeId),
357 /// The ratio between buffer sizes at which we stop sending initial sync messages vs when we stop
358 /// forwarding gossip messages to peers altogether.
359 const FORWARD_INIT_SYNC_BUFFER_LIMIT_RATIO: usize = 2;
361 /// When the outbound buffer has this many messages, we'll stop reading bytes from the peer until
362 /// we have fewer than this many messages in the outbound buffer again.
363 /// We also use this as the target number of outbound gossip messages to keep in the write buffer,
364 /// refilled as we send bytes.
365 const OUTBOUND_BUFFER_LIMIT_READ_PAUSE: usize = 12;
366 /// When the outbound buffer has this many messages, we'll simply skip relaying gossip messages to
368 const OUTBOUND_BUFFER_LIMIT_DROP_GOSSIP: usize = OUTBOUND_BUFFER_LIMIT_READ_PAUSE * FORWARD_INIT_SYNC_BUFFER_LIMIT_RATIO;
370 /// If we've sent a ping, and are still awaiting a response, we may need to churn our way through
371 /// the socket receive buffer before receiving the ping.
373 /// On a fairly old Arm64 board, with Linux defaults, this can take as long as 20 seconds, not
374 /// including any network delays, outbound traffic, or the same for messages from other peers.
376 /// Thus, to avoid needlessly disconnecting a peer, we allow a peer to take this many timer ticks
377 /// per connected peer to respond to a ping, as long as they send us at least one message during
378 /// each tick, ensuring we aren't actually just disconnected.
379 /// With a timer tick interval of ten seconds, this translates to about 40 seconds per connected
382 /// When we improve parallelism somewhat we should reduce this to e.g. this many timer ticks per
383 /// two connected peers, assuming most LDK-running systems have at least two cores.
384 const MAX_BUFFER_DRAIN_TICK_INTERVALS_PER_PEER: i8 = 4;
386 /// This is the minimum number of messages we expect a peer to be able to handle within one timer
387 /// tick. Once we have sent this many messages since the last ping, we send a ping right away to
388 /// ensures we don't just fill up our send buffer and leave the peer with too many messages to
389 /// process before the next ping.
391 /// Note that we continue responding to other messages even after we've sent this many messages, so
392 /// it's more of a general guideline used for gossip backfill (and gossip forwarding, times
393 /// [`FORWARD_INIT_SYNC_BUFFER_LIMIT_RATIO`]) than a hard limit.
394 const BUFFER_DRAIN_MSGS_PER_TICK: usize = 32;
397 channel_encryptor: PeerChannelEncryptor,
398 /// We cache a `NodeId` here to avoid serializing peers' keys every time we forward gossip
399 /// messages in `PeerManager`. Use `Peer::set_their_node_id` to modify this field.
400 their_node_id: Option<(PublicKey, NodeId)>,
401 /// The features provided in the peer's [`msgs::Init`] message.
403 /// This is set only after we've processed the [`msgs::Init`] message and called relevant
404 /// `peer_connected` handler methods. Thus, this field is set *iff* we've finished our
405 /// handshake and can talk to this peer normally (though use [`Peer::handshake_complete`] to
407 their_features: Option<InitFeatures>,
408 their_net_address: Option<NetAddress>,
410 pending_outbound_buffer: LinkedList<Vec<u8>>,
411 pending_outbound_buffer_first_msg_offset: usize,
412 /// Queue gossip broadcasts separately from `pending_outbound_buffer` so we can easily
413 /// prioritize channel messages over them.
415 /// Note that these messages are *not* encrypted/MAC'd, and are only serialized.
416 gossip_broadcast_buffer: LinkedList<Vec<u8>>,
417 awaiting_write_event: bool,
419 pending_read_buffer: Vec<u8>,
420 pending_read_buffer_pos: usize,
421 pending_read_is_header: bool,
423 sync_status: InitSyncTracker,
425 msgs_sent_since_pong: usize,
426 awaiting_pong_timer_tick_intervals: i64,
427 received_message_since_timer_tick: bool,
428 sent_gossip_timestamp_filter: bool,
430 /// Indicates we've received a `channel_announcement` since the last time we had
431 /// [`PeerManager::gossip_processing_backlogged`] set (or, really, that we've received a
432 /// `channel_announcement` at all - we set this unconditionally but unset it every time we
433 /// check if we're gossip-processing-backlogged).
434 received_channel_announce_since_backlogged: bool,
436 inbound_connection: bool,
440 /// True after we've processed the [`msgs::Init`] message and called relevant `peer_connected`
441 /// handler methods. Thus, this implies we've finished our handshake and can talk to this peer
443 fn handshake_complete(&self) -> bool {
444 self.their_features.is_some()
447 /// Returns true if the channel announcements/updates for the given channel should be
448 /// forwarded to this peer.
449 /// If we are sending our routing table to this peer and we have not yet sent channel
450 /// announcements/updates for the given channel_id then we will send it when we get to that
451 /// point and we shouldn't send it yet to avoid sending duplicate updates. If we've already
452 /// sent the old versions, we should send the update, and so return true here.
453 fn should_forward_channel_announcement(&self, channel_id: u64) -> bool {
454 if !self.handshake_complete() { return false; }
455 if self.their_features.as_ref().unwrap().supports_gossip_queries() &&
456 !self.sent_gossip_timestamp_filter {
459 match self.sync_status {
460 InitSyncTracker::NoSyncRequested => true,
461 InitSyncTracker::ChannelsSyncing(i) => i < channel_id,
462 InitSyncTracker::NodesSyncing(_) => true,
466 /// Similar to the above, but for node announcements indexed by node_id.
467 fn should_forward_node_announcement(&self, node_id: NodeId) -> bool {
468 if !self.handshake_complete() { return false; }
469 if self.their_features.as_ref().unwrap().supports_gossip_queries() &&
470 !self.sent_gossip_timestamp_filter {
473 match self.sync_status {
474 InitSyncTracker::NoSyncRequested => true,
475 InitSyncTracker::ChannelsSyncing(_) => false,
476 InitSyncTracker::NodesSyncing(sync_node_id) => sync_node_id.as_slice() < node_id.as_slice(),
480 /// Returns whether we should be reading bytes from this peer, based on whether its outbound
481 /// buffer still has space and we don't need to pause reads to get some writes out.
482 fn should_read(&mut self, gossip_processing_backlogged: bool) -> bool {
483 if !gossip_processing_backlogged {
484 self.received_channel_announce_since_backlogged = false;
486 self.pending_outbound_buffer.len() < OUTBOUND_BUFFER_LIMIT_READ_PAUSE &&
487 (!gossip_processing_backlogged || !self.received_channel_announce_since_backlogged)
490 /// Determines if we should push additional gossip background sync (aka "backfill") onto a peer's
491 /// outbound buffer. This is checked every time the peer's buffer may have been drained.
492 fn should_buffer_gossip_backfill(&self) -> bool {
493 self.pending_outbound_buffer.is_empty() && self.gossip_broadcast_buffer.is_empty()
494 && self.msgs_sent_since_pong < BUFFER_DRAIN_MSGS_PER_TICK
495 && self.handshake_complete()
498 /// Determines if we should push an onion message onto a peer's outbound buffer. This is checked
499 /// every time the peer's buffer may have been drained.
500 fn should_buffer_onion_message(&self) -> bool {
501 self.pending_outbound_buffer.is_empty() && self.handshake_complete()
502 && self.msgs_sent_since_pong < BUFFER_DRAIN_MSGS_PER_TICK
505 /// Determines if we should push additional gossip broadcast messages onto a peer's outbound
506 /// buffer. This is checked every time the peer's buffer may have been drained.
507 fn should_buffer_gossip_broadcast(&self) -> bool {
508 self.pending_outbound_buffer.is_empty() && self.handshake_complete()
509 && self.msgs_sent_since_pong < BUFFER_DRAIN_MSGS_PER_TICK
512 /// Returns whether this peer's outbound buffers are full and we should drop gossip broadcasts.
513 fn buffer_full_drop_gossip_broadcast(&self) -> bool {
514 let total_outbound_buffered =
515 self.gossip_broadcast_buffer.len() + self.pending_outbound_buffer.len();
517 total_outbound_buffered > OUTBOUND_BUFFER_LIMIT_DROP_GOSSIP ||
518 self.msgs_sent_since_pong > BUFFER_DRAIN_MSGS_PER_TICK * FORWARD_INIT_SYNC_BUFFER_LIMIT_RATIO
521 fn set_their_node_id(&mut self, node_id: PublicKey) {
522 self.their_node_id = Some((node_id, NodeId::from_pubkey(&node_id)));
526 /// SimpleArcPeerManager is useful when you need a PeerManager with a static lifetime, e.g.
527 /// when you're using lightning-net-tokio (since tokio::spawn requires parameters with static
528 /// lifetimes). Other times you can afford a reference, which is more efficient, in which case
529 /// SimpleRefPeerManager is the more appropriate type. Defining these type aliases prevents
530 /// issues such as overly long function definitions.
532 /// This is not exported to bindings users as `Arc`s don't make sense in bindings.
533 pub type SimpleArcPeerManager<SD, M, T, F, C, L> = PeerManager<SD, Arc<SimpleArcChannelManager<M, T, F, L>>, Arc<P2PGossipSync<Arc<NetworkGraph<Arc<L>>>, Arc<C>, Arc<L>>>, Arc<SimpleArcOnionMessenger<L>>, Arc<L>, IgnoringMessageHandler, Arc<KeysManager>>;
535 /// SimpleRefPeerManager is a type alias for a PeerManager reference, and is the reference
536 /// counterpart to the SimpleArcPeerManager type alias. Use this type by default when you don't
537 /// need a PeerManager with a static lifetime. You'll need a static lifetime in cases such as
538 /// usage of lightning-net-tokio (since tokio::spawn requires parameters with static lifetimes).
539 /// But if this is not necessary, using a reference is more efficient. Defining these type aliases
540 /// helps with issues such as long function definitions.
542 /// This is not exported to bindings users as general type aliases don't make sense in bindings.
543 pub type SimpleRefPeerManager<'a, 'b, 'c, 'd, 'e, 'f, 'g, 'h, 'i, 'j, 'k, 'l, 'm, SD, M, T, F, C, L> = PeerManager<SD, SimpleRefChannelManager<'a, 'b, 'c, 'd, 'e, 'f, 'g, 'm, M, T, F, L>, &'f P2PGossipSync<&'g NetworkGraph<&'f L>, &'h C, &'f L>, &'i SimpleRefOnionMessenger<'j, 'k, L>, &'f L, IgnoringMessageHandler, &'c KeysManager>;
546 /// A generic trait which is implemented for all [`PeerManager`]s. This makes bounding functions or
547 /// structs on any [`PeerManager`] much simpler as only this trait is needed as a bound, rather
548 /// than the full set of bounds on [`PeerManager`] itself.
549 #[allow(missing_docs)]
550 pub trait APeerManager {
551 type Descriptor: SocketDescriptor;
552 type CMT: ChannelMessageHandler + ?Sized;
553 type CM: Deref<Target=Self::CMT>;
554 type RMT: RoutingMessageHandler + ?Sized;
555 type RM: Deref<Target=Self::RMT>;
556 type OMT: OnionMessageHandler + ?Sized;
557 type OM: Deref<Target=Self::OMT>;
558 type LT: Logger + ?Sized;
559 type L: Deref<Target=Self::LT>;
560 type CMHT: CustomMessageHandler + ?Sized;
561 type CMH: Deref<Target=Self::CMHT>;
562 type NST: NodeSigner + ?Sized;
563 type NS: Deref<Target=Self::NST>;
564 /// Gets a reference to the underlying [`PeerManager`].
565 fn as_ref(&self) -> &PeerManager<Self::Descriptor, Self::CM, Self::RM, Self::OM, Self::L, Self::CMH, Self::NS>;
568 impl<Descriptor: SocketDescriptor, CM: Deref, RM: Deref, OM: Deref, L: Deref, CMH: Deref, NS: Deref>
569 APeerManager for PeerManager<Descriptor, CM, RM, OM, L, CMH, NS> where
570 CM::Target: ChannelMessageHandler,
571 RM::Target: RoutingMessageHandler,
572 OM::Target: OnionMessageHandler,
574 CMH::Target: CustomMessageHandler,
575 NS::Target: NodeSigner,
577 type Descriptor = Descriptor;
578 type CMT = <CM as Deref>::Target;
580 type RMT = <RM as Deref>::Target;
582 type OMT = <OM as Deref>::Target;
584 type LT = <L as Deref>::Target;
586 type CMHT = <CMH as Deref>::Target;
588 type NST = <NS as Deref>::Target;
590 fn as_ref(&self) -> &PeerManager<Descriptor, CM, RM, OM, L, CMH, NS> { self }
593 /// A PeerManager manages a set of peers, described by their [`SocketDescriptor`] and marshalls
594 /// socket events into messages which it passes on to its [`MessageHandler`].
596 /// Locks are taken internally, so you must never assume that reentrancy from a
597 /// [`SocketDescriptor`] call back into [`PeerManager`] methods will not deadlock.
599 /// Calls to [`read_event`] will decode relevant messages and pass them to the
600 /// [`ChannelMessageHandler`], likely doing message processing in-line. Thus, the primary form of
601 /// parallelism in Rust-Lightning is in calls to [`read_event`]. Note, however, that calls to any
602 /// [`PeerManager`] functions related to the same connection must occur only in serial, making new
603 /// calls only after previous ones have returned.
605 /// Rather than using a plain [`PeerManager`], it is preferable to use either a [`SimpleArcPeerManager`]
606 /// a [`SimpleRefPeerManager`], for conciseness. See their documentation for more details, but
607 /// essentially you should default to using a [`SimpleRefPeerManager`], and use a
608 /// [`SimpleArcPeerManager`] when you require a `PeerManager` with a static lifetime, such as when
609 /// you're using lightning-net-tokio.
611 /// [`read_event`]: PeerManager::read_event
612 pub struct PeerManager<Descriptor: SocketDescriptor, CM: Deref, RM: Deref, OM: Deref, L: Deref, CMH: Deref, NS: Deref> where
613 CM::Target: ChannelMessageHandler,
614 RM::Target: RoutingMessageHandler,
615 OM::Target: OnionMessageHandler,
617 CMH::Target: CustomMessageHandler,
618 NS::Target: NodeSigner {
619 message_handler: MessageHandler<CM, RM, OM, CMH>,
620 /// Connection state for each connected peer - we have an outer read-write lock which is taken
621 /// as read while we're doing processing for a peer and taken write when a peer is being added
624 /// The inner Peer lock is held for sending and receiving bytes, but note that we do *not* hold
625 /// it while we're processing a message. This is fine as [`PeerManager::read_event`] requires
626 /// that there be no parallel calls for a given peer, so mutual exclusion of messages handed to
627 /// the `MessageHandler`s for a given peer is already guaranteed.
628 peers: FairRwLock<HashMap<Descriptor, Mutex<Peer>>>,
629 /// Only add to this set when noise completes.
630 /// Locked *after* peers. When an item is removed, it must be removed with the `peers` write
631 /// lock held. Entries may be added with only the `peers` read lock held (though the
632 /// `Descriptor` value must already exist in `peers`).
633 node_id_to_descriptor: Mutex<HashMap<PublicKey, Descriptor>>,
634 /// We can only have one thread processing events at once, but we don't usually need the full
635 /// `peers` write lock to do so, so instead we block on this empty mutex when entering
636 /// `process_events`.
637 event_processing_lock: Mutex<()>,
638 /// Because event processing is global and always does all available work before returning,
639 /// there is no reason for us to have many event processors waiting on the lock at once.
640 /// Instead, we limit the total blocked event processors to always exactly one by setting this
641 /// when an event process call is waiting.
642 blocked_event_processors: AtomicBool,
644 /// Used to track the last value sent in a node_announcement "timestamp" field. We ensure this
645 /// value increases strictly since we don't assume access to a time source.
646 last_node_announcement_serial: AtomicU32,
648 ephemeral_key_midstate: Sha256Engine,
650 peer_counter: AtomicCounter,
652 gossip_processing_backlogged: AtomicBool,
653 gossip_processing_backlog_lifted: AtomicBool,
658 secp_ctx: Secp256k1<secp256k1::SignOnly>
661 enum MessageHandlingError {
662 PeerHandleError(PeerHandleError),
663 LightningError(LightningError),
666 impl From<PeerHandleError> for MessageHandlingError {
667 fn from(error: PeerHandleError) -> Self {
668 MessageHandlingError::PeerHandleError(error)
672 impl From<LightningError> for MessageHandlingError {
673 fn from(error: LightningError) -> Self {
674 MessageHandlingError::LightningError(error)
678 macro_rules! encode_msg {
680 let mut buffer = VecWriter(Vec::new());
681 wire::write($msg, &mut buffer).unwrap();
686 impl<Descriptor: SocketDescriptor, CM: Deref, OM: Deref, L: Deref, NS: Deref> PeerManager<Descriptor, CM, IgnoringMessageHandler, OM, L, IgnoringMessageHandler, NS> where
687 CM::Target: ChannelMessageHandler,
688 OM::Target: OnionMessageHandler,
690 NS::Target: NodeSigner {
691 /// Constructs a new `PeerManager` with the given `ChannelMessageHandler` and
692 /// `OnionMessageHandler`. No routing message handler is used and network graph messages are
695 /// `ephemeral_random_data` is used to derive per-connection ephemeral keys and must be
696 /// cryptographically secure random bytes.
698 /// `current_time` is used as an always-increasing counter that survives across restarts and is
699 /// incremented irregularly internally. In general it is best to simply use the current UNIX
700 /// timestamp, however if it is not available a persistent counter that increases once per
701 /// minute should suffice.
703 /// This is not exported to bindings users as we can't export a PeerManager with a dummy route handler
704 pub fn new_channel_only(channel_message_handler: CM, onion_message_handler: OM, current_time: u32, ephemeral_random_data: &[u8; 32], logger: L, node_signer: NS) -> Self {
705 Self::new(MessageHandler {
706 chan_handler: channel_message_handler,
707 route_handler: IgnoringMessageHandler{},
708 onion_message_handler,
709 custom_message_handler: IgnoringMessageHandler{},
710 }, current_time, ephemeral_random_data, logger, node_signer)
714 impl<Descriptor: SocketDescriptor, RM: Deref, L: Deref, NS: Deref> PeerManager<Descriptor, ErroringMessageHandler, RM, IgnoringMessageHandler, L, IgnoringMessageHandler, NS> where
715 RM::Target: RoutingMessageHandler,
717 NS::Target: NodeSigner {
718 /// Constructs a new `PeerManager` with the given `RoutingMessageHandler`. No channel message
719 /// handler or onion message handler is used and onion and channel messages will be ignored (or
720 /// generate error messages). Note that some other lightning implementations time-out connections
721 /// after some time if no channel is built with the peer.
723 /// `current_time` is used as an always-increasing counter that survives across restarts and is
724 /// incremented irregularly internally. In general it is best to simply use the current UNIX
725 /// timestamp, however if it is not available a persistent counter that increases once per
726 /// minute should suffice.
728 /// `ephemeral_random_data` is used to derive per-connection ephemeral keys and must be
729 /// cryptographically secure random bytes.
731 /// This is not exported to bindings users as we can't export a PeerManager with a dummy channel handler
732 pub fn new_routing_only(routing_message_handler: RM, current_time: u32, ephemeral_random_data: &[u8; 32], logger: L, node_signer: NS) -> Self {
733 Self::new(MessageHandler {
734 chan_handler: ErroringMessageHandler::new(),
735 route_handler: routing_message_handler,
736 onion_message_handler: IgnoringMessageHandler{},
737 custom_message_handler: IgnoringMessageHandler{},
738 }, current_time, ephemeral_random_data, logger, node_signer)
742 /// A simple wrapper that optionally prints ` from <pubkey>` for an optional pubkey.
743 /// This works around `format!()` taking a reference to each argument, preventing
744 /// `if let Some(node_id) = peer.their_node_id { format!(.., node_id) } else { .. }` from compiling
745 /// due to lifetime errors.
746 struct OptionalFromDebugger<'a>(&'a Option<(PublicKey, NodeId)>);
747 impl core::fmt::Display for OptionalFromDebugger<'_> {
748 fn fmt(&self, f: &mut core::fmt::Formatter<'_>) -> Result<(), core::fmt::Error> {
749 if let Some((node_id, _)) = self.0 { write!(f, " from {}", log_pubkey!(node_id)) } else { Ok(()) }
753 /// A function used to filter out local or private addresses
754 /// <https://www.iana.org./assignments/ipv4-address-space/ipv4-address-space.xhtml>
755 /// <https://www.iana.org/assignments/ipv6-address-space/ipv6-address-space.xhtml>
756 fn filter_addresses(ip_address: Option<NetAddress>) -> Option<NetAddress> {
758 // For IPv4 range 10.0.0.0 - 10.255.255.255 (10/8)
759 Some(NetAddress::IPv4{addr: [10, _, _, _], port: _}) => None,
760 // For IPv4 range 0.0.0.0 - 0.255.255.255 (0/8)
761 Some(NetAddress::IPv4{addr: [0, _, _, _], port: _}) => None,
762 // For IPv4 range 100.64.0.0 - 100.127.255.255 (100.64/10)
763 Some(NetAddress::IPv4{addr: [100, 64..=127, _, _], port: _}) => None,
764 // For IPv4 range 127.0.0.0 - 127.255.255.255 (127/8)
765 Some(NetAddress::IPv4{addr: [127, _, _, _], port: _}) => None,
766 // For IPv4 range 169.254.0.0 - 169.254.255.255 (169.254/16)
767 Some(NetAddress::IPv4{addr: [169, 254, _, _], port: _}) => None,
768 // For IPv4 range 172.16.0.0 - 172.31.255.255 (172.16/12)
769 Some(NetAddress::IPv4{addr: [172, 16..=31, _, _], port: _}) => None,
770 // For IPv4 range 192.168.0.0 - 192.168.255.255 (192.168/16)
771 Some(NetAddress::IPv4{addr: [192, 168, _, _], port: _}) => None,
772 // For IPv4 range 192.88.99.0 - 192.88.99.255 (192.88.99/24)
773 Some(NetAddress::IPv4{addr: [192, 88, 99, _], port: _}) => None,
774 // For IPv6 range 2000:0000:0000:0000:0000:0000:0000:0000 - 3fff:ffff:ffff:ffff:ffff:ffff:ffff:ffff (2000::/3)
775 Some(NetAddress::IPv6{addr: [0x20..=0x3F, _, _, _, _, _, _, _, _, _, _, _, _, _, _, _], port: _}) => ip_address,
776 // For remaining addresses
777 Some(NetAddress::IPv6{addr: _, port: _}) => None,
778 Some(..) => ip_address,
783 impl<Descriptor: SocketDescriptor, CM: Deref, RM: Deref, OM: Deref, L: Deref, CMH: Deref, NS: Deref> PeerManager<Descriptor, CM, RM, OM, L, CMH, NS> where
784 CM::Target: ChannelMessageHandler,
785 RM::Target: RoutingMessageHandler,
786 OM::Target: OnionMessageHandler,
788 CMH::Target: CustomMessageHandler,
789 NS::Target: NodeSigner
791 /// Constructs a new `PeerManager` with the given message handlers.
793 /// `ephemeral_random_data` is used to derive per-connection ephemeral keys and must be
794 /// cryptographically secure random bytes.
796 /// `current_time` is used as an always-increasing counter that survives across restarts and is
797 /// incremented irregularly internally. In general it is best to simply use the current UNIX
798 /// timestamp, however if it is not available a persistent counter that increases once per
799 /// minute should suffice.
800 pub fn new(message_handler: MessageHandler<CM, RM, OM, CMH>, current_time: u32, ephemeral_random_data: &[u8; 32], logger: L, node_signer: NS) -> Self {
801 let mut ephemeral_key_midstate = Sha256::engine();
802 ephemeral_key_midstate.input(ephemeral_random_data);
804 let mut secp_ctx = Secp256k1::signing_only();
805 let ephemeral_hash = Sha256::from_engine(ephemeral_key_midstate.clone()).into_inner();
806 secp_ctx.seeded_randomize(&ephemeral_hash);
810 peers: FairRwLock::new(HashMap::new()),
811 node_id_to_descriptor: Mutex::new(HashMap::new()),
812 event_processing_lock: Mutex::new(()),
813 blocked_event_processors: AtomicBool::new(false),
814 ephemeral_key_midstate,
815 peer_counter: AtomicCounter::new(),
816 gossip_processing_backlogged: AtomicBool::new(false),
817 gossip_processing_backlog_lifted: AtomicBool::new(false),
818 last_node_announcement_serial: AtomicU32::new(current_time),
825 /// Get a list of tuples mapping from node id to network addresses for peers which have
826 /// completed the initial handshake.
828 /// For outbound connections, the [`PublicKey`] will be the same as the `their_node_id` parameter
829 /// passed in to [`Self::new_outbound_connection`], however entries will only appear once the initial
830 /// handshake has completed and we are sure the remote peer has the private key for the given
833 /// The returned `Option`s will only be `Some` if an address had been previously given via
834 /// [`Self::new_outbound_connection`] or [`Self::new_inbound_connection`].
835 pub fn get_peer_node_ids(&self) -> Vec<(PublicKey, Option<NetAddress>)> {
836 let peers = self.peers.read().unwrap();
837 peers.values().filter_map(|peer_mutex| {
838 let p = peer_mutex.lock().unwrap();
839 if !p.handshake_complete() {
842 Some((p.their_node_id.unwrap().0, p.their_net_address.clone()))
846 fn get_ephemeral_key(&self) -> SecretKey {
847 let mut ephemeral_hash = self.ephemeral_key_midstate.clone();
848 let counter = self.peer_counter.get_increment();
849 ephemeral_hash.input(&counter.to_le_bytes());
850 SecretKey::from_slice(&Sha256::from_engine(ephemeral_hash).into_inner()).expect("You broke SHA-256!")
853 /// Indicates a new outbound connection has been established to a node with the given `node_id`
854 /// and an optional remote network address.
856 /// The remote network address adds the option to report a remote IP address back to a connecting
857 /// peer using the init message.
858 /// The user should pass the remote network address of the host they are connected to.
860 /// If an `Err` is returned here you must disconnect the connection immediately.
862 /// Returns a small number of bytes to send to the remote node (currently always 50).
864 /// Panics if descriptor is duplicative with some other descriptor which has not yet been
865 /// [`socket_disconnected`].
867 /// [`socket_disconnected`]: PeerManager::socket_disconnected
868 pub fn new_outbound_connection(&self, their_node_id: PublicKey, descriptor: Descriptor, remote_network_address: Option<NetAddress>) -> Result<Vec<u8>, PeerHandleError> {
869 let mut peer_encryptor = PeerChannelEncryptor::new_outbound(their_node_id.clone(), self.get_ephemeral_key());
870 let res = peer_encryptor.get_act_one(&self.secp_ctx).to_vec();
871 let pending_read_buffer = [0; 50].to_vec(); // Noise act two is 50 bytes
873 let mut peers = self.peers.write().unwrap();
874 match peers.entry(descriptor) {
875 hash_map::Entry::Occupied(_) => {
876 debug_assert!(false, "PeerManager driver duplicated descriptors!");
877 Err(PeerHandleError {})
879 hash_map::Entry::Vacant(e) => {
880 e.insert(Mutex::new(Peer {
881 channel_encryptor: peer_encryptor,
883 their_features: None,
884 their_net_address: remote_network_address,
886 pending_outbound_buffer: LinkedList::new(),
887 pending_outbound_buffer_first_msg_offset: 0,
888 gossip_broadcast_buffer: LinkedList::new(),
889 awaiting_write_event: false,
892 pending_read_buffer_pos: 0,
893 pending_read_is_header: false,
895 sync_status: InitSyncTracker::NoSyncRequested,
897 msgs_sent_since_pong: 0,
898 awaiting_pong_timer_tick_intervals: 0,
899 received_message_since_timer_tick: false,
900 sent_gossip_timestamp_filter: false,
902 received_channel_announce_since_backlogged: false,
903 inbound_connection: false,
910 /// Indicates a new inbound connection has been established to a node with an optional remote
913 /// The remote network address adds the option to report a remote IP address back to a connecting
914 /// peer using the init message.
915 /// The user should pass the remote network address of the host they are connected to.
917 /// May refuse the connection by returning an Err, but will never write bytes to the remote end
918 /// (outbound connector always speaks first). If an `Err` is returned here you must disconnect
919 /// the connection immediately.
921 /// Panics if descriptor is duplicative with some other descriptor which has not yet been
922 /// [`socket_disconnected`].
924 /// [`socket_disconnected`]: PeerManager::socket_disconnected
925 pub fn new_inbound_connection(&self, descriptor: Descriptor, remote_network_address: Option<NetAddress>) -> Result<(), PeerHandleError> {
926 let peer_encryptor = PeerChannelEncryptor::new_inbound(&self.node_signer);
927 let pending_read_buffer = [0; 50].to_vec(); // Noise act one is 50 bytes
929 let mut peers = self.peers.write().unwrap();
930 match peers.entry(descriptor) {
931 hash_map::Entry::Occupied(_) => {
932 debug_assert!(false, "PeerManager driver duplicated descriptors!");
933 Err(PeerHandleError {})
935 hash_map::Entry::Vacant(e) => {
936 e.insert(Mutex::new(Peer {
937 channel_encryptor: peer_encryptor,
939 their_features: None,
940 their_net_address: remote_network_address,
942 pending_outbound_buffer: LinkedList::new(),
943 pending_outbound_buffer_first_msg_offset: 0,
944 gossip_broadcast_buffer: LinkedList::new(),
945 awaiting_write_event: false,
948 pending_read_buffer_pos: 0,
949 pending_read_is_header: false,
951 sync_status: InitSyncTracker::NoSyncRequested,
953 msgs_sent_since_pong: 0,
954 awaiting_pong_timer_tick_intervals: 0,
955 received_message_since_timer_tick: false,
956 sent_gossip_timestamp_filter: false,
958 received_channel_announce_since_backlogged: false,
959 inbound_connection: true,
966 fn peer_should_read(&self, peer: &mut Peer) -> bool {
967 peer.should_read(self.gossip_processing_backlogged.load(Ordering::Relaxed))
970 fn update_gossip_backlogged(&self) {
971 let new_state = self.message_handler.route_handler.processing_queue_high();
972 let prev_state = self.gossip_processing_backlogged.swap(new_state, Ordering::Relaxed);
973 if prev_state && !new_state {
974 self.gossip_processing_backlog_lifted.store(true, Ordering::Relaxed);
978 fn do_attempt_write_data(&self, descriptor: &mut Descriptor, peer: &mut Peer, force_one_write: bool) {
979 let mut have_written = false;
980 while !peer.awaiting_write_event {
981 if peer.should_buffer_onion_message() {
982 if let Some((peer_node_id, _)) = peer.their_node_id {
983 if let Some(next_onion_message) =
984 self.message_handler.onion_message_handler.next_onion_message_for_peer(peer_node_id) {
985 self.enqueue_message(peer, &next_onion_message);
989 if peer.should_buffer_gossip_broadcast() {
990 if let Some(msg) = peer.gossip_broadcast_buffer.pop_front() {
991 peer.pending_outbound_buffer.push_back(peer.channel_encryptor.encrypt_buffer(&msg[..]));
994 if peer.should_buffer_gossip_backfill() {
995 match peer.sync_status {
996 InitSyncTracker::NoSyncRequested => {},
997 InitSyncTracker::ChannelsSyncing(c) if c < 0xffff_ffff_ffff_ffff => {
998 if let Some((announce, update_a_option, update_b_option)) =
999 self.message_handler.route_handler.get_next_channel_announcement(c)
1001 self.enqueue_message(peer, &announce);
1002 if let Some(update_a) = update_a_option {
1003 self.enqueue_message(peer, &update_a);
1005 if let Some(update_b) = update_b_option {
1006 self.enqueue_message(peer, &update_b);
1008 peer.sync_status = InitSyncTracker::ChannelsSyncing(announce.contents.short_channel_id + 1);
1010 peer.sync_status = InitSyncTracker::ChannelsSyncing(0xffff_ffff_ffff_ffff);
1013 InitSyncTracker::ChannelsSyncing(c) if c == 0xffff_ffff_ffff_ffff => {
1014 if let Some(msg) = self.message_handler.route_handler.get_next_node_announcement(None) {
1015 self.enqueue_message(peer, &msg);
1016 peer.sync_status = InitSyncTracker::NodesSyncing(msg.contents.node_id);
1018 peer.sync_status = InitSyncTracker::NoSyncRequested;
1021 InitSyncTracker::ChannelsSyncing(_) => unreachable!(),
1022 InitSyncTracker::NodesSyncing(sync_node_id) => {
1023 if let Some(msg) = self.message_handler.route_handler.get_next_node_announcement(Some(&sync_node_id)) {
1024 self.enqueue_message(peer, &msg);
1025 peer.sync_status = InitSyncTracker::NodesSyncing(msg.contents.node_id);
1027 peer.sync_status = InitSyncTracker::NoSyncRequested;
1032 if peer.msgs_sent_since_pong >= BUFFER_DRAIN_MSGS_PER_TICK {
1033 self.maybe_send_extra_ping(peer);
1036 let should_read = self.peer_should_read(peer);
1037 let next_buff = match peer.pending_outbound_buffer.front() {
1039 if force_one_write && !have_written {
1041 let data_sent = descriptor.send_data(&[], should_read);
1042 debug_assert_eq!(data_sent, 0, "Can't write more than no data");
1050 let pending = &next_buff[peer.pending_outbound_buffer_first_msg_offset..];
1051 let data_sent = descriptor.send_data(pending, should_read);
1052 have_written = true;
1053 peer.pending_outbound_buffer_first_msg_offset += data_sent;
1054 if peer.pending_outbound_buffer_first_msg_offset == next_buff.len() {
1055 peer.pending_outbound_buffer_first_msg_offset = 0;
1056 peer.pending_outbound_buffer.pop_front();
1058 peer.awaiting_write_event = true;
1063 /// Indicates that there is room to write data to the given socket descriptor.
1065 /// May return an Err to indicate that the connection should be closed.
1067 /// May call [`send_data`] on the descriptor passed in (or an equal descriptor) before
1068 /// returning. Thus, be very careful with reentrancy issues! The invariants around calling
1069 /// [`write_buffer_space_avail`] in case a write did not fully complete must still hold - be
1070 /// ready to call [`write_buffer_space_avail`] again if a write call generated here isn't
1073 /// [`send_data`]: SocketDescriptor::send_data
1074 /// [`write_buffer_space_avail`]: PeerManager::write_buffer_space_avail
1075 pub fn write_buffer_space_avail(&self, descriptor: &mut Descriptor) -> Result<(), PeerHandleError> {
1076 let peers = self.peers.read().unwrap();
1077 match peers.get(descriptor) {
1079 // This is most likely a simple race condition where the user found that the socket
1080 // was writeable, then we told the user to `disconnect_socket()`, then they called
1081 // this method. Return an error to make sure we get disconnected.
1082 return Err(PeerHandleError { });
1084 Some(peer_mutex) => {
1085 let mut peer = peer_mutex.lock().unwrap();
1086 peer.awaiting_write_event = false;
1087 self.do_attempt_write_data(descriptor, &mut peer, false);
1093 /// Indicates that data was read from the given socket descriptor.
1095 /// May return an Err to indicate that the connection should be closed.
1097 /// Will *not* call back into [`send_data`] on any descriptors to avoid reentrancy complexity.
1098 /// Thus, however, you should call [`process_events`] after any `read_event` to generate
1099 /// [`send_data`] calls to handle responses.
1101 /// If `Ok(true)` is returned, further read_events should not be triggered until a
1102 /// [`send_data`] call on this descriptor has `resume_read` set (preventing DoS issues in the
1105 /// In order to avoid processing too many messages at once per peer, `data` should be on the
1108 /// [`send_data`]: SocketDescriptor::send_data
1109 /// [`process_events`]: PeerManager::process_events
1110 pub fn read_event(&self, peer_descriptor: &mut Descriptor, data: &[u8]) -> Result<bool, PeerHandleError> {
1111 match self.do_read_event(peer_descriptor, data) {
1114 log_trace!(self.logger, "Disconnecting peer due to a protocol error (usually a duplicate connection).");
1115 self.disconnect_event_internal(peer_descriptor);
1121 /// Append a message to a peer's pending outbound/write buffer
1122 fn enqueue_message<M: wire::Type>(&self, peer: &mut Peer, message: &M) {
1123 if is_gossip_msg(message.type_id()) {
1124 log_gossip!(self.logger, "Enqueueing message {:?} to {}", message, log_pubkey!(peer.their_node_id.unwrap().0));
1126 log_trace!(self.logger, "Enqueueing message {:?} to {}", message, log_pubkey!(peer.their_node_id.unwrap().0))
1128 peer.msgs_sent_since_pong += 1;
1129 peer.pending_outbound_buffer.push_back(peer.channel_encryptor.encrypt_message(message));
1132 /// Append a message to a peer's pending outbound/write gossip broadcast buffer
1133 fn enqueue_encoded_gossip_broadcast(&self, peer: &mut Peer, encoded_message: Vec<u8>) {
1134 peer.msgs_sent_since_pong += 1;
1135 peer.gossip_broadcast_buffer.push_back(encoded_message);
1138 fn do_read_event(&self, peer_descriptor: &mut Descriptor, data: &[u8]) -> Result<bool, PeerHandleError> {
1139 let mut pause_read = false;
1140 let peers = self.peers.read().unwrap();
1141 let mut msgs_to_forward = Vec::new();
1142 let mut peer_node_id = None;
1143 match peers.get(peer_descriptor) {
1145 // This is most likely a simple race condition where the user read some bytes
1146 // from the socket, then we told the user to `disconnect_socket()`, then they
1147 // called this method. Return an error to make sure we get disconnected.
1148 return Err(PeerHandleError { });
1150 Some(peer_mutex) => {
1151 let mut read_pos = 0;
1152 while read_pos < data.len() {
1153 macro_rules! try_potential_handleerror {
1154 ($peer: expr, $thing: expr) => {
1159 msgs::ErrorAction::DisconnectPeer { msg: _ } => {
1160 //TODO: Try to push msg
1161 log_debug!(self.logger, "Error handling message{}; disconnecting peer with: {}", OptionalFromDebugger(&peer_node_id), e.err);
1162 return Err(PeerHandleError { });
1164 msgs::ErrorAction::IgnoreAndLog(level) => {
1165 log_given_level!(self.logger, level, "Error handling message{}; ignoring: {}", OptionalFromDebugger(&peer_node_id), e.err);
1168 msgs::ErrorAction::IgnoreDuplicateGossip => continue, // Don't even bother logging these
1169 msgs::ErrorAction::IgnoreError => {
1170 log_debug!(self.logger, "Error handling message{}; ignoring: {}", OptionalFromDebugger(&peer_node_id), e.err);
1173 msgs::ErrorAction::SendErrorMessage { msg } => {
1174 log_debug!(self.logger, "Error handling message{}; sending error message with: {}", OptionalFromDebugger(&peer_node_id), e.err);
1175 self.enqueue_message($peer, &msg);
1178 msgs::ErrorAction::SendWarningMessage { msg, log_level } => {
1179 log_given_level!(self.logger, log_level, "Error handling message{}; sending warning message with: {}", OptionalFromDebugger(&peer_node_id), e.err);
1180 self.enqueue_message($peer, &msg);
1189 let mut peer_lock = peer_mutex.lock().unwrap();
1190 let peer = &mut *peer_lock;
1191 let mut msg_to_handle = None;
1192 if peer_node_id.is_none() {
1193 peer_node_id = peer.their_node_id.clone();
1196 assert!(peer.pending_read_buffer.len() > 0);
1197 assert!(peer.pending_read_buffer.len() > peer.pending_read_buffer_pos);
1200 let data_to_copy = cmp::min(peer.pending_read_buffer.len() - peer.pending_read_buffer_pos, data.len() - read_pos);
1201 peer.pending_read_buffer[peer.pending_read_buffer_pos..peer.pending_read_buffer_pos + data_to_copy].copy_from_slice(&data[read_pos..read_pos + data_to_copy]);
1202 read_pos += data_to_copy;
1203 peer.pending_read_buffer_pos += data_to_copy;
1206 if peer.pending_read_buffer_pos == peer.pending_read_buffer.len() {
1207 peer.pending_read_buffer_pos = 0;
1209 macro_rules! insert_node_id {
1211 match self.node_id_to_descriptor.lock().unwrap().entry(peer.their_node_id.unwrap().0) {
1212 hash_map::Entry::Occupied(e) => {
1213 log_trace!(self.logger, "Got second connection with {}, closing", log_pubkey!(peer.their_node_id.unwrap().0));
1214 peer.their_node_id = None; // Unset so that we don't generate a peer_disconnected event
1215 // Check that the peers map is consistent with the
1216 // node_id_to_descriptor map, as this has been broken
1218 debug_assert!(peers.get(e.get()).is_some());
1219 return Err(PeerHandleError { })
1221 hash_map::Entry::Vacant(entry) => {
1222 log_debug!(self.logger, "Finished noise handshake for connection with {}", log_pubkey!(peer.their_node_id.unwrap().0));
1223 entry.insert(peer_descriptor.clone())
1229 let next_step = peer.channel_encryptor.get_noise_step();
1231 NextNoiseStep::ActOne => {
1232 let act_two = try_potential_handleerror!(peer, peer.channel_encryptor
1233 .process_act_one_with_keys(&peer.pending_read_buffer[..],
1234 &self.node_signer, self.get_ephemeral_key(), &self.secp_ctx)).to_vec();
1235 peer.pending_outbound_buffer.push_back(act_two);
1236 peer.pending_read_buffer = [0; 66].to_vec(); // act three is 66 bytes long
1238 NextNoiseStep::ActTwo => {
1239 let (act_three, their_node_id) = try_potential_handleerror!(peer,
1240 peer.channel_encryptor.process_act_two(&peer.pending_read_buffer[..],
1241 &self.node_signer));
1242 peer.pending_outbound_buffer.push_back(act_three.to_vec());
1243 peer.pending_read_buffer = [0; 18].to_vec(); // Message length header is 18 bytes
1244 peer.pending_read_is_header = true;
1246 peer.set_their_node_id(their_node_id);
1248 let features = self.message_handler.chan_handler.provided_init_features(&their_node_id)
1249 .or(self.message_handler.route_handler.provided_init_features(&their_node_id))
1250 .or(self.message_handler.onion_message_handler.provided_init_features(&their_node_id));
1251 let resp = msgs::Init { features, remote_network_address: filter_addresses(peer.their_net_address.clone()) };
1252 self.enqueue_message(peer, &resp);
1253 peer.awaiting_pong_timer_tick_intervals = 0;
1255 NextNoiseStep::ActThree => {
1256 let their_node_id = try_potential_handleerror!(peer,
1257 peer.channel_encryptor.process_act_three(&peer.pending_read_buffer[..]));
1258 peer.pending_read_buffer = [0; 18].to_vec(); // Message length header is 18 bytes
1259 peer.pending_read_is_header = true;
1260 peer.set_their_node_id(their_node_id);
1262 let features = self.message_handler.chan_handler.provided_init_features(&their_node_id)
1263 .or(self.message_handler.route_handler.provided_init_features(&their_node_id))
1264 .or(self.message_handler.onion_message_handler.provided_init_features(&their_node_id));
1265 let resp = msgs::Init { features, remote_network_address: filter_addresses(peer.their_net_address.clone()) };
1266 self.enqueue_message(peer, &resp);
1267 peer.awaiting_pong_timer_tick_intervals = 0;
1269 NextNoiseStep::NoiseComplete => {
1270 if peer.pending_read_is_header {
1271 let msg_len = try_potential_handleerror!(peer,
1272 peer.channel_encryptor.decrypt_length_header(&peer.pending_read_buffer[..]));
1273 if peer.pending_read_buffer.capacity() > 8192 { peer.pending_read_buffer = Vec::new(); }
1274 peer.pending_read_buffer.resize(msg_len as usize + 16, 0);
1275 if msg_len < 2 { // Need at least the message type tag
1276 return Err(PeerHandleError { });
1278 peer.pending_read_is_header = false;
1280 let msg_data = try_potential_handleerror!(peer,
1281 peer.channel_encryptor.decrypt_message(&peer.pending_read_buffer[..]));
1282 assert!(msg_data.len() >= 2);
1284 // Reset read buffer
1285 if peer.pending_read_buffer.capacity() > 8192 { peer.pending_read_buffer = Vec::new(); }
1286 peer.pending_read_buffer.resize(18, 0);
1287 peer.pending_read_is_header = true;
1289 let mut reader = io::Cursor::new(&msg_data[..]);
1290 let message_result = wire::read(&mut reader, &*self.message_handler.custom_message_handler);
1291 let message = match message_result {
1295 // Note that to avoid recursion we never call
1296 // `do_attempt_write_data` from here, causing
1297 // the messages enqueued here to not actually
1298 // be sent before the peer is disconnected.
1299 (msgs::DecodeError::UnknownRequiredFeature, Some(ty)) if is_gossip_msg(ty) => {
1300 log_gossip!(self.logger, "Got a channel/node announcement with an unknown required feature flag, you may want to update!");
1303 (msgs::DecodeError::UnsupportedCompression, _) => {
1304 log_gossip!(self.logger, "We don't support zlib-compressed message fields, sending a warning and ignoring message");
1305 self.enqueue_message(peer, &msgs::WarningMessage { channel_id: [0; 32], data: "Unsupported message compression: zlib".to_owned() });
1308 (_, Some(ty)) if is_gossip_msg(ty) => {
1309 log_gossip!(self.logger, "Got an invalid value while deserializing a gossip message");
1310 self.enqueue_message(peer, &msgs::WarningMessage {
1311 channel_id: [0; 32],
1312 data: format!("Unreadable/bogus gossip message of type {}", ty),
1316 (msgs::DecodeError::UnknownRequiredFeature, ty) => {
1317 log_gossip!(self.logger, "Received a message with an unknown required feature flag or TLV, you may want to update!");
1318 self.enqueue_message(peer, &msgs::WarningMessage { channel_id: [0; 32], data: format!("Received an unknown required feature/TLV in message type {:?}", ty) });
1319 return Err(PeerHandleError { });
1321 (msgs::DecodeError::UnknownVersion, _) => return Err(PeerHandleError { }),
1322 (msgs::DecodeError::InvalidValue, _) => {
1323 log_debug!(self.logger, "Got an invalid value while deserializing message");
1324 return Err(PeerHandleError { });
1326 (msgs::DecodeError::ShortRead, _) => {
1327 log_debug!(self.logger, "Deserialization failed due to shortness of message");
1328 return Err(PeerHandleError { });
1330 (msgs::DecodeError::BadLengthDescriptor, _) => return Err(PeerHandleError { }),
1331 (msgs::DecodeError::Io(_), _) => return Err(PeerHandleError { }),
1336 msg_to_handle = Some(message);
1341 pause_read = !self.peer_should_read(peer);
1343 if let Some(message) = msg_to_handle {
1344 match self.handle_message(&peer_mutex, peer_lock, message) {
1345 Err(handling_error) => match handling_error {
1346 MessageHandlingError::PeerHandleError(e) => { return Err(e) },
1347 MessageHandlingError::LightningError(e) => {
1348 try_potential_handleerror!(&mut peer_mutex.lock().unwrap(), Err(e));
1352 msgs_to_forward.push(msg);
1361 for msg in msgs_to_forward.drain(..) {
1362 self.forward_broadcast_msg(&*peers, &msg, peer_node_id.as_ref().map(|(pk, _)| pk));
1368 /// Process an incoming message and return a decision (ok, lightning error, peer handling error) regarding the next action with the peer
1369 /// Returns the message back if it needs to be broadcasted to all other peers.
1372 peer_mutex: &Mutex<Peer>,
1373 mut peer_lock: MutexGuard<Peer>,
1374 message: wire::Message<<<CMH as core::ops::Deref>::Target as wire::CustomMessageReader>::CustomMessage>
1375 ) -> Result<Option<wire::Message<<<CMH as core::ops::Deref>::Target as wire::CustomMessageReader>::CustomMessage>>, MessageHandlingError> {
1376 let their_node_id = peer_lock.their_node_id.clone().expect("We know the peer's public key by the time we receive messages").0;
1377 peer_lock.received_message_since_timer_tick = true;
1379 // Need an Init as first message
1380 if let wire::Message::Init(msg) = message {
1381 if msg.features.requires_unknown_bits() {
1382 log_debug!(self.logger, "Peer features required unknown version bits");
1383 return Err(PeerHandleError { }.into());
1385 if peer_lock.their_features.is_some() {
1386 return Err(PeerHandleError { }.into());
1389 log_info!(self.logger, "Received peer Init message from {}: {}", log_pubkey!(their_node_id), msg.features);
1391 // For peers not supporting gossip queries start sync now, otherwise wait until we receive a filter.
1392 if msg.features.initial_routing_sync() && !msg.features.supports_gossip_queries() {
1393 peer_lock.sync_status = InitSyncTracker::ChannelsSyncing(0);
1396 if let Err(()) = self.message_handler.route_handler.peer_connected(&their_node_id, &msg, peer_lock.inbound_connection) {
1397 log_debug!(self.logger, "Route Handler decided we couldn't communicate with peer {}", log_pubkey!(their_node_id));
1398 return Err(PeerHandleError { }.into());
1400 if let Err(()) = self.message_handler.chan_handler.peer_connected(&their_node_id, &msg, peer_lock.inbound_connection) {
1401 log_debug!(self.logger, "Channel Handler decided we couldn't communicate with peer {}", log_pubkey!(their_node_id));
1402 return Err(PeerHandleError { }.into());
1404 if let Err(()) = self.message_handler.onion_message_handler.peer_connected(&their_node_id, &msg, peer_lock.inbound_connection) {
1405 log_debug!(self.logger, "Onion Message Handler decided we couldn't communicate with peer {}", log_pubkey!(their_node_id));
1406 return Err(PeerHandleError { }.into());
1409 peer_lock.their_features = Some(msg.features);
1411 } else if peer_lock.their_features.is_none() {
1412 log_debug!(self.logger, "Peer {} sent non-Init first message", log_pubkey!(their_node_id));
1413 return Err(PeerHandleError { }.into());
1416 if let wire::Message::GossipTimestampFilter(_msg) = message {
1417 // When supporting gossip messages, start inital gossip sync only after we receive
1418 // a GossipTimestampFilter
1419 if peer_lock.their_features.as_ref().unwrap().supports_gossip_queries() &&
1420 !peer_lock.sent_gossip_timestamp_filter {
1421 peer_lock.sent_gossip_timestamp_filter = true;
1422 peer_lock.sync_status = InitSyncTracker::ChannelsSyncing(0);
1427 if let wire::Message::ChannelAnnouncement(ref _msg) = message {
1428 peer_lock.received_channel_announce_since_backlogged = true;
1431 mem::drop(peer_lock);
1433 if is_gossip_msg(message.type_id()) {
1434 log_gossip!(self.logger, "Received message {:?} from {}", message, log_pubkey!(their_node_id));
1436 log_trace!(self.logger, "Received message {:?} from {}", message, log_pubkey!(their_node_id));
1439 let mut should_forward = None;
1442 // Setup and Control messages:
1443 wire::Message::Init(_) => {
1446 wire::Message::GossipTimestampFilter(_) => {
1449 wire::Message::Error(msg) => {
1450 let mut data_is_printable = true;
1451 for b in msg.data.bytes() {
1452 if b < 32 || b > 126 {
1453 data_is_printable = false;
1458 if data_is_printable {
1459 log_debug!(self.logger, "Got Err message from {}: {}", log_pubkey!(their_node_id), msg.data);
1461 log_debug!(self.logger, "Got Err message from {} with non-ASCII error message", log_pubkey!(their_node_id));
1463 self.message_handler.chan_handler.handle_error(&their_node_id, &msg);
1464 if msg.channel_id == [0; 32] {
1465 return Err(PeerHandleError { }.into());
1468 wire::Message::Warning(msg) => {
1469 let mut data_is_printable = true;
1470 for b in msg.data.bytes() {
1471 if b < 32 || b > 126 {
1472 data_is_printable = false;
1477 if data_is_printable {
1478 log_debug!(self.logger, "Got warning message from {}: {}", log_pubkey!(their_node_id), msg.data);
1480 log_debug!(self.logger, "Got warning message from {} with non-ASCII error message", log_pubkey!(their_node_id));
1484 wire::Message::Ping(msg) => {
1485 if msg.ponglen < 65532 {
1486 let resp = msgs::Pong { byteslen: msg.ponglen };
1487 self.enqueue_message(&mut *peer_mutex.lock().unwrap(), &resp);
1490 wire::Message::Pong(_msg) => {
1491 let mut peer_lock = peer_mutex.lock().unwrap();
1492 peer_lock.awaiting_pong_timer_tick_intervals = 0;
1493 peer_lock.msgs_sent_since_pong = 0;
1496 // Channel messages:
1497 wire::Message::OpenChannel(msg) => {
1498 self.message_handler.chan_handler.handle_open_channel(&their_node_id, &msg);
1500 wire::Message::AcceptChannel(msg) => {
1501 self.message_handler.chan_handler.handle_accept_channel(&their_node_id, &msg);
1504 wire::Message::FundingCreated(msg) => {
1505 self.message_handler.chan_handler.handle_funding_created(&their_node_id, &msg);
1507 wire::Message::FundingSigned(msg) => {
1508 self.message_handler.chan_handler.handle_funding_signed(&their_node_id, &msg);
1510 wire::Message::ChannelReady(msg) => {
1511 self.message_handler.chan_handler.handle_channel_ready(&their_node_id, &msg);
1514 wire::Message::Shutdown(msg) => {
1515 self.message_handler.chan_handler.handle_shutdown(&their_node_id, &msg);
1517 wire::Message::ClosingSigned(msg) => {
1518 self.message_handler.chan_handler.handle_closing_signed(&their_node_id, &msg);
1521 // Commitment messages:
1522 wire::Message::UpdateAddHTLC(msg) => {
1523 self.message_handler.chan_handler.handle_update_add_htlc(&their_node_id, &msg);
1525 wire::Message::UpdateFulfillHTLC(msg) => {
1526 self.message_handler.chan_handler.handle_update_fulfill_htlc(&their_node_id, &msg);
1528 wire::Message::UpdateFailHTLC(msg) => {
1529 self.message_handler.chan_handler.handle_update_fail_htlc(&their_node_id, &msg);
1531 wire::Message::UpdateFailMalformedHTLC(msg) => {
1532 self.message_handler.chan_handler.handle_update_fail_malformed_htlc(&their_node_id, &msg);
1535 wire::Message::CommitmentSigned(msg) => {
1536 self.message_handler.chan_handler.handle_commitment_signed(&their_node_id, &msg);
1538 wire::Message::RevokeAndACK(msg) => {
1539 self.message_handler.chan_handler.handle_revoke_and_ack(&their_node_id, &msg);
1541 wire::Message::UpdateFee(msg) => {
1542 self.message_handler.chan_handler.handle_update_fee(&their_node_id, &msg);
1544 wire::Message::ChannelReestablish(msg) => {
1545 self.message_handler.chan_handler.handle_channel_reestablish(&their_node_id, &msg);
1548 // Routing messages:
1549 wire::Message::AnnouncementSignatures(msg) => {
1550 self.message_handler.chan_handler.handle_announcement_signatures(&their_node_id, &msg);
1552 wire::Message::ChannelAnnouncement(msg) => {
1553 if self.message_handler.route_handler.handle_channel_announcement(&msg)
1554 .map_err(|e| -> MessageHandlingError { e.into() })? {
1555 should_forward = Some(wire::Message::ChannelAnnouncement(msg));
1557 self.update_gossip_backlogged();
1559 wire::Message::NodeAnnouncement(msg) => {
1560 if self.message_handler.route_handler.handle_node_announcement(&msg)
1561 .map_err(|e| -> MessageHandlingError { e.into() })? {
1562 should_forward = Some(wire::Message::NodeAnnouncement(msg));
1564 self.update_gossip_backlogged();
1566 wire::Message::ChannelUpdate(msg) => {
1567 self.message_handler.chan_handler.handle_channel_update(&their_node_id, &msg);
1568 if self.message_handler.route_handler.handle_channel_update(&msg)
1569 .map_err(|e| -> MessageHandlingError { e.into() })? {
1570 should_forward = Some(wire::Message::ChannelUpdate(msg));
1572 self.update_gossip_backlogged();
1574 wire::Message::QueryShortChannelIds(msg) => {
1575 self.message_handler.route_handler.handle_query_short_channel_ids(&their_node_id, msg)?;
1577 wire::Message::ReplyShortChannelIdsEnd(msg) => {
1578 self.message_handler.route_handler.handle_reply_short_channel_ids_end(&their_node_id, msg)?;
1580 wire::Message::QueryChannelRange(msg) => {
1581 self.message_handler.route_handler.handle_query_channel_range(&their_node_id, msg)?;
1583 wire::Message::ReplyChannelRange(msg) => {
1584 self.message_handler.route_handler.handle_reply_channel_range(&their_node_id, msg)?;
1588 wire::Message::OnionMessage(msg) => {
1589 self.message_handler.onion_message_handler.handle_onion_message(&their_node_id, &msg);
1592 // Unknown messages:
1593 wire::Message::Unknown(type_id) if message.is_even() => {
1594 log_debug!(self.logger, "Received unknown even message of type {}, disconnecting peer!", type_id);
1595 return Err(PeerHandleError { }.into());
1597 wire::Message::Unknown(type_id) => {
1598 log_trace!(self.logger, "Received unknown odd message of type {}, ignoring", type_id);
1600 wire::Message::Custom(custom) => {
1601 self.message_handler.custom_message_handler.handle_custom_message(custom, &their_node_id)?;
1607 fn forward_broadcast_msg(&self, peers: &HashMap<Descriptor, Mutex<Peer>>, msg: &wire::Message<<<CMH as core::ops::Deref>::Target as wire::CustomMessageReader>::CustomMessage>, except_node: Option<&PublicKey>) {
1609 wire::Message::ChannelAnnouncement(ref msg) => {
1610 log_gossip!(self.logger, "Sending message to all peers except {:?} or the announced channel's counterparties: {:?}", except_node, msg);
1611 let encoded_msg = encode_msg!(msg);
1613 for (_, peer_mutex) in peers.iter() {
1614 let mut peer = peer_mutex.lock().unwrap();
1615 if !peer.handshake_complete() ||
1616 !peer.should_forward_channel_announcement(msg.contents.short_channel_id) {
1619 debug_assert!(peer.their_node_id.is_some());
1620 debug_assert!(peer.channel_encryptor.is_ready_for_encryption());
1621 if peer.buffer_full_drop_gossip_broadcast() {
1622 log_gossip!(self.logger, "Skipping broadcast message to {:?} as its outbound buffer is full", peer.their_node_id);
1625 if let Some((_, their_node_id)) = peer.their_node_id {
1626 if their_node_id == msg.contents.node_id_1 || their_node_id == msg.contents.node_id_2 {
1630 if except_node.is_some() && peer.their_node_id.as_ref().map(|(pk, _)| pk) == except_node {
1633 self.enqueue_encoded_gossip_broadcast(&mut *peer, encoded_msg.clone());
1636 wire::Message::NodeAnnouncement(ref msg) => {
1637 log_gossip!(self.logger, "Sending message to all peers except {:?} or the announced node: {:?}", except_node, msg);
1638 let encoded_msg = encode_msg!(msg);
1640 for (_, peer_mutex) in peers.iter() {
1641 let mut peer = peer_mutex.lock().unwrap();
1642 if !peer.handshake_complete() ||
1643 !peer.should_forward_node_announcement(msg.contents.node_id) {
1646 debug_assert!(peer.their_node_id.is_some());
1647 debug_assert!(peer.channel_encryptor.is_ready_for_encryption());
1648 if peer.buffer_full_drop_gossip_broadcast() {
1649 log_gossip!(self.logger, "Skipping broadcast message to {:?} as its outbound buffer is full", peer.their_node_id);
1652 if let Some((_, their_node_id)) = peer.their_node_id {
1653 if their_node_id == msg.contents.node_id {
1657 if except_node.is_some() && peer.their_node_id.as_ref().map(|(pk, _)| pk) == except_node {
1660 self.enqueue_encoded_gossip_broadcast(&mut *peer, encoded_msg.clone());
1663 wire::Message::ChannelUpdate(ref msg) => {
1664 log_gossip!(self.logger, "Sending message to all peers except {:?}: {:?}", except_node, msg);
1665 let encoded_msg = encode_msg!(msg);
1667 for (_, peer_mutex) in peers.iter() {
1668 let mut peer = peer_mutex.lock().unwrap();
1669 if !peer.handshake_complete() ||
1670 !peer.should_forward_channel_announcement(msg.contents.short_channel_id) {
1673 debug_assert!(peer.their_node_id.is_some());
1674 debug_assert!(peer.channel_encryptor.is_ready_for_encryption());
1675 if peer.buffer_full_drop_gossip_broadcast() {
1676 log_gossip!(self.logger, "Skipping broadcast message to {:?} as its outbound buffer is full", peer.their_node_id);
1679 if except_node.is_some() && peer.their_node_id.as_ref().map(|(pk, _)| pk) == except_node {
1682 self.enqueue_encoded_gossip_broadcast(&mut *peer, encoded_msg.clone());
1685 _ => debug_assert!(false, "We shouldn't attempt to forward anything but gossip messages"),
1689 /// Checks for any events generated by our handlers and processes them. Includes sending most
1690 /// response messages as well as messages generated by calls to handler functions directly (eg
1691 /// functions like [`ChannelManager::process_pending_htlc_forwards`] or [`send_payment`]).
1693 /// May call [`send_data`] on [`SocketDescriptor`]s. Thus, be very careful with reentrancy
1696 /// You don't have to call this function explicitly if you are using [`lightning-net-tokio`]
1697 /// or one of the other clients provided in our language bindings.
1699 /// Note that if there are any other calls to this function waiting on lock(s) this may return
1700 /// without doing any work. All available events that need handling will be handled before the
1701 /// other calls return.
1703 /// [`send_payment`]: crate::ln::channelmanager::ChannelManager::send_payment
1704 /// [`ChannelManager::process_pending_htlc_forwards`]: crate::ln::channelmanager::ChannelManager::process_pending_htlc_forwards
1705 /// [`send_data`]: SocketDescriptor::send_data
1706 pub fn process_events(&self) {
1707 let mut _single_processor_lock = self.event_processing_lock.try_lock();
1708 if _single_processor_lock.is_err() {
1709 // While we could wake the older sleeper here with a CV and make more even waiting
1710 // times, that would be a lot of overengineering for a simple "reduce total waiter
1712 match self.blocked_event_processors.compare_exchange(false, true, Ordering::AcqRel, Ordering::Acquire) {
1714 debug_assert!(val, "compare_exchange failed spuriously?");
1718 debug_assert!(!val, "compare_exchange succeeded spuriously?");
1719 // We're the only waiter, as the running process_events may have emptied the
1720 // pending events "long" ago and there are new events for us to process, wait until
1721 // its done and process any leftover events before returning.
1722 _single_processor_lock = Ok(self.event_processing_lock.lock().unwrap());
1723 self.blocked_event_processors.store(false, Ordering::Release);
1728 self.update_gossip_backlogged();
1729 let flush_read_disabled = self.gossip_processing_backlog_lifted.swap(false, Ordering::Relaxed);
1731 let mut peers_to_disconnect = HashMap::new();
1732 let mut events_generated = self.message_handler.chan_handler.get_and_clear_pending_msg_events();
1733 events_generated.append(&mut self.message_handler.route_handler.get_and_clear_pending_msg_events());
1736 // TODO: There are some DoS attacks here where you can flood someone's outbound send
1737 // buffer by doing things like announcing channels on another node. We should be willing to
1738 // drop optional-ish messages when send buffers get full!
1740 let peers_lock = self.peers.read().unwrap();
1741 let peers = &*peers_lock;
1742 macro_rules! get_peer_for_forwarding {
1743 ($node_id: expr) => {
1745 if peers_to_disconnect.get($node_id).is_some() {
1746 // If we've "disconnected" this peer, do not send to it.
1749 let descriptor_opt = self.node_id_to_descriptor.lock().unwrap().get($node_id).cloned();
1750 match descriptor_opt {
1751 Some(descriptor) => match peers.get(&descriptor) {
1752 Some(peer_mutex) => {
1753 let peer_lock = peer_mutex.lock().unwrap();
1754 if !peer_lock.handshake_complete() {
1760 debug_assert!(false, "Inconsistent peers set state!");
1771 for event in events_generated.drain(..) {
1773 MessageSendEvent::SendAcceptChannel { ref node_id, ref msg } => {
1774 log_debug!(self.logger, "Handling SendAcceptChannel event in peer_handler for node {} for channel {}",
1775 log_pubkey!(node_id),
1776 log_bytes!(msg.temporary_channel_id));
1777 self.enqueue_message(&mut *get_peer_for_forwarding!(node_id), msg);
1779 MessageSendEvent::SendOpenChannel { ref node_id, ref msg } => {
1780 log_debug!(self.logger, "Handling SendOpenChannel event in peer_handler for node {} for channel {}",
1781 log_pubkey!(node_id),
1782 log_bytes!(msg.temporary_channel_id));
1783 self.enqueue_message(&mut *get_peer_for_forwarding!(node_id), msg);
1785 MessageSendEvent::SendFundingCreated { ref node_id, ref msg } => {
1786 log_debug!(self.logger, "Handling SendFundingCreated event in peer_handler for node {} for channel {} (which becomes {})",
1787 log_pubkey!(node_id),
1788 log_bytes!(msg.temporary_channel_id),
1789 log_funding_channel_id!(msg.funding_txid, msg.funding_output_index));
1790 // TODO: If the peer is gone we should generate a DiscardFunding event
1791 // indicating to the wallet that they should just throw away this funding transaction
1792 self.enqueue_message(&mut *get_peer_for_forwarding!(node_id), msg);
1794 MessageSendEvent::SendFundingSigned { ref node_id, ref msg } => {
1795 log_debug!(self.logger, "Handling SendFundingSigned event in peer_handler for node {} for channel {}",
1796 log_pubkey!(node_id),
1797 log_bytes!(msg.channel_id));
1798 self.enqueue_message(&mut *get_peer_for_forwarding!(node_id), msg);
1800 MessageSendEvent::SendChannelReady { ref node_id, ref msg } => {
1801 log_debug!(self.logger, "Handling SendChannelReady event in peer_handler for node {} for channel {}",
1802 log_pubkey!(node_id),
1803 log_bytes!(msg.channel_id));
1804 self.enqueue_message(&mut *get_peer_for_forwarding!(node_id), msg);
1806 MessageSendEvent::SendAnnouncementSignatures { ref node_id, ref msg } => {
1807 log_debug!(self.logger, "Handling SendAnnouncementSignatures event in peer_handler for node {} for channel {})",
1808 log_pubkey!(node_id),
1809 log_bytes!(msg.channel_id));
1810 self.enqueue_message(&mut *get_peer_for_forwarding!(node_id), msg);
1812 MessageSendEvent::UpdateHTLCs { ref node_id, updates: msgs::CommitmentUpdate { ref update_add_htlcs, ref update_fulfill_htlcs, ref update_fail_htlcs, ref update_fail_malformed_htlcs, ref update_fee, ref commitment_signed } } => {
1813 log_debug!(self.logger, "Handling UpdateHTLCs event in peer_handler for node {} with {} adds, {} fulfills, {} fails for channel {}",
1814 log_pubkey!(node_id),
1815 update_add_htlcs.len(),
1816 update_fulfill_htlcs.len(),
1817 update_fail_htlcs.len(),
1818 log_bytes!(commitment_signed.channel_id));
1819 let mut peer = get_peer_for_forwarding!(node_id);
1820 for msg in update_add_htlcs {
1821 self.enqueue_message(&mut *peer, msg);
1823 for msg in update_fulfill_htlcs {
1824 self.enqueue_message(&mut *peer, msg);
1826 for msg in update_fail_htlcs {
1827 self.enqueue_message(&mut *peer, msg);
1829 for msg in update_fail_malformed_htlcs {
1830 self.enqueue_message(&mut *peer, msg);
1832 if let &Some(ref msg) = update_fee {
1833 self.enqueue_message(&mut *peer, msg);
1835 self.enqueue_message(&mut *peer, commitment_signed);
1837 MessageSendEvent::SendRevokeAndACK { ref node_id, ref msg } => {
1838 log_debug!(self.logger, "Handling SendRevokeAndACK event in peer_handler for node {} for channel {}",
1839 log_pubkey!(node_id),
1840 log_bytes!(msg.channel_id));
1841 self.enqueue_message(&mut *get_peer_for_forwarding!(node_id), msg);
1843 MessageSendEvent::SendClosingSigned { ref node_id, ref msg } => {
1844 log_debug!(self.logger, "Handling SendClosingSigned event in peer_handler for node {} for channel {}",
1845 log_pubkey!(node_id),
1846 log_bytes!(msg.channel_id));
1847 self.enqueue_message(&mut *get_peer_for_forwarding!(node_id), msg);
1849 MessageSendEvent::SendShutdown { ref node_id, ref msg } => {
1850 log_debug!(self.logger, "Handling Shutdown event in peer_handler for node {} for channel {}",
1851 log_pubkey!(node_id),
1852 log_bytes!(msg.channel_id));
1853 self.enqueue_message(&mut *get_peer_for_forwarding!(node_id), msg);
1855 MessageSendEvent::SendChannelReestablish { ref node_id, ref msg } => {
1856 log_debug!(self.logger, "Handling SendChannelReestablish event in peer_handler for node {} for channel {}",
1857 log_pubkey!(node_id),
1858 log_bytes!(msg.channel_id));
1859 self.enqueue_message(&mut *get_peer_for_forwarding!(node_id), msg);
1861 MessageSendEvent::SendChannelAnnouncement { ref node_id, ref msg, ref update_msg } => {
1862 log_debug!(self.logger, "Handling SendChannelAnnouncement event in peer_handler for node {} for short channel id {}",
1863 log_pubkey!(node_id),
1864 msg.contents.short_channel_id);
1865 self.enqueue_message(&mut *get_peer_for_forwarding!(node_id), msg);
1866 self.enqueue_message(&mut *get_peer_for_forwarding!(node_id), update_msg);
1868 MessageSendEvent::BroadcastChannelAnnouncement { msg, update_msg } => {
1869 log_debug!(self.logger, "Handling BroadcastChannelAnnouncement event in peer_handler for short channel id {}", msg.contents.short_channel_id);
1870 match self.message_handler.route_handler.handle_channel_announcement(&msg) {
1871 Ok(_) | Err(LightningError { action: msgs::ErrorAction::IgnoreDuplicateGossip, .. }) =>
1872 self.forward_broadcast_msg(peers, &wire::Message::ChannelAnnouncement(msg), None),
1875 if let Some(msg) = update_msg {
1876 match self.message_handler.route_handler.handle_channel_update(&msg) {
1877 Ok(_) | Err(LightningError { action: msgs::ErrorAction::IgnoreDuplicateGossip, .. }) =>
1878 self.forward_broadcast_msg(peers, &wire::Message::ChannelUpdate(msg), None),
1883 MessageSendEvent::BroadcastChannelUpdate { msg } => {
1884 log_debug!(self.logger, "Handling BroadcastChannelUpdate event in peer_handler for short channel id {}", msg.contents.short_channel_id);
1885 match self.message_handler.route_handler.handle_channel_update(&msg) {
1886 Ok(_) | Err(LightningError { action: msgs::ErrorAction::IgnoreDuplicateGossip, .. }) =>
1887 self.forward_broadcast_msg(peers, &wire::Message::ChannelUpdate(msg), None),
1891 MessageSendEvent::BroadcastNodeAnnouncement { msg } => {
1892 log_debug!(self.logger, "Handling BroadcastNodeAnnouncement event in peer_handler for node {}", msg.contents.node_id);
1893 match self.message_handler.route_handler.handle_node_announcement(&msg) {
1894 Ok(_) | Err(LightningError { action: msgs::ErrorAction::IgnoreDuplicateGossip, .. }) =>
1895 self.forward_broadcast_msg(peers, &wire::Message::NodeAnnouncement(msg), None),
1899 MessageSendEvent::SendChannelUpdate { ref node_id, ref msg } => {
1900 log_trace!(self.logger, "Handling SendChannelUpdate event in peer_handler for node {} for channel {}",
1901 log_pubkey!(node_id), msg.contents.short_channel_id);
1902 self.enqueue_message(&mut *get_peer_for_forwarding!(node_id), msg);
1904 MessageSendEvent::HandleError { ref node_id, ref action } => {
1906 msgs::ErrorAction::DisconnectPeer { ref msg } => {
1907 // We do not have the peers write lock, so we just store that we're
1908 // about to disconenct the peer and do it after we finish
1909 // processing most messages.
1910 peers_to_disconnect.insert(*node_id, msg.clone());
1912 msgs::ErrorAction::IgnoreAndLog(level) => {
1913 log_given_level!(self.logger, level, "Received a HandleError event to be ignored for node {}", log_pubkey!(node_id));
1915 msgs::ErrorAction::IgnoreDuplicateGossip => {},
1916 msgs::ErrorAction::IgnoreError => {
1917 log_debug!(self.logger, "Received a HandleError event to be ignored for node {}", log_pubkey!(node_id));
1919 msgs::ErrorAction::SendErrorMessage { ref msg } => {
1920 log_trace!(self.logger, "Handling SendErrorMessage HandleError event in peer_handler for node {} with message {}",
1921 log_pubkey!(node_id),
1923 self.enqueue_message(&mut *get_peer_for_forwarding!(node_id), msg);
1925 msgs::ErrorAction::SendWarningMessage { ref msg, ref log_level } => {
1926 log_given_level!(self.logger, *log_level, "Handling SendWarningMessage HandleError event in peer_handler for node {} with message {}",
1927 log_pubkey!(node_id),
1929 self.enqueue_message(&mut *get_peer_for_forwarding!(node_id), msg);
1933 MessageSendEvent::SendChannelRangeQuery { ref node_id, ref msg } => {
1934 self.enqueue_message(&mut *get_peer_for_forwarding!(node_id), msg);
1936 MessageSendEvent::SendShortIdsQuery { ref node_id, ref msg } => {
1937 self.enqueue_message(&mut *get_peer_for_forwarding!(node_id), msg);
1939 MessageSendEvent::SendReplyChannelRange { ref node_id, ref msg } => {
1940 log_gossip!(self.logger, "Handling SendReplyChannelRange event in peer_handler for node {} with num_scids={} first_blocknum={} number_of_blocks={}, sync_complete={}",
1941 log_pubkey!(node_id),
1942 msg.short_channel_ids.len(),
1944 msg.number_of_blocks,
1946 self.enqueue_message(&mut *get_peer_for_forwarding!(node_id), msg);
1948 MessageSendEvent::SendGossipTimestampFilter { ref node_id, ref msg } => {
1949 self.enqueue_message(&mut *get_peer_for_forwarding!(node_id), msg);
1954 for (node_id, msg) in self.message_handler.custom_message_handler.get_and_clear_pending_msg() {
1955 if peers_to_disconnect.get(&node_id).is_some() { continue; }
1956 self.enqueue_message(&mut *get_peer_for_forwarding!(&node_id), &msg);
1959 for (descriptor, peer_mutex) in peers.iter() {
1960 let mut peer = peer_mutex.lock().unwrap();
1961 if flush_read_disabled { peer.received_channel_announce_since_backlogged = false; }
1962 self.do_attempt_write_data(&mut (*descriptor).clone(), &mut *peer, flush_read_disabled);
1965 if !peers_to_disconnect.is_empty() {
1966 let mut peers_lock = self.peers.write().unwrap();
1967 let peers = &mut *peers_lock;
1968 for (node_id, msg) in peers_to_disconnect.drain() {
1969 // Note that since we are holding the peers *write* lock we can
1970 // remove from node_id_to_descriptor immediately (as no other
1971 // thread can be holding the peer lock if we have the global write
1974 let descriptor_opt = self.node_id_to_descriptor.lock().unwrap().remove(&node_id);
1975 if let Some(mut descriptor) = descriptor_opt {
1976 if let Some(peer_mutex) = peers.remove(&descriptor) {
1977 let mut peer = peer_mutex.lock().unwrap();
1978 if let Some(msg) = msg {
1979 log_trace!(self.logger, "Handling DisconnectPeer HandleError event in peer_handler for node {} with message {}",
1980 log_pubkey!(node_id),
1982 self.enqueue_message(&mut *peer, &msg);
1983 // This isn't guaranteed to work, but if there is enough free
1984 // room in the send buffer, put the error message there...
1985 self.do_attempt_write_data(&mut descriptor, &mut *peer, false);
1987 self.do_disconnect(descriptor, &*peer, "DisconnectPeer HandleError");
1988 } else { debug_assert!(false, "Missing connection for peer"); }
1994 /// Indicates that the given socket descriptor's connection is now closed.
1995 pub fn socket_disconnected(&self, descriptor: &Descriptor) {
1996 self.disconnect_event_internal(descriptor);
1999 fn do_disconnect(&self, mut descriptor: Descriptor, peer: &Peer, reason: &'static str) {
2000 if !peer.handshake_complete() {
2001 log_trace!(self.logger, "Disconnecting peer which hasn't completed handshake due to {}", reason);
2002 descriptor.disconnect_socket();
2006 debug_assert!(peer.their_node_id.is_some());
2007 if let Some((node_id, _)) = peer.their_node_id {
2008 log_trace!(self.logger, "Disconnecting peer with id {} due to {}", node_id, reason);
2009 self.message_handler.chan_handler.peer_disconnected(&node_id);
2010 self.message_handler.onion_message_handler.peer_disconnected(&node_id);
2012 descriptor.disconnect_socket();
2015 fn disconnect_event_internal(&self, descriptor: &Descriptor) {
2016 let mut peers = self.peers.write().unwrap();
2017 let peer_option = peers.remove(descriptor);
2020 // This is most likely a simple race condition where the user found that the socket
2021 // was disconnected, then we told the user to `disconnect_socket()`, then they
2022 // called this method. Either way we're disconnected, return.
2024 Some(peer_lock) => {
2025 let peer = peer_lock.lock().unwrap();
2026 if let Some((node_id, _)) = peer.their_node_id {
2027 log_trace!(self.logger, "Handling disconnection of peer {}", log_pubkey!(node_id));
2028 let removed = self.node_id_to_descriptor.lock().unwrap().remove(&node_id);
2029 debug_assert!(removed.is_some(), "descriptor maps should be consistent");
2030 if !peer.handshake_complete() { return; }
2031 self.message_handler.chan_handler.peer_disconnected(&node_id);
2032 self.message_handler.onion_message_handler.peer_disconnected(&node_id);
2038 /// Disconnect a peer given its node id.
2040 /// If a peer is connected, this will call [`disconnect_socket`] on the descriptor for the
2041 /// peer. Thus, be very careful about reentrancy issues.
2043 /// [`disconnect_socket`]: SocketDescriptor::disconnect_socket
2044 pub fn disconnect_by_node_id(&self, node_id: PublicKey) {
2045 let mut peers_lock = self.peers.write().unwrap();
2046 if let Some(descriptor) = self.node_id_to_descriptor.lock().unwrap().remove(&node_id) {
2047 let peer_opt = peers_lock.remove(&descriptor);
2048 if let Some(peer_mutex) = peer_opt {
2049 self.do_disconnect(descriptor, &*peer_mutex.lock().unwrap(), "client request");
2050 } else { debug_assert!(false, "node_id_to_descriptor thought we had a peer"); }
2054 /// Disconnects all currently-connected peers. This is useful on platforms where there may be
2055 /// an indication that TCP sockets have stalled even if we weren't around to time them out
2056 /// using regular ping/pongs.
2057 pub fn disconnect_all_peers(&self) {
2058 let mut peers_lock = self.peers.write().unwrap();
2059 self.node_id_to_descriptor.lock().unwrap().clear();
2060 let peers = &mut *peers_lock;
2061 for (descriptor, peer_mutex) in peers.drain() {
2062 self.do_disconnect(descriptor, &*peer_mutex.lock().unwrap(), "client request to disconnect all peers");
2066 /// This is called when we're blocked on sending additional gossip messages until we receive a
2067 /// pong. If we aren't waiting on a pong, we take this opportunity to send a ping (setting
2068 /// `awaiting_pong_timer_tick_intervals` to a special flag value to indicate this).
2069 fn maybe_send_extra_ping(&self, peer: &mut Peer) {
2070 if peer.awaiting_pong_timer_tick_intervals == 0 {
2071 peer.awaiting_pong_timer_tick_intervals = -1;
2072 let ping = msgs::Ping {
2076 self.enqueue_message(peer, &ping);
2080 /// Send pings to each peer and disconnect those which did not respond to the last round of
2083 /// This may be called on any timescale you want, however, roughly once every ten seconds is
2084 /// preferred. The call rate determines both how often we send a ping to our peers and how much
2085 /// time they have to respond before we disconnect them.
2087 /// May call [`send_data`] on all [`SocketDescriptor`]s. Thus, be very careful with reentrancy
2090 /// [`send_data`]: SocketDescriptor::send_data
2091 pub fn timer_tick_occurred(&self) {
2092 let mut descriptors_needing_disconnect = Vec::new();
2094 let peers_lock = self.peers.read().unwrap();
2096 self.update_gossip_backlogged();
2097 let flush_read_disabled = self.gossip_processing_backlog_lifted.swap(false, Ordering::Relaxed);
2099 for (descriptor, peer_mutex) in peers_lock.iter() {
2100 let mut peer = peer_mutex.lock().unwrap();
2101 if flush_read_disabled { peer.received_channel_announce_since_backlogged = false; }
2103 if !peer.handshake_complete() {
2104 // The peer needs to complete its handshake before we can exchange messages. We
2105 // give peers one timer tick to complete handshake, reusing
2106 // `awaiting_pong_timer_tick_intervals` to track number of timer ticks taken
2107 // for handshake completion.
2108 if peer.awaiting_pong_timer_tick_intervals != 0 {
2109 descriptors_needing_disconnect.push(descriptor.clone());
2111 peer.awaiting_pong_timer_tick_intervals = 1;
2115 debug_assert!(peer.channel_encryptor.is_ready_for_encryption());
2116 debug_assert!(peer.their_node_id.is_some());
2118 loop { // Used as a `goto` to skip writing a Ping message.
2119 if peer.awaiting_pong_timer_tick_intervals == -1 {
2120 // Magic value set in `maybe_send_extra_ping`.
2121 peer.awaiting_pong_timer_tick_intervals = 1;
2122 peer.received_message_since_timer_tick = false;
2126 if (peer.awaiting_pong_timer_tick_intervals > 0 && !peer.received_message_since_timer_tick)
2127 || peer.awaiting_pong_timer_tick_intervals as u64 >
2128 MAX_BUFFER_DRAIN_TICK_INTERVALS_PER_PEER as u64 * peers_lock.len() as u64
2130 descriptors_needing_disconnect.push(descriptor.clone());
2133 peer.received_message_since_timer_tick = false;
2135 if peer.awaiting_pong_timer_tick_intervals > 0 {
2136 peer.awaiting_pong_timer_tick_intervals += 1;
2140 peer.awaiting_pong_timer_tick_intervals = 1;
2141 let ping = msgs::Ping {
2145 self.enqueue_message(&mut *peer, &ping);
2148 self.do_attempt_write_data(&mut (descriptor.clone()), &mut *peer, flush_read_disabled);
2152 if !descriptors_needing_disconnect.is_empty() {
2154 let mut peers_lock = self.peers.write().unwrap();
2155 for descriptor in descriptors_needing_disconnect {
2156 if let Some(peer_mutex) = peers_lock.remove(&descriptor) {
2157 let peer = peer_mutex.lock().unwrap();
2158 if let Some((node_id, _)) = peer.their_node_id {
2159 self.node_id_to_descriptor.lock().unwrap().remove(&node_id);
2161 self.do_disconnect(descriptor, &*peer, "ping/handshake timeout");
2169 // Messages of up to 64KB should never end up more than half full with addresses, as that would
2170 // be absurd. We ensure this by checking that at least 100 (our stated public contract on when
2171 // broadcast_node_announcement panics) of the maximum-length addresses would fit in a 64KB
2173 const HALF_MESSAGE_IS_ADDRS: u32 = ::core::u16::MAX as u32 / (NetAddress::MAX_LEN as u32 + 1) / 2;
2176 // ...by failing to compile if the number of addresses that would be half of a message is
2177 // smaller than 100:
2178 const STATIC_ASSERT: u32 = Self::HALF_MESSAGE_IS_ADDRS - 100;
2180 /// Generates a signed node_announcement from the given arguments, sending it to all connected
2181 /// peers. Note that peers will likely ignore this message unless we have at least one public
2182 /// channel which has at least six confirmations on-chain.
2184 /// `rgb` is a node "color" and `alias` is a printable human-readable string to describe this
2185 /// node to humans. They carry no in-protocol meaning.
2187 /// `addresses` represent the set (possibly empty) of socket addresses on which this node
2188 /// accepts incoming connections. These will be included in the node_announcement, publicly
2189 /// tying these addresses together and to this node. If you wish to preserve user privacy,
2190 /// addresses should likely contain only Tor Onion addresses.
2192 /// Panics if `addresses` is absurdly large (more than 100).
2194 /// [`get_and_clear_pending_msg_events`]: MessageSendEventsProvider::get_and_clear_pending_msg_events
2195 pub fn broadcast_node_announcement(&self, rgb: [u8; 3], alias: [u8; 32], mut addresses: Vec<NetAddress>) {
2196 if addresses.len() > 100 {
2197 panic!("More than half the message size was taken up by public addresses!");
2200 // While all existing nodes handle unsorted addresses just fine, the spec requires that
2201 // addresses be sorted for future compatibility.
2202 addresses.sort_by_key(|addr| addr.get_id());
2204 let features = self.message_handler.chan_handler.provided_node_features()
2205 .or(self.message_handler.route_handler.provided_node_features())
2206 .or(self.message_handler.onion_message_handler.provided_node_features());
2207 let announcement = msgs::UnsignedNodeAnnouncement {
2209 timestamp: self.last_node_announcement_serial.fetch_add(1, Ordering::AcqRel),
2210 node_id: NodeId::from_pubkey(&self.node_signer.get_node_id(Recipient::Node).unwrap()),
2212 alias: NodeAlias(alias),
2214 excess_address_data: Vec::new(),
2215 excess_data: Vec::new(),
2217 let node_announce_sig = match self.node_signer.sign_gossip_message(
2218 msgs::UnsignedGossipMessage::NodeAnnouncement(&announcement)
2222 log_error!(self.logger, "Failed to generate signature for node_announcement");
2227 let msg = msgs::NodeAnnouncement {
2228 signature: node_announce_sig,
2229 contents: announcement
2232 log_debug!(self.logger, "Broadcasting NodeAnnouncement after passing it to our own RoutingMessageHandler.");
2233 let _ = self.message_handler.route_handler.handle_node_announcement(&msg);
2234 self.forward_broadcast_msg(&*self.peers.read().unwrap(), &wire::Message::NodeAnnouncement(msg), None);
2238 fn is_gossip_msg(type_id: u16) -> bool {
2240 msgs::ChannelAnnouncement::TYPE |
2241 msgs::ChannelUpdate::TYPE |
2242 msgs::NodeAnnouncement::TYPE |
2243 msgs::QueryChannelRange::TYPE |
2244 msgs::ReplyChannelRange::TYPE |
2245 msgs::QueryShortChannelIds::TYPE |
2246 msgs::ReplyShortChannelIdsEnd::TYPE => true,
2253 use crate::chain::keysinterface::{NodeSigner, Recipient};
2255 use crate::ln::peer_channel_encryptor::PeerChannelEncryptor;
2256 use crate::ln::peer_handler::{PeerManager, MessageHandler, SocketDescriptor, IgnoringMessageHandler, filter_addresses};
2257 use crate::ln::{msgs, wire};
2258 use crate::ln::msgs::NetAddress;
2259 use crate::util::test_utils;
2261 use bitcoin::secp256k1::SecretKey;
2263 use crate::prelude::*;
2264 use crate::sync::{Arc, Mutex};
2265 use core::sync::atomic::{AtomicBool, Ordering};
2268 struct FileDescriptor {
2270 outbound_data: Arc<Mutex<Vec<u8>>>,
2271 disconnect: Arc<AtomicBool>,
2273 impl PartialEq for FileDescriptor {
2274 fn eq(&self, other: &Self) -> bool {
2278 impl Eq for FileDescriptor { }
2279 impl core::hash::Hash for FileDescriptor {
2280 fn hash<H: core::hash::Hasher>(&self, hasher: &mut H) {
2281 self.fd.hash(hasher)
2285 impl SocketDescriptor for FileDescriptor {
2286 fn send_data(&mut self, data: &[u8], _resume_read: bool) -> usize {
2287 self.outbound_data.lock().unwrap().extend_from_slice(data);
2291 fn disconnect_socket(&mut self) { self.disconnect.store(true, Ordering::Release); }
2294 struct PeerManagerCfg {
2295 chan_handler: test_utils::TestChannelMessageHandler,
2296 routing_handler: test_utils::TestRoutingMessageHandler,
2297 logger: test_utils::TestLogger,
2298 node_signer: test_utils::TestNodeSigner,
2301 fn create_peermgr_cfgs(peer_count: usize) -> Vec<PeerManagerCfg> {
2302 let mut cfgs = Vec::new();
2303 for i in 0..peer_count {
2304 let node_secret = SecretKey::from_slice(&[42 + i as u8; 32]).unwrap();
2307 chan_handler: test_utils::TestChannelMessageHandler::new(),
2308 logger: test_utils::TestLogger::new(),
2309 routing_handler: test_utils::TestRoutingMessageHandler::new(),
2310 node_signer: test_utils::TestNodeSigner::new(node_secret),
2318 fn create_network<'a>(peer_count: usize, cfgs: &'a Vec<PeerManagerCfg>) -> Vec<PeerManager<FileDescriptor, &'a test_utils::TestChannelMessageHandler, &'a test_utils::TestRoutingMessageHandler, IgnoringMessageHandler, &'a test_utils::TestLogger, IgnoringMessageHandler, &'a test_utils::TestNodeSigner>> {
2319 let mut peers = Vec::new();
2320 for i in 0..peer_count {
2321 let ephemeral_bytes = [i as u8; 32];
2322 let msg_handler = MessageHandler {
2323 chan_handler: &cfgs[i].chan_handler, route_handler: &cfgs[i].routing_handler,
2324 onion_message_handler: IgnoringMessageHandler {}, custom_message_handler: IgnoringMessageHandler {}
2326 let peer = PeerManager::new(msg_handler, 0, &ephemeral_bytes, &cfgs[i].logger, &cfgs[i].node_signer);
2333 fn establish_connection<'a>(peer_a: &PeerManager<FileDescriptor, &'a test_utils::TestChannelMessageHandler, &'a test_utils::TestRoutingMessageHandler, IgnoringMessageHandler, &'a test_utils::TestLogger, IgnoringMessageHandler, &'a test_utils::TestNodeSigner>, peer_b: &PeerManager<FileDescriptor, &'a test_utils::TestChannelMessageHandler, &'a test_utils::TestRoutingMessageHandler, IgnoringMessageHandler, &'a test_utils::TestLogger, IgnoringMessageHandler, &'a test_utils::TestNodeSigner>) -> (FileDescriptor, FileDescriptor) {
2334 let id_a = peer_a.node_signer.get_node_id(Recipient::Node).unwrap();
2335 let mut fd_a = FileDescriptor {
2336 fd: 1, outbound_data: Arc::new(Mutex::new(Vec::new())),
2337 disconnect: Arc::new(AtomicBool::new(false)),
2339 let addr_a = NetAddress::IPv4{addr: [127, 0, 0, 1], port: 1000};
2340 let id_b = peer_b.node_signer.get_node_id(Recipient::Node).unwrap();
2341 let mut fd_b = FileDescriptor {
2342 fd: 1, outbound_data: Arc::new(Mutex::new(Vec::new())),
2343 disconnect: Arc::new(AtomicBool::new(false)),
2345 let addr_b = NetAddress::IPv4{addr: [127, 0, 0, 1], port: 1001};
2346 let initial_data = peer_b.new_outbound_connection(id_a, fd_b.clone(), Some(addr_a.clone())).unwrap();
2347 peer_a.new_inbound_connection(fd_a.clone(), Some(addr_b.clone())).unwrap();
2348 assert_eq!(peer_a.read_event(&mut fd_a, &initial_data).unwrap(), false);
2349 peer_a.process_events();
2351 let a_data = fd_a.outbound_data.lock().unwrap().split_off(0);
2352 assert_eq!(peer_b.read_event(&mut fd_b, &a_data).unwrap(), false);
2354 peer_b.process_events();
2355 let b_data = fd_b.outbound_data.lock().unwrap().split_off(0);
2356 assert_eq!(peer_a.read_event(&mut fd_a, &b_data).unwrap(), false);
2358 peer_a.process_events();
2359 let a_data = fd_a.outbound_data.lock().unwrap().split_off(0);
2360 assert_eq!(peer_b.read_event(&mut fd_b, &a_data).unwrap(), false);
2362 assert!(peer_a.get_peer_node_ids().contains(&(id_b, Some(addr_b))));
2363 assert!(peer_b.get_peer_node_ids().contains(&(id_a, Some(addr_a))));
2365 (fd_a.clone(), fd_b.clone())
2369 #[cfg(feature = "std")]
2370 fn fuzz_threaded_connections() {
2371 // Spawn two threads which repeatedly connect two peers together, leading to "got second
2372 // connection with peer" disconnections and rapid reconnect. This previously found an issue
2373 // with our internal map consistency, and is a generally good smoke test of disconnection.
2374 let cfgs = Arc::new(create_peermgr_cfgs(2));
2375 // Until we have std::thread::scoped we have to unsafe { turn off the borrow checker }.
2376 let peers = Arc::new(create_network(2, unsafe { &*(&*cfgs as *const _) as &'static _ }));
2378 let start_time = std::time::Instant::now();
2379 macro_rules! spawn_thread { ($id: expr) => { {
2380 let peers = Arc::clone(&peers);
2381 let cfgs = Arc::clone(&cfgs);
2382 std::thread::spawn(move || {
2384 while start_time.elapsed() < std::time::Duration::from_secs(1) {
2385 let id_a = peers[0].node_signer.get_node_id(Recipient::Node).unwrap();
2386 let mut fd_a = FileDescriptor {
2387 fd: $id + ctr * 3, outbound_data: Arc::new(Mutex::new(Vec::new())),
2388 disconnect: Arc::new(AtomicBool::new(false)),
2390 let addr_a = NetAddress::IPv4{addr: [127, 0, 0, 1], port: 1000};
2391 let mut fd_b = FileDescriptor {
2392 fd: $id + ctr * 3, outbound_data: Arc::new(Mutex::new(Vec::new())),
2393 disconnect: Arc::new(AtomicBool::new(false)),
2395 let addr_b = NetAddress::IPv4{addr: [127, 0, 0, 1], port: 1001};
2396 let initial_data = peers[1].new_outbound_connection(id_a, fd_b.clone(), Some(addr_a.clone())).unwrap();
2397 peers[0].new_inbound_connection(fd_a.clone(), Some(addr_b.clone())).unwrap();
2398 if peers[0].read_event(&mut fd_a, &initial_data).is_err() { break; }
2400 while start_time.elapsed() < std::time::Duration::from_secs(1) {
2401 peers[0].process_events();
2402 if fd_a.disconnect.load(Ordering::Acquire) { break; }
2403 let a_data = fd_a.outbound_data.lock().unwrap().split_off(0);
2404 if peers[1].read_event(&mut fd_b, &a_data).is_err() { break; }
2406 peers[1].process_events();
2407 if fd_b.disconnect.load(Ordering::Acquire) { break; }
2408 let b_data = fd_b.outbound_data.lock().unwrap().split_off(0);
2409 if peers[0].read_event(&mut fd_a, &b_data).is_err() { break; }
2411 cfgs[0].chan_handler.pending_events.lock().unwrap()
2412 .push(crate::events::MessageSendEvent::SendShutdown {
2413 node_id: peers[1].node_signer.get_node_id(Recipient::Node).unwrap(),
2414 msg: msgs::Shutdown {
2415 channel_id: [0; 32],
2416 scriptpubkey: bitcoin::Script::new(),
2419 cfgs[1].chan_handler.pending_events.lock().unwrap()
2420 .push(crate::events::MessageSendEvent::SendShutdown {
2421 node_id: peers[0].node_signer.get_node_id(Recipient::Node).unwrap(),
2422 msg: msgs::Shutdown {
2423 channel_id: [0; 32],
2424 scriptpubkey: bitcoin::Script::new(),
2429 peers[0].timer_tick_occurred();
2430 peers[1].timer_tick_occurred();
2434 peers[0].socket_disconnected(&fd_a);
2435 peers[1].socket_disconnected(&fd_b);
2437 std::thread::sleep(std::time::Duration::from_micros(1));
2441 let thrd_a = spawn_thread!(1);
2442 let thrd_b = spawn_thread!(2);
2444 thrd_a.join().unwrap();
2445 thrd_b.join().unwrap();
2449 fn test_disconnect_peer() {
2450 // Simple test which builds a network of PeerManager, connects and brings them to NoiseState::Finished and
2451 // push a DisconnectPeer event to remove the node flagged by id
2452 let cfgs = create_peermgr_cfgs(2);
2453 let peers = create_network(2, &cfgs);
2454 establish_connection(&peers[0], &peers[1]);
2455 assert_eq!(peers[0].peers.read().unwrap().len(), 1);
2457 let their_id = peers[1].node_signer.get_node_id(Recipient::Node).unwrap();
2458 cfgs[0].chan_handler.pending_events.lock().unwrap().push(events::MessageSendEvent::HandleError {
2460 action: msgs::ErrorAction::DisconnectPeer { msg: None },
2463 peers[0].process_events();
2464 assert_eq!(peers[0].peers.read().unwrap().len(), 0);
2468 fn test_send_simple_msg() {
2469 // Simple test which builds a network of PeerManager, connects and brings them to NoiseState::Finished and
2470 // push a message from one peer to another.
2471 let cfgs = create_peermgr_cfgs(2);
2472 let a_chan_handler = test_utils::TestChannelMessageHandler::new();
2473 let b_chan_handler = test_utils::TestChannelMessageHandler::new();
2474 let mut peers = create_network(2, &cfgs);
2475 let (fd_a, mut fd_b) = establish_connection(&peers[0], &peers[1]);
2476 assert_eq!(peers[0].peers.read().unwrap().len(), 1);
2478 let their_id = peers[1].node_signer.get_node_id(Recipient::Node).unwrap();
2480 let msg = msgs::Shutdown { channel_id: [42; 32], scriptpubkey: bitcoin::Script::new() };
2481 a_chan_handler.pending_events.lock().unwrap().push(events::MessageSendEvent::SendShutdown {
2482 node_id: their_id, msg: msg.clone()
2484 peers[0].message_handler.chan_handler = &a_chan_handler;
2486 b_chan_handler.expect_receive_msg(wire::Message::Shutdown(msg));
2487 peers[1].message_handler.chan_handler = &b_chan_handler;
2489 peers[0].process_events();
2491 let a_data = fd_a.outbound_data.lock().unwrap().split_off(0);
2492 assert_eq!(peers[1].read_event(&mut fd_b, &a_data).unwrap(), false);
2496 fn test_non_init_first_msg() {
2497 // Simple test of the first message received over a connection being something other than
2498 // Init. This results in an immediate disconnection, which previously included a spurious
2499 // peer_disconnected event handed to event handlers (which would panic in
2500 // `TestChannelMessageHandler` here).
2501 let cfgs = create_peermgr_cfgs(2);
2502 let peers = create_network(2, &cfgs);
2504 let mut fd_dup = FileDescriptor {
2505 fd: 3, outbound_data: Arc::new(Mutex::new(Vec::new())),
2506 disconnect: Arc::new(AtomicBool::new(false)),
2508 let addr_dup = NetAddress::IPv4{addr: [127, 0, 0, 1], port: 1003};
2509 let id_a = cfgs[0].node_signer.get_node_id(Recipient::Node).unwrap();
2510 peers[0].new_inbound_connection(fd_dup.clone(), Some(addr_dup.clone())).unwrap();
2512 let mut dup_encryptor = PeerChannelEncryptor::new_outbound(id_a, SecretKey::from_slice(&[42; 32]).unwrap());
2513 let initial_data = dup_encryptor.get_act_one(&peers[1].secp_ctx);
2514 assert_eq!(peers[0].read_event(&mut fd_dup, &initial_data).unwrap(), false);
2515 peers[0].process_events();
2517 let a_data = fd_dup.outbound_data.lock().unwrap().split_off(0);
2518 let (act_three, _) =
2519 dup_encryptor.process_act_two(&a_data[..], &&cfgs[1].node_signer).unwrap();
2520 assert_eq!(peers[0].read_event(&mut fd_dup, &act_three).unwrap(), false);
2522 let not_init_msg = msgs::Ping { ponglen: 4, byteslen: 0 };
2523 let msg_bytes = dup_encryptor.encrypt_message(¬_init_msg);
2524 assert!(peers[0].read_event(&mut fd_dup, &msg_bytes).is_err());
2528 fn test_disconnect_all_peer() {
2529 // Simple test which builds a network of PeerManager, connects and brings them to NoiseState::Finished and
2530 // then calls disconnect_all_peers
2531 let cfgs = create_peermgr_cfgs(2);
2532 let peers = create_network(2, &cfgs);
2533 establish_connection(&peers[0], &peers[1]);
2534 assert_eq!(peers[0].peers.read().unwrap().len(), 1);
2536 peers[0].disconnect_all_peers();
2537 assert_eq!(peers[0].peers.read().unwrap().len(), 0);
2541 fn test_timer_tick_occurred() {
2542 // Create peers, a vector of two peer managers, perform initial set up and check that peers[0] has one Peer.
2543 let cfgs = create_peermgr_cfgs(2);
2544 let peers = create_network(2, &cfgs);
2545 establish_connection(&peers[0], &peers[1]);
2546 assert_eq!(peers[0].peers.read().unwrap().len(), 1);
2548 // peers[0] awaiting_pong is set to true, but the Peer is still connected
2549 peers[0].timer_tick_occurred();
2550 peers[0].process_events();
2551 assert_eq!(peers[0].peers.read().unwrap().len(), 1);
2553 // Since timer_tick_occurred() is called again when awaiting_pong is true, all Peers are disconnected
2554 peers[0].timer_tick_occurred();
2555 peers[0].process_events();
2556 assert_eq!(peers[0].peers.read().unwrap().len(), 0);
2560 fn test_do_attempt_write_data() {
2561 // Create 2 peers with custom TestRoutingMessageHandlers and connect them.
2562 let cfgs = create_peermgr_cfgs(2);
2563 cfgs[0].routing_handler.request_full_sync.store(true, Ordering::Release);
2564 cfgs[1].routing_handler.request_full_sync.store(true, Ordering::Release);
2565 let peers = create_network(2, &cfgs);
2567 // By calling establish_connect, we trigger do_attempt_write_data between
2568 // the peers. Previously this function would mistakenly enter an infinite loop
2569 // when there were more channel messages available than could fit into a peer's
2570 // buffer. This issue would now be detected by this test (because we use custom
2571 // RoutingMessageHandlers that intentionally return more channel messages
2572 // than can fit into a peer's buffer).
2573 let (mut fd_a, mut fd_b) = establish_connection(&peers[0], &peers[1]);
2575 // Make each peer to read the messages that the other peer just wrote to them. Note that
2576 // due to the max-message-before-ping limits this may take a few iterations to complete.
2577 for _ in 0..150/super::BUFFER_DRAIN_MSGS_PER_TICK + 1 {
2578 peers[1].process_events();
2579 let a_read_data = fd_b.outbound_data.lock().unwrap().split_off(0);
2580 assert!(!a_read_data.is_empty());
2582 peers[0].read_event(&mut fd_a, &a_read_data).unwrap();
2583 peers[0].process_events();
2585 let b_read_data = fd_a.outbound_data.lock().unwrap().split_off(0);
2586 assert!(!b_read_data.is_empty());
2587 peers[1].read_event(&mut fd_b, &b_read_data).unwrap();
2589 peers[0].process_events();
2590 assert_eq!(fd_a.outbound_data.lock().unwrap().len(), 0, "Until A receives data, it shouldn't send more messages");
2593 // Check that each peer has received the expected number of channel updates and channel
2595 assert_eq!(cfgs[0].routing_handler.chan_upds_recvd.load(Ordering::Acquire), 108);
2596 assert_eq!(cfgs[0].routing_handler.chan_anns_recvd.load(Ordering::Acquire), 54);
2597 assert_eq!(cfgs[1].routing_handler.chan_upds_recvd.load(Ordering::Acquire), 108);
2598 assert_eq!(cfgs[1].routing_handler.chan_anns_recvd.load(Ordering::Acquire), 54);
2602 fn test_handshake_timeout() {
2603 // Tests that we time out a peer still waiting on handshake completion after a full timer
2605 let cfgs = create_peermgr_cfgs(2);
2606 cfgs[0].routing_handler.request_full_sync.store(true, Ordering::Release);
2607 cfgs[1].routing_handler.request_full_sync.store(true, Ordering::Release);
2608 let peers = create_network(2, &cfgs);
2610 let a_id = peers[0].node_signer.get_node_id(Recipient::Node).unwrap();
2611 let mut fd_a = FileDescriptor {
2612 fd: 1, outbound_data: Arc::new(Mutex::new(Vec::new())),
2613 disconnect: Arc::new(AtomicBool::new(false)),
2615 let mut fd_b = FileDescriptor {
2616 fd: 1, outbound_data: Arc::new(Mutex::new(Vec::new())),
2617 disconnect: Arc::new(AtomicBool::new(false)),
2619 let initial_data = peers[1].new_outbound_connection(a_id, fd_b.clone(), None).unwrap();
2620 peers[0].new_inbound_connection(fd_a.clone(), None).unwrap();
2622 // If we get a single timer tick before completion, that's fine
2623 assert_eq!(peers[0].peers.read().unwrap().len(), 1);
2624 peers[0].timer_tick_occurred();
2625 assert_eq!(peers[0].peers.read().unwrap().len(), 1);
2627 assert_eq!(peers[0].read_event(&mut fd_a, &initial_data).unwrap(), false);
2628 peers[0].process_events();
2629 let a_data = fd_a.outbound_data.lock().unwrap().split_off(0);
2630 assert_eq!(peers[1].read_event(&mut fd_b, &a_data).unwrap(), false);
2631 peers[1].process_events();
2633 // ...but if we get a second timer tick, we should disconnect the peer
2634 peers[0].timer_tick_occurred();
2635 assert_eq!(peers[0].peers.read().unwrap().len(), 0);
2637 let b_data = fd_b.outbound_data.lock().unwrap().split_off(0);
2638 assert!(peers[0].read_event(&mut fd_a, &b_data).is_err());
2642 fn test_filter_addresses(){
2643 // Tests the filter_addresses function.
2646 let ip_address = NetAddress::IPv4{addr: [10, 0, 0, 0], port: 1000};
2647 assert_eq!(filter_addresses(Some(ip_address.clone())), None);
2648 let ip_address = NetAddress::IPv4{addr: [10, 0, 255, 201], port: 1000};
2649 assert_eq!(filter_addresses(Some(ip_address.clone())), None);
2650 let ip_address = NetAddress::IPv4{addr: [10, 255, 255, 255], port: 1000};
2651 assert_eq!(filter_addresses(Some(ip_address.clone())), None);
2654 let ip_address = NetAddress::IPv4{addr: [0, 0, 0, 0], port: 1000};
2655 assert_eq!(filter_addresses(Some(ip_address.clone())), None);
2656 let ip_address = NetAddress::IPv4{addr: [0, 0, 255, 187], port: 1000};
2657 assert_eq!(filter_addresses(Some(ip_address.clone())), None);
2658 let ip_address = NetAddress::IPv4{addr: [0, 255, 255, 255], port: 1000};
2659 assert_eq!(filter_addresses(Some(ip_address.clone())), None);
2662 let ip_address = NetAddress::IPv4{addr: [100, 64, 0, 0], port: 1000};
2663 assert_eq!(filter_addresses(Some(ip_address.clone())), None);
2664 let ip_address = NetAddress::IPv4{addr: [100, 78, 255, 0], port: 1000};
2665 assert_eq!(filter_addresses(Some(ip_address.clone())), None);
2666 let ip_address = NetAddress::IPv4{addr: [100, 127, 255, 255], port: 1000};
2667 assert_eq!(filter_addresses(Some(ip_address.clone())), None);
2670 let ip_address = NetAddress::IPv4{addr: [127, 0, 0, 0], port: 1000};
2671 assert_eq!(filter_addresses(Some(ip_address.clone())), None);
2672 let ip_address = NetAddress::IPv4{addr: [127, 65, 73, 0], port: 1000};
2673 assert_eq!(filter_addresses(Some(ip_address.clone())), None);
2674 let ip_address = NetAddress::IPv4{addr: [127, 255, 255, 255], port: 1000};
2675 assert_eq!(filter_addresses(Some(ip_address.clone())), None);
2678 let ip_address = NetAddress::IPv4{addr: [169, 254, 0, 0], port: 1000};
2679 assert_eq!(filter_addresses(Some(ip_address.clone())), None);
2680 let ip_address = NetAddress::IPv4{addr: [169, 254, 221, 101], port: 1000};
2681 assert_eq!(filter_addresses(Some(ip_address.clone())), None);
2682 let ip_address = NetAddress::IPv4{addr: [169, 254, 255, 255], port: 1000};
2683 assert_eq!(filter_addresses(Some(ip_address.clone())), None);
2686 let ip_address = NetAddress::IPv4{addr: [172, 16, 0, 0], port: 1000};
2687 assert_eq!(filter_addresses(Some(ip_address.clone())), None);
2688 let ip_address = NetAddress::IPv4{addr: [172, 27, 101, 23], port: 1000};
2689 assert_eq!(filter_addresses(Some(ip_address.clone())), None);
2690 let ip_address = NetAddress::IPv4{addr: [172, 31, 255, 255], port: 1000};
2691 assert_eq!(filter_addresses(Some(ip_address.clone())), None);
2694 let ip_address = NetAddress::IPv4{addr: [192, 168, 0, 0], port: 1000};
2695 assert_eq!(filter_addresses(Some(ip_address.clone())), None);
2696 let ip_address = NetAddress::IPv4{addr: [192, 168, 205, 159], port: 1000};
2697 assert_eq!(filter_addresses(Some(ip_address.clone())), None);
2698 let ip_address = NetAddress::IPv4{addr: [192, 168, 255, 255], port: 1000};
2699 assert_eq!(filter_addresses(Some(ip_address.clone())), None);
2701 // For (192.88.99/24)
2702 let ip_address = NetAddress::IPv4{addr: [192, 88, 99, 0], port: 1000};
2703 assert_eq!(filter_addresses(Some(ip_address.clone())), None);
2704 let ip_address = NetAddress::IPv4{addr: [192, 88, 99, 140], port: 1000};
2705 assert_eq!(filter_addresses(Some(ip_address.clone())), None);
2706 let ip_address = NetAddress::IPv4{addr: [192, 88, 99, 255], port: 1000};
2707 assert_eq!(filter_addresses(Some(ip_address.clone())), None);
2709 // For other IPv4 addresses
2710 let ip_address = NetAddress::IPv4{addr: [188, 255, 99, 0], port: 1000};
2711 assert_eq!(filter_addresses(Some(ip_address.clone())), Some(ip_address.clone()));
2712 let ip_address = NetAddress::IPv4{addr: [123, 8, 129, 14], port: 1000};
2713 assert_eq!(filter_addresses(Some(ip_address.clone())), Some(ip_address.clone()));
2714 let ip_address = NetAddress::IPv4{addr: [2, 88, 9, 255], port: 1000};
2715 assert_eq!(filter_addresses(Some(ip_address.clone())), Some(ip_address.clone()));
2718 let ip_address = NetAddress::IPv6{addr: [32, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0], port: 1000};
2719 assert_eq!(filter_addresses(Some(ip_address.clone())), Some(ip_address.clone()));
2720 let ip_address = NetAddress::IPv6{addr: [45, 34, 209, 190, 0, 123, 55, 34, 0, 0, 3, 27, 201, 0, 0, 0], port: 1000};
2721 assert_eq!(filter_addresses(Some(ip_address.clone())), Some(ip_address.clone()));
2722 let ip_address = NetAddress::IPv6{addr: [63, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255, 255], port: 1000};
2723 assert_eq!(filter_addresses(Some(ip_address.clone())), Some(ip_address.clone()));
2725 // For other IPv6 addresses
2726 let ip_address = NetAddress::IPv6{addr: [24, 240, 12, 32, 0, 0, 0, 0, 20, 97, 0, 32, 121, 254, 0, 0], port: 1000};
2727 assert_eq!(filter_addresses(Some(ip_address.clone())), None);
2728 let ip_address = NetAddress::IPv6{addr: [68, 23, 56, 63, 0, 0, 2, 7, 75, 109, 0, 39, 0, 0, 0, 0], port: 1000};
2729 assert_eq!(filter_addresses(Some(ip_address.clone())), None);
2730 let ip_address = NetAddress::IPv6{addr: [101, 38, 140, 230, 100, 0, 30, 98, 0, 26, 0, 0, 57, 96, 0, 0], port: 1000};
2731 assert_eq!(filter_addresses(Some(ip_address.clone())), None);
2734 assert_eq!(filter_addresses(None), None);