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 //! The top-level channel management and payment tracking stuff lives here.
12 //! The [`ChannelManager`] is the main chunk of logic implementing the lightning protocol and is
13 //! responsible for tracking which channels are open, HTLCs are in flight and reestablishing those
14 //! upon reconnect to the relevant peer(s).
16 //! It does not manage routing logic (see [`Router`] for that) nor does it manage constructing
17 //! on-chain transactions (it only monitors the chain to watch for any force-closes that might
18 //! imply it needs to fail HTLCs/payments/channels it manages).
20 use bitcoin::blockdata::block::BlockHeader;
21 use bitcoin::blockdata::transaction::Transaction;
22 use bitcoin::blockdata::constants::genesis_block;
23 use bitcoin::network::constants::Network;
25 use bitcoin::hashes::Hash;
26 use bitcoin::hashes::sha256::Hash as Sha256;
27 use bitcoin::hash_types::{BlockHash, Txid};
29 use bitcoin::secp256k1::{SecretKey,PublicKey};
30 use bitcoin::secp256k1::Secp256k1;
31 use bitcoin::{LockTime, secp256k1, Sequence};
34 use crate::chain::{Confirm, ChannelMonitorUpdateStatus, Watch, BestBlock};
35 use crate::chain::chaininterface::{BroadcasterInterface, ConfirmationTarget, FeeEstimator, LowerBoundedFeeEstimator};
36 use crate::chain::channelmonitor::{ChannelMonitor, ChannelMonitorUpdate, ChannelMonitorUpdateStep, HTLC_FAIL_BACK_BUFFER, CLTV_CLAIM_BUFFER, LATENCY_GRACE_PERIOD_BLOCKS, ANTI_REORG_DELAY, MonitorEvent, CLOSED_CHANNEL_UPDATE_ID};
37 use crate::chain::transaction::{OutPoint, TransactionData};
39 use crate::events::{Event, EventHandler, EventsProvider, MessageSendEvent, MessageSendEventsProvider, ClosureReason, HTLCDestination};
40 // Since this struct is returned in `list_channels` methods, expose it here in case users want to
41 // construct one themselves.
42 use crate::ln::{inbound_payment, PaymentHash, PaymentPreimage, PaymentSecret};
43 use crate::ln::channel::{Channel, ChannelError, ChannelUpdateStatus, UpdateFulfillCommitFetch};
44 use crate::ln::features::{ChannelFeatures, ChannelTypeFeatures, InitFeatures, NodeFeatures};
45 #[cfg(any(feature = "_test_utils", test))]
46 use crate::ln::features::InvoiceFeatures;
47 use crate::routing::gossip::NetworkGraph;
48 use crate::routing::router::{DefaultRouter, InFlightHtlcs, PaymentParameters, Route, RouteHop, RouteParameters, RoutePath, Router};
49 use crate::routing::scoring::ProbabilisticScorer;
51 use crate::ln::onion_utils;
52 use crate::ln::onion_utils::HTLCFailReason;
53 use crate::ln::msgs::{ChannelMessageHandler, DecodeError, LightningError, MAX_VALUE_MSAT};
55 use crate::ln::outbound_payment;
56 use crate::ln::outbound_payment::{OutboundPayments, PaymentAttempts, PendingOutboundPayment};
57 use crate::ln::wire::Encode;
58 use crate::chain::keysinterface::{EntropySource, KeysManager, NodeSigner, Recipient, SignerProvider, ChannelSigner, WriteableEcdsaChannelSigner};
59 use crate::util::config::{UserConfig, ChannelConfig};
60 use crate::util::wakers::{Future, Notifier};
61 use crate::util::scid_utils::fake_scid;
62 use crate::util::string::UntrustedString;
63 use crate::util::ser::{BigSize, FixedLengthReader, Readable, ReadableArgs, MaybeReadable, Writeable, Writer, VecWriter};
64 use crate::util::logger::{Level, Logger};
65 use crate::util::errors::APIError;
67 use alloc::collections::BTreeMap;
70 use crate::prelude::*;
72 use core::cell::RefCell;
74 use crate::sync::{Arc, Mutex, RwLock, RwLockReadGuard, FairRwLock, LockTestExt, LockHeldState};
75 use core::sync::atomic::{AtomicUsize, Ordering};
76 use core::time::Duration;
79 // Re-export this for use in the public API.
80 pub use crate::ln::outbound_payment::{PaymentSendFailure, Retry, RetryableSendFailure};
82 // We hold various information about HTLC relay in the HTLC objects in Channel itself:
84 // Upon receipt of an HTLC from a peer, we'll give it a PendingHTLCStatus indicating if it should
85 // forward the HTLC with information it will give back to us when it does so, or if it should Fail
86 // the HTLC with the relevant message for the Channel to handle giving to the remote peer.
88 // Once said HTLC is committed in the Channel, if the PendingHTLCStatus indicated Forward, the
89 // Channel will return the PendingHTLCInfo back to us, and we will create an HTLCForwardInfo
90 // with it to track where it came from (in case of onwards-forward error), waiting a random delay
91 // before we forward it.
93 // We will then use HTLCForwardInfo's PendingHTLCInfo to construct an outbound HTLC, with a
94 // relevant HTLCSource::PreviousHopData filled in to indicate where it came from (which we can use
95 // to either fail-backwards or fulfill the HTLC backwards along the relevant path).
96 // Alternatively, we can fill an outbound HTLC with a HTLCSource::OutboundRoute indicating this is
97 // our payment, which we can use to decode errors or inform the user that the payment was sent.
99 #[derive(Clone)] // See Channel::revoke_and_ack for why, tl;dr: Rust bug
100 pub(super) enum PendingHTLCRouting {
102 onion_packet: msgs::OnionPacket,
103 /// The SCID from the onion that we should forward to. This could be a real SCID or a fake one
104 /// generated using `get_fake_scid` from the scid_utils::fake_scid module.
105 short_channel_id: u64, // This should be NonZero<u64> eventually when we bump MSRV
108 payment_data: msgs::FinalOnionHopData,
109 incoming_cltv_expiry: u32, // Used to track when we should expire pending HTLCs that go unclaimed
110 phantom_shared_secret: Option<[u8; 32]>,
113 payment_preimage: PaymentPreimage,
114 incoming_cltv_expiry: u32, // Used to track when we should expire pending HTLCs that go unclaimed
118 #[derive(Clone)] // See Channel::revoke_and_ack for why, tl;dr: Rust bug
119 pub(super) struct PendingHTLCInfo {
120 pub(super) routing: PendingHTLCRouting,
121 pub(super) incoming_shared_secret: [u8; 32],
122 payment_hash: PaymentHash,
123 pub(super) incoming_amt_msat: Option<u64>, // Added in 0.0.113
124 pub(super) outgoing_amt_msat: u64,
125 pub(super) outgoing_cltv_value: u32,
128 #[derive(Clone)] // See Channel::revoke_and_ack for why, tl;dr: Rust bug
129 pub(super) enum HTLCFailureMsg {
130 Relay(msgs::UpdateFailHTLC),
131 Malformed(msgs::UpdateFailMalformedHTLC),
134 /// Stores whether we can't forward an HTLC or relevant forwarding info
135 #[derive(Clone)] // See Channel::revoke_and_ack for why, tl;dr: Rust bug
136 pub(super) enum PendingHTLCStatus {
137 Forward(PendingHTLCInfo),
138 Fail(HTLCFailureMsg),
141 pub(super) struct PendingAddHTLCInfo {
142 pub(super) forward_info: PendingHTLCInfo,
144 // These fields are produced in `forward_htlcs()` and consumed in
145 // `process_pending_htlc_forwards()` for constructing the
146 // `HTLCSource::PreviousHopData` for failed and forwarded
149 // Note that this may be an outbound SCID alias for the associated channel.
150 prev_short_channel_id: u64,
152 prev_funding_outpoint: OutPoint,
153 prev_user_channel_id: u128,
156 pub(super) enum HTLCForwardInfo {
157 AddHTLC(PendingAddHTLCInfo),
160 err_packet: msgs::OnionErrorPacket,
164 /// Tracks the inbound corresponding to an outbound HTLC
165 #[derive(Clone, Hash, PartialEq, Eq)]
166 pub(crate) struct HTLCPreviousHopData {
167 // Note that this may be an outbound SCID alias for the associated channel.
168 short_channel_id: u64,
170 incoming_packet_shared_secret: [u8; 32],
171 phantom_shared_secret: Option<[u8; 32]>,
173 // This field is consumed by `claim_funds_from_hop()` when updating a force-closed backwards
174 // channel with a preimage provided by the forward channel.
179 /// Indicates this incoming onion payload is for the purpose of paying an invoice.
181 /// This is only here for backwards-compatibility in serialization, in the future it can be
182 /// removed, breaking clients running 0.0.106 and earlier.
183 _legacy_hop_data: Option<msgs::FinalOnionHopData>,
185 /// Contains the payer-provided preimage.
186 Spontaneous(PaymentPreimage),
189 /// HTLCs that are to us and can be failed/claimed by the user
190 struct ClaimableHTLC {
191 prev_hop: HTLCPreviousHopData,
193 /// The amount (in msats) of this MPP part
195 onion_payload: OnionPayload,
197 /// The total value received for a payment (sum of all MPP parts if the payment is a MPP).
198 /// Gets set to the amount reported when pushing [`Event::PaymentClaimable`].
199 total_value_received: Option<u64>,
200 /// The sender intended sum total of all MPP parts specified in the onion
204 /// A payment identifier used to uniquely identify a payment to LDK.
206 /// This is not exported to bindings users as we just use [u8; 32] directly
207 #[derive(Hash, Copy, Clone, PartialEq, Eq, Debug)]
208 pub struct PaymentId(pub [u8; 32]);
210 impl Writeable for PaymentId {
211 fn write<W: Writer>(&self, w: &mut W) -> Result<(), io::Error> {
216 impl Readable for PaymentId {
217 fn read<R: Read>(r: &mut R) -> Result<Self, DecodeError> {
218 let buf: [u8; 32] = Readable::read(r)?;
223 /// An identifier used to uniquely identify an intercepted HTLC to LDK.
225 /// This is not exported to bindings users as we just use [u8; 32] directly
226 #[derive(Hash, Copy, Clone, PartialEq, Eq, Debug)]
227 pub struct InterceptId(pub [u8; 32]);
229 impl Writeable for InterceptId {
230 fn write<W: Writer>(&self, w: &mut W) -> Result<(), io::Error> {
235 impl Readable for InterceptId {
236 fn read<R: Read>(r: &mut R) -> Result<Self, DecodeError> {
237 let buf: [u8; 32] = Readable::read(r)?;
242 #[derive(Clone, Copy, PartialEq, Eq, Hash)]
243 /// Uniquely describes an HTLC by its source. Just the guaranteed-unique subset of [`HTLCSource`].
244 pub(crate) enum SentHTLCId {
245 PreviousHopData { short_channel_id: u64, htlc_id: u64 },
246 OutboundRoute { session_priv: SecretKey },
249 pub(crate) fn from_source(source: &HTLCSource) -> Self {
251 HTLCSource::PreviousHopData(hop_data) => Self::PreviousHopData {
252 short_channel_id: hop_data.short_channel_id,
253 htlc_id: hop_data.htlc_id,
255 HTLCSource::OutboundRoute { session_priv, .. } =>
256 Self::OutboundRoute { session_priv: *session_priv },
260 impl_writeable_tlv_based_enum!(SentHTLCId,
261 (0, PreviousHopData) => {
262 (0, short_channel_id, required),
263 (2, htlc_id, required),
265 (2, OutboundRoute) => {
266 (0, session_priv, required),
271 /// Tracks the inbound corresponding to an outbound HTLC
272 #[allow(clippy::derive_hash_xor_eq)] // Our Hash is faithful to the data, we just don't have SecretKey::hash
273 #[derive(Clone, PartialEq, Eq)]
274 pub(crate) enum HTLCSource {
275 PreviousHopData(HTLCPreviousHopData),
278 session_priv: SecretKey,
279 /// Technically we can recalculate this from the route, but we cache it here to avoid
280 /// doing a double-pass on route when we get a failure back
281 first_hop_htlc_msat: u64,
282 payment_id: PaymentId,
283 payment_secret: Option<PaymentSecret>,
286 #[allow(clippy::derive_hash_xor_eq)] // Our Hash is faithful to the data, we just don't have SecretKey::hash
287 impl core::hash::Hash for HTLCSource {
288 fn hash<H: core::hash::Hasher>(&self, hasher: &mut H) {
290 HTLCSource::PreviousHopData(prev_hop_data) => {
292 prev_hop_data.hash(hasher);
294 HTLCSource::OutboundRoute { path, session_priv, payment_id, payment_secret, first_hop_htlc_msat } => {
297 session_priv[..].hash(hasher);
298 payment_id.hash(hasher);
299 payment_secret.hash(hasher);
300 first_hop_htlc_msat.hash(hasher);
305 #[cfg(not(feature = "grind_signatures"))]
308 pub fn dummy() -> Self {
309 HTLCSource::OutboundRoute {
311 session_priv: SecretKey::from_slice(&[1; 32]).unwrap(),
312 first_hop_htlc_msat: 0,
313 payment_id: PaymentId([2; 32]),
314 payment_secret: None,
319 struct ReceiveError {
325 /// This enum is used to specify which error data to send to peers when failing back an HTLC
326 /// using [`ChannelManager::fail_htlc_backwards_with_reason`].
328 /// For more info on failure codes, see <https://github.com/lightning/bolts/blob/master/04-onion-routing.md#failure-messages>.
329 #[derive(Clone, Copy)]
330 pub enum FailureCode {
331 /// We had a temporary error processing the payment. Useful if no other error codes fit
332 /// and you want to indicate that the payer may want to retry.
333 TemporaryNodeFailure = 0x2000 | 2,
334 /// We have a required feature which was not in this onion. For example, you may require
335 /// some additional metadata that was not provided with this payment.
336 RequiredNodeFeatureMissing = 0x4000 | 0x2000 | 3,
337 /// You may wish to use this when a `payment_preimage` is unknown, or the CLTV expiry of
338 /// the HTLC is too close to the current block height for safe handling.
339 /// Using this failure code in [`ChannelManager::fail_htlc_backwards_with_reason`] is
340 /// equivalent to calling [`ChannelManager::fail_htlc_backwards`].
341 IncorrectOrUnknownPaymentDetails = 0x4000 | 15,
344 type ShutdownResult = (Option<(OutPoint, ChannelMonitorUpdate)>, Vec<(HTLCSource, PaymentHash, PublicKey, [u8; 32])>);
346 /// Error type returned across the peer_state mutex boundary. When an Err is generated for a
347 /// Channel, we generally end up with a ChannelError::Close for which we have to close the channel
348 /// immediately (ie with no further calls on it made). Thus, this step happens inside a
349 /// peer_state lock. We then return the set of things that need to be done outside the lock in
350 /// this struct and call handle_error!() on it.
352 struct MsgHandleErrInternal {
353 err: msgs::LightningError,
354 chan_id: Option<([u8; 32], u128)>, // If Some a channel of ours has been closed
355 shutdown_finish: Option<(ShutdownResult, Option<msgs::ChannelUpdate>)>,
357 impl MsgHandleErrInternal {
359 fn send_err_msg_no_close(err: String, channel_id: [u8; 32]) -> Self {
361 err: LightningError {
363 action: msgs::ErrorAction::SendErrorMessage {
364 msg: msgs::ErrorMessage {
371 shutdown_finish: None,
375 fn from_no_close(err: msgs::LightningError) -> Self {
376 Self { err, chan_id: None, shutdown_finish: None }
379 fn from_finish_shutdown(err: String, channel_id: [u8; 32], user_channel_id: u128, shutdown_res: ShutdownResult, channel_update: Option<msgs::ChannelUpdate>) -> Self {
381 err: LightningError {
383 action: msgs::ErrorAction::SendErrorMessage {
384 msg: msgs::ErrorMessage {
390 chan_id: Some((channel_id, user_channel_id)),
391 shutdown_finish: Some((shutdown_res, channel_update)),
395 fn from_chan_no_close(err: ChannelError, channel_id: [u8; 32]) -> Self {
398 ChannelError::Warn(msg) => LightningError {
400 action: msgs::ErrorAction::SendWarningMessage {
401 msg: msgs::WarningMessage {
405 log_level: Level::Warn,
408 ChannelError::Ignore(msg) => LightningError {
410 action: msgs::ErrorAction::IgnoreError,
412 ChannelError::Close(msg) => LightningError {
414 action: msgs::ErrorAction::SendErrorMessage {
415 msg: msgs::ErrorMessage {
423 shutdown_finish: None,
428 /// We hold back HTLCs we intend to relay for a random interval greater than this (see
429 /// Event::PendingHTLCsForwardable for the API guidelines indicating how long should be waited).
430 /// This provides some limited amount of privacy. Ideally this would range from somewhere like one
431 /// second to 30 seconds, but people expect lightning to be, you know, kinda fast, sadly.
432 pub(super) const MIN_HTLC_RELAY_HOLDING_CELL_MILLIS: u64 = 100;
434 /// For events which result in both a RevokeAndACK and a CommitmentUpdate, by default they should
435 /// be sent in the order they appear in the return value, however sometimes the order needs to be
436 /// variable at runtime (eg Channel::channel_reestablish needs to re-send messages in the order
437 /// they were originally sent). In those cases, this enum is also returned.
438 #[derive(Clone, PartialEq)]
439 pub(super) enum RAACommitmentOrder {
440 /// Send the CommitmentUpdate messages first
442 /// Send the RevokeAndACK message first
446 /// Information about a payment which is currently being claimed.
447 struct ClaimingPayment {
449 payment_purpose: events::PaymentPurpose,
450 receiver_node_id: PublicKey,
452 impl_writeable_tlv_based!(ClaimingPayment, {
453 (0, amount_msat, required),
454 (2, payment_purpose, required),
455 (4, receiver_node_id, required),
458 /// Information about claimable or being-claimed payments
459 struct ClaimablePayments {
460 /// Map from payment hash to the payment data and any HTLCs which are to us and can be
461 /// failed/claimed by the user.
463 /// Note that, no consistency guarantees are made about the channels given here actually
464 /// existing anymore by the time you go to read them!
466 /// When adding to the map, [`Self::pending_claiming_payments`] must also be checked to ensure
467 /// we don't get a duplicate payment.
468 claimable_htlcs: HashMap<PaymentHash, (events::PaymentPurpose, Vec<ClaimableHTLC>)>,
470 /// Map from payment hash to the payment data for HTLCs which we have begun claiming, but which
471 /// are waiting on a [`ChannelMonitorUpdate`] to complete in order to be surfaced to the user
472 /// as an [`events::Event::PaymentClaimed`].
473 pending_claiming_payments: HashMap<PaymentHash, ClaimingPayment>,
476 /// Events which we process internally but cannot be procsesed immediately at the generation site
477 /// for some reason. They are handled in timer_tick_occurred, so may be processed with
478 /// quite some time lag.
479 enum BackgroundEvent {
480 /// Handle a ChannelMonitorUpdate that closes a channel, broadcasting its current latest holder
481 /// commitment transaction.
482 ClosingMonitorUpdate((OutPoint, ChannelMonitorUpdate)),
486 pub(crate) enum MonitorUpdateCompletionAction {
487 /// Indicates that a payment ultimately destined for us was claimed and we should emit an
488 /// [`events::Event::PaymentClaimed`] to the user if we haven't yet generated such an event for
489 /// this payment. Note that this is only best-effort. On restart it's possible such a duplicate
490 /// event can be generated.
491 PaymentClaimed { payment_hash: PaymentHash },
492 /// Indicates an [`events::Event`] should be surfaced to the user.
493 EmitEvent { event: events::Event },
496 impl_writeable_tlv_based_enum_upgradable!(MonitorUpdateCompletionAction,
497 (0, PaymentClaimed) => { (0, payment_hash, required) },
498 (2, EmitEvent) => { (0, event, upgradable_required) },
501 /// State we hold per-peer.
502 pub(super) struct PeerState<Signer: ChannelSigner> {
503 /// `temporary_channel_id` or `channel_id` -> `channel`.
505 /// Holds all channels where the peer is the counterparty. Once a channel has been assigned a
506 /// `channel_id`, the `temporary_channel_id` key in the map is updated and is replaced by the
508 pub(super) channel_by_id: HashMap<[u8; 32], Channel<Signer>>,
509 /// The latest `InitFeatures` we heard from the peer.
510 latest_features: InitFeatures,
511 /// Messages to send to the peer - pushed to in the same lock that they are generated in (except
512 /// for broadcast messages, where ordering isn't as strict).
513 pub(super) pending_msg_events: Vec<MessageSendEvent>,
514 /// Map from a specific channel to some action(s) that should be taken when all pending
515 /// [`ChannelMonitorUpdate`]s for the channel complete updating.
517 /// Note that because we generally only have one entry here a HashMap is pretty overkill. A
518 /// BTreeMap currently stores more than ten elements per leaf node, so even up to a few
519 /// channels with a peer this will just be one allocation and will amount to a linear list of
520 /// channels to walk, avoiding the whole hashing rigmarole.
522 /// Note that the channel may no longer exist. For example, if a channel was closed but we
523 /// later needed to claim an HTLC which is pending on-chain, we may generate a monitor update
524 /// for a missing channel. While a malicious peer could construct a second channel with the
525 /// same `temporary_channel_id` (or final `channel_id` in the case of 0conf channels or prior
526 /// to funding appearing on-chain), the downstream `ChannelMonitor` set is required to ensure
527 /// duplicates do not occur, so such channels should fail without a monitor update completing.
528 monitor_update_blocked_actions: BTreeMap<[u8; 32], Vec<MonitorUpdateCompletionAction>>,
529 /// The peer is currently connected (i.e. we've seen a
530 /// [`ChannelMessageHandler::peer_connected`] and no corresponding
531 /// [`ChannelMessageHandler::peer_disconnected`].
535 impl <Signer: ChannelSigner> PeerState<Signer> {
536 /// Indicates that a peer meets the criteria where we're ok to remove it from our storage.
537 /// If true is passed for `require_disconnected`, the function will return false if we haven't
538 /// disconnected from the node already, ie. `PeerState::is_connected` is set to `true`.
539 fn ok_to_remove(&self, require_disconnected: bool) -> bool {
540 if require_disconnected && self.is_connected {
543 self.channel_by_id.is_empty() && self.monitor_update_blocked_actions.is_empty()
547 /// Stores a PaymentSecret and any other data we may need to validate an inbound payment is
548 /// actually ours and not some duplicate HTLC sent to us by a node along the route.
550 /// For users who don't want to bother doing their own payment preimage storage, we also store that
553 /// Note that this struct will be removed entirely soon, in favor of storing no inbound payment data
554 /// and instead encoding it in the payment secret.
555 struct PendingInboundPayment {
556 /// The payment secret that the sender must use for us to accept this payment
557 payment_secret: PaymentSecret,
558 /// Time at which this HTLC expires - blocks with a header time above this value will result in
559 /// this payment being removed.
561 /// Arbitrary identifier the user specifies (or not)
562 user_payment_id: u64,
563 // Other required attributes of the payment, optionally enforced:
564 payment_preimage: Option<PaymentPreimage>,
565 min_value_msat: Option<u64>,
568 /// [`SimpleArcChannelManager`] is useful when you need a [`ChannelManager`] with a static lifetime, e.g.
569 /// when you're using `lightning-net-tokio` (since `tokio::spawn` requires parameters with static
570 /// lifetimes). Other times you can afford a reference, which is more efficient, in which case
571 /// [`SimpleRefChannelManager`] is the more appropriate type. Defining these type aliases prevents
572 /// issues such as overly long function definitions. Note that the `ChannelManager` can take any type
573 /// that implements [`NodeSigner`], [`EntropySource`], and [`SignerProvider`] for its keys manager,
574 /// or, respectively, [`Router`] for its router, but this type alias chooses the concrete types
575 /// of [`KeysManager`] and [`DefaultRouter`].
577 /// This is not exported to bindings users as Arcs don't make sense in bindings
578 pub type SimpleArcChannelManager<M, T, F, L> = ChannelManager<
586 Arc<NetworkGraph<Arc<L>>>,
588 Arc<Mutex<ProbabilisticScorer<Arc<NetworkGraph<Arc<L>>>, Arc<L>>>>
593 /// [`SimpleRefChannelManager`] is a type alias for a ChannelManager reference, and is the reference
594 /// counterpart to the [`SimpleArcChannelManager`] type alias. Use this type by default when you don't
595 /// need a ChannelManager with a static lifetime. You'll need a static lifetime in cases such as
596 /// usage of lightning-net-tokio (since `tokio::spawn` requires parameters with static lifetimes).
597 /// But if this is not necessary, using a reference is more efficient. Defining these type aliases
598 /// issues such as overly long function definitions. Note that the ChannelManager can take any type
599 /// that implements [`NodeSigner`], [`EntropySource`], and [`SignerProvider`] for its keys manager,
600 /// or, respectively, [`Router`] for its router, but this type alias chooses the concrete types
601 /// of [`KeysManager`] and [`DefaultRouter`].
603 /// This is not exported to bindings users as Arcs don't make sense in bindings
604 pub type SimpleRefChannelManager<'a, 'b, 'c, 'd, 'e, 'f, 'g, 'h, M, T, F, L> = ChannelManager<&'a M, &'b T, &'c KeysManager, &'c KeysManager, &'c KeysManager, &'d F, &'e DefaultRouter<&'f NetworkGraph<&'g L>, &'g L, &'h Mutex<ProbabilisticScorer<&'f NetworkGraph<&'g L>, &'g L>>>, &'g L>;
606 /// Manager which keeps track of a number of channels and sends messages to the appropriate
607 /// channel, also tracking HTLC preimages and forwarding onion packets appropriately.
609 /// Implements [`ChannelMessageHandler`], handling the multi-channel parts and passing things through
610 /// to individual Channels.
612 /// Implements [`Writeable`] to write out all channel state to disk. Implies [`peer_disconnected`] for
613 /// all peers during write/read (though does not modify this instance, only the instance being
614 /// serialized). This will result in any channels which have not yet exchanged [`funding_created`] (i.e.,
615 /// called [`funding_transaction_generated`] for outbound channels) being closed.
617 /// Note that you can be a bit lazier about writing out `ChannelManager` than you can be with
618 /// [`ChannelMonitor`]. With [`ChannelMonitor`] you MUST write each monitor update out to disk before
619 /// returning from [`chain::Watch::watch_channel`]/[`update_channel`], with ChannelManagers, writing updates
620 /// happens out-of-band (and will prevent any other `ChannelManager` operations from occurring during
621 /// the serialization process). If the deserialized version is out-of-date compared to the
622 /// [`ChannelMonitor`] passed by reference to [`read`], those channels will be force-closed based on the
623 /// `ChannelMonitor` state and no funds will be lost (mod on-chain transaction fees).
625 /// Note that the deserializer is only implemented for `(`[`BlockHash`]`, `[`ChannelManager`]`)`, which
626 /// tells you the last block hash which was connected. You should get the best block tip before using the manager.
627 /// See [`chain::Listen`] and [`chain::Confirm`] for more details.
629 /// Note that `ChannelManager` is responsible for tracking liveness of its channels and generating
630 /// [`ChannelUpdate`] messages informing peers that the channel is temporarily disabled. To avoid
631 /// spam due to quick disconnection/reconnection, updates are not sent until the channel has been
632 /// offline for a full minute. In order to track this, you must call
633 /// [`timer_tick_occurred`] roughly once per minute, though it doesn't have to be perfect.
635 /// To avoid trivial DoS issues, `ChannelManager` limits the number of inbound connections and
636 /// inbound channels without confirmed funding transactions. This may result in nodes which we do
637 /// not have a channel with being unable to connect to us or open new channels with us if we have
638 /// many peers with unfunded channels.
640 /// Because it is an indication of trust, inbound channels which we've accepted as 0conf are
641 /// exempted from the count of unfunded channels. Similarly, outbound channels and connections are
642 /// never limited. Please ensure you limit the count of such channels yourself.
644 /// Rather than using a plain `ChannelManager`, it is preferable to use either a [`SimpleArcChannelManager`]
645 /// a [`SimpleRefChannelManager`], for conciseness. See their documentation for more details, but
646 /// essentially you should default to using a [`SimpleRefChannelManager`], and use a
647 /// [`SimpleArcChannelManager`] when you require a `ChannelManager` with a static lifetime, such as when
648 /// you're using lightning-net-tokio.
650 /// [`peer_disconnected`]: msgs::ChannelMessageHandler::peer_disconnected
651 /// [`funding_created`]: msgs::FundingCreated
652 /// [`funding_transaction_generated`]: Self::funding_transaction_generated
653 /// [`BlockHash`]: bitcoin::hash_types::BlockHash
654 /// [`update_channel`]: chain::Watch::update_channel
655 /// [`ChannelUpdate`]: msgs::ChannelUpdate
656 /// [`timer_tick_occurred`]: Self::timer_tick_occurred
657 /// [`read`]: ReadableArgs::read
660 // The tree structure below illustrates the lock order requirements for the different locks of the
661 // `ChannelManager`. Locks can be held at the same time if they are on the same branch in the tree,
662 // and should then be taken in the order of the lowest to the highest level in the tree.
663 // Note that locks on different branches shall not be taken at the same time, as doing so will
664 // create a new lock order for those specific locks in the order they were taken.
668 // `total_consistency_lock`
670 // |__`forward_htlcs`
672 // | |__`pending_intercepted_htlcs`
674 // |__`per_peer_state`
676 // | |__`pending_inbound_payments`
678 // | |__`claimable_payments`
680 // | |__`pending_outbound_payments` // This field's struct contains a map of pending outbounds
686 // | |__`short_to_chan_info`
688 // | |__`outbound_scid_aliases`
692 // | |__`pending_events`
694 // | |__`pending_background_events`
696 pub struct ChannelManager<M: Deref, T: Deref, ES: Deref, NS: Deref, SP: Deref, F: Deref, R: Deref, L: Deref>
698 M::Target: chain::Watch<<SP::Target as SignerProvider>::Signer>,
699 T::Target: BroadcasterInterface,
700 ES::Target: EntropySource,
701 NS::Target: NodeSigner,
702 SP::Target: SignerProvider,
703 F::Target: FeeEstimator,
707 default_configuration: UserConfig,
708 genesis_hash: BlockHash,
709 fee_estimator: LowerBoundedFeeEstimator<F>,
715 /// See `ChannelManager` struct-level documentation for lock order requirements.
717 pub(super) best_block: RwLock<BestBlock>,
719 best_block: RwLock<BestBlock>,
720 secp_ctx: Secp256k1<secp256k1::All>,
722 /// Storage for PaymentSecrets and any requirements on future inbound payments before we will
723 /// expose them to users via a PaymentClaimable event. HTLCs which do not meet the requirements
724 /// here are failed when we process them as pending-forwardable-HTLCs, and entries are removed
725 /// after we generate a PaymentClaimable upon receipt of all MPP parts or when they time out.
727 /// See `ChannelManager` struct-level documentation for lock order requirements.
728 pending_inbound_payments: Mutex<HashMap<PaymentHash, PendingInboundPayment>>,
730 /// The session_priv bytes and retry metadata of outbound payments which are pending resolution.
731 /// The authoritative state of these HTLCs resides either within Channels or ChannelMonitors
732 /// (if the channel has been force-closed), however we track them here to prevent duplicative
733 /// PaymentSent/PaymentPathFailed events. Specifically, in the case of a duplicative
734 /// update_fulfill_htlc message after a reconnect, we may "claim" a payment twice.
735 /// Additionally, because ChannelMonitors are often not re-serialized after connecting block(s)
736 /// which may generate a claim event, we may receive similar duplicate claim/fail MonitorEvents
737 /// after reloading from disk while replaying blocks against ChannelMonitors.
739 /// See `PendingOutboundPayment` documentation for more info.
741 /// See `ChannelManager` struct-level documentation for lock order requirements.
742 pending_outbound_payments: OutboundPayments,
744 /// SCID/SCID Alias -> forward infos. Key of 0 means payments received.
746 /// Note that because we may have an SCID Alias as the key we can have two entries per channel,
747 /// though in practice we probably won't be receiving HTLCs for a channel both via the alias
748 /// and via the classic SCID.
750 /// Note that no consistency guarantees are made about the existence of a channel with the
751 /// `short_channel_id` here, nor the `short_channel_id` in the `PendingHTLCInfo`!
753 /// See `ChannelManager` struct-level documentation for lock order requirements.
755 pub(super) forward_htlcs: Mutex<HashMap<u64, Vec<HTLCForwardInfo>>>,
757 forward_htlcs: Mutex<HashMap<u64, Vec<HTLCForwardInfo>>>,
758 /// Storage for HTLCs that have been intercepted and bubbled up to the user. We hold them here
759 /// until the user tells us what we should do with them.
761 /// See `ChannelManager` struct-level documentation for lock order requirements.
762 pending_intercepted_htlcs: Mutex<HashMap<InterceptId, PendingAddHTLCInfo>>,
764 /// The sets of payments which are claimable or currently being claimed. See
765 /// [`ClaimablePayments`]' individual field docs for more info.
767 /// See `ChannelManager` struct-level documentation for lock order requirements.
768 claimable_payments: Mutex<ClaimablePayments>,
770 /// The set of outbound SCID aliases across all our channels, including unconfirmed channels
771 /// and some closed channels which reached a usable state prior to being closed. This is used
772 /// only to avoid duplicates, and is not persisted explicitly to disk, but rebuilt from the
773 /// active channel list on load.
775 /// See `ChannelManager` struct-level documentation for lock order requirements.
776 outbound_scid_aliases: Mutex<HashSet<u64>>,
778 /// `channel_id` -> `counterparty_node_id`.
780 /// Only `channel_id`s are allowed as keys in this map, and not `temporary_channel_id`s. As
781 /// multiple channels with the same `temporary_channel_id` to different peers can exist,
782 /// allowing `temporary_channel_id`s in this map would cause collisions for such channels.
784 /// Note that this map should only be used for `MonitorEvent` handling, to be able to access
785 /// the corresponding channel for the event, as we only have access to the `channel_id` during
786 /// the handling of the events.
788 /// Note that no consistency guarantees are made about the existence of a peer with the
789 /// `counterparty_node_id` in our other maps.
792 /// The `counterparty_node_id` isn't passed with `MonitorEvent`s currently. To pass it, we need
793 /// to make `counterparty_node_id`'s a required field in `ChannelMonitor`s, which unfortunately
794 /// would break backwards compatability.
795 /// We should add `counterparty_node_id`s to `MonitorEvent`s, and eventually rely on it in the
796 /// future. That would make this map redundant, as only the `ChannelManager::per_peer_state` is
797 /// required to access the channel with the `counterparty_node_id`.
799 /// See `ChannelManager` struct-level documentation for lock order requirements.
800 id_to_peer: Mutex<HashMap<[u8; 32], PublicKey>>,
802 /// SCIDs (and outbound SCID aliases) -> `counterparty_node_id`s and `channel_id`s.
804 /// Outbound SCID aliases are added here once the channel is available for normal use, with
805 /// SCIDs being added once the funding transaction is confirmed at the channel's required
806 /// confirmation depth.
808 /// Note that while this holds `counterparty_node_id`s and `channel_id`s, no consistency
809 /// guarantees are made about the existence of a peer with the `counterparty_node_id` nor a
810 /// channel with the `channel_id` in our other maps.
812 /// See `ChannelManager` struct-level documentation for lock order requirements.
814 pub(super) short_to_chan_info: FairRwLock<HashMap<u64, (PublicKey, [u8; 32])>>,
816 short_to_chan_info: FairRwLock<HashMap<u64, (PublicKey, [u8; 32])>>,
818 our_network_pubkey: PublicKey,
820 inbound_payment_key: inbound_payment::ExpandedKey,
822 /// LDK puts the [fake scids] that it generates into namespaces, to identify the type of an
823 /// incoming payment. To make it harder for a third-party to identify the type of a payment,
824 /// we encrypt the namespace identifier using these bytes.
826 /// [fake scids]: crate::util::scid_utils::fake_scid
827 fake_scid_rand_bytes: [u8; 32],
829 /// When we send payment probes, we generate the [`PaymentHash`] based on this cookie secret
830 /// and a random [`PaymentId`]. This allows us to discern probes from real payments, without
831 /// keeping additional state.
832 probing_cookie_secret: [u8; 32],
834 /// The highest block timestamp we've seen, which is usually a good guess at the current time.
835 /// Assuming most miners are generating blocks with reasonable timestamps, this shouldn't be
836 /// very far in the past, and can only ever be up to two hours in the future.
837 highest_seen_timestamp: AtomicUsize,
839 /// The bulk of our storage. Currently the `per_peer_state` stores our channels on a per-peer
840 /// basis, as well as the peer's latest features.
842 /// If we are connected to a peer we always at least have an entry here, even if no channels
843 /// are currently open with that peer.
845 /// Because adding or removing an entry is rare, we usually take an outer read lock and then
846 /// operate on the inner value freely. This opens up for parallel per-peer operation for
849 /// Note that the same thread must never acquire two inner `PeerState` locks at the same time.
851 /// See `ChannelManager` struct-level documentation for lock order requirements.
852 #[cfg(not(any(test, feature = "_test_utils")))]
853 per_peer_state: FairRwLock<HashMap<PublicKey, Mutex<PeerState<<SP::Target as SignerProvider>::Signer>>>>,
854 #[cfg(any(test, feature = "_test_utils"))]
855 pub(super) per_peer_state: FairRwLock<HashMap<PublicKey, Mutex<PeerState<<SP::Target as SignerProvider>::Signer>>>>,
857 /// See `ChannelManager` struct-level documentation for lock order requirements.
858 pending_events: Mutex<Vec<events::Event>>,
859 /// See `ChannelManager` struct-level documentation for lock order requirements.
860 pending_background_events: Mutex<Vec<BackgroundEvent>>,
861 /// Used when we have to take a BIG lock to make sure everything is self-consistent.
862 /// Essentially just when we're serializing ourselves out.
863 /// Taken first everywhere where we are making changes before any other locks.
864 /// When acquiring this lock in read mode, rather than acquiring it directly, call
865 /// `PersistenceNotifierGuard::notify_on_drop(..)` and pass the lock to it, to ensure the
866 /// Notifier the lock contains sends out a notification when the lock is released.
867 total_consistency_lock: RwLock<()>,
869 persistence_notifier: Notifier,
878 /// Chain-related parameters used to construct a new `ChannelManager`.
880 /// Typically, the block-specific parameters are derived from the best block hash for the network,
881 /// as a newly constructed `ChannelManager` will not have created any channels yet. These parameters
882 /// are not needed when deserializing a previously constructed `ChannelManager`.
883 #[derive(Clone, Copy, PartialEq)]
884 pub struct ChainParameters {
885 /// The network for determining the `chain_hash` in Lightning messages.
886 pub network: Network,
888 /// The hash and height of the latest block successfully connected.
890 /// Used to track on-chain channel funding outputs and send payments with reliable timelocks.
891 pub best_block: BestBlock,
894 #[derive(Copy, Clone, PartialEq)]
900 /// Whenever we release the `ChannelManager`'s `total_consistency_lock`, from read mode, it is
901 /// desirable to notify any listeners on `await_persistable_update_timeout`/
902 /// `await_persistable_update` when new updates are available for persistence. Therefore, this
903 /// struct is responsible for locking the total consistency lock and, upon going out of scope,
904 /// sending the aforementioned notification (since the lock being released indicates that the
905 /// updates are ready for persistence).
907 /// We allow callers to either always notify by constructing with `notify_on_drop` or choose to
908 /// notify or not based on whether relevant changes have been made, providing a closure to
909 /// `optionally_notify` which returns a `NotifyOption`.
910 struct PersistenceNotifierGuard<'a, F: Fn() -> NotifyOption> {
911 persistence_notifier: &'a Notifier,
913 // We hold onto this result so the lock doesn't get released immediately.
914 _read_guard: RwLockReadGuard<'a, ()>,
917 impl<'a> PersistenceNotifierGuard<'a, fn() -> NotifyOption> { // We don't care what the concrete F is here, it's unused
918 fn notify_on_drop(lock: &'a RwLock<()>, notifier: &'a Notifier) -> PersistenceNotifierGuard<'a, impl Fn() -> NotifyOption> {
919 PersistenceNotifierGuard::optionally_notify(lock, notifier, || -> NotifyOption { NotifyOption::DoPersist })
922 fn optionally_notify<F: Fn() -> NotifyOption>(lock: &'a RwLock<()>, notifier: &'a Notifier, persist_check: F) -> PersistenceNotifierGuard<'a, F> {
923 let read_guard = lock.read().unwrap();
925 PersistenceNotifierGuard {
926 persistence_notifier: notifier,
927 should_persist: persist_check,
928 _read_guard: read_guard,
933 impl<'a, F: Fn() -> NotifyOption> Drop for PersistenceNotifierGuard<'a, F> {
935 if (self.should_persist)() == NotifyOption::DoPersist {
936 self.persistence_notifier.notify();
941 /// The amount of time in blocks we require our counterparty wait to claim their money (ie time
942 /// between when we, or our watchtower, must check for them having broadcast a theft transaction).
944 /// This can be increased (but not decreased) through [`ChannelHandshakeConfig::our_to_self_delay`]
946 /// [`ChannelHandshakeConfig::our_to_self_delay`]: crate::util::config::ChannelHandshakeConfig::our_to_self_delay
947 pub const BREAKDOWN_TIMEOUT: u16 = 6 * 24;
948 /// The amount of time in blocks we're willing to wait to claim money back to us. This matches
949 /// the maximum required amount in lnd as of March 2021.
950 pub(crate) const MAX_LOCAL_BREAKDOWN_TIMEOUT: u16 = 2 * 6 * 24 * 7;
952 /// The minimum number of blocks between an inbound HTLC's CLTV and the corresponding outbound
953 /// HTLC's CLTV. The current default represents roughly seven hours of blocks at six blocks/hour.
955 /// This can be increased (but not decreased) through [`ChannelConfig::cltv_expiry_delta`]
957 /// [`ChannelConfig::cltv_expiry_delta`]: crate::util::config::ChannelConfig::cltv_expiry_delta
958 // This should always be a few blocks greater than channelmonitor::CLTV_CLAIM_BUFFER,
959 // i.e. the node we forwarded the payment on to should always have enough room to reliably time out
960 // the HTLC via a full update_fail_htlc/commitment_signed dance before we hit the
961 // CLTV_CLAIM_BUFFER point (we static assert that it's at least 3 blocks more).
962 pub const MIN_CLTV_EXPIRY_DELTA: u16 = 6*7;
963 // This should be long enough to allow a payment path drawn across multiple routing hops with substantial
964 // `cltv_expiry_delta`. Indeed, the length of those values is the reaction delay offered to a routing node
965 // in case of HTLC on-chain settlement. While appearing less competitive, a node operator could decide to
966 // scale them up to suit its security policy. At the network-level, we shouldn't constrain them too much,
967 // while avoiding to introduce a DoS vector. Further, a low CTLV_FAR_FAR_AWAY could be a source of
968 // routing failure for any HTLC sender picking up an LDK node among the first hops.
969 pub(super) const CLTV_FAR_FAR_AWAY: u32 = 14 * 24 * 6;
971 /// Minimum CLTV difference between the current block height and received inbound payments.
972 /// Invoices generated for payment to us must set their `min_final_cltv_expiry_delta` field to at least
974 // Note that we fail if exactly HTLC_FAIL_BACK_BUFFER + 1 was used, so we need to add one for
975 // any payments to succeed. Further, we don't want payments to fail if a block was found while
976 // a payment was being routed, so we add an extra block to be safe.
977 pub const MIN_FINAL_CLTV_EXPIRY_DELTA: u16 = HTLC_FAIL_BACK_BUFFER as u16 + 3;
979 // Check that our CLTV_EXPIRY is at least CLTV_CLAIM_BUFFER + ANTI_REORG_DELAY + LATENCY_GRACE_PERIOD_BLOCKS,
980 // ie that if the next-hop peer fails the HTLC within
981 // LATENCY_GRACE_PERIOD_BLOCKS then we'll still have CLTV_CLAIM_BUFFER left to timeout it onchain,
982 // then waiting ANTI_REORG_DELAY to be reorg-safe on the outbound HLTC and
983 // failing the corresponding htlc backward, and us now seeing the last block of ANTI_REORG_DELAY before
984 // LATENCY_GRACE_PERIOD_BLOCKS.
987 const CHECK_CLTV_EXPIRY_SANITY: u32 = MIN_CLTV_EXPIRY_DELTA as u32 - LATENCY_GRACE_PERIOD_BLOCKS - CLTV_CLAIM_BUFFER - ANTI_REORG_DELAY - LATENCY_GRACE_PERIOD_BLOCKS;
989 // Check for ability of an attacker to make us fail on-chain by delaying an HTLC claim. See
990 // ChannelMonitor::should_broadcast_holder_commitment_txn for a description of why this is needed.
993 const CHECK_CLTV_EXPIRY_SANITY_2: u32 = MIN_CLTV_EXPIRY_DELTA as u32 - LATENCY_GRACE_PERIOD_BLOCKS - 2*CLTV_CLAIM_BUFFER;
995 /// The number of ticks of [`ChannelManager::timer_tick_occurred`] until expiry of incomplete MPPs
996 pub(crate) const MPP_TIMEOUT_TICKS: u8 = 3;
998 /// The number of ticks of [`ChannelManager::timer_tick_occurred`] until we time-out the
999 /// idempotency of payments by [`PaymentId`]. See
1000 /// [`OutboundPayments::remove_stale_resolved_payments`].
1001 pub(crate) const IDEMPOTENCY_TIMEOUT_TICKS: u8 = 7;
1003 /// The maximum number of unfunded channels we can have per-peer before we start rejecting new
1004 /// (inbound) ones. The number of peers with unfunded channels is limited separately in
1005 /// [`MAX_UNFUNDED_CHANNEL_PEERS`].
1006 const MAX_UNFUNDED_CHANS_PER_PEER: usize = 4;
1008 /// The maximum number of peers from which we will allow pending unfunded channels. Once we reach
1009 /// this many peers we reject new (inbound) channels from peers with which we don't have a channel.
1010 const MAX_UNFUNDED_CHANNEL_PEERS: usize = 50;
1012 /// The maximum number of peers which we do not have a (funded) channel with. Once we reach this
1013 /// many peers we reject new (inbound) connections.
1014 const MAX_NO_CHANNEL_PEERS: usize = 250;
1016 /// Information needed for constructing an invoice route hint for this channel.
1017 #[derive(Clone, Debug, PartialEq)]
1018 pub struct CounterpartyForwardingInfo {
1019 /// Base routing fee in millisatoshis.
1020 pub fee_base_msat: u32,
1021 /// Amount in millionths of a satoshi the channel will charge per transferred satoshi.
1022 pub fee_proportional_millionths: u32,
1023 /// The minimum difference in cltv_expiry between an ingoing HTLC and its outgoing counterpart,
1024 /// such that the outgoing HTLC is forwardable to this counterparty. See `msgs::ChannelUpdate`'s
1025 /// `cltv_expiry_delta` for more details.
1026 pub cltv_expiry_delta: u16,
1029 /// Channel parameters which apply to our counterparty. These are split out from [`ChannelDetails`]
1030 /// to better separate parameters.
1031 #[derive(Clone, Debug, PartialEq)]
1032 pub struct ChannelCounterparty {
1033 /// The node_id of our counterparty
1034 pub node_id: PublicKey,
1035 /// The Features the channel counterparty provided upon last connection.
1036 /// Useful for routing as it is the most up-to-date copy of the counterparty's features and
1037 /// many routing-relevant features are present in the init context.
1038 pub features: InitFeatures,
1039 /// The value, in satoshis, that must always be held in the channel for our counterparty. This
1040 /// value ensures that if our counterparty broadcasts a revoked state, we can punish them by
1041 /// claiming at least this value on chain.
1043 /// This value is not included in [`inbound_capacity_msat`] as it can never be spent.
1045 /// [`inbound_capacity_msat`]: ChannelDetails::inbound_capacity_msat
1046 pub unspendable_punishment_reserve: u64,
1047 /// Information on the fees and requirements that the counterparty requires when forwarding
1048 /// payments to us through this channel.
1049 pub forwarding_info: Option<CounterpartyForwardingInfo>,
1050 /// The smallest value HTLC (in msat) the remote peer will accept, for this channel. This field
1051 /// is only `None` before we have received either the `OpenChannel` or `AcceptChannel` message
1052 /// from the remote peer, or for `ChannelCounterparty` objects serialized prior to LDK 0.0.107.
1053 pub outbound_htlc_minimum_msat: Option<u64>,
1054 /// The largest value HTLC (in msat) the remote peer currently will accept, for this channel.
1055 pub outbound_htlc_maximum_msat: Option<u64>,
1058 /// Details of a channel, as returned by [`ChannelManager::list_channels`] and [`ChannelManager::list_usable_channels`]
1059 #[derive(Clone, Debug, PartialEq)]
1060 pub struct ChannelDetails {
1061 /// The channel's ID (prior to funding transaction generation, this is a random 32 bytes,
1062 /// thereafter this is the txid of the funding transaction xor the funding transaction output).
1063 /// Note that this means this value is *not* persistent - it can change once during the
1064 /// lifetime of the channel.
1065 pub channel_id: [u8; 32],
1066 /// Parameters which apply to our counterparty. See individual fields for more information.
1067 pub counterparty: ChannelCounterparty,
1068 /// The Channel's funding transaction output, if we've negotiated the funding transaction with
1069 /// our counterparty already.
1071 /// Note that, if this has been set, `channel_id` will be equivalent to
1072 /// `funding_txo.unwrap().to_channel_id()`.
1073 pub funding_txo: Option<OutPoint>,
1074 /// The features which this channel operates with. See individual features for more info.
1076 /// `None` until negotiation completes and the channel type is finalized.
1077 pub channel_type: Option<ChannelTypeFeatures>,
1078 /// The position of the funding transaction in the chain. None if the funding transaction has
1079 /// not yet been confirmed and the channel fully opened.
1081 /// Note that if [`inbound_scid_alias`] is set, it must be used for invoices and inbound
1082 /// payments instead of this. See [`get_inbound_payment_scid`].
1084 /// For channels with [`confirmations_required`] set to `Some(0)`, [`outbound_scid_alias`] may
1085 /// be used in place of this in outbound routes. See [`get_outbound_payment_scid`].
1087 /// [`inbound_scid_alias`]: Self::inbound_scid_alias
1088 /// [`outbound_scid_alias`]: Self::outbound_scid_alias
1089 /// [`get_inbound_payment_scid`]: Self::get_inbound_payment_scid
1090 /// [`get_outbound_payment_scid`]: Self::get_outbound_payment_scid
1091 /// [`confirmations_required`]: Self::confirmations_required
1092 pub short_channel_id: Option<u64>,
1093 /// An optional [`short_channel_id`] alias for this channel, randomly generated by us and
1094 /// usable in place of [`short_channel_id`] to reference the channel in outbound routes when
1095 /// the channel has not yet been confirmed (as long as [`confirmations_required`] is
1098 /// This will be `None` as long as the channel is not available for routing outbound payments.
1100 /// [`short_channel_id`]: Self::short_channel_id
1101 /// [`confirmations_required`]: Self::confirmations_required
1102 pub outbound_scid_alias: Option<u64>,
1103 /// An optional [`short_channel_id`] alias for this channel, randomly generated by our
1104 /// counterparty and usable in place of [`short_channel_id`] in invoice route hints. Our
1105 /// counterparty will recognize the alias provided here in place of the [`short_channel_id`]
1106 /// when they see a payment to be routed to us.
1108 /// Our counterparty may choose to rotate this value at any time, though will always recognize
1109 /// previous values for inbound payment forwarding.
1111 /// [`short_channel_id`]: Self::short_channel_id
1112 pub inbound_scid_alias: Option<u64>,
1113 /// The value, in satoshis, of this channel as appears in the funding output
1114 pub channel_value_satoshis: u64,
1115 /// The value, in satoshis, that must always be held in the channel for us. This value ensures
1116 /// that if we broadcast a revoked state, our counterparty can punish us by claiming at least
1117 /// this value on chain.
1119 /// This value is not included in [`outbound_capacity_msat`] as it can never be spent.
1121 /// This value will be `None` for outbound channels until the counterparty accepts the channel.
1123 /// [`outbound_capacity_msat`]: ChannelDetails::outbound_capacity_msat
1124 pub unspendable_punishment_reserve: Option<u64>,
1125 /// The `user_channel_id` passed in to create_channel, or a random value if the channel was
1126 /// inbound. This may be zero for inbound channels serialized with LDK versions prior to
1128 pub user_channel_id: u128,
1129 /// The currently negotiated fee rate denominated in satoshi per 1000 weight units,
1130 /// which is applied to commitment and HTLC transactions.
1132 /// This value will be `None` for objects serialized with LDK versions prior to 0.0.115.
1133 pub feerate_sat_per_1000_weight: Option<u32>,
1134 /// Our total balance. This is the amount we would get if we close the channel.
1135 /// This value is not exact. Due to various in-flight changes and feerate changes, exactly this
1136 /// amount is not likely to be recoverable on close.
1138 /// This does not include any pending HTLCs which are not yet fully resolved (and, thus, whose
1139 /// balance is not available for inclusion in new outbound HTLCs). This further does not include
1140 /// any pending outgoing HTLCs which are awaiting some other resolution to be sent.
1141 /// This does not consider any on-chain fees.
1143 /// See also [`ChannelDetails::outbound_capacity_msat`]
1144 pub balance_msat: u64,
1145 /// The available outbound capacity for sending HTLCs to the remote peer. This does not include
1146 /// any pending HTLCs which are not yet fully resolved (and, thus, whose balance is not
1147 /// available for inclusion in new outbound HTLCs). This further does not include any pending
1148 /// outgoing HTLCs which are awaiting some other resolution to be sent.
1150 /// See also [`ChannelDetails::balance_msat`]
1152 /// This value is not exact. Due to various in-flight changes, feerate changes, and our
1153 /// conflict-avoidance policy, exactly this amount is not likely to be spendable. However, we
1154 /// should be able to spend nearly this amount.
1155 pub outbound_capacity_msat: u64,
1156 /// The available outbound capacity for sending a single HTLC to the remote peer. This is
1157 /// similar to [`ChannelDetails::outbound_capacity_msat`] but it may be further restricted by
1158 /// the current state and per-HTLC limit(s). This is intended for use when routing, allowing us
1159 /// to use a limit as close as possible to the HTLC limit we can currently send.
1161 /// See also [`ChannelDetails::balance_msat`] and [`ChannelDetails::outbound_capacity_msat`].
1162 pub next_outbound_htlc_limit_msat: u64,
1163 /// The available inbound capacity for the remote peer to send HTLCs to us. This does not
1164 /// include any pending HTLCs which are not yet fully resolved (and, thus, whose balance is not
1165 /// available for inclusion in new inbound HTLCs).
1166 /// Note that there are some corner cases not fully handled here, so the actual available
1167 /// inbound capacity may be slightly higher than this.
1169 /// This value is not exact. Due to various in-flight changes, feerate changes, and our
1170 /// counterparty's conflict-avoidance policy, exactly this amount is not likely to be spendable.
1171 /// However, our counterparty should be able to spend nearly this amount.
1172 pub inbound_capacity_msat: u64,
1173 /// The number of required confirmations on the funding transaction before the funding will be
1174 /// considered "locked". This number is selected by the channel fundee (i.e. us if
1175 /// [`is_outbound`] is *not* set), and can be selected for inbound channels with
1176 /// [`ChannelHandshakeConfig::minimum_depth`] or limited for outbound channels with
1177 /// [`ChannelHandshakeLimits::max_minimum_depth`].
1179 /// This value will be `None` for outbound channels until the counterparty accepts the channel.
1181 /// [`is_outbound`]: ChannelDetails::is_outbound
1182 /// [`ChannelHandshakeConfig::minimum_depth`]: crate::util::config::ChannelHandshakeConfig::minimum_depth
1183 /// [`ChannelHandshakeLimits::max_minimum_depth`]: crate::util::config::ChannelHandshakeLimits::max_minimum_depth
1184 pub confirmations_required: Option<u32>,
1185 /// The current number of confirmations on the funding transaction.
1187 /// This value will be `None` for objects serialized with LDK versions prior to 0.0.113.
1188 pub confirmations: Option<u32>,
1189 /// The number of blocks (after our commitment transaction confirms) that we will need to wait
1190 /// until we can claim our funds after we force-close the channel. During this time our
1191 /// counterparty is allowed to punish us if we broadcasted a stale state. If our counterparty
1192 /// force-closes the channel and broadcasts a commitment transaction we do not have to wait any
1193 /// time to claim our non-HTLC-encumbered funds.
1195 /// This value will be `None` for outbound channels until the counterparty accepts the channel.
1196 pub force_close_spend_delay: Option<u16>,
1197 /// True if the channel was initiated (and thus funded) by us.
1198 pub is_outbound: bool,
1199 /// True if the channel is confirmed, channel_ready messages have been exchanged, and the
1200 /// channel is not currently being shut down. `channel_ready` message exchange implies the
1201 /// required confirmation count has been reached (and we were connected to the peer at some
1202 /// point after the funding transaction received enough confirmations). The required
1203 /// confirmation count is provided in [`confirmations_required`].
1205 /// [`confirmations_required`]: ChannelDetails::confirmations_required
1206 pub is_channel_ready: bool,
1207 /// True if the channel is (a) confirmed and channel_ready messages have been exchanged, (b)
1208 /// the peer is connected, and (c) the channel is not currently negotiating a shutdown.
1210 /// This is a strict superset of `is_channel_ready`.
1211 pub is_usable: bool,
1212 /// True if this channel is (or will be) publicly-announced.
1213 pub is_public: bool,
1214 /// The smallest value HTLC (in msat) we will accept, for this channel. This field
1215 /// is only `None` for `ChannelDetails` objects serialized prior to LDK 0.0.107
1216 pub inbound_htlc_minimum_msat: Option<u64>,
1217 /// The largest value HTLC (in msat) we currently will accept, for this channel.
1218 pub inbound_htlc_maximum_msat: Option<u64>,
1219 /// Set of configurable parameters that affect channel operation.
1221 /// This field is only `None` for `ChannelDetails` objects serialized prior to LDK 0.0.109.
1222 pub config: Option<ChannelConfig>,
1225 impl ChannelDetails {
1226 /// Gets the current SCID which should be used to identify this channel for inbound payments.
1227 /// This should be used for providing invoice hints or in any other context where our
1228 /// counterparty will forward a payment to us.
1230 /// This is either the [`ChannelDetails::inbound_scid_alias`], if set, or the
1231 /// [`ChannelDetails::short_channel_id`]. See those for more information.
1232 pub fn get_inbound_payment_scid(&self) -> Option<u64> {
1233 self.inbound_scid_alias.or(self.short_channel_id)
1236 /// Gets the current SCID which should be used to identify this channel for outbound payments.
1237 /// This should be used in [`Route`]s to describe the first hop or in other contexts where
1238 /// we're sending or forwarding a payment outbound over this channel.
1240 /// This is either the [`ChannelDetails::short_channel_id`], if set, or the
1241 /// [`ChannelDetails::outbound_scid_alias`]. See those for more information.
1242 pub fn get_outbound_payment_scid(&self) -> Option<u64> {
1243 self.short_channel_id.or(self.outbound_scid_alias)
1246 fn from_channel<Signer: WriteableEcdsaChannelSigner>(channel: &Channel<Signer>,
1247 best_block_height: u32, latest_features: InitFeatures) -> Self {
1249 let balance = channel.get_available_balances();
1250 let (to_remote_reserve_satoshis, to_self_reserve_satoshis) =
1251 channel.get_holder_counterparty_selected_channel_reserve_satoshis();
1253 channel_id: channel.channel_id(),
1254 counterparty: ChannelCounterparty {
1255 node_id: channel.get_counterparty_node_id(),
1256 features: latest_features,
1257 unspendable_punishment_reserve: to_remote_reserve_satoshis,
1258 forwarding_info: channel.counterparty_forwarding_info(),
1259 // Ensures that we have actually received the `htlc_minimum_msat` value
1260 // from the counterparty through the `OpenChannel` or `AcceptChannel`
1261 // message (as they are always the first message from the counterparty).
1262 // Else `Channel::get_counterparty_htlc_minimum_msat` could return the
1263 // default `0` value set by `Channel::new_outbound`.
1264 outbound_htlc_minimum_msat: if channel.have_received_message() {
1265 Some(channel.get_counterparty_htlc_minimum_msat()) } else { None },
1266 outbound_htlc_maximum_msat: channel.get_counterparty_htlc_maximum_msat(),
1268 funding_txo: channel.get_funding_txo(),
1269 // Note that accept_channel (or open_channel) is always the first message, so
1270 // `have_received_message` indicates that type negotiation has completed.
1271 channel_type: if channel.have_received_message() { Some(channel.get_channel_type().clone()) } else { None },
1272 short_channel_id: channel.get_short_channel_id(),
1273 outbound_scid_alias: if channel.is_usable() { Some(channel.outbound_scid_alias()) } else { None },
1274 inbound_scid_alias: channel.latest_inbound_scid_alias(),
1275 channel_value_satoshis: channel.get_value_satoshis(),
1276 feerate_sat_per_1000_weight: Some(channel.get_feerate_sat_per_1000_weight()),
1277 unspendable_punishment_reserve: to_self_reserve_satoshis,
1278 balance_msat: balance.balance_msat,
1279 inbound_capacity_msat: balance.inbound_capacity_msat,
1280 outbound_capacity_msat: balance.outbound_capacity_msat,
1281 next_outbound_htlc_limit_msat: balance.next_outbound_htlc_limit_msat,
1282 user_channel_id: channel.get_user_id(),
1283 confirmations_required: channel.minimum_depth(),
1284 confirmations: Some(channel.get_funding_tx_confirmations(best_block_height)),
1285 force_close_spend_delay: channel.get_counterparty_selected_contest_delay(),
1286 is_outbound: channel.is_outbound(),
1287 is_channel_ready: channel.is_usable(),
1288 is_usable: channel.is_live(),
1289 is_public: channel.should_announce(),
1290 inbound_htlc_minimum_msat: Some(channel.get_holder_htlc_minimum_msat()),
1291 inbound_htlc_maximum_msat: channel.get_holder_htlc_maximum_msat(),
1292 config: Some(channel.config()),
1297 /// Used by [`ChannelManager::list_recent_payments`] to express the status of recent payments.
1298 /// These include payments that have yet to find a successful path, or have unresolved HTLCs.
1299 #[derive(Debug, PartialEq)]
1300 pub enum RecentPaymentDetails {
1301 /// When a payment is still being sent and awaiting successful delivery.
1303 /// Hash of the payment that is currently being sent but has yet to be fulfilled or
1305 payment_hash: PaymentHash,
1306 /// Total amount (in msat, excluding fees) across all paths for this payment,
1307 /// not just the amount currently inflight.
1310 /// When a pending payment is fulfilled, we continue tracking it until all pending HTLCs have
1311 /// been resolved. Upon receiving [`Event::PaymentSent`], we delay for a few minutes before the
1312 /// payment is removed from tracking.
1314 /// Hash of the payment that was claimed. `None` for serializations of [`ChannelManager`]
1315 /// made before LDK version 0.0.104.
1316 payment_hash: Option<PaymentHash>,
1318 /// After a payment's retries are exhausted per the provided [`Retry`], or it is explicitly
1319 /// abandoned via [`ChannelManager::abandon_payment`], it is marked as abandoned until all
1320 /// pending HTLCs for this payment resolve and an [`Event::PaymentFailed`] is generated.
1322 /// Hash of the payment that we have given up trying to send.
1323 payment_hash: PaymentHash,
1327 /// Route hints used in constructing invoices for [phantom node payents].
1329 /// [phantom node payments]: crate::chain::keysinterface::PhantomKeysManager
1331 pub struct PhantomRouteHints {
1332 /// The list of channels to be included in the invoice route hints.
1333 pub channels: Vec<ChannelDetails>,
1334 /// A fake scid used for representing the phantom node's fake channel in generating the invoice
1336 pub phantom_scid: u64,
1337 /// The pubkey of the real backing node that would ultimately receive the payment.
1338 pub real_node_pubkey: PublicKey,
1341 macro_rules! handle_error {
1342 ($self: ident, $internal: expr, $counterparty_node_id: expr) => {
1345 Err(MsgHandleErrInternal { err, chan_id, shutdown_finish }) => {
1346 // In testing, ensure there are no deadlocks where the lock is already held upon
1347 // entering the macro.
1348 debug_assert_ne!($self.pending_events.held_by_thread(), LockHeldState::HeldByThread);
1349 debug_assert_ne!($self.per_peer_state.held_by_thread(), LockHeldState::HeldByThread);
1351 let mut msg_events = Vec::with_capacity(2);
1353 if let Some((shutdown_res, update_option)) = shutdown_finish {
1354 $self.finish_force_close_channel(shutdown_res);
1355 if let Some(update) = update_option {
1356 msg_events.push(events::MessageSendEvent::BroadcastChannelUpdate {
1360 if let Some((channel_id, user_channel_id)) = chan_id {
1361 $self.pending_events.lock().unwrap().push(events::Event::ChannelClosed {
1362 channel_id, user_channel_id,
1363 reason: ClosureReason::ProcessingError { err: err.err.clone() }
1368 log_error!($self.logger, "{}", err.err);
1369 if let msgs::ErrorAction::IgnoreError = err.action {
1371 msg_events.push(events::MessageSendEvent::HandleError {
1372 node_id: $counterparty_node_id,
1373 action: err.action.clone()
1377 if !msg_events.is_empty() {
1378 let per_peer_state = $self.per_peer_state.read().unwrap();
1379 if let Some(peer_state_mutex) = per_peer_state.get(&$counterparty_node_id) {
1380 let mut peer_state = peer_state_mutex.lock().unwrap();
1381 peer_state.pending_msg_events.append(&mut msg_events);
1385 // Return error in case higher-API need one
1392 macro_rules! update_maps_on_chan_removal {
1393 ($self: expr, $channel: expr) => {{
1394 $self.id_to_peer.lock().unwrap().remove(&$channel.channel_id());
1395 let mut short_to_chan_info = $self.short_to_chan_info.write().unwrap();
1396 if let Some(short_id) = $channel.get_short_channel_id() {
1397 short_to_chan_info.remove(&short_id);
1399 // If the channel was never confirmed on-chain prior to its closure, remove the
1400 // outbound SCID alias we used for it from the collision-prevention set. While we
1401 // generally want to avoid ever re-using an outbound SCID alias across all channels, we
1402 // also don't want a counterparty to be able to trivially cause a memory leak by simply
1403 // opening a million channels with us which are closed before we ever reach the funding
1405 let alias_removed = $self.outbound_scid_aliases.lock().unwrap().remove(&$channel.outbound_scid_alias());
1406 debug_assert!(alias_removed);
1408 short_to_chan_info.remove(&$channel.outbound_scid_alias());
1412 /// Returns (boolean indicating if we should remove the Channel object from memory, a mapped error)
1413 macro_rules! convert_chan_err {
1414 ($self: ident, $err: expr, $channel: expr, $channel_id: expr) => {
1416 ChannelError::Warn(msg) => {
1417 (false, MsgHandleErrInternal::from_chan_no_close(ChannelError::Warn(msg), $channel_id.clone()))
1419 ChannelError::Ignore(msg) => {
1420 (false, MsgHandleErrInternal::from_chan_no_close(ChannelError::Ignore(msg), $channel_id.clone()))
1422 ChannelError::Close(msg) => {
1423 log_error!($self.logger, "Closing channel {} due to close-required error: {}", log_bytes!($channel_id[..]), msg);
1424 update_maps_on_chan_removal!($self, $channel);
1425 let shutdown_res = $channel.force_shutdown(true);
1426 (true, MsgHandleErrInternal::from_finish_shutdown(msg, *$channel_id, $channel.get_user_id(),
1427 shutdown_res, $self.get_channel_update_for_broadcast(&$channel).ok()))
1433 macro_rules! break_chan_entry {
1434 ($self: ident, $res: expr, $entry: expr) => {
1438 let (drop, res) = convert_chan_err!($self, e, $entry.get_mut(), $entry.key());
1440 $entry.remove_entry();
1448 macro_rules! try_chan_entry {
1449 ($self: ident, $res: expr, $entry: expr) => {
1453 let (drop, res) = convert_chan_err!($self, e, $entry.get_mut(), $entry.key());
1455 $entry.remove_entry();
1463 macro_rules! remove_channel {
1464 ($self: expr, $entry: expr) => {
1466 let channel = $entry.remove_entry().1;
1467 update_maps_on_chan_removal!($self, channel);
1473 macro_rules! send_channel_ready {
1474 ($self: ident, $pending_msg_events: expr, $channel: expr, $channel_ready_msg: expr) => {{
1475 $pending_msg_events.push(events::MessageSendEvent::SendChannelReady {
1476 node_id: $channel.get_counterparty_node_id(),
1477 msg: $channel_ready_msg,
1479 // Note that we may send a `channel_ready` multiple times for a channel if we reconnect, so
1480 // we allow collisions, but we shouldn't ever be updating the channel ID pointed to.
1481 let mut short_to_chan_info = $self.short_to_chan_info.write().unwrap();
1482 let outbound_alias_insert = short_to_chan_info.insert($channel.outbound_scid_alias(), ($channel.get_counterparty_node_id(), $channel.channel_id()));
1483 assert!(outbound_alias_insert.is_none() || outbound_alias_insert.unwrap() == ($channel.get_counterparty_node_id(), $channel.channel_id()),
1484 "SCIDs should never collide - ensure you weren't behind the chain tip by a full month when creating channels");
1485 if let Some(real_scid) = $channel.get_short_channel_id() {
1486 let scid_insert = short_to_chan_info.insert(real_scid, ($channel.get_counterparty_node_id(), $channel.channel_id()));
1487 assert!(scid_insert.is_none() || scid_insert.unwrap() == ($channel.get_counterparty_node_id(), $channel.channel_id()),
1488 "SCIDs should never collide - ensure you weren't behind the chain tip by a full month when creating channels");
1493 macro_rules! emit_channel_ready_event {
1494 ($self: expr, $channel: expr) => {
1495 if $channel.should_emit_channel_ready_event() {
1497 let mut pending_events = $self.pending_events.lock().unwrap();
1498 pending_events.push(events::Event::ChannelReady {
1499 channel_id: $channel.channel_id(),
1500 user_channel_id: $channel.get_user_id(),
1501 counterparty_node_id: $channel.get_counterparty_node_id(),
1502 channel_type: $channel.get_channel_type().clone(),
1505 $channel.set_channel_ready_event_emitted();
1510 macro_rules! handle_monitor_update_completion {
1511 ($self: ident, $update_id: expr, $peer_state_lock: expr, $peer_state: expr, $per_peer_state_lock: expr, $chan: expr) => { {
1512 let mut updates = $chan.monitor_updating_restored(&$self.logger,
1513 &$self.node_signer, $self.genesis_hash, &$self.default_configuration,
1514 $self.best_block.read().unwrap().height());
1515 let counterparty_node_id = $chan.get_counterparty_node_id();
1516 let channel_update = if updates.channel_ready.is_some() && $chan.is_usable() {
1517 // We only send a channel_update in the case where we are just now sending a
1518 // channel_ready and the channel is in a usable state. We may re-send a
1519 // channel_update later through the announcement_signatures process for public
1520 // channels, but there's no reason not to just inform our counterparty of our fees
1522 if let Ok(msg) = $self.get_channel_update_for_unicast($chan) {
1523 Some(events::MessageSendEvent::SendChannelUpdate {
1524 node_id: counterparty_node_id,
1530 let update_actions = $peer_state.monitor_update_blocked_actions
1531 .remove(&$chan.channel_id()).unwrap_or(Vec::new());
1533 let htlc_forwards = $self.handle_channel_resumption(
1534 &mut $peer_state.pending_msg_events, $chan, updates.raa,
1535 updates.commitment_update, updates.order, updates.accepted_htlcs,
1536 updates.funding_broadcastable, updates.channel_ready,
1537 updates.announcement_sigs);
1538 if let Some(upd) = channel_update {
1539 $peer_state.pending_msg_events.push(upd);
1542 let channel_id = $chan.channel_id();
1543 core::mem::drop($peer_state_lock);
1544 core::mem::drop($per_peer_state_lock);
1546 $self.handle_monitor_update_completion_actions(update_actions);
1548 if let Some(forwards) = htlc_forwards {
1549 $self.forward_htlcs(&mut [forwards][..]);
1551 $self.finalize_claims(updates.finalized_claimed_htlcs);
1552 for failure in updates.failed_htlcs.drain(..) {
1553 let receiver = HTLCDestination::NextHopChannel { node_id: Some(counterparty_node_id), channel_id };
1554 $self.fail_htlc_backwards_internal(&failure.0, &failure.1, &failure.2, receiver);
1559 macro_rules! handle_new_monitor_update {
1560 ($self: ident, $update_res: expr, $update_id: expr, $peer_state_lock: expr, $peer_state: expr, $per_peer_state_lock: expr, $chan: expr, MANUALLY_REMOVING, $remove: expr) => { {
1561 // update_maps_on_chan_removal needs to be able to take id_to_peer, so make sure we can in
1562 // any case so that it won't deadlock.
1563 debug_assert!($self.id_to_peer.try_lock().is_ok());
1565 ChannelMonitorUpdateStatus::InProgress => {
1566 log_debug!($self.logger, "ChannelMonitor update for {} in flight, holding messages until the update completes.",
1567 log_bytes!($chan.channel_id()[..]));
1570 ChannelMonitorUpdateStatus::PermanentFailure => {
1571 log_error!($self.logger, "Closing channel {} due to monitor update ChannelMonitorUpdateStatus::PermanentFailure",
1572 log_bytes!($chan.channel_id()[..]));
1573 update_maps_on_chan_removal!($self, $chan);
1574 let res: Result<(), _> = Err(MsgHandleErrInternal::from_finish_shutdown(
1575 "ChannelMonitor storage failure".to_owned(), $chan.channel_id(),
1576 $chan.get_user_id(), $chan.force_shutdown(false),
1577 $self.get_channel_update_for_broadcast(&$chan).ok()));
1581 ChannelMonitorUpdateStatus::Completed => {
1582 if ($update_id == 0 || $chan.get_next_monitor_update()
1583 .expect("We can't be processing a monitor update if it isn't queued")
1584 .update_id == $update_id) &&
1585 $chan.get_latest_monitor_update_id() == $update_id
1587 handle_monitor_update_completion!($self, $update_id, $peer_state_lock, $peer_state, $per_peer_state_lock, $chan);
1593 ($self: ident, $update_res: expr, $update_id: expr, $peer_state_lock: expr, $peer_state: expr, $per_peer_state_lock: expr, $chan_entry: expr) => {
1594 handle_new_monitor_update!($self, $update_res, $update_id, $peer_state_lock, $peer_state, $per_peer_state_lock, $chan_entry.get_mut(), MANUALLY_REMOVING, $chan_entry.remove_entry())
1598 impl<M: Deref, T: Deref, ES: Deref, NS: Deref, SP: Deref, F: Deref, R: Deref, L: Deref> ChannelManager<M, T, ES, NS, SP, F, R, L>
1600 M::Target: chain::Watch<<SP::Target as SignerProvider>::Signer>,
1601 T::Target: BroadcasterInterface,
1602 ES::Target: EntropySource,
1603 NS::Target: NodeSigner,
1604 SP::Target: SignerProvider,
1605 F::Target: FeeEstimator,
1609 /// Constructs a new `ChannelManager` to hold several channels and route between them.
1611 /// This is the main "logic hub" for all channel-related actions, and implements
1612 /// [`ChannelMessageHandler`].
1614 /// Non-proportional fees are fixed according to our risk using the provided fee estimator.
1616 /// Users need to notify the new `ChannelManager` when a new block is connected or
1617 /// disconnected using its [`block_connected`] and [`block_disconnected`] methods, starting
1618 /// from after [`params.best_block.block_hash`]. See [`chain::Listen`] and [`chain::Confirm`] for
1621 /// [`block_connected`]: chain::Listen::block_connected
1622 /// [`block_disconnected`]: chain::Listen::block_disconnected
1623 /// [`params.best_block.block_hash`]: chain::BestBlock::block_hash
1624 pub fn new(fee_est: F, chain_monitor: M, tx_broadcaster: T, router: R, logger: L, entropy_source: ES, node_signer: NS, signer_provider: SP, config: UserConfig, params: ChainParameters) -> Self {
1625 let mut secp_ctx = Secp256k1::new();
1626 secp_ctx.seeded_randomize(&entropy_source.get_secure_random_bytes());
1627 let inbound_pmt_key_material = node_signer.get_inbound_payment_key_material();
1628 let expanded_inbound_key = inbound_payment::ExpandedKey::new(&inbound_pmt_key_material);
1630 default_configuration: config.clone(),
1631 genesis_hash: genesis_block(params.network).header.block_hash(),
1632 fee_estimator: LowerBoundedFeeEstimator::new(fee_est),
1637 best_block: RwLock::new(params.best_block),
1639 outbound_scid_aliases: Mutex::new(HashSet::new()),
1640 pending_inbound_payments: Mutex::new(HashMap::new()),
1641 pending_outbound_payments: OutboundPayments::new(),
1642 forward_htlcs: Mutex::new(HashMap::new()),
1643 claimable_payments: Mutex::new(ClaimablePayments { claimable_htlcs: HashMap::new(), pending_claiming_payments: HashMap::new() }),
1644 pending_intercepted_htlcs: Mutex::new(HashMap::new()),
1645 id_to_peer: Mutex::new(HashMap::new()),
1646 short_to_chan_info: FairRwLock::new(HashMap::new()),
1648 our_network_pubkey: node_signer.get_node_id(Recipient::Node).unwrap(),
1651 inbound_payment_key: expanded_inbound_key,
1652 fake_scid_rand_bytes: entropy_source.get_secure_random_bytes(),
1654 probing_cookie_secret: entropy_source.get_secure_random_bytes(),
1656 highest_seen_timestamp: AtomicUsize::new(0),
1658 per_peer_state: FairRwLock::new(HashMap::new()),
1660 pending_events: Mutex::new(Vec::new()),
1661 pending_background_events: Mutex::new(Vec::new()),
1662 total_consistency_lock: RwLock::new(()),
1663 persistence_notifier: Notifier::new(),
1673 /// Gets the current configuration applied to all new channels.
1674 pub fn get_current_default_configuration(&self) -> &UserConfig {
1675 &self.default_configuration
1678 fn create_and_insert_outbound_scid_alias(&self) -> u64 {
1679 let height = self.best_block.read().unwrap().height();
1680 let mut outbound_scid_alias = 0;
1683 if cfg!(fuzzing) { // fuzzing chacha20 doesn't use the key at all so we always get the same alias
1684 outbound_scid_alias += 1;
1686 outbound_scid_alias = fake_scid::Namespace::OutboundAlias.get_fake_scid(height, &self.genesis_hash, &self.fake_scid_rand_bytes, &self.entropy_source);
1688 if outbound_scid_alias != 0 && self.outbound_scid_aliases.lock().unwrap().insert(outbound_scid_alias) {
1692 if i > 1_000_000 { panic!("Your RNG is busted or we ran out of possible outbound SCID aliases (which should never happen before we run out of memory to store channels"); }
1697 /// Creates a new outbound channel to the given remote node and with the given value.
1699 /// `user_channel_id` will be provided back as in
1700 /// [`Event::FundingGenerationReady::user_channel_id`] to allow tracking of which events
1701 /// correspond with which `create_channel` call. Note that the `user_channel_id` defaults to a
1702 /// randomized value for inbound channels. `user_channel_id` has no meaning inside of LDK, it
1703 /// is simply copied to events and otherwise ignored.
1705 /// Raises [`APIError::APIMisuseError`] when `channel_value_satoshis` > 2**24 or `push_msat` is
1706 /// greater than `channel_value_satoshis * 1k` or `channel_value_satoshis < 1000`.
1708 /// Note that we do not check if you are currently connected to the given peer. If no
1709 /// connection is available, the outbound `open_channel` message may fail to send, resulting in
1710 /// the channel eventually being silently forgotten (dropped on reload).
1712 /// Returns the new Channel's temporary `channel_id`. This ID will appear as
1713 /// [`Event::FundingGenerationReady::temporary_channel_id`] and in
1714 /// [`ChannelDetails::channel_id`] until after
1715 /// [`ChannelManager::funding_transaction_generated`] is called, swapping the Channel's ID for
1716 /// one derived from the funding transaction's TXID. If the counterparty rejects the channel
1717 /// immediately, this temporary ID will appear in [`Event::ChannelClosed::channel_id`].
1719 /// [`Event::FundingGenerationReady::user_channel_id`]: events::Event::FundingGenerationReady::user_channel_id
1720 /// [`Event::FundingGenerationReady::temporary_channel_id`]: events::Event::FundingGenerationReady::temporary_channel_id
1721 /// [`Event::ChannelClosed::channel_id`]: events::Event::ChannelClosed::channel_id
1722 pub fn create_channel(&self, their_network_key: PublicKey, channel_value_satoshis: u64, push_msat: u64, user_channel_id: u128, override_config: Option<UserConfig>) -> Result<[u8; 32], APIError> {
1723 if channel_value_satoshis < 1000 {
1724 return Err(APIError::APIMisuseError { err: format!("Channel value must be at least 1000 satoshis. It was {}", channel_value_satoshis) });
1727 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
1728 // We want to make sure the lock is actually acquired by PersistenceNotifierGuard.
1729 debug_assert!(&self.total_consistency_lock.try_write().is_err());
1731 let per_peer_state = self.per_peer_state.read().unwrap();
1733 let peer_state_mutex = per_peer_state.get(&their_network_key)
1734 .ok_or_else(|| APIError::APIMisuseError{ err: format!("Not connected to node: {}", their_network_key) })?;
1736 let mut peer_state = peer_state_mutex.lock().unwrap();
1738 let outbound_scid_alias = self.create_and_insert_outbound_scid_alias();
1739 let their_features = &peer_state.latest_features;
1740 let config = if override_config.is_some() { override_config.as_ref().unwrap() } else { &self.default_configuration };
1741 match Channel::new_outbound(&self.fee_estimator, &self.entropy_source, &self.signer_provider, their_network_key,
1742 their_features, channel_value_satoshis, push_msat, user_channel_id, config,
1743 self.best_block.read().unwrap().height(), outbound_scid_alias)
1747 self.outbound_scid_aliases.lock().unwrap().remove(&outbound_scid_alias);
1752 let res = channel.get_open_channel(self.genesis_hash.clone());
1754 let temporary_channel_id = channel.channel_id();
1755 match peer_state.channel_by_id.entry(temporary_channel_id) {
1756 hash_map::Entry::Occupied(_) => {
1758 return Err(APIError::APIMisuseError { err: "Fuzzy bad RNG".to_owned() });
1760 panic!("RNG is bad???");
1763 hash_map::Entry::Vacant(entry) => { entry.insert(channel); }
1766 peer_state.pending_msg_events.push(events::MessageSendEvent::SendOpenChannel {
1767 node_id: their_network_key,
1770 Ok(temporary_channel_id)
1773 fn list_channels_with_filter<Fn: FnMut(&(&[u8; 32], &Channel<<SP::Target as SignerProvider>::Signer>)) -> bool + Copy>(&self, f: Fn) -> Vec<ChannelDetails> {
1774 // Allocate our best estimate of the number of channels we have in the `res`
1775 // Vec. Sadly the `short_to_chan_info` map doesn't cover channels without
1776 // a scid or a scid alias, and the `id_to_peer` shouldn't be used outside
1777 // of the ChannelMonitor handling. Therefore reallocations may still occur, but is
1778 // unlikely as the `short_to_chan_info` map often contains 2 entries for
1779 // the same channel.
1780 let mut res = Vec::with_capacity(self.short_to_chan_info.read().unwrap().len());
1782 let best_block_height = self.best_block.read().unwrap().height();
1783 let per_peer_state = self.per_peer_state.read().unwrap();
1784 for (_cp_id, peer_state_mutex) in per_peer_state.iter() {
1785 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
1786 let peer_state = &mut *peer_state_lock;
1787 for (_channel_id, channel) in peer_state.channel_by_id.iter().filter(f) {
1788 let details = ChannelDetails::from_channel(channel, best_block_height,
1789 peer_state.latest_features.clone());
1797 /// Gets the list of open channels, in random order. See [`ChannelDetails`] field documentation for
1798 /// more information.
1799 pub fn list_channels(&self) -> Vec<ChannelDetails> {
1800 self.list_channels_with_filter(|_| true)
1803 /// Gets the list of usable channels, in random order. Useful as an argument to
1804 /// [`Router::find_route`] to ensure non-announced channels are used.
1806 /// These are guaranteed to have their [`ChannelDetails::is_usable`] value set to true, see the
1807 /// documentation for [`ChannelDetails::is_usable`] for more info on exactly what the criteria
1809 pub fn list_usable_channels(&self) -> Vec<ChannelDetails> {
1810 // Note we use is_live here instead of usable which leads to somewhat confused
1811 // internal/external nomenclature, but that's ok cause that's probably what the user
1812 // really wanted anyway.
1813 self.list_channels_with_filter(|&(_, ref channel)| channel.is_live())
1816 /// Gets the list of channels we have with a given counterparty, in random order.
1817 pub fn list_channels_with_counterparty(&self, counterparty_node_id: &PublicKey) -> Vec<ChannelDetails> {
1818 let best_block_height = self.best_block.read().unwrap().height();
1819 let per_peer_state = self.per_peer_state.read().unwrap();
1821 if let Some(peer_state_mutex) = per_peer_state.get(counterparty_node_id) {
1822 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
1823 let peer_state = &mut *peer_state_lock;
1824 let features = &peer_state.latest_features;
1825 return peer_state.channel_by_id
1828 ChannelDetails::from_channel(channel, best_block_height, features.clone()))
1834 /// Returns in an undefined order recent payments that -- if not fulfilled -- have yet to find a
1835 /// successful path, or have unresolved HTLCs.
1837 /// This can be useful for payments that may have been prepared, but ultimately not sent, as a
1838 /// result of a crash. If such a payment exists, is not listed here, and an
1839 /// [`Event::PaymentSent`] has not been received, you may consider resending the payment.
1841 /// [`Event::PaymentSent`]: events::Event::PaymentSent
1842 pub fn list_recent_payments(&self) -> Vec<RecentPaymentDetails> {
1843 self.pending_outbound_payments.pending_outbound_payments.lock().unwrap().iter()
1844 .filter_map(|(_, pending_outbound_payment)| match pending_outbound_payment {
1845 PendingOutboundPayment::Retryable { payment_hash, total_msat, .. } => {
1846 Some(RecentPaymentDetails::Pending {
1847 payment_hash: *payment_hash,
1848 total_msat: *total_msat,
1851 PendingOutboundPayment::Abandoned { payment_hash, .. } => {
1852 Some(RecentPaymentDetails::Abandoned { payment_hash: *payment_hash })
1854 PendingOutboundPayment::Fulfilled { payment_hash, .. } => {
1855 Some(RecentPaymentDetails::Fulfilled { payment_hash: *payment_hash })
1857 PendingOutboundPayment::Legacy { .. } => None
1862 /// Helper function that issues the channel close events
1863 fn issue_channel_close_events(&self, channel: &Channel<<SP::Target as SignerProvider>::Signer>, closure_reason: ClosureReason) {
1864 let mut pending_events_lock = self.pending_events.lock().unwrap();
1865 match channel.unbroadcasted_funding() {
1866 Some(transaction) => {
1867 pending_events_lock.push(events::Event::DiscardFunding { channel_id: channel.channel_id(), transaction })
1871 pending_events_lock.push(events::Event::ChannelClosed {
1872 channel_id: channel.channel_id(),
1873 user_channel_id: channel.get_user_id(),
1874 reason: closure_reason
1878 fn close_channel_internal(&self, channel_id: &[u8; 32], counterparty_node_id: &PublicKey, target_feerate_sats_per_1000_weight: Option<u32>) -> Result<(), APIError> {
1879 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
1881 let mut failed_htlcs: Vec<(HTLCSource, PaymentHash)>;
1882 let result: Result<(), _> = loop {
1883 let per_peer_state = self.per_peer_state.read().unwrap();
1885 let peer_state_mutex = per_peer_state.get(counterparty_node_id)
1886 .ok_or_else(|| APIError::ChannelUnavailable { err: format!("Can't find a peer matching the passed counterparty node_id {}", counterparty_node_id) })?;
1888 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
1889 let peer_state = &mut *peer_state_lock;
1890 match peer_state.channel_by_id.entry(channel_id.clone()) {
1891 hash_map::Entry::Occupied(mut chan_entry) => {
1892 let funding_txo_opt = chan_entry.get().get_funding_txo();
1893 let their_features = &peer_state.latest_features;
1894 let (shutdown_msg, mut monitor_update_opt, htlcs) = chan_entry.get_mut()
1895 .get_shutdown(&self.signer_provider, their_features, target_feerate_sats_per_1000_weight)?;
1896 failed_htlcs = htlcs;
1898 // We can send the `shutdown` message before updating the `ChannelMonitor`
1899 // here as we don't need the monitor update to complete until we send a
1900 // `shutdown_signed`, which we'll delay if we're pending a monitor update.
1901 peer_state.pending_msg_events.push(events::MessageSendEvent::SendShutdown {
1902 node_id: *counterparty_node_id,
1906 // Update the monitor with the shutdown script if necessary.
1907 if let Some(monitor_update) = monitor_update_opt.take() {
1908 let update_id = monitor_update.update_id;
1909 let update_res = self.chain_monitor.update_channel(funding_txo_opt.unwrap(), monitor_update);
1910 break handle_new_monitor_update!(self, update_res, update_id, peer_state_lock, peer_state, per_peer_state, chan_entry);
1913 if chan_entry.get().is_shutdown() {
1914 let channel = remove_channel!(self, chan_entry);
1915 if let Ok(channel_update) = self.get_channel_update_for_broadcast(&channel) {
1916 peer_state.pending_msg_events.push(events::MessageSendEvent::BroadcastChannelUpdate {
1920 self.issue_channel_close_events(&channel, ClosureReason::HolderForceClosed);
1924 hash_map::Entry::Vacant(_) => return Err(APIError::ChannelUnavailable{err: format!("Channel with id {} not found for the passed counterparty node_id {}", log_bytes!(*channel_id), counterparty_node_id) })
1928 for htlc_source in failed_htlcs.drain(..) {
1929 let reason = HTLCFailReason::from_failure_code(0x4000 | 8);
1930 let receiver = HTLCDestination::NextHopChannel { node_id: Some(*counterparty_node_id), channel_id: *channel_id };
1931 self.fail_htlc_backwards_internal(&htlc_source.0, &htlc_source.1, &reason, receiver);
1934 let _ = handle_error!(self, result, *counterparty_node_id);
1938 /// Begins the process of closing a channel. After this call (plus some timeout), no new HTLCs
1939 /// will be accepted on the given channel, and after additional timeout/the closing of all
1940 /// pending HTLCs, the channel will be closed on chain.
1942 /// * If we are the channel initiator, we will pay between our [`Background`] and
1943 /// [`ChannelConfig::force_close_avoidance_max_fee_satoshis`] plus our [`Normal`] fee
1945 /// * If our counterparty is the channel initiator, we will require a channel closing
1946 /// transaction feerate of at least our [`Background`] feerate or the feerate which
1947 /// would appear on a force-closure transaction, whichever is lower. We will allow our
1948 /// counterparty to pay as much fee as they'd like, however.
1950 /// May generate a [`SendShutdown`] message event on success, which should be relayed.
1952 /// [`ChannelConfig::force_close_avoidance_max_fee_satoshis`]: crate::util::config::ChannelConfig::force_close_avoidance_max_fee_satoshis
1953 /// [`Background`]: crate::chain::chaininterface::ConfirmationTarget::Background
1954 /// [`Normal`]: crate::chain::chaininterface::ConfirmationTarget::Normal
1955 /// [`SendShutdown`]: crate::events::MessageSendEvent::SendShutdown
1956 pub fn close_channel(&self, channel_id: &[u8; 32], counterparty_node_id: &PublicKey) -> Result<(), APIError> {
1957 self.close_channel_internal(channel_id, counterparty_node_id, None)
1960 /// Begins the process of closing a channel. After this call (plus some timeout), no new HTLCs
1961 /// will be accepted on the given channel, and after additional timeout/the closing of all
1962 /// pending HTLCs, the channel will be closed on chain.
1964 /// `target_feerate_sat_per_1000_weight` has different meanings depending on if we initiated
1965 /// the channel being closed or not:
1966 /// * If we are the channel initiator, we will pay at least this feerate on the closing
1967 /// transaction. The upper-bound is set by
1968 /// [`ChannelConfig::force_close_avoidance_max_fee_satoshis`] plus our [`Normal`] fee
1969 /// estimate (or `target_feerate_sat_per_1000_weight`, if it is greater).
1970 /// * If our counterparty is the channel initiator, we will refuse to accept a channel closure
1971 /// transaction feerate below `target_feerate_sat_per_1000_weight` (or the feerate which
1972 /// will appear on a force-closure transaction, whichever is lower).
1974 /// May generate a [`SendShutdown`] message event on success, which should be relayed.
1976 /// [`ChannelConfig::force_close_avoidance_max_fee_satoshis`]: crate::util::config::ChannelConfig::force_close_avoidance_max_fee_satoshis
1977 /// [`Background`]: crate::chain::chaininterface::ConfirmationTarget::Background
1978 /// [`Normal`]: crate::chain::chaininterface::ConfirmationTarget::Normal
1979 /// [`SendShutdown`]: crate::events::MessageSendEvent::SendShutdown
1980 pub fn close_channel_with_target_feerate(&self, channel_id: &[u8; 32], counterparty_node_id: &PublicKey, target_feerate_sats_per_1000_weight: u32) -> Result<(), APIError> {
1981 self.close_channel_internal(channel_id, counterparty_node_id, Some(target_feerate_sats_per_1000_weight))
1985 fn finish_force_close_channel(&self, shutdown_res: ShutdownResult) {
1986 let (monitor_update_option, mut failed_htlcs) = shutdown_res;
1987 log_debug!(self.logger, "Finishing force-closure of channel with {} HTLCs to fail", failed_htlcs.len());
1988 for htlc_source in failed_htlcs.drain(..) {
1989 let (source, payment_hash, counterparty_node_id, channel_id) = htlc_source;
1990 let reason = HTLCFailReason::from_failure_code(0x4000 | 8);
1991 let receiver = HTLCDestination::NextHopChannel { node_id: Some(counterparty_node_id), channel_id };
1992 self.fail_htlc_backwards_internal(&source, &payment_hash, &reason, receiver);
1994 if let Some((funding_txo, monitor_update)) = monitor_update_option {
1995 // There isn't anything we can do if we get an update failure - we're already
1996 // force-closing. The monitor update on the required in-memory copy should broadcast
1997 // the latest local state, which is the best we can do anyway. Thus, it is safe to
1998 // ignore the result here.
1999 let _ = self.chain_monitor.update_channel(funding_txo, &monitor_update);
2003 /// `peer_msg` should be set when we receive a message from a peer, but not set when the
2004 /// user closes, which will be re-exposed as the `ChannelClosed` reason.
2005 fn force_close_channel_with_peer(&self, channel_id: &[u8; 32], peer_node_id: &PublicKey, peer_msg: Option<&String>, broadcast: bool)
2006 -> Result<PublicKey, APIError> {
2007 let per_peer_state = self.per_peer_state.read().unwrap();
2008 let peer_state_mutex = per_peer_state.get(peer_node_id)
2009 .ok_or_else(|| APIError::ChannelUnavailable { err: format!("Can't find a peer matching the passed counterparty node_id {}", peer_node_id) })?;
2011 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
2012 let peer_state = &mut *peer_state_lock;
2013 if let hash_map::Entry::Occupied(chan) = peer_state.channel_by_id.entry(channel_id.clone()) {
2014 if let Some(peer_msg) = peer_msg {
2015 self.issue_channel_close_events(chan.get(),ClosureReason::CounterpartyForceClosed { peer_msg: UntrustedString(peer_msg.to_string()) });
2017 self.issue_channel_close_events(chan.get(),ClosureReason::HolderForceClosed);
2019 remove_channel!(self, chan)
2021 return Err(APIError::ChannelUnavailable{ err: format!("Channel with id {} not found for the passed counterparty node_id {}", log_bytes!(*channel_id), peer_node_id) });
2024 log_error!(self.logger, "Force-closing channel {}", log_bytes!(channel_id[..]));
2025 self.finish_force_close_channel(chan.force_shutdown(broadcast));
2026 if let Ok(update) = self.get_channel_update_for_broadcast(&chan) {
2027 let mut peer_state = peer_state_mutex.lock().unwrap();
2028 peer_state.pending_msg_events.push(events::MessageSendEvent::BroadcastChannelUpdate {
2033 Ok(chan.get_counterparty_node_id())
2036 fn force_close_sending_error(&self, channel_id: &[u8; 32], counterparty_node_id: &PublicKey, broadcast: bool) -> Result<(), APIError> {
2037 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
2038 match self.force_close_channel_with_peer(channel_id, counterparty_node_id, None, broadcast) {
2039 Ok(counterparty_node_id) => {
2040 let per_peer_state = self.per_peer_state.read().unwrap();
2041 if let Some(peer_state_mutex) = per_peer_state.get(&counterparty_node_id) {
2042 let mut peer_state = peer_state_mutex.lock().unwrap();
2043 peer_state.pending_msg_events.push(
2044 events::MessageSendEvent::HandleError {
2045 node_id: counterparty_node_id,
2046 action: msgs::ErrorAction::SendErrorMessage {
2047 msg: msgs::ErrorMessage { channel_id: *channel_id, data: "Channel force-closed".to_owned() }
2058 /// Force closes a channel, immediately broadcasting the latest local transaction(s) and
2059 /// rejecting new HTLCs on the given channel. Fails if `channel_id` is unknown to
2060 /// the manager, or if the `counterparty_node_id` isn't the counterparty of the corresponding
2062 pub fn force_close_broadcasting_latest_txn(&self, channel_id: &[u8; 32], counterparty_node_id: &PublicKey)
2063 -> Result<(), APIError> {
2064 self.force_close_sending_error(channel_id, counterparty_node_id, true)
2067 /// Force closes a channel, rejecting new HTLCs on the given channel but skips broadcasting
2068 /// the latest local transaction(s). Fails if `channel_id` is unknown to the manager, or if the
2069 /// `counterparty_node_id` isn't the counterparty of the corresponding channel.
2071 /// You can always get the latest local transaction(s) to broadcast from
2072 /// [`ChannelMonitor::get_latest_holder_commitment_txn`].
2073 pub fn force_close_without_broadcasting_txn(&self, channel_id: &[u8; 32], counterparty_node_id: &PublicKey)
2074 -> Result<(), APIError> {
2075 self.force_close_sending_error(channel_id, counterparty_node_id, false)
2078 /// Force close all channels, immediately broadcasting the latest local commitment transaction
2079 /// for each to the chain and rejecting new HTLCs on each.
2080 pub fn force_close_all_channels_broadcasting_latest_txn(&self) {
2081 for chan in self.list_channels() {
2082 let _ = self.force_close_broadcasting_latest_txn(&chan.channel_id, &chan.counterparty.node_id);
2086 /// Force close all channels rejecting new HTLCs on each but without broadcasting the latest
2087 /// local transaction(s).
2088 pub fn force_close_all_channels_without_broadcasting_txn(&self) {
2089 for chan in self.list_channels() {
2090 let _ = self.force_close_without_broadcasting_txn(&chan.channel_id, &chan.counterparty.node_id);
2094 fn construct_recv_pending_htlc_info(&self, hop_data: msgs::OnionHopData, shared_secret: [u8; 32],
2095 payment_hash: PaymentHash, amt_msat: u64, cltv_expiry: u32, phantom_shared_secret: Option<[u8; 32]>) -> Result<PendingHTLCInfo, ReceiveError>
2097 // final_incorrect_cltv_expiry
2098 if hop_data.outgoing_cltv_value > cltv_expiry {
2099 return Err(ReceiveError {
2100 msg: "Upstream node set CLTV to less than the CLTV set by the sender",
2102 err_data: cltv_expiry.to_be_bytes().to_vec()
2105 // final_expiry_too_soon
2106 // We have to have some headroom to broadcast on chain if we have the preimage, so make sure
2107 // we have at least HTLC_FAIL_BACK_BUFFER blocks to go.
2109 // Also, ensure that, in the case of an unknown preimage for the received payment hash, our
2110 // payment logic has enough time to fail the HTLC backward before our onchain logic triggers a
2111 // channel closure (see HTLC_FAIL_BACK_BUFFER rationale).
2112 let current_height: u32 = self.best_block.read().unwrap().height();
2113 if (hop_data.outgoing_cltv_value as u64) <= current_height as u64 + HTLC_FAIL_BACK_BUFFER as u64 + 1 {
2114 let mut err_data = Vec::with_capacity(12);
2115 err_data.extend_from_slice(&amt_msat.to_be_bytes());
2116 err_data.extend_from_slice(¤t_height.to_be_bytes());
2117 return Err(ReceiveError {
2118 err_code: 0x4000 | 15, err_data,
2119 msg: "The final CLTV expiry is too soon to handle",
2122 if hop_data.amt_to_forward > amt_msat {
2123 return Err(ReceiveError {
2125 err_data: amt_msat.to_be_bytes().to_vec(),
2126 msg: "Upstream node sent less than we were supposed to receive in payment",
2130 let routing = match hop_data.format {
2131 msgs::OnionHopDataFormat::NonFinalNode { .. } => {
2132 return Err(ReceiveError {
2133 err_code: 0x4000|22,
2134 err_data: Vec::new(),
2135 msg: "Got non final data with an HMAC of 0",
2138 msgs::OnionHopDataFormat::FinalNode { payment_data, keysend_preimage } => {
2139 if payment_data.is_some() && keysend_preimage.is_some() {
2140 return Err(ReceiveError {
2141 err_code: 0x4000|22,
2142 err_data: Vec::new(),
2143 msg: "We don't support MPP keysend payments",
2145 } else if let Some(data) = payment_data {
2146 PendingHTLCRouting::Receive {
2148 incoming_cltv_expiry: hop_data.outgoing_cltv_value,
2149 phantom_shared_secret,
2151 } else if let Some(payment_preimage) = keysend_preimage {
2152 // We need to check that the sender knows the keysend preimage before processing this
2153 // payment further. Otherwise, an intermediary routing hop forwarding non-keysend-HTLC X
2154 // could discover the final destination of X, by probing the adjacent nodes on the route
2155 // with a keysend payment of identical payment hash to X and observing the processing
2156 // time discrepancies due to a hash collision with X.
2157 let hashed_preimage = PaymentHash(Sha256::hash(&payment_preimage.0).into_inner());
2158 if hashed_preimage != payment_hash {
2159 return Err(ReceiveError {
2160 err_code: 0x4000|22,
2161 err_data: Vec::new(),
2162 msg: "Payment preimage didn't match payment hash",
2166 PendingHTLCRouting::ReceiveKeysend {
2168 incoming_cltv_expiry: hop_data.outgoing_cltv_value,
2171 return Err(ReceiveError {
2172 err_code: 0x4000|0x2000|3,
2173 err_data: Vec::new(),
2174 msg: "We require payment_secrets",
2179 Ok(PendingHTLCInfo {
2182 incoming_shared_secret: shared_secret,
2183 incoming_amt_msat: Some(amt_msat),
2184 outgoing_amt_msat: amt_msat,
2185 outgoing_cltv_value: hop_data.outgoing_cltv_value,
2189 fn decode_update_add_htlc_onion(&self, msg: &msgs::UpdateAddHTLC) -> PendingHTLCStatus {
2190 macro_rules! return_malformed_err {
2191 ($msg: expr, $err_code: expr) => {
2193 log_info!(self.logger, "Failed to accept/forward incoming HTLC: {}", $msg);
2194 return PendingHTLCStatus::Fail(HTLCFailureMsg::Malformed(msgs::UpdateFailMalformedHTLC {
2195 channel_id: msg.channel_id,
2196 htlc_id: msg.htlc_id,
2197 sha256_of_onion: Sha256::hash(&msg.onion_routing_packet.hop_data).into_inner(),
2198 failure_code: $err_code,
2204 if let Err(_) = msg.onion_routing_packet.public_key {
2205 return_malformed_err!("invalid ephemeral pubkey", 0x8000 | 0x4000 | 6);
2208 let shared_secret = self.node_signer.ecdh(
2209 Recipient::Node, &msg.onion_routing_packet.public_key.unwrap(), None
2210 ).unwrap().secret_bytes();
2212 if msg.onion_routing_packet.version != 0 {
2213 //TODO: Spec doesn't indicate if we should only hash hop_data here (and in other
2214 //sha256_of_onion error data packets), or the entire onion_routing_packet. Either way,
2215 //the hash doesn't really serve any purpose - in the case of hashing all data, the
2216 //receiving node would have to brute force to figure out which version was put in the
2217 //packet by the node that send us the message, in the case of hashing the hop_data, the
2218 //node knows the HMAC matched, so they already know what is there...
2219 return_malformed_err!("Unknown onion packet version", 0x8000 | 0x4000 | 4);
2221 macro_rules! return_err {
2222 ($msg: expr, $err_code: expr, $data: expr) => {
2224 log_info!(self.logger, "Failed to accept/forward incoming HTLC: {}", $msg);
2225 return PendingHTLCStatus::Fail(HTLCFailureMsg::Relay(msgs::UpdateFailHTLC {
2226 channel_id: msg.channel_id,
2227 htlc_id: msg.htlc_id,
2228 reason: HTLCFailReason::reason($err_code, $data.to_vec())
2229 .get_encrypted_failure_packet(&shared_secret, &None),
2235 let next_hop = match onion_utils::decode_next_payment_hop(shared_secret, &msg.onion_routing_packet.hop_data[..], msg.onion_routing_packet.hmac, msg.payment_hash) {
2237 Err(onion_utils::OnionDecodeErr::Malformed { err_msg, err_code }) => {
2238 return_malformed_err!(err_msg, err_code);
2240 Err(onion_utils::OnionDecodeErr::Relay { err_msg, err_code }) => {
2241 return_err!(err_msg, err_code, &[0; 0]);
2245 let pending_forward_info = match next_hop {
2246 onion_utils::Hop::Receive(next_hop_data) => {
2248 match self.construct_recv_pending_htlc_info(next_hop_data, shared_secret, msg.payment_hash, msg.amount_msat, msg.cltv_expiry, None) {
2250 // Note that we could obviously respond immediately with an update_fulfill_htlc
2251 // message, however that would leak that we are the recipient of this payment, so
2252 // instead we stay symmetric with the forwarding case, only responding (after a
2253 // delay) once they've send us a commitment_signed!
2254 PendingHTLCStatus::Forward(info)
2256 Err(ReceiveError { err_code, err_data, msg }) => return_err!(msg, err_code, &err_data)
2259 onion_utils::Hop::Forward { next_hop_data, next_hop_hmac, new_packet_bytes } => {
2260 let new_pubkey = msg.onion_routing_packet.public_key.unwrap();
2261 let outgoing_packet = msgs::OnionPacket {
2263 public_key: onion_utils::next_hop_packet_pubkey(&self.secp_ctx, new_pubkey, &shared_secret),
2264 hop_data: new_packet_bytes,
2265 hmac: next_hop_hmac.clone(),
2268 let short_channel_id = match next_hop_data.format {
2269 msgs::OnionHopDataFormat::NonFinalNode { short_channel_id } => short_channel_id,
2270 msgs::OnionHopDataFormat::FinalNode { .. } => {
2271 return_err!("Final Node OnionHopData provided for us as an intermediary node", 0x4000 | 22, &[0;0]);
2275 PendingHTLCStatus::Forward(PendingHTLCInfo {
2276 routing: PendingHTLCRouting::Forward {
2277 onion_packet: outgoing_packet,
2280 payment_hash: msg.payment_hash.clone(),
2281 incoming_shared_secret: shared_secret,
2282 incoming_amt_msat: Some(msg.amount_msat),
2283 outgoing_amt_msat: next_hop_data.amt_to_forward,
2284 outgoing_cltv_value: next_hop_data.outgoing_cltv_value,
2289 if let &PendingHTLCStatus::Forward(PendingHTLCInfo { ref routing, ref outgoing_amt_msat, ref outgoing_cltv_value, .. }) = &pending_forward_info {
2290 // If short_channel_id is 0 here, we'll reject the HTLC as there cannot be a channel
2291 // with a short_channel_id of 0. This is important as various things later assume
2292 // short_channel_id is non-0 in any ::Forward.
2293 if let &PendingHTLCRouting::Forward { ref short_channel_id, .. } = routing {
2294 if let Some((err, mut code, chan_update)) = loop {
2295 let id_option = self.short_to_chan_info.read().unwrap().get(short_channel_id).cloned();
2296 let forwarding_chan_info_opt = match id_option {
2297 None => { // unknown_next_peer
2298 // Note that this is likely a timing oracle for detecting whether an scid is a
2299 // phantom or an intercept.
2300 if (self.default_configuration.accept_intercept_htlcs &&
2301 fake_scid::is_valid_intercept(&self.fake_scid_rand_bytes, *short_channel_id, &self.genesis_hash)) ||
2302 fake_scid::is_valid_phantom(&self.fake_scid_rand_bytes, *short_channel_id, &self.genesis_hash)
2306 break Some(("Don't have available channel for forwarding as requested.", 0x4000 | 10, None));
2309 Some((cp_id, id)) => Some((cp_id.clone(), id.clone())),
2311 let chan_update_opt = if let Some((counterparty_node_id, forwarding_id)) = forwarding_chan_info_opt {
2312 let per_peer_state = self.per_peer_state.read().unwrap();
2313 let peer_state_mutex_opt = per_peer_state.get(&counterparty_node_id);
2314 if peer_state_mutex_opt.is_none() {
2315 break Some(("Don't have available channel for forwarding as requested.", 0x4000 | 10, None));
2317 let mut peer_state_lock = peer_state_mutex_opt.unwrap().lock().unwrap();
2318 let peer_state = &mut *peer_state_lock;
2319 let chan = match peer_state.channel_by_id.get_mut(&forwarding_id) {
2321 // Channel was removed. The short_to_chan_info and channel_by_id maps
2322 // have no consistency guarantees.
2323 break Some(("Don't have available channel for forwarding as requested.", 0x4000 | 10, None));
2327 if !chan.should_announce() && !self.default_configuration.accept_forwards_to_priv_channels {
2328 // Note that the behavior here should be identical to the above block - we
2329 // should NOT reveal the existence or non-existence of a private channel if
2330 // we don't allow forwards outbound over them.
2331 break Some(("Refusing to forward to a private channel based on our config.", 0x4000 | 10, None));
2333 if chan.get_channel_type().supports_scid_privacy() && *short_channel_id != chan.outbound_scid_alias() {
2334 // `option_scid_alias` (referred to in LDK as `scid_privacy`) means
2335 // "refuse to forward unless the SCID alias was used", so we pretend
2336 // we don't have the channel here.
2337 break Some(("Refusing to forward over real channel SCID as our counterparty requested.", 0x4000 | 10, None));
2339 let chan_update_opt = self.get_channel_update_for_onion(*short_channel_id, chan).ok();
2341 // Note that we could technically not return an error yet here and just hope
2342 // that the connection is reestablished or monitor updated by the time we get
2343 // around to doing the actual forward, but better to fail early if we can and
2344 // hopefully an attacker trying to path-trace payments cannot make this occur
2345 // on a small/per-node/per-channel scale.
2346 if !chan.is_live() { // channel_disabled
2347 break Some(("Forwarding channel is not in a ready state.", 0x1000 | 20, chan_update_opt));
2349 if *outgoing_amt_msat < chan.get_counterparty_htlc_minimum_msat() { // amount_below_minimum
2350 break Some(("HTLC amount was below the htlc_minimum_msat", 0x1000 | 11, chan_update_opt));
2352 if let Err((err, code)) = chan.htlc_satisfies_config(&msg, *outgoing_amt_msat, *outgoing_cltv_value) {
2353 break Some((err, code, chan_update_opt));
2357 if (msg.cltv_expiry as u64) < (*outgoing_cltv_value) as u64 + MIN_CLTV_EXPIRY_DELTA as u64 {
2358 // We really should set `incorrect_cltv_expiry` here but as we're not
2359 // forwarding over a real channel we can't generate a channel_update
2360 // for it. Instead we just return a generic temporary_node_failure.
2362 "Forwarding node has tampered with the intended HTLC values or origin node has an obsolete cltv_expiry_delta",
2369 let cur_height = self.best_block.read().unwrap().height() + 1;
2370 // Theoretically, channel counterparty shouldn't send us a HTLC expiring now,
2371 // but we want to be robust wrt to counterparty packet sanitization (see
2372 // HTLC_FAIL_BACK_BUFFER rationale).
2373 if msg.cltv_expiry <= cur_height + HTLC_FAIL_BACK_BUFFER as u32 { // expiry_too_soon
2374 break Some(("CLTV expiry is too close", 0x1000 | 14, chan_update_opt));
2376 if msg.cltv_expiry > cur_height + CLTV_FAR_FAR_AWAY as u32 { // expiry_too_far
2377 break Some(("CLTV expiry is too far in the future", 21, None));
2379 // If the HTLC expires ~now, don't bother trying to forward it to our
2380 // counterparty. They should fail it anyway, but we don't want to bother with
2381 // the round-trips or risk them deciding they definitely want the HTLC and
2382 // force-closing to ensure they get it if we're offline.
2383 // We previously had a much more aggressive check here which tried to ensure
2384 // our counterparty receives an HTLC which has *our* risk threshold met on it,
2385 // but there is no need to do that, and since we're a bit conservative with our
2386 // risk threshold it just results in failing to forward payments.
2387 if (*outgoing_cltv_value) as u64 <= (cur_height + LATENCY_GRACE_PERIOD_BLOCKS) as u64 {
2388 break Some(("Outgoing CLTV value is too soon", 0x1000 | 14, chan_update_opt));
2394 let mut res = VecWriter(Vec::with_capacity(chan_update.serialized_length() + 2 + 8 + 2));
2395 if let Some(chan_update) = chan_update {
2396 if code == 0x1000 | 11 || code == 0x1000 | 12 {
2397 msg.amount_msat.write(&mut res).expect("Writes cannot fail");
2399 else if code == 0x1000 | 13 {
2400 msg.cltv_expiry.write(&mut res).expect("Writes cannot fail");
2402 else if code == 0x1000 | 20 {
2403 // TODO: underspecified, follow https://github.com/lightning/bolts/issues/791
2404 0u16.write(&mut res).expect("Writes cannot fail");
2406 (chan_update.serialized_length() as u16 + 2).write(&mut res).expect("Writes cannot fail");
2407 msgs::ChannelUpdate::TYPE.write(&mut res).expect("Writes cannot fail");
2408 chan_update.write(&mut res).expect("Writes cannot fail");
2409 } else if code & 0x1000 == 0x1000 {
2410 // If we're trying to return an error that requires a `channel_update` but
2411 // we're forwarding to a phantom or intercept "channel" (i.e. cannot
2412 // generate an update), just use the generic "temporary_node_failure"
2416 return_err!(err, code, &res.0[..]);
2421 pending_forward_info
2424 /// Gets the current [`channel_update`] for the given channel. This first checks if the channel is
2425 /// public, and thus should be called whenever the result is going to be passed out in a
2426 /// [`MessageSendEvent::BroadcastChannelUpdate`] event.
2428 /// Note that in [`internal_closing_signed`], this function is called without the `peer_state`
2429 /// corresponding to the channel's counterparty locked, as the channel been removed from the
2430 /// storage and the `peer_state` lock has been dropped.
2432 /// [`channel_update`]: msgs::ChannelUpdate
2433 /// [`internal_closing_signed`]: Self::internal_closing_signed
2434 fn get_channel_update_for_broadcast(&self, chan: &Channel<<SP::Target as SignerProvider>::Signer>) -> Result<msgs::ChannelUpdate, LightningError> {
2435 if !chan.should_announce() {
2436 return Err(LightningError {
2437 err: "Cannot broadcast a channel_update for a private channel".to_owned(),
2438 action: msgs::ErrorAction::IgnoreError
2441 if chan.get_short_channel_id().is_none() {
2442 return Err(LightningError{err: "Channel not yet established".to_owned(), action: msgs::ErrorAction::IgnoreError});
2444 log_trace!(self.logger, "Attempting to generate broadcast channel update for channel {}", log_bytes!(chan.channel_id()));
2445 self.get_channel_update_for_unicast(chan)
2448 /// Gets the current [`channel_update`] for the given channel. This does not check if the channel
2449 /// is public (only returning an `Err` if the channel does not yet have an assigned SCID),
2450 /// and thus MUST NOT be called unless the recipient of the resulting message has already
2451 /// provided evidence that they know about the existence of the channel.
2453 /// Note that through [`internal_closing_signed`], this function is called without the
2454 /// `peer_state` corresponding to the channel's counterparty locked, as the channel been
2455 /// removed from the storage and the `peer_state` lock has been dropped.
2457 /// [`channel_update`]: msgs::ChannelUpdate
2458 /// [`internal_closing_signed`]: Self::internal_closing_signed
2459 fn get_channel_update_for_unicast(&self, chan: &Channel<<SP::Target as SignerProvider>::Signer>) -> Result<msgs::ChannelUpdate, LightningError> {
2460 log_trace!(self.logger, "Attempting to generate channel update for channel {}", log_bytes!(chan.channel_id()));
2461 let short_channel_id = match chan.get_short_channel_id().or(chan.latest_inbound_scid_alias()) {
2462 None => return Err(LightningError{err: "Channel not yet established".to_owned(), action: msgs::ErrorAction::IgnoreError}),
2466 self.get_channel_update_for_onion(short_channel_id, chan)
2468 fn get_channel_update_for_onion(&self, short_channel_id: u64, chan: &Channel<<SP::Target as SignerProvider>::Signer>) -> Result<msgs::ChannelUpdate, LightningError> {
2469 log_trace!(self.logger, "Generating channel update for channel {}", log_bytes!(chan.channel_id()));
2470 let were_node_one = self.our_network_pubkey.serialize()[..] < chan.get_counterparty_node_id().serialize()[..];
2472 let unsigned = msgs::UnsignedChannelUpdate {
2473 chain_hash: self.genesis_hash,
2475 timestamp: chan.get_update_time_counter(),
2476 flags: (!were_node_one) as u8 | ((!chan.is_live() as u8) << 1),
2477 cltv_expiry_delta: chan.get_cltv_expiry_delta(),
2478 htlc_minimum_msat: chan.get_counterparty_htlc_minimum_msat(),
2479 htlc_maximum_msat: chan.get_announced_htlc_max_msat(),
2480 fee_base_msat: chan.get_outbound_forwarding_fee_base_msat(),
2481 fee_proportional_millionths: chan.get_fee_proportional_millionths(),
2482 excess_data: Vec::new(),
2484 // Panic on failure to signal LDK should be restarted to retry signing the `ChannelUpdate`.
2485 // If we returned an error and the `node_signer` cannot provide a signature for whatever
2486 // reason`, we wouldn't be able to receive inbound payments through the corresponding
2488 let sig = self.node_signer.sign_gossip_message(msgs::UnsignedGossipMessage::ChannelUpdate(&unsigned)).unwrap();
2490 Ok(msgs::ChannelUpdate {
2497 pub(crate) fn test_send_payment_along_path(&self, path: &Vec<RouteHop>, payment_hash: &PaymentHash, payment_secret: &Option<PaymentSecret>, total_value: u64, cur_height: u32, payment_id: PaymentId, keysend_preimage: &Option<PaymentPreimage>, session_priv_bytes: [u8; 32]) -> Result<(), APIError> {
2498 let _lck = self.total_consistency_lock.read().unwrap();
2499 self.send_payment_along_path(path, payment_hash, payment_secret, total_value, cur_height, payment_id, keysend_preimage, session_priv_bytes)
2502 fn send_payment_along_path(&self, path: &Vec<RouteHop>, payment_hash: &PaymentHash, payment_secret: &Option<PaymentSecret>, total_value: u64, cur_height: u32, payment_id: PaymentId, keysend_preimage: &Option<PaymentPreimage>, session_priv_bytes: [u8; 32]) -> Result<(), APIError> {
2503 // The top-level caller should hold the total_consistency_lock read lock.
2504 debug_assert!(self.total_consistency_lock.try_write().is_err());
2506 log_trace!(self.logger, "Attempting to send payment for path with next hop {}", path.first().unwrap().short_channel_id);
2507 let prng_seed = self.entropy_source.get_secure_random_bytes();
2508 let session_priv = SecretKey::from_slice(&session_priv_bytes[..]).expect("RNG is busted");
2510 let onion_keys = onion_utils::construct_onion_keys(&self.secp_ctx, &path, &session_priv)
2511 .map_err(|_| APIError::InvalidRoute{err: "Pubkey along hop was maliciously selected".to_owned()})?;
2512 let (onion_payloads, htlc_msat, htlc_cltv) = onion_utils::build_onion_payloads(path, total_value, payment_secret, cur_height, keysend_preimage)?;
2513 if onion_utils::route_size_insane(&onion_payloads) {
2514 return Err(APIError::InvalidRoute{err: "Route size too large considering onion data".to_owned()});
2516 let onion_packet = onion_utils::construct_onion_packet(onion_payloads, onion_keys, prng_seed, payment_hash);
2518 let err: Result<(), _> = loop {
2519 let (counterparty_node_id, id) = match self.short_to_chan_info.read().unwrap().get(&path.first().unwrap().short_channel_id) {
2520 None => return Err(APIError::ChannelUnavailable{err: "No channel available with first hop!".to_owned()}),
2521 Some((cp_id, chan_id)) => (cp_id.clone(), chan_id.clone()),
2524 let per_peer_state = self.per_peer_state.read().unwrap();
2525 let peer_state_mutex = per_peer_state.get(&counterparty_node_id)
2526 .ok_or_else(|| APIError::ChannelUnavailable{err: "No peer matching the path's first hop found!".to_owned() })?;
2527 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
2528 let peer_state = &mut *peer_state_lock;
2529 if let hash_map::Entry::Occupied(mut chan) = peer_state.channel_by_id.entry(id) {
2530 if !chan.get().is_live() {
2531 return Err(APIError::ChannelUnavailable{err: "Peer for first hop currently disconnected".to_owned()});
2533 let funding_txo = chan.get().get_funding_txo().unwrap();
2534 let send_res = chan.get_mut().send_htlc_and_commit(htlc_msat, payment_hash.clone(),
2535 htlc_cltv, HTLCSource::OutboundRoute {
2537 session_priv: session_priv.clone(),
2538 first_hop_htlc_msat: htlc_msat,
2540 payment_secret: payment_secret.clone(),
2541 }, onion_packet, &self.logger);
2542 match break_chan_entry!(self, send_res, chan) {
2543 Some(monitor_update) => {
2544 let update_id = monitor_update.update_id;
2545 let update_res = self.chain_monitor.update_channel(funding_txo, monitor_update);
2546 if let Err(e) = handle_new_monitor_update!(self, update_res, update_id, peer_state_lock, peer_state, per_peer_state, chan) {
2549 if update_res == ChannelMonitorUpdateStatus::InProgress {
2550 // Note that MonitorUpdateInProgress here indicates (per function
2551 // docs) that we will resend the commitment update once monitor
2552 // updating completes. Therefore, we must return an error
2553 // indicating that it is unsafe to retry the payment wholesale,
2554 // which we do in the send_payment check for
2555 // MonitorUpdateInProgress, below.
2556 return Err(APIError::MonitorUpdateInProgress);
2562 // The channel was likely removed after we fetched the id from the
2563 // `short_to_chan_info` map, but before we successfully locked the
2564 // `channel_by_id` map.
2565 // This can occur as no consistency guarantees exists between the two maps.
2566 return Err(APIError::ChannelUnavailable{err: "No channel available with first hop!".to_owned()});
2571 match handle_error!(self, err, path.first().unwrap().pubkey) {
2572 Ok(_) => unreachable!(),
2574 Err(APIError::ChannelUnavailable { err: e.err })
2579 /// Sends a payment along a given route.
2581 /// Value parameters are provided via the last hop in route, see documentation for [`RouteHop`]
2582 /// fields for more info.
2584 /// May generate [`UpdateHTLCs`] message(s) event on success, which should be relayed (e.g. via
2585 /// [`PeerManager::process_events`]).
2587 /// # Avoiding Duplicate Payments
2589 /// If a pending payment is currently in-flight with the same [`PaymentId`] provided, this
2590 /// method will error with an [`APIError::InvalidRoute`]. Note, however, that once a payment
2591 /// is no longer pending (either via [`ChannelManager::abandon_payment`], or handling of an
2592 /// [`Event::PaymentSent`] or [`Event::PaymentFailed`]) LDK will not stop you from sending a
2593 /// second payment with the same [`PaymentId`].
2595 /// Thus, in order to ensure duplicate payments are not sent, you should implement your own
2596 /// tracking of payments, including state to indicate once a payment has completed. Because you
2597 /// should also ensure that [`PaymentHash`]es are not re-used, for simplicity, you should
2598 /// consider using the [`PaymentHash`] as the key for tracking payments. In that case, the
2599 /// [`PaymentId`] should be a copy of the [`PaymentHash`] bytes.
2601 /// Additionally, in the scenario where we begin the process of sending a payment, but crash
2602 /// before `send_payment` returns (or prior to [`ChannelMonitorUpdate`] persistence if you're
2603 /// using [`ChannelMonitorUpdateStatus::InProgress`]), the payment may be lost on restart. See
2604 /// [`ChannelManager::list_recent_payments`] for more information.
2606 /// # Possible Error States on [`PaymentSendFailure`]
2608 /// Each path may have a different return value, and [`PaymentSendFailure`] may return a `Vec` with
2609 /// each entry matching the corresponding-index entry in the route paths, see
2610 /// [`PaymentSendFailure`] for more info.
2612 /// In general, a path may raise:
2613 /// * [`APIError::InvalidRoute`] when an invalid route or forwarding parameter (cltv_delta, fee,
2614 /// node public key) is specified.
2615 /// * [`APIError::ChannelUnavailable`] if the next-hop channel is not available for updates
2616 /// (including due to previous monitor update failure or new permanent monitor update
2618 /// * [`APIError::MonitorUpdateInProgress`] if a new monitor update failure prevented sending the
2619 /// relevant updates.
2621 /// Note that depending on the type of the [`PaymentSendFailure`] the HTLC may have been
2622 /// irrevocably committed to on our end. In such a case, do NOT retry the payment with a
2623 /// different route unless you intend to pay twice!
2625 /// # A caution on `payment_secret`
2627 /// `payment_secret` is unrelated to `payment_hash` (or [`PaymentPreimage`]) and exists to
2628 /// authenticate the sender to the recipient and prevent payment-probing (deanonymization)
2629 /// attacks. For newer nodes, it will be provided to you in the invoice. If you do not have one,
2630 /// the [`Route`] must not contain multiple paths as multi-path payments require a
2631 /// recipient-provided `payment_secret`.
2633 /// If a `payment_secret` *is* provided, we assume that the invoice had the payment_secret
2634 /// feature bit set (either as required or as available). If multiple paths are present in the
2635 /// [`Route`], we assume the invoice had the basic_mpp feature set.
2637 /// [`Event::PaymentSent`]: events::Event::PaymentSent
2638 /// [`Event::PaymentFailed`]: events::Event::PaymentFailed
2639 /// [`UpdateHTLCs`]: events::MessageSendEvent::UpdateHTLCs
2640 /// [`PeerManager::process_events`]: crate::ln::peer_handler::PeerManager::process_events
2641 /// [`ChannelMonitorUpdateStatus::InProgress`]: crate::chain::ChannelMonitorUpdateStatus::InProgress
2642 pub fn send_payment(&self, route: &Route, payment_hash: PaymentHash, payment_secret: &Option<PaymentSecret>, payment_id: PaymentId) -> Result<(), PaymentSendFailure> {
2643 let best_block_height = self.best_block.read().unwrap().height();
2644 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
2645 self.pending_outbound_payments
2646 .send_payment_with_route(route, payment_hash, payment_secret, payment_id, &self.entropy_source, &self.node_signer, best_block_height,
2647 |path, payment_hash, payment_secret, total_value, cur_height, payment_id, keysend_preimage, session_priv|
2648 self.send_payment_along_path(path, payment_hash, payment_secret, total_value, cur_height, payment_id, keysend_preimage, session_priv))
2651 /// Similar to [`ChannelManager::send_payment`], but will automatically find a route based on
2652 /// `route_params` and retry failed payment paths based on `retry_strategy`.
2653 pub fn send_payment_with_retry(&self, payment_hash: PaymentHash, payment_secret: &Option<PaymentSecret>, payment_id: PaymentId, route_params: RouteParameters, retry_strategy: Retry) -> Result<(), RetryableSendFailure> {
2654 let best_block_height = self.best_block.read().unwrap().height();
2655 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
2656 self.pending_outbound_payments
2657 .send_payment(payment_hash, payment_secret, payment_id, retry_strategy, route_params,
2658 &self.router, self.list_usable_channels(), || self.compute_inflight_htlcs(),
2659 &self.entropy_source, &self.node_signer, best_block_height, &self.logger,
2660 &self.pending_events,
2661 |path, payment_hash, payment_secret, total_value, cur_height, payment_id, keysend_preimage, session_priv|
2662 self.send_payment_along_path(path, payment_hash, payment_secret, total_value, cur_height, payment_id, keysend_preimage, session_priv))
2666 pub(super) fn test_send_payment_internal(&self, route: &Route, payment_hash: PaymentHash, payment_secret: &Option<PaymentSecret>, keysend_preimage: Option<PaymentPreimage>, payment_id: PaymentId, recv_value_msat: Option<u64>, onion_session_privs: Vec<[u8; 32]>) -> Result<(), PaymentSendFailure> {
2667 let best_block_height = self.best_block.read().unwrap().height();
2668 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
2669 self.pending_outbound_payments.test_send_payment_internal(route, payment_hash, payment_secret, keysend_preimage, payment_id, recv_value_msat, onion_session_privs, &self.node_signer, best_block_height,
2670 |path, payment_hash, payment_secret, total_value, cur_height, payment_id, keysend_preimage, session_priv|
2671 self.send_payment_along_path(path, payment_hash, payment_secret, total_value, cur_height, payment_id, keysend_preimage, session_priv))
2675 pub(crate) fn test_add_new_pending_payment(&self, payment_hash: PaymentHash, payment_secret: Option<PaymentSecret>, payment_id: PaymentId, route: &Route) -> Result<Vec<[u8; 32]>, PaymentSendFailure> {
2676 let best_block_height = self.best_block.read().unwrap().height();
2677 self.pending_outbound_payments.test_add_new_pending_payment(payment_hash, payment_secret, payment_id, route, None, &self.entropy_source, best_block_height)
2681 /// Signals that no further retries for the given payment should occur. Useful if you have a
2682 /// pending outbound payment with retries remaining, but wish to stop retrying the payment before
2683 /// retries are exhausted.
2685 /// If no [`Event::PaymentFailed`] event had been generated before, one will be generated as soon
2686 /// as there are no remaining pending HTLCs for this payment.
2688 /// Note that calling this method does *not* prevent a payment from succeeding. You must still
2689 /// wait until you receive either a [`Event::PaymentFailed`] or [`Event::PaymentSent`] event to
2690 /// determine the ultimate status of a payment.
2692 /// If an [`Event::PaymentFailed`] event is generated and we restart without this
2693 /// [`ChannelManager`] having been persisted, another [`Event::PaymentFailed`] may be generated.
2695 /// [`Event::PaymentFailed`]: events::Event::PaymentFailed
2696 /// [`Event::PaymentSent`]: events::Event::PaymentSent
2697 pub fn abandon_payment(&self, payment_id: PaymentId) {
2698 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
2699 self.pending_outbound_payments.abandon_payment(payment_id, &self.pending_events);
2702 /// Send a spontaneous payment, which is a payment that does not require the recipient to have
2703 /// generated an invoice. Optionally, you may specify the preimage. If you do choose to specify
2704 /// the preimage, it must be a cryptographically secure random value that no intermediate node
2705 /// would be able to guess -- otherwise, an intermediate node may claim the payment and it will
2706 /// never reach the recipient.
2708 /// See [`send_payment`] documentation for more details on the return value of this function
2709 /// and idempotency guarantees provided by the [`PaymentId`] key.
2711 /// Similar to regular payments, you MUST NOT reuse a `payment_preimage` value. See
2712 /// [`send_payment`] for more information about the risks of duplicate preimage usage.
2714 /// Note that `route` must have exactly one path.
2716 /// [`send_payment`]: Self::send_payment
2717 pub fn send_spontaneous_payment(&self, route: &Route, payment_preimage: Option<PaymentPreimage>, payment_id: PaymentId) -> Result<PaymentHash, PaymentSendFailure> {
2718 let best_block_height = self.best_block.read().unwrap().height();
2719 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
2720 self.pending_outbound_payments.send_spontaneous_payment_with_route(
2721 route, payment_preimage, payment_id, &self.entropy_source, &self.node_signer,
2723 |path, payment_hash, payment_secret, total_value, cur_height, payment_id, keysend_preimage, session_priv|
2724 self.send_payment_along_path(path, payment_hash, payment_secret, total_value, cur_height, payment_id, keysend_preimage, session_priv))
2727 /// Similar to [`ChannelManager::send_spontaneous_payment`], but will automatically find a route
2728 /// based on `route_params` and retry failed payment paths based on `retry_strategy`.
2730 /// See [`PaymentParameters::for_keysend`] for help in constructing `route_params` for spontaneous
2733 /// [`PaymentParameters::for_keysend`]: crate::routing::router::PaymentParameters::for_keysend
2734 pub fn send_spontaneous_payment_with_retry(&self, payment_preimage: Option<PaymentPreimage>, payment_id: PaymentId, route_params: RouteParameters, retry_strategy: Retry) -> Result<PaymentHash, RetryableSendFailure> {
2735 let best_block_height = self.best_block.read().unwrap().height();
2736 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
2737 self.pending_outbound_payments.send_spontaneous_payment(payment_preimage, payment_id,
2738 retry_strategy, route_params, &self.router, self.list_usable_channels(),
2739 || self.compute_inflight_htlcs(), &self.entropy_source, &self.node_signer, best_block_height,
2740 &self.logger, &self.pending_events,
2741 |path, payment_hash, payment_secret, total_value, cur_height, payment_id, keysend_preimage, session_priv|
2742 self.send_payment_along_path(path, payment_hash, payment_secret, total_value, cur_height, payment_id, keysend_preimage, session_priv))
2745 /// Send a payment that is probing the given route for liquidity. We calculate the
2746 /// [`PaymentHash`] of probes based on a static secret and a random [`PaymentId`], which allows
2747 /// us to easily discern them from real payments.
2748 pub fn send_probe(&self, hops: Vec<RouteHop>) -> Result<(PaymentHash, PaymentId), PaymentSendFailure> {
2749 let best_block_height = self.best_block.read().unwrap().height();
2750 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
2751 self.pending_outbound_payments.send_probe(hops, self.probing_cookie_secret, &self.entropy_source, &self.node_signer, best_block_height,
2752 |path, payment_hash, payment_secret, total_value, cur_height, payment_id, keysend_preimage, session_priv|
2753 self.send_payment_along_path(path, payment_hash, payment_secret, total_value, cur_height, payment_id, keysend_preimage, session_priv))
2756 /// Returns whether a payment with the given [`PaymentHash`] and [`PaymentId`] is, in fact, a
2759 pub(crate) fn payment_is_probe(&self, payment_hash: &PaymentHash, payment_id: &PaymentId) -> bool {
2760 outbound_payment::payment_is_probe(payment_hash, payment_id, self.probing_cookie_secret)
2763 /// Handles the generation of a funding transaction, optionally (for tests) with a function
2764 /// which checks the correctness of the funding transaction given the associated channel.
2765 fn funding_transaction_generated_intern<FundingOutput: Fn(&Channel<<SP::Target as SignerProvider>::Signer>, &Transaction) -> Result<OutPoint, APIError>>(
2766 &self, temporary_channel_id: &[u8; 32], counterparty_node_id: &PublicKey, funding_transaction: Transaction, find_funding_output: FundingOutput
2767 ) -> Result<(), APIError> {
2768 let per_peer_state = self.per_peer_state.read().unwrap();
2769 let peer_state_mutex = per_peer_state.get(counterparty_node_id)
2770 .ok_or_else(|| APIError::ChannelUnavailable { err: format!("Can't find a peer matching the passed counterparty node_id {}", counterparty_node_id) })?;
2772 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
2773 let peer_state = &mut *peer_state_lock;
2776 match peer_state.channel_by_id.remove(temporary_channel_id) {
2778 let funding_txo = find_funding_output(&chan, &funding_transaction)?;
2780 (chan.get_outbound_funding_created(funding_transaction, funding_txo, &self.logger)
2781 .map_err(|e| if let ChannelError::Close(msg) = e {
2782 MsgHandleErrInternal::from_finish_shutdown(msg, chan.channel_id(), chan.get_user_id(), chan.force_shutdown(true), None)
2783 } else { unreachable!(); })
2786 None => { return Err(APIError::ChannelUnavailable { err: format!("Channel with id {} not found for the passed counterparty node_id {}", log_bytes!(*temporary_channel_id), counterparty_node_id) }) },
2789 match handle_error!(self, res, chan.get_counterparty_node_id()) {
2790 Ok(funding_msg) => {
2793 Err(_) => { return Err(APIError::ChannelUnavailable {
2794 err: "Signer refused to sign the initial commitment transaction".to_owned()
2799 peer_state.pending_msg_events.push(events::MessageSendEvent::SendFundingCreated {
2800 node_id: chan.get_counterparty_node_id(),
2803 match peer_state.channel_by_id.entry(chan.channel_id()) {
2804 hash_map::Entry::Occupied(_) => {
2805 panic!("Generated duplicate funding txid?");
2807 hash_map::Entry::Vacant(e) => {
2808 let mut id_to_peer = self.id_to_peer.lock().unwrap();
2809 if id_to_peer.insert(chan.channel_id(), chan.get_counterparty_node_id()).is_some() {
2810 panic!("id_to_peer map already contained funding txid, which shouldn't be possible");
2819 pub(crate) fn funding_transaction_generated_unchecked(&self, temporary_channel_id: &[u8; 32], counterparty_node_id: &PublicKey, funding_transaction: Transaction, output_index: u16) -> Result<(), APIError> {
2820 self.funding_transaction_generated_intern(temporary_channel_id, counterparty_node_id, funding_transaction, |_, tx| {
2821 Ok(OutPoint { txid: tx.txid(), index: output_index })
2825 /// Call this upon creation of a funding transaction for the given channel.
2827 /// Returns an [`APIError::APIMisuseError`] if the funding_transaction spent non-SegWit outputs
2828 /// or if no output was found which matches the parameters in [`Event::FundingGenerationReady`].
2830 /// Returns [`APIError::APIMisuseError`] if the funding transaction is not final for propagation
2831 /// across the p2p network.
2833 /// Returns [`APIError::ChannelUnavailable`] if a funding transaction has already been provided
2834 /// for the channel or if the channel has been closed as indicated by [`Event::ChannelClosed`].
2836 /// May panic if the output found in the funding transaction is duplicative with some other
2837 /// channel (note that this should be trivially prevented by using unique funding transaction
2838 /// keys per-channel).
2840 /// Do NOT broadcast the funding transaction yourself. When we have safely received our
2841 /// counterparty's signature the funding transaction will automatically be broadcast via the
2842 /// [`BroadcasterInterface`] provided when this `ChannelManager` was constructed.
2844 /// Note that this includes RBF or similar transaction replacement strategies - lightning does
2845 /// not currently support replacing a funding transaction on an existing channel. Instead,
2846 /// create a new channel with a conflicting funding transaction.
2848 /// Note to keep the miner incentives aligned in moving the blockchain forward, we recommend
2849 /// the wallet software generating the funding transaction to apply anti-fee sniping as
2850 /// implemented by Bitcoin Core wallet. See <https://bitcoinops.org/en/topics/fee-sniping/>
2851 /// for more details.
2853 /// [`Event::FundingGenerationReady`]: crate::events::Event::FundingGenerationReady
2854 /// [`Event::ChannelClosed`]: crate::events::Event::ChannelClosed
2855 pub fn funding_transaction_generated(&self, temporary_channel_id: &[u8; 32], counterparty_node_id: &PublicKey, funding_transaction: Transaction) -> Result<(), APIError> {
2856 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
2858 for inp in funding_transaction.input.iter() {
2859 if inp.witness.is_empty() {
2860 return Err(APIError::APIMisuseError {
2861 err: "Funding transaction must be fully signed and spend Segwit outputs".to_owned()
2866 let height = self.best_block.read().unwrap().height();
2867 // Transactions are evaluated as final by network mempools at the next block. However, the modules
2868 // constituting our Lightning node might not have perfect sync about their blockchain views. Thus, if
2869 // the wallet module is in advance on the LDK view, allow one more block of headroom.
2870 if !funding_transaction.input.iter().all(|input| input.sequence == Sequence::MAX) && LockTime::from(funding_transaction.lock_time).is_block_height() && funding_transaction.lock_time.0 > height + 2 {
2871 return Err(APIError::APIMisuseError {
2872 err: "Funding transaction absolute timelock is non-final".to_owned()
2876 self.funding_transaction_generated_intern(temporary_channel_id, counterparty_node_id, funding_transaction, |chan, tx| {
2877 let mut output_index = None;
2878 let expected_spk = chan.get_funding_redeemscript().to_v0_p2wsh();
2879 for (idx, outp) in tx.output.iter().enumerate() {
2880 if outp.script_pubkey == expected_spk && outp.value == chan.get_value_satoshis() {
2881 if output_index.is_some() {
2882 return Err(APIError::APIMisuseError {
2883 err: "Multiple outputs matched the expected script and value".to_owned()
2886 if idx > u16::max_value() as usize {
2887 return Err(APIError::APIMisuseError {
2888 err: "Transaction had more than 2^16 outputs, which is not supported".to_owned()
2891 output_index = Some(idx as u16);
2894 if output_index.is_none() {
2895 return Err(APIError::APIMisuseError {
2896 err: "No output matched the script_pubkey and value in the FundingGenerationReady event".to_owned()
2899 Ok(OutPoint { txid: tx.txid(), index: output_index.unwrap() })
2903 /// Atomically updates the [`ChannelConfig`] for the given channels.
2905 /// Once the updates are applied, each eligible channel (advertised with a known short channel
2906 /// ID and a change in [`forwarding_fee_proportional_millionths`], [`forwarding_fee_base_msat`],
2907 /// or [`cltv_expiry_delta`]) has a [`BroadcastChannelUpdate`] event message generated
2908 /// containing the new [`ChannelUpdate`] message which should be broadcast to the network.
2910 /// Returns [`ChannelUnavailable`] when a channel is not found or an incorrect
2911 /// `counterparty_node_id` is provided.
2913 /// Returns [`APIMisuseError`] when a [`cltv_expiry_delta`] update is to be applied with a value
2914 /// below [`MIN_CLTV_EXPIRY_DELTA`].
2916 /// If an error is returned, none of the updates should be considered applied.
2918 /// [`forwarding_fee_proportional_millionths`]: ChannelConfig::forwarding_fee_proportional_millionths
2919 /// [`forwarding_fee_base_msat`]: ChannelConfig::forwarding_fee_base_msat
2920 /// [`cltv_expiry_delta`]: ChannelConfig::cltv_expiry_delta
2921 /// [`BroadcastChannelUpdate`]: events::MessageSendEvent::BroadcastChannelUpdate
2922 /// [`ChannelUpdate`]: msgs::ChannelUpdate
2923 /// [`ChannelUnavailable`]: APIError::ChannelUnavailable
2924 /// [`APIMisuseError`]: APIError::APIMisuseError
2925 pub fn update_channel_config(
2926 &self, counterparty_node_id: &PublicKey, channel_ids: &[[u8; 32]], config: &ChannelConfig,
2927 ) -> Result<(), APIError> {
2928 if config.cltv_expiry_delta < MIN_CLTV_EXPIRY_DELTA {
2929 return Err(APIError::APIMisuseError {
2930 err: format!("The chosen CLTV expiry delta is below the minimum of {}", MIN_CLTV_EXPIRY_DELTA),
2934 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(
2935 &self.total_consistency_lock, &self.persistence_notifier,
2937 let per_peer_state = self.per_peer_state.read().unwrap();
2938 let peer_state_mutex = per_peer_state.get(counterparty_node_id)
2939 .ok_or_else(|| APIError::ChannelUnavailable { err: format!("Can't find a peer matching the passed counterparty node_id {}", counterparty_node_id) })?;
2940 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
2941 let peer_state = &mut *peer_state_lock;
2942 for channel_id in channel_ids {
2943 if !peer_state.channel_by_id.contains_key(channel_id) {
2944 return Err(APIError::ChannelUnavailable {
2945 err: format!("Channel with ID {} was not found for the passed counterparty_node_id {}", log_bytes!(*channel_id), counterparty_node_id),
2949 for channel_id in channel_ids {
2950 let channel = peer_state.channel_by_id.get_mut(channel_id).unwrap();
2951 if !channel.update_config(config) {
2954 if let Ok(msg) = self.get_channel_update_for_broadcast(channel) {
2955 peer_state.pending_msg_events.push(events::MessageSendEvent::BroadcastChannelUpdate { msg });
2956 } else if let Ok(msg) = self.get_channel_update_for_unicast(channel) {
2957 peer_state.pending_msg_events.push(events::MessageSendEvent::SendChannelUpdate {
2958 node_id: channel.get_counterparty_node_id(),
2966 /// Attempts to forward an intercepted HTLC over the provided channel id and with the provided
2967 /// amount to forward. Should only be called in response to an [`HTLCIntercepted`] event.
2969 /// Intercepted HTLCs can be useful for Lightning Service Providers (LSPs) to open a just-in-time
2970 /// channel to a receiving node if the node lacks sufficient inbound liquidity.
2972 /// To make use of intercepted HTLCs, set [`UserConfig::accept_intercept_htlcs`] and use
2973 /// [`ChannelManager::get_intercept_scid`] to generate short channel id(s) to put in the
2974 /// receiver's invoice route hints. These route hints will signal to LDK to generate an
2975 /// [`HTLCIntercepted`] event when it receives the forwarded HTLC, and this method or
2976 /// [`ChannelManager::fail_intercepted_htlc`] MUST be called in response to the event.
2978 /// Note that LDK does not enforce fee requirements in `amt_to_forward_msat`, and will not stop
2979 /// you from forwarding more than you received.
2981 /// Errors if the event was not handled in time, in which case the HTLC was automatically failed
2984 /// [`UserConfig::accept_intercept_htlcs`]: crate::util::config::UserConfig::accept_intercept_htlcs
2985 /// [`HTLCIntercepted`]: events::Event::HTLCIntercepted
2986 // TODO: when we move to deciding the best outbound channel at forward time, only take
2987 // `next_node_id` and not `next_hop_channel_id`
2988 pub fn forward_intercepted_htlc(&self, intercept_id: InterceptId, next_hop_channel_id: &[u8; 32], next_node_id: PublicKey, amt_to_forward_msat: u64) -> Result<(), APIError> {
2989 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
2991 let next_hop_scid = {
2992 let peer_state_lock = self.per_peer_state.read().unwrap();
2993 let peer_state_mutex = peer_state_lock.get(&next_node_id)
2994 .ok_or_else(|| APIError::ChannelUnavailable { err: format!("Can't find a peer matching the passed counterparty node_id {}", next_node_id) })?;
2995 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
2996 let peer_state = &mut *peer_state_lock;
2997 match peer_state.channel_by_id.get(next_hop_channel_id) {
2999 if !chan.is_usable() {
3000 return Err(APIError::ChannelUnavailable {
3001 err: format!("Channel with id {} not fully established", log_bytes!(*next_hop_channel_id))
3004 chan.get_short_channel_id().unwrap_or(chan.outbound_scid_alias())
3006 None => return Err(APIError::ChannelUnavailable {
3007 err: format!("Channel with id {} not found for the passed counterparty node_id {}", log_bytes!(*next_hop_channel_id), next_node_id)
3012 let payment = self.pending_intercepted_htlcs.lock().unwrap().remove(&intercept_id)
3013 .ok_or_else(|| APIError::APIMisuseError {
3014 err: format!("Payment with intercept id {} not found", log_bytes!(intercept_id.0))
3017 let routing = match payment.forward_info.routing {
3018 PendingHTLCRouting::Forward { onion_packet, .. } => {
3019 PendingHTLCRouting::Forward { onion_packet, short_channel_id: next_hop_scid }
3021 _ => unreachable!() // Only `PendingHTLCRouting::Forward`s are intercepted
3023 let pending_htlc_info = PendingHTLCInfo {
3024 outgoing_amt_msat: amt_to_forward_msat, routing, ..payment.forward_info
3027 let mut per_source_pending_forward = [(
3028 payment.prev_short_channel_id,
3029 payment.prev_funding_outpoint,
3030 payment.prev_user_channel_id,
3031 vec![(pending_htlc_info, payment.prev_htlc_id)]
3033 self.forward_htlcs(&mut per_source_pending_forward);
3037 /// Fails the intercepted HTLC indicated by intercept_id. Should only be called in response to
3038 /// an [`HTLCIntercepted`] event. See [`ChannelManager::forward_intercepted_htlc`].
3040 /// Errors if the event was not handled in time, in which case the HTLC was automatically failed
3043 /// [`HTLCIntercepted`]: events::Event::HTLCIntercepted
3044 pub fn fail_intercepted_htlc(&self, intercept_id: InterceptId) -> Result<(), APIError> {
3045 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
3047 let payment = self.pending_intercepted_htlcs.lock().unwrap().remove(&intercept_id)
3048 .ok_or_else(|| APIError::APIMisuseError {
3049 err: format!("Payment with intercept id {} not found", log_bytes!(intercept_id.0))
3052 if let PendingHTLCRouting::Forward { short_channel_id, .. } = payment.forward_info.routing {
3053 let htlc_source = HTLCSource::PreviousHopData(HTLCPreviousHopData {
3054 short_channel_id: payment.prev_short_channel_id,
3055 outpoint: payment.prev_funding_outpoint,
3056 htlc_id: payment.prev_htlc_id,
3057 incoming_packet_shared_secret: payment.forward_info.incoming_shared_secret,
3058 phantom_shared_secret: None,
3061 let failure_reason = HTLCFailReason::from_failure_code(0x4000 | 10);
3062 let destination = HTLCDestination::UnknownNextHop { requested_forward_scid: short_channel_id };
3063 self.fail_htlc_backwards_internal(&htlc_source, &payment.forward_info.payment_hash, &failure_reason, destination);
3064 } else { unreachable!() } // Only `PendingHTLCRouting::Forward`s are intercepted
3069 /// Processes HTLCs which are pending waiting on random forward delay.
3071 /// Should only really ever be called in response to a PendingHTLCsForwardable event.
3072 /// Will likely generate further events.
3073 pub fn process_pending_htlc_forwards(&self) {
3074 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
3076 let mut new_events = Vec::new();
3077 let mut failed_forwards = Vec::new();
3078 let mut phantom_receives: Vec<(u64, OutPoint, u128, Vec<(PendingHTLCInfo, u64)>)> = Vec::new();
3080 let mut forward_htlcs = HashMap::new();
3081 mem::swap(&mut forward_htlcs, &mut self.forward_htlcs.lock().unwrap());
3083 for (short_chan_id, mut pending_forwards) in forward_htlcs {
3084 if short_chan_id != 0 {
3085 macro_rules! forwarding_channel_not_found {
3087 for forward_info in pending_forwards.drain(..) {
3088 match forward_info {
3089 HTLCForwardInfo::AddHTLC(PendingAddHTLCInfo {
3090 prev_short_channel_id, prev_htlc_id, prev_funding_outpoint, prev_user_channel_id,
3091 forward_info: PendingHTLCInfo {
3092 routing, incoming_shared_secret, payment_hash, outgoing_amt_msat,
3093 outgoing_cltv_value, incoming_amt_msat: _
3096 macro_rules! failure_handler {
3097 ($msg: expr, $err_code: expr, $err_data: expr, $phantom_ss: expr, $next_hop_unknown: expr) => {
3098 log_info!(self.logger, "Failed to accept/forward incoming HTLC: {}", $msg);
3100 let htlc_source = HTLCSource::PreviousHopData(HTLCPreviousHopData {
3101 short_channel_id: prev_short_channel_id,
3102 outpoint: prev_funding_outpoint,
3103 htlc_id: prev_htlc_id,
3104 incoming_packet_shared_secret: incoming_shared_secret,
3105 phantom_shared_secret: $phantom_ss,
3108 let reason = if $next_hop_unknown {
3109 HTLCDestination::UnknownNextHop { requested_forward_scid: short_chan_id }
3111 HTLCDestination::FailedPayment{ payment_hash }
3114 failed_forwards.push((htlc_source, payment_hash,
3115 HTLCFailReason::reason($err_code, $err_data),
3121 macro_rules! fail_forward {
3122 ($msg: expr, $err_code: expr, $err_data: expr, $phantom_ss: expr) => {
3124 failure_handler!($msg, $err_code, $err_data, $phantom_ss, true);
3128 macro_rules! failed_payment {
3129 ($msg: expr, $err_code: expr, $err_data: expr, $phantom_ss: expr) => {
3131 failure_handler!($msg, $err_code, $err_data, $phantom_ss, false);
3135 if let PendingHTLCRouting::Forward { onion_packet, .. } = routing {
3136 let phantom_pubkey_res = self.node_signer.get_node_id(Recipient::PhantomNode);
3137 if phantom_pubkey_res.is_ok() && fake_scid::is_valid_phantom(&self.fake_scid_rand_bytes, short_chan_id, &self.genesis_hash) {
3138 let phantom_shared_secret = self.node_signer.ecdh(Recipient::PhantomNode, &onion_packet.public_key.unwrap(), None).unwrap().secret_bytes();
3139 let next_hop = match onion_utils::decode_next_payment_hop(phantom_shared_secret, &onion_packet.hop_data, onion_packet.hmac, payment_hash) {
3141 Err(onion_utils::OnionDecodeErr::Malformed { err_msg, err_code }) => {
3142 let sha256_of_onion = Sha256::hash(&onion_packet.hop_data).into_inner();
3143 // In this scenario, the phantom would have sent us an
3144 // `update_fail_malformed_htlc`, meaning here we encrypt the error as
3145 // if it came from us (the second-to-last hop) but contains the sha256
3147 failed_payment!(err_msg, err_code, sha256_of_onion.to_vec(), None);
3149 Err(onion_utils::OnionDecodeErr::Relay { err_msg, err_code }) => {
3150 failed_payment!(err_msg, err_code, Vec::new(), Some(phantom_shared_secret));
3154 onion_utils::Hop::Receive(hop_data) => {
3155 match self.construct_recv_pending_htlc_info(hop_data, incoming_shared_secret, payment_hash, outgoing_amt_msat, outgoing_cltv_value, Some(phantom_shared_secret)) {
3156 Ok(info) => phantom_receives.push((prev_short_channel_id, prev_funding_outpoint, prev_user_channel_id, vec![(info, prev_htlc_id)])),
3157 Err(ReceiveError { err_code, err_data, msg }) => failed_payment!(msg, err_code, err_data, Some(phantom_shared_secret))
3163 fail_forward!(format!("Unknown short channel id {} for forward HTLC", short_chan_id), 0x4000 | 10, Vec::new(), None);
3166 fail_forward!(format!("Unknown short channel id {} for forward HTLC", short_chan_id), 0x4000 | 10, Vec::new(), None);
3169 HTLCForwardInfo::FailHTLC { .. } => {
3170 // Channel went away before we could fail it. This implies
3171 // the channel is now on chain and our counterparty is
3172 // trying to broadcast the HTLC-Timeout, but that's their
3173 // problem, not ours.
3179 let (counterparty_node_id, forward_chan_id) = match self.short_to_chan_info.read().unwrap().get(&short_chan_id) {
3180 Some((cp_id, chan_id)) => (cp_id.clone(), chan_id.clone()),
3182 forwarding_channel_not_found!();
3186 let per_peer_state = self.per_peer_state.read().unwrap();
3187 let peer_state_mutex_opt = per_peer_state.get(&counterparty_node_id);
3188 if peer_state_mutex_opt.is_none() {
3189 forwarding_channel_not_found!();
3192 let mut peer_state_lock = peer_state_mutex_opt.unwrap().lock().unwrap();
3193 let peer_state = &mut *peer_state_lock;
3194 match peer_state.channel_by_id.entry(forward_chan_id) {
3195 hash_map::Entry::Vacant(_) => {
3196 forwarding_channel_not_found!();
3199 hash_map::Entry::Occupied(mut chan) => {
3200 for forward_info in pending_forwards.drain(..) {
3201 match forward_info {
3202 HTLCForwardInfo::AddHTLC(PendingAddHTLCInfo {
3203 prev_short_channel_id, prev_htlc_id, prev_funding_outpoint, prev_user_channel_id: _,
3204 forward_info: PendingHTLCInfo {
3205 incoming_shared_secret, payment_hash, outgoing_amt_msat, outgoing_cltv_value,
3206 routing: PendingHTLCRouting::Forward { onion_packet, .. }, incoming_amt_msat: _,
3209 log_trace!(self.logger, "Adding HTLC from short id {} with payment_hash {} to channel with short id {} after delay", prev_short_channel_id, log_bytes!(payment_hash.0), short_chan_id);
3210 let htlc_source = HTLCSource::PreviousHopData(HTLCPreviousHopData {
3211 short_channel_id: prev_short_channel_id,
3212 outpoint: prev_funding_outpoint,
3213 htlc_id: prev_htlc_id,
3214 incoming_packet_shared_secret: incoming_shared_secret,
3215 // Phantom payments are only PendingHTLCRouting::Receive.
3216 phantom_shared_secret: None,
3218 if let Err(e) = chan.get_mut().queue_add_htlc(outgoing_amt_msat,
3219 payment_hash, outgoing_cltv_value, htlc_source.clone(),
3220 onion_packet, &self.logger)
3222 if let ChannelError::Ignore(msg) = e {
3223 log_trace!(self.logger, "Failed to forward HTLC with payment_hash {}: {}", log_bytes!(payment_hash.0), msg);
3225 panic!("Stated return value requirements in send_htlc() were not met");
3227 let (failure_code, data) = self.get_htlc_temp_fail_err_and_data(0x1000|7, short_chan_id, chan.get());
3228 failed_forwards.push((htlc_source, payment_hash,
3229 HTLCFailReason::reason(failure_code, data),
3230 HTLCDestination::NextHopChannel { node_id: Some(chan.get().get_counterparty_node_id()), channel_id: forward_chan_id }
3235 HTLCForwardInfo::AddHTLC { .. } => {
3236 panic!("short_channel_id != 0 should imply any pending_forward entries are of type Forward");
3238 HTLCForwardInfo::FailHTLC { htlc_id, err_packet } => {
3239 log_trace!(self.logger, "Failing HTLC back to channel with short id {} (backward HTLC ID {}) after delay", short_chan_id, htlc_id);
3240 if let Err(e) = chan.get_mut().queue_fail_htlc(
3241 htlc_id, err_packet, &self.logger
3243 if let ChannelError::Ignore(msg) = e {
3244 log_trace!(self.logger, "Failed to fail HTLC with ID {} backwards to short_id {}: {}", htlc_id, short_chan_id, msg);
3246 panic!("Stated return value requirements in queue_fail_htlc() were not met");
3248 // fail-backs are best-effort, we probably already have one
3249 // pending, and if not that's OK, if not, the channel is on
3250 // the chain and sending the HTLC-Timeout is their problem.
3259 for forward_info in pending_forwards.drain(..) {
3260 match forward_info {
3261 HTLCForwardInfo::AddHTLC(PendingAddHTLCInfo {
3262 prev_short_channel_id, prev_htlc_id, prev_funding_outpoint, prev_user_channel_id,
3263 forward_info: PendingHTLCInfo {
3264 routing, incoming_shared_secret, payment_hash, outgoing_amt_msat, ..
3267 let (cltv_expiry, onion_payload, payment_data, phantom_shared_secret) = match routing {
3268 PendingHTLCRouting::Receive { payment_data, incoming_cltv_expiry, phantom_shared_secret } => {
3269 let _legacy_hop_data = Some(payment_data.clone());
3270 (incoming_cltv_expiry, OnionPayload::Invoice { _legacy_hop_data }, Some(payment_data), phantom_shared_secret)
3272 PendingHTLCRouting::ReceiveKeysend { payment_preimage, incoming_cltv_expiry } =>
3273 (incoming_cltv_expiry, OnionPayload::Spontaneous(payment_preimage), None, None),
3275 panic!("short_channel_id == 0 should imply any pending_forward entries are of type Receive");
3278 let mut claimable_htlc = ClaimableHTLC {
3279 prev_hop: HTLCPreviousHopData {
3280 short_channel_id: prev_short_channel_id,
3281 outpoint: prev_funding_outpoint,
3282 htlc_id: prev_htlc_id,
3283 incoming_packet_shared_secret: incoming_shared_secret,
3284 phantom_shared_secret,
3286 value: outgoing_amt_msat,
3288 total_value_received: None,
3289 total_msat: if let Some(data) = &payment_data { data.total_msat } else { outgoing_amt_msat },
3294 macro_rules! fail_htlc {
3295 ($htlc: expr, $payment_hash: expr) => {
3296 let mut htlc_msat_height_data = $htlc.value.to_be_bytes().to_vec();
3297 htlc_msat_height_data.extend_from_slice(
3298 &self.best_block.read().unwrap().height().to_be_bytes(),
3300 failed_forwards.push((HTLCSource::PreviousHopData(HTLCPreviousHopData {
3301 short_channel_id: $htlc.prev_hop.short_channel_id,
3302 outpoint: prev_funding_outpoint,
3303 htlc_id: $htlc.prev_hop.htlc_id,
3304 incoming_packet_shared_secret: $htlc.prev_hop.incoming_packet_shared_secret,
3305 phantom_shared_secret,
3307 HTLCFailReason::reason(0x4000 | 15, htlc_msat_height_data),
3308 HTLCDestination::FailedPayment { payment_hash: $payment_hash },
3312 let phantom_shared_secret = claimable_htlc.prev_hop.phantom_shared_secret;
3313 let mut receiver_node_id = self.our_network_pubkey;
3314 if phantom_shared_secret.is_some() {
3315 receiver_node_id = self.node_signer.get_node_id(Recipient::PhantomNode)
3316 .expect("Failed to get node_id for phantom node recipient");
3319 macro_rules! check_total_value {
3320 ($payment_data: expr, $payment_preimage: expr) => {{
3321 let mut payment_claimable_generated = false;
3323 events::PaymentPurpose::InvoicePayment {
3324 payment_preimage: $payment_preimage,
3325 payment_secret: $payment_data.payment_secret,
3328 let mut claimable_payments = self.claimable_payments.lock().unwrap();
3329 if claimable_payments.pending_claiming_payments.contains_key(&payment_hash) {
3330 fail_htlc!(claimable_htlc, payment_hash);
3333 let (_, ref mut htlcs) = claimable_payments.claimable_htlcs.entry(payment_hash)
3334 .or_insert_with(|| (purpose(), Vec::new()));
3335 if htlcs.len() == 1 {
3336 if let OnionPayload::Spontaneous(_) = htlcs[0].onion_payload {
3337 log_trace!(self.logger, "Failing new HTLC with payment_hash {} as we already had an existing keysend HTLC with the same payment hash", log_bytes!(payment_hash.0));
3338 fail_htlc!(claimable_htlc, payment_hash);
3342 let mut total_value = claimable_htlc.value;
3343 for htlc in htlcs.iter() {
3344 total_value += htlc.value;
3345 match &htlc.onion_payload {
3346 OnionPayload::Invoice { .. } => {
3347 if htlc.total_msat != $payment_data.total_msat {
3348 log_trace!(self.logger, "Failing HTLCs with payment_hash {} as the HTLCs had inconsistent total values (eg {} and {})",
3349 log_bytes!(payment_hash.0), $payment_data.total_msat, htlc.total_msat);
3350 total_value = msgs::MAX_VALUE_MSAT;
3352 if total_value >= msgs::MAX_VALUE_MSAT { break; }
3354 _ => unreachable!(),
3357 if total_value >= msgs::MAX_VALUE_MSAT {
3358 fail_htlc!(claimable_htlc, payment_hash);
3359 } else if total_value - claimable_htlc.value >= $payment_data.total_msat {
3360 log_trace!(self.logger, "Failing HTLC with payment_hash {} as payment is already claimable",
3361 log_bytes!(payment_hash.0));
3362 fail_htlc!(claimable_htlc, payment_hash);
3363 } else if total_value >= $payment_data.total_msat {
3364 let prev_channel_id = prev_funding_outpoint.to_channel_id();
3365 htlcs.push(claimable_htlc);
3366 let amount_msat = htlcs.iter().map(|htlc| htlc.value).sum();
3367 htlcs.iter_mut().for_each(|htlc| htlc.total_value_received = Some(amount_msat));
3368 new_events.push(events::Event::PaymentClaimable {
3369 receiver_node_id: Some(receiver_node_id),
3373 via_channel_id: Some(prev_channel_id),
3374 via_user_channel_id: Some(prev_user_channel_id),
3376 payment_claimable_generated = true;
3378 // Nothing to do - we haven't reached the total
3379 // payment value yet, wait until we receive more
3381 htlcs.push(claimable_htlc);
3383 payment_claimable_generated
3387 // Check that the payment hash and secret are known. Note that we
3388 // MUST take care to handle the "unknown payment hash" and
3389 // "incorrect payment secret" cases here identically or we'd expose
3390 // that we are the ultimate recipient of the given payment hash.
3391 // Further, we must not expose whether we have any other HTLCs
3392 // associated with the same payment_hash pending or not.
3393 let mut payment_secrets = self.pending_inbound_payments.lock().unwrap();
3394 match payment_secrets.entry(payment_hash) {
3395 hash_map::Entry::Vacant(_) => {
3396 match claimable_htlc.onion_payload {
3397 OnionPayload::Invoice { .. } => {
3398 let payment_data = payment_data.unwrap();
3399 let (payment_preimage, min_final_cltv_expiry_delta) = match inbound_payment::verify(payment_hash, &payment_data, self.highest_seen_timestamp.load(Ordering::Acquire) as u64, &self.inbound_payment_key, &self.logger) {
3400 Ok(result) => result,
3402 log_trace!(self.logger, "Failing new HTLC with payment_hash {} as payment verification failed", log_bytes!(payment_hash.0));
3403 fail_htlc!(claimable_htlc, payment_hash);
3407 if let Some(min_final_cltv_expiry_delta) = min_final_cltv_expiry_delta {
3408 let expected_min_expiry_height = (self.current_best_block().height() + min_final_cltv_expiry_delta as u32) as u64;
3409 if (cltv_expiry as u64) < expected_min_expiry_height {
3410 log_trace!(self.logger, "Failing new HTLC with payment_hash {} as its CLTV expiry was too soon (had {}, earliest expected {})",
3411 log_bytes!(payment_hash.0), cltv_expiry, expected_min_expiry_height);
3412 fail_htlc!(claimable_htlc, payment_hash);
3416 check_total_value!(payment_data, payment_preimage);
3418 OnionPayload::Spontaneous(preimage) => {
3419 let mut claimable_payments = self.claimable_payments.lock().unwrap();
3420 if claimable_payments.pending_claiming_payments.contains_key(&payment_hash) {
3421 fail_htlc!(claimable_htlc, payment_hash);
3424 match claimable_payments.claimable_htlcs.entry(payment_hash) {
3425 hash_map::Entry::Vacant(e) => {
3426 let amount_msat = claimable_htlc.value;
3427 claimable_htlc.total_value_received = Some(amount_msat);
3428 let purpose = events::PaymentPurpose::SpontaneousPayment(preimage);
3429 e.insert((purpose.clone(), vec![claimable_htlc]));
3430 let prev_channel_id = prev_funding_outpoint.to_channel_id();
3431 new_events.push(events::Event::PaymentClaimable {
3432 receiver_node_id: Some(receiver_node_id),
3434 amount_msat: outgoing_amt_msat,
3436 via_channel_id: Some(prev_channel_id),
3437 via_user_channel_id: Some(prev_user_channel_id),
3440 hash_map::Entry::Occupied(_) => {
3441 log_trace!(self.logger, "Failing new keysend HTLC with payment_hash {} for a duplicative payment hash", log_bytes!(payment_hash.0));
3442 fail_htlc!(claimable_htlc, payment_hash);
3448 hash_map::Entry::Occupied(inbound_payment) => {
3449 if payment_data.is_none() {
3450 log_trace!(self.logger, "Failing new keysend HTLC with payment_hash {} because we already have an inbound payment with the same payment hash", log_bytes!(payment_hash.0));
3451 fail_htlc!(claimable_htlc, payment_hash);
3454 let payment_data = payment_data.unwrap();
3455 if inbound_payment.get().payment_secret != payment_data.payment_secret {
3456 log_trace!(self.logger, "Failing new HTLC with payment_hash {} as it didn't match our expected payment secret.", log_bytes!(payment_hash.0));
3457 fail_htlc!(claimable_htlc, payment_hash);
3458 } else if inbound_payment.get().min_value_msat.is_some() && payment_data.total_msat < inbound_payment.get().min_value_msat.unwrap() {
3459 log_trace!(self.logger, "Failing new HTLC with payment_hash {} as it didn't match our minimum value (had {}, needed {}).",
3460 log_bytes!(payment_hash.0), payment_data.total_msat, inbound_payment.get().min_value_msat.unwrap());
3461 fail_htlc!(claimable_htlc, payment_hash);
3463 let payment_claimable_generated = check_total_value!(payment_data, inbound_payment.get().payment_preimage);
3464 if payment_claimable_generated {
3465 inbound_payment.remove_entry();
3471 HTLCForwardInfo::FailHTLC { .. } => {
3472 panic!("Got pending fail of our own HTLC");
3480 let best_block_height = self.best_block.read().unwrap().height();
3481 self.pending_outbound_payments.check_retry_payments(&self.router, || self.list_usable_channels(),
3482 || self.compute_inflight_htlcs(), &self.entropy_source, &self.node_signer, best_block_height,
3483 &self.pending_events, &self.logger,
3484 |path, payment_hash, payment_secret, total_value, cur_height, payment_id, keysend_preimage, session_priv|
3485 self.send_payment_along_path(path, payment_hash, payment_secret, total_value, cur_height, payment_id, keysend_preimage, session_priv));
3487 for (htlc_source, payment_hash, failure_reason, destination) in failed_forwards.drain(..) {
3488 self.fail_htlc_backwards_internal(&htlc_source, &payment_hash, &failure_reason, destination);
3490 self.forward_htlcs(&mut phantom_receives);
3492 // Freeing the holding cell here is relatively redundant - in practice we'll do it when we
3493 // next get a `get_and_clear_pending_msg_events` call, but some tests rely on it, and it's
3494 // nice to do the work now if we can rather than while we're trying to get messages in the
3496 self.check_free_holding_cells();
3498 if new_events.is_empty() { return }
3499 let mut events = self.pending_events.lock().unwrap();
3500 events.append(&mut new_events);
3503 /// Free the background events, generally called from timer_tick_occurred.
3505 /// Exposed for testing to allow us to process events quickly without generating accidental
3506 /// BroadcastChannelUpdate events in timer_tick_occurred.
3508 /// Expects the caller to have a total_consistency_lock read lock.
3509 fn process_background_events(&self) -> bool {
3510 let mut background_events = Vec::new();
3511 mem::swap(&mut *self.pending_background_events.lock().unwrap(), &mut background_events);
3512 if background_events.is_empty() {
3516 for event in background_events.drain(..) {
3518 BackgroundEvent::ClosingMonitorUpdate((funding_txo, update)) => {
3519 // The channel has already been closed, so no use bothering to care about the
3520 // monitor updating completing.
3521 let _ = self.chain_monitor.update_channel(funding_txo, &update);
3528 #[cfg(any(test, feature = "_test_utils"))]
3529 /// Process background events, for functional testing
3530 pub fn test_process_background_events(&self) {
3531 self.process_background_events();
3534 fn update_channel_fee(&self, chan_id: &[u8; 32], chan: &mut Channel<<SP::Target as SignerProvider>::Signer>, new_feerate: u32) -> NotifyOption {
3535 if !chan.is_outbound() { return NotifyOption::SkipPersist; }
3536 // If the feerate has decreased by less than half, don't bother
3537 if new_feerate <= chan.get_feerate_sat_per_1000_weight() && new_feerate * 2 > chan.get_feerate_sat_per_1000_weight() {
3538 log_trace!(self.logger, "Channel {} does not qualify for a feerate change from {} to {}.",
3539 log_bytes!(chan_id[..]), chan.get_feerate_sat_per_1000_weight(), new_feerate);
3540 return NotifyOption::SkipPersist;
3542 if !chan.is_live() {
3543 log_trace!(self.logger, "Channel {} does not qualify for a feerate change from {} to {} as it cannot currently be updated (probably the peer is disconnected).",
3544 log_bytes!(chan_id[..]), chan.get_feerate_sat_per_1000_weight(), new_feerate);
3545 return NotifyOption::SkipPersist;
3547 log_trace!(self.logger, "Channel {} qualifies for a feerate change from {} to {}.",
3548 log_bytes!(chan_id[..]), chan.get_feerate_sat_per_1000_weight(), new_feerate);
3550 chan.queue_update_fee(new_feerate, &self.logger);
3551 NotifyOption::DoPersist
3555 /// In chanmon_consistency we want to sometimes do the channel fee updates done in
3556 /// timer_tick_occurred, but we can't generate the disabled channel updates as it considers
3557 /// these a fuzz failure (as they usually indicate a channel force-close, which is exactly what
3558 /// it wants to detect). Thus, we have a variant exposed here for its benefit.
3559 pub fn maybe_update_chan_fees(&self) {
3560 PersistenceNotifierGuard::optionally_notify(&self.total_consistency_lock, &self.persistence_notifier, || {
3561 let mut should_persist = NotifyOption::SkipPersist;
3563 let new_feerate = self.fee_estimator.bounded_sat_per_1000_weight(ConfirmationTarget::Normal);
3565 let per_peer_state = self.per_peer_state.read().unwrap();
3566 for (_cp_id, peer_state_mutex) in per_peer_state.iter() {
3567 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
3568 let peer_state = &mut *peer_state_lock;
3569 for (chan_id, chan) in peer_state.channel_by_id.iter_mut() {
3570 let chan_needs_persist = self.update_channel_fee(chan_id, chan, new_feerate);
3571 if chan_needs_persist == NotifyOption::DoPersist { should_persist = NotifyOption::DoPersist; }
3579 /// Performs actions which should happen on startup and roughly once per minute thereafter.
3581 /// This currently includes:
3582 /// * Increasing or decreasing the on-chain feerate estimates for our outbound channels,
3583 /// * Broadcasting [`ChannelUpdate`] messages if we've been disconnected from our peer for more
3584 /// than a minute, informing the network that they should no longer attempt to route over
3586 /// * Expiring a channel's previous [`ChannelConfig`] if necessary to only allow forwarding HTLCs
3587 /// with the current [`ChannelConfig`].
3588 /// * Removing peers which have disconnected but and no longer have any channels.
3590 /// Note that this may cause reentrancy through [`chain::Watch::update_channel`] calls or feerate
3591 /// estimate fetches.
3593 /// [`ChannelUpdate`]: msgs::ChannelUpdate
3594 /// [`ChannelConfig`]: crate::util::config::ChannelConfig
3595 pub fn timer_tick_occurred(&self) {
3596 PersistenceNotifierGuard::optionally_notify(&self.total_consistency_lock, &self.persistence_notifier, || {
3597 let mut should_persist = NotifyOption::SkipPersist;
3598 if self.process_background_events() { should_persist = NotifyOption::DoPersist; }
3600 let new_feerate = self.fee_estimator.bounded_sat_per_1000_weight(ConfirmationTarget::Normal);
3602 let mut handle_errors: Vec<(Result<(), _>, _)> = Vec::new();
3603 let mut timed_out_mpp_htlcs = Vec::new();
3604 let mut pending_peers_awaiting_removal = Vec::new();
3606 let per_peer_state = self.per_peer_state.read().unwrap();
3607 for (counterparty_node_id, peer_state_mutex) in per_peer_state.iter() {
3608 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
3609 let peer_state = &mut *peer_state_lock;
3610 let pending_msg_events = &mut peer_state.pending_msg_events;
3611 let counterparty_node_id = *counterparty_node_id;
3612 peer_state.channel_by_id.retain(|chan_id, chan| {
3613 let chan_needs_persist = self.update_channel_fee(chan_id, chan, new_feerate);
3614 if chan_needs_persist == NotifyOption::DoPersist { should_persist = NotifyOption::DoPersist; }
3616 if let Err(e) = chan.timer_check_closing_negotiation_progress() {
3617 let (needs_close, err) = convert_chan_err!(self, e, chan, chan_id);
3618 handle_errors.push((Err(err), counterparty_node_id));
3619 if needs_close { return false; }
3622 match chan.channel_update_status() {
3623 ChannelUpdateStatus::Enabled if !chan.is_live() => chan.set_channel_update_status(ChannelUpdateStatus::DisabledStaged),
3624 ChannelUpdateStatus::Disabled if chan.is_live() => chan.set_channel_update_status(ChannelUpdateStatus::EnabledStaged),
3625 ChannelUpdateStatus::DisabledStaged if chan.is_live() => chan.set_channel_update_status(ChannelUpdateStatus::Enabled),
3626 ChannelUpdateStatus::EnabledStaged if !chan.is_live() => chan.set_channel_update_status(ChannelUpdateStatus::Disabled),
3627 ChannelUpdateStatus::DisabledStaged if !chan.is_live() => {
3628 if let Ok(update) = self.get_channel_update_for_broadcast(&chan) {
3629 pending_msg_events.push(events::MessageSendEvent::BroadcastChannelUpdate {
3633 should_persist = NotifyOption::DoPersist;
3634 chan.set_channel_update_status(ChannelUpdateStatus::Disabled);
3636 ChannelUpdateStatus::EnabledStaged if chan.is_live() => {
3637 if let Ok(update) = self.get_channel_update_for_broadcast(&chan) {
3638 pending_msg_events.push(events::MessageSendEvent::BroadcastChannelUpdate {
3642 should_persist = NotifyOption::DoPersist;
3643 chan.set_channel_update_status(ChannelUpdateStatus::Enabled);
3648 chan.maybe_expire_prev_config();
3652 if peer_state.ok_to_remove(true) {
3653 pending_peers_awaiting_removal.push(counterparty_node_id);
3658 // When a peer disconnects but still has channels, the peer's `peer_state` entry in the
3659 // `per_peer_state` is not removed by the `peer_disconnected` function. If the channels
3660 // of to that peer is later closed while still being disconnected (i.e. force closed),
3661 // we therefore need to remove the peer from `peer_state` separately.
3662 // To avoid having to take the `per_peer_state` `write` lock once the channels are
3663 // closed, we instead remove such peers awaiting removal here on a timer, to limit the
3664 // negative effects on parallelism as much as possible.
3665 if pending_peers_awaiting_removal.len() > 0 {
3666 let mut per_peer_state = self.per_peer_state.write().unwrap();
3667 for counterparty_node_id in pending_peers_awaiting_removal {
3668 match per_peer_state.entry(counterparty_node_id) {
3669 hash_map::Entry::Occupied(entry) => {
3670 // Remove the entry if the peer is still disconnected and we still
3671 // have no channels to the peer.
3672 let remove_entry = {
3673 let peer_state = entry.get().lock().unwrap();
3674 peer_state.ok_to_remove(true)
3677 entry.remove_entry();
3680 hash_map::Entry::Vacant(_) => { /* The PeerState has already been removed */ }
3685 self.claimable_payments.lock().unwrap().claimable_htlcs.retain(|payment_hash, (_, htlcs)| {
3686 if htlcs.is_empty() {
3687 // This should be unreachable
3688 debug_assert!(false);
3691 if let OnionPayload::Invoice { .. } = htlcs[0].onion_payload {
3692 // Check if we've received all the parts we need for an MPP (the value of the parts adds to total_msat).
3693 // In this case we're not going to handle any timeouts of the parts here.
3694 if htlcs[0].total_msat <= htlcs.iter().fold(0, |total, htlc| total + htlc.value) {
3696 } else if htlcs.into_iter().any(|htlc| {
3697 htlc.timer_ticks += 1;
3698 return htlc.timer_ticks >= MPP_TIMEOUT_TICKS
3700 timed_out_mpp_htlcs.extend(htlcs.drain(..).map(|htlc: ClaimableHTLC| (htlc.prev_hop, *payment_hash)));
3707 for htlc_source in timed_out_mpp_htlcs.drain(..) {
3708 let source = HTLCSource::PreviousHopData(htlc_source.0.clone());
3709 let reason = HTLCFailReason::from_failure_code(23);
3710 let receiver = HTLCDestination::FailedPayment { payment_hash: htlc_source.1 };
3711 self.fail_htlc_backwards_internal(&source, &htlc_source.1, &reason, receiver);
3714 for (err, counterparty_node_id) in handle_errors.drain(..) {
3715 let _ = handle_error!(self, err, counterparty_node_id);
3718 self.pending_outbound_payments.remove_stale_resolved_payments(&self.pending_events);
3720 // Technically we don't need to do this here, but if we have holding cell entries in a
3721 // channel that need freeing, it's better to do that here and block a background task
3722 // than block the message queueing pipeline.
3723 if self.check_free_holding_cells() {
3724 should_persist = NotifyOption::DoPersist;
3731 /// Indicates that the preimage for payment_hash is unknown or the received amount is incorrect
3732 /// after a PaymentClaimable event, failing the HTLC back to its origin and freeing resources
3733 /// along the path (including in our own channel on which we received it).
3735 /// Note that in some cases around unclean shutdown, it is possible the payment may have
3736 /// already been claimed by you via [`ChannelManager::claim_funds`] prior to you seeing (a
3737 /// second copy of) the [`events::Event::PaymentClaimable`] event. Alternatively, the payment
3738 /// may have already been failed automatically by LDK if it was nearing its expiration time.
3740 /// While LDK will never claim a payment automatically on your behalf (i.e. without you calling
3741 /// [`ChannelManager::claim_funds`]), you should still monitor for
3742 /// [`events::Event::PaymentClaimed`] events even for payments you intend to fail, especially on
3743 /// startup during which time claims that were in-progress at shutdown may be replayed.
3744 pub fn fail_htlc_backwards(&self, payment_hash: &PaymentHash) {
3745 self.fail_htlc_backwards_with_reason(payment_hash, FailureCode::IncorrectOrUnknownPaymentDetails);
3748 /// This is a variant of [`ChannelManager::fail_htlc_backwards`] that allows you to specify the
3749 /// reason for the failure.
3751 /// See [`FailureCode`] for valid failure codes.
3752 pub fn fail_htlc_backwards_with_reason(&self, payment_hash: &PaymentHash, failure_code: FailureCode) {
3753 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
3755 let removed_source = self.claimable_payments.lock().unwrap().claimable_htlcs.remove(payment_hash);
3756 if let Some((_, mut sources)) = removed_source {
3757 for htlc in sources.drain(..) {
3758 let reason = self.get_htlc_fail_reason_from_failure_code(failure_code, &htlc);
3759 let source = HTLCSource::PreviousHopData(htlc.prev_hop);
3760 let receiver = HTLCDestination::FailedPayment { payment_hash: *payment_hash };
3761 self.fail_htlc_backwards_internal(&source, &payment_hash, &reason, receiver);
3766 /// Gets error data to form an [`HTLCFailReason`] given a [`FailureCode`] and [`ClaimableHTLC`].
3767 fn get_htlc_fail_reason_from_failure_code(&self, failure_code: FailureCode, htlc: &ClaimableHTLC) -> HTLCFailReason {
3768 match failure_code {
3769 FailureCode::TemporaryNodeFailure => HTLCFailReason::from_failure_code(failure_code as u16),
3770 FailureCode::RequiredNodeFeatureMissing => HTLCFailReason::from_failure_code(failure_code as u16),
3771 FailureCode::IncorrectOrUnknownPaymentDetails => {
3772 let mut htlc_msat_height_data = htlc.value.to_be_bytes().to_vec();
3773 htlc_msat_height_data.extend_from_slice(&self.best_block.read().unwrap().height().to_be_bytes());
3774 HTLCFailReason::reason(failure_code as u16, htlc_msat_height_data)
3779 /// Gets an HTLC onion failure code and error data for an `UPDATE` error, given the error code
3780 /// that we want to return and a channel.
3782 /// This is for failures on the channel on which the HTLC was *received*, not failures
3784 fn get_htlc_inbound_temp_fail_err_and_data(&self, desired_err_code: u16, chan: &Channel<<SP::Target as SignerProvider>::Signer>) -> (u16, Vec<u8>) {
3785 // We can't be sure what SCID was used when relaying inbound towards us, so we have to
3786 // guess somewhat. If its a public channel, we figure best to just use the real SCID (as
3787 // we're not leaking that we have a channel with the counterparty), otherwise we try to use
3788 // an inbound SCID alias before the real SCID.
3789 let scid_pref = if chan.should_announce() {
3790 chan.get_short_channel_id().or(chan.latest_inbound_scid_alias())
3792 chan.latest_inbound_scid_alias().or(chan.get_short_channel_id())
3794 if let Some(scid) = scid_pref {
3795 self.get_htlc_temp_fail_err_and_data(desired_err_code, scid, chan)
3797 (0x4000|10, Vec::new())
3802 /// Gets an HTLC onion failure code and error data for an `UPDATE` error, given the error code
3803 /// that we want to return and a channel.
3804 fn get_htlc_temp_fail_err_and_data(&self, desired_err_code: u16, scid: u64, chan: &Channel<<SP::Target as SignerProvider>::Signer>) -> (u16, Vec<u8>) {
3805 debug_assert_eq!(desired_err_code & 0x1000, 0x1000);
3806 if let Ok(upd) = self.get_channel_update_for_onion(scid, chan) {
3807 let mut enc = VecWriter(Vec::with_capacity(upd.serialized_length() + 6));
3808 if desired_err_code == 0x1000 | 20 {
3809 // No flags for `disabled_flags` are currently defined so they're always two zero bytes.
3810 // See https://github.com/lightning/bolts/blob/341ec84/04-onion-routing.md?plain=1#L1008
3811 0u16.write(&mut enc).expect("Writes cannot fail");
3813 (upd.serialized_length() as u16 + 2).write(&mut enc).expect("Writes cannot fail");
3814 msgs::ChannelUpdate::TYPE.write(&mut enc).expect("Writes cannot fail");
3815 upd.write(&mut enc).expect("Writes cannot fail");
3816 (desired_err_code, enc.0)
3818 // If we fail to get a unicast channel_update, it implies we don't yet have an SCID,
3819 // which means we really shouldn't have gotten a payment to be forwarded over this
3820 // channel yet, or if we did it's from a route hint. Either way, returning an error of
3821 // PERM|no_such_channel should be fine.
3822 (0x4000|10, Vec::new())
3826 // Fail a list of HTLCs that were just freed from the holding cell. The HTLCs need to be
3827 // failed backwards or, if they were one of our outgoing HTLCs, then their failure needs to
3828 // be surfaced to the user.
3829 fn fail_holding_cell_htlcs(
3830 &self, mut htlcs_to_fail: Vec<(HTLCSource, PaymentHash)>, channel_id: [u8; 32],
3831 counterparty_node_id: &PublicKey
3833 let (failure_code, onion_failure_data) = {
3834 let per_peer_state = self.per_peer_state.read().unwrap();
3835 if let Some(peer_state_mutex) = per_peer_state.get(counterparty_node_id) {
3836 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
3837 let peer_state = &mut *peer_state_lock;
3838 match peer_state.channel_by_id.entry(channel_id) {
3839 hash_map::Entry::Occupied(chan_entry) => {
3840 self.get_htlc_inbound_temp_fail_err_and_data(0x1000|7, &chan_entry.get())
3842 hash_map::Entry::Vacant(_) => (0x4000|10, Vec::new())
3844 } else { (0x4000|10, Vec::new()) }
3847 for (htlc_src, payment_hash) in htlcs_to_fail.drain(..) {
3848 let reason = HTLCFailReason::reason(failure_code, onion_failure_data.clone());
3849 let receiver = HTLCDestination::NextHopChannel { node_id: Some(counterparty_node_id.clone()), channel_id };
3850 self.fail_htlc_backwards_internal(&htlc_src, &payment_hash, &reason, receiver);
3854 /// Fails an HTLC backwards to the sender of it to us.
3855 /// Note that we do not assume that channels corresponding to failed HTLCs are still available.
3856 fn fail_htlc_backwards_internal(&self, source: &HTLCSource, payment_hash: &PaymentHash, onion_error: &HTLCFailReason, destination: HTLCDestination) {
3857 // Ensure that no peer state channel storage lock is held when calling this function.
3858 // This ensures that future code doesn't introduce a lock-order requirement for
3859 // `forward_htlcs` to be locked after the `per_peer_state` peer locks, which calling
3860 // this function with any `per_peer_state` peer lock acquired would.
3861 for (_, peer) in self.per_peer_state.read().unwrap().iter() {
3862 debug_assert_ne!(peer.held_by_thread(), LockHeldState::HeldByThread);
3865 //TODO: There is a timing attack here where if a node fails an HTLC back to us they can
3866 //identify whether we sent it or not based on the (I presume) very different runtime
3867 //between the branches here. We should make this async and move it into the forward HTLCs
3870 // Note that we MUST NOT end up calling methods on self.chain_monitor here - we're called
3871 // from block_connected which may run during initialization prior to the chain_monitor
3872 // being fully configured. See the docs for `ChannelManagerReadArgs` for more.
3874 HTLCSource::OutboundRoute { ref path, ref session_priv, ref payment_id, .. } => {
3875 if self.pending_outbound_payments.fail_htlc(source, payment_hash, onion_error, path,
3876 session_priv, payment_id, self.probing_cookie_secret, &self.secp_ctx,
3877 &self.pending_events, &self.logger)
3878 { self.push_pending_forwards_ev(); }
3880 HTLCSource::PreviousHopData(HTLCPreviousHopData { ref short_channel_id, ref htlc_id, ref incoming_packet_shared_secret, ref phantom_shared_secret, ref outpoint }) => {
3881 log_trace!(self.logger, "Failing HTLC with payment_hash {} backwards from us with {:?}", log_bytes!(payment_hash.0), onion_error);
3882 let err_packet = onion_error.get_encrypted_failure_packet(incoming_packet_shared_secret, phantom_shared_secret);
3884 let mut push_forward_ev = false;
3885 let mut forward_htlcs = self.forward_htlcs.lock().unwrap();
3886 if forward_htlcs.is_empty() {
3887 push_forward_ev = true;
3889 match forward_htlcs.entry(*short_channel_id) {
3890 hash_map::Entry::Occupied(mut entry) => {
3891 entry.get_mut().push(HTLCForwardInfo::FailHTLC { htlc_id: *htlc_id, err_packet });
3893 hash_map::Entry::Vacant(entry) => {
3894 entry.insert(vec!(HTLCForwardInfo::FailHTLC { htlc_id: *htlc_id, err_packet }));
3897 mem::drop(forward_htlcs);
3898 if push_forward_ev { self.push_pending_forwards_ev(); }
3899 let mut pending_events = self.pending_events.lock().unwrap();
3900 pending_events.push(events::Event::HTLCHandlingFailed {
3901 prev_channel_id: outpoint.to_channel_id(),
3902 failed_next_destination: destination,
3908 /// Provides a payment preimage in response to [`Event::PaymentClaimable`], generating any
3909 /// [`MessageSendEvent`]s needed to claim the payment.
3911 /// Note that calling this method does *not* guarantee that the payment has been claimed. You
3912 /// *must* wait for an [`Event::PaymentClaimed`] event which upon a successful claim will be
3913 /// provided to your [`EventHandler`] when [`process_pending_events`] is next called.
3915 /// Note that if you did not set an `amount_msat` when calling [`create_inbound_payment`] or
3916 /// [`create_inbound_payment_for_hash`] you must check that the amount in the `PaymentClaimable`
3917 /// event matches your expectation. If you fail to do so and call this method, you may provide
3918 /// the sender "proof-of-payment" when they did not fulfill the full expected payment.
3920 /// [`Event::PaymentClaimable`]: crate::events::Event::PaymentClaimable
3921 /// [`Event::PaymentClaimed`]: crate::events::Event::PaymentClaimed
3922 /// [`process_pending_events`]: EventsProvider::process_pending_events
3923 /// [`create_inbound_payment`]: Self::create_inbound_payment
3924 /// [`create_inbound_payment_for_hash`]: Self::create_inbound_payment_for_hash
3925 pub fn claim_funds(&self, payment_preimage: PaymentPreimage) {
3926 let payment_hash = PaymentHash(Sha256::hash(&payment_preimage.0).into_inner());
3928 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
3931 let mut claimable_payments = self.claimable_payments.lock().unwrap();
3932 if let Some((payment_purpose, sources)) = claimable_payments.claimable_htlcs.remove(&payment_hash) {
3933 let mut receiver_node_id = self.our_network_pubkey;
3934 for htlc in sources.iter() {
3935 if htlc.prev_hop.phantom_shared_secret.is_some() {
3936 let phantom_pubkey = self.node_signer.get_node_id(Recipient::PhantomNode)
3937 .expect("Failed to get node_id for phantom node recipient");
3938 receiver_node_id = phantom_pubkey;
3943 let dup_purpose = claimable_payments.pending_claiming_payments.insert(payment_hash,
3944 ClaimingPayment { amount_msat: sources.iter().map(|source| source.value).sum(),
3945 payment_purpose, receiver_node_id,
3947 if dup_purpose.is_some() {
3948 debug_assert!(false, "Shouldn't get a duplicate pending claim event ever");
3949 log_error!(self.logger, "Got a duplicate pending claimable event on payment hash {}! Please report this bug",
3950 log_bytes!(payment_hash.0));
3955 debug_assert!(!sources.is_empty());
3957 // If we are claiming an MPP payment, we check that all channels which contain a claimable
3958 // HTLC still exist. While this isn't guaranteed to remain true if a channel closes while
3959 // we're claiming (or even after we claim, before the commitment update dance completes),
3960 // it should be a relatively rare race, and we'd rather not claim HTLCs that require us to
3961 // go on-chain (and lose the on-chain fee to do so) than just reject the payment.
3963 // Note that we'll still always get our funds - as long as the generated
3964 // `ChannelMonitorUpdate` makes it out to the relevant monitor we can claim on-chain.
3966 // If we find an HTLC which we would need to claim but for which we do not have a
3967 // channel, we will fail all parts of the MPP payment. While we could wait and see if
3968 // the sender retries the already-failed path(s), it should be a pretty rare case where
3969 // we got all the HTLCs and then a channel closed while we were waiting for the user to
3970 // provide the preimage, so worrying too much about the optimal handling isn't worth
3972 let mut claimable_amt_msat = 0;
3973 let mut prev_total_msat = None;
3974 let mut expected_amt_msat = None;
3975 let mut valid_mpp = true;
3976 let mut errs = Vec::new();
3977 let per_peer_state = self.per_peer_state.read().unwrap();
3978 for htlc in sources.iter() {
3979 let (counterparty_node_id, chan_id) = match self.short_to_chan_info.read().unwrap().get(&htlc.prev_hop.short_channel_id) {
3980 Some((cp_id, chan_id)) => (cp_id.clone(), chan_id.clone()),
3987 let peer_state_mutex_opt = per_peer_state.get(&counterparty_node_id);
3988 if peer_state_mutex_opt.is_none() {
3993 let mut peer_state_lock = peer_state_mutex_opt.unwrap().lock().unwrap();
3994 let peer_state = &mut *peer_state_lock;
3996 if peer_state.channel_by_id.get(&chan_id).is_none() {
4001 if prev_total_msat.is_some() && prev_total_msat != Some(htlc.total_msat) {
4002 log_error!(self.logger, "Somehow ended up with an MPP payment with different expected total amounts - this should not be reachable!");
4003 debug_assert!(false);
4007 prev_total_msat = Some(htlc.total_msat);
4009 if expected_amt_msat.is_some() && expected_amt_msat != htlc.total_value_received {
4010 log_error!(self.logger, "Somehow ended up with an MPP payment with different received total amounts - this should not be reachable!");
4011 debug_assert!(false);
4015 expected_amt_msat = htlc.total_value_received;
4017 if let OnionPayload::Spontaneous(_) = &htlc.onion_payload {
4018 // We don't currently support MPP for spontaneous payments, so just check
4019 // that there's one payment here and move on.
4020 if sources.len() != 1 {
4021 log_error!(self.logger, "Somehow ended up with an MPP spontaneous payment - this should not be reachable!");
4022 debug_assert!(false);
4028 claimable_amt_msat += htlc.value;
4030 mem::drop(per_peer_state);
4031 if sources.is_empty() || expected_amt_msat.is_none() {
4032 self.claimable_payments.lock().unwrap().pending_claiming_payments.remove(&payment_hash);
4033 log_info!(self.logger, "Attempted to claim an incomplete payment which no longer had any available HTLCs!");
4036 if claimable_amt_msat != expected_amt_msat.unwrap() {
4037 self.claimable_payments.lock().unwrap().pending_claiming_payments.remove(&payment_hash);
4038 log_info!(self.logger, "Attempted to claim an incomplete payment, expected {} msat, had {} available to claim.",
4039 expected_amt_msat.unwrap(), claimable_amt_msat);
4043 for htlc in sources.drain(..) {
4044 if let Err((pk, err)) = self.claim_funds_from_hop(
4045 htlc.prev_hop, payment_preimage,
4046 |_| Some(MonitorUpdateCompletionAction::PaymentClaimed { payment_hash }))
4048 if let msgs::ErrorAction::IgnoreError = err.err.action {
4049 // We got a temporary failure updating monitor, but will claim the
4050 // HTLC when the monitor updating is restored (or on chain).
4051 log_error!(self.logger, "Temporary failure claiming HTLC, treating as success: {}", err.err.err);
4052 } else { errs.push((pk, err)); }
4057 for htlc in sources.drain(..) {
4058 let mut htlc_msat_height_data = htlc.value.to_be_bytes().to_vec();
4059 htlc_msat_height_data.extend_from_slice(&self.best_block.read().unwrap().height().to_be_bytes());
4060 let source = HTLCSource::PreviousHopData(htlc.prev_hop);
4061 let reason = HTLCFailReason::reason(0x4000 | 15, htlc_msat_height_data);
4062 let receiver = HTLCDestination::FailedPayment { payment_hash };
4063 self.fail_htlc_backwards_internal(&source, &payment_hash, &reason, receiver);
4065 self.claimable_payments.lock().unwrap().pending_claiming_payments.remove(&payment_hash);
4068 // Now we can handle any errors which were generated.
4069 for (counterparty_node_id, err) in errs.drain(..) {
4070 let res: Result<(), _> = Err(err);
4071 let _ = handle_error!(self, res, counterparty_node_id);
4075 fn claim_funds_from_hop<ComplFunc: FnOnce(Option<u64>) -> Option<MonitorUpdateCompletionAction>>(&self,
4076 prev_hop: HTLCPreviousHopData, payment_preimage: PaymentPreimage, completion_action: ComplFunc)
4077 -> Result<(), (PublicKey, MsgHandleErrInternal)> {
4078 //TODO: Delay the claimed_funds relaying just like we do outbound relay!
4080 let per_peer_state = self.per_peer_state.read().unwrap();
4081 let chan_id = prev_hop.outpoint.to_channel_id();
4082 let counterparty_node_id_opt = match self.short_to_chan_info.read().unwrap().get(&prev_hop.short_channel_id) {
4083 Some((cp_id, _dup_chan_id)) => Some(cp_id.clone()),
4087 let peer_state_opt = counterparty_node_id_opt.as_ref().map(
4088 |counterparty_node_id| per_peer_state.get(counterparty_node_id).map(
4089 |peer_mutex| peer_mutex.lock().unwrap()
4093 if peer_state_opt.is_some() {
4094 let mut peer_state_lock = peer_state_opt.unwrap();
4095 let peer_state = &mut *peer_state_lock;
4096 if let hash_map::Entry::Occupied(mut chan) = peer_state.channel_by_id.entry(chan_id) {
4097 let counterparty_node_id = chan.get().get_counterparty_node_id();
4098 let fulfill_res = chan.get_mut().get_update_fulfill_htlc_and_commit(prev_hop.htlc_id, payment_preimage, &self.logger);
4100 if let UpdateFulfillCommitFetch::NewClaim { htlc_value_msat, monitor_update } = fulfill_res {
4101 if let Some(action) = completion_action(Some(htlc_value_msat)) {
4102 log_trace!(self.logger, "Tracking monitor update completion action for channel {}: {:?}",
4103 log_bytes!(chan_id), action);
4104 peer_state.monitor_update_blocked_actions.entry(chan_id).or_insert(Vec::new()).push(action);
4106 let update_id = monitor_update.update_id;
4107 let update_res = self.chain_monitor.update_channel(prev_hop.outpoint, monitor_update);
4108 let res = handle_new_monitor_update!(self, update_res, update_id, peer_state_lock,
4109 peer_state, per_peer_state, chan);
4110 if let Err(e) = res {
4111 // TODO: This is a *critical* error - we probably updated the outbound edge
4112 // of the HTLC's monitor with a preimage. We should retry this monitor
4113 // update over and over again until morale improves.
4114 log_error!(self.logger, "Failed to update channel monitor with preimage {:?}", payment_preimage);
4115 return Err((counterparty_node_id, e));
4121 let preimage_update = ChannelMonitorUpdate {
4122 update_id: CLOSED_CHANNEL_UPDATE_ID,
4123 updates: vec![ChannelMonitorUpdateStep::PaymentPreimage {
4127 // We update the ChannelMonitor on the backward link, after
4128 // receiving an `update_fulfill_htlc` from the forward link.
4129 let update_res = self.chain_monitor.update_channel(prev_hop.outpoint, &preimage_update);
4130 if update_res != ChannelMonitorUpdateStatus::Completed {
4131 // TODO: This needs to be handled somehow - if we receive a monitor update
4132 // with a preimage we *must* somehow manage to propagate it to the upstream
4133 // channel, or we must have an ability to receive the same event and try
4134 // again on restart.
4135 log_error!(self.logger, "Critical error: failed to update channel monitor with preimage {:?}: {:?}",
4136 payment_preimage, update_res);
4138 // Note that we do process the completion action here. This totally could be a
4139 // duplicate claim, but we have no way of knowing without interrogating the
4140 // `ChannelMonitor` we've provided the above update to. Instead, note that `Event`s are
4141 // generally always allowed to be duplicative (and it's specifically noted in
4142 // `PaymentForwarded`).
4143 self.handle_monitor_update_completion_actions(completion_action(None));
4147 fn finalize_claims(&self, sources: Vec<HTLCSource>) {
4148 self.pending_outbound_payments.finalize_claims(sources, &self.pending_events);
4151 fn claim_funds_internal(&self, source: HTLCSource, payment_preimage: PaymentPreimage, forwarded_htlc_value_msat: Option<u64>, from_onchain: bool, next_channel_id: [u8; 32]) {
4153 HTLCSource::OutboundRoute { session_priv, payment_id, path, .. } => {
4154 self.pending_outbound_payments.claim_htlc(payment_id, payment_preimage, session_priv, path, from_onchain, &self.pending_events, &self.logger);
4156 HTLCSource::PreviousHopData(hop_data) => {
4157 let prev_outpoint = hop_data.outpoint;
4158 let res = self.claim_funds_from_hop(hop_data, payment_preimage,
4159 |htlc_claim_value_msat| {
4160 if let Some(forwarded_htlc_value) = forwarded_htlc_value_msat {
4161 let fee_earned_msat = if let Some(claimed_htlc_value) = htlc_claim_value_msat {
4162 Some(claimed_htlc_value - forwarded_htlc_value)
4165 let prev_channel_id = Some(prev_outpoint.to_channel_id());
4166 let next_channel_id = Some(next_channel_id);
4168 Some(MonitorUpdateCompletionAction::EmitEvent { event: events::Event::PaymentForwarded {
4170 claim_from_onchain_tx: from_onchain,
4176 if let Err((pk, err)) = res {
4177 let result: Result<(), _> = Err(err);
4178 let _ = handle_error!(self, result, pk);
4184 /// Gets the node_id held by this ChannelManager
4185 pub fn get_our_node_id(&self) -> PublicKey {
4186 self.our_network_pubkey.clone()
4189 fn handle_monitor_update_completion_actions<I: IntoIterator<Item=MonitorUpdateCompletionAction>>(&self, actions: I) {
4190 for action in actions.into_iter() {
4192 MonitorUpdateCompletionAction::PaymentClaimed { payment_hash } => {
4193 let payment = self.claimable_payments.lock().unwrap().pending_claiming_payments.remove(&payment_hash);
4194 if let Some(ClaimingPayment { amount_msat, payment_purpose: purpose, receiver_node_id }) = payment {
4195 self.pending_events.lock().unwrap().push(events::Event::PaymentClaimed {
4196 payment_hash, purpose, amount_msat, receiver_node_id: Some(receiver_node_id),
4200 MonitorUpdateCompletionAction::EmitEvent { event } => {
4201 self.pending_events.lock().unwrap().push(event);
4207 /// Handles a channel reentering a functional state, either due to reconnect or a monitor
4208 /// update completion.
4209 fn handle_channel_resumption(&self, pending_msg_events: &mut Vec<MessageSendEvent>,
4210 channel: &mut Channel<<SP::Target as SignerProvider>::Signer>, raa: Option<msgs::RevokeAndACK>,
4211 commitment_update: Option<msgs::CommitmentUpdate>, order: RAACommitmentOrder,
4212 pending_forwards: Vec<(PendingHTLCInfo, u64)>, funding_broadcastable: Option<Transaction>,
4213 channel_ready: Option<msgs::ChannelReady>, announcement_sigs: Option<msgs::AnnouncementSignatures>)
4214 -> Option<(u64, OutPoint, u128, Vec<(PendingHTLCInfo, u64)>)> {
4215 log_trace!(self.logger, "Handling channel resumption for channel {} with {} RAA, {} commitment update, {} pending forwards, {}broadcasting funding, {} channel ready, {} announcement",
4216 log_bytes!(channel.channel_id()),
4217 if raa.is_some() { "an" } else { "no" },
4218 if commitment_update.is_some() { "a" } else { "no" }, pending_forwards.len(),
4219 if funding_broadcastable.is_some() { "" } else { "not " },
4220 if channel_ready.is_some() { "sending" } else { "without" },
4221 if announcement_sigs.is_some() { "sending" } else { "without" });
4223 let mut htlc_forwards = None;
4225 let counterparty_node_id = channel.get_counterparty_node_id();
4226 if !pending_forwards.is_empty() {
4227 htlc_forwards = Some((channel.get_short_channel_id().unwrap_or(channel.outbound_scid_alias()),
4228 channel.get_funding_txo().unwrap(), channel.get_user_id(), pending_forwards));
4231 if let Some(msg) = channel_ready {
4232 send_channel_ready!(self, pending_msg_events, channel, msg);
4234 if let Some(msg) = announcement_sigs {
4235 pending_msg_events.push(events::MessageSendEvent::SendAnnouncementSignatures {
4236 node_id: counterparty_node_id,
4241 emit_channel_ready_event!(self, channel);
4243 macro_rules! handle_cs { () => {
4244 if let Some(update) = commitment_update {
4245 pending_msg_events.push(events::MessageSendEvent::UpdateHTLCs {
4246 node_id: counterparty_node_id,
4251 macro_rules! handle_raa { () => {
4252 if let Some(revoke_and_ack) = raa {
4253 pending_msg_events.push(events::MessageSendEvent::SendRevokeAndACK {
4254 node_id: counterparty_node_id,
4255 msg: revoke_and_ack,
4260 RAACommitmentOrder::CommitmentFirst => {
4264 RAACommitmentOrder::RevokeAndACKFirst => {
4270 if let Some(tx) = funding_broadcastable {
4271 log_info!(self.logger, "Broadcasting funding transaction with txid {}", tx.txid());
4272 self.tx_broadcaster.broadcast_transaction(&tx);
4278 fn channel_monitor_updated(&self, funding_txo: &OutPoint, highest_applied_update_id: u64, counterparty_node_id: Option<&PublicKey>) {
4279 debug_assert!(self.total_consistency_lock.try_write().is_err()); // Caller holds read lock
4281 let counterparty_node_id = match counterparty_node_id {
4282 Some(cp_id) => cp_id.clone(),
4284 // TODO: Once we can rely on the counterparty_node_id from the
4285 // monitor event, this and the id_to_peer map should be removed.
4286 let id_to_peer = self.id_to_peer.lock().unwrap();
4287 match id_to_peer.get(&funding_txo.to_channel_id()) {
4288 Some(cp_id) => cp_id.clone(),
4293 let per_peer_state = self.per_peer_state.read().unwrap();
4294 let mut peer_state_lock;
4295 let peer_state_mutex_opt = per_peer_state.get(&counterparty_node_id);
4296 if peer_state_mutex_opt.is_none() { return }
4297 peer_state_lock = peer_state_mutex_opt.unwrap().lock().unwrap();
4298 let peer_state = &mut *peer_state_lock;
4300 match peer_state.channel_by_id.entry(funding_txo.to_channel_id()){
4301 hash_map::Entry::Occupied(chan) => chan,
4302 hash_map::Entry::Vacant(_) => return,
4305 log_trace!(self.logger, "ChannelMonitor updated to {}. Current highest is {}",
4306 highest_applied_update_id, channel.get().get_latest_monitor_update_id());
4307 if !channel.get().is_awaiting_monitor_update() || channel.get().get_latest_monitor_update_id() != highest_applied_update_id {
4310 handle_monitor_update_completion!(self, highest_applied_update_id, peer_state_lock, peer_state, per_peer_state, channel.get_mut());
4313 /// Accepts a request to open a channel after a [`Event::OpenChannelRequest`].
4315 /// The `temporary_channel_id` parameter indicates which inbound channel should be accepted,
4316 /// and the `counterparty_node_id` parameter is the id of the peer which has requested to open
4319 /// The `user_channel_id` parameter will be provided back in
4320 /// [`Event::ChannelClosed::user_channel_id`] to allow tracking of which events correspond
4321 /// with which `accept_inbound_channel`/`accept_inbound_channel_from_trusted_peer_0conf` call.
4323 /// Note that this method will return an error and reject the channel, if it requires support
4324 /// for zero confirmations. Instead, `accept_inbound_channel_from_trusted_peer_0conf` must be
4325 /// used to accept such channels.
4327 /// [`Event::OpenChannelRequest`]: events::Event::OpenChannelRequest
4328 /// [`Event::ChannelClosed::user_channel_id`]: events::Event::ChannelClosed::user_channel_id
4329 pub fn accept_inbound_channel(&self, temporary_channel_id: &[u8; 32], counterparty_node_id: &PublicKey, user_channel_id: u128) -> Result<(), APIError> {
4330 self.do_accept_inbound_channel(temporary_channel_id, counterparty_node_id, false, user_channel_id)
4333 /// Accepts a request to open a channel after a [`events::Event::OpenChannelRequest`], treating
4334 /// it as confirmed immediately.
4336 /// The `user_channel_id` parameter will be provided back in
4337 /// [`Event::ChannelClosed::user_channel_id`] to allow tracking of which events correspond
4338 /// with which `accept_inbound_channel`/`accept_inbound_channel_from_trusted_peer_0conf` call.
4340 /// Unlike [`ChannelManager::accept_inbound_channel`], this method accepts the incoming channel
4341 /// and (if the counterparty agrees), enables forwarding of payments immediately.
4343 /// This fully trusts that the counterparty has honestly and correctly constructed the funding
4344 /// transaction and blindly assumes that it will eventually confirm.
4346 /// If it does not confirm before we decide to close the channel, or if the funding transaction
4347 /// does not pay to the correct script the correct amount, *you will lose funds*.
4349 /// [`Event::OpenChannelRequest`]: events::Event::OpenChannelRequest
4350 /// [`Event::ChannelClosed::user_channel_id`]: events::Event::ChannelClosed::user_channel_id
4351 pub fn accept_inbound_channel_from_trusted_peer_0conf(&self, temporary_channel_id: &[u8; 32], counterparty_node_id: &PublicKey, user_channel_id: u128) -> Result<(), APIError> {
4352 self.do_accept_inbound_channel(temporary_channel_id, counterparty_node_id, true, user_channel_id)
4355 fn do_accept_inbound_channel(&self, temporary_channel_id: &[u8; 32], counterparty_node_id: &PublicKey, accept_0conf: bool, user_channel_id: u128) -> Result<(), APIError> {
4356 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
4358 let peers_without_funded_channels = self.peers_without_funded_channels(|peer| !peer.channel_by_id.is_empty());
4359 let per_peer_state = self.per_peer_state.read().unwrap();
4360 let peer_state_mutex = per_peer_state.get(counterparty_node_id)
4361 .ok_or_else(|| APIError::ChannelUnavailable { err: format!("Can't find a peer matching the passed counterparty node_id {}", counterparty_node_id) })?;
4362 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
4363 let peer_state = &mut *peer_state_lock;
4364 let is_only_peer_channel = peer_state.channel_by_id.len() == 1;
4365 match peer_state.channel_by_id.entry(temporary_channel_id.clone()) {
4366 hash_map::Entry::Occupied(mut channel) => {
4367 if !channel.get().inbound_is_awaiting_accept() {
4368 return Err(APIError::APIMisuseError { err: "The channel isn't currently awaiting to be accepted.".to_owned() });
4371 channel.get_mut().set_0conf();
4372 } else if channel.get().get_channel_type().requires_zero_conf() {
4373 let send_msg_err_event = events::MessageSendEvent::HandleError {
4374 node_id: channel.get().get_counterparty_node_id(),
4375 action: msgs::ErrorAction::SendErrorMessage{
4376 msg: msgs::ErrorMessage { channel_id: temporary_channel_id.clone(), data: "No zero confirmation channels accepted".to_owned(), }
4379 peer_state.pending_msg_events.push(send_msg_err_event);
4380 let _ = remove_channel!(self, channel);
4381 return Err(APIError::APIMisuseError { err: "Please use accept_inbound_channel_from_trusted_peer_0conf to accept channels with zero confirmations.".to_owned() });
4383 // If this peer already has some channels, a new channel won't increase our number of peers
4384 // with unfunded channels, so as long as we aren't over the maximum number of unfunded
4385 // channels per-peer we can accept channels from a peer with existing ones.
4386 if is_only_peer_channel && peers_without_funded_channels >= MAX_UNFUNDED_CHANNEL_PEERS {
4387 let send_msg_err_event = events::MessageSendEvent::HandleError {
4388 node_id: channel.get().get_counterparty_node_id(),
4389 action: msgs::ErrorAction::SendErrorMessage{
4390 msg: msgs::ErrorMessage { channel_id: temporary_channel_id.clone(), data: "Have too many peers with unfunded channels, not accepting new ones".to_owned(), }
4393 peer_state.pending_msg_events.push(send_msg_err_event);
4394 let _ = remove_channel!(self, channel);
4395 return Err(APIError::APIMisuseError { err: "Too many peers with unfunded channels, refusing to accept new ones".to_owned() });
4399 peer_state.pending_msg_events.push(events::MessageSendEvent::SendAcceptChannel {
4400 node_id: channel.get().get_counterparty_node_id(),
4401 msg: channel.get_mut().accept_inbound_channel(user_channel_id),
4404 hash_map::Entry::Vacant(_) => {
4405 return Err(APIError::ChannelUnavailable { err: format!("Channel with id {} not found for the passed counterparty node_id {}", log_bytes!(*temporary_channel_id), counterparty_node_id) });
4411 /// Gets the number of peers which match the given filter and do not have any funded, outbound,
4412 /// or 0-conf channels.
4414 /// The filter is called for each peer and provided with the number of unfunded, inbound, and
4415 /// non-0-conf channels we have with the peer.
4416 fn peers_without_funded_channels<Filter>(&self, maybe_count_peer: Filter) -> usize
4417 where Filter: Fn(&PeerState<<SP::Target as SignerProvider>::Signer>) -> bool {
4418 let mut peers_without_funded_channels = 0;
4419 let best_block_height = self.best_block.read().unwrap().height();
4421 let peer_state_lock = self.per_peer_state.read().unwrap();
4422 for (_, peer_mtx) in peer_state_lock.iter() {
4423 let peer = peer_mtx.lock().unwrap();
4424 if !maybe_count_peer(&*peer) { continue; }
4425 let num_unfunded_channels = Self::unfunded_channel_count(&peer, best_block_height);
4426 if num_unfunded_channels == peer.channel_by_id.len() {
4427 peers_without_funded_channels += 1;
4431 return peers_without_funded_channels;
4434 fn unfunded_channel_count(
4435 peer: &PeerState<<SP::Target as SignerProvider>::Signer>, best_block_height: u32
4437 let mut num_unfunded_channels = 0;
4438 for (_, chan) in peer.channel_by_id.iter() {
4439 if !chan.is_outbound() && chan.minimum_depth().unwrap_or(1) != 0 &&
4440 chan.get_funding_tx_confirmations(best_block_height) == 0
4442 num_unfunded_channels += 1;
4445 num_unfunded_channels
4448 fn internal_open_channel(&self, counterparty_node_id: &PublicKey, msg: &msgs::OpenChannel) -> Result<(), MsgHandleErrInternal> {
4449 if msg.chain_hash != self.genesis_hash {
4450 return Err(MsgHandleErrInternal::send_err_msg_no_close("Unknown genesis block hash".to_owned(), msg.temporary_channel_id.clone()));
4453 if !self.default_configuration.accept_inbound_channels {
4454 return Err(MsgHandleErrInternal::send_err_msg_no_close("No inbound channels accepted".to_owned(), msg.temporary_channel_id.clone()));
4457 let mut random_bytes = [0u8; 16];
4458 random_bytes.copy_from_slice(&self.entropy_source.get_secure_random_bytes()[..16]);
4459 let user_channel_id = u128::from_be_bytes(random_bytes);
4460 let outbound_scid_alias = self.create_and_insert_outbound_scid_alias();
4462 // Get the number of peers with channels, but without funded ones. We don't care too much
4463 // about peers that never open a channel, so we filter by peers that have at least one
4464 // channel, and then limit the number of those with unfunded channels.
4465 let channeled_peers_without_funding = self.peers_without_funded_channels(|node| !node.channel_by_id.is_empty());
4467 let per_peer_state = self.per_peer_state.read().unwrap();
4468 let peer_state_mutex = per_peer_state.get(counterparty_node_id)
4470 debug_assert!(false);
4471 MsgHandleErrInternal::send_err_msg_no_close(format!("Can't find a peer matching the passed counterparty node_id {}", counterparty_node_id), msg.temporary_channel_id.clone())
4473 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
4474 let peer_state = &mut *peer_state_lock;
4476 // If this peer already has some channels, a new channel won't increase our number of peers
4477 // with unfunded channels, so as long as we aren't over the maximum number of unfunded
4478 // channels per-peer we can accept channels from a peer with existing ones.
4479 if peer_state.channel_by_id.is_empty() &&
4480 channeled_peers_without_funding >= MAX_UNFUNDED_CHANNEL_PEERS &&
4481 !self.default_configuration.manually_accept_inbound_channels
4483 return Err(MsgHandleErrInternal::send_err_msg_no_close(
4484 "Have too many peers with unfunded channels, not accepting new ones".to_owned(),
4485 msg.temporary_channel_id.clone()));
4488 let best_block_height = self.best_block.read().unwrap().height();
4489 if Self::unfunded_channel_count(peer_state, best_block_height) >= MAX_UNFUNDED_CHANS_PER_PEER {
4490 return Err(MsgHandleErrInternal::send_err_msg_no_close(
4491 format!("Refusing more than {} unfunded channels.", MAX_UNFUNDED_CHANS_PER_PEER),
4492 msg.temporary_channel_id.clone()));
4495 let mut channel = match Channel::new_from_req(&self.fee_estimator, &self.entropy_source, &self.signer_provider,
4496 counterparty_node_id.clone(), &self.channel_type_features(), &peer_state.latest_features, msg, user_channel_id,
4497 &self.default_configuration, best_block_height, &self.logger, outbound_scid_alias)
4500 self.outbound_scid_aliases.lock().unwrap().remove(&outbound_scid_alias);
4501 return Err(MsgHandleErrInternal::from_chan_no_close(e, msg.temporary_channel_id));
4505 match peer_state.channel_by_id.entry(channel.channel_id()) {
4506 hash_map::Entry::Occupied(_) => {
4507 self.outbound_scid_aliases.lock().unwrap().remove(&outbound_scid_alias);
4508 return Err(MsgHandleErrInternal::send_err_msg_no_close("temporary_channel_id collision for the same peer!".to_owned(), msg.temporary_channel_id.clone()))
4510 hash_map::Entry::Vacant(entry) => {
4511 if !self.default_configuration.manually_accept_inbound_channels {
4512 if channel.get_channel_type().requires_zero_conf() {
4513 return Err(MsgHandleErrInternal::send_err_msg_no_close("No zero confirmation channels accepted".to_owned(), msg.temporary_channel_id.clone()));
4515 peer_state.pending_msg_events.push(events::MessageSendEvent::SendAcceptChannel {
4516 node_id: counterparty_node_id.clone(),
4517 msg: channel.accept_inbound_channel(user_channel_id),
4520 let mut pending_events = self.pending_events.lock().unwrap();
4521 pending_events.push(
4522 events::Event::OpenChannelRequest {
4523 temporary_channel_id: msg.temporary_channel_id.clone(),
4524 counterparty_node_id: counterparty_node_id.clone(),
4525 funding_satoshis: msg.funding_satoshis,
4526 push_msat: msg.push_msat,
4527 channel_type: channel.get_channel_type().clone(),
4532 entry.insert(channel);
4538 fn internal_accept_channel(&self, counterparty_node_id: &PublicKey, msg: &msgs::AcceptChannel) -> Result<(), MsgHandleErrInternal> {
4539 let (value, output_script, user_id) = {
4540 let per_peer_state = self.per_peer_state.read().unwrap();
4541 let peer_state_mutex = per_peer_state.get(counterparty_node_id)
4543 debug_assert!(false);
4544 MsgHandleErrInternal::send_err_msg_no_close(format!("Can't find a peer matching the passed counterparty node_id {}", counterparty_node_id), msg.temporary_channel_id)
4546 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
4547 let peer_state = &mut *peer_state_lock;
4548 match peer_state.channel_by_id.entry(msg.temporary_channel_id) {
4549 hash_map::Entry::Occupied(mut chan) => {
4550 try_chan_entry!(self, chan.get_mut().accept_channel(&msg, &self.default_configuration.channel_handshake_limits, &peer_state.latest_features), chan);
4551 (chan.get().get_value_satoshis(), chan.get().get_funding_redeemscript().to_v0_p2wsh(), chan.get().get_user_id())
4553 hash_map::Entry::Vacant(_) => return Err(MsgHandleErrInternal::send_err_msg_no_close(format!("Got a message for a channel from the wrong node! No such channel for the passed counterparty_node_id {}", counterparty_node_id), msg.temporary_channel_id))
4556 let mut pending_events = self.pending_events.lock().unwrap();
4557 pending_events.push(events::Event::FundingGenerationReady {
4558 temporary_channel_id: msg.temporary_channel_id,
4559 counterparty_node_id: *counterparty_node_id,
4560 channel_value_satoshis: value,
4562 user_channel_id: user_id,
4567 fn internal_funding_created(&self, counterparty_node_id: &PublicKey, msg: &msgs::FundingCreated) -> Result<(), MsgHandleErrInternal> {
4568 let best_block = *self.best_block.read().unwrap();
4570 let per_peer_state = self.per_peer_state.read().unwrap();
4571 let peer_state_mutex = per_peer_state.get(counterparty_node_id)
4573 debug_assert!(false);
4574 MsgHandleErrInternal::send_err_msg_no_close(format!("Can't find a peer matching the passed counterparty node_id {}", counterparty_node_id), msg.temporary_channel_id)
4577 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
4578 let peer_state = &mut *peer_state_lock;
4579 let ((funding_msg, monitor), chan) =
4580 match peer_state.channel_by_id.entry(msg.temporary_channel_id) {
4581 hash_map::Entry::Occupied(mut chan) => {
4582 (try_chan_entry!(self, chan.get_mut().funding_created(msg, best_block, &self.signer_provider, &self.logger), chan), chan.remove())
4584 hash_map::Entry::Vacant(_) => return Err(MsgHandleErrInternal::send_err_msg_no_close(format!("Got a message for a channel from the wrong node! No such channel for the passed counterparty_node_id {}", counterparty_node_id), msg.temporary_channel_id))
4587 match peer_state.channel_by_id.entry(funding_msg.channel_id) {
4588 hash_map::Entry::Occupied(_) => {
4589 Err(MsgHandleErrInternal::send_err_msg_no_close("Already had channel with the new channel_id".to_owned(), funding_msg.channel_id))
4591 hash_map::Entry::Vacant(e) => {
4592 match self.id_to_peer.lock().unwrap().entry(chan.channel_id()) {
4593 hash_map::Entry::Occupied(_) => {
4594 return Err(MsgHandleErrInternal::send_err_msg_no_close(
4595 "The funding_created message had the same funding_txid as an existing channel - funding is not possible".to_owned(),
4596 funding_msg.channel_id))
4598 hash_map::Entry::Vacant(i_e) => {
4599 i_e.insert(chan.get_counterparty_node_id());
4603 // There's no problem signing a counterparty's funding transaction if our monitor
4604 // hasn't persisted to disk yet - we can't lose money on a transaction that we haven't
4605 // accepted payment from yet. We do, however, need to wait to send our channel_ready
4606 // until we have persisted our monitor.
4607 let new_channel_id = funding_msg.channel_id;
4608 peer_state.pending_msg_events.push(events::MessageSendEvent::SendFundingSigned {
4609 node_id: counterparty_node_id.clone(),
4613 let monitor_res = self.chain_monitor.watch_channel(monitor.get_funding_txo().0, monitor);
4615 let chan = e.insert(chan);
4616 let mut res = handle_new_monitor_update!(self, monitor_res, 0, peer_state_lock, peer_state,
4617 per_peer_state, chan, MANUALLY_REMOVING, { peer_state.channel_by_id.remove(&new_channel_id) });
4619 // Note that we reply with the new channel_id in error messages if we gave up on the
4620 // channel, not the temporary_channel_id. This is compatible with ourselves, but the
4621 // spec is somewhat ambiguous here. Not a huge deal since we'll send error messages for
4622 // any messages referencing a previously-closed channel anyway.
4623 // We do not propagate the monitor update to the user as it would be for a monitor
4624 // that we didn't manage to store (and that we don't care about - we don't respond
4625 // with the funding_signed so the channel can never go on chain).
4626 if let Err(MsgHandleErrInternal { shutdown_finish: Some((res, _)), .. }) = &mut res {
4634 fn internal_funding_signed(&self, counterparty_node_id: &PublicKey, msg: &msgs::FundingSigned) -> Result<(), MsgHandleErrInternal> {
4635 let best_block = *self.best_block.read().unwrap();
4636 let per_peer_state = self.per_peer_state.read().unwrap();
4637 let peer_state_mutex = per_peer_state.get(counterparty_node_id)
4639 debug_assert!(false);
4640 MsgHandleErrInternal::send_err_msg_no_close(format!("Can't find a peer matching the passed counterparty node_id {}", counterparty_node_id), msg.channel_id)
4643 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
4644 let peer_state = &mut *peer_state_lock;
4645 match peer_state.channel_by_id.entry(msg.channel_id) {
4646 hash_map::Entry::Occupied(mut chan) => {
4647 let monitor = try_chan_entry!(self,
4648 chan.get_mut().funding_signed(&msg, best_block, &self.signer_provider, &self.logger), chan);
4649 let update_res = self.chain_monitor.watch_channel(chan.get().get_funding_txo().unwrap(), monitor);
4650 let mut res = handle_new_monitor_update!(self, update_res, 0, peer_state_lock, peer_state, per_peer_state, chan);
4651 if let Err(MsgHandleErrInternal { ref mut shutdown_finish, .. }) = res {
4652 // We weren't able to watch the channel to begin with, so no updates should be made on
4653 // it. Previously, full_stack_target found an (unreachable) panic when the
4654 // monitor update contained within `shutdown_finish` was applied.
4655 if let Some((ref mut shutdown_finish, _)) = shutdown_finish {
4656 shutdown_finish.0.take();
4661 hash_map::Entry::Vacant(_) => return Err(MsgHandleErrInternal::send_err_msg_no_close("Failed to find corresponding channel".to_owned(), msg.channel_id))
4665 fn internal_channel_ready(&self, counterparty_node_id: &PublicKey, msg: &msgs::ChannelReady) -> Result<(), MsgHandleErrInternal> {
4666 let per_peer_state = self.per_peer_state.read().unwrap();
4667 let peer_state_mutex = per_peer_state.get(counterparty_node_id)
4669 debug_assert!(false);
4670 MsgHandleErrInternal::send_err_msg_no_close(format!("Can't find a peer matching the passed counterparty node_id {}", counterparty_node_id), msg.channel_id)
4672 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
4673 let peer_state = &mut *peer_state_lock;
4674 match peer_state.channel_by_id.entry(msg.channel_id) {
4675 hash_map::Entry::Occupied(mut chan) => {
4676 let announcement_sigs_opt = try_chan_entry!(self, chan.get_mut().channel_ready(&msg, &self.node_signer,
4677 self.genesis_hash.clone(), &self.default_configuration, &self.best_block.read().unwrap(), &self.logger), chan);
4678 if let Some(announcement_sigs) = announcement_sigs_opt {
4679 log_trace!(self.logger, "Sending announcement_signatures for channel {}", log_bytes!(chan.get().channel_id()));
4680 peer_state.pending_msg_events.push(events::MessageSendEvent::SendAnnouncementSignatures {
4681 node_id: counterparty_node_id.clone(),
4682 msg: announcement_sigs,
4684 } else if chan.get().is_usable() {
4685 // If we're sending an announcement_signatures, we'll send the (public)
4686 // channel_update after sending a channel_announcement when we receive our
4687 // counterparty's announcement_signatures. Thus, we only bother to send a
4688 // channel_update here if the channel is not public, i.e. we're not sending an
4689 // announcement_signatures.
4690 log_trace!(self.logger, "Sending private initial channel_update for our counterparty on channel {}", log_bytes!(chan.get().channel_id()));
4691 if let Ok(msg) = self.get_channel_update_for_unicast(chan.get()) {
4692 peer_state.pending_msg_events.push(events::MessageSendEvent::SendChannelUpdate {
4693 node_id: counterparty_node_id.clone(),
4699 emit_channel_ready_event!(self, chan.get_mut());
4703 hash_map::Entry::Vacant(_) => Err(MsgHandleErrInternal::send_err_msg_no_close(format!("Got a message for a channel from the wrong node! No such channel for the passed counterparty_node_id {}", counterparty_node_id), msg.channel_id))
4707 fn internal_shutdown(&self, counterparty_node_id: &PublicKey, msg: &msgs::Shutdown) -> Result<(), MsgHandleErrInternal> {
4708 let mut dropped_htlcs: Vec<(HTLCSource, PaymentHash)>;
4709 let result: Result<(), _> = loop {
4710 let per_peer_state = self.per_peer_state.read().unwrap();
4711 let peer_state_mutex = per_peer_state.get(counterparty_node_id)
4713 debug_assert!(false);
4714 MsgHandleErrInternal::send_err_msg_no_close(format!("Can't find a peer matching the passed counterparty node_id {}", counterparty_node_id), msg.channel_id)
4716 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
4717 let peer_state = &mut *peer_state_lock;
4718 match peer_state.channel_by_id.entry(msg.channel_id.clone()) {
4719 hash_map::Entry::Occupied(mut chan_entry) => {
4721 if !chan_entry.get().received_shutdown() {
4722 log_info!(self.logger, "Received a shutdown message from our counterparty for channel {}{}.",
4723 log_bytes!(msg.channel_id),
4724 if chan_entry.get().sent_shutdown() { " after we initiated shutdown" } else { "" });
4727 let funding_txo_opt = chan_entry.get().get_funding_txo();
4728 let (shutdown, monitor_update_opt, htlcs) = try_chan_entry!(self,
4729 chan_entry.get_mut().shutdown(&self.signer_provider, &peer_state.latest_features, &msg), chan_entry);
4730 dropped_htlcs = htlcs;
4732 if let Some(msg) = shutdown {
4733 // We can send the `shutdown` message before updating the `ChannelMonitor`
4734 // here as we don't need the monitor update to complete until we send a
4735 // `shutdown_signed`, which we'll delay if we're pending a monitor update.
4736 peer_state.pending_msg_events.push(events::MessageSendEvent::SendShutdown {
4737 node_id: *counterparty_node_id,
4742 // Update the monitor with the shutdown script if necessary.
4743 if let Some(monitor_update) = monitor_update_opt {
4744 let update_id = monitor_update.update_id;
4745 let update_res = self.chain_monitor.update_channel(funding_txo_opt.unwrap(), monitor_update);
4746 break handle_new_monitor_update!(self, update_res, update_id, peer_state_lock, peer_state, per_peer_state, chan_entry);
4750 hash_map::Entry::Vacant(_) => return Err(MsgHandleErrInternal::send_err_msg_no_close(format!("Got a message for a channel from the wrong node! No such channel for the passed counterparty_node_id {}", counterparty_node_id), msg.channel_id))
4753 for htlc_source in dropped_htlcs.drain(..) {
4754 let receiver = HTLCDestination::NextHopChannel { node_id: Some(counterparty_node_id.clone()), channel_id: msg.channel_id };
4755 let reason = HTLCFailReason::from_failure_code(0x4000 | 8);
4756 self.fail_htlc_backwards_internal(&htlc_source.0, &htlc_source.1, &reason, receiver);
4762 fn internal_closing_signed(&self, counterparty_node_id: &PublicKey, msg: &msgs::ClosingSigned) -> Result<(), MsgHandleErrInternal> {
4763 let per_peer_state = self.per_peer_state.read().unwrap();
4764 let peer_state_mutex = per_peer_state.get(counterparty_node_id)
4766 debug_assert!(false);
4767 MsgHandleErrInternal::send_err_msg_no_close(format!("Can't find a peer matching the passed counterparty node_id {}", counterparty_node_id), msg.channel_id)
4769 let (tx, chan_option) = {
4770 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
4771 let peer_state = &mut *peer_state_lock;
4772 match peer_state.channel_by_id.entry(msg.channel_id.clone()) {
4773 hash_map::Entry::Occupied(mut chan_entry) => {
4774 let (closing_signed, tx) = try_chan_entry!(self, chan_entry.get_mut().closing_signed(&self.fee_estimator, &msg), chan_entry);
4775 if let Some(msg) = closing_signed {
4776 peer_state.pending_msg_events.push(events::MessageSendEvent::SendClosingSigned {
4777 node_id: counterparty_node_id.clone(),
4782 // We're done with this channel, we've got a signed closing transaction and
4783 // will send the closing_signed back to the remote peer upon return. This
4784 // also implies there are no pending HTLCs left on the channel, so we can
4785 // fully delete it from tracking (the channel monitor is still around to
4786 // watch for old state broadcasts)!
4787 (tx, Some(remove_channel!(self, chan_entry)))
4788 } else { (tx, None) }
4790 hash_map::Entry::Vacant(_) => return Err(MsgHandleErrInternal::send_err_msg_no_close(format!("Got a message for a channel from the wrong node! No such channel for the passed counterparty_node_id {}", counterparty_node_id), msg.channel_id))
4793 if let Some(broadcast_tx) = tx {
4794 log_info!(self.logger, "Broadcasting {}", log_tx!(broadcast_tx));
4795 self.tx_broadcaster.broadcast_transaction(&broadcast_tx);
4797 if let Some(chan) = chan_option {
4798 if let Ok(update) = self.get_channel_update_for_broadcast(&chan) {
4799 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
4800 let peer_state = &mut *peer_state_lock;
4801 peer_state.pending_msg_events.push(events::MessageSendEvent::BroadcastChannelUpdate {
4805 self.issue_channel_close_events(&chan, ClosureReason::CooperativeClosure);
4810 fn internal_update_add_htlc(&self, counterparty_node_id: &PublicKey, msg: &msgs::UpdateAddHTLC) -> Result<(), MsgHandleErrInternal> {
4811 //TODO: BOLT 4 points out a specific attack where a peer may re-send an onion packet and
4812 //determine the state of the payment based on our response/if we forward anything/the time
4813 //we take to respond. We should take care to avoid allowing such an attack.
4815 //TODO: There exists a further attack where a node may garble the onion data, forward it to
4816 //us repeatedly garbled in different ways, and compare our error messages, which are
4817 //encrypted with the same key. It's not immediately obvious how to usefully exploit that,
4818 //but we should prevent it anyway.
4820 let pending_forward_info = self.decode_update_add_htlc_onion(msg);
4821 let per_peer_state = self.per_peer_state.read().unwrap();
4822 let peer_state_mutex = per_peer_state.get(counterparty_node_id)
4824 debug_assert!(false);
4825 MsgHandleErrInternal::send_err_msg_no_close(format!("Can't find a peer matching the passed counterparty node_id {}", counterparty_node_id), msg.channel_id)
4827 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
4828 let peer_state = &mut *peer_state_lock;
4829 match peer_state.channel_by_id.entry(msg.channel_id) {
4830 hash_map::Entry::Occupied(mut chan) => {
4832 let create_pending_htlc_status = |chan: &Channel<<SP::Target as SignerProvider>::Signer>, pending_forward_info: PendingHTLCStatus, error_code: u16| {
4833 // If the update_add is completely bogus, the call will Err and we will close,
4834 // but if we've sent a shutdown and they haven't acknowledged it yet, we just
4835 // want to reject the new HTLC and fail it backwards instead of forwarding.
4836 match pending_forward_info {
4837 PendingHTLCStatus::Forward(PendingHTLCInfo { ref incoming_shared_secret, .. }) => {
4838 let reason = if (error_code & 0x1000) != 0 {
4839 let (real_code, error_data) = self.get_htlc_inbound_temp_fail_err_and_data(error_code, chan);
4840 HTLCFailReason::reason(real_code, error_data)
4842 HTLCFailReason::from_failure_code(error_code)
4843 }.get_encrypted_failure_packet(incoming_shared_secret, &None);
4844 let msg = msgs::UpdateFailHTLC {
4845 channel_id: msg.channel_id,
4846 htlc_id: msg.htlc_id,
4849 PendingHTLCStatus::Fail(HTLCFailureMsg::Relay(msg))
4851 _ => pending_forward_info
4854 try_chan_entry!(self, chan.get_mut().update_add_htlc(&msg, pending_forward_info, create_pending_htlc_status, &self.logger), chan);
4856 hash_map::Entry::Vacant(_) => return Err(MsgHandleErrInternal::send_err_msg_no_close(format!("Got a message for a channel from the wrong node! No such channel for the passed counterparty_node_id {}", counterparty_node_id), msg.channel_id))
4861 fn internal_update_fulfill_htlc(&self, counterparty_node_id: &PublicKey, msg: &msgs::UpdateFulfillHTLC) -> Result<(), MsgHandleErrInternal> {
4862 let (htlc_source, forwarded_htlc_value) = {
4863 let per_peer_state = self.per_peer_state.read().unwrap();
4864 let peer_state_mutex = per_peer_state.get(counterparty_node_id)
4866 debug_assert!(false);
4867 MsgHandleErrInternal::send_err_msg_no_close(format!("Can't find a peer matching the passed counterparty node_id {}", counterparty_node_id), msg.channel_id)
4869 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
4870 let peer_state = &mut *peer_state_lock;
4871 match peer_state.channel_by_id.entry(msg.channel_id) {
4872 hash_map::Entry::Occupied(mut chan) => {
4873 try_chan_entry!(self, chan.get_mut().update_fulfill_htlc(&msg), chan)
4875 hash_map::Entry::Vacant(_) => return Err(MsgHandleErrInternal::send_err_msg_no_close(format!("Got a message for a channel from the wrong node! No such channel for the passed counterparty_node_id {}", counterparty_node_id), msg.channel_id))
4878 self.claim_funds_internal(htlc_source, msg.payment_preimage.clone(), Some(forwarded_htlc_value), false, msg.channel_id);
4882 fn internal_update_fail_htlc(&self, counterparty_node_id: &PublicKey, msg: &msgs::UpdateFailHTLC) -> Result<(), MsgHandleErrInternal> {
4883 let per_peer_state = self.per_peer_state.read().unwrap();
4884 let peer_state_mutex = per_peer_state.get(counterparty_node_id)
4886 debug_assert!(false);
4887 MsgHandleErrInternal::send_err_msg_no_close(format!("Can't find a peer matching the passed counterparty node_id {}", counterparty_node_id), msg.channel_id)
4889 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
4890 let peer_state = &mut *peer_state_lock;
4891 match peer_state.channel_by_id.entry(msg.channel_id) {
4892 hash_map::Entry::Occupied(mut chan) => {
4893 try_chan_entry!(self, chan.get_mut().update_fail_htlc(&msg, HTLCFailReason::from_msg(msg)), chan);
4895 hash_map::Entry::Vacant(_) => return Err(MsgHandleErrInternal::send_err_msg_no_close(format!("Got a message for a channel from the wrong node! No such channel for the passed counterparty_node_id {}", counterparty_node_id), msg.channel_id))
4900 fn internal_update_fail_malformed_htlc(&self, counterparty_node_id: &PublicKey, msg: &msgs::UpdateFailMalformedHTLC) -> Result<(), MsgHandleErrInternal> {
4901 let per_peer_state = self.per_peer_state.read().unwrap();
4902 let peer_state_mutex = per_peer_state.get(counterparty_node_id)
4904 debug_assert!(false);
4905 MsgHandleErrInternal::send_err_msg_no_close(format!("Can't find a peer matching the passed counterparty node_id {}", counterparty_node_id), msg.channel_id)
4907 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
4908 let peer_state = &mut *peer_state_lock;
4909 match peer_state.channel_by_id.entry(msg.channel_id) {
4910 hash_map::Entry::Occupied(mut chan) => {
4911 if (msg.failure_code & 0x8000) == 0 {
4912 let chan_err: ChannelError = ChannelError::Close("Got update_fail_malformed_htlc with BADONION not set".to_owned());
4913 try_chan_entry!(self, Err(chan_err), chan);
4915 try_chan_entry!(self, chan.get_mut().update_fail_malformed_htlc(&msg, HTLCFailReason::reason(msg.failure_code, msg.sha256_of_onion.to_vec())), chan);
4918 hash_map::Entry::Vacant(_) => return Err(MsgHandleErrInternal::send_err_msg_no_close(format!("Got a message for a channel from the wrong node! No such channel for the passed counterparty_node_id {}", counterparty_node_id), msg.channel_id))
4922 fn internal_commitment_signed(&self, counterparty_node_id: &PublicKey, msg: &msgs::CommitmentSigned) -> Result<(), MsgHandleErrInternal> {
4923 let per_peer_state = self.per_peer_state.read().unwrap();
4924 let peer_state_mutex = per_peer_state.get(counterparty_node_id)
4926 debug_assert!(false);
4927 MsgHandleErrInternal::send_err_msg_no_close(format!("Can't find a peer matching the passed counterparty node_id {}", counterparty_node_id), msg.channel_id)
4929 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
4930 let peer_state = &mut *peer_state_lock;
4931 match peer_state.channel_by_id.entry(msg.channel_id) {
4932 hash_map::Entry::Occupied(mut chan) => {
4933 let funding_txo = chan.get().get_funding_txo();
4934 let monitor_update = try_chan_entry!(self, chan.get_mut().commitment_signed(&msg, &self.logger), chan);
4935 let update_res = self.chain_monitor.update_channel(funding_txo.unwrap(), monitor_update);
4936 let update_id = monitor_update.update_id;
4937 handle_new_monitor_update!(self, update_res, update_id, peer_state_lock,
4938 peer_state, per_peer_state, chan)
4940 hash_map::Entry::Vacant(_) => return Err(MsgHandleErrInternal::send_err_msg_no_close(format!("Got a message for a channel from the wrong node! No such channel for the passed counterparty_node_id {}", counterparty_node_id), msg.channel_id))
4945 fn forward_htlcs(&self, per_source_pending_forwards: &mut [(u64, OutPoint, u128, Vec<(PendingHTLCInfo, u64)>)]) {
4946 for &mut (prev_short_channel_id, prev_funding_outpoint, prev_user_channel_id, ref mut pending_forwards) in per_source_pending_forwards {
4947 let mut push_forward_event = false;
4948 let mut new_intercept_events = Vec::new();
4949 let mut failed_intercept_forwards = Vec::new();
4950 if !pending_forwards.is_empty() {
4951 for (forward_info, prev_htlc_id) in pending_forwards.drain(..) {
4952 let scid = match forward_info.routing {
4953 PendingHTLCRouting::Forward { short_channel_id, .. } => short_channel_id,
4954 PendingHTLCRouting::Receive { .. } => 0,
4955 PendingHTLCRouting::ReceiveKeysend { .. } => 0,
4957 // Pull this now to avoid introducing a lock order with `forward_htlcs`.
4958 let is_our_scid = self.short_to_chan_info.read().unwrap().contains_key(&scid);
4960 let mut forward_htlcs = self.forward_htlcs.lock().unwrap();
4961 let forward_htlcs_empty = forward_htlcs.is_empty();
4962 match forward_htlcs.entry(scid) {
4963 hash_map::Entry::Occupied(mut entry) => {
4964 entry.get_mut().push(HTLCForwardInfo::AddHTLC(PendingAddHTLCInfo {
4965 prev_short_channel_id, prev_funding_outpoint, prev_htlc_id, prev_user_channel_id, forward_info }));
4967 hash_map::Entry::Vacant(entry) => {
4968 if !is_our_scid && forward_info.incoming_amt_msat.is_some() &&
4969 fake_scid::is_valid_intercept(&self.fake_scid_rand_bytes, scid, &self.genesis_hash)
4971 let intercept_id = InterceptId(Sha256::hash(&forward_info.incoming_shared_secret).into_inner());
4972 let mut pending_intercepts = self.pending_intercepted_htlcs.lock().unwrap();
4973 match pending_intercepts.entry(intercept_id) {
4974 hash_map::Entry::Vacant(entry) => {
4975 new_intercept_events.push(events::Event::HTLCIntercepted {
4976 requested_next_hop_scid: scid,
4977 payment_hash: forward_info.payment_hash,
4978 inbound_amount_msat: forward_info.incoming_amt_msat.unwrap(),
4979 expected_outbound_amount_msat: forward_info.outgoing_amt_msat,
4982 entry.insert(PendingAddHTLCInfo {
4983 prev_short_channel_id, prev_funding_outpoint, prev_htlc_id, prev_user_channel_id, forward_info });
4985 hash_map::Entry::Occupied(_) => {
4986 log_info!(self.logger, "Failed to forward incoming HTLC: detected duplicate intercepted payment over short channel id {}", scid);
4987 let htlc_source = HTLCSource::PreviousHopData(HTLCPreviousHopData {
4988 short_channel_id: prev_short_channel_id,
4989 outpoint: prev_funding_outpoint,
4990 htlc_id: prev_htlc_id,
4991 incoming_packet_shared_secret: forward_info.incoming_shared_secret,
4992 phantom_shared_secret: None,
4995 failed_intercept_forwards.push((htlc_source, forward_info.payment_hash,
4996 HTLCFailReason::from_failure_code(0x4000 | 10),
4997 HTLCDestination::InvalidForward { requested_forward_scid: scid },
5002 // We don't want to generate a PendingHTLCsForwardable event if only intercepted
5003 // payments are being processed.
5004 if forward_htlcs_empty {
5005 push_forward_event = true;
5007 entry.insert(vec!(HTLCForwardInfo::AddHTLC(PendingAddHTLCInfo {
5008 prev_short_channel_id, prev_funding_outpoint, prev_htlc_id, prev_user_channel_id, forward_info })));
5015 for (htlc_source, payment_hash, failure_reason, destination) in failed_intercept_forwards.drain(..) {
5016 self.fail_htlc_backwards_internal(&htlc_source, &payment_hash, &failure_reason, destination);
5019 if !new_intercept_events.is_empty() {
5020 let mut events = self.pending_events.lock().unwrap();
5021 events.append(&mut new_intercept_events);
5023 if push_forward_event { self.push_pending_forwards_ev() }
5027 // We only want to push a PendingHTLCsForwardable event if no others are queued.
5028 fn push_pending_forwards_ev(&self) {
5029 let mut pending_events = self.pending_events.lock().unwrap();
5030 let forward_ev_exists = pending_events.iter()
5031 .find(|ev| if let events::Event::PendingHTLCsForwardable { .. } = ev { true } else { false })
5033 if !forward_ev_exists {
5034 pending_events.push(events::Event::PendingHTLCsForwardable {
5036 Duration::from_millis(MIN_HTLC_RELAY_HOLDING_CELL_MILLIS),
5041 fn internal_revoke_and_ack(&self, counterparty_node_id: &PublicKey, msg: &msgs::RevokeAndACK) -> Result<(), MsgHandleErrInternal> {
5042 let (htlcs_to_fail, res) = {
5043 let per_peer_state = self.per_peer_state.read().unwrap();
5044 let mut peer_state_lock = per_peer_state.get(counterparty_node_id)
5046 debug_assert!(false);
5047 MsgHandleErrInternal::send_err_msg_no_close(format!("Can't find a peer matching the passed counterparty node_id {}", counterparty_node_id), msg.channel_id)
5048 }).map(|mtx| mtx.lock().unwrap())?;
5049 let peer_state = &mut *peer_state_lock;
5050 match peer_state.channel_by_id.entry(msg.channel_id) {
5051 hash_map::Entry::Occupied(mut chan) => {
5052 let funding_txo = chan.get().get_funding_txo();
5053 let (htlcs_to_fail, monitor_update) = try_chan_entry!(self, chan.get_mut().revoke_and_ack(&msg, &self.logger), chan);
5054 let update_res = self.chain_monitor.update_channel(funding_txo.unwrap(), monitor_update);
5055 let update_id = monitor_update.update_id;
5056 let res = handle_new_monitor_update!(self, update_res, update_id,
5057 peer_state_lock, peer_state, per_peer_state, chan);
5058 (htlcs_to_fail, res)
5060 hash_map::Entry::Vacant(_) => return Err(MsgHandleErrInternal::send_err_msg_no_close(format!("Got a message for a channel from the wrong node! No such channel for the passed counterparty_node_id {}", counterparty_node_id), msg.channel_id))
5063 self.fail_holding_cell_htlcs(htlcs_to_fail, msg.channel_id, counterparty_node_id);
5067 fn internal_update_fee(&self, counterparty_node_id: &PublicKey, msg: &msgs::UpdateFee) -> Result<(), MsgHandleErrInternal> {
5068 let per_peer_state = self.per_peer_state.read().unwrap();
5069 let peer_state_mutex = per_peer_state.get(counterparty_node_id)
5071 debug_assert!(false);
5072 MsgHandleErrInternal::send_err_msg_no_close(format!("Can't find a peer matching the passed counterparty node_id {}", counterparty_node_id), msg.channel_id)
5074 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
5075 let peer_state = &mut *peer_state_lock;
5076 match peer_state.channel_by_id.entry(msg.channel_id) {
5077 hash_map::Entry::Occupied(mut chan) => {
5078 try_chan_entry!(self, chan.get_mut().update_fee(&self.fee_estimator, &msg, &self.logger), chan);
5080 hash_map::Entry::Vacant(_) => return Err(MsgHandleErrInternal::send_err_msg_no_close(format!("Got a message for a channel from the wrong node! No such channel for the passed counterparty_node_id {}", counterparty_node_id), msg.channel_id))
5085 fn internal_announcement_signatures(&self, counterparty_node_id: &PublicKey, msg: &msgs::AnnouncementSignatures) -> Result<(), MsgHandleErrInternal> {
5086 let per_peer_state = self.per_peer_state.read().unwrap();
5087 let peer_state_mutex = per_peer_state.get(counterparty_node_id)
5089 debug_assert!(false);
5090 MsgHandleErrInternal::send_err_msg_no_close(format!("Can't find a peer matching the passed counterparty node_id {}", counterparty_node_id), msg.channel_id)
5092 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
5093 let peer_state = &mut *peer_state_lock;
5094 match peer_state.channel_by_id.entry(msg.channel_id) {
5095 hash_map::Entry::Occupied(mut chan) => {
5096 if !chan.get().is_usable() {
5097 return Err(MsgHandleErrInternal::from_no_close(LightningError{err: "Got an announcement_signatures before we were ready for it".to_owned(), action: msgs::ErrorAction::IgnoreError}));
5100 peer_state.pending_msg_events.push(events::MessageSendEvent::BroadcastChannelAnnouncement {
5101 msg: try_chan_entry!(self, chan.get_mut().announcement_signatures(
5102 &self.node_signer, self.genesis_hash.clone(), self.best_block.read().unwrap().height(),
5103 msg, &self.default_configuration
5105 // Note that announcement_signatures fails if the channel cannot be announced,
5106 // so get_channel_update_for_broadcast will never fail by the time we get here.
5107 update_msg: Some(self.get_channel_update_for_broadcast(chan.get()).unwrap()),
5110 hash_map::Entry::Vacant(_) => return Err(MsgHandleErrInternal::send_err_msg_no_close(format!("Got a message for a channel from the wrong node! No such channel for the passed counterparty_node_id {}", counterparty_node_id), msg.channel_id))
5115 /// Returns ShouldPersist if anything changed, otherwise either SkipPersist or an Err.
5116 fn internal_channel_update(&self, counterparty_node_id: &PublicKey, msg: &msgs::ChannelUpdate) -> Result<NotifyOption, MsgHandleErrInternal> {
5117 let (chan_counterparty_node_id, chan_id) = match self.short_to_chan_info.read().unwrap().get(&msg.contents.short_channel_id) {
5118 Some((cp_id, chan_id)) => (cp_id.clone(), chan_id.clone()),
5120 // It's not a local channel
5121 return Ok(NotifyOption::SkipPersist)
5124 let per_peer_state = self.per_peer_state.read().unwrap();
5125 let peer_state_mutex_opt = per_peer_state.get(&chan_counterparty_node_id);
5126 if peer_state_mutex_opt.is_none() {
5127 return Ok(NotifyOption::SkipPersist)
5129 let mut peer_state_lock = peer_state_mutex_opt.unwrap().lock().unwrap();
5130 let peer_state = &mut *peer_state_lock;
5131 match peer_state.channel_by_id.entry(chan_id) {
5132 hash_map::Entry::Occupied(mut chan) => {
5133 if chan.get().get_counterparty_node_id() != *counterparty_node_id {
5134 if chan.get().should_announce() {
5135 // If the announcement is about a channel of ours which is public, some
5136 // other peer may simply be forwarding all its gossip to us. Don't provide
5137 // a scary-looking error message and return Ok instead.
5138 return Ok(NotifyOption::SkipPersist);
5140 return Err(MsgHandleErrInternal::send_err_msg_no_close("Got a channel_update for a channel from the wrong node - it shouldn't know about our private channels!".to_owned(), chan_id));
5142 let were_node_one = self.get_our_node_id().serialize()[..] < chan.get().get_counterparty_node_id().serialize()[..];
5143 let msg_from_node_one = msg.contents.flags & 1 == 0;
5144 if were_node_one == msg_from_node_one {
5145 return Ok(NotifyOption::SkipPersist);
5147 log_debug!(self.logger, "Received channel_update for channel {}.", log_bytes!(chan_id));
5148 try_chan_entry!(self, chan.get_mut().channel_update(&msg), chan);
5151 hash_map::Entry::Vacant(_) => return Ok(NotifyOption::SkipPersist)
5153 Ok(NotifyOption::DoPersist)
5156 fn internal_channel_reestablish(&self, counterparty_node_id: &PublicKey, msg: &msgs::ChannelReestablish) -> Result<(), MsgHandleErrInternal> {
5158 let need_lnd_workaround = {
5159 let per_peer_state = self.per_peer_state.read().unwrap();
5161 let peer_state_mutex = per_peer_state.get(counterparty_node_id)
5163 debug_assert!(false);
5164 MsgHandleErrInternal::send_err_msg_no_close(format!("Can't find a peer matching the passed counterparty node_id {}", counterparty_node_id), msg.channel_id)
5166 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
5167 let peer_state = &mut *peer_state_lock;
5168 match peer_state.channel_by_id.entry(msg.channel_id) {
5169 hash_map::Entry::Occupied(mut chan) => {
5170 // Currently, we expect all holding cell update_adds to be dropped on peer
5171 // disconnect, so Channel's reestablish will never hand us any holding cell
5172 // freed HTLCs to fail backwards. If in the future we no longer drop pending
5173 // add-HTLCs on disconnect, we may be handed HTLCs to fail backwards here.
5174 let responses = try_chan_entry!(self, chan.get_mut().channel_reestablish(
5175 msg, &self.logger, &self.node_signer, self.genesis_hash,
5176 &self.default_configuration, &*self.best_block.read().unwrap()), chan);
5177 let mut channel_update = None;
5178 if let Some(msg) = responses.shutdown_msg {
5179 peer_state.pending_msg_events.push(events::MessageSendEvent::SendShutdown {
5180 node_id: counterparty_node_id.clone(),
5183 } else if chan.get().is_usable() {
5184 // If the channel is in a usable state (ie the channel is not being shut
5185 // down), send a unicast channel_update to our counterparty to make sure
5186 // they have the latest channel parameters.
5187 if let Ok(msg) = self.get_channel_update_for_unicast(chan.get()) {
5188 channel_update = Some(events::MessageSendEvent::SendChannelUpdate {
5189 node_id: chan.get().get_counterparty_node_id(),
5194 let need_lnd_workaround = chan.get_mut().workaround_lnd_bug_4006.take();
5195 htlc_forwards = self.handle_channel_resumption(
5196 &mut peer_state.pending_msg_events, chan.get_mut(), responses.raa, responses.commitment_update, responses.order,
5197 Vec::new(), None, responses.channel_ready, responses.announcement_sigs);
5198 if let Some(upd) = channel_update {
5199 peer_state.pending_msg_events.push(upd);
5203 hash_map::Entry::Vacant(_) => return Err(MsgHandleErrInternal::send_err_msg_no_close(format!("Got a message for a channel from the wrong node! No such channel for the passed counterparty_node_id {}", counterparty_node_id), msg.channel_id))
5207 if let Some(forwards) = htlc_forwards {
5208 self.forward_htlcs(&mut [forwards][..]);
5211 if let Some(channel_ready_msg) = need_lnd_workaround {
5212 self.internal_channel_ready(counterparty_node_id, &channel_ready_msg)?;
5217 /// Process pending events from the [`chain::Watch`], returning whether any events were processed.
5218 fn process_pending_monitor_events(&self) -> bool {
5219 debug_assert!(self.total_consistency_lock.try_write().is_err()); // Caller holds read lock
5221 let mut failed_channels = Vec::new();
5222 let mut pending_monitor_events = self.chain_monitor.release_pending_monitor_events();
5223 let has_pending_monitor_events = !pending_monitor_events.is_empty();
5224 for (funding_outpoint, mut monitor_events, counterparty_node_id) in pending_monitor_events.drain(..) {
5225 for monitor_event in monitor_events.drain(..) {
5226 match monitor_event {
5227 MonitorEvent::HTLCEvent(htlc_update) => {
5228 if let Some(preimage) = htlc_update.payment_preimage {
5229 log_trace!(self.logger, "Claiming HTLC with preimage {} from our monitor", log_bytes!(preimage.0));
5230 self.claim_funds_internal(htlc_update.source, preimage, htlc_update.htlc_value_satoshis.map(|v| v * 1000), true, funding_outpoint.to_channel_id());
5232 log_trace!(self.logger, "Failing HTLC with hash {} from our monitor", log_bytes!(htlc_update.payment_hash.0));
5233 let receiver = HTLCDestination::NextHopChannel { node_id: counterparty_node_id, channel_id: funding_outpoint.to_channel_id() };
5234 let reason = HTLCFailReason::from_failure_code(0x4000 | 8);
5235 self.fail_htlc_backwards_internal(&htlc_update.source, &htlc_update.payment_hash, &reason, receiver);
5238 MonitorEvent::CommitmentTxConfirmed(funding_outpoint) |
5239 MonitorEvent::UpdateFailed(funding_outpoint) => {
5240 let counterparty_node_id_opt = match counterparty_node_id {
5241 Some(cp_id) => Some(cp_id),
5243 // TODO: Once we can rely on the counterparty_node_id from the
5244 // monitor event, this and the id_to_peer map should be removed.
5245 let id_to_peer = self.id_to_peer.lock().unwrap();
5246 id_to_peer.get(&funding_outpoint.to_channel_id()).cloned()
5249 if let Some(counterparty_node_id) = counterparty_node_id_opt {
5250 let per_peer_state = self.per_peer_state.read().unwrap();
5251 if let Some(peer_state_mutex) = per_peer_state.get(&counterparty_node_id) {
5252 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
5253 let peer_state = &mut *peer_state_lock;
5254 let pending_msg_events = &mut peer_state.pending_msg_events;
5255 if let hash_map::Entry::Occupied(chan_entry) = peer_state.channel_by_id.entry(funding_outpoint.to_channel_id()) {
5256 let mut chan = remove_channel!(self, chan_entry);
5257 failed_channels.push(chan.force_shutdown(false));
5258 if let Ok(update) = self.get_channel_update_for_broadcast(&chan) {
5259 pending_msg_events.push(events::MessageSendEvent::BroadcastChannelUpdate {
5263 let reason = if let MonitorEvent::UpdateFailed(_) = monitor_event {
5264 ClosureReason::ProcessingError { err: "Failed to persist ChannelMonitor update during chain sync".to_string() }
5266 ClosureReason::CommitmentTxConfirmed
5268 self.issue_channel_close_events(&chan, reason);
5269 pending_msg_events.push(events::MessageSendEvent::HandleError {
5270 node_id: chan.get_counterparty_node_id(),
5271 action: msgs::ErrorAction::SendErrorMessage {
5272 msg: msgs::ErrorMessage { channel_id: chan.channel_id(), data: "Channel force-closed".to_owned() }
5279 MonitorEvent::Completed { funding_txo, monitor_update_id } => {
5280 self.channel_monitor_updated(&funding_txo, monitor_update_id, counterparty_node_id.as_ref());
5286 for failure in failed_channels.drain(..) {
5287 self.finish_force_close_channel(failure);
5290 has_pending_monitor_events
5293 /// In chanmon_consistency_target, we'd like to be able to restore monitor updating without
5294 /// handling all pending events (i.e. not PendingHTLCsForwardable). Thus, we expose monitor
5295 /// update events as a separate process method here.
5297 pub fn process_monitor_events(&self) {
5298 PersistenceNotifierGuard::optionally_notify(&self.total_consistency_lock, &self.persistence_notifier, || {
5299 if self.process_pending_monitor_events() {
5300 NotifyOption::DoPersist
5302 NotifyOption::SkipPersist
5307 /// Check the holding cell in each channel and free any pending HTLCs in them if possible.
5308 /// Returns whether there were any updates such as if pending HTLCs were freed or a monitor
5309 /// update was applied.
5310 fn check_free_holding_cells(&self) -> bool {
5311 let mut has_monitor_update = false;
5312 let mut failed_htlcs = Vec::new();
5313 let mut handle_errors = Vec::new();
5315 // Walk our list of channels and find any that need to update. Note that when we do find an
5316 // update, if it includes actions that must be taken afterwards, we have to drop the
5317 // per-peer state lock as well as the top level per_peer_state lock. Thus, we loop until we
5318 // manage to go through all our peers without finding a single channel to update.
5320 let per_peer_state = self.per_peer_state.read().unwrap();
5321 for (_cp_id, peer_state_mutex) in per_peer_state.iter() {
5323 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
5324 let peer_state: &mut PeerState<_> = &mut *peer_state_lock;
5325 for (channel_id, chan) in peer_state.channel_by_id.iter_mut() {
5326 let counterparty_node_id = chan.get_counterparty_node_id();
5327 let funding_txo = chan.get_funding_txo();
5328 let (monitor_opt, holding_cell_failed_htlcs) =
5329 chan.maybe_free_holding_cell_htlcs(&self.logger);
5330 if !holding_cell_failed_htlcs.is_empty() {
5331 failed_htlcs.push((holding_cell_failed_htlcs, *channel_id, counterparty_node_id));
5333 if let Some(monitor_update) = monitor_opt {
5334 has_monitor_update = true;
5336 let update_res = self.chain_monitor.update_channel(
5337 funding_txo.expect("channel is live"), monitor_update);
5338 let update_id = monitor_update.update_id;
5339 let channel_id: [u8; 32] = *channel_id;
5340 let res = handle_new_monitor_update!(self, update_res, update_id,
5341 peer_state_lock, peer_state, per_peer_state, chan, MANUALLY_REMOVING,
5342 peer_state.channel_by_id.remove(&channel_id));
5344 handle_errors.push((counterparty_node_id, res));
5346 continue 'peer_loop;
5355 let has_update = has_monitor_update || !failed_htlcs.is_empty() || !handle_errors.is_empty();
5356 for (failures, channel_id, counterparty_node_id) in failed_htlcs.drain(..) {
5357 self.fail_holding_cell_htlcs(failures, channel_id, &counterparty_node_id);
5360 for (counterparty_node_id, err) in handle_errors.drain(..) {
5361 let _ = handle_error!(self, err, counterparty_node_id);
5367 /// Check whether any channels have finished removing all pending updates after a shutdown
5368 /// exchange and can now send a closing_signed.
5369 /// Returns whether any closing_signed messages were generated.
5370 fn maybe_generate_initial_closing_signed(&self) -> bool {
5371 let mut handle_errors: Vec<(PublicKey, Result<(), _>)> = Vec::new();
5372 let mut has_update = false;
5374 let per_peer_state = self.per_peer_state.read().unwrap();
5376 for (_cp_id, peer_state_mutex) in per_peer_state.iter() {
5377 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
5378 let peer_state = &mut *peer_state_lock;
5379 let pending_msg_events = &mut peer_state.pending_msg_events;
5380 peer_state.channel_by_id.retain(|channel_id, chan| {
5381 match chan.maybe_propose_closing_signed(&self.fee_estimator, &self.logger) {
5382 Ok((msg_opt, tx_opt)) => {
5383 if let Some(msg) = msg_opt {
5385 pending_msg_events.push(events::MessageSendEvent::SendClosingSigned {
5386 node_id: chan.get_counterparty_node_id(), msg,
5389 if let Some(tx) = tx_opt {
5390 // We're done with this channel. We got a closing_signed and sent back
5391 // a closing_signed with a closing transaction to broadcast.
5392 if let Ok(update) = self.get_channel_update_for_broadcast(&chan) {
5393 pending_msg_events.push(events::MessageSendEvent::BroadcastChannelUpdate {
5398 self.issue_channel_close_events(chan, ClosureReason::CooperativeClosure);
5400 log_info!(self.logger, "Broadcasting {}", log_tx!(tx));
5401 self.tx_broadcaster.broadcast_transaction(&tx);
5402 update_maps_on_chan_removal!(self, chan);
5408 let (close_channel, res) = convert_chan_err!(self, e, chan, channel_id);
5409 handle_errors.push((chan.get_counterparty_node_id(), Err(res)));
5417 for (counterparty_node_id, err) in handle_errors.drain(..) {
5418 let _ = handle_error!(self, err, counterparty_node_id);
5424 /// Handle a list of channel failures during a block_connected or block_disconnected call,
5425 /// pushing the channel monitor update (if any) to the background events queue and removing the
5427 fn handle_init_event_channel_failures(&self, mut failed_channels: Vec<ShutdownResult>) {
5428 for mut failure in failed_channels.drain(..) {
5429 // Either a commitment transactions has been confirmed on-chain or
5430 // Channel::block_disconnected detected that the funding transaction has been
5431 // reorganized out of the main chain.
5432 // We cannot broadcast our latest local state via monitor update (as
5433 // Channel::force_shutdown tries to make us do) as we may still be in initialization,
5434 // so we track the update internally and handle it when the user next calls
5435 // timer_tick_occurred, guaranteeing we're running normally.
5436 if let Some((funding_txo, update)) = failure.0.take() {
5437 assert_eq!(update.updates.len(), 1);
5438 if let ChannelMonitorUpdateStep::ChannelForceClosed { should_broadcast } = update.updates[0] {
5439 assert!(should_broadcast);
5440 } else { unreachable!(); }
5441 self.pending_background_events.lock().unwrap().push(BackgroundEvent::ClosingMonitorUpdate((funding_txo, update)));
5443 self.finish_force_close_channel(failure);
5447 fn set_payment_hash_secret_map(&self, payment_hash: PaymentHash, payment_preimage: Option<PaymentPreimage>, min_value_msat: Option<u64>, invoice_expiry_delta_secs: u32) -> Result<PaymentSecret, APIError> {
5448 assert!(invoice_expiry_delta_secs <= 60*60*24*365); // Sadly bitcoin timestamps are u32s, so panic before 2106
5450 if min_value_msat.is_some() && min_value_msat.unwrap() > MAX_VALUE_MSAT {
5451 return Err(APIError::APIMisuseError { err: format!("min_value_msat of {} greater than total 21 million bitcoin supply", min_value_msat.unwrap()) });
5454 let payment_secret = PaymentSecret(self.entropy_source.get_secure_random_bytes());
5456 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
5457 let mut payment_secrets = self.pending_inbound_payments.lock().unwrap();
5458 match payment_secrets.entry(payment_hash) {
5459 hash_map::Entry::Vacant(e) => {
5460 e.insert(PendingInboundPayment {
5461 payment_secret, min_value_msat, payment_preimage,
5462 user_payment_id: 0, // For compatibility with version 0.0.103 and earlier
5463 // We assume that highest_seen_timestamp is pretty close to the current time -
5464 // it's updated when we receive a new block with the maximum time we've seen in
5465 // a header. It should never be more than two hours in the future.
5466 // Thus, we add two hours here as a buffer to ensure we absolutely
5467 // never fail a payment too early.
5468 // Note that we assume that received blocks have reasonably up-to-date
5470 expiry_time: self.highest_seen_timestamp.load(Ordering::Acquire) as u64 + invoice_expiry_delta_secs as u64 + 7200,
5473 hash_map::Entry::Occupied(_) => return Err(APIError::APIMisuseError { err: "Duplicate payment hash".to_owned() }),
5478 /// Gets a payment secret and payment hash for use in an invoice given to a third party wishing
5481 /// This differs from [`create_inbound_payment_for_hash`] only in that it generates the
5482 /// [`PaymentHash`] and [`PaymentPreimage`] for you.
5484 /// The [`PaymentPreimage`] will ultimately be returned to you in the [`PaymentClaimable`], which
5485 /// will have the [`PaymentClaimable::purpose`] be [`PaymentPurpose::InvoicePayment`] with
5486 /// its [`PaymentPurpose::InvoicePayment::payment_preimage`] field filled in. That should then be
5487 /// passed directly to [`claim_funds`].
5489 /// See [`create_inbound_payment_for_hash`] for detailed documentation on behavior and requirements.
5491 /// Note that a malicious eavesdropper can intuit whether an inbound payment was created by
5492 /// `create_inbound_payment` or `create_inbound_payment_for_hash` based on runtime.
5496 /// If you register an inbound payment with this method, then serialize the `ChannelManager`, then
5497 /// deserialize it with a node running 0.0.103 and earlier, the payment will fail to be received.
5499 /// Errors if `min_value_msat` is greater than total bitcoin supply.
5501 /// If `min_final_cltv_expiry_delta` is set to some value, then the payment will not be receivable
5502 /// on versions of LDK prior to 0.0.114.
5504 /// [`claim_funds`]: Self::claim_funds
5505 /// [`PaymentClaimable`]: events::Event::PaymentClaimable
5506 /// [`PaymentClaimable::purpose`]: events::Event::PaymentClaimable::purpose
5507 /// [`PaymentPurpose::InvoicePayment`]: events::PaymentPurpose::InvoicePayment
5508 /// [`PaymentPurpose::InvoicePayment::payment_preimage`]: events::PaymentPurpose::InvoicePayment::payment_preimage
5509 /// [`create_inbound_payment_for_hash`]: Self::create_inbound_payment_for_hash
5510 pub fn create_inbound_payment(&self, min_value_msat: Option<u64>, invoice_expiry_delta_secs: u32,
5511 min_final_cltv_expiry_delta: Option<u16>) -> Result<(PaymentHash, PaymentSecret), ()> {
5512 inbound_payment::create(&self.inbound_payment_key, min_value_msat, invoice_expiry_delta_secs,
5513 &self.entropy_source, self.highest_seen_timestamp.load(Ordering::Acquire) as u64,
5514 min_final_cltv_expiry_delta)
5517 /// Legacy version of [`create_inbound_payment`]. Use this method if you wish to share
5518 /// serialized state with LDK node(s) running 0.0.103 and earlier.
5520 /// May panic if `invoice_expiry_delta_secs` is greater than one year.
5523 /// This method is deprecated and will be removed soon.
5525 /// [`create_inbound_payment`]: Self::create_inbound_payment
5527 pub fn create_inbound_payment_legacy(&self, min_value_msat: Option<u64>, invoice_expiry_delta_secs: u32) -> Result<(PaymentHash, PaymentSecret), APIError> {
5528 let payment_preimage = PaymentPreimage(self.entropy_source.get_secure_random_bytes());
5529 let payment_hash = PaymentHash(Sha256::hash(&payment_preimage.0).into_inner());
5530 let payment_secret = self.set_payment_hash_secret_map(payment_hash, Some(payment_preimage), min_value_msat, invoice_expiry_delta_secs)?;
5531 Ok((payment_hash, payment_secret))
5534 /// Gets a [`PaymentSecret`] for a given [`PaymentHash`], for which the payment preimage is
5535 /// stored external to LDK.
5537 /// A [`PaymentClaimable`] event will only be generated if the [`PaymentSecret`] matches a
5538 /// payment secret fetched via this method or [`create_inbound_payment`], and which is at least
5539 /// the `min_value_msat` provided here, if one is provided.
5541 /// The [`PaymentHash`] (and corresponding [`PaymentPreimage`]) should be globally unique, though
5542 /// note that LDK will not stop you from registering duplicate payment hashes for inbound
5545 /// `min_value_msat` should be set if the invoice being generated contains a value. Any payment
5546 /// received for the returned [`PaymentHash`] will be required to be at least `min_value_msat`
5547 /// before a [`PaymentClaimable`] event will be generated, ensuring that we do not provide the
5548 /// sender "proof-of-payment" unless they have paid the required amount.
5550 /// `invoice_expiry_delta_secs` describes the number of seconds that the invoice is valid for
5551 /// in excess of the current time. This should roughly match the expiry time set in the invoice.
5552 /// After this many seconds, we will remove the inbound payment, resulting in any attempts to
5553 /// pay the invoice failing. The BOLT spec suggests 3,600 secs as a default validity time for
5554 /// invoices when no timeout is set.
5556 /// Note that we use block header time to time-out pending inbound payments (with some margin
5557 /// to compensate for the inaccuracy of block header timestamps). Thus, in practice we will
5558 /// accept a payment and generate a [`PaymentClaimable`] event for some time after the expiry.
5559 /// If you need exact expiry semantics, you should enforce them upon receipt of
5560 /// [`PaymentClaimable`].
5562 /// Note that invoices generated for inbound payments should have their `min_final_cltv_expiry_delta`
5563 /// set to at least [`MIN_FINAL_CLTV_EXPIRY_DELTA`].
5565 /// Note that a malicious eavesdropper can intuit whether an inbound payment was created by
5566 /// `create_inbound_payment` or `create_inbound_payment_for_hash` based on runtime.
5570 /// If you register an inbound payment with this method, then serialize the `ChannelManager`, then
5571 /// deserialize it with a node running 0.0.103 and earlier, the payment will fail to be received.
5573 /// Errors if `min_value_msat` is greater than total bitcoin supply.
5575 /// If `min_final_cltv_expiry_delta` is set to some value, then the payment will not be receivable
5576 /// on versions of LDK prior to 0.0.114.
5578 /// [`create_inbound_payment`]: Self::create_inbound_payment
5579 /// [`PaymentClaimable`]: events::Event::PaymentClaimable
5580 pub fn create_inbound_payment_for_hash(&self, payment_hash: PaymentHash, min_value_msat: Option<u64>,
5581 invoice_expiry_delta_secs: u32, min_final_cltv_expiry: Option<u16>) -> Result<PaymentSecret, ()> {
5582 inbound_payment::create_from_hash(&self.inbound_payment_key, min_value_msat, payment_hash,
5583 invoice_expiry_delta_secs, self.highest_seen_timestamp.load(Ordering::Acquire) as u64,
5584 min_final_cltv_expiry)
5587 /// Legacy version of [`create_inbound_payment_for_hash`]. Use this method if you wish to share
5588 /// serialized state with LDK node(s) running 0.0.103 and earlier.
5590 /// May panic if `invoice_expiry_delta_secs` is greater than one year.
5593 /// This method is deprecated and will be removed soon.
5595 /// [`create_inbound_payment_for_hash`]: Self::create_inbound_payment_for_hash
5597 pub fn create_inbound_payment_for_hash_legacy(&self, payment_hash: PaymentHash, min_value_msat: Option<u64>, invoice_expiry_delta_secs: u32) -> Result<PaymentSecret, APIError> {
5598 self.set_payment_hash_secret_map(payment_hash, None, min_value_msat, invoice_expiry_delta_secs)
5601 /// Gets an LDK-generated payment preimage from a payment hash and payment secret that were
5602 /// previously returned from [`create_inbound_payment`].
5604 /// [`create_inbound_payment`]: Self::create_inbound_payment
5605 pub fn get_payment_preimage(&self, payment_hash: PaymentHash, payment_secret: PaymentSecret) -> Result<PaymentPreimage, APIError> {
5606 inbound_payment::get_payment_preimage(payment_hash, payment_secret, &self.inbound_payment_key)
5609 /// Gets a fake short channel id for use in receiving [phantom node payments]. These fake scids
5610 /// are used when constructing the phantom invoice's route hints.
5612 /// [phantom node payments]: crate::chain::keysinterface::PhantomKeysManager
5613 pub fn get_phantom_scid(&self) -> u64 {
5614 let best_block_height = self.best_block.read().unwrap().height();
5615 let short_to_chan_info = self.short_to_chan_info.read().unwrap();
5617 let scid_candidate = fake_scid::Namespace::Phantom.get_fake_scid(best_block_height, &self.genesis_hash, &self.fake_scid_rand_bytes, &self.entropy_source);
5618 // Ensure the generated scid doesn't conflict with a real channel.
5619 match short_to_chan_info.get(&scid_candidate) {
5620 Some(_) => continue,
5621 None => return scid_candidate
5626 /// Gets route hints for use in receiving [phantom node payments].
5628 /// [phantom node payments]: crate::chain::keysinterface::PhantomKeysManager
5629 pub fn get_phantom_route_hints(&self) -> PhantomRouteHints {
5631 channels: self.list_usable_channels(),
5632 phantom_scid: self.get_phantom_scid(),
5633 real_node_pubkey: self.get_our_node_id(),
5637 /// Gets a fake short channel id for use in receiving intercepted payments. These fake scids are
5638 /// used when constructing the route hints for HTLCs intended to be intercepted. See
5639 /// [`ChannelManager::forward_intercepted_htlc`].
5641 /// Note that this method is not guaranteed to return unique values, you may need to call it a few
5642 /// times to get a unique scid.
5643 pub fn get_intercept_scid(&self) -> u64 {
5644 let best_block_height = self.best_block.read().unwrap().height();
5645 let short_to_chan_info = self.short_to_chan_info.read().unwrap();
5647 let scid_candidate = fake_scid::Namespace::Intercept.get_fake_scid(best_block_height, &self.genesis_hash, &self.fake_scid_rand_bytes, &self.entropy_source);
5648 // Ensure the generated scid doesn't conflict with a real channel.
5649 if short_to_chan_info.contains_key(&scid_candidate) { continue }
5650 return scid_candidate
5654 /// Gets inflight HTLC information by processing pending outbound payments that are in
5655 /// our channels. May be used during pathfinding to account for in-use channel liquidity.
5656 pub fn compute_inflight_htlcs(&self) -> InFlightHtlcs {
5657 let mut inflight_htlcs = InFlightHtlcs::new();
5659 let per_peer_state = self.per_peer_state.read().unwrap();
5660 for (_cp_id, peer_state_mutex) in per_peer_state.iter() {
5661 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
5662 let peer_state = &mut *peer_state_lock;
5663 for chan in peer_state.channel_by_id.values() {
5664 for (htlc_source, _) in chan.inflight_htlc_sources() {
5665 if let HTLCSource::OutboundRoute { path, .. } = htlc_source {
5666 inflight_htlcs.process_path(path, self.get_our_node_id());
5675 #[cfg(any(test, fuzzing, feature = "_test_utils"))]
5676 pub fn get_and_clear_pending_events(&self) -> Vec<events::Event> {
5677 let events = core::cell::RefCell::new(Vec::new());
5678 let event_handler = |event: events::Event| events.borrow_mut().push(event);
5679 self.process_pending_events(&event_handler);
5683 #[cfg(feature = "_test_utils")]
5684 pub fn push_pending_event(&self, event: events::Event) {
5685 let mut events = self.pending_events.lock().unwrap();
5690 pub fn pop_pending_event(&self) -> Option<events::Event> {
5691 let mut events = self.pending_events.lock().unwrap();
5692 if events.is_empty() { None } else { Some(events.remove(0)) }
5696 pub fn has_pending_payments(&self) -> bool {
5697 self.pending_outbound_payments.has_pending_payments()
5701 pub fn clear_pending_payments(&self) {
5702 self.pending_outbound_payments.clear_pending_payments()
5705 /// Processes any events asynchronously in the order they were generated since the last call
5706 /// using the given event handler.
5708 /// See the trait-level documentation of [`EventsProvider`] for requirements.
5709 pub async fn process_pending_events_async<Future: core::future::Future, H: Fn(Event) -> Future>(
5712 // We'll acquire our total consistency lock until the returned future completes so that
5713 // we can be sure no other persists happen while processing events.
5714 let _read_guard = self.total_consistency_lock.read().unwrap();
5716 let mut result = NotifyOption::SkipPersist;
5718 // TODO: This behavior should be documented. It's unintuitive that we query
5719 // ChannelMonitors when clearing other events.
5720 if self.process_pending_monitor_events() {
5721 result = NotifyOption::DoPersist;
5724 let pending_events = mem::replace(&mut *self.pending_events.lock().unwrap(), vec![]);
5725 if !pending_events.is_empty() {
5726 result = NotifyOption::DoPersist;
5729 for event in pending_events {
5730 handler(event).await;
5733 if result == NotifyOption::DoPersist {
5734 self.persistence_notifier.notify();
5739 impl<M: Deref, T: Deref, ES: Deref, NS: Deref, SP: Deref, F: Deref, R: Deref, L: Deref> MessageSendEventsProvider for ChannelManager<M, T, ES, NS, SP, F, R, L>
5741 M::Target: chain::Watch<<SP::Target as SignerProvider>::Signer>,
5742 T::Target: BroadcasterInterface,
5743 ES::Target: EntropySource,
5744 NS::Target: NodeSigner,
5745 SP::Target: SignerProvider,
5746 F::Target: FeeEstimator,
5750 /// Returns `MessageSendEvent`s strictly ordered per-peer, in the order they were generated.
5751 /// The returned array will contain `MessageSendEvent`s for different peers if
5752 /// `MessageSendEvent`s to more than one peer exists, but `MessageSendEvent`s to the same peer
5753 /// is always placed next to each other.
5755 /// Note that that while `MessageSendEvent`s are strictly ordered per-peer, the peer order for
5756 /// the chunks of `MessageSendEvent`s for different peers is random. I.e. if the array contains
5757 /// `MessageSendEvent`s for both `node_a` and `node_b`, the `MessageSendEvent`s for `node_a`
5758 /// will randomly be placed first or last in the returned array.
5760 /// Note that even though `BroadcastChannelAnnouncement` and `BroadcastChannelUpdate`
5761 /// `MessageSendEvent`s are intended to be broadcasted to all peers, they will be pleaced among
5762 /// the `MessageSendEvent`s to the specific peer they were generated under.
5763 fn get_and_clear_pending_msg_events(&self) -> Vec<MessageSendEvent> {
5764 let events = RefCell::new(Vec::new());
5765 PersistenceNotifierGuard::optionally_notify(&self.total_consistency_lock, &self.persistence_notifier, || {
5766 let mut result = NotifyOption::SkipPersist;
5768 // TODO: This behavior should be documented. It's unintuitive that we query
5769 // ChannelMonitors when clearing other events.
5770 if self.process_pending_monitor_events() {
5771 result = NotifyOption::DoPersist;
5774 if self.check_free_holding_cells() {
5775 result = NotifyOption::DoPersist;
5777 if self.maybe_generate_initial_closing_signed() {
5778 result = NotifyOption::DoPersist;
5781 let mut pending_events = Vec::new();
5782 let per_peer_state = self.per_peer_state.read().unwrap();
5783 for (_cp_id, peer_state_mutex) in per_peer_state.iter() {
5784 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
5785 let peer_state = &mut *peer_state_lock;
5786 if peer_state.pending_msg_events.len() > 0 {
5787 pending_events.append(&mut peer_state.pending_msg_events);
5791 if !pending_events.is_empty() {
5792 events.replace(pending_events);
5801 impl<M: Deref, T: Deref, ES: Deref, NS: Deref, SP: Deref, F: Deref, R: Deref, L: Deref> EventsProvider for ChannelManager<M, T, ES, NS, SP, F, R, L>
5803 M::Target: chain::Watch<<SP::Target as SignerProvider>::Signer>,
5804 T::Target: BroadcasterInterface,
5805 ES::Target: EntropySource,
5806 NS::Target: NodeSigner,
5807 SP::Target: SignerProvider,
5808 F::Target: FeeEstimator,
5812 /// Processes events that must be periodically handled.
5814 /// An [`EventHandler`] may safely call back to the provider in order to handle an event.
5815 /// However, it must not call [`Writeable::write`] as doing so would result in a deadlock.
5816 fn process_pending_events<H: Deref>(&self, handler: H) where H::Target: EventHandler {
5817 PersistenceNotifierGuard::optionally_notify(&self.total_consistency_lock, &self.persistence_notifier, || {
5818 let mut result = NotifyOption::SkipPersist;
5820 // TODO: This behavior should be documented. It's unintuitive that we query
5821 // ChannelMonitors when clearing other events.
5822 if self.process_pending_monitor_events() {
5823 result = NotifyOption::DoPersist;
5826 let pending_events = mem::replace(&mut *self.pending_events.lock().unwrap(), vec![]);
5827 if !pending_events.is_empty() {
5828 result = NotifyOption::DoPersist;
5831 for event in pending_events {
5832 handler.handle_event(event);
5840 impl<M: Deref, T: Deref, ES: Deref, NS: Deref, SP: Deref, F: Deref, R: Deref, L: Deref> chain::Listen for ChannelManager<M, T, ES, NS, SP, F, R, L>
5842 M::Target: chain::Watch<<SP::Target as SignerProvider>::Signer>,
5843 T::Target: BroadcasterInterface,
5844 ES::Target: EntropySource,
5845 NS::Target: NodeSigner,
5846 SP::Target: SignerProvider,
5847 F::Target: FeeEstimator,
5851 fn filtered_block_connected(&self, header: &BlockHeader, txdata: &TransactionData, height: u32) {
5853 let best_block = self.best_block.read().unwrap();
5854 assert_eq!(best_block.block_hash(), header.prev_blockhash,
5855 "Blocks must be connected in chain-order - the connected header must build on the last connected header");
5856 assert_eq!(best_block.height(), height - 1,
5857 "Blocks must be connected in chain-order - the connected block height must be one greater than the previous height");
5860 self.transactions_confirmed(header, txdata, height);
5861 self.best_block_updated(header, height);
5864 fn block_disconnected(&self, header: &BlockHeader, height: u32) {
5865 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
5866 let new_height = height - 1;
5868 let mut best_block = self.best_block.write().unwrap();
5869 assert_eq!(best_block.block_hash(), header.block_hash(),
5870 "Blocks must be disconnected in chain-order - the disconnected header must be the last connected header");
5871 assert_eq!(best_block.height(), height,
5872 "Blocks must be disconnected in chain-order - the disconnected block must have the correct height");
5873 *best_block = BestBlock::new(header.prev_blockhash, new_height)
5876 self.do_chain_event(Some(new_height), |channel| channel.best_block_updated(new_height, header.time, self.genesis_hash.clone(), &self.node_signer, &self.default_configuration, &self.logger));
5880 impl<M: Deref, T: Deref, ES: Deref, NS: Deref, SP: Deref, F: Deref, R: Deref, L: Deref> chain::Confirm for ChannelManager<M, T, ES, NS, SP, F, R, L>
5882 M::Target: chain::Watch<<SP::Target as SignerProvider>::Signer>,
5883 T::Target: BroadcasterInterface,
5884 ES::Target: EntropySource,
5885 NS::Target: NodeSigner,
5886 SP::Target: SignerProvider,
5887 F::Target: FeeEstimator,
5891 fn transactions_confirmed(&self, header: &BlockHeader, txdata: &TransactionData, height: u32) {
5892 // Note that we MUST NOT end up calling methods on self.chain_monitor here - we're called
5893 // during initialization prior to the chain_monitor being fully configured in some cases.
5894 // See the docs for `ChannelManagerReadArgs` for more.
5896 let block_hash = header.block_hash();
5897 log_trace!(self.logger, "{} transactions included in block {} at height {} provided", txdata.len(), block_hash, height);
5899 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
5900 self.do_chain_event(Some(height), |channel| channel.transactions_confirmed(&block_hash, height, txdata, self.genesis_hash.clone(), &self.node_signer, &self.default_configuration, &self.logger)
5901 .map(|(a, b)| (a, Vec::new(), b)));
5903 let last_best_block_height = self.best_block.read().unwrap().height();
5904 if height < last_best_block_height {
5905 let timestamp = self.highest_seen_timestamp.load(Ordering::Acquire);
5906 self.do_chain_event(Some(last_best_block_height), |channel| channel.best_block_updated(last_best_block_height, timestamp as u32, self.genesis_hash.clone(), &self.node_signer, &self.default_configuration, &self.logger));
5910 fn best_block_updated(&self, header: &BlockHeader, height: u32) {
5911 // Note that we MUST NOT end up calling methods on self.chain_monitor here - we're called
5912 // during initialization prior to the chain_monitor being fully configured in some cases.
5913 // See the docs for `ChannelManagerReadArgs` for more.
5915 let block_hash = header.block_hash();
5916 log_trace!(self.logger, "New best block: {} at height {}", block_hash, height);
5918 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
5920 *self.best_block.write().unwrap() = BestBlock::new(block_hash, height);
5922 self.do_chain_event(Some(height), |channel| channel.best_block_updated(height, header.time, self.genesis_hash.clone(), &self.node_signer, &self.default_configuration, &self.logger));
5924 macro_rules! max_time {
5925 ($timestamp: expr) => {
5927 // Update $timestamp to be the max of its current value and the block
5928 // timestamp. This should keep us close to the current time without relying on
5929 // having an explicit local time source.
5930 // Just in case we end up in a race, we loop until we either successfully
5931 // update $timestamp or decide we don't need to.
5932 let old_serial = $timestamp.load(Ordering::Acquire);
5933 if old_serial >= header.time as usize { break; }
5934 if $timestamp.compare_exchange(old_serial, header.time as usize, Ordering::AcqRel, Ordering::Relaxed).is_ok() {
5940 max_time!(self.highest_seen_timestamp);
5941 let mut payment_secrets = self.pending_inbound_payments.lock().unwrap();
5942 payment_secrets.retain(|_, inbound_payment| {
5943 inbound_payment.expiry_time > header.time as u64
5947 fn get_relevant_txids(&self) -> Vec<(Txid, Option<BlockHash>)> {
5948 let mut res = Vec::with_capacity(self.short_to_chan_info.read().unwrap().len());
5949 for (_cp_id, peer_state_mutex) in self.per_peer_state.read().unwrap().iter() {
5950 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
5951 let peer_state = &mut *peer_state_lock;
5952 for chan in peer_state.channel_by_id.values() {
5953 if let (Some(funding_txo), Some(block_hash)) = (chan.get_funding_txo(), chan.get_funding_tx_confirmed_in()) {
5954 res.push((funding_txo.txid, Some(block_hash)));
5961 fn transaction_unconfirmed(&self, txid: &Txid) {
5962 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
5963 self.do_chain_event(None, |channel| {
5964 if let Some(funding_txo) = channel.get_funding_txo() {
5965 if funding_txo.txid == *txid {
5966 channel.funding_transaction_unconfirmed(&self.logger).map(|()| (None, Vec::new(), None))
5967 } else { Ok((None, Vec::new(), None)) }
5968 } else { Ok((None, Vec::new(), None)) }
5973 impl<M: Deref, T: Deref, ES: Deref, NS: Deref, SP: Deref, F: Deref, R: Deref, L: Deref> ChannelManager<M, T, ES, NS, SP, F, R, L>
5975 M::Target: chain::Watch<<SP::Target as SignerProvider>::Signer>,
5976 T::Target: BroadcasterInterface,
5977 ES::Target: EntropySource,
5978 NS::Target: NodeSigner,
5979 SP::Target: SignerProvider,
5980 F::Target: FeeEstimator,
5984 /// Calls a function which handles an on-chain event (blocks dis/connected, transactions
5985 /// un/confirmed, etc) on each channel, handling any resulting errors or messages generated by
5987 fn do_chain_event<FN: Fn(&mut Channel<<SP::Target as SignerProvider>::Signer>) -> Result<(Option<msgs::ChannelReady>, Vec<(HTLCSource, PaymentHash)>, Option<msgs::AnnouncementSignatures>), ClosureReason>>
5988 (&self, height_opt: Option<u32>, f: FN) {
5989 // Note that we MUST NOT end up calling methods on self.chain_monitor here - we're called
5990 // during initialization prior to the chain_monitor being fully configured in some cases.
5991 // See the docs for `ChannelManagerReadArgs` for more.
5993 let mut failed_channels = Vec::new();
5994 let mut timed_out_htlcs = Vec::new();
5996 let per_peer_state = self.per_peer_state.read().unwrap();
5997 for (_cp_id, peer_state_mutex) in per_peer_state.iter() {
5998 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
5999 let peer_state = &mut *peer_state_lock;
6000 let pending_msg_events = &mut peer_state.pending_msg_events;
6001 peer_state.channel_by_id.retain(|_, channel| {
6002 let res = f(channel);
6003 if let Ok((channel_ready_opt, mut timed_out_pending_htlcs, announcement_sigs)) = res {
6004 for (source, payment_hash) in timed_out_pending_htlcs.drain(..) {
6005 let (failure_code, data) = self.get_htlc_inbound_temp_fail_err_and_data(0x1000|14 /* expiry_too_soon */, &channel);
6006 timed_out_htlcs.push((source, payment_hash, HTLCFailReason::reason(failure_code, data),
6007 HTLCDestination::NextHopChannel { node_id: Some(channel.get_counterparty_node_id()), channel_id: channel.channel_id() }));
6009 if let Some(channel_ready) = channel_ready_opt {
6010 send_channel_ready!(self, pending_msg_events, channel, channel_ready);
6011 if channel.is_usable() {
6012 log_trace!(self.logger, "Sending channel_ready with private initial channel_update for our counterparty on channel {}", log_bytes!(channel.channel_id()));
6013 if let Ok(msg) = self.get_channel_update_for_unicast(channel) {
6014 pending_msg_events.push(events::MessageSendEvent::SendChannelUpdate {
6015 node_id: channel.get_counterparty_node_id(),
6020 log_trace!(self.logger, "Sending channel_ready WITHOUT channel_update for {}", log_bytes!(channel.channel_id()));
6024 emit_channel_ready_event!(self, channel);
6026 if let Some(announcement_sigs) = announcement_sigs {
6027 log_trace!(self.logger, "Sending announcement_signatures for channel {}", log_bytes!(channel.channel_id()));
6028 pending_msg_events.push(events::MessageSendEvent::SendAnnouncementSignatures {
6029 node_id: channel.get_counterparty_node_id(),
6030 msg: announcement_sigs,
6032 if let Some(height) = height_opt {
6033 if let Some(announcement) = channel.get_signed_channel_announcement(&self.node_signer, self.genesis_hash, height, &self.default_configuration) {
6034 pending_msg_events.push(events::MessageSendEvent::BroadcastChannelAnnouncement {
6036 // Note that announcement_signatures fails if the channel cannot be announced,
6037 // so get_channel_update_for_broadcast will never fail by the time we get here.
6038 update_msg: Some(self.get_channel_update_for_broadcast(channel).unwrap()),
6043 if channel.is_our_channel_ready() {
6044 if let Some(real_scid) = channel.get_short_channel_id() {
6045 // If we sent a 0conf channel_ready, and now have an SCID, we add it
6046 // to the short_to_chan_info map here. Note that we check whether we
6047 // can relay using the real SCID at relay-time (i.e.
6048 // enforce option_scid_alias then), and if the funding tx is ever
6049 // un-confirmed we force-close the channel, ensuring short_to_chan_info
6050 // is always consistent.
6051 let mut short_to_chan_info = self.short_to_chan_info.write().unwrap();
6052 let scid_insert = short_to_chan_info.insert(real_scid, (channel.get_counterparty_node_id(), channel.channel_id()));
6053 assert!(scid_insert.is_none() || scid_insert.unwrap() == (channel.get_counterparty_node_id(), channel.channel_id()),
6054 "SCIDs should never collide - ensure you weren't behind by a full {} blocks when creating channels",
6055 fake_scid::MAX_SCID_BLOCKS_FROM_NOW);
6058 } else if let Err(reason) = res {
6059 update_maps_on_chan_removal!(self, channel);
6060 // It looks like our counterparty went on-chain or funding transaction was
6061 // reorged out of the main chain. Close the channel.
6062 failed_channels.push(channel.force_shutdown(true));
6063 if let Ok(update) = self.get_channel_update_for_broadcast(&channel) {
6064 pending_msg_events.push(events::MessageSendEvent::BroadcastChannelUpdate {
6068 let reason_message = format!("{}", reason);
6069 self.issue_channel_close_events(channel, reason);
6070 pending_msg_events.push(events::MessageSendEvent::HandleError {
6071 node_id: channel.get_counterparty_node_id(),
6072 action: msgs::ErrorAction::SendErrorMessage { msg: msgs::ErrorMessage {
6073 channel_id: channel.channel_id(),
6074 data: reason_message,
6084 if let Some(height) = height_opt {
6085 self.claimable_payments.lock().unwrap().claimable_htlcs.retain(|payment_hash, (_, htlcs)| {
6086 htlcs.retain(|htlc| {
6087 // If height is approaching the number of blocks we think it takes us to get
6088 // our commitment transaction confirmed before the HTLC expires, plus the
6089 // number of blocks we generally consider it to take to do a commitment update,
6090 // just give up on it and fail the HTLC.
6091 if height >= htlc.cltv_expiry - HTLC_FAIL_BACK_BUFFER {
6092 let mut htlc_msat_height_data = htlc.value.to_be_bytes().to_vec();
6093 htlc_msat_height_data.extend_from_slice(&height.to_be_bytes());
6095 timed_out_htlcs.push((HTLCSource::PreviousHopData(htlc.prev_hop.clone()), payment_hash.clone(),
6096 HTLCFailReason::reason(0x4000 | 15, htlc_msat_height_data),
6097 HTLCDestination::FailedPayment { payment_hash: payment_hash.clone() }));
6101 !htlcs.is_empty() // Only retain this entry if htlcs has at least one entry.
6104 let mut intercepted_htlcs = self.pending_intercepted_htlcs.lock().unwrap();
6105 intercepted_htlcs.retain(|_, htlc| {
6106 if height >= htlc.forward_info.outgoing_cltv_value - HTLC_FAIL_BACK_BUFFER {
6107 let prev_hop_data = HTLCSource::PreviousHopData(HTLCPreviousHopData {
6108 short_channel_id: htlc.prev_short_channel_id,
6109 htlc_id: htlc.prev_htlc_id,
6110 incoming_packet_shared_secret: htlc.forward_info.incoming_shared_secret,
6111 phantom_shared_secret: None,
6112 outpoint: htlc.prev_funding_outpoint,
6115 let requested_forward_scid /* intercept scid */ = match htlc.forward_info.routing {
6116 PendingHTLCRouting::Forward { short_channel_id, .. } => short_channel_id,
6117 _ => unreachable!(),
6119 timed_out_htlcs.push((prev_hop_data, htlc.forward_info.payment_hash,
6120 HTLCFailReason::from_failure_code(0x2000 | 2),
6121 HTLCDestination::InvalidForward { requested_forward_scid }));
6122 log_trace!(self.logger, "Timing out intercepted HTLC with requested forward scid {}", requested_forward_scid);
6128 self.handle_init_event_channel_failures(failed_channels);
6130 for (source, payment_hash, reason, destination) in timed_out_htlcs.drain(..) {
6131 self.fail_htlc_backwards_internal(&source, &payment_hash, &reason, destination);
6135 /// Blocks until ChannelManager needs to be persisted or a timeout is reached. It returns a bool
6136 /// indicating whether persistence is necessary. Only one listener on
6137 /// [`await_persistable_update`], [`await_persistable_update_timeout`], or a future returned by
6138 /// [`get_persistable_update_future`] is guaranteed to be woken up.
6140 /// Note that this method is not available with the `no-std` feature.
6142 /// [`await_persistable_update`]: Self::await_persistable_update
6143 /// [`await_persistable_update_timeout`]: Self::await_persistable_update_timeout
6144 /// [`get_persistable_update_future`]: Self::get_persistable_update_future
6145 #[cfg(any(test, feature = "std"))]
6146 pub fn await_persistable_update_timeout(&self, max_wait: Duration) -> bool {
6147 self.persistence_notifier.wait_timeout(max_wait)
6150 /// Blocks until ChannelManager needs to be persisted. Only one listener on
6151 /// [`await_persistable_update`], `await_persistable_update_timeout`, or a future returned by
6152 /// [`get_persistable_update_future`] is guaranteed to be woken up.
6154 /// [`await_persistable_update`]: Self::await_persistable_update
6155 /// [`get_persistable_update_future`]: Self::get_persistable_update_future
6156 pub fn await_persistable_update(&self) {
6157 self.persistence_notifier.wait()
6160 /// Gets a [`Future`] that completes when a persistable update is available. Note that
6161 /// callbacks registered on the [`Future`] MUST NOT call back into this [`ChannelManager`] and
6162 /// should instead register actions to be taken later.
6163 pub fn get_persistable_update_future(&self) -> Future {
6164 self.persistence_notifier.get_future()
6167 #[cfg(any(test, feature = "_test_utils"))]
6168 pub fn get_persistence_condvar_value(&self) -> bool {
6169 self.persistence_notifier.notify_pending()
6172 /// Gets the latest best block which was connected either via the [`chain::Listen`] or
6173 /// [`chain::Confirm`] interfaces.
6174 pub fn current_best_block(&self) -> BestBlock {
6175 self.best_block.read().unwrap().clone()
6178 /// Fetches the set of [`NodeFeatures`] flags which are provided by or required by
6179 /// [`ChannelManager`].
6180 pub fn node_features(&self) -> NodeFeatures {
6181 provided_node_features(&self.default_configuration)
6184 /// Fetches the set of [`InvoiceFeatures`] flags which are provided by or required by
6185 /// [`ChannelManager`].
6187 /// Note that the invoice feature flags can vary depending on if the invoice is a "phantom invoice"
6188 /// or not. Thus, this method is not public.
6189 #[cfg(any(feature = "_test_utils", test))]
6190 pub fn invoice_features(&self) -> InvoiceFeatures {
6191 provided_invoice_features(&self.default_configuration)
6194 /// Fetches the set of [`ChannelFeatures`] flags which are provided by or required by
6195 /// [`ChannelManager`].
6196 pub fn channel_features(&self) -> ChannelFeatures {
6197 provided_channel_features(&self.default_configuration)
6200 /// Fetches the set of [`ChannelTypeFeatures`] flags which are provided by or required by
6201 /// [`ChannelManager`].
6202 pub fn channel_type_features(&self) -> ChannelTypeFeatures {
6203 provided_channel_type_features(&self.default_configuration)
6206 /// Fetches the set of [`InitFeatures`] flags which are provided by or required by
6207 /// [`ChannelManager`].
6208 pub fn init_features(&self) -> InitFeatures {
6209 provided_init_features(&self.default_configuration)
6213 impl<M: Deref, T: Deref, ES: Deref, NS: Deref, SP: Deref, F: Deref, R: Deref, L: Deref>
6214 ChannelMessageHandler for ChannelManager<M, T, ES, NS, SP, F, R, L>
6216 M::Target: chain::Watch<<SP::Target as SignerProvider>::Signer>,
6217 T::Target: BroadcasterInterface,
6218 ES::Target: EntropySource,
6219 NS::Target: NodeSigner,
6220 SP::Target: SignerProvider,
6221 F::Target: FeeEstimator,
6225 fn handle_open_channel(&self, counterparty_node_id: &PublicKey, msg: &msgs::OpenChannel) {
6226 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
6227 let _ = handle_error!(self, self.internal_open_channel(counterparty_node_id, msg), *counterparty_node_id);
6230 fn handle_accept_channel(&self, counterparty_node_id: &PublicKey, msg: &msgs::AcceptChannel) {
6231 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
6232 let _ = handle_error!(self, self.internal_accept_channel(counterparty_node_id, msg), *counterparty_node_id);
6235 fn handle_funding_created(&self, counterparty_node_id: &PublicKey, msg: &msgs::FundingCreated) {
6236 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
6237 let _ = handle_error!(self, self.internal_funding_created(counterparty_node_id, msg), *counterparty_node_id);
6240 fn handle_funding_signed(&self, counterparty_node_id: &PublicKey, msg: &msgs::FundingSigned) {
6241 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
6242 let _ = handle_error!(self, self.internal_funding_signed(counterparty_node_id, msg), *counterparty_node_id);
6245 fn handle_channel_ready(&self, counterparty_node_id: &PublicKey, msg: &msgs::ChannelReady) {
6246 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
6247 let _ = handle_error!(self, self.internal_channel_ready(counterparty_node_id, msg), *counterparty_node_id);
6250 fn handle_shutdown(&self, counterparty_node_id: &PublicKey, msg: &msgs::Shutdown) {
6251 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
6252 let _ = handle_error!(self, self.internal_shutdown(counterparty_node_id, msg), *counterparty_node_id);
6255 fn handle_closing_signed(&self, counterparty_node_id: &PublicKey, msg: &msgs::ClosingSigned) {
6256 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
6257 let _ = handle_error!(self, self.internal_closing_signed(counterparty_node_id, msg), *counterparty_node_id);
6260 fn handle_update_add_htlc(&self, counterparty_node_id: &PublicKey, msg: &msgs::UpdateAddHTLC) {
6261 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
6262 let _ = handle_error!(self, self.internal_update_add_htlc(counterparty_node_id, msg), *counterparty_node_id);
6265 fn handle_update_fulfill_htlc(&self, counterparty_node_id: &PublicKey, msg: &msgs::UpdateFulfillHTLC) {
6266 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
6267 let _ = handle_error!(self, self.internal_update_fulfill_htlc(counterparty_node_id, msg), *counterparty_node_id);
6270 fn handle_update_fail_htlc(&self, counterparty_node_id: &PublicKey, msg: &msgs::UpdateFailHTLC) {
6271 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
6272 let _ = handle_error!(self, self.internal_update_fail_htlc(counterparty_node_id, msg), *counterparty_node_id);
6275 fn handle_update_fail_malformed_htlc(&self, counterparty_node_id: &PublicKey, msg: &msgs::UpdateFailMalformedHTLC) {
6276 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
6277 let _ = handle_error!(self, self.internal_update_fail_malformed_htlc(counterparty_node_id, msg), *counterparty_node_id);
6280 fn handle_commitment_signed(&self, counterparty_node_id: &PublicKey, msg: &msgs::CommitmentSigned) {
6281 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
6282 let _ = handle_error!(self, self.internal_commitment_signed(counterparty_node_id, msg), *counterparty_node_id);
6285 fn handle_revoke_and_ack(&self, counterparty_node_id: &PublicKey, msg: &msgs::RevokeAndACK) {
6286 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
6287 let _ = handle_error!(self, self.internal_revoke_and_ack(counterparty_node_id, msg), *counterparty_node_id);
6290 fn handle_update_fee(&self, counterparty_node_id: &PublicKey, msg: &msgs::UpdateFee) {
6291 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
6292 let _ = handle_error!(self, self.internal_update_fee(counterparty_node_id, msg), *counterparty_node_id);
6295 fn handle_announcement_signatures(&self, counterparty_node_id: &PublicKey, msg: &msgs::AnnouncementSignatures) {
6296 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
6297 let _ = handle_error!(self, self.internal_announcement_signatures(counterparty_node_id, msg), *counterparty_node_id);
6300 fn handle_channel_update(&self, counterparty_node_id: &PublicKey, msg: &msgs::ChannelUpdate) {
6301 PersistenceNotifierGuard::optionally_notify(&self.total_consistency_lock, &self.persistence_notifier, || {
6302 if let Ok(persist) = handle_error!(self, self.internal_channel_update(counterparty_node_id, msg), *counterparty_node_id) {
6305 NotifyOption::SkipPersist
6310 fn handle_channel_reestablish(&self, counterparty_node_id: &PublicKey, msg: &msgs::ChannelReestablish) {
6311 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
6312 let _ = handle_error!(self, self.internal_channel_reestablish(counterparty_node_id, msg), *counterparty_node_id);
6315 fn peer_disconnected(&self, counterparty_node_id: &PublicKey) {
6316 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
6317 let mut failed_channels = Vec::new();
6318 let mut per_peer_state = self.per_peer_state.write().unwrap();
6320 log_debug!(self.logger, "Marking channels with {} disconnected and generating channel_updates.",
6321 log_pubkey!(counterparty_node_id));
6322 if let Some(peer_state_mutex) = per_peer_state.get(counterparty_node_id) {
6323 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
6324 let peer_state = &mut *peer_state_lock;
6325 let pending_msg_events = &mut peer_state.pending_msg_events;
6326 peer_state.channel_by_id.retain(|_, chan| {
6327 chan.remove_uncommitted_htlcs_and_mark_paused(&self.logger);
6328 if chan.is_shutdown() {
6329 update_maps_on_chan_removal!(self, chan);
6330 self.issue_channel_close_events(chan, ClosureReason::DisconnectedPeer);
6335 pending_msg_events.retain(|msg| {
6337 &events::MessageSendEvent::SendAcceptChannel { .. } => false,
6338 &events::MessageSendEvent::SendOpenChannel { .. } => false,
6339 &events::MessageSendEvent::SendFundingCreated { .. } => false,
6340 &events::MessageSendEvent::SendFundingSigned { .. } => false,
6341 &events::MessageSendEvent::SendChannelReady { .. } => false,
6342 &events::MessageSendEvent::SendAnnouncementSignatures { .. } => false,
6343 &events::MessageSendEvent::UpdateHTLCs { .. } => false,
6344 &events::MessageSendEvent::SendRevokeAndACK { .. } => false,
6345 &events::MessageSendEvent::SendClosingSigned { .. } => false,
6346 &events::MessageSendEvent::SendShutdown { .. } => false,
6347 &events::MessageSendEvent::SendChannelReestablish { .. } => false,
6348 &events::MessageSendEvent::SendChannelAnnouncement { .. } => false,
6349 &events::MessageSendEvent::BroadcastChannelAnnouncement { .. } => true,
6350 &events::MessageSendEvent::BroadcastChannelUpdate { .. } => true,
6351 &events::MessageSendEvent::BroadcastNodeAnnouncement { .. } => true,
6352 &events::MessageSendEvent::SendChannelUpdate { .. } => false,
6353 &events::MessageSendEvent::HandleError { .. } => false,
6354 &events::MessageSendEvent::SendChannelRangeQuery { .. } => false,
6355 &events::MessageSendEvent::SendShortIdsQuery { .. } => false,
6356 &events::MessageSendEvent::SendReplyChannelRange { .. } => false,
6357 &events::MessageSendEvent::SendGossipTimestampFilter { .. } => false,
6360 debug_assert!(peer_state.is_connected, "A disconnected peer cannot disconnect");
6361 peer_state.is_connected = false;
6362 peer_state.ok_to_remove(true)
6363 } else { debug_assert!(false, "Unconnected peer disconnected"); true }
6366 per_peer_state.remove(counterparty_node_id);
6368 mem::drop(per_peer_state);
6370 for failure in failed_channels.drain(..) {
6371 self.finish_force_close_channel(failure);
6375 fn peer_connected(&self, counterparty_node_id: &PublicKey, init_msg: &msgs::Init, inbound: bool) -> Result<(), ()> {
6376 if !init_msg.features.supports_static_remote_key() {
6377 log_debug!(self.logger, "Peer {} does not support static remote key, disconnecting", log_pubkey!(counterparty_node_id));
6381 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
6383 // If we have too many peers connected which don't have funded channels, disconnect the
6384 // peer immediately (as long as it doesn't have funded channels). If we have a bunch of
6385 // unfunded channels taking up space in memory for disconnected peers, we still let new
6386 // peers connect, but we'll reject new channels from them.
6387 let connected_peers_without_funded_channels = self.peers_without_funded_channels(|node| node.is_connected);
6388 let inbound_peer_limited = inbound && connected_peers_without_funded_channels >= MAX_NO_CHANNEL_PEERS;
6391 let mut peer_state_lock = self.per_peer_state.write().unwrap();
6392 match peer_state_lock.entry(counterparty_node_id.clone()) {
6393 hash_map::Entry::Vacant(e) => {
6394 if inbound_peer_limited {
6397 e.insert(Mutex::new(PeerState {
6398 channel_by_id: HashMap::new(),
6399 latest_features: init_msg.features.clone(),
6400 pending_msg_events: Vec::new(),
6401 monitor_update_blocked_actions: BTreeMap::new(),
6405 hash_map::Entry::Occupied(e) => {
6406 let mut peer_state = e.get().lock().unwrap();
6407 peer_state.latest_features = init_msg.features.clone();
6409 let best_block_height = self.best_block.read().unwrap().height();
6410 if inbound_peer_limited &&
6411 Self::unfunded_channel_count(&*peer_state, best_block_height) ==
6412 peer_state.channel_by_id.len()
6417 debug_assert!(!peer_state.is_connected, "A peer shouldn't be connected twice");
6418 peer_state.is_connected = true;
6423 log_debug!(self.logger, "Generating channel_reestablish events for {}", log_pubkey!(counterparty_node_id));
6425 let per_peer_state = self.per_peer_state.read().unwrap();
6426 for (_cp_id, peer_state_mutex) in per_peer_state.iter() {
6427 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
6428 let peer_state = &mut *peer_state_lock;
6429 let pending_msg_events = &mut peer_state.pending_msg_events;
6430 peer_state.channel_by_id.retain(|_, chan| {
6431 let retain = if chan.get_counterparty_node_id() == *counterparty_node_id {
6432 if !chan.have_received_message() {
6433 // If we created this (outbound) channel while we were disconnected from the
6434 // peer we probably failed to send the open_channel message, which is now
6435 // lost. We can't have had anything pending related to this channel, so we just
6439 pending_msg_events.push(events::MessageSendEvent::SendChannelReestablish {
6440 node_id: chan.get_counterparty_node_id(),
6441 msg: chan.get_channel_reestablish(&self.logger),
6446 if retain && chan.get_counterparty_node_id() != *counterparty_node_id {
6447 if let Some(msg) = chan.get_signed_channel_announcement(&self.node_signer, self.genesis_hash.clone(), self.best_block.read().unwrap().height(), &self.default_configuration) {
6448 if let Ok(update_msg) = self.get_channel_update_for_broadcast(chan) {
6449 pending_msg_events.push(events::MessageSendEvent::SendChannelAnnouncement {
6450 node_id: *counterparty_node_id,
6459 //TODO: Also re-broadcast announcement_signatures
6463 fn handle_error(&self, counterparty_node_id: &PublicKey, msg: &msgs::ErrorMessage) {
6464 let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
6466 if msg.channel_id == [0; 32] {
6467 let channel_ids: Vec<[u8; 32]> = {
6468 let per_peer_state = self.per_peer_state.read().unwrap();
6469 let peer_state_mutex_opt = per_peer_state.get(counterparty_node_id);
6470 if peer_state_mutex_opt.is_none() { return; }
6471 let mut peer_state_lock = peer_state_mutex_opt.unwrap().lock().unwrap();
6472 let peer_state = &mut *peer_state_lock;
6473 peer_state.channel_by_id.keys().cloned().collect()
6475 for channel_id in channel_ids {
6476 // Untrusted messages from peer, we throw away the error if id points to a non-existent channel
6477 let _ = self.force_close_channel_with_peer(&channel_id, counterparty_node_id, Some(&msg.data), true);
6481 // First check if we can advance the channel type and try again.
6482 let per_peer_state = self.per_peer_state.read().unwrap();
6483 let peer_state_mutex_opt = per_peer_state.get(counterparty_node_id);
6484 if peer_state_mutex_opt.is_none() { return; }
6485 let mut peer_state_lock = peer_state_mutex_opt.unwrap().lock().unwrap();
6486 let peer_state = &mut *peer_state_lock;
6487 if let Some(chan) = peer_state.channel_by_id.get_mut(&msg.channel_id) {
6488 if let Ok(msg) = chan.maybe_handle_error_without_close(self.genesis_hash) {
6489 peer_state.pending_msg_events.push(events::MessageSendEvent::SendOpenChannel {
6490 node_id: *counterparty_node_id,
6498 // Untrusted messages from peer, we throw away the error if id points to a non-existent channel
6499 let _ = self.force_close_channel_with_peer(&msg.channel_id, counterparty_node_id, Some(&msg.data), true);
6503 fn provided_node_features(&self) -> NodeFeatures {
6504 provided_node_features(&self.default_configuration)
6507 fn provided_init_features(&self, _their_init_features: &PublicKey) -> InitFeatures {
6508 provided_init_features(&self.default_configuration)
6512 /// Fetches the set of [`NodeFeatures`] flags which are provided by or required by
6513 /// [`ChannelManager`].
6514 pub(crate) fn provided_node_features(config: &UserConfig) -> NodeFeatures {
6515 provided_init_features(config).to_context()
6518 /// Fetches the set of [`InvoiceFeatures`] flags which are provided by or required by
6519 /// [`ChannelManager`].
6521 /// Note that the invoice feature flags can vary depending on if the invoice is a "phantom invoice"
6522 /// or not. Thus, this method is not public.
6523 #[cfg(any(feature = "_test_utils", test))]
6524 pub(crate) fn provided_invoice_features(config: &UserConfig) -> InvoiceFeatures {
6525 provided_init_features(config).to_context()
6528 /// Fetches the set of [`ChannelFeatures`] flags which are provided by or required by
6529 /// [`ChannelManager`].
6530 pub(crate) fn provided_channel_features(config: &UserConfig) -> ChannelFeatures {
6531 provided_init_features(config).to_context()
6534 /// Fetches the set of [`ChannelTypeFeatures`] flags which are provided by or required by
6535 /// [`ChannelManager`].
6536 pub(crate) fn provided_channel_type_features(config: &UserConfig) -> ChannelTypeFeatures {
6537 ChannelTypeFeatures::from_init(&provided_init_features(config))
6540 /// Fetches the set of [`InitFeatures`] flags which are provided by or required by
6541 /// [`ChannelManager`].
6542 pub fn provided_init_features(_config: &UserConfig) -> InitFeatures {
6543 // Note that if new features are added here which other peers may (eventually) require, we
6544 // should also add the corresponding (optional) bit to the [`ChannelMessageHandler`] impl for
6545 // [`ErroringMessageHandler`].
6546 let mut features = InitFeatures::empty();
6547 features.set_data_loss_protect_optional();
6548 features.set_upfront_shutdown_script_optional();
6549 features.set_variable_length_onion_required();
6550 features.set_static_remote_key_required();
6551 features.set_payment_secret_required();
6552 features.set_basic_mpp_optional();
6553 features.set_wumbo_optional();
6554 features.set_shutdown_any_segwit_optional();
6555 features.set_channel_type_optional();
6556 features.set_scid_privacy_optional();
6557 features.set_zero_conf_optional();
6559 { // Attributes are not allowed on if expressions on our current MSRV of 1.41.
6560 if _config.channel_handshake_config.negotiate_anchors_zero_fee_htlc_tx {
6561 features.set_anchors_zero_fee_htlc_tx_optional();
6567 const SERIALIZATION_VERSION: u8 = 1;
6568 const MIN_SERIALIZATION_VERSION: u8 = 1;
6570 impl_writeable_tlv_based!(CounterpartyForwardingInfo, {
6571 (2, fee_base_msat, required),
6572 (4, fee_proportional_millionths, required),
6573 (6, cltv_expiry_delta, required),
6576 impl_writeable_tlv_based!(ChannelCounterparty, {
6577 (2, node_id, required),
6578 (4, features, required),
6579 (6, unspendable_punishment_reserve, required),
6580 (8, forwarding_info, option),
6581 (9, outbound_htlc_minimum_msat, option),
6582 (11, outbound_htlc_maximum_msat, option),
6585 impl Writeable for ChannelDetails {
6586 fn write<W: Writer>(&self, writer: &mut W) -> Result<(), io::Error> {
6587 // `user_channel_id` used to be a single u64 value. In order to remain backwards compatible with
6588 // versions prior to 0.0.113, the u128 is serialized as two separate u64 values.
6589 let user_channel_id_low = self.user_channel_id as u64;
6590 let user_channel_id_high_opt = Some((self.user_channel_id >> 64) as u64);
6591 write_tlv_fields!(writer, {
6592 (1, self.inbound_scid_alias, option),
6593 (2, self.channel_id, required),
6594 (3, self.channel_type, option),
6595 (4, self.counterparty, required),
6596 (5, self.outbound_scid_alias, option),
6597 (6, self.funding_txo, option),
6598 (7, self.config, option),
6599 (8, self.short_channel_id, option),
6600 (9, self.confirmations, option),
6601 (10, self.channel_value_satoshis, required),
6602 (12, self.unspendable_punishment_reserve, option),
6603 (14, user_channel_id_low, required),
6604 (16, self.balance_msat, required),
6605 (18, self.outbound_capacity_msat, required),
6606 // Note that by the time we get past the required read above, outbound_capacity_msat will be
6607 // filled in, so we can safely unwrap it here.
6608 (19, self.next_outbound_htlc_limit_msat, (default_value, outbound_capacity_msat.0.unwrap() as u64)),
6609 (20, self.inbound_capacity_msat, required),
6610 (22, self.confirmations_required, option),
6611 (24, self.force_close_spend_delay, option),
6612 (26, self.is_outbound, required),
6613 (28, self.is_channel_ready, required),
6614 (30, self.is_usable, required),
6615 (32, self.is_public, required),
6616 (33, self.inbound_htlc_minimum_msat, option),
6617 (35, self.inbound_htlc_maximum_msat, option),
6618 (37, user_channel_id_high_opt, option),
6619 (39, self.feerate_sat_per_1000_weight, option),
6625 impl Readable for ChannelDetails {
6626 fn read<R: Read>(reader: &mut R) -> Result<Self, DecodeError> {
6627 _init_and_read_tlv_fields!(reader, {
6628 (1, inbound_scid_alias, option),
6629 (2, channel_id, required),
6630 (3, channel_type, option),
6631 (4, counterparty, required),
6632 (5, outbound_scid_alias, option),
6633 (6, funding_txo, option),
6634 (7, config, option),
6635 (8, short_channel_id, option),
6636 (9, confirmations, option),
6637 (10, channel_value_satoshis, required),
6638 (12, unspendable_punishment_reserve, option),
6639 (14, user_channel_id_low, required),
6640 (16, balance_msat, required),
6641 (18, outbound_capacity_msat, required),
6642 // Note that by the time we get past the required read above, outbound_capacity_msat will be
6643 // filled in, so we can safely unwrap it here.
6644 (19, next_outbound_htlc_limit_msat, (default_value, outbound_capacity_msat.0.unwrap() as u64)),
6645 (20, inbound_capacity_msat, required),
6646 (22, confirmations_required, option),
6647 (24, force_close_spend_delay, option),
6648 (26, is_outbound, required),
6649 (28, is_channel_ready, required),
6650 (30, is_usable, required),
6651 (32, is_public, required),
6652 (33, inbound_htlc_minimum_msat, option),
6653 (35, inbound_htlc_maximum_msat, option),
6654 (37, user_channel_id_high_opt, option),
6655 (39, feerate_sat_per_1000_weight, option),
6658 // `user_channel_id` used to be a single u64 value. In order to remain backwards compatible with
6659 // versions prior to 0.0.113, the u128 is serialized as two separate u64 values.
6660 let user_channel_id_low: u64 = user_channel_id_low.0.unwrap();
6661 let user_channel_id = user_channel_id_low as u128 +
6662 ((user_channel_id_high_opt.unwrap_or(0 as u64) as u128) << 64);
6666 channel_id: channel_id.0.unwrap(),
6668 counterparty: counterparty.0.unwrap(),
6669 outbound_scid_alias,
6673 channel_value_satoshis: channel_value_satoshis.0.unwrap(),
6674 unspendable_punishment_reserve,
6676 balance_msat: balance_msat.0.unwrap(),
6677 outbound_capacity_msat: outbound_capacity_msat.0.unwrap(),
6678 next_outbound_htlc_limit_msat: next_outbound_htlc_limit_msat.0.unwrap(),
6679 inbound_capacity_msat: inbound_capacity_msat.0.unwrap(),
6680 confirmations_required,
6682 force_close_spend_delay,
6683 is_outbound: is_outbound.0.unwrap(),
6684 is_channel_ready: is_channel_ready.0.unwrap(),
6685 is_usable: is_usable.0.unwrap(),
6686 is_public: is_public.0.unwrap(),
6687 inbound_htlc_minimum_msat,
6688 inbound_htlc_maximum_msat,
6689 feerate_sat_per_1000_weight,
6694 impl_writeable_tlv_based!(PhantomRouteHints, {
6695 (2, channels, vec_type),
6696 (4, phantom_scid, required),
6697 (6, real_node_pubkey, required),
6700 impl_writeable_tlv_based_enum!(PendingHTLCRouting,
6702 (0, onion_packet, required),
6703 (2, short_channel_id, required),
6706 (0, payment_data, required),
6707 (1, phantom_shared_secret, option),
6708 (2, incoming_cltv_expiry, required),
6710 (2, ReceiveKeysend) => {
6711 (0, payment_preimage, required),
6712 (2, incoming_cltv_expiry, required),
6716 impl_writeable_tlv_based!(PendingHTLCInfo, {
6717 (0, routing, required),
6718 (2, incoming_shared_secret, required),
6719 (4, payment_hash, required),
6720 (6, outgoing_amt_msat, required),
6721 (8, outgoing_cltv_value, required),
6722 (9, incoming_amt_msat, option),
6726 impl Writeable for HTLCFailureMsg {
6727 fn write<W: Writer>(&self, writer: &mut W) -> Result<(), io::Error> {
6729 HTLCFailureMsg::Relay(msgs::UpdateFailHTLC { channel_id, htlc_id, reason }) => {
6731 channel_id.write(writer)?;
6732 htlc_id.write(writer)?;
6733 reason.write(writer)?;
6735 HTLCFailureMsg::Malformed(msgs::UpdateFailMalformedHTLC {
6736 channel_id, htlc_id, sha256_of_onion, failure_code
6739 channel_id.write(writer)?;
6740 htlc_id.write(writer)?;
6741 sha256_of_onion.write(writer)?;
6742 failure_code.write(writer)?;
6749 impl Readable for HTLCFailureMsg {
6750 fn read<R: Read>(reader: &mut R) -> Result<Self, DecodeError> {
6751 let id: u8 = Readable::read(reader)?;
6754 Ok(HTLCFailureMsg::Relay(msgs::UpdateFailHTLC {
6755 channel_id: Readable::read(reader)?,
6756 htlc_id: Readable::read(reader)?,
6757 reason: Readable::read(reader)?,
6761 Ok(HTLCFailureMsg::Malformed(msgs::UpdateFailMalformedHTLC {
6762 channel_id: Readable::read(reader)?,
6763 htlc_id: Readable::read(reader)?,
6764 sha256_of_onion: Readable::read(reader)?,
6765 failure_code: Readable::read(reader)?,
6768 // In versions prior to 0.0.101, HTLCFailureMsg objects were written with type 0 or 1 but
6769 // weren't length-prefixed and thus didn't support reading the TLV stream suffix of the network
6770 // messages contained in the variants.
6771 // In version 0.0.101, support for reading the variants with these types was added, and
6772 // we should migrate to writing these variants when UpdateFailHTLC or
6773 // UpdateFailMalformedHTLC get TLV fields.
6775 let length: BigSize = Readable::read(reader)?;
6776 let mut s = FixedLengthReader::new(reader, length.0);
6777 let res = Readable::read(&mut s)?;
6778 s.eat_remaining()?; // Return ShortRead if there's actually not enough bytes
6779 Ok(HTLCFailureMsg::Relay(res))
6782 let length: BigSize = Readable::read(reader)?;
6783 let mut s = FixedLengthReader::new(reader, length.0);
6784 let res = Readable::read(&mut s)?;
6785 s.eat_remaining()?; // Return ShortRead if there's actually not enough bytes
6786 Ok(HTLCFailureMsg::Malformed(res))
6788 _ => Err(DecodeError::UnknownRequiredFeature),
6793 impl_writeable_tlv_based_enum!(PendingHTLCStatus, ;
6798 impl_writeable_tlv_based!(HTLCPreviousHopData, {
6799 (0, short_channel_id, required),
6800 (1, phantom_shared_secret, option),
6801 (2, outpoint, required),
6802 (4, htlc_id, required),
6803 (6, incoming_packet_shared_secret, required)
6806 impl Writeable for ClaimableHTLC {
6807 fn write<W: Writer>(&self, writer: &mut W) -> Result<(), io::Error> {
6808 let (payment_data, keysend_preimage) = match &self.onion_payload {
6809 OnionPayload::Invoice { _legacy_hop_data } => (_legacy_hop_data.as_ref(), None),
6810 OnionPayload::Spontaneous(preimage) => (None, Some(preimage)),
6812 write_tlv_fields!(writer, {
6813 (0, self.prev_hop, required),
6814 (1, self.total_msat, required),
6815 (2, self.value, required),
6816 (4, payment_data, option),
6817 (5, self.total_value_received, option),
6818 (6, self.cltv_expiry, required),
6819 (8, keysend_preimage, option),
6825 impl Readable for ClaimableHTLC {
6826 fn read<R: Read>(reader: &mut R) -> Result<Self, DecodeError> {
6827 let mut prev_hop = crate::util::ser::RequiredWrapper(None);
6829 let mut payment_data: Option<msgs::FinalOnionHopData> = None;
6830 let mut cltv_expiry = 0;
6831 let mut total_value_received = None;
6832 let mut total_msat = None;
6833 let mut keysend_preimage: Option<PaymentPreimage> = None;
6834 read_tlv_fields!(reader, {
6835 (0, prev_hop, required),
6836 (1, total_msat, option),
6837 (2, value, required),
6838 (4, payment_data, option),
6839 (5, total_value_received, option),
6840 (6, cltv_expiry, required),
6841 (8, keysend_preimage, option)
6843 let onion_payload = match keysend_preimage {
6845 if payment_data.is_some() {
6846 return Err(DecodeError::InvalidValue)
6848 if total_msat.is_none() {
6849 total_msat = Some(value);
6851 OnionPayload::Spontaneous(p)
6854 if total_msat.is_none() {
6855 if payment_data.is_none() {
6856 return Err(DecodeError::InvalidValue)
6858 total_msat = Some(payment_data.as_ref().unwrap().total_msat);
6860 OnionPayload::Invoice { _legacy_hop_data: payment_data }
6864 prev_hop: prev_hop.0.unwrap(),
6867 total_value_received,
6868 total_msat: total_msat.unwrap(),
6875 impl Readable for HTLCSource {
6876 fn read<R: Read>(reader: &mut R) -> Result<Self, DecodeError> {
6877 let id: u8 = Readable::read(reader)?;
6880 let mut session_priv: crate::util::ser::RequiredWrapper<SecretKey> = crate::util::ser::RequiredWrapper(None);
6881 let mut first_hop_htlc_msat: u64 = 0;
6882 let mut path: Option<Vec<RouteHop>> = Some(Vec::new());
6883 let mut payment_id = None;
6884 let mut payment_secret = None;
6885 let mut payment_params: Option<PaymentParameters> = None;
6886 read_tlv_fields!(reader, {
6887 (0, session_priv, required),
6888 (1, payment_id, option),
6889 (2, first_hop_htlc_msat, required),
6890 (3, payment_secret, option),
6891 (4, path, vec_type),
6892 (5, payment_params, (option: ReadableArgs, 0)),
6894 if payment_id.is_none() {
6895 // For backwards compat, if there was no payment_id written, use the session_priv bytes
6897 payment_id = Some(PaymentId(*session_priv.0.unwrap().as_ref()));
6899 if path.is_none() || path.as_ref().unwrap().is_empty() {
6900 return Err(DecodeError::InvalidValue);
6902 let path = path.unwrap();
6903 if let Some(params) = payment_params.as_mut() {
6904 if params.final_cltv_expiry_delta == 0 {
6905 params.final_cltv_expiry_delta = path.last().unwrap().cltv_expiry_delta;
6908 Ok(HTLCSource::OutboundRoute {
6909 session_priv: session_priv.0.unwrap(),
6910 first_hop_htlc_msat,
6912 payment_id: payment_id.unwrap(),
6916 1 => Ok(HTLCSource::PreviousHopData(Readable::read(reader)?)),
6917 _ => Err(DecodeError::UnknownRequiredFeature),
6922 impl Writeable for HTLCSource {
6923 fn write<W: Writer>(&self, writer: &mut W) -> Result<(), crate::io::Error> {
6925 HTLCSource::OutboundRoute { ref session_priv, ref first_hop_htlc_msat, ref path, payment_id, payment_secret } => {
6927 let payment_id_opt = Some(payment_id);
6928 write_tlv_fields!(writer, {
6929 (0, session_priv, required),
6930 (1, payment_id_opt, option),
6931 (2, first_hop_htlc_msat, required),
6932 (3, payment_secret, option),
6933 (4, *path, vec_type),
6934 (5, None::<PaymentParameters>, option), // payment_params in LDK versions prior to 0.0.115
6937 HTLCSource::PreviousHopData(ref field) => {
6939 field.write(writer)?;
6946 impl_writeable_tlv_based!(PendingAddHTLCInfo, {
6947 (0, forward_info, required),
6948 (1, prev_user_channel_id, (default_value, 0)),
6949 (2, prev_short_channel_id, required),
6950 (4, prev_htlc_id, required),
6951 (6, prev_funding_outpoint, required),
6954 impl_writeable_tlv_based_enum!(HTLCForwardInfo,
6956 (0, htlc_id, required),
6957 (2, err_packet, required),
6962 impl_writeable_tlv_based!(PendingInboundPayment, {
6963 (0, payment_secret, required),
6964 (2, expiry_time, required),
6965 (4, user_payment_id, required),
6966 (6, payment_preimage, required),
6967 (8, min_value_msat, required),
6970 impl<M: Deref, T: Deref, ES: Deref, NS: Deref, SP: Deref, F: Deref, R: Deref, L: Deref> Writeable for ChannelManager<M, T, ES, NS, SP, F, R, L>
6972 M::Target: chain::Watch<<SP::Target as SignerProvider>::Signer>,
6973 T::Target: BroadcasterInterface,
6974 ES::Target: EntropySource,
6975 NS::Target: NodeSigner,
6976 SP::Target: SignerProvider,
6977 F::Target: FeeEstimator,
6981 fn write<W: Writer>(&self, writer: &mut W) -> Result<(), io::Error> {
6982 let _consistency_lock = self.total_consistency_lock.write().unwrap();
6984 write_ver_prefix!(writer, SERIALIZATION_VERSION, MIN_SERIALIZATION_VERSION);
6986 self.genesis_hash.write(writer)?;
6988 let best_block = self.best_block.read().unwrap();
6989 best_block.height().write(writer)?;
6990 best_block.block_hash().write(writer)?;
6993 let mut serializable_peer_count: u64 = 0;
6995 let per_peer_state = self.per_peer_state.read().unwrap();
6996 let mut unfunded_channels = 0;
6997 let mut number_of_channels = 0;
6998 for (_, peer_state_mutex) in per_peer_state.iter() {
6999 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
7000 let peer_state = &mut *peer_state_lock;
7001 if !peer_state.ok_to_remove(false) {
7002 serializable_peer_count += 1;
7004 number_of_channels += peer_state.channel_by_id.len();
7005 for (_, channel) in peer_state.channel_by_id.iter() {
7006 if !channel.is_funding_initiated() {
7007 unfunded_channels += 1;
7012 ((number_of_channels - unfunded_channels) as u64).write(writer)?;
7014 for (_, peer_state_mutex) in per_peer_state.iter() {
7015 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
7016 let peer_state = &mut *peer_state_lock;
7017 for (_, channel) in peer_state.channel_by_id.iter() {
7018 if channel.is_funding_initiated() {
7019 channel.write(writer)?;
7026 let forward_htlcs = self.forward_htlcs.lock().unwrap();
7027 (forward_htlcs.len() as u64).write(writer)?;
7028 for (short_channel_id, pending_forwards) in forward_htlcs.iter() {
7029 short_channel_id.write(writer)?;
7030 (pending_forwards.len() as u64).write(writer)?;
7031 for forward in pending_forwards {
7032 forward.write(writer)?;
7037 let per_peer_state = self.per_peer_state.write().unwrap();
7039 let pending_inbound_payments = self.pending_inbound_payments.lock().unwrap();
7040 let claimable_payments = self.claimable_payments.lock().unwrap();
7041 let pending_outbound_payments = self.pending_outbound_payments.pending_outbound_payments.lock().unwrap();
7043 let mut htlc_purposes: Vec<&events::PaymentPurpose> = Vec::new();
7044 (claimable_payments.claimable_htlcs.len() as u64).write(writer)?;
7045 for (payment_hash, (purpose, previous_hops)) in claimable_payments.claimable_htlcs.iter() {
7046 payment_hash.write(writer)?;
7047 (previous_hops.len() as u64).write(writer)?;
7048 for htlc in previous_hops.iter() {
7049 htlc.write(writer)?;
7051 htlc_purposes.push(purpose);
7054 let mut monitor_update_blocked_actions_per_peer = None;
7055 let mut peer_states = Vec::new();
7056 for (_, peer_state_mutex) in per_peer_state.iter() {
7057 // Because we're holding the owning `per_peer_state` write lock here there's no chance
7058 // of a lockorder violation deadlock - no other thread can be holding any
7059 // per_peer_state lock at all.
7060 peer_states.push(peer_state_mutex.unsafe_well_ordered_double_lock_self());
7063 (serializable_peer_count).write(writer)?;
7064 for ((peer_pubkey, _), peer_state) in per_peer_state.iter().zip(peer_states.iter()) {
7065 // Peers which we have no channels to should be dropped once disconnected. As we
7066 // disconnect all peers when shutting down and serializing the ChannelManager, we
7067 // consider all peers as disconnected here. There's therefore no need write peers with
7069 if !peer_state.ok_to_remove(false) {
7070 peer_pubkey.write(writer)?;
7071 peer_state.latest_features.write(writer)?;
7072 if !peer_state.monitor_update_blocked_actions.is_empty() {
7073 monitor_update_blocked_actions_per_peer
7074 .get_or_insert_with(Vec::new)
7075 .push((*peer_pubkey, &peer_state.monitor_update_blocked_actions));
7080 let events = self.pending_events.lock().unwrap();
7081 (events.len() as u64).write(writer)?;
7082 for event in events.iter() {
7083 event.write(writer)?;
7086 let background_events = self.pending_background_events.lock().unwrap();
7087 (background_events.len() as u64).write(writer)?;
7088 for event in background_events.iter() {
7090 BackgroundEvent::ClosingMonitorUpdate((funding_txo, monitor_update)) => {
7092 funding_txo.write(writer)?;
7093 monitor_update.write(writer)?;
7098 // Prior to 0.0.111 we tracked node_announcement serials here, however that now happens in
7099 // `PeerManager`, and thus we simply write the `highest_seen_timestamp` twice, which is
7100 // likely to be identical.
7101 (self.highest_seen_timestamp.load(Ordering::Acquire) as u32).write(writer)?;
7102 (self.highest_seen_timestamp.load(Ordering::Acquire) as u32).write(writer)?;
7104 (pending_inbound_payments.len() as u64).write(writer)?;
7105 for (hash, pending_payment) in pending_inbound_payments.iter() {
7106 hash.write(writer)?;
7107 pending_payment.write(writer)?;
7110 // For backwards compat, write the session privs and their total length.
7111 let mut num_pending_outbounds_compat: u64 = 0;
7112 for (_, outbound) in pending_outbound_payments.iter() {
7113 if !outbound.is_fulfilled() && !outbound.abandoned() {
7114 num_pending_outbounds_compat += outbound.remaining_parts() as u64;
7117 num_pending_outbounds_compat.write(writer)?;
7118 for (_, outbound) in pending_outbound_payments.iter() {
7120 PendingOutboundPayment::Legacy { session_privs } |
7121 PendingOutboundPayment::Retryable { session_privs, .. } => {
7122 for session_priv in session_privs.iter() {
7123 session_priv.write(writer)?;
7126 PendingOutboundPayment::Fulfilled { .. } => {},
7127 PendingOutboundPayment::Abandoned { .. } => {},
7131 // Encode without retry info for 0.0.101 compatibility.
7132 let mut pending_outbound_payments_no_retry: HashMap<PaymentId, HashSet<[u8; 32]>> = HashMap::new();
7133 for (id, outbound) in pending_outbound_payments.iter() {
7135 PendingOutboundPayment::Legacy { session_privs } |
7136 PendingOutboundPayment::Retryable { session_privs, .. } => {
7137 pending_outbound_payments_no_retry.insert(*id, session_privs.clone());
7143 let mut pending_intercepted_htlcs = None;
7144 let our_pending_intercepts = self.pending_intercepted_htlcs.lock().unwrap();
7145 if our_pending_intercepts.len() != 0 {
7146 pending_intercepted_htlcs = Some(our_pending_intercepts);
7149 let mut pending_claiming_payments = Some(&claimable_payments.pending_claiming_payments);
7150 if pending_claiming_payments.as_ref().unwrap().is_empty() {
7151 // LDK versions prior to 0.0.113 do not know how to read the pending claimed payments
7152 // map. Thus, if there are no entries we skip writing a TLV for it.
7153 pending_claiming_payments = None;
7156 write_tlv_fields!(writer, {
7157 (1, pending_outbound_payments_no_retry, required),
7158 (2, pending_intercepted_htlcs, option),
7159 (3, pending_outbound_payments, required),
7160 (4, pending_claiming_payments, option),
7161 (5, self.our_network_pubkey, required),
7162 (6, monitor_update_blocked_actions_per_peer, option),
7163 (7, self.fake_scid_rand_bytes, required),
7164 (9, htlc_purposes, vec_type),
7165 (11, self.probing_cookie_secret, required),
7172 /// Arguments for the creation of a ChannelManager that are not deserialized.
7174 /// At a high-level, the process for deserializing a ChannelManager and resuming normal operation
7176 /// 1) Deserialize all stored [`ChannelMonitor`]s.
7177 /// 2) Deserialize the [`ChannelManager`] by filling in this struct and calling:
7178 /// `<(BlockHash, ChannelManager)>::read(reader, args)`
7179 /// This may result in closing some channels if the [`ChannelMonitor`] is newer than the stored
7180 /// [`ChannelManager`] state to ensure no loss of funds. Thus, transactions may be broadcasted.
7181 /// 3) If you are not fetching full blocks, register all relevant [`ChannelMonitor`] outpoints the
7182 /// same way you would handle a [`chain::Filter`] call using
7183 /// [`ChannelMonitor::get_outputs_to_watch`] and [`ChannelMonitor::get_funding_txo`].
7184 /// 4) Reconnect blocks on your [`ChannelMonitor`]s.
7185 /// 5) Disconnect/connect blocks on the [`ChannelManager`].
7186 /// 6) Re-persist the [`ChannelMonitor`]s to ensure the latest state is on disk.
7187 /// Note that if you're using a [`ChainMonitor`] for your [`chain::Watch`] implementation, you
7188 /// will likely accomplish this as a side-effect of calling [`chain::Watch::watch_channel`] in
7190 /// 7) Move the [`ChannelMonitor`]s into your local [`chain::Watch`]. If you're using a
7191 /// [`ChainMonitor`], this is done by calling [`chain::Watch::watch_channel`].
7193 /// Note that the ordering of #4-7 is not of importance, however all four must occur before you
7194 /// call any other methods on the newly-deserialized [`ChannelManager`].
7196 /// Note that because some channels may be closed during deserialization, it is critical that you
7197 /// always deserialize only the latest version of a ChannelManager and ChannelMonitors available to
7198 /// you. If you deserialize an old ChannelManager (during which force-closure transactions may be
7199 /// broadcast), and then later deserialize a newer version of the same ChannelManager (which will
7200 /// not force-close the same channels but consider them live), you may end up revoking a state for
7201 /// which you've already broadcasted the transaction.
7203 /// [`ChainMonitor`]: crate::chain::chainmonitor::ChainMonitor
7204 pub struct ChannelManagerReadArgs<'a, M: Deref, T: Deref, ES: Deref, NS: Deref, SP: Deref, F: Deref, R: Deref, L: Deref>
7206 M::Target: chain::Watch<<SP::Target as SignerProvider>::Signer>,
7207 T::Target: BroadcasterInterface,
7208 ES::Target: EntropySource,
7209 NS::Target: NodeSigner,
7210 SP::Target: SignerProvider,
7211 F::Target: FeeEstimator,
7215 /// A cryptographically secure source of entropy.
7216 pub entropy_source: ES,
7218 /// A signer that is able to perform node-scoped cryptographic operations.
7219 pub node_signer: NS,
7221 /// The keys provider which will give us relevant keys. Some keys will be loaded during
7222 /// deserialization and KeysInterface::read_chan_signer will be used to read per-Channel
7224 pub signer_provider: SP,
7226 /// The fee_estimator for use in the ChannelManager in the future.
7228 /// No calls to the FeeEstimator will be made during deserialization.
7229 pub fee_estimator: F,
7230 /// The chain::Watch for use in the ChannelManager in the future.
7232 /// No calls to the chain::Watch will be made during deserialization. It is assumed that
7233 /// you have deserialized ChannelMonitors separately and will add them to your
7234 /// chain::Watch after deserializing this ChannelManager.
7235 pub chain_monitor: M,
7237 /// The BroadcasterInterface which will be used in the ChannelManager in the future and may be
7238 /// used to broadcast the latest local commitment transactions of channels which must be
7239 /// force-closed during deserialization.
7240 pub tx_broadcaster: T,
7241 /// The router which will be used in the ChannelManager in the future for finding routes
7242 /// on-the-fly for trampoline payments. Absent in private nodes that don't support forwarding.
7244 /// No calls to the router will be made during deserialization.
7246 /// The Logger for use in the ChannelManager and which may be used to log information during
7247 /// deserialization.
7249 /// Default settings used for new channels. Any existing channels will continue to use the
7250 /// runtime settings which were stored when the ChannelManager was serialized.
7251 pub default_config: UserConfig,
7253 /// A map from channel funding outpoints to ChannelMonitors for those channels (ie
7254 /// value.get_funding_txo() should be the key).
7256 /// If a monitor is inconsistent with the channel state during deserialization the channel will
7257 /// be force-closed using the data in the ChannelMonitor and the channel will be dropped. This
7258 /// is true for missing channels as well. If there is a monitor missing for which we find
7259 /// channel data Err(DecodeError::InvalidValue) will be returned.
7261 /// In such cases the latest local transactions will be sent to the tx_broadcaster included in
7264 /// This is not exported to bindings users because we have no HashMap bindings
7265 pub channel_monitors: HashMap<OutPoint, &'a mut ChannelMonitor<<SP::Target as SignerProvider>::Signer>>,
7268 impl<'a, M: Deref, T: Deref, ES: Deref, NS: Deref, SP: Deref, F: Deref, R: Deref, L: Deref>
7269 ChannelManagerReadArgs<'a, M, T, ES, NS, SP, F, R, L>
7271 M::Target: chain::Watch<<SP::Target as SignerProvider>::Signer>,
7272 T::Target: BroadcasterInterface,
7273 ES::Target: EntropySource,
7274 NS::Target: NodeSigner,
7275 SP::Target: SignerProvider,
7276 F::Target: FeeEstimator,
7280 /// Simple utility function to create a ChannelManagerReadArgs which creates the monitor
7281 /// HashMap for you. This is primarily useful for C bindings where it is not practical to
7282 /// populate a HashMap directly from C.
7283 pub fn new(entropy_source: ES, node_signer: NS, signer_provider: SP, fee_estimator: F, chain_monitor: M, tx_broadcaster: T, router: R, logger: L, default_config: UserConfig,
7284 mut channel_monitors: Vec<&'a mut ChannelMonitor<<SP::Target as SignerProvider>::Signer>>) -> Self {
7286 entropy_source, node_signer, signer_provider, fee_estimator, chain_monitor, tx_broadcaster, router, logger, default_config,
7287 channel_monitors: channel_monitors.drain(..).map(|monitor| { (monitor.get_funding_txo().0, monitor) }).collect()
7292 // Implement ReadableArgs for an Arc'd ChannelManager to make it a bit easier to work with the
7293 // SipmleArcChannelManager type:
7294 impl<'a, M: Deref, T: Deref, ES: Deref, NS: Deref, SP: Deref, F: Deref, R: Deref, L: Deref>
7295 ReadableArgs<ChannelManagerReadArgs<'a, M, T, ES, NS, SP, F, R, L>> for (BlockHash, Arc<ChannelManager<M, T, ES, NS, SP, F, R, L>>)
7297 M::Target: chain::Watch<<SP::Target as SignerProvider>::Signer>,
7298 T::Target: BroadcasterInterface,
7299 ES::Target: EntropySource,
7300 NS::Target: NodeSigner,
7301 SP::Target: SignerProvider,
7302 F::Target: FeeEstimator,
7306 fn read<Reader: io::Read>(reader: &mut Reader, args: ChannelManagerReadArgs<'a, M, T, ES, NS, SP, F, R, L>) -> Result<Self, DecodeError> {
7307 let (blockhash, chan_manager) = <(BlockHash, ChannelManager<M, T, ES, NS, SP, F, R, L>)>::read(reader, args)?;
7308 Ok((blockhash, Arc::new(chan_manager)))
7312 impl<'a, M: Deref, T: Deref, ES: Deref, NS: Deref, SP: Deref, F: Deref, R: Deref, L: Deref>
7313 ReadableArgs<ChannelManagerReadArgs<'a, M, T, ES, NS, SP, F, R, L>> for (BlockHash, ChannelManager<M, T, ES, NS, SP, F, R, L>)
7315 M::Target: chain::Watch<<SP::Target as SignerProvider>::Signer>,
7316 T::Target: BroadcasterInterface,
7317 ES::Target: EntropySource,
7318 NS::Target: NodeSigner,
7319 SP::Target: SignerProvider,
7320 F::Target: FeeEstimator,
7324 fn read<Reader: io::Read>(reader: &mut Reader, mut args: ChannelManagerReadArgs<'a, M, T, ES, NS, SP, F, R, L>) -> Result<Self, DecodeError> {
7325 let _ver = read_ver_prefix!(reader, SERIALIZATION_VERSION);
7327 let genesis_hash: BlockHash = Readable::read(reader)?;
7328 let best_block_height: u32 = Readable::read(reader)?;
7329 let best_block_hash: BlockHash = Readable::read(reader)?;
7331 let mut failed_htlcs = Vec::new();
7333 let channel_count: u64 = Readable::read(reader)?;
7334 let mut funding_txo_set = HashSet::with_capacity(cmp::min(channel_count as usize, 128));
7335 let mut peer_channels: HashMap<PublicKey, HashMap<[u8; 32], Channel<<SP::Target as SignerProvider>::Signer>>> = HashMap::with_capacity(cmp::min(channel_count as usize, 128));
7336 let mut id_to_peer = HashMap::with_capacity(cmp::min(channel_count as usize, 128));
7337 let mut short_to_chan_info = HashMap::with_capacity(cmp::min(channel_count as usize, 128));
7338 let mut channel_closures = Vec::new();
7339 for _ in 0..channel_count {
7340 let mut channel: Channel<<SP::Target as SignerProvider>::Signer> = Channel::read(reader, (
7341 &args.entropy_source, &args.signer_provider, best_block_height, &provided_channel_type_features(&args.default_config)
7343 let funding_txo = channel.get_funding_txo().ok_or(DecodeError::InvalidValue)?;
7344 funding_txo_set.insert(funding_txo.clone());
7345 if let Some(ref mut monitor) = args.channel_monitors.get_mut(&funding_txo) {
7346 if channel.get_cur_holder_commitment_transaction_number() < monitor.get_cur_holder_commitment_number() ||
7347 channel.get_revoked_counterparty_commitment_transaction_number() < monitor.get_min_seen_secret() ||
7348 channel.get_cur_counterparty_commitment_transaction_number() < monitor.get_cur_counterparty_commitment_number() ||
7349 channel.get_latest_monitor_update_id() > monitor.get_latest_update_id() {
7350 // If the channel is ahead of the monitor, return InvalidValue:
7351 log_error!(args.logger, "A ChannelMonitor is stale compared to the current ChannelManager! This indicates a potentially-critical violation of the chain::Watch API!");
7352 log_error!(args.logger, " The ChannelMonitor for channel {} is at update_id {} but the ChannelManager is at update_id {}.",
7353 log_bytes!(channel.channel_id()), monitor.get_latest_update_id(), channel.get_latest_monitor_update_id());
7354 log_error!(args.logger, " The chain::Watch API *requires* that monitors are persisted durably before returning,");
7355 log_error!(args.logger, " client applications must ensure that ChannelMonitor data is always available and the latest to avoid funds loss!");
7356 log_error!(args.logger, " Without the latest ChannelMonitor we cannot continue without risking funds.");
7357 log_error!(args.logger, " Please ensure the chain::Watch API requirements are met and file a bug report at https://github.com/lightningdevkit/rust-lightning");
7358 return Err(DecodeError::InvalidValue);
7359 } else if channel.get_cur_holder_commitment_transaction_number() > monitor.get_cur_holder_commitment_number() ||
7360 channel.get_revoked_counterparty_commitment_transaction_number() > monitor.get_min_seen_secret() ||
7361 channel.get_cur_counterparty_commitment_transaction_number() > monitor.get_cur_counterparty_commitment_number() ||
7362 channel.get_latest_monitor_update_id() < monitor.get_latest_update_id() {
7363 // But if the channel is behind of the monitor, close the channel:
7364 log_error!(args.logger, "A ChannelManager is stale compared to the current ChannelMonitor!");
7365 log_error!(args.logger, " The channel will be force-closed and the latest commitment transaction from the ChannelMonitor broadcast.");
7366 log_error!(args.logger, " The ChannelMonitor for channel {} is at update_id {} but the ChannelManager is at update_id {}.",
7367 log_bytes!(channel.channel_id()), monitor.get_latest_update_id(), channel.get_latest_monitor_update_id());
7368 let (_, mut new_failed_htlcs) = channel.force_shutdown(true);
7369 failed_htlcs.append(&mut new_failed_htlcs);
7370 monitor.broadcast_latest_holder_commitment_txn(&args.tx_broadcaster, &args.logger);
7371 channel_closures.push(events::Event::ChannelClosed {
7372 channel_id: channel.channel_id(),
7373 user_channel_id: channel.get_user_id(),
7374 reason: ClosureReason::OutdatedChannelManager
7376 for (channel_htlc_source, payment_hash) in channel.inflight_htlc_sources() {
7377 let mut found_htlc = false;
7378 for (monitor_htlc_source, _) in monitor.get_all_current_outbound_htlcs() {
7379 if *channel_htlc_source == monitor_htlc_source { found_htlc = true; break; }
7382 // If we have some HTLCs in the channel which are not present in the newer
7383 // ChannelMonitor, they have been removed and should be failed back to
7384 // ensure we don't forget them entirely. Note that if the missing HTLC(s)
7385 // were actually claimed we'd have generated and ensured the previous-hop
7386 // claim update ChannelMonitor updates were persisted prior to persising
7387 // the ChannelMonitor update for the forward leg, so attempting to fail the
7388 // backwards leg of the HTLC will simply be rejected.
7389 log_info!(args.logger,
7390 "Failing HTLC with hash {} as it is missing in the ChannelMonitor for channel {} but was present in the (stale) ChannelManager",
7391 log_bytes!(channel.channel_id()), log_bytes!(payment_hash.0));
7392 failed_htlcs.push((channel_htlc_source.clone(), *payment_hash, channel.get_counterparty_node_id(), channel.channel_id()));
7396 log_info!(args.logger, "Successfully loaded channel {}", log_bytes!(channel.channel_id()));
7397 if let Some(short_channel_id) = channel.get_short_channel_id() {
7398 short_to_chan_info.insert(short_channel_id, (channel.get_counterparty_node_id(), channel.channel_id()));
7400 if channel.is_funding_initiated() {
7401 id_to_peer.insert(channel.channel_id(), channel.get_counterparty_node_id());
7403 match peer_channels.entry(channel.get_counterparty_node_id()) {
7404 hash_map::Entry::Occupied(mut entry) => {
7405 let by_id_map = entry.get_mut();
7406 by_id_map.insert(channel.channel_id(), channel);
7408 hash_map::Entry::Vacant(entry) => {
7409 let mut by_id_map = HashMap::new();
7410 by_id_map.insert(channel.channel_id(), channel);
7411 entry.insert(by_id_map);
7415 } else if channel.is_awaiting_initial_mon_persist() {
7416 // If we were persisted and shut down while the initial ChannelMonitor persistence
7417 // was in-progress, we never broadcasted the funding transaction and can still
7418 // safely discard the channel.
7419 let _ = channel.force_shutdown(false);
7420 channel_closures.push(events::Event::ChannelClosed {
7421 channel_id: channel.channel_id(),
7422 user_channel_id: channel.get_user_id(),
7423 reason: ClosureReason::DisconnectedPeer,
7426 log_error!(args.logger, "Missing ChannelMonitor for channel {} needed by ChannelManager.", log_bytes!(channel.channel_id()));
7427 log_error!(args.logger, " The chain::Watch API *requires* that monitors are persisted durably before returning,");
7428 log_error!(args.logger, " client applications must ensure that ChannelMonitor data is always available and the latest to avoid funds loss!");
7429 log_error!(args.logger, " Without the ChannelMonitor we cannot continue without risking funds.");
7430 log_error!(args.logger, " Please ensure the chain::Watch API requirements are met and file a bug report at https://github.com/lightningdevkit/rust-lightning");
7431 return Err(DecodeError::InvalidValue);
7435 for (funding_txo, monitor) in args.channel_monitors.iter_mut() {
7436 if !funding_txo_set.contains(funding_txo) {
7437 log_info!(args.logger, "Broadcasting latest holder commitment transaction for closed channel {}", log_bytes!(funding_txo.to_channel_id()));
7438 monitor.broadcast_latest_holder_commitment_txn(&args.tx_broadcaster, &args.logger);
7442 const MAX_ALLOC_SIZE: usize = 1024 * 64;
7443 let forward_htlcs_count: u64 = Readable::read(reader)?;
7444 let mut forward_htlcs = HashMap::with_capacity(cmp::min(forward_htlcs_count as usize, 128));
7445 for _ in 0..forward_htlcs_count {
7446 let short_channel_id = Readable::read(reader)?;
7447 let pending_forwards_count: u64 = Readable::read(reader)?;
7448 let mut pending_forwards = Vec::with_capacity(cmp::min(pending_forwards_count as usize, MAX_ALLOC_SIZE/mem::size_of::<HTLCForwardInfo>()));
7449 for _ in 0..pending_forwards_count {
7450 pending_forwards.push(Readable::read(reader)?);
7452 forward_htlcs.insert(short_channel_id, pending_forwards);
7455 let claimable_htlcs_count: u64 = Readable::read(reader)?;
7456 let mut claimable_htlcs_list = Vec::with_capacity(cmp::min(claimable_htlcs_count as usize, 128));
7457 for _ in 0..claimable_htlcs_count {
7458 let payment_hash = Readable::read(reader)?;
7459 let previous_hops_len: u64 = Readable::read(reader)?;
7460 let mut previous_hops = Vec::with_capacity(cmp::min(previous_hops_len as usize, MAX_ALLOC_SIZE/mem::size_of::<ClaimableHTLC>()));
7461 for _ in 0..previous_hops_len {
7462 previous_hops.push(<ClaimableHTLC as Readable>::read(reader)?);
7464 claimable_htlcs_list.push((payment_hash, previous_hops));
7467 let peer_count: u64 = Readable::read(reader)?;
7468 let mut per_peer_state = HashMap::with_capacity(cmp::min(peer_count as usize, MAX_ALLOC_SIZE/mem::size_of::<(PublicKey, Mutex<PeerState<<SP::Target as SignerProvider>::Signer>>)>()));
7469 for _ in 0..peer_count {
7470 let peer_pubkey = Readable::read(reader)?;
7471 let peer_state = PeerState {
7472 channel_by_id: peer_channels.remove(&peer_pubkey).unwrap_or(HashMap::new()),
7473 latest_features: Readable::read(reader)?,
7474 pending_msg_events: Vec::new(),
7475 monitor_update_blocked_actions: BTreeMap::new(),
7476 is_connected: false,
7478 per_peer_state.insert(peer_pubkey, Mutex::new(peer_state));
7481 let event_count: u64 = Readable::read(reader)?;
7482 let mut pending_events_read: Vec<events::Event> = Vec::with_capacity(cmp::min(event_count as usize, MAX_ALLOC_SIZE/mem::size_of::<events::Event>()));
7483 for _ in 0..event_count {
7484 match MaybeReadable::read(reader)? {
7485 Some(event) => pending_events_read.push(event),
7490 let background_event_count: u64 = Readable::read(reader)?;
7491 let mut pending_background_events_read: Vec<BackgroundEvent> = Vec::with_capacity(cmp::min(background_event_count as usize, MAX_ALLOC_SIZE/mem::size_of::<BackgroundEvent>()));
7492 for _ in 0..background_event_count {
7493 match <u8 as Readable>::read(reader)? {
7494 0 => pending_background_events_read.push(BackgroundEvent::ClosingMonitorUpdate((Readable::read(reader)?, Readable::read(reader)?))),
7495 _ => return Err(DecodeError::InvalidValue),
7499 let _last_node_announcement_serial: u32 = Readable::read(reader)?; // Only used < 0.0.111
7500 let highest_seen_timestamp: u32 = Readable::read(reader)?;
7502 let pending_inbound_payment_count: u64 = Readable::read(reader)?;
7503 let mut pending_inbound_payments: HashMap<PaymentHash, PendingInboundPayment> = HashMap::with_capacity(cmp::min(pending_inbound_payment_count as usize, MAX_ALLOC_SIZE/(3*32)));
7504 for _ in 0..pending_inbound_payment_count {
7505 if pending_inbound_payments.insert(Readable::read(reader)?, Readable::read(reader)?).is_some() {
7506 return Err(DecodeError::InvalidValue);
7510 let pending_outbound_payments_count_compat: u64 = Readable::read(reader)?;
7511 let mut pending_outbound_payments_compat: HashMap<PaymentId, PendingOutboundPayment> =
7512 HashMap::with_capacity(cmp::min(pending_outbound_payments_count_compat as usize, MAX_ALLOC_SIZE/32));
7513 for _ in 0..pending_outbound_payments_count_compat {
7514 let session_priv = Readable::read(reader)?;
7515 let payment = PendingOutboundPayment::Legacy {
7516 session_privs: [session_priv].iter().cloned().collect()
7518 if pending_outbound_payments_compat.insert(PaymentId(session_priv), payment).is_some() {
7519 return Err(DecodeError::InvalidValue)
7523 // pending_outbound_payments_no_retry is for compatibility with 0.0.101 clients.
7524 let mut pending_outbound_payments_no_retry: Option<HashMap<PaymentId, HashSet<[u8; 32]>>> = None;
7525 let mut pending_outbound_payments = None;
7526 let mut pending_intercepted_htlcs: Option<HashMap<InterceptId, PendingAddHTLCInfo>> = Some(HashMap::new());
7527 let mut received_network_pubkey: Option<PublicKey> = None;
7528 let mut fake_scid_rand_bytes: Option<[u8; 32]> = None;
7529 let mut probing_cookie_secret: Option<[u8; 32]> = None;
7530 let mut claimable_htlc_purposes = None;
7531 let mut pending_claiming_payments = Some(HashMap::new());
7532 let mut monitor_update_blocked_actions_per_peer = Some(Vec::new());
7533 read_tlv_fields!(reader, {
7534 (1, pending_outbound_payments_no_retry, option),
7535 (2, pending_intercepted_htlcs, option),
7536 (3, pending_outbound_payments, option),
7537 (4, pending_claiming_payments, option),
7538 (5, received_network_pubkey, option),
7539 (6, monitor_update_blocked_actions_per_peer, option),
7540 (7, fake_scid_rand_bytes, option),
7541 (9, claimable_htlc_purposes, vec_type),
7542 (11, probing_cookie_secret, option),
7544 if fake_scid_rand_bytes.is_none() {
7545 fake_scid_rand_bytes = Some(args.entropy_source.get_secure_random_bytes());
7548 if probing_cookie_secret.is_none() {
7549 probing_cookie_secret = Some(args.entropy_source.get_secure_random_bytes());
7552 if !channel_closures.is_empty() {
7553 pending_events_read.append(&mut channel_closures);
7556 if pending_outbound_payments.is_none() && pending_outbound_payments_no_retry.is_none() {
7557 pending_outbound_payments = Some(pending_outbound_payments_compat);
7558 } else if pending_outbound_payments.is_none() {
7559 let mut outbounds = HashMap::new();
7560 for (id, session_privs) in pending_outbound_payments_no_retry.unwrap().drain() {
7561 outbounds.insert(id, PendingOutboundPayment::Legacy { session_privs });
7563 pending_outbound_payments = Some(outbounds);
7565 let pending_outbounds = OutboundPayments {
7566 pending_outbound_payments: Mutex::new(pending_outbound_payments.unwrap()),
7567 retry_lock: Mutex::new(())
7571 // If we're tracking pending payments, ensure we haven't lost any by looking at the
7572 // ChannelMonitor data for any channels for which we do not have authorative state
7573 // (i.e. those for which we just force-closed above or we otherwise don't have a
7574 // corresponding `Channel` at all).
7575 // This avoids several edge-cases where we would otherwise "forget" about pending
7576 // payments which are still in-flight via their on-chain state.
7577 // We only rebuild the pending payments map if we were most recently serialized by
7579 for (_, monitor) in args.channel_monitors.iter() {
7580 if id_to_peer.get(&monitor.get_funding_txo().0.to_channel_id()).is_none() {
7581 for (htlc_source, (htlc, _)) in monitor.get_pending_or_resolved_outbound_htlcs() {
7582 if let HTLCSource::OutboundRoute { payment_id, session_priv, path, payment_secret, .. } = htlc_source {
7583 if path.is_empty() {
7584 log_error!(args.logger, "Got an empty path for a pending payment");
7585 return Err(DecodeError::InvalidValue);
7588 let path_amt = path.last().unwrap().fee_msat;
7589 let mut session_priv_bytes = [0; 32];
7590 session_priv_bytes[..].copy_from_slice(&session_priv[..]);
7591 match pending_outbounds.pending_outbound_payments.lock().unwrap().entry(payment_id) {
7592 hash_map::Entry::Occupied(mut entry) => {
7593 let newly_added = entry.get_mut().insert(session_priv_bytes, &path);
7594 log_info!(args.logger, "{} a pending payment path for {} msat for session priv {} on an existing pending payment with payment hash {}",
7595 if newly_added { "Added" } else { "Had" }, path_amt, log_bytes!(session_priv_bytes), log_bytes!(htlc.payment_hash.0));
7597 hash_map::Entry::Vacant(entry) => {
7598 let path_fee = path.get_path_fees();
7599 entry.insert(PendingOutboundPayment::Retryable {
7600 retry_strategy: None,
7601 attempts: PaymentAttempts::new(),
7602 payment_params: None,
7603 session_privs: [session_priv_bytes].iter().map(|a| *a).collect(),
7604 payment_hash: htlc.payment_hash,
7606 keysend_preimage: None, // only used for retries, and we'll never retry on startup
7607 pending_amt_msat: path_amt,
7608 pending_fee_msat: Some(path_fee),
7609 total_msat: path_amt,
7610 starting_block_height: best_block_height,
7612 log_info!(args.logger, "Added a pending payment for {} msat with payment hash {} for path with session priv {}",
7613 path_amt, log_bytes!(htlc.payment_hash.0), log_bytes!(session_priv_bytes));
7618 for (htlc_source, (htlc, preimage_opt)) in monitor.get_all_current_outbound_htlcs() {
7620 HTLCSource::PreviousHopData(prev_hop_data) => {
7621 let pending_forward_matches_htlc = |info: &PendingAddHTLCInfo| {
7622 info.prev_funding_outpoint == prev_hop_data.outpoint &&
7623 info.prev_htlc_id == prev_hop_data.htlc_id
7625 // The ChannelMonitor is now responsible for this HTLC's
7626 // failure/success and will let us know what its outcome is. If we
7627 // still have an entry for this HTLC in `forward_htlcs` or
7628 // `pending_intercepted_htlcs`, we were apparently not persisted after
7629 // the monitor was when forwarding the payment.
7630 forward_htlcs.retain(|_, forwards| {
7631 forwards.retain(|forward| {
7632 if let HTLCForwardInfo::AddHTLC(htlc_info) = forward {
7633 if pending_forward_matches_htlc(&htlc_info) {
7634 log_info!(args.logger, "Removing pending to-forward HTLC with hash {} as it was forwarded to the closed channel {}",
7635 log_bytes!(htlc.payment_hash.0), log_bytes!(monitor.get_funding_txo().0.to_channel_id()));
7640 !forwards.is_empty()
7642 pending_intercepted_htlcs.as_mut().unwrap().retain(|intercepted_id, htlc_info| {
7643 if pending_forward_matches_htlc(&htlc_info) {
7644 log_info!(args.logger, "Removing pending intercepted HTLC with hash {} as it was forwarded to the closed channel {}",
7645 log_bytes!(htlc.payment_hash.0), log_bytes!(monitor.get_funding_txo().0.to_channel_id()));
7646 pending_events_read.retain(|event| {
7647 if let Event::HTLCIntercepted { intercept_id: ev_id, .. } = event {
7648 intercepted_id != ev_id
7655 HTLCSource::OutboundRoute { payment_id, session_priv, path, .. } => {
7656 if let Some(preimage) = preimage_opt {
7657 let pending_events = Mutex::new(pending_events_read);
7658 // Note that we set `from_onchain` to "false" here,
7659 // deliberately keeping the pending payment around forever.
7660 // Given it should only occur when we have a channel we're
7661 // force-closing for being stale that's okay.
7662 // The alternative would be to wipe the state when claiming,
7663 // generating a `PaymentPathSuccessful` event but regenerating
7664 // it and the `PaymentSent` on every restart until the
7665 // `ChannelMonitor` is removed.
7666 pending_outbounds.claim_htlc(payment_id, preimage, session_priv, path, false, &pending_events, &args.logger);
7667 pending_events_read = pending_events.into_inner().unwrap();
7676 if !forward_htlcs.is_empty() || pending_outbounds.needs_abandon() {
7677 // If we have pending HTLCs to forward, assume we either dropped a
7678 // `PendingHTLCsForwardable` or the user received it but never processed it as they
7679 // shut down before the timer hit. Either way, set the time_forwardable to a small
7680 // constant as enough time has likely passed that we should simply handle the forwards
7681 // now, or at least after the user gets a chance to reconnect to our peers.
7682 pending_events_read.push(events::Event::PendingHTLCsForwardable {
7683 time_forwardable: Duration::from_secs(2),
7687 let inbound_pmt_key_material = args.node_signer.get_inbound_payment_key_material();
7688 let expanded_inbound_key = inbound_payment::ExpandedKey::new(&inbound_pmt_key_material);
7690 let mut claimable_htlcs = HashMap::with_capacity(claimable_htlcs_list.len());
7691 if let Some(mut purposes) = claimable_htlc_purposes {
7692 if purposes.len() != claimable_htlcs_list.len() {
7693 return Err(DecodeError::InvalidValue);
7695 for (purpose, (payment_hash, previous_hops)) in purposes.drain(..).zip(claimable_htlcs_list.drain(..)) {
7696 claimable_htlcs.insert(payment_hash, (purpose, previous_hops));
7699 // LDK versions prior to 0.0.107 did not write a `pending_htlc_purposes`, but do
7700 // include a `_legacy_hop_data` in the `OnionPayload`.
7701 for (payment_hash, previous_hops) in claimable_htlcs_list.drain(..) {
7702 if previous_hops.is_empty() {
7703 return Err(DecodeError::InvalidValue);
7705 let purpose = match &previous_hops[0].onion_payload {
7706 OnionPayload::Invoice { _legacy_hop_data } => {
7707 if let Some(hop_data) = _legacy_hop_data {
7708 events::PaymentPurpose::InvoicePayment {
7709 payment_preimage: match pending_inbound_payments.get(&payment_hash) {
7710 Some(inbound_payment) => inbound_payment.payment_preimage,
7711 None => match inbound_payment::verify(payment_hash, &hop_data, 0, &expanded_inbound_key, &args.logger) {
7712 Ok((payment_preimage, _)) => payment_preimage,
7714 log_error!(args.logger, "Failed to read claimable payment data for HTLC with payment hash {} - was not a pending inbound payment and didn't match our payment key", log_bytes!(payment_hash.0));
7715 return Err(DecodeError::InvalidValue);
7719 payment_secret: hop_data.payment_secret,
7721 } else { return Err(DecodeError::InvalidValue); }
7723 OnionPayload::Spontaneous(payment_preimage) =>
7724 events::PaymentPurpose::SpontaneousPayment(*payment_preimage),
7726 claimable_htlcs.insert(payment_hash, (purpose, previous_hops));
7730 let mut secp_ctx = Secp256k1::new();
7731 secp_ctx.seeded_randomize(&args.entropy_source.get_secure_random_bytes());
7733 let our_network_pubkey = match args.node_signer.get_node_id(Recipient::Node) {
7735 Err(()) => return Err(DecodeError::InvalidValue)
7737 if let Some(network_pubkey) = received_network_pubkey {
7738 if network_pubkey != our_network_pubkey {
7739 log_error!(args.logger, "Key that was generated does not match the existing key.");
7740 return Err(DecodeError::InvalidValue);
7744 let mut outbound_scid_aliases = HashSet::new();
7745 for (_peer_node_id, peer_state_mutex) in per_peer_state.iter_mut() {
7746 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
7747 let peer_state = &mut *peer_state_lock;
7748 for (chan_id, chan) in peer_state.channel_by_id.iter_mut() {
7749 if chan.outbound_scid_alias() == 0 {
7750 let mut outbound_scid_alias;
7752 outbound_scid_alias = fake_scid::Namespace::OutboundAlias
7753 .get_fake_scid(best_block_height, &genesis_hash, fake_scid_rand_bytes.as_ref().unwrap(), &args.entropy_source);
7754 if outbound_scid_aliases.insert(outbound_scid_alias) { break; }
7756 chan.set_outbound_scid_alias(outbound_scid_alias);
7757 } else if !outbound_scid_aliases.insert(chan.outbound_scid_alias()) {
7758 // Note that in rare cases its possible to hit this while reading an older
7759 // channel if we just happened to pick a colliding outbound alias above.
7760 log_error!(args.logger, "Got duplicate outbound SCID alias; {}", chan.outbound_scid_alias());
7761 return Err(DecodeError::InvalidValue);
7763 if chan.is_usable() {
7764 if short_to_chan_info.insert(chan.outbound_scid_alias(), (chan.get_counterparty_node_id(), *chan_id)).is_some() {
7765 // Note that in rare cases its possible to hit this while reading an older
7766 // channel if we just happened to pick a colliding outbound alias above.
7767 log_error!(args.logger, "Got duplicate outbound SCID alias; {}", chan.outbound_scid_alias());
7768 return Err(DecodeError::InvalidValue);
7774 let bounded_fee_estimator = LowerBoundedFeeEstimator::new(args.fee_estimator);
7776 for (_, monitor) in args.channel_monitors.iter() {
7777 for (payment_hash, payment_preimage) in monitor.get_stored_preimages() {
7778 if let Some((payment_purpose, claimable_htlcs)) = claimable_htlcs.remove(&payment_hash) {
7779 log_info!(args.logger, "Re-claiming HTLCs with payment hash {} as we've released the preimage to a ChannelMonitor!", log_bytes!(payment_hash.0));
7780 let mut claimable_amt_msat = 0;
7781 let mut receiver_node_id = Some(our_network_pubkey);
7782 let phantom_shared_secret = claimable_htlcs[0].prev_hop.phantom_shared_secret;
7783 if phantom_shared_secret.is_some() {
7784 let phantom_pubkey = args.node_signer.get_node_id(Recipient::PhantomNode)
7785 .expect("Failed to get node_id for phantom node recipient");
7786 receiver_node_id = Some(phantom_pubkey)
7788 for claimable_htlc in claimable_htlcs {
7789 claimable_amt_msat += claimable_htlc.value;
7791 // Add a holding-cell claim of the payment to the Channel, which should be
7792 // applied ~immediately on peer reconnection. Because it won't generate a
7793 // new commitment transaction we can just provide the payment preimage to
7794 // the corresponding ChannelMonitor and nothing else.
7796 // We do so directly instead of via the normal ChannelMonitor update
7797 // procedure as the ChainMonitor hasn't yet been initialized, implying
7798 // we're not allowed to call it directly yet. Further, we do the update
7799 // without incrementing the ChannelMonitor update ID as there isn't any
7801 // If we were to generate a new ChannelMonitor update ID here and then
7802 // crash before the user finishes block connect we'd end up force-closing
7803 // this channel as well. On the flip side, there's no harm in restarting
7804 // without the new monitor persisted - we'll end up right back here on
7806 let previous_channel_id = claimable_htlc.prev_hop.outpoint.to_channel_id();
7807 if let Some(peer_node_id) = id_to_peer.get(&previous_channel_id){
7808 let peer_state_mutex = per_peer_state.get(peer_node_id).unwrap();
7809 let mut peer_state_lock = peer_state_mutex.lock().unwrap();
7810 let peer_state = &mut *peer_state_lock;
7811 if let Some(channel) = peer_state.channel_by_id.get_mut(&previous_channel_id) {
7812 channel.claim_htlc_while_disconnected_dropping_mon_update(claimable_htlc.prev_hop.htlc_id, payment_preimage, &args.logger);
7815 if let Some(previous_hop_monitor) = args.channel_monitors.get(&claimable_htlc.prev_hop.outpoint) {
7816 previous_hop_monitor.provide_payment_preimage(&payment_hash, &payment_preimage, &args.tx_broadcaster, &bounded_fee_estimator, &args.logger);
7819 pending_events_read.push(events::Event::PaymentClaimed {
7822 purpose: payment_purpose,
7823 amount_msat: claimable_amt_msat,
7829 for (node_id, monitor_update_blocked_actions) in monitor_update_blocked_actions_per_peer.unwrap() {
7830 if let Some(peer_state) = per_peer_state.get_mut(&node_id) {
7831 peer_state.lock().unwrap().monitor_update_blocked_actions = monitor_update_blocked_actions;
7833 log_error!(args.logger, "Got blocked actions without a per-peer-state for {}", node_id);
7834 return Err(DecodeError::InvalidValue);
7838 let channel_manager = ChannelManager {
7840 fee_estimator: bounded_fee_estimator,
7841 chain_monitor: args.chain_monitor,
7842 tx_broadcaster: args.tx_broadcaster,
7843 router: args.router,
7845 best_block: RwLock::new(BestBlock::new(best_block_hash, best_block_height)),
7847 inbound_payment_key: expanded_inbound_key,
7848 pending_inbound_payments: Mutex::new(pending_inbound_payments),
7849 pending_outbound_payments: pending_outbounds,
7850 pending_intercepted_htlcs: Mutex::new(pending_intercepted_htlcs.unwrap()),
7852 forward_htlcs: Mutex::new(forward_htlcs),
7853 claimable_payments: Mutex::new(ClaimablePayments { claimable_htlcs, pending_claiming_payments: pending_claiming_payments.unwrap() }),
7854 outbound_scid_aliases: Mutex::new(outbound_scid_aliases),
7855 id_to_peer: Mutex::new(id_to_peer),
7856 short_to_chan_info: FairRwLock::new(short_to_chan_info),
7857 fake_scid_rand_bytes: fake_scid_rand_bytes.unwrap(),
7859 probing_cookie_secret: probing_cookie_secret.unwrap(),
7864 highest_seen_timestamp: AtomicUsize::new(highest_seen_timestamp as usize),
7866 per_peer_state: FairRwLock::new(per_peer_state),
7868 pending_events: Mutex::new(pending_events_read),
7869 pending_background_events: Mutex::new(pending_background_events_read),
7870 total_consistency_lock: RwLock::new(()),
7871 persistence_notifier: Notifier::new(),
7873 entropy_source: args.entropy_source,
7874 node_signer: args.node_signer,
7875 signer_provider: args.signer_provider,
7877 logger: args.logger,
7878 default_configuration: args.default_config,
7881 for htlc_source in failed_htlcs.drain(..) {
7882 let (source, payment_hash, counterparty_node_id, channel_id) = htlc_source;
7883 let receiver = HTLCDestination::NextHopChannel { node_id: Some(counterparty_node_id), channel_id };
7884 let reason = HTLCFailReason::from_failure_code(0x4000 | 8);
7885 channel_manager.fail_htlc_backwards_internal(&source, &payment_hash, &reason, receiver);
7888 //TODO: Broadcast channel update for closed channels, but only after we've made a
7889 //connection or two.
7891 Ok((best_block_hash.clone(), channel_manager))
7897 use bitcoin::hashes::Hash;
7898 use bitcoin::hashes::sha256::Hash as Sha256;
7899 use bitcoin::secp256k1::{PublicKey, Secp256k1, SecretKey};
7900 use core::time::Duration;
7901 use core::sync::atomic::Ordering;
7902 use crate::events::{Event, HTLCDestination, MessageSendEvent, MessageSendEventsProvider, ClosureReason};
7903 use crate::ln::{PaymentPreimage, PaymentHash, PaymentSecret};
7904 use crate::ln::channelmanager::{inbound_payment, PaymentId, PaymentSendFailure, InterceptId};
7905 use crate::ln::functional_test_utils::*;
7906 use crate::ln::msgs;
7907 use crate::ln::msgs::ChannelMessageHandler;
7908 use crate::routing::router::{PaymentParameters, RouteParameters, find_route};
7909 use crate::util::errors::APIError;
7910 use crate::util::test_utils;
7911 use crate::util::config::ChannelConfig;
7912 use crate::chain::keysinterface::EntropySource;
7915 fn test_notify_limits() {
7916 // Check that a few cases which don't require the persistence of a new ChannelManager,
7917 // indeed, do not cause the persistence of a new ChannelManager.
7918 let chanmon_cfgs = create_chanmon_cfgs(3);
7919 let node_cfgs = create_node_cfgs(3, &chanmon_cfgs);
7920 let node_chanmgrs = create_node_chanmgrs(3, &node_cfgs, &[None, None, None]);
7921 let nodes = create_network(3, &node_cfgs, &node_chanmgrs);
7923 // All nodes start with a persistable update pending as `create_network` connects each node
7924 // with all other nodes to make most tests simpler.
7925 assert!(nodes[0].node.await_persistable_update_timeout(Duration::from_millis(1)));
7926 assert!(nodes[1].node.await_persistable_update_timeout(Duration::from_millis(1)));
7927 assert!(nodes[2].node.await_persistable_update_timeout(Duration::from_millis(1)));
7929 let mut chan = create_announced_chan_between_nodes(&nodes, 0, 1);
7931 // We check that the channel info nodes have doesn't change too early, even though we try
7932 // to connect messages with new values
7933 chan.0.contents.fee_base_msat *= 2;
7934 chan.1.contents.fee_base_msat *= 2;
7935 let node_a_chan_info = nodes[0].node.list_channels_with_counterparty(
7936 &nodes[1].node.get_our_node_id()).pop().unwrap();
7937 let node_b_chan_info = nodes[1].node.list_channels_with_counterparty(
7938 &nodes[0].node.get_our_node_id()).pop().unwrap();
7940 // The first two nodes (which opened a channel) should now require fresh persistence
7941 assert!(nodes[0].node.await_persistable_update_timeout(Duration::from_millis(1)));
7942 assert!(nodes[1].node.await_persistable_update_timeout(Duration::from_millis(1)));
7943 // ... but the last node should not.
7944 assert!(!nodes[2].node.await_persistable_update_timeout(Duration::from_millis(1)));
7945 // After persisting the first two nodes they should no longer need fresh persistence.
7946 assert!(!nodes[0].node.await_persistable_update_timeout(Duration::from_millis(1)));
7947 assert!(!nodes[1].node.await_persistable_update_timeout(Duration::from_millis(1)));
7949 // Node 3, unrelated to the only channel, shouldn't care if it receives a channel_update
7950 // about the channel.
7951 nodes[2].node.handle_channel_update(&nodes[1].node.get_our_node_id(), &chan.0);
7952 nodes[2].node.handle_channel_update(&nodes[1].node.get_our_node_id(), &chan.1);
7953 assert!(!nodes[2].node.await_persistable_update_timeout(Duration::from_millis(1)));
7955 // The nodes which are a party to the channel should also ignore messages from unrelated
7957 nodes[0].node.handle_channel_update(&nodes[2].node.get_our_node_id(), &chan.0);
7958 nodes[0].node.handle_channel_update(&nodes[2].node.get_our_node_id(), &chan.1);
7959 nodes[1].node.handle_channel_update(&nodes[2].node.get_our_node_id(), &chan.0);
7960 nodes[1].node.handle_channel_update(&nodes[2].node.get_our_node_id(), &chan.1);
7961 assert!(!nodes[0].node.await_persistable_update_timeout(Duration::from_millis(1)));
7962 assert!(!nodes[1].node.await_persistable_update_timeout(Duration::from_millis(1)));
7964 // At this point the channel info given by peers should still be the same.
7965 assert_eq!(nodes[0].node.list_channels()[0], node_a_chan_info);
7966 assert_eq!(nodes[1].node.list_channels()[0], node_b_chan_info);
7968 // An earlier version of handle_channel_update didn't check the directionality of the
7969 // update message and would always update the local fee info, even if our peer was
7970 // (spuriously) forwarding us our own channel_update.
7971 let as_node_one = nodes[0].node.get_our_node_id().serialize()[..] < nodes[1].node.get_our_node_id().serialize()[..];
7972 let as_update = if as_node_one == (chan.0.contents.flags & 1 == 0 /* chan.0 is from node one */) { &chan.0 } else { &chan.1 };
7973 let bs_update = if as_node_one == (chan.0.contents.flags & 1 == 0 /* chan.0 is from node one */) { &chan.1 } else { &chan.0 };
7975 // First deliver each peers' own message, checking that the node doesn't need to be
7976 // persisted and that its channel info remains the same.
7977 nodes[0].node.handle_channel_update(&nodes[1].node.get_our_node_id(), &as_update);
7978 nodes[1].node.handle_channel_update(&nodes[0].node.get_our_node_id(), &bs_update);
7979 assert!(!nodes[0].node.await_persistable_update_timeout(Duration::from_millis(1)));
7980 assert!(!nodes[1].node.await_persistable_update_timeout(Duration::from_millis(1)));
7981 assert_eq!(nodes[0].node.list_channels()[0], node_a_chan_info);
7982 assert_eq!(nodes[1].node.list_channels()[0], node_b_chan_info);
7984 // Finally, deliver the other peers' message, ensuring each node needs to be persisted and
7985 // the channel info has updated.
7986 nodes[0].node.handle_channel_update(&nodes[1].node.get_our_node_id(), &bs_update);
7987 nodes[1].node.handle_channel_update(&nodes[0].node.get_our_node_id(), &as_update);
7988 assert!(nodes[0].node.await_persistable_update_timeout(Duration::from_millis(1)));
7989 assert!(nodes[1].node.await_persistable_update_timeout(Duration::from_millis(1)));
7990 assert_ne!(nodes[0].node.list_channels()[0], node_a_chan_info);
7991 assert_ne!(nodes[1].node.list_channels()[0], node_b_chan_info);
7995 fn test_keysend_dup_hash_partial_mpp() {
7996 // Test that a keysend payment with a duplicate hash to an existing partial MPP payment fails as
7998 let chanmon_cfgs = create_chanmon_cfgs(2);
7999 let node_cfgs = create_node_cfgs(2, &chanmon_cfgs);
8000 let node_chanmgrs = create_node_chanmgrs(2, &node_cfgs, &[None, None]);
8001 let nodes = create_network(2, &node_cfgs, &node_chanmgrs);
8002 create_announced_chan_between_nodes(&nodes, 0, 1);
8004 // First, send a partial MPP payment.
8005 let (route, our_payment_hash, payment_preimage, payment_secret) = get_route_and_payment_hash!(&nodes[0], nodes[1], 100_000);
8006 let mut mpp_route = route.clone();
8007 mpp_route.paths.push(mpp_route.paths[0].clone());
8009 let payment_id = PaymentId([42; 32]);
8010 // Use the utility function send_payment_along_path to send the payment with MPP data which
8011 // indicates there are more HTLCs coming.
8012 let cur_height = CHAN_CONFIRM_DEPTH + 1; // route_payment calls send_payment, which adds 1 to the current height. So we do the same here to match.
8013 let session_privs = nodes[0].node.test_add_new_pending_payment(our_payment_hash, Some(payment_secret), payment_id, &mpp_route).unwrap();
8014 nodes[0].node.test_send_payment_along_path(&mpp_route.paths[0], &our_payment_hash, &Some(payment_secret), 200_000, cur_height, payment_id, &None, session_privs[0]).unwrap();
8015 check_added_monitors!(nodes[0], 1);
8016 let mut events = nodes[0].node.get_and_clear_pending_msg_events();
8017 assert_eq!(events.len(), 1);
8018 pass_along_path(&nodes[0], &[&nodes[1]], 200_000, our_payment_hash, Some(payment_secret), events.drain(..).next().unwrap(), false, None);
8020 // Next, send a keysend payment with the same payment_hash and make sure it fails.
8021 nodes[0].node.send_spontaneous_payment(&route, Some(payment_preimage), PaymentId(payment_preimage.0)).unwrap();
8022 check_added_monitors!(nodes[0], 1);
8023 let mut events = nodes[0].node.get_and_clear_pending_msg_events();
8024 assert_eq!(events.len(), 1);
8025 let ev = events.drain(..).next().unwrap();
8026 let payment_event = SendEvent::from_event(ev);
8027 nodes[1].node.handle_update_add_htlc(&nodes[0].node.get_our_node_id(), &payment_event.msgs[0]);
8028 check_added_monitors!(nodes[1], 0);
8029 commitment_signed_dance!(nodes[1], nodes[0], payment_event.commitment_msg, false);
8030 expect_pending_htlcs_forwardable!(nodes[1]);
8031 expect_pending_htlcs_forwardable_and_htlc_handling_failed!(nodes[1], vec![HTLCDestination::FailedPayment { payment_hash: our_payment_hash }]);
8032 check_added_monitors!(nodes[1], 1);
8033 let updates = get_htlc_update_msgs!(nodes[1], nodes[0].node.get_our_node_id());
8034 assert!(updates.update_add_htlcs.is_empty());
8035 assert!(updates.update_fulfill_htlcs.is_empty());
8036 assert_eq!(updates.update_fail_htlcs.len(), 1);
8037 assert!(updates.update_fail_malformed_htlcs.is_empty());
8038 assert!(updates.update_fee.is_none());
8039 nodes[0].node.handle_update_fail_htlc(&nodes[1].node.get_our_node_id(), &updates.update_fail_htlcs[0]);
8040 commitment_signed_dance!(nodes[0], nodes[1], updates.commitment_signed, true, true);
8041 expect_payment_failed!(nodes[0], our_payment_hash, true);
8043 // Send the second half of the original MPP payment.
8044 nodes[0].node.test_send_payment_along_path(&mpp_route.paths[1], &our_payment_hash, &Some(payment_secret), 200_000, cur_height, payment_id, &None, session_privs[1]).unwrap();
8045 check_added_monitors!(nodes[0], 1);
8046 let mut events = nodes[0].node.get_and_clear_pending_msg_events();
8047 assert_eq!(events.len(), 1);
8048 pass_along_path(&nodes[0], &[&nodes[1]], 200_000, our_payment_hash, Some(payment_secret), events.drain(..).next().unwrap(), true, None);
8050 // Claim the full MPP payment. Note that we can't use a test utility like
8051 // claim_funds_along_route because the ordering of the messages causes the second half of the
8052 // payment to be put in the holding cell, which confuses the test utilities. So we exchange the
8053 // lightning messages manually.
8054 nodes[1].node.claim_funds(payment_preimage);
8055 expect_payment_claimed!(nodes[1], our_payment_hash, 200_000);
8056 check_added_monitors!(nodes[1], 2);
8058 let bs_first_updates = get_htlc_update_msgs!(nodes[1], nodes[0].node.get_our_node_id());
8059 nodes[0].node.handle_update_fulfill_htlc(&nodes[1].node.get_our_node_id(), &bs_first_updates.update_fulfill_htlcs[0]);
8060 nodes[0].node.handle_commitment_signed(&nodes[1].node.get_our_node_id(), &bs_first_updates.commitment_signed);
8061 check_added_monitors!(nodes[0], 1);
8062 let (as_first_raa, as_first_cs) = get_revoke_commit_msgs!(nodes[0], nodes[1].node.get_our_node_id());
8063 nodes[1].node.handle_revoke_and_ack(&nodes[0].node.get_our_node_id(), &as_first_raa);
8064 check_added_monitors!(nodes[1], 1);
8065 let bs_second_updates = get_htlc_update_msgs!(nodes[1], nodes[0].node.get_our_node_id());
8066 nodes[1].node.handle_commitment_signed(&nodes[0].node.get_our_node_id(), &as_first_cs);
8067 check_added_monitors!(nodes[1], 1);
8068 let bs_first_raa = get_event_msg!(nodes[1], MessageSendEvent::SendRevokeAndACK, nodes[0].node.get_our_node_id());
8069 nodes[0].node.handle_update_fulfill_htlc(&nodes[1].node.get_our_node_id(), &bs_second_updates.update_fulfill_htlcs[0]);
8070 nodes[0].node.handle_commitment_signed(&nodes[1].node.get_our_node_id(), &bs_second_updates.commitment_signed);
8071 check_added_monitors!(nodes[0], 1);
8072 let as_second_raa = get_event_msg!(nodes[0], MessageSendEvent::SendRevokeAndACK, nodes[1].node.get_our_node_id());
8073 nodes[0].node.handle_revoke_and_ack(&nodes[1].node.get_our_node_id(), &bs_first_raa);
8074 let as_second_updates = get_htlc_update_msgs!(nodes[0], nodes[1].node.get_our_node_id());
8075 check_added_monitors!(nodes[0], 1);
8076 nodes[1].node.handle_revoke_and_ack(&nodes[0].node.get_our_node_id(), &as_second_raa);
8077 check_added_monitors!(nodes[1], 1);
8078 nodes[1].node.handle_commitment_signed(&nodes[0].node.get_our_node_id(), &as_second_updates.commitment_signed);
8079 check_added_monitors!(nodes[1], 1);
8080 let bs_third_raa = get_event_msg!(nodes[1], MessageSendEvent::SendRevokeAndACK, nodes[0].node.get_our_node_id());
8081 nodes[0].node.handle_revoke_and_ack(&nodes[1].node.get_our_node_id(), &bs_third_raa);
8082 check_added_monitors!(nodes[0], 1);
8084 // Note that successful MPP payments will generate a single PaymentSent event upon the first
8085 // path's success and a PaymentPathSuccessful event for each path's success.
8086 let events = nodes[0].node.get_and_clear_pending_events();
8087 assert_eq!(events.len(), 3);
8089 Event::PaymentSent { payment_id: ref id, payment_preimage: ref preimage, payment_hash: ref hash, .. } => {
8090 assert_eq!(Some(payment_id), *id);
8091 assert_eq!(payment_preimage, *preimage);
8092 assert_eq!(our_payment_hash, *hash);
8094 _ => panic!("Unexpected event"),
8097 Event::PaymentPathSuccessful { payment_id: ref actual_payment_id, ref payment_hash, ref path } => {
8098 assert_eq!(payment_id, *actual_payment_id);
8099 assert_eq!(our_payment_hash, *payment_hash.as_ref().unwrap());
8100 assert_eq!(route.paths[0], *path);
8102 _ => panic!("Unexpected event"),
8105 Event::PaymentPathSuccessful { payment_id: ref actual_payment_id, ref payment_hash, ref path } => {
8106 assert_eq!(payment_id, *actual_payment_id);
8107 assert_eq!(our_payment_hash, *payment_hash.as_ref().unwrap());
8108 assert_eq!(route.paths[0], *path);
8110 _ => panic!("Unexpected event"),
8115 fn test_keysend_dup_payment_hash() {
8116 // (1): Test that a keysend payment with a duplicate payment hash to an existing pending
8117 // outbound regular payment fails as expected.
8118 // (2): Test that a regular payment with a duplicate payment hash to an existing keysend payment
8119 // fails as expected.
8120 let chanmon_cfgs = create_chanmon_cfgs(2);
8121 let node_cfgs = create_node_cfgs(2, &chanmon_cfgs);
8122 let node_chanmgrs = create_node_chanmgrs(2, &node_cfgs, &[None, None]);
8123 let nodes = create_network(2, &node_cfgs, &node_chanmgrs);
8124 create_announced_chan_between_nodes(&nodes, 0, 1);
8125 let scorer = test_utils::TestScorer::new();
8126 let random_seed_bytes = chanmon_cfgs[1].keys_manager.get_secure_random_bytes();
8128 // To start (1), send a regular payment but don't claim it.
8129 let expected_route = [&nodes[1]];
8130 let (payment_preimage, payment_hash, _) = route_payment(&nodes[0], &expected_route, 100_000);
8132 // Next, attempt a keysend payment and make sure it fails.
8133 let route_params = RouteParameters {
8134 payment_params: PaymentParameters::for_keysend(expected_route.last().unwrap().node.get_our_node_id(), TEST_FINAL_CLTV),
8135 final_value_msat: 100_000,
8137 let route = find_route(
8138 &nodes[0].node.get_our_node_id(), &route_params, &nodes[0].network_graph,
8139 None, nodes[0].logger, &scorer, &random_seed_bytes
8141 nodes[0].node.send_spontaneous_payment(&route, Some(payment_preimage), PaymentId(payment_preimage.0)).unwrap();
8142 check_added_monitors!(nodes[0], 1);
8143 let mut events = nodes[0].node.get_and_clear_pending_msg_events();
8144 assert_eq!(events.len(), 1);
8145 let ev = events.drain(..).next().unwrap();
8146 let payment_event = SendEvent::from_event(ev);
8147 nodes[1].node.handle_update_add_htlc(&nodes[0].node.get_our_node_id(), &payment_event.msgs[0]);
8148 check_added_monitors!(nodes[1], 0);
8149 commitment_signed_dance!(nodes[1], nodes[0], payment_event.commitment_msg, false);
8150 // We have to forward pending HTLCs twice - once tries to forward the payment forward (and
8151 // fails), the second will process the resulting failure and fail the HTLC backward
8152 expect_pending_htlcs_forwardable!(nodes[1]);
8153 expect_pending_htlcs_forwardable_and_htlc_handling_failed!(nodes[1], vec![HTLCDestination::FailedPayment { payment_hash }]);
8154 check_added_monitors!(nodes[1], 1);
8155 let updates = get_htlc_update_msgs!(nodes[1], nodes[0].node.get_our_node_id());
8156 assert!(updates.update_add_htlcs.is_empty());
8157 assert!(updates.update_fulfill_htlcs.is_empty());
8158 assert_eq!(updates.update_fail_htlcs.len(), 1);
8159 assert!(updates.update_fail_malformed_htlcs.is_empty());
8160 assert!(updates.update_fee.is_none());
8161 nodes[0].node.handle_update_fail_htlc(&nodes[1].node.get_our_node_id(), &updates.update_fail_htlcs[0]);
8162 commitment_signed_dance!(nodes[0], nodes[1], updates.commitment_signed, true, true);
8163 expect_payment_failed!(nodes[0], payment_hash, true);
8165 // Finally, claim the original payment.
8166 claim_payment(&nodes[0], &expected_route, payment_preimage);
8168 // To start (2), send a keysend payment but don't claim it.
8169 let payment_preimage = PaymentPreimage([42; 32]);
8170 let route = find_route(
8171 &nodes[0].node.get_our_node_id(), &route_params, &nodes[0].network_graph,
8172 None, nodes[0].logger, &scorer, &random_seed_bytes
8174 let payment_hash = nodes[0].node.send_spontaneous_payment(&route, Some(payment_preimage), PaymentId(payment_preimage.0)).unwrap();
8175 check_added_monitors!(nodes[0], 1);
8176 let mut events = nodes[0].node.get_and_clear_pending_msg_events();
8177 assert_eq!(events.len(), 1);
8178 let event = events.pop().unwrap();
8179 let path = vec![&nodes[1]];
8180 pass_along_path(&nodes[0], &path, 100_000, payment_hash, None, event, true, Some(payment_preimage));
8182 // Next, attempt a regular payment and make sure it fails.
8183 let payment_secret = PaymentSecret([43; 32]);
8184 nodes[0].node.send_payment(&route, payment_hash, &Some(payment_secret), PaymentId(payment_hash.0)).unwrap();
8185 check_added_monitors!(nodes[0], 1);
8186 let mut events = nodes[0].node.get_and_clear_pending_msg_events();
8187 assert_eq!(events.len(), 1);
8188 let ev = events.drain(..).next().unwrap();
8189 let payment_event = SendEvent::from_event(ev);
8190 nodes[1].node.handle_update_add_htlc(&nodes[0].node.get_our_node_id(), &payment_event.msgs[0]);
8191 check_added_monitors!(nodes[1], 0);
8192 commitment_signed_dance!(nodes[1], nodes[0], payment_event.commitment_msg, false);
8193 expect_pending_htlcs_forwardable!(nodes[1]);
8194 expect_pending_htlcs_forwardable_and_htlc_handling_failed!(nodes[1], vec![HTLCDestination::FailedPayment { payment_hash }]);
8195 check_added_monitors!(nodes[1], 1);
8196 let updates = get_htlc_update_msgs!(nodes[1], nodes[0].node.get_our_node_id());
8197 assert!(updates.update_add_htlcs.is_empty());
8198 assert!(updates.update_fulfill_htlcs.is_empty());
8199 assert_eq!(updates.update_fail_htlcs.len(), 1);
8200 assert!(updates.update_fail_malformed_htlcs.is_empty());
8201 assert!(updates.update_fee.is_none());
8202 nodes[0].node.handle_update_fail_htlc(&nodes[1].node.get_our_node_id(), &updates.update_fail_htlcs[0]);
8203 commitment_signed_dance!(nodes[0], nodes[1], updates.commitment_signed, true, true);
8204 expect_payment_failed!(nodes[0], payment_hash, true);
8206 // Finally, succeed the keysend payment.
8207 claim_payment(&nodes[0], &expected_route, payment_preimage);
8211 fn test_keysend_hash_mismatch() {
8212 // Test that if we receive a keysend `update_add_htlc` msg, we fail as expected if the keysend
8213 // preimage doesn't match the msg's payment hash.
8214 let chanmon_cfgs = create_chanmon_cfgs(2);
8215 let node_cfgs = create_node_cfgs(2, &chanmon_cfgs);
8216 let node_chanmgrs = create_node_chanmgrs(2, &node_cfgs, &[None, None]);
8217 let nodes = create_network(2, &node_cfgs, &node_chanmgrs);
8219 let payer_pubkey = nodes[0].node.get_our_node_id();
8220 let payee_pubkey = nodes[1].node.get_our_node_id();
8222 let _chan = create_chan_between_nodes(&nodes[0], &nodes[1]);
8223 let route_params = RouteParameters {
8224 payment_params: PaymentParameters::for_keysend(payee_pubkey, 40),
8225 final_value_msat: 10_000,
8227 let network_graph = nodes[0].network_graph.clone();
8228 let first_hops = nodes[0].node.list_usable_channels();
8229 let scorer = test_utils::TestScorer::new();
8230 let random_seed_bytes = chanmon_cfgs[1].keys_manager.get_secure_random_bytes();
8231 let route = find_route(
8232 &payer_pubkey, &route_params, &network_graph, Some(&first_hops.iter().collect::<Vec<_>>()),
8233 nodes[0].logger, &scorer, &random_seed_bytes
8236 let test_preimage = PaymentPreimage([42; 32]);
8237 let mismatch_payment_hash = PaymentHash([43; 32]);
8238 let session_privs = nodes[0].node.test_add_new_pending_payment(mismatch_payment_hash, None, PaymentId(mismatch_payment_hash.0), &route).unwrap();
8239 nodes[0].node.test_send_payment_internal(&route, mismatch_payment_hash, &None, Some(test_preimage), PaymentId(mismatch_payment_hash.0), None, session_privs).unwrap();
8240 check_added_monitors!(nodes[0], 1);
8242 let updates = get_htlc_update_msgs!(nodes[0], nodes[1].node.get_our_node_id());
8243 assert_eq!(updates.update_add_htlcs.len(), 1);
8244 assert!(updates.update_fulfill_htlcs.is_empty());
8245 assert!(updates.update_fail_htlcs.is_empty());
8246 assert!(updates.update_fail_malformed_htlcs.is_empty());
8247 assert!(updates.update_fee.is_none());
8248 nodes[1].node.handle_update_add_htlc(&nodes[0].node.get_our_node_id(), &updates.update_add_htlcs[0]);
8250 nodes[1].logger.assert_log_contains("lightning::ln::channelmanager", "Payment preimage didn't match payment hash", 1);
8254 fn test_keysend_msg_with_secret_err() {
8255 // Test that we error as expected if we receive a keysend payment that includes a payment secret.
8256 let chanmon_cfgs = create_chanmon_cfgs(2);
8257 let node_cfgs = create_node_cfgs(2, &chanmon_cfgs);
8258 let node_chanmgrs = create_node_chanmgrs(2, &node_cfgs, &[None, None]);
8259 let nodes = create_network(2, &node_cfgs, &node_chanmgrs);
8261 let payer_pubkey = nodes[0].node.get_our_node_id();
8262 let payee_pubkey = nodes[1].node.get_our_node_id();
8264 let _chan = create_chan_between_nodes(&nodes[0], &nodes[1]);
8265 let route_params = RouteParameters {
8266 payment_params: PaymentParameters::for_keysend(payee_pubkey, 40),
8267 final_value_msat: 10_000,
8269 let network_graph = nodes[0].network_graph.clone();
8270 let first_hops = nodes[0].node.list_usable_channels();
8271 let scorer = test_utils::TestScorer::new();
8272 let random_seed_bytes = chanmon_cfgs[1].keys_manager.get_secure_random_bytes();
8273 let route = find_route(
8274 &payer_pubkey, &route_params, &network_graph, Some(&first_hops.iter().collect::<Vec<_>>()),
8275 nodes[0].logger, &scorer, &random_seed_bytes
8278 let test_preimage = PaymentPreimage([42; 32]);
8279 let test_secret = PaymentSecret([43; 32]);
8280 let payment_hash = PaymentHash(Sha256::hash(&test_preimage.0).into_inner());
8281 let session_privs = nodes[0].node.test_add_new_pending_payment(payment_hash, Some(test_secret), PaymentId(payment_hash.0), &route).unwrap();
8282 nodes[0].node.test_send_payment_internal(&route, payment_hash, &Some(test_secret), Some(test_preimage), PaymentId(payment_hash.0), None, session_privs).unwrap();
8283 check_added_monitors!(nodes[0], 1);
8285 let updates = get_htlc_update_msgs!(nodes[0], nodes[1].node.get_our_node_id());
8286 assert_eq!(updates.update_add_htlcs.len(), 1);
8287 assert!(updates.update_fulfill_htlcs.is_empty());
8288 assert!(updates.update_fail_htlcs.is_empty());
8289 assert!(updates.update_fail_malformed_htlcs.is_empty());
8290 assert!(updates.update_fee.is_none());
8291 nodes[1].node.handle_update_add_htlc(&nodes[0].node.get_our_node_id(), &updates.update_add_htlcs[0]);
8293 nodes[1].logger.assert_log_contains("lightning::ln::channelmanager", "We don't support MPP keysend payments", 1);
8297 fn test_multi_hop_missing_secret() {
8298 let chanmon_cfgs = create_chanmon_cfgs(4);
8299 let node_cfgs = create_node_cfgs(4, &chanmon_cfgs);
8300 let node_chanmgrs = create_node_chanmgrs(4, &node_cfgs, &[None, None, None, None]);
8301 let nodes = create_network(4, &node_cfgs, &node_chanmgrs);
8303 let chan_1_id = create_announced_chan_between_nodes(&nodes, 0, 1).0.contents.short_channel_id;
8304 let chan_2_id = create_announced_chan_between_nodes(&nodes, 0, 2).0.contents.short_channel_id;
8305 let chan_3_id = create_announced_chan_between_nodes(&nodes, 1, 3).0.contents.short_channel_id;
8306 let chan_4_id = create_announced_chan_between_nodes(&nodes, 2, 3).0.contents.short_channel_id;
8308 // Marshall an MPP route.
8309 let (mut route, payment_hash, _, _) = get_route_and_payment_hash!(&nodes[0], nodes[3], 100000);
8310 let path = route.paths[0].clone();
8311 route.paths.push(path);
8312 route.paths[0][0].pubkey = nodes[1].node.get_our_node_id();
8313 route.paths[0][0].short_channel_id = chan_1_id;
8314 route.paths[0][1].short_channel_id = chan_3_id;
8315 route.paths[1][0].pubkey = nodes[2].node.get_our_node_id();
8316 route.paths[1][0].short_channel_id = chan_2_id;
8317 route.paths[1][1].short_channel_id = chan_4_id;
8319 match nodes[0].node.send_payment(&route, payment_hash, &None, PaymentId(payment_hash.0)).unwrap_err() {
8320 PaymentSendFailure::ParameterError(APIError::APIMisuseError { ref err }) => {
8321 assert!(regex::Regex::new(r"Payment secret is required for multi-path payments").unwrap().is_match(err))
8323 _ => panic!("unexpected error")
8328 fn test_drop_disconnected_peers_when_removing_channels() {
8329 let chanmon_cfgs = create_chanmon_cfgs(2);
8330 let node_cfgs = create_node_cfgs(2, &chanmon_cfgs);
8331 let node_chanmgrs = create_node_chanmgrs(2, &node_cfgs, &[None, None]);
8332 let nodes = create_network(2, &node_cfgs, &node_chanmgrs);
8334 let chan = create_announced_chan_between_nodes(&nodes, 0, 1);
8336 nodes[0].node.peer_disconnected(&nodes[1].node.get_our_node_id());
8337 nodes[1].node.peer_disconnected(&nodes[0].node.get_our_node_id());
8339 nodes[0].node.force_close_broadcasting_latest_txn(&chan.2, &nodes[1].node.get_our_node_id()).unwrap();
8340 check_closed_broadcast!(nodes[0], true);
8341 check_added_monitors!(nodes[0], 1);
8342 check_closed_event!(nodes[0], 1, ClosureReason::HolderForceClosed);
8345 // Assert that nodes[1] is awaiting removal for nodes[0] once nodes[1] has been
8346 // disconnected and the channel between has been force closed.
8347 let nodes_0_per_peer_state = nodes[0].node.per_peer_state.read().unwrap();
8348 // Assert that nodes[1] isn't removed before `timer_tick_occurred` has been executed.
8349 assert_eq!(nodes_0_per_peer_state.len(), 1);
8350 assert!(nodes_0_per_peer_state.get(&nodes[1].node.get_our_node_id()).is_some());
8353 nodes[0].node.timer_tick_occurred();
8356 // Assert that nodes[1] has now been removed.
8357 assert_eq!(nodes[0].node.per_peer_state.read().unwrap().len(), 0);
8362 fn bad_inbound_payment_hash() {
8363 // Add coverage for checking that a user-provided payment hash matches the payment secret.
8364 let chanmon_cfgs = create_chanmon_cfgs(2);
8365 let node_cfgs = create_node_cfgs(2, &chanmon_cfgs);
8366 let node_chanmgrs = create_node_chanmgrs(2, &node_cfgs, &[None, None]);
8367 let nodes = create_network(2, &node_cfgs, &node_chanmgrs);
8369 let (_, payment_hash, payment_secret) = get_payment_preimage_hash!(&nodes[0]);
8370 let payment_data = msgs::FinalOnionHopData {
8372 total_msat: 100_000,
8375 // Ensure that if the payment hash given to `inbound_payment::verify` differs from the original,
8376 // payment verification fails as expected.
8377 let mut bad_payment_hash = payment_hash.clone();
8378 bad_payment_hash.0[0] += 1;
8379 match inbound_payment::verify(bad_payment_hash, &payment_data, nodes[0].node.highest_seen_timestamp.load(Ordering::Acquire) as u64, &nodes[0].node.inbound_payment_key, &nodes[0].logger) {
8380 Ok(_) => panic!("Unexpected ok"),
8382 nodes[0].logger.assert_log_contains("lightning::ln::inbound_payment", "Failing HTLC with user-generated payment_hash", 1);
8386 // Check that using the original payment hash succeeds.
8387 assert!(inbound_payment::verify(payment_hash, &payment_data, nodes[0].node.highest_seen_timestamp.load(Ordering::Acquire) as u64, &nodes[0].node.inbound_payment_key, &nodes[0].logger).is_ok());
8391 fn test_id_to_peer_coverage() {
8392 // Test that the `ChannelManager:id_to_peer` contains channels which have been assigned
8393 // a `channel_id` (i.e. have had the funding tx created), and that they are removed once
8394 // the channel is successfully closed.
8395 let chanmon_cfgs = create_chanmon_cfgs(2);
8396 let node_cfgs = create_node_cfgs(2, &chanmon_cfgs);
8397 let node_chanmgrs = create_node_chanmgrs(2, &node_cfgs, &[None, None]);
8398 let nodes = create_network(2, &node_cfgs, &node_chanmgrs);
8400 nodes[0].node.create_channel(nodes[1].node.get_our_node_id(), 1_000_000, 500_000_000, 42, None).unwrap();
8401 let open_channel = get_event_msg!(nodes[0], MessageSendEvent::SendOpenChannel, nodes[1].node.get_our_node_id());
8402 nodes[1].node.handle_open_channel(&nodes[0].node.get_our_node_id(), &open_channel);
8403 let accept_channel = get_event_msg!(nodes[1], MessageSendEvent::SendAcceptChannel, nodes[0].node.get_our_node_id());
8404 nodes[0].node.handle_accept_channel(&nodes[1].node.get_our_node_id(), &accept_channel);
8406 let (temporary_channel_id, tx, _funding_output) = create_funding_transaction(&nodes[0], &nodes[1].node.get_our_node_id(), 1_000_000, 42);
8407 let channel_id = &tx.txid().into_inner();
8409 // Ensure that the `id_to_peer` map is empty until either party has received the
8410 // funding transaction, and have the real `channel_id`.
8411 assert_eq!(nodes[0].node.id_to_peer.lock().unwrap().len(), 0);
8412 assert_eq!(nodes[1].node.id_to_peer.lock().unwrap().len(), 0);
8415 nodes[0].node.funding_transaction_generated(&temporary_channel_id, &nodes[1].node.get_our_node_id(), tx.clone()).unwrap();
8417 // Assert that `nodes[0]`'s `id_to_peer` map is populated with the channel as soon as
8418 // as it has the funding transaction.
8419 let nodes_0_lock = nodes[0].node.id_to_peer.lock().unwrap();
8420 assert_eq!(nodes_0_lock.len(), 1);
8421 assert!(nodes_0_lock.contains_key(channel_id));
8424 assert_eq!(nodes[1].node.id_to_peer.lock().unwrap().len(), 0);
8426 let funding_created_msg = get_event_msg!(nodes[0], MessageSendEvent::SendFundingCreated, nodes[1].node.get_our_node_id());
8428 nodes[1].node.handle_funding_created(&nodes[0].node.get_our_node_id(), &funding_created_msg);
8430 let nodes_0_lock = nodes[0].node.id_to_peer.lock().unwrap();
8431 assert_eq!(nodes_0_lock.len(), 1);
8432 assert!(nodes_0_lock.contains_key(channel_id));
8436 // Assert that `nodes[1]`'s `id_to_peer` map is populated with the channel as soon as
8437 // as it has the funding transaction.
8438 let nodes_1_lock = nodes[1].node.id_to_peer.lock().unwrap();
8439 assert_eq!(nodes_1_lock.len(), 1);
8440 assert!(nodes_1_lock.contains_key(channel_id));
8442 check_added_monitors!(nodes[1], 1);
8443 let funding_signed = get_event_msg!(nodes[1], MessageSendEvent::SendFundingSigned, nodes[0].node.get_our_node_id());
8444 nodes[0].node.handle_funding_signed(&nodes[1].node.get_our_node_id(), &funding_signed);
8445 check_added_monitors!(nodes[0], 1);
8446 let (channel_ready, _) = create_chan_between_nodes_with_value_confirm(&nodes[0], &nodes[1], &tx);
8447 let (announcement, nodes_0_update, nodes_1_update) = create_chan_between_nodes_with_value_b(&nodes[0], &nodes[1], &channel_ready);
8448 update_nodes_with_chan_announce(&nodes, 0, 1, &announcement, &nodes_0_update, &nodes_1_update);
8450 nodes[0].node.close_channel(channel_id, &nodes[1].node.get_our_node_id()).unwrap();
8451 nodes[1].node.handle_shutdown(&nodes[0].node.get_our_node_id(), &get_event_msg!(nodes[0], MessageSendEvent::SendShutdown, nodes[1].node.get_our_node_id()));
8452 let nodes_1_shutdown = get_event_msg!(nodes[1], MessageSendEvent::SendShutdown, nodes[0].node.get_our_node_id());
8453 nodes[0].node.handle_shutdown(&nodes[1].node.get_our_node_id(), &nodes_1_shutdown);
8455 let closing_signed_node_0 = get_event_msg!(nodes[0], MessageSendEvent::SendClosingSigned, nodes[1].node.get_our_node_id());
8456 nodes[1].node.handle_closing_signed(&nodes[0].node.get_our_node_id(), &closing_signed_node_0);
8458 // Assert that the channel is kept in the `id_to_peer` map for both nodes until the
8459 // channel can be fully closed by both parties (i.e. no outstanding htlcs exists, the
8460 // fee for the closing transaction has been negotiated and the parties has the other
8461 // party's signature for the fee negotiated closing transaction.)
8462 let nodes_0_lock = nodes[0].node.id_to_peer.lock().unwrap();
8463 assert_eq!(nodes_0_lock.len(), 1);
8464 assert!(nodes_0_lock.contains_key(channel_id));
8468 // At this stage, `nodes[1]` has proposed a fee for the closing transaction in the
8469 // `handle_closing_signed` call above. As `nodes[1]` has not yet received the signature
8470 // from `nodes[0]` for the closing transaction with the proposed fee, the channel is
8471 // kept in the `nodes[1]`'s `id_to_peer` map.
8472 let nodes_1_lock = nodes[1].node.id_to_peer.lock().unwrap();
8473 assert_eq!(nodes_1_lock.len(), 1);
8474 assert!(nodes_1_lock.contains_key(channel_id));
8477 nodes[0].node.handle_closing_signed(&nodes[1].node.get_our_node_id(), &get_event_msg!(nodes[1], MessageSendEvent::SendClosingSigned, nodes[0].node.get_our_node_id()));
8479 // `nodes[0]` accepts `nodes[1]`'s proposed fee for the closing transaction, and
8480 // therefore has all it needs to fully close the channel (both signatures for the
8481 // closing transaction).
8482 // Assert that the channel is removed from `nodes[0]`'s `id_to_peer` map as it can be
8483 // fully closed by `nodes[0]`.
8484 assert_eq!(nodes[0].node.id_to_peer.lock().unwrap().len(), 0);
8486 // Assert that the channel is still in `nodes[1]`'s `id_to_peer` map, as `nodes[1]`
8487 // doesn't have `nodes[0]`'s signature for the closing transaction yet.
8488 let nodes_1_lock = nodes[1].node.id_to_peer.lock().unwrap();
8489 assert_eq!(nodes_1_lock.len(), 1);
8490 assert!(nodes_1_lock.contains_key(channel_id));
8493 let (_nodes_0_update, closing_signed_node_0) = get_closing_signed_broadcast!(nodes[0].node, nodes[1].node.get_our_node_id());
8495 nodes[1].node.handle_closing_signed(&nodes[0].node.get_our_node_id(), &closing_signed_node_0.unwrap());
8497 // Assert that the channel has now been removed from both parties `id_to_peer` map once
8498 // they both have everything required to fully close the channel.
8499 assert_eq!(nodes[1].node.id_to_peer.lock().unwrap().len(), 0);
8501 let (_nodes_1_update, _none) = get_closing_signed_broadcast!(nodes[1].node, nodes[0].node.get_our_node_id());
8503 check_closed_event!(nodes[0], 1, ClosureReason::CooperativeClosure);
8504 check_closed_event!(nodes[1], 1, ClosureReason::CooperativeClosure);
8507 fn check_not_connected_to_peer_error<T>(res_err: Result<T, APIError>, expected_public_key: PublicKey) {
8508 let expected_message = format!("Not connected to node: {}", expected_public_key);
8509 check_api_error_message(expected_message, res_err)
8512 fn check_unkown_peer_error<T>(res_err: Result<T, APIError>, expected_public_key: PublicKey) {
8513 let expected_message = format!("Can't find a peer matching the passed counterparty node_id {}", expected_public_key);
8514 check_api_error_message(expected_message, res_err)
8517 fn check_api_error_message<T>(expected_err_message: String, res_err: Result<T, APIError>) {
8519 Err(APIError::APIMisuseError { err }) => {
8520 assert_eq!(err, expected_err_message);
8522 Err(APIError::ChannelUnavailable { err }) => {
8523 assert_eq!(err, expected_err_message);
8525 Ok(_) => panic!("Unexpected Ok"),
8526 Err(_) => panic!("Unexpected Error"),
8531 fn test_api_calls_with_unkown_counterparty_node() {
8532 // Tests that our API functions that expects a `counterparty_node_id` as input, behaves as
8533 // expected if the `counterparty_node_id` is an unkown peer in the
8534 // `ChannelManager::per_peer_state` map.
8535 let chanmon_cfg = create_chanmon_cfgs(2);
8536 let node_cfg = create_node_cfgs(2, &chanmon_cfg);
8537 let node_chanmgr = create_node_chanmgrs(2, &node_cfg, &[None, None]);
8538 let nodes = create_network(2, &node_cfg, &node_chanmgr);
8541 let channel_id = [4; 32];
8542 let unkown_public_key = PublicKey::from_secret_key(&Secp256k1::signing_only(), &SecretKey::from_slice(&[42; 32]).unwrap());
8543 let intercept_id = InterceptId([0; 32]);
8545 // Test the API functions.
8546 check_not_connected_to_peer_error(nodes[0].node.create_channel(unkown_public_key, 1_000_000, 500_000_000, 42, None), unkown_public_key);
8548 check_unkown_peer_error(nodes[0].node.accept_inbound_channel(&channel_id, &unkown_public_key, 42), unkown_public_key);
8550 check_unkown_peer_error(nodes[0].node.close_channel(&channel_id, &unkown_public_key), unkown_public_key);
8552 check_unkown_peer_error(nodes[0].node.force_close_broadcasting_latest_txn(&channel_id, &unkown_public_key), unkown_public_key);
8554 check_unkown_peer_error(nodes[0].node.force_close_without_broadcasting_txn(&channel_id, &unkown_public_key), unkown_public_key);
8556 check_unkown_peer_error(nodes[0].node.forward_intercepted_htlc(intercept_id, &channel_id, unkown_public_key, 1_000_000), unkown_public_key);
8558 check_unkown_peer_error(nodes[0].node.update_channel_config(&unkown_public_key, &[channel_id], &ChannelConfig::default()), unkown_public_key);
8562 fn test_connection_limiting() {
8563 // Test that we limit un-channel'd peers and un-funded channels properly.
8564 let chanmon_cfgs = create_chanmon_cfgs(2);
8565 let node_cfgs = create_node_cfgs(2, &chanmon_cfgs);
8566 let node_chanmgrs = create_node_chanmgrs(2, &node_cfgs, &[None, None]);
8567 let nodes = create_network(2, &node_cfgs, &node_chanmgrs);
8569 // Note that create_network connects the nodes together for us
8571 nodes[0].node.create_channel(nodes[1].node.get_our_node_id(), 100_000, 0, 42, None).unwrap();
8572 let mut open_channel_msg = get_event_msg!(nodes[0], MessageSendEvent::SendOpenChannel, nodes[1].node.get_our_node_id());
8574 let mut funding_tx = None;
8575 for idx in 0..super::MAX_UNFUNDED_CHANS_PER_PEER {
8576 nodes[1].node.handle_open_channel(&nodes[0].node.get_our_node_id(), &open_channel_msg);
8577 let accept_channel = get_event_msg!(nodes[1], MessageSendEvent::SendAcceptChannel, nodes[0].node.get_our_node_id());
8580 nodes[0].node.handle_accept_channel(&nodes[1].node.get_our_node_id(), &accept_channel);
8581 let (temporary_channel_id, tx, _) = create_funding_transaction(&nodes[0], &nodes[1].node.get_our_node_id(), 100_000, 42);
8582 funding_tx = Some(tx.clone());
8583 nodes[0].node.funding_transaction_generated(&temporary_channel_id, &nodes[1].node.get_our_node_id(), tx).unwrap();
8584 let funding_created_msg = get_event_msg!(nodes[0], MessageSendEvent::SendFundingCreated, nodes[1].node.get_our_node_id());
8586 nodes[1].node.handle_funding_created(&nodes[0].node.get_our_node_id(), &funding_created_msg);
8587 check_added_monitors!(nodes[1], 1);
8588 let funding_signed = get_event_msg!(nodes[1], MessageSendEvent::SendFundingSigned, nodes[0].node.get_our_node_id());
8590 nodes[0].node.handle_funding_signed(&nodes[1].node.get_our_node_id(), &funding_signed);
8591 check_added_monitors!(nodes[0], 1);
8593 open_channel_msg.temporary_channel_id = nodes[0].keys_manager.get_secure_random_bytes();
8596 // A MAX_UNFUNDED_CHANS_PER_PEER + 1 channel will be summarily rejected
8597 open_channel_msg.temporary_channel_id = nodes[0].keys_manager.get_secure_random_bytes();
8598 nodes[1].node.handle_open_channel(&nodes[0].node.get_our_node_id(), &open_channel_msg);
8599 assert_eq!(get_err_msg(&nodes[1], &nodes[0].node.get_our_node_id()).channel_id,
8600 open_channel_msg.temporary_channel_id);
8602 // Further, because all of our channels with nodes[0] are inbound, and none of them funded,
8603 // it doesn't count as a "protected" peer, i.e. it counts towards the MAX_NO_CHANNEL_PEERS
8605 let mut peer_pks = Vec::with_capacity(super::MAX_NO_CHANNEL_PEERS);
8606 for _ in 1..super::MAX_NO_CHANNEL_PEERS {
8607 let random_pk = PublicKey::from_secret_key(&nodes[0].node.secp_ctx,
8608 &SecretKey::from_slice(&nodes[1].keys_manager.get_secure_random_bytes()).unwrap());
8609 peer_pks.push(random_pk);
8610 nodes[1].node.peer_connected(&random_pk, &msgs::Init {
8611 features: nodes[0].node.init_features(), remote_network_address: None }, true).unwrap();
8613 let last_random_pk = PublicKey::from_secret_key(&nodes[0].node.secp_ctx,
8614 &SecretKey::from_slice(&nodes[1].keys_manager.get_secure_random_bytes()).unwrap());
8615 nodes[1].node.peer_connected(&last_random_pk, &msgs::Init {
8616 features: nodes[0].node.init_features(), remote_network_address: None }, true).unwrap_err();
8618 // Also importantly, because nodes[0] isn't "protected", we will refuse a reconnection from
8619 // them if we have too many un-channel'd peers.
8620 nodes[1].node.peer_disconnected(&nodes[0].node.get_our_node_id());
8621 let chan_closed_events = nodes[1].node.get_and_clear_pending_events();
8622 assert_eq!(chan_closed_events.len(), super::MAX_UNFUNDED_CHANS_PER_PEER - 1);
8623 for ev in chan_closed_events {
8624 if let Event::ChannelClosed { .. } = ev { } else { panic!(); }
8626 nodes[1].node.peer_connected(&last_random_pk, &msgs::Init {
8627 features: nodes[0].node.init_features(), remote_network_address: None }, true).unwrap();
8628 nodes[1].node.peer_connected(&nodes[0].node.get_our_node_id(), &msgs::Init {
8629 features: nodes[0].node.init_features(), remote_network_address: None }, true).unwrap_err();
8631 // but of course if the connection is outbound its allowed...
8632 nodes[1].node.peer_connected(&nodes[0].node.get_our_node_id(), &msgs::Init {
8633 features: nodes[0].node.init_features(), remote_network_address: None }, false).unwrap();
8634 nodes[1].node.peer_disconnected(&nodes[0].node.get_our_node_id());
8636 // Now nodes[0] is disconnected but still has a pending, un-funded channel lying around.
8637 // Even though we accept one more connection from new peers, we won't actually let them
8639 assert!(peer_pks.len() > super::MAX_UNFUNDED_CHANNEL_PEERS - 1);
8640 for i in 0..super::MAX_UNFUNDED_CHANNEL_PEERS - 1 {
8641 nodes[1].node.handle_open_channel(&peer_pks[i], &open_channel_msg);
8642 get_event_msg!(nodes[1], MessageSendEvent::SendAcceptChannel, peer_pks[i]);
8643 open_channel_msg.temporary_channel_id = nodes[0].keys_manager.get_secure_random_bytes();
8645 nodes[1].node.handle_open_channel(&last_random_pk, &open_channel_msg);
8646 assert_eq!(get_err_msg(&nodes[1], &last_random_pk).channel_id,
8647 open_channel_msg.temporary_channel_id);
8649 // Of course, however, outbound channels are always allowed
8650 nodes[1].node.create_channel(last_random_pk, 100_000, 0, 42, None).unwrap();
8651 get_event_msg!(nodes[1], MessageSendEvent::SendOpenChannel, last_random_pk);
8653 // If we fund the first channel, nodes[0] has a live on-chain channel with us, it is now
8654 // "protected" and can connect again.
8655 mine_transaction(&nodes[1], funding_tx.as_ref().unwrap());
8656 nodes[1].node.peer_connected(&nodes[0].node.get_our_node_id(), &msgs::Init {
8657 features: nodes[0].node.init_features(), remote_network_address: None }, true).unwrap();
8658 get_event_msg!(nodes[1], MessageSendEvent::SendChannelReestablish, nodes[0].node.get_our_node_id());
8660 // Further, because the first channel was funded, we can open another channel with
8662 nodes[1].node.handle_open_channel(&last_random_pk, &open_channel_msg);
8663 get_event_msg!(nodes[1], MessageSendEvent::SendAcceptChannel, last_random_pk);
8667 fn test_outbound_chans_unlimited() {
8668 // Test that we never refuse an outbound channel even if a peer is unfuned-channel-limited
8669 let chanmon_cfgs = create_chanmon_cfgs(2);
8670 let node_cfgs = create_node_cfgs(2, &chanmon_cfgs);
8671 let node_chanmgrs = create_node_chanmgrs(2, &node_cfgs, &[None, None]);
8672 let nodes = create_network(2, &node_cfgs, &node_chanmgrs);
8674 // Note that create_network connects the nodes together for us
8676 nodes[0].node.create_channel(nodes[1].node.get_our_node_id(), 100_000, 0, 42, None).unwrap();
8677 let mut open_channel_msg = get_event_msg!(nodes[0], MessageSendEvent::SendOpenChannel, nodes[1].node.get_our_node_id());
8679 for _ in 0..super::MAX_UNFUNDED_CHANS_PER_PEER {
8680 nodes[1].node.handle_open_channel(&nodes[0].node.get_our_node_id(), &open_channel_msg);
8681 get_event_msg!(nodes[1], MessageSendEvent::SendAcceptChannel, nodes[0].node.get_our_node_id());
8682 open_channel_msg.temporary_channel_id = nodes[0].keys_manager.get_secure_random_bytes();
8685 // Once we have MAX_UNFUNDED_CHANS_PER_PEER unfunded channels, new inbound channels will be
8687 nodes[1].node.handle_open_channel(&nodes[0].node.get_our_node_id(), &open_channel_msg);
8688 assert_eq!(get_err_msg(&nodes[1], &nodes[0].node.get_our_node_id()).channel_id,
8689 open_channel_msg.temporary_channel_id);
8691 // but we can still open an outbound channel.
8692 nodes[1].node.create_channel(nodes[0].node.get_our_node_id(), 100_000, 0, 42, None).unwrap();
8693 get_event_msg!(nodes[1], MessageSendEvent::SendOpenChannel, nodes[0].node.get_our_node_id());
8695 // but even with such an outbound channel, additional inbound channels will still fail.
8696 nodes[1].node.handle_open_channel(&nodes[0].node.get_our_node_id(), &open_channel_msg);
8697 assert_eq!(get_err_msg(&nodes[1], &nodes[0].node.get_our_node_id()).channel_id,
8698 open_channel_msg.temporary_channel_id);
8702 fn test_0conf_limiting() {
8703 // Tests that we properly limit inbound channels when we have the manual-channel-acceptance
8704 // flag set and (sometimes) accept channels as 0conf.
8705 let chanmon_cfgs = create_chanmon_cfgs(2);
8706 let node_cfgs = create_node_cfgs(2, &chanmon_cfgs);
8707 let mut settings = test_default_channel_config();
8708 settings.manually_accept_inbound_channels = true;
8709 let node_chanmgrs = create_node_chanmgrs(2, &node_cfgs, &[None, Some(settings)]);
8710 let nodes = create_network(2, &node_cfgs, &node_chanmgrs);
8712 // Note that create_network connects the nodes together for us
8714 nodes[0].node.create_channel(nodes[1].node.get_our_node_id(), 100_000, 0, 42, None).unwrap();
8715 let mut open_channel_msg = get_event_msg!(nodes[0], MessageSendEvent::SendOpenChannel, nodes[1].node.get_our_node_id());
8717 // First, get us up to MAX_UNFUNDED_CHANNEL_PEERS so we can test at the edge
8718 for _ in 0..super::MAX_UNFUNDED_CHANNEL_PEERS - 1 {
8719 let random_pk = PublicKey::from_secret_key(&nodes[0].node.secp_ctx,
8720 &SecretKey::from_slice(&nodes[1].keys_manager.get_secure_random_bytes()).unwrap());
8721 nodes[1].node.peer_connected(&random_pk, &msgs::Init {
8722 features: nodes[0].node.init_features(), remote_network_address: None }, true).unwrap();
8724 nodes[1].node.handle_open_channel(&random_pk, &open_channel_msg);
8725 let events = nodes[1].node.get_and_clear_pending_events();
8727 Event::OpenChannelRequest { temporary_channel_id, .. } => {
8728 nodes[1].node.accept_inbound_channel(&temporary_channel_id, &random_pk, 23).unwrap();
8730 _ => panic!("Unexpected event"),
8732 get_event_msg!(nodes[1], MessageSendEvent::SendAcceptChannel, random_pk);
8733 open_channel_msg.temporary_channel_id = nodes[0].keys_manager.get_secure_random_bytes();
8736 // If we try to accept a channel from another peer non-0conf it will fail.
8737 let last_random_pk = PublicKey::from_secret_key(&nodes[0].node.secp_ctx,
8738 &SecretKey::from_slice(&nodes[1].keys_manager.get_secure_random_bytes()).unwrap());
8739 nodes[1].node.peer_connected(&last_random_pk, &msgs::Init {
8740 features: nodes[0].node.init_features(), remote_network_address: None }, true).unwrap();
8741 nodes[1].node.handle_open_channel(&last_random_pk, &open_channel_msg);
8742 let events = nodes[1].node.get_and_clear_pending_events();
8744 Event::OpenChannelRequest { temporary_channel_id, .. } => {
8745 match nodes[1].node.accept_inbound_channel(&temporary_channel_id, &last_random_pk, 23) {
8746 Err(APIError::APIMisuseError { err }) =>
8747 assert_eq!(err, "Too many peers with unfunded channels, refusing to accept new ones"),
8751 _ => panic!("Unexpected event"),
8753 assert_eq!(get_err_msg(&nodes[1], &last_random_pk).channel_id,
8754 open_channel_msg.temporary_channel_id);
8756 // ...however if we accept the same channel 0conf it should work just fine.
8757 nodes[1].node.handle_open_channel(&last_random_pk, &open_channel_msg);
8758 let events = nodes[1].node.get_and_clear_pending_events();
8760 Event::OpenChannelRequest { temporary_channel_id, .. } => {
8761 nodes[1].node.accept_inbound_channel_from_trusted_peer_0conf(&temporary_channel_id, &last_random_pk, 23).unwrap();
8763 _ => panic!("Unexpected event"),
8765 get_event_msg!(nodes[1], MessageSendEvent::SendAcceptChannel, last_random_pk);
8770 fn test_anchors_zero_fee_htlc_tx_fallback() {
8771 // Tests that if both nodes support anchors, but the remote node does not want to accept
8772 // anchor channels at the moment, an error it sent to the local node such that it can retry
8773 // the channel without the anchors feature.
8774 let chanmon_cfgs = create_chanmon_cfgs(2);
8775 let node_cfgs = create_node_cfgs(2, &chanmon_cfgs);
8776 let mut anchors_config = test_default_channel_config();
8777 anchors_config.channel_handshake_config.negotiate_anchors_zero_fee_htlc_tx = true;
8778 anchors_config.manually_accept_inbound_channels = true;
8779 let node_chanmgrs = create_node_chanmgrs(2, &node_cfgs, &[Some(anchors_config.clone()), Some(anchors_config.clone())]);
8780 let nodes = create_network(2, &node_cfgs, &node_chanmgrs);
8782 nodes[0].node.create_channel(nodes[1].node.get_our_node_id(), 100_000, 0, 0, None).unwrap();
8783 let open_channel_msg = get_event_msg!(nodes[0], MessageSendEvent::SendOpenChannel, nodes[1].node.get_our_node_id());
8784 assert!(open_channel_msg.channel_type.as_ref().unwrap().supports_anchors_zero_fee_htlc_tx());
8786 nodes[1].node.handle_open_channel(&nodes[0].node.get_our_node_id(), &open_channel_msg);
8787 let events = nodes[1].node.get_and_clear_pending_events();
8789 Event::OpenChannelRequest { temporary_channel_id, .. } => {
8790 nodes[1].node.force_close_broadcasting_latest_txn(&temporary_channel_id, &nodes[0].node.get_our_node_id()).unwrap();
8792 _ => panic!("Unexpected event"),
8795 let error_msg = get_err_msg(&nodes[1], &nodes[0].node.get_our_node_id());
8796 nodes[0].node.handle_error(&nodes[1].node.get_our_node_id(), &error_msg);
8798 let open_channel_msg = get_event_msg!(nodes[0], MessageSendEvent::SendOpenChannel, nodes[1].node.get_our_node_id());
8799 assert!(!open_channel_msg.channel_type.unwrap().supports_anchors_zero_fee_htlc_tx());
8801 check_closed_event!(nodes[1], 1, ClosureReason::HolderForceClosed);
8805 #[cfg(all(any(test, feature = "_test_utils"), feature = "_bench_unstable"))]
8807 use crate::chain::Listen;
8808 use crate::chain::chainmonitor::{ChainMonitor, Persist};
8809 use crate::chain::keysinterface::{EntropySource, KeysManager, InMemorySigner};
8810 use crate::events::{Event, MessageSendEvent, MessageSendEventsProvider};
8811 use crate::ln::channelmanager::{self, BestBlock, ChainParameters, ChannelManager, PaymentHash, PaymentPreimage, PaymentId};
8812 use crate::ln::functional_test_utils::*;
8813 use crate::ln::msgs::{ChannelMessageHandler, Init};
8814 use crate::routing::gossip::NetworkGraph;
8815 use crate::routing::router::{PaymentParameters, get_route};
8816 use crate::util::test_utils;
8817 use crate::util::config::UserConfig;
8819 use bitcoin::hashes::Hash;
8820 use bitcoin::hashes::sha256::Hash as Sha256;
8821 use bitcoin::{Block, BlockHeader, PackedLockTime, Transaction, TxMerkleNode, TxOut};
8823 use crate::sync::{Arc, Mutex};
8827 struct NodeHolder<'a, P: Persist<InMemorySigner>> {
8828 node: &'a ChannelManager<
8829 &'a ChainMonitor<InMemorySigner, &'a test_utils::TestChainSource,
8830 &'a test_utils::TestBroadcaster, &'a test_utils::TestFeeEstimator,
8831 &'a test_utils::TestLogger, &'a P>,
8832 &'a test_utils::TestBroadcaster, &'a KeysManager, &'a KeysManager, &'a KeysManager,
8833 &'a test_utils::TestFeeEstimator, &'a test_utils::TestRouter<'a>,
8834 &'a test_utils::TestLogger>,
8839 fn bench_sends(bench: &mut Bencher) {
8840 bench_two_sends(bench, test_utils::TestPersister::new(), test_utils::TestPersister::new());
8843 pub fn bench_two_sends<P: Persist<InMemorySigner>>(bench: &mut Bencher, persister_a: P, persister_b: P) {
8844 // Do a simple benchmark of sending a payment back and forth between two nodes.
8845 // Note that this is unrealistic as each payment send will require at least two fsync
8847 let network = bitcoin::Network::Testnet;
8849 let tx_broadcaster = test_utils::TestBroadcaster{txn_broadcasted: Mutex::new(Vec::new()), blocks: Arc::new(Mutex::new(Vec::new()))};
8850 let fee_estimator = test_utils::TestFeeEstimator { sat_per_kw: Mutex::new(253) };
8851 let logger_a = test_utils::TestLogger::with_id("node a".to_owned());
8852 let scorer = Mutex::new(test_utils::TestScorer::new());
8853 let router = test_utils::TestRouter::new(Arc::new(NetworkGraph::new(network, &logger_a)), &scorer);
8855 let mut config: UserConfig = Default::default();
8856 config.channel_handshake_config.minimum_depth = 1;
8858 let chain_monitor_a = ChainMonitor::new(None, &tx_broadcaster, &logger_a, &fee_estimator, &persister_a);
8859 let seed_a = [1u8; 32];
8860 let keys_manager_a = KeysManager::new(&seed_a, 42, 42);
8861 let node_a = ChannelManager::new(&fee_estimator, &chain_monitor_a, &tx_broadcaster, &router, &logger_a, &keys_manager_a, &keys_manager_a, &keys_manager_a, config.clone(), ChainParameters {
8863 best_block: BestBlock::from_network(network),
8865 let node_a_holder = NodeHolder { node: &node_a };
8867 let logger_b = test_utils::TestLogger::with_id("node a".to_owned());
8868 let chain_monitor_b = ChainMonitor::new(None, &tx_broadcaster, &logger_a, &fee_estimator, &persister_b);
8869 let seed_b = [2u8; 32];
8870 let keys_manager_b = KeysManager::new(&seed_b, 42, 42);
8871 let node_b = ChannelManager::new(&fee_estimator, &chain_monitor_b, &tx_broadcaster, &router, &logger_b, &keys_manager_b, &keys_manager_b, &keys_manager_b, config.clone(), ChainParameters {
8873 best_block: BestBlock::from_network(network),
8875 let node_b_holder = NodeHolder { node: &node_b };
8877 node_a.peer_connected(&node_b.get_our_node_id(), &Init { features: node_b.init_features(), remote_network_address: None }, true).unwrap();
8878 node_b.peer_connected(&node_a.get_our_node_id(), &Init { features: node_a.init_features(), remote_network_address: None }, false).unwrap();
8879 node_a.create_channel(node_b.get_our_node_id(), 8_000_000, 100_000_000, 42, None).unwrap();
8880 node_b.handle_open_channel(&node_a.get_our_node_id(), &get_event_msg!(node_a_holder, MessageSendEvent::SendOpenChannel, node_b.get_our_node_id()));
8881 node_a.handle_accept_channel(&node_b.get_our_node_id(), &get_event_msg!(node_b_holder, MessageSendEvent::SendAcceptChannel, node_a.get_our_node_id()));
8884 if let Event::FundingGenerationReady { temporary_channel_id, output_script, .. } = get_event!(node_a_holder, Event::FundingGenerationReady) {
8885 tx = Transaction { version: 2, lock_time: PackedLockTime::ZERO, input: Vec::new(), output: vec![TxOut {
8886 value: 8_000_000, script_pubkey: output_script,
8888 node_a.funding_transaction_generated(&temporary_channel_id, &node_b.get_our_node_id(), tx.clone()).unwrap();
8889 } else { panic!(); }
8891 node_b.handle_funding_created(&node_a.get_our_node_id(), &get_event_msg!(node_a_holder, MessageSendEvent::SendFundingCreated, node_b.get_our_node_id()));
8892 node_a.handle_funding_signed(&node_b.get_our_node_id(), &get_event_msg!(node_b_holder, MessageSendEvent::SendFundingSigned, node_a.get_our_node_id()));
8894 assert_eq!(&tx_broadcaster.txn_broadcasted.lock().unwrap()[..], &[tx.clone()]);
8897 header: BlockHeader { version: 0x20000000, prev_blockhash: BestBlock::from_network(network).block_hash(), merkle_root: TxMerkleNode::all_zeros(), time: 42, bits: 42, nonce: 42 },
8900 Listen::block_connected(&node_a, &block, 1);
8901 Listen::block_connected(&node_b, &block, 1);
8903 node_a.handle_channel_ready(&node_b.get_our_node_id(), &get_event_msg!(node_b_holder, MessageSendEvent::SendChannelReady, node_a.get_our_node_id()));
8904 let msg_events = node_a.get_and_clear_pending_msg_events();
8905 assert_eq!(msg_events.len(), 2);
8906 match msg_events[0] {
8907 MessageSendEvent::SendChannelReady { ref msg, .. } => {
8908 node_b.handle_channel_ready(&node_a.get_our_node_id(), msg);
8909 get_event_msg!(node_b_holder, MessageSendEvent::SendChannelUpdate, node_a.get_our_node_id());
8913 match msg_events[1] {
8914 MessageSendEvent::SendChannelUpdate { .. } => {},
8918 let events_a = node_a.get_and_clear_pending_events();
8919 assert_eq!(events_a.len(), 1);
8921 Event::ChannelReady{ ref counterparty_node_id, .. } => {
8922 assert_eq!(*counterparty_node_id, node_b.get_our_node_id());
8924 _ => panic!("Unexpected event"),
8927 let events_b = node_b.get_and_clear_pending_events();
8928 assert_eq!(events_b.len(), 1);
8930 Event::ChannelReady{ ref counterparty_node_id, .. } => {
8931 assert_eq!(*counterparty_node_id, node_a.get_our_node_id());
8933 _ => panic!("Unexpected event"),
8936 let dummy_graph = NetworkGraph::new(network, &logger_a);
8938 let mut payment_count: u64 = 0;
8939 macro_rules! send_payment {
8940 ($node_a: expr, $node_b: expr) => {
8941 let usable_channels = $node_a.list_usable_channels();
8942 let payment_params = PaymentParameters::from_node_id($node_b.get_our_node_id(), TEST_FINAL_CLTV)
8943 .with_features($node_b.invoice_features());
8944 let scorer = test_utils::TestScorer::new();
8945 let seed = [3u8; 32];
8946 let keys_manager = KeysManager::new(&seed, 42, 42);
8947 let random_seed_bytes = keys_manager.get_secure_random_bytes();
8948 let route = get_route(&$node_a.get_our_node_id(), &payment_params, &dummy_graph.read_only(),
8949 Some(&usable_channels.iter().map(|r| r).collect::<Vec<_>>()), 10_000, TEST_FINAL_CLTV, &logger_a, &scorer, &random_seed_bytes).unwrap();
8951 let mut payment_preimage = PaymentPreimage([0; 32]);
8952 payment_preimage.0[0..8].copy_from_slice(&payment_count.to_le_bytes());
8954 let payment_hash = PaymentHash(Sha256::hash(&payment_preimage.0[..]).into_inner());
8955 let payment_secret = $node_b.create_inbound_payment_for_hash(payment_hash, None, 7200, None).unwrap();
8957 $node_a.send_payment(&route, payment_hash, &Some(payment_secret), PaymentId(payment_hash.0)).unwrap();
8958 let payment_event = SendEvent::from_event($node_a.get_and_clear_pending_msg_events().pop().unwrap());
8959 $node_b.handle_update_add_htlc(&$node_a.get_our_node_id(), &payment_event.msgs[0]);
8960 $node_b.handle_commitment_signed(&$node_a.get_our_node_id(), &payment_event.commitment_msg);
8961 let (raa, cs) = do_get_revoke_commit_msgs!(NodeHolder { node: &$node_b }, &$node_a.get_our_node_id());
8962 $node_a.handle_revoke_and_ack(&$node_b.get_our_node_id(), &raa);
8963 $node_a.handle_commitment_signed(&$node_b.get_our_node_id(), &cs);
8964 $node_b.handle_revoke_and_ack(&$node_a.get_our_node_id(), &get_event_msg!(NodeHolder { node: &$node_a }, MessageSendEvent::SendRevokeAndACK, $node_b.get_our_node_id()));
8966 expect_pending_htlcs_forwardable!(NodeHolder { node: &$node_b });
8967 expect_payment_claimable!(NodeHolder { node: &$node_b }, payment_hash, payment_secret, 10_000);
8968 $node_b.claim_funds(payment_preimage);
8969 expect_payment_claimed!(NodeHolder { node: &$node_b }, payment_hash, 10_000);
8971 match $node_b.get_and_clear_pending_msg_events().pop().unwrap() {
8972 MessageSendEvent::UpdateHTLCs { node_id, updates } => {
8973 assert_eq!(node_id, $node_a.get_our_node_id());
8974 $node_a.handle_update_fulfill_htlc(&$node_b.get_our_node_id(), &updates.update_fulfill_htlcs[0]);
8975 $node_a.handle_commitment_signed(&$node_b.get_our_node_id(), &updates.commitment_signed);
8977 _ => panic!("Failed to generate claim event"),
8980 let (raa, cs) = do_get_revoke_commit_msgs!(NodeHolder { node: &$node_a }, &$node_b.get_our_node_id());
8981 $node_b.handle_revoke_and_ack(&$node_a.get_our_node_id(), &raa);
8982 $node_b.handle_commitment_signed(&$node_a.get_our_node_id(), &cs);
8983 $node_a.handle_revoke_and_ack(&$node_b.get_our_node_id(), &get_event_msg!(NodeHolder { node: &$node_b }, MessageSendEvent::SendRevokeAndACK, $node_a.get_our_node_id()));
8985 expect_payment_sent!(NodeHolder { node: &$node_a }, payment_preimage);
8990 send_payment!(node_a, node_b);
8991 send_payment!(node_b, node_a);