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rust-lightning/lightning/src/ln/channelmanager.rs
valentinewallace ab20284e26
Merge pull request #1505 from tnull/2022-05-support-0conf-channeltype 
Support `ZeroConf` channel type.
2022-06-02 13:02:25 -07:00

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// This file is Copyright its original authors, visible in version control
// history.
//
// This file is licensed under the Apache License, Version 2.0 <LICENSE-APACHE
// or http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your option.
// You may not use this file except in accordance with one or both of these
// licenses.
//! The top-level channel management and payment tracking stuff lives here.
//!
//! The ChannelManager is the main chunk of logic implementing the lightning protocol and is
//! responsible for tracking which channels are open, HTLCs are in flight and reestablishing those
//! upon reconnect to the relevant peer(s).
//!
//! It does not manage routing logic (see routing::router::get_route for that) nor does it manage constructing
//! on-chain transactions (it only monitors the chain to watch for any force-closes that might
//! imply it needs to fail HTLCs/payments/channels it manages).
//!
use bitcoin::blockdata::block::BlockHeader;
use bitcoin::blockdata::transaction::Transaction;
use bitcoin::blockdata::constants::genesis_block;
use bitcoin::network::constants::Network;
use bitcoin::hashes::{Hash, HashEngine};
use bitcoin::hashes::sha256::Hash as Sha256;
use bitcoin::hashes::sha256d::Hash as Sha256dHash;
use bitcoin::hash_types::{BlockHash, Txid};
use bitcoin::secp256k1::{SecretKey,PublicKey};
use bitcoin::secp256k1::Secp256k1;
use bitcoin::secp256k1::ecdh::SharedSecret;
use bitcoin::secp256k1;
use chain;
use chain::{Confirm, ChannelMonitorUpdateErr, Watch, BestBlock};
use chain::chaininterface::{BroadcasterInterface, ConfirmationTarget, FeeEstimator};
use chain::channelmonitor::{ChannelMonitor, ChannelMonitorUpdate, ChannelMonitorUpdateStep, HTLC_FAIL_BACK_BUFFER, CLTV_CLAIM_BUFFER, LATENCY_GRACE_PERIOD_BLOCKS, ANTI_REORG_DELAY, MonitorEvent, CLOSED_CHANNEL_UPDATE_ID};
use chain::transaction::{OutPoint, TransactionData};
// Since this struct is returned in `list_channels` methods, expose it here in case users want to
// construct one themselves.
use ln::{inbound_payment, PaymentHash, PaymentPreimage, PaymentSecret};
use ln::channel::{Channel, ChannelError, ChannelUpdateStatus, UpdateFulfillCommitFetch};
use ln::features::{ChannelTypeFeatures, InitFeatures, NodeFeatures};
use routing::router::{PaymentParameters, Route, RouteHop, RoutePath, RouteParameters};
use ln::msgs;
use ln::msgs::NetAddress;
use ln::onion_utils;
use ln::msgs::{ChannelMessageHandler, DecodeError, LightningError, MAX_VALUE_MSAT, OptionalField};
use ln::wire::Encode;
use chain::keysinterface::{Sign, KeysInterface, KeysManager, InMemorySigner, Recipient};
use util::config::UserConfig;
use util::events::{EventHandler, EventsProvider, MessageSendEvent, MessageSendEventsProvider, ClosureReason};
use util::{byte_utils, events};
use util::scid_utils::fake_scid;
use util::ser::{BigSize, FixedLengthReader, Readable, ReadableArgs, MaybeReadable, Writeable, Writer, VecWriter};
use util::logger::{Level, Logger};
use util::errors::APIError;
use io;
use prelude::*;
use core::{cmp, mem};
use core::cell::RefCell;
use io::Read;
use sync::{Arc, Condvar, Mutex, MutexGuard, RwLock, RwLockReadGuard};
use core::sync::atomic::{AtomicUsize, Ordering};
use core::time::Duration;
use core::ops::Deref;
#[cfg(any(test, feature = "std"))]
use std::time::Instant;
use util::crypto::sign;
// We hold various information about HTLC relay in the HTLC objects in Channel itself:
//
// Upon receipt of an HTLC from a peer, we'll give it a PendingHTLCStatus indicating if it should
// forward the HTLC with information it will give back to us when it does so, or if it should Fail
// the HTLC with the relevant message for the Channel to handle giving to the remote peer.
//
// Once said HTLC is committed in the Channel, if the PendingHTLCStatus indicated Forward, the
// Channel will return the PendingHTLCInfo back to us, and we will create an HTLCForwardInfo
// with it to track where it came from (in case of onwards-forward error), waiting a random delay
// before we forward it.
//
// We will then use HTLCForwardInfo's PendingHTLCInfo to construct an outbound HTLC, with a
// relevant HTLCSource::PreviousHopData filled in to indicate where it came from (which we can use
// to either fail-backwards or fulfill the HTLC backwards along the relevant path).
// Alternatively, we can fill an outbound HTLC with a HTLCSource::OutboundRoute indicating this is
// our payment, which we can use to decode errors or inform the user that the payment was sent.
#[derive(Clone)] // See Channel::revoke_and_ack for why, tl;dr: Rust bug
pub(super) enum PendingHTLCRouting {
Forward {
onion_packet: msgs::OnionPacket,
/// The SCID from the onion that we should forward to. This could be a "real" SCID, an
/// outbound SCID alias, or a phantom node SCID.
short_channel_id: u64, // This should be NonZero<u64> eventually when we bump MSRV
},
Receive {
payment_data: msgs::FinalOnionHopData,
incoming_cltv_expiry: u32, // Used to track when we should expire pending HTLCs that go unclaimed
phantom_shared_secret: Option<[u8; 32]>,
},
ReceiveKeysend {
payment_preimage: PaymentPreimage,
incoming_cltv_expiry: u32, // Used to track when we should expire pending HTLCs that go unclaimed
},
}
#[derive(Clone)] // See Channel::revoke_and_ack for why, tl;dr: Rust bug
pub(super) struct PendingHTLCInfo {
pub(super) routing: PendingHTLCRouting,
pub(super) incoming_shared_secret: [u8; 32],
payment_hash: PaymentHash,
pub(super) amt_to_forward: u64,
pub(super) outgoing_cltv_value: u32,
}
#[derive(Clone)] // See Channel::revoke_and_ack for why, tl;dr: Rust bug
pub(super) enum HTLCFailureMsg {
Relay(msgs::UpdateFailHTLC),
Malformed(msgs::UpdateFailMalformedHTLC),
}
/// Stores whether we can't forward an HTLC or relevant forwarding info
#[derive(Clone)] // See Channel::revoke_and_ack for why, tl;dr: Rust bug
pub(super) enum PendingHTLCStatus {
Forward(PendingHTLCInfo),
Fail(HTLCFailureMsg),
}
pub(super) enum HTLCForwardInfo {
AddHTLC {
forward_info: PendingHTLCInfo,
// These fields are produced in `forward_htlcs()` and consumed in
// `process_pending_htlc_forwards()` for constructing the
// `HTLCSource::PreviousHopData` for failed and forwarded
// HTLCs.
//
// Note that this may be an outbound SCID alias for the associated channel.
prev_short_channel_id: u64,
prev_htlc_id: u64,
prev_funding_outpoint: OutPoint,
},
FailHTLC {
htlc_id: u64,
err_packet: msgs::OnionErrorPacket,
},
}
/// Tracks the inbound corresponding to an outbound HTLC
#[derive(Clone, Hash, PartialEq, Eq)]
pub(crate) struct HTLCPreviousHopData {
// Note that this may be an outbound SCID alias for the associated channel.
short_channel_id: u64,
htlc_id: u64,
incoming_packet_shared_secret: [u8; 32],
phantom_shared_secret: Option<[u8; 32]>,
// This field is consumed by `claim_funds_from_hop()` when updating a force-closed backwards
// channel with a preimage provided by the forward channel.
outpoint: OutPoint,
}
enum OnionPayload {
/// Indicates this incoming onion payload is for the purpose of paying an invoice.
Invoice {
/// This is only here for backwards-compatibility in serialization, in the future it can be
/// removed, breaking clients running 0.0.106 and earlier.
_legacy_hop_data: Option<msgs::FinalOnionHopData>,
},
/// Contains the payer-provided preimage.
Spontaneous(PaymentPreimage),
}
/// HTLCs that are to us and can be failed/claimed by the user
struct ClaimableHTLC {
prev_hop: HTLCPreviousHopData,
cltv_expiry: u32,
/// The amount (in msats) of this MPP part
value: u64,
onion_payload: OnionPayload,
timer_ticks: u8,
/// The sum total of all MPP parts
total_msat: u64,
}
/// A payment identifier used to uniquely identify a payment to LDK.
/// (C-not exported) as we just use [u8; 32] directly
#[derive(Hash, Copy, Clone, PartialEq, Eq, Debug)]
pub struct PaymentId(pub [u8; 32]);
impl Writeable for PaymentId {
fn write<W: Writer>(&self, w: &mut W) -> Result<(), io::Error> {
self.0.write(w)
}
}
impl Readable for PaymentId {
fn read<R: Read>(r: &mut R) -> Result<Self, DecodeError> {
let buf: [u8; 32] = Readable::read(r)?;
Ok(PaymentId(buf))
}
}
/// Tracks the inbound corresponding to an outbound HTLC
#[allow(clippy::derive_hash_xor_eq)] // Our Hash is faithful to the data, we just don't have SecretKey::hash
#[derive(Clone, PartialEq, Eq)]
pub(crate) enum HTLCSource {
PreviousHopData(HTLCPreviousHopData),
OutboundRoute {
path: Vec<RouteHop>,
session_priv: SecretKey,
/// Technically we can recalculate this from the route, but we cache it here to avoid
/// doing a double-pass on route when we get a failure back
first_hop_htlc_msat: u64,
payment_id: PaymentId,
payment_secret: Option<PaymentSecret>,
payment_params: Option<PaymentParameters>,
},
}
#[allow(clippy::derive_hash_xor_eq)] // Our Hash is faithful to the data, we just don't have SecretKey::hash
impl core::hash::Hash for HTLCSource {
fn hash<H: core::hash::Hasher>(&self, hasher: &mut H) {
match self {
HTLCSource::PreviousHopData(prev_hop_data) => {
0u8.hash(hasher);
prev_hop_data.hash(hasher);
},
HTLCSource::OutboundRoute { path, session_priv, payment_id, payment_secret, first_hop_htlc_msat, payment_params } => {
1u8.hash(hasher);
path.hash(hasher);
session_priv[..].hash(hasher);
payment_id.hash(hasher);
payment_secret.hash(hasher);
first_hop_htlc_msat.hash(hasher);
payment_params.hash(hasher);
},
}
}
}
#[cfg(not(feature = "grind_signatures"))]
#[cfg(test)]
impl HTLCSource {
pub fn dummy() -> Self {
HTLCSource::OutboundRoute {
path: Vec::new(),
session_priv: SecretKey::from_slice(&[1; 32]).unwrap(),
first_hop_htlc_msat: 0,
payment_id: PaymentId([2; 32]),
payment_secret: None,
payment_params: None,
}
}
}
#[derive(Clone)] // See Channel::revoke_and_ack for why, tl;dr: Rust bug
pub(super) enum HTLCFailReason {
LightningError {
err: msgs::OnionErrorPacket,
},
Reason {
failure_code: u16,
data: Vec<u8>,
}
}
struct ReceiveError {
err_code: u16,
err_data: Vec<u8>,
msg: &'static str,
}
/// Return value for claim_funds_from_hop
enum ClaimFundsFromHop {
PrevHopForceClosed,
MonitorUpdateFail(PublicKey, MsgHandleErrInternal, Option<u64>),
Success(u64),
DuplicateClaim,
}
type ShutdownResult = (Option<(OutPoint, ChannelMonitorUpdate)>, Vec<(HTLCSource, PaymentHash)>);
/// Error type returned across the channel_state mutex boundary. When an Err is generated for a
/// Channel, we generally end up with a ChannelError::Close for which we have to close the channel
/// immediately (ie with no further calls on it made). Thus, this step happens inside a
/// channel_state lock. We then return the set of things that need to be done outside the lock in
/// this struct and call handle_error!() on it.
struct MsgHandleErrInternal {
err: msgs::LightningError,
chan_id: Option<([u8; 32], u64)>, // If Some a channel of ours has been closed
shutdown_finish: Option<(ShutdownResult, Option<msgs::ChannelUpdate>)>,
}
impl MsgHandleErrInternal {
#[inline]
fn send_err_msg_no_close(err: String, channel_id: [u8; 32]) -> Self {
Self {
err: LightningError {
err: err.clone(),
action: msgs::ErrorAction::SendErrorMessage {
msg: msgs::ErrorMessage {
channel_id,
data: err
},
},
},
chan_id: None,
shutdown_finish: None,
}
}
#[inline]
fn ignore_no_close(err: String) -> Self {
Self {
err: LightningError {
err,
action: msgs::ErrorAction::IgnoreError,
},
chan_id: None,
shutdown_finish: None,
}
}
#[inline]
fn from_no_close(err: msgs::LightningError) -> Self {
Self { err, chan_id: None, shutdown_finish: None }
}
#[inline]
fn from_finish_shutdown(err: String, channel_id: [u8; 32], user_channel_id: u64, shutdown_res: ShutdownResult, channel_update: Option<msgs::ChannelUpdate>) -> Self {
Self {
err: LightningError {
err: err.clone(),
action: msgs::ErrorAction::SendErrorMessage {
msg: msgs::ErrorMessage {
channel_id,
data: err
},
},
},
chan_id: Some((channel_id, user_channel_id)),
shutdown_finish: Some((shutdown_res, channel_update)),
}
}
#[inline]
fn from_chan_no_close(err: ChannelError, channel_id: [u8; 32]) -> Self {
Self {
err: match err {
ChannelError::Warn(msg) => LightningError {
err: msg.clone(),
action: msgs::ErrorAction::SendWarningMessage {
msg: msgs::WarningMessage {
channel_id,
data: msg
},
log_level: Level::Warn,
},
},
ChannelError::Ignore(msg) => LightningError {
err: msg,
action: msgs::ErrorAction::IgnoreError,
},
ChannelError::Close(msg) => LightningError {
err: msg.clone(),
action: msgs::ErrorAction::SendErrorMessage {
msg: msgs::ErrorMessage {
channel_id,
data: msg
},
},
},
ChannelError::CloseDelayBroadcast(msg) => LightningError {
err: msg.clone(),
action: msgs::ErrorAction::SendErrorMessage {
msg: msgs::ErrorMessage {
channel_id,
data: msg
},
},
},
},
chan_id: None,
shutdown_finish: None,
}
}
}
/// We hold back HTLCs we intend to relay for a random interval greater than this (see
/// Event::PendingHTLCsForwardable for the API guidelines indicating how long should be waited).
/// This provides some limited amount of privacy. Ideally this would range from somewhere like one
/// second to 30 seconds, but people expect lightning to be, you know, kinda fast, sadly.
const MIN_HTLC_RELAY_HOLDING_CELL_MILLIS: u64 = 100;
/// For events which result in both a RevokeAndACK and a CommitmentUpdate, by default they should
/// be sent in the order they appear in the return value, however sometimes the order needs to be
/// variable at runtime (eg Channel::channel_reestablish needs to re-send messages in the order
/// they were originally sent). In those cases, this enum is also returned.
#[derive(Clone, PartialEq)]
pub(super) enum RAACommitmentOrder {
/// Send the CommitmentUpdate messages first
CommitmentFirst,
/// Send the RevokeAndACK message first
RevokeAndACKFirst,
}
// Note this is only exposed in cfg(test):
pub(super) struct ChannelHolder<Signer: Sign> {
pub(super) by_id: HashMap<[u8; 32], Channel<Signer>>,
/// SCIDs (and outbound SCID aliases) to the real channel id. Outbound SCID aliases are added
/// here once the channel is available for normal use, with SCIDs being added once the funding
/// transaction is confirmed at the channel's required confirmation depth.
pub(super) short_to_id: HashMap<u64, [u8; 32]>,
/// SCID/SCID Alias -> forward infos. Key of 0 means payments received.
///
/// Note that because we may have an SCID Alias as the key we can have two entries per channel,
/// though in practice we probably won't be receiving HTLCs for a channel both via the alias
/// and via the classic SCID.
///
/// Note that while this is held in the same mutex as the channels themselves, no consistency
/// guarantees are made about the existence of a channel with the short id here, nor the short
/// ids in the PendingHTLCInfo!
pub(super) forward_htlcs: HashMap<u64, Vec<HTLCForwardInfo>>,
/// Map from payment hash to the payment data and any HTLCs which are to us and can be
/// failed/claimed by the user.
///
/// Note that while this is held in the same mutex as the channels themselves, no consistency
/// guarantees are made about the channels given here actually existing anymore by the time you
/// go to read them!
claimable_htlcs: HashMap<PaymentHash, (events::PaymentPurpose, Vec<ClaimableHTLC>)>,
/// Messages to send to peers - pushed to in the same lock that they are generated in (except
/// for broadcast messages, where ordering isn't as strict).
pub(super) pending_msg_events: Vec<MessageSendEvent>,
}
/// Events which we process internally but cannot be procsesed immediately at the generation site
/// for some reason. They are handled in timer_tick_occurred, so may be processed with
/// quite some time lag.
enum BackgroundEvent {
/// Handle a ChannelMonitorUpdate that closes a channel, broadcasting its current latest holder
/// commitment transaction.
ClosingMonitorUpdate((OutPoint, ChannelMonitorUpdate)),
}
/// State we hold per-peer. In the future we should put channels in here, but for now we only hold
/// the latest Init features we heard from the peer.
struct PeerState {
latest_features: InitFeatures,
}
/// Stores a PaymentSecret and any other data we may need to validate an inbound payment is
/// actually ours and not some duplicate HTLC sent to us by a node along the route.
///
/// For users who don't want to bother doing their own payment preimage storage, we also store that
/// here.
///
/// Note that this struct will be removed entirely soon, in favor of storing no inbound payment data
/// and instead encoding it in the payment secret.
struct PendingInboundPayment {
/// The payment secret that the sender must use for us to accept this payment
payment_secret: PaymentSecret,
/// Time at which this HTLC expires - blocks with a header time above this value will result in
/// this payment being removed.
expiry_time: u64,
/// Arbitrary identifier the user specifies (or not)
user_payment_id: u64,
// Other required attributes of the payment, optionally enforced:
payment_preimage: Option<PaymentPreimage>,
min_value_msat: Option<u64>,
}
/// Stores the session_priv for each part of a payment that is still pending. For versions 0.0.102
/// and later, also stores information for retrying the payment.
pub(crate) enum PendingOutboundPayment {
Legacy {
session_privs: HashSet<[u8; 32]>,
},
Retryable {
session_privs: HashSet<[u8; 32]>,
payment_hash: PaymentHash,
payment_secret: Option<PaymentSecret>,
pending_amt_msat: u64,
/// Used to track the fee paid. Only present if the payment was serialized on 0.0.103+.
pending_fee_msat: Option<u64>,
/// The total payment amount across all paths, used to verify that a retry is not overpaying.
total_msat: u64,
/// Our best known block height at the time this payment was initiated.
starting_block_height: u32,
},
/// When a pending payment is fulfilled, we continue tracking it until all pending HTLCs have
/// been resolved. This ensures we don't look up pending payments in ChannelMonitors on restart
/// and add a pending payment that was already fulfilled.
Fulfilled {
session_privs: HashSet<[u8; 32]>,
payment_hash: Option<PaymentHash>,
},
/// When a payer gives up trying to retry a payment, they inform us, letting us generate a
/// `PaymentFailed` event when all HTLCs have irrevocably failed. This avoids a number of race
/// conditions in MPP-aware payment retriers (1), where the possibility of multiple
/// `PaymentPathFailed` events with `all_paths_failed` can be pending at once, confusing a
/// downstream event handler as to when a payment has actually failed.
///
/// (1) https://github.com/lightningdevkit/rust-lightning/issues/1164
Abandoned {
session_privs: HashSet<[u8; 32]>,
payment_hash: PaymentHash,
},
}
impl PendingOutboundPayment {
fn is_retryable(&self) -> bool {
match self {
PendingOutboundPayment::Retryable { .. } => true,
_ => false,
}
}
fn is_fulfilled(&self) -> bool {
match self {
PendingOutboundPayment::Fulfilled { .. } => true,
_ => false,
}
}
fn abandoned(&self) -> bool {
match self {
PendingOutboundPayment::Abandoned { .. } => true,
_ => false,
}
}
fn get_pending_fee_msat(&self) -> Option<u64> {
match self {
PendingOutboundPayment::Retryable { pending_fee_msat, .. } => pending_fee_msat.clone(),
_ => None,
}
}
fn payment_hash(&self) -> Option<PaymentHash> {
match self {
PendingOutboundPayment::Legacy { .. } => None,
PendingOutboundPayment::Retryable { payment_hash, .. } => Some(*payment_hash),
PendingOutboundPayment::Fulfilled { payment_hash, .. } => *payment_hash,
PendingOutboundPayment::Abandoned { payment_hash, .. } => Some(*payment_hash),
}
}
fn mark_fulfilled(&mut self) {
let mut session_privs = HashSet::new();
core::mem::swap(&mut session_privs, match self {
PendingOutboundPayment::Legacy { session_privs } |
PendingOutboundPayment::Retryable { session_privs, .. } |
PendingOutboundPayment::Fulfilled { session_privs, .. } |
PendingOutboundPayment::Abandoned { session_privs, .. }
=> session_privs,
});
let payment_hash = self.payment_hash();
*self = PendingOutboundPayment::Fulfilled { session_privs, payment_hash };
}
fn mark_abandoned(&mut self) -> Result<(), ()> {
let mut session_privs = HashSet::new();
let our_payment_hash;
core::mem::swap(&mut session_privs, match self {
PendingOutboundPayment::Legacy { .. } |
PendingOutboundPayment::Fulfilled { .. } =>
return Err(()),
PendingOutboundPayment::Retryable { session_privs, payment_hash, .. } |
PendingOutboundPayment::Abandoned { session_privs, payment_hash, .. } => {
our_payment_hash = *payment_hash;
session_privs
},
});
*self = PendingOutboundPayment::Abandoned { session_privs, payment_hash: our_payment_hash };
Ok(())
}
/// panics if path is None and !self.is_fulfilled
fn remove(&mut self, session_priv: &[u8; 32], path: Option<&Vec<RouteHop>>) -> bool {
let remove_res = match self {
PendingOutboundPayment::Legacy { session_privs } |
PendingOutboundPayment::Retryable { session_privs, .. } |
PendingOutboundPayment::Fulfilled { session_privs, .. } |
PendingOutboundPayment::Abandoned { session_privs, .. } => {
session_privs.remove(session_priv)
}
};
if remove_res {
if let PendingOutboundPayment::Retryable { ref mut pending_amt_msat, ref mut pending_fee_msat, .. } = self {
let path = path.expect("Fulfilling a payment should always come with a path");
let path_last_hop = path.last().expect("Outbound payments must have had a valid path");
*pending_amt_msat -= path_last_hop.fee_msat;
if let Some(fee_msat) = pending_fee_msat.as_mut() {
*fee_msat -= path.get_path_fees();
}
}
}
remove_res
}
fn insert(&mut self, session_priv: [u8; 32], path: &Vec<RouteHop>) -> bool {
let insert_res = match self {
PendingOutboundPayment::Legacy { session_privs } |
PendingOutboundPayment::Retryable { session_privs, .. } => {
session_privs.insert(session_priv)
}
PendingOutboundPayment::Fulfilled { .. } => false,
PendingOutboundPayment::Abandoned { .. } => false,
};
if insert_res {
if let PendingOutboundPayment::Retryable { ref mut pending_amt_msat, ref mut pending_fee_msat, .. } = self {
let path_last_hop = path.last().expect("Outbound payments must have had a valid path");
*pending_amt_msat += path_last_hop.fee_msat;
if let Some(fee_msat) = pending_fee_msat.as_mut() {
*fee_msat += path.get_path_fees();
}
}
}
insert_res
}
fn remaining_parts(&self) -> usize {
match self {
PendingOutboundPayment::Legacy { session_privs } |
PendingOutboundPayment::Retryable { session_privs, .. } |
PendingOutboundPayment::Fulfilled { session_privs, .. } |
PendingOutboundPayment::Abandoned { session_privs, .. } => {
session_privs.len()
}
}
}
}
/// SimpleArcChannelManager is useful when you need a ChannelManager with a static lifetime, e.g.
/// when you're using lightning-net-tokio (since tokio::spawn requires parameters with static
/// lifetimes). Other times you can afford a reference, which is more efficient, in which case
/// SimpleRefChannelManager is the more appropriate type. Defining these type aliases prevents
/// issues such as overly long function definitions. Note that the ChannelManager can take any
/// type that implements KeysInterface for its keys manager, but this type alias chooses the
/// concrete type of the KeysManager.
///
/// (C-not exported) as Arcs don't make sense in bindings
pub type SimpleArcChannelManager<M, T, F, L> = ChannelManager<InMemorySigner, Arc<M>, Arc<T>, Arc<KeysManager>, Arc<F>, Arc<L>>;
/// SimpleRefChannelManager is a type alias for a ChannelManager reference, and is the reference
/// counterpart to the SimpleArcChannelManager type alias. Use this type by default when you don't
/// need a ChannelManager with a static lifetime. You'll need a static lifetime in cases such as
/// usage of lightning-net-tokio (since tokio::spawn requires parameters with static lifetimes).
/// But if this is not necessary, using a reference is more efficient. Defining these type aliases
/// helps with issues such as long function definitions. Note that the ChannelManager can take any
/// type that implements KeysInterface for its keys manager, but this type alias chooses the
/// concrete type of the KeysManager.
///
/// (C-not exported) as Arcs don't make sense in bindings
pub type SimpleRefChannelManager<'a, 'b, 'c, 'd, 'e, M, T, F, L> = ChannelManager<InMemorySigner, &'a M, &'b T, &'c KeysManager, &'d F, &'e L>;
/// Manager which keeps track of a number of channels and sends messages to the appropriate
/// channel, also tracking HTLC preimages and forwarding onion packets appropriately.
///
/// Implements ChannelMessageHandler, handling the multi-channel parts and passing things through
/// to individual Channels.
///
/// Implements Writeable to write out all channel state to disk. Implies peer_disconnected() for
/// all peers during write/read (though does not modify this instance, only the instance being
/// serialized). This will result in any channels which have not yet exchanged funding_created (ie
/// called funding_transaction_generated for outbound channels).
///
/// Note that you can be a bit lazier about writing out ChannelManager than you can be with
/// ChannelMonitors. With ChannelMonitors you MUST write each monitor update out to disk before
/// returning from chain::Watch::watch_/update_channel, with ChannelManagers, writing updates
/// happens out-of-band (and will prevent any other ChannelManager operations from occurring during
/// the serialization process). If the deserialized version is out-of-date compared to the
/// ChannelMonitors passed by reference to read(), those channels will be force-closed based on the
/// ChannelMonitor state and no funds will be lost (mod on-chain transaction fees).
///
/// Note that the deserializer is only implemented for (BlockHash, ChannelManager), which
/// tells you the last block hash which was block_connect()ed. You MUST rescan any blocks along
/// the "reorg path" (ie call block_disconnected() until you get to a common block and then call
/// block_connected() to step towards your best block) upon deserialization before using the
/// object!
///
/// Note that ChannelManager is responsible for tracking liveness of its channels and generating
/// ChannelUpdate messages informing peers that the channel is temporarily disabled. To avoid
/// spam due to quick disconnection/reconnection, updates are not sent until the channel has been
/// offline for a full minute. In order to track this, you must call
/// timer_tick_occurred roughly once per minute, though it doesn't have to be perfect.
///
/// Rather than using a plain ChannelManager, it is preferable to use either a SimpleArcChannelManager
/// a SimpleRefChannelManager, for conciseness. See their documentation for more details, but
/// essentially you should default to using a SimpleRefChannelManager, and use a
/// SimpleArcChannelManager when you require a ChannelManager with a static lifetime, such as when
/// you're using lightning-net-tokio.
pub struct ChannelManager<Signer: Sign, M: Deref, T: Deref, K: Deref, F: Deref, L: Deref>
where M::Target: chain::Watch<Signer>,
T::Target: BroadcasterInterface,
K::Target: KeysInterface<Signer = Signer>,
F::Target: FeeEstimator,
L::Target: Logger,
{
default_configuration: UserConfig,
genesis_hash: BlockHash,
fee_estimator: F,
chain_monitor: M,
tx_broadcaster: T,
#[cfg(test)]
pub(super) best_block: RwLock<BestBlock>,
#[cfg(not(test))]
best_block: RwLock<BestBlock>,
secp_ctx: Secp256k1<secp256k1::All>,
#[cfg(any(test, feature = "_test_utils"))]
pub(super) channel_state: Mutex<ChannelHolder<Signer>>,
#[cfg(not(any(test, feature = "_test_utils")))]
channel_state: Mutex<ChannelHolder<Signer>>,
/// Storage for PaymentSecrets and any requirements on future inbound payments before we will
/// expose them to users via a PaymentReceived event. HTLCs which do not meet the requirements
/// here are failed when we process them as pending-forwardable-HTLCs, and entries are removed
/// after we generate a PaymentReceived upon receipt of all MPP parts or when they time out.
/// Locked *after* channel_state.
pending_inbound_payments: Mutex<HashMap<PaymentHash, PendingInboundPayment>>,
/// The session_priv bytes and retry metadata of outbound payments which are pending resolution.
/// The authoritative state of these HTLCs resides either within Channels or ChannelMonitors
/// (if the channel has been force-closed), however we track them here to prevent duplicative
/// PaymentSent/PaymentPathFailed events. Specifically, in the case of a duplicative
/// update_fulfill_htlc message after a reconnect, we may "claim" a payment twice.
/// Additionally, because ChannelMonitors are often not re-serialized after connecting block(s)
/// which may generate a claim event, we may receive similar duplicate claim/fail MonitorEvents
/// after reloading from disk while replaying blocks against ChannelMonitors.
///
/// See `PendingOutboundPayment` documentation for more info.
///
/// Locked *after* channel_state.
pending_outbound_payments: Mutex<HashMap<PaymentId, PendingOutboundPayment>>,
/// The set of outbound SCID aliases across all our channels, including unconfirmed channels
/// and some closed channels which reached a usable state prior to being closed. This is used
/// only to avoid duplicates, and is not persisted explicitly to disk, but rebuilt from the
/// active channel list on load.
outbound_scid_aliases: Mutex<HashSet<u64>>,
our_network_key: SecretKey,
our_network_pubkey: PublicKey,
inbound_payment_key: inbound_payment::ExpandedKey,
/// LDK puts the [fake scids] that it generates into namespaces, to identify the type of an
/// incoming payment. To make it harder for a third-party to identify the type of a payment,
/// we encrypt the namespace identifier using these bytes.
///
/// [fake scids]: crate::util::scid_utils::fake_scid
fake_scid_rand_bytes: [u8; 32],
/// Used to track the last value sent in a node_announcement "timestamp" field. We ensure this
/// value increases strictly since we don't assume access to a time source.
last_node_announcement_serial: AtomicUsize,
/// The highest block timestamp we've seen, which is usually a good guess at the current time.
/// Assuming most miners are generating blocks with reasonable timestamps, this shouldn't be
/// very far in the past, and can only ever be up to two hours in the future.
highest_seen_timestamp: AtomicUsize,
/// The bulk of our storage will eventually be here (channels and message queues and the like).
/// If we are connected to a peer we always at least have an entry here, even if no channels
/// are currently open with that peer.
/// Because adding or removing an entry is rare, we usually take an outer read lock and then
/// operate on the inner value freely. Sadly, this prevents parallel operation when opening a
/// new channel.
///
/// If also holding `channel_state` lock, must lock `channel_state` prior to `per_peer_state`.
per_peer_state: RwLock<HashMap<PublicKey, Mutex<PeerState>>>,
pending_events: Mutex<Vec<events::Event>>,
pending_background_events: Mutex<Vec<BackgroundEvent>>,
/// Used when we have to take a BIG lock to make sure everything is self-consistent.
/// Essentially just when we're serializing ourselves out.
/// Taken first everywhere where we are making changes before any other locks.
/// When acquiring this lock in read mode, rather than acquiring it directly, call
/// `PersistenceNotifierGuard::notify_on_drop(..)` and pass the lock to it, to ensure the
/// PersistenceNotifier the lock contains sends out a notification when the lock is released.
total_consistency_lock: RwLock<()>,
persistence_notifier: PersistenceNotifier,
keys_manager: K,
logger: L,
}
/// Chain-related parameters used to construct a new `ChannelManager`.
///
/// Typically, the block-specific parameters are derived from the best block hash for the network,
/// as a newly constructed `ChannelManager` will not have created any channels yet. These parameters
/// are not needed when deserializing a previously constructed `ChannelManager`.
#[derive(Clone, Copy, PartialEq)]
pub struct ChainParameters {
/// The network for determining the `chain_hash` in Lightning messages.
pub network: Network,
/// The hash and height of the latest block successfully connected.
///
/// Used to track on-chain channel funding outputs and send payments with reliable timelocks.
pub best_block: BestBlock,
}
#[derive(Copy, Clone, PartialEq)]
enum NotifyOption {
DoPersist,
SkipPersist,
}
/// Whenever we release the `ChannelManager`'s `total_consistency_lock`, from read mode, it is
/// desirable to notify any listeners on `await_persistable_update_timeout`/
/// `await_persistable_update` when new updates are available for persistence. Therefore, this
/// struct is responsible for locking the total consistency lock and, upon going out of scope,
/// sending the aforementioned notification (since the lock being released indicates that the
/// updates are ready for persistence).
///
/// We allow callers to either always notify by constructing with `notify_on_drop` or choose to
/// notify or not based on whether relevant changes have been made, providing a closure to
/// `optionally_notify` which returns a `NotifyOption`.
struct PersistenceNotifierGuard<'a, F: Fn() -> NotifyOption> {
persistence_notifier: &'a PersistenceNotifier,
should_persist: F,
// We hold onto this result so the lock doesn't get released immediately.
_read_guard: RwLockReadGuard<'a, ()>,
}
impl<'a> PersistenceNotifierGuard<'a, fn() -> NotifyOption> { // We don't care what the concrete F is here, it's unused
fn notify_on_drop(lock: &'a RwLock<()>, notifier: &'a PersistenceNotifier) -> PersistenceNotifierGuard<'a, impl Fn() -> NotifyOption> {
PersistenceNotifierGuard::optionally_notify(lock, notifier, || -> NotifyOption { NotifyOption::DoPersist })
}
fn optionally_notify<F: Fn() -> NotifyOption>(lock: &'a RwLock<()>, notifier: &'a PersistenceNotifier, persist_check: F) -> PersistenceNotifierGuard<'a, F> {
let read_guard = lock.read().unwrap();
PersistenceNotifierGuard {
persistence_notifier: notifier,
should_persist: persist_check,
_read_guard: read_guard,
}
}
}
impl<'a, F: Fn() -> NotifyOption> Drop for PersistenceNotifierGuard<'a, F> {
fn drop(&mut self) {
if (self.should_persist)() == NotifyOption::DoPersist {
self.persistence_notifier.notify();
}
}
}
/// The amount of time in blocks we require our counterparty wait to claim their money (ie time
/// between when we, or our watchtower, must check for them having broadcast a theft transaction).
///
/// This can be increased (but not decreased) through [`ChannelHandshakeConfig::our_to_self_delay`]
///
/// [`ChannelHandshakeConfig::our_to_self_delay`]: crate::util::config::ChannelHandshakeConfig::our_to_self_delay
pub const BREAKDOWN_TIMEOUT: u16 = 6 * 24;
/// The amount of time in blocks we're willing to wait to claim money back to us. This matches
/// the maximum required amount in lnd as of March 2021.
pub(crate) const MAX_LOCAL_BREAKDOWN_TIMEOUT: u16 = 2 * 6 * 24 * 7;
/// The minimum number of blocks between an inbound HTLC's CLTV and the corresponding outbound
/// HTLC's CLTV. The current default represents roughly seven hours of blocks at six blocks/hour.
///
/// This can be increased (but not decreased) through [`ChannelConfig::cltv_expiry_delta`]
///
/// [`ChannelConfig::cltv_expiry_delta`]: crate::util::config::ChannelConfig::cltv_expiry_delta
// This should always be a few blocks greater than channelmonitor::CLTV_CLAIM_BUFFER,
// i.e. the node we forwarded the payment on to should always have enough room to reliably time out
// the HTLC via a full update_fail_htlc/commitment_signed dance before we hit the
// CLTV_CLAIM_BUFFER point (we static assert that it's at least 3 blocks more).
pub const MIN_CLTV_EXPIRY_DELTA: u16 = 6*7;
pub(super) const CLTV_FAR_FAR_AWAY: u32 = 6 * 24 * 7; //TODO?
/// Minimum CLTV difference between the current block height and received inbound payments.
/// Invoices generated for payment to us must set their `min_final_cltv_expiry` field to at least
/// this value.
// Note that we fail if exactly HTLC_FAIL_BACK_BUFFER + 1 was used, so we need to add one for
// any payments to succeed. Further, we don't want payments to fail if a block was found while
// a payment was being routed, so we add an extra block to be safe.
pub const MIN_FINAL_CLTV_EXPIRY: u32 = HTLC_FAIL_BACK_BUFFER + 3;
// Check that our CLTV_EXPIRY is at least CLTV_CLAIM_BUFFER + ANTI_REORG_DELAY + LATENCY_GRACE_PERIOD_BLOCKS,
// ie that if the next-hop peer fails the HTLC within
// LATENCY_GRACE_PERIOD_BLOCKS then we'll still have CLTV_CLAIM_BUFFER left to timeout it onchain,
// then waiting ANTI_REORG_DELAY to be reorg-safe on the outbound HLTC and
// failing the corresponding htlc backward, and us now seeing the last block of ANTI_REORG_DELAY before
// LATENCY_GRACE_PERIOD_BLOCKS.
#[deny(const_err)]
#[allow(dead_code)]
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;
// Check for ability of an attacker to make us fail on-chain by delaying an HTLC claim. See
// ChannelMonitor::should_broadcast_holder_commitment_txn for a description of why this is needed.
#[deny(const_err)]
#[allow(dead_code)]
const CHECK_CLTV_EXPIRY_SANITY_2: u32 = MIN_CLTV_EXPIRY_DELTA as u32 - LATENCY_GRACE_PERIOD_BLOCKS - 2*CLTV_CLAIM_BUFFER;
/// The number of blocks before we consider an outbound payment for expiry if it doesn't have any
/// pending HTLCs in flight.
pub(crate) const PAYMENT_EXPIRY_BLOCKS: u32 = 3;
/// The number of ticks of [`ChannelManager::timer_tick_occurred`] until expiry of incomplete MPPs
pub(crate) const MPP_TIMEOUT_TICKS: u8 = 3;
/// Information needed for constructing an invoice route hint for this channel.
#[derive(Clone, Debug, PartialEq)]
pub struct CounterpartyForwardingInfo {
/// Base routing fee in millisatoshis.
pub fee_base_msat: u32,
/// Amount in millionths of a satoshi the channel will charge per transferred satoshi.
pub fee_proportional_millionths: u32,
/// The minimum difference in cltv_expiry between an ingoing HTLC and its outgoing counterpart,
/// such that the outgoing HTLC is forwardable to this counterparty. See `msgs::ChannelUpdate`'s
/// `cltv_expiry_delta` for more details.
pub cltv_expiry_delta: u16,
}
/// Channel parameters which apply to our counterparty. These are split out from [`ChannelDetails`]
/// to better separate parameters.
#[derive(Clone, Debug, PartialEq)]
pub struct ChannelCounterparty {
/// The node_id of our counterparty
pub node_id: PublicKey,
/// The Features the channel counterparty provided upon last connection.
/// Useful for routing as it is the most up-to-date copy of the counterparty's features and
/// many routing-relevant features are present in the init context.
pub features: InitFeatures,
/// The value, in satoshis, that must always be held in the channel for our counterparty. This
/// value ensures that if our counterparty broadcasts a revoked state, we can punish them by
/// claiming at least this value on chain.
///
/// This value is not included in [`inbound_capacity_msat`] as it can never be spent.
///
/// [`inbound_capacity_msat`]: ChannelDetails::inbound_capacity_msat
pub unspendable_punishment_reserve: u64,
/// Information on the fees and requirements that the counterparty requires when forwarding
/// payments to us through this channel.
pub forwarding_info: Option<CounterpartyForwardingInfo>,
/// The smallest value HTLC (in msat) the remote peer will accept, for this channel. This field
/// is only `None` before we have received either the `OpenChannel` or `AcceptChannel` message
/// from the remote peer, or for `ChannelCounterparty` objects serialized prior to LDK 0.0.107.
pub outbound_htlc_minimum_msat: Option<u64>,
/// The largest value HTLC (in msat) the remote peer currently will accept, for this channel.
pub outbound_htlc_maximum_msat: Option<u64>,
}
/// Details of a channel, as returned by ChannelManager::list_channels and ChannelManager::list_usable_channels
#[derive(Clone, Debug, PartialEq)]
pub struct ChannelDetails {
/// The channel's ID (prior to funding transaction generation, this is a random 32 bytes,
/// thereafter this is the txid of the funding transaction xor the funding transaction output).
/// Note that this means this value is *not* persistent - it can change once during the
/// lifetime of the channel.
pub channel_id: [u8; 32],
/// Parameters which apply to our counterparty. See individual fields for more information.
pub counterparty: ChannelCounterparty,
/// The Channel's funding transaction output, if we've negotiated the funding transaction with
/// our counterparty already.
///
/// Note that, if this has been set, `channel_id` will be equivalent to
/// `funding_txo.unwrap().to_channel_id()`.
pub funding_txo: Option<OutPoint>,
/// The features which this channel operates with. See individual features for more info.
///
/// `None` until negotiation completes and the channel type is finalized.
pub channel_type: Option<ChannelTypeFeatures>,
/// The position of the funding transaction in the chain. None if the funding transaction has
/// not yet been confirmed and the channel fully opened.
///
/// Note that if [`inbound_scid_alias`] is set, it must be used for invoices and inbound
/// payments instead of this. See [`get_inbound_payment_scid`].
///
/// For channels with [`confirmations_required`] set to `Some(0)`, [`outbound_scid_alias`] may
/// be used in place of this in outbound routes. See [`get_outbound_payment_scid`].
///
/// [`inbound_scid_alias`]: Self::inbound_scid_alias
/// [`outbound_scid_alias`]: Self::outbound_scid_alias
/// [`get_inbound_payment_scid`]: Self::get_inbound_payment_scid
/// [`get_outbound_payment_scid`]: Self::get_outbound_payment_scid
/// [`confirmations_required`]: Self::confirmations_required
pub short_channel_id: Option<u64>,
/// An optional [`short_channel_id`] alias for this channel, randomly generated by us and
/// usable in place of [`short_channel_id`] to reference the channel in outbound routes when
/// the channel has not yet been confirmed (as long as [`confirmations_required`] is
/// `Some(0)`).
///
/// This will be `None` as long as the channel is not available for routing outbound payments.
///
/// [`short_channel_id`]: Self::short_channel_id
/// [`confirmations_required`]: Self::confirmations_required
pub outbound_scid_alias: Option<u64>,
/// An optional [`short_channel_id`] alias for this channel, randomly generated by our
/// counterparty and usable in place of [`short_channel_id`] in invoice route hints. Our
/// counterparty will recognize the alias provided here in place of the [`short_channel_id`]
/// when they see a payment to be routed to us.
///
/// Our counterparty may choose to rotate this value at any time, though will always recognize
/// previous values for inbound payment forwarding.
///
/// [`short_channel_id`]: Self::short_channel_id
pub inbound_scid_alias: Option<u64>,
/// The value, in satoshis, of this channel as appears in the funding output
pub channel_value_satoshis: u64,
/// The value, in satoshis, that must always be held in the channel for us. This value ensures
/// that if we broadcast a revoked state, our counterparty can punish us by claiming at least
/// this value on chain.
///
/// This value is not included in [`outbound_capacity_msat`] as it can never be spent.
///
/// This value will be `None` for outbound channels until the counterparty accepts the channel.
///
/// [`outbound_capacity_msat`]: ChannelDetails::outbound_capacity_msat
pub unspendable_punishment_reserve: Option<u64>,
/// The `user_channel_id` passed in to create_channel, or 0 if the channel was inbound.
pub user_channel_id: u64,
/// Our total balance. This is the amount we would get if we close the channel.
/// This value is not exact. Due to various in-flight changes and feerate changes, exactly this
/// amount is not likely to be recoverable on close.
///
/// This does not include any pending HTLCs which are not yet fully resolved (and, thus, whose
/// balance is not available for inclusion in new outbound HTLCs). This further does not include
/// any pending outgoing HTLCs which are awaiting some other resolution to be sent.
/// This does not consider any on-chain fees.
///
/// See also [`ChannelDetails::outbound_capacity_msat`]
pub balance_msat: u64,
/// The available outbound capacity for sending HTLCs to the remote peer. This does not include
/// any pending HTLCs which are not yet fully resolved (and, thus, whose balance is not
/// available for inclusion in new outbound HTLCs). This further does not include any pending
/// outgoing HTLCs which are awaiting some other resolution to be sent.
///
/// See also [`ChannelDetails::balance_msat`]
///
/// This value is not exact. Due to various in-flight changes, feerate changes, and our
/// conflict-avoidance policy, exactly this amount is not likely to be spendable. However, we
/// should be able to spend nearly this amount.
pub outbound_capacity_msat: u64,
/// The available outbound capacity for sending a single HTLC to the remote peer. This is
/// similar to [`ChannelDetails::outbound_capacity_msat`] but it may be further restricted by
/// the current state and per-HTLC limit(s). This is intended for use when routing, allowing us
/// to use a limit as close as possible to the HTLC limit we can currently send.
///
/// See also [`ChannelDetails::balance_msat`] and [`ChannelDetails::outbound_capacity_msat`].
pub next_outbound_htlc_limit_msat: u64,
/// The available inbound capacity for the remote peer to send HTLCs to us. This does not
/// include any pending HTLCs which are not yet fully resolved (and, thus, whose balance is not
/// available for inclusion in new inbound HTLCs).
/// Note that there are some corner cases not fully handled here, so the actual available
/// inbound capacity may be slightly higher than this.
///
/// This value is not exact. Due to various in-flight changes, feerate changes, and our
/// counterparty's conflict-avoidance policy, exactly this amount is not likely to be spendable.
/// However, our counterparty should be able to spend nearly this amount.
pub inbound_capacity_msat: u64,
/// The number of required confirmations on the funding transaction before the funding will be
/// considered "locked". This number is selected by the channel fundee (i.e. us if
/// [`is_outbound`] is *not* set), and can be selected for inbound channels with
/// [`ChannelHandshakeConfig::minimum_depth`] or limited for outbound channels with
/// [`ChannelHandshakeLimits::max_minimum_depth`].
///
/// This value will be `None` for outbound channels until the counterparty accepts the channel.
///
/// [`is_outbound`]: ChannelDetails::is_outbound
/// [`ChannelHandshakeConfig::minimum_depth`]: crate::util::config::ChannelHandshakeConfig::minimum_depth
/// [`ChannelHandshakeLimits::max_minimum_depth`]: crate::util::config::ChannelHandshakeLimits::max_minimum_depth
pub confirmations_required: Option<u32>,
/// The number of blocks (after our commitment transaction confirms) that we will need to wait
/// until we can claim our funds after we force-close the channel. During this time our
/// counterparty is allowed to punish us if we broadcasted a stale state. If our counterparty
/// force-closes the channel and broadcasts a commitment transaction we do not have to wait any
/// time to claim our non-HTLC-encumbered funds.
///
/// This value will be `None` for outbound channels until the counterparty accepts the channel.
pub force_close_spend_delay: Option<u16>,
/// True if the channel was initiated (and thus funded) by us.
pub is_outbound: bool,
/// True if the channel is confirmed, channel_ready messages have been exchanged, and the
/// channel is not currently being shut down. `channel_ready` message exchange implies the
/// required confirmation count has been reached (and we were connected to the peer at some
/// point after the funding transaction received enough confirmations). The required
/// confirmation count is provided in [`confirmations_required`].
///
/// [`confirmations_required`]: ChannelDetails::confirmations_required
pub is_channel_ready: bool,
/// True if the channel is (a) confirmed and channel_ready messages have been exchanged, (b)
/// the peer is connected, and (c) the channel is not currently negotiating a shutdown.
///
/// This is a strict superset of `is_channel_ready`.
pub is_usable: bool,
/// True if this channel is (or will be) publicly-announced.
pub is_public: bool,
/// The smallest value HTLC (in msat) we will accept, for this channel. This field
/// is only `None` for `ChannelDetails` objects serialized prior to LDK 0.0.107
pub inbound_htlc_minimum_msat: Option<u64>,
/// The largest value HTLC (in msat) we currently will accept, for this channel.
pub inbound_htlc_maximum_msat: Option<u64>,
}
impl ChannelDetails {
/// Gets the current SCID which should be used to identify this channel for inbound payments.
/// This should be used for providing invoice hints or in any other context where our
/// counterparty will forward a payment to us.
///
/// This is either the [`ChannelDetails::inbound_scid_alias`], if set, or the
/// [`ChannelDetails::short_channel_id`]. See those for more information.
pub fn get_inbound_payment_scid(&self) -> Option<u64> {
self.inbound_scid_alias.or(self.short_channel_id)
}
/// Gets the current SCID which should be used to identify this channel for outbound payments.
/// This should be used in [`Route`]s to describe the first hop or in other contexts where
/// we're sending or forwarding a payment outbound over this channel.
///
/// This is either the [`ChannelDetails::short_channel_id`], if set, or the
/// [`ChannelDetails::outbound_scid_alias`]. See those for more information.
pub fn get_outbound_payment_scid(&self) -> Option<u64> {
self.short_channel_id.or(self.outbound_scid_alias)
}
}
/// If a payment fails to send, it can be in one of several states. This enum is returned as the
/// Err() type describing which state the payment is in, see the description of individual enum
/// states for more.
#[derive(Clone, Debug)]
pub enum PaymentSendFailure {
/// A parameter which was passed to send_payment was invalid, preventing us from attempting to
/// send the payment at all. No channel state has been changed or messages sent to peers, and
/// once you've changed the parameter at error, you can freely retry the payment in full.
ParameterError(APIError),
/// A parameter in a single path which was passed to send_payment was invalid, preventing us
/// from attempting to send the payment at all. No channel state has been changed or messages
/// sent to peers, and once you've changed the parameter at error, you can freely retry the
/// payment in full.
///
/// The results here are ordered the same as the paths in the route object which was passed to
/// send_payment.
PathParameterError(Vec<Result<(), APIError>>),
/// All paths which were attempted failed to send, with no channel state change taking place.
/// You can freely retry the payment in full (though you probably want to do so over different
/// paths than the ones selected).
AllFailedRetrySafe(Vec<APIError>),
/// Some paths which were attempted failed to send, though possibly not all. At least some
/// paths have irrevocably committed to the HTLC and retrying the payment in full would result
/// in over-/re-payment.
///
/// The results here are ordered the same as the paths in the route object which was passed to
/// send_payment, and any Errs which are not APIError::MonitorUpdateFailed can be safely
/// retried (though there is currently no API with which to do so).
///
/// Any entries which contain Err(APIError::MonitorUpdateFailed) or Ok(()) MUST NOT be retried
/// as they will result in over-/re-payment. These HTLCs all either successfully sent (in the
/// case of Ok(())) or will send once channel_monitor_updated is called on the next-hop channel
/// with the latest update_id.
PartialFailure {
/// The errors themselves, in the same order as the route hops.
results: Vec<Result<(), APIError>>,
/// If some paths failed without irrevocably committing to the new HTLC(s), this will
/// contain a [`RouteParameters`] object which can be used to calculate a new route that
/// will pay all remaining unpaid balance.
failed_paths_retry: Option<RouteParameters>,
/// The payment id for the payment, which is now at least partially pending.
payment_id: PaymentId,
},
}
/// Route hints used in constructing invoices for [phantom node payents].
///
/// [phantom node payments]: crate::chain::keysinterface::PhantomKeysManager
#[derive(Clone)]
pub struct PhantomRouteHints {
/// The list of channels to be included in the invoice route hints.
pub channels: Vec<ChannelDetails>,
/// A fake scid used for representing the phantom node's fake channel in generating the invoice
/// route hints.
pub phantom_scid: u64,
/// The pubkey of the real backing node that would ultimately receive the payment.
pub real_node_pubkey: PublicKey,
}
macro_rules! handle_error {
($self: ident, $internal: expr, $counterparty_node_id: expr) => {
match $internal {
Ok(msg) => Ok(msg),
Err(MsgHandleErrInternal { err, chan_id, shutdown_finish }) => {
#[cfg(debug_assertions)]
{
// In testing, ensure there are no deadlocks where the lock is already held upon
// entering the macro.
assert!($self.channel_state.try_lock().is_ok());
assert!($self.pending_events.try_lock().is_ok());
}
let mut msg_events = Vec::with_capacity(2);
if let Some((shutdown_res, update_option)) = shutdown_finish {
$self.finish_force_close_channel(shutdown_res);
if let Some(update) = update_option {
msg_events.push(events::MessageSendEvent::BroadcastChannelUpdate {
msg: update
});
}
if let Some((channel_id, user_channel_id)) = chan_id {
$self.pending_events.lock().unwrap().push(events::Event::ChannelClosed {
channel_id, user_channel_id,
reason: ClosureReason::ProcessingError { err: err.err.clone() }
});
}
}
log_error!($self.logger, "{}", err.err);
if let msgs::ErrorAction::IgnoreError = err.action {
} else {
msg_events.push(events::MessageSendEvent::HandleError {
node_id: $counterparty_node_id,
action: err.action.clone()
});
}
if !msg_events.is_empty() {
$self.channel_state.lock().unwrap().pending_msg_events.append(&mut msg_events);
}
// Return error in case higher-API need one
Err(err)
},
}
}
}
macro_rules! update_maps_on_chan_removal {
($self: expr, $short_to_id: expr, $channel: expr) => {
if let Some(short_id) = $channel.get_short_channel_id() {
$short_to_id.remove(&short_id);
} else {
// If the channel was never confirmed on-chain prior to its closure, remove the
// outbound SCID alias we used for it from the collision-prevention set. While we
// generally want to avoid ever re-using an outbound SCID alias across all channels, we
// also don't want a counterparty to be able to trivially cause a memory leak by simply
// opening a million channels with us which are closed before we ever reach the funding
// stage.
let alias_removed = $self.outbound_scid_aliases.lock().unwrap().remove(&$channel.outbound_scid_alias());
debug_assert!(alias_removed);
}
$short_to_id.remove(&$channel.outbound_scid_alias());
}
}
/// Returns (boolean indicating if we should remove the Channel object from memory, a mapped error)
macro_rules! convert_chan_err {
($self: ident, $err: expr, $short_to_id: expr, $channel: expr, $channel_id: expr) => {
match $err {
ChannelError::Warn(msg) => {
(false, MsgHandleErrInternal::from_chan_no_close(ChannelError::Warn(msg), $channel_id.clone()))
},
ChannelError::Ignore(msg) => {
(false, MsgHandleErrInternal::from_chan_no_close(ChannelError::Ignore(msg), $channel_id.clone()))
},
ChannelError::Close(msg) => {
log_error!($self.logger, "Closing channel {} due to close-required error: {}", log_bytes!($channel_id[..]), msg);
update_maps_on_chan_removal!($self, $short_to_id, $channel);
let shutdown_res = $channel.force_shutdown(true);
(true, MsgHandleErrInternal::from_finish_shutdown(msg, *$channel_id, $channel.get_user_id(),
shutdown_res, $self.get_channel_update_for_broadcast(&$channel).ok()))
},
ChannelError::CloseDelayBroadcast(msg) => {
log_error!($self.logger, "Channel {} need to be shutdown but closing transactions not broadcast due to {}", log_bytes!($channel_id[..]), msg);
update_maps_on_chan_removal!($self, $short_to_id, $channel);
let shutdown_res = $channel.force_shutdown(false);
(true, MsgHandleErrInternal::from_finish_shutdown(msg, *$channel_id, $channel.get_user_id(),
shutdown_res, $self.get_channel_update_for_broadcast(&$channel).ok()))
}
}
}
}
macro_rules! break_chan_entry {
($self: ident, $res: expr, $channel_state: expr, $entry: expr) => {
match $res {
Ok(res) => res,
Err(e) => {
let (drop, res) = convert_chan_err!($self, e, $channel_state.short_to_id, $entry.get_mut(), $entry.key());
if drop {
$entry.remove_entry();
}
break Err(res);
}
}
}
}
macro_rules! try_chan_entry {
($self: ident, $res: expr, $channel_state: expr, $entry: expr) => {
match $res {
Ok(res) => res,
Err(e) => {
let (drop, res) = convert_chan_err!($self, e, $channel_state.short_to_id, $entry.get_mut(), $entry.key());
if drop {
$entry.remove_entry();
}
return Err(res);
}
}
}
}
macro_rules! remove_channel {
($self: expr, $channel_state: expr, $entry: expr) => {
{
let channel = $entry.remove_entry().1;
update_maps_on_chan_removal!($self, $channel_state.short_to_id, channel);
channel
}
}
}
macro_rules! handle_monitor_err {
($self: ident, $err: expr, $short_to_id: expr, $chan: expr, $action_type: path, $resend_raa: expr, $resend_commitment: expr, $resend_channel_ready: expr, $failed_forwards: expr, $failed_fails: expr, $failed_finalized_fulfills: expr, $chan_id: expr) => {
match $err {
ChannelMonitorUpdateErr::PermanentFailure => {
log_error!($self.logger, "Closing channel {} due to monitor update ChannelMonitorUpdateErr::PermanentFailure", log_bytes!($chan_id[..]));
update_maps_on_chan_removal!($self, $short_to_id, $chan);
// TODO: $failed_fails is dropped here, which will cause other channels to hit the
// chain in a confused state! We need to move them into the ChannelMonitor which
// will be responsible for failing backwards once things confirm on-chain.
// It's ok that we drop $failed_forwards here - at this point we'd rather they
// broadcast HTLC-Timeout and pay the associated fees to get their funds back than
// us bother trying to claim it just to forward on to another peer. If we're
// splitting hairs we'd prefer to claim payments that were to us, but we haven't
// given up the preimage yet, so might as well just wait until the payment is
// retried, avoiding the on-chain fees.
let res: Result<(), _> = Err(MsgHandleErrInternal::from_finish_shutdown("ChannelMonitor storage failure".to_owned(), *$chan_id, $chan.get_user_id(),
$chan.force_shutdown(true), $self.get_channel_update_for_broadcast(&$chan).ok() ));
(res, true)
},
ChannelMonitorUpdateErr::TemporaryFailure => {
log_info!($self.logger, "Disabling channel {} due to monitor update TemporaryFailure. On restore will send {} and process {} forwards, {} fails, and {} fulfill finalizations",
log_bytes!($chan_id[..]),
if $resend_commitment && $resend_raa {
match $action_type {
RAACommitmentOrder::CommitmentFirst => { "commitment then RAA" },
RAACommitmentOrder::RevokeAndACKFirst => { "RAA then commitment" },
}
} else if $resend_commitment { "commitment" }
else if $resend_raa { "RAA" }
else { "nothing" },
(&$failed_forwards as &Vec<(PendingHTLCInfo, u64)>).len(),
(&$failed_fails as &Vec<(HTLCSource, PaymentHash, HTLCFailReason)>).len(),
(&$failed_finalized_fulfills as &Vec<HTLCSource>).len());
if !$resend_commitment {
debug_assert!($action_type == RAACommitmentOrder::RevokeAndACKFirst || !$resend_raa);
}
if !$resend_raa {
debug_assert!($action_type == RAACommitmentOrder::CommitmentFirst || !$resend_commitment);
}
$chan.monitor_update_failed($resend_raa, $resend_commitment, $resend_channel_ready, $failed_forwards, $failed_fails, $failed_finalized_fulfills);
(Err(MsgHandleErrInternal::from_chan_no_close(ChannelError::Ignore("Failed to update ChannelMonitor".to_owned()), *$chan_id)), false)
},
}
};
($self: ident, $err: expr, $channel_state: expr, $entry: expr, $action_type: path, $resend_raa: expr, $resend_commitment: expr, $resend_channel_ready: expr, $failed_forwards: expr, $failed_fails: expr, $failed_finalized_fulfills: expr) => { {
let (res, drop) = handle_monitor_err!($self, $err, $channel_state.short_to_id, $entry.get_mut(), $action_type, $resend_raa, $resend_commitment, $resend_channel_ready, $failed_forwards, $failed_fails, $failed_finalized_fulfills, $entry.key());
if drop {
$entry.remove_entry();
}
res
} };
($self: ident, $err: expr, $channel_state: expr, $entry: expr, $action_type: path, $chan_id: expr, COMMITMENT_UPDATE_ONLY) => { {
debug_assert!($action_type == RAACommitmentOrder::CommitmentFirst);
handle_monitor_err!($self, $err, $channel_state, $entry, $action_type, false, true, false, Vec::new(), Vec::new(), Vec::new(), $chan_id)
} };
($self: ident, $err: expr, $channel_state: expr, $entry: expr, $action_type: path, $chan_id: expr, NO_UPDATE) => {
handle_monitor_err!($self, $err, $channel_state, $entry, $action_type, false, false, false, Vec::new(), Vec::new(), Vec::new(), $chan_id)
};
($self: ident, $err: expr, $channel_state: expr, $entry: expr, $action_type: path, $resend_channel_ready: expr, OPTIONALLY_RESEND_FUNDING_LOCKED) => {
handle_monitor_err!($self, $err, $channel_state, $entry, $action_type, false, false, $resend_channel_ready, Vec::new(), Vec::new(), Vec::new())
};
($self: ident, $err: expr, $channel_state: expr, $entry: expr, $action_type: path, $resend_raa: expr, $resend_commitment: expr) => {
handle_monitor_err!($self, $err, $channel_state, $entry, $action_type, $resend_raa, $resend_commitment, false, Vec::new(), Vec::new(), Vec::new())
};
($self: ident, $err: expr, $channel_state: expr, $entry: expr, $action_type: path, $resend_raa: expr, $resend_commitment: expr, $failed_forwards: expr, $failed_fails: expr) => {
handle_monitor_err!($self, $err, $channel_state, $entry, $action_type, $resend_raa, $resend_commitment, false, $failed_forwards, $failed_fails, Vec::new())
};
}
macro_rules! return_monitor_err {
($self: ident, $err: expr, $channel_state: expr, $entry: expr, $action_type: path, $resend_raa: expr, $resend_commitment: expr) => {
return handle_monitor_err!($self, $err, $channel_state, $entry, $action_type, $resend_raa, $resend_commitment);
};
($self: ident, $err: expr, $channel_state: expr, $entry: expr, $action_type: path, $resend_raa: expr, $resend_commitment: expr, $failed_forwards: expr, $failed_fails: expr) => {
return handle_monitor_err!($self, $err, $channel_state, $entry, $action_type, $resend_raa, $resend_commitment, $failed_forwards, $failed_fails);
}
}
// Does not break in case of TemporaryFailure!
macro_rules! maybe_break_monitor_err {
($self: ident, $err: expr, $channel_state: expr, $entry: expr, $action_type: path, $resend_raa: expr, $resend_commitment: expr) => {
match (handle_monitor_err!($self, $err, $channel_state, $entry, $action_type, $resend_raa, $resend_commitment), $err) {
(e, ChannelMonitorUpdateErr::PermanentFailure) => {
break e;
},
(_, ChannelMonitorUpdateErr::TemporaryFailure) => { },
}
}
}
macro_rules! send_channel_ready {
($short_to_id: expr, $pending_msg_events: expr, $channel: expr, $channel_ready_msg: expr) => {
$pending_msg_events.push(events::MessageSendEvent::SendChannelReady {
node_id: $channel.get_counterparty_node_id(),
msg: $channel_ready_msg,
});
// Note that we may send a `channel_ready` multiple times for a channel if we reconnect, so
// we allow collisions, but we shouldn't ever be updating the channel ID pointed to.
let outbound_alias_insert = $short_to_id.insert($channel.outbound_scid_alias(), $channel.channel_id());
assert!(outbound_alias_insert.is_none() || outbound_alias_insert.unwrap() == $channel.channel_id(),
"SCIDs should never collide - ensure you weren't behind the chain tip by a full month when creating channels");
if let Some(real_scid) = $channel.get_short_channel_id() {
let scid_insert = $short_to_id.insert(real_scid, $channel.channel_id());
assert!(scid_insert.is_none() || scid_insert.unwrap() == $channel.channel_id(),
"SCIDs should never collide - ensure you weren't behind the chain tip by a full month when creating channels");
}
}
}
macro_rules! handle_chan_restoration_locked {
($self: ident, $channel_lock: expr, $channel_state: expr, $channel_entry: expr,
$raa: expr, $commitment_update: expr, $order: expr, $chanmon_update: expr,
$pending_forwards: expr, $funding_broadcastable: expr, $channel_ready: expr, $announcement_sigs: expr) => { {
let mut htlc_forwards = None;
let chanmon_update: Option<ChannelMonitorUpdate> = $chanmon_update; // Force type-checking to resolve
let chanmon_update_is_none = chanmon_update.is_none();
let counterparty_node_id = $channel_entry.get().get_counterparty_node_id();
let res = loop {
let forwards: Vec<(PendingHTLCInfo, u64)> = $pending_forwards; // Force type-checking to resolve
if !forwards.is_empty() {
htlc_forwards = Some(($channel_entry.get().get_short_channel_id().unwrap_or($channel_entry.get().outbound_scid_alias()),
$channel_entry.get().get_funding_txo().unwrap(), forwards));
}
if chanmon_update.is_some() {
// On reconnect, we, by definition, only resend a channel_ready if there have been
// no commitment updates, so the only channel monitor update which could also be
// associated with a channel_ready would be the funding_created/funding_signed
// monitor update. That monitor update failing implies that we won't send
// channel_ready until it's been updated, so we can't have a channel_ready and a
// monitor update here (so we don't bother to handle it correctly below).
assert!($channel_ready.is_none());
// A channel monitor update makes no sense without either a channel_ready or a
// commitment update to process after it. Since we can't have a channel_ready, we
// only bother to handle the monitor-update + commitment_update case below.
assert!($commitment_update.is_some());
}
if let Some(msg) = $channel_ready {
// Similar to the above, this implies that we're letting the channel_ready fly
// before it should be allowed to.
assert!(chanmon_update.is_none());
send_channel_ready!($channel_state.short_to_id, $channel_state.pending_msg_events, $channel_entry.get(), msg);
}
if let Some(msg) = $announcement_sigs {
$channel_state.pending_msg_events.push(events::MessageSendEvent::SendAnnouncementSignatures {
node_id: counterparty_node_id,
msg,
});
}
let funding_broadcastable: Option<Transaction> = $funding_broadcastable; // Force type-checking to resolve
if let Some(monitor_update) = chanmon_update {
// We only ever broadcast a funding transaction in response to a funding_signed
// message and the resulting monitor update. Thus, on channel_reestablish
// message handling we can't have a funding transaction to broadcast. When
// processing a monitor update finishing resulting in a funding broadcast, we
// cannot have a second monitor update, thus this case would indicate a bug.
assert!(funding_broadcastable.is_none());
// Given we were just reconnected or finished updating a channel monitor, the
// only case where we can get a new ChannelMonitorUpdate would be if we also
// have some commitment updates to send as well.
assert!($commitment_update.is_some());
if let Err(e) = $self.chain_monitor.update_channel($channel_entry.get().get_funding_txo().unwrap(), monitor_update) {
// channel_reestablish doesn't guarantee the order it returns is sensical
// for the messages it returns, but if we're setting what messages to
// re-transmit on monitor update success, we need to make sure it is sane.
let mut order = $order;
if $raa.is_none() {
order = RAACommitmentOrder::CommitmentFirst;
}
break handle_monitor_err!($self, e, $channel_state, $channel_entry, order, $raa.is_some(), true);
}
}
macro_rules! handle_cs { () => {
if let Some(update) = $commitment_update {
$channel_state.pending_msg_events.push(events::MessageSendEvent::UpdateHTLCs {
node_id: counterparty_node_id,
updates: update,
});
}
} }
macro_rules! handle_raa { () => {
if let Some(revoke_and_ack) = $raa {
$channel_state.pending_msg_events.push(events::MessageSendEvent::SendRevokeAndACK {
node_id: counterparty_node_id,
msg: revoke_and_ack,
});
}
} }
match $order {
RAACommitmentOrder::CommitmentFirst => {
handle_cs!();
handle_raa!();
},
RAACommitmentOrder::RevokeAndACKFirst => {
handle_raa!();
handle_cs!();
},
}
if let Some(tx) = funding_broadcastable {
log_info!($self.logger, "Broadcasting funding transaction with txid {}", tx.txid());
$self.tx_broadcaster.broadcast_transaction(&tx);
}
break Ok(());
};
if chanmon_update_is_none {
// If there was no ChannelMonitorUpdate, we should never generate an Err in the res loop
// above. Doing so would imply calling handle_err!() from channel_monitor_updated() which
// should *never* end up calling back to `chain_monitor.update_channel()`.
assert!(res.is_ok());
}
(htlc_forwards, res, counterparty_node_id)
} }
}
macro_rules! post_handle_chan_restoration {
($self: ident, $locked_res: expr) => { {
let (htlc_forwards, res, counterparty_node_id) = $locked_res;
let _ = handle_error!($self, res, counterparty_node_id);
if let Some(forwards) = htlc_forwards {
$self.forward_htlcs(&mut [forwards][..]);
}
} }
}
impl<Signer: Sign, M: Deref, T: Deref, K: Deref, F: Deref, L: Deref> ChannelManager<Signer, M, T, K, F, L>
where M::Target: chain::Watch<Signer>,
T::Target: BroadcasterInterface,
K::Target: KeysInterface<Signer = Signer>,
F::Target: FeeEstimator,
L::Target: Logger,
{
/// Constructs a new ChannelManager to hold several channels and route between them.
///
/// This is the main "logic hub" for all channel-related actions, and implements
/// ChannelMessageHandler.
///
/// Non-proportional fees are fixed according to our risk using the provided fee estimator.
///
/// Users need to notify the new ChannelManager when a new block is connected or
/// disconnected using its `block_connected` and `block_disconnected` methods, starting
/// from after `params.latest_hash`.
pub fn new(fee_est: F, chain_monitor: M, tx_broadcaster: T, logger: L, keys_manager: K, config: UserConfig, params: ChainParameters) -> Self {
let mut secp_ctx = Secp256k1::new();
secp_ctx.seeded_randomize(&keys_manager.get_secure_random_bytes());
let inbound_pmt_key_material = keys_manager.get_inbound_payment_key_material();
let expanded_inbound_key = inbound_payment::ExpandedKey::new(&inbound_pmt_key_material);
ChannelManager {
default_configuration: config.clone(),
genesis_hash: genesis_block(params.network).header.block_hash(),
fee_estimator: fee_est,
chain_monitor,
tx_broadcaster,
best_block: RwLock::new(params.best_block),
channel_state: Mutex::new(ChannelHolder{
by_id: HashMap::new(),
short_to_id: HashMap::new(),
forward_htlcs: HashMap::new(),
claimable_htlcs: HashMap::new(),
pending_msg_events: Vec::new(),
}),
outbound_scid_aliases: Mutex::new(HashSet::new()),
pending_inbound_payments: Mutex::new(HashMap::new()),
pending_outbound_payments: Mutex::new(HashMap::new()),
our_network_key: keys_manager.get_node_secret(Recipient::Node).unwrap(),
our_network_pubkey: PublicKey::from_secret_key(&secp_ctx, &keys_manager.get_node_secret(Recipient::Node).unwrap()),
secp_ctx,
inbound_payment_key: expanded_inbound_key,
fake_scid_rand_bytes: keys_manager.get_secure_random_bytes(),
last_node_announcement_serial: AtomicUsize::new(0),
highest_seen_timestamp: AtomicUsize::new(0),
per_peer_state: RwLock::new(HashMap::new()),
pending_events: Mutex::new(Vec::new()),
pending_background_events: Mutex::new(Vec::new()),
total_consistency_lock: RwLock::new(()),
persistence_notifier: PersistenceNotifier::new(),
keys_manager,
logger,
}
}
/// Gets the current configuration applied to all new channels, as
pub fn get_current_default_configuration(&self) -> &UserConfig {
&self.default_configuration
}
fn create_and_insert_outbound_scid_alias(&self) -> u64 {
let height = self.best_block.read().unwrap().height();
let mut outbound_scid_alias = 0;
let mut i = 0;
loop {
if cfg!(fuzzing) { // fuzzing chacha20 doesn't use the key at all so we always get the same alias
outbound_scid_alias += 1;
} else {
outbound_scid_alias = fake_scid::Namespace::OutboundAlias.get_fake_scid(height, &self.genesis_hash, &self.fake_scid_rand_bytes, &self.keys_manager);
}
if outbound_scid_alias != 0 && self.outbound_scid_aliases.lock().unwrap().insert(outbound_scid_alias) {
break;
}
i += 1;
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"); }
}
outbound_scid_alias
}
/// Creates a new outbound channel to the given remote node and with the given value.
///
/// `user_channel_id` will be provided back as in
/// [`Event::FundingGenerationReady::user_channel_id`] to allow tracking of which events
/// correspond with which `create_channel` call. Note that the `user_channel_id` defaults to 0
/// for inbound channels, so you may wish to avoid using 0 for `user_channel_id` here.
/// `user_channel_id` has no meaning inside of LDK, it is simply copied to events and otherwise
/// ignored.
///
/// Raises [`APIError::APIMisuseError`] when `channel_value_satoshis` > 2**24 or `push_msat` is
/// greater than `channel_value_satoshis * 1k` or `channel_value_satoshis < 1000`.
///
/// Note that we do not check if you are currently connected to the given peer. If no
/// connection is available, the outbound `open_channel` message may fail to send, resulting in
/// the channel eventually being silently forgotten (dropped on reload).
///
/// Returns the new Channel's temporary `channel_id`. This ID will appear as
/// [`Event::FundingGenerationReady::temporary_channel_id`] and in
/// [`ChannelDetails::channel_id`] until after
/// [`ChannelManager::funding_transaction_generated`] is called, swapping the Channel's ID for
/// one derived from the funding transaction's TXID. If the counterparty rejects the channel
/// immediately, this temporary ID will appear in [`Event::ChannelClosed::channel_id`].
///
/// [`Event::FundingGenerationReady::user_channel_id`]: events::Event::FundingGenerationReady::user_channel_id
/// [`Event::FundingGenerationReady::temporary_channel_id`]: events::Event::FundingGenerationReady::temporary_channel_id
/// [`Event::ChannelClosed::channel_id`]: events::Event::ChannelClosed::channel_id
pub fn create_channel(&self, their_network_key: PublicKey, channel_value_satoshis: u64, push_msat: u64, user_channel_id: u64, override_config: Option<UserConfig>) -> Result<[u8; 32], APIError> {
if channel_value_satoshis < 1000 {
return Err(APIError::APIMisuseError { err: format!("Channel value must be at least 1000 satoshis. It was {}", channel_value_satoshis) });
}
let channel = {
let per_peer_state = self.per_peer_state.read().unwrap();
match per_peer_state.get(&their_network_key) {
Some(peer_state) => {
let outbound_scid_alias = self.create_and_insert_outbound_scid_alias();
let peer_state = peer_state.lock().unwrap();
let their_features = &peer_state.latest_features;
let config = if override_config.is_some() { override_config.as_ref().unwrap() } else { &self.default_configuration };
match Channel::new_outbound(&self.fee_estimator, &self.keys_manager, their_network_key,
their_features, channel_value_satoshis, push_msat, user_channel_id, config,
self.best_block.read().unwrap().height(), outbound_scid_alias)
{
Ok(res) => res,
Err(e) => {
self.outbound_scid_aliases.lock().unwrap().remove(&outbound_scid_alias);
return Err(e);
},
}
},
None => return Err(APIError::ChannelUnavailable { err: format!("Not connected to node: {}", their_network_key) }),
}
};
let res = channel.get_open_channel(self.genesis_hash.clone());
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
// We want to make sure the lock is actually acquired by PersistenceNotifierGuard.
debug_assert!(&self.total_consistency_lock.try_write().is_err());
let temporary_channel_id = channel.channel_id();
let mut channel_state = self.channel_state.lock().unwrap();
match channel_state.by_id.entry(temporary_channel_id) {
hash_map::Entry::Occupied(_) => {
if cfg!(fuzzing) {
return Err(APIError::APIMisuseError { err: "Fuzzy bad RNG".to_owned() });
} else {
panic!("RNG is bad???");
}
},
hash_map::Entry::Vacant(entry) => { entry.insert(channel); }
}
channel_state.pending_msg_events.push(events::MessageSendEvent::SendOpenChannel {
node_id: their_network_key,
msg: res,
});
Ok(temporary_channel_id)
}
fn list_channels_with_filter<Fn: FnMut(&(&[u8; 32], &Channel<Signer>)) -> bool>(&self, f: Fn) -> Vec<ChannelDetails> {
let mut res = Vec::new();
{
let channel_state = self.channel_state.lock().unwrap();
res.reserve(channel_state.by_id.len());
for (channel_id, channel) in channel_state.by_id.iter().filter(f) {
let balance = channel.get_available_balances();
let (to_remote_reserve_satoshis, to_self_reserve_satoshis) =
channel.get_holder_counterparty_selected_channel_reserve_satoshis();
res.push(ChannelDetails {
channel_id: (*channel_id).clone(),
counterparty: ChannelCounterparty {
node_id: channel.get_counterparty_node_id(),
features: InitFeatures::empty(),
unspendable_punishment_reserve: to_remote_reserve_satoshis,
forwarding_info: channel.counterparty_forwarding_info(),
// Ensures that we have actually received the `htlc_minimum_msat` value
// from the counterparty through the `OpenChannel` or `AcceptChannel`
// message (as they are always the first message from the counterparty).
// Else `Channel::get_counterparty_htlc_minimum_msat` could return the
// default `0` value set by `Channel::new_outbound`.
outbound_htlc_minimum_msat: if channel.have_received_message() {
Some(channel.get_counterparty_htlc_minimum_msat()) } else { None },
outbound_htlc_maximum_msat: channel.get_counterparty_htlc_maximum_msat(),
},
funding_txo: channel.get_funding_txo(),
// Note that accept_channel (or open_channel) is always the first message, so
// `have_received_message` indicates that type negotiation has completed.
channel_type: if channel.have_received_message() { Some(channel.get_channel_type().clone()) } else { None },
short_channel_id: channel.get_short_channel_id(),
outbound_scid_alias: if channel.is_usable() { Some(channel.outbound_scid_alias()) } else { None },
inbound_scid_alias: channel.latest_inbound_scid_alias(),
channel_value_satoshis: channel.get_value_satoshis(),
unspendable_punishment_reserve: to_self_reserve_satoshis,
balance_msat: balance.balance_msat,
inbound_capacity_msat: balance.inbound_capacity_msat,
outbound_capacity_msat: balance.outbound_capacity_msat,
next_outbound_htlc_limit_msat: balance.next_outbound_htlc_limit_msat,
user_channel_id: channel.get_user_id(),
confirmations_required: channel.minimum_depth(),
force_close_spend_delay: channel.get_counterparty_selected_contest_delay(),
is_outbound: channel.is_outbound(),
is_channel_ready: channel.is_usable(),
is_usable: channel.is_live(),
is_public: channel.should_announce(),
inbound_htlc_minimum_msat: Some(channel.get_holder_htlc_minimum_msat()),
inbound_htlc_maximum_msat: channel.get_holder_htlc_maximum_msat()
});
}
}
let per_peer_state = self.per_peer_state.read().unwrap();
for chan in res.iter_mut() {
if let Some(peer_state) = per_peer_state.get(&chan.counterparty.node_id) {
chan.counterparty.features = peer_state.lock().unwrap().latest_features.clone();
}
}
res
}
/// Gets the list of open channels, in random order. See ChannelDetail field documentation for
/// more information.
pub fn list_channels(&self) -> Vec<ChannelDetails> {
self.list_channels_with_filter(|_| true)
}
/// Gets the list of usable channels, in random order. Useful as an argument to
/// get_route to ensure non-announced channels are used.
///
/// These are guaranteed to have their [`ChannelDetails::is_usable`] value set to true, see the
/// documentation for [`ChannelDetails::is_usable`] for more info on exactly what the criteria
/// are.
pub fn list_usable_channels(&self) -> Vec<ChannelDetails> {
// Note we use is_live here instead of usable which leads to somewhat confused
// internal/external nomenclature, but that's ok cause that's probably what the user
// really wanted anyway.
self.list_channels_with_filter(|&(_, ref channel)| channel.is_live())
}
/// Helper function that issues the channel close events
fn issue_channel_close_events(&self, channel: &Channel<Signer>, closure_reason: ClosureReason) {
let mut pending_events_lock = self.pending_events.lock().unwrap();
match channel.unbroadcasted_funding() {
Some(transaction) => {
pending_events_lock.push(events::Event::DiscardFunding { channel_id: channel.channel_id(), transaction })
},
None => {},
}
pending_events_lock.push(events::Event::ChannelClosed {
channel_id: channel.channel_id(),
user_channel_id: channel.get_user_id(),
reason: closure_reason
});
}
fn close_channel_internal(&self, channel_id: &[u8; 32], counterparty_node_id: &PublicKey, target_feerate_sats_per_1000_weight: Option<u32>) -> Result<(), APIError> {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
let mut failed_htlcs: Vec<(HTLCSource, PaymentHash)>;
let result: Result<(), _> = loop {
let mut channel_state_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_state_lock;
match channel_state.by_id.entry(channel_id.clone()) {
hash_map::Entry::Occupied(mut chan_entry) => {
if *counterparty_node_id != chan_entry.get().get_counterparty_node_id(){
return Err(APIError::APIMisuseError { err: "The passed counterparty_node_id doesn't match the channel's counterparty node_id".to_owned() });
}
let per_peer_state = self.per_peer_state.read().unwrap();
let (shutdown_msg, monitor_update, htlcs) = match per_peer_state.get(&counterparty_node_id) {
Some(peer_state) => {
let peer_state = peer_state.lock().unwrap();
let their_features = &peer_state.latest_features;
chan_entry.get_mut().get_shutdown(&self.keys_manager, their_features, target_feerate_sats_per_1000_weight)?
},
None => return Err(APIError::ChannelUnavailable { err: format!("Not connected to node: {}", counterparty_node_id) }),
};
failed_htlcs = htlcs;
// Update the monitor with the shutdown script if necessary.
if let Some(monitor_update) = monitor_update {
if let Err(e) = self.chain_monitor.update_channel(chan_entry.get().get_funding_txo().unwrap(), monitor_update) {
let (result, is_permanent) =
handle_monitor_err!(self, e, channel_state.short_to_id, chan_entry.get_mut(), RAACommitmentOrder::CommitmentFirst, chan_entry.key(), NO_UPDATE);
if is_permanent {
remove_channel!(self, channel_state, chan_entry);
break result;
}
}
}
channel_state.pending_msg_events.push(events::MessageSendEvent::SendShutdown {
node_id: *counterparty_node_id,
msg: shutdown_msg
});
if chan_entry.get().is_shutdown() {
let channel = remove_channel!(self, channel_state, chan_entry);
if let Ok(channel_update) = self.get_channel_update_for_broadcast(&channel) {
channel_state.pending_msg_events.push(events::MessageSendEvent::BroadcastChannelUpdate {
msg: channel_update
});
}
self.issue_channel_close_events(&channel, ClosureReason::HolderForceClosed);
}
break Ok(());
},
hash_map::Entry::Vacant(_) => return Err(APIError::ChannelUnavailable{err: "No such channel".to_owned()})
}
};
for htlc_source in failed_htlcs.drain(..) {
self.fail_htlc_backwards_internal(self.channel_state.lock().unwrap(), htlc_source.0, &htlc_source.1, HTLCFailReason::Reason { failure_code: 0x4000 | 8, data: Vec::new() });
}
let _ = handle_error!(self, result, *counterparty_node_id);
Ok(())
}
/// Begins the process of closing a channel. After this call (plus some timeout), no new HTLCs
/// will be accepted on the given channel, and after additional timeout/the closing of all
/// pending HTLCs, the channel will be closed on chain.
///
/// * If we are the channel initiator, we will pay between our [`Background`] and
/// [`ChannelConfig::force_close_avoidance_max_fee_satoshis`] plus our [`Normal`] fee
/// estimate.
/// * If our counterparty is the channel initiator, we will require a channel closing
/// transaction feerate of at least our [`Background`] feerate or the feerate which
/// would appear on a force-closure transaction, whichever is lower. We will allow our
/// counterparty to pay as much fee as they'd like, however.
///
/// May generate a SendShutdown message event on success, which should be relayed.
///
/// [`ChannelConfig::force_close_avoidance_max_fee_satoshis`]: crate::util::config::ChannelConfig::force_close_avoidance_max_fee_satoshis
/// [`Background`]: crate::chain::chaininterface::ConfirmationTarget::Background
/// [`Normal`]: crate::chain::chaininterface::ConfirmationTarget::Normal
pub fn close_channel(&self, channel_id: &[u8; 32], counterparty_node_id: &PublicKey) -> Result<(), APIError> {
self.close_channel_internal(channel_id, counterparty_node_id, None)
}
/// Begins the process of closing a channel. After this call (plus some timeout), no new HTLCs
/// will be accepted on the given channel, and after additional timeout/the closing of all
/// pending HTLCs, the channel will be closed on chain.
///
/// `target_feerate_sat_per_1000_weight` has different meanings depending on if we initiated
/// the channel being closed or not:
/// * If we are the channel initiator, we will pay at least this feerate on the closing
/// transaction. The upper-bound is set by
/// [`ChannelConfig::force_close_avoidance_max_fee_satoshis`] plus our [`Normal`] fee
/// estimate (or `target_feerate_sat_per_1000_weight`, if it is greater).
/// * If our counterparty is the channel initiator, we will refuse to accept a channel closure
/// transaction feerate below `target_feerate_sat_per_1000_weight` (or the feerate which
/// will appear on a force-closure transaction, whichever is lower).
///
/// May generate a SendShutdown message event on success, which should be relayed.
///
/// [`ChannelConfig::force_close_avoidance_max_fee_satoshis`]: crate::util::config::ChannelConfig::force_close_avoidance_max_fee_satoshis
/// [`Background`]: crate::chain::chaininterface::ConfirmationTarget::Background
/// [`Normal`]: crate::chain::chaininterface::ConfirmationTarget::Normal
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> {
self.close_channel_internal(channel_id, counterparty_node_id, Some(target_feerate_sats_per_1000_weight))
}
#[inline]
fn finish_force_close_channel(&self, shutdown_res: ShutdownResult) {
let (monitor_update_option, mut failed_htlcs) = shutdown_res;
log_debug!(self.logger, "Finishing force-closure of channel with {} HTLCs to fail", failed_htlcs.len());
for htlc_source in failed_htlcs.drain(..) {
self.fail_htlc_backwards_internal(self.channel_state.lock().unwrap(), htlc_source.0, &htlc_source.1, HTLCFailReason::Reason { failure_code: 0x4000 | 8, data: Vec::new() });
}
if let Some((funding_txo, monitor_update)) = monitor_update_option {
// There isn't anything we can do if we get an update failure - we're already
// force-closing. The monitor update on the required in-memory copy should broadcast
// the latest local state, which is the best we can do anyway. Thus, it is safe to
// ignore the result here.
let _ = self.chain_monitor.update_channel(funding_txo, monitor_update);
}
}
/// `peer_msg` should be set when we receive a message from a peer, but not set when the
/// user closes, which will be re-exposed as the `ChannelClosed` reason.
fn force_close_channel_with_peer(&self, channel_id: &[u8; 32], peer_node_id: &PublicKey, peer_msg: Option<&String>) -> Result<PublicKey, APIError> {
let mut chan = {
let mut channel_state_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_state_lock;
if let hash_map::Entry::Occupied(chan) = channel_state.by_id.entry(channel_id.clone()) {
if chan.get().get_counterparty_node_id() != *peer_node_id {
return Err(APIError::ChannelUnavailable{err: "No such channel".to_owned()});
}
if let Some(peer_msg) = peer_msg {
self.issue_channel_close_events(chan.get(),ClosureReason::CounterpartyForceClosed { peer_msg: peer_msg.to_string() });
} else {
self.issue_channel_close_events(chan.get(),ClosureReason::HolderForceClosed);
}
remove_channel!(self, channel_state, chan)
} else {
return Err(APIError::ChannelUnavailable{err: "No such channel".to_owned()});
}
};
log_error!(self.logger, "Force-closing channel {}", log_bytes!(channel_id[..]));
self.finish_force_close_channel(chan.force_shutdown(true));
if let Ok(update) = self.get_channel_update_for_broadcast(&chan) {
let mut channel_state = self.channel_state.lock().unwrap();
channel_state.pending_msg_events.push(events::MessageSendEvent::BroadcastChannelUpdate {
msg: update
});
}
Ok(chan.get_counterparty_node_id())
}
/// Force closes a channel, immediately broadcasting the latest local commitment transaction to
/// the chain and rejecting new HTLCs on the given channel. Fails if `channel_id` is unknown to
/// the manager, or if the `counterparty_node_id` isn't the counterparty of the corresponding
/// channel.
pub fn force_close_channel(&self, channel_id: &[u8; 32], counterparty_node_id: &PublicKey) -> Result<(), APIError> {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
match self.force_close_channel_with_peer(channel_id, counterparty_node_id, None) {
Ok(counterparty_node_id) => {
self.channel_state.lock().unwrap().pending_msg_events.push(
events::MessageSendEvent::HandleError {
node_id: counterparty_node_id,
action: msgs::ErrorAction::SendErrorMessage {
msg: msgs::ErrorMessage { channel_id: *channel_id, data: "Channel force-closed".to_owned() }
},
}
);
Ok(())
},
Err(e) => Err(e)
}
}
/// Force close all channels, immediately broadcasting the latest local commitment transaction
/// for each to the chain and rejecting new HTLCs on each.
pub fn force_close_all_channels(&self) {
for chan in self.list_channels() {
let _ = self.force_close_channel(&chan.channel_id, &chan.counterparty.node_id);
}
}
fn construct_recv_pending_htlc_info(&self, hop_data: msgs::OnionHopData, shared_secret: [u8; 32],
payment_hash: PaymentHash, amt_msat: u64, cltv_expiry: u32, phantom_shared_secret: Option<[u8; 32]>) -> Result<PendingHTLCInfo, ReceiveError>
{
// final_incorrect_cltv_expiry
if hop_data.outgoing_cltv_value != cltv_expiry {
return Err(ReceiveError {
msg: "Upstream node set CLTV to the wrong value",
err_code: 18,
err_data: byte_utils::be32_to_array(cltv_expiry).to_vec()
})
}
// final_expiry_too_soon
// We have to have some headroom to broadcast on chain if we have the preimage, so make sure
// we have at least HTLC_FAIL_BACK_BUFFER blocks to go.
// Also, ensure that, in the case of an unknown preimage for the received payment hash, our
// payment logic has enough time to fail the HTLC backward before our onchain logic triggers a
// channel closure (see HTLC_FAIL_BACK_BUFFER rationale).
if (hop_data.outgoing_cltv_value as u64) <= self.best_block.read().unwrap().height() as u64 + HTLC_FAIL_BACK_BUFFER as u64 + 1 {
return Err(ReceiveError {
err_code: 17,
err_data: Vec::new(),
msg: "The final CLTV expiry is too soon to handle",
});
}
if hop_data.amt_to_forward > amt_msat {
return Err(ReceiveError {
err_code: 19,
err_data: byte_utils::be64_to_array(amt_msat).to_vec(),
msg: "Upstream node sent less than we were supposed to receive in payment",
});
}
let routing = match hop_data.format {
msgs::OnionHopDataFormat::Legacy { .. } => {
return Err(ReceiveError {
err_code: 0x4000|0x2000|3,
err_data: Vec::new(),
msg: "We require payment_secrets",
});
},
msgs::OnionHopDataFormat::NonFinalNode { .. } => {
return Err(ReceiveError {
err_code: 0x4000|22,
err_data: Vec::new(),
msg: "Got non final data with an HMAC of 0",
});
},
msgs::OnionHopDataFormat::FinalNode { payment_data, keysend_preimage } => {
if payment_data.is_some() && keysend_preimage.is_some() {
return Err(ReceiveError {
err_code: 0x4000|22,
err_data: Vec::new(),
msg: "We don't support MPP keysend payments",
});
} else if let Some(data) = payment_data {
PendingHTLCRouting::Receive {
payment_data: data,
incoming_cltv_expiry: hop_data.outgoing_cltv_value,
phantom_shared_secret,
}
} else if let Some(payment_preimage) = keysend_preimage {
// We need to check that the sender knows the keysend preimage before processing this
// payment further. Otherwise, an intermediary routing hop forwarding non-keysend-HTLC X
// could discover the final destination of X, by probing the adjacent nodes on the route
// with a keysend payment of identical payment hash to X and observing the processing
// time discrepancies due to a hash collision with X.
let hashed_preimage = PaymentHash(Sha256::hash(&payment_preimage.0).into_inner());
if hashed_preimage != payment_hash {
return Err(ReceiveError {
err_code: 0x4000|22,
err_data: Vec::new(),
msg: "Payment preimage didn't match payment hash",
});
}
PendingHTLCRouting::ReceiveKeysend {
payment_preimage,
incoming_cltv_expiry: hop_data.outgoing_cltv_value,
}
} else {
return Err(ReceiveError {
err_code: 0x4000|0x2000|3,
err_data: Vec::new(),
msg: "We require payment_secrets",
});
}
},
};
Ok(PendingHTLCInfo {
routing,
payment_hash,
incoming_shared_secret: shared_secret,
amt_to_forward: amt_msat,
outgoing_cltv_value: hop_data.outgoing_cltv_value,
})
}
fn decode_update_add_htlc_onion(&self, msg: &msgs::UpdateAddHTLC) -> (PendingHTLCStatus, MutexGuard<ChannelHolder<Signer>>) {
macro_rules! return_malformed_err {
($msg: expr, $err_code: expr) => {
{
log_info!(self.logger, "Failed to accept/forward incoming HTLC: {}", $msg);
return (PendingHTLCStatus::Fail(HTLCFailureMsg::Malformed(msgs::UpdateFailMalformedHTLC {
channel_id: msg.channel_id,
htlc_id: msg.htlc_id,
sha256_of_onion: Sha256::hash(&msg.onion_routing_packet.hop_data).into_inner(),
failure_code: $err_code,
})), self.channel_state.lock().unwrap());
}
}
}
if let Err(_) = msg.onion_routing_packet.public_key {
return_malformed_err!("invalid ephemeral pubkey", 0x8000 | 0x4000 | 6);
}
let shared_secret = SharedSecret::new(&msg.onion_routing_packet.public_key.unwrap(), &self.our_network_key).secret_bytes();
if msg.onion_routing_packet.version != 0 {
//TODO: Spec doesn't indicate if we should only hash hop_data here (and in other
//sha256_of_onion error data packets), or the entire onion_routing_packet. Either way,
//the hash doesn't really serve any purpose - in the case of hashing all data, the
//receiving node would have to brute force to figure out which version was put in the
//packet by the node that send us the message, in the case of hashing the hop_data, the
//node knows the HMAC matched, so they already know what is there...
return_malformed_err!("Unknown onion packet version", 0x8000 | 0x4000 | 4);
}
let mut channel_state = None;
macro_rules! return_err {
($msg: expr, $err_code: expr, $data: expr) => {
{
log_info!(self.logger, "Failed to accept/forward incoming HTLC: {}", $msg);
if channel_state.is_none() {
channel_state = Some(self.channel_state.lock().unwrap());
}
return (PendingHTLCStatus::Fail(HTLCFailureMsg::Relay(msgs::UpdateFailHTLC {
channel_id: msg.channel_id,
htlc_id: msg.htlc_id,
reason: onion_utils::build_first_hop_failure_packet(&shared_secret, $err_code, $data),
})), channel_state.unwrap());
}
}
}
let next_hop = match onion_utils::decode_next_hop(shared_secret, &msg.onion_routing_packet.hop_data[..], msg.onion_routing_packet.hmac, msg.payment_hash) {
Ok(res) => res,
Err(onion_utils::OnionDecodeErr::Malformed { err_msg, err_code }) => {
return_malformed_err!(err_msg, err_code);
},
Err(onion_utils::OnionDecodeErr::Relay { err_msg, err_code }) => {
return_err!(err_msg, err_code, &[0; 0]);
},
};
let pending_forward_info = match next_hop {
onion_utils::Hop::Receive(next_hop_data) => {
// OUR PAYMENT!
match self.construct_recv_pending_htlc_info(next_hop_data, shared_secret, msg.payment_hash, msg.amount_msat, msg.cltv_expiry, None) {
Ok(info) => {
// Note that we could obviously respond immediately with an update_fulfill_htlc
// message, however that would leak that we are the recipient of this payment, so
// instead we stay symmetric with the forwarding case, only responding (after a
// delay) once they've send us a commitment_signed!
PendingHTLCStatus::Forward(info)
},
Err(ReceiveError { err_code, err_data, msg }) => return_err!(msg, err_code, &err_data)
}
},
onion_utils::Hop::Forward { next_hop_data, next_hop_hmac, new_packet_bytes } => {
let mut new_pubkey = msg.onion_routing_packet.public_key.unwrap();
let blinding_factor = {
let mut sha = Sha256::engine();
sha.input(&new_pubkey.serialize()[..]);
sha.input(&shared_secret);
Sha256::from_engine(sha).into_inner()
};
let public_key = if let Err(e) = new_pubkey.mul_assign(&self.secp_ctx, &blinding_factor[..]) {
Err(e)
} else { Ok(new_pubkey) };
let outgoing_packet = msgs::OnionPacket {
version: 0,
public_key,
hop_data: new_packet_bytes,
hmac: next_hop_hmac.clone(),
};
let short_channel_id = match next_hop_data.format {
msgs::OnionHopDataFormat::Legacy { short_channel_id } => short_channel_id,
msgs::OnionHopDataFormat::NonFinalNode { short_channel_id } => short_channel_id,
msgs::OnionHopDataFormat::FinalNode { .. } => {
return_err!("Final Node OnionHopData provided for us as an intermediary node", 0x4000 | 22, &[0;0]);
},
};
PendingHTLCStatus::Forward(PendingHTLCInfo {
routing: PendingHTLCRouting::Forward {
onion_packet: outgoing_packet,
short_channel_id,
},
payment_hash: msg.payment_hash.clone(),
incoming_shared_secret: shared_secret,
amt_to_forward: next_hop_data.amt_to_forward,
outgoing_cltv_value: next_hop_data.outgoing_cltv_value,
})
}
};
channel_state = Some(self.channel_state.lock().unwrap());
if let &PendingHTLCStatus::Forward(PendingHTLCInfo { ref routing, ref amt_to_forward, ref outgoing_cltv_value, .. }) = &pending_forward_info {
// If short_channel_id is 0 here, we'll reject the HTLC as there cannot be a channel
// with a short_channel_id of 0. This is important as various things later assume
// short_channel_id is non-0 in any ::Forward.
if let &PendingHTLCRouting::Forward { ref short_channel_id, .. } = routing {
let id_option = channel_state.as_ref().unwrap().short_to_id.get(&short_channel_id).cloned();
if let Some((err, code, chan_update)) = loop {
let forwarding_id_opt = match id_option {
None => { // unknown_next_peer
// Note that this is likely a timing oracle for detecting whether an scid is a
// phantom.
if fake_scid::is_valid_phantom(&self.fake_scid_rand_bytes, *short_channel_id) {
None
} else {
break Some(("Don't have available channel for forwarding as requested.", 0x4000 | 10, None));
}
},
Some(id) => Some(id.clone()),
};
let (chan_update_opt, forwardee_cltv_expiry_delta) = if let Some(forwarding_id) = forwarding_id_opt {
let chan = channel_state.as_mut().unwrap().by_id.get_mut(&forwarding_id).unwrap();
if !chan.should_announce() && !self.default_configuration.accept_forwards_to_priv_channels {
// Note that the behavior here should be identical to the above block - we
// should NOT reveal the existence or non-existence of a private channel if
// we don't allow forwards outbound over them.
break Some(("Refusing to forward to a private channel based on our config.", 0x4000 | 10, None));
}
if chan.get_channel_type().supports_scid_privacy() && *short_channel_id != chan.outbound_scid_alias() {
// `option_scid_alias` (referred to in LDK as `scid_privacy`) means
// "refuse to forward unless the SCID alias was used", so we pretend
// we don't have the channel here.
break Some(("Refusing to forward over real channel SCID as our counterparty requested.", 0x4000 | 10, None));
}
let chan_update_opt = self.get_channel_update_for_onion(*short_channel_id, chan).ok();
// Note that we could technically not return an error yet here and just hope
// that the connection is reestablished or monitor updated by the time we get
// around to doing the actual forward, but better to fail early if we can and
// hopefully an attacker trying to path-trace payments cannot make this occur
// on a small/per-node/per-channel scale.
if !chan.is_live() { // channel_disabled
break Some(("Forwarding channel is not in a ready state.", 0x1000 | 20, chan_update_opt));
}
if *amt_to_forward < chan.get_counterparty_htlc_minimum_msat() { // amount_below_minimum
break Some(("HTLC amount was below the htlc_minimum_msat", 0x1000 | 11, chan_update_opt));
}
let fee = amt_to_forward.checked_mul(chan.get_fee_proportional_millionths() as u64)
.and_then(|prop_fee| { (prop_fee / 1000000)
.checked_add(chan.get_outbound_forwarding_fee_base_msat() as u64) });
if fee.is_none() || msg.amount_msat < fee.unwrap() || (msg.amount_msat - fee.unwrap()) < *amt_to_forward { // fee_insufficient
break Some(("Prior hop has deviated from specified fees parameters or origin node has obsolete ones", 0x1000 | 12, chan_update_opt));
}
(chan_update_opt, chan.get_cltv_expiry_delta())
} else { (None, MIN_CLTV_EXPIRY_DELTA) };
if (msg.cltv_expiry as u64) < (*outgoing_cltv_value) as u64 + forwardee_cltv_expiry_delta as u64 { // incorrect_cltv_expiry
break Some(("Forwarding node has tampered with the intended HTLC values or origin node has an obsolete cltv_expiry_delta", 0x1000 | 13, chan_update_opt));
}
let cur_height = self.best_block.read().unwrap().height() + 1;
// Theoretically, channel counterparty shouldn't send us a HTLC expiring now,
// but we want to be robust wrt to counterparty packet sanitization (see
// HTLC_FAIL_BACK_BUFFER rationale).
if msg.cltv_expiry <= cur_height + HTLC_FAIL_BACK_BUFFER as u32 { // expiry_too_soon
break Some(("CLTV expiry is too close", 0x1000 | 14, chan_update_opt));
}
if msg.cltv_expiry > cur_height + CLTV_FAR_FAR_AWAY as u32 { // expiry_too_far
break Some(("CLTV expiry is too far in the future", 21, None));
}
// If the HTLC expires ~now, don't bother trying to forward it to our
// counterparty. They should fail it anyway, but we don't want to bother with
// the round-trips or risk them deciding they definitely want the HTLC and
// force-closing to ensure they get it if we're offline.
// We previously had a much more aggressive check here which tried to ensure
// our counterparty receives an HTLC which has *our* risk threshold met on it,
// but there is no need to do that, and since we're a bit conservative with our
// risk threshold it just results in failing to forward payments.
if (*outgoing_cltv_value) as u64 <= (cur_height + LATENCY_GRACE_PERIOD_BLOCKS) as u64 {
break Some(("Outgoing CLTV value is too soon", 0x1000 | 14, chan_update_opt));
}
break None;
}
{
let mut res = VecWriter(Vec::with_capacity(chan_update.serialized_length() + 2 + 8 + 2));
if let Some(chan_update) = chan_update {
if code == 0x1000 | 11 || code == 0x1000 | 12 {
msg.amount_msat.write(&mut res).expect("Writes cannot fail");
}
else if code == 0x1000 | 13 {
msg.cltv_expiry.write(&mut res).expect("Writes cannot fail");
}
else if code == 0x1000 | 20 {
// TODO: underspecified, follow https://github.com/lightning/bolts/issues/791
0u16.write(&mut res).expect("Writes cannot fail");
}
(chan_update.serialized_length() as u16 + 2).write(&mut res).expect("Writes cannot fail");
msgs::ChannelUpdate::TYPE.write(&mut res).expect("Writes cannot fail");
chan_update.write(&mut res).expect("Writes cannot fail");
}
return_err!(err, code, &res.0[..]);
}
}
}
(pending_forward_info, channel_state.unwrap())
}
/// Gets the current channel_update for the given channel. This first checks if the channel is
/// public, and thus should be called whenever the result is going to be passed out in a
/// [`MessageSendEvent::BroadcastChannelUpdate`] event.
///
/// May be called with channel_state already locked!
fn get_channel_update_for_broadcast(&self, chan: &Channel<Signer>) -> Result<msgs::ChannelUpdate, LightningError> {
if !chan.should_announce() {
return Err(LightningError {
err: "Cannot broadcast a channel_update for a private channel".to_owned(),
action: msgs::ErrorAction::IgnoreError
});
}
if chan.get_short_channel_id().is_none() {
return Err(LightningError{err: "Channel not yet established".to_owned(), action: msgs::ErrorAction::IgnoreError});
}
log_trace!(self.logger, "Attempting to generate broadcast channel update for channel {}", log_bytes!(chan.channel_id()));
self.get_channel_update_for_unicast(chan)
}
/// Gets the current channel_update for the given channel. This does not check if the channel
/// is public (only returning an Err if the channel does not yet have an assigned short_id),
/// and thus MUST NOT be called unless the recipient of the resulting message has already
/// provided evidence that they know about the existence of the channel.
/// May be called with channel_state already locked!
fn get_channel_update_for_unicast(&self, chan: &Channel<Signer>) -> Result<msgs::ChannelUpdate, LightningError> {
log_trace!(self.logger, "Attempting to generate channel update for channel {}", log_bytes!(chan.channel_id()));
let short_channel_id = match chan.get_short_channel_id().or(chan.latest_inbound_scid_alias()) {
None => return Err(LightningError{err: "Channel not yet established".to_owned(), action: msgs::ErrorAction::IgnoreError}),
Some(id) => id,
};
self.get_channel_update_for_onion(short_channel_id, chan)
}
fn get_channel_update_for_onion(&self, short_channel_id: u64, chan: &Channel<Signer>) -> Result<msgs::ChannelUpdate, LightningError> {
log_trace!(self.logger, "Generating channel update for channel {}", log_bytes!(chan.channel_id()));
let were_node_one = PublicKey::from_secret_key(&self.secp_ctx, &self.our_network_key).serialize()[..] < chan.get_counterparty_node_id().serialize()[..];
let unsigned = msgs::UnsignedChannelUpdate {
chain_hash: self.genesis_hash,
short_channel_id,
timestamp: chan.get_update_time_counter(),
flags: (!were_node_one) as u8 | ((!chan.is_live() as u8) << 1),
cltv_expiry_delta: chan.get_cltv_expiry_delta(),
htlc_minimum_msat: chan.get_counterparty_htlc_minimum_msat(),
htlc_maximum_msat: OptionalField::Present(chan.get_announced_htlc_max_msat()),
fee_base_msat: chan.get_outbound_forwarding_fee_base_msat(),
fee_proportional_millionths: chan.get_fee_proportional_millionths(),
excess_data: Vec::new(),
};
let msg_hash = Sha256dHash::hash(&unsigned.encode()[..]);
let sig = self.secp_ctx.sign_ecdsa(&hash_to_message!(&msg_hash[..]), &self.our_network_key);
Ok(msgs::ChannelUpdate {
signature: sig,
contents: unsigned
})
}
// Only public for testing, this should otherwise never be called direcly
pub(crate) fn send_payment_along_path(&self, path: &Vec<RouteHop>, payment_params: &Option<PaymentParameters>, payment_hash: &PaymentHash, payment_secret: &Option<PaymentSecret>, total_value: u64, cur_height: u32, payment_id: PaymentId, keysend_preimage: &Option<PaymentPreimage>) -> Result<(), APIError> {
log_trace!(self.logger, "Attempting to send payment for path with next hop {}", path.first().unwrap().short_channel_id);
let prng_seed = self.keys_manager.get_secure_random_bytes();
let session_priv_bytes = self.keys_manager.get_secure_random_bytes();
let session_priv = SecretKey::from_slice(&session_priv_bytes[..]).expect("RNG is busted");
let onion_keys = onion_utils::construct_onion_keys(&self.secp_ctx, &path, &session_priv)
.map_err(|_| APIError::RouteError{err: "Pubkey along hop was maliciously selected"})?;
let (onion_payloads, htlc_msat, htlc_cltv) = onion_utils::build_onion_payloads(path, total_value, payment_secret, cur_height, keysend_preimage)?;
if onion_utils::route_size_insane(&onion_payloads) {
return Err(APIError::RouteError{err: "Route size too large considering onion data"});
}
let onion_packet = onion_utils::construct_onion_packet(onion_payloads, onion_keys, prng_seed, payment_hash);
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
let err: Result<(), _> = loop {
let mut channel_lock = self.channel_state.lock().unwrap();
let mut pending_outbounds = self.pending_outbound_payments.lock().unwrap();
let payment_entry = pending_outbounds.entry(payment_id);
if let hash_map::Entry::Occupied(payment) = &payment_entry {
if !payment.get().is_retryable() {
return Err(APIError::RouteError {
err: "Payment already completed"
});
}
}
let id = match channel_lock.short_to_id.get(&path.first().unwrap().short_channel_id) {
None => return Err(APIError::ChannelUnavailable{err: "No channel available with first hop!".to_owned()}),
Some(id) => id.clone(),
};
macro_rules! insert_outbound_payment {
() => {
let payment = payment_entry.or_insert_with(|| PendingOutboundPayment::Retryable {
session_privs: HashSet::new(),
pending_amt_msat: 0,
pending_fee_msat: Some(0),
payment_hash: *payment_hash,
payment_secret: *payment_secret,
starting_block_height: self.best_block.read().unwrap().height(),
total_msat: total_value,
});
assert!(payment.insert(session_priv_bytes, path));
}
}
let channel_state = &mut *channel_lock;
if let hash_map::Entry::Occupied(mut chan) = channel_state.by_id.entry(id) {
match {
if chan.get().get_counterparty_node_id() != path.first().unwrap().pubkey {
return Err(APIError::RouteError{err: "Node ID mismatch on first hop!"});
}
if !chan.get().is_live() {
return Err(APIError::ChannelUnavailable{err: "Peer for first hop currently disconnected/pending monitor update!".to_owned()});
}
break_chan_entry!(self, chan.get_mut().send_htlc_and_commit(
htlc_msat, payment_hash.clone(), htlc_cltv, HTLCSource::OutboundRoute {
path: path.clone(),
session_priv: session_priv.clone(),
first_hop_htlc_msat: htlc_msat,
payment_id,
payment_secret: payment_secret.clone(),
payment_params: payment_params.clone(),
}, onion_packet, &self.logger),
channel_state, chan)
} {
Some((update_add, commitment_signed, monitor_update)) => {
if let Err(e) = self.chain_monitor.update_channel(chan.get().get_funding_txo().unwrap(), monitor_update) {
maybe_break_monitor_err!(self, e, channel_state, chan, RAACommitmentOrder::CommitmentFirst, false, true);
// Note that MonitorUpdateFailed here indicates (per function docs)
// that we will resend the commitment update once monitor updating
// is restored. Therefore, we must return an error indicating that
// it is unsafe to retry the payment wholesale, which we do in the
// send_payment check for MonitorUpdateFailed, below.
insert_outbound_payment!(); // Only do this after possibly break'ing on Perm failure above.
return Err(APIError::MonitorUpdateFailed);
}
insert_outbound_payment!();
log_debug!(self.logger, "Sending payment along path resulted in a commitment_signed for channel {}", log_bytes!(chan.get().channel_id()));
channel_state.pending_msg_events.push(events::MessageSendEvent::UpdateHTLCs {
node_id: path.first().unwrap().pubkey,
updates: msgs::CommitmentUpdate {
update_add_htlcs: vec![update_add],
update_fulfill_htlcs: Vec::new(),
update_fail_htlcs: Vec::new(),
update_fail_malformed_htlcs: Vec::new(),
update_fee: None,
commitment_signed,
},
});
},
None => { insert_outbound_payment!(); },
}
} else { unreachable!(); }
return Ok(());
};
match handle_error!(self, err, path.first().unwrap().pubkey) {
Ok(_) => unreachable!(),
Err(e) => {
Err(APIError::ChannelUnavailable { err: e.err })
},
}
}
/// Sends a payment along a given route.
///
/// Value parameters are provided via the last hop in route, see documentation for RouteHop
/// fields for more info.
///
/// Note that if the payment_hash already exists elsewhere (eg you're sending a duplicative
/// payment), we don't do anything to stop you! We always try to ensure that if the provided
/// next hop knows the preimage to payment_hash they can claim an additional amount as
/// specified in the last hop in the route! Thus, you should probably do your own
/// payment_preimage tracking (which you should already be doing as they represent "proof of
/// payment") and prevent double-sends yourself.
///
/// May generate SendHTLCs message(s) event on success, which should be relayed.
///
/// Each path may have a different return value, and PaymentSendValue may return a Vec with
/// each entry matching the corresponding-index entry in the route paths, see
/// PaymentSendFailure for more info.
///
/// In general, a path may raise:
/// * APIError::RouteError when an invalid route or forwarding parameter (cltv_delta, fee,
/// node public key) is specified.
/// * APIError::ChannelUnavailable if the next-hop channel is not available for updates
/// (including due to previous monitor update failure or new permanent monitor update
/// failure).
/// * APIError::MonitorUpdateFailed if a new monitor update failure prevented sending the
/// relevant updates.
///
/// Note that depending on the type of the PaymentSendFailure the HTLC may have been
/// irrevocably committed to on our end. In such a case, do NOT retry the payment with a
/// different route unless you intend to pay twice!
///
/// payment_secret is unrelated to payment_hash (or PaymentPreimage) and exists to authenticate
/// the sender to the recipient and prevent payment-probing (deanonymization) attacks. For
/// newer nodes, it will be provided to you in the invoice. If you do not have one, the Route
/// must not contain multiple paths as multi-path payments require a recipient-provided
/// payment_secret.
/// If a payment_secret *is* provided, we assume that the invoice had the payment_secret feature
/// bit set (either as required or as available). If multiple paths are present in the Route,
/// we assume the invoice had the basic_mpp feature set.
pub fn send_payment(&self, route: &Route, payment_hash: PaymentHash, payment_secret: &Option<PaymentSecret>) -> Result<PaymentId, PaymentSendFailure> {
self.send_payment_internal(route, payment_hash, payment_secret, None, None, None)
}
fn send_payment_internal(&self, route: &Route, payment_hash: PaymentHash, payment_secret: &Option<PaymentSecret>, keysend_preimage: Option<PaymentPreimage>, payment_id: Option<PaymentId>, recv_value_msat: Option<u64>) -> Result<PaymentId, PaymentSendFailure> {
if route.paths.len() < 1 {
return Err(PaymentSendFailure::ParameterError(APIError::RouteError{err: "There must be at least one path to send over"}));
}
if route.paths.len() > 10 {
// This limit is completely arbitrary - there aren't any real fundamental path-count
// limits. After we support retrying individual paths we should likely bump this, but
// for now more than 10 paths likely carries too much one-path failure.
return Err(PaymentSendFailure::ParameterError(APIError::RouteError{err: "Sending over more than 10 paths is not currently supported"}));
}
if payment_secret.is_none() && route.paths.len() > 1 {
return Err(PaymentSendFailure::ParameterError(APIError::APIMisuseError{err: "Payment secret is required for multi-path payments".to_string()}));
}
let mut total_value = 0;
let our_node_id = self.get_our_node_id();
let mut path_errs = Vec::with_capacity(route.paths.len());
let payment_id = if let Some(id) = payment_id { id } else { PaymentId(self.keys_manager.get_secure_random_bytes()) };
'path_check: for path in route.paths.iter() {
if path.len() < 1 || path.len() > 20 {
path_errs.push(Err(APIError::RouteError{err: "Path didn't go anywhere/had bogus size"}));
continue 'path_check;
}
for (idx, hop) in path.iter().enumerate() {
if idx != path.len() - 1 && hop.pubkey == our_node_id {
path_errs.push(Err(APIError::RouteError{err: "Path went through us but wasn't a simple rebalance loop to us"}));
continue 'path_check;
}
}
total_value += path.last().unwrap().fee_msat;
path_errs.push(Ok(()));
}
if path_errs.iter().any(|e| e.is_err()) {
return Err(PaymentSendFailure::PathParameterError(path_errs));
}
if let Some(amt_msat) = recv_value_msat {
debug_assert!(amt_msat >= total_value);
total_value = amt_msat;
}
let cur_height = self.best_block.read().unwrap().height() + 1;
let mut results = Vec::new();
for path in route.paths.iter() {
results.push(self.send_payment_along_path(&path, &route.payment_params, &payment_hash, payment_secret, total_value, cur_height, payment_id, &keysend_preimage));
}
let mut has_ok = false;
let mut has_err = false;
let mut pending_amt_unsent = 0;
let mut max_unsent_cltv_delta = 0;
for (res, path) in results.iter().zip(route.paths.iter()) {
if res.is_ok() { has_ok = true; }
if res.is_err() { has_err = true; }
if let &Err(APIError::MonitorUpdateFailed) = res {
// MonitorUpdateFailed is inherently unsafe to retry, so we call it a
// PartialFailure.
has_err = true;
has_ok = true;
} else if res.is_err() {
pending_amt_unsent += path.last().unwrap().fee_msat;
max_unsent_cltv_delta = cmp::max(max_unsent_cltv_delta, path.last().unwrap().cltv_expiry_delta);
}
}
if has_err && has_ok {
Err(PaymentSendFailure::PartialFailure {
results,
payment_id,
failed_paths_retry: if pending_amt_unsent != 0 {
if let Some(payment_params) = &route.payment_params {
Some(RouteParameters {
payment_params: payment_params.clone(),
final_value_msat: pending_amt_unsent,
final_cltv_expiry_delta: max_unsent_cltv_delta,
})
} else { None }
} else { None },
})
} else if has_err {
// If we failed to send any paths, we shouldn't have inserted the new PaymentId into
// our `pending_outbound_payments` map at all.
debug_assert!(self.pending_outbound_payments.lock().unwrap().get(&payment_id).is_none());
Err(PaymentSendFailure::AllFailedRetrySafe(results.drain(..).map(|r| r.unwrap_err()).collect()))
} else {
Ok(payment_id)
}
}
/// Retries a payment along the given [`Route`].
///
/// Errors returned are a superset of those returned from [`send_payment`], so see
/// [`send_payment`] documentation for more details on errors. This method will also error if the
/// retry amount puts the payment more than 10% over the payment's total amount, if the payment
/// for the given `payment_id` cannot be found (likely due to timeout or success), or if
/// further retries have been disabled with [`abandon_payment`].
///
/// [`send_payment`]: [`ChannelManager::send_payment`]
/// [`abandon_payment`]: [`ChannelManager::abandon_payment`]
pub fn retry_payment(&self, route: &Route, payment_id: PaymentId) -> Result<(), PaymentSendFailure> {
const RETRY_OVERFLOW_PERCENTAGE: u64 = 10;
for path in route.paths.iter() {
if path.len() == 0 {
return Err(PaymentSendFailure::ParameterError(APIError::APIMisuseError {
err: "length-0 path in route".to_string()
}))
}
}
let (total_msat, payment_hash, payment_secret) = {
let outbounds = self.pending_outbound_payments.lock().unwrap();
if let Some(payment) = outbounds.get(&payment_id) {
match payment {
PendingOutboundPayment::Retryable {
total_msat, payment_hash, payment_secret, pending_amt_msat, ..
} => {
let retry_amt_msat: u64 = route.paths.iter().map(|path| path.last().unwrap().fee_msat).sum();
if retry_amt_msat + *pending_amt_msat > *total_msat * (100 + RETRY_OVERFLOW_PERCENTAGE) / 100 {
return Err(PaymentSendFailure::ParameterError(APIError::APIMisuseError {
err: format!("retry_amt_msat of {} will put pending_amt_msat (currently: {}) more than 10% over total_payment_amt_msat of {}", retry_amt_msat, pending_amt_msat, total_msat).to_string()
}))
}
(*total_msat, *payment_hash, *payment_secret)
},
PendingOutboundPayment::Legacy { .. } => {
return Err(PaymentSendFailure::ParameterError(APIError::APIMisuseError {
err: "Unable to retry payments that were initially sent on LDK versions prior to 0.0.102".to_string()
}))
},
PendingOutboundPayment::Fulfilled { .. } => {
return Err(PaymentSendFailure::ParameterError(APIError::APIMisuseError {
err: "Payment already completed".to_owned()
}));
},
PendingOutboundPayment::Abandoned { .. } => {
return Err(PaymentSendFailure::ParameterError(APIError::APIMisuseError {
err: "Payment already abandoned (with some HTLCs still pending)".to_owned()
}));
},
}
} else {
return Err(PaymentSendFailure::ParameterError(APIError::APIMisuseError {
err: format!("Payment with ID {} not found", log_bytes!(payment_id.0)),
}))
}
};
return self.send_payment_internal(route, payment_hash, &payment_secret, None, Some(payment_id), Some(total_msat)).map(|_| ())
}
/// Signals that no further retries for the given payment will occur.
///
/// After this method returns, any future calls to [`retry_payment`] for the given `payment_id`
/// will fail with [`PaymentSendFailure::ParameterError`]. If no such event has been generated,
/// an [`Event::PaymentFailed`] event will be generated as soon as there are no remaining
/// pending HTLCs for this payment.
///
/// Note that calling this method does *not* prevent a payment from succeeding. You must still
/// wait until you receive either a [`Event::PaymentFailed`] or [`Event::PaymentSent`] event to
/// determine the ultimate status of a payment.
///
/// [`retry_payment`]: Self::retry_payment
/// [`Event::PaymentFailed`]: events::Event::PaymentFailed
/// [`Event::PaymentSent`]: events::Event::PaymentSent
pub fn abandon_payment(&self, payment_id: PaymentId) {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
let mut outbounds = self.pending_outbound_payments.lock().unwrap();
if let hash_map::Entry::Occupied(mut payment) = outbounds.entry(payment_id) {
if let Ok(()) = payment.get_mut().mark_abandoned() {
if payment.get().remaining_parts() == 0 {
self.pending_events.lock().unwrap().push(events::Event::PaymentFailed {
payment_id,
payment_hash: payment.get().payment_hash().expect("PendingOutboundPayments::RetriesExceeded always has a payment hash set"),
});
payment.remove();
}
}
}
}
/// Send a spontaneous payment, which is a payment that does not require the recipient to have
/// generated an invoice. Optionally, you may specify the preimage. If you do choose to specify
/// the preimage, it must be a cryptographically secure random value that no intermediate node
/// would be able to guess -- otherwise, an intermediate node may claim the payment and it will
/// never reach the recipient.
///
/// See [`send_payment`] documentation for more details on the return value of this function.
///
/// Similar to regular payments, you MUST NOT reuse a `payment_preimage` value. See
/// [`send_payment`] for more information about the risks of duplicate preimage usage.
///
/// Note that `route` must have exactly one path.
///
/// [`send_payment`]: Self::send_payment
pub fn send_spontaneous_payment(&self, route: &Route, payment_preimage: Option<PaymentPreimage>) -> Result<(PaymentHash, PaymentId), PaymentSendFailure> {
let preimage = match payment_preimage {
Some(p) => p,
None => PaymentPreimage(self.keys_manager.get_secure_random_bytes()),
};
let payment_hash = PaymentHash(Sha256::hash(&preimage.0).into_inner());
match self.send_payment_internal(route, payment_hash, &None, Some(preimage), None, None) {
Ok(payment_id) => Ok((payment_hash, payment_id)),
Err(e) => Err(e)
}
}
/// Handles the generation of a funding transaction, optionally (for tests) with a function
/// which checks the correctness of the funding transaction given the associated channel.
fn funding_transaction_generated_intern<FundingOutput: Fn(&Channel<Signer>, &Transaction) -> Result<OutPoint, APIError>>(
&self, temporary_channel_id: &[u8; 32], _counterparty_node_id: &PublicKey, funding_transaction: Transaction, find_funding_output: FundingOutput
) -> Result<(), APIError> {
let (chan, msg) = {
let (res, chan) = match self.channel_state.lock().unwrap().by_id.remove(temporary_channel_id) {
Some(mut chan) => {
let funding_txo = find_funding_output(&chan, &funding_transaction)?;
(chan.get_outbound_funding_created(funding_transaction, funding_txo, &self.logger)
.map_err(|e| if let ChannelError::Close(msg) = e {
MsgHandleErrInternal::from_finish_shutdown(msg, chan.channel_id(), chan.get_user_id(), chan.force_shutdown(true), None)
} else { unreachable!(); })
, chan)
},
None => { return Err(APIError::ChannelUnavailable { err: "No such channel".to_owned() }) },
};
match handle_error!(self, res, chan.get_counterparty_node_id()) {
Ok(funding_msg) => {
(chan, funding_msg)
},
Err(_) => { return Err(APIError::ChannelUnavailable {
err: "Error deriving keys or signing initial commitment transactions - either our RNG or our counterparty's RNG is broken or the Signer refused to sign".to_owned()
}) },
}
};
let mut channel_state = self.channel_state.lock().unwrap();
channel_state.pending_msg_events.push(events::MessageSendEvent::SendFundingCreated {
node_id: chan.get_counterparty_node_id(),
msg,
});
match channel_state.by_id.entry(chan.channel_id()) {
hash_map::Entry::Occupied(_) => {
panic!("Generated duplicate funding txid?");
},
hash_map::Entry::Vacant(e) => {
e.insert(chan);
}
}
Ok(())
}
#[cfg(test)]
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> {
self.funding_transaction_generated_intern(temporary_channel_id, counterparty_node_id, funding_transaction, |_, tx| {
Ok(OutPoint { txid: tx.txid(), index: output_index })
})
}
/// Call this upon creation of a funding transaction for the given channel.
///
/// Returns an [`APIError::APIMisuseError`] if the funding_transaction spent non-SegWit outputs
/// or if no output was found which matches the parameters in [`Event::FundingGenerationReady`].
///
/// Returns [`APIError::ChannelUnavailable`] if a funding transaction has already been provided
/// for the channel or if the channel has been closed as indicated by [`Event::ChannelClosed`].
///
/// May panic if the output found in the funding transaction is duplicative with some other
/// channel (note that this should be trivially prevented by using unique funding transaction
/// keys per-channel).
///
/// Do NOT broadcast the funding transaction yourself. When we have safely received our
/// counterparty's signature the funding transaction will automatically be broadcast via the
/// [`BroadcasterInterface`] provided when this `ChannelManager` was constructed.
///
/// Note that this includes RBF or similar transaction replacement strategies - lightning does
/// not currently support replacing a funding transaction on an existing channel. Instead,
/// create a new channel with a conflicting funding transaction.
///
/// [`Event::FundingGenerationReady`]: crate::util::events::Event::FundingGenerationReady
/// [`Event::ChannelClosed`]: crate::util::events::Event::ChannelClosed
pub fn funding_transaction_generated(&self, temporary_channel_id: &[u8; 32], counterparty_node_id: &PublicKey, funding_transaction: Transaction) -> Result<(), APIError> {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
for inp in funding_transaction.input.iter() {
if inp.witness.is_empty() {
return Err(APIError::APIMisuseError {
err: "Funding transaction must be fully signed and spend Segwit outputs".to_owned()
});
}
}
self.funding_transaction_generated_intern(temporary_channel_id, counterparty_node_id, funding_transaction, |chan, tx| {
let mut output_index = None;
let expected_spk = chan.get_funding_redeemscript().to_v0_p2wsh();
for (idx, outp) in tx.output.iter().enumerate() {
if outp.script_pubkey == expected_spk && outp.value == chan.get_value_satoshis() {
if output_index.is_some() {
return Err(APIError::APIMisuseError {
err: "Multiple outputs matched the expected script and value".to_owned()
});
}
if idx > u16::max_value() as usize {
return Err(APIError::APIMisuseError {
err: "Transaction had more than 2^16 outputs, which is not supported".to_owned()
});
}
output_index = Some(idx as u16);
}
}
if output_index.is_none() {
return Err(APIError::APIMisuseError {
err: "No output matched the script_pubkey and value in the FundingGenerationReady event".to_owned()
});
}
Ok(OutPoint { txid: tx.txid(), index: output_index.unwrap() })
})
}
#[allow(dead_code)]
// Messages of up to 64KB should never end up more than half full with addresses, as that would
// be absurd. We ensure this by checking that at least 500 (our stated public contract on when
// broadcast_node_announcement panics) of the maximum-length addresses would fit in a 64KB
// message...
const HALF_MESSAGE_IS_ADDRS: u32 = ::core::u16::MAX as u32 / (NetAddress::MAX_LEN as u32 + 1) / 2;
#[deny(const_err)]
#[allow(dead_code)]
// ...by failing to compile if the number of addresses that would be half of a message is
// smaller than 500:
const STATIC_ASSERT: u32 = Self::HALF_MESSAGE_IS_ADDRS - 500;
/// Regenerates channel_announcements and generates a signed node_announcement from the given
/// arguments, providing them in corresponding events via
/// [`get_and_clear_pending_msg_events`], if at least one public channel has been confirmed
/// on-chain. This effectively re-broadcasts all channel announcements and sends our node
/// announcement to ensure that the lightning P2P network is aware of the channels we have and
/// our network addresses.
///
/// `rgb` is a node "color" and `alias` is a printable human-readable string to describe this
/// node to humans. They carry no in-protocol meaning.
///
/// `addresses` represent the set (possibly empty) of socket addresses on which this node
/// accepts incoming connections. These will be included in the node_announcement, publicly
/// tying these addresses together and to this node. If you wish to preserve user privacy,
/// addresses should likely contain only Tor Onion addresses.
///
/// Panics if `addresses` is absurdly large (more than 500).
///
/// [`get_and_clear_pending_msg_events`]: MessageSendEventsProvider::get_and_clear_pending_msg_events
pub fn broadcast_node_announcement(&self, rgb: [u8; 3], alias: [u8; 32], mut addresses: Vec<NetAddress>) {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
if addresses.len() > 500 {
panic!("More than half the message size was taken up by public addresses!");
}
// While all existing nodes handle unsorted addresses just fine, the spec requires that
// addresses be sorted for future compatibility.
addresses.sort_by_key(|addr| addr.get_id());
let announcement = msgs::UnsignedNodeAnnouncement {
features: NodeFeatures::known(),
timestamp: self.last_node_announcement_serial.fetch_add(1, Ordering::AcqRel) as u32,
node_id: self.get_our_node_id(),
rgb, alias, addresses,
excess_address_data: Vec::new(),
excess_data: Vec::new(),
};
let msghash = hash_to_message!(&Sha256dHash::hash(&announcement.encode()[..])[..]);
let node_announce_sig = sign(&self.secp_ctx, &msghash, &self.our_network_key);
let mut channel_state_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_state_lock;
let mut announced_chans = false;
for (_, chan) in channel_state.by_id.iter() {
if let Some(msg) = chan.get_signed_channel_announcement(self.get_our_node_id(), self.genesis_hash.clone(), self.best_block.read().unwrap().height()) {
channel_state.pending_msg_events.push(events::MessageSendEvent::BroadcastChannelAnnouncement {
msg,
update_msg: match self.get_channel_update_for_broadcast(chan) {
Ok(msg) => msg,
Err(_) => continue,
},
});
announced_chans = true;
} else {
// If the channel is not public or has not yet reached channel_ready, check the
// next channel. If we don't yet have any public channels, we'll skip the broadcast
// below as peers may not accept it without channels on chain first.
}
}
if announced_chans {
channel_state.pending_msg_events.push(events::MessageSendEvent::BroadcastNodeAnnouncement {
msg: msgs::NodeAnnouncement {
signature: node_announce_sig,
contents: announcement
},
});
}
}
/// Processes HTLCs which are pending waiting on random forward delay.
///
/// Should only really ever be called in response to a PendingHTLCsForwardable event.
/// Will likely generate further events.
pub fn process_pending_htlc_forwards(&self) {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
let mut new_events = Vec::new();
let mut failed_forwards = Vec::new();
let mut phantom_receives: Vec<(u64, OutPoint, Vec<(PendingHTLCInfo, u64)>)> = Vec::new();
let mut handle_errors = Vec::new();
{
let mut channel_state_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_state_lock;
for (short_chan_id, mut pending_forwards) in channel_state.forward_htlcs.drain() {
if short_chan_id != 0 {
let forward_chan_id = match channel_state.short_to_id.get(&short_chan_id) {
Some(chan_id) => chan_id.clone(),
None => {
for forward_info in pending_forwards.drain(..) {
match forward_info {
HTLCForwardInfo::AddHTLC { prev_short_channel_id, prev_htlc_id, forward_info: PendingHTLCInfo {
routing, incoming_shared_secret, payment_hash, amt_to_forward, outgoing_cltv_value },
prev_funding_outpoint } => {
macro_rules! fail_forward {
($msg: expr, $err_code: expr, $err_data: expr, $phantom_ss: expr) => {
{
log_info!(self.logger, "Failed to accept/forward incoming HTLC: {}", $msg);
let htlc_source = HTLCSource::PreviousHopData(HTLCPreviousHopData {
short_channel_id: prev_short_channel_id,
outpoint: prev_funding_outpoint,
htlc_id: prev_htlc_id,
incoming_packet_shared_secret: incoming_shared_secret,
phantom_shared_secret: $phantom_ss,
});
failed_forwards.push((htlc_source, payment_hash,
HTLCFailReason::Reason { failure_code: $err_code, data: $err_data }
));
continue;
}
}
}
if let PendingHTLCRouting::Forward { onion_packet, .. } = routing {
let phantom_secret_res = self.keys_manager.get_node_secret(Recipient::PhantomNode);
if phantom_secret_res.is_ok() && fake_scid::is_valid_phantom(&self.fake_scid_rand_bytes, short_chan_id) {
let phantom_shared_secret = SharedSecret::new(&onion_packet.public_key.unwrap(), &phantom_secret_res.unwrap()).secret_bytes();
let next_hop = match onion_utils::decode_next_hop(phantom_shared_secret, &onion_packet.hop_data, onion_packet.hmac, payment_hash) {
Ok(res) => res,
Err(onion_utils::OnionDecodeErr::Malformed { err_msg, err_code }) => {
let sha256_of_onion = Sha256::hash(&onion_packet.hop_data).into_inner();
// In this scenario, the phantom would have sent us an
// `update_fail_malformed_htlc`, meaning here we encrypt the error as
// if it came from us (the second-to-last hop) but contains the sha256
// of the onion.
fail_forward!(err_msg, err_code, sha256_of_onion.to_vec(), None);
},
Err(onion_utils::OnionDecodeErr::Relay { err_msg, err_code }) => {
fail_forward!(err_msg, err_code, Vec::new(), Some(phantom_shared_secret));
},
};
match next_hop {
onion_utils::Hop::Receive(hop_data) => {
match self.construct_recv_pending_htlc_info(hop_data, incoming_shared_secret, payment_hash, amt_to_forward, outgoing_cltv_value, Some(phantom_shared_secret)) {
Ok(info) => phantom_receives.push((prev_short_channel_id, prev_funding_outpoint, vec![(info, prev_htlc_id)])),
Err(ReceiveError { err_code, err_data, msg }) => fail_forward!(msg, err_code, err_data, Some(phantom_shared_secret))
}
},
_ => panic!(),
}
} else {
fail_forward!(format!("Unknown short channel id {} for forward HTLC", short_chan_id), 0x4000 | 10, Vec::new(), None);
}
} else {
fail_forward!(format!("Unknown short channel id {} for forward HTLC", short_chan_id), 0x4000 | 10, Vec::new(), None);
}
},
HTLCForwardInfo::FailHTLC { .. } => {
// Channel went away before we could fail it. This implies
// the channel is now on chain and our counterparty is
// trying to broadcast the HTLC-Timeout, but that's their
// problem, not ours.
}
}
}
continue;
}
};
if let hash_map::Entry::Occupied(mut chan) = channel_state.by_id.entry(forward_chan_id) {
let mut add_htlc_msgs = Vec::new();
let mut fail_htlc_msgs = Vec::new();
for forward_info in pending_forwards.drain(..) {
match forward_info {
HTLCForwardInfo::AddHTLC { prev_short_channel_id, prev_htlc_id, forward_info: PendingHTLCInfo {
routing: PendingHTLCRouting::Forward {
onion_packet, ..
}, incoming_shared_secret, payment_hash, amt_to_forward, outgoing_cltv_value },
prev_funding_outpoint } => {
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);
let htlc_source = HTLCSource::PreviousHopData(HTLCPreviousHopData {
short_channel_id: prev_short_channel_id,
outpoint: prev_funding_outpoint,
htlc_id: prev_htlc_id,
incoming_packet_shared_secret: incoming_shared_secret,
// Phantom payments are only PendingHTLCRouting::Receive.
phantom_shared_secret: None,
});
match chan.get_mut().send_htlc(amt_to_forward, payment_hash, outgoing_cltv_value, htlc_source.clone(), onion_packet, &self.logger) {
Err(e) => {
if let ChannelError::Ignore(msg) = e {
log_trace!(self.logger, "Failed to forward HTLC with payment_hash {}: {}", log_bytes!(payment_hash.0), msg);
} else {
panic!("Stated return value requirements in send_htlc() were not met");
}
let (failure_code, data) = self.get_htlc_temp_fail_err_and_data(0x1000|7, short_chan_id, chan.get());
failed_forwards.push((htlc_source, payment_hash,
HTLCFailReason::Reason { failure_code, data }
));
continue;
},
Ok(update_add) => {
match update_add {
Some(msg) => { add_htlc_msgs.push(msg); },
None => {
// Nothing to do here...we're waiting on a remote
// revoke_and_ack before we can add anymore HTLCs. The Channel
// will automatically handle building the update_add_htlc and
// commitment_signed messages when we can.
// TODO: Do some kind of timer to set the channel as !is_live()
// as we don't really want others relying on us relaying through
// this channel currently :/.
}
}
}
}
},
HTLCForwardInfo::AddHTLC { .. } => {
panic!("short_channel_id != 0 should imply any pending_forward entries are of type Forward");
},
HTLCForwardInfo::FailHTLC { htlc_id, err_packet } => {
log_trace!(self.logger, "Failing HTLC back to channel with short id {} (backward HTLC ID {}) after delay", short_chan_id, htlc_id);
match chan.get_mut().get_update_fail_htlc(htlc_id, err_packet, &self.logger) {
Err(e) => {
if let ChannelError::Ignore(msg) = e {
log_trace!(self.logger, "Failed to fail HTLC with ID {} backwards to short_id {}: {}", htlc_id, short_chan_id, msg);
} else {
panic!("Stated return value requirements in get_update_fail_htlc() were not met");
}
// fail-backs are best-effort, we probably already have one
// pending, and if not that's OK, if not, the channel is on
// the chain and sending the HTLC-Timeout is their problem.
continue;
},
Ok(Some(msg)) => { fail_htlc_msgs.push(msg); },
Ok(None) => {
// Nothing to do here...we're waiting on a remote
// revoke_and_ack before we can update the commitment
// transaction. The Channel will automatically handle
// building the update_fail_htlc and commitment_signed
// messages when we can.
// We don't need any kind of timer here as they should fail
// the channel onto the chain if they can't get our
// update_fail_htlc in time, it's not our problem.
}
}
},
}
}
if !add_htlc_msgs.is_empty() || !fail_htlc_msgs.is_empty() {
let (commitment_msg, monitor_update) = match chan.get_mut().send_commitment(&self.logger) {
Ok(res) => res,
Err(e) => {
// We surely failed send_commitment due to bad keys, in that case
// close channel and then send error message to peer.
let counterparty_node_id = chan.get().get_counterparty_node_id();
let err: Result<(), _> = match e {
ChannelError::Ignore(_) | ChannelError::Warn(_) => {
panic!("Stated return value requirements in send_commitment() were not met");
}
ChannelError::Close(msg) => {
log_trace!(self.logger, "Closing channel {} due to Close-required error: {}", log_bytes!(chan.key()[..]), msg);
let mut channel = remove_channel!(self, channel_state, chan);
// ChannelClosed event is generated by handle_error for us.
Err(MsgHandleErrInternal::from_finish_shutdown(msg, channel.channel_id(), channel.get_user_id(), channel.force_shutdown(true), self.get_channel_update_for_broadcast(&channel).ok()))
},
ChannelError::CloseDelayBroadcast(_) => { panic!("Wait is only generated on receipt of channel_reestablish, which is handled by try_chan_entry, we don't bother to support it here"); }
};
handle_errors.push((counterparty_node_id, err));
continue;
}
};
if let Err(e) = self.chain_monitor.update_channel(chan.get().get_funding_txo().unwrap(), monitor_update) {
handle_errors.push((chan.get().get_counterparty_node_id(), handle_monitor_err!(self, e, channel_state, chan, RAACommitmentOrder::CommitmentFirst, false, true)));
continue;
}
log_debug!(self.logger, "Forwarding HTLCs resulted in a commitment update with {} HTLCs added and {} HTLCs failed for channel {}",
add_htlc_msgs.len(), fail_htlc_msgs.len(), log_bytes!(chan.get().channel_id()));
channel_state.pending_msg_events.push(events::MessageSendEvent::UpdateHTLCs {
node_id: chan.get().get_counterparty_node_id(),
updates: msgs::CommitmentUpdate {
update_add_htlcs: add_htlc_msgs,
update_fulfill_htlcs: Vec::new(),
update_fail_htlcs: fail_htlc_msgs,
update_fail_malformed_htlcs: Vec::new(),
update_fee: None,
commitment_signed: commitment_msg,
},
});
}
} else {
unreachable!();
}
} else {
for forward_info in pending_forwards.drain(..) {
match forward_info {
HTLCForwardInfo::AddHTLC { prev_short_channel_id, prev_htlc_id, forward_info: PendingHTLCInfo {
routing, incoming_shared_secret, payment_hash, amt_to_forward, .. },
prev_funding_outpoint } => {
let (cltv_expiry, onion_payload, payment_data, phantom_shared_secret) = match routing {
PendingHTLCRouting::Receive { payment_data, incoming_cltv_expiry, phantom_shared_secret } => {
let _legacy_hop_data = Some(payment_data.clone());
(incoming_cltv_expiry, OnionPayload::Invoice { _legacy_hop_data }, Some(payment_data), phantom_shared_secret)
},
PendingHTLCRouting::ReceiveKeysend { payment_preimage, incoming_cltv_expiry } =>
(incoming_cltv_expiry, OnionPayload::Spontaneous(payment_preimage), None, None),
_ => {
panic!("short_channel_id == 0 should imply any pending_forward entries are of type Receive");
}
};
let claimable_htlc = ClaimableHTLC {
prev_hop: HTLCPreviousHopData {
short_channel_id: prev_short_channel_id,
outpoint: prev_funding_outpoint,
htlc_id: prev_htlc_id,
incoming_packet_shared_secret: incoming_shared_secret,
phantom_shared_secret,
},
value: amt_to_forward,
timer_ticks: 0,
total_msat: if let Some(data) = &payment_data { data.total_msat } else { amt_to_forward },
cltv_expiry,
onion_payload,
};
macro_rules! fail_htlc {
($htlc: expr) => {
let mut htlc_msat_height_data = byte_utils::be64_to_array($htlc.value).to_vec();
htlc_msat_height_data.extend_from_slice(
&byte_utils::be32_to_array(self.best_block.read().unwrap().height()),
);
failed_forwards.push((HTLCSource::PreviousHopData(HTLCPreviousHopData {
short_channel_id: $htlc.prev_hop.short_channel_id,
outpoint: prev_funding_outpoint,
htlc_id: $htlc.prev_hop.htlc_id,
incoming_packet_shared_secret: $htlc.prev_hop.incoming_packet_shared_secret,
phantom_shared_secret,
}), payment_hash,
HTLCFailReason::Reason { failure_code: 0x4000 | 15, data: htlc_msat_height_data }
));
}
}
macro_rules! check_total_value {
($payment_data: expr, $payment_preimage: expr) => {{
let mut payment_received_generated = false;
let purpose = || {
events::PaymentPurpose::InvoicePayment {
payment_preimage: $payment_preimage,
payment_secret: $payment_data.payment_secret,
}
};
let (_, htlcs) = channel_state.claimable_htlcs.entry(payment_hash)
.or_insert_with(|| (purpose(), Vec::new()));
if htlcs.len() == 1 {
if let OnionPayload::Spontaneous(_) = htlcs[0].onion_payload {
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));
fail_htlc!(claimable_htlc);
continue
}
}
let mut total_value = claimable_htlc.value;
for htlc in htlcs.iter() {
total_value += htlc.value;
match &htlc.onion_payload {
OnionPayload::Invoice { .. } => {
if htlc.total_msat != $payment_data.total_msat {
log_trace!(self.logger, "Failing HTLCs with payment_hash {} as the HTLCs had inconsistent total values (eg {} and {})",
log_bytes!(payment_hash.0), $payment_data.total_msat, htlc.total_msat);
total_value = msgs::MAX_VALUE_MSAT;
}
if total_value >= msgs::MAX_VALUE_MSAT { break; }
},
_ => unreachable!(),
}
}
if total_value >= msgs::MAX_VALUE_MSAT || total_value > $payment_data.total_msat {
log_trace!(self.logger, "Failing HTLCs with payment_hash {} as the total value {} ran over expected value {} (or HTLCs were inconsistent)",
log_bytes!(payment_hash.0), total_value, $payment_data.total_msat);
fail_htlc!(claimable_htlc);
} else if total_value == $payment_data.total_msat {
htlcs.push(claimable_htlc);
new_events.push(events::Event::PaymentReceived {
payment_hash,
purpose: purpose(),
amount_msat: total_value,
});
payment_received_generated = true;
} else {
// Nothing to do - we haven't reached the total
// payment value yet, wait until we receive more
// MPP parts.
htlcs.push(claimable_htlc);
}
payment_received_generated
}}
}
// Check that the payment hash and secret are known. Note that we
// MUST take care to handle the "unknown payment hash" and
// "incorrect payment secret" cases here identically or we'd expose
// that we are the ultimate recipient of the given payment hash.
// Further, we must not expose whether we have any other HTLCs
// associated with the same payment_hash pending or not.
let mut payment_secrets = self.pending_inbound_payments.lock().unwrap();
match payment_secrets.entry(payment_hash) {
hash_map::Entry::Vacant(_) => {
match claimable_htlc.onion_payload {
OnionPayload::Invoice { .. } => {
let payment_data = payment_data.unwrap();
let payment_preimage = match inbound_payment::verify(payment_hash, &payment_data, self.highest_seen_timestamp.load(Ordering::Acquire) as u64, &self.inbound_payment_key, &self.logger) {
Ok(payment_preimage) => payment_preimage,
Err(()) => {
fail_htlc!(claimable_htlc);
continue
}
};
check_total_value!(payment_data, payment_preimage);
},
OnionPayload::Spontaneous(preimage) => {
match channel_state.claimable_htlcs.entry(payment_hash) {
hash_map::Entry::Vacant(e) => {
let purpose = events::PaymentPurpose::SpontaneousPayment(preimage);
e.insert((purpose.clone(), vec![claimable_htlc]));
new_events.push(events::Event::PaymentReceived {
payment_hash,
amount_msat: amt_to_forward,
purpose,
});
},
hash_map::Entry::Occupied(_) => {
log_trace!(self.logger, "Failing new keysend HTLC with payment_hash {} for a duplicative payment hash", log_bytes!(payment_hash.0));
fail_htlc!(claimable_htlc);
}
}
}
}
},
hash_map::Entry::Occupied(inbound_payment) => {
if payment_data.is_none() {
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));
fail_htlc!(claimable_htlc);
continue
};
let payment_data = payment_data.unwrap();
if inbound_payment.get().payment_secret != payment_data.payment_secret {
log_trace!(self.logger, "Failing new HTLC with payment_hash {} as it didn't match our expected payment secret.", log_bytes!(payment_hash.0));
fail_htlc!(claimable_htlc);
} else if inbound_payment.get().min_value_msat.is_some() && payment_data.total_msat < inbound_payment.get().min_value_msat.unwrap() {
log_trace!(self.logger, "Failing new HTLC with payment_hash {} as it didn't match our minimum value (had {}, needed {}).",
log_bytes!(payment_hash.0), payment_data.total_msat, inbound_payment.get().min_value_msat.unwrap());
fail_htlc!(claimable_htlc);
} else {
let payment_received_generated = check_total_value!(payment_data, inbound_payment.get().payment_preimage);
if payment_received_generated {
inbound_payment.remove_entry();
}
}
},
};
},
HTLCForwardInfo::FailHTLC { .. } => {
panic!("Got pending fail of our own HTLC");
}
}
}
}
}
}
for (htlc_source, payment_hash, failure_reason) in failed_forwards.drain(..) {
self.fail_htlc_backwards_internal(self.channel_state.lock().unwrap(), htlc_source, &payment_hash, failure_reason);
}
self.forward_htlcs(&mut phantom_receives);
for (counterparty_node_id, err) in handle_errors.drain(..) {
let _ = handle_error!(self, err, counterparty_node_id);
}
if new_events.is_empty() { return }
let mut events = self.pending_events.lock().unwrap();
events.append(&mut new_events);
}
/// Free the background events, generally called from timer_tick_occurred.
///
/// Exposed for testing to allow us to process events quickly without generating accidental
/// BroadcastChannelUpdate events in timer_tick_occurred.
///
/// Expects the caller to have a total_consistency_lock read lock.
fn process_background_events(&self) -> bool {
let mut background_events = Vec::new();
mem::swap(&mut *self.pending_background_events.lock().unwrap(), &mut background_events);
if background_events.is_empty() {
return false;
}
for event in background_events.drain(..) {
match event {
BackgroundEvent::ClosingMonitorUpdate((funding_txo, update)) => {
// The channel has already been closed, so no use bothering to care about the
// monitor updating completing.
let _ = self.chain_monitor.update_channel(funding_txo, update);
},
}
}
true
}
#[cfg(any(test, feature = "_test_utils"))]
/// Process background events, for functional testing
pub fn test_process_background_events(&self) {
self.process_background_events();
}
fn update_channel_fee(&self, short_to_id: &mut HashMap<u64, [u8; 32]>, pending_msg_events: &mut Vec<events::MessageSendEvent>, chan_id: &[u8; 32], chan: &mut Channel<Signer>, new_feerate: u32) -> (bool, NotifyOption, Result<(), MsgHandleErrInternal>) {
if !chan.is_outbound() { return (true, NotifyOption::SkipPersist, Ok(())); }
// If the feerate has decreased by less than half, don't bother
if new_feerate <= chan.get_feerate() && new_feerate * 2 > chan.get_feerate() {
log_trace!(self.logger, "Channel {} does not qualify for a feerate change from {} to {}.",
log_bytes!(chan_id[..]), chan.get_feerate(), new_feerate);
return (true, NotifyOption::SkipPersist, Ok(()));
}
if !chan.is_live() {
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).",
log_bytes!(chan_id[..]), chan.get_feerate(), new_feerate);
return (true, NotifyOption::SkipPersist, Ok(()));
}
log_trace!(self.logger, "Channel {} qualifies for a feerate change from {} to {}.",
log_bytes!(chan_id[..]), chan.get_feerate(), new_feerate);
let mut retain_channel = true;
let res = match chan.send_update_fee_and_commit(new_feerate, &self.logger) {
Ok(res) => Ok(res),
Err(e) => {
let (drop, res) = convert_chan_err!(self, e, short_to_id, chan, chan_id);
if drop { retain_channel = false; }
Err(res)
}
};
let ret_err = match res {
Ok(Some((update_fee, commitment_signed, monitor_update))) => {
if let Err(e) = self.chain_monitor.update_channel(chan.get_funding_txo().unwrap(), monitor_update) {
let (res, drop) = handle_monitor_err!(self, e, short_to_id, chan, RAACommitmentOrder::CommitmentFirst, chan_id, COMMITMENT_UPDATE_ONLY);
if drop { retain_channel = false; }
res
} else {
pending_msg_events.push(events::MessageSendEvent::UpdateHTLCs {
node_id: chan.get_counterparty_node_id(),
updates: msgs::CommitmentUpdate {
update_add_htlcs: Vec::new(),
update_fulfill_htlcs: Vec::new(),
update_fail_htlcs: Vec::new(),
update_fail_malformed_htlcs: Vec::new(),
update_fee: Some(update_fee),
commitment_signed,
},
});
Ok(())
}
},
Ok(None) => Ok(()),
Err(e) => Err(e),
};
(retain_channel, NotifyOption::DoPersist, ret_err)
}
#[cfg(fuzzing)]
/// In chanmon_consistency we want to sometimes do the channel fee updates done in
/// timer_tick_occurred, but we can't generate the disabled channel updates as it considers
/// these a fuzz failure (as they usually indicate a channel force-close, which is exactly what
/// it wants to detect). Thus, we have a variant exposed here for its benefit.
pub fn maybe_update_chan_fees(&self) {
PersistenceNotifierGuard::optionally_notify(&self.total_consistency_lock, &self.persistence_notifier, || {
let mut should_persist = NotifyOption::SkipPersist;
let new_feerate = self.fee_estimator.get_est_sat_per_1000_weight(ConfirmationTarget::Normal);
let mut handle_errors = Vec::new();
{
let mut channel_state_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_state_lock;
let pending_msg_events = &mut channel_state.pending_msg_events;
let short_to_id = &mut channel_state.short_to_id;
channel_state.by_id.retain(|chan_id, chan| {
let (retain_channel, chan_needs_persist, err) = self.update_channel_fee(short_to_id, pending_msg_events, chan_id, chan, new_feerate);
if chan_needs_persist == NotifyOption::DoPersist { should_persist = NotifyOption::DoPersist; }
if err.is_err() {
handle_errors.push(err);
}
retain_channel
});
}
should_persist
});
}
/// Performs actions which should happen on startup and roughly once per minute thereafter.
///
/// This currently includes:
/// * Increasing or decreasing the on-chain feerate estimates for our outbound channels,
/// * Broadcasting `ChannelUpdate` messages if we've been disconnected from our peer for more
/// than a minute, informing the network that they should no longer attempt to route over
/// the channel.
///
/// Note that this may cause reentrancy through `chain::Watch::update_channel` calls or feerate
/// estimate fetches.
pub fn timer_tick_occurred(&self) {
PersistenceNotifierGuard::optionally_notify(&self.total_consistency_lock, &self.persistence_notifier, || {
let mut should_persist = NotifyOption::SkipPersist;
if self.process_background_events() { should_persist = NotifyOption::DoPersist; }
let new_feerate = self.fee_estimator.get_est_sat_per_1000_weight(ConfirmationTarget::Normal);
let mut handle_errors = Vec::new();
let mut timed_out_mpp_htlcs = Vec::new();
{
let mut channel_state_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_state_lock;
let pending_msg_events = &mut channel_state.pending_msg_events;
let short_to_id = &mut channel_state.short_to_id;
channel_state.by_id.retain(|chan_id, chan| {
let counterparty_node_id = chan.get_counterparty_node_id();
let (retain_channel, chan_needs_persist, err) = self.update_channel_fee(short_to_id, pending_msg_events, chan_id, chan, new_feerate);
if chan_needs_persist == NotifyOption::DoPersist { should_persist = NotifyOption::DoPersist; }
if err.is_err() {
handle_errors.push((err, counterparty_node_id));
}
if !retain_channel { return false; }
if let Err(e) = chan.timer_check_closing_negotiation_progress() {
let (needs_close, err) = convert_chan_err!(self, e, short_to_id, chan, chan_id);
handle_errors.push((Err(err), chan.get_counterparty_node_id()));
if needs_close { return false; }
}
match chan.channel_update_status() {
ChannelUpdateStatus::Enabled if !chan.is_live() => chan.set_channel_update_status(ChannelUpdateStatus::DisabledStaged),
ChannelUpdateStatus::Disabled if chan.is_live() => chan.set_channel_update_status(ChannelUpdateStatus::EnabledStaged),
ChannelUpdateStatus::DisabledStaged if chan.is_live() => chan.set_channel_update_status(ChannelUpdateStatus::Enabled),
ChannelUpdateStatus::EnabledStaged if !chan.is_live() => chan.set_channel_update_status(ChannelUpdateStatus::Disabled),
ChannelUpdateStatus::DisabledStaged if !chan.is_live() => {
if let Ok(update) = self.get_channel_update_for_broadcast(&chan) {
pending_msg_events.push(events::MessageSendEvent::BroadcastChannelUpdate {
msg: update
});
}
should_persist = NotifyOption::DoPersist;
chan.set_channel_update_status(ChannelUpdateStatus::Disabled);
},
ChannelUpdateStatus::EnabledStaged if chan.is_live() => {
if let Ok(update) = self.get_channel_update_for_broadcast(&chan) {
pending_msg_events.push(events::MessageSendEvent::BroadcastChannelUpdate {
msg: update
});
}
should_persist = NotifyOption::DoPersist;
chan.set_channel_update_status(ChannelUpdateStatus::Enabled);
},
_ => {},
}
true
});
channel_state.claimable_htlcs.retain(|payment_hash, (_, htlcs)| {
if htlcs.is_empty() {
// This should be unreachable
debug_assert!(false);
return false;
}
if let OnionPayload::Invoice { .. } = htlcs[0].onion_payload {
// Check if we've received all the parts we need for an MPP (the value of the parts adds to total_msat).
// In this case we're not going to handle any timeouts of the parts here.
if htlcs[0].total_msat == htlcs.iter().fold(0, |total, htlc| total + htlc.value) {
return true;
} else if htlcs.into_iter().any(|htlc| {
htlc.timer_ticks += 1;
return htlc.timer_ticks >= MPP_TIMEOUT_TICKS
}) {
timed_out_mpp_htlcs.extend(htlcs.into_iter().map(|htlc| (htlc.prev_hop.clone(), payment_hash.clone())));
return false;
}
}
true
});
}
for htlc_source in timed_out_mpp_htlcs.drain(..) {
self.fail_htlc_backwards_internal(self.channel_state.lock().unwrap(), HTLCSource::PreviousHopData(htlc_source.0), &htlc_source.1, HTLCFailReason::Reason { failure_code: 23, data: Vec::new() });
}
for (err, counterparty_node_id) in handle_errors.drain(..) {
let _ = handle_error!(self, err, counterparty_node_id);
}
should_persist
});
}
/// Indicates that the preimage for payment_hash is unknown or the received amount is incorrect
/// after a PaymentReceived event, failing the HTLC back to its origin and freeing resources
/// along the path (including in our own channel on which we received it).
///
/// Note that in some cases around unclean shutdown, it is possible the payment may have
/// already been claimed by you via [`ChannelManager::claim_funds`] prior to you seeing (a
/// second copy of) the [`events::Event::PaymentReceived`] event. Alternatively, the payment
/// may have already been failed automatically by LDK if it was nearing its expiration time.
///
/// While LDK will never claim a payment automatically on your behalf (i.e. without you calling
/// [`ChannelManager::claim_funds`]), you should still monitor for
/// [`events::Event::PaymentClaimed`] events even for payments you intend to fail, especially on
/// startup during which time claims that were in-progress at shutdown may be replayed.
pub fn fail_htlc_backwards(&self, payment_hash: &PaymentHash) {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
let mut channel_state = Some(self.channel_state.lock().unwrap());
let removed_source = channel_state.as_mut().unwrap().claimable_htlcs.remove(payment_hash);
if let Some((_, mut sources)) = removed_source {
for htlc in sources.drain(..) {
if channel_state.is_none() { channel_state = Some(self.channel_state.lock().unwrap()); }
let mut htlc_msat_height_data = byte_utils::be64_to_array(htlc.value).to_vec();
htlc_msat_height_data.extend_from_slice(&byte_utils::be32_to_array(
self.best_block.read().unwrap().height()));
self.fail_htlc_backwards_internal(channel_state.take().unwrap(),
HTLCSource::PreviousHopData(htlc.prev_hop), payment_hash,
HTLCFailReason::Reason { failure_code: 0x4000 | 15, data: htlc_msat_height_data });
}
}
}
/// Gets an HTLC onion failure code and error data for an `UPDATE` error, given the error code
/// that we want to return and a channel.
///
/// This is for failures on the channel on which the HTLC was *received*, not failures
/// forwarding
fn get_htlc_inbound_temp_fail_err_and_data(&self, desired_err_code: u16, chan: &Channel<Signer>) -> (u16, Vec<u8>) {
// We can't be sure what SCID was used when relaying inbound towards us, so we have to
// guess somewhat. If its a public channel, we figure best to just use the real SCID (as
// we're not leaking that we have a channel with the counterparty), otherwise we try to use
// an inbound SCID alias before the real SCID.
let scid_pref = if chan.should_announce() {
chan.get_short_channel_id().or(chan.latest_inbound_scid_alias())
} else {
chan.latest_inbound_scid_alias().or(chan.get_short_channel_id())
};
if let Some(scid) = scid_pref {
self.get_htlc_temp_fail_err_and_data(desired_err_code, scid, chan)
} else {
(0x4000|10, Vec::new())
}
}
/// Gets an HTLC onion failure code and error data for an `UPDATE` error, given the error code
/// that we want to return and a channel.
fn get_htlc_temp_fail_err_and_data(&self, desired_err_code: u16, scid: u64, chan: &Channel<Signer>) -> (u16, Vec<u8>) {
debug_assert_eq!(desired_err_code & 0x1000, 0x1000);
if let Ok(upd) = self.get_channel_update_for_onion(scid, chan) {
let mut enc = VecWriter(Vec::with_capacity(upd.serialized_length() + 6));
if desired_err_code == 0x1000 | 20 {
// TODO: underspecified, follow https://github.com/lightning/bolts/issues/791
0u16.write(&mut enc).expect("Writes cannot fail");
}
(upd.serialized_length() as u16 + 2).write(&mut enc).expect("Writes cannot fail");
msgs::ChannelUpdate::TYPE.write(&mut enc).expect("Writes cannot fail");
upd.write(&mut enc).expect("Writes cannot fail");
(desired_err_code, enc.0)
} else {
// If we fail to get a unicast channel_update, it implies we don't yet have an SCID,
// which means we really shouldn't have gotten a payment to be forwarded over this
// channel yet, or if we did it's from a route hint. Either way, returning an error of
// PERM|no_such_channel should be fine.
(0x4000|10, Vec::new())
}
}
// Fail a list of HTLCs that were just freed from the holding cell. The HTLCs need to be
// failed backwards or, if they were one of our outgoing HTLCs, then their failure needs to
// be surfaced to the user.
fn fail_holding_cell_htlcs(&self, mut htlcs_to_fail: Vec<(HTLCSource, PaymentHash)>, channel_id: [u8; 32]) {
for (htlc_src, payment_hash) in htlcs_to_fail.drain(..) {
match htlc_src {
HTLCSource::PreviousHopData(HTLCPreviousHopData { .. }) => {
let (failure_code, onion_failure_data) =
match self.channel_state.lock().unwrap().by_id.entry(channel_id) {
hash_map::Entry::Occupied(chan_entry) => {
self.get_htlc_inbound_temp_fail_err_and_data(0x1000|7, &chan_entry.get())
},
hash_map::Entry::Vacant(_) => (0x4000|10, Vec::new())
};
let channel_state = self.channel_state.lock().unwrap();
self.fail_htlc_backwards_internal(channel_state,
htlc_src, &payment_hash, HTLCFailReason::Reason { failure_code, data: onion_failure_data});
},
HTLCSource::OutboundRoute { session_priv, payment_id, path, payment_params, .. } => {
let mut session_priv_bytes = [0; 32];
session_priv_bytes.copy_from_slice(&session_priv[..]);
let mut outbounds = self.pending_outbound_payments.lock().unwrap();
if let hash_map::Entry::Occupied(mut payment) = outbounds.entry(payment_id) {
if payment.get_mut().remove(&session_priv_bytes, Some(&path)) && !payment.get().is_fulfilled() {
let retry = if let Some(payment_params_data) = payment_params {
let path_last_hop = path.last().expect("Outbound payments must have had a valid path");
Some(RouteParameters {
payment_params: payment_params_data,
final_value_msat: path_last_hop.fee_msat,
final_cltv_expiry_delta: path_last_hop.cltv_expiry_delta,
})
} else { None };
let mut pending_events = self.pending_events.lock().unwrap();
pending_events.push(events::Event::PaymentPathFailed {
payment_id: Some(payment_id),
payment_hash,
rejected_by_dest: false,
network_update: None,
all_paths_failed: payment.get().remaining_parts() == 0,
path: path.clone(),
short_channel_id: None,
retry,
#[cfg(test)]
error_code: None,
#[cfg(test)]
error_data: None,
});
if payment.get().abandoned() && payment.get().remaining_parts() == 0 {
pending_events.push(events::Event::PaymentFailed {
payment_id,
payment_hash: payment.get().payment_hash().expect("PendingOutboundPayments::RetriesExceeded always has a payment hash set"),
});
payment.remove();
}
}
} else {
log_trace!(self.logger, "Received duplicative fail for HTLC with payment_hash {}", log_bytes!(payment_hash.0));
}
},
};
}
}
/// Fails an HTLC backwards to the sender of it to us.
/// Note that while we take a channel_state lock as input, we do *not* assume consistency here.
/// There are several callsites that do stupid things like loop over a list of payment_hashes
/// to fail and take the channel_state lock for each iteration (as we take ownership and may
/// drop it). In other words, no assumptions are made that entries in claimable_htlcs point to
/// still-available channels.
fn fail_htlc_backwards_internal(&self, mut channel_state_lock: MutexGuard<ChannelHolder<Signer>>, source: HTLCSource, payment_hash: &PaymentHash, onion_error: HTLCFailReason) {
//TODO: There is a timing attack here where if a node fails an HTLC back to us they can
//identify whether we sent it or not based on the (I presume) very different runtime
//between the branches here. We should make this async and move it into the forward HTLCs
//timer handling.
// Note that we MUST NOT end up calling methods on self.chain_monitor here - we're called
// from block_connected which may run during initialization prior to the chain_monitor
// being fully configured. See the docs for `ChannelManagerReadArgs` for more.
match source {
HTLCSource::OutboundRoute { ref path, session_priv, payment_id, ref payment_params, .. } => {
let mut session_priv_bytes = [0; 32];
session_priv_bytes.copy_from_slice(&session_priv[..]);
let mut outbounds = self.pending_outbound_payments.lock().unwrap();
let mut all_paths_failed = false;
let mut full_failure_ev = None;
if let hash_map::Entry::Occupied(mut payment) = outbounds.entry(payment_id) {
if !payment.get_mut().remove(&session_priv_bytes, Some(&path)) {
log_trace!(self.logger, "Received duplicative fail for HTLC with payment_hash {}", log_bytes!(payment_hash.0));
return;
}
if payment.get().is_fulfilled() {
log_trace!(self.logger, "Received failure of HTLC with payment_hash {} after payment completion", log_bytes!(payment_hash.0));
return;
}
if payment.get().remaining_parts() == 0 {
all_paths_failed = true;
if payment.get().abandoned() {
full_failure_ev = Some(events::Event::PaymentFailed {
payment_id,
payment_hash: payment.get().payment_hash().expect("PendingOutboundPayments::RetriesExceeded always has a payment hash set"),
});
payment.remove();
}
}
} else {
log_trace!(self.logger, "Received duplicative fail for HTLC with payment_hash {}", log_bytes!(payment_hash.0));
return;
}
mem::drop(channel_state_lock);
let retry = if let Some(payment_params_data) = payment_params {
let path_last_hop = path.last().expect("Outbound payments must have had a valid path");
Some(RouteParameters {
payment_params: payment_params_data.clone(),
final_value_msat: path_last_hop.fee_msat,
final_cltv_expiry_delta: path_last_hop.cltv_expiry_delta,
})
} else { None };
log_trace!(self.logger, "Failing outbound payment HTLC with payment_hash {}", log_bytes!(payment_hash.0));
let path_failure = match &onion_error {
&HTLCFailReason::LightningError { ref err } => {
#[cfg(test)]
let (network_update, short_channel_id, payment_retryable, onion_error_code, onion_error_data) = onion_utils::process_onion_failure(&self.secp_ctx, &self.logger, &source, err.data.clone());
#[cfg(not(test))]
let (network_update, short_channel_id, payment_retryable, _, _) = onion_utils::process_onion_failure(&self.secp_ctx, &self.logger, &source, err.data.clone());
// TODO: If we decided to blame ourselves (or one of our channels) in
// process_onion_failure we should close that channel as it implies our
// next-hop is needlessly blaming us!
events::Event::PaymentPathFailed {
payment_id: Some(payment_id),
payment_hash: payment_hash.clone(),
rejected_by_dest: !payment_retryable,
network_update,
all_paths_failed,
path: path.clone(),
short_channel_id,
retry,
#[cfg(test)]
error_code: onion_error_code,
#[cfg(test)]
error_data: onion_error_data
}
},
&HTLCFailReason::Reason {
#[cfg(test)]
ref failure_code,
#[cfg(test)]
ref data,
.. } => {
// we get a fail_malformed_htlc from the first hop
// TODO: We'd like to generate a NetworkUpdate for temporary
// failures here, but that would be insufficient as get_route
// generally ignores its view of our own channels as we provide them via
// ChannelDetails.
// TODO: For non-temporary failures, we really should be closing the
// channel here as we apparently can't relay through them anyway.
events::Event::PaymentPathFailed {
payment_id: Some(payment_id),
payment_hash: payment_hash.clone(),
rejected_by_dest: path.len() == 1,
network_update: None,
all_paths_failed,
path: path.clone(),
short_channel_id: Some(path.first().unwrap().short_channel_id),
retry,
#[cfg(test)]
error_code: Some(*failure_code),
#[cfg(test)]
error_data: Some(data.clone()),
}
}
};
let mut pending_events = self.pending_events.lock().unwrap();
pending_events.push(path_failure);
if let Some(ev) = full_failure_ev { pending_events.push(ev); }
},
HTLCSource::PreviousHopData(HTLCPreviousHopData { short_channel_id, htlc_id, incoming_packet_shared_secret, phantom_shared_secret, .. }) => {
let err_packet = match onion_error {
HTLCFailReason::Reason { failure_code, data } => {
log_trace!(self.logger, "Failing HTLC with payment_hash {} backwards from us with code {}", log_bytes!(payment_hash.0), failure_code);
if let Some(phantom_ss) = phantom_shared_secret {
let phantom_packet = onion_utils::build_failure_packet(&phantom_ss, failure_code, &data[..]).encode();
let encrypted_phantom_packet = onion_utils::encrypt_failure_packet(&phantom_ss, &phantom_packet);
onion_utils::encrypt_failure_packet(&incoming_packet_shared_secret, &encrypted_phantom_packet.data[..])
} else {
let packet = onion_utils::build_failure_packet(&incoming_packet_shared_secret, failure_code, &data[..]).encode();
onion_utils::encrypt_failure_packet(&incoming_packet_shared_secret, &packet)
}
},
HTLCFailReason::LightningError { err } => {
log_trace!(self.logger, "Failing HTLC with payment_hash {} backwards with pre-built LightningError", log_bytes!(payment_hash.0));
onion_utils::encrypt_failure_packet(&incoming_packet_shared_secret, &err.data)
}
};
let mut forward_event = None;
if channel_state_lock.forward_htlcs.is_empty() {
forward_event = Some(Duration::from_millis(MIN_HTLC_RELAY_HOLDING_CELL_MILLIS));
}
match channel_state_lock.forward_htlcs.entry(short_channel_id) {
hash_map::Entry::Occupied(mut entry) => {
entry.get_mut().push(HTLCForwardInfo::FailHTLC { htlc_id, err_packet });
},
hash_map::Entry::Vacant(entry) => {
entry.insert(vec!(HTLCForwardInfo::FailHTLC { htlc_id, err_packet }));
}
}
mem::drop(channel_state_lock);
if let Some(time) = forward_event {
let mut pending_events = self.pending_events.lock().unwrap();
pending_events.push(events::Event::PendingHTLCsForwardable {
time_forwardable: time
});
}
},
}
}
/// Provides a payment preimage in response to [`Event::PaymentReceived`], generating any
/// [`MessageSendEvent`]s needed to claim the payment.
///
/// Note that calling this method does *not* guarantee that the payment has been claimed. You
/// *must* wait for an [`Event::PaymentClaimed`] event which upon a successful claim will be
/// provided to your [`EventHandler`] when [`process_pending_events`] is next called.
///
/// Note that if you did not set an `amount_msat` when calling [`create_inbound_payment`] or
/// [`create_inbound_payment_for_hash`] you must check that the amount in the `PaymentReceived`
/// event matches your expectation. If you fail to do so and call this method, you may provide
/// the sender "proof-of-payment" when they did not fulfill the full expected payment.
///
/// [`Event::PaymentReceived`]: crate::util::events::Event::PaymentReceived
/// [`Event::PaymentClaimed`]: crate::util::events::Event::PaymentClaimed
/// [`process_pending_events`]: EventsProvider::process_pending_events
/// [`create_inbound_payment`]: Self::create_inbound_payment
/// [`create_inbound_payment_for_hash`]: Self::create_inbound_payment_for_hash
/// [`get_and_clear_pending_msg_events`]: MessageSendEventsProvider::get_and_clear_pending_msg_events
pub fn claim_funds(&self, payment_preimage: PaymentPreimage) {
let payment_hash = PaymentHash(Sha256::hash(&payment_preimage.0).into_inner());
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
let mut channel_state = Some(self.channel_state.lock().unwrap());
let removed_source = channel_state.as_mut().unwrap().claimable_htlcs.remove(&payment_hash);
if let Some((payment_purpose, mut sources)) = removed_source {
assert!(!sources.is_empty());
// If we are claiming an MPP payment, we have to take special care to ensure that each
// channel exists before claiming all of the payments (inside one lock).
// Note that channel existance is sufficient as we should always get a monitor update
// which will take care of the real HTLC claim enforcement.
//
// If we find an HTLC which we would need to claim but for which we do not have a
// channel, we will fail all parts of the MPP payment. While we could wait and see if
// the sender retries the already-failed path(s), it should be a pretty rare case where
// we got all the HTLCs and then a channel closed while we were waiting for the user to
// provide the preimage, so worrying too much about the optimal handling isn't worth
// it.
let mut claimable_amt_msat = 0;
let mut expected_amt_msat = None;
let mut valid_mpp = true;
for htlc in sources.iter() {
if let None = channel_state.as_ref().unwrap().short_to_id.get(&htlc.prev_hop.short_channel_id) {
valid_mpp = false;
break;
}
if expected_amt_msat.is_some() && expected_amt_msat != Some(htlc.total_msat) {
log_error!(self.logger, "Somehow ended up with an MPP payment with different total amounts - this should not be reachable!");
debug_assert!(false);
valid_mpp = false;
break;
}
expected_amt_msat = Some(htlc.total_msat);
if let OnionPayload::Spontaneous(_) = &htlc.onion_payload {
// We don't currently support MPP for spontaneous payments, so just check
// that there's one payment here and move on.
if sources.len() != 1 {
log_error!(self.logger, "Somehow ended up with an MPP spontaneous payment - this should not be reachable!");
debug_assert!(false);
valid_mpp = false;
break;
}
}
claimable_amt_msat += htlc.value;
}
if sources.is_empty() || expected_amt_msat.is_none() {
log_info!(self.logger, "Attempted to claim an incomplete payment which no longer had any available HTLCs!");
return;
}
if claimable_amt_msat != expected_amt_msat.unwrap() {
log_info!(self.logger, "Attempted to claim an incomplete payment, expected {} msat, had {} available to claim.",
expected_amt_msat.unwrap(), claimable_amt_msat);
return;
}
let mut errs = Vec::new();
let mut claimed_any_htlcs = false;
for htlc in sources.drain(..) {
if !valid_mpp {
if channel_state.is_none() { channel_state = Some(self.channel_state.lock().unwrap()); }
let mut htlc_msat_height_data = byte_utils::be64_to_array(htlc.value).to_vec();
htlc_msat_height_data.extend_from_slice(&byte_utils::be32_to_array(
self.best_block.read().unwrap().height()));
self.fail_htlc_backwards_internal(channel_state.take().unwrap(),
HTLCSource::PreviousHopData(htlc.prev_hop), &payment_hash,
HTLCFailReason::Reason { failure_code: 0x4000|15, data: htlc_msat_height_data });
} else {
match self.claim_funds_from_hop(channel_state.as_mut().unwrap(), htlc.prev_hop, payment_preimage) {
ClaimFundsFromHop::MonitorUpdateFail(pk, err, _) => {
if let msgs::ErrorAction::IgnoreError = err.err.action {
// We got a temporary failure updating monitor, but will claim the
// HTLC when the monitor updating is restored (or on chain).
log_error!(self.logger, "Temporary failure claiming HTLC, treating as success: {}", err.err.err);
claimed_any_htlcs = true;
} else { errs.push((pk, err)); }
},
ClaimFundsFromHop::PrevHopForceClosed => unreachable!("We already checked for channel existence, we can't fail here!"),
ClaimFundsFromHop::DuplicateClaim => {
// While we should never get here in most cases, if we do, it likely
// indicates that the HTLC was timed out some time ago and is no longer
// available to be claimed. Thus, it does not make sense to set
// `claimed_any_htlcs`.
},
ClaimFundsFromHop::Success(_) => claimed_any_htlcs = true,
}
}
}
if claimed_any_htlcs {
self.pending_events.lock().unwrap().push(events::Event::PaymentClaimed {
payment_hash,
purpose: payment_purpose,
amount_msat: claimable_amt_msat,
});
}
// Now that we've done the entire above loop in one lock, we can handle any errors
// which were generated.
channel_state.take();
for (counterparty_node_id, err) in errs.drain(..) {
let res: Result<(), _> = Err(err);
let _ = handle_error!(self, res, counterparty_node_id);
}
}
}
fn claim_funds_from_hop(&self, channel_state_lock: &mut MutexGuard<ChannelHolder<Signer>>, prev_hop: HTLCPreviousHopData, payment_preimage: PaymentPreimage) -> ClaimFundsFromHop {
//TODO: Delay the claimed_funds relaying just like we do outbound relay!
let channel_state = &mut **channel_state_lock;
let chan_id = match channel_state.short_to_id.get(&prev_hop.short_channel_id) {
Some(chan_id) => chan_id.clone(),
None => {
return ClaimFundsFromHop::PrevHopForceClosed
}
};
if let hash_map::Entry::Occupied(mut chan) = channel_state.by_id.entry(chan_id) {
match chan.get_mut().get_update_fulfill_htlc_and_commit(prev_hop.htlc_id, payment_preimage, &self.logger) {
Ok(msgs_monitor_option) => {
if let UpdateFulfillCommitFetch::NewClaim { msgs, htlc_value_msat, monitor_update } = msgs_monitor_option {
if let Err(e) = self.chain_monitor.update_channel(chan.get().get_funding_txo().unwrap(), monitor_update) {
log_given_level!(self.logger, if e == ChannelMonitorUpdateErr::PermanentFailure { Level::Error } else { Level::Debug },
"Failed to update channel monitor with preimage {:?}: {:?}",
payment_preimage, e);
return ClaimFundsFromHop::MonitorUpdateFail(
chan.get().get_counterparty_node_id(),
handle_monitor_err!(self, e, channel_state, chan, RAACommitmentOrder::CommitmentFirst, false, msgs.is_some()).unwrap_err(),
Some(htlc_value_msat)
);
}
if let Some((msg, commitment_signed)) = msgs {
log_debug!(self.logger, "Claiming funds for HTLC with preimage {} resulted in a commitment_signed for channel {}",
log_bytes!(payment_preimage.0), log_bytes!(chan.get().channel_id()));
channel_state.pending_msg_events.push(events::MessageSendEvent::UpdateHTLCs {
node_id: chan.get().get_counterparty_node_id(),
updates: msgs::CommitmentUpdate {
update_add_htlcs: Vec::new(),
update_fulfill_htlcs: vec![msg],
update_fail_htlcs: Vec::new(),
update_fail_malformed_htlcs: Vec::new(),
update_fee: None,
commitment_signed,
}
});
}
return ClaimFundsFromHop::Success(htlc_value_msat);
} else {
return ClaimFundsFromHop::DuplicateClaim;
}
},
Err((e, monitor_update)) => {
if let Err(e) = self.chain_monitor.update_channel(chan.get().get_funding_txo().unwrap(), monitor_update) {
log_given_level!(self.logger, if e == ChannelMonitorUpdateErr::PermanentFailure { Level::Error } else { Level::Info },
"Failed to update channel monitor with preimage {:?} immediately prior to force-close: {:?}",
payment_preimage, e);
}
let counterparty_node_id = chan.get().get_counterparty_node_id();
let (drop, res) = convert_chan_err!(self, e, channel_state.short_to_id, chan.get_mut(), &chan_id);
if drop {
chan.remove_entry();
}
return ClaimFundsFromHop::MonitorUpdateFail(counterparty_node_id, res, None);
},
}
} else { unreachable!(); }
}
fn finalize_claims(&self, mut sources: Vec<HTLCSource>) {
let mut outbounds = self.pending_outbound_payments.lock().unwrap();
let mut pending_events = self.pending_events.lock().unwrap();
for source in sources.drain(..) {
if let HTLCSource::OutboundRoute { session_priv, payment_id, path, .. } = source {
let mut session_priv_bytes = [0; 32];
session_priv_bytes.copy_from_slice(&session_priv[..]);
if let hash_map::Entry::Occupied(mut payment) = outbounds.entry(payment_id) {
assert!(payment.get().is_fulfilled());
if payment.get_mut().remove(&session_priv_bytes, None) {
pending_events.push(
events::Event::PaymentPathSuccessful {
payment_id,
payment_hash: payment.get().payment_hash(),
path,
}
);
}
if payment.get().remaining_parts() == 0 {
payment.remove();
}
}
}
}
}
fn claim_funds_internal(&self, mut channel_state_lock: MutexGuard<ChannelHolder<Signer>>, source: HTLCSource, payment_preimage: PaymentPreimage, forwarded_htlc_value_msat: Option<u64>, from_onchain: bool, next_channel_id: [u8; 32]) {
match source {
HTLCSource::OutboundRoute { session_priv, payment_id, path, .. } => {
mem::drop(channel_state_lock);
let mut session_priv_bytes = [0; 32];
session_priv_bytes.copy_from_slice(&session_priv[..]);
let mut outbounds = self.pending_outbound_payments.lock().unwrap();
if let hash_map::Entry::Occupied(mut payment) = outbounds.entry(payment_id) {
let mut pending_events = self.pending_events.lock().unwrap();
if !payment.get().is_fulfilled() {
let payment_hash = PaymentHash(Sha256::hash(&payment_preimage.0).into_inner());
let fee_paid_msat = payment.get().get_pending_fee_msat();
pending_events.push(
events::Event::PaymentSent {
payment_id: Some(payment_id),
payment_preimage,
payment_hash,
fee_paid_msat,
}
);
payment.get_mut().mark_fulfilled();
}
if from_onchain {
// We currently immediately remove HTLCs which were fulfilled on-chain.
// This could potentially lead to removing a pending payment too early,
// with a reorg of one block causing us to re-add the fulfilled payment on
// restart.
// TODO: We should have a second monitor event that informs us of payments
// irrevocably fulfilled.
if payment.get_mut().remove(&session_priv_bytes, Some(&path)) {
let payment_hash = Some(PaymentHash(Sha256::hash(&payment_preimage.0).into_inner()));
pending_events.push(
events::Event::PaymentPathSuccessful {
payment_id,
payment_hash,
path,
}
);
}
if payment.get().remaining_parts() == 0 {
payment.remove();
}
}
} else {
log_trace!(self.logger, "Received duplicative fulfill for HTLC with payment_preimage {}", log_bytes!(payment_preimage.0));
}
},
HTLCSource::PreviousHopData(hop_data) => {
let prev_outpoint = hop_data.outpoint;
let res = self.claim_funds_from_hop(&mut channel_state_lock, hop_data, payment_preimage);
let claimed_htlc = if let ClaimFundsFromHop::DuplicateClaim = res { false } else { true };
let htlc_claim_value_msat = match res {
ClaimFundsFromHop::MonitorUpdateFail(_, _, amt_opt) => amt_opt,
ClaimFundsFromHop::Success(amt) => Some(amt),
_ => None,
};
if let ClaimFundsFromHop::PrevHopForceClosed = res {
let preimage_update = ChannelMonitorUpdate {
update_id: CLOSED_CHANNEL_UPDATE_ID,
updates: vec![ChannelMonitorUpdateStep::PaymentPreimage {
payment_preimage: payment_preimage.clone(),
}],
};
// We update the ChannelMonitor on the backward link, after
// receiving an offchain preimage event from the forward link (the
// event being update_fulfill_htlc).
if let Err(e) = self.chain_monitor.update_channel(prev_outpoint, preimage_update) {
log_error!(self.logger, "Critical error: failed to update channel monitor with preimage {:?}: {:?}",
payment_preimage, e);
}
// Note that we do *not* set `claimed_htlc` to false here. In fact, this
// totally could be a duplicate claim, but we have no way of knowing
// without interrogating the `ChannelMonitor` we've provided the above
// update to. Instead, we simply document in `PaymentForwarded` that this
// can happen.
}
mem::drop(channel_state_lock);
if let ClaimFundsFromHop::MonitorUpdateFail(pk, err, _) = res {
let result: Result<(), _> = Err(err);
let _ = handle_error!(self, result, pk);
}
if claimed_htlc {
if let Some(forwarded_htlc_value) = forwarded_htlc_value_msat {
let fee_earned_msat = if let Some(claimed_htlc_value) = htlc_claim_value_msat {
Some(claimed_htlc_value - forwarded_htlc_value)
} else { None };
let mut pending_events = self.pending_events.lock().unwrap();
let prev_channel_id = Some(prev_outpoint.to_channel_id());
let next_channel_id = Some(next_channel_id);
pending_events.push(events::Event::PaymentForwarded {
fee_earned_msat,
claim_from_onchain_tx: from_onchain,
prev_channel_id,
next_channel_id,
});
}
}
},
}
}
/// Gets the node_id held by this ChannelManager
pub fn get_our_node_id(&self) -> PublicKey {
self.our_network_pubkey.clone()
}
fn channel_monitor_updated(&self, funding_txo: &OutPoint, highest_applied_update_id: u64) {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
let chan_restoration_res;
let (mut pending_failures, finalized_claims) = {
let mut channel_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_lock;
let mut channel = match channel_state.by_id.entry(funding_txo.to_channel_id()) {
hash_map::Entry::Occupied(chan) => chan,
hash_map::Entry::Vacant(_) => return,
};
if !channel.get().is_awaiting_monitor_update() || channel.get().get_latest_monitor_update_id() != highest_applied_update_id {
return;
}
let updates = channel.get_mut().monitor_updating_restored(&self.logger, self.get_our_node_id(), self.genesis_hash, self.best_block.read().unwrap().height());
let channel_update = if updates.channel_ready.is_some() && channel.get().is_usable() {
// We only send a channel_update in the case where we are just now sending a
// channel_ready and the channel is in a usable state. We may re-send a
// channel_update later through the announcement_signatures process for public
// channels, but there's no reason not to just inform our counterparty of our fees
// now.
if let Ok(msg) = self.get_channel_update_for_unicast(channel.get()) {
Some(events::MessageSendEvent::SendChannelUpdate {
node_id: channel.get().get_counterparty_node_id(),
msg,
})
} else { None }
} else { None };
chan_restoration_res = handle_chan_restoration_locked!(self, channel_lock, channel_state, channel, updates.raa, updates.commitment_update, updates.order, None, updates.accepted_htlcs, updates.funding_broadcastable, updates.channel_ready, updates.announcement_sigs);
if let Some(upd) = channel_update {
channel_state.pending_msg_events.push(upd);
}
(updates.failed_htlcs, updates.finalized_claimed_htlcs)
};
post_handle_chan_restoration!(self, chan_restoration_res);
self.finalize_claims(finalized_claims);
for failure in pending_failures.drain(..) {
self.fail_htlc_backwards_internal(self.channel_state.lock().unwrap(), failure.0, &failure.1, failure.2);
}
}
/// Accepts a request to open a channel after a [`Event::OpenChannelRequest`].
///
/// The `temporary_channel_id` parameter indicates which inbound channel should be accepted,
/// and the `counterparty_node_id` parameter is the id of the peer which has requested to open
/// the channel.
///
/// The `user_channel_id` parameter will be provided back in
/// [`Event::ChannelClosed::user_channel_id`] to allow tracking of which events correspond
/// with which `accept_inbound_channel`/`accept_inbound_channel_from_trusted_peer_0conf` call.
///
/// Note that this method will return an error and reject the channel, if it requires support
/// for zero confirmations. Instead, `accept_inbound_channel_from_trusted_peer_0conf` must be
/// used to accept such channels.
///
/// [`Event::OpenChannelRequest`]: events::Event::OpenChannelRequest
/// [`Event::ChannelClosed::user_channel_id`]: events::Event::ChannelClosed::user_channel_id
pub fn accept_inbound_channel(&self, temporary_channel_id: &[u8; 32], counterparty_node_id: &PublicKey, user_channel_id: u64) -> Result<(), APIError> {
self.do_accept_inbound_channel(temporary_channel_id, counterparty_node_id, false, user_channel_id)
}
/// Accepts a request to open a channel after a [`events::Event::OpenChannelRequest`], treating
/// it as confirmed immediately.
///
/// The `user_channel_id` parameter will be provided back in
/// [`Event::ChannelClosed::user_channel_id`] to allow tracking of which events correspond
/// with which `accept_inbound_channel`/`accept_inbound_channel_from_trusted_peer_0conf` call.
///
/// Unlike [`ChannelManager::accept_inbound_channel`], this method accepts the incoming channel
/// and (if the counterparty agrees), enables forwarding of payments immediately.
///
/// This fully trusts that the counterparty has honestly and correctly constructed the funding
/// transaction and blindly assumes that it will eventually confirm.
///
/// If it does not confirm before we decide to close the channel, or if the funding transaction
/// does not pay to the correct script the correct amount, *you will lose funds*.
///
/// [`Event::OpenChannelRequest`]: events::Event::OpenChannelRequest
/// [`Event::ChannelClosed::user_channel_id`]: events::Event::ChannelClosed::user_channel_id
pub fn accept_inbound_channel_from_trusted_peer_0conf(&self, temporary_channel_id: &[u8; 32], counterparty_node_id: &PublicKey, user_channel_id: u64) -> Result<(), APIError> {
self.do_accept_inbound_channel(temporary_channel_id, counterparty_node_id, true, user_channel_id)
}
fn do_accept_inbound_channel(&self, temporary_channel_id: &[u8; 32], counterparty_node_id: &PublicKey, accept_0conf: bool, user_channel_id: u64) -> Result<(), APIError> {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
let mut channel_state_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_state_lock;
match channel_state.by_id.entry(temporary_channel_id.clone()) {
hash_map::Entry::Occupied(mut channel) => {
if !channel.get().inbound_is_awaiting_accept() {
return Err(APIError::APIMisuseError { err: "The channel isn't currently awaiting to be accepted.".to_owned() });
}
if *counterparty_node_id != channel.get().get_counterparty_node_id() {
return Err(APIError::APIMisuseError { err: "The passed counterparty_node_id doesn't match the channel's counterparty node_id".to_owned() });
}
if accept_0conf {
channel.get_mut().set_0conf();
} else if channel.get().get_channel_type().requires_zero_conf() {
let send_msg_err_event = events::MessageSendEvent::HandleError {
node_id: channel.get().get_counterparty_node_id(),
action: msgs::ErrorAction::SendErrorMessage{
msg: msgs::ErrorMessage { channel_id: temporary_channel_id.clone(), data: "No zero confirmation channels accepted".to_owned(), }
}
};
channel_state.pending_msg_events.push(send_msg_err_event);
let _ = remove_channel!(self, channel_state, channel);
return Err(APIError::APIMisuseError { err: "Please use accept_inbound_channel_from_trusted_peer_0conf to accept channels with zero confirmations.".to_owned() });
}
channel_state.pending_msg_events.push(events::MessageSendEvent::SendAcceptChannel {
node_id: channel.get().get_counterparty_node_id(),
msg: channel.get_mut().accept_inbound_channel(user_channel_id),
});
}
hash_map::Entry::Vacant(_) => {
return Err(APIError::ChannelUnavailable { err: "Can't accept a channel that doesn't exist".to_owned() });
}
}
Ok(())
}
fn internal_open_channel(&self, counterparty_node_id: &PublicKey, their_features: InitFeatures, msg: &msgs::OpenChannel) -> Result<(), MsgHandleErrInternal> {
if msg.chain_hash != self.genesis_hash {
return Err(MsgHandleErrInternal::send_err_msg_no_close("Unknown genesis block hash".to_owned(), msg.temporary_channel_id.clone()));
}
if !self.default_configuration.accept_inbound_channels {
return Err(MsgHandleErrInternal::send_err_msg_no_close("No inbound channels accepted".to_owned(), msg.temporary_channel_id.clone()));
}
let outbound_scid_alias = self.create_and_insert_outbound_scid_alias();
let mut channel = match Channel::new_from_req(&self.fee_estimator, &self.keys_manager,
counterparty_node_id.clone(), &their_features, msg, 0, &self.default_configuration,
self.best_block.read().unwrap().height(), &self.logger, outbound_scid_alias)
{
Err(e) => {
self.outbound_scid_aliases.lock().unwrap().remove(&outbound_scid_alias);
return Err(MsgHandleErrInternal::from_chan_no_close(e, msg.temporary_channel_id));
},
Ok(res) => res
};
let mut channel_state_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_state_lock;
match channel_state.by_id.entry(channel.channel_id()) {
hash_map::Entry::Occupied(_) => {
self.outbound_scid_aliases.lock().unwrap().remove(&outbound_scid_alias);
return Err(MsgHandleErrInternal::send_err_msg_no_close("temporary_channel_id collision!".to_owned(), msg.temporary_channel_id.clone()))
},
hash_map::Entry::Vacant(entry) => {
if !self.default_configuration.manually_accept_inbound_channels {
if channel.get_channel_type().requires_zero_conf() {
return Err(MsgHandleErrInternal::send_err_msg_no_close("No zero confirmation channels accepted".to_owned(), msg.temporary_channel_id.clone()));
}
channel_state.pending_msg_events.push(events::MessageSendEvent::SendAcceptChannel {
node_id: counterparty_node_id.clone(),
msg: channel.accept_inbound_channel(0),
});
} else {
let mut pending_events = self.pending_events.lock().unwrap();
pending_events.push(
events::Event::OpenChannelRequest {
temporary_channel_id: msg.temporary_channel_id.clone(),
counterparty_node_id: counterparty_node_id.clone(),
funding_satoshis: msg.funding_satoshis,
push_msat: msg.push_msat,
channel_type: channel.get_channel_type().clone(),
}
);
}
entry.insert(channel);
}
}
Ok(())
}
fn internal_accept_channel(&self, counterparty_node_id: &PublicKey, their_features: InitFeatures, msg: &msgs::AcceptChannel) -> Result<(), MsgHandleErrInternal> {
let (value, output_script, user_id) = {
let mut channel_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_lock;
match channel_state.by_id.entry(msg.temporary_channel_id) {
hash_map::Entry::Occupied(mut chan) => {
if chan.get().get_counterparty_node_id() != *counterparty_node_id {
return Err(MsgHandleErrInternal::send_err_msg_no_close("Got a message for a channel from the wrong node!".to_owned(), msg.temporary_channel_id));
}
try_chan_entry!(self, chan.get_mut().accept_channel(&msg, &self.default_configuration.peer_channel_config_limits, &their_features), channel_state, chan);
(chan.get().get_value_satoshis(), chan.get().get_funding_redeemscript().to_v0_p2wsh(), chan.get().get_user_id())
},
hash_map::Entry::Vacant(_) => return Err(MsgHandleErrInternal::send_err_msg_no_close("Failed to find corresponding channel".to_owned(), msg.temporary_channel_id))
}
};
let mut pending_events = self.pending_events.lock().unwrap();
pending_events.push(events::Event::FundingGenerationReady {
temporary_channel_id: msg.temporary_channel_id,
counterparty_node_id: *counterparty_node_id,
channel_value_satoshis: value,
output_script,
user_channel_id: user_id,
});
Ok(())
}
fn internal_funding_created(&self, counterparty_node_id: &PublicKey, msg: &msgs::FundingCreated) -> Result<(), MsgHandleErrInternal> {
let ((funding_msg, monitor, mut channel_ready), mut chan) = {
let best_block = *self.best_block.read().unwrap();
let mut channel_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_lock;
match channel_state.by_id.entry(msg.temporary_channel_id.clone()) {
hash_map::Entry::Occupied(mut chan) => {
if chan.get().get_counterparty_node_id() != *counterparty_node_id {
return Err(MsgHandleErrInternal::send_err_msg_no_close("Got a message for a channel from the wrong node!".to_owned(), msg.temporary_channel_id));
}
(try_chan_entry!(self, chan.get_mut().funding_created(msg, best_block, &self.logger), channel_state, chan), chan.remove())
},
hash_map::Entry::Vacant(_) => return Err(MsgHandleErrInternal::send_err_msg_no_close("Failed to find corresponding channel".to_owned(), msg.temporary_channel_id))
}
};
// Because we have exclusive ownership of the channel here we can release the channel_state
// lock before watch_channel
if let Err(e) = self.chain_monitor.watch_channel(monitor.get_funding_txo().0, monitor) {
match e {
ChannelMonitorUpdateErr::PermanentFailure => {
// Note that we reply with the new channel_id in error messages if we gave up on the
// channel, not the temporary_channel_id. This is compatible with ourselves, but the
// spec is somewhat ambiguous here. Not a huge deal since we'll send error messages for
// any messages referencing a previously-closed channel anyway.
// We do not do a force-close here as that would generate a monitor update for
// a monitor that we didn't manage to store (and that we don't care about - we
// don't respond with the funding_signed so the channel can never go on chain).
let (_monitor_update, failed_htlcs) = chan.force_shutdown(true);
assert!(failed_htlcs.is_empty());
return Err(MsgHandleErrInternal::send_err_msg_no_close("ChannelMonitor storage failure".to_owned(), funding_msg.channel_id));
},
ChannelMonitorUpdateErr::TemporaryFailure => {
// There's no problem signing a counterparty's funding transaction if our monitor
// hasn't persisted to disk yet - we can't lose money on a transaction that we haven't
// accepted payment from yet. We do, however, need to wait to send our channel_ready
// until we have persisted our monitor.
chan.monitor_update_failed(false, false, channel_ready.is_some(), Vec::new(), Vec::new(), Vec::new());
channel_ready = None; // Don't send the channel_ready now
},
}
}
let mut channel_state_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_state_lock;
match channel_state.by_id.entry(funding_msg.channel_id) {
hash_map::Entry::Occupied(_) => {
return Err(MsgHandleErrInternal::send_err_msg_no_close("Already had channel with the new channel_id".to_owned(), funding_msg.channel_id))
},
hash_map::Entry::Vacant(e) => {
channel_state.pending_msg_events.push(events::MessageSendEvent::SendFundingSigned {
node_id: counterparty_node_id.clone(),
msg: funding_msg,
});
if let Some(msg) = channel_ready {
send_channel_ready!(channel_state.short_to_id, channel_state.pending_msg_events, chan, msg);
}
e.insert(chan);
}
}
Ok(())
}
fn internal_funding_signed(&self, counterparty_node_id: &PublicKey, msg: &msgs::FundingSigned) -> Result<(), MsgHandleErrInternal> {
let funding_tx = {
let best_block = *self.best_block.read().unwrap();
let mut channel_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_lock;
match channel_state.by_id.entry(msg.channel_id) {
hash_map::Entry::Occupied(mut chan) => {
if chan.get().get_counterparty_node_id() != *counterparty_node_id {
return Err(MsgHandleErrInternal::send_err_msg_no_close("Got a message for a channel from the wrong node!".to_owned(), msg.channel_id));
}
let (monitor, funding_tx, channel_ready) = match chan.get_mut().funding_signed(&msg, best_block, &self.logger) {
Ok(update) => update,
Err(e) => try_chan_entry!(self, Err(e), channel_state, chan),
};
if let Err(e) = self.chain_monitor.watch_channel(chan.get().get_funding_txo().unwrap(), monitor) {
let mut res = handle_monitor_err!(self, e, channel_state, chan, RAACommitmentOrder::RevokeAndACKFirst, channel_ready.is_some(), OPTIONALLY_RESEND_FUNDING_LOCKED);
if let Err(MsgHandleErrInternal { ref mut shutdown_finish, .. }) = res {
// We weren't able to watch the channel to begin with, so no updates should be made on
// it. Previously, full_stack_target found an (unreachable) panic when the
// monitor update contained within `shutdown_finish` was applied.
if let Some((ref mut shutdown_finish, _)) = shutdown_finish {
shutdown_finish.0.take();
}
}
return res
}
if let Some(msg) = channel_ready {
send_channel_ready!(channel_state.short_to_id, channel_state.pending_msg_events, chan.get(), msg);
}
funding_tx
},
hash_map::Entry::Vacant(_) => return Err(MsgHandleErrInternal::send_err_msg_no_close("Failed to find corresponding channel".to_owned(), msg.channel_id))
}
};
log_info!(self.logger, "Broadcasting funding transaction with txid {}", funding_tx.txid());
self.tx_broadcaster.broadcast_transaction(&funding_tx);
Ok(())
}
fn internal_channel_ready(&self, counterparty_node_id: &PublicKey, msg: &msgs::ChannelReady) -> Result<(), MsgHandleErrInternal> {
let mut channel_state_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_state_lock;
match channel_state.by_id.entry(msg.channel_id) {
hash_map::Entry::Occupied(mut chan) => {
if chan.get().get_counterparty_node_id() != *counterparty_node_id {
return Err(MsgHandleErrInternal::send_err_msg_no_close("Got a message for a channel from the wrong node!".to_owned(), msg.channel_id));
}
let announcement_sigs_opt = try_chan_entry!(self, chan.get_mut().channel_ready(&msg, self.get_our_node_id(),
self.genesis_hash.clone(), &self.best_block.read().unwrap(), &self.logger), channel_state, chan);
if let Some(announcement_sigs) = announcement_sigs_opt {
log_trace!(self.logger, "Sending announcement_signatures for channel {}", log_bytes!(chan.get().channel_id()));
channel_state.pending_msg_events.push(events::MessageSendEvent::SendAnnouncementSignatures {
node_id: counterparty_node_id.clone(),
msg: announcement_sigs,
});
} else if chan.get().is_usable() {
// If we're sending an announcement_signatures, we'll send the (public)
// channel_update after sending a channel_announcement when we receive our
// counterparty's announcement_signatures. Thus, we only bother to send a
// channel_update here if the channel is not public, i.e. we're not sending an
// announcement_signatures.
log_trace!(self.logger, "Sending private initial channel_update for our counterparty on channel {}", log_bytes!(chan.get().channel_id()));
if let Ok(msg) = self.get_channel_update_for_unicast(chan.get()) {
channel_state.pending_msg_events.push(events::MessageSendEvent::SendChannelUpdate {
node_id: counterparty_node_id.clone(),
msg,
});
}
}
Ok(())
},
hash_map::Entry::Vacant(_) => Err(MsgHandleErrInternal::send_err_msg_no_close("Failed to find corresponding channel".to_owned(), msg.channel_id))
}
}
fn internal_shutdown(&self, counterparty_node_id: &PublicKey, their_features: &InitFeatures, msg: &msgs::Shutdown) -> Result<(), MsgHandleErrInternal> {
let mut dropped_htlcs: Vec<(HTLCSource, PaymentHash)>;
let result: Result<(), _> = loop {
let mut channel_state_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_state_lock;
match channel_state.by_id.entry(msg.channel_id.clone()) {
hash_map::Entry::Occupied(mut chan_entry) => {
if chan_entry.get().get_counterparty_node_id() != *counterparty_node_id {
return Err(MsgHandleErrInternal::send_err_msg_no_close("Got a message for a channel from the wrong node!".to_owned(), msg.channel_id));
}
if !chan_entry.get().received_shutdown() {
log_info!(self.logger, "Received a shutdown message from our counterparty for channel {}{}.",
log_bytes!(msg.channel_id),
if chan_entry.get().sent_shutdown() { " after we initiated shutdown" } else { "" });
}
let (shutdown, monitor_update, htlcs) = try_chan_entry!(self, chan_entry.get_mut().shutdown(&self.keys_manager, &their_features, &msg), channel_state, chan_entry);
dropped_htlcs = htlcs;
// Update the monitor with the shutdown script if necessary.
if let Some(monitor_update) = monitor_update {
if let Err(e) = self.chain_monitor.update_channel(chan_entry.get().get_funding_txo().unwrap(), monitor_update) {
let (result, is_permanent) =
handle_monitor_err!(self, e, channel_state.short_to_id, chan_entry.get_mut(), RAACommitmentOrder::CommitmentFirst, chan_entry.key(), NO_UPDATE);
if is_permanent {
remove_channel!(self, channel_state, chan_entry);
break result;
}
}
}
if let Some(msg) = shutdown {
channel_state.pending_msg_events.push(events::MessageSendEvent::SendShutdown {
node_id: *counterparty_node_id,
msg,
});
}
break Ok(());
},
hash_map::Entry::Vacant(_) => return Err(MsgHandleErrInternal::send_err_msg_no_close("Failed to find corresponding channel".to_owned(), msg.channel_id))
}
};
for htlc_source in dropped_htlcs.drain(..) {
self.fail_htlc_backwards_internal(self.channel_state.lock().unwrap(), htlc_source.0, &htlc_source.1, HTLCFailReason::Reason { failure_code: 0x4000 | 8, data: Vec::new() });
}
let _ = handle_error!(self, result, *counterparty_node_id);
Ok(())
}
fn internal_closing_signed(&self, counterparty_node_id: &PublicKey, msg: &msgs::ClosingSigned) -> Result<(), MsgHandleErrInternal> {
let (tx, chan_option) = {
let mut channel_state_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_state_lock;
match channel_state.by_id.entry(msg.channel_id.clone()) {
hash_map::Entry::Occupied(mut chan_entry) => {
if chan_entry.get().get_counterparty_node_id() != *counterparty_node_id {
return Err(MsgHandleErrInternal::send_err_msg_no_close("Got a message for a channel from the wrong node!".to_owned(), msg.channel_id));
}
let (closing_signed, tx) = try_chan_entry!(self, chan_entry.get_mut().closing_signed(&self.fee_estimator, &msg), channel_state, chan_entry);
if let Some(msg) = closing_signed {
channel_state.pending_msg_events.push(events::MessageSendEvent::SendClosingSigned {
node_id: counterparty_node_id.clone(),
msg,
});
}
if tx.is_some() {
// We're done with this channel, we've got a signed closing transaction and
// will send the closing_signed back to the remote peer upon return. This
// also implies there are no pending HTLCs left on the channel, so we can
// fully delete it from tracking (the channel monitor is still around to
// watch for old state broadcasts)!
(tx, Some(remove_channel!(self, channel_state, chan_entry)))
} else { (tx, None) }
},
hash_map::Entry::Vacant(_) => return Err(MsgHandleErrInternal::send_err_msg_no_close("Failed to find corresponding channel".to_owned(), msg.channel_id))
}
};
if let Some(broadcast_tx) = tx {
log_info!(self.logger, "Broadcasting {}", log_tx!(broadcast_tx));
self.tx_broadcaster.broadcast_transaction(&broadcast_tx);
}
if let Some(chan) = chan_option {
if let Ok(update) = self.get_channel_update_for_broadcast(&chan) {
let mut channel_state = self.channel_state.lock().unwrap();
channel_state.pending_msg_events.push(events::MessageSendEvent::BroadcastChannelUpdate {
msg: update
});
}
self.issue_channel_close_events(&chan, ClosureReason::CooperativeClosure);
}
Ok(())
}
fn internal_update_add_htlc(&self, counterparty_node_id: &PublicKey, msg: &msgs::UpdateAddHTLC) -> Result<(), MsgHandleErrInternal> {
//TODO: BOLT 4 points out a specific attack where a peer may re-send an onion packet and
//determine the state of the payment based on our response/if we forward anything/the time
//we take to respond. We should take care to avoid allowing such an attack.
//
//TODO: There exists a further attack where a node may garble the onion data, forward it to
//us repeatedly garbled in different ways, and compare our error messages, which are
//encrypted with the same key. It's not immediately obvious how to usefully exploit that,
//but we should prevent it anyway.
let (pending_forward_info, mut channel_state_lock) = self.decode_update_add_htlc_onion(msg);
let channel_state = &mut *channel_state_lock;
match channel_state.by_id.entry(msg.channel_id) {
hash_map::Entry::Occupied(mut chan) => {
if chan.get().get_counterparty_node_id() != *counterparty_node_id {
return Err(MsgHandleErrInternal::send_err_msg_no_close("Got a message for a channel from the wrong node!".to_owned(), msg.channel_id));
}
let create_pending_htlc_status = |chan: &Channel<Signer>, pending_forward_info: PendingHTLCStatus, error_code: u16| {
// If the update_add is completely bogus, the call will Err and we will close,
// but if we've sent a shutdown and they haven't acknowledged it yet, we just
// want to reject the new HTLC and fail it backwards instead of forwarding.
match pending_forward_info {
PendingHTLCStatus::Forward(PendingHTLCInfo { ref incoming_shared_secret, .. }) => {
let reason = if (error_code & 0x1000) != 0 {
let (real_code, error_data) = self.get_htlc_inbound_temp_fail_err_and_data(error_code, chan);
onion_utils::build_first_hop_failure_packet(incoming_shared_secret, real_code, &error_data)
} else {
onion_utils::build_first_hop_failure_packet(incoming_shared_secret, error_code, &[])
};
let msg = msgs::UpdateFailHTLC {
channel_id: msg.channel_id,
htlc_id: msg.htlc_id,
reason
};
PendingHTLCStatus::Fail(HTLCFailureMsg::Relay(msg))
},
_ => pending_forward_info
}
};
try_chan_entry!(self, chan.get_mut().update_add_htlc(&msg, pending_forward_info, create_pending_htlc_status, &self.logger), channel_state, chan);
},
hash_map::Entry::Vacant(_) => return Err(MsgHandleErrInternal::send_err_msg_no_close("Failed to find corresponding channel".to_owned(), msg.channel_id))
}
Ok(())
}
fn internal_update_fulfill_htlc(&self, counterparty_node_id: &PublicKey, msg: &msgs::UpdateFulfillHTLC) -> Result<(), MsgHandleErrInternal> {
let mut channel_lock = self.channel_state.lock().unwrap();
let (htlc_source, forwarded_htlc_value) = {
let channel_state = &mut *channel_lock;
match channel_state.by_id.entry(msg.channel_id) {
hash_map::Entry::Occupied(mut chan) => {
if chan.get().get_counterparty_node_id() != *counterparty_node_id {
return Err(MsgHandleErrInternal::send_err_msg_no_close("Got a message for a channel from the wrong node!".to_owned(), msg.channel_id));
}
try_chan_entry!(self, chan.get_mut().update_fulfill_htlc(&msg), channel_state, chan)
},
hash_map::Entry::Vacant(_) => return Err(MsgHandleErrInternal::send_err_msg_no_close("Failed to find corresponding channel".to_owned(), msg.channel_id))
}
};
self.claim_funds_internal(channel_lock, htlc_source, msg.payment_preimage.clone(), Some(forwarded_htlc_value), false, msg.channel_id);
Ok(())
}
fn internal_update_fail_htlc(&self, counterparty_node_id: &PublicKey, msg: &msgs::UpdateFailHTLC) -> Result<(), MsgHandleErrInternal> {
let mut channel_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_lock;
match channel_state.by_id.entry(msg.channel_id) {
hash_map::Entry::Occupied(mut chan) => {
if chan.get().get_counterparty_node_id() != *counterparty_node_id {
return Err(MsgHandleErrInternal::send_err_msg_no_close("Got a message for a channel from the wrong node!".to_owned(), msg.channel_id));
}
try_chan_entry!(self, chan.get_mut().update_fail_htlc(&msg, HTLCFailReason::LightningError { err: msg.reason.clone() }), channel_state, chan);
},
hash_map::Entry::Vacant(_) => return Err(MsgHandleErrInternal::send_err_msg_no_close("Failed to find corresponding channel".to_owned(), msg.channel_id))
}
Ok(())
}
fn internal_update_fail_malformed_htlc(&self, counterparty_node_id: &PublicKey, msg: &msgs::UpdateFailMalformedHTLC) -> Result<(), MsgHandleErrInternal> {
let mut channel_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_lock;
match channel_state.by_id.entry(msg.channel_id) {
hash_map::Entry::Occupied(mut chan) => {
if chan.get().get_counterparty_node_id() != *counterparty_node_id {
return Err(MsgHandleErrInternal::send_err_msg_no_close("Got a message for a channel from the wrong node!".to_owned(), msg.channel_id));
}
if (msg.failure_code & 0x8000) == 0 {
let chan_err: ChannelError = ChannelError::Close("Got update_fail_malformed_htlc with BADONION not set".to_owned());
try_chan_entry!(self, Err(chan_err), channel_state, chan);
}
try_chan_entry!(self, chan.get_mut().update_fail_malformed_htlc(&msg, HTLCFailReason::Reason { failure_code: msg.failure_code, data: Vec::new() }), channel_state, chan);
Ok(())
},
hash_map::Entry::Vacant(_) => return Err(MsgHandleErrInternal::send_err_msg_no_close("Failed to find corresponding channel".to_owned(), msg.channel_id))
}
}
fn internal_commitment_signed(&self, counterparty_node_id: &PublicKey, msg: &msgs::CommitmentSigned) -> Result<(), MsgHandleErrInternal> {
let mut channel_state_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_state_lock;
match channel_state.by_id.entry(msg.channel_id) {
hash_map::Entry::Occupied(mut chan) => {
if chan.get().get_counterparty_node_id() != *counterparty_node_id {
return Err(MsgHandleErrInternal::send_err_msg_no_close("Got a message for a channel from the wrong node!".to_owned(), msg.channel_id));
}
let (revoke_and_ack, commitment_signed, monitor_update) =
match chan.get_mut().commitment_signed(&msg, &self.logger) {
Err((None, e)) => try_chan_entry!(self, Err(e), channel_state, chan),
Err((Some(update), e)) => {
assert!(chan.get().is_awaiting_monitor_update());
let _ = self.chain_monitor.update_channel(chan.get().get_funding_txo().unwrap(), update);
try_chan_entry!(self, Err(e), channel_state, chan);
unreachable!();
},
Ok(res) => res
};
if let Err(e) = self.chain_monitor.update_channel(chan.get().get_funding_txo().unwrap(), monitor_update) {
return_monitor_err!(self, e, channel_state, chan, RAACommitmentOrder::RevokeAndACKFirst, true, commitment_signed.is_some());
}
channel_state.pending_msg_events.push(events::MessageSendEvent::SendRevokeAndACK {
node_id: counterparty_node_id.clone(),
msg: revoke_and_ack,
});
if let Some(msg) = commitment_signed {
channel_state.pending_msg_events.push(events::MessageSendEvent::UpdateHTLCs {
node_id: counterparty_node_id.clone(),
updates: msgs::CommitmentUpdate {
update_add_htlcs: Vec::new(),
update_fulfill_htlcs: Vec::new(),
update_fail_htlcs: Vec::new(),
update_fail_malformed_htlcs: Vec::new(),
update_fee: None,
commitment_signed: msg,
},
});
}
Ok(())
},
hash_map::Entry::Vacant(_) => return Err(MsgHandleErrInternal::send_err_msg_no_close("Failed to find corresponding channel".to_owned(), msg.channel_id))
}
}
#[inline]
fn forward_htlcs(&self, per_source_pending_forwards: &mut [(u64, OutPoint, Vec<(PendingHTLCInfo, u64)>)]) {
for &mut (prev_short_channel_id, prev_funding_outpoint, ref mut pending_forwards) in per_source_pending_forwards {
let mut forward_event = None;
if !pending_forwards.is_empty() {
let mut channel_state = self.channel_state.lock().unwrap();
if channel_state.forward_htlcs.is_empty() {
forward_event = Some(Duration::from_millis(MIN_HTLC_RELAY_HOLDING_CELL_MILLIS))
}
for (forward_info, prev_htlc_id) in pending_forwards.drain(..) {
match channel_state.forward_htlcs.entry(match forward_info.routing {
PendingHTLCRouting::Forward { short_channel_id, .. } => short_channel_id,
PendingHTLCRouting::Receive { .. } => 0,
PendingHTLCRouting::ReceiveKeysend { .. } => 0,
}) {
hash_map::Entry::Occupied(mut entry) => {
entry.get_mut().push(HTLCForwardInfo::AddHTLC { prev_short_channel_id, prev_funding_outpoint,
prev_htlc_id, forward_info });
},
hash_map::Entry::Vacant(entry) => {
entry.insert(vec!(HTLCForwardInfo::AddHTLC { prev_short_channel_id, prev_funding_outpoint,
prev_htlc_id, forward_info }));
}
}
}
}
match forward_event {
Some(time) => {
let mut pending_events = self.pending_events.lock().unwrap();
pending_events.push(events::Event::PendingHTLCsForwardable {
time_forwardable: time
});
}
None => {},
}
}
}
fn internal_revoke_and_ack(&self, counterparty_node_id: &PublicKey, msg: &msgs::RevokeAndACK) -> Result<(), MsgHandleErrInternal> {
let mut htlcs_to_fail = Vec::new();
let res = loop {
let mut channel_state_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_state_lock;
match channel_state.by_id.entry(msg.channel_id) {
hash_map::Entry::Occupied(mut chan) => {
if chan.get().get_counterparty_node_id() != *counterparty_node_id {
break Err(MsgHandleErrInternal::send_err_msg_no_close("Got a message for a channel from the wrong node!".to_owned(), msg.channel_id));
}
let was_frozen_for_monitor = chan.get().is_awaiting_monitor_update();
let raa_updates = break_chan_entry!(self,
chan.get_mut().revoke_and_ack(&msg, &self.logger), channel_state, chan);
htlcs_to_fail = raa_updates.holding_cell_failed_htlcs;
if let Err(e) = self.chain_monitor.update_channel(chan.get().get_funding_txo().unwrap(), raa_updates.monitor_update) {
if was_frozen_for_monitor {
assert!(raa_updates.commitment_update.is_none());
assert!(raa_updates.accepted_htlcs.is_empty());
assert!(raa_updates.failed_htlcs.is_empty());
assert!(raa_updates.finalized_claimed_htlcs.is_empty());
break Err(MsgHandleErrInternal::ignore_no_close("Previous monitor update failure prevented responses to RAA".to_owned()));
} else {
if let Err(e) = handle_monitor_err!(self, e, channel_state, chan,
RAACommitmentOrder::CommitmentFirst, false,
raa_updates.commitment_update.is_some(), false,
raa_updates.accepted_htlcs, raa_updates.failed_htlcs,
raa_updates.finalized_claimed_htlcs) {
break Err(e);
} else { unreachable!(); }
}
}
if let Some(updates) = raa_updates.commitment_update {
channel_state.pending_msg_events.push(events::MessageSendEvent::UpdateHTLCs {
node_id: counterparty_node_id.clone(),
updates,
});
}
break Ok((raa_updates.accepted_htlcs, raa_updates.failed_htlcs,
raa_updates.finalized_claimed_htlcs,
chan.get().get_short_channel_id()
.unwrap_or(chan.get().outbound_scid_alias()),
chan.get().get_funding_txo().unwrap()))
},
hash_map::Entry::Vacant(_) => break Err(MsgHandleErrInternal::send_err_msg_no_close("Failed to find corresponding channel".to_owned(), msg.channel_id))
}
};
self.fail_holding_cell_htlcs(htlcs_to_fail, msg.channel_id);
match res {
Ok((pending_forwards, mut pending_failures, finalized_claim_htlcs,
short_channel_id, channel_outpoint)) =>
{
for failure in pending_failures.drain(..) {
self.fail_htlc_backwards_internal(self.channel_state.lock().unwrap(), failure.0, &failure.1, failure.2);
}
self.forward_htlcs(&mut [(short_channel_id, channel_outpoint, pending_forwards)]);
self.finalize_claims(finalized_claim_htlcs);
Ok(())
},
Err(e) => Err(e)
}
}
fn internal_update_fee(&self, counterparty_node_id: &PublicKey, msg: &msgs::UpdateFee) -> Result<(), MsgHandleErrInternal> {
let mut channel_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_lock;
match channel_state.by_id.entry(msg.channel_id) {
hash_map::Entry::Occupied(mut chan) => {
if chan.get().get_counterparty_node_id() != *counterparty_node_id {
return Err(MsgHandleErrInternal::send_err_msg_no_close("Got a message for a channel from the wrong node!".to_owned(), msg.channel_id));
}
try_chan_entry!(self, chan.get_mut().update_fee(&self.fee_estimator, &msg), channel_state, chan);
},
hash_map::Entry::Vacant(_) => return Err(MsgHandleErrInternal::send_err_msg_no_close("Failed to find corresponding channel".to_owned(), msg.channel_id))
}
Ok(())
}
fn internal_announcement_signatures(&self, counterparty_node_id: &PublicKey, msg: &msgs::AnnouncementSignatures) -> Result<(), MsgHandleErrInternal> {
let mut channel_state_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_state_lock;
match channel_state.by_id.entry(msg.channel_id) {
hash_map::Entry::Occupied(mut chan) => {
if chan.get().get_counterparty_node_id() != *counterparty_node_id {
return Err(MsgHandleErrInternal::send_err_msg_no_close("Got a message for a channel from the wrong node!".to_owned(), msg.channel_id));
}
if !chan.get().is_usable() {
return Err(MsgHandleErrInternal::from_no_close(LightningError{err: "Got an announcement_signatures before we were ready for it".to_owned(), action: msgs::ErrorAction::IgnoreError}));
}
channel_state.pending_msg_events.push(events::MessageSendEvent::BroadcastChannelAnnouncement {
msg: try_chan_entry!(self, chan.get_mut().announcement_signatures(
self.get_our_node_id(), self.genesis_hash.clone(), self.best_block.read().unwrap().height(), msg), channel_state, chan),
// Note that announcement_signatures fails if the channel cannot be announced,
// so get_channel_update_for_broadcast will never fail by the time we get here.
update_msg: self.get_channel_update_for_broadcast(chan.get()).unwrap(),
});
},
hash_map::Entry::Vacant(_) => return Err(MsgHandleErrInternal::send_err_msg_no_close("Failed to find corresponding channel".to_owned(), msg.channel_id))
}
Ok(())
}
/// Returns ShouldPersist if anything changed, otherwise either SkipPersist or an Err.
fn internal_channel_update(&self, counterparty_node_id: &PublicKey, msg: &msgs::ChannelUpdate) -> Result<NotifyOption, MsgHandleErrInternal> {
let mut channel_state_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_state_lock;
let chan_id = match channel_state.short_to_id.get(&msg.contents.short_channel_id) {
Some(chan_id) => chan_id.clone(),
None => {
// It's not a local channel
return Ok(NotifyOption::SkipPersist)
}
};
match channel_state.by_id.entry(chan_id) {
hash_map::Entry::Occupied(mut chan) => {
if chan.get().get_counterparty_node_id() != *counterparty_node_id {
if chan.get().should_announce() {
// If the announcement is about a channel of ours which is public, some
// other peer may simply be forwarding all its gossip to us. Don't provide
// a scary-looking error message and return Ok instead.
return Ok(NotifyOption::SkipPersist);
}
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));
}
let were_node_one = self.get_our_node_id().serialize()[..] < chan.get().get_counterparty_node_id().serialize()[..];
let msg_from_node_one = msg.contents.flags & 1 == 0;
if were_node_one == msg_from_node_one {
return Ok(NotifyOption::SkipPersist);
} else {
try_chan_entry!(self, chan.get_mut().channel_update(&msg), channel_state, chan);
}
},
hash_map::Entry::Vacant(_) => unreachable!()
}
Ok(NotifyOption::DoPersist)
}
fn internal_channel_reestablish(&self, counterparty_node_id: &PublicKey, msg: &msgs::ChannelReestablish) -> Result<(), MsgHandleErrInternal> {
let chan_restoration_res;
let (htlcs_failed_forward, need_lnd_workaround) = {
let mut channel_state_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_state_lock;
match channel_state.by_id.entry(msg.channel_id) {
hash_map::Entry::Occupied(mut chan) => {
if chan.get().get_counterparty_node_id() != *counterparty_node_id {
return Err(MsgHandleErrInternal::send_err_msg_no_close("Got a message for a channel from the wrong node!".to_owned(), msg.channel_id));
}
// Currently, we expect all holding cell update_adds to be dropped on peer
// disconnect, so Channel's reestablish will never hand us any holding cell
// freed HTLCs to fail backwards. If in the future we no longer drop pending
// add-HTLCs on disconnect, we may be handed HTLCs to fail backwards here.
let responses = try_chan_entry!(self, chan.get_mut().channel_reestablish(
msg, &self.logger, self.our_network_pubkey.clone(), self.genesis_hash,
&*self.best_block.read().unwrap()), channel_state, chan);
let mut channel_update = None;
if let Some(msg) = responses.shutdown_msg {
channel_state.pending_msg_events.push(events::MessageSendEvent::SendShutdown {
node_id: counterparty_node_id.clone(),
msg,
});
} else if chan.get().is_usable() {
// If the channel is in a usable state (ie the channel is not being shut
// down), send a unicast channel_update to our counterparty to make sure
// they have the latest channel parameters.
if let Ok(msg) = self.get_channel_update_for_unicast(chan.get()) {
channel_update = Some(events::MessageSendEvent::SendChannelUpdate {
node_id: chan.get().get_counterparty_node_id(),
msg,
});
}
}
let need_lnd_workaround = chan.get_mut().workaround_lnd_bug_4006.take();
chan_restoration_res = handle_chan_restoration_locked!(
self, channel_state_lock, channel_state, chan, responses.raa, responses.commitment_update, responses.order,
responses.mon_update, Vec::new(), None, responses.channel_ready, responses.announcement_sigs);
if let Some(upd) = channel_update {
channel_state.pending_msg_events.push(upd);
}
(responses.holding_cell_failed_htlcs, need_lnd_workaround)
},
hash_map::Entry::Vacant(_) => return Err(MsgHandleErrInternal::send_err_msg_no_close("Failed to find corresponding channel".to_owned(), msg.channel_id))
}
};
post_handle_chan_restoration!(self, chan_restoration_res);
self.fail_holding_cell_htlcs(htlcs_failed_forward, msg.channel_id);
if let Some(channel_ready_msg) = need_lnd_workaround {
self.internal_channel_ready(counterparty_node_id, &channel_ready_msg)?;
}
Ok(())
}
/// Process pending events from the `chain::Watch`, returning whether any events were processed.
fn process_pending_monitor_events(&self) -> bool {
let mut failed_channels = Vec::new();
let mut pending_monitor_events = self.chain_monitor.release_pending_monitor_events();
let has_pending_monitor_events = !pending_monitor_events.is_empty();
for (funding_outpoint, mut monitor_events) in pending_monitor_events.drain(..) {
for monitor_event in monitor_events.drain(..) {
match monitor_event {
MonitorEvent::HTLCEvent(htlc_update) => {
if let Some(preimage) = htlc_update.payment_preimage {
log_trace!(self.logger, "Claiming HTLC with preimage {} from our monitor", log_bytes!(preimage.0));
self.claim_funds_internal(self.channel_state.lock().unwrap(), htlc_update.source, preimage, htlc_update.htlc_value_satoshis.map(|v| v * 1000), true, funding_outpoint.to_channel_id());
} else {
log_trace!(self.logger, "Failing HTLC with hash {} from our monitor", log_bytes!(htlc_update.payment_hash.0));
self.fail_htlc_backwards_internal(self.channel_state.lock().unwrap(), htlc_update.source, &htlc_update.payment_hash, HTLCFailReason::Reason { failure_code: 0x4000 | 8, data: Vec::new() });
}
},
MonitorEvent::CommitmentTxConfirmed(funding_outpoint) |
MonitorEvent::UpdateFailed(funding_outpoint) => {
let mut channel_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_lock;
let by_id = &mut channel_state.by_id;
let pending_msg_events = &mut channel_state.pending_msg_events;
if let hash_map::Entry::Occupied(chan_entry) = by_id.entry(funding_outpoint.to_channel_id()) {
let mut chan = remove_channel!(self, channel_state, chan_entry);
failed_channels.push(chan.force_shutdown(false));
if let Ok(update) = self.get_channel_update_for_broadcast(&chan) {
pending_msg_events.push(events::MessageSendEvent::BroadcastChannelUpdate {
msg: update
});
}
let reason = if let MonitorEvent::UpdateFailed(_) = monitor_event {
ClosureReason::ProcessingError { err: "Failed to persist ChannelMonitor update during chain sync".to_string() }
} else {
ClosureReason::CommitmentTxConfirmed
};
self.issue_channel_close_events(&chan, reason);
pending_msg_events.push(events::MessageSendEvent::HandleError {
node_id: chan.get_counterparty_node_id(),
action: msgs::ErrorAction::SendErrorMessage {
msg: msgs::ErrorMessage { channel_id: chan.channel_id(), data: "Channel force-closed".to_owned() }
},
});
}
},
MonitorEvent::UpdateCompleted { funding_txo, monitor_update_id } => {
self.channel_monitor_updated(&funding_txo, monitor_update_id);
},
}
}
}
for failure in failed_channels.drain(..) {
self.finish_force_close_channel(failure);
}
has_pending_monitor_events
}
/// In chanmon_consistency_target, we'd like to be able to restore monitor updating without
/// handling all pending events (i.e. not PendingHTLCsForwardable). Thus, we expose monitor
/// update events as a separate process method here.
#[cfg(fuzzing)]
pub fn process_monitor_events(&self) {
self.process_pending_monitor_events();
}
/// Check the holding cell in each channel and free any pending HTLCs in them if possible.
/// Returns whether there were any updates such as if pending HTLCs were freed or a monitor
/// update was applied.
///
/// This should only apply to HTLCs which were added to the holding cell because we were
/// waiting on a monitor update to finish. In that case, we don't want to free the holding cell
/// directly in `channel_monitor_updated` as it may introduce deadlocks calling back into user
/// code to inform them of a channel monitor update.
fn check_free_holding_cells(&self) -> bool {
let mut has_monitor_update = false;
let mut failed_htlcs = Vec::new();
let mut handle_errors = Vec::new();
{
let mut channel_state_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_state_lock;
let by_id = &mut channel_state.by_id;
let short_to_id = &mut channel_state.short_to_id;
let pending_msg_events = &mut channel_state.pending_msg_events;
by_id.retain(|channel_id, chan| {
match chan.maybe_free_holding_cell_htlcs(&self.logger) {
Ok((commitment_opt, holding_cell_failed_htlcs)) => {
if !holding_cell_failed_htlcs.is_empty() {
failed_htlcs.push((holding_cell_failed_htlcs, *channel_id));
}
if let Some((commitment_update, monitor_update)) = commitment_opt {
if let Err(e) = self.chain_monitor.update_channel(chan.get_funding_txo().unwrap(), monitor_update) {
has_monitor_update = true;
let (res, close_channel) = handle_monitor_err!(self, e, short_to_id, chan, RAACommitmentOrder::CommitmentFirst, channel_id, COMMITMENT_UPDATE_ONLY);
handle_errors.push((chan.get_counterparty_node_id(), res));
if close_channel { return false; }
} else {
pending_msg_events.push(events::MessageSendEvent::UpdateHTLCs {
node_id: chan.get_counterparty_node_id(),
updates: commitment_update,
});
}
}
true
},
Err(e) => {
let (close_channel, res) = convert_chan_err!(self, e, short_to_id, chan, channel_id);
handle_errors.push((chan.get_counterparty_node_id(), Err(res)));
// ChannelClosed event is generated by handle_error for us
!close_channel
}
}
});
}
let has_update = has_monitor_update || !failed_htlcs.is_empty() || !handle_errors.is_empty();
for (failures, channel_id) in failed_htlcs.drain(..) {
self.fail_holding_cell_htlcs(failures, channel_id);
}
for (counterparty_node_id, err) in handle_errors.drain(..) {
let _ = handle_error!(self, err, counterparty_node_id);
}
has_update
}
/// Check whether any channels have finished removing all pending updates after a shutdown
/// exchange and can now send a closing_signed.
/// Returns whether any closing_signed messages were generated.
fn maybe_generate_initial_closing_signed(&self) -> bool {
let mut handle_errors: Vec<(PublicKey, Result<(), _>)> = Vec::new();
let mut has_update = false;
{
let mut channel_state_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_state_lock;
let by_id = &mut channel_state.by_id;
let short_to_id = &mut channel_state.short_to_id;
let pending_msg_events = &mut channel_state.pending_msg_events;
by_id.retain(|channel_id, chan| {
match chan.maybe_propose_closing_signed(&self.fee_estimator, &self.logger) {
Ok((msg_opt, tx_opt)) => {
if let Some(msg) = msg_opt {
has_update = true;
pending_msg_events.push(events::MessageSendEvent::SendClosingSigned {
node_id: chan.get_counterparty_node_id(), msg,
});
}
if let Some(tx) = tx_opt {
// We're done with this channel. We got a closing_signed and sent back
// a closing_signed with a closing transaction to broadcast.
if let Ok(update) = self.get_channel_update_for_broadcast(&chan) {
pending_msg_events.push(events::MessageSendEvent::BroadcastChannelUpdate {
msg: update
});
}
self.issue_channel_close_events(chan, ClosureReason::CooperativeClosure);
log_info!(self.logger, "Broadcasting {}", log_tx!(tx));
self.tx_broadcaster.broadcast_transaction(&tx);
update_maps_on_chan_removal!(self, short_to_id, chan);
false
} else { true }
},
Err(e) => {
has_update = true;
let (close_channel, res) = convert_chan_err!(self, e, short_to_id, chan, channel_id);
handle_errors.push((chan.get_counterparty_node_id(), Err(res)));
!close_channel
}
}
});
}
for (counterparty_node_id, err) in handle_errors.drain(..) {
let _ = handle_error!(self, err, counterparty_node_id);
}
has_update
}
/// Handle a list of channel failures during a block_connected or block_disconnected call,
/// pushing the channel monitor update (if any) to the background events queue and removing the
/// Channel object.
fn handle_init_event_channel_failures(&self, mut failed_channels: Vec<ShutdownResult>) {
for mut failure in failed_channels.drain(..) {
// Either a commitment transactions has been confirmed on-chain or
// Channel::block_disconnected detected that the funding transaction has been
// reorganized out of the main chain.
// We cannot broadcast our latest local state via monitor update (as
// Channel::force_shutdown tries to make us do) as we may still be in initialization,
// so we track the update internally and handle it when the user next calls
// timer_tick_occurred, guaranteeing we're running normally.
if let Some((funding_txo, update)) = failure.0.take() {
assert_eq!(update.updates.len(), 1);
if let ChannelMonitorUpdateStep::ChannelForceClosed { should_broadcast } = update.updates[0] {
assert!(should_broadcast);
} else { unreachable!(); }
self.pending_background_events.lock().unwrap().push(BackgroundEvent::ClosingMonitorUpdate((funding_txo, update)));
}
self.finish_force_close_channel(failure);
}
}
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> {
assert!(invoice_expiry_delta_secs <= 60*60*24*365); // Sadly bitcoin timestamps are u32s, so panic before 2106
if min_value_msat.is_some() && min_value_msat.unwrap() > MAX_VALUE_MSAT {
return Err(APIError::APIMisuseError { err: format!("min_value_msat of {} greater than total 21 million bitcoin supply", min_value_msat.unwrap()) });
}
let payment_secret = PaymentSecret(self.keys_manager.get_secure_random_bytes());
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
let mut payment_secrets = self.pending_inbound_payments.lock().unwrap();
match payment_secrets.entry(payment_hash) {
hash_map::Entry::Vacant(e) => {
e.insert(PendingInboundPayment {
payment_secret, min_value_msat, payment_preimage,
user_payment_id: 0, // For compatibility with version 0.0.103 and earlier
// We assume that highest_seen_timestamp is pretty close to the current time -
// it's updated when we receive a new block with the maximum time we've seen in
// a header. It should never be more than two hours in the future.
// Thus, we add two hours here as a buffer to ensure we absolutely
// never fail a payment too early.
// Note that we assume that received blocks have reasonably up-to-date
// timestamps.
expiry_time: self.highest_seen_timestamp.load(Ordering::Acquire) as u64 + invoice_expiry_delta_secs as u64 + 7200,
});
},
hash_map::Entry::Occupied(_) => return Err(APIError::APIMisuseError { err: "Duplicate payment hash".to_owned() }),
}
Ok(payment_secret)
}
/// Gets a payment secret and payment hash for use in an invoice given to a third party wishing
/// to pay us.
///
/// This differs from [`create_inbound_payment_for_hash`] only in that it generates the
/// [`PaymentHash`] and [`PaymentPreimage`] for you.
///
/// The [`PaymentPreimage`] will ultimately be returned to you in the [`PaymentReceived`], which
/// will have the [`PaymentReceived::payment_preimage`] field filled in. That should then be
/// passed directly to [`claim_funds`].
///
/// See [`create_inbound_payment_for_hash`] for detailed documentation on behavior and requirements.
///
/// Note that a malicious eavesdropper can intuit whether an inbound payment was created by
/// `create_inbound_payment` or `create_inbound_payment_for_hash` based on runtime.
///
/// # Note
///
/// If you register an inbound payment with this method, then serialize the `ChannelManager`, then
/// deserialize it with a node running 0.0.103 and earlier, the payment will fail to be received.
///
/// Errors if `min_value_msat` is greater than total bitcoin supply.
///
/// [`claim_funds`]: Self::claim_funds
/// [`PaymentReceived`]: events::Event::PaymentReceived
/// [`PaymentReceived::payment_preimage`]: events::Event::PaymentReceived::payment_preimage
/// [`create_inbound_payment_for_hash`]: Self::create_inbound_payment_for_hash
pub fn create_inbound_payment(&self, min_value_msat: Option<u64>, invoice_expiry_delta_secs: u32) -> Result<(PaymentHash, PaymentSecret), ()> {
inbound_payment::create(&self.inbound_payment_key, min_value_msat, invoice_expiry_delta_secs, &self.keys_manager, self.highest_seen_timestamp.load(Ordering::Acquire) as u64)
}
/// Legacy version of [`create_inbound_payment`]. Use this method if you wish to share
/// serialized state with LDK node(s) running 0.0.103 and earlier.
///
/// May panic if `invoice_expiry_delta_secs` is greater than one year.
///
/// # Note
/// This method is deprecated and will be removed soon.
///
/// [`create_inbound_payment`]: Self::create_inbound_payment
#[deprecated]
pub fn create_inbound_payment_legacy(&self, min_value_msat: Option<u64>, invoice_expiry_delta_secs: u32) -> Result<(PaymentHash, PaymentSecret), APIError> {
let payment_preimage = PaymentPreimage(self.keys_manager.get_secure_random_bytes());
let payment_hash = PaymentHash(Sha256::hash(&payment_preimage.0).into_inner());
let payment_secret = self.set_payment_hash_secret_map(payment_hash, Some(payment_preimage), min_value_msat, invoice_expiry_delta_secs)?;
Ok((payment_hash, payment_secret))
}
/// Gets a [`PaymentSecret`] for a given [`PaymentHash`], for which the payment preimage is
/// stored external to LDK.
///
/// A [`PaymentReceived`] event will only be generated if the [`PaymentSecret`] matches a
/// payment secret fetched via this method or [`create_inbound_payment`], and which is at least
/// the `min_value_msat` provided here, if one is provided.
///
/// The [`PaymentHash`] (and corresponding [`PaymentPreimage`]) should be globally unique, though
/// note that LDK will not stop you from registering duplicate payment hashes for inbound
/// payments.
///
/// `min_value_msat` should be set if the invoice being generated contains a value. Any payment
/// received for the returned [`PaymentHash`] will be required to be at least `min_value_msat`
/// before a [`PaymentReceived`] event will be generated, ensuring that we do not provide the
/// sender "proof-of-payment" unless they have paid the required amount.
///
/// `invoice_expiry_delta_secs` describes the number of seconds that the invoice is valid for
/// in excess of the current time. This should roughly match the expiry time set in the invoice.
/// After this many seconds, we will remove the inbound payment, resulting in any attempts to
/// pay the invoice failing. The BOLT spec suggests 3,600 secs as a default validity time for
/// invoices when no timeout is set.
///
/// Note that we use block header time to time-out pending inbound payments (with some margin
/// to compensate for the inaccuracy of block header timestamps). Thus, in practice we will
/// accept a payment and generate a [`PaymentReceived`] event for some time after the expiry.
/// If you need exact expiry semantics, you should enforce them upon receipt of
/// [`PaymentReceived`].
///
/// Note that invoices generated for inbound payments should have their `min_final_cltv_expiry`
/// set to at least [`MIN_FINAL_CLTV_EXPIRY`].
///
/// Note that a malicious eavesdropper can intuit whether an inbound payment was created by
/// `create_inbound_payment` or `create_inbound_payment_for_hash` based on runtime.
///
/// # Note
///
/// If you register an inbound payment with this method, then serialize the `ChannelManager`, then
/// deserialize it with a node running 0.0.103 and earlier, the payment will fail to be received.
///
/// Errors if `min_value_msat` is greater than total bitcoin supply.
///
/// [`create_inbound_payment`]: Self::create_inbound_payment
/// [`PaymentReceived`]: events::Event::PaymentReceived
pub fn create_inbound_payment_for_hash(&self, payment_hash: PaymentHash, min_value_msat: Option<u64>, invoice_expiry_delta_secs: u32) -> Result<PaymentSecret, ()> {
inbound_payment::create_from_hash(&self.inbound_payment_key, min_value_msat, payment_hash, invoice_expiry_delta_secs, self.highest_seen_timestamp.load(Ordering::Acquire) as u64)
}
/// Legacy version of [`create_inbound_payment_for_hash`]. Use this method if you wish to share
/// serialized state with LDK node(s) running 0.0.103 and earlier.
///
/// May panic if `invoice_expiry_delta_secs` is greater than one year.
///
/// # Note
/// This method is deprecated and will be removed soon.
///
/// [`create_inbound_payment_for_hash`]: Self::create_inbound_payment_for_hash
#[deprecated]
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> {
self.set_payment_hash_secret_map(payment_hash, None, min_value_msat, invoice_expiry_delta_secs)
}
/// Gets an LDK-generated payment preimage from a payment hash and payment secret that were
/// previously returned from [`create_inbound_payment`].
///
/// [`create_inbound_payment`]: Self::create_inbound_payment
pub fn get_payment_preimage(&self, payment_hash: PaymentHash, payment_secret: PaymentSecret) -> Result<PaymentPreimage, APIError> {
inbound_payment::get_payment_preimage(payment_hash, payment_secret, &self.inbound_payment_key)
}
/// Gets a fake short channel id for use in receiving [phantom node payments]. These fake scids
/// are used when constructing the phantom invoice's route hints.
///
/// [phantom node payments]: crate::chain::keysinterface::PhantomKeysManager
pub fn get_phantom_scid(&self) -> u64 {
let mut channel_state = self.channel_state.lock().unwrap();
let best_block = self.best_block.read().unwrap();
loop {
let scid_candidate = fake_scid::Namespace::Phantom.get_fake_scid(best_block.height(), &self.genesis_hash, &self.fake_scid_rand_bytes, &self.keys_manager);
// Ensure the generated scid doesn't conflict with a real channel.
match channel_state.short_to_id.entry(scid_candidate) {
hash_map::Entry::Occupied(_) => continue,
hash_map::Entry::Vacant(_) => return scid_candidate
}
}
}
/// Gets route hints for use in receiving [phantom node payments].
///
/// [phantom node payments]: crate::chain::keysinterface::PhantomKeysManager
pub fn get_phantom_route_hints(&self) -> PhantomRouteHints {
PhantomRouteHints {
channels: self.list_usable_channels(),
phantom_scid: self.get_phantom_scid(),
real_node_pubkey: self.get_our_node_id(),
}
}
#[cfg(any(test, fuzzing, feature = "_test_utils"))]
pub fn get_and_clear_pending_events(&self) -> Vec<events::Event> {
let events = core::cell::RefCell::new(Vec::new());
let event_handler = |event: &events::Event| events.borrow_mut().push(event.clone());
self.process_pending_events(&event_handler);
events.into_inner()
}
#[cfg(test)]
pub fn has_pending_payments(&self) -> bool {
!self.pending_outbound_payments.lock().unwrap().is_empty()
}
#[cfg(test)]
pub fn clear_pending_payments(&self) {
self.pending_outbound_payments.lock().unwrap().clear()
}
}
impl<Signer: Sign, M: Deref, T: Deref, K: Deref, F: Deref, L: Deref> MessageSendEventsProvider for ChannelManager<Signer, M, T, K, F, L>
where M::Target: chain::Watch<Signer>,
T::Target: BroadcasterInterface,
K::Target: KeysInterface<Signer = Signer>,
F::Target: FeeEstimator,
L::Target: Logger,
{
fn get_and_clear_pending_msg_events(&self) -> Vec<MessageSendEvent> {
let events = RefCell::new(Vec::new());
PersistenceNotifierGuard::optionally_notify(&self.total_consistency_lock, &self.persistence_notifier, || {
let mut result = NotifyOption::SkipPersist;
// TODO: This behavior should be documented. It's unintuitive that we query
// ChannelMonitors when clearing other events.
if self.process_pending_monitor_events() {
result = NotifyOption::DoPersist;
}
if self.check_free_holding_cells() {
result = NotifyOption::DoPersist;
}
if self.maybe_generate_initial_closing_signed() {
result = NotifyOption::DoPersist;
}
let mut pending_events = Vec::new();
let mut channel_state = self.channel_state.lock().unwrap();
mem::swap(&mut pending_events, &mut channel_state.pending_msg_events);
if !pending_events.is_empty() {
events.replace(pending_events);
}
result
});
events.into_inner()
}
}
impl<Signer: Sign, M: Deref, T: Deref, K: Deref, F: Deref, L: Deref> EventsProvider for ChannelManager<Signer, M, T, K, F, L>
where
M::Target: chain::Watch<Signer>,
T::Target: BroadcasterInterface,
K::Target: KeysInterface<Signer = Signer>,
F::Target: FeeEstimator,
L::Target: Logger,
{
/// Processes events that must be periodically handled.
///
/// An [`EventHandler`] may safely call back to the provider in order to handle an event.
/// However, it must not call [`Writeable::write`] as doing so would result in a deadlock.
///
/// Pending events are persisted as part of [`ChannelManager`]. While these events are cleared
/// when processed, an [`EventHandler`] must be able to handle previously seen events when
/// restarting from an old state.
fn process_pending_events<H: Deref>(&self, handler: H) where H::Target: EventHandler {
PersistenceNotifierGuard::optionally_notify(&self.total_consistency_lock, &self.persistence_notifier, || {
let mut result = NotifyOption::SkipPersist;
// TODO: This behavior should be documented. It's unintuitive that we query
// ChannelMonitors when clearing other events.
if self.process_pending_monitor_events() {
result = NotifyOption::DoPersist;
}
let mut pending_events = mem::replace(&mut *self.pending_events.lock().unwrap(), vec![]);
if !pending_events.is_empty() {
result = NotifyOption::DoPersist;
}
for event in pending_events.drain(..) {
handler.handle_event(&event);
}
result
});
}
}
impl<Signer: Sign, M: Deref, T: Deref, K: Deref, F: Deref, L: Deref> chain::Listen for ChannelManager<Signer, M, T, K, F, L>
where
M::Target: chain::Watch<Signer>,
T::Target: BroadcasterInterface,
K::Target: KeysInterface<Signer = Signer>,
F::Target: FeeEstimator,
L::Target: Logger,
{
fn filtered_block_connected(&self, header: &BlockHeader, txdata: &TransactionData, height: u32) {
{
let best_block = self.best_block.read().unwrap();
assert_eq!(best_block.block_hash(), header.prev_blockhash,
"Blocks must be connected in chain-order - the connected header must build on the last connected header");
assert_eq!(best_block.height(), height - 1,
"Blocks must be connected in chain-order - the connected block height must be one greater than the previous height");
}
self.transactions_confirmed(header, txdata, height);
self.best_block_updated(header, height);
}
fn block_disconnected(&self, header: &BlockHeader, height: u32) {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
let new_height = height - 1;
{
let mut best_block = self.best_block.write().unwrap();
assert_eq!(best_block.block_hash(), header.block_hash(),
"Blocks must be disconnected in chain-order - the disconnected header must be the last connected header");
assert_eq!(best_block.height(), height,
"Blocks must be disconnected in chain-order - the disconnected block must have the correct height");
*best_block = BestBlock::new(header.prev_blockhash, new_height)
}
self.do_chain_event(Some(new_height), |channel| channel.best_block_updated(new_height, header.time, self.genesis_hash.clone(), self.get_our_node_id(), &self.logger));
}
}
impl<Signer: Sign, M: Deref, T: Deref, K: Deref, F: Deref, L: Deref> chain::Confirm for ChannelManager<Signer, M, T, K, F, L>
where
M::Target: chain::Watch<Signer>,
T::Target: BroadcasterInterface,
K::Target: KeysInterface<Signer = Signer>,
F::Target: FeeEstimator,
L::Target: Logger,
{
fn transactions_confirmed(&self, header: &BlockHeader, txdata: &TransactionData, height: u32) {
// Note that we MUST NOT end up calling methods on self.chain_monitor here - we're called
// during initialization prior to the chain_monitor being fully configured in some cases.
// See the docs for `ChannelManagerReadArgs` for more.
let block_hash = header.block_hash();
log_trace!(self.logger, "{} transactions included in block {} at height {} provided", txdata.len(), block_hash, height);
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
self.do_chain_event(Some(height), |channel| channel.transactions_confirmed(&block_hash, height, txdata, self.genesis_hash.clone(), self.get_our_node_id(), &self.logger)
.map(|(a, b)| (a, Vec::new(), b)));
let last_best_block_height = self.best_block.read().unwrap().height();
if height < last_best_block_height {
let timestamp = self.highest_seen_timestamp.load(Ordering::Acquire);
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.get_our_node_id(), &self.logger));
}
}
fn best_block_updated(&self, header: &BlockHeader, height: u32) {
// Note that we MUST NOT end up calling methods on self.chain_monitor here - we're called
// during initialization prior to the chain_monitor being fully configured in some cases.
// See the docs for `ChannelManagerReadArgs` for more.
let block_hash = header.block_hash();
log_trace!(self.logger, "New best block: {} at height {}", block_hash, height);
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
*self.best_block.write().unwrap() = BestBlock::new(block_hash, height);
self.do_chain_event(Some(height), |channel| channel.best_block_updated(height, header.time, self.genesis_hash.clone(), self.get_our_node_id(), &self.logger));
macro_rules! max_time {
($timestamp: expr) => {
loop {
// Update $timestamp to be the max of its current value and the block
// timestamp. This should keep us close to the current time without relying on
// having an explicit local time source.
// Just in case we end up in a race, we loop until we either successfully
// update $timestamp or decide we don't need to.
let old_serial = $timestamp.load(Ordering::Acquire);
if old_serial >= header.time as usize { break; }
if $timestamp.compare_exchange(old_serial, header.time as usize, Ordering::AcqRel, Ordering::Relaxed).is_ok() {
break;
}
}
}
}
max_time!(self.last_node_announcement_serial);
max_time!(self.highest_seen_timestamp);
let mut payment_secrets = self.pending_inbound_payments.lock().unwrap();
payment_secrets.retain(|_, inbound_payment| {
inbound_payment.expiry_time > header.time as u64
});
let mut outbounds = self.pending_outbound_payments.lock().unwrap();
let mut pending_events = self.pending_events.lock().unwrap();
outbounds.retain(|payment_id, payment| {
if payment.remaining_parts() != 0 { return true }
if let PendingOutboundPayment::Retryable { starting_block_height, payment_hash, .. } = payment {
if *starting_block_height + PAYMENT_EXPIRY_BLOCKS <= height {
log_info!(self.logger, "Timing out payment with id {} and hash {}", log_bytes!(payment_id.0), log_bytes!(payment_hash.0));
pending_events.push(events::Event::PaymentFailed {
payment_id: *payment_id, payment_hash: *payment_hash,
});
false
} else { true }
} else { true }
});
}
fn get_relevant_txids(&self) -> Vec<Txid> {
let channel_state = self.channel_state.lock().unwrap();
let mut res = Vec::with_capacity(channel_state.short_to_id.len());
for chan in channel_state.by_id.values() {
if let Some(funding_txo) = chan.get_funding_txo() {
res.push(funding_txo.txid);
}
}
res
}
fn transaction_unconfirmed(&self, txid: &Txid) {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
self.do_chain_event(None, |channel| {
if let Some(funding_txo) = channel.get_funding_txo() {
if funding_txo.txid == *txid {
channel.funding_transaction_unconfirmed(&self.logger).map(|()| (None, Vec::new(), None))
} else { Ok((None, Vec::new(), None)) }
} else { Ok((None, Vec::new(), None)) }
});
}
}
impl<Signer: Sign, M: Deref, T: Deref, K: Deref, F: Deref, L: Deref> ChannelManager<Signer, M, T, K, F, L>
where
M::Target: chain::Watch<Signer>,
T::Target: BroadcasterInterface,
K::Target: KeysInterface<Signer = Signer>,
F::Target: FeeEstimator,
L::Target: Logger,
{
/// Calls a function which handles an on-chain event (blocks dis/connected, transactions
/// un/confirmed, etc) on each channel, handling any resulting errors or messages generated by
/// the function.
fn do_chain_event<FN: Fn(&mut Channel<Signer>) -> Result<(Option<msgs::ChannelReady>, Vec<(HTLCSource, PaymentHash)>, Option<msgs::AnnouncementSignatures>), ClosureReason>>
(&self, height_opt: Option<u32>, f: FN) {
// Note that we MUST NOT end up calling methods on self.chain_monitor here - we're called
// during initialization prior to the chain_monitor being fully configured in some cases.
// See the docs for `ChannelManagerReadArgs` for more.
let mut failed_channels = Vec::new();
let mut timed_out_htlcs = Vec::new();
{
let mut channel_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_lock;
let short_to_id = &mut channel_state.short_to_id;
let pending_msg_events = &mut channel_state.pending_msg_events;
channel_state.by_id.retain(|_, channel| {
let res = f(channel);
if let Ok((channel_ready_opt, mut timed_out_pending_htlcs, announcement_sigs)) = res {
for (source, payment_hash) in timed_out_pending_htlcs.drain(..) {
let (failure_code, data) = self.get_htlc_inbound_temp_fail_err_and_data(0x1000|14 /* expiry_too_soon */, &channel);
timed_out_htlcs.push((source, payment_hash, HTLCFailReason::Reason {
failure_code, data,
}));
}
if let Some(channel_ready) = channel_ready_opt {
send_channel_ready!(short_to_id, pending_msg_events, channel, channel_ready);
if channel.is_usable() {
log_trace!(self.logger, "Sending channel_ready with private initial channel_update for our counterparty on channel {}", log_bytes!(channel.channel_id()));
if let Ok(msg) = self.get_channel_update_for_unicast(channel) {
pending_msg_events.push(events::MessageSendEvent::SendChannelUpdate {
node_id: channel.get_counterparty_node_id(),
msg,
});
}
} else {
log_trace!(self.logger, "Sending channel_ready WITHOUT channel_update for {}", log_bytes!(channel.channel_id()));
}
}
if let Some(announcement_sigs) = announcement_sigs {
log_trace!(self.logger, "Sending announcement_signatures for channel {}", log_bytes!(channel.channel_id()));
pending_msg_events.push(events::MessageSendEvent::SendAnnouncementSignatures {
node_id: channel.get_counterparty_node_id(),
msg: announcement_sigs,
});
if let Some(height) = height_opt {
if let Some(announcement) = channel.get_signed_channel_announcement(self.get_our_node_id(), self.genesis_hash, height) {
pending_msg_events.push(events::MessageSendEvent::BroadcastChannelAnnouncement {
msg: announcement,
// Note that announcement_signatures fails if the channel cannot be announced,
// so get_channel_update_for_broadcast will never fail by the time we get here.
update_msg: self.get_channel_update_for_broadcast(channel).unwrap(),
});
}
}
}
if channel.is_our_channel_ready() {
if let Some(real_scid) = channel.get_short_channel_id() {
// If we sent a 0conf channel_ready, and now have an SCID, we add it
// to the short_to_id map here. Note that we check whether we can relay
// using the real SCID at relay-time (i.e. enforce option_scid_alias
// then), and if the funding tx is ever un-confirmed we force-close the
// channel, ensuring short_to_id is always consistent.
let scid_insert = short_to_id.insert(real_scid, channel.channel_id());
assert!(scid_insert.is_none() || scid_insert.unwrap() == channel.channel_id(),
"SCIDs should never collide - ensure you weren't behind by a full {} blocks when creating channels",
fake_scid::MAX_SCID_BLOCKS_FROM_NOW);
}
}
} else if let Err(reason) = res {
update_maps_on_chan_removal!(self, short_to_id, channel);
// It looks like our counterparty went on-chain or funding transaction was
// reorged out of the main chain. Close the channel.
failed_channels.push(channel.force_shutdown(true));
if let Ok(update) = self.get_channel_update_for_broadcast(&channel) {
pending_msg_events.push(events::MessageSendEvent::BroadcastChannelUpdate {
msg: update
});
}
let reason_message = format!("{}", reason);
self.issue_channel_close_events(channel, reason);
pending_msg_events.push(events::MessageSendEvent::HandleError {
node_id: channel.get_counterparty_node_id(),
action: msgs::ErrorAction::SendErrorMessage { msg: msgs::ErrorMessage {
channel_id: channel.channel_id(),
data: reason_message,
} },
});
return false;
}
true
});
if let Some(height) = height_opt {
channel_state.claimable_htlcs.retain(|payment_hash, (_, htlcs)| {
htlcs.retain(|htlc| {
// If height is approaching the number of blocks we think it takes us to get
// our commitment transaction confirmed before the HTLC expires, plus the
// number of blocks we generally consider it to take to do a commitment update,
// just give up on it and fail the HTLC.
if height >= htlc.cltv_expiry - HTLC_FAIL_BACK_BUFFER {
let mut htlc_msat_height_data = byte_utils::be64_to_array(htlc.value).to_vec();
htlc_msat_height_data.extend_from_slice(&byte_utils::be32_to_array(height));
timed_out_htlcs.push((HTLCSource::PreviousHopData(htlc.prev_hop.clone()), payment_hash.clone(), HTLCFailReason::Reason {
failure_code: 0x4000 | 15,
data: htlc_msat_height_data
}));
false
} else { true }
});
!htlcs.is_empty() // Only retain this entry if htlcs has at least one entry.
});
}
}
self.handle_init_event_channel_failures(failed_channels);
for (source, payment_hash, reason) in timed_out_htlcs.drain(..) {
self.fail_htlc_backwards_internal(self.channel_state.lock().unwrap(), source, &payment_hash, reason);
}
}
/// Blocks until ChannelManager needs to be persisted or a timeout is reached. It returns a bool
/// indicating whether persistence is necessary. Only one listener on
/// `await_persistable_update` or `await_persistable_update_timeout` is guaranteed to be woken
/// up.
///
/// Note that this method is not available with the `no-std` feature.
#[cfg(any(test, feature = "std"))]
pub fn await_persistable_update_timeout(&self, max_wait: Duration) -> bool {
self.persistence_notifier.wait_timeout(max_wait)
}
/// Blocks until ChannelManager needs to be persisted. Only one listener on
/// `await_persistable_update` or `await_persistable_update_timeout` is guaranteed to be woken
/// up.
pub fn await_persistable_update(&self) {
self.persistence_notifier.wait()
}
#[cfg(any(test, feature = "_test_utils"))]
pub fn get_persistence_condvar_value(&self) -> bool {
let mutcond = &self.persistence_notifier.persistence_lock;
let &(ref mtx, _) = mutcond;
let guard = mtx.lock().unwrap();
*guard
}
/// Gets the latest best block which was connected either via the [`chain::Listen`] or
/// [`chain::Confirm`] interfaces.
pub fn current_best_block(&self) -> BestBlock {
self.best_block.read().unwrap().clone()
}
}
impl<Signer: Sign, M: Deref , T: Deref , K: Deref , F: Deref , L: Deref >
ChannelMessageHandler for ChannelManager<Signer, M, T, K, F, L>
where M::Target: chain::Watch<Signer>,
T::Target: BroadcasterInterface,
K::Target: KeysInterface<Signer = Signer>,
F::Target: FeeEstimator,
L::Target: Logger,
{
fn handle_open_channel(&self, counterparty_node_id: &PublicKey, their_features: InitFeatures, msg: &msgs::OpenChannel) {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
let _ = handle_error!(self, self.internal_open_channel(counterparty_node_id, their_features, msg), *counterparty_node_id);
}
fn handle_accept_channel(&self, counterparty_node_id: &PublicKey, their_features: InitFeatures, msg: &msgs::AcceptChannel) {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
let _ = handle_error!(self, self.internal_accept_channel(counterparty_node_id, their_features, msg), *counterparty_node_id);
}
fn handle_funding_created(&self, counterparty_node_id: &PublicKey, msg: &msgs::FundingCreated) {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
let _ = handle_error!(self, self.internal_funding_created(counterparty_node_id, msg), *counterparty_node_id);
}
fn handle_funding_signed(&self, counterparty_node_id: &PublicKey, msg: &msgs::FundingSigned) {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
let _ = handle_error!(self, self.internal_funding_signed(counterparty_node_id, msg), *counterparty_node_id);
}
fn handle_channel_ready(&self, counterparty_node_id: &PublicKey, msg: &msgs::ChannelReady) {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
let _ = handle_error!(self, self.internal_channel_ready(counterparty_node_id, msg), *counterparty_node_id);
}
fn handle_shutdown(&self, counterparty_node_id: &PublicKey, their_features: &InitFeatures, msg: &msgs::Shutdown) {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
let _ = handle_error!(self, self.internal_shutdown(counterparty_node_id, their_features, msg), *counterparty_node_id);
}
fn handle_closing_signed(&self, counterparty_node_id: &PublicKey, msg: &msgs::ClosingSigned) {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
let _ = handle_error!(self, self.internal_closing_signed(counterparty_node_id, msg), *counterparty_node_id);
}
fn handle_update_add_htlc(&self, counterparty_node_id: &PublicKey, msg: &msgs::UpdateAddHTLC) {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
let _ = handle_error!(self, self.internal_update_add_htlc(counterparty_node_id, msg), *counterparty_node_id);
}
fn handle_update_fulfill_htlc(&self, counterparty_node_id: &PublicKey, msg: &msgs::UpdateFulfillHTLC) {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
let _ = handle_error!(self, self.internal_update_fulfill_htlc(counterparty_node_id, msg), *counterparty_node_id);
}
fn handle_update_fail_htlc(&self, counterparty_node_id: &PublicKey, msg: &msgs::UpdateFailHTLC) {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
let _ = handle_error!(self, self.internal_update_fail_htlc(counterparty_node_id, msg), *counterparty_node_id);
}
fn handle_update_fail_malformed_htlc(&self, counterparty_node_id: &PublicKey, msg: &msgs::UpdateFailMalformedHTLC) {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
let _ = handle_error!(self, self.internal_update_fail_malformed_htlc(counterparty_node_id, msg), *counterparty_node_id);
}
fn handle_commitment_signed(&self, counterparty_node_id: &PublicKey, msg: &msgs::CommitmentSigned) {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
let _ = handle_error!(self, self.internal_commitment_signed(counterparty_node_id, msg), *counterparty_node_id);
}
fn handle_revoke_and_ack(&self, counterparty_node_id: &PublicKey, msg: &msgs::RevokeAndACK) {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
let _ = handle_error!(self, self.internal_revoke_and_ack(counterparty_node_id, msg), *counterparty_node_id);
}
fn handle_update_fee(&self, counterparty_node_id: &PublicKey, msg: &msgs::UpdateFee) {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
let _ = handle_error!(self, self.internal_update_fee(counterparty_node_id, msg), *counterparty_node_id);
}
fn handle_announcement_signatures(&self, counterparty_node_id: &PublicKey, msg: &msgs::AnnouncementSignatures) {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
let _ = handle_error!(self, self.internal_announcement_signatures(counterparty_node_id, msg), *counterparty_node_id);
}
fn handle_channel_update(&self, counterparty_node_id: &PublicKey, msg: &msgs::ChannelUpdate) {
PersistenceNotifierGuard::optionally_notify(&self.total_consistency_lock, &self.persistence_notifier, || {
if let Ok(persist) = handle_error!(self, self.internal_channel_update(counterparty_node_id, msg), *counterparty_node_id) {
persist
} else {
NotifyOption::SkipPersist
}
});
}
fn handle_channel_reestablish(&self, counterparty_node_id: &PublicKey, msg: &msgs::ChannelReestablish) {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
let _ = handle_error!(self, self.internal_channel_reestablish(counterparty_node_id, msg), *counterparty_node_id);
}
fn peer_disconnected(&self, counterparty_node_id: &PublicKey, no_connection_possible: bool) {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
let mut failed_channels = Vec::new();
let mut no_channels_remain = true;
{
let mut channel_state_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_state_lock;
let pending_msg_events = &mut channel_state.pending_msg_events;
let short_to_id = &mut channel_state.short_to_id;
log_debug!(self.logger, "Marking channels with {} disconnected and generating channel_updates. We believe we {} make future connections to this peer.",
log_pubkey!(counterparty_node_id), if no_connection_possible { "cannot" } else { "can" });
channel_state.by_id.retain(|_, chan| {
if chan.get_counterparty_node_id() == *counterparty_node_id {
chan.remove_uncommitted_htlcs_and_mark_paused(&self.logger);
if chan.is_shutdown() {
update_maps_on_chan_removal!(self, short_to_id, chan);
self.issue_channel_close_events(chan, ClosureReason::DisconnectedPeer);
return false;
} else {
no_channels_remain = false;
}
}
true
});
pending_msg_events.retain(|msg| {
match msg {
&events::MessageSendEvent::SendAcceptChannel { ref node_id, .. } => node_id != counterparty_node_id,
&events::MessageSendEvent::SendOpenChannel { ref node_id, .. } => node_id != counterparty_node_id,
&events::MessageSendEvent::SendFundingCreated { ref node_id, .. } => node_id != counterparty_node_id,
&events::MessageSendEvent::SendFundingSigned { ref node_id, .. } => node_id != counterparty_node_id,
&events::MessageSendEvent::SendChannelReady { ref node_id, .. } => node_id != counterparty_node_id,
&events::MessageSendEvent::SendAnnouncementSignatures { ref node_id, .. } => node_id != counterparty_node_id,
&events::MessageSendEvent::UpdateHTLCs { ref node_id, .. } => node_id != counterparty_node_id,
&events::MessageSendEvent::SendRevokeAndACK { ref node_id, .. } => node_id != counterparty_node_id,
&events::MessageSendEvent::SendClosingSigned { ref node_id, .. } => node_id != counterparty_node_id,
&events::MessageSendEvent::SendShutdown { ref node_id, .. } => node_id != counterparty_node_id,
&events::MessageSendEvent::SendChannelReestablish { ref node_id, .. } => node_id != counterparty_node_id,
&events::MessageSendEvent::BroadcastChannelAnnouncement { .. } => true,
&events::MessageSendEvent::BroadcastNodeAnnouncement { .. } => true,
&events::MessageSendEvent::BroadcastChannelUpdate { .. } => true,
&events::MessageSendEvent::SendChannelUpdate { ref node_id, .. } => node_id != counterparty_node_id,
&events::MessageSendEvent::HandleError { ref node_id, .. } => node_id != counterparty_node_id,
&events::MessageSendEvent::SendChannelRangeQuery { .. } => false,
&events::MessageSendEvent::SendShortIdsQuery { .. } => false,
&events::MessageSendEvent::SendReplyChannelRange { .. } => false,
&events::MessageSendEvent::SendGossipTimestampFilter { .. } => false,
}
});
}
if no_channels_remain {
self.per_peer_state.write().unwrap().remove(counterparty_node_id);
}
for failure in failed_channels.drain(..) {
self.finish_force_close_channel(failure);
}
}
fn peer_connected(&self, counterparty_node_id: &PublicKey, init_msg: &msgs::Init) {
log_debug!(self.logger, "Generating channel_reestablish events for {}", log_pubkey!(counterparty_node_id));
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
{
let mut peer_state_lock = self.per_peer_state.write().unwrap();
match peer_state_lock.entry(counterparty_node_id.clone()) {
hash_map::Entry::Vacant(e) => {
e.insert(Mutex::new(PeerState {
latest_features: init_msg.features.clone(),
}));
},
hash_map::Entry::Occupied(e) => {
e.get().lock().unwrap().latest_features = init_msg.features.clone();
},
}
}
let mut channel_state_lock = self.channel_state.lock().unwrap();
let channel_state = &mut *channel_state_lock;
let pending_msg_events = &mut channel_state.pending_msg_events;
channel_state.by_id.retain(|_, chan| {
if chan.get_counterparty_node_id() == *counterparty_node_id {
if !chan.have_received_message() {
// If we created this (outbound) channel while we were disconnected from the
// peer we probably failed to send the open_channel message, which is now
// lost. We can't have had anything pending related to this channel, so we just
// drop it.
false
} else {
pending_msg_events.push(events::MessageSendEvent::SendChannelReestablish {
node_id: chan.get_counterparty_node_id(),
msg: chan.get_channel_reestablish(&self.logger),
});
true
}
} else { true }
});
//TODO: Also re-broadcast announcement_signatures
}
fn handle_error(&self, counterparty_node_id: &PublicKey, msg: &msgs::ErrorMessage) {
let _persistence_guard = PersistenceNotifierGuard::notify_on_drop(&self.total_consistency_lock, &self.persistence_notifier);
if msg.channel_id == [0; 32] {
for chan in self.list_channels() {
if chan.counterparty.node_id == *counterparty_node_id {
// Untrusted messages from peer, we throw away the error if id points to a non-existent channel
let _ = self.force_close_channel_with_peer(&chan.channel_id, counterparty_node_id, Some(&msg.data));
}
}
} else {
{
// First check if we can advance the channel type and try again.
let mut channel_state = self.channel_state.lock().unwrap();
if let Some(chan) = channel_state.by_id.get_mut(&msg.channel_id) {
if chan.get_counterparty_node_id() != *counterparty_node_id {
return;
}
if let Ok(msg) = chan.maybe_handle_error_without_close(self.genesis_hash) {
channel_state.pending_msg_events.push(events::MessageSendEvent::SendOpenChannel {
node_id: *counterparty_node_id,
msg,
});
return;
}
}
}
// Untrusted messages from peer, we throw away the error if id points to a non-existent channel
let _ = self.force_close_channel_with_peer(&msg.channel_id, counterparty_node_id, Some(&msg.data));
}
}
}
/// Used to signal to the ChannelManager persister that the manager needs to be re-persisted to
/// disk/backups, through `await_persistable_update_timeout` and `await_persistable_update`.
struct PersistenceNotifier {
/// Users won't access the persistence_lock directly, but rather wait on its bool using
/// `wait_timeout` and `wait`.
persistence_lock: (Mutex<bool>, Condvar),
}
impl PersistenceNotifier {
fn new() -> Self {
Self {
persistence_lock: (Mutex::new(false), Condvar::new()),
}
}
fn wait(&self) {
loop {
let &(ref mtx, ref cvar) = &self.persistence_lock;
let mut guard = mtx.lock().unwrap();
if *guard {
*guard = false;
return;
}
guard = cvar.wait(guard).unwrap();
let result = *guard;
if result {
*guard = false;
return
}
}
}
#[cfg(any(test, feature = "std"))]
fn wait_timeout(&self, max_wait: Duration) -> bool {
let current_time = Instant::now();
loop {
let &(ref mtx, ref cvar) = &self.persistence_lock;
let mut guard = mtx.lock().unwrap();
if *guard {
*guard = false;
return true;
}
guard = cvar.wait_timeout(guard, max_wait).unwrap().0;
// Due to spurious wakeups that can happen on `wait_timeout`, here we need to check if the
// desired wait time has actually passed, and if not then restart the loop with a reduced wait
// time. Note that this logic can be highly simplified through the use of
// `Condvar::wait_while` and `Condvar::wait_timeout_while`, if and when our MSRV is raised to
// 1.42.0.
let elapsed = current_time.elapsed();
let result = *guard;
if result || elapsed >= max_wait {
*guard = false;
return result;
}
match max_wait.checked_sub(elapsed) {
None => return result,
Some(_) => continue
}
}
}
// Signal to the ChannelManager persister that there are updates necessitating persisting to disk.
fn notify(&self) {
let &(ref persist_mtx, ref cnd) = &self.persistence_lock;
let mut persistence_lock = persist_mtx.lock().unwrap();
*persistence_lock = true;
mem::drop(persistence_lock);
cnd.notify_all();
}
}
const SERIALIZATION_VERSION: u8 = 1;
const MIN_SERIALIZATION_VERSION: u8 = 1;
impl_writeable_tlv_based!(CounterpartyForwardingInfo, {
(2, fee_base_msat, required),
(4, fee_proportional_millionths, required),
(6, cltv_expiry_delta, required),
});
impl_writeable_tlv_based!(ChannelCounterparty, {
(2, node_id, required),
(4, features, required),
(6, unspendable_punishment_reserve, required),
(8, forwarding_info, option),
(9, outbound_htlc_minimum_msat, option),
(11, outbound_htlc_maximum_msat, option),
});
impl_writeable_tlv_based!(ChannelDetails, {
(1, inbound_scid_alias, option),
(2, channel_id, required),
(3, channel_type, option),
(4, counterparty, required),
(5, outbound_scid_alias, option),
(6, funding_txo, option),
(8, short_channel_id, option),
(10, channel_value_satoshis, required),
(12, unspendable_punishment_reserve, option),
(14, user_channel_id, required),
(16, balance_msat, required),
(18, outbound_capacity_msat, required),
// Note that by the time we get past the required read above, outbound_capacity_msat will be
// filled in, so we can safely unwrap it here.
(19, next_outbound_htlc_limit_msat, (default_value, outbound_capacity_msat.0.unwrap())),
(20, inbound_capacity_msat, required),
(22, confirmations_required, option),
(24, force_close_spend_delay, option),
(26, is_outbound, required),
(28, is_channel_ready, required),
(30, is_usable, required),
(32, is_public, required),
(33, inbound_htlc_minimum_msat, option),
(35, inbound_htlc_maximum_msat, option),
});
impl_writeable_tlv_based!(PhantomRouteHints, {
(2, channels, vec_type),
(4, phantom_scid, required),
(6, real_node_pubkey, required),
});
impl_writeable_tlv_based_enum!(PendingHTLCRouting,
(0, Forward) => {
(0, onion_packet, required),
(2, short_channel_id, required),
},
(1, Receive) => {
(0, payment_data, required),
(1, phantom_shared_secret, option),
(2, incoming_cltv_expiry, required),
},
(2, ReceiveKeysend) => {
(0, payment_preimage, required),
(2, incoming_cltv_expiry, required),
},
;);
impl_writeable_tlv_based!(PendingHTLCInfo, {
(0, routing, required),
(2, incoming_shared_secret, required),
(4, payment_hash, required),
(6, amt_to_forward, required),
(8, outgoing_cltv_value, required)
});
impl Writeable for HTLCFailureMsg {
fn write<W: Writer>(&self, writer: &mut W) -> Result<(), io::Error> {
match self {
HTLCFailureMsg::Relay(msgs::UpdateFailHTLC { channel_id, htlc_id, reason }) => {
0u8.write(writer)?;
channel_id.write(writer)?;
htlc_id.write(writer)?;
reason.write(writer)?;
},
HTLCFailureMsg::Malformed(msgs::UpdateFailMalformedHTLC {
channel_id, htlc_id, sha256_of_onion, failure_code
}) => {
1u8.write(writer)?;
channel_id.write(writer)?;
htlc_id.write(writer)?;
sha256_of_onion.write(writer)?;
failure_code.write(writer)?;
},
}
Ok(())
}
}
impl Readable for HTLCFailureMsg {
fn read<R: Read>(reader: &mut R) -> Result<Self, DecodeError> {
let id: u8 = Readable::read(reader)?;
match id {
0 => {
Ok(HTLCFailureMsg::Relay(msgs::UpdateFailHTLC {
channel_id: Readable::read(reader)?,
htlc_id: Readable::read(reader)?,
reason: Readable::read(reader)?,
}))
},
1 => {
Ok(HTLCFailureMsg::Malformed(msgs::UpdateFailMalformedHTLC {
channel_id: Readable::read(reader)?,
htlc_id: Readable::read(reader)?,
sha256_of_onion: Readable::read(reader)?,
failure_code: Readable::read(reader)?,
}))
},
// In versions prior to 0.0.101, HTLCFailureMsg objects were written with type 0 or 1 but
// weren't length-prefixed and thus didn't support reading the TLV stream suffix of the network
// messages contained in the variants.
// In version 0.0.101, support for reading the variants with these types was added, and
// we should migrate to writing these variants when UpdateFailHTLC or
// UpdateFailMalformedHTLC get TLV fields.
2 => {
let length: BigSize = Readable::read(reader)?;
let mut s = FixedLengthReader::new(reader, length.0);
let res = Readable::read(&mut s)?;
s.eat_remaining()?; // Return ShortRead if there's actually not enough bytes
Ok(HTLCFailureMsg::Relay(res))
},
3 => {
let length: BigSize = Readable::read(reader)?;
let mut s = FixedLengthReader::new(reader, length.0);
let res = Readable::read(&mut s)?;
s.eat_remaining()?; // Return ShortRead if there's actually not enough bytes
Ok(HTLCFailureMsg::Malformed(res))
},
_ => Err(DecodeError::UnknownRequiredFeature),
}
}
}
impl_writeable_tlv_based_enum!(PendingHTLCStatus, ;
(0, Forward),
(1, Fail),
);
impl_writeable_tlv_based!(HTLCPreviousHopData, {
(0, short_channel_id, required),
(1, phantom_shared_secret, option),
(2, outpoint, required),
(4, htlc_id, required),
(6, incoming_packet_shared_secret, required)
});
impl Writeable for ClaimableHTLC {
fn write<W: Writer>(&self, writer: &mut W) -> Result<(), io::Error> {
let (payment_data, keysend_preimage) = match &self.onion_payload {
OnionPayload::Invoice { _legacy_hop_data } => (_legacy_hop_data.as_ref(), None),
OnionPayload::Spontaneous(preimage) => (None, Some(preimage)),
};
write_tlv_fields!(writer, {
(0, self.prev_hop, required),
(1, self.total_msat, required),
(2, self.value, required),
(4, payment_data, option),
(6, self.cltv_expiry, required),
(8, keysend_preimage, option),
});
Ok(())
}
}
impl Readable for ClaimableHTLC {
fn read<R: Read>(reader: &mut R) -> Result<Self, DecodeError> {
let mut prev_hop = ::util::ser::OptionDeserWrapper(None);
let mut value = 0;
let mut payment_data: Option<msgs::FinalOnionHopData> = None;
let mut cltv_expiry = 0;
let mut total_msat = None;
let mut keysend_preimage: Option<PaymentPreimage> = None;
read_tlv_fields!(reader, {
(0, prev_hop, required),
(1, total_msat, option),
(2, value, required),
(4, payment_data, option),
(6, cltv_expiry, required),
(8, keysend_preimage, option)
});
let onion_payload = match keysend_preimage {
Some(p) => {
if payment_data.is_some() {
return Err(DecodeError::InvalidValue)
}
if total_msat.is_none() {
total_msat = Some(value);
}
OnionPayload::Spontaneous(p)
},
None => {
if total_msat.is_none() {
if payment_data.is_none() {
return Err(DecodeError::InvalidValue)
}
total_msat = Some(payment_data.as_ref().unwrap().total_msat);
}
OnionPayload::Invoice { _legacy_hop_data: payment_data }
},
};
Ok(Self {
prev_hop: prev_hop.0.unwrap(),
timer_ticks: 0,
value,
total_msat: total_msat.unwrap(),
onion_payload,
cltv_expiry,
})
}
}
impl Readable for HTLCSource {
fn read<R: Read>(reader: &mut R) -> Result<Self, DecodeError> {
let id: u8 = Readable::read(reader)?;
match id {
0 => {
let mut session_priv: ::util::ser::OptionDeserWrapper<SecretKey> = ::util::ser::OptionDeserWrapper(None);
let mut first_hop_htlc_msat: u64 = 0;
let mut path = Some(Vec::new());
let mut payment_id = None;
let mut payment_secret = None;
let mut payment_params = None;
read_tlv_fields!(reader, {
(0, session_priv, required),
(1, payment_id, option),
(2, first_hop_htlc_msat, required),
(3, payment_secret, option),
(4, path, vec_type),
(5, payment_params, option),
});
if payment_id.is_none() {
// For backwards compat, if there was no payment_id written, use the session_priv bytes
// instead.
payment_id = Some(PaymentId(*session_priv.0.unwrap().as_ref()));
}
Ok(HTLCSource::OutboundRoute {
session_priv: session_priv.0.unwrap(),
first_hop_htlc_msat: first_hop_htlc_msat,
path: path.unwrap(),
payment_id: payment_id.unwrap(),
payment_secret,
payment_params,
})
}
1 => Ok(HTLCSource::PreviousHopData(Readable::read(reader)?)),
_ => Err(DecodeError::UnknownRequiredFeature),
}
}
}
impl Writeable for HTLCSource {
fn write<W: Writer>(&self, writer: &mut W) -> Result<(), ::io::Error> {
match self {
HTLCSource::OutboundRoute { ref session_priv, ref first_hop_htlc_msat, ref path, payment_id, payment_secret, payment_params } => {
0u8.write(writer)?;
let payment_id_opt = Some(payment_id);
write_tlv_fields!(writer, {
(0, session_priv, required),
(1, payment_id_opt, option),
(2, first_hop_htlc_msat, required),
(3, payment_secret, option),
(4, path, vec_type),
(5, payment_params, option),
});
}
HTLCSource::PreviousHopData(ref field) => {
1u8.write(writer)?;
field.write(writer)?;
}
}
Ok(())
}
}
impl_writeable_tlv_based_enum!(HTLCFailReason,
(0, LightningError) => {
(0, err, required),
},
(1, Reason) => {
(0, failure_code, required),
(2, data, vec_type),
},
;);
impl_writeable_tlv_based_enum!(HTLCForwardInfo,
(0, AddHTLC) => {
(0, forward_info, required),
(2, prev_short_channel_id, required),
(4, prev_htlc_id, required),
(6, prev_funding_outpoint, required),
},
(1, FailHTLC) => {
(0, htlc_id, required),
(2, err_packet, required),
},
;);
impl_writeable_tlv_based!(PendingInboundPayment, {
(0, payment_secret, required),
(2, expiry_time, required),
(4, user_payment_id, required),
(6, payment_preimage, required),
(8, min_value_msat, required),
});
impl_writeable_tlv_based_enum_upgradable!(PendingOutboundPayment,
(0, Legacy) => {
(0, session_privs, required),
},
(1, Fulfilled) => {
(0, session_privs, required),
(1, payment_hash, option),
},
(2, Retryable) => {
(0, session_privs, required),
(1, pending_fee_msat, option),
(2, payment_hash, required),
(4, payment_secret, option),
(6, total_msat, required),
(8, pending_amt_msat, required),
(10, starting_block_height, required),
},
(3, Abandoned) => {
(0, session_privs, required),
(2, payment_hash, required),
},
);
impl<Signer: Sign, M: Deref, T: Deref, K: Deref, F: Deref, L: Deref> Writeable for ChannelManager<Signer, M, T, K, F, L>
where M::Target: chain::Watch<Signer>,
T::Target: BroadcasterInterface,
K::Target: KeysInterface<Signer = Signer>,
F::Target: FeeEstimator,
L::Target: Logger,
{
fn write<W: Writer>(&self, writer: &mut W) -> Result<(), io::Error> {
let _consistency_lock = self.total_consistency_lock.write().unwrap();
write_ver_prefix!(writer, SERIALIZATION_VERSION, MIN_SERIALIZATION_VERSION);
self.genesis_hash.write(writer)?;
{
let best_block = self.best_block.read().unwrap();
best_block.height().write(writer)?;
best_block.block_hash().write(writer)?;
}
let channel_state = self.channel_state.lock().unwrap();
let mut unfunded_channels = 0;
for (_, channel) in channel_state.by_id.iter() {
if !channel.is_funding_initiated() {
unfunded_channels += 1;
}
}
((channel_state.by_id.len() - unfunded_channels) as u64).write(writer)?;
for (_, channel) in channel_state.by_id.iter() {
if channel.is_funding_initiated() {
channel.write(writer)?;
}
}
(channel_state.forward_htlcs.len() as u64).write(writer)?;
for (short_channel_id, pending_forwards) in channel_state.forward_htlcs.iter() {
short_channel_id.write(writer)?;
(pending_forwards.len() as u64).write(writer)?;
for forward in pending_forwards {
forward.write(writer)?;
}
}
let mut htlc_purposes: Vec<&events::PaymentPurpose> = Vec::new();
(channel_state.claimable_htlcs.len() as u64).write(writer)?;
for (payment_hash, (purpose, previous_hops)) in channel_state.claimable_htlcs.iter() {
payment_hash.write(writer)?;
(previous_hops.len() as u64).write(writer)?;
for htlc in previous_hops.iter() {
htlc.write(writer)?;
}
htlc_purposes.push(purpose);
}
let per_peer_state = self.per_peer_state.write().unwrap();
(per_peer_state.len() as u64).write(writer)?;
for (peer_pubkey, peer_state_mutex) in per_peer_state.iter() {
peer_pubkey.write(writer)?;
let peer_state = peer_state_mutex.lock().unwrap();
peer_state.latest_features.write(writer)?;
}
let pending_inbound_payments = self.pending_inbound_payments.lock().unwrap();
let pending_outbound_payments = self.pending_outbound_payments.lock().unwrap();
let events = self.pending_events.lock().unwrap();
(events.len() as u64).write(writer)?;
for event in events.iter() {
event.write(writer)?;
}
let background_events = self.pending_background_events.lock().unwrap();
(background_events.len() as u64).write(writer)?;
for event in background_events.iter() {
match event {
BackgroundEvent::ClosingMonitorUpdate((funding_txo, monitor_update)) => {
0u8.write(writer)?;
funding_txo.write(writer)?;
monitor_update.write(writer)?;
},
}
}
(self.last_node_announcement_serial.load(Ordering::Acquire) as u32).write(writer)?;
(self.highest_seen_timestamp.load(Ordering::Acquire) as u32).write(writer)?;
(pending_inbound_payments.len() as u64).write(writer)?;
for (hash, pending_payment) in pending_inbound_payments.iter() {
hash.write(writer)?;
pending_payment.write(writer)?;
}
// For backwards compat, write the session privs and their total length.
let mut num_pending_outbounds_compat: u64 = 0;
for (_, outbound) in pending_outbound_payments.iter() {
if !outbound.is_fulfilled() && !outbound.abandoned() {
num_pending_outbounds_compat += outbound.remaining_parts() as u64;
}
}
num_pending_outbounds_compat.write(writer)?;
for (_, outbound) in pending_outbound_payments.iter() {
match outbound {
PendingOutboundPayment::Legacy { session_privs } |
PendingOutboundPayment::Retryable { session_privs, .. } => {
for session_priv in session_privs.iter() {
session_priv.write(writer)?;
}
}
PendingOutboundPayment::Fulfilled { .. } => {},
PendingOutboundPayment::Abandoned { .. } => {},
}
}
// Encode without retry info for 0.0.101 compatibility.
let mut pending_outbound_payments_no_retry: HashMap<PaymentId, HashSet<[u8; 32]>> = HashMap::new();
for (id, outbound) in pending_outbound_payments.iter() {
match outbound {
PendingOutboundPayment::Legacy { session_privs } |
PendingOutboundPayment::Retryable { session_privs, .. } => {
pending_outbound_payments_no_retry.insert(*id, session_privs.clone());
},
_ => {},
}
}
write_tlv_fields!(writer, {
(1, pending_outbound_payments_no_retry, required),
(3, pending_outbound_payments, required),
(5, self.our_network_pubkey, required),
(7, self.fake_scid_rand_bytes, required),
(9, htlc_purposes, vec_type),
});
Ok(())
}
}
/// Arguments for the creation of a ChannelManager that are not deserialized.
///
/// At a high-level, the process for deserializing a ChannelManager and resuming normal operation
/// is:
/// 1) Deserialize all stored [`ChannelMonitor`]s.
/// 2) Deserialize the [`ChannelManager`] by filling in this struct and calling:
/// `<(BlockHash, ChannelManager)>::read(reader, args)`
/// This may result in closing some channels if the [`ChannelMonitor`] is newer than the stored
/// [`ChannelManager`] state to ensure no loss of funds. Thus, transactions may be broadcasted.
/// 3) If you are not fetching full blocks, register all relevant [`ChannelMonitor`] outpoints the
/// same way you would handle a [`chain::Filter`] call using
/// [`ChannelMonitor::get_outputs_to_watch`] and [`ChannelMonitor::get_funding_txo`].
/// 4) Reconnect blocks on your [`ChannelMonitor`]s.
/// 5) Disconnect/connect blocks on the [`ChannelManager`].
/// 6) Re-persist the [`ChannelMonitor`]s to ensure the latest state is on disk.
/// Note that if you're using a [`ChainMonitor`] for your [`chain::Watch`] implementation, you
/// will likely accomplish this as a side-effect of calling [`chain::Watch::watch_channel`] in
/// the next step.
/// 7) Move the [`ChannelMonitor`]s into your local [`chain::Watch`]. If you're using a
/// [`ChainMonitor`], this is done by calling [`chain::Watch::watch_channel`].
///
/// Note that the ordering of #4-7 is not of importance, however all four must occur before you
/// call any other methods on the newly-deserialized [`ChannelManager`].
///
/// Note that because some channels may be closed during deserialization, it is critical that you
/// always deserialize only the latest version of a ChannelManager and ChannelMonitors available to
/// you. If you deserialize an old ChannelManager (during which force-closure transactions may be
/// broadcast), and then later deserialize a newer version of the same ChannelManager (which will
/// not force-close the same channels but consider them live), you may end up revoking a state for
/// which you've already broadcasted the transaction.
///
/// [`ChainMonitor`]: crate::chain::chainmonitor::ChainMonitor
pub struct ChannelManagerReadArgs<'a, Signer: 'a + Sign, M: Deref, T: Deref, K: Deref, F: Deref, L: Deref>
where M::Target: chain::Watch<Signer>,
T::Target: BroadcasterInterface,
K::Target: KeysInterface<Signer = Signer>,
F::Target: FeeEstimator,
L::Target: Logger,
{
/// The keys provider which will give us relevant keys. Some keys will be loaded during
/// deserialization and KeysInterface::read_chan_signer will be used to read per-Channel
/// signing data.
pub keys_manager: K,
/// The fee_estimator for use in the ChannelManager in the future.
///
/// No calls to the FeeEstimator will be made during deserialization.
pub fee_estimator: F,
/// The chain::Watch for use in the ChannelManager in the future.
///
/// No calls to the chain::Watch will be made during deserialization. It is assumed that
/// you have deserialized ChannelMonitors separately and will add them to your
/// chain::Watch after deserializing this ChannelManager.
pub chain_monitor: M,
/// The BroadcasterInterface which will be used in the ChannelManager in the future and may be
/// used to broadcast the latest local commitment transactions of channels which must be
/// force-closed during deserialization.
pub tx_broadcaster: T,
/// The Logger for use in the ChannelManager and which may be used to log information during
/// deserialization.
pub logger: L,
/// Default settings used for new channels. Any existing channels will continue to use the
/// runtime settings which were stored when the ChannelManager was serialized.
pub default_config: UserConfig,
/// A map from channel funding outpoints to ChannelMonitors for those channels (ie
/// value.get_funding_txo() should be the key).
///
/// If a monitor is inconsistent with the channel state during deserialization the channel will
/// be force-closed using the data in the ChannelMonitor and the channel will be dropped. This
/// is true for missing channels as well. If there is a monitor missing for which we find
/// channel data Err(DecodeError::InvalidValue) will be returned.
///
/// In such cases the latest local transactions will be sent to the tx_broadcaster included in
/// this struct.
///
/// (C-not exported) because we have no HashMap bindings
pub channel_monitors: HashMap<OutPoint, &'a mut ChannelMonitor<Signer>>,
}
impl<'a, Signer: 'a + Sign, M: Deref, T: Deref, K: Deref, F: Deref, L: Deref>
ChannelManagerReadArgs<'a, Signer, M, T, K, F, L>
where M::Target: chain::Watch<Signer>,
T::Target: BroadcasterInterface,
K::Target: KeysInterface<Signer = Signer>,
F::Target: FeeEstimator,
L::Target: Logger,
{
/// Simple utility function to create a ChannelManagerReadArgs which creates the monitor
/// HashMap for you. This is primarily useful for C bindings where it is not practical to
/// populate a HashMap directly from C.
pub fn new(keys_manager: K, fee_estimator: F, chain_monitor: M, tx_broadcaster: T, logger: L, default_config: UserConfig,
mut channel_monitors: Vec<&'a mut ChannelMonitor<Signer>>) -> Self {
Self {
keys_manager, fee_estimator, chain_monitor, tx_broadcaster, logger, default_config,
channel_monitors: channel_monitors.drain(..).map(|monitor| { (monitor.get_funding_txo().0, monitor) }).collect()
}
}
}
// Implement ReadableArgs for an Arc'd ChannelManager to make it a bit easier to work with the
// SipmleArcChannelManager type:
impl<'a, Signer: Sign, M: Deref, T: Deref, K: Deref, F: Deref, L: Deref>
ReadableArgs<ChannelManagerReadArgs<'a, Signer, M, T, K, F, L>> for (BlockHash, Arc<ChannelManager<Signer, M, T, K, F, L>>)
where M::Target: chain::Watch<Signer>,
T::Target: BroadcasterInterface,
K::Target: KeysInterface<Signer = Signer>,
F::Target: FeeEstimator,
L::Target: Logger,
{
fn read<R: io::Read>(reader: &mut R, args: ChannelManagerReadArgs<'a, Signer, M, T, K, F, L>) -> Result<Self, DecodeError> {
let (blockhash, chan_manager) = <(BlockHash, ChannelManager<Signer, M, T, K, F, L>)>::read(reader, args)?;
Ok((blockhash, Arc::new(chan_manager)))
}
}
impl<'a, Signer: Sign, M: Deref, T: Deref, K: Deref, F: Deref, L: Deref>
ReadableArgs<ChannelManagerReadArgs<'a, Signer, M, T, K, F, L>> for (BlockHash, ChannelManager<Signer, M, T, K, F, L>)
where M::Target: chain::Watch<Signer>,
T::Target: BroadcasterInterface,
K::Target: KeysInterface<Signer = Signer>,
F::Target: FeeEstimator,
L::Target: Logger,
{
fn read<R: io::Read>(reader: &mut R, mut args: ChannelManagerReadArgs<'a, Signer, M, T, K, F, L>) -> Result<Self, DecodeError> {
let _ver = read_ver_prefix!(reader, SERIALIZATION_VERSION);
let genesis_hash: BlockHash = Readable::read(reader)?;
let best_block_height: u32 = Readable::read(reader)?;
let best_block_hash: BlockHash = Readable::read(reader)?;
let mut failed_htlcs = Vec::new();
let channel_count: u64 = Readable::read(reader)?;
let mut funding_txo_set = HashSet::with_capacity(cmp::min(channel_count as usize, 128));
let mut by_id = HashMap::with_capacity(cmp::min(channel_count as usize, 128));
let mut short_to_id = HashMap::with_capacity(cmp::min(channel_count as usize, 128));
let mut channel_closures = Vec::new();
for _ in 0..channel_count {
let mut channel: Channel<Signer> = Channel::read(reader, (&args.keys_manager, best_block_height))?;
let funding_txo = channel.get_funding_txo().ok_or(DecodeError::InvalidValue)?;
funding_txo_set.insert(funding_txo.clone());
if let Some(ref mut monitor) = args.channel_monitors.get_mut(&funding_txo) {
if channel.get_cur_holder_commitment_transaction_number() < monitor.get_cur_holder_commitment_number() ||
channel.get_revoked_counterparty_commitment_transaction_number() < monitor.get_min_seen_secret() ||
channel.get_cur_counterparty_commitment_transaction_number() < monitor.get_cur_counterparty_commitment_number() ||
channel.get_latest_monitor_update_id() > monitor.get_latest_update_id() {
// If the channel is ahead of the monitor, return InvalidValue:
log_error!(args.logger, "A ChannelMonitor is stale compared to the current ChannelManager! This indicates a potentially-critical violation of the chain::Watch API!");
log_error!(args.logger, " The ChannelMonitor for channel {} is at update_id {} but the ChannelManager is at update_id {}.",
log_bytes!(channel.channel_id()), monitor.get_latest_update_id(), channel.get_latest_monitor_update_id());
log_error!(args.logger, " The chain::Watch API *requires* that monitors are persisted durably before returning,");
log_error!(args.logger, " client applications must ensure that ChannelMonitor data is always available and the latest to avoid funds loss!");
log_error!(args.logger, " Without the latest ChannelMonitor we cannot continue without risking funds.");
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");
return Err(DecodeError::InvalidValue);
} else if channel.get_cur_holder_commitment_transaction_number() > monitor.get_cur_holder_commitment_number() ||
channel.get_revoked_counterparty_commitment_transaction_number() > monitor.get_min_seen_secret() ||
channel.get_cur_counterparty_commitment_transaction_number() > monitor.get_cur_counterparty_commitment_number() ||
channel.get_latest_monitor_update_id() < monitor.get_latest_update_id() {
// But if the channel is behind of the monitor, close the channel:
log_error!(args.logger, "A ChannelManager is stale compared to the current ChannelMonitor!");
log_error!(args.logger, " The channel will be force-closed and the latest commitment transaction from the ChannelMonitor broadcast.");
log_error!(args.logger, " The ChannelMonitor for channel {} is at update_id {} but the ChannelManager is at update_id {}.",
log_bytes!(channel.channel_id()), monitor.get_latest_update_id(), channel.get_latest_monitor_update_id());
let (_, mut new_failed_htlcs) = channel.force_shutdown(true);
failed_htlcs.append(&mut new_failed_htlcs);
monitor.broadcast_latest_holder_commitment_txn(&args.tx_broadcaster, &args.logger);
channel_closures.push(events::Event::ChannelClosed {
channel_id: channel.channel_id(),
user_channel_id: channel.get_user_id(),
reason: ClosureReason::OutdatedChannelManager
});
} else {
log_info!(args.logger, "Successfully loaded channel {}", log_bytes!(channel.channel_id()));
if let Some(short_channel_id) = channel.get_short_channel_id() {
short_to_id.insert(short_channel_id, channel.channel_id());
}
by_id.insert(channel.channel_id(), channel);
}
} else {
log_error!(args.logger, "Missing ChannelMonitor for channel {} needed by ChannelManager.", log_bytes!(channel.channel_id()));
log_error!(args.logger, " The chain::Watch API *requires* that monitors are persisted durably before returning,");
log_error!(args.logger, " client applications must ensure that ChannelMonitor data is always available and the latest to avoid funds loss!");
log_error!(args.logger, " Without the ChannelMonitor we cannot continue without risking funds.");
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");
return Err(DecodeError::InvalidValue);
}
}
for (ref funding_txo, ref mut monitor) in args.channel_monitors.iter_mut() {
if !funding_txo_set.contains(funding_txo) {
log_info!(args.logger, "Broadcasting latest holder commitment transaction for closed channel {}", log_bytes!(funding_txo.to_channel_id()));
monitor.broadcast_latest_holder_commitment_txn(&args.tx_broadcaster, &args.logger);
}
}
const MAX_ALLOC_SIZE: usize = 1024 * 64;
let forward_htlcs_count: u64 = Readable::read(reader)?;
let mut forward_htlcs = HashMap::with_capacity(cmp::min(forward_htlcs_count as usize, 128));
for _ in 0..forward_htlcs_count {
let short_channel_id = Readable::read(reader)?;
let pending_forwards_count: u64 = Readable::read(reader)?;
let mut pending_forwards = Vec::with_capacity(cmp::min(pending_forwards_count as usize, MAX_ALLOC_SIZE/mem::size_of::<HTLCForwardInfo>()));
for _ in 0..pending_forwards_count {
pending_forwards.push(Readable::read(reader)?);
}
forward_htlcs.insert(short_channel_id, pending_forwards);
}
let claimable_htlcs_count: u64 = Readable::read(reader)?;
let mut claimable_htlcs_list = Vec::with_capacity(cmp::min(claimable_htlcs_count as usize, 128));
for _ in 0..claimable_htlcs_count {
let payment_hash = Readable::read(reader)?;
let previous_hops_len: u64 = Readable::read(reader)?;
let mut previous_hops = Vec::with_capacity(cmp::min(previous_hops_len as usize, MAX_ALLOC_SIZE/mem::size_of::<ClaimableHTLC>()));
for _ in 0..previous_hops_len {
previous_hops.push(<ClaimableHTLC as Readable>::read(reader)?);
}
claimable_htlcs_list.push((payment_hash, previous_hops));
}
let peer_count: u64 = Readable::read(reader)?;
let mut per_peer_state = HashMap::with_capacity(cmp::min(peer_count as usize, MAX_ALLOC_SIZE/mem::size_of::<(PublicKey, Mutex<PeerState>)>()));
for _ in 0..peer_count {
let peer_pubkey = Readable::read(reader)?;
let peer_state = PeerState {
latest_features: Readable::read(reader)?,
};
per_peer_state.insert(peer_pubkey, Mutex::new(peer_state));
}
let event_count: u64 = Readable::read(reader)?;
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>()));
for _ in 0..event_count {
match MaybeReadable::read(reader)? {
Some(event) => pending_events_read.push(event),
None => continue,
}
}
if forward_htlcs_count > 0 {
// If we have pending HTLCs to forward, assume we either dropped a
// `PendingHTLCsForwardable` or the user received it but never processed it as they
// shut down before the timer hit. Either way, set the time_forwardable to a small
// constant as enough time has likely passed that we should simply handle the forwards
// now, or at least after the user gets a chance to reconnect to our peers.
pending_events_read.push(events::Event::PendingHTLCsForwardable {
time_forwardable: Duration::from_secs(2),
});
}
let background_event_count: u64 = Readable::read(reader)?;
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>()));
for _ in 0..background_event_count {
match <u8 as Readable>::read(reader)? {
0 => pending_background_events_read.push(BackgroundEvent::ClosingMonitorUpdate((Readable::read(reader)?, Readable::read(reader)?))),
_ => return Err(DecodeError::InvalidValue),
}
}
let last_node_announcement_serial: u32 = Readable::read(reader)?;
let highest_seen_timestamp: u32 = Readable::read(reader)?;
let pending_inbound_payment_count: u64 = Readable::read(reader)?;
let mut pending_inbound_payments: HashMap<PaymentHash, PendingInboundPayment> = HashMap::with_capacity(cmp::min(pending_inbound_payment_count as usize, MAX_ALLOC_SIZE/(3*32)));
for _ in 0..pending_inbound_payment_count {
if pending_inbound_payments.insert(Readable::read(reader)?, Readable::read(reader)?).is_some() {
return Err(DecodeError::InvalidValue);
}
}
let pending_outbound_payments_count_compat: u64 = Readable::read(reader)?;
let mut pending_outbound_payments_compat: HashMap<PaymentId, PendingOutboundPayment> =
HashMap::with_capacity(cmp::min(pending_outbound_payments_count_compat as usize, MAX_ALLOC_SIZE/32));
for _ in 0..pending_outbound_payments_count_compat {
let session_priv = Readable::read(reader)?;
let payment = PendingOutboundPayment::Legacy {
session_privs: [session_priv].iter().cloned().collect()
};
if pending_outbound_payments_compat.insert(PaymentId(session_priv), payment).is_some() {
return Err(DecodeError::InvalidValue)
};
}
// pending_outbound_payments_no_retry is for compatibility with 0.0.101 clients.
let mut pending_outbound_payments_no_retry: Option<HashMap<PaymentId, HashSet<[u8; 32]>>> = None;
let mut pending_outbound_payments = None;
let mut received_network_pubkey: Option<PublicKey> = None;
let mut fake_scid_rand_bytes: Option<[u8; 32]> = None;
let mut claimable_htlc_purposes = None;
read_tlv_fields!(reader, {
(1, pending_outbound_payments_no_retry, option),
(3, pending_outbound_payments, option),
(5, received_network_pubkey, option),
(7, fake_scid_rand_bytes, option),
(9, claimable_htlc_purposes, vec_type),
});
if fake_scid_rand_bytes.is_none() {
fake_scid_rand_bytes = Some(args.keys_manager.get_secure_random_bytes());
}
if pending_outbound_payments.is_none() && pending_outbound_payments_no_retry.is_none() {
pending_outbound_payments = Some(pending_outbound_payments_compat);
} else if pending_outbound_payments.is_none() {
let mut outbounds = HashMap::new();
for (id, session_privs) in pending_outbound_payments_no_retry.unwrap().drain() {
outbounds.insert(id, PendingOutboundPayment::Legacy { session_privs });
}
pending_outbound_payments = Some(outbounds);
} else {
// If we're tracking pending payments, ensure we haven't lost any by looking at the
// ChannelMonitor data for any channels for which we do not have authorative state
// (i.e. those for which we just force-closed above or we otherwise don't have a
// corresponding `Channel` at all).
// This avoids several edge-cases where we would otherwise "forget" about pending
// payments which are still in-flight via their on-chain state.
// We only rebuild the pending payments map if we were most recently serialized by
// 0.0.102+
for (_, monitor) in args.channel_monitors.iter() {
if by_id.get(&monitor.get_funding_txo().0.to_channel_id()).is_none() {
for (htlc_source, htlc) in monitor.get_pending_outbound_htlcs() {
if let HTLCSource::OutboundRoute { payment_id, session_priv, path, payment_secret, .. } = htlc_source {
if path.is_empty() {
log_error!(args.logger, "Got an empty path for a pending payment");
return Err(DecodeError::InvalidValue);
}
let path_amt = path.last().unwrap().fee_msat;
let mut session_priv_bytes = [0; 32];
session_priv_bytes[..].copy_from_slice(&session_priv[..]);
match pending_outbound_payments.as_mut().unwrap().entry(payment_id) {
hash_map::Entry::Occupied(mut entry) => {
let newly_added = entry.get_mut().insert(session_priv_bytes, &path);
log_info!(args.logger, "{} a pending payment path for {} msat for session priv {} on an existing pending payment with payment hash {}",
if newly_added { "Added" } else { "Had" }, path_amt, log_bytes!(session_priv_bytes), log_bytes!(htlc.payment_hash.0));
},
hash_map::Entry::Vacant(entry) => {
let path_fee = path.get_path_fees();
entry.insert(PendingOutboundPayment::Retryable {
session_privs: [session_priv_bytes].iter().map(|a| *a).collect(),
payment_hash: htlc.payment_hash,
payment_secret,
pending_amt_msat: path_amt,
pending_fee_msat: Some(path_fee),
total_msat: path_amt,
starting_block_height: best_block_height,
});
log_info!(args.logger, "Added a pending payment for {} msat with payment hash {} for path with session priv {}",
path_amt, log_bytes!(htlc.payment_hash.0), log_bytes!(session_priv_bytes));
}
}
}
}
}
}
}
let inbound_pmt_key_material = args.keys_manager.get_inbound_payment_key_material();
let expanded_inbound_key = inbound_payment::ExpandedKey::new(&inbound_pmt_key_material);
let mut claimable_htlcs = HashMap::with_capacity(claimable_htlcs_list.len());
if let Some(mut purposes) = claimable_htlc_purposes {
if purposes.len() != claimable_htlcs_list.len() {
return Err(DecodeError::InvalidValue);
}
for (purpose, (payment_hash, previous_hops)) in purposes.drain(..).zip(claimable_htlcs_list.drain(..)) {
claimable_htlcs.insert(payment_hash, (purpose, previous_hops));
}
} else {
// LDK versions prior to 0.0.107 did not write a `pending_htlc_purposes`, but do
// include a `_legacy_hop_data` in the `OnionPayload`.
for (payment_hash, previous_hops) in claimable_htlcs_list.drain(..) {
if previous_hops.is_empty() {
return Err(DecodeError::InvalidValue);
}
let purpose = match &previous_hops[0].onion_payload {
OnionPayload::Invoice { _legacy_hop_data } => {
if let Some(hop_data) = _legacy_hop_data {
events::PaymentPurpose::InvoicePayment {
payment_preimage: match pending_inbound_payments.get(&payment_hash) {
Some(inbound_payment) => inbound_payment.payment_preimage,
None => match inbound_payment::verify(payment_hash, &hop_data, 0, &expanded_inbound_key, &args.logger) {
Ok(payment_preimage) => payment_preimage,
Err(()) => {
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));
return Err(DecodeError::InvalidValue);
}
}
},
payment_secret: hop_data.payment_secret,
}
} else { return Err(DecodeError::InvalidValue); }
},
OnionPayload::Spontaneous(payment_preimage) =>
events::PaymentPurpose::SpontaneousPayment(*payment_preimage),
};
claimable_htlcs.insert(payment_hash, (purpose, previous_hops));
}
}
let mut secp_ctx = Secp256k1::new();
secp_ctx.seeded_randomize(&args.keys_manager.get_secure_random_bytes());
if !channel_closures.is_empty() {
pending_events_read.append(&mut channel_closures);
}
let our_network_key = match args.keys_manager.get_node_secret(Recipient::Node) {
Ok(key) => key,
Err(()) => return Err(DecodeError::InvalidValue)
};
let our_network_pubkey = PublicKey::from_secret_key(&secp_ctx, &our_network_key);
if let Some(network_pubkey) = received_network_pubkey {
if network_pubkey != our_network_pubkey {
log_error!(args.logger, "Key that was generated does not match the existing key.");
return Err(DecodeError::InvalidValue);
}
}
let mut outbound_scid_aliases = HashSet::new();
for (chan_id, chan) in by_id.iter_mut() {
if chan.outbound_scid_alias() == 0 {
let mut outbound_scid_alias;
loop {
outbound_scid_alias = fake_scid::Namespace::OutboundAlias
.get_fake_scid(best_block_height, &genesis_hash, fake_scid_rand_bytes.as_ref().unwrap(), &args.keys_manager);
if outbound_scid_aliases.insert(outbound_scid_alias) { break; }
}
chan.set_outbound_scid_alias(outbound_scid_alias);
} else if !outbound_scid_aliases.insert(chan.outbound_scid_alias()) {
// Note that in rare cases its possible to hit this while reading an older
// channel if we just happened to pick a colliding outbound alias above.
log_error!(args.logger, "Got duplicate outbound SCID alias; {}", chan.outbound_scid_alias());
return Err(DecodeError::InvalidValue);
}
if chan.is_usable() {
if short_to_id.insert(chan.outbound_scid_alias(), *chan_id).is_some() {
// Note that in rare cases its possible to hit this while reading an older
// channel if we just happened to pick a colliding outbound alias above.
log_error!(args.logger, "Got duplicate outbound SCID alias; {}", chan.outbound_scid_alias());
return Err(DecodeError::InvalidValue);
}
}
}
for (_, monitor) in args.channel_monitors.iter() {
for (payment_hash, payment_preimage) in monitor.get_stored_preimages() {
if let Some((payment_purpose, claimable_htlcs)) = claimable_htlcs.remove(&payment_hash) {
log_info!(args.logger, "Re-claiming HTLCs with payment hash {} as we've released the preimage to a ChannelMonitor!", log_bytes!(payment_hash.0));
let mut claimable_amt_msat = 0;
for claimable_htlc in claimable_htlcs {
claimable_amt_msat += claimable_htlc.value;
// Add a holding-cell claim of the payment to the Channel, which should be
// applied ~immediately on peer reconnection. Because it won't generate a
// new commitment transaction we can just provide the payment preimage to
// the corresponding ChannelMonitor and nothing else.
//
// We do so directly instead of via the normal ChannelMonitor update
// procedure as the ChainMonitor hasn't yet been initialized, implying
// we're not allowed to call it directly yet. Further, we do the update
// without incrementing the ChannelMonitor update ID as there isn't any
// reason to.
// If we were to generate a new ChannelMonitor update ID here and then
// crash before the user finishes block connect we'd end up force-closing
// this channel as well. On the flip side, there's no harm in restarting
// without the new monitor persisted - we'll end up right back here on
// restart.
let previous_channel_id = claimable_htlc.prev_hop.outpoint.to_channel_id();
if let Some(channel) = by_id.get_mut(&previous_channel_id) {
channel.claim_htlc_while_disconnected_dropping_mon_update(claimable_htlc.prev_hop.htlc_id, payment_preimage, &args.logger);
}
if let Some(previous_hop_monitor) = args.channel_monitors.get(&claimable_htlc.prev_hop.outpoint) {
previous_hop_monitor.provide_payment_preimage(&payment_hash, &payment_preimage, &args.tx_broadcaster, &args.fee_estimator, &args.logger);
}
}
pending_events_read.push(events::Event::PaymentClaimed {
payment_hash,
purpose: payment_purpose,
amount_msat: claimable_amt_msat,
});
}
}
}
let channel_manager = ChannelManager {
genesis_hash,
fee_estimator: args.fee_estimator,
chain_monitor: args.chain_monitor,
tx_broadcaster: args.tx_broadcaster,
best_block: RwLock::new(BestBlock::new(best_block_hash, best_block_height)),
channel_state: Mutex::new(ChannelHolder {
by_id,
short_to_id,
forward_htlcs,
claimable_htlcs,
pending_msg_events: Vec::new(),
}),
inbound_payment_key: expanded_inbound_key,
pending_inbound_payments: Mutex::new(pending_inbound_payments),
pending_outbound_payments: Mutex::new(pending_outbound_payments.unwrap()),
outbound_scid_aliases: Mutex::new(outbound_scid_aliases),
fake_scid_rand_bytes: fake_scid_rand_bytes.unwrap(),
our_network_key,
our_network_pubkey,
secp_ctx,
last_node_announcement_serial: AtomicUsize::new(last_node_announcement_serial as usize),
highest_seen_timestamp: AtomicUsize::new(highest_seen_timestamp as usize),
per_peer_state: RwLock::new(per_peer_state),
pending_events: Mutex::new(pending_events_read),
pending_background_events: Mutex::new(pending_background_events_read),
total_consistency_lock: RwLock::new(()),
persistence_notifier: PersistenceNotifier::new(),
keys_manager: args.keys_manager,
logger: args.logger,
default_configuration: args.default_config,
};
for htlc_source in failed_htlcs.drain(..) {
channel_manager.fail_htlc_backwards_internal(channel_manager.channel_state.lock().unwrap(), htlc_source.0, &htlc_source.1, HTLCFailReason::Reason { failure_code: 0x4000 | 8, data: Vec::new() });
}
//TODO: Broadcast channel update for closed channels, but only after we've made a
//connection or two.
Ok((best_block_hash.clone(), channel_manager))
}
}
#[cfg(test)]
mod tests {
use bitcoin::hashes::Hash;
use bitcoin::hashes::sha256::Hash as Sha256;
use core::time::Duration;
use core::sync::atomic::Ordering;
use ln::{PaymentPreimage, PaymentHash, PaymentSecret};
use ln::channelmanager::{PaymentId, PaymentSendFailure};
use ln::channelmanager::inbound_payment;
use ln::features::InitFeatures;
use ln::functional_test_utils::*;
use ln::msgs;
use ln::msgs::ChannelMessageHandler;
use routing::router::{PaymentParameters, RouteParameters, find_route};
use util::errors::APIError;
use util::events::{Event, MessageSendEvent, MessageSendEventsProvider};
use util::test_utils;
use chain::keysinterface::KeysInterface;
#[cfg(feature = "std")]
#[test]
fn test_wait_timeout() {
use ln::channelmanager::PersistenceNotifier;
use sync::Arc;
use core::sync::atomic::AtomicBool;
use std::thread;
let persistence_notifier = Arc::new(PersistenceNotifier::new());
let thread_notifier = Arc::clone(&persistence_notifier);
let exit_thread = Arc::new(AtomicBool::new(false));
let exit_thread_clone = exit_thread.clone();
thread::spawn(move || {
loop {
let &(ref persist_mtx, ref cnd) = &thread_notifier.persistence_lock;
let mut persistence_lock = persist_mtx.lock().unwrap();
*persistence_lock = true;
cnd.notify_all();
if exit_thread_clone.load(Ordering::SeqCst) {
break
}
}
});
// Check that we can block indefinitely until updates are available.
let _ = persistence_notifier.wait();
// Check that the PersistenceNotifier will return after the given duration if updates are
// available.
loop {
if persistence_notifier.wait_timeout(Duration::from_millis(100)) {
break
}
}
exit_thread.store(true, Ordering::SeqCst);
// Check that the PersistenceNotifier will return after the given duration even if no updates
// are available.
loop {
if !persistence_notifier.wait_timeout(Duration::from_millis(100)) {
break
}
}
}
#[test]
fn test_notify_limits() {
// Check that a few cases which don't require the persistence of a new ChannelManager,
// indeed, do not cause the persistence of a new ChannelManager.
let chanmon_cfgs = create_chanmon_cfgs(3);
let node_cfgs = create_node_cfgs(3, &chanmon_cfgs);
let node_chanmgrs = create_node_chanmgrs(3, &node_cfgs, &[None, None, None]);
let nodes = create_network(3, &node_cfgs, &node_chanmgrs);
// All nodes start with a persistable update pending as `create_network` connects each node
// with all other nodes to make most tests simpler.
assert!(nodes[0].node.await_persistable_update_timeout(Duration::from_millis(1)));
assert!(nodes[1].node.await_persistable_update_timeout(Duration::from_millis(1)));
assert!(nodes[2].node.await_persistable_update_timeout(Duration::from_millis(1)));
let mut chan = create_announced_chan_between_nodes(&nodes, 0, 1, InitFeatures::known(), InitFeatures::known());
// We check that the channel info nodes have doesn't change too early, even though we try
// to connect messages with new values
chan.0.contents.fee_base_msat *= 2;
chan.1.contents.fee_base_msat *= 2;
let node_a_chan_info = nodes[0].node.list_channels()[0].clone();
let node_b_chan_info = nodes[1].node.list_channels()[0].clone();
// The first two nodes (which opened a channel) should now require fresh persistence
assert!(nodes[0].node.await_persistable_update_timeout(Duration::from_millis(1)));
assert!(nodes[1].node.await_persistable_update_timeout(Duration::from_millis(1)));
// ... but the last node should not.
assert!(!nodes[2].node.await_persistable_update_timeout(Duration::from_millis(1)));
// After persisting the first two nodes they should no longer need fresh persistence.
assert!(!nodes[0].node.await_persistable_update_timeout(Duration::from_millis(1)));
assert!(!nodes[1].node.await_persistable_update_timeout(Duration::from_millis(1)));
// Node 3, unrelated to the only channel, shouldn't care if it receives a channel_update
// about the channel.
nodes[2].node.handle_channel_update(&nodes[1].node.get_our_node_id(), &chan.0);
nodes[2].node.handle_channel_update(&nodes[1].node.get_our_node_id(), &chan.1);
assert!(!nodes[2].node.await_persistable_update_timeout(Duration::from_millis(1)));
// The nodes which are a party to the channel should also ignore messages from unrelated
// parties.
nodes[0].node.handle_channel_update(&nodes[2].node.get_our_node_id(), &chan.0);
nodes[0].node.handle_channel_update(&nodes[2].node.get_our_node_id(), &chan.1);
nodes[1].node.handle_channel_update(&nodes[2].node.get_our_node_id(), &chan.0);
nodes[1].node.handle_channel_update(&nodes[2].node.get_our_node_id(), &chan.1);
assert!(!nodes[0].node.await_persistable_update_timeout(Duration::from_millis(1)));
assert!(!nodes[1].node.await_persistable_update_timeout(Duration::from_millis(1)));
// At this point the channel info given by peers should still be the same.
assert_eq!(nodes[0].node.list_channels()[0], node_a_chan_info);
assert_eq!(nodes[1].node.list_channels()[0], node_b_chan_info);
// An earlier version of handle_channel_update didn't check the directionality of the
// update message and would always update the local fee info, even if our peer was
// (spuriously) forwarding us our own channel_update.
let as_node_one = nodes[0].node.get_our_node_id().serialize()[..] < nodes[1].node.get_our_node_id().serialize()[..];
let as_update = if as_node_one == (chan.0.contents.flags & 1 == 0 /* chan.0 is from node one */) { &chan.0 } else { &chan.1 };
let bs_update = if as_node_one == (chan.0.contents.flags & 1 == 0 /* chan.0 is from node one */) { &chan.1 } else { &chan.0 };
// First deliver each peers' own message, checking that the node doesn't need to be
// persisted and that its channel info remains the same.
nodes[0].node.handle_channel_update(&nodes[1].node.get_our_node_id(), &as_update);
nodes[1].node.handle_channel_update(&nodes[0].node.get_our_node_id(), &bs_update);
assert!(!nodes[0].node.await_persistable_update_timeout(Duration::from_millis(1)));
assert!(!nodes[1].node.await_persistable_update_timeout(Duration::from_millis(1)));
assert_eq!(nodes[0].node.list_channels()[0], node_a_chan_info);
assert_eq!(nodes[1].node.list_channels()[0], node_b_chan_info);
// Finally, deliver the other peers' message, ensuring each node needs to be persisted and
// the channel info has updated.
nodes[0].node.handle_channel_update(&nodes[1].node.get_our_node_id(), &bs_update);
nodes[1].node.handle_channel_update(&nodes[0].node.get_our_node_id(), &as_update);
assert!(nodes[0].node.await_persistable_update_timeout(Duration::from_millis(1)));
assert!(nodes[1].node.await_persistable_update_timeout(Duration::from_millis(1)));
assert_ne!(nodes[0].node.list_channels()[0], node_a_chan_info);
assert_ne!(nodes[1].node.list_channels()[0], node_b_chan_info);
}
#[test]
fn test_keysend_dup_hash_partial_mpp() {
// Test that a keysend payment with a duplicate hash to an existing partial MPP payment fails as
// expected.
let chanmon_cfgs = create_chanmon_cfgs(2);
let node_cfgs = create_node_cfgs(2, &chanmon_cfgs);
let node_chanmgrs = create_node_chanmgrs(2, &node_cfgs, &[None, None]);
let nodes = create_network(2, &node_cfgs, &node_chanmgrs);
create_announced_chan_between_nodes(&nodes, 0, 1, InitFeatures::known(), InitFeatures::known());
// First, send a partial MPP payment.
let (route, our_payment_hash, payment_preimage, payment_secret) = get_route_and_payment_hash!(&nodes[0], nodes[1], 100_000);
let payment_id = PaymentId([42; 32]);
// Use the utility function send_payment_along_path to send the payment with MPP data which
// indicates there are more HTLCs coming.
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.
nodes[0].node.send_payment_along_path(&route.paths[0], &route.payment_params, &our_payment_hash, &Some(payment_secret), 200_000, cur_height, payment_id, &None).unwrap();
check_added_monitors!(nodes[0], 1);
let mut events = nodes[0].node.get_and_clear_pending_msg_events();
assert_eq!(events.len(), 1);
pass_along_path(&nodes[0], &[&nodes[1]], 200_000, our_payment_hash, Some(payment_secret), events.drain(..).next().unwrap(), false, None);
// Next, send a keysend payment with the same payment_hash and make sure it fails.
nodes[0].node.send_spontaneous_payment(&route, Some(payment_preimage)).unwrap();
check_added_monitors!(nodes[0], 1);
let mut events = nodes[0].node.get_and_clear_pending_msg_events();
assert_eq!(events.len(), 1);
let ev = events.drain(..).next().unwrap();
let payment_event = SendEvent::from_event(ev);
nodes[1].node.handle_update_add_htlc(&nodes[0].node.get_our_node_id(), &payment_event.msgs[0]);
check_added_monitors!(nodes[1], 0);
commitment_signed_dance!(nodes[1], nodes[0], payment_event.commitment_msg, false);
expect_pending_htlcs_forwardable!(nodes[1]);
expect_pending_htlcs_forwardable!(nodes[1]);
check_added_monitors!(nodes[1], 1);
let updates = get_htlc_update_msgs!(nodes[1], nodes[0].node.get_our_node_id());
assert!(updates.update_add_htlcs.is_empty());
assert!(updates.update_fulfill_htlcs.is_empty());
assert_eq!(updates.update_fail_htlcs.len(), 1);
assert!(updates.update_fail_malformed_htlcs.is_empty());
assert!(updates.update_fee.is_none());
nodes[0].node.handle_update_fail_htlc(&nodes[1].node.get_our_node_id(), &updates.update_fail_htlcs[0]);
commitment_signed_dance!(nodes[0], nodes[1], updates.commitment_signed, true, true);
expect_payment_failed!(nodes[0], our_payment_hash, true);
// Send the second half of the original MPP payment.
nodes[0].node.send_payment_along_path(&route.paths[0], &route.payment_params, &our_payment_hash, &Some(payment_secret), 200_000, cur_height, payment_id, &None).unwrap();
check_added_monitors!(nodes[0], 1);
let mut events = nodes[0].node.get_and_clear_pending_msg_events();
assert_eq!(events.len(), 1);
pass_along_path(&nodes[0], &[&nodes[1]], 200_000, our_payment_hash, Some(payment_secret), events.drain(..).next().unwrap(), true, None);
// Claim the full MPP payment. Note that we can't use a test utility like
// claim_funds_along_route because the ordering of the messages causes the second half of the
// payment to be put in the holding cell, which confuses the test utilities. So we exchange the
// lightning messages manually.
nodes[1].node.claim_funds(payment_preimage);
expect_payment_claimed!(nodes[1], our_payment_hash, 200_000);
check_added_monitors!(nodes[1], 2);
let bs_first_updates = get_htlc_update_msgs!(nodes[1], nodes[0].node.get_our_node_id());
nodes[0].node.handle_update_fulfill_htlc(&nodes[1].node.get_our_node_id(), &bs_first_updates.update_fulfill_htlcs[0]);
nodes[0].node.handle_commitment_signed(&nodes[1].node.get_our_node_id(), &bs_first_updates.commitment_signed);
check_added_monitors!(nodes[0], 1);
let (as_first_raa, as_first_cs) = get_revoke_commit_msgs!(nodes[0], nodes[1].node.get_our_node_id());
nodes[1].node.handle_revoke_and_ack(&nodes[0].node.get_our_node_id(), &as_first_raa);
check_added_monitors!(nodes[1], 1);
let bs_second_updates = get_htlc_update_msgs!(nodes[1], nodes[0].node.get_our_node_id());
nodes[1].node.handle_commitment_signed(&nodes[0].node.get_our_node_id(), &as_first_cs);
check_added_monitors!(nodes[1], 1);
let bs_first_raa = get_event_msg!(nodes[1], MessageSendEvent::SendRevokeAndACK, nodes[0].node.get_our_node_id());
nodes[0].node.handle_update_fulfill_htlc(&nodes[1].node.get_our_node_id(), &bs_second_updates.update_fulfill_htlcs[0]);
nodes[0].node.handle_commitment_signed(&nodes[1].node.get_our_node_id(), &bs_second_updates.commitment_signed);
check_added_monitors!(nodes[0], 1);
let as_second_raa = get_event_msg!(nodes[0], MessageSendEvent::SendRevokeAndACK, nodes[1].node.get_our_node_id());
nodes[0].node.handle_revoke_and_ack(&nodes[1].node.get_our_node_id(), &bs_first_raa);
let as_second_updates = get_htlc_update_msgs!(nodes[0], nodes[1].node.get_our_node_id());
check_added_monitors!(nodes[0], 1);
nodes[1].node.handle_revoke_and_ack(&nodes[0].node.get_our_node_id(), &as_second_raa);
check_added_monitors!(nodes[1], 1);
nodes[1].node.handle_commitment_signed(&nodes[0].node.get_our_node_id(), &as_second_updates.commitment_signed);
check_added_monitors!(nodes[1], 1);
let bs_third_raa = get_event_msg!(nodes[1], MessageSendEvent::SendRevokeAndACK, nodes[0].node.get_our_node_id());
nodes[0].node.handle_revoke_and_ack(&nodes[1].node.get_our_node_id(), &bs_third_raa);
check_added_monitors!(nodes[0], 1);
// Note that successful MPP payments will generate a single PaymentSent event upon the first
// path's success and a PaymentPathSuccessful event for each path's success.
let events = nodes[0].node.get_and_clear_pending_events();
assert_eq!(events.len(), 3);
match events[0] {
Event::PaymentSent { payment_id: ref id, payment_preimage: ref preimage, payment_hash: ref hash, .. } => {
assert_eq!(Some(payment_id), *id);
assert_eq!(payment_preimage, *preimage);
assert_eq!(our_payment_hash, *hash);
},
_ => panic!("Unexpected event"),
}
match events[1] {
Event::PaymentPathSuccessful { payment_id: ref actual_payment_id, ref payment_hash, ref path } => {
assert_eq!(payment_id, *actual_payment_id);
assert_eq!(our_payment_hash, *payment_hash.as_ref().unwrap());
assert_eq!(route.paths[0], *path);
},
_ => panic!("Unexpected event"),
}
match events[2] {
Event::PaymentPathSuccessful { payment_id: ref actual_payment_id, ref payment_hash, ref path } => {
assert_eq!(payment_id, *actual_payment_id);
assert_eq!(our_payment_hash, *payment_hash.as_ref().unwrap());
assert_eq!(route.paths[0], *path);
},
_ => panic!("Unexpected event"),
}
}
#[test]
fn test_keysend_dup_payment_hash() {
// (1): Test that a keysend payment with a duplicate payment hash to an existing pending
// outbound regular payment fails as expected.
// (2): Test that a regular payment with a duplicate payment hash to an existing keysend payment
// fails as expected.
let chanmon_cfgs = create_chanmon_cfgs(2);
let node_cfgs = create_node_cfgs(2, &chanmon_cfgs);
let node_chanmgrs = create_node_chanmgrs(2, &node_cfgs, &[None, None]);
let nodes = create_network(2, &node_cfgs, &node_chanmgrs);
create_announced_chan_between_nodes(&nodes, 0, 1, InitFeatures::known(), InitFeatures::known());
let scorer = test_utils::TestScorer::with_penalty(0);
let random_seed_bytes = chanmon_cfgs[1].keys_manager.get_secure_random_bytes();
// To start (1), send a regular payment but don't claim it.
let expected_route = [&nodes[1]];
let (payment_preimage, payment_hash, _) = route_payment(&nodes[0], &expected_route, 100_000);
// Next, attempt a keysend payment and make sure it fails.
let route_params = RouteParameters {
payment_params: PaymentParameters::for_keysend(expected_route.last().unwrap().node.get_our_node_id()),
final_value_msat: 100_000,
final_cltv_expiry_delta: TEST_FINAL_CLTV,
};
let route = find_route(
&nodes[0].node.get_our_node_id(), &route_params, nodes[0].network_graph, None,
nodes[0].logger, &scorer, &random_seed_bytes
).unwrap();
nodes[0].node.send_spontaneous_payment(&route, Some(payment_preimage)).unwrap();
check_added_monitors!(nodes[0], 1);
let mut events = nodes[0].node.get_and_clear_pending_msg_events();
assert_eq!(events.len(), 1);
let ev = events.drain(..).next().unwrap();
let payment_event = SendEvent::from_event(ev);
nodes[1].node.handle_update_add_htlc(&nodes[0].node.get_our_node_id(), &payment_event.msgs[0]);
check_added_monitors!(nodes[1], 0);
commitment_signed_dance!(nodes[1], nodes[0], payment_event.commitment_msg, false);
expect_pending_htlcs_forwardable!(nodes[1]);
expect_pending_htlcs_forwardable!(nodes[1]);
check_added_monitors!(nodes[1], 1);
let updates = get_htlc_update_msgs!(nodes[1], nodes[0].node.get_our_node_id());
assert!(updates.update_add_htlcs.is_empty());
assert!(updates.update_fulfill_htlcs.is_empty());
assert_eq!(updates.update_fail_htlcs.len(), 1);
assert!(updates.update_fail_malformed_htlcs.is_empty());
assert!(updates.update_fee.is_none());
nodes[0].node.handle_update_fail_htlc(&nodes[1].node.get_our_node_id(), &updates.update_fail_htlcs[0]);
commitment_signed_dance!(nodes[0], nodes[1], updates.commitment_signed, true, true);
expect_payment_failed!(nodes[0], payment_hash, true);
// Finally, claim the original payment.
claim_payment(&nodes[0], &expected_route, payment_preimage);
// To start (2), send a keysend payment but don't claim it.
let payment_preimage = PaymentPreimage([42; 32]);
let route = find_route(
&nodes[0].node.get_our_node_id(), &route_params, nodes[0].network_graph, None,
nodes[0].logger, &scorer, &random_seed_bytes
).unwrap();
let (payment_hash, _) = nodes[0].node.send_spontaneous_payment(&route, Some(payment_preimage)).unwrap();
check_added_monitors!(nodes[0], 1);
let mut events = nodes[0].node.get_and_clear_pending_msg_events();
assert_eq!(events.len(), 1);
let event = events.pop().unwrap();
let path = vec![&nodes[1]];
pass_along_path(&nodes[0], &path, 100_000, payment_hash, None, event, true, Some(payment_preimage));
// Next, attempt a regular payment and make sure it fails.
let payment_secret = PaymentSecret([43; 32]);
nodes[0].node.send_payment(&route, payment_hash, &Some(payment_secret)).unwrap();
check_added_monitors!(nodes[0], 1);
let mut events = nodes[0].node.get_and_clear_pending_msg_events();
assert_eq!(events.len(), 1);
let ev = events.drain(..).next().unwrap();
let payment_event = SendEvent::from_event(ev);
nodes[1].node.handle_update_add_htlc(&nodes[0].node.get_our_node_id(), &payment_event.msgs[0]);
check_added_monitors!(nodes[1], 0);
commitment_signed_dance!(nodes[1], nodes[0], payment_event.commitment_msg, false);
expect_pending_htlcs_forwardable!(nodes[1]);
expect_pending_htlcs_forwardable!(nodes[1]);
check_added_monitors!(nodes[1], 1);
let updates = get_htlc_update_msgs!(nodes[1], nodes[0].node.get_our_node_id());
assert!(updates.update_add_htlcs.is_empty());
assert!(updates.update_fulfill_htlcs.is_empty());
assert_eq!(updates.update_fail_htlcs.len(), 1);
assert!(updates.update_fail_malformed_htlcs.is_empty());
assert!(updates.update_fee.is_none());
nodes[0].node.handle_update_fail_htlc(&nodes[1].node.get_our_node_id(), &updates.update_fail_htlcs[0]);
commitment_signed_dance!(nodes[0], nodes[1], updates.commitment_signed, true, true);
expect_payment_failed!(nodes[0], payment_hash, true);
// Finally, succeed the keysend payment.
claim_payment(&nodes[0], &expected_route, payment_preimage);
}
#[test]
fn test_keysend_hash_mismatch() {
// Test that if we receive a keysend `update_add_htlc` msg, we fail as expected if the keysend
// preimage doesn't match the msg's payment hash.
let chanmon_cfgs = create_chanmon_cfgs(2);
let node_cfgs = create_node_cfgs(2, &chanmon_cfgs);
let node_chanmgrs = create_node_chanmgrs(2, &node_cfgs, &[None, None]);
let nodes = create_network(2, &node_cfgs, &node_chanmgrs);
let payer_pubkey = nodes[0].node.get_our_node_id();
let payee_pubkey = nodes[1].node.get_our_node_id();
nodes[0].node.peer_connected(&payee_pubkey, &msgs::Init { features: InitFeatures::known(), remote_network_address: None });
nodes[1].node.peer_connected(&payer_pubkey, &msgs::Init { features: InitFeatures::known(), remote_network_address: None });
let _chan = create_chan_between_nodes(&nodes[0], &nodes[1], InitFeatures::known(), InitFeatures::known());
let route_params = RouteParameters {
payment_params: PaymentParameters::for_keysend(payee_pubkey),
final_value_msat: 10000,
final_cltv_expiry_delta: 40,
};
let network_graph = nodes[0].network_graph;
let first_hops = nodes[0].node.list_usable_channels();
let scorer = test_utils::TestScorer::with_penalty(0);
let random_seed_bytes = chanmon_cfgs[1].keys_manager.get_secure_random_bytes();
let route = find_route(
&payer_pubkey, &route_params, network_graph, Some(&first_hops.iter().collect::<Vec<_>>()),
nodes[0].logger, &scorer, &random_seed_bytes
).unwrap();
let test_preimage = PaymentPreimage([42; 32]);
let mismatch_payment_hash = PaymentHash([43; 32]);
let _ = nodes[0].node.send_payment_internal(&route, mismatch_payment_hash, &None, Some(test_preimage), None, None).unwrap();
check_added_monitors!(nodes[0], 1);
let updates = get_htlc_update_msgs!(nodes[0], nodes[1].node.get_our_node_id());
assert_eq!(updates.update_add_htlcs.len(), 1);
assert!(updates.update_fulfill_htlcs.is_empty());
assert!(updates.update_fail_htlcs.is_empty());
assert!(updates.update_fail_malformed_htlcs.is_empty());
assert!(updates.update_fee.is_none());
nodes[1].node.handle_update_add_htlc(&nodes[0].node.get_our_node_id(), &updates.update_add_htlcs[0]);
nodes[1].logger.assert_log_contains("lightning::ln::channelmanager".to_string(), "Payment preimage didn't match payment hash".to_string(), 1);
}
#[test]
fn test_keysend_msg_with_secret_err() {
// Test that we error as expected if we receive a keysend payment that includes a payment secret.
let chanmon_cfgs = create_chanmon_cfgs(2);
let node_cfgs = create_node_cfgs(2, &chanmon_cfgs);
let node_chanmgrs = create_node_chanmgrs(2, &node_cfgs, &[None, None]);
let nodes = create_network(2, &node_cfgs, &node_chanmgrs);
let payer_pubkey = nodes[0].node.get_our_node_id();
let payee_pubkey = nodes[1].node.get_our_node_id();
nodes[0].node.peer_connected(&payee_pubkey, &msgs::Init { features: InitFeatures::known(), remote_network_address: None });
nodes[1].node.peer_connected(&payer_pubkey, &msgs::Init { features: InitFeatures::known(), remote_network_address: None });
let _chan = create_chan_between_nodes(&nodes[0], &nodes[1], InitFeatures::known(), InitFeatures::known());
let route_params = RouteParameters {
payment_params: PaymentParameters::for_keysend(payee_pubkey),
final_value_msat: 10000,
final_cltv_expiry_delta: 40,
};
let network_graph = nodes[0].network_graph;
let first_hops = nodes[0].node.list_usable_channels();
let scorer = test_utils::TestScorer::with_penalty(0);
let random_seed_bytes = chanmon_cfgs[1].keys_manager.get_secure_random_bytes();
let route = find_route(
&payer_pubkey, &route_params, network_graph, Some(&first_hops.iter().collect::<Vec<_>>()),
nodes[0].logger, &scorer, &random_seed_bytes
).unwrap();
let test_preimage = PaymentPreimage([42; 32]);
let test_secret = PaymentSecret([43; 32]);
let payment_hash = PaymentHash(Sha256::hash(&test_preimage.0).into_inner());
let _ = nodes[0].node.send_payment_internal(&route, payment_hash, &Some(test_secret), Some(test_preimage), None, None).unwrap();
check_added_monitors!(nodes[0], 1);
let updates = get_htlc_update_msgs!(nodes[0], nodes[1].node.get_our_node_id());
assert_eq!(updates.update_add_htlcs.len(), 1);
assert!(updates.update_fulfill_htlcs.is_empty());
assert!(updates.update_fail_htlcs.is_empty());
assert!(updates.update_fail_malformed_htlcs.is_empty());
assert!(updates.update_fee.is_none());
nodes[1].node.handle_update_add_htlc(&nodes[0].node.get_our_node_id(), &updates.update_add_htlcs[0]);
nodes[1].logger.assert_log_contains("lightning::ln::channelmanager".to_string(), "We don't support MPP keysend payments".to_string(), 1);
}
#[test]
fn test_multi_hop_missing_secret() {
let chanmon_cfgs = create_chanmon_cfgs(4);
let node_cfgs = create_node_cfgs(4, &chanmon_cfgs);
let node_chanmgrs = create_node_chanmgrs(4, &node_cfgs, &[None, None, None, None]);
let nodes = create_network(4, &node_cfgs, &node_chanmgrs);
let chan_1_id = create_announced_chan_between_nodes(&nodes, 0, 1, InitFeatures::known(), InitFeatures::known()).0.contents.short_channel_id;
let chan_2_id = create_announced_chan_between_nodes(&nodes, 0, 2, InitFeatures::known(), InitFeatures::known()).0.contents.short_channel_id;
let chan_3_id = create_announced_chan_between_nodes(&nodes, 1, 3, InitFeatures::known(), InitFeatures::known()).0.contents.short_channel_id;
let chan_4_id = create_announced_chan_between_nodes(&nodes, 2, 3, InitFeatures::known(), InitFeatures::known()).0.contents.short_channel_id;
// Marshall an MPP route.
let (mut route, payment_hash, _, _) = get_route_and_payment_hash!(&nodes[0], nodes[3], 100000);
let path = route.paths[0].clone();
route.paths.push(path);
route.paths[0][0].pubkey = nodes[1].node.get_our_node_id();
route.paths[0][0].short_channel_id = chan_1_id;
route.paths[0][1].short_channel_id = chan_3_id;
route.paths[1][0].pubkey = nodes[2].node.get_our_node_id();
route.paths[1][0].short_channel_id = chan_2_id;
route.paths[1][1].short_channel_id = chan_4_id;
match nodes[0].node.send_payment(&route, payment_hash, &None).unwrap_err() {
PaymentSendFailure::ParameterError(APIError::APIMisuseError { ref err }) => {
assert!(regex::Regex::new(r"Payment secret is required for multi-path payments").unwrap().is_match(err)) },
_ => panic!("unexpected error")
}
}
#[test]
fn bad_inbound_payment_hash() {
// Add coverage for checking that a user-provided payment hash matches the payment secret.
let chanmon_cfgs = create_chanmon_cfgs(2);
let node_cfgs = create_node_cfgs(2, &chanmon_cfgs);
let node_chanmgrs = create_node_chanmgrs(2, &node_cfgs, &[None, None]);
let nodes = create_network(2, &node_cfgs, &node_chanmgrs);
let (_, payment_hash, payment_secret) = get_payment_preimage_hash!(&nodes[0]);
let payment_data = msgs::FinalOnionHopData {
payment_secret,
total_msat: 100_000,
};
// Ensure that if the payment hash given to `inbound_payment::verify` differs from the original,
// payment verification fails as expected.
let mut bad_payment_hash = payment_hash.clone();
bad_payment_hash.0[0] += 1;
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) {
Ok(_) => panic!("Unexpected ok"),
Err(()) => {
nodes[0].logger.assert_log_contains("lightning::ln::inbound_payment".to_string(), "Failing HTLC with user-generated payment_hash".to_string(), 1);
}
}
// Check that using the original payment hash succeeds.
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());
}
}
#[cfg(all(any(test, feature = "_test_utils"), feature = "_bench_unstable"))]
pub mod bench {
use chain::Listen;
use chain::chainmonitor::{ChainMonitor, Persist};
use chain::keysinterface::{KeysManager, KeysInterface, InMemorySigner};
use ln::channelmanager::{BestBlock, ChainParameters, ChannelManager, PaymentHash, PaymentPreimage};
use ln::features::{InitFeatures, InvoiceFeatures};
use ln::functional_test_utils::*;
use ln::msgs::{ChannelMessageHandler, Init};
use routing::network_graph::NetworkGraph;
use routing::router::{PaymentParameters, get_route};
use util::test_utils;
use util::config::UserConfig;
use util::events::{Event, MessageSendEvent, MessageSendEventsProvider};
use bitcoin::hashes::Hash;
use bitcoin::hashes::sha256::Hash as Sha256;
use bitcoin::{Block, BlockHeader, Transaction, TxOut};
use sync::{Arc, Mutex};
use test::Bencher;
struct NodeHolder<'a, P: Persist<InMemorySigner>> {
node: &'a ChannelManager<InMemorySigner,
&'a ChainMonitor<InMemorySigner, &'a test_utils::TestChainSource,
&'a test_utils::TestBroadcaster, &'a test_utils::TestFeeEstimator,
&'a test_utils::TestLogger, &'a P>,
&'a test_utils::TestBroadcaster, &'a KeysManager,
&'a test_utils::TestFeeEstimator, &'a test_utils::TestLogger>
}
#[cfg(test)]
#[bench]
fn bench_sends(bench: &mut Bencher) {
bench_two_sends(bench, test_utils::TestPersister::new(), test_utils::TestPersister::new());
}
pub fn bench_two_sends<P: Persist<InMemorySigner>>(bench: &mut Bencher, persister_a: P, persister_b: P) {
// Do a simple benchmark of sending a payment back and forth between two nodes.
// Note that this is unrealistic as each payment send will require at least two fsync
// calls per node.
let network = bitcoin::Network::Testnet;
let genesis_hash = bitcoin::blockdata::constants::genesis_block(network).header.block_hash();
let tx_broadcaster = test_utils::TestBroadcaster{txn_broadcasted: Mutex::new(Vec::new()), blocks: Arc::new(Mutex::new(Vec::new()))};
let fee_estimator = test_utils::TestFeeEstimator { sat_per_kw: Mutex::new(253) };
let mut config: UserConfig = Default::default();
config.own_channel_config.minimum_depth = 1;
let logger_a = test_utils::TestLogger::with_id("node a".to_owned());
let chain_monitor_a = ChainMonitor::new(None, &tx_broadcaster, &logger_a, &fee_estimator, &persister_a);
let seed_a = [1u8; 32];
let keys_manager_a = KeysManager::new(&seed_a, 42, 42);
let node_a = ChannelManager::new(&fee_estimator, &chain_monitor_a, &tx_broadcaster, &logger_a, &keys_manager_a, config.clone(), ChainParameters {
network,
best_block: BestBlock::from_genesis(network),
});
let node_a_holder = NodeHolder { node: &node_a };
let logger_b = test_utils::TestLogger::with_id("node a".to_owned());
let chain_monitor_b = ChainMonitor::new(None, &tx_broadcaster, &logger_a, &fee_estimator, &persister_b);
let seed_b = [2u8; 32];
let keys_manager_b = KeysManager::new(&seed_b, 42, 42);
let node_b = ChannelManager::new(&fee_estimator, &chain_monitor_b, &tx_broadcaster, &logger_b, &keys_manager_b, config.clone(), ChainParameters {
network,
best_block: BestBlock::from_genesis(network),
});
let node_b_holder = NodeHolder { node: &node_b };
node_a.peer_connected(&node_b.get_our_node_id(), &Init { features: InitFeatures::known(), remote_network_address: None });
node_b.peer_connected(&node_a.get_our_node_id(), &Init { features: InitFeatures::known(), remote_network_address: None });
node_a.create_channel(node_b.get_our_node_id(), 8_000_000, 100_000_000, 42, None).unwrap();
node_b.handle_open_channel(&node_a.get_our_node_id(), InitFeatures::known(), &get_event_msg!(node_a_holder, MessageSendEvent::SendOpenChannel, node_b.get_our_node_id()));
node_a.handle_accept_channel(&node_b.get_our_node_id(), InitFeatures::known(), &get_event_msg!(node_b_holder, MessageSendEvent::SendAcceptChannel, node_a.get_our_node_id()));
let tx;
if let Event::FundingGenerationReady { temporary_channel_id, output_script, .. } = get_event!(node_a_holder, Event::FundingGenerationReady) {
tx = Transaction { version: 2, lock_time: 0, input: Vec::new(), output: vec![TxOut {
value: 8_000_000, script_pubkey: output_script,
}]};
node_a.funding_transaction_generated(&temporary_channel_id, &node_b.get_our_node_id(), tx.clone()).unwrap();
} else { panic!(); }
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()));
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()));
assert_eq!(&tx_broadcaster.txn_broadcasted.lock().unwrap()[..], &[tx.clone()]);
let block = Block {
header: BlockHeader { version: 0x20000000, prev_blockhash: genesis_hash, merkle_root: Default::default(), time: 42, bits: 42, nonce: 42 },
txdata: vec![tx],
};
Listen::block_connected(&node_a, &block, 1);
Listen::block_connected(&node_b, &block, 1);
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()));
let msg_events = node_a.get_and_clear_pending_msg_events();
assert_eq!(msg_events.len(), 2);
match msg_events[0] {
MessageSendEvent::SendChannelReady { ref msg, .. } => {
node_b.handle_channel_ready(&node_a.get_our_node_id(), msg);
get_event_msg!(node_b_holder, MessageSendEvent::SendChannelUpdate, node_a.get_our_node_id());
},
_ => panic!(),
}
match msg_events[1] {
MessageSendEvent::SendChannelUpdate { .. } => {},
_ => panic!(),
}
let dummy_graph = NetworkGraph::new(genesis_hash);
let mut payment_count: u64 = 0;
macro_rules! send_payment {
($node_a: expr, $node_b: expr) => {
let usable_channels = $node_a.list_usable_channels();
let payment_params = PaymentParameters::from_node_id($node_b.get_our_node_id())
.with_features(InvoiceFeatures::known());
let scorer = test_utils::TestScorer::with_penalty(0);
let seed = [3u8; 32];
let keys_manager = KeysManager::new(&seed, 42, 42);
let random_seed_bytes = keys_manager.get_secure_random_bytes();
let route = get_route(&$node_a.get_our_node_id(), &payment_params, &dummy_graph.read_only(),
Some(&usable_channels.iter().map(|r| r).collect::<Vec<_>>()), 10_000, TEST_FINAL_CLTV, &logger_a, &scorer, &random_seed_bytes).unwrap();
let mut payment_preimage = PaymentPreimage([0; 32]);
payment_preimage.0[0..8].copy_from_slice(&payment_count.to_le_bytes());
payment_count += 1;
let payment_hash = PaymentHash(Sha256::hash(&payment_preimage.0[..]).into_inner());
let payment_secret = $node_b.create_inbound_payment_for_hash(payment_hash, None, 7200).unwrap();
$node_a.send_payment(&route, payment_hash, &Some(payment_secret)).unwrap();
let payment_event = SendEvent::from_event($node_a.get_and_clear_pending_msg_events().pop().unwrap());
$node_b.handle_update_add_htlc(&$node_a.get_our_node_id(), &payment_event.msgs[0]);
$node_b.handle_commitment_signed(&$node_a.get_our_node_id(), &payment_event.commitment_msg);
let (raa, cs) = get_revoke_commit_msgs!(NodeHolder { node: &$node_b }, $node_a.get_our_node_id());
$node_a.handle_revoke_and_ack(&$node_b.get_our_node_id(), &raa);
$node_a.handle_commitment_signed(&$node_b.get_our_node_id(), &cs);
$node_b.handle_revoke_and_ack(&$node_a.get_our_node_id(), &get_event_msg!(NodeHolder { node: &$node_a }, MessageSendEvent::SendRevokeAndACK, $node_b.get_our_node_id()));
expect_pending_htlcs_forwardable!(NodeHolder { node: &$node_b });
expect_payment_received!(NodeHolder { node: &$node_b }, payment_hash, payment_secret, 10_000);
$node_b.claim_funds(payment_preimage);
expect_payment_claimed!(NodeHolder { node: &$node_b }, payment_hash, 10_000);
match $node_b.get_and_clear_pending_msg_events().pop().unwrap() {
MessageSendEvent::UpdateHTLCs { node_id, updates } => {
assert_eq!(node_id, $node_a.get_our_node_id());
$node_a.handle_update_fulfill_htlc(&$node_b.get_our_node_id(), &updates.update_fulfill_htlcs[0]);
$node_a.handle_commitment_signed(&$node_b.get_our_node_id(), &updates.commitment_signed);
},
_ => panic!("Failed to generate claim event"),
}
let (raa, cs) = get_revoke_commit_msgs!(NodeHolder { node: &$node_a }, $node_b.get_our_node_id());
$node_b.handle_revoke_and_ack(&$node_a.get_our_node_id(), &raa);
$node_b.handle_commitment_signed(&$node_a.get_our_node_id(), &cs);
$node_a.handle_revoke_and_ack(&$node_b.get_our_node_id(), &get_event_msg!(NodeHolder { node: &$node_b }, MessageSendEvent::SendRevokeAndACK, $node_a.get_our_node_id()));
expect_payment_sent!(NodeHolder { node: &$node_a }, payment_preimage);
}
}
bench.iter(|| {
send_payment!(node_a, node_b);
send_payment!(node_b, node_a);
});
}
}
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