// You may not use this file except in accordance with one or both of these
// licenses.
+use bitcoin::blockdata::constants::ChainHash;
use bitcoin::blockdata::script::{Script,Builder};
use bitcoin::blockdata::transaction::{Transaction, EcdsaSighashType};
use bitcoin::util::sighash;
use bitcoin::secp256k1::{Secp256k1,ecdsa::Signature};
use bitcoin::secp256k1;
-use crate::ln::{PaymentPreimage, PaymentHash};
+use crate::ln::{ChannelId, PaymentPreimage, PaymentHash};
use crate::ln::features::{ChannelTypeFeatures, InitFeatures};
use crate::ln::msgs;
use crate::ln::msgs::DecodeError;
use crate::chain::chaininterface::{FeeEstimator, ConfirmationTarget, LowerBoundedFeeEstimator};
use crate::chain::channelmonitor::{ChannelMonitor, ChannelMonitorUpdate, ChannelMonitorUpdateStep, LATENCY_GRACE_PERIOD_BLOCKS, CLOSED_CHANNEL_UPDATE_ID};
use crate::chain::transaction::{OutPoint, TransactionData};
-use crate::sign::{WriteableEcdsaChannelSigner, EntropySource, ChannelSigner, SignerProvider, NodeSigner, Recipient};
+use crate::sign::{EcdsaChannelSigner, WriteableEcdsaChannelSigner, EntropySource, ChannelSigner, SignerProvider, NodeSigner, Recipient};
use crate::events::ClosureReason;
use crate::routing::gossip::NodeId;
-use crate::util::ser::{Readable, ReadableArgs, Writeable, Writer, VecWriter};
+use crate::util::ser::{Readable, ReadableArgs, Writeable, Writer};
use crate::util::logger::Logger;
use crate::util::errors::APIError;
use crate::util::config::{UserConfig, ChannelConfig, LegacyChannelConfig, ChannelHandshakeConfig, ChannelHandshakeLimits, MaxDustHTLCExposure};
use crate::io;
use crate::prelude::*;
use core::{cmp,mem,fmt};
+use core::convert::TryInto;
use core::ops::Deref;
#[cfg(any(test, fuzzing, debug_assertions))]
use crate::sync::Mutex;
use bitcoin::hashes::hex::ToHex;
+use crate::sign::type_resolver::ChannelSignerType;
#[cfg(test)]
pub struct ChannelValueStat {
}
pub struct AvailableBalances {
+ /// The amount that would go to us if we close the channel, ignoring any on-chain fees.
+ pub balance_msat: u64,
/// Total amount available for our counterparty to send to us.
pub inbound_capacity_msat: u64,
/// Total amount available for us to send to our counterparty.
/// We've successfully negotiated a closing_signed dance. At this point ChannelManager is about
/// to drop us, but we store this anyway.
ShutdownComplete = 4096,
+ /// Flag which is set on `FundingSent` to indicate this channel is funded in a batch and the
+ /// broadcasting of the funding transaction is being held until all channels in the batch
+ /// have received funding_signed and have their monitors persisted.
+ WaitingForBatch = 1 << 13,
}
-const BOTH_SIDES_SHUTDOWN_MASK: u32 = ChannelState::LocalShutdownSent as u32 | ChannelState::RemoteShutdownSent as u32;
-const MULTI_STATE_FLAGS: u32 = BOTH_SIDES_SHUTDOWN_MASK | ChannelState::PeerDisconnected as u32 | ChannelState::MonitorUpdateInProgress as u32;
+const BOTH_SIDES_SHUTDOWN_MASK: u32 =
+ ChannelState::LocalShutdownSent as u32 |
+ ChannelState::RemoteShutdownSent as u32;
+const MULTI_STATE_FLAGS: u32 =
+ BOTH_SIDES_SHUTDOWN_MASK |
+ ChannelState::PeerDisconnected as u32 |
+ ChannelState::MonitorUpdateInProgress as u32;
+const STATE_FLAGS: u32 =
+ MULTI_STATE_FLAGS |
+ ChannelState::TheirChannelReady as u32 |
+ ChannelState::OurChannelReady as u32 |
+ ChannelState::AwaitingRemoteRevoke as u32 |
+ ChannelState::WaitingForBatch as u32;
pub const INITIAL_COMMITMENT_NUMBER: u64 = (1 << 48) - 1;
pub announcement_sigs: Option<msgs::AnnouncementSignatures>,
}
+/// The return value of `signer_maybe_unblocked`
+#[allow(unused)]
+pub(super) struct SignerResumeUpdates {
+ pub commitment_update: Option<msgs::CommitmentUpdate>,
+ pub funding_signed: Option<msgs::FundingSigned>,
+ pub funding_created: Option<msgs::FundingCreated>,
+ pub channel_ready: Option<msgs::ChannelReady>,
+}
+
/// The return value of `channel_reestablish`
pub(super) struct ReestablishResponses {
pub channel_ready: Option<msgs::ChannelReady>,
pub shutdown_msg: Option<msgs::Shutdown>,
}
-/// The return type of `force_shutdown`
-///
-/// Contains a (counterparty_node_id, funding_txo, [`ChannelMonitorUpdate`]) tuple
-/// followed by a list of HTLCs to fail back in the form of the (source, payment hash, and this
-/// channel's counterparty_node_id and channel_id).
-pub(crate) type ShutdownResult = (
- Option<(PublicKey, OutPoint, ChannelMonitorUpdate)>,
- Vec<(HTLCSource, PaymentHash, PublicKey, [u8; 32])>
-);
+/// The result of a shutdown that should be handled.
+#[must_use]
+pub(crate) struct ShutdownResult {
+ /// A channel monitor update to apply.
+ pub(crate) monitor_update: Option<(PublicKey, OutPoint, ChannelMonitorUpdate)>,
+ /// A list of dropped outbound HTLCs that can safely be failed backwards immediately.
+ pub(crate) dropped_outbound_htlcs: Vec<(HTLCSource, PaymentHash, PublicKey, ChannelId)>,
+ /// An unbroadcasted batch funding transaction id. The closure of this channel should be
+ /// propagated to the remainder of the batch.
+ pub(crate) unbroadcasted_batch_funding_txid: Option<Txid>,
+}
/// If the majority of the channels funds are to the fundee and the initiator holds only just
/// enough funds to cover their reserve value, channels are at risk of getting "stuck". Because the
/// exceeding this age limit will be force-closed and purged from memory.
pub(crate) const UNFUNDED_CHANNEL_AGE_LIMIT_TICKS: usize = 60;
+/// Number of blocks needed for an output from a coinbase transaction to be spendable.
+pub(crate) const COINBASE_MATURITY: u32 = 100;
+
struct PendingChannelMonitorUpdate {
update: ChannelMonitorUpdate,
}
(0, update, required),
});
+/// The `ChannelPhase` enum describes the current phase in life of a lightning channel with each of
+/// its variants containing an appropriate channel struct.
+pub(super) enum ChannelPhase<SP: Deref> where SP::Target: SignerProvider {
+ UnfundedOutboundV1(OutboundV1Channel<SP>),
+ UnfundedInboundV1(InboundV1Channel<SP>),
+ Funded(Channel<SP>),
+}
+
+impl<'a, SP: Deref> ChannelPhase<SP> where
+ SP::Target: SignerProvider,
+ <SP::Target as SignerProvider>::Signer: ChannelSigner,
+{
+ pub fn context(&'a self) -> &'a ChannelContext<SP> {
+ match self {
+ ChannelPhase::Funded(chan) => &chan.context,
+ ChannelPhase::UnfundedOutboundV1(chan) => &chan.context,
+ ChannelPhase::UnfundedInboundV1(chan) => &chan.context,
+ }
+ }
+
+ pub fn context_mut(&'a mut self) -> &'a mut ChannelContext<SP> {
+ match self {
+ ChannelPhase::Funded(ref mut chan) => &mut chan.context,
+ ChannelPhase::UnfundedOutboundV1(ref mut chan) => &mut chan.context,
+ ChannelPhase::UnfundedInboundV1(ref mut chan) => &mut chan.context,
+ }
+ }
+}
+
/// Contains all state common to unfunded inbound/outbound channels.
pub(super) struct UnfundedChannelContext {
/// A counter tracking how many ticks have elapsed since this unfunded channel was
}
/// Contains everything about the channel including state, and various flags.
-pub(super) struct ChannelContext<Signer: ChannelSigner> {
+pub(super) struct ChannelContext<SP: Deref> where SP::Target: SignerProvider {
config: LegacyChannelConfig,
// Track the previous `ChannelConfig` so that we can continue forwarding HTLCs that were
user_id: u128,
- channel_id: [u8; 32],
- temporary_channel_id: Option<[u8; 32]>, // Will be `None` for channels created prior to 0.0.115.
+ /// The current channel ID.
+ channel_id: ChannelId,
+ /// The temporary channel ID used during channel setup. Value kept even after transitioning to a final channel ID.
+ /// Will be `None` for channels created prior to 0.0.115.
+ temporary_channel_id: Option<ChannelId>,
channel_state: u32,
// When we reach max(6 blocks, minimum_depth), we need to send an AnnouncementSigs message to
latest_monitor_update_id: u64,
- holder_signer: Signer,
+ holder_signer: ChannelSignerType<<SP::Target as SignerProvider>::Signer>,
shutdown_scriptpubkey: Option<ShutdownScript>,
destination_script: Script,
cur_holder_commitment_transaction_number: u64,
cur_counterparty_commitment_transaction_number: u64,
- value_to_self_msat: u64, // Excluding all pending_htlcs, excluding fees
+ value_to_self_msat: u64, // Excluding all pending_htlcs, fees, and anchor outputs
pending_inbound_htlcs: Vec<InboundHTLCOutput>,
pending_outbound_htlcs: Vec<OutboundHTLCOutput>,
holding_cell_htlc_updates: Vec<HTLCUpdateAwaitingACK>,
monitor_pending_failures: Vec<(HTLCSource, PaymentHash, HTLCFailReason)>,
monitor_pending_finalized_fulfills: Vec<HTLCSource>,
+ /// If we went to send a commitment update (ie some messages then [`msgs::CommitmentSigned`])
+ /// but our signer (initially) refused to give us a signature, we should retry at some point in
+ /// the future when the signer indicates it may have a signature for us.
+ ///
+ /// This flag is set in such a case. Note that we don't need to persist this as we'll end up
+ /// setting it again as a side-effect of [`Channel::channel_reestablish`].
+ signer_pending_commitment_update: bool,
+ /// Similar to [`Self::signer_pending_commitment_update`] but we're waiting to send either a
+ /// [`msgs::FundingCreated`] or [`msgs::FundingSigned`] depending on if this channel is
+ /// outbound or inbound.
+ signer_pending_funding: bool,
+
// pending_update_fee is filled when sending and receiving update_fee.
//
// Because it follows the same commitment flow as HTLCs, `FeeUpdateState` is either `Outbound`
pub(crate) channel_transaction_parameters: ChannelTransactionParameters,
funding_transaction: Option<Transaction>,
+ is_batch_funding: Option<()>,
counterparty_cur_commitment_point: Option<PublicKey>,
counterparty_prev_commitment_point: Option<PublicKey>,
blocked_monitor_updates: Vec<PendingChannelMonitorUpdate>,
}
-impl<Signer: ChannelSigner> ChannelContext<Signer> {
+impl<SP: Deref> ChannelContext<SP> where SP::Target: SignerProvider {
/// Allowed in any state (including after shutdown)
pub fn get_update_time_counter(&self) -> u32 {
self.update_time_counter
/// Returns true if we've ever received a message from the remote end for this Channel
pub fn have_received_message(&self) -> bool {
- self.channel_state > (ChannelState::OurInitSent as u32)
+ self.channel_state & !STATE_FLAGS > (ChannelState::OurInitSent as u32)
}
/// Returns true if this channel is fully established and not known to be closing.
// Public utilities:
- pub fn channel_id(&self) -> [u8; 32] {
+ pub fn channel_id(&self) -> ChannelId {
self.channel_id
}
// Return the `temporary_channel_id` used during channel establishment.
//
// Will return `None` for channels created prior to LDK version 0.0.115.
- pub fn temporary_channel_id(&self) -> Option<[u8; 32]> {
+ pub fn temporary_channel_id(&self) -> Option<ChannelId> {
self.temporary_channel_id
}
self.outbound_scid_alias
}
+ /// Returns the holder signer for this channel.
+ #[cfg(test)]
+ pub fn get_signer(&self) -> &ChannelSignerType<<SP::Target as SignerProvider>::Signer> {
+ return &self.holder_signer
+ }
+
/// Only allowed immediately after deserialization if get_outbound_scid_alias returns 0,
/// indicating we were written by LDK prior to 0.0.106 which did not set outbound SCID aliases
/// or prior to any channel actions during `Channel` initialization.
match self.config.options.max_dust_htlc_exposure {
MaxDustHTLCExposure::FeeRateMultiplier(multiplier) => {
let feerate_per_kw = fee_estimator.bounded_sat_per_1000_weight(
- ConfirmationTarget::HighPriority);
- feerate_per_kw as u64 * multiplier
+ ConfirmationTarget::OnChainSweep) as u64;
+ feerate_per_kw.saturating_mul(multiplier)
},
MaxDustHTLCExposure::FixedLimitMsat(limit) => limit,
}
// Checks whether we should emit a `ChannelPending` event.
pub(crate) fn should_emit_channel_pending_event(&mut self) -> bool {
- self.is_funding_initiated() && !self.channel_pending_event_emitted
+ self.is_funding_broadcast() && !self.channel_pending_event_emitted
}
// Returns whether we already emitted a `ChannelPending` event.
did_channel_update
}
- /// Returns true if funding_created was sent/received.
- pub fn is_funding_initiated(&self) -> bool {
- self.channel_state >= ChannelState::FundingSent as u32
+ /// Returns true if funding_signed was sent/received and the
+ /// funding transaction has been broadcast if necessary.
+ pub fn is_funding_broadcast(&self) -> bool {
+ self.channel_state & !STATE_FLAGS >= ChannelState::FundingSent as u32 &&
+ self.channel_state & ChannelState::WaitingForBatch as u32 == 0
}
/// Transaction nomenclature is somewhat confusing here as there are many different cases - a
log_trace!(logger, "Building commitment transaction number {} (really {} xor {}) for channel {} for {}, generated by {} with fee {}...",
commitment_number, (INITIAL_COMMITMENT_NUMBER - commitment_number),
get_commitment_transaction_number_obscure_factor(&self.get_holder_pubkeys().payment_point, &self.get_counterparty_pubkeys().payment_point, self.is_outbound()),
- log_bytes!(self.channel_id), if local { "us" } else { "remote" }, if generated_by_local { "us" } else { "remote" }, feerate_per_kw);
+ &self.channel_id,
+ if local { "us" } else { "remote" }, if generated_by_local { "us" } else { "remote" }, feerate_per_kw);
macro_rules! get_htlc_in_commitment {
($htlc: expr, $offered: expr) => {
feerate_per_kw as u64 * htlc_timeout_tx_weight(self.get_channel_type()) / 1000
};
if $htlc.amount_msat / 1000 >= broadcaster_dust_limit_satoshis + htlc_tx_fee {
- log_trace!(logger, " ...including {} {} HTLC {} (hash {}) with value {}", if $outbound { "outbound" } else { "inbound" }, $state_name, $htlc.htlc_id, log_bytes!($htlc.payment_hash.0), $htlc.amount_msat);
+ log_trace!(logger, " ...including {} {} HTLC {} (hash {}) with value {}", if $outbound { "outbound" } else { "inbound" }, $state_name, $htlc.htlc_id, &$htlc.payment_hash, $htlc.amount_msat);
included_non_dust_htlcs.push((htlc_in_tx, $source));
} else {
- log_trace!(logger, " ...including {} {} dust HTLC {} (hash {}) with value {} due to dust limit", if $outbound { "outbound" } else { "inbound" }, $state_name, $htlc.htlc_id, log_bytes!($htlc.payment_hash.0), $htlc.amount_msat);
+ log_trace!(logger, " ...including {} {} dust HTLC {} (hash {}) with value {} due to dust limit", if $outbound { "outbound" } else { "inbound" }, $state_name, $htlc.htlc_id, &$htlc.payment_hash, $htlc.amount_msat);
included_dust_htlcs.push((htlc_in_tx, $source));
}
} else {
feerate_per_kw as u64 * htlc_success_tx_weight(self.get_channel_type()) / 1000
};
if $htlc.amount_msat / 1000 >= broadcaster_dust_limit_satoshis + htlc_tx_fee {
- log_trace!(logger, " ...including {} {} HTLC {} (hash {}) with value {}", if $outbound { "outbound" } else { "inbound" }, $state_name, $htlc.htlc_id, log_bytes!($htlc.payment_hash.0), $htlc.amount_msat);
+ log_trace!(logger, " ...including {} {} HTLC {} (hash {}) with value {}", if $outbound { "outbound" } else { "inbound" }, $state_name, $htlc.htlc_id, &$htlc.payment_hash, $htlc.amount_msat);
included_non_dust_htlcs.push((htlc_in_tx, $source));
} else {
- log_trace!(logger, " ...including {} {} dust HTLC {} (hash {}) with value {}", if $outbound { "outbound" } else { "inbound" }, $state_name, $htlc.htlc_id, log_bytes!($htlc.payment_hash.0), $htlc.amount_msat);
+ log_trace!(logger, " ...including {} {} dust HTLC {} (hash {}) with value {}", if $outbound { "outbound" } else { "inbound" }, $state_name, $htlc.htlc_id, &$htlc.payment_hash, $htlc.amount_msat);
included_dust_htlcs.push((htlc_in_tx, $source));
}
}
add_htlc_output!(htlc, false, None, state_name);
remote_htlc_total_msat += htlc.amount_msat;
} else {
- log_trace!(logger, " ...not including inbound HTLC {} (hash {}) with value {} due to state ({})", htlc.htlc_id, log_bytes!(htlc.payment_hash.0), htlc.amount_msat, state_name);
+ log_trace!(logger, " ...not including inbound HTLC {} (hash {}) with value {} due to state ({})", htlc.htlc_id, &htlc.payment_hash, htlc.amount_msat, state_name);
match &htlc.state {
&InboundHTLCState::LocalRemoved(ref reason) => {
if generated_by_local {
add_htlc_output!(htlc, true, Some(&htlc.source), state_name);
local_htlc_total_msat += htlc.amount_msat;
} else {
- log_trace!(logger, " ...not including outbound HTLC {} (hash {}) with value {} due to state ({})", htlc.htlc_id, log_bytes!(htlc.payment_hash.0), htlc.amount_msat, state_name);
+ log_trace!(logger, " ...not including outbound HTLC {} (hash {}) with value {} due to state ({})", htlc.htlc_id, &htlc.payment_hash, htlc.amount_msat, state_name);
match htlc.state {
OutboundHTLCState::AwaitingRemoteRevokeToRemove(OutboundHTLCOutcome::Success(_))|OutboundHTLCState::AwaitingRemovedRemoteRevoke(OutboundHTLCOutcome::Success(_)) => {
value_to_self_msat_offset -= htlc.amount_msat as i64;
/// The result is a transaction which we can revoke broadcastership of (ie a "local" transaction)
/// TODO Some magic rust shit to compile-time check this?
fn build_holder_transaction_keys(&self, commitment_number: u64) -> TxCreationKeys {
- let per_commitment_point = self.holder_signer.get_per_commitment_point(commitment_number, &self.secp_ctx);
+ let per_commitment_point = self.holder_signer.as_ref().get_per_commitment_point(commitment_number, &self.secp_ctx);
let delayed_payment_base = &self.get_holder_pubkeys().delayed_payment_basepoint;
let htlc_basepoint = &self.get_holder_pubkeys().htlc_basepoint;
let counterparty_pubkeys = self.get_counterparty_pubkeys();
let inbound_stats = context.get_inbound_pending_htlc_stats(None);
let outbound_stats = context.get_outbound_pending_htlc_stats(None);
+ let mut balance_msat = context.value_to_self_msat;
+ for ref htlc in context.pending_inbound_htlcs.iter() {
+ if let InboundHTLCState::LocalRemoved(InboundHTLCRemovalReason::Fulfill(_)) = htlc.state {
+ balance_msat += htlc.amount_msat;
+ }
+ }
+ balance_msat -= outbound_stats.pending_htlcs_value_msat;
+
let outbound_capacity_msat = context.value_to_self_msat
.saturating_sub(outbound_stats.pending_htlcs_value_msat)
.saturating_sub(
let mut available_capacity_msat = outbound_capacity_msat;
+ let anchor_outputs_value_msat = if context.get_channel_type().supports_anchors_zero_fee_htlc_tx() {
+ ANCHOR_OUTPUT_VALUE_SATOSHI * 2 * 1000
+ } else {
+ 0
+ };
if context.is_outbound() {
// We should mind channel commit tx fee when computing how much of the available capacity
// can be used in the next htlc. Mirrors the logic in send_htlc.
}
let htlc_above_dust = HTLCCandidate::new(real_dust_limit_timeout_sat * 1000, HTLCInitiator::LocalOffered);
- let max_reserved_commit_tx_fee_msat = FEE_SPIKE_BUFFER_FEE_INCREASE_MULTIPLE * context.next_local_commit_tx_fee_msat(htlc_above_dust, Some(()));
+ let mut max_reserved_commit_tx_fee_msat = context.next_local_commit_tx_fee_msat(htlc_above_dust, Some(()));
let htlc_dust = HTLCCandidate::new(real_dust_limit_timeout_sat * 1000 - 1, HTLCInitiator::LocalOffered);
- let min_reserved_commit_tx_fee_msat = FEE_SPIKE_BUFFER_FEE_INCREASE_MULTIPLE * context.next_local_commit_tx_fee_msat(htlc_dust, Some(()));
+ let mut min_reserved_commit_tx_fee_msat = context.next_local_commit_tx_fee_msat(htlc_dust, Some(()));
+ if !context.get_channel_type().supports_anchors_zero_fee_htlc_tx() {
+ max_reserved_commit_tx_fee_msat *= FEE_SPIKE_BUFFER_FEE_INCREASE_MULTIPLE;
+ min_reserved_commit_tx_fee_msat *= FEE_SPIKE_BUFFER_FEE_INCREASE_MULTIPLE;
+ }
// We will first subtract the fee as if we were above-dust. Then, if the resulting
// value ends up being below dust, we have this fee available again. In that case,
// match the value to right-below-dust.
- let mut capacity_minus_commitment_fee_msat: i64 = (available_capacity_msat as i64) - (max_reserved_commit_tx_fee_msat as i64);
+ let mut capacity_minus_commitment_fee_msat: i64 = available_capacity_msat as i64 -
+ max_reserved_commit_tx_fee_msat as i64 - anchor_outputs_value_msat as i64;
if capacity_minus_commitment_fee_msat < (real_dust_limit_timeout_sat as i64) * 1000 {
let one_htlc_difference_msat = max_reserved_commit_tx_fee_msat - min_reserved_commit_tx_fee_msat;
debug_assert!(one_htlc_difference_msat != 0);
let remote_balance_msat = (context.channel_value_satoshis * 1000 - context.value_to_self_msat)
.saturating_sub(inbound_stats.pending_htlcs_value_msat);
- if remote_balance_msat < max_reserved_commit_tx_fee_msat + holder_selected_chan_reserve_msat {
+ if remote_balance_msat < max_reserved_commit_tx_fee_msat + holder_selected_chan_reserve_msat + anchor_outputs_value_msat {
// If another HTLC's fee would reduce the remote's balance below the reserve limit
// we've selected for them, we can only send dust HTLCs.
available_capacity_msat = cmp::min(available_capacity_msat, real_dust_limit_success_sat * 1000 - 1);
context.holder_dust_limit_satoshis + dust_buffer_feerate * htlc_timeout_tx_weight(context.get_channel_type()) / 1000)
};
let on_counterparty_dust_htlc_exposure_msat = inbound_stats.on_counterparty_tx_dust_exposure_msat + outbound_stats.on_counterparty_tx_dust_exposure_msat;
- if on_counterparty_dust_htlc_exposure_msat as i64 + htlc_success_dust_limit as i64 * 1000 - 1 > max_dust_htlc_exposure_msat as i64 {
+ if on_counterparty_dust_htlc_exposure_msat as i64 + htlc_success_dust_limit as i64 * 1000 - 1 > max_dust_htlc_exposure_msat.try_into().unwrap_or(i64::max_value()) {
remaining_msat_below_dust_exposure_limit =
Some(max_dust_htlc_exposure_msat.saturating_sub(on_counterparty_dust_htlc_exposure_msat));
dust_exposure_dust_limit_msat = cmp::max(dust_exposure_dust_limit_msat, htlc_success_dust_limit * 1000);
}
let on_holder_dust_htlc_exposure_msat = inbound_stats.on_holder_tx_dust_exposure_msat + outbound_stats.on_holder_tx_dust_exposure_msat;
- if on_holder_dust_htlc_exposure_msat as i64 + htlc_timeout_dust_limit as i64 * 1000 - 1 > max_dust_htlc_exposure_msat as i64 {
+ if on_holder_dust_htlc_exposure_msat as i64 + htlc_timeout_dust_limit as i64 * 1000 - 1 > max_dust_htlc_exposure_msat.try_into().unwrap_or(i64::max_value()) {
remaining_msat_below_dust_exposure_limit = Some(cmp::min(
remaining_msat_below_dust_exposure_limit.unwrap_or(u64::max_value()),
max_dust_htlc_exposure_msat.saturating_sub(on_holder_dust_htlc_exposure_msat)));
outbound_capacity_msat,
next_outbound_htlc_limit_msat: available_capacity_msat,
next_outbound_htlc_minimum_msat,
+ balance_msat,
}
}
res
}
- /// Returns transaction if there is pending funding transaction that is yet to broadcast
- pub fn unbroadcasted_funding(&self) -> Option<Transaction> {
- if self.channel_state & (ChannelState::FundingCreated as u32) != 0 {
- self.funding_transaction.clone()
+ fn if_unbroadcasted_funding<F, O>(&self, f: F) -> Option<O>
+ where F: Fn() -> Option<O> {
+ if self.channel_state & ChannelState::FundingCreated as u32 != 0 ||
+ self.channel_state & ChannelState::WaitingForBatch as u32 != 0 {
+ f()
} else {
None
}
}
+ /// Returns the transaction if there is a pending funding transaction that is yet to be
+ /// broadcast.
+ pub fn unbroadcasted_funding(&self) -> Option<Transaction> {
+ self.if_unbroadcasted_funding(|| self.funding_transaction.clone())
+ }
+
+ /// Returns the transaction ID if there is a pending funding transaction that is yet to be
+ /// broadcast.
+ pub fn unbroadcasted_funding_txid(&self) -> Option<Txid> {
+ self.if_unbroadcasted_funding(||
+ self.channel_transaction_parameters.funding_outpoint.map(|txo| txo.txid)
+ )
+ }
+
+ /// Returns whether the channel is funded in a batch.
+ pub fn is_batch_funding(&self) -> bool {
+ self.is_batch_funding.is_some()
+ }
+
+ /// Returns the transaction ID if there is a pending batch funding transaction that is yet to be
+ /// broadcast.
+ pub fn unbroadcasted_batch_funding_txid(&self) -> Option<Txid> {
+ self.unbroadcasted_funding_txid().filter(|_| self.is_batch_funding())
+ }
+
/// Gets the latest commitment transaction and any dependent transactions for relay (forcing
/// shutdown of this channel - no more calls into this Channel may be made afterwards except
/// those explicitly stated to be allowed after shutdown completes, eg some simple getters).
}))
} else { None }
} else { None };
+ let unbroadcasted_batch_funding_txid = self.unbroadcasted_batch_funding_txid();
self.channel_state = ChannelState::ShutdownComplete as u32;
self.update_time_counter += 1;
- (monitor_update, dropped_outbound_htlcs)
+ ShutdownResult {
+ monitor_update,
+ dropped_outbound_htlcs,
+ unbroadcasted_batch_funding_txid,
+ }
+ }
+
+ /// Only allowed after [`Self::channel_transaction_parameters`] is set.
+ fn get_funding_created_msg<L: Deref>(&mut self, logger: &L) -> Option<msgs::FundingCreated> where L::Target: Logger {
+ let counterparty_keys = self.build_remote_transaction_keys();
+ let counterparty_initial_commitment_tx = self.build_commitment_transaction(self.cur_counterparty_commitment_transaction_number, &counterparty_keys, false, false, logger).tx;
+ let signature = match &self.holder_signer {
+ // TODO (taproot|arik): move match into calling method for Taproot
+ ChannelSignerType::Ecdsa(ecdsa) => {
+ ecdsa.sign_counterparty_commitment(&counterparty_initial_commitment_tx, Vec::new(), &self.secp_ctx)
+ .map(|(sig, _)| sig).ok()?
+ }
+ };
+
+ if self.signer_pending_funding {
+ log_trace!(logger, "Counterparty commitment signature ready for funding_created message: clearing signer_pending_funding");
+ self.signer_pending_funding = false;
+ }
+
+ Some(msgs::FundingCreated {
+ temporary_channel_id: self.temporary_channel_id.unwrap(),
+ funding_txid: self.channel_transaction_parameters.funding_outpoint.as_ref().unwrap().txid,
+ funding_output_index: self.channel_transaction_parameters.funding_outpoint.as_ref().unwrap().index,
+ signature,
+ #[cfg(taproot)]
+ partial_signature_with_nonce: None,
+ #[cfg(taproot)]
+ next_local_nonce: None,
+ })
+ }
+
+ /// Only allowed after [`Self::channel_transaction_parameters`] is set.
+ fn get_funding_signed_msg<L: Deref>(&mut self, logger: &L) -> (CommitmentTransaction, Option<msgs::FundingSigned>) where L::Target: Logger {
+ let counterparty_keys = self.build_remote_transaction_keys();
+ let counterparty_initial_commitment_tx = self.build_commitment_transaction(self.cur_counterparty_commitment_transaction_number + 1, &counterparty_keys, false, false, logger).tx;
+
+ let counterparty_trusted_tx = counterparty_initial_commitment_tx.trust();
+ let counterparty_initial_bitcoin_tx = counterparty_trusted_tx.built_transaction();
+ log_trace!(logger, "Initial counterparty tx for channel {} is: txid {} tx {}",
+ &self.channel_id(), counterparty_initial_bitcoin_tx.txid, encode::serialize_hex(&counterparty_initial_bitcoin_tx.transaction));
+
+ match &self.holder_signer {
+ // TODO (arik): move match into calling method for Taproot
+ ChannelSignerType::Ecdsa(ecdsa) => {
+ let funding_signed = ecdsa.sign_counterparty_commitment(&counterparty_initial_commitment_tx, Vec::new(), &self.secp_ctx)
+ .map(|(signature, _)| msgs::FundingSigned {
+ channel_id: self.channel_id(),
+ signature,
+ #[cfg(taproot)]
+ partial_signature_with_nonce: None,
+ })
+ .ok();
+
+ if funding_signed.is_none() {
+ log_trace!(logger, "Counterparty commitment signature not available for funding_signed message; setting signer_pending_funding");
+ self.signer_pending_funding = true;
+ } else if self.signer_pending_funding {
+ log_trace!(logger, "Counterparty commitment signature available for funding_signed message; clearing signer_pending_funding");
+ self.signer_pending_funding = false;
+ }
+
+ // We sign "counterparty" commitment transaction, allowing them to broadcast the tx if they wish.
+ (counterparty_initial_commitment_tx, funding_signed)
+ }
+ }
}
}
// Get the fee cost in MSATS of a commitment tx with a given number of HTLC outputs.
// Note that num_htlcs should not include dust HTLCs.
-fn commit_tx_fee_msat(feerate_per_kw: u32, num_htlcs: usize, channel_type_features: &ChannelTypeFeatures) -> u64 {
+pub(crate) fn commit_tx_fee_msat(feerate_per_kw: u32, num_htlcs: usize, channel_type_features: &ChannelTypeFeatures) -> u64 {
// Note that we need to divide before multiplying to round properly,
// since the lowest denomination of bitcoin on-chain is the satoshi.
(commitment_tx_base_weight(channel_type_features) + num_htlcs as u64 * COMMITMENT_TX_WEIGHT_PER_HTLC) * feerate_per_kw as u64 / 1000 * 1000
}
-// TODO: We should refactor this to be an Inbound/OutboundChannel until initial setup handshaking
-// has been completed, and then turn into a Channel to get compiler-time enforcement of things like
-// calling channel_id() before we're set up or things like get_funding_signed on an
-// inbound channel.
-//
// Holder designates channel data owned for the benefit of the user client.
// Counterparty designates channel data owned by the another channel participant entity.
-pub(super) struct Channel<Signer: ChannelSigner> {
- pub context: ChannelContext<Signer>,
+pub(super) struct Channel<SP: Deref> where SP::Target: SignerProvider {
+ pub context: ChannelContext<SP>,
}
#[cfg(any(test, fuzzing))]
feerate: u32,
}
-impl<Signer: WriteableEcdsaChannelSigner> Channel<Signer> {
+impl<SP: Deref> Channel<SP> where
+ SP::Target: SignerProvider,
+ <SP::Target as SignerProvider>::Signer: WriteableEcdsaChannelSigner
+{
fn check_remote_fee<F: Deref, L: Deref>(
channel_type: &ChannelTypeFeatures, fee_estimator: &LowerBoundedFeeEstimator<F>,
feerate_per_kw: u32, cur_feerate_per_kw: Option<u32>, logger: &L
// apply to channels supporting anchor outputs since HTLC transactions are pre-signed with a
// zero fee, so their fee is no longer considered to determine dust limits.
if !channel_type.supports_anchors_zero_fee_htlc_tx() {
- let upper_limit = cmp::max(250 * 25,
- fee_estimator.bounded_sat_per_1000_weight(ConfirmationTarget::HighPriority) as u64 * 10);
+ let upper_limit =
+ fee_estimator.bounded_sat_per_1000_weight(ConfirmationTarget::MaxAllowedNonAnchorChannelRemoteFee) as u64;
if feerate_per_kw as u64 > upper_limit {
return Err(ChannelError::Close(format!("Peer's feerate much too high. Actual: {}. Our expected upper limit: {}", feerate_per_kw, upper_limit)));
}
}
- // We can afford to use a lower bound with anchors than previously since we can now bump
- // fees when broadcasting our commitment. However, we must still make sure we meet the
- // minimum mempool feerate, until package relay is deployed, such that we can ensure the
- // commitment transaction propagates throughout node mempools on its own.
let lower_limit_conf_target = if channel_type.supports_anchors_zero_fee_htlc_tx() {
- ConfirmationTarget::MempoolMinimum
+ ConfirmationTarget::MinAllowedAnchorChannelRemoteFee
} else {
- ConfirmationTarget::Background
+ ConfirmationTarget::MinAllowedNonAnchorChannelRemoteFee
};
let lower_limit = fee_estimator.bounded_sat_per_1000_weight(lower_limit_conf_target);
- // Some fee estimators round up to the next full sat/vbyte (ie 250 sats per kw), causing
- // occasional issues with feerate disagreements between an initiator that wants a feerate
- // of 1.1 sat/vbyte and a receiver that wants 1.1 rounded up to 2. Thus, we always add 250
- // sat/kw before the comparison here.
- if feerate_per_kw + 250 < lower_limit {
+ if feerate_per_kw < lower_limit {
if let Some(cur_feerate) = cur_feerate_per_kw {
if feerate_per_kw > cur_feerate {
log_warn!(logger,
return Ok(());
}
}
- return Err(ChannelError::Close(format!("Peer's feerate much too low. Actual: {}. Our expected lower limit: {} (- 250)", feerate_per_kw, lower_limit)));
+ return Err(ChannelError::Close(format!("Peer's feerate much too low. Actual: {}. Our expected lower limit: {}", feerate_per_kw, lower_limit)));
}
Ok(())
}
}
assert_eq!(self.context.channel_state & ChannelState::ShutdownComplete as u32, 0);
- let payment_hash_calc = PaymentHash(Sha256::hash(&payment_preimage_arg.0[..]).into_inner());
-
// ChannelManager may generate duplicate claims/fails due to HTLC update events from
// on-chain ChannelsMonitors during block rescan. Ideally we'd figure out a way to drop
// these, but for now we just have to treat them as normal.
let mut htlc_value_msat = 0;
for (idx, htlc) in self.context.pending_inbound_htlcs.iter().enumerate() {
if htlc.htlc_id == htlc_id_arg {
- assert_eq!(htlc.payment_hash, payment_hash_calc);
+ debug_assert_eq!(htlc.payment_hash, PaymentHash(Sha256::hash(&payment_preimage_arg.0[..]).into_inner()));
+ log_debug!(logger, "Claiming inbound HTLC id {} with payment hash {} with preimage {}",
+ htlc.htlc_id, htlc.payment_hash, payment_preimage_arg);
match htlc.state {
InboundHTLCState::Committed => {},
InboundHTLCState::LocalRemoved(ref reason) => {
if let &InboundHTLCRemovalReason::Fulfill(_) = reason {
} else {
- log_warn!(logger, "Have preimage and want to fulfill HTLC with payment hash {} we already failed against channel {}", log_bytes!(htlc.payment_hash.0), log_bytes!(self.context.channel_id()));
+ log_warn!(logger, "Have preimage and want to fulfill HTLC with payment hash {} we already failed against channel {}", &htlc.payment_hash, &self.context.channel_id());
debug_assert!(false, "Tried to fulfill an HTLC that was already failed");
}
return UpdateFulfillFetch::DuplicateClaim {};
},
&HTLCUpdateAwaitingACK::FailHTLC { htlc_id, .. } => {
if htlc_id_arg == htlc_id {
- log_warn!(logger, "Have preimage and want to fulfill HTLC with pending failure against channel {}", log_bytes!(self.context.channel_id()));
+ log_warn!(logger, "Have preimage and want to fulfill HTLC with pending failure against channel {}", &self.context.channel_id());
// TODO: We may actually be able to switch to a fulfill here, though its
// rare enough it may not be worth the complexity burden.
debug_assert!(false, "Tried to fulfill an HTLC that was already failed");
_ => {}
}
}
- log_trace!(logger, "Adding HTLC claim to holding_cell in channel {}! Current state: {}", log_bytes!(self.context.channel_id()), self.context.channel_state);
+ log_trace!(logger, "Adding HTLC claim to holding_cell in channel {}! Current state: {}", &self.context.channel_id(), self.context.channel_state);
self.context.holding_cell_htlc_updates.push(HTLCUpdateAwaitingACK::ClaimHTLC {
payment_preimage: payment_preimage_arg, htlc_id: htlc_id_arg,
});
debug_assert!(false, "Have an inbound HTLC we tried to claim before it was fully committed to");
return UpdateFulfillFetch::NewClaim { monitor_update, htlc_value_msat, msg: None };
}
- log_trace!(logger, "Upgrading HTLC {} to LocalRemoved with a Fulfill in channel {}!", log_bytes!(htlc.payment_hash.0), log_bytes!(self.context.channel_id));
+ log_trace!(logger, "Upgrading HTLC {} to LocalRemoved with a Fulfill in channel {}!", &htlc.payment_hash, &self.context.channel_id);
htlc.state = InboundHTLCState::LocalRemoved(InboundHTLCRemovalReason::Fulfill(payment_preimage_arg.clone()));
}
_ => {}
}
}
- log_trace!(logger, "Placing failure for HTLC ID {} in holding cell in channel {}.", htlc_id_arg, log_bytes!(self.context.channel_id()));
+ log_trace!(logger, "Placing failure for HTLC ID {} in holding cell in channel {}.", htlc_id_arg, &self.context.channel_id());
self.context.holding_cell_htlc_updates.push(HTLCUpdateAwaitingACK::FailHTLC {
htlc_id: htlc_id_arg,
err_packet,
return Ok(None);
}
- log_trace!(logger, "Failing HTLC ID {} back with a update_fail_htlc message in channel {}.", htlc_id_arg, log_bytes!(self.context.channel_id()));
+ log_trace!(logger, "Failing HTLC ID {} back with a update_fail_htlc message in channel {}.", htlc_id_arg, &self.context.channel_id());
{
let htlc = &mut self.context.pending_inbound_htlcs[pending_idx];
htlc.state = InboundHTLCState::LocalRemoved(InboundHTLCRemovalReason::FailRelay(err_packet.clone()));
/// Handles a funding_signed message from the remote end.
/// If this call is successful, broadcast the funding transaction (and not before!)
- pub fn funding_signed<SP: Deref, L: Deref>(
+ pub fn funding_signed<L: Deref>(
&mut self, msg: &msgs::FundingSigned, best_block: BestBlock, signer_provider: &SP, logger: &L
- ) -> Result<ChannelMonitor<Signer>, ChannelError>
+ ) -> Result<ChannelMonitor<<SP::Target as SignerProvider>::Signer>, ChannelError>
where
- SP::Target: SignerProvider<Signer = Signer>,
L::Target: Logger
{
if !self.context.is_outbound() {
let counterparty_initial_bitcoin_tx = counterparty_trusted_tx.built_transaction();
log_trace!(logger, "Initial counterparty tx for channel {} is: txid {} tx {}",
- log_bytes!(self.context.channel_id()), counterparty_initial_bitcoin_tx.txid, encode::serialize_hex(&counterparty_initial_bitcoin_tx.transaction));
+ &self.context.channel_id(), counterparty_initial_bitcoin_tx.txid, encode::serialize_hex(&counterparty_initial_bitcoin_tx.transaction));
let holder_signer = self.context.build_holder_transaction_keys(self.context.cur_holder_commitment_transaction_number);
let initial_commitment_tx = self.context.build_commitment_transaction(self.context.cur_holder_commitment_transaction_number, &holder_signer, true, false, logger).tx;
self.context.counterparty_funding_pubkey()
);
- self.context.holder_signer.validate_holder_commitment(&holder_commitment_tx, Vec::new())
+ self.context.holder_signer.as_ref().validate_holder_commitment(&holder_commitment_tx, Vec::new())
.map_err(|_| ChannelError::Close("Failed to validate our commitment".to_owned()))?;
obscure_factor,
holder_commitment_tx, best_block, self.context.counterparty_node_id);
- channel_monitor.provide_latest_counterparty_commitment_tx(counterparty_initial_bitcoin_tx.txid, Vec::new(), self.context.cur_counterparty_commitment_transaction_number, self.context.counterparty_cur_commitment_point.unwrap(), logger);
+ channel_monitor.provide_initial_counterparty_commitment_tx(
+ counterparty_initial_bitcoin_tx.txid, Vec::new(),
+ self.context.cur_counterparty_commitment_transaction_number,
+ self.context.counterparty_cur_commitment_point.unwrap(),
+ counterparty_initial_commitment_tx.feerate_per_kw(),
+ counterparty_initial_commitment_tx.to_broadcaster_value_sat(),
+ counterparty_initial_commitment_tx.to_countersignatory_value_sat(), logger);
assert_eq!(self.context.channel_state & (ChannelState::MonitorUpdateInProgress as u32), 0); // We have no had any monitor(s) yet to fail update!
- self.context.channel_state = ChannelState::FundingSent as u32;
+ if self.context.is_batch_funding() {
+ self.context.channel_state = ChannelState::FundingSent as u32 | ChannelState::WaitingForBatch as u32;
+ } else {
+ self.context.channel_state = ChannelState::FundingSent as u32;
+ }
self.context.cur_holder_commitment_transaction_number -= 1;
self.context.cur_counterparty_commitment_transaction_number -= 1;
- log_info!(logger, "Received funding_signed from peer for channel {}", log_bytes!(self.context.channel_id()));
+ log_info!(logger, "Received funding_signed from peer for channel {}", &self.context.channel_id());
let need_channel_ready = self.check_get_channel_ready(0).is_some();
self.monitor_updating_paused(false, false, need_channel_ready, Vec::new(), Vec::new(), Vec::new());
Ok(channel_monitor)
}
+ /// Updates the state of the channel to indicate that all channels in the batch have received
+ /// funding_signed and persisted their monitors.
+ /// The funding transaction is consequently allowed to be broadcast, and the channel can be
+ /// treated as a non-batch channel going forward.
+ pub fn set_batch_ready(&mut self) {
+ self.context.is_batch_funding = None;
+ self.context.channel_state &= !(ChannelState::WaitingForBatch as u32);
+ }
+
/// Handles a channel_ready message from our peer. If we've already sent our channel_ready
/// and the channel is now usable (and public), this may generate an announcement_signatures to
/// reply with.
pub fn channel_ready<NS: Deref, L: Deref>(
- &mut self, msg: &msgs::ChannelReady, node_signer: &NS, genesis_block_hash: BlockHash,
+ &mut self, msg: &msgs::ChannelReady, node_signer: &NS, chain_hash: ChainHash,
user_config: &UserConfig, best_block: &BestBlock, logger: &L
) -> Result<Option<msgs::AnnouncementSignatures>, ChannelError>
where
let non_shutdown_state = self.context.channel_state & (!MULTI_STATE_FLAGS);
- if non_shutdown_state == ChannelState::FundingSent as u32 {
+ // Our channel_ready shouldn't have been sent if we are waiting for other channels in the
+ // batch, but we can receive channel_ready messages.
+ debug_assert!(
+ non_shutdown_state & ChannelState::OurChannelReady as u32 == 0 ||
+ non_shutdown_state & ChannelState::WaitingForBatch as u32 == 0
+ );
+ if non_shutdown_state & !(ChannelState::WaitingForBatch as u32) == ChannelState::FundingSent as u32 {
self.context.channel_state |= ChannelState::TheirChannelReady as u32;
} else if non_shutdown_state == (ChannelState::FundingSent as u32 | ChannelState::OurChannelReady as u32) {
self.context.channel_state = ChannelState::ChannelReady as u32 | (self.context.channel_state & MULTI_STATE_FLAGS);
self.context.counterparty_prev_commitment_point = self.context.counterparty_cur_commitment_point;
self.context.counterparty_cur_commitment_point = Some(msg.next_per_commitment_point);
- log_info!(logger, "Received channel_ready from peer for channel {}", log_bytes!(self.context.channel_id()));
+ log_info!(logger, "Received channel_ready from peer for channel {}", &self.context.channel_id());
- Ok(self.get_announcement_sigs(node_signer, genesis_block_hash, user_config, best_block.height(), logger))
+ Ok(self.get_announcement_sigs(node_signer, chain_hash, user_config, best_block.height(), logger))
}
pub fn update_add_htlc<F, FE: Deref, L: Deref>(
if inbound_stats.pending_htlcs_value_msat + msg.amount_msat > self.context.holder_max_htlc_value_in_flight_msat {
return Err(ChannelError::Close(format!("Remote HTLC add would put them over our max HTLC value ({})", self.context.holder_max_htlc_value_in_flight_msat)));
}
+
// Check holder_selected_channel_reserve_satoshis (we're getting paid, so they have to at least meet
// the reserve_satoshis we told them to always have as direct payment so that they lose
// something if we punish them for broadcasting an old state).
// Check that the remote can afford to pay for this HTLC on-chain at the current
// feerate_per_kw, while maintaining their channel reserve (as required by the spec).
- let remote_commit_tx_fee_msat = if self.context.is_outbound() { 0 } else {
- let htlc_candidate = HTLCCandidate::new(msg.amount_msat, HTLCInitiator::RemoteOffered);
- self.context.next_remote_commit_tx_fee_msat(htlc_candidate, None) // Don't include the extra fee spike buffer HTLC in calculations
- };
- if pending_remote_value_msat - msg.amount_msat < remote_commit_tx_fee_msat {
- return Err(ChannelError::Close("Remote HTLC add would not leave enough to pay for fees".to_owned()));
- };
-
- if pending_remote_value_msat - msg.amount_msat - remote_commit_tx_fee_msat < self.context.holder_selected_channel_reserve_satoshis * 1000 {
- return Err(ChannelError::Close("Remote HTLC add would put them under remote reserve value".to_owned()));
+ {
+ let remote_commit_tx_fee_msat = if self.context.is_outbound() { 0 } else {
+ let htlc_candidate = HTLCCandidate::new(msg.amount_msat, HTLCInitiator::RemoteOffered);
+ self.context.next_remote_commit_tx_fee_msat(htlc_candidate, None) // Don't include the extra fee spike buffer HTLC in calculations
+ };
+ let anchor_outputs_value_msat = if !self.context.is_outbound() && self.context.get_channel_type().supports_anchors_zero_fee_htlc_tx() {
+ ANCHOR_OUTPUT_VALUE_SATOSHI * 2 * 1000
+ } else {
+ 0
+ };
+ if pending_remote_value_msat.saturating_sub(msg.amount_msat).saturating_sub(anchor_outputs_value_msat) < remote_commit_tx_fee_msat {
+ return Err(ChannelError::Close("Remote HTLC add would not leave enough to pay for fees".to_owned()));
+ };
+ if pending_remote_value_msat.saturating_sub(msg.amount_msat).saturating_sub(remote_commit_tx_fee_msat).saturating_sub(anchor_outputs_value_msat) < self.context.holder_selected_channel_reserve_satoshis * 1000 {
+ return Err(ChannelError::Close("Remote HTLC add would put them under remote reserve value".to_owned()));
+ }
}
+ let anchor_outputs_value_msat = if self.context.get_channel_type().supports_anchors_zero_fee_htlc_tx() {
+ ANCHOR_OUTPUT_VALUE_SATOSHI * 2 * 1000
+ } else {
+ 0
+ };
if !self.context.is_outbound() {
- // `2 *` and `Some(())` is for the fee spike buffer we keep for the remote. This deviates from
- // the spec because in the spec, the fee spike buffer requirement doesn't exist on the
- // receiver's side, only on the sender's.
- // Note that when we eventually remove support for fee updates and switch to anchor output
- // fees, we will drop the `2 *`, since we no longer be as sensitive to fee spikes. But, keep
- // the extra htlc when calculating the next remote commitment transaction fee as we should
- // still be able to afford adding this HTLC plus one more future HTLC, regardless of being
- // sensitive to fee spikes.
+ // `Some(())` is for the fee spike buffer we keep for the remote. This deviates from
+ // the spec because the fee spike buffer requirement doesn't exist on the receiver's
+ // side, only on the sender's. Note that with anchor outputs we are no longer as
+ // sensitive to fee spikes, so we need to account for them.
let htlc_candidate = HTLCCandidate::new(msg.amount_msat, HTLCInitiator::RemoteOffered);
- let remote_fee_cost_incl_stuck_buffer_msat = 2 * self.context.next_remote_commit_tx_fee_msat(htlc_candidate, Some(()));
- if pending_remote_value_msat - msg.amount_msat - self.context.holder_selected_channel_reserve_satoshis * 1000 < remote_fee_cost_incl_stuck_buffer_msat {
+ let mut remote_fee_cost_incl_stuck_buffer_msat = self.context.next_remote_commit_tx_fee_msat(htlc_candidate, Some(()));
+ if !self.context.get_channel_type().supports_anchors_zero_fee_htlc_tx() {
+ remote_fee_cost_incl_stuck_buffer_msat *= FEE_SPIKE_BUFFER_FEE_INCREASE_MULTIPLE;
+ }
+ if pending_remote_value_msat.saturating_sub(msg.amount_msat).saturating_sub(self.context.holder_selected_channel_reserve_satoshis * 1000).saturating_sub(anchor_outputs_value_msat) < remote_fee_cost_incl_stuck_buffer_msat {
// Note that if the pending_forward_status is not updated here, then it's because we're already failing
// the HTLC, i.e. its status is already set to failing.
- log_info!(logger, "Attempting to fail HTLC due to fee spike buffer violation in channel {}. Rebalancing is required.", log_bytes!(self.context.channel_id()));
+ log_info!(logger, "Attempting to fail HTLC due to fee spike buffer violation in channel {}. Rebalancing is required.", &self.context.channel_id());
pending_forward_status = create_pending_htlc_status(self, pending_forward_status, 0x1000|7);
}
} else {
// Check that they won't violate our local required channel reserve by adding this HTLC.
let htlc_candidate = HTLCCandidate::new(msg.amount_msat, HTLCInitiator::RemoteOffered);
let local_commit_tx_fee_msat = self.context.next_local_commit_tx_fee_msat(htlc_candidate, None);
- if self.context.value_to_self_msat < self.context.counterparty_selected_channel_reserve_satoshis.unwrap() * 1000 + local_commit_tx_fee_msat {
+ if self.context.value_to_self_msat < self.context.counterparty_selected_channel_reserve_satoshis.unwrap() * 1000 + local_commit_tx_fee_msat + anchor_outputs_value_msat {
return Err(ChannelError::Close("Cannot accept HTLC that would put our balance under counterparty-announced channel reserve value".to_owned()));
}
}
log_trace!(logger, "Checking commitment tx signature {} by key {} against tx {} (sighash {}) with redeemscript {} in channel {}",
log_bytes!(msg.signature.serialize_compact()[..]),
log_bytes!(self.context.counterparty_funding_pubkey().serialize()), encode::serialize_hex(&bitcoin_tx.transaction),
- log_bytes!(sighash[..]), encode::serialize_hex(&funding_script), log_bytes!(self.context.channel_id()));
+ log_bytes!(sighash[..]), encode::serialize_hex(&funding_script), &self.context.channel_id());
if let Err(_) = self.context.secp_ctx.verify_ecdsa(&sighash, &msg.signature, &self.context.counterparty_funding_pubkey()) {
return Err(ChannelError::Close("Invalid commitment tx signature from peer".to_owned()));
}
let htlc_sighash = hash_to_message!(&sighash::SighashCache::new(&htlc_tx).segwit_signature_hash(0, &htlc_redeemscript, htlc.amount_msat / 1000, htlc_sighashtype).unwrap()[..]);
log_trace!(logger, "Checking HTLC tx signature {} by key {} against tx {} (sighash {}) with redeemscript {} in channel {}.",
log_bytes!(msg.htlc_signatures[idx].serialize_compact()[..]), log_bytes!(keys.countersignatory_htlc_key.serialize()),
- encode::serialize_hex(&htlc_tx), log_bytes!(htlc_sighash[..]), encode::serialize_hex(&htlc_redeemscript), log_bytes!(self.context.channel_id()));
+ encode::serialize_hex(&htlc_tx), log_bytes!(htlc_sighash[..]), encode::serialize_hex(&htlc_redeemscript), &self.context.channel_id());
if let Err(_) = self.context.secp_ctx.verify_ecdsa(&htlc_sighash, &msg.htlc_signatures[idx], &keys.countersignatory_htlc_key) {
return Err(ChannelError::Close("Invalid HTLC tx signature from peer".to_owned()));
}
self.context.counterparty_funding_pubkey()
);
- self.context.holder_signer.validate_holder_commitment(&holder_commitment_tx, commitment_stats.preimages)
+ self.context.holder_signer.as_ref().validate_holder_commitment(&holder_commitment_tx, commitment_stats.preimages)
.map_err(|_| ChannelError::Close("Failed to validate our commitment".to_owned()))?;
// Update state now that we've passed all the can-fail calls...
} else { None };
if let Some(forward_info) = new_forward {
log_trace!(logger, "Updating HTLC {} to AwaitingRemoteRevokeToAnnounce due to commitment_signed in channel {}.",
- log_bytes!(htlc.payment_hash.0), log_bytes!(self.context.channel_id));
+ &htlc.payment_hash, &self.context.channel_id);
htlc.state = InboundHTLCState::AwaitingRemoteRevokeToAnnounce(forward_info);
need_commitment = true;
}
for htlc in self.context.pending_outbound_htlcs.iter_mut() {
if let &mut OutboundHTLCState::RemoteRemoved(ref mut outcome) = &mut htlc.state {
log_trace!(logger, "Updating HTLC {} to AwaitingRemoteRevokeToRemove due to commitment_signed in channel {}.",
- log_bytes!(htlc.payment_hash.0), log_bytes!(self.context.channel_id));
+ &htlc.payment_hash, &self.context.channel_id);
// Grab the preimage, if it exists, instead of cloning
let mut reason = OutboundHTLCOutcome::Success(None);
mem::swap(outcome, &mut reason);
self.context.monitor_pending_revoke_and_ack = true;
if need_commitment && (self.context.channel_state & (ChannelState::AwaitingRemoteRevoke as u32)) == 0 {
// If we were going to send a commitment_signed after the RAA, go ahead and do all
- // the corresponding HTLC status updates so that get_last_commitment_update
- // includes the right HTLCs.
+ // the corresponding HTLC status updates so that
+ // get_last_commitment_update_for_send includes the right HTLCs.
self.context.monitor_pending_commitment_signed = true;
let mut additional_update = self.build_commitment_no_status_check(logger);
// build_commitment_no_status_check may bump latest_monitor_id but we want them to be
monitor_update.updates.append(&mut additional_update.updates);
}
log_debug!(logger, "Received valid commitment_signed from peer in channel {}, updated HTLC state but awaiting a monitor update resolution to reply.",
- log_bytes!(self.context.channel_id));
+ &self.context.channel_id);
return Ok(self.push_ret_blockable_mon_update(monitor_update));
}
} else { false };
log_debug!(logger, "Received valid commitment_signed from peer in channel {}, updating HTLC state and responding with{} a revoke_and_ack.",
- log_bytes!(self.context.channel_id()), if need_commitment_signed { " our own commitment_signed and" } else { "" });
+ &self.context.channel_id(), if need_commitment_signed { " our own commitment_signed and" } else { "" });
self.monitor_updating_paused(true, need_commitment_signed, false, Vec::new(), Vec::new(), Vec::new());
return Ok(self.push_ret_blockable_mon_update(monitor_update));
}
) -> (Option<ChannelMonitorUpdate>, Vec<(HTLCSource, PaymentHash)>)
where F::Target: FeeEstimator, L::Target: Logger
{
- if self.context.channel_state >= ChannelState::ChannelReady as u32 &&
+ if self.context.channel_state & !STATE_FLAGS >= ChannelState::ChannelReady as u32 &&
(self.context.channel_state & (ChannelState::AwaitingRemoteRevoke as u32 | ChannelState::PeerDisconnected as u32 | ChannelState::MonitorUpdateInProgress as u32)) == 0 {
self.free_holding_cell_htlcs(fee_estimator, logger)
} else { (None, Vec::new()) }
assert_eq!(self.context.channel_state & ChannelState::MonitorUpdateInProgress as u32, 0);
if self.context.holding_cell_htlc_updates.len() != 0 || self.context.holding_cell_update_fee.is_some() {
log_trace!(logger, "Freeing holding cell with {} HTLC updates{} in channel {}", self.context.holding_cell_htlc_updates.len(),
- if self.context.holding_cell_update_fee.is_some() { " and a fee update" } else { "" }, log_bytes!(self.context.channel_id()));
+ if self.context.holding_cell_update_fee.is_some() { " and a fee update" } else { "" }, &self.context.channel_id());
let mut monitor_update = ChannelMonitorUpdate {
update_id: self.context.latest_monitor_update_id + 1, // We don't increment this yet!
Err(e) => {
match e {
ChannelError::Ignore(ref msg) => {
- log_info!(logger, "Failed to send HTLC with payment_hash {} due to {} in channel {}",
- log_bytes!(payment_hash.0), msg, log_bytes!(self.context.channel_id()));
+ log_info!(logger, "Failed to send HTLC with payment_hash {} due to {} in channel {}", &payment_hash, msg, &self.context.channel_id());
// If we fail to send here, then this HTLC should
// be failed backwards. Failing to send here
// indicates that this HTLC may keep being put back
monitor_update.updates.append(&mut additional_update.updates);
log_debug!(logger, "Freeing holding cell in channel {} resulted in {}{} HTLCs added, {} HTLCs fulfilled, and {} HTLCs failed.",
- log_bytes!(self.context.channel_id()), if update_fee.is_some() { "a fee update, " } else { "" },
+ &self.context.channel_id(), if update_fee.is_some() { "a fee update, " } else { "" },
update_add_count, update_fulfill_count, update_fail_count);
self.monitor_updating_paused(false, true, false, Vec::new(), Vec::new(), Vec::new());
*self.context.next_remote_commitment_tx_fee_info_cached.lock().unwrap() = None;
}
- self.context.holder_signer.validate_counterparty_revocation(
- self.context.cur_counterparty_commitment_transaction_number + 1,
- &secret
- ).map_err(|_| ChannelError::Close("Failed to validate revocation from peer".to_owned()))?;
+ match &self.context.holder_signer {
+ ChannelSignerType::Ecdsa(ecdsa) => {
+ ecdsa.validate_counterparty_revocation(
+ self.context.cur_counterparty_commitment_transaction_number + 1,
+ &secret
+ ).map_err(|_| ChannelError::Close("Failed to validate revocation from peer".to_owned()))?;
+ }
+ };
self.context.commitment_secrets.provide_secret(self.context.cur_counterparty_commitment_transaction_number + 1, msg.per_commitment_secret)
.map_err(|_| ChannelError::Close("Previous secrets did not match new one".to_owned()))?;
self.context.announcement_sigs_state = AnnouncementSigsState::PeerReceived;
}
- log_trace!(logger, "Updating HTLCs on receipt of RAA in channel {}...", log_bytes!(self.context.channel_id()));
+ log_trace!(logger, "Updating HTLCs on receipt of RAA in channel {}...", &self.context.channel_id());
let mut to_forward_infos = Vec::new();
let mut revoked_htlcs = Vec::new();
let mut finalized_claimed_htlcs = Vec::new();
// We really shouldnt have two passes here, but retain gives a non-mutable ref (Rust bug)
pending_inbound_htlcs.retain(|htlc| {
if let &InboundHTLCState::LocalRemoved(ref reason) = &htlc.state {
- log_trace!(logger, " ...removing inbound LocalRemoved {}", log_bytes!(htlc.payment_hash.0));
+ log_trace!(logger, " ...removing inbound LocalRemoved {}", &htlc.payment_hash);
if let &InboundHTLCRemovalReason::Fulfill(_) = reason {
value_to_self_msat_diff += htlc.amount_msat as i64;
}
});
pending_outbound_htlcs.retain(|htlc| {
if let &OutboundHTLCState::AwaitingRemovedRemoteRevoke(ref outcome) = &htlc.state {
- log_trace!(logger, " ...removing outbound AwaitingRemovedRemoteRevoke {}", log_bytes!(htlc.payment_hash.0));
+ log_trace!(logger, " ...removing outbound AwaitingRemovedRemoteRevoke {}", &htlc.payment_hash);
if let OutboundHTLCOutcome::Failure(reason) = outcome.clone() { // We really want take() here, but, again, non-mut ref :(
revoked_htlcs.push((htlc.source.clone(), htlc.payment_hash, reason));
} else {
mem::swap(&mut state, &mut htlc.state);
if let InboundHTLCState::AwaitingRemoteRevokeToAnnounce(forward_info) = state {
- log_trace!(logger, " ...promoting inbound AwaitingRemoteRevokeToAnnounce {} to AwaitingAnnouncedRemoteRevoke", log_bytes!(htlc.payment_hash.0));
+ log_trace!(logger, " ...promoting inbound AwaitingRemoteRevokeToAnnounce {} to AwaitingAnnouncedRemoteRevoke", &htlc.payment_hash);
htlc.state = InboundHTLCState::AwaitingAnnouncedRemoteRevoke(forward_info);
require_commitment = true;
} else if let InboundHTLCState::AwaitingAnnouncedRemoteRevoke(forward_info) = state {
match forward_info {
PendingHTLCStatus::Fail(fail_msg) => {
- log_trace!(logger, " ...promoting inbound AwaitingAnnouncedRemoteRevoke {} to LocalRemoved due to PendingHTLCStatus indicating failure", log_bytes!(htlc.payment_hash.0));
+ log_trace!(logger, " ...promoting inbound AwaitingAnnouncedRemoteRevoke {} to LocalRemoved due to PendingHTLCStatus indicating failure", &htlc.payment_hash);
require_commitment = true;
match fail_msg {
HTLCFailureMsg::Relay(msg) => {
}
},
PendingHTLCStatus::Forward(forward_info) => {
- log_trace!(logger, " ...promoting inbound AwaitingAnnouncedRemoteRevoke {} to Committed", log_bytes!(htlc.payment_hash.0));
+ log_trace!(logger, " ...promoting inbound AwaitingAnnouncedRemoteRevoke {} to Committed", &htlc.payment_hash);
to_forward_infos.push((forward_info, htlc.htlc_id));
htlc.state = InboundHTLCState::Committed;
}
}
for htlc in pending_outbound_htlcs.iter_mut() {
if let OutboundHTLCState::LocalAnnounced(_) = htlc.state {
- log_trace!(logger, " ...promoting outbound LocalAnnounced {} to Committed", log_bytes!(htlc.payment_hash.0));
+ log_trace!(logger, " ...promoting outbound LocalAnnounced {} to Committed", &htlc.payment_hash);
htlc.state = OutboundHTLCState::Committed;
}
if let &mut OutboundHTLCState::AwaitingRemoteRevokeToRemove(ref mut outcome) = &mut htlc.state {
- log_trace!(logger, " ...promoting outbound AwaitingRemoteRevokeToRemove {} to AwaitingRemovedRemoteRevoke", log_bytes!(htlc.payment_hash.0));
+ log_trace!(logger, " ...promoting outbound AwaitingRemoteRevokeToRemove {} to AwaitingRemovedRemoteRevoke", &htlc.payment_hash);
// Grab the preimage, if it exists, instead of cloning
let mut reason = OutboundHTLCOutcome::Success(None);
mem::swap(outcome, &mut reason);
// cells) while we can't update the monitor, so we just return what we have.
if require_commitment {
self.context.monitor_pending_commitment_signed = true;
- // When the monitor updating is restored we'll call get_last_commitment_update(),
- // which does not update state, but we're definitely now awaiting a remote revoke
- // before we can step forward any more, so set it here.
+ // When the monitor updating is restored we'll call
+ // get_last_commitment_update_for_send(), which does not update state, but we're
+ // definitely now awaiting a remote revoke before we can step forward any more, so
+ // set it here.
let mut additional_update = self.build_commitment_no_status_check(logger);
// build_commitment_no_status_check may bump latest_monitor_id but we want them to be
// strictly increasing by one, so decrement it here.
self.context.monitor_pending_forwards.append(&mut to_forward_infos);
self.context.monitor_pending_failures.append(&mut revoked_htlcs);
self.context.monitor_pending_finalized_fulfills.append(&mut finalized_claimed_htlcs);
- log_debug!(logger, "Received a valid revoke_and_ack for channel {} but awaiting a monitor update resolution to reply.", log_bytes!(self.context.channel_id()));
+ log_debug!(logger, "Received a valid revoke_and_ack for channel {} but awaiting a monitor update resolution to reply.", &self.context.channel_id());
return_with_htlcs_to_fail!(Vec::new());
}
monitor_update.updates.append(&mut additional_update.updates);
log_debug!(logger, "Received a valid revoke_and_ack for channel {} with holding cell HTLCs freed. {} monitor update.",
- log_bytes!(self.context.channel_id()), release_state_str);
+ &self.context.channel_id(), release_state_str);
self.monitor_updating_paused(false, true, false, to_forward_infos, revoked_htlcs, finalized_claimed_htlcs);
return_with_htlcs_to_fail!(htlcs_to_fail);
monitor_update.updates.append(&mut additional_update.updates);
log_debug!(logger, "Received a valid revoke_and_ack for channel {}. Responding with a commitment update with {} HTLCs failed. {} monitor update.",
- log_bytes!(self.context.channel_id()),
+ &self.context.channel_id(),
update_fail_htlcs.len() + update_fail_malformed_htlcs.len(),
release_state_str);
return_with_htlcs_to_fail!(htlcs_to_fail);
} else {
log_debug!(logger, "Received a valid revoke_and_ack for channel {} with no reply necessary. {} monitor update.",
- log_bytes!(self.context.channel_id()), release_state_str);
+ &self.context.channel_id(), release_state_str);
self.monitor_updating_paused(false, false, false, to_forward_infos, revoked_htlcs, finalized_claimed_htlcs);
return_with_htlcs_to_fail!(htlcs_to_fail);
/// resent.
/// No further message handling calls may be made until a channel_reestablish dance has
/// completed.
- pub fn remove_uncommitted_htlcs_and_mark_paused<L: Deref>(&mut self, logger: &L) where L::Target: Logger {
+ /// May return `Err(())`, which implies [`ChannelContext::force_shutdown`] should be called immediately.
+ pub fn remove_uncommitted_htlcs_and_mark_paused<L: Deref>(&mut self, logger: &L) -> Result<(), ()> where L::Target: Logger {
assert_eq!(self.context.channel_state & ChannelState::ShutdownComplete as u32, 0);
- if self.context.channel_state < ChannelState::FundingSent as u32 {
- self.context.channel_state = ChannelState::ShutdownComplete as u32;
- return;
+ if self.context.channel_state & !STATE_FLAGS < ChannelState::FundingSent as u32 {
+ return Err(());
}
if self.context.channel_state & (ChannelState::PeerDisconnected as u32) == (ChannelState::PeerDisconnected as u32) {
// While the below code should be idempotent, it's simpler to just return early, as
// redundant disconnect events can fire, though they should be rare.
- return;
+ return Ok(());
}
if self.context.announcement_sigs_state == AnnouncementSigsState::MessageSent || self.context.announcement_sigs_state == AnnouncementSigsState::Committed {
self.context.sent_message_awaiting_response = None;
self.context.channel_state |= ChannelState::PeerDisconnected as u32;
- log_trace!(logger, "Peer disconnection resulted in {} remote-announced HTLC drops on channel {}", inbound_drop_count, log_bytes!(self.context.channel_id()));
+ log_trace!(logger, "Peer disconnection resulted in {} remote-announced HTLC drops on channel {}", inbound_drop_count, &self.context.channel_id());
+ Ok(())
}
/// Indicates that a ChannelMonitor update is in progress and has not yet been fully persisted.
/// successfully and we should restore normal operation. Returns messages which should be sent
/// to the remote side.
pub fn monitor_updating_restored<L: Deref, NS: Deref>(
- &mut self, logger: &L, node_signer: &NS, genesis_block_hash: BlockHash,
+ &mut self, logger: &L, node_signer: &NS, chain_hash: ChainHash,
user_config: &UserConfig, best_block_height: u32
) -> MonitorRestoreUpdates
where
// (re-)broadcast the funding transaction as we may have declined to broadcast it when we
// first received the funding_signed.
let mut funding_broadcastable =
- if self.context.is_outbound() && self.context.channel_state & !MULTI_STATE_FLAGS >= ChannelState::FundingSent as u32 {
+ if self.context.is_outbound() && self.context.channel_state & !STATE_FLAGS >= ChannelState::FundingSent as u32 && self.context.channel_state & ChannelState::WaitingForBatch as u32 == 0 {
self.context.funding_transaction.take()
} else { None };
// That said, if the funding transaction is already confirmed (ie we're active with a
// minimum_depth over 0) don't bother re-broadcasting the confirmed funding tx.
- if self.context.channel_state & !MULTI_STATE_FLAGS >= ChannelState::ChannelReady as u32 && self.context.minimum_depth != Some(0) {
+ if self.context.channel_state & !STATE_FLAGS >= ChannelState::ChannelReady as u32 && self.context.minimum_depth != Some(0) {
funding_broadcastable = None;
}
assert!(!self.context.is_outbound() || self.context.minimum_depth == Some(0),
"Funding transaction broadcast by the local client before it should have - LDK didn't do it!");
self.context.monitor_pending_channel_ready = false;
- let next_per_commitment_point = self.context.holder_signer.get_per_commitment_point(self.context.cur_holder_commitment_transaction_number, &self.context.secp_ctx);
+ let next_per_commitment_point = self.context.holder_signer.as_ref().get_per_commitment_point(self.context.cur_holder_commitment_transaction_number, &self.context.secp_ctx);
Some(msgs::ChannelReady {
channel_id: self.context.channel_id(),
next_per_commitment_point,
})
} else { None };
- let announcement_sigs = self.get_announcement_sigs(node_signer, genesis_block_hash, user_config, best_block_height, logger);
+ let announcement_sigs = self.get_announcement_sigs(node_signer, chain_hash, user_config, best_block_height, logger);
let mut accepted_htlcs = Vec::new();
mem::swap(&mut accepted_htlcs, &mut self.context.monitor_pending_forwards);
Some(self.get_last_revoke_and_ack())
} else { None };
let commitment_update = if self.context.monitor_pending_commitment_signed {
- self.mark_awaiting_response();
- Some(self.get_last_commitment_update(logger))
+ self.get_last_commitment_update_for_send(logger).ok()
} else { None };
+ if commitment_update.is_some() {
+ self.mark_awaiting_response();
+ }
self.context.monitor_pending_revoke_and_ack = false;
self.context.monitor_pending_commitment_signed = false;
let order = self.context.resend_order.clone();
log_debug!(logger, "Restored monitor updating in channel {} resulting in {}{} commitment update and {} RAA, with {} first",
- log_bytes!(self.context.channel_id()), if funding_broadcastable.is_some() { "a funding broadcastable, " } else { "" },
+ &self.context.channel_id(), if funding_broadcastable.is_some() { "a funding broadcastable, " } else { "" },
if commitment_update.is_some() { "a" } else { "no" }, if raa.is_some() { "an" } else { "no" },
match order { RAACommitmentOrder::CommitmentFirst => "commitment", RAACommitmentOrder::RevokeAndACKFirst => "RAA"});
MonitorRestoreUpdates {
if self.context.channel_state & (ChannelState::PeerDisconnected as u32) == ChannelState::PeerDisconnected as u32 {
return Err(ChannelError::Close("Peer sent update_fee when we needed a channel_reestablish".to_owned()));
}
- Channel::<Signer>::check_remote_fee(&self.context.channel_type, fee_estimator, msg.feerate_per_kw, Some(self.context.feerate_per_kw), logger)?;
+ Channel::<SP>::check_remote_fee(&self.context.channel_type, fee_estimator, msg.feerate_per_kw, Some(self.context.feerate_per_kw), logger)?;
let feerate_over_dust_buffer = msg.feerate_per_kw > self.context.get_dust_buffer_feerate(None);
self.context.pending_update_fee = Some((msg.feerate_per_kw, FeeUpdateState::RemoteAnnounced));
Ok(())
}
+ /// Indicates that the signer may have some signatures for us, so we should retry if we're
+ /// blocked.
+ #[allow(unused)]
+ pub fn signer_maybe_unblocked<L: Deref>(&mut self, logger: &L) -> SignerResumeUpdates where L::Target: Logger {
+ let commitment_update = if self.context.signer_pending_commitment_update {
+ self.get_last_commitment_update_for_send(logger).ok()
+ } else { None };
+ let funding_signed = if self.context.signer_pending_funding && !self.context.is_outbound() {
+ self.context.get_funding_signed_msg(logger).1
+ } else { None };
+ let channel_ready = if funding_signed.is_some() {
+ self.check_get_channel_ready(0)
+ } else { None };
+ let funding_created = if self.context.signer_pending_funding && self.context.is_outbound() {
+ self.context.get_funding_created_msg(logger)
+ } else { None };
+
+ log_trace!(logger, "Signer unblocked with {} commitment_update, {} funding_signed, {} funding_created, and {} channel_ready",
+ if commitment_update.is_some() { "a" } else { "no" },
+ if funding_signed.is_some() { "a" } else { "no" },
+ if funding_created.is_some() { "a" } else { "no" },
+ if channel_ready.is_some() { "a" } else { "no" });
+
+ SignerResumeUpdates {
+ commitment_update,
+ funding_signed,
+ funding_created,
+ channel_ready,
+ }
+ }
+
fn get_last_revoke_and_ack(&self) -> msgs::RevokeAndACK {
- let next_per_commitment_point = self.context.holder_signer.get_per_commitment_point(self.context.cur_holder_commitment_transaction_number, &self.context.secp_ctx);
- let per_commitment_secret = self.context.holder_signer.release_commitment_secret(self.context.cur_holder_commitment_transaction_number + 2);
+ let next_per_commitment_point = self.context.holder_signer.as_ref().get_per_commitment_point(self.context.cur_holder_commitment_transaction_number, &self.context.secp_ctx);
+ let per_commitment_secret = self.context.holder_signer.as_ref().release_commitment_secret(self.context.cur_holder_commitment_transaction_number + 2);
msgs::RevokeAndACK {
channel_id: self.context.channel_id,
per_commitment_secret,
}
}
- fn get_last_commitment_update<L: Deref>(&self, logger: &L) -> msgs::CommitmentUpdate where L::Target: Logger {
+ /// Gets the last commitment update for immediate sending to our peer.
+ fn get_last_commitment_update_for_send<L: Deref>(&mut self, logger: &L) -> Result<msgs::CommitmentUpdate, ()> where L::Target: Logger {
let mut update_add_htlcs = Vec::new();
let mut update_fulfill_htlcs = Vec::new();
let mut update_fail_htlcs = Vec::new();
})
} else { None };
- log_trace!(logger, "Regenerated latest commitment update in channel {} with{} {} update_adds, {} update_fulfills, {} update_fails, and {} update_fail_malformeds",
- log_bytes!(self.context.channel_id()), if update_fee.is_some() { " update_fee," } else { "" },
+ log_trace!(logger, "Regenerating latest commitment update in channel {} with{} {} update_adds, {} update_fulfills, {} update_fails, and {} update_fail_malformeds",
+ &self.context.channel_id(), if update_fee.is_some() { " update_fee," } else { "" },
update_add_htlcs.len(), update_fulfill_htlcs.len(), update_fail_htlcs.len(), update_fail_malformed_htlcs.len());
- msgs::CommitmentUpdate {
+ let commitment_signed = if let Ok(update) = self.send_commitment_no_state_update(logger).map(|(cu, _)| cu) {
+ if self.context.signer_pending_commitment_update {
+ log_trace!(logger, "Commitment update generated: clearing signer_pending_commitment_update");
+ self.context.signer_pending_commitment_update = false;
+ }
+ update
+ } else {
+ if !self.context.signer_pending_commitment_update {
+ log_trace!(logger, "Commitment update awaiting signer: setting signer_pending_commitment_update");
+ self.context.signer_pending_commitment_update = true;
+ }
+ return Err(());
+ };
+ Ok(msgs::CommitmentUpdate {
update_add_htlcs, update_fulfill_htlcs, update_fail_htlcs, update_fail_malformed_htlcs, update_fee,
- commitment_signed: self.send_commitment_no_state_update(logger).expect("It looks like we failed to re-generate a commitment_signed we had previously sent?").0,
- }
+ commitment_signed,
+ })
+ }
+
+ /// Gets the `Shutdown` message we should send our peer on reconnect, if any.
+ pub fn get_outbound_shutdown(&self) -> Option<msgs::Shutdown> {
+ if self.context.channel_state & (ChannelState::LocalShutdownSent as u32) != 0 {
+ assert!(self.context.shutdown_scriptpubkey.is_some());
+ Some(msgs::Shutdown {
+ channel_id: self.context.channel_id,
+ scriptpubkey: self.get_closing_scriptpubkey(),
+ })
+ } else { None }
}
/// May panic if some calls other than message-handling calls (which will all Err immediately)
/// [`super::channelmanager::ChannelManager::force_close_all_channels_without_broadcasting_txn`].
pub fn channel_reestablish<L: Deref, NS: Deref>(
&mut self, msg: &msgs::ChannelReestablish, logger: &L, node_signer: &NS,
- genesis_block_hash: BlockHash, user_config: &UserConfig, best_block: &BestBlock
+ chain_hash: ChainHash, user_config: &UserConfig, best_block: &BestBlock
) -> Result<ReestablishResponses, ChannelError>
where
L::Target: Logger,
if msg.next_local_commitment_number >= INITIAL_COMMITMENT_NUMBER || msg.next_remote_commitment_number >= INITIAL_COMMITMENT_NUMBER ||
msg.next_local_commitment_number == 0 {
- return Err(ChannelError::Close("Peer sent a garbage channel_reestablish (usually an lnd node with lost state asking us to force-close for them)".to_owned()));
+ return Err(ChannelError::Close("Peer sent an invalid channel_reestablish to force close in a non-standard way".to_owned()));
}
if msg.next_remote_commitment_number > 0 {
- let expected_point = self.context.holder_signer.get_per_commitment_point(INITIAL_COMMITMENT_NUMBER - msg.next_remote_commitment_number + 1, &self.context.secp_ctx);
+ let expected_point = self.context.holder_signer.as_ref().get_per_commitment_point(INITIAL_COMMITMENT_NUMBER - msg.next_remote_commitment_number + 1, &self.context.secp_ctx);
let given_secret = SecretKey::from_slice(&msg.your_last_per_commitment_secret)
.map_err(|_| ChannelError::Close("Peer sent a garbage channel_reestablish with unparseable secret key".to_owned()))?;
if expected_point != PublicKey::from_secret_key(&self.context.secp_ctx, &given_secret) {
if msg.next_remote_commitment_number > INITIAL_COMMITMENT_NUMBER - self.context.cur_holder_commitment_transaction_number {
macro_rules! log_and_panic {
($err_msg: expr) => {
- log_error!(logger, $err_msg, log_bytes!(self.context.channel_id), log_pubkey!(self.context.counterparty_node_id));
- panic!($err_msg, log_bytes!(self.context.channel_id), log_pubkey!(self.context.counterparty_node_id));
+ log_error!(logger, $err_msg, &self.context.channel_id, log_pubkey!(self.context.counterparty_node_id));
+ panic!($err_msg, &self.context.channel_id, log_pubkey!(self.context.counterparty_node_id));
}
}
log_and_panic!("We have fallen behind - we have received proof that if we broadcast our counterparty is going to claim all our funds.\n\
self.context.channel_state &= !(ChannelState::PeerDisconnected as u32);
self.context.sent_message_awaiting_response = None;
- let shutdown_msg = if self.context.channel_state & (ChannelState::LocalShutdownSent as u32) != 0 {
- assert!(self.context.shutdown_scriptpubkey.is_some());
- Some(msgs::Shutdown {
- channel_id: self.context.channel_id,
- scriptpubkey: self.get_closing_scriptpubkey(),
- })
- } else { None };
+ let shutdown_msg = self.get_outbound_shutdown();
- let announcement_sigs = self.get_announcement_sigs(node_signer, genesis_block_hash, user_config, best_block.height(), logger);
+ let announcement_sigs = self.get_announcement_sigs(node_signer, chain_hash, user_config, best_block.height(), logger);
if self.context.channel_state & (ChannelState::FundingSent as u32) == ChannelState::FundingSent as u32 {
// If we're waiting on a monitor update, we shouldn't re-send any channel_ready's.
}
// We have OurChannelReady set!
- let next_per_commitment_point = self.context.holder_signer.get_per_commitment_point(self.context.cur_holder_commitment_transaction_number, &self.context.secp_ctx);
+ let next_per_commitment_point = self.context.holder_signer.as_ref().get_per_commitment_point(self.context.cur_holder_commitment_transaction_number, &self.context.secp_ctx);
return Ok(ReestablishResponses {
channel_ready: Some(msgs::ChannelReady {
channel_id: self.context.channel_id(),
let channel_ready = if msg.next_local_commitment_number == 1 && INITIAL_COMMITMENT_NUMBER - self.context.cur_holder_commitment_transaction_number == 1 {
// We should never have to worry about MonitorUpdateInProgress resending ChannelReady
- let next_per_commitment_point = self.context.holder_signer.get_per_commitment_point(self.context.cur_holder_commitment_transaction_number, &self.context.secp_ctx);
+ let next_per_commitment_point = self.context.holder_signer.as_ref().get_per_commitment_point(self.context.cur_holder_commitment_transaction_number, &self.context.secp_ctx);
Some(msgs::ChannelReady {
channel_id: self.context.channel_id(),
next_per_commitment_point,
if msg.next_local_commitment_number == next_counterparty_commitment_number {
if required_revoke.is_some() {
- log_debug!(logger, "Reconnected channel {} with only lost outbound RAA", log_bytes!(self.context.channel_id()));
+ log_debug!(logger, "Reconnected channel {} with only lost outbound RAA", &self.context.channel_id());
} else {
- log_debug!(logger, "Reconnected channel {} with no loss", log_bytes!(self.context.channel_id()));
+ log_debug!(logger, "Reconnected channel {} with no loss", &self.context.channel_id());
}
Ok(ReestablishResponses {
})
} else if msg.next_local_commitment_number == next_counterparty_commitment_number - 1 {
if required_revoke.is_some() {
- log_debug!(logger, "Reconnected channel {} with lost outbound RAA and lost remote commitment tx", log_bytes!(self.context.channel_id()));
+ log_debug!(logger, "Reconnected channel {} with lost outbound RAA and lost remote commitment tx", &self.context.channel_id());
} else {
- log_debug!(logger, "Reconnected channel {} with only lost remote commitment tx", log_bytes!(self.context.channel_id()));
+ log_debug!(logger, "Reconnected channel {} with only lost remote commitment tx", &self.context.channel_id());
}
if self.context.channel_state & (ChannelState::MonitorUpdateInProgress as u32) != 0 {
Ok(ReestablishResponses {
channel_ready, shutdown_msg, announcement_sigs,
raa: required_revoke,
- commitment_update: Some(self.get_last_commitment_update(logger)),
+ commitment_update: self.get_last_commitment_update_for_send(logger).ok(),
order: self.context.resend_order.clone(),
})
}
// Propose a range from our current Background feerate to our Normal feerate plus our
// force_close_avoidance_max_fee_satoshis.
// If we fail to come to consensus, we'll have to force-close.
- let mut proposed_feerate = fee_estimator.bounded_sat_per_1000_weight(ConfirmationTarget::Background);
- let normal_feerate = fee_estimator.bounded_sat_per_1000_weight(ConfirmationTarget::Normal);
+ let mut proposed_feerate = fee_estimator.bounded_sat_per_1000_weight(ConfirmationTarget::ChannelCloseMinimum);
+ // Use NonAnchorChannelFee because this should be an estimate for a channel close
+ // that we don't expect to need fee bumping
+ let normal_feerate = fee_estimator.bounded_sat_per_1000_weight(ConfirmationTarget::NonAnchorChannelFee);
let mut proposed_max_feerate = if self.context.is_outbound() { normal_feerate } else { u32::max_value() };
// The spec requires that (when the channel does not have anchors) we only send absolute
pub fn maybe_propose_closing_signed<F: Deref, L: Deref>(
&mut self, fee_estimator: &LowerBoundedFeeEstimator<F>, logger: &L)
- -> Result<(Option<msgs::ClosingSigned>, Option<Transaction>), ChannelError>
+ -> Result<(Option<msgs::ClosingSigned>, Option<Transaction>, Option<ShutdownResult>), ChannelError>
where F::Target: FeeEstimator, L::Target: Logger
{
if self.context.last_sent_closing_fee.is_some() || !self.closing_negotiation_ready() {
- return Ok((None, None));
+ return Ok((None, None, None));
}
if !self.context.is_outbound() {
if let Some(msg) = &self.context.pending_counterparty_closing_signed.take() {
return self.closing_signed(fee_estimator, &msg);
}
- return Ok((None, None));
+ return Ok((None, None, None));
}
let (our_min_fee, our_max_fee) = self.calculate_closing_fee_limits(fee_estimator);
log_trace!(logger, "Proposing initial closing_signed for our counterparty with a fee range of {}-{} sat (with initial proposal {} sats)",
our_min_fee, our_max_fee, total_fee_satoshis);
- let sig = self.context.holder_signer
- .sign_closing_transaction(&closing_tx, &self.context.secp_ctx)
- .map_err(|()| ChannelError::Close("Failed to get signature for closing transaction.".to_owned()))?;
+ match &self.context.holder_signer {
+ ChannelSignerType::Ecdsa(ecdsa) => {
+ let sig = ecdsa
+ .sign_closing_transaction(&closing_tx, &self.context.secp_ctx)
+ .map_err(|()| ChannelError::Close("Failed to get signature for closing transaction.".to_owned()))?;
- self.context.last_sent_closing_fee = Some((total_fee_satoshis, sig.clone()));
- Ok((Some(msgs::ClosingSigned {
- channel_id: self.context.channel_id,
- fee_satoshis: total_fee_satoshis,
- signature: sig,
- fee_range: Some(msgs::ClosingSignedFeeRange {
- min_fee_satoshis: our_min_fee,
- max_fee_satoshis: our_max_fee,
- }),
- }), None))
+ self.context.last_sent_closing_fee = Some((total_fee_satoshis, sig.clone()));
+ Ok((Some(msgs::ClosingSigned {
+ channel_id: self.context.channel_id,
+ fee_satoshis: total_fee_satoshis,
+ signature: sig,
+ fee_range: Some(msgs::ClosingSignedFeeRange {
+ min_fee_satoshis: our_min_fee,
+ max_fee_satoshis: our_max_fee,
+ }),
+ }), None, None))
+ }
+ }
}
// Marks a channel as waiting for a response from the counterparty. If it's not received
*ticks_elapsed >= DISCONNECT_PEER_AWAITING_RESPONSE_TICKS
}
- pub fn shutdown<SP: Deref>(
+ pub fn shutdown(
&mut self, signer_provider: &SP, their_features: &InitFeatures, msg: &msgs::Shutdown
) -> Result<(Option<msgs::Shutdown>, Option<ChannelMonitorUpdate>, Vec<(HTLCSource, PaymentHash)>), ChannelError>
- where SP::Target: SignerProvider
{
if self.context.channel_state & (ChannelState::PeerDisconnected as u32) == ChannelState::PeerDisconnected as u32 {
return Err(ChannelError::Close("Peer sent shutdown when we needed a channel_reestablish".to_owned()));
}
- if self.context.channel_state < ChannelState::FundingSent as u32 {
+ if self.context.channel_state & !STATE_FLAGS < ChannelState::FundingSent as u32 {
// Spec says we should fail the connection, not the channel, but that's nonsense, there
// are plenty of reasons you may want to fail a channel pre-funding, and spec says you
// can do that via error message without getting a connection fail anyway...
pub fn closing_signed<F: Deref>(
&mut self, fee_estimator: &LowerBoundedFeeEstimator<F>, msg: &msgs::ClosingSigned)
- -> Result<(Option<msgs::ClosingSigned>, Option<Transaction>), ChannelError>
+ -> Result<(Option<msgs::ClosingSigned>, Option<Transaction>, Option<ShutdownResult>), ChannelError>
where F::Target: FeeEstimator
{
if self.context.channel_state & BOTH_SIDES_SHUTDOWN_MASK != BOTH_SIDES_SHUTDOWN_MASK {
if self.context.channel_state & ChannelState::MonitorUpdateInProgress as u32 != 0 {
self.context.pending_counterparty_closing_signed = Some(msg.clone());
- return Ok((None, None));
+ return Ok((None, None, None));
}
let funding_redeemscript = self.context.get_funding_redeemscript();
assert!(self.context.shutdown_scriptpubkey.is_some());
if let Some((last_fee, sig)) = self.context.last_sent_closing_fee {
if last_fee == msg.fee_satoshis {
+ let shutdown_result = ShutdownResult {
+ monitor_update: None,
+ dropped_outbound_htlcs: Vec::new(),
+ unbroadcasted_batch_funding_txid: self.context.unbroadcasted_batch_funding_txid(),
+ };
let tx = self.build_signed_closing_transaction(&mut closing_tx, &msg.signature, &sig);
self.context.channel_state = ChannelState::ShutdownComplete as u32;
self.context.update_time_counter += 1;
- return Ok((None, Some(tx)));
+ return Ok((None, Some(tx), Some(shutdown_result)));
}
}
self.build_closing_transaction($new_fee, false)
};
- let sig = self.context.holder_signer
- .sign_closing_transaction(&closing_tx, &self.context.secp_ctx)
- .map_err(|_| ChannelError::Close("External signer refused to sign closing transaction".to_owned()))?;
-
- let signed_tx = if $new_fee == msg.fee_satoshis {
- self.context.channel_state = ChannelState::ShutdownComplete as u32;
- self.context.update_time_counter += 1;
- let tx = self.build_signed_closing_transaction(&closing_tx, &msg.signature, &sig);
- Some(tx)
- } else { None };
-
- self.context.last_sent_closing_fee = Some((used_fee, sig.clone()));
- return Ok((Some(msgs::ClosingSigned {
- channel_id: self.context.channel_id,
- fee_satoshis: used_fee,
- signature: sig,
- fee_range: Some(msgs::ClosingSignedFeeRange {
- min_fee_satoshis: our_min_fee,
- max_fee_satoshis: our_max_fee,
- }),
- }), signed_tx))
+ return match &self.context.holder_signer {
+ ChannelSignerType::Ecdsa(ecdsa) => {
+ let sig = ecdsa
+ .sign_closing_transaction(&closing_tx, &self.context.secp_ctx)
+ .map_err(|_| ChannelError::Close("External signer refused to sign closing transaction".to_owned()))?;
+ let (signed_tx, shutdown_result) = if $new_fee == msg.fee_satoshis {
+ let shutdown_result = ShutdownResult {
+ monitor_update: None,
+ dropped_outbound_htlcs: Vec::new(),
+ unbroadcasted_batch_funding_txid: self.context.unbroadcasted_batch_funding_txid(),
+ };
+ self.context.channel_state = ChannelState::ShutdownComplete as u32;
+ self.context.update_time_counter += 1;
+ let tx = self.build_signed_closing_transaction(&closing_tx, &msg.signature, &sig);
+ (Some(tx), Some(shutdown_result))
+ } else {
+ (None, None)
+ };
+
+ self.context.last_sent_closing_fee = Some((used_fee, sig.clone()));
+ Ok((Some(msgs::ClosingSigned {
+ channel_id: self.context.channel_id,
+ fee_satoshis: used_fee,
+ signature: sig,
+ fee_range: Some(msgs::ClosingSignedFeeRange {
+ min_fee_satoshis: our_min_fee,
+ max_fee_satoshis: our_max_fee,
+ }),
+ }), signed_tx, shutdown_result))
+ }
+ }
}
}
}
#[cfg(test)]
- pub fn get_signer(&self) -> &Signer {
+ pub fn get_signer(&self) -> &ChannelSignerType<<SP::Target as SignerProvider>::Signer> {
&self.context.holder_signer
}
pub fn is_awaiting_initial_mon_persist(&self) -> bool {
if !self.is_awaiting_monitor_update() { return false; }
if self.context.channel_state &
- !(ChannelState::TheirChannelReady as u32 | ChannelState::PeerDisconnected as u32 | ChannelState::MonitorUpdateInProgress as u32)
+ !(ChannelState::TheirChannelReady as u32 | ChannelState::PeerDisconnected as u32 | ChannelState::MonitorUpdateInProgress as u32 | ChannelState::WaitingForBatch as u32)
== ChannelState::FundingSent as u32 {
// If we're not a 0conf channel, we'll be waiting on a monitor update with only
// FundingSent set, though our peer could have sent their channel_ready.
/// Returns true if our channel_ready has been sent
pub fn is_our_channel_ready(&self) -> bool {
- (self.context.channel_state & ChannelState::OurChannelReady as u32) != 0 || self.context.channel_state >= ChannelState::ChannelReady as u32
+ (self.context.channel_state & ChannelState::OurChannelReady as u32) != 0 || self.context.channel_state & !STATE_FLAGS >= ChannelState::ChannelReady as u32
}
/// Returns true if our peer has either initiated or agreed to shut down the channel.
return None;
}
+ // If we're still pending the signature on a funding transaction, then we're not ready to send a
+ // channel_ready yet.
+ if self.context.signer_pending_funding {
+ return None;
+ }
+
+ // Note that we don't include ChannelState::WaitingForBatch as we don't want to send
+ // channel_ready until the entire batch is ready.
let non_shutdown_state = self.context.channel_state & (!MULTI_STATE_FLAGS);
let need_commitment_update = if non_shutdown_state == ChannelState::FundingSent as u32 {
self.context.channel_state |= ChannelState::OurChannelReady as u32;
// We got a reorg but not enough to trigger a force close, just ignore.
false
} else {
- if self.context.funding_tx_confirmation_height != 0 && self.context.channel_state < ChannelState::ChannelReady as u32 {
+ if self.context.funding_tx_confirmation_height != 0 && self.context.channel_state & !STATE_FLAGS < ChannelState::ChannelReady as u32 {
// We should never see a funding transaction on-chain until we've received
// funding_signed (if we're an outbound channel), or seen funding_generated (if we're
// an inbound channel - before that we have no known funding TXID). The fuzzer,
if self.context.channel_state & (ChannelState::MonitorUpdateInProgress as u32) == 0 {
if self.context.channel_state & (ChannelState::PeerDisconnected as u32) == 0 {
let next_per_commitment_point =
- self.context.holder_signer.get_per_commitment_point(INITIAL_COMMITMENT_NUMBER - 1, &self.context.secp_ctx);
+ self.context.holder_signer.as_ref().get_per_commitment_point(INITIAL_COMMITMENT_NUMBER - 1, &self.context.secp_ctx);
return Some(msgs::ChannelReady {
channel_id: self.context.channel_id,
next_per_commitment_point,
/// In the second, we simply return an Err indicating we need to be force-closed now.
pub fn transactions_confirmed<NS: Deref, L: Deref>(
&mut self, block_hash: &BlockHash, height: u32, txdata: &TransactionData,
- genesis_block_hash: BlockHash, node_signer: &NS, user_config: &UserConfig, logger: &L
+ chain_hash: ChainHash, node_signer: &NS, user_config: &UserConfig, logger: &L
) -> Result<(Option<msgs::ChannelReady>, Option<msgs::AnnouncementSignatures>), ClosureReason>
where
NS::Target: NodeSigner,
L::Target: Logger
{
+ let mut msgs = (None, None);
if let Some(funding_txo) = self.context.get_funding_txo() {
for &(index_in_block, tx) in txdata.iter() {
// Check if the transaction is the expected funding transaction, and if it is,
return Err(ClosureReason::ProcessingError { err: err_reason.to_owned() });
} else {
if self.context.is_outbound() {
- for input in tx.input.iter() {
- if input.witness.is_empty() {
- // We generated a malleable funding transaction, implying we've
- // just exposed ourselves to funds loss to our counterparty.
- #[cfg(not(fuzzing))]
- panic!("Client called ChannelManager::funding_transaction_generated with bogus transaction!");
+ if !tx.is_coin_base() {
+ for input in tx.input.iter() {
+ if input.witness.is_empty() {
+ // We generated a malleable funding transaction, implying we've
+ // just exposed ourselves to funds loss to our counterparty.
+ #[cfg(not(fuzzing))]
+ panic!("Client called ChannelManager::funding_transaction_generated with bogus transaction!");
+ }
}
}
}
Err(_) => panic!("Block was bogus - either height was > 16 million, had > 16 million transactions, or had > 65k outputs"),
}
}
+ // If this is a coinbase transaction and not a 0-conf channel
+ // we should update our min_depth to 100 to handle coinbase maturity
+ if tx.is_coin_base() &&
+ self.context.minimum_depth.unwrap_or(0) > 0 &&
+ self.context.minimum_depth.unwrap_or(0) < COINBASE_MATURITY {
+ self.context.minimum_depth = Some(COINBASE_MATURITY);
+ }
}
// If we allow 1-conf funding, we may need to check for channel_ready here and
// send it immediately instead of waiting for a best_block_updated call (which
// may have already happened for this block).
if let Some(channel_ready) = self.check_get_channel_ready(height) {
- log_info!(logger, "Sending a channel_ready to our peer for channel {}", log_bytes!(self.context.channel_id));
- let announcement_sigs = self.get_announcement_sigs(node_signer, genesis_block_hash, user_config, height, logger);
- return Ok((Some(channel_ready), announcement_sigs));
+ log_info!(logger, "Sending a channel_ready to our peer for channel {}", &self.context.channel_id);
+ let announcement_sigs = self.get_announcement_sigs(node_signer, chain_hash, user_config, height, logger);
+ msgs = (Some(channel_ready), announcement_sigs);
}
}
for inp in tx.input.iter() {
if inp.previous_output == funding_txo.into_bitcoin_outpoint() {
- log_info!(logger, "Detected channel-closing tx {} spending {}:{}, closing channel {}", tx.txid(), inp.previous_output.txid, inp.previous_output.vout, log_bytes!(self.context.channel_id()));
+ log_info!(logger, "Detected channel-closing tx {} spending {}:{}, closing channel {}", tx.txid(), inp.previous_output.txid, inp.previous_output.vout, &self.context.channel_id());
return Err(ClosureReason::CommitmentTxConfirmed);
}
}
}
}
- Ok((None, None))
+ Ok(msgs)
}
/// When a new block is connected, we check the height of the block against outbound holding
/// May return some HTLCs (and their payment_hash) which have timed out and should be failed
/// back.
pub fn best_block_updated<NS: Deref, L: Deref>(
- &mut self, height: u32, highest_header_time: u32, genesis_block_hash: BlockHash,
+ &mut self, height: u32, highest_header_time: u32, chain_hash: ChainHash,
node_signer: &NS, user_config: &UserConfig, logger: &L
) -> Result<(Option<msgs::ChannelReady>, Vec<(HTLCSource, PaymentHash)>, Option<msgs::AnnouncementSignatures>), ClosureReason>
where
NS::Target: NodeSigner,
L::Target: Logger
{
- self.do_best_block_updated(height, highest_header_time, Some((genesis_block_hash, node_signer, user_config)), logger)
+ self.do_best_block_updated(height, highest_header_time, Some((chain_hash, node_signer, user_config)), logger)
}
fn do_best_block_updated<NS: Deref, L: Deref>(
&mut self, height: u32, highest_header_time: u32,
- genesis_node_signer: Option<(BlockHash, &NS, &UserConfig)>, logger: &L
+ chain_node_signer: Option<(ChainHash, &NS, &UserConfig)>, logger: &L
) -> Result<(Option<msgs::ChannelReady>, Vec<(HTLCSource, PaymentHash)>, Option<msgs::AnnouncementSignatures>), ClosureReason>
where
NS::Target: NodeSigner,
self.context.update_time_counter = cmp::max(self.context.update_time_counter, highest_header_time);
if let Some(channel_ready) = self.check_get_channel_ready(height) {
- let announcement_sigs = if let Some((genesis_block_hash, node_signer, user_config)) = genesis_node_signer {
- self.get_announcement_sigs(node_signer, genesis_block_hash, user_config, height, logger)
+ let announcement_sigs = if let Some((chain_hash, node_signer, user_config)) = chain_node_signer {
+ self.get_announcement_sigs(node_signer, chain_hash, user_config, height, logger)
} else { None };
- log_info!(logger, "Sending a channel_ready to our peer for channel {}", log_bytes!(self.context.channel_id));
+ log_info!(logger, "Sending a channel_ready to our peer for channel {}", &self.context.channel_id);
return Ok((Some(channel_ready), timed_out_htlcs, announcement_sigs));
}
let non_shutdown_state = self.context.channel_state & (!MULTI_STATE_FLAGS);
- if non_shutdown_state >= ChannelState::ChannelReady as u32 ||
+ if non_shutdown_state & !STATE_FLAGS >= ChannelState::ChannelReady as u32 ||
(non_shutdown_state & ChannelState::OurChannelReady as u32) == ChannelState::OurChannelReady as u32 {
let mut funding_tx_confirmations = height as i64 - self.context.funding_tx_confirmation_height as i64 + 1;
if self.context.funding_tx_confirmation_height == 0 {
}
} else if !self.context.is_outbound() && self.context.funding_tx_confirmed_in.is_none() &&
height >= self.context.channel_creation_height + FUNDING_CONF_DEADLINE_BLOCKS {
- log_info!(logger, "Closing channel {} due to funding timeout", log_bytes!(self.context.channel_id));
+ log_info!(logger, "Closing channel {} due to funding timeout", &self.context.channel_id);
// If funding_tx_confirmed_in is unset, the channel must not be active
- assert!(non_shutdown_state <= ChannelState::ChannelReady as u32);
+ assert!(non_shutdown_state & !STATE_FLAGS <= ChannelState::ChannelReady as u32);
assert_eq!(non_shutdown_state & ChannelState::OurChannelReady as u32, 0);
return Err(ClosureReason::FundingTimedOut);
}
- let announcement_sigs = if let Some((genesis_block_hash, node_signer, user_config)) = genesis_node_signer {
- self.get_announcement_sigs(node_signer, genesis_block_hash, user_config, height, logger)
+ let announcement_sigs = if let Some((chain_hash, node_signer, user_config)) = chain_node_signer {
+ self.get_announcement_sigs(node_signer, chain_hash, user_config, height, logger)
} else { None };
Ok((None, timed_out_htlcs, announcement_sigs))
}
// larger. If we don't know that time has moved forward, we can just set it to the last
// time we saw and it will be ignored.
let best_time = self.context.update_time_counter;
- match self.do_best_block_updated(reorg_height, best_time, None::<(BlockHash, &&NodeSigner, &UserConfig)>, logger) {
+ match self.do_best_block_updated(reorg_height, best_time, None::<(ChainHash, &&NodeSigner, &UserConfig)>, logger) {
Ok((channel_ready, timed_out_htlcs, announcement_sigs)) => {
assert!(channel_ready.is_none(), "We can't generate a funding with 0 confirmations?");
assert!(timed_out_htlcs.is_empty(), "We can't have accepted HTLCs with a timeout before our funding confirmation?");
///
/// [`ChannelReady`]: crate::ln::msgs::ChannelReady
fn get_channel_announcement<NS: Deref>(
- &self, node_signer: &NS, chain_hash: BlockHash, user_config: &UserConfig,
+ &self, node_signer: &NS, chain_hash: ChainHash, user_config: &UserConfig,
) -> Result<msgs::UnsignedChannelAnnouncement, ChannelError> where NS::Target: NodeSigner {
if !self.context.config.announced_channel {
return Err(ChannelError::Ignore("Channel is not available for public announcements".to_owned()));
}
fn get_announcement_sigs<NS: Deref, L: Deref>(
- &mut self, node_signer: &NS, genesis_block_hash: BlockHash, user_config: &UserConfig,
+ &mut self, node_signer: &NS, chain_hash: ChainHash, user_config: &UserConfig,
best_block_height: u32, logger: &L
) -> Option<msgs::AnnouncementSignatures>
where
return None;
}
- log_trace!(logger, "Creating an announcement_signatures message for channel {}", log_bytes!(self.context.channel_id()));
- let announcement = match self.get_channel_announcement(node_signer, genesis_block_hash, user_config) {
+ log_trace!(logger, "Creating an announcement_signatures message for channel {}", &self.context.channel_id());
+ let announcement = match self.get_channel_announcement(node_signer, chain_hash, user_config) {
Ok(a) => a,
Err(e) => {
log_trace!(logger, "{:?}", e);
},
Ok(v) => v
};
- let our_bitcoin_sig = match self.context.holder_signer.sign_channel_announcement_with_funding_key(&announcement, &self.context.secp_ctx) {
- Err(_) => {
- log_error!(logger, "Signer rejected channel_announcement signing. Channel will not be announced!");
- return None;
- },
- Ok(v) => v
- };
- let short_channel_id = match self.context.get_short_channel_id() {
- Some(scid) => scid,
- None => return None,
- };
+ match &self.context.holder_signer {
+ ChannelSignerType::Ecdsa(ecdsa) => {
+ let our_bitcoin_sig = match ecdsa.sign_channel_announcement_with_funding_key(&announcement, &self.context.secp_ctx) {
+ Err(_) => {
+ log_error!(logger, "Signer rejected channel_announcement signing. Channel will not be announced!");
+ return None;
+ },
+ Ok(v) => v
+ };
+ let short_channel_id = match self.context.get_short_channel_id() {
+ Some(scid) => scid,
+ None => return None,
+ };
- self.context.announcement_sigs_state = AnnouncementSigsState::MessageSent;
+ self.context.announcement_sigs_state = AnnouncementSigsState::MessageSent;
- Some(msgs::AnnouncementSignatures {
- channel_id: self.context.channel_id(),
- short_channel_id,
- node_signature: our_node_sig,
- bitcoin_signature: our_bitcoin_sig,
- })
+ Some(msgs::AnnouncementSignatures {
+ channel_id: self.context.channel_id(),
+ short_channel_id,
+ node_signature: our_node_sig,
+ bitcoin_signature: our_bitcoin_sig,
+ })
+ }
+ }
}
/// Signs the given channel announcement, returning a ChannelError::Ignore if no keys are
let our_node_sig = node_signer.sign_gossip_message(msgs::UnsignedGossipMessage::ChannelAnnouncement(&announcement))
.map_err(|_| ChannelError::Ignore("Failed to generate node signature for channel_announcement".to_owned()))?;
- let our_bitcoin_sig = self.context.holder_signer.sign_channel_announcement_with_funding_key(&announcement, &self.context.secp_ctx)
- .map_err(|_| ChannelError::Ignore("Signer rejected channel_announcement".to_owned()))?;
- Ok(msgs::ChannelAnnouncement {
- node_signature_1: if were_node_one { our_node_sig } else { their_node_sig },
- node_signature_2: if were_node_one { their_node_sig } else { our_node_sig },
- bitcoin_signature_1: if were_node_one { our_bitcoin_sig } else { their_bitcoin_sig },
- bitcoin_signature_2: if were_node_one { their_bitcoin_sig } else { our_bitcoin_sig },
- contents: announcement,
- })
+ match &self.context.holder_signer {
+ ChannelSignerType::Ecdsa(ecdsa) => {
+ let our_bitcoin_sig = ecdsa.sign_channel_announcement_with_funding_key(&announcement, &self.context.secp_ctx)
+ .map_err(|_| ChannelError::Ignore("Signer rejected channel_announcement".to_owned()))?;
+ Ok(msgs::ChannelAnnouncement {
+ node_signature_1: if were_node_one { our_node_sig } else { their_node_sig },
+ node_signature_2: if were_node_one { their_node_sig } else { our_node_sig },
+ bitcoin_signature_1: if were_node_one { our_bitcoin_sig } else { their_bitcoin_sig },
+ bitcoin_signature_2: if were_node_one { their_bitcoin_sig } else { our_bitcoin_sig },
+ contents: announcement,
+ })
+ }
+ }
} else {
Err(ChannelError::Ignore("Attempted to sign channel announcement before we'd received announcement_signatures".to_string()))
}
/// channel_announcement message which we can broadcast and storing our counterparty's
/// signatures for later reconstruction/rebroadcast of the channel_announcement.
pub fn announcement_signatures<NS: Deref>(
- &mut self, node_signer: &NS, chain_hash: BlockHash, best_block_height: u32,
+ &mut self, node_signer: &NS, chain_hash: ChainHash, best_block_height: u32,
msg: &msgs::AnnouncementSignatures, user_config: &UserConfig
) -> Result<msgs::ChannelAnnouncement, ChannelError> where NS::Target: NodeSigner {
let announcement = self.get_channel_announcement(node_signer, chain_hash, user_config)?;
/// Gets a signed channel_announcement for this channel, if we previously received an
/// announcement_signatures from our counterparty.
pub fn get_signed_channel_announcement<NS: Deref>(
- &self, node_signer: &NS, chain_hash: BlockHash, best_block_height: u32, user_config: &UserConfig
+ &self, node_signer: &NS, chain_hash: ChainHash, best_block_height: u32, user_config: &UserConfig
) -> Option<msgs::ChannelAnnouncement> where NS::Target: NodeSigner {
if self.context.funding_tx_confirmation_height == 0 || self.context.funding_tx_confirmation_height + 5 > best_block_height {
return None;
let dummy_pubkey = PublicKey::from_slice(&pk).unwrap();
let remote_last_secret = if self.context.cur_counterparty_commitment_transaction_number + 1 < INITIAL_COMMITMENT_NUMBER {
let remote_last_secret = self.context.commitment_secrets.get_secret(self.context.cur_counterparty_commitment_transaction_number + 2).unwrap();
- log_trace!(logger, "Enough info to generate a Data Loss Protect with per_commitment_secret {} for channel {}", log_bytes!(remote_last_secret), log_bytes!(self.context.channel_id()));
+ log_trace!(logger, "Enough info to generate a Data Loss Protect with per_commitment_secret {} for channel {}", log_bytes!(remote_last_secret), &self.context.channel_id());
remote_last_secret
} else {
- log_info!(logger, "Sending a data_loss_protect with no previous remote per_commitment_secret for channel {}", log_bytes!(self.context.channel_id()));
+ log_info!(logger, "Sending a data_loss_protect with no previous remote per_commitment_secret for channel {}", &self.context.channel_id());
[0;32]
};
self.mark_awaiting_response();
}
let need_holding_cell = (self.context.channel_state & (ChannelState::AwaitingRemoteRevoke as u32 | ChannelState::MonitorUpdateInProgress as u32)) != 0;
- log_debug!(logger, "Pushing new outbound HTLC for {} msat {}", amount_msat,
+ log_debug!(logger, "Pushing new outbound HTLC with hash {} for {} msat {}",
+ payment_hash, amount_msat,
if force_holding_cell { "into holding cell" }
else if need_holding_cell { "into holding cell as we're awaiting an RAA or monitor" }
else { "to peer" });
Some(InboundHTLCState::AwaitingAnnouncedRemoteRevoke(forward_info.clone()))
} else { None };
if let Some(state) = new_state {
- log_trace!(logger, " ...promoting inbound AwaitingRemoteRevokeToAnnounce {} to AwaitingAnnouncedRemoteRevoke", log_bytes!(htlc.payment_hash.0));
+ log_trace!(logger, " ...promoting inbound AwaitingRemoteRevokeToAnnounce {} to AwaitingAnnouncedRemoteRevoke", &htlc.payment_hash);
htlc.state = state;
}
}
for htlc in self.context.pending_outbound_htlcs.iter_mut() {
if let &mut OutboundHTLCState::AwaitingRemoteRevokeToRemove(ref mut outcome) = &mut htlc.state {
- log_trace!(logger, " ...promoting outbound AwaitingRemoteRevokeToRemove {} to AwaitingRemovedRemoteRevoke", log_bytes!(htlc.payment_hash.0));
+ log_trace!(logger, " ...promoting outbound AwaitingRemoteRevokeToRemove {} to AwaitingRemovedRemoteRevoke", &htlc.payment_hash);
// Grab the preimage, if it exists, instead of cloning
let mut reason = OutboundHTLCOutcome::Success(None);
mem::swap(outcome, &mut reason);
}
self.context.resend_order = RAACommitmentOrder::RevokeAndACKFirst;
- let (counterparty_commitment_txid, mut htlcs_ref) = self.build_commitment_no_state_update(logger);
+ let (mut htlcs_ref, counterparty_commitment_tx) =
+ self.build_commitment_no_state_update(logger);
+ let counterparty_commitment_txid = counterparty_commitment_tx.trust().txid();
let htlcs: Vec<(HTLCOutputInCommitment, Option<Box<HTLCSource>>)> =
htlcs_ref.drain(..).map(|(htlc, htlc_source)| (htlc, htlc_source.map(|source_ref| Box::new(source_ref.clone())))).collect();
commitment_txid: counterparty_commitment_txid,
htlc_outputs: htlcs.clone(),
commitment_number: self.context.cur_counterparty_commitment_transaction_number,
- their_per_commitment_point: self.context.counterparty_cur_commitment_point.unwrap()
+ their_per_commitment_point: self.context.counterparty_cur_commitment_point.unwrap(),
+ feerate_per_kw: Some(counterparty_commitment_tx.feerate_per_kw()),
+ to_broadcaster_value_sat: Some(counterparty_commitment_tx.to_broadcaster_value_sat()),
+ to_countersignatory_value_sat: Some(counterparty_commitment_tx.to_countersignatory_value_sat()),
}]
};
self.context.channel_state |= ChannelState::AwaitingRemoteRevoke as u32;
monitor_update
}
- fn build_commitment_no_state_update<L: Deref>(&self, logger: &L) -> (Txid, Vec<(HTLCOutputInCommitment, Option<&HTLCSource>)>) where L::Target: Logger {
+ fn build_commitment_no_state_update<L: Deref>(&self, logger: &L)
+ -> (Vec<(HTLCOutputInCommitment, Option<&HTLCSource>)>, CommitmentTransaction)
+ where L::Target: Logger
+ {
let counterparty_keys = self.context.build_remote_transaction_keys();
let commitment_stats = self.context.build_commitment_transaction(self.context.cur_counterparty_commitment_transaction_number, &counterparty_keys, false, true, logger);
- let counterparty_commitment_txid = commitment_stats.tx.trust().txid();
+ let counterparty_commitment_tx = commitment_stats.tx;
#[cfg(any(test, fuzzing))]
{
}
}
- (counterparty_commitment_txid, commitment_stats.htlcs_included)
+ (commitment_stats.htlcs_included, counterparty_commitment_tx)
}
/// Only fails in case of signer rejection. Used for channel_reestablish commitment_signed
let counterparty_keys = self.context.build_remote_transaction_keys();
let commitment_stats = self.context.build_commitment_transaction(self.context.cur_counterparty_commitment_transaction_number, &counterparty_keys, false, true, logger);
let counterparty_commitment_txid = commitment_stats.tx.trust().txid();
- let (signature, htlc_signatures);
- {
- let mut htlcs = Vec::with_capacity(commitment_stats.htlcs_included.len());
- for &(ref htlc, _) in commitment_stats.htlcs_included.iter() {
- htlcs.push(htlc);
- }
+ match &self.context.holder_signer {
+ ChannelSignerType::Ecdsa(ecdsa) => {
+ let (signature, htlc_signatures);
- let res = self.context.holder_signer.sign_counterparty_commitment(&commitment_stats.tx, commitment_stats.preimages, &self.context.secp_ctx)
- .map_err(|_| ChannelError::Close("Failed to get signatures for new commitment_signed".to_owned()))?;
- signature = res.0;
- htlc_signatures = res.1;
+ {
+ let mut htlcs = Vec::with_capacity(commitment_stats.htlcs_included.len());
+ for &(ref htlc, _) in commitment_stats.htlcs_included.iter() {
+ htlcs.push(htlc);
+ }
- log_trace!(logger, "Signed remote commitment tx {} (txid {}) with redeemscript {} -> {} in channel {}",
- encode::serialize_hex(&commitment_stats.tx.trust().built_transaction().transaction),
- &counterparty_commitment_txid, encode::serialize_hex(&self.context.get_funding_redeemscript()),
- log_bytes!(signature.serialize_compact()[..]), log_bytes!(self.context.channel_id()));
+ let res = ecdsa.sign_counterparty_commitment(&commitment_stats.tx, commitment_stats.preimages, &self.context.secp_ctx)
+ .map_err(|_| ChannelError::Ignore("Failed to get signatures for new commitment_signed".to_owned()))?;
+ signature = res.0;
+ htlc_signatures = res.1;
+
+ log_trace!(logger, "Signed remote commitment tx {} (txid {}) with redeemscript {} -> {} in channel {}",
+ encode::serialize_hex(&commitment_stats.tx.trust().built_transaction().transaction),
+ &counterparty_commitment_txid, encode::serialize_hex(&self.context.get_funding_redeemscript()),
+ log_bytes!(signature.serialize_compact()[..]), &self.context.channel_id());
+
+ for (ref htlc_sig, ref htlc) in htlc_signatures.iter().zip(htlcs) {
+ log_trace!(logger, "Signed remote HTLC tx {} with redeemscript {} with pubkey {} -> {} in channel {}",
+ encode::serialize_hex(&chan_utils::build_htlc_transaction(&counterparty_commitment_txid, commitment_stats.feerate_per_kw, self.context.get_holder_selected_contest_delay(), htlc, &self.context.channel_type, &counterparty_keys.broadcaster_delayed_payment_key, &counterparty_keys.revocation_key)),
+ encode::serialize_hex(&chan_utils::get_htlc_redeemscript(&htlc, &self.context.channel_type, &counterparty_keys)),
+ log_bytes!(counterparty_keys.broadcaster_htlc_key.serialize()),
+ log_bytes!(htlc_sig.serialize_compact()[..]), &self.context.channel_id());
+ }
+ }
- for (ref htlc_sig, ref htlc) in htlc_signatures.iter().zip(htlcs) {
- log_trace!(logger, "Signed remote HTLC tx {} with redeemscript {} with pubkey {} -> {} in channel {}",
- encode::serialize_hex(&chan_utils::build_htlc_transaction(&counterparty_commitment_txid, commitment_stats.feerate_per_kw, self.context.get_holder_selected_contest_delay(), htlc, &self.context.channel_type, &counterparty_keys.broadcaster_delayed_payment_key, &counterparty_keys.revocation_key)),
- encode::serialize_hex(&chan_utils::get_htlc_redeemscript(&htlc, &self.context.channel_type, &counterparty_keys)),
- log_bytes!(counterparty_keys.broadcaster_htlc_key.serialize()),
- log_bytes!(htlc_sig.serialize_compact()[..]), log_bytes!(self.context.channel_id()));
+ Ok((msgs::CommitmentSigned {
+ channel_id: self.context.channel_id,
+ signature,
+ htlc_signatures,
+ #[cfg(taproot)]
+ partial_signature_with_nonce: None,
+ }, (counterparty_commitment_txid, commitment_stats.htlcs_included)))
}
}
-
- Ok((msgs::CommitmentSigned {
- channel_id: self.context.channel_id,
- signature,
- htlc_signatures,
- #[cfg(taproot)]
- partial_signature_with_nonce: None,
- }, (counterparty_commitment_txid, commitment_stats.htlcs_included)))
}
/// Adds a pending outbound HTLC to this channel, and builds a new remote commitment
}
}
- pub fn channel_update(&mut self, msg: &msgs::ChannelUpdate) -> Result<(), ChannelError> {
- if msg.contents.htlc_minimum_msat >= self.context.channel_value_satoshis * 1000 {
- return Err(ChannelError::Close("Minimum htlc value is greater than channel value".to_string()));
- }
- self.context.counterparty_forwarding_info = Some(CounterpartyForwardingInfo {
+ /// Applies the `ChannelUpdate` and returns a boolean indicating whether a change actually
+ /// happened.
+ pub fn channel_update(&mut self, msg: &msgs::ChannelUpdate) -> Result<bool, ChannelError> {
+ let new_forwarding_info = Some(CounterpartyForwardingInfo {
fee_base_msat: msg.contents.fee_base_msat,
fee_proportional_millionths: msg.contents.fee_proportional_millionths,
cltv_expiry_delta: msg.contents.cltv_expiry_delta
});
+ let did_change = self.context.counterparty_forwarding_info != new_forwarding_info;
+ if did_change {
+ self.context.counterparty_forwarding_info = new_forwarding_info;
+ }
- Ok(())
+ Ok(did_change)
}
/// Begins the shutdown process, getting a message for the remote peer and returning all
///
/// May jump to the channel being fully shutdown (see [`Self::is_shutdown`]) in which case no
/// [`ChannelMonitorUpdate`] will be returned).
- pub fn get_shutdown<SP: Deref>(&mut self, signer_provider: &SP, their_features: &InitFeatures,
+ pub fn get_shutdown(&mut self, signer_provider: &SP, their_features: &InitFeatures,
target_feerate_sats_per_kw: Option<u32>, override_shutdown_script: Option<ShutdownScript>)
- -> Result<(msgs::Shutdown, Option<ChannelMonitorUpdate>, Vec<(HTLCSource, PaymentHash)>), APIError>
- where SP::Target: SignerProvider {
+ -> Result<(msgs::Shutdown, Option<ChannelMonitorUpdate>, Vec<(HTLCSource, PaymentHash)>, Option<ShutdownResult>), APIError>
+ {
for htlc in self.context.pending_outbound_htlcs.iter() {
if let OutboundHTLCState::LocalAnnounced(_) = htlc.state {
return Err(APIError::APIMisuseError{err: "Cannot begin shutdown with pending HTLCs. Process pending events first".to_owned()});
// If we haven't funded the channel yet, we don't need to bother ensuring the shutdown
// script is set, we just force-close and call it a day.
let mut chan_closed = false;
- if self.context.channel_state < ChannelState::FundingSent as u32 {
+ if self.context.channel_state & !STATE_FLAGS < ChannelState::FundingSent as u32 {
chan_closed = true;
}
// From here on out, we may not fail!
self.context.target_closing_feerate_sats_per_kw = target_feerate_sats_per_kw;
- if self.context.channel_state < ChannelState::FundingSent as u32 {
+ let shutdown_result = if self.context.channel_state & !STATE_FLAGS < ChannelState::FundingSent as u32 {
+ let shutdown_result = ShutdownResult {
+ monitor_update: None,
+ dropped_outbound_htlcs: Vec::new(),
+ unbroadcasted_batch_funding_txid: self.context.unbroadcasted_batch_funding_txid(),
+ };
self.context.channel_state = ChannelState::ShutdownComplete as u32;
+ Some(shutdown_result)
} else {
self.context.channel_state |= ChannelState::LocalShutdownSent as u32;
- }
+ None
+ };
self.context.update_time_counter += 1;
let monitor_update = if update_shutdown_script {
debug_assert!(!self.is_shutdown() || monitor_update.is_none(),
"we can't both complete shutdown and return a monitor update");
- Ok((shutdown, monitor_update, dropped_outbound_htlcs))
+ Ok((shutdown, monitor_update, dropped_outbound_htlcs, shutdown_result))
}
pub fn inflight_htlc_sources(&self) -> impl Iterator<Item=(&HTLCSource, &PaymentHash)> {
}
/// A not-yet-funded outbound (from holder) channel using V1 channel establishment.
-pub(super) struct OutboundV1Channel<Signer: ChannelSigner> {
- pub context: ChannelContext<Signer>,
+pub(super) struct OutboundV1Channel<SP: Deref> where SP::Target: SignerProvider {
+ pub context: ChannelContext<SP>,
pub unfunded_context: UnfundedChannelContext,
}
-impl<Signer: WriteableEcdsaChannelSigner> OutboundV1Channel<Signer> {
- pub fn new<ES: Deref, SP: Deref, F: Deref>(
+impl<SP: Deref> OutboundV1Channel<SP> where SP::Target: SignerProvider {
+ pub fn new<ES: Deref, F: Deref>(
fee_estimator: &LowerBoundedFeeEstimator<F>, entropy_source: &ES, signer_provider: &SP, counterparty_node_id: PublicKey, their_features: &InitFeatures,
channel_value_satoshis: u64, push_msat: u64, user_id: u128, config: &UserConfig, current_chain_height: u32,
- outbound_scid_alias: u64
- ) -> Result<OutboundV1Channel<Signer>, APIError>
+ outbound_scid_alias: u64, temporary_channel_id: Option<ChannelId>
+ ) -> Result<OutboundV1Channel<SP>, APIError>
where ES::Target: EntropySource,
- SP::Target: SignerProvider<Signer = Signer>,
- F::Target: FeeEstimator,
+ F::Target: FeeEstimator
{
let holder_selected_contest_delay = config.channel_handshake_config.our_to_self_delay;
let channel_keys_id = signer_provider.generate_channel_keys_id(false, channel_value_satoshis, user_id);
let channel_type = Self::get_initial_channel_type(&config, their_features);
debug_assert!(channel_type.is_subset(&channelmanager::provided_channel_type_features(&config)));
- let commitment_conf_target = if channel_type.supports_anchors_zero_fee_htlc_tx() {
- ConfirmationTarget::MempoolMinimum
+ let (commitment_conf_target, anchor_outputs_value_msat) = if channel_type.supports_anchors_zero_fee_htlc_tx() {
+ (ConfirmationTarget::AnchorChannelFee, ANCHOR_OUTPUT_VALUE_SATOSHI * 2 * 1000)
} else {
- ConfirmationTarget::Normal
+ (ConfirmationTarget::NonAnchorChannelFee, 0)
};
let commitment_feerate = fee_estimator.bounded_sat_per_1000_weight(commitment_conf_target);
let value_to_self_msat = channel_value_satoshis * 1000 - push_msat;
let commitment_tx_fee = commit_tx_fee_msat(commitment_feerate, MIN_AFFORDABLE_HTLC_COUNT, &channel_type);
- if value_to_self_msat < commitment_tx_fee {
+ if value_to_self_msat.saturating_sub(anchor_outputs_value_msat) < commitment_tx_fee {
return Err(APIError::APIMisuseError{ err: format!("Funding amount ({}) can't even pay fee for initial commitment transaction fee of {}.", value_to_self_msat / 1000, commitment_tx_fee / 1000) });
}
Err(_) => return Err(APIError::ChannelUnavailable { err: "Failed to get destination script".to_owned()}),
};
- let temporary_channel_id = entropy_source.get_secure_random_bytes();
+ let temporary_channel_id = temporary_channel_id.unwrap_or_else(|| ChannelId::temporary_from_entropy_source(entropy_source));
Ok(Self {
context: ChannelContext {
latest_monitor_update_id: 0,
- holder_signer,
+ holder_signer: ChannelSignerType::Ecdsa(holder_signer),
shutdown_scriptpubkey,
destination_script,
monitor_pending_failures: Vec::new(),
monitor_pending_finalized_fulfills: Vec::new(),
+ signer_pending_commitment_update: false,
+ signer_pending_funding: false,
+
#[cfg(debug_assertions)]
holder_max_commitment_tx_output: Mutex::new((channel_value_satoshis * 1000 - push_msat, push_msat)),
#[cfg(debug_assertions)]
channel_type_features: channel_type.clone()
},
funding_transaction: None,
+ is_batch_funding: None,
counterparty_cur_commitment_point: None,
counterparty_prev_commitment_point: None,
})
}
- /// If an Err is returned, it is a ChannelError::Close (for get_funding_created)
- fn get_funding_created_signature<L: Deref>(&mut self, logger: &L) -> Result<Signature, ChannelError> where L::Target: Logger {
- let counterparty_keys = self.context.build_remote_transaction_keys();
- let counterparty_initial_commitment_tx = self.context.build_commitment_transaction(self.context.cur_counterparty_commitment_transaction_number, &counterparty_keys, false, false, logger).tx;
- Ok(self.context.holder_signer.sign_counterparty_commitment(&counterparty_initial_commitment_tx, Vec::new(), &self.context.secp_ctx)
- .map_err(|_| ChannelError::Close("Failed to get signatures for new commitment_signed".to_owned()))?.0)
- }
-
/// Updates channel state with knowledge of the funding transaction's txid/index, and generates
/// a funding_created message for the remote peer.
/// Panics if called at some time other than immediately after initial handshake, if called twice,
/// Note that channel_id changes during this call!
/// Do NOT broadcast the funding transaction until after a successful funding_signed call!
/// If an Err is returned, it is a ChannelError::Close.
- pub fn get_funding_created<L: Deref>(mut self, funding_transaction: Transaction, funding_txo: OutPoint, logger: &L)
- -> Result<(Channel<Signer>, msgs::FundingCreated), (Self, ChannelError)> where L::Target: Logger {
+ pub fn get_funding_created<L: Deref>(mut self, funding_transaction: Transaction, funding_txo: OutPoint, is_batch_funding: bool, logger: &L)
+ -> Result<(Channel<SP>, Option<msgs::FundingCreated>), (Self, ChannelError)> where L::Target: Logger {
if !self.context.is_outbound() {
panic!("Tried to create outbound funding_created message on an inbound channel!");
}
}
self.context.channel_transaction_parameters.funding_outpoint = Some(funding_txo);
- self.context.holder_signer.provide_channel_parameters(&self.context.channel_transaction_parameters);
-
- let signature = match self.get_funding_created_signature(logger) {
- Ok(res) => res,
- Err(e) => {
- log_error!(logger, "Got bad signatures: {:?}!", e);
- self.context.channel_transaction_parameters.funding_outpoint = None;
- return Err((self, e));
- }
- };
-
- let temporary_channel_id = self.context.channel_id;
+ self.context.holder_signer.as_mut().provide_channel_parameters(&self.context.channel_transaction_parameters);
// Now that we're past error-generating stuff, update our local state:
self.context.channel_state = ChannelState::FundingCreated as u32;
self.context.channel_id = funding_txo.to_channel_id();
+
+ // If the funding transaction is a coinbase transaction, we need to set the minimum depth to 100.
+ // We can skip this if it is a zero-conf channel.
+ if funding_transaction.is_coin_base() &&
+ self.context.minimum_depth.unwrap_or(0) > 0 &&
+ self.context.minimum_depth.unwrap_or(0) < COINBASE_MATURITY {
+ self.context.minimum_depth = Some(COINBASE_MATURITY);
+ }
+
self.context.funding_transaction = Some(funding_transaction);
+ self.context.is_batch_funding = Some(()).filter(|_| is_batch_funding);
+
+ let funding_created = self.context.get_funding_created_msg(logger);
+ if funding_created.is_none() {
+ if !self.context.signer_pending_funding {
+ log_trace!(logger, "funding_created awaiting signer; setting signer_pending_funding");
+ self.context.signer_pending_funding = true;
+ }
+ }
let channel = Channel {
context: self.context,
};
- Ok((channel, msgs::FundingCreated {
- temporary_channel_id,
- funding_txid: funding_txo.txid,
- funding_output_index: funding_txo.index,
- signature,
- #[cfg(taproot)]
- partial_signature_with_nonce: None,
- #[cfg(taproot)]
- next_local_nonce: None,
- }))
+ Ok((channel, funding_created))
}
fn get_initial_channel_type(config: &UserConfig, their_features: &InitFeatures) -> ChannelTypeFeatures {
/// not of our ability to open any channel at all. Thus, on error, we should first call this
/// and see if we get a new `OpenChannel` message, otherwise the channel is failed.
pub(crate) fn maybe_handle_error_without_close<F: Deref>(
- &mut self, chain_hash: BlockHash, fee_estimator: &LowerBoundedFeeEstimator<F>
+ &mut self, chain_hash: ChainHash, fee_estimator: &LowerBoundedFeeEstimator<F>
) -> Result<msgs::OpenChannel, ()>
where
F::Target: FeeEstimator
// whatever reason.
if self.context.channel_type.supports_anchors_zero_fee_htlc_tx() {
self.context.channel_type.clear_anchors_zero_fee_htlc_tx();
- self.context.feerate_per_kw = fee_estimator.bounded_sat_per_1000_weight(ConfirmationTarget::Normal);
+ self.context.feerate_per_kw = fee_estimator.bounded_sat_per_1000_weight(ConfirmationTarget::NonAnchorChannelFee);
assert!(!self.context.channel_transaction_parameters.channel_type_features.supports_anchors_nonzero_fee_htlc_tx());
} else if self.context.channel_type.supports_scid_privacy() {
self.context.channel_type.clear_scid_privacy();
Ok(self.get_open_channel(chain_hash))
}
- pub fn get_open_channel(&self, chain_hash: BlockHash) -> msgs::OpenChannel {
+ pub fn get_open_channel(&self, chain_hash: ChainHash) -> msgs::OpenChannel {
if !self.context.is_outbound() {
panic!("Tried to open a channel for an inbound channel?");
}
panic!("Tried to send an open_channel for a channel that has already advanced");
}
- let first_per_commitment_point = self.context.holder_signer.get_per_commitment_point(self.context.cur_holder_commitment_transaction_number, &self.context.secp_ctx);
+ let first_per_commitment_point = self.context.holder_signer.as_ref().get_per_commitment_point(self.context.cur_holder_commitment_transaction_number, &self.context.secp_ctx);
let keys = self.context.get_holder_pubkeys();
msgs::OpenChannel {
}
/// A not-yet-funded inbound (from counterparty) channel using V1 channel establishment.
-pub(super) struct InboundV1Channel<Signer: ChannelSigner> {
- pub context: ChannelContext<Signer>,
+pub(super) struct InboundV1Channel<SP: Deref> where SP::Target: SignerProvider {
+ pub context: ChannelContext<SP>,
pub unfunded_context: UnfundedChannelContext,
}
-impl<Signer: WriteableEcdsaChannelSigner> InboundV1Channel<Signer> {
+impl<SP: Deref> InboundV1Channel<SP> where SP::Target: SignerProvider {
/// Creates a new channel from a remote sides' request for one.
/// Assumes chain_hash has already been checked and corresponds with what we expect!
- pub fn new<ES: Deref, SP: Deref, F: Deref, L: Deref>(
+ pub fn new<ES: Deref, F: Deref, L: Deref>(
fee_estimator: &LowerBoundedFeeEstimator<F>, entropy_source: &ES, signer_provider: &SP,
counterparty_node_id: PublicKey, our_supported_features: &ChannelTypeFeatures,
their_features: &InitFeatures, msg: &msgs::OpenChannel, user_id: u128, config: &UserConfig,
current_chain_height: u32, logger: &L, is_0conf: bool,
- ) -> Result<InboundV1Channel<Signer>, ChannelError>
+ ) -> Result<InboundV1Channel<SP>, ChannelError>
where ES::Target: EntropySource,
- SP::Target: SignerProvider<Signer = Signer>,
F::Target: FeeEstimator,
L::Target: Logger,
{
if msg.htlc_minimum_msat >= full_channel_value_msat {
return Err(ChannelError::Close(format!("Minimum htlc value ({}) was larger than full channel value ({})", msg.htlc_minimum_msat, full_channel_value_msat)));
}
- Channel::<Signer>::check_remote_fee(&channel_type, fee_estimator, msg.feerate_per_kw, None, logger)?;
+ Channel::<SP>::check_remote_fee(&channel_type, fee_estimator, msg.feerate_per_kw, None, logger)?;
let max_counterparty_selected_contest_delay = u16::min(config.channel_handshake_limits.their_to_self_delay, MAX_LOCAL_BREAKDOWN_TIMEOUT);
if msg.to_self_delay > max_counterparty_selected_contest_delay {
// check if the funder's amount for the initial commitment tx is sufficient
// for full fee payment plus a few HTLCs to ensure the channel will be useful.
+ let anchor_outputs_value = if channel_type.supports_anchors_zero_fee_htlc_tx() {
+ ANCHOR_OUTPUT_VALUE_SATOSHI * 2
+ } else {
+ 0
+ };
let funders_amount_msat = msg.funding_satoshis * 1000 - msg.push_msat;
let commitment_tx_fee = commit_tx_fee_msat(msg.feerate_per_kw, MIN_AFFORDABLE_HTLC_COUNT, &channel_type) / 1000;
- if funders_amount_msat / 1000 < commitment_tx_fee {
- return Err(ChannelError::Close(format!("Funding amount ({} sats) can't even pay fee for initial commitment transaction fee of {} sats.", funders_amount_msat / 1000, commitment_tx_fee)));
+ if (funders_amount_msat / 1000).saturating_sub(anchor_outputs_value) < commitment_tx_fee {
+ return Err(ChannelError::Close(format!("Funding amount ({} sats) can't even pay fee for initial commitment transaction fee of {} sats.", (funders_amount_msat / 1000).saturating_sub(anchor_outputs_value), commitment_tx_fee)));
}
- let to_remote_satoshis = funders_amount_msat / 1000 - commitment_tx_fee;
+ let to_remote_satoshis = funders_amount_msat / 1000 - commitment_tx_fee - anchor_outputs_value;
// While it's reasonable for us to not meet the channel reserve initially (if they don't
// want to push much to us), our counterparty should always have more than our reserve.
if to_remote_satoshis < holder_selected_channel_reserve_satoshis {
latest_monitor_update_id: 0,
- holder_signer,
+ holder_signer: ChannelSignerType::Ecdsa(holder_signer),
shutdown_scriptpubkey,
destination_script,
monitor_pending_failures: Vec::new(),
monitor_pending_finalized_fulfills: Vec::new(),
+ signer_pending_commitment_update: false,
+ signer_pending_funding: false,
+
#[cfg(debug_assertions)]
holder_max_commitment_tx_output: Mutex::new((msg.push_msat, msg.funding_satoshis * 1000 - msg.push_msat)),
#[cfg(debug_assertions)]
channel_type_features: channel_type.clone()
},
funding_transaction: None,
+ is_batch_funding: None,
counterparty_cur_commitment_point: Some(msg.first_per_commitment_point),
counterparty_prev_commitment_point: None,
///
/// [`msgs::AcceptChannel`]: crate::ln::msgs::AcceptChannel
fn generate_accept_channel_message(&self) -> msgs::AcceptChannel {
- let first_per_commitment_point = self.context.holder_signer.get_per_commitment_point(self.context.cur_holder_commitment_transaction_number, &self.context.secp_ctx);
+ let first_per_commitment_point = self.context.holder_signer.as_ref().get_per_commitment_point(self.context.cur_holder_commitment_transaction_number, &self.context.secp_ctx);
let keys = self.context.get_holder_pubkeys();
msgs::AcceptChannel {
self.generate_accept_channel_message()
}
- fn funding_created_signature<L: Deref>(&mut self, sig: &Signature, logger: &L) -> Result<(Txid, CommitmentTransaction, Signature), ChannelError> where L::Target: Logger {
+ fn check_funding_created_signature<L: Deref>(&mut self, sig: &Signature, logger: &L) -> Result<CommitmentTransaction, ChannelError> where L::Target: Logger {
let funding_script = self.context.get_funding_redeemscript();
let keys = self.context.build_holder_transaction_keys(self.context.cur_holder_commitment_transaction_number);
let initial_commitment_tx = self.context.build_commitment_transaction(self.context.cur_holder_commitment_transaction_number, &keys, true, false, logger).tx;
- {
- let trusted_tx = initial_commitment_tx.trust();
- let initial_commitment_bitcoin_tx = trusted_tx.built_transaction();
- let sighash = initial_commitment_bitcoin_tx.get_sighash_all(&funding_script, self.context.channel_value_satoshis);
- // They sign the holder commitment transaction...
- log_trace!(logger, "Checking funding_created tx signature {} by key {} against tx {} (sighash {}) with redeemscript {} for channel {}.",
- log_bytes!(sig.serialize_compact()[..]), log_bytes!(self.context.counterparty_funding_pubkey().serialize()),
- encode::serialize_hex(&initial_commitment_bitcoin_tx.transaction), log_bytes!(sighash[..]),
- encode::serialize_hex(&funding_script), log_bytes!(self.context.channel_id()));
- secp_check!(self.context.secp_ctx.verify_ecdsa(&sighash, &sig, self.context.counterparty_funding_pubkey()), "Invalid funding_created signature from peer".to_owned());
- }
+ let trusted_tx = initial_commitment_tx.trust();
+ let initial_commitment_bitcoin_tx = trusted_tx.built_transaction();
+ let sighash = initial_commitment_bitcoin_tx.get_sighash_all(&funding_script, self.context.channel_value_satoshis);
+ // They sign the holder commitment transaction...
+ log_trace!(logger, "Checking funding_created tx signature {} by key {} against tx {} (sighash {}) with redeemscript {} for channel {}.",
+ log_bytes!(sig.serialize_compact()[..]), log_bytes!(self.context.counterparty_funding_pubkey().serialize()),
+ encode::serialize_hex(&initial_commitment_bitcoin_tx.transaction), log_bytes!(sighash[..]),
+ encode::serialize_hex(&funding_script), &self.context.channel_id());
+ secp_check!(self.context.secp_ctx.verify_ecdsa(&sighash, &sig, self.context.counterparty_funding_pubkey()), "Invalid funding_created signature from peer".to_owned());
- let counterparty_keys = self.context.build_remote_transaction_keys();
- let counterparty_initial_commitment_tx = self.context.build_commitment_transaction(self.context.cur_counterparty_commitment_transaction_number, &counterparty_keys, false, false, logger).tx;
-
- let counterparty_trusted_tx = counterparty_initial_commitment_tx.trust();
- let counterparty_initial_bitcoin_tx = counterparty_trusted_tx.built_transaction();
- log_trace!(logger, "Initial counterparty tx for channel {} is: txid {} tx {}",
- log_bytes!(self.context.channel_id()), counterparty_initial_bitcoin_tx.txid, encode::serialize_hex(&counterparty_initial_bitcoin_tx.transaction));
-
- let counterparty_signature = self.context.holder_signer.sign_counterparty_commitment(&counterparty_initial_commitment_tx, Vec::new(), &self.context.secp_ctx)
- .map_err(|_| ChannelError::Close("Failed to get signatures for new commitment_signed".to_owned()))?.0;
-
- // We sign "counterparty" commitment transaction, allowing them to broadcast the tx if they wish.
- Ok((counterparty_initial_bitcoin_tx.txid, initial_commitment_tx, counterparty_signature))
+ Ok(initial_commitment_tx)
}
- pub fn funding_created<SP: Deref, L: Deref>(
+ pub fn funding_created<L: Deref>(
mut self, msg: &msgs::FundingCreated, best_block: BestBlock, signer_provider: &SP, logger: &L
- ) -> Result<(Channel<Signer>, msgs::FundingSigned, ChannelMonitor<Signer>), (Self, ChannelError)>
+ ) -> Result<(Channel<SP>, Option<msgs::FundingSigned>, ChannelMonitor<<SP::Target as SignerProvider>::Signer>), (Self, ChannelError)>
where
- SP::Target: SignerProvider<Signer = Signer>,
L::Target: Logger
{
if self.context.is_outbound() {
let funding_txo = OutPoint { txid: msg.funding_txid, index: msg.funding_output_index };
self.context.channel_transaction_parameters.funding_outpoint = Some(funding_txo);
// This is an externally observable change before we finish all our checks. In particular
- // funding_created_signature may fail.
- self.context.holder_signer.provide_channel_parameters(&self.context.channel_transaction_parameters);
+ // check_funding_created_signature may fail.
+ self.context.holder_signer.as_mut().provide_channel_parameters(&self.context.channel_transaction_parameters);
- let (counterparty_initial_commitment_txid, initial_commitment_tx, signature) = match self.funding_created_signature(&msg.signature, logger) {
+ let initial_commitment_tx = match self.check_funding_created_signature(&msg.signature, logger) {
Ok(res) => res,
Err(ChannelError::Close(e)) => {
self.context.channel_transaction_parameters.funding_outpoint = None;
Err(e) => {
// The only error we know how to handle is ChannelError::Close, so we fall over here
// to make sure we don't continue with an inconsistent state.
- panic!("unexpected error type from funding_created_signature {:?}", e);
+ panic!("unexpected error type from check_funding_created_signature {:?}", e);
}
};
self.context.counterparty_funding_pubkey()
);
- if let Err(_) = self.context.holder_signer.validate_holder_commitment(&holder_commitment_tx, Vec::new()) {
+ if let Err(_) = self.context.holder_signer.as_ref().validate_holder_commitment(&holder_commitment_tx, Vec::new()) {
return Err((self, ChannelError::Close("Failed to validate our commitment".to_owned())));
}
// Now that we're past error-generating stuff, update our local state:
+ self.context.channel_state = ChannelState::FundingSent as u32;
+ self.context.channel_id = funding_txo.to_channel_id();
+ self.context.cur_counterparty_commitment_transaction_number -= 1;
+ self.context.cur_holder_commitment_transaction_number -= 1;
+
+ let (counterparty_initial_commitment_tx, funding_signed) = self.context.get_funding_signed_msg(logger);
+
let funding_redeemscript = self.context.get_funding_redeemscript();
let funding_txo_script = funding_redeemscript.to_v0_p2wsh();
let obscure_factor = get_commitment_transaction_number_obscure_factor(&self.context.get_holder_pubkeys().payment_point, &self.context.get_counterparty_pubkeys().payment_point, self.context.is_outbound());
obscure_factor,
holder_commitment_tx, best_block, self.context.counterparty_node_id);
- channel_monitor.provide_latest_counterparty_commitment_tx(counterparty_initial_commitment_txid, Vec::new(), self.context.cur_counterparty_commitment_transaction_number, self.context.counterparty_cur_commitment_point.unwrap(), logger);
-
- self.context.channel_state = ChannelState::FundingSent as u32;
- self.context.channel_id = funding_txo.to_channel_id();
- self.context.cur_counterparty_commitment_transaction_number -= 1;
- self.context.cur_holder_commitment_transaction_number -= 1;
+ channel_monitor.provide_initial_counterparty_commitment_tx(
+ counterparty_initial_commitment_tx.trust().txid(), Vec::new(),
+ self.context.cur_counterparty_commitment_transaction_number + 1,
+ self.context.counterparty_cur_commitment_point.unwrap(), self.context.feerate_per_kw,
+ counterparty_initial_commitment_tx.to_broadcaster_value_sat(),
+ counterparty_initial_commitment_tx.to_countersignatory_value_sat(), logger);
- log_info!(logger, "Generated funding_signed for peer for channel {}", log_bytes!(self.context.channel_id()));
+ log_info!(logger, "{} funding_signed for peer for channel {}",
+ if funding_signed.is_some() { "Generated" } else { "Waiting for signature on" }, &self.context.channel_id());
// Promote the channel to a full-fledged one now that we have updated the state and have a
// `ChannelMonitor`.
let mut channel = Channel {
context: self.context,
};
- let channel_id = channel.context.channel_id.clone();
let need_channel_ready = channel.check_get_channel_ready(0).is_some();
channel.monitor_updating_paused(false, false, need_channel_ready, Vec::new(), Vec::new(), Vec::new());
- Ok((channel, msgs::FundingSigned {
- channel_id,
- signature,
- #[cfg(taproot)]
- partial_signature_with_nonce: None,
- }, channel_monitor))
+ Ok((channel, funding_signed, channel_monitor))
}
}
const SERIALIZATION_VERSION: u8 = 3;
-const MIN_SERIALIZATION_VERSION: u8 = 2;
+const MIN_SERIALIZATION_VERSION: u8 = 3;
impl_writeable_tlv_based_enum!(InboundHTLCRemovalReason,;
(0, FailRelay),
}
}
-impl<Signer: WriteableEcdsaChannelSigner> Writeable for Channel<Signer> {
+impl<SP: Deref> Writeable for Channel<SP> where SP::Target: SignerProvider {
fn write<W: Writer>(&self, writer: &mut W) -> Result<(), io::Error> {
// Note that we write out as if remove_uncommitted_htlcs_and_mark_paused had just been
// called.
self.context.latest_monitor_update_id.write(writer)?;
- let mut key_data = VecWriter(Vec::new());
- self.context.holder_signer.write(&mut key_data)?;
- assert!(key_data.0.len() < core::usize::MAX);
- assert!(key_data.0.len() < core::u32::MAX as usize);
- (key_data.0.len() as u32).write(writer)?;
- writer.write_all(&key_data.0[..])?;
-
// Write out the old serialization for shutdown_pubkey for backwards compatibility, if
// deserialized from that format.
match self.context.shutdown_scriptpubkey.as_ref().and_then(|script| script.as_legacy_pubkey()) {
(31, channel_pending_event_emitted, option),
(35, pending_outbound_skimmed_fees, optional_vec),
(37, holding_cell_skimmed_fees, optional_vec),
+ (38, self.context.is_batch_funding, option),
});
Ok(())
}
const MAX_ALLOC_SIZE: usize = 64*1024;
-impl<'a, 'b, 'c, ES: Deref, SP: Deref> ReadableArgs<(&'a ES, &'b SP, u32, &'c ChannelTypeFeatures)> for Channel<<SP::Target as SignerProvider>::Signer>
+impl<'a, 'b, 'c, ES: Deref, SP: Deref> ReadableArgs<(&'a ES, &'b SP, u32, &'c ChannelTypeFeatures)> for Channel<SP>
where
ES::Target: EntropySource,
SP::Target: SignerProvider
};
let mut channel_parameters: ChannelTransactionParameters = Readable::read(reader)?;
- let funding_transaction = Readable::read(reader)?;
+ let funding_transaction: Option<Transaction> = Readable::read(reader)?;
let counterparty_cur_commitment_point = Readable::read(reader)?;
let mut user_id_high_opt: Option<u64> = None;
let mut channel_keys_id: Option<[u8; 32]> = None;
- let mut temporary_channel_id: Option<[u8; 32]> = None;
+ let mut temporary_channel_id: Option<ChannelId> = None;
let mut holder_max_accepted_htlcs: Option<u16> = None;
let mut blocked_monitor_updates = Some(Vec::new());
let mut pending_outbound_skimmed_fees_opt: Option<Vec<Option<u64>>> = None;
let mut holding_cell_skimmed_fees_opt: Option<Vec<Option<u64>>> = None;
+ let mut is_batch_funding: Option<()> = None;
+
read_tlv_fields!(reader, {
(0, announcement_sigs, option),
(1, minimum_depth, option),
(31, channel_pending_event_emitted, option),
(35, pending_outbound_skimmed_fees_opt, optional_vec),
(37, holding_cell_skimmed_fees_opt, optional_vec),
+ (38, is_batch_funding, option),
});
let (channel_keys_id, holder_signer) = if let Some(channel_keys_id) = channel_keys_id {
// If we've gotten to the funding stage of the channel, populate the signer with its
// required channel parameters.
let non_shutdown_state = channel_state & (!MULTI_STATE_FLAGS);
- if non_shutdown_state >= (ChannelState::FundingCreated as u32) {
+ if non_shutdown_state & !STATE_FLAGS >= (ChannelState::FundingCreated as u32) {
holder_signer.provide_channel_parameters(&channel_parameters);
}
(channel_keys_id, holder_signer)
latest_monitor_update_id,
- holder_signer,
+ holder_signer: ChannelSignerType::Ecdsa(holder_signer),
shutdown_scriptpubkey,
destination_script,
monitor_pending_failures,
monitor_pending_finalized_fulfills: monitor_pending_finalized_fulfills.unwrap(),
+ signer_pending_commitment_update: false,
+ signer_pending_funding: false,
+
pending_update_fee,
holding_cell_update_fee,
next_holder_htlc_id,
channel_transaction_parameters: channel_parameters,
funding_transaction,
+ is_batch_funding,
counterparty_cur_commitment_point,
counterparty_prev_commitment_point,
#[cfg(test)]
mod tests {
use std::cmp;
+ use bitcoin::blockdata::constants::ChainHash;
use bitcoin::blockdata::script::{Script, Builder};
use bitcoin::blockdata::transaction::{Transaction, TxOut};
- use bitcoin::blockdata::constants::genesis_block;
use bitcoin::blockdata::opcodes;
use bitcoin::network::constants::Network;
use hex;
use crate::ln::PaymentHash;
use crate::ln::channelmanager::{self, HTLCSource, PaymentId};
use crate::ln::channel::InitFeatures;
- use crate::ln::channel::{Channel, InboundHTLCOutput, OutboundV1Channel, InboundV1Channel, OutboundHTLCOutput, InboundHTLCState, OutboundHTLCState, HTLCCandidate, HTLCInitiator, commit_tx_fee_msat};
+ use crate::ln::channel::{Channel, ChannelState, InboundHTLCOutput, OutboundV1Channel, InboundV1Channel, OutboundHTLCOutput, InboundHTLCState, OutboundHTLCState, HTLCCandidate, HTLCInitiator, commit_tx_fee_msat};
use crate::ln::channel::{MAX_FUNDING_SATOSHIS_NO_WUMBO, TOTAL_BITCOIN_SUPPLY_SATOSHIS, MIN_THEIR_CHAN_RESERVE_SATOSHIS};
use crate::ln::features::ChannelTypeFeatures;
use crate::ln::msgs::{ChannelUpdate, DecodeError, UnsignedChannelUpdate, MAX_VALUE_MSAT};
use crate::chain::transaction::OutPoint;
use crate::routing::router::Path;
use crate::util::config::UserConfig;
- use crate::util::enforcing_trait_impls::EnforcingSigner;
use crate::util::errors::APIError;
use crate::util::test_utils;
- use crate::util::test_utils::OnGetShutdownScriptpubkey;
+ use crate::util::test_utils::{OnGetShutdownScriptpubkey, TestKeysInterface};
use bitcoin::secp256k1::{Secp256k1, ecdsa::Signature};
use bitcoin::secp256k1::ffi::Signature as FFISignature;
use bitcoin::secp256k1::{SecretKey,PublicKey};
// arithmetic, causing a panic with debug assertions enabled.
let fee_est = TestFeeEstimator { fee_est: 42 };
let bounded_fee_estimator = LowerBoundedFeeEstimator::new(&fee_est);
- assert!(Channel::<InMemorySigner>::check_remote_fee(
+ assert!(Channel::<&TestKeysInterface>::check_remote_fee(
&ChannelTypeFeatures::only_static_remote_key(), &bounded_fee_estimator,
u32::max_value(), None, &&test_utils::TestLogger::new()).is_err());
}
let secp_ctx = Secp256k1::new();
let node_id = PublicKey::from_secret_key(&secp_ctx, &SecretKey::from_slice(&[42; 32]).unwrap());
let config = UserConfig::default();
- match OutboundV1Channel::<EnforcingSigner>::new(&LowerBoundedFeeEstimator::new(&TestFeeEstimator { fee_est: 253 }), &&keys_provider, &&keys_provider, node_id, &features, 10000000, 100000, 42, &config, 0, 42) {
+ match OutboundV1Channel::<&TestKeysInterface>::new(&LowerBoundedFeeEstimator::new(&TestFeeEstimator { fee_est: 253 }), &&keys_provider, &&keys_provider, node_id, &features, 10000000, 100000, 42, &config, 0, 42, None) {
Err(APIError::IncompatibleShutdownScript { script }) => {
assert_eq!(script.into_inner(), non_v0_segwit_shutdown_script.into_inner());
},
let node_a_node_id = PublicKey::from_secret_key(&secp_ctx, &SecretKey::from_slice(&[42; 32]).unwrap());
let config = UserConfig::default();
- let node_a_chan = OutboundV1Channel::<EnforcingSigner>::new(&bounded_fee_estimator, &&keys_provider, &&keys_provider, node_a_node_id, &channelmanager::provided_init_features(&config), 10000000, 100000, 42, &config, 0, 42).unwrap();
+ let node_a_chan = OutboundV1Channel::<&TestKeysInterface>::new(&bounded_fee_estimator, &&keys_provider, &&keys_provider, node_a_node_id, &channelmanager::provided_init_features(&config), 10000000, 100000, 42, &config, 0, 42, None).unwrap();
// Now change the fee so we can check that the fee in the open_channel message is the
// same as the old fee.
fee_est.fee_est = 500;
- let open_channel_msg = node_a_chan.get_open_channel(genesis_block(network).header.block_hash());
+ let open_channel_msg = node_a_chan.get_open_channel(ChainHash::using_genesis_block(network));
assert_eq!(open_channel_msg.feerate_per_kw, original_fee);
}
// Create Node A's channel pointing to Node B's pubkey
let node_b_node_id = PublicKey::from_secret_key(&secp_ctx, &SecretKey::from_slice(&[42; 32]).unwrap());
let config = UserConfig::default();
- let mut node_a_chan = OutboundV1Channel::<EnforcingSigner>::new(&feeest, &&keys_provider, &&keys_provider, node_b_node_id, &channelmanager::provided_init_features(&config), 10000000, 100000, 42, &config, 0, 42).unwrap();
+ let mut node_a_chan = OutboundV1Channel::<&TestKeysInterface>::new(&feeest, &&keys_provider, &&keys_provider, node_b_node_id, &channelmanager::provided_init_features(&config), 10000000, 100000, 42, &config, 0, 42, None).unwrap();
// Create Node B's channel by receiving Node A's open_channel message
// Make sure A's dust limit is as we expect.
- let open_channel_msg = node_a_chan.get_open_channel(genesis_block(network).header.block_hash());
+ let open_channel_msg = node_a_chan.get_open_channel(ChainHash::using_genesis_block(network));
let node_b_node_id = PublicKey::from_secret_key(&secp_ctx, &SecretKey::from_slice(&[7; 32]).unwrap());
- let mut node_b_chan = InboundV1Channel::<EnforcingSigner>::new(&feeest, &&keys_provider, &&keys_provider, node_b_node_id, &channelmanager::provided_channel_type_features(&config), &channelmanager::provided_init_features(&config), &open_channel_msg, 7, &config, 0, &&logger, /*is_0conf=*/false).unwrap();
+ let mut node_b_chan = InboundV1Channel::<&TestKeysInterface>::new(&feeest, &&keys_provider, &&keys_provider, node_b_node_id, &channelmanager::provided_channel_type_features(&config), &channelmanager::provided_init_features(&config), &open_channel_msg, 7, &config, 0, &&logger, /*is_0conf=*/false).unwrap();
// Node B --> Node A: accept channel, explicitly setting B's dust limit.
let mut accept_channel_msg = node_b_chan.accept_inbound_channel();
value: 10000000, script_pubkey: output_script.clone(),
}]};
let funding_outpoint = OutPoint{ txid: tx.txid(), index: 0 };
- let (mut node_a_chan, funding_created_msg) = node_a_chan.get_funding_created(tx.clone(), funding_outpoint, &&logger).map_err(|_| ()).unwrap();
- let (_, funding_signed_msg, _) = node_b_chan.funding_created(&funding_created_msg, best_block, &&keys_provider, &&logger).map_err(|_| ()).unwrap();
+ let (mut node_a_chan, funding_created_msg) = node_a_chan.get_funding_created(tx.clone(), funding_outpoint, false, &&logger).map_err(|_| ()).unwrap();
+ let (_, funding_signed_msg, _) = node_b_chan.funding_created(&funding_created_msg.unwrap(), best_block, &&keys_provider, &&logger).map_err(|_| ()).unwrap();
// Node B --> Node A: funding signed
- let _ = node_a_chan.funding_signed(&funding_signed_msg, best_block, &&keys_provider, &&logger).unwrap();
+ let _ = node_a_chan.funding_signed(&funding_signed_msg.unwrap(), best_block, &&keys_provider, &&logger).unwrap();
// Put some inbound and outbound HTLCs in A's channel.
let htlc_amount_msat = 11_092_000; // put an amount below A's effective dust limit but above B's.
let node_id = PublicKey::from_secret_key(&secp_ctx, &SecretKey::from_slice(&[42; 32]).unwrap());
let config = UserConfig::default();
- let mut chan = OutboundV1Channel::<EnforcingSigner>::new(&fee_est, &&keys_provider, &&keys_provider, node_id, &channelmanager::provided_init_features(&config), 10000000, 100000, 42, &config, 0, 42).unwrap();
+ let mut chan = OutboundV1Channel::<&TestKeysInterface>::new(&fee_est, &&keys_provider, &&keys_provider, node_id, &channelmanager::provided_init_features(&config), 10000000, 100000, 42, &config, 0, 42, None).unwrap();
let commitment_tx_fee_0_htlcs = commit_tx_fee_msat(chan.context.feerate_per_kw, 0, chan.context.get_channel_type());
let commitment_tx_fee_1_htlc = commit_tx_fee_msat(chan.context.feerate_per_kw, 1, chan.context.get_channel_type());
let seed = [42; 32];
let network = Network::Testnet;
let best_block = BestBlock::from_network(network);
- let chain_hash = best_block.block_hash();
+ let chain_hash = ChainHash::using_genesis_block(network);
let keys_provider = test_utils::TestKeysInterface::new(&seed, network);
// Go through the flow of opening a channel between two nodes.
// Create Node A's channel pointing to Node B's pubkey
let node_b_node_id = PublicKey::from_secret_key(&secp_ctx, &SecretKey::from_slice(&[42; 32]).unwrap());
let config = UserConfig::default();
- let mut node_a_chan = OutboundV1Channel::<EnforcingSigner>::new(&feeest, &&keys_provider, &&keys_provider, node_b_node_id, &channelmanager::provided_init_features(&config), 10000000, 100000, 42, &config, 0, 42).unwrap();
+ let mut node_a_chan = OutboundV1Channel::<&TestKeysInterface>::new(&feeest, &&keys_provider, &&keys_provider, node_b_node_id, &channelmanager::provided_init_features(&config), 10000000, 100000, 42, &config, 0, 42, None).unwrap();
// Create Node B's channel by receiving Node A's open_channel message
let open_channel_msg = node_a_chan.get_open_channel(chain_hash);
let node_b_node_id = PublicKey::from_secret_key(&secp_ctx, &SecretKey::from_slice(&[7; 32]).unwrap());
- let mut node_b_chan = InboundV1Channel::<EnforcingSigner>::new(&feeest, &&keys_provider, &&keys_provider, node_b_node_id, &channelmanager::provided_channel_type_features(&config), &channelmanager::provided_init_features(&config), &open_channel_msg, 7, &config, 0, &&logger, /*is_0conf=*/false).unwrap();
+ let mut node_b_chan = InboundV1Channel::<&TestKeysInterface>::new(&feeest, &&keys_provider, &&keys_provider, node_b_node_id, &channelmanager::provided_channel_type_features(&config), &channelmanager::provided_init_features(&config), &open_channel_msg, 7, &config, 0, &&logger, /*is_0conf=*/false).unwrap();
// Node B --> Node A: accept channel
let accept_channel_msg = node_b_chan.accept_inbound_channel();
value: 10000000, script_pubkey: output_script.clone(),
}]};
let funding_outpoint = OutPoint{ txid: tx.txid(), index: 0 };
- let (mut node_a_chan, funding_created_msg) = node_a_chan.get_funding_created(tx.clone(), funding_outpoint, &&logger).map_err(|_| ()).unwrap();
- let (mut node_b_chan, funding_signed_msg, _) = node_b_chan.funding_created(&funding_created_msg, best_block, &&keys_provider, &&logger).map_err(|_| ()).unwrap();
+ let (mut node_a_chan, funding_created_msg) = node_a_chan.get_funding_created(tx.clone(), funding_outpoint, false, &&logger).map_err(|_| ()).unwrap();
+ let (mut node_b_chan, funding_signed_msg, _) = node_b_chan.funding_created(&funding_created_msg.unwrap(), best_block, &&keys_provider, &&logger).map_err(|_| ()).unwrap();
// Node B --> Node A: funding signed
- let _ = node_a_chan.funding_signed(&funding_signed_msg, best_block, &&keys_provider, &&logger).unwrap();
+ let _ = node_a_chan.funding_signed(&funding_signed_msg.unwrap(), best_block, &&keys_provider, &&logger).unwrap();
// Now disconnect the two nodes and check that the commitment point in
// Node B's channel_reestablish message is sane.
- node_b_chan.remove_uncommitted_htlcs_and_mark_paused(&&logger);
+ assert!(node_b_chan.remove_uncommitted_htlcs_and_mark_paused(&&logger).is_ok());
let msg = node_b_chan.get_channel_reestablish(&&logger);
assert_eq!(msg.next_local_commitment_number, 1); // now called next_commitment_number
assert_eq!(msg.next_remote_commitment_number, 0); // now called next_revocation_number
// Check that the commitment point in Node A's channel_reestablish message
// is sane.
- node_a_chan.remove_uncommitted_htlcs_and_mark_paused(&&logger);
+ assert!(node_a_chan.remove_uncommitted_htlcs_and_mark_paused(&&logger).is_ok());
let msg = node_a_chan.get_channel_reestablish(&&logger);
assert_eq!(msg.next_local_commitment_number, 1); // now called next_commitment_number
assert_eq!(msg.next_remote_commitment_number, 0); // now called next_revocation_number
// Test that `OutboundV1Channel::new` creates a channel with the correct value for
// `holder_max_htlc_value_in_flight_msat`, when configured with a valid percentage value,
// which is set to the lower bound + 1 (2%) of the `channel_value`.
- let chan_1 = OutboundV1Channel::<EnforcingSigner>::new(&feeest, &&keys_provider, &&keys_provider, outbound_node_id, &channelmanager::provided_init_features(&config_2_percent), 10000000, 100000, 42, &config_2_percent, 0, 42).unwrap();
+ let chan_1 = OutboundV1Channel::<&TestKeysInterface>::new(&feeest, &&keys_provider, &&keys_provider, outbound_node_id, &channelmanager::provided_init_features(&config_2_percent), 10000000, 100000, 42, &config_2_percent, 0, 42, None).unwrap();
let chan_1_value_msat = chan_1.context.channel_value_satoshis * 1000;
assert_eq!(chan_1.context.holder_max_htlc_value_in_flight_msat, (chan_1_value_msat as f64 * 0.02) as u64);
// Test with the upper bound - 1 of valid values (99%).
- let chan_2 = OutboundV1Channel::<EnforcingSigner>::new(&feeest, &&keys_provider, &&keys_provider, outbound_node_id, &channelmanager::provided_init_features(&config_99_percent), 10000000, 100000, 42, &config_99_percent, 0, 42).unwrap();
+ let chan_2 = OutboundV1Channel::<&TestKeysInterface>::new(&feeest, &&keys_provider, &&keys_provider, outbound_node_id, &channelmanager::provided_init_features(&config_99_percent), 10000000, 100000, 42, &config_99_percent, 0, 42, None).unwrap();
let chan_2_value_msat = chan_2.context.channel_value_satoshis * 1000;
assert_eq!(chan_2.context.holder_max_htlc_value_in_flight_msat, (chan_2_value_msat as f64 * 0.99) as u64);
- let chan_1_open_channel_msg = chan_1.get_open_channel(genesis_block(network).header.block_hash());
+ let chan_1_open_channel_msg = chan_1.get_open_channel(ChainHash::using_genesis_block(network));
// Test that `InboundV1Channel::new` creates a channel with the correct value for
// `holder_max_htlc_value_in_flight_msat`, when configured with a valid percentage value,
// which is set to the lower bound - 1 (2%) of the `channel_value`.
- let chan_3 = InboundV1Channel::<EnforcingSigner>::new(&feeest, &&keys_provider, &&keys_provider, inbound_node_id, &channelmanager::provided_channel_type_features(&config_2_percent), &channelmanager::provided_init_features(&config_2_percent), &chan_1_open_channel_msg, 7, &config_2_percent, 0, &&logger, /*is_0conf=*/false).unwrap();
+ let chan_3 = InboundV1Channel::<&TestKeysInterface>::new(&feeest, &&keys_provider, &&keys_provider, inbound_node_id, &channelmanager::provided_channel_type_features(&config_2_percent), &channelmanager::provided_init_features(&config_2_percent), &chan_1_open_channel_msg, 7, &config_2_percent, 0, &&logger, /*is_0conf=*/false).unwrap();
let chan_3_value_msat = chan_3.context.channel_value_satoshis * 1000;
assert_eq!(chan_3.context.holder_max_htlc_value_in_flight_msat, (chan_3_value_msat as f64 * 0.02) as u64);
// Test with the upper bound - 1 of valid values (99%).
- let chan_4 = InboundV1Channel::<EnforcingSigner>::new(&feeest, &&keys_provider, &&keys_provider, inbound_node_id, &channelmanager::provided_channel_type_features(&config_99_percent), &channelmanager::provided_init_features(&config_99_percent), &chan_1_open_channel_msg, 7, &config_99_percent, 0, &&logger, /*is_0conf=*/false).unwrap();
+ let chan_4 = InboundV1Channel::<&TestKeysInterface>::new(&feeest, &&keys_provider, &&keys_provider, inbound_node_id, &channelmanager::provided_channel_type_features(&config_99_percent), &channelmanager::provided_init_features(&config_99_percent), &chan_1_open_channel_msg, 7, &config_99_percent, 0, &&logger, /*is_0conf=*/false).unwrap();
let chan_4_value_msat = chan_4.context.channel_value_satoshis * 1000;
assert_eq!(chan_4.context.holder_max_htlc_value_in_flight_msat, (chan_4_value_msat as f64 * 0.99) as u64);
// Test that `OutboundV1Channel::new` uses the lower bound of the configurable percentage values (1%)
// if `max_inbound_htlc_value_in_flight_percent_of_channel` is set to a value less than 1.
- let chan_5 = OutboundV1Channel::<EnforcingSigner>::new(&feeest, &&keys_provider, &&keys_provider, outbound_node_id, &channelmanager::provided_init_features(&config_0_percent), 10000000, 100000, 42, &config_0_percent, 0, 42).unwrap();
+ let chan_5 = OutboundV1Channel::<&TestKeysInterface>::new(&feeest, &&keys_provider, &&keys_provider, outbound_node_id, &channelmanager::provided_init_features(&config_0_percent), 10000000, 100000, 42, &config_0_percent, 0, 42, None).unwrap();
let chan_5_value_msat = chan_5.context.channel_value_satoshis * 1000;
assert_eq!(chan_5.context.holder_max_htlc_value_in_flight_msat, (chan_5_value_msat as f64 * 0.01) as u64);
// Test that `OutboundV1Channel::new` uses the upper bound of the configurable percentage values
// (100%) if `max_inbound_htlc_value_in_flight_percent_of_channel` is set to a larger value
// than 100.
- let chan_6 = OutboundV1Channel::<EnforcingSigner>::new(&feeest, &&keys_provider, &&keys_provider, outbound_node_id, &channelmanager::provided_init_features(&config_101_percent), 10000000, 100000, 42, &config_101_percent, 0, 42).unwrap();
+ let chan_6 = OutboundV1Channel::<&TestKeysInterface>::new(&feeest, &&keys_provider, &&keys_provider, outbound_node_id, &channelmanager::provided_init_features(&config_101_percent), 10000000, 100000, 42, &config_101_percent, 0, 42, None).unwrap();
let chan_6_value_msat = chan_6.context.channel_value_satoshis * 1000;
assert_eq!(chan_6.context.holder_max_htlc_value_in_flight_msat, chan_6_value_msat);
// Test that `InboundV1Channel::new` uses the lower bound of the configurable percentage values (1%)
// if `max_inbound_htlc_value_in_flight_percent_of_channel` is set to a value less than 1.
- let chan_7 = InboundV1Channel::<EnforcingSigner>::new(&feeest, &&keys_provider, &&keys_provider, inbound_node_id, &channelmanager::provided_channel_type_features(&config_0_percent), &channelmanager::provided_init_features(&config_0_percent), &chan_1_open_channel_msg, 7, &config_0_percent, 0, &&logger, /*is_0conf=*/false).unwrap();
+ let chan_7 = InboundV1Channel::<&TestKeysInterface>::new(&feeest, &&keys_provider, &&keys_provider, inbound_node_id, &channelmanager::provided_channel_type_features(&config_0_percent), &channelmanager::provided_init_features(&config_0_percent), &chan_1_open_channel_msg, 7, &config_0_percent, 0, &&logger, /*is_0conf=*/false).unwrap();
let chan_7_value_msat = chan_7.context.channel_value_satoshis * 1000;
assert_eq!(chan_7.context.holder_max_htlc_value_in_flight_msat, (chan_7_value_msat as f64 * 0.01) as u64);
// Test that `InboundV1Channel::new` uses the upper bound of the configurable percentage values
// (100%) if `max_inbound_htlc_value_in_flight_percent_of_channel` is set to a larger value
// than 100.
- let chan_8 = InboundV1Channel::<EnforcingSigner>::new(&feeest, &&keys_provider, &&keys_provider, inbound_node_id, &channelmanager::provided_channel_type_features(&config_101_percent), &channelmanager::provided_init_features(&config_101_percent), &chan_1_open_channel_msg, 7, &config_101_percent, 0, &&logger, /*is_0conf=*/false).unwrap();
+ let chan_8 = InboundV1Channel::<&TestKeysInterface>::new(&feeest, &&keys_provider, &&keys_provider, inbound_node_id, &channelmanager::provided_channel_type_features(&config_101_percent), &channelmanager::provided_init_features(&config_101_percent), &chan_1_open_channel_msg, 7, &config_101_percent, 0, &&logger, /*is_0conf=*/false).unwrap();
let chan_8_value_msat = chan_8.context.channel_value_satoshis * 1000;
assert_eq!(chan_8.context.holder_max_htlc_value_in_flight_msat, chan_8_value_msat);
}
let mut outbound_node_config = UserConfig::default();
outbound_node_config.channel_handshake_config.their_channel_reserve_proportional_millionths = (outbound_selected_channel_reserve_perc * 1_000_000.0) as u32;
- let chan = OutboundV1Channel::<EnforcingSigner>::new(&&fee_est, &&keys_provider, &&keys_provider, outbound_node_id, &channelmanager::provided_init_features(&outbound_node_config), channel_value_satoshis, 100_000, 42, &outbound_node_config, 0, 42).unwrap();
+ let chan = OutboundV1Channel::<&TestKeysInterface>::new(&&fee_est, &&keys_provider, &&keys_provider, outbound_node_id, &channelmanager::provided_init_features(&outbound_node_config), channel_value_satoshis, 100_000, 42, &outbound_node_config, 0, 42, None).unwrap();
let expected_outbound_selected_chan_reserve = cmp::max(MIN_THEIR_CHAN_RESERVE_SATOSHIS, (chan.context.channel_value_satoshis as f64 * outbound_selected_channel_reserve_perc) as u64);
assert_eq!(chan.context.holder_selected_channel_reserve_satoshis, expected_outbound_selected_chan_reserve);
- let chan_open_channel_msg = chan.get_open_channel(genesis_block(network).header.block_hash());
+ let chan_open_channel_msg = chan.get_open_channel(ChainHash::using_genesis_block(network));
let mut inbound_node_config = UserConfig::default();
inbound_node_config.channel_handshake_config.their_channel_reserve_proportional_millionths = (inbound_selected_channel_reserve_perc * 1_000_000.0) as u32;
if outbound_selected_channel_reserve_perc + inbound_selected_channel_reserve_perc < 1.0 {
- let chan_inbound_node = InboundV1Channel::<EnforcingSigner>::new(&&fee_est, &&keys_provider, &&keys_provider, inbound_node_id, &channelmanager::provided_channel_type_features(&inbound_node_config), &channelmanager::provided_init_features(&outbound_node_config), &chan_open_channel_msg, 7, &inbound_node_config, 0, &&logger, /*is_0conf=*/false).unwrap();
+ let chan_inbound_node = InboundV1Channel::<&TestKeysInterface>::new(&&fee_est, &&keys_provider, &&keys_provider, inbound_node_id, &channelmanager::provided_channel_type_features(&inbound_node_config), &channelmanager::provided_init_features(&outbound_node_config), &chan_open_channel_msg, 7, &inbound_node_config, 0, &&logger, /*is_0conf=*/false).unwrap();
let expected_inbound_selected_chan_reserve = cmp::max(MIN_THEIR_CHAN_RESERVE_SATOSHIS, (chan.context.channel_value_satoshis as f64 * inbound_selected_channel_reserve_perc) as u64);
assert_eq!(chan_inbound_node.context.counterparty_selected_channel_reserve_satoshis.unwrap(), expected_outbound_selected_chan_reserve);
} else {
// Channel Negotiations failed
- let result = InboundV1Channel::<EnforcingSigner>::new(&&fee_est, &&keys_provider, &&keys_provider, inbound_node_id, &channelmanager::provided_channel_type_features(&inbound_node_config), &channelmanager::provided_init_features(&outbound_node_config), &chan_open_channel_msg, 7, &inbound_node_config, 0, &&logger, /*is_0conf=*/false);
+ let result = InboundV1Channel::<&TestKeysInterface>::new(&&fee_est, &&keys_provider, &&keys_provider, inbound_node_id, &channelmanager::provided_channel_type_features(&inbound_node_config), &channelmanager::provided_init_features(&outbound_node_config), &chan_open_channel_msg, 7, &inbound_node_config, 0, &&logger, /*is_0conf=*/false);
assert!(result.is_err());
}
}
let seed = [42; 32];
let network = Network::Testnet;
let best_block = BestBlock::from_network(network);
- let chain_hash = genesis_block(network).header.block_hash();
+ let chain_hash = ChainHash::using_genesis_block(network);
let keys_provider = test_utils::TestKeysInterface::new(&seed, network);
// Create Node A's channel pointing to Node B's pubkey
let node_b_node_id = PublicKey::from_secret_key(&secp_ctx, &SecretKey::from_slice(&[42; 32]).unwrap());
let config = UserConfig::default();
- let mut node_a_chan = OutboundV1Channel::<EnforcingSigner>::new(&feeest, &&keys_provider, &&keys_provider, node_b_node_id, &channelmanager::provided_init_features(&config), 10000000, 100000, 42, &config, 0, 42).unwrap();
+ let mut node_a_chan = OutboundV1Channel::<&TestKeysInterface>::new(&feeest, &&keys_provider, &&keys_provider, node_b_node_id, &channelmanager::provided_init_features(&config), 10000000, 100000, 42, &config, 0, 42, None).unwrap();
// Create Node B's channel by receiving Node A's open_channel message
// Make sure A's dust limit is as we expect.
- let open_channel_msg = node_a_chan.get_open_channel(genesis_block(network).header.block_hash());
+ let open_channel_msg = node_a_chan.get_open_channel(ChainHash::using_genesis_block(network));
let node_b_node_id = PublicKey::from_secret_key(&secp_ctx, &SecretKey::from_slice(&[7; 32]).unwrap());
- let mut node_b_chan = InboundV1Channel::<EnforcingSigner>::new(&feeest, &&keys_provider, &&keys_provider, node_b_node_id, &channelmanager::provided_channel_type_features(&config), &channelmanager::provided_init_features(&config), &open_channel_msg, 7, &config, 0, &&logger, /*is_0conf=*/false).unwrap();
+ let mut node_b_chan = InboundV1Channel::<&TestKeysInterface>::new(&feeest, &&keys_provider, &&keys_provider, node_b_node_id, &channelmanager::provided_channel_type_features(&config), &channelmanager::provided_init_features(&config), &open_channel_msg, 7, &config, 0, &&logger, /*is_0conf=*/false).unwrap();
// Node B --> Node A: accept channel, explicitly setting B's dust limit.
let mut accept_channel_msg = node_b_chan.accept_inbound_channel();
value: 10000000, script_pubkey: output_script.clone(),
}]};
let funding_outpoint = OutPoint{ txid: tx.txid(), index: 0 };
- let (mut node_a_chan, funding_created_msg) = node_a_chan.get_funding_created(tx.clone(), funding_outpoint, &&logger).map_err(|_| ()).unwrap();
- let (_, funding_signed_msg, _) = node_b_chan.funding_created(&funding_created_msg, best_block, &&keys_provider, &&logger).map_err(|_| ()).unwrap();
+ let (mut node_a_chan, funding_created_msg) = node_a_chan.get_funding_created(tx.clone(), funding_outpoint, false, &&logger).map_err(|_| ()).unwrap();
+ let (_, funding_signed_msg, _) = node_b_chan.funding_created(&funding_created_msg.unwrap(), best_block, &&keys_provider, &&logger).map_err(|_| ()).unwrap();
// Node B --> Node A: funding signed
- let _ = node_a_chan.funding_signed(&funding_signed_msg, best_block, &&keys_provider, &&logger).unwrap();
+ let _ = node_a_chan.funding_signed(&funding_signed_msg.unwrap(), best_block, &&keys_provider, &&logger).unwrap();
// Make sure that receiving a channel update will update the Channel as expected.
let update = ChannelUpdate {
},
signature: Signature::from(unsafe { FFISignature::new() })
};
- node_a_chan.channel_update(&update).unwrap();
+ assert!(node_a_chan.channel_update(&update).unwrap());
// The counterparty can send an update with a higher minimum HTLC, but that shouldn't
// change our official htlc_minimum_msat.
},
None => panic!("expected counterparty forwarding info to be Some")
}
+
+ assert!(!node_a_chan.channel_update(&update).unwrap());
}
#[cfg(feature = "_test_vectors")]
use bitcoin::hashes::hex::FromHex;
use bitcoin::hash_types::Txid;
use bitcoin::secp256k1::Message;
- use crate::sign::EcdsaChannelSigner;
+ use crate::sign::{ChannelDerivationParameters, HTLCDescriptor, EcdsaChannelSigner};
use crate::ln::PaymentPreimage;
use crate::ln::channel::{HTLCOutputInCommitment ,TxCreationKeys};
use crate::ln::chan_utils::{ChannelPublicKeys, HolderCommitmentTransaction, CounterpartyChannelTransactionParameters};
let counterparty_node_id = PublicKey::from_secret_key(&secp_ctx, &SecretKey::from_slice(&[42; 32]).unwrap());
let mut config = UserConfig::default();
config.channel_handshake_config.announced_channel = false;
- let mut chan = OutboundV1Channel::<InMemorySigner>::new(&LowerBoundedFeeEstimator::new(&feeest), &&keys_provider, &&keys_provider, counterparty_node_id, &channelmanager::provided_init_features(&config), 10_000_000, 0, 42, &config, 0, 42).unwrap(); // Nothing uses their network key in this test
+ let mut chan = OutboundV1Channel::<&Keys>::new(&LowerBoundedFeeEstimator::new(&feeest), &&keys_provider, &&keys_provider, counterparty_node_id, &channelmanager::provided_init_features(&config), 10_000_000, 0, 42, &config, 0, 42, None).unwrap(); // Nothing uses their network key in this test
chan.context.holder_dust_limit_satoshis = 546;
chan.context.counterparty_selected_channel_reserve_satoshis = Some(0); // Filled in in accept_channel
// We can't just use build_holder_transaction_keys here as the per_commitment_secret is not
// derived from a commitment_seed, so instead we copy it here and call
// build_commitment_transaction.
- let delayed_payment_base = &chan.context.holder_signer.pubkeys().delayed_payment_basepoint;
+ let delayed_payment_base = &chan.context.holder_signer.as_ref().pubkeys().delayed_payment_basepoint;
let per_commitment_secret = SecretKey::from_slice(&hex::decode("1f1e1d1c1b1a191817161514131211100f0e0d0c0b0a09080706050403020100").unwrap()[..]).unwrap();
let per_commitment_point = PublicKey::from_secret_key(&secp_ctx, &per_commitment_secret);
- let htlc_basepoint = &chan.context.holder_signer.pubkeys().htlc_basepoint;
+ let htlc_basepoint = &chan.context.holder_signer.as_ref().pubkeys().htlc_basepoint;
let keys = TxCreationKeys::derive_new(&secp_ctx, &per_commitment_point, delayed_payment_base, htlc_basepoint, &counterparty_pubkeys.revocation_basepoint, &counterparty_pubkeys.htlc_basepoint);
macro_rules! test_commitment {
commitment_tx.clone(),
counterparty_signature,
counterparty_htlc_sigs,
- &chan.context.holder_signer.pubkeys().funding_pubkey,
+ &chan.context.holder_signer.as_ref().pubkeys().funding_pubkey,
chan.context.counterparty_funding_pubkey()
);
- let (holder_sig, htlc_sigs) = signer.sign_holder_commitment_and_htlcs(&holder_commitment_tx, &secp_ctx).unwrap();
+ let holder_sig = signer.sign_holder_commitment(&holder_commitment_tx, &secp_ctx).unwrap();
assert_eq!(Signature::from_der(&hex::decode($sig_hex).unwrap()[..]).unwrap(), holder_sig, "holder_sig");
let funding_redeemscript = chan.context.get_funding_redeemscript();
assert_eq!(serialize(&tx)[..], hex::decode($tx_hex).unwrap()[..], "tx");
// ((htlc, counterparty_sig), (index, holder_sig))
- let mut htlc_sig_iter = holder_commitment_tx.htlcs().iter().zip(&holder_commitment_tx.counterparty_htlc_sigs).zip(htlc_sigs.iter().enumerate());
+ let mut htlc_counterparty_sig_iter = holder_commitment_tx.counterparty_htlc_sigs.iter();
$({
log_trace!(logger, "verifying htlc {}", $htlc_idx);
let remote_signature = Signature::from_der(&hex::decode($counterparty_htlc_sig_hex).unwrap()[..]).unwrap();
let ref htlc = htlcs[$htlc_idx];
- let htlc_tx = chan_utils::build_htlc_transaction(&unsigned_tx.txid, chan.context.feerate_per_kw,
+ let mut htlc_tx = chan_utils::build_htlc_transaction(&unsigned_tx.txid, chan.context.feerate_per_kw,
chan.context.get_counterparty_selected_contest_delay().unwrap(),
&htlc, $opt_anchors, &keys.broadcaster_delayed_payment_key, &keys.revocation_key);
let htlc_redeemscript = chan_utils::get_htlc_redeemscript(&htlc, $opt_anchors, &keys);
assert!(preimage.is_some());
}
- let htlc_sig = htlc_sig_iter.next().unwrap();
+ let htlc_counterparty_sig = htlc_counterparty_sig_iter.next().unwrap();
+ let htlc_holder_sig = signer.sign_holder_htlc_transaction(&htlc_tx, 0, &HTLCDescriptor {
+ channel_derivation_parameters: ChannelDerivationParameters {
+ value_satoshis: chan.context.channel_value_satoshis,
+ keys_id: chan.context.channel_keys_id,
+ transaction_parameters: chan.context.channel_transaction_parameters.clone(),
+ },
+ commitment_txid: trusted_tx.txid(),
+ per_commitment_number: trusted_tx.commitment_number(),
+ per_commitment_point: trusted_tx.per_commitment_point(),
+ feerate_per_kw: trusted_tx.feerate_per_kw(),
+ htlc: htlc.clone(),
+ preimage: preimage.clone(),
+ counterparty_sig: *htlc_counterparty_sig,
+ }, &secp_ctx).unwrap();
let num_anchors = if $opt_anchors.supports_anchors_zero_fee_htlc_tx() { 2 } else { 0 };
- assert_eq!((htlc_sig.0).0.transaction_output_index, Some($htlc_idx + num_anchors), "output index");
+ assert_eq!(htlc.transaction_output_index, Some($htlc_idx + num_anchors), "output index");
let signature = Signature::from_der(&hex::decode($htlc_sig_hex).unwrap()[..]).unwrap();
- assert_eq!(signature, *(htlc_sig.1).1, "htlc sig");
- let index = (htlc_sig.1).0;
- let channel_parameters = chan.context.channel_transaction_parameters.as_holder_broadcastable();
+ assert_eq!(signature, htlc_holder_sig, "htlc sig");
let trusted_tx = holder_commitment_tx.trust();
- log_trace!(logger, "htlc_tx = {}", hex::encode(serialize(&trusted_tx.get_signed_htlc_tx(&channel_parameters, index, &(htlc_sig.0).1, (htlc_sig.1).1, &preimage))));
- assert_eq!(serialize(&trusted_tx.get_signed_htlc_tx(&channel_parameters, index, &(htlc_sig.0).1, (htlc_sig.1).1, &preimage))[..],
- hex::decode($htlc_tx_hex).unwrap()[..], "htlc tx");
+ htlc_tx.input[0].witness = trusted_tx.build_htlc_input_witness($htlc_idx, htlc_counterparty_sig, &htlc_holder_sig, &preimage);
+ log_trace!(logger, "htlc_tx = {}", hex::encode(serialize(&htlc_tx)));
+ assert_eq!(serialize(&htlc_tx)[..], hex::decode($htlc_tx_hex).unwrap()[..], "htlc tx");
})*
- assert!(htlc_sig_iter.next().is_none());
+ assert!(htlc_counterparty_sig_iter.next().is_none());
} }
}
let node_b_node_id = PublicKey::from_secret_key(&secp_ctx, &SecretKey::from_slice(&[42; 32]).unwrap());
let config = UserConfig::default();
- let node_a_chan = OutboundV1Channel::<EnforcingSigner>::new(&feeest, &&keys_provider, &&keys_provider,
- node_b_node_id, &channelmanager::provided_init_features(&config), 10000000, 100000, 42, &config, 0, 42).unwrap();
+ let node_a_chan = OutboundV1Channel::<&TestKeysInterface>::new(&feeest, &&keys_provider, &&keys_provider,
+ node_b_node_id, &channelmanager::provided_init_features(&config), 10000000, 100000, 42, &config, 0, 42, None).unwrap();
let mut channel_type_features = ChannelTypeFeatures::only_static_remote_key();
channel_type_features.set_zero_conf_required();
- let mut open_channel_msg = node_a_chan.get_open_channel(genesis_block(network).header.block_hash());
+ let mut open_channel_msg = node_a_chan.get_open_channel(ChainHash::using_genesis_block(network));
open_channel_msg.channel_type = Some(channel_type_features);
let node_b_node_id = PublicKey::from_secret_key(&secp_ctx, &SecretKey::from_slice(&[7; 32]).unwrap());
- let res = InboundV1Channel::<EnforcingSigner>::new(&feeest, &&keys_provider, &&keys_provider,
+ let res = InboundV1Channel::<&TestKeysInterface>::new(&feeest, &&keys_provider, &&keys_provider,
node_b_node_id, &channelmanager::provided_channel_type_features(&config),
&channelmanager::provided_init_features(&config), &open_channel_msg, 7, &config, 0, &&logger, /*is_0conf=*/false);
assert!(res.is_ok());
// It is not enough for just the initiator to signal `option_anchors_zero_fee_htlc_tx`, both
// need to signal it.
- let channel_a = OutboundV1Channel::<EnforcingSigner>::new(
+ let channel_a = OutboundV1Channel::<&TestKeysInterface>::new(
&fee_estimator, &&keys_provider, &&keys_provider, node_id_b,
&channelmanager::provided_init_features(&UserConfig::default()), 10000000, 100000, 42,
- &config, 0, 42
+ &config, 0, 42, None
).unwrap();
assert!(!channel_a.context.channel_type.supports_anchors_zero_fee_htlc_tx());
expected_channel_type.set_static_remote_key_required();
expected_channel_type.set_anchors_zero_fee_htlc_tx_required();
- let channel_a = OutboundV1Channel::<EnforcingSigner>::new(
+ let channel_a = OutboundV1Channel::<&TestKeysInterface>::new(
&fee_estimator, &&keys_provider, &&keys_provider, node_id_b,
- &channelmanager::provided_init_features(&config), 10000000, 100000, 42, &config, 0, 42
+ &channelmanager::provided_init_features(&config), 10000000, 100000, 42, &config, 0, 42,
+ None
).unwrap();
- let open_channel_msg = channel_a.get_open_channel(genesis_block(network).header.block_hash());
- let channel_b = InboundV1Channel::<EnforcingSigner>::new(
+ let open_channel_msg = channel_a.get_open_channel(ChainHash::using_genesis_block(network));
+ let channel_b = InboundV1Channel::<&TestKeysInterface>::new(
&fee_estimator, &&keys_provider, &&keys_provider, node_id_a,
&channelmanager::provided_channel_type_features(&config), &channelmanager::provided_init_features(&config),
&open_channel_msg, 7, &config, 0, &&logger, /*is_0conf=*/false
let raw_init_features = static_remote_key_required | simple_anchors_required;
let init_features_with_simple_anchors = InitFeatures::from_le_bytes(raw_init_features.to_le_bytes().to_vec());
- let channel_a = OutboundV1Channel::<EnforcingSigner>::new(
+ let channel_a = OutboundV1Channel::<&TestKeysInterface>::new(
&fee_estimator, &&keys_provider, &&keys_provider, node_id_b,
- &channelmanager::provided_init_features(&config), 10000000, 100000, 42, &config, 0, 42
+ &channelmanager::provided_init_features(&config), 10000000, 100000, 42, &config, 0, 42,
+ None
).unwrap();
// Set `channel_type` to `None` to force the implicit feature negotiation.
- let mut open_channel_msg = channel_a.get_open_channel(genesis_block(network).header.block_hash());
+ let mut open_channel_msg = channel_a.get_open_channel(ChainHash::using_genesis_block(network));
open_channel_msg.channel_type = None;
// Since A supports both `static_remote_key` and `option_anchors`, but B only accepts
// `static_remote_key`, it will fail the channel.
- let channel_b = InboundV1Channel::<EnforcingSigner>::new(
+ let channel_b = InboundV1Channel::<&TestKeysInterface>::new(
&fee_estimator, &&keys_provider, &&keys_provider, node_id_a,
&channelmanager::provided_channel_type_features(&config), &init_features_with_simple_anchors,
&open_channel_msg, 7, &config, 0, &&logger, /*is_0conf=*/false
// First, we'll try to open a channel between A and B where A requests a channel type for
// the original `option_anchors` feature (non zero fee htlc tx). This should be rejected by
// B as it's not supported by LDK.
- let channel_a = OutboundV1Channel::<EnforcingSigner>::new(
+ let channel_a = OutboundV1Channel::<&TestKeysInterface>::new(
&fee_estimator, &&keys_provider, &&keys_provider, node_id_b,
- &channelmanager::provided_init_features(&config), 10000000, 100000, 42, &config, 0, 42
+ &channelmanager::provided_init_features(&config), 10000000, 100000, 42, &config, 0, 42,
+ None
).unwrap();
- let mut open_channel_msg = channel_a.get_open_channel(genesis_block(network).header.block_hash());
+ let mut open_channel_msg = channel_a.get_open_channel(ChainHash::using_genesis_block(network));
open_channel_msg.channel_type = Some(simple_anchors_channel_type.clone());
- let res = InboundV1Channel::<EnforcingSigner>::new(
+ let res = InboundV1Channel::<&TestKeysInterface>::new(
&fee_estimator, &&keys_provider, &&keys_provider, node_id_a,
&channelmanager::provided_channel_type_features(&config), &simple_anchors_init,
&open_channel_msg, 7, &config, 0, &&logger, /*is_0conf=*/false
// `anchors_zero_fee_htlc_tx`. B is malicious and tries to downgrade the channel type to the
// original `option_anchors` feature, which should be rejected by A as it's not supported by
// LDK.
- let mut channel_a = OutboundV1Channel::<EnforcingSigner>::new(
+ let mut channel_a = OutboundV1Channel::<&TestKeysInterface>::new(
&fee_estimator, &&keys_provider, &&keys_provider, node_id_b, &simple_anchors_init,
- 10000000, 100000, 42, &config, 0, 42
+ 10000000, 100000, 42, &config, 0, 42, None
).unwrap();
- let open_channel_msg = channel_a.get_open_channel(genesis_block(network).header.block_hash());
+ let open_channel_msg = channel_a.get_open_channel(ChainHash::using_genesis_block(network));
- let channel_b = InboundV1Channel::<EnforcingSigner>::new(
+ let channel_b = InboundV1Channel::<&TestKeysInterface>::new(
&fee_estimator, &&keys_provider, &&keys_provider, node_id_a,
&channelmanager::provided_channel_type_features(&config), &channelmanager::provided_init_features(&config),
&open_channel_msg, 7, &config, 0, &&logger, /*is_0conf=*/false
);
assert!(res.is_err());
}
+
+ #[test]
+ fn test_waiting_for_batch() {
+ let feeest = LowerBoundedFeeEstimator::new(&TestFeeEstimator{fee_est: 15000});
+ let logger = test_utils::TestLogger::new();
+ let secp_ctx = Secp256k1::new();
+ let seed = [42; 32];
+ let network = Network::Testnet;
+ let best_block = BestBlock::from_network(network);
+ let chain_hash = ChainHash::using_genesis_block(network);
+ let keys_provider = test_utils::TestKeysInterface::new(&seed, network);
+
+ let mut config = UserConfig::default();
+ // Set trust_own_funding_0conf while ensuring we don't send channel_ready for a
+ // channel in a batch before all channels are ready.
+ config.channel_handshake_limits.trust_own_funding_0conf = true;
+
+ // Create a channel from node a to node b that will be part of batch funding.
+ let node_b_node_id = PublicKey::from_secret_key(&secp_ctx, &SecretKey::from_slice(&[42; 32]).unwrap());
+ let mut node_a_chan = OutboundV1Channel::<&TestKeysInterface>::new(
+ &feeest,
+ &&keys_provider,
+ &&keys_provider,
+ node_b_node_id,
+ &channelmanager::provided_init_features(&config),
+ 10000000,
+ 100000,
+ 42,
+ &config,
+ 0,
+ 42,
+ None
+ ).unwrap();
+
+ let open_channel_msg = node_a_chan.get_open_channel(ChainHash::using_genesis_block(network));
+ let node_b_node_id = PublicKey::from_secret_key(&secp_ctx, &SecretKey::from_slice(&[7; 32]).unwrap());
+ let mut node_b_chan = InboundV1Channel::<&TestKeysInterface>::new(
+ &feeest,
+ &&keys_provider,
+ &&keys_provider,
+ node_b_node_id,
+ &channelmanager::provided_channel_type_features(&config),
+ &channelmanager::provided_init_features(&config),
+ &open_channel_msg,
+ 7,
+ &config,
+ 0,
+ &&logger,
+ true, // Allow node b to send a 0conf channel_ready.
+ ).unwrap();
+
+ let accept_channel_msg = node_b_chan.accept_inbound_channel();
+ node_a_chan.accept_channel(
+ &accept_channel_msg,
+ &config.channel_handshake_limits,
+ &channelmanager::provided_init_features(&config),
+ ).unwrap();
+
+ // Fund the channel with a batch funding transaction.
+ let output_script = node_a_chan.context.get_funding_redeemscript();
+ let tx = Transaction {
+ version: 1,
+ lock_time: PackedLockTime::ZERO,
+ input: Vec::new(),
+ output: vec![
+ TxOut {
+ value: 10000000, script_pubkey: output_script.clone(),
+ },
+ TxOut {
+ value: 10000000, script_pubkey: Builder::new().into_script(),
+ },
+ ]};
+ let funding_outpoint = OutPoint{ txid: tx.txid(), index: 0 };
+ let (mut node_a_chan, funding_created_msg) = node_a_chan.get_funding_created(
+ tx.clone(),
+ funding_outpoint,
+ true,
+ &&logger,
+ ).map_err(|_| ()).unwrap();
+ let (mut node_b_chan, funding_signed_msg, _) = node_b_chan.funding_created(
+ &funding_created_msg.unwrap(),
+ best_block,
+ &&keys_provider,
+ &&logger,
+ ).map_err(|_| ()).unwrap();
+ let node_b_updates = node_b_chan.monitor_updating_restored(
+ &&logger,
+ &&keys_provider,
+ chain_hash,
+ &config,
+ 0,
+ );
+
+ // Receive funding_signed, but the channel will be configured to hold sending channel_ready and
+ // broadcasting the funding transaction until the batch is ready.
+ let _ = node_a_chan.funding_signed(
+ &funding_signed_msg.unwrap(),
+ best_block,
+ &&keys_provider,
+ &&logger,
+ ).unwrap();
+ let node_a_updates = node_a_chan.monitor_updating_restored(
+ &&logger,
+ &&keys_provider,
+ chain_hash,
+ &config,
+ 0,
+ );
+ // Our channel_ready shouldn't be sent yet, even with trust_own_funding_0conf set,
+ // as the funding transaction depends on all channels in the batch becoming ready.
+ assert!(node_a_updates.channel_ready.is_none());
+ assert!(node_a_updates.funding_broadcastable.is_none());
+ assert_eq!(
+ node_a_chan.context.channel_state,
+ ChannelState::FundingSent as u32 |
+ ChannelState::WaitingForBatch as u32,
+ );
+
+ // It is possible to receive a 0conf channel_ready from the remote node.
+ node_a_chan.channel_ready(
+ &node_b_updates.channel_ready.unwrap(),
+ &&keys_provider,
+ chain_hash,
+ &config,
+ &best_block,
+ &&logger,
+ ).unwrap();
+ assert_eq!(
+ node_a_chan.context.channel_state,
+ ChannelState::FundingSent as u32 |
+ ChannelState::WaitingForBatch as u32 |
+ ChannelState::TheirChannelReady as u32,
+ );
+
+ // Clear the ChannelState::WaitingForBatch only when called by ChannelManager.
+ node_a_chan.set_batch_ready();
+ assert_eq!(
+ node_a_chan.context.channel_state,
+ ChannelState::FundingSent as u32 |
+ ChannelState::TheirChannelReady as u32,
+ );
+ assert!(node_a_chan.check_get_channel_ready(0).is_some());
+ }
}