lnd/contractcourt/chain_watcher.go
Oliver Gugger 7dfe4018ce
multi: use btcd's btcec/v2 and btcutil modules
This commit was previously split into the following parts to ease
review:
 - 2d746f68: replace imports
 - 4008f0fd: use ecdsa.Signature
 - 849e33d1: remove btcec.S256()
 - b8f6ebbd: use v2 library correctly
 - fa80bca9: bump go modules
2022-03-09 19:02:37 +01:00

1244 lines
42 KiB
Go

package contractcourt
import (
"bytes"
"fmt"
"sync"
"sync/atomic"
"time"
"github.com/btcsuite/btcd/btcec/v2"
"github.com/btcsuite/btcd/btcutil"
"github.com/btcsuite/btcd/chaincfg"
"github.com/btcsuite/btcd/chaincfg/chainhash"
"github.com/btcsuite/btcd/txscript"
"github.com/btcsuite/btcd/wire"
"github.com/davecgh/go-spew/spew"
"github.com/lightningnetwork/lnd/chainntnfs"
"github.com/lightningnetwork/lnd/channeldb"
"github.com/lightningnetwork/lnd/input"
"github.com/lightningnetwork/lnd/lnwallet"
)
const (
// minCommitPointPollTimeout is the minimum time we'll wait before
// polling the database for a channel's commitpoint.
minCommitPointPollTimeout = 1 * time.Second
// maxCommitPointPollTimeout is the maximum time we'll wait before
// polling the database for a channel's commitpoint.
maxCommitPointPollTimeout = 10 * time.Minute
)
// LocalUnilateralCloseInfo encapsulates all the information we need to act on
// a local force close that gets confirmed.
type LocalUnilateralCloseInfo struct {
*chainntnfs.SpendDetail
*lnwallet.LocalForceCloseSummary
*channeldb.ChannelCloseSummary
// CommitSet is the set of known valid commitments at the time the
// remote party's commitment hit the chain.
CommitSet CommitSet
}
// CooperativeCloseInfo encapsulates all the information we need to act on a
// cooperative close that gets confirmed.
type CooperativeCloseInfo struct {
*channeldb.ChannelCloseSummary
}
// RemoteUnilateralCloseInfo wraps the normal UnilateralCloseSummary to couple
// the CommitSet at the time of channel closure.
type RemoteUnilateralCloseInfo struct {
*lnwallet.UnilateralCloseSummary
// CommitSet is the set of known valid commitments at the time the
// remote party's commitment hit the chain.
CommitSet CommitSet
}
// BreachResolution wraps the outpoint of the breached channel.
type BreachResolution struct {
FundingOutPoint wire.OutPoint
}
// BreachCloseInfo wraps the BreachResolution with a CommitSet for the latest,
// non-breached state, with the AnchorResolution for the breached state.
type BreachCloseInfo struct {
*BreachResolution
*lnwallet.AnchorResolution
// CommitHash is the hash of the commitment transaction.
CommitHash chainhash.Hash
// CommitSet is the set of known valid commitments at the time the
// breach occurred on-chain.
CommitSet CommitSet
// CloseSummary gives the recipient of the BreachCloseInfo information
// to mark the channel closed in the database.
CloseSummary channeldb.ChannelCloseSummary
}
// CommitSet is a collection of the set of known valid commitments at a given
// instant. If ConfCommitKey is set, then the commitment identified by the
// HtlcSetKey has hit the chain. This struct will be used to examine all live
// HTLCs to determine if any additional actions need to be made based on the
// remote party's commitments.
type CommitSet struct {
// ConfCommitKey if non-nil, identifies the commitment that was
// confirmed in the chain.
ConfCommitKey *HtlcSetKey
// HtlcSets stores the set of all known active HTLC for each active
// commitment at the time of channel closure.
HtlcSets map[HtlcSetKey][]channeldb.HTLC
}
// IsEmpty returns true if there are no HTLCs at all within all commitments
// that are a part of this commitment diff.
func (c *CommitSet) IsEmpty() bool {
if c == nil {
return true
}
for _, htlcs := range c.HtlcSets {
if len(htlcs) != 0 {
return false
}
}
return true
}
// toActiveHTLCSets returns the set of all active HTLCs across all commitment
// transactions.
func (c *CommitSet) toActiveHTLCSets() map[HtlcSetKey]htlcSet {
htlcSets := make(map[HtlcSetKey]htlcSet)
for htlcSetKey, htlcs := range c.HtlcSets {
htlcSets[htlcSetKey] = newHtlcSet(htlcs)
}
return htlcSets
}
// ChainEventSubscription is a struct that houses a subscription to be notified
// for any on-chain events related to a channel. There are three types of
// possible on-chain events: a cooperative channel closure, a unilateral
// channel closure, and a channel breach. The fourth type: a force close is
// locally initiated, so we don't provide any event stream for said event.
type ChainEventSubscription struct {
// ChanPoint is that channel that chain events will be dispatched for.
ChanPoint wire.OutPoint
// RemoteUnilateralClosure is a channel that will be sent upon in the
// event that the remote party's commitment transaction is confirmed.
RemoteUnilateralClosure chan *RemoteUnilateralCloseInfo
// LocalUnilateralClosure is a channel that will be sent upon in the
// event that our commitment transaction is confirmed.
LocalUnilateralClosure chan *LocalUnilateralCloseInfo
// CooperativeClosure is a signal that will be sent upon once a
// cooperative channel closure has been detected confirmed.
CooperativeClosure chan *CooperativeCloseInfo
// ContractBreach is a channel that will be sent upon if we detect a
// contract breach. The struct sent across the channel contains all the
// material required to bring the cheating channel peer to justice.
ContractBreach chan *BreachCloseInfo
// Cancel cancels the subscription to the event stream for a particular
// channel. This method should be called once the caller no longer needs to
// be notified of any on-chain events for a particular channel.
Cancel func()
}
// chainWatcherConfig encapsulates all the necessary functions and interfaces
// needed to watch and act on on-chain events for a particular channel.
type chainWatcherConfig struct {
// chanState is a snapshot of the persistent state of the channel that
// we're watching. In the event of an on-chain event, we'll query the
// database to ensure that we act using the most up to date state.
chanState *channeldb.OpenChannel
// notifier is a reference to the channel notifier that we'll use to be
// notified of output spends and when transactions are confirmed.
notifier chainntnfs.ChainNotifier
// signer is the main signer instances that will be responsible for
// signing any HTLC and commitment transaction generated by the state
// machine.
signer input.Signer
// contractBreach is a method that will be called by the watcher if it
// detects that a contract breach transaction has been confirmed. It
// will only return a non-nil error when the breachArbiter has
// preserved the necessary breach info for this channel point.
contractBreach func(*lnwallet.BreachRetribution) error
// isOurAddr is a function that returns true if the passed address is
// known to us.
isOurAddr func(btcutil.Address) bool
// extractStateNumHint extracts the encoded state hint using the passed
// obfuscater. This is used by the chain watcher to identify which
// state was broadcast and confirmed on-chain.
extractStateNumHint func(*wire.MsgTx, [lnwallet.StateHintSize]byte) uint64
}
// chainWatcher is a system that's assigned to every active channel. The duty
// of this system is to watch the chain for spends of the channels chan point.
// If a spend is detected then with chain watcher will notify all subscribers
// that the channel has been closed, and also give them the materials necessary
// to sweep the funds of the channel on chain eventually.
type chainWatcher struct {
started int32 // To be used atomically.
stopped int32 // To be used atomically.
quit chan struct{}
wg sync.WaitGroup
cfg chainWatcherConfig
// stateHintObfuscator is a 48-bit state hint that's used to obfuscate
// the current state number on the commitment transactions.
stateHintObfuscator [lnwallet.StateHintSize]byte
// All the fields below are protected by this mutex.
sync.Mutex
// clientID is an ephemeral counter used to keep track of each
// individual client subscription.
clientID uint64
// clientSubscriptions is a map that keeps track of all the active
// client subscriptions for events related to this channel.
clientSubscriptions map[uint64]*ChainEventSubscription
}
// newChainWatcher returns a new instance of a chainWatcher for a channel given
// the chan point to watch, and also a notifier instance that will allow us to
// detect on chain events.
func newChainWatcher(cfg chainWatcherConfig) (*chainWatcher, error) {
// In order to be able to detect the nature of a potential channel
// closure we'll need to reconstruct the state hint bytes used to
// obfuscate the commitment state number encoded in the lock time and
// sequence fields.
var stateHint [lnwallet.StateHintSize]byte
chanState := cfg.chanState
if chanState.IsInitiator {
stateHint = lnwallet.DeriveStateHintObfuscator(
chanState.LocalChanCfg.PaymentBasePoint.PubKey,
chanState.RemoteChanCfg.PaymentBasePoint.PubKey,
)
} else {
stateHint = lnwallet.DeriveStateHintObfuscator(
chanState.RemoteChanCfg.PaymentBasePoint.PubKey,
chanState.LocalChanCfg.PaymentBasePoint.PubKey,
)
}
return &chainWatcher{
cfg: cfg,
stateHintObfuscator: stateHint,
quit: make(chan struct{}),
clientSubscriptions: make(map[uint64]*ChainEventSubscription),
}, nil
}
// Start starts all goroutines that the chainWatcher needs to perform its
// duties.
func (c *chainWatcher) Start() error {
if !atomic.CompareAndSwapInt32(&c.started, 0, 1) {
return nil
}
chanState := c.cfg.chanState
log.Debugf("Starting chain watcher for ChannelPoint(%v)",
chanState.FundingOutpoint)
// First, we'll register for a notification to be dispatched if the
// funding output is spent.
fundingOut := &chanState.FundingOutpoint
// As a height hint, we'll try to use the opening height, but if the
// channel isn't yet open, then we'll use the height it was broadcast
// at.
heightHint := c.cfg.chanState.ShortChanID().BlockHeight
if heightHint == 0 {
heightHint = chanState.FundingBroadcastHeight
}
localKey := chanState.LocalChanCfg.MultiSigKey.PubKey.SerializeCompressed()
remoteKey := chanState.RemoteChanCfg.MultiSigKey.PubKey.SerializeCompressed()
multiSigScript, err := input.GenMultiSigScript(
localKey, remoteKey,
)
if err != nil {
return err
}
pkScript, err := input.WitnessScriptHash(multiSigScript)
if err != nil {
return err
}
spendNtfn, err := c.cfg.notifier.RegisterSpendNtfn(
fundingOut, pkScript, heightHint,
)
if err != nil {
return err
}
// With the spend notification obtained, we'll now dispatch the
// closeObserver which will properly react to any changes.
c.wg.Add(1)
go c.closeObserver(spendNtfn)
return nil
}
// Stop signals the close observer to gracefully exit.
func (c *chainWatcher) Stop() error {
if !atomic.CompareAndSwapInt32(&c.stopped, 0, 1) {
return nil
}
close(c.quit)
c.wg.Wait()
return nil
}
// SubscribeChannelEvents returns an active subscription to the set of channel
// events for the channel watched by this chain watcher. Once clients no longer
// require the subscription, they should call the Cancel() method to allow the
// watcher to regain those committed resources.
func (c *chainWatcher) SubscribeChannelEvents() *ChainEventSubscription {
c.Lock()
clientID := c.clientID
c.clientID++
c.Unlock()
log.Debugf("New ChainEventSubscription(id=%v) for ChannelPoint(%v)",
clientID, c.cfg.chanState.FundingOutpoint)
sub := &ChainEventSubscription{
ChanPoint: c.cfg.chanState.FundingOutpoint,
RemoteUnilateralClosure: make(chan *RemoteUnilateralCloseInfo, 1),
LocalUnilateralClosure: make(chan *LocalUnilateralCloseInfo, 1),
CooperativeClosure: make(chan *CooperativeCloseInfo, 1),
ContractBreach: make(chan *BreachCloseInfo, 1),
Cancel: func() {
c.Lock()
delete(c.clientSubscriptions, clientID)
c.Unlock()
},
}
c.Lock()
c.clientSubscriptions[clientID] = sub
c.Unlock()
return sub
}
// handleUnknownLocalState checks whether the passed spend _could_ be a local
// state that for some reason is unknown to us. This could be a state published
// by us before we lost state, which we will try to sweep. Or it could be one
// of our revoked states that somehow made it to the chain. If that's the case
// we cannot really hope that we'll be able to get our money back, but we'll
// try to sweep it anyway. If this is not an unknown local state, false is
// returned.
func (c *chainWatcher) handleUnknownLocalState(
commitSpend *chainntnfs.SpendDetail, broadcastStateNum uint64,
chainSet *chainSet) (bool, error) {
// If the spend was a local commitment, at this point it must either be
// a past state (we breached!) or a future state (we lost state!). In
// either case, the only thing we can do is to attempt to sweep what is
// there.
// First, we'll re-derive our commitment point for this state since
// this is what we use to randomize each of the keys for this state.
commitSecret, err := c.cfg.chanState.RevocationProducer.AtIndex(
broadcastStateNum,
)
if err != nil {
return false, err
}
commitPoint := input.ComputeCommitmentPoint(commitSecret[:])
// Now that we have the commit point, we'll derive the tweaked local
// and remote keys for this state. We use our point as only we can
// revoke our own commitment.
commitKeyRing := lnwallet.DeriveCommitmentKeys(
commitPoint, true, c.cfg.chanState.ChanType,
&c.cfg.chanState.LocalChanCfg, &c.cfg.chanState.RemoteChanCfg,
)
// With the keys derived, we'll construct the remote script that'll be
// present if they have a non-dust balance on the commitment.
var leaseExpiry uint32
if c.cfg.chanState.ChanType.HasLeaseExpiration() {
leaseExpiry = c.cfg.chanState.ThawHeight
}
remoteScript, _, err := lnwallet.CommitScriptToRemote(
c.cfg.chanState.ChanType, c.cfg.chanState.IsInitiator,
commitKeyRing.ToRemoteKey, leaseExpiry,
)
if err != nil {
return false, err
}
// Next, we'll derive our script that includes the revocation base for
// the remote party allowing them to claim this output before the CSV
// delay if we breach.
localScript, err := lnwallet.CommitScriptToSelf(
c.cfg.chanState.ChanType, c.cfg.chanState.IsInitiator,
commitKeyRing.ToLocalKey, commitKeyRing.RevocationKey,
uint32(c.cfg.chanState.LocalChanCfg.CsvDelay), leaseExpiry,
)
if err != nil {
return false, err
}
// With all our scripts assembled, we'll examine the outputs of the
// commitment transaction to determine if this is a local force close
// or not.
ourCommit := false
for _, output := range commitSpend.SpendingTx.TxOut {
pkScript := output.PkScript
switch {
case bytes.Equal(localScript.PkScript, pkScript):
ourCommit = true
case bytes.Equal(remoteScript.PkScript, pkScript):
ourCommit = true
}
}
// If the script is not present, this cannot be our commit.
if !ourCommit {
return false, nil
}
log.Warnf("Detected local unilateral close of unknown state %v "+
"(our state=%v)", broadcastStateNum,
chainSet.localCommit.CommitHeight)
// If this is our commitment transaction, then we try to act even
// though we won't be able to sweep HTLCs.
chainSet.commitSet.ConfCommitKey = &LocalHtlcSet
if err := c.dispatchLocalForceClose(
commitSpend, broadcastStateNum, chainSet.commitSet,
); err != nil {
return false, fmt.Errorf("unable to handle local"+
"close for chan_point=%v: %v",
c.cfg.chanState.FundingOutpoint, err)
}
return true, nil
}
// chainSet includes all the information we need to dispatch a channel close
// event to any subscribers.
type chainSet struct {
// remoteStateNum is the commitment number of the lowest valid
// commitment the remote party holds from our PoV. This value is used
// to determine if the remote party is playing a state that's behind,
// in line, or ahead of the latest state we know for it.
remoteStateNum uint64
// commitSet includes information pertaining to the set of active HTLCs
// on each commitment.
commitSet CommitSet
// remoteCommit is the current commitment of the remote party.
remoteCommit channeldb.ChannelCommitment
// localCommit is our current commitment.
localCommit channeldb.ChannelCommitment
// remotePendingCommit points to the dangling commitment of the remote
// party, if it exists. If there's no dangling commitment, then this
// pointer will be nil.
remotePendingCommit *channeldb.ChannelCommitment
}
// newChainSet creates a new chainSet given the current up to date channel
// state.
func newChainSet(chanState *channeldb.OpenChannel) (*chainSet, error) {
// First, we'll grab the current unrevoked commitments for ourselves
// and the remote party.
localCommit, remoteCommit, err := chanState.LatestCommitments()
if err != nil {
return nil, fmt.Errorf("unable to fetch channel state for "+
"chan_point=%v", chanState.FundingOutpoint)
}
log.Debugf("ChannelPoint(%v): local_commit_type=%v, local_commit=%v",
chanState.FundingOutpoint, chanState.ChanType,
spew.Sdump(localCommit))
log.Debugf("ChannelPoint(%v): remote_commit_type=%v, remote_commit=%v",
chanState.FundingOutpoint, chanState.ChanType,
spew.Sdump(remoteCommit))
// Fetch the current known commit height for the remote party, and
// their pending commitment chain tip if it exists.
remoteStateNum := remoteCommit.CommitHeight
remoteChainTip, err := chanState.RemoteCommitChainTip()
if err != nil && err != channeldb.ErrNoPendingCommit {
return nil, fmt.Errorf("unable to obtain chain tip for "+
"ChannelPoint(%v): %v",
chanState.FundingOutpoint, err)
}
// Now that we have all the possible valid commitments, we'll make the
// CommitSet the ChannelArbitrator will need in order to carry out its
// duty.
commitSet := CommitSet{
HtlcSets: map[HtlcSetKey][]channeldb.HTLC{
LocalHtlcSet: localCommit.Htlcs,
RemoteHtlcSet: remoteCommit.Htlcs,
},
}
var remotePendingCommit *channeldb.ChannelCommitment
if remoteChainTip != nil {
remotePendingCommit = &remoteChainTip.Commitment
log.Debugf("ChannelPoint(%v): remote_pending_commit_type=%v, "+
"remote_pending_commit=%v", chanState.FundingOutpoint,
chanState.ChanType,
spew.Sdump(remoteChainTip.Commitment))
htlcs := remoteChainTip.Commitment.Htlcs
commitSet.HtlcSets[RemotePendingHtlcSet] = htlcs
}
// We'll now retrieve the latest state of the revocation store so we
// can populate the revocation information within the channel state
// object that we have.
//
// TODO(roasbeef): mutation is bad mkay
_, err = chanState.RemoteRevocationStore()
if err != nil {
return nil, fmt.Errorf("unable to fetch revocation state for "+
"chan_point=%v", chanState.FundingOutpoint)
}
return &chainSet{
remoteStateNum: remoteStateNum,
commitSet: commitSet,
localCommit: *localCommit,
remoteCommit: *remoteCommit,
remotePendingCommit: remotePendingCommit,
}, nil
}
// closeObserver is a dedicated goroutine that will watch for any closes of the
// channel that it's watching on chain. In the event of an on-chain event, the
// close observer will assembled the proper materials required to claim the
// funds of the channel on-chain (if required), then dispatch these as
// notifications to all subscribers.
func (c *chainWatcher) closeObserver(spendNtfn *chainntnfs.SpendEvent) {
defer c.wg.Done()
log.Infof("Close observer for ChannelPoint(%v) active",
c.cfg.chanState.FundingOutpoint)
select {
// We've detected a spend of the channel onchain! Depending on the type
// of spend, we'll act accordingly, so we'll examine the spending
// transaction to determine what we should do.
//
// TODO(Roasbeef): need to be able to ensure this only triggers
// on confirmation, to ensure if multiple txns are broadcast, we
// act on the one that's timestamped
case commitSpend, ok := <-spendNtfn.Spend:
// If the channel was closed, then this means that the notifier
// exited, so we will as well.
if !ok {
return
}
// Otherwise, the remote party might have broadcast a prior
// revoked state...!!!
commitTxBroadcast := commitSpend.SpendingTx
// First, we'll construct the chainset which includes all the
// data we need to dispatch an event to our subscribers about
// this possible channel close event.
chainSet, err := newChainSet(c.cfg.chanState)
if err != nil {
log.Errorf("unable to create commit set: %v", err)
return
}
// Decode the state hint encoded within the commitment
// transaction to determine if this is a revoked state or not.
obfuscator := c.stateHintObfuscator
broadcastStateNum := c.cfg.extractStateNumHint(
commitTxBroadcast, obfuscator,
)
// We'll go on to check whether it could be our own commitment
// that was published and know is confirmed.
ok, err = c.handleKnownLocalState(
commitSpend, broadcastStateNum, chainSet,
)
if err != nil {
log.Errorf("Unable to handle known local state: %v",
err)
return
}
if ok {
return
}
// Now that we know it is neither a non-cooperative closure nor
// a local close with the latest state, we check if it is the
// remote that closed with any prior or current state.
ok, err = c.handleKnownRemoteState(
commitSpend, broadcastStateNum, chainSet,
)
if err != nil {
log.Errorf("Unable to handle known remote state: %v",
err)
return
}
if ok {
return
}
// Next, we'll check to see if this is a cooperative channel
// closure or not. This is characterized by having an input
// sequence number that's finalized. This won't happen with
// regular commitment transactions due to the state hint
// encoding scheme.
if commitTxBroadcast.TxIn[0].Sequence == wire.MaxTxInSequenceNum {
// TODO(roasbeef): rare but possible, need itest case
// for
err := c.dispatchCooperativeClose(commitSpend)
if err != nil {
log.Errorf("unable to handle co op close: %v", err)
}
return
}
log.Warnf("Unknown commitment broadcast for "+
"ChannelPoint(%v) ", c.cfg.chanState.FundingOutpoint)
// We'll try to recover as best as possible from losing state.
// We first check if this was a local unknown state. This could
// happen if we force close, then lose state or attempt
// recovery before the commitment confirms.
ok, err = c.handleUnknownLocalState(
commitSpend, broadcastStateNum, chainSet,
)
if err != nil {
log.Errorf("Unable to handle known local state: %v",
err)
return
}
if ok {
return
}
// Since it was neither a known remote state, nor a local state
// that was published, it most likely mean we lost state and
// the remote node closed. In this case we must start the DLP
// protocol in hope of getting our money back.
ok, err = c.handleUnknownRemoteState(
commitSpend, broadcastStateNum, chainSet,
)
if err != nil {
log.Errorf("Unable to handle unknown remote state: %v",
err)
return
}
if ok {
return
}
log.Warnf("Unable to handle spending tx %v of channel point %v",
commitTxBroadcast.TxHash(), c.cfg.chanState.FundingOutpoint)
return
// The chainWatcher has been signalled to exit, so we'll do so now.
case <-c.quit:
return
}
}
// handleKnownLocalState checks whether the passed spend is a local state that
// is known to us (the current state). If so we will act on this state using
// the passed chainSet. If this is not a known local state, false is returned.
func (c *chainWatcher) handleKnownLocalState(
commitSpend *chainntnfs.SpendDetail, broadcastStateNum uint64,
chainSet *chainSet) (bool, error) {
// If the channel is recovered, we won't have a local commit to check
// against, so immediately return.
if c.cfg.chanState.HasChanStatus(channeldb.ChanStatusRestored) {
return false, nil
}
commitTxBroadcast := commitSpend.SpendingTx
commitHash := commitTxBroadcast.TxHash()
// Check whether our latest local state hit the chain.
if chainSet.localCommit.CommitTx.TxHash() != commitHash {
return false, nil
}
chainSet.commitSet.ConfCommitKey = &LocalHtlcSet
if err := c.dispatchLocalForceClose(
commitSpend, broadcastStateNum, chainSet.commitSet,
); err != nil {
return false, fmt.Errorf("unable to handle local"+
"close for chan_point=%v: %v",
c.cfg.chanState.FundingOutpoint, err)
}
return true, nil
}
// handleKnownRemoteState checks whether the passed spend is a remote state
// that is known to us (a revoked, current or pending state). If so we will act
// on this state using the passed chainSet. If this is not a known remote
// state, false is returned.
func (c *chainWatcher) handleKnownRemoteState(
commitSpend *chainntnfs.SpendDetail, broadcastStateNum uint64,
chainSet *chainSet) (bool, error) {
// If the channel is recovered, we won't have any remote commit to
// check against, so imemdiately return.
if c.cfg.chanState.HasChanStatus(channeldb.ChanStatusRestored) {
return false, nil
}
commitTxBroadcast := commitSpend.SpendingTx
commitHash := commitTxBroadcast.TxHash()
spendHeight := uint32(commitSpend.SpendingHeight)
switch {
// If the spending transaction matches the current latest state, then
// they've initiated a unilateral close. So we'll trigger the
// unilateral close signal so subscribers can clean up the state as
// necessary.
case chainSet.remoteCommit.CommitTx.TxHash() == commitHash:
log.Infof("Remote party broadcast base set, "+
"commit_num=%v", chainSet.remoteStateNum)
chainSet.commitSet.ConfCommitKey = &RemoteHtlcSet
err := c.dispatchRemoteForceClose(
commitSpend, chainSet.remoteCommit,
chainSet.commitSet,
c.cfg.chanState.RemoteCurrentRevocation,
)
if err != nil {
return false, fmt.Errorf("unable to handle remote "+
"close for chan_point=%v: %v",
c.cfg.chanState.FundingOutpoint, err)
}
return true, nil
// We'll also handle the case of the remote party broadcasting
// their commitment transaction which is one height above ours.
// This case can arise when we initiate a state transition, but
// the remote party has a fail crash _after_ accepting the new
// state, but _before_ sending their signature to us.
case chainSet.remotePendingCommit != nil &&
chainSet.remotePendingCommit.CommitTx.TxHash() == commitHash:
log.Infof("Remote party broadcast pending set, "+
"commit_num=%v", chainSet.remoteStateNum+1)
chainSet.commitSet.ConfCommitKey = &RemotePendingHtlcSet
err := c.dispatchRemoteForceClose(
commitSpend, *chainSet.remotePendingCommit,
chainSet.commitSet,
c.cfg.chanState.RemoteNextRevocation,
)
if err != nil {
return false, fmt.Errorf("unable to handle remote "+
"close for chan_point=%v: %v",
c.cfg.chanState.FundingOutpoint, err)
}
return true, nil
}
// We check if we have a revoked state at this state num that matches
// the spend transaction.
retribution, err := lnwallet.NewBreachRetribution(
c.cfg.chanState, broadcastStateNum, spendHeight,
)
switch {
// If we had no log entry at this height, this was not a revoked state.
case err == channeldb.ErrLogEntryNotFound:
return false, nil
case err == channeldb.ErrNoPastDeltas:
return false, nil
case err != nil:
return false, fmt.Errorf("unable to create breach "+
"retribution: %v", err)
}
// We found a revoked state at this height, but it could still be our
// own broadcasted state we are looking at. Therefore check that the
// commit matches before assuming it was a breach.
if retribution.BreachTransaction.TxHash() != commitHash {
return false, nil
}
// Create an AnchorResolution for the breached state.
anchorRes, err := lnwallet.NewAnchorResolution(
c.cfg.chanState, commitSpend.SpendingTx,
)
if err != nil {
return false, fmt.Errorf("unable to create anchor "+
"resolution: %v", err)
}
// We'll set the ConfCommitKey here as the remote htlc set. This is
// only used to ensure a nil-pointer-dereference doesn't occur and is
// not used otherwise. The HTLC's may not exist for the
// RemotePendingHtlcSet.
chainSet.commitSet.ConfCommitKey = &RemoteHtlcSet
// THEY'RE ATTEMPTING TO VIOLATE THE CONTRACT LAID OUT WITHIN THE
// PAYMENT CHANNEL. Therefore we close the signal indicating a revoked
// broadcast to allow subscribers to swiftly dispatch justice!!!
err = c.dispatchContractBreach(
commitSpend, chainSet, broadcastStateNum, retribution,
anchorRes,
)
if err != nil {
return false, fmt.Errorf("unable to handle channel "+
"breach for chan_point=%v: %v",
c.cfg.chanState.FundingOutpoint, err)
}
return true, nil
}
// handleUnknownRemoteState is the last attempt we make at reclaiming funds
// from the closed channel, by checkin whether the passed spend _could_ be a
// remote spend that is unknown to us (we lost state). We will try to initiate
// Data Loss Protection in order to restore our commit point and reclaim our
// funds from the channel. If we are not able to act on it, false is returned.
func (c *chainWatcher) handleUnknownRemoteState(
commitSpend *chainntnfs.SpendDetail, broadcastStateNum uint64,
chainSet *chainSet) (bool, error) {
log.Warnf("Remote node broadcast state #%v, "+
"which is more than 1 beyond best known "+
"state #%v!!! Attempting recovery...",
broadcastStateNum, chainSet.remoteStateNum)
// If this isn't a tweakless commitment, then we'll need to wait for
// the remote party's latest unrevoked commitment point to be presented
// to us as we need this to sweep. Otherwise, we can dispatch the
// remote close and sweep immediately using a fake commitPoint as it
// isn't actually needed for recovery anymore.
commitPoint := c.cfg.chanState.RemoteCurrentRevocation
tweaklessCommit := c.cfg.chanState.ChanType.IsTweakless()
if !tweaklessCommit {
commitPoint = c.waitForCommitmentPoint()
if commitPoint == nil {
return false, fmt.Errorf("unable to get commit point")
}
log.Infof("Recovered commit point(%x) for "+
"channel(%v)! Now attempting to use it to "+
"sweep our funds...",
commitPoint.SerializeCompressed(),
c.cfg.chanState.FundingOutpoint)
} else {
log.Infof("ChannelPoint(%v) is tweakless, "+
"moving to sweep directly on chain",
c.cfg.chanState.FundingOutpoint)
}
// Since we don't have the commitment stored for this state, we'll just
// pass an empty commitment within the commitment set. Note that this
// means we won't be able to recover any HTLC funds.
//
// TODO(halseth): can we try to recover some HTLCs?
chainSet.commitSet.ConfCommitKey = &RemoteHtlcSet
err := c.dispatchRemoteForceClose(
commitSpend, channeldb.ChannelCommitment{},
chainSet.commitSet, commitPoint,
)
if err != nil {
return false, fmt.Errorf("unable to handle remote "+
"close for chan_point=%v: %v",
c.cfg.chanState.FundingOutpoint, err)
}
return true, nil
}
// toSelfAmount takes a transaction and returns the sum of all outputs that pay
// to a script that the wallet controls. If no outputs pay to us, then we
// return zero. This is possible as our output may have been trimmed due to
// being dust.
func (c *chainWatcher) toSelfAmount(tx *wire.MsgTx) btcutil.Amount {
var selfAmt btcutil.Amount
for _, txOut := range tx.TxOut {
_, addrs, _, err := txscript.ExtractPkScriptAddrs(
// Doesn't matter what net we actually pass in.
txOut.PkScript, &chaincfg.TestNet3Params,
)
if err != nil {
continue
}
for _, addr := range addrs {
if c.cfg.isOurAddr(addr) {
selfAmt += btcutil.Amount(txOut.Value)
}
}
}
return selfAmt
}
// dispatchCooperativeClose processed a detect cooperative channel closure.
// We'll use the spending transaction to locate our output within the
// transaction, then clean up the database state. We'll also dispatch a
// notification to all subscribers that the channel has been closed in this
// manner.
func (c *chainWatcher) dispatchCooperativeClose(commitSpend *chainntnfs.SpendDetail) error {
broadcastTx := commitSpend.SpendingTx
log.Infof("Cooperative closure for ChannelPoint(%v): %v",
c.cfg.chanState.FundingOutpoint, spew.Sdump(broadcastTx))
// If the input *is* final, then we'll check to see which output is
// ours.
localAmt := c.toSelfAmount(broadcastTx)
// Once this is known, we'll mark the state as fully closed in the
// database. We can do this as a cooperatively closed channel has all
// its outputs resolved after only one confirmation.
closeSummary := &channeldb.ChannelCloseSummary{
ChanPoint: c.cfg.chanState.FundingOutpoint,
ChainHash: c.cfg.chanState.ChainHash,
ClosingTXID: *commitSpend.SpenderTxHash,
RemotePub: c.cfg.chanState.IdentityPub,
Capacity: c.cfg.chanState.Capacity,
CloseHeight: uint32(commitSpend.SpendingHeight),
SettledBalance: localAmt,
CloseType: channeldb.CooperativeClose,
ShortChanID: c.cfg.chanState.ShortChanID(),
IsPending: true,
RemoteCurrentRevocation: c.cfg.chanState.RemoteCurrentRevocation,
RemoteNextRevocation: c.cfg.chanState.RemoteNextRevocation,
LocalChanConfig: c.cfg.chanState.LocalChanCfg,
}
// Attempt to add a channel sync message to the close summary.
chanSync, err := c.cfg.chanState.ChanSyncMsg()
if err != nil {
log.Errorf("ChannelPoint(%v): unable to create channel sync "+
"message: %v", c.cfg.chanState.FundingOutpoint, err)
} else {
closeSummary.LastChanSyncMsg = chanSync
}
// Create a summary of all the information needed to handle the
// cooperative closure.
closeInfo := &CooperativeCloseInfo{
ChannelCloseSummary: closeSummary,
}
// With the event processed, we'll now notify all subscribers of the
// event.
c.Lock()
for _, sub := range c.clientSubscriptions {
select {
case sub.CooperativeClosure <- closeInfo:
case <-c.quit:
c.Unlock()
return fmt.Errorf("exiting")
}
}
c.Unlock()
return nil
}
// dispatchLocalForceClose processes a unilateral close by us being confirmed.
func (c *chainWatcher) dispatchLocalForceClose(
commitSpend *chainntnfs.SpendDetail,
stateNum uint64, commitSet CommitSet) error {
log.Infof("Local unilateral close of ChannelPoint(%v) "+
"detected", c.cfg.chanState.FundingOutpoint)
forceClose, err := lnwallet.NewLocalForceCloseSummary(
c.cfg.chanState, c.cfg.signer,
commitSpend.SpendingTx, stateNum,
)
if err != nil {
return err
}
// As we've detected that the channel has been closed, immediately
// creating a close summary for future usage by related sub-systems.
chanSnapshot := forceClose.ChanSnapshot
closeSummary := &channeldb.ChannelCloseSummary{
ChanPoint: chanSnapshot.ChannelPoint,
ChainHash: chanSnapshot.ChainHash,
ClosingTXID: forceClose.CloseTx.TxHash(),
RemotePub: &chanSnapshot.RemoteIdentity,
Capacity: chanSnapshot.Capacity,
CloseType: channeldb.LocalForceClose,
IsPending: true,
ShortChanID: c.cfg.chanState.ShortChanID(),
CloseHeight: uint32(commitSpend.SpendingHeight),
RemoteCurrentRevocation: c.cfg.chanState.RemoteCurrentRevocation,
RemoteNextRevocation: c.cfg.chanState.RemoteNextRevocation,
LocalChanConfig: c.cfg.chanState.LocalChanCfg,
}
// If our commitment output isn't dust or we have active HTLC's on the
// commitment transaction, then we'll populate the balances on the
// close channel summary.
if forceClose.CommitResolution != nil {
closeSummary.SettledBalance = chanSnapshot.LocalBalance.ToSatoshis()
closeSummary.TimeLockedBalance = chanSnapshot.LocalBalance.ToSatoshis()
}
for _, htlc := range forceClose.HtlcResolutions.OutgoingHTLCs {
htlcValue := btcutil.Amount(htlc.SweepSignDesc.Output.Value)
closeSummary.TimeLockedBalance += htlcValue
}
// Attempt to add a channel sync message to the close summary.
chanSync, err := c.cfg.chanState.ChanSyncMsg()
if err != nil {
log.Errorf("ChannelPoint(%v): unable to create channel sync "+
"message: %v", c.cfg.chanState.FundingOutpoint, err)
} else {
closeSummary.LastChanSyncMsg = chanSync
}
// With the event processed, we'll now notify all subscribers of the
// event.
closeInfo := &LocalUnilateralCloseInfo{
SpendDetail: commitSpend,
LocalForceCloseSummary: forceClose,
ChannelCloseSummary: closeSummary,
CommitSet: commitSet,
}
c.Lock()
for _, sub := range c.clientSubscriptions {
select {
case sub.LocalUnilateralClosure <- closeInfo:
case <-c.quit:
c.Unlock()
return fmt.Errorf("exiting")
}
}
c.Unlock()
return nil
}
// dispatchRemoteForceClose processes a detected unilateral channel closure by
// the remote party. This function will prepare a UnilateralCloseSummary which
// will then be sent to any subscribers allowing them to resolve all our funds
// in the channel on chain. Once this close summary is prepared, all registered
// subscribers will receive a notification of this event. The commitPoint
// argument should be set to the per_commitment_point corresponding to the
// spending commitment.
//
// NOTE: The remoteCommit argument should be set to the stored commitment for
// this particular state. If we don't have the commitment stored (should only
// happen in case we have lost state) it should be set to an empty struct, in
// which case we will attempt to sweep the non-HTLC output using the passed
// commitPoint.
func (c *chainWatcher) dispatchRemoteForceClose(
commitSpend *chainntnfs.SpendDetail,
remoteCommit channeldb.ChannelCommitment,
commitSet CommitSet, commitPoint *btcec.PublicKey) error {
log.Infof("Unilateral close of ChannelPoint(%v) "+
"detected", c.cfg.chanState.FundingOutpoint)
// First, we'll create a closure summary that contains all the
// materials required to let each subscriber sweep the funds in the
// channel on-chain.
uniClose, err := lnwallet.NewUnilateralCloseSummary(
c.cfg.chanState, c.cfg.signer, commitSpend,
remoteCommit, commitPoint,
)
if err != nil {
return err
}
// With the event processed, we'll now notify all subscribers of the
// event.
c.Lock()
for _, sub := range c.clientSubscriptions {
select {
case sub.RemoteUnilateralClosure <- &RemoteUnilateralCloseInfo{
UnilateralCloseSummary: uniClose,
CommitSet: commitSet,
}:
case <-c.quit:
c.Unlock()
return fmt.Errorf("exiting")
}
}
c.Unlock()
return nil
}
// dispatchContractBreach processes a detected contract breached by the remote
// party. This method is to be called once we detect that the remote party has
// broadcast a prior revoked commitment state. This method well prepare all the
// materials required to bring the cheater to justice, then notify all
// registered subscribers of this event.
func (c *chainWatcher) dispatchContractBreach(spendEvent *chainntnfs.SpendDetail,
chainSet *chainSet, broadcastStateNum uint64,
retribution *lnwallet.BreachRetribution,
anchorRes *lnwallet.AnchorResolution) error {
log.Warnf("Remote peer has breached the channel contract for "+
"ChannelPoint(%v). Revoked state #%v was broadcast!!!",
c.cfg.chanState.FundingOutpoint, broadcastStateNum)
if err := c.cfg.chanState.MarkBorked(); err != nil {
return fmt.Errorf("unable to mark channel as borked: %v", err)
}
spendHeight := uint32(spendEvent.SpendingHeight)
log.Debugf("Punishment breach retribution created: %v",
newLogClosure(func() string {
retribution.KeyRing.LocalHtlcKey = nil
retribution.KeyRing.RemoteHtlcKey = nil
retribution.KeyRing.ToLocalKey = nil
retribution.KeyRing.ToRemoteKey = nil
retribution.KeyRing.RevocationKey = nil
return spew.Sdump(retribution)
}))
settledBalance := chainSet.remoteCommit.LocalBalance.ToSatoshis()
closeSummary := channeldb.ChannelCloseSummary{
ChanPoint: c.cfg.chanState.FundingOutpoint,
ChainHash: c.cfg.chanState.ChainHash,
ClosingTXID: *spendEvent.SpenderTxHash,
CloseHeight: spendHeight,
RemotePub: c.cfg.chanState.IdentityPub,
Capacity: c.cfg.chanState.Capacity,
SettledBalance: settledBalance,
CloseType: channeldb.BreachClose,
IsPending: true,
ShortChanID: c.cfg.chanState.ShortChanID(),
RemoteCurrentRevocation: c.cfg.chanState.RemoteCurrentRevocation,
RemoteNextRevocation: c.cfg.chanState.RemoteNextRevocation,
LocalChanConfig: c.cfg.chanState.LocalChanCfg,
}
// Attempt to add a channel sync message to the close summary.
chanSync, err := c.cfg.chanState.ChanSyncMsg()
if err != nil {
log.Errorf("ChannelPoint(%v): unable to create channel sync "+
"message: %v", c.cfg.chanState.FundingOutpoint, err)
} else {
closeSummary.LastChanSyncMsg = chanSync
}
// Hand the retribution info over to the breach arbiter. This function
// will wait for a response from the breach arbiter and then proceed to
// send a BreachCloseInfo to the channel arbitrator. The channel arb
// will then mark the channel as closed after resolutions and the
// commit set are logged in the arbitrator log.
if err := c.cfg.contractBreach(retribution); err != nil {
log.Errorf("unable to hand breached contract off to "+
"breachArbiter: %v", err)
return err
}
breachRes := &BreachResolution{
FundingOutPoint: c.cfg.chanState.FundingOutpoint,
}
breachInfo := &BreachCloseInfo{
CommitHash: spendEvent.SpendingTx.TxHash(),
BreachResolution: breachRes,
AnchorResolution: anchorRes,
CommitSet: chainSet.commitSet,
CloseSummary: closeSummary,
}
// With the event processed and channel closed, we'll now notify all
// subscribers of the event.
c.Lock()
for _, sub := range c.clientSubscriptions {
select {
case sub.ContractBreach <- breachInfo:
case <-c.quit:
c.Unlock()
return fmt.Errorf("quitting")
}
}
c.Unlock()
return nil
}
// waitForCommitmentPoint waits for the commitment point to be inserted into
// the local database. We'll use this method in the DLP case, to wait for the
// remote party to send us their point, as we can't proceed until we have that.
func (c *chainWatcher) waitForCommitmentPoint() *btcec.PublicKey {
// If we are lucky, the remote peer sent us the correct commitment
// point during channel sync, such that we can sweep our funds. If we
// cannot find the commit point, there's not much we can do other than
// wait for us to retrieve it. We will attempt to retrieve it from the
// peer each time we connect to it.
//
// TODO(halseth): actively initiate re-connection to the peer?
backoff := minCommitPointPollTimeout
for {
commitPoint, err := c.cfg.chanState.DataLossCommitPoint()
if err == nil {
return commitPoint
}
log.Errorf("Unable to retrieve commitment point for "+
"channel(%v) with lost state: %v. Retrying in %v.",
c.cfg.chanState.FundingOutpoint, err, backoff)
select {
// Wait before retrying, with an exponential backoff.
case <-time.After(backoff):
backoff = 2 * backoff
if backoff > maxCommitPointPollTimeout {
backoff = maxCommitPointPollTimeout
}
case <-c.quit:
return nil
}
}
}