lnd.xprv/chancloser.go

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package lnd
import (
"fmt"
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"github.com/btcsuite/btcd/txscript"
"github.com/btcsuite/btcd/wire"
"github.com/btcsuite/btcutil"
"github.com/davecgh/go-spew/spew"
"github.com/lightningnetwork/lnd/htlcswitch"
"github.com/lightningnetwork/lnd/lnwallet"
"github.com/lightningnetwork/lnd/lnwire"
)
var (
// ErrChanAlreadyClosing is returned when a channel shutdown is
// attempted more than once.
ErrChanAlreadyClosing = fmt.Errorf("channel shutdown already initiated")
// ErrChanCloseNotFinished is returned when a caller attempts to access
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// a field or function that is contingent on the channel closure
// negotiation already being completed.
ErrChanCloseNotFinished = fmt.Errorf("close negotiation not finished")
// ErrInvalidState is returned when the closing state machine receives
// a message while it is in an unknown state.
ErrInvalidState = fmt.Errorf("invalid state")
)
// closeState represents all the possible states the channel closer state
// machine can be in. Each message will either advance to the next state, or
// remain at the current state. Once the state machine reaches a state of
// closeFinished, then negotiation is over.
type closeState uint8
const (
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// closeIdle is the initial starting state. In this state, the state
// machine has been instantiated, but no state transitions have been
// attempted. If a state machine receives a message while in this
// state, then it is the responder to an initiated cooperative channel
// closure.
closeIdle closeState = iota
// closeShutdownInitiated is the state that's transitioned to once the
// initiator of a closing workflow sends the shutdown message. At this
// point, they're waiting for the remote party to respond with their
// own shutdown message. After which, they'll both enter the fee
// negotiation phase.
closeShutdownInitiated
// closeFeeNegotiation is the third, and most persistent state. Both
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// parties enter this state after they've sent and received a shutdown
// message. During this phase, both sides will send monotonically
// increasing fee requests until one side accepts the last fee rate
// offered by the other party. In this case, the party will broadcast
// the closing transaction, and send the accepted fee to the remote
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// party. This then causes a shift into the closeFinished state.
closeFeeNegotiation
// closeFinished is the final state of the state machine. In this,
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// state a side has accepted a fee offer and has broadcast the valid
// closing transaction to the network. During this phase, the closing
// transaction becomes available for examination.
closeFinished
)
// chanCloseCfg holds all the items that a channelCloser requires to carry out
// its duties.
type chanCloseCfg struct {
// channel is the channel that should be closed.
channel *lnwallet.LightningChannel
// unregisterChannel is a function closure that allows the
// channelCloser to re-register a channel. Once this has been done, no
// further HTLC's should be routed through the channel.
unregisterChannel func(lnwire.ChannelID)
// broadcastTx broadcasts the passed transaction to the network.
broadcastTx func(*wire.MsgTx) error
// disableChannel disables a channel, resulting in it not being able to
// forward payments.
disableChannel func(wire.OutPoint) error
// quit is a channel that should be sent upon in the occasion the state
// machine should cease all progress and shutdown.
quit chan struct{}
}
// channelCloser is a state machine that handles the cooperative channel
// closure procedure. This includes shutting down a channel, marking it
// ineligible for routing HTLC's, negotiating fees with the remote party, and
// finally broadcasting the fully signed closure transaction to the network.
type channelCloser struct {
// state is the current state of the state machine.
state closeState
// cfg holds the configuration for this channelCloser instance.
cfg chanCloseCfg
// chanPoint is the full channel point of the target channel.
chanPoint wire.OutPoint
// cid is the full channel ID of the target channel.
cid lnwire.ChannelID
// negotiationHeight is the height that the fee negotiation begun at.
negotiationHeight uint32
// closingTx is the final, fully signed closing transaction. This will
// only be populated once the state machine shifts to the closeFinished
// state.
closingTx *wire.MsgTx
// idealFeeSat is the ideal fee that the state machine should initially
// offer when starting negotiation. This will be used as a baseline.
idealFeeSat btcutil.Amount
// lastFeeProposal is the last fee that we proposed to the remote
// party. We'll use this as a pivot point to rachet our next offer up,
// or down, or simply accept the remote party's prior offer.
lastFeeProposal btcutil.Amount
// priorFeeOffers is a map that keeps track of all the proposed fees
// that we've offered during the fee negotiation. We use this map to
// cut the negotiation early if the remote party ever sends an offer
// that we've sent in the past. Once negotiation terminates, we can
// extract the prior signature of our accepted offer from this map.
//
// TODO(roasbeef): need to ensure if they broadcast w/ any of our prior
// sigs, we are aware of
priorFeeOffers map[btcutil.Amount]*lnwire.ClosingSigned
// closeReq is the initial closing request. This will only be populated
// if we're the initiator of this closing negotiation.
//
// TODO(roasbeef): abstract away
closeReq *htlcswitch.ChanClose
// localDeliveryScript is the script that we'll send our settled
// channel funds to.
localDeliveryScript []byte
// remoteDeliveryScript is the script that we'll send the remote
// party's settled channel funds to.
remoteDeliveryScript []byte
}
// newChannelCloser creates a new instance of the channel closure given the
// passed configuration, and delivery+fee preference. The final argument should
// only be populated iff, we're the initiator of this closing request.
func newChannelCloser(cfg chanCloseCfg, deliveryScript []byte,
idealFeePerKw lnwallet.SatPerKWeight, negotiationHeight uint32,
closeReq *htlcswitch.ChanClose) *channelCloser {
// Given the target fee-per-kw, we'll compute what our ideal _total_
// fee will be starting at for this fee negotiation.
//
// TODO(roasbeef): should factor in minimal commit
idealFeeSat := cfg.channel.CalcFee(idealFeePerKw)
// If this fee is greater than the fee currently present within the
// commitment transaction, then we'll clamp it down to be within the
// proper range.
//
// TODO(roasbeef): clamp fee func?
channelCommitFee := cfg.channel.StateSnapshot().CommitFee
if idealFeeSat > channelCommitFee {
peerLog.Infof("Ideal starting fee of %v is greater than "+
"commit fee of %v, clamping", int64(idealFeeSat),
int64(channelCommitFee))
idealFeeSat = channelCommitFee
}
peerLog.Infof("Ideal fee for closure of ChannelPoint(%v) is: %v sat",
cfg.channel.ChannelPoint(), int64(idealFeeSat))
cid := lnwire.NewChanIDFromOutPoint(cfg.channel.ChannelPoint())
return &channelCloser{
closeReq: closeReq,
state: closeIdle,
chanPoint: *cfg.channel.ChannelPoint(),
cid: cid,
cfg: cfg,
negotiationHeight: negotiationHeight,
idealFeeSat: idealFeeSat,
localDeliveryScript: deliveryScript,
priorFeeOffers: make(map[btcutil.Amount]*lnwire.ClosingSigned),
}
}
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// initChanShutdown begins the shutdown process by un-registering the channel,
// and creating a valid shutdown message to our target delivery address.
func (c *channelCloser) initChanShutdown() (*lnwire.Shutdown, error) {
// With both items constructed we'll now send the shutdown message for
// this particular channel, advertising a shutdown request to our
// desired closing script.
shutdown := lnwire.NewShutdown(c.cid, c.localDeliveryScript)
// TODO(roasbeef): err if channel has htlc's?
// Before returning the shutdown message, we'll unregister the channel
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// to ensure that it isn't seen as usable within the system.
//
// TODO(roasbeef): fail if err?
c.cfg.unregisterChannel(c.cid)
peerLog.Infof("ChannelPoint(%v): sending shutdown message", c.chanPoint)
return shutdown, nil
}
// ShutdownChan is the first method that's to be called by the initiator of the
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// cooperative channel closure. This message returns the shutdown message to
// send to the remote party. Upon completion, we enter the
// closeShutdownInitiated phase as we await a response.
func (c *channelCloser) ShutdownChan() (*lnwire.Shutdown, error) {
// If we attempt to shutdown the channel for the first time, and we're
// not in the closeIdle state, then the caller made an error.
if c.state != closeIdle {
return nil, ErrChanAlreadyClosing
}
peerLog.Infof("ChannelPoint(%v): initiating shutdown of", c.chanPoint)
shutdownMsg, err := c.initChanShutdown()
if err != nil {
return nil, err
}
// With the opening steps complete, we'll transition into the
// closeShutdownInitiated state. In this state, we'll wait until the
// other party sends their version of the shutdown message.
c.state = closeShutdownInitiated
// Finally, we'll return the shutdown message to the caller so it can
// send it to the remote peer.
return shutdownMsg, nil
}
// ClosingTx returns the fully signed, final closing transaction.
//
// NOTE: This transaction is only available if the state machine is in the
// closeFinished state.
func (c *channelCloser) ClosingTx() (*wire.MsgTx, error) {
// If the state machine hasn't finished closing the channel then we'll
// return an error as we haven't yet computed the closing tx.
if c.state != closeFinished {
return nil, ErrChanCloseNotFinished
}
return c.closingTx, nil
}
// CloseRequest returns the original close request that prompted the creation
// of the state machine.
//
// NOTE: This will only return a non-nil pointer if we were the initiator of
// the cooperative closure workflow.
func (c *channelCloser) CloseRequest() *htlcswitch.ChanClose {
return c.closeReq
}
// ProcessCloseMsg attempts to process the next message in the closing series.
// This method will update the state accordingly and return two primary values:
// the next set of messages to be sent, and a bool indicating if the fee
// negotiation process has completed. If the second value is true, then this
// means the channelCloser can be garbage collected.
func (c *channelCloser) ProcessCloseMsg(msg lnwire.Message) ([]lnwire.Message, bool, error) {
switch c.state {
// If we're in the close idle state, and we're receiving a channel
// closure related message, then this indicates that we're on the
// receiving side of an initiated channel closure.
case closeIdle:
// First, we'll assert that we have a channel shutdown message,
// otherwise, this is an attempted invalid state transition.
shutDownMsg, ok := msg.(*lnwire.Shutdown)
if !ok {
return nil, false, fmt.Errorf("expected lnwire.Shutdown, "+
"instead have %v", spew.Sdump(msg))
}
// Next, we'll note the other party's preference for their
// delivery address. We'll use this when we craft the closure
// transaction.
c.remoteDeliveryScript = shutDownMsg.Address
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// We'll generate a shutdown message of our own to send across
// the wire.
localShutdown, err := c.initChanShutdown()
if err != nil {
return nil, false, err
}
peerLog.Infof("ChannelPoint(%v): Responding to shutdown",
c.chanPoint)
msgsToSend := make([]lnwire.Message, 0, 2)
msgsToSend = append(msgsToSend, localShutdown)
// After the other party receives this message, we'll actually
// start the final stage of the closure process: fee
// negotiation. So we'll update our internal state to reflect
// this, so we can handle the next message sent.
c.state = closeFeeNegotiation
// We'll also craft our initial close proposal in order to keep
// the negotiation moving, but only if we're the negotiator.
if c.cfg.channel.IsInitiator() {
closeSigned, err := c.proposeCloseSigned(c.idealFeeSat)
if err != nil {
return nil, false, err
}
msgsToSend = append(msgsToSend, closeSigned)
}
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// We'll return both sets of messages to send to the remote
// party to kick off the fee negotiation process.
return msgsToSend, false, nil
// If we just initiated a channel shutdown, and we receive a new
// message, then this indicates the other party is ready to shutdown as
// well. In this state we'll send our first signature.
case closeShutdownInitiated:
// First, we'll assert that we have a channel shutdown message,
// otherwise, this is an attempted invalid state transition.
shutDownMsg, ok := msg.(*lnwire.Shutdown)
if !ok {
return nil, false, fmt.Errorf("expected lnwire.Shutdown, "+
"instead have %v", spew.Sdump(msg))
}
// Now that we know this is a valid shutdown message, we'll
// record their preferred delivery closing script.
c.remoteDeliveryScript = shutDownMsg.Address
// At this point, we can now start the fee negotiation state,
// by constructing and sending our initial signature for what
// we think the closing transaction should look like.
c.state = closeFeeNegotiation
peerLog.Infof("ChannelPoint(%v): shutdown response received, "+
"entering fee negotiation", c.chanPoint)
// Starting with our ideal fee rate, we'll create an initial
// closing proposal, but only if we're the initiator, as
// otherwise, the other party will send their first proposal
// first.
if c.cfg.channel.IsInitiator() {
closeSigned, err := c.proposeCloseSigned(c.idealFeeSat)
if err != nil {
return nil, false, err
}
return []lnwire.Message{closeSigned}, false, nil
}
return nil, false, nil
// If we're receiving a message while we're in the fee negotiation
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// phase, then this indicates the remote party is responding to a closed
// signed message we sent, or kicking off the process with their own.
case closeFeeNegotiation:
// First, we'll assert that we're actually getting a
// CloseSigned message, otherwise an invalid state transition
// was attempted.
closeSignedMsg, ok := msg.(*lnwire.ClosingSigned)
if !ok {
return nil, false, fmt.Errorf("expected lnwire.ClosingSigned, "+
"instead have %v", spew.Sdump(msg))
}
// We'll compare the proposed total fee, to what we've proposed
// during the negotiations, if it doesn't match any of our
// prior offers, then we'll attempt to rachet the fee closer to
remoteProposedFee := closeSignedMsg.FeeSatoshis
if _, ok := c.priorFeeOffers[remoteProposedFee]; !ok {
// We'll now attempt to rachet towards a fee deemed
// acceptable by both parties, factoring in our ideal
// fee rate, and the last proposed fee by both sides.
feeProposal := calcCompromiseFee(c.chanPoint,
c.idealFeeSat, c.lastFeeProposal,
remoteProposedFee,
)
// With our new fee proposal calculated, we'll craft a
// new close signed signature to send to the other
// party so we can continue the fee negotiation
// process.
closeSigned, err := c.proposeCloseSigned(feeProposal)
if err != nil {
return nil, false, err
}
// If the compromise fee doesn't match what the peer
// proposed, then we'll return this latest close signed
// message so we continue negotiation.
if feeProposal != remoteProposedFee {
peerLog.Debugf("ChannelPoint(%v): close tx "+
"fee disagreement, continuing negotiation",
c.chanPoint)
return []lnwire.Message{closeSigned}, false, nil
}
}
peerLog.Infof("ChannelPoint(%v) fee of %v accepted, ending "+
"negotiation", c.chanPoint, remoteProposedFee)
// Otherwise, we've agreed on a fee for the closing
// transaction! We'll craft the final closing transaction so
// we can broadcast it to the network.
matchingSig := c.priorFeeOffers[remoteProposedFee].Signature
localSigBytes := matchingSig.ToSignatureBytes()
localSig := append(localSigBytes, byte(txscript.SigHashAll))
remoteSigBytes := closeSignedMsg.Signature.ToSignatureBytes()
remoteSig := append(remoteSigBytes, byte(txscript.SigHashAll))
closeTx, _, err := c.cfg.channel.CompleteCooperativeClose(
localSig, remoteSig, c.localDeliveryScript,
c.remoteDeliveryScript, remoteProposedFee,
)
if err != nil {
return nil, false, err
}
c.closingTx = closeTx
// Before closing, we'll attempt to send a disable update for
// the channel. We do so before closing the channel as otherwise
// the current edge policy won't be retrievable from the graph.
if err := c.cfg.disableChannel(c.chanPoint); err != nil {
peerLog.Warnf("Unable to disable channel %v on "+
"close: %v", c.chanPoint, err)
}
// With the closing transaction crafted, we'll now broadcast it
// to the network.
peerLog.Infof("Broadcasting cooperative close tx: %v",
newLogClosure(func() string {
return spew.Sdump(closeTx)
}))
if err := c.cfg.broadcastTx(closeTx); err != nil {
return nil, false, err
}
if err := c.cfg.channel.MarkCommitmentBroadcasted(); err != nil {
return nil, false, err
}
// Finally, we'll transition to the closeFinished state, and
// also return the final close signed message we sent.
// Additionally, we return true for the second argument to
// indicate we're finished with the channel closing
// negotiation.
c.state = closeFinished
matchingOffer := c.priorFeeOffers[remoteProposedFee]
return []lnwire.Message{matchingOffer}, true, nil
// If we receive a message while in the closeFinished state, then this
// should only be the remote party echoing the last ClosingSigned
// message that we agreed on.
case closeFinished:
if _, ok := msg.(*lnwire.ClosingSigned); !ok {
return nil, false, fmt.Errorf("expected "+
"lnwire.ClosingSigned, instead have %v",
spew.Sdump(msg))
}
// There's no more to do as both sides should have already
// broadcast the closing transaction at this state.
return nil, true, nil
// Otherwise, we're in an unknown state, and can't proceed.
default:
return nil, false, ErrInvalidState
}
}
// proposeCloseSigned attempts to propose a new signature for the closing
// transaction for a channel based on the prior fee negotiations and our
// current compromise fee.
func (c *channelCloser) proposeCloseSigned(fee btcutil.Amount) (*lnwire.ClosingSigned, error) {
rawSig, _, _, err := c.cfg.channel.CreateCloseProposal(
fee, c.localDeliveryScript, c.remoteDeliveryScript,
)
if err != nil {
return nil, err
}
// We'll note our last signature and proposed fee so when the remote
// party responds we'll be able to decide if we've agreed on fees or
// not.
c.lastFeeProposal = fee
parsedSig, err := lnwire.NewSigFromRawSignature(rawSig)
if err != nil {
return nil, err
}
peerLog.Infof("ChannelPoint(%v): proposing fee of %v sat to close "+
"chan", c.chanPoint, int64(fee))
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// We'll assemble a ClosingSigned message using this information and
// return it to the caller so we can kick off the final stage of the
// channel closure project.
closeSignedMsg := lnwire.NewClosingSigned(c.cid, fee, parsedSig)
// We'll also save this close signed, in the case that the remote party
// accepts our offer. This way, we don't have to re-sign.
c.priorFeeOffers[fee] = closeSignedMsg
return closeSignedMsg, nil
}
// feeInAcceptableRange returns true if the passed remote fee is deemed to be
// in an "acceptable" range to our local fee. This is an attempt at a
// compromise and to ensure that the fee negotiation has a stopping point. We
// consider their fee acceptable if it's within 30% of our fee.
func feeInAcceptableRange(localFee, remoteFee btcutil.Amount) bool {
// If our offer is lower than theirs, then we'll accept their
// offer if it's no more than 30% *greater* than our current
// offer.
if localFee < remoteFee {
acceptableRange := localFee + ((localFee * 3) / 10)
return remoteFee <= acceptableRange
}
// If our offer is greater than theirs, then we'll accept their offer
// if it's no more than 30% *less* than our current offer.
acceptableRange := localFee - ((localFee * 3) / 10)
return remoteFee >= acceptableRange
}
// rachetFee is our step function used to inch our fee closer to something that
// both sides can agree on. If up is true, then we'll attempt to increase our
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// offered fee. Otherwise, if up is false, then we'll attempt to decrease our
// offered fee.
func rachetFee(fee btcutil.Amount, up bool) btcutil.Amount {
// If we need to rachet up, then we'll increase our fee by 10%.
if up {
return fee + ((fee * 1) / 10)
}
// Otherwise, we'll *decrease* our fee by 10%.
return fee - ((fee * 1) / 10)
}
// calcCompromiseFee performs the current fee negotiation algorithm, taking
// into consideration our ideal fee based on current fee environment, the fee
// we last proposed (if any), and the fee proposed by the peer.
func calcCompromiseFee(chanPoint wire.OutPoint,
ourIdealFee, lastSentFee, remoteFee btcutil.Amount) btcutil.Amount {
// TODO(roasbeef): take in number of rounds as well?
peerLog.Infof("ChannelPoint(%v): computing fee compromise, ideal=%v, "+
"last_sent=%v, remote_offer=%v", chanPoint, int64(ourIdealFee),
int64(lastSentFee), int64(remoteFee))
// Otherwise, we'll need to attempt to make a fee compromise if this is
// the second round, and neither side has agreed on fees.
switch {
// If their proposed fee is identical to our ideal fee, then we'll go
// with that as we can short circuit the fee negotiation. Similarly, if
// we haven't sent an offer yet, we'll default to our ideal fee.
case ourIdealFee == remoteFee || lastSentFee == 0:
return ourIdealFee
// If the last fee we sent, is equal to the fee the remote party is
// offering, then we can simply return this fee as the negotiation is
// over.
case remoteFee == lastSentFee:
return lastSentFee
// If the fee the remote party is offering is less than the last one we
// sent, then we'll need to rachet down in order to move our offer
// closer to theirs.
case remoteFee < lastSentFee:
// If the fee is lower, but still acceptable, then we'll just
// return this fee and end the negotiation.
if feeInAcceptableRange(lastSentFee, remoteFee) {
peerLog.Infof("ChannelPoint(%v): proposed remote fee "+
"is close enough, capitulating", chanPoint)
return remoteFee
}
// Otherwise, we'll rachet the fee *down* using our current
// algorithm.
return rachetFee(lastSentFee, false)
// If the fee the remote party is offering is greater than the last one
// we sent, then we'll rachet up in order to ensure we terminate
// eventually.
case remoteFee > lastSentFee:
// If the fee is greater, but still acceptable, then we'll just
// return this fee in order to put an end to the negotiation.
if feeInAcceptableRange(lastSentFee, remoteFee) {
peerLog.Infof("ChannelPoint(%v): proposed remote fee "+
"is close enough, capitulating", chanPoint)
return remoteFee
}
// Otherwise, we'll rachet the fee up using our current
// algorithm.
return rachetFee(lastSentFee, true)
default:
// TODO(roasbeef): fail if their fee isn't in expected range
return remoteFee
}
}