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mirror of https://github.com/lightninglabs/loop synced 2024-11-09 19:10:47 +00:00
loop/loopout.go
carla 65c847674d
multi: add preimage push to loop out after sweep attempt
Once we have revealed our preimage to the world with a sweep attempt,
we can safely push our preimage to the server to speed up on chain
claim.

Rather than rely on the server, we use the state of our invoice in lnd
to determine whether we should continue trying to push the preimage to
the server.
2020-06-08 12:54:08 +02:00

960 lines
26 KiB
Go

package loop
import (
"context"
"crypto/rand"
"crypto/sha256"
"errors"
"fmt"
"time"
"github.com/btcsuite/btcd/wire"
"github.com/btcsuite/btcutil"
"github.com/lightninglabs/loop/lndclient"
"github.com/lightninglabs/loop/loopdb"
"github.com/lightninglabs/loop/swap"
"github.com/lightninglabs/loop/sweep"
"github.com/lightningnetwork/lnd/chainntnfs"
"github.com/lightningnetwork/lnd/channeldb"
"github.com/lightningnetwork/lnd/lnrpc"
"github.com/lightningnetwork/lnd/lntypes"
)
var (
// MinLoopOutPreimageRevealDelta configures the minimum number of
// remaining blocks before htlc expiry required to reveal preimage.
MinLoopOutPreimageRevealDelta int32 = 20
// DefaultSweepConfTarget is the default confirmation target we'll use
// when sweeping on-chain HTLCs.
DefaultSweepConfTarget int32 = 6
// DefaultHtlcConfTarget is the default confirmation target we'll use
// for on-chain htlcs published by the swap client for Loop In.
DefaultHtlcConfTarget int32 = 6
// DefaultSweepConfTargetDelta is the delta of blocks from a Loop Out
// swap's expiration height at which we begin to use the default sweep
// confirmation target.
//
// TODO(wilmer): tune?
DefaultSweepConfTargetDelta = DefaultSweepConfTarget * 2
// paymentTimeout is the timeout for the loop out payment loop as
// communicated to lnd.
paymentTimeout = time.Minute
)
// loopOutSwap contains all the in-memory state related to a pending loop out
// swap.
type loopOutSwap struct {
swapKit
loopdb.LoopOutContract
executeConfig
htlc *swap.Htlc
swapPaymentChan chan lndclient.PaymentResult
prePaymentChan chan lndclient.PaymentResult
}
// executeConfig contains extra configuration to execute the swap.
type executeConfig struct {
sweeper *sweep.Sweeper
statusChan chan<- SwapInfo
blockEpochChan <-chan interface{}
timerFactory func(d time.Duration) <-chan time.Time
loopOutMaxParts uint32
}
// newLoopOutSwap initiates a new swap with the server and returns a
// corresponding swap object.
func newLoopOutSwap(globalCtx context.Context, cfg *swapConfig,
currentHeight int32, request *OutRequest) (*loopOutSwap, error) {
// Generate random preimage.
var swapPreimage [32]byte
if _, err := rand.Read(swapPreimage[:]); err != nil {
log.Error("Cannot generate preimage")
}
swapHash := lntypes.Hash(sha256.Sum256(swapPreimage[:]))
// Derive a receiver key for this swap.
keyDesc, err := cfg.lnd.WalletKit.DeriveNextKey(
globalCtx, swap.KeyFamily,
)
if err != nil {
return nil, err
}
var receiverKey [33]byte
copy(receiverKey[:], keyDesc.PubKey.SerializeCompressed())
// Post the swap parameters to the swap server. The response contains
// the server revocation key and the swap and prepay invoices.
log.Infof("Initiating swap request at height %v", currentHeight)
// The swap deadline will be given to the server for it to use as the
// latest swap publication time.
swapResp, err := cfg.server.NewLoopOutSwap(
globalCtx, swapHash, request.Amount, receiverKey,
request.SwapPublicationDeadline,
)
if err != nil {
return nil, fmt.Errorf("cannot initiate swap: %v", err)
}
err = validateLoopOutContract(
cfg.lnd, currentHeight, request, swapHash, swapResp,
)
if err != nil {
return nil, err
}
// Check channel set for duplicates.
chanSet, err := loopdb.NewChannelSet(request.OutgoingChanSet)
if err != nil {
return nil, err
}
// Instantiate a struct that contains all required data to start the
// swap.
initiationTime := time.Now()
contract := loopdb.LoopOutContract{
SwapInvoice: swapResp.swapInvoice,
DestAddr: request.DestAddr,
MaxSwapRoutingFee: request.MaxSwapRoutingFee,
SweepConfTarget: request.SweepConfTarget,
PrepayInvoice: swapResp.prepayInvoice,
MaxPrepayRoutingFee: request.MaxPrepayRoutingFee,
SwapPublicationDeadline: request.SwapPublicationDeadline,
SwapContract: loopdb.SwapContract{
InitiationHeight: currentHeight,
InitiationTime: initiationTime,
ReceiverKey: receiverKey,
SenderKey: swapResp.senderKey,
Preimage: swapPreimage,
AmountRequested: request.Amount,
CltvExpiry: swapResp.expiry,
MaxMinerFee: request.MaxMinerFee,
MaxSwapFee: request.MaxSwapFee,
},
OutgoingChanSet: chanSet,
}
swapKit := newSwapKit(
swapHash, swap.TypeOut, cfg, &contract.SwapContract,
)
swapKit.lastUpdateTime = initiationTime
// Create the htlc.
htlc, err := swapKit.getHtlc(swap.HtlcP2WSH)
if err != nil {
return nil, err
}
// Log htlc address for debugging.
swapKit.log.Infof("Htlc address: %v", htlc.Address)
swap := &loopOutSwap{
LoopOutContract: contract,
swapKit: *swapKit,
htlc: htlc,
}
// Persist the data before exiting this function, so that the caller
// can trust that this swap will be resumed on restart.
err = cfg.store.CreateLoopOut(swapHash, &swap.LoopOutContract)
if err != nil {
return nil, fmt.Errorf("cannot store swap: %v", err)
}
return swap, nil
}
// resumeLoopOutSwap returns a swap object representing a pending swap that has
// been restored from the database.
func resumeLoopOutSwap(reqContext context.Context, cfg *swapConfig,
pend *loopdb.LoopOut) (*loopOutSwap, error) {
hash := lntypes.Hash(sha256.Sum256(pend.Contract.Preimage[:]))
log.Infof("Resuming loop out swap %v", hash)
swapKit := newSwapKit(
hash, swap.TypeOut, cfg, &pend.Contract.SwapContract,
)
// Create the htlc.
htlc, err := swapKit.getHtlc(swap.HtlcP2WSH)
if err != nil {
return nil, err
}
// Log htlc address for debugging.
swapKit.log.Infof("Htlc address: %v", htlc.Address)
// Create the swap.
swap := &loopOutSwap{
LoopOutContract: *pend.Contract,
swapKit: *swapKit,
htlc: htlc,
}
lastUpdate := pend.LastUpdate()
if lastUpdate == nil {
swap.lastUpdateTime = pend.Contract.InitiationTime
} else {
swap.state = lastUpdate.State
swap.lastUpdateTime = lastUpdate.Time
}
return swap, nil
}
// sendUpdate reports an update to the swap state.
func (s *loopOutSwap) sendUpdate(ctx context.Context) error {
info := s.swapInfo()
s.log.Infof("Loop out swap state: %v", info.State)
info.HtlcAddressP2WSH = s.htlc.Address
select {
case s.statusChan <- *info:
case <-ctx.Done():
return ctx.Err()
}
return nil
}
// execute starts/resumes the swap. It is a thin wrapper around
// executeAndFinalize to conveniently handle the error case.
func (s *loopOutSwap) execute(mainCtx context.Context,
cfg *executeConfig, height int32) error {
s.executeConfig = *cfg
s.height = height
// Execute swap.
err := s.executeAndFinalize(mainCtx)
// If an unexpected error happened, report a temporary failure.
// Otherwise for example a connection error could lead to abandoning
// the swap permanently and losing funds.
if err != nil {
s.log.Errorf("Swap error: %v", err)
s.state = loopdb.StateFailTemporary
// If we cannot send out this update, there is nothing we can
// do.
_ = s.sendUpdate(mainCtx)
}
return err
}
// executeAndFinalize executes a swap and awaits the definitive outcome of the
// offchain payments. When this method returns, the swap outcome is final.
func (s *loopOutSwap) executeAndFinalize(globalCtx context.Context) error {
// Announce swap by sending out an initial update.
err := s.sendUpdate(globalCtx)
if err != nil {
return err
}
// Execute swap. When this call returns, the swap outcome is final, but
// it may be that there are still off-chain payments pending.
err = s.executeSwap(globalCtx)
if err != nil {
return err
}
// Sanity check.
if s.state.Type() == loopdb.StateTypePending {
return fmt.Errorf("swap in non-final state %v", s.state)
}
// Wait until all offchain payments have completed. If payments have
// already completed early, their channels have been set to nil.
s.log.Infof("Wait for server pulling off-chain payment(s)")
for s.swapPaymentChan != nil || s.prePaymentChan != nil {
select {
case result := <-s.swapPaymentChan:
s.swapPaymentChan = nil
if result.Err != nil {
// Server didn't pull the swap payment.
s.log.Infof("Swap payment failed: %v",
result.Err)
continue
}
s.cost.Server += result.PaidAmt
s.cost.Offchain += result.PaidFee
case result := <-s.prePaymentChan:
s.prePaymentChan = nil
if result.Err != nil {
// Server didn't pull the prepayment.
s.log.Infof("Prepayment failed: %v",
result.Err)
continue
}
s.cost.Server += result.PaidAmt
s.cost.Offchain += result.PaidFee
case <-globalCtx.Done():
return globalCtx.Err()
}
}
// Mark swap completed in store.
s.log.Infof("Swap completed: %v "+
"(final cost: server %v, onchain %v, offchain %v)",
s.state,
s.cost.Server,
s.cost.Onchain,
s.cost.Offchain,
)
return s.persistState(globalCtx)
}
// executeSwap executes the swap, but returns as soon as the swap outcome is
// final. At that point, there may still be pending off-chain payment(s).
func (s *loopOutSwap) executeSwap(globalCtx context.Context) error {
// We always pay both invoices (again). This is currently the only way
// to sort of resume payments.
//
// TODO: We shouldn't pay the invoices if it is already too late to
// start the swap. But because we don't know if we already fired the
// payments in a previous run, we cannot just abandon here.
s.payInvoices(globalCtx)
// Wait for confirmation of the on-chain htlc by watching for a tx
// producing the swap script output.
txConf, err := s.waitForConfirmedHtlc(globalCtx)
if err != nil {
return err
}
// If no error and no confirmation, the swap is aborted without an
// error. The swap state has been updated to a final state.
if txConf == nil {
return nil
}
// TODO: Off-chain payments can be canceled here. Most probably the HTLC
// is accepted by the server, but in case there are not for whatever
// reason, we don't need to have mission control start another payment
// attempt.
// Retrieve outpoint for sweep.
htlcOutpoint, htlcValue, err := swap.GetScriptOutput(
txConf.Tx, s.htlc.PkScript,
)
if err != nil {
return err
}
s.log.Infof("Htlc value: %v", htlcValue)
// Verify amount if preimage hasn't been revealed yet.
if s.state != loopdb.StatePreimageRevealed && htlcValue < s.AmountRequested {
log.Warnf("Swap amount too low, expected %v but received %v",
s.AmountRequested, htlcValue)
s.state = loopdb.StateFailInsufficientValue
return nil
}
// Try to spend htlc and continue (rbf) until a spend has confirmed.
spendDetails, err := s.waitForHtlcSpendConfirmed(globalCtx,
func() error {
return s.sweep(globalCtx, *htlcOutpoint, htlcValue)
},
)
if err != nil {
return err
}
// Inspect witness stack to see if it is a success transaction. We
// don't just try to match with the hash of our sweep tx, because it
// may be swept by a different (fee) sweep tx from a previous run.
htlcInput, err := swap.GetTxInputByOutpoint(
spendDetails.SpendingTx, htlcOutpoint,
)
if err != nil {
return err
}
sweepSuccessful := s.htlc.IsSuccessWitness(htlcInput.Witness)
if sweepSuccessful {
s.cost.Server -= htlcValue
s.cost.Onchain = htlcValue -
btcutil.Amount(spendDetails.SpendingTx.TxOut[0].Value)
s.state = loopdb.StateSuccess
} else {
s.state = loopdb.StateFailSweepTimeout
}
return nil
}
// persistState updates the swap state and sends out an update notification.
func (s *loopOutSwap) persistState(ctx context.Context) error {
updateTime := time.Now()
s.lastUpdateTime = updateTime
// Update state in store.
err := s.store.UpdateLoopOut(
s.hash, updateTime,
loopdb.SwapStateData{
State: s.state,
Cost: s.cost,
},
)
if err != nil {
return err
}
// Send out swap update
return s.sendUpdate(ctx)
}
// payInvoices pays both swap invoices.
func (s *loopOutSwap) payInvoices(ctx context.Context) {
// Pay the swap invoice.
s.log.Infof("Sending swap payment %v", s.SwapInvoice)
s.swapPaymentChan = s.payInvoice(
ctx, s.SwapInvoice, s.MaxSwapRoutingFee,
s.LoopOutContract.OutgoingChanSet,
)
// Pay the prepay invoice.
s.log.Infof("Sending prepayment %v", s.PrepayInvoice)
s.prePaymentChan = s.payInvoice(
ctx, s.PrepayInvoice, s.MaxPrepayRoutingFee,
nil,
)
}
// payInvoice pays a single invoice.
func (s *loopOutSwap) payInvoice(ctx context.Context, invoice string,
maxFee btcutil.Amount,
outgoingChanIds loopdb.ChannelSet) chan lndclient.PaymentResult {
resultChan := make(chan lndclient.PaymentResult)
go func() {
var result lndclient.PaymentResult
status, err := s.payInvoiceAsync(
ctx, invoice, maxFee, outgoingChanIds,
)
if err != nil {
result.Err = err
} else {
result.Preimage = status.Preimage
result.PaidFee = status.Fee.ToSatoshis()
result.PaidAmt = status.Value.ToSatoshis()
}
select {
case resultChan <- result:
case <-ctx.Done():
}
}()
return resultChan
}
// payInvoiceAsync is the asynchronously executed part of paying an invoice.
func (s *loopOutSwap) payInvoiceAsync(ctx context.Context,
invoice string, maxFee btcutil.Amount,
outgoingChanIds loopdb.ChannelSet) (*lndclient.PaymentStatus, error) {
// Extract hash from payment request. Unfortunately the request
// components aren't available directly.
chainParams := s.lnd.ChainParams
hash, _, err := swap.DecodeInvoice(chainParams, invoice)
if err != nil {
return nil, err
}
req := lndclient.SendPaymentRequest{
MaxFee: maxFee,
Invoice: invoice,
OutgoingChanIds: outgoingChanIds,
Timeout: paymentTimeout,
MaxParts: s.executeConfig.loopOutMaxParts,
}
// Lookup state of the swap payment.
paymentStateCtx, cancel := context.WithCancel(ctx)
defer cancel()
payStatusChan, payErrChan, err := s.lnd.Router.SendPayment(
paymentStateCtx, req,
)
if err != nil {
return nil, err
}
for {
select {
// Payment advanced to the next state.
case payState := <-payStatusChan:
s.log.Infof("Payment %v: %v", hash, payState)
switch payState.State {
case lnrpc.Payment_SUCCEEDED:
return &payState, nil
case lnrpc.Payment_FAILED:
return nil, errors.New("payment failed")
case lnrpc.Payment_IN_FLIGHT:
// Continue waiting for final state.
default:
return nil, errors.New("unknown payment state")
}
// Abort the swap in case of an error. An unknown payment error
// from TrackPayment is no longer expected here.
case err := <-payErrChan:
if err != channeldb.ErrAlreadyPaid {
return nil, err
}
payStatusChan, payErrChan, err =
s.lnd.Router.TrackPayment(paymentStateCtx, hash)
if err != nil {
return nil, err
}
case <-ctx.Done():
return nil, ctx.Err()
}
}
}
// waitForConfirmedHtlc waits for a confirmed htlc to appear on the chain. In
// case we haven't revealed the preimage yet, it also monitors block height and
// off-chain payment failure.
func (s *loopOutSwap) waitForConfirmedHtlc(globalCtx context.Context) (
*chainntnfs.TxConfirmation, error) {
// Wait for confirmation of the on-chain htlc by watching for a tx
// producing the swap script output.
s.log.Infof(
"Register conf ntfn for swap script on chain (hh=%v)",
s.InitiationHeight,
)
ctx, cancel := context.WithCancel(globalCtx)
defer cancel()
htlcConfChan, htlcErrChan, err :=
s.lnd.ChainNotifier.RegisterConfirmationsNtfn(
ctx, nil, s.htlc.PkScript, 1,
s.InitiationHeight,
)
if err != nil {
return nil, err
}
var txConf *chainntnfs.TxConfirmation
if s.state == loopdb.StateInitiated {
// Check if it is already too late to start this swap. If we
// already revealed the preimage, this check is irrelevant and
// we need to sweep in any case.
maxPreimageRevealHeight := s.CltvExpiry -
MinLoopOutPreimageRevealDelta
checkMaxRevealHeightExceeded := func() bool {
s.log.Infof("Checking preimage reveal height %v "+
"exceeded (height %v)",
maxPreimageRevealHeight, s.height)
if s.height <= maxPreimageRevealHeight {
return false
}
s.log.Infof("Max preimage reveal height %v "+
"exceeded (height %v)",
maxPreimageRevealHeight, s.height)
s.state = loopdb.StateFailTimeout
return true
}
// First check, because after resume we may otherwise reveal the
// preimage after the max height (depending on order in which
// events are received in the select loop below).
if checkMaxRevealHeightExceeded() {
return nil, nil
}
s.log.Infof("Waiting for either htlc on-chain confirmation or " +
" off-chain payment failure")
loop:
for {
select {
// If the swap payment fails, abandon the swap. We may
// have lost the prepayment.
case result := <-s.swapPaymentChan:
s.swapPaymentChan = nil
if result.Err != nil {
s.state = loopdb.StateFailOffchainPayments
s.log.Infof("Failed swap payment: %v",
result.Err)
return nil, nil
}
s.cost.Server += result.PaidAmt
s.cost.Offchain += result.PaidFee
// If the prepay fails, abandon the swap. Because we
// didn't reveal the preimage, the swap payment will be
// canceled or time out.
case result := <-s.prePaymentChan:
s.prePaymentChan = nil
if result.Err != nil {
s.state = loopdb.StateFailOffchainPayments
s.log.Infof("Failed prepayment: %v",
result.Err)
return nil, nil
}
s.cost.Server += result.PaidAmt
s.cost.Offchain += result.PaidFee
// Unexpected error on the confirm channel happened,
// abandon the swap.
case err := <-htlcErrChan:
return nil, err
// Htlc got confirmed, continue to sweeping.
case htlcConfNtfn := <-htlcConfChan:
txConf = htlcConfNtfn
break loop
// New block is received. Recheck max reveal height.
case notification := <-s.blockEpochChan:
s.height = notification.(int32)
log.Infof("Received block %v", s.height)
if checkMaxRevealHeightExceeded() {
return nil, nil
}
// Client quit.
case <-globalCtx.Done():
return nil, globalCtx.Err()
}
}
s.log.Infof("Swap script confirmed on chain")
} else {
s.log.Infof("Retrieving htlc onchain")
select {
case err := <-htlcErrChan:
return nil, err
case htlcConfNtfn := <-htlcConfChan:
txConf = htlcConfNtfn
case <-globalCtx.Done():
return nil, globalCtx.Err()
}
}
s.log.Infof("Htlc tx %v at height %v", txConf.Tx.TxHash(),
txConf.BlockHeight)
return txConf, nil
}
// waitForHtlcSpendConfirmed waits for the htlc to be spent either by our own
// sweep or a server revocation tx. During this process, this function will try
// to spend the htlc every block by calling spendFunc.
//
// TODO: Improve retry/fee increase mechanism. Once in the mempool, server can
// sweep offchain. So we must make sure we sweep successfully before on-chain
// timeout.
func (s *loopOutSwap) waitForHtlcSpendConfirmed(globalCtx context.Context,
spendFunc func() error) (*chainntnfs.SpendDetail, error) {
// Register the htlc spend notification.
ctx, cancel := context.WithCancel(globalCtx)
defer cancel()
spendChan, spendErr, err := s.lnd.ChainNotifier.RegisterSpendNtfn(
ctx, nil, s.htlc.PkScript, s.InitiationHeight,
)
if err != nil {
return nil, fmt.Errorf("register spend ntfn: %v", err)
}
// Track our payment status so that we can detect whether our off chain
// htlc is settled. We track this information to determine whether it is
// necessary to continue trying to push our preimage to the server.
trackChan, trackErrChan, err := s.lnd.Router.TrackPayment(
ctx, s.hash,
)
if err != nil {
return nil, fmt.Errorf("track payment: %v", err)
}
// paymentComplete tracks whether our payment is complete, and is used
// to decide whether we need to push our preimage to the server.
var paymentComplete bool
timerChan := s.timerFactory(republishDelay)
for {
select {
// Htlc spend, break loop.
case spendDetails := <-spendChan:
s.log.Infof("Htlc spend by tx: %v", spendDetails.SpenderTxHash)
return spendDetails, nil
// Spend notification error.
case err := <-spendErr:
return nil, err
// Receive status updates for our payment so that we can detect
// whether we've successfully pushed our preimage.
case status, ok := <-trackChan:
// If our channel has been closed, indicating that the
// server is finished providing updates because the
// payment has reached a terminal state, we replace
// the closed channel with nil so that we will no longer
// listen on it.
if !ok {
trackChan = nil
continue
}
if status.State == lnrpc.Payment_SUCCEEDED {
s.log.Infof("Off chain payment succeeded")
paymentComplete = true
}
// If we receive a track payment error that indicates that the
// server stream is complete, we ignore it because we want to
// continue this loop beyond the completion of the payment.
case err, ok := <-trackErrChan:
// If our channel has been closed, indicating that the
// server is finished providing updates because the
// payment has reached a terminal state, we replace
// the closed channel with nil so that we will no longer
// listen on it.
if !ok {
trackErrChan = nil
continue
}
// Otherwise, if we receive a non-nil error, we return
// it.
if err != nil {
return nil, err
}
// New block arrived, update height and restart the republish
// timer.
case notification := <-s.blockEpochChan:
s.height = notification.(int32)
timerChan = s.timerFactory(republishDelay)
// Some time after start or after arrival of a new block, try
// to spend again.
case <-timerChan:
err := spendFunc()
if err != nil {
return nil, err
}
// If our off chain payment is not yet complete, we
// try to push our preimage to the server.
if !paymentComplete {
s.pushPreimage(ctx)
}
// Context canceled.
case <-globalCtx.Done():
return nil, globalCtx.Err()
}
}
}
// pushPreimage pushes our preimage to the server if we have already revealed
// our preimage on chain with a sweep attempt.
func (s *loopOutSwap) pushPreimage(ctx context.Context) {
// If we have not yet revealed our preimage through a sweep, we do not
// push the preimage because we may choose to never sweep if fees are
// too high.
if s.state != loopdb.StatePreimageRevealed {
return
}
s.log.Infof("Pushing preimage to server")
// Push the preimage to the server, just log server errors since we rely
// on our payment state rather than the server response to judge the
// outcome of our preimage push.
if err := s.server.PushLoopOutPreimage(ctx, s.Preimage); err != nil {
s.log.Warnf("Could not push preimage: %v", err)
}
}
// sweep tries to sweep the given htlc to a destination address. It takes into
// account the max miner fee and marks the preimage as revealed when it
// published the tx.
//
// TODO: Use lnd sweeper?
func (s *loopOutSwap) sweep(ctx context.Context,
htlcOutpoint wire.OutPoint,
htlcValue btcutil.Amount) error {
witnessFunc := func(sig []byte) (wire.TxWitness, error) {
return s.htlc.GenSuccessWitness(sig, s.Preimage)
}
// Calculate the transaction fee based on the confirmation target
// required to sweep the HTLC before the timeout. We'll use the
// confirmation target provided by the client unless we've come too
// close to the expiration height, in which case we'll use the default
// if it is better than what the client provided.
confTarget := s.SweepConfTarget
if s.CltvExpiry-s.height <= DefaultSweepConfTargetDelta &&
confTarget > DefaultSweepConfTarget {
confTarget = DefaultSweepConfTarget
}
fee, err := s.sweeper.GetSweepFee(
ctx, s.htlc.AddSuccessToEstimator, s.DestAddr, confTarget,
)
if err != nil {
return err
}
// Ensure it doesn't exceed our maximum fee allowed.
if fee > s.MaxMinerFee {
s.log.Warnf("Required fee %v exceeds max miner fee of %v",
fee, s.MaxMinerFee)
if s.state == loopdb.StatePreimageRevealed {
// The currently required fee exceeds the max, but we
// already revealed the preimage. The best we can do now
// is to republish with the max fee.
fee = s.MaxMinerFee
} else {
s.log.Warnf("Not revealing preimage")
return nil
}
}
// Create sweep tx.
sweepTx, err := s.sweeper.CreateSweepTx(
ctx, s.height, s.htlc, htlcOutpoint, s.ReceiverKey, witnessFunc,
htlcValue, fee, s.DestAddr,
)
if err != nil {
return err
}
// Before publishing the tx, already mark the preimage as revealed. This
// is a precaution in case the publish call never returns and would
// leave us thinking we didn't reveal yet.
if s.state != loopdb.StatePreimageRevealed {
s.state = loopdb.StatePreimageRevealed
err := s.persistState(ctx)
if err != nil {
return err
}
}
// Publish tx.
s.log.Infof("Sweep on chain HTLC to address %v with fee %v (tx %v)",
s.DestAddr, fee, sweepTx.TxHash())
err = s.lnd.WalletKit.PublishTransaction(ctx, sweepTx)
if err != nil {
s.log.Warnf("Publish sweep: %v", err)
}
return nil
}
// validateLoopOutContract validates the contract parameters against our
// request.
func validateLoopOutContract(lnd *lndclient.LndServices,
height int32, request *OutRequest, swapHash lntypes.Hash,
response *newLoopOutResponse) error {
// Check invoice amounts.
chainParams := lnd.ChainParams
swapInvoiceHash, swapInvoiceAmt, err := swap.DecodeInvoice(
chainParams, response.swapInvoice,
)
if err != nil {
return err
}
if swapInvoiceHash != swapHash {
return fmt.Errorf(
"cannot initiate swap, swap invoice hash %v not equal generated swap hash %v",
swapInvoiceHash, swapHash)
}
_, prepayInvoiceAmt, err := swap.DecodeInvoice(
chainParams, response.prepayInvoice,
)
if err != nil {
return err
}
swapFee := swapInvoiceAmt + prepayInvoiceAmt - request.Amount
if swapFee > request.MaxSwapFee {
log.Warnf("Swap fee %v exceeding maximum of %v",
swapFee, request.MaxSwapFee)
return ErrSwapFeeTooHigh
}
if prepayInvoiceAmt > request.MaxPrepayAmount {
log.Warnf("Prepay amount %v exceeding maximum of %v",
prepayInvoiceAmt, request.MaxPrepayAmount)
return ErrPrepayAmountTooHigh
}
if response.expiry-height < MinLoopOutPreimageRevealDelta {
log.Warnf("Proposed expiry %v (delta %v) too soon",
response.expiry, response.expiry-height)
return ErrExpiryTooSoon
}
// Ensure the client has provided a sweep confirmation target that does
// not exceed the height at which we revert back to using the default.
if height+request.SweepConfTarget >= response.expiry-DefaultSweepConfTargetDelta {
return ErrSweepConfTargetTooFar
}
return nil
}