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mirror of https://github.com/lightninglabs/loop synced 2024-11-09 19:10:47 +00:00
loop/loopout.go
2019-04-04 15:49:02 +02:00

680 lines
18 KiB
Go

package loop
import (
"context"
"crypto/rand"
"crypto/sha256"
"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/lntypes"
)
var (
// MinLoopOutPreimageRevealDelta configures the minimum number of
// remaining blocks before htlc expiry required to reveal preimage.
MinLoopOutPreimageRevealDelta = int32(20)
)
// loopOutSwap contains all the in-memory state related to a pending loop out
// swap.
type loopOutSwap struct {
swapKit
loopdb.LoopOutContract
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
}
// 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 {
logger.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.
logger.Infof("Initiating swap request at height %v", currentHeight)
swapResp, err := cfg.server.NewLoopOutSwap(globalCtx, swapHash,
request.Amount, receiverKey,
)
if err != nil {
return nil, fmt.Errorf("cannot initiate swap: %v", err)
}
err = validateLoopOutContract(cfg.lnd, currentHeight, request, swapResp)
if err != nil {
return nil, err
}
// Instantie 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,
UnchargeChannel: request.LoopOutChannel,
PrepayInvoice: swapResp.prepayInvoice,
MaxPrepayRoutingFee: request.MaxPrepayRoutingFee,
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,
},
}
swapKit, err := newSwapKit(
swapHash, TypeOut, cfg, &contract.SwapContract, swap.HtlcP2WSH,
)
if err != nil {
return nil, err
}
swapKit.lastUpdateTime = initiationTime
swap := &loopOutSwap{
LoopOutContract: contract,
swapKit: *swapKit,
}
// 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[:]))
logger.Infof("Resuming loop out swap %v", hash)
swapKit, err := newSwapKit(
hash, TypeOut, cfg, &pend.Contract.SwapContract, swap.HtlcP2WSH,
)
if err != nil {
return nil, err
}
swap := &loopOutSwap{
LoopOutContract: *pend.Contract,
swapKit: *swapKit,
}
lastUpdate := pend.LastUpdate()
if lastUpdate == nil {
swap.lastUpdateTime = pend.Contract.InitiationTime
} else {
swap.state = lastUpdate.State
swap.lastUpdateTime = lastUpdate.Time
}
return swap, 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
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
case <-globalCtx.Done():
return globalCtx.Err()
}
}
// Mark swap completed in store.
s.log.Infof("Swap completed: %v "+
"(final cost: server %v, onchain %v)",
s.state,
s.cost.Server,
s.cost.Onchain,
)
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 {
logger.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, s.state)
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.lnd.Client.PayInvoice(
ctx, s.SwapInvoice, s.MaxSwapRoutingFee,
s.LoopOutContract.UnchargeChannel,
)
// Pay the prepay invoice.
s.log.Infof("Sending prepayment %v", s.PrepayInvoice)
s.prePaymentChan = s.lnd.Client.PayInvoice(
ctx, s.PrepayInvoice, s.MaxPrepayRoutingFee,
nil,
)
}
// 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
// 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
// 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)
logger.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)
}
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
// 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
}
// Context canceled.
case <-globalCtx.Done():
return nil, globalCtx.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 sweep tx fee
fee, err := s.sweeper.GetSweepFee(
ctx, s.htlc.AddSuccessToEstimator,
s.SweepConfTarget,
)
if err != nil {
return err
}
if fee > s.MaxMinerFee {
s.log.Warnf("Required miner fee %v exceeds max 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,
response *newLoopOutResponse) error {
// Check invoice amounts.
chainParams := lnd.ChainParams
swapInvoiceAmt, err := swap.GetInvoiceAmt(
chainParams, response.swapInvoice,
)
if err != nil {
return err
}
prepayInvoiceAmt, err := swap.GetInvoiceAmt(
chainParams, response.prepayInvoice,
)
if err != nil {
return err
}
swapFee := swapInvoiceAmt + prepayInvoiceAmt - request.Amount
if swapFee > request.MaxSwapFee {
logger.Warnf("Swap fee %v exceeding maximum of %v",
swapFee, request.MaxSwapFee)
return ErrSwapFeeTooHigh
}
if prepayInvoiceAmt > request.MaxPrepayAmount {
logger.Warnf("Prepay amount %v exceeding maximum of %v",
prepayInvoiceAmt, request.MaxPrepayAmount)
return ErrPrepayAmountTooHigh
}
if response.expiry-height < MinLoopOutPreimageRevealDelta {
logger.Warnf("Proposed expiry %v (delta %v) too soon",
response.expiry, response.expiry-height)
return ErrExpiryTooSoon
}
return nil
}