495 lines
17 KiB
Go
495 lines
17 KiB
Go
package contractcourt
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import (
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"encoding/binary"
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"fmt"
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"io"
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"github.com/btcsuite/btcd/wire"
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"github.com/btcsuite/btcutil"
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"github.com/davecgh/go-spew/spew"
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"github.com/lightningnetwork/lnd/chainntnfs"
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"github.com/lightningnetwork/lnd/channeldb"
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"github.com/lightningnetwork/lnd/input"
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"github.com/lightningnetwork/lnd/lntypes"
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"github.com/lightningnetwork/lnd/lnwallet"
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"github.com/lightningnetwork/lnd/lnwire"
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)
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// htlcTimeoutResolver is a ContractResolver that's capable of resolving an
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// outgoing HTLC. The HTLC may be on our commitment transaction, or on the
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// commitment transaction of the remote party. An output on our commitment
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// transaction is considered fully resolved once the second-level transaction
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// has been confirmed (and reached a sufficient depth). An output on the
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// commitment transaction of the remote party is resolved once we detect a
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// spend of the direct HTLC output using the timeout clause.
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type htlcTimeoutResolver struct {
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// htlcResolution contains all the information required to properly
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// resolve this outgoing HTLC.
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htlcResolution lnwallet.OutgoingHtlcResolution
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// outputIncubating returns true if we've sent the output to the output
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// incubator (utxo nursery).
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outputIncubating bool
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// resolved reflects if the contract has been fully resolved or not.
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resolved bool
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// broadcastHeight is the height that the original contract was
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// broadcast to the main-chain at. We'll use this value to bound any
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// historical queries to the chain for spends/confirmations.
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//
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// TODO(roasbeef): wrap above into definite resolution embedding?
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broadcastHeight uint32
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// htlc contains information on the htlc that we are resolving on-chain.
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htlc channeldb.HTLC
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contractResolverKit
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}
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// newTimeoutResolver instantiates a new timeout htlc resolver.
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func newTimeoutResolver(res lnwallet.OutgoingHtlcResolution,
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broadcastHeight uint32, htlc channeldb.HTLC,
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resCfg ResolverConfig) *htlcTimeoutResolver {
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return &htlcTimeoutResolver{
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contractResolverKit: *newContractResolverKit(resCfg),
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htlcResolution: res,
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broadcastHeight: broadcastHeight,
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htlc: htlc,
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}
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}
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// ResolverKey returns an identifier which should be globally unique for this
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// particular resolver within the chain the original contract resides within.
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//
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// NOTE: Part of the ContractResolver interface.
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func (h *htlcTimeoutResolver) ResolverKey() []byte {
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// The primary key for this resolver will be the outpoint of the HTLC
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// on the commitment transaction itself. If this is our commitment,
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// then the output can be found within the signed timeout tx,
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// otherwise, it's just the ClaimOutpoint.
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var op wire.OutPoint
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if h.htlcResolution.SignedTimeoutTx != nil {
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op = h.htlcResolution.SignedTimeoutTx.TxIn[0].PreviousOutPoint
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} else {
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op = h.htlcResolution.ClaimOutpoint
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}
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key := newResolverID(op)
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return key[:]
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}
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const (
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// expectedRemoteWitnessSuccessSize is the expected size of the witness
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// on the remote commitment transaction for an outgoing HTLC that is
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// swept on-chain by them with pre-image.
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expectedRemoteWitnessSuccessSize = 5
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// remotePreimageIndex index within the witness on the remote
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// commitment transaction that will hold they pre-image if they go to
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// sweep it on chain.
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remotePreimageIndex = 3
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// localPreimageIndex is the index within the witness on the local
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// commitment transaction for an outgoing HTLC that will hold the
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// pre-image if the remote party sweeps it.
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localPreimageIndex = 1
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)
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// claimCleanUp is a helper method that's called once the HTLC output is spent
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// by the remote party. It'll extract the preimage, add it to the global cache,
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// and finally send the appropriate clean up message.
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func (h *htlcTimeoutResolver) claimCleanUp(
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commitSpend *chainntnfs.SpendDetail) (ContractResolver, error) {
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// Depending on if this is our commitment or not, then we'll be looking
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// for a different witness pattern.
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spenderIndex := commitSpend.SpenderInputIndex
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spendingInput := commitSpend.SpendingTx.TxIn[spenderIndex]
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log.Infof("%T(%v): extracting preimage! remote party spent "+
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"HTLC with tx=%v", h, h.htlcResolution.ClaimOutpoint,
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spew.Sdump(commitSpend.SpendingTx))
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// If this is the remote party's commitment, then we'll be looking for
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// them to spend using the second-level success transaction.
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var preimageBytes []byte
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if h.htlcResolution.SignedTimeoutTx == nil {
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// The witness stack when the remote party sweeps the output to
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// them looks like:
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//
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// * <0> <sender sig> <recvr sig> <preimage> <witness script>
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preimageBytes = spendingInput.Witness[remotePreimageIndex]
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} else {
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// Otherwise, they'll be spending directly from our commitment
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// output. In which case the witness stack looks like:
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//
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// * <sig> <preimage> <witness script>
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preimageBytes = spendingInput.Witness[localPreimageIndex]
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}
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preimage, err := lntypes.MakePreimage(preimageBytes)
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if err != nil {
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return nil, fmt.Errorf("unable to create pre-image from "+
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"witness: %v", err)
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}
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log.Infof("%T(%v): extracting preimage=%v from on-chain "+
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"spend!", h, h.htlcResolution.ClaimOutpoint, preimage)
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// With the preimage obtained, we can now add it to the global cache.
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if err := h.PreimageDB.AddPreimages(preimage); err != nil {
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log.Errorf("%T(%v): unable to add witness to cache",
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h, h.htlcResolution.ClaimOutpoint)
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}
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var pre [32]byte
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copy(pre[:], preimage[:])
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// Finally, we'll send the clean up message, mark ourselves as
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// resolved, then exit.
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if err := h.DeliverResolutionMsg(ResolutionMsg{
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SourceChan: h.ShortChanID,
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HtlcIndex: h.htlc.HtlcIndex,
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PreImage: &pre,
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}); err != nil {
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return nil, err
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}
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h.resolved = true
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// Checkpoint our resolver with a report which reflects the preimage
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// claim by the remote party.
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amt := btcutil.Amount(h.htlcResolution.SweepSignDesc.Output.Value)
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report := &channeldb.ResolverReport{
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OutPoint: h.htlcResolution.ClaimOutpoint,
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Amount: amt,
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ResolverType: channeldb.ResolverTypeOutgoingHtlc,
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ResolverOutcome: channeldb.ResolverOutcomeClaimed,
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SpendTxID: commitSpend.SpenderTxHash,
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}
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return nil, h.Checkpoint(h, report)
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}
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// chainDetailsToWatch returns the output and script which we use to watch for
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// spends from the direct HTLC output on the commitment transaction.
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//
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// TODO(joostjager): output already set properly in
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// lnwallet.newOutgoingHtlcResolution? And script too?
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func (h *htlcTimeoutResolver) chainDetailsToWatch() (*wire.OutPoint, []byte, error) {
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// If there's no timeout transaction, then the claim output is the
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// output directly on the commitment transaction, so we'll just use
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// that.
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if h.htlcResolution.SignedTimeoutTx == nil {
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outPointToWatch := h.htlcResolution.ClaimOutpoint
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scriptToWatch := h.htlcResolution.SweepSignDesc.Output.PkScript
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return &outPointToWatch, scriptToWatch, nil
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}
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// If this is the remote party's commitment, then we'll need to grab
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// watch the output that our timeout transaction points to. We can
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// directly grab the outpoint, then also extract the witness script
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// (the last element of the witness stack) to re-construct the pkScript
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// we need to watch.
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outPointToWatch := h.htlcResolution.SignedTimeoutTx.TxIn[0].PreviousOutPoint
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witness := h.htlcResolution.SignedTimeoutTx.TxIn[0].Witness
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scriptToWatch, err := input.WitnessScriptHash(witness[len(witness)-1])
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if err != nil {
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return nil, nil, err
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}
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return &outPointToWatch, scriptToWatch, nil
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}
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// isSuccessSpend returns true if the passed spend on the specified commitment
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// is a success spend that reveals the pre-image or not.
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func isSuccessSpend(spend *chainntnfs.SpendDetail, localCommit bool) bool {
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// Based on the spending input index and transaction, obtain the
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// witness that tells us what type of spend this is.
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spenderIndex := spend.SpenderInputIndex
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spendingInput := spend.SpendingTx.TxIn[spenderIndex]
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spendingWitness := spendingInput.Witness
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// If this is the remote commitment then the only possible spends for
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// outgoing HTLCs are:
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//
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// RECVR: <0> <sender sig> <recvr sig> <preimage> (2nd level success spend)
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// REVOK: <sig> <key>
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// SENDR: <sig> 0
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//
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// In this case, if 5 witness elements are present (factoring the
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// witness script), and the 3rd element is the size of the pre-image,
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// then this is a remote spend. If not, then we swept it ourselves, or
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// revoked their output.
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if !localCommit {
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return len(spendingWitness) == expectedRemoteWitnessSuccessSize &&
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len(spendingWitness[remotePreimageIndex]) == lntypes.HashSize
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}
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// Otherwise, for our commitment, the only possible spends for an
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// outgoing HTLC are:
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//
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// SENDR: <0> <sendr sig> <recvr sig> <0> (2nd level timeout)
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// RECVR: <recvr sig> <preimage>
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// REVOK: <revoke sig> <revoke key>
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//
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// So the only success case has the pre-image as the 2nd (index 1)
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// element in the witness.
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return len(spendingWitness[localPreimageIndex]) == lntypes.HashSize
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}
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// Resolve kicks off full resolution of an outgoing HTLC output. If it's our
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// commitment, it isn't resolved until we see the second level HTLC txn
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// confirmed. If it's the remote party's commitment, we don't resolve until we
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// see a direct sweep via the timeout clause.
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//
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// NOTE: Part of the ContractResolver interface.
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func (h *htlcTimeoutResolver) Resolve() (ContractResolver, error) {
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// If we're already resolved, then we can exit early.
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if h.resolved {
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return nil, nil
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}
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// If we haven't already sent the output to the utxo nursery, then
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// we'll do so now.
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if !h.outputIncubating {
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log.Tracef("%T(%v): incubating htlc output", h,
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h.htlcResolution.ClaimOutpoint)
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err := h.IncubateOutputs(
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h.ChanPoint, &h.htlcResolution, nil,
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h.broadcastHeight,
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)
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if err != nil {
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return nil, err
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}
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h.outputIncubating = true
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if err := h.Checkpoint(h); err != nil {
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log.Errorf("unable to Checkpoint: %v", err)
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return nil, err
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}
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}
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// Now that we've handed off the HTLC to the nursery, we'll watch for a
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// spend of the output, and make our next move off of that. Depending
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// on if this is our commitment, or the remote party's commitment,
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// we'll be watching a different outpoint and script.
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outpointToWatch, scriptToWatch, err := h.chainDetailsToWatch()
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if err != nil {
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return nil, err
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}
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log.Infof("%T(%v): waiting for HTLC output %v to be spent"+
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"fully confirmed", h, h.htlcResolution.ClaimOutpoint,
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outpointToWatch)
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// We'll block here until either we exit, or the HTLC output on the
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// commitment transaction has been spent.
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spend, err := waitForSpend(
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outpointToWatch, scriptToWatch, h.broadcastHeight,
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h.Notifier, h.quit,
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)
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if err != nil {
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return nil, err
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}
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spendTxID := spend.SpenderTxHash
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// If the spend reveals the pre-image, then we'll enter the clean up
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// workflow to pass the pre-image back to the incoming link, add it to
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// the witness cache, and exit.
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if isSuccessSpend(spend, h.htlcResolution.SignedTimeoutTx != nil) {
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log.Infof("%T(%v): HTLC has been swept with pre-image by "+
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"remote party during timeout flow! Adding pre-image to "+
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"witness cache", h.htlcResolution.ClaimOutpoint)
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return h.claimCleanUp(spend)
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}
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log.Infof("%T(%v): resolving htlc with incoming fail msg, fully "+
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"confirmed", h, h.htlcResolution.ClaimOutpoint)
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// At this point, the second-level transaction is sufficiently
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// confirmed, or a transaction directly spending the output is.
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// Therefore, we can now send back our clean up message, failing the
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// HTLC on the incoming link.
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failureMsg := &lnwire.FailPermanentChannelFailure{}
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if err := h.DeliverResolutionMsg(ResolutionMsg{
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SourceChan: h.ShortChanID,
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HtlcIndex: h.htlc.HtlcIndex,
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Failure: failureMsg,
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}); err != nil {
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return nil, err
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}
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var reports []*channeldb.ResolverReport
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// Finally, if this was an output on our commitment transaction, we'll
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// wait for the second-level HTLC output to be spent, and for that
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// transaction itself to confirm.
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if h.htlcResolution.SignedTimeoutTx != nil {
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log.Infof("%T(%v): waiting for nursery to spend CSV delayed "+
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"output", h, h.htlcResolution.ClaimOutpoint)
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sweep, err := waitForSpend(
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&h.htlcResolution.ClaimOutpoint,
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h.htlcResolution.SweepSignDesc.Output.PkScript,
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h.broadcastHeight, h.Notifier, h.quit,
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)
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if err != nil {
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return nil, err
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}
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// Update the spend txid to the hash of the sweep transaction.
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spendTxID = sweep.SpenderTxHash
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// Once our timeout tx has confirmed, we add a resolution for
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// our timeoutTx tx first stage transaction.
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timeoutTx := h.htlcResolution.SignedTimeoutTx
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spendHash := timeoutTx.TxHash()
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reports = append(reports, &channeldb.ResolverReport{
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OutPoint: timeoutTx.TxIn[0].PreviousOutPoint,
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Amount: h.htlc.Amt.ToSatoshis(),
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ResolverType: channeldb.ResolverTypeOutgoingHtlc,
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ResolverOutcome: channeldb.ResolverOutcomeFirstStage,
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SpendTxID: &spendHash,
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})
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}
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// With the clean up message sent, we'll now mark the contract
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// resolved, record the timeout and the sweep txid on disk, and wait.
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h.resolved = true
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amt := btcutil.Amount(h.htlcResolution.SweepSignDesc.Output.Value)
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reports = append(reports, &channeldb.ResolverReport{
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OutPoint: h.htlcResolution.ClaimOutpoint,
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Amount: amt,
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ResolverType: channeldb.ResolverTypeOutgoingHtlc,
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ResolverOutcome: channeldb.ResolverOutcomeTimeout,
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SpendTxID: spendTxID,
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})
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return nil, h.Checkpoint(h, reports...)
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}
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// Stop signals the resolver to cancel any current resolution processes, and
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// suspend.
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//
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// NOTE: Part of the ContractResolver interface.
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func (h *htlcTimeoutResolver) Stop() {
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close(h.quit)
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}
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// IsResolved returns true if the stored state in the resolve is fully
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// resolved. In this case the target output can be forgotten.
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//
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// NOTE: Part of the ContractResolver interface.
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func (h *htlcTimeoutResolver) IsResolved() bool {
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return h.resolved
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}
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// Encode writes an encoded version of the ContractResolver into the passed
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// Writer.
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//
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// NOTE: Part of the ContractResolver interface.
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func (h *htlcTimeoutResolver) Encode(w io.Writer) error {
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// First, we'll write out the relevant fields of the
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// OutgoingHtlcResolution to the writer.
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if err := encodeOutgoingResolution(w, &h.htlcResolution); err != nil {
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return err
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}
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// With that portion written, we can now write out the fields specific
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// to the resolver itself.
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if err := binary.Write(w, endian, h.outputIncubating); err != nil {
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return err
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}
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if err := binary.Write(w, endian, h.resolved); err != nil {
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return err
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}
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if err := binary.Write(w, endian, h.broadcastHeight); err != nil {
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return err
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}
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if err := binary.Write(w, endian, h.htlc.HtlcIndex); err != nil {
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return err
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}
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// We encode the sign details last for backwards compatibility.
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err := encodeSignDetails(w, h.htlcResolution.SignDetails)
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if err != nil {
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return err
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}
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return nil
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}
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// newTimeoutResolverFromReader attempts to decode an encoded ContractResolver
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// from the passed Reader instance, returning an active ContractResolver
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// instance.
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func newTimeoutResolverFromReader(r io.Reader, resCfg ResolverConfig) (
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*htlcTimeoutResolver, error) {
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h := &htlcTimeoutResolver{
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contractResolverKit: *newContractResolverKit(resCfg),
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}
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// First, we'll read out all the mandatory fields of the
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// OutgoingHtlcResolution that we store.
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if err := decodeOutgoingResolution(r, &h.htlcResolution); err != nil {
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return nil, err
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}
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// With those fields read, we can now read back the fields that are
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// specific to the resolver itself.
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if err := binary.Read(r, endian, &h.outputIncubating); err != nil {
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return nil, err
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}
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if err := binary.Read(r, endian, &h.resolved); err != nil {
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return nil, err
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}
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if err := binary.Read(r, endian, &h.broadcastHeight); err != nil {
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return nil, err
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}
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if err := binary.Read(r, endian, &h.htlc.HtlcIndex); err != nil {
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return nil, err
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}
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// Sign details is a new field that was added to the htlc resolution,
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// so it is serialized last for backwards compatibility. We try to read
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// it, but don't error out if there are not bytes left.
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signDetails, err := decodeSignDetails(r)
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if err == nil {
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h.htlcResolution.SignDetails = signDetails
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} else if err != io.EOF && err != io.ErrUnexpectedEOF {
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return nil, err
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}
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return h, nil
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}
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// Supplement adds additional information to the resolver that is required
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// before Resolve() is called.
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//
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// NOTE: Part of the htlcContractResolver interface.
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func (h *htlcTimeoutResolver) Supplement(htlc channeldb.HTLC) {
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h.htlc = htlc
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}
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// HtlcPoint returns the htlc's outpoint on the commitment tx.
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//
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// NOTE: Part of the htlcContractResolver interface.
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func (h *htlcTimeoutResolver) HtlcPoint() wire.OutPoint {
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return h.htlcResolution.HtlcPoint()
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}
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// A compile time assertion to ensure htlcTimeoutResolver meets the
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// ContractResolver interface.
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var _ htlcContractResolver = (*htlcTimeoutResolver)(nil)
|