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lnd.xprv/utxonursery.go
Olaoluwa Osuntokun 2faafbcd93
breacharbiter: properly account for second-level spends during breach remedy 
In this commit, we address an un accounted for case during the breach
remedy process. If the remote node actually went directly to the second
layer during a channel breach attempt, then we wouldn’t properly be
able to sweep with out justice transaction, as some HTLC inputs may
actually be spent at that point.

In order to address this case, we’ll now catch the transaction
rejection, then check to see which input was spent, promote that to a
second level spend, and repeat as necessary. At the end of this loop,
any inputs which have been spent to the second level will have had the
prevouts and witnesses updated.

In order to perform this transition, we now also store the second level
witness script in the database. This allow us to modify the sign desc
with the proper input value, as well as witness script.
2018-01-22 19:20:01 -08:00

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package main
import (
"bytes"
"encoding/binary"
"fmt"
"io"
"strings"
"sync"
"sync/atomic"
"github.com/davecgh/go-spew/spew"
"github.com/lightningnetwork/lnd/chainntnfs"
"github.com/lightningnetwork/lnd/channeldb"
"github.com/lightningnetwork/lnd/lnwallet"
"github.com/roasbeef/btcd/blockchain"
"github.com/roasbeef/btcd/txscript"
"github.com/roasbeef/btcd/wire"
"github.com/roasbeef/btcutil"
)
// SUMMARY OF OUTPUT STATES
//
// - CRIB
// - SerializedType: babyOutput
// - OriginalOutputType: HTLC
// - Awaiting: First-stage HTLC CLTV expiry
// - HeightIndexEntry: Absolute block height of CLTV expiry.
// - NextState: KNDR
// - PSCL
// - SerializedType: kidOutput
// - OriginalOutputType: Commitment
// - Awaiting: Confirmation of commitment txn
// - HeightIndexEntry: None.
// - NextState: KNDR
// - KNDR
// - SerializedType: kidOutput
// - OriginalOutputType: Commitment or HTLC
// - Awaiting: Commitment CSV expiry or second-stage HTLC CSV expiry.
// - HeightIndexEntry: Input confirmation height + relative CSV delay
// - NextState: GRAD
// - GRAD:
// - SerializedType: kidOutput
// - OriginalOutputType: Commitment or HTLC
// - Awaiting: All other outputs in channel to become GRAD.
// - NextState: Mark channel fully closed in channeldb and remove.
//
// DESCRIPTION OF OUTPUT STATES
//
// TODO(roasbeef): update comment with both new output types
//
// - CRIB (babyOutput) outputs are two-stage htlc outputs that are initially
// locked using a CLTV delay, followed by a CSV delay. The first stage of a
// crib output requires broadcasting a presigned htlc timeout txn generated
// by the wallet after an absolute expiry height. Since the timeout txns are
// predetermined, they cannot be batched after-the-fact, meaning that all
// CRIB outputs are broadcast and confirmed independently. After the first
// stage is complete, a CRIB output is moved to the KNDR state, which will
// finishing sweeping the second-layer CSV delay.
//
// - PSCL (kidOutput) outputs are commitment outputs locked under a CSV delay.
// These outputs are stored temporarily in this state until the commitment
// transaction confirms, as this solidifies an absolute height that the
// relative time lock will expire. Once this maturity height is determined,
// the PSCL output is moved into KNDR.
//
// - KNDR (kidOutput) outputs are CSV delayed outputs for which the maturity
// height has been fully determined. This results from having received
// confirmation of the UTXO we are trying to spend, contained in either the
// commitment txn or htlc timeout txn. Once the maturity height is reached,
// the utxo nursery will sweep all KNDR outputs scheduled for that height
// using a single txn.
//
// NOTE: Due to the fact that KNDR outputs can be dynamically aggregated and
// swept, we make precautions to finalize the KNDR outputs at a particular
// height on our first attempt to sweep it. Finalizing involves signing the
// sweep transaction and persisting it in the nursery store, and recording
// the last finalized height. Any attempts to replay an already finalized
// height will result in broadcasting the already finalized txn, ensuring the
// nursery does not broadcast different txids for the same batch of KNDR
// outputs. The reason txids may change is due to the probabilistic nature of
// generating the pkscript in the sweep txn's output, even if the set of
// inputs remains static across attempts.
//
// - GRAD (kidOutput) outputs are KNDR outputs that have successfully been
// swept into the user's wallet. A channel is considered mature once all of
// its outputs, including two-stage htlcs, have entered the GRAD state,
// indicating that it safe to mark the channel as fully closed.
//
//
// OUTPUT STATE TRANSITIONS IN UTXO NURSERY
//
// ┌────────────────┐ ┌──────────────┐
// │ Commit Outputs │ │ HTLC Outputs │
// └────────────────┘ └──────────────┘
// │ │
// │ │
// │ │ UTXO NURSERY
// ┌───────────┼────────────────┬───────────┼───────────────────────────────┐
// │ │ │ │
// │ │ │ │ │
// │ │ │ CLTV-Delayed │
// │ │ │ V babyOutputs │
// │ │ ┌──────┐ │
// │ │ │ │ CRIB │ │
// │ │ └──────┘ │
// │ │ │ │ │
// │ │ │ │
// │ │ │ | │
// │ │ V Wait CLTV │
// │ │ │ [ ] + │
// │ │ | Publish Txn │
// │ │ │ │ │
// │ │ │ │
// │ │ │ V ┌ ─ ─ ─ ─ ─ ─ ─ ─ ─ ─┐ │
// │ │ ( ) waitForTimeoutConf │
// │ │ │ | └ ─ ─ ─ ─ ─ ─ ─ ─ ─ ─┘ │
// │ │ │ │
// │ │ │ │ │
// │ │ │ │
// │ V │ │ │
// │ ┌──────┐ │ │
// │ │ PSCL │ └ ── ── ─┼ ── ── ── ── ── ── ── ─┤
// │ └──────┘ │ │
// │ │ │ │
// │ │ │ │
// │ V ┌ ─ ─ ─ ─ ─ ─ ─ ─ ─ ─┐ │ CSV-Delayed │
// │ ( ) waitForCommitConf │ kidOutputs │
// │ | └ ─ ─ ─ ─ ─ ─ ─ ─ ─ ─┘ │ │
// │ │ │ │
// │ │ │ │
// │ │ V │
// │ │ ┌──────┐ │
// │ └─ ─ ─ ─ ─ ─ ─ ─ ─ ─ ─ ─▶│ KNDR │ │
// │ └──────┘ │
// │ │ │
// │ │ │
// │ | │
// │ V Wait CSV │
// │ [ ] + │
// │ | Publish Txn │
// │ │ │
// │ │ │
// │ V ┌ ─ ─ ─ ─ ─ ─ ─ ─ ─ ┐ │
// │ ( ) waitForSweepConf │
// │ | └ ─ ─ ─ ─ ─ ─ ─ ─ ─ ┘ │
// │ │ │
// │ │ │
// │ V │
// │ ┌──────┐ │
// │ │ GRAD │ │
// │ └──────┘ │
// │ │ │
// │ │ │
// │ │ │
// └────────────────────────────────────────┼───────────────────────────────┘
// │
// │
// │
// │
// V
// ┌────────────────┐
// │ Wallet Outputs │
// └────────────────┘
var byteOrder = binary.BigEndian
var (
// ErrContractNotFound is returned when the nursery is unable to
// retrieve information about a queried contract.
ErrContractNotFound = fmt.Errorf("unable to locate contract")
)
// NurseryConfig abstracts the required subsystems used by the utxo nursery. An
// instance of NurseryConfig is passed to newUtxoNursery during instantiation.
type NurseryConfig struct {
// ChainIO is used by the utxo nursery to determine the current block
// height, which drives the incubation of the nursery's outputs.
ChainIO lnwallet.BlockChainIO
// ConfDepth is the number of blocks the nursery store waits before
// determining outputs in the chain as confirmed.
ConfDepth uint32
// DB provides access to a user's channels, such that they can be marked
// fully closed after incubation has concluded.
DB *channeldb.DB
// Estimator is used when crafting sweep transactions to estimate the
// necessary fee relative to the expected size of the sweep transaction.
Estimator lnwallet.FeeEstimator
// GenSweepScript generates a P2WKH script belonging to the wallet where
// funds can be swept.
GenSweepScript func() ([]byte, error)
// Notifier provides the utxo nursery the ability to subscribe to
// transaction confirmation events, which advance outputs through their
// persistence state transitions.
Notifier chainntnfs.ChainNotifier
// PublishTransaction facilitates the process of broadcasting a signed
// transaction to the appropriate network.
PublishTransaction func(*wire.MsgTx) error
// Signer is used by the utxo nursery to generate valid witnesses at the
// time the incubated outputs need to be spent.
Signer lnwallet.Signer
// Store provides access to and modification of the persistent state
// maintained about the utxo nursery's incubating outputs.
Store NurseryStore
}
// utxoNursery is a system dedicated to incubating time-locked outputs created
// by the broadcast of a commitment transaction either by us, or the remote
// peer. The nursery accepts outputs and "incubates" them until they've reached
// maturity, then sweep the outputs into the source wallet. An output is
// considered mature after the relative time-lock within the pkScript has
// passed. As outputs reach their maturity age, they're swept in batches into
// the source wallet, returning the outputs so they can be used within future
// channels, or regular Bitcoin transactions.
type utxoNursery struct {
started uint32
stopped uint32
cfg *NurseryConfig
mu sync.Mutex
bestHeight uint32
quit chan struct{}
wg sync.WaitGroup
}
// newUtxoNursery creates a new instance of the utxoNursery from a
// ChainNotifier and LightningWallet instance.
func newUtxoNursery(cfg *NurseryConfig) *utxoNursery {
return &utxoNursery{
cfg: cfg,
quit: make(chan struct{}),
}
}
// Start launches all goroutines the utxoNursery needs to properly carry out
// its duties.
func (u *utxoNursery) Start() error {
if !atomic.CompareAndSwapUint32(&u.started, 0, 1) {
return nil
}
utxnLog.Tracef("Starting UTXO nursery")
// 1. Start watching for new blocks, as this will drive the nursery
// store's state machine.
// Register with the notifier to receive notifications for each newly
// connected block. We register immediately on startup to ensure that
// no blocks are missed while we are handling blocks that were missed
// during the time the UTXO nursery was unavailable.
newBlockChan, err := u.cfg.Notifier.RegisterBlockEpochNtfn()
if err != nil {
return err
}
// 2. Flush all fully-graduated channels from the pipeline.
// Load any pending close channels, which represents the super set of
// all channels that may still be incubating.
pendingCloseChans, err := u.cfg.DB.FetchClosedChannels(true)
if err != nil {
newBlockChan.Cancel()
return err
}
// Ensure that all mature channels have been marked as fully closed in
// the channeldb.
for _, pendingClose := range pendingCloseChans {
err := u.closeAndRemoveIfMature(&pendingClose.ChanPoint)
if err != nil {
newBlockChan.Cancel()
return err
}
}
// TODO(conner): check if any fully closed channels can be removed from
// utxn.
// Query the nursery store for the lowest block height we could be
// incubating, which is taken to be the last height for which the
// database was purged.
lastGraduatedHeight, err := u.cfg.Store.LastGraduatedHeight()
if err != nil {
newBlockChan.Cancel()
return err
}
// 2. Restart spend ntfns for any preschool outputs, which are waiting
// for the force closed commitment txn to confirm, or any second-layer
// HTLC success transactions.
//
// NOTE: The next two steps *may* spawn go routines, thus from this
// point forward, we must close the nursery's quit channel if we detect
// any failures during startup to ensure they terminate.
if err := u.reloadPreschool(lastGraduatedHeight); err != nil {
newBlockChan.Cancel()
close(u.quit)
return err
}
// 3. Replay all crib and kindergarten outputs from last pruned to
// current best height.
if err := u.reloadClasses(lastGraduatedHeight); err != nil {
newBlockChan.Cancel()
close(u.quit)
return err
}
u.wg.Add(1)
go u.incubator(newBlockChan)
return nil
}
// Stop gracefully shuts down any lingering goroutines launched during normal
// operation of the utxoNursery.
func (u *utxoNursery) Stop() error {
if !atomic.CompareAndSwapUint32(&u.stopped, 0, 1) {
return nil
}
utxnLog.Infof("UTXO nursery shutting down")
close(u.quit)
u.wg.Wait()
return nil
}
// IncubateOutputs sends a request to the utxoNursery to incubate a set of
// outputs from an existing commitment transaction. Outputs need to incubate if
// they're CLTV absolute time locked, or if they're CSV relative time locked.
// Once all outputs reach maturity, they'll be swept back into the wallet.
func (u *utxoNursery) IncubateOutputs(chanPoint wire.OutPoint,
commitResolution *lnwallet.CommitOutputResolution,
outgoingHtlcs []lnwallet.OutgoingHtlcResolution,
incomingHtlcs []lnwallet.IncomingHtlcResolution) error {
numHtlcs := len(incomingHtlcs) + len(outgoingHtlcs)
var (
hasCommit bool
// Kid outputs can be swept after an initial confirmation
// followed by a maturity period.Baby outputs are two stage and
// will need to wait for a absolute time out to reach a
// confirmation, then require a relative confirmation delay.
kidOutputs = make([]kidOutput, 0, 1+len(incomingHtlcs))
babyOutputs = make([]babyOutput, 0, len(outgoingHtlcs))
)
// 1. Build all the spendable outputs that we will try to incubate.
// It could be that our to-self output was below the dust limit. In
// that case the commit resolution would be nil and we would not have
// that output to incubate.
if commitResolution != nil {
hasCommit = true
selfOutput := makeKidOutput(
&commitResolution.SelfOutPoint,
&chanPoint,
commitResolution.MaturityDelay,
lnwallet.CommitmentTimeLock,
&commitResolution.SelfOutputSignDesc,
0,
)
// We'll skip any zero value'd outputs as this indicates we
// don't have a settled balance within the commitment
// transaction.
if selfOutput.Amount() > 0 {
kidOutputs = append(kidOutputs, selfOutput)
}
}
// TODO(roasbeef): query and see if we already have, if so don't add?
// For each incoming HTLC, we'll register a kid output marked as a
// second-layer HTLC output. We effectively skip the baby stage (as the
// timelock is zero), and enter the kid stage.
for _, htlcRes := range incomingHtlcs {
htlcOutput := makeKidOutput(
&htlcRes.ClaimOutpoint, &chanPoint, htlcRes.CsvDelay,
lnwallet.HtlcAcceptedSuccessSecondLevel,
&htlcRes.SweepSignDesc, 0,
)
if htlcOutput.Amount() > 0 {
kidOutputs = append(kidOutputs, htlcOutput)
}
}
// For each outgoing HTLC, we'll create a baby output. If this is our
// commitment transaction, then we'll broadcast a second-layer
// transaction to transition to a kid output. Otherwise, we'll directly
// spend once the CLTV delay us up.
for _, htlcRes := range outgoingHtlcs {
// If this HTLC is on our commitment transaction, then it'll be
// a baby output as we need to go to the second level to sweep
// it.
if htlcRes.SignedTimeoutTx != nil {
htlcOutput := makeBabyOutput(&chanPoint, &htlcRes)
if htlcOutput.Amount() > 0 {
babyOutputs = append(babyOutputs, htlcOutput)
}
continue
}
// Otherwise, this is actually a kid output as we can sweep it
// once the commitment transaction confirms, and the absolute
// CLTV lock has expired. We set the CSV delay to zero to
// indicate this is actually a CLTV output.
htlcOutput := makeKidOutput(
&htlcRes.ClaimOutpoint, &chanPoint, 0,
lnwallet.HtlcOfferedRemoteTimeout,
&htlcRes.SweepSignDesc, htlcRes.Expiry,
)
kidOutputs = append(kidOutputs, htlcOutput)
}
// TODO(roasbeef): if want to handle outgoing on remote commit
// * need ability to cancel in the case that we learn of pre-image or
// remote party pulls
utxnLog.Infof("Incubating Channel(%s) has-commit=%v, num-htlcs=%d",
chanPoint, hasCommit, numHtlcs)
u.mu.Lock()
defer u.mu.Unlock()
// 2. Persist the outputs we intended to sweep in the nursery store
if err := u.cfg.Store.Incubate(kidOutputs, babyOutputs); err != nil {
utxnLog.Errorf("unable to begin incubation of Channel(%s): %v",
chanPoint, err)
return err
}
// As an intermediate step, we'll now check to see if any of the baby
// outputs has actually _already_ expired. This may be the case if
// blocks were mined while we processed this message.
_, bestHeight, err := u.cfg.ChainIO.GetBestBlock()
if err != nil {
return err
}
// We'll examine all the baby outputs just inserted into the database,
// if the output has already expired, then we'll *immediately* sweep
// it. This may happen if the caller raced a block to call this method.
for _, babyOutput := range babyOutputs {
if uint32(bestHeight) >= babyOutput.expiry {
err = u.sweepCribOutput(uint32(bestHeight), &babyOutput)
if err != nil {
return err
}
}
}
// 3. If we are incubating any preschool outputs, register for a
// confirmation notification that will transition it to the
// kindergarten bucket.
if len(kidOutputs) != 0 {
for _, kidOutput := range kidOutputs {
err := u.registerPreschoolConf(&kidOutput, u.bestHeight)
if err != nil {
return err
}
}
}
return nil
}
// NurseryReport attempts to return a nursery report stored for the target
// outpoint. A nursery report details the maturity/sweeping progress for a
// contract that was previously force closed. If a report entry for the target
// chanPoint is unable to be constructed, then an error will be returned.
func (u *utxoNursery) NurseryReport(
chanPoint *wire.OutPoint) (*contractMaturityReport, error) {
u.mu.Lock()
defer u.mu.Unlock()
utxnLog.Infof("NurseryReport: building nursery report for channel %v",
chanPoint)
report := &contractMaturityReport{
chanPoint: *chanPoint,
}
if err := u.cfg.Store.ForChanOutputs(chanPoint, func(k, v []byte) error {
switch {
case bytes.HasPrefix(k, cribPrefix):
// Cribs outputs are the only kind currently stored as
// baby outputs.
var baby babyOutput
err := baby.Decode(bytes.NewReader(v))
if err != nil {
return err
}
// Each crib output represents a stage one htlc, and
// will contribute towards the limbo balance.
report.AddLimboStage1TimeoutHtlc(&baby)
case bytes.HasPrefix(k, psclPrefix),
bytes.HasPrefix(k, kndrPrefix),
bytes.HasPrefix(k, gradPrefix):
// All others states can be deserialized as kid outputs.
var kid kidOutput
err := kid.Decode(bytes.NewReader(v))
if err != nil {
return err
}
// Now, use the state prefixes to determine how the
// this output should be represented in the nursery
// report. An output's funds are always in limbo until
// reaching the graduate state.
switch {
case bytes.HasPrefix(k, psclPrefix):
// Preschool outputs are awaiting the
// confirmation of the commitment transaction.
switch kid.WitnessType() {
case lnwallet.CommitmentTimeLock:
report.AddLimboCommitment(&kid)
// An HTLC output on our commitment transaction
// where the second-layer transaction hasn't
// yet confirmed.
case lnwallet.HtlcAcceptedSuccessSecondLevel:
report.AddLimboStage1SuccessHtlc(&kid)
}
case bytes.HasPrefix(k, kndrPrefix):
// Kindergarten outputs may originate from
// either the commitment transaction or an htlc.
// We can distinguish them via their witness
// types.
switch kid.WitnessType() {
case lnwallet.CommitmentTimeLock:
// The commitment transaction has been
// confirmed, and we are waiting the CSV
// delay to expire.
report.AddLimboCommitment(&kid)
case lnwallet.HtlcOfferedRemoteTimeout:
// This is an HTLC output on the
// commitment transaction of the remote
// party. The CLTV timelock has
// expired, and we only need to sweep
// it.
report.AddLimboDirectHtlc(&kid)
case lnwallet.HtlcAcceptedSuccessSecondLevel:
fallthrough
case lnwallet.HtlcOfferedTimeoutSecondLevel:
// The htlc timeout or success
// transaction has confirmed, and the
// CSV delay has begun ticking.
report.AddLimboStage2Htlc(&kid)
}
case bytes.HasPrefix(k, gradPrefix):
// Graduate outputs are those whose funds have
// been swept back into the wallet. Each output
// will contribute towards the recovered
// balance.
switch kid.WitnessType() {
case lnwallet.CommitmentTimeLock:
// The commitment output was
// successfully swept back into a
// regular p2wkh output.
report.AddRecoveredCommitment(&kid)
case lnwallet.HtlcAcceptedSuccessSecondLevel:
fallthrough
case lnwallet.HtlcOfferedTimeoutSecondLevel:
fallthrough
case lnwallet.HtlcOfferedRemoteTimeout:
// This htlc output successfully
// resides in a p2wkh output belonging
// to the user.
report.AddRecoveredHtlc(&kid)
}
}
default:
}
return nil
}); err != nil {
return nil, err
}
return report, nil
}
// reloadPreschool re-initializes the chain notifier with all of the outputs
// that had been saved to the "preschool" database bucket prior to shutdown.
func (u *utxoNursery) reloadPreschool(heightHint uint32) error {
psclOutputs, err := u.cfg.Store.FetchPreschools()
if err != nil {
return err
}
for i := range psclOutputs {
err := u.registerPreschoolConf(&psclOutputs[i], heightHint)
if err != nil {
return err
}
}
return nil
}
// reloadClasses reinitializes any height-dependent state transitions for which
// the utxonursery has not received confirmation, and replays the graduation of
// all kindergarten and crib outputs for heights that have not been finalized.
// This allows the nursery to reinitialize all state to continue sweeping
// outputs, even in the event that we missed blocks while offline.
// reloadClasses is called during the startup of the UTXO Nursery.
func (u *utxoNursery) reloadClasses(lastGradHeight uint32) error {
// Begin by loading all of the still-active heights up to and including
// the last height we successfully graduated.
activeHeights, err := u.cfg.Store.HeightsBelowOrEqual(lastGradHeight)
if err != nil {
return err
}
if len(activeHeights) > 0 {
utxnLog.Infof("Re-registering confirmations for %d already "+
"graduated heights below height=%d", len(activeHeights),
lastGradHeight)
}
// Attempt to re-register notifications for any outputs still at these
// heights.
for _, classHeight := range activeHeights {
utxnLog.Debugf("Attempting to regraduate outputs at height=%v",
classHeight)
if err = u.regraduateClass(classHeight); err != nil {
utxnLog.Errorf("Failed to regraduate outputs at "+
"height=%v: %v", classHeight, err)
return err
}
}
// Get the most recently mined block.
_, bestHeight, err := u.cfg.ChainIO.GetBestBlock()
if err != nil {
return err
}
// If we haven't yet seen any registered force closes, or we're already
// caught up with the current best chain, then we can exit early.
if lastGradHeight == 0 || uint32(bestHeight) == lastGradHeight {
return nil
}
utxnLog.Infof("Processing outputs from missed blocks. Starting with "+
"blockHeight=%v, to current blockHeight=%v", lastGradHeight,
bestHeight)
// Loop through and check for graduating outputs at each of the missed
// block heights.
for curHeight := lastGradHeight + 1; curHeight <= uint32(bestHeight); curHeight++ {
utxnLog.Debugf("Attempting to graduate outputs at height=%v",
curHeight)
if err := u.graduateClass(curHeight); err != nil {
utxnLog.Errorf("Failed to graduate outputs at "+
"height=%v: %v", curHeight, err)
return err
}
}
utxnLog.Infof("UTXO Nursery is now fully synced")
return nil
}
// regraduateClass handles the steps involved in re-registering for
// confirmations for all still-active outputs at a particular height. This is
// used during restarts to ensure that any still-pending state transitions are
// properly registered, so they can be driven by the chain notifier. No
// transactions or signing are done as a result of this step.
func (u *utxoNursery) regraduateClass(classHeight uint32) error {
// Fetch all information about the crib and kindergarten outputs at
// this height. In addition to the outputs, we also retrieve the
// finalized kindergarten sweep txn, which will be nil if we have not
// attempted this height before, or if no kindergarten outputs exist at
// this height.
finalTx, kgtnOutputs, cribOutputs, err := u.cfg.Store.FetchClass(
classHeight)
if err != nil {
return err
}
if finalTx != nil {
utxnLog.Infof("Re-registering confirmation for kindergarten "+
"sweep transaction at height=%d ", classHeight)
err = u.registerSweepConf(finalTx, kgtnOutputs, classHeight)
if err != nil {
utxnLog.Errorf("Failed to re-register for kindergarten "+
"sweep transaction at height=%d: %v",
classHeight, err)
return err
}
}
if len(cribOutputs) == 0 {
return nil
}
utxnLog.Infof("Re-registering confirmation for first-stage HTLC "+
"outputs at height=%d ", classHeight)
// Now, we broadcast all pre-signed htlc txns from the crib outputs at
// this height. There is no need to finalize these txns, since the txid
// is predetermined when signed in the wallet.
for i := range cribOutputs {
err := u.sweepCribOutput(classHeight, &cribOutputs[i])
if err != nil {
utxnLog.Errorf("Failed to re-register first-stage "+
"HTLC output %v", cribOutputs[i].OutPoint())
return err
}
}
return nil
}
// incubator is tasked with driving all state transitions that are dependent on
// the current height of the blockchain. As new blocks arrive, the incubator
// will attempt spend outputs at the latest height. The asynchronous
// confirmation of these spends will either 1) move a crib output into the
// kindergarten bucket or 2) move a kindergarten output into the graduated
// bucket.
func (u *utxoNursery) incubator(newBlockChan *chainntnfs.BlockEpochEvent) {
defer u.wg.Done()
defer newBlockChan.Cancel()
for {
select {
case epoch, ok := <-newBlockChan.Epochs:
// If the epoch channel has been closed, then the
// ChainNotifier is exiting which means the daemon is
// as well. Therefore, we exit early also in order to
// ensure the daemon shuts down gracefully, yet
// swiftly.
if !ok {
return
}
// TODO(roasbeef): if the BlockChainIO is rescanning
// will give stale data
// A new block has just been connected to the main
// chain, which means we might be able to graduate crib
// or kindergarten outputs at this height. This involves
// broadcasting any presigned htlc timeout txns, as well
// as signing and broadcasting a sweep txn that spends
// from all kindergarten outputs at this height.
height := uint32(epoch.Height)
if err := u.graduateClass(height); err != nil {
utxnLog.Errorf("error while graduating "+
"class at height=%d: %v", height, err)
// TODO(conner): signal fatal error to daemon
}
case <-u.quit:
return
}
}
}
// graduateClass handles the steps involved in spending outputs whose CSV or
// CLTV delay expires at the nursery's current height. This method is called
// each time a new block arrives, or during startup to catch up on heights we
// may have missed while the nursery was offline.
func (u *utxoNursery) graduateClass(classHeight uint32) error {
// Record this height as the nursery's current best height.
u.mu.Lock()
defer u.mu.Unlock()
u.bestHeight = classHeight
// Fetch all information about the crib and kindergarten outputs at
// this height. In addition to the outputs, we also retrieve the
// finalized kindergarten sweep txn, which will be nil if we have not
// attempted this height before, or if no kindergarten outputs exist at
// this height.
finalTx, kgtnOutputs, cribOutputs, err := u.cfg.Store.FetchClass(
classHeight)
if err != nil {
return err
}
utxnLog.Infof("Attempting to graduate height=%v: num_kids=%v, "+
"num_babies=%v", classHeight, len(kgtnOutputs), len(cribOutputs))
// Load the last finalized height, so we can determine if the
// kindergarten sweep txn should be crafted.
lastFinalizedHeight, err := u.cfg.Store.LastFinalizedHeight()
if err != nil {
return err
}
// If we haven't processed this height before, we finalize the
// graduating kindergarten outputs, by signing a sweep transaction that
// spends from them. This txn is persisted such that we never broadcast
// a different txn for the same height. This allows us to recover from
// failures, and watch for the correct txid.
if classHeight > lastFinalizedHeight {
// If this height has never been finalized, we have never
// generated a sweep txn for this height. Generate one if there
// are kindergarten outputs or cltv crib outputs to be spent.
if len(kgtnOutputs) > 0 {
finalTx, err = u.createSweepTx(kgtnOutputs, classHeight)
if err != nil {
utxnLog.Errorf("Failed to create sweep txn at "+
"height=%d", classHeight)
return err
}
}
// Persist the kindergarten sweep txn to the nursery store. It
// is safe to store a nil finalTx, which happens if there are
// no graduating kindergarten outputs.
err = u.cfg.Store.FinalizeKinder(classHeight, finalTx)
if err != nil {
utxnLog.Errorf("Failed to finalize kindergarten at "+
"height=%d", classHeight)
return err
}
// Log if the finalized transaction is non-trivial.
if finalTx != nil {
utxnLog.Infof("Finalized kindergarten at height=%d ",
classHeight)
}
}
// Now that the kindergarten sweep txn has either been finalized or
// restored, broadcast the txn, and set up notifications that will
// transition the swept kindergarten outputs and cltvCrib into
// graduated outputs.
if finalTx != nil {
err := u.sweepMatureOutputs(classHeight, finalTx, kgtnOutputs)
if err != nil {
utxnLog.Errorf("Failed to sweep %d kindergarten "+
"outputs at height=%d: %v",
len(kgtnOutputs), classHeight, err)
return err
}
}
// Now, we broadcast all pre-signed htlc txns from the csv crib outputs
// at this height. There is no need to finalize these txns, since the
// txid is predetermined when signed in the wallet.
for i := range cribOutputs {
err := u.sweepCribOutput(classHeight, &cribOutputs[i])
if err != nil {
utxnLog.Errorf("Failed to sweep first-stage HTLC "+
"(CLTV-delayed) output %v",
cribOutputs[i].OutPoint())
return err
}
}
return u.cfg.Store.GraduateHeight(classHeight)
}
// craftSweepTx accepts accepts a list of kindergarten outputs, and baby
// outputs which don't required a second-layer claim, and signs and generates a
// signed txn that spends from them. This method also makes an accurate fee
// estimate before generating the required witnesses.
func (u *utxoNursery) createSweepTx(kgtnOutputs []kidOutput,
classHeight uint32) (*wire.MsgTx, error) {
// Create a transaction which sweeps all the newly mature outputs into
// a output controlled by the wallet.
// TODO(roasbeef): can be more intelligent about buffering outputs to
// be more efficient on-chain.
// Assemble the kindergarten class into a slice csv spendable outputs,
// and also a set of regular spendable outputs. The set of regular
// outputs are CLTV locked outputs that have had their timelocks
// expire.
var (
csvOutputs []CsvSpendableOutput
cltvOutputs []SpendableOutput
weightEstimate lnwallet.TxWeightEstimator
)
// Allocate enough room for both types of kindergarten outputs.
csvOutputs = make([]CsvSpendableOutput, 0, len(kgtnOutputs))
cltvOutputs = make([]SpendableOutput, 0, len(kgtnOutputs))
// Our sweep transaction will pay to a single segwit p2wkh address,
// ensure it contributes to our weight estimate.
weightEstimate.AddP2WKHOutput()
// For each kindergarten output, use its witness type to determine the
// estimate weight of its witness, and add it to the proper set of
// spendable outputs.
for i := range kgtnOutputs {
input := &kgtnOutputs[i]
switch input.WitnessType() {
// Outputs on a past commitment transaction that pay directly
// to us.
case lnwallet.CommitmentTimeLock:
weightEstimate.AddWitnessInput(
lnwallet.ToLocalTimeoutWitnessSize,
)
csvOutputs = append(csvOutputs, input)
// Outgoing second layer HTLC's that have confirmed within the
// chain, and the output they produced is now mature enough to
// sweep.
case lnwallet.HtlcOfferedTimeoutSecondLevel:
weightEstimate.AddWitnessInput(
lnwallet.SecondLevelHtlcSuccessWitnessSize,
)
csvOutputs = append(csvOutputs, input)
// Incoming second layer HTLC's that have confirmed within the
// chain, and the output they produced is now mature enough to
// sweep.
case lnwallet.HtlcAcceptedSuccessSecondLevel:
weightEstimate.AddWitnessInput(
lnwallet.SecondLevelHtlcSuccessWitnessSize,
)
csvOutputs = append(csvOutputs, input)
// An HTLC on the commitment transaction of the remote party,
// that has had its absolute timelock expire.
case lnwallet.HtlcOfferedRemoteTimeout:
weightEstimate.AddWitnessInput(
lnwallet.AcceptedHtlcTimeoutWitnessSize,
)
cltvOutputs = append(cltvOutputs, input)
default:
utxnLog.Warnf("kindergarten output in nursery store "+
"contains unexpected witness type: %v",
input.WitnessType())
continue
}
}
utxnLog.Infof("Creating sweep transaction for %v CSV inputs, %v CLTV "+
"inputs", len(csvOutputs), len(cltvOutputs))
txWeight := uint64(weightEstimate.Weight())
return u.populateSweepTx(txWeight, classHeight, csvOutputs, cltvOutputs)
}
// populateSweepTx populate the final sweeping transaction with all witnesses
// in place for all inputs using the provided txn fee. The created transaction
// has a single output sending all the funds back to the source wallet, after
// accounting for the fee estimate.
func (u *utxoNursery) populateSweepTx(txWeight uint64, classHeight uint32,
csvInputs []CsvSpendableOutput,
cltvInputs []SpendableOutput) (*wire.MsgTx, error) {
// Generate the receiving script to which the funds will be swept.
pkScript, err := u.cfg.GenSweepScript()
if err != nil {
return nil, err
}
// Sum up the total value contained in the inputs.
var totalSum btcutil.Amount
for _, o := range csvInputs {
totalSum += o.Amount()
}
for _, o := range cltvInputs {
totalSum += o.Amount()
}
// Using the txn weight estimate, compute the required txn fee.
feePerWeight, err := u.cfg.Estimator.EstimateFeePerWeight(6)
if err != nil {
return nil, err
}
txFee := btcutil.Amount(txWeight) * feePerWeight
// Sweep as much possible, after subtracting txn fees.
sweepAmt := int64(totalSum - txFee)
// Create the sweep transaction that we will be building. We use
// version 2 as it is required for CSV. The txn will sweep the amount
// after fees to the pkscript generated above.
sweepTx := wire.NewMsgTx(2)
sweepTx.AddTxOut(&wire.TxOut{
PkScript: pkScript,
Value: sweepAmt,
})
// We'll also ensure that the transaction has the required lock time if
// we're sweeping any cltvInputs.
if len(cltvInputs) > 0 {
sweepTx.LockTime = classHeight
}
// Add all inputs to the sweep transaction. Ensure that for each
// csvInput, we set the sequence number properly.
for _, input := range csvInputs {
sweepTx.AddTxIn(&wire.TxIn{
PreviousOutPoint: *input.OutPoint(),
Sequence: input.BlocksToMaturity(),
})
}
for _, input := range cltvInputs {
sweepTx.AddTxIn(&wire.TxIn{
PreviousOutPoint: *input.OutPoint(),
})
}
// Before signing the transaction, check to ensure that it meets some
// basic validity requirements.
// TODO(conner): add more control to sanity checks, allowing us to delay
// spending "problem" outputs, e.g. possibly batching with other classes
// if fees are too low.
btx := btcutil.NewTx(sweepTx)
if err := blockchain.CheckTransactionSanity(btx); err != nil {
return nil, err
}
hashCache := txscript.NewTxSigHashes(sweepTx)
// With all the inputs in place, use each output's unique witness
// function to generate the final witness required for spending.
addWitness := func(idx int, tso SpendableOutput) error {
witness, err := tso.BuildWitness(
u.cfg.Signer, sweepTx, hashCache, idx,
)
if err != nil {
return err
}
sweepTx.TxIn[idx].Witness = witness
return nil
}
// Finally we'll attach a valid witness to each csv and cltv input
// within the sweeping transaction.
for i, input := range csvInputs {
if err := addWitness(i, input); err != nil {
return nil, err
}
}
for i, input := range cltvInputs {
if err := addWitness(i, input); err != nil {
return nil, err
}
}
return sweepTx, nil
}
// sweepMatureOutputs generates and broadcasts the transaction that transfers
// control of funds from a prior channel commitment transaction to the user's
// wallet. The outputs swept were previously time locked (either absolute or
// relative), but are not mature enough to sweep into the wallet.
func (u *utxoNursery) sweepMatureOutputs(classHeight uint32, finalTx *wire.MsgTx,
kgtnOutputs []kidOutput) error {
utxnLog.Infof("Sweeping %v CSV-delayed outputs with sweep tx "+
"(txid=%v): %v", len(kgtnOutputs),
finalTx.TxHash(), newLogClosure(func() string {
return spew.Sdump(finalTx)
}),
)
// With the sweep transaction fully signed, broadcast the transaction
// to the network. Additionally, we can stop tracking these outputs as
// they've just been swept.
// TODO(conner): handle concrete error types returned from publication
err := u.cfg.PublishTransaction(finalTx)
if err != nil && !strings.Contains(err.Error(), "TX rejected:") {
utxnLog.Errorf("unable to broadcast sweep tx: %v, %v",
err, spew.Sdump(finalTx))
return err
}
return u.registerSweepConf(finalTx, kgtnOutputs, classHeight)
}
// registerSweepConf is responsible for registering a finalized kindergarten
// sweep transaction for confirmation notifications. If the confirmation was
// successfully registered, a goroutine will be spawned that waits for the
// confirmation, and graduates the provided kindergarten class within the
// nursery store.
func (u *utxoNursery) registerSweepConf(finalTx *wire.MsgTx,
kgtnOutputs []kidOutput, heightHint uint32) error {
finalTxID := finalTx.TxHash()
confChan, err := u.cfg.Notifier.RegisterConfirmationsNtfn(
&finalTxID, u.cfg.ConfDepth, heightHint)
if err != nil {
utxnLog.Errorf("unable to register notification for "+
"sweep confirmation: %v", finalTxID)
return err
}
utxnLog.Infof("Registering sweep tx %v for confs at height=%d",
finalTxID, heightHint)
u.wg.Add(1)
go u.waitForSweepConf(heightHint, kgtnOutputs, confChan)
return nil
}
// waitForSweepConf watches for the confirmation of a sweep transaction
// containing a batch of kindergarten outputs. Once confirmation has been
// received, the nursery will mark those outputs as fully graduated, and proceed
// to mark any mature channels as fully closed in channeldb.
// NOTE(conner): this method MUST be called as a go routine.
func (u *utxoNursery) waitForSweepConf(classHeight uint32,
kgtnOutputs []kidOutput, confChan *chainntnfs.ConfirmationEvent) {
defer u.wg.Done()
select {
case _, ok := <-confChan.Confirmed:
if !ok {
utxnLog.Errorf("Notification chan closed, can't"+
" advance %v graduating outputs",
len(kgtnOutputs))
return
}
case <-u.quit:
return
}
u.mu.Lock()
defer u.mu.Unlock()
// TODO(conner): add retry logic?
// Mark the confirmed kindergarten outputs as graduated.
if err := u.cfg.Store.GraduateKinder(classHeight); err != nil {
utxnLog.Errorf("Unable to graduate %v kingdergarten outputs: "+
"%v", len(kgtnOutputs), err)
return
}
utxnLog.Infof("Graduated %d kindergarten outputs from height=%d",
len(kgtnOutputs), classHeight)
// Iterate over the kid outputs and construct a set of all channel
// points to which they belong.
var possibleCloses = make(map[wire.OutPoint]struct{})
for _, kid := range kgtnOutputs {
possibleCloses[*kid.OriginChanPoint()] = struct{}{}
}
// Attempt to close each channel, only doing so if all of the channel's
// outputs have been graduated.
for chanPoint := range possibleCloses {
if err := u.closeAndRemoveIfMature(&chanPoint); err != nil {
utxnLog.Errorf("Failed to close and remove channel %v",
chanPoint)
return
}
}
}
// sweepCribOutput broadcasts the crib output's htlc timeout txn, and sets up a
// notification that will advance it to the kindergarten bucket upon
// confirmation.
func (u *utxoNursery) sweepCribOutput(classHeight uint32, baby *babyOutput) error {
utxnLog.Infof("Publishing CLTV-delayed HTLC output using timeout tx "+
"(txid=%v): %v", baby.timeoutTx.TxHash(),
newLogClosure(func() string {
return spew.Sdump(baby.timeoutTx)
}),
)
// We'll now broadcast the HTLC transaction, then wait for it to be
// confirmed before transitioning it to kindergarten.
//
// TODO(conner): handle concrete error types returned from publication
err := u.cfg.PublishTransaction(baby.timeoutTx)
if err != nil &&
!strings.Contains(err.Error(), "TX rejected:") {
utxnLog.Errorf("Unable to broadcast baby tx: "+
"%v, %v", err,
spew.Sdump(baby.timeoutTx))
return err
}
return u.registerTimeoutConf(baby, classHeight)
}
// registerTimeoutConf is responsible for subscribing to confirmation
// notification for an htlc timeout transaction. If successful, a goroutine
// will be spawned that will transition the provided baby output into the
// kindergarten state within the nursery store.
func (u *utxoNursery) registerTimeoutConf(baby *babyOutput, heightHint uint32) error {
birthTxID := baby.timeoutTx.TxHash()
// Register for the confirmation of presigned htlc txn.
confChan, err := u.cfg.Notifier.RegisterConfirmationsNtfn(
&birthTxID, u.cfg.ConfDepth, heightHint)
if err != nil {
return err
}
utxnLog.Infof("Htlc output %v registered for promotion "+
"notification.", baby.OutPoint())
u.wg.Add(1)
go u.waitForTimeoutConf(baby, confChan)
return nil
}
// waitForTimeoutConf watches for the confirmation of an htlc timeout
// transaction, and attempts to move the htlc output from the crib bucket to the
// kindergarten bucket upon success.
func (u *utxoNursery) waitForTimeoutConf(baby *babyOutput,
confChan *chainntnfs.ConfirmationEvent) {
defer u.wg.Done()
select {
case txConfirmation, ok := <-confChan.Confirmed:
if !ok {
utxnLog.Errorf("Notification chan "+
"closed, can't advance baby output %v",
baby.OutPoint())
return
}
baby.SetConfHeight(txConfirmation.BlockHeight)
case <-u.quit:
return
}
u.mu.Lock()
defer u.mu.Unlock()
// TODO(conner): add retry logic?
err := u.cfg.Store.CribToKinder(baby)
if err != nil {
utxnLog.Errorf("Unable to move htlc output from "+
"crib to kindergarten bucket: %v", err)
return
}
utxnLog.Infof("Htlc output %v promoted to "+
"kindergarten", baby.OutPoint())
}
// registerPreschoolConf is responsible for subscribing to the confirmation of
// a commitment transaction, or an htlc success transaction for an incoming
// HTLC on our commitment transaction.. If successful, the provided preschool
// output will be moved persistently into the kindergarten state within the
// nursery store.
func (u *utxoNursery) registerPreschoolConf(kid *kidOutput, heightHint uint32) error {
txID := kid.OutPoint().Hash
// TODO(roasbeef): ensure we don't already have one waiting, need to
// de-duplicate
// * need to do above?
confChan, err := u.cfg.Notifier.RegisterConfirmationsNtfn(&txID,
u.cfg.ConfDepth, heightHint)
if err != nil {
return err
}
var outputType string
if kid.isHtlc {
outputType = "HTLC"
} else {
outputType = "Commitment"
}
utxnLog.Infof("%v outpoint %v registered for "+
"confirmation notification.", outputType, kid.OutPoint())
u.wg.Add(1)
go u.waitForPreschoolConf(kid, confChan)
return nil
}
// waitForPreschoolConf is intended to be run as a goroutine that will wait until
// a channel force close commitment transaction, or a second layer HTLC success
// transaction has been included in a confirmed block. Once the transaction has
// been confirmed (as reported by the Chain Notifier), waitForPreschoolConf
// will delete the output from the "preschool" database bucket and atomically
// add it to the "kindergarten" database bucket. This is the second step in
// the output incubation process.
func (u *utxoNursery) waitForPreschoolConf(kid *kidOutput,
confChan *chainntnfs.ConfirmationEvent) {
defer u.wg.Done()
select {
case txConfirmation, ok := <-confChan.Confirmed:
if !ok {
utxnLog.Errorf("Notification chan "+
"closed, can't advance output %v",
kid.OutPoint())
return
}
kid.SetConfHeight(txConfirmation.BlockHeight)
case <-u.quit:
return
}
u.mu.Lock()
defer u.mu.Unlock()
// TODO(conner): add retry logic?
var outputType string
if kid.isHtlc {
outputType = "HTLC"
} else {
outputType = "Commitment"
}
err := u.cfg.Store.PreschoolToKinder(kid)
if err != nil {
utxnLog.Errorf("Unable to move %v output "+
"from preschool to kindergarten bucket: %v",
outputType, err)
return
}
}
// contractMaturityReport is a report that details the maturity progress of a
// particular force closed contract.
type contractMaturityReport struct {
// chanPoint is the channel point of the original contract that is now
// awaiting maturity within the utxoNursery.
chanPoint wire.OutPoint
// limboBalance is the total number of frozen coins within this
// contract.
limboBalance btcutil.Amount
// recoveredBalance is the total value that has been successfully swept
// back to the user's wallet.
recoveredBalance btcutil.Amount
// localAmount is the local value of the commitment output.
localAmount btcutil.Amount
// confHeight is the block height that this output originally confirmed.
confHeight uint32
// maturityRequirement is the input age required for this output to
// reach maturity.
maturityRequirement uint32
// maturityHeight is the absolute block height that this output will
// mature at.
maturityHeight uint32
// htlcs records a maturity report for each htlc output in this channel.
htlcs []htlcMaturityReport
}
// htlcMaturityReport provides a summary of a single htlc output, and is
// embedded as party of the overarching contractMaturityReport
type htlcMaturityReport struct {
// outpoint is the final output that will be swept back to the wallet.
outpoint wire.OutPoint
// amount is the final value that will be swept in back to the wallet.
amount btcutil.Amount
// confHeight is the block height that this output originally confirmed.
confHeight uint32
// maturityRequirement is the input age required for this output to
// reach maturity.
maturityRequirement uint32
// maturityHeight is the absolute block height that this output will
// mature at.
maturityHeight uint32
// stage indicates whether the htlc is in the CLTV-timeout stage (1) or
// the CSV-delay stage (2). A stage 1 htlc's maturity height will be set
// to it's expiry height, while a stage 2 htlc's maturity height will be
// set to it's confirmation height plus the maturity requirement.
stage uint32
}
// AddLimboCommitment adds an incubating commitment output to maturity
// report's htlcs, and contributes its amount to the limbo balance.
func (c *contractMaturityReport) AddLimboCommitment(kid *kidOutput) {
c.limboBalance += kid.Amount()
c.localAmount += kid.Amount()
c.confHeight = kid.ConfHeight()
c.maturityRequirement = kid.BlocksToMaturity()
// If the confirmation height is set, then this means the contract has
// been confirmed, and we know the final maturity height.
if kid.ConfHeight() != 0 {
c.maturityHeight = kid.BlocksToMaturity() + kid.ConfHeight()
}
}
// AddRecoveredCommitment adds a graduated commitment output to maturity
// report's htlcs, and contributes its amount to the recovered balance.
func (c *contractMaturityReport) AddRecoveredCommitment(kid *kidOutput) {
c.recoveredBalance += kid.Amount()
c.localAmount += kid.Amount()
c.confHeight = kid.ConfHeight()
c.maturityRequirement = kid.BlocksToMaturity()
c.maturityHeight = kid.BlocksToMaturity() + kid.ConfHeight()
}
// AddLimboStage1TimeoutHtlc adds an htlc crib output to the maturity report's
// htlcs, and contributes its amount to the limbo balance.
func (c *contractMaturityReport) AddLimboStage1TimeoutHtlc(baby *babyOutput) {
c.limboBalance += baby.Amount()
// TODO(roasbeef): bool to indicate stage 1 vs stage 2?
c.htlcs = append(c.htlcs, htlcMaturityReport{
outpoint: *baby.OutPoint(),
amount: baby.Amount(),
confHeight: baby.ConfHeight(),
maturityHeight: baby.expiry,
stage: 1,
})
}
// AddLimboDirectHtlc adds a direct HTLC on the commitment transaction of the
// remote party to the maturity report. This a CLTV time-locked output that
// hasn't yet expired.
func (c *contractMaturityReport) AddLimboDirectHtlc(kid *kidOutput) {
c.limboBalance += kid.Amount()
htlcReport := htlcMaturityReport{
outpoint: *kid.OutPoint(),
amount: kid.Amount(),
confHeight: kid.ConfHeight(),
maturityHeight: kid.absoluteMaturity,
stage: 2,
}
c.htlcs = append(c.htlcs, htlcReport)
}
// AddLimboStage1SuccessHtlcHtlc adds an htlc crib output to the maturity
// report's set of HTLC's. We'll use this to report any incoming HTLC sweeps
// where the second level transaction hasn't yet confirmed.
func (c *contractMaturityReport) AddLimboStage1SuccessHtlc(kid *kidOutput) {
c.limboBalance += kid.Amount()
c.htlcs = append(c.htlcs, htlcMaturityReport{
outpoint: *kid.OutPoint(),
amount: kid.Amount(),
confHeight: kid.ConfHeight(),
maturityRequirement: kid.BlocksToMaturity(),
stage: 1,
})
}
// AddLimboStage2Htlc adds an htlc kindergarten output to the maturity report's
// htlcs, and contributes its amount to the limbo balance.
func (c *contractMaturityReport) AddLimboStage2Htlc(kid *kidOutput) {
c.limboBalance += kid.Amount()
htlcReport := htlcMaturityReport{
outpoint: *kid.OutPoint(),
amount: kid.Amount(),
confHeight: kid.ConfHeight(),
maturityRequirement: kid.BlocksToMaturity(),
stage: 2,
}
// If the confirmation height is set, then this means the first stage
// has been confirmed, and we know the final maturity height of the CSV
// delay.
if kid.ConfHeight() != 0 {
htlcReport.maturityHeight = kid.ConfHeight() + kid.BlocksToMaturity()
}
c.htlcs = append(c.htlcs, htlcReport)
}
// AddRecoveredHtlc adds an graduate output to the maturity report's htlcs, and
// contributes its amount to the recovered balance.
func (c *contractMaturityReport) AddRecoveredHtlc(kid *kidOutput) {
c.recoveredBalance += kid.Amount()
c.htlcs = append(c.htlcs, htlcMaturityReport{
outpoint: *kid.OutPoint(),
amount: kid.Amount(),
confHeight: kid.ConfHeight(),
maturityRequirement: kid.BlocksToMaturity(),
maturityHeight: kid.ConfHeight() + kid.BlocksToMaturity(),
})
}
// closeAndRemoveIfMature removes a particular channel from the channel index
// if and only if all of its outputs have been marked graduated. If the channel
// still has ungraduated outputs, the method will succeed without altering the
// database state.
func (u *utxoNursery) closeAndRemoveIfMature(chanPoint *wire.OutPoint) error {
isMature, err := u.cfg.Store.IsMatureChannel(chanPoint)
if err == ErrContractNotFound {
return nil
} else if err != nil {
utxnLog.Errorf("Unable to determine maturity of "+
"channel=%s", chanPoint)
return err
}
// Nothing to do if we are still incubating.
if !isMature {
return nil
}
// Now that the channel is fully closed, we remove the channel from the
// nursery store here. This preserves the invariant that we never remove
// a channel unless it is mature, as this is the only place the utxo
// nursery removes a channel.
if err := u.cfg.Store.RemoveChannel(chanPoint); err != nil {
utxnLog.Errorf("Unable to remove channel=%s from "+
"nursery store: %v", chanPoint, err)
return err
}
utxnLog.Infof("Removed channel %v from nursery store", chanPoint)
return nil
}
// newSweepPkScript creates a new public key script which should be used to
// sweep any time-locked, or contested channel funds into the wallet.
// Specifically, the script generated is a version 0, pay-to-witness-pubkey-hash
// (p2wkh) output.
func newSweepPkScript(wallet lnwallet.WalletController) ([]byte, error) {
sweepAddr, err := wallet.NewAddress(lnwallet.WitnessPubKey, false)
if err != nil {
return nil, err
}
return txscript.PayToAddrScript(sweepAddr)
}
// CsvSpendableOutput is a SpendableOutput that contains all of the information
// necessary to construct, sign, and sweep an output locked with a CSV delay.
type CsvSpendableOutput interface {
SpendableOutput
// ConfHeight returns the height at which this output was confirmed.
// A zero value indicates that the output has not been confirmed.
ConfHeight() uint32
// SetConfHeight marks the height at which the output is confirmed in
// the chain.
SetConfHeight(height uint32)
// BlocksToMaturity returns the relative timelock, as a number of
// blocks, that must be built on top of the confirmation height before
// the output can be spent.
BlocksToMaturity() uint32
// OriginChanPoint returns the outpoint of the channel from which this
// output is derived.
OriginChanPoint() *wire.OutPoint
}
// babyOutput represents a two-stage CSV locked output, and is used to track
// htlc outputs through incubation. The first stage requires broadcasting a
// presigned timeout txn that spends from the CLTV locked output on the
// commitment txn. A babyOutput is treated as a subset of CsvSpendableOutputs,
// with the additional constraint that a transaction must be broadcast before
// it can be spent. Each baby transaction embeds the kidOutput that can later
// be used to spend the CSV output contained in the timeout txn.
//
// TODO(roasbeef): re-rename to timeout tx
// * create CltvCsvSpendableOutput
type babyOutput struct {
// expiry is the absolute block height at which the secondLevelTx
// should be broadcast to the network.
//
// NOTE: This value will be zero if this is a baby output for a prior
// incoming HTLC.
expiry uint32
// timeoutTx is a fully-signed transaction that, upon confirmation,
// transitions the htlc into the delay+claim stage.
timeoutTx *wire.MsgTx
// kidOutput represents the CSV output to be swept from the
// secondLevelTx after it has been broadcast and confirmed.
kidOutput
}
// makeBabyOutput constructs a baby output that wraps a future kidOutput. The
// provided sign descriptors and witness types will be used once the output
// reaches the delay and claim stage.
func makeBabyOutput(chanPoint *wire.OutPoint,
htlcResolution *lnwallet.OutgoingHtlcResolution) babyOutput {
htlcOutpoint := htlcResolution.ClaimOutpoint
blocksToMaturity := htlcResolution.CsvDelay
witnessType := lnwallet.HtlcOfferedTimeoutSecondLevel
kid := makeKidOutput(
&htlcOutpoint, chanPoint, blocksToMaturity, witnessType,
&htlcResolution.SweepSignDesc, 0,
)
return babyOutput{
kidOutput: kid,
expiry: htlcResolution.Expiry,
timeoutTx: htlcResolution.SignedTimeoutTx,
}
}
// Encode writes the baby output to the given io.Writer.
func (bo *babyOutput) Encode(w io.Writer) error {
var scratch [4]byte
byteOrder.PutUint32(scratch[:], bo.expiry)
if _, err := w.Write(scratch[:]); err != nil {
return err
}
if err := bo.timeoutTx.Serialize(w); err != nil {
return err
}
return bo.kidOutput.Encode(w)
}
// Decode reconstructs a baby output using the provided io.Reader.
func (bo *babyOutput) Decode(r io.Reader) error {
var scratch [4]byte
if _, err := r.Read(scratch[:]); err != nil {
return err
}
bo.expiry = byteOrder.Uint32(scratch[:])
bo.timeoutTx = new(wire.MsgTx)
if err := bo.timeoutTx.Deserialize(r); err != nil {
return err
}
return bo.kidOutput.Decode(r)
}
// kidOutput represents an output that's waiting for a required blockheight
// before its funds will be available to be moved into the user's wallet. The
// struct includes a WitnessGenerator closure which will be used to generate
// the witness required to sweep the output once it's mature.
//
// TODO(roasbeef): rename to immatureOutput?
type kidOutput struct {
breachedOutput
originChanPoint wire.OutPoint
// isHtlc denotes if this kid output is an HTLC output or not. This
// value will be used to determine how to report this output within the
// nursery report.
isHtlc bool
// blocksToMaturity is the relative CSV delay required after initial
// confirmation of the commitment transaction before we can sweep this
// output.
//
// NOTE: This will be set for: commitment outputs, and incoming HTLC's.
// Otherwise, this will be zero.
blocksToMaturity uint32
// absoluteMaturity is the absolute height that this output will be
// mature at. In order to sweep the output after this height, the
// locktime of sweep transaction will need to be set to this value.
//
// NOTE: This will only be set for: outgoing HTLC's on the commitment
// transaction of the remote party.
absoluteMaturity uint32
confHeight uint32
}
func makeKidOutput(outpoint, originChanPoint *wire.OutPoint,
blocksToMaturity uint32, witnessType lnwallet.WitnessType,
signDescriptor *lnwallet.SignDescriptor,
absoluteMaturity uint32) kidOutput {
// This is an HTLC either if it's an incoming HTLC on our commitment
// transaction, or is an outgoing HTLC on the commitment transaction of
// the remote peer.
isHtlc := (witnessType == lnwallet.HtlcAcceptedSuccessSecondLevel ||
witnessType == lnwallet.HtlcOfferedRemoteTimeout)
return kidOutput{
breachedOutput: makeBreachedOutput(
outpoint, witnessType, nil, signDescriptor,
),
isHtlc: isHtlc,
originChanPoint: *originChanPoint,
blocksToMaturity: blocksToMaturity,
absoluteMaturity: absoluteMaturity,
}
}
func (k *kidOutput) OriginChanPoint() *wire.OutPoint {
return &k.originChanPoint
}
func (k *kidOutput) BlocksToMaturity() uint32 {
return k.blocksToMaturity
}
func (k *kidOutput) SetConfHeight(height uint32) {
k.confHeight = height
}
func (k *kidOutput) ConfHeight() uint32 {
return k.confHeight
}
// Encode converts a KidOutput struct into a form suitable for on-disk database
// storage. Note that the signDescriptor struct field is included so that the
// output's witness can be generated by createSweepTx() when the output becomes
// spendable.
func (k *kidOutput) Encode(w io.Writer) error {
var scratch [8]byte
byteOrder.PutUint64(scratch[:], uint64(k.Amount()))
if _, err := w.Write(scratch[:]); err != nil {
return err
}
if err := writeOutpoint(w, k.OutPoint()); err != nil {
return err
}
if err := writeOutpoint(w, k.OriginChanPoint()); err != nil {
return err
}
if err := binary.Write(w, byteOrder, k.isHtlc); err != nil {
return err
}
byteOrder.PutUint32(scratch[:4], k.BlocksToMaturity())
if _, err := w.Write(scratch[:4]); err != nil {
return err
}
byteOrder.PutUint32(scratch[:4], k.absoluteMaturity)
if _, err := w.Write(scratch[:4]); err != nil {
return err
}
byteOrder.PutUint32(scratch[:4], k.ConfHeight())
if _, err := w.Write(scratch[:4]); err != nil {
return err
}
byteOrder.PutUint16(scratch[:2], uint16(k.WitnessType()))
if _, err := w.Write(scratch[:2]); err != nil {
return err
}
return lnwallet.WriteSignDescriptor(w, k.SignDesc())
}
// Decode takes a byte array representation of a kidOutput and converts it to an
// struct. Note that the witnessFunc method isn't added during deserialization
// and must be added later based on the value of the witnessType field.
func (k *kidOutput) Decode(r io.Reader) error {
var scratch [8]byte
if _, err := r.Read(scratch[:]); err != nil {
return err
}
k.amt = btcutil.Amount(byteOrder.Uint64(scratch[:]))
if err := readOutpoint(io.LimitReader(r, 40), &k.outpoint); err != nil {
return err
}
err := readOutpoint(io.LimitReader(r, 40), &k.originChanPoint)
if err != nil {
return err
}
if err := binary.Read(r, byteOrder, &k.isHtlc); err != nil {
return err
}
if _, err := r.Read(scratch[:4]); err != nil {
return err
}
k.blocksToMaturity = byteOrder.Uint32(scratch[:4])
if _, err := r.Read(scratch[:4]); err != nil {
return err
}
k.absoluteMaturity = byteOrder.Uint32(scratch[:4])
if _, err := r.Read(scratch[:4]); err != nil {
return err
}
k.confHeight = byteOrder.Uint32(scratch[:4])
if _, err := r.Read(scratch[:2]); err != nil {
return err
}
k.witnessType = lnwallet.WitnessType(byteOrder.Uint16(scratch[:2]))
return lnwallet.ReadSignDescriptor(r, &k.signDesc)
}
// TODO(bvu): copied from channeldb, remove repetition
func writeOutpoint(w io.Writer, o *wire.OutPoint) error {
// TODO(roasbeef): make all scratch buffers on the stack
scratch := make([]byte, 4)
// TODO(roasbeef): write raw 32 bytes instead of wasting the extra
// byte.
if err := wire.WriteVarBytes(w, 0, o.Hash[:]); err != nil {
return err
}
byteOrder.PutUint32(scratch, o.Index)
_, err := w.Write(scratch)
return err
}
// TODO(bvu): copied from channeldb, remove repetition
func readOutpoint(r io.Reader, o *wire.OutPoint) error {
scratch := make([]byte, 4)
txid, err := wire.ReadVarBytes(r, 0, 32, "prevout")
if err != nil {
return err
}
copy(o.Hash[:], txid)
if _, err := r.Read(scratch); err != nil {
return err
}
o.Index = byteOrder.Uint32(scratch)
return nil
}
func writeTxOut(w io.Writer, txo *wire.TxOut) error {
scratch := make([]byte, 8)
byteOrder.PutUint64(scratch, uint64(txo.Value))
if _, err := w.Write(scratch); err != nil {
return err
}
if err := wire.WriteVarBytes(w, 0, txo.PkScript); err != nil {
return err
}
return nil
}
func readTxOut(r io.Reader, txo *wire.TxOut) error {
scratch := make([]byte, 8)
if _, err := r.Read(scratch); err != nil {
return err
}
txo.Value = int64(byteOrder.Uint64(scratch))
pkScript, err := wire.ReadVarBytes(r, 0, 80, "pkScript")
if err != nil {
return err
}
txo.PkScript = pkScript
return nil
}
// Compile-time constraint to ensure kidOutput and babyOutpt implement the
// CsvSpendableOutput interface.
var _ CsvSpendableOutput = (*kidOutput)(nil)
var _ CsvSpendableOutput = (*babyOutput)(nil)
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