lnd/sweep/sweeper.go
Oliver Gugger 55b53555e9
multi: improve readability of goroutine defers
This commit fixes the readability of some of the defer calls in
goroutines by making sure the defer stands out properly.
2022-11-21 13:54:24 +01:00

1638 lines
51 KiB
Go

package sweep
import (
"errors"
"fmt"
"math/rand"
"sort"
"sync"
"sync/atomic"
"time"
"github.com/btcsuite/btcd/btcutil"
"github.com/btcsuite/btcd/chaincfg/chainhash"
"github.com/btcsuite/btcd/wire"
"github.com/davecgh/go-spew/spew"
"github.com/lightningnetwork/lnd/chainntnfs"
"github.com/lightningnetwork/lnd/input"
"github.com/lightningnetwork/lnd/labels"
"github.com/lightningnetwork/lnd/lnwallet"
"github.com/lightningnetwork/lnd/lnwallet/chainfee"
)
const (
// DefaultMaxFeeRate is the default maximum fee rate allowed within the
// UtxoSweeper. The current value is equivalent to a fee rate of 10,000
// sat/vbyte.
DefaultMaxFeeRate = chainfee.FeePerKwFloor * 1e4
// DefaultFeeRateBucketSize is the default size of fee rate buckets
// we'll use when clustering inputs into buckets with similar fee rates
// within the UtxoSweeper.
//
// Given a minimum relay fee rate of 1 sat/vbyte, a multiplier of 10
// would result in the following fee rate buckets up to the maximum fee
// rate:
//
// #1: min = 1 sat/vbyte, max = 10 sat/vbyte
// #2: min = 11 sat/vbyte, max = 20 sat/vbyte...
DefaultFeeRateBucketSize = 10
)
var (
// ErrRemoteSpend is returned in case an output that we try to sweep is
// confirmed in a tx of the remote party.
ErrRemoteSpend = errors.New("remote party swept utxo")
// ErrTooManyAttempts is returned in case sweeping an output has failed
// for the configured max number of attempts.
ErrTooManyAttempts = errors.New("sweep failed after max attempts")
// ErrNoFeePreference is returned when we attempt to satisfy a sweep
// request from a client whom did not specify a fee preference.
ErrNoFeePreference = errors.New("no fee preference specified")
// ErrExclusiveGroupSpend is returned in case a different input of the
// same exclusive group was spent.
ErrExclusiveGroupSpend = errors.New("other member of exclusive group " +
"was spent")
// ErrSweeperShuttingDown is an error returned when a client attempts to
// make a request to the UtxoSweeper, but it is unable to handle it as
// it is/has already been stopped.
ErrSweeperShuttingDown = errors.New("utxo sweeper shutting down")
// DefaultMaxSweepAttempts specifies the default maximum number of times
// an input is included in a publish attempt before giving up and
// returning an error to the caller.
DefaultMaxSweepAttempts = 10
)
// Params contains the parameters that control the sweeping process.
type Params struct {
// Fee is the fee preference of the client who requested the input to be
// swept. If a confirmation target is specified, then we'll map it into
// a fee rate whenever we attempt to cluster inputs for a sweep.
Fee FeePreference
// Force indicates whether the input should be swept regardless of
// whether it is economical to do so.
Force bool
// ExclusiveGroup is an identifier that, if set, prevents other inputs
// with the same identifier from being batched together.
ExclusiveGroup *uint64
}
// ParamsUpdate contains a new set of parameters to update a pending sweep with.
type ParamsUpdate struct {
// Fee is the fee preference of the client who requested the input to be
// swept. If a confirmation target is specified, then we'll map it into
// a fee rate whenever we attempt to cluster inputs for a sweep.
Fee FeePreference
// Force indicates whether the input should be swept regardless of
// whether it is economical to do so.
Force bool
}
// String returns a human readable interpretation of the sweep parameters.
func (p Params) String() string {
return fmt.Sprintf("fee=%v, force=%v, exclusive_group=%v",
p.Fee, p.Force, p.ExclusiveGroup)
}
// pendingInput is created when an input reaches the main loop for the first
// time. It wraps the input and tracks all relevant state that is needed for
// sweeping.
type pendingInput struct {
input.Input
// listeners is a list of channels over which the final outcome of the
// sweep needs to be broadcasted.
listeners []chan Result
// ntfnRegCancel is populated with a function that cancels the chain
// notifier spend registration.
ntfnRegCancel func()
// minPublishHeight indicates the minimum block height at which this
// input may be (re)published.
minPublishHeight int32
// publishAttempts records the number of attempts that have already been
// made to sweep this tx.
publishAttempts int
// params contains the parameters that control the sweeping process.
params Params
// lastFeeRate is the most recent fee rate used for this input within a
// transaction broadcast to the network.
lastFeeRate chainfee.SatPerKWeight
}
// parameters returns the sweep parameters for this input.
//
// NOTE: Part of the txInput interface.
func (p *pendingInput) parameters() Params {
return p.params
}
// pendingInputs is a type alias for a set of pending inputs.
type pendingInputs = map[wire.OutPoint]*pendingInput
// inputCluster is a helper struct to gather a set of pending inputs that should
// be swept with the specified fee rate.
type inputCluster struct {
lockTime *uint32
sweepFeeRate chainfee.SatPerKWeight
inputs pendingInputs
}
// pendingSweepsReq is an internal message we'll use to represent an external
// caller's intent to retrieve all of the pending inputs the UtxoSweeper is
// attempting to sweep.
type pendingSweepsReq struct {
respChan chan map[wire.OutPoint]*PendingInput
errChan chan error
}
// PendingInput contains information about an input that is currently being
// swept by the UtxoSweeper.
type PendingInput struct {
// OutPoint is the identify outpoint of the input being swept.
OutPoint wire.OutPoint
// WitnessType is the witness type of the input being swept.
WitnessType input.WitnessType
// Amount is the amount of the input being swept.
Amount btcutil.Amount
// LastFeeRate is the most recent fee rate used for the input being
// swept within a transaction broadcast to the network.
LastFeeRate chainfee.SatPerKWeight
// BroadcastAttempts is the number of attempts we've made to sweept the
// input.
BroadcastAttempts int
// NextBroadcastHeight is the next height of the chain at which we'll
// attempt to broadcast a transaction sweeping the input.
NextBroadcastHeight uint32
// Params contains the sweep parameters for this pending request.
Params Params
}
// updateReq is an internal message we'll use to represent an external caller's
// intent to update the sweep parameters of a given input.
type updateReq struct {
input wire.OutPoint
params ParamsUpdate
responseChan chan *updateResp
}
// updateResp is an internal message we'll use to hand off the response of a
// updateReq from the UtxoSweeper's main event loop back to the caller.
type updateResp struct {
resultChan chan Result
err error
}
// UtxoSweeper is responsible for sweeping outputs back into the wallet
type UtxoSweeper struct {
started uint32 // To be used atomically.
stopped uint32 // To be used atomically.
cfg *UtxoSweeperConfig
newInputs chan *sweepInputMessage
spendChan chan *chainntnfs.SpendDetail
// pendingSweepsReq is a channel that will be sent requests by external
// callers in order to retrieve the set of pending inputs the
// UtxoSweeper is attempting to sweep.
pendingSweepsReqs chan *pendingSweepsReq
// updateReqs is a channel that will be sent requests by external
// callers who wish to bump the fee rate of a given input.
updateReqs chan *updateReq
// pendingInputs is the total set of inputs the UtxoSweeper has been
// requested to sweep.
pendingInputs pendingInputs
// timer is the channel that signals expiry of the sweep batch timer.
timer <-chan time.Time
testSpendChan chan wire.OutPoint
currentOutputScript []byte
relayFeeRate chainfee.SatPerKWeight
quit chan struct{}
wg sync.WaitGroup
}
// UtxoSweeperConfig contains dependencies of UtxoSweeper.
type UtxoSweeperConfig struct {
// GenSweepScript generates a P2WKH script belonging to the wallet where
// funds can be swept.
GenSweepScript func() ([]byte, error)
// FeeEstimator is used when crafting sweep transactions to estimate
// the necessary fee relative to the expected size of the sweep
// transaction.
FeeEstimator chainfee.Estimator
// Wallet contains the wallet functions that sweeper requires.
Wallet Wallet
// NewBatchTimer creates a channel that will be sent on when a certain
// time window has passed. During this time window, new inputs can still
// be added to the sweep tx that is about to be generated.
NewBatchTimer func() <-chan time.Time
// Notifier is an instance of a chain notifier we'll use to watch for
// certain on-chain events.
Notifier chainntnfs.ChainNotifier
// Store stores the published sweeper txes.
Store SweeperStore
// Signer is used by the sweeper to generate valid witnesses at the
// time the incubated outputs need to be spent.
Signer input.Signer
// MaxInputsPerTx specifies the default maximum number of inputs allowed
// in a single sweep tx. If more need to be swept, multiple txes are
// created and published.
MaxInputsPerTx int
// MaxSweepAttempts specifies the maximum number of times an input is
// included in a publish attempt before giving up and returning an error
// to the caller.
MaxSweepAttempts int
// NextAttemptDeltaFunc returns given the number of already attempted
// sweeps, how many blocks to wait before retrying to sweep.
NextAttemptDeltaFunc func(int) int32
// MaxFeeRate is the the maximum fee rate allowed within the
// UtxoSweeper.
MaxFeeRate chainfee.SatPerKWeight
// FeeRateBucketSize is the default size of fee rate buckets we'll use
// when clustering inputs into buckets with similar fee rates within the
// UtxoSweeper.
//
// Given a minimum relay fee rate of 1 sat/vbyte, a fee rate bucket size
// of 10 would result in the following fee rate buckets up to the
// maximum fee rate:
//
// #1: min = 1 sat/vbyte, max (exclusive) = 11 sat/vbyte
// #2: min = 11 sat/vbyte, max (exclusive) = 21 sat/vbyte...
FeeRateBucketSize int
}
// Result is the struct that is pushed through the result channel. Callers can
// use this to be informed of the final sweep result. In case of a remote
// spend, Err will be ErrRemoteSpend.
type Result struct {
// Err is the final result of the sweep. It is nil when the input is
// swept successfully by us. ErrRemoteSpend is returned when another
// party took the input.
Err error
// Tx is the transaction that spent the input.
Tx *wire.MsgTx
}
// sweepInputMessage structs are used in the internal channel between the
// SweepInput call and the sweeper main loop.
type sweepInputMessage struct {
input input.Input
params Params
resultChan chan Result
}
// New returns a new Sweeper instance.
func New(cfg *UtxoSweeperConfig) *UtxoSweeper {
return &UtxoSweeper{
cfg: cfg,
newInputs: make(chan *sweepInputMessage),
spendChan: make(chan *chainntnfs.SpendDetail),
updateReqs: make(chan *updateReq),
pendingSweepsReqs: make(chan *pendingSweepsReq),
quit: make(chan struct{}),
pendingInputs: make(pendingInputs),
}
}
// Start starts the process of constructing and publish sweep txes.
func (s *UtxoSweeper) Start() error {
if !atomic.CompareAndSwapUint32(&s.started, 0, 1) {
return nil
}
log.Info("Sweeper starting")
// Retrieve last published tx from database.
lastTx, err := s.cfg.Store.GetLastPublishedTx()
if err != nil {
return fmt.Errorf("get last published tx: %v", err)
}
// Republish in case the previous call crashed lnd. We don't care about
// the return value, because inputs will be re-offered and retried
// anyway. The only reason we republish here is to prevent the corner
// case where lnd goes into a restart loop because of a crashing publish
// tx where we keep deriving new output script. By publishing and
// possibly crashing already now, we haven't derived a new output script
// yet.
if lastTx != nil {
log.Debugf("Publishing last tx %v", lastTx.TxHash())
// Error can be ignored. Because we are starting up, there are
// no pending inputs to update based on the publish result.
err := s.cfg.Wallet.PublishTransaction(lastTx, "")
if err != nil && err != lnwallet.ErrDoubleSpend {
log.Errorf("last tx publish: %v", err)
}
}
// Retrieve relay fee for dust limit calculation. Assume that this will
// not change from here on.
s.relayFeeRate = s.cfg.FeeEstimator.RelayFeePerKW()
// We need to register for block epochs and retry sweeping every block.
// We should get a notification with the current best block immediately
// if we don't provide any epoch. We'll wait for that in the collector.
blockEpochs, err := s.cfg.Notifier.RegisterBlockEpochNtfn(nil)
if err != nil {
return fmt.Errorf("register block epoch ntfn: %v", err)
}
// Start sweeper main loop.
s.wg.Add(1)
go func() {
defer blockEpochs.Cancel()
defer s.wg.Done()
s.collector(blockEpochs.Epochs)
// The collector exited and won't longer handle incoming
// requests. This can happen on shutdown, when the block
// notifier shuts down before the sweeper and its clients. In
// order to not deadlock the clients waiting for their requests
// being handled, we handle them here and immediately return an
// error. When the sweeper finally is shut down we can exit as
// the clients will be notified.
for {
select {
case inp := <-s.newInputs:
inp.resultChan <- Result{
Err: ErrSweeperShuttingDown,
}
case req := <-s.pendingSweepsReqs:
req.errChan <- ErrSweeperShuttingDown
case req := <-s.updateReqs:
req.responseChan <- &updateResp{
err: ErrSweeperShuttingDown,
}
case <-s.quit:
return
}
}
}()
return nil
}
// RelayFeePerKW returns the minimum fee rate required for transactions to be
// relayed.
func (s *UtxoSweeper) RelayFeePerKW() chainfee.SatPerKWeight {
return s.relayFeeRate
}
// Stop stops sweeper from listening to block epochs and constructing sweep
// txes.
func (s *UtxoSweeper) Stop() error {
if !atomic.CompareAndSwapUint32(&s.stopped, 0, 1) {
return nil
}
log.Info("Sweeper shutting down")
close(s.quit)
s.wg.Wait()
log.Debugf("Sweeper shut down")
return nil
}
// SweepInput sweeps inputs back into the wallet. The inputs will be batched and
// swept after the batch time window ends. A custom fee preference can be
// provided to determine what fee rate should be used for the input. Note that
// the input may not always be swept with this exact value, as its possible for
// it to be batched under the same transaction with other similar fee rate
// inputs.
//
// NOTE: Extreme care needs to be taken that input isn't changed externally.
// Because it is an interface and we don't know what is exactly behind it, we
// cannot make a local copy in sweeper.
func (s *UtxoSweeper) SweepInput(input input.Input,
params Params) (chan Result, error) {
if input == nil || input.OutPoint() == nil || input.SignDesc() == nil {
return nil, errors.New("nil input received")
}
// Ensure the client provided a sane fee preference.
if _, err := s.feeRateForPreference(params.Fee); err != nil {
return nil, err
}
absoluteTimeLock, _ := input.RequiredLockTime()
log.Infof("Sweep request received: out_point=%v, witness_type=%v, "+
"relative_time_lock=%v, absolute_time_lock=%v, amount=%v, "+
"params=(%v)", input.OutPoint(), input.WitnessType(),
input.BlocksToMaturity(), absoluteTimeLock,
btcutil.Amount(input.SignDesc().Output.Value), params)
sweeperInput := &sweepInputMessage{
input: input,
params: params,
resultChan: make(chan Result, 1),
}
// Deliver input to the main event loop.
select {
case s.newInputs <- sweeperInput:
case <-s.quit:
return nil, ErrSweeperShuttingDown
}
return sweeperInput.resultChan, nil
}
// feeRateForPreference returns a fee rate for the given fee preference. It
// ensures that the fee rate respects the bounds of the UtxoSweeper.
func (s *UtxoSweeper) feeRateForPreference(
feePreference FeePreference) (chainfee.SatPerKWeight, error) {
// Ensure a type of fee preference is specified to prevent using a
// default below.
if feePreference.FeeRate == 0 && feePreference.ConfTarget == 0 {
return 0, ErrNoFeePreference
}
feeRate, err := DetermineFeePerKw(s.cfg.FeeEstimator, feePreference)
if err != nil {
return 0, err
}
if feeRate < s.relayFeeRate {
return 0, fmt.Errorf("fee preference resulted in invalid fee "+
"rate %v, minimum is %v", feeRate, s.relayFeeRate)
}
if feeRate > s.cfg.MaxFeeRate {
return 0, fmt.Errorf("fee preference resulted in invalid fee "+
"rate %v, maximum is %v", feeRate, s.cfg.MaxFeeRate)
}
return feeRate, nil
}
// removeLastSweepDescendants removes any transactions from the wallet that
// spend outputs produced by the passed spendingTx. This needs to be done in
// cases where we're not the only ones that can sweep an output, but there may
// exist unconfirmed spends that spend outputs created by a sweep transaction.
// The most common case for this is when someone sweeps our anchor outputs
// after 16 blocks.
func (s *UtxoSweeper) removeLastSweepDescendants(spendingTx *wire.MsgTx) error {
// Obtain all the past sweeps that we've done so far. We'll need these
// to ensure that if the spendingTx spends any of the same inputs, then
// we remove any transaction that may be spending those inputs from the
// wallet.
//
// TODO(roasbeef): can be last sweep here if we remove anything confirmed
// from the store?
pastSweepHashes, err := s.cfg.Store.ListSweeps()
if err != nil {
return err
}
log.Debugf("Attempting to remove descendant txns invalidated by "+
"(txid=%v): %v", spendingTx.TxHash(), spew.Sdump(spendingTx))
// Construct a map of the inputs this transaction spends for each look
// up.
inputsSpent := make(map[wire.OutPoint]struct{}, len(spendingTx.TxIn))
for _, txIn := range spendingTx.TxIn {
inputsSpent[txIn.PreviousOutPoint] = struct{}{}
}
// We'll now go through each past transaction we published during this
// epoch and cross reference the spent inputs. If there're any inputs
// in common with the inputs the spendingTx spent, then we'll remove
// those.
//
// TODO(roasbeef): need to start to remove all transaction hashes after
// every N blocks (assumed point of no return)
for _, sweepHash := range pastSweepHashes {
sweepTx, err := s.cfg.Wallet.FetchTx(sweepHash)
if err != nil {
return err
}
// Transaction wasn't found in the wallet, may have already
// been replaced/removed.
if sweepTx == nil {
continue
}
// Check to see if this past sweep transaction spent any of the
// same inputs as spendingTx.
var isConflicting bool
for _, txIn := range sweepTx.TxIn {
if _, ok := inputsSpent[txIn.PreviousOutPoint]; ok {
isConflicting = true
break
}
}
// If it did, then we'll signal the wallet to remove all the
// transactions that are descendants of outputs created by the
// sweepTx.
if isConflicting {
log.Debugf("Removing sweep txid=%v from wallet: %v",
sweepTx.TxHash(), spew.Sdump(sweepTx))
err := s.cfg.Wallet.RemoveDescendants(sweepTx)
if err != nil {
log.Warnf("unable to remove descendants: %v", err)
}
}
}
return nil
}
// collector is the sweeper main loop. It processes new inputs, spend
// notifications and counts down to publication of the sweep tx.
func (s *UtxoSweeper) collector(blockEpochs <-chan *chainntnfs.BlockEpoch) {
// We registered for the block epochs with a nil request. The notifier
// should send us the current best block immediately. So we need to wait
// for it here because we need to know the current best height.
var bestHeight int32
select {
case bestBlock := <-blockEpochs:
bestHeight = bestBlock.Height
case <-s.quit:
return
}
for {
select {
// A new inputs is offered to the sweeper. We check to see if we
// are already trying to sweep this input and if not, set up a
// listener to spend and schedule a sweep.
case input := <-s.newInputs:
outpoint := *input.input.OutPoint()
pendInput, pending := s.pendingInputs[outpoint]
if pending {
log.Debugf("Already pending input %v received",
outpoint)
// Before updating the input details, check if
// an exclusive group was set, and if so, assume
// this input as finalized and remove all other
// inputs belonging to the same exclusive group.
var prevExclGroup *uint64
if pendInput.params.ExclusiveGroup != nil &&
input.params.ExclusiveGroup == nil {
prevExclGroup = new(uint64)
*prevExclGroup = *pendInput.params.ExclusiveGroup
}
// Update input details and sweep parameters.
// The re-offered input details may contain a
// change to the unconfirmed parent tx info.
pendInput.params = input.params
pendInput.Input = input.input
// Add additional result channel to signal
// spend of this input.
pendInput.listeners = append(
pendInput.listeners, input.resultChan,
)
if prevExclGroup != nil {
s.removeExclusiveGroup(*prevExclGroup)
}
continue
}
// Create a new pendingInput and initialize the
// listeners slice with the passed in result channel. If
// this input is offered for sweep again, the result
// channel will be appended to this slice.
pendInput = &pendingInput{
listeners: []chan Result{input.resultChan},
Input: input.input,
minPublishHeight: bestHeight,
params: input.params,
}
s.pendingInputs[outpoint] = pendInput
log.Tracef("input %v added to pendingInputs", outpoint)
// Start watching for spend of this input, either by us
// or the remote party.
cancel, err := s.waitForSpend(
outpoint,
input.input.SignDesc().Output.PkScript,
input.input.HeightHint(),
)
if err != nil {
err := fmt.Errorf("wait for spend: %v", err)
s.signalAndRemove(&outpoint, Result{Err: err})
continue
}
pendInput.ntfnRegCancel = cancel
// Check to see if with this new input a sweep tx can be
// formed.
if err := s.scheduleSweep(bestHeight); err != nil {
log.Errorf("schedule sweep: %v", err)
}
log.Tracef("input %v scheduled", outpoint)
// A spend of one of our inputs is detected. Signal sweep
// results to the caller(s).
case spend := <-s.spendChan:
// For testing purposes.
if s.testSpendChan != nil {
s.testSpendChan <- *spend.SpentOutPoint
}
// Query store to find out if we ever published this
// tx.
spendHash := *spend.SpenderTxHash
isOurTx, err := s.cfg.Store.IsOurTx(spendHash)
if err != nil {
log.Errorf("cannot determine if tx %v "+
"is ours: %v", spendHash, err,
)
continue
}
// If this isn't our transaction, it means someone else
// swept outputs that we were attempting to sweep. This
// can happen for anchor outputs as well as justice
// transactions. In this case, we'll notify the wallet
// to remove any spends that a descent from this
// output.
if !isOurTx {
err := s.removeLastSweepDescendants(
spend.SpendingTx,
)
if err != nil {
log.Warnf("unable to remove descendant "+
"transactions due to tx %v: ",
spendHash)
}
log.Debugf("Detected spend related to in flight inputs "+
"(is_ours=%v): %v",
newLogClosure(func() string {
return spew.Sdump(spend.SpendingTx)
}), isOurTx,
)
}
// Signal sweep results for inputs in this confirmed
// tx.
for _, txIn := range spend.SpendingTx.TxIn {
outpoint := txIn.PreviousOutPoint
// Check if this input is known to us. It could
// probably be unknown if we canceled the
// registration, deleted from pendingInputs but
// the ntfn was in-flight already. Or this could
// be not one of our inputs.
input, ok := s.pendingInputs[outpoint]
if !ok {
continue
}
// Return either a nil or a remote spend result.
var err error
if !isOurTx {
err = ErrRemoteSpend
}
// Signal result channels.
s.signalAndRemove(&outpoint, Result{
Tx: spend.SpendingTx,
Err: err,
})
// Remove all other inputs in this exclusive
// group.
if input.params.ExclusiveGroup != nil {
s.removeExclusiveGroup(
*input.params.ExclusiveGroup,
)
}
}
// Now that an input of ours is spent, we can try to
// resweep the remaining inputs.
if err := s.scheduleSweep(bestHeight); err != nil {
log.Errorf("schedule sweep: %v", err)
}
// A new external request has been received to retrieve all of
// the inputs we're currently attempting to sweep.
case req := <-s.pendingSweepsReqs:
req.respChan <- s.handlePendingSweepsReq(req)
// A new external request has been received to bump the fee rate
// of a given input.
case req := <-s.updateReqs:
resultChan, err := s.handleUpdateReq(req, bestHeight)
req.responseChan <- &updateResp{
resultChan: resultChan,
err: err,
}
// The timer expires and we are going to (re)sweep.
case <-s.timer:
log.Debugf("Sweep timer expired")
// Set timer to nil so we know that a new timer needs to
// be started when new inputs arrive.
s.timer = nil
// We'll attempt to cluster all of our inputs with
// similar fee rates. Before attempting to sweep them,
// we'll sort them in descending fee rate order. We do
// this to ensure any inputs which have had their fee
// rate bumped are broadcast first in order enforce the
// RBF policy.
inputClusters := s.createInputClusters()
sort.Slice(inputClusters, func(i, j int) bool {
return inputClusters[i].sweepFeeRate >
inputClusters[j].sweepFeeRate
})
for _, cluster := range inputClusters {
err := s.sweepCluster(cluster, bestHeight)
if err != nil {
log.Errorf("input cluster sweep: %v",
err)
}
}
// A new block comes in. Things may have changed, so we retry a
// sweep.
case epoch, ok := <-blockEpochs:
if !ok {
return
}
bestHeight = epoch.Height
log.Debugf("New block: height=%v, sha=%v",
epoch.Height, epoch.Hash)
if err := s.scheduleSweep(bestHeight); err != nil {
log.Errorf("schedule sweep: %v", err)
}
case <-s.quit:
return
}
}
}
// removeExclusiveGroup removes all inputs in the given exclusive group. This
// function is called when one of the exclusive group inputs has been spent. The
// other inputs won't ever be spendable and can be removed. This also prevents
// them from being part of future sweep transactions that would fail.
func (s *UtxoSweeper) removeExclusiveGroup(group uint64) {
for outpoint, input := range s.pendingInputs {
outpoint := outpoint
// Skip inputs that aren't exclusive.
if input.params.ExclusiveGroup == nil {
continue
}
// Skip inputs from other exclusive groups.
if *input.params.ExclusiveGroup != group {
continue
}
// Signal result channels.
s.signalAndRemove(&outpoint, Result{
Err: ErrExclusiveGroupSpend,
})
}
}
// sweepCluster tries to sweep the given input cluster.
func (s *UtxoSweeper) sweepCluster(cluster inputCluster,
currentHeight int32) error {
// Execute the sweep within a coin select lock. Otherwise the coins that
// we are going to spend may be selected for other transactions like
// funding of a channel.
return s.cfg.Wallet.WithCoinSelectLock(func() error {
// Examine pending inputs and try to construct
// lists of inputs.
inputLists, err := s.getInputLists(cluster, currentHeight)
if err != nil {
return fmt.Errorf("unable to examine pending inputs: %v", err)
}
// Sweep selected inputs.
for _, inputs := range inputLists {
err := s.sweep(inputs, cluster.sweepFeeRate, currentHeight)
if err != nil {
return fmt.Errorf("unable to sweep inputs: %v", err)
}
}
return nil
})
}
// bucketForFeeReate determines the proper bucket for a fee rate. This is done
// in order to batch inputs with similar fee rates together.
func (s *UtxoSweeper) bucketForFeeRate(
feeRate chainfee.SatPerKWeight) int {
// Create an isolated bucket for sweeps at the minimum fee rate. This is
// to prevent very small outputs (anchors) from becoming uneconomical if
// their fee rate would be averaged with higher fee rate inputs in a
// regular bucket.
if feeRate == s.relayFeeRate {
return 0
}
return 1 + int(feeRate-s.relayFeeRate)/s.cfg.FeeRateBucketSize
}
// createInputClusters creates a list of input clusters from the set of pending
// inputs known by the UtxoSweeper. It clusters inputs by
// 1) Required tx locktime
// 2) Similar fee rates.
func (s *UtxoSweeper) createInputClusters() []inputCluster {
inputs := s.pendingInputs
// We start by getting the inputs clusters by locktime. Since the
// inputs commit to the locktime, they can only be clustered together
// if the locktime is equal.
lockTimeClusters, nonLockTimeInputs := s.clusterByLockTime(inputs)
// Cluster the the remaining inputs by sweep fee rate.
feeClusters := s.clusterBySweepFeeRate(nonLockTimeInputs)
// Since the inputs that we clustered by fee rate don't commit to a
// specific locktime, we can try to merge a locktime cluster with a fee
// cluster.
return zipClusters(lockTimeClusters, feeClusters)
}
// clusterByLockTime takes the given set of pending inputs and clusters those
// with equal locktime together. Each cluster contains a sweep fee rate, which
// is determined by calculating the average fee rate of all inputs within that
// cluster. In addition to the created clusters, inputs that did not specify a
// required lock time are returned.
func (s *UtxoSweeper) clusterByLockTime(inputs pendingInputs) ([]inputCluster,
pendingInputs) {
locktimes := make(map[uint32]pendingInputs)
inputFeeRates := make(map[wire.OutPoint]chainfee.SatPerKWeight)
rem := make(pendingInputs)
// Go through all inputs and check if they require a certain locktime.
for op, input := range inputs {
lt, ok := input.RequiredLockTime()
if !ok {
rem[op] = input
continue
}
// Check if we already have inputs with this locktime.
p, ok := locktimes[lt]
if !ok {
p = make(pendingInputs)
}
p[op] = input
locktimes[lt] = p
// We also get the preferred fee rate for this input.
feeRate, err := s.feeRateForPreference(input.params.Fee)
if err != nil {
log.Warnf("Skipping input %v: %v", op, err)
continue
}
input.lastFeeRate = feeRate
inputFeeRates[op] = feeRate
}
// We'll then determine the sweep fee rate for each set of inputs by
// calculating the average fee rate of the inputs within each set.
inputClusters := make([]inputCluster, 0, len(locktimes))
for lt, inputs := range locktimes {
lt := lt
var sweepFeeRate chainfee.SatPerKWeight
for op := range inputs {
sweepFeeRate += inputFeeRates[op]
}
sweepFeeRate /= chainfee.SatPerKWeight(len(inputs))
inputClusters = append(inputClusters, inputCluster{
lockTime: &lt,
sweepFeeRate: sweepFeeRate,
inputs: inputs,
})
}
return inputClusters, rem
}
// clusterBySweepFeeRate takes the set of pending inputs within the UtxoSweeper
// and clusters those together with similar fee rates. Each cluster contains a
// sweep fee rate, which is determined by calculating the average fee rate of
// all inputs within that cluster.
func (s *UtxoSweeper) clusterBySweepFeeRate(inputs pendingInputs) []inputCluster {
bucketInputs := make(map[int]*bucketList)
inputFeeRates := make(map[wire.OutPoint]chainfee.SatPerKWeight)
// First, we'll group together all inputs with similar fee rates. This
// is done by determining the fee rate bucket they should belong in.
for op, input := range inputs {
feeRate, err := s.feeRateForPreference(input.params.Fee)
if err != nil {
log.Warnf("Skipping input %v: %v", op, err)
continue
}
// Only try to sweep inputs with an unconfirmed parent if the
// current sweep fee rate exceeds the parent tx fee rate. This
// assumes that such inputs are offered to the sweeper solely
// for the purpose of anchoring down the parent tx using cpfp.
parentTx := input.UnconfParent()
if parentTx != nil {
parentFeeRate :=
chainfee.SatPerKWeight(parentTx.Fee*1000) /
chainfee.SatPerKWeight(parentTx.Weight)
if parentFeeRate >= feeRate {
log.Debugf("Skipping cpfp input %v: fee_rate=%v, "+
"parent_fee_rate=%v", op, feeRate,
parentFeeRate)
continue
}
}
feeGroup := s.bucketForFeeRate(feeRate)
// Create a bucket list for this fee rate if there isn't one
// yet.
buckets, ok := bucketInputs[feeGroup]
if !ok {
buckets = &bucketList{}
bucketInputs[feeGroup] = buckets
}
// Request the bucket list to add this input. The bucket list
// will take into account exclusive group constraints.
buckets.add(input)
input.lastFeeRate = feeRate
inputFeeRates[op] = feeRate
}
// We'll then determine the sweep fee rate for each set of inputs by
// calculating the average fee rate of the inputs within each set.
inputClusters := make([]inputCluster, 0, len(bucketInputs))
for _, buckets := range bucketInputs {
for _, inputs := range buckets.buckets {
var sweepFeeRate chainfee.SatPerKWeight
for op := range inputs {
sweepFeeRate += inputFeeRates[op]
}
sweepFeeRate /= chainfee.SatPerKWeight(len(inputs))
inputClusters = append(inputClusters, inputCluster{
sweepFeeRate: sweepFeeRate,
inputs: inputs,
})
}
}
return inputClusters
}
// zipClusters merges pairwise clusters from as and bs such that cluster a from
// as is merged with a cluster from bs that has at least the fee rate of a.
// This to ensure we don't delay confirmation by decreasing the fee rate (the
// lock time inputs are typically second level HTLC transactions, that are time
// sensitive).
func zipClusters(as, bs []inputCluster) []inputCluster {
// Sort the clusters by decreasing fee rates.
sort.Slice(as, func(i, j int) bool {
return as[i].sweepFeeRate >
as[j].sweepFeeRate
})
sort.Slice(bs, func(i, j int) bool {
return bs[i].sweepFeeRate >
bs[j].sweepFeeRate
})
var (
finalClusters []inputCluster
j int
)
// Go through each cluster in as, and merge with the next one from bs
// if it has at least the fee rate needed.
for i := range as {
a := as[i]
switch {
// If the fee rate for the next one from bs is at least a's, we
// merge.
case j < len(bs) && bs[j].sweepFeeRate >= a.sweepFeeRate:
merged := mergeClusters(a, bs[j])
finalClusters = append(finalClusters, merged...)
// Increment j for the next round.
j++
// We did not merge, meaning all the remaining clusters from bs
// have lower fee rate. Instead we add a directly to the final
// clusters.
default:
finalClusters = append(finalClusters, a)
}
}
// Add any remaining clusters from bs.
for ; j < len(bs); j++ {
b := bs[j]
finalClusters = append(finalClusters, b)
}
return finalClusters
}
// mergeClusters attempts to merge cluster a and b if they are compatible. The
// new cluster will have the locktime set if a or b had a locktime set, and a
// sweep fee rate that is the maximum of a and b's. If the two clusters are not
// compatible, they will be returned unchanged.
func mergeClusters(a, b inputCluster) []inputCluster {
newCluster := inputCluster{}
switch {
// Incompatible locktimes, return the sets without merging them.
case a.lockTime != nil && b.lockTime != nil && *a.lockTime != *b.lockTime:
return []inputCluster{a, b}
case a.lockTime != nil:
newCluster.lockTime = a.lockTime
case b.lockTime != nil:
newCluster.lockTime = b.lockTime
}
if a.sweepFeeRate > b.sweepFeeRate {
newCluster.sweepFeeRate = a.sweepFeeRate
} else {
newCluster.sweepFeeRate = b.sweepFeeRate
}
newCluster.inputs = make(pendingInputs)
for op, in := range a.inputs {
newCluster.inputs[op] = in
}
for op, in := range b.inputs {
newCluster.inputs[op] = in
}
return []inputCluster{newCluster}
}
// scheduleSweep starts the sweep timer to create an opportunity for more inputs
// to be added.
func (s *UtxoSweeper) scheduleSweep(currentHeight int32) error {
// The timer is already ticking, no action needed for the sweep to
// happen.
if s.timer != nil {
log.Debugf("Timer still ticking at height=%v", currentHeight)
return nil
}
// We'll only start our timer once we have inputs we're able to sweep.
startTimer := false
for _, cluster := range s.createInputClusters() {
// Examine pending inputs and try to construct lists of inputs.
// We don't need to obtain the coin selection lock, because we
// just need an indication as to whether we can sweep. More
// inputs may be added until we publish the transaction and
// coins that we select now may be used in other transactions.
inputLists, err := s.getInputLists(cluster, currentHeight)
if err != nil {
return fmt.Errorf("get input lists: %v", err)
}
log.Infof("Sweep candidates at height=%v with fee_rate=%v, "+
"yield %v distinct txns", currentHeight,
cluster.sweepFeeRate, len(inputLists))
if len(inputLists) != 0 {
startTimer = true
break
}
}
if !startTimer {
return nil
}
// Start sweep timer to create opportunity for more inputs to be added
// before a tx is constructed.
s.timer = s.cfg.NewBatchTimer()
log.Debugf("Sweep timer started")
return nil
}
// signalAndRemove notifies the listeners of the final result of the input
// sweep. It cancels any pending spend notification and removes the input from
// the list of pending inputs. When this function returns, the sweeper has
// completely forgotten about the input.
func (s *UtxoSweeper) signalAndRemove(outpoint *wire.OutPoint, result Result) {
pendInput := s.pendingInputs[*outpoint]
listeners := pendInput.listeners
if result.Err == nil {
log.Debugf("Dispatching sweep success for %v to %v listeners",
outpoint, len(listeners),
)
} else {
log.Debugf("Dispatching sweep error for %v to %v listeners: %v",
outpoint, len(listeners), result.Err,
)
}
// Signal all listeners. Channel is buffered. Because we only send once
// on every channel, it should never block.
for _, resultChan := range listeners {
resultChan <- result
}
// Cancel spend notification with chain notifier. This is not necessary
// in case of a success, except for that a reorg could still happen.
if pendInput.ntfnRegCancel != nil {
log.Debugf("Canceling spend ntfn for %v", outpoint)
pendInput.ntfnRegCancel()
}
// Inputs are no longer pending after result has been sent.
delete(s.pendingInputs, *outpoint)
}
// getInputLists goes through the given inputs and constructs multiple distinct
// sweep lists with the given fee rate, each up to the configured maximum number
// of inputs. Negative yield inputs are skipped. Transactions with an output
// below the dust limit are not published. Those inputs remain pending and will
// be bundled with future inputs if possible.
func (s *UtxoSweeper) getInputLists(cluster inputCluster,
currentHeight int32) ([]inputSet, error) {
// Filter for inputs that need to be swept. Create two lists: all
// sweepable inputs and a list containing only the new, never tried
// inputs.
//
// We want to create as large a tx as possible, so we return a final set
// list that starts with sets created from all inputs. However, there is
// a chance that those txes will not publish, because they already
// contain inputs that failed before. Therefore we also add sets
// consisting of only new inputs to the list, to make sure that new
// inputs are given a good, isolated chance of being published.
var newInputs, retryInputs []txInput
for _, input := range cluster.inputs {
// Skip inputs that have a minimum publish height that is not
// yet reached.
if input.minPublishHeight > currentHeight {
continue
}
// Add input to the either one of the lists.
if input.publishAttempts == 0 {
newInputs = append(newInputs, input)
} else {
retryInputs = append(retryInputs, input)
}
}
// If there is anything to retry, combine it with the new inputs and
// form input sets.
var allSets []inputSet
if len(retryInputs) > 0 {
var err error
allSets, err = generateInputPartitionings(
append(retryInputs, newInputs...),
cluster.sweepFeeRate, s.cfg.MaxInputsPerTx,
s.cfg.Wallet,
)
if err != nil {
return nil, fmt.Errorf("input partitionings: %v", err)
}
}
// Create sets for just the new inputs.
newSets, err := generateInputPartitionings(
newInputs, cluster.sweepFeeRate, s.cfg.MaxInputsPerTx,
s.cfg.Wallet,
)
if err != nil {
return nil, fmt.Errorf("input partitionings: %v", err)
}
log.Debugf("Sweep candidates at height=%v: total_num_pending=%v, "+
"total_num_new=%v", currentHeight, len(allSets), len(newSets))
// Append the new sets at the end of the list, because those tx likely
// have a higher fee per input.
return append(allSets, newSets...), nil
}
// sweep takes a set of preselected inputs, creates a sweep tx and publishes the
// tx. The output address is only marked as used if the publish succeeds.
func (s *UtxoSweeper) sweep(inputs inputSet, feeRate chainfee.SatPerKWeight,
currentHeight int32) error {
// Generate an output script if there isn't an unused script available.
if s.currentOutputScript == nil {
pkScript, err := s.cfg.GenSweepScript()
if err != nil {
return fmt.Errorf("gen sweep script: %v", err)
}
s.currentOutputScript = pkScript
}
// Create sweep tx.
tx, err := createSweepTx(
inputs, nil, s.currentOutputScript, uint32(currentHeight),
feeRate, s.cfg.Signer,
)
if err != nil {
return fmt.Errorf("create sweep tx: %v", err)
}
// Add tx before publication, so that we will always know that a spend
// by this tx is ours. Otherwise if the publish doesn't return, but did
// publish, we loose track of this tx. Even republication on startup
// doesn't prevent this, because that call returns a double spend error
// then and would also not add the hash to the store.
err = s.cfg.Store.NotifyPublishTx(tx)
if err != nil {
return fmt.Errorf("notify publish tx: %v", err)
}
// Publish sweep tx.
log.Debugf("Publishing sweep tx %v, num_inputs=%v, height=%v",
tx.TxHash(), len(tx.TxIn), currentHeight)
log.Tracef("Sweep tx at height=%v: %v", currentHeight,
newLogClosure(func() string {
return spew.Sdump(tx)
}),
)
err = s.cfg.Wallet.PublishTransaction(
tx, labels.MakeLabel(labels.LabelTypeSweepTransaction, nil),
)
// In case of an unexpected error, don't try to recover.
if err != nil && err != lnwallet.ErrDoubleSpend {
return fmt.Errorf("publish tx: %v", err)
}
// Otherwise log the error.
if err != nil {
log.Errorf("Publish sweep tx %v got error: %v", tx.TxHash(),
err)
} else {
// If there's no error, remove the output script. Otherwise
// keep it so that it can be reused for the next transaction
// and causes no address inflation.
s.currentOutputScript = nil
}
// Reschedule sweep.
for _, input := range tx.TxIn {
pi, ok := s.pendingInputs[input.PreviousOutPoint]
if !ok {
// It can be that the input has been removed because it
// exceed the maximum number of attempts in a previous
// input set. It could also be that this input is an
// additional wallet input that was attached. In that
// case there also isn't a pending input to update.
continue
}
// Record another publish attempt.
pi.publishAttempts++
// We don't care what the result of the publish call was. Even
// if it is published successfully, it can still be that it
// needs to be retried. Call NextAttemptDeltaFunc to calculate
// when to resweep this input.
nextAttemptDelta := s.cfg.NextAttemptDeltaFunc(
pi.publishAttempts,
)
pi.minPublishHeight = currentHeight + nextAttemptDelta
log.Debugf("Rescheduling input %v after %v attempts at "+
"height %v (delta %v)", input.PreviousOutPoint,
pi.publishAttempts, pi.minPublishHeight,
nextAttemptDelta)
if pi.publishAttempts >= s.cfg.MaxSweepAttempts {
log.Warnf("input %v: publishAttempts(%v) exceeds "+
"MaxSweepAttempts(%v), removed",
input.PreviousOutPoint, pi.publishAttempts,
s.cfg.MaxSweepAttempts)
// Signal result channels sweep result.
s.signalAndRemove(&input.PreviousOutPoint, Result{
Err: ErrTooManyAttempts,
})
}
}
return nil
}
// waitForSpend registers a spend notification with the chain notifier. It
// returns a cancel function that can be used to cancel the registration.
func (s *UtxoSweeper) waitForSpend(outpoint wire.OutPoint,
script []byte, heightHint uint32) (func(), error) {
log.Tracef("Wait for spend of %v at heightHint=%v",
outpoint, heightHint)
spendEvent, err := s.cfg.Notifier.RegisterSpendNtfn(
&outpoint, script, heightHint,
)
if err != nil {
return nil, fmt.Errorf("register spend ntfn: %v", err)
}
s.wg.Add(1)
go func() {
defer s.wg.Done()
select {
case spend, ok := <-spendEvent.Spend:
if !ok {
log.Debugf("Spend ntfn for %v canceled",
outpoint)
return
}
log.Debugf("Delivering spend ntfn for %v",
outpoint)
select {
case s.spendChan <- spend:
log.Debugf("Delivered spend ntfn for %v",
outpoint)
case <-s.quit:
}
case <-s.quit:
}
}()
return spendEvent.Cancel, nil
}
// PendingInputs returns the set of inputs that the UtxoSweeper is currently
// attempting to sweep.
func (s *UtxoSweeper) PendingInputs() (map[wire.OutPoint]*PendingInput, error) {
respChan := make(chan map[wire.OutPoint]*PendingInput, 1)
errChan := make(chan error, 1)
select {
case s.pendingSweepsReqs <- &pendingSweepsReq{
respChan: respChan,
errChan: errChan,
}:
case <-s.quit:
return nil, ErrSweeperShuttingDown
}
select {
case pendingSweeps := <-respChan:
return pendingSweeps, nil
case err := <-errChan:
return nil, err
case <-s.quit:
return nil, ErrSweeperShuttingDown
}
}
// handlePendingSweepsReq handles a request to retrieve all pending inputs the
// UtxoSweeper is attempting to sweep.
func (s *UtxoSweeper) handlePendingSweepsReq(
req *pendingSweepsReq) map[wire.OutPoint]*PendingInput {
pendingInputs := make(map[wire.OutPoint]*PendingInput, len(s.pendingInputs))
for _, pendingInput := range s.pendingInputs {
// Only the exported fields are set, as we expect the response
// to only be consumed externally.
op := *pendingInput.OutPoint()
pendingInputs[op] = &PendingInput{
OutPoint: op,
WitnessType: pendingInput.WitnessType(),
Amount: btcutil.Amount(
pendingInput.SignDesc().Output.Value,
),
LastFeeRate: pendingInput.lastFeeRate,
BroadcastAttempts: pendingInput.publishAttempts,
NextBroadcastHeight: uint32(pendingInput.minPublishHeight),
Params: pendingInput.params,
}
}
return pendingInputs
}
// UpdateParams allows updating the sweep parameters of a pending input in the
// UtxoSweeper. This function can be used to provide an updated fee preference
// and force flag that will be used for a new sweep transaction of the input
// that will act as a replacement transaction (RBF) of the original sweeping
// transaction, if any. The exclusive group is left unchanged.
//
// NOTE: This currently doesn't do any fee rate validation to ensure that a bump
// is actually successful. The responsibility of doing so should be handled by
// the caller.
func (s *UtxoSweeper) UpdateParams(input wire.OutPoint,
params ParamsUpdate) (chan Result, error) {
// Ensure the client provided a sane fee preference.
if _, err := s.feeRateForPreference(params.Fee); err != nil {
return nil, err
}
responseChan := make(chan *updateResp, 1)
select {
case s.updateReqs <- &updateReq{
input: input,
params: params,
responseChan: responseChan,
}:
case <-s.quit:
return nil, ErrSweeperShuttingDown
}
select {
case response := <-responseChan:
return response.resultChan, response.err
case <-s.quit:
return nil, ErrSweeperShuttingDown
}
}
// handleUpdateReq handles an update request by simply updating the sweep
// parameters of the pending input. Currently, no validation is done on the new
// fee preference to ensure it will properly create a replacement transaction.
//
// TODO(wilmer):
// - Validate fee preference to ensure we'll create a valid replacement
// transaction to allow the new fee rate to propagate throughout the
// network.
// - Ensure we don't combine this input with any other unconfirmed inputs that
// did not exist in the original sweep transaction, resulting in an invalid
// replacement transaction.
func (s *UtxoSweeper) handleUpdateReq(req *updateReq, bestHeight int32) (
chan Result, error) {
// If the UtxoSweeper is already trying to sweep this input, then we can
// simply just increase its fee rate. This will allow the input to be
// batched with others which also have a similar fee rate, creating a
// higher fee rate transaction that replaces the original input's
// sweeping transaction.
pendingInput, ok := s.pendingInputs[req.input]
if !ok {
return nil, lnwallet.ErrNotMine
}
// Create the updated parameters struct. Leave the exclusive group
// unchanged.
newParams := pendingInput.params
newParams.Fee = req.params.Fee
newParams.Force = req.params.Force
log.Debugf("Updating sweep parameters for %v from %v to %v", req.input,
pendingInput.params, newParams)
pendingInput.params = newParams
// We'll reset the input's publish height to the current so that a new
// transaction can be created that replaces the transaction currently
// spending the input. We only do this for inputs that have been
// broadcast at least once to ensure we don't spend an input before its
// maturity height.
//
// NOTE: The UtxoSweeper is not yet offered time-locked inputs, so the
// check for broadcast attempts is redundant at the moment.
if pendingInput.publishAttempts > 0 {
pendingInput.minPublishHeight = bestHeight
}
if err := s.scheduleSweep(bestHeight); err != nil {
log.Errorf("Unable to schedule sweep: %v", err)
}
resultChan := make(chan Result, 1)
pendingInput.listeners = append(pendingInput.listeners, resultChan)
return resultChan, nil
}
// CreateSweepTx accepts a list of inputs and signs and generates a txn that
// spends from them. This method also makes an accurate fee estimate before
// generating the required witnesses.
//
// The created transaction has a single output sending all the funds back to
// the source wallet, after accounting for the fee estimate.
//
// The value of currentBlockHeight argument will be set as the tx locktime.
// This function assumes that all CLTV inputs will be unlocked after
// currentBlockHeight. Reasons not to use the maximum of all actual CLTV expiry
// values of the inputs:
//
// - Make handling re-orgs easier.
// - Thwart future possible fee sniping attempts.
// - Make us blend in with the bitcoind wallet.
func (s *UtxoSweeper) CreateSweepTx(inputs []input.Input, feePref FeePreference,
currentBlockHeight uint32) (*wire.MsgTx, error) {
feePerKw, err := DetermineFeePerKw(s.cfg.FeeEstimator, feePref)
if err != nil {
return nil, err
}
// Generate the receiving script to which the funds will be swept.
pkScript, err := s.cfg.GenSweepScript()
if err != nil {
return nil, err
}
return createSweepTx(
inputs, nil, pkScript, currentBlockHeight, feePerKw,
s.cfg.Signer,
)
}
// DefaultNextAttemptDeltaFunc is the default calculation for next sweep attempt
// scheduling. It implements exponential back-off with some randomness. This is
// to prevent a stuck tx (for example because fee is too low and can't be bumped
// in btcd) from blocking all other retried inputs in the same tx.
func DefaultNextAttemptDeltaFunc(attempts int) int32 {
return 1 + rand.Int31n(1<<uint(attempts-1))
}
// ListSweeps returns a list of the the sweeps recorded by the sweep store.
func (s *UtxoSweeper) ListSweeps() ([]chainhash.Hash, error) {
return s.cfg.Store.ListSweeps()
}
// init initializes the random generator for random input rescheduling.
func init() {
rand.Seed(time.Now().Unix())
}