lnd.xprv/chainntnfs/btcdnotify/btcd.go

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package btcdnotify
import (
"container/heap"
"errors"
"sync"
"sync/atomic"
"time"
"github.com/lightningnetwork/lnd/chainntnfs"
"github.com/roasbeef/btcd/btcjson"
"github.com/roasbeef/btcd/chaincfg/chainhash"
"github.com/roasbeef/btcd/rpcclient"
"github.com/roasbeef/btcd/wire"
"github.com/roasbeef/btcutil"
)
const (
// notifierType uniquely identifies this concrete implementation of the
// ChainNotifier interface.
notifierType = "btcd"
)
var (
// ErrChainNotifierShuttingDown is used when we are trying to
// measure a spend notification when notifier is already stopped.
ErrChainNotifierShuttingDown = errors.New("chainntnfs: system interrupt " +
"while attempting to register for spend notification.")
)
// chainUpdate encapsulates an update to the current main chain. This struct is
// used as an element within an unbounded queue in order to avoid blocking the
// main rpc dispatch rule.
type chainUpdate struct {
blockHash *chainhash.Hash
blockHeight int32
}
// txUpdate encapsulates a transaction related notification sent from btcd to
// the registered RPC client. This struct is used as an element within an
// unbounded queue in order to avoid blocking the main rpc dispatch rule.
type txUpdate struct {
tx *btcutil.Tx
details *btcjson.BlockDetails
}
// TODO(roasbeef): generalize struct below:
// * move chans to config, allow outside callers to handle send conditions
// BtcdNotifier implements the ChainNotifier interface using btcd's websockets
// notifications. Multiple concurrent clients are supported. All notifications
// are achieved via non-blocking sends on client channels.
type BtcdNotifier struct {
spendClientCounter uint64 // To be used atomically.
epochClientCounter uint64 // To be used atomically.
started int32 // To be used atomically.
stopped int32 // To be used atomically.
chainConn *rpcclient.Client
notificationCancels chan interface{}
notificationRegistry chan interface{}
spendNotifications map[wire.OutPoint]map[uint64]*spendNotification
confNotifications map[chainhash.Hash][]*confirmationsNotification
confHeap *confirmationHeap
blockEpochClients map[uint64]*blockEpochRegistration
disconnectedBlockHashes chan *blockNtfn
chainUpdates []*chainUpdate
chainUpdateSignal chan struct{}
chainUpdateMtx sync.Mutex
txUpdates []*txUpdate
txUpdateSignal chan struct{}
txUpdateMtx sync.Mutex
wg sync.WaitGroup
quit chan struct{}
}
// Ensure BtcdNotifier implements the ChainNotifier interface at compile time.
var _ chainntnfs.ChainNotifier = (*BtcdNotifier)(nil)
// New returns a new BtcdNotifier instance. This function assumes the btcd node
// detailed in the passed configuration is already running, and willing to
// accept new websockets clients.
func New(config *rpcclient.ConnConfig) (*BtcdNotifier, error) {
notifier := &BtcdNotifier{
notificationCancels: make(chan interface{}),
notificationRegistry: make(chan interface{}),
blockEpochClients: make(map[uint64]*blockEpochRegistration),
spendNotifications: make(map[wire.OutPoint]map[uint64]*spendNotification),
confNotifications: make(map[chainhash.Hash][]*confirmationsNotification),
confHeap: newConfirmationHeap(),
disconnectedBlockHashes: make(chan *blockNtfn, 20),
chainUpdateSignal: make(chan struct{}),
txUpdateSignal: make(chan struct{}),
quit: make(chan struct{}),
}
ntfnCallbacks := &rpcclient.NotificationHandlers{
OnBlockConnected: notifier.onBlockConnected,
OnBlockDisconnected: notifier.onBlockDisconnected,
OnRedeemingTx: notifier.onRedeemingTx,
}
// Disable connecting to btcd within the rpcclient.New method. We
// defer establishing the connection to our .Start() method.
config.DisableConnectOnNew = true
config.DisableAutoReconnect = false
chainConn, err := rpcclient.New(config, ntfnCallbacks)
if err != nil {
return nil, err
}
notifier.chainConn = chainConn
return notifier, nil
}
// Start connects to the running btcd node over websockets, registers for block
// notifications, and finally launches all related helper goroutines.
func (b *BtcdNotifier) Start() error {
// Already started?
if atomic.AddInt32(&b.started, 1) != 1 {
return nil
}
// Connect to btcd, and register for notifications on connected, and
// disconnected blocks.
if err := b.chainConn.Connect(20); err != nil {
return err
}
if err := b.chainConn.NotifyBlocks(); err != nil {
return err
}
_, currentHeight, err := b.chainConn.GetBestBlock()
if err != nil {
return err
}
b.wg.Add(1)
go b.notificationDispatcher(currentHeight)
return nil
}
// Stop shutsdown the BtcdNotifier.
func (b *BtcdNotifier) Stop() error {
// Already shutting down?
if atomic.AddInt32(&b.stopped, 1) != 1 {
return nil
}
// Shutdown the rpc client, this gracefully disconnects from btcd, and
// cleans up all related resources.
b.chainConn.Shutdown()
close(b.quit)
b.wg.Wait()
// Notify all pending clients of our shutdown by closing the related
// notification channels.
for _, spendClients := range b.spendNotifications {
for _, spendClient := range spendClients {
close(spendClient.spendChan)
}
}
for _, confClients := range b.confNotifications {
for _, confClient := range confClients {
close(confClient.finConf)
close(confClient.negativeConf)
}
}
for _, epochClient := range b.blockEpochClients {
close(epochClient.epochChan)
}
return nil
}
// blockNtfn packages a notification of a connected/disconnected block along
// with its height at the time.
type blockNtfn struct {
sha *chainhash.Hash
height int32
}
// onBlockConnected implements on OnBlockConnected callback for rpcclient.
// Ingesting a block updates the wallet's internal utxo state based on the
// outputs created and destroyed within each block.
func (b *BtcdNotifier) onBlockConnected(hash *chainhash.Hash, height int32, t time.Time) {
// Append this new chain update to the end of the queue of new chain
// updates.
b.chainUpdateMtx.Lock()
b.chainUpdates = append(b.chainUpdates, &chainUpdate{hash, height})
b.chainUpdateMtx.Unlock()
// Launch a goroutine to signal the notification dispatcher that a new
// block update is available. We do this in a new goroutine in order to
// avoid blocking the main loop of the rpc client.
go func() {
b.chainUpdateSignal <- struct{}{}
}()
}
// onBlockDisconnected implements on OnBlockDisconnected callback for rpcclient.
func (b *BtcdNotifier) onBlockDisconnected(hash *chainhash.Hash, height int32, t time.Time) {
}
// onRedeemingTx implements on OnRedeemingTx callback for rpcclient.
func (b *BtcdNotifier) onRedeemingTx(tx *btcutil.Tx, details *btcjson.BlockDetails) {
// Append this new transaction update to the end of the queue of new
// chain updates.
b.txUpdateMtx.Lock()
b.txUpdates = append(b.txUpdates, &txUpdate{tx, details})
b.txUpdateMtx.Unlock()
// Launch a goroutine to signal the notification dispatcher that a new
// transaction update is available. We do this in a new goroutine in
// order to avoid blocking the main loop of the rpc client.
go func() {
b.txUpdateSignal <- struct{}{}
}()
}
// notificationDispatcher is the primary goroutine which handles client
// notification registrations, as well as notification dispatches.
func (b *BtcdNotifier) notificationDispatcher(currentHeight int32) {
out:
for {
select {
case cancelMsg := <-b.notificationCancels:
switch msg := cancelMsg.(type) {
case *spendCancel:
chainntnfs.Log.Infof("Cancelling spend "+
"notification for out_point=%v, "+
"spend_id=%v", msg.op, msg.spendID)
// Before we attempt to close the spendChan,
// ensure that the notification hasn't already
// yet been dispatched.
if outPointClients, ok := b.spendNotifications[msg.op]; ok {
close(outPointClients[msg.spendID].spendChan)
delete(b.spendNotifications[msg.op], msg.spendID)
}
case *epochCancel:
chainntnfs.Log.Infof("Cancelling epoch "+
"notification, epoch_id=%v", msg.epochID)
// First, close the cancel channel for this
// specific client, and wait for the client to
// exit.
close(b.blockEpochClients[msg.epochID].cancelChan)
b.blockEpochClients[msg.epochID].wg.Wait()
// Once the client has exited, we can then
// safely close the channel used to send epoch
// notifications, in order to notify any
// listeners that the intent has been
// cancelled.
close(b.blockEpochClients[msg.epochID].epochChan)
delete(b.blockEpochClients, msg.epochID)
}
case registerMsg := <-b.notificationRegistry:
switch msg := registerMsg.(type) {
case *spendNotification:
chainntnfs.Log.Infof("New spend subscription: "+
"utxo=%v", msg.targetOutpoint)
op := *msg.targetOutpoint
if _, ok := b.spendNotifications[op]; !ok {
b.spendNotifications[op] = make(map[uint64]*spendNotification)
}
b.spendNotifications[op][msg.spendID] = msg
case *confirmationsNotification:
chainntnfs.Log.Infof("New confirmations "+
"subscription: txid=%v, numconfs=%v",
*msg.txid, msg.numConfirmations)
// If the notification can be partially or
// fully dispatched, then we can skip the first
// phase for ntfns.
if b.attemptHistoricalDispatch(msg) {
continue
}
txid := *msg.txid
b.confNotifications[txid] = append(b.confNotifications[txid], msg)
case *blockEpochRegistration:
chainntnfs.Log.Infof("New block epoch subscription")
b.blockEpochClients[msg.epochID] = msg
}
case staleBlockHash := <-b.disconnectedBlockHashes:
// TODO(roasbeef): re-orgs
// * second channel to notify of confirmation decrementing
// re-org?
// * notify of negative confirmations
chainntnfs.Log.Warnf("Block disconnected from main "+
"chain: %v", staleBlockHash)
case <-b.chainUpdateSignal:
// A new update is available, so pop the new chain
// update from the front of the update queue.
b.chainUpdateMtx.Lock()
update := b.chainUpdates[0]
b.chainUpdates[0] = nil // Set to nil to prevent GC leak.
b.chainUpdates = b.chainUpdates[1:]
b.chainUpdateMtx.Unlock()
currentHeight = update.blockHeight
newBlock, err := b.chainConn.GetBlock(update.blockHash)
if err != nil {
chainntnfs.Log.Errorf("Unable to get block: %v", err)
continue
}
chainntnfs.Log.Infof("New block: height=%v, sha=%v",
update.blockHeight, update.blockHash)
b.notifyBlockEpochs(update.blockHeight,
update.blockHash)
newHeight := update.blockHeight
for i, tx := range newBlock.Transactions {
// Check if the inclusion of this transaction
// within a block by itself triggers a block
// confirmation threshold, if so send a
// notification. Otherwise, place the
// notification on a heap to be triggered in
// the future once additional confirmations are
// attained.
txSha := tx.TxHash()
b.checkConfirmationTrigger(&txSha, update, i)
}
// A new block has been connected to the main
// chain. Send out any N confirmation notifications
// which may have been triggered by this new block.
b.notifyConfs(newHeight)
case <-b.txUpdateSignal:
// A new update is available, so pop the new chain
// update from the front of the update queue.
b.txUpdateMtx.Lock()
newSpend := b.txUpdates[0]
b.txUpdates[0] = nil // Set to nil to prevent GC leak.
b.txUpdates = b.txUpdates[1:]
b.txUpdateMtx.Unlock()
spendingTx := newSpend.tx
// First, check if this transaction spends an output
// that has an existing spend notification for it.
for i, txIn := range spendingTx.MsgTx().TxIn {
prevOut := txIn.PreviousOutPoint
// If this transaction indeed does spend an
// output which we have a registered
// notification for, then create a spend
// summary, finally sending off the details to
// the notification subscriber.
if clients, ok := b.spendNotifications[prevOut]; ok {
spenderSha := newSpend.tx.Hash()
spendDetails := &chainntnfs.SpendDetail{
SpentOutPoint: &prevOut,
SpenderTxHash: spenderSha,
SpendingTx: spendingTx.MsgTx(),
SpenderInputIndex: uint32(i),
}
// TODO(roasbeef): after change to
// loadfilter, only notify on block
// inclusion?
if newSpend.details != nil {
spendDetails.SpendingHeight = newSpend.details.Height
} else {
spendDetails.SpendingHeight = currentHeight + 1
}
for _, ntfn := range clients {
chainntnfs.Log.Infof("Dispatching "+
"spend notification for "+
"outpoint=%v", ntfn.targetOutpoint)
ntfn.spendChan <- spendDetails
// Close spendChan to ensure that any calls to Cancel will not
// block. This is safe to do since the channel is buffered, and the
// message can still be read by the receiver.
close(ntfn.spendChan)
}
delete(b.spendNotifications, prevOut)
}
}
case <-b.quit:
break out
}
}
b.wg.Done()
}
// attemptHistoricalDispatch tries to use historical information to decide if a
// notification ca be dispatched immediately, or is partially confirmed so it
// can skip straight to the confirmations heap.
//
// Returns true if the transaction was either partially or completely confirmed
func (b *BtcdNotifier) attemptHistoricalDispatch(
msg *confirmationsNotification) bool {
chainntnfs.Log.Infof("Attempting to trigger dispatch for %v from "+
"historical chain", msg.txid)
// If the transaction already has some or all of the confirmations,
// then we may be able to dispatch it immediately.
tx, err := b.chainConn.GetRawTransactionVerbose(msg.txid)
if err != nil || tx == nil || tx.BlockHash == "" {
jsonErr, ok := err.(*btcjson.RPCError)
switch {
case ok && jsonErr.Code == -5:
default:
chainntnfs.Log.Warnf("unable to query for txid(%v): %v",
msg.txid, err)
}
return false
}
// As we need to fully populate the returned TxConfirmation struct,
// grab the block in which the transaction was confirmed so we can
// locate its exact index within the block.
blockHash, err := chainhash.NewHashFromStr(tx.BlockHash)
if err != nil {
chainntnfs.Log.Errorf("unable to get block hash %v for "+
"historical dispatch: %v", tx.BlockHash, err)
return false
}
block, err := b.chainConn.GetBlockVerbose(blockHash)
if err != nil {
chainntnfs.Log.Errorf("unable to get block hash: %v", err)
return false
}
// If the block obtained, locate the transaction's index within the
// block so we can give the subscriber full confirmation details.
var txIndex uint32
targetTxidStr := msg.txid.String()
for i, txHash := range block.Tx {
if txHash == targetTxidStr {
txIndex = uint32(i)
break
}
}
confDetails := &chainntnfs.TxConfirmation{
BlockHash: blockHash,
BlockHeight: uint32(block.Height),
TxIndex: txIndex,
}
// If the transaction has more that enough confirmations, then we can
// dispatch it immediately after obtaining for information w.r.t
// exactly *when* if got all its confirmations.
if uint32(tx.Confirmations) >= msg.numConfirmations {
msg.finConf <- confDetails
return true
}
// Otherwise, the transaction has only been *partially* confirmed, so
// we need to insert it into the confirmation heap.
// Find the block height at which this transaction will be confirmed
confHeight := uint32(block.Height) + msg.numConfirmations - 1
heapEntry := &confEntry{
msg,
confDetails,
confHeight,
}
heap.Push(b.confHeap, heapEntry)
return true
}
// notifyBlockEpochs notifies all registered block epoch clients of the newly
// connected block to the main chain.
func (b *BtcdNotifier) notifyBlockEpochs(newHeight int32, newSha *chainhash.Hash) {
epoch := &chainntnfs.BlockEpoch{
Height: newHeight,
Hash: newSha,
}
for _, epochClient := range b.blockEpochClients {
b.wg.Add(1)
epochClient.wg.Add(1)
go func(ntfnChan chan *chainntnfs.BlockEpoch, cancelChan chan struct{},
clientWg *sync.WaitGroup) {
// TODO(roasbeef): move to goroutine per client, use sync queue
defer clientWg.Done()
defer b.wg.Done()
select {
case ntfnChan <- epoch:
case <-cancelChan:
return
case <-b.quit:
return
}
}(epochClient.epochChan, epochClient.cancelChan, &epochClient.wg)
}
}
// notifyConfs examines the current confirmation heap, sending off any
// notifications which have been triggered by the connection of a new block at
// newBlockHeight.
func (b *BtcdNotifier) notifyConfs(newBlockHeight int32) {
// If the heap is empty, we have nothing to do.
if b.confHeap.Len() == 0 {
return
}
// Traverse our confirmation heap. The heap is a
// min-heap, so the confirmation notification which requires
// the smallest block-height will always be at the top
// of the heap. If a confirmation notification is eligible
// for triggering, then fire it off, and check if another
// is eligible until there are no more eligible entries.
nextConf := heap.Pop(b.confHeap).(*confEntry)
for nextConf.triggerHeight <= uint32(newBlockHeight) {
// TODO(roasbeef): shake out possible of by one in height calc
// for historical dispatches
nextConf.finConf <- nextConf.initialConfDetails
if b.confHeap.Len() == 0 {
return
}
nextConf = heap.Pop(b.confHeap).(*confEntry)
}
heap.Push(b.confHeap, nextConf)
}
// checkConfirmationTrigger determines if the passed txSha included at blockHeight
// triggers any single confirmation notifications. In the event that the txid
// matches, yet needs additional confirmations, it is added to the confirmation
// heap to be triggered at a later time.
// TODO(roasbeef): perhaps lookup, then track by inputs instead?
func (b *BtcdNotifier) checkConfirmationTrigger(txSha *chainhash.Hash,
newTip *chainUpdate, txIndex int) {
// If a confirmation notification has been registered
// for this txid, then either trigger a notification
// event if only a single confirmation notification was
// requested, or place the notification on the
// confirmation heap for future usage.
if confClients, ok := b.confNotifications[*txSha]; ok {
// Either all of the registered confirmations will be
// dispatched due to a single confirmation, or added to the
// conf head. Therefore we unconditionally delete the registered
// confirmations from the staging zone.
defer func() {
delete(b.confNotifications, *txSha)
}()
for _, confClient := range confClients {
confDetails := &chainntnfs.TxConfirmation{
BlockHash: newTip.blockHash,
BlockHeight: uint32(newTip.blockHeight),
TxIndex: uint32(txIndex),
}
if confClient.numConfirmations == 1 {
chainntnfs.Log.Infof("Dispatching single conf "+
"notification, sha=%v, height=%v", txSha,
newTip.blockHeight)
confClient.finConf <- confDetails
continue
}
// The registered notification requires more
// than one confirmation before triggering. So
// we create a heapConf entry for this notification.
// The heapConf allows us to easily keep track of
// which notification(s) we should fire off with
// each incoming block.
confClient.initialConfirmHeight = uint32(newTip.blockHeight)
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finalConfHeight := confClient.initialConfirmHeight + confClient.numConfirmations - 1
heapEntry := &confEntry{
confClient,
confDetails,
finalConfHeight,
}
heap.Push(b.confHeap, heapEntry)
}
}
}
// spendNotification couples a target outpoint along with the channel used for
// notifications once a spend of the outpoint has been detected.
type spendNotification struct {
targetOutpoint *wire.OutPoint
spendChan chan *chainntnfs.SpendDetail
spendID uint64
}
// spendCancel is a message sent to the BtcdNotifier when a client wishes to
// cancel an outstanding spend notification that has yet to be dispatched.
type spendCancel struct {
// op is the target outpoint of the notification to be cancelled.
op wire.OutPoint
// spendID the ID of the notification to cancel.
spendID uint64
}
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// RegisterSpendNtfn registers an intent to be notified once the target
// outpoint has been spent by a transaction on-chain. Once a spend of the target
// outpoint has been detected, the details of the spending event will be sent
// across the 'Spend' channel.
func (b *BtcdNotifier) RegisterSpendNtfn(outpoint *wire.OutPoint,
_ uint32) (*chainntnfs.SpendEvent, error) {
if err := b.chainConn.NotifySpent([]*wire.OutPoint{outpoint}); err != nil {
return nil, err
}
ntfn := &spendNotification{
targetOutpoint: outpoint,
spendChan: make(chan *chainntnfs.SpendDetail, 1),
spendID: atomic.AddUint64(&b.spendClientCounter, 1),
}
select {
case <-b.quit:
return nil, ErrChainNotifierShuttingDown
case b.notificationRegistry <- ntfn:
}
// The following conditional checks to ensure that when a spend notification
// is registered, the output hasn't already been spent. If the output
// is no longer in the UTXO set, the chain will be rescanned from the point
// where the output was added. The rescan will dispatch the notification.
txout, err := b.chainConn.GetTxOut(&outpoint.Hash, outpoint.Index, true)
if err != nil {
return nil, err
}
if txout == nil {
transaction, err := b.chainConn.GetRawTransactionVerbose(&outpoint.Hash)
if err != nil {
jsonErr, ok := err.(*btcjson.RPCError)
switch {
case ok && jsonErr.Code == -5:
default:
return nil, err
}
}
if transaction != nil {
blockhash, err := chainhash.NewHashFromStr(transaction.BlockHash)
if err != nil {
return nil, err
}
ops := []*wire.OutPoint{outpoint}
if err := b.chainConn.Rescan(blockhash, nil, ops); err != nil {
chainntnfs.Log.Errorf("Rescan for spend "+
"notification txout failed: %v", err)
return nil, err
}
}
}
return &chainntnfs.SpendEvent{
Spend: ntfn.spendChan,
Cancel: func() {
cancel := &spendCancel{
op: *outpoint,
spendID: ntfn.spendID,
}
// Submit spend cancellation to notification dispatcher.
select {
case b.notificationCancels <- cancel:
// Cancellation is being handled, drain the spend chan until it is
// closed before yielding to the caller.
for {
select {
case _, ok := <-ntfn.spendChan:
if !ok {
return
}
case <-b.quit:
return
}
}
case <-b.quit:
}
},
}, nil
}
// confirmationNotification represents a client's intent to receive a
// notification once the target txid reaches numConfirmations confirmations.
type confirmationsNotification struct {
txid *chainhash.Hash
initialConfirmHeight uint32
numConfirmations uint32
finConf chan *chainntnfs.TxConfirmation
negativeConf chan int32 // TODO(roasbeef): re-org funny business
}
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// RegisterConfirmationsNtfn registers a notification with BtcdNotifier
// which will be triggered once the txid reaches numConfs number of
// confirmations.
func (b *BtcdNotifier) RegisterConfirmationsNtfn(txid *chainhash.Hash,
numConfs, _ uint32) (*chainntnfs.ConfirmationEvent, error) {
ntfn := &confirmationsNotification{
txid: txid,
numConfirmations: numConfs,
finConf: make(chan *chainntnfs.TxConfirmation, 1),
negativeConf: make(chan int32, 1),
}
select {
case <-b.quit:
return nil, ErrChainNotifierShuttingDown
case b.notificationRegistry <- ntfn:
return &chainntnfs.ConfirmationEvent{
Confirmed: ntfn.finConf,
NegativeConf: ntfn.negativeConf,
}, nil
}
}
// blockEpochRegistration represents a client's intent to receive a
// notification with each newly connected block.
type blockEpochRegistration struct {
epochID uint64
epochChan chan *chainntnfs.BlockEpoch
cancelChan chan struct{}
wg sync.WaitGroup
}
// epochCancel is a message sent to the BtcdNotifier when a client wishes to
// cancel an outstanding epoch notification that has yet to be dispatched.
type epochCancel struct {
epochID uint64
}
// RegisterBlockEpochNtfn returns a BlockEpochEvent which subscribes the
// caller to receive notifications, of each new block connected to the main
// chain.
func (b *BtcdNotifier) RegisterBlockEpochNtfn() (*chainntnfs.BlockEpochEvent, error) {
registration := &blockEpochRegistration{
epochChan: make(chan *chainntnfs.BlockEpoch, 20),
cancelChan: make(chan struct{}),
epochID: atomic.AddUint64(&b.epochClientCounter, 1),
}
select {
case <-b.quit:
return nil, errors.New("chainntnfs: system interrupt while " +
"attempting to register for block epoch notification.")
case b.notificationRegistry <- registration:
return &chainntnfs.BlockEpochEvent{
Epochs: registration.epochChan,
Cancel: func() {
cancel := &epochCancel{
epochID: registration.epochID,
}
// Submit epoch cancellation to notification dispatcher.
select {
case b.notificationCancels <- cancel:
// Cancellation is being handled, drain the epoch channel until it is
// closed before yielding to caller.
for {
select {
case _, ok := <-registration.epochChan:
if !ok {
return
}
case <-b.quit:
return
}
}
case <-b.quit:
}
},
}, nil
}
}