lnd.xprv/invoices/invoiceregistry.go
Joost Jager 32f2b047e8
htlcswitch: hodl invoice
This commit modifies the invoice registry to handle invoices for which
the preimage is not known yet (hodl invoices). In that case, the
resolution channel passed in from links and resolvers is stored until we
either learn the preimage or want to cancel the htlc.
2019-03-15 10:09:17 +01:00

893 lines
26 KiB
Go

package invoices
import (
"bytes"
"fmt"
"sync"
"sync/atomic"
"time"
"github.com/btcsuite/btcutil"
"github.com/davecgh/go-spew/spew"
"github.com/lightningnetwork/lnd/channeldb"
"github.com/lightningnetwork/lnd/lntypes"
"github.com/lightningnetwork/lnd/lnwire"
"github.com/lightningnetwork/lnd/queue"
)
var (
// DebugPre is the default debug preimage which is inserted into the
// invoice registry if the --debughtlc flag is activated on start up.
// All nodes initialized with the flag active will immediately settle
// any incoming HTLC whose rHash corresponds with the debug
// preimage.
DebugPre, _ = lntypes.MakePreimage(bytes.Repeat([]byte{1}, 32))
// DebugHash is the hash of the default preimage.
DebugHash = DebugPre.Hash()
)
// HodlEvent describes how an htlc should be resolved. If HodlEvent.Preimage is
// set, the event indicates a settle event. If Preimage is nil, it is a cancel
// event.
type HodlEvent struct {
Preimage *lntypes.Preimage
Hash lntypes.Hash
}
// InvoiceRegistry is a central registry of all the outstanding invoices
// created by the daemon. The registry is a thin wrapper around a map in order
// to ensure that all updates/reads are thread safe.
type InvoiceRegistry struct {
sync.RWMutex
cdb *channeldb.DB
clientMtx sync.Mutex
nextClientID uint32
notificationClients map[uint32]*InvoiceSubscription
singleNotificationClients map[uint32]*SingleInvoiceSubscription
newSubscriptions chan *InvoiceSubscription
newSingleSubscriptions chan *SingleInvoiceSubscription
subscriptionCancels chan uint32
invoiceEvents chan *invoiceEvent
// debugInvoices is a map which stores special "debug" invoices which
// should be only created/used when manual tests require an invoice
// that *all* nodes are able to fully settle.
debugInvoices map[lntypes.Hash]*channeldb.Invoice
// decodeFinalCltvExpiry is a function used to decode the final expiry
// value from the payment request.
decodeFinalCltvExpiry func(invoice string) (uint32, error)
// subscriptions is a map from a payment hash to a list of subscribers.
// It is used for efficient notification of links.
hodlSubscriptions map[lntypes.Hash]map[chan<- interface{}]struct{}
// reverseSubscriptions tracks hashes subscribed to per subscriber. This
// is used to unsubscribe from all hashes efficiently.
hodlReverseSubscriptions map[chan<- interface{}]map[lntypes.Hash]struct{}
wg sync.WaitGroup
quit chan struct{}
}
// NewRegistry creates a new invoice registry. The invoice registry
// wraps the persistent on-disk invoice storage with an additional in-memory
// layer. The in-memory layer is in place such that debug invoices can be added
// which are volatile yet available system wide within the daemon.
func NewRegistry(cdb *channeldb.DB, decodeFinalCltvExpiry func(invoice string) (
uint32, error)) *InvoiceRegistry {
return &InvoiceRegistry{
cdb: cdb,
debugInvoices: make(map[lntypes.Hash]*channeldb.Invoice),
notificationClients: make(map[uint32]*InvoiceSubscription),
singleNotificationClients: make(map[uint32]*SingleInvoiceSubscription),
newSubscriptions: make(chan *InvoiceSubscription),
newSingleSubscriptions: make(chan *SingleInvoiceSubscription),
subscriptionCancels: make(chan uint32),
invoiceEvents: make(chan *invoiceEvent, 100),
hodlSubscriptions: make(map[lntypes.Hash]map[chan<- interface{}]struct{}),
hodlReverseSubscriptions: make(map[chan<- interface{}]map[lntypes.Hash]struct{}),
decodeFinalCltvExpiry: decodeFinalCltvExpiry,
quit: make(chan struct{}),
}
}
// Start starts the registry and all goroutines it needs to carry out its task.
func (i *InvoiceRegistry) Start() error {
i.wg.Add(1)
go i.invoiceEventNotifier()
return nil
}
// Stop signals the registry for a graceful shutdown.
func (i *InvoiceRegistry) Stop() {
close(i.quit)
i.wg.Wait()
}
// invoiceEvent represents a new event that has modified on invoice on disk.
// Only two event types are currently supported: newly created invoices, and
// instance where invoices are settled.
type invoiceEvent struct {
state channeldb.ContractState
hash lntypes.Hash
invoice *channeldb.Invoice
}
// invoiceEventNotifier is the dedicated goroutine responsible for accepting
// new notification subscriptions, cancelling old subscriptions, and
// dispatching new invoice events.
func (i *InvoiceRegistry) invoiceEventNotifier() {
defer i.wg.Done()
for {
select {
// A new invoice subscription for all invoices has just arrived!
// We'll query for any backlog notifications, then add it to the
// set of clients.
case newClient := <-i.newSubscriptions:
// Before we add the client to our set of active
// clients, we'll first attempt to deliver any backlog
// invoice events.
err := i.deliverBacklogEvents(newClient)
if err != nil {
log.Errorf("unable to deliver backlog invoice "+
"notifications: %v", err)
}
log.Infof("New invoice subscription "+
"client: id=%v", newClient.id)
// With the backlog notifications delivered (if any),
// we'll add this to our active subscriptions and
// continue.
i.notificationClients[newClient.id] = newClient
// A new single invoice subscription has arrived. We'll query
// for any backlog notifications, then add it to the set of
// clients.
case newClient := <-i.newSingleSubscriptions:
err := i.deliverSingleBacklogEvents(newClient)
if err != nil {
log.Errorf("Unable to deliver backlog invoice "+
"notifications: %v", err)
}
log.Infof("New single invoice subscription "+
"client: id=%v, hash=%v",
newClient.id, newClient.hash,
)
i.singleNotificationClients[newClient.id] = newClient
// A client no longer wishes to receive invoice notifications.
// So we'll remove them from the set of active clients.
case clientID := <-i.subscriptionCancels:
log.Infof("Cancelling invoice subscription for "+
"client=%v", clientID)
delete(i.notificationClients, clientID)
delete(i.singleNotificationClients, clientID)
// A sub-systems has just modified the invoice state, so we'll
// dispatch notifications to all registered clients.
case event := <-i.invoiceEvents:
// For backwards compatibility, do not notify all
// invoice subscribers of cancel and accept events.
if event.state != channeldb.ContractCanceled &&
event.state != channeldb.ContractAccepted {
i.dispatchToClients(event)
}
i.dispatchToSingleClients(event)
case <-i.quit:
return
}
}
}
// dispatchToSingleClients passes the supplied event to all notification clients
// that subscribed to all the invoice this event applies to.
func (i *InvoiceRegistry) dispatchToSingleClients(event *invoiceEvent) {
// Dispatch to single invoice subscribers.
for _, client := range i.singleNotificationClients {
if client.hash != event.hash {
continue
}
select {
case client.ntfnQueue.ChanIn() <- &invoiceEvent{
state: event.state,
invoice: event.invoice,
}:
case <-i.quit:
return
}
}
}
// dispatchToClients passes the supplied event to all notification clients that
// subscribed to all invoices. Add and settle indices are used to make sure that
// clients don't receive duplicate or unwanted events.
func (i *InvoiceRegistry) dispatchToClients(event *invoiceEvent) {
invoice := event.invoice
for clientID, client := range i.notificationClients {
// Before we dispatch this event, we'll check
// to ensure that this client hasn't already
// received this notification in order to
// ensure we don't duplicate any events.
// TODO(joostjager): Refactor switches.
switch {
// If we've already sent this settle event to
// the client, then we can skip this.
case event.state == channeldb.ContractSettled &&
client.settleIndex >= invoice.SettleIndex:
continue
// Similarly, if we've already sent this add to
// the client then we can skip this one.
case event.state == channeldb.ContractOpen &&
client.addIndex >= invoice.AddIndex:
continue
// These two states should never happen, but we
// log them just in case so we can detect this
// instance.
case event.state == channeldb.ContractOpen &&
client.addIndex+1 != invoice.AddIndex:
log.Warnf("client=%v for invoice "+
"notifications missed an update, "+
"add_index=%v, new add event index=%v",
clientID, client.addIndex,
invoice.AddIndex)
case event.state == channeldb.ContractSettled &&
client.settleIndex+1 != invoice.SettleIndex:
log.Warnf("client=%v for invoice "+
"notifications missed an update, "+
"settle_index=%v, new settle event index=%v",
clientID, client.settleIndex,
invoice.SettleIndex)
}
select {
case client.ntfnQueue.ChanIn() <- &invoiceEvent{
state: event.state,
invoice: invoice,
}:
case <-i.quit:
return
}
// Each time we send a notification to a client, we'll record
// the latest add/settle index it has. We'll use this to ensure
// we don't send a notification twice, which can happen if a new
// event is added while we're catching up a new client.
switch event.state {
case channeldb.ContractSettled:
client.settleIndex = invoice.SettleIndex
case channeldb.ContractOpen:
client.addIndex = invoice.AddIndex
default:
log.Errorf("unexpected invoice state: %v", event.state)
}
}
}
// deliverBacklogEvents will attempts to query the invoice database for any
// notifications that the client has missed since it reconnected last.
func (i *InvoiceRegistry) deliverBacklogEvents(client *InvoiceSubscription) error {
// First, we'll query the database to see if based on the provided
// addIndex and settledIndex we need to deliver any backlog
// notifications.
addEvents, err := i.cdb.InvoicesAddedSince(client.addIndex)
if err != nil {
return err
}
settleEvents, err := i.cdb.InvoicesSettledSince(client.settleIndex)
if err != nil {
return err
}
// If we have any to deliver, then we'll append them to the end of the
// notification queue in order to catch up the client before delivering
// any new notifications.
for _, addEvent := range addEvents {
// We re-bind the loop variable to ensure we don't hold onto
// the loop reference causing is to point to the same item.
addEvent := addEvent
select {
case client.ntfnQueue.ChanIn() <- &invoiceEvent{
state: channeldb.ContractOpen,
invoice: &addEvent,
}:
case <-i.quit:
return fmt.Errorf("registry shutting down")
}
}
for _, settleEvent := range settleEvents {
// We re-bind the loop variable to ensure we don't hold onto
// the loop reference causing is to point to the same item.
settleEvent := settleEvent
select {
case client.ntfnQueue.ChanIn() <- &invoiceEvent{
state: channeldb.ContractSettled,
invoice: &settleEvent,
}:
case <-i.quit:
return fmt.Errorf("registry shutting down")
}
}
return nil
}
// deliverSingleBacklogEvents will attempt to query the invoice database to
// retrieve the current invoice state and deliver this to the subscriber. Single
// invoice subscribers will always receive the current state right after
// subscribing. Only in case the invoice does not yet exist, nothing is sent
// yet.
func (i *InvoiceRegistry) deliverSingleBacklogEvents(
client *SingleInvoiceSubscription) error {
invoice, err := i.cdb.LookupInvoice(client.hash)
// It is possible that the invoice does not exist yet, but the client is
// already watching it in anticipation.
if err == channeldb.ErrInvoiceNotFound {
return nil
}
if err != nil {
return err
}
err = client.notify(&invoiceEvent{
hash: client.hash,
invoice: &invoice,
state: invoice.Terms.State,
})
if err != nil {
return err
}
return nil
}
// AddDebugInvoice adds a debug invoice for the specified amount, identified
// by the passed preimage. Once this invoice is added, subsystems within the
// daemon add/forward HTLCs that are able to obtain the proper preimage
// required for redemption in the case that we're the final destination.
func (i *InvoiceRegistry) AddDebugInvoice(amt btcutil.Amount,
preimage lntypes.Preimage) {
paymentHash := preimage.Hash()
invoice := &channeldb.Invoice{
CreationDate: time.Now(),
Terms: channeldb.ContractTerm{
Value: lnwire.NewMSatFromSatoshis(amt),
PaymentPreimage: preimage,
},
}
i.Lock()
i.debugInvoices[paymentHash] = invoice
i.Unlock()
log.Debugf("Adding debug invoice %v", newLogClosure(func() string {
return spew.Sdump(invoice)
}))
}
// AddInvoice adds a regular invoice for the specified amount, identified by
// the passed preimage. Additionally, any memo or receipt data provided will
// also be stored on-disk. Once this invoice is added, subsystems within the
// daemon add/forward HTLCs are able to obtain the proper preimage required for
// redemption in the case that we're the final destination. We also return the
// addIndex of the newly created invoice which monotonically increases for each
// new invoice added. A side effect of this function is that it also sets
// AddIndex on the invoice argument.
func (i *InvoiceRegistry) AddInvoice(invoice *channeldb.Invoice,
paymentHash lntypes.Hash) (uint64, error) {
i.Lock()
defer i.Unlock()
log.Debugf("Adding invoice %v", newLogClosure(func() string {
return spew.Sdump(invoice)
}))
addIndex, err := i.cdb.AddInvoice(invoice, paymentHash)
if err != nil {
return 0, err
}
// Now that we've added the invoice, we'll send dispatch a message to
// notify the clients of this new invoice.
i.notifyClients(paymentHash, invoice, channeldb.ContractOpen)
return addIndex, nil
}
// LookupInvoice looks up an invoice by its payment hash (R-Hash), if found
// then we're able to pull the funds pending within an HTLC. We'll also return
// what the expected min final CLTV delta is, pre-parsed from the payment
// request. This may be used by callers to determine if an HTLC is well formed
// according to the cltv delta.
//
// TODO(roasbeef): ignore if settled?
func (i *InvoiceRegistry) LookupInvoice(rHash lntypes.Hash) (channeldb.Invoice, uint32, error) {
// First check the in-memory debug invoice index to see if this is an
// existing invoice added for debugging.
i.RLock()
debugInv, ok := i.debugInvoices[rHash]
i.RUnlock()
// If found, then simply return the invoice directly.
if ok {
return *debugInv, 0, nil
}
// Otherwise, we'll check the database to see if there's an existing
// matching invoice.
invoice, err := i.cdb.LookupInvoice(rHash)
if err != nil {
return channeldb.Invoice{}, 0, err
}
expiry, err := i.decodeFinalCltvExpiry(string(invoice.PaymentRequest))
if err != nil {
return channeldb.Invoice{}, 0, err
}
return invoice, expiry, nil
}
// NotifyExitHopHtlc attempts to mark an invoice as settled. If the invoice is a
// debug invoice, then this method is a noop as debug invoices are never fully
// settled. The return value describes how the htlc should be resolved.
//
// When the preimage of the invoice is not yet known (hodl invoice), this
// function moves the invoice to the accepted state. When SettleHoldInvoice is
// called later, a resolution message will be send back to the caller via the
// provided hodlChan. Invoice registry sends on this channel what action needs
// to be taken on the htlc (settle or cancel). The caller needs to ensure that
// the channel is either buffered or received on from another goroutine to
// prevent deadlock.
func (i *InvoiceRegistry) NotifyExitHopHtlc(rHash lntypes.Hash,
amtPaid lnwire.MilliSatoshi, hodlChan chan<- interface{}) (
*HodlEvent, error) {
i.Lock()
defer i.Unlock()
log.Debugf("Settling invoice %x", rHash[:])
createEvent := func(preimage *lntypes.Preimage) *HodlEvent {
return &HodlEvent{
Hash: rHash,
Preimage: preimage,
}
}
// First check the in-memory debug invoice index to see if this is an
// existing invoice added for debugging.
if invoice, ok := i.debugInvoices[rHash]; ok {
// Debug invoices are never fully settled, so we just settle the
// htlc in this case.
return createEvent(&invoice.Terms.PaymentPreimage), nil
}
// If this isn't a debug invoice, then we'll attempt to settle an
// invoice matching this rHash on disk (if one exists).
invoice, err := i.cdb.AcceptOrSettleInvoice(rHash, amtPaid)
switch err {
// If invoice is already settled, settle htlc. This means we accept more
// payments to the same invoice hash.
case channeldb.ErrInvoiceAlreadySettled:
return createEvent(&invoice.Terms.PaymentPreimage), nil
// If invoice is already canceled, cancel htlc.
case channeldb.ErrInvoiceAlreadyCanceled:
return createEvent(nil), nil
// If invoice is already accepted, add this htlc to the list of
// subscribers.
case channeldb.ErrInvoiceAlreadyAccepted:
i.hodlSubscribe(hodlChan, rHash)
return nil, nil
// If this call settled the invoice, settle the htlc. Otherwise
// subscribe for a future hodl event.
case nil:
i.notifyClients(rHash, invoice, invoice.Terms.State)
switch invoice.Terms.State {
case channeldb.ContractSettled:
return createEvent(&invoice.Terms.PaymentPreimage), nil
case channeldb.ContractAccepted:
// Subscribe to updates to this invoice.
i.hodlSubscribe(hodlChan, rHash)
return nil, nil
default:
return nil, fmt.Errorf("unexpected invoice state %v",
invoice.Terms.State)
}
default:
return nil, err
}
}
// SettleHodlInvoice sets the preimage of a hodl invoice.
func (i *InvoiceRegistry) SettleHodlInvoice(preimage lntypes.Preimage) error {
i.Lock()
defer i.Unlock()
invoice, err := i.cdb.SettleHoldInvoice(preimage)
if err != nil {
log.Errorf("Invoice SetPreimage %v: %v", preimage, err)
return err
}
hash := preimage.Hash()
log.Infof("Notifying clients of set preimage to %v",
invoice.Terms.PaymentPreimage)
i.notifyHodlSubscribers(HodlEvent{
Hash: hash,
Preimage: &preimage,
})
i.notifyClients(hash, invoice, invoice.Terms.State)
return nil
}
// CancelInvoice attempts to cancel the invoice corresponding to the passed
// payment hash.
func (i *InvoiceRegistry) CancelInvoice(payHash lntypes.Hash) error {
i.Lock()
defer i.Unlock()
log.Debugf("Canceling invoice %v", payHash)
invoice, err := i.cdb.CancelInvoice(payHash)
// Implement idempotency by returning success if the invoice was already
// canceled.
if err == channeldb.ErrInvoiceAlreadyCanceled {
log.Debugf("Invoice %v already canceled", payHash)
return nil
}
if err != nil {
return err
}
log.Infof("Invoice %v canceled", payHash)
i.notifyHodlSubscribers(HodlEvent{
Hash: payHash,
})
i.notifyClients(payHash, invoice, channeldb.ContractCanceled)
return nil
}
// notifyClients notifies all currently registered invoice notification clients
// of a newly added/settled invoice.
func (i *InvoiceRegistry) notifyClients(hash lntypes.Hash,
invoice *channeldb.Invoice,
state channeldb.ContractState) {
event := &invoiceEvent{
state: state,
invoice: invoice,
hash: hash,
}
select {
case i.invoiceEvents <- event:
case <-i.quit:
}
}
// invoiceSubscriptionKit defines that are common to both all invoice
// subscribers and single invoice subscribers.
type invoiceSubscriptionKit struct {
id uint32
inv *InvoiceRegistry
ntfnQueue *queue.ConcurrentQueue
cancelled uint32 // To be used atomically.
cancelChan chan struct{}
wg sync.WaitGroup
}
// InvoiceSubscription represents an intent to receive updates for newly added
// or settled invoices. For each newly added invoice, a copy of the invoice
// will be sent over the NewInvoices channel. Similarly, for each newly settled
// invoice, a copy of the invoice will be sent over the SettledInvoices
// channel.
type InvoiceSubscription struct {
invoiceSubscriptionKit
// NewInvoices is a channel that we'll use to send all newly created
// invoices with an invoice index greater than the specified
// StartingInvoiceIndex field.
NewInvoices chan *channeldb.Invoice
// SettledInvoices is a channel that we'll use to send all setted
// invoices with an invoices index greater than the specified
// StartingInvoiceIndex field.
SettledInvoices chan *channeldb.Invoice
// addIndex is the highest add index the caller knows of. We'll use
// this information to send out an event backlog to the notifications
// subscriber. Any new add events with an index greater than this will
// be dispatched before any new notifications are sent out.
addIndex uint64
// settleIndex is the highest settle index the caller knows of. We'll
// use this information to send out an event backlog to the
// notifications subscriber. Any new settle events with an index
// greater than this will be dispatched before any new notifications
// are sent out.
settleIndex uint64
}
// SingleInvoiceSubscription represents an intent to receive updates for a
// specific invoice.
type SingleInvoiceSubscription struct {
invoiceSubscriptionKit
hash lntypes.Hash
// Updates is a channel that we'll use to send all invoice events for
// the invoice that is subscribed to.
Updates chan *channeldb.Invoice
}
// Cancel unregisters the InvoiceSubscription, freeing any previously allocated
// resources.
func (i *invoiceSubscriptionKit) Cancel() {
if !atomic.CompareAndSwapUint32(&i.cancelled, 0, 1) {
return
}
select {
case i.inv.subscriptionCancels <- i.id:
case <-i.inv.quit:
}
i.ntfnQueue.Stop()
close(i.cancelChan)
i.wg.Wait()
}
func (i *invoiceSubscriptionKit) notify(event *invoiceEvent) error {
select {
case i.ntfnQueue.ChanIn() <- event:
case <-i.inv.quit:
return fmt.Errorf("registry shutting down")
}
return nil
}
// SubscribeNotifications returns an InvoiceSubscription which allows the
// caller to receive async notifications when any invoices are settled or
// added. The invoiceIndex parameter is a streaming "checkpoint". We'll start
// by first sending out all new events with an invoice index _greater_ than
// this value. Afterwards, we'll send out real-time notifications.
func (i *InvoiceRegistry) SubscribeNotifications(addIndex, settleIndex uint64) *InvoiceSubscription {
client := &InvoiceSubscription{
NewInvoices: make(chan *channeldb.Invoice),
SettledInvoices: make(chan *channeldb.Invoice),
addIndex: addIndex,
settleIndex: settleIndex,
invoiceSubscriptionKit: invoiceSubscriptionKit{
inv: i,
ntfnQueue: queue.NewConcurrentQueue(20),
cancelChan: make(chan struct{}),
},
}
client.ntfnQueue.Start()
i.clientMtx.Lock()
client.id = i.nextClientID
i.nextClientID++
i.clientMtx.Unlock()
// Before we register this new invoice subscription, we'll launch a new
// goroutine that will proxy all notifications appended to the end of
// the concurrent queue to the two client-side channels the caller will
// feed off of.
i.wg.Add(1)
go func() {
defer i.wg.Done()
for {
select {
// A new invoice event has been sent by the
// invoiceRegistry! We'll figure out if this is an add
// event or a settle event, then dispatch the event to
// the client.
case ntfn := <-client.ntfnQueue.ChanOut():
invoiceEvent := ntfn.(*invoiceEvent)
var targetChan chan *channeldb.Invoice
switch invoiceEvent.state {
case channeldb.ContractOpen:
targetChan = client.NewInvoices
case channeldb.ContractSettled:
targetChan = client.SettledInvoices
default:
log.Errorf("unknown invoice "+
"state: %v", invoiceEvent.state)
continue
}
select {
case targetChan <- invoiceEvent.invoice:
case <-client.cancelChan:
return
case <-i.quit:
return
}
case <-client.cancelChan:
return
case <-i.quit:
return
}
}
}()
select {
case i.newSubscriptions <- client:
case <-i.quit:
}
return client
}
// SubscribeSingleInvoice returns an SingleInvoiceSubscription which allows the
// caller to receive async notifications for a specific invoice.
func (i *InvoiceRegistry) SubscribeSingleInvoice(
hash lntypes.Hash) *SingleInvoiceSubscription {
client := &SingleInvoiceSubscription{
Updates: make(chan *channeldb.Invoice),
invoiceSubscriptionKit: invoiceSubscriptionKit{
inv: i,
ntfnQueue: queue.NewConcurrentQueue(20),
cancelChan: make(chan struct{}),
},
hash: hash,
}
client.ntfnQueue.Start()
i.clientMtx.Lock()
client.id = i.nextClientID
i.nextClientID++
i.clientMtx.Unlock()
// Before we register this new invoice subscription, we'll launch a new
// goroutine that will proxy all notifications appended to the end of
// the concurrent queue to the two client-side channels the caller will
// feed off of.
i.wg.Add(1)
go func() {
defer i.wg.Done()
for {
select {
// A new invoice event has been sent by the
// invoiceRegistry. We will dispatch the event to the
// client.
case ntfn := <-client.ntfnQueue.ChanOut():
invoiceEvent := ntfn.(*invoiceEvent)
select {
case client.Updates <- invoiceEvent.invoice:
case <-client.cancelChan:
return
case <-i.quit:
return
}
case <-client.cancelChan:
return
case <-i.quit:
return
}
}
}()
select {
case i.newSingleSubscriptions <- client:
case <-i.quit:
}
return client
}
// notifyHodlSubscribers sends out the hodl event to all current subscribers.
func (i *InvoiceRegistry) notifyHodlSubscribers(hodlEvent HodlEvent) {
subscribers, ok := i.hodlSubscriptions[hodlEvent.Hash]
if !ok {
return
}
// Notify all interested subscribers and remove subscription from both
// maps. The subscription can be removed as there only ever will be a
// single resolution for each hash.
for subscriber := range subscribers {
select {
case subscriber <- hodlEvent:
case <-i.quit:
return
}
delete(i.hodlReverseSubscriptions[subscriber], hodlEvent.Hash)
}
delete(i.hodlSubscriptions, hodlEvent.Hash)
}
// hodlSubscribe adds a new invoice subscription.
func (i *InvoiceRegistry) hodlSubscribe(subscriber chan<- interface{},
hash lntypes.Hash) {
log.Debugf("Hodl subscribe for %v", hash)
subscriptions, ok := i.hodlSubscriptions[hash]
if !ok {
subscriptions = make(map[chan<- interface{}]struct{})
i.hodlSubscriptions[hash] = subscriptions
}
subscriptions[subscriber] = struct{}{}
reverseSubscriptions, ok := i.hodlReverseSubscriptions[subscriber]
if !ok {
reverseSubscriptions = make(map[lntypes.Hash]struct{})
i.hodlReverseSubscriptions[subscriber] = reverseSubscriptions
}
reverseSubscriptions[hash] = struct{}{}
}
// HodlUnsubscribeAll cancels the subscription.
func (i *InvoiceRegistry) HodlUnsubscribeAll(subscriber chan<- interface{}) {
i.Lock()
defer i.Unlock()
hashes := i.hodlReverseSubscriptions[subscriber]
for hash := range hashes {
delete(i.hodlSubscriptions[hash], subscriber)
}
delete(i.hodlReverseSubscriptions, subscriber)
}