lnd.xprv/chainntnfs/txnotifier.go

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package chainntnfs
import (
"bytes"
"errors"
"fmt"
"sync"
"github.com/btcsuite/btcd/chaincfg/chainhash"
"github.com/btcsuite/btcd/txscript"
"github.com/btcsuite/btcd/wire"
"github.com/btcsuite/btcutil"
"github.com/lightningnetwork/lnd/channeldb"
)
const (
// ReorgSafetyLimit is the chain depth beyond which it is assumed a
// block will not be reorganized out of the chain. This is used to
// determine when to prune old confirmation requests so that reorgs are
// handled correctly. The average number of blocks in a day is a
// reasonable value to use.
ReorgSafetyLimit = 144
// MaxNumConfs is the maximum number of confirmations that can be
// requested on a transaction.
MaxNumConfs = ReorgSafetyLimit
)
var (
// ZeroHash is the value that should be used as the txid when
// registering for the confirmation of a script on-chain. This allows
// the notifier to match _and_ dispatch upon the inclusion of the script
// on-chain, rather than the txid.
ZeroHash chainhash.Hash
// ZeroOutPoint is the value that should be used as the outpoint when
// registering for the spend of a script on-chain. This allows the
// notifier to match _and_ dispatch upon detecting the spend of the
// script on-chain, rather than the outpoint.
ZeroOutPoint wire.OutPoint
)
var (
// ErrTxNotifierExiting is an error returned when attempting to interact
// with the TxNotifier but it been shut down.
ErrTxNotifierExiting = errors.New("TxNotifier is exiting")
// ErrTxMaxConfs signals that the user requested a number of
// confirmations beyond the reorg safety limit.
2018-12-05 03:58:54 +03:00
ErrTxMaxConfs = fmt.Errorf("too many confirmations requested, max is %d",
MaxNumConfs)
)
// rescanState indicates the progression of a registration before the notifier
// can begin dispatching confirmations at tip.
type rescanState byte
const (
// rescanNotStarted is the initial state, denoting that a historical
// dispatch may be required.
rescanNotStarted rescanState = iota
// rescanPending indicates that a dispatch has already been made, and we
// are waiting for its completion. No other rescans should be dispatched
// while in this state.
rescanPending
// rescanComplete signals either that a rescan was dispatched and has
// completed, or that we began watching at tip immediately. In either
// case, the notifier can only dispatch notifications from tip when in
// this state.
rescanComplete
)
// confNtfnSet holds all known, registered confirmation notifications for a
// txid/output script. If duplicates notifications are requested, only one
// historical dispatch will be spawned to ensure redundant scans are not
// permitted. A single conf detail will be constructed and dispatched to all
// interested
// clients.
type confNtfnSet struct {
// ntfns keeps tracks of all the active client notification requests for
// a transaction/output script
ntfns map[uint64]*ConfNtfn
// rescanStatus represents the current rescan state for the
// transaction/output script.
rescanStatus rescanState
// details serves as a cache of the confirmation details of a
// transaction that we'll use to determine if a transaction/output
// script has already confirmed at the time of registration.
details *TxConfirmation
}
// newConfNtfnSet constructs a fresh confNtfnSet for a group of clients
// interested in a notification for a particular txid.
func newConfNtfnSet() *confNtfnSet {
return &confNtfnSet{
ntfns: make(map[uint64]*ConfNtfn),
rescanStatus: rescanNotStarted,
}
}
// spendNtfnSet holds all known, registered spend notifications for a spend
// request (outpoint/output script). If duplicate notifications are requested,
// only one historical dispatch will be spawned to ensure redundant scans are
// not permitted.
type spendNtfnSet struct {
// ntfns keeps tracks of all the active client notification requests for
// an outpoint/output script.
ntfns map[uint64]*SpendNtfn
// rescanStatus represents the current rescan state for the spend
// request (outpoint/output script).
rescanStatus rescanState
// details serves as a cache of the spend details for an outpoint/output
// script that we'll use to determine if it has already been spent at
// the time of registration.
details *SpendDetail
}
// newSpendNtfnSet constructs a new spend notification set.
func newSpendNtfnSet() *spendNtfnSet {
return &spendNtfnSet{
ntfns: make(map[uint64]*SpendNtfn),
rescanStatus: rescanNotStarted,
}
}
// ConfRequest encapsulates a request for a confirmation notification of either
// a txid or output script.
type ConfRequest struct {
// TxID is the hash of the transaction for which confirmation
// notifications are requested. If set to a zero hash, then a
// confirmation notification will be dispatched upon inclusion of the
// _script_, rather than the txid.
TxID chainhash.Hash
// PkScript is the public key script of an outpoint created in this
// transaction.
PkScript txscript.PkScript
}
// NewConfRequest creates a request for a confirmation notification of either a
// txid or output script. A nil txid or an allocated ZeroHash can be used to
// dispatch the confirmation notification on the script.
func NewConfRequest(txid *chainhash.Hash, pkScript []byte) (ConfRequest, error) {
var r ConfRequest
outputScript, err := txscript.ParsePkScript(pkScript)
if err != nil {
return r, err
}
// We'll only set a txid for which we'll dispatch a confirmation
// notification on this request if one was provided. Otherwise, we'll
// default to dispatching on the confirmation of the script instead.
if txid != nil {
r.TxID = *txid
}
r.PkScript = outputScript
return r, nil
}
// String returns the string representation of the ConfRequest.
func (r ConfRequest) String() string {
if r.TxID != ZeroHash {
return fmt.Sprintf("txid=%v", r.TxID)
}
return fmt.Sprintf("script=%v", r.PkScript)
}
// ConfHintKey returns the key that will be used to index the confirmation
// request's hint within the height hint cache.
func (r ConfRequest) ConfHintKey() ([]byte, error) {
if r.TxID == ZeroHash {
return r.PkScript.Script(), nil
}
var txid bytes.Buffer
if err := channeldb.WriteElement(&txid, r.TxID); err != nil {
return nil, err
}
return txid.Bytes(), nil
}
// MatchesTx determines whether the given transaction satisfies the confirmation
// request. If the confirmation request is for a script, then we'll check all of
// the outputs of the transaction to determine if it matches. Otherwise, we'll
// match on the txid.
func (r ConfRequest) MatchesTx(tx *wire.MsgTx) bool {
scriptMatches := func() bool {
pkScript := r.PkScript.Script()
for _, txOut := range tx.TxOut {
if bytes.Equal(txOut.PkScript, pkScript) {
return true
}
}
return false
}
if r.TxID != ZeroHash {
return r.TxID == tx.TxHash() && scriptMatches()
}
return scriptMatches()
}
// ConfNtfn represents a notifier client's request to receive a notification
2019-05-05 01:35:37 +03:00
// once the target transaction/output script gets sufficient confirmations. The
// client is asynchronously notified via the ConfirmationEvent channels.
type ConfNtfn struct {
// ConfID uniquely identifies the confirmation notification request for
// the specified transaction/output script.
ConfID uint64
// ConfRequest represents either the txid or script we should detect
// inclusion of within the chain.
ConfRequest
// NumConfirmations is the number of confirmations after which the
// notification is to be sent.
NumConfirmations uint32
// Event contains references to the channels that the notifications are to
// be sent over.
Event *ConfirmationEvent
// HeightHint is the minimum height in the chain that we expect to find
// this txid.
HeightHint uint32
// dispatched is false if the confirmed notification has not been sent yet.
dispatched bool
}
// HistoricalConfDispatch parameterizes a manual rescan for a particular
// transaction/output script. The parameters include the start and end block
// heights specifying the range of blocks to scan.
type HistoricalConfDispatch struct {
// ConfRequest represents either the txid or script we should detect
// inclusion of within the chain.
ConfRequest
// StartHeight specifies the block height at which to being the
// historical rescan.
StartHeight uint32
// EndHeight specifies the last block height (inclusive) that the
// historical scan should consider.
EndHeight uint32
}
// SpendRequest encapsulates a request for a spend notification of either an
// outpoint or output script.
type SpendRequest struct {
// OutPoint is the outpoint for which a client has requested a spend
// notification for. If set to a zero outpoint, then a spend
// notification will be dispatched upon detecting the spend of the
// _script_, rather than the outpoint.
OutPoint wire.OutPoint
// PkScript is the script of the outpoint. If a zero outpoint is set,
// then this can be an arbitrary script.
PkScript txscript.PkScript
}
// NewSpendRequest creates a request for a spend notification of either an
// outpoint or output script. A nil outpoint or an allocated ZeroOutPoint can be
// used to dispatch the confirmation notification on the script.
func NewSpendRequest(op *wire.OutPoint, pkScript []byte) (SpendRequest, error) {
var r SpendRequest
outputScript, err := txscript.ParsePkScript(pkScript)
if err != nil {
return r, err
}
// We'll only set an outpoint for which we'll dispatch a spend
// notification on this request if one was provided. Otherwise, we'll
// default to dispatching on the spend of the script instead.
if op != nil {
r.OutPoint = *op
}
r.PkScript = outputScript
return r, nil
}
// String returns the string representation of the SpendRequest.
func (r SpendRequest) String() string {
if r.OutPoint != ZeroOutPoint {
return fmt.Sprintf("outpoint=%v", r.OutPoint)
}
return fmt.Sprintf("script=%v", r.PkScript)
}
// SpendHintKey returns the key that will be used to index the spend request's
// hint within the height hint cache.
func (r SpendRequest) SpendHintKey() ([]byte, error) {
if r.OutPoint == ZeroOutPoint {
return r.PkScript.Script(), nil
}
var outpoint bytes.Buffer
err := channeldb.WriteElement(&outpoint, r.OutPoint)
if err != nil {
return nil, err
}
return outpoint.Bytes(), nil
}
// MatchesTx determines whether the given transaction satisfies the spend
// request. If the spend request is for an outpoint, then we'll check all of
// the outputs being spent by the inputs of the transaction to determine if it
// matches. Otherwise, we'll need to match on the output script being spent, so
// we'll recompute it for each input of the transaction to determine if it
// matches.
func (r SpendRequest) MatchesTx(tx *wire.MsgTx) (bool, uint32, error) {
if r.OutPoint != ZeroOutPoint {
for i, txIn := range tx.TxIn {
if txIn.PreviousOutPoint == r.OutPoint {
return true, uint32(i), nil
}
}
return false, 0, nil
}
for i, txIn := range tx.TxIn {
pkScript, err := txscript.ComputePkScript(
txIn.SignatureScript, txIn.Witness,
)
if err == txscript.ErrUnsupportedScriptType {
continue
}
if err != nil {
return false, 0, err
}
if bytes.Equal(pkScript.Script(), r.PkScript.Script()) {
return true, uint32(i), nil
}
}
return false, 0, nil
}
// SpendNtfn represents a client's request to receive a notification once an
// outpoint/output script has been spent on-chain. The client is asynchronously
// notified via the SpendEvent channels.
type SpendNtfn struct {
// SpendID uniquely identies the spend notification request for the
// specified outpoint/output script.
SpendID uint64
// SpendRequest represents either the outpoint or script we should
// detect the spend of.
SpendRequest
// Event contains references to the channels that the notifications are
// to be sent over.
Event *SpendEvent
// HeightHint is the earliest height in the chain that we expect to find
// the spending transaction of the specified outpoint/output script.
// This value will be overridden by the spend hint cache if it contains
// an entry for it.
HeightHint uint32
// dispatched signals whether a spend notification has been disptached
// to the client.
dispatched bool
}
// HistoricalSpendDispatch parameterizes a manual rescan to determine the
// spending details (if any) of an outpoint/output script. The parameters
// include the start and end block heights specifying the range of blocks to
// scan.
type HistoricalSpendDispatch struct {
// SpendRequest represents either the outpoint or script we should
// detect the spend of.
SpendRequest
// StartHeight specified the block height at which to begin the
// historical rescan.
StartHeight uint32
// EndHeight specifies the last block height (inclusive) that the
// historical rescan should consider.
EndHeight uint32
}
// TxNotifier is a struct responsible for delivering transaction notifications
// to subscribers. These notifications can be of two different types:
// transaction/output script confirmations and/or outpoint/output script spends.
// The TxNotifier will watch the blockchain as new blocks come in, in order to
// satisfy its client requests.
type TxNotifier struct {
// currentHeight is the height of the tracked blockchain. It is used to
// determine the number of confirmations a tx has and ensure blocks are
// connected and disconnected in order.
currentHeight uint32
// reorgSafetyLimit is the chain depth beyond which it is assumed a
// block will not be reorganized out of the chain. This is used to
// determine when to prune old notification requests so that reorgs are
// handled correctly. The coinbase maturity period is a reasonable value
// to use.
reorgSafetyLimit uint32
// reorgDepth is the depth of a chain organization that this system is
// being informed of. This is incremented as long as a sequence of
// blocks are disconnected without being interrupted by a new block.
reorgDepth uint32
// confNotifications is an index of confirmation notification requests
// by transaction hash/output script.
confNotifications map[ConfRequest]*confNtfnSet
// confsByInitialHeight is an index of watched transactions/output
// scripts by the height that they are included at in the chain. This
// is tracked so that incorrect notifications are not sent if a
// transaction/output script is reorged out of the chain and so that
// negative confirmations can be recognized.
confsByInitialHeight map[uint32]map[ConfRequest]struct{}
// ntfnsByConfirmHeight is an index of notification requests by the
// height at which the transaction/output script will have sufficient
// confirmations.
ntfnsByConfirmHeight map[uint32]map[*ConfNtfn]struct{}
// spendNotifications is an index of all active notification requests
// per outpoint/output script.
spendNotifications map[SpendRequest]*spendNtfnSet
// spendsByHeight is an index that keeps tracks of the spending height
// of outpoints/output scripts we are currently tracking notifications
// for. This is used in order to recover from spending transactions
// being reorged out of the chain.
spendsByHeight map[uint32]map[SpendRequest]struct{}
// confirmHintCache is a cache used to maintain the latest height hints
// for transactions/output scripts. Each height hint represents the
// earliest height at which they scripts could have been confirmed
// within the chain.
confirmHintCache ConfirmHintCache
// spendHintCache is a cache used to maintain the latest height hints
// for outpoints/output scripts. Each height hint represents the
// earliest height at which they could have been spent within the chain.
spendHintCache SpendHintCache
// quit is closed in order to signal that the notifier is gracefully
// exiting.
quit chan struct{}
sync.Mutex
}
// NewTxNotifier creates a TxNotifier. The current height of the blockchain is
// accepted as a parameter. The different hint caches (confirm and spend) are
// used as an optimization in order to retrieve a better starting point when
// dispatching a recan for a historical event in the chain.
func NewTxNotifier(startHeight uint32, reorgSafetyLimit uint32,
confirmHintCache ConfirmHintCache,
spendHintCache SpendHintCache) *TxNotifier {
return &TxNotifier{
currentHeight: startHeight,
reorgSafetyLimit: reorgSafetyLimit,
confNotifications: make(map[ConfRequest]*confNtfnSet),
confsByInitialHeight: make(map[uint32]map[ConfRequest]struct{}),
ntfnsByConfirmHeight: make(map[uint32]map[*ConfNtfn]struct{}),
spendNotifications: make(map[SpendRequest]*spendNtfnSet),
spendsByHeight: make(map[uint32]map[SpendRequest]struct{}),
confirmHintCache: confirmHintCache,
spendHintCache: spendHintCache,
quit: make(chan struct{}),
}
}
// RegisterConf handles a new confirmation notification request. The client will
// be notified when the transaction/output script gets a sufficient number of
// confirmations in the blockchain. The registration succeeds if no error is
// returned. If the returned HistoricalConfDispatch is non-nil, the caller is
// responsible for attempting to manually rescan blocks for the txid/output
// script between the start and end heights. The notifier's current height is
// also returned so that backends can request to be notified of confirmations
// from this point forwards.
//
// NOTE: If the transaction/output script has already been included in a block
// on the chain, the confirmation details must be provided with the
// UpdateConfDetails method, otherwise we will wait for the transaction/output
// script to confirm even though it already has.
func (n *TxNotifier) RegisterConf(ntfn *ConfNtfn) (*HistoricalConfDispatch,
uint32, error) {
select {
case <-n.quit:
return nil, 0, ErrTxNotifierExiting
default:
}
// Enforce that we will not dispatch confirmations beyond the reorg
// safety limit.
if ntfn.NumConfirmations > n.reorgSafetyLimit {
return nil, 0, ErrTxMaxConfs
}
// Before proceeding to register the notification, we'll query our
// height hint cache to determine whether a better one exists.
//
// TODO(conner): verify that all submitted height hints are identical.
startHeight := ntfn.HeightHint
hint, err := n.confirmHintCache.QueryConfirmHint(ntfn.ConfRequest)
if err == nil {
if hint > startHeight {
Log.Debugf("Using height hint %d retrieved from cache "+
"for %v instead of %d", hint, ntfn.ConfRequest,
startHeight)
startHeight = hint
}
} else if err != ErrConfirmHintNotFound {
Log.Errorf("Unable to query confirm hint for %v: %v",
ntfn.ConfRequest, err)
}
n.Lock()
defer n.Unlock()
Log.Infof("New confirmation subscription: conf_id=%d, %v, "+
"height_hint=%d", ntfn.ConfID, ntfn.ConfRequest, startHeight)
confSet, ok := n.confNotifications[ntfn.ConfRequest]
if !ok {
// If this is the first registration for this request, construct
// a confSet to coalesce all notifications for the same request.
confSet = newConfNtfnSet()
n.confNotifications[ntfn.ConfRequest] = confSet
}
confSet.ntfns[ntfn.ConfID] = ntfn
switch confSet.rescanStatus {
// A prior rescan has already completed and we are actively watching at
// tip for this request.
case rescanComplete:
// If the confirmation details for this set of notifications has
// already been found, we'll attempt to deliver them immediately
// to this client.
Log.Debugf("Attempting to dispatch confirmation for %v on "+
"registration since rescan has finished",
ntfn.ConfRequest)
return nil, n.currentHeight, n.dispatchConfDetails(
ntfn, confSet.details,
)
// A rescan is already in progress, return here to prevent dispatching
// another. When the rescan returns, this notification's details will be
// updated as well.
case rescanPending:
Log.Debugf("Waiting for pending rescan to finish before "+
"notifying %v at tip", ntfn.ConfRequest)
return nil, n.currentHeight, nil
// If no rescan has been dispatched, attempt to do so now.
case rescanNotStarted:
}
// If the provided or cached height hint indicates that the
// transaction with the given txid/output script is to be confirmed at a
// height greater than the notifier's current height, we'll refrain from
// spawning a historical dispatch.
if startHeight > n.currentHeight {
Log.Debugf("Height hint is above current height, not "+
"dispatching historical confirmation rescan for %v",
ntfn.ConfRequest)
// Set the rescan status to complete, which will allow the
// notifier to start delivering messages for this set
// immediately.
confSet.rescanStatus = rescanComplete
return nil, n.currentHeight, nil
}
Log.Debugf("Dispatching historical confirmation rescan for %v",
ntfn.ConfRequest)
// Construct the parameters for historical dispatch, scanning the range
// of blocks between our best known height hint and the notifier's
// current height. The notifier will begin also watching for
// confirmations at tip starting with the next block.
dispatch := &HistoricalConfDispatch{
ConfRequest: ntfn.ConfRequest,
StartHeight: startHeight,
EndHeight: n.currentHeight,
}
// Set this confSet's status to pending, ensuring subsequent
// registrations don't also attempt a dispatch.
confSet.rescanStatus = rescanPending
return dispatch, n.currentHeight, nil
}
// CancelConf cancels an existing request for a spend notification of an
// outpoint/output script. The request is identified by its spend ID.
func (n *TxNotifier) CancelConf(confRequest ConfRequest, confID uint64) {
select {
case <-n.quit:
return
default:
}
n.Lock()
defer n.Unlock()
confSet, ok := n.confNotifications[confRequest]
if !ok {
return
}
ntfn, ok := confSet.ntfns[confID]
if !ok {
return
}
Log.Infof("Canceling confirmation notification: conf_id=%d, %v", confID,
confRequest)
// We'll close all the notification channels to let the client know
// their cancel request has been fulfilled.
close(ntfn.Event.Confirmed)
close(ntfn.Event.Updates)
close(ntfn.Event.NegativeConf)
delete(confSet.ntfns, confID)
}
// UpdateConfDetails attempts to update the confirmation details for an active
// notification within the notifier. This should only be used in the case of a
// transaction/output script that has confirmed before the notifier's current
// height.
//
// NOTE: The notification should be registered first to ensure notifications are
// dispatched correctly.
func (n *TxNotifier) UpdateConfDetails(confRequest ConfRequest,
details *TxConfirmation) error {
select {
case <-n.quit:
return ErrTxNotifierExiting
default:
}
// Ensure we hold the lock throughout handling the notification to
// prevent the notifier from advancing its height underneath us.
n.Lock()
defer n.Unlock()
// First, we'll determine whether we have an active confirmation
// notification for the given txid/script.
confSet, ok := n.confNotifications[confRequest]
if !ok {
return fmt.Errorf("confirmation notification for %v not found",
confRequest)
}
// If the confirmation details were already found at tip, all existing
// notifications will have been dispatched or queued for dispatch. We
// can exit early to avoid sending too many notifications on the
// buffered channels.
if confSet.details != nil {
return nil
}
// The historical dispatch has been completed for this confSet. We'll
// update the rescan status and cache any details that were found. If
// the details are nil, that implies we did not find them and will
// continue to watch for them at tip.
confSet.rescanStatus = rescanComplete
// The notifier has yet to reach the height at which the
// transaction/output script was included in a block, so we should defer
// until handling it then within ConnectTip.
if details == nil {
Log.Debugf("Confirmation details for %v not found during "+
"historical dispatch, waiting to dispatch at tip",
confRequest)
// We'll commit the current height as the confirm hint to
// prevent another potentially long rescan if we restart before
// a new block comes in.
err := n.confirmHintCache.CommitConfirmHint(
n.currentHeight, confRequest,
)
if err != nil {
// The error is not fatal as this is an optimistic
// optimization, so we'll avoid returning an error.
Log.Debugf("Unable to update confirm hint to %d for "+
"%v: %v", n.currentHeight, confRequest, err)
}
return nil
}
if details.BlockHeight > n.currentHeight {
Log.Debugf("Confirmation details for %v found above current "+
"height, waiting to dispatch at tip", confRequest)
return nil
}
Log.Debugf("Updating confirmation details for %v", confRequest)
err := n.confirmHintCache.CommitConfirmHint(
details.BlockHeight, confRequest,
)
if err != nil {
// The error is not fatal, so we should not return an error to
// the caller.
Log.Errorf("Unable to update confirm hint to %d for %v: %v",
details.BlockHeight, confRequest, err)
}
// Cache the details found in the rescan and attempt to dispatch any
// notifications that have not yet been delivered.
confSet.details = details
for _, ntfn := range confSet.ntfns {
err = n.dispatchConfDetails(ntfn, details)
if err != nil {
return err
}
}
return nil
}
// dispatchConfDetails attempts to cache and dispatch details to a particular
// client if the transaction/output script has sufficiently confirmed. If the
// provided details are nil, this method will be a no-op.
func (n *TxNotifier) dispatchConfDetails(
ntfn *ConfNtfn, details *TxConfirmation) error {
// If no details are provided, return early as we can't dispatch.
if details == nil {
Log.Debugf("Unable to dispatch %v, no details provided",
ntfn.ConfRequest)
return nil
}
// Now, we'll examine whether the transaction/output script of this
// request has reached its required number of confirmations. If it has,
// we'll dispatch a confirmation notification to the caller.
confHeight := details.BlockHeight + ntfn.NumConfirmations - 1
if confHeight <= n.currentHeight {
Log.Infof("Dispatching %v confirmation notification for %v",
ntfn.NumConfirmations, ntfn.ConfRequest)
// We'll send a 0 value to the Updates channel,
// indicating that the transaction/output script has already
// been confirmed.
select {
case ntfn.Event.Updates <- 0:
case <-n.quit:
return ErrTxNotifierExiting
}
select {
case ntfn.Event.Confirmed <- details:
ntfn.dispatched = true
case <-n.quit:
return ErrTxNotifierExiting
}
} else {
Log.Debugf("Queueing %v confirmation notification for %v at tip ",
ntfn.NumConfirmations, ntfn.ConfRequest)
// Otherwise, we'll keep track of the notification
// request by the height at which we should dispatch the
// confirmation notification.
ntfnSet, exists := n.ntfnsByConfirmHeight[confHeight]
if !exists {
ntfnSet = make(map[*ConfNtfn]struct{})
n.ntfnsByConfirmHeight[confHeight] = ntfnSet
}
ntfnSet[ntfn] = struct{}{}
// We'll also send an update to the client of how many
// confirmations are left for the transaction/output script to
// be confirmed.
numConfsLeft := confHeight - n.currentHeight
select {
case ntfn.Event.Updates <- numConfsLeft:
case <-n.quit:
return ErrTxNotifierExiting
}
}
// As a final check, we'll also watch the transaction/output script if
// it's still possible for it to get reorged out of the chain.
reorgSafeHeight := details.BlockHeight + n.reorgSafetyLimit
if reorgSafeHeight > n.currentHeight {
txSet, exists := n.confsByInitialHeight[details.BlockHeight]
if !exists {
txSet = make(map[ConfRequest]struct{})
n.confsByInitialHeight[details.BlockHeight] = txSet
}
txSet[ntfn.ConfRequest] = struct{}{}
}
return nil
}
// RegisterSpend handles a new spend notification request. The client will be
// notified once the outpoint/output script is detected as spent within the
// chain.
//
// The registration succeeds if no error is returned. If the returned
// HistoricalSpendDisaptch is non-nil, the caller is responsible for attempting
// to determine whether the outpoint/output script has been spent between the
// start and end heights. The notifier's current height is also returned so that
// backends can request to be notified of spends from this point forwards.
//
// NOTE: If the outpoint/output script has already been spent within the chain
// before the notifier's current tip, the spend details must be provided with
// the UpdateSpendDetails method, otherwise we will wait for the outpoint/output
// script to be spent at tip, even though it already has.
func (n *TxNotifier) RegisterSpend(ntfn *SpendNtfn) (*HistoricalSpendDispatch,
uint32, error) {
select {
case <-n.quit:
return nil, 0, ErrTxNotifierExiting
default:
}
// Before proceeding to register the notification, we'll query our spend
// hint cache to determine whether a better one exists.
startHeight := ntfn.HeightHint
hint, err := n.spendHintCache.QuerySpendHint(ntfn.SpendRequest)
if err == nil {
if hint > startHeight {
Log.Debugf("Using height hint %d retrieved from cache "+
"for %v instead of %d", hint, ntfn.SpendRequest,
startHeight)
startHeight = hint
}
} else if err != ErrSpendHintNotFound {
Log.Errorf("Unable to query spend hint for %v: %v",
ntfn.SpendRequest, err)
}
n.Lock()
defer n.Unlock()
Log.Infof("New spend subscription: spend_id=%d, %v, height_hint=%d",
ntfn.SpendID, ntfn.SpendRequest, startHeight)
// Keep track of the notification request so that we can properly
// dispatch a spend notification later on.
spendSet, ok := n.spendNotifications[ntfn.SpendRequest]
if !ok {
// If this is the first registration for the request, we'll
// construct a spendNtfnSet to coalesce all notifications.
spendSet = newSpendNtfnSet()
n.spendNotifications[ntfn.SpendRequest] = spendSet
}
spendSet.ntfns[ntfn.SpendID] = ntfn
// We'll now let the caller know whether a historical rescan is needed
// depending on the current rescan status.
switch spendSet.rescanStatus {
// If the spending details for this request have already been determined
// and cached, then we can use them to immediately dispatch the spend
// notification to the client.
case rescanComplete:
Log.Debugf("Attempting to dispatch spend for %v on "+
"registration since rescan has finished",
ntfn.SpendRequest)
return nil, n.currentHeight, n.dispatchSpendDetails(
ntfn, spendSet.details,
)
// If there is an active rescan to determine whether the request has
// been spent, then we won't trigger another one.
case rescanPending:
Log.Debugf("Waiting for pending rescan to finish before "+
"notifying %v at tip", ntfn.SpendRequest)
return nil, n.currentHeight, nil
// Otherwise, we'll fall through and let the caller know that a rescan
// should be dispatched to determine whether the request has already
// been spent.
case rescanNotStarted:
}
// However, if the spend hint, either provided by the caller or
// retrieved from the cache, is found to be at a later height than the
// TxNotifier is aware of, then we'll refrain from dispatching a
// historical rescan and wait for the spend to come in at tip.
if startHeight > n.currentHeight {
Log.Debugf("Spend hint of %d for %v is above current height %d",
startHeight, ntfn.SpendRequest, n.currentHeight)
// We'll also set the rescan status as complete to ensure that
// spend hints for this request get updated upon
// connected/disconnected blocks.
spendSet.rescanStatus = rescanComplete
return nil, n.currentHeight, nil
}
// We'll set the rescan status to pending to ensure subsequent
// notifications don't also attempt a historical dispatch.
spendSet.rescanStatus = rescanPending
Log.Debugf("Dispatching historical spend rescan for %v",
ntfn.SpendRequest)
return &HistoricalSpendDispatch{
SpendRequest: ntfn.SpendRequest,
StartHeight: startHeight,
EndHeight: n.currentHeight,
}, n.currentHeight, nil
}
// CancelSpend cancels an existing request for a spend notification of an
// outpoint/output script. The request is identified by its spend ID.
func (n *TxNotifier) CancelSpend(spendRequest SpendRequest, spendID uint64) {
select {
case <-n.quit:
return
default:
}
n.Lock()
defer n.Unlock()
spendSet, ok := n.spendNotifications[spendRequest]
if !ok {
return
}
ntfn, ok := spendSet.ntfns[spendID]
if !ok {
return
}
Log.Infof("Canceling spend notification: spend_id=%d, %v", spendID,
spendRequest)
// We'll close all the notification channels to let the client know
// their cancel request has been fulfilled.
close(ntfn.Event.Spend)
close(ntfn.Event.Reorg)
close(ntfn.Event.Done)
delete(spendSet.ntfns, spendID)
}
// ProcessRelevantSpendTx processes a transaction provided externally. This will
// check whether the transaction is relevant to the notifier if it spends any
// outpoints/output scripts for which we currently have registered notifications
// for. If it is relevant, spend notifications will be dispatched to the caller.
func (n *TxNotifier) ProcessRelevantSpendTx(tx *btcutil.Tx,
blockHeight uint32) error {
select {
case <-n.quit:
return ErrTxNotifierExiting
default:
}
// Ensure we hold the lock throughout handling the notification to
// prevent the notifier from advancing its height underneath us.
n.Lock()
defer n.Unlock()
// We'll use a channel to coalesce all the spend requests that this
// transaction fulfills.
type spend struct {
request *SpendRequest
details *SpendDetail
}
// We'll set up the onSpend filter callback to gather all the fulfilled
// spends requests within this transaction.
var spends []spend
onSpend := func(request SpendRequest, details *SpendDetail) {
spends = append(spends, spend{&request, details})
}
n.filterTx(tx, nil, blockHeight, nil, onSpend)
// After the transaction has been filtered, we can finally dispatch
// notifications for each request.
for _, spend := range spends {
err := n.updateSpendDetails(*spend.request, spend.details)
if err != nil {
return err
}
}
return nil
}
// UpdateSpendDetails attempts to update the spend details for all active spend
// notification requests for an outpoint/output script. This method should be
// used once a historical scan of the chain has finished. If the historical scan
// did not find a spending transaction for it, the spend details may be nil.
//
// NOTE: A notification request for the outpoint/output script must be
// registered first to ensure notifications are delivered.
func (n *TxNotifier) UpdateSpendDetails(spendRequest SpendRequest,
details *SpendDetail) error {
select {
case <-n.quit:
return ErrTxNotifierExiting
default:
}
// Ensure we hold the lock throughout handling the notification to
// prevent the notifier from advancing its height underneath us.
n.Lock()
defer n.Unlock()
return n.updateSpendDetails(spendRequest, details)
}
// updateSpendDetails attempts to update the spend details for all active spend
// notification requests for an outpoint/output script. This method should be
// used once a historical scan of the chain has finished. If the historical scan
// did not find a spending transaction for it, the spend details may be nil.
//
// NOTE: This method must be called with the TxNotifier's lock held.
func (n *TxNotifier) updateSpendDetails(spendRequest SpendRequest,
details *SpendDetail) error {
// Mark the ongoing historical rescan for this request as finished. This
// will allow us to update the spend hints for it at tip.
spendSet, ok := n.spendNotifications[spendRequest]
if !ok {
return fmt.Errorf("spend notification for %v not found",
spendRequest)
}
// If the spend details have already been found either at tip, then the
// notifications should have already been dispatched, so we can exit
// early to prevent sending duplicate notifications.
if spendSet.details != nil {
return nil
}
// Since the historical rescan has completed for this request, we'll
// mark its rescan status as complete in order to ensure that the
// TxNotifier can properly update its spend hints upon
// connected/disconnected blocks.
spendSet.rescanStatus = rescanComplete
// If the historical rescan was not able to find a spending transaction
// for this request, then we can track the spend at tip.
if details == nil {
// We'll commit the current height as the spend hint to prevent
// another potentially long rescan if we restart before a new
// block comes in.
err := n.spendHintCache.CommitSpendHint(
n.currentHeight, spendRequest,
)
if err != nil {
// The error is not fatal as this is an optimistic
// optimization, so we'll avoid returning an error.
Log.Debugf("Unable to update spend hint to %d for %v: %v",
n.currentHeight, spendRequest, err)
}
return nil
}
// If the historical rescan found the spending transaction for this
// request, but it's at a later height than the notifier (this can
// happen due to latency with the backend during a reorg), then we'll
// defer handling the notification until the notifier has caught up to
// such height.
if uint32(details.SpendingHeight) > n.currentHeight {
return nil
}
// Now that we've determined the request has been spent, we'll commit
// its spending height as its hint in the cache and dispatch
// notifications to all of its respective clients.
err := n.spendHintCache.CommitSpendHint(
uint32(details.SpendingHeight), spendRequest,
)
if err != nil {
// The error is not fatal as this is an optimistic optimization,
// so we'll avoid returning an error.
Log.Debugf("Unable to update spend hint to %d for %v: %v",
details.SpendingHeight, spendRequest, err)
}
spendSet.details = details
for _, ntfn := range spendSet.ntfns {
err := n.dispatchSpendDetails(ntfn, spendSet.details)
if err != nil {
return err
}
}
return nil
}
// dispatchSpendDetails dispatches a spend notification to the client.
//
// NOTE: This must be called with the TxNotifier's lock held.
func (n *TxNotifier) dispatchSpendDetails(ntfn *SpendNtfn, details *SpendDetail) error {
// If there are no spend details to dispatch or if the notification has
// already been dispatched, then we can skip dispatching to this client.
if details == nil || ntfn.dispatched {
return nil
}
Log.Infof("Dispatching confirmed spend notification for %v at height=%d",
ntfn.SpendRequest, n.currentHeight)
select {
case ntfn.Event.Spend <- details:
ntfn.dispatched = true
case <-n.quit:
return ErrTxNotifierExiting
}
return nil
}
// ConnectTip handles a new block extending the current chain. It will go
// through every transaction and determine if it is relevant to any of its
// clients. A transaction can be relevant in either of the following two ways:
//
// 1. One of the inputs in the transaction spends an outpoint/output script
// for which we currently have an active spend registration for.
//
// 2. The transaction has a txid or output script for which we currently have
// an active confirmation registration for.
//
// In the event that the transaction is relevant, a confirmation/spend
// notification will be queued for dispatch to the relevant clients.
// Confirmation notifications will only be dispatched for transactions/output
// scripts that have met the required number of confirmations required by the
// client.
//
// NOTE: In order to actually dispatch the relevant transaction notifications to
// clients, NotifyHeight must be called with the same block height in order to
// maintain correctness.
func (n *TxNotifier) ConnectTip(blockHash *chainhash.Hash, blockHeight uint32,
txns []*btcutil.Tx) error {
select {
case <-n.quit:
return ErrTxNotifierExiting
default:
}
n.Lock()
defer n.Unlock()
if blockHeight != n.currentHeight+1 {
return fmt.Errorf("received blocks out of order: "+
"current height=%d, new height=%d",
n.currentHeight, blockHeight)
}
n.currentHeight++
n.reorgDepth = 0
// First, we'll iterate over all the transactions found in this block to
// determine if it includes any relevant transactions to the TxNotifier.
for _, tx := range txns {
n.filterTx(
tx, blockHash, blockHeight, n.handleConfDetailsAtTip,
n.handleSpendDetailsAtTip,
)
}
// Now that we've determined which requests were confirmed and spent
// within the new block, we can update their entries in their respective
// caches, along with all of our unconfirmed and unspent requests.
n.updateHints(blockHeight)
// Finally, we'll clear the entries from our set of notifications for
// requests that are no longer under the risk of being reorged out of
// the chain.
if blockHeight >= n.reorgSafetyLimit {
matureBlockHeight := blockHeight - n.reorgSafetyLimit
for confRequest := range n.confsByInitialHeight[matureBlockHeight] {
confSet := n.confNotifications[confRequest]
for _, ntfn := range confSet.ntfns {
select {
case ntfn.Event.Done <- struct{}{}:
case <-n.quit:
return ErrTxNotifierExiting
}
}
delete(n.confNotifications, confRequest)
}
delete(n.confsByInitialHeight, matureBlockHeight)
for spendRequest := range n.spendsByHeight[matureBlockHeight] {
spendSet := n.spendNotifications[spendRequest]
for _, ntfn := range spendSet.ntfns {
select {
case ntfn.Event.Done <- struct{}{}:
case <-n.quit:
return ErrTxNotifierExiting
}
}
delete(n.spendNotifications, spendRequest)
}
delete(n.spendsByHeight, matureBlockHeight)
}
return nil
}
// filterTx determines whether the transaction spends or confirms any
// outstanding pending requests. The onConf and onSpend callbacks can be used to
// retrieve all the requests fulfilled by this transaction as they occur.
func (n *TxNotifier) filterTx(tx *btcutil.Tx, blockHash *chainhash.Hash,
blockHeight uint32, onConf func(ConfRequest, *TxConfirmation),
onSpend func(SpendRequest, *SpendDetail)) {
// In order to determine if this transaction is relevant to the
// notifier, we'll check its inputs for any outstanding spend
// requests.
txHash := tx.Hash()
if onSpend != nil {
// notifyDetails is a helper closure that will construct the
// spend details of a request and hand them off to the onSpend
// callback.
notifyDetails := func(spendRequest SpendRequest,
prevOut wire.OutPoint, inputIdx uint32) {
Log.Debugf("Found spend of %v: spend_tx=%v, "+
"block_height=%d", spendRequest, txHash,
blockHeight)
onSpend(spendRequest, &SpendDetail{
SpentOutPoint: &prevOut,
SpenderTxHash: txHash,
SpendingTx: tx.MsgTx(),
SpenderInputIndex: inputIdx,
SpendingHeight: int32(blockHeight),
})
}
for i, txIn := range tx.MsgTx().TxIn {
// We'll re-derive the script of the output being spent
// to determine if the inputs spends any registered
// requests.
prevOut := txIn.PreviousOutPoint
pkScript, err := txscript.ComputePkScript(
txIn.SignatureScript, txIn.Witness,
)
if err != nil {
continue
}
spendRequest := SpendRequest{
OutPoint: prevOut,
PkScript: pkScript,
}
// If we have any, we'll record their spend height so
// that notifications get dispatched to the respective
// clients.
if _, ok := n.spendNotifications[spendRequest]; ok {
notifyDetails(spendRequest, prevOut, uint32(i))
}
spendRequest.OutPoint = ZeroOutPoint
if _, ok := n.spendNotifications[spendRequest]; ok {
notifyDetails(spendRequest, prevOut, uint32(i))
}
}
}
// We'll also check its outputs to determine if there are any
// outstanding confirmation requests.
if onConf != nil {
// notifyDetails is a helper closure that will construct the
// confirmation details of a request and hand them off to the
// onConf callback.
notifyDetails := func(confRequest ConfRequest) {
Log.Debugf("Found initial confirmation of %v: "+
"height=%d, hash=%v", confRequest,
blockHeight, blockHash)
details := &TxConfirmation{
Tx: tx.MsgTx(),
BlockHash: blockHash,
BlockHeight: blockHeight,
TxIndex: uint32(tx.Index()),
}
onConf(confRequest, details)
}
for _, txOut := range tx.MsgTx().TxOut {
// We'll parse the script of the output to determine if
// we have any registered requests for it or the
// transaction itself.
pkScript, err := txscript.ParsePkScript(txOut.PkScript)
if err != nil {
continue
}
confRequest := ConfRequest{
TxID: *txHash,
PkScript: pkScript,
}
// If we have any, we'll record their confirmed height
// so that notifications get dispatched when they
// reaches the clients' desired number of confirmations.
if _, ok := n.confNotifications[confRequest]; ok {
notifyDetails(confRequest)
}
confRequest.TxID = ZeroHash
if _, ok := n.confNotifications[confRequest]; ok {
notifyDetails(confRequest)
}
}
}
}
// handleConfDetailsAtTip tracks the confirmation height of the txid/output
// script in order to properly dispatch a confirmation notification after
// meeting each request's desired number of confirmations for all current and
// future registered clients.
func (n *TxNotifier) handleConfDetailsAtTip(confRequest ConfRequest,
details *TxConfirmation) {
// TODO(wilmer): cancel pending historical rescans if any?
confSet := n.confNotifications[confRequest]
confSet.rescanStatus = rescanComplete
confSet.details = details
for _, ntfn := range confSet.ntfns {
// In the event that this notification was aware that the
// transaction/output script was reorged out of the chain, we'll
// consume the reorg notification if it hasn't been done yet
// already.
select {
case <-ntfn.Event.NegativeConf:
default:
}
// We'll note this client's required number of confirmations so
// that we can notify them when expected.
confHeight := details.BlockHeight + ntfn.NumConfirmations - 1
ntfnSet, exists := n.ntfnsByConfirmHeight[confHeight]
if !exists {
ntfnSet = make(map[*ConfNtfn]struct{})
n.ntfnsByConfirmHeight[confHeight] = ntfnSet
}
ntfnSet[ntfn] = struct{}{}
}
// We'll also note the initial confirmation height in order to correctly
// handle dispatching notifications when the transaction/output script
// gets reorged out of the chain.
txSet, exists := n.confsByInitialHeight[details.BlockHeight]
if !exists {
txSet = make(map[ConfRequest]struct{})
n.confsByInitialHeight[details.BlockHeight] = txSet
}
txSet[confRequest] = struct{}{}
}
// handleSpendDetailsAtTip tracks the spend height of the outpoint/output script
// in order to properly dispatch a spend notification for all current and future
// registered clients.
func (n *TxNotifier) handleSpendDetailsAtTip(spendRequest SpendRequest,
details *SpendDetail) {
// TODO(wilmer): cancel pending historical rescans if any?
spendSet := n.spendNotifications[spendRequest]
spendSet.rescanStatus = rescanComplete
spendSet.details = details
for _, ntfn := range spendSet.ntfns {
// In the event that this notification was aware that the
// spending transaction of its outpoint/output script was
// reorged out of the chain, we'll consume the reorg
// notification if it hasn't been done yet already.
select {
case <-ntfn.Event.Reorg:
default:
}
}
// We'll note the spending height of the request in order to correctly
// handle dispatching notifications when the spending transactions gets
// reorged out of the chain.
spendHeight := uint32(details.SpendingHeight)
opSet, exists := n.spendsByHeight[spendHeight]
if !exists {
opSet = make(map[SpendRequest]struct{})
n.spendsByHeight[spendHeight] = opSet
}
opSet[spendRequest] = struct{}{}
}
// NotifyHeight dispatches confirmation and spend notifications to the clients
// who registered for a notification which has been fulfilled at the passed
// height.
func (n *TxNotifier) NotifyHeight(height uint32) error {
n.Lock()
defer n.Unlock()
// First, we'll dispatch an update to all of the notification clients
// for our watched requests with the number of confirmations left at
// this new height.
for _, confRequests := range n.confsByInitialHeight {
for confRequest := range confRequests {
confSet := n.confNotifications[confRequest]
for _, ntfn := range confSet.ntfns {
txConfHeight := confSet.details.BlockHeight +
ntfn.NumConfirmations - 1
numConfsLeft := txConfHeight - height
// Since we don't clear notifications until
// transactions/output scripts are no longer
// under the risk of being reorganized out of
// the chain, we'll skip sending updates for
// those that have already been confirmed.
if int32(numConfsLeft) < 0 {
continue
}
select {
case ntfn.Event.Updates <- numConfsLeft:
case <-n.quit:
return ErrTxNotifierExiting
}
}
}
}
// Then, we'll dispatch notifications for all the requests that have
// become confirmed at this new block height.
for ntfn := range n.ntfnsByConfirmHeight[height] {
confSet := n.confNotifications[ntfn.ConfRequest]
Log.Infof("Dispatching %v confirmation notification for %v",
ntfn.NumConfirmations, ntfn.ConfRequest)
select {
case ntfn.Event.Confirmed <- confSet.details:
ntfn.dispatched = true
case <-n.quit:
return ErrTxNotifierExiting
}
}
delete(n.ntfnsByConfirmHeight, height)
// Finally, we'll dispatch spend notifications for all the requests that
// were spent at this new block height.
for spendRequest := range n.spendsByHeight[height] {
spendSet := n.spendNotifications[spendRequest]
for _, ntfn := range spendSet.ntfns {
err := n.dispatchSpendDetails(ntfn, spendSet.details)
if err != nil {
return err
}
}
}
return nil
}
// DisconnectTip handles the tip of the current chain being disconnected during
// a chain reorganization. If any watched requests were included in this block,
// internal structures are updated to ensure confirmation/spend notifications
// are consumed (if not already), and reorg notifications are dispatched
// instead. Confirmation/spend notifications will be dispatched again upon block
// inclusion.
func (n *TxNotifier) DisconnectTip(blockHeight uint32) error {
select {
case <-n.quit:
return ErrTxNotifierExiting
default:
}
n.Lock()
defer n.Unlock()
if blockHeight != n.currentHeight {
return fmt.Errorf("Received blocks out of order: "+
"current height=%d, disconnected height=%d",
n.currentHeight, blockHeight)
}
n.currentHeight--
n.reorgDepth++
// With the block disconnected, we'll update the confirm and spend hints
// for our notification requests to reflect the new height, except for
// those that have confirmed/spent at previous heights.
n.updateHints(blockHeight)
// We'll go through all of our watched confirmation requests and attempt
// to drain their notification channels to ensure sending notifications
// to the clients is always non-blocking.
for initialHeight, txHashes := range n.confsByInitialHeight {
for txHash := range txHashes {
// If the transaction/output script has been reorged out
// of the chain, we'll make sure to remove the cached
// confirmation details to prevent notifying clients
// with old information.
confSet := n.confNotifications[txHash]
if initialHeight == blockHeight {
confSet.details = nil
}
for _, ntfn := range confSet.ntfns {
// First, we'll attempt to drain an update
// from each notification to ensure sends to the
// Updates channel are always non-blocking.
select {
case <-ntfn.Event.Updates:
case <-n.quit:
return ErrTxNotifierExiting
default:
}
// Then, we'll check if the current
// transaction/output script was included in the
// block currently being disconnected. If it
// was, we'll need to dispatch a reorg
// notification to the client.
if initialHeight == blockHeight {
err := n.dispatchConfReorg(
ntfn, blockHeight,
)
if err != nil {
return err
}
}
}
}
}
// We'll also go through our watched spend requests and attempt to drain
// their dispatched notifications to ensure dispatching notifications to
// clients later on is always non-blocking. We're only interested in
// requests whose spending transaction was included at the height being
// disconnected.
for op := range n.spendsByHeight[blockHeight] {
// Since the spending transaction is being reorged out of the
// chain, we'll need to clear out the spending details of the
// request.
spendSet := n.spendNotifications[op]
spendSet.details = nil
// For all requests which have had a spend notification
// dispatched, we'll attempt to drain it and send a reorg
// notification instead.
for _, ntfn := range spendSet.ntfns {
if err := n.dispatchSpendReorg(ntfn); err != nil {
return err
}
}
}
// Finally, we can remove the requests that were confirmed and/or spent
// at the height being disconnected. We'll still continue to track them
// until they have been confirmed/spent and are no longer under the risk
// of being reorged out of the chain again.
delete(n.confsByInitialHeight, blockHeight)
delete(n.spendsByHeight, blockHeight)
return nil
}
// updateHints attempts to update the confirm and spend hints for all relevant
// requests respectively. The height parameter is used to determine which
// requests we should update based on whether a new block is being
// connected/disconnected.
//
// NOTE: This must be called with the TxNotifier's lock held and after its
// height has already been reflected by a block being connected/disconnected.
func (n *TxNotifier) updateHints(height uint32) {
// TODO(wilmer): update under one database transaction.
//
// To update the height hint for all the required confirmation requests
// under one database transaction, we'll gather the set of unconfirmed
// requests along with the ones that confirmed at the height being
// connected/disconnected.
confRequests := n.unconfirmedRequests()
for confRequest := range n.confsByInitialHeight[height] {
confRequests = append(confRequests, confRequest)
}
err := n.confirmHintCache.CommitConfirmHint(
n.currentHeight, confRequests...,
)
if err != nil {
// The error is not fatal as this is an optimistic optimization,
// so we'll avoid returning an error.
Log.Debugf("Unable to update confirm hints to %d for "+
"%v: %v", n.currentHeight, confRequests, err)
}
// Similarly, to update the height hint for all the required spend
// requests under one database transaction, we'll gather the set of
// unspent requests along with the ones that were spent at the height
// being connected/disconnected.
spendRequests := n.unspentRequests()
for spendRequest := range n.spendsByHeight[height] {
spendRequests = append(spendRequests, spendRequest)
}
err = n.spendHintCache.CommitSpendHint(n.currentHeight, spendRequests...)
if err != nil {
// The error is not fatal as this is an optimistic optimization,
// so we'll avoid returning an error.
Log.Debugf("Unable to update spend hints to %d for "+
"%v: %v", n.currentHeight, spendRequests, err)
}
}
// unconfirmedRequests returns the set of confirmation requests that are
// still seen as unconfirmed by the TxNotifier.
//
// NOTE: This method must be called with the TxNotifier's lock held.
func (n *TxNotifier) unconfirmedRequests() []ConfRequest {
var unconfirmed []ConfRequest
for confRequest, confNtfnSet := range n.confNotifications {
// If the notification is already aware of its confirmation
// details, or it's in the process of learning them, we'll skip
// it as we can't yet determine if it's confirmed or not.
if confNtfnSet.rescanStatus != rescanComplete ||
confNtfnSet.details != nil {
continue
}
unconfirmed = append(unconfirmed, confRequest)
}
return unconfirmed
}
// unspentRequests returns the set of spend requests that are still seen as
// unspent by the TxNotifier.
//
// NOTE: This method must be called with the TxNotifier's lock held.
func (n *TxNotifier) unspentRequests() []SpendRequest {
var unspent []SpendRequest
for spendRequest, spendNtfnSet := range n.spendNotifications {
// If the notification is already aware of its spend details, or
// it's in the process of learning them, we'll skip it as we
// can't yet determine if it's unspent or not.
if spendNtfnSet.rescanStatus != rescanComplete ||
spendNtfnSet.details != nil {
continue
}
unspent = append(unspent, spendRequest)
}
return unspent
}
// dispatchConfReorg dispatches a reorg notification to the client if the
// confirmation notification was already delivered.
//
// NOTE: This must be called with the TxNotifier's lock held.
func (n *TxNotifier) dispatchConfReorg(ntfn *ConfNtfn,
heightDisconnected uint32) error {
// If the request's confirmation notification has yet to be dispatched,
// we'll need to clear its entry within the ntfnsByConfirmHeight index
// to prevent from notifying the client once the notifier reaches the
// confirmation height.
if !ntfn.dispatched {
confHeight := heightDisconnected + ntfn.NumConfirmations - 1
ntfnSet, exists := n.ntfnsByConfirmHeight[confHeight]
if exists {
delete(ntfnSet, ntfn)
}
return nil
}
// Otherwise, the entry within the ntfnsByConfirmHeight has already been
// deleted, so we'll attempt to drain the confirmation notification to
// ensure sends to the Confirmed channel are always non-blocking.
select {
case <-ntfn.Event.Confirmed:
case <-n.quit:
return ErrTxNotifierExiting
default:
}
ntfn.dispatched = false
// Send a negative confirmation notification to the client indicating
// how many blocks have been disconnected successively.
select {
case ntfn.Event.NegativeConf <- int32(n.reorgDepth):
case <-n.quit:
return ErrTxNotifierExiting
}
return nil
}
// dispatchSpendReorg dispatches a reorg notification to the client if a spend
// notiification was already delivered.
//
// NOTE: This must be called with the TxNotifier's lock held.
func (n *TxNotifier) dispatchSpendReorg(ntfn *SpendNtfn) error {
if !ntfn.dispatched {
return nil
}
// Attempt to drain the spend notification to ensure sends to the Spend
// channel are always non-blocking.
select {
case <-ntfn.Event.Spend:
default:
}
// Send a reorg notification to the client in order for them to
// correctly handle reorgs.
select {
case ntfn.Event.Reorg <- struct{}{}:
case <-n.quit:
return ErrTxNotifierExiting
}
ntfn.dispatched = false
return nil
}
// TearDown is to be called when the owner of the TxNotifier is exiting. This
// closes the event channels of all registered notifications that have not been
// dispatched yet.
func (n *TxNotifier) TearDown() {
n.Lock()
defer n.Unlock()
close(n.quit)
for _, confSet := range n.confNotifications {
for _, ntfn := range confSet.ntfns {
close(ntfn.Event.Confirmed)
close(ntfn.Event.Updates)
close(ntfn.Event.NegativeConf)
close(ntfn.Event.Done)
}
}
for _, spendSet := range n.spendNotifications {
for _, ntfn := range spendSet.ntfns {
close(ntfn.Event.Spend)
close(ntfn.Event.Reorg)
close(ntfn.Event.Done)
}
}
}