lnd.xprv/chainntnfs/interface.go
Wilmer Paulino 87123d5e23
chainntnfs: extend SpendEvent with reorg channel
In this commit, we add a new channel within the SpendEvent struct that
will be sent upon whenever the spending transaction of the registered
outpoint gets reorged out of the chain. This will pave the road for
successfully handling a funding transaction getting reorged out of the
chain among other things.
2018-10-30 17:59:31 -07:00

548 lines
19 KiB
Go

package chainntnfs
import (
"fmt"
"sync"
"github.com/btcsuite/btcd/btcjson"
"github.com/btcsuite/btcd/chaincfg/chainhash"
"github.com/btcsuite/btcd/wire"
)
// TxConfStatus denotes the status of a transaction's lookup.
type TxConfStatus uint8
const (
// TxFoundMempool denotes that the transaction was found within the
// backend node's mempool.
TxFoundMempool TxConfStatus = iota
// TxFoundIndex denotes that the transaction was found within the
// backend node's txindex.
TxFoundIndex
// TxNotFoundIndex denotes that the transaction was not found within the
// backend node's txindex.
TxNotFoundIndex
// TxFoundManually denotes that the transaction was found within the
// chain by scanning for it manually.
TxFoundManually
// TxNotFoundManually denotes that the transaction was not found within
// the chain by scanning for it manually.
TxNotFoundManually
)
// String returns the string representation of the TxConfStatus.
func (t TxConfStatus) String() string {
switch t {
case TxFoundMempool:
return "TxFoundMempool"
case TxFoundIndex:
return "TxFoundIndex"
case TxNotFoundIndex:
return "TxNotFoundIndex"
case TxFoundManually:
return "TxFoundManually"
case TxNotFoundManually:
return "TxNotFoundManually"
default:
return "unknown"
}
}
// ChainNotifier represents a trusted source to receive notifications concerning
// targeted events on the Bitcoin blockchain. The interface specification is
// intentionally general in order to support a wide array of chain notification
// implementations such as: btcd's websockets notifications, Bitcoin Core's
// ZeroMQ notifications, various Bitcoin API services, Electrum servers, etc.
//
// Concrete implementations of ChainNotifier should be able to support multiple
// concurrent client requests, as well as multiple concurrent notification events.
// TODO(roasbeef): all events should have a Cancel() method to free up the
// resource
type ChainNotifier interface {
// RegisterConfirmationsNtfn registers an intent to be notified once
// txid reaches numConfs confirmations. We also pass in the pkScript as
// the default light client instead needs to match on scripts created
// in the block. The returned ConfirmationEvent should properly notify
// the client once the specified number of confirmations has been
// reached for the txid, as well as if the original tx gets re-org'd
// out of the mainchain. The heightHint parameter is provided as a
// convenience to light clients. The heightHint denotes the earliest
// height in the blockchain in which the target txid _could_ have been
// included in the chain. This can be used to bound the search space
// when checking to see if a notification can immediately be dispatched
// due to historical data.
//
// NOTE: Dispatching notifications to multiple clients subscribed to
// the same (txid, numConfs) tuple MUST be supported.
RegisterConfirmationsNtfn(txid *chainhash.Hash, pkScript []byte, numConfs,
heightHint uint32) (*ConfirmationEvent, error)
// RegisterSpendNtfn registers an intent to be notified once the target
// outpoint is successfully spent within a transaction. The script that
// the outpoint creates must also be specified. This allows this
// interface to be implemented by BIP 158-like filtering. The returned
// SpendEvent will receive a send on the 'Spend' transaction once a
// transaction spending the input is detected on the blockchain. The
// heightHint parameter is provided as a convenience to light clients.
// The heightHint denotes the earliest height in the blockchain in
// which the target output could have been created.
//
// NOTE: The notification should only be triggered when the spending
// transaction receives a single confirmation.
//
// NOTE: Dispatching notifications to multiple clients subscribed to a
// spend of the same outpoint MUST be supported.
RegisterSpendNtfn(outpoint *wire.OutPoint, pkScript []byte,
heightHint uint32) (*SpendEvent, error)
// RegisterBlockEpochNtfn registers an intent to be notified of each
// new block connected to the tip of the main chain. The returned
// BlockEpochEvent struct contains a channel which will be sent upon
// for each new block discovered.
//
// Clients have the option of passing in their best known block.
// If they specify a block, the ChainNotifier checks whether the client
// is behind on blocks. If they are, the ChainNotifier sends a backlog
// of block notifications for the missed blocks.
RegisterBlockEpochNtfn(*BlockEpoch) (*BlockEpochEvent, error)
// Start the ChainNotifier. Once started, the implementation should be
// ready, and able to receive notification registrations from clients.
Start() error
// Stops the concrete ChainNotifier. Once stopped, the ChainNotifier
// should disallow any future requests from potential clients.
// Additionally, all pending client notifications will be cancelled
// by closing the related channels on the *Event's.
Stop() error
}
// TxConfirmation carries some additional block-level details of the exact
// block that specified transactions was confirmed within.
type TxConfirmation struct {
// BlockHash is the hash of the block that confirmed the original
// transition.
BlockHash *chainhash.Hash
// BlockHeight is the height of the block in which the transaction was
// confirmed within.
BlockHeight uint32
// TxIndex is the index within the block of the ultimate confirmed
// transaction.
TxIndex uint32
}
// ConfirmationEvent encapsulates a confirmation notification. With this struct,
// callers can be notified of: the instance the target txid reaches the targeted
// number of confirmations, how many confirmations are left for the target txid
// to be fully confirmed at every new block height, and also in the event that
// the original txid becomes disconnected from the blockchain as a result of a
// re-org.
//
// Once the txid reaches the specified number of confirmations, the 'Confirmed'
// channel will be sent upon fulfilling the notification.
//
// If the event that the original transaction becomes re-org'd out of the main
// chain, the 'NegativeConf' will be sent upon with a value representing the
// depth of the re-org.
type ConfirmationEvent struct {
// Confirmed is a channel that will be sent upon once the transaction
// has been fully confirmed. The struct sent will contain all the
// details of the channel's confirmation.
//
// NOTE: This channel must be buffered.
Confirmed chan *TxConfirmation
// Updates is a channel that will sent upon, at every incremental
// confirmation, how many confirmations are left to declare the
// transaction as fully confirmed.
//
// NOTE: This channel must be buffered with the number of required
// confirmations.
Updates chan uint32
// TODO(roasbeef): all goroutines on ln channel updates should also
// have a struct chan that's closed if funding gets re-org out. Need
// to sync, to request another confirmation event ntfn, then re-open
// channel after confs.
// NegativeConf is a channel that will be sent upon if the transaction
// confirms, but is later reorged out of the chain. The integer sent
// through the channel represents the reorg depth.
//
// NOTE: This channel must be buffered.
NegativeConf chan int32
}
// NewConfirmationEvent constructs a new ConfirmationEvent with newly opened
// channels.
func NewConfirmationEvent(numConfs uint32) *ConfirmationEvent {
return &ConfirmationEvent{
Confirmed: make(chan *TxConfirmation, 1),
Updates: make(chan uint32, numConfs),
NegativeConf: make(chan int32, 1),
}
}
// SpendDetail contains details pertaining to a spent output. This struct itself
// is the spentness notification. It includes the original outpoint which triggered
// the notification, the hash of the transaction spending the output, the
// spending transaction itself, and finally the input index which spent the
// target output.
type SpendDetail struct {
SpentOutPoint *wire.OutPoint
SpenderTxHash *chainhash.Hash
SpendingTx *wire.MsgTx
SpenderInputIndex uint32
SpendingHeight int32
}
// SpendEvent encapsulates a spentness notification. Its only field 'Spend' will
// be sent upon once the target output passed into RegisterSpendNtfn has been
// spent on the blockchain.
//
// NOTE: If the caller wishes to cancel their registered spend notification,
// the Cancel closure MUST be called.
type SpendEvent struct {
// Spend is a receive only channel which will be sent upon once the
// target outpoint has been spent.
//
// NOTE: This channel must be buffered.
Spend chan *SpendDetail
// Reorg is a channel that will be sent upon once we detect the spending
// transaction of the outpoint in question has been reorged out of the
// chain.
//
// NOTE: This channel must be buffered.
Reorg chan struct{}
// Cancel is a closure that should be executed by the caller in the
// case that they wish to prematurely abandon their registered spend
// notification.
Cancel func()
}
// NewSpendEvent constructs a new SpendEvent with newly opened channels.
func NewSpendEvent(cancel func()) *SpendEvent {
return &SpendEvent{
Spend: make(chan *SpendDetail, 1),
Reorg: make(chan struct{}, 1),
Cancel: cancel,
}
}
// BlockEpoch represents metadata concerning each new block connected to the
// main chain.
type BlockEpoch struct {
// Hash is the block hash of the latest block to be added to the tip of
// the main chain.
Hash *chainhash.Hash
// Height is the height of the latest block to be added to the tip of
// the main chain.
Height int32
}
// BlockEpochEvent encapsulates an on-going stream of block epoch
// notifications. Its only field 'Epochs' will be sent upon for each new block
// connected to the main-chain.
//
// NOTE: If the caller wishes to cancel their registered block epoch
// notification, the Cancel closure MUST be called.
type BlockEpochEvent struct {
// Epochs is a receive only channel that will be sent upon each time a
// new block is connected to the end of the main chain.
//
// NOTE: This channel must be buffered.
Epochs <-chan *BlockEpoch
// Cancel is a closure that should be executed by the caller in the
// case that they wish to abandon their registered spend notification.
Cancel func()
}
// NotifierDriver represents a "driver" for a particular interface. A driver is
// identified by a globally unique string identifier along with a 'New()'
// method which is responsible for initializing a particular ChainNotifier
// concrete implementation.
type NotifierDriver struct {
// NotifierType is a string which uniquely identifies the ChainNotifier
// that this driver, drives.
NotifierType string
// New creates a new instance of a concrete ChainNotifier
// implementation given a variadic set up arguments. The function takes
// a variadic number of interface parameters in order to provide
// initialization flexibility, thereby accommodating several potential
// ChainNotifier implementations.
New func(args ...interface{}) (ChainNotifier, error)
}
var (
notifiers = make(map[string]*NotifierDriver)
registerMtx sync.Mutex
)
// RegisteredNotifiers returns a slice of all currently registered notifiers.
//
// NOTE: This function is safe for concurrent access.
func RegisteredNotifiers() []*NotifierDriver {
registerMtx.Lock()
defer registerMtx.Unlock()
drivers := make([]*NotifierDriver, 0, len(notifiers))
for _, driver := range notifiers {
drivers = append(drivers, driver)
}
return drivers
}
// RegisterNotifier registers a NotifierDriver which is capable of driving a
// concrete ChainNotifier interface. In the case that this driver has already
// been registered, an error is returned.
//
// NOTE: This function is safe for concurrent access.
func RegisterNotifier(driver *NotifierDriver) error {
registerMtx.Lock()
defer registerMtx.Unlock()
if _, ok := notifiers[driver.NotifierType]; ok {
return fmt.Errorf("notifier already registered")
}
notifiers[driver.NotifierType] = driver
return nil
}
// SupportedNotifiers returns a slice of strings that represent the database
// drivers that have been registered and are therefore supported.
//
// NOTE: This function is safe for concurrent access.
func SupportedNotifiers() []string {
registerMtx.Lock()
defer registerMtx.Unlock()
supportedNotifiers := make([]string, 0, len(notifiers))
for driverName := range notifiers {
supportedNotifiers = append(supportedNotifiers, driverName)
}
return supportedNotifiers
}
// ChainConn enables notifiers to pass in their chain backend to interface
// functions that require it.
type ChainConn interface {
// GetBlockHeader returns the block header for a hash.
GetBlockHeader(blockHash *chainhash.Hash) (*wire.BlockHeader, error)
// GetBlockHeaderVerbose returns the verbose block header for a hash.
GetBlockHeaderVerbose(blockHash *chainhash.Hash) (
*btcjson.GetBlockHeaderVerboseResult, error)
// GetBlockHash returns the hash from a block height.
GetBlockHash(blockHeight int64) (*chainhash.Hash, error)
}
// GetCommonBlockAncestorHeight takes in:
// (1) the hash of a block that has been reorged out of the main chain
// (2) the hash of the block of the same height from the main chain
// It returns the height of the nearest common ancestor between the two hashes,
// or an error
func GetCommonBlockAncestorHeight(chainConn ChainConn, reorgHash,
chainHash chainhash.Hash) (int32, error) {
for reorgHash != chainHash {
reorgHeader, err := chainConn.GetBlockHeader(&reorgHash)
if err != nil {
return 0, fmt.Errorf("unable to get header for hash=%v: %v",
reorgHash, err)
}
chainHeader, err := chainConn.GetBlockHeader(&chainHash)
if err != nil {
return 0, fmt.Errorf("unable to get header for hash=%v: %v",
chainHash, err)
}
reorgHash = reorgHeader.PrevBlock
chainHash = chainHeader.PrevBlock
}
verboseHeader, err := chainConn.GetBlockHeaderVerbose(&chainHash)
if err != nil {
return 0, fmt.Errorf("unable to get verbose header for hash=%v: %v",
chainHash, err)
}
return verboseHeader.Height, nil
}
// GetClientMissedBlocks uses a client's best block to determine what blocks
// it missed being notified about, and returns them in a slice. Its
// backendStoresReorgs parameter tells it whether or not the notifier's
// chainConn stores information about blocks that have been reorged out of the
// chain, which allows GetClientMissedBlocks to find out whether the client's
// best block has been reorged out of the chain, rewind to the common ancestor
// and return blocks starting right after the common ancestor.
func GetClientMissedBlocks(chainConn ChainConn, clientBestBlock *BlockEpoch,
notifierBestHeight int32, backendStoresReorgs bool) ([]BlockEpoch, error) {
startingHeight := clientBestBlock.Height
if backendStoresReorgs {
// If a reorg causes the client's best hash to be incorrect,
// retrieve the closest common ancestor and dispatch
// notifications from there.
hashAtBestHeight, err := chainConn.GetBlockHash(
int64(clientBestBlock.Height))
if err != nil {
return nil, fmt.Errorf("unable to find blockhash for "+
"height=%d: %v", clientBestBlock.Height, err)
}
startingHeight, err = GetCommonBlockAncestorHeight(
chainConn, *clientBestBlock.Hash, *hashAtBestHeight,
)
if err != nil {
return nil, fmt.Errorf("unable to find common ancestor: "+
"%v", err)
}
}
// We want to start dispatching historical notifications from the block
// right after the client's best block, to avoid a redundant notification.
missedBlocks, err := getMissedBlocks(
chainConn, startingHeight+1, notifierBestHeight+1,
)
if err != nil {
return nil, fmt.Errorf("unable to get missed blocks: %v", err)
}
return missedBlocks, nil
}
// RewindChain handles internal state updates for the notifier's TxNotifier It
// has no effect if given a height greater than or equal to our current best
// known height. It returns the new best block for the notifier.
func RewindChain(chainConn ChainConn, txNotifier *TxNotifier,
currBestBlock BlockEpoch, targetHeight int32) (BlockEpoch, error) {
newBestBlock := BlockEpoch{
Height: currBestBlock.Height,
Hash: currBestBlock.Hash,
}
for height := currBestBlock.Height; height > targetHeight; height-- {
hash, err := chainConn.GetBlockHash(int64(height - 1))
if err != nil {
return newBestBlock, fmt.Errorf("unable to "+
"find blockhash for disconnected height=%d: %v",
height, err)
}
Log.Infof("Block disconnected from main chain: "+
"height=%v, sha=%v", height, newBestBlock.Hash)
err = txNotifier.DisconnectTip(uint32(height))
if err != nil {
return newBestBlock, fmt.Errorf("unable to "+
" disconnect tip for height=%d: %v",
height, err)
}
newBestBlock.Height = height - 1
newBestBlock.Hash = hash
}
return newBestBlock, nil
}
// HandleMissedBlocks is called when the chain backend for a notifier misses a
// series of blocks, handling a reorg if necessary. Its backendStoresReorgs
// parameter tells it whether or not the notifier's chainConn stores
// information about blocks that have been reorged out of the chain, which allows
// HandleMissedBlocks to check whether the notifier's best block has been
// reorged out, and rewind the chain accordingly. It returns the best block for
// the notifier and a slice of the missed blocks. The new best block needs to be
// returned in case a chain rewind occurs and partially completes before
// erroring. In the case where there is no rewind, the notifier's
// current best block is returned.
func HandleMissedBlocks(chainConn ChainConn, txNotifier *TxNotifier,
currBestBlock BlockEpoch, newHeight int32,
backendStoresReorgs bool) (BlockEpoch, []BlockEpoch, error) {
startingHeight := currBestBlock.Height
if backendStoresReorgs {
// If a reorg causes our best hash to be incorrect, rewind the
// chain so our best block is set to the closest common
// ancestor, then dispatch notifications from there.
hashAtBestHeight, err :=
chainConn.GetBlockHash(int64(currBestBlock.Height))
if err != nil {
return currBestBlock, nil, fmt.Errorf("unable to find "+
"blockhash for height=%d: %v",
currBestBlock.Height, err)
}
startingHeight, err = GetCommonBlockAncestorHeight(
chainConn, *currBestBlock.Hash, *hashAtBestHeight,
)
if err != nil {
return currBestBlock, nil, fmt.Errorf("unable to find "+
"common ancestor: %v", err)
}
currBestBlock, err = RewindChain(chainConn, txNotifier,
currBestBlock, startingHeight)
if err != nil {
return currBestBlock, nil, fmt.Errorf("unable to "+
"rewind chain: %v", err)
}
}
// We want to start dispatching historical notifications from the block
// right after our best block, to avoid a redundant notification.
missedBlocks, err := getMissedBlocks(chainConn, startingHeight+1, newHeight)
if err != nil {
return currBestBlock, nil, fmt.Errorf("unable to get missed "+
"blocks: %v", err)
}
return currBestBlock, missedBlocks, nil
}
// getMissedBlocks returns a slice of blocks: [startingHeight, endingHeight)
// fetched from the chain.
func getMissedBlocks(chainConn ChainConn, startingHeight,
endingHeight int32) ([]BlockEpoch, error) {
numMissedBlocks := endingHeight - startingHeight
if numMissedBlocks < 0 {
return nil, fmt.Errorf("starting height %d is greater than "+
"ending height %d", startingHeight, endingHeight)
}
missedBlocks := make([]BlockEpoch, 0, numMissedBlocks)
for height := startingHeight; height < endingHeight; height++ {
hash, err := chainConn.GetBlockHash(int64(height))
if err != nil {
return nil, fmt.Errorf("unable to find blockhash for "+
"height=%d: %v", height, err)
}
missedBlocks = append(missedBlocks,
BlockEpoch{Hash: hash, Height: height})
}
return missedBlocks, nil
}