package lookout import ( "sync" "sync/atomic" "github.com/btcsuite/btcd/wire" "github.com/lightningnetwork/lnd/chainntnfs" "github.com/lightningnetwork/lnd/watchtower/blob" "github.com/lightningnetwork/lnd/watchtower/wtdb" ) // Config houses the Lookout's required resources to properly fulfill it's duty, // including block fetching, querying accepted state updates, and construction // and publication of justice transactions. type Config struct { // DB provides persistent access to the watchtower's accepted state // updates such that they can be queried as new blocks arrive from the // network. DB DB // EpochRegistrar supports the ability to register for events corresponding to // newly created blocks. EpochRegistrar EpochRegistrar // BlockFetcher supports the ability to fetch blocks from the backend or // network. BlockFetcher BlockFetcher // Punisher handles the responsibility of crafting and broadcasting // justice transaction for any breached transactions. Punisher Punisher } // Lookout will check any incoming blocks against the transactions found in the // database, and in case of matches send the information needed to create a // penalty transaction to the punisher. type Lookout struct { started int32 // atomic shutdown int32 // atomic cfg *Config wg sync.WaitGroup quit chan struct{} } // New constructs a new Lookout from the given LookoutConfig. func New(cfg *Config) *Lookout { return &Lookout{ cfg: cfg, quit: make(chan struct{}), } } // Start safely spins up the Lookout and begins monitoring for breaches. func (l *Lookout) Start() error { if !atomic.CompareAndSwapInt32(&l.started, 0, 1) { return nil } log.Infof("Starting lookout") startEpoch, err := l.cfg.DB.GetLookoutTip() if err != nil { return err } if startEpoch == nil { log.Infof("Starting lookout from chain tip") } else { log.Infof("Starting lookout from epoch(height=%d hash=%x)", startEpoch.Height, startEpoch.Hash) } events, err := l.cfg.EpochRegistrar.RegisterBlockEpochNtfn(startEpoch) if err != nil { log.Errorf("Unable to register for block epochs: %v", err) return err } l.wg.Add(1) go l.watchBlocks(events) log.Infof("Lookout started successfully") return nil } // Stop safely shuts down the Lookout. func (l *Lookout) Stop() error { if !atomic.CompareAndSwapInt32(&l.shutdown, 0, 1) { return nil } log.Infof("Stopping lookout") close(l.quit) l.wg.Wait() log.Infof("Lookout stopped successfully") return nil } // watchBlocks serially pulls incoming epochs from the epoch source and searches // our accepted state updates for any breached transactions. If any are found, // we will attempt to decrypt the state updates' encrypted blobs and exact // justice for the victim. // // This method MUST be run as a goroutine. func (l *Lookout) watchBlocks(epochs *chainntnfs.BlockEpochEvent) { defer l.wg.Done() defer epochs.Cancel() for { select { case epoch := <-epochs.Epochs: log.Debugf("Fetching block for (height=%d, hash=%x)", epoch.Height, epoch.Hash) // Fetch the full block from the backend corresponding // to the newly arriving epoch. block, err := l.cfg.BlockFetcher.GetBlock(epoch.Hash) if err != nil { // TODO(conner): add retry logic? log.Errorf("Unable to fetch block for "+ "(height=%x, hash=%x): %v", epoch.Height, epoch.Hash, err) continue } // Process the block to see if it contains any breaches // that we are monitoring on behalf of our clients. err = l.processEpoch(epoch, block) if err != nil { log.Errorf("Unable to process %s: %v", epoch, err) } case <-l.quit: return } } } // processEpoch accepts an Epoch and queries the database for any matching state // updates for the confirmed transactions. If any are found, the lookout // responds by attempting to decrypt the encrypted blob and publishing the // justice transaction. func (l *Lookout) processEpoch(epoch *chainntnfs.BlockEpoch, block *wire.MsgBlock) error { numTxnsInBlock := len(block.Transactions) log.Debugf("Scanning %d transaction in block (height=%d, hash=%x) "+ "for breaches", numTxnsInBlock, epoch.Height, epoch.Hash) // Iterate over the transactions contained in the block, deriving a // breach hint for each transaction and constructing an index mapping // the hint back to it's original transaction. hintToTx := make(map[wtdb.BreachHint]*wire.MsgTx, numTxnsInBlock) txHints := make([]wtdb.BreachHint, 0, numTxnsInBlock) for _, tx := range block.Transactions { hash := tx.TxHash() hint := wtdb.NewBreachHintFromHash(&hash) txHints = append(txHints, hint) hintToTx[hint] = tx } // Query the database to see if any of the breach hints cause a match // with any of our accepted state updates. matches, err := l.cfg.DB.QueryMatches(txHints) if err != nil { return err } // No matches were found, we are done. if len(matches) == 0 { log.Debugf("No breaches found in (height=%d, hash=%x)", epoch.Height, epoch.Hash) return nil } breachCountStr := "breach" if len(matches) > 1 { breachCountStr = "breaches" } log.Infof("Found %d %s in (height=%d, hash=%x)", len(matches), breachCountStr, epoch.Height, epoch.Hash) // For each match, use our index to retrieve the original transaction, // which corresponds to the breaching commitment transaction. If the // decryption succeeds, we will accumlate the assembled justice // descriptors in a single slice var successes []*JusticeDescriptor for _, match := range matches { commitTx := hintToTx[match.Hint] log.Infof("Dispatching punisher for client %s, breach-txid=%s", match.ID, commitTx.TxHash().String()) // The decryption key for the state update should be the full // txid of the breaching commitment transaction. commitTxID := commitTx.TxHash() // Now, decrypt the blob of justice that we received in the // state update. This will contain all information required to // sweep the breached commitment outputs. justiceKit, err := blob.Decrypt( commitTxID[:], match.EncryptedBlob, match.SessionInfo.Version, ) if err != nil { // If the decryption fails, this implies either that the // client sent an invalid blob, or that the breach hint // caused a match on the txid, but this isn't actually // the right transaction. log.Debugf("Unable to decrypt blob for client %s, "+ "breach-txid %s: %v", match.ID, commitTx.TxHash().String(), err) continue } justiceDesc := &JusticeDescriptor{ BreachedCommitTx: commitTx, SessionInfo: match.SessionInfo, JusticeKit: justiceKit, } successes = append(successes, justiceDesc) } // TODO(conner): mark successfully decrypted blob so that we can // reliably rebroadcast on startup // Now, we'll dispatch a punishment for each successful match in // parallel. This will assemble the justice transaction for each and // watch for their confirmation on chain. for _, justiceDesc := range successes { l.wg.Add(1) go l.dispatchPunisher(justiceDesc) } return l.cfg.DB.SetLookoutTip(epoch) } // dispatchPunisher accepts a justice descriptor corresponding to a successfully // decrypted blob. The punisher will then construct the witness scripts and // witness stacks for the breached outputs. If construction of the justice // transaction is successful, it will be published to the network to retrieve // the funds and claim the watchtower's reward. // // This method MUST be run as a goroutine. func (l *Lookout) dispatchPunisher(desc *JusticeDescriptor) { defer l.wg.Done() // Give the justice descriptor to the punisher to construct and publish // the justice transaction. The lookout's quit channel is provided so // that long-running tasks that watch for on-chain events can be // canceled during shutdown since this method is waitgrouped. err := l.cfg.Punisher.Punish(desc, l.quit) if err != nil { log.Errorf("Unable to punish breach-txid %s for %x: %v", desc.SessionInfo.ID, desc.BreachedCommitTx.TxHash().String(), err) return } log.Infof("Punishment for client %s with breach-txid=%s dispatched", desc.SessionInfo.ID, desc.BreachedCommitTx.TxHash().String()) }