package chain import ( "errors" "fmt" "sync" "time" "github.com/lightninglabs/neutrino" "github.com/roasbeef/btcd/chaincfg/chainhash" "github.com/roasbeef/btcd/wire" "github.com/roasbeef/btcrpcclient" "github.com/roasbeef/btcutil" "github.com/roasbeef/btcwallet/waddrmgr" "github.com/roasbeef/btcwallet/wtxmgr" ) // NeutrinoClient is an implementation of the btcwalet chain.Interface interface. type NeutrinoClient struct { CS *neutrino.ChainService // We currently support one rescan/notifiction goroutine per client rescan neutrino.Rescan enqueueNotification chan interface{} dequeueNotification chan interface{} currentBlock chan *waddrmgr.BlockStamp quit chan struct{} rescanQuit chan struct{} rescanErr <-chan error wg sync.WaitGroup started bool scanning bool finished bool clientMtx sync.Mutex } // NewNeutrinoClient creates a new NeutrinoClient struct with a backing // ChainService. func NewNeutrinoClient(chainService *neutrino.ChainService) *NeutrinoClient { return &NeutrinoClient{CS: chainService} } // Start replicates the RPC client's Start method. func (s *NeutrinoClient) Start() error { s.CS.Start() s.clientMtx.Lock() defer s.clientMtx.Unlock() if !s.started { s.enqueueNotification = make(chan interface{}) s.dequeueNotification = make(chan interface{}) s.currentBlock = make(chan *waddrmgr.BlockStamp) s.quit = make(chan struct{}) s.started = true s.wg.Add(1) go func() { select { case s.enqueueNotification <- ClientConnected{}: case <-s.quit: return } }() go s.notificationHandler() } return nil } // Stop replicates the RPC client's Stop method. func (s *NeutrinoClient) Stop() { s.clientMtx.Lock() defer s.clientMtx.Unlock() if !s.started { return } close(s.quit) s.started = false } // WaitForShutdown replicates the RPC client's WaitForShutdown method. func (s *NeutrinoClient) WaitForShutdown() { s.wg.Wait() } // GetBlock replicates the RPC client's GetBlock command. func (s *NeutrinoClient) GetBlock(hash *chainhash.Hash) (*wire.MsgBlock, error) { // TODO(roasbeef): add a block cache? // * which evication strategy? depends on use case // Should the block cache be INSIDE neutrino instead of in btcwallet? block, err := s.CS.GetBlockFromNetwork(*hash) if err != nil { return nil, err } return block.MsgBlock(), nil } // GetBlockHeight gets the height of a block by its hash. It serves as a // replacement for the use of GetBlockVerboseTxAsync for the wallet package // since we can't actually return a FutureGetBlockVerboseResult because the // underlying type is private to btcrpcclient. func (s *NeutrinoClient) GetBlockHeight(hash *chainhash.Hash) (int32, error) { _, height, err := s.CS.BlockHeaders.FetchHeader(hash) if err != nil { return 0, err } return int32(height), nil } // GetBestBlock replicates the RPC client's GetBestBlock command. func (s *NeutrinoClient) GetBestBlock() (*chainhash.Hash, int32, error) { chainTip, err := s.CS.BestSnapshot() if err != nil { return nil, 0, err } return &chainTip.Hash, chainTip.Height, nil } // BlockStamp returns the latest block notified by the client, or an error // if the client has been shut down. func (s *NeutrinoClient) BlockStamp() (*waddrmgr.BlockStamp, error) { select { case bs := <-s.currentBlock: return bs, nil case <-s.quit: return nil, errors.New("disconnected") } } // GetBlockHash returns the block hash for the given height, or an error if the // client has been shut down or the hash at the block height doesn't exist or // is unknown. func (s *NeutrinoClient) GetBlockHash(height int64) (*chainhash.Hash, error) { header, err := s.CS.BlockHeaders.FetchHeaderByHeight(uint32(height)) if err != nil { return nil, err } hash := header.BlockHash() return &hash, nil } // SendRawTransaction replicates the RPC client's SendRawTransaction command. func (s *NeutrinoClient) SendRawTransaction(tx *wire.MsgTx, allowHighFees bool) ( *chainhash.Hash, error) { err := s.CS.SendTransaction(tx) if err != nil { return nil, err } hash := tx.TxHash() return &hash, nil } // Rescan replicates the RPC client's Rescan command. func (s *NeutrinoClient) Rescan(startHash *chainhash.Hash, addrs []btcutil.Address, outPoints []*wire.OutPoint) error { s.clientMtx.Lock() defer s.clientMtx.Unlock() if !s.started { return fmt.Errorf("can't do a rescan when the chain client " + "is not started") } if s.scanning { // Restart the rescan by killing the existing rescan. close(s.rescanQuit) s.rescan.WaitForShutdown() } s.rescanQuit = make(chan struct{}) s.scanning = true s.finished = false watchOutPoints := make([]wire.OutPoint, 0, len(outPoints)) for _, op := range outPoints { watchOutPoints = append(watchOutPoints, *op) } header, height, err := s.CS.BlockHeaders.ChainTip() if err != nil { return fmt.Errorf("Can't get chain service's best block: %s", err) } // If the wallet is already fully caught up, or the rescan has started // with state that indicates a "fresh" wallet, we'll send a // notification indicating the rescan has "finished". if header.BlockHash() == *startHash { s.finished = true select { case s.enqueueNotification <- &RescanFinished{ Hash: startHash, Height: int32(height), Time: header.Timestamp, }: case <-s.quit: return nil case <-s.rescanQuit: return nil } } s.rescan = s.CS.NewRescan( neutrino.NotificationHandlers(btcrpcclient.NotificationHandlers{ OnBlockConnected: s.onBlockConnected, OnFilteredBlockConnected: s.onFilteredBlockConnected, OnBlockDisconnected: s.onBlockDisconnected, }), neutrino.StartBlock(&waddrmgr.BlockStamp{Hash: *startHash}), neutrino.QuitChan(s.rescanQuit), neutrino.WatchAddrs(addrs...), neutrino.WatchOutPoints(watchOutPoints...), ) s.rescanErr = s.rescan.Start() return nil } // NotifyBlocks replicates the RPC client's NotifyBlocks command. func (s *NeutrinoClient) NotifyBlocks() error { s.clientMtx.Lock() // If we're scanning, we're already notifying on blocks. Otherwise, // start a rescan without watching any addresses. if !s.scanning { s.clientMtx.Unlock() return s.NotifyReceived([]btcutil.Address{}) } s.clientMtx.Unlock() return nil } // NotifyReceived replicates the RPC client's NotifyReceived command. func (s *NeutrinoClient) NotifyReceived(addrs []btcutil.Address) error { s.clientMtx.Lock() defer s.clientMtx.Unlock() // If we have a rescan running, we just need to add the appropriate // addresses to the watch list. if s.scanning { s.clientMtx.Unlock() return s.rescan.Update(neutrino.AddAddrs(addrs...)) } s.rescanQuit = make(chan struct{}) s.scanning = true // Don't need RescanFinished notifications. s.finished = true // Rescan with just the specified addresses. s.rescan = s.CS.NewRescan( neutrino.NotificationHandlers(btcrpcclient.NotificationHandlers{ OnBlockConnected: s.onBlockConnected, OnFilteredBlockConnected: s.onFilteredBlockConnected, OnBlockDisconnected: s.onBlockDisconnected, }), neutrino.QuitChan(s.rescanQuit), neutrino.WatchAddrs(addrs...), ) s.rescanErr = s.rescan.Start() return nil } // Notifications replicates the RPC client's Notifications method. func (s *NeutrinoClient) Notifications() <-chan interface{} { return s.dequeueNotification } // onFilteredBlockConnected sends appropriate notifications to the notification // channel. func (s *NeutrinoClient) onFilteredBlockConnected(height int32, header *wire.BlockHeader, relevantTxs []*btcutil.Tx) { ntfn := FilteredBlockConnected{ Block: &wtxmgr.BlockMeta{ Block: wtxmgr.Block{ Hash: header.BlockHash(), Height: height, }, Time: header.Timestamp, }, } for _, tx := range relevantTxs { rec, err := wtxmgr.NewTxRecordFromMsgTx(tx.MsgTx(), header.Timestamp) if err != nil { log.Errorf("Cannot create transaction record for "+ "relevant tx: %s", err) // TODO(aakselrod): Return? continue } ntfn.RelevantTxs = append(ntfn.RelevantTxs, rec) } select { case s.enqueueNotification <- ntfn: case <-s.quit: return case <-s.rescanQuit: return } bs, err := s.CS.BestSnapshot() if err != nil { log.Errorf("Can't get chain service's best block: %s", err) return } if bs.Hash == header.BlockHash() { // Only send the RescanFinished notification once. s.clientMtx.Lock() if s.finished { s.clientMtx.Unlock() return } s.finished = true s.clientMtx.Unlock() select { case s.enqueueNotification <- &RescanFinished{ Hash: &bs.Hash, Height: bs.Height, Time: header.Timestamp, }: case <-s.quit: return case <-s.rescanQuit: return } } } // onBlockDisconnected sends appropriate notifications to the notification // channel. func (s *NeutrinoClient) onBlockDisconnected(hash *chainhash.Hash, height int32, t time.Time) { select { case s.enqueueNotification <- BlockDisconnected{ Block: wtxmgr.Block{ Hash: *hash, Height: height, }, Time: t, }: case <-s.quit: case <-s.rescanQuit: } } func (s *NeutrinoClient) onBlockConnected(hash *chainhash.Hash, height int32, time time.Time) { select { case s.enqueueNotification <- BlockConnected{ Block: wtxmgr.Block{ Hash: *hash, Height: height, }, Time: time, }: case <-s.quit: case <-s.rescanQuit: } } // notificationHandler queues and dequeues notifications. There are currently // no bounds on the queue, so the dequeue channel should be read continually to // avoid running out of memory. func (s *NeutrinoClient) notificationHandler() { hash, height, err := s.GetBestBlock() if err != nil { log.Errorf("Failed to get best block from chain service: %s", err) s.Stop() s.wg.Done() return } bs := &waddrmgr.BlockStamp{Hash: *hash, Height: height} // TODO: Rather than leaving this as an unbounded queue for all types of // notifications, try dropping ones where a later enqueued notification // can fully invalidate one waiting to be processed. For example, // blockconnected notifications for greater block heights can remove the // need to process earlier blockconnected notifications still waiting // here. var notifications []interface{} enqueue := s.enqueueNotification var dequeue chan interface{} var next interface{} out: for { select { case n, ok := <-enqueue: if !ok { // If no notifications are queued for handling, // the queue is finished. if len(notifications) == 0 { break out } // nil channel so no more reads can occur. enqueue = nil continue } if len(notifications) == 0 { next = n dequeue = s.dequeueNotification } notifications = append(notifications, n) case dequeue <- next: if n, ok := next.(BlockConnected); ok { bs = &waddrmgr.BlockStamp{ Height: n.Height, Hash: n.Hash, } } notifications[0] = nil notifications = notifications[1:] if len(notifications) != 0 { next = notifications[0] } else { // If no more notifications can be enqueued, the // queue is finished. if enqueue == nil { break out } dequeue = nil } case err := <-s.rescanErr: if err != nil { log.Errorf("Neutrino rescan ended with error: %s", err) } case s.currentBlock <- bs: case <-s.quit: break out } } s.Stop() close(s.dequeueNotification) s.wg.Done() }