// Copyright (c) 2013-2016 The btcsuite developers // Use of this source code is governed by an ISC // license that can be found in the LICENSE file. package main import ( "bytes" "container/list" "crypto/subtle" "encoding/base64" "encoding/hex" "encoding/json" "errors" "fmt" "io" "math" "sync" "time" "github.com/btcsuite/btcd/blockchain" "github.com/btcsuite/btcd/btcjson" "github.com/btcsuite/btcd/chaincfg/chainhash" "github.com/btcsuite/btcd/database" "github.com/btcsuite/btcd/txscript" "github.com/btcsuite/btcd/wire" "github.com/btcsuite/btcutil" "github.com/btcsuite/fastsha256" "github.com/btcsuite/golangcrypto/ripemd160" "github.com/btcsuite/websocket" ) const ( // websocketSendBufferSize is the number of elements the send channel // can queue before blocking. Note that this only applies to requests // handled directly in the websocket client input handler or the async // handler since notifications have their own queuing mechanism // independent of the send channel buffer. websocketSendBufferSize = 50 ) type semaphore chan struct{} func makeSemaphore(n int) semaphore { return make(chan struct{}, n) } func (s semaphore) acquire() { s <- struct{}{} } func (s semaphore) release() { <-s } // timeZeroVal is simply the zero value for a time.Time and is used to avoid // creating multiple instances. var timeZeroVal time.Time // wsCommandHandler describes a callback function used to handle a specific // command. type wsCommandHandler func(*wsClient, interface{}) (interface{}, error) // wsHandlers maps RPC command strings to appropriate websocket handler // functions. This is set by init because help references wsHandlers and thus // causes a dependency loop. var wsHandlers map[string]wsCommandHandler var wsHandlersBeforeInit = map[string]wsCommandHandler{ "help": handleWebsocketHelp, "notifyblocks": handleNotifyBlocks, "notifynewtransactions": handleNotifyNewTransactions, "notifyreceived": handleNotifyReceived, "notifyspent": handleNotifySpent, "session": handleSession, "stopnotifyblocks": handleStopNotifyBlocks, "stopnotifynewtransactions": handleStopNotifyNewTransactions, "stopnotifyspent": handleStopNotifySpent, "stopnotifyreceived": handleStopNotifyReceived, "rescan": handleRescan, } // WebsocketHandler handles a new websocket client by creating a new wsClient, // starting it, and blocking until the connection closes. Since it blocks, it // must be run in a separate goroutine. It should be invoked from the websocket // server handler which runs each new connection in a new goroutine thereby // satisfying the requirement. func (s *rpcServer) WebsocketHandler(conn *websocket.Conn, remoteAddr string, authenticated bool, isAdmin bool) { // Clear the read deadline that was set before the websocket hijacked // the connection. conn.SetReadDeadline(timeZeroVal) // Limit max number of websocket clients. rpcsLog.Infof("New websocket client %s", remoteAddr) if s.ntfnMgr.NumClients()+1 > cfg.RPCMaxWebsockets { rpcsLog.Infof("Max websocket clients exceeded [%d] - "+ "disconnecting client %s", cfg.RPCMaxWebsockets, remoteAddr) conn.Close() return } // Create a new websocket client to handle the new websocket connection // and wait for it to shutdown. Once it has shutdown (and hence // disconnected), remove it and any notifications it registered for. client, err := newWebsocketClient(s, conn, remoteAddr, authenticated, isAdmin) if err != nil { rpcsLog.Errorf("Failed to serve client %s: %v", remoteAddr, err) conn.Close() return } s.ntfnMgr.AddClient(client) client.Start() client.WaitForShutdown() s.ntfnMgr.RemoveClient(client) rpcsLog.Infof("Disconnected websocket client %s", remoteAddr) } // wsNotificationManager is a connection and notification manager used for // websockets. It allows websocket clients to register for notifications they // are interested in. When an event happens elsewhere in the code such as // transactions being added to the memory pool or block connects/disconnects, // the notification manager is provided with the relevant details needed to // figure out which websocket clients need to be notified based on what they // have registered for and notifies them accordingly. It is also used to keep // track of all connected websocket clients. type wsNotificationManager struct { // server is the RPC server the notification manager is associated with. server *rpcServer // queueNotification queues a notification for handling. queueNotification chan interface{} // notificationMsgs feeds notificationHandler with notifications // and client (un)registeration requests from a queue as well as // registeration and unregisteration requests from clients. notificationMsgs chan interface{} // Access channel for current number of connected clients. numClients chan int // Shutdown handling wg sync.WaitGroup quit chan struct{} } // queueHandler manages a queue of empty interfaces, reading from in and // sending the oldest unsent to out. This handler stops when either of the // in or quit channels are closed, and closes out before returning, without // waiting to send any variables still remaining in the queue. func queueHandler(in <-chan interface{}, out chan<- interface{}, quit <-chan struct{}) { var q []interface{} var dequeue chan<- interface{} skipQueue := out var next interface{} out: for { select { case n, ok := <-in: if !ok { // Sender closed input channel. break out } // Either send to out immediately if skipQueue is // non-nil (queue is empty) and reader is ready, // or append to the queue and send later. select { case skipQueue <- n: default: q = append(q, n) dequeue = out skipQueue = nil next = q[0] } case dequeue <- next: copy(q, q[1:]) q[len(q)-1] = nil // avoid leak q = q[:len(q)-1] if len(q) == 0 { dequeue = nil skipQueue = out } else { next = q[0] } case <-quit: break out } } close(out) } // queueHandler maintains a queue of notifications and notification handler // control messages. func (m *wsNotificationManager) queueHandler() { queueHandler(m.queueNotification, m.notificationMsgs, m.quit) m.wg.Done() } // NotifyBlockConnected passes a block newly-connected to the best chain // to the notification manager for block and transaction notification // processing. func (m *wsNotificationManager) NotifyBlockConnected(block *btcutil.Block) { // As NotifyBlockConnected will be called by the block manager // and the RPC server may no longer be running, use a select // statement to unblock enqueuing the notification once the RPC // server has begun shutting down. select { case m.queueNotification <- (*notificationBlockConnected)(block): case <-m.quit: } } // NotifyBlockDisconnected passes a block disconnected from the best chain // to the notification manager for block notification processing. func (m *wsNotificationManager) NotifyBlockDisconnected(block *btcutil.Block) { // As NotifyBlockDisconnected will be called by the block manager // and the RPC server may no longer be running, use a select // statement to unblock enqueuing the notification once the RPC // server has begun shutting down. select { case m.queueNotification <- (*notificationBlockDisconnected)(block): case <-m.quit: } } // NotifyMempoolTx passes a transaction accepted by mempool to the // notification manager for transaction notification processing. If // isNew is true, the tx is is a new transaction, rather than one // added to the mempool during a reorg. func (m *wsNotificationManager) NotifyMempoolTx(tx *btcutil.Tx, isNew bool) { n := ¬ificationTxAcceptedByMempool{ isNew: isNew, tx: tx, } // As NotifyMempoolTx will be called by mempool and the RPC server // may no longer be running, use a select statement to unblock // enqueuing the notification once the RPC server has begun // shutting down. select { case m.queueNotification <- n: case <-m.quit: } } // Notification types type notificationBlockConnected btcutil.Block type notificationBlockDisconnected btcutil.Block type notificationTxAcceptedByMempool struct { isNew bool tx *btcutil.Tx } // Notification control requests type notificationRegisterClient wsClient type notificationUnregisterClient wsClient type notificationRegisterBlocks wsClient type notificationUnregisterBlocks wsClient type notificationRegisterNewMempoolTxs wsClient type notificationUnregisterNewMempoolTxs wsClient type notificationRegisterSpent struct { wsc *wsClient ops []*wire.OutPoint } type notificationUnregisterSpent struct { wsc *wsClient op *wire.OutPoint } type notificationRegisterAddr struct { wsc *wsClient addrs []string } type notificationUnregisterAddr struct { wsc *wsClient addr string } // notificationHandler reads notifications and control messages from the queue // handler and processes one at a time. func (m *wsNotificationManager) notificationHandler() { // clients is a map of all currently connected websocket clients. clients := make(map[chan struct{}]*wsClient) // Maps used to hold lists of websocket clients to be notified on // certain events. Each websocket client also keeps maps for the events // which have multiple triggers to make removal from these lists on // connection close less horrendously expensive. // // Where possible, the quit channel is used as the unique id for a client // since it is quite a bit more efficient than using the entire struct. blockNotifications := make(map[chan struct{}]*wsClient) txNotifications := make(map[chan struct{}]*wsClient) watchedOutPoints := make(map[wire.OutPoint]map[chan struct{}]*wsClient) watchedAddrs := make(map[string]map[chan struct{}]*wsClient) out: for { select { case n, ok := <-m.notificationMsgs: if !ok { // queueHandler quit. break out } switch n := n.(type) { case *notificationBlockConnected: block := (*btcutil.Block)(n) // Skip iterating through all txs if no // tx notification requests exist. if len(watchedOutPoints) != 0 || len(watchedAddrs) != 0 { for _, tx := range block.Transactions() { m.notifyForTx(watchedOutPoints, watchedAddrs, tx, block) } } if len(blockNotifications) != 0 { m.notifyBlockConnected(blockNotifications, block) } case *notificationBlockDisconnected: m.notifyBlockDisconnected(blockNotifications, (*btcutil.Block)(n)) case *notificationTxAcceptedByMempool: if n.isNew && len(txNotifications) != 0 { m.notifyForNewTx(txNotifications, n.tx) } m.notifyForTx(watchedOutPoints, watchedAddrs, n.tx, nil) case *notificationRegisterBlocks: wsc := (*wsClient)(n) blockNotifications[wsc.quit] = wsc case *notificationUnregisterBlocks: wsc := (*wsClient)(n) delete(blockNotifications, wsc.quit) case *notificationRegisterClient: wsc := (*wsClient)(n) clients[wsc.quit] = wsc case *notificationUnregisterClient: wsc := (*wsClient)(n) // Remove any requests made by the client as well as // the client itself. delete(blockNotifications, wsc.quit) delete(txNotifications, wsc.quit) for k := range wsc.spentRequests { op := k m.removeSpentRequest(watchedOutPoints, wsc, &op) } for addr := range wsc.addrRequests { m.removeAddrRequest(watchedAddrs, wsc, addr) } delete(clients, wsc.quit) case *notificationRegisterSpent: m.addSpentRequests(watchedOutPoints, n.wsc, n.ops) case *notificationUnregisterSpent: m.removeSpentRequest(watchedOutPoints, n.wsc, n.op) case *notificationRegisterAddr: m.addAddrRequests(watchedAddrs, n.wsc, n.addrs) case *notificationUnregisterAddr: m.removeAddrRequest(watchedAddrs, n.wsc, n.addr) case *notificationRegisterNewMempoolTxs: wsc := (*wsClient)(n) txNotifications[wsc.quit] = wsc case *notificationUnregisterNewMempoolTxs: wsc := (*wsClient)(n) delete(txNotifications, wsc.quit) default: rpcsLog.Warn("Unhandled notification type") } case m.numClients <- len(clients): case <-m.quit: // RPC server shutting down. break out } } for _, c := range clients { c.Disconnect() } m.wg.Done() } // NumClients returns the number of clients actively being served. func (m *wsNotificationManager) NumClients() (n int) { select { case n = <-m.numClients: case <-m.quit: // Use default n (0) if server has shut down. } return } // RegisterBlockUpdates requests block update notifications to the passed // websocket client. func (m *wsNotificationManager) RegisterBlockUpdates(wsc *wsClient) { m.queueNotification <- (*notificationRegisterBlocks)(wsc) } // UnregisterBlockUpdates removes block update notifications for the passed // websocket client. func (m *wsNotificationManager) UnregisterBlockUpdates(wsc *wsClient) { m.queueNotification <- (*notificationUnregisterBlocks)(wsc) } // notifyBlockConnected notifies websocket clients that have registered for // block updates when a block is connected to the main chain. func (*wsNotificationManager) notifyBlockConnected(clients map[chan struct{}]*wsClient, block *btcutil.Block) { // Notify interested websocket clients about the connected block. ntfn := btcjson.NewBlockConnectedNtfn(block.Hash().String(), int32(block.Height()), block.MsgBlock().Header.Timestamp.Unix()) marshalledJSON, err := btcjson.MarshalCmd(nil, ntfn) if err != nil { rpcsLog.Error("Failed to marshal block connected notification: "+ "%v", err) return } for _, wsc := range clients { wsc.QueueNotification(marshalledJSON) } } // notifyBlockDisconnected notifies websocket clients that have registered for // block updates when a block is disconnected from the main chain (due to a // reorganize). func (*wsNotificationManager) notifyBlockDisconnected(clients map[chan struct{}]*wsClient, block *btcutil.Block) { // Skip notification creation if no clients have requested block // connected/disconnected notifications. if len(clients) == 0 { return } // Notify interested websocket clients about the disconnected block. ntfn := btcjson.NewBlockDisconnectedNtfn(block.Hash().String(), int32(block.Height()), block.MsgBlock().Header.Timestamp.Unix()) marshalledJSON, err := btcjson.MarshalCmd(nil, ntfn) if err != nil { rpcsLog.Error("Failed to marshal block disconnected "+ "notification: %v", err) return } for _, wsc := range clients { wsc.QueueNotification(marshalledJSON) } } // RegisterNewMempoolTxsUpdates requests notifications to the passed websocket // client when new transactions are added to the memory pool. func (m *wsNotificationManager) RegisterNewMempoolTxsUpdates(wsc *wsClient) { m.queueNotification <- (*notificationRegisterNewMempoolTxs)(wsc) } // UnregisterNewMempoolTxsUpdates removes notifications to the passed websocket // client when new transaction are added to the memory pool. func (m *wsNotificationManager) UnregisterNewMempoolTxsUpdates(wsc *wsClient) { m.queueNotification <- (*notificationUnregisterNewMempoolTxs)(wsc) } // notifyForNewTx notifies websocket clients that have registered for updates // when a new transaction is added to the memory pool. func (m *wsNotificationManager) notifyForNewTx(clients map[chan struct{}]*wsClient, tx *btcutil.Tx) { txHashStr := tx.Hash().String() mtx := tx.MsgTx() var amount int64 for _, txOut := range mtx.TxOut { amount += txOut.Value } ntfn := btcjson.NewTxAcceptedNtfn(txHashStr, btcutil.Amount(amount).ToBTC()) marshalledJSON, err := btcjson.MarshalCmd(nil, ntfn) if err != nil { rpcsLog.Errorf("Failed to marshal tx notification: %s", err.Error()) return } var verboseNtfn *btcjson.TxAcceptedVerboseNtfn var marshalledJSONVerbose []byte for _, wsc := range clients { if wsc.verboseTxUpdates { if marshalledJSONVerbose != nil { wsc.QueueNotification(marshalledJSONVerbose) continue } net := m.server.server.chainParams rawTx, err := createTxRawResult(net, mtx, txHashStr, nil, "", 0, 0) if err != nil { return } verboseNtfn = btcjson.NewTxAcceptedVerboseNtfn(*rawTx) marshalledJSONVerbose, err = btcjson.MarshalCmd(nil, verboseNtfn) if err != nil { rpcsLog.Errorf("Failed to marshal verbose tx "+ "notification: %s", err.Error()) return } wsc.QueueNotification(marshalledJSONVerbose) } else { wsc.QueueNotification(marshalledJSON) } } } // RegisterSpentRequests requests a notification when each of the passed // outpoints is confirmed spent (contained in a block connected to the main // chain) for the passed websocket client. The request is automatically // removed once the notification has been sent. func (m *wsNotificationManager) RegisterSpentRequests(wsc *wsClient, ops []*wire.OutPoint) { m.queueNotification <- ¬ificationRegisterSpent{ wsc: wsc, ops: ops, } } // addSpentRequests modifies a map of watched outpoints to sets of websocket // clients to add a new request watch all of the outpoints in ops and create // and send a notification when spent to the websocket client wsc. func (*wsNotificationManager) addSpentRequests(opMap map[wire.OutPoint]map[chan struct{}]*wsClient, wsc *wsClient, ops []*wire.OutPoint) { for _, op := range ops { // Track the request in the client as well so it can be quickly // be removed on disconnect. wsc.spentRequests[*op] = struct{}{} // Add the client to the list to notify when the outpoint is seen. // Create the list as needed. cmap, ok := opMap[*op] if !ok { cmap = make(map[chan struct{}]*wsClient) opMap[*op] = cmap } cmap[wsc.quit] = wsc } } // UnregisterSpentRequest removes a request from the passed websocket client // to be notified when the passed outpoint is confirmed spent (contained in a // block connected to the main chain). func (m *wsNotificationManager) UnregisterSpentRequest(wsc *wsClient, op *wire.OutPoint) { m.queueNotification <- ¬ificationUnregisterSpent{ wsc: wsc, op: op, } } // removeSpentRequest modifies a map of watched outpoints to remove the // websocket client wsc from the set of clients to be notified when a // watched outpoint is spent. If wsc is the last client, the outpoint // key is removed from the map. func (*wsNotificationManager) removeSpentRequest(ops map[wire.OutPoint]map[chan struct{}]*wsClient, wsc *wsClient, op *wire.OutPoint) { // Remove the request tracking from the client. delete(wsc.spentRequests, *op) // Remove the client from the list to notify. notifyMap, ok := ops[*op] if !ok { rpcsLog.Warnf("Attempt to remove nonexistent spent request "+ "for websocket client %s", wsc.addr) return } delete(notifyMap, wsc.quit) // Remove the map entry altogether if there are // no more clients interested in it. if len(notifyMap) == 0 { delete(ops, *op) } } // txHexString returns the serialized transaction encoded in hexadecimal. func txHexString(tx *btcutil.Tx) string { buf := bytes.NewBuffer(make([]byte, 0, tx.MsgTx().SerializeSize())) // Ignore Serialize's error, as writing to a bytes.buffer cannot fail. tx.MsgTx().Serialize(buf) return hex.EncodeToString(buf.Bytes()) } // blockDetails creates a BlockDetails struct to include in btcws notifications // from a block and a transaction's block index. func blockDetails(block *btcutil.Block, txIndex int) *btcjson.BlockDetails { if block == nil { return nil } return &btcjson.BlockDetails{ Height: int32(block.Height()), Hash: block.Hash().String(), Index: txIndex, Time: block.MsgBlock().Header.Timestamp.Unix(), } } // newRedeemingTxNotification returns a new marshalled redeemingtx notification // with the passed parameters. func newRedeemingTxNotification(txHex string, index int, block *btcutil.Block) ([]byte, error) { // Create and marshal the notification. ntfn := btcjson.NewRedeemingTxNtfn(txHex, blockDetails(block, index)) return btcjson.MarshalCmd(nil, ntfn) } // notifyForTxOuts examines each transaction output, notifying interested // websocket clients of the transaction if an output spends to a watched // address. A spent notification request is automatically registered for // the client for each matching output. func (m *wsNotificationManager) notifyForTxOuts(ops map[wire.OutPoint]map[chan struct{}]*wsClient, addrs map[string]map[chan struct{}]*wsClient, tx *btcutil.Tx, block *btcutil.Block) { // Nothing to do if nobody is listening for address notifications. if len(addrs) == 0 { return } txHex := "" wscNotified := make(map[chan struct{}]struct{}) for i, txOut := range tx.MsgTx().TxOut { _, txAddrs, _, err := txscript.ExtractPkScriptAddrs( txOut.PkScript, m.server.server.chainParams) if err != nil { continue } for _, txAddr := range txAddrs { cmap, ok := addrs[txAddr.EncodeAddress()] if !ok { continue } if txHex == "" { txHex = txHexString(tx) } ntfn := btcjson.NewRecvTxNtfn(txHex, blockDetails(block, tx.Index())) marshalledJSON, err := btcjson.MarshalCmd(nil, ntfn) if err != nil { rpcsLog.Errorf("Failed to marshal processedtx notification: %v", err) continue } op := []*wire.OutPoint{wire.NewOutPoint(tx.Hash(), uint32(i))} for wscQuit, wsc := range cmap { m.addSpentRequests(ops, wsc, op) if _, ok := wscNotified[wscQuit]; !ok { wscNotified[wscQuit] = struct{}{} wsc.QueueNotification(marshalledJSON) } } } } } // notifyForTx examines the inputs and outputs of the passed transaction, // notifying websocket clients of outputs spending to a watched address // and inputs spending a watched outpoint. func (m *wsNotificationManager) notifyForTx(ops map[wire.OutPoint]map[chan struct{}]*wsClient, addrs map[string]map[chan struct{}]*wsClient, tx *btcutil.Tx, block *btcutil.Block) { if len(ops) != 0 { m.notifyForTxIns(ops, tx, block) } if len(addrs) != 0 { m.notifyForTxOuts(ops, addrs, tx, block) } } // notifyForTxIns examines the inputs of the passed transaction and sends // interested websocket clients a redeemingtx notification if any inputs // spend a watched output. If block is non-nil, any matching spent // requests are removed. func (m *wsNotificationManager) notifyForTxIns(ops map[wire.OutPoint]map[chan struct{}]*wsClient, tx *btcutil.Tx, block *btcutil.Block) { // Nothing to do if nobody is watching outpoints. if len(ops) == 0 { return } txHex := "" wscNotified := make(map[chan struct{}]struct{}) for _, txIn := range tx.MsgTx().TxIn { prevOut := &txIn.PreviousOutPoint if cmap, ok := ops[*prevOut]; ok { if txHex == "" { txHex = txHexString(tx) } marshalledJSON, err := newRedeemingTxNotification(txHex, tx.Index(), block) if err != nil { rpcsLog.Warnf("Failed to marshal redeemingtx notification: %v", err) continue } for wscQuit, wsc := range cmap { if block != nil { m.removeSpentRequest(ops, wsc, prevOut) } if _, ok := wscNotified[wscQuit]; !ok { wscNotified[wscQuit] = struct{}{} wsc.QueueNotification(marshalledJSON) } } } } } // RegisterTxOutAddressRequests requests notifications to the passed websocket // client when a transaction output spends to the passed address. func (m *wsNotificationManager) RegisterTxOutAddressRequests(wsc *wsClient, addrs []string) { m.queueNotification <- ¬ificationRegisterAddr{ wsc: wsc, addrs: addrs, } } // addAddrRequests adds the websocket client wsc to the address to client set // addrMap so wsc will be notified for any mempool or block transaction outputs // spending to any of the addresses in addrs. func (*wsNotificationManager) addAddrRequests(addrMap map[string]map[chan struct{}]*wsClient, wsc *wsClient, addrs []string) { for _, addr := range addrs { // Track the request in the client as well so it can be quickly be // removed on disconnect. wsc.addrRequests[addr] = struct{}{} // Add the client to the set of clients to notify when the // outpoint is seen. Create map as needed. cmap, ok := addrMap[addr] if !ok { cmap = make(map[chan struct{}]*wsClient) addrMap[addr] = cmap } cmap[wsc.quit] = wsc } } // UnregisterTxOutAddressRequest removes a request from the passed websocket // client to be notified when a transaction spends to the passed address. func (m *wsNotificationManager) UnregisterTxOutAddressRequest(wsc *wsClient, addr string) { m.queueNotification <- ¬ificationUnregisterAddr{ wsc: wsc, addr: addr, } } // removeAddrRequest removes the websocket client wsc from the address to // client set addrs so it will no longer receive notification updates for // any transaction outputs send to addr. func (*wsNotificationManager) removeAddrRequest(addrs map[string]map[chan struct{}]*wsClient, wsc *wsClient, addr string) { // Remove the request tracking from the client. delete(wsc.addrRequests, addr) // Remove the client from the list to notify. cmap, ok := addrs[addr] if !ok { rpcsLog.Warnf("Attempt to remove nonexistent addr request "+ "<%s> for websocket client %s", addr, wsc.addr) return } delete(cmap, wsc.quit) // Remove the map entry altogether if there are no more clients // interested in it. if len(cmap) == 0 { delete(addrs, addr) } } // AddClient adds the passed websocket client to the notification manager. func (m *wsNotificationManager) AddClient(wsc *wsClient) { m.queueNotification <- (*notificationRegisterClient)(wsc) } // RemoveClient removes the passed websocket client and all notifications // registered for it. func (m *wsNotificationManager) RemoveClient(wsc *wsClient) { select { case m.queueNotification <- (*notificationUnregisterClient)(wsc): case <-m.quit: } } // Start starts the goroutines required for the manager to queue and process // websocket client notifications. func (m *wsNotificationManager) Start() { m.wg.Add(2) go m.queueHandler() go m.notificationHandler() } // WaitForShutdown blocks until all notification manager goroutines have // finished. func (m *wsNotificationManager) WaitForShutdown() { m.wg.Wait() } // Shutdown shuts down the manager, stopping the notification queue and // notification handler goroutines. func (m *wsNotificationManager) Shutdown() { close(m.quit) } // newWsNotificationManager returns a new notification manager ready for use. // See wsNotificationManager for more details. func newWsNotificationManager(server *rpcServer) *wsNotificationManager { return &wsNotificationManager{ server: server, queueNotification: make(chan interface{}), notificationMsgs: make(chan interface{}), numClients: make(chan int), quit: make(chan struct{}), } } // wsResponse houses a message to send to a connected websocket client as // well as a channel to reply on when the message is sent. type wsResponse struct { msg []byte doneChan chan bool } // wsClient provides an abstraction for handling a websocket client. The // overall data flow is split into 3 main goroutines, a possible 4th goroutine // for long-running operations (only started if request is made), and a // websocket manager which is used to allow things such as broadcasting // requested notifications to all connected websocket clients. Inbound // messages are read via the inHandler goroutine and generally dispatched to // their own handler. However, certain potentially long-running operations such // as rescans, are sent to the asyncHander goroutine and are limited to one at a // time. There are two outbound message types - one for responding to client // requests and another for async notifications. Responses to client requests // use SendMessage which employs a buffered channel thereby limiting the number // of outstanding requests that can be made. Notifications are sent via // QueueNotification which implements a queue via notificationQueueHandler to // ensure sending notifications from other subsystems can't block. Ultimately, // all messages are sent via the outHandler. type wsClient struct { sync.Mutex // server is the RPC server that is servicing the client. server *rpcServer // conn is the underlying websocket connection. conn *websocket.Conn // disconnected indicated whether or not the websocket client is // disconnected. disconnected bool // addr is the remote address of the client. addr string // authenticated specifies whether a client has been authenticated // and therefore is allowed to communicated over the websocket. authenticated bool // isAdmin specifies whether a client may change the state of the server; // false means its access is only to the limited set of RPC calls. isAdmin bool // sessionID is a random ID generated for each client when connected. // These IDs may be queried by a client using the session RPC. A change // to the session ID indicates that the client reconnected. sessionID uint64 // verboseTxUpdates specifies whether a client has requested verbose // information about all new transactions. verboseTxUpdates bool // addrRequests is a set of addresses the caller has requested to be // notified about. It is maintained here so all requests can be removed // when a wallet disconnects. Owned by the notification manager. addrRequests map[string]struct{} // spentRequests is a set of unspent Outpoints a wallet has requested // notifications for when they are spent by a processed transaction. // Owned by the notification manager. spentRequests map[wire.OutPoint]struct{} // Networking infrastructure. serviceRequestSem semaphore ntfnChan chan []byte sendChan chan wsResponse quit chan struct{} wg sync.WaitGroup } // inHandler handles all incoming messages for the websocket connection. It // must be run as a goroutine. func (c *wsClient) inHandler() { out: for { // Break out of the loop once the quit channel has been closed. // Use a non-blocking select here so we fall through otherwise. select { case <-c.quit: break out default: } _, msg, err := c.conn.ReadMessage() if err != nil { // Log the error if it's not due to disconnecting. if err != io.EOF { rpcsLog.Errorf("Websocket receive error from "+ "%s: %v", c.addr, err) } break out } var request btcjson.Request err = json.Unmarshal(msg, &request) if err != nil { if !c.authenticated { break out } jsonErr := &btcjson.RPCError{ Code: btcjson.ErrRPCParse.Code, Message: "Failed to parse request: " + err.Error(), } reply, err := createMarshalledReply(nil, nil, jsonErr) if err != nil { rpcsLog.Errorf("Failed to marshal parse failure "+ "reply: %v", err) continue } c.SendMessage(reply, nil) continue } // Requests with no ID (notifications) must not have a response per the // JSON-RPC spec. if request.ID == nil { if !c.authenticated { break out } continue } cmd := parseCmd(&request) if cmd.err != nil { if !c.authenticated { break out } reply, err := createMarshalledReply(cmd.id, nil, cmd.err) if err != nil { rpcsLog.Errorf("Failed to marshal parse failure "+ "reply: %v", err) continue } c.SendMessage(reply, nil) continue } rpcsLog.Debugf("Received command <%s> from %s", cmd.method, c.addr) // Check auth. The client is immediately disconnected if the // first request of an unauthentiated websocket client is not // the authenticate request, an authenticate request is received // when the client is already authenticated, or incorrect // authentication credentials are provided in the request. switch authCmd, ok := cmd.cmd.(*btcjson.AuthenticateCmd); { case c.authenticated && ok: rpcsLog.Warnf("Websocket client %s is already authenticated", c.addr) break out case !c.authenticated && !ok: rpcsLog.Warnf("Unauthenticated websocket message " + "received") break out case !c.authenticated: // Check credentials. login := authCmd.Username + ":" + authCmd.Passphrase auth := "Basic " + base64.StdEncoding.EncodeToString([]byte(login)) authSha := fastsha256.Sum256([]byte(auth)) cmp := subtle.ConstantTimeCompare(authSha[:], c.server.authsha[:]) limitcmp := subtle.ConstantTimeCompare(authSha[:], c.server.limitauthsha[:]) if cmp != 1 && limitcmp != 1 { rpcsLog.Warnf("Auth failure.") break out } c.authenticated = true c.isAdmin = cmp == 1 // Marshal and send response. reply, err := createMarshalledReply(cmd.id, nil, nil) if err != nil { rpcsLog.Errorf("Failed to marshal authenticate reply: "+ "%v", err.Error()) continue } c.SendMessage(reply, nil) continue } // Check if the client is using limited RPC credentials and // error when not authorized to call this RPC. if !c.isAdmin { if _, ok := rpcLimited[request.Method]; !ok { jsonErr := &btcjson.RPCError{ Code: btcjson.ErrRPCInvalidParams.Code, Message: "limited user not authorized for this method", } // Marshal and send response. reply, err := createMarshalledReply(request.ID, nil, jsonErr) if err != nil { rpcsLog.Errorf("Failed to marshal parse failure "+ "reply: %v", err) continue } c.SendMessage(reply, nil) continue } } // Asynchronously handle the request. A semaphore is used to // limit the number of concurrent requests currently being // serviced. If the semaphore can not be acquired, simply wait // until a request finished before reading the next RPC request // from the websocket client. // // This could be a little fancier by timing out and erroring // when it takes too long to service the request, but if that is // done, the read of the next request should not be blocked by // this semaphore, otherwise the next request will be read and // will probably sit here for another few seconds before timing // out as well. This will cause the total timeout duration for // later requests to be much longer than the check here would // imply. // // If a timeout is added, the semaphore acquiring should be // moved inside of the new goroutine with a select statement // that also reads a time.After channel. This will unblock the // read of the next request from the websocket client and allow // many requests to be waited on concurrently. c.serviceRequestSem.acquire() go func() { c.serviceRequest(cmd) c.serviceRequestSem.release() }() } // Ensure the connection is closed. c.Disconnect() c.wg.Done() rpcsLog.Tracef("Websocket client input handler done for %s", c.addr) } // serviceRequest services a parsed RPC request by looking up and executing the // appropiate RPC handler. The response is marshalled and sent to the websocket // client. func (c *wsClient) serviceRequest(r *parsedRPCCmd) { var ( result interface{} err error ) // Lookup the websocket extension for the command and if it doesn't // exist fallback to handling the command as a standard command. wsHandler, ok := wsHandlers[r.method] if ok { result, err = wsHandler(c, r.cmd) } else { result, err = c.server.standardCmdResult(r, nil) } reply, err := createMarshalledReply(r.id, result, err) if err != nil { rpcsLog.Errorf("Failed to marshal reply for <%s> "+ "command: %v", r.method, err) return } c.SendMessage(reply, nil) } // notificationQueueHandler handles the queuing of outgoing notifications for // the websocket client. This runs as a muxer for various sources of input to // ensure that queuing up notifications to be sent will not block. Otherwise, // slow clients could bog down the other systems (such as the mempool or block // manager) which are queuing the data. The data is passed on to outHandler to // actually be written. It must be run as a goroutine. func (c *wsClient) notificationQueueHandler() { ntfnSentChan := make(chan bool, 1) // nonblocking sync // pendingNtfns is used as a queue for notifications that are ready to // be sent once there are no outstanding notifications currently being // sent. The waiting flag is used over simply checking for items in the // pending list to ensure cleanup knows what has and hasn't been sent // to the outHandler. Currently no special cleanup is needed, however // if something like a done channel is added to notifications in the // future, not knowing what has and hasn't been sent to the outHandler // (and thus who should respond to the done channel) would be // problematic without using this approach. pendingNtfns := list.New() waiting := false out: for { select { // This channel is notified when a message is being queued to // be sent across the network socket. It will either send the // message immediately if a send is not already in progress, or // queue the message to be sent once the other pending messages // are sent. case msg := <-c.ntfnChan: if !waiting { c.SendMessage(msg, ntfnSentChan) } else { pendingNtfns.PushBack(msg) } waiting = true // This channel is notified when a notification has been sent // across the network socket. case <-ntfnSentChan: // No longer waiting if there are no more messages in // the pending messages queue. next := pendingNtfns.Front() if next == nil { waiting = false continue } // Notify the outHandler about the next item to // asynchronously send. msg := pendingNtfns.Remove(next).([]byte) c.SendMessage(msg, ntfnSentChan) case <-c.quit: break out } } // Drain any wait channels before exiting so nothing is left waiting // around to send. cleanup: for { select { case <-c.ntfnChan: case <-ntfnSentChan: default: break cleanup } } c.wg.Done() rpcsLog.Tracef("Websocket client notification queue handler done "+ "for %s", c.addr) } // outHandler handles all outgoing messages for the websocket connection. It // must be run as a goroutine. It uses a buffered channel to serialize output // messages while allowing the sender to continue running asynchronously. It // must be run as a goroutine. func (c *wsClient) outHandler() { out: for { // Send any messages ready for send until the quit channel is // closed. select { case r := <-c.sendChan: err := c.conn.WriteMessage(websocket.TextMessage, r.msg) if err != nil { c.Disconnect() break out } if r.doneChan != nil { r.doneChan <- true } case <-c.quit: break out } } // Drain any wait channels before exiting so nothing is left waiting // around to send. cleanup: for { select { case r := <-c.sendChan: if r.doneChan != nil { r.doneChan <- false } default: break cleanup } } c.wg.Done() rpcsLog.Tracef("Websocket client output handler done for %s", c.addr) } // SendMessage sends the passed json to the websocket client. It is backed // by a buffered channel, so it will not block until the send channel is full. // Note however that QueueNotification must be used for sending async // notifications instead of the this function. This approach allows a limit to // the number of outstanding requests a client can make without preventing or // blocking on async notifications. func (c *wsClient) SendMessage(marshalledJSON []byte, doneChan chan bool) { // Don't send the message if disconnected. if c.Disconnected() { if doneChan != nil { doneChan <- false } return } c.sendChan <- wsResponse{msg: marshalledJSON, doneChan: doneChan} } // ErrClientQuit describes the error where a client send is not processed due // to the client having already been disconnected or dropped. var ErrClientQuit = errors.New("client quit") // QueueNotification queues the passed notification to be sent to the websocket // client. This function, as the name implies, is only intended for // notifications since it has additional logic to prevent other subsystems, such // as the memory pool and block manager, from blocking even when the send // channel is full. // // If the client is in the process of shutting down, this function returns // ErrClientQuit. This is intended to be checked by long-running notification // handlers to stop processing if there is no more work needed to be done. func (c *wsClient) QueueNotification(marshalledJSON []byte) error { // Don't queue the message if disconnected. if c.Disconnected() { return ErrClientQuit } c.ntfnChan <- marshalledJSON return nil } // Disconnected returns whether or not the websocket client is disconnected. func (c *wsClient) Disconnected() bool { c.Lock() isDisconnected := c.disconnected c.Unlock() return isDisconnected } // Disconnect disconnects the websocket client. func (c *wsClient) Disconnect() { c.Lock() defer c.Unlock() // Nothing to do if already disconnected. if c.disconnected { return } rpcsLog.Tracef("Disconnecting websocket client %s", c.addr) close(c.quit) c.conn.Close() c.disconnected = true } // Start begins processing input and output messages. func (c *wsClient) Start() { rpcsLog.Tracef("Starting websocket client %s", c.addr) // Start processing input and output. c.wg.Add(3) go c.inHandler() go c.notificationQueueHandler() go c.outHandler() } // WaitForShutdown blocks until the websocket client goroutines are stopped // and the connection is closed. func (c *wsClient) WaitForShutdown() { c.wg.Wait() } // newWebsocketClient returns a new websocket client given the notification // manager, websocket connection, remote address, and whether or not the client // has already been authenticated (via HTTP Basic access authentication). The // returned client is ready to start. Once started, the client will process // incoming and outgoing messages in separate goroutines complete with queuing // and asynchrous handling for long-running operations. func newWebsocketClient(server *rpcServer, conn *websocket.Conn, remoteAddr string, authenticated bool, isAdmin bool) (*wsClient, error) { sessionID, err := wire.RandomUint64() if err != nil { return nil, err } client := &wsClient{ conn: conn, addr: remoteAddr, authenticated: authenticated, isAdmin: isAdmin, sessionID: sessionID, server: server, addrRequests: make(map[string]struct{}), spentRequests: make(map[wire.OutPoint]struct{}), serviceRequestSem: makeSemaphore(cfg.RPCMaxConcurrentReqs), ntfnChan: make(chan []byte, 1), // nonblocking sync sendChan: make(chan wsResponse, websocketSendBufferSize), quit: make(chan struct{}), } return client, nil } // handleWebsocketHelp implements the help command for websocket connections. func handleWebsocketHelp(wsc *wsClient, icmd interface{}) (interface{}, error) { cmd, ok := icmd.(*btcjson.HelpCmd) if !ok { return nil, btcjson.ErrRPCInternal } // Provide a usage overview of all commands when no specific command // was specified. var command string if cmd.Command != nil { command = *cmd.Command } if command == "" { usage, err := wsc.server.helpCacher.rpcUsage(true) if err != nil { context := "Failed to generate RPC usage" return nil, internalRPCError(err.Error(), context) } return usage, nil } // Check that the command asked for is supported and implemented. // Search the list of websocket handlers as well as the main list of // handlers since help should only be provided for those cases. valid := true if _, ok := rpcHandlers[command]; !ok { if _, ok := wsHandlers[command]; !ok { valid = false } } if !valid { return nil, &btcjson.RPCError{ Code: btcjson.ErrRPCInvalidParameter, Message: "Unknown command: " + command, } } // Get the help for the command. help, err := wsc.server.helpCacher.rpcMethodHelp(command) if err != nil { context := "Failed to generate help" return nil, internalRPCError(err.Error(), context) } return help, nil } // handleNotifyBlocks implements the notifyblocks command extension for // websocket connections. func handleNotifyBlocks(wsc *wsClient, icmd interface{}) (interface{}, error) { wsc.server.ntfnMgr.RegisterBlockUpdates(wsc) return nil, nil } // handleSession implements the session command extension for websocket // connections. func handleSession(wsc *wsClient, icmd interface{}) (interface{}, error) { return &btcjson.SessionResult{SessionID: wsc.sessionID}, nil } // handleStopNotifyBlocks implements the stopnotifyblocks command extension for // websocket connections. func handleStopNotifyBlocks(wsc *wsClient, icmd interface{}) (interface{}, error) { wsc.server.ntfnMgr.UnregisterBlockUpdates(wsc) return nil, nil } // handleNotifySpent implements the notifyspent command extension for // websocket connections. func handleNotifySpent(wsc *wsClient, icmd interface{}) (interface{}, error) { cmd, ok := icmd.(*btcjson.NotifySpentCmd) if !ok { return nil, btcjson.ErrRPCInternal } outpoints, err := deserializeOutpoints(cmd.OutPoints) if err != nil { return nil, err } wsc.server.ntfnMgr.RegisterSpentRequests(wsc, outpoints) return nil, nil } // handleNotifyNewTransations implements the notifynewtransactions command // extension for websocket connections. func handleNotifyNewTransactions(wsc *wsClient, icmd interface{}) (interface{}, error) { cmd, ok := icmd.(*btcjson.NotifyNewTransactionsCmd) if !ok { return nil, btcjson.ErrRPCInternal } wsc.verboseTxUpdates = cmd.Verbose != nil && *cmd.Verbose wsc.server.ntfnMgr.RegisterNewMempoolTxsUpdates(wsc) return nil, nil } // handleStopNotifyNewTransations implements the stopnotifynewtransactions // command extension for websocket connections. func handleStopNotifyNewTransactions(wsc *wsClient, icmd interface{}) (interface{}, error) { wsc.server.ntfnMgr.UnregisterNewMempoolTxsUpdates(wsc) return nil, nil } // handleNotifyReceived implements the notifyreceived command extension for // websocket connections. func handleNotifyReceived(wsc *wsClient, icmd interface{}) (interface{}, error) { cmd, ok := icmd.(*btcjson.NotifyReceivedCmd) if !ok { return nil, btcjson.ErrRPCInternal } // Decode addresses to validate input, but the strings slice is used // directly if these are all ok. err := checkAddressValidity(cmd.Addresses) if err != nil { return nil, err } wsc.server.ntfnMgr.RegisterTxOutAddressRequests(wsc, cmd.Addresses) return nil, nil } // handleStopNotifySpent implements the stopnotifyspent command extension for // websocket connections. func handleStopNotifySpent(wsc *wsClient, icmd interface{}) (interface{}, error) { cmd, ok := icmd.(*btcjson.StopNotifySpentCmd) if !ok { return nil, btcjson.ErrRPCInternal } outpoints, err := deserializeOutpoints(cmd.OutPoints) if err != nil { return nil, err } for _, outpoint := range outpoints { wsc.server.ntfnMgr.UnregisterSpentRequest(wsc, outpoint) } return nil, nil } // handleStopNotifyReceived implements the stopnotifyreceived command extension // for websocket connections. func handleStopNotifyReceived(wsc *wsClient, icmd interface{}) (interface{}, error) { cmd, ok := icmd.(*btcjson.StopNotifyReceivedCmd) if !ok { return nil, btcjson.ErrRPCInternal } // Decode addresses to validate input, but the strings slice is used // directly if these are all ok. err := checkAddressValidity(cmd.Addresses) if err != nil { return nil, err } for _, addr := range cmd.Addresses { wsc.server.ntfnMgr.UnregisterTxOutAddressRequest(wsc, addr) } return nil, nil } // checkAddressValidity checks the validity of each address in the passed // string slice. It does this by attempting to decode each address using the // current active network parameters. If any single address fails to decode // properly, the function returns an error. Otherwise, nil is returned. func checkAddressValidity(addrs []string) error { for _, addr := range addrs { _, err := btcutil.DecodeAddress(addr, activeNetParams.Params) if err != nil { return &btcjson.RPCError{ Code: btcjson.ErrRPCInvalidAddressOrKey, Message: fmt.Sprintf("Invalid address or key: %v", addr), } } } return nil } // deserializeOutpoints deserializes each serialized outpoint. func deserializeOutpoints(serializedOuts []btcjson.OutPoint) ([]*wire.OutPoint, error) { outpoints := make([]*wire.OutPoint, 0, len(serializedOuts)) for i := range serializedOuts { blockHash, err := chainhash.NewHashFromStr(serializedOuts[i].Hash) if err != nil { return nil, rpcDecodeHexError(serializedOuts[i].Hash) } index := serializedOuts[i].Index outpoints = append(outpoints, wire.NewOutPoint(blockHash, index)) } return outpoints, nil } type rescanKeys struct { fallbacks map[string]struct{} pubKeyHashes map[[ripemd160.Size]byte]struct{} scriptHashes map[[ripemd160.Size]byte]struct{} compressedPubKeys map[[33]byte]struct{} uncompressedPubKeys map[[65]byte]struct{} unspent map[wire.OutPoint]struct{} } // unspentSlice returns a slice of currently-unspent outpoints for the rescan // lookup keys. This is primarily intended to be used to register outpoints // for continuous notifications after a rescan has completed. func (r *rescanKeys) unspentSlice() []*wire.OutPoint { ops := make([]*wire.OutPoint, 0, len(r.unspent)) for op := range r.unspent { opCopy := op ops = append(ops, &opCopy) } return ops } // ErrRescanReorg defines the error that is returned when an unrecoverable // reorganize is detected during a rescan. var ErrRescanReorg = btcjson.RPCError{ Code: btcjson.ErrRPCDatabase, Message: "Reorganize", } // rescanBlock rescans all transactions in a single block. This is a helper // function for handleRescan. func rescanBlock(wsc *wsClient, lookups *rescanKeys, blk *btcutil.Block) { for _, tx := range blk.Transactions() { // Hexadecimal representation of this tx. Only created if // needed, and reused for later notifications if already made. var txHex string // All inputs and outputs must be iterated through to correctly // modify the unspent map, however, just a single notification // for any matching transaction inputs or outputs should be // created and sent. spentNotified := false recvNotified := false for _, txin := range tx.MsgTx().TxIn { if _, ok := lookups.unspent[txin.PreviousOutPoint]; ok { delete(lookups.unspent, txin.PreviousOutPoint) if spentNotified { continue } if txHex == "" { txHex = txHexString(tx) } marshalledJSON, err := newRedeemingTxNotification(txHex, tx.Index(), blk) if err != nil { rpcsLog.Errorf("Failed to marshal redeemingtx notification: %v", err) continue } err = wsc.QueueNotification(marshalledJSON) // Stop the rescan early if the websocket client // disconnected. if err == ErrClientQuit { return } spentNotified = true } } for txOutIdx, txout := range tx.MsgTx().TxOut { _, addrs, _, _ := txscript.ExtractPkScriptAddrs( txout.PkScript, wsc.server.server.chainParams) for _, addr := range addrs { switch a := addr.(type) { case *btcutil.AddressPubKeyHash: if _, ok := lookups.pubKeyHashes[*a.Hash160()]; !ok { continue } case *btcutil.AddressScriptHash: if _, ok := lookups.scriptHashes[*a.Hash160()]; !ok { continue } case *btcutil.AddressPubKey: found := false switch sa := a.ScriptAddress(); len(sa) { case 33: // Compressed var key [33]byte copy(key[:], sa) if _, ok := lookups.compressedPubKeys[key]; ok { found = true } case 65: // Uncompressed var key [65]byte copy(key[:], sa) if _, ok := lookups.uncompressedPubKeys[key]; ok { found = true } default: rpcsLog.Warnf("Skipping rescanned pubkey of unknown "+ "serialized length %d", len(sa)) continue } // If the transaction output pays to the pubkey of // a rescanned P2PKH address, include it as well. if !found { pkh := a.AddressPubKeyHash() if _, ok := lookups.pubKeyHashes[*pkh.Hash160()]; !ok { continue } } default: // A new address type must have been added. Encode as a // payment address string and check the fallback map. addrStr := addr.EncodeAddress() _, ok := lookups.fallbacks[addrStr] if !ok { continue } } outpoint := wire.OutPoint{ Hash: *tx.Hash(), Index: uint32(txOutIdx), } lookups.unspent[outpoint] = struct{}{} if recvNotified { continue } if txHex == "" { txHex = txHexString(tx) } ntfn := btcjson.NewRecvTxNtfn(txHex, blockDetails(blk, tx.Index())) marshalledJSON, err := btcjson.MarshalCmd(nil, ntfn) if err != nil { rpcsLog.Errorf("Failed to marshal recvtx notification: %v", err) return } err = wsc.QueueNotification(marshalledJSON) // Stop the rescan early if the websocket client // disconnected. if err == ErrClientQuit { return } recvNotified = true } } } } // recoverFromReorg attempts to recover from a detected reorganize during a // rescan. It fetches a new range of block shas from the database and // verifies that the new range of blocks is on the same fork as a previous // range of blocks. If this condition does not hold true, the JSON-RPC error // for an unrecoverable reorganize is returned. func recoverFromReorg(chain *blockchain.BlockChain, minBlock, maxBlock int32, lastBlock *chainhash.Hash) ([]chainhash.Hash, error) { hashList, err := chain.HeightRange(minBlock, maxBlock) if err != nil { rpcsLog.Errorf("Error looking up block range: %v", err) return nil, &btcjson.RPCError{ Code: btcjson.ErrRPCDatabase, Message: "Database error: " + err.Error(), } } if lastBlock == nil || len(hashList) == 0 { return hashList, nil } blk, err := chain.BlockByHash(&hashList[0]) if err != nil { rpcsLog.Errorf("Error looking up possibly reorged block: %v", err) return nil, &btcjson.RPCError{ Code: btcjson.ErrRPCDatabase, Message: "Database error: " + err.Error(), } } jsonErr := descendantBlock(lastBlock, blk) if jsonErr != nil { return nil, jsonErr } return hashList, nil } // descendantBlock returns the appropriate JSON-RPC error if a current block // fetched during a reorganize is not a direct child of the parent block hash. func descendantBlock(prevHash *chainhash.Hash, curBlock *btcutil.Block) error { curHash := &curBlock.MsgBlock().Header.PrevBlock if !prevHash.IsEqual(curHash) { rpcsLog.Errorf("Stopping rescan for reorged block %v "+ "(replaced by block %v)", prevHash, curHash) return &ErrRescanReorg } return nil } // handleRescan implements the rescan command extension for websocket // connections. // // NOTE: This does not smartly handle reorgs, and fixing requires database // changes (for safe, concurrent access to full block ranges, and support // for other chains than the best chain). It will, however, detect whether // a reorg removed a block that was previously processed, and result in the // handler erroring. Clients must handle this by finding a block still in // the chain (perhaps from a rescanprogress notification) to resume their // rescan. func handleRescan(wsc *wsClient, icmd interface{}) (interface{}, error) { cmd, ok := icmd.(*btcjson.RescanCmd) if !ok { return nil, btcjson.ErrRPCInternal } outpoints := make([]*wire.OutPoint, 0, len(cmd.OutPoints)) for i := range cmd.OutPoints { cmdOutpoint := &cmd.OutPoints[i] blockHash, err := chainhash.NewHashFromStr(cmdOutpoint.Hash) if err != nil { return nil, rpcDecodeHexError(cmdOutpoint.Hash) } outpoint := wire.NewOutPoint(blockHash, cmdOutpoint.Index) outpoints = append(outpoints, outpoint) } numAddrs := len(cmd.Addresses) if numAddrs == 1 { rpcsLog.Info("Beginning rescan for 1 address") } else { rpcsLog.Infof("Beginning rescan for %d addresses", numAddrs) } // Build lookup maps. lookups := rescanKeys{ fallbacks: map[string]struct{}{}, pubKeyHashes: map[[ripemd160.Size]byte]struct{}{}, scriptHashes: map[[ripemd160.Size]byte]struct{}{}, compressedPubKeys: map[[33]byte]struct{}{}, uncompressedPubKeys: map[[65]byte]struct{}{}, unspent: map[wire.OutPoint]struct{}{}, } var compressedPubkey [33]byte var uncompressedPubkey [65]byte for _, addrStr := range cmd.Addresses { addr, err := btcutil.DecodeAddress(addrStr, activeNetParams.Params) if err != nil { jsonErr := btcjson.RPCError{ Code: btcjson.ErrRPCInvalidAddressOrKey, Message: "Rescan address " + addrStr + ": " + err.Error(), } return nil, &jsonErr } switch a := addr.(type) { case *btcutil.AddressPubKeyHash: lookups.pubKeyHashes[*a.Hash160()] = struct{}{} case *btcutil.AddressScriptHash: lookups.scriptHashes[*a.Hash160()] = struct{}{} case *btcutil.AddressPubKey: pubkeyBytes := a.ScriptAddress() switch len(pubkeyBytes) { case 33: // Compressed copy(compressedPubkey[:], pubkeyBytes) lookups.compressedPubKeys[compressedPubkey] = struct{}{} case 65: // Uncompressed copy(uncompressedPubkey[:], pubkeyBytes) lookups.uncompressedPubKeys[uncompressedPubkey] = struct{}{} default: jsonErr := btcjson.RPCError{ Code: btcjson.ErrRPCInvalidAddressOrKey, Message: "Pubkey " + addrStr + " is of unknown length", } return nil, &jsonErr } default: // A new address type must have been added. Use encoded // payment address string as a fallback until a fast path // is added. lookups.fallbacks[addrStr] = struct{}{} } } for _, outpoint := range outpoints { lookups.unspent[*outpoint] = struct{}{} } chain := wsc.server.chain minBlockHash, err := chainhash.NewHashFromStr(cmd.BeginBlock) if err != nil { return nil, rpcDecodeHexError(cmd.BeginBlock) } minBlock, err := chain.BlockHeightByHash(minBlockHash) if err != nil { return nil, &btcjson.RPCError{ Code: btcjson.ErrRPCBlockNotFound, Message: "Error getting block: " + err.Error(), } } maxBlock := int32(math.MaxInt32) if cmd.EndBlock != nil { maxBlockHash, err := chainhash.NewHashFromStr(*cmd.EndBlock) if err != nil { return nil, rpcDecodeHexError(*cmd.EndBlock) } maxBlock, err = chain.BlockHeightByHash(maxBlockHash) if err != nil { return nil, &btcjson.RPCError{ Code: btcjson.ErrRPCBlockNotFound, Message: "Error getting block: " + err.Error(), } } } // lastBlock and lastBlockHash track the previously-rescanned block. // They equal nil when no previous blocks have been rescanned. var lastBlock *btcutil.Block var lastBlockHash *chainhash.Hash // A ticker is created to wait at least 10 seconds before notifying the // websocket client of the current progress completed by the rescan. ticker := time.NewTicker(10 * time.Second) defer ticker.Stop() // Instead of fetching all block shas at once, fetch in smaller chunks // to ensure large rescans consume a limited amount of memory. fetchRange: for minBlock < maxBlock { // Limit the max number of hashes to fetch at once to the // maximum number of items allowed in a single inventory. // This value could be higher since it's not creating inventory // messages, but this mirrors the limiting logic used in the // peer-to-peer protocol. maxLoopBlock := maxBlock if maxLoopBlock-minBlock > wire.MaxInvPerMsg { maxLoopBlock = minBlock + wire.MaxInvPerMsg } hashList, err := chain.HeightRange(minBlock, maxLoopBlock) if err != nil { rpcsLog.Errorf("Error looking up block range: %v", err) return nil, &btcjson.RPCError{ Code: btcjson.ErrRPCDatabase, Message: "Database error: " + err.Error(), } } if len(hashList) == 0 { // The rescan is finished if no blocks hashes for this // range were successfully fetched and a stop block // was provided. if maxBlock != math.MaxInt32 { break } // If the rescan is through the current block, set up // the client to continue to receive notifications // regarding all rescanned addresses and the current set // of unspent outputs. // // This is done safely by temporarily grabbing exclusive // access of the block manager. If no more blocks have // been attached between this pause and the fetch above, // then it is safe to register the websocket client for // continuous notifications if necessary. Otherwise, // continue the fetch loop again to rescan the new // blocks (or error due to an irrecoverable reorganize). blockManager := wsc.server.server.blockManager pauseGuard := blockManager.Pause() best := blockManager.chain.BestSnapshot() curHash := best.Hash again := true if lastBlockHash == nil || *lastBlockHash == *curHash { again = false n := wsc.server.ntfnMgr n.RegisterSpentRequests(wsc, lookups.unspentSlice()) n.RegisterTxOutAddressRequests(wsc, cmd.Addresses) } close(pauseGuard) if err != nil { rpcsLog.Errorf("Error fetching best block "+ "hash: %v", err) return nil, &btcjson.RPCError{ Code: btcjson.ErrRPCDatabase, Message: "Database error: " + err.Error(), } } if again { continue } break } loopHashList: for i := range hashList { blk, err := chain.BlockByHash(&hashList[i]) if err != nil { // Only handle reorgs if a block could not be // found for the hash. if dbErr, ok := err.(database.Error); !ok || dbErr.ErrorCode != database.ErrBlockNotFound { rpcsLog.Errorf("Error looking up "+ "block: %v", err) return nil, &btcjson.RPCError{ Code: btcjson.ErrRPCDatabase, Message: "Database error: " + err.Error(), } } // If an absolute max block was specified, don't // attempt to handle the reorg. if maxBlock != math.MaxInt32 { rpcsLog.Errorf("Stopping rescan for "+ "reorged block %v", cmd.EndBlock) return nil, &ErrRescanReorg } // If the lookup for the previously valid block // hash failed, there may have been a reorg. // Fetch a new range of block hashes and verify // that the previously processed block (if there // was any) still exists in the database. If it // doesn't, we error. // // A goto is used to branch executation back to // before the range was evaluated, as it must be // reevaluated for the new hashList. minBlock += int32(i) hashList, err = recoverFromReorg(chain, minBlock, maxBlock, lastBlockHash) if err != nil { return nil, err } if len(hashList) == 0 { break fetchRange } goto loopHashList } if i == 0 && lastBlockHash != nil { // Ensure the new hashList is on the same fork // as the last block from the old hashList. jsonErr := descendantBlock(lastBlockHash, blk) if jsonErr != nil { return nil, jsonErr } } // A select statement is used to stop rescans if the // client requesting the rescan has disconnected. select { case <-wsc.quit: rpcsLog.Debugf("Stopped rescan at height %v "+ "for disconnected client", blk.Height()) return nil, nil default: rescanBlock(wsc, &lookups, blk) lastBlock = blk lastBlockHash = blk.Hash() } // Periodically notify the client of the progress // completed. Continue with next block if no progress // notification is needed yet. select { case <-ticker.C: // fallthrough default: continue } n := btcjson.NewRescanProgressNtfn(hashList[i].String(), int32(blk.Height()), blk.MsgBlock().Header.Timestamp.Unix()) mn, err := btcjson.MarshalCmd(nil, n) if err != nil { rpcsLog.Errorf("Failed to marshal rescan "+ "progress notification: %v", err) continue } if err = wsc.QueueNotification(mn); err == ErrClientQuit { // Finished if the client disconnected. rpcsLog.Debugf("Stopped rescan at height %v "+ "for disconnected client", blk.Height()) return nil, nil } } minBlock += int32(len(hashList)) } // Notify websocket client of the finished rescan. Due to how btcd // asynchronously queues notifications to not block calling code, // there is no guarantee that any of the notifications created during // rescan (such as rescanprogress, recvtx and redeemingtx) will be // received before the rescan RPC returns. Therefore, another method // is needed to safely inform clients that all rescan notifications have // been sent. n := btcjson.NewRescanFinishedNtfn(lastBlockHash.String(), lastBlock.Height(), lastBlock.MsgBlock().Header.Timestamp.Unix()) if mn, err := btcjson.MarshalCmd(nil, n); err != nil { rpcsLog.Errorf("Failed to marshal rescan finished "+ "notification: %v", err) } else { // The rescan is finished, so we don't care whether the client // has disconnected at this point, so discard error. _ = wsc.QueueNotification(mn) } rpcsLog.Info("Finished rescan") return nil, nil } func init() { wsHandlers = wsHandlersBeforeInit }