lbcd/rpcwebsocket.go
Josh Rickmar bcc78565fd Initial pass at updating to btcnet.
This change modifies the params struct to embed a *btcnet.Params,
removing the old parameter fields that are handled by the btcnet
package.

Hardcoded network checks have also been removed in favor of modifying
behavior based on the current active net's parameters.

Not all library packages, notable btcutil and btcchain, have been
updated to use btcnet yet, but with this change, each package can be
updated one at a time since the active net's btcnet.Params are
available at each callsite.

ok @davecgh
2014-05-23 01:02:14 -05:00

1747 lines
52 KiB
Go

// Copyright (c) 2013-2014 Conformal Systems LLC.
// Use of this source code is governed by an ISC
// license that can be found in the LICENSE file.
package main
import (
"bytes"
"code.google.com/p/go.crypto/ripemd160"
"code.google.com/p/go.net/websocket"
"container/list"
"crypto/subtle"
"encoding/base64"
"encoding/hex"
"encoding/json"
"errors"
"fmt"
"github.com/conformal/btcjson"
"github.com/conformal/btcscript"
"github.com/conformal/btcutil"
"github.com/conformal/btcwire"
"github.com/conformal/btcws"
"github.com/conformal/fastsha256"
"io"
"sync"
"time"
)
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 queueing mechanism
// independent of the send channel buffer.
websocketSendBufferSize = 50
)
// 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, btcjson.Cmd) (interface{}, *btcjson.Error)
// wsHandlers maps RPC command strings to appropriate websocket handler
// functions.
var wsHandlers = map[string]wsCommandHandler{
"notifyblocks": handleNotifyBlocks,
"notifynewtransactions": handleNotifyNewTransactions,
"notifyreceived": handleNotifyReceived,
"notifyspent": handleNotifySpent,
"rescan": handleRescan,
}
// wsAsyncHandlers holds the websocket commands which should be run
// asynchronously to the main input handler goroutine. This allows long-running
// operations to run concurrently (and one at a time) while still responding
// to the majority of normal requests which can be answered quickly.
var wsAsyncHandlers = map[string]bool{
"rescan": true,
}
// 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) {
// 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 := newWebsocketClient(s, conn, remoteAddr, authenticated)
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
}
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 enqueueing 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 enqueueing 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 := &notificationTxAcceptedByMempool{
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
// enqueueing 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
op *btcwire.OutPoint
}
type notificationUnregisterSpent struct {
wsc *wsClient
op *btcwire.OutPoint
}
type notificationRegisterAddr struct {
wsc *wsClient
addr 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 bool]*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 bool]*wsClient)
txNotifications := make(map[chan bool]*wsClient)
watchedOutPoints := make(map[btcwire.OutPoint]map[chan bool]*wsClient)
watchedAddrs := make(map[string]map[chan bool]*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)
if len(blockNotifications) != 0 {
m.notifyBlockConnected(blockNotifications,
block)
}
// Skip iterating through all txs if no
// tx notification requests exist.
if len(watchedOutPoints) == 0 && len(watchedAddrs) == 0 {
continue
}
for _, tx := range block.Transactions() {
m.notifyForTx(watchedOutPoints,
watchedAddrs, tx, 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.addSpentRequest(watchedOutPoints, n.wsc, n.op)
case *notificationUnregisterSpent:
m.removeSpentRequest(watchedOutPoints, n.wsc, n.op)
case *notificationRegisterAddr:
m.addAddrRequest(watchedAddrs, n.wsc, n.addr)
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 bool]*wsClient,
block *btcutil.Block) {
hash, err := block.Sha()
if err != nil {
rpcsLog.Error("Bad block; connected block notification dropped")
return
}
// Notify interested websocket clients about the connected block.
ntfn := btcws.NewBlockConnectedNtfn(hash.String(), int32(block.Height()))
marshalledJSON, err := json.Marshal(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 bool]*wsClient, block *btcutil.Block) {
// Skip notification creation if no clients have requested block
// connected/disconnected notifications.
if len(clients) == 0 {
return
}
hash, err := block.Sha()
if err != nil {
rpcsLog.Error("Bad block; disconnected block notification " +
"dropped")
return
}
// Notify interested websocket clients about the disconnected block.
ntfn := btcws.NewBlockDisconnectedNtfn(hash.String(),
int32(block.Height()))
marshalledJSON, err := json.Marshal(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 registerd for updates
// when a new transaction is added to the memory pool.
func (m *wsNotificationManager) notifyForNewTx(clients map[chan bool]*wsClient, tx *btcutil.Tx) {
txShaStr := tx.Sha().String()
mtx := tx.MsgTx()
var amount int64
for _, txOut := range mtx.TxOut {
amount += txOut.Value
}
ntfn := btcws.NewTxAcceptedNtfn(txShaStr, amount)
marshalledJSON, err := json.Marshal(ntfn)
if err != nil {
rpcsLog.Errorf("Failed to marshal tx notification: %s", err.Error())
return
}
var verboseNtfn *btcws.TxAcceptedVerboseNtfn
var marshalledJSONVerbose []byte
for _, wsc := range clients {
if wsc.verboseTxUpdates {
if verboseNtfn == nil {
net := m.server.server.btcnet
rawTx, err := createTxRawResult(net, txShaStr,
mtx, nil, 0, nil)
if err != nil {
return
}
verboseNtfn = btcws.NewTxAcceptedVerboseNtfn(rawTx)
marshalledJSONVerbose, err = json.Marshal(verboseNtfn)
if err != nil {
rpcsLog.Errorf("Failed to marshal verbose tx notification: %s", err.Error())
return
}
}
wsc.QueueNotification(marshalledJSONVerbose)
} else {
wsc.QueueNotification(marshalledJSON)
}
}
}
// RegisterSpentRequest requests an notification when the passed outpoint 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) RegisterSpentRequest(wsc *wsClient, op *btcwire.OutPoint) {
m.queueNotification <- &notificationRegisterSpent{
wsc: wsc,
op: op,
}
}
// addSpentRequest modifies a map of watched outpoints to sets of websocket
// clients to add a new request watch the outpoint op and create and send
// a notification when spent to the websocket client wsc.
func (*wsNotificationManager) addSpentRequest(ops map[btcwire.OutPoint]map[chan bool]*wsClient,
wsc *wsClient, op *btcwire.OutPoint) {
// 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 := ops[*op]
if !ok {
cmap = make(map[chan bool]*wsClient)
ops[*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 *btcwire.OutPoint) {
m.queueNotification <- &notificationUnregisterSpent{
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[btcwire.OutPoint]map[chan bool]*wsClient,
wsc *wsClient, op *btcwire.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) *btcws.BlockDetails {
if block == nil {
return nil
}
blockSha, _ := block.Sha() // never errors
return &btcws.BlockDetails{
Height: int32(block.Height()),
Hash: blockSha.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 := btcws.NewRedeemingTxNtfn(txHex, blockDetails(block, index))
return json.Marshal(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[btcwire.OutPoint]map[chan bool]*wsClient,
addrs map[string]map[chan bool]*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 bool]bool)
for i, txOut := range tx.MsgTx().TxOut {
_, txAddrs, _, err := btcscript.ExtractPkScriptAddrs(
txOut.PkScript, m.server.server.btcnet)
if err != nil {
continue
}
for _, txAddr := range txAddrs {
cmap, ok := addrs[txAddr.EncodeAddress()]
if !ok {
continue
}
if txHex == "" {
txHex = txHexString(tx)
}
ntfn := btcws.NewRecvTxNtfn(txHex, blockDetails(block, tx.Index()))
marshalledJSON, err := json.Marshal(ntfn)
if err != nil {
rpcsLog.Errorf("Failed to marshal processedtx notification: %v", err)
continue
}
op := btcwire.NewOutPoint(tx.Sha(), uint32(i))
for wscQuit, wsc := range cmap {
m.addSpentRequest(ops, wsc, op)
if !wscNotified[wscQuit] {
wscNotified[wscQuit] = true
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[btcwire.OutPoint]map[chan bool]*wsClient,
addrs map[string]map[chan bool]*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[btcwire.OutPoint]map[chan bool]*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 bool]bool)
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 !wscNotified[wscQuit] {
wscNotified[wscQuit] = true
wsc.QueueNotification(marshalledJSON)
}
}
}
}
}
// RegisterTxOutAddressRequest requests notifications to the passed websocket
// client when a transaction output spends to the passed address.
func (m *wsNotificationManager) RegisterTxOutAddressRequest(wsc *wsClient, addr string) {
m.queueNotification <- &notificationRegisterAddr{
wsc: wsc,
addr: addr,
}
}
// addAddrRequest adds the websocket client wsc to the address to client set
// addrs so wsc will be notified for any mempool or block transaction outputs
// spending to addr.
func (*wsNotificationManager) addAddrRequest(addrs map[string]map[chan bool]*wsClient,
wsc *wsClient, addr string) {
// 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 := addrs[addr]
if !ok {
cmap = make(map[chan bool]*wsClient)
addrs[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 <- &notificationUnregisterAddr{
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 bool]*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 the 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
}
// createMarshalledReply returns a new marshalled btcjson.Reply given the
// passed parameters. It will automatically convert errors that are not of
// the type *btcjson.Error to the appropriate type as needed.
func createMarshalledReply(id, result interface{}, replyErr error) ([]byte, error) {
var jsonErr *btcjson.Error
if replyErr != nil {
if jErr, ok := replyErr.(*btcjson.Error); ok {
jsonErr = jErr
} else {
jsonErr = &btcjson.Error{
Code: btcjson.ErrInternal.Code,
Message: replyErr.Error(),
}
}
}
response := btcjson.Reply{
Id: &id,
Result: result,
Error: jsonErr,
}
marshalledJSON, err := json.Marshal(response)
if err != nil {
return nil, err
}
return marshalledJSON, nil
}
// 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
// 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[btcwire.OutPoint]struct{}
// Networking infrastructure.
asyncStarted bool
asyncChan chan btcjson.Cmd
ntfnChan chan []byte
sendChan chan wsResponse
quit chan bool
wg sync.WaitGroup
}
// handleMessage is the main handler for incoming requests. It enforces
// authentication, parses the incoming json, looks up and executes handlers
// (including pass through for standard RPC commands), sends the appropriate
// response. It also detects commands which are marked as long-running and
// sends them off to the asyncHander for processing.
func (c *wsClient) handleMessage(msg string) {
if !c.authenticated {
// Disconnect immediately if the provided command fails to
// parse when the client is not already authenticated.
cmd, jsonErr := parseCmd([]byte(msg))
if jsonErr != nil {
c.Disconnect()
return
}
// Disconnect immediately if the first command is not
// authenticate when not already authenticated.
authCmd, ok := cmd.(*btcws.AuthenticateCmd)
if !ok {
rpcsLog.Warnf("Unauthenticated websocket message " +
"received")
c.Disconnect()
return
}
// 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[:])
if cmp != 1 {
rpcsLog.Warnf("Auth failure.")
c.Disconnect()
return
}
c.authenticated = true
// Marshal and send response.
reply, err := createMarshalledReply(authCmd.Id(), nil, nil)
if err != nil {
rpcsLog.Errorf("Failed to marshal authenticate reply: "+
"%v", err.Error())
return
}
c.SendMessage(reply, nil)
return
}
// Attmpt to parse the raw json into a known btcjson.Cmd.
cmd, jsonErr := parseCmd([]byte(msg))
if jsonErr != nil {
// Use the provided id for errors when a valid JSON-RPC message
// was parsed. Requests with no IDs are ignored.
var id interface{}
if cmd != nil {
id = cmd.Id()
if id == nil {
return
}
}
// Marshal and send response.
reply, err := createMarshalledReply(id, nil, jsonErr)
if err != nil {
rpcsLog.Errorf("Failed to marshal parse failure "+
"reply: %v", err)
return
}
c.SendMessage(reply, nil)
return
}
rpcsLog.Debugf("Received command <%s> from %s", cmd.Method(), c.addr)
// Disconnect if already authenticated and another authenticate command
// is received.
if _, ok := cmd.(*btcws.AuthenticateCmd); ok {
rpcsLog.Warnf("Websocket client %s is already authenticated",
c.addr)
c.Disconnect()
return
}
// When the command is marked as a long-running command, send it off
// to the asyncHander goroutine for processing.
if _, ok := wsAsyncHandlers[cmd.Method()]; ok {
// Start up the async goroutine for handling long-running
// requests asynchonrously if needed.
if !c.asyncStarted {
rpcsLog.Tracef("Starting async handler for %s", c.addr)
c.wg.Add(1)
go c.asyncHandler()
c.asyncStarted = true
}
c.asyncChan <- cmd
return
}
// 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[cmd.Method()]
if !ok {
// No websocket-specific handler so handle like a legacy
// RPC connection.
response := standardCmdReply(cmd, c.server)
reply, err := json.Marshal(response)
if err != nil {
rpcsLog.Errorf("Failed to marshal reply for <%s> "+
"command: %v", cmd.Method(), err)
return
}
c.SendMessage(reply, nil)
return
}
// Invoke the handler and marshal and send response.
result, jsonErr := wsHandler(c, cmd)
reply, err := createMarshalledReply(cmd.Id(), result, jsonErr)
if err != nil {
rpcsLog.Errorf("Failed to marshal reply for <%s> command: %v",
cmd.Method(), err)
return
}
c.SendMessage(reply, nil)
}
// 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:
}
var msg string
if err := websocket.Message.Receive(c.conn, &msg); 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
}
c.handleMessage(msg)
}
// Ensure the connection is closed.
c.Disconnect()
c.wg.Done()
rpcsLog.Tracef("Websocket client input handler done for %s", c.addr)
}
// notificationQueueHandler handles the queueing of outgoing notifications for
// the websocket client. This runs as a muxer for various sources of input to
// ensure that queueing 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 queueing 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 := websocket.Message.Send(c.conn, string(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)
}
// asyncHandler handles all long-running requests such as rescans which are
// not run directly in the inHandler routine unlike most requests. This allows
// normal quick requests to continue to be processed and responded to even while
// lengthy operations are underway. Only one long-running operation is
// permitted at a time, so multiple long-running requests are queued and
// serialized. It must be run as a goroutine. Also, this goroutine is not
// started until/if the first long-running request is made.
func (c *wsClient) asyncHandler() {
asyncHandlerDoneChan := make(chan bool, 1) // nonblocking sync
pendingCmds := list.New()
waiting := false
// runHandler runs the handler for the passed command and sends the
// reply.
runHandler := func(cmd btcjson.Cmd) {
wsHandler, ok := wsHandlers[cmd.Method()]
if !ok {
rpcsLog.Warnf("No handler for command <%s>",
cmd.Method())
return
}
// Invoke the handler and marshal and send response.
result, jsonErr := wsHandler(c, cmd)
reply, err := createMarshalledReply(cmd.Id(), result, jsonErr)
if err != nil {
rpcsLog.Errorf("Failed to marshal reply for <%s> "+
"command: %v", cmd.Method(), err)
return
}
c.SendMessage(reply, nil)
}
out:
for {
select {
case cmd := <-c.asyncChan:
if !waiting {
c.wg.Add(1)
go func(cmd btcjson.Cmd) {
runHandler(cmd)
asyncHandlerDoneChan <- true
c.wg.Done()
}(cmd)
} else {
pendingCmds.PushBack(cmd)
}
waiting = true
case <-asyncHandlerDoneChan:
// No longer waiting if there are no more messages in
// the pending messages queue.
next := pendingCmds.Front()
if next == nil {
waiting = false
continue
}
// Notify the outHandler about the next item to
// asynchronously send.
element := pendingCmds.Remove(next)
c.wg.Add(1)
go func(cmd btcjson.Cmd) {
runHandler(cmd)
asyncHandlerDoneChan <- true
c.wg.Done()
}(element.(btcjson.Cmd))
case <-c.quit:
break out
}
}
// Drain any wait channels before exiting so nothing is left waiting
// around to send.
cleanup:
for {
select {
case <-c.asyncChan:
case <-asyncHandlerDoneChan:
default:
break cleanup
}
}
c.wg.Done()
rpcsLog.Tracef("Websocket client async 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")
// QueueMessage 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()
defer c.Unlock()
return c.disconnected
}
// 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 queueing
// and asynchrous handling for long-running operations.
func newWebsocketClient(server *rpcServer, conn *websocket.Conn,
remoteAddr string, authenticated bool) *wsClient {
return &wsClient{
conn: conn,
addr: remoteAddr,
authenticated: authenticated,
server: server,
addrRequests: make(map[string]struct{}),
spentRequests: make(map[btcwire.OutPoint]struct{}),
ntfnChan: make(chan []byte, 1), // nonblocking sync
asyncChan: make(chan btcjson.Cmd, 1), // nonblocking sync
sendChan: make(chan wsResponse, websocketSendBufferSize),
quit: make(chan bool),
}
}
// handleNotifyBlocks implements the notifyblocks command extension for
// websocket connections.
func handleNotifyBlocks(wsc *wsClient, icmd btcjson.Cmd) (interface{}, *btcjson.Error) {
wsc.server.ntfnMgr.RegisterBlockUpdates(wsc)
return nil, nil
}
// handleNotifySpent implements the notifyspent command extension for
// websocket connections.
func handleNotifySpent(wsc *wsClient, icmd btcjson.Cmd) (interface{}, *btcjson.Error) {
cmd, ok := icmd.(*btcws.NotifySpentCmd)
if !ok {
return nil, &btcjson.ErrInternal
}
outpoints := make([]*btcwire.OutPoint, 0, len(cmd.OutPoints))
for i := range cmd.OutPoints {
blockHash, err := btcwire.NewShaHashFromStr(cmd.OutPoints[i].Hash)
if err != nil {
return nil, &btcjson.Error{
Code: btcjson.ErrParse.Code,
Message: err.Error(),
}
}
index := cmd.OutPoints[i].Index
outpoints = append(outpoints, btcwire.NewOutPoint(blockHash, index))
}
for _, outpoint := range outpoints {
wsc.server.ntfnMgr.RegisterSpentRequest(wsc, outpoint)
}
return nil, nil
}
// handleNotifyNewTransations implements the notifynewtransactions command
// extension for websocket connections.
func handleNotifyNewTransactions(wsc *wsClient, icmd btcjson.Cmd) (interface{}, *btcjson.Error) {
cmd, ok := icmd.(*btcws.NotifyNewTransactionsCmd)
if !ok {
return nil, &btcjson.ErrInternal
}
wsc.verboseTxUpdates = cmd.Verbose
wsc.server.ntfnMgr.RegisterNewMempoolTxsUpdates(wsc)
return nil, nil
}
// handleNotifyReceived implements the notifyreceived command extension for
// websocket connections.
func handleNotifyReceived(wsc *wsClient, icmd btcjson.Cmd) (interface{}, *btcjson.Error) {
cmd, ok := icmd.(*btcws.NotifyReceivedCmd)
if !ok {
return nil, &btcjson.ErrInternal
}
for _, addrStr := range cmd.Addresses {
addr, err := btcutil.DecodeAddress(addrStr, activeNetParams.Net)
if err != nil {
e := btcjson.Error{
Code: btcjson.ErrInvalidAddressOrKey.Code,
Message: fmt.Sprintf("Invalid address or key: %v", addrStr),
}
return nil, &e
}
wsc.server.ntfnMgr.RegisterTxOutAddressRequest(wsc, addr.EncodeAddress())
}
return nil, 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[btcwire.OutPoint]struct{}
}
// 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, _, _ := btcscript.ExtractPkScriptAddrs(
txout.PkScript, wsc.server.server.btcnet)
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 := btcwire.OutPoint{
Hash: *tx.Sha(),
Index: uint32(txOutIdx),
}
lookups.unspent[outpoint] = struct{}{}
if recvNotified {
continue
}
if txHex == "" {
txHex = txHexString(tx)
}
ntfn := btcws.NewRecvTxNtfn(txHex, blockDetails(blk, tx.Index()))
marshalledJSON, err := json.Marshal(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
}
}
}
}
// handleRescan implements the rescan command extension for websocket
// connections.
func handleRescan(wsc *wsClient, icmd btcjson.Cmd) (interface{}, *btcjson.Error) {
cmd, ok := icmd.(*btcws.RescanCmd)
if !ok {
return nil, &btcjson.ErrInternal
}
outpoints := make([]*btcwire.OutPoint, 0, len(cmd.OutPoints))
for i := range cmd.OutPoints {
blockHash, err := btcwire.NewShaHashFromStr(cmd.OutPoints[i].Hash)
if err != nil {
return nil, &btcjson.Error{
Code: btcjson.ErrParse.Code,
Message: err.Error(),
}
}
index := cmd.OutPoints[i].Index
outpoints = append(outpoints, btcwire.NewOutPoint(blockHash, index))
}
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[btcwire.OutPoint]struct{}{},
}
var compressedPubkey [33]byte
var uncompressedPubkey [65]byte
for _, addrStr := range cmd.Addresses {
addr, err := btcutil.DecodeAddress(addrStr, activeNetParams.Net)
if err != nil {
jsonErr := btcjson.Error{
Code: btcjson.ErrInvalidAddressOrKey.Code,
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.Error{
Code: btcjson.ErrInvalidAddressOrKey.Code,
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{}{}
}
minBlock := int64(cmd.BeginBlock)
maxBlock := int64(cmd.EndBlock)
// 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()
// FetchHeightRange may not return a complete list of block shas for
// the given range, so fetch range as many times as necessary.
db := wsc.server.server.db
for minBlock < maxBlock {
hashList, err := db.FetchHeightRange(minBlock, maxBlock)
if err != nil {
rpcsLog.Errorf("Error looking up block range: %v", err)
return nil, &btcjson.ErrDatabase
}
if len(hashList) == 0 {
break
}
for i := range hashList {
blk, err := db.FetchBlockBySha(&hashList[i])
if err != nil {
rpcsLog.Errorf("Error looking up block sha: %v", err)
return nil, &btcjson.ErrDatabase
}
// 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)
}
// 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 := btcws.NewRescanProgressNtfn(int32(blk.Height()))
mn, err := n.MarshalJSON()
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 += int64(len(hashList))
}
rpcsLog.Info("Finished rescan")
return nil, nil
}