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peer.go
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peer.go
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package main
import (
"bytes"
"container/list"
"errors"
"fmt"
"net"
"sync"
"sync/atomic"
"time"
"github.com/btcsuite/btcd/btcec"
"github.com/btcsuite/btcd/chaincfg/chainhash"
"github.com/btcsuite/btcd/connmgr"
"github.com/btcsuite/btcd/txscript"
"github.com/btcsuite/btcd/wire"
"github.com/davecgh/go-spew/spew"
"github.com/lightningnetwork/lnd/brontide"
"github.com/lightningnetwork/lnd/chainntnfs"
"github.com/lightningnetwork/lnd/channeldb"
"github.com/lightningnetwork/lnd/contractcourt"
"github.com/lightningnetwork/lnd/htlcswitch"
"github.com/lightningnetwork/lnd/lnpeer"
"github.com/lightningnetwork/lnd/lnrpc"
"github.com/lightningnetwork/lnd/lnwallet"
"github.com/lightningnetwork/lnd/lnwire"
"github.com/lightningnetwork/lnd/ticker"
)
var (
numNodes int32
// ErrPeerExiting signals that the peer received a disconnect request.
ErrPeerExiting = fmt.Errorf("peer exiting")
)
const (
// pingInterval is the interval at which ping messages are sent.
pingInterval = 1 * time.Minute
// idleTimeout is the duration of inactivity before we time out a peer.
idleTimeout = 5 * time.Minute
// writeMessageTimeout is the timeout used when writing a message to peer.
writeMessageTimeout = 50 * time.Second
// outgoingQueueLen is the buffer size of the channel which houses
// messages to be sent across the wire, requested by objects outside
// this struct.
outgoingQueueLen = 50
)
// outgoingMsg packages an lnwire.Message to be sent out on the wire, along with
// a buffered channel which will be sent upon once the write is complete. This
// buffered channel acts as a semaphore to be used for synchronization purposes.
type outgoingMsg struct {
msg lnwire.Message
errChan chan error // MUST be buffered.
}
// newChannelMsg packages a channeldb.OpenChannel with a channel that allows
// the receiver of the request to report when the funding transaction has been
// confirmed and the channel creation process completed.
type newChannelMsg struct {
channel *channeldb.OpenChannel
err chan error
}
// closeMsgs is a wrapper struct around any wire messages that deal with the
// cooperative channel closure negotiation process. This struct includes the
// raw channel ID targeted along with the original message.
type closeMsg struct {
cid lnwire.ChannelID
msg lnwire.Message
}
// chanSnapshotReq is a message sent by outside subsystems to a peer in order
// to gain a snapshot of the peer's currently active channels.
type chanSnapshotReq struct {
resp chan []*channeldb.ChannelSnapshot
}
// peer is an active peer on the Lightning Network. This struct is responsible
// for managing any channel state related to this peer. To do so, it has
// several helper goroutines to handle events such as HTLC timeouts, new
// funding workflow, and detecting an uncooperative closure of any active
// channels.
// TODO(roasbeef): proper reconnection logic
type peer struct {
// MUST be used atomically.
started int32
disconnect int32
// The following fields are only meant to be used *atomically*
bytesReceived uint64
bytesSent uint64
// pingTime is a rough estimate of the RTT (round-trip-time) between us
// and the connected peer. This time is expressed in micro seconds.
// To be used atomically.
// TODO(roasbeef): also use a WMA or EMA?
pingTime int64
// pingLastSend is the Unix time expressed in nanoseconds when we sent
// our last ping message. To be used atomically.
pingLastSend int64
connReq *connmgr.ConnReq
conn net.Conn
addr *lnwire.NetAddress
pubKeyBytes [33]byte
// startTime is the time this peer connection was successfully
// established. It will be zero for peers that did not successfully
// Start().
startTime time.Time
inbound bool
// sendQueue is the channel which is used to queue outgoing to be
// written onto the wire. Note that this channel is unbuffered.
sendQueue chan outgoingMsg
// outgoingQueue is a buffered channel which allows second/third party
// objects to queue messages to be sent out on the wire.
outgoingQueue chan outgoingMsg
// activeChannels is a map which stores the state machines of all
// active channels. Channels are indexed into the map by the txid of
// the funding transaction which opened the channel.
activeChanMtx sync.RWMutex
activeChannels map[lnwire.ChannelID]*lnwallet.LightningChannel
// newChannels is used by the fundingManager to send fully opened
// channels to the source peer which handled the funding workflow.
newChannels chan *newChannelMsg
// activeChanCloses is a map that keep track of all the active
// cooperative channel closures that are active. Any channel closing
// messages are directed to one of these active state machines. Once
// the channel has been closed, the state machine will be delete from
// the map.
activeChanCloses map[lnwire.ChannelID]*channelCloser
// localCloseChanReqs is a channel in which any local requests to close
// a particular channel are sent over.
localCloseChanReqs chan *htlcswitch.ChanClose
// linkFailures receives all reported channel failures from the switch,
// and instructs the channelManager to clean remaining channel state.
linkFailures chan linkFailureReport
// chanCloseMsgs is a channel that any message related to channel
// closures are sent over. This includes lnwire.Shutdown message as
// well as lnwire.ClosingSigned messages.
chanCloseMsgs chan *closeMsg
server *server
// localFeatures is the set of local features that we advertised to the
// remote node.
localFeatures *lnwire.RawFeatureVector
// remoteLocalFeatures is the local feature vector received from the
// peer during the connection handshake.
remoteLocalFeatures *lnwire.FeatureVector
// remoteGlobalFeatures is the global feature vector received from the
// peer during the connection handshake.
remoteGlobalFeatures *lnwire.FeatureVector
// failedChannels is a set that tracks channels we consider `failed`.
// This is a temporary measure until we have implemented real failure
// handling at the link level, to handle the case where we reconnect to
// a peer and try to re-sync a failed channel, triggering a disconnect
// loop.
// TODO(halseth): remove when link failure is properly handled.
failedChannels map[lnwire.ChannelID]struct{}
// writeBuf is a buffer that we'll re-use in order to encode wire
// messages to write out directly on the socket. By re-using this
// buffer, we avoid needing to allocate more memory each time a new
// message is to be sent to a peer.
writeBuf [lnwire.MaxMessagePayload]byte
queueQuit chan struct{}
quit chan struct{}
wg sync.WaitGroup
}
// A compile-time check to ensure that peer satisfies the lnpeer.Peer interface.
var _ lnpeer.Peer = (*peer)(nil)
// newPeer creates a new peer from an establish connection object, and a
// pointer to the main server.
func newPeer(conn net.Conn, connReq *connmgr.ConnReq, server *server,
addr *lnwire.NetAddress, inbound bool,
localFeatures *lnwire.RawFeatureVector) (*peer, error) {
nodePub := addr.IdentityKey
p := &peer{
conn: conn,
addr: addr,
inbound: inbound,
connReq: connReq,
server: server,
localFeatures: localFeatures,
sendQueue: make(chan outgoingMsg),
outgoingQueue: make(chan outgoingMsg),
activeChannels: make(map[lnwire.ChannelID]*lnwallet.LightningChannel),
newChannels: make(chan *newChannelMsg, 1),
activeChanCloses: make(map[lnwire.ChannelID]*channelCloser),
localCloseChanReqs: make(chan *htlcswitch.ChanClose),
linkFailures: make(chan linkFailureReport),
chanCloseMsgs: make(chan *closeMsg),
failedChannels: make(map[lnwire.ChannelID]struct{}),
queueQuit: make(chan struct{}),
quit: make(chan struct{}),
}
copy(p.pubKeyBytes[:], nodePub.SerializeCompressed())
return p, nil
}
// Start starts all helper goroutines the peer needs for normal operations. In
// the case this peer has already been started, then this function is a loop.
func (p *peer) Start() error {
if atomic.AddInt32(&p.started, 1) != 1 {
return nil
}
peerLog.Tracef("Peer %v starting", p)
// Exchange local and global features, the init message should be very
// first between two nodes.
if err := p.sendInitMsg(); err != nil {
return fmt.Errorf("unable to send init msg: %v", err)
}
// Before we launch any of the helper goroutines off the peer struct,
// we'll first ensure proper adherence to the p2p protocol. The init
// message MUST be sent before any other message.
readErr := make(chan error, 1)
msgChan := make(chan lnwire.Message, 1)
p.wg.Add(1)
go func() {
defer p.wg.Done()
msg, err := p.readNextMessage()
if err != nil {
readErr <- err
msgChan <- nil
return
}
readErr <- nil
msgChan <- msg
}()
select {
// In order to avoid blocking indefinitely, we'll give the other peer
// an upper timeout of 15 seconds to respond before we bail out early.
case <-time.After(time.Second * 15):
return fmt.Errorf("peer did not complete handshake within 5 " +
"seconds")
case err := <-readErr:
if err != nil {
return fmt.Errorf("unable to read init msg: %v", err)
}
}
// Once the init message arrives, we can parse it so we can figure out
// the negotiation of features for this session.
msg := <-msgChan
if msg, ok := msg.(*lnwire.Init); ok {
if err := p.handleInitMsg(msg); err != nil {
return err
}
} else {
return errors.New("very first message between nodes " +
"must be init message")
}
// Fetch and then load all the active channels we have with this remote
// peer from the database.
activeChans, err := p.server.chanDB.FetchOpenChannels(p.addr.IdentityKey)
if err != nil {
peerLog.Errorf("unable to fetch active chans "+
"for peer %v: %v", p, err)
return err
}
if len(activeChans) == 0 {
p.server.prunePersistentPeerConnection(p.pubKeyBytes)
}
// Next, load all the active channels we have with this peer,
// registering them with the switch and launching the necessary
// goroutines required to operate them.
peerLog.Debugf("Loaded %v active channels from database with "+
"NodeKey(%x)", len(activeChans), p.PubKey())
if err := p.loadActiveChannels(activeChans); err != nil {
return fmt.Errorf("unable to load channels: %v", err)
}
p.startTime = time.Now()
p.wg.Add(5)
go p.queueHandler()
go p.writeHandler()
go p.readHandler()
go p.channelManager()
go p.pingHandler()
return nil
}
// initGossipSync initializes either a gossip syncer or an initial routing
// dump, depending on the negotiated synchronization method.
func (p *peer) initGossipSync() {
switch {
// If the remote peer knows of the new gossip queries feature, then
// we'll create a new gossipSyncer in the AuthenticatedGossiper for it.
case p.remoteLocalFeatures.HasFeature(lnwire.GossipQueriesOptional):
srvrLog.Infof("Negotiated chan series queries with %x",
p.pubKeyBytes[:])
// We'll only request channel updates from the remote peer if
// its enabled in the config, or we're already getting updates
// from enough peers.
//
// TODO(roasbeef): craft s.t. we only get updates from a few
// peers
recvUpdates := !cfg.NoChanUpdates
// Register the this peer's for gossip syncer with the gossiper.
// This is blocks synchronously to ensure the gossip syncer is
// registered with the gossiper before attempting to read
// messages from the remote peer.
p.server.authGossiper.InitSyncState(p, recvUpdates)
// If the remote peer has the initial sync feature bit set, then we'll
// being the synchronization protocol to exchange authenticated channel
// graph edges/vertexes, but only if they don't know of the new gossip
// queries.
case p.remoteLocalFeatures.HasFeature(lnwire.InitialRoutingSync):
srvrLog.Infof("Requesting full table sync with %x",
p.pubKeyBytes[:])
go p.server.authGossiper.SynchronizeNode(p)
}
}
// QuitSignal is a method that should return a channel which will be sent upon
// or closed once the backing peer exits. This allows callers using the
// interface to cancel any processing in the event the backing implementation
// exits.
//
// NOTE: Part of the lnpeer.Peer interface.
func (p *peer) QuitSignal() <-chan struct{} {
return p.quit
}
// loadActiveChannels creates indexes within the peer for tracking all active
// channels returned by the database.
func (p *peer) loadActiveChannels(chans []*channeldb.OpenChannel) error {
var activePublicChans []wire.OutPoint
for _, dbChan := range chans {
lnChan, err := lnwallet.NewLightningChannel(
p.server.cc.signer, p.server.witnessBeacon, dbChan,
)
if err != nil {
return err
}
chanPoint := &dbChan.FundingOutpoint
chanID := lnwire.NewChanIDFromOutPoint(chanPoint)
peerLog.Infof("NodeKey(%x) loading ChannelPoint(%v)",
p.PubKey(), chanPoint)
// Skip adding any permanently irreconcilable channels to the
// htlcswitch.
if dbChan.ChanStatus() != channeldb.Default {
peerLog.Warnf("ChannelPoint(%v) has status %v, won't "+
"start.", chanPoint, dbChan.ChanStatus())
lnChan.Stop()
continue
}
// Also skip adding any channel marked as `failed` for this
// session.
if _, ok := p.failedChannels[chanID]; ok {
peerLog.Warnf("ChannelPoint(%v) is failed, won't "+
"start.", chanPoint)
lnChan.Stop()
continue
}
_, currentHeight, err := p.server.cc.chainIO.GetBestBlock()
if err != nil {
lnChan.Stop()
return err
}
// Before we register this new link with the HTLC Switch, we'll
// need to fetch its current link-layer forwarding policy from
// the database.
graph := p.server.chanDB.ChannelGraph()
info, p1, p2, err := graph.FetchChannelEdgesByOutpoint(chanPoint)
if err != nil && err != channeldb.ErrEdgeNotFound {
lnChan.Stop()
return err
}
// We'll filter out our policy from the directional channel
// edges based whom the edge connects to. If it doesn't connect
// to us, then we know that we were the one that advertised the
// policy.
//
// TODO(roasbeef): can add helper method to get policy for
// particular channel.
var selfPolicy *channeldb.ChannelEdgePolicy
if info != nil && bytes.Equal(info.NodeKey1Bytes[:],
p.server.identityPriv.PubKey().SerializeCompressed()) {
selfPolicy = p1
} else {
selfPolicy = p2
}
// If we don't yet have an advertised routing policy, then
// we'll use the current default, otherwise we'll translate the
// routing policy into a forwarding policy.
var forwardingPolicy *htlcswitch.ForwardingPolicy
if selfPolicy != nil {
forwardingPolicy = &htlcswitch.ForwardingPolicy{
MinHTLC: selfPolicy.MinHTLC,
BaseFee: selfPolicy.FeeBaseMSat,
FeeRate: selfPolicy.FeeProportionalMillionths,
TimeLockDelta: uint32(selfPolicy.TimeLockDelta),
}
} else {
peerLog.Warnf("Unable to find our forwarding policy "+
"for channel %v, using default values",
chanPoint)
forwardingPolicy = &p.server.cc.routingPolicy
}
peerLog.Tracef("Using link policy of: %v",
spew.Sdump(forwardingPolicy))
// Register this new channel link with the HTLC Switch. This is
// necessary to properly route multi-hop payments, and forward
// new payments triggered by RPC clients.
chainEvents, err := p.server.chainArb.SubscribeChannelEvents(
*chanPoint,
)
if err != nil {
lnChan.Stop()
return err
}
// Create the link and add it to the switch.
err = p.addLink(
chanPoint, lnChan, forwardingPolicy, chainEvents,
currentHeight, true,
)
if err != nil {
lnChan.Stop()
return fmt.Errorf("unable to add link %v to switch: %v",
chanPoint, err)
}
p.activeChanMtx.Lock()
p.activeChannels[chanID] = lnChan
p.activeChanMtx.Unlock()
// To ensure we can route through this channel now that the peer
// is back online, we'll attempt to send an update to enable it.
// This will only be used for non-pending public channels, as
// they are the only ones capable of routing.
chanIsPublic := dbChan.ChannelFlags&lnwire.FFAnnounceChannel != 0
if chanIsPublic && !dbChan.IsPending {
activePublicChans = append(activePublicChans, *chanPoint)
}
}
// As a final measure we launch a goroutine that will ensure the newly
// loaded public channels are not currently disabled, as that will make
// us skip it during path finding.
go func() {
for _, chanPoint := range activePublicChans {
// Set the channel disabled=false by sending out a new
// ChannelUpdate. If this channel is already active,
// the update won't be sent.
err := p.server.announceChanStatus(chanPoint, false)
if err != nil && err != channeldb.ErrEdgeNotFound {
srvrLog.Errorf("Unable to enable channel %v: %v",
chanPoint, err)
}
}
}()
return nil
}
// addLink creates and adds a new link from the specified channel.
func (p *peer) addLink(chanPoint *wire.OutPoint,
lnChan *lnwallet.LightningChannel,
forwardingPolicy *htlcswitch.ForwardingPolicy,
chainEvents *contractcourt.ChainEventSubscription,
currentHeight int32, syncStates bool) error {
// onChannelFailure will be called by the link in case the channel
// fails for some reason.
onChannelFailure := func(chanID lnwire.ChannelID,
shortChanID lnwire.ShortChannelID,
linkErr htlcswitch.LinkFailureError) {
failure := linkFailureReport{
chanPoint: *chanPoint,
chanID: chanID,
shortChanID: shortChanID,
linkErr: linkErr,
}
select {
case p.linkFailures <- failure:
case <-p.quit:
case <-p.server.quit:
}
}
linkCfg := htlcswitch.ChannelLinkConfig{
Peer: p,
DecodeHopIterators: p.server.sphinx.DecodeHopIterators,
ExtractErrorEncrypter: p.server.sphinx.ExtractErrorEncrypter,
FetchLastChannelUpdate: p.server.fetchLastChanUpdate(),
DebugHTLC: cfg.DebugHTLC,
HodlMask: cfg.Hodl.Mask(),
Registry: p.server.invoices,
Switch: p.server.htlcSwitch,
Circuits: p.server.htlcSwitch.CircuitModifier(),
ForwardPackets: p.server.htlcSwitch.ForwardPackets,
FwrdingPolicy: *forwardingPolicy,
FeeEstimator: p.server.cc.feeEstimator,
PreimageCache: p.server.witnessBeacon,
ChainEvents: chainEvents,
UpdateContractSignals: func(signals *contractcourt.ContractSignals) error {
return p.server.chainArb.UpdateContractSignals(
*chanPoint, signals,
)
},
OnChannelFailure: onChannelFailure,
SyncStates: syncStates,
BatchTicker: ticker.New(50 * time.Millisecond),
FwdPkgGCTicker: ticker.New(time.Minute),
BatchSize: 10,
UnsafeReplay: cfg.UnsafeReplay,
MinFeeUpdateTimeout: htlcswitch.DefaultMinLinkFeeUpdateTimeout,
MaxFeeUpdateTimeout: htlcswitch.DefaultMaxLinkFeeUpdateTimeout,
}
link := htlcswitch.NewChannelLink(linkCfg, lnChan)
// Before adding our new link, purge the switch of any pending or live
// links going by the same channel id. If one is found, we'll shut it
// down to ensure that the mailboxes are only ever under the control of
// one link.
p.server.htlcSwitch.RemoveLink(link.ChanID())
// With the channel link created, we'll now notify the htlc switch so
// this channel can be used to dispatch local payments and also
// passively forward payments.
return p.server.htlcSwitch.AddLink(link)
}
// WaitForDisconnect waits until the peer has disconnected. A peer may be
// disconnected if the local or remote side terminating the connection, or an
// irrecoverable protocol error has been encountered. This method will only
// begin watching the peer's waitgroup after the ready channel or the peer's
// quit channel are signaled. The ready channel should only be signaled if a
// call to Start returns no error. Otherwise, if the peer fails to start,
// calling Disconnect will signal the quit channel and the method will not
// block, since no goroutines were spawned.
func (p *peer) WaitForDisconnect(ready chan struct{}) {
select {
case <-ready:
case <-p.quit:
}
p.wg.Wait()
}
// Disconnect terminates the connection with the remote peer. Additionally, a
// signal is sent to the server and htlcSwitch indicating the resources
// allocated to the peer can now be cleaned up.
func (p *peer) Disconnect(reason error) {
if !atomic.CompareAndSwapInt32(&p.disconnect, 0, 1) {
return
}
peerLog.Infof("Disconnecting %s, reason: %v", p, reason)
// Ensure that the TCP connection is properly closed before continuing.
p.conn.Close()
close(p.quit)
}
// String returns the string representation of this peer.
func (p *peer) String() string {
return p.conn.RemoteAddr().String()
}
// readNextMessage reads, and returns the next message on the wire along with
// any additional raw payload.
func (p *peer) readNextMessage() (lnwire.Message, error) {
noiseConn, ok := p.conn.(*brontide.Conn)
if !ok {
return nil, fmt.Errorf("brontide.Conn required to read messages")
}
// First we'll read the next _full_ message. We do this rather than
// reading incrementally from the stream as the Lightning wire protocol
// is message oriented and allows nodes to pad on additional data to
// the message stream.
rawMsg, err := noiseConn.ReadNextMessage()
atomic.AddUint64(&p.bytesReceived, uint64(len(rawMsg)))
if err != nil {
return nil, err
}
// Next, create a new io.Reader implementation from the raw message,
// and use this to decode the message directly from.
msgReader := bytes.NewReader(rawMsg)
nextMsg, err := lnwire.ReadMessage(msgReader, 0)
if err != nil {
return nil, err
}
p.logWireMessage(nextMsg, true)
return nextMsg, nil
}
// msgStream implements a goroutine-safe, in-order stream of messages to be
// delivered via closure to a receiver. These messages MUST be in order due to
// the nature of the lightning channel commitment and gossiper state machines.
// TODO(conner): use stream handler interface to abstract out stream
// state/logging
type msgStream struct {
streamShutdown int32 // To be used atomically.
peer *peer
apply func(lnwire.Message)
startMsg string
stopMsg string
msgCond *sync.Cond
msgs []lnwire.Message
mtx sync.Mutex
bufSize uint32
producerSema chan struct{}
wg sync.WaitGroup
quit chan struct{}
}
// newMsgStream creates a new instance of a chanMsgStream for a particular
// channel identified by its channel ID. bufSize is the max number of messages
// that should be buffered in the internal queue. Callers should set this to a
// sane value that avoids blocking unnecessarily, but doesn't allow an
// unbounded amount of memory to be allocated to buffer incoming messages.
func newMsgStream(p *peer, startMsg, stopMsg string, bufSize uint32,
apply func(lnwire.Message)) *msgStream {
stream := &msgStream{
peer: p,
apply: apply,
startMsg: startMsg,
stopMsg: stopMsg,
producerSema: make(chan struct{}, bufSize),
quit: make(chan struct{}),
}
stream.msgCond = sync.NewCond(&stream.mtx)
// Before we return the active stream, we'll populate the producer's
// semaphore channel. We'll use this to ensure that the producer won't
// attempt to allocate memory in the queue for an item until it has
// sufficient extra space.
for i := uint32(0); i < bufSize; i++ {
stream.producerSema <- struct{}{}
}
return stream
}
// Start starts the chanMsgStream.
func (ms *msgStream) Start() {
ms.wg.Add(1)
go ms.msgConsumer()
}
// Stop stops the chanMsgStream.
func (ms *msgStream) Stop() {
// TODO(roasbeef): signal too?
close(ms.quit)
// Now that we've closed the channel, we'll repeatedly signal the msg
// consumer until we've detected that it has exited.
for atomic.LoadInt32(&ms.streamShutdown) == 0 {
ms.msgCond.Signal()
time.Sleep(time.Millisecond * 100)
}
ms.wg.Wait()
}
// msgConsumer is the main goroutine that streams messages from the peer's
// readHandler directly to the target channel.
func (ms *msgStream) msgConsumer() {
defer ms.wg.Done()
defer peerLog.Tracef(ms.stopMsg)
defer atomic.StoreInt32(&ms.streamShutdown, 1)
peerLog.Tracef(ms.startMsg)
for {
// First, we'll check our condition. If the queue of messages
// is empty, then we'll wait until a new item is added.
ms.msgCond.L.Lock()
for len(ms.msgs) == 0 {
ms.msgCond.Wait()
// If we woke up in order to exit, then we'll do so.
// Otherwise, we'll check the message queue for any new
// items.
select {
case <-ms.peer.quit:
ms.msgCond.L.Unlock()
return
case <-ms.quit:
ms.msgCond.L.Unlock()
return
default:
}
}
// Grab the message off the front of the queue, shifting the
// slice's reference down one in order to remove the message
// from the queue.
msg := ms.msgs[0]
ms.msgs[0] = nil // Set to nil to prevent GC leak.
ms.msgs = ms.msgs[1:]
ms.msgCond.L.Unlock()
ms.apply(msg)
// We've just successfully processed an item, so we'll signal
// to the producer that a new slot in the buffer. We'll use
// this to bound the size of the buffer to avoid allowing it to
// grow indefinitely.
select {
case ms.producerSema <- struct{}{}:
case <-ms.peer.quit:
return
case <-ms.quit:
return
}
}
}
// AddMsg adds a new message to the msgStream. This function is safe for
// concurrent access.
func (ms *msgStream) AddMsg(msg lnwire.Message, quit chan struct{}) {
// First, we'll attempt to receive from the producerSema struct. This
// acts as a sempahore to prevent us from indefinitely buffering
// incoming items from the wire. Either the msg queue isn't full, and
// we'll not block, or the queue is full, and we'll block until either
// we're signalled to quit, or a slot is freed up.
select {
case <-ms.producerSema:
case <-quit:
return
case <-ms.quit:
return
}
// Next, we'll lock the condition, and add the message to the end of
// the message queue.
ms.msgCond.L.Lock()
ms.msgs = append(ms.msgs, msg)
ms.msgCond.L.Unlock()
// With the message added, we signal to the msgConsumer that there are
// additional messages to consume.
ms.msgCond.Signal()
}
// newChanMsgStream is used to create a msgStream between the peer and
// particular channel link in the htlcswitch. We utilize additional
// synchronization with the fundingManager to ensure we don't attempt to
// dispatch a message to a channel before it is fully active. A reference to the
// channel this stream forwards to his held in scope to prevent unnecessary
// lookups.
func newChanMsgStream(p *peer, cid lnwire.ChannelID) *msgStream {
var chanLink htlcswitch.ChannelLink
return newMsgStream(p,
fmt.Sprintf("Update stream for ChannelID(%x) created", cid[:]),
fmt.Sprintf("Update stream for ChannelID(%x) exiting", cid[:]),
1000,
func(msg lnwire.Message) {
_, isChanSycMsg := msg.(*lnwire.ChannelReestablish)
// If this is the chanSync message, then we'll deliver
// it immediately to the active link.
if !isChanSycMsg {
// We'll send a message to the funding manager
// and wait iff an active funding process for
// this channel hasn't yet completed. We do
// this in order to account for the following
// scenario: we send the funding locked message
// to the other side, they immediately send a
// channel update message, but we haven't yet
// sent the channel to the channelManager.
err := p.server.fundingMgr.waitUntilChannelOpen(
cid, p.quit,
)
if err != nil {
// If we have a non-nil error, then the
// funding manager is shutting down, s
// we can exit here without attempting
// to deliver the message.
return
}
}
// In order to avoid unnecessarily delivering message
// as the peer is exiting, we'll check quickly to see
// if we need to exit.
select {
case <-p.quit:
return
default:
}
// Dispatch the commitment update message to the proper
// active goroutine dedicated to this channel.
if chanLink == nil {
link, err := p.server.htlcSwitch.GetLink(cid)
if err != nil {
peerLog.Errorf("recv'd update for unknown "+
"channel %v from %v", cid, p)
return
}
chanLink = link
}
// In order to avoid unnecessarily delivering message
// as the peer is exiting, we'll check quickly to see
// if we need to exit.
select {
case <-p.quit:
return
default:
}
chanLink.HandleChannelUpdate(msg)
},
)
}
// newDiscMsgStream is used to setup a msgStream between the peer and the
// authenticated gossiper. This stream should be used to forward all remote
// channel announcements.
func newDiscMsgStream(p *peer) *msgStream {
return newMsgStream(p,
"Update stream for gossiper created",
"Update stream for gossiper exited",
1000,
func(msg lnwire.Message) {
p.server.authGossiper.ProcessRemoteAnnouncement(msg, p)
},
)
}
// readHandler is responsible for reading messages off the wire in series, then
// properly dispatching the handling of the message to the proper subsystem.
//
// NOTE: This method MUST be run as a goroutine.
func (p *peer) readHandler() {
defer p.wg.Done()
// We'll stop the timer after a new messages is received, and also
// reset it after we process the next message.
idleTimer := time.AfterFunc(idleTimeout, func() {
err := fmt.Errorf("Peer %s no answer for %s -- disconnecting",
p, idleTimeout)
p.Disconnect(err)
})
// Initialize our negotiated gossip sync method before reading
// messages off the wire. When using gossip queries, this ensures
// a gossip syncer is active by the time query messages arrive.
//
// TODO(conner): have peer store gossip syncer directly and bypass
// gossiper?
p.initGossipSync()
discStream := newDiscMsgStream(p)
discStream.Start()
defer discStream.Stop()
chanMsgStreams := make(map[lnwire.ChannelID]*msgStream)
out:
for atomic.LoadInt32(&p.disconnect) == 0 {
nextMsg, err := p.readNextMessage()
idleTimer.Stop()
if err != nil {
peerLog.Infof("unable to read message from %v: %v",
p, err)
switch err.(type) {
// If this is just a message we don't yet recognize,
// we'll continue processing as normal as this allows
// us to introduce new messages in a forwards
// compatible manner.
case *lnwire.UnknownMessage:
idleTimer.Reset(idleTimeout)
continue
// If they sent us an address type that we don't yet
// know of, then this isn't a dire error, so we'll
// simply continue parsing the remainder of their
// messages.
case *lnwire.ErrUnknownAddrType:
idleTimer.Reset(idleTimeout)
continue
// If the error we encountered wasn't just a message we
// didn't recognize, then we'll stop all processing s
// this is a fatal error.
default:
break out
}
}
var (
isChanUpdate bool
targetChan lnwire.ChannelID
)
switch msg := nextMsg.(type) {
case *lnwire.Pong:
// When we receive a Pong message in response to our
// last ping message, we'll use the time in which we
// sent the ping message to measure a rough estimate of
// round trip time.
pingSendTime := atomic.LoadInt64(&p.pingLastSend)
delay := (time.Now().UnixNano() - pingSendTime) / 1000
atomic.StoreInt64(&p.pingTime, delay)
case *lnwire.Ping:
pongBytes := make([]byte, msg.NumPongBytes)
p.queueMsg(lnwire.NewPong(pongBytes), nil)
case *lnwire.OpenChannel:
p.server.fundingMgr.processFundingOpen(msg, p)
case *lnwire.AcceptChannel:
p.server.fundingMgr.processFundingAccept(msg, p)
case *lnwire.FundingCreated:
p.server.fundingMgr.processFundingCreated(msg, p)
case *lnwire.FundingSigned:
p.server.fundingMgr.processFundingSigned(msg, p)
case *lnwire.FundingLocked:
p.server.fundingMgr.processFundingLocked(msg, p)
case *lnwire.Shutdown: