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connection.go
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connection.go
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package quic
import (
"bytes"
"context"
"crypto/tls"
"errors"
"fmt"
"io"
"net"
"reflect"
"sync"
"sync/atomic"
"time"
"github.com/xtls/quic-go/internal/ackhandler"
"github.com/xtls/quic-go/internal/flowcontrol"
"github.com/xtls/quic-go/internal/handshake"
"github.com/xtls/quic-go/internal/protocol"
"github.com/xtls/quic-go/internal/qerr"
"github.com/xtls/quic-go/internal/utils"
"github.com/xtls/quic-go/internal/wire"
"github.com/xtls/quic-go/logging"
)
type unpacker interface {
UnpackLongHeader(hdr *wire.Header, data []byte) (*unpackedPacket, error)
UnpackShortHeader(rcvTime time.Time, data []byte) (protocol.PacketNumber, protocol.PacketNumberLen, protocol.KeyPhaseBit, []byte, error)
}
type streamManager interface {
GetOrOpenSendStream(protocol.StreamID) (sendStreamI, error)
GetOrOpenReceiveStream(protocol.StreamID) (receiveStreamI, error)
OpenStream() (Stream, error)
OpenUniStream() (SendStream, error)
OpenStreamSync(context.Context) (Stream, error)
OpenUniStreamSync(context.Context) (SendStream, error)
AcceptStream(context.Context) (Stream, error)
AcceptUniStream(context.Context) (ReceiveStream, error)
DeleteStream(protocol.StreamID) error
UpdateLimits(*wire.TransportParameters)
HandleMaxStreamsFrame(*wire.MaxStreamsFrame)
CloseWithError(error)
ResetFor0RTT()
UseResetMaps()
}
type cryptoStreamHandler interface {
StartHandshake(context.Context) error
ChangeConnectionID(protocol.ConnectionID)
SetLargest1RTTAcked(protocol.PacketNumber) error
SetHandshakeConfirmed()
GetSessionTicket() ([]byte, error)
NextEvent() handshake.Event
DiscardInitialKeys()
HandleMessage([]byte, protocol.EncryptionLevel) error
io.Closer
ConnectionState() handshake.ConnectionState
}
type receivedPacket struct {
buffer *packetBuffer
remoteAddr net.Addr
rcvTime time.Time
data []byte
ecn protocol.ECN
info packetInfo // only valid if the contained IP address is valid
}
func (p *receivedPacket) Size() protocol.ByteCount { return protocol.ByteCount(len(p.data)) }
func (p *receivedPacket) Clone() *receivedPacket {
return &receivedPacket{
remoteAddr: p.remoteAddr,
rcvTime: p.rcvTime,
data: p.data,
buffer: p.buffer,
ecn: p.ecn,
info: p.info,
}
}
type connRunner interface {
Add(protocol.ConnectionID, packetHandler) bool
GetStatelessResetToken(protocol.ConnectionID) protocol.StatelessResetToken
Retire(protocol.ConnectionID)
Remove(protocol.ConnectionID)
ReplaceWithClosed([]protocol.ConnectionID, []byte)
AddResetToken(protocol.StatelessResetToken, packetHandler)
RemoveResetToken(protocol.StatelessResetToken)
}
type closeError struct {
err error
remote bool
immediate bool
}
type errCloseForRecreating struct {
nextPacketNumber protocol.PacketNumber
nextVersion protocol.Version
}
func (e *errCloseForRecreating) Error() string {
return "closing connection in order to recreate it"
}
var connTracingID atomic.Uint64 // to be accessed atomically
func nextConnTracingID() ConnectionTracingID { return ConnectionTracingID(connTracingID.Add(1)) }
// A Connection is a QUIC connection
type connection struct {
// Destination connection ID used during the handshake.
// Used to check source connection ID on incoming packets.
handshakeDestConnID protocol.ConnectionID
// Set for the client. Destination connection ID used on the first Initial sent.
origDestConnID protocol.ConnectionID
retrySrcConnID *protocol.ConnectionID // only set for the client (and if a Retry was performed)
srcConnIDLen int
perspective protocol.Perspective
version protocol.Version
config *Config
conn sendConn
sendQueue sender
streamsMap streamManager
connIDManager *connIDManager
connIDGenerator *connIDGenerator
rttStats *utils.RTTStats
cryptoStreamManager *cryptoStreamManager
sentPacketHandler ackhandler.SentPacketHandler
receivedPacketHandler ackhandler.ReceivedPacketHandler
retransmissionQueue *retransmissionQueue
framer *framer
connFlowController flowcontrol.ConnectionFlowController
tokenStoreKey string // only set for the client
tokenGenerator *handshake.TokenGenerator // only set for the server
unpacker unpacker
frameParser wire.FrameParser
packer packer
mtuDiscoverer mtuDiscoverer // initialized when the transport parameters are received
maxPayloadSizeEstimate atomic.Uint32
initialStream *cryptoStream
handshakeStream *cryptoStream
oneRTTStream *cryptoStream // only set for the server
cryptoStreamHandler cryptoStreamHandler
receivedPackets chan receivedPacket
sendingScheduled chan struct{}
closeOnce sync.Once
// closeChan is used to notify the run loop that it should terminate
closeChan chan closeError
ctx context.Context
ctxCancel context.CancelCauseFunc
handshakeCompleteChan chan struct{}
undecryptablePackets []receivedPacket // undecryptable packets, waiting for a change in encryption level
undecryptablePacketsToProcess []receivedPacket
earlyConnReadyChan chan struct{}
sentFirstPacket bool
droppedInitialKeys bool
handshakeComplete bool
handshakeConfirmed bool
receivedRetry bool
versionNegotiated bool
receivedFirstPacket bool
// the minimum of the max_idle_timeout values advertised by both endpoints
idleTimeout time.Duration
creationTime time.Time
// The idle timeout is set based on the max of the time we received the last packet...
lastPacketReceivedTime time.Time
// ... and the time we sent a new ack-eliciting packet after receiving a packet.
firstAckElicitingPacketAfterIdleSentTime time.Time
// pacingDeadline is the time when the next packet should be sent
pacingDeadline time.Time
peerParams *wire.TransportParameters
timer connectionTimer
// keepAlivePingSent stores whether a keep alive PING is in flight.
// It is reset as soon as we receive a packet from the peer.
keepAlivePingSent bool
keepAliveInterval time.Duration
datagramQueue *datagramQueue
connStateMutex sync.Mutex
connState ConnectionState
logID string
tracer *logging.ConnectionTracer
logger utils.Logger
}
var (
_ Connection = &connection{}
_ EarlyConnection = &connection{}
_ streamSender = &connection{}
)
var newConnection = func(
ctx context.Context,
ctxCancel context.CancelCauseFunc,
conn sendConn,
runner connRunner,
origDestConnID protocol.ConnectionID,
retrySrcConnID *protocol.ConnectionID,
clientDestConnID protocol.ConnectionID,
destConnID protocol.ConnectionID,
srcConnID protocol.ConnectionID,
connIDGenerator ConnectionIDGenerator,
statelessResetToken protocol.StatelessResetToken,
conf *Config,
tlsConf *tls.Config,
tokenGenerator *handshake.TokenGenerator,
clientAddressValidated bool,
tracer *logging.ConnectionTracer,
logger utils.Logger,
v protocol.Version,
) quicConn {
s := &connection{
ctx: ctx,
ctxCancel: ctxCancel,
conn: conn,
config: conf,
handshakeDestConnID: destConnID,
srcConnIDLen: srcConnID.Len(),
tokenGenerator: tokenGenerator,
oneRTTStream: newCryptoStream(),
perspective: protocol.PerspectiveServer,
tracer: tracer,
logger: logger,
version: v,
}
if origDestConnID.Len() > 0 {
s.logID = origDestConnID.String()
} else {
s.logID = destConnID.String()
}
s.connIDManager = newConnIDManager(
destConnID,
func(token protocol.StatelessResetToken) { runner.AddResetToken(token, s) },
runner.RemoveResetToken,
s.queueControlFrame,
)
s.connIDGenerator = newConnIDGenerator(
srcConnID,
&clientDestConnID,
func(connID protocol.ConnectionID) { runner.Add(connID, s) },
runner.GetStatelessResetToken,
runner.Remove,
runner.Retire,
runner.ReplaceWithClosed,
s.queueControlFrame,
connIDGenerator,
)
s.preSetup()
s.sentPacketHandler, s.receivedPacketHandler = ackhandler.NewAckHandler(
0,
protocol.ByteCount(s.config.InitialPacketSize),
s.rttStats,
clientAddressValidated,
s.conn.capabilities().ECN,
s.perspective,
s.tracer,
s.logger,
)
s.maxPayloadSizeEstimate.Store(uint32(estimateMaxPayloadSize(protocol.ByteCount(s.config.InitialPacketSize))))
params := &wire.TransportParameters{
InitialMaxStreamDataBidiLocal: protocol.ByteCount(s.config.InitialStreamReceiveWindow),
InitialMaxStreamDataBidiRemote: protocol.ByteCount(s.config.InitialStreamReceiveWindow),
InitialMaxStreamDataUni: protocol.ByteCount(s.config.InitialStreamReceiveWindow),
InitialMaxData: protocol.ByteCount(s.config.InitialConnectionReceiveWindow),
MaxIdleTimeout: s.config.MaxIdleTimeout,
MaxBidiStreamNum: protocol.StreamNum(s.config.MaxIncomingStreams),
MaxUniStreamNum: protocol.StreamNum(s.config.MaxIncomingUniStreams),
MaxAckDelay: protocol.MaxAckDelayInclGranularity,
AckDelayExponent: protocol.AckDelayExponent,
MaxUDPPayloadSize: protocol.MaxPacketBufferSize,
DisableActiveMigration: true,
StatelessResetToken: &statelessResetToken,
OriginalDestinationConnectionID: origDestConnID,
// For interoperability with quic-go versions before May 2023, this value must be set to a value
// different from protocol.DefaultActiveConnectionIDLimit.
// If set to the default value, it will be omitted from the transport parameters, which will make
// old quic-go versions interpret it as 0, instead of the default value of 2.
// See https://github.com/quic-go/quic-go/pull/3806.
ActiveConnectionIDLimit: protocol.MaxActiveConnectionIDs,
InitialSourceConnectionID: srcConnID,
RetrySourceConnectionID: retrySrcConnID,
}
if s.config.EnableDatagrams {
params.MaxDatagramFrameSize = wire.MaxDatagramSize
} else {
params.MaxDatagramFrameSize = protocol.InvalidByteCount
}
if s.tracer != nil && s.tracer.SentTransportParameters != nil {
s.tracer.SentTransportParameters(params)
}
cs := handshake.NewCryptoSetupServer(
clientDestConnID,
conn.LocalAddr(),
conn.RemoteAddr(),
params,
tlsConf,
conf.Allow0RTT,
s.rttStats,
tracer,
logger,
s.version,
)
s.cryptoStreamHandler = cs
s.packer = newPacketPacker(srcConnID, s.connIDManager.Get, s.initialStream, s.handshakeStream, s.sentPacketHandler, s.retransmissionQueue, cs, s.framer, s.receivedPacketHandler, s.datagramQueue, s.perspective)
s.unpacker = newPacketUnpacker(cs, s.srcConnIDLen)
s.cryptoStreamManager = newCryptoStreamManager(s.initialStream, s.handshakeStream, s.oneRTTStream)
return s
}
// declare this as a variable, such that we can it mock it in the tests
var newClientConnection = func(
ctx context.Context,
conn sendConn,
runner connRunner,
destConnID protocol.ConnectionID,
srcConnID protocol.ConnectionID,
connIDGenerator ConnectionIDGenerator,
conf *Config,
tlsConf *tls.Config,
initialPacketNumber protocol.PacketNumber,
enable0RTT bool,
hasNegotiatedVersion bool,
tracer *logging.ConnectionTracer,
logger utils.Logger,
v protocol.Version,
) quicConn {
s := &connection{
conn: conn,
config: conf,
origDestConnID: destConnID,
handshakeDestConnID: destConnID,
srcConnIDLen: srcConnID.Len(),
perspective: protocol.PerspectiveClient,
logID: destConnID.String(),
logger: logger,
tracer: tracer,
versionNegotiated: hasNegotiatedVersion,
version: v,
}
s.connIDManager = newConnIDManager(
destConnID,
func(token protocol.StatelessResetToken) { runner.AddResetToken(token, s) },
runner.RemoveResetToken,
s.queueControlFrame,
)
s.connIDGenerator = newConnIDGenerator(
srcConnID,
nil,
func(connID protocol.ConnectionID) { runner.Add(connID, s) },
runner.GetStatelessResetToken,
runner.Remove,
runner.Retire,
runner.ReplaceWithClosed,
s.queueControlFrame,
connIDGenerator,
)
s.ctx, s.ctxCancel = context.WithCancelCause(ctx)
s.preSetup()
s.sentPacketHandler, s.receivedPacketHandler = ackhandler.NewAckHandler(
initialPacketNumber,
protocol.ByteCount(s.config.InitialPacketSize),
s.rttStats,
false, // has no effect
s.conn.capabilities().ECN,
s.perspective,
s.tracer,
s.logger,
)
s.maxPayloadSizeEstimate.Store(uint32(estimateMaxPayloadSize(protocol.ByteCount(s.config.InitialPacketSize))))
oneRTTStream := newCryptoStream()
params := &wire.TransportParameters{
InitialMaxStreamDataBidiRemote: protocol.ByteCount(s.config.InitialStreamReceiveWindow),
InitialMaxStreamDataBidiLocal: protocol.ByteCount(s.config.InitialStreamReceiveWindow),
InitialMaxStreamDataUni: protocol.ByteCount(s.config.InitialStreamReceiveWindow),
InitialMaxData: protocol.ByteCount(s.config.InitialConnectionReceiveWindow),
MaxIdleTimeout: s.config.MaxIdleTimeout,
MaxBidiStreamNum: protocol.StreamNum(s.config.MaxIncomingStreams),
MaxUniStreamNum: protocol.StreamNum(s.config.MaxIncomingUniStreams),
MaxAckDelay: protocol.MaxAckDelayInclGranularity,
MaxUDPPayloadSize: protocol.MaxPacketBufferSize,
AckDelayExponent: protocol.AckDelayExponent,
DisableActiveMigration: true,
// For interoperability with quic-go versions before May 2023, this value must be set to a value
// different from protocol.DefaultActiveConnectionIDLimit.
// If set to the default value, it will be omitted from the transport parameters, which will make
// old quic-go versions interpret it as 0, instead of the default value of 2.
// See https://github.com/quic-go/quic-go/pull/3806.
ActiveConnectionIDLimit: protocol.MaxActiveConnectionIDs,
InitialSourceConnectionID: srcConnID,
}
if s.config.EnableDatagrams {
params.MaxDatagramFrameSize = wire.MaxDatagramSize
} else {
params.MaxDatagramFrameSize = protocol.InvalidByteCount
}
if s.tracer != nil && s.tracer.SentTransportParameters != nil {
s.tracer.SentTransportParameters(params)
}
cs := handshake.NewCryptoSetupClient(
destConnID,
params,
tlsConf,
enable0RTT,
s.rttStats,
tracer,
logger,
s.version,
)
s.cryptoStreamHandler = cs
s.cryptoStreamManager = newCryptoStreamManager(s.initialStream, s.handshakeStream, oneRTTStream)
s.unpacker = newPacketUnpacker(cs, s.srcConnIDLen)
s.packer = newPacketPacker(srcConnID, s.connIDManager.Get, s.initialStream, s.handshakeStream, s.sentPacketHandler, s.retransmissionQueue, cs, s.framer, s.receivedPacketHandler, s.datagramQueue, s.perspective)
if len(tlsConf.ServerName) > 0 {
s.tokenStoreKey = tlsConf.ServerName
} else {
s.tokenStoreKey = conn.RemoteAddr().String()
}
if s.config.TokenStore != nil {
if token := s.config.TokenStore.Pop(s.tokenStoreKey); token != nil {
s.packer.SetToken(token.data)
}
}
return s
}
func (s *connection) preSetup() {
s.initialStream = newCryptoStream()
s.handshakeStream = newCryptoStream()
s.sendQueue = newSendQueue(s.conn)
s.retransmissionQueue = newRetransmissionQueue()
s.frameParser = *wire.NewFrameParser(s.config.EnableDatagrams)
s.rttStats = &utils.RTTStats{}
s.connFlowController = flowcontrol.NewConnectionFlowController(
protocol.ByteCount(s.config.InitialConnectionReceiveWindow),
protocol.ByteCount(s.config.MaxConnectionReceiveWindow),
func(size protocol.ByteCount) bool {
if s.config.AllowConnectionWindowIncrease == nil {
return true
}
return s.config.AllowConnectionWindowIncrease(s, uint64(size))
},
s.rttStats,
s.logger,
)
s.earlyConnReadyChan = make(chan struct{})
s.streamsMap = newStreamsMap(
s.ctx,
s,
s.queueControlFrame,
s.newFlowController,
uint64(s.config.MaxIncomingStreams),
uint64(s.config.MaxIncomingUniStreams),
s.perspective,
)
s.framer = newFramer()
s.receivedPackets = make(chan receivedPacket, protocol.MaxConnUnprocessedPackets)
s.closeChan = make(chan closeError, 1)
s.sendingScheduled = make(chan struct{}, 1)
s.handshakeCompleteChan = make(chan struct{})
now := time.Now()
s.lastPacketReceivedTime = now
s.creationTime = now
s.datagramQueue = newDatagramQueue(s.scheduleSending, s.logger)
s.connState.Version = s.version
}
// run the connection main loop
func (s *connection) run() error {
var closeErr closeError
defer func() { s.ctxCancel(closeErr.err) }()
s.timer = *newTimer()
if err := s.cryptoStreamHandler.StartHandshake(s.ctx); err != nil {
return err
}
if err := s.handleHandshakeEvents(); err != nil {
return err
}
go func() {
if err := s.sendQueue.Run(); err != nil {
s.destroyImpl(err)
}
}()
if s.perspective == protocol.PerspectiveClient {
s.scheduleSending() // so the ClientHello actually gets sent
}
var sendQueueAvailable <-chan struct{}
runLoop:
for {
if s.framer.QueuedTooManyControlFrames() {
s.closeLocal(&qerr.TransportError{ErrorCode: InternalError})
}
// Close immediately if requested
select {
case closeErr = <-s.closeChan:
break runLoop
default:
}
s.maybeResetTimer()
var processedUndecryptablePacket bool
if len(s.undecryptablePacketsToProcess) > 0 {
queue := s.undecryptablePacketsToProcess
s.undecryptablePacketsToProcess = nil
for _, p := range queue {
if processed := s.handlePacketImpl(p); processed {
processedUndecryptablePacket = true
}
// Don't set timers and send packets if the packet made us close the connection.
select {
case closeErr = <-s.closeChan:
break runLoop
default:
}
}
}
// If we processed any undecryptable packets, jump to the resetting of the timers directly.
if !processedUndecryptablePacket {
select {
case closeErr = <-s.closeChan:
break runLoop
case <-s.timer.Chan():
s.timer.SetRead()
// We do all the interesting stuff after the switch statement, so
// nothing to see here.
case <-s.sendingScheduled:
// We do all the interesting stuff after the switch statement, so
// nothing to see here.
case <-sendQueueAvailable:
case firstPacket := <-s.receivedPackets:
wasProcessed := s.handlePacketImpl(firstPacket)
// Don't set timers and send packets if the packet made us close the connection.
select {
case closeErr = <-s.closeChan:
break runLoop
default:
}
if s.handshakeComplete {
// Now process all packets in the receivedPackets channel.
// Limit the number of packets to the length of the receivedPackets channel,
// so we eventually get a chance to send out an ACK when receiving a lot of packets.
numPackets := len(s.receivedPackets)
receiveLoop:
for i := 0; i < numPackets; i++ {
select {
case p := <-s.receivedPackets:
if processed := s.handlePacketImpl(p); processed {
wasProcessed = true
}
select {
case closeErr = <-s.closeChan:
break runLoop
default:
}
default:
break receiveLoop
}
}
}
// Only reset the timers if this packet was actually processed.
// This avoids modifying any state when handling undecryptable packets,
// which could be injected by an attacker.
if !wasProcessed {
continue
}
}
}
now := time.Now()
if timeout := s.sentPacketHandler.GetLossDetectionTimeout(); !timeout.IsZero() && timeout.Before(now) {
// This could cause packets to be retransmitted.
// Check it before trying to send packets.
if err := s.sentPacketHandler.OnLossDetectionTimeout(); err != nil {
s.closeLocal(err)
}
}
if keepAliveTime := s.nextKeepAliveTime(); !keepAliveTime.IsZero() && !now.Before(keepAliveTime) {
// send a PING frame since there is no activity in the connection
s.logger.Debugf("Sending a keep-alive PING to keep the connection alive.")
s.framer.QueueControlFrame(&wire.PingFrame{})
s.keepAlivePingSent = true
} else if !s.handshakeComplete && now.Sub(s.creationTime) >= s.config.handshakeTimeout() {
s.destroyImpl(qerr.ErrHandshakeTimeout)
continue
} else {
idleTimeoutStartTime := s.idleTimeoutStartTime()
if (!s.handshakeComplete && now.Sub(idleTimeoutStartTime) >= s.config.HandshakeIdleTimeout) ||
(s.handshakeComplete && now.After(s.nextIdleTimeoutTime())) {
s.destroyImpl(qerr.ErrIdleTimeout)
continue
}
}
if s.sendQueue.WouldBlock() {
// The send queue is still busy sending out packets.
// Wait until there's space to enqueue new packets.
sendQueueAvailable = s.sendQueue.Available()
continue
}
if err := s.triggerSending(now); err != nil {
s.closeLocal(err)
}
if s.sendQueue.WouldBlock() {
sendQueueAvailable = s.sendQueue.Available()
} else {
sendQueueAvailable = nil
}
}
s.cryptoStreamHandler.Close()
s.sendQueue.Close() // close the send queue before sending the CONNECTION_CLOSE
s.handleCloseError(&closeErr)
if s.tracer != nil && s.tracer.Close != nil {
if e := (&errCloseForRecreating{}); !errors.As(closeErr.err, &e) {
s.tracer.Close()
}
}
s.logger.Infof("Connection %s closed.", s.logID)
s.timer.Stop()
return closeErr.err
}
// blocks until the early connection can be used
func (s *connection) earlyConnReady() <-chan struct{} {
return s.earlyConnReadyChan
}
func (s *connection) HandshakeComplete() <-chan struct{} {
return s.handshakeCompleteChan
}
func (s *connection) Context() context.Context {
return s.ctx
}
func (s *connection) supportsDatagrams() bool {
return s.peerParams.MaxDatagramFrameSize > 0
}
func (s *connection) ConnectionState() ConnectionState {
s.connStateMutex.Lock()
defer s.connStateMutex.Unlock()
cs := s.cryptoStreamHandler.ConnectionState()
s.connState.TLS = cs.ConnectionState
s.connState.Used0RTT = cs.Used0RTT
s.connState.GSO = s.conn.capabilities().GSO
return s.connState
}
// Time when the connection should time out
func (s *connection) nextIdleTimeoutTime() time.Time {
idleTimeout := max(s.idleTimeout, s.rttStats.PTO(true)*3)
return s.idleTimeoutStartTime().Add(idleTimeout)
}
// Time when the next keep-alive packet should be sent.
// It returns a zero time if no keep-alive should be sent.
func (s *connection) nextKeepAliveTime() time.Time {
if s.config.KeepAlivePeriod == 0 || s.keepAlivePingSent || !s.firstAckElicitingPacketAfterIdleSentTime.IsZero() {
return time.Time{}
}
keepAliveInterval := max(s.keepAliveInterval, s.rttStats.PTO(true)*3/2)
return s.lastPacketReceivedTime.Add(keepAliveInterval)
}
func (s *connection) maybeResetTimer() {
var deadline time.Time
if !s.handshakeComplete {
deadline = s.creationTime.Add(s.config.handshakeTimeout())
if t := s.idleTimeoutStartTime().Add(s.config.HandshakeIdleTimeout); t.Before(deadline) {
deadline = t
}
} else {
if keepAliveTime := s.nextKeepAliveTime(); !keepAliveTime.IsZero() {
deadline = keepAliveTime
} else {
deadline = s.nextIdleTimeoutTime()
}
}
s.timer.SetTimer(
deadline,
s.receivedPacketHandler.GetAlarmTimeout(),
s.sentPacketHandler.GetLossDetectionTimeout(),
s.pacingDeadline,
)
}
func (s *connection) idleTimeoutStartTime() time.Time {
startTime := s.lastPacketReceivedTime
if t := s.firstAckElicitingPacketAfterIdleSentTime; t.After(startTime) {
startTime = t
}
return startTime
}
func (s *connection) handleHandshakeComplete() error {
defer close(s.handshakeCompleteChan)
// Once the handshake completes, we have derived 1-RTT keys.
// There's no point in queueing undecryptable packets for later decryption anymore.
s.undecryptablePackets = nil
s.connIDManager.SetHandshakeComplete()
s.connIDGenerator.SetHandshakeComplete()
if s.tracer != nil && s.tracer.ChoseALPN != nil {
s.tracer.ChoseALPN(s.cryptoStreamHandler.ConnectionState().NegotiatedProtocol)
}
// The server applies transport parameters right away, but the client side has to wait for handshake completion.
// During a 0-RTT connection, the client is only allowed to use the new transport parameters for 1-RTT packets.
if s.perspective == protocol.PerspectiveClient {
s.applyTransportParameters()
return nil
}
// All these only apply to the server side.
if err := s.handleHandshakeConfirmed(); err != nil {
return err
}
ticket, err := s.cryptoStreamHandler.GetSessionTicket()
if err != nil {
return err
}
if ticket != nil { // may be nil if session tickets are disabled via tls.Config.SessionTicketsDisabled
s.oneRTTStream.Write(ticket)
for s.oneRTTStream.HasData() {
s.queueControlFrame(s.oneRTTStream.PopCryptoFrame(protocol.MaxPostHandshakeCryptoFrameSize))
}
}
token, err := s.tokenGenerator.NewToken(s.conn.RemoteAddr())
if err != nil {
return err
}
s.queueControlFrame(&wire.NewTokenFrame{Token: token})
s.queueControlFrame(&wire.HandshakeDoneFrame{})
return nil
}
func (s *connection) handleHandshakeConfirmed() error {
if err := s.dropEncryptionLevel(protocol.EncryptionHandshake); err != nil {
return err
}
s.handshakeConfirmed = true
s.sentPacketHandler.SetHandshakeConfirmed()
s.cryptoStreamHandler.SetHandshakeConfirmed()
if !s.config.DisablePathMTUDiscovery && s.conn.capabilities().DF {
s.mtuDiscoverer.Start()
}
return nil
}
func (s *connection) handlePacketImpl(rp receivedPacket) bool {
s.sentPacketHandler.ReceivedBytes(rp.Size())
if wire.IsVersionNegotiationPacket(rp.data) {
s.handleVersionNegotiationPacket(rp)
return false
}
var counter uint8
var lastConnID protocol.ConnectionID
var processed bool
data := rp.data
p := rp
for len(data) > 0 {
if counter > 0 {
p = *(p.Clone())
p.data = data
destConnID, err := wire.ParseConnectionID(p.data, s.srcConnIDLen)
if err != nil {
if s.tracer != nil && s.tracer.DroppedPacket != nil {
s.tracer.DroppedPacket(logging.PacketTypeNotDetermined, protocol.InvalidPacketNumber, protocol.ByteCount(len(data)), logging.PacketDropHeaderParseError)
}
s.logger.Debugf("error parsing packet, couldn't parse connection ID: %s", err)
break
}
if destConnID != lastConnID {
if s.tracer != nil && s.tracer.DroppedPacket != nil {
s.tracer.DroppedPacket(logging.PacketTypeNotDetermined, protocol.InvalidPacketNumber, protocol.ByteCount(len(data)), logging.PacketDropUnknownConnectionID)
}
s.logger.Debugf("coalesced packet has different destination connection ID: %s, expected %s", destConnID, lastConnID)
break
}
}
if wire.IsLongHeaderPacket(p.data[0]) {
hdr, packetData, rest, err := wire.ParsePacket(p.data)
if err != nil {
if s.tracer != nil && s.tracer.DroppedPacket != nil {
dropReason := logging.PacketDropHeaderParseError
if err == wire.ErrUnsupportedVersion {
dropReason = logging.PacketDropUnsupportedVersion
}
s.tracer.DroppedPacket(logging.PacketTypeNotDetermined, protocol.InvalidPacketNumber, protocol.ByteCount(len(data)), dropReason)
}
s.logger.Debugf("error parsing packet: %s", err)
break
}
lastConnID = hdr.DestConnectionID
if hdr.Version != s.version {
if s.tracer != nil && s.tracer.DroppedPacket != nil {
s.tracer.DroppedPacket(logging.PacketTypeFromHeader(hdr), protocol.InvalidPacketNumber, protocol.ByteCount(len(data)), logging.PacketDropUnexpectedVersion)
}
s.logger.Debugf("Dropping packet with version %x. Expected %x.", hdr.Version, s.version)
break
}
if counter > 0 {
p.buffer.Split()
}
counter++
// only log if this actually a coalesced packet
if s.logger.Debug() && (counter > 1 || len(rest) > 0) {
s.logger.Debugf("Parsed a coalesced packet. Part %d: %d bytes. Remaining: %d bytes.", counter, len(packetData), len(rest))
}
p.data = packetData
if wasProcessed := s.handleLongHeaderPacket(p, hdr); wasProcessed {
processed = true
}
data = rest
} else {
if counter > 0 {
p.buffer.Split()
}
processed = s.handleShortHeaderPacket(p)
break
}
}
p.buffer.MaybeRelease()
return processed
}
func (s *connection) handleShortHeaderPacket(p receivedPacket) bool {
var wasQueued bool
defer func() {
// Put back the packet buffer if the packet wasn't queued for later decryption.
if !wasQueued {
p.buffer.Decrement()
}
}()
destConnID, err := wire.ParseConnectionID(p.data, s.srcConnIDLen)
if err != nil {
s.tracer.DroppedPacket(logging.PacketType1RTT, protocol.InvalidPacketNumber, protocol.ByteCount(len(p.data)), logging.PacketDropHeaderParseError)
return false
}
pn, pnLen, keyPhase, data, err := s.unpacker.UnpackShortHeader(p.rcvTime, p.data)
if err != nil {
wasQueued = s.handleUnpackError(err, p, logging.PacketType1RTT)
return false
}
if s.logger.Debug() {
s.logger.Debugf("<- Reading packet %d (%d bytes) for connection %s, 1-RTT", pn, p.Size(), destConnID)
wire.LogShortHeader(s.logger, destConnID, pn, pnLen, keyPhase)
}
if s.receivedPacketHandler.IsPotentiallyDuplicate(pn, protocol.Encryption1RTT) {
s.logger.Debugf("Dropping (potentially) duplicate packet.")
if s.tracer != nil && s.tracer.DroppedPacket != nil {
s.tracer.DroppedPacket(logging.PacketType1RTT, pn, p.Size(), logging.PacketDropDuplicate)
}
return false
}
var log func([]logging.Frame)
if s.tracer != nil && s.tracer.ReceivedShortHeaderPacket != nil {
log = func(frames []logging.Frame) {
s.tracer.ReceivedShortHeaderPacket(
&logging.ShortHeader{
DestConnectionID: destConnID,
PacketNumber: pn,
PacketNumberLen: pnLen,
KeyPhase: keyPhase,
},
p.Size(),
p.ecn,
frames,
)
}
}
if err := s.handleUnpackedShortHeaderPacket(destConnID, pn, data, p.ecn, p.rcvTime, log); err != nil {
s.closeLocal(err)
return false
}
return true
}
func (s *connection) handleLongHeaderPacket(p receivedPacket, hdr *wire.Header) bool /* was the packet successfully processed */ {
var wasQueued bool
defer func() {
// Put back the packet buffer if the packet wasn't queued for later decryption.
if !wasQueued {
p.buffer.Decrement()
}
}()
if hdr.Type == protocol.PacketTypeRetry {
return s.handleRetryPacket(hdr, p.data, p.rcvTime)
}
// The server can change the source connection ID with the first Handshake packet.
// After this, all packets with a different source connection have to be ignored.
if s.receivedFirstPacket && hdr.Type == protocol.PacketTypeInitial && hdr.SrcConnectionID != s.handshakeDestConnID {
if s.tracer != nil && s.tracer.DroppedPacket != nil {
s.tracer.DroppedPacket(logging.PacketTypeInitial, protocol.InvalidPacketNumber, p.Size(), logging.PacketDropUnknownConnectionID)
}
s.logger.Debugf("Dropping Initial packet (%d bytes) with unexpected source connection ID: %s (expected %s)", p.Size(), hdr.SrcConnectionID, s.handshakeDestConnID)
return false
}
// drop 0-RTT packets, if we are a client
if s.perspective == protocol.PerspectiveClient && hdr.Type == protocol.PacketType0RTT {
if s.tracer != nil && s.tracer.DroppedPacket != nil {
s.tracer.DroppedPacket(logging.PacketType0RTT, protocol.InvalidPacketNumber, p.Size(), logging.PacketDropKeyUnavailable)
}
return false
}
packet, err := s.unpacker.UnpackLongHeader(hdr, p.data)
if err != nil {
wasQueued = s.handleUnpackError(err, p, logging.PacketTypeFromHeader(hdr))
return false
}
if s.logger.Debug() {
s.logger.Debugf("<- Reading packet %d (%d bytes) for connection %s, %s", packet.hdr.PacketNumber, p.Size(), hdr.DestConnectionID, packet.encryptionLevel)
packet.hdr.Log(s.logger)
}
if pn := packet.hdr.PacketNumber; s.receivedPacketHandler.IsPotentiallyDuplicate(pn, packet.encryptionLevel) {
s.logger.Debugf("Dropping (potentially) duplicate packet.")
if s.tracer != nil && s.tracer.DroppedPacket != nil {
s.tracer.DroppedPacket(logging.PacketTypeFromHeader(hdr), pn, p.Size(), logging.PacketDropDuplicate)
}
return false
}
if err := s.handleUnpackedLongHeaderPacket(packet, p.ecn, p.rcvTime, p.Size()); err != nil {
s.closeLocal(err)
return false
}
return true
}
func (s *connection) handleUnpackError(err error, p receivedPacket, pt logging.PacketType) (wasQueued bool) {
switch err {
case handshake.ErrKeysDropped:
if s.tracer != nil && s.tracer.DroppedPacket != nil {
s.tracer.DroppedPacket(pt, protocol.InvalidPacketNumber, p.Size(), logging.PacketDropKeyUnavailable)
}
s.logger.Debugf("Dropping %s packet (%d bytes) because we already dropped the keys.", pt, p.Size())
case handshake.ErrKeysNotYetAvailable:
// Sealer for this encryption level not yet available.
// Try again later.
s.tryQueueingUndecryptablePacket(p, pt)