cloudflared-mirror/vendor/github.com/lucas-clemente/quic-go/server.go

670 lines
20 KiB
Go

package quic
import (
"bytes"
"context"
"crypto/rand"
"crypto/tls"
"errors"
"fmt"
"net"
"sync"
"sync/atomic"
"time"
"github.com/lucas-clemente/quic-go/internal/handshake"
"github.com/lucas-clemente/quic-go/internal/protocol"
"github.com/lucas-clemente/quic-go/internal/qerr"
"github.com/lucas-clemente/quic-go/internal/utils"
"github.com/lucas-clemente/quic-go/internal/wire"
"github.com/lucas-clemente/quic-go/logging"
)
// packetHandler handles packets
type packetHandler interface {
handlePacket(*receivedPacket)
shutdown()
destroy(error)
getPerspective() protocol.Perspective
}
type unknownPacketHandler interface {
handlePacket(*receivedPacket)
setCloseError(error)
}
type packetHandlerManager interface {
AddWithConnID(protocol.ConnectionID, protocol.ConnectionID, func() packetHandler) bool
Destroy() error
sessionRunner
SetServer(unknownPacketHandler)
CloseServer()
}
type quicSession interface {
EarlySession
earlySessionReady() <-chan struct{}
handlePacket(*receivedPacket)
GetVersion() protocol.VersionNumber
getPerspective() protocol.Perspective
run() error
destroy(error)
shutdown()
}
// A Listener of QUIC
type baseServer struct {
mutex sync.Mutex
acceptEarlySessions bool
tlsConf *tls.Config
config *Config
conn connection
// If the server is started with ListenAddr, we create a packet conn.
// If it is started with Listen, we take a packet conn as a parameter.
createdPacketConn bool
tokenGenerator *handshake.TokenGenerator
sessionHandler packetHandlerManager
receivedPackets chan *receivedPacket
// set as a member, so they can be set in the tests
newSession func(
sendConn,
sessionRunner,
protocol.ConnectionID, /* original dest connection ID */
*protocol.ConnectionID, /* retry src connection ID */
protocol.ConnectionID, /* client dest connection ID */
protocol.ConnectionID, /* destination connection ID */
protocol.ConnectionID, /* source connection ID */
protocol.StatelessResetToken,
*Config,
*tls.Config,
*handshake.TokenGenerator,
bool, /* enable 0-RTT */
logging.ConnectionTracer,
uint64,
utils.Logger,
protocol.VersionNumber,
) quicSession
serverError error
errorChan chan struct{}
closed bool
running chan struct{} // closed as soon as run() returns
sessionQueue chan quicSession
sessionQueueLen int32 // to be used as an atomic
logger utils.Logger
}
var (
_ Listener = &baseServer{}
_ unknownPacketHandler = &baseServer{}
)
type earlyServer struct{ *baseServer }
var _ EarlyListener = &earlyServer{}
func (s *earlyServer) Accept(ctx context.Context) (EarlySession, error) {
return s.baseServer.accept(ctx)
}
// ListenAddr creates a QUIC server listening on a given address.
// The tls.Config must not be nil and must contain a certificate configuration.
// The quic.Config may be nil, in that case the default values will be used.
func ListenAddr(addr string, tlsConf *tls.Config, config *Config) (Listener, error) {
return listenAddr(addr, tlsConf, config, false)
}
// ListenAddrEarly works like ListenAddr, but it returns sessions before the handshake completes.
func ListenAddrEarly(addr string, tlsConf *tls.Config, config *Config) (EarlyListener, error) {
s, err := listenAddr(addr, tlsConf, config, true)
if err != nil {
return nil, err
}
return &earlyServer{s}, nil
}
func listenAddr(addr string, tlsConf *tls.Config, config *Config, acceptEarly bool) (*baseServer, error) {
udpAddr, err := net.ResolveUDPAddr("udp", addr)
if err != nil {
return nil, err
}
conn, err := net.ListenUDP("udp", udpAddr)
if err != nil {
return nil, err
}
serv, err := listen(conn, tlsConf, config, acceptEarly)
if err != nil {
return nil, err
}
serv.createdPacketConn = true
return serv, nil
}
// Listen listens for QUIC connections on a given net.PacketConn. If the
// PacketConn satisfies the OOBCapablePacketConn interface (as a net.UDPConn
// does), ECN and packet info support will be enabled. In this case, ReadMsgUDP
// and WriteMsgUDP will be used instead of ReadFrom and WriteTo to read/write
// packets. A single net.PacketConn only be used for a single call to Listen.
// The PacketConn can be used for simultaneous calls to Dial. QUIC connection
// IDs are used for demultiplexing the different connections. The tls.Config
// must not be nil and must contain a certificate configuration. The
// tls.Config.CipherSuites allows setting of TLS 1.3 cipher suites. Furthermore,
// it must define an application control (using NextProtos). The quic.Config may
// be nil, in that case the default values will be used.
func Listen(conn net.PacketConn, tlsConf *tls.Config, config *Config) (Listener, error) {
return listen(conn, tlsConf, config, false)
}
// ListenEarly works like Listen, but it returns sessions before the handshake completes.
func ListenEarly(conn net.PacketConn, tlsConf *tls.Config, config *Config) (EarlyListener, error) {
s, err := listen(conn, tlsConf, config, true)
if err != nil {
return nil, err
}
return &earlyServer{s}, nil
}
func listen(conn net.PacketConn, tlsConf *tls.Config, config *Config, acceptEarly bool) (*baseServer, error) {
if tlsConf == nil {
return nil, errors.New("quic: tls.Config not set")
}
if err := validateConfig(config); err != nil {
return nil, err
}
config = populateServerConfig(config)
for _, v := range config.Versions {
if !protocol.IsValidVersion(v) {
return nil, fmt.Errorf("%s is not a valid QUIC version", v)
}
}
sessionHandler, err := getMultiplexer().AddConn(conn, config.ConnectionIDLength, config.StatelessResetKey, config.Tracer)
if err != nil {
return nil, err
}
tokenGenerator, err := handshake.NewTokenGenerator(rand.Reader)
if err != nil {
return nil, err
}
c, err := wrapConn(conn)
if err != nil {
return nil, err
}
s := &baseServer{
conn: c,
tlsConf: tlsConf,
config: config,
tokenGenerator: tokenGenerator,
sessionHandler: sessionHandler,
sessionQueue: make(chan quicSession),
errorChan: make(chan struct{}),
running: make(chan struct{}),
receivedPackets: make(chan *receivedPacket, protocol.MaxServerUnprocessedPackets),
newSession: newSession,
logger: utils.DefaultLogger.WithPrefix("server"),
acceptEarlySessions: acceptEarly,
}
go s.run()
sessionHandler.SetServer(s)
s.logger.Debugf("Listening for %s connections on %s", conn.LocalAddr().Network(), conn.LocalAddr().String())
return s, nil
}
func (s *baseServer) run() {
defer close(s.running)
for {
select {
case <-s.errorChan:
return
default:
}
select {
case <-s.errorChan:
return
case p := <-s.receivedPackets:
if bufferStillInUse := s.handlePacketImpl(p); !bufferStillInUse {
p.buffer.Release()
}
}
}
}
var defaultAcceptToken = func(clientAddr net.Addr, token *Token) bool {
if token == nil {
return false
}
validity := protocol.TokenValidity
if token.IsRetryToken {
validity = protocol.RetryTokenValidity
}
if time.Now().After(token.SentTime.Add(validity)) {
return false
}
var sourceAddr string
if udpAddr, ok := clientAddr.(*net.UDPAddr); ok {
sourceAddr = udpAddr.IP.String()
} else {
sourceAddr = clientAddr.String()
}
return sourceAddr == token.RemoteAddr
}
// Accept returns sessions that already completed the handshake.
// It is only valid if acceptEarlySessions is false.
func (s *baseServer) Accept(ctx context.Context) (Session, error) {
return s.accept(ctx)
}
func (s *baseServer) accept(ctx context.Context) (quicSession, error) {
select {
case <-ctx.Done():
return nil, ctx.Err()
case sess := <-s.sessionQueue:
atomic.AddInt32(&s.sessionQueueLen, -1)
return sess, nil
case <-s.errorChan:
return nil, s.serverError
}
}
// Close the server
func (s *baseServer) Close() error {
s.mutex.Lock()
if s.closed {
s.mutex.Unlock()
return nil
}
if s.serverError == nil {
s.serverError = errors.New("server closed")
}
// If the server was started with ListenAddr, we created the packet conn.
// We need to close it in order to make the go routine reading from that conn return.
createdPacketConn := s.createdPacketConn
s.closed = true
close(s.errorChan)
s.mutex.Unlock()
<-s.running
s.sessionHandler.CloseServer()
if createdPacketConn {
return s.sessionHandler.Destroy()
}
return nil
}
func (s *baseServer) setCloseError(e error) {
s.mutex.Lock()
defer s.mutex.Unlock()
if s.closed {
return
}
s.closed = true
s.serverError = e
close(s.errorChan)
}
// Addr returns the server's network address
func (s *baseServer) Addr() net.Addr {
return s.conn.LocalAddr()
}
func (s *baseServer) handlePacket(p *receivedPacket) {
select {
case s.receivedPackets <- p:
default:
s.logger.Debugf("Dropping packet from %s (%d bytes). Server receive queue full.", p.remoteAddr, p.Size())
if s.config.Tracer != nil {
s.config.Tracer.DroppedPacket(p.remoteAddr, logging.PacketTypeNotDetermined, p.Size(), logging.PacketDropDOSPrevention)
}
}
}
func (s *baseServer) handlePacketImpl(p *receivedPacket) bool /* is the buffer still in use? */ {
if wire.IsVersionNegotiationPacket(p.data) {
s.logger.Debugf("Dropping Version Negotiation packet.")
if s.config.Tracer != nil {
s.config.Tracer.DroppedPacket(p.remoteAddr, logging.PacketTypeVersionNegotiation, p.Size(), logging.PacketDropUnexpectedPacket)
}
return false
}
// If we're creating a new session, the packet will be passed to the session.
// The header will then be parsed again.
hdr, _, _, err := wire.ParsePacket(p.data, s.config.ConnectionIDLength)
if err != nil && err != wire.ErrUnsupportedVersion {
if s.config.Tracer != nil {
s.config.Tracer.DroppedPacket(p.remoteAddr, logging.PacketTypeNotDetermined, p.Size(), logging.PacketDropHeaderParseError)
}
s.logger.Debugf("Error parsing packet: %s", err)
return false
}
// Short header packets should never end up here in the first place
if !hdr.IsLongHeader {
panic(fmt.Sprintf("misrouted packet: %#v", hdr))
}
if hdr.Type == protocol.PacketTypeInitial && p.Size() < protocol.MinInitialPacketSize {
s.logger.Debugf("Dropping a packet that is too small to be a valid Initial (%d bytes)", p.Size())
if s.config.Tracer != nil {
s.config.Tracer.DroppedPacket(p.remoteAddr, logging.PacketTypeInitial, p.Size(), logging.PacketDropUnexpectedPacket)
}
return false
}
// send a Version Negotiation Packet if the client is speaking a different protocol version
if !protocol.IsSupportedVersion(s.config.Versions, hdr.Version) {
if p.Size() < protocol.MinUnknownVersionPacketSize {
s.logger.Debugf("Dropping a packet with an unknown version that is too small (%d bytes)", p.Size())
if s.config.Tracer != nil {
s.config.Tracer.DroppedPacket(p.remoteAddr, logging.PacketTypeNotDetermined, p.Size(), logging.PacketDropUnexpectedPacket)
}
return false
}
go s.sendVersionNegotiationPacket(p, hdr)
return false
}
if hdr.IsLongHeader && hdr.Type != protocol.PacketTypeInitial {
// Drop long header packets.
// There's little point in sending a Stateless Reset, since the client
// might not have received the token yet.
s.logger.Debugf("Dropping long header packet of type %s (%d bytes)", hdr.Type, len(p.data))
if s.config.Tracer != nil {
s.config.Tracer.DroppedPacket(p.remoteAddr, logging.PacketTypeFromHeader(hdr), p.Size(), logging.PacketDropUnexpectedPacket)
}
return false
}
s.logger.Debugf("<- Received Initial packet.")
if err := s.handleInitialImpl(p, hdr); err != nil {
s.logger.Errorf("Error occurred handling initial packet: %s", err)
}
// Don't put the packet buffer back.
// handleInitialImpl deals with the buffer.
return true
}
func (s *baseServer) handleInitialImpl(p *receivedPacket, hdr *wire.Header) error {
if len(hdr.Token) == 0 && hdr.DestConnectionID.Len() < protocol.MinConnectionIDLenInitial {
p.buffer.Release()
if s.config.Tracer != nil {
s.config.Tracer.DroppedPacket(p.remoteAddr, logging.PacketTypeInitial, p.Size(), logging.PacketDropUnexpectedPacket)
}
return errors.New("too short connection ID")
}
var (
token *Token
retrySrcConnID *protocol.ConnectionID
)
origDestConnID := hdr.DestConnectionID
if len(hdr.Token) > 0 {
c, err := s.tokenGenerator.DecodeToken(hdr.Token)
if err == nil {
token = &Token{
IsRetryToken: c.IsRetryToken,
RemoteAddr: c.RemoteAddr,
SentTime: c.SentTime,
}
if token.IsRetryToken {
origDestConnID = c.OriginalDestConnectionID
retrySrcConnID = &c.RetrySrcConnectionID
}
}
}
if !s.config.AcceptToken(p.remoteAddr, token) {
go func() {
defer p.buffer.Release()
if token != nil && token.IsRetryToken {
if err := s.maybeSendInvalidToken(p, hdr); err != nil {
s.logger.Debugf("Error sending INVALID_TOKEN error: %s", err)
}
return
}
if err := s.sendRetry(p.remoteAddr, hdr, p.info); err != nil {
s.logger.Debugf("Error sending Retry: %s", err)
}
}()
return nil
}
if queueLen := atomic.LoadInt32(&s.sessionQueueLen); queueLen >= protocol.MaxAcceptQueueSize {
s.logger.Debugf("Rejecting new connection. Server currently busy. Accept queue length: %d (max %d)", queueLen, protocol.MaxAcceptQueueSize)
go func() {
defer p.buffer.Release()
if err := s.sendConnectionRefused(p.remoteAddr, hdr, p.info); err != nil {
s.logger.Debugf("Error rejecting connection: %s", err)
}
}()
return nil
}
connID, err := protocol.GenerateConnectionID(s.config.ConnectionIDLength)
if err != nil {
return err
}
s.logger.Debugf("Changing connection ID to %s.", connID)
var sess quicSession
tracingID := nextSessionTracingID()
if added := s.sessionHandler.AddWithConnID(hdr.DestConnectionID, connID, func() packetHandler {
var tracer logging.ConnectionTracer
if s.config.Tracer != nil {
// Use the same connection ID that is passed to the client's GetLogWriter callback.
connID := hdr.DestConnectionID
if origDestConnID.Len() > 0 {
connID = origDestConnID
}
tracer = s.config.Tracer.TracerForConnection(
context.WithValue(context.Background(), SessionTracingKey, tracingID),
protocol.PerspectiveServer,
connID,
)
}
sess = s.newSession(
newSendConn(s.conn, p.remoteAddr, p.info),
s.sessionHandler,
origDestConnID,
retrySrcConnID,
hdr.DestConnectionID,
hdr.SrcConnectionID,
connID,
s.sessionHandler.GetStatelessResetToken(connID),
s.config,
s.tlsConf,
s.tokenGenerator,
s.acceptEarlySessions,
tracer,
tracingID,
s.logger,
hdr.Version,
)
sess.handlePacket(p)
return sess
}); !added {
return nil
}
go sess.run()
go s.handleNewSession(sess)
if sess == nil {
p.buffer.Release()
return nil
}
return nil
}
func (s *baseServer) handleNewSession(sess quicSession) {
sessCtx := sess.Context()
if s.acceptEarlySessions {
// wait until the early session is ready (or the handshake fails)
select {
case <-sess.earlySessionReady():
case <-sessCtx.Done():
return
}
} else {
// wait until the handshake is complete (or fails)
select {
case <-sess.HandshakeComplete().Done():
case <-sessCtx.Done():
return
}
}
atomic.AddInt32(&s.sessionQueueLen, 1)
select {
case s.sessionQueue <- sess:
// blocks until the session is accepted
case <-sessCtx.Done():
atomic.AddInt32(&s.sessionQueueLen, -1)
// don't pass sessions that were already closed to Accept()
}
}
func (s *baseServer) sendRetry(remoteAddr net.Addr, hdr *wire.Header, info *packetInfo) error {
// Log the Initial packet now.
// If no Retry is sent, the packet will be logged by the session.
(&wire.ExtendedHeader{Header: *hdr}).Log(s.logger)
srcConnID, err := protocol.GenerateConnectionID(s.config.ConnectionIDLength)
if err != nil {
return err
}
token, err := s.tokenGenerator.NewRetryToken(remoteAddr, hdr.DestConnectionID, srcConnID)
if err != nil {
return err
}
replyHdr := &wire.ExtendedHeader{}
replyHdr.IsLongHeader = true
replyHdr.Type = protocol.PacketTypeRetry
replyHdr.Version = hdr.Version
replyHdr.SrcConnectionID = srcConnID
replyHdr.DestConnectionID = hdr.SrcConnectionID
replyHdr.Token = token
if s.logger.Debug() {
s.logger.Debugf("Changing connection ID to %s.", srcConnID)
s.logger.Debugf("-> Sending Retry")
replyHdr.Log(s.logger)
}
packetBuffer := getPacketBuffer()
defer packetBuffer.Release()
buf := bytes.NewBuffer(packetBuffer.Data)
if err := replyHdr.Write(buf, hdr.Version); err != nil {
return err
}
// append the Retry integrity tag
tag := handshake.GetRetryIntegrityTag(buf.Bytes(), hdr.DestConnectionID, hdr.Version)
buf.Write(tag[:])
if s.config.Tracer != nil {
s.config.Tracer.SentPacket(remoteAddr, &replyHdr.Header, protocol.ByteCount(buf.Len()), nil)
}
_, err = s.conn.WritePacket(buf.Bytes(), remoteAddr, info.OOB())
return err
}
func (s *baseServer) maybeSendInvalidToken(p *receivedPacket, hdr *wire.Header) error {
// Only send INVALID_TOKEN if we can unprotect the packet.
// This makes sure that we won't send it for packets that were corrupted.
sealer, opener := handshake.NewInitialAEAD(hdr.DestConnectionID, protocol.PerspectiveServer, hdr.Version)
data := p.data[:hdr.ParsedLen()+hdr.Length]
extHdr, err := unpackHeader(opener, hdr, data, hdr.Version)
if err != nil {
if s.config.Tracer != nil {
s.config.Tracer.DroppedPacket(p.remoteAddr, logging.PacketTypeInitial, p.Size(), logging.PacketDropHeaderParseError)
}
// don't return the error here. Just drop the packet.
return nil
}
hdrLen := extHdr.ParsedLen()
if _, err := opener.Open(data[hdrLen:hdrLen], data[hdrLen:], extHdr.PacketNumber, data[:hdrLen]); err != nil {
// don't return the error here. Just drop the packet.
if s.config.Tracer != nil {
s.config.Tracer.DroppedPacket(p.remoteAddr, logging.PacketTypeInitial, p.Size(), logging.PacketDropPayloadDecryptError)
}
return nil
}
if s.logger.Debug() {
s.logger.Debugf("Client sent an invalid retry token. Sending INVALID_TOKEN to %s.", p.remoteAddr)
}
return s.sendError(p.remoteAddr, hdr, sealer, qerr.InvalidToken, p.info)
}
func (s *baseServer) sendConnectionRefused(remoteAddr net.Addr, hdr *wire.Header, info *packetInfo) error {
sealer, _ := handshake.NewInitialAEAD(hdr.DestConnectionID, protocol.PerspectiveServer, hdr.Version)
return s.sendError(remoteAddr, hdr, sealer, qerr.ConnectionRefused, info)
}
// sendError sends the error as a response to the packet received with header hdr
func (s *baseServer) sendError(remoteAddr net.Addr, hdr *wire.Header, sealer handshake.LongHeaderSealer, errorCode qerr.TransportErrorCode, info *packetInfo) error {
packetBuffer := getPacketBuffer()
defer packetBuffer.Release()
buf := bytes.NewBuffer(packetBuffer.Data)
ccf := &wire.ConnectionCloseFrame{ErrorCode: uint64(errorCode)}
replyHdr := &wire.ExtendedHeader{}
replyHdr.IsLongHeader = true
replyHdr.Type = protocol.PacketTypeInitial
replyHdr.Version = hdr.Version
replyHdr.SrcConnectionID = hdr.DestConnectionID
replyHdr.DestConnectionID = hdr.SrcConnectionID
replyHdr.PacketNumberLen = protocol.PacketNumberLen4
replyHdr.Length = 4 /* packet number len */ + ccf.Length(hdr.Version) + protocol.ByteCount(sealer.Overhead())
if err := replyHdr.Write(buf, hdr.Version); err != nil {
return err
}
payloadOffset := buf.Len()
if err := ccf.Write(buf, hdr.Version); err != nil {
return err
}
raw := buf.Bytes()
_ = sealer.Seal(raw[payloadOffset:payloadOffset], raw[payloadOffset:], replyHdr.PacketNumber, raw[:payloadOffset])
raw = raw[0 : buf.Len()+sealer.Overhead()]
pnOffset := payloadOffset - int(replyHdr.PacketNumberLen)
sealer.EncryptHeader(
raw[pnOffset+4:pnOffset+4+16],
&raw[0],
raw[pnOffset:payloadOffset],
)
replyHdr.Log(s.logger)
wire.LogFrame(s.logger, ccf, true)
if s.config.Tracer != nil {
s.config.Tracer.SentPacket(remoteAddr, &replyHdr.Header, protocol.ByteCount(len(raw)), []logging.Frame{ccf})
}
_, err := s.conn.WritePacket(raw, remoteAddr, info.OOB())
return err
}
func (s *baseServer) sendVersionNegotiationPacket(p *receivedPacket, hdr *wire.Header) {
s.logger.Debugf("Client offered version %s, sending Version Negotiation", hdr.Version)
data, err := wire.ComposeVersionNegotiation(hdr.SrcConnectionID, hdr.DestConnectionID, s.config.Versions)
if err != nil {
s.logger.Debugf("Error composing Version Negotiation: %s", err)
return
}
if s.config.Tracer != nil {
s.config.Tracer.SentPacket(
p.remoteAddr,
&wire.Header{
IsLongHeader: true,
DestConnectionID: hdr.SrcConnectionID,
SrcConnectionID: hdr.DestConnectionID,
},
protocol.ByteCount(len(data)),
nil,
)
}
if _, err := s.conn.WritePacket(data, p.remoteAddr, p.info.OOB()); err != nil {
s.logger.Debugf("Error sending Version Negotiation: %s", err)
}
}