// Package proxy contains all proxies used by Xray. // // To implement an inbound or outbound proxy, one needs to do the following: // 1. Implement the interface(s) below. // 2. Register a config creator through common.RegisterConfig. package proxy import ( "bytes" "context" "crypto/rand" "io" "math/big" "runtime" "strconv" "time" "github.com/pires/go-proxyproto" "github.com/xtls/xray-core/app/dispatcher" "github.com/xtls/xray-core/common/buf" "github.com/xtls/xray-core/common/errors" "github.com/xtls/xray-core/common/net" "github.com/xtls/xray-core/common/protocol" "github.com/xtls/xray-core/common/session" "github.com/xtls/xray-core/common/signal" "github.com/xtls/xray-core/features/routing" "github.com/xtls/xray-core/features/stats" "github.com/xtls/xray-core/transport" "github.com/xtls/xray-core/transport/internet" "github.com/xtls/xray-core/transport/internet/reality" "github.com/xtls/xray-core/transport/internet/stat" "github.com/xtls/xray-core/transport/internet/tls" ) var ( Tls13SupportedVersions = []byte{0x00, 0x2b, 0x00, 0x02, 0x03, 0x04} TlsClientHandShakeStart = []byte{0x16, 0x03} TlsServerHandShakeStart = []byte{0x16, 0x03, 0x03} TlsApplicationDataStart = []byte{0x17, 0x03, 0x03} Tls13CipherSuiteDic = map[uint16]string{ 0x1301: "TLS_AES_128_GCM_SHA256", 0x1302: "TLS_AES_256_GCM_SHA384", 0x1303: "TLS_CHACHA20_POLY1305_SHA256", 0x1304: "TLS_AES_128_CCM_SHA256", 0x1305: "TLS_AES_128_CCM_8_SHA256", } ) const ( TlsHandshakeTypeClientHello byte = 0x01 TlsHandshakeTypeServerHello byte = 0x02 CommandPaddingContinue byte = 0x00 CommandPaddingEnd byte = 0x01 CommandPaddingDirect byte = 0x02 ) // An Inbound processes inbound connections. type Inbound interface { // Network returns a list of networks that this inbound supports. Connections with not-supported networks will not be passed into Process(). Network() []net.Network // Process processes a connection of given network. If necessary, the Inbound can dispatch the connection to an Outbound. Process(context.Context, net.Network, stat.Connection, routing.Dispatcher) error } // An Outbound process outbound connections. type Outbound interface { // Process processes the given connection. The given dialer may be used to dial a system outbound connection. Process(context.Context, *transport.Link, internet.Dialer) error } // UserManager is the interface for Inbounds and Outbounds that can manage their users. type UserManager interface { // AddUser adds a new user. AddUser(context.Context, *protocol.MemoryUser) error // RemoveUser removes a user by email. RemoveUser(context.Context, string) error // Get user by email. GetUser(context.Context, string) *protocol.MemoryUser // Get all users. GetUsers(context.Context) []*protocol.MemoryUser // Get users count. GetUsersCount(context.Context) int64 } type GetInbound interface { GetInbound() Inbound } type GetOutbound interface { GetOutbound() Outbound } // TrafficState is used to track uplink and downlink of one connection // It is used by XTLS to determine if switch to raw copy mode, It is used by Vision to calculate padding type TrafficState struct { UserUUID []byte NumberOfPacketToFilter int EnableXtls bool IsTLS12orAbove bool IsTLS bool Cipher uint16 RemainingServerHello int32 // reader link state WithinPaddingBuffers bool ReaderSwitchToDirectCopy bool RemainingCommand int32 RemainingContent int32 RemainingPadding int32 CurrentCommand int // write link state IsPadding bool WriterSwitchToDirectCopy bool } func NewTrafficState(userUUID []byte) *TrafficState { return &TrafficState{ UserUUID: userUUID, NumberOfPacketToFilter: 8, EnableXtls: false, IsTLS12orAbove: false, IsTLS: false, Cipher: 0, RemainingServerHello: -1, WithinPaddingBuffers: true, ReaderSwitchToDirectCopy: false, RemainingCommand: -1, RemainingContent: -1, RemainingPadding: -1, CurrentCommand: 0, IsPadding: true, WriterSwitchToDirectCopy: false, } } // VisionReader is used to read xtls vision protocol // Note Vision probably only make sense as the inner most layer of reader, since it need assess traffic state from origin proxy traffic type VisionReader struct { buf.Reader trafficState *TrafficState ctx context.Context } func NewVisionReader(reader buf.Reader, state *TrafficState, context context.Context) *VisionReader { return &VisionReader{ Reader: reader, trafficState: state, ctx: context, } } func (w *VisionReader) ReadMultiBuffer() (buf.MultiBuffer, error) { buffer, err := w.Reader.ReadMultiBuffer() if !buffer.IsEmpty() { if w.trafficState.WithinPaddingBuffers || w.trafficState.NumberOfPacketToFilter > 0 { mb2 := make(buf.MultiBuffer, 0, len(buffer)) for _, b := range buffer { newbuffer := XtlsUnpadding(b, w.trafficState, w.ctx) if newbuffer.Len() > 0 { mb2 = append(mb2, newbuffer) } } buffer = mb2 if w.trafficState.RemainingContent > 0 || w.trafficState.RemainingPadding > 0 || w.trafficState.CurrentCommand == 0 { w.trafficState.WithinPaddingBuffers = true } else if w.trafficState.CurrentCommand == 1 { w.trafficState.WithinPaddingBuffers = false } else if w.trafficState.CurrentCommand == 2 { w.trafficState.WithinPaddingBuffers = false w.trafficState.ReaderSwitchToDirectCopy = true } else { errors.LogInfo(w.ctx, "XtlsRead unknown command ", w.trafficState.CurrentCommand, buffer.Len()) } } if w.trafficState.NumberOfPacketToFilter > 0 { XtlsFilterTls(buffer, w.trafficState, w.ctx) } } return buffer, err } // VisionWriter is used to write xtls vision protocol // Note Vision probably only make sense as the inner most layer of writer, since it need assess traffic state from origin proxy traffic type VisionWriter struct { buf.Writer trafficState *TrafficState ctx context.Context writeOnceUserUUID []byte } func NewVisionWriter(writer buf.Writer, state *TrafficState, context context.Context) *VisionWriter { w := make([]byte, len(state.UserUUID)) copy(w, state.UserUUID) return &VisionWriter{ Writer: writer, trafficState: state, ctx: context, writeOnceUserUUID: w, } } func (w *VisionWriter) WriteMultiBuffer(mb buf.MultiBuffer) error { if w.trafficState.NumberOfPacketToFilter > 0 { XtlsFilterTls(mb, w.trafficState, w.ctx) } if w.trafficState.IsPadding { if len(mb) == 1 && mb[0] == nil { mb[0] = XtlsPadding(nil, CommandPaddingContinue, &w.writeOnceUserUUID, true, w.ctx) // we do a long padding to hide vless header return w.Writer.WriteMultiBuffer(mb) } mb = ReshapeMultiBuffer(w.ctx, mb) longPadding := w.trafficState.IsTLS for i, b := range mb { if w.trafficState.IsTLS && b.Len() >= 6 && bytes.Equal(TlsApplicationDataStart, b.BytesTo(3)) { if w.trafficState.EnableXtls { w.trafficState.WriterSwitchToDirectCopy = true } var command byte = CommandPaddingContinue if i == len(mb)-1 { command = CommandPaddingEnd if w.trafficState.EnableXtls { command = CommandPaddingDirect } } mb[i] = XtlsPadding(b, command, &w.writeOnceUserUUID, true, w.ctx) w.trafficState.IsPadding = false // padding going to end longPadding = false continue } else if !w.trafficState.IsTLS12orAbove && w.trafficState.NumberOfPacketToFilter <= 1 { // For compatibility with earlier vision receiver, we finish padding 1 packet early w.trafficState.IsPadding = false mb[i] = XtlsPadding(b, CommandPaddingEnd, &w.writeOnceUserUUID, longPadding, w.ctx) break } var command byte = CommandPaddingContinue if i == len(mb)-1 && !w.trafficState.IsPadding { command = CommandPaddingEnd if w.trafficState.EnableXtls { command = CommandPaddingDirect } } mb[i] = XtlsPadding(b, command, &w.writeOnceUserUUID, longPadding, w.ctx) } } return w.Writer.WriteMultiBuffer(mb) } // ReshapeMultiBuffer prepare multi buffer for padding structure (max 21 bytes) func ReshapeMultiBuffer(ctx context.Context, buffer buf.MultiBuffer) buf.MultiBuffer { needReshape := 0 for _, b := range buffer { if b.Len() >= buf.Size-21 { needReshape += 1 } } if needReshape == 0 { return buffer } mb2 := make(buf.MultiBuffer, 0, len(buffer)+needReshape) toPrint := "" for i, buffer1 := range buffer { if buffer1.Len() >= buf.Size-21 { index := int32(bytes.LastIndex(buffer1.Bytes(), TlsApplicationDataStart)) if index < 21 || index > buf.Size-21 { index = buf.Size / 2 } buffer2 := buf.New() buffer2.Write(buffer1.BytesFrom(index)) buffer1.Resize(0, index) mb2 = append(mb2, buffer1, buffer2) toPrint += " " + strconv.Itoa(int(buffer1.Len())) + " " + strconv.Itoa(int(buffer2.Len())) } else { mb2 = append(mb2, buffer1) toPrint += " " + strconv.Itoa(int(buffer1.Len())) } buffer[i] = nil } buffer = buffer[:0] errors.LogInfo(ctx, "ReshapeMultiBuffer ", toPrint) return mb2 } // XtlsPadding add padding to eliminate length signature during tls handshake func XtlsPadding(b *buf.Buffer, command byte, userUUID *[]byte, longPadding bool, ctx context.Context) *buf.Buffer { var contentLen int32 = 0 var paddingLen int32 = 0 if b != nil { contentLen = b.Len() } if contentLen < 900 && longPadding { l, err := rand.Int(rand.Reader, big.NewInt(500)) if err != nil { errors.LogDebugInner(ctx, err, "failed to generate padding") } paddingLen = int32(l.Int64()) + 900 - contentLen } else { l, err := rand.Int(rand.Reader, big.NewInt(256)) if err != nil { errors.LogDebugInner(ctx, err, "failed to generate padding") } paddingLen = int32(l.Int64()) } if paddingLen > buf.Size-21-contentLen { paddingLen = buf.Size - 21 - contentLen } newbuffer := buf.New() if userUUID != nil { newbuffer.Write(*userUUID) *userUUID = nil } newbuffer.Write([]byte{command, byte(contentLen >> 8), byte(contentLen), byte(paddingLen >> 8), byte(paddingLen)}) if b != nil { newbuffer.Write(b.Bytes()) b.Release() b = nil } newbuffer.Extend(paddingLen) errors.LogInfo(ctx, "XtlsPadding ", contentLen, " ", paddingLen, " ", command) return newbuffer } // XtlsUnpadding remove padding and parse command func XtlsUnpadding(b *buf.Buffer, s *TrafficState, ctx context.Context) *buf.Buffer { if s.RemainingCommand == -1 && s.RemainingContent == -1 && s.RemainingPadding == -1 { // initial state if b.Len() >= 21 && bytes.Equal(s.UserUUID, b.BytesTo(16)) { b.Advance(16) s.RemainingCommand = 5 } else { return b } } newbuffer := buf.New() for b.Len() > 0 { if s.RemainingCommand > 0 { data, err := b.ReadByte() if err != nil { return newbuffer } switch s.RemainingCommand { case 5: s.CurrentCommand = int(data) case 4: s.RemainingContent = int32(data) << 8 case 3: s.RemainingContent = s.RemainingContent | int32(data) case 2: s.RemainingPadding = int32(data) << 8 case 1: s.RemainingPadding = s.RemainingPadding | int32(data) errors.LogInfo(ctx, "Xtls Unpadding new block, content ", s.RemainingContent, " padding ", s.RemainingPadding, " command ", s.CurrentCommand) } s.RemainingCommand-- } else if s.RemainingContent > 0 { len := s.RemainingContent if b.Len() < len { len = b.Len() } data, err := b.ReadBytes(len) if err != nil { return newbuffer } newbuffer.Write(data) s.RemainingContent -= len } else { // remainingPadding > 0 len := s.RemainingPadding if b.Len() < len { len = b.Len() } b.Advance(len) s.RemainingPadding -= len } if s.RemainingCommand <= 0 && s.RemainingContent <= 0 && s.RemainingPadding <= 0 { // this block done if s.CurrentCommand == 0 { s.RemainingCommand = 5 } else { s.RemainingCommand = -1 // set to initial state s.RemainingContent = -1 s.RemainingPadding = -1 if b.Len() > 0 { // shouldn't happen newbuffer.Write(b.Bytes()) } break } } } b.Release() b = nil return newbuffer } // XtlsFilterTls filter and recognize tls 1.3 and other info func XtlsFilterTls(buffer buf.MultiBuffer, trafficState *TrafficState, ctx context.Context) { for _, b := range buffer { if b == nil { continue } trafficState.NumberOfPacketToFilter-- if b.Len() >= 6 { startsBytes := b.BytesTo(6) if bytes.Equal(TlsServerHandShakeStart, startsBytes[:3]) && startsBytes[5] == TlsHandshakeTypeServerHello { trafficState.RemainingServerHello = (int32(startsBytes[3])<<8 | int32(startsBytes[4])) + 5 trafficState.IsTLS12orAbove = true trafficState.IsTLS = true if b.Len() >= 79 && trafficState.RemainingServerHello >= 79 { sessionIdLen := int32(b.Byte(43)) cipherSuite := b.BytesRange(43+sessionIdLen+1, 43+sessionIdLen+3) trafficState.Cipher = uint16(cipherSuite[0])<<8 | uint16(cipherSuite[1]) } else { errors.LogInfo(ctx, "XtlsFilterTls short server hello, tls 1.2 or older? ", b.Len(), " ", trafficState.RemainingServerHello) } } else if bytes.Equal(TlsClientHandShakeStart, startsBytes[:2]) && startsBytes[5] == TlsHandshakeTypeClientHello { trafficState.IsTLS = true errors.LogInfo(ctx, "XtlsFilterTls found tls client hello! ", buffer.Len()) } } if trafficState.RemainingServerHello > 0 { end := trafficState.RemainingServerHello if end > b.Len() { end = b.Len() } trafficState.RemainingServerHello -= b.Len() if bytes.Contains(b.BytesTo(end), Tls13SupportedVersions) { v, ok := Tls13CipherSuiteDic[trafficState.Cipher] if !ok { v = "Old cipher: " + strconv.FormatUint(uint64(trafficState.Cipher), 16) } else if v != "TLS_AES_128_CCM_8_SHA256" { trafficState.EnableXtls = true } errors.LogInfo(ctx, "XtlsFilterTls found tls 1.3! ", b.Len(), " ", v) trafficState.NumberOfPacketToFilter = 0 return } else if trafficState.RemainingServerHello <= 0 { errors.LogInfo(ctx, "XtlsFilterTls found tls 1.2! ", b.Len()) trafficState.NumberOfPacketToFilter = 0 return } errors.LogInfo(ctx, "XtlsFilterTls inconclusive server hello ", b.Len(), " ", trafficState.RemainingServerHello) } if trafficState.NumberOfPacketToFilter <= 0 { errors.LogInfo(ctx, "XtlsFilterTls stop filtering", buffer.Len()) } } } // UnwrapRawConn support unwrap stats, tls, utls, reality and proxyproto conn and get raw tcp conn from it func UnwrapRawConn(conn net.Conn) (net.Conn, stats.Counter, stats.Counter) { var readCounter, writerCounter stats.Counter if conn != nil { statConn, ok := conn.(*stat.CounterConnection) if ok { conn = statConn.Connection readCounter = statConn.ReadCounter writerCounter = statConn.WriteCounter } if xc, ok := conn.(*tls.Conn); ok { conn = xc.NetConn() } else if utlsConn, ok := conn.(*tls.UConn); ok { conn = utlsConn.NetConn() } else if realityConn, ok := conn.(*reality.Conn); ok { conn = realityConn.NetConn() } else if realityUConn, ok := conn.(*reality.UConn); ok { conn = realityUConn.NetConn() } if pc, ok := conn.(*proxyproto.Conn); ok { conn = pc.Raw() // 8192 > 4096, there is no need to process pc's bufReader } } return conn, readCounter, writerCounter } // CopyRawConnIfExist use the most efficient copy method. // - If caller don't want to turn on splice, do not pass in both reader conn and writer conn // - writer are from *transport.Link func CopyRawConnIfExist(ctx context.Context, readerConn net.Conn, writerConn net.Conn, writer buf.Writer, timer *signal.ActivityTimer, inTimer *signal.ActivityTimer) error { readerConn, readCounter, _ := UnwrapRawConn(readerConn) writerConn, _, writeCounter := UnwrapRawConn(writerConn) reader := buf.NewReader(readerConn) if runtime.GOOS != "linux" && runtime.GOOS != "android" { return readV(ctx, reader, writer, timer, readCounter) } tc, ok := writerConn.(*net.TCPConn) if !ok || readerConn == nil || writerConn == nil { return readV(ctx, reader, writer, timer, readCounter) } inbound := session.InboundFromContext(ctx) if inbound == nil || inbound.CanSpliceCopy == 3 { return readV(ctx, reader, writer, timer, readCounter) } outbounds := session.OutboundsFromContext(ctx) if len(outbounds) == 0 { return readV(ctx, reader, writer, timer, readCounter) } for _, ob := range outbounds { if ob.CanSpliceCopy == 3 { return readV(ctx, reader, writer, timer, readCounter) } } for { inbound := session.InboundFromContext(ctx) outbounds := session.OutboundsFromContext(ctx) var splice = inbound.CanSpliceCopy == 1 for _, ob := range outbounds { if ob.CanSpliceCopy != 1 { splice = false } } if splice { errors.LogInfo(ctx, "CopyRawConn splice") statWriter, _ := writer.(*dispatcher.SizeStatWriter) //runtime.Gosched() // necessary time.Sleep(time.Millisecond) // without this, there will be a rare ssl error for freedom splice timer.SetTimeout(8 * time.Hour) // prevent leak, just in case if inTimer != nil { inTimer.SetTimeout(8 * time.Hour) } w, err := tc.ReadFrom(readerConn) if readCounter != nil { readCounter.Add(w) // outbound stats } if writeCounter != nil { writeCounter.Add(w) // inbound stats } if statWriter != nil { statWriter.Counter.Add(w) // user stats } if err != nil && errors.Cause(err) != io.EOF { return err } return nil } buffer, err := reader.ReadMultiBuffer() if !buffer.IsEmpty() { if readCounter != nil { readCounter.Add(int64(buffer.Len())) } timer.Update() if werr := writer.WriteMultiBuffer(buffer); werr != nil { return werr } } if err != nil { return err } } } func readV(ctx context.Context, reader buf.Reader, writer buf.Writer, timer signal.ActivityUpdater, readCounter stats.Counter) error { errors.LogInfo(ctx, "CopyRawConn readv") if err := buf.Copy(reader, writer, buf.UpdateActivity(timer), buf.AddToStatCounter(readCounter)); err != nil { return errors.New("failed to process response").Base(err) } return nil }