Xray-core/proxy/vless/encoding/encoding.go

580 lines
18 KiB
Go

package encoding
//go:generate go run github.com/xtls/xray-core/common/errors/errorgen
import (
"bytes"
"context"
"crypto/rand"
"fmt"
"io"
"math/big"
"runtime"
"strconv"
"syscall"
"time"
"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/stats"
"github.com/xtls/xray-core/proxy/vless"
"github.com/xtls/xray-core/transport/internet/stat"
"github.com/xtls/xray-core/transport/internet/tls"
"github.com/xtls/xray-core/transport/internet/xtls"
)
const (
Version = byte(0)
)
var tls13SupportedVersions = []byte{0x00, 0x2b, 0x00, 0x02, 0x03, 0x04}
var tlsClientHandShakeStart = []byte{0x16, 0x03}
var tlsServerHandShakeStart = []byte{0x16, 0x03, 0x03}
var tlsApplicationDataStart = []byte{0x17, 0x03, 0x03}
var addrParser = protocol.NewAddressParser(
protocol.AddressFamilyByte(byte(protocol.AddressTypeIPv4), net.AddressFamilyIPv4),
protocol.AddressFamilyByte(byte(protocol.AddressTypeDomain), net.AddressFamilyDomain),
protocol.AddressFamilyByte(byte(protocol.AddressTypeIPv6), net.AddressFamilyIPv6),
protocol.PortThenAddress(),
)
// EncodeRequestHeader writes encoded request header into the given writer.
func EncodeRequestHeader(writer io.Writer, request *protocol.RequestHeader, requestAddons *Addons) error {
buffer := buf.StackNew()
defer buffer.Release()
if err := buffer.WriteByte(request.Version); err != nil {
return newError("failed to write request version").Base(err)
}
if _, err := buffer.Write(request.User.Account.(*vless.MemoryAccount).ID.Bytes()); err != nil {
return newError("failed to write request user id").Base(err)
}
if err := EncodeHeaderAddons(&buffer, requestAddons); err != nil {
return newError("failed to encode request header addons").Base(err)
}
if err := buffer.WriteByte(byte(request.Command)); err != nil {
return newError("failed to write request command").Base(err)
}
if request.Command != protocol.RequestCommandMux {
if err := addrParser.WriteAddressPort(&buffer, request.Address, request.Port); err != nil {
return newError("failed to write request address and port").Base(err)
}
}
if _, err := writer.Write(buffer.Bytes()); err != nil {
return newError("failed to write request header").Base(err)
}
return nil
}
// DecodeRequestHeader decodes and returns (if successful) a RequestHeader from an input stream.
func DecodeRequestHeader(isfb bool, first *buf.Buffer, reader io.Reader, validator *vless.Validator) (*protocol.RequestHeader, *Addons, bool, error) {
buffer := buf.StackNew()
defer buffer.Release()
request := new(protocol.RequestHeader)
if isfb {
request.Version = first.Byte(0)
} else {
if _, err := buffer.ReadFullFrom(reader, 1); err != nil {
return nil, nil, false, newError("failed to read request version").Base(err)
}
request.Version = buffer.Byte(0)
}
switch request.Version {
case 0:
var id [16]byte
if isfb {
copy(id[:], first.BytesRange(1, 17))
} else {
buffer.Clear()
if _, err := buffer.ReadFullFrom(reader, 16); err != nil {
return nil, nil, false, newError("failed to read request user id").Base(err)
}
copy(id[:], buffer.Bytes())
}
if request.User = validator.Get(id); request.User == nil {
return nil, nil, isfb, newError("invalid request user id")
}
if isfb {
first.Advance(17)
}
requestAddons, err := DecodeHeaderAddons(&buffer, reader)
if err != nil {
return nil, nil, false, newError("failed to decode request header addons").Base(err)
}
buffer.Clear()
if _, err := buffer.ReadFullFrom(reader, 1); err != nil {
return nil, nil, false, newError("failed to read request command").Base(err)
}
request.Command = protocol.RequestCommand(buffer.Byte(0))
switch request.Command {
case protocol.RequestCommandMux:
request.Address = net.DomainAddress("v1.mux.cool")
request.Port = 0
case protocol.RequestCommandTCP, protocol.RequestCommandUDP:
if addr, port, err := addrParser.ReadAddressPort(&buffer, reader); err == nil {
request.Address = addr
request.Port = port
}
}
if request.Address == nil {
return nil, nil, false, newError("invalid request address")
}
return request, requestAddons, false, nil
default:
return nil, nil, isfb, newError("invalid request version")
}
}
// EncodeResponseHeader writes encoded response header into the given writer.
func EncodeResponseHeader(writer io.Writer, request *protocol.RequestHeader, responseAddons *Addons) error {
buffer := buf.StackNew()
defer buffer.Release()
if err := buffer.WriteByte(request.Version); err != nil {
return newError("failed to write response version").Base(err)
}
if err := EncodeHeaderAddons(&buffer, responseAddons); err != nil {
return newError("failed to encode response header addons").Base(err)
}
if _, err := writer.Write(buffer.Bytes()); err != nil {
return newError("failed to write response header").Base(err)
}
return nil
}
// DecodeResponseHeader decodes and returns (if successful) a ResponseHeader from an input stream.
func DecodeResponseHeader(reader io.Reader, request *protocol.RequestHeader) (*Addons, error) {
buffer := buf.StackNew()
defer buffer.Release()
if _, err := buffer.ReadFullFrom(reader, 1); err != nil {
return nil, newError("failed to read response version").Base(err)
}
if buffer.Byte(0) != request.Version {
return nil, newError("unexpected response version. Expecting ", int(request.Version), " but actually ", int(buffer.Byte(0)))
}
responseAddons, err := DecodeHeaderAddons(&buffer, reader)
if err != nil {
return nil, newError("failed to decode response header addons").Base(err)
}
return responseAddons, nil
}
func ReadV(reader buf.Reader, writer buf.Writer, timer signal.ActivityUpdater, conn *xtls.Conn, rawConn syscall.RawConn, counter stats.Counter, ctx context.Context) error {
err := func() error {
var ct stats.Counter
for {
if conn.DirectIn {
conn.DirectIn = false
if inbound := session.InboundFromContext(ctx); inbound != nil && inbound.Conn != nil {
iConn := inbound.Conn
statConn, ok := iConn.(*stat.CounterConnection)
if ok {
iConn = statConn.Connection
}
if xc, ok := iConn.(*xtls.Conn); ok {
iConn = xc.NetConn()
}
if tc, ok := iConn.(*net.TCPConn); ok {
if conn.SHOW {
fmt.Println(conn.MARK, "Splice")
}
runtime.Gosched() // necessary
w, err := tc.ReadFrom(conn.NetConn())
if counter != nil {
counter.Add(w)
}
if statConn != nil && statConn.WriteCounter != nil {
statConn.WriteCounter.Add(w)
}
return err
} else {
panic("XTLS Splice: not TCP inbound")
}
}
reader = buf.NewReadVReader(conn.NetConn(), rawConn, nil)
ct = counter
if conn.SHOW {
fmt.Println(conn.MARK, "ReadV")
}
}
buffer, err := reader.ReadMultiBuffer()
if !buffer.IsEmpty() {
if ct != nil {
ct.Add(int64(buffer.Len()))
}
timer.Update()
if werr := writer.WriteMultiBuffer(buffer); werr != nil {
return werr
}
}
if err != nil {
return err
}
}
}()
if err != nil && errors.Cause(err) != io.EOF {
return err
}
return nil
}
// XtlsRead filter and read xtls protocol
func XtlsRead(reader buf.Reader, writer buf.Writer, timer signal.ActivityUpdater, conn net.Conn, rawConn syscall.RawConn, counter stats.Counter, ctx context.Context, userUUID []byte, numberOfPacketToFilter *int, enableXtls *bool, isTLS12orAbove *bool, isTLS *bool) error {
err := func() error {
var ct stats.Counter
filterUUID := true
shouldSwitchToDirectCopy := false
var remainingContent int32 = -1
var remainingPadding int32 = -1
currentCommand := 0
for {
if shouldSwitchToDirectCopy {
shouldSwitchToDirectCopy = false
if runtime.GOOS == "linux" || runtime.GOOS == "android" {
if inbound := session.InboundFromContext(ctx); inbound != nil && inbound.Conn != nil {
iConn := inbound.Conn
statConn, ok := iConn.(*stat.CounterConnection)
if ok {
iConn = statConn.Connection
}
if xc, ok := iConn.(*tls.Conn); ok {
iConn = xc.NetConn()
}
if tc, ok := iConn.(*net.TCPConn); ok {
newError("XtlsRead splice").WriteToLog(session.ExportIDToError(ctx))
runtime.Gosched() // necessary
w, err := tc.ReadFrom(conn)
if counter != nil {
counter.Add(w)
}
if statConn != nil && statConn.WriteCounter != nil {
statConn.WriteCounter.Add(w)
}
return err
} else {
panic("XTLS Splice: not TCP inbound")
}
} else {
// panic("XTLS Splice: nil inbound or nil inbound.Conn")
}
}
reader = buf.NewReadVReader(conn, rawConn, nil)
ct = counter
newError("XtlsRead readV").WriteToLog(session.ExportIDToError(ctx))
}
buffer, err := reader.ReadMultiBuffer()
if !buffer.IsEmpty() {
if filterUUID && (*isTLS || *numberOfPacketToFilter > 0) {
buffer = XtlsUnpadding(ctx, buffer, userUUID, &remainingContent, &remainingPadding, &currentCommand)
if remainingContent == 0 && remainingPadding == 0 {
if currentCommand == 1 {
filterUUID = false
} else if currentCommand == 2 {
filterUUID = false
shouldSwitchToDirectCopy = true
} else if currentCommand != 0 {
newError("XtlsRead unknown command ", currentCommand, buffer.Len()).WriteToLog(session.ExportIDToError(ctx))
}
}
}
if *numberOfPacketToFilter > 0 {
XtlsFilterTls(buffer, numberOfPacketToFilter, enableXtls, isTLS12orAbove, isTLS, ctx)
}
if ct != nil {
ct.Add(int64(buffer.Len()))
}
timer.Update()
if werr := writer.WriteMultiBuffer(buffer); werr != nil {
return werr
}
}
if err != nil {
return err
}
}
}()
if err != nil && errors.Cause(err) != io.EOF {
return err
}
return nil
}
// XtlsWrite filter and write xtls protocol
func XtlsWrite(reader buf.Reader, writer buf.Writer, timer signal.ActivityUpdater, conn net.Conn, counter stats.Counter, ctx context.Context, userUUID *[]byte, numberOfPacketToFilter *int, enableXtls *bool, isTLS12orAbove *bool, isTLS *bool) error {
err := func() error {
var ct stats.Counter
filterTlsApplicationData := true
shouldSwitchToDirectCopy := false
for {
buffer, err := reader.ReadMultiBuffer()
if !buffer.IsEmpty() {
if *numberOfPacketToFilter > 0 {
XtlsFilterTls(buffer, numberOfPacketToFilter, enableXtls, isTLS12orAbove, isTLS, ctx)
}
if filterTlsApplicationData && *isTLS {
buffer = ReshapeMultiBuffer(ctx, buffer)
var xtlsSpecIndex int
for i, b := range buffer {
if b.Len() >= 6 && bytes.Equal(tlsApplicationDataStart, b.BytesTo(3)) {
var command byte = 0x01
if *enableXtls {
shouldSwitchToDirectCopy = true
xtlsSpecIndex = i
command = 0x02
}
filterTlsApplicationData = false
buffer[i] = XtlsPadding(b, command, userUUID, ctx)
break
} else if !*isTLS12orAbove && *numberOfPacketToFilter <= 0 {
//maybe tls 1.1 or 1.0
filterTlsApplicationData = false
buffer[i] = XtlsPadding(b, 0x01, userUUID, ctx)
break
}
buffer[i] = XtlsPadding(b, 0x00, userUUID, ctx)
}
if shouldSwitchToDirectCopy {
encryptBuffer, directBuffer := buf.SplitMulti(buffer, xtlsSpecIndex+1)
length := encryptBuffer.Len()
if !encryptBuffer.IsEmpty() {
timer.Update()
if werr := writer.WriteMultiBuffer(encryptBuffer); werr != nil {
return werr
}
}
buffer = directBuffer
writer = buf.NewWriter(conn)
ct = counter
newError("XtlsWrite writeV ", xtlsSpecIndex, " ", length, " ", buffer.Len()).WriteToLog(session.ExportIDToError(ctx))
time.Sleep(5 * time.Millisecond) // for some device, the first xtls direct packet fails without this delay
}
}
if !buffer.IsEmpty() {
if ct != nil {
ct.Add(int64(buffer.Len()))
}
timer.Update()
if werr := writer.WriteMultiBuffer(buffer); werr != nil {
return werr
}
}
}
if err != nil {
return err
}
}
}()
if err != nil && errors.Cause(err) != io.EOF {
return err
}
return nil
}
// XtlsFilterTls filter and recognize tls 1.3 and other info
func XtlsFilterTls(buffer buf.MultiBuffer, numberOfPacketToFilter *int, enableXtls *bool, isTLS12orAbove *bool, isTLS *bool, ctx context.Context) {
for _, b := range buffer {
*numberOfPacketToFilter--
if b.Len() >= 6 {
startsBytes := b.BytesTo(6)
if bytes.Equal(tlsServerHandShakeStart, startsBytes[:3]) && startsBytes[5] == 0x02 {
total := (int(startsBytes[3])<<8 | int(startsBytes[4])) + 5
if b.Len() >= 74 && total >= 74 {
if bytes.Contains(b.BytesTo(int32(total)), tls13SupportedVersions) {
sessionIdLen := int32(b.Byte(43))
cipherSuite := b.BytesRange(43 + sessionIdLen + 1, 43 + sessionIdLen + 3)
cipherNum := uint16(cipherSuite[0]) << 8 | uint16(cipherSuite[1])
v, ok := Tls13CipherSuiteDic[cipherNum]
if !ok {
v = "Unknown cipher!"
} else if (v != "TLS_AES_128_CCM_8_SHA256") {
*enableXtls = true
}
newError("XtlsFilterTls found tls 1.3! ", buffer.Len(), " ", v).WriteToLog(session.ExportIDToError(ctx))
} else {
newError("XtlsFilterTls found tls 1.2! ", buffer.Len()).WriteToLog(session.ExportIDToError(ctx))
}
*isTLS12orAbove = true
*isTLS = true
*numberOfPacketToFilter = 0
return
} else {
newError("XtlsFilterTls short server hello, tls 1.2 or older? ", b.Len(), " ", total).WriteToLog(session.ExportIDToError(ctx))
}
} else if bytes.Equal(tlsClientHandShakeStart, startsBytes[:2]) && startsBytes[5] == 0x01 {
*isTLS = true
newError("XtlsFilterTls found tls client hello! ", buffer.Len()).WriteToLog(session.ExportIDToError(ctx))
}
}
if *numberOfPacketToFilter <= 0 {
newError("XtlsFilterTls stop filtering", buffer.Len()).WriteToLog(session.ExportIDToError(ctx))
}
}
}
// ReshapeMultiBuffer prepare multi buffer for padding stucture (max 21 bytes)
func ReshapeMultiBuffer(ctx context.Context, buffer buf.MultiBuffer) buf.MultiBuffer {
needReshape := false
for _, b := range buffer {
if b.Len() >= buf.Size-21 {
needReshape = true
}
}
if !needReshape {
return buffer
}
mb2 := make(buf.MultiBuffer, 0, len(buffer))
print := ""
for _, b := range buffer {
if b.Len() >= buf.Size-21 {
index := int32(bytes.LastIndex(b.Bytes(), tlsApplicationDataStart))
if index <= 0 {
index = buf.Size / 2
}
buffer1 := buf.New()
buffer2 := buf.New()
buffer1.Write(b.BytesTo(index))
buffer2.Write(b.BytesFrom(index))
mb2 = append(mb2, buffer1, buffer2)
print += " " + strconv.Itoa(int(buffer1.Len())) + " " + strconv.Itoa(int(buffer2.Len()))
} else {
newbuffer := buf.New()
newbuffer.Write(b.Bytes())
mb2 = append(mb2, newbuffer)
print += " " + strconv.Itoa(int(b.Len()))
}
}
buf.ReleaseMulti(buffer)
newError("ReshapeMultiBuffer ", print).WriteToLog(session.ExportIDToError(ctx))
return mb2
}
// XtlsPadding add padding to eliminate length siganature during tls handshake
func XtlsPadding(b *buf.Buffer, command byte, userUUID *[]byte, ctx context.Context) *buf.Buffer {
var length int32 = 0
if b.Len() < 900 {
l, err := rand.Int(rand.Reader, big.NewInt(500))
if err != nil {
newError("failed to generate padding").Base(err).WriteToLog(session.ExportIDToError(ctx))
}
length = int32(l.Int64()) + 900 - b.Len()
}
newbuffer := buf.New()
if userUUID != nil {
newbuffer.Write(*userUUID)
*userUUID = nil
}
newbuffer.Write([]byte{command, byte(b.Len() >> 8), byte(b.Len()), byte(length >> 8), byte(length)})
newbuffer.Write(b.Bytes())
newbuffer.Extend(length)
newError("XtlsPadding ", b.Len(), " ", length, " ", command).WriteToLog(session.ExportIDToError(ctx))
b.Release()
b = nil
return newbuffer
}
// XtlsUnpadding remove padding and parse command
func XtlsUnpadding(ctx context.Context, buffer buf.MultiBuffer, userUUID []byte, remainingContent *int32, remainingPadding *int32, currentCommand *int) buf.MultiBuffer {
posindex := 0
var posByte int32 = 0
if *remainingContent == -1 && *remainingPadding == -1 {
for i, b := range buffer {
if b.Len() >= 21 && bytes.Equal(userUUID, b.BytesTo(16)) {
posindex = i
posByte = 16
*remainingContent = 0
*remainingPadding = 0
break
}
}
}
if *remainingContent == -1 && *remainingPadding == -1 {
return buffer
}
mb2 := make(buf.MultiBuffer, 0, len(buffer))
for i := 0; i < posindex; i++ {
newbuffer := buf.New()
newbuffer.Write(buffer[i].Bytes())
mb2 = append(mb2, newbuffer)
}
for i := posindex; i < len(buffer); i++ {
b := buffer[i]
for posByte < b.Len() {
if *remainingContent <= 0 && *remainingPadding <= 0 {
if *currentCommand == 1 { // possible buffer after padding, no need to worry about xtls (command 2)
len := b.Len() - posByte
newbuffer := buf.New()
newbuffer.Write(b.BytesRange(posByte, posByte+len))
mb2 = append(mb2, newbuffer)
posByte += len
} else {
paddingInfo := b.BytesRange(posByte, posByte+5)
*currentCommand = int(paddingInfo[0])
*remainingContent = int32(paddingInfo[1])<<8 | int32(paddingInfo[2])
*remainingPadding = int32(paddingInfo[3])<<8 | int32(paddingInfo[4])
newError("Xtls Unpadding new block", i, " ", posByte, " content ", *remainingContent, " padding ", *remainingPadding, " ", paddingInfo[0]).WriteToLog(session.ExportIDToError(ctx))
posByte += 5
}
} else if *remainingContent > 0 {
len := *remainingContent
if b.Len() < posByte+*remainingContent {
len = b.Len() - posByte
}
newbuffer := buf.New()
newbuffer.Write(b.BytesRange(posByte, posByte+len))
mb2 = append(mb2, newbuffer)
*remainingContent -= len
posByte += len
} else { // remainingPadding > 0
len := *remainingPadding
if b.Len() < posByte+*remainingPadding {
len = b.Len() - posByte
}
*remainingPadding -= len
posByte += len
}
if posByte == b.Len() {
posByte = 0
break
}
}
}
buf.ReleaseMulti(buffer)
return mb2
}
var 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",
}