Xray-core/proxy/shadowsocks/protocol.go

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package shadowsocks
import (
"crypto/cipher"
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"crypto/hmac"
"crypto/rand"
"crypto/sha256"
"hash/crc32"
"io"
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"github.com/xtls/xray-core/common"
"github.com/xtls/xray-core/common/buf"
"github.com/xtls/xray-core/common/crypto"
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"github.com/xtls/xray-core/common/dice"
"github.com/xtls/xray-core/common/net"
"github.com/xtls/xray-core/common/protocol"
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)
const (
Version = 1
)
var addrParser = protocol.NewAddressParser(
protocol.AddressFamilyByte(0x01, net.AddressFamilyIPv4),
protocol.AddressFamilyByte(0x04, net.AddressFamilyIPv6),
protocol.AddressFamilyByte(0x03, net.AddressFamilyDomain),
protocol.WithAddressTypeParser(func(b byte) byte {
return b & 0x0F
}),
)
type FullReader struct {
reader io.Reader
buffer []byte
}
func (r *FullReader) Read(p []byte) (n int, err error) {
if r.buffer != nil {
n := copy(p, r.buffer)
if n == len(r.buffer) {
r.buffer = nil
} else {
r.buffer = r.buffer[n:]
}
if n == len(p) {
return n, nil
} else {
m, err := r.reader.Read(p[n:])
return n + m, err
}
}
return r.reader.Read(p)
}
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// ReadTCPSession reads a Shadowsocks TCP session from the given reader, returns its header and remaining parts.
func ReadTCPSession(validator *Validator, reader io.Reader) (*protocol.RequestHeader, buf.Reader, error) {
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hashkdf := hmac.New(sha256.New, []byte("SSBSKDF"))
behaviorSeed := crc32.ChecksumIEEE(hashkdf.Sum(nil))
behaviorRand := dice.NewDeterministicDice(int64(behaviorSeed))
BaseDrainSize := behaviorRand.Roll(3266)
RandDrainMax := behaviorRand.Roll(64) + 1
RandDrainRolled := dice.Roll(RandDrainMax)
DrainSize := BaseDrainSize + 16 + 38 + RandDrainRolled
readSizeRemain := DrainSize
var r2 buf.Reader
buffer := buf.New()
defer buffer.Release()
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var user *protocol.MemoryUser
var ivLen int32
var iv []byte
var err error
count := validator.Count()
if count == 0 {
readSizeRemain -= int(buffer.Len())
DrainConnN(reader, readSizeRemain)
return nil, nil, newError("invalid user")
} else if count > 1 {
var aead cipher.AEAD
if _, err := buffer.ReadFullFrom(reader, 50); err != nil {
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readSizeRemain -= int(buffer.Len())
DrainConnN(reader, readSizeRemain)
return nil, nil, newError("failed to read 50 bytes").Base(err)
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}
bs := buffer.Bytes()
user, aead, _, ivLen, err = validator.Get(bs, protocol.RequestCommandTCP)
if user != nil {
if ivLen > 0 {
iv = append([]byte(nil), bs[:ivLen]...)
}
reader = &FullReader{reader, bs[ivLen:]}
auth := &crypto.AEADAuthenticator{
AEAD: aead,
NonceGenerator: crypto.GenerateInitialAEADNonce(),
}
r2 = crypto.NewAuthenticationReader(auth, &crypto.AEADChunkSizeParser{
Auth: auth,
}, reader, protocol.TransferTypeStream, nil)
} else {
readSizeRemain -= int(buffer.Len())
DrainConnN(reader, readSizeRemain)
return nil, nil, newError("failed to match an user").Base(err)
}
} else {
user, ivLen = validator.GetOnlyUser()
account := user.Account.(*MemoryAccount)
hashkdf.Write(account.Key)
if ivLen > 0 {
if _, err := buffer.ReadFullFrom(reader, ivLen); err != nil {
readSizeRemain -= int(buffer.Len())
DrainConnN(reader, readSizeRemain)
return nil, nil, newError("failed to read IV").Base(err)
}
iv = append([]byte(nil), buffer.BytesTo(ivLen)...)
}
r, err := account.Cipher.NewDecryptionReader(account.Key, iv, reader)
if err != nil {
readSizeRemain -= int(buffer.Len())
DrainConnN(reader, readSizeRemain)
return nil, nil, newError("failed to initialize decoding stream").Base(err).AtError()
}
r2 = r
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}
br := &buf.BufferedReader{Reader: r2}
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request := &protocol.RequestHeader{
Version: Version,
User: user,
Command: protocol.RequestCommandTCP,
}
readSizeRemain -= int(buffer.Len())
buffer.Clear()
addr, port, err := addrParser.ReadAddressPort(buffer, br)
if err != nil {
readSizeRemain -= int(buffer.Len())
DrainConnN(reader, readSizeRemain)
return nil, nil, newError("failed to read address").Base(err)
}
request.Address = addr
request.Port = port
if request.Address == nil {
readSizeRemain -= int(buffer.Len())
DrainConnN(reader, readSizeRemain)
return nil, nil, newError("invalid remote address.")
}
account := user.Account.(*MemoryAccount)
if ivError := account.CheckIV(iv); ivError != nil {
readSizeRemain -= int(buffer.Len())
DrainConnN(reader, readSizeRemain)
return nil, nil, newError("failed iv check").Base(ivError)
}
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return request, br, nil
}
func DrainConnN(reader io.Reader, n int) error {
_, err := io.CopyN(io.Discard, reader, int64(n))
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return err
}
// WriteTCPRequest writes Shadowsocks request into the given writer, and returns a writer for body.
func WriteTCPRequest(request *protocol.RequestHeader, writer io.Writer) (buf.Writer, error) {
user := request.User
account := user.Account.(*MemoryAccount)
var iv []byte
if account.Cipher.IVSize() > 0 {
iv = make([]byte, account.Cipher.IVSize())
common.Must2(rand.Read(iv))
if ivError := account.CheckIV(iv); ivError != nil {
return nil, newError("failed to mark outgoing iv").Base(ivError)
}
if err := buf.WriteAllBytes(writer, iv, nil); err != nil {
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return nil, newError("failed to write IV")
}
}
w, err := account.Cipher.NewEncryptionWriter(account.Key, iv, writer)
if err != nil {
return nil, newError("failed to create encoding stream").Base(err).AtError()
}
header := buf.New()
if err := addrParser.WriteAddressPort(header, request.Address, request.Port); err != nil {
return nil, newError("failed to write address").Base(err)
}
if err := w.WriteMultiBuffer(buf.MultiBuffer{header}); err != nil {
return nil, newError("failed to write header").Base(err)
}
return w, nil
}
func ReadTCPResponse(user *protocol.MemoryUser, reader io.Reader) (buf.Reader, error) {
account := user.Account.(*MemoryAccount)
var iv []byte
if account.Cipher.IVSize() > 0 {
iv = make([]byte, account.Cipher.IVSize())
if _, err := io.ReadFull(reader, iv); err != nil {
return nil, newError("failed to read IV").Base(err)
}
}
if ivError := account.CheckIV(iv); ivError != nil {
return nil, newError("failed iv check").Base(ivError)
}
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return account.Cipher.NewDecryptionReader(account.Key, iv, reader)
}
func WriteTCPResponse(request *protocol.RequestHeader, writer io.Writer) (buf.Writer, error) {
user := request.User
account := user.Account.(*MemoryAccount)
var iv []byte
if account.Cipher.IVSize() > 0 {
iv = make([]byte, account.Cipher.IVSize())
common.Must2(rand.Read(iv))
if ivError := account.CheckIV(iv); ivError != nil {
return nil, newError("failed to mark outgoing iv").Base(ivError)
}
if err := buf.WriteAllBytes(writer, iv, nil); err != nil {
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return nil, newError("failed to write IV.").Base(err)
}
}
return account.Cipher.NewEncryptionWriter(account.Key, iv, writer)
}
func EncodeUDPPacket(request *protocol.RequestHeader, payload []byte) (*buf.Buffer, error) {
user := request.User
account := user.Account.(*MemoryAccount)
buffer := buf.New()
ivLen := account.Cipher.IVSize()
if ivLen > 0 {
common.Must2(buffer.ReadFullFrom(rand.Reader, ivLen))
}
if err := addrParser.WriteAddressPort(buffer, request.Address, request.Port); err != nil {
return nil, newError("failed to write address").Base(err)
}
buffer.Write(payload)
if err := account.Cipher.EncodePacket(account.Key, buffer); err != nil {
return nil, newError("failed to encrypt UDP payload").Base(err)
}
return buffer, nil
}
func DecodeUDPPacket(validator *Validator, payload *buf.Buffer) (*protocol.RequestHeader, *buf.Buffer, error) {
bs := payload.Bytes()
if len(bs) <= 32 {
return nil, nil, newError("len(bs) <= 32")
}
var user *protocol.MemoryUser
var err error
count := validator.Count()
if count == 0 {
return nil, nil, newError("invalid user")
} else if count > 1 {
var d []byte
user, _, d, _, err = validator.Get(bs, protocol.RequestCommandUDP)
if user != nil {
payload.Clear()
payload.Write(d)
} else {
return nil, nil, newError("failed to decrypt UDP payload").Base(err)
}
} else {
user, _ = validator.GetOnlyUser()
account := user.Account.(*MemoryAccount)
var iv []byte
if !account.Cipher.IsAEAD() && account.Cipher.IVSize() > 0 {
// Keep track of IV as it gets removed from payload in DecodePacket.
iv = make([]byte, account.Cipher.IVSize())
copy(iv, payload.BytesTo(account.Cipher.IVSize()))
}
if err = account.Cipher.DecodePacket(account.Key, payload); err != nil {
return nil, nil, newError("failed to decrypt UDP payload").Base(err)
}
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}
request := &protocol.RequestHeader{
Version: Version,
User: user,
Command: protocol.RequestCommandUDP,
}
payload.SetByte(0, payload.Byte(0)&0x0F)
addr, port, err := addrParser.ReadAddressPort(nil, payload)
if err != nil {
return nil, nil, newError("failed to parse address").Base(err)
}
request.Address = addr
request.Port = port
return request, payload, nil
}
type UDPReader struct {
Reader io.Reader
User *protocol.MemoryUser
}
func (v *UDPReader) ReadMultiBuffer() (buf.MultiBuffer, error) {
buffer := buf.New()
_, err := buffer.ReadFrom(v.Reader)
if err != nil {
buffer.Release()
return nil, err
}
validator := new(Validator)
validator.Add(v.User)
u, payload, err := DecodeUDPPacket(validator, buffer)
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if err != nil {
buffer.Release()
return nil, err
}
dest := u.Destination()
payload.UDP = &dest
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return buf.MultiBuffer{payload}, nil
}
type UDPWriter struct {
Writer io.Writer
Request *protocol.RequestHeader
}
func (w *UDPWriter) WriteMultiBuffer(mb buf.MultiBuffer) error {
for {
mb2, b := buf.SplitFirst(mb)
mb = mb2
if b == nil {
break
}
request := w.Request
if b.UDP != nil {
request = &protocol.RequestHeader{
User: w.Request.User,
Address: b.UDP.Address,
Port: b.UDP.Port,
}
}
packet, err := EncodeUDPPacket(request, b.Bytes())
b.Release()
if err != nil {
buf.ReleaseMulti(mb)
return err
}
_, err = w.Writer.Write(packet.Bytes())
packet.Release()
if err != nil {
buf.ReleaseMulti(mb)
return err
}
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}
return nil
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}