Clash.Meta/component/ssr/protocol/auth_chain_a.go

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package protocol
import (
"bytes"
"crypto/aes"
"crypto/cipher"
"crypto/rc4"
"encoding/base64"
"encoding/binary"
"math/rand"
"strconv"
"strings"
"time"
"github.com/Dreamacro/clash/common/pool"
"github.com/Dreamacro/clash/component/ssr/tools"
"github.com/Dreamacro/go-shadowsocks2/core"
)
type authChain struct {
*Base
*recvInfo
*authData
randomClient shift128PlusContext
randomServer shift128PlusContext
enc cipher.Stream
dec cipher.Stream
headerSent bool
lastClientHash []byte
lastServerHash []byte
userKey []byte
uid [4]byte
salt string
hmac hmacMethod
hashDigest hashDigestMethod
rnd rndMethod
dataSizeList []int
dataSizeList2 []int
chunkID uint32
}
func init() {
register("auth_chain_a", newAuthChainA)
}
func newAuthChainA(b *Base) Protocol {
return &authChain{
Base: b,
authData: &authData{},
salt: "auth_chain_a",
hmac: tools.HmacMD5,
hashDigest: tools.SHA1Sum,
rnd: authChainAGetRandLen,
}
}
func (a *authChain) initForConn(iv []byte) Protocol {
r := &authChain{
Base: &Base{
IV: iv,
Key: a.Key,
TCPMss: a.TCPMss,
Overhead: a.Overhead,
Param: a.Param,
},
recvInfo: &recvInfo{recvID: 1, buffer: new(bytes.Buffer)},
authData: a.authData,
salt: a.salt,
hmac: a.hmac,
hashDigest: a.hashDigest,
rnd: a.rnd,
}
if r.salt == "auth_chain_b" {
initDataSize(r)
}
return r
}
func (a *authChain) GetProtocolOverhead() int {
return 4
}
func (a *authChain) SetOverhead(overhead int) {
a.Overhead = overhead
}
func (a *authChain) Decode(b []byte) ([]byte, int, error) {
a.buffer.Reset()
key := pool.Get(len(a.userKey) + 4)
defer pool.Put(key)
readSize := 0
copy(key, a.userKey)
for len(b) > 4 {
binary.LittleEndian.PutUint32(key[len(a.userKey):], a.recvID)
dataLen := (int)((uint(b[1]^a.lastServerHash[15]) << 8) + uint(b[0]^a.lastServerHash[14]))
randLen := a.getServerRandLen(dataLen, a.Overhead)
length := randLen + dataLen
if length >= 4096 {
return nil, 0, errAuthChainDataLengthError
}
length += 4
if length > len(b) {
break
}
hash := a.hmac(key, b[:length-2])
if !bytes.Equal(hash[:2], b[length-2:length]) {
return nil, 0, errAuthChainHMACError
}
var dataPos int
if dataLen > 0 && randLen > 0 {
dataPos = 2 + getRandStartPos(&a.randomServer, randLen)
} else {
dataPos = 2
}
d := pool.Get(dataLen)
a.dec.XORKeyStream(d, b[dataPos:dataPos+dataLen])
a.buffer.Write(d)
pool.Put(d)
if a.recvID == 1 {
a.TCPMss = int(binary.LittleEndian.Uint16(a.buffer.Next(2)))
}
a.lastServerHash = hash
a.recvID++
b = b[length:]
readSize += length
}
return a.buffer.Bytes(), readSize, nil
}
func (a *authChain) Encode(b []byte) ([]byte, error) {
a.buffer.Reset()
bSize := len(b)
offset := 0
if bSize > 0 && !a.headerSent {
headSize := 1200
if headSize > bSize {
headSize = bSize
}
a.buffer.Write(a.packAuthData(b[:headSize]))
offset += headSize
bSize -= headSize
a.headerSent = true
}
var unitSize = a.TCPMss - a.Overhead
for bSize > unitSize {
dataLen, randLength := a.packedDataLen(b[offset : offset+unitSize])
d := pool.Get(dataLen)
a.packData(d, b[offset:offset+unitSize], randLength)
a.buffer.Write(d)
pool.Put(d)
bSize -= unitSize
offset += unitSize
}
if bSize > 0 {
dataLen, randLength := a.packedDataLen(b[offset:])
d := pool.Get(dataLen)
a.packData(d, b[offset:], randLength)
a.buffer.Write(d)
pool.Put(d)
}
return a.buffer.Bytes(), nil
}
func (a *authChain) DecodePacket(b []byte) ([]byte, int, error) {
bSize := len(b)
if bSize < 9 {
return nil, 0, errAuthChainDataLengthError
}
h := a.hmac(a.userKey, b[:bSize-1])
if h[0] != b[bSize-1] {
return nil, 0, errAuthChainHMACError
}
hash := a.hmac(a.Key, b[bSize-8:bSize-1])
cipherKey := a.getRC4CipherKey(hash)
dec, _ := rc4.NewCipher(cipherKey)
randLength := udpGetRandLen(&a.randomServer, hash)
bSize -= 8 + randLength
dec.XORKeyStream(b, b[:bSize])
return b, bSize, nil
}
func (a *authChain) EncodePacket(b []byte) ([]byte, error) {
a.initUserKeyAndID()
authData := pool.Get(3)
defer pool.Put(authData)
rand.Read(authData)
hash := a.hmac(a.Key, authData)
uid := pool.Get(4)
defer pool.Put(uid)
for i := 0; i < 4; i++ {
uid[i] = a.uid[i] ^ hash[i]
}
cipherKey := a.getRC4CipherKey(hash)
enc, _ := rc4.NewCipher(cipherKey)
var buf bytes.Buffer
enc.XORKeyStream(b, b)
buf.Write(b)
randLength := udpGetRandLen(&a.randomClient, hash)
randBytes := pool.Get(randLength)
defer pool.Put(randBytes)
buf.Write(randBytes)
buf.Write(authData)
buf.Write(uid)
h := a.hmac(a.userKey, buf.Bytes())
buf.Write(h[:1])
return buf.Bytes(), nil
}
func (a *authChain) getRC4CipherKey(hash []byte) []byte {
base64UserKey := base64.StdEncoding.EncodeToString(a.userKey)
return a.calcRC4CipherKey(hash, base64UserKey)
}
func (a *authChain) calcRC4CipherKey(hash []byte, base64UserKey string) []byte {
password := pool.Get(len(base64UserKey) + base64.StdEncoding.EncodedLen(16))
defer pool.Put(password)
copy(password, base64UserKey)
base64.StdEncoding.Encode(password[len(base64UserKey):], hash[:16])
return core.Kdf(string(password), 16)
}
func (a *authChain) initUserKeyAndID() {
if a.userKey == nil {
params := strings.Split(a.Param, ":")
if len(params) >= 2 {
if userID, err := strconv.ParseUint(params[0], 10, 32); err == nil {
binary.LittleEndian.PutUint32(a.uid[:], uint32(userID))
a.userKey = []byte(params[1])
}
}
if a.userKey == nil {
rand.Read(a.uid[:])
a.userKey = make([]byte, len(a.Key))
copy(a.userKey, a.Key)
}
}
}
func (a *authChain) getClientRandLen(dataLength int, overhead int) int {
return a.rnd(dataLength, &a.randomClient, a.lastClientHash, a.dataSizeList, a.dataSizeList2, overhead)
}
func (a *authChain) getServerRandLen(dataLength int, overhead int) int {
return a.rnd(dataLength, &a.randomServer, a.lastServerHash, a.dataSizeList, a.dataSizeList2, overhead)
}
func (a *authChain) packedDataLen(data []byte) (chunkLength, randLength int) {
dataLength := len(data)
randLength = a.getClientRandLen(dataLength, a.Overhead)
chunkLength = randLength + dataLength + 2 + 2
return
}
func (a *authChain) packData(outData []byte, data []byte, randLength int) {
dataLength := len(data)
outLength := randLength + dataLength + 2
outData[0] = byte(dataLength) ^ a.lastClientHash[14]
outData[1] = byte(dataLength>>8) ^ a.lastClientHash[15]
{
if dataLength > 0 {
randPart1Length := getRandStartPos(&a.randomClient, randLength)
rand.Read(outData[2 : 2+randPart1Length])
a.enc.XORKeyStream(outData[2+randPart1Length:], data)
rand.Read(outData[2+randPart1Length+dataLength : outLength])
} else {
rand.Read(outData[2 : 2+randLength])
}
}
userKeyLen := uint8(len(a.userKey))
key := pool.Get(int(userKeyLen + 4))
defer pool.Put(key)
copy(key, a.userKey)
a.chunkID++
binary.LittleEndian.PutUint32(key[userKeyLen:], a.chunkID)
a.lastClientHash = a.hmac(key, outData[:outLength])
copy(outData[outLength:], a.lastClientHash[:2])
}
const authHeadLength = 4 + 8 + 4 + 16 + 4
func (a *authChain) packAuthData(data []byte) (outData []byte) {
outData = make([]byte, authHeadLength, authHeadLength+1500)
a.mutex.Lock()
defer a.mutex.Unlock()
a.connectionID++
if a.connectionID > 0xFF000000 {
a.clientID = nil
}
if len(a.clientID) == 0 {
a.clientID = make([]byte, 4)
rand.Read(a.clientID)
b := make([]byte, 4)
rand.Read(b)
a.connectionID = binary.LittleEndian.Uint32(b) & 0xFFFFFF
}
var key = make([]byte, len(a.IV)+len(a.Key))
copy(key, a.IV)
copy(key[len(a.IV):], a.Key)
encrypt := make([]byte, 20)
t := time.Now().Unix()
binary.LittleEndian.PutUint32(encrypt[:4], uint32(t))
copy(encrypt[4:8], a.clientID)
binary.LittleEndian.PutUint32(encrypt[8:], a.connectionID)
binary.LittleEndian.PutUint16(encrypt[12:], uint16(a.Overhead))
binary.LittleEndian.PutUint16(encrypt[14:], 0)
// first 12 bytes
{
rand.Read(outData[:4])
a.lastClientHash = a.hmac(key, outData[:4])
copy(outData[4:], a.lastClientHash[:8])
}
var base64UserKey string
// uid & 16 bytes auth data
{
a.initUserKeyAndID()
uid := make([]byte, 4)
for i := 0; i < 4; i++ {
uid[i] = a.uid[i] ^ a.lastClientHash[8+i]
}
base64UserKey = base64.StdEncoding.EncodeToString(a.userKey)
aesCipherKey := core.Kdf(base64UserKey+a.salt, 16)
block, err := aes.NewCipher(aesCipherKey)
if err != nil {
return
}
encryptData := make([]byte, 16)
iv := make([]byte, aes.BlockSize)
cbc := cipher.NewCBCEncrypter(block, iv)
cbc.CryptBlocks(encryptData, encrypt[:16])
copy(encrypt[:4], uid[:])
copy(encrypt[4:4+16], encryptData)
}
// final HMAC
{
a.lastServerHash = a.hmac(a.userKey, encrypt[:20])
copy(outData[12:], encrypt)
copy(outData[12+20:], a.lastServerHash[:4])
}
// init cipher
cipherKey := a.calcRC4CipherKey(a.lastClientHash, base64UserKey)
a.enc, _ = rc4.NewCipher(cipherKey)
a.dec, _ = rc4.NewCipher(cipherKey)
// data
chunkLength, randLength := a.packedDataLen(data)
if chunkLength+authHeadLength <= cap(outData) {
outData = outData[:authHeadLength+chunkLength]
} else {
newOutData := make([]byte, authHeadLength+chunkLength)
copy(newOutData, outData[:authHeadLength])
outData = newOutData
}
a.packData(outData[authHeadLength:], data, randLength)
return
}
func getRandStartPos(random *shift128PlusContext, randLength int) int {
if randLength > 0 {
return int(random.Next() % 8589934609 % uint64(randLength))
}
return 0
}
func authChainAGetRandLen(dataLength int, random *shift128PlusContext, lastHash []byte, dataSizeList, dataSizeList2 []int, overhead int) int {
if dataLength > 1440 {
return 0
}
random.InitFromBinDatalen(lastHash[:16], dataLength)
if dataLength > 1300 {
return int(random.Next() % 31)
}
if dataLength > 900 {
return int(random.Next() % 127)
}
if dataLength > 400 {
return int(random.Next() % 521)
}
return int(random.Next() % 1021)
}
func udpGetRandLen(random *shift128PlusContext, lastHash []byte) int {
random.InitFromBin(lastHash[:16])
return int(random.Next() % 127)
}
type shift128PlusContext struct {
v [2]uint64
}
func (ctx *shift128PlusContext) InitFromBin(bin []byte) {
var fillBin [16]byte
copy(fillBin[:], bin)
ctx.v[0] = binary.LittleEndian.Uint64(fillBin[:8])
ctx.v[1] = binary.LittleEndian.Uint64(fillBin[8:])
}
func (ctx *shift128PlusContext) InitFromBinDatalen(bin []byte, datalen int) {
var fillBin [16]byte
copy(fillBin[:], bin)
binary.LittleEndian.PutUint16(fillBin[:2], uint16(datalen))
ctx.v[0] = binary.LittleEndian.Uint64(fillBin[:8])
ctx.v[1] = binary.LittleEndian.Uint64(fillBin[8:])
for i := 0; i < 4; i++ {
ctx.Next()
}
}
func (ctx *shift128PlusContext) Next() uint64 {
x := ctx.v[0]
y := ctx.v[1]
ctx.v[0] = y
x ^= x << 23
x ^= y ^ (x >> 17) ^ (y >> 26)
ctx.v[1] = x
return x + y
}