mihomo/component/ssr/protocol/auth_sha1_v4.go

254 lines
6.0 KiB
Go

package protocol
import (
"bytes"
"encoding/binary"
"hash/adler32"
"hash/crc32"
"math/rand"
"time"
"github.com/Dreamacro/clash/common/pool"
"github.com/Dreamacro/clash/component/ssr/tools"
)
type authSHA1V4 struct {
*Base
*authData
headerSent bool
buffer bytes.Buffer
}
func init() {
register("auth_sha1_v4", newAuthSHA1V4)
}
func newAuthSHA1V4(b *Base) Protocol {
return &authSHA1V4{Base: b, authData: &authData{}}
}
func (a *authSHA1V4) initForConn(iv []byte) Protocol {
return &authSHA1V4{
Base: &Base{
IV: iv,
Key: a.Key,
TCPMss: a.TCPMss,
Overhead: a.Overhead,
Param: a.Param,
},
authData: a.authData,
}
}
func (a *authSHA1V4) GetProtocolOverhead() int {
return 7
}
func (a *authSHA1V4) SetOverhead(overhead int) {
a.Overhead = overhead
}
func (a *authSHA1V4) Decode(b []byte) ([]byte, int, error) {
a.buffer.Reset()
bSize := len(b)
originalSize := bSize
for bSize > 4 {
crc := crc32.ChecksumIEEE(b[:2]) & 0xFFFF
if binary.LittleEndian.Uint16(b[2:4]) != uint16(crc) {
return nil, 0, errAuthSHA1v4CRC32Error
}
length := int(binary.BigEndian.Uint16(b[:2]))
if length >= 8192 || length < 8 {
return nil, 0, errAuthSHA1v4DataLengthError
}
if length > bSize {
break
}
if adler32.Checksum(b[:length-4]) == binary.LittleEndian.Uint32(b[length-4:]) {
pos := int(b[4])
if pos != 0xFF {
pos += 4
} else {
pos = int(binary.BigEndian.Uint16(b[5:5+2])) + 4
}
retSize := length - pos - 4
a.buffer.Write(b[pos : pos+retSize])
bSize -= length
b = b[length:]
} else {
return nil, 0, errAuthSHA1v4IncorrectChecksum
}
}
return a.buffer.Bytes(), originalSize - bSize, nil
}
func (a *authSHA1V4) Encode(b []byte) ([]byte, error) {
a.buffer.Reset()
bSize := len(b)
offset := 0
if !a.headerSent && bSize > 0 {
headSize := getHeadSize(b, 30)
if headSize > bSize {
headSize = bSize
}
a.buffer.Write(a.packAuthData(b[:headSize]))
offset += headSize
bSize -= headSize
a.headerSent = true
}
const blockSize = 4096
for bSize > blockSize {
packSize, randSize := a.packedDataSize(b[offset : offset+blockSize])
pack := pool.Get(packSize)
a.packData(b[offset:offset+blockSize], pack, randSize)
a.buffer.Write(pack)
pool.Put(pack)
offset += blockSize
bSize -= blockSize
}
if bSize > 0 {
packSize, randSize := a.packedDataSize(b[offset:])
pack := pool.Get(packSize)
a.packData(b[offset:], pack, randSize)
a.buffer.Write(pack)
pool.Put(pack)
}
return a.buffer.Bytes(), nil
}
func (a *authSHA1V4) DecodePacket(b []byte) ([]byte, int, error) {
return b, len(b), nil
}
func (a *authSHA1V4) EncodePacket(b []byte) ([]byte, error) {
return b, nil
}
func (a *authSHA1V4) packedDataSize(data []byte) (packSize, randSize int) {
dataSize := len(data)
randSize = 1
if dataSize <= 1300 {
if dataSize > 400 {
randSize += rand.Intn(128)
} else {
randSize += rand.Intn(1024)
}
}
packSize = randSize + dataSize + 8
return
}
func (a *authSHA1V4) packData(data, ret []byte, randSize int) {
dataSize := len(data)
retSize := len(ret)
// 0~1, ret size
binary.BigEndian.PutUint16(ret[:2], uint16(retSize&0xFFFF))
// 2~3, crc of ret size
crc := crc32.ChecksumIEEE(ret[:2]) & 0xFFFF
binary.LittleEndian.PutUint16(ret[2:4], uint16(crc))
// 4, rand size
if randSize < 128 {
ret[4] = uint8(randSize & 0xFF)
} else {
ret[4] = uint8(0xFF)
binary.BigEndian.PutUint16(ret[5:7], uint16(randSize&0xFFFF))
}
// (rand size+4)~(ret size-4), data
if dataSize > 0 {
copy(ret[randSize+4:], data)
}
// (ret size-4)~end, adler32 of full data
adler := adler32.Checksum(ret[:retSize-4])
binary.LittleEndian.PutUint32(ret[retSize-4:], adler)
}
func (a *authSHA1V4) packAuthData(data []byte) (ret []byte) {
dataSize := len(data)
randSize := 1
if dataSize <= 1300 {
if dataSize > 400 {
randSize += rand.Intn(128)
} else {
randSize += rand.Intn(1024)
}
}
dataOffset := randSize + 4 + 2
retSize := dataOffset + dataSize + 12 + tools.HmacSHA1Len
ret = make([]byte, retSize)
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, 8)
rand.Read(a.clientID)
b := make([]byte, 4)
rand.Read(b)
a.connectionID = binary.LittleEndian.Uint32(b) & 0xFFFFFF
}
// 0~1, ret size
binary.BigEndian.PutUint16(ret[:2], uint16(retSize&0xFFFF))
// 2~6, crc of (ret size+salt+key)
salt := []byte("auth_sha1_v4")
crcData := make([]byte, len(salt)+len(a.Key)+2)
copy(crcData[:2], ret[:2])
copy(crcData[2:], salt)
copy(crcData[2+len(salt):], a.Key)
crc := crc32.ChecksumIEEE(crcData) & 0xFFFFFFFF
// 2~6, crc of (ret size+salt+key)
binary.LittleEndian.PutUint32(ret[2:], crc)
// 6~(rand size+6), rand numbers
rand.Read(ret[dataOffset-randSize : dataOffset])
// 6, rand size
if randSize < 128 {
ret[6] = byte(randSize & 0xFF)
} else {
// 6, magic number 0xFF
ret[6] = 0xFF
// 7~8, rand size
binary.BigEndian.PutUint16(ret[7:9], uint16(randSize&0xFFFF))
}
// rand size+6~(rand size+10), time stamp
now := time.Now().Unix()
binary.LittleEndian.PutUint32(ret[dataOffset:dataOffset+4], uint32(now))
// rand size+10~(rand size+14), client ID
copy(ret[dataOffset+4:dataOffset+4+4], a.clientID[:4])
// rand size+14~(rand size+18), connection ID
binary.LittleEndian.PutUint32(ret[dataOffset+8:dataOffset+8+4], a.connectionID)
// rand size+18~(rand size+18)+data length, data
copy(ret[dataOffset+12:], data)
key := make([]byte, len(a.IV)+len(a.Key))
copy(key, a.IV)
copy(key[len(a.IV):], a.Key)
h := tools.HmacSHA1(key, ret[:retSize-tools.HmacSHA1Len])
// (ret size-10)~(ret size)/(rand size)+18+data length~end, hmac
copy(ret[retSize-tools.HmacSHA1Len:], h[:tools.HmacSHA1Len])
return ret
}
func getHeadSize(data []byte, defaultValue int) int {
if data == nil || len(data) < 2 {
return defaultValue
}
headType := data[0] & 0x07
switch headType {
case 1:
// IPv4 1+4+2
return 7
case 4:
// IPv6 1+16+2
return 19
case 3:
// domain name, variant length
return 4 + int(data[1])
}
return defaultValue
}