package encoding import ( "bytes" "context" "crypto/aes" "crypto/cipher" "crypto/md5" "crypto/rand" "crypto/sha256" "encoding/binary" "hash" "hash/fnv" "io" "golang.org/x/crypto/chacha20poly1305" "github.com/xtls/xray-core/common" "github.com/xtls/xray-core/common/bitmask" "github.com/xtls/xray-core/common/buf" "github.com/xtls/xray-core/common/crypto" "github.com/xtls/xray-core/common/dice" "github.com/xtls/xray-core/common/protocol" "github.com/xtls/xray-core/common/serial" "github.com/xtls/xray-core/proxy/vmess" vmessaead "github.com/xtls/xray-core/proxy/vmess/aead" ) func hashTimestamp(h hash.Hash, t protocol.Timestamp) []byte { common.Must2(serial.WriteUint64(h, uint64(t))) common.Must2(serial.WriteUint64(h, uint64(t))) common.Must2(serial.WriteUint64(h, uint64(t))) common.Must2(serial.WriteUint64(h, uint64(t))) return h.Sum(nil) } // ClientSession stores connection session info for VMess client. type ClientSession struct { isAEAD bool idHash protocol.IDHash requestBodyKey [16]byte requestBodyIV [16]byte responseBodyKey [16]byte responseBodyIV [16]byte responseReader io.Reader responseHeader byte } // NewClientSession creates a new ClientSession. func NewClientSession(ctx context.Context, isAEAD bool, idHash protocol.IDHash) *ClientSession { session := &ClientSession{ isAEAD: isAEAD, idHash: idHash, } randomBytes := make([]byte, 33) // 16 + 16 + 1 common.Must2(rand.Read(randomBytes)) copy(session.requestBodyKey[:], randomBytes[:16]) copy(session.requestBodyIV[:], randomBytes[16:32]) session.responseHeader = randomBytes[32] if !session.isAEAD { session.responseBodyKey = md5.Sum(session.requestBodyKey[:]) session.responseBodyIV = md5.Sum(session.requestBodyIV[:]) } else { BodyKey := sha256.Sum256(session.requestBodyKey[:]) copy(session.responseBodyKey[:], BodyKey[:16]) BodyIV := sha256.Sum256(session.requestBodyIV[:]) copy(session.responseBodyIV[:], BodyIV[:16]) } return session } func (c *ClientSession) EncodeRequestHeader(header *protocol.RequestHeader, writer io.Writer) error { timestamp := protocol.NewTimestampGenerator(protocol.NowTime(), 30)() account := header.User.Account.(*vmess.MemoryAccount) if !c.isAEAD { idHash := c.idHash(account.AnyValidID().Bytes()) common.Must2(serial.WriteUint64(idHash, uint64(timestamp))) common.Must2(writer.Write(idHash.Sum(nil))) } buffer := buf.New() defer buffer.Release() common.Must(buffer.WriteByte(Version)) common.Must2(buffer.Write(c.requestBodyIV[:])) common.Must2(buffer.Write(c.requestBodyKey[:])) common.Must(buffer.WriteByte(c.responseHeader)) common.Must(buffer.WriteByte(byte(header.Option))) paddingLen := dice.Roll(16) security := byte(paddingLen<<4) | byte(header.Security) common.Must2(buffer.Write([]byte{security, byte(0), byte(header.Command)})) if header.Command != protocol.RequestCommandMux { if err := addrParser.WriteAddressPort(buffer, header.Address, header.Port); err != nil { return newError("failed to writer address and port").Base(err) } } if paddingLen > 0 { common.Must2(buffer.ReadFullFrom(rand.Reader, int32(paddingLen))) } { fnv1a := fnv.New32a() common.Must2(fnv1a.Write(buffer.Bytes())) hashBytes := buffer.Extend(int32(fnv1a.Size())) fnv1a.Sum(hashBytes[:0]) } if !c.isAEAD { iv := hashTimestamp(md5.New(), timestamp) aesStream := crypto.NewAesEncryptionStream(account.ID.CmdKey(), iv) aesStream.XORKeyStream(buffer.Bytes(), buffer.Bytes()) common.Must2(writer.Write(buffer.Bytes())) } else { var fixedLengthCmdKey [16]byte copy(fixedLengthCmdKey[:], account.ID.CmdKey()) vmessout := vmessaead.SealVMessAEADHeader(fixedLengthCmdKey, buffer.Bytes()) common.Must2(io.Copy(writer, bytes.NewReader(vmessout))) } return nil } func (c *ClientSession) EncodeRequestBody(request *protocol.RequestHeader, writer io.Writer) buf.Writer { var sizeParser crypto.ChunkSizeEncoder = crypto.PlainChunkSizeParser{} if request.Option.Has(protocol.RequestOptionChunkMasking) { sizeParser = NewShakeSizeParser(c.requestBodyIV[:]) } var padding crypto.PaddingLengthGenerator if request.Option.Has(protocol.RequestOptionGlobalPadding) { padding = sizeParser.(crypto.PaddingLengthGenerator) } switch request.Security { case protocol.SecurityType_NONE: if request.Option.Has(protocol.RequestOptionChunkStream) { if request.Command.TransferType() == protocol.TransferTypeStream { return crypto.NewChunkStreamWriter(sizeParser, writer) } auth := &crypto.AEADAuthenticator{ AEAD: new(NoOpAuthenticator), NonceGenerator: crypto.GenerateEmptyBytes(), AdditionalDataGenerator: crypto.GenerateEmptyBytes(), } return crypto.NewAuthenticationWriter(auth, sizeParser, writer, protocol.TransferTypePacket, padding) } return buf.NewWriter(writer) case protocol.SecurityType_LEGACY: aesStream := crypto.NewAesEncryptionStream(c.requestBodyKey[:], c.requestBodyIV[:]) cryptionWriter := crypto.NewCryptionWriter(aesStream, writer) if request.Option.Has(protocol.RequestOptionChunkStream) { auth := &crypto.AEADAuthenticator{ AEAD: new(FnvAuthenticator), NonceGenerator: crypto.GenerateEmptyBytes(), AdditionalDataGenerator: crypto.GenerateEmptyBytes(), } return crypto.NewAuthenticationWriter(auth, sizeParser, cryptionWriter, request.Command.TransferType(), padding) } return &buf.SequentialWriter{Writer: cryptionWriter} case protocol.SecurityType_AES128_GCM: aead := crypto.NewAesGcm(c.requestBodyKey[:]) auth := &crypto.AEADAuthenticator{ AEAD: aead, NonceGenerator: GenerateChunkNonce(c.requestBodyIV[:], uint32(aead.NonceSize())), AdditionalDataGenerator: crypto.GenerateEmptyBytes(), } return crypto.NewAuthenticationWriter(auth, sizeParser, writer, request.Command.TransferType(), padding) case protocol.SecurityType_CHACHA20_POLY1305: aead, err := chacha20poly1305.New(GenerateChacha20Poly1305Key(c.requestBodyKey[:])) common.Must(err) auth := &crypto.AEADAuthenticator{ AEAD: aead, NonceGenerator: GenerateChunkNonce(c.requestBodyIV[:], uint32(aead.NonceSize())), AdditionalDataGenerator: crypto.GenerateEmptyBytes(), } return crypto.NewAuthenticationWriter(auth, sizeParser, writer, request.Command.TransferType(), padding) default: panic("Unknown security type.") } } func (c *ClientSession) DecodeResponseHeader(reader io.Reader) (*protocol.ResponseHeader, error) { if !c.isAEAD { aesStream := crypto.NewAesDecryptionStream(c.responseBodyKey[:], c.responseBodyIV[:]) c.responseReader = crypto.NewCryptionReader(aesStream, reader) } else { aeadResponseHeaderLengthEncryptionKey := vmessaead.KDF16(c.responseBodyKey[:], vmessaead.KDFSaltConstAEADRespHeaderLenKey) aeadResponseHeaderLengthEncryptionIV := vmessaead.KDF(c.responseBodyIV[:], vmessaead.KDFSaltConstAEADRespHeaderLenIV)[:12] aeadResponseHeaderLengthEncryptionKeyAESBlock := common.Must2(aes.NewCipher(aeadResponseHeaderLengthEncryptionKey)).(cipher.Block) aeadResponseHeaderLengthEncryptionAEAD := common.Must2(cipher.NewGCM(aeadResponseHeaderLengthEncryptionKeyAESBlock)).(cipher.AEAD) var aeadEncryptedResponseHeaderLength [18]byte var decryptedResponseHeaderLength int var decryptedResponseHeaderLengthBinaryDeserializeBuffer uint16 if _, err := io.ReadFull(reader, aeadEncryptedResponseHeaderLength[:]); err != nil { return nil, newError("Unable to Read Header Len").Base(err) } if decryptedResponseHeaderLengthBinaryBuffer, err := aeadResponseHeaderLengthEncryptionAEAD.Open(nil, aeadResponseHeaderLengthEncryptionIV, aeadEncryptedResponseHeaderLength[:], nil); err != nil { return nil, newError("Failed To Decrypt Length").Base(err) } else { common.Must(binary.Read(bytes.NewReader(decryptedResponseHeaderLengthBinaryBuffer), binary.BigEndian, &decryptedResponseHeaderLengthBinaryDeserializeBuffer)) decryptedResponseHeaderLength = int(decryptedResponseHeaderLengthBinaryDeserializeBuffer) } aeadResponseHeaderPayloadEncryptionKey := vmessaead.KDF16(c.responseBodyKey[:], vmessaead.KDFSaltConstAEADRespHeaderPayloadKey) aeadResponseHeaderPayloadEncryptionIV := vmessaead.KDF(c.responseBodyIV[:], vmessaead.KDFSaltConstAEADRespHeaderPayloadIV)[:12] aeadResponseHeaderPayloadEncryptionKeyAESBlock := common.Must2(aes.NewCipher(aeadResponseHeaderPayloadEncryptionKey)).(cipher.Block) aeadResponseHeaderPayloadEncryptionAEAD := common.Must2(cipher.NewGCM(aeadResponseHeaderPayloadEncryptionKeyAESBlock)).(cipher.AEAD) encryptedResponseHeaderBuffer := make([]byte, decryptedResponseHeaderLength+16) if _, err := io.ReadFull(reader, encryptedResponseHeaderBuffer); err != nil { return nil, newError("Unable to Read Header Data").Base(err) } if decryptedResponseHeaderBuffer, err := aeadResponseHeaderPayloadEncryptionAEAD.Open(nil, aeadResponseHeaderPayloadEncryptionIV, encryptedResponseHeaderBuffer, nil); err != nil { return nil, newError("Failed To Decrypt Payload").Base(err) } else { c.responseReader = bytes.NewReader(decryptedResponseHeaderBuffer) } } buffer := buf.StackNew() defer buffer.Release() if _, err := buffer.ReadFullFrom(c.responseReader, 4); err != nil { return nil, newError("failed to read response header").Base(err).AtWarning() } if buffer.Byte(0) != c.responseHeader { return nil, newError("unexpected response header. Expecting ", int(c.responseHeader), " but actually ", int(buffer.Byte(0))) } header := &protocol.ResponseHeader{ Option: bitmask.Byte(buffer.Byte(1)), } if buffer.Byte(2) != 0 { cmdID := buffer.Byte(2) dataLen := int32(buffer.Byte(3)) buffer.Clear() if _, err := buffer.ReadFullFrom(c.responseReader, dataLen); err != nil { return nil, newError("failed to read response command").Base(err) } command, err := UnmarshalCommand(cmdID, buffer.Bytes()) if err == nil { header.Command = command } } if c.isAEAD { aesStream := crypto.NewAesDecryptionStream(c.responseBodyKey[:], c.responseBodyIV[:]) c.responseReader = crypto.NewCryptionReader(aesStream, reader) } return header, nil } func (c *ClientSession) DecodeResponseBody(request *protocol.RequestHeader, reader io.Reader) buf.Reader { var sizeParser crypto.ChunkSizeDecoder = crypto.PlainChunkSizeParser{} if request.Option.Has(protocol.RequestOptionChunkMasking) { sizeParser = NewShakeSizeParser(c.responseBodyIV[:]) } var padding crypto.PaddingLengthGenerator if request.Option.Has(protocol.RequestOptionGlobalPadding) { padding = sizeParser.(crypto.PaddingLengthGenerator) } switch request.Security { case protocol.SecurityType_NONE: if request.Option.Has(protocol.RequestOptionChunkStream) { if request.Command.TransferType() == protocol.TransferTypeStream { return crypto.NewChunkStreamReader(sizeParser, reader) } auth := &crypto.AEADAuthenticator{ AEAD: new(NoOpAuthenticator), NonceGenerator: crypto.GenerateEmptyBytes(), AdditionalDataGenerator: crypto.GenerateEmptyBytes(), } return crypto.NewAuthenticationReader(auth, sizeParser, reader, protocol.TransferTypePacket, padding) } return buf.NewReader(reader) case protocol.SecurityType_LEGACY: if request.Option.Has(protocol.RequestOptionChunkStream) { auth := &crypto.AEADAuthenticator{ AEAD: new(FnvAuthenticator), NonceGenerator: crypto.GenerateEmptyBytes(), AdditionalDataGenerator: crypto.GenerateEmptyBytes(), } return crypto.NewAuthenticationReader(auth, sizeParser, c.responseReader, request.Command.TransferType(), padding) } return buf.NewReader(c.responseReader) case protocol.SecurityType_AES128_GCM: aead := crypto.NewAesGcm(c.responseBodyKey[:]) auth := &crypto.AEADAuthenticator{ AEAD: aead, NonceGenerator: GenerateChunkNonce(c.responseBodyIV[:], uint32(aead.NonceSize())), AdditionalDataGenerator: crypto.GenerateEmptyBytes(), } return crypto.NewAuthenticationReader(auth, sizeParser, reader, request.Command.TransferType(), padding) case protocol.SecurityType_CHACHA20_POLY1305: aead, _ := chacha20poly1305.New(GenerateChacha20Poly1305Key(c.responseBodyKey[:])) auth := &crypto.AEADAuthenticator{ AEAD: aead, NonceGenerator: GenerateChunkNonce(c.responseBodyIV[:], uint32(aead.NonceSize())), AdditionalDataGenerator: crypto.GenerateEmptyBytes(), } return crypto.NewAuthenticationReader(auth, sizeParser, reader, request.Command.TransferType(), padding) default: panic("Unknown security type.") } } func GenerateChunkNonce(nonce []byte, size uint32) crypto.BytesGenerator { c := append([]byte(nil), nonce...) count := uint16(0) return func() []byte { binary.BigEndian.PutUint16(c, count) count++ return c[:size] } }