// Copyright (c) 2021 Tailscale Inc & AUTHORS All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. package controlbase import ( "context" "crypto/cipher" "encoding/binary" "errors" "fmt" "hash" "io" "net" "strconv" "time" "go4.org/mem" "golang.org/x/crypto/blake2s" chp "golang.org/x/crypto/chacha20poly1305" "golang.org/x/crypto/curve25519" "golang.org/x/crypto/hkdf" "tailscale.com/types/key" ) const ( // protocolName is the name of the specific instantiation of Noise // that the control protocol uses. This string's value is fixed by // the Noise spec, and shouldn't be changed unless we're updating // the control protocol to use a different Noise instance. protocolName = "Noise_IK_25519_ChaChaPoly_BLAKE2s" // protocolVersion is the version of the control protocol that // Client will use when initiating a handshake. protocolVersion uint16 = 1 // protocolVersionPrefix is the name portion of the protocol // name+version string that gets mixed into the handshake as a // prologue. // // This mixing verifies that both clients agree that they're // executing the control protocol at a specific version that // matches the advertised version in the cleartext packet header. protocolVersionPrefix = "Tailscale Control Protocol v" invalidNonce = ^uint64(0) ) func protocolVersionPrologue(version uint16) []byte { ret := make([]byte, 0, len(protocolVersionPrefix)+5) // 5 bytes is enough to encode all possible version numbers. ret = append(ret, protocolVersionPrefix...) return strconv.AppendUint(ret, uint64(version), 10) } // HandshakeContinuation upgrades a net.Conn to a Conn. The net.Conn // is assumed to have already sent the client>server handshake // initiation message. type HandshakeContinuation func(context.Context, net.Conn) (*Conn, error) // ClientDeferred initiates a control client handshake, returning the // initial message to send to the server and a continuation to // finalize the handshake. // // ClientDeferred is split in this way for RTT reduction: we run this // protocol after negotiating a protocol switch from HTTP/HTTPS. If we // completely serialized the negotiation followed by the handshake, // we'd pay an extra RTT to transmit the handshake initiation after // protocol switching. By splitting the handshake into an initial // message and a continuation, we can embed the handshake initiation // into the HTTP protocol switching request and avoid a bit of delay. func ClientDeferred(machineKey key.MachinePrivate, controlKey key.MachinePublic) (initialHandshake []byte, continueHandshake HandshakeContinuation, err error) { var s symmetricState s.Initialize() // prologue s.MixHash(protocolVersionPrologue(protocolVersion)) // <- s // ... s.MixHash(controlKey.UntypedBytes()) // -> e, es, s, ss init := mkInitiationMessage() machineEphemeral := key.NewMachine() machineEphemeralPub := machineEphemeral.Public() copy(init.EphemeralPub(), machineEphemeralPub.UntypedBytes()) s.MixHash(machineEphemeralPub.UntypedBytes()) cipher, err := s.MixDH(machineEphemeral, controlKey) if err != nil { return nil, nil, fmt.Errorf("computing es: %w", err) } machineKeyPub := machineKey.Public() s.EncryptAndHash(cipher, init.MachinePub(), machineKeyPub.UntypedBytes()) cipher, err = s.MixDH(machineKey, controlKey) if err != nil { return nil, nil, fmt.Errorf("computing ss: %w", err) } s.EncryptAndHash(cipher, init.Tag(), nil) // empty message payload cont := func(ctx context.Context, conn net.Conn) (*Conn, error) { return continueClientHandshake(ctx, conn, &s, machineKey, machineEphemeral, controlKey) } return init[:], cont, nil } // Client wraps ClientDeferred and immediately invokes the returned // continuation with conn. // // This is a helper for when you don't need the fancy // continuation-style handshake, and just want to synchronously // upgrade a net.Conn to a secure transport. func Client(ctx context.Context, conn net.Conn, machineKey key.MachinePrivate, controlKey key.MachinePublic) (*Conn, error) { init, cont, err := ClientDeferred(machineKey, controlKey) if err != nil { return nil, err } if _, err := conn.Write(init); err != nil { return nil, err } return cont(ctx, conn) } func continueClientHandshake(ctx context.Context, conn net.Conn, s *symmetricState, machineKey, machineEphemeral key.MachinePrivate, controlKey key.MachinePublic) (*Conn, error) { // No matter what, this function can only run once per s. Ensure // attempted reuse causes a panic. defer func() { s.finished = true }() if deadline, ok := ctx.Deadline(); ok { if err := conn.SetDeadline(deadline); err != nil { return nil, fmt.Errorf("setting conn deadline: %w", err) } defer func() { conn.SetDeadline(time.Time{}) }() } // Read in the payload and look for errors/protocol violations from the server. var resp responseMessage if _, err := io.ReadFull(conn, resp.Header()); err != nil { return nil, fmt.Errorf("reading response header: %w", err) } if resp.Type() != msgTypeResponse { if resp.Type() != msgTypeError { return nil, fmt.Errorf("unexpected response message type %d", resp.Type()) } msg := make([]byte, resp.Length()) if _, err := io.ReadFull(conn, msg); err != nil { return nil, err } return nil, fmt.Errorf("server error: %q", msg) } if resp.Length() != len(resp.Payload()) { return nil, fmt.Errorf("wrong length %d received for handshake response", resp.Length()) } if _, err := io.ReadFull(conn, resp.Payload()); err != nil { return nil, err } // <- e, ee, se controlEphemeralPub := key.MachinePublicFromRaw32(mem.B(resp.EphemeralPub())) s.MixHash(controlEphemeralPub.UntypedBytes()) if _, err := s.MixDH(machineEphemeral, controlEphemeralPub); err != nil { return nil, fmt.Errorf("computing ee: %w", err) } cipher, err := s.MixDH(machineKey, controlEphemeralPub) if err != nil { return nil, fmt.Errorf("computing se: %w", err) } if err := s.DecryptAndHash(cipher, nil, resp.Tag()); err != nil { return nil, fmt.Errorf("decrypting payload: %w", err) } c1, c2, err := s.Split() if err != nil { return nil, fmt.Errorf("finalizing handshake: %w", err) } c := &Conn{ conn: conn, version: protocolVersion, peer: controlKey, handshakeHash: s.h, tx: txState{ cipher: c1, }, rx: rxState{ cipher: c2, }, } return c, nil } // Server initiates a control server handshake, returning the resulting // control connection. // // optionalInit can be the client's initial handshake message as // returned by ClientDeferred, or nil in which case the initial // message is read from conn. // // The context deadline, if any, covers the entire handshaking // process. func Server(ctx context.Context, conn net.Conn, controlKey key.MachinePrivate, optionalInit []byte) (*Conn, error) { if deadline, ok := ctx.Deadline(); ok { if err := conn.SetDeadline(deadline); err != nil { return nil, fmt.Errorf("setting conn deadline: %w", err) } defer func() { conn.SetDeadline(time.Time{}) }() } // Deliberately does not support formatting, so that we don't echo // attacker-controlled input back to them. sendErr := func(msg string) error { if len(msg) >= 1<<16 { msg = msg[:1<<16] } var hdr [headerLen]byte hdr[0] = msgTypeError binary.BigEndian.PutUint16(hdr[1:3], uint16(len(msg))) if _, err := conn.Write(hdr[:]); err != nil { return fmt.Errorf("sending %q error to client: %w", msg, err) } if _, err := io.WriteString(conn, msg); err != nil { return fmt.Errorf("sending %q error to client: %w", msg, err) } return fmt.Errorf("refused client handshake: %q", msg) } var s symmetricState s.Initialize() var init initiationMessage if optionalInit != nil { if len(optionalInit) != len(init) { return nil, sendErr("wrong handshake initiation size") } copy(init[:], optionalInit) } else if _, err := io.ReadFull(conn, init.Header()); err != nil { return nil, err } if init.Version() != protocolVersion { return nil, sendErr("unsupported protocol version") } if init.Type() != msgTypeInitiation { return nil, sendErr("unexpected handshake message type") } if init.Length() != len(init.Payload()) { return nil, sendErr("wrong handshake initiation length") } // if optionalInit was provided, we have the payload already. if optionalInit == nil { if _, err := io.ReadFull(conn, init.Payload()); err != nil { return nil, err } } // prologue. Can only do this once we at least think the client is // handshaking using a supported version. s.MixHash(protocolVersionPrologue(protocolVersion)) // <- s // ... controlKeyPub := controlKey.Public() s.MixHash(controlKeyPub.UntypedBytes()) // -> e, es, s, ss machineEphemeralPub := key.MachinePublicFromRaw32(mem.B(init.EphemeralPub())) s.MixHash(machineEphemeralPub.UntypedBytes()) cipher, err := s.MixDH(controlKey, machineEphemeralPub) if err != nil { return nil, fmt.Errorf("computing es: %w", err) } var machineKeyBytes [32]byte if err := s.DecryptAndHash(cipher, machineKeyBytes[:], init.MachinePub()); err != nil { return nil, fmt.Errorf("decrypting machine key: %w", err) } machineKey := key.MachinePublicFromRaw32(mem.B(machineKeyBytes[:])) cipher, err = s.MixDH(controlKey, machineKey) if err != nil { return nil, fmt.Errorf("computing ss: %w", err) } if err := s.DecryptAndHash(cipher, nil, init.Tag()); err != nil { return nil, fmt.Errorf("decrypting initiation tag: %w", err) } // <- e, ee, se resp := mkResponseMessage() controlEphemeral := key.NewMachine() controlEphemeralPub := controlEphemeral.Public() copy(resp.EphemeralPub(), controlEphemeralPub.UntypedBytes()) s.MixHash(controlEphemeralPub.UntypedBytes()) if _, err := s.MixDH(controlEphemeral, machineEphemeralPub); err != nil { return nil, fmt.Errorf("computing ee: %w", err) } cipher, err = s.MixDH(controlEphemeral, machineKey) if err != nil { return nil, fmt.Errorf("computing se: %w", err) } s.EncryptAndHash(cipher, resp.Tag(), nil) // empty message payload c1, c2, err := s.Split() if err != nil { return nil, fmt.Errorf("finalizing handshake: %w", err) } if _, err := conn.Write(resp[:]); err != nil { return nil, err } c := &Conn{ conn: conn, version: protocolVersion, peer: machineKey, handshakeHash: s.h, tx: txState{ cipher: c2, }, rx: rxState{ cipher: c1, }, } return c, nil } // symmetricState contains the state of an in-flight handshake. type symmetricState struct { finished bool h [blake2s.Size]byte // hash of currently-processed handshake state ck [blake2s.Size]byte // chaining key used to construct session keys at the end of the handshake } func (s *symmetricState) checkFinished() { if s.finished { panic("attempted to use symmetricState after Split was called") } } // Initialize sets s to the initial handshake state, prior to // processing any handshake messages. func (s *symmetricState) Initialize() { s.checkFinished() s.h = blake2s.Sum256([]byte(protocolName)) s.ck = s.h } // MixHash updates s.h to be BLAKE2s(s.h || data), where || is // concatenation. func (s *symmetricState) MixHash(data []byte) { s.checkFinished() h := newBLAKE2s() h.Write(s.h[:]) h.Write(data) h.Sum(s.h[:0]) } // MixDH updates s.ck with the result of X25519(priv, pub) and returns // a singleUseCHP that can be used to encrypt or decrypt handshake // data. // // MixDH corresponds to MixKey(X25519(...))) in the spec. Implementing // it as a single function allows for strongly-typed arguments that // reduce the risk of error in the caller (e.g. invoking X25519 with // two private keys, or two public keys), and thus producing the wrong // calculation. func (s *symmetricState) MixDH(priv key.MachinePrivate, pub key.MachinePublic) (*singleUseCHP, error) { s.checkFinished() keyData, err := curve25519.X25519(priv.UntypedBytes(), pub.UntypedBytes()) if err != nil { return nil, fmt.Errorf("computing X25519: %w", err) } r := hkdf.New(newBLAKE2s, keyData, s.ck[:], nil) if _, err := io.ReadFull(r, s.ck[:]); err != nil { return nil, fmt.Errorf("extracting ck: %w", err) } var k [chp.KeySize]byte if _, err := io.ReadFull(r, k[:]); err != nil { return nil, fmt.Errorf("extracting k: %w", err) } return newSingleUseCHP(k), nil } // EncryptAndHash encrypts plaintext into ciphertext (which must be // the correct size to hold the encrypted plaintext) using cipher, // mixes the ciphertext into s.h, and returns the ciphertext. func (s *symmetricState) EncryptAndHash(cipher *singleUseCHP, ciphertext, plaintext []byte) { s.checkFinished() if len(ciphertext) != len(plaintext)+chp.Overhead { panic("ciphertext is wrong size for given plaintext") } ret := cipher.Seal(ciphertext[:0], plaintext, s.h[:]) s.MixHash(ret) } // DecryptAndHash decrypts the given ciphertext into plaintext (which // must be the correct size to hold the decrypted ciphertext) using // cipher. If decryption is successful, it mixes the ciphertext into // s.h. func (s *symmetricState) DecryptAndHash(cipher *singleUseCHP, plaintext, ciphertext []byte) error { s.checkFinished() if len(ciphertext) != len(plaintext)+chp.Overhead { return errors.New("plaintext is wrong size for given ciphertext") } if _, err := cipher.Open(plaintext[:0], ciphertext, s.h[:]); err != nil { return err } s.MixHash(ciphertext) return nil } // Split returns two ChaCha20Poly1305 ciphers with keys derived from // the current handshake state. Methods on s cannot be used again // after calling Split. func (s *symmetricState) Split() (c1, c2 cipher.AEAD, err error) { s.finished = true var k1, k2 [chp.KeySize]byte r := hkdf.New(newBLAKE2s, nil, s.ck[:], nil) if _, err := io.ReadFull(r, k1[:]); err != nil { return nil, nil, fmt.Errorf("extracting k1: %w", err) } if _, err := io.ReadFull(r, k2[:]); err != nil { return nil, nil, fmt.Errorf("extracting k2: %w", err) } c1, err = chp.New(k1[:]) if err != nil { return nil, nil, fmt.Errorf("constructing AEAD c1: %w", err) } c2, err = chp.New(k2[:]) if err != nil { return nil, nil, fmt.Errorf("constructing AEAD c2: %w", err) } return c1, c2, nil } // newBLAKE2s returns a hash.Hash implementing BLAKE2s, or panics on // error. func newBLAKE2s() hash.Hash { h, err := blake2s.New256(nil) if err != nil { // Should never happen, errors only happen when using BLAKE2s // in MAC mode with a key. panic(err) } return h } // newCHP returns a cipher.AEAD implementing ChaCha20Poly1305, or // panics on error. func newCHP(key [chp.KeySize]byte) cipher.AEAD { aead, err := chp.New(key[:]) if err != nil { // Can only happen if we passed a key of the wrong length. The // function signature prevents that. panic(err) } return aead } // singleUseCHP is an instance of ChaCha20Poly1305 that can be used // only once, either for encrypting or decrypting, but not both. The // chosen operation is always executed with an all-zeros // nonce. Subsequent calls to either Seal or Open panic. type singleUseCHP struct { c cipher.AEAD } func newSingleUseCHP(key [chp.KeySize]byte) *singleUseCHP { return &singleUseCHP{newCHP(key)} } func (c *singleUseCHP) Seal(dst, plaintext, additionalData []byte) []byte { if c.c == nil { panic("Attempted reuse of singleUseAEAD") } cipher := c.c c.c = nil var nonce [chp.NonceSize]byte return cipher.Seal(dst, nonce[:], plaintext, additionalData) } func (c *singleUseCHP) Open(dst, ciphertext, additionalData []byte) ([]byte, error) { if c.c == nil { panic("Attempted reuse of singleUseAEAD") } cipher := c.c c.c = nil var nonce [chp.NonceSize]byte return cipher.Open(dst, nonce[:], ciphertext, additionalData) }