diff options
Diffstat (limited to 'vendor/github.com/OperatorFoundation/obfs4/common/ntor')
-rw-r--r-- | vendor/github.com/OperatorFoundation/obfs4/common/ntor/ntor.go | 433 |
1 files changed, 433 insertions, 0 deletions
diff --git a/vendor/github.com/OperatorFoundation/obfs4/common/ntor/ntor.go b/vendor/github.com/OperatorFoundation/obfs4/common/ntor/ntor.go new file mode 100644 index 0000000..0994782 --- /dev/null +++ b/vendor/github.com/OperatorFoundation/obfs4/common/ntor/ntor.go @@ -0,0 +1,433 @@ +/* + * Copyright (c) 2014, Yawning Angel <yawning at torproject dot org> + * All rights reserved. + * + * Redistribution and use in source and binary forms, with or without + * modification, are permitted provided that the following conditions are met: + * + * * Redistributions of source code must retain the above copyright notice, + * this list of conditions and the following disclaimer. + * + * * Redistributions in binary form must reproduce the above copyright notice, + * this list of conditions and the following disclaimer in the documentation + * and/or other materials provided with the distribution. + * + * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" + * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE + * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE + * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE + * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR + * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF + * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS + * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN + * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) + * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE + * POSSIBILITY OF SUCH DAMAGE. + */ + +// Package ntor implements the Tor Project's ntor handshake as defined in +// proposal 216 "Improved circuit-creation key exchange". It also supports +// using Elligator to transform the Curve25519 public keys sent over the wire +// to a form that is indistinguishable from random strings. +// +// Before using this package, it is strongly recommended that the specification +// is read and understood. +package ntor + +import ( + "bytes" + "crypto/hmac" + "crypto/sha256" + "crypto/subtle" + "encoding/hex" + "fmt" + "io" + + "golang.org/x/crypto/curve25519" + "golang.org/x/crypto/hkdf" + + "github.com/agl/ed25519/extra25519" + + "github.com/OperatorFoundation/obfs4/common/csrand" +) + +const ( + // PublicKeyLength is the length of a Curve25519 public key. + PublicKeyLength = 32 + + // RepresentativeLength is the length of an Elligator representative. + RepresentativeLength = 32 + + // PrivateKeyLength is the length of a Curve25519 private key. + PrivateKeyLength = 32 + + // SharedSecretLength is the length of a Curve25519 shared secret. + SharedSecretLength = 32 + + // NodeIDLength is the length of a ntor node identifier. + NodeIDLength = 20 + + // KeySeedLength is the length of the derived KEY_SEED. + KeySeedLength = sha256.Size + + // AuthLength is the lenght of the derived AUTH. + AuthLength = sha256.Size +) + +var protoID = []byte("ntor-curve25519-sha256-1") +var tMac = append(protoID, []byte(":mac")...) +var tKey = append(protoID, []byte(":key_extract")...) +var tVerify = append(protoID, []byte(":key_verify")...) +var mExpand = append(protoID, []byte(":key_expand")...) + +// PublicKeyLengthError is the error returned when the public key being +// imported is an invalid length. +type PublicKeyLengthError int + +func (e PublicKeyLengthError) Error() string { + return fmt.Sprintf("ntor: Invalid Curve25519 public key length: %d", + int(e)) +} + +// PrivateKeyLengthError is the error returned when the private key being +// imported is an invalid length. +type PrivateKeyLengthError int + +func (e PrivateKeyLengthError) Error() string { + return fmt.Sprintf("ntor: Invalid Curve25519 private key length: %d", + int(e)) +} + +// NodeIDLengthError is the error returned when the node ID being imported is +// an invalid length. +type NodeIDLengthError int + +func (e NodeIDLengthError) Error() string { + return fmt.Sprintf("ntor: Invalid NodeID length: %d", int(e)) +} + +// KeySeed is the key material that results from a handshake (KEY_SEED). +type KeySeed [KeySeedLength]byte + +// Bytes returns a pointer to the raw key material. +func (key_seed *KeySeed) Bytes() *[KeySeedLength]byte { + return (*[KeySeedLength]byte)(key_seed) +} + +// Auth is the verifier that results from a handshake (AUTH). +type Auth [AuthLength]byte + +// Bytes returns a pointer to the raw auth. +func (auth *Auth) Bytes() *[AuthLength]byte { + return (*[AuthLength]byte)(auth) +} + +// NodeID is a ntor node identifier. +type NodeID [NodeIDLength]byte + +// NewNodeID creates a NodeID from the raw bytes. +func NewNodeID(raw []byte) (*NodeID, error) { + if len(raw) != NodeIDLength { + return nil, NodeIDLengthError(len(raw)) + } + + nodeID := new(NodeID) + copy(nodeID[:], raw) + + return nodeID, nil +} + +// NodeIDFromHex creates a new NodeID from the hexdecimal representation. +func NodeIDFromHex(encoded string) (*NodeID, error) { + raw, err := hex.DecodeString(encoded) + if err != nil { + return nil, err + } + + return NewNodeID(raw) +} + +// Bytes returns a pointer to the raw NodeID. +func (id *NodeID) Bytes() *[NodeIDLength]byte { + return (*[NodeIDLength]byte)(id) +} + +// Hex returns the hexdecimal representation of the NodeID. +func (id *NodeID) Hex() string { + return hex.EncodeToString(id[:]) +} + +// PublicKey is a Curve25519 public key in little-endian byte order. +type PublicKey [PublicKeyLength]byte + +// Bytes returns a pointer to the raw Curve25519 public key. +func (public *PublicKey) Bytes() *[PublicKeyLength]byte { + return (*[PublicKeyLength]byte)(public) +} + +// Hex returns the hexdecimal representation of the Curve25519 public key. +func (public *PublicKey) Hex() string { + return hex.EncodeToString(public.Bytes()[:]) +} + +// NewPublicKey creates a PublicKey from the raw bytes. +func NewPublicKey(raw []byte) (*PublicKey, error) { + if len(raw) != PublicKeyLength { + return nil, PublicKeyLengthError(len(raw)) + } + + pubKey := new(PublicKey) + copy(pubKey[:], raw) + + return pubKey, nil +} + +// PublicKeyFromHex returns a PublicKey from the hexdecimal representation. +func PublicKeyFromHex(encoded string) (*PublicKey, error) { + raw, err := hex.DecodeString(encoded) + if err != nil { + return nil, err + } + + return NewPublicKey(raw) +} + +// Representative is an Elligator representative of a Curve25519 public key +// in little-endian byte order. +type Representative [RepresentativeLength]byte + +// Bytes returns a pointer to the raw Elligator representative. +func (repr *Representative) Bytes() *[RepresentativeLength]byte { + return (*[RepresentativeLength]byte)(repr) +} + +// ToPublic converts a Elligator representative to a Curve25519 public key. +func (repr *Representative) ToPublic() *PublicKey { + pub := new(PublicKey) + + extra25519.RepresentativeToPublicKey(pub.Bytes(), repr.Bytes()) + return pub +} + +// PrivateKey is a Curve25519 private key in little-endian byte order. +type PrivateKey [PrivateKeyLength]byte + +// Bytes returns a pointer to the raw Curve25519 private key. +func (private *PrivateKey) Bytes() *[PrivateKeyLength]byte { + return (*[PrivateKeyLength]byte)(private) +} + +// Hex returns the hexdecimal representation of the Curve25519 private key. +func (private *PrivateKey) Hex() string { + return hex.EncodeToString(private.Bytes()[:]) +} + +// Keypair is a Curve25519 keypair with an optional Elligator representative. +// As only certain Curve25519 keys can be obfuscated with Elligator, the +// representative must be generated along with the keypair. +type Keypair struct { + public *PublicKey + private *PrivateKey + representative *Representative +} + +// Public returns the Curve25519 public key belonging to the Keypair. +func (keypair *Keypair) Public() *PublicKey { + return keypair.public +} + +// Private returns the Curve25519 private key belonging to the Keypair. +func (keypair *Keypair) Private() *PrivateKey { + return keypair.private +} + +// Representative returns the Elligator representative of the public key +// belonging to the Keypair. +func (keypair *Keypair) Representative() *Representative { + return keypair.representative +} + +// HasElligator returns true if the Keypair has an Elligator representative. +func (keypair *Keypair) HasElligator() bool { + return nil != keypair.representative +} + +// NewKeypair generates a new Curve25519 keypair, and optionally also generates +// an Elligator representative of the public key. +func NewKeypair(elligator bool) (*Keypair, error) { + keypair := new(Keypair) + keypair.private = new(PrivateKey) + keypair.public = new(PublicKey) + if elligator { + keypair.representative = new(Representative) + } + + for { + // Generate a Curve25519 private key. Like everyone who does this, + // run the CSPRNG output through SHA256 for extra tinfoil hattery. + priv := keypair.private.Bytes()[:] + if err := csrand.Bytes(priv); err != nil { + return nil, err + } + digest := sha256.Sum256(priv) + digest[0] &= 248 + digest[31] &= 127 + digest[31] |= 64 + copy(priv, digest[:]) + + if elligator { + // Apply the Elligator transform. This fails ~50% of the time. + if !extra25519.ScalarBaseMult(keypair.public.Bytes(), + keypair.representative.Bytes(), + keypair.private.Bytes()) { + continue + } + } else { + // Generate the corresponding Curve25519 public key. + curve25519.ScalarBaseMult(keypair.public.Bytes(), + keypair.private.Bytes()) + } + + return keypair, nil + } +} + +// KeypairFromHex returns a Keypair from the hexdecimal representation of the +// private key. +func KeypairFromHex(encoded string) (*Keypair, error) { + raw, err := hex.DecodeString(encoded) + if err != nil { + return nil, err + } + + if len(raw) != PrivateKeyLength { + return nil, PrivateKeyLengthError(len(raw)) + } + + keypair := new(Keypair) + keypair.private = new(PrivateKey) + keypair.public = new(PublicKey) + + copy(keypair.private[:], raw) + curve25519.ScalarBaseMult(keypair.public.Bytes(), + keypair.private.Bytes()) + + return keypair, nil +} + +// ServerHandshake does the server side of a ntor handshake and returns status, +// KEY_SEED, and AUTH. If status is not true, the handshake MUST be aborted. +func ServerHandshake(clientPublic *PublicKey, serverKeypair *Keypair, idKeypair *Keypair, id *NodeID) (ok bool, keySeed *KeySeed, auth *Auth) { + var notOk int + var secretInput bytes.Buffer + + // Server side uses EXP(X,y) | EXP(X,b) + var exp [SharedSecretLength]byte + curve25519.ScalarMult(&exp, serverKeypair.private.Bytes(), + clientPublic.Bytes()) + notOk |= constantTimeIsZero(exp[:]) + secretInput.Write(exp[:]) + + curve25519.ScalarMult(&exp, idKeypair.private.Bytes(), + clientPublic.Bytes()) + notOk |= constantTimeIsZero(exp[:]) + secretInput.Write(exp[:]) + + keySeed, auth = ntorCommon(secretInput, id, idKeypair.public, + clientPublic, serverKeypair.public) + return notOk == 0, keySeed, auth +} + +// ClientHandshake does the client side of a ntor handshake and returnes +// status, KEY_SEED, and AUTH. If status is not true or AUTH does not match +// the value recieved from the server, the handshake MUST be aborted. +func ClientHandshake(clientKeypair *Keypair, serverPublic *PublicKey, idPublic *PublicKey, id *NodeID) (ok bool, keySeed *KeySeed, auth *Auth) { + var notOk int + var secretInput bytes.Buffer + + // Client side uses EXP(Y,x) | EXP(B,x) + var exp [SharedSecretLength]byte + curve25519.ScalarMult(&exp, clientKeypair.private.Bytes(), + serverPublic.Bytes()) + notOk |= constantTimeIsZero(exp[:]) + secretInput.Write(exp[:]) + + curve25519.ScalarMult(&exp, clientKeypair.private.Bytes(), + idPublic.Bytes()) + notOk |= constantTimeIsZero(exp[:]) + secretInput.Write(exp[:]) + + keySeed, auth = ntorCommon(secretInput, id, idPublic, + clientKeypair.public, serverPublic) + return notOk == 0, keySeed, auth +} + +// CompareAuth does a constant time compare of a Auth and a byte slice +// (presumably received over a network). +func CompareAuth(auth1 *Auth, auth2 []byte) bool { + auth1Bytes := auth1.Bytes() + return hmac.Equal(auth1Bytes[:], auth2) +} + +func ntorCommon(secretInput bytes.Buffer, id *NodeID, b *PublicKey, x *PublicKey, y *PublicKey) (*KeySeed, *Auth) { + keySeed := new(KeySeed) + auth := new(Auth) + + // secret_input/auth_input use this common bit, build it once. + suffix := bytes.NewBuffer(b.Bytes()[:]) + suffix.Write(b.Bytes()[:]) + suffix.Write(x.Bytes()[:]) + suffix.Write(y.Bytes()[:]) + suffix.Write(protoID) + suffix.Write(id[:]) + + // At this point secret_input has the 2 exponents, concatenated, append the + // client/server common suffix. + secretInput.Write(suffix.Bytes()) + + // KEY_SEED = H(secret_input, t_key) + h := hmac.New(sha256.New, tKey) + h.Write(secretInput.Bytes()) + tmp := h.Sum(nil) + copy(keySeed[:], tmp) + + // verify = H(secret_input, t_verify) + h = hmac.New(sha256.New, tVerify) + h.Write(secretInput.Bytes()) + verify := h.Sum(nil) + + // auth_input = verify | ID | B | Y | X | PROTOID | "Server" + authInput := bytes.NewBuffer(verify) + authInput.Write(suffix.Bytes()) + authInput.Write([]byte("Server")) + h = hmac.New(sha256.New, tMac) + h.Write(authInput.Bytes()) + tmp = h.Sum(nil) + copy(auth[:], tmp) + + return keySeed, auth +} + +func constantTimeIsZero(x []byte) int { + var ret byte + for _, v := range x { + ret |= v + } + + return subtle.ConstantTimeByteEq(ret, 0) +} + +// Kdf extracts and expands KEY_SEED via HKDF-SHA256 and returns `okm_len` bytes +// of key material. +func Kdf(keySeed []byte, okmLen int) []byte { + kdf := hkdf.New(sha256.New, keySeed, tKey, mExpand) + okm := make([]byte, okmLen) + n, err := io.ReadFull(kdf, okm) + if err != nil { + panic(fmt.Sprintf("BUG: Failed HKDF: %s", err.Error())) + } else if n != len(okm) { + panic(fmt.Sprintf("BUG: Got truncated HKDF output: %d", n)) + } + + return okm +} |