e375a308b9
This commit modifies the NewBrontideMachine constructor to allow a caller to specify exactly _how_ new ephemeral private keys for the crypto handshake are generated. This allows callers a bit more flexibility when using brontide, and also allow test cases to insert specific public keys for use within the hand shake.
723 lines
22 KiB
Go
723 lines
22 KiB
Go
package brontide
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import (
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"crypto/cipher"
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"crypto/sha256"
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"encoding/binary"
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"errors"
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"fmt"
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"io"
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"math"
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"golang.org/x/crypto/chacha20poly1305"
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"golang.org/x/crypto/hkdf"
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"github.com/roasbeef/btcd/btcec"
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)
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const (
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// protocolName is the precise instantiation of the Noise protocol
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// handshake at the center of Brontide. This value will be used as part
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// of the prologue. If the initiator and responder aren't using the
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// exact same string for this value, along with prologue of the Bitcoin
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// network, then the initial handshake will fail.
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protocolName = "Noise_XK_secp256k1_ChaChaPoly_SHA256"
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// macSize is the length in bytes of the tags generated by poly1305.
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macSize = 16
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// lengthHeaderSize is the number of bytes used to prefix encode the
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// length of a message payload.
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lengthHeaderSize = 2
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// keyRotationInterval is the number of messages sent on a single
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// cipher stream before the keys are rotated forwards.
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keyRotationInterval = 1000
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)
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var (
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// ErrMaxMessageLengthExceeded is returned a message to be written to
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// the cipher session exceeds the maximum allowed message payload.
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ErrMaxMessageLengthExceeded = errors.New("the generated payload exceeds " +
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"the max allowed message length of (2^16)-1")
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)
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// TODO(roasbeef): free buffer pool?
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// ecdh performs an ECDH operation between pub and priv. The returned value is
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// the sha256 of the compressed shared point.
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func ecdh(pub *btcec.PublicKey, priv *btcec.PrivateKey) []byte {
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s := &btcec.PublicKey{}
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x, y := btcec.S256().ScalarMult(pub.X, pub.Y, priv.D.Bytes())
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s.X = x
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s.Y = y
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h := sha256.Sum256(s.SerializeCompressed())
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return h[:]
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}
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// cipherState encapsulates the state for the AEAD which will be used to
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// encrypt+authenticate any payloads sent during the handshake, and messages
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// sent once the handshake has completed.
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type cipherState struct {
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// nonce is the nonce passed into the chacha20-poly1305 instance for
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// encryption+decryption. The nonce is incremented after each successful
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// encryption/decryption.
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//
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// TODO(roasbeef): this should actually be 96 bit
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nonce uint64
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// secretKey is the shared symmetric key which will be used to
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// instantiate the cipher.
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//
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// TODO(roasbeef): m-lock??
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secretKey [32]byte
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// salt is an additional secret which is used during key rotation to
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// generate new keys.
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salt [32]byte
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// cipher is an instance of the ChaCha20-Poly1305 AEAD construction
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// created using the secretKey above.
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cipher cipher.AEAD
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}
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// Encrypt returns a ciphertext which is the encryption of the plainText
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// observing the passed associatedData within the AEAD construction.
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func (c *cipherState) Encrypt(associatedData, cipherText, plainText []byte) []byte {
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defer func() {
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c.nonce++
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if c.nonce == keyRotationInterval {
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c.rotateKey()
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}
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}()
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var nonce [12]byte
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binary.LittleEndian.PutUint64(nonce[4:], c.nonce)
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return c.cipher.Seal(cipherText, nonce[:], plainText, associatedData)
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}
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// Decrypt attempts to decrypt the passed ciphertext observing the specified
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// associatedData within the AEAD construction. In the case that the final MAC
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// check fails, then a non-nil error will be returned.
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func (c *cipherState) Decrypt(associatedData, plainText, cipherText []byte) ([]byte, error) {
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defer func() {
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c.nonce++
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if c.nonce == keyRotationInterval {
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c.rotateKey()
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}
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}()
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var nonce [12]byte
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binary.LittleEndian.PutUint64(nonce[4:], c.nonce)
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return c.cipher.Open(plainText, nonce[:], cipherText, associatedData)
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}
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// InitializeKey initializes the secret key and AEAD cipher scheme based off of
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// the passed key.
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func (c *cipherState) InitializeKey(key [32]byte) {
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c.secretKey = key
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c.nonce = 0
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// Safe to ignore the error here as our key is properly sized
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// (32-bytes).
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c.cipher, _ = chacha20poly1305.New(c.secretKey[:])
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}
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// InitializeKeyWithSalt is identical to InitializeKey however it also sets the
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// cipherState's salt field which is used for key rotation.
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func (c *cipherState) InitializeKeyWithSalt(salt, key [32]byte) {
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c.salt = salt
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c.InitializeKey(key)
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}
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// rotateKey rotates the current encryption/decryption key for this cipherState
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// instance. Key rotation is performed by ratcheting the current key forward
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// using an HKDF invocation with the cipherState's salt as the salt, and the
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// current key as the input.
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func (c *cipherState) rotateKey() {
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var (
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info []byte
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nextKey [32]byte
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)
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oldKey := c.secretKey
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h := hkdf.New(sha256.New, oldKey[:], c.salt[:], info)
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// hkdf(ck, k, zero)
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// |
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// | \
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// | \
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// ck k'
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h.Read(c.salt[:])
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h.Read(nextKey[:])
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c.InitializeKey(nextKey)
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}
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// symmetricState encapsulates a cipherState object and houses the ephemeral
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// handshake digest state. This struct is used during the handshake to derive
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// new shared secrets based off of the result of ECDH operations. Ultimately,
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// the final key yielded by this struct is the result of an incremental
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// Triple-DH operation.
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type symmetricState struct {
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cipherState
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// chainingKey is used as the salt to the HKDF function to derive a new
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// chaining key as well as a new tempKey which is used for
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// encryption/decryption.
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chainingKey [32]byte
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// tempKey is the latter 32 bytes resulted from the latest HKDF
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// iteration. This key is used to encrypt/decrypt any handshake
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// messages or payloads sent until the next DH operation is executed.
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tempKey [32]byte
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// handshakeDigest is the cumulative hash digest of all handshake
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// messages sent from start to finish. This value is never transmitted
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// to the other side, but will be used as the AD when
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// encrypting/decrypting messages using our AEAD construction.
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handshakeDigest [32]byte
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}
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// mixKey is implements a basic HKDF-based key ratchet. This method is called
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// with the result of each DH output generated during the handshake process.
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// The first 32 bytes extract from the HKDF reader is the next chaining key,
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// then latter 32 bytes become the temp secret key using within any future AEAD
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// operations until another DH operation is performed.
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func (s *symmetricState) mixKey(input []byte) {
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var info []byte
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secret := input
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salt := s.chainingKey
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h := hkdf.New(sha256.New, secret, salt[:], info)
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// hkdf(ck, input, zero)
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// |
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// | \
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// | \
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// ck k
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h.Read(s.chainingKey[:])
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h.Read(s.tempKey[:])
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// cipher.k = temp_key
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s.InitializeKey(s.tempKey)
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}
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// mixHash hashes the passed input data into the cumulative handshake digest.
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// The running result of this value (h) is used as the associated data in all
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// decryption/encryption operations.
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func (s *symmetricState) mixHash(data []byte) {
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h := sha256.New()
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h.Write(s.handshakeDigest[:])
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h.Write(data)
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copy(s.handshakeDigest[:], h.Sum(nil))
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}
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// EncryptAndHash returns the authenticated encryption of the passed plaintext.
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// When encrypting the handshake digest (h) is used as the associated data to
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// the AEAD cipher.
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func (s *symmetricState) EncryptAndHash(plaintext []byte) []byte {
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ciphertext := s.Encrypt(s.handshakeDigest[:], nil, plaintext)
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s.mixHash(ciphertext)
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return ciphertext
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}
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// DecryptAndHash returns the authenticated decryption of the passed
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// ciphertext. When encrypting the handshake digest (h) is used as the
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// associated data to the AEAD cipher.
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func (s *symmetricState) DecryptAndHash(ciphertext []byte) ([]byte, error) {
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plaintext, err := s.Decrypt(s.handshakeDigest[:], nil, ciphertext)
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if err != nil {
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return nil, err
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}
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s.mixHash(ciphertext)
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return plaintext, nil
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}
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// InitializeSymmetric initializes the symmetric state by setting the handshake
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// digest (h) and the chaining key (ck) to protocol name.
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func (s *symmetricState) InitializeSymmetric(protocolName []byte) {
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var empty [32]byte
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s.handshakeDigest = sha256.Sum256(protocolName)
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s.chainingKey = s.handshakeDigest
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s.InitializeKey(empty)
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}
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// handshakeState encapsulates the symmetricState and keeps track of all the
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// public keys (static and ephemeral) for both sides during the handshake
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// transcript. If the handshake completes successfully, then two instances of a
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// cipherState are emitted: one to encrypt messages from initiator to
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// responder, and the other for the opposite direction.
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type handshakeState struct {
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symmetricState
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initiator bool
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localStatic *btcec.PrivateKey
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localEphemeral *btcec.PrivateKey
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remoteStatic *btcec.PublicKey
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remoteEphemeral *btcec.PublicKey
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}
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// newHandshakeState returns a new instance of the handshake state initialized
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// with the prologue and protocol name. If this is the responder's handshake
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// state, then the remotePub can be nil.
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func newHandshakeState(initiator bool, prologue []byte,
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localPub *btcec.PrivateKey, remotePub *btcec.PublicKey) handshakeState {
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h := handshakeState{
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initiator: initiator,
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localStatic: localPub,
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remoteStatic: remotePub,
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}
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// Set the current chaining key and handshake digest to the hash of the
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// protocol name, and additionally mix in the prologue. If either sides
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// disagree about the prologue or protocol name, then the handshake
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// will fail.
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h.InitializeSymmetric([]byte(protocolName))
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h.mixHash(prologue)
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// In Noise_XK, then initiator should know the responder's static
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// public key, therefore we include the responder's static key in the
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// handshake digest. If the initiator gets this value wrong, then the
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// handshake will fail.
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if initiator {
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h.mixHash(remotePub.SerializeCompressed())
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} else {
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h.mixHash(localPub.PubKey().SerializeCompressed())
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}
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return h
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}
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// EphemeralGenerator is a functional option that allows callers to substitute
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// a custom function for use when generating ephemeral keys for ActOne or
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// ActTwo. The function closure return by this function can be passed into
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// NewBrontideMachine as a function option parameter.
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func EphemeralGenerator(gen func() (*btcec.PrivateKey, error)) func(*Machine) {
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return func(m *Machine) {
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m.ephemeralGen = gen
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}
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}
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// Machine is a state-machine which implements Brontide: an
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// Authenticated-key Exchange in Three Acts. Brontide is derived from the Noise
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// framework, specifically implementing the Noise_XK handshake. Once the
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// initial 3-act handshake has completed all messages are encrypted with a
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// chacha20 AEAD cipher. On the wire, all messages are prefixed with an
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// authenticated+encrypted length field. Additionally, the encrypted+auth'd
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// length prefix is used as the AD when encrypting+decryption messages. This
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// construction provides confidentiality of packet length, avoids introducing
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// a padding-oracle, and binds the encrypted packet length to the packet
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// itself.
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//
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// The acts proceeds the following order (initiator on the left):
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// GenActOne() ->
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// RecvActOne()
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// <- GenActTwo()
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// RecvActTwo()
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// GenActThree() ->
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// RecvActThree()
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//
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// This exchange corresponds to the following Noise handshake:
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// <- s
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// ...
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// -> e, es
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// <- e, ee
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// -> s, se
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type Machine struct {
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sendCipher cipherState
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recvCipher cipherState
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ephemeralGen func() (*btcec.PrivateKey, error)
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handshakeState
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}
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// NewBrontideMachine creates a new instance of the brontide state-machine. If
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// the responder (listener) is creating the object, then the remotePub should
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// be nil. The handshake state within brontide is initialized using the ascii
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// string "bitcoin" as the prologue. The last parameter is a set of variadic
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// arguments for adding additional options to the brontide Machine
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// initialization.
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func NewBrontideMachine(initiator bool, localPub *btcec.PrivateKey,
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remotePub *btcec.PublicKey, options ...func(*Machine)) *Machine {
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handshake := newHandshakeState(initiator, []byte("lightning"), localPub,
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remotePub)
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m := &Machine{handshakeState: handshake}
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// With the initial base machine created, we'll assign our default
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// version of the ephemeral key generator.
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m.ephemeralGen = func() (*btcec.PrivateKey, error) {
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return btcec.NewPrivateKey(btcec.S256())
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}
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// With the default options established, we'll now process all the
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// options passed in as parameters.
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for _, option := range options {
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option(m)
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}
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return m
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}
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const (
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// HandshakeVersion is the expected version of the brontide handshake.
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// Any messages that carry a different version will cause the handshake
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// to abort immediately.
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HandshakeVersion = byte(0)
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// ActOneSize is the size of the packet sent from initiator to
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// responder in ActOne. The packet consists of a handshake version, an
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// ephemeral key in compressed format, and a 16-byte poly1305 tag.
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//
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// 1 + 33 + 16
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ActOneSize = 50
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// ActTwoSize is the size the packet sent from responder to initiator
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// in ActTwo. The packet consists of a handshake version, an ephemeral
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// key in compressed format and a 16-byte poly1305 tag.
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//
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// 1 + 33 + 16
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ActTwoSize = 50
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// ActThreeSize is the size of the packet sent from initiator to
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// responder in ActThree. The packet consists of a handshake version,
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// the initiators static key encrypted with strong forward secrecy and
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// a 16-byte poly1035
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// tag.
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//
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// 1 + 33 + 16 + 16
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ActThreeSize = 66
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)
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// GenActOne generates the initial packet (act one) to be sent from initiator
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// to responder. During act one the initiator generates a fresh ephemeral key,
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// hashes it into the handshake digest, and performs an ECDH between this key
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// and the responder's static key. Future payloads are encrypted with a key
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// derived from this result.
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//
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// -> e, es
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func (b *Machine) GenActOne() ([ActOneSize]byte, error) {
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var (
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err error
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actOne [ActOneSize]byte
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)
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// e
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b.localEphemeral, err = b.ephemeralGen()
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if err != nil {
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return actOne, err
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}
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ephemeral := b.localEphemeral.PubKey().SerializeCompressed()
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b.mixHash(ephemeral)
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// es
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s := ecdh(b.remoteStatic, b.localEphemeral)
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b.mixKey(s[:])
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authPayload := b.EncryptAndHash([]byte{})
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actOne[0] = HandshakeVersion
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copy(actOne[1:34], ephemeral)
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copy(actOne[34:], authPayload)
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return actOne, nil
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}
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// RecvActOne processes the act one packet sent by the initiator. The responder
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// executes the mirrored actions to that of the initiator extending the
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// handshake digest and deriving a new shared secret based on a ECDH with the
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// initiator's ephemeral key and responder's static key.
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func (b *Machine) RecvActOne(actOne [ActOneSize]byte) error {
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var (
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err error
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e [33]byte
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p [16]byte
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)
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// If the handshake version is unknown, then the handshake fails
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// immediately.
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if actOne[0] != HandshakeVersion {
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return fmt.Errorf("Act One: invalid handshake version: %v, "+
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"only %v is valid, msg=%x", actOne[0], HandshakeVersion,
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actOne[:])
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}
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copy(e[:], actOne[1:34])
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copy(p[:], actOne[34:])
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// e
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b.remoteEphemeral, err = btcec.ParsePubKey(e[:], btcec.S256())
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if err != nil {
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return err
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}
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b.mixHash(b.remoteEphemeral.SerializeCompressed())
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// es
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s := ecdh(b.remoteEphemeral, b.localStatic)
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b.mixKey(s)
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// If the initiator doesn't know our static key, then this operation
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// will fail.
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_, err = b.DecryptAndHash(p[:])
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return err
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}
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// GenActTwo generates the second packet (act two) to be sent from the
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// responder to the initiator. The packet for act two is identify to that of
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// act one, but then results in a different ECDH operation between the
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// initiator's and responder's ephemeral keys.
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//
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// <- e, ee
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func (b *Machine) GenActTwo() ([ActTwoSize]byte, error) {
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var (
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err error
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actTwo [ActTwoSize]byte
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)
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// e
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b.localEphemeral, err = b.ephemeralGen()
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if err != nil {
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return actTwo, err
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}
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ephemeral := b.localEphemeral.PubKey().SerializeCompressed()
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b.mixHash(b.localEphemeral.PubKey().SerializeCompressed())
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// ee
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s := ecdh(b.remoteEphemeral, b.localEphemeral)
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b.mixKey(s)
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authPayload := b.EncryptAndHash([]byte{})
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actTwo[0] = HandshakeVersion
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copy(actTwo[1:34], ephemeral)
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copy(actTwo[34:], authPayload)
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return actTwo, nil
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}
|
|
|
|
// RecvActTwo processes the second packet (act two) sent from the responder to
|
|
// the initiator. A successful processing of this packet authenticates the
|
|
// initiator to the responder.
|
|
func (b *Machine) RecvActTwo(actTwo [ActTwoSize]byte) error {
|
|
var (
|
|
err error
|
|
e [33]byte
|
|
p [16]byte
|
|
)
|
|
|
|
// If the handshake version is unknown, then the handshake fails
|
|
// immediately.
|
|
if actTwo[0] != HandshakeVersion {
|
|
return fmt.Errorf("Act Two: invalid handshake version: %v, "+
|
|
"only %v is valid, msg=%x", actTwo[0], HandshakeVersion,
|
|
actTwo[:])
|
|
}
|
|
|
|
copy(e[:], actTwo[1:34])
|
|
copy(p[:], actTwo[34:])
|
|
|
|
// e
|
|
b.remoteEphemeral, err = btcec.ParsePubKey(e[:], btcec.S256())
|
|
if err != nil {
|
|
return err
|
|
}
|
|
b.mixHash(b.remoteEphemeral.SerializeCompressed())
|
|
|
|
// ee
|
|
s := ecdh(b.remoteEphemeral, b.localEphemeral)
|
|
b.mixKey(s)
|
|
|
|
_, err = b.DecryptAndHash(p[:])
|
|
return err
|
|
}
|
|
|
|
// GenActThree creates the final (act three) packet of the handshake. Act three
|
|
// is to be sent from the initiator to the responder. The purpose of act three
|
|
// is to transmit the initiator's public key under strong forward secrecy to
|
|
// the responder. This act also includes the final ECDH operation which yields
|
|
// the final session.
|
|
//
|
|
// -> s, se
|
|
func (b *Machine) GenActThree() ([ActThreeSize]byte, error) {
|
|
var actThree [ActThreeSize]byte
|
|
|
|
ourPubkey := b.localStatic.PubKey().SerializeCompressed()
|
|
ciphertext := b.EncryptAndHash(ourPubkey)
|
|
|
|
s := ecdh(b.remoteEphemeral, b.localStatic)
|
|
b.mixKey(s)
|
|
|
|
authPayload := b.EncryptAndHash([]byte{})
|
|
|
|
actThree[0] = HandshakeVersion
|
|
copy(actThree[1:50], ciphertext)
|
|
copy(actThree[50:], authPayload)
|
|
|
|
// With the final ECDH operation complete, derive the session sending
|
|
// and receiving keys.
|
|
b.split()
|
|
|
|
return actThree, nil
|
|
}
|
|
|
|
// RecvActThree processes the final act (act three) sent from the initiator to
|
|
// the responder. After processing this act, the responder learns of the
|
|
// initiator's static public key. Decryption of the static key serves to
|
|
// authenticate the initiator to the responder.
|
|
func (b *Machine) RecvActThree(actThree [ActThreeSize]byte) error {
|
|
var (
|
|
err error
|
|
s [33 + 16]byte
|
|
p [16]byte
|
|
)
|
|
|
|
// If the handshake version is unknown, then the handshake fails
|
|
// immediately.
|
|
if actThree[0] != HandshakeVersion {
|
|
return fmt.Errorf("Act Three: invalid handshake version: %v, "+
|
|
"only %v is valid, msg=%x", actThree[0], HandshakeVersion,
|
|
actThree[:])
|
|
}
|
|
|
|
copy(s[:], actThree[1:33+16+1])
|
|
copy(p[:], actThree[33+16+1:])
|
|
|
|
// s
|
|
remotePub, err := b.DecryptAndHash(s[:])
|
|
if err != nil {
|
|
return err
|
|
}
|
|
b.remoteStatic, err = btcec.ParsePubKey(remotePub, btcec.S256())
|
|
if err != nil {
|
|
return err
|
|
}
|
|
|
|
// se
|
|
se := ecdh(b.remoteStatic, b.localEphemeral)
|
|
b.mixKey(se)
|
|
|
|
if _, err := b.DecryptAndHash(p[:]); err != nil {
|
|
return err
|
|
}
|
|
|
|
// With the final ECDH operation complete, derive the session sending
|
|
// and receiving keys.
|
|
b.split()
|
|
|
|
return nil
|
|
}
|
|
|
|
// split is the final wrap-up act to be executed at the end of a successful
|
|
// three act handshake. This function creates to internal cipherState
|
|
// instances: one which is used to encrypt messages from the initiator to the
|
|
// responder, and another which is used to encrypt message for the opposite
|
|
// direction.
|
|
func (b *Machine) split() {
|
|
var (
|
|
empty []byte
|
|
sendKey [32]byte
|
|
recvKey [32]byte
|
|
)
|
|
|
|
h := hkdf.New(sha256.New, empty, b.chainingKey[:], empty)
|
|
|
|
// If we're the initiator the first 32 bytes are used to encrypt our
|
|
// messages and the second 32-bytes to decrypt their messages. For the
|
|
// responder the opposite is true.
|
|
if b.initiator {
|
|
h.Read(sendKey[:])
|
|
b.sendCipher = cipherState{}
|
|
b.sendCipher.InitializeKeyWithSalt(b.chainingKey, sendKey)
|
|
|
|
h.Read(recvKey[:])
|
|
b.recvCipher = cipherState{}
|
|
b.recvCipher.InitializeKeyWithSalt(b.chainingKey, recvKey)
|
|
} else {
|
|
h.Read(recvKey[:])
|
|
b.recvCipher = cipherState{}
|
|
b.recvCipher.InitializeKeyWithSalt(b.chainingKey, recvKey)
|
|
|
|
h.Read(sendKey[:])
|
|
b.sendCipher = cipherState{}
|
|
b.sendCipher.InitializeKeyWithSalt(b.chainingKey, sendKey)
|
|
}
|
|
}
|
|
|
|
// WriteMessage writes the next message p to the passed io.Writer. The
|
|
// ciphertext of the message is pre-pended with an encrypt+auth'd length which
|
|
// must be used as the AD to the AEAD construction when being decrypted by the
|
|
// other side.
|
|
func (b *Machine) WriteMessage(w io.Writer, p []byte) error {
|
|
// The total length of each message payload including the MAC size
|
|
// payload exceed the largest number encodable within a 16-bit unsigned
|
|
// integer.
|
|
if len(p) > math.MaxUint16 {
|
|
return ErrMaxMessageLengthExceeded
|
|
}
|
|
|
|
// The full length of the packet is only the packet length, and does
|
|
// NOT include the MAC.
|
|
fullLength := uint16(len(p))
|
|
|
|
var pktLen [2]byte
|
|
binary.BigEndian.PutUint16(pktLen[:], fullLength)
|
|
|
|
// First, write out the encrypted+MAC'd length prefix for the packet.
|
|
cipherLen := b.sendCipher.Encrypt(nil, nil, pktLen[:])
|
|
if _, err := w.Write(cipherLen); err != nil {
|
|
return err
|
|
}
|
|
|
|
// Finally, write out the encrypted packet itself. We only write out a
|
|
// single packet, as any fragmentation should have taken place at a
|
|
// higher level.
|
|
cipherText := b.sendCipher.Encrypt(nil, nil, p)
|
|
_, err := w.Write(cipherText)
|
|
return err
|
|
}
|
|
|
|
// ReadMessage attempts to read the next message from the passed io.Reader. In
|
|
// the case of an authentication error, a non-nil error is returned.
|
|
func (b *Machine) ReadMessage(r io.Reader) ([]byte, error) {
|
|
var cipherLen [lengthHeaderSize + macSize]byte
|
|
if _, err := io.ReadFull(r, cipherLen[:]); err != nil {
|
|
return nil, err
|
|
}
|
|
|
|
// Attempt to decrypt+auth the packet length present in the stream.
|
|
pktLenBytes, err := b.recvCipher.Decrypt(nil, nil, cipherLen[:])
|
|
if err != nil {
|
|
return nil, err
|
|
}
|
|
|
|
// Next, using the length read from the packet header, read the
|
|
// encrypted packet itself.
|
|
var cipherText [math.MaxUint16 + macSize]byte
|
|
pktLen := uint32(binary.BigEndian.Uint16(pktLenBytes)) + macSize
|
|
if _, err := io.ReadFull(r, cipherText[:pktLen]); err != nil {
|
|
return nil, err
|
|
}
|
|
|
|
// TODO(roasbeef): modify to let pass in slice
|
|
return b.recvCipher.Decrypt(nil, nil, cipherText[:pktLen])
|
|
}
|