2015-01-18 11:46:08 +02:00
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package p2p
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import (
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"crypto/ecdsa"
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"crypto/rand"
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"fmt"
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2015-01-20 01:42:13 +02:00
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"io"
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2015-01-18 11:46:08 +02:00
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"github.com/ethereum/go-ethereum/crypto"
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"github.com/obscuren/ecies"
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"github.com/obscuren/secp256k1-go"
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)
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var (
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2015-01-20 18:47:46 +02:00
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sskLen int = 16 // ecies.MaxSharedKeyLength(pubKey) / 2
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sigLen int = 65 // elliptic S256
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pubLen int = 64 // 512 bit pubkey in uncompressed representation without format byte
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keyLen int = 32 // ECDSA
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msgLen int = 194 // sigLen + keyLen + pubLen + keyLen + 1 = 194
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resLen int = 97 // pubLen + keyLen + 1
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2015-01-18 11:46:08 +02:00
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)
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2015-01-21 12:22:07 +02:00
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// secretRW implements a message read writer with encryption and authentication
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// it is initialised by cryptoId.Run() after a successful crypto handshake
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2015-01-19 01:53:45 +02:00
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// aesSecret, macSecret, egressMac, ingress
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2015-01-18 11:46:08 +02:00
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type secretRW struct {
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aesSecret, macSecret, egressMac, ingressMac []byte
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}
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2015-01-21 12:22:07 +02:00
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/*
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cryptoId implements the crypto layer for the p2p networking
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It is initialised on the node's own identity (which has access to the node's private key) and run separately on a peer connection to set up a secure session after a crypto handshake
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After it performs a crypto handshake it returns
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*/
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2015-01-18 11:46:08 +02:00
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type cryptoId struct {
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2015-01-20 18:47:46 +02:00
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prvKey *ecdsa.PrivateKey
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pubKey *ecdsa.PublicKey
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pubKeyS []byte
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2015-01-18 11:46:08 +02:00
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}
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2015-01-21 12:22:07 +02:00
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/*
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newCryptoId(id ClientIdentity) initialises a crypto layer manager. This object has a short lifecycle when the peer connection starts. It is survived by a secretRW (an message read writer with encryption and authentication) if the crypto handshake is successful.
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*/
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2015-01-18 11:46:08 +02:00
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func newCryptoId(id ClientIdentity) (self *cryptoId, err error) {
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// will be at server init
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2015-01-20 18:47:46 +02:00
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var prvKeyS []byte = id.PrivKey()
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if prvKeyS == nil {
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2015-01-18 11:46:08 +02:00
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err = fmt.Errorf("no private key for client")
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return
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}
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2015-01-20 18:47:46 +02:00
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// initialise ecies private key via importing keys (known via our own clientIdentity)
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// the key format is what elliptic package is using: elliptic.Marshal(Curve, X, Y)
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var prvKey = crypto.ToECDSA(prvKeyS)
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2015-01-18 11:46:08 +02:00
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if prvKey == nil {
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err = fmt.Errorf("invalid private key for client")
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return
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}
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self = &cryptoId{
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prvKey: prvKey,
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// initialise public key from the imported private key
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pubKey: &prvKey.PublicKey,
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// to be created at server init shared between peers and sessions
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// for reuse, call wth ReadAt, no reset seek needed
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}
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2015-01-20 18:47:46 +02:00
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self.pubKeyS = id.Pubkey()
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2015-01-18 11:46:08 +02:00
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return
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}
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2015-01-21 12:22:07 +02:00
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/*
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Run(connection, remotePublicKey, sessionToken) is called when the peer connection starts to set up a secure session by performing a crypto handshake.
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connection is (a buffered) network connection.
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remotePublicKey is the remote peer's node Id.
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sessionToken is the token from the previous session with this same peer. Nil if no token is found.
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initiator is a boolean flag. True if the node represented by cryptoId is the initiator of the connection (ie., remote is an outbound peer reached by dialing out). False if the connection was established by accepting a call from the remote peer via a listener.
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It returns a secretRW which implements the MsgReadWriter interface.
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*/
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2015-01-20 18:47:46 +02:00
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func (self *cryptoId) Run(conn io.ReadWriter, remotePubKeyS []byte, sessionToken []byte, initiator bool) (token []byte, rw *secretRW, err error) {
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var auth, initNonce, recNonce []byte
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var randomPrivKey *ecdsa.PrivateKey
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var remoteRandomPubKey *ecdsa.PublicKey
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if initiator {
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2015-01-20 18:47:46 +02:00
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if auth, initNonce, randomPrivKey, _, err = self.startHandshake(remotePubKeyS, sessionToken); err != nil {
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2015-01-20 01:42:13 +02:00
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return
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}
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conn.Write(auth)
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var response []byte
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conn.Read(response)
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// write out auth message
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// wait for response, then call complete
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if recNonce, remoteRandomPubKey, _, err = self.completeHandshake(response); err != nil {
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return
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}
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2015-01-19 13:21:13 +02:00
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} else {
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conn.Read(auth)
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// we are listening connection. we are responders in the handshake.
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2015-01-19 13:21:13 +02:00
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// Extract info from the authentication. The initiator starts by sending us a handshake that we need to respond to.
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2015-01-20 01:42:13 +02:00
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// so we read auth message first, then respond
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var response []byte
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2015-01-20 18:47:46 +02:00
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if response, recNonce, initNonce, randomPrivKey, remoteRandomPubKey, err = self.respondToHandshake(auth, remotePubKeyS, sessionToken); err != nil {
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2015-01-20 01:42:13 +02:00
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return
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}
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conn.Write(response)
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2015-01-19 13:21:13 +02:00
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}
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2015-01-20 01:42:13 +02:00
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return self.newSession(initNonce, recNonce, auth, randomPrivKey, remoteRandomPubKey)
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2015-01-19 13:21:13 +02:00
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}
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2015-01-21 12:22:07 +02:00
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/*
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ImportPublicKey creates a 512 bit *ecsda.PublicKey from a byte slice. It accepts the simple 64 byte uncompressed format or the 65 byte format given by calling elliptic.Marshal on the EC point represented by the key. Any other length will result in an invalid public key error.
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2015-01-19 06:53:48 +02:00
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*/
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2015-01-20 18:47:46 +02:00
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func ImportPublicKey(pubKey []byte) (pubKeyEC *ecdsa.PublicKey, err error) {
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var pubKey65 []byte
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switch len(pubKey) {
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case 64:
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pubKey65 = append([]byte{0x04}, pubKey...)
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case 65:
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pubKey65 = pubKey
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default:
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return nil, fmt.Errorf("invalid public key length %v (expect 64/65)", len(pubKey))
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}
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return crypto.ToECDSAPub(pubKey65), nil
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}
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2015-01-21 12:22:07 +02:00
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/*
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ExportPublicKey exports a *ecdsa.PublicKey into a byte slice using a simple 64-byte format. and is used for simple serialisation in network communication
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*/
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2015-01-20 18:47:46 +02:00
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func ExportPublicKey(pubKeyEC *ecdsa.PublicKey) (pubKey []byte, err error) {
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if pubKeyEC == nil {
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return nil, fmt.Errorf("no ECDSA public key given")
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}
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return crypto.FromECDSAPub(pubKeyEC)[1:], nil
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}
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2015-01-21 12:22:07 +02:00
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/* startHandshake is called by if the node is the initiator of the connection.
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The caller provides the public key of the peer as conjuctured from lookup based on IP:port, given as user input or proven by signatures. The caller must have access to persistant information about the peers, and pass the previous session token as an argument to cryptoId.
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The first return value is the auth message that is to be sent out to the remote receiver.
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*/
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2015-01-20 18:47:46 +02:00
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func (self *cryptoId) startHandshake(remotePubKeyS, sessionToken []byte) (auth []byte, initNonce []byte, randomPrvKey *ecdsa.PrivateKey, remotePubKey *ecdsa.PublicKey, err error) {
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2015-01-18 11:46:08 +02:00
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// session init, common to both parties
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2015-01-20 18:47:46 +02:00
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if remotePubKey, err = ImportPublicKey(remotePubKeyS); err != nil {
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2015-01-18 11:46:08 +02:00
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return
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}
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2015-01-19 01:53:45 +02:00
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var tokenFlag byte
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2015-01-18 11:46:08 +02:00
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if sessionToken == nil {
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2015-01-19 01:53:45 +02:00
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// no session token found means we need to generate shared secret.
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// ecies shared secret is used as initial session token for new peers
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// generate shared key from prv and remote pubkey
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if sessionToken, err = ecies.ImportECDSA(self.prvKey).GenerateShared(ecies.ImportECDSAPublic(remotePubKey), sskLen, sskLen); err != nil {
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return
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}
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// tokenFlag = 0x00 // redundant
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} else {
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// for known peers, we use stored token from the previous session
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tokenFlag = 0x01
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2015-01-18 11:46:08 +02:00
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}
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2015-01-19 01:53:45 +02:00
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//E(remote-pubk, S(ecdhe-random, ecdh-shared-secret^nonce) || H(ecdhe-random-pubk) || pubk || nonce || 0x0)
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// E(remote-pubk, S(ecdhe-random, token^nonce) || H(ecdhe-random-pubk) || pubk || nonce || 0x1)
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// allocate msgLen long message,
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2015-01-18 11:46:08 +02:00
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var msg []byte = make([]byte, msgLen)
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2015-01-19 01:53:45 +02:00
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initNonce = msg[msgLen-keyLen-1 : msgLen-1]
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if _, err = rand.Read(initNonce); err != nil {
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2015-01-18 11:46:08 +02:00
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return
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}
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// create known message
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2015-01-19 01:53:45 +02:00
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// ecdh-shared-secret^nonce for new peers
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// token^nonce for old peers
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var sharedSecret = Xor(sessionToken, initNonce)
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2015-01-18 11:46:08 +02:00
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// generate random keypair to use for signing
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2015-01-19 06:53:48 +02:00
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if randomPrvKey, err = crypto.GenerateKey(); err != nil {
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2015-01-18 11:46:08 +02:00
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return
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}
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2015-01-19 01:53:45 +02:00
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// sign shared secret (message known to both parties): shared-secret
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2015-01-18 11:46:08 +02:00
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var signature []byte
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2015-01-19 01:53:45 +02:00
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// signature = sign(ecdhe-random, shared-secret)
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2015-01-18 11:46:08 +02:00
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// uses secp256k1.Sign
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2015-01-19 06:53:48 +02:00
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if signature, err = crypto.Sign(sharedSecret, randomPrvKey); err != nil {
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2015-01-18 11:46:08 +02:00
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return
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}
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2015-01-19 01:53:45 +02:00
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// message
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// signed-shared-secret || H(ecdhe-random-pubk) || pubk || nonce || 0x0
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copy(msg, signature) // copy signed-shared-secret
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// H(ecdhe-random-pubk)
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2015-01-20 18:47:46 +02:00
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var randomPubKey64 []byte
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if randomPubKey64, err = ExportPublicKey(&randomPrvKey.PublicKey); err != nil {
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return
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}
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copy(msg[sigLen:sigLen+keyLen], crypto.Sha3(randomPubKey64))
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2015-01-19 01:53:45 +02:00
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// pubkey copied to the correct segment.
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2015-01-20 18:47:46 +02:00
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copy(msg[sigLen+keyLen:sigLen+keyLen+pubLen], self.pubKeyS)
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2015-01-19 01:53:45 +02:00
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// nonce is already in the slice
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// stick tokenFlag byte to the end
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msg[msgLen-1] = tokenFlag
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// encrypt using remote-pubk
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2015-01-18 11:46:08 +02:00
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// auth = eciesEncrypt(remote-pubk, msg)
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2015-01-19 01:53:45 +02:00
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2015-01-18 11:46:08 +02:00
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if auth, err = crypto.Encrypt(remotePubKey, msg); err != nil {
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return
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}
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2015-01-19 01:53:45 +02:00
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2015-01-18 11:46:08 +02:00
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return
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}
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2015-01-21 12:22:07 +02:00
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/*
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respondToHandshake is called by peer if it accepted (but not initiated) the connection from the remote. It is passed the initiator handshake received, the public key and session token belonging to the remote initiator.
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The first return value is the authentication response (aka receiver handshake) that is to be sent to the remote initiator.
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*/
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2015-01-20 18:47:46 +02:00
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func (self *cryptoId) respondToHandshake(auth, remotePubKeyS, sessionToken []byte) (authResp []byte, respNonce []byte, initNonce []byte, randomPrivKey *ecdsa.PrivateKey, remoteRandomPubKey *ecdsa.PublicKey, err error) {
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2015-01-18 11:46:08 +02:00
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var msg []byte
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2015-01-20 18:47:46 +02:00
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var remotePubKey *ecdsa.PublicKey
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if remotePubKey, err = ImportPublicKey(remotePubKeyS); err != nil {
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2015-01-20 01:42:13 +02:00
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return
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}
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2015-01-18 11:46:08 +02:00
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// they prove that msg is meant for me,
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// I prove I possess private key if i can read it
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if msg, err = crypto.Decrypt(self.prvKey, auth); err != nil {
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return
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}
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2015-01-19 02:55:24 +02:00
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var tokenFlag byte
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if sessionToken == nil {
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// no session token found means we need to generate shared secret.
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// ecies shared secret is used as initial session token for new peers
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// generate shared key from prv and remote pubkey
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if sessionToken, err = ecies.ImportECDSA(self.prvKey).GenerateShared(ecies.ImportECDSAPublic(remotePubKey), sskLen, sskLen); err != nil {
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return
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}
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// tokenFlag = 0x00 // redundant
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} else {
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// for known peers, we use stored token from the previous session
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tokenFlag = 0x01
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}
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// the initiator nonce is read off the end of the message
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2015-01-19 01:53:45 +02:00
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initNonce = msg[msgLen-keyLen-1 : msgLen-1]
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// I prove that i own prv key (to derive shared secret, and read nonce off encrypted msg) and that I own shared secret
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// they prove they own the private key belonging to ecdhe-random-pubk
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2015-01-19 02:55:24 +02:00
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// we can now reconstruct the signed message and recover the peers pubkey
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var signedMsg = Xor(sessionToken, initNonce)
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2015-01-20 18:47:46 +02:00
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var remoteRandomPubKeyS []byte
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if remoteRandomPubKeyS, err = secp256k1.RecoverPubkey(signedMsg, msg[:sigLen]); err != nil {
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2015-01-18 11:46:08 +02:00
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return
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}
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2015-01-19 02:55:24 +02:00
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// convert to ECDSA standard
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2015-01-20 18:47:46 +02:00
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if remoteRandomPubKey, err = ImportPublicKey(remoteRandomPubKeyS); err != nil {
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2015-01-18 11:46:08 +02:00
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return
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}
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2015-01-19 01:53:45 +02:00
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2015-01-19 02:55:24 +02:00
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// now we find ourselves a long task too, fill it random
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var resp = make([]byte, resLen)
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// generate keyLen long nonce
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2015-01-20 18:47:46 +02:00
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respNonce = resp[pubLen : pubLen+keyLen]
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2015-01-19 01:53:45 +02:00
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if _, err = rand.Read(respNonce); err != nil {
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return
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}
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2015-01-19 02:55:24 +02:00
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// generate random keypair for session
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2015-01-20 01:42:13 +02:00
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if randomPrivKey, err = crypto.GenerateKey(); err != nil {
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2015-01-19 01:53:45 +02:00
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return
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}
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2015-01-19 02:55:24 +02:00
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// responder auth message
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2015-01-19 01:53:45 +02:00
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// E(remote-pubk, ecdhe-random-pubk || nonce || 0x0)
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2015-01-20 18:47:46 +02:00
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var randomPubKeyS []byte
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if randomPubKeyS, err = ExportPublicKey(&randomPrivKey.PublicKey); err != nil {
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return
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}
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copy(resp[:pubLen], randomPubKeyS)
|
2015-01-19 01:53:45 +02:00
|
|
|
// nonce is already in the slice
|
2015-01-19 02:55:24 +02:00
|
|
|
resp[resLen-1] = tokenFlag
|
2015-01-19 01:53:45 +02:00
|
|
|
|
|
|
|
// encrypt using remote-pubk
|
|
|
|
// auth = eciesEncrypt(remote-pubk, msg)
|
|
|
|
// why not encrypt with ecdhe-random-remote
|
|
|
|
if authResp, err = crypto.Encrypt(remotePubKey, resp); err != nil {
|
|
|
|
return
|
|
|
|
}
|
|
|
|
return
|
|
|
|
}
|
|
|
|
|
2015-01-21 12:22:07 +02:00
|
|
|
/*
|
|
|
|
completeHandshake is called when the initiator receives an authentication response (aka receiver handshake). It completes the handshake by reading off parameters the remote peer provides needed to set up the secure session
|
|
|
|
*/
|
2015-01-19 06:53:48 +02:00
|
|
|
func (self *cryptoId) completeHandshake(auth []byte) (respNonce []byte, remoteRandomPubKey *ecdsa.PublicKey, tokenFlag bool, err error) {
|
2015-01-19 01:53:45 +02:00
|
|
|
var msg []byte
|
|
|
|
// they prove that msg is meant for me,
|
|
|
|
// I prove I possess private key if i can read it
|
|
|
|
if msg, err = crypto.Decrypt(self.prvKey, auth); err != nil {
|
|
|
|
return
|
|
|
|
}
|
|
|
|
|
2015-01-20 18:47:46 +02:00
|
|
|
respNonce = msg[pubLen : pubLen+keyLen]
|
|
|
|
var remoteRandomPubKeyS = msg[:pubLen]
|
|
|
|
if remoteRandomPubKey, err = ImportPublicKey(remoteRandomPubKeyS); err != nil {
|
2015-01-19 01:53:45 +02:00
|
|
|
return
|
|
|
|
}
|
|
|
|
if msg[resLen-1] == 0x01 {
|
|
|
|
tokenFlag = true
|
|
|
|
}
|
|
|
|
return
|
|
|
|
}
|
|
|
|
|
2015-01-21 12:22:07 +02:00
|
|
|
/*
|
|
|
|
newSession is called after the handshake is completed. The arguments are values negotiated in the handshake and the return value is a new session : a new session Token to be remembered for the next time we connect with this peer. And a MsgReadWriter that implements an encrypted and authenticated connection with key material obtained from the crypto handshake key exchange
|
|
|
|
*/
|
2015-01-19 06:53:48 +02:00
|
|
|
func (self *cryptoId) newSession(initNonce, respNonce, auth []byte, privKey *ecdsa.PrivateKey, remoteRandomPubKey *ecdsa.PublicKey) (sessionToken []byte, rw *secretRW, err error) {
|
2015-01-19 01:53:45 +02:00
|
|
|
// 3) Now we can trust ecdhe-random-pubk to derive new keys
|
2015-01-18 11:46:08 +02:00
|
|
|
//ecdhe-shared-secret = ecdh.agree(ecdhe-random, remote-ecdhe-random-pubk)
|
|
|
|
var dhSharedSecret []byte
|
2015-01-19 06:53:48 +02:00
|
|
|
pubKey := ecies.ImportECDSAPublic(remoteRandomPubKey)
|
|
|
|
if dhSharedSecret, err = ecies.ImportECDSA(privKey).GenerateShared(pubKey, sskLen, sskLen); err != nil {
|
2015-01-18 11:46:08 +02:00
|
|
|
return
|
|
|
|
}
|
|
|
|
// shared-secret = crypto.Sha3(ecdhe-shared-secret || crypto.Sha3(nonce || initiator-nonce))
|
2015-01-19 01:53:45 +02:00
|
|
|
var sharedSecret = crypto.Sha3(append(dhSharedSecret, crypto.Sha3(append(respNonce, initNonce...))...))
|
2015-01-18 11:46:08 +02:00
|
|
|
// token = crypto.Sha3(shared-secret)
|
|
|
|
sessionToken = crypto.Sha3(sharedSecret)
|
|
|
|
// aes-secret = crypto.Sha3(ecdhe-shared-secret || shared-secret)
|
|
|
|
var aesSecret = crypto.Sha3(append(dhSharedSecret, sharedSecret...))
|
|
|
|
// # destroy shared-secret
|
|
|
|
// mac-secret = crypto.Sha3(ecdhe-shared-secret || aes-secret)
|
|
|
|
var macSecret = crypto.Sha3(append(dhSharedSecret, aesSecret...))
|
|
|
|
// # destroy ecdhe-shared-secret
|
|
|
|
// egress-mac = crypto.Sha3(mac-secret^nonce || auth)
|
2015-01-19 01:53:45 +02:00
|
|
|
var egressMac = crypto.Sha3(append(Xor(macSecret, respNonce), auth...))
|
2015-01-18 11:46:08 +02:00
|
|
|
// # destroy nonce
|
|
|
|
// ingress-mac = crypto.Sha3(mac-secret^initiator-nonce || auth),
|
2015-01-19 01:53:45 +02:00
|
|
|
var ingressMac = crypto.Sha3(append(Xor(macSecret, initNonce), auth...))
|
2015-01-18 11:46:08 +02:00
|
|
|
// # destroy remote-nonce
|
|
|
|
rw = &secretRW{
|
|
|
|
aesSecret: aesSecret,
|
|
|
|
macSecret: macSecret,
|
|
|
|
egressMac: egressMac,
|
|
|
|
ingressMac: ingressMac,
|
|
|
|
}
|
|
|
|
return
|
|
|
|
}
|
|
|
|
|
2015-01-21 12:22:07 +02:00
|
|
|
// TODO: optimisation
|
2015-01-19 01:53:45 +02:00
|
|
|
// should use cipher.xorBytes from crypto/cipher/xor.go for fast xor
|
2015-01-18 11:46:08 +02:00
|
|
|
func Xor(one, other []byte) (xor []byte) {
|
2015-01-19 01:53:45 +02:00
|
|
|
xor = make([]byte, len(one))
|
2015-01-18 11:46:08 +02:00
|
|
|
for i := 0; i < len(one); i++ {
|
|
|
|
xor[i] = one[i] ^ other[i]
|
|
|
|
}
|
|
|
|
return
|
|
|
|
}
|