Beispiel #1
0
Datei: init.go Projekt: rht/ipget
// identityConfig initializes a new identity.
func identityConfig(out io.Writer, nbits int) (Identity, error) {
	// TODO guard higher up
	ident := Identity{}
	if nbits < 1024 {
		return ident, errors.New("Bitsize less than 1024 is considered unsafe.")
	}

	fmt.Fprintf(out, "generating %v-bit RSA keypair...", nbits)
	sk, pk, err := ci.GenerateKeyPair(ci.RSA, nbits)
	if err != nil {
		return ident, err
	}
	fmt.Fprintf(out, "done\n")

	// currently storing key unencrypted. in the future we need to encrypt it.
	// TODO(security)
	skbytes, err := sk.Bytes()
	if err != nil {
		return ident, err
	}
	ident.PrivKey = base64.StdEncoding.EncodeToString(skbytes)

	id, err := peer.IDFromPublicKey(pk)
	if err != nil {
		return ident, err
	}
	ident.PeerID = id.Pretty()
	fmt.Fprintf(out, "peer identity: %s\n", ident.PeerID)
	return ident, nil
}
Beispiel #2
0
func (mn *mocknet) AddPeer(k ic.PrivKey, a ma.Multiaddr) (host.Host, error) {
	p, err := peer.IDFromPublicKey(k.GetPublic())
	if err != nil {
		return nil, err
	}

	ps := peer.NewPeerstore()
	ps.AddAddr(p, a, peer.PermanentAddrTTL)
	ps.AddPrivKey(p, k)
	ps.AddPubKey(p, k.GetPublic())

	return mn.AddPeerWithPeerstore(p, ps)
}
Beispiel #3
0
Datei: gen.go Projekt: rht/ipget
func RandPeerNetParams() (*PeerNetParams, error) {
	var p PeerNetParams
	var err error
	p.Addr = ZeroLocalTCPAddress
	p.PrivKey, p.PubKey, err = RandTestKeyPair(512)
	if err != nil {
		return nil, err
	}
	p.ID, err = peer.IDFromPublicKey(p.PubKey)
	if err != nil {
		return nil, err
	}
	if err := p.checkKeys(); err != nil {
		return nil, err
	}
	return &p, nil
}
Beispiel #4
0
func (dht *IpfsDHT) getPublicKeyFromNode(ctx context.Context, p peer.ID) (ci.PubKey, error) {

	// check locally, just in case...
	pk := dht.peerstore.PubKey(p)
	if pk != nil {
		return pk, nil
	}

	pkkey := routing.KeyForPublicKey(p)
	pmes, err := dht.getValueSingle(ctx, p, pkkey)
	if err != nil {
		return nil, err
	}

	// node doesn't have key :(
	record := pmes.GetRecord()
	if record == nil {
		return nil, fmt.Errorf("node not responding with its public key: %s", p)
	}

	// Success! We were given the value. we don't need to check
	// validity because a) we can't. b) we know the hash of the
	// key we're looking for.
	val := record.GetValue()
	log.Debug("dht got a value from other peer.")

	pk, err = ci.UnmarshalPublicKey(val)
	if err != nil {
		return nil, err
	}

	id, err := peer.IDFromPublicKey(pk)
	if err != nil {
		return nil, err
	}
	if id != p {
		return nil, fmt.Errorf("public key does not match id: %s", p)
	}

	// ok! it's valid. we got it!
	log.Debugf("dht got public key from node itself.")
	return pk, nil
}
Beispiel #5
0
// runHandshake performs initial communication over insecure channel to share
// keys, IDs, and initiate communication, assigning all necessary params.
// requires the duplex channel to be a msgio.ReadWriter (for framed messaging)
func (s *secureSession) runHandshake() error {
	ctx, cancel := context.WithTimeout(s.ctx, HandshakeTimeout) // remove
	defer cancel()

	// =============================================================================
	// step 1. Propose -- propose cipher suite + send pubkeys + nonce

	// Generate and send Hello packet.
	// Hello = (rand, PublicKey, Supported)
	nonceOut := make([]byte, nonceSize)
	_, err := rand.Read(nonceOut)
	if err != nil {
		return err
	}

	defer log.EventBegin(ctx, "secureHandshake", s).Done()

	s.local.permanentPubKey = s.localKey.GetPublic()
	myPubKeyBytes, err := s.local.permanentPubKey.Bytes()
	if err != nil {
		return err
	}

	proposeOut := new(pb.Propose)
	proposeOut.Rand = nonceOut
	proposeOut.Pubkey = myPubKeyBytes
	proposeOut.Exchanges = &SupportedExchanges
	proposeOut.Ciphers = &SupportedCiphers
	proposeOut.Hashes = &SupportedHashes

	// log.Debugf("1.0 Propose: nonce:%s exchanges:%s ciphers:%s hashes:%s",
	// 	nonceOut, SupportedExchanges, SupportedCiphers, SupportedHashes)

	// Send Propose packet (respects ctx)
	proposeOutBytes, err := writeMsgCtx(ctx, s.insecureM, proposeOut)
	if err != nil {
		return err
	}

	// Receive + Parse their Propose packet and generate an Exchange packet.
	proposeIn := new(pb.Propose)
	proposeInBytes, err := readMsgCtx(ctx, s.insecureM, proposeIn)
	if err != nil {
		return err
	}

	// log.Debugf("1.0.1 Propose recv: nonce:%s exchanges:%s ciphers:%s hashes:%s",
	// 	proposeIn.GetRand(), proposeIn.GetExchanges(), proposeIn.GetCiphers(), proposeIn.GetHashes())

	// =============================================================================
	// step 1.1 Identify -- get identity from their key

	// get remote identity
	s.remote.permanentPubKey, err = ci.UnmarshalPublicKey(proposeIn.GetPubkey())
	if err != nil {
		return err
	}

	// get peer id
	s.remotePeer, err = peer.IDFromPublicKey(s.remote.permanentPubKey)
	if err != nil {
		return err
	}

	log.Debugf("1.1 Identify: %s Remote Peer Identified as %s", s.localPeer, s.remotePeer)

	// =============================================================================
	// step 1.2 Selection -- select/agree on best encryption parameters

	// to determine order, use cmp(H(remote_pubkey||local_rand), H(local_pubkey||remote_rand)).
	oh1 := u.Hash(append(proposeIn.GetPubkey(), nonceOut...))
	oh2 := u.Hash(append(myPubKeyBytes, proposeIn.GetRand()...))
	order := bytes.Compare(oh1, oh2)
	if order == 0 {
		return ErrEcho // talking to self (same socket. must be reuseport + dialing self)
	}

	s.local.curveT, err = selectBest(order, SupportedExchanges, proposeIn.GetExchanges())
	if err != nil {
		return err
	}

	s.local.cipherT, err = selectBest(order, SupportedCiphers, proposeIn.GetCiphers())
	if err != nil {
		return err
	}

	s.local.hashT, err = selectBest(order, SupportedHashes, proposeIn.GetHashes())
	if err != nil {
		return err
	}

	// we use the same params for both directions (must choose same curve)
	// WARNING: if they dont SelectBest the same way, this won't work...
	s.remote.curveT = s.local.curveT
	s.remote.cipherT = s.local.cipherT
	s.remote.hashT = s.local.hashT

	// log.Debugf("1.2 selection: exchange:%s cipher:%s hash:%s",
	// 	s.local.curveT, s.local.cipherT, s.local.hashT)

	// =============================================================================
	// step 2. Exchange -- exchange (signed) ephemeral keys. verify signatures.

	// Generate EphemeralPubKey
	var genSharedKey ci.GenSharedKey
	s.local.ephemeralPubKey, genSharedKey, err = ci.GenerateEKeyPair(s.local.curveT)

	// Gather corpus to sign.
	selectionOut := new(bytes.Buffer)
	selectionOut.Write(proposeOutBytes)
	selectionOut.Write(proposeInBytes)
	selectionOut.Write(s.local.ephemeralPubKey)
	selectionOutBytes := selectionOut.Bytes()

	// log.Debugf("2.0 exchange: %v", selectionOutBytes)
	exchangeOut := new(pb.Exchange)
	exchangeOut.Epubkey = s.local.ephemeralPubKey
	exchangeOut.Signature, err = s.localKey.Sign(selectionOutBytes)
	if err != nil {
		return err
	}

	// Send Propose packet (respects ctx)
	if _, err := writeMsgCtx(ctx, s.insecureM, exchangeOut); err != nil {
		return err
	}

	// Receive + Parse their Exchange packet.
	exchangeIn := new(pb.Exchange)
	if _, err := readMsgCtx(ctx, s.insecureM, exchangeIn); err != nil {
		return err
	}

	// =============================================================================
	// step 2.1. Verify -- verify their exchange packet is good.

	// get their ephemeral pub key
	s.remote.ephemeralPubKey = exchangeIn.GetEpubkey()

	selectionIn := new(bytes.Buffer)
	selectionIn.Write(proposeInBytes)
	selectionIn.Write(proposeOutBytes)
	selectionIn.Write(s.remote.ephemeralPubKey)
	selectionInBytes := selectionIn.Bytes()
	// log.Debugf("2.0.1 exchange recv: %v", selectionInBytes)

	// u.POut("Remote Peer Identified as %s\n", s.remote)
	sigOK, err := s.remote.permanentPubKey.Verify(selectionInBytes, exchangeIn.GetSignature())
	if err != nil {
		// log.Error("2.1 Verify: failed: %s", err)
		return err
	}

	if !sigOK {
		err := errors.New("Bad signature!")
		// log.Error("2.1 Verify: failed: %s", err)
		return err
	}
	// log.Debugf("2.1 Verify: signature verified.")

	// =============================================================================
	// step 2.2. Keys -- generate keys for mac + encryption

	// OK! seems like we're good to go.
	s.sharedSecret, err = genSharedKey(exchangeIn.GetEpubkey())
	if err != nil {
		return err
	}

	// generate two sets of keys (stretching)
	k1, k2 := ci.KeyStretcher(s.local.cipherT, s.local.hashT, s.sharedSecret)

	// use random nonces to decide order.
	switch {
	case order > 0:
		// just break
	case order < 0:
		k1, k2 = k2, k1 // swap
	default:
		// we should've bailed before this. but if not, bail here.
		return ErrEcho
	}
	s.local.keys = k1
	s.remote.keys = k2

	// log.Debug("2.2 keys:\n\tshared: %v\n\tk1: %v\n\tk2: %v",
	// 	s.sharedSecret, s.local.keys, s.remote.keys)

	// =============================================================================
	// step 2.3. MAC + Cipher -- prepare MAC + cipher

	if err := s.local.makeMacAndCipher(); err != nil {
		return err
	}

	if err := s.remote.makeMacAndCipher(); err != nil {
		return err
	}

	// log.Debug("2.3 mac + cipher.")

	// =============================================================================
	// step 3. Finish -- send expected message to verify encryption works (send local nonce)

	// setup ETM ReadWriter
	w := NewETMWriter(s.insecure, s.local.cipher, s.local.mac)
	r := NewETMReader(s.insecure, s.remote.cipher, s.remote.mac)
	s.secure = msgio.Combine(w, r).(msgio.ReadWriteCloser)

	// log.Debug("3.0 finish. sending: %v", proposeIn.GetRand())
	// send their Nonce.
	if _, err := s.secure.Write(proposeIn.GetRand()); err != nil {
		return fmt.Errorf("Failed to write Finish nonce: %s", err)
	}

	// read our Nonce
	nonceOut2 := make([]byte, len(nonceOut))
	if _, err := io.ReadFull(s.secure, nonceOut2); err != nil {
		return fmt.Errorf("Failed to read Finish nonce: %s", err)
	}

	// log.Debug("3.0 finish.\n\texpect: %v\n\tactual: %v", nonceOut, nonceOut2)
	if !bytes.Equal(nonceOut, nonceOut2) {
		return fmt.Errorf("Failed to read our encrypted nonce: %s != %s", nonceOut2, nonceOut)
	}

	// Whew! ok, that's all folks.
	return nil
}