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secret_connection.go
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secret_connection.go
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// Uses nacl's secret_box to encrypt a net.Conn.
// It is (meant to be) an implementation of the STS protocol.
// Note we do not (yet) assume that a remote peer's pubkey
// is known ahead of time, and thus we are technically
// still vulnerable to MITM. (TODO!)
// See docs/sts-final.pdf for more info
package conn
import (
"bytes"
crand "crypto/rand"
"crypto/sha256"
"encoding/binary"
"errors"
"io"
"net"
"time"
"golang.org/x/crypto/nacl/box"
"golang.org/x/crypto/nacl/secretbox"
"golang.org/x/crypto/ripemd160"
"github.com/tendermint/go-crypto"
cmn "github.com/tendermint/tmlibs/common"
)
// 4 + 1024 == 1028 total frame size
const dataLenSize = 4
const dataMaxSize = 1024
const totalFrameSize = dataMaxSize + dataLenSize
const sealedFrameSize = totalFrameSize + secretbox.Overhead
// Implements net.Conn
type SecretConnection struct {
conn io.ReadWriteCloser
recvBuffer []byte
recvNonce *[24]byte
sendNonce *[24]byte
remPubKey crypto.PubKey
shrSecret *[32]byte // shared secret
}
// Performs handshake and returns a new authenticated SecretConnection.
// Returns nil if error in handshake.
// Caller should call conn.Close()
// See docs/sts-final.pdf for more information.
func MakeSecretConnection(conn io.ReadWriteCloser, locPrivKey crypto.PrivKey) (*SecretConnection, error) {
locPubKey := locPrivKey.PubKey()
// Generate ephemeral keys for perfect forward secrecy.
locEphPub, locEphPriv := genEphKeys()
// Write local ephemeral pubkey and receive one too.
// NOTE: every 32-byte string is accepted as a Curve25519 public key
// (see DJB's Curve25519 paper: http://cr.yp.to/ecdh/curve25519-20060209.pdf)
remEphPub, err := shareEphPubKey(conn, locEphPub)
if err != nil {
return nil, err
}
// Compute common shared secret.
shrSecret := computeSharedSecret(remEphPub, locEphPriv)
// Sort by lexical order.
loEphPub, hiEphPub := sort32(locEphPub, remEphPub)
// Check if the local ephemeral public key
// was the least, lexicographically sorted.
locIsLeast := bytes.Equal(locEphPub[:], loEphPub[:])
// Generate nonces to use for secretbox.
recvNonce, sendNonce := genNonces(loEphPub, hiEphPub, locIsLeast)
// Generate common challenge to sign.
challenge := genChallenge(loEphPub, hiEphPub)
// Construct SecretConnection.
sc := &SecretConnection{
conn: conn,
recvBuffer: nil,
recvNonce: recvNonce,
sendNonce: sendNonce,
shrSecret: shrSecret,
}
// Sign the challenge bytes for authentication.
locSignature := signChallenge(challenge, locPrivKey)
// Share (in secret) each other's pubkey & challenge signature
authSigMsg, err := shareAuthSignature(sc, locPubKey, locSignature)
if err != nil {
return nil, err
}
remPubKey, remSignature := authSigMsg.Key, authSigMsg.Sig
if !remPubKey.VerifyBytes(challenge[:], remSignature) {
return nil, errors.New("Challenge verification failed")
}
// We've authorized.
sc.remPubKey = remPubKey
return sc, nil
}
// Returns authenticated remote pubkey
func (sc *SecretConnection) RemotePubKey() crypto.PubKey {
return sc.remPubKey
}
// Writes encrypted frames of `sealedFrameSize`
// CONTRACT: data smaller than dataMaxSize is read atomically.
func (sc *SecretConnection) Write(data []byte) (n int, err error) {
for 0 < len(data) {
var frame = make([]byte, totalFrameSize)
var chunk []byte
if dataMaxSize < len(data) {
chunk = data[:dataMaxSize]
data = data[dataMaxSize:]
} else {
chunk = data
data = nil
}
chunkLength := len(chunk)
binary.BigEndian.PutUint32(frame, uint32(chunkLength))
copy(frame[dataLenSize:], chunk)
// encrypt the frame
var sealedFrame = make([]byte, sealedFrameSize)
secretbox.Seal(sealedFrame[:0], frame, sc.sendNonce, sc.shrSecret)
// fmt.Printf("secretbox.Seal(sealed:%X,sendNonce:%X,shrSecret:%X\n", sealedFrame, sc.sendNonce, sc.shrSecret)
incr2Nonce(sc.sendNonce)
// end encryption
_, err := sc.conn.Write(sealedFrame)
if err != nil {
return n, err
}
n += len(chunk)
}
return
}
// CONTRACT: data smaller than dataMaxSize is read atomically.
func (sc *SecretConnection) Read(data []byte) (n int, err error) {
if 0 < len(sc.recvBuffer) {
n = copy(data, sc.recvBuffer)
sc.recvBuffer = sc.recvBuffer[n:]
return
}
sealedFrame := make([]byte, sealedFrameSize)
_, err = io.ReadFull(sc.conn, sealedFrame)
if err != nil {
return
}
// decrypt the frame
var frame = make([]byte, totalFrameSize)
// fmt.Printf("secretbox.Open(sealed:%X,recvNonce:%X,shrSecret:%X\n", sealedFrame, sc.recvNonce, sc.shrSecret)
_, ok := secretbox.Open(frame[:0], sealedFrame, sc.recvNonce, sc.shrSecret)
if !ok {
return n, errors.New("Failed to decrypt SecretConnection")
}
incr2Nonce(sc.recvNonce)
// end decryption
var chunkLength = binary.BigEndian.Uint32(frame) // read the first two bytes
if chunkLength > dataMaxSize {
return 0, errors.New("chunkLength is greater than dataMaxSize")
}
var chunk = frame[dataLenSize : dataLenSize+chunkLength]
n = copy(data, chunk)
sc.recvBuffer = chunk[n:]
return
}
// Implements net.Conn
func (sc *SecretConnection) Close() error { return sc.conn.Close() }
func (sc *SecretConnection) LocalAddr() net.Addr { return sc.conn.(net.Conn).LocalAddr() }
func (sc *SecretConnection) RemoteAddr() net.Addr { return sc.conn.(net.Conn).RemoteAddr() }
func (sc *SecretConnection) SetDeadline(t time.Time) error { return sc.conn.(net.Conn).SetDeadline(t) }
func (sc *SecretConnection) SetReadDeadline(t time.Time) error {
return sc.conn.(net.Conn).SetReadDeadline(t)
}
func (sc *SecretConnection) SetWriteDeadline(t time.Time) error {
return sc.conn.(net.Conn).SetWriteDeadline(t)
}
func genEphKeys() (ephPub, ephPriv *[32]byte) {
var err error
ephPub, ephPriv, err = box.GenerateKey(crand.Reader)
if err != nil {
panic("Could not generate ephemeral keypairs")
}
return
}
func shareEphPubKey(conn io.ReadWriteCloser, locEphPub *[32]byte) (remEphPub *[32]byte, err error) {
// Send our pubkey and receive theirs in tandem.
var trs, _ = cmn.Parallel(
func(_ int) (val interface{}, err error, abort bool) {
var _, err1 = cdc.MarshalBinaryWriter(conn, locEphPub)
if err1 != nil {
return nil, err1, true // abort
} else {
return nil, nil, false
}
},
func(_ int) (val interface{}, err error, abort bool) {
var _remEphPub [32]byte
var _, err2 = cdc.UnmarshalBinaryReader(conn, &_remEphPub, 1024*1024) // TODO
if err2 != nil {
return nil, err2, true // abort
} else {
return _remEphPub, nil, false
}
},
)
// If error:
if trs.FirstError() != nil {
err = trs.FirstError()
return
}
// Otherwise:
var _remEphPub = trs.FirstValue().([32]byte)
return &_remEphPub, nil
}
func computeSharedSecret(remPubKey, locPrivKey *[32]byte) (shrSecret *[32]byte) {
shrSecret = new([32]byte)
box.Precompute(shrSecret, remPubKey, locPrivKey)
return
}
func sort32(foo, bar *[32]byte) (lo, hi *[32]byte) {
if bytes.Compare(foo[:], bar[:]) < 0 {
lo = foo
hi = bar
} else {
lo = bar
hi = foo
}
return
}
func genNonces(loPubKey, hiPubKey *[32]byte, locIsLo bool) (recvNonce, sendNonce *[24]byte) {
nonce1 := hash24(append(loPubKey[:], hiPubKey[:]...))
nonce2 := new([24]byte)
copy(nonce2[:], nonce1[:])
nonce2[len(nonce2)-1] ^= 0x01
if locIsLo {
recvNonce = nonce1
sendNonce = nonce2
} else {
recvNonce = nonce2
sendNonce = nonce1
}
return
}
func genChallenge(loPubKey, hiPubKey *[32]byte) (challenge *[32]byte) {
return hash32(append(loPubKey[:], hiPubKey[:]...))
}
func signChallenge(challenge *[32]byte, locPrivKey crypto.PrivKey) (signature crypto.Signature) {
signature = locPrivKey.Sign(challenge[:])
return
}
type authSigMessage struct {
Key crypto.PubKey
Sig crypto.Signature
}
func shareAuthSignature(sc *SecretConnection, pubKey crypto.PubKey, signature crypto.Signature) (recvMsg authSigMessage, err error) {
// Send our info and receive theirs in tandem.
var trs, _ = cmn.Parallel(
func(_ int) (val interface{}, err error, abort bool) {
var _, err1 = cdc.MarshalBinaryWriter(sc, authSigMessage{pubKey, signature})
if err1 != nil {
return nil, err1, true // abort
} else {
return nil, nil, false
}
},
func(_ int) (val interface{}, err error, abort bool) {
var _recvMsg authSigMessage
var _, err2 = cdc.UnmarshalBinaryReader(sc, &_recvMsg, 1024*1024) // TODO
if err2 != nil {
return nil, err2, true // abort
} else {
return _recvMsg, nil, false
}
},
)
// If error:
if trs.FirstError() != nil {
err = trs.FirstError()
return
}
var _recvMsg = trs.FirstValue().(authSigMessage)
return _recvMsg, nil
}
//--------------------------------------------------------------------------------
// sha256
func hash32(input []byte) (res *[32]byte) {
hasher := sha256.New()
hasher.Write(input) // nolint: errcheck, gas
resSlice := hasher.Sum(nil)
res = new([32]byte)
copy(res[:], resSlice)
return
}
// We only fill in the first 20 bytes with ripemd160
func hash24(input []byte) (res *[24]byte) {
hasher := ripemd160.New()
hasher.Write(input) // nolint: errcheck, gas
resSlice := hasher.Sum(nil)
res = new([24]byte)
copy(res[:], resSlice)
return
}
// increment nonce big-endian by 2 with wraparound.
func incr2Nonce(nonce *[24]byte) {
incrNonce(nonce)
incrNonce(nonce)
}
// increment nonce big-endian by 1 with wraparound.
func incrNonce(nonce *[24]byte) {
for i := 23; 0 <= i; i-- {
nonce[i]++
if nonce[i] != 0 {
return
}
}
}