// Copyright 2011 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. package packet import ( "bytes" "crypto/cipher" "crypto/dsa" "crypto/ecdsa" "crypto/sha1" "fmt" "io" "io/ioutil" "math/big" "strconv" "time" "github.com/keybase/go-crypto/ed25519" "github.com/keybase/go-crypto/openpgp/ecdh" "github.com/keybase/go-crypto/openpgp/elgamal" "github.com/keybase/go-crypto/openpgp/errors" "github.com/keybase/go-crypto/openpgp/s2k" "github.com/keybase/go-crypto/rsa" ) // PrivateKey represents a possibly encrypted private key. See RFC 4880, // section 5.5.3. type PrivateKey struct { PublicKey Encrypted bool // if true then the private key is unavailable until Decrypt has been called. encryptedData []byte cipher CipherFunction s2k func(out, in []byte) PrivateKey interface{} // An *rsa.PrivateKey or *dsa.PrivateKey. sha1Checksum bool iv []byte s2kHeader []byte } type EdDSAPrivateKey struct { PrivateKey seed parsedMPI } func (e *EdDSAPrivateKey) Seed() []byte { return e.seed.bytes } func (e *EdDSAPrivateKey) Sign(digest []byte) (R, S []byte, err error) { r := bytes.NewReader(e.seed.bytes) publicKey, privateKey, err := ed25519.GenerateKey(r) if err != nil { return nil, nil, err } if !bytes.Equal(publicKey, e.PublicKey.edk.p.bytes[1:]) { // [1:] because [0] is 0x40 mpi header return nil, nil, errors.UnsupportedError("EdDSA: Private key does not match public key.") } sig := ed25519.Sign(privateKey, digest) sigLen := ed25519.SignatureSize / 2 return sig[:sigLen], sig[sigLen:], nil } func NewRSAPrivateKey(currentTime time.Time, priv *rsa.PrivateKey) *PrivateKey { pk := new(PrivateKey) pk.PublicKey = *NewRSAPublicKey(currentTime, &priv.PublicKey) pk.PrivateKey = priv return pk } func NewDSAPrivateKey(currentTime time.Time, priv *dsa.PrivateKey) *PrivateKey { pk := new(PrivateKey) pk.PublicKey = *NewDSAPublicKey(currentTime, &priv.PublicKey) pk.PrivateKey = priv return pk } func NewElGamalPrivateKey(currentTime time.Time, priv *elgamal.PrivateKey) *PrivateKey { pk := new(PrivateKey) pk.PublicKey = *NewElGamalPublicKey(currentTime, &priv.PublicKey) pk.PrivateKey = priv return pk } func NewECDSAPrivateKey(currentTime time.Time, priv *ecdsa.PrivateKey) *PrivateKey { pk := new(PrivateKey) pk.PublicKey = *NewECDSAPublicKey(currentTime, &priv.PublicKey) pk.PrivateKey = priv return pk } func NewECDHPrivateKey(currentTime time.Time, priv *ecdh.PrivateKey) *PrivateKey { pk := new(PrivateKey) pk.PublicKey = *NewECDHPublicKey(currentTime, &priv.PublicKey) pk.PrivateKey = priv return pk } func (pk *PrivateKey) parse(r io.Reader) (err error) { err = (&pk.PublicKey).parse(r) if err != nil { return } var buf [1]byte _, err = readFull(r, buf[:]) if err != nil { return } s2kType := buf[0] switch s2kType { case 0: pk.s2k = nil pk.Encrypted = false case 254, 255: _, err = readFull(r, buf[:]) if err != nil { return } pk.cipher = CipherFunction(buf[0]) pk.Encrypted = true pk.s2k, err = s2k.Parse(r) if err != nil { return } if s2kType == 254 { pk.sha1Checksum = true } // S2K == nil implies that we got a "GNU Dummy" S2K. For instance, // because our master secret key is on a USB key in a vault somewhere. // In that case, there is no further data to consume here. if pk.s2k == nil { pk.Encrypted = false return } default: return errors.UnsupportedError("deprecated s2k function in private key") } if pk.Encrypted { blockSize := pk.cipher.blockSize() if blockSize == 0 { return errors.UnsupportedError("unsupported cipher in private key: " + strconv.Itoa(int(pk.cipher))) } pk.iv = make([]byte, blockSize) _, err = readFull(r, pk.iv) if err != nil { return } } pk.encryptedData, err = ioutil.ReadAll(r) if err != nil { return } if !pk.Encrypted { return pk.parsePrivateKey(pk.encryptedData) } return } func mod64kHash(d []byte) uint16 { var h uint16 for _, b := range d { h += uint16(b) } return h } // Encrypt is the counterpart to the Decrypt() method below. It encrypts // the private key with the provided passphrase. If config is nil, then // the standard, and sensible, defaults apply. // // A key will be derived from the given passphrase using S2K Specifier // Type 3 (Iterated + Salted, see RFC-4880 Sec. 3.7.1.3). This choice // is hardcoded in s2k.Serialize(). S2KCount is hardcoded to 0, which is // equivalent to 65536. And the hash algorithm for key-derivation can be // set with config. The encrypted PrivateKey, using the algorithm specified // in config (if provided), is written out to the encryptedData member. // When Serialize() is called, this encryptedData member will be // serialized, using S2K Usage value of 254, and thus SHA1 checksum. func (pk *PrivateKey) Encrypt(passphrase []byte, config *Config) (err error) { if pk.PrivateKey == nil { return errors.InvalidArgumentError("there is no private key to encrypt") } pk.sha1Checksum = true pk.cipher = config.Cipher() s2kConfig := s2k.Config{ Hash: config.Hash(), S2KCount: 0, } s2kBuf := bytes.NewBuffer(nil) derivedKey := make([]byte, pk.cipher.KeySize()) err = s2k.Serialize(s2kBuf, derivedKey, config.Random(), passphrase, &s2kConfig) if err != nil { return err } pk.s2kHeader = s2kBuf.Bytes() // No good way to set pk.s2k but to call s2k.Parse(), // even though we have all the information here, but // most of the functions needed are private to s2k. pk.s2k, err = s2k.Parse(s2kBuf) pk.iv = make([]byte, pk.cipher.blockSize()) if _, err = config.Random().Read(pk.iv); err != nil { return err } privateKeyBuf := bytes.NewBuffer(nil) if err = pk.serializePrivateKey(privateKeyBuf); err != nil { return err } checksum := sha1.Sum(privateKeyBuf.Bytes()) if _, err = privateKeyBuf.Write(checksum[:]); err != nil { return err } pkData := privateKeyBuf.Bytes() block := pk.cipher.new(derivedKey) pk.encryptedData = make([]byte, len(pkData)) cfb := cipher.NewCFBEncrypter(block, pk.iv) cfb.XORKeyStream(pk.encryptedData, pkData) pk.Encrypted = true return nil } func (pk *PrivateKey) Serialize(w io.Writer) (err error) { buf := bytes.NewBuffer(nil) err = pk.PublicKey.serializeWithoutHeaders(buf) if err != nil { return } privateKeyBuf := bytes.NewBuffer(nil) if pk.PrivateKey == nil { _, err = buf.Write([]byte{ 254, // SHA-1 Convention 9, // Encryption scheme (AES256) 101, // GNU Extensions 2, // Hash value (SHA1) 'G', 'N', 'U', // "GNU" as a string 1, // Extension type 1001 (minus 1000) }) } else if pk.Encrypted { _, err = buf.Write([]byte{ 254, // SHA-1 Convention byte(pk.cipher), // Encryption scheme }) if err != nil { return err } if _, err = buf.Write(pk.s2kHeader); err != nil { return err } if _, err = buf.Write(pk.iv); err != nil { return err } if _, err = privateKeyBuf.Write(pk.encryptedData); err != nil { return err } } else { buf.WriteByte(0 /* no encryption */) if err = pk.serializePrivateKey(privateKeyBuf); err != nil { return err } } ptype := packetTypePrivateKey contents := buf.Bytes() privateKeyBytes := privateKeyBuf.Bytes() if pk.IsSubkey { ptype = packetTypePrivateSubkey } totalLen := len(contents) + len(privateKeyBytes) if !pk.Encrypted { totalLen += 2 } err = serializeHeader(w, ptype, totalLen) if err != nil { return } _, err = w.Write(contents) if err != nil { return } _, err = w.Write(privateKeyBytes) if err != nil { return } if len(privateKeyBytes) > 0 && !pk.Encrypted { checksum := mod64kHash(privateKeyBytes) var checksumBytes [2]byte checksumBytes[0] = byte(checksum >> 8) checksumBytes[1] = byte(checksum) _, err = w.Write(checksumBytes[:]) } return } func (pk *PrivateKey) serializePrivateKey(w io.Writer) (err error) { switch priv := pk.PrivateKey.(type) { case *rsa.PrivateKey: err = serializeRSAPrivateKey(w, priv) case *dsa.PrivateKey: err = serializeDSAPrivateKey(w, priv) case *elgamal.PrivateKey: err = serializeElGamalPrivateKey(w, priv) case *ecdsa.PrivateKey: err = serializeECDSAPrivateKey(w, priv) case *ecdh.PrivateKey: err = serializeECDHPrivateKey(w, priv) case *EdDSAPrivateKey: err = serializeEdDSAPrivateKey(w, priv) default: err = errors.InvalidArgumentError("unknown private key type") } return err } func serializeRSAPrivateKey(w io.Writer, priv *rsa.PrivateKey) error { err := writeBig(w, priv.D) if err != nil { return err } err = writeBig(w, priv.Primes[1]) if err != nil { return err } err = writeBig(w, priv.Primes[0]) if err != nil { return err } return writeBig(w, priv.Precomputed.Qinv) } func serializeDSAPrivateKey(w io.Writer, priv *dsa.PrivateKey) error { return writeBig(w, priv.X) } func serializeElGamalPrivateKey(w io.Writer, priv *elgamal.PrivateKey) error { return writeBig(w, priv.X) } func serializeECDSAPrivateKey(w io.Writer, priv *ecdsa.PrivateKey) error { return writeBig(w, priv.D) } func serializeECDHPrivateKey(w io.Writer, priv *ecdh.PrivateKey) error { return writeBig(w, priv.X) } func serializeEdDSAPrivateKey(w io.Writer, priv *EdDSAPrivateKey) error { return writeMPI(w, priv.seed.bitLength, priv.seed.bytes) } // Decrypt decrypts an encrypted private key using a passphrase. func (pk *PrivateKey) Decrypt(passphrase []byte) error { if !pk.Encrypted { return nil } // For GNU Dummy S2K, there's no key here, so don't do anything. if pk.s2k == nil { return nil } key := make([]byte, pk.cipher.KeySize()) pk.s2k(key, passphrase) block := pk.cipher.new(key) cfb := cipher.NewCFBDecrypter(block, pk.iv) data := make([]byte, len(pk.encryptedData)) cfb.XORKeyStream(data, pk.encryptedData) if pk.sha1Checksum { if len(data) < sha1.Size { return errors.StructuralError("truncated private key data") } h := sha1.New() h.Write(data[:len(data)-sha1.Size]) sum := h.Sum(nil) if !bytes.Equal(sum, data[len(data)-sha1.Size:]) { return errors.StructuralError("private key checksum failure") } data = data[:len(data)-sha1.Size] } else { if len(data) < 2 { return errors.StructuralError("truncated private key data") } var sum uint16 for i := 0; i < len(data)-2; i++ { sum += uint16(data[i]) } if data[len(data)-2] != uint8(sum>>8) || data[len(data)-1] != uint8(sum) { return errors.StructuralError("private key checksum failure") } data = data[:len(data)-2] } return pk.parsePrivateKey(data) } func (pk *PrivateKey) parsePrivateKey(data []byte) (err error) { switch pk.PublicKey.PubKeyAlgo { case PubKeyAlgoRSA, PubKeyAlgoRSASignOnly, PubKeyAlgoRSAEncryptOnly: return pk.parseRSAPrivateKey(data) case PubKeyAlgoDSA: return pk.parseDSAPrivateKey(data) case PubKeyAlgoElGamal: return pk.parseElGamalPrivateKey(data) case PubKeyAlgoECDSA: return pk.parseECDSAPrivateKey(data) case PubKeyAlgoECDH: return pk.parseECDHPrivateKey(data) case PubKeyAlgoEdDSA: return pk.parseEdDSAPrivateKey(data) case PubKeyAlgoBadElGamal: return errors.UnsupportedError("parsing el-gamal sign-or-encrypt privatekeys is unsupported") default: return errors.UnsupportedError("cannot parse this private key type") } } func (pk *PrivateKey) parseRSAPrivateKey(data []byte) (err error) { rsaPub := pk.PublicKey.PublicKey.(*rsa.PublicKey) rsaPriv := new(rsa.PrivateKey) rsaPriv.PublicKey = *rsaPub buf := bytes.NewBuffer(data) d, _, err := readMPI(buf) if err != nil { return } p, _, err := readMPI(buf) if err != nil { return } q, _, err := readMPI(buf) if err != nil { return } rsaPriv.D = new(big.Int).SetBytes(d) rsaPriv.Primes = make([]*big.Int, 2) rsaPriv.Primes[0] = new(big.Int).SetBytes(p) rsaPriv.Primes[1] = new(big.Int).SetBytes(q) if err := rsaPriv.Validate(); err != nil { return err } rsaPriv.Precompute() pk.PrivateKey = rsaPriv pk.Encrypted = false pk.encryptedData = nil return nil } func (pk *PrivateKey) parseDSAPrivateKey(data []byte) (err error) { dsaPub := pk.PublicKey.PublicKey.(*dsa.PublicKey) dsaPriv := new(dsa.PrivateKey) dsaPriv.PublicKey = *dsaPub buf := bytes.NewBuffer(data) x, _, err := readMPI(buf) if err != nil { return } dsaPriv.X = new(big.Int).SetBytes(x) pk.PrivateKey = dsaPriv pk.Encrypted = false pk.encryptedData = nil return nil } func (pk *PrivateKey) parseElGamalPrivateKey(data []byte) (err error) { pub := pk.PublicKey.PublicKey.(*elgamal.PublicKey) priv := new(elgamal.PrivateKey) priv.PublicKey = *pub buf := bytes.NewBuffer(data) x, _, err := readMPI(buf) if err != nil { return } priv.X = new(big.Int).SetBytes(x) pk.PrivateKey = priv pk.Encrypted = false pk.encryptedData = nil return nil } func (pk *PrivateKey) parseECDHPrivateKey(data []byte) (err error) { pub := pk.PublicKey.PublicKey.(*ecdh.PublicKey) priv := new(ecdh.PrivateKey) priv.PublicKey = *pub buf := bytes.NewBuffer(data) d, _, err := readMPI(buf) if err != nil { return } priv.X = new(big.Int).SetBytes(d) pk.PrivateKey = priv pk.Encrypted = false pk.encryptedData = nil return nil } func (pk *PrivateKey) parseECDSAPrivateKey(data []byte) (err error) { ecdsaPub := pk.PublicKey.PublicKey.(*ecdsa.PublicKey) ecdsaPriv := new(ecdsa.PrivateKey) ecdsaPriv.PublicKey = *ecdsaPub buf := bytes.NewBuffer(data) d, _, err := readMPI(buf) if err != nil { return } ecdsaPriv.D = new(big.Int).SetBytes(d) pk.PrivateKey = ecdsaPriv pk.Encrypted = false pk.encryptedData = nil return nil } func (pk *PrivateKey) parseEdDSAPrivateKey(data []byte) (err error) { eddsaPriv := new(EdDSAPrivateKey) eddsaPriv.PublicKey = pk.PublicKey buf := bytes.NewBuffer(data) eddsaPriv.seed.bytes, eddsaPriv.seed.bitLength, err = readMPI(buf) if err != nil { return err } if bLen := len(eddsaPriv.seed.bytes); bLen != 32 { // 32 bytes private part of ed25519 key. return errors.UnsupportedError(fmt.Sprintf("Unexpected EdDSA private key length: %d", bLen)) } pk.PrivateKey = eddsaPriv pk.Encrypted = false pk.encryptedData = nil return nil }