openpgp/packet/public_key.go - crypto - Git at Google

 // 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"
 	"crypto/dsa"
 	"crypto/ecdsa"
 	"crypto/elliptic"
 	"crypto/rsa"
 	"crypto/sha1"
 	_ "crypto/sha256"
 	_ "crypto/sha512"
 	"encoding/binary"
 	"fmt"
 	"hash"
 	"io"
 	"math/big"
 	"strconv"
 	"time"

 	"golang.org/x/crypto/openpgp/elgamal"
 	"golang.org/x/crypto/openpgp/errors"
 )

 var (
 	// NIST curve P-256
 	oidCurveP256 []byte = []byte{0x2A, 0x86, 0x48, 0xCE, 0x3D, 0x03, 0x01, 0x07}
 	// NIST curve P-384
 	oidCurveP384 []byte = []byte{0x2B, 0x81, 0x04, 0x00, 0x22}
 	// NIST curve P-521
 	oidCurveP521 []byte = []byte{0x2B, 0x81, 0x04, 0x00, 0x23}
 )

 const maxOIDLength = 8

 // ecdsaKey stores the algorithm-specific fields for ECDSA keys.
 // as defined in RFC 6637, Section 9.
 type ecdsaKey struct {
 	// oid contains the OID byte sequence identifying the elliptic curve used
 	oid []byte
 	// p contains the elliptic curve point that represents the public key
 	p parsedMPI
 }

 // parseOID reads the OID for the curve as defined in RFC 6637, Section 9.
 func parseOID(r io.Reader) (oid []byte, err error) {
 	buf := make([]byte, maxOIDLength)
 	if _, err = readFull(r, buf[:1]); err != nil {
 		return
 	}
 	oidLen := buf[0]
 	if int(oidLen) > len(buf) {
 		err = errors.UnsupportedError("invalid oid length: " + strconv.Itoa(int(oidLen)))
 		return
 	}
 	oid = buf[:oidLen]
 	_, err = readFull(r, oid)
 	return
 }

 func (f *ecdsaKey) parse(r io.Reader) (err error) {
 	if f.oid, err = parseOID(r); err != nil {
 		return err
 	}
 	f.p.bytes, f.p.bitLength, err = readMPI(r)
 	return
 }

 func (f *ecdsaKey) serialize(w io.Writer) (err error) {
 	buf := make([]byte, maxOIDLength+1)
 	buf[0] = byte(len(f.oid))
 	copy(buf[1:], f.oid)
 	if _, err = w.Write(buf[:len(f.oid)+1]); err != nil {
 		return
 	}
 	return writeMPIs(w, f.p)
 }

 func (f *ecdsaKey) newECDSA() (*ecdsa.PublicKey, error) {
 	var c elliptic.Curve
 	if bytes.Equal(f.oid, oidCurveP256) {
 		c = elliptic.P256()
 	} else if bytes.Equal(f.oid, oidCurveP384) {
 		c = elliptic.P384()
 	} else if bytes.Equal(f.oid, oidCurveP521) {
 		c = elliptic.P521()
 	} else {
 		return nil, errors.UnsupportedError(fmt.Sprintf("unsupported oid: %x", f.oid))
 	}
 	x, y := elliptic.Unmarshal(c, f.p.bytes)
 	if x == nil {
 		return nil, errors.UnsupportedError("failed to parse EC point")
 	}
 	return &ecdsa.PublicKey{Curve: c, X: x, Y: y}, nil
 }

 func (f *ecdsaKey) byteLen() int {
 	return 1 + len(f.oid) + 2 + len(f.p.bytes)
 }

 type kdfHashFunction byte
 type kdfAlgorithm byte

 // ecdhKdf stores key derivation function parameters
 // used for ECDH encryption. See RFC 6637, Section 9.
 type ecdhKdf struct {
 	KdfHash kdfHashFunction
 	KdfAlgo kdfAlgorithm
 }

 func (f *ecdhKdf) parse(r io.Reader) (err error) {
 	buf := make([]byte, 1)
 	if _, err = readFull(r, buf); err != nil {
 		return
 	}
 	kdfLen := int(buf[0])
 	if kdfLen < 3 {
 		return errors.UnsupportedError("Unsupported ECDH KDF length: " + strconv.Itoa(kdfLen))
 	}
 	buf = make([]byte, kdfLen)
 	if _, err = readFull(r, buf); err != nil {
 		return
 	}
 	reserved := int(buf[0])
 	f.KdfHash = kdfHashFunction(buf[1])
 	f.KdfAlgo = kdfAlgorithm(buf[2])
 	if reserved != 0x01 {
 		return errors.UnsupportedError("Unsupported KDF reserved field: " + strconv.Itoa(reserved))
 	}
 	return
 }

 func (f *ecdhKdf) serialize(w io.Writer) (err error) {
 	buf := make([]byte, 4)
 	// See RFC 6637, Section 9, Algorithm-Specific Fields for ECDH keys.
 	buf[0] = byte(0x03) // Length of the following fields
 	buf[1] = byte(0x01) // Reserved for future extensions, must be 1 for now
 	buf[2] = byte(f.KdfHash)
 	buf[3] = byte(f.KdfAlgo)
 	_, err = w.Write(buf[:])
 	return
 }

 func (f *ecdhKdf) byteLen() int {
 	return 4
 }

 // PublicKey represents an OpenPGP public key. See RFC 4880, section 5.5.2.
 type PublicKey struct {
 	CreationTime time.Time
 	PubKeyAlgo   PublicKeyAlgorithm
 	PublicKey    interface{} // *rsa.PublicKey, *dsa.PublicKey or *ecdsa.PublicKey
 	Fingerprint  [20]byte
 	KeyId        uint64
 	IsSubkey     bool

 	n, e, p, q, g, y parsedMPI

 	// RFC 6637 fields
 	ec   *ecdsaKey
 	ecdh *ecdhKdf
 }

 // signingKey provides a convenient abstraction over signature verification
 // for v3 and v4 public keys.
 type signingKey interface {
 	SerializeSignaturePrefix(io.Writer)
 	serializeWithoutHeaders(io.Writer) error
 }

 func fromBig(n *big.Int) parsedMPI {
 	return parsedMPI{
 		bytes:     n.Bytes(),
 		bitLength: uint16(n.BitLen()),
 	}
 }

 // NewRSAPublicKey returns a PublicKey that wraps the given rsa.PublicKey.
 func NewRSAPublicKey(creationTime time.Time, pub *rsa.PublicKey) *PublicKey {
 	pk := &PublicKey{
 		CreationTime: creationTime,
 		PubKeyAlgo:   PubKeyAlgoRSA,
 		PublicKey:    pub,
 		n:            fromBig(pub.N),
 		e:            fromBig(big.NewInt(int64(pub.E))),
 	}

 	pk.setFingerPrintAndKeyId()
 	return pk
 }

 // NewDSAPublicKey returns a PublicKey that wraps the given dsa.PublicKey.
 func NewDSAPublicKey(creationTime time.Time, pub *dsa.PublicKey) *PublicKey {
 	pk := &PublicKey{
 		CreationTime: creationTime,
 		PubKeyAlgo:   PubKeyAlgoDSA,
 		PublicKey:    pub,
 		p:            fromBig(pub.P),
 		q:            fromBig(pub.Q),
 		g:            fromBig(pub.G),
 		y:            fromBig(pub.Y),
 	}

 	pk.setFingerPrintAndKeyId()
 	return pk
 }

 // NewElGamalPublicKey returns a PublicKey that wraps the given elgamal.PublicKey.
 func NewElGamalPublicKey(creationTime time.Time, pub *elgamal.PublicKey) *PublicKey {
 	pk := &PublicKey{
 		CreationTime: creationTime,
 		PubKeyAlgo:   PubKeyAlgoElGamal,
 		PublicKey:    pub,
 		p:            fromBig(pub.P),
 		g:            fromBig(pub.G),
 		y:            fromBig(pub.Y),
 	}

 	pk.setFingerPrintAndKeyId()
 	return pk
 }

 func NewECDSAPublicKey(creationTime time.Time, pub *ecdsa.PublicKey) *PublicKey {
 	pk := &PublicKey{
 		CreationTime: creationTime,
 		PubKeyAlgo:   PubKeyAlgoECDSA,
 		PublicKey:    pub,
 		ec:           new(ecdsaKey),
 	}

 	switch pub.Curve {
 	case elliptic.P256():
 		pk.ec.oid = oidCurveP256
 	case elliptic.P384():
 		pk.ec.oid = oidCurveP384
 	case elliptic.P521():
 		pk.ec.oid = oidCurveP521
 	default:
 		panic("unknown elliptic curve")
 	}

 	pk.ec.p.bytes = elliptic.Marshal(pub.Curve, pub.X, pub.Y)

 	// The bit length is 3 (for the 0x04 specifying an uncompressed key)
 	// plus two field elements (for x and y), which are rounded up to the
 	// nearest byte. See https://tools.ietf.org/html/rfc6637#section-6
 	fieldBytes := (pub.Curve.Params().BitSize + 7) & ^7
 	pk.ec.p.bitLength = uint16(3 + fieldBytes + fieldBytes)

 	pk.setFingerPrintAndKeyId()
 	return pk
 }

 func (pk *PublicKey) parse(r io.Reader) (err error) {
 	// RFC 4880, section 5.5.2
 	var buf [6]byte
 	_, err = readFull(r, buf[:])
 	if err != nil {
 		return
 	}
 	if buf[0] != 4 {
 		return errors.UnsupportedError("public key version")
 	}
 	pk.CreationTime = time.Unix(int64(uint32(buf[1])<<24|uint32(buf[2])<<16|uint32(buf[3])<<8|uint32(buf[4])), 0)
 	pk.PubKeyAlgo = PublicKeyAlgorithm(buf[5])
 	switch pk.PubKeyAlgo {
 	case PubKeyAlgoRSA, PubKeyAlgoRSAEncryptOnly, PubKeyAlgoRSASignOnly:
 		err = pk.parseRSA(r)
 	case PubKeyAlgoDSA:
 		err = pk.parseDSA(r)
 	case PubKeyAlgoElGamal:
 		err = pk.parseElGamal(r)
 	case PubKeyAlgoECDSA:
 		pk.ec = new(ecdsaKey)
 		if err = pk.ec.parse(r); err != nil {
 			return err
 		}
 		pk.PublicKey, err = pk.ec.newECDSA()
 	case PubKeyAlgoECDH:
 		pk.ec = new(ecdsaKey)
 		if err = pk.ec.parse(r); err != nil {
 			return
 		}
 		pk.ecdh = new(ecdhKdf)
 		if err = pk.ecdh.parse(r); err != nil {
 			return
 		}
 		// The ECDH key is stored in an ecdsa.PublicKey for convenience.
 		pk.PublicKey, err = pk.ec.newECDSA()
 	default:
 		err = errors.UnsupportedError("public key type: " + strconv.Itoa(int(pk.PubKeyAlgo)))
 	}
 	if err != nil {
 		return
 	}

 	pk.setFingerPrintAndKeyId()
 	return
 }

 func (pk *PublicKey) setFingerPrintAndKeyId() {
 	// RFC 4880, section 12.2
 	fingerPrint := sha1.New()
 	pk.SerializeSignaturePrefix(fingerPrint)
 	pk.serializeWithoutHeaders(fingerPrint)
 	copy(pk.Fingerprint[:], fingerPrint.Sum(nil))
 	pk.KeyId = binary.BigEndian.Uint64(pk.Fingerprint[12:20])
 }

 // parseRSA parses RSA public key material from the given Reader. See RFC 4880,
 // section 5.5.2.
 func (pk *PublicKey) parseRSA(r io.Reader) (err error) {
 	pk.n.bytes, pk.n.bitLength, err = readMPI(r)
 	if err != nil {
 		return
 	}
 	pk.e.bytes, pk.e.bitLength, err = readMPI(r)
 	if err != nil {
 		return
 	}

 	if len(pk.e.bytes) > 3 {
 		err = errors.UnsupportedError("large public exponent")
 		return
 	}
 	rsa := &rsa.PublicKey{
 		N: new(big.Int).SetBytes(pk.n.bytes),
 		E: 0,
 	}
 	for i := 0; i < len(pk.e.bytes); i++ {
 		rsa.E <<= 8
 		rsa.E |= int(pk.e.bytes[i])
 	}
 	pk.PublicKey = rsa
 	return
 }

 // parseDSA parses DSA public key material from the given Reader. See RFC 4880,
 // section 5.5.2.
 func (pk *PublicKey) parseDSA(r io.Reader) (err error) {
 	pk.p.bytes, pk.p.bitLength, err = readMPI(r)
 	if err != nil {
 		return
 	}
 	pk.q.bytes, pk.q.bitLength, err = readMPI(r)
 	if err != nil {
 		return
 	}
 	pk.g.bytes, pk.g.bitLength, err = readMPI(r)
 	if err != nil {
 		return
 	}
 	pk.y.bytes, pk.y.bitLength, err = readMPI(r)
 	if err != nil {
 		return
 	}

 	dsa := new(dsa.PublicKey)
 	dsa.P = new(big.Int).SetBytes(pk.p.bytes)
 	dsa.Q = new(big.Int).SetBytes(pk.q.bytes)
 	dsa.G = new(big.Int).SetBytes(pk.g.bytes)
 	dsa.Y = new(big.Int).SetBytes(pk.y.bytes)
 	pk.PublicKey = dsa
 	return
 }

 // parseElGamal parses ElGamal public key material from the given Reader. See
 // RFC 4880, section 5.5.2.
 func (pk *PublicKey) parseElGamal(r io.Reader) (err error) {
 	pk.p.bytes, pk.p.bitLength, err = readMPI(r)
 	if err != nil {
 		return
 	}
 	pk.g.bytes, pk.g.bitLength, err = readMPI(r)
 	if err != nil {
 		return
 	}
 	pk.y.bytes, pk.y.bitLength, err = readMPI(r)
 	if err != nil {
 		return
 	}

 	elgamal := new(elgamal.PublicKey)
 	elgamal.P = new(big.Int).SetBytes(pk.p.bytes)
 	elgamal.G = new(big.Int).SetBytes(pk.g.bytes)
 	elgamal.Y = new(big.Int).SetBytes(pk.y.bytes)
 	pk.PublicKey = elgamal
 	return
 }

 // SerializeSignaturePrefix writes the prefix for this public key to the given Writer.
 // The prefix is used when calculating a signature over this public key. See
 // RFC 4880, section 5.2.4.
 func (pk *PublicKey) SerializeSignaturePrefix(h io.Writer) {
 	var pLength uint16
 	switch pk.PubKeyAlgo {
 	case PubKeyAlgoRSA, PubKeyAlgoRSAEncryptOnly, PubKeyAlgoRSASignOnly:
 		pLength += 2 + uint16(len(pk.n.bytes))
 		pLength += 2 + uint16(len(pk.e.bytes))
 	case PubKeyAlgoDSA:
 		pLength += 2 + uint16(len(pk.p.bytes))
 		pLength += 2 + uint16(len(pk.q.bytes))
 		pLength += 2 + uint16(len(pk.g.bytes))
 		pLength += 2 + uint16(len(pk.y.bytes))
 	case PubKeyAlgoElGamal:
 		pLength += 2 + uint16(len(pk.p.bytes))
 		pLength += 2 + uint16(len(pk.g.bytes))
 		pLength += 2 + uint16(len(pk.y.bytes))
 	case PubKeyAlgoECDSA:
 		pLength += uint16(pk.ec.byteLen())
 	case PubKeyAlgoECDH:
 		pLength += uint16(pk.ec.byteLen())
 		pLength += uint16(pk.ecdh.byteLen())
 	default:
 		panic("unknown public key algorithm")
 	}
 	pLength += 6
 	h.Write([]byte{0x99, byte(pLength >> 8), byte(pLength)})
 	return
 }

 func (pk *PublicKey) Serialize(w io.Writer) (err error) {
 	length := 6 // 6 byte header

 	switch pk.PubKeyAlgo {
 	case PubKeyAlgoRSA, PubKeyAlgoRSAEncryptOnly, PubKeyAlgoRSASignOnly:
 		length += 2 + len(pk.n.bytes)
 		length += 2 + len(pk.e.bytes)
 	case PubKeyAlgoDSA:
 		length += 2 + len(pk.p.bytes)
 		length += 2 + len(pk.q.bytes)
 		length += 2 + len(pk.g.bytes)
 		length += 2 + len(pk.y.bytes)
 	case PubKeyAlgoElGamal:
 		length += 2 + len(pk.p.bytes)
 		length += 2 + len(pk.g.bytes)
 		length += 2 + len(pk.y.bytes)
 	case PubKeyAlgoECDSA:
 		length += pk.ec.byteLen()
 	case PubKeyAlgoECDH:
 		length += pk.ec.byteLen()
 		length += pk.ecdh.byteLen()
 	default:
 		panic("unknown public key algorithm")
 	}

 	packetType := packetTypePublicKey
 	if pk.IsSubkey {
 		packetType = packetTypePublicSubkey
 	}
 	err = serializeHeader(w, packetType, length)
 	if err != nil {
 		return
 	}
 	return pk.serializeWithoutHeaders(w)
 }

 // serializeWithoutHeaders marshals the PublicKey to w in the form of an
 // OpenPGP public key packet, not including the packet header.
 func (pk *PublicKey) serializeWithoutHeaders(w io.Writer) (err error) {
 	var buf [6]byte
 	buf[0] = 4
 	t := uint32(pk.CreationTime.Unix())
 	buf[1] = byte(t >> 24)
 	buf[2] = byte(t >> 16)
 	buf[3] = byte(t >> 8)
 	buf[4] = byte(t)
 	buf[5] = byte(pk.PubKeyAlgo)

 	_, err = w.Write(buf[:])
 	if err != nil {
 		return
 	}

 	switch pk.PubKeyAlgo {
 	case PubKeyAlgoRSA, PubKeyAlgoRSAEncryptOnly, PubKeyAlgoRSASignOnly:
 		return writeMPIs(w, pk.n, pk.e)
 	case PubKeyAlgoDSA:
 		return writeMPIs(w, pk.p, pk.q, pk.g, pk.y)
 	case PubKeyAlgoElGamal:
 		return writeMPIs(w, pk.p, pk.g, pk.y)
 	case PubKeyAlgoECDSA:
 		return pk.ec.serialize(w)
 	case PubKeyAlgoECDH:
 		if err = pk.ec.serialize(w); err != nil {
 			return
 		}
 		return pk.ecdh.serialize(w)
 	}
 	return errors.InvalidArgumentError("bad public-key algorithm")
 }

 // CanSign returns true iff this public key can generate signatures
 func (pk *PublicKey) CanSign() bool {
 	return pk.PubKeyAlgo != PubKeyAlgoRSAEncryptOnly && pk.PubKeyAlgo != PubKeyAlgoElGamal
 }

 // VerifySignature returns nil iff sig is a valid signature, made by this
 // public key, of the data hashed into signed. signed is mutated by this call.
 func (pk *PublicKey) VerifySignature(signed hash.Hash, sig *Signature) (err error) {
 	if !pk.CanSign() {
 		return errors.InvalidArgumentError("public key cannot generate signatures")
 	}

 	signed.Write(sig.HashSuffix)
 	hashBytes := signed.Sum(nil)

 	if hashBytes[0] != sig.HashTag[0] || hashBytes[1] != sig.HashTag[1] {
 		return errors.SignatureError("hash tag doesn't match")
 	}

 	if pk.PubKeyAlgo != sig.PubKeyAlgo {
 		return errors.InvalidArgumentError("public key and signature use different algorithms")
 	}

 	switch pk.PubKeyAlgo {
 	case PubKeyAlgoRSA, PubKeyAlgoRSASignOnly:
 		rsaPublicKey, _ := pk.PublicKey.(*rsa.PublicKey)
 		err = rsa.VerifyPKCS1v15(rsaPublicKey, sig.Hash, hashBytes, padToKeySize(rsaPublicKey, sig.RSASignature.bytes))
 		if err != nil {
 			return errors.SignatureError("RSA verification failure")
 		}
 		return nil
 	case PubKeyAlgoDSA:
 		dsaPublicKey, _ := pk.PublicKey.(*dsa.PublicKey)
 		// Need to truncate hashBytes to match FIPS 186-3 section 4.6.
 		subgroupSize := (dsaPublicKey.Q.BitLen() + 7) / 8
 		if len(hashBytes) > subgroupSize {
 			hashBytes = hashBytes[:subgroupSize]
 		}
 		if !dsa.Verify(dsaPublicKey, hashBytes, new(big.Int).SetBytes(sig.DSASigR.bytes), new(big.Int).SetBytes(sig.DSASigS.bytes)) {
 			return errors.SignatureError("DSA verification failure")
 		}
 		return nil
 	case PubKeyAlgoECDSA:
 		ecdsaPublicKey := pk.PublicKey.(*ecdsa.PublicKey)
 		if !ecdsa.Verify(ecdsaPublicKey, hashBytes, new(big.Int).SetBytes(sig.ECDSASigR.bytes), new(big.Int).SetBytes(sig.ECDSASigS.bytes)) {
 			return errors.SignatureError("ECDSA verification failure")
 		}
 		return nil
 	default:
 		return errors.SignatureError("Unsupported public key algorithm used in signature")
 	}
 }

 // VerifySignatureV3 returns nil iff sig is a valid signature, made by this
 // public key, of the data hashed into signed. signed is mutated by this call.
 func (pk *PublicKey) VerifySignatureV3(signed hash.Hash, sig *SignatureV3) (err error) {
 	if !pk.CanSign() {
 		return errors.InvalidArgumentError("public key cannot generate signatures")
 	}

 	suffix := make([]byte, 5)
 	suffix[0] = byte(sig.SigType)
 	binary.BigEndian.PutUint32(suffix[1:], uint32(sig.CreationTime.Unix()))
 	signed.Write(suffix)
 	hashBytes := signed.Sum(nil)

 	if hashBytes[0] != sig.HashTag[0] || hashBytes[1] != sig.HashTag[1] {
 		return errors.SignatureError("hash tag doesn't match")
 	}

 	if pk.PubKeyAlgo != sig.PubKeyAlgo {
 		return errors.InvalidArgumentError("public key and signature use different algorithms")
 	}

 	switch pk.PubKeyAlgo {
 	case PubKeyAlgoRSA, PubKeyAlgoRSASignOnly:
 		rsaPublicKey := pk.PublicKey.(*rsa.PublicKey)
 		if err = rsa.VerifyPKCS1v15(rsaPublicKey, sig.Hash, hashBytes, padToKeySize(rsaPublicKey, sig.RSASignature.bytes)); err != nil {
 			return errors.SignatureError("RSA verification failure")
 		}
 		return
 	case PubKeyAlgoDSA:
 		dsaPublicKey := pk.PublicKey.(*dsa.PublicKey)
 		// Need to truncate hashBytes to match FIPS 186-3 section 4.6.
 		subgroupSize := (dsaPublicKey.Q.BitLen() + 7) / 8
 		if len(hashBytes) > subgroupSize {
 			hashBytes = hashBytes[:subgroupSize]
 		}
 		if !dsa.Verify(dsaPublicKey, hashBytes, new(big.Int).SetBytes(sig.DSASigR.bytes), new(big.Int).SetBytes(sig.DSASigS.bytes)) {
 			return errors.SignatureError("DSA verification failure")
 		}
 		return nil
 	default:
 		panic("shouldn't happen")
 	}
 }

 // keySignatureHash returns a Hash of the message that needs to be signed for
 // pk to assert a subkey relationship to signed.
 func keySignatureHash(pk, signed signingKey, hashFunc crypto.Hash) (h hash.Hash, err error) {
 	if !hashFunc.Available() {
 		return nil, errors.UnsupportedError("hash function")
 	}
 	h = hashFunc.New()

 	// RFC 4880, section 5.2.4
 	pk.SerializeSignaturePrefix(h)
 	pk.serializeWithoutHeaders(h)
 	signed.SerializeSignaturePrefix(h)
 	signed.serializeWithoutHeaders(h)
 	return
 }

 // VerifyKeySignature returns nil iff sig is a valid signature, made by this
 // public key, of signed.
 func (pk *PublicKey) VerifyKeySignature(signed *PublicKey, sig *Signature) error {
 	h, err := keySignatureHash(pk, signed, sig.Hash)
 	if err != nil {
 		return err
 	}
 	if err = pk.VerifySignature(h, sig); err != nil {
 		return err
 	}

 	if sig.FlagSign {
 		// Signing subkeys must be cross-signed. See
 		// https://www.gnupg.org/faq/subkey-cross-certify.html.
 		if sig.EmbeddedSignature == nil {
 			return errors.StructuralError("signing subkey is missing cross-signature")
 		}
 		// Verify the cross-signature. This is calculated over the same
 		// data as the main signature, so we cannot just recursively
 		// call signed.VerifyKeySignature(...)
 		if h, err = keySignatureHash(pk, signed, sig.EmbeddedSignature.Hash); err != nil {
 			return errors.StructuralError("error while hashing for cross-signature: " + err.Error())
 		}
 		if err := signed.VerifySignature(h, sig.EmbeddedSignature); err != nil {
 			return errors.StructuralError("error while verifying cross-signature: " + err.Error())
 		}
 	}

 	return nil
 }

 func keyRevocationHash(pk signingKey, hashFunc crypto.Hash) (h hash.Hash, err error) {
 	if !hashFunc.Available() {
 		return nil, errors.UnsupportedError("hash function")
 	}
 	h = hashFunc.New()

 	// RFC 4880, section 5.2.4
 	pk.SerializeSignaturePrefix(h)
 	pk.serializeWithoutHeaders(h)

 	return
 }

 // VerifyRevocationSignature returns nil iff sig is a valid signature, made by this
 // public key.
 func (pk *PublicKey) VerifyRevocationSignature(sig *Signature) (err error) {
 	h, err := keyRevocationHash(pk, sig.Hash)
 	if err != nil {
 		return err
 	}
 	return pk.VerifySignature(h, sig)
 }

 // userIdSignatureHash returns a Hash of the message that needs to be signed
 // to assert that pk is a valid key for id.
 func userIdSignatureHash(id string, pk *PublicKey, hashFunc crypto.Hash) (h hash.Hash, err error) {
 	if !hashFunc.Available() {
 		return nil, errors.UnsupportedError("hash function")
 	}
 	h = hashFunc.New()

 	// RFC 4880, section 5.2.4
 	pk.SerializeSignaturePrefix(h)
 	pk.serializeWithoutHeaders(h)

 	var buf [5]byte
 	buf[0] = 0xb4
 	buf[1] = byte(len(id) >> 24)
 	buf[2] = byte(len(id) >> 16)
 	buf[3] = byte(len(id) >> 8)
 	buf[4] = byte(len(id))
 	h.Write(buf[:])
 	h.Write([]byte(id))

 	return
 }

 // VerifyUserIdSignature returns nil iff sig is a valid signature, made by this
 // public key, that id is the identity of pub.
 func (pk *PublicKey) VerifyUserIdSignature(id string, pub *PublicKey, sig *Signature) (err error) {
 	h, err := userIdSignatureHash(id, pub, sig.Hash)
 	if err != nil {
 		return err
 	}
 	return pk.VerifySignature(h, sig)
 }

 // VerifyUserIdSignatureV3 returns nil iff sig is a valid signature, made by this
 // public key, that id is the identity of pub.
 func (pk *PublicKey) VerifyUserIdSignatureV3(id string, pub *PublicKey, sig *SignatureV3) (err error) {
 	h, err := userIdSignatureV3Hash(id, pub, sig.Hash)
 	if err != nil {
 		return err
 	}
 	return pk.VerifySignatureV3(h, sig)
 }

 // KeyIdString returns the public key's fingerprint in capital hex
 // (e.g. "6C7EE1B8621CC013").
 func (pk *PublicKey) KeyIdString() string {
 	return fmt.Sprintf("%X", pk.Fingerprint[12:20])
 }

 // KeyIdShortString returns the short form of public key's fingerprint
 // in capital hex, as shown by gpg --list-keys (e.g. "621CC013").
 func (pk *PublicKey) KeyIdShortString() string {
 	return fmt.Sprintf("%X", pk.Fingerprint[16:20])
 }

 // A parsedMPI is used to store the contents of a big integer, along with the
 // bit length that was specified in the original input. This allows the MPI to
 // be reserialized exactly.
 type parsedMPI struct {
 	bytes     []byte
 	bitLength uint16
 }

 // writeMPIs is a utility function for serializing several big integers to the
 // given Writer.
 func writeMPIs(w io.Writer, mpis ...parsedMPI) (err error) {
 	for _, mpi := range mpis {
 		err = writeMPI(w, mpi.bitLength, mpi.bytes)
 		if err != nil {
 			return
 		}
 	}
 	return
 }

 // BitLength returns the bit length for the given public key.
 func (pk *PublicKey) BitLength() (bitLength uint16, err error) {
 	switch pk.PubKeyAlgo {
 	case PubKeyAlgoRSA, PubKeyAlgoRSAEncryptOnly, PubKeyAlgoRSASignOnly:
 		bitLength = pk.n.bitLength
 	case PubKeyAlgoDSA:
 		bitLength = pk.p.bitLength
 	case PubKeyAlgoElGamal:
 		bitLength = pk.p.bitLength
 	default:
 		err = errors.InvalidArgumentError("bad public-key algorithm")
 	}
 	return
 }
	// 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"
	"crypto/dsa"
	"crypto/ecdsa"
	"crypto/elliptic"
	"crypto/rsa"
	"crypto/sha1"
	_ "crypto/sha256"
	_ "crypto/sha512"
	"encoding/binary"
	"fmt"
	"hash"
	"io"
	"math/big"
	"strconv"
	"time"

	"golang.org/x/crypto/openpgp/elgamal"
	"golang.org/x/crypto/openpgp/errors"
	)

	var (
	// NIST curve P-256
	oidCurveP256 []byte = []byte{0x2A, 0x86, 0x48, 0xCE, 0x3D, 0x03, 0x01, 0x07}
	// NIST curve P-384
	oidCurveP384 []byte = []byte{0x2B, 0x81, 0x04, 0x00, 0x22}
	// NIST curve P-521
	oidCurveP521 []byte = []byte{0x2B, 0x81, 0x04, 0x00, 0x23}
	)

	const maxOIDLength = 8

	// ecdsaKey stores the algorithm-specific fields for ECDSA keys.
	// as defined in RFC 6637, Section 9.
	type ecdsaKey struct {
	// oid contains the OID byte sequence identifying the elliptic curve used
	oid []byte
	// p contains the elliptic curve point that represents the public key
	p parsedMPI
	}

	// parseOID reads the OID for the curve as defined in RFC 6637, Section 9.
	func parseOID(r io.Reader) (oid []byte, err error) {
	buf := make([]byte, maxOIDLength)
	if _, err = readFull(r, buf[:1]); err != nil {
	return
	}
	oidLen := buf[0]
	if int(oidLen) > len(buf) {
	err = errors.UnsupportedError("invalid oid length: " + strconv.Itoa(int(oidLen)))
	return
	}
	oid = buf[:oidLen]
	_, err = readFull(r, oid)
	return
	}

	func (f *ecdsaKey) parse(r io.Reader) (err error) {
	if f.oid, err = parseOID(r); err != nil {
	return err
	}
	f.p.bytes, f.p.bitLength, err = readMPI(r)
	return
	}

	func (f *ecdsaKey) serialize(w io.Writer) (err error) {
	buf := make([]byte, maxOIDLength+1)
	buf[0] = byte(len(f.oid))
	copy(buf[1:], f.oid)
	if _, err = w.Write(buf[:len(f.oid)+1]); err != nil {
	return
	}
	return writeMPIs(w, f.p)
	}

	func (f ecdsaKey) newECDSA() (ecdsa.PublicKey, error) {
	var c elliptic.Curve
	if bytes.Equal(f.oid, oidCurveP256) {
	c = elliptic.P256()
	} else if bytes.Equal(f.oid, oidCurveP384) {
	c = elliptic.P384()
	} else if bytes.Equal(f.oid, oidCurveP521) {
	c = elliptic.P521()
	} else {
	return nil, errors.UnsupportedError(fmt.Sprintf("unsupported oid: %x", f.oid))
	}
	x, y := elliptic.Unmarshal(c, f.p.bytes)
	if x == nil {
	return nil, errors.UnsupportedError("failed to parse EC point")
	}
	return &ecdsa.PublicKey{Curve: c, X: x, Y: y}, nil
	}

	func (f *ecdsaKey) byteLen() int {
	return 1 + len(f.oid) + 2 + len(f.p.bytes)
	}

	type kdfHashFunction byte
	type kdfAlgorithm byte

	// ecdhKdf stores key derivation function parameters
	// used for ECDH encryption. See RFC 6637, Section 9.
	type ecdhKdf struct {
	KdfHash kdfHashFunction
	KdfAlgo kdfAlgorithm
	}

	func (f *ecdhKdf) parse(r io.Reader) (err error) {
	buf := make([]byte, 1)
	if _, err = readFull(r, buf); err != nil {
	return
	}
	kdfLen := int(buf[0])
	if kdfLen < 3 {
	return errors.UnsupportedError("Unsupported ECDH KDF length: " + strconv.Itoa(kdfLen))
	}
	buf = make([]byte, kdfLen)
	if _, err = readFull(r, buf); err != nil {
	return
	}
	reserved := int(buf[0])
	f.KdfHash = kdfHashFunction(buf[1])
	f.KdfAlgo = kdfAlgorithm(buf[2])
	if reserved != 0x01 {
	return errors.UnsupportedError("Unsupported KDF reserved field: " + strconv.Itoa(reserved))
	}
	return
	}

	func (f *ecdhKdf) serialize(w io.Writer) (err error) {
	buf := make([]byte, 4)
	// See RFC 6637, Section 9, Algorithm-Specific Fields for ECDH keys.
	buf[0] = byte(0x03) // Length of the following fields
	buf[1] = byte(0x01) // Reserved for future extensions, must be 1 for now
	buf[2] = byte(f.KdfHash)
	buf[3] = byte(f.KdfAlgo)
	_, err = w.Write(buf[:])
	return
	}

	func (f *ecdhKdf) byteLen() int {
	return 4
	}

	// PublicKey represents an OpenPGP public key. See RFC 4880, section 5.5.2.
	type PublicKey struct {
	CreationTime time.Time
	PubKeyAlgo PublicKeyAlgorithm
	PublicKey interface{} // rsa.PublicKey, dsa.PublicKey or *ecdsa.PublicKey
	Fingerprint [20]byte
	KeyId uint64
	IsSubkey bool

	n, e, p, q, g, y parsedMPI

	// RFC 6637 fields
	ec *ecdsaKey
	ecdh *ecdhKdf
	}

	// signingKey provides a convenient abstraction over signature verification
	// for v3 and v4 public keys.
	type signingKey interface {
	SerializeSignaturePrefix(io.Writer)
	serializeWithoutHeaders(io.Writer) error
	}

	func fromBig(n *big.Int) parsedMPI {
	return parsedMPI{
	bytes: n.Bytes(),
	bitLength: uint16(n.BitLen()),
	}
	}

	// NewRSAPublicKey returns a PublicKey that wraps the given rsa.PublicKey.
	func NewRSAPublicKey(creationTime time.Time, pub rsa.PublicKey) PublicKey {
	pk := &PublicKey{
	CreationTime: creationTime,
	PubKeyAlgo: PubKeyAlgoRSA,
	PublicKey: pub,
	n: fromBig(pub.N),
	e: fromBig(big.NewInt(int64(pub.E))),
	}

	pk.setFingerPrintAndKeyId()
	return pk
	}

	// NewDSAPublicKey returns a PublicKey that wraps the given dsa.PublicKey.
	func NewDSAPublicKey(creationTime time.Time, pub dsa.PublicKey) PublicKey {
	pk := &PublicKey{
	CreationTime: creationTime,
	PubKeyAlgo: PubKeyAlgoDSA,
	PublicKey: pub,
	p: fromBig(pub.P),
	q: fromBig(pub.Q),
	g: fromBig(pub.G),
	y: fromBig(pub.Y),
	}

	pk.setFingerPrintAndKeyId()
	return pk
	}

	// NewElGamalPublicKey returns a PublicKey that wraps the given elgamal.PublicKey.
	func NewElGamalPublicKey(creationTime time.Time, pub elgamal.PublicKey) PublicKey {
	pk := &PublicKey{
	CreationTime: creationTime,
	PubKeyAlgo: PubKeyAlgoElGamal,
	PublicKey: pub,
	p: fromBig(pub.P),
	g: fromBig(pub.G),
	y: fromBig(pub.Y),
	}

	pk.setFingerPrintAndKeyId()
	return pk
	}

	func NewECDSAPublicKey(creationTime time.Time, pub ecdsa.PublicKey) PublicKey {
	pk := &PublicKey{
	CreationTime: creationTime,
	PubKeyAlgo: PubKeyAlgoECDSA,
	PublicKey: pub,
	ec: new(ecdsaKey),
	}

	switch pub.Curve {
	case elliptic.P256():
	pk.ec.oid = oidCurveP256
	case elliptic.P384():
	pk.ec.oid = oidCurveP384
	case elliptic.P521():
	pk.ec.oid = oidCurveP521
	default:
	panic("unknown elliptic curve")
	}

	pk.ec.p.bytes = elliptic.Marshal(pub.Curve, pub.X, pub.Y)

	// The bit length is 3 (for the 0x04 specifying an uncompressed key)
	// plus two field elements (for x and y), which are rounded up to the
	// nearest byte. See https://tools.ietf.org/html/rfc6637#section-6
	fieldBytes := (pub.Curve.Params().BitSize + 7) & ^7
	pk.ec.p.bitLength = uint16(3 + fieldBytes + fieldBytes)

	pk.setFingerPrintAndKeyId()
	return pk
	}

	func (pk *PublicKey) parse(r io.Reader) (err error) {
	// RFC 4880, section 5.5.2
	var buf [6]byte
	_, err = readFull(r, buf[:])
	if err != nil {
	return
	}
	if buf[0] != 4 {
	return errors.UnsupportedError("public key version")
	}
	pk.CreationTime = time.Unix(int64(uint32(buf[1])<<24\|uint32(buf[2])<<16\|uint32(buf[3])<<8\|uint32(buf[4])), 0)
	pk.PubKeyAlgo = PublicKeyAlgorithm(buf[5])
	switch pk.PubKeyAlgo {
	case PubKeyAlgoRSA, PubKeyAlgoRSAEncryptOnly, PubKeyAlgoRSASignOnly:
	err = pk.parseRSA(r)
	case PubKeyAlgoDSA:
	err = pk.parseDSA(r)
	case PubKeyAlgoElGamal:
	err = pk.parseElGamal(r)
	case PubKeyAlgoECDSA:
	pk.ec = new(ecdsaKey)
	if err = pk.ec.parse(r); err != nil {
	return err
	}
	pk.PublicKey, err = pk.ec.newECDSA()
	case PubKeyAlgoECDH:
	pk.ec = new(ecdsaKey)
	if err = pk.ec.parse(r); err != nil {
	return
	}
	pk.ecdh = new(ecdhKdf)
	if err = pk.ecdh.parse(r); err != nil {
	return
	}
	// The ECDH key is stored in an ecdsa.PublicKey for convenience.
	pk.PublicKey, err = pk.ec.newECDSA()
	default:
	err = errors.UnsupportedError("public key type: " + strconv.Itoa(int(pk.PubKeyAlgo)))
	}
	if err != nil {
	return
	}

	pk.setFingerPrintAndKeyId()
	return
	}

	func (pk *PublicKey) setFingerPrintAndKeyId() {
	// RFC 4880, section 12.2
	fingerPrint := sha1.New()
	pk.SerializeSignaturePrefix(fingerPrint)
	pk.serializeWithoutHeaders(fingerPrint)
	copy(pk.Fingerprint[:], fingerPrint.Sum(nil))
	pk.KeyId = binary.BigEndian.Uint64(pk.Fingerprint[12:20])
	}

	// parseRSA parses RSA public key material from the given Reader. See RFC 4880,
	// section 5.5.2.
	func (pk *PublicKey) parseRSA(r io.Reader) (err error) {
	pk.n.bytes, pk.n.bitLength, err = readMPI(r)
	if err != nil {
	return
	}
	pk.e.bytes, pk.e.bitLength, err = readMPI(r)
	if err != nil {
	return
	}

	if len(pk.e.bytes) > 3 {
	err = errors.UnsupportedError("large public exponent")
	return
	}
	rsa := &rsa.PublicKey{
	N: new(big.Int).SetBytes(pk.n.bytes),
	E: 0,
	}
	for i := 0; i < len(pk.e.bytes); i++ {
	rsa.E <<= 8
	rsa.E \|= int(pk.e.bytes[i])
	}
	pk.PublicKey = rsa
	return
	}

	// parseDSA parses DSA public key material from the given Reader. See RFC 4880,
	// section 5.5.2.
	func (pk *PublicKey) parseDSA(r io.Reader) (err error) {
	pk.p.bytes, pk.p.bitLength, err = readMPI(r)
	if err != nil {
	return
	}
	pk.q.bytes, pk.q.bitLength, err = readMPI(r)
	if err != nil {
	return
	}
	pk.g.bytes, pk.g.bitLength, err = readMPI(r)
	if err != nil {
	return
	}
	pk.y.bytes, pk.y.bitLength, err = readMPI(r)
	if err != nil {
	return
	}

	dsa := new(dsa.PublicKey)
	dsa.P = new(big.Int).SetBytes(pk.p.bytes)
	dsa.Q = new(big.Int).SetBytes(pk.q.bytes)
	dsa.G = new(big.Int).SetBytes(pk.g.bytes)
	dsa.Y = new(big.Int).SetBytes(pk.y.bytes)
	pk.PublicKey = dsa
	return
	}

	// parseElGamal parses ElGamal public key material from the given Reader. See
	// RFC 4880, section 5.5.2.
	func (pk *PublicKey) parseElGamal(r io.Reader) (err error) {
	pk.p.bytes, pk.p.bitLength, err = readMPI(r)
	if err != nil {
	return
	}
	pk.g.bytes, pk.g.bitLength, err = readMPI(r)
	if err != nil {
	return
	}
	pk.y.bytes, pk.y.bitLength, err = readMPI(r)
	if err != nil {
	return
	}

	elgamal := new(elgamal.PublicKey)
	elgamal.P = new(big.Int).SetBytes(pk.p.bytes)
	elgamal.G = new(big.Int).SetBytes(pk.g.bytes)
	elgamal.Y = new(big.Int).SetBytes(pk.y.bytes)
	pk.PublicKey = elgamal
	return
	}

	// SerializeSignaturePrefix writes the prefix for this public key to the given Writer.
	// The prefix is used when calculating a signature over this public key. See
	// RFC 4880, section 5.2.4.
	func (pk *PublicKey) SerializeSignaturePrefix(h io.Writer) {
	var pLength uint16
	switch pk.PubKeyAlgo {
	case PubKeyAlgoRSA, PubKeyAlgoRSAEncryptOnly, PubKeyAlgoRSASignOnly:
	pLength += 2 + uint16(len(pk.n.bytes))
	pLength += 2 + uint16(len(pk.e.bytes))
	case PubKeyAlgoDSA:
	pLength += 2 + uint16(len(pk.p.bytes))
	pLength += 2 + uint16(len(pk.q.bytes))
	pLength += 2 + uint16(len(pk.g.bytes))
	pLength += 2 + uint16(len(pk.y.bytes))
	case PubKeyAlgoElGamal:
	pLength += 2 + uint16(len(pk.p.bytes))
	pLength += 2 + uint16(len(pk.g.bytes))
	pLength += 2 + uint16(len(pk.y.bytes))
	case PubKeyAlgoECDSA:
	pLength += uint16(pk.ec.byteLen())
	case PubKeyAlgoECDH:
	pLength += uint16(pk.ec.byteLen())
	pLength += uint16(pk.ecdh.byteLen())
	default:
	panic("unknown public key algorithm")
	}
	pLength += 6
	h.Write([]byte{0x99, byte(pLength >> 8), byte(pLength)})
	return
	}

	func (pk *PublicKey) Serialize(w io.Writer) (err error) {
	length := 6 // 6 byte header

	switch pk.PubKeyAlgo {
	case PubKeyAlgoRSA, PubKeyAlgoRSAEncryptOnly, PubKeyAlgoRSASignOnly:
	length += 2 + len(pk.n.bytes)
	length += 2 + len(pk.e.bytes)
	case PubKeyAlgoDSA:
	length += 2 + len(pk.p.bytes)
	length += 2 + len(pk.q.bytes)
	length += 2 + len(pk.g.bytes)
	length += 2 + len(pk.y.bytes)
	case PubKeyAlgoElGamal:
	length += 2 + len(pk.p.bytes)
	length += 2 + len(pk.g.bytes)
	length += 2 + len(pk.y.bytes)
	case PubKeyAlgoECDSA:
	length += pk.ec.byteLen()
	case PubKeyAlgoECDH:
	length += pk.ec.byteLen()
	length += pk.ecdh.byteLen()
	default:
	panic("unknown public key algorithm")
	}

	packetType := packetTypePublicKey
	if pk.IsSubkey {
	packetType = packetTypePublicSubkey
	}
	err = serializeHeader(w, packetType, length)
	if err != nil {
	return
	}
	return pk.serializeWithoutHeaders(w)
	}

	// serializeWithoutHeaders marshals the PublicKey to w in the form of an
	// OpenPGP public key packet, not including the packet header.
	func (pk *PublicKey) serializeWithoutHeaders(w io.Writer) (err error) {
	var buf [6]byte
	buf[0] = 4
	t := uint32(pk.CreationTime.Unix())
	buf[1] = byte(t >> 24)
	buf[2] = byte(t >> 16)
	buf[3] = byte(t >> 8)
	buf[4] = byte(t)
	buf[5] = byte(pk.PubKeyAlgo)

	_, err = w.Write(buf[:])
	if err != nil {
	return
	}

	switch pk.PubKeyAlgo {
	case PubKeyAlgoRSA, PubKeyAlgoRSAEncryptOnly, PubKeyAlgoRSASignOnly:
	return writeMPIs(w, pk.n, pk.e)
	case PubKeyAlgoDSA:
	return writeMPIs(w, pk.p, pk.q, pk.g, pk.y)
	case PubKeyAlgoElGamal:
	return writeMPIs(w, pk.p, pk.g, pk.y)
	case PubKeyAlgoECDSA:
	return pk.ec.serialize(w)
	case PubKeyAlgoECDH:
	if err = pk.ec.serialize(w); err != nil {
	return
	}
	return pk.ecdh.serialize(w)
	}
	return errors.InvalidArgumentError("bad public-key algorithm")
	}

	// CanSign returns true iff this public key can generate signatures
	func (pk *PublicKey) CanSign() bool {
	return pk.PubKeyAlgo != PubKeyAlgoRSAEncryptOnly && pk.PubKeyAlgo != PubKeyAlgoElGamal
	}

	// VerifySignature returns nil iff sig is a valid signature, made by this
	// public key, of the data hashed into signed. signed is mutated by this call.
	func (pk PublicKey) VerifySignature(signed hash.Hash, sig Signature) (err error) {
	if !pk.CanSign() {
	return errors.InvalidArgumentError("public key cannot generate signatures")
	}

	signed.Write(sig.HashSuffix)
	hashBytes := signed.Sum(nil)

	if hashBytes[0] != sig.HashTag[0] \|\| hashBytes[1] != sig.HashTag[1] {
	return errors.SignatureError("hash tag doesn't match")
	}

	if pk.PubKeyAlgo != sig.PubKeyAlgo {
	return errors.InvalidArgumentError("public key and signature use different algorithms")
	}

	switch pk.PubKeyAlgo {
	case PubKeyAlgoRSA, PubKeyAlgoRSASignOnly:
	rsaPublicKey, _ := pk.PublicKey.(*rsa.PublicKey)
	err = rsa.VerifyPKCS1v15(rsaPublicKey, sig.Hash, hashBytes, padToKeySize(rsaPublicKey, sig.RSASignature.bytes))
	if err != nil {
	return errors.SignatureError("RSA verification failure")
	}
	return nil
	case PubKeyAlgoDSA:
	dsaPublicKey, _ := pk.PublicKey.(*dsa.PublicKey)
	// Need to truncate hashBytes to match FIPS 186-3 section 4.6.
	subgroupSize := (dsaPublicKey.Q.BitLen() + 7) / 8
	if len(hashBytes) > subgroupSize {
	hashBytes = hashBytes[:subgroupSize]
	}
	if !dsa.Verify(dsaPublicKey, hashBytes, new(big.Int).SetBytes(sig.DSASigR.bytes), new(big.Int).SetBytes(sig.DSASigS.bytes)) {
	return errors.SignatureError("DSA verification failure")
	}
	return nil
	case PubKeyAlgoECDSA:
	ecdsaPublicKey := pk.PublicKey.(*ecdsa.PublicKey)
	if !ecdsa.Verify(ecdsaPublicKey, hashBytes, new(big.Int).SetBytes(sig.ECDSASigR.bytes), new(big.Int).SetBytes(sig.ECDSASigS.bytes)) {
	return errors.SignatureError("ECDSA verification failure")
	}
	return nil
	default:
	return errors.SignatureError("Unsupported public key algorithm used in signature")
	}
	}

	// VerifySignatureV3 returns nil iff sig is a valid signature, made by this
	// public key, of the data hashed into signed. signed is mutated by this call.
	func (pk PublicKey) VerifySignatureV3(signed hash.Hash, sig SignatureV3) (err error) {
	if !pk.CanSign() {
	return errors.InvalidArgumentError("public key cannot generate signatures")
	}

	suffix := make([]byte, 5)
	suffix[0] = byte(sig.SigType)
	binary.BigEndian.PutUint32(suffix[1:], uint32(sig.CreationTime.Unix()))
	signed.Write(suffix)
	hashBytes := signed.Sum(nil)

	if hashBytes[0] != sig.HashTag[0] \|\| hashBytes[1] != sig.HashTag[1] {
	return errors.SignatureError("hash tag doesn't match")
	}

	if pk.PubKeyAlgo != sig.PubKeyAlgo {
	return errors.InvalidArgumentError("public key and signature use different algorithms")
	}

	switch pk.PubKeyAlgo {
	case PubKeyAlgoRSA, PubKeyAlgoRSASignOnly:
	rsaPublicKey := pk.PublicKey.(*rsa.PublicKey)
	if err = rsa.VerifyPKCS1v15(rsaPublicKey, sig.Hash, hashBytes, padToKeySize(rsaPublicKey, sig.RSASignature.bytes)); err != nil {
	return errors.SignatureError("RSA verification failure")
	}
	return
	case PubKeyAlgoDSA:
	dsaPublicKey := pk.PublicKey.(*dsa.PublicKey)
	// Need to truncate hashBytes to match FIPS 186-3 section 4.6.
	subgroupSize := (dsaPublicKey.Q.BitLen() + 7) / 8
	if len(hashBytes) > subgroupSize {
	hashBytes = hashBytes[:subgroupSize]
	}
	if !dsa.Verify(dsaPublicKey, hashBytes, new(big.Int).SetBytes(sig.DSASigR.bytes), new(big.Int).SetBytes(sig.DSASigS.bytes)) {
	return errors.SignatureError("DSA verification failure")
	}
	return nil
	default:
	panic("shouldn't happen")
	}
	}

	// keySignatureHash returns a Hash of the message that needs to be signed for
	// pk to assert a subkey relationship to signed.
	func keySignatureHash(pk, signed signingKey, hashFunc crypto.Hash) (h hash.Hash, err error) {
	if !hashFunc.Available() {
	return nil, errors.UnsupportedError("hash function")
	}
	h = hashFunc.New()

	// RFC 4880, section 5.2.4
	pk.SerializeSignaturePrefix(h)
	pk.serializeWithoutHeaders(h)
	signed.SerializeSignaturePrefix(h)
	signed.serializeWithoutHeaders(h)
	return
	}

	// VerifyKeySignature returns nil iff sig is a valid signature, made by this
	// public key, of signed.
	func (pk PublicKey) VerifyKeySignature(signed PublicKey, sig *Signature) error {
	h, err := keySignatureHash(pk, signed, sig.Hash)
	if err != nil {
	return err
	}
	if err = pk.VerifySignature(h, sig); err != nil {
	return err
	}

	if sig.FlagSign {
	// Signing subkeys must be cross-signed. See
	// https://www.gnupg.org/faq/subkey-cross-certify.html.
	if sig.EmbeddedSignature == nil {
	return errors.StructuralError("signing subkey is missing cross-signature")
	}
	// Verify the cross-signature. This is calculated over the same
	// data as the main signature, so we cannot just recursively
	// call signed.VerifyKeySignature(...)
	if h, err = keySignatureHash(pk, signed, sig.EmbeddedSignature.Hash); err != nil {
	return errors.StructuralError("error while hashing for cross-signature: " + err.Error())
	}
	if err := signed.VerifySignature(h, sig.EmbeddedSignature); err != nil {
	return errors.StructuralError("error while verifying cross-signature: " + err.Error())
	}
	}

	return nil
	}

	func keyRevocationHash(pk signingKey, hashFunc crypto.Hash) (h hash.Hash, err error) {
	if !hashFunc.Available() {
	return nil, errors.UnsupportedError("hash function")
	}
	h = hashFunc.New()

	// RFC 4880, section 5.2.4
	pk.SerializeSignaturePrefix(h)
	pk.serializeWithoutHeaders(h)

	return
	}

	// VerifyRevocationSignature returns nil iff sig is a valid signature, made by this
	// public key.
	func (pk PublicKey) VerifyRevocationSignature(sig Signature) (err error) {
	h, err := keyRevocationHash(pk, sig.Hash)
	if err != nil {
	return err
	}
	return pk.VerifySignature(h, sig)
	}

	// userIdSignatureHash returns a Hash of the message that needs to be signed
	// to assert that pk is a valid key for id.
	func userIdSignatureHash(id string, pk *PublicKey, hashFunc crypto.Hash) (h hash.Hash, err error) {
	if !hashFunc.Available() {
	return nil, errors.UnsupportedError("hash function")
	}
	h = hashFunc.New()

	// RFC 4880, section 5.2.4
	pk.SerializeSignaturePrefix(h)
	pk.serializeWithoutHeaders(h)

	var buf [5]byte
	buf[0] = 0xb4
	buf[1] = byte(len(id) >> 24)
	buf[2] = byte(len(id) >> 16)
	buf[3] = byte(len(id) >> 8)
	buf[4] = byte(len(id))
	h.Write(buf[:])
	h.Write([]byte(id))

	return
	}

	// VerifyUserIdSignature returns nil iff sig is a valid signature, made by this
	// public key, that id is the identity of pub.
	func (pk PublicKey) VerifyUserIdSignature(id string, pub PublicKey, sig *Signature) (err error) {
	h, err := userIdSignatureHash(id, pub, sig.Hash)
	if err != nil {
	return err
	}
	return pk.VerifySignature(h, sig)
	}

	// VerifyUserIdSignatureV3 returns nil iff sig is a valid signature, made by this
	// public key, that id is the identity of pub.
	func (pk PublicKey) VerifyUserIdSignatureV3(id string, pub PublicKey, sig *SignatureV3) (err error) {
	h, err := userIdSignatureV3Hash(id, pub, sig.Hash)
	if err != nil {
	return err
	}
	return pk.VerifySignatureV3(h, sig)
	}

	// KeyIdString returns the public key's fingerprint in capital hex
	// (e.g. "6C7EE1B8621CC013").
	func (pk *PublicKey) KeyIdString() string {
	return fmt.Sprintf("%X", pk.Fingerprint[12:20])
	}

	// KeyIdShortString returns the short form of public key's fingerprint
	// in capital hex, as shown by gpg --list-keys (e.g. "621CC013").
	func (pk *PublicKey) KeyIdShortString() string {
	return fmt.Sprintf("%X", pk.Fingerprint[16:20])
	}

	// A parsedMPI is used to store the contents of a big integer, along with the
	// bit length that was specified in the original input. This allows the MPI to
	// be reserialized exactly.
	type parsedMPI struct {
	bytes []byte
	bitLength uint16
	}

	// writeMPIs is a utility function for serializing several big integers to the
	// given Writer.
	func writeMPIs(w io.Writer, mpis ...parsedMPI) (err error) {
	for _, mpi := range mpis {
	err = writeMPI(w, mpi.bitLength, mpi.bytes)
	if err != nil {
	return
	}
	}
	return
	}

	// BitLength returns the bit length for the given public key.
	func (pk *PublicKey) BitLength() (bitLength uint16, err error) {
	switch pk.PubKeyAlgo {
	case PubKeyAlgoRSA, PubKeyAlgoRSAEncryptOnly, PubKeyAlgoRSASignOnly:
	bitLength = pk.n.bitLength
	case PubKeyAlgoDSA:
	bitLength = pk.p.bitLength
	case PubKeyAlgoElGamal:
	bitLength = pk.p.bitLength
	default:
	err = errors.InvalidArgumentError("bad public-key algorithm")
	}
	return
	}