forked from TrueCloudLab/distribution
429 lines
12 KiB
Go
429 lines
12 KiB
Go
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package libtrust
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import (
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"crypto"
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"crypto/ecdsa"
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"crypto/elliptic"
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"crypto/rand"
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"crypto/x509"
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"encoding/json"
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"encoding/pem"
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"errors"
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"fmt"
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"io"
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"math/big"
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)
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/*
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* EC DSA PUBLIC KEY
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*/
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// ecPublicKey implements a libtrust.PublicKey using elliptic curve digital
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// signature algorithms.
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type ecPublicKey struct {
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*ecdsa.PublicKey
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curveName string
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signatureAlgorithm *signatureAlgorithm
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extended map[string]interface{}
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}
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func fromECPublicKey(cryptoPublicKey *ecdsa.PublicKey) (*ecPublicKey, error) {
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curve := cryptoPublicKey.Curve
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switch {
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case curve == elliptic.P256():
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return &ecPublicKey{cryptoPublicKey, "P-256", es256, map[string]interface{}{}}, nil
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case curve == elliptic.P384():
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return &ecPublicKey{cryptoPublicKey, "P-384", es384, map[string]interface{}{}}, nil
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case curve == elliptic.P521():
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return &ecPublicKey{cryptoPublicKey, "P-521", es512, map[string]interface{}{}}, nil
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default:
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return nil, errors.New("unsupported elliptic curve")
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}
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}
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// KeyType returns the key type for elliptic curve keys, i.e., "EC".
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func (k *ecPublicKey) KeyType() string {
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return "EC"
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}
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// CurveName returns the elliptic curve identifier.
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// Possible values are "P-256", "P-384", and "P-521".
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func (k *ecPublicKey) CurveName() string {
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return k.curveName
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}
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// KeyID returns a distinct identifier which is unique to this Public Key.
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func (k *ecPublicKey) KeyID() string {
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return keyIDFromCryptoKey(k)
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}
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func (k *ecPublicKey) String() string {
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return fmt.Sprintf("EC Public Key <%s>", k.KeyID())
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}
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// Verify verifyies the signature of the data in the io.Reader using this
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// PublicKey. The alg parameter should identify the digital signature
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// algorithm which was used to produce the signature and should be supported
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// by this public key. Returns a nil error if the signature is valid.
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func (k *ecPublicKey) Verify(data io.Reader, alg string, signature []byte) error {
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// For EC keys there is only one supported signature algorithm depending
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// on the curve parameters.
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if k.signatureAlgorithm.HeaderParam() != alg {
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return fmt.Errorf("unable to verify signature: EC Public Key with curve %q does not support signature algorithm %q", k.curveName, alg)
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}
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// signature is the concatenation of (r, s), base64Url encoded.
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sigLength := len(signature)
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expectedOctetLength := 2 * ((k.Params().BitSize + 7) >> 3)
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if sigLength != expectedOctetLength {
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return fmt.Errorf("signature length is %d octets long, should be %d", sigLength, expectedOctetLength)
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}
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rBytes, sBytes := signature[:sigLength/2], signature[sigLength/2:]
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r := new(big.Int).SetBytes(rBytes)
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s := new(big.Int).SetBytes(sBytes)
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hasher := k.signatureAlgorithm.HashID().New()
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_, err := io.Copy(hasher, data)
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if err != nil {
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return fmt.Errorf("error reading data to sign: %s", err)
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}
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hash := hasher.Sum(nil)
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if !ecdsa.Verify(k.PublicKey, hash, r, s) {
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return errors.New("invalid signature")
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}
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return nil
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}
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// CryptoPublicKey returns the internal object which can be used as a
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// crypto.PublicKey for use with other standard library operations. The type
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// is either *rsa.PublicKey or *ecdsa.PublicKey
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func (k *ecPublicKey) CryptoPublicKey() crypto.PublicKey {
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return k.PublicKey
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}
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func (k *ecPublicKey) toMap() map[string]interface{} {
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jwk := make(map[string]interface{})
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for k, v := range k.extended {
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jwk[k] = v
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}
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jwk["kty"] = k.KeyType()
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jwk["kid"] = k.KeyID()
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jwk["crv"] = k.CurveName()
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xBytes := k.X.Bytes()
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yBytes := k.Y.Bytes()
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octetLength := (k.Params().BitSize + 7) >> 3
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// MUST include leading zeros in the output so that x, y are each
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// *octetLength* bytes long.
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xBuf := make([]byte, octetLength-len(xBytes), octetLength)
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yBuf := make([]byte, octetLength-len(yBytes), octetLength)
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xBuf = append(xBuf, xBytes...)
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yBuf = append(yBuf, yBytes...)
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jwk["x"] = joseBase64UrlEncode(xBuf)
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jwk["y"] = joseBase64UrlEncode(yBuf)
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return jwk
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}
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// MarshalJSON serializes this Public Key using the JWK JSON serialization format for
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// elliptic curve keys.
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func (k *ecPublicKey) MarshalJSON() (data []byte, err error) {
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return json.Marshal(k.toMap())
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}
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// PEMBlock serializes this Public Key to DER-encoded PKIX format.
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func (k *ecPublicKey) PEMBlock() (*pem.Block, error) {
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derBytes, err := x509.MarshalPKIXPublicKey(k.PublicKey)
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if err != nil {
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return nil, fmt.Errorf("unable to serialize EC PublicKey to DER-encoded PKIX format: %s", err)
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}
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k.extended["kid"] = k.KeyID() // For display purposes.
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return createPemBlock("PUBLIC KEY", derBytes, k.extended)
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}
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func (k *ecPublicKey) AddExtendedField(field string, value interface{}) {
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k.extended[field] = value
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}
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func (k *ecPublicKey) GetExtendedField(field string) interface{} {
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v, ok := k.extended[field]
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if !ok {
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return nil
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}
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return v
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}
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func ecPublicKeyFromMap(jwk map[string]interface{}) (*ecPublicKey, error) {
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// JWK key type (kty) has already been determined to be "EC".
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// Need to extract 'crv', 'x', 'y', and 'kid' and check for
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// consistency.
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// Get the curve identifier value.
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crv, err := stringFromMap(jwk, "crv")
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if err != nil {
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return nil, fmt.Errorf("JWK EC Public Key curve identifier: %s", err)
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}
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var (
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curve elliptic.Curve
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sigAlg *signatureAlgorithm
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)
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switch {
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case crv == "P-256":
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curve = elliptic.P256()
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sigAlg = es256
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case crv == "P-384":
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curve = elliptic.P384()
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sigAlg = es384
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case crv == "P-521":
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curve = elliptic.P521()
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sigAlg = es512
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default:
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return nil, fmt.Errorf("JWK EC Public Key curve identifier not supported: %q\n", crv)
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}
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// Get the X and Y coordinates for the public key point.
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xB64Url, err := stringFromMap(jwk, "x")
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if err != nil {
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return nil, fmt.Errorf("JWK EC Public Key x-coordinate: %s", err)
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}
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x, err := parseECCoordinate(xB64Url, curve)
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if err != nil {
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return nil, fmt.Errorf("JWK EC Public Key x-coordinate: %s", err)
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}
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yB64Url, err := stringFromMap(jwk, "y")
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if err != nil {
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return nil, fmt.Errorf("JWK EC Public Key y-coordinate: %s", err)
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}
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y, err := parseECCoordinate(yB64Url, curve)
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if err != nil {
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return nil, fmt.Errorf("JWK EC Public Key y-coordinate: %s", err)
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}
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key := &ecPublicKey{
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PublicKey: &ecdsa.PublicKey{Curve: curve, X: x, Y: y},
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curveName: crv, signatureAlgorithm: sigAlg,
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}
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// Key ID is optional too, but if it exists, it should match the key.
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_, ok := jwk["kid"]
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if ok {
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kid, err := stringFromMap(jwk, "kid")
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if err != nil {
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return nil, fmt.Errorf("JWK EC Public Key ID: %s", err)
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}
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if kid != key.KeyID() {
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return nil, fmt.Errorf("JWK EC Public Key ID does not match: %s", kid)
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}
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}
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key.extended = jwk
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return key, nil
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}
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/*
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* EC DSA PRIVATE KEY
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*/
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// ecPrivateKey implements a JWK Private Key using elliptic curve digital signature
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// algorithms.
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type ecPrivateKey struct {
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ecPublicKey
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*ecdsa.PrivateKey
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}
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func fromECPrivateKey(cryptoPrivateKey *ecdsa.PrivateKey) (*ecPrivateKey, error) {
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publicKey, err := fromECPublicKey(&cryptoPrivateKey.PublicKey)
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if err != nil {
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return nil, err
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}
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return &ecPrivateKey{*publicKey, cryptoPrivateKey}, nil
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}
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// PublicKey returns the Public Key data associated with this Private Key.
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func (k *ecPrivateKey) PublicKey() PublicKey {
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return &k.ecPublicKey
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}
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func (k *ecPrivateKey) String() string {
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return fmt.Sprintf("EC Private Key <%s>", k.KeyID())
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}
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// Sign signs the data read from the io.Reader using a signature algorithm supported
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// by the elliptic curve private key. If the specified hashing algorithm is
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// supported by this key, that hash function is used to generate the signature
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// otherwise the the default hashing algorithm for this key is used. Returns
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// the signature and the name of the JWK signature algorithm used, e.g.,
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// "ES256", "ES384", "ES512".
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func (k *ecPrivateKey) Sign(data io.Reader, hashID crypto.Hash) (signature []byte, alg string, err error) {
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// Generate a signature of the data using the internal alg.
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// The given hashId is only a suggestion, and since EC keys only support
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// on signature/hash algorithm given the curve name, we disregard it for
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// the elliptic curve JWK signature implementation.
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hasher := k.signatureAlgorithm.HashID().New()
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_, err = io.Copy(hasher, data)
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if err != nil {
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return nil, "", fmt.Errorf("error reading data to sign: %s", err)
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}
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hash := hasher.Sum(nil)
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r, s, err := ecdsa.Sign(rand.Reader, k.PrivateKey, hash)
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if err != nil {
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return nil, "", fmt.Errorf("error producing signature: %s", err)
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}
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rBytes, sBytes := r.Bytes(), s.Bytes()
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octetLength := (k.ecPublicKey.Params().BitSize + 7) >> 3
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// MUST include leading zeros in the output
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rBuf := make([]byte, octetLength-len(rBytes), octetLength)
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sBuf := make([]byte, octetLength-len(sBytes), octetLength)
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rBuf = append(rBuf, rBytes...)
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sBuf = append(sBuf, sBytes...)
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signature = append(rBuf, sBuf...)
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alg = k.signatureAlgorithm.HeaderParam()
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return
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}
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// CryptoPrivateKey returns the internal object which can be used as a
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// crypto.PublicKey for use with other standard library operations. The type
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// is either *rsa.PublicKey or *ecdsa.PublicKey
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func (k *ecPrivateKey) CryptoPrivateKey() crypto.PrivateKey {
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return k.PrivateKey
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}
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func (k *ecPrivateKey) toMap() map[string]interface{} {
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jwk := k.ecPublicKey.toMap()
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dBytes := k.D.Bytes()
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// The length of this octet string MUST be ceiling(log-base-2(n)/8)
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// octets (where n is the order of the curve). This is because the private
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// key d must be in the interval [1, n-1] so the bitlength of d should be
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// no larger than the bitlength of n-1. The easiest way to find the octet
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// length is to take bitlength(n-1), add 7 to force a carry, and shift this
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// bit sequence right by 3, which is essentially dividing by 8 and adding
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// 1 if there is any remainder. Thus, the private key value d should be
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// output to (bitlength(n-1)+7)>>3 octets.
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n := k.ecPublicKey.Params().N
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octetLength := (new(big.Int).Sub(n, big.NewInt(1)).BitLen() + 7) >> 3
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// Create a buffer with the necessary zero-padding.
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dBuf := make([]byte, octetLength-len(dBytes), octetLength)
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dBuf = append(dBuf, dBytes...)
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jwk["d"] = joseBase64UrlEncode(dBuf)
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return jwk
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}
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// MarshalJSON serializes this Private Key using the JWK JSON serialization format for
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// elliptic curve keys.
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func (k *ecPrivateKey) MarshalJSON() (data []byte, err error) {
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return json.Marshal(k.toMap())
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}
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// PEMBlock serializes this Private Key to DER-encoded PKIX format.
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func (k *ecPrivateKey) PEMBlock() (*pem.Block, error) {
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derBytes, err := x509.MarshalECPrivateKey(k.PrivateKey)
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if err != nil {
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return nil, fmt.Errorf("unable to serialize EC PrivateKey to DER-encoded PKIX format: %s", err)
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}
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k.extended["keyID"] = k.KeyID() // For display purposes.
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return createPemBlock("EC PRIVATE KEY", derBytes, k.extended)
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}
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func ecPrivateKeyFromMap(jwk map[string]interface{}) (*ecPrivateKey, error) {
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dB64Url, err := stringFromMap(jwk, "d")
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if err != nil {
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return nil, fmt.Errorf("JWK EC Private Key: %s", err)
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}
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// JWK key type (kty) has already been determined to be "EC".
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// Need to extract the public key information, then extract the private
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// key value 'd'.
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publicKey, err := ecPublicKeyFromMap(jwk)
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if err != nil {
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return nil, err
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}
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d, err := parseECPrivateParam(dB64Url, publicKey.Curve)
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if err != nil {
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return nil, fmt.Errorf("JWK EC Private Key d-param: %s", err)
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}
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key := &ecPrivateKey{
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ecPublicKey: *publicKey,
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PrivateKey: &ecdsa.PrivateKey{
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PublicKey: *publicKey.PublicKey,
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D: d,
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},
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}
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return key, nil
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}
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/*
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* Key Generation Functions.
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*/
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func generateECPrivateKey(curve elliptic.Curve) (k *ecPrivateKey, err error) {
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k = new(ecPrivateKey)
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k.PrivateKey, err = ecdsa.GenerateKey(curve, rand.Reader)
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if err != nil {
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return nil, err
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}
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k.ecPublicKey.PublicKey = &k.PrivateKey.PublicKey
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k.extended = make(map[string]interface{})
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return
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}
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// GenerateECP256PrivateKey generates a key pair using elliptic curve P-256.
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func GenerateECP256PrivateKey() (PrivateKey, error) {
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k, err := generateECPrivateKey(elliptic.P256())
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if err != nil {
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return nil, fmt.Errorf("error generating EC P-256 key: %s", err)
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}
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k.curveName = "P-256"
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k.signatureAlgorithm = es256
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return k, nil
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}
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// GenerateECP384PrivateKey generates a key pair using elliptic curve P-384.
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func GenerateECP384PrivateKey() (PrivateKey, error) {
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k, err := generateECPrivateKey(elliptic.P384())
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if err != nil {
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return nil, fmt.Errorf("error generating EC P-384 key: %s", err)
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}
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k.curveName = "P-384"
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k.signatureAlgorithm = es384
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return k, nil
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}
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// GenerateECP521PrivateKey generates aß key pair using elliptic curve P-521.
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func GenerateECP521PrivateKey() (PrivateKey, error) {
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k, err := generateECPrivateKey(elliptic.P521())
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if err != nil {
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return nil, fmt.Errorf("error generating EC P-521 key: %s", err)
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}
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k.curveName = "P-521"
|
||
|
k.signatureAlgorithm = es512
|
||
|
|
||
|
return k, nil
|
||
|
}
|