public Signer(OneKey key, CBORObject algorithm = null)
{
if (algorithm != null)
{
AddAttribute(HeaderKeys.Algorithm, algorithm, UNPROTECTED);
}
if (key.ContainsName(CoseKeyKeys.KeyIdentifier))
{
AddAttribute(HeaderKeys.KeyId, key[CoseKeyKeys.KeyIdentifier], UNPROTECTED);
}
if (key.ContainsName("use"))
{
string usage = key.AsString("use");
if (usage != "sig")
{
throw new Exception("Key cannot be used for encryption");
}
}
if (key.ContainsName(CoseKeyKeys.Key_Operations))
{
CBORObject usageObject = key[CoseKeyKeys.Key_Operations];
bool validUsage = false;
if (usageObject.Type != CBORType.Array)
{
throw new Exception("key_ops is incorrectly formed");
}
for (int i = 0; i < usageObject.Count; i++)
{
switch (usageObject[i].AsString())
{
case "encrypt":
case "keywrap":
validUsage = true;
break;
}
}
if (!validUsage)
{
throw new Exception("Key cannot be used for encryption");
}
}
_keyToSign = key;
}
private byte[] Sign(byte[] bytesToBeSigned)
{
CBORObject alg; // Get the set algorithm or infer one
alg = FindAttribute(HeaderKeys.Algorithm);
if (alg == null)
{
if (_keyToSign[CoseKeyKeys.KeyType].Type == CBORType.Integer)
{
switch ((GeneralValuesInt)_keyToSign[CoseKeyKeys.KeyType].AsInt32())
{
case GeneralValuesInt.KeyType_RSA:
alg = AlgorithmValues.RSA_PSS_256;
break;
case GeneralValuesInt.KeyType_EC2:
if (_keyToSign[CoseKeyParameterKeys.EC_Curve].Type == CBORType.Integer)
{
switch ((GeneralValuesInt)_keyToSign[CoseKeyParameterKeys.EC_Curve].AsInt32())
{
case GeneralValuesInt.P256:
alg = AlgorithmValues.ECDSA_256;
break;
case GeneralValuesInt.P384:
alg = AlgorithmValues.ECDSA_384;
break;
case GeneralValuesInt.P521:
alg = AlgorithmValues.ECDSA_512;
break;
default:
throw new CoseException("Unknown curve");
}
}
else if (_keyToSign[CoseKeyParameterKeys.EC_Curve].Type == CBORType.TextString)
{
switch (_keyToSign[CoseKeyParameterKeys.EC_Curve].AsString())
{
default:
throw new CoseException("Unknown curve");
}
}
else
{
throw new CoseException("Curve is incorrectly encoded");
}
break;
case GeneralValuesInt.KeyType_OKP:
if (_keyToSign[CoseKeyParameterKeys.EC_Curve].Type == CBORType.Integer)
{
switch ((GeneralValuesInt)_keyToSign[CoseKeyParameterKeys.EC_Curve].AsInt32())
{
case GeneralValuesInt.Ed25519:
alg = AlgorithmValues.EdDSA;
break;
case GeneralValuesInt.Ed448:
alg = AlgorithmValues.EdDSA;
break;
default:
throw new CoseException("Unknown curve");
}
}
else if (_keyToSign[CoseKeyParameterKeys.EC_Curve].Type == CBORType.TextString)
{
switch (_keyToSign[CoseKeyParameterKeys.EC_Curve].AsString())
{
default:
throw new CoseException("Unknown curve");
}
}
else
{
throw new CoseException("Curve is incorrectly encoded");
}
break;
default:
throw new Exception("Unknown or unsupported key type " + _keyToSign.AsString("kty"));
}
}
else if (_keyToSign[CoseKeyKeys.KeyType].Type == CBORType.TextString)
{
throw new CoseException("Unknown or unsupported key type " + _keyToSign[CoseKeyKeys.KeyType].AsString());
}
else
{
throw new CoseException("Key type is not correctly encoded");
}
UnprotectedMap.Add(HeaderKeys.Algorithm, alg);
}
return(Sign(bytesToBeSigned, alg, _keyToSign));
}
private byte[] _Sign(byte[] bytesToBeSigned)
{
CBORObject alg; // Get the set algorithm or infer one
if (rgbContent == null)
{
throw new CoseException("No Content Specified");
}
alg = FindAttribute(HeaderKeys.Algorithm);
if (alg == null)
{
if (_keyToSign[CoseKeyKeys.KeyType].Type == CBORType.Integer)
{
switch ((GeneralValuesInt)_keyToSign[CoseKeyKeys.KeyType].AsInt32())
{
case GeneralValuesInt.KeyType_RSA:
alg = AlgorithmValues.RSA_PSS_256;
break;
case GeneralValuesInt.KeyType_EC2:
if (_keyToSign[CoseKeyParameterKeys.EC_Curve].Type == CBORType.Integer)
{
switch ((GeneralValuesInt)_keyToSign[CoseKeyParameterKeys.EC_Curve].AsInt32())
{
case GeneralValuesInt.P256:
alg = AlgorithmValues.ECDSA_256;
break;
case GeneralValuesInt.P521:
alg = AlgorithmValues.ECDSA_512;
break;
default:
throw new CoseException("Unknown curve");
}
}
else if (_keyToSign[CoseKeyParameterKeys.EC_Curve].Type == CBORType.TextString)
{
switch (_keyToSign[CoseKeyParameterKeys.EC_Curve].AsString())
{
case "P-384":
alg = CBORObject.FromObject("ES384");
break;
default:
throw new CoseException("Unknown curve");
}
}
else
{
throw new CoseException("Curve is incorrectly encoded");
}
break;
case GeneralValuesInt.KeyType_OKP:
if (_keyToSign[CoseKeyParameterKeys.EC_Curve].Type == CBORType.Integer)
{
switch ((GeneralValuesInt)_keyToSign[CoseKeyParameterKeys.EC_Curve].AsInt32())
{
case GeneralValuesInt.Ed25519:
alg = AlgorithmValues.EdDSA;
break;
case GeneralValuesInt.Ed448:
alg = AlgorithmValues.EdDSA;
break;
default:
throw new CoseException("Unknown curve");
}
}
else if (_keyToSign[CoseKeyParameterKeys.EC_Curve].Type == CBORType.TextString)
{
switch (_keyToSign[CoseKeyParameterKeys.EC_Curve].AsString())
{
default:
throw new CoseException("Unknown curve");
}
}
else
{
throw new CoseException("Curve is incorrectly encoded");
}
break;
default:
throw new CoseException("Unknown or unsupported key type " + _keyToSign.AsString("kty"));
}
}
else if (_keyToSign[CoseKeyKeys.KeyType].Type == CBORType.TextString)
{
throw new CoseException("Unknown or unsupported key type " + _keyToSign[CoseKeyKeys.KeyType].AsString());
}
else
{
throw new CoseException("Key type is not correctly encoded");
}
UnprotectedMap.Add(HeaderKeys.Algorithm, alg);
}
IDigest digest = null;
IDigest digest2 = null;
if (alg.Type == CBORType.TextString)
{
switch (alg.AsString())
{
case "ES384":
case "PS384":
digest = new Sha384Digest();
digest2 = new Sha384Digest();
break;
case "HSS-LMS":
break;
default:
throw new CoseException("Unknown Algorithm Specified");
}
}
else if (alg.Type == CBORType.Integer)
{
switch ((AlgorithmValuesInt)alg.AsInt32())
{
case AlgorithmValuesInt.ECDSA_256:
case AlgorithmValuesInt.RSA_PSS_256:
digest = new Sha256Digest();
digest2 = new Sha256Digest();
break;
case AlgorithmValuesInt.ECDSA_384:
case AlgorithmValuesInt.RSA_PSS_384:
digest = new Sha384Digest();
digest2 = new Sha384Digest();
break;
case AlgorithmValuesInt.ECDSA_512:
case AlgorithmValuesInt.RSA_PSS_512:
digest = new Sha512Digest();
digest2 = new Sha512Digest();
break;
case AlgorithmValuesInt.EdDSA:
break;
default:
throw new CoseException("Unknown Algorithm Specified");
}
}
else
{
throw new CoseException("Algorithm incorrectly encoded");
}
if (alg.Type == CBORType.TextString)
{
switch (alg.AsString())
{
case "HSS-LMS":
HashSig sig = new HashSig(_keyToSign[CoseKeyParameterKeys.Lms_Private].AsString());
byte[] signBytes = sig.Sign(bytesToBeSigned);
_keyToSign.Replace(CoseKeyParameterKeys.Lms_Private, CBORObject.FromObject(sig.PrivateKey));
return(signBytes);
default:
throw new CoseException("Unknown Algorithm Specified");
}
}
else if (alg.Type == CBORType.Integer)
{
switch ((AlgorithmValuesInt)alg.AsInt32())
{
case AlgorithmValuesInt.RSA_PSS_256:
case AlgorithmValuesInt.RSA_PSS_384:
case AlgorithmValuesInt.RSA_PSS_512: {
PssSigner signer = new PssSigner(new RsaEngine(), digest, digest2, digest.GetByteLength());
RsaKeyParameters prv = new RsaPrivateCrtKeyParameters(
_keyToSign.AsBigInteger(CoseKeyParameterKeys.RSA_n),
_keyToSign.AsBigInteger(CoseKeyParameterKeys.RSA_e),
_keyToSign.AsBigInteger(CoseKeyParameterKeys.RSA_d),
_keyToSign.AsBigInteger(CoseKeyParameterKeys.RSA_p),
_keyToSign.AsBigInteger(CoseKeyParameterKeys.RSA_q),
_keyToSign.AsBigInteger(CoseKeyParameterKeys.RSA_dP),
_keyToSign.AsBigInteger(CoseKeyParameterKeys.RSA_dQ),
_keyToSign.AsBigInteger(CoseKeyParameterKeys.RSA_qInv));
ParametersWithRandom param = new ParametersWithRandom(prv, GetPRNG());
signer.Init(true, param);
signer.BlockUpdate(bytesToBeSigned, 0, bytesToBeSigned.Length);
return(signer.GenerateSignature());
}
case AlgorithmValuesInt.ECDSA_256:
case AlgorithmValuesInt.ECDSA_384:
case AlgorithmValuesInt.ECDSA_512: {
CBORObject privateKeyD = _keyToSign[CoseKeyParameterKeys.EC_D];
if (privateKeyD == null)
{
throw new CoseException("Private key required to sign");
}
SecureRandom random = GetPRNG();
digest.BlockUpdate(bytesToBeSigned, 0, bytesToBeSigned.Length);
byte[] digestedMessage = new byte[digest.GetDigestSize()];
digest.DoFinal(digestedMessage, 0);
X9ECParameters p = _keyToSign.GetCurve();
ECDomainParameters parameters = new ECDomainParameters(p.Curve, p.G, p.N, p.H);
ECPrivateKeyParameters privKey =
new ECPrivateKeyParameters("ECDSA", ConvertBigNum(privateKeyD), parameters);
ParametersWithRandom param = new ParametersWithRandom(privKey, random);
ECDsaSigner ecdsa = new ECDsaSigner(new HMacDsaKCalculator(new Sha256Digest()));
ecdsa.Init(true, param);
BigInteger[] sig = ecdsa.GenerateSignature(digestedMessage);
byte[] r = sig[0].ToByteArrayUnsigned();
byte[] s = sig[1].ToByteArrayUnsigned();
int cbR = (p.Curve.FieldSize + 7) / 8;
byte[] sigs = new byte[cbR * 2];
Array.Copy(r, 0, sigs, cbR - r.Length, r.Length);
Array.Copy(s, 0, sigs, cbR + cbR - s.Length, s.Length);
return(sigs);
}
#if true
case AlgorithmValuesInt.EdDSA: {
ISigner eddsa;
if (_keyToSign[CoseKeyParameterKeys.EC_Curve].Equals(GeneralValues.Ed25519))
{
Ed25519PrivateKeyParameters privKey =
new Ed25519PrivateKeyParameters(_keyToSign[CoseKeyParameterKeys.OKP_D].GetByteString(), 0);
eddsa = new Ed25519Signer();
eddsa.Init(true, privKey);
}
else if (_keyToSign[CoseKeyParameterKeys.EC_Curve].Equals(GeneralValues.Ed448))
{
Ed448PrivateKeyParameters privKey =
new Ed448PrivateKeyParameters(_keyToSign[CoseKeyParameterKeys.OKP_D].GetByteString(), 0);
eddsa = new Ed448Signer(new byte[0]);
eddsa.Init(true, privKey);
}
else
{
throw new CoseException("Unrecognized curve");
}
eddsa.BlockUpdate(bytesToBeSigned, 0, bytesToBeSigned.Length);
return(eddsa.GenerateSignature());
}
#endif
default:
throw new CoseException("Unknown Algorithm Specified");
}
}
else
{
throw new CoseException("Algorithm incorrectly encoded");
}
}
