public virtual BigInteger[] GenerateSignature(byte[] message)
{
DsaParameters parameters = key.Parameters;
BigInteger q = parameters.Q;
BigInteger bigInteger = CalculateE(q, message);
BigInteger x = ((DsaPrivateKeyParameters)key).X;
if (kCalculator.IsDeterministic)
{
kCalculator.Init(q, x, message);
}
else
{
kCalculator.Init(q, random);
}
BigInteger bigInteger2 = kCalculator.NextK();
BigInteger bigInteger3 = parameters.G.ModPow(bigInteger2, parameters.P).Mod(q);
bigInteger2 = bigInteger2.ModInverse(q).Multiply(bigInteger.Add(x.Multiply(bigInteger3)));
BigInteger bigInteger4 = bigInteger2.Mod(q);
return(new BigInteger[2] {
bigInteger3, bigInteger4
});
}
/**
* Generate a signature for the given message using the key we were
* initialised with. For conventional DSA the message should be a SHA-1
* hash of the message of interest.
*
* @param message the message that will be verified later.
*/
public virtual BigInteger[] GenerateSignature(byte[] message)
{
DsaParameters parameters = key.Parameters;
BigInteger q = parameters.Q;
BigInteger m = CalculateE(q, message);
BigInteger x = ((DsaPrivateKeyParameters)key).X;
if (kCalculator.IsDeterministic)
{
kCalculator.Init(q, x, message);
}
else
{
kCalculator.Init(q, random);
}
BigInteger k = kCalculator.NextK();
BigInteger r = parameters.G.ModPow(k, parameters.P).Mod(q);
k = k.ModInverse(q).Multiply(m.Add(x.Multiply(r)));
BigInteger s = k.Mod(q);
return(new BigInteger[] { r, s });
}
/// <inheritdoc />
public void GenerateSignature(byte[] message, out BigInteger r, out BigInteger s)
{
BigInteger n = _ecDomain.N;
BigInteger e = CalculateE(n, message);
var d = new BigInteger(_privateKey.EncodedKey);
if (_kCalculator.IsDeterministic)
{
_kCalculator.Init(n, d, message);
}
else
{
_kCalculator.Init(n, _random);
}
// 5.3.2
// Generate s
do
{
BigInteger k;
// Generate r
do
{
k = _kCalculator.NextK();
ECPoint p = EcBasePointMultiplier.Multiply(_ecDomain.G, k).Normalize();
// 5.3.3
r = p.AffineXCoord.ToBigInteger().Mod(n);
} while (r.SignValue == 0);
s = k.ModInverse(n).Multiply(e.Add(d.Multiply(r))).Mod(n);
} while (s.SignValue == 0);
}
public virtual void Init(bool forSigning, ICipherParameters parameters)
{
ICipherParameters baseParam;
byte[] userID;
if (parameters is ParametersWithID)
{
baseParam = ((ParametersWithID)parameters).Parameters;
userID = ((ParametersWithID)parameters).GetID();
if (userID.Length >= 8192)
{
throw new ArgumentException("SM2 user ID must be less than 2^16 bits long");
}
}
else
{
baseParam = parameters;
// the default value, string value is "1234567812345678"
userID = Hex.Decode("31323334353637383132333435363738");
}
if (forSigning)
{
if (baseParam is ParametersWithRandom)
{
ParametersWithRandom rParam = (ParametersWithRandom)baseParam;
ecKey = (ECKeyParameters)rParam.Parameters;
ecParams = ecKey.Parameters;
kCalculator.Init(ecParams.N, rParam.Random);
}
else
{
ecKey = (ECKeyParameters)baseParam;
ecParams = ecKey.Parameters;
kCalculator.Init(ecParams.N, new SecureRandom());
}
pubPoint = CreateBasePointMultiplier().Multiply(ecParams.G, ((ECPrivateKeyParameters)ecKey).D).Normalize();
}
else
{
ecKey = (ECKeyParameters)baseParam;
ecParams = ecKey.Parameters;
pubPoint = ((ECPublicKeyParameters)ecKey).Q;
}
digest.Reset();
z = GetZ(userID);
digest.BlockUpdate(z, 0, z.Length);
}
// 5.3 pg 28
/**
* Generate a signature for the given message using the key we were
* initialised with. For conventional DSA the message should be a SHA-1
* hash of the message of interest.
*
* @param message the message that will be verified later.
*/
public virtual BigInteger[] GenerateSignature(byte[] message)
{
ECDomainParameters ec = key.Parameters;
BigInteger n = ec.N;
BigInteger e = CalculateE(n, message);
BigInteger d = ((ECPrivateKeyParameters)key).D;
if (kCalculator.IsDeterministic)
{
kCalculator.Init(n, d, message);
}
else
{
kCalculator.Init(n, random);
}
BigInteger r, s;
ECMultiplier basePointMultiplier = CreateBasePointMultiplier();
// 5.3.2
do // Generate s
{
BigInteger k;
byte[] rBytes = null;
do // Generate r
{
do
{
k = kCalculator.NextK();
ECPoint p = basePointMultiplier.Multiply(ec.G, k).Normalize();
// 5.3.3
r = p.AffineXCoord.ToBigInteger().Mod(n);
}while(r.SignValue == 0);
}while(forceLowR && r.ToByteArrayUnsigned()[0] >= 0x80);
s = k.ModInverse(n).Multiply(e.Add(d.Multiply(r))).Mod(n);
}while(s.SignValue == 0);
return(new BigInteger[] { r, s });
}
public virtual BigInteger[] GenerateSignature(byte[] message)
{
ECDomainParameters parameters = key.Parameters;
BigInteger n = parameters.N;
BigInteger bigInteger = CalculateE(n, message);
BigInteger d = ((ECPrivateKeyParameters)key).D;
if (kCalculator.IsDeterministic)
{
kCalculator.Init(n, d, message);
}
else
{
kCalculator.Init(n, random);
}
ECMultiplier eCMultiplier = CreateBasePointMultiplier();
BigInteger bigInteger3;
BigInteger bigInteger4;
while (true)
{
BigInteger bigInteger2 = kCalculator.NextK();
ECPoint eCPoint = eCMultiplier.Multiply(parameters.G, bigInteger2).Normalize();
bigInteger3 = eCPoint.AffineXCoord.ToBigInteger().Mod(n);
if (bigInteger3.SignValue != 0)
{
bigInteger4 = bigInteger2.ModInverse(n).Multiply(bigInteger.Add(d.Multiply(bigInteger3))).Mod(n);
if (bigInteger4.SignValue != 0)
{
break;
}
}
}
return(new BigInteger[2]
{
bigInteger3,
bigInteger4
});
}
public Requester()
{
_k = new RandomDsaKCalculator();
_k.Init(BigInteger.Arbitrary(256), new SecureRandom());
}
