org.bouncycastle.tls.crypto.impl.jcajce.ECUtil Maven / Gradle / Ivy
package org.bouncycastle.tls.crypto.impl.jcajce;
import java.math.BigInteger;
import java.security.AlgorithmParameters;
import java.security.KeyPair;
import java.security.KeyPairGenerator;
import java.security.PrivateKey;
import java.security.interfaces.ECKey;
import java.security.interfaces.ECPrivateKey;
import java.security.spec.AlgorithmParameterSpec;
import java.security.spec.ECField;
import java.security.spec.ECFieldF2m;
import java.security.spec.ECFieldFp;
import java.security.spec.ECGenParameterSpec;
import java.security.spec.ECParameterSpec;
import java.security.spec.EllipticCurve;
import org.bouncycastle.math.ec.ECCurve;
class ECUtil
{
static ECCurve convertCurve(EllipticCurve ec, BigInteger order, int cofactor)
{
ECField field = ec.getField();
BigInteger a = ec.getA();
BigInteger b = ec.getB();
if (field instanceof ECFieldFp)
{
return new ECCurve.Fp(((ECFieldFp)field).getP(), a, b, order, BigInteger.valueOf(cofactor));
}
else
{
ECFieldF2m fieldF2m = (ECFieldF2m)field;
int m = fieldF2m.getM();
int ks[] = convertMidTerms(fieldF2m.getMidTermsOfReductionPolynomial());
return new ECCurve.F2m(m, ks[0], ks[1], ks[2], a, b, order, BigInteger.valueOf(cofactor));
}
}
static int[] convertMidTerms(int[] k)
{
int[] res = new int[3];
if (k.length == 1)
{
res[0] = k[0];
}
else
{
if (k.length != 3)
{
throw new IllegalArgumentException("Only Trinomials and pentanomials supported");
}
if (k[0] < k[1] && k[0] < k[2])
{
res[0] = k[0];
if (k[1] < k[2])
{
res[1] = k[1];
res[2] = k[2];
}
else
{
res[1] = k[2];
res[2] = k[1];
}
}
else if (k[1] < k[2])
{
res[0] = k[1];
if (k[0] < k[2])
{
res[1] = k[0];
res[2] = k[2];
}
else
{
res[1] = k[2];
res[2] = k[0];
}
}
else
{
res[0] = k[2];
if (k[0] < k[1])
{
res[1] = k[0];
res[2] = k[1];
}
else
{
res[1] = k[1];
res[2] = k[0];
}
}
}
return res;
}
static AlgorithmParameterSpec createInitSpec(String curveName)
{
return new ECGenParameterSpec(curveName);
}
static AlgorithmParameters getAlgorithmParameters(JcaTlsCrypto crypto, String curveName)
{
return getAlgorithmParameters(crypto, new ECGenParameterSpec(curveName));
}
static AlgorithmParameters getAlgorithmParameters(JcaTlsCrypto crypto, AlgorithmParameterSpec initSpec)
{
try
{
AlgorithmParameters ecAlgParams = crypto.getHelper().createAlgorithmParameters("EC");
ecAlgParams.init(initSpec);
ECParameterSpec ecSpec = ecAlgParams.getParameterSpec(ECParameterSpec.class);
if (null != ecSpec)
{
return ecAlgParams;
}
}
catch (Exception e)
{
}
return null;
}
static ECParameterSpec getECParameterSpec(JcaTlsCrypto crypto, String curveName)
{
return getECParameterSpec(crypto, createInitSpec(curveName));
}
static ECParameterSpec getECParameterSpec(JcaTlsCrypto crypto, AlgorithmParameterSpec initSpec)
{
// Try the "modern" way
try
{
AlgorithmParameters ecAlgParams = crypto.getHelper().createAlgorithmParameters("EC");
ecAlgParams.init(initSpec);
ECParameterSpec ecSpec = ecAlgParams.getParameterSpec(ECParameterSpec.class);
if (null != ecSpec)
{
return ecSpec;
}
}
catch (Exception e)
{
}
/*
* Try a more round about way (the IBM JCE is an example of this).
*
* NOTE: For these providers, we will not be able to provide an AlgorithmParameters object
* to BCJSSE for use with AlgorithmConstraints checks, so curve constraints will not work.
*/
try
{
KeyPairGenerator kpGen = crypto.getHelper().createKeyPairGenerator("EC");
kpGen.initialize(initSpec, crypto.getSecureRandom());
KeyPair kp = kpGen.generateKeyPair();
return ((ECKey)kp.getPrivate()).getParams();
}
catch (Exception e)
{
}
return null;
}
static boolean isECPrivateKey(PrivateKey key)
{
return key instanceof ECPrivateKey || "EC".equalsIgnoreCase(key.getAlgorithm());
}
static boolean isCurveSupported(JcaTlsCrypto crypto, String curveName)
{
return isCurveSupported(crypto, new ECGenParameterSpec(curveName));
}
static boolean isCurveSupported(JcaTlsCrypto crypto, ECGenParameterSpec initSpec)
{
return null != getECParameterSpec(crypto, initSpec);
}
}