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The Bouncy Castle Crypto package is a Java implementation of cryptographic algorithms. This jar contains JCE provider and lightweight API for the Bouncy Castle Cryptography APIs for JDK 1.4.
package org.bouncycastle.asn1.ua;
import java.math.BigInteger;
import java.util.Random;
import org.bouncycastle.math.ec.ECConstants;
import org.bouncycastle.math.ec.ECCurve;
import org.bouncycastle.math.ec.ECFieldElement;
import org.bouncycastle.math.ec.ECPoint;
/**
* DSTU4145 encodes points somewhat differently than X9.62
* It compresses the point to the size of the field element
*/
public abstract class DSTU4145PointEncoder
{
private static ECFieldElement trace(ECFieldElement fe)
{
ECFieldElement t = fe;
for (int i = 1; i < fe.getFieldSize(); ++i)
{
t = t.square().add(fe);
}
return t;
}
/**
* Solves a quadratic equation z2 + z = beta
(X9.62
* D.1.6) The other solution is z + 1
.
*
* @param beta The value to solve the quadratic equation for.
* @return the solution for z2 + z = beta
or
* null
if no solution exists.
*/
private static ECFieldElement solveQuadraticEquation(ECCurve curve, ECFieldElement beta)
{
if (beta.isZero())
{
return beta;
}
ECFieldElement zeroElement = curve.fromBigInteger(ECConstants.ZERO);
ECFieldElement z = null;
ECFieldElement gamma = null;
Random rand = new Random();
int m = beta.getFieldSize();
do
{
ECFieldElement t = curve.fromBigInteger(new BigInteger(m, rand));
z = zeroElement;
ECFieldElement w = beta;
for (int i = 1; i <= m - 1; i++)
{
ECFieldElement w2 = w.square();
z = z.square().add(w2.multiply(t));
w = w2.add(beta);
}
if (!w.isZero())
{
return null;
}
gamma = z.square().add(z);
}
while (gamma.isZero());
return z;
}
public static byte[] encodePoint(ECPoint Q)
{
/*if (!Q.isCompressed())
Q=new ECPoint.F2m(Q.getCurve(),Q.getX(),Q.getY(),true);
byte[] bytes=Q.getEncoded();
if (bytes[0]==0x02)
bytes[bytes.length-1]&=0xFE;
else if (bytes[0]==0x02)
bytes[bytes.length-1]|=0x01;
return Arrays.copyOfRange(bytes, 1, bytes.length);*/
Q = Q.normalize();
ECFieldElement x = Q.getAffineXCoord();
byte[] bytes = x.getEncoded();
if (!x.isZero())
{
ECFieldElement z = Q.getAffineYCoord().divide(x);
if (trace(z).isOne())
{
bytes[bytes.length - 1] |= 0x01;
}
else
{
bytes[bytes.length - 1] &= 0xFE;
}
}
return bytes;
}
public static ECPoint decodePoint(ECCurve curve, byte[] bytes)
{
/*byte[] bp_enc=new byte[bytes.length+1];
if (0==(bytes[bytes.length-1]&0x1))
bp_enc[0]=0x02;
else
bp_enc[0]=0x03;
System.arraycopy(bytes, 0, bp_enc, 1, bytes.length);
if (!trace(curve.fromBigInteger(new BigInteger(1, bytes))).equals(curve.getA().toBigInteger()))
bp_enc[bp_enc.length-1]^=0x01;
return curve.decodePoint(bp_enc);*/
ECFieldElement k = curve.fromBigInteger(BigInteger.valueOf(bytes[bytes.length - 1] & 0x1));
ECFieldElement xp = curve.fromBigInteger(new BigInteger(1, bytes));
if (!trace(xp).equals(curve.getA()))
{
xp = xp.addOne();
}
ECFieldElement yp = null;
if (xp.isZero())
{
yp = curve.getB().sqrt();
}
else
{
ECFieldElement beta = xp.square().invert().multiply(curve.getB()).add(curve.getA()).add(xp);
ECFieldElement z = solveQuadraticEquation(curve, beta);
if (z != null)
{
if (!trace(z).equals(k))
{
z = z.addOne();
}
yp = xp.multiply(z);
}
}
if (yp == null)
{
throw new IllegalArgumentException("Invalid point compression");
}
return curve.validatePoint(xp.toBigInteger(), yp.toBigInteger());
}
}
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