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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 1.8 and up.
package org.bouncycastle.pqc.crypto.rainbow;
import java.security.SecureRandom;
import org.bouncycastle.crypto.CipherParameters;
import org.bouncycastle.crypto.CryptoServicesRegistrar;
import org.bouncycastle.crypto.Digest;
import org.bouncycastle.crypto.params.ParametersWithRandom;
import org.bouncycastle.pqc.crypto.MessageSigner;
import org.bouncycastle.util.Arrays;
public class RainbowSigner
implements MessageSigner
{
private static final int MAXITS = 65536;
// Source of randomness
private SecureRandom random;
// The length of a document that can be signed with the privKey
int signableDocumentLength;
private ComputeInField cf = new ComputeInField();
private RainbowKeyParameters key;
private Digest hashAlgo;
private Version version;
public void init(boolean forSigning, CipherParameters param)
{
RainbowKeyParameters tmpParam;
if (forSigning)
{
if (param instanceof ParametersWithRandom)
{
ParametersWithRandom rParam = (ParametersWithRandom)param;
this.random = rParam.getRandom();
tmpParam = (RainbowKeyParameters)rParam.getParameters();
}
else
{
tmpParam = (RainbowKeyParameters)param;
SecureRandom sr = CryptoServicesRegistrar.getSecureRandom();
byte[] seed = new byte[tmpParam.getParameters().getLen_skseed()];
sr.nextBytes(seed);
this.random = new RainbowDRBG(seed, tmpParam.getParameters().getHash_algo());
}
this.version = tmpParam.getParameters().getVersion();
this.key = tmpParam;
}
else
{
this.key = (RainbowKeyParameters)param;
this.version = key.getParameters().getVersion();
}
this.signableDocumentLength = this.key.getDocLength();
this.hashAlgo = this.key.getParameters().getHash_algo();
}
private byte[] genSignature(byte[] message)
{
byte[] msgHash = new byte[hashAlgo.getDigestSize()];
hashAlgo.update(message, 0, message.length);
hashAlgo.doFinal(msgHash, 0);
int v1 = this.key.getParameters().getV1();
int o1 = this.key.getParameters().getO1();
int o2 = this.key.getParameters().getO2();
int m = this.key.getParameters().getM(); // o1 + o2
int n = this.key.getParameters().getN(); // o1 + o2 + v1
RainbowPrivateKeyParameters sk = (RainbowPrivateKeyParameters)this.key;
byte[] seed = RainbowUtil.hash(hashAlgo, sk.sk_seed, msgHash, new byte[hashAlgo.getDigestSize()]);
this.random = new RainbowDRBG(seed, sk.getParameters().getHash_algo());
short[] vinegar = new short[v1];
short[][] L1 = null; // layer 1 linear equations
short[][] L2; // layer 2 linear equations
short[] r_l1_F1 = new short[o1];
short[] r_l2_F1 = new short[o2];
short[] r_l2_F5 = new short[o2];
short[][] L2_F2 = new short[o2][o1];
short[][] L2_F3 = new short[o2][o2];
byte[] salt = new byte[sk.getParameters().getLen_salt()];
byte[] hash;
short[] h;
// x = S^-1 * h
short[] x = new short[m];
// y = F^-1 * x
short[] y_o1 = new short[o1];
short[] y_o2 = null;
// z = T^-1 * y
short[] z;
byte[] tmpRandom;
short temp;
short[] tmp_vec;
int counter = 0;
while (L1 == null && counter < MAXITS)
{
tmpRandom = new byte[v1];
this.random.nextBytes(tmpRandom);
for (int i = 0; i < v1; i++)
{
vinegar[i] = (short)(tmpRandom[i] & GF2Field.MASK);
}
L1 = new short[o1][o1];
for (int i = 0; i < v1; i++)
{
for (int k = 0; k < o1; k++)
{
for (int j = 0; j < o1; j++)
{
temp = GF2Field.multElem(sk.l1_F2[k][i][j], vinegar[i]);
L1[k][j] = GF2Field.addElem(L1[k][j], temp);
}
}
}
L1 = cf.inverse(L1);
counter++;
}
// Given the vinegars, pre-compute variables needed for layer 2
for (int k = 0; k < o1; k++)
{
r_l1_F1[k] = cf.multiplyMatrix_quad(sk.l1_F1[k], vinegar);
}
for (int i = 0; i < v1; i++)
{
for (int k = 0; k < o2; k++)
{
r_l2_F1[k] = cf.multiplyMatrix_quad(sk.l2_F1[k], vinegar);
for (int j = 0; j < o1; j++)
{
temp = GF2Field.multElem(sk.l2_F2[k][i][j], vinegar[i]);
L2_F2[k][j] = GF2Field.addElem(L2_F2[k][j], temp);
}
for (int j = 0; j < o2; j++)
{
temp = GF2Field.multElem(sk.l2_F3[k][i][j], vinegar[i]);
L2_F3[k][j] = GF2Field.addElem(L2_F3[k][j], temp);
}
}
}
byte[] mHash = new byte[m];
while (y_o2 == null && counter < MAXITS)
{
L2 = new short[o2][o2];
this.random.nextBytes(salt);
// h = (short)H(msg_digest||salt)
hash = RainbowUtil.hash(this.hashAlgo, msgHash, salt, mHash);
h = makeMessageRepresentative(hash);
// x = S^-1 * h
tmp_vec = cf.multiplyMatrix(sk.s1, Arrays.copyOfRange(h, o1, m));
tmp_vec = cf.addVect(Arrays.copyOf(h, o1), tmp_vec);
System.arraycopy(tmp_vec, 0, x, 0, o1);
System.arraycopy(h, o1, x, o1, o2); // identity part of S
// y = F^-1 * x
// layer 1: calculate y_o1
tmp_vec = cf.addVect(r_l1_F1, Arrays.copyOf(x, o1));
y_o1 = cf.multiplyMatrix(L1, tmp_vec);
// layer 2: calculate y_o2
tmp_vec = cf.multiplyMatrix(L2_F2, y_o1);
for (int k = 0; k < o2; k++)
{
r_l2_F5[k] = cf.multiplyMatrix_quad(sk.l2_F5[k], y_o1);
}
tmp_vec = cf.addVect(tmp_vec, r_l2_F5);
tmp_vec = cf.addVect(tmp_vec, r_l2_F1);
tmp_vec = cf.addVect(tmp_vec, Arrays.copyOfRange(x, o1, m));
for (int i = 0; i < o1; i++)
{
for (int k = 0; k < o2; k++)
{
for (int j = 0; j < o2; j++)
{
temp = GF2Field.multElem(sk.l2_F6[k][i][j], y_o1[i]);
L2[k][j] = GF2Field.addElem(L2[k][j], temp);
}
}
}
L2 = cf.addMatrix(L2, L2_F3);
// y_o2 = null if LES not solvable - try again
y_o2 = cf.solveEquation(L2, tmp_vec);
counter++;
}
// continue even though LES wasn't solvable for time consistency
y_o2 = (y_o2 == null) ? new short[o2] : y_o2;
// z = T^-1 * y
tmp_vec = cf.multiplyMatrix(sk.t1, y_o1);
z = cf.addVect(vinegar, tmp_vec);
tmp_vec = cf.multiplyMatrix(sk.t4, y_o2);
z = cf.addVect(z, tmp_vec);
tmp_vec = cf.multiplyMatrix(sk.t3, y_o2);
tmp_vec = cf.addVect(y_o1, tmp_vec);
z = Arrays.copyOf(z, n);
System.arraycopy(tmp_vec, 0, z, v1, o1);
System.arraycopy(y_o2, 0, z, o1 + v1, o2); // identity part of T
if (counter == MAXITS)
{
throw new IllegalStateException("unable to generate signature - LES not solvable");
}
// cast signature from short[] to byte[]
byte[] signature = RainbowUtil.convertArray(z);
return Arrays.concatenate(signature, salt);
}
public byte[] generateSignature(byte[] message)
{
return genSignature(message);
}
public boolean verifySignature(byte[] message, byte[] signature)
{
byte[] msgHash = new byte[hashAlgo.getDigestSize()];
hashAlgo.update(message, 0, message.length);
hashAlgo.doFinal(msgHash, 0);
int m = this.key.getParameters().getM(); // o1 + o2
int n = this.key.getParameters().getN(); // o1 + o2 + v1
RainbowPublicMap p_map = new RainbowPublicMap(this.key.getParameters());
// h = (short)H(msg_digest||salt)
byte[] salt = Arrays.copyOfRange(signature, n, signature.length);
byte[] hash = RainbowUtil.hash(this.hashAlgo, msgHash, salt, new byte[m]);
short[] h = makeMessageRepresentative(hash);
// verificationResult = P(sig)
byte[] sig_msg = Arrays.copyOfRange(signature, 0, n);
short[] sig = RainbowUtil.convertArray(sig_msg);
short[] verificationResult;
switch (this.version)
{
case CLASSIC:
RainbowPublicKeyParameters pk = (RainbowPublicKeyParameters)this.key;
verificationResult = p_map.publicMap(pk, sig);
break;
case CIRCUMZENITHAL:
case COMPRESSED:
RainbowPublicKeyParameters cpk = (RainbowPublicKeyParameters)this.key;
verificationResult = p_map.publicMap_cyclic(cpk, sig);
break;
default:
throw new IllegalArgumentException(
"No valid version. Please choose one of the following: classic, circumzenithal, compressed");
}
// compare
return RainbowUtil.equals(h, verificationResult);
}
/**
* This function creates the representative of the message which gets signed
* or verified.
*
* @param message the message
* @return message representative
*/
private short[] makeMessageRepresentative(byte[] message)
{
// the message representative
short[] output = new short[this.signableDocumentLength];
int h = 0;
int i = 0;
do
{
if (i >= message.length)
{
break;
}
output[i] = (short)(message[h] & 0xff);
h++;
i++;
}
while (i < output.length);
return output;
}
}
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