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package sun.security.provider;
import java.math.BigInteger;
import java.security.AlgorithmParameterGeneratorSpi;
import java.security.AlgorithmParameters;
import java.security.InvalidAlgorithmParameterException;
import java.security.NoSuchAlgorithmException;
import java.security.NoSuchProviderException;
import java.security.InvalidParameterException;
import java.security.MessageDigest;
import java.security.SecureRandom;
import java.security.ProviderException;
import java.security.spec.AlgorithmParameterSpec;
import java.security.spec.InvalidParameterSpecException;
import java.security.spec.DSAParameterSpec;
import java.security.spec.DSAGenParameterSpec;
import static sun.security.util.SecurityProviderConstants.DEF_DSA_KEY_SIZE;
import static sun.security.util.SecurityProviderConstants.getDefDSASubprimeSize;
This class generates parameters for the DSA algorithm.
Author: Jan Luehe See Also: Since: 1.2
/**
* This class generates parameters for the DSA algorithm.
*
* @author Jan Luehe
*
*
* @see java.security.AlgorithmParameters
* @see java.security.spec.AlgorithmParameterSpec
* @see DSAParameters
*
* @since 1.2
*/
public class DSAParameterGenerator extends AlgorithmParameterGeneratorSpi {
// the length of prime P, subPrime Q, and seed in bits
private int valueL = -1;
private int valueN = -1;
private int seedLen = -1;
// the source of randomness
private SecureRandom random;
public DSAParameterGenerator() {
}
Initializes this parameter generator for a certain strength
and source of randomness.
Params: - strength – the strength (size of prime) in bits
- random – the source of randomness
/**
* Initializes this parameter generator for a certain strength
* and source of randomness.
*
* @param strength the strength (size of prime) in bits
* @param random the source of randomness
*/
@Override
protected void engineInit(int strength, SecureRandom random) {
if ((strength != 2048) && (strength != 3072) &&
((strength < 512) || (strength > 1024) || (strength % 64 != 0))) {
throw new InvalidParameterException(
"Unexpected strength (size of prime): " + strength +
". Prime size should be 512-1024, 2048, or 3072");
}
this.valueL = strength;
this.valueN = getDefDSASubprimeSize(strength);
this.seedLen = valueN;
this.random = random;
}
Initializes this parameter generator with a set of
algorithm-specific parameter generation values.
Params: - genParamSpec – the set of algorithm-specific parameter
generation values
- random – the source of randomness
Throws: - InvalidAlgorithmParameterException – if the given parameter
generation values are inappropriate for this parameter generator
/**
* Initializes this parameter generator with a set of
* algorithm-specific parameter generation values.
*
* @param genParamSpec the set of algorithm-specific parameter
* generation values
* @param random the source of randomness
*
* @exception InvalidAlgorithmParameterException if the given parameter
* generation values are inappropriate for this parameter generator
*/
@Override
protected void engineInit(AlgorithmParameterSpec genParamSpec,
SecureRandom random) throws InvalidAlgorithmParameterException {
if (!(genParamSpec instanceof DSAGenParameterSpec)) {
throw new InvalidAlgorithmParameterException("Invalid parameter");
}
DSAGenParameterSpec dsaGenParams = (DSAGenParameterSpec)genParamSpec;
// directly initialize using the already validated values
this.valueL = dsaGenParams.getPrimePLength();
this.valueN = dsaGenParams.getSubprimeQLength();
this.seedLen = dsaGenParams.getSeedLength();
this.random = random;
}
Generates the parameters.
Returns: the new AlgorithmParameters object
/**
* Generates the parameters.
*
* @return the new AlgorithmParameters object
*/
@Override
protected AlgorithmParameters engineGenerateParameters() {
AlgorithmParameters algParams = null;
try {
if (this.random == null) {
this.random = new SecureRandom();
}
if (valueL == -1) {
engineInit(DEF_DSA_KEY_SIZE, this.random);
}
BigInteger[] pAndQ = generatePandQ(this.random, valueL,
valueN, seedLen);
BigInteger paramP = pAndQ[0];
BigInteger paramQ = pAndQ[1];
BigInteger paramG = generateG(paramP, paramQ);
DSAParameterSpec dsaParamSpec =
new DSAParameterSpec(paramP, paramQ, paramG);
algParams = AlgorithmParameters.getInstance("DSA", "SUN");
algParams.init(dsaParamSpec);
} catch (InvalidParameterSpecException e) {
// this should never happen
throw new RuntimeException(e.getMessage());
} catch (NoSuchAlgorithmException e) {
// this should never happen, because we provide it
throw new RuntimeException(e.getMessage());
} catch (NoSuchProviderException e) {
// this should never happen, because we provide it
throw new RuntimeException(e.getMessage());
}
return algParams;
}
/*
* Generates the prime and subprime parameters for DSA,
* using the provided source of randomness.
* This method will generate new seeds until a suitable
* seed has been found.
*
* @param random the source of randomness to generate the
* seed
* @param valueL the size of <code>p</code>, in bits.
* @param valueN the size of <code>q</code>, in bits.
* @param seedLen the length of <code>seed</code>, in bits.
*
* @return an array of BigInteger, with <code>p</code> at index 0 and
* <code>q</code> at index 1, the seed at index 2, and the counter value
* at index 3.
*/
private static BigInteger[] generatePandQ(SecureRandom random, int valueL,
int valueN, int seedLen) {
String hashAlg = null;
if (valueN == 160) {
hashAlg = "SHA";
} else if (valueN == 224) {
hashAlg = "SHA-224";
} else if (valueN == 256) {
hashAlg = "SHA-256";
}
MessageDigest hashObj = null;
try {
hashObj = MessageDigest.getInstance(hashAlg);
} catch (NoSuchAlgorithmException nsae) {
// should never happen
nsae.printStackTrace();
}
/* Step 3, 4: Useful variables */
int outLen = hashObj.getDigestLength()*8;
int n = (valueL - 1) / outLen;
int b = (valueL - 1) % outLen;
byte[] seedBytes = new byte[seedLen/8];
BigInteger twoSl = BigInteger.TWO.pow(seedLen);
int primeCertainty = -1;
if (valueL <= 1024) {
primeCertainty = 80;
} else if (valueL == 2048) {
primeCertainty = 112;
} else if (valueL == 3072) {
primeCertainty = 128;
}
if (primeCertainty < 0) {
throw new ProviderException("Invalid valueL: " + valueL);
}
BigInteger resultP, resultQ, seed = null;
int counter;
while (true) {
do {
/* Step 5 */
random.nextBytes(seedBytes);
seed = new BigInteger(1, seedBytes);
/* Step 6 */
BigInteger U = new BigInteger(1, hashObj.digest(seedBytes)).
mod(BigInteger.TWO.pow(valueN - 1));
/* Step 7 */
resultQ = BigInteger.TWO.pow(valueN - 1)
.add(U)
.add(BigInteger.ONE)
.subtract(U.mod(BigInteger.TWO));
} while (!resultQ.isProbablePrime(primeCertainty));
/* Step 10 */
BigInteger offset = BigInteger.ONE;
/* Step 11 */
for (counter = 0; counter < 4*valueL; counter++) {
BigInteger[] V = new BigInteger[n + 1];
/* Step 11.1 */
for (int j = 0; j <= n; j++) {
BigInteger J = BigInteger.valueOf(j);
BigInteger tmp = (seed.add(offset).add(J)).mod(twoSl);
byte[] vjBytes = hashObj.digest(toByteArray(tmp));
V[j] = new BigInteger(1, vjBytes);
}
/* Step 11.2 */
BigInteger W = V[0];
for (int i = 1; i < n; i++) {
W = W.add(V[i].multiply(BigInteger.TWO.pow(i * outLen)));
}
W = W.add((V[n].mod(BigInteger.TWO.pow(b)))
.multiply(BigInteger.TWO.pow(n * outLen)));
/* Step 11.3 */
BigInteger twoLm1 = BigInteger.TWO.pow(valueL - 1);
BigInteger X = W.add(twoLm1);
/* Step 11.4, 11.5 */
BigInteger c = X.mod(resultQ.multiply(BigInteger.TWO));
resultP = X.subtract(c.subtract(BigInteger.ONE));
/* Step 11.6, 11.7 */
if (resultP.compareTo(twoLm1) > -1
&& resultP.isProbablePrime(primeCertainty)) {
/* Step 11.8 */
BigInteger[] result = {resultP, resultQ, seed,
BigInteger.valueOf(counter)};
return result;
}
/* Step 11.9 */
offset = offset.add(BigInteger.valueOf(n)).add(BigInteger.ONE);
}
}
}
/*
* Generates the <code>g</code> parameter for DSA.
*
* @param p the prime, <code>p</code>.
* @param q the subprime, <code>q</code>.
*
* @param the <code>g</code>
*/
private static BigInteger generateG(BigInteger p, BigInteger q) {
BigInteger h = BigInteger.ONE;
/* Step 1 */
BigInteger pMinusOneOverQ = (p.subtract(BigInteger.ONE)).divide(q);
BigInteger resultG = BigInteger.ONE;
while (resultG.compareTo(BigInteger.TWO) < 0) {
/* Step 3 */
resultG = h.modPow(pMinusOneOverQ, p);
h = h.add(BigInteger.ONE);
}
return resultG;
}
/*
* Converts the result of a BigInteger.toByteArray call to an exact
* signed magnitude representation for any positive number.
*/
private static byte[] toByteArray(BigInteger bigInt) {
byte[] result = bigInt.toByteArray();
if (result[0] == 0) {
byte[] tmp = new byte[result.length - 1];
System.arraycopy(result, 1, tmp, 0, tmp.length);
result = tmp;
}
return result;
}
}