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package gnu.crypto.key.srp6;
// ----------------------------------------------------------------------------
// $Id: SRPKeyPairGenerator.java,v 1.1 2003/09/26 23:50:48 raif Exp $
//
// Copyright (C) 2003 Free Software Foundation, Inc.
//
// This file is part of GNU Crypto.
//
// GNU Crypto is free software; you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation; either version 2, or (at your option)
// any later version.
//
// GNU Crypto is distributed in the hope that it will be useful, but
// WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
// General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program; see the file COPYING. If not, write to the
//
// Free Software Foundation Inc.,
// 59 Temple Place - Suite 330,
// Boston, MA 02111-1307
// USA
//
// Linking this library statically or dynamically with other modules is
// making a combined work based on this library. Thus, the terms and
// conditions of the GNU General Public License cover the whole
// combination.
//
// As a special exception, the copyright holders of this library give
// you permission to link this library with independent modules to
// produce an executable, regardless of the license terms of these
// independent modules, and to copy and distribute the resulting
// executable under terms of your choice, provided that you also meet,
// for each linked independent module, the terms and conditions of the
// license of that module. An independent module is a module which is
// not derived from or based on this library. If you modify this
// library, you may extend this exception to your version of the
// library, but you are not obligated to do so. If you do not wish to
// do so, delete this exception statement from your version.
// ----------------------------------------------------------------------------
import gnu.crypto.Registry;
import gnu.crypto.key.IKeyPairGenerator;
import gnu.crypto.util.PRNG;
import gnu.crypto.util.Prime;
import java.io.PrintWriter;
import java.math.BigInteger;
import java.security.KeyPair;
import java.security.SecureRandom;
import java.util.Map;
/**
*
*
* Reference:
*
* - SRP Protocol Design
* Thomas J. Wu.
*
*
* @version $Revision: 1.1 $
*/
public class SRPKeyPairGenerator implements IKeyPairGenerator {
// Debugging methods and variables
// -------------------------------------------------------------------------
private static final String NAME = "srp";
private static final boolean DEBUG = false;
private static final int debuglevel = 5;
private static final PrintWriter err = new PrintWriter(System.out, true);
private static void debug(String s) {
err.println(">>> "+NAME+": "+s);
}
// Constants and variables
// -------------------------------------------------------------------------
private static final BigInteger ZERO = BigInteger.ZERO;
private static final BigInteger ONE = BigInteger.ONE;
private static final BigInteger TWO = BigInteger.valueOf(2L);
private static final BigInteger THREE = BigInteger.valueOf(3L);
/** Property name of the length (Integer) of the modulus (N) of an SRP key. */
public static final String MODULUS_LENGTH = "gnu.crypto.srp.L";
/** Property name of the Boolean indicating wether or not to use defaults. */
public static final String USE_DEFAULTS = "gnu.crypto.srp.use.defaults";
/** Property name of the modulus (N) of an SRP key. */
public static final String SHARED_MODULUS = "gnu.crypto.srp.N";
/** Property name of the generator (g) of an SRP key. */
public static final String GENERATOR= "gnu.crypto.srp.g";
/** Property name of the user's verifier (v) for a Server SRP key. */
public static final String USER_VERIFIER = "gnu.crypto.srp.v";
/**
* Property name of an optional {@link SecureRandom} instance to use. The
* default is to use a classloader singleton from {@link PRNG}.
*/
public static final String SOURCE_OF_RANDOMNESS = "gnu.crypto.srp.prng";
/** Default value for the modulus length. */
private static final int DEFAULT_MODULUS_LENGTH = 1024;
/** The optional {@link SecureRandom} instance to use. */
private SecureRandom rnd = null;
/** Bit length of the shared modulus. */
private int l;
/** The shared public modulus. */
private BigInteger N;
/** The Field generator. */
private BigInteger g;
/** The user's verifier MPI. */
private BigInteger v;
// Constructor(s)
// -------------------------------------------------------------------------
// implicit 0-arguments constructor
// Class methods
// -------------------------------------------------------------------------
// Instance methods
// -------------------------------------------------------------------------
// gnu.crypto.key.IKeyPairGenerator interface implementation ---------------
public String name() {
return Registry.SRP_KPG;
}
public void setup(Map attributes) {
// do we have a SecureRandom, or should we use our own?
rnd = (SecureRandom) attributes.get(SOURCE_OF_RANDOMNESS);
N = (BigInteger) attributes.get(SHARED_MODULUS);
if (N != null) {
l = N.bitLength();
g = (BigInteger) attributes.get(GENERATOR);
if (g == null) {
g = TWO;
}
SRPAlgorithm.checkParams(N, g);
} else { // generate or use default values for N and g
Boolean useDefaults = (Boolean) attributes.get(USE_DEFAULTS);
if (useDefaults == null) {
useDefaults = Boolean.TRUE;
}
Integer L = (Integer) attributes.get(MODULUS_LENGTH);
l = DEFAULT_MODULUS_LENGTH;
if (useDefaults.equals(Boolean.TRUE)) {
if (L != null) {
l = L.intValue();
switch (l) {
case 512: N = SRPAlgorithm.N_512; break;
case 640: N = SRPAlgorithm.N_640; break;
case 768: N = SRPAlgorithm.N_768; break;
case 1024: N = SRPAlgorithm.N_1024; break;
case 1280: N = SRPAlgorithm.N_1280; break;
case 1536: N = SRPAlgorithm.N_1536; break;
case 2048: N = SRPAlgorithm.N_2048; break;
default: throw new IllegalArgumentException(
"unknown default shared modulus bit length");
}
g = TWO;
l = N.bitLength();
}
} else { // generate new N and g
if (L != null) {
l = L.intValue();
if ((l % 256) != 0 || l < 512 || l > 2048) {
throw new IllegalArgumentException("invalid shared modulus bit length");
}
}
}
}
// are we using this generator on the server side, or the client side?
v = (BigInteger) attributes.get(USER_VERIFIER);
}
public KeyPair generate() {
if (N == null) {
BigInteger[] params = generateParameters();
BigInteger q = params[0];
N = params[1];
g = params[2];
if (DEBUG && debuglevel > 0) {
debug("q: "+q.toString(16));
debug("N: "+N.toString(16));
debug("g: "+g.toString(16));
}
}
return (v != null ? hostKeyPair() : userKeyPair());
}
// helper methods ----------------------------------------------------------
private synchronized BigInteger[] generateParameters() {
// N A large safe prime (N = 2q+1, where q is prime)
// g A generator modulo N
BigInteger q, p, g;
byte[] qBytes = new byte[l / 8];
do {
do {
nextRandomBytes(qBytes);
q = new BigInteger(1, qBytes);
q = q.setBit(0).setBit(l-2).clearBit(l-1);
} while (!Prime.isProbablePrime(q));
p = q.multiply(TWO).add(ONE);
} while (p.bitLength() != l || !Prime.isProbablePrime(p));
// compute g. from FIPS-186, Appendix 4: e == 2
BigInteger p_minus_1 = p.subtract(ONE);
g = TWO;
// Set h = any integer, where 1 < h < p - 1 and
// h differs from any value previously tried
for (BigInteger h = TWO; h.compareTo(p_minus_1) < 0; h = h.add(ONE)) {
// Set g = h**2 mod p
g = h.modPow(TWO, p);
// If g = 1, go to step 3
if (!g.equals(ONE)) {
break;
}
}
return new BigInteger[] { q, p, g };
}
private KeyPair hostKeyPair() {
byte[] bBytes = new byte[(l + 7) / 8];
BigInteger b, B;
do {
do {
nextRandomBytes(bBytes);
b = new BigInteger(1, bBytes);
} while (b.compareTo(ONE) <= 0 || b.compareTo(N) >= 0);
B = THREE.multiply(v).add(g.modPow(b, N)).mod(N);
} while (B.compareTo(ZERO) == 0 || B.compareTo(N) >= 0);
KeyPair result = new KeyPair(
new SRPPublicKey( new BigInteger[] { N, g, B }),
new SRPPrivateKey(new BigInteger[] { N, g, b, v }));
return result;
}
private KeyPair userKeyPair() {
byte[] aBytes = new byte[(l + 7) / 8];
BigInteger a, A;
do {
do {
nextRandomBytes(aBytes);
a = new BigInteger(1, aBytes);
} while (a.compareTo(ONE) <= 0 || a.compareTo(N) >= 0);
A = g.modPow(a, N);
} while (A.compareTo(ZERO) == 0 || A.compareTo(N) >= 0);
KeyPair result = new KeyPair(
new SRPPublicKey( new BigInteger[] { N, g, A } ),
new SRPPrivateKey(new BigInteger[] { N, g, a } ));
return result;
}
private void nextRandomBytes(byte[] buffer) {
if (rnd != null) {
rnd.nextBytes(buffer);
} else {
PRNG.nextBytes(buffer);
}
}
}