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author | upstream source tree <ports@midipix.org> | 2015-03-15 20:14:05 -0400 |
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committer | upstream source tree <ports@midipix.org> | 2015-03-15 20:14:05 -0400 |
commit | 554fd8c5195424bdbcabf5de30fdc183aba391bd (patch) | |
tree | 976dc5ab7fddf506dadce60ae936f43f58787092 /libjava/classpath/gnu/javax/crypto/key/dh/RFC2631.java | |
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Diffstat (limited to 'libjava/classpath/gnu/javax/crypto/key/dh/RFC2631.java')
-rw-r--r-- | libjava/classpath/gnu/javax/crypto/key/dh/RFC2631.java | 217 |
1 files changed, 217 insertions, 0 deletions
diff --git a/libjava/classpath/gnu/javax/crypto/key/dh/RFC2631.java b/libjava/classpath/gnu/javax/crypto/key/dh/RFC2631.java new file mode 100644 index 000000000..60ef49409 --- /dev/null +++ b/libjava/classpath/gnu/javax/crypto/key/dh/RFC2631.java @@ -0,0 +1,217 @@ +/* RFC2631.java -- + Copyright (C) 2003, 2006 Free Software Foundation, Inc. + +This file is a part of GNU Classpath. + +GNU Classpath 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 of the License, or (at +your option) any later version. + +GNU Classpath 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 GNU Classpath; if not, write to the Free Software +Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 +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. */ + + +package gnu.javax.crypto.key.dh; + +import gnu.java.security.hash.Sha160; +import gnu.java.security.util.PRNG; + +import java.math.BigInteger; +import java.security.SecureRandom; + +/** + * An implementation of the Diffie-Hellman parameter generation as defined in + * RFC-2631. + * <p> + * Reference: + * <ol> + * <li><a href="http://www.ietf.org/rfc/rfc2631.txt">Diffie-Hellman Key + * Agreement Method</a><br> + * Eric Rescorla.</li> + * </ol> + */ +public class RFC2631 +{ + public static final int DH_PARAMS_SEED = 0; + public static final int DH_PARAMS_COUNTER = 1; + public static final int DH_PARAMS_Q = 2; + public static final int DH_PARAMS_P = 3; + public static final int DH_PARAMS_J = 4; + public static final int DH_PARAMS_G = 5; + private static final BigInteger TWO = BigInteger.valueOf(2L); + /** The SHA instance to use. */ + private Sha160 sha = new Sha160(); + /** Length of private modulus and of q. */ + private int m; + /** Length of public modulus p. */ + private int L; + /** The optional {@link SecureRandom} instance to use. */ + private SecureRandom rnd = null; + /** Our default source of randomness. */ + private PRNG prng = null; + + public RFC2631(int m, int L, SecureRandom rnd) + { + super(); + + this.m = m; + this.L = L; + this.rnd = rnd; + } + + public BigInteger[] generateParameters() + { + int i, j, counter; + byte[] u1, u2, v; + byte[] seedBytes = new byte[m / 8]; + BigInteger SEED, U, q, R, V, W, X, p, g; + // start by genrating p and q, where q is of length m and p is of length L + // 1. Set m' = m/160 where / represents integer division with rounding + // upwards. I.e. 200/160 = 2. + int m_ = (m + 159) / 160; + // 2. Set L'= L/160 + int L_ = (L + 159) / 160; + // 3. Set N'= L/1024 + int N_ = (L + 1023) / 1024; + algorithm: while (true) + { + step4: while (true) + { + // 4. Select an arbitrary bit string SEED such that length of + // SEED >= m + nextRandomBytes(seedBytes); + SEED = new BigInteger(1, seedBytes).setBit(m - 1).setBit(0); + // 5. Set U = 0 + U = BigInteger.ZERO; + // 6. For i = 0 to m' - 1 + // U = U + (SHA1[SEED + i] XOR SHA1[(SEED + m' + i)) * 2^(160 * i) + // Note that for m=160, this reduces to the algorithm of FIPS-186 + // U = SHA1[SEED] XOR SHA1[(SEED+1) mod 2^160 ]. + for (i = 0; i < m_; i++) + { + u1 = SEED.add(BigInteger.valueOf(i)).toByteArray(); + u2 = SEED.add(BigInteger.valueOf(m_ + i)).toByteArray(); + sha.update(u1, 0, u1.length); + u1 = sha.digest(); + sha.update(u2, 0, u2.length); + u2 = sha.digest(); + for (j = 0; j < u1.length; j++) + u1[j] ^= u2[j]; + U = U.add(new BigInteger(1, u1).multiply(TWO.pow(160 * i))); + } + // 5. Form q from U by computing U mod (2^m) and setting the most + // significant bit (the 2^(m-1) bit) and the least significant + // bit to 1. In terms of boolean operations, q = U OR 2^(m-1) OR + // 1. Note that 2^(m-1) < q < 2^m + q = U.setBit(m - 1).setBit(0); + // 6. Use a robust primality algorithm to test whether q is prime. + // 7. If q is not prime then go to 4. + if (q.isProbablePrime(80)) + break step4; + } + // 8. Let counter = 0 + counter = 0; + while (true) + { + // 9. Set R = seed + 2*m' + (L' * counter) + R = SEED + .add(BigInteger.valueOf(2 * m_)) + .add(BigInteger.valueOf(L_ * counter)); + // 10. Set V = 0 + V = BigInteger.ZERO; + // 12. For i = 0 to L'-1 do: V = V + SHA1(R + i) * 2^(160 * i) + for (i = 0; i < L_; i++) + { + v = R.toByteArray(); + sha.update(v, 0, v.length); + v = sha.digest(); + V = V.add(new BigInteger(1, v).multiply(TWO.pow(160 * i))); + } + // 13. Set W = V mod 2^L + W = V.mod(TWO.pow(L)); + // 14. Set X = W OR 2^(L-1) + // Note that 0 <= W < 2^(L-1) and hence X >= 2^(L-1) + X = W.setBit(L - 1); + // 15. Set p = X - (X mod (2*q)) + 1 + p = X.add(BigInteger.ONE).subtract(X.mod(TWO.multiply(q))); + // 16. If p > 2^(L-1) use a robust primality test to test whether p + // is prime. Else go to 18. + // 17. If p is prime output p, q, seed, counter and stop. + if (p.isProbablePrime(80)) + { + break algorithm; + } + // 18. Set counter = counter + 1 + counter++; + // 19. If counter < (4096 * N) then go to 8. + // 20. Output "failure" + if (counter >= 4096 * N_) + continue algorithm; + } + } + // compute g. from FIPS-186, Appendix 4: + // 1. Generate p and q as specified in Appendix 2. + // 2. Let e = (p - 1) / q + BigInteger e = p.subtract(BigInteger.ONE).divide(q); + BigInteger h = TWO; + BigInteger p_minus_1 = p.subtract(BigInteger.ONE); + g = TWO; + // 3. Set h = any integer, where 1 < h < p - 1 and h differs from any + // value previously tried + for (; h.compareTo(p_minus_1) < 0; h = h.add(BigInteger.ONE)) + { + // 4. Set g = h**e mod p + g = h.modPow(e, p); + // 5. If g = 1, go to step 3 + if (! g.equals(BigInteger.ONE)) + break; + } + return new BigInteger[] { SEED, BigInteger.valueOf(counter), q, p, e, g }; + } + + /** + * Fills the designated byte array with random data. + * + * @param buffer the byte array to fill with random data. + */ + private void nextRandomBytes(byte[] buffer) + { + if (rnd != null) + rnd.nextBytes(buffer); + else + getDefaultPRNG().nextBytes(buffer); + } + + private PRNG getDefaultPRNG() + { + if (prng == null) + prng = PRNG.getInstance(); + + return prng; + } +} |