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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 1.5 to JDK 1.7. Note: this package includes the IDEA and NTRU encryption algorithms.

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package org.bouncycastle.crypto.signers;

import java.security.SecureRandom;

import org.bouncycastle.crypto.AsymmetricBlockCipher;
import org.bouncycastle.crypto.CipherParameters;
import org.bouncycastle.crypto.CryptoException;
import org.bouncycastle.crypto.DataLengthException;
import org.bouncycastle.crypto.Digest;
import org.bouncycastle.crypto.Signer;
import org.bouncycastle.crypto.params.ParametersWithRandom;
import org.bouncycastle.crypto.params.RSABlindingParameters;
import org.bouncycastle.crypto.params.RSAKeyParameters;

/**
 * RSA-PSS as described in PKCS# 1 v 2.1.
 * 

* Note: the usual value for the salt length is the number of * bytes in the hash function. */ public class PSSSigner implements Signer { static final public byte TRAILER_IMPLICIT = (byte)0xBC; private Digest contentDigest; private Digest mgfDigest; private AsymmetricBlockCipher cipher; private SecureRandom random; private int hLen; private int mgfhLen; private boolean sSet; private int sLen; private int emBits; private byte[] salt; private byte[] mDash; private byte[] block; private byte trailer; /** * basic constructor * * @param cipher the asymmetric cipher to use. * @param digest the digest to use. * @param sLen the length of the salt to use (in bytes). */ public PSSSigner( AsymmetricBlockCipher cipher, Digest digest, int sLen) { this(cipher, digest, sLen, TRAILER_IMPLICIT); } public PSSSigner( AsymmetricBlockCipher cipher, Digest contentDigest, Digest mgfDigest, int sLen) { this(cipher, contentDigest, mgfDigest, sLen, TRAILER_IMPLICIT); } public PSSSigner( AsymmetricBlockCipher cipher, Digest digest, int sLen, byte trailer) { this(cipher, digest, digest, sLen, trailer); } public PSSSigner( AsymmetricBlockCipher cipher, Digest contentDigest, Digest mgfDigest, int sLen, byte trailer) { this.cipher = cipher; this.contentDigest = contentDigest; this.mgfDigest = mgfDigest; this.hLen = contentDigest.getDigestSize(); this.mgfhLen = mgfDigest.getDigestSize(); this.sSet = false; this.sLen = sLen; this.salt = new byte[sLen]; this.mDash = new byte[8 + sLen + hLen]; this.trailer = trailer; } public PSSSigner( AsymmetricBlockCipher cipher, Digest digest, byte[] salt) { this(cipher, digest, digest, salt, TRAILER_IMPLICIT); } public PSSSigner( AsymmetricBlockCipher cipher, Digest contentDigest, Digest mgfDigest, byte[] salt) { this(cipher, contentDigest, mgfDigest, salt, TRAILER_IMPLICIT); } public PSSSigner( AsymmetricBlockCipher cipher, Digest contentDigest, Digest mgfDigest, byte[] salt, byte trailer) { this.cipher = cipher; this.contentDigest = contentDigest; this.mgfDigest = mgfDigest; this.hLen = contentDigest.getDigestSize(); this.mgfhLen = mgfDigest.getDigestSize(); this.sSet = true; this.sLen = salt.length; this.salt = salt; this.mDash = new byte[8 + sLen + hLen]; this.trailer = trailer; } public void init( boolean forSigning, CipherParameters param) { CipherParameters params; if (param instanceof ParametersWithRandom) { ParametersWithRandom p = (ParametersWithRandom)param; params = p.getParameters(); random = p.getRandom(); } else { params = param; if (forSigning) { random = new SecureRandom(); } } RSAKeyParameters kParam; if (params instanceof RSABlindingParameters) { kParam = ((RSABlindingParameters)params).getPublicKey(); cipher.init(forSigning, param); // pass on random } else { kParam = (RSAKeyParameters)params; cipher.init(forSigning, params); } emBits = kParam.getModulus().bitLength() - 1; if (emBits < (8 * hLen + 8 * sLen + 9)) { throw new IllegalArgumentException("key too small for specified hash and salt lengths"); } block = new byte[(emBits + 7) / 8]; reset(); } /** * clear possible sensitive data */ private void clearBlock( byte[] block) { for (int i = 0; i != block.length; i++) { block[i] = 0; } } /** * update the internal digest with the byte b */ public void update( byte b) { contentDigest.update(b); } /** * update the internal digest with the byte array in */ public void update( byte[] in, int off, int len) { contentDigest.update(in, off, len); } /** * reset the internal state */ public void reset() { contentDigest.reset(); } /** * generate a signature for the message we've been loaded with using * the key we were initialised with. */ public byte[] generateSignature() throws CryptoException, DataLengthException { contentDigest.doFinal(mDash, mDash.length - hLen - sLen); if (sLen != 0) { if (!sSet) { random.nextBytes(salt); } System.arraycopy(salt, 0, mDash, mDash.length - sLen, sLen); } byte[] h = new byte[hLen]; contentDigest.update(mDash, 0, mDash.length); contentDigest.doFinal(h, 0); block[block.length - sLen - 1 - hLen - 1] = 0x01; System.arraycopy(salt, 0, block, block.length - sLen - hLen - 1, sLen); byte[] dbMask = maskGeneratorFunction1(h, 0, h.length, block.length - hLen - 1); for (int i = 0; i != dbMask.length; i++) { block[i] ^= dbMask[i]; } block[0] &= (0xff >> ((block.length * 8) - emBits)); System.arraycopy(h, 0, block, block.length - hLen - 1, hLen); block[block.length - 1] = trailer; byte[] b = cipher.processBlock(block, 0, block.length); clearBlock(block); return b; } /** * return true if the internal state represents the signature described * in the passed in array. */ public boolean verifySignature( byte[] signature) { contentDigest.doFinal(mDash, mDash.length - hLen - sLen); try { byte[] b = cipher.processBlock(signature, 0, signature.length); System.arraycopy(b, 0, block, block.length - b.length, b.length); } catch (Exception e) { return false; } if (block[block.length - 1] != trailer) { clearBlock(block); return false; } byte[] dbMask = maskGeneratorFunction1(block, block.length - hLen - 1, hLen, block.length - hLen - 1); for (int i = 0; i != dbMask.length; i++) { block[i] ^= dbMask[i]; } block[0] &= (0xff >> ((block.length * 8) - emBits)); for (int i = 0; i != block.length - hLen - sLen - 2; i++) { if (block[i] != 0) { clearBlock(block); return false; } } if (block[block.length - hLen - sLen - 2] != 0x01) { clearBlock(block); return false; } if (sSet) { System.arraycopy(salt, 0, mDash, mDash.length - sLen, sLen); } else { System.arraycopy(block, block.length - sLen - hLen - 1, mDash, mDash.length - sLen, sLen); } contentDigest.update(mDash, 0, mDash.length); contentDigest.doFinal(mDash, mDash.length - hLen); for (int i = block.length - hLen - 1, j = mDash.length - hLen; j != mDash.length; i++, j++) { if ((block[i] ^ mDash[j]) != 0) { clearBlock(mDash); clearBlock(block); return false; } } clearBlock(mDash); clearBlock(block); return true; } /** * int to octet string. */ private void ItoOSP( int i, byte[] sp) { sp[0] = (byte)(i >>> 24); sp[1] = (byte)(i >>> 16); sp[2] = (byte)(i >>> 8); sp[3] = (byte)(i >>> 0); } /** * mask generator function, as described in PKCS1v2. */ private byte[] maskGeneratorFunction1( byte[] Z, int zOff, int zLen, int length) { byte[] mask = new byte[length]; byte[] hashBuf = new byte[mgfhLen]; byte[] C = new byte[4]; int counter = 0; mgfDigest.reset(); while (counter < (length / mgfhLen)) { ItoOSP(counter, C); mgfDigest.update(Z, zOff, zLen); mgfDigest.update(C, 0, C.length); mgfDigest.doFinal(hashBuf, 0); System.arraycopy(hashBuf, 0, mask, counter * mgfhLen, mgfhLen); counter++; } if ((counter * mgfhLen) < length) { ItoOSP(counter, C); mgfDigest.update(Z, zOff, zLen); mgfDigest.update(C, 0, C.length); mgfDigest.doFinal(hashBuf, 0); System.arraycopy(hashBuf, 0, mask, counter * mgfhLen, mask.length - (counter * mgfhLen)); } return mask; } }





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