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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 1.4.
package org.bouncycastle.crypto.digests;
/*
The BLAKE2 cryptographic hash function was designed by Jean-
Philippe Aumasson, Samuel Neves, Zooko Wilcox-O'Hearn, and Christian
Winnerlein.
Reference Implementation and Description can be found at: https://blake2.net/blake2x.pdf
*/
import org.bouncycastle.crypto.Xof;
import org.bouncycastle.util.Arrays;
/**
* Implementation of the eXtendable Output Function (XOF) BLAKE2xs.
*
* BLAKE2xs offers a built-in keying mechanism to be used directly
* for authentication ("Prefix-MAC") rather than a HMAC construction.
*
* BLAKE2xs offers a built-in support for a salt for randomized hashing
* and a personal string for defining a unique hash function for each application.
*
* BLAKE2xs is optimized for 32-bit platforms and produces digests of any size
* between 1 and 2^16-2 bytes. The length can also be unknown and then the maximum
* length will be 2^32 blocks of 32 bytes.
*/
public class Blake2xsDigest
implements Xof
{
/**
* Magic number to indicate an unknown length of digest
*/
public static final int UNKNOWN_DIGEST_LENGTH = 65535;
private static final int DIGEST_LENGTH = 32;
private static final long MAX_NUMBER_BLOCKS = 1L << 32;
/**
* Expected digest length for the xof. It can be unknown.
*/
private int digestLength;
/**
* Root hash that will take the updates
*/
private Blake2sDigest hash;
/**
* Digest of the root hash
*/
private byte[] h0 = null;
/**
* Digest of each round of the XOF
*/
private byte[] buf = new byte[32];
/**
* Current position for a round
*/
private int bufPos = 32;
/**
* Overall position of the digest. It is useful when the length is known
* in advance to get last block length.
*/
private int digestPos = 0;
/**
* Keep track of the round number to detect the end of the digest after
* 2^32 blocks of 32 bytes.
*/
private long blockPos = 0;
/**
* Current node offset incremented by 1 every round.
*/
private long nodeOffset;
/**
* BLAKE2xs for hashing with unknown digest length
*/
public Blake2xsDigest()
{
this(Blake2xsDigest.UNKNOWN_DIGEST_LENGTH);
}
/**
* BLAKE2xs for hashing
*
* @param digestBytes The desired digest length in bytes. Must be above 1 and less than 2^16-1
*/
public Blake2xsDigest(int digestBytes)
{
this(digestBytes, null, null, null);
}
/**
* BLAKE2xs with key
*
* @param digestBytes The desired digest length in bytes. Must be above 1 and less than 2^16-1
* @param key A key up to 32 bytes or null
*/
public Blake2xsDigest(int digestBytes, byte[] key)
{
this(digestBytes, key, null, null);
}
/**
* BLAKE2xs with key, salt and personalization
*
* @param digestBytes The desired digest length in bytes. Must be above 1 and less than 2^16-1
* @param key A key up to 32 bytes or null
* @param salt 8 bytes or null
* @param personalization 8 bytes or null
*/
public Blake2xsDigest(int digestBytes, byte[] key, byte[] salt, byte[] personalization)
{
if (digestBytes < 1 || digestBytes > Blake2xsDigest.UNKNOWN_DIGEST_LENGTH)
{
throw new IllegalArgumentException(
"BLAKE2xs digest length must be between 1 and 2^16-1");
}
digestLength = digestBytes;
nodeOffset = computeNodeOffset();
hash = new Blake2sDigest(Blake2xsDigest.DIGEST_LENGTH, key, salt, personalization, nodeOffset);
}
public Blake2xsDigest(Blake2xsDigest digest)
{
digestLength = digest.digestLength;
hash = new Blake2sDigest(digest.hash);
h0 = Arrays.clone(digest.h0);
buf = Arrays.clone(digest.buf);
bufPos = digest.bufPos;
digestPos = digest.digestPos;
blockPos = digest.blockPos;
nodeOffset = digest.nodeOffset;
}
/**
* Return the algorithm name.
*
* @return the algorithm name
*/
public String getAlgorithmName()
{
return "BLAKE2xs";
}
/**
* Return the size in bytes of the digest produced by this message digest.
*
* @return the size in bytes of the digest produced by this message digest.
*/
public int getDigestSize()
{
return digestLength;
}
/**
* Return the size in bytes of the internal buffer the digest applies its
* compression function to.
*
* @return byte length of the digest's internal buffer.
*/
public int getByteLength()
{
return hash.getByteLength();
}
/**
* Return the maximum size in bytes the digest can produce when the length
* is unknown
*
* @return byte length of the largest digest with unknown length
*/
public long getUnknownMaxLength()
{
return Blake2xsDigest.MAX_NUMBER_BLOCKS * Blake2xsDigest.DIGEST_LENGTH;
}
/**
* Update the message digest with a single byte.
*
* @param in the input byte to be entered.
*/
public void update(byte in)
{
hash.update(in);
}
/**
* Update the message digest with a block of bytes.
*
* @param in the byte array containing the data.
* @param inOff the offset into the byte array where the data starts.
* @param len the length of the data.
*/
public void update(byte[] in, int inOff, int len)
{
hash.update(in, inOff, len);
}
/**
* Reset the digest back to its initial state. The key, the salt and the
* personal string will remain for further computations.
*/
public void reset()
{
hash.reset();
h0 = null;
bufPos = Blake2xsDigest.DIGEST_LENGTH;
digestPos = 0;
blockPos = 0;
nodeOffset = computeNodeOffset();
}
/**
* Close the digest, producing the final digest value. The doFinal() call
* leaves the digest reset. Key, salt and personal string remain.
*
* @param out the array the digest is to be copied into.
* @param outOffset the offset into the out array the digest is to start at.
*/
public int doFinal(byte[] out, int outOffset)
{
return doFinal(out, outOffset, out.length);
}
/**
* Close the digest, producing the final digest value. The doFinal() call
* leaves the digest reset. Key, salt, personal string remain.
*
* @param out output array to write the output bytes to.
* @param outOff offset to start writing the bytes at.
* @param outLen the number of output bytes requested.
*/
public int doFinal(byte[] out, int outOff, int outLen)
{
int ret = doOutput(out, outOff, outLen);
reset();
return ret;
}
/**
* Start outputting the results of the final calculation for this digest. Unlike doFinal, this method
* will continue producing output until the Xof is explicitly reset, or signals otherwise.
*
* @param out output array to write the output bytes to.
* @param outOff offset to start writing the bytes at.
* @param outLen the number of output bytes requested.
* @return the number of bytes written
*/
public int doOutput(byte[] out, int outOff, int outLen)
{
if (h0 == null)
{
h0 = new byte[hash.getDigestSize()];
hash.doFinal(h0, 0);
}
if (digestLength != Blake2xsDigest.UNKNOWN_DIGEST_LENGTH)
{
if (digestPos + outLen > digestLength)
{
throw new IllegalArgumentException(
"Output length is above the digest length");
}
}
else if (blockPos << 5 >= getUnknownMaxLength())
{
throw new IllegalArgumentException(
"Maximum length is 2^32 blocks of 32 bytes");
}
for (int i = 0; i < outLen; i++)
{
if (bufPos >= Blake2xsDigest.DIGEST_LENGTH)
{
Blake2sDigest h = new Blake2sDigest(computeStepLength(), Blake2xsDigest.DIGEST_LENGTH, nodeOffset);
h.update(h0, 0, h0.length);
Arrays.fill(buf, (byte)0);
h.doFinal(buf, 0);
bufPos = 0;
nodeOffset++;
blockPos++;
}
out[i] = buf[bufPos];
bufPos++;
digestPos++;
}
return outLen;
}
// get the next round length. If the length is unknown, the digest length is
// always the maximum.
private int computeStepLength()
{
if (digestLength == Blake2xsDigest.UNKNOWN_DIGEST_LENGTH)
{
return Blake2xsDigest.DIGEST_LENGTH;
}
return Math.min(Blake2xsDigest.DIGEST_LENGTH, digestLength - digestPos);
}
private long computeNodeOffset()
{
return digestLength * 0x100000000L;
}
}
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