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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 and up.

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package org.bouncycastle.crypto.digests;

import org.bouncycastle.crypto.ExtendedDigest;
import org.bouncycastle.util.Arrays;
import org.bouncycastle.util.Pack;

/**
 * implementation of Keccak based on following KeccakNISTInterface.c from https://keccak.noekeon.org/
 * 

* Following the naming conventions used in the C source code to enable easy review of the implementation. */ public class KeccakDigest implements ExtendedDigest { private static long[] KeccakRoundConstants = new long[]{ 0x0000000000000001L, 0x0000000000008082L, 0x800000000000808aL, 0x8000000080008000L, 0x000000000000808bL, 0x0000000080000001L, 0x8000000080008081L, 0x8000000000008009L, 0x000000000000008aL, 0x0000000000000088L, 0x0000000080008009L, 0x000000008000000aL, 0x000000008000808bL, 0x800000000000008bL, 0x8000000000008089L, 0x8000000000008003L, 0x8000000000008002L, 0x8000000000000080L, 0x000000000000800aL, 0x800000008000000aL, 0x8000000080008081L, 0x8000000000008080L, 0x0000000080000001L, 0x8000000080008008L }; protected long[] state = new long[25]; protected byte[] dataQueue = new byte[192]; protected int rate; protected int bitsInQueue; protected int fixedOutputLength; protected boolean squeezing; public KeccakDigest() { this(288); } public KeccakDigest(int bitLength) { init(bitLength); } public KeccakDigest(KeccakDigest source) { System.arraycopy(source.state, 0, this.state, 0, source.state.length); System.arraycopy(source.dataQueue, 0, this.dataQueue, 0, source.dataQueue.length); this.rate = source.rate; this.bitsInQueue = source.bitsInQueue; this.fixedOutputLength = source.fixedOutputLength; this.squeezing = source.squeezing; } public String getAlgorithmName() { return "Keccak-" + fixedOutputLength; } public int getDigestSize() { return fixedOutputLength / 8; } public void update(byte in) { absorb(in); } public void update(byte[] in, int inOff, int len) { absorb(in, inOff, len); } public int doFinal(byte[] out, int outOff) { squeeze(out, outOff, fixedOutputLength); reset(); return getDigestSize(); } /* * TODO Possible API change to support partial-byte suffixes. */ protected int doFinal(byte[] out, int outOff, byte partialByte, int partialBits) { if (partialBits > 0) { absorbBits(partialByte, partialBits); } squeeze(out, outOff, fixedOutputLength); reset(); return getDigestSize(); } public void reset() { init(fixedOutputLength); } /** * Return the size of block that the compression function is applied to in bytes. * * @return internal byte length of a block. */ public int getByteLength() { return rate / 8; } private void init(int bitLength) { switch (bitLength) { case 128: case 224: case 256: case 288: case 384: case 512: initSponge(1600 - (bitLength << 1)); break; default: throw new IllegalArgumentException("bitLength must be one of 128, 224, 256, 288, 384, or 512."); } } private void initSponge(int rate) { if ((rate <= 0) || (rate >= 1600) || ((rate % 64) != 0)) { throw new IllegalStateException("invalid rate value"); } this.rate = rate; for (int i = 0; i < state.length; ++i) { state[i] = 0L; } Arrays.fill(this.dataQueue, (byte)0); this.bitsInQueue = 0; this.squeezing = false; this.fixedOutputLength = (1600 - rate) / 2; } protected void absorb(byte data) { if ((bitsInQueue % 8) != 0) { throw new IllegalStateException("attempt to absorb with odd length queue"); } if (squeezing) { throw new IllegalStateException("attempt to absorb while squeezing"); } dataQueue[bitsInQueue >>> 3] = data; if ((bitsInQueue += 8) == rate) { KeccakAbsorb(dataQueue, 0); bitsInQueue = 0; } } protected void absorb(byte[] data, int off, int len) { if ((bitsInQueue % 8) != 0) { throw new IllegalStateException("attempt to absorb with odd length queue"); } if (squeezing) { throw new IllegalStateException("attempt to absorb while squeezing"); } int bytesInQueue = bitsInQueue >>> 3; int rateBytes = rate >>> 3; int available = rateBytes - bytesInQueue; if (len < available) { System.arraycopy(data, off, dataQueue, bytesInQueue, len); this.bitsInQueue += len << 3; return; } int count = 0; if (bytesInQueue > 0) { System.arraycopy(data, off, dataQueue, bytesInQueue, available); count += available; KeccakAbsorb(dataQueue, 0); } int remaining; while ((remaining = (len - count)) >= rateBytes) { KeccakAbsorb(data, off + count); count += rateBytes; } System.arraycopy(data, off + count, dataQueue, 0, remaining); this.bitsInQueue = remaining << 3; } protected void absorbBits(int data, int bits) { if (bits < 1 || bits > 7) { throw new IllegalArgumentException("'bits' must be in the range 1 to 7"); } if ((bitsInQueue % 8) != 0) { throw new IllegalStateException("attempt to absorb with odd length queue"); } if (squeezing) { throw new IllegalStateException("attempt to absorb while squeezing"); } int mask = (1 << bits) - 1; dataQueue[bitsInQueue >>> 3] = (byte)(data & mask); // NOTE: After this, bitsInQueue is no longer a multiple of 8, so no more absorbs will work bitsInQueue += bits; } private void padAndSwitchToSqueezingPhase() { dataQueue[bitsInQueue >>> 3] |= (byte)(1 << (bitsInQueue & 7)); if (++bitsInQueue == rate) { KeccakAbsorb(dataQueue, 0); } else { int full = bitsInQueue >>> 6, partial = bitsInQueue & 63; int off = 0; for (int i = 0; i < full; ++i) { state[i] ^= Pack.littleEndianToLong(dataQueue, off); off += 8; } if (partial > 0) { long mask = (1L << partial) - 1L; state[full] ^= Pack.littleEndianToLong(dataQueue, off) & mask; } } state[(rate - 1) >>> 6] ^= (1L << 63); bitsInQueue = 0; squeezing = true; } protected void squeeze(byte[] output, int offset, long outputLength) { if (!squeezing) { padAndSwitchToSqueezingPhase(); } if ((outputLength % 8) != 0) { throw new IllegalStateException("outputLength not a multiple of 8"); } long i = 0; while (i < outputLength) { if (bitsInQueue == 0) { KeccakExtract(); } int partialBlock = (int)Math.min((long)bitsInQueue, outputLength - i); System.arraycopy(dataQueue, (rate - bitsInQueue) / 8, output, offset + (int)(i / 8), partialBlock / 8); bitsInQueue -= partialBlock; i += partialBlock; } } private void KeccakAbsorb(byte[] data, int off) { // assert 0 == bitsInQueue || (dataQueue == data && 0 == off); int count = rate >>> 6; for (int i = 0; i < count; ++i) { state[i] ^= Pack.littleEndianToLong(data, off); off += 8; } KeccakPermutation(); } private void KeccakExtract() { // assert 0 == bitsInQueue; KeccakPermutation(); Pack.longToLittleEndian(state, 0, rate >>> 6, dataQueue, 0); this.bitsInQueue = rate; } private void KeccakPermutation() { long[] A = state; long a00 = A[ 0], a01 = A[ 1], a02 = A[ 2], a03 = A[ 3], a04 = A[ 4]; long a05 = A[ 5], a06 = A[ 6], a07 = A[ 7], a08 = A[ 8], a09 = A[ 9]; long a10 = A[10], a11 = A[11], a12 = A[12], a13 = A[13], a14 = A[14]; long a15 = A[15], a16 = A[16], a17 = A[17], a18 = A[18], a19 = A[19]; long a20 = A[20], a21 = A[21], a22 = A[22], a23 = A[23], a24 = A[24]; for (int i = 0; i < 24; i++) { // theta long c0 = a00 ^ a05 ^ a10 ^ a15 ^ a20; long c1 = a01 ^ a06 ^ a11 ^ a16 ^ a21; long c2 = a02 ^ a07 ^ a12 ^ a17 ^ a22; long c3 = a03 ^ a08 ^ a13 ^ a18 ^ a23; long c4 = a04 ^ a09 ^ a14 ^ a19 ^ a24; long d1 = (c1 << 1 | c1 >>> -1) ^ c4; long d2 = (c2 << 1 | c2 >>> -1) ^ c0; long d3 = (c3 << 1 | c3 >>> -1) ^ c1; long d4 = (c4 << 1 | c4 >>> -1) ^ c2; long d0 = (c0 << 1 | c0 >>> -1) ^ c3; a00 ^= d1; a05 ^= d1; a10 ^= d1; a15 ^= d1; a20 ^= d1; a01 ^= d2; a06 ^= d2; a11 ^= d2; a16 ^= d2; a21 ^= d2; a02 ^= d3; a07 ^= d3; a12 ^= d3; a17 ^= d3; a22 ^= d3; a03 ^= d4; a08 ^= d4; a13 ^= d4; a18 ^= d4; a23 ^= d4; a04 ^= d0; a09 ^= d0; a14 ^= d0; a19 ^= d0; a24 ^= d0; // rho/pi c1 = a01 << 1 | a01 >>> 63; a01 = a06 << 44 | a06 >>> 20; a06 = a09 << 20 | a09 >>> 44; a09 = a22 << 61 | a22 >>> 3; a22 = a14 << 39 | a14 >>> 25; a14 = a20 << 18 | a20 >>> 46; a20 = a02 << 62 | a02 >>> 2; a02 = a12 << 43 | a12 >>> 21; a12 = a13 << 25 | a13 >>> 39; a13 = a19 << 8 | a19 >>> 56; a19 = a23 << 56 | a23 >>> 8; a23 = a15 << 41 | a15 >>> 23; a15 = a04 << 27 | a04 >>> 37; a04 = a24 << 14 | a24 >>> 50; a24 = a21 << 2 | a21 >>> 62; a21 = a08 << 55 | a08 >>> 9; a08 = a16 << 45 | a16 >>> 19; a16 = a05 << 36 | a05 >>> 28; a05 = a03 << 28 | a03 >>> 36; a03 = a18 << 21 | a18 >>> 43; a18 = a17 << 15 | a17 >>> 49; a17 = a11 << 10 | a11 >>> 54; a11 = a07 << 6 | a07 >>> 58; a07 = a10 << 3 | a10 >>> 61; a10 = c1; // chi c0 = a00 ^ (~a01 & a02); c1 = a01 ^ (~a02 & a03); a02 ^= ~a03 & a04; a03 ^= ~a04 & a00; a04 ^= ~a00 & a01; a00 = c0; a01 = c1; c0 = a05 ^ (~a06 & a07); c1 = a06 ^ (~a07 & a08); a07 ^= ~a08 & a09; a08 ^= ~a09 & a05; a09 ^= ~a05 & a06; a05 = c0; a06 = c1; c0 = a10 ^ (~a11 & a12); c1 = a11 ^ (~a12 & a13); a12 ^= ~a13 & a14; a13 ^= ~a14 & a10; a14 ^= ~a10 & a11; a10 = c0; a11 = c1; c0 = a15 ^ (~a16 & a17); c1 = a16 ^ (~a17 & a18); a17 ^= ~a18 & a19; a18 ^= ~a19 & a15; a19 ^= ~a15 & a16; a15 = c0; a16 = c1; c0 = a20 ^ (~a21 & a22); c1 = a21 ^ (~a22 & a23); a22 ^= ~a23 & a24; a23 ^= ~a24 & a20; a24 ^= ~a20 & a21; a20 = c0; a21 = c1; // iota a00 ^= KeccakRoundConstants[i]; } A[ 0] = a00; A[ 1] = a01; A[ 2] = a02; A[ 3] = a03; A[ 4] = a04; A[ 5] = a05; A[ 6] = a06; A[ 7] = a07; A[ 8] = a08; A[ 9] = a09; A[10] = a10; A[11] = a11; A[12] = a12; A[13] = a13; A[14] = a14; A[15] = a15; A[16] = a16; A[17] = a17; A[18] = a18; A[19] = a19; A[20] = a20; A[21] = a21; A[22] = a22; A[23] = a23; A[24] = a24; } }





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