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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 1.8. Note: this package includes the NTRU encryption algorithms.

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package org.bouncycastle.crypto.modes;

import java.io.ByteArrayOutputStream;

import org.bouncycastle.crypto.BlockCipher;
import org.bouncycastle.crypto.CipherParameters;
import org.bouncycastle.crypto.DataLengthException;
import org.bouncycastle.crypto.InvalidCipherTextException;
import org.bouncycastle.crypto.OutputLengthException;
import org.bouncycastle.crypto.engines.AESEngine;
import org.bouncycastle.crypto.modes.gcm.GCMMultiplier;
import org.bouncycastle.crypto.modes.gcm.Tables4kGCMMultiplier;
import org.bouncycastle.crypto.params.AEADParameters;
import org.bouncycastle.crypto.params.KeyParameter;
import org.bouncycastle.crypto.params.ParametersWithIV;
import org.bouncycastle.util.Arrays;
import org.bouncycastle.util.Bytes;
import org.bouncycastle.util.Integers;
import org.bouncycastle.util.Longs;
import org.bouncycastle.util.Pack;

/**
 * GCM-SIV Mode.
 * 

It should be noted that the specified limit of 236 bytes is not supported. This is because all bytes are * cached in a ByteArrayOutputStream object (which has a limit of a little less than 231 bytes), * and are output on the doFinal() call (which can only process a maximum of 231 bytes).

*

The practical limit of 231 - 24 bytes is policed, and attempts to breach the limit will be rejected

*

In order to properly support the higher limit, an extended form of ByteArrayOutputStream would be needed * which would use multiple arrays to store the data. In addition, a new doOutput method would be required (similar * to that in XOF digests), which would allow the data to be output over multiple calls. Alternatively an extended * form of ByteArrayInputStream could be used to deliver the data.

*/ public class GCMSIVBlockCipher implements AEADBlockCipher { /** * The buffer length. */ private static final int BUFLEN = 16; /** * The halfBuffer length. */ private static final int HALFBUFLEN = BUFLEN >> 1; /** * The nonce length. */ private static final int NONCELEN = 12; /** * The maximum data length (AEAD/PlainText). Due to implementation constraints this is restricted to the maximum * array length (https://programming.guide/java/array-maximum-length.html) minus the BUFLEN to allow for the MAC */ private static final int MAX_DATALEN = Integer.MAX_VALUE - 8 - BUFLEN; /** * The top bit mask. */ private static final byte MASK = (byte) 0x80; /** * The addition constant. */ private static final byte ADD = (byte) 0xE1; /** * The initialisation flag. */ private static final int INIT = 1; /** * The aeadComplete flag. */ private static final int AEAD_COMPLETE = 2; /** * The cipher. */ private final BlockCipher theCipher; /** * The multiplier. */ private final GCMMultiplier theMultiplier; /** * The gHash buffer. */ private final byte[] theGHash = new byte[BUFLEN]; /** * The reverse buffer. */ private final byte[] theReverse = new byte[BUFLEN]; /** * The aeadHasher. */ private final GCMSIVHasher theAEADHasher; /** * The dataHasher. */ private final GCMSIVHasher theDataHasher; /** * The plainDataStream. */ private GCMSIVCache thePlain; /** * The encryptedDataStream (decryption only). */ private GCMSIVCache theEncData; /** * Are we encrypting? */ private boolean forEncryption; /** * The initialAEAD. */ private byte[] theInitialAEAD; /** * The nonce. */ private byte[] theNonce; /** * The flags. */ private int theFlags; // defined fixed private byte[] macBlock = new byte[16]; /** * Constructor. */ public GCMSIVBlockCipher() { this(new AESEngine()); } /** * Constructor. * @param pCipher the underlying cipher */ public GCMSIVBlockCipher(final BlockCipher pCipher) { this(pCipher, new Tables4kGCMMultiplier()); } /** * Constructor. * @param pCipher the underlying cipher * @param pMultiplier the multiplier */ public GCMSIVBlockCipher(final BlockCipher pCipher, final GCMMultiplier pMultiplier) { /* Ensure that the cipher is the correct size */ if (pCipher.getBlockSize() != BUFLEN) { throw new IllegalArgumentException("Cipher required with a block size of " + BUFLEN + "."); } /* Store parameters */ theCipher = pCipher; theMultiplier = pMultiplier; /* Create the hashers */ theAEADHasher = new GCMSIVHasher(); theDataHasher = new GCMSIVHasher(); } public BlockCipher getUnderlyingCipher() { return theCipher; } public void init(final boolean pEncrypt, final CipherParameters cipherParameters) throws IllegalArgumentException { /* Set defaults */ byte[] myInitialAEAD = null; byte[] myNonce = null; KeyParameter myKey = null; /* Access parameters */ if (cipherParameters instanceof AEADParameters) { final AEADParameters myAEAD = (AEADParameters) cipherParameters; myInitialAEAD = myAEAD.getAssociatedText(); myNonce = myAEAD.getNonce(); myKey = myAEAD.getKey(); } else if (cipherParameters instanceof ParametersWithIV) { final ParametersWithIV myParms = (ParametersWithIV) cipherParameters; myNonce = myParms.getIV(); myKey = (KeyParameter) myParms.getParameters(); } else { throw new IllegalArgumentException("invalid parameters passed to GCM-SIV"); } /* Check nonceSize */ if (myNonce == null || myNonce.length != NONCELEN) { throw new IllegalArgumentException("Invalid nonce"); } /* Check keysize */ if (myKey == null || (myKey.getKey().length != BUFLEN && myKey.getKey().length != (BUFLEN << 1))) { throw new IllegalArgumentException("Invalid key"); } /* Reset details */ forEncryption = pEncrypt; theInitialAEAD = myInitialAEAD; theNonce = myNonce; /* Initialise the keys */ deriveKeys(myKey); resetStreams(); } public String getAlgorithmName() { return theCipher.getAlgorithmName() + "-GCM-SIV"; } /** * check AEAD status. * @param pLen the aeadLength */ private void checkAEADStatus(final int pLen) { /* Check we are initialised */ if ((theFlags & INIT) == 0) { throw new IllegalStateException("Cipher is not initialised"); } /* Check AAD is allowed */ if ((theFlags & AEAD_COMPLETE) != 0) { throw new IllegalStateException("AEAD data cannot be processed after ordinary data"); } /* Make sure that we haven't breached AEAD data limit */ if (theAEADHasher.getBytesProcessed() + Long.MIN_VALUE > (MAX_DATALEN - pLen) + Long.MIN_VALUE) { throw new IllegalStateException("AEAD byte count exceeded"); } } /** * check status. * @param pLen the dataLength */ private void checkStatus(final int pLen) { /* Check we are initialised */ if ((theFlags & INIT) == 0) { throw new IllegalStateException("Cipher is not initialised"); } /* Complete the AEAD section if this is the first data */ if ((theFlags & AEAD_COMPLETE) == 0) { theAEADHasher.completeHash(); theFlags |= AEAD_COMPLETE; } /* Make sure that we haven't breached data limit */ long dataLimit = MAX_DATALEN; long currBytes = thePlain.size(); if (!forEncryption) { dataLimit += BUFLEN; currBytes = theEncData.size(); } if (currBytes + Long.MIN_VALUE > (dataLimit - pLen) + Long.MIN_VALUE) { throw new IllegalStateException("byte count exceeded"); } } public void processAADByte(final byte pByte) { /* Check that we can supply AEAD */ checkAEADStatus(1); /* Process the aead */ theAEADHasher.updateHash(pByte); } public void processAADBytes(final byte[] pData, final int pOffset, final int pLen) { /* Check that we can supply AEAD */ checkAEADStatus(pLen); /* Check input buffer */ checkBuffer(pData, pOffset, pLen, false); /* Process the aead */ theAEADHasher.updateHash(pData, pOffset, pLen); } public int processByte(final byte pByte, final byte[] pOutput, final int pOutOffset) throws DataLengthException { /* Check that we have initialised */ checkStatus(1); /* Store the data */ if (forEncryption) { thePlain.write(pByte); theDataHasher.updateHash(pByte); } else { theEncData.write(pByte); } /* No data returned */ return 0; } public int processBytes(final byte[] pData, final int pOffset, final int pLen, final byte[] pOutput, final int pOutOffset) throws DataLengthException { /* Check that we have initialised */ checkStatus(pLen); /* Check input buffer */ checkBuffer(pData, pOffset, pLen, false); /* Store the data */ if (forEncryption) { thePlain.write(pData, pOffset, pLen); theDataHasher.updateHash(pData, pOffset, pLen); } else { theEncData.write(pData, pOffset, pLen); } /* No data returned */ return 0; } public int doFinal(final byte[] pOutput, final int pOffset) throws IllegalStateException, InvalidCipherTextException { /* Check that we have initialised */ checkStatus(0); /* Check output buffer */ checkBuffer(pOutput, pOffset, getOutputSize(0), true); /* If we are encrypting */ if (forEncryption) { /* Derive the tag */ final byte[] myTag = calculateTag(); /* encrypt the plain text */ final int myDataLen = BUFLEN + encryptPlain(myTag, pOutput, pOffset); /* Add the tag to the output */ System.arraycopy(myTag, 0, pOutput, pOffset + thePlain.size(), BUFLEN); System.arraycopy(myTag, 0, macBlock, 0, macBlock.length); /* Reset the streams */ resetStreams(); return myDataLen; /* else we are decrypting */ } else { /* decrypt to plain text */ decryptPlain(); /* Release plain text */ final int myDataLen = thePlain.size(); final byte[] mySrc = thePlain.getBuffer(); System.arraycopy(mySrc, 0, pOutput, pOffset, myDataLen); /* Reset the streams */ resetStreams(); return myDataLen; } } public byte[] getMac() { return Arrays.clone(macBlock); } public int getUpdateOutputSize(final int pLen) { return 0; } public int getOutputSize(final int pLen) { if (forEncryption) { return pLen + thePlain.size() + BUFLEN; } final int myCurr = pLen + theEncData.size(); return myCurr > BUFLEN ? myCurr - BUFLEN : 0; } public void reset() { resetStreams(); } /** * Reset Streams. */ private void resetStreams() { /* Clear the plainText buffer */ if (thePlain != null) { thePlain.clearBuffer(); } /* Reset hashers */ theAEADHasher.reset(); theDataHasher.reset(); /* Recreate streams (to release memory) */ thePlain = new GCMSIVCache(); theEncData = forEncryption ? null : new GCMSIVCache(); /* Initialise AEAD if required */ theFlags &= ~AEAD_COMPLETE; Arrays.fill(theGHash, (byte) 0); if (theInitialAEAD != null) { theAEADHasher.updateHash(theInitialAEAD, 0, theInitialAEAD.length); } } /** * Obtain buffer length (allowing for null). * @param pBuffer the buffere * @return the length */ private static int bufLength(final byte[] pBuffer) { return pBuffer == null ? 0 : pBuffer.length; } /** * Check buffer. * @param pBuffer the buffer * @param pOffset the offset * @param pLen the length * @param pOutput is this an output buffer? */ private static void checkBuffer(final byte[] pBuffer, final int pOffset, final int pLen, final boolean pOutput) { /* Access lengths */ final int myBufLen = bufLength(pBuffer); final int myLast = pOffset + pLen; /* Check for negative values and buffer overflow */ final boolean badLen = pLen < 0 || pOffset < 0 || myLast < 0; if (badLen || myLast > myBufLen) { throw pOutput ? new OutputLengthException("Output buffer too short.") : new DataLengthException("Input buffer too short."); } } /** * encrypt data stream. * @param pCounter the counter * @param pTarget the target buffer * @param pOffset the target offset * @return the length of data encrypted */ private int encryptPlain(final byte[] pCounter, final byte[] pTarget, final int pOffset) { /* Access buffer and length */ final byte[] mySrc = thePlain.getBuffer(); final byte[] myCounter = Arrays.clone(pCounter); myCounter[BUFLEN - 1] |= MASK; final byte[] myMask = new byte[BUFLEN]; int myRemaining = thePlain.size(); int myOff = 0; /* While we have data to process */ while (myRemaining > 0) { /* Generate the next mask */ theCipher.processBlock(myCounter, 0, myMask, 0); /* Xor data into mask */ final int myLen = Math.min(BUFLEN, myRemaining); xorBlock(myMask, mySrc, myOff, myLen); /* Copy encrypted data to output */ System.arraycopy(myMask, 0, pTarget, pOffset + myOff, myLen); /* Adjust counters */ myRemaining -= myLen; myOff += myLen; incrementCounter(myCounter); } /* Return the amount of data processed */ return thePlain.size(); } /** * decrypt data stream. * @throws InvalidCipherTextException on data too short or mac check failed */ private void decryptPlain() throws InvalidCipherTextException { /* Access buffer and length */ final byte[] mySrc = theEncData.getBuffer(); int myRemaining = theEncData.size() - BUFLEN; /* Check for insufficient data */ if (myRemaining < 0) { throw new InvalidCipherTextException("Data too short"); } /* Access counter */ final byte[] myExpected = Arrays.copyOfRange(mySrc, myRemaining, myRemaining + BUFLEN); final byte[] myCounter = Arrays.clone(myExpected); myCounter[BUFLEN - 1] |= MASK; final byte[] myMask = new byte[BUFLEN]; int myOff = 0; /* While we have data to process */ while (myRemaining > 0) { /* Generate the next mask */ theCipher.processBlock(myCounter, 0, myMask, 0); /* Xor data into mask */ final int myLen = Math.min(BUFLEN, myRemaining); xorBlock(myMask, mySrc, myOff, myLen); /* Write data to plain dataStream */ thePlain.write(myMask, 0, myLen); theDataHasher.updateHash(myMask, 0, myLen); /* Adjust counters */ myRemaining -= myLen; myOff += myLen; incrementCounter(myCounter); } /* Derive and check the tag */ final byte[] myTag = calculateTag(); if (!Arrays.constantTimeAreEqual(myTag, myExpected)) { reset(); throw new InvalidCipherTextException("mac check failed"); } System.arraycopy(myTag, 0, macBlock, 0, macBlock.length); } /** * calculate tag. * @return the calculated tag */ private byte[] calculateTag() { /* Complete the hash */ theDataHasher.completeHash(); final byte[] myPolyVal = completePolyVal(); /* calculate polyVal */ final byte[] myResult = new byte[BUFLEN]; /* Fold in the nonce */ for (int i = 0; i < NONCELEN; i++) { myPolyVal[i] ^= theNonce[i]; } /* Clear top bit */ myPolyVal[BUFLEN - 1] &= (MASK - 1); /* Calculate tag and return it */ theCipher.processBlock(myPolyVal, 0, myResult, 0); return myResult; } /** * complete polyVAL. * @return the calculated value */ private byte[] completePolyVal() { /* Build the polyVal result */ final byte[] myResult = new byte[BUFLEN]; gHashLengths(); fillReverse(theGHash, 0, BUFLEN, myResult); return myResult; } /** * process lengths. */ private void gHashLengths() { /* Create reversed bigEndian buffer to keep it simple */ final byte[] myIn = new byte[BUFLEN]; Pack.longToBigEndian(Bytes.SIZE * theDataHasher.getBytesProcessed(), myIn, 0); Pack.longToBigEndian(Bytes.SIZE * theAEADHasher.getBytesProcessed(), myIn, Longs.BYTES); /* hash value */ gHASH(myIn); } /** * perform the next GHASH step. * @param pNext the next value */ private void gHASH(final byte[] pNext) { xorBlock(theGHash, pNext); theMultiplier.multiplyH(theGHash); } /** * Byte reverse a buffer. * @param pInput the input buffer * @param pOffset the offset * @param pLength the length of data (<= BUFLEN) * @param pOutput the output buffer */ private static void fillReverse(final byte[] pInput, final int pOffset, final int pLength, final byte[] pOutput) { /* Loop through the buffer */ for (int i = 0, j = BUFLEN - 1; i < pLength; i++, j--) { /* Copy byte */ pOutput[j] = pInput[pOffset + i]; } } /** * xor a full block buffer. * @param pLeft the left operand and result * @param pRight the right operand */ private static void xorBlock(final byte[] pLeft, final byte[] pRight) { /* Loop through the bytes */ for (int i = 0; i < BUFLEN; i++) { pLeft[i] ^= pRight[i]; } } /** * xor a partial block buffer. * @param pLeft the left operand and result * @param pRight the right operand * @param pOffset the offset in the right operand * @param pLength the length of data in the right operand */ private static void xorBlock(final byte[] pLeft, final byte[] pRight, final int pOffset, final int pLength) { /* Loop through the bytes */ for (int i = 0; i < pLength; i++) { pLeft[i] ^= pRight[i + pOffset]; } } /** * increment the counter. * @param pCounter the counter to increment */ private static void incrementCounter(final byte[] pCounter) { /* Loop through the bytes incrementing counter */ for (int i = 0; i < Integers.BYTES; i++) { if (++pCounter[i] != 0) { break; } } } /** * multiply by X. * @param pValue the value to adjust */ private static void mulX(final byte[] pValue) { /* Loop through the bytes */ byte myMask = (byte) 0; for (int i = 0; i < BUFLEN; i++) { final byte myValue = pValue[i]; pValue[i] = (byte) (((myValue >> 1) & ~MASK) | myMask); myMask = (myValue & 1) == 0 ? 0 : MASK; } /* Xor in addition if last bit was set */ if (myMask != 0) { pValue[0] ^= ADD; } } /** * Derive Keys. * @param pKey the keyGeneration key */ private void deriveKeys(final KeyParameter pKey) { /* Create the buffers */ final byte[] myIn = new byte[BUFLEN]; final byte[] myOut = new byte[BUFLEN]; final byte[] myResult = new byte[BUFLEN]; final byte[] myEncKey = new byte[pKey.getKey().length]; /* Prepare for encryption */ System.arraycopy(theNonce, 0, myIn, BUFLEN - NONCELEN, NONCELEN); theCipher.init(true, pKey); /* Derive authentication key */ int myOff = 0; theCipher.processBlock(myIn, 0, myOut, 0); System.arraycopy(myOut, 0, myResult, myOff, HALFBUFLEN); myIn[0]++; myOff += HALFBUFLEN; theCipher.processBlock(myIn, 0, myOut, 0); System.arraycopy(myOut, 0, myResult, myOff, HALFBUFLEN); /* Derive encryption key */ myIn[0]++; myOff = 0; theCipher.processBlock(myIn, 0, myOut, 0); System.arraycopy(myOut, 0, myEncKey, myOff, HALFBUFLEN); myIn[0]++; myOff += HALFBUFLEN; theCipher.processBlock(myIn, 0, myOut, 0); System.arraycopy(myOut, 0, myEncKey, myOff, HALFBUFLEN); /* If we have a 32byte key */ if (myEncKey.length == BUFLEN << 1) { /* Derive remainder of encryption key */ myIn[0]++; myOff += HALFBUFLEN; theCipher.processBlock(myIn, 0, myOut, 0); System.arraycopy(myOut, 0, myEncKey, myOff, HALFBUFLEN); myIn[0]++; myOff += HALFBUFLEN; theCipher.processBlock(myIn, 0, myOut, 0); System.arraycopy(myOut, 0, myEncKey, myOff, HALFBUFLEN); } /* Initialise the Cipher */ theCipher.init(true, new KeyParameter(myEncKey)); /* Initialise the multiplier */ fillReverse(myResult, 0, BUFLEN, myOut); mulX(myOut); theMultiplier.init(myOut); theFlags |= INIT; } /** * GCMSIVCache. */ private static class GCMSIVCache extends ByteArrayOutputStream { /** * Constructor. */ GCMSIVCache() { } /** * Obtain the buffer. * @return the buffer */ byte[] getBuffer() { return this.buf; } /** * Clear the buffer. */ void clearBuffer() { Arrays.fill(getBuffer(), (byte) 0); } } /** * Hash Control. */ private class GCMSIVHasher { /** * Cache. */ private final byte[] theBuffer = new byte[BUFLEN]; /** * Single byte cache. */ private final byte[] theByte = new byte[1]; /** * Count of active bytes in cache. */ private int numActive; /** * Count of hashed bytes. */ private long numHashed; /** * Obtain the count of bytes hashed. * @return the count */ long getBytesProcessed() { return numHashed; } /** * Reset the hasher. */ void reset() { numActive = 0; numHashed = 0; } /** * update hash. * @param pByte the byte */ void updateHash(final byte pByte) { theByte[0] = pByte; updateHash(theByte, 0, 1); } /** * update hash. * @param pBuffer the buffer * @param pOffset the offset within the buffer * @param pLen the length of data */ void updateHash(final byte[] pBuffer, final int pOffset, final int pLen) { /* If we should process the cache */ final int mySpace = BUFLEN - numActive; int numProcessed = 0; int myRemaining = pLen; if (numActive > 0 && pLen >= mySpace) { /* Copy data into the cache and hash it */ System.arraycopy(pBuffer, pOffset, theBuffer, numActive, mySpace); fillReverse(theBuffer, 0, BUFLEN, theReverse); gHASH(theReverse); /* Adjust counters */ numProcessed += mySpace; myRemaining -= mySpace; numActive = 0; } /* While we have full blocks */ while (myRemaining >= BUFLEN) { /* Access the next data */ fillReverse(pBuffer, pOffset + numProcessed, BUFLEN, theReverse); gHASH(theReverse); /* Adjust counters */ numProcessed += mySpace; myRemaining -= mySpace; } /* If we have remaining data */ if (myRemaining > 0) { /* Copy data into the cache */ System.arraycopy(pBuffer, pOffset + numProcessed, theBuffer, numActive, myRemaining); numActive += myRemaining; } /* Adjust the number of bytes processed */ numHashed += pLen; } /** * complete hash. */ void completeHash() { /* If we have remaining data */ if (numActive > 0) { /* Access the next data */ Arrays.fill(theReverse, (byte) 0); fillReverse(theBuffer, 0, numActive, theReverse); /* hash value */ gHASH(theReverse); } } } }




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