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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.
package org.bouncycastle.pqc.crypto.ntru;
import java.security.SecureRandom;
import org.bouncycastle.crypto.AsymmetricBlockCipher;
import org.bouncycastle.crypto.CipherParameters;
import org.bouncycastle.crypto.CryptoServicesRegistrar;
import org.bouncycastle.crypto.DataLengthException;
import org.bouncycastle.crypto.Digest;
import org.bouncycastle.crypto.InvalidCipherTextException;
import org.bouncycastle.crypto.params.ParametersWithRandom;
import org.bouncycastle.pqc.math.ntru.polynomial.DenseTernaryPolynomial;
import org.bouncycastle.pqc.math.ntru.polynomial.IntegerPolynomial;
import org.bouncycastle.pqc.math.ntru.polynomial.Polynomial;
import org.bouncycastle.pqc.math.ntru.polynomial.ProductFormPolynomial;
import org.bouncycastle.pqc.math.ntru.polynomial.SparseTernaryPolynomial;
import org.bouncycastle.pqc.math.ntru.polynomial.TernaryPolynomial;
import org.bouncycastle.util.Arrays;
/**
* Encrypts, decrypts data and generates key pairs.
* The parameter p is hardcoded to 3.
*/
public class NTRUEngine
implements AsymmetricBlockCipher
{
private boolean forEncryption;
private NTRUEncryptionParameters params;
private NTRUEncryptionPublicKeyParameters pubKey;
private NTRUEncryptionPrivateKeyParameters privKey;
private SecureRandom random;
/**
* Constructs a new instance with a set of encryption parameters.
*
*/
public NTRUEngine()
{
}
public void init(boolean forEncryption, CipherParameters parameters)
{
this.forEncryption = forEncryption;
if (forEncryption)
{
if (parameters instanceof ParametersWithRandom)
{
ParametersWithRandom p = (ParametersWithRandom)parameters;
this.random = p.getRandom();
this.pubKey = (NTRUEncryptionPublicKeyParameters)p.getParameters();
}
else
{
this.random = CryptoServicesRegistrar.getSecureRandom();
this.pubKey = (NTRUEncryptionPublicKeyParameters)parameters;
}
this.params = pubKey.getParameters();
}
else
{
this.privKey = (NTRUEncryptionPrivateKeyParameters)parameters;
this.params = privKey.getParameters();
}
}
public int getInputBlockSize()
{
return params.maxMsgLenBytes;
}
public int getOutputBlockSize()
{
return ((params.N * log2(params.q)) + 7) / 8;
}
public byte[] processBlock(byte[] in, int inOff, int len)
throws InvalidCipherTextException
{
byte[] tmp = new byte[len];
System.arraycopy(in, inOff, tmp, 0, len);
if (forEncryption)
{
return encrypt(tmp, pubKey);
}
else
{
return decrypt(tmp, privKey);
}
}
/**
* Encrypts a message.
* See P1363.1 section 9.2.2.
*
* @param m The message to encrypt
* @param pubKey the public key to encrypt the message with
* @return the encrypted message
*/
private byte[] encrypt(byte[] m, NTRUEncryptionPublicKeyParameters pubKey)
{
IntegerPolynomial pub = pubKey.h;
int N = params.N;
int q = params.q;
int maxLenBytes = params.maxMsgLenBytes;
int db = params.db;
int bufferLenBits = params.bufferLenBits;
int dm0 = params.dm0;
int pkLen = params.pkLen;
int minCallsMask = params.minCallsMask;
boolean hashSeed = params.hashSeed;
byte[] oid = params.oid;
int l = m.length;
if (maxLenBytes > 255)
{
throw new IllegalArgumentException("llen values bigger than 1 are not supported");
}
if (l > maxLenBytes)
{
throw new DataLengthException("Message too long: " + l + ">" + maxLenBytes);
}
while (true)
{
// M = b|octL|m|p0
byte[] b = new byte[db / 8];
random.nextBytes(b);
byte[] p0 = new byte[maxLenBytes + 1 - l];
byte[] M = new byte[bufferLenBits / 8];
System.arraycopy(b, 0, M, 0, b.length);
M[b.length] = (byte)l;
System.arraycopy(m, 0, M, b.length + 1, m.length);
System.arraycopy(p0, 0, M, b.length + 1 + m.length, p0.length);
IntegerPolynomial mTrin = IntegerPolynomial.fromBinary3Sves(M, N);
// sData = OID|m|b|hTrunc
byte[] bh = pub.toBinary(q);
byte[] hTrunc = copyOf(bh, pkLen / 8);
byte[] sData = buildSData(oid, m, l, b, hTrunc);
Polynomial r = generateBlindingPoly(sData, M);
IntegerPolynomial R = r.mult(pub, q);
IntegerPolynomial R4 = (IntegerPolynomial)R.clone();
R4.modPositive(4);
byte[] oR4 = R4.toBinary(4);
IntegerPolynomial mask = MGF(oR4, N, minCallsMask, hashSeed);
mTrin.add(mask);
mTrin.mod3();
if (mTrin.count(-1) < dm0)
{
continue;
}
if (mTrin.count(0) < dm0)
{
continue;
}
if (mTrin.count(1) < dm0)
{
continue;
}
R.add(mTrin, q);
R.ensurePositive(q);
return R.toBinary(q);
}
}
private byte[] buildSData(byte[] oid, byte[] m, int l, byte[] b, byte[] hTrunc)
{
byte[] sData = new byte[oid.length + l + b.length + hTrunc.length];
System.arraycopy(oid, 0, sData, 0, oid.length);
System.arraycopy(m, 0, sData, oid.length, m.length);
System.arraycopy(b, 0, sData, oid.length + m.length, b.length);
System.arraycopy(hTrunc, 0, sData, oid.length + m.length + b.length, hTrunc.length);
return sData;
}
protected IntegerPolynomial encrypt(IntegerPolynomial m, TernaryPolynomial r, IntegerPolynomial pubKey)
{
IntegerPolynomial e = r.mult(pubKey, params.q);
e.add(m, params.q);
e.ensurePositive(params.q);
return e;
}
/**
* Deterministically generates a blinding polynomial from a seed and a message representative.
*
* @param seed
* @param M message representative
* @return a blinding polynomial
*/
private Polynomial generateBlindingPoly(byte[] seed, byte[] M)
{
IndexGenerator ig = new IndexGenerator(seed, params);
if (params.polyType == NTRUParameters.TERNARY_POLYNOMIAL_TYPE_PRODUCT)
{
SparseTernaryPolynomial r1 = new SparseTernaryPolynomial(generateBlindingCoeffs(ig, params.dr1));
SparseTernaryPolynomial r2 = new SparseTernaryPolynomial(generateBlindingCoeffs(ig, params.dr2));
SparseTernaryPolynomial r3 = new SparseTernaryPolynomial(generateBlindingCoeffs(ig, params.dr3));
return new ProductFormPolynomial(r1, r2, r3);
}
else
{
int dr = params.dr;
boolean sparse = params.sparse;
int[] r = generateBlindingCoeffs(ig, dr);
if (sparse)
{
return new SparseTernaryPolynomial(r);
}
else
{
return new DenseTernaryPolynomial(r);
}
}
}
/**
* Generates an int
array containing dr
elements equal to 1
* and dr
elements equal to -1
using an index generator.
*
* @param ig an index generator
* @param dr number of ones / negative ones
* @return an array containing numbers between -1
and 1
*/
private int[] generateBlindingCoeffs(IndexGenerator ig, int dr)
{
int N = params.N;
int[] r = new int[N];
for (int coeff = -1; coeff <= 1; coeff += 2)
{
int t = 0;
while (t < dr)
{
int i = ig.nextIndex();
if (r[i] == 0)
{
r[i] = coeff;
t++;
}
}
}
return r;
}
/**
* An implementation of MGF-TP-1 from P1363.1 section 8.4.1.1.
*
* @param seed
* @param N
* @param minCallsR
* @param hashSeed whether to hash the seed
*/
private IntegerPolynomial MGF(byte[] seed, int N, int minCallsR, boolean hashSeed)
{
Digest hashAlg = params.hashAlg;
int hashLen = hashAlg.getDigestSize();
byte[] buf = new byte[minCallsR * hashLen];
byte[] Z = hashSeed ? calcHash(hashAlg, seed) : seed;
int counter = 0;
while (counter < minCallsR)
{
hashAlg.update(Z, 0, Z.length);
putInt(hashAlg, counter);
byte[] hash = calcHash(hashAlg);
System.arraycopy(hash, 0, buf, counter * hashLen, hashLen);
counter++;
}
IntegerPolynomial i = new IntegerPolynomial(N);
while (true)
{
int cur = 0;
for (int index = 0; index != buf.length; index++)
{
int O = (int)buf[index] & 0xFF;
if (O >= 243) // 243 = 3^5
{
continue;
}
for (int terIdx = 0; terIdx < 4; terIdx++)
{
int rem3 = O % 3;
i.coeffs[cur] = rem3 - 1;
cur++;
if (cur == N)
{
return i;
}
O = (O - rem3) / 3;
}
i.coeffs[cur] = O - 1;
cur++;
if (cur == N)
{
return i;
}
}
if (cur >= N)
{
return i;
}
hashAlg.update(Z, 0, Z.length);
putInt(hashAlg, counter);
byte[] hash = calcHash(hashAlg);
buf = hash;
counter++;
}
}
private void putInt(Digest hashAlg, int counter)
{
hashAlg.update((byte)(counter >> 24));
hashAlg.update((byte)(counter >> 16));
hashAlg.update((byte)(counter >> 8));
hashAlg.update((byte)counter);
}
private byte[] calcHash(Digest hashAlg)
{
byte[] tmp = new byte[hashAlg.getDigestSize()];
hashAlg.doFinal(tmp, 0);
return tmp;
}
private byte[] calcHash(Digest hashAlg, byte[] input)
{
byte[] tmp = new byte[hashAlg.getDigestSize()];
hashAlg.update(input, 0, input.length);
hashAlg.doFinal(tmp, 0);
return tmp;
}
/**
* Decrypts a message.
* See P1363.1 section 9.2.3.
*
* @param data The message to decrypt
* @param privKey the corresponding private key
* @return the decrypted message
* @throws InvalidCipherTextException if the encrypted data is invalid, or maxLenBytes
is greater than 255
*/
private byte[] decrypt(byte[] data, NTRUEncryptionPrivateKeyParameters privKey)
throws InvalidCipherTextException
{
Polynomial priv_t = privKey.t;
IntegerPolynomial priv_fp = privKey.fp;
IntegerPolynomial pub = privKey.h;
int N = params.N;
int q = params.q;
int db = params.db;
int maxMsgLenBytes = params.maxMsgLenBytes;
int dm0 = params.dm0;
int pkLen = params.pkLen;
int minCallsMask = params.minCallsMask;
boolean hashSeed = params.hashSeed;
byte[] oid = params.oid;
if (maxMsgLenBytes > 255)
{
throw new DataLengthException("maxMsgLenBytes values bigger than 255 are not supported");
}
int bLen = db / 8;
IntegerPolynomial e = IntegerPolynomial.fromBinary(data, N, q);
IntegerPolynomial ci = decrypt(e, priv_t, priv_fp);
if (ci.count(-1) < dm0)
{
throw new InvalidCipherTextException("Less than dm0 coefficients equal -1");
}
if (ci.count(0) < dm0)
{
throw new InvalidCipherTextException("Less than dm0 coefficients equal 0");
}
if (ci.count(1) < dm0)
{
throw new InvalidCipherTextException("Less than dm0 coefficients equal 1");
}
IntegerPolynomial cR = (IntegerPolynomial)e.clone();
cR.sub(ci);
cR.modPositive(q);
IntegerPolynomial cR4 = (IntegerPolynomial)cR.clone();
cR4.modPositive(4);
byte[] coR4 = cR4.toBinary(4);
IntegerPolynomial mask = MGF(coR4, N, minCallsMask, hashSeed);
IntegerPolynomial cMTrin = ci;
cMTrin.sub(mask);
cMTrin.mod3();
byte[] cM = cMTrin.toBinary3Sves();
byte[] cb = new byte[bLen];
System.arraycopy(cM, 0, cb, 0, bLen);
int cl = cM[bLen] & 0xFF; // llen=1, so read one byte
if (cl > maxMsgLenBytes)
{
throw new InvalidCipherTextException("Message too long: " + cl + ">" + maxMsgLenBytes);
}
byte[] cm = new byte[cl];
System.arraycopy(cM, bLen + 1, cm, 0, cl);
byte[] p0 = new byte[cM.length - (bLen + 1 + cl)];
System.arraycopy(cM, bLen + 1 + cl, p0, 0, p0.length);
if (!Arrays.constantTimeAreEqual(p0, new byte[p0.length]))
{
throw new InvalidCipherTextException("The message is not followed by zeroes");
}
// sData = OID|m|b|hTrunc
byte[] bh = pub.toBinary(q);
byte[] hTrunc = copyOf(bh, pkLen / 8);
byte[] sData = buildSData(oid, cm, cl, cb, hTrunc);
Polynomial cr = generateBlindingPoly(sData, cm);
IntegerPolynomial cRPrime = cr.mult(pub);
cRPrime.modPositive(q);
if (!cRPrime.equals(cR))
{
throw new InvalidCipherTextException("Invalid message encoding");
}
return cm;
}
/**
* @param e
* @param priv_t a polynomial such that if fastFp=true
, f=1+3*priv_t
; otherwise, f=priv_t
* @param priv_fp
* @return an IntegerPolynomial representing the output.
*/
protected IntegerPolynomial decrypt(IntegerPolynomial e, Polynomial priv_t, IntegerPolynomial priv_fp)
{
IntegerPolynomial a;
if (params.fastFp)
{
a = priv_t.mult(e, params.q);
a.mult(3);
a.add(e);
}
else
{
a = priv_t.mult(e, params.q);
}
a.center0(params.q);
a.mod3();
IntegerPolynomial c = params.fastFp ? a : new DenseTernaryPolynomial(a).mult(priv_fp, 3);
c.center0(3);
return c;
}
private byte[] copyOf(byte[] src, int len)
{
byte[] tmp = new byte[len];
System.arraycopy(src, 0, tmp, 0, len < src.length ? len : src.length);
return tmp;
}
private int log2(int value)
{
if (value == 2048)
{
return 11;
}
throw new IllegalStateException("log2 not fully implemented");
}
}
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