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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.

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package org.bouncycastle.crypto.prng.drbg;

import java.math.BigInteger;

import org.bouncycastle.asn1.nist.NISTNamedCurves;
import org.bouncycastle.crypto.Digest;
import org.bouncycastle.crypto.prng.EntropySource;
import org.bouncycastle.math.ec.ECCurve;
import org.bouncycastle.math.ec.ECMultiplier;
import org.bouncycastle.math.ec.ECPoint;
import org.bouncycastle.math.ec.FixedPointCombMultiplier;
import org.bouncycastle.util.Arrays;
import org.bouncycastle.util.BigIntegers;

/**
 * A SP800-90A Dual EC DRBG.
 */
public class DualECSP800DRBG
    implements SP80090DRBG
{
    /*
     * Default P, Q values for each curve
     */
    private static final BigInteger p256_Px = new BigInteger("6b17d1f2e12c4247f8bce6e563a440f277037d812deb33a0f4a13945d898c296", 16);
    private static final BigInteger p256_Py = new BigInteger("4fe342e2fe1a7f9b8ee7eb4a7c0f9e162bce33576b315ececbb6406837bf51f5", 16);
    private static final BigInteger p256_Qx = new BigInteger("c97445f45cdef9f0d3e05e1e585fc297235b82b5be8ff3efca67c59852018192", 16);
    private static final BigInteger p256_Qy = new BigInteger("b28ef557ba31dfcbdd21ac46e2a91e3c304f44cb87058ada2cb815151e610046", 16);

    private static final BigInteger p384_Px = new BigInteger("aa87ca22be8b05378eb1c71ef320ad746e1d3b628ba79b9859f741e082542a385502f25dbf55296c3a545e3872760ab7", 16);
    private static final BigInteger p384_Py = new BigInteger("3617de4a96262c6f5d9e98bf9292dc29f8f41dbd289a147ce9da3113b5f0b8c00a60b1ce1d7e819d7a431d7c90ea0e5f", 16);
    private static final BigInteger p384_Qx = new BigInteger("8e722de3125bddb05580164bfe20b8b432216a62926c57502ceede31c47816edd1e89769124179d0b695106428815065", 16);
    private static final BigInteger p384_Qy = new BigInteger("023b1660dd701d0839fd45eec36f9ee7b32e13b315dc02610aa1b636e346df671f790f84c5e09b05674dbb7e45c803dd", 16);

    private static final BigInteger p521_Px = new BigInteger("c6858e06b70404e9cd9e3ecb662395b4429c648139053fb521f828af606b4d3dbaa14b5e77efe75928fe1dc127a2ffa8de3348b3c1856a429bf97e7e31c2e5bd66", 16);
    private static final BigInteger p521_Py = new BigInteger("11839296a789a3bc0045c8a5fb42c7d1bd998f54449579b446817afbd17273e662c97ee72995ef42640c550b9013fad0761353c7086a272c24088be94769fd16650", 16);
    private static final BigInteger p521_Qx = new BigInteger("1b9fa3e518d683c6b65763694ac8efbaec6fab44f2276171a42726507dd08add4c3b3f4c1ebc5b1222ddba077f722943b24c3edfa0f85fe24d0c8c01591f0be6f63", 16);
    private static final BigInteger p521_Qy = new BigInteger("1f3bdba585295d9a1110d1df1f9430ef8442c5018976ff3437ef91b81dc0b8132c8d5c39c32d0e004a3092b7d327c0e7a4d26d2c7b69b58f9066652911e457779de", 16);

    private static final DualECPoints[] nistPoints;

    static
    {
        nistPoints = new DualECPoints[3];

        ECCurve.Fp curve = (ECCurve.Fp)NISTNamedCurves.getByName("P-256").getCurve();

        nistPoints[0] = new DualECPoints(128, curve.createPoint(p256_Px, p256_Py), curve.createPoint(p256_Qx, p256_Qy), 1);

        curve = (ECCurve.Fp)NISTNamedCurves.getByName("P-384").getCurve();

        nistPoints[1] = new DualECPoints(192, curve.createPoint(p384_Px, p384_Py), curve.createPoint(p384_Qx, p384_Qy), 1);

        curve = (ECCurve.Fp)NISTNamedCurves.getByName("P-521").getCurve();

        nistPoints[2] = new DualECPoints(256, curve.createPoint(p521_Px, p521_Py), curve.createPoint(p521_Qx, p521_Qy), 1);
    }


    private static final long       RESEED_MAX = 1L << (32 - 1);
    private static final int        MAX_ADDITIONAL_INPUT = 1 << (13 - 1);
    private static final int        MAX_ENTROPY_LENGTH = 1 << (13 - 1);
    private static final int        MAX_PERSONALIZATION_STRING = 1 << (13 -1);

    private Digest                 _digest;
    private long                   _reseedCounter;
    private EntropySource          _entropySource;
    private int                    _securityStrength;
    private int                    _seedlen;
    private int                    _outlen;
    private ECCurve.Fp             _curve;
    private ECPoint                _P;
    private ECPoint                _Q;
    private byte[]                 _s;
    private int                    _sLength;
    private ECMultiplier           _fixedPointMultiplier = new FixedPointCombMultiplier();

    /**
     * Construct a SP800-90A Dual EC DRBG.
     * 

* Minimum entropy requirement is the security strength requested. *

* @param digest source digest to use with the DRB stream. * @param securityStrength security strength required (in bits) * @param entropySource source of entropy to use for seeding/reseeding. * @param personalizationString personalization string to distinguish this DRBG (may be null). * @param nonce nonce to further distinguish this DRBG (may be null). */ public DualECSP800DRBG(Digest digest, int securityStrength, EntropySource entropySource, byte[] personalizationString, byte[] nonce) { this(nistPoints, digest, securityStrength, entropySource, personalizationString, nonce); } /** * Construct a SP800-90A Dual EC DRBG. *

* Minimum entropy requirement is the security strength requested. *

* @param pointSet an array of points to choose from, in order of increasing security strength * @param digest source digest to use with the DRB stream. * @param securityStrength security strength required (in bits) * @param entropySource source of entropy to use for seeding/reseeding. * @param personalizationString personalization string to distinguish this DRBG (may be null). * @param nonce nonce to further distinguish this DRBG (may be null). */ public DualECSP800DRBG(DualECPoints[] pointSet, Digest digest, int securityStrength, EntropySource entropySource, byte[] personalizationString, byte[] nonce) { _digest = digest; _entropySource = entropySource; _securityStrength = securityStrength; if (Utils.isTooLarge(personalizationString, MAX_PERSONALIZATION_STRING / 8)) { throw new IllegalArgumentException("Personalization string too large"); } if (entropySource.entropySize() < securityStrength || entropySource.entropySize() > MAX_ENTROPY_LENGTH) { throw new IllegalArgumentException("EntropySource must provide between " + securityStrength + " and " + MAX_ENTROPY_LENGTH + " bits"); } byte[] entropy = getEntropy(); byte[] seedMaterial = Arrays.concatenate(entropy, nonce, personalizationString); for (int i = 0; i != pointSet.length; i++) { if (securityStrength <= pointSet[i].getSecurityStrength()) { if (Utils.getMaxSecurityStrength(digest) < pointSet[i].getSecurityStrength()) { throw new IllegalArgumentException("Requested security strength is not supported by digest"); } _seedlen = pointSet[i].getSeedLen(); _outlen = pointSet[i].getMaxOutlen() / 8; _P = pointSet[i].getP(); _Q = pointSet[i].getQ(); break; } } if (_P == null) { throw new IllegalArgumentException("security strength cannot be greater than 256 bits"); } _s = Utils.hash_df(_digest, seedMaterial, _seedlen); _sLength = _s.length; _reseedCounter = 0; } /** * Return the block size (in bits) of the DRBG. * * @return the number of bits produced on each internal round of the DRBG. */ public int getBlockSize() { return _outlen * 8; } /** * Populate a passed in array with random data. * * @param output output array for generated bits. * @param additionalInput additional input to be added to the DRBG in this step. * @param predictionResistant true if a reseed should be forced, false otherwise. * * @return number of bits generated, -1 if a reseed required. */ public int generate(byte[] output, byte[] additionalInput, boolean predictionResistant) { int numberOfBits = output.length*8; int m = output.length / _outlen; if (Utils.isTooLarge(additionalInput, MAX_ADDITIONAL_INPUT / 8)) { throw new IllegalArgumentException("Additional input too large"); } if (_reseedCounter + m > RESEED_MAX) { return -1; } if (predictionResistant) { reseed(additionalInput); additionalInput = null; } BigInteger s; if (additionalInput != null) { // Note: we ignore the use of pad8 on the additional input as we mandate byte arrays for it. additionalInput = Utils.hash_df(_digest, additionalInput, _seedlen); s = new BigInteger(1, xor(_s, additionalInput)); } else { s = new BigInteger(1, _s); } // make sure we start with a clean output array. Arrays.fill(output, (byte)0); int outOffset = 0; for (int i = 0; i < m; i++) { s = getScalarMultipleXCoord(_P, s); //System.err.println("S: " + new String(Hex.encode(_s))); byte[] r = getScalarMultipleXCoord(_Q, s).toByteArray(); if (r.length > _outlen) { System.arraycopy(r, r.length - _outlen, output, outOffset, _outlen); } else { System.arraycopy(r, 0, output, outOffset + (_outlen - r.length), r.length); } //System.err.println("R: " + new String(Hex.encode(r))); outOffset += _outlen; _reseedCounter++; } if (outOffset < output.length) { s = getScalarMultipleXCoord(_P, s); byte[] r = getScalarMultipleXCoord(_Q, s).toByteArray(); int required = output.length - outOffset; if (r.length > _outlen) { System.arraycopy(r, r.length - _outlen, output, outOffset, required); } else { System.arraycopy(r, 0, output, outOffset + (_outlen - r.length), required); } _reseedCounter++; } // Need to preserve length of S as unsigned int. _s = BigIntegers.asUnsignedByteArray(_sLength, getScalarMultipleXCoord(_P, s)); return numberOfBits; } /** * Reseed the DRBG. * * @param additionalInput additional input to be added to the DRBG in this step. */ public void reseed(byte[] additionalInput) { if (Utils.isTooLarge(additionalInput, MAX_ADDITIONAL_INPUT / 8)) { throw new IllegalArgumentException("Additional input string too large"); } byte[] entropy = getEntropy(); byte[] seedMaterial = Arrays.concatenate(pad8(_s, _seedlen), entropy, additionalInput); _s = Utils.hash_df(_digest, seedMaterial, _seedlen); _reseedCounter = 0; } private byte[] getEntropy() { byte[] entropy = _entropySource.getEntropy(); if (entropy.length < (_securityStrength + 7) / 8) { throw new IllegalStateException("Insufficient entropy provided by entropy source"); } return entropy; } private byte[] xor(byte[] a, byte[] b) { if (b == null) { return a; } byte[] rv = new byte[a.length]; for (int i = 0; i != rv.length; i++) { rv[i] = (byte)(a[i] ^ b[i]); } return rv; } // Note: works in place private byte[] pad8(byte[] s, int seedlen) { if (seedlen % 8 == 0) { return s; } int shift = 8 - (seedlen % 8); int carry = 0; for (int i = s.length - 1; i >= 0; i--) { int b = s[i] & 0xff; s[i] = (byte)((b << shift) | (carry >> (8 - shift))); carry = b; } return s; } private BigInteger getScalarMultipleXCoord(ECPoint p, BigInteger s) { return _fixedPointMultiplier.multiply(p, s).normalize().getAffineXCoord().toBigInteger(); } }




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