Java Code Examples for org.bouncycastle.math.ec.ECPoint#Fp

The following examples show how to use org.bouncycastle.math.ec.ECPoint#Fp . You can vote up the ones you like or vote down the ones you don't like, and go to the original project or source file by following the links above each example. You may check out the related API usage on the sidebar.
Example 1
Source File: ECKey.java    From javasdk with GNU Lesser General Public License v3.0 4 votes vote down vote up 
/**
 * <p>Given the components of a signature and a selector value, recover and return the public key
 * that generated the signature according to the algorithm in SEC1v2 section 4.1.6.</p>
 * <p>
 * <p>The recId is an index from 0 to 3 which indicates which of the 4 possible keys is the correct one. Because
 * the key recovery operation yields multiple potential keys, the correct key must either be stored alongside the
 * signature, or you must be willing to try each recId in turn until you find one that outputs the key you are
 * expecting.</p>
 * <p>
 * <p>If this method returns null it means recovery was not possible and recId should be iterated.</p>
 * <p>
 * <p>Given the above two points, a correct usage of this method is inside a for loop from 0 to 3, and if the
 * output is null OR a key that is not the one you expect, you try again with the next recId.</p>
 *
 * @param recId       Which possible key to recover.
 * @param sig         the R and S components of the signature, wrapped.
 * @param messageHash Hash of the data that was signed.
 * @return 65-byte encoded public key
 */
public static byte[] recoverPubBytesFromSignature(int recId, ECDSASignature sig, byte[] messageHash) {
    check(recId >= 0, "recId must be positive");
    check(sig.r.signum() >= 0, "r must be positive");
    check(sig.s.signum() >= 0, "s must be positive");
    check(messageHash != null, "messageHash must not be null");
    // 1.0 For j from 0 to h   (h == recId here and the loop is outside this function)
    //   1.1 Let x = r + jn
    BigInteger n = CURVE.getN();  // Curve order.
    BigInteger i = BigInteger.valueOf((long) recId / 2);
    BigInteger x = sig.r.add(i.multiply(n));
    //   1.2. Convert the integer x to an octet string X of length mlen using the conversion routine
    //        specified in Section 2.3.7, where mlen = ⌈(log2 p)/8⌉ or mlen = ⌈m/8⌉.
    //   1.3. Convert the octet string (16 set binary digits)||X to an elliptic curve point R using the
    //        conversion routine specified in Section 2.3.4. If this conversion routine outputs “invalid”, then
    //        do another iteration of Step 1.
    //
    // More concisely, what these points mean is to use X as a compressed public key.
    ECCurve.Fp curve = (ECCurve.Fp) CURVE.getCurve();
    BigInteger prime = curve.getQ();  // Bouncy Castle is not consistent about the letter it uses for the prime.
    if (x.compareTo(prime) >= 0) {
        // Cannot have point co-ordinates larger than this as everything takes place modulo Q.
        return null;
    }
    // Compressed keys require you to know an extra bit of data about the y-coord as there are two possibilities.
    // So it's encoded in the recId.
    ECPoint R = decompressKey(x, (recId & 1) == 1);
    //   1.4. If nR != point at infinity, then do another iteration of Step 1 (callers responsibility).
    if (!R.multiply(n).isInfinity())
        return null;
    //   1.5. Compute e from M using Steps 2 and 3 of ECDSA signature verification.
    BigInteger e = new BigInteger(1, messageHash);
    //   1.6. For k from 1 to 2 do the following.   (loop is outside this function via iterating recId)
    //   1.6.1. Compute a candidate public key as:
    //               Q = mi(r) * (sR - eG)
    //
    // Where mi(x) is the modular multiplicative inverse. We transform this into the following:
    //               Q = (mi(r) * s ** R) + (mi(r) * -e ** G)
    // Where -e is the modular additive inverse of e, that is z such that z + e = 0 (mod n). In the above equation
    // ** is point multiplication and + is point addition (the EC group operator).
    //
    // We can find the additive inverse by subtracting e from zero then taking the mod. For example the additive
    // inverse of 3 modulo 11 is 8 because 3 + 8 mod 11 = 0, and -3 mod 11 = 8.
    BigInteger eInv = BigInteger.ZERO.subtract(e).mod(n);
    BigInteger rInv = sig.r.modInverse(n);
    BigInteger srInv = rInv.multiply(sig.s).mod(n);
    BigInteger eInvrInv = rInv.multiply(eInv).mod(n);
    ECPoint.Fp q = (ECPoint.Fp) ECAlgorithms.sumOfTwoMultiplies(CURVE.getG(), eInvrInv, R, srInv);
    return q.getEncoded(/* compressed */ false);
}
Example 2
Source File: EthereumUtil.java    From hadoopcryptoledger with Apache License 2.0 4 votes vote down vote up 
/**
 * Calculates the sent address of an EthereumTransaction. Note this can be a costly operation to calculate. . This requires that you have Bouncy castle as a dependency in your project
 *
 *
 * @param eTrans transaction
 * @param chainId chain identifier (e.g. 1 main net)
 * @return sent address as byte array
 */
public static byte[] getSendAddress(EthereumTransaction eTrans, int chainId) {
	// init, maybe we move this out to save time
	X9ECParameters params = SECNamedCurves.getByName("secp256k1");
	ECDomainParameters CURVE=new ECDomainParameters(params.getCurve(), params.getG(), params.getN(), params.getH());	 // needed for getSentAddress

 
    byte[] transactionHash;

    if ((eTrans.getSig_v()[0]==chainId*2+EthereumUtil.CHAIN_ID_INC) || (eTrans.getSig_v()[0]==chainId*2+EthereumUtil.CHAIN_ID_INC+1)) {  // transaction hash with dummy signature data
    	 transactionHash = EthereumUtil.getTransactionHashWithDummySignatureEIP155(eTrans);
    } else {  // transaction hash without signature data
	 transactionHash = EthereumUtil.getTransactionHashWithoutSignature(eTrans);
    }
  // signature to address
	BigInteger bR = new BigInteger(1,eTrans.getSig_r());
	BigInteger bS = new BigInteger(1,eTrans.getSig_s());
  // calculate v for signature
	byte v =(byte) (eTrans.getSig_v()[0]);
	if (!((v == EthereumUtil.LOWER_REAL_V) || (v== (LOWER_REAL_V+1)))) {
		byte vReal = EthereumUtil.LOWER_REAL_V;
		if (((int)v%2 == 0)) {
			v = (byte) (vReal+0x01);
		} else {
			v = vReal;
		}
	}


	// the following lines are inspired from ECKey.java of EthereumJ, but adapted to the hadoopcryptoledger context
	if (v < 27 || v > 34) {
		LOG.error("Header out of Range:  "+v);
		throw new RuntimeException("Header out of range "+v);
	}
	if (v>=31) {

		v -=4;
	}
	int receiverId = v - 27;
	BigInteger n = CURVE.getN();
    BigInteger i = BigInteger.valueOf((long) receiverId / 2);
    BigInteger x = bR.add(i.multiply(n));
    ECCurve.Fp curve = (ECCurve.Fp) CURVE.getCurve();
    BigInteger prime = curve.getQ();
    if (x.compareTo(prime) >= 0) {
        return null;
     }
    // decompress Key
    X9IntegerConverter x9 = new X9IntegerConverter();
    byte[] compEnc = x9.integerToBytes(x, 1 + x9.getByteLength(CURVE.getCurve()));
    boolean yBit=(receiverId & 1) == 1;
    compEnc[0] = (byte)(yBit ? 0x03 : 0x02);
    ECPoint R =  CURVE.getCurve().decodePoint(compEnc);
    if (!R.multiply(n).isInfinity()) {
    		return null;
    }
    BigInteger e = new BigInteger(1,transactionHash);
    BigInteger eInv = BigInteger.ZERO.subtract(e).mod(n);
    BigInteger rInv = bR.modInverse(n);
    BigInteger srInv = rInv.multiply(bS).mod(n);
    BigInteger eInvrInv = rInv.multiply(eInv).mod(n);
    ECPoint.Fp q = (ECPoint.Fp) ECAlgorithms.sumOfTwoMultiplies(CURVE.getG(), eInvrInv, R, srInv);
    byte[] pubKey=q.getEncoded(false);
    // now we need to convert the public key into an ethereum send address which is the last 20 bytes of 32 byte KECCAK-256 Hash of the key.
	Keccak.Digest256 digest256 = new Keccak.Digest256();
	digest256.update(pubKey,1,pubKey.length-1);
	byte[] kcck = digest256.digest();
    return Arrays.copyOfRange(kcck,12,kcck.length);
}