// Used by SunEC

public static byte[] sArray(BigInteger s, ECParameterSpec params) {

byte[] arr = s.toByteArray();

ArrayUtil.reverse(arr);

int byteLength = (params.getOrder().bitLength() + 7) / 8;

byte[] arrayS = new byte[byteLength];

int length = Math.min(byteLength, arr.length);

System.arraycopy(arr, 0, arrayS, 0, length);

return arrayS;

}

// Used by SunPKCS11 and SunJSSE.

public static ECPoint decodePoint(byte[] data, EllipticCurve curve)

throws IOException {

if ((data.length == 0) || (data[0] != 4)) {

throw new IOException("Only uncompressed point format supported");

}

// Per ANSI X9.62, an encoded point is a 1 byte type followed by

// ceiling(log base 2 field-size / 8) bytes of x and the same of y.

int n = (data.length - 1) / 2;

if (n != ((curve.getField().getFieldSize() + 7 ) >> 3)) {

throw new IOException("Point does not match field size");

}

byte[] xb = Arrays.copyOfRange(data, 1, 1 + n);

byte[] yb = Arrays.copyOfRange(data, n + 1, n + 1 + n);

return new ECPoint(new BigInteger(1, xb), new BigInteger(1, yb));

}

// Used by SunPKCS11 and SunJSSE.

public static byte[] encodePoint(ECPoint point, EllipticCurve curve) {

// get field size in bytes (rounding up)

int n = (curve.getField().getFieldSize() + 7) >> 3;

byte[] xb = trimZeroes(point.getAffineX().toByteArray());

byte[] yb = trimZeroes(point.getAffineY().toByteArray());

if ((xb.length > n) || (yb.length > n)) {

throw new RuntimeException

("Point coordinates do not match field size");

}

byte[] b = new byte[1 + (n << 1)];

b[0] = 4; // uncompressed

System.arraycopy(xb, 0, b, n - xb.length + 1, xb.length);

System.arraycopy(yb, 0, b, b.length - yb.length, yb.length);

return b;

}

public static byte[] trimZeroes(byte[] b) {

int i = 0;

while ((i < b.length - 1) && (b[i] == 0)) {

i++;

}

if (i == 0) {

return b;

}

return Arrays.copyOfRange(b, i, b.length);

}

private static KeyFactory getKeyFactory() {

try {

return KeyFactory.getInstance("EC", "SunEC");

} catch (NoSuchAlgorithmException | NoSuchProviderException e) {

throw new RuntimeException(e);

}

}

public static ECPublicKey decodeX509ECPublicKey(byte[] encoded)

throws InvalidKeySpecException {

KeyFactory keyFactory = getKeyFactory();

X509EncodedKeySpec keySpec = new X509EncodedKeySpec(encoded);

return (ECPublicKey)keyFactory.generatePublic(keySpec);

}

public static byte[] x509EncodeECPublicKey(ECPoint w,

ECParameterSpec params) throws InvalidKeySpecException {

KeyFactory keyFactory = getKeyFactory();

ECPublicKeySpec keySpec = new ECPublicKeySpec(w, params);

Key key = keyFactory.generatePublic(keySpec);

return key.getEncoded();

}

public static ECPrivateKey decodePKCS8ECPrivateKey(byte[] encoded)

throws InvalidKeySpecException {

KeyFactory keyFactory = getKeyFactory();

PKCS8EncodedKeySpec keySpec = new PKCS8EncodedKeySpec(encoded);

return (ECPrivateKey)keyFactory.generatePrivate(keySpec);

}

public static ECPrivateKey generateECPrivateKey(BigInteger s,

ECParameterSpec params) throws InvalidKeySpecException {

KeyFactory keyFactory = getKeyFactory();

ECPrivateKeySpec keySpec = new ECPrivateKeySpec(s, params);

return (ECPrivateKey)keyFactory.generatePrivate(keySpec);

}

public static AlgorithmParameters getECParameters(Provider p) {

try {

if (p != null) {

return AlgorithmParameters.getInstance("EC", p);

}

return AlgorithmParameters.getInstance("EC");

} catch (NoSuchAlgorithmException nsae) {

throw new RuntimeException(nsae);

}

}

public static byte[] encodeECParameterSpec(Provider p,

ECParameterSpec spec) {

AlgorithmParameters parameters = getECParameters(p);

try {

parameters.init(spec);

} catch (InvalidParameterSpecException ipse) {

throw new RuntimeException("Not a known named curve: " + spec);

}

try {

return parameters.getEncoded();

} catch (IOException ioe) {

// it is a bug if this should happen

throw new RuntimeException(ioe);

}

}

public static ECParameterSpec getECParameterSpec(Provider p,

ECParameterSpec spec) {

AlgorithmParameters parameters = getECParameters(p);

try {

parameters.init(spec);

return parameters.getParameterSpec(ECParameterSpec.class);

} catch (InvalidParameterSpecException ipse) {

return null;

}

}

public static ECParameterSpec getECParameterSpec(Provider p,

byte[] params)

throws IOException {

AlgorithmParameters parameters = getECParameters(p);

parameters.init(params);

try {

return parameters.getParameterSpec(ECParameterSpec.class);

} catch (InvalidParameterSpecException ipse) {

return null;

}

}

public static ECParameterSpec getECParameterSpec(Provider p, String name) {

AlgorithmParameters parameters = getECParameters(p);

try {

parameters.init(new ECGenParameterSpec(name));

return parameters.getParameterSpec(ECParameterSpec.class);

} catch (InvalidParameterSpecException ipse) {

return null;

}

}

public static ECParameterSpec getECParameterSpec(Provider p, int keySize) {

AlgorithmParameters parameters = getECParameters(p);

try {

parameters.init(new ECKeySizeParameterSpec(keySize));

return parameters.getParameterSpec(ECParameterSpec.class);

} catch (InvalidParameterSpecException ipse) {

return null;

}

}

public static String getCurveName(Provider p, ECParameterSpec spec) {

ECGenParameterSpec nameSpec;

AlgorithmParameters parameters = getECParameters(p);

try {

parameters.init(spec);

nameSpec = parameters.getParameterSpec(ECGenParameterSpec.class);

} catch (InvalidParameterSpecException ipse) {

return null;

}

if (nameSpec == null) {

return null;

}

return nameSpec.getName();

}

public static boolean equals(ECParameterSpec spec1, ECParameterSpec spec2) {

if (spec1 == spec2) {

return true;

}

if (spec1 == null || spec2 == null) {

return false;

}

return (spec1.getCofactor() == spec2.getCofactor() &&

spec1.getOrder().equals(spec2.getOrder()) &&

spec1.getCurve().equals(spec2.getCurve()) &&

spec1.getGenerator().equals(spec2.getGenerator()));

}

// Convert the concatenation R and S in into their DER encoding

public static byte[] encodeSignature(byte[] signature) throws SignatureException {

try {

int n = signature.length >> 1;

byte[] bytes = new byte[n];

System.arraycopy(signature, 0, bytes, 0, n);

BigInteger r = new BigInteger(1, bytes);

System.arraycopy(signature, n, bytes, 0, n);

BigInteger s = new BigInteger(1, bytes);

DerOutputStream out = new DerOutputStream(signature.length + 10);

out.putInteger(r);

out.putInteger(s);

DerValue result =

new DerValue(DerValue.tag_Sequence, out.toByteArray());

return result.toByteArray();

} catch (Exception e) {

throw new SignatureException("Could not encode signature", e);

}

}

// Convert the DER encoding of R and S into a concatenation of R and S

public static byte[] decodeSignature(byte[] sig) throws SignatureException {

try {

// Enforce strict DER checking for signatures

DerInputStream in = new DerInputStream(sig, 0, sig.length, false);

DerValue[] values = in.getSequence(2);

// check number of components in the read sequence

// and trailing data

if ((values.length != 2) || (in.available() != 0)) {

throw new IOException("Invalid encoding for signature");

}

BigInteger r = values[0].getPositiveBigInteger();

BigInteger s = values[1].getPositiveBigInteger();

// trim leading zeroes

byte[] rBytes = trimZeroes(r.toByteArray());

byte[] sBytes = trimZeroes(s.toByteArray());

int k = Math.max(rBytes.length, sBytes.length);

// r and s each occupy half the array

byte[] result = new byte[k << 1];

System.arraycopy(rBytes, 0, result, k - rBytes.length,

rBytes.length);

System.arraycopy(sBytes, 0, result, result.length - sBytes.length,

sBytes.length);

return result;

} catch (Exception e) {

throw new SignatureException("Invalid encoding for signature", e);

}

}

private ECUtil() {}