public virtual BigInteger[] GenerateSignature(byte[] message)
{
AsymmetricCipherKeyPair pair;
if (!this.forSigning)
{
throw new InvalidOperationException("not initialised for signing");
}
BigInteger n = ((ECPrivateKeyParameters)this.key).Parameters.N;
int bitLength = n.BitLength;
BigInteger integer2 = new BigInteger(1, message);
int num2 = integer2.BitLength;
ECPrivateKeyParameters key = (ECPrivateKeyParameters)this.key;
if (num2 > bitLength)
{
throw new DataLengthException("input too large for ECNR key.");
}
BigInteger integer3 = null;
BigInteger integer4 = null;
do
{
ECKeyPairGenerator generator = new ECKeyPairGenerator();
generator.Init(new ECKeyGenerationParameters(key.Parameters, this.random));
pair = generator.GenerateKeyPair();
ECPublicKeyParameters @public = (ECPublicKeyParameters)pair.Public;
integer3 = @public.Q.AffineXCoord.ToBigInteger().Add(integer2).Mod(n);
}while (integer3.SignValue == 0);
BigInteger d = key.D;
integer4 = ((ECPrivateKeyParameters)pair.Private).D.Subtract(integer3.Multiply(d)).Mod(n);
return(new BigInteger[] { integer3, integer4 });
}
public override void PerformTest()
{
StaticTest();
BigInteger n = new BigInteger("6277101735386680763835789423176059013767194773182842284081");
FpCurve curve = new FpCurve(
new BigInteger("6277101735386680763835789423207666416083908700390324961279"), // q
new BigInteger("fffffffffffffffffffffffffffffffefffffffffffffffc", 16), // a
new BigInteger("64210519e59c80e70fa7e9ab72243049feb8deecc146b9b1", 16), // b
n, BigInteger.One);
ECDomainParameters parameters = new ECDomainParameters(
curve,
curve.DecodePoint(Hex.Decode("03188da80eb03090f67cbf20eb43a18800f4ff0afd82ff1012")), // G
n, BigInteger.One);
ECKeyPairGenerator eGen = new ECKeyPairGenerator();
KeyGenerationParameters gParam = new ECKeyGenerationParameters(parameters, new SecureRandom());
eGen.Init(gParam);
AsymmetricCipherKeyPair p1 = eGen.GenerateKeyPair();
AsymmetricCipherKeyPair p2 = eGen.GenerateKeyPair();
DoTest(p1, p2);
}
public static AsymmetricCipherKeyPair GenerateECKeyPair(SecureRandom random, ECDomainParameters ecParams)
{
ECKeyPairGenerator keyPairGenerator = new ECKeyPairGenerator();
keyPairGenerator.Init(new ECKeyGenerationParameters(ecParams, random));
return(keyPairGenerator.GenerateKeyPair());
}
private string ECC_GY = "BC3736A2F4F6779C59BDCEE36B692153D0A9877CC62A474002DF32E52139F0A0"; //坐标yG
public KeyParameter KeyGenerator()
{
var SM2_ECC_P = new BigInteger(ECC_P, 16);
var SM2_ECC_A = new BigInteger(ECC_A, 16);
var SM2_ECC_B = new BigInteger(ECC_B, 16);
var SM2_ECC_N = new BigInteger(ECC_N, 16);
var SM2_ECC_H = BigInteger.One;
var SM2_ECC_GX = new BigInteger(ECC_GX, 16);
var SM2_ECC_GY = new BigInteger(ECC_GY, 16);
ECCurve curve = new FpCurve(SM2_ECC_P, SM2_ECC_A, SM2_ECC_B, SM2_ECC_N, SM2_ECC_H);
var g = curve.CreatePoint(SM2_ECC_GX, SM2_ECC_GY);
var domainParams = new ECDomainParameters(curve, g, SM2_ECC_N);
var keyPairGenerator = new ECKeyPairGenerator();
var aKeyGenParams = new ECKeyGenerationParameters(domainParams, new SecureRandom());
keyPairGenerator.Init(aKeyGenParams);
var aKp = keyPairGenerator.GenerateKeyPair();
var subjectPublicKeyInfo = SubjectPublicKeyInfoFactory.CreateSubjectPublicKeyInfo(aKp.Public);
var privateKeyInfo = PrivateKeyInfoFactory.CreatePrivateKeyInfo(aKp.Private);
var pk = Hex.ToHexString(privateKeyInfo.GetEncoded());
return(new KeyParameter
{
PrivateKey = Base64.ToBase64String(privateKeyInfo.GetEncoded()),
PublicKey = Base64.ToBase64String(subjectPublicKeyInfo.GetEncoded())
});
}
private void ECDH_GenerateEphemeral(EncryptMessage msg)
{
CBORObject epk = CBORObject.NewMap();
if (_mKey.AsString("kty") == "EC")
{
X9ECParameters p = NistNamedCurves.GetByName(_mKey.AsString("crv"));
ECDomainParameters parameters = new ECDomainParameters(p.Curve, p.G, p.N, p.H);
ECKeyPairGenerator pGen = new ECKeyPairGenerator();
ECKeyGenerationParameters genParam = new ECKeyGenerationParameters(parameters, Message.s_PRNG);
pGen.Init(genParam);
AsymmetricCipherKeyPair p1 = pGen.GenerateKeyPair();
epk.Add("kty", "EC");
epk.Add("crv", _mKey.AsString("crv"));
ECPublicKeyParameters priv = (ECPublicKeyParameters)p1.Public;
epk.Add("x", priv.Q.Normalize().XCoord.ToBigInteger().ToByteArrayUnsigned());
epk.Add("y", priv.Q.Normalize().YCoord.ToBigInteger().ToByteArrayUnsigned());
}
else if (_mKey.AsString("kty") == "OKP")
{
switch (_mKey.AsString("crv"))
{
case "X25519":
Ed25519KeyPairGenerator pGen = new Ed25519KeyPairGenerator();
Ed25519KeyGenerationParameters genParam = new Ed25519KeyGenerationParameters(Message.s_PRNG);
pGen.Init(genParam);
AsymmetricCipherKeyPair p1 = pGen.GenerateKeyPair();
Ed25519PublicKeyParameters pub = (Ed25519PublicKeyParameters)p1.Public;
epk.Add("kty", "OKP");
epk.Add("crv", "X25519");
epk.Add("x", pub.GetEncoded());
break;
default:
throw new JoseException("Unknown OPK curve");
}
}
else
{
throw new JoseException("Internal Error");
}
if (msg.FindAttribute(CBORObject.FromObject("epk"), PROTECTED) != null)
{
msg.AddAttribute(CBORObject.FromObject("epk"), epk, PROTECTED);
}
else if (msg.FindAttribute(CBORObject.FromObject("epk"), PROTECTED) != null)
{
msg.AddAttribute(CBORObject.FromObject("epk"), epk, PROTECTED);
}
else
{
AddAttribute("epk", epk, UNPROTECTED);
}
}
public static CertPrivateKey GenerateEcPrivateKey(int bits)
{
// From:
// http://www.bouncycastle.org/wiki/display/JA1/Elliptic+Curve+Key+Pair+Generation+and+Key+Factories
// var csr = new Pkcs10CertificationRequest()
// string curveName;
// switch (bits)
// {
// case 256:
// curveName = "P-256";
// break;
// case 384:
// curveName = "P-384";
// break;
// default:
// throw new ArgumentException("bit length is unsupported or unknown", nameof(bits));
// }
// var ecParamSpec = ECNamedCurveTable.GetByName(curveName);
// From:
// https://www.codeproject.com/Tips/1150485/Csharp-Elliptical-Curve-Cryptography-with-Bouncy-C
var ecKpg = new ECKeyPairGenerator("ECDSA");
ecKpg.Init(new KeyGenerationParameters(new SecureRandom(), bits));
var ecKp = ecKpg.GenerateKeyPair();
return(new CertPrivateKey
{
KeyPair = ecKp
});
}
public static PemKeyPair GenerateKeyPair()
{
String privateKey = String.Empty;
String publicKey = String.Empty;
X9ECParameters ecParameters = ECNamedCurveTable.GetByName("secp256k1");
ECKeyPairGenerator keyGenerator = new ECKeyPairGenerator();
keyGenerator.Init(new ECKeyGenerationParameters(new ECDomainParameters(ecParameters.Curve, ecParameters.G, ecParameters.N, ecParameters.H), new SecureRandom()));
AsymmetricCipherKeyPair keyPair = keyGenerator.GenerateKeyPair();
using (TextWriter writer = new StringWriter())
{
PemWriter pemWriter = new PemWriter(writer);
pemWriter.WriteObject(keyPair.Private);
pemWriter.Writer.Flush();
privateKey = writer.ToString();
}
using (TextWriter writer = new StringWriter())
{
PemWriter pemWriter = new PemWriter(writer);
pemWriter.WriteObject(keyPair.Public);
pemWriter.Writer.Flush();
publicKey = writer.ToString();
}
return(new PemKeyPair(publicKey, privateKey));
}
public static Task <ECDSAKeyPair> Generate()
{
return(Task.Run(() =>
{
ECKeyGenerationParameters param = new ECKeyGenerationParameters(getDomain(), new Org.BouncyCastle.Security.SecureRandom());
var gen = new ECKeyPairGenerator("EC");
gen.Init(param);
var pair = gen.GenerateKeyPair();
var prv = (pair.Private as ECPrivateKeyParameters).D.ToByteArrayUnsigned();
if (prv.Length != 32)
{
var temp = new byte[32];
Array.Clear(temp, 0, 32 - prv.Length);
prv.CopyTo(temp, 32 - prv.Length);
prv = temp;
Insight.Track("Generate ECDSAKeyPair: prv.Length != 32");
}
return new ECDSAKeyPair()
{
PublicKeyData = (pair.Public as ECPublicKeyParameters).Q.GetEncoded(),
PrivateKeyData = prv
};
}));
}
private void button1_Click(object sender, EventArgs e)
{
ECKeyGenerationParameters keyGenerationParameters = new ECKeyGenerationParameters(parameters, random);
ECKeyPairGenerator keygenerator = new ECKeyPairGenerator("ECGOST3410");
keygenerator.Init(keyGenerationParameters);
AsymmetricCipherKeyPair pair = keygenerator.GenerateKeyPair();
ECPrivateKeyParameters validatorPrivate = (ECPrivateKeyParameters)pair.Private;
ECPublicKeyParameters validatorPublic = (ECPublicKeyParameters)pair.Public;
/*validatorPrivate = new ECPrivateKeyParameters(
* "ECGOST3410",
* new BigInteger("55441196065363246126355624130324183196576709222340016572108097750006097525544"), // d
* parameters);
*
* validatorPublic = new ECPublicKeyParameters(
* "ECGOST3410",
* new FpPoint(curve,
* new FpFieldElement(mod_p, new BigInteger("57520216126176808443631405023338071176630104906313632182896741342206604859403")), // x
* new FpFieldElement(mod_p, new BigInteger("17614944419213781543809391949654080031942662045363639260709847859438286763994"))), // y
* parameters);
*/
tbValPrivate.Text = validatorPrivate.D.ToString(16);
tbValPublicX.Text = validatorPublic.Q.X.ToBigInteger().ToString(16);
tbValPublicY.Text = validatorPublic.Q.Y.ToBigInteger().ToString(16);
}
/// <summary>
/// get csr
/// </summary>
/// <param name="issuerName"></param>
/// <returns></returns>
public static Tuple <string, AsymmetricKeyParameter> GetCsr(string issuerName)
{
//generate KeyPair
var keyGenerator = new ECKeyPairGenerator();
ECKeyGenerationParameters pa = new ECKeyGenerationParameters(SecObjectIdentifiers.SecP256r1, new SecureRandom());
keyGenerator.Init(pa);
var keypair = keyGenerator.GenerateKeyPair();
//domain name of CSR file
X509Name principal = new X509Name(string.Format("CN={0},OU=client,O=BSN", string.IsNullOrEmpty(issuerName) ? "test02@app0001202004161020152918451" : issuerName));
//load public key
SubjectPublicKeyInfo subjectPublicKeyInfo = SubjectPublicKeyInfoFactory.CreateSubjectPublicKeyInfo(keypair.Public);
CertificationRequestInfo info = new CertificationRequestInfo(principal, subjectPublicKeyInfo, new DerSet());
//signature
byte[] bs = ECDSAHelper.CsrSignData(info.GetEncoded(Asn1Encodable.Der), keypair.Private, pa.DomainParameters.N);
//generate csr object
Pkcs10CertificationRequest p10 = new Pkcs10CertificationRequest(new CertificationRequest
(info, new AlgorithmIdentifier(X9ObjectIdentifiers.ECDsaWithSha256),
new DerBitString(bs)).GetEncoded());
//generate csr string
Org.BouncyCastle.Utilities.IO.Pem.PemObject pemCSR = new Org.BouncyCastle.Utilities.IO.Pem.PemObject("CERTIFICATE REQUEST", p10.GetEncoded());
StringWriter str = new StringWriter();
Org.BouncyCastle.Utilities.IO.Pem.PemWriter pemCsr = new Org.BouncyCastle.Utilities.IO.Pem.PemWriter(str);
pemCsr.WriteObject(pemCSR);
pemCsr.Writer.Flush();
return(new Tuple <string, AsymmetricKeyParameter>(str.ToString(), keypair.Private));
}
private static AsymmetricCipherKeyPair GenerateKeyPair(ECDomainParameters domainParams, string x)
{
ECKeyPairGenerator kpg = new ECKeyPairGenerator();
kpg.Init(new ECKeyGenerationParameters(domainParams, new TestRandomBigInteger(x, 16)));
return(kpg.GenerateKeyPair());
}
//Method to generate RSA Key Pair
#region RSA KeyPair Generation Method
public static AsymmetricCipherKeyPair GetKeyPair(string type)
{
//bouncy Castle librray Method to generate RSA Key Pair
if (type == "RSA")
{
SecureRandom secureRandom = new SecureRandom();
var keyGenerationParameters = new KeyGenerationParameters(secureRandom, RsaKeySize);
var keyPairGenerator = new RsaKeyPairGenerator();
keyPairGenerator.Init(keyGenerationParameters);
//returning keys
AsymmetricCipherKeyPair keypair = keyPairGenerator.GenerateKeyPair();
return(keypair);
}
else
{
SecureRandom secureRandom = new SecureRandom();
ECKeyPairGenerator gen = new ECKeyPairGenerator("ECDSA");
//selecting the Secp256k1 curve
DerObjectIdentifier oid = SecObjectIdentifiers.SecP256k1;
X9ECParameters ecPs = CustomNamedCurves.GetByOid(oid);
ECDomainParameters ec = new ECDomainParameters(
ecPs.Curve, ecPs.G, ecPs.N, ecPs.H, ecPs.GetSeed());
ECKeyGenerationParameters ecP = new ECKeyGenerationParameters(ec, secureRandom);
gen.Init(ecP);
return(gen.GenerateKeyPair());
}
}
public static X509Certificate2 GenerateSelfSignedCertEcdsa()
{
var randomGenerator = new CryptoApiRandomGenerator();
var random = new SecureRandom(randomGenerator);
var certificateGenerator = new X509V3CertificateGenerator();
var serialNumber =
BigIntegers.CreateRandomInRange(
BigInteger.One, BigInteger.ValueOf(Int64.MaxValue), random);
certificateGenerator.SetSerialNumber(serialNumber);
const string signatureAlgorithm = "SHA256withECDSA";
certificateGenerator.SetSignatureAlgorithm(signatureAlgorithm);
var subjectDN = new X509Name("CN=simpletorrent");
var issuerDN = subjectDN;
certificateGenerator.SetIssuerDN(issuerDN);
certificateGenerator.SetSubjectDN(subjectDN);
var notBefore = DateTime.UtcNow.Date.AddHours(-24);
var notAfter = notBefore.AddYears(1000);
certificateGenerator.SetNotBefore(notBefore);
certificateGenerator.SetNotAfter(notAfter);
ECKeyGenerationParameters genParam
= new ECKeyGenerationParameters(X962NamedCurves.GetOid("prime256v1"), random);
var keyPairGenerator = new ECKeyPairGenerator();
keyPairGenerator.Init(genParam);
var subjectKeyPair = keyPairGenerator.GenerateKeyPair();
certificateGenerator.SetPublicKey(subjectKeyPair.Public);
var issuerKeyPair = subjectKeyPair;
var certificate = certificateGenerator.Generate(issuerKeyPair.Private, random);
var store = new Pkcs12Store();
string friendlyName = certificate.SubjectDN.ToString();
var certificateEntry = new X509CertificateEntry(certificate);
store.SetCertificateEntry(friendlyName, certificateEntry);
store.SetKeyEntry(friendlyName, new AsymmetricKeyEntry(subjectKeyPair.Private), new[] { certificateEntry });
string password = "******";
var stream = new MemoryStream();
store.Save(stream, password.ToCharArray(), random);
//mono bug #1660 fix -> convert to definite-length encoding
byte[] pfx = Pkcs12Utilities.ConvertToDefiniteLength(stream.ToArray(), password.ToCharArray());
var convertedCertificate =
new X509Certificate2(
pfx, password,
X509KeyStorageFlags.PersistKeySet | X509KeyStorageFlags.Exportable);
return(convertedCertificate);
}
public SM2CryptoServiceProvider()
{
ecc_param = sm2_param;
ecc_p = new BigInteger(sm2_param[0], 16);
ecc_a = new BigInteger(sm2_param[1], 16);
ecc_b = new BigInteger(sm2_param[2], 16);
ecc_n = new BigInteger(sm2_param[3], 16);
ecc_gx = new BigInteger(sm2_param[4], 16);
ecc_gy = new BigInteger(sm2_param[5], 16);
//ecc_curve = new FpCurve(ecc_p, ecc_a, ecc_b, ecc_gx, ecc_gy);
var ecc_gx_fieldelement = new FpFieldElement(ecc_p, ecc_gx); //ecc_curve.FromBigInteger(ecc_gx);//
var ecc_gy_fieldelement = new FpFieldElement(ecc_p, ecc_gy); // ecc_curve.FromBigInteger(ecc_gy);//
ecc_curve = new FpCurve(ecc_p, ecc_a, ecc_b); // ecc_curve.CreatePoint(ecc_gx, ecc_gy);//
ecc_point_g = new FpPoint(ecc_curve, ecc_gx_fieldelement, ecc_gy_fieldelement);
ecc_bc_spec = new ECDomainParameters(ecc_curve, ecc_point_g, ecc_n);
var ecc_ecgenparam = new ECKeyGenerationParameters(ecc_bc_spec, new SecureRandom());
ecc_key_pair_generator = new ECKeyPairGenerator();
ecc_key_pair_generator.Init(ecc_ecgenparam);
}
// CLIENT TO SERVER STUFF
public static AsymmetricCipherKeyPair GenerateClientKey()
{
var generator = new ECKeyPairGenerator("ECDH");
generator.Init(new ECKeyGenerationParameters(new DerObjectIdentifier("1.3.132.0.34"), SecureRandom.GetInstance("SHA256PRNG")));
return(generator.GenerateKeyPair());
}
internal static AsymmetricCipherKeyPair Create(int pkSize, string pkAlgo)
{
SecureRandom random = new SecureRandom(new CryptoApiRandomGenerator());
KeyGenerationParameters genParam = new KeyGenerationParameters(random, pkSize);
AsymmetricCipherKeyPair keyPair;
switch (pkAlgo)
{
case "RSA":
RsaKeyPairGenerator rsaGenerator = new RsaKeyPairGenerator();
rsaGenerator.Init(genParam);
keyPair = rsaGenerator.GenerateKeyPair();
break;
case "DSA":
DsaKeyPairGenerator dsaGenerator = new DsaKeyPairGenerator();
dsaGenerator.Init(genParam);
keyPair = dsaGenerator.GenerateKeyPair();
break;
case "ECDSA":
ECKeyPairGenerator ecGenerator = new ECKeyPairGenerator(pkAlgo);
ecGenerator.Init(genParam);
keyPair = ecGenerator.GenerateKeyPair();
break;
default:
throw new ArgumentException("Algorithm not supported", pkAlgo);
}
return(keyPair);
}
public static string[] GenerateKeys(byte[] seed)
{
ECKeyPairGenerator gen = new ECKeyPairGenerator();
var secureRandom = new SecureRandom();
secureRandom.SetSeed(seed);
var keyGenParam = new ECKeyGenerationParameters(domain, secureRandom);
gen.Init(keyGenParam);
AsymmetricCipherKeyPair keyPair = gen.GenerateKeyPair();
ECPrivateKeyParameters privateParams = (ECPrivateKeyParameters)keyPair.Private;
ECPublicKeyParameters publicParams = (ECPublicKeyParameters)keyPair.Public;
BigInteger privateKey = privateParams.D;
BigInteger publicKey = new BigInteger(publicParams.Q.GetEncoded());
BigInteger publicKeyCompressed = new BigInteger(publicParams.Q.GetEncoded(true));
string[] walletKeyPair = new string[2];
walletKeyPair[0] = privateKey.ToString(16);
walletKeyPair[1] = publicKey.ToString(16);
return(walletKeyPair);
}
public ECKey()
{
var generator = new ECKeyPairGenerator("EC");
generator.Init(new ECKeyGenerationParameters(CURVE, _secureRandom));
var pair = generator.GenerateKeyPair();
_Key = (ECPrivateKeyParameters)pair.Private;
}
private SM2(bool sm2Test)
{
this.sm2Test = sm2Test;
cipher_sm = new Cipher();
//if (sm2Test)//如果为对
// ecc_param = sm2_test_param;//使用国际密码管理局给的测试参数
//else
ecc_param = sm2_param; //否则使用国密标准256位曲线参数
ECFieldElement ecc_gx_fieldelement;
ECFieldElement ecc_gy_fieldelement;
ecc_p = new BigInteger(ecc_param[0], 16);
ecc_a = new BigInteger(ecc_param[1], 16);
ecc_b = new BigInteger(ecc_param[2], 16);
ecc_n = new BigInteger(ecc_param[3], 16);
ecc_gx = new BigInteger(ecc_param[4], 16);
ecc_gy = new BigInteger(ecc_param[5], 16);
ecc_gx_fieldelement = new FpFieldElement(ecc_p, ecc_gx); //选定椭圆曲线上基点G的x坐标
ecc_gy_fieldelement = new FpFieldElement(ecc_p, ecc_gy); //选定椭圆曲线上基点G的坐标
ecc_curve = new FpCurve(ecc_p, ecc_a, ecc_b); //生成椭圆曲线
ecc_point_g = new FpPoint(ecc_curve, ecc_gx_fieldelement, ecc_gy_fieldelement); //生成基点G
ecc_bc_spec = new ECDomainParameters(ecc_curve, ecc_point_g, ecc_n); //椭圆曲线,g点坐标,阶n.
ECKeyGenerationParameters ecc_ecgenparam;
ecc_ecgenparam = new ECKeyGenerationParameters(ecc_bc_spec, new SecureRandom());
ecc_key_pair_generator = new ECKeyPairGenerator();
ecc_key_pair_generator.Init(ecc_ecgenparam);
}
/// <summary>
/// Starts key exchange algorithm
/// </summary>
/// <param name="session">The session.</param>
/// <param name="message">Key exchange init message.</param>
public override void Start(Session session, KeyExchangeInitMessage message)
{
base.Start(session, message);
Session.RegisterMessage("SSH_MSG_KEX_ECDH_REPLY");
Session.KeyExchangeEcdhReplyMessageReceived += Session_KeyExchangeEcdhReplyMessageReceived;
DomainParameters = new ECDomainParameters(CurveParameter.Curve,
CurveParameter.G,
CurveParameter.N,
CurveParameter.H,
CurveParameter.GetSeed());
var g = new ECKeyPairGenerator();
g.Init(new ECKeyGenerationParameters(DomainParameters, new SecureRandom()));
var aKeyPair = g.GenerateKeyPair();
KeyAgreement = new ECDHCBasicAgreement();
KeyAgreement.Init(aKeyPair.Private);
_clientExchangeValue = ((ECPublicKeyParameters)aKeyPair.Public).Q.GetEncoded();
SendMessage(new KeyExchangeEcdhInitMessage(_clientExchangeValue));
}
public static void StartGenerateKeypair(byte[] seed, GenCompleteEventHandler evt)
{
Thread genThread = new Thread(new ParameterizedThreadStart((o) =>
{
//create a random number generator using SHA512 algorithm
SecureRandom rnd = SecureRandom.GetInstance(RANDOM_ALGO);
rnd.SetSeed(seed);
X9ECParameters curve = TeleTrusTNamedCurves.GetByName(ECDSA_CURVE);
ECDomainParameters domain = new ECDomainParameters(curve.Curve, curve.G, curve.N);
//create the parameters for initializing the key pair generator using the brainpoolp384t1 curve
ECKeyGenerationParameters parms = new ECKeyGenerationParameters(domain, rnd);
//create and initialize the key pair generator
ECKeyPairGenerator gen = new ECKeyPairGenerator("ECDSA");
gen.Init(parms);
//generate the key pair
AsymmetricCipherKeyPair kp = gen.GenerateKeyPair();
//trigger the event
Xamarin.Forms.Device.BeginInvokeOnMainThread(() =>
{
if (evt != null)
{
evt(kp);
}
});
}));
genThread.Start();
}
private SM2()
{
EccParam = CurveParameter;
EccP = new BigInteger(EccParam[0], 16);
EccA = new BigInteger(EccParam[1], 16);
EccB = new BigInteger(EccParam[2], 16);
EccN = new BigInteger(EccParam[3], 16);
EccGx = new BigInteger(EccParam[4], 16);
EccGy = new BigInteger(EccParam[5], 16);
ECFieldElement ecc_gx_fieldelement = new FpFieldElement(EccP, EccGx);
ECFieldElement ecc_gy_fieldelement = new FpFieldElement(EccP, EccGy);
EccCurve = new FpCurve(EccP, EccA, EccB);
EccPointG = new FpPoint(EccCurve, ecc_gx_fieldelement, ecc_gy_fieldelement);
EccBcSpec = new ECDomainParameters(EccCurve, EccPointG, EccN);
ECKeyGenerationParameters ecc_ecgenparam;
ecc_ecgenparam = new ECKeyGenerationParameters(EccBcSpec, new SecureRandom());
EccKeyPairGenerator = new ECKeyPairGenerator();
EccKeyPairGenerator.Init(ecc_ecgenparam);
}
public void TestECDHBasicAgreementCofactor()
{
SecureRandom random = new SecureRandom();
X9ECParameters x9 = CustomNamedCurves.GetByName("curve25519");
ECDomainParameters ec = new ECDomainParameters(x9.Curve, x9.G, x9.N, x9.H, x9.GetSeed());
ECKeyPairGenerator kpg = new ECKeyPairGenerator();
kpg.Init(new ECKeyGenerationParameters(ec, random));
AsymmetricCipherKeyPair p1 = kpg.GenerateKeyPair();
AsymmetricCipherKeyPair p2 = kpg.GenerateKeyPair();
IBasicAgreement e1 = new ECDHBasicAgreement();
IBasicAgreement e2 = new ECDHBasicAgreement();
e1.Init(p1.Private);
e2.Init(p2.Private);
BigInteger k1 = e1.CalculateAgreement(p2.Public);
BigInteger k2 = e2.CalculateAgreement(p1.Public);
if (!k1.Equals(k2))
{
Fail("calculated agreement test failed");
}
}
private static void GenerateIdentity(int keySize = 256)
{
ECKeyPairGenerator gen = new ECKeyPairGenerator();
SecureRandom secureRandom = new SecureRandom();
KeyGenerationParameters keyGenParam =
new KeyGenerationParameters(secureRandom, keySize);
gen.Init(keyGenParam);
var keyPair = gen.GenerateKeyPair();
BigInteger privateKey = ((ECPrivateKeyParameters)keyPair.Private).D;
Console.WriteLine("Private key (hex): " + privateKey.ToString(16));
Console.WriteLine("Private key: " + privateKey.ToString(10));
Console.WriteLine("Password for private key encryption:");
var password = Console.ReadLine();
var encryptedPrivateKey = CryptographyUtilities.Encrypt(privateKey.ToByteArray(), password);
StorageFileProvider <string> .SetModel(Constants.WalletEncryptedPrivateKeyFilePath, encryptedPrivateKey);
ECPoint pubKey = ((ECPublicKeyParameters)keyPair.Public).Q;
string pubKeyCompressed = CryptographyUtilities.EncodeECPointHexCompressed(pubKey);
Console.WriteLine("Public key (compressed): " + pubKeyCompressed);
string addr = CryptographyUtilities.CalcRipeMD160(pubKeyCompressed);
Console.WriteLine("Blockchain address: " + addr);
}
private static AsymmetricCipherKeyPair GenerateEllipticCurveKeyPair(SecureRandom secureRandom)
{
var keyPairGenerator = new ECKeyPairGenerator();
keyPairGenerator.Init(new ECKeyGenerationParameters(SecObjectIdentifiers.SecP256r1, secureRandom));
return(keyPairGenerator.GenerateKeyPair());
}
public void TestECMqvRandom()
{
var random = new SecureRandom();
var curve = new FPCurve(
new BigInteger("883423532389192164791648750360308885314476597252960362792450860609699839"), // q
new BigInteger("7fffffffffffffffffffffff7fffffffffff8000000000007ffffffffffc", 16), // a
new BigInteger("6b016c3bdcf18941d0d654921475ca71a9db2fb27d1d37796185c2942c0a", 16)); // b
var parameters = new ECDomainParameters(
curve,
curve.DecodePoint(Hex.Decode("020ffa963cdca8816ccc33b8642bedf905c3d358573d3f27fbbd3b3cb9aaaf")), // G
new BigInteger("883423532389192164791648750360308884807550341691627752275345424702807307")); // n
var pGen = new ECKeyPairGenerator();
pGen.Init(new ECKeyGenerationParameters(parameters, random));
// Pre-established key pairs
IAsymmetricCipherKeyPair u1 = pGen.GenerateKeyPair();
IAsymmetricCipherKeyPair v1 = pGen.GenerateKeyPair();
// Ephemeral key pairs
IAsymmetricCipherKeyPair u2 = pGen.GenerateKeyPair();
IAsymmetricCipherKeyPair v2 = pGen.GenerateKeyPair();
IBigInteger x = CalculateAgreement(u1, u2, v1, v2);
if (x == null)
{
Fail("MQV Test Vector (random) agreement failed");
}
}
private SM2()
{
ecc_param = sm2_param;
ECFieldElement ecc_gx_fieldelement;
ECFieldElement ecc_gy_fieldelement;
ecc_p = new BigInteger(ecc_param[0], 16);
ecc_a = new BigInteger(ecc_param[1], 16);
ecc_b = new BigInteger(ecc_param[2], 16);
ecc_n = new BigInteger(ecc_param[3], 16);
ecc_gx = new BigInteger(ecc_param[4], 16);
ecc_gy = new BigInteger(ecc_param[5], 16);
ecc_gx_fieldelement = new FpFieldElement(ecc_p, ecc_gx);
ecc_gy_fieldelement = new FpFieldElement(ecc_p, ecc_gy);
ecc_curve = new FpCurve(ecc_p, ecc_a, ecc_b);
ecc_point_g = new FpPoint(ecc_curve, ecc_gx_fieldelement, ecc_gy_fieldelement);
ecc_bc_spec = new ECDomainParameters(ecc_curve, ecc_point_g, ecc_n);
ECKeyGenerationParameters ecc_ecgenparam;
ecc_ecgenparam = new ECKeyGenerationParameters(ecc_bc_spec, new SecureRandom());
ecc_key_pair_generator = new ECKeyPairGenerator();
ecc_key_pair_generator.Init(ecc_ecgenparam);
}
public void TestECDsaP256Sha256WithGeneratedKey()
{
var secureRandom = new SecureRandom();
X9ECParameters p = NistNamedCurves.GetByName("P-256");
var parameters = new ECDomainParameters(p.Curve, p.G, p.N, p.H);
var ecParams = new ECKeyGenerationParameters(parameters, secureRandom);
var ecGen = new ECKeyPairGenerator("ECDSA");
ecGen.Init(ecParams);
var pairKey = ecGen.GenerateKeyPair();
var priKey = pairKey.Private as ECPrivateKeyParameters;
byte[] m = Hex.Decode("1BD4ED430B0F384B4E8D458EFF1A8A553286D7AC21CB2F6806172EF5F94A06AD");
var dsa = new ECDsaSigner();
dsa.Init(true, new ParametersWithRandom(priKey, secureRandom));
IBigInteger[] sig = dsa.GenerateSignature(m);
// Verify the signature
var pubKey = pairKey.Public as ECPublicKeyParameters;
dsa.Init(false, pubKey);
if (!dsa.VerifySignature(m, sig[0], sig[1]))
{
Fail("signature fails");
}
}
private byte[] NewKey(int keyLength, object externalPubKey, IDictionary <string, object> header)
{
// create ECDH-ES content encryption key
// generate keypair for ECDH
SecureRandom rnd = new SecureRandom();
var keyGen = new ECKeyPairGenerator();
var domainParams = new ECDomainParameters(_brainpoolP256R1.Curve, _brainpoolP256R1.G, _brainpoolP256R1.N, _brainpoolP256R1.H);
var genParam = new ECKeyGenerationParameters(domainParams, rnd);
keyGen.Init(genParam);
var ecdhKeyPair = keyGen.GenerateKeyPair();
var ephemeralPubkey = (ECPublicKeyParameters)ecdhKeyPair.Public;
var ephemeralPrvKey = (ECPrivateKeyParameters)ecdhKeyPair.Private;
header["epk"] = new Dictionary <string, object> {
["kty"] = "EC",
["x"] = Base64Url.Encode(ephemeralPubkey.Q.XCoord.GetEncoded()),
["y"] = Base64Url.Encode(ephemeralPubkey.Q.YCoord.GetEncoded()),
["crv"] = CRV
};
var deriveKey = DeriveKey(header, keyLength, externalPubKey as ECPublicKeyParameters, ephemeralPrvKey);
//Console.Out.WriteLine($"dervied key (cek): {VAU.ByteArrayToHexString(deriveKey)}");
return(deriveKey);
}
static AsymmetricCipherKeyPair GenerateKeyPair()
{
Console.WriteLine("Generating signature keys...");
var curve = ECNamedCurveTable.GetByName("secp256k1");
var domainParams = new ECDomainParameters(curve.Curve, curve.G, curve.N, curve.H, curve.GetSeed());
var secureRandom = new SecureRandom();
var keyParams = new ECKeyGenerationParameters(domainParams, secureRandom);
var generator = new ECKeyPairGenerator("ECDSA");
generator.Init(keyParams);
var keyPair = generator.GenerateKeyPair();
var privateKey = keyPair.Private as ECPrivateKeyParameters;
var publicKey = keyPair.Public as ECPublicKeyParameters;
var strPrivKey = ToHex(privateKey.D.ToByteArrayUnsigned());
var strPubKey = ToHex(publicKey.Q.GetEncoded());
Console.WriteLine($"{strPrivKey.Length} bytes Private key: {strPrivKey}");
Console.WriteLine($"{strPubKey.Length} bytes Public key: {strPubKey}");
Console.WriteLine("Done generating signature keys!");
return(keyPair);
}