/// <summary>
/// Initialises a new instance of the <see cref="KeyRingParameters"/> class.
/// </summary>
/// <param name="keyLength">
/// The keypair length.
/// </param>
/// <param name="type">
/// Key generation type.
/// </param>
public KeyRingParameters(int keyLength = 1024, string type = "RSA")
{
if (type == "RSA")
{
this.KeyParams = new RsaKeyGenerationParameters(
BigInteger.ValueOf(0x10001),
new SecureRandom(),
keyLength,
80);
}
else if (type == "DSA")
{
var pg = new DsaParametersGenerator();
pg.Init(keyLength, 80, new SecureRandom());
var dsaParam = pg.GenerateParameters();
this.KeyParams = new DsaKeyGenerationParameters(new SecureRandom(), dsaParam);
}
else if (type == "ELGAMAL")
{
var epg = new ElGamalParametersGenerator();
epg.Init(keyLength, 20, new SecureRandom());
var elgamalParams = epg.GenerateParameters();
this.KeyParams = new ElGamalKeyGenerationParameters(new SecureRandom(), elgamalParams);
}
else
{
throw new NotSupportedException($"Unsupport key generation type: {type}");
}
}
/// <summary>
/// Generate a new set of DSA domain parameters.
/// </summary>
/// <returns>A new set of DSADomainParameters</returns>
public DsaDomainParameters GenerateDomainParameters()
{
if (parameters.P != null)
{
byte[] seed = parameters.GetSeed();
if (seed != null && parameters.UsageIndex >= 0)
{
BigInteger g = DsaParametersGenerator.CalculateGenerator_FIPS186_3_Verifiable(FipsShs.CreateDigest(digestAlgorithm), parameters.P, parameters.Q, seed, parameters.UsageIndex);
return(new DsaDomainParameters(parameters.P, parameters.Q, g, new Org.BouncyCastle.Crypto.Asymmetric.DsaValidationParameters(seed, -1, parameters.UsageIndex)));
}
else
{
BigInteger g = DsaParametersGenerator.CalculateGenerator_FIPS186_3_Unverifiable(parameters.P, parameters.Q, random);
return(new DsaDomainParameters(parameters.P, parameters.Q, g, null));
}
}
else
{
DsaParametersGenerator pGen = new DsaParametersGenerator(FipsShs.CreateDigest(digestAlgorithm));
DsaParameterGenerationParameters dsaGenParameters = new DsaParameterGenerationParameters(
parameters.L, parameters.N, parameters.Certainty, random, parameters.UsageIndex);
pGen.Init(dsaGenParameters);
DsaParameters p = pGen.GenerateParameters();
Org.BouncyCastle.Crypto.Internal.Parameters.DsaValidationParameters validationParameters = p.ValidationParameters;
return(new DsaDomainParameters(p.P, p.Q, p.G, new Org.BouncyCastle.Crypto.Asymmetric.DsaValidationParameters(validationParameters.GetSeed(), validationParameters.Counter, validationParameters.UsageIndex)));
}
}
public static AsymmetricCipherKeyPair DSAGenerateKeyPair()
{
var keyGen = GeneratorUtilities.GetKeyPairGenerator("DSA");
var rand = new SecureRandom();
var pGen = new DsaParametersGenerator();
pGen.Init(512, 80, rand);
keyGen.Init(new DsaKeyGenerationParameters(rand, pGen.GenerateParameters()));
return(keyGen.GenerateKeyPair());
}
/// <summary>
/// Create a key pair for according to the key size
/// </summary>
/// <param name="keySize">the key size in bits</param>
public void CreateKeyPair(int keySize)
{
var dsaParametersGenerator = new DsaParametersGenerator();
dsaParametersGenerator.Init(keySize, 80, new SecureRandom());
var parameters = new DsaKeyGenerationParameters(new SecureRandom(), dsaParametersGenerator.GenerateParameters());
var keyGenerator = new DsaKeyPairGenerator();
keyGenerator.Init(parameters);
keyPair = keyGenerator.GenerateKeyPair();
}
/// <summary>
/// Generate key pair.
/// </summary>
/// <returns></returns>
public override AsymmetricCipherKeyPair GenerateKeyPair()
{
DsaParametersGenerator generator2 = new DsaParametersGenerator();
generator2.Init(_keySize, _certainty, Common.ThreadSecureRandom.Value);
DsaParameters parameters2 = generator2.GenerateParameters();
KeyGenerationParameters parameters = new DsaKeyGenerationParameters(Common.ThreadSecureRandom.Value, parameters2);
IAsymmetricCipherKeyPairGenerator generator = new DsaKeyPairGenerator();
generator.Init(parameters);
return(generator.GenerateKeyPair());
}
public void SetUp()
{
DsaParametersGenerator paramGen = new DsaParametersGenerator();
_dsaParameters = paramGen.GenerateParameters(1024, 160, 160);
_dsaParameters.HashFunction = new Hasher(Hasher.HashImplementation.Sha1);
UserKeyGenerator keyGen = new UserKeyGenerator(_dsaParameters);
_keyPair = keyGen.GenerateKeyPair();
_dsaAlgorithm = new DsaAlgorithm(_dsaParameters);
}
public void NoncompliantParametersGenerator()
{
var pGen1 = new DHParametersGenerator();
pGen1.Init(1024, 10, new SecureRandom()); // Noncompliant {{Use a key length of at least 2048 bits for DH cipher algorithm.}}
var pGen2 = new DsaParametersGenerator();
pGen2.Init(1024, 80, new SecureRandom()); // Noncompliant {{Use a key length of at least 2048 bits for DSA cipher algorithm.}}
var kp3 = new RsaKeyPairGenerator();
var r3 = new RsaKeyGenerationParameters(new BigInteger("1"), new SecureRandom(), 1024, 5); // Noncompliant {{Use a key length of at least 2048 bits for RSA cipher algorithm.}}
kp3.Init(r3);
}
public AsymmetricCipherKeyPair GenerateDsaKeyPair(int keySize)
{
var dsaParameterGenerator = new DsaParametersGenerator(new Sha256Digest());
//Key size is fixed to be either 2048 or 3072 (Table C.1 on FIPS 186-3)
dsaParameterGenerator.Init(new DsaParameterGenerationParameters(keySize, 256, 128, secureRandom.Generator));
DsaParameters dsaParameters = dsaParameterGenerator.GenerateParameters();
var keyGenerationParameters = new DsaKeyGenerationParameters(secureRandom.Generator, dsaParameters);
var keyPairGenerator = new DsaKeyPairGenerator();
keyPairGenerator.Init(keyGenerationParameters);
return(keyPairGenerator.GenerateKeyPair());
}
public void TestNONEwithDSA()
{
byte[] dummySha1 = Hex.Decode("01020304050607080910111213141516");
SecureRandom rand = new SecureRandom();
DsaParametersGenerator pGen = new DsaParametersGenerator();
pGen.Init(512, 80, rand);
IAsymmetricCipherKeyPairGenerator g = GeneratorUtilities.GetKeyPairGenerator("DSA");
g.Init(new DsaKeyGenerationParameters(rand, pGen.GenerateParameters()));
AsymmetricCipherKeyPair kp = g.GenerateKeyPair();
ISigner sig = SignerUtilities.GetSigner("NONEwithDSA");
sig.Init(true, kp.Private);
sig.BlockUpdate(dummySha1, 0, dummySha1.Length);
byte[] sigBytes = sig.GenerateSignature();
sig.Init(false, kp.Public);
sig.BlockUpdate(dummySha1, 0, dummySha1.Length);
sig.VerifySignature(sigBytes);
// reset test
sig.BlockUpdate(dummySha1, 0, dummySha1.Length);
if (!sig.VerifySignature(sigBytes))
{
Fail("NONEwithDSA failed to reset");
}
// lightweight test
DsaSigner signer = new DsaSigner();
Asn1Sequence derSig = Asn1Sequence.GetInstance(Asn1Object.FromByteArray(sigBytes));
signer.Init(false, kp.Public);
if (!signer.VerifySignature(dummySha1,
DerInteger.GetInstance(derSig[0]).Value, DerInteger.GetInstance(derSig[1]).Value))
{
Fail("NONEwithDSA not really NONE!");
}
}
private void InitKey()
{
_secure_random = new SecureRandom();
DsaParametersGenerator _dsa_param_gen = new DsaParametersGenerator();
DsaKeyPairGenerator _dsa_key_pair_gen = new DsaKeyPairGenerator();
_dsa_param_gen.Init(1024, 80, _secure_random);
DsaKeyGenerationParameters _dsa_key_gen_params = new DsaKeyGenerationParameters(_secure_random, _dsa_param_gen.GenerateParameters());
_dsa_key_pair_gen.Init(_dsa_key_gen_params);
_key_pair = _dsa_key_pair_gen.GenerateKeyPair();
_private_key_param = (DsaPrivateKeyParameters)_key_pair.Private;
_public_key_param = (DsaPublicKeyParameters)_key_pair.Public;
}
//constructor
/// <summary>
/// A utility for easily using cryptographic functions. Automatically generates PGP and RSA keypairs.
/// </summary>
public CryptoHelper()
{
DsaKeyPairGenerator gen = new DsaKeyPairGenerator();
DsaParametersGenerator pGen = new DsaParametersGenerator();
pgpRng.SetSeed(GetRandomBytes(512));
pGen.Init(1024, 100, pgpRng);
DsaKeyGenerationParameters p = new DsaKeyGenerationParameters(pgpRng, pGen.GenerateParameters());
gen.Init(p);
AsymmetricCipherKeyPair keys = gen.GenerateKeyPair();
pgpPublicKey = new PgpPublicKey(Org.BouncyCastle.Bcpg.PublicKeyAlgorithmTag.Dsa, keys.Public, DateTime.Now);
pgpPrivateKey = new PgpPrivateKey(pgpPublicKey.KeyId, pgpPublicKey.PublicKeyPacket, keys.Private);
rsaPublicKey = encodeRsaPublicKey(rsa.ExportParameters(false));
rsaPrivateKey = encodeRsaPrivateKey(rsa.ExportParameters(true));
}
private void GenerateElGamal(Stream outSecret, Stream outPublic)
{
// Prepare a strong Secure Random with seed
SecureRandom secureRandom = PgpEncryptionUtil.GetSecureRandom();
IAsymmetricCipherKeyPairGenerator dsaKpg = GeneratorUtilities.GetKeyPairGenerator("DSA");
DsaParametersGenerator pGen = new DsaParametersGenerator();
pGen.Init((int)PublicKeyLength.BITS_1024, 80, new SecureRandom()); // DSA is 1024 even for long 2048+ ElGamal keys
DsaParameters dsaParams = pGen.GenerateParameters();
DsaKeyGenerationParameters kgp = new DsaKeyGenerationParameters(secureRandom, dsaParams);
dsaKpg.Init(kgp);
//
// this takes a while as the key generator has to Generate some DSA parameters
// before it Generates the key.
//
AsymmetricCipherKeyPair dsaKp = dsaKpg.GenerateKeyPair();
IAsymmetricCipherKeyPairGenerator elgKpg = GeneratorUtilities.GetKeyPairGenerator("ELGAMAL");
Group elgamalGroup = Precomputed.GetElGamalGroup((int)this.publicKeyLength);
if (elgamalGroup == null)
{
throw new ArgumentException("ElGamal Group not found for key length: " + this.publicKeyLength);
}
Org.BouncyCastle.Math.BigInteger p = elgamalGroup.GetP();
Org.BouncyCastle.Math.BigInteger g = elgamalGroup.GetG();
secureRandom = PgpEncryptionUtil.GetSecureRandom();
ElGamalParameters elParams = new ElGamalParameters(p, g);
ElGamalKeyGenerationParameters elKgp = new ElGamalKeyGenerationParameters(secureRandom, elParams);
elgKpg.Init(elKgp);
//
// this is quicker because we are using preGenerated parameters.
//
AsymmetricCipherKeyPair elgKp = elgKpg.GenerateKeyPair();
DsaElGamalKeyGeneratorUtil.ExportKeyPair(outSecret, outPublic, dsaKp, elgKp, identity, passphrase, true);
}
/// <summary>
/// 随机生成密钥构造,默认密钥长度1024
/// </summary>
public AsymmetricCipher(AsymmetricAlgorithm algorithm, int keySize = 1024)
{
Algorithm = algorithm ?? throw new NullReferenceException("加密算法不能为空");
var keyGenerator = GeneratorUtilities.GetKeyPairGenerator(algorithm.Generation);
var random = new SecureRandom();
if (algorithm == AsymmetricAlgorithm.Dsa)
{
var dsaParametersGenerator = new DsaParametersGenerator();
dsaParametersGenerator.Init(keySize, 100, random);
keyGenerator.Init(new DsaKeyGenerationParameters(random, dsaParametersGenerator.GenerateParameters()));
}
else
{
keyGenerator.Init(new KeyGenerationParameters(new SecureRandom(), keySize));
}
var keyPair = keyGenerator.GenerateKeyPair();
_publicKeyParameter = keyPair.Public;
_privateKeyParameter = keyPair.Private;
}
public (string publicKey, string privateKey) GetDsaKeys()
{
var secureRandom = new SecureRandom();
var parametersGenerator = new DsaParametersGenerator(new Sha1Digest());
parametersGenerator.Init(1024, 100, secureRandom);
var parameters = parametersGenerator.GenerateParameters();
var g = new DsaKeyPairGenerator();
g.Init(new DsaKeyGenerationParameters(secureRandom, parameters));
var keyPair = g.GenerateKeyPair();
var pkInfo = PrivateKeyInfoFactory.CreatePrivateKeyInfo(keyPair.Private);
var privateKey = Convert.ToBase64String(pkInfo.ToAsn1Object().GetDerEncoded());
var publicKeyInfo = SubjectPublicKeyInfoFactory.CreateSubjectPublicKeyInfo(keyPair.Public);
var serializedPublicBytes = publicKeyInfo.ToAsn1Object().GetDerEncoded();
var publicKey = Convert.ToBase64String(serializedPublicBytes);
return(publicKey, privateKey);
}
/// <summary>
/// DSA密钥对生成
/// </summary>
/// <param name="size">size must be from 512 - 1024 and a multiple of 64</param>
/// <returns></returns>
public static KeyParameter Generator(int size = 1024)
{
var pGen = new DsaParametersGenerator();
pGen.Init(size, 80, new SecureRandom());
var dsaParams = pGen.GenerateParameters();
var kgp = new DsaKeyGenerationParameters(new SecureRandom(), dsaParams);
var kpg = GeneratorUtilities.GetKeyPairGenerator("DSA");
kpg.Init(kgp);
var kp = kpg.GenerateKeyPair();
var subjectPublicKeyInfo = SubjectPublicKeyInfoFactory.CreateSubjectPublicKeyInfo(kp.Public);
var privateKeyInfo = PrivateKeyInfoFactory.CreatePrivateKeyInfo(kp.Private);
return(new KeyParameter
{
PrivateKey = Base64.ToBase64String(privateKeyInfo.GetEncoded()),
PublicKey = Base64.ToBase64String(subjectPublicKeyInfo.GetEncoded())
});
}
/// <summary>
/// Generate a DSA2 Key pair given its bit size.
/// </summary>
/// <param name="keySize">"Key bit size of 1024, 2048 or 3072"</param>
/// <returns>"DSA2 key pair for the given size"</returns>
public AsymmetricCipherKeyPair Dsa2KeyGen(int keySize)
{
// Check that we got a proper key size
int[] allowedKeySizes = { 1024, 2048, 3072 };
if (!(allowedKeySizes.Contains(keySize)))
{
throw new ArgumentException("KeySize provided is not 1024, 2048 or 3072.", "keySize");
}
// Set the proper N parameter depending on the bit key size.
int dsa2NParam;
if (keySize == 1024)
{
dsa2NParam = 160;
}
else
{
dsa2NParam = 256;
}
var secRand = new SecureRandom();
var dsa2Genertor = GeneratorUtilities.GetKeyPairGenerator("DSA");
// Generate the proper parameters for the DSA2 Key.
var digest = new Sha256Digest();
var paramGen = new DsaParametersGenerator(digest);
var dsaParamsList = new DsaParameterGenerationParameters(keySize, dsa2NParam, 80, secRand);
paramGen.Init(dsaParamsList);
// This will take a while since it has to find a valid random prime number for use.
var dsaParams = paramGen.GenerateParameters();
var dsaOptions = new DsaKeyGenerationParameters(secRand, dsaParams);
var keyPair = dsa2Genertor.GenerateKeyPair();
return(keyPair);
}
public void CompliantParametersGenerator()
{
var pGen1 = new DHParametersGenerator();
pGen1.Init(2048, 10, new SecureRandom()); // Compliant
var pGen2 = new DsaParametersGenerator();
pGen2.Init(2048, 80, new SecureRandom()); // Compliant
var kp1 = new ECKeyPairGenerator(); // OK - ignore for now
var kp2 = new DsaKeyPairGenerator();
var d2 = new DsaParameters(new BigInteger("2"), new BigInteger("2"), new BigInteger("2")); // FN
var r2 = new DsaKeyGenerationParameters(new SecureRandom(), d2);
kp2.Init(r2);
var kp3 = new RsaKeyPairGenerator();
var r3 = new RsaKeyGenerationParameters(new BigInteger("2"), new SecureRandom(), 2048, 5); // Compliant
kp3.Init(r3);
}
private void doTestBadStrength(
int strength)
{
// IAsymmetricCipherKeyPairGenerator g = GeneratorUtilities.GetKeyPairGenerator("DSA");
// test exception
//
try
{
SecureRandom rand = new SecureRandom();
DsaParametersGenerator pGen = new DsaParametersGenerator();
pGen.Init(strength, 80, rand);
// g.Init(new DsaKeyGenerationParameters(rand, pGen.GenerateParameters()));
Fail("illegal parameter " + strength + " check failed.");
}
catch (ArgumentException)
{
// expected
}
}
/// <inheritdoc />
public void GenerateCerts()
{
var dsaKeyPairGen = new DsaKeyPairGenerator();
var dsaParamGen = new DsaParametersGenerator();
dsaParamGen.Init(512, 12, new SecureRandom());
dsaKeyPairGen.
Init(new DsaKeyGenerationParameters(new SecureRandom(),
dsaParamGen.GenerateParameters()));
var keyPair = dsaKeyPairGen.GenerateKeyPair();
_privateKey = keyPair.Private;
_publicKey = keyPair.Public;
var publicKeyDer = SubjectPublicKeyInfoFactory
.CreateSubjectPublicKeyInfo(_publicKey)
.GetDerEncoded();
var publicKeyDerBase64 = Convert.ToBase64String(publicKeyDer);
_config.SignaturePublicKey = publicKeyDerBase64;
}
public static IAsymmetricCipherKeyPairGenerator CreateGenerator(SecureRandom random, TypeWrapper kpGen,
int keystrength)
{
var keypairGen = kpGen.Instance <IAsymmetricCipherKeyPairGenerator>();
//var random = SecureRandomUtils.GetInstance(Model.RandomGenerator, Model.RandomGeneratorArgument);
if (keypairGen is DsaKeyPairGenerator)
{
DsaParametersGenerator pGen = new DsaParametersGenerator();
pGen.Init(keystrength, 80, random); //TODO:
DsaParameters parameters = pGen.GenerateParameters();
DsaKeyGenerationParameters genParam = new DsaKeyGenerationParameters(random, parameters);
keypairGen.Init(genParam);
return(keypairGen);
}
if (keypairGen is ECKeyPairGenerator)
{
keypairGen.Init(new KeyGenerationParameters(random, keystrength));
return(keypairGen);
}
keypairGen.Init(new KeyGenerationParameters(random, keystrength));
return(keypairGen);
}
/// <summary>
/// Generates the key.
/// </summary>
/// <param name="size">The size.</param>
protected override void GenerateKey(int size)
{
var paramgen = new DsaParametersGenerator();
paramgen.Init(size, 100, Secure.Random);
var keygen = new DsaKeyPairGenerator();
keygen.Init(new DsaKeyGenerationParameters(Secure.Random, paramgen.GenerateParameters()));
var pair = keygen.GenerateKeyPair();
var priv = (DsaPrivateKeyParameters)pair.Private;
X = priv.X.ToSystemBigInteger();
Size = size;
PublicKey = new DsaPublicKey();
var pub = (DsaPublicKeyParameters)pair.Public;
PublicKey.Y = pub.Y.ToSystemBigInteger();
PublicKey.G = pub.Parameters.G.ToSystemBigInteger();
PublicKey.P = pub.Parameters.P.ToSystemBigInteger();
PublicKey.Q = pub.Parameters.Q.ToSystemBigInteger();
PublicKey.Size = size;
}
public void TestDsa2Parameters()
{
byte[] seed = Hex.Decode("4783081972865EA95D43318AB2EAF9C61A2FC7BBF1B772A09017BDF5A58F4FF0");
//AlgorithmParameterGenerator a = AlgorithmParameterGenerator.getInstance("DSA", "BC");
//a.init(2048, new DSATestSecureRandom(seed));
DsaParametersGenerator a = new DsaParametersGenerator(new Sha256Digest());
a.Init(new DsaParameterGenerationParameters(2048, 256, 80, new DsaTestSecureRandom(seed)));
//AlgorithmParameters parameters = a.generateParameters();
//DSAParameterSpec dsaP = (DSAParameterSpec)parameters.getParameterSpec(DSAParameterSpec.class);
DsaParameters dsaP = a.GenerateParameters();
if (!dsaP.Q.Equals(new BigInteger("C24ED361870B61E0D367F008F99F8A1F75525889C89DB1B673C45AF5867CB467", 16)))
{
Fail("Q incorrect");
}
if (!dsaP.P.Equals(new BigInteger(
"F56C2A7D366E3EBDEAA1891FD2A0D099" +
"436438A673FED4D75F594959CFFEBCA7BE0FC72E4FE67D91" +
"D801CBA0693AC4ED9E411B41D19E2FD1699C4390AD27D94C" +
"69C0B143F1DC88932CFE2310C886412047BD9B1C7A67F8A2" +
"5909132627F51A0C866877E672E555342BDF9355347DBD43" +
"B47156B2C20BAD9D2B071BC2FDCF9757F75C168C5D9FC431" +
"31BE162A0756D1BDEC2CA0EB0E3B018A8B38D3EF2487782A" +
"EB9FBF99D8B30499C55E4F61E5C7DCEE2A2BB55BD7F75FCD" +
"F00E48F2E8356BDB59D86114028F67B8E07B127744778AFF" +
"1CF1399A4D679D92FDE7D941C5C85C5D7BFF91BA69F9489D" +
"531D1EBFA727CFDA651390F8021719FA9F7216CEB177BD75", 16)))
{
Fail("P incorrect");
}
if (!dsaP.G.Equals(new BigInteger(
"8DC6CC814CAE4A1C05A3E186A6FE27EA" +
"BA8CDB133FDCE14A963A92E809790CBA096EAA26140550C1" +
"29FA2B98C16E84236AA33BF919CD6F587E048C52666576DB" +
"6E925C6CBE9B9EC5C16020F9A44C9F1C8F7A8E611C1F6EC2" +
"513EA6AA0B8D0F72FED73CA37DF240DB57BBB27431D61869" +
"7B9E771B0B301D5DF05955425061A30DC6D33BB6D2A32BD0" +
"A75A0A71D2184F506372ABF84A56AEEEA8EB693BF29A6403" +
"45FA1298A16E85421B2208D00068A5A42915F82CF0B858C8" +
"FA39D43D704B6927E0B2F916304E86FB6A1B487F07D8139E" +
"428BB096C6D67A76EC0B8D4EF274B8A2CF556D279AD267CC" +
"EF5AF477AFED029F485B5597739F5D0240F67C2D948A6279", 16)))
{
Fail("G incorrect");
}
//KeyPairGenerator g = KeyPairGenerator.getInstance("DSA", "BC");
IAsymmetricCipherKeyPairGenerator g = GeneratorUtilities.GetKeyPairGenerator("DSA");
//g.initialize(dsaP, FixedSecureRandom.From(Hex.Decode("0CAF2EF547EC49C4F3A6FE6DF4223A174D01F2C115D49A6F73437C29A2A8458C")));
g.Init(new DsaKeyGenerationParameters(FixedSecureRandom.From(Hex.Decode("0CAF2EF547EC49C4F3A6FE6DF4223A174D01F2C115D49A6F73437C29A2A8458C")), dsaP));
//KeyPair p = g.generateKeyPair();
AsymmetricCipherKeyPair p = g.GenerateKeyPair();
//DSAPrivateKey sKey = (DSAPrivateKey)p.getPrivate();
//DSAPublicKey vKey = (DSAPublicKey)p.getPublic();
DsaPrivateKeyParameters sKey = (DsaPrivateKeyParameters)p.Private;
DsaPublicKeyParameters vKey = (DsaPublicKeyParameters)p.Public;
if (!vKey.Y.Equals(new BigInteger(
"2828003D7C747199143C370FDD07A286" +
"1524514ACC57F63F80C38C2087C6B795B62DE1C224BF8D1D" +
"1424E60CE3F5AE3F76C754A2464AF292286D873A7A30B7EA" +
"CBBC75AAFDE7191D9157598CDB0B60E0C5AA3F6EBE425500" +
"C611957DBF5ED35490714A42811FDCDEB19AF2AB30BEADFF" +
"2907931CEE7F3B55532CFFAEB371F84F01347630EB227A41" +
"9B1F3F558BC8A509D64A765D8987D493B007C4412C297CAF" +
"41566E26FAEE475137EC781A0DC088A26C8804A98C23140E" +
"7C936281864B99571EE95C416AA38CEEBB41FDBFF1EB1D1D" +
"C97B63CE1355257627C8B0FD840DDB20ED35BE92F08C49AE" +
"A5613957D7E5C7A6D5A5834B4CB069E0831753ECF65BA02B", 16)))
{
Fail("Y value incorrect");
}
if (!sKey.X.Equals(
new BigInteger("0CAF2EF547EC49C4F3A6FE6DF4223A174D01F2C115D49A6F73437C29A2A8458C", 16)))
{
Fail("X value incorrect");
}
//byte[] encodeParams = parameters.getEncoded();
byte[] encodeParams = new DsaParameter(dsaP.P, dsaP.Q, dsaP.G).GetDerEncoded();
//AlgorithmParameters a2 = AlgorithmParameters.getInstance("DSA", "BC");
//a2.init(encodeParams);
DsaParameter dsaP2 = DsaParameter.GetInstance(Asn1Object.FromByteArray(encodeParams));
DsaParameters p2 = new DsaParameters(dsaP.P, dsaP.Q, dsaP.G);
// a and a2 should be equivalent!
//byte[] encodeParams_2 = a2.GetEncoded();
byte[] encodeParams_2 = new DsaParameter(p2.P, p2.Q, p2.G).GetDerEncoded();
if (!AreEqual(encodeParams, encodeParams_2))
{
Fail("encode/decode parameters failed");
}
ISigner s = SignerUtilities.GetSigner("DSA");
byte[] data = { 1, 2, 3, 4, 5, 6, 7, 8, 9, 0 };
s.Init(true, sKey);
s.BlockUpdate(data, 0, data.Length);
byte[] sigBytes = s.GenerateSignature();
s = SignerUtilities.GetSigner("DSA");
s.Init(false, vKey);
s.BlockUpdate(data, 0, data.Length);
if (!s.VerifySignature(sigBytes))
{
Fail("DSA verification failed");
}
}
public void TestParameters()
{
// AlgorithmParameterGenerator a = AlgorithmParameterGenerator.GetInstance("DSA");
// a.init(512, random);
DsaParametersGenerator a = new DsaParametersGenerator();
a.Init(512, 20, random);
// AlgorithmParameters parameters = a.generateParameters();
DsaParameters p = a.GenerateParameters();
// byte[] encodeParams = parameters.GetEncoded();
byte[] encodeParams = new DsaParameter(p.P, p.Q, p.G).GetDerEncoded();
// AlgorithmParameters a2 = AlgorithmParameters.GetInstance("DSA");
// a2.init(encodeParams);
DsaParameter dsaP = DsaParameter.GetInstance(Asn1Object.FromByteArray(encodeParams));
DsaParameters p2 = new DsaParameters(dsaP.P, dsaP.Q, dsaP.G);
// a and a2 should be equivalent!
// byte[] encodeParams_2 = a2.GetEncoded();
byte[] encodeParams_2 = new DsaParameter(p2.P, p2.Q, p2.G).GetDerEncoded();
if (!AreEqual(encodeParams, encodeParams_2))
{
Fail("encode/Decode parameters failed");
}
// DSAParameterSpec dsaP = (DSAParameterSpec)parameters.getParameterSpec(typeof(DSAParameterSpec));
// KeyPairGenerator g = KeyPairGenerator.GetInstance("DSA");
IAsymmetricCipherKeyPairGenerator g = GeneratorUtilities.GetKeyPairGenerator("DSA");
// g.initialize(dsaP, new SecureRandom());
g.Init(new DsaKeyGenerationParameters(new SecureRandom(), p));
// KeyPair p = g.generateKeyPair();
AsymmetricCipherKeyPair pair = g.GenerateKeyPair();
// PrivateKey sKey = p.Private;
// PublicKey vKey = p.Public;
AsymmetricKeyParameter sKey = pair.Private;
AsymmetricKeyParameter vKey = pair.Public;
ISigner s = SignerUtilities.GetSigner("DSA");
byte[] data = { 1, 2, 3, 4, 5, 6, 7, 8, 9, 0 };
s.Init(true, sKey);
s.BlockUpdate(data, 0, data.Length);
byte[] sigBytes = s.GenerateSignature();
s = SignerUtilities.GetSigner("DSA");
s.Init(false, vKey);
s.BlockUpdate(data, 0, data.Length);
if (!s.VerifySignature(sigBytes))
{
Fail("DSA verification failed");
}
}
public void TestGeneration()
{
ISigner s = SignerUtilities.GetSigner("DSA");
byte[] data = { 1, 2, 3, 4, 5, 6, 7, 8, 9, 0 };
SecureRandom rand = new SecureRandom();
// KeyPairGenerator g = KeyPairGenerator.GetInstance("DSA");
IAsymmetricCipherKeyPairGenerator g = GeneratorUtilities.GetKeyPairGenerator("DSA");
// test exception
//
doTestBadStrength(513);
doTestBadStrength(510);
doTestBadStrength(1025);
//g.initialize(512, rand);
{
DsaParametersGenerator pGen = new DsaParametersGenerator();
pGen.Init(512, 80, rand);
g.Init(new DsaKeyGenerationParameters(rand, pGen.GenerateParameters()));
}
AsymmetricCipherKeyPair p = g.GenerateKeyPair();
AsymmetricKeyParameter sKey = p.Private;
AsymmetricKeyParameter vKey = p.Public;
s.Init(true, sKey);
s.BlockUpdate(data, 0, data.Length);
byte[] sigBytes = s.GenerateSignature();
s = SignerUtilities.GetSigner("DSA");
s.Init(false, vKey);
s.BlockUpdate(data, 0, data.Length);
if (!s.VerifySignature(sigBytes))
{
Fail("DSA verification failed");
}
//
// ECDSA Fp generation test
//
s = SignerUtilities.GetSigner("ECDSA");
X9ECParameters x9 = ECNamedCurveTable.GetByName("prime239v1");
ECCurve curve = x9.Curve;
ECDomainParameters ecSpec = new ECDomainParameters(curve, x9.G, x9.N, x9.H);
g = GeneratorUtilities.GetKeyPairGenerator("ECDSA");
g.Init(new ECKeyGenerationParameters(ecSpec, rand));
p = g.GenerateKeyPair();
sKey = p.Private;
vKey = p.Public;
s.Init(true, sKey);
s.BlockUpdate(data, 0, data.Length);
sigBytes = s.GenerateSignature();
s = SignerUtilities.GetSigner("ECDSA");
s.Init(false, vKey);
s.BlockUpdate(data, 0, data.Length);
if (!s.VerifySignature(sigBytes))
{
Fail("ECDSA verification failed");
}
//
// ECDSA F2m generation test
//
s = SignerUtilities.GetSigner("ECDSA");
x9 = ECNamedCurveTable.GetByName("c2tnb239v1");
curve = x9.Curve;
ecSpec = new ECDomainParameters(curve, x9.G, x9.N, x9.H);
g = GeneratorUtilities.GetKeyPairGenerator("ECDSA");
g.Init(new ECKeyGenerationParameters(ecSpec, rand));
p = g.GenerateKeyPair();
sKey = p.Private;
vKey = p.Public;
s.Init(true, sKey);
s.BlockUpdate(data, 0, data.Length);
sigBytes = s.GenerateSignature();
s = SignerUtilities.GetSigner("ECDSA");
s.Init(false, vKey);
s.BlockUpdate(data, 0, data.Length);
if (!s.VerifySignature(sigBytes))
{
Fail("ECDSA verification failed");
}
}
public void SetUp()
{
_generator = new DsaParametersGenerator();
_primalityTester = new MillerRabinPrimalityTester(40);
}
private void Dsa2Test4()
{
byte[] seed = Hex.Decode("193AFCA7C1E77B3C1ECC618C81322E47B8B8B997C9C83515C59CC446C2D9BD47");
DsaParametersGenerator pGen = new DsaParametersGenerator(new Sha256Digest());
pGen.Init(new DsaParameterGenerationParameters(3072, 256, 80, new DsaTestSecureRandom(seed)));
DsaParameters parameters = pGen.GenerateParameters();
DsaValidationParameters pv = parameters.ValidationParameters;
if (pv.Counter != 20)
{
Fail("counter incorrect");
}
if (!AreEqual(seed, pv.GetSeed()))
{
Fail("seed incorrect");
}
if (!parameters.Q.Equals(new BigInteger("CFA0478A54717B08CE64805B76E5B14249A77A4838469DF7F7DC987EFCCFB11D", 16)))
{
Fail("Q incorrect");
}
if (!parameters.P.Equals(new BigInteger(
"90066455B5CFC38F9CAA4A48B4281F292C260FEEF01FD610" +
"37E56258A7795A1C7AD46076982CE6BB956936C6AB4DCFE0" +
"5E6784586940CA544B9B2140E1EB523F009D20A7E7880E4E" +
"5BFA690F1B9004A27811CD9904AF70420EEFD6EA11EF7DA1" +
"29F58835FF56B89FAA637BC9AC2EFAAB903402229F491D8D" +
"3485261CD068699B6BA58A1DDBBEF6DB51E8FE34E8A78E54" +
"2D7BA351C21EA8D8F1D29F5D5D15939487E27F4416B0CA63" +
"2C59EFD1B1EB66511A5A0FBF615B766C5862D0BD8A3FE7A0" +
"E0DA0FB2FE1FCB19E8F9996A8EA0FCCDE538175238FC8B0E" +
"E6F29AF7F642773EBE8CD5402415A01451A840476B2FCEB0" +
"E388D30D4B376C37FE401C2A2C2F941DAD179C540C1C8CE0" +
"30D460C4D983BE9AB0B20F69144C1AE13F9383EA1C08504F" +
"B0BF321503EFE43488310DD8DC77EC5B8349B8BFE97C2C56" +
"0EA878DE87C11E3D597F1FEA742D73EEC7F37BE43949EF1A" +
"0D15C3F3E3FC0A8335617055AC91328EC22B50FC15B941D3" +
"D1624CD88BC25F3E941FDDC6200689581BFEC416B4B2CB73", 16)))
{
Fail("P incorrect");
}
if (!parameters.G.Equals(new BigInteger(
"5E5CBA992E0A680D885EB903AEA78E4A45A469103D448EDE" +
"3B7ACCC54D521E37F84A4BDD5B06B0970CC2D2BBB715F7B8" +
"2846F9A0C393914C792E6A923E2117AB805276A975AADB52" +
"61D91673EA9AAFFEECBFA6183DFCB5D3B7332AA19275AFA1" +
"F8EC0B60FB6F66CC23AE4870791D5982AAD1AA9485FD8F4A" +
"60126FEB2CF05DB8A7F0F09B3397F3937F2E90B9E5B9C9B6" +
"EFEF642BC48351C46FB171B9BFA9EF17A961CE96C7E7A7CC" +
"3D3D03DFAD1078BA21DA425198F07D2481622BCE45969D9C" +
"4D6063D72AB7A0F08B2F49A7CC6AF335E08C4720E31476B6" +
"7299E231F8BD90B39AC3AE3BE0C6B6CACEF8289A2E2873D5" +
"8E51E029CAFBD55E6841489AB66B5B4B9BA6E2F784660896" +
"AFF387D92844CCB8B69475496DE19DA2E58259B090489AC8" +
"E62363CDF82CFD8EF2A427ABCD65750B506F56DDE3B98856" +
"7A88126B914D7828E2B63A6D7ED0747EC59E0E0A23CE7D8A" +
"74C1D2C2A7AFB6A29799620F00E11C33787F7DED3B30E1A2" +
"2D09F1FBDA1ABBBFBF25CAE05A13F812E34563F99410E73B", 16)))
{
Fail("G incorrect");
}
DsaKeyPairGenerator kpGen = new DsaKeyPairGenerator();
kpGen.Init(new DsaKeyGenerationParameters(
FixedSecureRandom.From(Hex.Decode("3ABC1587297CE7B9EA1AD6651CF2BC4D7F92ED25CABC8553F567D1B40EBB8764")), parameters));
AsymmetricCipherKeyPair kp = kpGen.GenerateKeyPair();
DsaPublicKeyParameters pub = (DsaPublicKeyParameters)kp.Public;
DsaPrivateKeyParameters priv = (DsaPrivateKeyParameters)kp.Private;
if (!pub.Y.Equals(new BigInteger(
"8B891C8692D3DE875879390F2698B26FBECCA6B075535DCE" +
"6B0C862577F9FA0DEF6074E7A7624121224A595896ABD4CD" +
"A56B2CEFB942E025D2A4282FFAA98A48CDB47E1A6FCB5CFB" +
"393EF35AF9DF913102BB303C2B5C36C3F8FC04ED7B8B69FE" +
"FE0CF3E1FC05CFA713B3435B2656E913BA8874AEA9F93600" +
"6AEB448BCD005D18EC3562A33D04CF25C8D3D69844343442" +
"FA3DB7DE618C5E2DA064573E61E6D5581BFB694A23AC87FD" +
"5B52D62E954E1376DB8DDB524FFC0D469DF978792EE44173" +
"8E5DB05A7DC43E94C11A2E7A4FBE383071FA36D2A7EC8A93" +
"88FE1C4F79888A99D3B6105697C2556B79BB4D7E781CEBB3" +
"D4866AD825A5E830846072289FDBC941FA679CA82F5F78B7" +
"461B2404DB883D215F4E0676CF5493950AC5591697BFEA8D" +
"1EE6EC016B89BA51CAFB5F9C84C989FA117375E94578F28B" +
"E0B34CE0545DA46266FD77F62D8F2CEE92AB77012AFEBC11" +
"008985A821CD2D978C7E6FE7499D1AAF8DE632C21BB48CA5" +
"CBF9F31098FD3FD3854C49A65D9201744AACE540354974F9", 16)))
{
Fail("Y value incorrect");
}
if (!priv.X.Equals(
new BigInteger("3ABC1587297CE7B9EA1AD6651CF2BC4D7F92ED25CABC8553F567D1B40EBB8764", 16)))
{
Fail("X value incorrect");
}
DsaSigner signer = new DsaSigner();
signer.Init(true, new ParametersWithRandom(kp.Private,
FixedSecureRandom.From(Hex.Decode("A6902C1E6E3943C5628061588A8B007BCCEA91DBF12915483F04B24AB0678BEE"))));
byte[] msg = Hex.Decode("BA7816BF8F01CFEA414140DE5DAE2223B00361A396177A9CB410FF61F20015AD");
BigInteger[] sig = signer.GenerateSignature(msg);
if (!sig[0].Equals(new BigInteger("5F184E645A38BE8FB4A6871B6503A9D12924C7ABE04B71410066C2ECA6E3BE3E", 16)))
{
Fail("R value incorrect");
}
if (!sig[1].Equals(new BigInteger("91EB0C7BA3D4B9B60B825C3D9F2CADA8A2C9D7723267B033CBCDCF8803DB9C18", 16)))
{
Fail("S value incorrect");
}
signer.Init(false, kp.Public);
if (!signer.VerifySignature(msg, sig[0], sig[1]))
{
Fail("signature not verified");
}
}
private void Dsa2Test3()
{
byte[] seed = Hex.Decode("4783081972865EA95D43318AB2EAF9C61A2FC7BBF1B772A09017BDF5A58F4FF0");
DsaParametersGenerator pGen = new DsaParametersGenerator(new Sha256Digest());
pGen.Init(new DsaParameterGenerationParameters(2048, 256, 80, new DsaTestSecureRandom(seed)));
DsaParameters parameters = pGen.GenerateParameters();
DsaValidationParameters pv = parameters.ValidationParameters;
if (pv.Counter != 12)
{
Fail("counter incorrect");
}
if (!AreEqual(seed, pv.GetSeed()))
{
Fail("seed incorrect");
}
if (!parameters.Q.Equals(new BigInteger("C24ED361870B61E0D367F008F99F8A1F75525889C89DB1B673C45AF5867CB467", 16)))
{
Fail("Q incorrect");
}
if (!parameters.P.Equals(new BigInteger(
"F56C2A7D366E3EBDEAA1891FD2A0D099" +
"436438A673FED4D75F594959CFFEBCA7BE0FC72E4FE67D91" +
"D801CBA0693AC4ED9E411B41D19E2FD1699C4390AD27D94C" +
"69C0B143F1DC88932CFE2310C886412047BD9B1C7A67F8A2" +
"5909132627F51A0C866877E672E555342BDF9355347DBD43" +
"B47156B2C20BAD9D2B071BC2FDCF9757F75C168C5D9FC431" +
"31BE162A0756D1BDEC2CA0EB0E3B018A8B38D3EF2487782A" +
"EB9FBF99D8B30499C55E4F61E5C7DCEE2A2BB55BD7F75FCD" +
"F00E48F2E8356BDB59D86114028F67B8E07B127744778AFF" +
"1CF1399A4D679D92FDE7D941C5C85C5D7BFF91BA69F9489D" +
"531D1EBFA727CFDA651390F8021719FA9F7216CEB177BD75", 16)))
{
Fail("P incorrect");
}
if (!parameters.G.Equals(new BigInteger(
"8DC6CC814CAE4A1C05A3E186A6FE27EA" +
"BA8CDB133FDCE14A963A92E809790CBA096EAA26140550C1" +
"29FA2B98C16E84236AA33BF919CD6F587E048C52666576DB" +
"6E925C6CBE9B9EC5C16020F9A44C9F1C8F7A8E611C1F6EC2" +
"513EA6AA0B8D0F72FED73CA37DF240DB57BBB27431D61869" +
"7B9E771B0B301D5DF05955425061A30DC6D33BB6D2A32BD0" +
"A75A0A71D2184F506372ABF84A56AEEEA8EB693BF29A6403" +
"45FA1298A16E85421B2208D00068A5A42915F82CF0B858C8" +
"FA39D43D704B6927E0B2F916304E86FB6A1B487F07D8139E" +
"428BB096C6D67A76EC0B8D4EF274B8A2CF556D279AD267CC" +
"EF5AF477AFED029F485B5597739F5D0240F67C2D948A6279", 16)))
{
Fail("G incorrect");
}
DsaKeyPairGenerator kpGen = new DsaKeyPairGenerator();
kpGen.Init(new DsaKeyGenerationParameters(
FixedSecureRandom.From(Hex.Decode("0CAF2EF547EC49C4F3A6FE6DF4223A174D01F2C115D49A6F73437C29A2A8458C")), parameters));
AsymmetricCipherKeyPair kp = kpGen.GenerateKeyPair();
DsaPublicKeyParameters pub = (DsaPublicKeyParameters)kp.Public;
DsaPrivateKeyParameters priv = (DsaPrivateKeyParameters)kp.Private;
if (!pub.Y.Equals(new BigInteger(
"2828003D7C747199143C370FDD07A286" +
"1524514ACC57F63F80C38C2087C6B795B62DE1C224BF8D1D" +
"1424E60CE3F5AE3F76C754A2464AF292286D873A7A30B7EA" +
"CBBC75AAFDE7191D9157598CDB0B60E0C5AA3F6EBE425500" +
"C611957DBF5ED35490714A42811FDCDEB19AF2AB30BEADFF" +
"2907931CEE7F3B55532CFFAEB371F84F01347630EB227A41" +
"9B1F3F558BC8A509D64A765D8987D493B007C4412C297CAF" +
"41566E26FAEE475137EC781A0DC088A26C8804A98C23140E" +
"7C936281864B99571EE95C416AA38CEEBB41FDBFF1EB1D1D" +
"C97B63CE1355257627C8B0FD840DDB20ED35BE92F08C49AE" +
"A5613957D7E5C7A6D5A5834B4CB069E0831753ECF65BA02B", 16)))
{
Fail("Y value incorrect");
}
if (!priv.X.Equals(
new BigInteger("0CAF2EF547EC49C4F3A6FE6DF4223A174D01F2C115D49A6F73437C29A2A8458C", 16)))
{
Fail("X value incorrect");
}
DsaSigner signer = new DsaSigner();
signer.Init(true, new ParametersWithRandom(kp.Private,
FixedSecureRandom.From(Hex.Decode("0CAF2EF547EC49C4F3A6FE6DF4223A174D01F2C115D49A6F73437C29A2A8458C"))));
byte[] msg = Hex.Decode("BA7816BF8F01CFEA414140DE5DAE2223B00361A396177A9CB410FF61F20015AD");
BigInteger[] sig = signer.GenerateSignature(msg);
if (!sig[0].Equals(new BigInteger("315C875DCD4850E948B8AC42824E9483A32D5BA5ABE0681B9B9448D444F2BE3C", 16)))
{
Fail("R value incorrect");
}
if (!sig[1].Equals(new BigInteger("89718D12E54A8D9ED066E4A55F7ED5A2229CD23B9A3CEE78F83ED6AA61F6BCB9", 16)))
{
Fail("S value incorrect");
}
signer.Init(false, kp.Public);
if (!signer.VerifySignature(msg, sig[0], sig[1]))
{
Fail("signature not verified");
}
}
public override void PerformTest()
{
byte[] k1 = Hex.Decode("d5014e4b60ef2ba8b6211b4062ba3224e0427dd3");
byte[] k2 = Hex.Decode("345e8d05c075c3a508df729a1685690e68fcfb8c8117847e89063bca1f85d968fd281540b6e13bd1af989a1fbf17e06462bf511f9d0b140fb48ac1b1baa5bded");
SecureRandom random = FixedSecureRandom.From(k1, k2);
byte[] keyData = Hex.Decode("b5014e4b60ef2ba8b6211b4062ba3224e0427dd3");
SecureRandom keyRandom = FixedSecureRandom.From(keyData, keyData);
BigInteger r = new BigInteger("68076202252361894315274692543577577550894681403");
BigInteger s = new BigInteger("1089214853334067536215539335472893651470583479365");
DsaParametersGenerator pGen = new DsaParametersGenerator();
pGen.Init(512, 80, random);
DsaParameters parameters = pGen.GenerateParameters();
DsaValidationParameters pValid = parameters.ValidationParameters;
if (pValid.Counter != 105)
{
Fail("Counter wrong");
}
if (!pValue.Equals(parameters.P) || !qValue.Equals(parameters.Q))
{
Fail("p or q wrong");
}
DsaKeyPairGenerator dsaKeyGen = new DsaKeyPairGenerator();
DsaKeyGenerationParameters genParam = new DsaKeyGenerationParameters(keyRandom, parameters);
dsaKeyGen.Init(genParam);
AsymmetricCipherKeyPair pair = dsaKeyGen.GenerateKeyPair();
ParametersWithRandom param = new ParametersWithRandom(pair.Private, keyRandom);
DsaSigner dsa = new DsaSigner();
dsa.Init(true, param);
byte[] message = new BigInteger("968236873715988614170569073515315707566766479517").ToByteArrayUnsigned();
BigInteger[] sig = dsa.GenerateSignature(message);
if (!r.Equals(sig[0]))
{
Fail("r component wrong." + SimpleTest.NewLine
+ " expecting: " + r + SimpleTest.NewLine
+ " got : " + sig[0]);
}
if (!s.Equals(sig[1]))
{
Fail("s component wrong." + SimpleTest.NewLine
+ " expecting: " + s + SimpleTest.NewLine
+ " got : " + sig[1]);
}
dsa.Init(false, pair.Public);
if (!dsa.VerifySignature(message, sig[0], sig[1]))
{
Fail("verification fails");
}
Dsa2Test1();
Dsa2Test2();
Dsa2Test3();
Dsa2Test4();
}
private void Dsa2Test2()
{
byte[] seed = Hex.Decode("5AFCC1EFFC079A9CCA6ECA86D6E3CC3B18642D9BE1CC6207C84002A9");
DsaParametersGenerator pGen = new DsaParametersGenerator(new Sha224Digest());
pGen.Init(new DsaParameterGenerationParameters(2048, 224, 80, new DsaTestSecureRandom(seed)));
DsaParameters parameters = pGen.GenerateParameters();
DsaValidationParameters pv = parameters.ValidationParameters;
if (pv.Counter != 21)
{
Fail("counter incorrect");
}
if (!AreEqual(seed, pv.GetSeed()))
{
Fail("seed incorrect");
}
if (!parameters.Q.Equals(new BigInteger("90EAF4D1AF0708B1B612FF35E0A2997EB9E9D263C9CE659528945C0D", 16)))
{
Fail("Q incorrect");
}
if (!parameters.P.Equals(new BigInteger(
"C196BA05AC29E1F9C3C72D56DFFC6154" +
"A033F1477AC88EC37F09BE6C5BB95F51C296DD20D1A28A06" +
"7CCC4D4316A4BD1DCA55ED1066D438C35AEBAABF57E7DAE4" +
"28782A95ECA1C143DB701FD48533A3C18F0FE23557EA7AE6" +
"19ECACC7E0B51652A8776D02A425567DED36EABD90CA33A1" +
"E8D988F0BBB92D02D1D20290113BB562CE1FC856EEB7CDD9" +
"2D33EEA6F410859B179E7E789A8F75F645FAE2E136D252BF" +
"FAFF89528945C1ABE705A38DBC2D364AADE99BE0D0AAD82E" +
"5320121496DC65B3930E38047294FF877831A16D5228418D" +
"E8AB275D7D75651CEFED65F78AFC3EA7FE4D79B35F62A040" +
"2A1117599ADAC7B269A59F353CF450E6982D3B1702D9CA83", 16)))
{
Fail("P incorrect");
}
if (!parameters.G.Equals(new BigInteger(
"A59A749A11242C58C894E9E5A91804E8" +
"FA0AC64B56288F8D47D51B1EDC4D65444FECA0111D78F35F" +
"C9FDD4CB1F1B79A3BA9CBEE83A3F811012503C8117F98E50" +
"48B089E387AF6949BF8784EBD9EF45876F2E6A5A495BE64B" +
"6E770409494B7FEE1DBB1E4B2BC2A53D4F893D418B715959" +
"2E4FFFDF6969E91D770DAEBD0B5CB14C00AD68EC7DC1E574" +
"5EA55C706C4A1C5C88964E34D09DEB753AD418C1AD0F4FDF" +
"D049A955E5D78491C0B7A2F1575A008CCD727AB376DB6E69" +
"5515B05BD412F5B8C2F4C77EE10DA48ABD53F5DD498927EE" +
"7B692BBBCDA2FB23A516C5B4533D73980B2A3B60E384ED20" +
"0AE21B40D273651AD6060C13D97FD69AA13C5611A51B9085", 16)))
{
Fail("G incorrect");
}
DsaKeyPairGenerator kpGen = new DsaKeyPairGenerator();
kpGen.Init(new DsaKeyGenerationParameters(
FixedSecureRandom.From(Hex.Decode("00D0F09ED3E2568F6CADF9224117DA2AEC5A4300E009DE1366023E17")), parameters));
AsymmetricCipherKeyPair kp = kpGen.GenerateKeyPair();
DsaPublicKeyParameters pub = (DsaPublicKeyParameters)kp.Public;
DsaPrivateKeyParameters priv = (DsaPrivateKeyParameters)kp.Private;
if (!pub.Y.Equals(new BigInteger(
"70035C9A3B225B258F16741F3941FBF0" +
"6F3D056CD7BD864604CBB5EE9DD85304EE8E8E4ABD5E9032" +
"11DDF25CE149075510ACE166970AFDC7DF552B7244F342FA" +
"02F7A621405B754909D757F97290E1FE5036E904CF593446" +
"0C046D95659821E1597ED9F2B1F0E20863A6BBD0CE74DACB" +
"A5D8C68A90B29C2157CDEDB82EC12B81EE3068F9BF5F7F34" +
"6ECA41ED174CCCD7D154FA4F42F80FFE1BF46AE9D8125DEB" +
"5B4BA08A72BDD86596DBEDDC9550FDD650C58F5AE5133509" +
"A702F79A31ECB490F7A3C5581631F7C5BE4FF7F9E9F27FA3" +
"90E47347AD1183509FED6FCF198BA9A71AB3335B4F38BE8D" +
"15496A00B6DC2263E20A5F6B662320A3A1EC033AA61E3B68", 16)))
{
Fail("Y value incorrect");
}
if (!priv.X.Equals(
new BigInteger("00D0F09ED3E2568F6CADF9224117DA2AEC5A4300E009DE1366023E17", 16)))
{
Fail("X value incorrect");
}
DsaSigner signer = new DsaSigner();
signer.Init(true, new ParametersWithRandom(kp.Private,
FixedSecureRandom.From(Hex.Decode("735959CC4463B8B440E407EECA8A473BF6A6D1FE657546F67D401F05"))));
byte[] msg = Hex.Decode("23097D223405D8228642A477BDA255B32AADBCE4BDA0B3F7E36C9DA7");
BigInteger[] sig = signer.GenerateSignature(msg);
if (!sig[0].Equals(new BigInteger("4400138D05F9639CAF54A583CAAF25D2B76D0C3EAD752CE17DBC85FE", 16)))
{
Fail("R value incorrect");
}
if (!sig[1].Equals(new BigInteger("874D4F12CB13B61732D398445698CFA9D92381D938AA57EE2C9327B3", 16)))
{
Fail("S value incorrect");
}
signer.Init(false, kp.Public);
if (!signer.VerifySignature(msg, sig[0], sig[1]))
{
Fail("signature not verified");
}
}
private void Dsa2Test1()
{
byte[] seed = Hex.Decode("ED8BEE8D1CB89229D2903CBF0E51EE7377F48698");
DsaParametersGenerator pGen = new DsaParametersGenerator();
pGen.Init(new DsaParameterGenerationParameters(1024, 160, 80, new DsaTestSecureRandom(seed)));
DsaParameters parameters = pGen.GenerateParameters();
DsaValidationParameters pv = parameters.ValidationParameters;
if (pv.Counter != 5)
{
Fail("counter incorrect");
}
if (!AreEqual(seed, pv.GetSeed()))
{
Fail("seed incorrect");
}
if (!parameters.Q.Equals(new BigInteger("E950511EAB424B9A19A2AEB4E159B7844C589C4F", 16)))
{
Fail("Q incorrect");
}
if (!parameters.P.Equals(new BigInteger(
"E0A67598CD1B763B" +
"C98C8ABB333E5DDA0CD3AA0E5E1FB5BA8A7B4EABC10BA338" +
"FAE06DD4B90FDA70D7CF0CB0C638BE3341BEC0AF8A7330A3" +
"307DED2299A0EE606DF035177A239C34A912C202AA5F83B9" +
"C4A7CF0235B5316BFC6EFB9A248411258B30B839AF172440" +
"F32563056CB67A861158DDD90E6A894C72A5BBEF9E286C6B", 16)))
{
Fail("P incorrect");
}
if (!parameters.G.Equals(new BigInteger(
"D29D5121B0423C27" +
"69AB21843E5A3240FF19CACC792264E3BB6BE4F78EDD1B15" +
"C4DFF7F1D905431F0AB16790E1F773B5CE01C804E509066A" +
"9919F5195F4ABC58189FD9FF987389CB5BEDF21B4DAB4F8B" +
"76A055FFE2770988FE2EC2DE11AD92219F0B351869AC24DA" +
"3D7BA87011A701CE8EE7BFE49486ED4527B7186CA4610A75", 16)))
{
Fail("G incorrect");
}
DsaKeyPairGenerator kpGen = new DsaKeyPairGenerator();
kpGen.Init(new DsaKeyGenerationParameters(FixedSecureRandom.From(Hex.Decode("D0EC4E50BB290A42E9E355C73D8809345DE2E139")), parameters));
AsymmetricCipherKeyPair kp = kpGen.GenerateKeyPair();
DsaPublicKeyParameters pub = (DsaPublicKeyParameters)kp.Public;
DsaPrivateKeyParameters priv = (DsaPrivateKeyParameters)kp.Private;
if (!pub.Y.Equals(new BigInteger(
"25282217F5730501" +
"DD8DBA3EDFCF349AAFFEC20921128D70FAC44110332201BB" +
"A3F10986140CBB97C726938060473C8EC97B4731DB004293" +
"B5E730363609DF9780F8D883D8C4D41DED6A2F1E1BBBDC97" +
"9E1B9D6D3C940301F4E978D65B19041FCF1E8B518F5C0576" +
"C770FE5A7A485D8329EE2914A2DE1B5DA4A6128CEAB70F79", 16)))
{
Fail("Y value incorrect");
}
if (!priv.X.Equals(
new BigInteger("D0EC4E50BB290A42E9E355C73D8809345DE2E139", 16)))
{
Fail("X value incorrect");
}
DsaSigner signer = new DsaSigner();
signer.Init(true, new ParametersWithRandom(kp.Private, FixedSecureRandom.From(Hex.Decode("349C55648DCF992F3F33E8026CFAC87C1D2BA075"))));
byte[] msg = Hex.Decode("A9993E364706816ABA3E25717850C26C9CD0D89D");
BigInteger[] sig = signer.GenerateSignature(msg);
if (!sig[0].Equals(new BigInteger("636155AC9A4633B4665D179F9E4117DF68601F34", 16)))
{
Fail("R value incorrect");
}
if (!sig[1].Equals(new BigInteger("6C540B02D9D4852F89DF8CFC99963204F4347704", 16)))
{
Fail("S value incorrect");
}
signer.Init(false, kp.Public);
if (!signer.VerifySignature(msg, sig[0], sig[1]))
{
Fail("signature not verified");
}
}
