public void TransactionGenerateSignAndVerify(bool useBouncyCastle)
{
// Generate a keypair
EthereumEcdsa ecdsa;
if (useBouncyCastle)
{
ecdsa = EthereumEcdsaBouncyCastle.Generate(new SystemRandomAccountDerivation());
}
else
{
ecdsa = EthereumEcdsaNative.Generate(new SystemRandomAccountDerivation());
}
// Obtain our sender address for our keypair.
Address actualSender = new Address(ecdsa.GetPublicKeyHash());
// Define our chain IDs to test, including null to test pre-spurious dragon.
EthereumChainID?[] chainIDs = new EthereumChainID?[] { null, EthereumChainID.Ethereum_MainNet };
// Define our transaction to test
// Create a new transaction.
Transaction transaction = new Transaction(21, 18000000000, 100000, new Address("0xa593094cebb06bf34df7311845c2a34996b52324"), 1000000000000, null);
// Loop for each chain ID to test.
foreach (EthereumChainID?chainID in chainIDs)
{
// Sign our data
transaction.Sign(ecdsa, chainID);
// Obtain our sender from our signed transaction, verify it matches our actual sender.
Address transactionSender = transaction.GetSenderAddress();
Assert.Equal(actualSender.ToString(), transactionSender.ToString());
}
}
public void ProvidedKeySigning(bool useBouncyCastle)
{
// Use a provided private key to sign two different transactions and verify the sender should be the same.
string privateKeyStr = "e815acba8fcf085a0b4141060c13b8017a08da37f2eb1d6a5416adbb621560ef";
EthereumEcdsa provider;
if (useBouncyCastle)
{
provider = new EthereumEcdsaBouncyCastle(privateKeyStr.HexToBytes(), EthereumEcdsaKeyType.Private);
}
else
{
provider = new EthereumEcdsaNative(privateKeyStr.HexToBytes(), EthereumEcdsaKeyType.Private);
}
// Signing two different transactions with or without a chain ID should yield the same sender.
Transaction transaction1 = new Transaction(25, 77044660770, 100100, new Address("0xffff094cebb06bf34df7311845c2a34996b52324"), 2000055000000, null);
Transaction transaction2 = new Transaction(21, 18000000000, 100000, new Address("0xa593094cebb06bf34df7311845c2a34996b52324"), 1000000000000, null);
transaction1.Sign(provider);
transaction2.Sign(provider, EthereumChainID.Ethereum_MainNet);
Assert.Equal("0x75c8aa4b12bc52c1f1860bc4e8af981d6542cccd", transaction1.GetSenderAddress().ToString());
Assert.Equal("0x75c8aa4b12bc52c1f1860bc4e8af981d6542cccd", transaction2.GetSenderAddress().ToString());
Assert.Equal("0x75c8aa4b12bc52c1f1860bc4e8af981d6542cccd", new Address(provider.GetPublicKeyHash()).ToString());
}
public void GenerateSignRecoverVerify(bool useBouncyCastle)
{
// Generate ECDSA keypair, compute a hash, sign it, then recover the public key from the signature and verify it matches.
EthereumEcdsa provider;
if (useBouncyCastle)
{
provider = EthereumEcdsaBouncyCastle.Generate(new SystemRandomAccountDerivation());
}
else
{
provider = EthereumEcdsaNative.Generate(new SystemRandomAccountDerivation());
}
// Sign a hash.
byte[] hash = KeccakHash.ComputeHashBytes(new byte[] { 11, 22, 33, 44 });
(byte RecoveryID, BigInteger r, BigInteger s)signature = provider.SignData(hash);
// Recover the public key for the signature we just made and verify it.
EthereumEcdsa recovered = null;
if (useBouncyCastle)
{
recovered = EthereumEcdsaBouncyCastle.Recover(hash, signature.RecoveryID, signature.r, signature.s);
}
else
{
recovered = EthereumEcdsaNative.Recover(hash, signature.RecoveryID, signature.r, signature.s);
}
Assert.True(provider.GetPublicKeyHash().ValuesEqual(recovered.GetPublicKeyHash()));
// Verify the signature we just made.
Assert.True(recovered.VerifyData(hash, signature.r, signature.s));
// Generate a new ECDSA keypair (to verify other keypairs can't pass verification for signatures they didn't create).
EthereumEcdsa provider2;
if (useBouncyCastle)
{
provider2 = EthereumEcdsaBouncyCastle.Generate(new SystemRandomAccountDerivation());
}
else
{
provider2 = EthereumEcdsaNative.Generate(new SystemRandomAccountDerivation());
}
// Verify the prior signature cannot be verified with this new keypair.
Assert.False(provider2.VerifyData(hash, signature.r, signature.s));
}
public void PublicKeyFormatTests(bool useBouncyCastle)
{
// Test compressed, uncompressed, ethereum format public keys and verify they all equal the same resulting key.
string privateKeyStr = "e815acba8fcf085a0b4141060c13b8017a08da37f2eb1d6a5416adbb621560ef";
EthereumEcdsa provider;
if (useBouncyCastle)
{
provider = new EthereumEcdsaBouncyCastle(privateKeyStr.HexToBytes(), EthereumEcdsaKeyType.Private);
}
else
{
provider = new EthereumEcdsaNative(privateKeyStr.HexToBytes(), EthereumEcdsaKeyType.Private);
}
// Obtain our public key in different formats.
byte[] publicKeyCompressed = provider.ToPublicKeyArray(true, false);
byte[] publicKeyUncompressed = provider.ToPublicKeyArray(false, false);
byte[] publicKeyEthereum = provider.ToPublicKeyArray(false, true);
// Put them into a singular array to test.
byte[][] publicKeys = new byte[][] { publicKeyCompressed, publicKeyUncompressed, publicKeyEthereum };
// Loop for each format to test.
for (int i = 0; i < publicKeys.Length; i++)
{
// Parse the public key that is indexed.
EthereumEcdsa publicKeyProvider;
if (useBouncyCastle)
{
publicKeyProvider = new EthereumEcdsaBouncyCastle(publicKeys[i], EthereumEcdsaKeyType.Public);
}
else
{
publicKeyProvider = new EthereumEcdsaNative(publicKeys[i], EthereumEcdsaKeyType.Public);
}
// Verify the public key hashes match
Assert.Equal(provider.GetPublicKeyHash().ToHexString(), publicKeyProvider.GetPublicKeyHash().ToHexString());
}
}
public void SignAndVerify(bool useBouncyCastle)
{
// Generate ECDSA keypair, compute a hash, sign it, then recover the public key from the signature and verify it matches.
EthereumEcdsa provider;
if (useBouncyCastle)
{
provider = EthereumEcdsaBouncyCastle.Generate(new SystemRandomAccountDerivation());
}
else
{
provider = EthereumEcdsaNative.Generate(new SystemRandomAccountDerivation());
}
byte[] hash = KeccakHash.ComputeHashBytes(new byte[] { 11, 22, 33, 44 });
(byte RecoveryID, BigInteger r, BigInteger s)signature = provider.SignData(hash);
EthereumEcdsa recovered = EthereumEcdsa.Recover(hash, signature.RecoveryID, signature.r, signature.s);
Assert.True(provider.GetPublicKeyHash().ValuesEqual(recovered.GetPublicKeyHash()));
}
public void ComputeECDHKeyTest(bool useBouncyCastle, string privateKeyStr, string publicKeyStr, string expectedSecretStr)
{
// Generate ECDSA keypair
EthereumEcdsa privateKey = null;
EthereumEcdsa publicKey = null;
if (useBouncyCastle)
{
privateKey = new EthereumEcdsaBouncyCastle(privateKeyStr.HexToBytes(), EthereumEcdsaKeyType.Private);
publicKey = new EthereumEcdsaBouncyCastle(publicKeyStr.HexToBytes(), EthereumEcdsaKeyType.Public);
}
else
{
privateKey = new EthereumEcdsaNative(privateKeyStr.HexToBytes(), EthereumEcdsaKeyType.Private);
publicKey = new EthereumEcdsaNative(publicKeyStr.HexToBytes(), EthereumEcdsaKeyType.Public);
}
// Compute a shared key.
byte[] data = privateKey.ComputeECDHKey(publicKey);
Assert.Equal(expectedSecretStr, data.ToHexString(false));
}
