public static void Main(string[] args)
{
string cube3File = null;
string scriptFile = null;
if (args.Length > 0)
{
cube3File = args[0];
if (args.Length > 1)
{
scriptFile = args[1];
}
}
if (cube3File == null)
{
System.Console.WriteLine("usage: c3sg <cube3File> [<scriptFile>]");
System.Console.WriteLine("");
System.Console.WriteLine("c3sg reads cube3File and generates a script file. Will generate file");
System.Console.WriteLine("in specified scriptFile or in a file with the same name as the Cube3 File,");
System.Console.WriteLine("but with the extension CUBESCR");
System.Console.WriteLine("");
Environment.Exit(0);
}
if (scriptFile == null)
{
scriptFile = Path.GetFileNameWithoutExtension(cube3File) + ".CUBESCR";
}
engine = new BlowfishEngine(true);
generateScriptFromCube3File(cube3File, scriptFile);
}
public void saveKeysToFiles()
{
//save keys of a new user to files
using (FileStream fs = File.Create(MainWindow.publicKeysPath + "\\" + Email + ".txt"))
{
Byte[] info = new UTF8Encoding(true).GetBytes(publicKey);
fs.Write(info, 0, info.Length);
}
using (FileStream fs = File.Create(MainWindow.privateKeysPath + "\\" + Email + ".txt"))
{
Byte[] privateKeyBytes = new UTF8Encoding(true).GetBytes(privateKey);
string key = computeSha256Hash(password); //hashed password
BlowfishEngine engine = new BlowfishEngine();
PaddedBufferedBlockCipher cipher = new PaddedBufferedBlockCipher(engine); //ECB
KeyParameter keyBytes = new KeyParameter(Encoding.UTF8.GetBytes(key));
cipher.Init(true, keyBytes);
encPrivateKey = new byte[cipher.GetOutputSize(privateKeyBytes.Length)];
int len1 = cipher.ProcessBytes(privateKeyBytes, 0, privateKeyBytes.Length, encPrivateKey, 0); //private key encrypted with hashed password
cipher.DoFinal(encPrivateKey, len1);
fs.Write(encPrivateKey, 0, encPrivateKey.Length);
}
}
/**
* @param blowfishKey
*/
public NewCrypt(byte[] blowfishKey)
{
_crypt = new BlowfishEngine();
_crypt.init(true, blowfishKey);
_decrypt = new BlowfishEngine();
_decrypt.init(false, blowfishKey);
}
public void TestFunction()
{
string resultText = Perform().ToString();
BlowfishEngine blowfish = new BlowfishEngine();
// key range check
try
{
blowfish.Init(true, new KeyParameter(new byte[1]));
Fail("no exception");
}
catch (ArgumentException e)
{
Assert.AreEqual("key length must be in range 32 to 448 bits", e.Message);
}
try
{
blowfish.Init(true, new KeyParameter(new byte[59]));
Fail("no exception");
}
catch (ArgumentException e)
{
Assert.AreEqual("key length must be in range 32 to 448 bits", e.Message);
}
Assert.AreEqual(Name + ": Okay", resultText);
}
/// <summary>
/// After being initialized with a key, the schedule (p-array) and s-boxes needs some
/// work from the Blowfish engine to finish setting up.
/// </summary>
void Setup()
{
// The setup process starts with the all zero string.
UInt64 bitScape = 0;
// To set up the schedule (p-arrays),
for (int i = 0; i < 9; i++)
{
bitScape = BlowfishEngine.Encrypt(ByteOperations.Swap(bitScape), this);
Schedule.Set(i * 2, ByteOperations.Left(bitScape));
Schedule.Set(i * 2 + 1, ByteOperations.Right(bitScape));
bitScape = ByteOperations.Swap(bitScape);
}
// To finish the s-boxes
for (int i = 0; i < 1024;)
{
bitScape = BlowfishEngine.Encrypt(ByteOperations.Swap(bitScape), this);
sbox[i / 256, i % 256] = ByteOperations.Left(bitScape);
i++;
sbox[i / 256, i % 256] = ByteOperations.Right(bitScape);
i++;
bitScape = ByteOperations.Swap(bitScape);
}
}
public static void Main(string[] args)
{
string cube3File = null;
string bfbFile = null;
if (args.Length > 0)
{
bfbFile = args[0];
if (args.Length > 1)
{
cube3File = args[1];
}
}
if (bfbFile == null)
{
System.Console.WriteLine("usage: cube3Encoder <bfbFile> [<Cube3File>]");
System.Console.WriteLine("");
System.Console.WriteLine("cube3Encoder reads bfbFile and encodes into Cube3File. Will generate");
System.Console.WriteLine("into specified Cube3File or a file with the same name as the BFB File,");
System.Console.WriteLine("but with the extension Cube3");
System.Console.WriteLine("");
Environment.Exit(0);
}
if (cube3File == null)
{
cube3File = Path.GetFileNameWithoutExtension(bfbFile) + ".Cube3";
}
engine = new BlowfishEngine(true);
generateCube3FromBFBFile(bfbFile, cube3File);
}
public NewCrypt(string key)
{
byte[] blowfishKey = Encoding.UTF8.GetBytes(key);
_crypt = new BlowfishEngine();
_crypt.init(true, blowfishKey);
_decrypt = new BlowfishEngine();
_decrypt.init(false, blowfishKey);
}
public CryptoEngine(Window window, FileManager fileManager)
{
this.window = window;
this.fileManager = fileManager;
engine = new BlowfishEngine();
iv = null;
subBlockLength = 1;
}
public static void Main(string[] args)
{
int cube3FileIndex = 0;
int bfbFileIndex = 1;
bool xmlMode = false;
string cube3File = null;
string bfbFile = null;
if (args.Length > 0)
{
if (args[0].StartsWith("-") || args[0].StartsWith("/"))
{
cube3FileIndex++;
bfbFileIndex++;
if (args[0].ToUpper().Equals("-XML"))
{
xmlMode = true;
}
else
{
System.Console.WriteLine($"Invalid parameter {args[0]}!");
System.Console.WriteLine("");
displayHelp();
Environment.Exit(-1);
}
}
cube3File = args[cube3FileIndex];
if (args.Length > bfbFileIndex)
{
bfbFile = args[bfbFileIndex];
}
}
if (cube3File == null)
{
displayHelp();
Environment.Exit(0);
}
if (bfbFile == null)
{
if (!xmlMode)
{
bfbFile = Path.GetFileNameWithoutExtension(cube3File) + ".BFB";
}
else
{
bfbFile = Path.GetFileNameWithoutExtension(cube3File) + ".XML";
}
}
engine = new BlowfishEngine();
engine.UseLittleEndian = true;
generateBFBFromCube3File(cube3File, bfbFile, xmlMode);
}
const string KEY = "wHcnqpHNN"; // "STINGMIMI";
public static string Decode4odToken(string token)
{
byte[] encryptedBytes = Convert.FromBase64String(token);
BlowfishEngine bf = new BlowfishEngine();
bf.Init(false, new KeyParameter(Encoding.ASCII.GetBytes(KEY)));
byte[] decryptedBytes = decrypt(encryptedBytes, bf);
return(Encoding.ASCII.GetString(decryptedBytes));
}
static void Main(string[] args)
{
BlowfishEngine engine = new BlowfishEngine();
RestClient client = new RestClient("http://spectator.na.lol.riotgames.com:80/observer-mode/rest/");
JSON.Deserialize <Game[]>(
JSON.DeserializeDynamic(
client.Execute(new RestRequest("featured", Method.GET)).Content
).gameList
);
}
private string decryptPath(string path)
{
byte[] value = StringToBytes(path);
BlowfishEngine bf = new BlowfishEngine();
byte[] key1 = new byte[7] {
107, 108, 117, 99, 122, 121, 107
};
bf.Init(true, new KeyParameter(key1));
decrypt(value, bf);
return(Encoding.ASCII.GetString(value));
}
//private
private static byte[] encryptDecrypt(byte[] input, byte[] key, byte[] iv, BlockMode mode, BlockPadding padding, bool encrypt)
{
BlowfishEngine engine = new BlowfishEngine();
IBlockCipher cipherMode;
BufferedBlockCipher cipher;
KeyParameter keyP = new KeyParameter(key);
ParametersWithIV keyParams = new ParametersWithIV(keyP, iv);
if (mode == BlockMode.CBC)
{
cipherMode = new CbcBlockCipher(engine);
}
else if (mode == BlockMode.CFB)
{
cipherMode = new CfbBlockCipher(engine, iv.Length);
}
else if (mode == BlockMode.OFB)
{
cipherMode = new OfbBlockCipher(engine, iv.Length);
}
else
{
throw new Exception("mode must be a valid BlockMode.");
}
if (padding == BlockPadding.PKCS7Padding)
{
cipher = new PaddedBufferedBlockCipher(cipherMode, new Pkcs7Padding());
}
else if (padding == BlockPadding.ZeroBytePadding)
{
cipher = new PaddedBufferedBlockCipher(cipherMode, new ZeroBytePadding());
}
else if (padding == BlockPadding.NoPadding)
{
cipher = new BufferedBlockCipher(cipherMode);
}
else
{
throw new Exception("padding must be a valid BlockPadding.");
}
cipher.Init(encrypt, keyParams);
byte[] output = new byte[cipher.GetOutputSize(input.Length)];
int length = cipher.ProcessBytes(input, output, 0);
cipher.DoFinal(output, length);
return(output);
}
public void decryptPrivateKey(string keyString)
{
//decrypt private key with key = user password hashed with SHA-256
BlowfishEngine engine = new BlowfishEngine();
PaddedBufferedBlockCipher cipher = new PaddedBufferedBlockCipher(engine);
StringBuilder result = new StringBuilder();
cipher.Init(false, new KeyParameter(Encoding.UTF8.GetBytes(keyString)));
byte[] out2 = new byte[cipher.GetOutputSize(encPrivateKey.Length)];
int len2 = cipher.ProcessBytes(encPrivateKey, 0, encPrivateKey.Length, out2, 0);
cipher.DoFinal(out2, len2);
this.privateKey = Encoding.UTF8.GetString(out2);
}
public string Encrypt(string plainText, string key)
{
var engine = new BlowfishEngine();
var cipher = new PaddedBufferedBlockCipher(engine);
var keyBytes = new KeyParameter(Encoding.UTF8.GetBytes(key));
cipher.Init(true, keyBytes);
var plainBytes = Encoding.UTF8.GetBytes(plainText);
var result = new byte[cipher.GetOutputSize(plainBytes.Length)];
var length = cipher.ProcessBytes(plainBytes, 0, plainBytes.Length, result, 0);
cipher.DoFinal(result, length);
var base64 = Convert.ToBase64String(result);
return(base64);
}
static byte[] decrypt(byte[] byteArray, BlowfishEngine bf)
{
int blockSize = 8;
List <byte> decrypted = new List <byte>();
for (int i = 0; i < byteArray.Length; i = i + blockSize)
{
byte[] blockBytes = new byte[blockSize];
byte[] outBytes = new byte[blockSize];
for (int j = 0; j < blockSize; j++)
{
blockBytes[j] = byteArray[i + j];
}
bf.ProcessBlock(blockBytes, 0, outBytes, 0);
decrypted.AddRange(outBytes);
}
unpad(decrypted);
return(decrypted.ToArray());
}
/// <summary>
/// Encrypted the data.
/// </summary>
/// <param name="data">The data to encrypted.</param>
/// <param name="passphrase">The passphrase key used to mask the data.</param>
/// <returns>The encrypted data.</returns>
public byte[] Encrypt(byte[] data, string passphrase)
{
// Create the key parameters.
byte[] key = Encoding.Default.GetBytes(passphrase);
Key.Crypto.Parameters.KeyParameter keyParameter = new KeyParameter(key);
// Initialise the cryptography engine.
Key.Crypto.Engines.BlowfishEngine blowfish = new BlowfishEngine();
blowfish.Init(true, keyParameter);
int dataLength = data.Length;
int blockSize = blowfish.GetBlockSize();
int modBlockSize = dataLength % blockSize;
int blockCount = dataLength / blockSize;
// If there is a remained then add en extra block count.
if ((modBlockSize) > 0)
{
// Add one extra block.
blockCount++;
}
// Encrypted data store.
byte[] encryptedData = new byte[blockCount * blockSize];
byte[] decryptedData = new byte[blockCount * blockSize];
// Copy the decrypted data.
for (int j = 0; j < dataLength; j++)
{
// Assign the data.
decryptedData[j] = data[j];
}
// For each block size in the the data.
for (int i = 0; i < blockCount; i++)
{
// Encrypt the block.
blowfish.ProcessBlock(decryptedData, (i * blockSize), encryptedData, (i * blockSize));
}
// Return the encrypted data.
return(encryptedData);
}
public static ArrayLease <byte> DecryptBytes(ArraySegment <byte> ciphertext, ArraySegment <byte> key, out int count)
{
// Blowfish processes things in blocks of 8, so
// it doesn't make sense to have a non-multiple
// of 8 length ciphertext (TODO: right?)
if ((ciphertext.Count & 7) != 0) // ciphertext.Count % 8 != 0
{
// TODO: Have a Strings.resx file for this
// Does project.json support that? / What benefits will that yield?
throw new ArgumentException(
message: "The length of the ciphertext needs to be divisible by 8.",
paramName: nameof(ciphertext));
}
// Since there's guaranteed to be no leftover,
// the count is just ciphertext.Count
count = ciphertext.Count;
var engine = new BlowfishEngine();
var keyParameter = new KeyParameter(key.Array, key.Offset, key.Count);
engine.Init(forEncryption: false, parameters: keyParameter);
var lease = ArrayPool <byte> .Shared.Lease(count);
try
{
var encryptBuffer = ciphertext.Array;
var decryptBuffer = lease.Array;
for (int i = 0; i < count; i += 8)
{
engine.ProcessBlock(encryptBuffer, ciphertext.Offset + i, decryptBuffer, i);
}
}
catch
{
lease.Dispose();
throw;
}
return(lease);
}
public byte[] BlowfishEncrypt(byte[] contentBytes, string key)
{
try
{
//create blowfish engine
BlowfishEngine engine = new BlowfishEngine();
//create block cipher based on user choice
PaddedBufferedBlockCipher cipher = null;
switch (encryptTypes[encryptTypeIndex])
{
case "ECB":
cipher = new PaddedBufferedBlockCipher(engine);
break;
case "CBC":
cipher = new PaddedBufferedBlockCipher(new CbcBlockCipher(engine));
break;
case "CFB":
cipher = new PaddedBufferedBlockCipher(new CfbBlockCipher(engine, blockSize));
break;
case "OFB":
cipher = new PaddedBufferedBlockCipher(new OfbBlockCipher(engine, blockSize));
break;
}
//create key
KeyParameter keyBytes = new KeyParameter(Encoding.GetBytes(key));
cipher.Init(true, keyBytes);
//create byte array for encrypted data
byte[] outB = new byte[cipher.GetOutputSize(contentBytes.Length)];
int len1 = cipher.ProcessBytes(contentBytes, 0, contentBytes.Length, outB, 0);
cipher.DoFinal(outB, len1);
return(outB);
}
catch (Exception)
{
return(null);
}
}
public string EncryptWithBouncyCastle(
string token,
string encryptionKey
)
{
IBlockCipher blowFishCipher = new BlowfishEngine();
PaddedBufferedBlockCipher cipher = new PaddedBufferedBlockCipher(blowFishCipher);
cipher.Init(true, new KeyParameter(Base64.Decode(encryptionKey)));
var encoder = new ASCIIEncoding();
byte[] tokenBytes = encoder.GetBytes(token);
byte[] encryptedTokenBytes = cipher.DoFinal(tokenBytes);
var encryptedToken = Convert.ToBase64String(encryptedTokenBytes);
return(encryptedToken);
}
private static byte[] DecryptChunks(byte[] downloadBytes, long streamLength, byte[] keyBytes)
{
var decryptedBytes = new byte[streamLength];
var chunkSize = 2048;
var progress = 0;
while (progress < streamLength)
{
if (streamLength - progress < 2048)
{
chunkSize = (int)streamLength - progress;
}
var encryptedChunk = new byte[chunkSize];
Buffer.BlockCopy(downloadBytes, progress, encryptedChunk, 0, chunkSize);
// this will only decrypt every third chunk and if it's not at the end
if (progress % (chunkSize * 3) == 0 && chunkSize == 2048)
{
var blowfishEngine = new BlowfishEngine();
var cipher = new PaddedBufferedBlockCipher(new CbcBlockCipher(blowfishEngine), new ZeroBytePadding());
var keyParameter = new KeyParameter(keyBytes);
var parameters = new ParametersWithIV(keyParameter, new byte[] { 0, 1, 2, 3, 4, 5, 6, 7 });
cipher.Init(false, parameters);
var output = new byte[cipher.GetOutputSize(encryptedChunk.Length)];
int len = cipher.ProcessBytes(encryptedChunk, 0, encryptedChunk.Length, output, 0);
cipher.DoFinal(output, len);
Buffer.BlockCopy(output, 0, encryptedChunk, 0, output.Length);
}
Buffer.BlockCopy(encryptedChunk, 0, decryptedBytes, progress, encryptedChunk.Length);
progress += chunkSize;
}
return(decryptedBytes);
}
private void decrypt(byte[] value, BlowfishEngine bf)
{
int blockSize = bf.GetBlockSize();
byte[] vector = new byte[blockSize];
for (int i = 0; i < blockSize; i++)
{
vector[i] = 0;
}
for (int i = 0; i < value.Length; i += blockSize)
{
byte[] tmp = new byte[blockSize];
bf.ProcessBlock(vector, 0, tmp, 0);
int chunk = Math.Min(blockSize, value.Length - i);
for (int j = 0; j < chunk; j++)
{
vector[j] = value[i + j];
value[(i + j)] = (byte)(value[(i + j)] ^ tmp[j]);
}
;
}
;
}
static private string BlowfishEncrypt(string strValue, string key)
{
try
{
Encoding encoding = Encoding.UTF8;
BlowfishEngine engine = new BlowfishEngine();
PaddedBufferedBlockCipher cipher = new PaddedBufferedBlockCipher(engine);
cipher.Init(true, new KeyParameter(encoding.GetBytes(key)));
byte[] inn = encoding.GetBytes(strValue);
byte[] outt = new byte[cipher.GetOutputSize(inn.Length)];
int len1 = cipher.ProcessBytes(inn, 0, inn.Length, outt, 0);
cipher.DoFinal(outt, len1);
return(BitConverter.ToString(outt).Replace("-", ""));
}
catch (Exception)
{
return("");
}
}
public byte[] BlowfishDecrypt(byte[] contentBytes, string keyString, string cipherMode)
{
//create blowfish engine
BlowfishEngine engine = new BlowfishEngine();
//create block cipher based on user choice
PaddedBufferedBlockCipher cipher = null;
switch (cipherMode)
{
case "ECB":
cipher = new PaddedBufferedBlockCipher(engine);
break;
case "CBC":
cipher = new PaddedBufferedBlockCipher(new CbcBlockCipher(engine));
break;
case "CFB":
cipher = new PaddedBufferedBlockCipher(new CfbBlockCipher(engine, blockSize));
break;
case "OFB":
cipher = new PaddedBufferedBlockCipher(new OfbBlockCipher(engine, blockSize));
break;
}
StringBuilder result = new StringBuilder();
cipher.Init(false, new KeyParameter(Encoding.GetBytes(keyString)));
byte[] out2 = new byte[cipher.GetOutputSize(contentBytes.Length)];
int len2 = cipher.ProcessBytes(contentBytes, 0, contentBytes.Length, out2, 0);
cipher.DoFinal(out2, len2);
return(out2);
}
private static byte[] ProcessData(byte[] data, byte[] key, bool forEncryption)
{
byte[] input = data;
bool paddingRequired = data.Length % BlockSize > 0;
if (paddingRequired)
{
input = new byte[data.Length + BlockSize - data.Length % BlockSize];
Buffer.BlockCopy(data, 0, input, 0, data.Length);
}
byte[] output = new byte[input.Length];
BlowfishEngine engine = new BlowfishEngine();
engine.Init(forEncryption, key);
int offset = 0;
while (offset < input.Length)
{
engine.ProcessBlock(input, offset, output, offset);
offset += BlockSize;
}
if (paddingRequired)
{
byte[] unpaddedOutput = new byte[data.Length];
Buffer.BlockCopy(output, 0, unpaddedOutput, 0, unpaddedOutput.Length);
return(unpaddedOutput);
}
return(output);
}
public static IBufferedCipher GetCipher(
string algorithm)
{
if (algorithm == null)
{
throw new ArgumentNullException("algorithm");
}
algorithm = Platform.ToUpperInvariant(algorithm);
{
string aliased = (string)algorithms[algorithm];
if (aliased != null)
{
algorithm = aliased;
}
}
IBasicAgreement iesAgreement = null;
if (algorithm == "IES")
{
iesAgreement = new DHBasicAgreement();
}
else if (algorithm == "ECIES")
{
iesAgreement = new ECDHBasicAgreement();
}
if (iesAgreement != null)
{
return(new BufferedIesCipher(
new IesEngine(
iesAgreement,
new Kdf2BytesGenerator(
new Sha1Digest()),
new HMac(
new Sha1Digest()))));
}
if (Platform.StartsWith(algorithm, "PBE"))
{
if (Platform.EndsWith(algorithm, "-CBC"))
{
if (algorithm == "PBEWITHSHA1ANDDES-CBC")
{
return(new PaddedBufferedBlockCipher(
new CbcBlockCipher(new DesEngine())));
}
else if (algorithm == "PBEWITHSHA1ANDRC2-CBC")
{
return(new PaddedBufferedBlockCipher(
new CbcBlockCipher(new RC2Engine())));
}
else if (Strings.IsOneOf(algorithm,
"PBEWITHSHAAND2-KEYTRIPLEDES-CBC", "PBEWITHSHAAND3-KEYTRIPLEDES-CBC"))
{
return(new PaddedBufferedBlockCipher(
new CbcBlockCipher(new DesEdeEngine())));
}
else if (Strings.IsOneOf(algorithm,
"PBEWITHSHAAND128BITRC2-CBC", "PBEWITHSHAAND40BITRC2-CBC"))
{
return(new PaddedBufferedBlockCipher(
new CbcBlockCipher(new RC2Engine())));
}
}
else if (Platform.EndsWith(algorithm, "-BC") || Platform.EndsWith(algorithm, "-OPENSSL"))
{
if (Strings.IsOneOf(algorithm,
"PBEWITHSHAAND128BITAES-CBC-BC",
"PBEWITHSHAAND192BITAES-CBC-BC",
"PBEWITHSHAAND256BITAES-CBC-BC",
"PBEWITHSHA256AND128BITAES-CBC-BC",
"PBEWITHSHA256AND192BITAES-CBC-BC",
"PBEWITHSHA256AND256BITAES-CBC-BC",
"PBEWITHMD5AND128BITAES-CBC-OPENSSL",
"PBEWITHMD5AND192BITAES-CBC-OPENSSL",
"PBEWITHMD5AND256BITAES-CBC-OPENSSL"))
{
return(new PaddedBufferedBlockCipher(
new CbcBlockCipher(new AesFastEngine())));
}
}
}
string[] parts = algorithm.Split('/');
IBlockCipher blockCipher = null;
IAsymmetricBlockCipher asymBlockCipher = null;
IStreamCipher streamCipher = null;
string algorithmName = parts[0];
{
string aliased = (string)algorithms[algorithmName];
if (aliased != null)
{
algorithmName = aliased;
}
}
CipherAlgorithm cipherAlgorithm;
try
{
cipherAlgorithm = (CipherAlgorithm)Enums.GetEnumValue(typeof(CipherAlgorithm), algorithmName);
}
catch (ArgumentException)
{
throw new SecurityUtilityException("Cipher " + algorithm + " not recognised.");
}
switch (cipherAlgorithm)
{
case CipherAlgorithm.AES:
blockCipher = new AesFastEngine();
break;
case CipherAlgorithm.ARC4:
streamCipher = new RC4Engine();
break;
case CipherAlgorithm.BLOWFISH:
blockCipher = new BlowfishEngine();
break;
case CipherAlgorithm.CAMELLIA:
blockCipher = new CamelliaEngine();
break;
case CipherAlgorithm.CAST5:
blockCipher = new Cast5Engine();
break;
case CipherAlgorithm.CAST6:
blockCipher = new Cast6Engine();
break;
case CipherAlgorithm.DES:
blockCipher = new DesEngine();
break;
case CipherAlgorithm.DESEDE:
blockCipher = new DesEdeEngine();
break;
case CipherAlgorithm.ELGAMAL:
asymBlockCipher = new ElGamalEngine();
break;
case CipherAlgorithm.GOST28147:
blockCipher = new Gost28147Engine();
break;
case CipherAlgorithm.HC128:
streamCipher = new HC128Engine();
break;
case CipherAlgorithm.HC256:
streamCipher = new HC256Engine();
break;
case CipherAlgorithm.IDEA:
blockCipher = new IdeaEngine();
break;
case CipherAlgorithm.NOEKEON:
blockCipher = new NoekeonEngine();
break;
case CipherAlgorithm.PBEWITHSHAAND128BITRC4:
case CipherAlgorithm.PBEWITHSHAAND40BITRC4:
streamCipher = new RC4Engine();
break;
case CipherAlgorithm.RC2:
blockCipher = new RC2Engine();
break;
case CipherAlgorithm.RC5:
blockCipher = new RC532Engine();
break;
case CipherAlgorithm.RC5_64:
blockCipher = new RC564Engine();
break;
case CipherAlgorithm.RC6:
blockCipher = new RC6Engine();
break;
case CipherAlgorithm.RIJNDAEL:
blockCipher = new RijndaelEngine();
break;
case CipherAlgorithm.RSA:
asymBlockCipher = new RsaBlindedEngine();
break;
case CipherAlgorithm.SALSA20:
streamCipher = new Salsa20Engine();
break;
case CipherAlgorithm.SEED:
blockCipher = new SeedEngine();
break;
case CipherAlgorithm.SERPENT:
blockCipher = new SerpentEngine();
break;
case CipherAlgorithm.SKIPJACK:
blockCipher = new SkipjackEngine();
break;
case CipherAlgorithm.TEA:
blockCipher = new TeaEngine();
break;
case CipherAlgorithm.THREEFISH_256:
blockCipher = new ThreefishEngine(ThreefishEngine.BLOCKSIZE_256);
break;
case CipherAlgorithm.THREEFISH_512:
blockCipher = new ThreefishEngine(ThreefishEngine.BLOCKSIZE_512);
break;
case CipherAlgorithm.THREEFISH_1024:
blockCipher = new ThreefishEngine(ThreefishEngine.BLOCKSIZE_1024);
break;
case CipherAlgorithm.TNEPRES:
blockCipher = new TnepresEngine();
break;
case CipherAlgorithm.TWOFISH:
blockCipher = new TwofishEngine();
break;
case CipherAlgorithm.VMPC:
streamCipher = new VmpcEngine();
break;
case CipherAlgorithm.VMPC_KSA3:
streamCipher = new VmpcKsa3Engine();
break;
case CipherAlgorithm.XTEA:
blockCipher = new XteaEngine();
break;
default:
throw new SecurityUtilityException("Cipher " + algorithm + " not recognised.");
}
if (streamCipher != null)
{
if (parts.Length > 1)
{
throw new ArgumentException("Modes and paddings not used for stream ciphers");
}
return(new BufferedStreamCipher(streamCipher));
}
bool cts = false;
bool padded = true;
IBlockCipherPadding padding = null;
IAeadBlockCipher aeadBlockCipher = null;
if (parts.Length > 2)
{
if (streamCipher != null)
{
throw new ArgumentException("Paddings not used for stream ciphers");
}
string paddingName = parts[2];
CipherPadding cipherPadding;
if (paddingName == "")
{
cipherPadding = CipherPadding.RAW;
}
else if (paddingName == "X9.23PADDING")
{
cipherPadding = CipherPadding.X923PADDING;
}
else
{
try
{
cipherPadding = (CipherPadding)Enums.GetEnumValue(typeof(CipherPadding), paddingName);
}
catch (ArgumentException)
{
throw new SecurityUtilityException("Cipher " + algorithm + " not recognised.");
}
}
switch (cipherPadding)
{
case CipherPadding.NOPADDING:
padded = false;
break;
case CipherPadding.RAW:
break;
case CipherPadding.ISO10126PADDING:
case CipherPadding.ISO10126D2PADDING:
case CipherPadding.ISO10126_2PADDING:
padding = new ISO10126d2Padding();
break;
case CipherPadding.ISO7816_4PADDING:
case CipherPadding.ISO9797_1PADDING:
padding = new ISO7816d4Padding();
break;
case CipherPadding.ISO9796_1:
case CipherPadding.ISO9796_1PADDING:
asymBlockCipher = new ISO9796d1Encoding(asymBlockCipher);
break;
case CipherPadding.OAEP:
case CipherPadding.OAEPPADDING:
asymBlockCipher = new OaepEncoding(asymBlockCipher);
break;
case CipherPadding.OAEPWITHMD5ANDMGF1PADDING:
asymBlockCipher = new OaepEncoding(asymBlockCipher, new MD5Digest());
break;
case CipherPadding.OAEPWITHSHA1ANDMGF1PADDING:
case CipherPadding.OAEPWITHSHA_1ANDMGF1PADDING:
asymBlockCipher = new OaepEncoding(asymBlockCipher, new Sha1Digest());
break;
case CipherPadding.OAEPWITHSHA224ANDMGF1PADDING:
case CipherPadding.OAEPWITHSHA_224ANDMGF1PADDING:
asymBlockCipher = new OaepEncoding(asymBlockCipher, new Sha224Digest());
break;
case CipherPadding.OAEPWITHSHA256ANDMGF1PADDING:
case CipherPadding.OAEPWITHSHA_256ANDMGF1PADDING:
asymBlockCipher = new OaepEncoding(asymBlockCipher, new Sha256Digest());
break;
case CipherPadding.OAEPWITHSHA384ANDMGF1PADDING:
case CipherPadding.OAEPWITHSHA_384ANDMGF1PADDING:
asymBlockCipher = new OaepEncoding(asymBlockCipher, new Sha384Digest());
break;
case CipherPadding.OAEPWITHSHA512ANDMGF1PADDING:
case CipherPadding.OAEPWITHSHA_512ANDMGF1PADDING:
asymBlockCipher = new OaepEncoding(asymBlockCipher, new Sha512Digest());
break;
case CipherPadding.PKCS1:
case CipherPadding.PKCS1PADDING:
asymBlockCipher = new Pkcs1Encoding(asymBlockCipher);
break;
case CipherPadding.PKCS5:
case CipherPadding.PKCS5PADDING:
case CipherPadding.PKCS7:
case CipherPadding.PKCS7PADDING:
padding = new Pkcs7Padding();
break;
case CipherPadding.TBCPADDING:
padding = new TbcPadding();
break;
case CipherPadding.WITHCTS:
cts = true;
break;
case CipherPadding.X923PADDING:
padding = new X923Padding();
break;
case CipherPadding.ZEROBYTEPADDING:
padding = new ZeroBytePadding();
break;
default:
throw new SecurityUtilityException("Cipher " + algorithm + " not recognised.");
}
}
string mode = "";
if (parts.Length > 1)
{
mode = parts[1];
int di = GetDigitIndex(mode);
string modeName = di >= 0 ? mode.Substring(0, di) : mode;
try
{
CipherMode cipherMode = modeName == ""
? CipherMode.NONE
: (CipherMode)Enums.GetEnumValue(typeof(CipherMode), modeName);
switch (cipherMode)
{
case CipherMode.ECB:
case CipherMode.NONE:
break;
case CipherMode.CBC:
blockCipher = new CbcBlockCipher(blockCipher);
break;
case CipherMode.CCM:
aeadBlockCipher = new CcmBlockCipher(blockCipher);
break;
case CipherMode.CFB:
{
int bits = (di < 0)
? 8 * blockCipher.GetBlockSize()
: int.Parse(mode.Substring(di));
blockCipher = new CfbBlockCipher(blockCipher, bits);
break;
}
case CipherMode.CTR:
blockCipher = new SicBlockCipher(blockCipher);
break;
case CipherMode.CTS:
cts = true;
blockCipher = new CbcBlockCipher(blockCipher);
break;
case CipherMode.EAX:
aeadBlockCipher = new EaxBlockCipher(blockCipher);
break;
case CipherMode.GCM:
aeadBlockCipher = new GcmBlockCipher(blockCipher);
break;
case CipherMode.GOFB:
blockCipher = new GOfbBlockCipher(blockCipher);
break;
case CipherMode.OCB:
aeadBlockCipher = new OcbBlockCipher(blockCipher, CreateBlockCipher(cipherAlgorithm));
break;
case CipherMode.OFB:
{
int bits = (di < 0)
? 8 * blockCipher.GetBlockSize()
: int.Parse(mode.Substring(di));
blockCipher = new OfbBlockCipher(blockCipher, bits);
break;
}
case CipherMode.OPENPGPCFB:
blockCipher = new OpenPgpCfbBlockCipher(blockCipher);
break;
case CipherMode.SIC:
if (blockCipher.GetBlockSize() < 16)
{
throw new ArgumentException("Warning: SIC-Mode can become a twotime-pad if the blocksize of the cipher is too small. Use a cipher with a block size of at least 128 bits (e.g. AES)");
}
blockCipher = new SicBlockCipher(blockCipher);
break;
default:
throw new SecurityUtilityException("Cipher " + algorithm + " not recognised.");
}
}
catch (ArgumentException)
{
throw new SecurityUtilityException("Cipher " + algorithm + " not recognised.");
}
}
if (aeadBlockCipher != null)
{
if (cts)
{
throw new SecurityUtilityException("CTS mode not valid for AEAD ciphers.");
}
if (padded && parts.Length > 2 && parts[2] != "")
{
throw new SecurityUtilityException("Bad padding specified for AEAD cipher.");
}
return(new BufferedAeadBlockCipher(aeadBlockCipher));
}
if (blockCipher != null)
{
if (cts)
{
return(new CtsBlockCipher(blockCipher));
}
if (padding != null)
{
return(new PaddedBufferedBlockCipher(blockCipher, padding));
}
if (!padded || blockCipher.IsPartialBlockOkay)
{
return(new BufferedBlockCipher(blockCipher));
}
return(new PaddedBufferedBlockCipher(blockCipher));
}
if (asymBlockCipher != null)
{
return(new BufferedAsymmetricBlockCipher(asymBlockCipher));
}
throw new SecurityUtilityException("Cipher " + algorithm + " not recognised.");
}
/// <summary>
/// Build the engine
/// </summary>
/// <param name="algorithm">SymmetricBlockAlgorithm enum, algorithm name</param>
/// <returns>IBlockCipher with the algorithm Engine</returns>
internal IBlockCipher getCipherEngine(SymmetricBlockAlgorithm algorithm)
{
IBlockCipher engine = null;
switch (algorithm)
{
case SymmetricBlockAlgorithm.AES:
engine = new AesEngine();
break;
case SymmetricBlockAlgorithm.BLOWFISH:
engine = new BlowfishEngine();
break;
case SymmetricBlockAlgorithm.CAMELLIA:
engine = new CamelliaEngine();
break;
case SymmetricBlockAlgorithm.CAST5:
engine = new Cast5Engine();
break;
case SymmetricBlockAlgorithm.CAST6:
engine = new Cast6Engine();
break;
case SymmetricBlockAlgorithm.DES:
engine = new DesEngine();
break;
case SymmetricBlockAlgorithm.TRIPLEDES:
engine = new DesEdeEngine();
break;
case SymmetricBlockAlgorithm.DSTU7624_128:
engine = new Dstu7624Engine(SymmetricBlockAlgorithmUtils.getBlockSize(SymmetricBlockAlgorithm.DSTU7624_128, this.error));
break;
case SymmetricBlockAlgorithm.DSTU7624_256:
engine = new Dstu7624Engine(SymmetricBlockAlgorithmUtils.getBlockSize(SymmetricBlockAlgorithm.DSTU7624_256, this.error));
break;
case SymmetricBlockAlgorithm.DSTU7624_512:
engine = new Dstu7624Engine(SymmetricBlockAlgorithmUtils.getBlockSize(SymmetricBlockAlgorithm.DSTU7624_512, this.error));
break;
case SymmetricBlockAlgorithm.GOST28147:
engine = new Gost28147Engine();
break;
case SymmetricBlockAlgorithm.NOEKEON:
engine = new NoekeonEngine();
break;
case SymmetricBlockAlgorithm.RC2:
engine = new RC2Engine();
break;
case SymmetricBlockAlgorithm.RC532:
engine = new RC532Engine();
break;
case SymmetricBlockAlgorithm.RC564:
engine = new RC564Engine();
break;
case SymmetricBlockAlgorithm.RC6:
engine = new RC6Engine();
break;
case SymmetricBlockAlgorithm.RIJNDAEL_128:
engine = new RijndaelEngine(SymmetricBlockAlgorithmUtils.getBlockSize(SymmetricBlockAlgorithm.RIJNDAEL_128, this.error));
break;
case SymmetricBlockAlgorithm.RIJNDAEL_160:
engine = new RijndaelEngine(SymmetricBlockAlgorithmUtils.getBlockSize(SymmetricBlockAlgorithm.RIJNDAEL_160, this.error));
break;
case SymmetricBlockAlgorithm.RIJNDAEL_192:
engine = new RijndaelEngine(SymmetricBlockAlgorithmUtils.getBlockSize(SymmetricBlockAlgorithm.RIJNDAEL_192, this.error));
break;
case SymmetricBlockAlgorithm.RIJNDAEL_224:
engine = new RijndaelEngine(SymmetricBlockAlgorithmUtils.getBlockSize(SymmetricBlockAlgorithm.RIJNDAEL_224, this.error));
break;
case SymmetricBlockAlgorithm.RIJNDAEL_256:
engine = new RijndaelEngine(SymmetricBlockAlgorithmUtils.getBlockSize(SymmetricBlockAlgorithm.RIJNDAEL_256, this.error));
break;
case SymmetricBlockAlgorithm.SEED:
engine = new SeedEngine();
break;
case SymmetricBlockAlgorithm.SERPENT:
engine = new SerpentEngine();
break;
case SymmetricBlockAlgorithm.SKIPJACK:
engine = new SkipjackEngine();
break;
case SymmetricBlockAlgorithm.SM4:
engine = new SM4Engine();
break;
case SymmetricBlockAlgorithm.TEA:
engine = new TeaEngine();
break;
case SymmetricBlockAlgorithm.THREEFISH_256:
engine = new ThreefishEngine(SymmetricBlockAlgorithmUtils.getBlockSize(SymmetricBlockAlgorithm.THREEFISH_256, this.error));
break;
case SymmetricBlockAlgorithm.THREEFISH_512:
engine = new ThreefishEngine(SymmetricBlockAlgorithmUtils.getBlockSize(SymmetricBlockAlgorithm.THREEFISH_512, this.error));
break;
case SymmetricBlockAlgorithm.THREEFISH_1024:
engine = new ThreefishEngine(SymmetricBlockAlgorithmUtils.getBlockSize(SymmetricBlockAlgorithm.THREEFISH_1024, this.error));
break;
case SymmetricBlockAlgorithm.TWOFISH:
engine = new TwofishEngine();
break;
case SymmetricBlockAlgorithm.XTEA:
engine = new XteaEngine();
break;
default:
this.error.setError("SB020", "Cipher " + algorithm + " not recognised.");
break;
}
return(engine);
}
public static IBufferedCipher GetCipher(
string algorithm)
{
if (algorithm == null)
throw new ArgumentNullException("algorithm");
algorithm = Platform.ToUpperInvariant(algorithm);
{
string aliased = (string) algorithms[algorithm];
if (aliased != null)
algorithm = aliased;
}
IBasicAgreement iesAgreement = null;
if (algorithm == "IES")
{
iesAgreement = new DHBasicAgreement();
}
else if (algorithm == "ECIES")
{
iesAgreement = new ECDHBasicAgreement();
}
if (iesAgreement != null)
{
return new BufferedIesCipher(
new IesEngine(
iesAgreement,
new Kdf2BytesGenerator(
new Sha1Digest()),
new HMac(
new Sha1Digest())));
}
if (algorithm.StartsWith("PBE"))
{
if (algorithm.EndsWith("-CBC"))
{
if (algorithm == "PBEWITHSHA1ANDDES-CBC")
{
return new PaddedBufferedBlockCipher(
new CbcBlockCipher(new DesEngine()));
}
else if (algorithm == "PBEWITHSHA1ANDRC2-CBC")
{
return new PaddedBufferedBlockCipher(
new CbcBlockCipher(new RC2Engine()));
}
else if (Strings.IsOneOf(algorithm,
"PBEWITHSHAAND2-KEYTRIPLEDES-CBC", "PBEWITHSHAAND3-KEYTRIPLEDES-CBC"))
{
return new PaddedBufferedBlockCipher(
new CbcBlockCipher(new DesEdeEngine()));
}
else if (Strings.IsOneOf(algorithm,
"PBEWITHSHAAND128BITRC2-CBC", "PBEWITHSHAAND40BITRC2-CBC"))
{
return new PaddedBufferedBlockCipher(
new CbcBlockCipher(new RC2Engine()));
}
}
else if (algorithm.EndsWith("-BC") || algorithm.EndsWith("-OPENSSL"))
{
if (Strings.IsOneOf(algorithm,
"PBEWITHSHAAND128BITAES-CBC-BC",
"PBEWITHSHAAND192BITAES-CBC-BC",
"PBEWITHSHAAND256BITAES-CBC-BC",
"PBEWITHSHA256AND128BITAES-CBC-BC",
"PBEWITHSHA256AND192BITAES-CBC-BC",
"PBEWITHSHA256AND256BITAES-CBC-BC",
"PBEWITHMD5AND128BITAES-CBC-OPENSSL",
"PBEWITHMD5AND192BITAES-CBC-OPENSSL",
"PBEWITHMD5AND256BITAES-CBC-OPENSSL"))
{
return new PaddedBufferedBlockCipher(
new CbcBlockCipher(new AesFastEngine()));
}
}
}
string[] parts = algorithm.Split('/');
IBlockCipher blockCipher = null;
IAsymmetricBlockCipher asymBlockCipher = null;
IStreamCipher streamCipher = null;
string algorithmName = parts[0];
{
string aliased = (string)algorithms[algorithmName];
if (aliased != null)
algorithmName = aliased;
}
CipherAlgorithm cipherAlgorithm;
try
{
cipherAlgorithm = (CipherAlgorithm)Enums.GetEnumValue(typeof(CipherAlgorithm), algorithmName);
}
catch (ArgumentException)
{
throw new SecurityUtilityException("Cipher " + algorithm + " not recognised.");
}
switch (cipherAlgorithm)
{
case CipherAlgorithm.AES:
blockCipher = new AesFastEngine();
break;
case CipherAlgorithm.ARC4:
streamCipher = new RC4Engine();
break;
case CipherAlgorithm.BLOWFISH:
blockCipher = new BlowfishEngine();
break;
case CipherAlgorithm.CAMELLIA:
blockCipher = new CamelliaEngine();
break;
case CipherAlgorithm.CAST5:
blockCipher = new Cast5Engine();
break;
case CipherAlgorithm.CAST6:
blockCipher = new Cast6Engine();
break;
case CipherAlgorithm.DES:
blockCipher = new DesEngine();
break;
case CipherAlgorithm.DESEDE:
blockCipher = new DesEdeEngine();
break;
case CipherAlgorithm.ELGAMAL:
asymBlockCipher = new ElGamalEngine();
break;
case CipherAlgorithm.GOST28147:
blockCipher = new Gost28147Engine();
break;
case CipherAlgorithm.HC128:
streamCipher = new HC128Engine();
break;
case CipherAlgorithm.HC256:
streamCipher = new HC256Engine();
break;
case CipherAlgorithm.IDEA:
blockCipher = new IdeaEngine();
break;
case CipherAlgorithm.NOEKEON:
blockCipher = new NoekeonEngine();
break;
case CipherAlgorithm.PBEWITHSHAAND128BITRC4:
case CipherAlgorithm.PBEWITHSHAAND40BITRC4:
streamCipher = new RC4Engine();
break;
case CipherAlgorithm.RC2:
blockCipher = new RC2Engine();
break;
case CipherAlgorithm.RC5:
blockCipher = new RC532Engine();
break;
case CipherAlgorithm.RC5_64:
blockCipher = new RC564Engine();
break;
case CipherAlgorithm.RC6:
blockCipher = new RC6Engine();
break;
case CipherAlgorithm.RIJNDAEL:
blockCipher = new RijndaelEngine();
break;
case CipherAlgorithm.RSA:
asymBlockCipher = new RsaBlindedEngine();
break;
case CipherAlgorithm.SALSA20:
streamCipher = new Salsa20Engine();
break;
case CipherAlgorithm.SEED:
blockCipher = new SeedEngine();
break;
case CipherAlgorithm.SERPENT:
blockCipher = new SerpentEngine();
break;
case CipherAlgorithm.SKIPJACK:
blockCipher = new SkipjackEngine();
break;
case CipherAlgorithm.TEA:
blockCipher = new TeaEngine();
break;
case CipherAlgorithm.TWOFISH:
blockCipher = new TwofishEngine();
break;
case CipherAlgorithm.VMPC:
streamCipher = new VmpcEngine();
break;
case CipherAlgorithm.VMPC_KSA3:
streamCipher = new VmpcKsa3Engine();
break;
case CipherAlgorithm.XTEA:
blockCipher = new XteaEngine();
break;
default:
throw new SecurityUtilityException("Cipher " + algorithm + " not recognised.");
}
if (streamCipher != null)
{
if (parts.Length > 1)
throw new ArgumentException("Modes and paddings not used for stream ciphers");
return new BufferedStreamCipher(streamCipher);
}
bool cts = false;
bool padded = true;
IBlockCipherPadding padding = null;
IAeadBlockCipher aeadBlockCipher = null;
if (parts.Length > 2)
{
if (streamCipher != null)
throw new ArgumentException("Paddings not used for stream ciphers");
string paddingName = parts[2];
CipherPadding cipherPadding;
if (paddingName == "")
{
cipherPadding = CipherPadding.RAW;
}
else if (paddingName == "X9.23PADDING")
{
cipherPadding = CipherPadding.X923PADDING;
}
else
{
try
{
cipherPadding = (CipherPadding)Enums.GetEnumValue(typeof(CipherPadding), paddingName);
}
catch (ArgumentException)
{
throw new SecurityUtilityException("Cipher " + algorithm + " not recognised.");
}
}
switch (cipherPadding)
{
case CipherPadding.NOPADDING:
padded = false;
break;
case CipherPadding.RAW:
break;
case CipherPadding.ISO10126PADDING:
case CipherPadding.ISO10126D2PADDING:
case CipherPadding.ISO10126_2PADDING:
padding = new ISO10126d2Padding();
break;
case CipherPadding.ISO7816_4PADDING:
case CipherPadding.ISO9797_1PADDING:
padding = new ISO7816d4Padding();
break;
case CipherPadding.ISO9796_1:
case CipherPadding.ISO9796_1PADDING:
asymBlockCipher = new ISO9796d1Encoding(asymBlockCipher);
break;
case CipherPadding.OAEP:
case CipherPadding.OAEPPADDING:
asymBlockCipher = new OaepEncoding(asymBlockCipher);
break;
case CipherPadding.OAEPWITHMD5ANDMGF1PADDING:
asymBlockCipher = new OaepEncoding(asymBlockCipher, new MD5Digest());
break;
case CipherPadding.OAEPWITHSHA1ANDMGF1PADDING:
case CipherPadding.OAEPWITHSHA_1ANDMGF1PADDING:
asymBlockCipher = new OaepEncoding(asymBlockCipher, new Sha1Digest());
break;
case CipherPadding.OAEPWITHSHA224ANDMGF1PADDING:
case CipherPadding.OAEPWITHSHA_224ANDMGF1PADDING:
asymBlockCipher = new OaepEncoding(asymBlockCipher, new Sha224Digest());
break;
case CipherPadding.OAEPWITHSHA256ANDMGF1PADDING:
case CipherPadding.OAEPWITHSHA_256ANDMGF1PADDING:
asymBlockCipher = new OaepEncoding(asymBlockCipher, new Sha256Digest());
break;
case CipherPadding.OAEPWITHSHA384ANDMGF1PADDING:
case CipherPadding.OAEPWITHSHA_384ANDMGF1PADDING:
asymBlockCipher = new OaepEncoding(asymBlockCipher, new Sha384Digest());
break;
case CipherPadding.OAEPWITHSHA512ANDMGF1PADDING:
case CipherPadding.OAEPWITHSHA_512ANDMGF1PADDING:
asymBlockCipher = new OaepEncoding(asymBlockCipher, new Sha512Digest());
break;
case CipherPadding.PKCS1:
case CipherPadding.PKCS1PADDING:
asymBlockCipher = new Pkcs1Encoding(asymBlockCipher);
break;
case CipherPadding.PKCS5:
case CipherPadding.PKCS5PADDING:
case CipherPadding.PKCS7:
case CipherPadding.PKCS7PADDING:
padding = new Pkcs7Padding();
break;
case CipherPadding.TBCPADDING:
padding = new TbcPadding();
break;
case CipherPadding.WITHCTS:
cts = true;
break;
case CipherPadding.X923PADDING:
padding = new X923Padding();
break;
case CipherPadding.ZEROBYTEPADDING:
padding = new ZeroBytePadding();
break;
default:
throw new SecurityUtilityException("Cipher " + algorithm + " not recognised.");
}
}
string mode = "";
if (parts.Length > 1)
{
mode = parts[1];
int di = GetDigitIndex(mode);
string modeName = di >= 0 ? mode.Substring(0, di) : mode;
try
{
CipherMode cipherMode = modeName == ""
? CipherMode.NONE
: (CipherMode)Enums.GetEnumValue(typeof(CipherMode), modeName);
switch (cipherMode)
{
case CipherMode.ECB:
case CipherMode.NONE:
break;
case CipherMode.CBC:
blockCipher = new CbcBlockCipher(blockCipher);
break;
case CipherMode.CFB:
{
int bits = (di < 0)
? 8 * blockCipher.GetBlockSize()
: int.Parse(mode.Substring(di));
blockCipher = new CfbBlockCipher(blockCipher, bits);
break;
}
case CipherMode.CTR:
blockCipher = new SicBlockCipher(blockCipher);
break;
case CipherMode.CTS:
cts = true;
blockCipher = new CbcBlockCipher(blockCipher);
break;
case CipherMode.EAX:
aeadBlockCipher = new EaxBlockCipher(blockCipher);
break;
case CipherMode.GCM:
aeadBlockCipher = new GcmBlockCipher(blockCipher);
break;
case CipherMode.GOFB:
blockCipher = new GOfbBlockCipher(blockCipher);
break;
case CipherMode.OCB:
aeadBlockCipher = new OcbBlockCipher(blockCipher, CreateBlockCipher(cipherAlgorithm));
break;
case CipherMode.OFB:
{
int bits = (di < 0)
? 8 * blockCipher.GetBlockSize()
: int.Parse(mode.Substring(di));
blockCipher = new OfbBlockCipher(blockCipher, bits);
break;
}
case CipherMode.OPENPGPCFB:
blockCipher = new OpenPgpCfbBlockCipher(blockCipher);
break;
case CipherMode.SIC:
if (blockCipher.GetBlockSize() < 16)
{
throw new ArgumentException("Warning: SIC-Mode can become a twotime-pad if the blocksize of the cipher is too small. Use a cipher with a block size of at least 128 bits (e.g. AES)");
}
blockCipher = new SicBlockCipher(blockCipher);
break;
default:
throw new SecurityUtilityException("Cipher " + algorithm + " not recognised.");
}
}
catch (ArgumentException)
{
throw new SecurityUtilityException("Cipher " + algorithm + " not recognised.");
}
}
if (aeadBlockCipher != null)
{
if (cts)
throw new SecurityUtilityException("CTS mode not valid for AEAD ciphers.");
if (padded && parts.Length > 2 && parts[2] != "")
throw new SecurityUtilityException("Bad padding specified for AEAD cipher.");
return new BufferedAeadBlockCipher(aeadBlockCipher);
}
if (blockCipher != null)
{
if (cts)
{
return new CtsBlockCipher(blockCipher);
}
if (padding != null)
{
return new PaddedBufferedBlockCipher(blockCipher, padding);
}
if (!padded || blockCipher.IsPartialBlockOkay)
{
return new BufferedBlockCipher(blockCipher);
}
return new PaddedBufferedBlockCipher(blockCipher);
}
if (asymBlockCipher != null)
{
return new BufferedAsymmetricBlockCipher(asymBlockCipher);
}
throw new SecurityUtilityException("Cipher " + algorithm + " not recognised.");
}
public static IBufferedCipher GetCipher(string algorithm)
{
//IL_0008: Unknown result type (might be due to invalid IL or missing references)
//IL_0469: Unknown result type (might be due to invalid IL or missing references)
//IL_0495: Unknown result type (might be due to invalid IL or missing references)
//IL_07f1: Unknown result type (might be due to invalid IL or missing references)
if (algorithm == null)
{
throw new ArgumentNullException("algorithm");
}
algorithm = Platform.ToUpperInvariant(algorithm);
string text = (string)algorithms.get_Item((object)algorithm);
if (text != null)
{
algorithm = text;
}
IBasicAgreement basicAgreement = null;
if (algorithm == "IES")
{
basicAgreement = new DHBasicAgreement();
}
else if (algorithm == "ECIES")
{
basicAgreement = new ECDHBasicAgreement();
}
if (basicAgreement != null)
{
return(new BufferedIesCipher(new IesEngine(basicAgreement, new Kdf2BytesGenerator(new Sha1Digest()), new HMac(new Sha1Digest()))));
}
if (Platform.StartsWith(algorithm, "PBE"))
{
if (Platform.EndsWith(algorithm, "-CBC"))
{
if (algorithm == "PBEWITHSHA1ANDDES-CBC")
{
return(new PaddedBufferedBlockCipher(new CbcBlockCipher(new DesEngine())));
}
if (algorithm == "PBEWITHSHA1ANDRC2-CBC")
{
return(new PaddedBufferedBlockCipher(new CbcBlockCipher(new RC2Engine())));
}
if (Strings.IsOneOf(algorithm, "PBEWITHSHAAND2-KEYTRIPLEDES-CBC", "PBEWITHSHAAND3-KEYTRIPLEDES-CBC"))
{
return(new PaddedBufferedBlockCipher(new CbcBlockCipher(new DesEdeEngine())));
}
if (Strings.IsOneOf(algorithm, "PBEWITHSHAAND128BITRC2-CBC", "PBEWITHSHAAND40BITRC2-CBC"))
{
return(new PaddedBufferedBlockCipher(new CbcBlockCipher(new RC2Engine())));
}
}
else if ((Platform.EndsWith(algorithm, "-BC") || Platform.EndsWith(algorithm, "-OPENSSL")) && Strings.IsOneOf(algorithm, "PBEWITHSHAAND128BITAES-CBC-BC", "PBEWITHSHAAND192BITAES-CBC-BC", "PBEWITHSHAAND256BITAES-CBC-BC", "PBEWITHSHA256AND128BITAES-CBC-BC", "PBEWITHSHA256AND192BITAES-CBC-BC", "PBEWITHSHA256AND256BITAES-CBC-BC", "PBEWITHMD5AND128BITAES-CBC-OPENSSL", "PBEWITHMD5AND192BITAES-CBC-OPENSSL", "PBEWITHMD5AND256BITAES-CBC-OPENSSL"))
{
return(new PaddedBufferedBlockCipher(new CbcBlockCipher(new AesFastEngine())));
}
}
string[] array = algorithm.Split(new char[1] {
'/'
});
IBlockCipher blockCipher = null;
IAsymmetricBlockCipher asymmetricBlockCipher = null;
IStreamCipher streamCipher = null;
string text2 = array[0];
string text3 = (string)algorithms.get_Item((object)text2);
if (text3 != null)
{
text2 = text3;
}
CipherAlgorithm cipherAlgorithm;
try
{
cipherAlgorithm = (CipherAlgorithm)Enums.GetEnumValue(typeof(CipherAlgorithm), text2);
}
catch (ArgumentException)
{
throw new SecurityUtilityException("Cipher " + algorithm + " not recognised.");
}
switch (cipherAlgorithm)
{
case CipherAlgorithm.AES:
blockCipher = new AesFastEngine();
break;
case CipherAlgorithm.ARC4:
streamCipher = new RC4Engine();
break;
case CipherAlgorithm.BLOWFISH:
blockCipher = new BlowfishEngine();
break;
case CipherAlgorithm.CAMELLIA:
blockCipher = new CamelliaEngine();
break;
case CipherAlgorithm.CAST5:
blockCipher = new Cast5Engine();
break;
case CipherAlgorithm.CAST6:
blockCipher = new Cast6Engine();
break;
case CipherAlgorithm.DES:
blockCipher = new DesEngine();
break;
case CipherAlgorithm.DESEDE:
blockCipher = new DesEdeEngine();
break;
case CipherAlgorithm.ELGAMAL:
asymmetricBlockCipher = new ElGamalEngine();
break;
case CipherAlgorithm.GOST28147:
blockCipher = new Gost28147Engine();
break;
case CipherAlgorithm.HC128:
streamCipher = new HC128Engine();
break;
case CipherAlgorithm.HC256:
streamCipher = new HC256Engine();
break;
case CipherAlgorithm.IDEA:
blockCipher = new IdeaEngine();
break;
case CipherAlgorithm.NOEKEON:
blockCipher = new NoekeonEngine();
break;
case CipherAlgorithm.PBEWITHSHAAND128BITRC4:
case CipherAlgorithm.PBEWITHSHAAND40BITRC4:
streamCipher = new RC4Engine();
break;
case CipherAlgorithm.RC2:
blockCipher = new RC2Engine();
break;
case CipherAlgorithm.RC5:
blockCipher = new RC532Engine();
break;
case CipherAlgorithm.RC5_64:
blockCipher = new RC564Engine();
break;
case CipherAlgorithm.RC6:
blockCipher = new RC6Engine();
break;
case CipherAlgorithm.RIJNDAEL:
blockCipher = new RijndaelEngine();
break;
case CipherAlgorithm.RSA:
asymmetricBlockCipher = new RsaBlindedEngine();
break;
case CipherAlgorithm.SALSA20:
streamCipher = new Salsa20Engine();
break;
case CipherAlgorithm.SEED:
blockCipher = new SeedEngine();
break;
case CipherAlgorithm.SERPENT:
blockCipher = new SerpentEngine();
break;
case CipherAlgorithm.SKIPJACK:
blockCipher = new SkipjackEngine();
break;
case CipherAlgorithm.TEA:
blockCipher = new TeaEngine();
break;
case CipherAlgorithm.THREEFISH_256:
blockCipher = new ThreefishEngine(256);
break;
case CipherAlgorithm.THREEFISH_512:
blockCipher = new ThreefishEngine(512);
break;
case CipherAlgorithm.THREEFISH_1024:
blockCipher = new ThreefishEngine(1024);
break;
case CipherAlgorithm.TNEPRES:
blockCipher = new TnepresEngine();
break;
case CipherAlgorithm.TWOFISH:
blockCipher = new TwofishEngine();
break;
case CipherAlgorithm.VMPC:
streamCipher = new VmpcEngine();
break;
case CipherAlgorithm.VMPC_KSA3:
streamCipher = new VmpcKsa3Engine();
break;
case CipherAlgorithm.XTEA:
blockCipher = new XteaEngine();
break;
default:
throw new SecurityUtilityException("Cipher " + algorithm + " not recognised.");
}
if (streamCipher != null)
{
if (array.Length > 1)
{
throw new ArgumentException("Modes and paddings not used for stream ciphers");
}
return(new BufferedStreamCipher(streamCipher));
}
bool flag = false;
bool flag2 = true;
IBlockCipherPadding blockCipherPadding = null;
IAeadBlockCipher aeadBlockCipher = null;
if (array.Length > 2)
{
if (streamCipher != null)
{
throw new ArgumentException("Paddings not used for stream ciphers");
}
string text4 = array[2];
CipherPadding cipherPadding;
if (text4 == "")
{
cipherPadding = CipherPadding.RAW;
}
else if (text4 == "X9.23PADDING")
{
cipherPadding = CipherPadding.X923PADDING;
}
else
{
try
{
cipherPadding = (CipherPadding)Enums.GetEnumValue(typeof(CipherPadding), text4);
}
catch (ArgumentException)
{
throw new SecurityUtilityException("Cipher " + algorithm + " not recognised.");
}
}
switch (cipherPadding)
{
case CipherPadding.NOPADDING:
flag2 = false;
break;
case CipherPadding.ISO10126PADDING:
case CipherPadding.ISO10126D2PADDING:
case CipherPadding.ISO10126_2PADDING:
blockCipherPadding = new ISO10126d2Padding();
break;
case CipherPadding.ISO7816_4PADDING:
case CipherPadding.ISO9797_1PADDING:
blockCipherPadding = new ISO7816d4Padding();
break;
case CipherPadding.ISO9796_1:
case CipherPadding.ISO9796_1PADDING:
asymmetricBlockCipher = new ISO9796d1Encoding(asymmetricBlockCipher);
break;
case CipherPadding.OAEP:
case CipherPadding.OAEPPADDING:
asymmetricBlockCipher = new OaepEncoding(asymmetricBlockCipher);
break;
case CipherPadding.OAEPWITHMD5ANDMGF1PADDING:
asymmetricBlockCipher = new OaepEncoding(asymmetricBlockCipher, new MD5Digest());
break;
case CipherPadding.OAEPWITHSHA1ANDMGF1PADDING:
case CipherPadding.OAEPWITHSHA_1ANDMGF1PADDING:
asymmetricBlockCipher = new OaepEncoding(asymmetricBlockCipher, new Sha1Digest());
break;
case CipherPadding.OAEPWITHSHA224ANDMGF1PADDING:
case CipherPadding.OAEPWITHSHA_224ANDMGF1PADDING:
asymmetricBlockCipher = new OaepEncoding(asymmetricBlockCipher, new Sha224Digest());
break;
case CipherPadding.OAEPWITHSHA256ANDMGF1PADDING:
case CipherPadding.OAEPWITHSHA_256ANDMGF1PADDING:
asymmetricBlockCipher = new OaepEncoding(asymmetricBlockCipher, new Sha256Digest());
break;
case CipherPadding.OAEPWITHSHA384ANDMGF1PADDING:
case CipherPadding.OAEPWITHSHA_384ANDMGF1PADDING:
asymmetricBlockCipher = new OaepEncoding(asymmetricBlockCipher, new Sha384Digest());
break;
case CipherPadding.OAEPWITHSHA512ANDMGF1PADDING:
case CipherPadding.OAEPWITHSHA_512ANDMGF1PADDING:
asymmetricBlockCipher = new OaepEncoding(asymmetricBlockCipher, new Sha512Digest());
break;
case CipherPadding.PKCS1:
case CipherPadding.PKCS1PADDING:
asymmetricBlockCipher = new Pkcs1Encoding(asymmetricBlockCipher);
break;
case CipherPadding.PKCS5:
case CipherPadding.PKCS5PADDING:
case CipherPadding.PKCS7:
case CipherPadding.PKCS7PADDING:
blockCipherPadding = new Pkcs7Padding();
break;
case CipherPadding.TBCPADDING:
blockCipherPadding = new TbcPadding();
break;
case CipherPadding.WITHCTS:
flag = true;
break;
case CipherPadding.X923PADDING:
blockCipherPadding = new X923Padding();
break;
case CipherPadding.ZEROBYTEPADDING:
blockCipherPadding = new ZeroBytePadding();
break;
default:
throw new SecurityUtilityException("Cipher " + algorithm + " not recognised.");
case CipherPadding.RAW:
break;
}
}
string text5 = "";
if (array.Length > 1)
{
text5 = array[1];
int digitIndex = GetDigitIndex(text5);
string text6 = ((digitIndex >= 0) ? text5.Substring(0, digitIndex) : text5);
try
{
switch ((text6 == "") ? CipherMode.NONE : ((CipherMode)Enums.GetEnumValue(typeof(CipherMode), text6)))
{
case CipherMode.CBC:
blockCipher = new CbcBlockCipher(blockCipher);
break;
case CipherMode.CCM:
aeadBlockCipher = new CcmBlockCipher(blockCipher);
break;
case CipherMode.CFB:
{
int bitBlockSize = ((digitIndex < 0) ? (8 * blockCipher.GetBlockSize()) : int.Parse(text5.Substring(digitIndex)));
blockCipher = new CfbBlockCipher(blockCipher, bitBlockSize);
break;
}
case CipherMode.CTR:
blockCipher = new SicBlockCipher(blockCipher);
break;
case CipherMode.CTS:
flag = true;
blockCipher = new CbcBlockCipher(blockCipher);
break;
case CipherMode.EAX:
aeadBlockCipher = new EaxBlockCipher(blockCipher);
break;
case CipherMode.GCM:
aeadBlockCipher = new GcmBlockCipher(blockCipher);
break;
case CipherMode.GOFB:
blockCipher = new GOfbBlockCipher(blockCipher);
break;
case CipherMode.OCB:
aeadBlockCipher = new OcbBlockCipher(blockCipher, CreateBlockCipher(cipherAlgorithm));
break;
case CipherMode.OFB:
{
int blockSize = ((digitIndex < 0) ? (8 * blockCipher.GetBlockSize()) : int.Parse(text5.Substring(digitIndex)));
blockCipher = new OfbBlockCipher(blockCipher, blockSize);
break;
}
case CipherMode.OPENPGPCFB:
blockCipher = new OpenPgpCfbBlockCipher(blockCipher);
break;
case CipherMode.SIC:
if (blockCipher.GetBlockSize() < 16)
{
throw new ArgumentException("Warning: SIC-Mode can become a twotime-pad if the blocksize of the cipher is too small. Use a cipher with a block size of at least 128 bits (e.g. AES)");
}
blockCipher = new SicBlockCipher(blockCipher);
break;
default:
throw new SecurityUtilityException("Cipher " + algorithm + " not recognised.");
case CipherMode.ECB:
case CipherMode.NONE:
break;
}
}
catch (ArgumentException)
{
throw new SecurityUtilityException("Cipher " + algorithm + " not recognised.");
}
}
if (aeadBlockCipher != null)
{
if (flag)
{
throw new SecurityUtilityException("CTS mode not valid for AEAD ciphers.");
}
if (flag2 && array.Length > 2 && array[2] != "")
{
throw new SecurityUtilityException("Bad padding specified for AEAD cipher.");
}
return(new BufferedAeadBlockCipher(aeadBlockCipher));
}
if (blockCipher != null)
{
if (flag)
{
return(new CtsBlockCipher(blockCipher));
}
if (blockCipherPadding != null)
{
return(new PaddedBufferedBlockCipher(blockCipher, blockCipherPadding));
}
if (!flag2 || blockCipher.IsPartialBlockOkay)
{
return(new BufferedBlockCipher(blockCipher));
}
return(new PaddedBufferedBlockCipher(blockCipher));
}
if (asymmetricBlockCipher != null)
{
return(new BufferedAsymmetricBlockCipher(asymmetricBlockCipher));
}
throw new SecurityUtilityException("Cipher " + algorithm + " not recognised.");
}
public static IBufferedCipher GetCipher(
string algorithm)
{
if (algorithm == null)
{
throw new ArgumentNullException("algorithm");
}
algorithm = algorithm.ToUpper(CultureInfo.InvariantCulture);
string aliased = (string)algorithms[algorithm];
if (aliased != null)
{
algorithm = aliased;
}
IBasicAgreement iesAgreement = null;
if (algorithm == "IES")
{
iesAgreement = new DHBasicAgreement();
}
else if (algorithm == "ECIES")
{
iesAgreement = new ECDHBasicAgreement();
}
if (iesAgreement != null)
{
return(new BufferedIesCipher(
new IesEngine(
iesAgreement,
new Kdf2BytesGenerator(
new Sha1Digest()),
new HMac(
new Sha1Digest()))));
}
if (algorithm.StartsWith("PBE"))
{
switch (algorithm)
{
case "PBEWITHSHAAND2-KEYTRIPLEDES-CBC":
case "PBEWITHSHAAND3-KEYTRIPLEDES-CBC":
return(new PaddedBufferedBlockCipher(
new CbcBlockCipher(new DesEdeEngine())));
case "PBEWITHSHAAND128BITRC2-CBC":
case "PBEWITHSHAAND40BITRC2-CBC":
return(new PaddedBufferedBlockCipher(
new CbcBlockCipher(new RC2Engine())));
case "PBEWITHSHAAND128BITAES-CBC-BC":
case "PBEWITHSHAAND192BITAES-CBC-BC":
case "PBEWITHSHAAND256BITAES-CBC-BC":
case "PBEWITHSHA256AND128BITAES-CBC-BC":
case "PBEWITHSHA256AND192BITAES-CBC-BC":
case "PBEWITHSHA256AND256BITAES-CBC-BC":
case "PBEWITHMD5AND128BITAES-CBC-OPENSSL":
case "PBEWITHMD5AND192BITAES-CBC-OPENSSL":
case "PBEWITHMD5AND256BITAES-CBC-OPENSSL":
return(new PaddedBufferedBlockCipher(
new CbcBlockCipher(new AesFastEngine())));
case "PBEWITHSHA1ANDDES-CBC":
return(new PaddedBufferedBlockCipher(
new CbcBlockCipher(new DesEngine())));
case "PBEWITHSHA1ANDRC2-CBC":
return(new PaddedBufferedBlockCipher(
new CbcBlockCipher(new RC2Engine())));
}
}
string[] parts = algorithm.Split('/');
IBlockCipher blockCipher = null;
IAsymmetricBlockCipher asymBlockCipher = null;
IStreamCipher streamCipher = null;
switch (parts[0])
{
case "AES":
blockCipher = new AesFastEngine();
break;
case "ARC4":
streamCipher = new RC4Engine();
break;
case "BLOWFISH":
blockCipher = new BlowfishEngine();
break;
case "CAMELLIA":
blockCipher = new CamelliaEngine();
break;
case "CAST5":
blockCipher = new Cast5Engine();
break;
case "CAST6":
blockCipher = new Cast6Engine();
break;
case "DES":
blockCipher = new DesEngine();
break;
case "DESEDE":
blockCipher = new DesEdeEngine();
break;
case "ELGAMAL":
asymBlockCipher = new ElGamalEngine();
break;
case "GOST28147":
blockCipher = new Gost28147Engine();
break;
case "HC128":
streamCipher = new HC128Engine();
break;
case "HC256":
streamCipher = new HC256Engine();
break;
#if INCLUDE_IDEA
case "IDEA":
blockCipher = new IdeaEngine();
break;
#endif
case "NOEKEON":
blockCipher = new NoekeonEngine();
break;
case "PBEWITHSHAAND128BITRC4":
case "PBEWITHSHAAND40BITRC4":
streamCipher = new RC4Engine();
break;
case "RC2":
blockCipher = new RC2Engine();
break;
case "RC5":
blockCipher = new RC532Engine();
break;
case "RC5-64":
blockCipher = new RC564Engine();
break;
case "RC6":
blockCipher = new RC6Engine();
break;
case "RIJNDAEL":
blockCipher = new RijndaelEngine();
break;
case "RSA":
asymBlockCipher = new RsaBlindedEngine();
break;
case "SALSA20":
streamCipher = new Salsa20Engine();
break;
case "SEED":
blockCipher = new SeedEngine();
break;
case "SERPENT":
blockCipher = new SerpentEngine();
break;
case "SKIPJACK":
blockCipher = new SkipjackEngine();
break;
case "TEA":
blockCipher = new TeaEngine();
break;
case "TWOFISH":
blockCipher = new TwofishEngine();
break;
case "VMPC":
streamCipher = new VmpcEngine();
break;
case "VMPC-KSA3":
streamCipher = new VmpcKsa3Engine();
break;
case "XTEA":
blockCipher = new XteaEngine();
break;
default:
throw new SecurityUtilityException("Cipher " + algorithm + " not recognised.");
}
if (streamCipher != null)
{
if (parts.Length > 1)
{
throw new ArgumentException("Modes and paddings not used for stream ciphers");
}
return(new BufferedStreamCipher(streamCipher));
}
bool cts = false;
bool padded = true;
IBlockCipherPadding padding = null;
IAeadBlockCipher aeadBlockCipher = null;
if (parts.Length > 2)
{
if (streamCipher != null)
{
throw new ArgumentException("Paddings not used for stream ciphers");
}
switch (parts[2])
{
case "NOPADDING":
padded = false;
break;
case "":
case "RAW":
break;
case "ISO10126PADDING":
case "ISO10126D2PADDING":
case "ISO10126-2PADDING":
padding = new ISO10126d2Padding();
break;
case "ISO7816-4PADDING":
case "ISO9797-1PADDING":
padding = new ISO7816d4Padding();
break;
case "ISO9796-1":
case "ISO9796-1PADDING":
asymBlockCipher = new ISO9796d1Encoding(asymBlockCipher);
break;
case "OAEP":
case "OAEPPADDING":
asymBlockCipher = new OaepEncoding(asymBlockCipher);
break;
case "OAEPWITHMD5ANDMGF1PADDING":
asymBlockCipher = new OaepEncoding(asymBlockCipher, new MD5Digest());
break;
case "OAEPWITHSHA1ANDMGF1PADDING":
case "OAEPWITHSHA-1ANDMGF1PADDING":
asymBlockCipher = new OaepEncoding(asymBlockCipher, new Sha1Digest());
break;
case "OAEPWITHSHA224ANDMGF1PADDING":
case "OAEPWITHSHA-224ANDMGF1PADDING":
asymBlockCipher = new OaepEncoding(asymBlockCipher, new Sha224Digest());
break;
case "OAEPWITHSHA256ANDMGF1PADDING":
case "OAEPWITHSHA-256ANDMGF1PADDING":
asymBlockCipher = new OaepEncoding(asymBlockCipher, new Sha256Digest());
break;
case "OAEPWITHSHA384ANDMGF1PADDING":
case "OAEPWITHSHA-384ANDMGF1PADDING":
asymBlockCipher = new OaepEncoding(asymBlockCipher, new Sha384Digest());
break;
case "OAEPWITHSHA512ANDMGF1PADDING":
case "OAEPWITHSHA-512ANDMGF1PADDING":
asymBlockCipher = new OaepEncoding(asymBlockCipher, new Sha512Digest());
break;
case "PKCS1":
case "PKCS1PADDING":
asymBlockCipher = new Pkcs1Encoding(asymBlockCipher);
break;
case "PKCS5":
case "PKCS5PADDING":
case "PKCS7":
case "PKCS7PADDING":
// NB: Padding defaults to Pkcs7Padding already
break;
case "TBCPADDING":
padding = new TbcPadding();
break;
case "WITHCTS":
cts = true;
break;
case "X9.23PADDING":
case "X923PADDING":
padding = new X923Padding();
break;
case "ZEROBYTEPADDING":
padding = new ZeroBytePadding();
break;
default:
throw new SecurityUtilityException("Cipher " + algorithm + " not recognised.");
}
}
string mode = "";
if (parts.Length > 1)
{
mode = parts[1];
int di = GetDigitIndex(mode);
string modeName = di >= 0 ? mode.Substring(0, di) : mode;
switch (modeName)
{
case "":
case "ECB":
case "NONE":
break;
case "CBC":
blockCipher = new CbcBlockCipher(blockCipher);
break;
case "CCM":
aeadBlockCipher = new CcmBlockCipher(blockCipher);
break;
case "CFB":
{
int bits = (di < 0)
? 8 * blockCipher.GetBlockSize()
: int.Parse(mode.Substring(di));
blockCipher = new CfbBlockCipher(blockCipher, bits);
break;
}
case "CTR":
blockCipher = new SicBlockCipher(blockCipher);
break;
case "CTS":
cts = true;
blockCipher = new CbcBlockCipher(blockCipher);
break;
case "EAX":
aeadBlockCipher = new EaxBlockCipher(blockCipher);
break;
case "GCM":
aeadBlockCipher = new GcmBlockCipher(blockCipher);
break;
case "GOFB":
blockCipher = new GOfbBlockCipher(blockCipher);
break;
case "OFB":
{
int bits = (di < 0)
? 8 * blockCipher.GetBlockSize()
: int.Parse(mode.Substring(di));
blockCipher = new OfbBlockCipher(blockCipher, bits);
break;
}
case "OPENPGPCFB":
blockCipher = new OpenPgpCfbBlockCipher(blockCipher);
break;
case "SIC":
if (blockCipher.GetBlockSize() < 16)
{
throw new ArgumentException("Warning: SIC-Mode can become a twotime-pad if the blocksize of the cipher is too small. Use a cipher with a block size of at least 128 bits (e.g. AES)");
}
blockCipher = new SicBlockCipher(blockCipher);
break;
default:
throw new SecurityUtilityException("Cipher " + algorithm + " not recognised.");
}
}
if (aeadBlockCipher != null)
{
if (cts)
{
throw new SecurityUtilityException("CTS mode not valid for AEAD ciphers.");
}
if (padded && parts.Length > 1 && parts[2] != "")
{
throw new SecurityUtilityException("Bad padding specified for AEAD cipher.");
}
return(new BufferedAeadBlockCipher(aeadBlockCipher));
}
if (blockCipher != null)
{
if (cts)
{
return(new CtsBlockCipher(blockCipher));
}
if (!padded || blockCipher.IsPartialBlockOkay)
{
return(new BufferedBlockCipher(blockCipher));
}
if (padding != null)
{
return(new PaddedBufferedBlockCipher(blockCipher, padding));
}
return(new PaddedBufferedBlockCipher(blockCipher));
}
if (asymBlockCipher != null)
{
return(new BufferedAsymmetricBlockCipher(asymBlockCipher));
}
throw new SecurityUtilityException("Cipher " + algorithm + " not recognised.");
}
public static ArrayLease <byte> EncryptBytes(ArraySegment <byte> plaintext, ArraySegment <byte> key, out int count)
{
// Blowfish encrypts 8 bytes at a time
int leftover = plaintext.Count & 7;
count = (plaintext.Count + 7) & ~7; // branchless version of: n - (n % 8) + 8
// if there's leftover we'll need another extra 8 bytes to hold the input
// note that this should not be part of the outputted array,
// so store it in a new variable
int capacity = count + ((leftover + 7) & ~7);
Debug.Assert(leftover == 0 ^ capacity != plaintext.Count);
var engine = new BlowfishEngine();
var keyParameter = new KeyParameter(key.Array, key.Offset, key.Count);
engine.Init(forEncryption: true, parameters: keyParameter);
var lease = ArrayPool <byte> .Shared.Lease(capacity);
try
{
int i = plaintext.Offset;
int j = 0;
byte[] input = plaintext.Array;
byte[] output = lease.Array;
// Process each block of bytes
while (i + 7 < plaintext.Count)
{
engine.ProcessBlock(input, i, output, j);
i += 8;
j += 8;
}
Debug.Assert(
i + leftover == plaintext.Count &&
leftover >= 0 &&
leftover < 8);
if (leftover != 0)
{
// Handle the leftover input bytes
Debug.Assert(
count > plaintext.Count &&
(count % 8) == 0 &&
capacity == count + 8);
// Copy over the remaining input data to the end of the output array
int inputIndex = i, outputIndex = j + 8;
while (inputIndex < plaintext.Count)
{
output[outputIndex++] = input[inputIndex++];
}
// Since this is a rented array, clear any extraneous data at the end
// Use a regular while loop, since it's less than 8 bytes
Debug.Assert(
outputIndex <= capacity &&
capacity - outputIndex < 8);
while (outputIndex < capacity)
{
output[outputIndex++] = 0;
}
engine.ProcessBlock(output, j + 8, output, j);
}
}
catch
{
lease.Dispose();
throw;
}
return(lease);
}