/// <summary> /// Encrypt data with Salsa20 /// </summary> /// <param name="input">Input stream to encrypt</param> /// <param name="output">Output stream</param> /// <param name="key">Key</param> /// <param name="nonce">Nonce</param> /// <param name="notifyProgression">Notify progression method</param> /// <param name="bufferSize">Buffer size</param> public static void Encrypt(Stream input, Stream output, byte[] key, byte[] nonce, Action <int> notifyProgression = null, int bufferSize = 4096) { Salsa20Engine engine = new Salsa20Engine(); ParametersWithIV parameters = new ParametersWithIV(new KeyParameter(key, 0, key.Length), nonce, 0, nonce.Length); engine.Init(true, parameters); int bytesRead; byte[] buffer = new byte[bufferSize]; byte[] enc = new byte[bufferSize]; do { bytesRead = input.Read(buffer, 0, bufferSize); if (bytesRead > 0) { engine.ProcessBytes(buffer, 0, bytesRead, enc, 0); output.Write(enc, 0, bytesRead); if (notifyProgression != null) { notifyProgression(bytesRead); } } } while (bytesRead == bufferSize); }
private void salsa20Test1( int rounds, ICipherParameters parameters, string v0, string v192, string v256, string v448) { IStreamCipher salsa = new Salsa20Engine(rounds); byte[] buf = new byte[64]; salsa.Init(true, parameters); for (int i = 0; i != 7; i++) { salsa.ProcessBytes(zeroes, 0, 64, buf, 0); switch (i) { case 0: if (!AreEqual(buf, Hex.Decode(v0))) { mismatch("v0/" + rounds, v0, buf); } break; case 3: if (!AreEqual(buf, Hex.Decode(v192))) { mismatch("v192/" + rounds, v192, buf); } break; case 4: if (!AreEqual(buf, Hex.Decode(v256))) { mismatch("v256/" + rounds, v256, buf); } break; default: // ignore break; } } for (int i = 0; i != 64; i++) { buf[i] = salsa.ReturnByte(zeroes[i]); } if (!AreEqual(buf, Hex.Decode(v448))) { mismatch("v448", v448, buf); } }
/// <summary> /// Decrypt data with Salsa20 /// </summary> /// <param name="data">Data to decrypt</param> /// <param name="key">Key</param> /// <param name="nonce">Nonce</param> /// <returns>Decrypted data</returns> public static byte[] Decrypt(byte[] data, byte[] key, byte[] nonce) { byte[] dec = new byte[data.Length]; Salsa20Engine engine = new Salsa20Engine(); ParametersWithIV parameters = new ParametersWithIV(new KeyParameter(key, 0, key.Length), nonce, 0, nonce.Length); engine.Init(false, parameters); engine.ProcessBytes(data, 0, data.Length, dec, 0); return(dec); }
private static void BlockMix(uint[] B, uint[] X1, uint[] X2, uint[] Y, int r) { Array.Copy(B, B.Length - 16, X1, 0, 16); int BOff = 0, YOff = 0, halfLen = B.Length >> 1; for (int i = 2 * r; i > 0; --i) { Xor(X1, B, BOff, X2); Salsa20Engine.SalsaCore(8, X2, X1); Array.Copy(X1, 0, Y, YOff, 16); YOff = halfLen + BOff - YOff; BOff += 16; } }
private static void BlockMix(uint[] B, uint[] X1, uint[] X2, uint[] Y, int r) { Array.Copy(B, B.Length - 16, X1, 0, 16); int num = 0; int num2 = 0; int num3 = B.Length >> 1; for (int i = 2 * r; i > 0; i--) { SCrypt.Xor(X1, B, num, X2); Salsa20Engine.SalsaCore(8, X2, X1); Array.Copy(X1, 0, Y, num2, 16); num2 = num3 + num - num2; num += 16; } Array.Copy(Y, 0, B, 0, Y.Length); }
private byte[] SalsaB(byte[] Key, byte[] Vector, byte[] Data) { int len = Data.Length; int ct = 0; byte[] output = new byte[len]; Salsa20Engine salsa = new Salsa20Engine(); salsa.Init(true, Key, Vector); while (ct < len) { salsa.ProcessBytes(Data, ct, 64, output, ct); ct += 64; } return output; }
private static void BlockMix(uint[] B, uint[] X1, uint[] X2, uint[] Y, int r) { global::System.Array.Copy((global::System.Array)B, B.Length - 16, (global::System.Array)X1, 0, 16); int num = 0; int num2 = 0; int num3 = B.Length >> 1; for (int num4 = 2 * r; num4 > 0; num4--) { Xor(X1, B, num, X2); Salsa20Engine.SalsaCore(8, X2, X1); global::System.Array.Copy((global::System.Array)X1, 0, (global::System.Array)Y, num2, 16); num2 = num3 + num - num2; num += 16; } global::System.Array.Copy((global::System.Array)Y, 0, (global::System.Array)B, 0, Y.Length); }
private byte[] SalsaB(byte[] Key, byte[] Vector, byte[] Data) { int len = Data.Length; int ct = 0; byte[] output = new byte[len]; Salsa20Engine salsa = new Salsa20Engine(); salsa.Init(true, Key, Vector); while (ct < len) { salsa.ProcessBytes(Data, ct, 64, output, ct); ct += 64; } return(output); }
private void reinitBug() { KeyParameter key = new KeyParameter(Hex.Decode("80000000000000000000000000000000")); ParametersWithIV parameters = new ParametersWithIV(key, Hex.Decode("0000000000000000")); IStreamCipher salsa = new Salsa20Engine(); salsa.Init(true, parameters); try { salsa.Init(true, key); Fail("Salsa20 should throw exception if no IV in Init"); } catch (ArgumentException) { } }
/// <summary> /// Gets an ID for the key. /// </summary> /// <returns> /// A byte array that can be used as an identifier for the key. /// </returns> /// <remarks> /// C# implementation of the GO code at /// <see href="https://github.com/libp2p/go-libp2p-pnet/blob/bed5e6afdf9099121029f6fb675be12a50196114/fingerprint.go#L10"/>. /// </remarks> public byte[] Fingerprint() { // Encrypt data first so we don't feed PSK to hash function. // Salsa20 function is not reversible thus increasing our security margin. var encrypted = new byte[64]; var nonce = Encoding.ASCII.GetBytes("finprint"); var cipher = new Salsa20Engine(); cipher.Init(true, new ParametersWithIV(new KeyParameter(this.Value), nonce)); cipher.ProcessBytes(encrypted, 0, encrypted.Length, encrypted, 0); // Then do Shake-128 hash to reduce its length. // This way if for some reason Shake is broken and Salsa20 preimage is possible, // attacker has only half of the bytes necessary to recreate psk. return(MultiHash .GetHashAlgorithm("shake-128") .ComputeHash(encrypted)); }
private void salsa20Test2( ICipherParameters parameters, string v0, string v65472, string v65536) { IStreamCipher salsa = new Salsa20Engine(); byte[] buf = new byte[64]; salsa.Init(true, parameters); for (int i = 0; i != 1025; i++) { salsa.ProcessBytes(zeroes, 0, 64, buf, 0); switch (i) { case 0: if (!AreEqual(buf, Hex.Decode(v0))) { mismatch("v0", v0, buf); } break; case 1023: if (!AreEqual(buf, Hex.Decode(v65472))) { mismatch("v65472", v65472, buf); } break; case 1024: if (!AreEqual(buf, Hex.Decode(v65536))) { mismatch("v65536", v65536, buf); } break; default: // ignore break; } } }
/********EXTERNAL OBJECT PUBLIC METHODS - END ********/ /// <summary> /// Buils the StreamCipher /// </summary> /// <param name="algorithm">SymmetrcStreamAlgorithm enum, algorithm name</param> /// <returns>IStreamCipher with the algorithm Stream Engine</returns> private IStreamCipher getCipherEngine(SymmetricStreamAlgorithm algorithm) { IStreamCipher engine = null; switch (algorithm) { case SymmetricStreamAlgorithm.RC4: engine = new RC4Engine(); break; case SymmetricStreamAlgorithm.HC128: engine = new HC128Engine(); break; case SymmetricStreamAlgorithm.HC256: engine = new HC256Engine(); break; case SymmetricStreamAlgorithm.SALSA20: engine = new Salsa20Engine(); break; case SymmetricStreamAlgorithm.CHACHA20: engine = new ChaChaEngine(); break; case SymmetricStreamAlgorithm.XSALSA20: engine = new XSalsa20Engine(); break; case SymmetricStreamAlgorithm.ISAAC: engine = new IsaacEngine(); break; case SymmetricStreamAlgorithm.VMPC: engine = new VmpcEngine(); break; default: this.GetError().setError("SS005", "Cipher " + algorithm + " not recognised."); break; } return(engine); }
protected override void SetKey(byte[] keyBytes, byte[] ivBytes) { if (keyBytes.Length != 32) { throw new ArgumentException(AlgorithmName + " requires a 256 bit key"); } base.SetKey(keyBytes, ivBytes); engineState[8] = Pack.LE_To_UInt32(ivBytes, 8); engineState[9] = Pack.LE_To_UInt32(ivBytes, 12); uint[] array = new uint[engineState.Length]; Salsa20Engine.SalsaCore(20, engineState, array); engineState[1] = array[0] - engineState[0]; engineState[2] = array[5] - engineState[5]; engineState[3] = array[10] - engineState[10]; engineState[4] = array[15] - engineState[15]; engineState[11] = array[6] - engineState[6]; engineState[12] = array[7] - engineState[7]; engineState[13] = array[8] - engineState[8]; engineState[14] = array[9] - engineState[9]; engineState[6] = Pack.LE_To_UInt32(ivBytes, 16); engineState[7] = Pack.LE_To_UInt32(ivBytes, 20); ResetCounter(); }
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 BcSalsa20Crypto(byte[] key, byte[] iv) : base(key, iv) { _engine = new Salsa20Engine(); _engine.Init(default, new ParametersWithIV(new KeyParameter(key), iv));
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."); }
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."); }