Dispose() защищенный Метод

protected Dispose ( bool disposing ) : void
disposing bool
Результат void
Пример #1
0
        static void Decrypt(string[] args)
        {
            //Precheck if a tmp file already exists.
            //If so delete it.
            if (File.Exists(args[0] + ".tmp"))
            {
                Display("Destroying old .tmp files.");
                DestroyFile(args[0] + ".tmp");
                Display("Done.");
            }

            //SET UP STREAMS//
            FileStream Output;
            FileStream Input;
            CryptoStream CryptStream;

            //SET UP SERVICE PROVIDERS//
            AesCryptoServiceProvider ACSP = new AesCryptoServiceProvider();

            //AES PARAMETERS//
            ACSP.Padding = PaddingMode.PKCS7;
            Display("Creating keys.");
            ACSP.IV = GenerateIV(args[2]);      //initialization vector
            ACSP.Key = GenerateKey(args[2]);    //32 byte key
            Display("Done.");

            Input = new FileStream(args[0], FileMode.Open);
            Output = new FileStream(args[0] + ".tmp", FileMode.CreateNew);
            CryptStream = new CryptoStream(Input, ACSP.CreateDecryptor(), CryptoStreamMode.Read);

            Display("Starting decryption.");
            CryptStream.CopyTo(Output);
            Display("Done.");
            Input.Flush();
            Input.Dispose();
            CryptStream.Flush();
            //CryptStream.Dispose(); <-- Is disposed with input.
            Output.Flush();
            Output.Dispose();

            Display("Destroying old raw file.");
            DestroyFile(args[0]);
            Display("Done.");

            //Rename .tmp to the original file.
            Display("Renaming new file.");
            File.Move(args[0] + ".tmp", args[0]);
            Display("Done.");

            ACSP.Dispose();

            Display("Decryption process completed.");
            Console.ReadKey();
            return;
        }
Пример #2
0
        internal byte[] Decrypt(byte[] input, byte[] key)
        {
            var aes = new AesCryptoServiceProvider();
            aes.Padding = PaddingMode.Zeros;
            aes.Mode = CipherMode.CBC;
            aes.Key = key;
            aes.IV = key;

            var crypto = aes.CreateDecryptor();
            var decrypted = crypto.TransformFinalBlock(input, 4, input.Length - 4);

            aes.Dispose();

            this.LastData = decrypted;

            return decrypted;
        }
Пример #3
0
        private void btn_dencrypt_Click(object sender, EventArgs e)
        {
            String toDecrypt = tb_toDencryptUTF8.Text;

            if (String.IsNullOrEmpty(toDecrypt)) return;

            AesCryptoServiceProvider aes = null;
            MemoryStream ms = null;
            CryptoStream cs = null;
            try
            {
                aes = new AesCryptoServiceProvider();
                aes.Key = key;
                aes.IV = iv;

                var encrypted = Convert.FromBase64String(tb_toDencryptB64.Text);
                ms = new MemoryStream(encrypted);
                cs = new CryptoStream(ms, aes.CreateDecryptor(), CryptoStreamMode.Read);

                byte[] buffer = new byte[encrypted.Length];
                int offset = cs.Read(buffer, 0, buffer.Length);

                tb_dencrypted.Text = Encoding.UTF8.GetString(buffer, 0, offset);
            }
            catch (Exception ex)
            {
                Console.WriteLine(ex);
                throw;
            }
            finally
            {
                if (aes != null) aes.Dispose();
                if (cs != null) cs.Dispose();
                if (ms != null) ms.Dispose();
            }
        }
Пример #4
0
        /// <summary>
        /// Encrypts/decrypts a byte array
        /// </summary>
        /// <param name="buffer">Bytes to crypt</param>
        /// <param name="key">"Password" for encryption</param>
        /// <param name="iv">"Salt" for encryption. A starting point for encryption.</param>
        /// <param name="encrypt">Do you wish to encrypt or decrypt?</param>
        /// <param name="algorithm">Encryption algorithm. AES/DES/TripleDES</param>
        /// <returns></returns>
        public static byte[] Crypt(byte[] buffer, byte[] key, byte[] iv, bool encrypt = true, string algorithm = "aes")
        {

            AesCryptoServiceProvider aes = null;
            DESCryptoServiceProvider des = null;
            TripleDESCryptoServiceProvider tripsDes = null;

            ICryptoTransform cryptor;

            switch (algorithm.ToLower())
            {

                case "aes":
                    aes = new AesCryptoServiceProvider();
                    aes.Key = key;
                    aes.IV = iv;
                    //aes.Padding = PaddingMode.None;

                    if (encrypt) cryptor = aes.CreateEncryptor();
                    else cryptor = aes.CreateDecryptor();

                    break;

                case "des":
                    des = new DESCryptoServiceProvider();
                    des.Key = key;
                    des.IV = iv;
                    //des.Padding = PaddingMode.None;

                    if (encrypt) cryptor = des.CreateEncryptor();
                    else cryptor = des.CreateDecryptor();

                    break;

                case "tripledes":
                    tripsDes = new TripleDESCryptoServiceProvider();
                    tripsDes.Key = key;
                    tripsDes.IV = iv;
                    //tripsDes.Padding = PaddingMode.None;


                    if (encrypt) cryptor = tripsDes.CreateEncryptor();
                    else cryptor = tripsDes.CreateDecryptor();

                    break;

                default:
                    throw new ArgumentException(algorithm + " is not an implemented encryption algorithm. Use AES/DES/TripleDES.");

            }
            try
            {

                return cryptor.TransformFinalBlock(buffer, 0, buffer.Length);

            }
            catch (CryptographicException)
            {
                throw new ArgumentException("Ensure you have the right key/IV.");
            }
            finally
            {

                                        cryptor.Dispose();
                if (aes != null)        aes.Dispose();
                if (des != null)        des.Dispose();
                if (tripsDes != null)   tripsDes.Dispose();

            }

        }
Пример #5
0
        static void Main(string[] args)
        {
            const int n = 100 * 1000;
            var sw = new Stopwatch();
            Random r = new Random();
            var data = new byte[1024];
            var key8B = new byte[8];
            var key16B = new byte[16];
            var key24B = new byte[24];
            var key32B = new byte[32];
            r.NextBytes(data);
            r.NextBytes(key8B);
            r.NextBytes(key16B);
            r.NextBytes(key24B);
            r.NextBytes(key32B);
            Action<string> outputToConsole = (s) =>
            {
                Console.ForegroundColor = ConsoleColor.Yellow;
                Console.WriteLine(s);
            };

            // AES
            Console.ForegroundColor = ConsoleColor.DarkCyan;
            Console.WriteLine("AES");
            var aes = new AesCryptoServiceProvider();
            aes.Padding = PaddingMode.PKCS7;
            aes.Key = key16B;
            Action doAes = () => EncryptDecryptAndDispose(aes.CreateEncryptor(), aes.CreateDecryptor(), data);
            doAes.Repeat(n)
                .OutputPerformance(sw, outputToConsole)();
            aes.Dispose();

            // RSA
            Console.ForegroundColor = ConsoleColor.DarkCyan;
            Console.WriteLine("DES");
            var des = new DESCryptoServiceProvider();
            des.IV = key8B;
            des.Key = key8B;
            Action doDes = () => EncryptDecryptAndDispose(des.CreateEncryptor(), des.CreateDecryptor(), data);
            doDes.Repeat(n)
                .OutputPerformance(sw, outputToConsole)();
            des.Dispose();

            // RC2
            Console.ForegroundColor = ConsoleColor.DarkCyan;
            Console.WriteLine("RC2");
            var rc2 = new RC2CryptoServiceProvider();
            rc2.IV = key8B;
            rc2.Key = key8B;
            Action doRc2 = () => EncryptDecryptAndDispose(rc2.CreateEncryptor(), rc2.CreateDecryptor(), data);
            doRc2.Repeat(n)
                .OutputPerformance(sw, outputToConsole)();
            rc2.Dispose();

            // Rijndael
            Console.ForegroundColor = ConsoleColor.DarkCyan;
            Console.WriteLine("Rijndael");
            var rijndael = new RijndaelManaged();
            rijndael.IV = key16B;
            rijndael.Key = key16B;
            Action doRijndael = () => EncryptDecryptAndDispose(rijndael.CreateEncryptor(), rijndael.CreateDecryptor(), data);
            doRijndael.Repeat(n)
                .OutputPerformance(sw, outputToConsole)();
            rijndael.Dispose();

            // 3DES
            Console.ForegroundColor = ConsoleColor.DarkCyan;
            Console.WriteLine("3DES");
            var tripleDes = new TripleDESCryptoServiceProvider();
            tripleDes.IV = key8B;
            tripleDes.Key = key24B;
            Action do3des = () => EncryptDecryptAndDispose(tripleDes.CreateEncryptor(), tripleDes.CreateDecryptor(), data);
            do3des.Repeat(n)
                .OutputPerformance(sw, outputToConsole)();
            tripleDes.Dispose();

            // RSA
            Console.ForegroundColor = ConsoleColor.DarkCyan;
            Console.WriteLine("RSA");
            RSAParameters param = new RSAParameters();
            param.Exponent = new byte[] {0, 1, 0};
            var store = new X509Store(StoreLocation.LocalMachine);
            store.Open(OpenFlags.ReadOnly);
            X509Certificate cert = null;
            foreach (X509Certificate cer in store.Certificates)
            {
                if (cer != null)
                {
                    cert = cer;
                    break;
                }
            }
            param.Modulus = cert.GetPublicKey();

            var rsa = new RSACryptoServiceProvider();
            rsa.ImportParameters(param);

            Action doRsa = () =>
                {

                    var encryptedData = rsa.Encrypt(key32B, true);
                    //var decryptedData = rsa.Decrypt(encryptedData, true);
                };
            doRsa.Repeat(n)
                .OutputPerformance(sw, outputToConsole)();
            rsa.Dispose();

            Console.Read();
        }
Пример #6
0
        private void btn_encrypt_Click(object sender, EventArgs e)
        {
            String toEncrypt = tb_toEncrypt.Text;

            if (String.IsNullOrEmpty(toEncrypt)) return;

            AesCryptoServiceProvider aes = null;
            MemoryStream ms = null;
            CryptoStream cs = null;
            try
            {
                var data = Encoding.UTF8.GetBytes(toEncrypt);
                aes = new AesCryptoServiceProvider();
                iv = aes.IV;
                key = aes.Key;
                ms = new MemoryStream();
                cs = new CryptoStream(ms, aes.CreateEncryptor(), CryptoStreamMode.Write);

                cs.Write(data, 0, data.Length);
                cs.Flush();
                if (!cs.HasFlushedFinalBlock)
                    cs.FlushFinalBlock();
                cs.Close();

                var encrypted = ms.ToArray();

                tb_toDencryptUTF8.Text = Encoding.UTF8.GetString(encrypted);
                tb_toDencryptB64.Text = Convert.ToBase64String(encrypted);
            }
            catch (Exception)
            {
                throw;
            }
            finally
            {
                if (aes != null) aes.Dispose();
                if (cs != null) cs.Dispose();
                if (ms != null) ms.Dispose();
            }
        }
        /// <summary>
        /// Decrypts plain text data using AES in CBC mode
        /// </summary>
        /// <param name="plainText"> cipher text data to be decrypted</param>
        /// <param name="iv">IV to be used for decryption</param>
        /// <returns>Returns decrypted plain text data</returns>
        private byte[] DecryptData(byte[] iv, byte[] cipherText, int offset, int count) {
            Debug.Assert((iv != null) && (cipherText != null));
            Debug.Assert (offset > -1 && count > -1);
            Debug.Assert ((count+offset) <= cipherText.Length);

            byte[] plainText;
            AesCryptoServiceProvider aesAlg;

            // Try to get a provider from the pool.
            // If no provider is available, create a new one.
            if (!_cryptoProviderPool.TryDequeue(out aesAlg)) {
                aesAlg = new AesCryptoServiceProvider();

                try {
                    // Set various algorithm properties
                    aesAlg.Key = _columnEncryptionKey.EncryptionKey;
                    aesAlg.Mode = _cipherMode;
                    aesAlg.Padding = _paddingMode;
                }
                catch (Exception) {
                    if (aesAlg != null) {
                        aesAlg.Dispose();
                    }

                    throw;
                }
            }

            try {
                // Always set the IV since it changes from cell to cell.
                aesAlg.IV = iv;

                // Create the streams used for decryption. 
                using (MemoryStream msDecrypt = new MemoryStream()) {
                    // Create an encryptor to perform the stream transform.
                    using (ICryptoTransform decryptor = aesAlg.CreateDecryptor()) {
                        using (CryptoStream csDecrypt = new CryptoStream(msDecrypt, decryptor, CryptoStreamMode.Write)) {
                            // Decrypt the secret message and get the plain text data
                            csDecrypt.Write(cipherText, offset, count);
                            csDecrypt.FlushFinalBlock();
                            plainText = msDecrypt.ToArray();
                        }
                    }
                }
            }
            finally {
                // Return the provider to the pool.
                _cryptoProviderPool.Enqueue(aesAlg);
            }

            return plainText;
        }
        /// <summary>
        /// Encryption Algorithm
        /// cell_iv = HMAC_SHA-2-256(iv_key, cell_data) truncated to 128 bits
        /// cell_ciphertext = AES-CBC-256(enc_key, cell_iv, cell_data) with PKCS7 padding.
        /// (optional) cell_tag = HMAC_SHA-2-256(mac_key, versionbyte + cell_iv + cell_ciphertext + versionbyte_length)
        /// cell_blob = versionbyte + [cell_tag] + cell_iv + cell_ciphertext
        /// </summary>
        /// <param name="plainText">Plaintext data to be encrypted</param>
        /// <param name="hasAuthenticationTag">Does the algorithm require authentication tag.</param>
        /// <returns>Returns the ciphertext corresponding to the plaintext.</returns>
        protected byte[] EncryptData(byte[] plainText, bool hasAuthenticationTag) {
            // Empty values get encrypted and decrypted properly for both Deterministic and Randomized encryptions.
            Debug.Assert(plainText != null);

            byte[] iv = new byte[_BlockSizeInBytes];

            // Prepare IV
            // Should be 1 single block (16 bytes)
            if (_isDeterministic) {
                SqlSecurityUtility.GetHMACWithSHA256(plainText, _columnEncryptionKey.IVKey, iv);
            }
            else {
                SqlSecurityUtility.GenerateRandomBytes(iv);
            }

            int numBlocks = plainText.Length / _BlockSizeInBytes + 1;

            // Final blob we return = version + HMAC + iv + cipherText
            const int hmacStartIndex = 1;
            int authenticationTagLen = hasAuthenticationTag ? _KeySizeInBytes : 0;
            int ivStartIndex = hmacStartIndex + authenticationTagLen;
            int cipherStartIndex = ivStartIndex + _BlockSizeInBytes; // this is where hmac starts.

            // Output buffer size = size of VersionByte + Authentication Tag + IV + cipher Text blocks.
            int outputBufSize = sizeof(byte) + authenticationTagLen + iv.Length + (numBlocks*_BlockSizeInBytes);
            byte[] outBuffer = new byte[outputBufSize];

            // Store the version and IV rightaway
            outBuffer[0] = _algorithmVersion;
            Buffer.BlockCopy(iv, 0, outBuffer, ivStartIndex, iv.Length);

            AesCryptoServiceProvider aesAlg;

            // Try to get a provider from the pool.
            // If no provider is available, create a new one.
            if (!_cryptoProviderPool.TryDequeue(out aesAlg)) {
                aesAlg = new AesCryptoServiceProvider();

                try {
                    // Set various algorithm properties
                    aesAlg.Key = _columnEncryptionKey.EncryptionKey;
                    aesAlg.Mode = _cipherMode;
                    aesAlg.Padding = _paddingMode;
                }
                catch (Exception) {
                    if (aesAlg != null) {
                        aesAlg.Dispose();
                    }

                    throw;
                }
            }

            try {
                // Always set the IV since it changes from cell to cell.
                aesAlg.IV = iv;

                // Compute CipherText and authentication tag in a single pass
                using (ICryptoTransform encryptor = aesAlg.CreateEncryptor()) {
                    Debug.Assert(encryptor.CanTransformMultipleBlocks, "AES Encryptor can transform multiple blocks");
                    int count = 0;
                    int cipherIndex = cipherStartIndex; // this is where cipherText starts
                    if (numBlocks > 1) {
                        count = (numBlocks - 1) * _BlockSizeInBytes;
                        cipherIndex += encryptor.TransformBlock(plainText, 0, count, outBuffer, cipherIndex);
                    }

                    byte[] buffTmp = encryptor.TransformFinalBlock(plainText, count, plainText.Length - count); // done encrypting
                    Buffer.BlockCopy(buffTmp, 0, outBuffer, cipherIndex, buffTmp.Length);
                    cipherIndex += buffTmp.Length;
                }

                if (hasAuthenticationTag) {
                    using (HMACSHA256 hmac = new HMACSHA256(_columnEncryptionKey.MACKey)) {
                        Debug.Assert(hmac.CanTransformMultipleBlocks, "HMAC can't transform multiple blocks");
                        hmac.TransformBlock(_version, 0, _version.Length, _version, 0);
                        hmac.TransformBlock(iv, 0, iv.Length, iv, 0);

                        // Compute HMAC on final block
                        hmac.TransformBlock(outBuffer, cipherStartIndex, numBlocks * _BlockSizeInBytes, outBuffer, cipherStartIndex);
                        hmac.TransformFinalBlock(_versionSize, 0, _versionSize.Length);
                        byte[] hash = hmac.Hash;
                        Debug.Assert(hash.Length >= authenticationTagLen, "Unexpected hash size");
                        Buffer.BlockCopy(hash, 0, outBuffer, hmacStartIndex, authenticationTagLen);
                    }
                }
            }
            finally {
                // Return the provider to the pool.
                _cryptoProviderPool.Enqueue(aesAlg);
            }

            return outBuffer;
        }