private async Task <byte[]> AliceSendsDataAsync(string message)
{
WriteLine($"Alice sends message: {message}");
byte[] rawData = Encoding.UTF8.GetBytes(message);
byte[] encryptedData = null;
using (var aliceAlgorithm = new ECDiffieHellmanCng(_aliceKey))
using (CngKey bobPubKey = CngKey.Import(_bobPubKeyBlob,
CngKeyBlobFormat.EccPublicBlob))
{
byte[] symmKey = aliceAlgorithm.DeriveKeyMaterial(bobPubKey);
WriteLine("Alice creates this symmetric key with " +
$"Bobs public key information: { Convert.ToBase64String(symmKey)}");
using (var aes = new AesCryptoServiceProvider())
{
aes.Key = symmKey;
aes.GenerateIV();
using (ICryptoTransform encryptor = aes.CreateEncryptor())
using (var ms = new MemoryStream())
{
// create CryptoStream and encrypt data to send
using (var cs = new CryptoStream(ms, encryptor, CryptoStreamMode.Write))
{
// write initialization vector not encrypted
await ms.WriteAsync(aes.IV, 0, aes.IV.Length);
await cs.WriteAsync(rawData, 0, rawData.Length);
}
encryptedData = ms.ToArray();
}
aes.Clear();
}
}
WriteLine($"Alice: message is encrypted: {Convert.ToBase64String(encryptedData)}");;
WriteLine();
return(encryptedData);
}
public static string AESDecrypt(string hexString, string key = "56dPz3VDYwGpJYqe7dFG0g==")
{
try
{
using (AesCryptoServiceProvider aesProvider = new AesCryptoServiceProvider())
{
aesProvider.Key = Convert.FromBase64String(key);
aesProvider.Mode = CipherMode.ECB;
aesProvider.Padding = PaddingMode.PKCS7;
using (ICryptoTransform cryptoTransform = aesProvider.CreateDecryptor())
{
hexString = hexString.ToLower();
byte[] byteArray = new byte[hexString.Length >> 1];
int index = 0;
for (int i = 0; i < hexString.Length; i++)
{
if (index > hexString.Length - 1)
{
continue;
}
byte highDit = (byte)(Digit(hexString[index], 16) & 0xFF);
byte lowDit = (byte)(Digit(hexString[index + 1], 16) & 0xFF);
byteArray[i] = (byte)(highDit << 4 | lowDit & 0xFF);
index += 2;
}
byte[] inputBuffers = byteArray;
byte[] results = cryptoTransform.TransformFinalBlock(inputBuffers, 0, inputBuffers.Length);
aesProvider.Clear();
return(Encoding.UTF8.GetString(results));
}
}
}
catch (Exception)
{
return(string.Empty);
}
}
/// <summary>
/// Aes解密
/// </summary>
/// <param name="source">源字符串</param>
/// <param name="key">aes密钥,长度必须32位</param>
/// <returns>解密后的字符串</returns>
public static string DecryptAes(string source, string key)
{
try
{
using (AesCryptoServiceProvider aesProvider = new AesCryptoServiceProvider())
{
aesProvider.Key = GetAesKey(key);
aesProvider.Mode = CipherMode.ECB;
aesProvider.Padding = PaddingMode.PKCS7;
using (ICryptoTransform cryptoTransform = aesProvider.CreateDecryptor())
{
byte[] inputBuffers = Convert.FromBase64String(source);
byte[] results = cryptoTransform.TransformFinalBlock(inputBuffers, 0, inputBuffers.Length);
aesProvider.Clear();
return(Encoding.UTF8.GetString(results));
}
}
}
catch
{
return(null);
}
}
public static string DecryptString(string toDecrypt)
{
byte[] toEncryptArray = Convert.FromBase64String(toDecrypt);
byte[] IV = UTF8Encoding.UTF8.GetBytes("zT$3qIjUR$4rIj45");
string decryptionKey = "b14ca5898a4e4133bbce2ea2315a1910";
byte[] keyArray = UTF8Encoding.UTF8.GetBytes(decryptionKey);
AesCryptoServiceProvider aes = new AesCryptoServiceProvider();
aes.Key = keyArray;
//aes.KeySize = 256;
aes.BlockSize = 128;
aes.IV = IV;
aes.Padding = PaddingMode.PKCS7;
aes.Mode = CipherMode.CBC;
var transform = aes.CreateDecryptor();
var outputArray = transform.TransformFinalBlock(toEncryptArray, 0, toEncryptArray.Length);
aes.Clear();
return(UTF8Encoding.UTF8.GetString(outputArray));
}
public TestSymmetricKeyProvider(params string[] ids)
{
_keys = new Dictionary <string, TestSymmetricKey>();
foreach (var id in ids.Concat(new[] { "default" }).Distinct())
{
byte[] key;
byte[] iv;
using (var provider = new AesCryptoServiceProvider())
{
provider.GenerateIV();
provider.GenerateKey();
key = provider.Key;
iv = provider.IV;
provider.Clear();
}
_keys.Add(id, new TestSymmetricKey(key, iv));
}
}
public static string DecryptAES(string hash, string key, bool hashKey = true)
{
if (hash == null || key == null)
{
return(null);
}
var keyArray = HexStringToByteArray(hashKey ? HashMD5(key) : key);
var toEncryptArray = HexStringToByteArray(hash);
var aes = new AesCryptoServiceProvider
{
Key = keyArray,
Mode = CipherMode.ECB,
Padding = PaddingMode.PKCS7
};
var cTransform = aes.CreateDecryptor();
var resultArray = cTransform.TransformFinalBlock(toEncryptArray, 0, toEncryptArray.Length);
aes.Clear();
return(Encoding.UTF8.GetString(resultArray));
}
/// <summary>
/// AES解密
/// </summary>
/// <param name="data"></param>
/// <param name="key"></param>
/// <returns></returns>
public static string DeAES(byte[] content, string key)
{
KeyGenerator kgen = KeyGenerator.getInstance("AES");
SecureRandom secureRandom = SecureRandom.getInstance("SHA1PRNG");
secureRandom.setSeed(Encoding.ASCII.GetBytes(key));
kgen.init(128, secureRandom);
SecretKey secretKey = kgen.generateKey();
byte[] enCodeFormat = secretKey.getEncoded();
using (AesCryptoServiceProvider aesProvider = new AesCryptoServiceProvider())
{
aesProvider.Key = enCodeFormat;
aesProvider.Mode = CipherMode.ECB;
aesProvider.Padding = PaddingMode.PKCS7;
using (ICryptoTransform cryptoTransform = aesProvider.CreateDecryptor())
{
byte[] inputBuffers = content;
byte[] results = cryptoTransform.TransformFinalBlock(inputBuffers, 0, inputBuffers.Length);
aesProvider.Clear();
return Encoding.UTF8.GetString(results);
}
}
}
/// <summary>
/// 加密字节数组
/// </summary>
public static byte[] Encrypt(byte[] decodeBytes, string key, bool needIV = false)
{
decodeBytes.CheckNotNull("decodeBytes");
using (AesCryptoServiceProvider provider = new AesCryptoServiceProvider())
{
provider.Key = CheckKey(key);
provider.Padding = PaddingMode.PKCS7;
provider.Mode = CipherMode.ECB;
byte[] ivBytes = { };
if (needIV)
{
provider.Mode = CipherMode.CBC;
provider.GenerateIV();
ivBytes = provider.IV;
}
using (ICryptoTransform encryptor = provider.CreateEncryptor())
{
byte[] encodeBytes = encryptor.TransformFinalBlock(decodeBytes, 0, decodeBytes.Length);
provider.Clear();
return(needIV ? ivBytes.Concat(encodeBytes).ToArray() : encodeBytes);
}
}
}
static string Encode(long value, byte[] key)
{
byte[] InputBuffer = new byte[16];
byte[] OutputBuffer;
unsafe
{
fixed(byte *pInputBuffer = InputBuffer)
{
((long *)pInputBuffer)[0] = value;
((long *)pInputBuffer)[1] = value;
}
}
AesCryptoServiceProvider Aes = new AesCryptoServiceProvider();
Aes.Mode = CipherMode.ECB;
Aes.Padding = PaddingMode.None;
Aes.Key = key;
using (ICryptoTransform Encryptor = Aes.CreateEncryptor()) {
OutputBuffer = Encryptor.TransformFinalBlock(InputBuffer, 0, 16);
}
Aes.Clear();
return(ToHex(OutputBuffer));
}
/// <summary>
/// 加密
/// </summary>
/// <param name="message"></param>
/// <returns></returns>
private async Task <byte[]> AliceSendsDataAsync(string message)
{
Console.WriteLine("Alice sends message:" + message);
byte[] rawData = Encoding.UTF8.GetBytes(message);
byte[] encryptedData = null;
//创建ECDiffieHellmanCng对象,并使用Alice的密钥对初始化它
using (ECDiffieHellmanCng aliceAlgorithm = new ECDiffieHellmanCng(_aliceKey))
using (CngKey bobPubKey = CngKey.Import(_bobPubKeyBlob, CngKeyBlobFormat.EccPublicBlob))
{
//使用Alice的密钥对和Bob的公钥创建一个对称密钥,返回的对称密钥使用对称算法AES加密数据
byte[] symmKey = aliceAlgorithm.DeriveKeyMaterial(bobPubKey);
Console.WriteLine("Alice creates thsi symmetric key with Bobs public key Information:" + Convert.ToBase64String(symmKey));
//
using (AesCryptoServiceProvider aes = new AesCryptoServiceProvider())
{
aes.Key = symmKey;
aes.GenerateIV();
using (ICryptoTransform encryptor = aes.CreateEncryptor())
using (MemoryStream ms = new MemoryStream())
{
using (CryptoStream cs = new CryptoStream(ms, encryptor, CryptoStreamMode.Write))
{
await ms.WriteAsync(aes.IV, 0, aes.IV.Length);
cs.Write(rawData, 0, rawData.Length);
}
encryptedData = ms.ToArray();
}
//在访问内存流中的加密数据之前,必须关闭加密流,否则加密数据就会丢失最后的位
aes.Clear();
}
}
Console.WriteLine("Alice:message is encrypted:" + Convert.ToBase64String(encryptedData));
Console.WriteLine();
return(encryptedData);
}
/*Bob receives encrypted data in the argument of the method BobReceivesData() . First, the
* unencrypted initialization vector must be read. The BlockSize property of the class
* AesCryptoServiceProvider returns the number of bits for a block. The number of bytes can be
* calculated by doing a divide by 8, and the fastest way to do this is by doing a bit shift of 3 bits. Shifting
* by 1 bit is a division by 2, 2 bits by 4, and 3 bits by 8. With the for loop, the first bytes of the raw bytes
* that contain the IV unencrypted are written to the array iv . Next, an ECDiffieHellmanCng object is
* instantiated with the key pair from Bob. Using the public key from Alice, the symmetric key is returned
* from the method DeriveKeyMaterial() . Comparing the symmetric keys created from Alice and Bob
* shows that the same key value gets created. Using this symmetric key and the initialization vector, the
* message from Alice can be decrypted with the AesCryptoServiceProvider class.
*/
private static void BobReceivesData(byte[] encryptedData)
{
ReturnString += String.Format("\n\nBob receives encrypted data");
byte[] rawData = null;
AesCryptoServiceProvider aes = new AesCryptoServiceProvider();
int nBytes = aes.BlockSize >> 3;
byte[] iv = new byte[nBytes];
for (int i = 0; i < iv.Length; i++)
{
iv[i] = encryptedData[i];
}
ECDiffieHellmanCng bobAlgorithm = new ECDiffieHellmanCng(bobKey);
using (CngKey alicePubKey = CngKey.Import(alicePubKeyBlob,
CngKeyBlobFormat.EccPublicBlob))
{
byte[] symmKey = bobAlgorithm.DeriveKeyMaterial(alicePubKey);
ReturnString += String.Format("\nBob creates this symmetric key with " +
"Alice's public key information: {0}",
Convert.ToBase64String(symmKey));
aes.Key = symmKey;
aes.IV = iv;
using (ICryptoTransform decryptor = aes.CreateDecryptor())
using (MemoryStream ms = new MemoryStream())
{
CryptoStream cs = new CryptoStream(ms, decryptor,
CryptoStreamMode.Write);
cs.Write(encryptedData, nBytes, encryptedData.Length - nBytes);
cs.Close();
rawData = ms.ToArray();
ReturnString += String.Format("\nBob decrypts message to: {0}",
Encoding.UTF8.GetString(rawData));
}
aes.Clear();
}
}
public string Decrypt(string input)
{
if (string.IsNullOrEmpty(input))
{
return(input);
}
var inputBuffer = Convert.FromBase64String(input);
var cryptoServiceProvider1 = new MD5CryptoServiceProvider();
var hash =
cryptoServiceProvider1.ComputeHash(Encoding.UTF8.GetBytes(GetOriginalString(_salt).ToCharArray()));
cryptoServiceProvider1.Clear();
var cryptoServiceProvider2 = new AesCryptoServiceProvider
{
Key = hash, Mode = CipherMode.ECB, Padding = PaddingMode.PKCS7
};
var decryptor = cryptoServiceProvider2.CreateDecryptor();
var bytes = decryptor.TransformFinalBlock(inputBuffer, 0, inputBuffer.Length);
decryptor.Dispose();
cryptoServiceProvider2.Clear();
return(Encoding.UTF8.GetString(bytes));
}
public async Task BobReceivesDataAsync(byte[] encryptedData)
{
Console.WriteLine("Bob receives encrypted data");
byte[] rawData = null;
var aes = new AesCryptoServiceProvider();
int nBytes = aes.BlockSize;
byte[] iv = new byte[nBytes];
for (int i = 0; i < iv.Length; i++)
{
iv[i] = encryptedData[i];
}
using (var bobAlgorithm = new ECDiffieHellmanCng(bobKey))
{
using (CngKey alicePubKey = CngKey.Import(_alicePubKeyBlob, CngKeyBlobFormat.EccFullPublicBlob))
{
byte[] symmKey = bobAlgorithm.DeriveKeyMaterial(alicePubKey);
Console.WriteLine(Convert.ToBase64String(symmKey));
aes.Key = symmKey;
aes.IV = iv;
using (ICryptoTransform decryptor = aes.CreateDecryptor())
{
using (MemoryStream ms = new MemoryStream())
{
using (var cs = new CryptoStream(ms, decryptor, CryptoStreamMode.Write))
{
await cs.WriteAsync(encryptedData, nBytes, encryptedData.Length - nBytes);
}
rawData = ms.ToArray();
Console.WriteLine(Encoding.UTF8.GetString(rawData));
}
aes.Clear();
}
}
}
}
/// <summary>
/// 解密
/// </summary>
/// <param name="encrytpedData"></param>
/// <returns></returns>
private async Task BobReceivesDataAsync(byte[] encrytpedData)
{
Console.WriteLine("Bob receives encrypted data");
byte[] rawData = null;
//读取未加密的初始化矢量
AesCryptoServiceProvider aes = new AesCryptoServiceProvider();
//BlockSize属性返回块的位数,除以8就可以计算出字节数。
int nBytes = aes.BlockSize / 8;
byte[] iv = new byte[nBytes];
for (int i = 0; i < iv.Length; i++)
{
iv[i] = encrytpedData[i];
}
//实例化一个ECDiffieHellmanCng对象,使用Alice的公钥,从DeriveKeyMaterial()方法中返回对称密钥
using (ECDiffieHellmanCng bobAlgorithm = new ECDiffieHellmanCng(_bobKey))
using (CngKey alicePubKey = CngKey.Import(_alicePubKeyBlob, CngKeyBlobFormat.EccPublicBlob))
{
byte[] symmKey = bobAlgorithm.DeriveKeyMaterial(alicePubKey);
Console.WriteLine("Bob creates this symmetric key with Alices public key information:" + Convert.ToBase64String(symmKey));
aes.Key = symmKey;
aes.IV = iv;
using (ICryptoTransform decryptor = aes.CreateDecryptor())
using (MemoryStream ms = new MemoryStream())
{
using (CryptoStream cs = new CryptoStream(ms, decryptor, CryptoStreamMode.Write))
{
await cs.WriteAsync(encrytpedData, nBytes, encrytpedData.Length - nBytes);
}
rawData = ms.ToArray();
Console.WriteLine("Bob decrypts mesage to:" + Encoding.UTF8.GetString(rawData));
}
aes.Clear();
}
}
// decryption
static byte[] Decrypt(byte[] cipherBytes, byte[] key, byte[] iv)
{
byte[] plainBytes;
using (var aes = new AesCryptoServiceProvider())
{
//aes.Mode = CipherMode.CBC; // default
//aes.Padding = PaddingMode.PKCS7; // default
aes.Key = key;
aes.IV = iv;
using (var memoryStream = new MemoryStream())
{
var cryptoStream = new CryptoStream(
memoryStream, aes.CreateDecryptor(), CryptoStreamMode.Write);
cryptoStream.Write(cipherBytes, 0, cipherBytes.Length);
cryptoStream.FlushFinalBlock();
plainBytes = memoryStream.ToArray();
}
aes.Clear();
}
return(plainBytes);
}
private static void AnaPrimaPoruku(byte[] kriptiraniPodaci)
{
Console.WriteLine("Ana prima kriptiranu poruku");
byte[] podaci = null;
var aes = new AesCryptoServiceProvider();
int nBytes = aes.BlockSize >> 3;
byte[] iv = new byte[nBytes];
for (int i = 0; i < iv.Length; i++)
{
iv[i] = kriptiraniPodaci[i];
}
using (var anaAlgoritam = new ECDiffieHellmanCng(anakey))
using (CngKey ivanPubKey = CngKey.Import(ivanPubKeyBlob, CngKeyBlobFormat.EccPublicBlob))
{
byte[] simKljuč = anaAlgoritam.DeriveKeyMaterial(ivanPubKey);
Console.WriteLine("Ana kreira simetrični ključ s Ivanovim javnim ključem: {0}", Convert.ToBase64String(simKljuč));
aes.Key = simKljuč;
aes.IV = iv;
using (ICryptoTransform decryptor = aes.CreateDecryptor())
using (MemoryStream ms = new MemoryStream())
{
var cs = new CryptoStream(ms, decryptor, CryptoStreamMode.Write);
cs.Write(kriptiraniPodaci, nBytes, kriptiraniPodaci.Length - nBytes);
cs.Close();
podaci = ms.ToArray();
Console.WriteLine("Ana dekriptira poruku: {0}", Encoding.UTF8.GetString(podaci));
}
aes.Clear();
}
}
private static byte[] Encrypt(byte[] toEncrypt, byte[] key)
{
List <byte> te = toEncrypt.ToList();
while (te.Count % 16 != 0)
{
te.Add(0x00);
}
toEncrypt = te.ToArray();
AesCryptoServiceProvider aes = CreateProvider(key);
List <byte> K = new List <byte>();
K = key.ToList();
while (K.Count < 32)
{
K.Add(0x00);
}
key = K.ToArray();
ICryptoTransform cTransform = aes.CreateEncryptor();
byte[] resultArray = cTransform.TransformFinalBlock(toEncrypt, 0, toEncrypt.Length);
aes.Clear();
return(resultArray);
}
public static bool DecryptData(string data, string key, out string?output)
{
key = FixKeyLength(key);
try
{
var array = Convert.FromBase64String(data);
var provider = new AesCryptoServiceProvider
{
Key = Encoding.UTF8.GetBytes(key),
Mode = CipherMode.ECB,
Padding = PaddingMode.PKCS7
};
var decryptor = provider.CreateDecryptor();
var resultArray = decryptor.TransformFinalBlock(array, 0, array.Length);
provider.Clear();
output = Encoding.UTF8.GetString(resultArray);
return(true);
}
catch
{
output = null;
return(false);
}
}
private string Encrypt(string text, string strMeterID)
{
string strAESKey = string.Empty;
//Need to check does the key exist
using (var db = new uwkeydataEntities1())
{
foreach (MeterKey mk in db.MeterKeys)
{
if (mk.MeterID == strMeterID)
{
strAESKey = mk.AesKey;
}
}
}
//if key does not already exist
if (strAESKey == string.Empty)
{
//make key on the fly
using (RijndaelManaged myRijndael = new RijndaelManaged())
{
myRijndael.KeySize = 128;
myRijndael.GenerateKey();
// we dont need iv just key value
//myRijndael.GenerateIV();
byte[] xkey = myRijndael.Key;
//var xIV = myRijndael.IV;
AesCryptoServiceProvider aes;
// AesCryptoServiceProvider
using (aes = new AesCryptoServiceProvider())
{
aes.BlockSize = 128;
aes.KeySize = 128;
aes.IV = Encoding.UTF8.GetBytes(AesIV);
aes.Key = xkey;
aes.Mode = CipherMode.CBC;
aes.Padding = PaddingMode.PKCS7;
//store meterID AES Key AES IV in Database
using (var db = new uwkeydataEntities1())
{
MeterKey mk = new MeterKey();
mk.MeterID = strMeterID;
mk.AesKey = Convert.ToBase64String(aes.Key);
db.MeterKeys.Add(mk);
db.SaveChanges();
}
//byte[] encrypted = EncryptStringToBytes(original, myRijndael.Key, myRijndael.IV);
// Convert string to byte array
byte[] src = Encoding.Unicode.GetBytes(text);
// encryption
using (ICryptoTransform encrypt = aes.CreateEncryptor())
{
byte[] dest = encrypt.TransformFinalBlock(src, 0, src.Length);
aes.Clear();
aes.Dispose();
encrypt.Dispose();
// Convert byte array to Base64 strings
return(Convert.ToBase64String(dest));
}
}
}
}
else
{
//we have the key
AesCryptoServiceProvider aes;
// AesCryptoServiceProvider
using (aes = new AesCryptoServiceProvider())
{
aes.BlockSize = 128;
aes.KeySize = 128;
aes.IV = Encoding.UTF8.GetBytes(AesIV);
//aes.Key = Encoding.UTF8.GetBytes(strAESKey);
aes.Key = System.Convert.FromBase64String(strAESKey);
aes.Mode = CipherMode.CBC;
aes.Padding = PaddingMode.PKCS7;
//byte[] encrypted = EncryptStringToBytes(original, myRijndael.Key, myRijndael.IV);
// Convert string to byte array
byte[] src = Encoding.Unicode.GetBytes(text);
// encryption
using (ICryptoTransform encrypt = aes.CreateEncryptor())
{
byte[] dest = encrypt.TransformFinalBlock(src, 0, src.Length);
aes.Clear();
aes.Dispose();
encrypt.Dispose();
// Convert byte array to Base64 strings
return(Convert.ToBase64String(dest));
}
}
}
}
public static byte[] EncryptAESCryptProvider(byte[] privacyKey, byte[] scopedPDU, int pduLen, int snmpEngineBoots, int snmpEngineTime, int keySize)
{
int keyBytes = (keySize == 128) ? 16 : 32;
// Salt determinitation for Privacy Parameters
Int64 saltInt = NextSalt();
byte[] saltInvert = BitConverter.GetBytes(saltInt);
byte[] salt = new byte[8];
salt[0] = saltInvert[7];
salt[1] = saltInvert[6];
salt[2] = saltInvert[5];
salt[3] = saltInvert[4];
salt[4] = saltInvert[3];
salt[5] = saltInvert[2];
salt[6] = saltInvert[1];
salt[7] = saltInvert[0];
byte[] IV = new byte[keyBytes];
byte[] bootsBytes = BitConverter.GetBytes(snmpEngineBoots);
IV[0] = bootsBytes[3];
IV[1] = bootsBytes[2];
IV[2] = bootsBytes[1];
IV[3] = bootsBytes[0];
byte[] timeBytes = BitConverter.GetBytes(snmpEngineTime);
IV[4] = timeBytes[3];
IV[5] = timeBytes[2];
IV[6] = timeBytes[1];
IV[7] = timeBytes[0];
// Copy salt value to the iv array
Buffer.BlockCopy(salt, 0, IV, 8, 8);
// Create AES Key
byte[] aesKey = new byte[keyBytes];
Buffer.BlockCopy(privacyKey, 0, aesKey, 0, keyBytes);
byte[] encryptedRtn = new byte[scopedPDU.Length];
try
{
//perform the encyption..
//step 1.. Create the stream which will contain the encrypted data
System.IO.MemoryStream memStrm = new System.IO.MemoryStream();
//create the DES crypto service provider object
System.Security.Cryptography.AesCryptoServiceProvider des = new AesCryptoServiceProvider();
//set the cipher mode
des.KeySize = keyBytes * 8;
// PVC Setting to 128 caused Bad Data err des.FeedbackSize = 128;
des.BlockSize = bsBlockSize;
des.Padding = pmPaddingMode;
des.Mode = cmCipherMode;
des.Key = aesKey;
des.IV = IV;
//create the stream which will convert the data into enryped form and write into underline stream
ICryptoTransform cryptoTransform = des.CreateEncryptor(aesKey, IV);
CryptoStream encryptStrm = new CryptoStream(memStrm, cryptoTransform /* PVC des.CreateEncryptor(aesKey, IV)*/, CryptoStreamMode.Write);
//wencypt and write data into underline stream
encryptStrm.Write(scopedPDU, 0, scopedPDU.Length);
//flush the final block to stream
encryptStrm.FlushFinalBlock();
//close the streams
encryptStrm.Close();
//set the encypted data buffer
encryptedRtn = memStrm.ToArray();
//close the memory stream
memStrm.Close();
des.Clear();
}
catch (Exception exp)
{
}
return(encryptedRtn);
}
public string BRAPI_encrypt(string encrypt_Input)
{
// Assign the developer details to variables got from the UI textboxes
string devID = "your devID";
string devKey = "your devKey";
string devIV = "your devIV";
#region CODE FROM BR Documentation - http://www.blackoutrugby.com/game/help.documentation.php#category=35
// This is all from the Blackout Rugby documentation
// only changes are variables instead of direct string input
// Create an unencrypted request as an array of bytes
byte[] request = UTF8Encoding.UTF8.GetBytes(encrypt_Input);
// Set the key and IV as arrays of bytes
byte[] key = UTF8Encoding.UTF8.GetBytes(devKey);
byte[] iv = UTF8Encoding.UTF8.GetBytes(devIV);
// Create an instance of the AES Encryptor
AesCryptoServiceProvider aes = new AesCryptoServiceProvider();
// Set the key and IV
aes.Key = key;
aes.IV = iv;
// Set the mode of the AES Encryptor
aes.Mode = CipherMode.CBC;
// Set the padding mode of the AES Encryptor
aes.Padding = PaddingMode.Zeros;
// Get the transformer from the AES Encryptor
ICryptoTransform cTransform = aes.CreateEncryptor();
// Use the transformer to encrypt our request
byte[] result =
cTransform.TransformFinalBlock(request, 0, request.Length);
// Release resources held by AES Encryptor
aes.Clear();
// Encode to base64
string encryptedRequest =
Convert.ToBase64String(result, 0, result.Length);
// Send request to API
//string baseURL = "http://api.blackoutrugby.com/";
string requestString = devID + "&er=" + encryptedRequest;
//string response = getWebResponse(requestString); // Second function is called here <---
#region WebRequest Code
// Create a request for the URL.
WebRequest webRequest = WebRequest.Create("http://classic-api.blackoutrugby.com/?d=" + requestString);
WebResponse Webresponse = webRequest.GetResponse();
//Get the stream containing content returned by the server.
Stream dataStream = Webresponse.GetResponseStream();
// Open the stream using a StreamReader for easy access.
StreamReader reader = new StreamReader(dataStream);
// Read the content.
string responseFromServer = reader.ReadToEnd();
// Clean up the streams and the response.
reader.Close();
Webresponse.Close();
#endregion
return(responseFromServer);
#endregion CODE FROM BR Documentation
}
public void Dispose()
{
AES.Clear();
}