private void CheckECB(int effective_bits, byte[] key, byte[] pt, byte[] expected)
{
RC2 c = RC2.Create();
c.Mode = CipherMode.ECB;
c.Padding = PaddingMode.Zeros;
c.Key = key;
AssertEquals("KeySize", key.Length * 8, c.KeySize);
c.EffectiveKeySize = effective_bits;
ICryptoTransform encryptor = c.CreateEncryptor();
ICryptoTransform decryptor = c.CreateDecryptor();
byte[] ct = new byte [pt.Length];
int n = encryptor.TransformBlock(pt, 0, pt.Length, ct, 0);
AssertEquals("EncryptLen", n, pt.Length);
for (int i = 0; i < n; i++)
{
AssertEquals("Encrypt" + i, ct [i], expected [i]);
}
byte[] rt = new byte [ct.Length];
n = decryptor.TransformBlock(ct, 0, ct.Length, rt, 0);
AssertEquals("DecryptLen", n, ct.Length);
for (int i = 0; i < n; i++)
{
AssertEquals("Decrypt" + i, rt [i], pt [i]);
}
}
public static void InvalidCFBFeedbackSizes(int feedbackSize, bool discoverableInSetter)
{
using (RC2 rc2 = RC2Factory.Create())
{
rc2.GenerateKey();
rc2.Mode = CipherMode.CFB;
if (discoverableInSetter)
{
// there are some key sizes that are invalid for any of the modes,
// so the exception is thrown in the setter
Assert.Throws <CryptographicException>(() =>
{
rc2.FeedbackSize = feedbackSize;
});
}
else
{
rc2.FeedbackSize = feedbackSize;
// however, for CFB only few sizes are valid. Those should throw in the
// actual RC2 instantiation.
Assert.Throws <CryptographicException>(() => rc2.CreateDecryptor());
Assert.Throws <CryptographicException>(() => rc2.CreateEncryptor());
}
}
}
public static void MultipleBlockDecryptTransform(bool blockAlignedOutput)
{
const string ExpectedOutput = "This is a test";
int outputPadding = blockAlignedOutput ? 0 : 3;
byte[] key = "0123456789ABCDEF".HexToByteArray();
byte[] iv = "0123456789ABCDEF".HexToByteArray();
byte[] outputBytes = new byte[iv.Length * 2 + outputPadding];
byte[] input = "DB5400368C7E67FF5F9E1FA99641EB69".HexToByteArray();
int outputOffset = 0;
using (RC2 alg = RC2Factory.Create())
using (ICryptoTransform xform = alg.CreateDecryptor(key, iv))
{
Assert.Equal(2 * alg.BlockSize, (outputBytes.Length - outputPadding) * 8);
outputOffset += xform.TransformBlock(input, 0, input.Length, outputBytes, outputOffset);
byte[] overflow = xform.TransformFinalBlock(Array.Empty <byte>(), 0, 0);
Buffer.BlockCopy(overflow, 0, outputBytes, outputOffset, overflow.Length);
outputOffset += overflow.Length;
}
string decrypted = Encoding.ASCII.GetString(outputBytes, 0, outputOffset);
Assert.Equal(ExpectedOutput, decrypted);
}
public static void DecryptorReuse_LeadsToSameResults(CipherMode cipherMode, int feedbackSize)
{
// AppleCCCryptor does not allow calling Reset on CFB cipher.
// this test validates that the behavior is taken into consideration.
var input = "896072ab28e5fdfc".HexToByteArray();
var key = "3000000000000000".HexToByteArray();
var iv = "3000000000000000".HexToByteArray();
using (RC2 rc2 = RC2Factory.Create())
{
rc2.Mode = cipherMode;
rc2.Key = key;
rc2.IV = iv;
rc2.Padding = PaddingMode.None;
if (feedbackSize > 0)
{
rc2.FeedbackSize = feedbackSize;
}
using (ICryptoTransform transform = rc2.CreateDecryptor())
{
byte[] output1 = transform.TransformFinalBlock(input, 0, input.Length);
byte[] output2 = transform.TransformFinalBlock(input, 0, input.Length);
Assert.Equal(output1, output2);
}
}
}
/// <summary>
/// 解密方法
/// </summary>
/// <param name="Source">待解密的串</param>
/// <returns>经过解密的串</returns>
public string Decrypt(string Source)
{
try
{
byte[] bytIn = Convert.FromBase64String(Source);
MemoryStream ms = new MemoryStream(bytIn, 0, bytIn.Length);
rc.Key = GetLegalKey();
rc.IV = GetLegalIV();
ICryptoTransform encrypto = rc.CreateDecryptor();
CryptoStream cs = new CryptoStream(ms, encrypto, CryptoStreamMode.Read);
StreamReader sr = new StreamReader(cs);
return(sr.ReadToEnd());
}
catch (Exception ex)
{
throw new Exception("在文件解密的时候出现错误!错误提示: " + ex.Message);
}
}
private void Decrypt_Click(object sender, RoutedEventArgs e)
{
switch (algorithmNumber)
{
case 0: { Decryption(aes.CreateDecryptor(aes.Key, aes.IV)); break; }
case 1: { Decryption(des.CreateDecryptor(des.Key, des.IV)); break; }
case 2: { Decryption(rc2.CreateDecryptor(rc2.Key, rc2.IV)); break; }
}
}
public static String DecryptTextFromFile(String FileName, byte[] Key, byte[] IV)
{
FileStream fStream = File.Open(FileName, FileMode.OpenOrCreate);
RC2 RC2alg = RC2.Create();
CryptoStream cStream = new CryptoStream(fStream, RC2alg.CreateDecryptor(Key, IV), CryptoStreamMode.Read);
StreamReader sReader = new StreamReader(cStream);
string val = sReader.ReadToEnd();
sReader.Close();
cStream.Close();
fStream.Close();
return(val);
}
public byte[] Decrypt(byte[] Data)
{
byte[] Key = Encoding.UTF8.GetBytes(RC2Key);
byte[] IV = Encoding.UTF8.GetBytes(RC2IV);
MemoryStream mStream = new MemoryStream(Data);
RC2 RC2alg = RC2.Create();
CryptoStream cStream = new CryptoStream(mStream, RC2alg.CreateDecryptor(Key, IV), CryptoStreamMode.Read);
byte[] ret = new byte[Data.Length];
int decryptedByteCount = cStream.Read(ret, 0, ret.Length);
cStream.Close();
mStream.Close();
return(ret);
}
public CodySecurityHelper2(string key = CodySecurityHelper2.DefaultKey, string iv = CodySecurityHelper2.DefaultIV)
{
this.Key = key;
this.IV = iv;
RC2 rc = RC2.Create();
key = key.PadLeft(16, ' ');
key = key.Substring(key.Length - 16, 16);
iv = iv.PadLeft(8, ' ');
iv = iv.Substring(iv.Length - 8, 8);
this.Encryptor = rc.CreateEncryptor(Encoding.Default.GetBytes(key), Encoding.Default.GetBytes(iv));
this.Decryptor = rc.CreateDecryptor(Encoding.Default.GetBytes(key), Encoding.Default.GetBytes(iv));
}
public static byte[] RC2Decrypt(byte[] cipherData, string Password)
{
PasswordDeriveBytes pdb = new PasswordDeriveBytes(Password, MySalt);
MemoryStream ms = new MemoryStream();
RC2 alg = RC2.Create();
alg.Key = pdb.GetBytes(8);
alg.IV = pdb.GetBytes(8);
CryptoStream cs = new CryptoStream(ms, alg.CreateDecryptor(), CryptoStreamMode.Write);
cs.Write(cipherData, 0, cipherData.Length);
cs.Close();
byte[] decryptedData = ms.ToArray();
return(decryptedData);
}
public static void TransformWithTooShortOutputBuffer(bool encrypt, bool blockAlignedOutput)
{
using (RC2 alg = RC2Factory.Create())
using (ICryptoTransform xform = encrypt ? alg.CreateEncryptor() : alg.CreateDecryptor())
{
// 1 block, plus maybe three bytes
int outputPadding = blockAlignedOutput ? 0 : 3;
byte[] output = new byte[alg.BlockSize / 8 + outputPadding];
// 3 blocks of 0x00
byte[] input = new byte[3 * (alg.BlockSize / 8)];
Assert.Throws <ArgumentOutOfRangeException>(
() => xform.TransformBlock(input, 0, input.Length, output, 0));
Assert.Equal(new byte[output.Length], output);
}
}
public static string DecryptTextFromFile(String FileName, byte[] Key, byte[] IV)
{
try
{
// Create or open the specified file.
FileStream fStream = File.Open(FileName, FileMode.OpenOrCreate);
// Create a new RC2 object.
RC2 RC2alg = RC2.Create();
// Create a CryptoStream using the FileStream
// and the passed key and initialization vector (IV).
CryptoStream cStream = new CryptoStream(fStream,
RC2alg.CreateDecryptor(Key, IV),
CryptoStreamMode.Read);
// Create a StreamReader using the CryptoStream.
StreamReader sReader = new StreamReader(cStream);
// Read the data from the stream
// to decrypt it.
string val = sReader.ReadLine();
// Close the streams and
// close the file.
sReader.Close();
cStream.Close();
fStream.Close();
// Return the string.
return(val);
}
catch (CryptographicException e)
{
Console.WriteLine("A Cryptographic error occurred: {0}", e.Message);
return(null);
}
catch (UnauthorizedAccessException e)
{
Console.WriteLine("A file error occurred: {0}", e.Message);
return(null);
}
}
private void RC2Decode_Click(object sender, EventArgs e)// декодирование с помощью библиотеки RC2
{
string KeyText = KeyTextBox.Text;
string CodeText = CodeTextBox.Text;
RC2 RC2alg = RC2.Create();
byte[] KeyByte = new UTF8Encoding().GetBytes(KeyText);
byte[] toDecrypt = Convert.FromBase64String(CodeText);
byte[] IV = new byte[] { 1, 2, 3, 4, 5, 6, 7, 8 };
MemoryStream DecodeStream = new MemoryStream();
CryptoStream DecodeRC2 = new CryptoStream(DecodeStream, RC2alg.CreateDecryptor(KeyByte, IV), CryptoStreamMode.Write);//поток, декодирующий информацию с заданным ключем и вектором
DecodeRC2.Write(toDecrypt, 0, toDecrypt.Length);
DecodeRC2.FlushFinalBlock();
byte[] ret = DecodeStream.ToArray();
string DecryptMes = new UTF8Encoding().GetString(ret);
DecodeTextBox.Text = DecryptMes;
DecodeRC2.Close();
DecodeStream.Close();
}
private string RC2Decrypt(string cipherText, string key)
{
string EncryptionKey = key.Substring(0, 8);
byte[] cipherBytes = Convert.FromBase64String(cipherText);
using (RC2 encryptor = RC2.Create())
{
encryptor.Key = ASCIIEncoding.ASCII.GetBytes(EncryptionKey);
encryptor.IV = ASCIIEncoding.ASCII.GetBytes(EncryptionKey);
using (MemoryStream ms = new MemoryStream())
{
using (CryptoStream cs = new CryptoStream(ms, encryptor.CreateDecryptor(), CryptoStreamMode.Write))
{
cs.Write(cipherBytes, 0, cipherBytes.Length);
cs.Close();
}
cipherText = ASCIIEncoding.ASCII.GetString(ms.ToArray());
}
}
return(cipherText);
}
public static void RC2ReuseEncryptorDecryptor()
{
using (RC2 alg = RC2Factory.Create())
{
alg.Key = s_randomKey_64.HexToByteArray();
alg.IV = s_randomIv_64.HexToByteArray();
alg.Padding = PaddingMode.PKCS7;
alg.Mode = CipherMode.CBC;
using (ICryptoTransform encryptor = alg.CreateEncryptor())
using (ICryptoTransform decryptor = alg.CreateDecryptor())
{
for (int i = 0; i < 2; i++)
{
byte[] plainText1 = s_multiBlockString.HexToByteArray();
byte[] cipher1 = encryptor.Transform(plainText1);
byte[] expectedCipher1 = (
"85B5D998F35ECD98DB886798170F64BA2DBA4FE902791CDE900EEB0B35728FEE35FB6CADC41DF67FBB691B45D92B876A" +
"13FD18229E5ACB797D21D7B257520910360E00FEECDE3433FDC6F15233AE6B5CAC01289AC8B57A9A6B5DA734C2E7E733").HexToByteArray();
Assert.Equal <byte>(expectedCipher1, cipher1);
byte[] decrypted1 = decryptor.Transform(cipher1);
byte[] expectedDecrypted1 = s_multiBlockString.HexToByteArray();
Assert.Equal <byte>(expectedDecrypted1, decrypted1);
byte[] plainText2 = s_multiBlockString_8.HexToByteArray();
byte[] cipher2 = encryptor.Transform(plainText2);
byte[] expectedCipher2 = (
"85B5D998F35ECD98DB886798170F64BA2DBA4FE902791CDE900EEB0B35728FEE35FB6CADC41DF67F6056044F15B5C7ED" +
"4FAB086053D7DC458C206145AE9655F1590C590FBDE76365FA488CADBCDA67B325A35E7CCBC1B9A15E5EBE2879C7AEC2").HexToByteArray();
Assert.Equal <byte>(expectedCipher2, cipher2);
byte[] decrypted2 = decryptor.Transform(cipher2);
byte[] expectedDecrypted2 = s_multiBlockString_8.HexToByteArray();
Assert.Equal <byte>(expectedDecrypted2, decrypted2);
}
}
}
}
private void decode_RC2_CBF_Click(object sender, EventArgs e)
{
DateTime then = DateTime.Now;
try
{
MemoryStream msDecrypt = new MemoryStream(cipherbytes);
RC2 alg = RC2.Create();
CryptoStream csDecrypt = new CryptoStream(msDecrypt,
alg.CreateDecryptor(Key, IV),
CryptoStreamMode.Read);
byte[] fromEncrypt = new byte[cipherbytes.Length];
csDecrypt.Read(fromEncrypt, 0, fromEncrypt.Length);
input8.Text = new ASCIIEncoding().GetString(fromEncrypt);
delta4.Text = (DateTime.Now - then).TotalSeconds.ToString() + "сек";
}
catch (CryptographicException ex)
{
Console.WriteLine("A Cryptographic error occurred: {0}", ex.Message);
return;
}
}
public byte[] Decrypt(byte[] Data)
{
byte[] Key = System.Text.Encoding.UTF8.GetBytes(RC2Key);
byte[] IV = System.Text.Encoding.UTF8.GetBytes(RC2IV);
MemoryStream mStream = new MemoryStream(Data);
RC2 RC2alg = RC2.Create();
CryptoStream cStream = new CryptoStream(mStream, RC2alg.CreateDecryptor(Key, IV), CryptoStreamMode.Read);
/*StreamReader sReader = new StreamReader(cStream);
*
* string val = sReader.ReadLine();
* byte[] ret = System.Text.Encoding.UTF8.GetBytes(val);*/
byte[] ret = new byte[Data.Length];
int decryptedByteCount = cStream.Read(
ret,
0,
ret.Length);
//sReader.Close();
cStream.Close();
mStream.Close();
return(ret);
}
public static string Decrypt(CryptoType cryptoMethod, string txt, string cryptoKey, string cryptoIV)
{
string retValue = String.Empty;
try
{
byte[] key = Encoding.UTF8.GetBytes(cryptoKey);
byte[] iv = Encoding.UTF8.GetBytes(cryptoIV);
byte[] array = Convert.FromBase64String(txt);
ICryptoTransform cTransform = null;
switch (cryptoMethod)
{
case CryptoType.aes:
using (Aes aes = Aes.Create())
{
if ((checkSize(aes.Key.Length, key.Length).Equals(true)) & (checkSize(aes.IV.Length, iv.Length).Equals(true)))
{
cTransform = aes.CreateDecryptor(key, iv);
}
}
break;
case CryptoType.des:
using (DESCryptoServiceProvider des = new DESCryptoServiceProvider())
{
if ((checkSize(des.Key.Length, key.Length).Equals(true)) & (checkSize(des.IV.Length, iv.Length).Equals(true)))
{
cTransform = des.CreateDecryptor(key, iv);
}
}
break;
case CryptoType.rc2:
using (RC2 rc2 = RC2.Create())
{
if ((checkSize(rc2.Key.Length, key.Length).Equals(true)) & (checkSize(rc2.IV.Length, iv.Length).Equals(true)))
{
cTransform = rc2.CreateDecryptor(key, iv);
}
}
break;
case CryptoType.rijndael:
using (Rijndael rij = Rijndael.Create())
{
if ((checkSize(rij.Key.Length, key.Length).Equals(true)) & (checkSize(rij.IV.Length, iv.Length).Equals(true)))
{
cTransform = rij.CreateDecryptor(key, iv);
}
}
break;
case CryptoType.tripledes:
using (TripleDESCryptoServiceProvider trides = new TripleDESCryptoServiceProvider())
{
if ((checkSize(trides.Key.Length, key.Length).Equals(true)) & (checkSize(trides.IV.Length, iv.Length).Equals(true)))
{
cTransform = trides.CreateDecryptor(key, iv);
}
}
break;
}
if (cTransform != null)
{
using (MemoryStream ms = new MemoryStream(array))
{
using (CryptoStream cs = new CryptoStream(ms, cTransform, CryptoStreamMode.Read))
{
using (StreamReader sr = new StreamReader(cs))
{
retValue = sr.ReadToEnd();
}
}
}
cTransform.Dispose();
}
else
{
throw new CryptographicException();
}
}
catch (CryptographicException cex)
{
throw new ApplicationException("Cryptographic Decryption Exception", cex);
}
catch (Exception ex)
{
throw new ApplicationException("Decrypt Exception", ex);
}
return(retValue);
}
public static ICryptoTransform CreateDecryptor(RC2 provider, string key, int keySize)
{
var kv = CreateKeyVector(key, keySize);
return(provider.CreateDecryptor(kv.First, kv.Second));
}
