[英]Specified initialization vector(IV) does not match the block size for this algorithm
[英]The specified initialization vector (IV) does not match the block size for this algorithm
我正在嘗試改編示例RinjaelManaged加密類(請參閱:使用C#加密和解密字符串 )來代替使用AesCryptoServiceProvider,以便它可以在設置為僅使用FIPS兼容算法的計算機上運行。
但是,這似乎不像換掉類名那樣簡單,因為我現在收到有關初始化向量長度的錯誤。 我意識到已經有幾個問題,但是在我的特定用例中嘗試使用其他問題的答案並沒有成功。
我需要更改什么以使IV長度匹配所需的?
namespace Encryption
{
#region Using Statements
using System;
using System.IO;
using System.Linq;
using System.Security.Cryptography;
using System.Text;
#endregion
public class EncryptionHelper
{
#region Private Fields
// This constant determines the number of iterations for the password bytes generation function.
private const int DerivationIterations = 1000;
// This constant is used to determine the keysize of the encryption algorithm in bits.
// We divide this by 8 within the code below to get the equivalent number of bytes.
private const int KeySize = 256;
private const int BlockSize = 128;
#endregion Private Fields
#region Public Methods
/// <summary>Decrypts the specified cipher text.</summary>
/// <param name="cipherText">The cipher text.</param>
/// <param name="passPhrase">The pass phrase.</param>
/// <returns></returns>
public static string Decrypt(string cipherText, string passPhrase)
{
// Get the complete stream of bytes that represent:
// [32 bytes of Salt] + [32 bytes of IV] + [n bytes of CipherText]
byte[] cipherTextBytesWithSaltAndIv = Convert.FromBase64String(cipherText);
// Get the saltbytes by extracting the first 32 bytes from the supplied cipherText bytes.
byte[] saltStringBytes = cipherTextBytesWithSaltAndIv.Take(KeySize / 8).ToArray();
// Get the IV bytes by extracting the next 32 bytes from the supplied cipherText bytes.
byte[] ivStringBytes = cipherTextBytesWithSaltAndIv.Skip(KeySize / 8).Take(KeySize / 8).ToArray();
// Get the actual cipher text bytes by removing the first 64 bytes from the cipherText string.
byte[] cipherTextBytes = cipherTextBytesWithSaltAndIv.Skip(KeySize / 8 * 2).Take(cipherTextBytesWithSaltAndIv.Length - KeySize / 8 * 2).ToArray();
using (var password = new Rfc2898DeriveBytes(passPhrase, saltStringBytes, DerivationIterations))
{
byte[] keyBytes = password.GetBytes(KeySize / 8);
using (var aes = new AesCryptoServiceProvider())
{
aes.BlockSize = BlockSize;
aes.Mode = CipherMode.CBC;
aes.Padding = PaddingMode.PKCS7;
using (ICryptoTransform decryptor = aes.CreateDecryptor(keyBytes, ivStringBytes))
using (var memoryStream = new MemoryStream(cipherTextBytes))
using (var cryptoStream = new CryptoStream(memoryStream, decryptor, CryptoStreamMode.Read))
{
var plainTextBytes = new byte[cipherTextBytes.Length];
int decryptedByteCount = cryptoStream.Read(plainTextBytes, 0, plainTextBytes.Length);
memoryStream.Close();
cryptoStream.Close();
return Encoding.UTF8.GetString(plainTextBytes, 0, decryptedByteCount);
}
}
}
}
/// <summary>Encrypts the specified plain text.</summary>
/// <param name="plainText">The plain text.</param>
/// <param name="passPhrase">The pass phrase.</param>
/// <returns></returns>
public static string Encrypt(string plainText, string passPhrase)
{
// Salt and IV is randomly generated each time, but is preprended to encrypted cipher text
// so that the same Salt and IV values can be used when decrypting.
byte[] saltStringBytes = Generate256BitsOfRandomEntropy();
byte[] ivStringBytes = Generate256BitsOfRandomEntropy();
byte[] plainTextBytes = Encoding.UTF8.GetBytes(plainText);
using (var password = new Rfc2898DeriveBytes(passPhrase, saltStringBytes, DerivationIterations))
{
byte[] keyBytes = password.GetBytes(KeySize / 8);
using (var symmetricKey = new AesCryptoServiceProvider())
{
symmetricKey.BlockSize = BlockSize;
symmetricKey.Mode = CipherMode.CBC;
symmetricKey.Padding = PaddingMode.PKCS7;
using (ICryptoTransform encryptor = symmetricKey.CreateEncryptor(keyBytes, ivStringBytes))
{
using (var memoryStream = new MemoryStream())
{
using (var cryptoStream = new CryptoStream(memoryStream, encryptor, CryptoStreamMode.Write))
{
cryptoStream.Write(plainTextBytes, 0, plainTextBytes.Length);
cryptoStream.FlushFinalBlock();
// Create the final bytes as a concatenation of the random salt bytes, the random iv bytes and the cipher bytes.
byte[] cipherTextBytes = saltStringBytes;
cipherTextBytes = cipherTextBytes.Concat(ivStringBytes).ToArray();
cipherTextBytes = cipherTextBytes.Concat(memoryStream.ToArray()).ToArray();
memoryStream.Close();
cryptoStream.Close();
return Convert.ToBase64String(cipherTextBytes);
}
}
}
}
}
}
#endregion Public Methods
#region Private Methods
/// <summary>Generate256s the bits of random entropy.</summary>
/// <returns></returns>
private static byte[] Generate256BitsOfRandomEntropy()
{
var randomBytes = new byte[32]; // 32 Bytes will give us 256 bits.
using (var rngCsp = new RNGCryptoServiceProvider())
{
// Fill the array with cryptographically secure random bytes.
rngCsp.GetBytes(randomBytes);
}
return randomBytes;
}
#endregion Private Methods
}
}
IV的長度應與塊大小相同。 即128位。 當前,您的代碼采用256位IV。 在整個代碼中進行適當調整,這應該可以解決問題。
好吧,我最終通過將IV長度與Salt長度清楚地分開來弄清楚了:
public class EncryptionHelper
{
#region Private Fields
// This constant determines the number of iterations for the password bytes generation function.
private const int DerivationIterations = 1000;
// This constant is used to determine the keysize of the encryption algorithm in bits.
// We divide this by 8 within the code below to get the equivalent number of bytes.
private const int saltBytes = 32; // bytes
private const int ivBytes = 16; // bytes
#endregion Private Fields
#region Public Methods
/// <summary>Decrypts the specified cipher text.</summary>
/// <param name="cipherText">The cipher text.</param>
/// <param name="passPhrase">The pass phrase.</param>
/// <returns></returns>
public static string Decrypt(string cipherText, string passPhrase)
{
// Get the complete stream of bytes that represent:
// [32 bytes of Salt] + [16 bytes of IV] + [n bytes of CipherText]
byte[] cipherTextBytesWithSaltAndIv = Convert.FromBase64String(cipherText);
// Get the saltbytes by extracting the first 32 bytes from the supplied cipherText bytes.
byte[] saltStringBytes = cipherTextBytesWithSaltAndIv.Take(saltBytes).ToArray();
// Get the IV bytes by extracting the next 32 bytes from the supplied cipherText bytes.
byte[] ivStringBytes = cipherTextBytesWithSaltAndIv.Skip(saltBytes).Take(ivBytes).ToArray();
// Get the actual cipher text bytes by removing the first 48 bytes from the cipherText string.
byte[] cipherTextBytes = cipherTextBytesWithSaltAndIv.Skip(saltBytes + ivBytes).Take(cipherTextBytesWithSaltAndIv.Length - (saltBytes + ivBytes)).ToArray();
using (var password = new Rfc2898DeriveBytes(passPhrase, saltStringBytes, DerivationIterations))
{
byte[] keyBytes = password.GetBytes(saltBytes);
using (var symmetricKey = new AesCryptoServiceProvider())
{
symmetricKey.BlockSize = 128;
symmetricKey.Mode = CipherMode.CBC;
symmetricKey.Padding = PaddingMode.PKCS7;
using (ICryptoTransform decryptor = symmetricKey.CreateDecryptor(keyBytes, ivStringBytes))
using (var memoryStream = new MemoryStream(cipherTextBytes))
using (var cryptoStream = new CryptoStream(memoryStream, decryptor, CryptoStreamMode.Read))
{
var plainTextBytes = new byte[cipherTextBytes.Length];
int decryptedByteCount = cryptoStream.Read(plainTextBytes, 0, plainTextBytes.Length);
memoryStream.Close();
cryptoStream.Close();
return Encoding.UTF8.GetString(plainTextBytes, 0, decryptedByteCount);
}
}
}
}
/// <summary>Encrypts the specified plain text.</summary>
/// <param name="plainText">The plain text.</param>
/// <param name="passPhrase">The pass phrase.</param>
/// <returns></returns>
public static string Encrypt(string plainText, string passPhrase)
{
// Salt and IV is randomly generated each time, but is preprended to encrypted cipher text
// so that the same Salt and IV values can be used when decrypting.
byte[] saltStringBytes = GenerateBitsOfRandomEntropy(32);
byte[] ivStringBytes = GenerateBitsOfRandomEntropy(16);
byte[] plainTextBytes = Encoding.UTF8.GetBytes(plainText);
using (var password = new Rfc2898DeriveBytes(passPhrase, saltStringBytes, DerivationIterations))
{
byte[] keyBytes = password.GetBytes(saltBytes);
using (var symmetricKey = new AesCryptoServiceProvider())
{
symmetricKey.BlockSize = 128;
symmetricKey.Mode = CipherMode.CBC;
symmetricKey.Padding = PaddingMode.PKCS7;
using (ICryptoTransform encryptor = symmetricKey.CreateEncryptor(keyBytes, ivStringBytes))
{
using (var memoryStream = new MemoryStream())
{
using (var cryptoStream = new CryptoStream(memoryStream, encryptor, CryptoStreamMode.Write))
{
cryptoStream.Write(plainTextBytes, 0, plainTextBytes.Length);
cryptoStream.FlushFinalBlock();
// Create the final bytes as a concatenation of the random salt bytes, the random iv bytes and the cipher bytes.
byte[] cipherTextBytes = saltStringBytes;
cipherTextBytes = cipherTextBytes.Concat(ivStringBytes).ToArray();
cipherTextBytes = cipherTextBytes.Concat(memoryStream.ToArray()).ToArray();
memoryStream.Close();
cryptoStream.Close();
return Convert.ToBase64String(cipherTextBytes);
}
}
}
}
}
}
#endregion Public Methods
#region Private Methods
/// <summary>Generate bits of random entropy.</summary>
/// <returns></returns>
private static byte[] GenerateBitsOfRandomEntropy(int num)
{
var randomBytes = new byte[num]; // 32 Bytes will give us 256 bits.
using (var rngCsp = new RNGCryptoServiceProvider())
{
// Fill the array with cryptographically secure random bytes.
rngCsp.GetBytes(randomBytes);
}
return randomBytes;
}
#endregion Private Methods
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