monospace; direction: ltr; border-top-style: none; color: black; border-right-style: none; font-size: 8pt; overflow: visible; padding-top: 0px" id="codeSnippet">using System;
using System.IO;
using System.Security.Cryptography;
namespace ConsoleApp_SymmetricalEncryption
{
class Program
{
static void Main(string[] args)
{
SymmetricalEncryption ss = new SymmetricalEncryption();
ss.EncryptFile(@"C:\error.txt", @"C:\error_EncryptFile.txt", ss.Key);
Console.WriteLine("加密成功!");
Console.ReadKey();
ss.DecryptFile(@"C:\error_EncryptFile.txt", @"C:\error_DecryptFile.txt", ss.Key);
Console.WriteLine("解密成功!");
Console.ReadKey();
}
}
/// <summary>
/// 对文件使用对称加密算法
/// </summary>
public class SymmetricalEncryption
{
/* 对称加密:
* 需要发送者和接收者协定一个密钥K,K可以是一个密钥对,但必须是加密密钥和解密密钥之间能够互相推算出来的。
* 常用的对称加密算法中,加密解密共享一个密钥。
* 本例中使用的是同一个密钥;
*
* 非对称加密:
* 有一个密钥对,分别为 公钥、私钥(公钥用来加密,私钥用来解密)
* 私钥永远不需要传递给对方;
*
* 优缺点比较:
* 非对称加密算法复杂,导致加解密速度慢,只适合与数据量小的场合。
* 对称加密解密效率高,系统开销小,适合金星大数据量的加解密。(大文件一般适合使用对称加密)
*/
/// <summary>
/// 随机产生的密钥(也可以自己指定)
/// 【注意:对称加密算法 加密解密用的Key值是相同的(非对称加密才分:公钥和私钥)】
/// </summary>
public string Key = Guid.NewGuid().ToString().Replace("-", "").ToUpper() + Guid.NewGuid().ToString().Replace("-", "").ToUpper();
/// <summary>
/// 缓冲区大小
/// </summary>
private int bufferSize = 128 * 1024;
/// <summary>
/// 密钥salt
/// </summary>
private byte[] salt = { 134, 216, 7, 36, 88, 164, 91, 227, 174, 76, 191, 197, 192, 154, 200, 248 };
//salt用来防止穷举暴力破解(salt是在密钥导出之前在密码末尾引入的随机字节,它使得这类攻击变得非常困难)
/// <summary>
/// 初始化向量
/// </summary>
private byte[] iv = { 134, 216, 7, 36, 88, 164, 91, 227, 174, 76, 191, 197, 192, 154, 200, 248 };
//初始化向量iv起到的也是增强破解难度的作用
/// <summary>
/// 初始化 并返回对称加密算法
/// </summary>
/// <param name="argKey"></param>
/// <param name="argSalt"></param>
/// <returns></returns>
private SymmetricAlgorithm CreateRijindael(string argKey, byte[] argSalt)
{
PasswordDeriveBytes pdb = new PasswordDeriveBytes(argKey, argSalt, "SHA256", 1000);
SymmetricAlgorithm sma = Rijndael.Create();
sma.KeySize = 256;
sma.Key = pdb.GetBytes(32);
sma.Padding = PaddingMode.PKCS7;
return sma;
}
/// <summary>
/// 加密文件
/// </summary>
/// <param name="argInFile">输入文件</param>
/// <param name="argOutFile">输出加密后的文件</param>
/// <param name="argKey">加密用的Key</param>
public void EncryptFile(string argInFile, string argOutFile, string argKey)
{
using (FileStream inFileStream = File.OpenRead(argInFile),
outFileStream = File.Open(argOutFile, FileMode.OpenOrCreate))
using (SymmetricAlgorithm algorithm = CreateRijindael(argKey, salt))
{
algorithm.IV = iv;
using (CryptoStream cryptoStream = new CryptoStream(outFileStream, algorithm.CreateEncryptor(),
CryptoStreamMode.Write))
{
byte[] bytes = new byte[bufferSize];
int readSize = -1;
while ((readSize = inFileStream.Read(bytes, 0, bytes.Length)) != 0)
{
cryptoStream.Write(bytes, 0, readSize);
}
cryptoStream.Flush();
}
}
}
/// <summary>
/// 解密文件
/// </summary>
/// <param name="argInFile">输入待解密的文件</param>
/// <param name="argOutFile">输出解密后的文件</param>
/// <param name="argKey">加密用的Key</param>
public void DecryptFile(string argInFile, string argOutFile, string argKey)
{
try
{
using (FileStream inFileStream = File.OpenRead(argInFile), outFileStream = File.OpenWrite(argOutFile))
using (SymmetricAlgorithm algorithm = CreateRijindael(argKey, salt))
{
algorithm.IV = iv;
using (CryptoStream cryptoStream = new CryptoStream(inFileStream, algorithm.CreateDecryptor(),
CryptoStreamMode.Read))
{
byte[] bytes = new byte[bufferSize];
int readSize = -1;
int numReads = (int)(inFileStream.Length / bufferSize);
int slack = (int)(inFileStream.Length % bufferSize);
for (int i = 0; i < numReads; ++i)
{
readSize = cryptoStream.Read(bytes, 0, bytes.Length);
outFileStream.Write(bytes, 0, readSize);
}
if (slack > 0)
{
readSize = cryptoStream.Read(bytes, 0, (int)slack);
outFileStream.Write(bytes, 0, readSize);
}
outFileStream.Flush();
}
}
}
catch (Exception ex)
{
throw new Exception("解密失败:" + ex.Message);//可能是密钥输入的不正确,或者文件被修改过
}
}
}
}