C# 加密方法

1.DES加解密

　　DES一共就有4个参数参与运作：明文、密文、密钥、向量。其中这4者的关系可以理解为：
　　密文=明文+密钥+向量；
　　明文=密文-密钥-向量；
　　为什么要向量这个参数呢？因为如果有一篇文章，有几个词重复，那么这个词加上密钥形成的密文，仍然会重复，这给破解者有机可乘，破解者可以根据重复的内容，猜出是什么词，然而一旦猜对这个词，那么，他就能算出密钥，整篇文章就被破解了！加上向量这个参数以后，每块文字段都会依次加上一段值，这样，即使相同的文字，加密出来的密文，也是不一样的，算法的安全性大大提高！
　　下面给出DES加、解密的.Net封装版：

using System;using System.Text;using System.Security.Cryptography;using System.IO;namespace 开发测试{    class Program    {        static void Main(string[] args)        {            string user = Encrypt("admin");            string pass = Encrypt("999999");            Console.WriteLine(user);            Console.WriteLine(pass);            string GetUser = Decrypt(user);            string GetPass = Decrypt(pass);            Console.WriteLine(GetUser);            Console.WriteLine(GetPass);            Console.ReadLine();        }        /// <summary>        /// 获取密钥        /// </summary>        private static string Key        {            get { return @"P@+#wG%A"; }        }        /// <summary>        /// 获取向量        /// </summary>        private static string IV        {            get { return @"L*n67}G\Mk@k%:~Y"; }        }        /// <summary>        /// DES加密        /// </summary>        /// <param name="plainStr">明文字符串</param>        /// <returns>密文</returns>        public static string Encrypt(string plainStr)        {            byte[] bKey = Encoding.UTF8.GetBytes(Key);            byte[] bIV = Encoding.UTF8.GetBytes(IV);            byte[] byteArray = Encoding.UTF8.GetBytes(plainStr);            string encrypt = null;            DESCryptoServiceProvider des = new DESCryptoServiceProvider();            try            {                using (MemoryStream mStream = new MemoryStream())                {                    using (CryptoStream cStream = new CryptoStream(mStream, des.CreateEncryptor(bKey, bIV), CryptoStreamMode.Write))                    {                        cStream.Write(byteArray, 0, byteArray.Length);                        cStream.FlushFinalBlock();                        encrypt = Convert.ToBase64String(mStream.ToArray());                    }                }            }            catch { }            des.Clear();            return encrypt;        }        /// <summary>        /// DES解密        /// </summary>        /// <param name="encryptStr">密文字符串</param>        /// <returns>明文</returns>        public static string Decrypt(string encryptStr)        {            byte[] bKey = Encoding.UTF8.GetBytes(Key);            byte[] bIV = Encoding.UTF8.GetBytes(IV);            byte[] byteArray = Convert.FromBase64String(encryptStr);            string decrypt = null;            DESCryptoServiceProvider des = new DESCryptoServiceProvider();            try            {                using (MemoryStream mStream = new MemoryStream())                {                    using (CryptoStream cStream = new CryptoStream(mStream, des.CreateDecryptor(bKey, bIV), CryptoStreamMode.Write))                    {                        cStream.Write(byteArray, 0, byteArray.Length);                        cStream.FlushFinalBlock();                        decrypt = Encoding.UTF8.GetString(mStream.ToArray());                    }                }            }            catch { }            des.Clear();            return decrypt;        }    }}

2.AES加解密

　　AES是美国联邦政府采用的商业及政府数据加密标准，预计将在未来几十年里代替DES在各个领域中得到广泛应用。AES提供128位密钥，因此，128位AES的加密强度是56位DES加密强度的1021倍还多。假设可以制造一部可以在1秒内破解DES密码的机器，那么使用这台机器破解一个128位AES密码需要大约149亿万年的时间。
　　下面给出AES加解密的.Net封装版:

using System;using System.Text;using System.Security.Cryptography;using System.IO;namespace 开发测试{    class Program    {        static void Main(string[] args)        {            string user = Encrypt("admin");            string pass = Encrypt("999999");            Console.WriteLine(user);            Console.WriteLine(pass);            string GetUser = Decrypt(user);            string GetPass = Decrypt(pass);            Console.WriteLine(GetUser);            Console.WriteLine(GetPass);            Console.ReadLine();        }        /// <summary>        /// 获取密钥        /// </summary>        private static string Key        {            get { return @"qO[NB]6,YF}gefcaj{+oESb9d8>Z'e9M"; }        }        /// <summary>        /// 获取向量        /// </summary>        private static string IV        {            get { return @"L+\~f4.Ir)b$=pkf"; }        }        /// <summary>        /// AES加密        /// </summary>        /// <param name="plainStr">明文字符串</param>        /// <returns>密文</returns>        public static string Encrypt(string plainStr)        {            byte[] bKey = Encoding.UTF8.GetBytes(Key);            byte[] bIV = Encoding.UTF8.GetBytes(IV);            byte[] byteArray = Encoding.UTF8.GetBytes(plainStr);            string encrypt = null;            Rijndael aes = Rijndael.Create();            try            {                using (MemoryStream mStream = new MemoryStream())                {                    using (CryptoStream cStream = new CryptoStream(mStream, aes.CreateEncryptor(bKey, bIV), CryptoStreamMode.Write))                    {                        cStream.Write(byteArray, 0, byteArray.Length);                        cStream.FlushFinalBlock();                        encrypt = Convert.ToBase64String(mStream.ToArray());                    }                }            }            catch { }            aes.Clear();            return encrypt;        }        /// <summary>        /// AES解密        /// </summary>        /// <param name="encryptStr">密文字符串</param>        /// <returns>明文</returns>        public static string Decrypt(string encryptStr)        {            byte[] bKey = Encoding.UTF8.GetBytes(Key);            byte[] bIV = Encoding.UTF8.GetBytes(IV);            byte[] byteArray = Convert.FromBase64String(encryptStr);            string decrypt = null;            Rijndael aes = Rijndael.Create();            try            {                using (MemoryStream mStream = new MemoryStream())                {                    using (CryptoStream cStream = new CryptoStream(mStream, aes.CreateDecryptor(bKey, bIV), CryptoStreamMode.Write))                    {                        cStream.Write(byteArray, 0, byteArray.Length);                        cStream.FlushFinalBlock();                        decrypt = Encoding.UTF8.GetString(mStream.ToArray());                    }                }            }            catch { }            aes.Clear();            return decrypt;        }    }}

3.MD5与SHA128、256…散列

　　MD5和SHA1散列通常被用于密码中，很多人称其为散列算法，实际上它正确应该叫做散列算法。散列是不可逆的，也就是没有了”解密”这个说法。
　　下面给出MD5与SHA128散列的.Net的System.Web快速实现版：

using System;using System.Text;using System.IO;namespace 开发测试{    class Program    {        static void Main(string[] args)        {            string user = MD5("admin");            string pass = MD5("999999");            Console.WriteLine(user);            Console.WriteLine(pass);            string user2 = SHA1("admin");            string pass2 = SHA1("999999");            Console.WriteLine(user2);            Console.WriteLine(pass2);            Console.ReadLine();        }        //32位大写MD5散列        public static string MD5(string str)        {            return System.Web.Security.FormsAuthentication.HashPasswordForStoringInConfigFile(str, "MD5").ToUpper();        }        //大写SHA1散列        public static string SHA1(string str)        {            return System.Web.Security.FormsAuthentication.HashPasswordForStoringInConfigFile(str, "SHA1").ToUpper();        }    }}

　　全面版：

using System;using System.Text;using System.IO;using System.Security.Cryptography;namespace 开发测试{    class Program    {        static void Main(string[] args)        {            string user = MD5("admin");            string pass = MD5("999999");            Console.WriteLine(user);            Console.WriteLine(pass);            string user2 = SHA128("admin");            string pass2 = SHA128("999999");            Console.WriteLine(user2);            Console.WriteLine(pass2);            string user3 = SHA256("admin");            string pass3 = SHA256("999999");            Console.WriteLine(user3);            Console.WriteLine(pass3);            string user4 = SHA384("admin");            string pass4 = SHA384("999999");            Console.WriteLine(user4);            Console.WriteLine(pass4);            string user5 = SHA512("admin");            string pass5 = SHA512("999999");            Console.WriteLine(user5);            Console.WriteLine(pass5);            Console.ReadLine();        }        //16字节,128位        public static string MD5(string str)        {            byte[] buffer = Encoding.UTF8.GetBytes(str);            MD5CryptoServiceProvider MD5 = new MD5CryptoServiceProvider();            byte[] byteArr = MD5.ComputeHash(buffer);            return BitConverter.ToString(byteArr);        }        //20字节,160位        public static string SHA128(string str)        {            byte[] buffer = Encoding.UTF8.GetBytes(str);            SHA1CryptoServiceProvider SHA1 = new SHA1CryptoServiceProvider();            byte[] byteArr = SHA1.ComputeHash(buffer);            return BitConverter.ToString(byteArr);        }        //32字节,256位        public static string SHA256(string str)        {            byte[] buffer = Encoding.UTF8.GetBytes(str);            SHA256CryptoServiceProvider SHA256 = new SHA256CryptoServiceProvider();            byte[] byteArr = SHA256.ComputeHash(buffer);            return BitConverter.ToString(byteArr);        }        //48字节,384位        public static string SHA384(string str)        {            byte[] buffer = Encoding.UTF8.GetBytes(str);            SHA384CryptoServiceProvider SHA384 = new SHA384CryptoServiceProvider();            byte[] byteArr = SHA384.ComputeHash(buffer);            return BitConverter.ToString(byteArr);        }        //64字节,512位        public static string SHA512(string str)        {            byte[] buffer = Encoding.UTF8.GetBytes(str);            SHA512CryptoServiceProvider SHA512 = new SHA512CryptoServiceProvider();            byte[] byteArr = SHA512.ComputeHash(buffer);            return BitConverter.ToString(byteArr);        }    }}