33.NET对加密和解密的支持

  散列运算

mscorlib.dll下的System.Security.Cryptography下:
抽象类HashAlgorithm
    抽象类MD5
        MD5CryptoServiceProvider
    SHA1
        SHA1CryptoServiceProvider密封类:调用Windows Crypto API
        SHA1Managed普通类:用托管代码写的
    SHA256
        SHA256CryptoServiceProvider
        SHA256Managed
    SHA384
    SHA512

 

□ 对字节数组或流散列运算

    class Program 
    { 
        static void Main(string[] args) 
        { 
            string str = "Hello World"; 
            HashAlgorithm hashAlgorithm = HashAlgorithm.Create(HashAlgorithmType.SHA1); 
            byte[] data = Encoding.Default.GetBytes(str); 
            byte[] digest = hashAlgorithm.ComputeHash(data); 
            foreach (byte b in digest) 
            { 
                Console.Write("{0:X}",b); 
            } 
            Console.ReadKey(); 
        } 
    }
 
    public class HashAlgorithmType 
    { 
        public const string SHA1 = "SHA1"; 
        public const string SHA256 = "SHA256"; 
        public const string SHA384 = "SHA384"; 
        public const string SHA512 = "SHA512"; 
        public const string MD5 = "MD5"; 
    }

 

□ 密匙散列运算       

            string key = "secret key"; 
            byte[] data = Encoding.Default.GetBytes(key); 
            KeyedHashAlgorithm kha = new HMACSHA1(); 
            byte[] digest = kha.ComputeHash(data); 
            foreach (byte b in digest) 
            { 
                Console.Write("{0:x}",b); 
            }

 

  对称加密和解密

SymmetricAlgorithm
    DES
        DESCryptoServiceProvider
    TripleDES
        TripleDESCryptoServiceProvider
    Rijndael
        RijindaelManaged
    RC2  
        RC2CryptoServiceProvider

 

IV:Initialization vector初始化向量:
-为了解决加密字符串加密后仍然有重复部分,引入IV,加密字符串即使有重复,也会被打乱。
-IV值可以随意指定,但长度固定,通常为64位byte类型
-密匙长度也是固定的,通常为128位或196位byte类型

 

使用Encoding类将字符串转换为byte[]:
-如果使用UTF8,会变长编码

 

加密解密方法:
-加密方法:CreateEncryptor(),返回ICryptoTransform接口类型
-解密方法:CreateDecryptor(),返回ICrtyptoTransform接口类型

 

明文流和加密流的转换:

public CryptoStream(Stream stream, ICryptoTransform transform, CryptoStreamMode mode)
 
    class Program 
    { 
        static void Main(string[] args) 
        { 
            #region 对称加密和解密
 
            string key = "secret key"; 
            string str = "Hello World";
 
            //加密 
            string encryptedText = SymmetricCryptoHelper.Encrypt(str, key); 
            Console.WriteLine(encryptedText);
 
            //解密 
            string clearText = SymmetricCryptoHelper.Decrypt(encryptedText, key); 
            Console.WriteLine(clearText);
 
            Console.ReadKey();
 
            #endregion 
        } 
    }
 
    //对称加密帮助类 
    public class SymmetricCryptoHelper 
    { 
        private ICryptoTransform encryptor;  //加密器对象 
        private ICryptoTransform decryptor; //解密器对象 
        private const int BufferSize = 1024;
 
        public SymmetricCryptoHelper(string algorithmName, byte[] key) 
        { 
            SymmetricAlgorithm provider = SymmetricAlgorithm.Create(algorithmName); 
            provider.Key = key; 
            provider.IV = new byte[] { 0x12, 0x34, 0x56, 0x78, 0x90, 0xAB, 0xCD, 0xEF };
 
            encryptor = provider.CreateEncryptor(); 
            decryptor = provider.CreateDecryptor(); 
        }
 
        public SymmetricCryptoHelper(byte[] key) : this("TripleDES", key){}
 
        //加密算法 
        public string Encrypt(string clearText) 
        { 
            //创建明文流 
            byte[] clearBuffer = Encoding.UTF8.GetBytes(clearText); 
            //byte[] clearBuffer = Encoding.Default.GetBytes(clearText); 
            MemoryStream clearStream = new MemoryStream(clearBuffer);
 
            //创建空的密文流 
            MemoryStream encryptedStream = new MemoryStream();
 
            //明文流和密文流转换流,准备写到密文流中 
            CryptoStream cryptoStream = new CryptoStream(encryptedStream, encryptor, CryptoStreamMode.Write); 
           
            int bytesRead = 0; 
            byte[] buffer = new byte[BufferSize]; 
            do 
            { 
                //读取明文流到buffer中 
                bytesRead = clearStream.Read(buffer, 0, BufferSize); 
                //通过CryptoStream将buffer中的明文流字节数组写到明文流中 
                cryptoStream.Write(buffer, 0, bytesRead); 
            } while (bytesRead > 0);
 
            cryptoStream.FlushFinalBlock();
 
            //获取加密后的字节数组 
            buffer = encryptedStream.ToArray();
 
            //将加密后的字节数组转换成字符串 
            string encryptedText = Convert.ToBase64String(buffer); 
            return encryptedText; 
        }
 
        //解密算法 
        public string Decrypt(string encryptedText) 
        { 
            //把加密字符串转换为加密字节数组 
            byte[] encryptedBuffer = Convert.FromBase64String(encryptedText); 
            //创建密文流 
            Stream encryptedStream = new MemoryStream(encryptedBuffer);
 
            //创建空的明文流 
            MemoryStream clearStream = new MemoryStream();
 
            //创建明文流和密文流的转化流,读取密文流 
            CryptoStream cryptoStream = new CryptoStream(encryptedStream, decryptor, CryptoStreamMode.Read);
 
            int bytesRead = 0; 
            byte[] buffer = new byte[BufferSize];
 
            do 
            { 
                //通过CryptoStream读取密文流到Buffer 
                bytesRead = cryptoStream.Read(buffer, 0, BufferSize); 
                //把Buffer中的密文流写到明文流中 
                clearStream.Write(buffer, 0, bytesRead); 
            } while (bytesRead > 0);
 
            //将明文流转换成字节数组 
            buffer = clearStream.GetBuffer();
 
            string clearText = Encoding.UTF8.GetString(buffer, 0, (int)clearStream.Length); 
            //string clearText = Encoding.Default.GetString(buffer, 0, (int)clearStream.Length); 
            return clearText; 
        }
 
        //密匙加密 
        public static string Encrypt(string clearText, string key) 
        { 
            byte[] keyData = new byte[16]; //TripleDES密匙固定长度为16个字节
 
            //把密匙字符串转换成字节数组 
            byte[] sourceData = Encoding.Default.GetBytes(key); 
            int copyBytes = 16; 
            if (sourceData.Length < 16) 
            { 
                copyBytes = sourceData.Length; 
            }
 
            //把密匙数组复制到keyData字节数组中 
            Array.Copy(sourceData,keyData,copyBytes);
 
            SymmetricCryptoHelper helper = new SymmetricCryptoHelper(keyData); 
            return helper.Encrypt(clearText); 
        }
 
        //密匙解密 
        public static string Decrypt(string encryptedText, string key) 
        { 
            byte[] keyData = new byte[16]; 
            byte[] sourceData = Encoding.Default.GetBytes(key); 
            int copyBytes = 16; 
            if (sourceData.Length < 16) 
            { 
                copyBytes = sourceData.Length; 
            } 
            Array.Copy(sourceData,keyData,copyBytes);
 
            SymmetricCryptoHelper helper = new SymmetricCryptoHelper(keyData); 
            return helper.Decrypt(encryptedText); 
        } 
    }
 

 

  非对称加密

AsymmetricAlgorithm
    RSA
        RSACryptoServiceProvider
    DSA
        DSACryptoServiceProvider:只能进行认证模式,即数字签名

 

对称加密中的密匙:
密匙为由开发者设定的字符串

 

非对称加密中的密匙:
● 通常是自动生成,不同的算法有不同的密匙格式   
● 在创建RSACryptoServiceProvider实例时,会自动创建一个公/私密匙对。在实例上调用ToXmlString()方法获得。

            RSACryptoServiceProvider provider = new RSACryptoServiceProvider();
            string publicPrivate = provider.ToXmlString(true);//获得公/私匙对
            //string publicOnly = provider.ToXmlString(false); //只获得公匙
            Console.Write(publicPrivate);
            Console.ReadKey();

 

□ 非对称加密帮助类

    //非对称加密帮助类 
    public class RSACryptoHelper 
    { 
        //加密 
        public static string Encrypt(string publicKeyXml, string plainText) 
        { 
            RSACryptoServiceProvider provider = new RSACryptoServiceProvider(); 
            provider.FromXmlString(publicKeyXml); //使用公匙初始化对象 
            byte[] plainData = Encoding.Default.GetBytes(plainText); 
            byte[] encryptedData = provider.Encrypt(plainData, true); 
            return Convert.ToBase64String(encryptedData); 
        }
 
        //解密 
        public static string Decrypt(string privateKeyXml, string encryptedText) 
        { 
            RSACryptoServiceProvider provider = new RSACryptoServiceProvider(); 
            provider.FromXmlString(privateKeyXml); 
            byte[] encryptedData = Convert.FromBase64String(encryptedText); 
            byte[] plainData = provider.Decrypt(encryptedData, true); 
            string plainText = Encoding.Default.GetString(plainData); 
            return plainText; 
        } 
    }

 

  数字签名

RSACryptoServiceProvider或DSACryptoServiceProvider
SignData()对摘要进行签名,并返回签名后的摘要。
VerifyData()得出本地摘要,并解密传递进来的原始摘要,对比返回bool类型结果。

 

□ 数字签名帮助类

    public class RSACryptoHelper 
    { 
        public static string SignData(string plainText, string privateKeyXml) 
        { 
            RSACryptoServiceProvider provider = new RSACryptoServiceProvider(); 
            provider.FromXmlString(privateKeyXml);
 
            byte[] plainData = Encoding.Default.GetBytes(plainText); 
            //设置获取摘要的算法 
            HashAlgorithm sha1 = HashAlgorithm.Create("SHA1"); 
            //获取签名过的摘要,是使用私匙加密过的摘要 
            byte[] signedDigest = provider.SignData(plainData, sha1); 
            return Convert.ToBase64String(signedDigest); 
        }
 
        public static bool VerifyData(string plainText, string signature, string publicKeyXml) 
        { 
            RSACryptoServiceProvider provider = new RSACryptoServiceProvider(); 
            provider.FromXmlString(publicKeyXml);
 
            byte[] plainData = Encoding.Default.GetBytes(plainText); 
            byte[] signedDigest = Convert.FromBase64String(signature);
 
            HashAlgorithm sha1 = HashAlgorithm.Create("SHA1"); 
            bool isDataIntact = provider.VerifyData(plainData, sha1, signedDigest); 
            return isDataIntact; 
        }
 
        //使用SingnHash 
        public static string SignData2(string plainText, string privateKeyXml) 
        { 
            RSACryptoServiceProvider provider = new RSACryptoServiceProvider(); 
            provider.FromXmlString(privateKeyXml); 
            byte[] plainData = Encoding.Default.GetBytes(plainText);
 
            //设置获取摘要的算法 
            HashAlgorithm sha1 = HashAlgorithm.Create("SHA1"); 
            //获得原始摘要 
            byte[] digestData = sha1.ComputeHash(plainData); 
            //对元素摘要进行签名 
            byte[] signedDigest = provider.SignHash(digestData, "SHA1"); 
            return Convert.ToBase64String(signedDigest); 
        }
 
        //使用VerifyHash 
        public static bool VerifyData2(string plainText, string signedDigest, string publicKeyXml) 
        { 
            RSACryptoServiceProvider provider = new RSACryptoServiceProvider(); 
            provider.FromXmlString(publicKeyXml);
 
            byte[] plainData = Encoding.Default.GetBytes("SHA1"); 
            byte[] signedDigestData = Convert.FromBase64String(signedDigest);
 
            //获得本地摘要 
            HashAlgorithm sha1 = HashAlgorithm.Create("SHA1"); 
            byte[] digest = sha1.ComputeHash(plainData);
 
            //解密签名 
            bool isDataIntact = provider.VerifyHash(digest, "SHA1", signedDigestData); 
            return isDataIntact; 
        } 
    }
 

 

参考资料:
《.NET之美》--张子阳,感谢写了这么好的书!   

33.NET对加密和解密的支持,古老的榕树,5-wow.com

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