#region DES加密解密 /// <summary> /// DES加密 /// </summary> /// <param name="strSource">待加密字串</param> /// <param name="key">32位Key值</param> /// <returns>加密后的字符串</returns> public string DESEncrypt(string strSource) { return DESEncrypt(strSource, DESKey); } public string DESEncrypt(string strSource, byte[] key) { SymmetricAlgorithm sa = Rijndael.Create(); sa.Key = key; sa.Mode = CipherMode.ECB; sa.Padding = PaddingMode.Zeros; MemoryStream ms = new MemoryStream(); CryptoStream cs = new CryptoStream(ms, sa.CreateEncryptor(), CryptoStreamMode.Write); byte[] byt = Encoding.Unicode.GetBytes(strSource); cs.Write(byt, 0, byt.Length); cs.FlushFinalBlock(); cs.Close(); return Convert.ToBase64String(ms.ToArray()); } /// <summary> /// DES解密 /// </summary> /// <param name="strSource">待解密的字串</param> /// <param name="key">32位Key值</param> /// <returns>解密后的字符串</returns> public string DESDecrypt(string strSource) { return DESDecrypt(strSource, DESKey); } public string DESDecrypt(string strSource, byte[] key) { SymmetricAlgorithm sa = Rijndael.Create(); sa.Key = key; sa.Mode = CipherMode.ECB; sa.Padding = PaddingMode.Zeros; ICryptoTransform ct = sa.CreateDecryptor(); byte[] byt = Convert.FromBase64String(strSource); MemoryStream ms = new MemoryStream(byt); CryptoStream cs = new CryptoStream(ms, ct, CryptoStreamMode.Read); StreamReader sr = new StreamReader(cs, Encoding.Unicode); return sr.ReadToEnd(); } #endregion #region 一个用hash实现的加密解密方法 /// <summary> /// 加密 /// </summary> /// <param name="src"></param> /// <returns></returns> public static string EncryptStrByHash(string src) { if (src.Length == 0) { return ""; } byte[] HaKey = System.Text.Encoding.ASCII.GetBytes((src + "Test").ToCharArray()); byte[] HaData = new byte[20]; HMACSHA1 Hmac = new HMACSHA1(HaKey); CryptoStream cs = new CryptoStream(Stream.Null, Hmac, CryptoStreamMode.Write); try { cs.Write(HaData, 0, HaData.Length); } finally { cs.Close(); } string HaResult = System.Convert.ToBase64String(Hmac.Hash).Substring(0, 16); byte[] RiKey = System.Text.Encoding.ASCII.GetBytes(HaResult.ToCharArray()); byte[] RiDataBuf = System.Text.Encoding.ASCII.GetBytes(src.ToCharArray()); byte[] EncodedBytes = { }; MemoryStream ms = new MemoryStream(); RijndaelManaged rv = new RijndaelManaged(); cs = new CryptoStream(ms, rv.CreateEncryptor(RiKey, RiKey), CryptoStreamMode.Write); try { cs.Write(RiDataBuf, 0, RiDataBuf.Length); cs.FlushFinalBlock(); EncodedBytes = ms.ToArray(); } finally { ms.Close(); cs.Close(); } return HaResult + System.Convert.ToBase64String(EncodedBytes); } /// <summary> /// 解密 /// </summary> /// <param name="src"></param> /// <returns></returns> public static string DecrypStrByHash(string src) { if (src.Length < 40) return ""; byte[] SrcBytes = System.Convert.FromBase64String(src.Substring(16)); byte[] RiKey = System.Text.Encoding.ASCII.GetBytes(src.Substring(0, 16).ToCharArray()); byte[] InitialText = new byte[SrcBytes.Length]; RijndaelManaged rv = new RijndaelManaged(); MemoryStream ms = new MemoryStream(SrcBytes); CryptoStream cs = new CryptoStream(ms, rv.CreateDecryptor(RiKey, RiKey), CryptoStreamMode.Read); try { cs.Read(InitialText, 0, InitialText.Length); } finally { ms.Close(); cs.Close(); } System.Text.StringBuilder Result = new System.Text.StringBuilder(); for (int i = 0; i < InitialText.Length; ++i) if (InitialText[i] > 0) Result.Append((char)InitialText[i]); return Result.ToString(); } /// <summary> /// 对加密后的密文重新编码,如果密文长>16,则去掉前16个字符,如果长度小于16,返回空字符串 /// </summary> /// <param name="s"></param> /// <returns></returns> public string ReEncryptStrByHash(string s) { string e = Encrypt.EncryptStrByHash(s); return ((e.Length > 16) ? e.Substring(16) : ""); } #endregion #region Md5加密,生成16位或32位,生成的密文都是大写 public static string Md5To16(string str) { MD5CryptoServiceProvider md5 = new MD5CryptoServiceProvider(); string t2 = BitConverter.ToString(md5.ComputeHash(UTF8Encoding.Default.GetBytes(str)), 4, 8); t2 = t2.Replace("-", ""); return t2; } //// <summary> /// MD5 32位加密 /// </summary> /// <param name="str"></param> /// <returns></returns> public static string Md5To32(string str) { string pwd = ""; MD5 md5 = MD5.Create(); byte[] s = md5.ComputeHash(Encoding.UTF8.GetBytes(str)); for (int i = 0; i < s.Length; i++) { pwd = pwd + s[i].ToString("X"); } return pwd; } #endregion #region 3DES加密解密 public string Encrypt3DES(string str) { //密钥 string sKey = "wyw308"; // //矢量,可为空 string sIV = "scf521"; // //构造对称算法 SymmetricAlgorithm mCSP = new TripleDESCryptoServiceProvider(); ICryptoTransform ct; MemoryStream ms; CryptoStream cs; byte[] byt; mCSP.Key = Convert.FromBase64String(sKey); mCSP.IV = Convert.FromBase64String(sIV); mCSP.Mode = System.Security.Cryptography.CipherMode.ECB; mCSP.Padding = System.Security.Cryptography.PaddingMode.PKCS7; ct = mCSP.CreateEncryptor(mCSP.Key, mCSP.IV); byt = Encoding.UTF8.GetBytes(str); ms = new MemoryStream(); cs = new CryptoStream(ms, ct, CryptoStreamMode.Write); cs.Write(byt, 0, byt.Length); cs.FlushFinalBlock(); cs.Close(); return Convert.ToBase64String(ms.ToArray()); } /// <summary> /// 带指定密钥和矢量的3DES加密 /// </summary> /// <param name="str"></param> /// <param name="sKey"></param> /// <param name="sIV"></param> /// <returns></returns> public string Encrypt3DES(string str, string sKey, string sIV) { SymmetricAlgorithm mCSP = new TripleDESCryptoServiceProvider(); ICryptoTransform ct; MemoryStream ms; CryptoStream cs; byte[] byt; mCSP.Key = Convert.FromBase64String(sKey); mCSP.IV = Convert.FromBase64String(sIV); mCSP.Mode = System.Security.Cryptography.CipherMode.ECB; mCSP.Padding = System.Security.Cryptography.PaddingMode.PKCS7; ct = mCSP.CreateEncryptor(mCSP.Key, mCSP.IV); byt = Encoding.UTF8.GetBytes(str); ms = new MemoryStream(); cs = new CryptoStream(ms, ct, CryptoStreamMode.Write); cs.Write(byt, 0, byt.Length); cs.FlushFinalBlock(); cs.Close(); return Convert.ToBase64String(ms.ToArray()); } //解密 public string Decrypt3DES(string Value) { string sKey = "wyw308"; string sIV = "scf521"; SymmetricAlgorithm mCSP = new TripleDESCryptoServiceProvider(); ICryptoTransform ct; MemoryStream ms; CryptoStream cs; byte[] byt; mCSP.Key = Convert.FromBase64String(sKey); mCSP.IV = Convert.FromBase64String(sIV); mCSP.Mode = System.Security.Cryptography.CipherMode.ECB; mCSP.Padding = System.Security.Cryptography.PaddingMode.PKCS7; ct = mCSP.CreateDecryptor(mCSP.Key, mCSP.IV); byt = Convert.FromBase64String(Value); ms = new MemoryStream(); cs = new CryptoStream(ms, ct, CryptoStreamMode.Write); cs.Write(byt, 0, byt.Length); cs.FlushFinalBlock(); cs.Close(); return Encoding.UTF8.GetString(ms.ToArray()); } /// <summary> /// 带指定密钥和矢量的3DES解密 /// </summary> /// <param name="Value"></param> /// <param name="sKey"></param> /// <param name="sIV"></param> /// <returns></returns> public string Decrypt3DES(string str, string sKey, string sIV) { SymmetricAlgorithm mCSP = new TripleDESCryptoServiceProvider(); ICryptoTransform ct; MemoryStream ms; CryptoStream cs; byte[] byt; mCSP.Key = Convert.FromBase64String(sKey); mCSP.IV = Convert.FromBase64String(sIV); mCSP.Mode = System.Security.Cryptography.CipherMode.ECB; mCSP.Padding = System.Security.Cryptography.PaddingMode.PKCS7; ct = mCSP.CreateDecryptor(mCSP.Key, mCSP.IV); byt = Convert.FromBase64String(str); ms = new MemoryStream(); cs = new CryptoStream(ms, ct, CryptoStreamMode.Write); cs.Write(byt, 0, byt.Length); cs.FlushFinalBlock(); cs.Close(); return Encoding.UTF8.GetString(ms.ToArray()); } #endregion #region 一个简单的加密解密方法,只支持英文 public static string EnCryptEnStr(string str) //倒序加1加密 { byte[] by = new byte[str.Length]; for (int i = 0; i <= str.Length - 1; i++) { by[i] = (byte)((byte)str[i] + 1); } str = ""; for (int i = by.Length - 1; i >= 0; i--) { str += ((char)by[i]).ToString(); } return str; } public static string DeCryptEnStr(string str) //顺序减1解码 { byte[] by = new byte[str.Length]; for (int i = 0; i <= str.Length - 1; i++) { by[i] = (byte)((byte)str[i] - 1); } str = ""; for (int i = by.Length - 1; i >= 0; i--) { str += ((char)by[i]).ToString(); } return str; } #endregion #region 一个简单的加密解密方法,在上一个的基础上支持中文 public static string EnCryptCnStr(string str) { string htext = ""; // blank text for (int i = 0; i < str.Length; i++) { htext = htext + (char)(str[i] + 10 - 1 * 2); } return htext; } public static string DeCryptCnStr(string str) { string dtext = ""; for (int i = 0; i < str.Length; i++) { dtext = dtext + (char)(str[i] - 10 + 1 * 2); } return dtext; } #endregion #region Url地址编码解码 /// <summary> /// 编码Url地址 /// </summary> /// <param name="url"></param> /// <returns></returns> public static string UrlEncode(string url) { byte[] mByte = null; mByte = System.Text.Encoding.GetEncoding("GB2312").GetBytes(url); return System.Web.HttpUtility.UrlEncode(mByte); } /// <summary> /// 解码Url地址 /// </summary> /// <param name="url"></param> /// <returns></returns> public static string UrlDecode(string url) { return HttpUtility.UrlDecode(url, System.Text.Encoding.GetEncoding("GB2312")); } #endregion
以上所述就是本文的全部内容了,希望大家能够喜欢。
英特尔证实HDCP(高频宽数字内容保护)主密钥已经泄漏,现在研究人员在BSD许可证下发布了HDCP加密/解密算法的开源实现。他们表示公布软件的目的是帮助其他人研究或实现HDCP协议。 主密钥: 6692d179032205 b4116a96425a7f ecc2ef51af1740 959d3b6d07bce4 fa9f2af29814d9 82592e77a204a8 146a6970e3c4a
加解密算法 算法类型 特点 优势 缺陷 代表算法 对称加密 加解密密钥相同或可推算 计算效率高,加密强度高 需提前共享密钥;易泄露 DES、3DES、AES、IDEA 非对称加密 加解密密钥不相关 无需提前共享密钥 计算效率低,仍存在中间人攻击可能 RSA、ElGamal、椭圆曲线系列算法 算法体系 现代加密算法的典型组件包括:加解密算法、加密密钥、解密密钥。其中,加解密算法自身是固定不变的,一般
本文向大家介绍php用户密码加密算法分析【Discuz加密算法】,包括了php用户密码加密算法分析【Discuz加密算法】的使用技巧和注意事项,需要的朋友参考一下 本文实例讲述了php用户密码加密算法。分享给大家供大家参考,具体如下: 今天在拿Discuz进行二次开发时需要在代码里验证Discuz的用户名密码,结果不小心掉进了坑里,因为Discuz的论坛有两张表来存储用户数据,一张在Discuz的
本文向大家介绍python实现RSA加密(解密)算法,包括了python实现RSA加密(解密)算法的使用技巧和注意事项,需要的朋友参考一下 RSA是目前最有影响力的公钥加密算法,它能够抵抗到目前为止已知的绝大多数密码攻击,已被ISO推荐为公钥数据加密标准。 今天只有短的RSA钥匙才可能被强力方式解破。到2008年为止,世界上还没有任何可靠的攻击RSA算法的方式。只要其密钥的长度足够长,用RSA加密
本文向大家介绍java实现Base64加密解密算法,包括了java实现Base64加密解密算法的使用技巧和注意事项,需要的朋友参考一下 Base64是网络上最常见的用于传输8Bit字节代码的编码方式之一,大家可以查看RFC2045~RFC2049,上面有MIME的详细规范。Base64编码可用于在HTTP环境下传递较长的标识信息。例如,在Java Persistence系统Hibernate中,就
MD5 加密算法 类型:MD5 可配置属性:无 AES 加密算法 类型:AES 可配置属性: 名称 数据类型 说明 aes-key-value String AES 使用的 KEY RC4 加密算法 类型:RC4 可配置属性: 名称 数据类型 说明 rc4-key-value String RC4 使用的 KEY