兼容JS和C#的RSA加密解密算法 同时兼容JS和C#的RSA加密解密算法详解(对web提交的数据加密传输)
JackWang-CUMT 人气:0前言
我们在Web应用中往往涉及到敏感的数据,由于HTTP协议以明文的形式与服务器进行交互,因此可以通过截获请求的数据包进行分析来盗取有用的信息。虽然https可以对传输的数据进行加密,但是必须要申请证书(一般都是收费的),成本较高。那么问题来了,如果对web提交的敏感数据进行加密呢?web应用中,前端的数据处理和交互基本上都是靠javascript来完成,后台的逻辑处理可以C#(java)等进行处理。
微软的C#中虽然有RSA算法,但是格式和OpenSSL生成的公钥/私钥文件格式并不兼容。这个也给贯通前后台的RSA加密解密带来了难度。为了兼容OpenSSL生成的公钥/私钥文件格式,贯通javascript和C#的RSA加密解密算法,必须对C#内置的方法进行再度封装。
下面以登录为例,用户在密码框输入密码后,javascript发送ajax请求时,对密码先进行rsa加密后再发送,服务器接收到加密后的密码后,先对其进行解密, 然后再验证登录是否成功。
1、为了进行RSA加密解密,首先需要用openssl生成一对公钥和私钥(没有的先下载openssl):
1) 打开openssl.exe文件,输入 genrsa -out openssl_rsa_priv.pem 1024
此命令在openssl.exe同目录下生成openssl_rsa_private_key.pem文件。
2) 生成公钥 rsa -in openssl_rsa__private.pem -pubout -out openssl_rsa__public.pem
以上命令会创建如下的文件:
这个文件可以用文本编辑器进行打开,查看内容。
-----BEGIN PUBLIC KEY----- MIGfMA0GCSqGSIb3DQEBAQUAA4GNADCBiQKBgQC0w036ClSD0LvxPROMun0u022R OJlZE6P3m+gjq3gpi4n7lo8jhTqMqgccDbVJqnIfMzWS9O3lnlQXWTxJ3B4XJ52F AcriY5brOXUVgBLx5QMHLLd1gtJnmG4i7r4ytgX7XVKRnojR6zca1YnS0lbGGDF1 CGllB1riNrdksSQP+wIDAQAB -----END PUBLIC KEY-----
-----BEGIN RSA PRIVATE KEY----- MIICXQIBAAKBgQC0w036ClSD0LvxPROMun0u022ROJlZE6P3m+gjq3gpi4n7lo8j hTqMqgccDbVJqnIfMzWS9O3lnlQXWTxJ3B4XJ52FAcriY5brOXUVgBLx5QMHLLd1 gtJnmG4i7r4ytgX7XVKRnojR6zca1YnS0lbGGDF1CGllB1riNrdksSQP+wIDAQAB AoGAIOyl6lIxXKULZoBKbEqXfIz0GwxlGg1ywyn5mW2lAGQzKMken0ioBnD9xIVW rOlHyhkIvBCyuC0jgfE2Avn93MlB3j0WRuXMFlJpCBlEklMilO9Zgmwl+vTB3VZb 8VzdrEEEUBio7LWP/KvSo+IFlNjDTKgAczbLTwAmj4w6g0ECQQDm4yxPdxcU2ywZ 7PyjIMM9qnSah9KcrjU8gjEyHsUpgTjhw1cx7Peo+vRiHqxDy1yaSu1BlwRR52pC jKNnl0QhAkEAyGx3NxEIiLk2oXGGbIMZ4P6geC8gYu01BiRNWVf0Yi7+sCH68eUP oI+G5bJ8bvzXpvHjQi0s2OlRfct/qtPQmwJBALa+2DONbxdy4lUi3lO/esk0QVaO aoTY3gomggnJkQRo4zzOABXkGaIF/6gp3u9J5uG4rFFd1m19XP2Pk0ZK1AECQBYi lJAKW4zuF7CA3z3AxOzqckKTwdnrJL4G6FwDsMPfONWvCw4IJE+xSk64BbIkTpTr hhPa9WcHba6c+P6e4h0CQQDWeGMMpkqPG/w4afNCGmvRnM8vNkGUAmDGvCsfkTID ijpKl5SD55hPHsWE5rsv1TLUpkWtrFBcg61bHwMUP3cv -----END RSA PRIVATE KEY-----
2、用jsencrypt对密码进行加密:
首先需要导入js包文件
<script src="dist/js/jsencrypt.js"></script>
var encrypt = new JSEncrypt(); var pubkey = "-----BEGIN PUBLIC KEY----- \ MIGfMA0GCSqGSIb3DQEBAQUAA4GNADCBiQKBgQDAj0dPnBMf3Z4VT1B8Ee6bjKNs \ hlYj7xvGijAa8RCdmGR7mrtrExnk8mdUlwdcS05gc4SSFOyWJcYtKUHpWn8/pkS0 \ vgGOl9Bzn0Xt9hiqTb3pZAfykNrMDGZMgJgfD6KTnfzVUAOupvxjcGkcoj6/vV5I \ eMcx8mT/z3elfsDSjQIDAQAB \ -----END PUBLIC KEY-----"; encrypt.setPublicKey(pubkey); var encrypted = encrypt.encrypt($('#txtpwd').val()); //console.log(encrypted); $.ajax({ type: "POST", url: "http://localhost:24830/services/rsa_pem.ashx", data: { "pwd": encrypted }, dataType: "Json", error: function (xhr, status, error) { // alert(error); $("#txtInfo").text(' 请求服务器失败!'); $(that).text('登 录'); $(that).attr('disabled', false); }, success: function (json) { if (uid == "admin" && json.data=="000") { window.location.href = "index.html"; } else { $("#txtInfo").text(' 用户名或者密码错误!'); $(that).text('登 录'); $(that).attr('disabled', false); } } });
3、后台用C#进行解密
using System; using System.Collections.Generic; using System.IO; using System.Linq; using System.Security.Cryptography; using System.Text; using System.Threading.Tasks; namespace CMCloud.SaaS { public class RSACryptoService { private RSACryptoServiceProvider _privateKeyRsaProvider; private RSACryptoServiceProvider _publicKeyRsaProvider; /// <summary> /// RSA解密 /// </summary> /// <param name="cipherText"></param> /// <returns></returns> public string Decrypt(string cipherText) { if (_privateKeyRsaProvider == null) { throw new Exception("_privateKeyRsaProvider is null"); } return Decrypt2(cipherText); } /// <summary> /// RSA加密 /// </summary> /// <param name="text"></param> /// <returns></returns> public string Encrypt(string text) { if (_publicKeyRsaProvider == null) { throw new Exception("_publicKeyRsaProvider is null"); } return Encrypt2(text); //return Convert.ToBase64String(_publicKeyRsaProvider.Encrypt(Encoding.UTF8.GetBytes(text), false)); } private string Encrypt2(string text) { Byte[] PlaintextData = Encoding.UTF8.GetBytes(text); int MaxBlockSize = _publicKeyRsaProvider.KeySize / 8 - 11;//加密块最大长度限制 if (PlaintextData.Length <= MaxBlockSize) { return Convert.ToBase64String(_publicKeyRsaProvider.Encrypt(PlaintextData, false)); } else { using (MemoryStream PlaiStream = new MemoryStream(PlaintextData)) using (MemoryStream CrypStream = new MemoryStream()) { Byte[] Buffer = new Byte[MaxBlockSize]; int BlockSize = PlaiStream.Read(Buffer, 0, MaxBlockSize); while (BlockSize > 0) { Byte[] ToEncrypt = new Byte[BlockSize]; Array.Copy(Buffer, 0, ToEncrypt, 0, BlockSize); Byte[] Cryptograph = _publicKeyRsaProvider.Encrypt(ToEncrypt, false); CrypStream.Write(Cryptograph, 0, Cryptograph.Length); BlockSize = PlaiStream.Read(Buffer, 0, MaxBlockSize); } return Convert.ToBase64String(CrypStream.ToArray(), Base64FormattingOptions.None); } } } private string Decrypt2(string ciphertext) { Byte[] CiphertextData = Convert.FromBase64String(ciphertext); int MaxBlockSize = _privateKeyRsaProvider.KeySize / 8; //解密块最大长度限制 if (CiphertextData.Length <= MaxBlockSize) return System.Text.Encoding.UTF8.GetString(_privateKeyRsaProvider.Decrypt(CiphertextData, false)); using (MemoryStream CrypStream = new MemoryStream(CiphertextData)) using (MemoryStream PlaiStream = new MemoryStream()) { Byte[] Buffer = new Byte[MaxBlockSize]; int BlockSize = CrypStream.Read(Buffer, 0, MaxBlockSize); while (BlockSize > 0) { Byte[] ToDecrypt = new Byte[BlockSize]; Array.Copy(Buffer, 0, ToDecrypt, 0, BlockSize); Byte[] Plaintext = _privateKeyRsaProvider.Decrypt(ToDecrypt, false); PlaiStream.Write(Plaintext, 0, Plaintext.Length); BlockSize = CrypStream.Read(Buffer, 0, MaxBlockSize); } return System.Text.Encoding.UTF8.GetString(PlaiStream.ToArray()); } } public RSACryptoService(string privateKey, string publicKey = null) { if (!string.IsNullOrEmpty(privateKey)) { _privateKeyRsaProvider = CreateRsaProviderFromPrivateKey(privateKey); } if (!string.IsNullOrEmpty(publicKey)) { _publicKeyRsaProvider = CreateRsaProviderFromPublicKey(publicKey); } } private RSACryptoServiceProvider CreateRsaProviderFromPrivateKey(string privateKey) { var privateKeyBits = System.Convert.FromBase64String(privateKey); var RSA = new RSACryptoServiceProvider(); var RSAparams = new RSAParameters(); using (BinaryReader binr = new BinaryReader(new MemoryStream(privateKeyBits))) { byte bt = 0; ushort twobytes = 0; twobytes = binr.ReadUInt16(); if (twobytes == 0x8130) binr.ReadByte(); else if (twobytes == 0x8230) binr.ReadInt16(); else throw new Exception("Unexpected value read binr.ReadUInt16()"); twobytes = binr.ReadUInt16(); if (twobytes != 0x0102) throw new Exception("Unexpected version"); bt = binr.ReadByte(); if (bt != 0x00) throw new Exception("Unexpected value read binr.ReadByte()"); RSAparams.Modulus = binr.ReadBytes(GetIntegerSize(binr)); RSAparams.Exponent = binr.ReadBytes(GetIntegerSize(binr)); RSAparams.D = binr.ReadBytes(GetIntegerSize(binr)); RSAparams.P = binr.ReadBytes(GetIntegerSize(binr)); RSAparams.Q = binr.ReadBytes(GetIntegerSize(binr)); RSAparams.DP = binr.ReadBytes(GetIntegerSize(binr)); RSAparams.DQ = binr.ReadBytes(GetIntegerSize(binr)); RSAparams.InverseQ = binr.ReadBytes(GetIntegerSize(binr)); } RSA.ImportParameters(RSAparams); return RSA; } private int GetIntegerSize(BinaryReader binr) { byte bt = 0; byte lowbyte = 0x00; byte highbyte = 0x00; int count = 0; bt = binr.ReadByte(); if (bt != 0x02) return 0; bt = binr.ReadByte(); if (bt == 0x81) count = binr.ReadByte(); else if (bt == 0x82) { highbyte = binr.ReadByte(); lowbyte = binr.ReadByte(); byte[] modint = { lowbyte, highbyte, 0x00, 0x00 }; count = BitConverter.ToInt32(modint, 0); } else { count = bt; } while (binr.ReadByte() == 0x00) { count -= 1; } binr.BaseStream.Seek(-1, SeekOrigin.Current); return count; } private RSACryptoServiceProvider CreateRsaProviderFromPublicKey(string publicKeyString) { // encoded OID sequence for PKCS #1 rsaEncryption szOID_RSA_RSA = "1.2.840.113549.1.1.1" byte[] SeqOID = { 0x30, 0x0D, 0x06, 0x09, 0x2A, 0x86, 0x48, 0x86, 0xF7, 0x0D, 0x01, 0x01, 0x01, 0x05, 0x00 }; byte[] x509key; byte[] seq = new byte[15]; int x509size; x509key = Convert.FromBase64String(publicKeyString); x509size = x509key.Length; // --------- Set up stream to read the asn.1 encoded SubjectPublicKeyInfo blob ------ using (MemoryStream mem = new MemoryStream(x509key)) { using (BinaryReader binr = new BinaryReader(mem)) //wrap Memory Stream with BinaryReader for easy reading { byte bt = 0; ushort twobytes = 0; twobytes = binr.ReadUInt16(); if (twobytes == 0x8130) //data read as little endian order (actual data order for Sequence is 30 81) binr.ReadByte(); //advance 1 byte else if (twobytes == 0x8230) binr.ReadInt16(); //advance 2 bytes else return null; seq = binr.ReadBytes(15); //read the Sequence OID if (!CompareBytearrays(seq, SeqOID)) //make sure Sequence for OID is correct return null; twobytes = binr.ReadUInt16(); if (twobytes == 0x8103) //data read as little endian order (actual data order for Bit String is 03 81) binr.ReadByte(); //advance 1 byte else if (twobytes == 0x8203) binr.ReadInt16(); //advance 2 bytes else return null; bt = binr.ReadByte(); if (bt != 0x00) //expect null byte next return null; twobytes = binr.ReadUInt16(); if (twobytes == 0x8130) //data read as little endian order (actual data order for Sequence is 30 81) binr.ReadByte(); //advance 1 byte else if (twobytes == 0x8230) binr.ReadInt16(); //advance 2 bytes else return null; twobytes = binr.ReadUInt16(); byte lowbyte = 0x00; byte highbyte = 0x00; if (twobytes == 0x8102) //data read as little endian order (actual data order for Integer is 02 81) lowbyte = binr.ReadByte(); // read next bytes which is bytes in modulus else if (twobytes == 0x8202) { highbyte = binr.ReadByte(); //advance 2 bytes lowbyte = binr.ReadByte(); } else return null; byte[] modint = { lowbyte, highbyte, 0x00, 0x00 }; //reverse byte order since asn.1 key uses big endian order int modsize = BitConverter.ToInt32(modint, 0); int firstbyte = binr.PeekChar(); if (firstbyte == 0x00) { //if first byte (highest order) of modulus is zero, don't include it binr.ReadByte(); //skip this null byte modsize -= 1; //reduce modulus buffer size by 1 } byte[] modulus = binr.ReadBytes(modsize); //read the modulus bytes if (binr.ReadByte() != 0x02) //expect an Integer for the exponent data return null; int expbytes = (int)binr.ReadByte(); // should only need one byte for actual exponent data (for all useful values) byte[] exponent = binr.ReadBytes(expbytes); // ------- create RSACryptoServiceProvider instance and initialize with public key ----- RSACryptoServiceProvider RSA = new RSACryptoServiceProvider(); RSAParameters RSAKeyInfo = new RSAParameters(); RSAKeyInfo.Modulus = modulus; RSAKeyInfo.Exponent = exponent; RSA.ImportParameters(RSAKeyInfo); return RSA; } } } private bool CompareBytearrays(byte[] a, byte[] b) { if (a.Length != b.Length) return false; int i = 0; foreach (byte c in a) { if (c != b[i]) return false; i++; } return true; } } }
虽然将公钥暴露在js文件中,但是如果需要解密得到明文,必须需要私钥(这个存储在后台,不容易获取)。
调试运行,可以看到获取的密码是加密后的数据,然后在后台可以进行解密获取到明文。
总结
好了,大概就这样,以上就是这篇文章的全部内容了,希望本文的内容对大家的学习或者工作能带来一定的帮助,如果有疑问大家可以留言交流,谢谢大家对的支持
加载全部内容