基础知识
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什么是RSA?
答:RSA是一种非对称加密算法,常用来对传输数据进行加密,配合上数字摘要算法,也可以进行文字签名。 -
RSA加密中padding?
答:padding即填充方式,由于RSA加密算法中要加密的明文是要比模数小的,padding就是通过一些填充方式来限制明文的长度。后面会详细介绍padding的几种模式以及分段加密。 -
加密和加签有什么区别?
答:加密:公钥放在客户端,并使用公钥对数据进行加密,服务端拿到数据后用私钥进行解密;
加签:私钥放在客户端,并使用私钥对数据进行加签,服务端拿到数据后用公钥进行验签。
前者完全为了加密;后者主要是为了防恶意攻击,防止别人模拟我们的客户端对我们的服务器进行攻击,导致服务器瘫痪。
基本原理
RSA使用“密钥对”对数据进行加密解密,在加密解密前需要先生存公钥(Public Key)和私钥(Private Key)。
公钥(Public key): 用于加密数据. 用于公开, 一般存放在数据提供方, 例如iOS客户端。
私钥(Private key): 用于解密数据. 必须保密, 私钥泄露会造成安全问题。
iOS中的Security.framework提供了对RSA算法的支持,这种方式需要对密匙对进行处理, 根据public key生成证书, 通过private key生成p12格式的密匙。想想jave直接用字符串进行加密解密简单多了。(⊙o⊙)…
实战
证书生成
RSA加密这块公钥、私钥必不可少的。Apple是不支持直接使用字符串进行加密解密的,推荐使用p12文件。这边教大家去生成在加密中使用到的所有文件,并提供给Java使用,想当年这个公钥私钥搞了半天了。 %>_<%
- 生成模长为1024bit的私钥
openssl genrsa -out private_key.pem 1024- 生成certification require file
openssl req -new -key private_key.pem -out rsaCertReq.csr- 生成certification 并指定过期时间
openssl x509 -req -days3650-in rsaCertReq.csr -signkey private_key.pem -out rsaCert.crt- 生成公钥供iOS使用
openssl x509 -outform der -in rsaCert.crt -out public_key.der- 生成私钥供iOS使用 这边会让你输入密码,后期用到在生成secKeyRef的时候会用到这个密码
openssl pkcs12 -export -out private_key.p12 -inkey private_key.pem -in rsaCert.crt- 生成pem结尾的公钥供Java使用
openssl rsa -in private_key.pem -out rsa_public_key.pem -pubout- 生成pem结尾的私钥供Java使用openssl pkcs8 -topk8 -in private_key.pem -out pkcs8_private_key.pem -nocrypt
以上所有的步骤都是在终端下完成的哦 (^__^)
生成公钥和私钥的secKeyRef
//根据你的p12文件生成私钥对应的SecKeyRef 这边返回若是nil 请检查你p12文件的生成步骤 - (SecKeyRef)getPrivateKeyRefrenceFromData:(NSData*)p12Data password:(NSString*)password { SecKeyRef privateKeyRef = NULL; NSMutableDictionary * options = [[NSMutableDictionary alloc] init]; [options setObject: password forKey:(__bridge id)kSecImportExportPassphrase]; CFArrayRef items = CFArrayCreate(NULL, 0, 0, NULL); OSStatus securityError = SecPKCS12Import((__bridge CFDataRef) p12Data, (__bridge CFDictionaryRef)options, &items); if (securityError == noErr && CFArrayGetCount(items) > 0) { CFDictionaryRef identityDict = CFArrayGetValueAtIndex(items, 0); SecIdentityRef identityApp = (SecIdentityRef)CFDictionaryGetValue(identityDict, kSecImportItemIdentity); securityError = SecIdentityCopyPrivateKey(identityApp, &privateKeyRef); if (securityError != noErr) { privateKeyRef = NULL; } } CFRelease(items); return privateKeyRef; }
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//根据你的der文件公钥对应的SecKeyRef - (SecKeyRef)getPublicKeyRefrenceFromeData: (NSData*)derData { SecCertificateRef myCertificate = SecCertificateCreateWithData(kCFAllocatorDefault, (__bridge CFDataRef)derData); SecPolicyRef myPolicy = SecPolicyCreateBasicX509(); SecTrustRef myTrust; OSStatus status = SecTrustCreateWithCertificates(myCertificate,myPolicy,&myTrust); SecTrustResultType trustResult; if (status == noErr) { status = SecTrustEvaluate(myTrust, &trustResult); } SecKeyRef securityKey = SecTrustCopyPublicKey(myTrust); CFRelease(myCertificate); CFRelease(myPolicy); CFRelease(myTrust); return securityKey; }
加密与解密
- (NSData*)rsaEncryptData:(NSData*)data { SecKeyRef key = [self getPublicKey]; size_t cipherBufferSize = SecKeyGetBlockSize(key); uint8_t *cipherBuffer = malloc(cipherBufferSize * sizeof(uint8_t)); size_t blockSize = cipherBufferSize - 11; size_t blockCount = (size_t)ceil([data length] / (double)blockSize); NSMutableData *encryptedData = [[NSMutableData alloc] init]; for (int i=0; i<blockCount; i++) { unsigned long bufferSize = MIN(blockSize , [data length] - i * blockSize); NSData *buffer = [data subdataWithRange:NSMakeRange(i * blockSize, bufferSize)]; OSStatus status = SecKeyEncrypt(key, kSecPaddingPKCS1, (const uint8_t *)[buffer bytes], [buffer length], cipherBuffer, &cipherBufferSize); if (status != noErr) { return nil; } NSData *encryptedBytes = [[NSData alloc] initWithBytes:(const void *)cipherBuffer length:cipherBufferSize]; [encryptedData appendData:encryptedBytes]; } if (cipherBuffer){ free(cipherBuffer); } return encryptedData; }
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- (NSData*)rsaDecryptData:(NSData*)data { SecKeyRef key = [self getPrivatKey]; size_t cipherBufferSize = SecKeyGetBlockSize(key); size_t blockSize = cipherBufferSize; size_t blockCount = (size_t)ceil([data length] / (double)blockSize); NSMutableData *decryptedData = [[NSMutableData alloc] init]; for (int i = 0; i < blockCount; i++) { unsigned long bufferSize = MIN(blockSize , [data length] - i * blockSize); NSData *buffer = [data subdataWithRange:NSMakeRange(i * blockSize, bufferSize)]; size_t cipherLen = [buffer length]; void *cipher = malloc(cipherLen); [buffer getBytes:cipher length:cipherLen]; size_t plainLen = SecKeyGetBlockSize(key); void *plain = malloc(plainLen); OSStatus status = SecKeyDecrypt(key, kSecPaddingPKCS1, cipher, cipherLen, plain, &plainLen); if (status != noErr) { return nil; } NSData *decryptedBytes = [[NSData alloc] initWithBytes:(const void *)plain length:plainLen]; [decryptedData appendData:decryptedBytes]; } return decryptedData; }
RSA加密中的Padding
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RSA_PKCS1_PADDING 填充模式,最常用的模式
要求: 输入:必须 比 RSA 钥模长(modulus) 短至少11个字节, 也就是 RSA_size(rsa) – 11 如果输入的明文过长,必须切割,然后填充。
输出:和modulus一样长
根据这个要求,对于1024bit的密钥,block length = 1024/8 – 11 = 117 字节 -
RSA_PKCS1_OAEP_PADDING
输入:RSA_size(rsa) – 41
输出:和modulus一样长 -
RSA_NO_PADDING 不填充
输入:可以和RSA钥模长一样长,如果输入的明文过长,必须切割, 然后填充
输出:和modulus一样长
签名与验证
//对数据进行sha256签名 - (NSData *)rsaSHA256SignData:(NSData *)plainData { SecKeyRef key = [self getPrivatKey]; size_t signedHashBytesSize = SecKeyGetBlockSize(key); uint8_t* signedHashBytes = malloc(signedHashBytesSize); memset(signedHashBytes, 0x0, signedHashBytesSize); size_t hashBytesSize = CC_SHA256_DIGEST_LENGTH; uint8_t* hashBytes = malloc(hashBytesSize); if (!CC_SHA256([plainData bytes], (CC_LONG)[plainData length], hashBytes)) { return nil; } SecKeyRawSign(key, kSecPaddingPKCS1SHA256, hashBytes, hashBytesSize, signedHashBytes, &signedHashBytesSize); NSData* signedHash = [NSData dataWithBytes:signedHashBytes length:(NSUInteger)signedHashBytesSize]; if (hashBytes) free(hashBytes); if (signedHashBytes) free(signedHashBytes); return signedHash; }
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//这边对签名的数据进行验证 验签成功,则返回YES - (BOOL)rsaSHA256VerifyData:(NSData *)plainData withSignature:(NSData *)signature { SecKeyRef key = [self getPublicKey]; size_t signedHashBytesSize = SecKeyGetBlockSize(key); const void* signedHashBytes = [signature bytes]; size_t hashBytesSize = CC_SHA256_DIGEST_LENGTH; uint8_t* hashBytes = malloc(hashBytesSize); if (!CC_SHA256([plainData bytes], (CC_LONG)[plainData length], hashBytes)) { return NO; } OSStatus status = SecKeyRawVerify(key, kSecPaddingPKCS1SHA256, hashBytes, hashBytesSize, signedHashBytes, signedHashBytesSize); return status == errSecSuccess; }
文章到此就结束了,希望这篇文章对大家有所帮助。想看demo的请点击:XYRSACryptor
来源:https://www.cnblogs.com/On1Key/p/5459144.html