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This is a continuation of this question, PBEWithMD5AndDES Encryption in iOS, as it was suggested I start a new questions with a different approach.

What I basically need to do here is duplicate some encryption that's happening in an android app, in an iOS app. I have some encryption working, but as it says in the previous question, the encrypted value is inconsistent. I need the encrypted value on the iOS end to be the same as the encrypted value on the android side, because they will be sharing that data. I am including the java function as well as the objective c class. Both sides of this are flexible, I just have limited knowledge of encryption algorithms.

Here's the java function.

public DesEncrypter(String passPhrase) {
try {
    // Create the key
    KeySpec keySpec = new PBEKeySpec(passPhrase.toCharArray(), salt, iterationCount);
    SecretKey key = SecretKeyFactory.getInstance(
        "PBEWithMD5AndDES").generateSecret(keySpec);
    ecipher = Cipher.getInstance(key.getAlgorithm());
    dcipher = Cipher.getInstance(key.getAlgorithm());

    // Prepare the parameter to the ciphers
    AlgorithmParameterSpec paramSpec = new PBEParameterSpec(salt, iterationCount);

    // Create the ciphers
    ecipher.init(Cipher.ENCRYPT_MODE, key, paramSpec);
    dcipher.init(Cipher.DECRYPT_MODE, key, paramSpec);
} catch (java.security.InvalidAlgorithmParameterException e) {
} catch (java.security.spec.InvalidKeySpecException e) {
} catch (javax.crypto.NoSuchPaddingException e) {
} catch (java.security.NoSuchAlgorithmException e) {
} catch (java.security.InvalidKeyException e) {
}

}

Here's the objective c class.

@implementation CryptoHelper

#pragma mark -
#pragma mark Init Methods
- (id)init
{
    if(self = [super init])
    {

    }
    return self;
}

#pragma mark -
#pragma mark String Specific Methods

/** 
 *  Encrypts a string for social blast service. 
 *  
 *  @param  plainString The string to encrypt;
 *
 *  @return NSString    The encrypted string. 
 */
- (NSString *)encryptString: (NSString *) plainString{

    // Convert string to data and encrypt
    NSData *data = [self encryptPBEWithMD5AndDESData:[plainString dataUsingEncoding:NSUTF8StringEncoding] password:@"1111"];



    // Get encrypted string from data
    return [data base64EncodingWithLineLength:1024];

}


/** 
 *  Descrypts a string from social blast service. 
 *  
 *  @param  plainString The string to decrypt;
 *
 *  @return NSString    The decrypted string. 
 */
- (NSString *)decryptString: (NSString *) encryptedString{

    // decrypt the data
    NSData * data = [self decryptPBEWithMD5AndDESData:[NSData dataWithBase64EncodedString:encryptedString] password:@"1111"];

    // extract and return string
    return [NSString stringWithUTF8String:[data bytes]];

}


#pragma mark -
#pragma mark Crypto Methods

- (NSData *)encryptPBEWithMD5AndDESData:(NSData *)inData password:(NSString *)password {
    return [self encodePBEWithMD5AndDESData:inData password:password direction:1];
}

- (NSData *)decryptPBEWithMD5AndDESData:(NSData *)inData password:(NSString *)password {
    return [self encodePBEWithMD5AndDESData:inData password:password direction:0];
}

- (NSData *)encodePBEWithMD5AndDESData:(NSData *)inData password:(NSString *)password direction:(int)direction
{
    NSLog(@"helper data = %@", inData);

    static const char gSalt[] =
    {
        (unsigned char)0xAA, (unsigned char)0xAA, (unsigned char)0xAA, (unsigned char)0xAA,
        (unsigned char)0xAA, (unsigned char)0xAA, (unsigned char)0xAA, (unsigned char)0xAA,
        (unsigned char)0x00
    };

    unsigned char *salt = (unsigned char *)gSalt;
    int saltLen = strlen(gSalt);
    int iterations = 15;

    EVP_CIPHER_CTX cipherCtx;


    unsigned char *mResults; // allocated storage of results
    int mResultsLen = 0;

    const char *cPassword = [password UTF8String];

    unsigned char *mData = (unsigned char *)[inData bytes];
    int mDataLen = [inData length];


    SSLeay_add_all_algorithms();
    X509_ALGOR *algorithm = PKCS5_pbe_set(NID_pbeWithMD5AndDES_CBC,
                                          iterations, salt, saltLen);



    memset(&cipherCtx, 0, sizeof(cipherCtx));

    if (algorithm != NULL)
    {
        EVP_CIPHER_CTX_init(&(cipherCtx));



        if (EVP_PBE_CipherInit(algorithm->algorithm, cPassword, strlen(cPassword),
                               algorithm->parameter, &(cipherCtx), direction))
        {

            EVP_CIPHER_CTX_set_padding(&cipherCtx, 1);

            int blockSize = EVP_CIPHER_CTX_block_size(&cipherCtx);
            int allocLen = mDataLen + blockSize + 1; // plus 1 for null terminator on decrypt
            mResults = (unsigned char *)OPENSSL_malloc(allocLen);


            unsigned char *in_bytes = mData;
            int inLen = mDataLen;
            unsigned char *out_bytes = mResults;
            int outLen = 0;



            int outLenPart1 = 0;
            if (EVP_CipherUpdate(&(cipherCtx), out_bytes, &outLenPart1, in_bytes, inLen))
            {
                out_bytes += outLenPart1;
                int outLenPart2 = 0;
                if (EVP_CipherFinal(&(cipherCtx), out_bytes, &outLenPart2))
                {
                    outLen += outLenPart1 + outLenPart2;
                    mResults[outLen] = 0;
                    mResultsLen = outLen;
                }
            } else {
                unsigned long err = ERR_get_error();

                ERR_load_crypto_strings();
                ERR_load_ERR_strings();
                char errbuff[256];
                errbuff[0] = 0;
                ERR_error_string_n(err, errbuff, sizeof(errbuff));
                NSLog(@"OpenSLL ERROR:\n\tlib:%s\n\tfunction:%s\n\treason:%s\n",
                      ERR_lib_error_string(err),
                      ERR_func_error_string(err),
                      ERR_reason_error_string(err));
                ERR_free_strings();
            }


            NSData *encryptedData = [NSData dataWithBytes:mResults length:mResultsLen]; //(NSData *)encr_buf;


            //NSLog(@"encryption result: %@\n", [encryptedData base64EncodingWithLineLength:1024]);

            EVP_cleanup();

            return encryptedData;
        }
    }
    EVP_cleanup();
    return nil;

}

@end

I'm using an openssl static library for ios.

Thanks, Brandon

share|improve this question
1  
Why base64ENcoding? –  Zaph Aug 29 '11 at 14:25
    
Not really sure. Just the examples I saw. That seems to work. It's just that the encrypted value is different when I encrypt it in the context of different classes. I'm pretty flexible with how the encryption is done, it just needs to work the same in both platforms. –  btate Aug 29 '11 at 14:39
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1 Answer

up vote 2 down vote accepted

For encryption to work correctly everything needs to be exactly the same at both ends. The same mode, the same key, the same IV and the same padding. You need to check each of these. Don't rely on the default mode but explicitly specify CBC (or CTR) at both ends. After generating your key, print it in hex on both ends so you can check that it is identical. Print the IV in hex at both ends to check. Don't rely on the defaults but explicitly specify the padding (PKCS5 or PKCS7) on both ends.

I have also seen problems with cyphertext where is is converted into a string in one character encoding but converted back to bytes as if it was in another character encoding. Make sure that you are using the same character encoding at both ends.

Once you have identified where the mismatches are happening you can fix them.

On a side note I notice that you are using DES. This is now obsolete and should only be used for backwards compatibility. Use AES for all new applications.

share|improve this answer
    
I've tried using the using the objective c functions above in two different classes. They produced different encrypted strings depending on which class they were in. They consistently produced the same encrypted string within those classes though. What am I missing from that encryption setup specifically? I believe they're set up to use the same things for everything listed above. Am I misusing an openssl function? –  btate Aug 29 '11 at 15:21
    
Looking at the C code I am unhappy about the way the salt is set up. It is defined as an array of 0xAA bytes and then cast to a char* string. Where will the 0x00 byte be to mark the end of the string? That might account for the output being different if the code is in different classes with different memory contents then the resulting string will have a different length and different contents. Try adding an explicit 0x00 byte at the end of the salt. –  rossum Aug 29 '11 at 17:43
    
Added the terminating byte and good to go. I've been trying to figure out what's wrong with this for days. To match the java code I went back to my original algorithm with no IV. The question has been updated to reflect the new code. –  btate Aug 29 '11 at 18:12
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