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I am trying to encrypt some text using the AES algorithm on both the Android and IPhone platforms. My problem is, even using the same encryption/decryption algorithm (AES-128) and same fixed variables (key, IV, mode), I get different result on both platforms. I am including code samples from both platforms, that I am using to test the encryption/decryption. I would appreciate some help in determining what I am doing wrong.

  • Key: “123456789abcdefg”
  • IV: “1111111111111111”
  • Plain Text: “HelloThere”
  • Mode: “AES/CBC/NoPadding”

Android Code:

public class Crypto {
    private final static String HEX = "0123456789ABCDEF";

    public static String encrypt(String seed, String cleartext)
            throws Exception {
        byte[] rawKey = getRawKey(seed.getBytes());
        byte[] result = encrypt(rawKey, cleartext.getBytes());
        return toHex(result);

    public static String decrypt(String seed, String encrypted)
            throws Exception {
        byte[] rawKey = getRawKey(seed.getBytes());
        byte[] enc = toByte(encrypted);
        byte[] result = decrypt(rawKey, enc);
        return new String(result);

    private static byte[] getRawKey(byte[] seed) throws Exception {
        KeyGenerator kgen = KeyGenerator.getInstance("CBC");
        SecureRandom sr = SecureRandom.getInstance("SHA1PRNG");
        kgen.init(128, sr); // 192 and 256 bits may not be available
        SecretKey skey = kgen.generateKey();
        byte[] raw = skey.getEncoded();
        return raw;

    private static byte[] encrypt(byte[] raw, byte[] clear) throws Exception {
        SecretKeySpec skeySpec = new SecretKeySpec(raw, "AES");
        Cipher cipher = Cipher.getInstance("AES");
        cipher.init(Cipher.ENCRYPT_MODE, skeySpec);
        byte[] encrypted = cipher.doFinal(clear);
        return encrypted;

    private static byte[] decrypt(byte[] raw, byte[] encrypted)
            throws Exception {
        SecretKeySpec skeySpec = new SecretKeySpec(raw, "AES");
        Cipher cipher = Cipher.getInstance("AES");
        cipher.init(Cipher.DECRYPT_MODE, skeySpec);
        byte[] decrypted = cipher.doFinal(encrypted);
        return decrypted;

    public static String toHex(String txt) {
        return toHex(txt.getBytes());

    public static String fromHex(String hex) {
        return new String(toByte(hex));

    public static byte[] toByte(String hexString) {
        int len = hexString.length() / 2;
        byte[] result = new byte[len];
        for (int i = 0; i < len; i++)
            result[i] = Integer.valueOf(hexString.substring(2 * i, 2 * i + 2),
        return result;

    public static String toHex(byte[] buf) {
        if (buf == null)
            return "";

        StringBuffer result = new StringBuffer(2 * buf.length);
        for (int i = 0; i < buf.length; i++) {
            appendHex(result, buf[i]);

        return result.toString();

    private static void appendHex(StringBuffer sb, byte b) {
        sb.append(HEX.charAt((b >> 4) & 0x0f)).append(HEX.charAt(b & 0x0f));

IPhone (Objective-C) Code:

- (NSData *) transform:(CCOperation) encryptOrDecrypt data:(NSData *) inputData { 

    NSData* secretKey = [Cipher md5:cipherKey];

    CCCryptorRef cryptor = NULL;
    CCCryptorStatus status = kCCSuccess;

    uint8_t iv[kCCBlockSizeAES128];
    memset((void *) iv, 0x0, (size_t) sizeof(iv));

    status = CCCryptorCreate(encryptOrDecrypt, kCCAlgorithmAES128, kCCOptionPKCS7Padding,
                         [secretKey bytes], kCCKeySizeAES128, iv, &cryptor);

    if (status != kCCSuccess) {
        return nil;

    size_t bufsize = CCCryptorGetOutputLength(cryptor, (size_t)[inputData length], true);

    void * buf = malloc(bufsize * sizeof(uint8_t));
    memset(buf, 0x0, bufsize);

    size_t bufused = 0;
    size_t bytesTotal = 0;

    status = CCCryptorUpdate(cryptor, [inputData bytes], (size_t)[inputData length],
                         buf, bufsize, &bufused);

    if (status != kCCSuccess) {
        return nil;

    bytesTotal += bufused;

    status = CCCryptorFinal(cryptor, buf + bufused, bufsize - bufused, &bufused);

    if (status != kCCSuccess) {
        return nil;

    bytesTotal += bufused;


    return [NSData dataWithBytesNoCopy:buf length:bytesTotal];

+ (NSData *) md5:(NSString *) stringToHash {

    const char *src = [stringToHash UTF8String];

    unsigned char result[CC_MD5_DIGEST_LENGTH];

    CC_MD5(src, strlen(src), result);

    return [NSData dataWithBytes:result length:CC_MD5_DIGEST_LENGTH];

Some of my references :

share|improve this question
Which encrypt() method are you using? Your question is a mess. Only provide the essential code. –  erickson Nov 10 '12 at 17:58
you can use this solution ,it work for me : [enter link description here][1] [1]: stackoverflow.com/questions/17535918/… –  MacAhmed Nov 4 '13 at 18:41
Why do you need the encrypted data to be equal? Probably you'll make your code less secure without reason. In most use cases only decrypted data must be equal. See crypto.stackexchange.com/q/5094 –  Christian Strempfer Aug 7 '14 at 6:57

5 Answers 5

For iPhone I used AESCrypt-ObjC, and for Android use this code:

public class AESCrypt {

private final Cipher cipher;
private final SecretKeySpec key;
private AlgorithmParameterSpec spec;

public AESCrypt(String password) throws Exception
    // hash password with SHA-256 and crop the output to 128-bit for key
    MessageDigest digest = MessageDigest.getInstance("SHA-256");
    byte[] keyBytes = new byte[32];
    System.arraycopy(digest.digest(), 0, keyBytes, 0, keyBytes.length);

    cipher = Cipher.getInstance("AES/CBC/PKCS7Padding");
    key = new SecretKeySpec(keyBytes, "AES");
    spec = getIV();

public AlgorithmParameterSpec getIV()
    byte[] iv = {0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, };
    IvParameterSpec ivParameterSpec;
    ivParameterSpec = new IvParameterSpec(iv);

    return ivParameterSpec;

public String encrypt(String plainText) throws Exception
    cipher.init(Cipher.ENCRYPT_MODE, key, spec);
    byte[] encrypted = cipher.doFinal(plainText.getBytes("UTF-8"));
    String encryptedText = new String(Base64.encode(encrypted, Base64.DEFAULT), "UTF-8");

    return encryptedText;

public String decrypt(String cryptedText) throws Exception
    cipher.init(Cipher.DECRYPT_MODE, key, spec);
    byte[] bytes = Base64.decode(cryptedText, Base64.DEFAULT);
    byte[] decrypted = cipher.doFinal(bytes);
    String decryptedText = new String(decrypted, "UTF-8");

    return decryptedText;


share|improve this answer
-1 Don't use a fixed IV. crypto.stackexchange.com/q/5094 –  Christian Strempfer Aug 7 '14 at 6:56
@Chris This was done to align Android code with AESCrypt-ObjC iOS Library. Add AESCrypt-ObjC is not maintaing by me. –  Dimentar Aug 8 '14 at 12:32

If you want an example of compatible code for Android and iPhone, look at the RNCryptor library for iOS and the JNCryptor library for Java/Android.

Both projects are open source and share a common data format. In these libraries, AES 256-bit is used, however it would be trivial to adapt the code if necessary to support 128-bit AES.

As per the accepted answer, both libraries use PBKDF2.

share|improve this answer

See my answer for password-based AES encryption, since, you are effectively using your "seed" as a password. (Just change the key length of 256 to 128, if that's what you want.)

Trying to generate the same key by seeding a DRBG with the same value is not reliable.

Next, you are not using CBC or the IV in your Android encryption. My example shows how to do that properly too. By the way, you need to generate a new IV for every message you encrypt, as my example shows, and send it along with the cipher text. Otherwise, there's no point in using CBC.

share|improve this answer

It makes me no wonder that you get different results.

Your problem is that you use misuse a SHA1PRNG for key derivation. AFAIK there is no common standard how a SHA1PRNG work internally. AFAIR even the J2SE and Bouncycaste implementation output different results using the same seed.

Hence your implementation of your getRawKey(byte[] seed) will generate you a random key. If you use the key for encryption you are getting an result that depends on that key. As the key is random you will not get the same key on iOS and therefore you are getting a different result.

If you want a key derivation function use a function like PBKDF2 with is nearly fully standardized regarding the key derivation.

share|improve this answer
+1 - the key is in the name, psuedo random number generator. Different implementations don't give the same result, even when you use the same seed. –  Qwerky Nov 9 '12 at 16:15
First of all i wanna thank you for your feedback but i appreciate your effort if you can give more details or example since its little bit confusing for me –  UBA_MobileTeam Nov 9 '12 at 16:15
See my updated answer about your getRawKey(..) implementation. –  Robert Nov 10 '12 at 16:57
Exactly. No wonder! Cargo-cult programming at its worst. If you want any program to work, it will help to know what you are doing, instead of just throwing together bits of code you copied off the Internet. –  erickson Nov 10 '12 at 17:59

On Android, you are using getBytes(). This is an error as it means you are using the default charset rather than a known charset. Use getBytes("UTF-8") instead so you know exactly what bytes you are going to get.

I don't know the equivalent for Objective-C, but don't rely on the default. Explicitly specify UTF-8 when converting strings to bytes. That way you will get the same bytes on both sides.

I also note that you are using MD5 in the Objective-C code but not in the Android code. Is this deliberate?

share|improve this answer

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