Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.
from Crypto.Cipher import AES
import os

key = 'mysecretpassword'
iv = os.urandom(16)
plaintext1 = 'Secret Message A'
encobj = AES.new(key, AES.MODE_CBC, iv)
ciphertext1 = encobj.encrypt(plaintext1) 
encryptedText = ciphertext1.encode('base64')
print encryptedText
decobj = AES.new(key, AES.MODE_CBC, iv)
print decobj.decrypt(ciphertext1)

I copied the printed value of encryptedText and the key from my code and pasted to the websites below.



I would expected it to be able to decrypt my cipher, but it doesn't. Thus I must be using pycrypto wrong. How do I fix this? The two sites can both encrypt and decrypt between each other, but mines can't. Both the websites do indeed use CBC mode.

share|improve this question
Did you try different modes? I cannot see whether the site uses XTS, CBC or maybe only ECB. Try different modes. Note that you use an IV but the site does not ask for one. –  javex Aug 31 '12 at 19:37
You need to give the decrypter the IV. That website doesn't accept an IV. So it is probably using ECB, not CBC. –  Keith Randall Aug 31 '12 at 19:38
Also, how do you know that website takes the ciphertext as base64? –  Keith Randall Aug 31 '12 at 19:38
Yes, I made the wrong assumption that the website takes the ciphertext as base64. –  user299648 Aug 31 '12 at 19:53
Actually, my assumption is correct the website does take the ciphertext as base64. It even explicitly says in the second web link. There's no way it can be in ascii or something else. So I am still confused with what I'm doing wrong in the code. How do I get it to be decrypted by the websites. –  user299648 Aug 31 '12 at 20:16

1 Answer 1

up vote 3 down vote accepted

If you look at the page source for the website in question, you will see that it uses gibberish-aes javascript library. To see whet you have to do to make it work, you have to study what it does.

Looking through its source code, it seems to use a random salt for encryption. That, prepended by the string Salted__ forms the beginning of the cyphertext before it is base64 encoded.

randArr = function(num) {
    var result = [], i;
    for (i = 0; i < num; i++) {
        result = result.concat(Math.floor(Math.random() * 256));
    return result;


enc = function(string, pass, binary) {
        // string, password in plaintext
        var salt = randArr(8),
        pbe = openSSLKey(s2a(pass, binary), salt),
        key = pbe.key,
        iv = pbe.iv,
        saltBlock = [[83, 97, 108, 116, 101, 100, 95, 95].concat(salt)];
        string = s2a(string, binary);
        cipherBlocks = rawEncrypt(string, key, iv);
        // Spells out 'Salted__'
        cipherBlocks = saltBlock.concat(cipherBlocks);
        return Base64.encode(cipherBlocks);

For decryption, it uses picks the random portion of the salt out of the beginning of the cyphertext after base64 decoding (the first slice operator):

dec = function(string, pass, binary) {
    // string, password in plaintext
    var cryptArr = Base64.decode(string),
    salt = cryptArr.slice(8, 16),
    pbe = openSSLKey(s2a(pass, binary), salt),
    key = pbe.key,
    iv = pbe.iv;
    cryptArr = cryptArr.slice(16, cryptArr.length);
    // Take off the Salted__ffeeddcc
    string = rawDecrypt(cryptArr, key, iv, binary);
    return string;

The missing piece now is the openSSLkey function:

openSSLKey = function(passwordArr, saltArr) {
    // Number of rounds depends on the size of the AES in use
    // 3 rounds for 256
    // 2 rounds for the key, 1 for the IV
    // 2 rounds for 128
    // 1 round for the key, 1 round for the IV
    // 3 rounds for 192 since it's not evenly divided by 128 bits
    var rounds = Nr >= 12 ? 3: 2,
    key = [],
    iv = [],
    md5_hash = [],
    result = [],
    data00 = passwordArr.concat(saltArr),
    md5_hash[0] = GibberishAES.Hash.MD5(data00);
    result = md5_hash[0];
    for (i = 1; i < rounds; i++) {
        md5_hash[i] = GibberishAES.Hash.MD5(md5_hash[i - 1].concat(data00));
        result = result.concat(md5_hash[i]);
    key = result.slice(0, 4 * Nk);
    iv = result.slice(4 * Nk, 4 * Nk + 16);
    return {
        key: key,
        iv: iv

So basically you have to translate the openSSLKey function to Python and feed it your password and salt. That creates a (key, iv) tuple. Use those to encrypt your data. Prepend the string Salted__ and the salt to the ciphertext before encoding it with base64. Then it should work, I think.

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.