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.

I'm trying to figure out how to mirror encryption/decryption from an existing C function over to python. However, in my tests of encrypting with C and decrypting with python, I can't figure out some elements around the key.

These were all code samples online, so I commented things like the base64 call in Python, and at this point I'm unsure on:

1) If I correctly determined the KEYBIT to KEY_SIZE/BLOCK_SIZE settings.

2) How to get from password to key in python to match the C code.

3) Am I missing any core conversion steps?

rijndael.h in C:

#define KEYLENGTH(keybits) ((keybits)/8)
#define RKLENGTH(keybits)  ((keybits)/8+28)
#define NROUNDS(keybits)   ((keybits)/32+6)

encrypting in C

#define KEYBITS 256

unsigned long rk[RKLENGTH(KEYBITS)];
unsigned char key[KEYLENGTH(KEYBITS)];


for (i = 0; i < sizeof(key); i++)
    key[i] = *password != 0 ? *password++ : 0;  

nrounds = rijndaelSetupEncrypt(rk, key, 256);

count = 0;
while (count < strlen(input)) {
    unsigned char ciphertext[16];
    unsigned char plaintext[16];
    for (i = 0; i < sizeof(plaintext); i++) {
        if (count < strlen(input))
            plaintext[i] = input[count++];
            plaintext[i] = 0;
    rijndaelEncrypt(rk, nrounds, plaintext, ciphertext);
    if (fwrite(ciphertext, sizeof(ciphertext), 1, output) != 1)             
        fputs("File write error", stderr);
        return 0;

Decrypt in Python


def decrypt(password, filename):

    key = password

    padded_key = key.ljust(KEY_SIZE, '\0')

    #ciphertext = base64.b64decode(encoded)
    ciphertext = file_get_contents(filename);

    r = rijndael(padded_key, BLOCK_SIZE)

    padded_text = ''
    for start in range(0, len(ciphertext), BLOCK_SIZE):
        padded_text += r.decrypt(ciphertext[start:start+BLOCK_SIZE])

    plaintext = padded_text.split('\x00', 1)[0]

    return plaintext


share|improve this question
I have in the past run into real difficulties trying to do this same thing. My suggestion to you would be to rather compile the encryption / decryption piece in C, and rather figure out how to invoke a piece of C code from within Python, whether in-process (as a linked library of some kind), or out of process (as a service call) –  Joon Sep 30 '12 at 13:42
What is the source of the rijndael function? –  Keith Sep 30 '12 at 13:59
I have considered the external call method, but was hoping to keep it consolidated. @Keith The sample code is from somewhere on the web, I do not remember where I got it unfortunately. If you are talking about the actual rijndael.c and rijndael.py files, I could paste them, but they are very long and I believe pretty standard files. –  Fmstrat Sep 30 '12 at 14:09
Could you not implement AES using PyCrypto? If you choose 128-bit blocks and 256-bit keys, Rijndael is the same thing as AES256. –  lserni Sep 30 '12 at 18:19

1 Answer 1

up vote 0 down vote accepted

The example C code just copies 32 bytes from the password string into the key. If the key is less than 32 bytes, it padds on the right with zeroes. Translated into python, this would be:

key = password[:32]+b'\x00'*(32-len(password))

Which actually produces the same result as

password.ljust(32, '\0')

You should note however that this method of generating keys is considerd extremely unsafe. If the attacker suspects that the key consists of ASCII characters padded with 0 bytes, the keyspace (amount of possible keys) is reduced considerably. If the key is made out of random bytes, there are 256^32 = 1.15e77 keys. If the key e.g. begins with 8 ASCII characters followed by zeroes, there are only (127-32)^8 = 6.63e15 possible keys. And since there are dictionaries out there with often-used passwords, the attacker probably wouldn't have to exhaust this reduced keyspace; he would try the relatively small dictionaries first.

Consider using a cryptographic hash function or another proper key derivation function to convert the passphrase into a key.

Try using the pycrypto toolkit. It implements Rijndael/AES and other ciphers.

share|improve this answer
Neither a cryptographic hash function nor a KDF creates any entropy - if you use an 8 character password as input to SHA256 (or any other hash) there are still only (127-32)^8 possible keys. A KDF adds salt to make dictionary attacks across multiple passwords less effective, but since the salt is known, it adds no entropy and no difficulty to the search for a single password. –  Dave Sep 30 '12 at 16:35
@Dave I presume this is additional information for Ben as it doesn't invalidate any of the information in the answer? –  Maarten Bodewes - owlstead Sep 30 '12 at 17:15
@Dave: Using the entropy function ported from fourmilab.ch/random, the entropy of a SHA256 hashed string 'password' is much greater than that of the same string right-padded to 32 bytes with zeroes... –  Roland Smith Sep 30 '12 at 17:37
@RolandSmith: No, a program that performs statistical tests on a set of data does not measure entropy. What you care about is the number of inputs an attacker needs to try before guessing the password. That number is the same (on average half the number of possibilities) for the raw zero-padded password or a hash of the password or a salted hash of the password. –  Dave Sep 30 '12 at 17:49
The WPA2 password converter used for Wi-Fi network keys (jorisvr.nl/wpapsk.html) uses many iterations of a hash function to convert a password into a hex key. But if your WPA2 password is 4 digits, you can brute force guess it in 5000 tries on average (10,000 tries if you're unlucky), regardless of how complex the 64 hex digit string appears to a statistics-measuring function. –  Dave Sep 30 '12 at 17:59

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.