# PyCrypto problem using AES+CTR

I'm writing a piece of code to encrypt a text using symmetric encryption. But it's not coming back with the right result...

``````from Crypto.Cipher import AES
import os

crypto = AES.new(os.urandom(32), AES.MODE_CTR, counter = lambda : os.urandom(16))
encrypted = crypto.encrypt("aaaaaaaaaaaaaaaa")
print crypto.decrypt(encrypted)
``````

Here, the decrypted text is different from the original.

I don't really understand much about cryptography so please bear with me. I understand the CTR mode requires a "counter" function to supply a random counter each time, but why does it need it to be 16 bytes when my key is 32 bytes and it insists that my message is in multiples of 16 bytes too? Is this normal?

I'm guessing that it doesn't get back to the original message because the counter changed between encrypt and decrypt. But then, how is it supposed to work theoretically anyway? What am I doing wrong? Anyway, I'm forced to resort back to ECB until I figure this out :(

-

The `counter` must return the same on decryption as it did on encryption, as you intuit, so, one way to do it is:

``````>>> secret = os.urandom(16)
>>> crypto = AES.new(os.urandom(32), AES.MODE_CTR, counter=lambda: secret)
>>> encrypted = crypto.encrypt("aaaaaaaaaaaaaaaa")
>>> print crypto.decrypt(encrypted)
aaaaaaaaaaaaaaaa
``````

CTR is a block cipher, so the "16-at-a-time" constraint that seems to surprise you is a pretty natural one.

Of course, a so-called "counter" returning the same value at each call isn't going to be particularly secure. Doesn't take much to do better, e.g....:

``````import array

class Secret(object):
def __init__(self, secret=None):
if secret is None: secret = os.urandom(16)
self.secret = secret
self.reset()
def counter(self):
for i, c in enumerate(self.current):
self.current[i] = c + 1
if self.current: break
return self.current.tostring()
def reset(self):
self.current = array.array('B', self.secret)

secret = Secret()
crypto = AES.new(os.urandom(32), AES.MODE_CTR, counter=secret.counter)
encrypted = crypto.encrypt(16*'a' + 16*'b' + 16*'c')
secret.reset()
print crypto.decrypt(encrypted)
``````
-
awesome. ok, I get it. so essentially, CTR has no advantage over ECB if I just want to encrypt one or very few things? I just want to store some passwords across sessions. Do I even need AES or should I be using something more simple? –  xster Jul 1 '10 at 6:52
Actually CTR can encrypt any arbitrary amount of text; it converts a block cipher into a key stream generator. There is no actual reason for the restriction that the input be multiples of a block size in this case. –  Jack Lloyd Jul 1 '10 at 12:44
PyCrypto seems to give an error when the input is not a multiple of 16 bytes however –  xster Jul 5 '10 at 18:11
Yep, so you just need to pad the input (to the next closest multiple of 16) if you want to use pycrypto. –  Alex Martelli Jul 5 '10 at 19:02
but if I use AES to encrypt passwords across sessions, I'd have to save the counter somewhere too in order to decrypt the next time I run it? Doesn't that defeat the security of having random counters? –  xster Jul 6 '10 at 6:51

The initialization vector ("counter") needs to stay the same, just as the key does, between encryption and decryption. It is used so that you can encode the same text a million times, and get different ciphertext each time (preventing some known plaintext attacks and pattern matching / attacks). You still need to use the same IV when decrypting as when encrypting. Usually when you start decrypting a stream, you initialize the IV to the same value that you started with when you started encrypting that stream.

See http://en.wikipedia.org/wiki/Initialization_vector for info on initialization vectors.

Note that os.urandom(16) is not 'deterministic', which is a requirement for counter functions. I suggest you use the increment function, as that is how CTR mode is designed. The initial counter value should be random, but the successive values should be fully predictable from the initial value (deterministic). The initial value may even be taken care of for you (I don't know the details)

About the key, IV, and input sizes, it sounds like the cipher you chose has a block size of 16 bytes. Everything you describe fits that and seems normal to me.

-

Has anyone tested the AES crypto algorithm in Python to verify the Test Vectors from http://tools.ietf.org/html/rfc3686#page-9 ?

For the First Test Vector: AES.new('ae6852f8121067cc4bf7a5765577f39e',AES.MODE_CTR,counter = lambda : secret)

could anyone tell me what should be the counter function ?

I coded as below:

``````plaintext = '53696e676c6520626c6f636b206d7367'
ctr = Counter.new(nbits=32, prefix=binascii.a2b_hex('000000300000000000000000'))
key = "ae6852f8121067cc4bf7a5765577f39e"
crypto =  AES.new(binascii.a2b_hex(key),AES.MODE_CTR,counter = ctr)
encrypted = crypto.encrypt(binascii.a2b_hex(plaintext))
encrypted_2 = binascii.b2a_hex(encrypted)
print encrypted_2
``````

The RFC Test Vector is:

``````Test Vector #1: Encrypting 16 octets using AES-CTR with 128-bit key
AES Key          : AE 68 52 F8 12 10 67 CC 4B F7 A5 76 55 77 F3 9E
AES-CTR IV       : 00 00 00 00 00 00 00 00
Nonce            : 00 00 00 30
Plaintext String : 'Single block msg'
Plaintext        : 53 69 6E 67 6C 65 20 62 6C 6F 63 6B 20 6D 73 67
Counter Block (1): 00 00 00 30 00 00 00 00 00 00 00 00 00 00 00 01
Key Stream    (1): B7 60 33 28 DB C2 93 1B 41 0E 16 C8 06 7E 62 DF
Ciphertext       : E4 09 5D 4F B7 A7 B3 79 2D 61 75 A3 26 13 11 B8
``````
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This code gives the correct output = e4095d4fb7a7b3792d6175a3261311b8 but the tricky part is to get Nonce | IV which goes as input to Counter.new If anyone knows how to derive IV, would be great. –  w00t Mar 23 '11 at 9:29

why does it need it to be 16 bytes when my key is 32 bytes

It has to be the same length as the cipher's block size. CTR mode just encrypts the counter and XORs the plaintext with the encrypted counter block.

Notes:

1. the counter value MUST be unique -- if you EVER use the same counter value to encrypt two different plaintexts under the same key, you just gave away your key.
2. like an IV, the counter is NOT secret -- just send it along with the ciphertext. If you make the code more complicated by trying to keep it secret, you will probably shoot yourself in the foot.
3. the counter value need not be unpredictable -- starting with zero and adding one for each block is perfectly fine (and best because of its simplicity).
4. the plain text can be any length -- CTR mode turns a block cipher into a stream cipher.

Standard disclaimer: Crypto is hard. If you don't understand what you are doing, you will get it wrong.

I just want to store some passwords across sessions.

Use scrypt. scrypt includes `encrypt` and `decrypt` which use AES-CTR with a password-derived key.

``````\$ pip install scrypt

\$ python
>>> import scrypt
>>> import getpass
>>> encrypted = scrypt.encrypt("Guido is a space alien.",pw)
>>> out = scrypt.decrypt(encrypted,pw)
>>> out
'Guido is a space alien.'
``````
-

I may be definitely late and I may have overlooked the previous answers, but I didn't find a clear statement of how this should (at least IMHO) be done according with the PyCrypto packages.

The Crypto.Util.Counter package provides callable stateful counters, which are very useful, but it was easy at least for me to use them improperly.

You have to create a counter, with e.g. `ctr = Counter.new('parameters here')`. Every time your counter is called by your counter mode cipher object to encrypt the message, it is incremented. This is needed for good cryptography practices, otherwise information about equal blocks may leak from the ciphertext.

Now you cannot call the decryption function on the same cipher object, because it would call again the same counter which in the meanwhile has been incremented, possibly several times. What you need to do is to create a new cipher object with a different counter initialized with the same parameters. In this way the decryption works properly, starting the counter from the same point as the encryption was done.

Working example below:

``````# Import modules
from Crypto.Cipher import AES
from Crypto import Random
from Crypto.Util import Counter

# Generate a random initialization vector, to be used by both encryptor and decryptor
# This may be sent in clear in a real communication

random_generator = Random.new()

# Encryption steps

# Ask user for input and pad or truncate to a 32 bytes (256 bits) key
prompt = 'Input your key. It will padded or truncated at 32 bytes (256 bits).\n-: '
user_keye = raw_input(prompt)

# Create counter for encryptor
ctr_e = Counter.new(64, prefix=IV)

# Create encryptor, ask for plaintext to encrypt, then encrypt and print ciphertext
encryptor = AES.new(keye, AES.MODE_CTR, counter=ctr_e)
plaintext = raw_input('Enter message to cipher: ')
ciphertext = encryptor.encrypt(plaintext)
print ciphertext
print

# Decryption steps

# Ask user for key: it must be equal to that used for encryption
prompt = 'Input your key. It will padded or truncated at 32 bytes (256 bits).\n-: '
user_keyd = raw_input(prompt)