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I am using python 2.7.1 I want to encrypt sth using AES in CTR mode. I installed PyCrypto library for python. I wrote the following code:

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

i have to run crypto.decrypt as many times as the byte size of my plaintext in order to get correctly the decrypted data. I.e:

encrypted = crypto.encrypt("test")
print crypto.decrypt(encrypted)
print crypto.decrypt(encrypted)
print crypto.decrypt(encrypted)
print crypto.decrypt(encrypted)

The last call to decrypt will give me the plaintext back. The other outputs from decrypt are some gibberish strings . I am wondering if this is normal or not? Do i have to include into a loop with size equal of my plaintext every time or i have gotten sth wrong?

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3 Answers 3

up vote 2 down vote accepted

According to @gertvdijk, AES_CTR is a stream cipher which does not need padding. So I've deleted the related codes.

Here's something I know.

  1. You have to use a same key(the first parameter in AES.new(...)) in encryption and decryption, and keep the key private.

  2. The encryption/decryption methods are stateful, that means crypto.en(de)crypt("abcd")==crypto.en(de)crypt("abcd") is not always true. In your CTR, your counter callback always returns a same thing, so it becomes stateless when encrypt (I am not 100% sure it is the reason), but we still find that it is somewhat stateful in decryption. As a conclusion, we should always use a new object to do them.

  3. The counter callback function in both encryption and decryption should behave the same. In your case, it is to make both of them return the same secret. Yet I don't think the secret is a "secret". You can use a random generated "secret" and pass it across the communicating peers without any encryption so that the other side can directly use it, as long as the secret is not predictable.

So I would write my cipher like this, hope it will offer some help.

import os
import hashlib
import Crypto.Cipher.AES as AES

class Cipher:

        def md5sum( raw ):
                m = hashlib.md5()
                return m.hexdigest()

        BS = AES.block_size

        def pad( s ):
                """note that the padding is no necessary"""
                """return s + (Cipher.BS - len(s) % Cipher.BS) * chr(Cipher.BS - len(s) % Cipher.BS)"""
                return s

        def unpad( s ):
                """return s[0:-ord(s[-1])]"""
                return s

        def __init__(self, key):
                self.key = Cipher.md5sum(key)
                #the state of the counter callback 
                self.cnter_cb_called = 0 
                self.secret = None

        def _reset_counter_callback_state( self, secret ):
                self.cnter_cb_called = 0
                self.secret = secret

        def _counter_callback( self ):
                this function should be stateful
                self.cnter_cb_called += 1
                return self.secret[self.cnter_cb_called % Cipher.BS] * Cipher.BS

        def encrypt(self, raw):
                secret = os.urandom( Cipher.BS ) #random choose a "secret" which is not secret
                self._reset_counter_callback_state( secret )
                cipher = AES.new( self.key, AES.MODE_CTR, counter = self._counter_callback )
                raw_padded = Cipher.pad( raw )
                enc_padded = cipher.encrypt( raw_padded )
                return secret+enc_padded #yes, it is not secret

        def decrypt(self, enc):
                secret = enc[:Cipher.BS]
                self._reset_counter_callback_state( secret )
                cipher = AES.new( self.key, AES.MODE_CTR, counter = self._counter_callback )
                enc_padded = enc[Cipher.BS:] #we didn't encrypt the secret, so don't decrypt it
                raw_padded = cipher.decrypt( enc_padded )
                return Cipher.unpad( raw_padded )

Some test:

>>> from Cipher import Cipher
>>> x = Cipher("this is key")
>>> "a"==x.decrypt(x.encrypt("a"))
>>> "b"==x.decrypt(x.encrypt("b"))
>>> "c"==x.decrypt(x.encrypt("c"))
>>> x.encrypt("a")==x.encrypt("a")
False #though the input is same, the outputs are different

Reference: http://packages.python.org/pycrypto/Crypto.Cipher.blockalgo-module.html#MODE_CTR

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I can't get the idea of your padding function...Why multiplication is needed with the chr() of the predefined expression? –  curious Oct 2 '12 at 15:54
@curious, we need to know the added length when do unpad, and we store it by using a char(it will not larger than 16, so a byte is enough, and we use its ascii code). (BS - len(s) % BS) is the added length, and chr(...) returns a byte(string in python actually), then we add a X length string where all the char in it are chr(X). –  Marcus Oct 2 '12 at 16:03
but is this a safe padding technique? –  curious Oct 2 '12 at 16:37
@curious, why not? IMHO, it is alright. –  Marcus Oct 2 '12 at 16:40
@curious, so far I think the key point of the attacking is the pad-oracle, rather than the padding functions, so two possible solutions can be 1. to make our pad oracle never say no to any input, or 2. add authentication info in the encrypted data, i.e enc=secret+md5sum(secret+private_key)+enc_raw, so as to always say no to invalid inputs. –  Marcus Oct 3 '12 at 3:41

Here's my answer as I think the currently accepted answer by Marcus is completely wrong.

First of all, the whole point of AES-CTR is that you do not need padding. It's a stream cipher (unlike ECB/CBC and so on)!

The reason why this behaves as you described in the question is because your plaintext (4 bytes / 32 bits) is four times as small as the block size of AES (128 bits). And by reusing the same crypto object you're only getting the same data back after going through the block size. So, your issue will be solved by instantiating a new cryto object, like this:

counter = os.urandom(16)   # fixed counter - do not use this in production!
key = os.urandom(32)       # 256 bits key
encrypto = AES.new(key, AES.MODE_CTR, counter=lambda: counter)
encrypted = encrypto.encrypt("asdk")

# Instantiate a new cipher for decryption
decrypto = AES.new(key, AES.MODE_CTR, counter=lambda: counter)
print decrypto.decrypt(encrypted) # prints "asdk"
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In addition to what Marcus says, the Crypto.Util.Counter class can be used to build your counter block function.

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