Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

I'm working on a toy module to encrypt tempfiles. The idea is to expose an interface similar to that found in the tempfile module, but to have data transparently encrypted using session keys. Again, it's just a toy project and not production code.

First, a few technical details. This project is implemented with pycrypto and is employing:

  • A counter with a 1-bit randomized prefix

The basic class is structured so as to mimic the file object interface. When a method such as read or write is called, we initialize a Crypto.Cipher.AES object using the class' _cipher property. This property is implemented as follows:

def _cipher():
    doc = doc = "Returns a stateful AES object ready to decrypt at the required \
                 stream position"

    def fget(self):
        ctr =,
                          initial_value=self.tell()  # alias of self._file.tell
                          prefix=self._nonce)  # set by `
        return, counter=ctr, mode=self._opmode)  # self._opmode = Crypto.Cipher.AES.MODE_CTR

    def fset(self, value):
        raise AttributeError('Cannot set _cipher')

    def fdel(self, value):
        raise AttributeError('Cannot delete _cipher')

    return locals()
        _cipher = property(**_cipher())

Here is an example of how the _cipher property is used to encrypt transparently during a call to the write method.

def write(self, data):
    if not isinstance(data, str):
        raise TypeError('Data must be str (or bytestring)')

When decrypting, we apply the opposite transaction as such:

def read(self, size=-1):
    return self._cipher.decrypt(

This works when making single calls to write, but fails when multiple calls to write are chained. For instance:

ep = EphemeralFile()  # the class in question
ep.write('Now is the winter of our discontent')

>> Now is the winter of our discontent

So far so good... but here's where it fails

ep.write(' made glorious summer by this sun of York')

>> Now is the winter of our discontent"d_"��U�L~ �w���S��h��]"U(��P^��9k

What am I doing wrong? Shouldn't the use of self._file.tell() in the _cipher property yield the appropriate counter position for decryption?

Please note that I first suspected that I might be off by one counter tick, so I tried modifying the initial_value=self.tell() line to initial_value=self.tell() + 1 (also tried with -1), but to no avail.

For convenience, here is the full class definition. It's fairly short and may yield some insight.

import tempfile

from Crypto.Cipher import AES
from Crypto import Random
from Crypto.Util import Counter


class EphemeralFile(object):
    def __init__(self, mode='w+b', bufsize=-1, suffix='', prefix='', dir=None,

        self._key =
        self._nonce =
        self._opmode = AES.MODE_CTR

        self._file = tempfile.TemporaryFile(mode=mode, bufsize=bufsize,
                                            suffix=suffix, prefix=prefix, dir=dir)

        # alias tempfile methods and parameters
        self.close = self._file.close
        self.closed = self._file.closed
        self.encoding = self._file.encoding
        self.errors = self._file.errors
        self.fileno = self._file.fileno
        self.flush = self._file.flush
        self.isatty = self._file.isatty
        self.mode = self._file.mode =
        self.softspace = self._file.softspace
        self.truncate = self._file.truncate =
        self.tell = self._file.tell

    def __enter__(self):
        return self

    def __exit__(self, type, value, traceback):

    def __iter__(self):
        return (line for line in self.readlines())

    def _cipher():
        doc = "Returns a stateful AES object ready to decrypt at the required \
               stream position"

        def fget(self):
            ctr =,
            return, counter=ctr, mode=self._opmode)

        def fset(self, value):
            raise AttributeError('Cannot set EphemeralFile._cipher')

        def fdel(self):
            raise AttributeError('Cannot delete EphemeralFile._cipher')

        return locals()
    _cipher = property(**_cipher())

    def write(self, data):
        if not isinstance(data, str):
            raise TypeError('Data must be str (or bytestring)')


    def writelines(self, lines):

    def read(self, size=-1):
        return self._cipher.decrypt(

    def readline(self, size=-1):
        fptr = self.tell()
        bytes = []
        got_line = False
        while not got_line:
            if not bytes[-1] or ('\n' in bytes[-1]):
                bytes[-1] = bytes[-1][0:bytes[-1].find('\n') + 1]
                got_line = True

        plaintext = ''.join(bytes) + len(plaintext))  # rewind
        return plaintext

    def readlines(self, size=-1):
        return [line for line in self]

    def read_ciphertext(self, size=-1):
        """Read ciphertext without decrypting.

        size : int (default -1)
            Number of bytes to read.  Negative values read the entire stream

        return : str

    def next(self):
        return self.readline()

At this point I really don't see where the problem is, so please feel free to nag me with questions and suggest possible solutions.

Many thanks in advance!

share|improve this question

I believe one problem is that the Counter object should receive as initial_value the AES block number, not the byte offset. In other words, you need to have:

ctr =,
                  initial_value=self.tell() % 16,

That's needed because in AES CTR mode you increase the value each time you cross the AES data boundary (16 bytes).

That also means that the correct sequence for any write operation roughly is:

  1. Start the cipher object as shown above - in encryption mode.
  2. Encrypt self.tell() % 16 bytes of any data and throw away the result.
  3. Encrypt the input data and write it to the file.

Similarly for reading:

  1. Start the cipher object as shown above - in decryption mode.
  2. Decrypt self.tell() % 16 bytes of any data and throw away the result.
  3. Decrypt the data read from the file.

From a quick look at the code, a second problem could also be that you use the same AES object for both encryption and decryption. You need two separate objects, one for each direction.

share|improve this answer
Hello! Thanks for your insightful answer! I'm still not clear on why I need to perform step 2 in both encryption and decryption -- doesn't the initial_value kwarg offset the counter? – blz Sep 4 '13 at 15:44
Also, I didn't get the impression that AES objects had encryption-specific or decryption-specific modes. My understanding was that encryption vs. decryption was determined based on the method being called (i.e., AES.encrypt vs. AES.decrypt). And besides, the property makes it so that a seperate AES object is obtained with each call to _cipher. Am I missing something? – blz Sep 4 '13 at 16:00
@blz It helps to look at the wikipedia diagram for CTR mode. Encryption is done by XOR-ing the input data with a sequence of 16 bytes blocks, called key stream. If you start encryption mid-block (as it may happen with most calls to write() other than the first) you must "fast-forward" a few bytes to reach the correct piece of the key stream. The initial_value selects the block number, not the offset within the block. – SquareRootOfTwentyThree Sep 4 '13 at 18:49
@blz I had a closer look at the code and indeed the second problem I mention is bogus. You indeed instantiate a block for every operation. – SquareRootOfTwentyThree Sep 4 '13 at 18:51

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.