Currently I have some code that signs a byte string with the SHA256 algorithm using the native OpenSSL binary, the code calls an external process, sends the parameters, and receive the result back into the Python code.

The current code is as follows:

signed_digest_proc = subprocess.Popen(
    ['openssl', 'dgst', '-sha256', '-sign', tmp_path],
signed_digest, _ = signed_digest_proc.communicate()

base64.encodestring(signed_digest).decode().replace('\n', '')

When original_string is too big, I might have problems with the result (from the communication with an external process I think), that's why I'm trying to change it to a Python only solution:

import hmac, hashlib
h = hmac.new(bytes(key_pem(), 'ASCII'), original_string, hashlib.sha256)
result = base64.encodestring(h).decode().replace('\n', '')

This result in a completely different string than the first one.

What would be the way to implement the original code without calling an external process?

  • 2
    You are doing two things with openssl, neither of which use an HMAC signature. You are producing a regular SHA256 digest, and then you also sign the digest. – Martijn Pieters Mar 5 '18 at 18:01
  • 2
    To sign, look at the cryptography package, and pick one of the algorithms, based on the private key type you have (DSA, RSA, ..). Then read the Signing section. E.g. for RSA there is documentation on how to sign a message. – Martijn Pieters Mar 5 '18 at 18:12

The openssl command you used does three things:

  • Create a hash of the data, using SHA256
  • If RSA is used, pad out the message to a specific length, using PKCS#1 1.5
  • Sign the (padded) hash, using the private key you provided. It'll depend on the type of key what algorithm was used.

The hmac module does not serve the same function.

You'll need to install a cryptography package like cryptography to replicate what openssl dgst -sign does. cryptography uses OpenSSL as a backend, so it will produce the same output.

You can then

  • load the key with the load_pem_private_key() function. This returns the right type of object for the algorithm used.
  • use the key to sign the message; each key type has a sign() method, and this method will take care of hashing the message for you if you so wish. See for example the Signing section for RSA.

    However, you'll need to provide different kinds of config for the different .sign() methods. Only the RSA, DSA and Elliptic Curve keys can be used to create a signed digest.

You'll have to switch between the types to get the signature right:

from cryptography.hazmat.backends import default_backend
from cryptography.hazmat.primitives import hashes
from cryptography.hazmat.primitives.asymmetric import dsa, ec, rsa, utils
from cryptography.hazmat.primitives import serialization
from cryptography.hazmat.primitives.asymmetric import padding

# configuration per key type, each lambda takes a hashing algorithm
_signing_configs = (
    (dsa.DSAPrivateKey, lambda h: {
        'algorithm': h}),
    (ec.EllipticCurvePrivateKey, lambda h: {
        'signature_algorithm': ec.ECDSA(h)}),
    (rsa.RSAPrivateKey, lambda h: {
        'padding': padding.PKCS1v15(),
        'algorithm': h

def _key_singing_config(key, hashing_algorithm):
        factory = next(
            for type_, config in _signing_configs
            if isinstance(key, type_)
    except StopIteration:
        raise ValueError('Unsupported key type {!r}'.format(type(key)))
    return factory(hashing_algorithm)

def sign(private_key, data, algorithm=hashes.SHA256()):
    with open(private_key, 'rb') as private_key:
        key = serialization.load_pem_private_key(
            private_key.read(), None, default_backend())

    return key.sign(data, **_key_singing_config(key, algorithm))

If you need to hash a large amount of data, you can hash the data yourself first, in chunks, before passing in just the digest and the special util.Prehashed() object:

def sign_streaming(private_key, data_iterable, algorithm=hashes.SHA256()):
    with open(private_key, 'rb') as private_key:
        key = serialization.load_pem_private_key(
            private_key.read(), None, default_backend())

    hasher = hashes.Hash(algorithm, default_backend())
    for chunk in data_iterable:
    digest = hasher.finalize()
    prehashed = utils.Prehashed(algorithm)

    return key.sign(digest, **_key_singing_config(key, prehashed))

with open(large_file, 'rb') as large_file:
    signature = sign_streaming(private_key_file, iter(lambda: large_file.read(2 ** 16), b''))

This uses the iter() function to read data from a binary file in chunks of 64 kilobytes.

Demo; I'm using an RSA key I generated in /tmp/test_rsa.pem. Using the command-line to produce a signed digest for Hello world!:

$ echo -n 'Hello world!' | openssl dgst -sign /tmp/test_rsa.pem -sha256 | openssl base64

or using the Python code:

>>> signature = sign(keyfile, b'Hello world!')
>>> import base64
>>> print(base64.encodebytes(signature).decode())

Although the line lengths differ, the base64 data the two output is clearly the same.

Or, using a generated file with random binary data, size 32kb:

$ dd if=/dev/urandom of=/tmp/random_data.bin bs=16k count=2
2+0 records in
2+0 records out
32768 bytes transferred in 0.002227 secs (14713516 bytes/sec)
$ cat /tmp/random_data.bin | openssl dgst -sign /tmp/test_rsa.pem -sha256 | openssl base64

Processing the same file in Python:

>>> with open('/tmp/random_data.bin', 'rb') as random_data:
...     signature = sign_streaming('/tmp/test_rsa.pem', iter(lambda: random_data.read(2 ** 16), b''))
>>> print(base64.encodebytes(signature).decode())
  • Thank you, your example code made it very clear and now I'm getting the same results as the original OpenSSL implementation. – Luis Alberto Santana Mar 5 '18 at 23:43

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

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