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Which is the best way to parse with python a binary file with X509 Certificate in DER format to extract public key.

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3 Answers 3

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The above answers are somewhat old (as of 2017).

You can use asn1crypto to do this in a nicer way:

from asn1crypto.x509 import Certificate

with open("mycert.der", "rb") as f:
    cert = Certificate.load(f.read())

n = cert.public_key.native["public_key"]["modulus"]
e = cert.public_key.native["public_key"]["public_exponent"]

print("{:#x}".format(n))    # prints the modulus (hexadecimal)
print("{:#x}".format(e))    # same, for the public exponent

It's relatively new (from what I can see, mid-2015), provides a nicer interface than the libraries already mentioned, and is much faster than pyasn1 according to the author.

Update (2022-07-30): The cryptography package is another way to do it:

from cryptography import x509

with open("mycert.der", "rb") as f:
    cert = x509.load_der_x509_certificate(f.read())

modulus = cert.public_key().public_numbers().n
public_exponent = cert.public_key().public_numbers().e
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  • the modulus print command is throwing error as ValueError: Error parsing asn1crypto.x509.Certificate - tag should have been 16, but 13 was found Why is it so?
    – Bogota
    Jun 17, 2020 at 3:51
  • 1
    This can happen if you're trying to read a PEM-formatted certificate. The above code works with a DER-encoded one. (See here for more information on certificate formats.) Conversion from PEM to DER should be a matter of just stripping the header/footer and base64-decoding the middle part.
    – De117
    Jun 19, 2020 at 10:27
  • @Bogota It looks like the asn1cypto.pem module will do the conversion for you -- see this documentation page. If using cryptography.x509, there is the load_pem_x509_certificate function, which loads PEM-formatted certificates. asn1crypto.pem offers a detect function which lets you look before you leap, whereas with cryptography.x509 functions you just try one and then the other.
    – De117
    Jul 30, 2022 at 16:16
13

Neither the built-in SSL module of Python nor PyOpenSSL have an API to extract the private key and access its information. M2Crypto is no longer maintained and doesn't work with OpenSSL 1.0 and newer.

PyOpenSSL has a public key class but its features are limited:

>>> with open("cert.der", "rb") as f:
...     der = f.read()
... 
>>> import OpenSSL.crypto
>>> x509 = OpenSSL.crypto.load_certificate(OpenSSL.crypto.FILETYPE_ASN1, der)
>>> pkey = x509.get_pubkey()
>>> dir(pkey)
['__class__', '__delattr__', '__doc__', '__format__', '__getattribute__', '__hash__', '__init__', '__new__', '__reduce__', '__reduce_ex__', '__repr__', '__setattr__', '__sizeof__', '__str__', '__subclasshook__', 'bits', 'check', 'generate_key', 'type']
>>> pkey.bits()
4096L
>>> pkey.type() == OpenSSL.crypto.TYPE_RSA
True

Python 3.4 may get a X509 type that exposes more information like SPKI.

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  • exist any way to print pretty all the parsed certificated (just as pyasn1.printPretty()) or at least to print pubkey as hexstring.
    – David A
    Sep 15, 2013 at 3:07
5

It's been a long time since I asked this question, though due to the number of views, I would like to describe how I managed to make it worked.

By using the OpenSSL API, we can easily print the DER certificate in a pretty readable way. Even though its features are very limited, this is an example.

print OpenSSL.crypto.dump_certificate(OpenSSL.crypto.FILETYPE_TEXT,x509)

However, I wanted to have control over the keys in a var directly (it was needed to send it to other function), and in order to do that, I made the following function

def parse_asn1_der(derfile):
    from pyasn1_modules import  rfc2437,rfc2459
    from pyasn1.codec.der import decoder
    certType = rfc2459.Certificate(); 
    raw=derfile #the result of open(fname,"rb").read()
    cert,rest = decoder.decode(raw, asn1Spec=certType)
    RSAKEYSDATA=frombits(cert.getComponentByName("tbsCertificate").getComponentByName("subjectPublicKeyInfo").getComponentByName("subjectPublicKey"))
    SignatureCert=frombits(cert.getComponentByName("signatureValue")).encode("hex")
    rsaType=rfc2437.RSAPublicKey();
    rsadata,rsadata_rest = decoder.decode(RSAKEYSDATA, asn1Spec=rsaType)
    print "----"
    print "Certificate Plain Data"
    print "RSA Modulus: %X" %rsadata.getComponentByName("modulus")
    print "RSA Public exponent: %X" %rsadata.getComponentByName("publicExponent")
    print "Signature: %s"%SignatureCert
    return rsadata.getComponentByName("modulus")

Hope it helps anyone looking around.

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