community.general/lib/ansible/modules/crypto/openssl_privatekey.py

#!/usr/bin/python
# -*- coding: utf-8 -*-

# Copyright: (c) 2016, Yanis Guenane <yanis+ansible@guenane.org>
# GNU General Public License v3.0+ (see COPYING or https://www.gnu.org/licenses/gpl-3.0.txt)

from __future__ import absolute_import, division, print_function
__metaclass__ = type

ANSIBLE_METADATA = {'metadata_version': '1.1',
                    'status': ['preview'],
                    'supported_by': 'community'}

DOCUMENTATION = r'''
---
module: openssl_privatekey
version_added: "2.3"
short_description: Generate OpenSSL private keys
description:
    - This module allows one to (re)generate OpenSSL private keys.
    - One can generate L(RSA,https://en.wikipedia.org/wiki/RSA_(cryptosystem)),
      L(DSA,https://en.wikipedia.org/wiki/Digital_Signature_Algorithm) or
      L(ECC,https://en.wikipedia.org/wiki/Elliptic-curve_cryptography)
      private keys.
    - Keys are generated in PEM format.
    - The module can use the cryptography Python library, or the pyOpenSSL Python
      library. By default, it tries to detect which one is available. This can be
      overridden with the I(select_crypto_backend) option."
requirements:
    - Either cryptography >= 1.2.3 (older versions might work as well)
    - Or pyOpenSSL
author:
    - Yanis Guenane (@Spredzy)
    - Felix Fontein (@felixfontein)
options:
    state:
        description:
            - Whether the private key should exist or not, taking action if the state is different from what is stated.
        type: str
        default: present
        choices: [ absent, present ]
    size:
        description:
            - Size (in bits) of the TLS/SSL key to generate.
        type: int
        default: 4096
    type:
        description:
            - The algorithm used to generate the TLS/SSL private key.
            - Note that C(ECC) requires the C(cryptography) backend.
            - Depending on the curve, you need a newer version of the cryptography backend.
        type: str
        default: RSA
        #choices: [ DSA, ECC, RSA, X448, X25519 ]
        choices: [ DSA, ECC, RSA ]
    curve:
        description:
            - Note that not all curves are supported by all versions of C(cryptography).
            - For maximal interoperability, C(secp384r1) or C(secp256k1) should be used.
            - We use the curve names as defined in the
              L(IANA registry for TLS,https://www.iana.org/assignments/tls-parameters/tls-parameters.xhtml#tls-parameters-8).
        type: str
        choices:
            - secp384r1
            - secp521r1
            - secp224r1
            - secp192r1
            - secp256k1
            - brainpoolP256r1
            - brainpoolP384r1
            - brainpoolP512r1
            - sect571k1
            - sect409k1
            - sect283k1
            - sect233k1
            - sect163k1
            - sect571r1
            - sect409r1
            - sect283r1
            - sect233r1
            - sect163r2
        version_added: "2.8"
    force:
        description:
            - Should the key be regenerated even if it already exists.
        type: bool
        default: no
    path:
        description:
            - Name of the file in which the generated TLS/SSL private key will be written. It will have 0600 mode.
        type: path
        required: true
    passphrase:
        description:
            - The passphrase for the private key.
        type: str
        version_added: "2.4"
    cipher:
        description:
            - The cipher to encrypt the private key. (cipher can be found by running `openssl list-cipher-algorithms`)
            - When using the C(cryptography) backend, use C(auto).
        type: str
        version_added: "2.4"
    select_crypto_backend:
        description:
            - Determines which crypto backend to use.
            - The default choice is C(auto), which tries to use C(cryptography) if available, and falls back to C(pyopenssl).
            - If set to C(pyopenssl), will try to use the L(pyOpenSSL,https://pypi.org/project/pyOpenSSL/) library.
            - If set to C(cryptography), will try to use the L(cryptography,https://cryptography.io/) library.
        type: str
        default: auto
        choices: [ auto, cryptography, pyopenssl ]
        version_added: "2.8"
extends_documentation_fragment:
- files
seealso:
- module: openssl_certificate
- module: openssl_csr
- module: openssl_dhparam
- module: openssl_pkcs12
- module: openssl_publickey
'''

EXAMPLES = r'''
- name: Generate an OpenSSL private key with the default values (4096 bits, RSA)
  openssl_privatekey:
    path: /etc/ssl/private/ansible.com.pem

- name: Generate an OpenSSL private key with the default values (4096 bits, RSA) and a passphrase
  openssl_privatekey:
    path: /etc/ssl/private/ansible.com.pem
    passphrase: ansible
    cipher: aes256

- name: Generate an OpenSSL private key with a different size (2048 bits)
  openssl_privatekey:
    path: /etc/ssl/private/ansible.com.pem
    size: 2048

- name: Force regenerate an OpenSSL private key if it already exists
  openssl_privatekey:
    path: /etc/ssl/private/ansible.com.pem
    force: yes

- name: Generate an OpenSSL private key with a different algorithm (DSA)
  openssl_privatekey:
    path: /etc/ssl/private/ansible.com.pem
    type: DSA
'''

RETURN = r'''
size:
    description: Size (in bits) of the TLS/SSL private key.
    returned: changed or success
    type: int
    sample: 4096
type:
    description: Algorithm used to generate the TLS/SSL private key.
    returned: changed or success
    type: str
    sample: RSA
curve:
    description: Elliptic curve used to generate the TLS/SSL private key.
    returned: changed or success, and I(type) is C(ECC)
    type: str
    sample: secp256k1
filename:
    description: Path to the generated TLS/SSL private key file.
    returned: changed or success
    type: str
    sample: /etc/ssl/private/ansible.com.pem
fingerprint:
    description:
    - The fingerprint of the public key. Fingerprint will be generated for each C(hashlib.algorithms) available.
    - The PyOpenSSL backend requires PyOpenSSL >= 16.0 for meaningful output.
    returned: changed or success
    type: dict
    sample:
      md5: "84:75:71:72:8d:04:b5:6c:4d:37:6d:66:83:f5:4c:29"
      sha1: "51:cc:7c:68:5d:eb:41:43:88:7e:1a:ae:c7:f8:24:72:ee:71:f6:10"
      sha224: "b1:19:a6:6c:14:ac:33:1d:ed:18:50:d3:06:5c:b2:32:91:f1:f1:52:8c:cb:d5:75:e9:f5:9b:46"
      sha256: "41:ab:c7:cb:d5:5f:30:60:46:99:ac:d4:00:70:cf:a1:76:4f:24:5d:10:24:57:5d:51:6e:09:97:df:2f:de:c7"
      sha384: "85:39:50:4e:de:d9:19:33:40:70:ae:10:ab:59:24:19:51:c3:a2:e4:0b:1c:b1:6e:dd:b3:0c:d9:9e:6a:46:af:da:18:f8:ef:ae:2e:c0:9a:75:2c:9b:b3:0f:3a:5f:3d"
      sha512: "fd:ed:5e:39:48:5f:9f:fe:7f:25:06:3f:79:08:cd:ee:a5:e7:b3:3d:13:82:87:1f:84:e1:f5:c7:28:77:53:94:86:56:38:69:f0:d9:35:22:01:1e:a6:60:...:0f:9b"
'''

import abc
import os
import traceback
from distutils.version import LooseVersion

MINIMAL_PYOPENSSL_VERSION = '0.6'
MINIMAL_CRYPTOGRAPHY_VERSION = '1.2.3'

PYOPENSSL_IMP_ERR = None
try:
    import OpenSSL
    from OpenSSL import crypto
    PYOPENSSL_VERSION = LooseVersion(OpenSSL.__version__)
except ImportError:
    PYOPENSSL_IMP_ERR = traceback.format_exc()
    PYOPENSSL_FOUND = False
else:
    PYOPENSSL_FOUND = True

CRYPTOGRAPHY_IMP_ERR = None
try:
    import cryptography
    import cryptography.exceptions
    import cryptography.hazmat.backends
    import cryptography.hazmat.primitives.serialization
    import cryptography.hazmat.primitives.asymmetric.rsa
    import cryptography.hazmat.primitives.asymmetric.dsa
    import cryptography.hazmat.primitives.asymmetric.ec
    import cryptography.hazmat.primitives.asymmetric.utils
    CRYPTOGRAPHY_VERSION = LooseVersion(cryptography.__version__)
except ImportError:
    CRYPTOGRAPHY_IMP_ERR = traceback.format_exc()
    CRYPTOGRAPHY_FOUND = False
else:
    CRYPTOGRAPHY_FOUND = True
    try:
        import cryptography.hazmat.primitives.asymmetric.x25519
        CRYPTOGRAPHY_HAS_X25519 = True
    except ImportError:
        CRYPTOGRAPHY_HAS_X25519 = False
    try:
        import cryptography.hazmat.primitives.asymmetric.x448
        CRYPTOGRAPHY_HAS_X448 = True
    except ImportError:
        CRYPTOGRAPHY_HAS_X448 = False

from ansible.module_utils import crypto as crypto_utils
from ansible.module_utils._text import to_native, to_bytes
from ansible.module_utils.basic import AnsibleModule, missing_required_lib
from ansible.module_utils.six import string_types


class PrivateKeyError(crypto_utils.OpenSSLObjectError):
    pass


class PrivateKeyBase(crypto_utils.OpenSSLObject):

    def __init__(self, module):
        super(PrivateKeyBase, self).__init__(
            module.params['path'],
            module.params['state'],
            module.params['force'],
            module.check_mode
        )
        self.size = module.params['size']
        self.passphrase = module.params['passphrase']
        self.cipher = module.params['cipher']
        self.privatekey = None
        self.fingerprint = {}

        self.mode = module.params.get('mode', None)
        if self.mode is None:
            self.mode = 0o600

    @abc.abstractmethod
    def _generate_private_key_data(self):
        pass

    @abc.abstractmethod
    def _get_fingerprint(self):
        pass

    def generate(self, module):
        """Generate a keypair."""

        if not self.check(module, perms_required=False) or self.force:
            privatekey_data = self._generate_private_key_data()
            try:
                privatekey_file = os.open(self.path, os.O_WRONLY | os.O_CREAT | os.O_TRUNC)
                os.close(privatekey_file)
                if isinstance(self.mode, string_types):
                    try:
                        self.mode = int(self.mode, 8)
                    except ValueError as e:
                        try:
                            st = os.lstat(self.path)
                            self.mode = AnsibleModule._symbolic_mode_to_octal(st, self.mode)
                        except ValueError as e:
                            module.fail_json(msg="%s" % to_native(e), exception=traceback.format_exc())
                os.chmod(self.path, self.mode)
                privatekey_file = os.open(self.path, os.O_WRONLY | os.O_CREAT | os.O_TRUNC, self.mode)
                os.write(privatekey_file, privatekey_data)
                os.close(privatekey_file)
                self.changed = True
            except IOError as exc:
                self.remove()
                raise PrivateKeyError(exc)

        self.fingerprint = self._get_fingerprint()
        file_args = module.load_file_common_arguments(module.params)
        if module.set_fs_attributes_if_different(file_args, False):
            self.changed = True

    @abc.abstractmethod
    def _check_passphrase(self):
        pass

    @abc.abstractmethod
    def _check_size_and_type(self):
        pass

    def check(self, module, perms_required=True):
        """Ensure the resource is in its desired state."""

        state_and_perms = super(PrivateKeyBase, self).check(module, perms_required)

        if not state_and_perms or not self._check_passphrase():
            return False

        return self._check_size_and_type()

    def dump(self):
        """Serialize the object into a dictionary."""

        result = {
            'size': self.size,
            'filename': self.path,
            'changed': self.changed,
            'fingerprint': self.fingerprint,
        }

        return result


# Implementation with using pyOpenSSL
class PrivateKeyPyOpenSSL(PrivateKeyBase):

    def __init__(self, module):
        super(PrivateKeyPyOpenSSL, self).__init__(module)

        if module.params['type'] == 'RSA':
            self.type = crypto.TYPE_RSA
        elif module.params['type'] == 'DSA':
            self.type = crypto.TYPE_DSA
        else:
            module.fail_json(msg="PyOpenSSL backend only supports RSA and DSA keys.")

    def _generate_private_key_data(self):
        self.privatekey = crypto.PKey()

        try:
            self.privatekey.generate_key(self.type, self.size)
        except (TypeError, ValueError) as exc:
            raise PrivateKeyError(exc)

        if self.cipher and self.passphrase:
            return crypto.dump_privatekey(crypto.FILETYPE_PEM, self.privatekey,
                                          self.cipher, to_bytes(self.passphrase))
        else:
            return crypto.dump_privatekey(crypto.FILETYPE_PEM, self.privatekey)

    def _get_fingerprint(self):
        return crypto_utils.get_fingerprint(self.path, self.passphrase)

    def _check_passphrase(self):
        try:
            crypto_utils.load_privatekey(self.path, self.passphrase)
            return True
        except crypto.Error:
            return False

    def _check_size_and_type(self):
        def _check_size(privatekey):
            return self.size == privatekey.bits()

        def _check_type(privatekey):
            return self.type == privatekey.type()

        privatekey = crypto_utils.load_privatekey(self.path, self.passphrase)

        return _check_size(privatekey) and _check_type(privatekey)

    def dump(self):
        """Serialize the object into a dictionary."""

        result = super(PrivateKeyPyOpenSSL, self).dump()

        if self.type == crypto.TYPE_RSA:
            result['type'] = 'RSA'
        else:
            result['type'] = 'DSA'

        return result


# Implementation with using cryptography
class PrivateKeyCryptography(PrivateKeyBase):

    def _get_ec_class(self, ectype):
        ecclass = cryptography.hazmat.primitives.asymmetric.ec.__dict__.get(ectype)
        if ecclass is None:
            self.module.fail_json(msg='Your cryptography version does not support {0}'.format(ectype))
        return ecclass

    def _add_curve(self, name, ectype, deprecated=False):
        def create(size):
            ecclass = self._get_ec_class(ectype)
            return ecclass()

        def verify(privatekey):
            ecclass = self._get_ec_class(ectype)
            return isinstance(privatekey.private_numbers().public_numbers.curve, ecclass)

        self.curves[name] = {
            'create': create,
            'verify': verify,
            'deprecated': deprecated,
        }

    def __init__(self, module):
        super(PrivateKeyCryptography, self).__init__(module)

        self.curves = dict()
        self._add_curve('secp384r1', 'SECP384R1')
        self._add_curve('secp521r1', 'SECP521R1')
        self._add_curve('secp224r1', 'SECP224R1')
        self._add_curve('secp192r1', 'SECP192R1')
        self._add_curve('secp256k1', 'SECP256K1')
        self._add_curve('brainpoolP256r1', 'BrainpoolP256R1', deprecated=True)
        self._add_curve('brainpoolP384r1', 'BrainpoolP384R1', deprecated=True)
        self._add_curve('brainpoolP512r1', 'BrainpoolP512R1', deprecated=True)
        self._add_curve('sect571k1', 'SECT571K1', deprecated=True)
        self._add_curve('sect409k1', 'SECT409K1', deprecated=True)
        self._add_curve('sect283k1', 'SECT283K1', deprecated=True)
        self._add_curve('sect233k1', 'SECT233K1', deprecated=True)
        self._add_curve('sect163k1', 'SECT163K1', deprecated=True)
        self._add_curve('sect571r1', 'SECT571R1', deprecated=True)
        self._add_curve('sect409r1', 'SECT409R1', deprecated=True)
        self._add_curve('sect283r1', 'SECT283R1', deprecated=True)
        self._add_curve('sect233r1', 'SECT233R1', deprecated=True)
        self._add_curve('sect163r2', 'SECT163R2', deprecated=True)

        self.module = module
        self.cryptography_backend = cryptography.hazmat.backends.default_backend()

        self.type = module.params['type']
        self.curve = module.params['curve']
        if not CRYPTOGRAPHY_HAS_X25519 and self.type == 'X25519':
            self.module.fail_json(msg='Your cryptography version does not support X25519')
        if not CRYPTOGRAPHY_HAS_X448 and self.type == 'X448':
            self.module.fail_json(msg='Your cryptography version does not support X448')

    def _generate_private_key_data(self):
        try:
            if self.type == 'RSA':
                self.privatekey = cryptography.hazmat.primitives.asymmetric.rsa.generate_private_key(
                    public_exponent=65537,  # OpenSSL always uses this
                    key_size=self.size,
                    backend=self.cryptography_backend
                )
            if self.type == 'DSA':
                self.privatekey = cryptography.hazmat.primitives.asymmetric.dsa.generate_private_key(
                    key_size=self.size,
                    backend=self.cryptography_backend
                )
            if CRYPTOGRAPHY_HAS_X25519 and self.type == 'X25519':
                self.privatekey = cryptography.hazmat.primitives.asymmetric.x25519.X25519PrivateKey.generate()
            if CRYPTOGRAPHY_HAS_X448 and self.type == 'X448':
                self.privatekey = cryptography.hazmat.primitives.asymmetric.x448.X448PrivateKey.generate()
            if self.type == 'ECC' and self.curve in self.curves:
                if self.curves[self.curve]['deprecated']:
                    self.module.warn('Elliptic curves of type {0} should not be used for new keys!'.format(self.curve))
                self.privatekey = cryptography.hazmat.primitives.asymmetric.ec.generate_private_key(
                    curve=self.curves[self.curve]['create'](self.size),
                    backend=self.cryptography_backend
                )
        except cryptography.exceptions.UnsupportedAlgorithm as e:
            self.module.fail_json(msg='Cryptography backend does not support the algorithm required for {0}'.format(self.type))

        # Select key encryption
        encryption_algorithm = cryptography.hazmat.primitives.serialization.NoEncryption()
        if self.cipher and self.passphrase:
            if self.cipher == 'auto':
                encryption_algorithm = cryptography.hazmat.primitives.serialization.BestAvailableEncryption(to_bytes(self.passphrase))
            else:
                self.module.fail_json(msg='Cryptography backend can only use "auto" for cipher option.')

        # Serialize key
        return self.privatekey.private_bytes(
            encoding=cryptography.hazmat.primitives.serialization.Encoding.PEM,
            format=cryptography.hazmat.primitives.serialization.PrivateFormat.TraditionalOpenSSL,
            encryption_algorithm=encryption_algorithm
        )

    def _load_privatekey(self):
        try:
            with open(self.path, 'rb') as f:
                return cryptography.hazmat.primitives.serialization.load_pem_private_key(
                    f.read(),
                    None if self.passphrase is None else to_bytes(self.passphrase),
                    backend=self.cryptography_backend
                )
        except Exception as e:
            raise PrivateKeyError(e)

    def _get_fingerprint(self):
        # Get bytes of public key
        private_key = self._load_privatekey()
        public_key = private_key.public_key()
        public_key_bytes = public_key.public_bytes(
            cryptography.hazmat.primitives.serialization.Encoding.DER,
            cryptography.hazmat.primitives.serialization.PublicFormat.SubjectPublicKeyInfo
        )
        # Get fingerprints of public_key_bytes
        return crypto_utils.get_fingerprint_of_bytes(public_key_bytes)

    def _check_passphrase(self):
        try:
            self._load_privatekey()
            return True
        except crypto.Error:
            return False

    def _check_size_and_type(self):
        privatekey = self._load_privatekey()

        if isinstance(privatekey, cryptography.hazmat.primitives.asymmetric.rsa.RSAPrivateKey):
            return self.type == 'RSA' and self.size == privatekey.key_size
        if isinstance(privatekey, cryptography.hazmat.primitives.asymmetric.dsa.DSAPrivateKey):
            return self.type == 'DSA' and self.size == privatekey.key_size
        if CRYPTOGRAPHY_HAS_X25519 and isinstance(privatekey, cryptography.hazmat.primitives.asymmetric.x25519.X25519PrivateKey):
            return self.type == 'X25519'
        if CRYPTOGRAPHY_HAS_X448 and isinstance(privatekey, cryptography.hazmat.primitives.asymmetric.x448.X448PrivateKey):
            return self.type == 'X448'
        if isinstance(privatekey, cryptography.hazmat.primitives.asymmetric.ec.EllipticCurvePrivateKey):
            if self.type != 'ECC':
                return False
            if self.curve not in self.curves:
                return False
            return self.curves[self.curve]['verify'](privatekey)

        return False

    def dump(self):
        """Serialize the object into a dictionary."""
        result = super(PrivateKeyCryptography, self).dump()
        result['type'] = self.type
        if self.type == 'ECC':
            result['curve'] = self.curve
        return result


def main():

    module = AnsibleModule(
        argument_spec=dict(
            state=dict(type='str', default='present', choices=['present', 'absent']),
            size=dict(type='int', default=4096),
            type=dict(type='str', default='RSA', choices=[
                'RSA', 'DSA', 'ECC',
                # x25519 is missing serialization functions: https://github.com/pyca/cryptography/issues/4386
                # x448 is also missing it: https://github.com/pyca/cryptography/pull/4580#issuecomment-437913340
                # 'X448', 'X25519',
            ]),
            curve=dict(type='str', choices=[
                'secp384r1', 'secp521r1', 'secp224r1', 'secp192r1', 'secp256k1',
                'brainpoolP256r1', 'brainpoolP384r1', 'brainpoolP512r1',
                'sect571k1', 'sect409k1', 'sect283k1', 'sect233k1', 'sect163k1',
                'sect571r1', 'sect409r1', 'sect283r1', 'sect233r1', 'sect163r2',
            ]),
            force=dict(type='bool', default=False),
            path=dict(type='path', required=True),
            passphrase=dict(type='str', no_log=True),
            cipher=dict(type='str'),
            select_crypto_backend=dict(type='str', choices=['auto', 'pyopenssl', 'cryptography'], default='auto'),
        ),
        supports_check_mode=True,
        add_file_common_args=True,
        required_together=[
            ['cipher', 'passphrase']
        ],
        required_if=[
            ['type', 'ECC', ['curve']],
        ],
    )

    base_dir = os.path.dirname(module.params['path']) or '.'
    if not os.path.isdir(base_dir):
        module.fail_json(
            name=base_dir,
            msg='The directory %s does not exist or the file is not a directory' % base_dir
        )

    backend = module.params['select_crypto_backend']
    if backend == 'auto':
        # Detection what is possible
        can_use_cryptography = CRYPTOGRAPHY_FOUND and CRYPTOGRAPHY_VERSION >= LooseVersion(MINIMAL_CRYPTOGRAPHY_VERSION)
        can_use_pyopenssl = PYOPENSSL_FOUND and PYOPENSSL_VERSION >= LooseVersion(MINIMAL_PYOPENSSL_VERSION)

        # Decision
        if module.params['cipher'] and module.params['passphrase'] and module.params['cipher'] != 'auto':
            # First try pyOpenSSL, then cryptography
            if can_use_pyopenssl:
                backend = 'pyopenssl'
            elif can_use_cryptography:
                backend = 'cryptography'
        else:
            # First try cryptography, then pyOpenSSL
            if can_use_cryptography:
                backend = 'cryptography'
            elif can_use_pyopenssl:
                backend = 'pyopenssl'

        # Success?
        if backend == 'auto':
            module.fail_json(msg=('Can detect none of the Python libraries '
                                  'cryptography (>= {0}) and pyOpenSSL (>= {1})').format(
                                      MINIMAL_CRYPTOGRAPHY_VERSION,
                                      MINIMAL_PYOPENSSL_VERSION))
    if backend == 'pyopenssl':
        if not PYOPENSSL_FOUND:
            module.fail_json(msg=missing_required_lib('pyOpenSSL'), exception=PYOPENSSL_IMP_ERR)
        private_key = PrivateKeyPyOpenSSL(module)
    elif backend == 'cryptography':
        if not CRYPTOGRAPHY_FOUND:
            module.fail_json(msg=missing_required_lib('cryptography'), exception=CRYPTOGRAPHY_IMP_ERR)
        private_key = PrivateKeyCryptography(module)

    if private_key.state == 'present':

        if module.check_mode:
            result = private_key.dump()
            result['changed'] = module.params['force'] or not private_key.check(module)
            module.exit_json(**result)

        try:
            private_key.generate(module)
        except PrivateKeyError as exc:
            module.fail_json(msg=to_native(exc))
    else:

        if module.check_mode:
            result = private_key.dump()
            result['changed'] = os.path.exists(module.params['path'])
            module.exit_json(**result)

        try:
            private_key.remove()
        except PrivateKeyError as exc:
            module.fail_json(msg=to_native(exc))

    result = private_key.dump()

    module.exit_json(**result)


if __name__ == '__main__':
    main()