Mercurial > libervia-backend
view sat/memory/crypto.py @ 3372:5d926c7b0d99
plugin app manager: first draft:
/!\ new optional dependency: pyyaml
this plugin manage the life cycle of external applications. Application handlers register
to it.
Data needed to launch an application as set in YAML files. Local data types are used to
get values directly from SàT:
- !sat_conf to retrieve a configuration value
- !sat_generate_pwd to generate a password
- !sat_param for parameters specified a launch
Data can be exposed when an instance is launched, this can be used to specify the port
(notably the one used for web), or a generated password.
author | Goffi <goffi@goffi.org> |
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date | Mon, 28 Sep 2020 21:10:30 +0200 |
parents | 330a5f1d9eea |
children | be6d91572633 |
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#!/usr/bin/env python3 # SAT: a jabber client # Copyright (C) 2009-2020 Jérôme Poisson (goffi@goffi.org) # Copyright (C) 2013-2016 Adrien Cossa (souliane@mailoo.org) # This program is free software: you can redistribute it and/or modify # it under the terms of the GNU Affero General Public License as published by # the Free Software Foundation, either version 3 of the License, or # (at your option) any later version. # This program is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the # GNU Affero General Public License for more details. # You should have received a copy of the GNU Affero General Public License # along with this program. If not, see <http://www.gnu.org/licenses/>. from os import urandom from base64 import b64encode, b64decode from cryptography.hazmat.primitives import hashes from cryptography.hazmat.primitives.kdf.pbkdf2 import PBKDF2HMAC from cryptography.hazmat.primitives.ciphers import Cipher, algorithms, modes from cryptography.hazmat.backends import default_backend crypto_backend = default_backend() class BlockCipher: BLOCK_SIZE = 16 MAX_KEY_SIZE = 32 IV_SIZE = BLOCK_SIZE # initialization vector size, 16 bits @staticmethod def encrypt(key, text, leave_empty=True): """Encrypt a message. Based on http://stackoverflow.com/a/12525165 @param key (unicode): the encryption key @param text (unicode): the text to encrypt @param leave_empty (bool): if True, empty text will be returned "as is" @return (D(str)): base-64 encoded encrypted message """ if leave_empty and text == "": return "" iv = BlockCipher.getRandomKey() key = key.encode() key = ( key[: BlockCipher.MAX_KEY_SIZE] if len(key) >= BlockCipher.MAX_KEY_SIZE else BlockCipher.pad(key) ) cipher = Cipher(algorithms.AES(key), modes.CFB8(iv), backend=crypto_backend) encryptor = cipher.encryptor() encrypted = encryptor.update(BlockCipher.pad(text.encode())) + encryptor.finalize() return b64encode(iv + encrypted).decode() @staticmethod def decrypt(key, ciphertext, leave_empty=True): """Decrypt a message. Based on http://stackoverflow.com/a/12525165 @param key (unicode): the decryption key @param ciphertext (base-64 encoded str): the text to decrypt @param leave_empty (bool): if True, empty ciphertext will be returned "as is" @return: Deferred: str or None if the password could not be decrypted """ if leave_empty and ciphertext == "": return "" ciphertext = b64decode(ciphertext) iv, ciphertext = ( ciphertext[: BlockCipher.IV_SIZE], ciphertext[BlockCipher.IV_SIZE :], ) key = key.encode() key = ( key[: BlockCipher.MAX_KEY_SIZE] if len(key) >= BlockCipher.MAX_KEY_SIZE else BlockCipher.pad(key) ) cipher = Cipher(algorithms.AES(key), modes.CFB8(iv), backend=crypto_backend) decryptor = cipher.decryptor() decrypted = decryptor.update(ciphertext) + decryptor.finalize() return BlockCipher.unpad(decrypted) @staticmethod def getRandomKey(size=None, base64=False): """Return a random key suitable for block cipher encryption. Note: a good value for the key length is to make it as long as the block size. @param size: key length in bytes, positive or null (default: BlockCipher.IV_SIZE) @param base64: if True, encode the result to base-64 @return: str (eventually base-64 encoded) """ if size is None or size < 0: size = BlockCipher.IV_SIZE key = urandom(size) return b64encode(key) if base64 else key @staticmethod def pad(s): """Method from http://stackoverflow.com/a/12525165""" bs = BlockCipher.BLOCK_SIZE return s + (bs - len(s) % bs) * (chr(bs - len(s) % bs)).encode() @staticmethod def unpad(s): """Method from http://stackoverflow.com/a/12525165""" s = s.decode() return s[0 : -ord(s[-1])] class PasswordHasher: SALT_LEN = 16 # 128 bits @staticmethod def hash(password, salt=None, leave_empty=True): """Hash a password. @param password (str): the password to hash @param salt (base-64 encoded str): if not None, use the given salt instead of a random value @param leave_empty (bool): if True, empty password will be returned "as is" @return: Deferred: base-64 encoded str """ if leave_empty and password == "": return "" salt = ( b64decode(salt)[: PasswordHasher.SALT_LEN] if salt else urandom(PasswordHasher.SALT_LEN) ) # we use PyCrypto's PBKDF2 arguments while porting to crytography, to stay # compatible with existing installations. But this is temporary and we need # to update them to more secure values. kdf = PBKDF2HMAC( # FIXME: SHA1() is not secure, it is used here for historical reasons # and must be changed as soon as possible algorithm=hashes.SHA1(), length=16, salt=salt, iterations=1000, backend=crypto_backend ) key = kdf.derive(password.encode()) return b64encode(salt + key).decode() @staticmethod def verify(attempt, pwd_hash): """Verify a password attempt. @param attempt (str): the attempt to check @param pwd_hash (str): the hash of the password @return: Deferred: boolean """ assert isinstance(attempt, str) assert isinstance(pwd_hash, str) leave_empty = pwd_hash == "" attempt_hash = PasswordHasher.hash(attempt, pwd_hash, leave_empty) assert isinstance(attempt_hash, str) return attempt_hash == pwd_hash