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# Copyright (C) 2014-2023 RhodeCode GmbH
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#
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# This program is free software: you can redistribute it and/or modify
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# it under the terms of the GNU Affero General Public License, version 3
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# (only), as published by the Free Software Foundation.
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#
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# This program is distributed in the hope that it will be useful,
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# but WITHOUT ANY WARRANTY; without even the implied warranty of
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# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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# GNU General Public License for more details.
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#
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# You should have received a copy of the GNU Affero General Public License
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# along with this program. If not, see <http://www.gnu.org/licenses/>.
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#
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# This program is dual-licensed. If you wish to learn more about the
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# RhodeCode Enterprise Edition, including its added features, Support services,
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# and proprietary license terms, please see https://rhodecode.com/licenses/
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"""
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Generic encryption library for RhodeCode
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"""
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import base64
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import logging
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from Crypto.Cipher import AES
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from Crypto import Random
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from Crypto.Hash import HMAC, SHA256
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from rhodecode.lib.str_utils import safe_bytes, safe_str
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from rhodecode.lib.exceptions import signature_verification_error
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class InvalidDecryptedValue(str):
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def __new__(cls, content):
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"""
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This will generate something like this::
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<InvalidDecryptedValue(QkWusFgLJXR6m42v...)>
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And represent a safe indicator that encryption key is broken
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"""
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content = f'<{cls.__name__}({content[:16]}...)>'
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return str.__new__(cls, content)
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KEY_FORMAT = b'enc$aes_hmac${1}'
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class AESCipher(object):
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def __init__(self, key: bytes, hmac=False, strict_verification=True):
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if not key:
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raise ValueError('passed key variable is empty')
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self.strict_verification = strict_verification
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self.block_size = 32
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self.hmac_size = 32
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self.hmac = hmac
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self.key = SHA256.new(safe_bytes(key)).digest()
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self.hmac_key = SHA256.new(self.key).digest()
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def verify_hmac_signature(self, raw_data):
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org_hmac_signature = raw_data[-self.hmac_size:]
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data_without_sig = raw_data[:-self.hmac_size]
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recomputed_hmac = HMAC.new(
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self.hmac_key, data_without_sig, digestmod=SHA256).digest()
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return org_hmac_signature == recomputed_hmac
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def encrypt(self, raw: bytes):
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raw = self._pad(raw)
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iv = Random.new().read(AES.block_size)
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cipher = AES.new(self.key, AES.MODE_CBC, iv)
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enc_value = cipher.encrypt(raw)
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hmac_signature = b''
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if self.hmac:
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# compute hmac+sha256 on iv + enc text, we use
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# encrypt then mac method to create the signature
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hmac_signature = HMAC.new(
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self.hmac_key, iv + enc_value, digestmod=SHA256).digest()
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return base64.b64encode(iv + enc_value + hmac_signature)
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def decrypt(self, enc, safe=True) -> bytes | InvalidDecryptedValue:
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enc_org = enc
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try:
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enc = base64.b64decode(enc)
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except Exception:
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logging.exception('Failed Base64 decode')
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raise signature_verification_error('Failed Base64 decode')
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if self.hmac and len(enc) > self.hmac_size:
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if self.verify_hmac_signature(enc):
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# cut off the HMAC verification digest
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enc = enc[:-self.hmac_size]
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else:
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decrypt_fail = InvalidDecryptedValue(safe_str(enc_org))
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if safe:
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return decrypt_fail
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raise signature_verification_error(decrypt_fail)
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iv = enc[:AES.block_size]
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cipher = AES.new(self.key, AES.MODE_CBC, iv)
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return self._unpad(cipher.decrypt(enc[AES.block_size:]))
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def _pad(self, s):
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block_pad = (self.block_size - len(s) % self.block_size)
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return s + block_pad * safe_bytes(chr(block_pad))
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@staticmethod
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def _unpad(s):
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return s[:-ord(s[len(s)-1:])]
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def validate_and_decrypt_data(enc_data, enc_key, enc_strict_mode=False, safe=True):
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enc_data = safe_str(enc_data)
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if '$' not in enc_data:
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# probably not encrypted values
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return enc_data
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parts = enc_data.split('$', 3)
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if len(parts) != 3:
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raise ValueError(f'Encrypted Data has invalid format, expected {KEY_FORMAT}, got {parts}, org value: {enc_data}')
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enc_type = parts[1]
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enc_data_part = parts[2]
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if parts[0] != 'enc':
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# parts ok but without our header?
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return enc_data
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# at that stage we know it's our encryption
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if enc_type == 'aes':
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decrypted_data = AESCipher(enc_key).decrypt(enc_data_part, safe=safe)
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elif enc_type == 'aes_hmac':
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decrypted_data = AESCipher(
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enc_key, hmac=True,
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strict_verification=enc_strict_mode).decrypt(enc_data_part, safe=safe)
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else:
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raise ValueError(
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f'Encryption type part is wrong, must be `aes` '
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f'or `aes_hmac`, got `{enc_type}` instead')
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return decrypted_data
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def encrypt_data(data, enc_key: bytes):
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enc_key = safe_bytes(enc_key)
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enc_value = AESCipher(enc_key, hmac=True).encrypt(safe_bytes(data))
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return KEY_FORMAT.replace(b'{1}', enc_value)
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