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# This file is dual licensed under the terms of the Apache License, Version # 2.0, and the BSD License. See the LICENSE file in the root of this repository # for complete details. from __future__ import annotations import typing from cryptography import utils from cryptography.exceptions import ( AlreadyFinalized, InvalidKey, UnsupportedAlgorithm, _Reasons, ) from cryptography.hazmat.primitives import ( ciphers, cmac, constant_time, hashes, hmac, ) from cryptography.hazmat.primitives.kdf import KeyDerivationFunction class Mode(utils.Enum): CounterMode = "ctr" class CounterLocation(utils.Enum): BeforeFixed = "before_fixed" AfterFixed = "after_fixed" MiddleFixed = "middle_fixed" class _KBKDFDeriver: def __init__( self, prf: typing.Callable, mode: Mode, length: int, rlen: int, llen: typing.Optional[int], location: CounterLocation, break_location: typing.Optional[int], label: typing.Optional[bytes], context: typing.Optional[bytes], fixed: typing.Optional[bytes], ): assert callable(prf) if not isinstance(mode, Mode): raise TypeError("mode must be of type Mode") if not isinstance(location, CounterLocation): raise TypeError("location must be of type CounterLocation") if break_location is None and location is CounterLocation.MiddleFixed: raise ValueError("Please specify a break_location") if ( break_location is not None and location != CounterLocation.MiddleFixed ): raise ValueError( "break_location is ignored when location is not" " CounterLocation.MiddleFixed" ) if break_location is not None and not isinstance(break_location, int): raise TypeError("break_location must be an integer") if break_location is not None and break_location < 0: raise ValueError("break_location must be a positive integer") if (label or context) and fixed: raise ValueError( "When supplying fixed data, " "label and context are ignored." ) if rlen is None or not self._valid_byte_length(rlen): raise ValueError("rlen must be between 1 and 4") if llen is None and fixed is None: raise ValueError("Please specify an llen") if llen is not None and not isinstance(llen, int): raise TypeError("llen must be an integer") if label is None: label = b"" if context is None: context = b"" utils._check_bytes("label", label) utils._check_bytes("context", context) self._prf = prf self._mode = mode self._length = length self._rlen = rlen self._llen = llen self._location = location self._break_location = break_location self._label = label self._context = context self._used = False self._fixed_data = fixed @staticmethod def _valid_byte_length(value: int) -> bool: if not isinstance(value, int): raise TypeError("value must be of type int") value_bin = utils.int_to_bytes(1, value) if not 1 <= len(value_bin) <= 4: return False return True def derive(self, key_material: bytes, prf_output_size: int) -> bytes: if self._used: raise AlreadyFinalized utils._check_byteslike("key_material", key_material) self._used = True # inverse floor division (equivalent to ceiling) rounds = -(-self._length // prf_output_size) output = [b""] # For counter mode, the number of iterations shall not be # larger than 2^r-1, where r <= 32 is the binary length of the counter # This ensures that the counter values used as an input to the # PRF will not repeat during a particular call to the KDF function. r_bin = utils.int_to_bytes(1, self._rlen) if rounds > pow(2, len(r_bin) * 8) - 1: raise ValueError("There are too many iterations.") fixed = self._generate_fixed_input() if self._location == CounterLocation.BeforeFixed: data_before_ctr = b"" data_after_ctr = fixed elif self._location == CounterLocation.AfterFixed: data_before_ctr = fixed data_after_ctr = b"" else: if isinstance( self._break_location, int ) and self._break_location > len(fixed): raise ValueError("break_location offset > len(fixed)") data_before_ctr = fixed[: self._break_location] data_after_ctr = fixed[self._break_location :] for i in range(1, rounds + 1): h = self._prf(key_material) counter = utils.int_to_bytes(i, self._rlen) input_data = data_before_ctr + counter + data_after_ctr h.update(input_data) output.append(h.finalize()) return b"".join(output)[: self._length] def _generate_fixed_input(self) -> bytes: if self._fixed_data and isinstance(self._fixed_data, bytes): return self._fixed_data l_val = utils.int_to_bytes(self._length * 8, self._llen) return b"".join([self._label, b"\x00", self._context, l_val]) class KBKDFHMAC(KeyDerivationFunction): def __init__( self, algorithm: hashes.HashAlgorithm, mode: Mode, length: int, rlen: int, llen: typing.Optional[int], location: CounterLocation, label: typing.Optional[bytes], context: typing.Optional[bytes], fixed: typing.Optional[bytes], backend: typing.Any = None, *, break_location: typing.Optional[int] = None, ): if not isinstance(algorithm, hashes.HashAlgorithm): raise UnsupportedAlgorithm( "Algorithm supplied is not a supported hash algorithm.", _Reasons.UNSUPPORTED_HASH, ) from cryptography.hazmat.backends.openssl.backend import ( backend as ossl, ) if not ossl.hmac_supported(algorithm): raise UnsupportedAlgorithm( "Algorithm supplied is not a supported hmac algorithm.", _Reasons.UNSUPPORTED_HASH, ) self._algorithm = algorithm self._deriver = _KBKDFDeriver( self._prf, mode, length, rlen, llen, location, break_location, label, context, fixed, ) def _prf(self, key_material: bytes) -> hmac.HMAC: return hmac.HMAC(key_material, self._algorithm) def derive(self, key_material: bytes) -> bytes: return self._deriver.derive(key_material, self._algorithm.digest_size) def verify(self, key_material: bytes, expected_key: bytes) -> None: if not constant_time.bytes_eq(self.derive(key_material), expected_key): raise InvalidKey class KBKDFCMAC(KeyDerivationFunction): def __init__( self, algorithm, mode: Mode, length: int, rlen: int, llen: typing.Optional[int], location: CounterLocation, label: typing.Optional[bytes], context: typing.Optional[bytes], fixed: typing.Optional[bytes], backend: typing.Any = None, *, break_location: typing.Optional[int] = None, ): if not issubclass( algorithm, ciphers.BlockCipherAlgorithm ) or not issubclass(algorithm, ciphers.CipherAlgorithm): raise UnsupportedAlgorithm( "Algorithm supplied is not a supported cipher algorithm.", _Reasons.UNSUPPORTED_CIPHER, ) self._algorithm = algorithm self._cipher: typing.Optional[ciphers.BlockCipherAlgorithm] = None self._deriver = _KBKDFDeriver( self._prf, mode, length, rlen, llen, location, break_location, label, context, fixed, ) def _prf(self, _: bytes) -> cmac.CMAC: assert self._cipher is not None return cmac.CMAC(self._cipher) def derive(self, key_material: bytes) -> bytes: self._cipher = self._algorithm(key_material) assert self._cipher is not None from cryptography.hazmat.backends.openssl.backend import ( backend as ossl, ) if not ossl.cmac_algorithm_supported(self._cipher): raise UnsupportedAlgorithm( "Algorithm supplied is not a supported cipher algorithm.", _Reasons.UNSUPPORTED_CIPHER, ) return self._deriver.derive(key_material, self._cipher.block_size // 8) def verify(self, key_material: bytes, expected_key: bytes) -> None: if not constant_time.bytes_eq(self.derive(key_material), expected_key): raise InvalidKey