# -*- coding: utf-8 -*- # # Hash/CMAC.py - Implements the CMAC algorithm # # =================================================================== # The contents of this file are dedicated to the public domain. To # the extent that dedication to the public domain is not available, # everyone is granted a worldwide, perpetual, royalty-free, # non-exclusive license to exercise all rights associated with the # contents of this file for any purpose whatsoever. # No rights are reserved. # # THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, # EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF # MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND # NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS # BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN # ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN # CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE # SOFTWARE. # =================================================================== from Crypto.Util.py3compat import b, bchr, bord, tobytes from binascii import unhexlify from Crypto.Hash import BLAKE2s from Crypto.Util.strxor import strxor from Crypto.Util.number import long_to_bytes, bytes_to_long from Crypto.Random import get_random_bytes # The size of the authentication tag produced by the MAC. digest_size = None def _shift_bytes(bs, xor_lsb=0): num = (bytes_to_long(bs) << 1) ^ xor_lsb return long_to_bytes(num, len(bs))[-len(bs):] class CMAC(object): """A CMAC hash object. Do not instantiate directly. Use the :func:`new` function. :ivar digest_size: the size in bytes of the resulting MAC tag :vartype digest_size: integer """ digest_size = None def __init__(self, key, msg=None, ciphermod=None, cipher_params=None): if ciphermod is None: raise TypeError("ciphermod must be specified (try AES)") self._key = key self._factory = ciphermod if cipher_params is None: self._cipher_params = {} else: self._cipher_params = dict(cipher_params) # Section 5.3 of NIST SP 800 38B and Appendix B if ciphermod.block_size == 8: const_Rb = 0x1B self._max_size = 8 * (2 ** 21) elif ciphermod.block_size == 16: const_Rb = 0x87 self._max_size = 16 * (2 ** 48) else: raise TypeError("CMAC requires a cipher with a block size" "of 8 or 16 bytes, not %d" % (ciphermod.block_size,)) # Size of the final MAC tag, in bytes self.digest_size = ciphermod.block_size self._mac_tag = None # Compute sub-keys zero_block = bchr(0) * ciphermod.block_size cipher = ciphermod.new(key, ciphermod.MODE_ECB, **self._cipher_params) l = cipher.encrypt(zero_block) if bord(l[0]) & 0x80: self._k1 = _shift_bytes(l, const_Rb) else: self._k1 = _shift_bytes(l) if bord(self._k1[0]) & 0x80: self._k2 = _shift_bytes(self._k1, const_Rb) else: self._k2 = _shift_bytes(self._k1) # Initialize CBC cipher with zero IV self._cbc = ciphermod.new(key, ciphermod.MODE_CBC, zero_block, **self._cipher_params) # Cache for outstanding data to authenticate self._cache = b("") # Last two pieces of ciphertext produced self._last_ct = self._last_pt = zero_block self._before_last_ct = None # Counter for total message size self._data_size = 0 if msg: self.update(msg) def update(self, msg): """Authenticate the next chunk of message. Args: data (byte string): The next chunk of data """ self._data_size += len(msg) if len(self._cache) > 0: filler = min(self.digest_size - len(self._cache), len(msg)) self._cache += msg[:filler] if len(self._cache) < self.digest_size: return self msg = msg[filler:] self._update(self._cache) self._cache = b("") update_len, remain = divmod(len(msg), self.digest_size) update_len *= self.digest_size if remain > 0: self._update(msg[:update_len]) self._cache = msg[update_len:] else: self._update(msg) self._cache = b("") return self def _update(self, data_block): """Update a block aligned to the block boundary""" if len(data_block) == 0: return assert len(data_block) % self.digest_size == 0 ct = self._cbc.encrypt(data_block) if len(data_block) == self.digest_size: self._before_last_ct = self._last_ct else: self._before_last_ct = ct[-self.digest_size * 2:-self.digest_size] self._last_ct = ct[-self.digest_size:] self._last_pt = data_block[-self.digest_size:] def copy(self): """Return a copy ("clone") of the CMAC object. The copy will have the same internal state as the original CMAC object. This can be used to efficiently compute the MAC tag of byte strings that share a common initial substring. :return: An :class:`CMAC` """ obj = CMAC(self._key, ciphermod=self._factory, cipher_params=self._cipher_params) obj._cbc = self._factory.new(self._key, self._factory.MODE_CBC, self._last_ct, **self._cipher_params) for m in ['_mac_tag', '_last_ct', '_before_last_ct', '_cache', '_data_size', '_max_size']: setattr(obj, m, getattr(self, m)) return obj def digest(self): """Return the **binary** (non-printable) MAC tag of the message that has been authenticated so far. :return: The MAC tag, computed over the data processed so far. Binary form. :rtype: byte string """ if self._mac_tag is not None: return self._mac_tag if self._data_size > self._max_size: raise ValueError("MAC is unsafe for this message") if len(self._cache) == 0 and self._before_last_ct is not None: # Last block was full pt = strxor(strxor(self._before_last_ct, self._k1), self._last_pt) else: # Last block is partial (or message length is zero) ext = self._cache + bchr(0x80) +\ bchr(0) * (self.digest_size - len(self._cache) - 1) pt = strxor(strxor(self._last_ct, self._k2), ext) cipher = self._factory.new(self._key, self._factory.MODE_ECB, **self._cipher_params) self._mac_tag = cipher.encrypt(pt) return self._mac_tag def hexdigest(self): """Return the **printable** MAC tag of the message authenticated so far. :return: The MAC tag, computed over the data processed so far. Hexadecimal encoded. :rtype: string """ return "".join(["%02x" % bord(x) for x in tuple(self.digest())]) def verify(self, mac_tag): """Verify that a given **binary** MAC (computed by another party) is valid. Args: mac_tag (byte string): the expected MAC of the message. Raises: ValueError: if the MAC does not match. It means that the message has been tampered with or that the MAC key is incorrect. """ secret = get_random_bytes(16) mac1 = BLAKE2s.new(digest_bits=160, key=secret, data=mac_tag) mac2 = BLAKE2s.new(digest_bits=160, key=secret, data=self.digest()) if mac1.digest() != mac2.digest(): raise ValueError("MAC check failed") def hexverify(self, hex_mac_tag): """Return the **printable** MAC tag of the message authenticated so far. :return: The MAC tag, computed over the data processed so far. Hexadecimal encoded. :rtype: string """ self.verify(unhexlify(tobytes(hex_mac_tag))) def new(key, msg=None, ciphermod=None, cipher_params=None): """Create a new MAC object. Args: key (byte string): key for the CMAC object. The key must be valid for the underlying cipher algorithm. For instance, it must be 16 bytes long for AES-128. ciphermod (module): A cipher module from :mod:`Crypto.Cipher`. The cipher's block size has to be 128 bits, like :mod:`Crypto.Cipher.AES`, to reduce the probability of collisions. msg (byte string): Optional. The very first chunk of the message to authenticate. It is equivalent to an early call to `CMAC.update`. Optional. cipher_params (dict): Optional. A set of parameters to use when instantiating a cipher object. Returns: A :class:`CMAC` object """ return CMAC(key, msg, ciphermod, cipher_params)