# =================================================================== # # Copyright (c) 2014, Legrandin # All rights reserved. # # Redistribution and use in source and binary forms, with or without # modification, are permitted provided that the following conditions # are met: # # 1. Redistributions of source code must retain the above copyright # notice, this list of conditions and the following disclaimer. # 2. Redistributions in binary form must reproduce the above copyright # notice, this list of conditions and the following disclaimer in # the documentation and/or other materials provided with the # distribution. # # THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS # "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT # LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS # FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE # COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, # INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, # BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; # LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER # CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT # LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN # ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE # POSSIBILITY OF SUCH DAMAGE. # =================================================================== """ Counter with CBC-MAC (CCM) mode. """ __all__ = ['CcmMode'] from Crypto.Util.py3compat import * from binascii import unhexlify, hexlify from Crypto.Util import Counter from Crypto.Util.strxor import strxor from Crypto.Util.number import long_to_bytes, bytes_to_long from Crypto.Hash.CMAC import _SmoothMAC from Crypto.Hash import BLAKE2s from Crypto.Random import get_random_bytes class _CBCMAC(_SmoothMAC): """MAC class based on CBC-MAC that does not need to operate on data chunks multiple of the block size""" def __init__(self, key, cipher_factory, cipher_params): _SmoothMAC.__init__(self, cipher_factory.block_size, None, 0) self._key = key self._factory = cipher_factory self._cipher_params = dict(cipher_params) def ignite(self, data): """Start the MAC. Data provided here is consumed *before* whatever is already stored in the internal buffer.""" if self._mac: raise TypeError("ignite() cannot be called twice") self._buffer.insert(0, data) self._buffer_len += len(data) self._mac = self._factory.new(self._key, self._factory.MODE_CBC, bchr(0) * 16, **self._cipher_params) self.update(b("")) def _update(self, block_data): self._t = self._mac.encrypt(block_data)[-16:] def _digest(self, left_data): return self._t class CcmMode(object): """Counter with CBC-MAC (CCM). This is an Authenticated Encryption with Associated Data (`AEAD`_) mode. It provides both confidentiality and authenticity. The header of the message may be left in the clear, if needed, and it will still be subject to authentication. The decryption step tells the receiver if the message comes from a source that really knowns the secret key. Additionally, decryption detects if any part of the message - including the header - has been modified or corrupted. This mode requires a nonce. The nonce shall never repeat for two different messages encrypted with the same key, but it does not need to be random. Note that there is a trade-off between the size of the nonce and the maximum size of a single message you can encrypt. It is important to use a large nonce if the key is reused across several messages and the nonce is chosen randomly. It is acceptable to us a short nonce if the key is only used a few times or if the nonce is taken from a counter. The following table shows the trade-off when the nonce is chosen at random. The column on the left shows how many messages it takes for the keystream to repeat **on average**. In practice, you will want to stop using the key way before that. +--------------------+---------------+-------------------+ | Avg. # of messages | nonce | Max. message | | before keystream | size | size | | repeats | (bytes) | (bytes) | +====================+===============+===================+ | 2^52 | 13 | 64K | +--------------------+---------------+-------------------+ | 2^48 | 12 | 16M | +--------------------+---------------+-------------------+ | 2^44 | 11 | 4G | +--------------------+---------------+-------------------+ | 2^40 | 10 | 1T | +--------------------+---------------+-------------------+ | 2^36 | 9 | 64P | +--------------------+---------------+-------------------+ | 2^32 | 8 | 16E | +--------------------+---------------+-------------------+ This mode is only available for ciphers that operate on 128 bits blocks (e.g. AES but not TDES). See `NIST SP800-38C`_ or RFC3610_. .. _`NIST SP800-38C`: http://csrc.nist.gov/publications/nistpubs/800-38C/SP800-38C.pdf .. _RFC3610: https://tools.ietf.org/html/rfc3610 .. _AEAD: http://blog.cryptographyengineering.com/2012/05/how-to-choose-authenticated-encryption.html """ def __init__(self, factory, **kwargs): """Create a new block cipher, configured in CCM mode. :Parameters: factory : module A symmetric cipher module from `Crypto.Cipher` (like `Crypto.Cipher.AES`). :Keywords: key : byte string The secret key to use in the symmetric cipher. nonce : byte string A mandatory value that must never be reused for any other encryption. Its length must be in the range ``[7..13]``. 11 or 12 bytes are reasonable values in general. Bear in mind that with CCM there is a trade-off between nonce length and maximum message size. mac_len : integer Length of the MAC, in bytes. It must be even and in the range ``[4..16]``. The default is 16. msg_len : integer Length of the message to (de)cipher. If not specified, ``encrypt`` or ``decrypt`` may only be called once. assoc_len : integer Length of the associated data. If not specified, all data is internally buffered. """ #: The block size of the underlying cipher, in bytes. self.block_size = factory.block_size self._factory = factory try: self._key = key = kwargs.pop("key") self._nonce = kwargs.pop("nonce") # N except KeyError, e: raise TypeError("Missing parameter: " + str(e)) self._mac_len = kwargs.pop("mac_len", self.block_size) self._msg_len = kwargs.pop("msg_len", None) # p self._assoc_len = kwargs.pop("assoc_len", None) # a self._cipher_params = dict(kwargs) self._mac_tag = None # Cache for MAC tag if self.block_size != 16: raise ValueError("CCM mode is only available for ciphers" " that operate on 128 bits blocks") # MAC tag length (Tlen) if self._mac_len not in (4, 6, 8, 10, 12, 14, 16): raise ValueError("Parameter 'mac_len' must be even" " and in the range 4..16") # Nonce value if not (self._nonce and 7 <= len(self._nonce) <= 13): raise ValueError("Length of parameter 'nonce' must be" " in the range 7..13 bytes") self._signer = _CBCMAC(key, factory, self._cipher_params) self._no_more_assoc_data = False # True when all associated data # has been processed # Allowed transitions after initialization self._next = [self.update, self.encrypt, self.decrypt, self.digest, self.verify] # Try to start CCM self._start_ccm() def _start_ccm(self, assoc_len=None, msg_len=None): # CCM mode. This method creates the 2 ciphers used for the MAC # (self._signer) and for the encryption/decryption (self._cipher). # # Member _assoc_buffer may already contain user data that needs to be # authenticated. if self._signer.can_reduce(): # Already started return if assoc_len is not None: self._assoc_len = assoc_len if msg_len is not None: self._msg_len = msg_len if None in (self._assoc_len, self._msg_len): return ## Formatting control information and nonce (A.2.1) q = 15 - len(self._nonce) # length of Q, the encoded message length flags = ( 64 * (self._assoc_len > 0) + 8 * divmod(self._mac_len - 2, 2)[0] + (q - 1) ) b_0 = bchr(flags) + self._nonce + long_to_bytes(self._msg_len, q) ## Formatting associated data (A.2.2) ## Encoded 'a' is concatenated with the associated data 'A' assoc_len_encoded = b('') if self._assoc_len > 0: if self._assoc_len < (2 ** 16 - 2 ** 8): enc_size = 2 elif self._assoc_len < (2L ** 32): assoc_len_encoded = b('\xFF\xFE') enc_size = 4 else: assoc_len_encoded = b('\xFF\xFF') enc_size = 8 assoc_len_encoded += long_to_bytes(self._assoc_len, enc_size) self._signer.ignite(b_0 + assoc_len_encoded) # CBC-MAC will consume # B_0, 'a' and then 'A' # Start CTR cipher, by formatting the counter (A.3) prefix = bchr(q - 1) + self._nonce ctr = Counter.new(128 - len(prefix) * 8, prefix, initial_value=0) self._cipher = self._factory.new(self._key, self._factory.MODE_CTR, counter=ctr, **self._cipher_params) # S_0, step 6 in 6.1 for j=0 self._s_0 = self._cipher.encrypt(bchr(0) * 16) def update(self, assoc_data): """Protect associated data If there is any associated data, the caller has to invoke this function one or more times, before using ``decrypt`` or ``encrypt``. By *associated data* it is meant any data (e.g. packet headers) that will not be encrypted and will be transmitted in the clear. However, the receiver is still able to detect any modification to it. In CCM, the *associated data* is also called *additional authenticated data* (AAD). If there is no associated data, this method must not be called. The caller may split associated data in segments of any size, and invoke this method multiple times, each time with the next segment. :Parameters: assoc_data : byte string A piece of associated data. There are no restrictions on its size. """ if self.update not in self._next: raise TypeError("update() can only be called" " immediately after initialization") self._next = [self.update, self.encrypt, self.decrypt, self.digest, self.verify] return self._signer.update(assoc_data) def encrypt(self, plaintext): """Encrypt data with the key set at initialization. A cipher object is stateful: once you have encrypted a message you cannot encrypt (or decrypt) another message using the same object. This method can be called only **once** if ``msg_len`` was not passed at initialization. If ``msg_len`` was given, the data to encrypt can be broken up in two or more pieces and `encrypt` can be called multiple times. That is, the statement: >>> c.encrypt(a) + c.encrypt(b) is equivalent to: >>> c.encrypt(a+b) This function does not add any padding to the plaintext. :Parameters: plaintext : byte string The piece of data to encrypt. It can be of any length. :Return: the encrypted data, as a byte string. It is as long as *plaintext*. """ if self.encrypt not in self._next: raise TypeError("encrypt() can only be called after" " initialization or an update()") self._next = [self.encrypt, self.digest] if self._assoc_len is None: self._start_ccm(assoc_len=self._signer.data_signed_so_far()) if self._msg_len is None: self._start_ccm(msg_len=len(plaintext)) self._next = [self.digest] if not self._no_more_assoc_data: # Associated data is concatenated with the least number # of zero bytes (possibly none) to reach alignment to # the 16 byte boundary (A.2.3) self._signer.zero_pad() self._no_more_assoc_data = True self._signer.update(plaintext) return self._cipher.encrypt(plaintext) def decrypt(self, ciphertext): """Decrypt data with the key set at initialization. A cipher object is stateful: once you have decrypted a message you cannot decrypt (or encrypt) another message with the same object. This method can be called only **once** if ``msg_len`` was not passed at initialization. If ``msg_len`` was given, the data to decrypt can be broken up in two or more pieces and `decrypt` can be called multiple times. That is, the statement: >>> c.decrypt(a) + c.decrypt(b) is equivalent to: >>> c.decrypt(a+b) This function does not remove any padding from the plaintext. :Parameters: ciphertext : byte string The piece of data to decrypt. It can be of any length. :Return: the decrypted data (byte string). """ if self.decrypt not in self._next: raise TypeError("decrypt() can only be called" " after initialization or an update()") self._next = [self.decrypt, self.verify] if self._assoc_len is None: self._start_ccm(assoc_len=self._signer.data_signed_so_far()) if self._msg_len is None: self._start_ccm(msg_len=len(ciphertext)) self._next = [self.verify] if not self._no_more_assoc_data: # Associated data is concatenated with the least number # of zero bytes (possibly none) to reach alignment to # the 16 byte boundary (A.2.3) self._signer.zero_pad() self._no_more_assoc_data = True plaintext = self._cipher.decrypt(ciphertext) self._signer.update(plaintext) return plaintext def digest(self): """Compute the *binary* MAC tag. The caller invokes this function at the very end. This method returns the MAC that shall be sent to the receiver, together with the ciphertext. :Return: the MAC, as a byte string. """ if self.digest not in self._next: raise TypeError("digest() cannot be called when decrypting" " or validating a message") self._next = [self.digest] if self._mac_tag: return self._mac_tag if self._assoc_len is None: self._start_ccm(assoc_len=self._signer.data_signed_so_far()) if self._msg_len is None: self._start_ccm(msg_len=0) # Both associated data and payload are concatenated with the least # number of zero bytes (possibly none) that align it to the # 16 byte boundary (A.2.2 and A.2.3) self._signer.zero_pad() # Step 8 in 6.1 (T xor MSB_Tlen(S_0)) self._mac_tag = strxor(self._signer.digest(), self._s_0)[:self._mac_len] return self._mac_tag def hexdigest(self): """Compute the *printable* MAC tag. This method is like `digest`. :Return: the MAC, as a hexadecimal string. """ return "".join(["%02x" % bord(x) for x in self.digest()]) def verify(self, received_mac_tag): """Validate the *binary* MAC tag. The caller invokes this function at the very end. This method checks if the decrypted message is indeed valid (that is, if the key is correct) and it has not been tampered with while in transit. :Parameters: received_mac_tag : byte string This is the *binary* MAC, as received from the sender. :Raises ValueError: if the MAC does not match. The message has been tampered with or the key is incorrect. """ if self.verify not in self._next: raise TypeError("verify() cannot be called" " when encrypting a message") self._next = [self.verify] if not self._mac_tag: if self._assoc_len is None: self._start_ccm(assoc_len=self._signer.data_signed_so_far()) if self._msg_len is None: self._start_ccm(msg_len=0) # Both associated data and payload are concatenated with the least # number of zero bytes (possibly none) that align it to the # 16 byte boundary (A.2.2 and A.2.3) self._signer.zero_pad() # Step 8 in 6.1 (T xor MSB_Tlen(S_0)) self._mac_tag = strxor(self._signer.digest(), self._s_0)[:self._mac_len] secret = get_random_bytes(16) mac1 = BLAKE2s.new(digest_bits=160, key=secret, data=self._mac_tag) mac2 = BLAKE2s.new(digest_bits=160, key=secret, data=received_mac_tag) if mac1.digest() != mac2.digest(): raise ValueError("MAC check failed") def hexverify(self, hex_mac_tag): """Validate the *printable* MAC tag. This method is like `verify`. :Parameters: hex_mac_tag : string This is the *printable* MAC, as received from the sender. :Raises ValueError: if the MAC does not match. The message has been tampered with or the key is incorrect. """ self.verify(unhexlify(hex_mac_tag)) def encrypt_and_digest(self, plaintext): """Perform encrypt() and digest() in one step. :Parameters: plaintext : byte string The piece of data to encrypt. :Return: a tuple with two byte strings: - the encrypted data - the MAC """ return self.encrypt(plaintext), self.digest() def decrypt_and_verify(self, ciphertext, received_mac_tag): """Perform decrypt() and verify() in one step. :Parameters: ciphertext : byte string The piece of data to decrypt. received_mac_tag : byte string This is the *binary* MAC, as received from the sender. :Return: the decrypted data (byte string). :Raises ValueError: if the MAC does not match. The message has been tampered with or the key is incorrect. """ plaintext = self.decrypt(ciphertext) self.verify(received_mac_tag) return plaintext def _create_ccm_cipher(factory, **kwargs): return CcmMode(factory, **kwargs)