path: root/frozen_deps/Cryptodome/Cipher/_mode_ccm.py

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"""
Counter with CBC-MAC (CCM) mode.
"""

__all__ = ['CcmMode']

import struct
from binascii import unhexlify

from Cryptodome.Util.py3compat import (byte_string, bord,
                                   _copy_bytes)
from Cryptodome.Util._raw_api import is_writeable_buffer

from Cryptodome.Util.strxor import strxor
from Cryptodome.Util.number import long_to_bytes

from Cryptodome.Hash import BLAKE2s
from Cryptodome.Random import get_random_bytes


def enum(**enums):
    return type('Enum', (), enums)

MacStatus = enum(NOT_STARTED=0, PROCESSING_AUTH_DATA=1, PROCESSING_PLAINTEXT=2)


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

    :undocumented: __init__
    """

    def __init__(self, factory, key, nonce, mac_len, msg_len, assoc_len,
                 cipher_params):

        self.block_size = factory.block_size
        """The block size of the underlying cipher, in bytes."""

        self.nonce = _copy_bytes(None, None, nonce)
        """The nonce used for this cipher instance"""

        self._factory = factory
        self._key = _copy_bytes(None, None, key)
        self._mac_len = mac_len
        self._msg_len = msg_len
        self._assoc_len = assoc_len
        self._cipher_params = cipher_params

        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 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 (not %d)" % mac_len)

        # Nonce value
        if not (nonce and 7 <= len(nonce) <= 13):
            raise ValueError("Length of parameter 'nonce' must be"
                             " in the range 7..13 bytes")

        # Create MAC object (the tag will be the last block
        # bytes worth of ciphertext)
        self._mac = self._factory.new(key,
                                      factory.MODE_CBC,
                                      iv=b'\x00' * 16,
                                      **cipher_params)
        self._mac_status = MacStatus.NOT_STARTED
        self._t = None

        # Allowed transitions after initialization
        self._next = [self.update, self.encrypt, self.decrypt,
                      self.digest, self.verify]

        # Cumulative lengths
        self._cumul_assoc_len = 0
        self._cumul_msg_len = 0

        # Cache for unaligned associated data/plaintext.
        # This is a list with byte strings, but when the MAC starts,
        # it will become a binary string no longer than the block size.
        self._cache = []

        # Start CTR cipher, by formatting the counter (A.3)
        q = 15 - len(nonce)  # length of Q, the encoded message length
        self._cipher = self._factory.new(key,
                                         self._factory.MODE_CTR,
                                         nonce=struct.pack("B", q - 1) + self.nonce,
                                         **cipher_params)

        # S_0, step 6 in 6.1 for j=0
        self._s_0 = self._cipher.encrypt(b'\x00' * 16)

        # Try to start the MAC
        if None not in (assoc_len, msg_len):
            self._start_mac()

    def _start_mac(self):

        assert(self._mac_status == MacStatus.NOT_STARTED)
        assert(None not in (self._assoc_len, self._msg_len))
        assert(isinstance(self._cache, list))

        # 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 * ((self._mac_len - 2) // 2) +
                 (q - 1))
        b_0 = struct.pack("B", 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 < (2 ** 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)

        # b_0 and assoc_len_encoded must be processed first
        self._cache.insert(0, b_0)
        self._cache.insert(1, assoc_len_encoded)

        # Process all the data cached so far
        first_data_to_mac = b"".join(self._cache)
        self._cache = b""
        self._mac_status = MacStatus.PROCESSING_AUTH_DATA
        self._update(first_data_to_mac)

    def _pad_cache_and_update(self):

        assert(self._mac_status != MacStatus.NOT_STARTED)
        assert(len(self._cache) < self.block_size)

        # Associated data is concatenated with the least number
        # of zero bytes (possibly none) to reach alignment to
        # the 16 byte boundary (A.2.3)
        len_cache = len(self._cache)
        if len_cache > 0:
            self._update(b'\x00' * (self.block_size - len_cache))

    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 : bytes/bytearray/memoryview
            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]

        self._cumul_assoc_len += len(assoc_data)
        if self._assoc_len is not None and \
           self._cumul_assoc_len > self._assoc_len:
            raise ValueError("Associated data is too long")

        self._update(assoc_data)
        return self

    def _update(self, assoc_data_pt=b""):
        """Update the MAC with associated data or plaintext
           (without FSM checks)"""

        # If MAC has not started yet, we just park the data into a list.
        # If the data is mutable, we create a copy and store that instead.
        if self._mac_status == MacStatus.NOT_STARTED:
            if is_writeable_buffer(assoc_data_pt):
                assoc_data_pt = _copy_bytes(None, None, assoc_data_pt)
            self._cache.append(assoc_data_pt)
            return

        assert(len(self._cache) < self.block_size)

        if len(self._cache) > 0:
            filler = min(self.block_size - len(self._cache),
                         len(assoc_data_pt))
            self._cache += _copy_bytes(None, filler, assoc_data_pt)
            assoc_data_pt = _copy_bytes(filler, None, assoc_data_pt)

            if len(self._cache) < self.block_size:
                return

            # The cache is exactly one block
            self._t = self._mac.encrypt(self._cache)
            self._cache = b""

        update_len = len(assoc_data_pt) // self.block_size * self.block_size
        self._cache = _copy_bytes(update_len, None, assoc_data_pt)
        if update_len > 0:
            self._t = self._mac.encrypt(assoc_data_pt[:update_len])[-16:]

    def encrypt(self, plaintext, output=None):
        """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