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# ===================================================================
#
# Copyright (c) 2014, Legrandin <helderijs@gmail.com>
# 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
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# ===================================================================

"""
Synthetic Initialization Vector (SIV) mode.
"""

__all__ = ['SivMode']

from binascii import hexlify, unhexlify

from Crypto.Util.py3compat import bord, _copy_bytes

from Crypto.Util._raw_api import is_buffer

from Crypto.Util.number import long_to_bytes, bytes_to_long
from Crypto.Protocol.KDF import _S2V
from Crypto.Hash import BLAKE2s
from Crypto.Random import get_random_bytes


class SivMode(object):
    """Synthetic Initialization Vector (SIV).

    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.

    Unlike other AEAD modes such as CCM, EAX or GCM, accidental reuse of a
    nonce is not catastrophic for the confidentiality of the message. The only
    effect is that an attacker can tell when the same plaintext (and same
    associated data) is protected with the same key.

    The length of the MAC is fixed to the block size of the underlying cipher.
    The key size is twice the length of the key of the underlying cipher.

    This mode is only available for AES ciphers.

    +--------------------+---------------+-------------------+
    |      Cipher        | SIV MAC size  |   SIV key length  |
    |                    |    (bytes)    |     (bytes)       |
    +====================+===============+===================+
    |    AES-128         |      16       |        32         |
    +--------------------+---------------+-------------------+
    |    AES-192         |      16       |        48         |
    +--------------------+---------------+-------------------+
    |    AES-256         |      16       |        64         |
    +--------------------+---------------+-------------------+

    See `RFC5297`_ and the `original paper`__.

    .. _RFC5297: https://tools.ietf.org/html/rfc5297
    .. _AEAD: http://blog.cryptographyengineering.com/2012/05/how-to-choose-authenticated-encryption.html
    .. __: http://www.cs.ucdavis.edu/~rogaway/papers/keywrap.pdf

    :undocumented: __init__
    """

    def __init__(self, factory, key, nonce, kwargs):

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

        self._factory = factory

        self._cipher_params = kwargs

        if len(key) not in (32, 48, 64):
            raise ValueError("Incorrect key length (%d bytes)" % len(key))

        if nonce is not None:
            if not is_buffer(nonce):
                raise TypeError("When provided, the nonce must be bytes, bytearray or memoryview")

            if len(nonce) == 0:
                raise ValueError("When provided, the nonce must be non-empty")

            self.nonce = _copy_bytes(None, None, nonce)
            """Public attribute is only available in case of non-deterministic
            encryption."""

        subkey_size = len(key) // 2

        self._mac_tag = None  # Cache for MAC tag
        self._kdf = _S2V(key[:subkey_size],
                         ciphermod=factory,
                         cipher_params=self._cipher_params)
        self._subkey_cipher = key[subkey_size:]

        # Purely for the purpose of verifying that cipher_params are OK
        factory.new(key[:subkey_size], factory.MODE_ECB, **kwargs)

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

    def _create_ctr_cipher(self, v):
        """Create a new CTR cipher from V in SIV mode"""

        v_int = bytes_to_long(v)
        q = v_int & 0xFFFFFFFFFFFFFFFF7FFFFFFF7FFFFFFF
        return self._factory.new(
                    self._subkey_cipher,
                    self._factory.MODE_CTR,
                    initial_value=q,
                    nonce=b"",
                    **self._cipher_params)

    def update(self, component):
        """Protect one associated data component

        For SIV, the associated data is a sequence (*vector*) of non-empty
        byte strings (*components*).

        This method consumes the next component. It must be called
        once for each of the components that constitue the associated data.

        Note that the components have clear boundaries, so that:

            >>> cipher.update(b"builtin")
            >>> cipher.update(b"securely")

        is not equivalent to:

            >>> cipher.update(b"built")
            >>> cipher.update(b"insecurely")

        If there is no associated data, this method must not be called.

        :Parameters:
          component : bytes/bytearray/memoryview
            The next associated data component.
        """

        if "update" not in self._next:
            raise TypeError("update() can only be called"
                                " immediately after initialization")

        self._next = ["update", "encrypt", "decrypt",
                      "digest", "verify"]

        return self._kdf.update(component)

    def encrypt(self, plaintext):
        """
        For SIV, encryption and MAC authentication must take place at the same
        point. This method shall not be used.

        Use `encrypt_and_digest` instead.
        """

        raise TypeError("encrypt() not allowed for SIV mode."
                        " Use encrypt_and_digest() instead.")

    def decrypt(self, ciphertext):
        """
        For SIV, decryption and verification must take place at the same
        point. This method shall not be used.

        Use `decrypt_and_verify` instead.
        """

        raise TypeError("decrypt() not allowed for SIV mode."
                        " Use decrypt_and_verify() instead.")

    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 "digest" not in self._next:
            raise TypeError("digest() cannot be called when decrypting"
                            " or validating a message")
        self._next = ["digest"]
        if self._mac_tag is None:
            self._mac_tag = self._kdf.derive()
        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 : bytes/bytearray/memoryview
            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 "verify" not in self._next:
            raise TypeError("verify() cannot be called"
                            " when encrypting a message")
        self._next = ["verify"]

        if self._mac_tag is None:
            self._mac_tag = self._kdf.derive()

        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, output=None):
        """Perform encrypt() and digest() in one step.

        :Parameters:
          plaintext : bytes/bytearray/memoryview
            The piece of data to encrypt.
        :Keywords:
          output : bytearray/memoryview
            The location where the ciphertext must be written to.
            If ``None``, the ciphertext is returned.
        :Return:
            a tuple with two items:

            - the ciphertext, as ``bytes``
            - the MAC tag, as ``bytes``

            The first item becomes ``None`` when the ``output`` parameter
            specified a location for the result.
        """

        if "encrypt" not in self._next:
            raise TypeError("encrypt() can only be called after"
                            " initialization or an update()")

        self._next = ["digest"]

        # Compute V (MAC)
        if hasattr(self, 'nonce'):
            self._kdf.update(self.nonce)
        self._kdf.update(plaintext)
        self._mac_tag = self._kdf.derive()

        cipher = self._create_ctr_cipher(self._mac_tag)

        return cipher.encrypt(plaintext, output=output), self._mac_tag

    def decrypt_and_verify(self, ciphertext, mac_tag, output=None):
        """Perform decryption and verification in one step.

        A cipher object is stateful: once you have decrypted a message
        you cannot decrypt (or encrypt) another message with the same
        object.

        You cannot reuse an object for encrypting
        or decrypting other data with the same key.

        This function does not remove any padding from the plaintext.

        :Parameters:
          ciphertext : bytes/bytearray/memoryview
            The piece of data to decrypt.
            It can be of any length.
          mac_tag : bytes/bytearray/memoryview
            This is the *binary* MAC, as received from the sender.
        :Keywords:
          output : bytearray/memoryview
            The location where the plaintext must be written to.
            If ``None``, the plaintext is returned.
        :Return: the plaintext as ``bytes`` or ``None`` when the ``output``
            parameter specified a location for the result.
        :Raises ValueError:
            if the MAC does not match. The message has been tampered with
            or the key is incorrect.
        """

        if "decrypt" not in self._next:
            raise TypeError("decrypt() can only be called"
                            " after initialization or an update()")
        self._next = ["verify"]

        # Take the MAC and start the cipher for decryption
        self._cipher = self._create_ctr_cipher(mac_tag)

        plaintext = self._cipher.decrypt(ciphertext, output=output)

        if hasattr(self, 'nonce'):
            self._kdf.update(self.nonce)
        self._kdf.update(plaintext if output is None else output)
        self.verify(mac_tag)

        return plaintext


def _create_siv_cipher(factory, **kwargs):
    """Create a new block cipher, configured in
    Synthetic Initializaton Vector (SIV) mode.

    :Parameters:

      factory : object
        A symmetric cipher module from `Crypto.Cipher`
        (like `Crypto.Cipher.AES`).

    :Keywords:

      key : bytes/bytearray/memoryview
        The secret key to use in the symmetric cipher.
        It must be 32, 48 or 64 bytes long.
        If AES is the chosen cipher, the variants *AES-128*,
        *AES-192* and or *AES-256* will be used internally.

      nonce : bytes/bytearray/memoryview
        For deterministic encryption, it is not present.

        Otherwise, it is a value that must never be reused
        for encrypting message under this key.

        There are no restrictions on its length,
        but it is recommended to use at least 16 bytes.
    """

    try:
        key = kwargs.pop("key")
    except KeyError as e:
        raise TypeError("Missing parameter: " + str(e))

    nonce = kwargs.pop("nonce", None)

    return SivMode(factory, key, nonce, kwargs)

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