Updated DB_Helper by adding firebase methods.

venv/Lib/site-packages/Crypto/Cipher/_mode_ctr.py

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+# -*- coding: utf-8 -*-
+#
+#  Cipher/mode_ctr.py : CTR mode
+#
+# ===================================================================
+# 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.
+# ===================================================================
+
+"""
+Counter (CTR) mode.
+"""
+
+__all__ = ['CtrMode']
+
+from Crypto.Util._raw_api import (load_pycryptodome_raw_lib, VoidPointer,
+                                  create_string_buffer, get_raw_buffer,
+                                  SmartPointer, c_size_t, expect_byte_string)
+
+from Crypto.Random import get_random_bytes
+from Crypto.Util.py3compat import b, bchr
+from Crypto.Util.number import long_to_bytes
+
+raw_ctr_lib = load_pycryptodome_raw_lib("Crypto.Cipher._raw_ctr", """
+                    int CTR_start_operation(void *cipher,
+                                            uint8_t   initialCounterBlock[],
+                                            size_t    initialCounterBlock_len,
+                                            size_t    prefix_len,
+                                            unsigned  counter_len,
+                                            unsigned  littleEndian,
+                                            void **pResult);
+                    int CTR_encrypt(void *ctrState,
+                                    const uint8_t *in,
+                                    uint8_t *out,
+                                    size_t data_len);
+                    int CTR_decrypt(void *ctrState,
+                                    const uint8_t *in,
+                                    uint8_t *out,
+                                    size_t data_len);
+                    int CTR_stop_operation(void *ctrState);"""
+                                        )
+
+
+class CtrMode(object):
+    """*CounTeR (CTR)* mode.
+
+    This mode is very similar to ECB, in that
+    encryption of one block is done independently of all other blocks.
+
+    Unlike ECB, the block *position* contributes to the encryption
+    and no information leaks about symbol frequency.
+
+    Each message block is associated to a *counter* which
+    must be unique across all messages that get encrypted
+    with the same key (not just within the same message).
+    The counter is as big as the block size.
+
+    Counters can be generated in several ways. The most
+    straightword one is to choose an *initial counter block*
+    (which can be made public, similarly to the *IV* for the
+    other modes) and increment its lowest **m** bits by one
+    (modulo *2^m*) for each block. In most cases, **m** is
+    chosen to be half the block size.
+
+    See `NIST SP800-38A`_, Section 6.5 (for the mode) and
+    Appendix B (for how to manage the *initial counter block*).
+
+    .. _`NIST SP800-38A` : http://csrc.nist.gov/publications/nistpubs/800-38a/sp800-38a.pdf
+
+    :undocumented: __init__
+    """
+
+    def __init__(self, block_cipher, initial_counter_block,
+                 prefix_len, counter_len, little_endian):
+        """Create a new block cipher, configured in CTR mode.
+
+        :Parameters:
+          block_cipher : C pointer
+            A smart pointer to the low-level block cipher instance.
+
+          initial_counter_block : byte string
+            The initial plaintext to use to generate the key stream.
+
+            It is as large as the cipher block, and it embeds
+            the initial value of the counter.
+
+            This value must not be reused.
+            It shall contain a nonce or a random component.
+            Reusing the *initial counter block* for encryptions
+            performed with the same key compromises confidentiality.
+
+          prefix_len : integer
+            The amount of bytes at the beginning of the counter block
+            that never change.
+
+          counter_len : integer
+            The length in bytes of the counter embedded in the counter
+            block.
+
+          little_endian : boolean
+            True if the counter in the counter block is an integer encoded
+            in little endian mode. If False, it is big endian.
+        """
+
+        if len(initial_counter_block) == prefix_len + counter_len:
+            self.nonce = initial_counter_block[:prefix_len]
+            """Nonce; not available if there is a fixed suffix"""
+
+        expect_byte_string(initial_counter_block)
+        self._state = VoidPointer()
+        result = raw_ctr_lib.CTR_start_operation(block_cipher.get(),
+                                                 initial_counter_block,
+                                                 c_size_t(len(initial_counter_block)),
+                                                 c_size_t(prefix_len),
+                                                 counter_len,
+                                                 little_endian,
+                                                 self._state.address_of())
+        if result:
+            raise ValueError("Error %X while instatiating the CTR mode"
+                             % result)
+
+        # Ensure that object disposal of this Python object will (eventually)
+        # free the memory allocated by the raw library for the cipher mode
+        self._state = SmartPointer(self._state.get(),
+                                   raw_ctr_lib.CTR_stop_operation)
+
+        # Memory allocated for the underlying block cipher is now owed
+        # by the cipher mode
+        block_cipher.release()
+
+        self.block_size = len(initial_counter_block)
+        """The block size of the underlying cipher, in bytes."""
+
+        self._next = [self.encrypt, self.decrypt]
+
+    def encrypt(self, plaintext):
+        """Encrypt data with the key and the parameters 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.
+
+        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() cannot be called after decrypt()")
+        self._next = [self.encrypt]
+
+        expect_byte_string(plaintext)
+        ciphertext = create_string_buffer(len(plaintext))
+        result = raw_ctr_lib.CTR_encrypt(self._state.get(),
+                                         plaintext,
+                                         ciphertext,
+                                         c_size_t(len(plaintext)))
+        if result:
+            if result == 0x60002:
+                raise OverflowError("The counter has wrapped around in"
+                                    " CTR mode")
+            raise ValueError("Error %X while encrypting in CTR mode" % result)
+        return get_raw_buffer(ciphertext)
+
+    def decrypt(self, ciphertext):
+        """Decrypt data with the key and the parameters 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.
+
+        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() cannot be called after encrypt()")
+        self._next = [self.decrypt]
+
+        expect_byte_string(ciphertext)
+        plaintext = create_string_buffer(len(ciphertext))
+        result = raw_ctr_lib.CTR_decrypt(self._state.get(),
+                                         ciphertext,
+                                         plaintext,
+                                         c_size_t(len(ciphertext)))
+        if result:
+            if result == 0x60002:
+                raise OverflowError("The counter has wrapped around in"
+                                    " CTR mode")
+            raise ValueError("Error %X while decrypting in CTR mode" % result)
+        return get_raw_buffer(plaintext)
+
+
+def _create_ctr_cipher(factory, **kwargs):
+    """Instantiate a cipher object that performs CTR encryption/decryption.
+
+    :Parameters:
+      factory : module
+        The underlying block cipher, a module from ``Crypto.Cipher``.
+
+    :Keywords:
+      nonce : binary string
+        The fixed part at the beginning of the counter block - the rest is
+        the counter number that gets increased when processing the next block.
+        The nonce must be such that no two messages are encrypted under the
+        same key and the same nonce.
+
+        The nonce must be shorter than the block size (it can have
+        zero length).
+
+        If this parameter is not present, a random nonce will be created with
+        length equal to half the block size. No random nonce shorter than
+        64 bits will be created though - you must really think through all
+        security consequences of using such a short block size.
+
+      initial_value : posive integer
+        The initial value for the counter. If not present, the cipher will
+        start counting from 0. The value is incremented by one for each block.
+        The counter number is encoded in big endian mode.
+
+      counter : object
+        Instance of ``Crypto.Util.Counter``, which allows full customization
+        of the counter block. This parameter is incompatible to both ``nonce``
+        and ``initial_value``.
+
+    Any other keyword will be passed to the underlying block cipher.
+    See the relevant documentation for details (at least ``key`` will need
+    to be present).
+    """
+
+    cipher_state = factory._create_base_cipher(kwargs)
+
+    counter = kwargs.pop("counter", None)
+    nonce = kwargs.pop("nonce", None)
+    initial_value = kwargs.pop("initial_value", None)
+    if kwargs:
+        raise TypeError("Invalid parameters for CTR mode: %s" % str(kwargs))
+
+    if counter is not None and (nonce, initial_value) != (None, None):
+            raise TypeError("'counter' and 'nonce'/'initial_value'"
+                            " are mutually exclusive")
+
+    if counter is None:
+        # Crypto.Util.Counter is not used
+        if nonce is None:
+            if factory.block_size < 16:
+                raise TypeError("Impossible to create a safe nonce for short"
+                                " block sizes")
+            nonce = get_random_bytes(factory.block_size // 2)
+
+        if initial_value is None:
+            initial_value = 0
+
+        if len(nonce) >= factory.block_size:
+            raise ValueError("Nonce is too long")
+
+        counter_len = factory.block_size - len(nonce)
+        if (1 << (counter_len * 8)) - 1 < initial_value:
+            raise ValueError("Initial counter value is too large")
+
+        return CtrMode(cipher_state,
+                       # initial_counter_block
+                       nonce + long_to_bytes(initial_value, counter_len),
+                       len(nonce),                     # prefix
+                       counter_len,
+                       False)                          # little_endian
+
+    # Crypto.Util.Counter is used
+
+    # 'counter' used to be a callable object, but now it is
+    # just a dictionary for backward compatibility.
+    _counter = dict(counter)
+    try:
+        counter_len = _counter.pop("counter_len")
+        prefix = _counter.pop("prefix")
+        suffix = _counter.pop("suffix")
+        initial_value = _counter.pop("initial_value")
+        little_endian = _counter.pop("little_endian")
+    except KeyError:
+        raise TypeError("Incorrect counter object"
+                        " (use Crypto.Util.Counter.new)")
+
+    # Compute initial counter block
+    words = []
+    while initial_value > 0:
+        words.append(bchr(initial_value & 255))
+        initial_value >>= 8
+    words += [bchr(0)] * max(0, counter_len - len(words))
+    if not little_endian:
+        words.reverse()
+    initial_counter_block = prefix + b("").join(words) + suffix
+
+    if len(initial_counter_block) != factory.block_size:
+        raise ValueError("Size of the counter block (% bytes) must match"
+                         " block size (%d)" % (len(initial_counter_block),
+                                               factory.block_size))
+
+    return CtrMode(cipher_state, initial_counter_block,
+                   len(prefix), counter_len, little_endian)