.. hazmat:: Symmetric Encryption ==================== .. currentmodule:: cryptography.hazmat.primitives.block .. testsetup:: import binascii key = binascii.unhexlify(b"0" * 32) iv = binascii.unhexlify(b"0" * 32) Symmetric encryption is a way to encrypt (hide the plaintext value) material where the encrypter and decrypter both use the same key. .. class:: BlockCipher(cipher, mode) Block ciphers work by encrypting content in chunks, often 64- or 128-bits. They combine an underlying algorithm (such as AES), with a mode (such as CBC, CTR, or GCM). A simple example of encrypting (and then decrypting) content with AES is: .. doctest:: >>> from cryptography.hazmat.primitives.block import BlockCipher, ciphers, modes >>> cipher = BlockCipher(ciphers.AES(key), modes.CBC(iv)) >>> encryptor = cipher.encryptor() >>> ct = encryptor.update(b"a secret message") + encryptor.finalize() >>> decryptor = cipher.decryptor() >>> decryptor.update(ct) + decryptor.finalize() 'a secret message' :param cipher: One of the ciphers described below. :param mode: One of the modes described below. .. method:: encryptor() :return: An encrypting :class:`~cryptography.hazmat.primitives.interfaces.CipherContext` provider. .. method:: decryptor() :return: A decrypting :class:`~cryptography.hazmat.primitives.interfaces.CipherContext` provider. .. currentmodule:: cryptography.hazmat.primitives.interfaces .. class:: CipherContext When calling ``encryptor()`` or ``decryptor()`` on a ``BlockCipher`` object you will receive a return object conforming to the ``CipherContext`` interface. You can then call ``update(data)`` with data until you have fed everything into the context. Once that is done call ``finalize()`` to finish the operation and obtain the remainder of the data. .. method:: update(data) :param bytes data: The data you wish to pass into the context. :return bytes: Returns the data that was encrypted or decrypted. When the ``BlockCipher`` was constructed in a mode turns it into a stream cipher (e.g. :class:`cryptography.hazmat.primitives.block.modes.CTR`), this will return bytes immediately, however in other modes it will return chunks, whose size is determined by the cipher's block size. .. method:: finalize() :return bytes: Returns the remainder of the data. Ciphers ~~~~~~~ .. currentmodule:: cryptography.hazmat.primitives.block.ciphers .. class:: AES(key) AES (Advanced Encryption Standard) is a block cipher standardized by NIST. AES is both fast, and cryptographically strong. It is a good default choice for encryption. :param bytes key: The secret key, either ``128``, ``192``, or ``256`` bits. This must be kept secret. .. class:: Camellia(key) Camellia is a block cipher approved for use by CRYPTREC and ISO/IEC. It is considered to have comparable security and performance to AES, but is not as widely studied or deployed. :param bytes key: The secret key, either ``128``, ``192``, or ``256`` bits. This must be kept secret. .. class:: TripleDES(key) Triple DES (Data Encryption Standard), sometimes refered to as 3DES, is a block cipher standardized by NIST. Triple DES has known cryptoanalytic flaws, however none of them currently enable a practical attack. Nonetheless, Triples DES is not reccomended for new applications because it is incredibly slow; old applications should consider moving away from it. :param bytes key: The secret key, either ``64``, ``128``, or ``192`` bits (note that DES functionally uses ``56``, ``112``, or ``168`` bits of the key, there is a parity byte in each component of the key), in some materials these are referred to as being up to three separate keys (each ``56`` bits long), they can simply be concatenated to produce the full key. This must be kept secret. .. class:: CAST5(key) CAST5 (also known as CAST-128) is a block cipher approved for use in the Canadian government by their Communications Security Establishment. It is a variable key length cipher and supports keys from 40-128 bits in length. :param bytes key: The secret key, 40-128 bits in length (in increments of 8). This must be kept secret. Weak Ciphers ------------ .. warning:: These ciphers are considered weak for a variety of reasons. New applications should avoid their use and existing applications should strongly consider migrating away. .. class:: Blowfish(key) Blowfish is a block cipher developed by Bruce Schneier. It is known to be susceptible to attacks when using weak keys. The author has recommended that users of Blowfish move to newer algorithms like :class:`AES`. :param bytes key: The secret key, 32-448 bits in length (in increments of 8). This must be kept secret. Modes ~~~~~ .. currentmodule:: cryptography.hazmat.primitives.block.modes .. class:: CBC(initialization_vector) CBC (Cipher block chaining) is a mode of operation for block ciphers. It is considered cryptographically strong. :param bytes initialization_vector: Must be random bytes. They do not need to be kept secret (they can be included in a transmitted message). Must be the same number of bytes as the ``block_size`` of the cipher. Do not reuse an ``initialization_vector`` with a given ``key``. .. class:: CTR(nonce) .. warning:: Counter mode is not recommended for use with block ciphers that have a block size of less than 128-bits. CTR (Counter) is a mode of operation for block ciphers. It is considered cryptographically strong. It transforms a block cipher into a stream cipher. :param bytes nonce: Should be random bytes. It is critical to never reuse a ``nonce`` with a given key. Any reuse of a nonce with the same key compromises the security of every message encrypted with that key. Must be the same number of bytes as the ``block_size`` of the cipher with a given key. The nonce does not need to be kept secret and may be included alongside the ciphertext. .. class:: OFB(initialization_vector) OFB (Output Feedback) is a mode of operation for block ciphers. It transforms a block cipher into a stream cipher. :param bytes initialization_vector: Must be random bytes. They do not need to be kept secret (they can be included in a transmitted message). Must be the same number of bytes as the ``block_size`` of the cipher. Do not reuse an ``initialization_vector`` with a given ``key``. .. class:: CFB(initialization_vector) CFB (Cipher Feedback) is a mode of operation for block ciphers. It transforms a block cipher into a stream cipher. :param bytes initialization_vector: Must be random bytes. They do not need to be kept secret (they can be included in a transmitted message). Must be the same number of bytes as the ``block_size`` of the cipher. Do not reuse an ``initialization_vector`` with a given ``key``. Insecure Modes -------------- .. warning:: These modes are insecure. New applications should never make use of them, and existing applications should strongly consider migrating away. .. class:: ECB() ECB (Electronic Code Book) is the simplest mode of operation for block ciphers. Each block of data is encrypted in the same way. This means identical plaintext blocks will always result in identical ciphertext blocks, and thus result in information leakage