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Glossary ======== .. glossary:: :sorted: plaintext User-readable data you care about. ciphertext The encoded data, it's not user readable. Potential attackers are able to see this. encryption The process of converting plaintext to ciphertext. decryption The process of converting ciphertext to plaintext. key Secret data is encoded with a function using this key. Sometimes multiple keys are used. These **must** be kept secret, if a key is exposed to an attacker, any data encrypted with it will be exposed. symmetric cryptography Cryptographic operations where encryption and decryption use the same key. public-key cryptography asymmetric cryptography Cryptographic operations where encryption and decryption use different keys. There are separate encryption and decryption keys. Typically encryption is performed using a :term:`public key`, and it can then be decrypted using a :term:`private key`. Asymmetric cryptography can also be used to create signatures, which can be generated with a :term:`private key` and verified with a :term:`public key`. public key This is one of two keys involved in :term:`public-key cryptography`. It can be used to encrypt messages for someone possessing the corresponding :term:`private key` and to verify signatures created with the corresponding :term:`private key`. This can be distributed publicly, hence the name. private key This is one of two keys involved in :term:`public-key cryptography`. It can be used to decrypt messages which were encrypted with the corresponding :term:`public key`, as well as to create signatures, which can be verified with the corresponding :term:`public key`. These **must** be kept secret, if they are exposed, all encrypted messages are compromised, and an attacker will be able to forge signatures. authentication The process of verifying that a message was created by a specific individual (or program). Like encryption, authentication can be either symmetric or asymmetric. Authentication is necessary for effective encryption. ciphertext indistinguishability This is a property of encryption systems whereby two encrypted messages aren't distinguishable without knowing the encryption key. This is considered a basic, necessary property for a working encryption system. text This type corresponds to ``unicode`` on Python 2 and ``str`` on Python 3. This is equivalent to ``six.text_type``. nonce A nonce is a **n**\ umber used **once**. Nonces are used in many cryptographic protocols. Generally, a nonce does not have to be secret or unpredictable, but it must be unique. A nonce is often a random or pseudo-random number (see :doc:`Random number generation </random-numbers>`). Since a nonce does not have to be unpredictable, it can also take a form of a counter. opaque key An opaque key is a type of key that allows you to perform cryptographic operations such as encryption, decryption, signing, and verification, but does not allow access to the key itself. Typically an opaque key is loaded from a `hardware security module`_ (HSM). A-label The ASCII compatible encoded (ACE) representation of an internationalized (unicode) domain name. A-labels begin with the prefix ``xn--``. To create an A-label from a unicode domain string use a library like `idna`_. bits A bit is binary value -- a value that has only two possible states. Typically binary values are represented visually as 0 or 1, but remember that their actual value is not a printable character. A byte on modern computers is 8 bits and represents 256 possible values. In cryptographic applications when you see something say it requires a 128 bit key, you can calculate the number of bytes by dividing by 8. 128 divided by 8 is 16, so a 128 bit key is a 16 byte key. U-label The presentational unicode form of an internationalized domain name. U-labels use unicode characters outside the ASCII range and are encoded as A-labels when stored in certificates. .. _`hardware security module`: https://en.wikipedia.org/wiki/Hardware_security_module .. _`idna`: https://pypi.org/project/idna/