- ext
- ssl
- ssl.pl
- crypto.pl -- Cryptography and authentication library
- crypto_n_random_bytes/2
- crypto_data_hash/3
- crypto_file_hash/3
- crypto_context_new/2
- crypto_data_context/3
- crypto_context_hash/2
- crypto_open_hash_stream/3
- crypto_stream_hash/2
- crypto_password_hash/2
- crypto_password_hash/3
- crypto_data_hkdf/4
- ecdsa_sign/4
- ecdsa_verify/4
- hex_bytes/2
- rsa_private_decrypt/4
- rsa_private_encrypt/4
- rsa_public_decrypt/4
- rsa_public_encrypt/4
- rsa_sign/4
- rsa_verify/4
- crypto_data_decrypt/6
- crypto_data_encrypt/6
- crypto_modular_inverse/3
- crypto_generate_prime/3
- crypto_is_prime/2
- crypto_name_curve/2
- crypto_curve_order/2
- crypto_curve_generator/2
- crypto_curve_scalar_mult/4
- xmldsig.pl -- XML Digital signature
- xmlenc.pl -- XML encryption library
- ssl
- crypto_data_encrypt(+PlainText, +Algorithm, +Key, +IV, -CipherText, +Options)
- Encrypt the given PlainText, using the symmetric algorithm
Algorithm, key Key, and initialization vector (or nonce) IV, to give
CipherText.
PlainText must be a string, atom or list of codes or characters, and CipherText is created as a string. Key and IV are typically lists of bytes, though atoms and strings are also permitted. Algorithm must be an algorithm which your copy of OpenSSL knows about.
Keys and IVs can be chosen at random (using for example crypto_n_random_bytes/2) or derived from input keying material (IKM) using for example crypto_data_hkdf/4. This input is often a shared secret, such as a negotiated point on an elliptic curve, or the hash that was computed from a password via crypto_password_hash/3 with a freshly generated and specified salt.
Reusing the same combination of Key and IV typically leaks at least some information about the plaintext. For example, identical plaintexts will then correspond to identical ciphertexts. For some algorithms, reusing an IV with the same Key has disastrous results and can cause the loss of all properties that are otherwise guaranteed. Especially in such cases, an IV is also called a nonce (number used once). If an IV is not needed for your algorithm (such as
'aes-128-ecb'
) then any value can be provided as it will be ignored by the underlying implementation. Note that such algorithms do not provide semantic security and are thus insecure. You should use stronger algorithms instead.It is safe to store and transfer the used initialization vector (or nonce) in plain text, but the key must be kept secret.
Commonly used algorithms include:
'chacha20-poly1305'
- A powerful and efficient authenticated encryption scheme, providing secrecy and at the same time reliable protection against undetected modifications of the encrypted data. This is a very good choice for virtually all use cases. It is a stream cipher and can encrypt data of any length up to 256 GB. Further, the encrypted data has exactly the same length as the original, and no padding is used. It requires OpenSSL 1.1.0 or greater. See below for an example.
'aes-128-gcm'
- Also an authenticated encryption scheme. It uses a 128-bit (i.e., 16 bytes) key and a 96-bit (i.e., 12 bytes) nonce. It requires OpenSSL 1.1.0 or greater.
'aes-128-cbc'
- A block cipher that provides secrecy, but does not protect against unintended modifications of the cipher text. This algorithm uses 128-bit (16 bytes) keys and initialization vectors. It works with all supported versions of OpenSSL. If possible, consider using an authenticated encryption scheme instead.
Options:
- encoding(+Encoding)
- Encoding to use for PlainText. Default is
utf8
. Alternatives areutf8
andoctet
. - padding(+PaddingScheme)
- For block ciphers, the padding scheme to use. Default is
block
. You can disable padding by supplyingnone
here. If padding is disabled for block ciphers, then the length of the ciphertext must be a multiple of the block size. - tag(-List)
- For authenticated encryption schemes, List is unified with a list of bytes holding the tag. This tag must be provided for decryption. Authenticated encryption requires OpenSSL 1.1.0 or greater.
- tag_length(+Length)
- For authenticated encryption schemes, the desired length of the tag, specified as the number of bytes. The default is 16. Smaller numbers are not recommended.
For example, with OpenSSL 1.1.0 and greater, we can use the ChaCha20 stream cipher with the Poly1305 authenticator. This cipher uses a 256-bit key and a 96-bit nonce, i.e., 32 and 12 bytes, respectively:
?- Algorithm = 'chacha20-poly1305', crypto_n_random_bytes(32, Key), crypto_n_random_bytes(12, IV), crypto_data_encrypt("this is some input", Algorithm, Key, IV, CipherText, [tag(Tag)]), crypto_data_decrypt(CipherText, Algorithm, Key, IV, RecoveredText, [tag(Tag)]). Algorithm = 'chacha20-poly1305', Key = [65, 147, 140, 197, 27, 60, 198, 50, 218|...], IV = [253, 232, 174, 84, 168, 208, 218, 168, 228|...], CipherText = <binary string>, Tag = [248, 220, 46, 62, 255, 9, 178, 130, 250|...], RecoveredText = "this is some input".
In this example, we use crypto_n_random_bytes/2 to generate a key and nonce from cryptographically secure random numbers. For repeated applications, you must ensure that a nonce is only used once together with the same key. Note that for authenticated encryption schemes, the tag that was computed during encryption is necessary for decryption. It is safe to store and transfer the tag in plain text.
- See also
- - crypto_data_decrypt/6.
- - hex_bytes/2 for conversion between bytes and hex encoding.