NAME
EVP_AEAD_CTX_new,
EVP_AEAD_CTX_free,
EVP_AEAD_CTX_init,
EVP_AEAD_CTX_cleanup,
EVP_AEAD_CTX_open,
EVP_AEAD_CTX_seal,
EVP_AEAD_key_length,
EVP_AEAD_max_overhead,
EVP_AEAD_max_tag_len,
EVP_AEAD_nonce_length,
EVP_aead_aes_128_gcm,
EVP_aead_aes_256_gcm,
EVP_aead_chacha20_poly1305,
EVP_aead_xchacha20_poly1305 —
authenticated encryption with
additional data
SYNOPSIS
#include
<openssl/evp.h>
EVP_AEAD_CTX *
EVP_AEAD_CTX_new(void);
void
EVP_AEAD_CTX_free(EVP_AEAD_CTX
*ctx);
int
EVP_AEAD_CTX_init(EVP_AEAD_CTX
*ctx, const EVP_AEAD *aead,
const unsigned char *key, size_t
key_len, size_t tag_len, ENGINE
*impl);
void
EVP_AEAD_CTX_cleanup(EVP_AEAD_CTX
*ctx);
int
EVP_AEAD_CTX_open(const EVP_AEAD_CTX
*ctx, unsigned char *out, size_t
*out_len, size_t max_out_len,
const unsigned char *nonce, size_t
nonce_len, const unsigned char *in,
size_t in_len, const unsigned char
*ad, size_t ad_len);
int
EVP_AEAD_CTX_seal(const EVP_AEAD_CTX
*ctx, unsigned char *out, size_t
*out_len, size_t max_out_len,
const unsigned char *nonce, size_t
nonce_len, const unsigned char *in,
size_t in_len, const unsigned char
*ad, size_t ad_len);
size_t
EVP_AEAD_key_length(const EVP_AEAD
*aead);
size_t
EVP_AEAD_max_overhead(const EVP_AEAD
*aead);
size_t
EVP_AEAD_max_tag_len(const EVP_AEAD
*aead);
size_t
EVP_AEAD_nonce_length(const EVP_AEAD
*aead);
const EVP_AEAD *
EVP_aead_aes_128_gcm(void);
const EVP_AEAD *
EVP_aead_aes_256_gcm(void);
const EVP_AEAD *
EVP_aead_chacha20_poly1305(void);
const EVP_AEAD *
EVP_aead_xchacha20_poly1305(void);
DESCRIPTION
AEAD (Authenticated Encryption with Additional Data) couples confidentiality and integrity in a single primitive. AEAD algorithms take a key and can then seal and open individual messages. Each message has a unique, per-message nonce and, optionally, additional data which is authenticated but not included in the output.
EVP_AEAD_CTX_new()
allocates a new context for use with
EVP_AEAD_CTX_init(). It can be cleaned up for reuse
with EVP_AEAD_CTX_cleanup() and must be freed with
EVP_AEAD_CTX_free().
EVP_AEAD_CTX_free()
cleans up ctx and frees the space allocated to it.
EVP_AEAD_CTX_init()
initializes the context ctx for the given AEAD
algorithm aead. The impl
argument must be NULL for the default
implementation; other values are currently not supported. Authentication
tags may be truncated by passing a tag length. A
tag_len argument of
EVP_AEAD_DEFAULT_TAG_LENGTH, which has the value 0,
causes the default tag length to be used.
EVP_AEAD_CTX_cleanup()
frees any data allocated for the context ctx. After
EVP_AEAD_CTX_cleanup(), ctx is
in the same state as after EVP_AEAD_CTX_new().
EVP_AEAD_CTX_open()
authenticates the input in and optional additional
data ad, decrypting the input and writing it as output
out. This function may be called (with the same
EVP_AEAD_CTX) concurrently with itself or with
EVP_AEAD_CTX_seal(). At most the number of input
bytes are written as output. In order to ensure success,
max_out_len should be at least the same as the input
length in_len. On successful return
out_len is set to the actual number of bytes written.
The length of the nonce specified with
nonce_len must be equal to the result of
EVP_AEAD_nonce_length for this AEAD.
EVP_AEAD_CTX_open() never results in partial output.
If max_out_len is insufficient, zero will be returned
and out_len will be set to zero. If the input and
output are aliased then out must be <=
in.
EVP_AEAD_CTX_seal()
encrypts and authenticates the input and authenticates any additional data
provided in ad, the encrypted input and authentication
tag being written as output out. This function may be
called (with the same EVP_AEAD_CTX) concurrently with
itself or with EVP_AEAD_CTX_open(). At most
max_out_len bytes are written as output and, in order
to ensure success, this value should be the in_len
plus the result of EVP_AEAD_max_overhead(). On
successful return, out_len is set to the actual number
of bytes written. The length of the nonce specified
with nonce_len must be equal to the result of
EVP_AEAD_nonce_length()
for this AEAD. EVP_AEAD_CTX_seal() never results in
a partial output. If max_out_len is insufficient, zero
will be returned and out_len will be set to zero. If
the input and output are aliased then out must be
<= in.
EVP_AEAD_key_length(),
EVP_AEAD_max_overhead(),
EVP_AEAD_max_tag_len(), and
EVP_AEAD_nonce_length()
provide information about the AEAD algorithm aead.
EVP_AEAD_max_tag_len()
returns the maximum tag length that can be used with the given
aead. This is the largest value that can be passed as
the tag_len argument to
EVP_AEAD_CTX_init(). No built-in
EVP_AEAD object has a maximum tag length larger than
the constant EVP_AEAD_MAX_TAG_LENGTH.
All cipher algorithms have a fixed key length unless otherwise stated. The following ciphers are available:
EVP_aead_aes_128_gcm()- AES-128 in Galois Counter Mode, using a key_len of 16 bytes and a nonce_len of 12 bytes.
EVP_aead_aes_256_gcm()- AES-256 in Galois Counter Mode, using a key_len of 32 bytes and a nonce_len of 12 bytes.
EVP_aead_chacha20_poly1305()- ChaCha20 with a Poly1305 authenticator, using a
key_len of 32 bytes and a
nonce_len of 12 bytes. The constant
EVP_CHACHAPOLY_TLS_TAG_LENspecifies the length of the authentication tag in bytes and has a value of 16. EVP_aead_xchacha20_poly1305()- XChaCha20 with a Poly1305 authenticator, using a key_len of 32 bytes and a nonce_len of 24 bytes.
Unless compatibility with other implementations like OpenSSL or BoringSSL is required, using the EVP_AEAD interface to AEAD ciphers is recommended in preference to the functions documented in the EVP_EncryptInit(3), EVP_aes_256_gcm(3), and EVP_chacha20_poly1305(3) manual pages. The code then becomes transparent to the AEAD cipher used and much more flexible. It is also safer to use as it prevents common mistakes with the EVP APIs.
RETURN VALUES
EVP_AEAD_CTX_new() returns the new
EVP_AEAD_CTX object on success; otherwise
NULL is returned and errno is
set to ENOMEM.
EVP_AEAD_CTX_init(),
EVP_AEAD_CTX_open(), and
EVP_AEAD_CTX_seal() return 1 for success or zero for
failure.
EVP_AEAD_key_length() returns the length
of the key used for this AEAD.
EVP_AEAD_max_overhead() returns the
maximum number of additional bytes added by the act of sealing data with the
AEAD.
EVP_AEAD_max_tag_len() returns the maximum
tag length when using this AEAD.
EVP_AEAD_nonce_length() returns the length
of the per-message nonce.
EXAMPLES
Encrypt a string using ChaCha20-Poly1305:
const EVP_AEAD *aead = EVP_aead_chacha20_poly1305();
static const unsigned char nonce[32] = {0};
size_t buf_len, nonce_len;
EVP_AEAD_CTX *ctx;
ctx = EVP_AEAD_CTX_new();
EVP_AEAD_CTX_init(ctx, aead, key32, EVP_AEAD_key_length(aead),
EVP_AEAD_DEFAULT_TAG_LENGTH, NULL);
nonce_len = EVP_AEAD_nonce_length(aead);
EVP_AEAD_CTX_seal(ctx, out, &out_len, BUFSIZE, nonce,
nonce_len, in, in_len, NULL, 0);
EVP_AEAD_CTX_free(ctx);
SEE ALSO
STANDARDS
A. Langley, W. Chang, N. Mavrogiannopoulos, J. Strombergson, and S. Josefsson, ChaCha20-Poly1305 Cipher Suites for Transport Layer Security (TLS), RFC 7905, June 2016.
S. Arciszewski, XChaCha: eXtended-nonce ChaCha and AEAD_XChaCha20_Poly1305, draft-arciszewski-xchacha-02, October 2018.
HISTORY
AEAD is based on the implementation by Adam Langley for Chromium/BoringSSL and first appeared in OpenBSD 5.6.
EVP_AEAD_CTX_new() and
EVP_AEAD_CTX_free() first appeared in
OpenBSD 7.1.
CAVEATS
The original publications and code by Adam Langley used a modified AEAD construction that is incompatible with the common style used by AEAD in TLS and incompatible with RFC 7905:
A. Langley and W. Chang, ChaCha20 and Poly1305 based Cipher Suites for TLS, draft-agl-tls-chacha20poly1305-04, November 2013.
Y. Nir and A. Langley, ChaCha20 and Poly1305 for IETF Protocols, RFC 8439, June 2018.
In particular, the original version used a nonce_len of 8 bytes.