toxcore/toxencryptsave/toxencryptsave.api.h
iphydf bbdd798256
Fix unresolved reference in toxencryptsave API.
Also, make sure this won't happen again by checking for it in
format-source.
2016-12-14 11:35:43 +00:00

323 lines
10 KiB
C++

%{
/* toxencryptsave.h
*
* Batch encryption functions.
*
* Copyright (C) 2013-2016 Tox Developers. All Rights Reserved.
*
* This file is part of Tox.
*
* Tox is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* Tox is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with Tox. If not, see <http://www.gnu.org/licenses/>.
*
*/
#ifndef TOXENCRYPTSAVE_H
#define TOXENCRYPTSAVE_H
#ifdef __cplusplus
extern "C" {
#endif
#include <stdbool.h>
#include <stddef.h>
#include <stdint.h>
%}
/*******************************************************************************
*
* This module is organized into two parts.
*
* 1. A simple API operating on plain text/cipher text data and a password to
* encrypt or decrypt it.
* 2. A more advanced API that splits key derivation and encryption into two
* separate function calls.
*
* The first part is implemented in terms of the second part and simply calls
* the separate functions in sequence. Since key derivation is very expensive
* compared to the actual encryption, clients that do a lot of crypto should
* prefer the advanced API and reuse pass-key objects.
*
* To use the second part, first derive an encryption key from a password with
* ${tox.pass_Key.derive}, then use the derived key to encrypt the data.
*
* The encrypted data is prepended with a magic number, to aid validity
* checking (no guarantees are made of course). Any data to be decrypted must
* start with the magic number.
*
* Clients should consider alerting their users that, unlike plain data, if
* even one bit becomes corrupted, the data will be entirely unrecoverable.
* Ditto if they forget their password, there is no way to recover the data.
*
*******************************************************************************/
class tox {
/**
* The size of the salt part of a pass-key.
*/
const PASS_SALT_LENGTH = 32;
/**
* The size of the key part of a pass-key.
*/
const PASS_KEY_LENGTH = 32;
/**
* The amount of additional data required to store any encrypted byte array.
* Encrypting an array of N bytes requires N + $PASS_ENCRYPTION_EXTRA_LENGTH
* bytes in the encrypted byte array.
*/
const PASS_ENCRYPTION_EXTRA_LENGTH = 80;
error for key_derivation {
NULL,
/**
* The crypto lib was unable to derive a key from the given passphrase,
* which is usually a lack of memory issue. The functions accepting keys
* do not produce this error.
*/
FAILED,
}
error for encryption {
NULL,
/**
* The crypto lib was unable to derive a key from the given passphrase,
* which is usually a lack of memory issue. The functions accepting keys
* do not produce this error.
*/
KEY_DERIVATION_FAILED,
/**
* The encryption itself failed.
*/
FAILED,
}
error for decryption {
NULL,
/**
* The input data was shorter than $PASS_ENCRYPTION_EXTRA_LENGTH bytes
*/
INVALID_LENGTH,
/**
* The input data is missing the magic number (i.e. wasn't created by this
* module, or is corrupted).
*/
BAD_FORMAT,
/**
* The crypto lib was unable to derive a key from the given passphrase,
* which is usually a lack of memory issue. The functions accepting keys
* do not produce this error.
*/
KEY_DERIVATION_FAILED,
/**
* The encrypted byte array could not be decrypted. Either the data was
* corrupted or the password/key was incorrect.
*/
FAILED,
}
/*******************************************************************************
*
* BEGIN PART 1
*
* The simple API is presented first. If your code spends too much time using
* these functions, consider using the advanced functions instead and caching
* the generated pass-key.
*
*******************************************************************************/
/**
* Encrypts the given data with the given passphrase.
*
* The output array must be at least `plaintext_len + $PASS_ENCRYPTION_EXTRA_LENGTH`
* bytes long. This delegates to ${pass_Key.derive} and
* ${pass_Key.encrypt}.
*
* @param plaintext A byte array of length `plaintext_len`.
* @param plaintext_len The length of the plain text array. May be 0.
* @param passphrase The user-provided password.
* @param passphrase_len The length of the password.
* @param ciphertext The cipher text array to write the encrypted data to.
*
* @return true on success.
*/
static bool pass_encrypt(const uint8_t[plaintext_len] plaintext, const uint8_t[passphrase_len] passphrase, uint8_t *ciphertext)
with error for encryption;
/**
* Decrypts the given data with the given passphrase.
*
* The output array must be at least `ciphertext_len - $PASS_ENCRYPTION_EXTRA_LENGTH`
* bytes long. This delegates to ${pass_Key.decrypt}.
*
* @param ciphertext A byte array of length `ciphertext_len`.
* @param ciphertext_len The length of the cipher text array. May be 0.
* @param passphrase The user-provided password.
* @param passphrase_len The length of the password.
* @param plaintext The plain text array to write the decrypted data to.
*
* @return true on success.
*/
static bool pass_decrypt(const uint8_t[ciphertext_len] ciphertext, const uint8_t[passphrase_len] passphrase, uint8_t *plaintext)
with error for decryption;
/*******************************************************************************
*
* BEGIN PART 2
*
* And now part 2, which does the actual encryption, and can be used to write
* less CPU intensive client code than part one.
*
*******************************************************************************/
class pass_Key {
/**
* This type represents a pass-key.
*
* A pass-key and a password are two different concepts: a password is given
* by the user in plain text. A pass-key is the generated symmetric key used
* for encryption and decryption. It is derived from a salt and the user-
* provided password.
*
* The $this structure is hidden in the implementation. It can be allocated
* using $new and must be deallocated using $free.
*/
struct this;
/**
* Create a new $this. The initial value of it is indeterminate. To
* initialise it, use one of the derive_* functions below.
*/
static this new();
/**
* Deallocate a $this. This function behaves like free(), so NULL is an
* acceptable argument value.
*/
void free();
/**
* Generates a secret symmetric key from the given passphrase.
*
* Be sure to not compromise the key! Only keep it in memory, do not write
* it to disk.
*
* Note that this function is not deterministic; to derive the same key from
* a password, you also must know the random salt that was used. A
* deterministic version of this function is $derive_with_salt.
*
* @param passphrase The user-provided password.
* @param passphrase_len The length of the password.
*
* @return true on success.
*/
bool derive(const uint8_t[passphrase_len] passphrase)
with error for key_derivation;
/**
* Same as above, except use the given salt for deterministic key derivation.
*
* @param passphrase The user-provided password.
* @param passphrase_len The length of the password.
* @param salt An array of at least $PASS_SALT_LENGTH bytes.
*
* @return true on success.
*/
bool derive_with_salt(const uint8_t[passphrase_len] passphrase, const uint8_t[PASS_SALT_LENGTH] salt)
with error for key_derivation;
/**
* Encrypt a plain text with a key produced by $derive or $derive_with_salt.
*
* The output array must be at least `plaintext_len + $PASS_ENCRYPTION_EXTRA_LENGTH`
* bytes long.
*
* @param plaintext A byte array of length `plaintext_len`.
* @param plaintext_len The length of the plain text array. May be 0.
* @param ciphertext The cipher text array to write the encrypted data to.
*
* @return true on success.
*/
const bool encrypt(const uint8_t[plaintext_len] plaintext, uint8_t *ciphertext)
with error for encryption;
/**
* This is the inverse of $encrypt, also using only keys produced by
* $derive or $derive_with_salt.
*
* @param ciphertext A byte array of length `ciphertext_len`.
* @param ciphertext_len The length of the cipher text array. May be 0.
* @param plaintext The plain text array to write the decrypted data to.
*
* @return true on success.
*/
const bool decrypt(const uint8_t[ciphertext_len] ciphertext, uint8_t *plaintext)
with error for decryption;
}
/**
* Retrieves the salt used to encrypt the given data.
*
* The retrieved salt can then be passed to ${pass_Key.derive_with_salt} to
* produce the same key as was previously used. Any data encrypted with this
* module can be used as input.
*
* The cipher text must be at least $PASS_ENCRYPTION_EXTRA_LENGTH bytes in length.
* The salt must be $PASS_SALT_LENGTH bytes in length.
* If the passed byte arrays are smaller than required, the behaviour is
* undefined.
*
* Success does not say anything about the validity of the data, only that
* data of the appropriate size was copied.
*
* @return true on success.
*/
static bool get_salt(const uint8_t *ciphertext, uint8_t[PASS_SALT_LENGTH] salt) {
NULL,
/**
* The input data is missing the magic number (i.e. wasn't created by this
* module, or is corrupted).
*/
BAD_FORMAT,
}
/**
* Determines whether or not the given data is encrypted by this module.
*
* It does this check by verifying that the magic number is the one put in
* place by the encryption functions.
*
* The data must be at least $PASS_ENCRYPTION_EXTRA_LENGTH bytes in length.
* If the passed byte array is smaller than required, the behaviour is
* undefined.
*
* If the cipher text pointer is NULL, this function returns false.
*
* @return true if the data is encrypted by this module.
*/
static bool is_data_encrypted(const uint8_t *data);
}
%{
#ifdef __cplusplus
}
#endif
#endif
%}