/*
ChibiOS - Copyright (C) 2006..2018 Giovanni Di Sirio
Licensed under the Apache License, Version 2.0 (the "License");
you may not use this file except in compliance with the License.
You may obtain a copy of the License at
http://www.apache.org/licenses/LICENSE-2.0
Unless required by applicable law or agreed to in writing, software
distributed under the License is distributed on an "AS IS" BASIS,
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
See the License for the specific language governing permissions and
limitations under the License.
*/
/**
* @file hal_crypto.c
* @brief Cryptographic Driver code.
*
* @addtogroup CRYPTO
* @{
*/
#include "hal.h"
#if (HAL_USE_CRY == TRUE) || defined(__DOXYGEN__)
/*===========================================================================*/
/* Driver local definitions. */
/*===========================================================================*/
/*===========================================================================*/
/* Driver exported variables. */
/*===========================================================================*/
/*===========================================================================*/
/* Driver local variables and types. */
/*===========================================================================*/
/*===========================================================================*/
/* Driver local functions. */
/*===========================================================================*/
/*===========================================================================*/
/* Driver exported functions. */
/*===========================================================================*/
/**
* @brief Cryptographic Driver initialization.
* @note This function is implicitly invoked by @p halInit(), there is
* no need to explicitly initialize the driver.
*
* @init
*/
void cryInit(void) {
#if HAL_CRY_ENFORCE_FALLBACK == FALSE
cry_lld_init();
#endif
}
/**
* @brief Initializes the standard part of a @p CRYDriver structure.
*
* @param[out] cryp pointer to the @p CRYDriver object
*
* @init
*/
void cryObjectInit(CRYDriver *cryp) {
cryp->state = CRY_STOP;
cryp->config = NULL;
#if defined(CRY_DRIVER_EXT_INIT_HOOK)
CRY_DRIVER_EXT_INIT_HOOK(cryp);
#endif
}
/**
* @brief Configures and activates the cryptographic peripheral.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] config pointer to the @p CRYConfig object. Depending
* on the implementation the value can be @p NULL.
*
* @api
*/
void cryStart(CRYDriver *cryp, const CRYConfig *config) {
osalDbgCheck(cryp != NULL);
osalSysLock();
osalDbgAssert((cryp->state == CRY_STOP) || (cryp->state == CRY_READY),
"invalid state");
cryp->config = config;
#if HAL_CRY_ENFORCE_FALLBACK == FALSE
cry_lld_start(cryp);
#endif
cryp->state = CRY_READY;
osalSysUnlock();
}
/**
* @brief Deactivates the cryptographic peripheral.
*
* @param[in] cryp pointer to the @p CRYDriver object
*
* @api
*/
void cryStop(CRYDriver *cryp) {
osalDbgCheck(cryp != NULL);
osalSysLock();
osalDbgAssert((cryp->state == CRY_STOP) || (cryp->state == CRY_READY),
"invalid state");
#if HAL_CRY_ENFORCE_FALLBACK == FALSE
cry_lld_stop(cryp);
#endif
cryp->config = NULL;
cryp->state = CRY_STOP;
osalSysUnlock();
}
/**
* @brief Initializes the AES transient key.
* @note It is the underlying implementation to decide which key sizes are
* allowable.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] size key size in bytes
* @param[in] keyp pointer to the key data
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the algorithm is unsupported.
* @retval CRY_ERR_INV_KEY_SIZE if the specified key size is invalid for
* the specified algorithm.
*
* @api
*/
cryerror_t cryLoadAESTransientKey(CRYDriver *cryp,
size_t size,
const uint8_t *keyp) {
osalDbgCheck((cryp != NULL) && (keyp != NULL));
#if CRY_LLD_SUPPORTS_AES == TRUE
return cry_lld_aes_loadkey(cryp, size, keyp);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_aes_loadkey(cryp, size, keyp);
#else
(void)cryp;
(void)size;
(void)keyp;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Encryption of a single block using AES.
* @note The implementation of this function must guarantee that it can
* be called from any context.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] key_id the key to be used for the operation, zero is
* the transient key, other values are keys stored
* in an unspecified way
* @param[in] in buffer containing the input plaintext
* @param[out] out buffer for the output cyphertext
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_INV_KEY_TYPE the selected key is invalid for this operation.
* @retval CRY_ERR_INV_KEY_ID if the specified key identifier is invalid
* or refers to an empty key slot.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @special
*/
cryerror_t cryEncryptAES(CRYDriver *cryp,
crykey_t key_id,
const uint8_t *in,
uint8_t *out) {
osalDbgCheck((cryp != NULL) && (in != NULL) && (out != NULL));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_AES == TRUE
return cry_lld_encrypt_AES(cryp, key_id, in, out);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_encrypt_AES(cryp, key_id, in, out);
#else
(void)cryp;
(void)key_id;
(void)in;
(void)out;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Decryption of a single block using AES.
* @note The implementation of this function must guarantee that it can
* be called from any context.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] key_id the key to be used for the operation, zero is
* the transient key, other values are keys stored
* in an unspecified way
* @param[in] in buffer containing the input cyphertext
* @param[out] out buffer for the output plaintext
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_INV_KEY_TYPE the selected key is invalid for this operation.
* @retval CRY_ERR_INV_KEY_ID if the specified key identifier is invalid
* or refers to an empty key slot.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @special
*/
cryerror_t cryDecryptAES(CRYDriver *cryp,
crykey_t key_id,
const uint8_t *in,
uint8_t *out) {
osalDbgCheck((cryp != NULL) && (in != NULL) && (out != NULL));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_AES == TRUE
return cry_lld_decrypt_AES(cryp, key_id, in, out);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_decrypt_AES(cryp, key_id, in, out);
#else
(void)cryp;
(void)key_id;
(void)in;
(void)out;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Encryption operation using AES-ECB.
* @note The function operates on data buffers whose length is a multiple
* of an AES block, this means that padding must be done by the
* caller.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] key_id the key to be used for the operation, zero is
* the transient key, other values are keys stored
* in an unspecified way
* @param[in] size size of both buffers, this number must be a
* multiple of 16
* @param[in] in buffer containing the input plaintext
* @param[out] out buffer for the output cyphertext
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_INV_KEY_TYPE the selected key is invalid for this operation.
* @retval CRY_ERR_INV_KEY_ID if the specified key identifier is invalid
* or refers to an empty key slot.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t cryEncryptAES_ECB(CRYDriver *cryp,
crykey_t key_id,
size_t size,
const uint8_t *in,
uint8_t *out) {
osalDbgCheck((cryp != NULL) && (in != NULL) && (out != NULL) &&
((size & (size_t)15) == (size_t)0));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_AES_ECB == TRUE
return cry_lld_encrypt_AES_ECB(cryp, key_id, size, in, out);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_encrypt_AES_ECB(cryp, key_id, size, in, out);
#else
(void)cryp;
(void)key_id;
(void)size;
(void)in;
(void)out;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Decryption operation using AES-ECB.
* @note The function operates on data buffers whose length is a multiple
* of an AES block, this means that padding must be done by the
* caller.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] key_id the key to be used for the operation, zero is
* the transient key, other values are keys stored
* in an unspecified way
* @param[in] size size of both buffers, this number must be a
* multiple of 16
* @param[in] in buffer containing the input cyphertext
* @param[out] out buffer for the output plaintext
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_INV_KEY_TYPE the selected key is invalid for this operation.
* @retval CRY_ERR_INV_KEY_ID if the specified key identifier is invalid
* or refers to an empty key slot.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t cryDecryptAES_ECB(CRYDriver *cryp,
crykey_t key_id,
size_t size,
const uint8_t *in,
uint8_t *out) {
osalDbgCheck((cryp != NULL) && (in != NULL) && (out != NULL) &&
((size & (size_t)15) == (size_t)0));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_AES_ECB == TRUE
return cry_lld_decrypt_AES_ECB(cryp, key_id, size, in, out);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_decrypt_AES_ECB(cryp, key_id, size, in, out);
#else
(void)cryp;
(void)key_id;
(void)size;
(void)in;
(void)out;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Encryption operation using AES-CBC.
* @note The function operates on data buffers whose length is a multiple
* of an AES block, this means that padding must be done by the
* caller.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] key_id the key to be used for the operation, zero is
* the transient key, other values are keys stored
* in an unspecified way
* @param[in] size size of both buffers, this number must be a
* multiple of 16
* @param[in] in buffer containing the input plaintext
* @param[out] out buffer for the output cyphertext
* @param[in] iv 128 bits input vector
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_INV_KEY_TYPE the selected key is invalid for this operation.
* @retval CRY_ERR_INV_KEY_ID if the specified key identifier is invalid
* or refers to an empty key slot.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t cryEncryptAES_CBC(CRYDriver *cryp,
crykey_t key_id,
size_t size,
const uint8_t *in,
uint8_t *out,
const uint8_t *iv) {
osalDbgCheck((cryp != NULL) && (in != NULL) && (out != NULL) &&
(iv != NULL) && ((size & (size_t)15) == (size_t)0));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_AES_CBC == TRUE
return cry_lld_encrypt_AES_CBC(cryp, key_id, size, in, out, iv);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_encrypt_AES_CBC(cryp, key_id, size, in, out, iv);
#else
(void)cryp;
(void)key_id;
(void)size;
(void)in;
(void)out;
(void)iv;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Decryption operation using AES-CBC.
* @note The function operates on data buffers whose length is a multiple
* of an AES block, this means that padding must be done by the
* caller.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] key_id the key to be used for the operation, zero is
* the transient key, other values are keys stored
* in an unspecified way
* @param[in] size size of both buffers, this number must be a
* multiple of 16
* @param[in] in buffer containing the input cyphertext
* @param[out] out buffer for the output plaintext
* @param[in] iv 128 bits input vector
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_INV_KEY_TYPE the selected key is invalid for this operation.
* @retval CRY_ERR_INV_KEY_ID if the specified key identifier is invalid
* or refers to an empty key slot.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t cryDecryptAES_CBC(CRYDriver *cryp,
crykey_t key_id,
size_t size,
const uint8_t *in,
uint8_t *out,
const uint8_t *iv) {
osalDbgCheck((cryp != NULL) && (in != NULL) && (out != NULL) &&
(iv != NULL) && ((size & (size_t)15) == (size_t)0));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_AES_CBC == TRUE
return cry_lld_decrypt_AES_CBC(cryp, key_id, size, in, out, iv);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_decrypt_AES_CBC(cryp, key_id, size, in, out, iv);
#else
(void)cryp;
(void)key_id;
(void)size;
(void)in;
(void)out;
(void)iv;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Encryption operation using AES-CFB.
* @note The function operates on data buffers whose length is a multiple
* of an AES block, this means that padding must be done by the
* caller.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] key_id the key to be used for the operation, zero is
* the transient key, other values are keys stored
* in an unspecified way
* @param[in] size size of both buffers, this number must be a
* multiple of 16
* @param[in] in buffer containing the input plaintext
* @param[out] out buffer for the output cyphertext
* @param[in] iv 128 bits input vector
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_INV_KEY_TYPE the selected key is invalid for this operation.
* @retval CRY_ERR_INV_KEY_ID if the specified key identifier is invalid
* or refers to an empty key slot.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t cryEncryptAES_CFB(CRYDriver *cryp,
crykey_t key_id,
size_t size,
const uint8_t *in,
uint8_t *out,
const uint8_t *iv) {
osalDbgCheck((cryp != NULL) && (in != NULL) && (out != NULL) &&
(iv != NULL) && ((size & (size_t)15) == (size_t)0));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_AES_CFB == TRUE
return cry_lld_encrypt_AES_CFB(cryp, key_id, size, in, out, iv);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_encrypt_AES_CFB(cryp, key_id, size, in, out, iv);
#else
(void)cryp;
(void)key_id;
(void)size;
(void)in;
(void)out;
(void)iv;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Decryption operation using AES-CFB.
* @note The function operates on data buffers whose length is a multiple
* of an AES block, this means that padding must be done by the
* caller.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] key_id the key to be used for the operation, zero is
* the transient key, other values are keys stored
* in an unspecified way
* @param[in] size size of both buffers, this number must be a
* multiple of 16
* @param[in] in buffer containing the input cyphertext
* @param[out] out buffer for the output plaintext
* @param[in] iv 128 bits input vector
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_INV_KEY_TYPE the selected key is invalid for this operation.
* @retval CRY_ERR_INV_KEY_ID if the specified key identifier is invalid
* or refers to an empty key slot.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t cryDecryptAES_CFB(CRYDriver *cryp,
crykey_t key_id,
size_t size,
const uint8_t *in,
uint8_t *out,
const uint8_t *iv) {
osalDbgCheck((cryp != NULL) && (in != NULL) && (out != NULL) &&
(iv != NULL) && ((size & (size_t)15) == (size_t)0));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_AES_CFB == TRUE
return cry_lld_decrypt_AES_CFB(cryp, key_id, size, in, out, iv);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_decrypt_AES_CFB(cryp, key_id, size, in, out, iv);
#else
(void)cryp;
(void)key_id;
(void)size;
(void)in;
(void)out;
(void)iv;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Encryption operation using AES-CTR.
* @note The function operates on data buffers whose length is a multiple
* of an AES block, this means that padding must be done by the
* caller.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] key_id the key to be used for the operation, zero is
* the transient key, other values are keys stored
* in an unspecified way
* @param[in] size size of both buffers, this number must be a
* multiple of 16
* @param[in] in buffer containing the input plaintext
* @param[out] out buffer for the output cyphertext
* @param[in] iv 128 bits input vector + counter, it contains
* a 96 bits IV and a 32 bits counter
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_INV_KEY_TYPE the selected key is invalid for this operation.
* @retval CRY_ERR_INV_KEY_ID if the specified key identifier is invalid
* or refers to an empty key slot.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t cryEncryptAES_CTR(CRYDriver *cryp,
crykey_t key_id,
size_t size,
const uint8_t *in,
uint8_t *out,
const uint8_t *iv) {
osalDbgCheck((cryp != NULL) && (in != NULL) && (out != NULL) &&
(iv != NULL) && ((size & (size_t)15) == (size_t)0));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_AES_CTR == TRUE
return cry_lld_encrypt_AES_CTR(cryp, key_id, size, in, out, iv);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_encrypt_AES_CTR(cryp, key_id, size, in, out, iv);
#else
(void)cryp;
(void)key_id;
(void)size;
(void)in;
(void)out;
(void)iv;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Decryption operation using AES-CTR.
* @note The function operates on data buffers whose length is a multiple
* of an AES block, this means that padding must be done by the
* caller.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] key_id the key to be used for the operation, zero is
* the transient key, other values are keys stored
* in an unspecified way
* @param[in] size size of both buffers, this number must be a
* multiple of 16
* @param[in] in buffer containing the input cyphertext
* @param[out] out buffer for the output plaintext
* @param[in] iv 128 bits input vector + counter, it contains
* a 96 bits IV and a 32 bits counter
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_INV_KEY_TYPE the selected key is invalid for this operation.
* @retval CRY_ERR_INV_KEY_ID if the specified key identifier is invalid
* or refers to an empty key slot.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t cryDecryptAES_CTR(CRYDriver *cryp,
crykey_t key_id,
size_t size,
const uint8_t *in,
uint8_t *out,
const uint8_t *iv) {
osalDbgCheck((cryp != NULL) && (in != NULL) && (out != NULL) &&
(iv != NULL) && ((size & (size_t)15) == (size_t)0));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_AES_CTR == TRUE
return cry_lld_decrypt_AES_CTR(cryp, key_id, size, in, out, iv);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_decrypt_AES_CTR(cryp, key_id, size, in, out, iv);
#else
(void)cryp;
(void)key_id;
(void)size;
(void)in;
(void)out;
(void)iv;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Encryption operation using AES-GCM.
* @note The function operates on data buffers whose length is a multiple
* of an AES block, this means that padding must be done by the
* caller.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] key_id the key to be used for the operation, zero is
* the transient key, other values are keys stored
* in an unspecified way
* @param[in] auth_size size of the data buffer to be authenticated
* @param[in] auth_in buffer containing the data to be authenticated
* @param[in] text_size size of the text buffer, this number must be a
* multiple of 16
* @param[in] text_in buffer containing the input plaintext
* @param[out] text_out buffer for the output cyphertext
* @param[in] iv 128 bits input vector
* @param[in] tag_size size of the authentication tag, this number
* must be between 1 and 16
* @param[out] tag_out buffer for the generated authentication tag
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_INV_KEY_TYPE the selected key is invalid for this operation.
* @retval CRY_ERR_INV_KEY_ID if the specified key identifier is invalid
* or refers to an empty key slot.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t cryEncryptAES_GCM(CRYDriver *cryp,
crykey_t key_id,
size_t auth_size,
const uint8_t *auth_in,
size_t text_size,
const uint8_t *text_in,
uint8_t *text_out,
const uint8_t *iv,
size_t tag_size,
uint8_t *tag_out) {
osalDbgCheck((cryp != NULL) && (auth_in != NULL) &&
(text_size > (size_t)0) &&
((text_size & (size_t)15) == (size_t)0) &&
(text_in != NULL) && (text_out != NULL) && (iv != NULL) &&
(tag_size >= (size_t)1) && (tag_size <= (size_t)16) &&
(tag_out != NULL));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_AES_GCM== TRUE
return cry_lld_encrypt_AES_GCM(cryp, key_id, auth_size, auth_in,
text_size, text_in, text_out, iv,
tag_size, tag_out);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_encrypt_AES_GCM(cryp, key_id, auth_size, auth_in,
text_size, text_in, text_out, iv,
tag_size, tag_out);
#else
(void)cryp;
(void)key_id;
(void)auth_size;
(void)auth_in;
(void)text_size;
(void)text_in;
(void)text_out;
(void)iv;
(void)tag_size;
(void)tag_out;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Decryption operation using AES-GCM.
* @note The function operates on data buffers whose length is a multiple
* of an AES block, this means that padding must be done by the
* caller.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] key_id the key to be used for the operation, zero is
* the transient key, other values are keys stored
* in an unspecified way
* @param[in] auth_size size of the data buffer to be authenticated
* @param[in] auth_in buffer containing the data to be authenticated
* @param[in] text_size size of the text buffer, this number must be a
* multiple of 16
* @param[in] text_in buffer containing the input plaintext
* @param[out] text_out buffer for the output cyphertext
* @param[in] iv 128 bits input vector
* @param[in] tag_size size of the authentication tag, this number
* must be between 1 and 16
* @param[in] tag_in buffer for the generated authentication tag
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_INV_KEY_TYPE the selected key is invalid for this operation.
* @retval CRY_ERR_INV_KEY_ID if the specified key identifier is invalid
* or refers to an empty key slot.
* @retval CRY_ERR_AUTH_FAILED authentication failed
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t cryDecryptAES_GCM(CRYDriver *cryp,
crykey_t key_id,
size_t auth_size,
const uint8_t *auth_in,
size_t text_size,
const uint8_t *text_in,
uint8_t *text_out,
const uint8_t *iv,
size_t tag_size,
const uint8_t *tag_in) {
osalDbgCheck((cryp != NULL) && (auth_in != NULL) &&
(text_size > (size_t)0) &&
((text_size & (size_t)15) == (size_t)0) &&
(text_in != NULL) && (text_out != NULL) && (iv != NULL) &&
(tag_size >= (size_t)1) && (tag_size <= (size_t)16) &&
(tag_in != NULL));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_AES_GCM== TRUE
return cry_lld_decrypt_AES_GCM(cryp, key_id, auth_size, auth_in,
text_size, text_in, text_out, iv,
tag_size, tag_in);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_decrypt_AES_GCM(cryp, key_id, auth_size, auth_in,
text_size, text_in, text_out, iv,
tag_size, tag_in);
#else
(void)cryp;
(void)key_id;
(void)auth_size;
(void)auth_in;
(void)text_size;
(void)text_in;
(void)text_out;
(void)iv;
(void)tag_size;
(void)tag_in;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Initializes the DES transient key.
* @note It is the underlying implementation to decide which key sizes are
* allowable.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] size key size in bytes
* @param[in] keyp pointer to the key data
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the algorithm is unsupported.
* @retval CRY_ERR_INV_KEY_SIZE if the specified key size is invalid for
* the specified algorithm.
*
* @api
*/
cryerror_t cryLoadDESTransientKey(CRYDriver *cryp,
size_t size,
const uint8_t *keyp) {
osalDbgCheck((cryp != NULL) && (keyp != NULL));
#if CRY_LLD_SUPPORTS_DES == TRUE
return cry_lld_des_loadkey(cryp, size, keyp);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_des_loadkey(cryp, size, keyp);
#else
(void)cryp;
(void)size;
(void)keyp;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Encryption of a single block using (T)DES.
* @note The implementation of this function must guarantee that it can
* be called from any context.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] key_id the key to be used for the operation, zero is
* the transient key, other values are keys stored
* in an unspecified way
* @param[in] in buffer containing the input plaintext
* @param[out] out buffer for the output cyphertext
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_INV_KEY_TYPE the selected key is invalid for this operation.
* @retval CRY_ERR_INV_KEY_ID if the specified key identifier is invalid
* or refers to an empty key slot.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @special
*/
cryerror_t cryEncryptDES(CRYDriver *cryp,
crykey_t key_id,
const uint8_t *in,
uint8_t *out) {
osalDbgCheck((cryp != NULL) && (in != NULL) && (out != NULL));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_DES == TRUE
return cry_lld_encrypt_DES(cryp, key_id, in, out);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_encrypt_DES(cryp, key_id, in, out);
#else
(void)cryp;
(void)key_id;
(void)in;
(void)out;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Decryption of a single block using (T)DES.
* @note The implementation of this function must guarantee that it can
* be called from any context.
*
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] key_id the key to be used for the operation, zero is
* the transient key, other values are keys stored
* in an unspecified way
* @param[in] in buffer containing the input cyphertext
* @param[out] out buffer for the output plaintext
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_INV_KEY_TYPE the selected key is invalid for this operation.
* @retval CRY_ERR_INV_KEY_ID if the specified key identifier is invalid
* or refers to an empty key slot.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @special
*/
cryerror_t cryDecryptDES(CRYDriver *cryp,
crykey_t key_id,
const uint8_t *in,
uint8_t *out) {
osalDbgCheck((cryp != NULL) && (in != NULL) && (out != NULL));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_DES == TRUE
return cry_lld_decrypt_DES(cryp, key_id, in, out);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_decrypt_DES(cryp, key_id, in, out);
#else
(void)cryp;
(void)key_id;
(void)in;
(void)out;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Encryption operation using (T)DES-ECB.
* @note The function operates on data buffers whose length is a multiple
* of an DES block, this means that padding must be done by the
* caller.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] key_id the key to be used for the operation, zero is
* the transient key, other values are keys stored
* in an unspecified way
* @param[in] size size of both buffers, this number must be a
* multiple of 8
* @param[in] in buffer containing the input plaintext
* @param[out] out buffer for the output cyphertext
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_INV_KEY_TYPE the selected key is invalid for this operation.
* @retval CRY_ERR_INV_KEY_ID if the specified key identifier is invalid
* or refers to an empty key slot.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t cryEncryptDES_ECB(CRYDriver *cryp,
crykey_t key_id,
size_t size,
const uint8_t *in,
uint8_t *out) {
osalDbgCheck((cryp != NULL) && (in != NULL) && (out != NULL) &&
((size & (size_t)7) == (size_t)0));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_DES_ECB == TRUE
return cry_lld_encrypt_DES_ECB(cryp, key_id, size, in, out);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_encrypt_DES_ECB(cryp, key_id, size, in, out);
#else
(void)cryp;
(void)key_id;
(void)size;
(void)in;
(void)out;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Decryption operation using (T)DES-ECB.
* @note The function operates on data buffers whose length is a multiple
* of an DES block, this means that padding must be done by the
* caller.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] key_id the key to be used for the operation, zero is
* the transient key, other values are keys stored
* in an unspecified way
* @param[in] size size of both buffers, this number must be a
* multiple of 8
* @param[in] in buffer containing the input cyphertext
* @param[out] out buffer for the output plaintext
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_INV_KEY_TYPE the selected key is invalid for this operation.
* @retval CRY_ERR_INV_KEY_ID if the specified key identifier is invalid
* or refers to an empty key slot.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t cryDecryptDES_ECB(CRYDriver *cryp,
crykey_t key_id,
size_t size,
const uint8_t *in,
uint8_t *out) {
osalDbgCheck((cryp != NULL) && (in != NULL) && (out != NULL) &&
((size & (size_t)7) == (size_t)0));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_DES_ECB == TRUE
return cry_lld_decrypt_DES_ECB(cryp, key_id, size, in, out);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_decrypt_DES_ECB(cryp, key_id, size, in, out);
#else
(void)cryp;
(void)key_id;
(void)size;
(void)in;
(void)out;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Encryption operation using (T)DES-CBC.
* @note The function operates on data buffers whose length is a multiple
* of an DES block, this means that padding must be done by the
* caller.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] key_id the key to be used for the operation, zero is
* the transient key, other values are keys stored
* in an unspecified way
* @param[in] size size of both buffers, this number must be a
* multiple of 8
* @param[in] in buffer containing the input plaintext
* @param[out] out buffer for the output cyphertext
* @param[in] iv 64 bits input vector
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_INV_KEY_TYPE the selected key is invalid for this operation.
* @retval CRY_ERR_INV_KEY_ID if the specified key identifier is invalid
* or refers to an empty key slot.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t cryEncryptDES_CBC(CRYDriver *cryp,
crykey_t key_id,
size_t size,
const uint8_t *in,
uint8_t *out,
const uint8_t *iv) {
osalDbgCheck((cryp != NULL) && (in != NULL) && (out != NULL) &&
(iv != NULL) && ((size & (size_t)7) == (size_t)0));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_DES_CBC == TRUE
return cry_lld_encrypt_DES_CBC(cryp, key_id, size, in, out, iv);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_encrypt_DES_CBC(cryp, key_id, size, in, out, iv);
#else
(void)cryp;
(void)key_id;
(void)size;
(void)in;
(void)out;
(void)iv;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Decryption operation using (T)DES-CBC.
* @note The function operates on data buffers whose length is a multiple
* of an DES block, this means that padding must be done by the
* caller.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] key_id the key to be used for the operation, zero is
* the transient key, other values are keys stored
* in an unspecified way
* @param[in] size size of both buffers, this number must be a
* multiple of 8
* @param[in] in buffer containing the input cyphertext
* @param[out] out buffer for the output plaintext
* @param[in] iv 64 bits input vector
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_INV_KEY_TYPE the selected key is invalid for this operation.
* @retval CRY_ERR_INV_KEY_ID if the specified key identifier is invalid
* or refers to an empty key slot.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t cryDecryptDES_CBC(CRYDriver *cryp,
crykey_t key_id,
size_t size,
const uint8_t *in,
uint8_t *out,
const uint8_t *iv) {
osalDbgCheck((cryp != NULL) && (in != NULL) && (out != NULL) &&
(iv != NULL) && ((size & (size_t)7) == (size_t)0));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_DES_CBC == TRUE
return cry_lld_decrypt_DES_CBC(cryp, key_id, size, in, out, iv);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_decrypt_DES_CBC(cryp, key_id, size, in, out, iv);
#else
(void)cryp;
(void)key_id;
(void)size;
(void)in;
(void)out;
(void)iv;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Hash initialization using SHA1.
* @note Use of this algorithm is not recommended because proven weak.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[out] sha1ctxp pointer to a SHA1 context to be initialized
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t crySHA1Init(CRYDriver *cryp, SHA1Context *sha1ctxp) {
osalDbgCheck((cryp != NULL) && (sha1ctxp != NULL));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_SHA1 == TRUE
return cry_lld_SHA1_init(cryp, sha1ctxp);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_SHA1_init(cryp, sha1ctxp);
#else
(void)cryp;
(void)sha1ctxp;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Hash update using SHA1.
* @note Use of this algorithm is not recommended because proven weak.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] sha1ctxp pointer to a SHA1 context
* @param[in] size size of input buffer
* @param[in] in buffer containing the input text
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t crySHA1Update(CRYDriver *cryp, SHA1Context *sha1ctxp,
size_t size, const uint8_t *in) {
osalDbgCheck((cryp != NULL) && (sha1ctxp != NULL) && (in != NULL));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_SHA1 == TRUE
return cry_lld_SHA1_update(cryp, sha1ctxp, size, in);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_SHA1_update(cryp, sha1ctxp, size, in);
#else
(void)cryp;
(void)sha1ctxp;
(void)size;
(void)in;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Hash finalization using SHA1.
* @note Use of this algorithm is not recommended because proven weak.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] sha1ctxp pointer to a SHA1 context
* @param[out] out 160 bits output buffer
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t crySHA1Final(CRYDriver *cryp, SHA1Context *sha1ctxp, uint8_t *out) {
osalDbgCheck((cryp != NULL) && (sha1ctxp != NULL) && (out != NULL));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_SHA1 == TRUE
return cry_lld_SHA1_final(cryp, sha1ctxp, out);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_SHA1_final(cryp, sha1ctxp, out);
#else
(void)cryp;
(void)sha1ctxp;
(void)out;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Hash initialization using SHA256.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[out] sha256ctxp pointer to a SHA256 context to be initialized
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t crySHA256Init(CRYDriver *cryp, SHA256Context *sha256ctxp) {
osalDbgCheck((cryp != NULL) && (sha256ctxp != NULL));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_SHA256 == TRUE
return cry_lld_SHA256_init(cryp, sha256ctxp);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_SHA256_init(cryp, sha256ctxp);
#else
(void)cryp;
(void)sha256ctxp;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Hash update using SHA256.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] sha256ctxp pointer to a SHA256 context
* @param[in] size size of input buffer
* @param[in] in buffer containing the input text
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t crySHA256Update(CRYDriver *cryp, SHA256Context *sha256ctxp,
size_t size, const uint8_t *in) {
osalDbgCheck((cryp != NULL) && (sha256ctxp != NULL) && (in != NULL));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_SHA256 == TRUE
return cry_lld_SHA256_update(cryp, sha256ctxp, size, in);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_SHA256_update(cryp, sha256ctxp, size, in);
#else
(void)cryp;
(void)sha256ctxp;
(void)size;
(void)in;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Hash finalization using SHA256.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] sha256ctxp pointer to a SHA256 context
* @param[out] out 256 bits output buffer
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t crySHA256Final(CRYDriver *cryp, SHA256Context *sha256ctxp,
uint8_t *out) {
osalDbgCheck((cryp != NULL) && (sha256ctxp != NULL) && (out != NULL));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_SHA256 == TRUE
return cry_lld_SHA256_final(cryp, sha256ctxp, out);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_SHA256_final(cryp, sha256ctxp, out);
#else
(void)cryp;
(void)sha256ctxp;
(void)out;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Hash initialization using SHA512.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[out] sha512ctxp pointer to a SHA512 context to be initialized
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t crySHA512Init(CRYDriver *cryp, SHA512Context *sha512ctxp) {
osalDbgCheck((cryp != NULL) && (sha512ctxp != NULL));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_SHA512 == TRUE
return cry_lld_SHA512_init(cryp, sha512ctxp);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_SHA512_init(cryp, sha512ctxp);
#else
(void)cryp;
(void)sha512ctxp;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Hash update using SHA512.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] sha512ctxp pointer to a SHA512 context
* @param[in] size size of input buffer
* @param[in] in buffer containing the input text
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t crySHA512Update(CRYDriver *cryp, SHA512Context *sha512ctxp,
size_t size, const uint8_t *in) {
osalDbgCheck((cryp != NULL) && (sha512ctxp != NULL) && (in != NULL));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_SHA512 == TRUE
return cry_lld_SHA512_update(cryp, sha512ctxp, size, in);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_SHA512_update(cryp, sha512ctxp, size, in);
#else
(void)cryp;
(void)sha512ctxp;
(void)size;
(void)in;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Hash finalization using SHA512.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] sha512ctxp pointer to a SHA512 context
* @param[out] out 512 bits output buffer
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t crySHA512Final(CRYDriver *cryp, SHA512Context *sha512ctxp,
uint8_t *out) {
osalDbgCheck((cryp != NULL) && (sha512ctxp != NULL) && (out != NULL));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_SHA512 == TRUE
return cry_lld_SHA512_final(cryp, sha512ctxp, out);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_SHA512_final(cryp, sha512ctxp, out);
#else
(void)cryp;
(void)sha512ctxp;
(void)out;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Initializes the HMAC transient key.
* @note It is the underlying implementation to decide which key sizes are
* allowable.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] size key size in bytes
* @param[in] keyp pointer to the key data
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the algorithm is unsupported.
* @retval CRY_ERR_INV_KEY_SIZE if the specified key size is invalid for
* the specified algorithm.
*
* @api
*/
cryerror_t cryLoadHMACTransientKey(CRYDriver *cryp,
size_t size,
const uint8_t *keyp) {
osalDbgCheck((cryp != NULL) && (keyp != NULL));
#if (CRY_LLD_SUPPORTS_HMAC_SHA256 == TRUE) || \
(CRY_LLD_SUPPORTS_HMAC_SHA512 == TRUE)
return cry_lld_hmac_loadkey(cryp, size, keyp);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_hmac_loadkey(cryp, size, keyp);
#else
(void)cryp;
(void)size;
(void)keyp;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Hash initialization using HMAC_SHA256.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[out] hmacsha256ctxp pointer to a HMAC_SHA256 context to be
* initialized
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t cryHMACSHA256Init(CRYDriver *cryp,
HMACSHA256Context *hmacsha256ctxp) {
osalDbgCheck((cryp != NULL) && (hmacsha256ctxp != NULL));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_HMAC_SHA256 == TRUE
return cry_lld_HMACSHA256_init(cryp, hmacsha256ctxp);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_HMACSHA256_init(cryp, hmacsha256ctxp);
#else
(void)cryp;
(void)hmacsha256ctxp;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Hash update using HMAC.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] hmacsha256ctxp pointer to a HMAC_SHA256 context
* @param[in] size size of input buffer
* @param[in] in buffer containing the input text
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t cryHMACSHA256Update(CRYDriver *cryp,
HMACSHA256Context *hmacsha256ctxp,
size_t size,
const uint8_t *in) {
osalDbgCheck((cryp != NULL) && (hmacsha256ctxp != NULL) && (in != NULL));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_HMAC_SHA256 == TRUE
return cry_lld_HMACSHA256_update(cryp, hmacsha256ctxp, size, in);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_HMACSHA256_update(cryp, hmacsha256ctxp, size, in);
#else
(void)cryp;
(void)hmacsha256ctxp;
(void)size;
(void)in;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Hash finalization using HMAC.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] hmacsha256ctxp pointer to a HMAC_SHA256 context
* @param[out] out 256 bits output buffer
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t cryHMACSHA256Final(CRYDriver *cryp,
HMACSHA256Context *hmacsha256ctxp,
uint8_t *out) {
osalDbgCheck((cryp != NULL) && (hmacsha256ctxp != NULL) && (out != NULL));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_HMAC_SHA256 == TRUE
return cry_lld_HMACSHA256_final(cryp, hmacsha256ctxp, out);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_HMACSHA256_final(cryp, hmacsha256ctxp, out);
#else
(void)cryp;
(void)hmacsha256ctxp;
(void)out;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Hash initialization using HMAC_SHA512.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[out] hmacsha512ctxp pointer to a HMAC_SHA512 context to be
* initialized
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t cryHMACSHA512Init(CRYDriver *cryp,
HMACSHA512Context *hmacsha512ctxp) {
osalDbgCheck((cryp != NULL) && (hmacsha512ctxp != NULL));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_HMAC_SHA512 == TRUE
return cry_lld_HMACSHA512_init(cryp, hmacsha512ctxp);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_HMACSHA512_init(cryp, hmacsha512ctxp);
#else
(void)cryp;
(void)hmacsha512ctxp;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Hash update using HMAC.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] hmacsha512ctxp pointer to a HMAC_SHA512 context
* @param[in] size size of input buffer
* @param[in] in buffer containing the input text
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t cryHMACSHA512Update(CRYDriver *cryp,
HMACSHA512Context *hmacsha512ctxp,
size_t size,
const uint8_t *in) {
osalDbgCheck((cryp != NULL) && (hmacsha512ctxp != NULL) && (in != NULL));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_HMAC_SHA512 == TRUE
return cry_lld_HMACSHA512_update(cryp, hmacsha512ctxp, size, in);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_HMACSHA512_update(cryp, hmacsha512ctxp, size, in);
#else
(void)cryp;
(void)hmacsha512ctxp;
(void)size;
(void)in;
return CRY_ERR_INV_ALGO;
#endif
}
/**
* @brief Hash finalization using HMAC.
*
* @param[in] cryp pointer to the @p CRYDriver object
* @param[in] hmacsha512ctxp pointer to a HMAC_SHA512 context
* @param[out] out 512 bits output buffer
* @return The operation status.
* @retval CRY_NOERROR if the operation succeeded.
* @retval CRY_ERR_INV_ALGO if the operation is unsupported on this
* device instance.
* @retval CRY_ERR_OP_FAILURE if the operation failed, implementation
* dependent.
*
* @api
*/
cryerror_t cryHMACSHA512Final(CRYDriver *cryp,
HMACSHA512Context *hmacsha512ctxp,
uint8_t *out) {
osalDbgCheck((cryp != NULL) && (hmacsha512ctxp != NULL) && (out != NULL));
osalDbgAssert(cryp->state == CRY_READY, "not ready");
#if CRY_LLD_SUPPORTS_HMAC_SHA512 == TRUE
return cry_lld_HMACSHA512_final(cryp, hmacsha512ctxp, out);
#elif HAL_CRY_USE_FALLBACK == TRUE
return cry_fallback_HMACSHA512_final(cryp, hmacsha512ctxp, out);
#else
(void)cryp;
(void)hmacsha512ctxp;
(void)out;
return CRY_ERR_INV_ALGO;
#endif
}
#endif /* HAL_USE_CRY == TRUE */
/** @} */