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mbed-os/targets/TARGET_STM/TARGET_STM32H7/device/stm32h7xx_hal_cryp.c

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/**
******************************************************************************
* @file stm32h7xx_hal_cryp.c
* @author MCD Application Team
* @brief CRYP HAL module driver.
* This file provides firmware functions to manage the following
* functionalities of the Cryptography (CRYP) peripheral:
* + Initialization and de-initialization functions
* + AES processing functions
* + DES processing functions
* + TDES processing functions
* + DMA callback functions
* + CRYP IRQ handler management
* + Peripheral State functions
*
@verbatim
==============================================================================
##### How to use this driver #####
==============================================================================
[..]
The CRYP HAL driver can be used in CRYP IP as follows:
(#)Initialize the CRYP low level resources by implementing the HAL_CRYP_MspInit():
(##) Enable the CRYP interface clock using __HAL_RCC_CRYP_CLK_ENABLE()
(##) In case of using interrupts (e.g. HAL_CRYP_Encrypt_IT())
(+++) Configure the CRYP interrupt priority using HAL_NVIC_SetPriority()
(+++) Enable the CRYP IRQ handler using HAL_NVIC_EnableIRQ()
(+++) In CRYP IRQ handler, call HAL_CRYP_IRQHandler()
(##) In case of using DMA to control data transfer (e.g. HAL_CRYP_Encrypt_DMA())
(+++) Enable the DMAx interface clock using __RCC_DMAx_CLK_ENABLE()
(+++) Configure and enable two DMA streams one for managing data transfer from
memory to peripheral (input stream) and another stream for managing data
transfer from peripheral to memory (output stream)
(+++) Associate the initialized DMA handle to the CRYP DMA handle
using __HAL_LINKDMA()
(+++) Configure the priority and enable the NVIC for the transfer complete
interrupt on the two DMA Streams. The output stream should have higher
priority than the input stream HAL_NVIC_SetPriority() and HAL_NVIC_EnableIRQ()
(#)Initialize the CRYP according to the specified parameters :
(##) The data type: 1-bit, 8-bit, 16-bit or 32-bit.
(##) The key size: 128, 192 or 256.
(##) The AlgoMode DES/ TDES Algorithm ECB/CBC or AES Algorithm ECB/CBC/CTR/GCM or CCM.
(##) The initialization vector (counter). It is not used in ECB mode.
(##) The key buffer used for encryption/decryption.
(##) The Header used only in AES GCM and CCM Algorithm for authentication.
(##) The HeaderSize The size of header buffer in word.
(##) The B0 block is the first authentication block used only in AES CCM mode.
(#)Three processing (encryption/decryption) functions are available:
(##) Polling mode: encryption and decryption APIs are blocking functions
i.e. they process the data and wait till the processing is finished,
e.g. HAL_CRYP_Encrypt & HAL_CRYP_Decrypt
(##) Interrupt mode: encryption and decryption APIs are not blocking functions
i.e. they process the data under interrupt,
e.g. HAL_CRYP_Encrypt_IT & HAL_CRYP_Decrypt_IT
(##) DMA mode: encryption and decryption APIs are not blocking functions
i.e. the data transfer is ensured by DMA,
e.g. HAL_CRYP_Encrypt_DMA & HAL_CRYP_Decrypt_DMA
(#)When the processing function is called at first time after HAL_CRYP_Init()
the CRYP peripheral is configured and processes the buffer in input.
At second call, no need to Initialize the CRYP, user have to get current configuration via
HAL_CRYP_GetConfig() API, then only HAL_CRYP_SetConfig() is requested to set
new parametres, finally user can start encryption/decryption.
(#)Call HAL_CRYP_DeInit() to deinitialize the CRYP peripheral.
[..]
The cryptographic processor supports following standards:
(#) The data encryption standard (DES) and Triple-DES (TDES) supported only by CRYP1 IP:
(##)64-bit data block processing
(##) chaining modes supported :
(+++) Electronic Code Book(ECB)
(+++) Cipher Block Chaining (CBC)
(##) keys length supported :64-bit, 128-bit and 192-bit.
(#) The advanced encryption standard (AES) supported by CRYP1:
(##)128-bit data block processing
(##) chaining modes supported :
(+++) Electronic Code Book(ECB)
(+++) Cipher Block Chaining (CBC)
(+++) Counter mode (CTR)
(+++) Galois/counter mode (GCM/GMAC)
(+++) Counter with Cipher Block Chaining-Message(CCM)
(##) keys length Supported :
(+++) for CRYP1 IP: 128-bit, 192-bit and 256-bit.
[..] This section describes the AES Galois/counter mode (GCM) supported by both CRYP1 IP:
(#) Algorithm supported :
(##) Galois/counter mode (GCM)
(##) Galois message authentication code (GMAC) :is exactly the same as
GCM algorithm composed only by an header.
(#) Four phases are performed in GCM :
(##) Init phase: IP prepares the GCM hash subkey (H) and do the IV processing
(##) Header phase: IP processes the Additional Authenticated Data (AAD), with hash
computation only.
(##) Payload phase: IP processes the plaintext (P) with hash computation + keystream
encryption + data XORing. It works in a similar way for ciphertext (C).
(##) Final phase: IP generates the authenticated tag (T) using the last block of data.
(#) structure of message construction in GCM is defined as below :
(##) 16 bytes Initial Counter Block (ICB)composed of IV and counter
(##) The authenticated header A (also knows as Additional Authentication Data AAD)
this part of the message is only authenticated, not encrypted.
(##) The plaintext message P is both authenticated and encrypted as ciphertext.
GCM standard specifies that ciphertext has same bit length as the plaintext.
(##) The last block is composed of the length of A (on 64 bits) and the length of ciphertext
(on 64 bits)
[..] This section describe The AES Counter with Cipher Block Chaining-Message
Authentication Code (CCM) supported by both CRYP1 IP:
(#) Specific parameters for CCM :
(##) B0 block : According to NIST Special Publication 800-38C,
The first block B0 is formatted as follows, where l(m) is encoded in
most-significant-byte first order(see below table 3)
(+++) Q: a bit string representation of the octet length of P (plaintext)
(+++) q The octet length of the binary representation of the octet length of the payload
(+++) A nonce (N), n The octet length of the where n+q=15.
(+++) Flags: most significant octet containing four flags for control information,
(+++) t The octet length of the MAC.
(##) B1 block (header) : associated data length(a) concatenated with Associated Data (A)
the associated data length expressed in bytes (a) defined as below:
(+++) If 0 < a < 216-28, then it is encoded as [a]16, i.e. two octets
(+++) If 216-28 < a < 232, then it is encoded as 0xff || 0xfe || [a]32, i.e. six octets
(+++) If 232 < a < 264, then it is encoded as 0xff || 0xff || [a]64, i.e. ten octets
(##) CTRx block : control blocks
(+++) Generation of CTR1 from first block B0 information :
equal to B0 with first 5 bits zeroed and most significant bits storing octet
length of P also zeroed, then incremented by one ( see below Table 4)
(+++) Generation of CTR0: same as CTR1 with bit[0] set to zero.
(#) Four phases are performed in CCM for CRYP1 IP:
(##) Init phase: IP prepares the GCM hash subkey (H) and do the IV processing
(##) Header phase: IP processes the Additional Authenticated Data (AAD), with hash
computation only.
(##) Payload phase: IP processes the plaintext (P) with hash computation + keystream
encryption + data XORing. It works in a similar way for ciphertext (C).
(##) Final phase: IP generates the authenticated tag (T) using the last block of data.
*** Callback registration ***
=============================================
The compilation define USE_HAL_CRYP_REGISTER_CALLBACKS when set to 1
allows the user to configure dynamically the driver callbacks.
Use Functions @ref HAL_CRYP_RegisterCallback() or HAL_CRYP_RegisterXXXCallback()
to register an interrupt callback.
Function @ref HAL_CRYP_RegisterCallback() allows to register following callbacks:
(+) InCpltCallback : Input FIFO transfer completed callback.
(+) OutCpltCallback : Output FIFO transfer completed callback.
(+) ErrorCallback : callback for error detection.
(+) MspInitCallback : CRYP MspInit.
(+) MspDeInitCallback : CRYP MspDeInit.
This function takes as parameters the HAL peripheral handle, the Callback ID
and a pointer to the user callback function.
Use function @ref HAL_CRYP_UnRegisterCallback() to reset a callback to the default
weak function.
@ref HAL_CRYP_UnRegisterCallback() takes as parameters the HAL peripheral handle,
and the Callback ID.
This function allows to reset following callbacks:
(+) InCpltCallback : Input FIFO transfer completed callback.
(+) OutCpltCallback : Output FIFO transfer completed callback.
(+) ErrorCallback : callback for error detection.
(+) MspInitCallback : CRYP MspInit.
(+) MspDeInitCallback : CRYP MspDeInit.
By default, after the @ref HAL_CRYP_Init() and when the state is HAL_CRYP_STATE_RESET
all callbacks are set to the corresponding weak functions :
examples @ref HAL_CRYP_InCpltCallback() , @ref HAL_CRYP_OutCpltCallback().
Exception done for MspInit and MspDeInit functions that are
reset to the legacy weak function in the @ref HAL_CRYP_Init()/ @ref HAL_CRYP_DeInit() only when
these callbacks are null (not registered beforehand).
if not, MspInit or MspDeInit are not null, the @ref HAL_CRYP_Init() / @ref HAL_CRYP_DeInit()
keep and use the user MspInit/MspDeInit functions (registered beforehand)
Callbacks can be registered/unregistered in HAL_CRYP_STATE_READY state only.
Exception done MspInit/MspDeInit callbacks that can be registered/unregistered
in HAL_CRYP_STATE_READY or HAL_CRYP_STATE_RESET state,
thus registered (user) MspInit/DeInit callbacks can be used during the Init/DeInit.
In that case first register the MspInit/MspDeInit user callbacks
using @ref HAL_CRYP_RegisterCallback() before calling @ref HAL_CRYP_DeInit()
or @ref HAL_CRYP_Init() function.
When The compilation define USE_HAL_CRYP_REGISTER_CALLBACKS is set to 0 or
not defined, the callback registration feature is not available and all callbacks
are set to the corresponding weak functions.
@endverbatim
Table 1. Initial Counter Block (ICB)
+-------------------------------------------------------+
| Initialization vector (IV) | Counter |
|----------------|----------------|-----------|---------|
127 95 63 31 0
Bit Number Register Contents
---------- --------------- -----------
127 ...96 CRYP_IV1R[31:0] ICB[127:96]
95 ...64 CRYP_IV1L[31:0] B0[95:64]
63 ... 32 CRYP_IV0R[31:0] ICB[63:32]
31 ... 0 CRYP_IV0L[31:0] ICB[31:0], where 32-bit counter= 0x2
Table 2. GCM last block definition
+-------------------------------------------------------------------+
| Bit[0] | Bit[32] | Bit[64] | Bit[96] |
|-----------|--------------------|-----------|----------------------|
| 0x0 | Header length[31:0]| 0x0 | Payload length[31:0] |
|-----------|--------------------|-----------|----------------------|
Table 3. B0 block
Octet Number Contents
------------ ---------
0 Flags
1 ... 15-q Nonce N
16-q ... 15 Q
the Flags field is formatted as follows:
Bit Number Contents
---------- ----------------------
7 Reserved (always zero)
6 Adata
5 ... 3 (t-2)/2
2 ... 0 [q-1]3
Table 4. CTRx block
Bit Number Register Contents
---------- --------------- -----------
127 ...96 CRYP_IV1R[31:0] B0[127:96], where Q length bits are set to 0, except for
bit 0 that is set to 1
95 ...64 CRYP_IV1L[31:0] B0[95:64]
63 ... 32 CRYP_IV0R[31:0] B0[63:32]
31 ... 0 CRYP_IV0L[31:0] B0[31:0], where flag bits set to 0
******************************************************************************
* @attention
*
* <h2><center>&copy; Copyright (c) 2017 STMicroelectronics.
* All rights reserved.</center></h2>
*
* This software component is licensed by ST under BSD 3-Clause license,
* the "License"; You may not use this file except in compliance with the
* License. You may obtain a copy of the License at:
* opensource.org/licenses/BSD-3-Clause
*
******************************************************************************
*/
/* Includes ------------------------------------------------------------------*/
#include "stm32h7xx_hal.h"
/** @addtogroup STM32H7xx_HAL_Driver
* @{
*/
#if defined (CRYP)
/** @defgroup CRYP CRYP
* @brief CRYP HAL module driver.
* @{
*/
#ifdef HAL_CRYP_MODULE_ENABLED
/* Private typedef -----------------------------------------------------------*/
/* Private define ------------------------------------------------------------*/
/** @addtogroup CRYP_Private_Defines
* @{
*/
#define CRYP_TIMEOUT_KEYPREPARATION 82U /*The latency of key preparation operation is 82 clock cycles.*/
#define CRYP_TIMEOUT_GCMCCMINITPHASE 299U /* The latency of GCM/CCM init phase to prepare hash subkey is 299 clock cycles.*/
#define CRYP_TIMEOUT_GCMCCMHEADERPHASE 290U /* The latency of GCM/CCM header phase is 290 clock cycles.*/
#define CRYP_PHASE_READY 0x00000001U /*!< CRYP peripheral is ready for initialization. */
#define CRYP_PHASE_PROCESS 0x00000002U /*!< CRYP peripheral is in processing phase */
#define CRYP_PHASE_INIT 0x00000000U /*!< GCM/GMAC (or CCM) init phase */
#define CRYP_PHASE_HEADER CRYP_CR_GCM_CCMPH_0 /*!< GCM/GMAC or CCM header phase */
#define CRYP_PHASE_PAYLOAD CRYP_CR_GCM_CCMPH_1 /*!< GCM(/CCM) payload phase */
#define CRYP_PHASE_FINAL CRYP_CR_GCM_CCMPH /*!< GCM/GMAC or CCM final phase */
#define CRYP_OPERATINGMODE_ENCRYPT 0x00000000U /*!< Encryption mode */
#define CRYP_OPERATINGMODE_DECRYPT CRYP_CR_ALGODIR /*!< Decryption */
/* CTR1 information to use in CCM algorithm */
#define CRYP_CCM_CTR1_0 0x07FFFFFFU
#define CRYP_CCM_CTR1_1 0xFFFFFF00U
#define CRYP_CCM_CTR1_2 0x00000001U
/**
* @}
*/
/* Private macro -------------------------------------------------------------*/
/** @addtogroup CRYP_Private_Macros
* @{
*/
#define CRYP_SET_PHASE(__HANDLE__, __PHASE__) do{(__HANDLE__)->Instance->CR &= (uint32_t)(~CRYP_CR_GCM_CCMPH);\
(__HANDLE__)->Instance->CR |= (uint32_t)(__PHASE__);\
}while(0)
#define HAL_CRYP_FIFO_FLUSH(__HANDLE__) ((__HANDLE__)->Instance->CR |= CRYP_CR_FFLUSH)
/**
* @}
*/
/* Private struct -------------------------------------------------------------*/
/* Private variables ---------------------------------------------------------*/
/* Private function prototypes -----------------------------------------------*/
/** @addtogroup CRYP_Private_Functions_prototypes
* @{
*/
static void CRYP_SetDMAConfig(CRYP_HandleTypeDef *hcryp, uint32_t inputaddr, uint16_t Size, uint32_t outputaddr);
static void CRYP_DMAInCplt(DMA_HandleTypeDef *hdma);
static void CRYP_DMAOutCplt(DMA_HandleTypeDef *hdma);
static void CRYP_DMAError(DMA_HandleTypeDef *hdma);
static void CRYP_SetKey(CRYP_HandleTypeDef *hcryp, uint32_t KeySize);
static void CRYP_AES_IT(CRYP_HandleTypeDef *hcryp);
static HAL_StatusTypeDef CRYP_GCMCCM_SetHeaderPhase(CRYP_HandleTypeDef *hcryp, uint32_t Timeout);
static void CRYP_GCMCCM_SetPayloadPhase_IT(CRYP_HandleTypeDef *hcryp);
static void CRYP_GCMCCM_SetHeaderPhase_IT(CRYP_HandleTypeDef *hcryp);
static HAL_StatusTypeDef CRYP_GCMCCM_SetHeaderPhase_DMA(CRYP_HandleTypeDef *hcryp);
static void CRYP_Workaround(CRYP_HandleTypeDef *hcryp, uint32_t Timeout);
static HAL_StatusTypeDef CRYP_AESGCM_Process_DMA(CRYP_HandleTypeDef *hcryp);
static HAL_StatusTypeDef CRYP_AESGCM_Process_IT(CRYP_HandleTypeDef *hcryp);
static HAL_StatusTypeDef CRYP_AESGCM_Process(CRYP_HandleTypeDef *hcryp, uint32_t Timeout);
static HAL_StatusTypeDef CRYP_AESCCM_Process(CRYP_HandleTypeDef *hcryp, uint32_t Timeout);
static HAL_StatusTypeDef CRYP_AESCCM_Process_IT(CRYP_HandleTypeDef *hcryp);
static HAL_StatusTypeDef CRYP_AESCCM_Process_DMA(CRYP_HandleTypeDef *hcryp);
static void CRYP_AES_ProcessData(CRYP_HandleTypeDef *hcrypt, uint32_t Timeout);
static HAL_StatusTypeDef CRYP_AES_Encrypt(CRYP_HandleTypeDef *hcryp, uint32_t Timeout);
static HAL_StatusTypeDef CRYP_AES_Decrypt(CRYP_HandleTypeDef *hcryp, uint32_t Timeout);
static HAL_StatusTypeDef CRYP_AES_Decrypt_IT(CRYP_HandleTypeDef *hcryp);
static HAL_StatusTypeDef CRYP_AES_Encrypt_IT(CRYP_HandleTypeDef *hcryp);
static HAL_StatusTypeDef CRYP_AES_Decrypt_DMA(CRYP_HandleTypeDef *hcryp);
static void CRYP_TDES_IT(CRYP_HandleTypeDef *hcryp);
static HAL_StatusTypeDef CRYP_WaitOnIFEMFlag(const CRYP_HandleTypeDef *hcryp, uint32_t Timeout);
static HAL_StatusTypeDef CRYP_WaitOnBUSYFlag(const CRYP_HandleTypeDef *hcryp, uint32_t Timeout);
static HAL_StatusTypeDef CRYP_WaitOnOFNEFlag(const CRYP_HandleTypeDef *hcryp, uint32_t Timeout);
static HAL_StatusTypeDef CRYP_TDES_Process(CRYP_HandleTypeDef *hcryp, uint32_t Timeout);
/**
* @}
*/
/* Exported functions ---------------------------------------------------------*/
/** @defgroup CRYP_Exported_Functions CRYP Exported Functions
* @{
*/
/** @defgroup CRYP_Exported_Functions_Group1 Initialization and de-initialization functions
* @brief CRYP Initialization and Configuration functions.
*
@verbatim
========================================================================================
##### Initialization, de-initialization and Set and Get configuration functions #####
========================================================================================
[..] This section provides functions allowing to:
(+) Initialize the CRYP
(+) DeInitialize the CRYP
(+) Initialize the CRYP MSP
(+) DeInitialize the CRYP MSP
(+) configure CRYP (HAL_CRYP_SetConfig) with the specified parameters in the CRYP_ConfigTypeDef
Parameters which are configured in This section are :
(++) Key size
(++) Data Type : 32,16, 8 or 1bit
(++) AlgoMode : for CRYP1 IP
ECB and CBC in DES/TDES Standard
ECB,CBC,CTR,GCM/GMAC and CCM in AES Standard.
(+) Get CRYP configuration (HAL_CRYP_GetConfig) from the specified parameters in the CRYP_HandleTypeDef
@endverbatim
* @{
*/
/**
* @brief Initializes the CRYP according to the specified
* parameters in the CRYP_ConfigTypeDef and creates the associated handle.
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module
* @retval HAL status
*/
HAL_StatusTypeDef HAL_CRYP_Init(CRYP_HandleTypeDef *hcryp)
{
/* Check the CRYP handle allocation */
if (hcryp == NULL)
{
return HAL_ERROR;
}
/* Check parameters */
assert_param(IS_CRYP_KEYSIZE(hcryp->Init.KeySize));
assert_param(IS_CRYP_DATATYPE(hcryp->Init.DataType));
assert_param(IS_CRYP_ALGORITHM(hcryp->Init.Algorithm));
#if (USE_HAL_CRYP_REGISTER_CALLBACKS == 1)
if (hcryp->State == HAL_CRYP_STATE_RESET)
{
/* Allocate lock resource and initialize it */
hcryp->Lock = HAL_UNLOCKED;
hcryp->InCpltCallback = HAL_CRYP_InCpltCallback; /* Legacy weak InCpltCallback */
hcryp->OutCpltCallback = HAL_CRYP_OutCpltCallback; /* Legacy weak OutCpltCallback */
hcryp->ErrorCallback = HAL_CRYP_ErrorCallback; /* Legacy weak ErrorCallback */
if (hcryp->MspInitCallback == NULL)
{
hcryp->MspInitCallback = HAL_CRYP_MspInit; /* Legacy weak MspInit */
}
/* Init the low level hardware */
hcryp->MspInitCallback(hcryp);
}
#else
if (hcryp->State == HAL_CRYP_STATE_RESET)
{
/* Allocate lock resource and initialize it */
hcryp->Lock = HAL_UNLOCKED;
/* Init the low level hardware */
HAL_CRYP_MspInit(hcryp);
}
#endif /* (USE_HAL_CRYP_REGISTER_CALLBACKS) */
/* Set the key size(This bit field is <20>don<6F>t care<72> in the DES or TDES modes) data type and Algorithm */
MODIFY_REG(hcryp->Instance->CR, CRYP_CR_DATATYPE | CRYP_CR_KEYSIZE | CRYP_CR_ALGOMODE,
hcryp->Init.DataType | hcryp->Init.KeySize | hcryp->Init.Algorithm);
/* Reset Error Code field */
hcryp->ErrorCode = HAL_CRYP_ERROR_NONE;
/* Change the CRYP state */
hcryp->State = HAL_CRYP_STATE_READY;
/* Set the default CRYP phase */
hcryp->Phase = CRYP_PHASE_READY;
/* Return function status */
return HAL_OK;
}
/**
* @brief De-Initializes the CRYP peripheral.
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module
* @retval HAL status
*/
HAL_StatusTypeDef HAL_CRYP_DeInit(CRYP_HandleTypeDef *hcryp)
{
/* Check the CRYP handle allocation */
if (hcryp == NULL)
{
return HAL_ERROR;
}
/* Set the default CRYP phase */
hcryp->Phase = CRYP_PHASE_READY;
/* Reset CrypInCount and CrypOutCount */
hcryp->CrypInCount = 0;
hcryp->CrypOutCount = 0;
hcryp->CrypHeaderCount = 0;
/* Disable the CRYP peripheral clock */
__HAL_CRYP_DISABLE(hcryp);
#if (USE_HAL_CRYP_REGISTER_CALLBACKS == 1)
if (hcryp->MspDeInitCallback == NULL)
{
hcryp->MspDeInitCallback = HAL_CRYP_MspDeInit; /* Legacy weak MspDeInit */
}
/* DeInit the low level hardware */
hcryp->MspDeInitCallback(hcryp);
#else
/* DeInit the low level hardware: CLOCK, NVIC.*/
HAL_CRYP_MspDeInit(hcryp);
#endif /* USE_HAL_CRYP_REGISTER_CALLBACKS */
/* Change the CRYP state */
hcryp->State = HAL_CRYP_STATE_RESET;
/* Release Lock */
__HAL_UNLOCK(hcryp);
/* Return function status */
return HAL_OK;
}
/**
* @brief Configure the CRYP according to the specified
* parameters in the CRYP_ConfigTypeDef
* @param hcryp: pointer to a CRYP_HandleTypeDef structure
* @param pConf: pointer to a CRYP_ConfigTypeDef structure that contains
* the configuration information for CRYP module
* @retval HAL status
*/
HAL_StatusTypeDef HAL_CRYP_SetConfig(CRYP_HandleTypeDef *hcryp, CRYP_ConfigTypeDef *pConf)
{
/* Check the CRYP handle allocation */
if ((hcryp == NULL) || (pConf == NULL))
{
return HAL_ERROR;
}
/* Check parameters */
assert_param(IS_CRYP_KEYSIZE(pConf->KeySize));
assert_param(IS_CRYP_DATATYPE(pConf->DataType));
assert_param(IS_CRYP_ALGORITHM(pConf->Algorithm));
if (hcryp->State == HAL_CRYP_STATE_READY)
{
/* Change the CRYP state */
hcryp->State = HAL_CRYP_STATE_BUSY;
/* Process locked */
__HAL_LOCK(hcryp);
/* Set CRYP parameters */
hcryp->Init.DataType = pConf->DataType;
hcryp->Init.pKey = pConf->pKey;
hcryp->Init.Algorithm = pConf->Algorithm;
hcryp->Init.KeySize = pConf->KeySize;
hcryp->Init.pInitVect = pConf->pInitVect;
hcryp->Init.Header = pConf->Header;
hcryp->Init.HeaderSize = pConf->HeaderSize;
hcryp->Init.B0 = pConf->B0;
hcryp->Init.DataWidthUnit = pConf->DataWidthUnit;
/* Set the key size(This bit field is <20>don<6F>t care<72> in the DES or TDES modes) data type, AlgoMode and operating mode*/
MODIFY_REG(hcryp->Instance->CR, CRYP_CR_DATATYPE | CRYP_CR_KEYSIZE | CRYP_CR_ALGOMODE,
hcryp->Init.DataType | hcryp->Init.KeySize | hcryp->Init.Algorithm);
/* Process Unlocked */
__HAL_UNLOCK(hcryp);
/* Reset Error Code field */
hcryp->ErrorCode = HAL_CRYP_ERROR_NONE;
/* Change the CRYP state */
hcryp->State = HAL_CRYP_STATE_READY;
/* Set the default CRYP phase */
hcryp->Phase = CRYP_PHASE_READY;
/* Return function status */
return HAL_OK;
}
else
{
/* Process Unlocked */
__HAL_UNLOCK(hcryp);
/* Busy error code field */
hcryp->ErrorCode |= HAL_CRYP_ERROR_BUSY;
return HAL_ERROR;
}
}
/**
* @brief Get CRYP Configuration parameters in associated handle.
* @param pConf: pointer to a CRYP_ConfigTypeDef structure
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module
* @retval HAL status
*/
HAL_StatusTypeDef HAL_CRYP_GetConfig(CRYP_HandleTypeDef *hcryp, CRYP_ConfigTypeDef *pConf)
{
/* Check the CRYP handle allocation */
if ((hcryp == NULL) || (pConf == NULL))
{
return HAL_ERROR;
}
if (hcryp->State == HAL_CRYP_STATE_READY)
{
/* Change the CRYP state */
hcryp->State = HAL_CRYP_STATE_BUSY;
/* Process locked */
__HAL_LOCK(hcryp);
/* Get CRYP parameters */
pConf->DataType = hcryp->Init.DataType;
pConf->pKey = hcryp->Init.pKey;
pConf->Algorithm = hcryp->Init.Algorithm;
pConf->KeySize = hcryp->Init.KeySize ;
pConf->pInitVect = hcryp->Init.pInitVect;
pConf->Header = hcryp->Init.Header ;
pConf->HeaderSize = hcryp->Init.HeaderSize;
pConf->B0 = hcryp->Init.B0;
pConf->DataWidthUnit = hcryp->Init.DataWidthUnit;
/* Process Unlocked */
__HAL_UNLOCK(hcryp);
/* Change the CRYP state */
hcryp->State = HAL_CRYP_STATE_READY;
/* Return function status */
return HAL_OK;
}
else
{
/* Process Unlocked */
__HAL_UNLOCK(hcryp);
/* Busy error code field */
hcryp->ErrorCode |= HAL_CRYP_ERROR_BUSY;
return HAL_ERROR;
}
}
/**
* @brief Initializes the CRYP MSP.
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module
* @retval None
*/
__weak void HAL_CRYP_MspInit(CRYP_HandleTypeDef *hcryp)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(hcryp);
/* NOTE : This function Should not be modified, when the callback is needed,
the HAL_CRYP_MspInit could be implemented in the user file
*/
}
/**
* @brief DeInitializes CRYP MSP.
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module
* @retval None
*/
__weak void HAL_CRYP_MspDeInit(CRYP_HandleTypeDef *hcryp)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(hcryp);
/* NOTE : This function Should not be modified, when the callback is needed,
the HAL_CRYP_MspDeInit could be implemented in the user file
*/
}
#if (USE_HAL_CRYP_REGISTER_CALLBACKS == 1)
/**
* @brief Register a User CRYP Callback
* To be used instead of the weak predefined callback
* @param hcryp cryp handle
* @param CallbackID ID of the callback to be registered
* This parameter can be one of the following values:
* @arg @ref HAL_CRYP_INPUT_COMPLETE_CB_ID Input FIFO transfer completed callback ID
* @arg @ref HAL_CRYP_OUTPUT_COMPLETE_CB_ID Output FIFO transfer completed callback ID
* @arg @ref HAL_CRYP_ERROR_CB_ID Rx Half Error callback ID
* @arg @ref HAL_CRYP_MSPINIT_CB_ID MspInit callback ID
* @arg @ref HAL_CRYP_MSPDEINIT_CB_ID MspDeInit callback ID
* @param pCallback pointer to the Callback function
* @retval status
*/
HAL_StatusTypeDef HAL_CRYP_RegisterCallback(CRYP_HandleTypeDef *hcryp, HAL_CRYP_CallbackIDTypeDef CallbackID,
pCRYP_CallbackTypeDef pCallback)
{
HAL_StatusTypeDef status = HAL_OK;
if (pCallback == NULL)
{
/* Update the error code */
hcryp->ErrorCode |= HAL_CRYP_ERROR_INVALID_CALLBACK;
return HAL_ERROR;
}
/* Process locked */
__HAL_LOCK(hcryp);
if (hcryp->State == HAL_CRYP_STATE_READY)
{
switch (CallbackID)
{
case HAL_CRYP_INPUT_COMPLETE_CB_ID :
hcryp->InCpltCallback = pCallback;
break;
case HAL_CRYP_OUTPUT_COMPLETE_CB_ID :
hcryp->OutCpltCallback = pCallback;
break;
case HAL_CRYP_ERROR_CB_ID :
hcryp->ErrorCallback = pCallback;
break;
case HAL_CRYP_MSPINIT_CB_ID :
hcryp->MspInitCallback = pCallback;
break;
case HAL_CRYP_MSPDEINIT_CB_ID :
hcryp->MspDeInitCallback = pCallback;
break;
default :
/* Update the error code */
hcryp->ErrorCode |= HAL_CRYP_ERROR_INVALID_CALLBACK;
/* Return error status */
status = HAL_ERROR;
break;
}
}
else if (hcryp->State == HAL_CRYP_STATE_RESET)
{
switch (CallbackID)
{
case HAL_CRYP_MSPINIT_CB_ID :
hcryp->MspInitCallback = pCallback;
break;
case HAL_CRYP_MSPDEINIT_CB_ID :
hcryp->MspDeInitCallback = pCallback;
break;
default :
/* Update the error code */
hcryp->ErrorCode |= HAL_CRYP_ERROR_INVALID_CALLBACK;
/* Return error status */
status = HAL_ERROR;
break;
}
}
else
{
/* Update the error code */
hcryp->ErrorCode |= HAL_CRYP_ERROR_INVALID_CALLBACK;
/* Return error status */
status = HAL_ERROR;
}
/* Release Lock */
__HAL_UNLOCK(hcryp);
return status;
}
/**
* @brief Unregister an CRYP Callback
* CRYP callabck is redirected to the weak predefined callback
* @param hcryp cryp handle
* @param CallbackID ID of the callback to be unregistered
* This parameter can be one of the following values:
* @arg @ref HAL_CRYP_INPUT_COMPLETE_CB_ID Input FIFO transfer completed callback ID
* @arg @ref HAL_CRYP_OUTPUT_COMPLETE_CB_ID Output FIFO transfer completed callback ID
* @arg @ref HAL_CRYP_ERROR_CB_ID Rx Half Error callback ID
* @arg @ref HAL_CRYP_MSPINIT_CB_ID MspInit callback ID
* @arg @ref HAL_CRYP_MSPDEINIT_CB_ID MspDeInit callback ID
* @retval status
*/
HAL_StatusTypeDef HAL_CRYP_UnRegisterCallback(CRYP_HandleTypeDef *hcryp, HAL_CRYP_CallbackIDTypeDef CallbackID)
{
HAL_StatusTypeDef status = HAL_OK;
/* Process locked */
__HAL_LOCK(hcryp);
if (hcryp->State == HAL_CRYP_STATE_READY)
{
switch (CallbackID)
{
case HAL_CRYP_INPUT_COMPLETE_CB_ID :
hcryp->InCpltCallback = HAL_CRYP_InCpltCallback; /* Legacy weak InCpltCallback */
break;
case HAL_CRYP_OUTPUT_COMPLETE_CB_ID :
hcryp->OutCpltCallback = HAL_CRYP_OutCpltCallback; /* Legacy weak OutCpltCallback */
break;
case HAL_CRYP_ERROR_CB_ID :
hcryp->ErrorCallback = HAL_CRYP_ErrorCallback; /* Legacy weak ErrorCallback */
break;
case HAL_CRYP_MSPINIT_CB_ID :
hcryp->MspInitCallback = HAL_CRYP_MspInit;
break;
case HAL_CRYP_MSPDEINIT_CB_ID :
hcryp->MspDeInitCallback = HAL_CRYP_MspDeInit;
break;
default :
/* Update the error code */
hcryp->ErrorCode |= HAL_CRYP_ERROR_INVALID_CALLBACK;
/* Return error status */
status = HAL_ERROR;
break;
}
}
else if (hcryp->State == HAL_CRYP_STATE_RESET)
{
switch (CallbackID)
{
case HAL_CRYP_MSPINIT_CB_ID :
hcryp->MspInitCallback = HAL_CRYP_MspInit;
break;
case HAL_CRYP_MSPDEINIT_CB_ID :
hcryp->MspDeInitCallback = HAL_CRYP_MspDeInit;
break;
default :
/* Update the error code */
hcryp->ErrorCode |= HAL_CRYP_ERROR_INVALID_CALLBACK;
/* Return error status */
status = HAL_ERROR;
break;
}
}
else
{
/* Update the error code */
hcryp->ErrorCode |= HAL_CRYP_ERROR_INVALID_CALLBACK;;
/* Return error status */
status = HAL_ERROR;
}
/* Release Lock */
__HAL_UNLOCK(hcryp);
return status;
}
#endif /* USE_HAL_UART_REGISTER_CALLBACKS */
/**
* @}
*/
/** @defgroup CRYP_Exported_Functions_Group2 Encrypt Decrypt functions
* @brief CRYP processing functions.
*
@verbatim
==============================================================================
##### Encrypt Decrypt functions #####
==============================================================================
[..] This section provides API allowing to Encrypt/Decrypt Data following
Standard DES/TDES or AES, and Algorithm configured by the user:
(+) Standard DES/TDES only supported by CRYP1 IP, below list of Algorithm supported :
(++) Electronic Code Book(ECB)
(++) Cipher Block Chaining (CBC)
(+) Standard AES supported by CRYP1 IP , list of Algorithm supported:
(++) Electronic Code Book(ECB)
(++) Cipher Block Chaining (CBC)
(++) Counter mode (CTR)
(++) Cipher Block Chaining (CBC)
(++) Counter mode (CTR)
(++) Galois/counter mode (GCM)
(++) Counter with Cipher Block Chaining-Message(CCM)
[..] Three processing functions are available:
(+) Polling mode : HAL_CRYP_Encrypt & HAL_CRYP_Decrypt
(+) Interrupt mode : HAL_CRYP_Encrypt_IT & HAL_CRYP_Decrypt_IT
(+) DMA mode : HAL_CRYP_Encrypt_DMA & HAL_CRYP_Decrypt_DMA
@endverbatim
* @{
*/
/**
* @brief Encryption mode.
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module
* @param Input: Pointer to the input buffer (plaintext)
* @param Size: Length of the plaintext buffer in word.
* @param Output: Pointer to the output buffer(ciphertext)
* @param Timeout: Specify Timeout value
* @retval HAL status
*/
HAL_StatusTypeDef HAL_CRYP_Encrypt(CRYP_HandleTypeDef *hcryp, uint32_t *Input, uint16_t Size, uint32_t *Output,
uint32_t Timeout)
{
uint32_t algo;
HAL_StatusTypeDef status;
if (hcryp->State == HAL_CRYP_STATE_READY)
{
/* Change state Busy */
hcryp->State = HAL_CRYP_STATE_BUSY;
/* Process locked */
__HAL_LOCK(hcryp);
/* Reset CrypInCount, CrypOutCount and Initialize pCrypInBuffPtr, pCrypOutBuffPtr and Size parameters*/
hcryp->CrypInCount = 0U;
hcryp->CrypOutCount = 0U;
hcryp->pCrypInBuffPtr = Input;
hcryp->pCrypOutBuffPtr = Output;
/* Calculate Size parameter in Byte*/
if (hcryp->Init.DataWidthUnit == CRYP_DATAWIDTHUNIT_WORD)
{
hcryp->Size = Size * 4U;
}
else
{
hcryp->Size = Size;
}
/* Set Encryption operating mode*/
MODIFY_REG(hcryp->Instance->CR, CRYP_CR_ALGODIR, CRYP_OPERATINGMODE_ENCRYPT);
/* algo get algorithm selected */
algo = hcryp->Instance->CR & CRYP_CR_ALGOMODE;
switch (algo)
{
case CRYP_DES_ECB:
case CRYP_DES_CBC:
case CRYP_TDES_ECB:
case CRYP_TDES_CBC:
/*Set Key */
hcryp->Instance->K1LR = *(uint32_t *)(hcryp->Init.pKey);
hcryp->Instance->K1RR = *(uint32_t *)(hcryp->Init.pKey + 1);
if ((hcryp->Init.Algorithm == CRYP_TDES_ECB) || (hcryp->Init.Algorithm == CRYP_TDES_CBC))
{
hcryp->Instance->K2LR = *(uint32_t *)(hcryp->Init.pKey + 2);
hcryp->Instance->K2RR = *(uint32_t *)(hcryp->Init.pKey + 3);
hcryp->Instance->K3LR = *(uint32_t *)(hcryp->Init.pKey + 4);
hcryp->Instance->K3RR = *(uint32_t *)(hcryp->Init.pKey + 5);
}
/*Set Initialization Vector (IV)*/
if ((hcryp->Init.Algorithm == CRYP_DES_CBC) || (hcryp->Init.Algorithm == CRYP_TDES_CBC))
{
hcryp->Instance->IV0LR = *(uint32_t *)(hcryp->Init.pInitVect);
hcryp->Instance->IV0RR = *(uint32_t *)(hcryp->Init.pInitVect + 1);
}
/* Flush FIFO */
HAL_CRYP_FIFO_FLUSH(hcryp);
/* Set the phase */
hcryp->Phase = CRYP_PHASE_PROCESS;
/* Statrt DES/TDES encryption process */
status = CRYP_TDES_Process(hcryp, Timeout);
break;
case CRYP_AES_ECB:
case CRYP_AES_CBC:
case CRYP_AES_CTR:
/* AES encryption */
status = CRYP_AES_Encrypt(hcryp, Timeout);
break;
case CRYP_AES_GCM:
/* AES GCM encryption */
status = CRYP_AESGCM_Process(hcryp, Timeout);
break;
case CRYP_AES_CCM:
/* AES CCM encryption */
status = CRYP_AESCCM_Process(hcryp, Timeout);
break;
default:
hcryp->ErrorCode |= HAL_CRYP_ERROR_NOT_SUPPORTED;
status = HAL_ERROR;
break;
}
if (status == HAL_OK)
{
/* Change the CRYP peripheral state */
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
}
}
else
{
/* Process unlocked */
__HAL_UNLOCK(hcryp);
/* Busy error code field */
hcryp->ErrorCode |= HAL_CRYP_ERROR_BUSY;
status = HAL_ERROR;
}
/* Return function status */
return status ;
}
/**
* @brief Decryption mode.
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module
* @param Input: Pointer to the input buffer (ciphertext )
* @param Size: Length of the plaintext buffer in word.
* @param Output: Pointer to the output buffer(plaintext)
* @param Timeout: Specify Timeout value
* @retval HAL status
*/
HAL_StatusTypeDef HAL_CRYP_Decrypt(CRYP_HandleTypeDef *hcryp, uint32_t *Input, uint16_t Size, uint32_t *Output,
uint32_t Timeout)
{
HAL_StatusTypeDef status;
uint32_t algo;
if (hcryp->State == HAL_CRYP_STATE_READY)
{
/* Change state Busy */
hcryp->State = HAL_CRYP_STATE_BUSY;
/* Process locked */
__HAL_LOCK(hcryp);
/* Reset CrypInCount, CrypOutCount and Initialize pCrypInBuffPtr, pCrypOutBuffPtr and Size parameters*/
hcryp->CrypInCount = 0U;
hcryp->CrypOutCount = 0U;
hcryp->pCrypInBuffPtr = Input;
hcryp->pCrypOutBuffPtr = Output;
/* Calculate Size parameter in Byte*/
if (hcryp->Init.DataWidthUnit == CRYP_DATAWIDTHUNIT_WORD)
{
hcryp->Size = Size * 4U;
}
else
{
hcryp->Size = Size;
}
/* Set Decryption operating mode*/
MODIFY_REG(hcryp->Instance->CR, CRYP_CR_ALGODIR, CRYP_OPERATINGMODE_DECRYPT);
/* algo get algorithm selected */
algo = hcryp->Instance->CR & CRYP_CR_ALGOMODE;
switch (algo)
{
case CRYP_DES_ECB:
case CRYP_DES_CBC:
case CRYP_TDES_ECB:
case CRYP_TDES_CBC:
/*Set Key */
hcryp->Instance->K1LR = *(uint32_t *)(hcryp->Init.pKey);
hcryp->Instance->K1RR = *(uint32_t *)(hcryp->Init.pKey + 1);
if ((hcryp->Init.Algorithm == CRYP_TDES_ECB) || (hcryp->Init.Algorithm == CRYP_TDES_CBC))
{
hcryp->Instance->K2LR = *(uint32_t *)(hcryp->Init.pKey + 2);
hcryp->Instance->K2RR = *(uint32_t *)(hcryp->Init.pKey + 3);
hcryp->Instance->K3LR = *(uint32_t *)(hcryp->Init.pKey + 4);
hcryp->Instance->K3RR = *(uint32_t *)(hcryp->Init.pKey + 5);
}
/*Set Initialization Vector (IV)*/
if ((hcryp->Init.Algorithm == CRYP_DES_CBC) || (hcryp->Init.Algorithm == CRYP_TDES_CBC))
{
hcryp->Instance->IV0LR = *(uint32_t *)(hcryp->Init.pInitVect);
hcryp->Instance->IV0RR = *(uint32_t *)(hcryp->Init.pInitVect + 1);
}
/* Flush FIFO */
HAL_CRYP_FIFO_FLUSH(hcryp);
/* Set the phase */
hcryp->Phase = CRYP_PHASE_PROCESS;
/* Start DES/TDES decryption process */
status = CRYP_TDES_Process(hcryp, Timeout);
break;
case CRYP_AES_ECB:
case CRYP_AES_CBC:
case CRYP_AES_CTR:
/* AES decryption */
status = CRYP_AES_Decrypt(hcryp, Timeout);
break;
case CRYP_AES_GCM:
/* AES GCM decryption */
status = CRYP_AESGCM_Process(hcryp, Timeout) ;
break;
case CRYP_AES_CCM:
/* AES CCM decryption */
status = CRYP_AESCCM_Process(hcryp, Timeout);
break;
default:
hcryp->ErrorCode |= HAL_CRYP_ERROR_NOT_SUPPORTED;
status = HAL_ERROR;
break;
}
if (status == HAL_OK)
{
/* Change the CRYP peripheral state */
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
}
}
else
{
/* Process unlocked */
__HAL_UNLOCK(hcryp);
/* Busy error code field */
hcryp->ErrorCode |= HAL_CRYP_ERROR_BUSY;
status = HAL_ERROR;
}
/* Return function status */
return status;
}
/**
* @brief Encryption in interrupt mode.
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module
* @param Input: Pointer to the input buffer (plaintext)
* @param Size: Length of the plaintext buffer in word
* @param Output: Pointer to the output buffer(ciphertext)
* @retval HAL status
*/
HAL_StatusTypeDef HAL_CRYP_Encrypt_IT(CRYP_HandleTypeDef *hcryp, uint32_t *Input, uint16_t Size, uint32_t *Output)
{
uint32_t algo;
HAL_StatusTypeDef status = HAL_OK;
if (hcryp->State == HAL_CRYP_STATE_READY)
{
/* Change state Busy */
hcryp->State = HAL_CRYP_STATE_BUSY;
/* Process locked */
__HAL_LOCK(hcryp);
/* Reset CrypInCount, CrypOutCount and Initialize pCrypInBuffPtr, pCrypOutBuffPtr and Size parameters*/
hcryp->CrypInCount = 0U;
hcryp->CrypOutCount = 0U;
hcryp->pCrypInBuffPtr = Input;
hcryp->pCrypOutBuffPtr = Output;
/* Calculate Size parameter in Byte*/
if (hcryp->Init.DataWidthUnit == CRYP_DATAWIDTHUNIT_WORD)
{
hcryp->Size = Size * 4U;
}
else
{
hcryp->Size = Size;
}
/* Set encryption operating mode*/
MODIFY_REG(hcryp->Instance->CR, CRYP_CR_ALGODIR, CRYP_OPERATINGMODE_ENCRYPT);
/* algo get algorithm selected */
algo = (hcryp->Instance->CR & CRYP_CR_ALGOMODE);
switch (algo)
{
case CRYP_DES_ECB:
case CRYP_DES_CBC:
case CRYP_TDES_ECB:
case CRYP_TDES_CBC:
/*Set Key */
hcryp->Instance->K1LR = *(uint32_t *)(hcryp->Init.pKey);
hcryp->Instance->K1RR = *(uint32_t *)(hcryp->Init.pKey + 1);
if ((hcryp->Init.Algorithm == CRYP_TDES_ECB) || (hcryp->Init.Algorithm == CRYP_TDES_CBC))
{
hcryp->Instance->K2LR = *(uint32_t *)(hcryp->Init.pKey + 2);
hcryp->Instance->K2RR = *(uint32_t *)(hcryp->Init.pKey + 3);
hcryp->Instance->K3LR = *(uint32_t *)(hcryp->Init.pKey + 4);
hcryp->Instance->K3RR = *(uint32_t *)(hcryp->Init.pKey + 5);
}
/* Set the Initialization Vector*/
if ((hcryp->Init.Algorithm == CRYP_DES_CBC) || (hcryp->Init.Algorithm == CRYP_TDES_CBC))
{
hcryp->Instance->IV0LR = *(uint32_t *)(hcryp->Init.pInitVect);
hcryp->Instance->IV0RR = *(uint32_t *)(hcryp->Init.pInitVect + 1);
}
/* Flush FIFO */
HAL_CRYP_FIFO_FLUSH(hcryp);
/* Set the phase */
hcryp->Phase = CRYP_PHASE_PROCESS;
/* Enable interrupts */
__HAL_CRYP_ENABLE_IT(hcryp, CRYP_IT_INI | CRYP_IT_OUTI);
/* Enable CRYP to start DES/TDES process*/
__HAL_CRYP_ENABLE(hcryp);
break;
case CRYP_AES_ECB:
case CRYP_AES_CBC:
case CRYP_AES_CTR:
status = CRYP_AES_Encrypt_IT(hcryp);
break;
case CRYP_AES_GCM:
status = CRYP_AESGCM_Process_IT(hcryp) ;
break;
case CRYP_AES_CCM:
status = CRYP_AESCCM_Process_IT(hcryp);
break;
default:
hcryp->ErrorCode |= HAL_CRYP_ERROR_NOT_SUPPORTED;
status = HAL_ERROR;
break;
}
}
else
{
/* Busy error code field */
hcryp->ErrorCode |= HAL_CRYP_ERROR_BUSY;
status = HAL_ERROR;
}
/* Return function status */
return status ;
}
/**
* @brief Decryption in itnterrupt mode.
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module
* @param Input: Pointer to the input buffer (ciphertext )
* @param Size: Length of the plaintext buffer in word.
* @param Output: Pointer to the output buffer(plaintext)
* @retval HAL status
*/
HAL_StatusTypeDef HAL_CRYP_Decrypt_IT(CRYP_HandleTypeDef *hcryp, uint32_t *Input, uint16_t Size, uint32_t *Output)
{
uint32_t algo;
HAL_StatusTypeDef status = HAL_OK;
if (hcryp->State == HAL_CRYP_STATE_READY)
{
/* Change state Busy */
hcryp->State = HAL_CRYP_STATE_BUSY;
/* Process locked */
__HAL_LOCK(hcryp);
/* Reset CrypInCount, CrypOutCount and Initialize pCrypInBuffPtr, pCrypOutBuffPtr and Size parameters*/
hcryp->CrypInCount = 0U;
hcryp->CrypOutCount = 0U;
hcryp->pCrypInBuffPtr = Input;
hcryp->pCrypOutBuffPtr = Output;
/* Calculate Size parameter in Byte*/
if (hcryp->Init.DataWidthUnit == CRYP_DATAWIDTHUNIT_WORD)
{
hcryp->Size = Size * 4U;
}
else
{
hcryp->Size = Size;
}
/* Set decryption operating mode*/
MODIFY_REG(hcryp->Instance->CR, CRYP_CR_ALGODIR, CRYP_OPERATINGMODE_DECRYPT);
/* algo get algorithm selected */
algo = hcryp->Instance->CR & CRYP_CR_ALGOMODE;
switch (algo)
{
case CRYP_DES_ECB:
case CRYP_DES_CBC:
case CRYP_TDES_ECB:
case CRYP_TDES_CBC:
/*Set Key */
hcryp->Instance->K1LR = *(uint32_t *)(hcryp->Init.pKey);
hcryp->Instance->K1RR = *(uint32_t *)(hcryp->Init.pKey + 1);
if ((hcryp->Init.Algorithm == CRYP_TDES_ECB) || (hcryp->Init.Algorithm == CRYP_TDES_CBC))
{
hcryp->Instance->K2LR = *(uint32_t *)(hcryp->Init.pKey + 2);
hcryp->Instance->K2RR = *(uint32_t *)(hcryp->Init.pKey + 3);
hcryp->Instance->K3LR = *(uint32_t *)(hcryp->Init.pKey + 4);
hcryp->Instance->K3RR = *(uint32_t *)(hcryp->Init.pKey + 5);
}
/* Set the Initialization Vector*/
if ((hcryp->Init.Algorithm == CRYP_DES_CBC) || (hcryp->Init.Algorithm == CRYP_TDES_CBC))
{
hcryp->Instance->IV0LR = *(uint32_t *)(hcryp->Init.pInitVect);
hcryp->Instance->IV0RR = *(uint32_t *)(hcryp->Init.pInitVect + 1);
}
/* Flush FIFO */
HAL_CRYP_FIFO_FLUSH(hcryp);
/* Set the phase */
hcryp->Phase = CRYP_PHASE_PROCESS;
/* Enable interrupts */
__HAL_CRYP_ENABLE_IT(hcryp, CRYP_IT_INI | CRYP_IT_OUTI);
/* Enable CRYP and start DES/TDES process*/
__HAL_CRYP_ENABLE(hcryp);
break;
case CRYP_AES_ECB:
case CRYP_AES_CBC:
case CRYP_AES_CTR:
/* AES decryption */
status = CRYP_AES_Decrypt_IT(hcryp);
break;
case CRYP_AES_GCM:
/* AES GCM decryption */
status = CRYP_AESGCM_Process_IT(hcryp) ;
break;
case CRYP_AES_CCM:
/* AES CCMdecryption */
status = CRYP_AESCCM_Process_IT(hcryp);
break;
default:
hcryp->ErrorCode |= HAL_CRYP_ERROR_NOT_SUPPORTED;
status = HAL_ERROR;
break;
}
}
else
{
/* Busy error code field */
hcryp->ErrorCode |= HAL_CRYP_ERROR_BUSY;
status = HAL_ERROR;
}
/* Return function status */
return status;
}
/**
* @brief Encryption in DMA mode.
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module
* @param Input: Pointer to the input buffer (plaintext)
* @param Size: Length of the plaintext buffer in word.
* @param Output: Pointer to the output buffer(ciphertext)
* @retval HAL status
*/
HAL_StatusTypeDef HAL_CRYP_Encrypt_DMA(CRYP_HandleTypeDef *hcryp, uint32_t *Input, uint16_t Size, uint32_t *Output)
{
uint32_t algo;
HAL_StatusTypeDef status = HAL_OK;
if (hcryp->State == HAL_CRYP_STATE_READY)
{
/* Change state Busy */
hcryp->State = HAL_CRYP_STATE_BUSY;
/* Process locked */
__HAL_LOCK(hcryp);
/* Reset CrypInCount, CrypOutCount and Initialize pCrypInBuffPtr, pCrypOutBuffPtr and Size parameters*/
hcryp->CrypInCount = 0U;
hcryp->CrypOutCount = 0U;
hcryp->pCrypInBuffPtr = Input;
hcryp->pCrypOutBuffPtr = Output;
/* Calculate Size parameter in Byte*/
if (hcryp->Init.DataWidthUnit == CRYP_DATAWIDTHUNIT_WORD)
{
hcryp->Size = Size * 4U;
}
else
{
hcryp->Size = Size;
}
/* Set encryption operating mode*/
MODIFY_REG(hcryp->Instance->CR, CRYP_CR_ALGODIR, CRYP_OPERATINGMODE_ENCRYPT);
/* algo get algorithm selected */
algo = hcryp->Instance->CR & CRYP_CR_ALGOMODE;
switch (algo)
{
case CRYP_DES_ECB:
case CRYP_DES_CBC:
case CRYP_TDES_ECB:
case CRYP_TDES_CBC:
/*Set Key */
hcryp->Instance->K1LR = *(uint32_t *)(hcryp->Init.pKey);
hcryp->Instance->K1RR = *(uint32_t *)(hcryp->Init.pKey + 1);
if ((hcryp->Init.Algorithm == CRYP_TDES_ECB) || (hcryp->Init.Algorithm == CRYP_TDES_CBC))
{
hcryp->Instance->K2LR = *(uint32_t *)(hcryp->Init.pKey + 2);
hcryp->Instance->K2RR = *(uint32_t *)(hcryp->Init.pKey + 3);
hcryp->Instance->K3LR = *(uint32_t *)(hcryp->Init.pKey + 4);
hcryp->Instance->K3RR = *(uint32_t *)(hcryp->Init.pKey + 5);
}
/* Set the Initialization Vector*/
if ((hcryp->Init.Algorithm == CRYP_DES_CBC) || (hcryp->Init.Algorithm == CRYP_TDES_CBC))
{
hcryp->Instance->IV0LR = *(uint32_t *)(hcryp->Init.pInitVect);
hcryp->Instance->IV0RR = *(uint32_t *)(hcryp->Init.pInitVect + 1);
}
/* Flush FIFO */
HAL_CRYP_FIFO_FLUSH(hcryp);
/* Set the phase */
hcryp->Phase = CRYP_PHASE_PROCESS;
/* Start DMA process transfer for DES/TDES */
CRYP_SetDMAConfig(hcryp, (uint32_t)(hcryp->pCrypInBuffPtr), (hcryp->Size / 4U), (uint32_t)(hcryp->pCrypOutBuffPtr));
break;
case CRYP_AES_ECB:
case CRYP_AES_CBC:
case CRYP_AES_CTR:
/* Set the Key*/
CRYP_SetKey(hcryp, hcryp->Init.KeySize);
/* Set the Initialization Vector IV */
if (hcryp->Init.Algorithm != CRYP_AES_ECB)
{
hcryp->Instance->IV0LR = *(uint32_t *)(hcryp->Init.pInitVect);
hcryp->Instance->IV0RR = *(uint32_t *)(hcryp->Init.pInitVect + 1);
hcryp->Instance->IV1LR = *(uint32_t *)(hcryp->Init.pInitVect + 2);
hcryp->Instance->IV1RR = *(uint32_t *)(hcryp->Init.pInitVect + 3);
}
/* Set the phase */
hcryp->Phase = CRYP_PHASE_PROCESS;
/* Start DMA process transfer for AES */
CRYP_SetDMAConfig(hcryp, (uint32_t)(hcryp->pCrypInBuffPtr), (hcryp->Size / 4U), (uint32_t)(hcryp->pCrypOutBuffPtr));
break;
case CRYP_AES_GCM:
/* AES GCM encryption */
status = CRYP_AESGCM_Process_DMA(hcryp) ;
break;
case CRYP_AES_CCM:
/* AES CCM encryption */
status = CRYP_AESCCM_Process_DMA(hcryp);
break;
default:
hcryp->ErrorCode |= HAL_CRYP_ERROR_NOT_SUPPORTED;
status = HAL_ERROR;
break;
}
}
else
{
/* Busy error code field */
hcryp->ErrorCode |= HAL_CRYP_ERROR_BUSY;
status = HAL_ERROR;
}
/* Return function status */
return status;
}
/**
* @brief Decryption in DMA mode.
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module
* @param Input: Pointer to the input buffer (ciphertext )
* @param Size: Length of the plaintext buffer in word
* @param Output: Pointer to the output buffer(plaintext)
* @retval HAL status
*/
HAL_StatusTypeDef HAL_CRYP_Decrypt_DMA(CRYP_HandleTypeDef *hcryp, uint32_t *Input, uint16_t Size, uint32_t *Output)
{
uint32_t algo;
HAL_StatusTypeDef status = HAL_OK;
if (hcryp->State == HAL_CRYP_STATE_READY)
{
/* Change state Busy */
hcryp->State = HAL_CRYP_STATE_BUSY;
/* Process locked */
__HAL_LOCK(hcryp);
/* Reset CrypInCount, CrypOutCount and Initialize pCrypInBuffPtr, pCrypOutBuffPtr and Size parameters*/
hcryp->CrypInCount = 0U;
hcryp->CrypOutCount = 0U;
hcryp->pCrypInBuffPtr = Input;
hcryp->pCrypOutBuffPtr = Output;
/* Calculate Size parameter in Byte*/
if (hcryp->Init.DataWidthUnit == CRYP_DATAWIDTHUNIT_WORD)
{
hcryp->Size = Size * 4U;
}
else
{
hcryp->Size = Size;
}
/* Set decryption operating mode*/
MODIFY_REG(hcryp->Instance->CR, CRYP_CR_ALGODIR, CRYP_OPERATINGMODE_DECRYPT);
/* algo get algorithm selected */
algo = hcryp->Instance->CR & CRYP_CR_ALGOMODE;
switch (algo)
{
case CRYP_DES_ECB:
case CRYP_DES_CBC:
case CRYP_TDES_ECB:
case CRYP_TDES_CBC:
/*Set Key */
hcryp->Instance->K1LR = *(uint32_t *)(hcryp->Init.pKey);
hcryp->Instance->K1RR = *(uint32_t *)(hcryp->Init.pKey + 1);
if ((hcryp->Init.Algorithm == CRYP_TDES_ECB) || (hcryp->Init.Algorithm == CRYP_TDES_CBC))
{
hcryp->Instance->K2LR = *(uint32_t *)(hcryp->Init.pKey + 2);
hcryp->Instance->K2RR = *(uint32_t *)(hcryp->Init.pKey + 3);
hcryp->Instance->K3LR = *(uint32_t *)(hcryp->Init.pKey + 4);
hcryp->Instance->K3RR = *(uint32_t *)(hcryp->Init.pKey + 5);
}
/* Set the Initialization Vector*/
if ((hcryp->Init.Algorithm == CRYP_DES_CBC) || (hcryp->Init.Algorithm == CRYP_TDES_CBC))
{
hcryp->Instance->IV0LR = *(uint32_t *)(hcryp->Init.pInitVect);
hcryp->Instance->IV0RR = *(uint32_t *)(hcryp->Init.pInitVect + 1);
}
/* Flush FIFO */
HAL_CRYP_FIFO_FLUSH(hcryp);
/* Set the phase */
hcryp->Phase = CRYP_PHASE_PROCESS;
/* Start DMA process transfer for DES/TDES */
CRYP_SetDMAConfig(hcryp, (uint32_t)(hcryp->pCrypInBuffPtr), (hcryp->Size / 4U), (uint32_t)(hcryp->pCrypOutBuffPtr));
break;
case CRYP_AES_ECB:
case CRYP_AES_CBC:
case CRYP_AES_CTR:
/* AES decryption */
status = CRYP_AES_Decrypt_DMA(hcryp);
break;
case CRYP_AES_GCM:
/* AES GCM decryption */
status = CRYP_AESGCM_Process_DMA(hcryp) ;
break;
case CRYP_AES_CCM:
/* AES CCM decryption */
status = CRYP_AESCCM_Process_DMA(hcryp);
break;
default:
hcryp->ErrorCode |= HAL_CRYP_ERROR_NOT_SUPPORTED;
status = HAL_ERROR;
break;
}
}
else
{
/* Busy error code field */
hcryp->ErrorCode |= HAL_CRYP_ERROR_BUSY;
status = HAL_ERROR;
}
/* Return function status */
return status;
}
/**
* @}
*/
/** @defgroup CRYP_Exported_Functions_Group3 CRYP IRQ handler management
* @brief CRYP IRQ handler.
*
@verbatim
==============================================================================
##### CRYP IRQ handler management #####
==============================================================================
[..] This section provides CRYP IRQ handler and callback functions.
(+) HAL_CRYP_IRQHandler CRYP interrupt request
(+) HAL_CRYP_InCpltCallback input data transfer complete callback
(+) HAL_CRYP_OutCpltCallback output data transfer complete callback
(+) HAL_CRYP_ErrorCallback CRYP error callback
(+) HAL_CRYP_GetState return the CRYP state
(+) HAL_CRYP_GetError return the CRYP error code
@endverbatim
* @{
*/
/**
* @brief This function handles cryptographic interrupt request.
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module
* @retval None
*/
void HAL_CRYP_IRQHandler(CRYP_HandleTypeDef *hcryp)
{
uint32_t itstatus = hcryp->Instance->MISR;
if ((itstatus & (CRYP_IT_INI | CRYP_IT_OUTI)) != 0U)
{
if ((hcryp->Init.Algorithm == CRYP_DES_ECB) || (hcryp->Init.Algorithm == CRYP_DES_CBC) || (hcryp->Init.Algorithm == CRYP_TDES_ECB) || (hcryp->Init.Algorithm == CRYP_TDES_CBC))
{
CRYP_TDES_IT(hcryp); /* DES or TDES*/
}
else if ((hcryp->Init.Algorithm == CRYP_AES_ECB) || (hcryp->Init.Algorithm == CRYP_AES_CBC) || (hcryp->Init.Algorithm == CRYP_AES_CTR))
{
CRYP_AES_IT(hcryp); /*AES*/
}
else if ((hcryp->Init.Algorithm == CRYP_AES_GCM) || (hcryp->Init.Algorithm == CRYP_CR_ALGOMODE_AES_CCM))
{
/* if header phase */
if ((hcryp->Instance->CR & CRYP_PHASE_HEADER) == CRYP_PHASE_HEADER)
{
CRYP_GCMCCM_SetHeaderPhase_IT(hcryp);
}
else /* if payload phase */
{
CRYP_GCMCCM_SetPayloadPhase_IT(hcryp);
}
}
else
{
/* Nothing to do */
}
}
}
/**
* @brief Return the CRYP error code.
* @param hcryp : pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for the CRYP IP
* @retval CRYP error code
*/
uint32_t HAL_CRYP_GetError(CRYP_HandleTypeDef *hcryp)
{
return hcryp->ErrorCode;
}
/**
* @brief Returns the CRYP state.
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module.
* @retval HAL state
*/
HAL_CRYP_STATETypeDef HAL_CRYP_GetState(CRYP_HandleTypeDef *hcryp)
{
return hcryp->State;
}
/**
* @brief Input FIFO transfer completed callback.
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module.
* @retval None
*/
__weak void HAL_CRYP_InCpltCallback(CRYP_HandleTypeDef *hcryp)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(hcryp);
/* NOTE : This function Should not be modified, when the callback is needed,
the HAL_CRYP_InCpltCallback could be implemented in the user file
*/
}
/**
* @brief Output FIFO transfer completed callback.
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module.
* @retval None
*/
__weak void HAL_CRYP_OutCpltCallback(CRYP_HandleTypeDef *hcryp)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(hcryp);
/* NOTE : This function Should not be modified, when the callback is needed,
the HAL_CRYP_OutCpltCallback could be implemented in the user file
*/
}
/**
* @brief CRYP error callback.
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module.
* @retval None
*/
__weak void HAL_CRYP_ErrorCallback(CRYP_HandleTypeDef *hcryp)
{
/* Prevent unused argument(s) compilation warning */
UNUSED(hcryp);
/* NOTE : This function Should not be modified, when the callback is needed,
the HAL_CRYP_ErrorCallback could be implemented in the user file
*/
}
/**
* @}
*/
/* Private functions ---------------------------------------------------------*/
/** @addtogroup CRYP_Private_Functions
* @{
*/
/**
* @brief Encryption in ECB/CBC Algorithm with DES/TDES standard.
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module
* @param Timeout: Timeout value
* @retval HAL status
*/
static HAL_StatusTypeDef CRYP_TDES_Process(CRYP_HandleTypeDef *hcryp, uint32_t Timeout)
{
uint32_t temp; /* Temporary CrypOutBuff */
uint16_t incount; /* Temporary CrypInCount Value */
uint16_t outcount; /* Temporary CrypOutCount Value */
/* Enable CRYP */
__HAL_CRYP_ENABLE(hcryp);
/*Temporary CrypOutCount Value*/
outcount = hcryp->CrypOutCount;
/*Start processing*/
while ((hcryp->CrypInCount < (hcryp->Size / 4U)) && (outcount < (hcryp->Size / 4U)))
{
/* Temporary CrypInCount Value */
incount = hcryp->CrypInCount;
/* Write plain data and get cipher data */
if (((hcryp->Instance->SR & CRYP_FLAG_IFNF) != 0x0U) && (incount < (hcryp->Size / 4U)))
{
/* Write the input block in the IN FIFO */
hcryp->Instance->DIN = *(uint32_t *)(hcryp->pCrypInBuffPtr + hcryp->CrypInCount);
hcryp->CrypInCount++;
hcryp->Instance->DIN = *(uint32_t *)(hcryp->pCrypInBuffPtr + hcryp->CrypInCount);
hcryp->CrypInCount++;
}
/* Wait for OFNE flag to be raised */
if (CRYP_WaitOnOFNEFlag(hcryp, Timeout) != HAL_OK)
{
/* Disable the CRYP peripheral clock */
__HAL_CRYP_DISABLE(hcryp);
/* Change state & errorCode*/
hcryp->ErrorCode |= HAL_CRYP_ERROR_TIMEOUT;
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
#if (USE_HAL_CRYP_REGISTER_CALLBACKS == 1)
/*Call registered error callback*/
hcryp->ErrorCallback(hcryp);
#else
/*Call legacy weak error callback*/
HAL_CRYP_ErrorCallback(hcryp);
#endif /* USE_HAL_CRYP_REGISTER_CALLBACKS */
}
/*Temporary CrypOutCount Value*/
outcount = hcryp->CrypOutCount;
if (((hcryp->Instance->SR & CRYP_FLAG_OFNE) != 0x0U) && (outcount < (hcryp->Size / 4U)))
{
/* Read the output block from the Output FIFO and put them in temporary Buffer then get CrypOutBuff from temporary buffer */
temp = hcryp->Instance->DOUT;
*(uint32_t *)(hcryp->pCrypOutBuffPtr + (hcryp->CrypOutCount)) = temp;
hcryp->CrypOutCount++;
temp = hcryp->Instance->DOUT;
*(uint32_t *)(hcryp->pCrypOutBuffPtr + (hcryp->CrypOutCount)) = temp;
hcryp->CrypOutCount++;
}
/*Temporary CrypOutCount Value*/
outcount = hcryp->CrypOutCount;
}
/* Disable CRYP */
__HAL_CRYP_DISABLE(hcryp);
/* Change the CRYP state */
hcryp->State = HAL_CRYP_STATE_READY;
/* Return function status */
return HAL_OK;
}
/**
* @brief CRYP block input/output data handling under interruption with DES/TDES standard.
* @note The function is called under interruption only, once
* interruptions have been enabled by CRYP_Decrypt_IT() and CRYP_Encrypt_IT().
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module.
* @retval HAL status
*/
static void CRYP_TDES_IT(CRYP_HandleTypeDef *hcryp)
{
uint32_t temp; /* Temporary CrypOutBuff */
if (hcryp->State == HAL_CRYP_STATE_BUSY)
{
if (__HAL_CRYP_GET_IT(hcryp, CRYP_IT_INI) != 0x0U)
{
if(__HAL_CRYP_GET_FLAG(hcryp, CRYP_FLAG_INRIS) != 0x0U)
{
/* Write input block in the IN FIFO */
hcryp->Instance->DIN = *(uint32_t *)(hcryp->pCrypInBuffPtr + hcryp->CrypInCount);
hcryp->CrypInCount++;
hcryp->Instance->DIN = *(uint32_t *)(hcryp->pCrypInBuffPtr + hcryp->CrypInCount);
hcryp->CrypInCount++;
if (hcryp->CrypInCount == (hcryp->Size / 4U))
{
/* Disable interruption */
__HAL_CRYP_DISABLE_IT(hcryp, CRYP_IT_INI);
/* Call the input data transfer complete callback */
#if (USE_HAL_CRYP_REGISTER_CALLBACKS == 1)
/*Call registered Input complete callback*/
hcryp->InCpltCallback(hcryp);
#else
/*Call legacy weak Input complete callback*/
HAL_CRYP_InCpltCallback(hcryp);
#endif /* USE_HAL_CRYP_REGISTER_CALLBACKS */
}
}
}
if (__HAL_CRYP_GET_IT(hcryp, CRYP_IT_OUTI) != 0x0U)
{
if(__HAL_CRYP_GET_FLAG(hcryp, CRYP_FLAG_OUTRIS) != 0x0U)
{
/* Read the output block from the Output FIFO and put them in temporary Buffer then get CrypOutBuff from temporary buffer */
temp = hcryp->Instance->DOUT;
*(uint32_t *)(hcryp->pCrypOutBuffPtr + (hcryp->CrypOutCount)) = temp;
hcryp->CrypOutCount++;
temp = hcryp->Instance->DOUT;
*(uint32_t *)(hcryp->pCrypOutBuffPtr + (hcryp->CrypOutCount)) = temp;
hcryp->CrypOutCount++;
if (hcryp->CrypOutCount == (hcryp->Size / 4U))
{
/* Disable interruption */
__HAL_CRYP_DISABLE_IT(hcryp, CRYP_IT_OUTI);
/* Disable CRYP */
__HAL_CRYP_DISABLE(hcryp);
/* Process unlocked */
__HAL_UNLOCK(hcryp);
/* Change the CRYP state */
hcryp->State = HAL_CRYP_STATE_READY;
/* Call output transfer complete callback */
#if (USE_HAL_CRYP_REGISTER_CALLBACKS == 1)
/*Call registered Output complete callback*/
hcryp->OutCpltCallback(hcryp);
#else
/*Call legacy weak Output complete callback*/
HAL_CRYP_OutCpltCallback(hcryp);
#endif /* USE_HAL_CRYP_REGISTER_CALLBACKS */
}
}
}
}
else
{
/* Process unlocked */
__HAL_UNLOCK(hcryp);
/* Busy error code field */
hcryp->ErrorCode |= HAL_CRYP_ERROR_BUSY;
#if (USE_HAL_CRYP_REGISTER_CALLBACKS == 1)
/*Call registered error callback*/
hcryp->ErrorCallback(hcryp);
#else
/*Call legacy weak error callback*/
HAL_CRYP_ErrorCallback(hcryp);
#endif /* USE_HAL_CRYP_REGISTER_CALLBACKS */
}
}
/**
* @brief Encryption in ECB/CBC & CTR Algorithm with AES Standard
* @param hcryp: pointer to a CRYP_HandleTypeDef structure
* @param Timeout: specify Timeout value
* @retval HAL status
*/
static HAL_StatusTypeDef CRYP_AES_Encrypt(CRYP_HandleTypeDef *hcryp, uint32_t Timeout)
{
uint16_t outcount; /* Temporary CrypOutCount Value */
/* Set the Key*/
CRYP_SetKey(hcryp, hcryp->Init.KeySize);
if (hcryp->Init.Algorithm != CRYP_AES_ECB)
{
/* Set the Initialization Vector*/
hcryp->Instance->IV0LR = *(uint32_t *)(hcryp->Init.pInitVect);
hcryp->Instance->IV0RR = *(uint32_t *)(hcryp->Init.pInitVect + 1);
hcryp->Instance->IV1LR = *(uint32_t *)(hcryp->Init.pInitVect + 2);
hcryp->Instance->IV1RR = *(uint32_t *)(hcryp->Init.pInitVect + 3);
}
/* Set the phase */
hcryp->Phase = CRYP_PHASE_PROCESS;
/* Enable CRYP */
__HAL_CRYP_ENABLE(hcryp);
/*Temporary CrypOutCount Value*/
outcount = hcryp->CrypOutCount;
while ((hcryp->CrypInCount < (hcryp->Size / 4U)) && (outcount < (hcryp->Size / 4U)))
{
/* Write plain Ddta and get cipher data */
CRYP_AES_ProcessData(hcryp, Timeout);
/*Temporary CrypOutCount Value*/
outcount = hcryp->CrypOutCount;
}
/* Disable CRYP */
__HAL_CRYP_DISABLE(hcryp);
/* Change the CRYP state */
hcryp->State = HAL_CRYP_STATE_READY;
/* Return function status */
return HAL_OK;
}
/**
* @brief Encryption in ECB/CBC & CTR mode with AES Standard using interrupt mode
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module
* @retval HAL status
*/
static HAL_StatusTypeDef CRYP_AES_Encrypt_IT(CRYP_HandleTypeDef *hcryp)
{
/* Set the Key*/
CRYP_SetKey(hcryp, hcryp->Init.KeySize);
if (hcryp->Init.Algorithm != CRYP_AES_ECB)
{
/* Set the Initialization Vector*/
hcryp->Instance->IV0LR = *(uint32_t *)(hcryp->Init.pInitVect);
hcryp->Instance->IV0RR = *(uint32_t *)(hcryp->Init.pInitVect + 1);
hcryp->Instance->IV1LR = *(uint32_t *)(hcryp->Init.pInitVect + 2);
hcryp->Instance->IV1RR = *(uint32_t *)(hcryp->Init.pInitVect + 3);
}
/* Set the phase */
hcryp->Phase = CRYP_PHASE_PROCESS;
if (hcryp->Size != 0U)
{
/* Enable interrupts */
__HAL_CRYP_ENABLE_IT(hcryp, CRYP_IT_INI | CRYP_IT_OUTI);
/* Enable CRYP */
__HAL_CRYP_ENABLE(hcryp);
}
else
{
/* Change the CRYP state */
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
}
/* Return function status */
return HAL_OK;
}
/**
* @brief Decryption in ECB/CBC & CTR mode with AES Standard
* @param hcryp: pointer to a CRYP_HandleTypeDef structure
* @param Timeout: Specify Timeout value
* @retval HAL status
*/
static HAL_StatusTypeDef CRYP_AES_Decrypt(CRYP_HandleTypeDef *hcryp, uint32_t Timeout)
{
uint16_t outcount; /* Temporary CrypOutCount Value */
/* Key preparation for ECB/CBC */
if (hcryp->Init.Algorithm != CRYP_AES_CTR) /*ECB or CBC*/
{
/* change ALGOMODE to key preparation for decryption*/
MODIFY_REG(hcryp->Instance->CR, CRYP_CR_ALGOMODE, CRYP_CR_ALGOMODE_AES_KEY);
/* Set the Key*/
CRYP_SetKey(hcryp, hcryp->Init.KeySize);
/* Enable CRYP */
__HAL_CRYP_ENABLE(hcryp);
/* Wait for BUSY flag to be raised */
if (CRYP_WaitOnBUSYFlag(hcryp, Timeout) != HAL_OK)
{
/* Disable the CRYP peripheral clock */
__HAL_CRYP_DISABLE(hcryp);
/* Change state */
hcryp->ErrorCode |= HAL_CRYP_ERROR_TIMEOUT;
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
return HAL_ERROR;
}
/* Turn back to ALGOMODE of the configuration */
MODIFY_REG(hcryp->Instance->CR, CRYP_CR_ALGOMODE, hcryp->Init.Algorithm);
}
else /*Algorithm CTR */
{
/* Set the Key*/
CRYP_SetKey(hcryp, hcryp->Init.KeySize);
}
/* Set IV */
if (hcryp->Init.Algorithm != CRYP_AES_ECB)
{
/* Set the Initialization Vector*/
hcryp->Instance->IV0LR = *(uint32_t *)(hcryp->Init.pInitVect);
hcryp->Instance->IV0RR = *(uint32_t *)(hcryp->Init.pInitVect + 1);
hcryp->Instance->IV1LR = *(uint32_t *)(hcryp->Init.pInitVect + 2);
hcryp->Instance->IV1RR = *(uint32_t *)(hcryp->Init.pInitVect + 3);
}
/* Set the phase */
hcryp->Phase = CRYP_PHASE_PROCESS;
/* Enable CRYP */
__HAL_CRYP_ENABLE(hcryp);
/*Temporary CrypOutCount Value*/
outcount = hcryp->CrypOutCount;
while ((hcryp->CrypInCount < (hcryp->Size / 4U)) && (outcount < (hcryp->Size / 4U)))
{
/* Write plain data and get cipher data */
CRYP_AES_ProcessData(hcryp, Timeout);
/*Temporary CrypOutCount Value*/
outcount = hcryp->CrypOutCount;
}
/* Disable CRYP */
__HAL_CRYP_DISABLE(hcryp);
/* Change the CRYP state */
hcryp->State = HAL_CRYP_STATE_READY;
/* Return function status */
return HAL_OK;
}
/**
* @brief Decryption in ECB/CBC & CTR mode with AES Standard using interrupt mode
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module
* @retval HAL status
*/
static HAL_StatusTypeDef CRYP_AES_Decrypt_IT(CRYP_HandleTypeDef *hcryp)
{
__IO uint32_t count = 0U;
/* Key preparation for ECB/CBC */
if (hcryp->Init.Algorithm != CRYP_AES_CTR)
{
/* change ALGOMODE to key preparation for decryption*/
MODIFY_REG(hcryp->Instance->CR, CRYP_CR_ALGOMODE, CRYP_CR_ALGOMODE_AES_KEY);
/* Set the Key*/
CRYP_SetKey(hcryp, hcryp->Init.KeySize);
/* Enable CRYP */
__HAL_CRYP_ENABLE(hcryp);
/* Wait for BUSY flag to be raised */
count = CRYP_TIMEOUT_KEYPREPARATION;
do
{
count-- ;
if (count == 0U)
{
/* Change state */
hcryp->ErrorCode |= HAL_CRYP_ERROR_TIMEOUT;
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
return HAL_ERROR;
}
} while (HAL_IS_BIT_SET(hcryp->Instance->SR, CRYP_FLAG_BUSY));
/* Turn back to ALGOMODE of the configuration */
MODIFY_REG(hcryp->Instance->CR, CRYP_CR_ALGOMODE, hcryp->Init.Algorithm);
}
else /*Algorithm CTR */
{
/* Set the Key*/
CRYP_SetKey(hcryp, hcryp->Init.KeySize);
}
/* Set IV */
if (hcryp->Init.Algorithm != CRYP_AES_ECB)
{
/* Set the Initialization Vector*/
hcryp->Instance->IV0LR = *(uint32_t *)(hcryp->Init.pInitVect);
hcryp->Instance->IV0RR = *(uint32_t *)(hcryp->Init.pInitVect + 1);
hcryp->Instance->IV1LR = *(uint32_t *)(hcryp->Init.pInitVect + 2);
hcryp->Instance->IV1RR = *(uint32_t *)(hcryp->Init.pInitVect + 3);
}
/* Set the phase */
hcryp->Phase = CRYP_PHASE_PROCESS;
if (hcryp->Size != 0U)
{
/* Enable interrupts */
__HAL_CRYP_ENABLE_IT(hcryp, CRYP_IT_INI | CRYP_IT_OUTI);
/* Enable CRYP */
__HAL_CRYP_ENABLE(hcryp);
}
else
{
/* Process locked */
__HAL_UNLOCK(hcryp);
/* Change the CRYP state */
hcryp->State = HAL_CRYP_STATE_READY;
}
/* Return function status */
return HAL_OK;
}
/**
* @brief Decryption in ECB/CBC & CTR mode with AES Standard using DMA mode
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module
* @retval HAL status
*/
static HAL_StatusTypeDef CRYP_AES_Decrypt_DMA(CRYP_HandleTypeDef *hcryp)
{
__IO uint32_t count = 0U;
/* Key preparation for ECB/CBC */
if (hcryp->Init.Algorithm != CRYP_AES_CTR)
{
/* change ALGOMODE to key preparation for decryption*/
MODIFY_REG(hcryp->Instance->CR, CRYP_CR_ALGOMODE, CRYP_CR_ALGOMODE_AES_KEY);
/* Set the Key*/
CRYP_SetKey(hcryp, hcryp->Init.KeySize);
/* Enable CRYP */
__HAL_CRYP_ENABLE(hcryp);
/* Wait for BUSY flag to be raised */
count = CRYP_TIMEOUT_KEYPREPARATION;
do
{
count-- ;
if (count == 0U)
{
/* Disable the CRYP peripheral clock */
__HAL_CRYP_DISABLE(hcryp);
/* Change state */
hcryp->ErrorCode |= HAL_CRYP_ERROR_TIMEOUT;
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
return HAL_ERROR;
}
} while (HAL_IS_BIT_SET(hcryp->Instance->SR, CRYP_FLAG_BUSY));
/* Turn back to ALGOMODE of the configuration */
MODIFY_REG(hcryp->Instance->CR, CRYP_CR_ALGOMODE, hcryp->Init.Algorithm);
}
else /*Algorithm CTR */
{
/* Set the Key*/
CRYP_SetKey(hcryp, hcryp->Init.KeySize);
}
if (hcryp->Init.Algorithm != CRYP_AES_ECB)
{
/* Set the Initialization Vector*/
hcryp->Instance->IV0LR = *(uint32_t *)(hcryp->Init.pInitVect);
hcryp->Instance->IV0RR = *(uint32_t *)(hcryp->Init.pInitVect + 1);
hcryp->Instance->IV1LR = *(uint32_t *)(hcryp->Init.pInitVect + 2);
hcryp->Instance->IV1RR = *(uint32_t *)(hcryp->Init.pInitVect + 3);
}
/* Set the phase */
hcryp->Phase = CRYP_PHASE_PROCESS;
if (hcryp->Size != 0U)
{
/* Set the input and output addresses and start DMA transfer */
CRYP_SetDMAConfig(hcryp, (uint32_t)(hcryp->pCrypInBuffPtr), (hcryp->Size / 4U), (uint32_t)(hcryp->pCrypOutBuffPtr));
}
else
{
/* Process unlocked */
__HAL_UNLOCK(hcryp);
/* Change the CRYP state */
hcryp->State = HAL_CRYP_STATE_READY;
}
/* Return function status */
return HAL_OK;
}
/**
* @brief DMA CRYP input data process complete callback.
* @param hdma: DMA handle
* @retval None
*/
static void CRYP_DMAInCplt(DMA_HandleTypeDef *hdma)
{
CRYP_HandleTypeDef *hcryp = (CRYP_HandleTypeDef *)((DMA_HandleTypeDef *)hdma)->Parent;
/* Disable the DMA transfer for input FIFO request by resetting the DIEN bit
in the DMACR register */
hcryp->Instance->DMACR &= (uint32_t)(~CRYP_DMACR_DIEN);
/* Call input data transfer complete callback */
#if (USE_HAL_CRYP_REGISTER_CALLBACKS == 1)
/*Call registered Input complete callback*/
hcryp->InCpltCallback(hcryp);
#else
/*Call legacy weak Input complete callback*/
HAL_CRYP_InCpltCallback(hcryp);
#endif /* USE_HAL_CRYP_REGISTER_CALLBACKS */
}
/**
* @brief DMA CRYP output data process complete callback.
* @param hdma: DMA handle
* @retval None
*/
static void CRYP_DMAOutCplt(DMA_HandleTypeDef *hdma)
{
uint32_t count;
uint32_t npblb;
uint32_t lastwordsize;
uint32_t temp; /* Temporary CrypOutBuff */
CRYP_HandleTypeDef *hcryp = (CRYP_HandleTypeDef *)((DMA_HandleTypeDef *)hdma)->Parent;
/* Disable the DMA transfer for output FIFO */
hcryp->Instance->DMACR &= (uint32_t)(~CRYP_DMACR_DOEN);
/* Last block transfer in case of GCM or CCM with Size not %16*/
if (((hcryp->Size) % 16U) != 0U)
{
/* set CrypInCount and CrypOutCount to exact number of word already computed via DMA */
hcryp->CrypInCount = (hcryp->Size / 16U) * 4U ;
hcryp->CrypOutCount = hcryp->CrypInCount;
/* Compute the number of padding bytes in last block of payload */
npblb = ((((uint32_t)(hcryp->Size) / 16U) + 1U) * 16U) - (uint32_t)(hcryp->Size);
/* Number of valid words (lastwordsize) in last block */
if ((npblb % 4U) == 0U)
{
lastwordsize = (16U - npblb) / 4U;
}
else
{
lastwordsize = ((16U - npblb) / 4U) + 1U;
}
/* Write the last input block in the IN FIFO */
for (count = 0U; count < lastwordsize; count ++)
{
hcryp->Instance->DIN = *(uint32_t *)(hcryp->pCrypInBuffPtr + hcryp->CrypInCount);
hcryp->CrypInCount++;
}
/* Pad the data with zeros to have a complete block */
while (count < 4U)
{
hcryp->Instance->DIN = 0U;
count++;
}
/* Wait for OFNE flag to be raised */
count = CRYP_TIMEOUT_GCMCCMHEADERPHASE;
do
{
count-- ;
if (count == 0U)
{
/* Disable the CRYP peripheral clock */
__HAL_CRYP_DISABLE(hcryp);
/* Change state */
hcryp->ErrorCode |= HAL_CRYP_ERROR_TIMEOUT;
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
#if (USE_HAL_CRYP_REGISTER_CALLBACKS == 1)
/*Call registered error callback*/
hcryp->ErrorCallback(hcryp);
#else
/*Call legacy weak error callback*/
HAL_CRYP_ErrorCallback(hcryp);
#endif /* USE_HAL_CRYP_REGISTER_CALLBACKS */
}
} while (HAL_IS_BIT_CLR(hcryp->Instance->SR, CRYP_FLAG_OFNE));
/*Read the output block from the output FIFO */
for (count = 0U; count < 4U; count++)
{
/* Read the output block from the output FIFO and put them in temporary buffer then get CrypOutBuff from temporary buffer */
temp = hcryp->Instance->DOUT;
*(uint32_t *)(hcryp->pCrypOutBuffPtr + (hcryp->CrypOutCount)) = temp;
hcryp->CrypOutCount++;
}
} /*End of last block transfer in case of GCM or CCM */
if ((hcryp->Init.Algorithm & CRYP_AES_GCM) != CRYP_AES_GCM)
{
/* Disable CRYP (not allowed in GCM)*/
__HAL_CRYP_DISABLE(hcryp);
}
/* Change the CRYP state to ready */
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
/* Call output data transfer complete callback */
#if (USE_HAL_CRYP_REGISTER_CALLBACKS == 1)
/*Call registered Output complete callback*/
hcryp->OutCpltCallback(hcryp);
#else
/*Call legacy weak Output complete callback*/
HAL_CRYP_OutCpltCallback(hcryp);
#endif /* USE_HAL_CRYP_REGISTER_CALLBACKS */
}
/**
* @brief DMA CRYP communication error callback.
* @param hdma: DMA handle
* @retval None
*/
static void CRYP_DMAError(DMA_HandleTypeDef *hdma)
{
CRYP_HandleTypeDef *hcryp = (CRYP_HandleTypeDef *)((DMA_HandleTypeDef *)hdma)->Parent;
/* Change the CRYP peripheral state */
hcryp->State = HAL_CRYP_STATE_READY;
/* DMA error code field */
hcryp->ErrorCode |= HAL_CRYP_ERROR_DMA;
/* Call error callback */
#if (USE_HAL_CRYP_REGISTER_CALLBACKS == 1)
/*Call registered error callback*/
hcryp->ErrorCallback(hcryp);
#else
/*Call legacy weak error callback*/
HAL_CRYP_ErrorCallback(hcryp);
#endif /* USE_HAL_CRYP_REGISTER_CALLBACKS */
}
/**
* @brief Set the DMA configuration and start the DMA transfer
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module
* @param inputaddr: address of the input buffer
* @param Size: size of the input buffer, must be a multiple of 16.
* @param outputaddr: address of the output buffer
* @retval None
*/
static void CRYP_SetDMAConfig(CRYP_HandleTypeDef *hcryp, uint32_t inputaddr, uint16_t Size, uint32_t outputaddr)
{
/* Set the CRYP DMA transfer complete callback */
hcryp->hdmain->XferCpltCallback = CRYP_DMAInCplt;
/* Set the DMA input error callback */
hcryp->hdmain->XferErrorCallback = CRYP_DMAError;
/* Set the CRYP DMA transfer complete callback */
hcryp->hdmaout->XferCpltCallback = CRYP_DMAOutCplt;
/* Set the DMA output error callback */
hcryp->hdmaout->XferErrorCallback = CRYP_DMAError;
/* Enable CRYP */
__HAL_CRYP_ENABLE(hcryp);
/* Enable the input DMA Stream */
if (HAL_DMA_Start_IT(hcryp->hdmain, inputaddr, (uint32_t)&hcryp->Instance->DIN, Size) != HAL_OK)
{
/* DMA error code field */
hcryp->ErrorCode |= HAL_CRYP_ERROR_DMA;
/* Call error callback */
#if (USE_HAL_CRYP_REGISTER_CALLBACKS == 1)
/*Call registered error callback*/
hcryp->ErrorCallback(hcryp);
#else
/*Call legacy weak error callback*/
HAL_CRYP_ErrorCallback(hcryp);
#endif /* USE_HAL_CRYP_REGISTER_CALLBACKS */
}
/* Enable the output DMA Stream */
if (HAL_DMA_Start_IT(hcryp->hdmaout, (uint32_t)&hcryp->Instance->DOUT, outputaddr, Size) != HAL_OK)
{
/* DMA error code field */
hcryp->ErrorCode |= HAL_CRYP_ERROR_DMA;
/* Call error callback */
#if (USE_HAL_CRYP_REGISTER_CALLBACKS == 1)
/*Call registered error callback*/
hcryp->ErrorCallback(hcryp);
#else
/*Call legacy weak error callback*/
HAL_CRYP_ErrorCallback(hcryp);
#endif /* USE_HAL_CRYP_REGISTER_CALLBACKS */
}
/* Enable In/Out DMA request */
hcryp->Instance->DMACR = CRYP_DMACR_DOEN | CRYP_DMACR_DIEN;
}
/**
* @brief Process Data: Write Input data in polling mode and used in AES functions.
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module
* @param Timeout: Specify Timeout value
* @retval None
*/
static void CRYP_AES_ProcessData(CRYP_HandleTypeDef *hcryp, uint32_t Timeout)
{
uint32_t temp; /* Temporary CrypOutBuff */
uint16_t incount; /* Temporary CrypInCount Value */
uint16_t outcount; /* Temporary CrypOutCount Value */
/*Temporary CrypOutCount Value*/
incount = hcryp->CrypInCount;
if (((hcryp->Instance->SR & CRYP_FLAG_IFNF) != 0x0U) && (incount < ((hcryp->Size) / 4U)))
{
/* Write the input block in the IN FIFO */
hcryp->Instance->DIN = *(uint32_t *)(hcryp->pCrypInBuffPtr + hcryp->CrypInCount);
hcryp->CrypInCount++;
hcryp->Instance->DIN = *(uint32_t *)(hcryp->pCrypInBuffPtr + hcryp->CrypInCount);
hcryp->CrypInCount++;
hcryp->Instance->DIN = *(uint32_t *)(hcryp->pCrypInBuffPtr + hcryp->CrypInCount);
hcryp->CrypInCount++;
hcryp->Instance->DIN = *(uint32_t *)(hcryp->pCrypInBuffPtr + hcryp->CrypInCount);
hcryp->CrypInCount++;
}
/* Wait for OFNE flag to be raised */
if (CRYP_WaitOnOFNEFlag(hcryp, Timeout) != HAL_OK)
{
/* Disable the CRYP peripheral clock */
__HAL_CRYP_DISABLE(hcryp);
/* Change state & error code*/
hcryp->ErrorCode |= HAL_CRYP_ERROR_TIMEOUT;
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
#if (USE_HAL_CRYP_REGISTER_CALLBACKS == 1)
/*Call registered error callback*/
hcryp->ErrorCallback(hcryp);
#else
/*Call legacy weak error callback*/
HAL_CRYP_ErrorCallback(hcryp);
#endif /* USE_HAL_CRYP_REGISTER_CALLBACKS */
}
/*Temporary CrypOutCount Value*/
outcount = hcryp->CrypOutCount;
if (((hcryp->Instance->SR & CRYP_FLAG_OFNE) != 0x0U) && (outcount < ((hcryp->Size) / 4U)))
{
/* Read the output block from the Output FIFO and put them in temporary buffer then get CrypOutBuff from temporary buffer */
temp = hcryp->Instance->DOUT;
*(uint32_t *)(hcryp->pCrypOutBuffPtr + hcryp->CrypOutCount) = temp;
hcryp->CrypOutCount++;
temp = hcryp->Instance->DOUT;
*(uint32_t *)(hcryp->pCrypOutBuffPtr + hcryp->CrypOutCount) = temp;
hcryp->CrypOutCount++;
temp = hcryp->Instance->DOUT;
*(uint32_t *)(hcryp->pCrypOutBuffPtr + hcryp->CrypOutCount) = temp;
hcryp->CrypOutCount++;
temp = hcryp->Instance->DOUT;
*(uint32_t *)(hcryp->pCrypOutBuffPtr + hcryp->CrypOutCount) = temp;
hcryp->CrypOutCount++;
}
}
/**
* @brief Handle CRYP block input/output data handling under interruption.
* @note The function is called under interruption only, once
* interruptions have been enabled by HAL_CRYP_Encrypt_IT or HAL_CRYP_Decrypt_IT.
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module.
* @retval HAL status
*/
static void CRYP_AES_IT(CRYP_HandleTypeDef *hcryp)
{
uint32_t temp; /* Temporary CrypOutBuff */
uint16_t incount; /* Temporary CrypInCount Value */
uint16_t outcount; /* Temporary CrypOutCount Value */
if (hcryp->State == HAL_CRYP_STATE_BUSY)
{
/*Temporary CrypOutCount Value*/
incount = hcryp->CrypInCount;
if (((hcryp->Instance->SR & CRYP_FLAG_IFNF) != 0x0U) && (incount < (hcryp->Size / 4U)))
{
/* Write the input block in the IN FIFO */
hcryp->Instance->DIN = *(uint32_t *)(hcryp->pCrypInBuffPtr + hcryp->CrypInCount);
hcryp->CrypInCount++;
hcryp->Instance->DIN = *(uint32_t *)(hcryp->pCrypInBuffPtr + hcryp->CrypInCount);
hcryp->CrypInCount++;
hcryp->Instance->DIN = *(uint32_t *)(hcryp->pCrypInBuffPtr + hcryp->CrypInCount);
hcryp->CrypInCount++;
hcryp->Instance->DIN = *(uint32_t *)(hcryp->pCrypInBuffPtr + hcryp->CrypInCount);
hcryp->CrypInCount++;
if (hcryp->CrypInCount == (hcryp->Size / 4U))
{
/* Disable interrupts */
__HAL_CRYP_DISABLE_IT(hcryp, CRYP_IT_INI);
/* Call the input data transfer complete callback */
#if (USE_HAL_CRYP_REGISTER_CALLBACKS == 1)
/*Call registered Input complete callback*/
hcryp->InCpltCallback(hcryp);
#else
/*Call legacy weak Input complete callback*/
HAL_CRYP_InCpltCallback(hcryp);
#endif /* USE_HAL_CRYP_REGISTER_CALLBACKS */
}
}
/*Temporary CrypOutCount Value*/
outcount = hcryp->CrypOutCount;
if (((hcryp->Instance->SR & CRYP_FLAG_OFNE) != 0x0U) && (outcount < (hcryp->Size / 4U)))
{
/* Read the output block from the output FIFO and put them in temporary buffer then get CrypOutBuff from temporary buffer */
temp = hcryp->Instance->DOUT;
*(uint32_t *)(hcryp->pCrypOutBuffPtr + hcryp->CrypOutCount) = temp;
hcryp->CrypOutCount++;
temp = hcryp->Instance->DOUT;
*(uint32_t *)(hcryp->pCrypOutBuffPtr + hcryp->CrypOutCount) = temp;
hcryp->CrypOutCount++;
temp = hcryp->Instance->DOUT;
*(uint32_t *)(hcryp->pCrypOutBuffPtr + hcryp->CrypOutCount) = temp;
hcryp->CrypOutCount++;
temp = hcryp->Instance->DOUT;
*(uint32_t *)(hcryp->pCrypOutBuffPtr + hcryp->CrypOutCount) = temp;
hcryp->CrypOutCount++;
if (hcryp->CrypOutCount == (hcryp->Size / 4U))
{
/* Disable interrupts */
__HAL_CRYP_DISABLE_IT(hcryp, CRYP_IT_OUTI);
/* Change the CRYP state */
hcryp->State = HAL_CRYP_STATE_READY;
/* Disable CRYP */
__HAL_CRYP_DISABLE(hcryp);
/* Process unlocked */
__HAL_UNLOCK(hcryp);
/* Call output transfer complete callback */
#if (USE_HAL_CRYP_REGISTER_CALLBACKS == 1)
/*Call registered Output complete callback*/
hcryp->OutCpltCallback(hcryp);
#else
/*Call legacy weak Output complete callback*/
HAL_CRYP_OutCpltCallback(hcryp);
#endif /* USE_HAL_CRYP_REGISTER_CALLBACKS */
}
}
}
else
{
/* Process unlocked */
__HAL_UNLOCK(hcryp);
/* Busy error code field */
hcryp->ErrorCode |= HAL_CRYP_ERROR_BUSY;
#if (USE_HAL_CRYP_REGISTER_CALLBACKS == 1)
/*Call registered error callback*/
hcryp->ErrorCallback(hcryp);
#else
/*Call legacy weak error callback*/
HAL_CRYP_ErrorCallback(hcryp);
#endif /* USE_HAL_CRYP_REGISTER_CALLBACKS */
}
}
/**
* @brief Writes Key in Key registers.
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module
* @param KeySize: Size of Key
* @retval None
*/
static void CRYP_SetKey(CRYP_HandleTypeDef *hcryp, uint32_t KeySize)
{
switch (KeySize)
{
case CRYP_KEYSIZE_256B:
hcryp->Instance->K0LR = *(uint32_t *)(hcryp->Init.pKey);
hcryp->Instance->K0RR = *(uint32_t *)(hcryp->Init.pKey + 1);
hcryp->Instance->K1LR = *(uint32_t *)(hcryp->Init.pKey + 2);
hcryp->Instance->K1RR = *(uint32_t *)(hcryp->Init.pKey + 3);
hcryp->Instance->K2LR = *(uint32_t *)(hcryp->Init.pKey + 4);
hcryp->Instance->K2RR = *(uint32_t *)(hcryp->Init.pKey + 5);
hcryp->Instance->K3LR = *(uint32_t *)(hcryp->Init.pKey + 6);
hcryp->Instance->K3RR = *(uint32_t *)(hcryp->Init.pKey + 7);
break;
case CRYP_KEYSIZE_192B:
hcryp->Instance->K1LR = *(uint32_t *)(hcryp->Init.pKey);
hcryp->Instance->K1RR = *(uint32_t *)(hcryp->Init.pKey + 1);
hcryp->Instance->K2LR = *(uint32_t *)(hcryp->Init.pKey + 2);
hcryp->Instance->K2RR = *(uint32_t *)(hcryp->Init.pKey + 3);
hcryp->Instance->K3LR = *(uint32_t *)(hcryp->Init.pKey + 4);
hcryp->Instance->K3RR = *(uint32_t *)(hcryp->Init.pKey + 5);
break;
case CRYP_KEYSIZE_128B:
hcryp->Instance->K2LR = *(uint32_t *)(hcryp->Init.pKey);
hcryp->Instance->K2RR = *(uint32_t *)(hcryp->Init.pKey + 1);
hcryp->Instance->K3LR = *(uint32_t *)(hcryp->Init.pKey + 2);
hcryp->Instance->K3RR = *(uint32_t *)(hcryp->Init.pKey + 3);
break;
default:
break;
}
}
/**
* @brief Encryption/Decryption process in AES GCM mode and prepare the authentication TAG
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module
* @param Timeout: Timeout duration
* @retval HAL status
*/
static HAL_StatusTypeDef CRYP_AESGCM_Process(CRYP_HandleTypeDef *hcryp, uint32_t Timeout)
{
uint32_t tickstart;
uint32_t wordsize = (uint32_t)(hcryp->Size) / 4U;
uint16_t outcount; /* Temporary CrypOutCount Value */
/* Reset CrypHeaderCount */
hcryp->CrypHeaderCount = 0U;
/****************************** Init phase **********************************/
CRYP_SET_PHASE(hcryp, CRYP_PHASE_INIT);
/* Set the key */
CRYP_SetKey(hcryp, hcryp->Init.KeySize);
/* Set the initialization vector and the counter : Initial Counter Block (ICB)*/
hcryp->Instance->IV0LR = *(uint32_t *)(hcryp->Init.pInitVect);
hcryp->Instance->IV0RR = *(uint32_t *)(hcryp->Init.pInitVect + 1);
hcryp->Instance->IV1LR = *(uint32_t *)(hcryp->Init.pInitVect + 2);
hcryp->Instance->IV1RR = *(uint32_t *)(hcryp->Init.pInitVect + 3);
/* Enable the CRYP peripheral */
__HAL_CRYP_ENABLE(hcryp);
/* Get tick */
tickstart = HAL_GetTick();
/*Wait for the CRYPEN bit to be cleared*/
while ((hcryp->Instance->CR & CRYP_CR_CRYPEN) == CRYP_CR_CRYPEN)
{
/* Check for the Timeout */
if (Timeout != HAL_MAX_DELAY)
{
if (((HAL_GetTick() - tickstart) > Timeout) || (Timeout == 0U))
{
/* Disable the CRYP peripheral clock */
__HAL_CRYP_DISABLE(hcryp);
/* Change state */
hcryp->ErrorCode |= HAL_CRYP_ERROR_TIMEOUT;
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
return HAL_ERROR;
}
}
}
/************************ Header phase *************************************/
if (CRYP_GCMCCM_SetHeaderPhase(hcryp, Timeout) != HAL_OK)
{
return HAL_ERROR;
}
/*************************Payload phase ************************************/
/* Set the phase */
hcryp->Phase = CRYP_PHASE_PROCESS;
/* Disable the CRYP peripheral */
__HAL_CRYP_DISABLE(hcryp);
/* Select payload phase once the header phase is performed */
CRYP_SET_PHASE(hcryp, CRYP_PHASE_PAYLOAD);
/* Enable the CRYP peripheral */
__HAL_CRYP_ENABLE(hcryp);
if ((hcryp->Size % 16U) != 0U)
{
/* recalculate wordsize */
wordsize = ((wordsize / 4U) * 4U) ;
}
/* Get tick */
tickstart = HAL_GetTick();
/*Temporary CrypOutCount Value*/
outcount = hcryp->CrypOutCount;
/* Write input data and get output Data */
while ((hcryp->CrypInCount < wordsize) && (outcount < wordsize))
{
/* Write plain data and get cipher data */
CRYP_AES_ProcessData(hcryp, Timeout);
/*Temporary CrypOutCount Value*/
outcount = hcryp->CrypOutCount;
/* Check for the Timeout */
if (Timeout != HAL_MAX_DELAY)
{
if (((HAL_GetTick() - tickstart) > Timeout) || (Timeout == 0U))
{
/* Disable the CRYP peripheral clock */
__HAL_CRYP_DISABLE(hcryp);
/* Change state & error code */
hcryp->ErrorCode |= HAL_CRYP_ERROR_TIMEOUT;
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
return HAL_ERROR;
}
}
}
if ((hcryp->Size % 16U) != 0U)
{
CRYP_Workaround(hcryp, Timeout);
}
/* Return function status */
return HAL_OK;
}
/**
* @brief Encryption/Decryption process in AES GCM mode and prepare the authentication TAG in interrupt mode
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module
* @retval HAL status
*/
static HAL_StatusTypeDef CRYP_AESGCM_Process_IT(CRYP_HandleTypeDef *hcryp)
{
__IO uint32_t count = 0U;
/* Reset CrypHeaderCount */
hcryp->CrypHeaderCount = 0U;
/******************************* Init phase *********************************/
CRYP_SET_PHASE(hcryp, CRYP_PHASE_INIT);
/* Set the key */
CRYP_SetKey(hcryp, hcryp->Init.KeySize);
/* Set the initialization vector and the counter : Initial Counter Block (ICB)*/
hcryp->Instance->IV0LR = *(uint32_t *)(hcryp->Init.pInitVect);
hcryp->Instance->IV0RR = *(uint32_t *)(hcryp->Init.pInitVect + 1);
hcryp->Instance->IV1LR = *(uint32_t *)(hcryp->Init.pInitVect + 2);
hcryp->Instance->IV1RR = *(uint32_t *)(hcryp->Init.pInitVect + 3);
/* Enable the CRYP peripheral */
__HAL_CRYP_ENABLE(hcryp);
/*Wait for the CRYPEN bit to be cleared*/
count = CRYP_TIMEOUT_GCMCCMINITPHASE;
do
{
count-- ;
if (count == 0U)
{
/* Disable the CRYP peripheral clock */
__HAL_CRYP_DISABLE(hcryp);
/* Change state */
hcryp->ErrorCode |= HAL_CRYP_ERROR_TIMEOUT;
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
return HAL_ERROR;
}
} while ((hcryp->Instance->CR & CRYP_CR_CRYPEN) == CRYP_CR_CRYPEN);
/***************************** Header phase *********************************/
/* Select header phase */
CRYP_SET_PHASE(hcryp, CRYP_PHASE_HEADER);
/* Enable interrupts */
__HAL_CRYP_ENABLE_IT(hcryp, CRYP_IT_INI);
/* Enable CRYP */
__HAL_CRYP_ENABLE(hcryp);
/* Return function status */
return HAL_OK;
}
/**
* @brief Encryption/Decryption process in AES GCM mode and prepare the authentication TAG using DMA
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module
* @retval HAL status
*/
static HAL_StatusTypeDef CRYP_AESGCM_Process_DMA(CRYP_HandleTypeDef *hcryp)
{
__IO uint32_t count = 0U;
uint32_t wordsize = (uint32_t)(hcryp->Size) / 4U ;
uint32_t index;
uint32_t npblb;
uint32_t lastwordsize;
uint32_t temp; /* Temporary CrypOutBuff */
/* Reset CrypHeaderCount */
hcryp->CrypHeaderCount = 0U;
/*************************** Init phase ************************************/
CRYP_SET_PHASE(hcryp, CRYP_PHASE_INIT);
/* Set the key */
CRYP_SetKey(hcryp, hcryp->Init.KeySize);
/* Set the initialization vector and the counter : Initial Counter Block (ICB)*/
hcryp->Instance->IV0LR = *(uint32_t *)(hcryp->Init.pInitVect);
hcryp->Instance->IV0RR = *(uint32_t *)(hcryp->Init.pInitVect + 1);
hcryp->Instance->IV1LR = *(uint32_t *)(hcryp->Init.pInitVect + 2);
hcryp->Instance->IV1RR = *(uint32_t *)(hcryp->Init.pInitVect + 3);
/* Enable the CRYP peripheral */
__HAL_CRYP_ENABLE(hcryp);
/*Wait for the CRYPEN bit to be cleared*/
count = CRYP_TIMEOUT_GCMCCMINITPHASE;
do
{
count-- ;
if (count == 0U)
{
/* Disable the CRYP peripheral clock */
__HAL_CRYP_DISABLE(hcryp);
/* Change state */
hcryp->ErrorCode |= HAL_CRYP_ERROR_TIMEOUT;
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
return HAL_ERROR;
}
} while ((hcryp->Instance->CR & CRYP_CR_CRYPEN) == CRYP_CR_CRYPEN);
/************************ Header phase *************************************/
if (CRYP_GCMCCM_SetHeaderPhase_DMA(hcryp) != HAL_OK)
{
return HAL_ERROR;
}
/************************ Payload phase ************************************/
/* Set the phase */
hcryp->Phase = CRYP_PHASE_PROCESS;
/* Disable the CRYP peripheral */
__HAL_CRYP_DISABLE(hcryp);
/* Select payload phase once the header phase is performed */
CRYP_SET_PHASE(hcryp, CRYP_PHASE_PAYLOAD);
if (hcryp->Size == 0U)
{
/* Process unLocked */
__HAL_UNLOCK(hcryp);
/* Change the CRYP state and phase */
hcryp->State = HAL_CRYP_STATE_READY;
}
else if (hcryp->Size >= 16U)
{
/* for STM32H7 : Size should be %4 otherwise Tag will be incorrectly generated for GCM Encryption:
Workaround is implemented in polling mode, so if last block of payload <128bit don't use DMA mode otherwise TAG is incorrectly generated */
/*DMA transfer must not include the last block in case of Size is not %16 */
wordsize = wordsize - (wordsize % 4U);
/*DMA transfer */
CRYP_SetDMAConfig(hcryp, (uint32_t)(hcryp->pCrypInBuffPtr), (uint16_t)wordsize, (uint32_t)(hcryp->pCrypOutBuffPtr));
}
else /* length of input data is < 16 */
{
/* Compute the number of padding bytes in last block of payload */
npblb = 16U - (uint32_t)hcryp->Size;
/* Enable CRYP to start the final phase */
__HAL_CRYP_ENABLE(hcryp);
/* Number of valid words (lastwordsize) in last block */
if ((npblb % 4U) == 0U)
{
lastwordsize = (16U - npblb) / 4U;
}
else
{
lastwordsize = ((16U - npblb) / 4U) + 1U;
}
/* Write the last input block in the IN FIFO */
for (index = 0; index < lastwordsize; index ++)
{
hcryp->Instance->DIN = *(uint32_t *)(hcryp->pCrypInBuffPtr + hcryp->CrypInCount);
hcryp->CrypInCount++;
}
/* Pad the data with zeros to have a complete block */
while (index < 4U)
{
hcryp->Instance->DIN = 0U;
index++;
}
/* Wait for OFNE flag to be raised */
count = CRYP_TIMEOUT_GCMCCMHEADERPHASE;
do
{
count-- ;
if (count == 0U)
{
/* Disable the CRYP peripheral clock */
__HAL_CRYP_DISABLE(hcryp);
/* Change state */
hcryp->ErrorCode |= HAL_CRYP_ERROR_TIMEOUT;
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
#if (USE_HAL_CRYP_REGISTER_CALLBACKS == 1)
/*Call registered error callback*/
hcryp->ErrorCallback(hcryp);
#else
/*Call legacy weak error callback*/
HAL_CRYP_ErrorCallback(hcryp);
#endif /* USE_HAL_CRYP_REGISTER_CALLBACKS */
}
} while (HAL_IS_BIT_CLR(hcryp->Instance->SR, CRYP_FLAG_OFNE));
/*Read the output block from the output FIFO */
for (index = 0U; index < 4U; index++)
{
/* Read the output block from the output FIFO and put them in temporary buffer then get CrypOutBuff from temporary buffer */
temp = hcryp->Instance->DOUT;
*(uint32_t *)(hcryp->pCrypOutBuffPtr + (hcryp->CrypOutCount)) = temp;
hcryp->CrypOutCount++;
}
/* Change the CRYP state to ready */
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
}
/* Return function status */
return HAL_OK;
}
/**
* @brief AES CCM encryption/decryption processing in polling mode
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module
* @param Timeout: Timeout duration
* @retval HAL status
*/
static HAL_StatusTypeDef CRYP_AESCCM_Process(CRYP_HandleTypeDef *hcryp, uint32_t Timeout)
{
uint32_t tickstart;
uint32_t wordsize = (uint32_t)(hcryp->Size) / 4U;
uint16_t outcount; /* Temporary CrypOutCount Value */
/* Reset CrypHeaderCount */
hcryp->CrypHeaderCount = 0U;
/********************** Init phase ******************************************/
CRYP_SET_PHASE(hcryp, CRYP_PHASE_INIT);
/* Set the key */
CRYP_SetKey(hcryp, hcryp->Init.KeySize);
/* Set the initialization vector (IV) with CTR1 information */
hcryp->Instance->IV0LR = (hcryp->Init.B0[0]) & CRYP_CCM_CTR1_0;
hcryp->Instance->IV0RR = hcryp->Init.B0[1];
hcryp->Instance->IV1LR = hcryp->Init.B0[2];
hcryp->Instance->IV1RR = (hcryp->Init.B0[3] & CRYP_CCM_CTR1_1) | CRYP_CCM_CTR1_2;
/* Enable the CRYP peripheral */
__HAL_CRYP_ENABLE(hcryp);
if (hcryp->Init.DataType == CRYP_DATATYPE_8B)
{
hcryp->Instance->DIN = __REV(*(uint32_t *)(hcryp->Init.B0));
hcryp->Instance->DIN = __REV(*(uint32_t *)(hcryp->Init.B0 + 1));
hcryp->Instance->DIN = __REV(*(uint32_t *)(hcryp->Init.B0 + 2));
hcryp->Instance->DIN = __REV(*(uint32_t *)(hcryp->Init.B0 + 3));
}
else if (hcryp->Init.DataType == CRYP_DATATYPE_16B)
{
hcryp->Instance->DIN = __ROR(*(uint32_t *)(hcryp->Init.B0), 16);
hcryp->Instance->DIN = __ROR(*(uint32_t *)(hcryp->Init.B0 + 1), 16);
hcryp->Instance->DIN = __ROR(*(uint32_t *)(hcryp->Init.B0 + 2), 16);
hcryp->Instance->DIN = __ROR(*(uint32_t *)(hcryp->Init.B0 + 3), 16);
}
else if (hcryp->Init.DataType == CRYP_DATATYPE_1B)
{
hcryp->Instance->DIN = __RBIT(*(uint32_t *)(hcryp->Init.B0));
hcryp->Instance->DIN = __RBIT(*(uint32_t *)(hcryp->Init.B0 + 1));
hcryp->Instance->DIN = __RBIT(*(uint32_t *)(hcryp->Init.B0 + 2));
hcryp->Instance->DIN = __RBIT(*(uint32_t *)(hcryp->Init.B0 + 3));
}
else
{
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.B0);
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.B0 + 1);
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.B0 + 2);
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.B0 + 3);
}
/* Get tick */
tickstart = HAL_GetTick();
/*Wait for the CRYPEN bit to be cleared*/
while ((hcryp->Instance->CR & CRYP_CR_CRYPEN) == CRYP_CR_CRYPEN)
{
/* Check for the Timeout */
if (Timeout != HAL_MAX_DELAY)
{
if (((HAL_GetTick() - tickstart) > Timeout) || (Timeout == 0U))
{
/* Disable the CRYP peripheral clock */
__HAL_CRYP_DISABLE(hcryp);
/* Change state */
hcryp->ErrorCode |= HAL_CRYP_ERROR_TIMEOUT;
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
return HAL_ERROR;
}
}
}
/************************* Header phase *************************************/
/* Header block(B1) : associated data length expressed in bytes concatenated
with Associated Data (A)*/
if (CRYP_GCMCCM_SetHeaderPhase(hcryp, Timeout) != HAL_OK)
{
return HAL_ERROR;
}
/********************** Payload phase ***************************************/
/* Set the phase */
hcryp->Phase = CRYP_PHASE_PROCESS;
/* Disable the CRYP peripheral */
__HAL_CRYP_DISABLE(hcryp);
/* Select payload phase once the header phase is performed */
CRYP_SET_PHASE(hcryp, CRYP_PHASE_PAYLOAD);
/* Enable the CRYP peripheral */
__HAL_CRYP_ENABLE(hcryp);
if ((hcryp->Size % 16U) != 0U)
{
/* recalculate wordsize */
wordsize = ((wordsize / 4U) * 4U) ;
}
/* Get tick */
tickstart = HAL_GetTick();
/*Temporary CrypOutCount Value*/
outcount = hcryp->CrypOutCount;
/* Write input data and get output data */
while ((hcryp->CrypInCount < wordsize) && (outcount < wordsize))
{
/* Write plain data and get cipher data */
CRYP_AES_ProcessData(hcryp, Timeout);
/*Temporary CrypOutCount Value*/
outcount = hcryp->CrypOutCount;
/* Check for the Timeout */
if (Timeout != HAL_MAX_DELAY)
{
if (((HAL_GetTick() - tickstart) > Timeout) || (Timeout == 0U))
{
/* Disable the CRYP peripheral clock */
__HAL_CRYP_DISABLE(hcryp);
/* Change state */
hcryp->ErrorCode |= HAL_CRYP_ERROR_TIMEOUT;
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
return HAL_ERROR;
}
}
}
if ((hcryp->Size % 16U) != 0U)
{
CRYP_Workaround(hcryp, Timeout);
}
/* Return function status */
return HAL_OK;
}
/**
* @brief AES CCM encryption/decryption process in interrupt mode
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module
* @retval HAL status
*/
static HAL_StatusTypeDef CRYP_AESCCM_Process_IT(CRYP_HandleTypeDef *hcryp)
{
__IO uint32_t count = 0U;
/* Reset CrypHeaderCount */
hcryp->CrypHeaderCount = 0U;
/************ Init phase ************/
CRYP_SET_PHASE(hcryp, CRYP_PHASE_INIT);
/* Set the key */
CRYP_SetKey(hcryp, hcryp->Init.KeySize);
/* Set the initialization vector (IV) with CTR1 information */
hcryp->Instance->IV0LR = (hcryp->Init.B0[0]) & CRYP_CCM_CTR1_0;
hcryp->Instance->IV0RR = hcryp->Init.B0[1];
hcryp->Instance->IV1LR = hcryp->Init.B0[2];
hcryp->Instance->IV1RR = (hcryp->Init.B0[3] & CRYP_CCM_CTR1_1) | CRYP_CCM_CTR1_2;
/* Enable the CRYP peripheral */
__HAL_CRYP_ENABLE(hcryp);
/*Write the B0 packet into CRYP_DR*/
if (hcryp->Init.DataType == CRYP_DATATYPE_8B)
{
hcryp->Instance->DIN = __REV(*(uint32_t *)(hcryp->Init.B0));
hcryp->Instance->DIN = __REV(*(uint32_t *)(hcryp->Init.B0 + 1));
hcryp->Instance->DIN = __REV(*(uint32_t *)(hcryp->Init.B0 + 2));
hcryp->Instance->DIN = __REV(*(uint32_t *)(hcryp->Init.B0 + 3));
}
else if (hcryp->Init.DataType == CRYP_DATATYPE_16B)
{
hcryp->Instance->DIN = __ROR(*(uint32_t *)(hcryp->Init.B0), 16);
hcryp->Instance->DIN = __ROR(*(uint32_t *)(hcryp->Init.B0 + 1), 16);
hcryp->Instance->DIN = __ROR(*(uint32_t *)(hcryp->Init.B0 + 2), 16);
hcryp->Instance->DIN = __ROR(*(uint32_t *)(hcryp->Init.B0 + 3), 16);
}
else if (hcryp->Init.DataType == CRYP_DATATYPE_1B)
{
hcryp->Instance->DIN = __RBIT(*(uint32_t *)(hcryp->Init.B0));
hcryp->Instance->DIN = __RBIT(*(uint32_t *)(hcryp->Init.B0 + 1));
hcryp->Instance->DIN = __RBIT(*(uint32_t *)(hcryp->Init.B0 + 2));
hcryp->Instance->DIN = __RBIT(*(uint32_t *)(hcryp->Init.B0 + 3));
}
else
{
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.B0);
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.B0 + 1);
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.B0 + 2);
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.B0 + 3);
}
/*Wait for the CRYPEN bit to be cleared*/
count = CRYP_TIMEOUT_GCMCCMINITPHASE;
do
{
count-- ;
if (count == 0U)
{
/* Disable the CRYP peripheral clock */
__HAL_CRYP_DISABLE(hcryp);
/* Change state */
hcryp->ErrorCode |= HAL_CRYP_ERROR_TIMEOUT;
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
return HAL_ERROR;
}
} while ((hcryp->Instance->CR & CRYP_CR_CRYPEN) == CRYP_CR_CRYPEN);
/* Select header phase */
CRYP_SET_PHASE(hcryp, CRYP_PHASE_HEADER);
/* Enable interrupts */
__HAL_CRYP_ENABLE_IT(hcryp, CRYP_IT_INI);
/* Enable CRYP */
__HAL_CRYP_ENABLE(hcryp);
/* Return function status */
return HAL_OK;
}
/**
* @brief AES CCM encryption/decryption process in DMA mode
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module
* @retval HAL status
*/
static HAL_StatusTypeDef CRYP_AESCCM_Process_DMA(CRYP_HandleTypeDef *hcryp)
{
__IO uint32_t count = 0U;
uint32_t wordsize = (uint32_t)(hcryp->Size) / 4U ;
uint32_t index;
uint32_t npblb;
uint32_t lastwordsize;
uint32_t temp; /* Temporary CrypOutBuff */
/* Reset CrypHeaderCount */
hcryp->CrypHeaderCount = 0U;
/************************** Init phase **************************************/
CRYP_SET_PHASE(hcryp, CRYP_PHASE_INIT);
/* Set the key */
CRYP_SetKey(hcryp, hcryp->Init.KeySize);
/* Set the initialization vector (IV) with CTR1 information */
hcryp->Instance->IV0LR = (hcryp->Init.B0[0]) & CRYP_CCM_CTR1_0;
hcryp->Instance->IV0RR = hcryp->Init.B0[1];
hcryp->Instance->IV1LR = hcryp->Init.B0[2];
hcryp->Instance->IV1RR = (hcryp->Init.B0[3] & CRYP_CCM_CTR1_1) | CRYP_CCM_CTR1_2;
/* Enable the CRYP peripheral */
__HAL_CRYP_ENABLE(hcryp);
/*Write the B0 packet into CRYP_DR*/
if (hcryp->Init.DataType == CRYP_DATATYPE_8B)
{
hcryp->Instance->DIN = __REV(*(uint32_t *)(hcryp->Init.B0));
hcryp->Instance->DIN = __REV(*(uint32_t *)(hcryp->Init.B0 + 1));
hcryp->Instance->DIN = __REV(*(uint32_t *)(hcryp->Init.B0 + 2));
hcryp->Instance->DIN = __REV(*(uint32_t *)(hcryp->Init.B0 + 3));
}
else if (hcryp->Init.DataType == CRYP_DATATYPE_16B)
{
hcryp->Instance->DIN = __ROR(*(uint32_t *)(hcryp->Init.B0), 16);
hcryp->Instance->DIN = __ROR(*(uint32_t *)(hcryp->Init.B0 + 1), 16);
hcryp->Instance->DIN = __ROR(*(uint32_t *)(hcryp->Init.B0 + 2), 16);
hcryp->Instance->DIN = __ROR(*(uint32_t *)(hcryp->Init.B0 + 3), 16);
}
else if (hcryp->Init.DataType == CRYP_DATATYPE_1B)
{
hcryp->Instance->DIN = __RBIT(*(uint32_t *)(hcryp->Init.B0));
hcryp->Instance->DIN = __RBIT(*(uint32_t *)(hcryp->Init.B0 + 1));
hcryp->Instance->DIN = __RBIT(*(uint32_t *)(hcryp->Init.B0 + 2));
hcryp->Instance->DIN = __RBIT(*(uint32_t *)(hcryp->Init.B0 + 3));
}
else
{
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.B0);
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.B0 + 1);
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.B0 + 2);
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.B0 + 3);
}
/*Wait for the CRYPEN bit to be cleared*/
count = CRYP_TIMEOUT_GCMCCMINITPHASE;
do
{
count-- ;
if (count == 0U)
{
/* Disable the CRYP peripheral clock */
__HAL_CRYP_DISABLE(hcryp);
/* Change state */
hcryp->ErrorCode |= HAL_CRYP_ERROR_TIMEOUT;
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
return HAL_ERROR;
}
} while ((hcryp->Instance->CR & CRYP_CR_CRYPEN) == CRYP_CR_CRYPEN);
/********************* Header phase *****************************************/
if (CRYP_GCMCCM_SetHeaderPhase_DMA(hcryp) != HAL_OK)
{
return HAL_ERROR;
}
/******************** Payload phase *****************************************/
/* Set the phase */
hcryp->Phase = CRYP_PHASE_PROCESS;
/* Disable the CRYP peripheral */
__HAL_CRYP_DISABLE(hcryp);
/* Select payload phase once the header phase is performed */
CRYP_SET_PHASE(hcryp, CRYP_PHASE_PAYLOAD);
if (hcryp->Size == 0U)
{
/* Process unLocked */
__HAL_UNLOCK(hcryp);
/* Change the CRYP state and phase */
hcryp->State = HAL_CRYP_STATE_READY;
}
else if (hcryp->Size >= 16U)
{
/* for STM32H7 : Size should be %4 otherwise Tag will be incorrectly generated for CCM Decryption, Workaround is implemented in polling mode*/
/*DMA transfer must not include the last block in case of Size is not %16 */
wordsize = wordsize - (wordsize % 4U);
/*DMA transfer */
CRYP_SetDMAConfig(hcryp, (uint32_t)(hcryp->pCrypInBuffPtr), (uint16_t) wordsize, (uint32_t)(hcryp->pCrypOutBuffPtr));
}
else /* length of input data is < 16U */
{
/* Compute the number of padding bytes in last block of payload */
npblb = 16U - (uint32_t)(hcryp->Size);
/* Enable CRYP to start the final phase */
__HAL_CRYP_ENABLE(hcryp);
/* Number of valid words (lastwordsize) in last block */
if ((npblb % 4U) == 0U)
{
lastwordsize = (16U - npblb) / 4U;
}
else
{
lastwordsize = ((16U - npblb) / 4U) + 1U;
}
/* Write the last input block in the IN FIFO */
for (index = 0U; index < lastwordsize; index ++)
{
hcryp->Instance->DIN = *(uint32_t *)(hcryp->pCrypInBuffPtr + hcryp->CrypInCount);
hcryp->CrypInCount++;
}
/* Pad the data with zeros to have a complete block */
while (index < 4U)
{
hcryp->Instance->DIN = 0U;
index++;
}
/* Wait for OFNE flag to be raised */
count = CRYP_TIMEOUT_GCMCCMHEADERPHASE;
do
{
count-- ;
if (count == 0U)
{
/* Disable the CRYP peripheral clock */
__HAL_CRYP_DISABLE(hcryp);
/* Change state */
hcryp->ErrorCode |= HAL_CRYP_ERROR_TIMEOUT;
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
#if (USE_HAL_CRYP_REGISTER_CALLBACKS == 1)
/*Call registered error callback*/
hcryp->ErrorCallback(hcryp);
#else
/*Call legacy weak error callback*/
HAL_CRYP_ErrorCallback(hcryp);
#endif /* USE_HAL_CRYP_REGISTER_CALLBACKS */
}
} while (HAL_IS_BIT_CLR(hcryp->Instance->SR, CRYP_FLAG_OFNE));
/*Read the output block from the output FIFO */
for (index = 0U; index < 4U; index++)
{
/* Read the output block from the output FIFO and put them in temporary buffer then get CrypOutBuff from temporary buffer */
temp = hcryp->Instance->DOUT;
*(uint32_t *)(hcryp->pCrypOutBuffPtr + (hcryp->CrypOutCount)) = temp;
hcryp->CrypOutCount++;
}
/* Change the CRYP state to ready */
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
}
/* Return function status */
return HAL_OK;
}
/**
* @brief Sets the payload phase in iterrupt mode
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module
* @retval state
*/
static void CRYP_GCMCCM_SetPayloadPhase_IT(CRYP_HandleTypeDef *hcryp)
{
uint32_t loopcounter;
uint32_t temp; /* Temporary CrypOutBuff */
uint32_t lastwordsize;
uint32_t npblb;
/***************************** Payload phase *******************************/
if (hcryp->Size == 0U)
{
/* Disable interrupts */
__HAL_CRYP_DISABLE_IT(hcryp, CRYP_IT_INI | CRYP_IT_OUTI);
/* Process unlocked */
__HAL_UNLOCK(hcryp);
/* Change the CRYP state */
hcryp->State = HAL_CRYP_STATE_READY;
}
else if (((hcryp->Size / 4U) - (hcryp->CrypInCount)) >= 4U)
{
if ((hcryp->Instance->IMSCR & CRYP_IMSCR_INIM)!= 0x0U)
{
/* Write the input block in the IN FIFO */
hcryp->Instance->DIN = *(uint32_t *)(hcryp->pCrypInBuffPtr + hcryp->CrypInCount);
hcryp->CrypInCount++;
hcryp->Instance->DIN = *(uint32_t *)(hcryp->pCrypInBuffPtr + hcryp->CrypInCount);
hcryp->CrypInCount++;
hcryp->Instance->DIN = *(uint32_t *)(hcryp->pCrypInBuffPtr + hcryp->CrypInCount);
hcryp->CrypInCount++;
hcryp->Instance->DIN = *(uint32_t *)(hcryp->pCrypInBuffPtr + hcryp->CrypInCount);
hcryp->CrypInCount++;
if (((hcryp->Size / 4U) == hcryp->CrypInCount) && ((hcryp->Size % 16U) == 0U))
{
/* Disable interrupts */
__HAL_CRYP_DISABLE_IT(hcryp, CRYP_IT_INI);
/* Call the input data transfer complete callback */
#if (USE_HAL_CRYP_REGISTER_CALLBACKS == 1U)
/*Call registered Input complete callback*/
hcryp->InCpltCallback(hcryp);
#else
/*Call legacy weak Input complete callback*/
HAL_CRYP_InCpltCallback(hcryp);
#endif /* USE_HAL_CRYP_REGISTER_CALLBACKS */
}
if (hcryp->CrypOutCount < (hcryp->Size / 4U))
{
if ((hcryp->Instance->SR & CRYP_FLAG_OFNE) != 0x0U)
{
/* Read the output block from the Output FIFO and put them in temporary buffer then get CrypOutBuff from temporary buffer */
temp = hcryp->Instance->DOUT;
*(uint32_t *)(hcryp->pCrypOutBuffPtr + hcryp->CrypOutCount) = temp;
hcryp->CrypOutCount++;
temp = hcryp->Instance->DOUT;
*(uint32_t *)(hcryp->pCrypOutBuffPtr + hcryp->CrypOutCount) = temp;
hcryp->CrypOutCount++;
temp = hcryp->Instance->DOUT;
*(uint32_t *)(hcryp->pCrypOutBuffPtr + hcryp->CrypOutCount) = temp;
hcryp->CrypOutCount++;
temp = hcryp->Instance->DOUT;
*(uint32_t *)(hcryp->pCrypOutBuffPtr + hcryp->CrypOutCount) = temp;
hcryp->CrypOutCount++;
if (((hcryp->Size / 4U) == hcryp->CrypOutCount) && ((hcryp->Size % 16U) == 0U))
{
/* Disable interrupts */
__HAL_CRYP_DISABLE_IT(hcryp, CRYP_IT_OUTI);
/* Change the CRYP state */
hcryp->State = HAL_CRYP_STATE_READY;
/* Disable CRYP */
__HAL_CRYP_DISABLE(hcryp);
/* Process unlocked */
__HAL_UNLOCK(hcryp);
/* Call output transfer complete callback */
#if (USE_HAL_CRYP_REGISTER_CALLBACKS == 1U)
/*Call registered Output complete callback*/
hcryp->OutCpltCallback(hcryp);
#else
/*Call legacy weak Output complete callback*/
HAL_CRYP_OutCpltCallback(hcryp);
#endif /* USE_HAL_CRYP_REGISTER_CALLBACKS */
}
}
}
}
}
else if ((hcryp->Size % 16U) != 0U)
{
/* Set padding only in case of input fifo interrupt */
if ((hcryp->Instance->IMSCR & CRYP_IMSCR_INIM)!= 0x0U)
{
/* Compute the number of padding bytes in last block of payload */
npblb = ((((uint32_t)hcryp->Size / 16U) + 1U) * 16U) - (uint32_t)(hcryp->Size);
/* Number of valid words (lastwordsize) in last block */
if ((npblb % 4U) == 0U)
{
lastwordsize = (16U - npblb) / 4U;
}
else
{
lastwordsize = ((16U - npblb) / 4U) + 1U;
}
/* Write the last input block in the IN FIFO */
for (loopcounter = 0U; loopcounter < lastwordsize; loopcounter++)
{
hcryp->Instance->DIN = *(uint32_t *)(hcryp->pCrypInBuffPtr + hcryp->CrypInCount);
hcryp->CrypInCount++;
}
/* Pad the data with zeros to have a complete block */
while (loopcounter < 4U)
{
hcryp->Instance->DIN = 0U;
loopcounter++;
}
/* Disable the input FIFO Interrupt */
__HAL_CRYP_DISABLE_IT(hcryp, CRYP_IT_INI);
}
/*Read the output block from the output FIFO */
if ((hcryp->Instance->SR & CRYP_FLAG_OFNE) != 0x0U)
{
for (loopcounter = 0U; loopcounter < 4U; loopcounter++)
{
/* Read the output block from the output FIFO and put them in temporary buffer then get CrypOutBuff from temporary buffer */
temp = hcryp->Instance->DOUT;
*(uint32_t *)(hcryp->pCrypOutBuffPtr + (hcryp->CrypOutCount)) = temp;
hcryp->CrypOutCount++;
}
}
/* Disable the output FIFO Interrupt */
if (hcryp->CrypOutCount > ((hcryp->Size) / 4U))
{
/* Disable interrupts */
__HAL_CRYP_DISABLE_IT(hcryp, CRYP_IT_OUTI | CRYP_IT_INI);
/* Change the CRYP peripheral state */
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
/* Call output transfer complete callback */
#if (USE_HAL_CRYP_REGISTER_CALLBACKS == 1U)
/*Call registered Output complete callback*/
hcryp->OutCpltCallback(hcryp);
#else
/*Call legacy weak Output complete callback*/
HAL_CRYP_OutCpltCallback(hcryp);
#endif /* USE_HAL_CRYP_REGISTER_CALLBACKS */
}
}
else
{
/* Nothing to do */
}
}
/**
* @brief Sets the header phase in polling mode
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module(Header & HeaderSize)
* @param Timeout: Timeout value
* @retval state
*/
static HAL_StatusTypeDef CRYP_GCMCCM_SetHeaderPhase(CRYP_HandleTypeDef *hcryp, uint32_t Timeout)
{
uint32_t loopcounter;
/***************************** Header phase for GCM/GMAC or CCM *********************************/
if ((hcryp->Init.HeaderSize != 0U))
{
/* Select header phase */
CRYP_SET_PHASE(hcryp, CRYP_PHASE_HEADER);
/* Enable the CRYP peripheral */
__HAL_CRYP_ENABLE(hcryp);
if ((hcryp->Init.HeaderSize % 4U) == 0U)
{
/* HeaderSize %4, no padding */
for (loopcounter = 0U; (loopcounter < hcryp->Init.HeaderSize); loopcounter += 4U)
{
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.Header + hcryp->CrypHeaderCount);
hcryp->CrypHeaderCount++ ;
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.Header + hcryp->CrypHeaderCount);
hcryp->CrypHeaderCount++ ;
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.Header + hcryp->CrypHeaderCount);
hcryp->CrypHeaderCount++ ;
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.Header + hcryp->CrypHeaderCount);
hcryp->CrypHeaderCount++ ;
/* Wait for IFEM to be raised */
if (CRYP_WaitOnIFEMFlag(hcryp, Timeout) != HAL_OK)
{
/* Disable the CRYP peripheral clock */
__HAL_CRYP_DISABLE(hcryp);
/* Change state */
hcryp->ErrorCode |= HAL_CRYP_ERROR_TIMEOUT;
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
return HAL_ERROR;
}
}
}
else
{
/*Write header block in the IN FIFO without last block */
for (loopcounter = 0U; (loopcounter < ((hcryp->Init.HeaderSize) - (hcryp->Init.HeaderSize % 4U))); loopcounter += 4U)
{
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.Header + hcryp->CrypHeaderCount);
hcryp->CrypHeaderCount++ ;
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.Header + hcryp->CrypHeaderCount);
hcryp->CrypHeaderCount++ ;
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.Header + hcryp->CrypHeaderCount);
hcryp->CrypHeaderCount++ ;
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.Header + hcryp->CrypHeaderCount);
hcryp->CrypHeaderCount++ ;
/* Wait for IFEM to be raised */
if (CRYP_WaitOnIFEMFlag(hcryp, Timeout) != HAL_OK)
{
/* Disable the CRYP peripheral clock */
__HAL_CRYP_DISABLE(hcryp);
/* Change state */
hcryp->ErrorCode |= HAL_CRYP_ERROR_TIMEOUT;
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
return HAL_ERROR;
}
}
/* Last block optionally pad the data with zeros*/
for (loopcounter = 0U; (loopcounter < (hcryp->Init.HeaderSize % 4U)); loopcounter++)
{
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.Header + hcryp->CrypHeaderCount);
hcryp->CrypHeaderCount++ ;
}
while (loopcounter < 4U)
{
/* pad the data with zeros to have a complete block */
hcryp->Instance->DIN = 0x0U;
loopcounter++;
}
/* Wait for CCF IFEM to be raised */
if (CRYP_WaitOnIFEMFlag(hcryp, Timeout) != HAL_OK)
{
/* Disable the CRYP peripheral clock */
__HAL_CRYP_DISABLE(hcryp);
/* Change state */
hcryp->ErrorCode |= HAL_CRYP_ERROR_TIMEOUT;
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
return HAL_ERROR;
}
}
/* Wait until the complete message has been processed */
if (CRYP_WaitOnBUSYFlag(hcryp, Timeout) != HAL_OK)
{
/* Disable the CRYP peripheral clock */
__HAL_CRYP_DISABLE(hcryp);
/* Change state */
hcryp->ErrorCode |= HAL_CRYP_ERROR_TIMEOUT;
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked & return error */
__HAL_UNLOCK(hcryp);
return HAL_ERROR;
}
}
/* Return function status */
return HAL_OK;
}
/**
* @brief Sets the header phase when using DMA in process
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module(Header & HeaderSize)
* @retval None
*/
static HAL_StatusTypeDef CRYP_GCMCCM_SetHeaderPhase_DMA(CRYP_HandleTypeDef *hcryp)
{
__IO uint32_t count = 0U;
uint32_t loopcounter;
/***************************** Header phase for GCM/GMAC or CCM *********************************/
if ((hcryp->Init.HeaderSize != 0U))
{
/* Select header phase */
CRYP_SET_PHASE(hcryp, CRYP_PHASE_HEADER);
/* Enable the CRYP peripheral */
__HAL_CRYP_ENABLE(hcryp);
if ((hcryp->Init.HeaderSize % 4U) == 0U)
{
/* HeaderSize %4, no padding */
for (loopcounter = 0U; (loopcounter < hcryp->Init.HeaderSize); loopcounter += 4U)
{
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.Header + hcryp->CrypHeaderCount);
hcryp->CrypHeaderCount++ ;
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.Header + hcryp->CrypHeaderCount);
hcryp->CrypHeaderCount++ ;
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.Header + hcryp->CrypHeaderCount);
hcryp->CrypHeaderCount++ ;
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.Header + hcryp->CrypHeaderCount);
hcryp->CrypHeaderCount++ ;
/* Wait for IFEM to be raised */
count = CRYP_TIMEOUT_GCMCCMHEADERPHASE;
do
{
count-- ;
if (count == 0U)
{
/* Disable the CRYP peripheral clock */
__HAL_CRYP_DISABLE(hcryp);
/* Change state */
hcryp->ErrorCode |= HAL_CRYP_ERROR_TIMEOUT;
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
return HAL_ERROR;
}
} while (HAL_IS_BIT_CLR(hcryp->Instance->SR, CRYP_FLAG_IFEM));
}
}
else
{
/*Write header block in the IN FIFO without last block */
for (loopcounter = 0U; (loopcounter < ((hcryp->Init.HeaderSize) - (hcryp->Init.HeaderSize % 4U))); loopcounter += 4U)
{
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.Header + hcryp->CrypHeaderCount);
hcryp->CrypHeaderCount++ ;
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.Header + hcryp->CrypHeaderCount);
hcryp->CrypHeaderCount++ ;
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.Header + hcryp->CrypHeaderCount);
hcryp->CrypHeaderCount++ ;
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.Header + hcryp->CrypHeaderCount);
hcryp->CrypHeaderCount++ ;
/* Wait for IFEM to be raised */
count = CRYP_TIMEOUT_GCMCCMHEADERPHASE;
do
{
count-- ;
if (count == 0U)
{
/* Disable the CRYP peripheral clock */
__HAL_CRYP_DISABLE(hcryp);
/* Change state */
hcryp->ErrorCode |= HAL_CRYP_ERROR_TIMEOUT;
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
return HAL_ERROR;
}
} while (HAL_IS_BIT_CLR(hcryp->Instance->SR, CRYP_FLAG_IFEM));
}
/* Last block optionally pad the data with zeros*/
for (loopcounter = 0U; (loopcounter < (hcryp->Init.HeaderSize % 4U)); loopcounter++)
{
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.Header + hcryp->CrypHeaderCount);
hcryp->CrypHeaderCount++ ;
}
while (loopcounter < 4U)
{
/* Pad the data with zeros to have a complete block */
hcryp->Instance->DIN = 0x0U;
loopcounter++;
}
/* Wait for IFEM to be raised */
count = CRYP_TIMEOUT_GCMCCMHEADERPHASE;
do
{
count-- ;
if (count == 0U)
{
/* Disable the CRYP peripheral clock */
__HAL_CRYP_DISABLE(hcryp);
/* Change state */
hcryp->ErrorCode |= HAL_CRYP_ERROR_TIMEOUT;
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
return HAL_ERROR;
}
} while (HAL_IS_BIT_CLR(hcryp->Instance->SR, CRYP_FLAG_IFEM));
}
/* Wait until the complete message has been processed */
count = CRYP_TIMEOUT_GCMCCMHEADERPHASE;
do
{
count-- ;
if (count == 0U)
{
/* Disable the CRYP peripheral clock */
__HAL_CRYP_DISABLE(hcryp);
/* Change state */
hcryp->ErrorCode |= HAL_CRYP_ERROR_TIMEOUT;
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
return HAL_ERROR;
}
} while (HAL_IS_BIT_SET(hcryp->Instance->SR, CRYP_FLAG_BUSY));
}
/* Return function status */
return HAL_OK;
}
/**
* @brief Sets the header phase in interrupt mode
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module(Header & HeaderSize)
* @retval None
*/
static void CRYP_GCMCCM_SetHeaderPhase_IT(CRYP_HandleTypeDef *hcryp)
{
uint32_t loopcounter;
/***************************** Header phase *********************************/
if (hcryp->Init.HeaderSize == hcryp->CrypHeaderCount)
{
/* Disable interrupts */
__HAL_CRYP_DISABLE_IT(hcryp, CRYP_IT_INI);
/* Disable the CRYP peripheral */
__HAL_CRYP_DISABLE(hcryp);
/* Set the phase */
hcryp->Phase = CRYP_PHASE_PROCESS;
/* Select payload phase once the header phase is performed */
CRYP_SET_PHASE(hcryp, CRYP_PHASE_PAYLOAD);
/* Enable Interrupts */
__HAL_CRYP_ENABLE_IT(hcryp, CRYP_IT_INI | CRYP_IT_OUTI);
/* Enable the CRYP peripheral */
__HAL_CRYP_ENABLE(hcryp);
}
else if (((hcryp->Init.HeaderSize) - (hcryp->CrypHeaderCount)) >= 4U)
{
/* HeaderSize %4, no padding */
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.Header + hcryp->CrypHeaderCount);
hcryp->CrypHeaderCount++ ;
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.Header + hcryp->CrypHeaderCount);
hcryp->CrypHeaderCount++ ;
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.Header + hcryp->CrypHeaderCount);
hcryp->CrypHeaderCount++ ;
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.Header + hcryp->CrypHeaderCount);
hcryp->CrypHeaderCount++ ;
}
else
{
/* Last block optionally pad the data with zeros*/
for (loopcounter = 0U; loopcounter < (hcryp->Init.HeaderSize % 4U); loopcounter++)
{
hcryp->Instance->DIN = *(uint32_t *)(hcryp->Init.Header + hcryp->CrypHeaderCount);
hcryp->CrypHeaderCount++ ;
}
while (loopcounter < 4U)
{
/* Pad the data with zeros to have a complete block */
hcryp->Instance->DIN = 0x0U;
loopcounter++;
}
}
}
/**
* @brief Workaround used for GCM/CCM mode.
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module
* @param Timeout: Timeout value
* @retval None
*/
static void CRYP_Workaround(CRYP_HandleTypeDef *hcryp, uint32_t Timeout)
{
uint32_t iv1temp;
uint32_t temp[4] = {0};
uint32_t temp2[4] = {0};
uint32_t intermediate_data[4] = {0};
uint32_t index;
uint32_t lastwordsize;
uint32_t npblb;
/* Compute the number of padding bytes in last block of payload */
npblb = ((((uint32_t)(hcryp->Size) / 16U) + 1U) * 16U) - (uint32_t)(hcryp->Size);
/* Number of valid words (lastwordsize) in last block */
if ((npblb % 4U) == 0U)
{
lastwordsize = (16U - npblb) / 4U;
}
else
{
lastwordsize = ((16U - npblb) / 4U) + 1U;
}
/* Workaround 2, case GCM encryption */
if (hcryp->Init.Algorithm == CRYP_AES_GCM)
{
if ((hcryp->Instance->CR & CRYP_CR_ALGODIR) == CRYP_OPERATINGMODE_ENCRYPT)
{
/*Workaround in order to properly compute authentication tags while doing
a GCM encryption with the last block of payload size inferior to 128 bits*/
/* Disable CRYP to start the final phase */
__HAL_CRYP_DISABLE(hcryp);
/*Load CRYP_IV1R register content in a temporary variable. Decrement the value
by 1 and reinsert the result in CRYP_IV1R register*/
hcryp->Instance->IV1RR = 0x5U;
MODIFY_REG(hcryp->Instance->CR, CRYP_CR_ALGOMODE, CRYP_AES_CTR);
/* Enable CRYP to start the final phase */
__HAL_CRYP_ENABLE(hcryp);
}
for (index = 0; index < lastwordsize ; index ++)
{
/* Write the last input block in the IN FIFO */
hcryp->Instance->DIN = *(uint32_t *)(hcryp->pCrypInBuffPtr + hcryp->CrypInCount);
hcryp->CrypInCount++;
}
while (index < 4U)
{
/* Pad the data with zeros to have a complete block */
hcryp->Instance->DIN = 0U;
index++;
}
/* Wait for OFNE flag to be raised */
if (CRYP_WaitOnOFNEFlag(hcryp, Timeout) != HAL_OK)
{
/* Disable the CRYP peripheral clock */
__HAL_CRYP_DISABLE(hcryp);
/* Change state */
hcryp->ErrorCode |= HAL_CRYP_ERROR_TIMEOUT;
hcryp->State = HAL_CRYP_STATE_READY;
/* Process Unlocked */
__HAL_UNLOCK(hcryp);
#if (USE_HAL_CRYP_REGISTER_CALLBACKS == 1)
/*Call registered error callback*/
hcryp->ErrorCallback(hcryp);
#else
/*Call legacy weak error callback*/
HAL_CRYP_ErrorCallback(hcryp);
#endif /* USE_HAL_CRYP_REGISTER_CALLBACKS */
}
if ((hcryp->Instance->SR & CRYP_FLAG_OFNE) != 0x0U)
{
for (index = 0U; index < 4U; index++)
{
/* Read the output block from the output FIFO */
intermediate_data[index] = hcryp->Instance->DOUT;
/* Intermediate data buffer to be used in for the workaround*/
*(uint32_t *)(hcryp->pCrypOutBuffPtr + (hcryp->CrypOutCount)) = intermediate_data[index];
hcryp->CrypOutCount++;
}
}
if ((hcryp->Instance->CR & CRYP_CR_ALGODIR) == CRYP_OPERATINGMODE_ENCRYPT)
{
/*workaround in order to properly compute authentication tags while doing
a GCM encryption with the last block of payload size inferior to 128 bits*/
/* Change the AES mode to GCM mode and Select Final phase */
/* configured CHMOD GCM */
MODIFY_REG(hcryp->Instance->CR, CRYP_CR_ALGOMODE, CRYP_AES_GCM);
/* configured final phase */
MODIFY_REG(hcryp->Instance->CR, CRYP_CR_GCM_CCMPH, CRYP_PHASE_FINAL);
for (index = 0U; index < lastwordsize ; index ++)
{
/*Write the intermediate_data in the IN FIFO */
hcryp->Instance->DIN = intermediate_data[index];
}
while (index < 4U)
{
/* Pad the data with zeros to have a complete block */
hcryp->Instance->DIN = 0x0U;
index++;
}
/* Wait for OFNE flag to be raised */
if (CRYP_WaitOnOFNEFlag(hcryp, Timeout) != HAL_OK)
{
/* Disable the CRYP peripheral clock */
__HAL_CRYP_DISABLE(hcryp);
/* Change state */
hcryp->ErrorCode |= HAL_CRYP_ERROR_TIMEOUT;
hcryp->State = HAL_CRYP_STATE_READY;
/* Process unlocked */
__HAL_UNLOCK(hcryp);
#if (USE_HAL_CRYP_REGISTER_CALLBACKS == 1U)
/*Call registered error callback*/
hcryp->ErrorCallback(hcryp);
#else
/*Call legacy weak error callback*/
HAL_CRYP_ErrorCallback(hcryp);
#endif /* USE_HAL_CRYP_REGISTER_CALLBACKS */
}
if ((hcryp->Instance->SR & CRYP_FLAG_OFNE) != 0x0U)
{
for (index = 0U; index < 4U; index++)
{
intermediate_data[index] = hcryp->Instance->DOUT;
}
}
}
} /* End of GCM encryption */
else
{
/* Workaround 2, case CCM decryption, in order to properly compute
authentication tags while doing a CCM decryption with the last block
of payload size inferior to 128 bits*/
if ((hcryp->Instance->CR & CRYP_CR_ALGODIR) == CRYP_OPERATINGMODE_DECRYPT)
{
iv1temp = hcryp->Instance->CSGCMCCM7R;
/* Disable CRYP to start the final phase */
__HAL_CRYP_DISABLE(hcryp);
temp[0] = hcryp->Instance->CSGCMCCM0R;
temp[1] = hcryp->Instance->CSGCMCCM1R;
temp[2] = hcryp->Instance->CSGCMCCM2R;
temp[3] = hcryp->Instance->CSGCMCCM3R;
hcryp->Instance->IV1RR = iv1temp;
/* Configured CHMOD CTR */
MODIFY_REG(hcryp->Instance->CR, CRYP_CR_ALGOMODE, CRYP_AES_CTR);
/* Enable CRYP to start the final phase */
__HAL_CRYP_ENABLE(hcryp);
}
/* Last block optionally pad the data with zeros*/
for (index = 0; index < lastwordsize; index ++)
{
/* Write the last Input block in the IN FIFO */
hcryp->Instance->DIN = *(uint32_t *)(hcryp->pCrypInBuffPtr + hcryp->CrypInCount);
hcryp->CrypInCount++;
}
while (index < 4U)
{
/* Pad the data with zeros to have a complete block */
hcryp->Instance->DIN = 0U;
index++;
}
/* Wait for OFNE flag to be raised */
if (CRYP_WaitOnOFNEFlag(hcryp, Timeout) != HAL_OK)
{
/* Disable the CRYP peripheral clock */
__HAL_CRYP_DISABLE(hcryp);
/* Change state */
hcryp->ErrorCode |= HAL_CRYP_ERROR_TIMEOUT;
hcryp->State = HAL_CRYP_STATE_READY;
/* Process Unlocked */
__HAL_UNLOCK(hcryp);
#if (USE_HAL_CRYP_REGISTER_CALLBACKS == 1)
/*Call registered error callback*/
hcryp->ErrorCallback(hcryp);
#else
/*Call legacy weak error callback*/
HAL_CRYP_ErrorCallback(hcryp);
#endif /* USE_HAL_CRYP_REGISTER_CALLBACKS */
}
if ((hcryp->Instance->SR & CRYP_FLAG_OFNE) != 0x0U)
{
for (index = 0U; index < 4U; index++)
{
/* Read the Output block from the Output FIFO */
intermediate_data[index] = hcryp->Instance->DOUT;
/*intermediate data buffer to be used in for the workaround*/
*(uint32_t *)(hcryp->pCrypOutBuffPtr + (hcryp->CrypOutCount)) = intermediate_data[index];
hcryp->CrypOutCount++;
}
}
if ((hcryp->Instance->CR & CRYP_CR_ALGODIR) == CRYP_OPERATINGMODE_DECRYPT)
{
temp2[0] = hcryp->Instance->CSGCMCCM0R;
temp2[1] = hcryp->Instance->CSGCMCCM1R;
temp2[2] = hcryp->Instance->CSGCMCCM2R;
temp2[3] = hcryp->Instance->CSGCMCCM3R;
/* configured CHMOD CCM */
MODIFY_REG(hcryp->Instance->CR, CRYP_CR_ALGOMODE, CRYP_AES_CCM);
/* configured Header phase */
MODIFY_REG(hcryp->Instance->CR, CRYP_CR_GCM_CCMPH, CRYP_PHASE_HEADER);
/*set to zero the bits corresponding to the padded bits*/
for (index = lastwordsize; index < 4U; index ++)
{
intermediate_data[index] = 0U;
}
if ((npblb % 4U) == 1U)
{
intermediate_data[lastwordsize - 1U] &= 0xFFFFFF00U;
}
if ((npblb % 4U) == 2U)
{
intermediate_data[lastwordsize - 1U] &= 0xFFFF0000U;
}
if ((npblb % 4U) == 3U)
{
intermediate_data[lastwordsize - 1U] &= 0xFF000000U;
}
for (index = 0U; index < 4U ; index ++)
{
intermediate_data[index] ^= temp[index];
intermediate_data[index] ^= temp2[index];
}
for (index = 0U; index < 4U; index ++)
{
/* Write the last Input block in the IN FIFO */
hcryp->Instance->DIN = intermediate_data[index] ;
}
/* Wait for BUSY flag to be raised */
if (CRYP_WaitOnBUSYFlag(hcryp, Timeout) != HAL_OK)
{
/* Disable the CRYP peripheral clock */
__HAL_CRYP_DISABLE(hcryp);
/* Change state */
hcryp->ErrorCode |= HAL_CRYP_ERROR_TIMEOUT;
hcryp->State = HAL_CRYP_STATE_READY;
/* Process Unlocked */
__HAL_UNLOCK(hcryp);
#if (USE_HAL_CRYP_REGISTER_CALLBACKS == 1)
/*Call registered error callback*/
hcryp->ErrorCallback(hcryp);
#else
/*Call legacy weak error callback*/
HAL_CRYP_ErrorCallback(hcryp);
#endif /* USE_HAL_CRYP_REGISTER_CALLBACKS */
}
}
} /* End of CCM WKA*/
/* Process Unlocked */
__HAL_UNLOCK(hcryp);
}
/**
* @brief Handle CRYP hardware block Timeout when waiting for IFEM flag to be raised.
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module.
* @param Timeout: Timeout duration.
* @retval HAL status
*/
static HAL_StatusTypeDef CRYP_WaitOnIFEMFlag(const CRYP_HandleTypeDef *hcryp, uint32_t Timeout)
{
uint32_t tickstart;
/* Get timeout */
tickstart = HAL_GetTick();
while (HAL_IS_BIT_CLR(hcryp->Instance->SR, CRYP_FLAG_IFEM))
{
/* Check for the Timeout */
if (Timeout != HAL_MAX_DELAY)
{
if (((HAL_GetTick() - tickstart) > Timeout) || (Timeout == 0U))
{
return HAL_ERROR;
}
}
}
return HAL_OK;
}
/**
* @brief Handle CRYP hardware block Timeout when waiting for BUSY flag to be raised.
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module.
* @param Timeout: Timeout duration.
* @retval HAL status
*/
static HAL_StatusTypeDef CRYP_WaitOnBUSYFlag(const CRYP_HandleTypeDef *hcryp, uint32_t Timeout)
{
uint32_t tickstart;
/* Get timeout */
tickstart = HAL_GetTick();
while (HAL_IS_BIT_SET(hcryp->Instance->SR, CRYP_FLAG_BUSY))
{
/* Check for the Timeout */
if (Timeout != HAL_MAX_DELAY)
{
if (((HAL_GetTick() - tickstart) > Timeout) || (Timeout == 0U))
{
return HAL_ERROR;
}
}
}
return HAL_OK;
}
/**
* @brief Handle CRYP hardware block Timeout when waiting for OFNE flag to be raised.
* @param hcryp: pointer to a CRYP_HandleTypeDef structure that contains
* the configuration information for CRYP module.
* @param Timeout: Timeout duration.
* @retval HAL status
*/
static HAL_StatusTypeDef CRYP_WaitOnOFNEFlag(const CRYP_HandleTypeDef *hcryp, uint32_t Timeout)
{
uint32_t tickstart;
/* Get timeout */
tickstart = HAL_GetTick();
while (HAL_IS_BIT_CLR(hcryp->Instance->SR, CRYP_FLAG_OFNE))
{
/* Check for the Timeout */
if (Timeout != HAL_MAX_DELAY)
{
if (((HAL_GetTick() - tickstart) > Timeout) || (Timeout == 0U))
{
return HAL_ERROR;
}
}
}
return HAL_OK;
}
/**
* @}
*/
/**
* @}
*/
/**
* @}
*/
#endif /* HAL_CRYP_MODULE_ENABLED */
/**
* @}
*/
#endif /* CRYP */
/**
* @}
*/
/************************ (C) COPYRIGHT STMicroelectronics *****END OF FILE****/
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