tests/html/database_8c_source.html

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 /**

  * @file    database.c

  * @author  foxBMS Team

  * @date    2015-08-18 (date of creation)

  * @updated 2023-10-12 (date of last update)

  * @version v1.6.0

  * @ingroup ENGINE

  * @prefix  DATA

  *

  * @brief   Database module implementation

  *

  * @details The database read/write functions put references to the database

  *          entries to be read/written in the database queue. The function

  *          DATA_Task() reads the queue to get the database entries to be

  *          read/written. Up to DATA_MAX_ENTRIES_PER_ACCESS entries can be

  *          read/written with the same function call. To avoid code

  *          duplication, the functions to read/write 1 to

  *          DATA_MAX_ENTRIES_PER_ACCESS-1 entries call the function to

  *          read/write DATA_MAX_ENTRIES_PER_ACCESS entries and use NULL_PTR

  *          for the entries that are not to be read/written. DATA_Task()

  *          checks that the first entry is not a NULL_PTR and asserts if it

  *          is not the case. If subsequent entries are found in the database

  *          queue, they are simply ignored if they are NULL_PTR.

  */


 /*========== Includes =======================================================*/

 #include "general.h"


 #include "database.h"


 #include "ftask.h"

 #include "os.h"


 #include <stdint.h>

 #include <string.h>


 /*========== Macros and Definitions =========================================*/

 /** Maximum queue timeout time in milliseconds */

 #define DATA_MAX_QUEUE_TIMEOUT_MS (10u)


 #define DATA_QUEUE_TIMEOUT_MS (DATA_MAX_QUEUE_TIMEOUT_MS / OS_TICK_RATE_MS)


 FAS_STATIC_ASSERT(DATA_QUEUE_TIMEOUT_MS > 0u, "invalid database queue timeout!");


 /** configuration struct of database device */

 typedef struct {

     uint8_t nrDatabaseEntries; /*!< number of database entries */

     DATA_BASE_s *pDatabase;    /*!< pointer to the array with the database entries */

 } DATA_BASE_HEADER_s;


 /*========== Static Constant and Variable Definitions =======================*/


 /**

  * @brief   device configuration of database

  * @details all attributes of device configuration are listed here (pointer to

  *          channel list, number of channels)

  */

 static const DATA_BASE_HEADER_s data_baseHeader = {

     .nrDatabaseEntries = sizeof(data_database) / sizeof(DATA_BASE_s), /**< number of blocks (and block headers) */

     .pDatabase         = &data_database[0],

 };


 /**

  * @brief   uniqueId to respective database entry selector

  * @details This array is the link between the uniqueId of a database entry and

  *          the actual position of the database entry in data_database[].

  *          The IDs are set to its final value, when Data_Initialize is called.

  */

 static uint8_t data_uniqueIdToDatabaseEntry[DATA_BLOCK_ID_MAX] = {0};


 /*========== Extern Constant and Variable Definitions =======================*/


 /*========== Static Function Prototypes =====================================*/

 static void DATA_IterateOverDatabaseEntries(const DATA_QUEUE_MESSAGE_s *kpReceiveMessage);


 static STD_RETURN_TYPE_e DATA_AccessDatabaseEntries(

     DATA_BLOCK_ACCESS_TYPE_e accessType,

     void *pData0,

     void *pData1,

     void *pData2,

     void *pData3);


 static void DATA_CopyData(

     DATA_BLOCK_ACCESS_TYPE_e accessType,

     uint32_t dataLength,

     void *pDatabaseStruct,

     void *pPassedDataStruct);


 /*========== Static Function Implementations ================================*/

 static STD_RETURN_TYPE_e DATA_AccessDatabaseEntries(

     DATA_BLOCK_ACCESS_TYPE_e accessType,

     void *pData0,

     void *pData1,

     void *pData2,

     void *pData3) {

     FAS_ASSERT((accessType == DATA_WRITE_ACCESS) || (accessType == DATA_READ_ACCESS));

     FAS_ASSERT(pData0 != NULL_PTR);

     /* AXIVION Routine Generic-MissingParameterAssert: pData1: pointer might be NULL_PTR (i.e., if the caller

      * is DATA_Read1DataBlock/DATA_Write1DataBlock). The DATA_Task function checks the pointer being not NULL_PTR prior

      * to usage. */

     /* AXIVION Routine Generic-MissingParameterAssert: pData2: pointer might be NULL_PTR (i.e., if the caller

      * is DATA_Read1DataBlock/DATA_Write1DataBlock or DATA_Read2DataBlocks/DATA_Write2DataBlocks). The DATA_Task

      * function checks the pointer being not NULL_PTR prior to usage. */

     /* AXIVION Routine Generic-MissingParameterAssert: pData3: pointer might be NULL_PTR (i.e., if the caller

      * is DATA_Read1DataBlock/DATA_Write1DataBlock, DATA_Read2DataBlocks/DATA_Write2DataBlocks or

      * DATA_Read3DataBlocks/DATA_Write3DataBlocks). The DATA_Task function checks the pointer being not NULL_PTR prior

      * to usage. */

     STD_RETURN_TYPE_e retval = STD_NOT_OK;

     /* prepare send message with attributes of data block */

     DATA_QUEUE_MESSAGE_s data_sendMessage = {

         .pDatabaseEntry[DATA_ENTRY_0] = pData0,

         .pDatabaseEntry[DATA_ENTRY_1] = pData1,

         .pDatabaseEntry[DATA_ENTRY_2] = pData2,

         .pDatabaseEntry[DATA_ENTRY_3] = pData3,

         .accessType                   = accessType,

     };

     /* Send a pointer to a message object and maximum block time: DATA_QUEUE_TIMEOUT_MS */

     if (OS_SendToBackOfQueue(ftsk_databaseQueue, (void *)&data_sendMessage, DATA_QUEUE_TIMEOUT_MS) == OS_SUCCESS) {

         retval = STD_OK;

     }

     return retval;

 }


 static void DATA_CopyData(

     DATA_BLOCK_ACCESS_TYPE_e accessType,

     uint32_t dataLength,

     void *pDatabaseStruct,

     void *pPassedDataStruct) {

     FAS_ASSERT((accessType == DATA_WRITE_ACCESS) || (accessType == DATA_READ_ACCESS));

     /* AXIVION Routine Generic-MissingParameterAssert: dataLength: parameter accepts whole range */

     /* Copy data either into database or passed database struct */

     FAS_ASSERT(pDatabaseStruct != NULL_PTR);

     FAS_ASSERT(pPassedDataStruct != NULL_PTR);


     if (accessType == DATA_WRITE_ACCESS) {

         /* Pointer on data block header of passed struct */

         /* AXIVION Next Codeline Style MisraC2012-11.5 this casted is required in order to have a generic interface

          * for all database entries. */

         DATA_BLOCK_HEADER_s *pHeader = (DATA_BLOCK_HEADER_s *)pPassedDataStruct;

         /* Update timestamps in passed database struct and then copy this struct into database */

         pHeader->previousTimestamp = pHeader->timestamp;

         pHeader->timestamp         = OS_GetTickCount();

         /* Copy passed struct in database struct */

         /* memcpy has no return value therefore there is nothing to check: casting to void */

         /* AXIVION Next Codeline Style MisraC2012-21.18

          * */

         (void)memcpy(pDatabaseStruct, pPassedDataStruct, dataLength);

     } else if (accessType == DATA_READ_ACCESS) {

         /* Copy database entry in passed struct */

         /* memcpy has no return value therefore there is nothing to check: casting to void */

         (void)memcpy(pPassedDataStruct, pDatabaseStruct, dataLength);

     } else {

         /* invalid database operation */

         FAS_ASSERT(FAS_TRAP);

     }

 }


 static void DATA_IterateOverDatabaseEntries(const DATA_QUEUE_MESSAGE_s *kpReceiveMessage) {

     FAS_ASSERT(kpReceiveMessage != NULL_PTR);

     for (uint8_t queueEntry = 0u; queueEntry < DATA_MAX_ENTRIES_PER_ACCESS; queueEntry++) {

         /* Iterate over pointer array and handle all access operations if pointer != NULL_PTR

          * All pointers in the array, expect the first one, might be NULL_PTR, which is valid.

          * Again, to understand explanation see the comments in DATA_Read1DataBlock, DATA_Read2DataBlocks,

          * DATA_Read3DataBlocks and DATA_Read4DataBlocks as well as DATA_Write1DataBlock,

          * DATA_Write2DataBlocks, DATA_Write3DataBlocks and DATA_Write4DataBlocks */

         if (kpReceiveMessage->pDatabaseEntry[queueEntry] != NULL_PTR) {

             /* pointer to passed database struct */

             void *pPassedDataStruct = kpReceiveMessage->pDatabaseEntry[queueEntry];

             /* Get access type (read or write) of passed data struct */

             DATA_BLOCK_ACCESS_TYPE_e accessType = kpReceiveMessage->accessType;


             /* Get pointer to database header entry */

             const DATA_BLOCK_HEADER_s *kpHeader = (DATA_BLOCK_HEADER_s *)kpReceiveMessage->pDatabaseEntry[queueEntry];

             uint8_t uniqueId                    = (uint8_t)(kpHeader->uniqueId);

             FAS_ASSERT(uniqueId < (uint8_t)DATA_BLOCK_ID_MAX);

             uint8_t entryIndex = data_uniqueIdToDatabaseEntry[uniqueId];

             /* Pointer to database struct representation of passed struct */

             void *pDatabaseStruct = (void *)data_baseHeader.pDatabase[entryIndex].pDatabaseEntry;

             /* Get dataLength of database entry */

             uint32_t dataLength = data_baseHeader.pDatabase[entryIndex].dataLength;


             DATA_CopyData(accessType, dataLength, pDatabaseStruct, pPassedDataStruct);

         }

     }

 }


 /*========== Extern Function Implementations ================================*/

 STD_RETURN_TYPE_e DATA_Initialize(void) {

     STD_RETURN_TYPE_e retval = STD_OK;

     /* Check that database queue has been created */

     const bool allQueuesCreatedCopyForAssert = ftsk_allQueuesCreated;

     FAS_ASSERT(allQueuesCreatedCopyForAssert == true);


     FAS_STATIC_ASSERT((sizeof(data_database) != 0u), "No database defined");

     /*  make sure that no basic assumptions are broken -- since data_database is

         declared with length DATA_BLOCK_ID_MAX, this assert should never fail */

     FAS_STATIC_ASSERT(

         ((sizeof(data_database) / sizeof(DATA_BASE_s)) == (uint8_t)(DATA_BLOCK_ID_MAX)), "Database array length error");


     /* Iterate over database and set respective read/write pointer for each database entry */

     for (uint16_t i = 0u; i < data_baseHeader.nrDatabaseEntries; i++) {

         /* Initialize database entry with 0, set write pointer to start of database entry */

         uint8_t *pStartDatabaseEntryWR = (uint8_t *)data_baseHeader.pDatabase[i].pDatabaseEntry;


         /* Start after uniqueId entry. Set j'th byte to zero in database entry */

         for (uint32_t j = 0u; j < (data_baseHeader.pDatabase + i)->dataLength; j++) {

             if (j >= sizeof(DATA_BLOCK_ID_e)) {

                 *pStartDatabaseEntryWR = 0;

             }

             pStartDatabaseEntryWR++;

         }

     }


     /* Configure link between uniqueId and database entry array position */

     for (uint8_t databaseEntry = 0u; databaseEntry < data_baseHeader.nrDatabaseEntries; databaseEntry++) {

         /* Get pointer to database header entry */

         DATA_BLOCK_HEADER_s *pHeader = (DATA_BLOCK_HEADER_s *)data_baseHeader.pDatabase[databaseEntry].pDatabaseEntry;

         /*  make sure that the database entry is not a null pointer (which would happen if an entry is missing

             despite the ID existing) */

         FAS_ASSERT(pHeader != NULL_PTR);

         /* Get uniqueId */

         DATA_BLOCK_ID_e blockId = pHeader->uniqueId;

         if ((blockId < DATA_BLOCK_ID_MAX) && (databaseEntry < DATA_BLOCK_ID_MAX)) {

             /* e.g., data_uniqueIdToDatabaseEntry[<some id>] = configured database entry index */

             data_uniqueIdToDatabaseEntry[blockId] = databaseEntry;

         } else {

             /* Configuration error -> set retval to #STD_NOT_OK */

             retval = STD_NOT_OK;

         }

     }


     if (ftsk_databaseQueue == NULL_PTR) {

         retval = STD_NOT_OK; /* Failed to create the queue */

     }

     return retval;

 }


 void DATA_Task(void) {

     if (ftsk_databaseQueue != NULL_PTR) {

         DATA_QUEUE_MESSAGE_s receiveMessage = {

             .accessType     = DATA_READ_ACCESS,

             .pDatabaseEntry = {GEN_REPEAT_U(NULL_PTR, GEN_STRIP(DATA_MAX_ENTRIES_PER_ACCESS))}};

         /* scan queue and wait for a message up to a maximum amount of 1ms (block time) */

         if (OS_ReceiveFromQueue(ftsk_databaseQueue, (&receiveMessage), 1u) == OS_SUCCESS) {

             /* plausibility check, error whether the first pointer is a NULL_PTR, as this must not happen.

              * See the comments in DATA_Read1DataBlock, DATA_Read2DataBlocks, DATA_Read3DataBlocks and

              * DATA_Read4DataBlocks as well as DATA_Write1DataBlock, DATA_Write2DataBlocks,

              * DATA_Write3DataBlocks and DATA_Write4DataBlocks */

             FAS_ASSERT(receiveMessage.pDatabaseEntry[0] != NULL_PTR);

             /* ready to start reading/writing database entries */

             DATA_IterateOverDatabaseEntries(&receiveMessage);

         }

     }

 }


 void DATA_DummyFunction(void) {

 }


 STD_RETURN_TYPE_e DATA_Read1DataBlock(void *pDataToReceiver0) {

     FAS_ASSERT(pDataToReceiver0 != NULL_PTR);

     return DATA_AccessDatabaseEntries(DATA_READ_ACCESS, pDataToReceiver0, NULL_PTR, NULL_PTR, NULL_PTR);

 }


 STD_RETURN_TYPE_e DATA_Read2DataBlocks(void *pDataToReceiver0, void *pDataToReceiver1) {

     FAS_ASSERT(pDataToReceiver0 != NULL_PTR);

     FAS_ASSERT(pDataToReceiver1 != NULL_PTR);

     return DATA_AccessDatabaseEntries(DATA_READ_ACCESS, pDataToReceiver0, pDataToReceiver1, NULL_PTR, NULL_PTR);

 }


 STD_RETURN_TYPE_e DATA_Read3DataBlocks(void *pDataToReceiver0, void *pDataToReceiver1, void *pDataToReceiver2) {

     FAS_ASSERT(pDataToReceiver0 != NULL_PTR);

     FAS_ASSERT(pDataToReceiver1 != NULL_PTR);

     FAS_ASSERT(pDataToReceiver2 != NULL_PTR);

     return DATA_AccessDatabaseEntries(DATA_READ_ACCESS, pDataToReceiver0, pDataToReceiver1, pDataToReceiver2, NULL_PTR);

 }


 STD_RETURN_TYPE_e DATA_Read4DataBlocks(

     void *pDataToReceiver0,

     void *pDataToReceiver1,

     void *pDataToReceiver2,

     void *pDataToReceiver3) {

     FAS_ASSERT(pDataToReceiver0 != NULL_PTR);

     FAS_ASSERT(pDataToReceiver1 != NULL_PTR);

     FAS_ASSERT(pDataToReceiver2 != NULL_PTR);

     FAS_ASSERT(pDataToReceiver3 != NULL_PTR);

     return DATA_AccessDatabaseEntries(

         DATA_READ_ACCESS, pDataToReceiver0, pDataToReceiver1, pDataToReceiver2, pDataToReceiver3);

 }


 STD_RETURN_TYPE_e DATA_Write1DataBlock(void *pDataFromSender0) {

     FAS_ASSERT(pDataFromSender0 != NULL_PTR);

     return DATA_AccessDatabaseEntries(DATA_WRITE_ACCESS, pDataFromSender0, NULL_PTR, NULL_PTR, NULL_PTR);

 }


 STD_RETURN_TYPE_e DATA_Write2DataBlocks(void *pDataFromSender0, void *pDataFromSender1) {

     FAS_ASSERT(pDataFromSender0 != NULL_PTR);

     FAS_ASSERT(pDataFromSender1 != NULL_PTR);

     return DATA_AccessDatabaseEntries(DATA_WRITE_ACCESS, pDataFromSender0, pDataFromSender1, NULL_PTR, NULL_PTR);

 }


 STD_RETURN_TYPE_e DATA_Write3DataBlocks(void *pDataFromSender0, void *pDataFromSender1, void *pDataFromSender2) {

     FAS_ASSERT(pDataFromSender0 != NULL_PTR);

     FAS_ASSERT(pDataFromSender1 != NULL_PTR);

     FAS_ASSERT(pDataFromSender2 != NULL_PTR);

     return DATA_AccessDatabaseEntries(

         DATA_WRITE_ACCESS, pDataFromSender0, pDataFromSender1, pDataFromSender2, NULL_PTR);

 }


 STD_RETURN_TYPE_e DATA_Write4DataBlocks(

     void *pDataFromSender0,

     void *pDataFromSender1,

     void *pDataFromSender2,

     void *pDataFromSender3) {

     FAS_ASSERT(pDataFromSender0 != NULL_PTR);

     FAS_ASSERT(pDataFromSender1 != NULL_PTR);

     FAS_ASSERT(pDataFromSender2 != NULL_PTR);

     FAS_ASSERT(pDataFromSender3 != NULL_PTR);

     return DATA_AccessDatabaseEntries(

         DATA_WRITE_ACCESS, pDataFromSender0, pDataFromSender1, pDataFromSender2, pDataFromSender3);

 }


 extern void DATA_ExecuteDataBist(void) {

     /* compile database entry */

     DATA_BLOCK_DUMMY_FOR_SELF_TEST_s dummyWriteTable = {.header.uniqueId = DATA_BLOCK_ID_DUMMY_FOR_SELF_TEST};

     dummyWriteTable.member1                          = UINT8_MAX;

     dummyWriteTable.member2                          = DATA_DUMMY_VALUE_UINT8_T_ALTERNATING_BIT_PATTERN;


     /* write entry */

     STD_RETURN_TYPE_e writeReturnValue = DATA_WRITE_DATA(&dummyWriteTable);

     FAS_ASSERT(writeReturnValue == STD_OK);


     DATA_BLOCK_DUMMY_FOR_SELF_TEST_s dummyReadTable = {.header.uniqueId = DATA_BLOCK_ID_DUMMY_FOR_SELF_TEST};


     /* read entry into new variable */

     STD_RETURN_TYPE_e readReturnValue = DATA_READ_DATA(&dummyReadTable);

     FAS_ASSERT(readReturnValue == STD_OK);


     FAS_ASSERT(dummyReadTable.member1 == dummyWriteTable.member1);

     FAS_ASSERT(dummyReadTable.member2 == dummyWriteTable.member2);

 }


 /*========== Externalized Static Function Implementations (Unit Test) =======*/

 #ifdef UNITY_UNIT_TEST

 #endif

DATA_Write4DataBlocks
STD_RETURN_TYPE_e DATA_Write4DataBlocks(void *pDataFromSender0, void *pDataFromSender1, void *pDataFromSender2, void *pDataFromSender3)
Stores four data blocks in database.
Definition: database.c:350

DATA_Task
void DATA_Task(void)
trigger of database manager
Definition: database.c:279

DATA_Read2DataBlocks
STD_RETURN_TYPE_e DATA_Read2DataBlocks(void *pDataToReceiver0, void *pDataToReceiver1)
Reads two data blocks in database by value.
Definition: database.c:305

DATA_AccessDatabaseEntries
static STD_RETURN_TYPE_e DATA_AccessDatabaseEntries(DATA_BLOCK_ACCESS_TYPE_e accessType, void *pData0, void *pData1, void *pData2, void *pData3)
Definition: database.c:131

DATA_IterateOverDatabaseEntries
static void DATA_IterateOverDatabaseEntries(const DATA_QUEUE_MESSAGE_s *kpReceiveMessage)
Definition: database.c:199

FAS_STATIC_ASSERT
FAS_STATIC_ASSERT(DATA_QUEUE_TIMEOUT_MS > 0u, "invalid database queue timeout!")

DATA_Read1DataBlock
STD_RETURN_TYPE_e DATA_Read1DataBlock(void *pDataToReceiver0)
Reads one data block in database by value.
Definition: database.c:300

DATA_DummyFunction
void DATA_DummyFunction(void)
Dummy void function of the database module.
Definition: database.c:297

DATA_Write1DataBlock
STD_RETURN_TYPE_e DATA_Write1DataBlock(void *pDataFromSender0)
Stores one data block in database.
Definition: database.c:331

DATA_Read3DataBlocks
STD_RETURN_TYPE_e DATA_Read3DataBlocks(void *pDataToReceiver0, void *pDataToReceiver1, void *pDataToReceiver2)
Reads three data blocks in database by value.
Definition: database.c:311

DATA_Write3DataBlocks
STD_RETURN_TYPE_e DATA_Write3DataBlocks(void *pDataFromSender0, void *pDataFromSender1, void *pDataFromSender2)
Stores three data blocks in database.
Definition: database.c:342

DATA_ExecuteDataBist
void DATA_ExecuteDataBist(void)
Executes a built-in self-test for the database module.
Definition: database.c:363

data_baseHeader
static const DATA_BASE_HEADER_s data_baseHeader
device configuration of database
Definition: database.c:99

DATA_Read4DataBlocks
STD_RETURN_TYPE_e DATA_Read4DataBlocks(void *pDataToReceiver0, void *pDataToReceiver1, void *pDataToReceiver2, void *pDataToReceiver3)
Reads four data blocks in database by value.
Definition: database.c:318

data_uniqueIdToDatabaseEntry
static uint8_t data_uniqueIdToDatabaseEntry[DATA_BLOCK_ID_MAX]
uniqueId to respective database entry selector
Definition: database.c:110

DATA_Write2DataBlocks
STD_RETURN_TYPE_e DATA_Write2DataBlocks(void *pDataFromSender0, void *pDataFromSender1)
Stores two data blocks in database.
Definition: database.c:336

DATA_QUEUE_TIMEOUT_MS
#define DATA_QUEUE_TIMEOUT_MS
Definition: database.c:82

DATA_Initialize
STD_RETURN_TYPE_e DATA_Initialize(void)
Initialization of database manager.
Definition: database.c:229

DATA_CopyData
static void DATA_CopyData(DATA_BLOCK_ACCESS_TYPE_e accessType, uint32_t dataLength, void *pDatabaseStruct, void *pPassedDataStruct)
Definition: database.c:165

database.h
Database module header.

DATA_BLOCK_ACCESS_TYPE_e
DATA_BLOCK_ACCESS_TYPE_e
data block access types (read or write)
Definition: database.h:109

DATA_READ_ACCESS
@ DATA_READ_ACCESS
Definition: database.h:111

DATA_WRITE_ACCESS
@ DATA_WRITE_ACCESS
Definition: database.h:110

DATA_ENTRY_0
#define DATA_ENTRY_0
Definition: database.h:77

DATA_ENTRY_2
#define DATA_ENTRY_2
Definition: database.h:79

DATA_ENTRY_3
#define DATA_ENTRY_3
Definition: database.h:80

DATA_ENTRY_1
#define DATA_ENTRY_1
Definition: database.h:78

DATA_MAX_ENTRIES_PER_ACCESS
#define DATA_MAX_ENTRIES_PER_ACCESS
Definition: database.h:75

DATA_DUMMY_VALUE_UINT8_T_ALTERNATING_BIT_PATTERN
#define DATA_DUMMY_VALUE_UINT8_T_ALTERNATING_BIT_PATTERN
Definition: database.h:115

DATA_READ_DATA
#define DATA_READ_DATA(...)
Definition: database.h:86

DATA_WRITE_DATA
#define DATA_WRITE_DATA(...)
Definition: database.h:96

data_database
DATA_BASE_s data_database[]
channel configuration of database (data blocks)
Definition: database_cfg.c:188

DATA_BLOCK_ID_e
DATA_BLOCK_ID_e
Definition: database_cfg.h:78

DATA_BLOCK_ID_DUMMY_FOR_SELF_TEST
@ DATA_BLOCK_ID_DUMMY_FOR_SELF_TEST
Definition: database_cfg.h:94

DATA_BLOCK_ID_MAX
@ DATA_BLOCK_ID_MAX
Definition: database_cfg.h:115

FAS_ASSERT
#define FAS_ASSERT(x)
Assertion macro that asserts that x is true.
Definition: fassert.h:251

FAS_TRAP
#define FAS_TRAP
Define that evaluates to essential boolean false thus tripping an assert.
Definition: fassert.h:129

STD_RETURN_TYPE_e
STD_RETURN_TYPE_e
Definition: fstd_types.h:82

STD_NOT_OK
@ STD_NOT_OK
Definition: fstd_types.h:84

STD_OK
@ STD_OK
Definition: fstd_types.h:83

NULL_PTR
#define NULL_PTR
Null pointer.
Definition: fstd_types.h:77

ftask.h
Header of task driver implementation.

ftsk_allQueuesCreated
volatile bool ftsk_allQueuesCreated
Definition: ftask_freertos.c:112

ftsk_databaseQueue
OS_QUEUE ftsk_databaseQueue
Definition: ftask_freertos.c:114

general.h
General macros and definitions for the whole platform.

GEN_REPEAT_U
#define GEN_REPEAT_U(x, n)
Macro that helps to generate a series of literals (for array initializers).
Definition: general.h:250

GEN_STRIP
#define GEN_STRIP(x)
Definition: general.h:261

os.h
Declaration of the OS wrapper interface.

OS_SUCCESS
@ OS_SUCCESS
Definition: os.h:86

OS_ReceiveFromQueue
OS_STD_RETURN_e OS_ReceiveFromQueue(OS_QUEUE xQueue, void *const pvBuffer, uint32_t ticksToWait)
Receive an item from a queue.
Definition: os_freertos.c:264

OS_SendToBackOfQueue
OS_STD_RETURN_e OS_SendToBackOfQueue(OS_QUEUE xQueue, const void *const pvItemToQueue, uint32_t ticksToWait)
Post an item to the back the provided queue.
Definition: os_freertos.c:277

OS_GetTickCount
uint32_t OS_GetTickCount(void)
Returns OS based system tick value.
Definition: os_freertos.c:158

DATA_BASE_HEADER_s
Definition: database.c:87

DATA_BASE_HEADER_s::nrDatabaseEntries
uint8_t nrDatabaseEntries
Definition: database.c:88

DATA_BASE_HEADER_s::pDatabase
DATA_BASE_s * pDatabase
Definition: database.c:89

DATA_BASE_s
Definition: database_cfg.h:72

DATA_BASE_s::dataLength
uint32_t dataLength
Definition: database_cfg.h:74

DATA_BASE_s::pDatabaseEntry
void * pDatabaseEntry
Definition: database_cfg.h:73

DATA_BLOCK_DUMMY_FOR_SELF_TEST_s
Definition: database_cfg.h:621

DATA_BLOCK_DUMMY_FOR_SELF_TEST_s::member1
uint8_t member1
Definition: database_cfg.h:626

DATA_BLOCK_DUMMY_FOR_SELF_TEST_s::header
DATA_BLOCK_HEADER_s header
Definition: database_cfg.h:625

DATA_BLOCK_DUMMY_FOR_SELF_TEST_s::member2
uint8_t member2
Definition: database_cfg.h:627

DATA_BLOCK_HEADER_s
Definition: database_cfg.h:124

DATA_BLOCK_HEADER_s::previousTimestamp
uint32_t previousTimestamp
Definition: database_cfg.h:127

DATA_BLOCK_HEADER_s::timestamp
uint32_t timestamp
Definition: database_cfg.h:126

DATA_BLOCK_HEADER_s::uniqueId
DATA_BLOCK_ID_e uniqueId
Definition: database_cfg.h:125

DATA_QUEUE_MESSAGE_s
Definition: database.h:120

DATA_QUEUE_MESSAGE_s::pDatabaseEntry
void * pDatabaseEntry[DATA_MAX_ENTRIES_PER_ACCESS]
Definition: database.h:122

DATA_QUEUE_MESSAGE_s::accessType
DATA_BLOCK_ACCESS_TYPE_e accessType
Definition: database.h:121