/* @req SWS_Ocu_00100 */
Ocu_ReturnType Ocu_SetRelativeThreshold(Ocu_ChannelType ChannelNumber,Ocu_ValueType RelativeValue)
{
Ocu_ValueType newAbsThreshld;
Ocu_ValueType cntrval;
uint8 cntrchnl;
const volatile struct EMIOS_tag * emiosUnit;
uint8 channelId;
uint8 absChnlId;
/* @req SWS_Ocu_00104 **/
VALIDATE_W_RV( (OcuDriverStatus != OCU_UNINIT), OCU_SETRELATIVETHRESHOLD_SERVICE_ID, OCU_E_UNINIT,OCU_CM_OUT_REF_INTERVAL );
/* @req SWS_Ocu_00105 **/
VALIDATE_W_RV( (ChannelNumber < OCU_MATCH_CHANNEL_COUNT), OCU_SETRELATIVETHRESHOLD_SERVICE_ID, OCU_E_PARAM_INVALID_CHANNEL,OCU_CM_OUT_REF_INTERVAL );
channelId = OcuConfigPtr->OcuChannelConfig[ChannelNumber].OcuChannelId;
if (CHANNELS_PER_EMIOS_UNIT != 0) {
emiosUnit = GET_EMIOS_UNIT(channelId/CHANNELS_PER_EMIOS_UNIT);
} else { return OCU_CM_OUT_REF_INTERVAL; }
absChnlId = GET_EMIOS_CHANNEL(channelId);
cntrchnl = (absChnlId < UNIFIED_CHANNEL_D) ? UNIFIED_CHANNEL_C:UNIFIED_CHANNEL_D ;
cntrval = (Ocu_ValueType)(emiosUnit->CH[cntrchnl].CCNTR.R - 1UL);
/* @req SWS_Ocu_00101 */
newAbsThreshld = cntrval + RelativeValue;
/* @req SWS_Ocu_00106 */
/* @req SWS_Ocu_00107 */
return setthrshld(ChannelNumber, cntrval, newAbsThreshld);
}
Gpt_ValueType Gpt_GetTimeRemaining(Gpt_ChannelType channel)
{
VALIDATE_W_RV( (Gpt_Global.initRun == STD_ON), GPT_GETTIMEREMAINING_SERVICE_ID, GPT_E_UNINIT, 0 );
VALIDATE_W_RV( VALID_CHANNEL(channel),GPT_GETTIMEREMAINING_SERVICE_ID, GPT_E_PARAM_CHANNEL, 0 );
Gpt_ValueType remaining = 0;
/* @req SWS_Gpt_00301 */
/* @req SWS_Gpt_00305 */
if( (GPT_STATE_INITIALIZED == Gpt_Unit[channel].state) ||
(GPT_STATE_EXPIRED == Gpt_Unit[channel].state) ||
((GPT_STATE_STOPPED == Gpt_Unit[channel].state) && (Gpt_Unit[channel].expiredWhenStopped)) ) {
return 0;
}
if (channel <= GPT_CHANNEL_CNT)
{
uint32 *tval = (uint32 *)&(TimAddr[channel]->CNT);
// Time remaining is the time until it hits 0, so just return the current timer value
remaining = *tval;
}
return remaining;
}
Gpt_ValueType Gpt_GetTimeElapsed(Gpt_ChannelType channel)
{
Gpt_ValueType timer = 0;
VALIDATE_W_RV( (Gpt_Global.initRun == STD_ON), GPT_GETTIMEELAPSED_SERVICE_ID, GPT_E_UNINIT ,0 );
VALIDATE_W_RV( VALID_CHANNEL(channel),GPT_GETTIMEELAPSED_SERVICE_ID, GPT_E_PARAM_CHANNEL, 0 );
/* @req SWS_Gpt_00295 */
if(Gpt_Unit[channel].state == GPT_STATE_INITIALIZED) {
return timer;
}
/* @req SWS_Gpt_00299 */
if( (GPT_STATE_EXPIRED == Gpt_Unit[channel].state) ||
((GPT_STATE_STOPPED == Gpt_Unit[channel].state) && (Gpt_Unit[channel].expiredWhenStopped)) ) {
return TimAddr[channel]->ARR;
}
// NOTE!
// These little creatures count down
if (channel <= GPT_CHANNEL_CNT)
{
uint32 *tlval = (uint32 *)&(TimAddr[channel]->ARR);
uint32 *tval = (uint32 *)&(TimAddr[channel]->CNT);
timer = *tlval - *tval;
}
return (timer);
}
/* @req SWS_Ocu_00085 */
Ocu_ValueType Ocu_GetCounter(Ocu_ChannelType ChannelNumber)
{
vuint32_t cntr;
uint8 cntrchnl;
const volatile struct EMIOS_tag * emiosUnit;
uint8 channelId;
uint8 absChnlId;
/* @req SWS_Ocu_00090 **/
VALIDATE_W_RV( (OcuDriverStatus != OCU_UNINIT), OCU_GETCOUNTER_SERVICE_ID, OCU_E_UNINIT,INVALID_COUNTERVALUE );
/* @req SWS_Ocu_00089 **/
VALIDATE_W_RV( (ChannelNumber < OCU_MATCH_CHANNEL_COUNT), OCU_GETCOUNTER_SERVICE_ID, OCU_E_PARAM_INVALID_CHANNEL,INVALID_COUNTERVALUE );
channelId = OcuConfigPtr->OcuChannelConfig[ChannelNumber].OcuChannelId;
if (CHANNELS_PER_EMIOS_UNIT != 0) {
emiosUnit = GET_EMIOS_UNIT(channelId/CHANNELS_PER_EMIOS_UNIT);
} else { return INVALID_COUNTERVALUE; }
absChnlId = GET_EMIOS_CHANNEL(channelId);
// Get the unified channel section which drives the counter
cntrchnl = (absChnlId < UNIFIED_CHANNEL_D) ? UNIFIED_CHANNEL_C:UNIFIED_CHANNEL_D ;
/* @req SWS_Ocu_00086 */
cntr = emiosUnit->CH[cntrchnl].CCNTR.R -1UL; //In MCB mode CNTR is 1 based
return (Ocu_ValueType)cntr;
}
Lin_StatusType Lin_GetStatus( uint8 Channel, uint8** Lin_SduPtr )
{
volatile struct LINFLEX_tag * LINFLEXHw = LINFLEX(Channel);
VALIDATE_W_RV( (LinDriverStatus != LIN_UNINIT), LIN_GETSTATUS_SERVICE_ID, LIN_E_UNINIT, LIN_NOT_OK);
VALIDATE_W_RV( (LinChannelStatus[Channel] != LIN_CH_UNINIT), LIN_GETSTATUS_SERVICE_ID, LIN_E_CHANNEL_UNINIT, LIN_NOT_OK);
VALIDATE_W_RV( (Channel < LIN_CONTROLLER_CNT), LIN_GETSTATUS_SERVICE_ID, LIN_E_INVALID_CHANNEL, LIN_NOT_OK);
VALIDATE_W_RV( (Lin_SduPtr!=NULL), LIN_GETSTATUS_SERVICE_ID, LIN_E_INVALID_POINTER, LIN_NOT_OK);
imask_t state;
Irq_Save(state);
Lin_StatusType res = LinChannelStatus[Channel];
/* We can only check for valid sdu ptr when LIN_RX_OK */
if(LinChannelStatus[Channel] == LIN_RX_OK || LinChannelStatus[Channel] == LIN_RX_ERROR){
CopyToBuffer(LinBufRx[Channel], LINFLEXHw);
*Lin_SduPtr = LinBufRx[Channel];
if(LinChannelStatus[Channel] == LIN_RX_ERROR){
ResyncDriver(Channel);
}
LinChannelStatus[Channel]=LIN_CH_OPERATIONAL;
} else if(LinChannelStatus[Channel] == LIN_TX_OK || LinChannelStatus[Channel] == LIN_TX_ERROR){
if(LinChannelStatus[Channel] == LIN_TX_ERROR){
ResyncDriver(Channel);
}
LinChannelStatus[Channel]=LIN_CH_OPERATIONAL;
}
Irq_Restore(state);
return res;
}
Std_ReturnType LinSM_RequestComMode(NetworkHandleType network,ComM_ModeType mode)
{
Std_ReturnType res = E_NOT_OK;
VALIDATE_W_RV( (LinSMStatus != LINSM_UNINIT), LINSM_REQUEST_COM_MODE_SERVICE_ID, LINSM_E_UNINIT, E_NOT_OK);
VALIDATE_W_RV( (network < LINIF_CONTROLLER_CNT), LINSM_REQUEST_COM_MODE_SERVICE_ID, LINSM_E_NOXEXISTENT_CHANNEL, E_NOT_OK);
switch(mode)
{
case COMM_NO_COMMUNICATION:
if (E_OK == LinIf_GotoSleep(network)){
LinSMChannelStatus[network] = LINSM_GOTO_SLEEP;
GoToSleepTimer[network]=LINSM_GOTO_SLEEP_TIMEOUT;
res = E_OK;
}
break;
case COMM_SILENT_COMMUNICATION:
// Standard say nothing about this case.
break;
case COMM_FULL_COMMUNICATION:
WakeUpTimer[network]=LINSM_WAKEUP_TIMEOUT; //should be done here since some implementations will confirm immediatly
if (E_OK == LinIf_WakeUp(network)){
res = E_OK;
}
else
{
WakeUpTimer[network]=0;
}
break;
default:
break;
}
return res;
}
Std_ReturnType Lin_GoToSleepInternal( uint8 Channel )
{
VALIDATE_W_RV( (LinDriverStatus != LIN_UNINIT), LIN_GO_TO_SLEEP_INTERNAL_SERVICE_ID, LIN_E_UNINIT, E_NOT_OK);
VALIDATE_W_RV( (LinChannelStatus[Channel] != LIN_CH_UNINIT), LIN_GO_TO_SLEEP_INTERNAL_SERVICE_ID, LIN_E_CHANNEL_UNINIT, E_NOT_OK);
VALIDATE_W_RV( (Channel < LIN_CONTROLLER_CNT), LIN_GO_TO_SLEEP_INTERNAL_SERVICE_ID, LIN_E_INVALID_CHANNEL, E_NOT_OK);
VALIDATE_W_RV( (LinChannelStatus[Channel] != LIN_CH_SLEEP), LIN_GO_TO_SLEEP_INTERNAL_SERVICE_ID, LIN_E_STATE_TRANSITION, E_NOT_OK);
Lin_GoToSleep(Channel);
return E_OK;
}
Std_ReturnType Mcu_InitRamSection(const Mcu_RamSectionType RamSection)
{
VALIDATE_W_RV( ( 1 == Mcu_Global.initRun ), MCU_INITRAMSECTION_SERVICE_ID, MCU_E_UNINIT, E_NOT_OK );
VALIDATE_W_RV( ( RamSection <= Mcu_Global.config->McuRamSectors ), MCU_INITRAMSECTION_SERVICE_ID, MCU_E_PARAM_RAMSECTION, E_NOT_OK );
/* NOT SUPPORTED, reason: no support for external RAM */
return E_OK;
}
/* !req SWS_Mcu_00056 */
Std_ReturnType Mcu_DistributePllClock(void)
{
/* @req SWS_Mcu_00125 */
/* !req SWS_Mcu_00122 */
VALIDATE_W_RV( ( TRUE == Mcu_Global.initRun ), MCU_DISTRIBUTEPLLCLOCK_SERVICE_ID, MCU_E_UNINIT, E_NOT_OK );
VALIDATE_W_RV( ( zynq_GetPllStatus() == MCU_PLL_LOCKED), MCU_DISTRIBUTEPLLCLOCK_SERVICE_ID, MCU_E_PLL_NOT_LOCKED, E_NOT_OK);
return E_OK;
}
Std_ReturnType LinSM_ScheduleRequest(NetworkHandleType channel,LinIf_SchHandleType schedule)
{
VALIDATE_W_RV( (LinSMStatus != LINSM_UNINIT), LINSM_SCHEDULE_REQUEST_SERVICE_ID, LINSM_E_UNINIT, E_NOT_OK);
VALIDATE_W_RV( (channel < LINIF_CONTROLLER_CNT), LINSM_SCHEDULE_REQUEST_SERVICE_ID, LINSM_E_NOXEXISTENT_CHANNEL, E_NOT_OK);
VALIDATE_W_RV( (LinSMChannelStatus[channel] == LINSM_RUN_SCHEDULE), LINSM_SCHEDULE_REQUEST_SERVICE_ID, LINSM_E_NOT_IN_RUN_SCHEDULE, E_NOT_OK);
VALIDATE_W_RV( (schedule < LINIF_SCH_CNT), LINSM_SCHEDULE_REQUEST_SERVICE_ID, LINSM_E_PARAMETER, E_NOT_OK);
ScheduleRequestTimer[channel]=LINSM_SCHEDULE_REQUEST_TIMEOUT;
return LinIf_ScheduleRequest(channel, schedule);
}
Std_ReturnType Lin_SendResponse( uint8 Channel, Lin_PduType* PduInfoPtr )
{
VALIDATE_W_RV( (LinDriverStatus != LIN_UNINIT), LIN_SEND_RESPONSE_SERVICE_ID, LIN_E_UNINIT, E_NOT_OK);
VALIDATE_W_RV( (LinChannelStatus[Channel] != LIN_CH_UNINIT), LIN_SEND_RESPONSE_SERVICE_ID, LIN_E_CHANNEL_UNINIT, E_NOT_OK);
VALIDATE_W_RV( (Channel < LIN_CONTROLLER_CNT), LIN_SEND_RESPONSE_SERVICE_ID, LIN_E_INVALID_CHANNEL, E_NOT_OK);
VALIDATE_W_RV( (LinChannelStatus[Channel] != LIN_CH_SLEEP), LIN_SEND_RESPONSE_SERVICE_ID, LIN_E_STATE_TRANSITION, E_NOT_OK);
VALIDATE_W_RV( (PduInfoPtr != NULL), LIN_SEND_RESPONSE_SERVICE_ID, LIN_E_INVALID_POINTER, E_NOT_OK);
/* The response is sent from within the header in this implementation since this is a master only implementation */
return E_OK;
}
Std_ReturnType Mcu_InitRamSection(Mcu_RamSectionType RamSection)
{
/* @req SWS_Mcu_00021 */
/* @req SWS_Mcu_00125 */
VALIDATE_W_RV( ( TRUE == Mcu_Global.initRun ), MCU_INITRAMSECTION_SERVICE_ID, MCU_E_UNINIT, E_NOT_OK );
VALIDATE_W_RV( ( RamSection <= Mcu_Global.config->McuRamSectors ), MCU_INITRAMSECTION_SERVICE_ID, MCU_E_PARAM_RAMSECTION, E_NOT_OK );
memset( (void *)Mcu_Global.config->McuRamSectorSettingConfig[RamSection].McuRamSectionBaseAddress,
Mcu_Global.config->McuRamSectorSettingConfig[RamSection].McuRamDefaultValue,
Mcu_Global.config->McuRamSectorSettingConfig[RamSection].McuRamSectionSize);
return E_OK;
}
/* @req SWS_Ocu_00091 */
Ocu_ReturnType Ocu_SetAbsoluteThreshold(Ocu_ChannelType ChannelNumber,Ocu_ValueType ReferenceValue,Ocu_ValueType AbsoluteValue)
{
/* @req SWS_Ocu_00095 **/
VALIDATE_W_RV( (OcuDriverStatus != OCU_UNINIT), OCU_SETABSOLUTETHRESHOLD_SERVICE_ID, OCU_E_UNINIT,OCU_CM_OUT_REF_INTERVAL );
/* @req SWS_Ocu_00096 **/
VALIDATE_W_RV( (ChannelNumber < OCU_MATCH_CHANNEL_COUNT), OCU_SETABSOLUTETHRESHOLD_SERVICE_ID, OCU_E_PARAM_INVALID_CHANNEL,OCU_CM_OUT_REF_INTERVAL );
/* @req SWS_Ocu_00098 */
return setthrshld(ChannelNumber,ReferenceValue,AbsoluteValue);
}
Std_ReturnType Mcu_InitClock(const Mcu_ClockType ClockSetting)
{
const Mcu_ClockSettingConfigType *clockSettingsPtr;
VALIDATE_W_RV( ( 1 == Mcu_Global.initRun ), MCU_INITCLOCK_SERVICE_ID, MCU_E_UNINIT, E_NOT_OK );
VALIDATE_W_RV( ( ClockSetting < Mcu_Global.config->McuClockSettings ), MCU_INITCLOCK_SERVICE_ID, MCU_E_PARAM_CLOCK, E_NOT_OK );
Mcu_Global.clockSetting = ClockSetting;
clockSettingsPtr = &Mcu_Global.config->McuClockSettingConfig[Mcu_Global.clockSetting];
InitMcuClocks(clockSettingsPtr);
InitPerClocks(clockSettingsPtr);
return E_OK;
}
RamTst_TestResultType RamTst_GetTestResultPerBlock( RamTst_NumberOfBlocksType BlockID )
{
/* @req SWS_RamTst_00089 */
VALIDATE_W_RV( ( RamTst_Internal.InitStatus != RAMTST_UNINIT ), RAMTST_GETRESULTPERBLOCK_SERVICE_ID, RAMTST_E_UNINIT, RAMTST_RESULT_NOT_TESTED);
/* Find the block */
const RamTst_BlockParamsType *blockParamPtr = NULL;
const RamTst_AlgParamsType *algParams = NULL;
for(RamTst_AlgParamsIdType i = 0; (i < RamTst_ConfigParams.RamTstNumberOfAlgParamSets) && (NULL == blockParamPtr); i++) {
algParams = &RamTst_ConfigParams.RamTstAlgParams[i];
/* Run for all blocks */
for(RamTst_NumberOfBlocksType block = 0; (block < algParams->RamTstNumberOfBlocks) && (NULL == blockParamPtr); block++) {
if(algParams->RamTstBlockParams[block].RamTstBlockId == BlockID) {
blockParamPtr = &algParams->RamTstBlockParams[block];
}
}
}
if(NULL != blockParamPtr) {
/* @req SWS_RamTst_00038 */
return RamTst_Internal.RamTst_BlockResultBuffer[blockParamPtr->RamTstBlockIndex];
} else {
/* Invalid block id */
#if ( RAMTST_DEV_ERROR_DETECT == STD_ON )
/* @req SWS_RamTst_00039 */
(void)Det_ReportError(MODULE_ID_RAMTST, 0, RAMTST_GETRESULTPERBLOCK_SERVICE_ID, RAMTST_E_OUT_OF_RANGE);
#endif
return RAMTST_RESULT_UNDEFINED;
}
}
RamTst_TestResultType RamTst_GetTestResult( void )
{
/* @req SWS_RamTst_00089 */
VALIDATE_W_RV( ( RamTst_Internal.InitStatus != RAMTST_UNINIT ), RAMTST_GETTESTRESULT_SERVICE_ID, RAMTST_E_UNINIT, RAMTST_RESULT_NOT_TESTED);
/* @req SWS_RamTst_00024 */
return RamTst_Internal.CurrentTestResult;
}
Mcu_ResetType Mcu_GetResetReason(void)
{
Mcu_ResetType rv;
VALIDATE_W_RV( ( 1 == Mcu_Global.initRun ), MCU_GETRESETREASON_SERVICE_ID, MCU_E_UNINIT, MCU_RESET_UNDEFINED );
#if defined(CFG_MPC560X)
if( RGM.FES.B.F_SOFT ) {
rv = MCU_SW_RESET;
} else if( RGM.DES.B.F_SWT ) {
rv = MCU_WATCHDOG_RESET;
} else if( RGM.DES.B.F_POR ) {
rv = MCU_POWER_ON_RESET;
} else {
rv = MCU_RESET_UNDEFINED;
}
#else
if( SIU.RSR.B.SSRS ) {
rv = MCU_SW_RESET;
} else if( SIU.RSR.B.WDRS ) {
rv = MCU_WATCHDOG_RESET;
} else if( SIU.RSR.B.PORS || SIU.RSR.B.ERS ) {
rv = MCU_POWER_ON_RESET;
} else {
rv = MCU_RESET_UNDEFINED;
}
#endif
return rv;
}
RamTst_AlgParamsIdType RamTst_GetAlgParams( void )
{
/* @req SWS_RamTst_00089 */
VALIDATE_W_RV( ( RamTst_Internal.InitStatus != RAMTST_UNINIT ), RAMTST_GETALGPARAMS_SERVICE_ID, RAMTST_E_UNINIT, 0);
return RamTst_Internal.ActiveAlgParamID;
}
Std_ReturnType Lin_GoToSleep( uint8 Channel )
{
volatile struct LINFLEX_tag * LINFLEXHw = LINFLEX(Channel);
VALIDATE_W_RV( (LinDriverStatus != LIN_UNINIT), LIN_GO_TO_SLEEP_SERVICE_ID, LIN_E_UNINIT, E_NOT_OK);
VALIDATE_W_RV( (LinChannelStatus[Channel] != LIN_CH_UNINIT), LIN_GO_TO_SLEEP_SERVICE_ID, LIN_E_CHANNEL_UNINIT, E_NOT_OK);
VALIDATE_W_RV( (Channel < LIN_CONTROLLER_CNT), LIN_GO_TO_SLEEP_SERVICE_ID, LIN_E_INVALID_CHANNEL, E_NOT_OK);
VALIDATE_W_RV( (LinChannelStatus[Channel] != LIN_CH_SLEEP), LIN_GO_TO_SLEEP_SERVICE_ID, LIN_E_STATE_TRANSITION, E_NOT_OK);
LINFLEXHw->LINCR1.B.SLEEP = 1;
LINFLEXHw->LINIER.B.WUIE = 1; /* enable wake-up irq */
LinChannelStatus[Channel]=LIN_CH_SLEEP;
return E_OK;
}
Std_ReturnType Lin_WakeUp( uint8 Channel )
{
volatile struct LINFLEX_tag * LINFLEXHw = LINFLEX(Channel);
VALIDATE_W_RV( (LinDriverStatus != LIN_UNINIT), LIN_WAKE_UP_SERVICE_ID, LIN_E_UNINIT, E_NOT_OK);
VALIDATE_W_RV( (LinChannelStatus[Channel] != LIN_CH_UNINIT), LIN_WAKE_UP_SERVICE_ID, LIN_E_CHANNEL_UNINIT, E_NOT_OK);
VALIDATE_W_RV( (Channel < LIN_CONTROLLER_CNT), LIN_WAKE_UP_SERVICE_ID, LIN_E_INVALID_CHANNEL, E_NOT_OK);
VALIDATE_W_RV( (LinChannelStatus[Channel] == LIN_CH_SLEEP), LIN_WAKE_UP_SERVICE_ID, LIN_E_STATE_TRANSITION, E_NOT_OK);
/* Disable wake interrupt */
LINFLEXHw->LINIER.B.WUIE = 0;
/* Clear sleep bit */
LINFLEXHw->LINCR1.B.SLEEP = 0;
LinChannelStatus[Channel]=LIN_CH_OPERATIONAL;
return E_OK;
}
Std_ReturnType Mcu_InitClock(Mcu_ClockType ClockSetting)
{
const Mcu_ClockSettingConfigType *clockSettingsPtr;
/* @req SWS_Mcu_00125 */
/* @req SWS_Mcu_00019 */
VALIDATE_W_RV( ( TRUE == Mcu_Global.initRun ), MCU_INITCLOCK_SERVICE_ID, MCU_E_UNINIT, E_NOT_OK );
VALIDATE_W_RV( ( ClockSetting < Mcu_Global.config->McuClockSettings ), MCU_INITCLOCK_SERVICE_ID, MCU_E_PARAM_CLOCK, E_NOT_OK );
Mcu_Global.clockSetting = ClockSetting;
clockSettingsPtr = &Mcu_Global.config->McuClockSettingConfig[Mcu_Global.clockSetting];
zynq_InitPll(clockSettingsPtr);
zynq_InitClocks(clockSettingsPtr);
return E_OK;
}
Std_ReturnType LinSM_GetCurrentComMode(NetworkHandleType network,ComM_ModeType* mode)
{
VALIDATE_W_RV( (LinSMStatus != LINSM_UNINIT), LINSM_GET_CURRENT_COM_MODE_SERVICE_ID, LINSM_E_UNINIT, E_NOT_OK);
VALIDATE_W_RV( (network < LINIF_CONTROLLER_CNT), LINSM_GET_CURRENT_COM_MODE_SERVICE_ID, LINSM_E_NOXEXISTENT_CHANNEL, E_NOT_OK);
VALIDATE_W_RV( (mode != NULL), LINSM_GET_CURRENT_COM_MODE_SERVICE_ID, LINSM_E_PARAMETER_POINTER, E_NOT_OK);
switch (LinSMChannelStatus[network])
{
case LINSM_RUN_SCHEDULE:
*mode= COMM_FULL_COMMUNICATION;
break;
default:
*mode= COMM_NO_COMMUNICATION;
break;
}
return E_OK;
}
Mcu_ResetType Mcu_GetResetReason(void)
{
/* @req SWS_Mcu_00133 */
/* @req SWS_Mcu_00125 */
/* @req SWS_Mcu_00005 */
VALIDATE_W_RV( ( TRUE == Mcu_Global.initRun ), MCU_GETRESETREASON_SERVICE_ID, MCU_E_UNINIT, MCU_RESET_UNDEFINED );
return Mcu_Global.resetReason;
}
/**
* Read from flash memory
*
* @param SourceAddress
* @param TargetAddressPtr
* @param Length
* @return
*/
Std_ReturnType Fls_Read( Fls_AddressType SourceAddress,
uint8 *TargetAddressPtr,
Fls_LengthType Length)
{
SourceAddress += FLS_BASE_ADDRESS;
/** @req FLS256 */
/** @req FLS236 */
/** !req FLS239 TODO */
/** !req FLS240 Have no idea what the requirement means*/
/** @req FLS099 */
VALIDATE_W_RV(Fls_Global.status != MEMIF_UNINIT,FLS_READ_ID, FLS_E_UNINIT,E_NOT_OK );
/** @req FLS100 */
VALIDATE_W_RV( Fls_Global.status != MEMIF_BUSY, FLS_READ_ID, FLS_E_BUSY, E_NOT_OK );
/** @req FLS158 */
VALIDATE_W_RV( TargetAddressPtr != NULL , FLS_READ_ID, FLS_E_PARAM_DATA, E_NOT_OK );
/** @req FLS097 */
VALIDATE_W_RV( E_OK == fls_CheckValidAddress(SourceAddress), FLS_READ_ID, FLS_E_PARAM_ADDRESS, E_NOT_OK );
/** @req FLS098 */
VALIDATE_W_RV( (Length != 0) && (E_OK == fls_CheckValidAddress(SourceAddress + Length)), FLS_READ_ID, FLS_E_PARAM_LENGTH, E_NOT_OK );
// Always check if status is not busy
if (Fls_Global.status == MEMIF_BUSY)
return E_NOT_OK;
Fls_Global.status = MEMIF_BUSY;
Fls_Global.jobResultType = MEMIF_JOB_PENDING;
Fls_Global.jobType = FLS_JOB_READ;
LOG_HEX2("Fls_Read() ",(uint32)TargetAddressPtr," ", Length);
/** @req FLS237 */
Fls_Global.flashAddr = SourceAddress;
Fls_Global.ramAddr = TargetAddressPtr;
Fls_Global.length = Length;
if( Fls_Global.mode == MEMIF_MODE_FAST ) {
Fls_Global.readChunkSize = Fls_Global.config->FlsMaxReadFastMode;
} else {
Fls_Global.readChunkSize = Fls_Global.config->FlsMaxReadNormalMode;
}
return E_OK;
}
Std_ReturnType Fls_Compare( Fls_AddressType SourceAddress,
uint8 *TargetAddressPtr,
Fls_LengthType Length )
{
SourceAddress += FLS_BASE_ADDRESS;
/** @req FLS257 */
/** @req FLS241 */
/** @req FLS186 */
/** @req FLS152 */
VALIDATE_W_RV(Fls_Global.status != MEMIF_UNINIT,FLS_COMPARE_ID, FLS_E_UNINIT,E_NOT_OK );
/** @req FLS153 */
VALIDATE_W_RV( Fls_Global.status != MEMIF_BUSY, FLS_COMPARE_ID, FLS_E_BUSY, E_NOT_OK );
/** @req FLS273 */
VALIDATE_W_RV( TargetAddressPtr != NULL , FLS_COMPARE_ID, FLS_E_PARAM_DATA, E_NOT_OK );
/** @req FLS150 */
VALIDATE_W_RV( E_OK == fls_CheckValidAddress(SourceAddress), FLS_COMPARE_ID, FLS_E_PARAM_ADDRESS, E_NOT_OK );
/** @req FLS151 */
VALIDATE_W_RV( (Length != 0) && (E_OK == fls_CheckValidAddress(SourceAddress + Length)),
FLS_COMPARE_ID, FLS_E_PARAM_LENGTH, E_NOT_OK );
// Always check if status is not busy
if (Fls_Global.status == MEMIF_BUSY )
return E_NOT_OK;
Fls_Global.status = MEMIF_BUSY;
Fls_Global.jobResultType = MEMIF_JOB_PENDING;
Fls_Global.jobType = FLS_JOB_COMPARE;
if( Fls_Global.mode == MEMIF_MODE_FAST ) {
Fls_Global.readChunkSize = Fls_Global.config->FlsMaxReadFastMode;
} else {
Fls_Global.readChunkSize = Fls_Global.config->FlsMaxReadNormalMode;
}
/* @req FLS242 */
Fls_Global.flashAddr = SourceAddress;
Fls_Global.ramAddr = TargetAddressPtr;
Fls_Global.length = Length;
return E_OK;
}
/**
* Erase flash sectors
*
* @param TargetAddress Always from 0 to FLS_TOTAL_SIZE
* @param Length
* @return
*/
Std_ReturnType Fls_Erase(Fls_AddressType TargetAddress, Fls_LengthType Length) {
#if FLS_BASE_ADDRESS > 0
/* Avoid compiler warning */
TargetAddress += FLS_BASE_ADDRESS;
#endif
/** @req SWS_Fls_00218 */
/** @req SWS_Fls_00220 */
/** @req SWS_Fls_00327 */
/** @req SWS_Fls_00065 */
VALIDATE_W_RV( Fls_Global.status != MEMIF_UNINIT, FLS_ERASE_ID, FLS_E_UNINIT, E_NOT_OK );
/** @req SWS_Fls_00023 */
VALIDATE_W_RV( Fls_Global.status != MEMIF_BUSY, FLS_ERASE_ID, FLS_E_BUSY, E_NOT_OK );
/** @req SWS_Fls_00020 */
VALIDATE_W_RV( E_OK == sectorAligned( TargetAddress ),
FLS_ERASE_ID, FLS_E_PARAM_ADDRESS, E_NOT_OK );
/** @req SWS_Fls_00021 */
VALIDATE_W_RV( (Length != 0) && (EE_OK == sectorAligned( TargetAddress + Length)),
FLS_ERASE_ID, FLS_E_PARAM_LENGTH, E_NOT_OK );
#if defined(CFG_MPC5777M)
VALIDATE_W_RV((E_OK == checkValidChunk(TargetAddress, TargetAddress + Length - 1)), FLS_ERASE_ID, FLS_E_INVALID_AREA, E_NOT_OK);
#endif
Fls_Global.status = MEMIF_BUSY; /** @req SWS_Fls_00328 */
Fls_Global.jobResultType = MEMIF_JOB_PENDING; /** @req SWS_Fls_00329 */
Fls_Global.jobType = FLS_JOB_ERASE;
Fls_Global.flashAddr = TargetAddress;
Fls_Global.length = Length;
LOG_HEX2("Fls_Erase() ",TargetAddress," ", Length);
/* Unlock */
Flash_Lock(Fls_Global.config->FlsInfo,FLASH_OP_UNLOCK,TargetAddress, Length );
/** @req SWS_Fls_00145 */
if (EE_OK != Flash_Erase(Fls_Global.config->FlsInfo,TargetAddress, Length, NULL )) {
return E_NOT_OK;
}
return E_OK; /** @req SWS_Fls_00330 */
}
Std_ReturnType Mcu_InitClock(const Mcu_ClockType ClockSetting)
{
const Mcu_ClockSettingConfigType *clockSettingsPtr;
VALIDATE_W_RV( ( 1 == Mcu_Global.initRun ), MCU_INITCLOCK_SERVICE_ID, MCU_E_UNINIT, E_NOT_OK );
VALIDATE_W_RV( ( ClockSetting < Mcu_Global.config->McuClockSettings ), MCU_INITCLOCK_SERVICE_ID, MCU_E_PARAM_CLOCK, E_NOT_OK );
Mcu_Global.clockSetting = ClockSetting;
clockSettingsPtr = &Mcu_Global.config->McuClockSettingConfig[Mcu_Global.clockSetting];
CLKSEL &= ~BM_PLLSEL; // Turn off PLL
PLLCTL |= BM_PLLON+BM_AUTO; // Enable PLL module, Auto Mode
REFDV = clockSettingsPtr->Pll1; // Set reference divider
SYNR = clockSettingsPtr->Pll2; // Set synthesizer multiplier
while (Mcu_GetPllStatus() != MCU_PLL_LOCKED) ;
CLKSEL |= BM_PLLSEL; // Switch to PLL clock
return E_OK;
}
/**
* Erase flash sectors
*
* @param TargetAddress Always from 0 to FLS_TOTAL_SIZE
* @param Length
* @return
*/
Std_ReturnType Fls_Erase(Fls_AddressType TargetAddress, Fls_LengthType Length) {
TargetAddress += FLS_BASE_ADDRESS;
/** @req FLS250 3.0/4.0 */
/** @req FLS218 3.0/4.0 */
/** @req FLS220 3.0/4.0 */
/** @req FLS327 4.0 */
/** @req FLS065 */
VALIDATE_W_RV( Fls_Global.status != MEMIF_UNINIT, FLS_ERASE_ID, FLS_E_UNINIT, E_NOT_OK );
/** @req FLS023 */
VALIDATE_W_RV( Fls_Global.status != MEMIF_BUSY, FLS_ERASE_ID, FLS_E_BUSY, E_NOT_OK );
/** @req FLS020 3.0/4.0 */
VALIDATE_W_RV( E_OK == fls_SectorAligned( TargetAddress ),
FLS_ERASE_ID, FLS_E_PARAM_ADDRESS, E_NOT_OK );
/** @req FLS021 3.0/4.0 */
VALIDATE_W_RV( (Length != 0) && (EE_OK == fls_SectorAligned( TargetAddress + Length)),
FLS_ERASE_ID, FLS_E_PARAM_LENGTH, E_NOT_OK );
// Check if we trying to erase a partition that we are executing in
#if 0
pc = fls_GetPc();
#endif
Fls_Global.status = MEMIF_BUSY; /** @req FLS219 3.0 */ /** @req FLS328 4.0 */
Fls_Global.jobResultType = MEMIF_JOB_PENDING; /** @req FLS329 4.0 */
Fls_Global.jobType = FLS_JOB_ERASE;
Fls_Global.flashAddr = TargetAddress;
Fls_Global.length = Length;
LOG_HEX2("Fls_Erase() ",TargetAddress," ", Length);
/* Unlock */
Flash_Lock(Fls_Global.config->FlsInfo,FLASH_OP_UNLOCK,TargetAddress, Length );
/** @req FLS145 */
Flash_Erase(Fls_Global.config->FlsInfo,TargetAddress, Length, NULL );
return E_OK; /** @req FLS330 4.0 */
}
Mcu_RawResetType Mcu_GetResetRawValue(void) {
VALIDATE_W_RV( ( 1 == Mcu_Global.initRun ), MCU_GETRESETREASON_SERVICE_ID, MCU_E_UNINIT, MCU_GETRESETRAWVALUE_UNINIT_RV );
if (!Mcu_Global.initRun) {
return MCU_GETRESETRAWVALUE_UNINIT_RV;
} else {
return (RCC->CSR) & (RCC_CSR_RMVF | RCC_CSR_PINRSTF | RCC_CSR_PORRSTF
| RCC_CSR_SFTRSTF | RCC_CSR_IWDGRSTF | RCC_CSR_WWDGRSTF
| RCC_CSR_LPWRRSTF);
}
return 0;
}
/* @req SWS_Mcu_00006 */
Mcu_RawResetType Mcu_GetResetRawValue(void)
{
/* @req SWS_Mcu_00135 */
/* @req SWS_Mcu_00125 */
VALIDATE_W_RV( ( TRUE == Mcu_Global.initRun ), MCU_GETRESETREASON_SERVICE_ID, MCU_E_UNINIT, MCU_GETRESETRAWVALUE_UNINIT_RV );
if( !Mcu_Global.initRun ) {
return MCU_GETRESETRAWVALUE_UNINIT_RV;
}
return Mcu_Global.rawResetvalue;
}
