/* * The Clear BSD License * Copyright (c) 2015, Freescale Semiconductor, Inc. * Copyright 2016-2017 NXP * All rights reserved. * * Redistribution and use in source and binary forms, with or without modification, * are permitted (subject to the limitations in the disclaimer below) provided * that the following conditions are met: * * o Redistributions of source code must retain the above copyright notice, this list * of conditions and the following disclaimer. * * o Redistributions in binary form must reproduce the above copyright notice, this * list of conditions and the following disclaimer in the documentation and/or * other materials provided with the distribution. * * o Neither the name of the copyright holder nor the names of its * contributors may be used to endorse or promote products derived from this * software without specific prior written permission. * * NO EXPRESS OR IMPLIED LICENSES TO ANY PARTY'S PATENT RIGHTS ARE GRANTED BY THIS LICENSE. * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR * ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON * ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include "fsl_rtc.h" /******************************************************************************* * Definitions ******************************************************************************/ #define SECONDS_IN_A_DAY (86400U) #define SECONDS_IN_A_HOUR (3600U) #define SECONDS_IN_A_MINUTE (60U) #define DAYS_IN_A_YEAR (365U) #define YEAR_RANGE_START (1970U) #define YEAR_RANGE_END (2099U) /******************************************************************************* * Prototypes ******************************************************************************/ /*! * @brief Checks whether the date and time passed in is valid * * @param datetime Pointer to structure where the date and time details are stored * * @return Returns false if the date & time details are out of range; true if in range */ static bool RTC_CheckDatetimeFormat(const rtc_datetime_t *datetime); /*! * @brief Converts time data from datetime to seconds * * @param datetime Pointer to datetime structure where the date and time details are stored * * @return The result of the conversion in seconds */ static uint32_t RTC_ConvertDatetimeToSeconds(const rtc_datetime_t *datetime); /*! * @brief Converts time data from seconds to a datetime structure * * @param seconds Seconds value that needs to be converted to datetime format * @param datetime Pointer to the datetime structure where the result of the conversion is stored */ static void RTC_ConvertSecondsToDatetime(uint32_t seconds, rtc_datetime_t *datetime); /******************************************************************************* * Code ******************************************************************************/ static bool RTC_CheckDatetimeFormat(const rtc_datetime_t *datetime) { assert(datetime); /* Table of days in a month for a non leap year. First entry in the table is not used, * valid months start from 1 */ uint8_t daysPerMonth[] = {0U, 31U, 28U, 31U, 30U, 31U, 30U, 31U, 31U, 30U, 31U, 30U, 31U}; /* Check year, month, hour, minute, seconds */ if ((datetime->year < YEAR_RANGE_START) || (datetime->year > YEAR_RANGE_END) || (datetime->month > 12U) || (datetime->month < 1U) || (datetime->hour >= 24U) || (datetime->minute >= 60U) || (datetime->second >= 60U)) { /* If not correct then error*/ return false; } /* Adjust the days in February for a leap year */ if ((((datetime->year & 3U) == 0) && (datetime->year % 100 != 0)) || (datetime->year % 400 == 0)) { daysPerMonth[2] = 29U; } /* Check the validity of the day */ if ((datetime->day > daysPerMonth[datetime->month]) || (datetime->day < 1U)) { return false; } return true; } static uint32_t RTC_ConvertDatetimeToSeconds(const rtc_datetime_t *datetime) { assert(datetime); /* Number of days from begin of the non Leap-year*/ /* Number of days from begin of the non Leap-year*/ uint16_t monthDays[] = {0U, 0U, 31U, 59U, 90U, 120U, 151U, 181U, 212U, 243U, 273U, 304U, 334U}; uint32_t seconds; /* Compute number of days from 1970 till given year*/ seconds = (datetime->year - 1970U) * DAYS_IN_A_YEAR; /* Add leap year days */ seconds += ((datetime->year / 4) - (1970U / 4)); /* Add number of days till given month*/ seconds += monthDays[datetime->month]; /* Add days in given month. We subtract the current day as it is * represented in the hours, minutes and seconds field*/ seconds += (datetime->day - 1); /* For leap year if month less than or equal to Febraury, decrement day counter*/ if ((!(datetime->year & 3U)) && (datetime->month <= 2U)) { seconds--; } seconds = (seconds * SECONDS_IN_A_DAY) + (datetime->hour * SECONDS_IN_A_HOUR) + (datetime->minute * SECONDS_IN_A_MINUTE) + datetime->second; return seconds; } static void RTC_ConvertSecondsToDatetime(uint32_t seconds, rtc_datetime_t *datetime) { assert(datetime); uint32_t x; uint32_t secondsRemaining, days; uint16_t daysInYear; /* Table of days in a month for a non leap year. First entry in the table is not used, * valid months start from 1 */ uint8_t daysPerMonth[] = {0U, 31U, 28U, 31U, 30U, 31U, 30U, 31U, 31U, 30U, 31U, 30U, 31U}; /* Start with the seconds value that is passed in to be converted to date time format */ secondsRemaining = seconds; /* Calcuate the number of days, we add 1 for the current day which is represented in the * hours and seconds field */ days = secondsRemaining / SECONDS_IN_A_DAY + 1; /* Update seconds left*/ secondsRemaining = secondsRemaining % SECONDS_IN_A_DAY; /* Calculate the datetime hour, minute and second fields */ datetime->hour = secondsRemaining / SECONDS_IN_A_HOUR; secondsRemaining = secondsRemaining % SECONDS_IN_A_HOUR; datetime->minute = secondsRemaining / 60U; datetime->second = secondsRemaining % SECONDS_IN_A_MINUTE; /* Calculate year */ daysInYear = DAYS_IN_A_YEAR; datetime->year = YEAR_RANGE_START; while (days > daysInYear) { /* Decrease day count by a year and increment year by 1 */ days -= daysInYear; datetime->year++; /* Adjust the number of days for a leap year */ if (datetime->year & 3U) { daysInYear = DAYS_IN_A_YEAR; } else { daysInYear = DAYS_IN_A_YEAR + 1; } } /* Adjust the days in February for a leap year */ if (!(datetime->year & 3U)) { daysPerMonth[2] = 29U; } for (x = 1U; x <= 12U; x++) { if (days <= daysPerMonth[x]) { datetime->month = x; break; } else { days -= daysPerMonth[x]; } } datetime->day = days; } void RTC_Init(RTC_Type *base, const rtc_config_t *config) { assert(config); uint32_t reg; #if defined(RTC_CLOCKS) #if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) CLOCK_EnableClock(kCLOCK_Rtc0); #endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */ #endif /* RTC_CLOCKS */ /* Issue a software reset if timer is invalid */ if (RTC_GetStatusFlags(RTC) & kRTC_TimeInvalidFlag) { RTC_Reset(RTC); } reg = base->CR; /* Setup the update mode and supervisor access mode */ reg &= ~(RTC_CR_UM_MASK | RTC_CR_SUP_MASK); reg |= RTC_CR_UM(config->updateMode) | RTC_CR_SUP(config->supervisorAccess); #if defined(FSL_FEATURE_RTC_HAS_WAKEUP_PIN_SELECTION) && FSL_FEATURE_RTC_HAS_WAKEUP_PIN_SELECTION /* Setup the wakeup pin select */ reg &= ~(RTC_CR_WPS_MASK); reg |= RTC_CR_WPS(config->wakeupSelect); #endif /* FSL_FEATURE_RTC_HAS_WAKEUP_PIN */ base->CR = reg; /* Configure the RTC time compensation register */ base->TCR = (RTC_TCR_CIR(config->compensationInterval) | RTC_TCR_TCR(config->compensationTime)); #if defined(FSL_FEATURE_RTC_HAS_TSIC) && FSL_FEATURE_RTC_HAS_TSIC /* Configure RTC timer seconds interrupt to be generated once per second */ base->IER &= ~(RTC_IER_TSIC_MASK | RTC_IER_TSIE_MASK); #endif } void RTC_GetDefaultConfig(rtc_config_t *config) { assert(config); /* Wakeup pin will assert if the RTC interrupt asserts or if the wakeup pin is turned on */ config->wakeupSelect = false; /* Registers cannot be written when locked */ config->updateMode = false; /* Non-supervisor mode write accesses are not supported and will generate a bus error */ config->supervisorAccess = false; /* Compensation interval used by the crystal compensation logic */ config->compensationInterval = 0; /* Compensation time used by the crystal compensation logic */ config->compensationTime = 0; } status_t RTC_SetDatetime(RTC_Type *base, const rtc_datetime_t *datetime) { assert(datetime); /* Return error if the time provided is not valid */ if (!(RTC_CheckDatetimeFormat(datetime))) { return kStatus_InvalidArgument; } /* Set time in seconds */ base->TSR = RTC_ConvertDatetimeToSeconds(datetime); return kStatus_Success; } void RTC_GetDatetime(RTC_Type *base, rtc_datetime_t *datetime) { assert(datetime); uint32_t seconds = 0; seconds = base->TSR; RTC_ConvertSecondsToDatetime(seconds, datetime); } status_t RTC_SetAlarm(RTC_Type *base, const rtc_datetime_t *alarmTime) { assert(alarmTime); uint32_t alarmSeconds = 0; uint32_t currSeconds = 0; /* Return error if the alarm time provided is not valid */ if (!(RTC_CheckDatetimeFormat(alarmTime))) { return kStatus_InvalidArgument; } alarmSeconds = RTC_ConvertDatetimeToSeconds(alarmTime); /* Get the current time */ currSeconds = base->TSR; /* Return error if the alarm time has passed */ if (alarmSeconds < currSeconds) { return kStatus_Fail; } /* Set alarm in seconds*/ base->TAR = alarmSeconds; return kStatus_Success; } void RTC_GetAlarm(RTC_Type *base, rtc_datetime_t *datetime) { assert(datetime); uint32_t alarmSeconds = 0; /* Get alarm in seconds */ alarmSeconds = base->TAR; RTC_ConvertSecondsToDatetime(alarmSeconds, datetime); } void RTC_EnableInterrupts(RTC_Type *base, uint32_t mask) { uint32_t tmp32 = 0U; /* RTC_IER */ if (kRTC_TimeInvalidInterruptEnable == (kRTC_TimeInvalidInterruptEnable & mask)) { tmp32 |= RTC_IER_TIIE_MASK; } if (kRTC_TimeOverflowInterruptEnable == (kRTC_TimeOverflowInterruptEnable & mask)) { tmp32 |= RTC_IER_TOIE_MASK; } if (kRTC_AlarmInterruptEnable == (kRTC_AlarmInterruptEnable & mask)) { tmp32 |= RTC_IER_TAIE_MASK; } if (kRTC_SecondsInterruptEnable == (kRTC_SecondsInterruptEnable & mask)) { tmp32 |= RTC_IER_TSIE_MASK; } #if defined(FSL_FEATURE_RTC_HAS_MONOTONIC) && (FSL_FEATURE_RTC_HAS_MONOTONIC) if (kRTC_MonotonicOverflowInterruptEnable == (kRTC_MonotonicOverflowInterruptEnable & mask)) { tmp32 |= RTC_IER_MOIE_MASK; } #endif /* FSL_FEATURE_RTC_HAS_MONOTONIC */ base->IER |= tmp32; #if (defined(FSL_FEATURE_RTC_HAS_TIR) && FSL_FEATURE_RTC_HAS_TIR) tmp32 = 0U; /* RTC_TIR */ if (kRTC_TestModeInterruptEnable == (kRTC_TestModeInterruptEnable & mask)) { tmp32 |= RTC_TIR_TMIE_MASK; } if (kRTC_FlashSecurityInterruptEnable == (kRTC_FlashSecurityInterruptEnable & mask)) { tmp32 |= RTC_TIR_FSIE_MASK; } #if (defined(FSL_FEATURE_RTC_HAS_TIR_TPIE) && FSL_FEATURE_RTC_HAS_TIR_TPIE) if (kRTC_TamperPinInterruptEnable == (kRTC_TamperPinInterruptEnable & mask)) { tmp32 |= RTC_TIR_TPIE_MASK; } #endif /* FSL_FEATURE_RTC_HAS_TIR_TPIE */ #if (defined(FSL_FEATURE_RTC_HAS_TIR_SIE) && FSL_FEATURE_RTC_HAS_TIR_SIE) if (kRTC_SecurityModuleInterruptEnable == (kRTC_SecurityModuleInterruptEnable & mask)) { tmp32 |= RTC_TIR_SIE_MASK; } #endif /* FSL_FEATURE_RTC_HAS_TIR_SIE */ #if (defined(FSL_FEATURE_RTC_HAS_TIR_LCIE) && FSL_FEATURE_RTC_HAS_TIR_LCIE) if (kRTC_LossOfClockInterruptEnable == (kRTC_LossOfClockInterruptEnable & mask)) { tmp32 |= RTC_TIR_LCIE_MASK; } #endif /* FSL_FEATURE_RTC_HAS_TIR_LCIE */ base->TIR |= tmp32; #endif /* FSL_FEATURE_RTC_HAS_TIR */ } void RTC_DisableInterrupts(RTC_Type *base, uint32_t mask) { uint32_t tmp32 = 0U; /* RTC_IER */ if (kRTC_TimeInvalidInterruptEnable == (kRTC_TimeInvalidInterruptEnable & mask)) { tmp32 |= RTC_IER_TIIE_MASK; } if (kRTC_TimeOverflowInterruptEnable == (kRTC_TimeOverflowInterruptEnable & mask)) { tmp32 |= RTC_IER_TOIE_MASK; } if (kRTC_AlarmInterruptEnable == (kRTC_AlarmInterruptEnable & mask)) { tmp32 |= RTC_IER_TAIE_MASK; } if (kRTC_SecondsInterruptEnable == (kRTC_SecondsInterruptEnable & mask)) { tmp32 |= RTC_IER_TSIE_MASK; } #if defined(FSL_FEATURE_RTC_HAS_MONOTONIC) && (FSL_FEATURE_RTC_HAS_MONOTONIC) if (kRTC_MonotonicOverflowInterruptEnable == (kRTC_MonotonicOverflowInterruptEnable & mask)) { tmp32 |= RTC_IER_MOIE_MASK; } #endif /* FSL_FEATURE_RTC_HAS_MONOTONIC */ base->IER &= (uint32_t)(~tmp32); #if (defined(FSL_FEATURE_RTC_HAS_TIR) && FSL_FEATURE_RTC_HAS_TIR) tmp32 = 0U; /* RTC_TIR */ if (kRTC_TestModeInterruptEnable == (kRTC_TestModeInterruptEnable & mask)) { tmp32 |= RTC_TIR_TMIE_MASK; } if (kRTC_FlashSecurityInterruptEnable == (kRTC_FlashSecurityInterruptEnable & mask)) { tmp32 |= RTC_TIR_FSIE_MASK; } #if (defined(FSL_FEATURE_RTC_HAS_TIR_TPIE) && FSL_FEATURE_RTC_HAS_TIR_TPIE) if (kRTC_TamperPinInterruptEnable == (kRTC_TamperPinInterruptEnable & mask)) { tmp32 |= RTC_TIR_TPIE_MASK; } #endif /* FSL_FEATURE_RTC_HAS_TIR_TPIE */ #if (defined(FSL_FEATURE_RTC_HAS_TIR_SIE) && FSL_FEATURE_RTC_HAS_TIR_SIE) if (kRTC_SecurityModuleInterruptEnable == (kRTC_SecurityModuleInterruptEnable & mask)) { tmp32 |= RTC_TIR_SIE_MASK; } #endif /* FSL_FEATURE_RTC_HAS_TIR_SIE */ #if (defined(FSL_FEATURE_RTC_HAS_TIR_LCIE) && FSL_FEATURE_RTC_HAS_TIR_LCIE) if (kRTC_LossOfClockInterruptEnable == (kRTC_LossOfClockInterruptEnable & mask)) { tmp32 |= RTC_TIR_LCIE_MASK; } #endif /* FSL_FEATURE_RTC_HAS_TIR_LCIE */ base->TIR &= (uint32_t)(~tmp32); #endif /* FSL_FEATURE_RTC_HAS_TIR */ } uint32_t RTC_GetEnabledInterrupts(RTC_Type *base) { uint32_t tmp32 = 0U; /* RTC_IER */ if (RTC_IER_TIIE_MASK == (RTC_IER_TIIE_MASK & base->IER)) { tmp32 |= kRTC_TimeInvalidInterruptEnable; } if (RTC_IER_TOIE_MASK == (RTC_IER_TOIE_MASK & base->IER)) { tmp32 |= kRTC_TimeOverflowInterruptEnable; } if (RTC_IER_TAIE_MASK == (RTC_IER_TAIE_MASK & base->IER)) { tmp32 |= kRTC_AlarmInterruptEnable; } if (RTC_IER_TSIE_MASK == (RTC_IER_TSIE_MASK & base->IER)) { tmp32 |= kRTC_SecondsInterruptEnable; } #if defined(FSL_FEATURE_RTC_HAS_MONOTONIC) && (FSL_FEATURE_RTC_HAS_MONOTONIC) if (RTC_IER_MOIE_MASK == (RTC_IER_MOIE_MASK & base->IER)) { tmp32 |= kRTC_MonotonicOverflowInterruptEnable; } #endif /* FSL_FEATURE_RTC_HAS_MONOTONIC */ #if (defined(FSL_FEATURE_RTC_HAS_TIR) && FSL_FEATURE_RTC_HAS_TIR) /* RTC_TIR */ if (RTC_TIR_TMIE_MASK == (RTC_TIR_TMIE_MASK & base->TIR)) { tmp32 |= kRTC_TestModeInterruptEnable; } if (RTC_TIR_FSIE_MASK == (RTC_TIR_FSIE_MASK & base->TIR)) { tmp32 |= kRTC_FlashSecurityInterruptEnable; } #if (defined(FSL_FEATURE_RTC_HAS_TIR_TPIE) && FSL_FEATURE_RTC_HAS_TIR_TPIE) if (RTC_TIR_TPIE_MASK == (RTC_TIR_TPIE_MASK & base->TIR)) { tmp32 |= kRTC_TamperPinInterruptEnable; } #endif /* FSL_FEATURE_RTC_HAS_TIR_TPIE */ #if (defined(FSL_FEATURE_RTC_HAS_TIR_SIE) && FSL_FEATURE_RTC_HAS_TIR_SIE) if (RTC_TIR_SIE_MASK == (RTC_TIR_SIE_MASK & base->TIR)) { tmp32 |= kRTC_SecurityModuleInterruptEnable; } #endif /* FSL_FEATURE_RTC_HAS_TIR_SIE */ #if (defined(FSL_FEATURE_RTC_HAS_TIR_LCIE) && FSL_FEATURE_RTC_HAS_TIR_LCIE) if (RTC_TIR_LCIE_MASK == (RTC_TIR_LCIE_MASK & base->TIR)) { tmp32 |= kRTC_LossOfClockInterruptEnable; } #endif /* FSL_FEATURE_RTC_HAS_TIR_LCIE */ #endif /* FSL_FEATURE_RTC_HAS_TIR */ return tmp32; } uint32_t RTC_GetStatusFlags(RTC_Type *base) { uint32_t tmp32 = 0U; /* RTC_SR */ if (RTC_SR_TIF_MASK == (RTC_SR_TIF_MASK & base->SR)) { tmp32 |= kRTC_TimeInvalidFlag; } if (RTC_SR_TOF_MASK == (RTC_SR_TOF_MASK & base->SR)) { tmp32 |= kRTC_TimeOverflowFlag; } if (RTC_SR_TAF_MASK == (RTC_SR_TAF_MASK & base->SR)) { tmp32 |= kRTC_AlarmFlag; } #if defined(FSL_FEATURE_RTC_HAS_MONOTONIC) && (FSL_FEATURE_RTC_HAS_MONOTONIC) if (RTC_SR_MOF_MASK == (RTC_SR_MOF_MASK & base->SR)) { tmp32 |= kRTC_MonotonicOverflowFlag; } #endif /* FSL_FEATURE_RTC_HAS_MONOTONIC */ #if (defined(FSL_FEATURE_RTC_HAS_SR_TIDF) && FSL_FEATURE_RTC_HAS_SR_TIDF) if (RTC_SR_TIDF_MASK == (RTC_SR_TIDF_MASK & base->SR)) { tmp32 |= kRTC_TamperInterruptDetectFlag; } #endif /* FSL_FEATURE_RTC_HAS_SR_TIDF */ #if (defined(FSL_FEATURE_RTC_HAS_TDR) && FSL_FEATURE_RTC_HAS_TDR) /* RTC_TDR */ if (RTC_TDR_TMF_MASK == (RTC_TDR_TMF_MASK & base->TDR)) { tmp32 |= kRTC_TestModeFlag; } if (RTC_TDR_FSF_MASK == (RTC_TDR_FSF_MASK & base->TDR)) { tmp32 |= kRTC_FlashSecurityFlag; } #if (defined(FSL_FEATURE_RTC_HAS_TDR_TPF) && FSL_FEATURE_RTC_HAS_TDR_TPF) if (RTC_TDR_TPF_MASK == (RTC_TDR_TPF_MASK & base->TDR)) { tmp32 |= kRTC_TamperPinFlag; } #endif /* FSL_FEATURE_RTC_HAS_TDR_TPF */ #if (defined(FSL_FEATURE_RTC_HAS_TDR_STF) && FSL_FEATURE_RTC_HAS_TDR_STF) if (RTC_TDR_STF_MASK == (RTC_TDR_STF_MASK & base->TDR)) { tmp32 |= kRTC_SecurityTamperFlag; } #endif /* FSL_FEATURE_RTC_HAS_TDR_STF */ #if (defined(FSL_FEATURE_RTC_HAS_TDR_LCTF) && FSL_FEATURE_RTC_HAS_TDR_LCTF) if (RTC_TDR_LCTF_MASK == (RTC_TDR_LCTF_MASK & base->TDR)) { tmp32 |= kRTC_LossOfClockTamperFlag; } #endif /* FSL_FEATURE_RTC_HAS_TDR_LCTF */ #endif /* FSL_FEATURE_RTC_HAS_TDR */ return tmp32; } void RTC_ClearStatusFlags(RTC_Type *base, uint32_t mask) { /* The alarm flag is cleared by writing to the TAR register */ if (mask & kRTC_AlarmFlag) { base->TAR = 0U; } /* The timer overflow flag is cleared by initializing the TSR register. * The time counter should be disabled for this write to be successful */ if (mask & kRTC_TimeOverflowFlag) { base->TSR = 1U; } /* The timer overflow flag is cleared by initializing the TSR register. * The time counter should be disabled for this write to be successful */ if (mask & kRTC_TimeInvalidFlag) { base->TSR = 1U; } #if (defined(FSL_FEATURE_RTC_HAS_TDR) && FSL_FEATURE_RTC_HAS_TDR) /* To clear, write logic one to this flag after exiting from all test modes */ if (kRTC_TestModeFlag == (kRTC_TestModeFlag & mask)) { base->TDR = RTC_TDR_TMF_MASK; } /* To clear, write logic one to this flag after flash security is enabled */ if (kRTC_FlashSecurityFlag == (kRTC_FlashSecurityFlag & mask)) { base->TDR = RTC_TDR_FSF_MASK; } #if (defined(FSL_FEATURE_RTC_HAS_TDR_TPF) && FSL_FEATURE_RTC_HAS_TDR_TPF) /* To clear, write logic one to the corresponding flag after that tamper pin negates */ if (kRTC_TamperPinFlag == (kRTC_TamperPinFlag & mask)) { base->TDR = RTC_TDR_TPF_MASK; } #endif /* FSL_FEATURE_RTC_HAS_TDR_TPF */ #if (defined(FSL_FEATURE_RTC_HAS_TDR_STF) && FSL_FEATURE_RTC_HAS_TDR_STF) /* To clear, write logic one to this flag after security module has negated its tamper detect */ if (kRTC_SecurityTamperFlag == (kRTC_SecurityTamperFlag & mask)) { base->TDR = RTC_TDR_STF_MASK; } #endif /* FSL_FEATURE_RTC_HAS_TDR_STF */ #if (defined(FSL_FEATURE_RTC_HAS_TDR_LCTF) && FSL_FEATURE_RTC_HAS_TDR_LCTF) /* To clear, write logic one to this flag after loss of clock negates */ if (kRTC_LossOfClockTamperFlag == (kRTC_LossOfClockTamperFlag & mask)) { base->TDR = RTC_TDR_LCTF_MASK; } #endif /* FSL_FEATURE_RTC_HAS_TDR_LCTF */ #endif /* FSL_FEATURE_RTC_HAS_TDR */ } #if defined(FSL_FEATURE_RTC_HAS_MONOTONIC) && (FSL_FEATURE_RTC_HAS_MONOTONIC) void RTC_GetMonotonicCounter(RTC_Type *base, uint64_t *counter) { assert(counter); *counter = (((uint64_t)base->MCHR << 32) | ((uint64_t)base->MCLR)); } void RTC_SetMonotonicCounter(RTC_Type *base, uint64_t counter) { /* Prepare to initialize the register with the new value written */ base->MER &= ~RTC_MER_MCE_MASK; base->MCHR = (uint32_t)((counter) >> 32); base->MCLR = (uint32_t)(counter); } status_t RTC_IncrementMonotonicCounter(RTC_Type *base) { if (base->SR & (RTC_SR_MOF_MASK | RTC_SR_TIF_MASK)) { return kStatus_Fail; } /* Prepare to switch to increment mode */ base->MER |= RTC_MER_MCE_MASK; /* Write anything so the counter increments*/ base->MCLR = 1U; return kStatus_Success; } #endif /* FSL_FEATURE_RTC_HAS_MONOTONIC */