drivers/rtc/rtc_ll_stm32.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2023 Prevas A/S
  * Copyright (c) 2023 Syslinbit
  *
  * SPDX-License-Identifier: Apache-2.0
  *
  */

 #define DT_DRV_COMPAT st_stm32_rtc

 #include <errno.h>
 #include <zephyr/device.h>
 #include <zephyr/kernel.h>
 #include <zephyr/init.h>
 #include <zephyr/devicetree.h>
 #include <zephyr/drivers/rtc.h>
 #include <zephyr/drivers/clock_control/stm32_clock_control.h>
 #include <zephyr/drivers/clock_control.h>
 #include <zephyr/sys/util.h>
 #include <soc.h>
 #include <stm32_ll_pwr.h>
 #include <stm32_ll_rcc.h>
 #include <stm32_ll_rtc.h>
 #include <stm32_hsem.h>

 #include <zephyr/logging/log.h>

 #include <stdbool.h>

 LOG_MODULE_REGISTER(rtc_stm32, CONFIG_RTC_LOG_LEVEL);

 #if defined(CONFIG_SOC_SERIES_STM32L1X) && !defined(RTC_SUBSECOND_SUPPORT)
 /* subsecond counting is not supported by some STM32L1x MCUs */
 #define HW_SUBSECOND_SUPPORT (0)
 #else
 #define HW_SUBSECOND_SUPPORT (1)
 #endif

 /* RTC start time: 1st, Jan, 2000 */
 #define RTC_YEAR_REF 2000
 /* struct tm start time:   1st, Jan, 1900 */
 #define TM_YEAR_REF 1900

 /* Convert part per billion calibration value to a number of clock pulses added or removed each
  * 2^20 clock cycles so it is suitable for the CALR register fields
  *
  * nb_pulses = ppb * 2^20 / 10^9 = ppb * 2^11 / 5^9 = ppb * 2048 / 1953125
  */
 #define PPB_TO_NB_PULSES(ppb) DIV_ROUND_CLOSEST((ppb) * 2048, 1953125)

 /* Convert CALR register value (number of clock pulses added or removed each 2^20 clock cycles)
  * to part ber billion calibration value
  *
  * ppb = nb_pulses * 10^9 / 2^20 = nb_pulses * 5^9 / 2^11 = nb_pulses * 1953125 / 2048
  */
 #define NB_PULSES_TO_PPB(pulses) DIV_ROUND_CLOSEST((pulses) * 1953125, 2048)

 /* CALP field can only be 512 or 0 as in reality CALP is a single bit field representing 512 pulses
  * added every 2^20 clock cycles
  */
 #define MAX_CALP (512)
 #define MAX_CALM (511)

 #define MAX_PPB NB_PULSES_TO_PPB(MAX_CALP)
 #define MIN_PPB -NB_PULSES_TO_PPB(MAX_CALM)

 /* Timeout in microseconds used to wait for flags */
 #define RTC_TIMEOUT 1000000

 struct rtc_stm32_config {
 	uint32_t async_prescaler;
 	uint32_t sync_prescaler;
 	const struct stm32_pclken *pclken;
 };

 struct rtc_stm32_data {
 	struct k_mutex lock;
 };

 static int rtc_stm32_enter_initialization_mode(bool kernel_available)
 {
 	if (kernel_available) {
 		LL_RTC_EnableInitMode(RTC);
 		bool success = WAIT_FOR(LL_RTC_IsActiveFlag_INIT(RTC), RTC_TIMEOUT, k_msleep(1));

 		if (!success) {
 			return -EIO;
 		}
 	} else {
 		/* kernel is not available so use the blocking but otherwise equivalent function
 		 * provided by LL
 		 */
 		ErrorStatus status = LL_RTC_EnterInitMode(RTC);

 		if (status != SUCCESS) {
 			return -EIO;
 		}
 	}

 	return 0;
 }

 static inline void rtc_stm32_leave_initialization_mode(void)
 {
 	LL_RTC_DisableInitMode(RTC);
 }

 static int rtc_stm32_configure(const struct device *dev)
 {
 	const struct rtc_stm32_config *cfg = dev->config;

 	int err = 0;

 	uint32_t hour_format     = LL_RTC_GetHourFormat(RTC);
 	uint32_t sync_prescaler  = LL_RTC_GetSynchPrescaler(RTC);
 	uint32_t async_prescaler = LL_RTC_GetAsynchPrescaler(RTC);

 	LL_RTC_DisableWriteProtection(RTC);

 	/* configuration process requires to stop the RTC counter so do it
 	 * only if needed to avoid inducing time drift at each reset
 	 */
 	if ((hour_format != LL_RTC_HOURFORMAT_24HOUR) ||
 	    (sync_prescaler != cfg->sync_prescaler) ||
 	    (async_prescaler != cfg->async_prescaler)) {
 		err = rtc_stm32_enter_initialization_mode(false);
 		if (err == 0) {
 			LL_RTC_SetHourFormat(RTC, LL_RTC_HOURFORMAT_24HOUR);
 			LL_RTC_SetSynchPrescaler(RTC, cfg->sync_prescaler);
 			LL_RTC_SetAsynchPrescaler(RTC, cfg->async_prescaler);
 		}

 		rtc_stm32_leave_initialization_mode();
 	}

 #ifdef RTC_CR_BYPSHAD
 	LL_RTC_EnableShadowRegBypass(RTC);
 #endif /* RTC_CR_BYPSHAD */

 	LL_RTC_EnableWriteProtection(RTC);

 	return err;
 }

 static int rtc_stm32_init(const struct device *dev)
 {
 	const struct device *const clk = DEVICE_DT_GET(STM32_CLOCK_CONTROL_NODE);
 	const struct rtc_stm32_config *cfg = dev->config;
 	struct rtc_stm32_data *data = dev->data;

 	int err = 0;

 	if (!device_is_ready(clk)) {
 		LOG_ERR("clock control device not ready");
 		return -ENODEV;
 	}

 	/* Enable RTC bus clock */
 	if (clock_control_on(clk, (clock_control_subsys_t)&cfg->pclken[0]) != 0) {
 		LOG_ERR("clock op failed\n");
 		return -EIO;
 	}

 	k_mutex_init(&data->lock);

 	/* Enable Backup access */
 	z_stm32_hsem_lock(CFG_HW_RCC_SEMID, HSEM_LOCK_DEFAULT_RETRY);
 #if defined(PWR_CR_DBP) || defined(PWR_CR1_DBP) || defined(PWR_DBPCR_DBP) || defined(PWR_DBPR_DBP)
 	LL_PWR_EnableBkUpAccess();
 #endif /* PWR_CR_DBP || PWR_CR1_DBP || PWR_DBPR_DBP */

 	/* Enable RTC clock source */
 	if (clock_control_configure(clk, (clock_control_subsys_t)&cfg->pclken[1], NULL) != 0) {
 		LOG_ERR("clock configure failed\n");
 		return -EIO;
 	}

 	LL_RCC_EnableRTC();

 	z_stm32_hsem_unlock(CFG_HW_RCC_SEMID);

 	err = rtc_stm32_configure(dev);

 	return err;
 }

 static int rtc_stm32_set_time(const struct device *dev, const struct rtc_time *timeptr)
 {
 	struct rtc_stm32_data *data = dev->data;

 	uint32_t real_year = timeptr->tm_year + TM_YEAR_REF;

 	int err = 0;

 	if (real_year < RTC_YEAR_REF) {
 		/* RTC does not support years before 2000 */
 		return -EINVAL;
 	}

 	if (timeptr->tm_wday == -1) {
 		/* day of the week is expected */
 		return -EINVAL;
 	}

 	err = k_mutex_lock(&data->lock, K_NO_WAIT);
 	if (err) {
 		return err;
 	}

 	LOG_INF("Setting clock");
 	LL_RTC_DisableWriteProtection(RTC);

 	err = rtc_stm32_enter_initialization_mode(true);
 	if (err) {
 		k_mutex_unlock(&data->lock);
 		return err;
 	}

 	LL_RTC_DATE_SetYear(RTC, bin2bcd(real_year - RTC_YEAR_REF));
 	LL_RTC_DATE_SetMonth(RTC, bin2bcd(timeptr->tm_mon + 1));
 	LL_RTC_DATE_SetDay(RTC, bin2bcd(timeptr->tm_mday));

 	if (timeptr->tm_wday == 0) {
 		/* sunday (tm_wday = 0) is not represented by the same value in hardware */
 		LL_RTC_DATE_SetWeekDay(RTC, LL_RTC_WEEKDAY_SUNDAY);
 	} else {
 		/* all the other values are consistent with what is expected by hardware */
 		LL_RTC_DATE_SetWeekDay(RTC, timeptr->tm_wday);
 	}


 	LL_RTC_TIME_SetHour(RTC, bin2bcd(timeptr->tm_hour));
 	LL_RTC_TIME_SetMinute(RTC, bin2bcd(timeptr->tm_min));
 	LL_RTC_TIME_SetSecond(RTC, bin2bcd(timeptr->tm_sec));

 	rtc_stm32_leave_initialization_mode();

 	LL_RTC_EnableWriteProtection(RTC);

 	k_mutex_unlock(&data->lock);

 	return err;
 }

 static int rtc_stm32_get_time(const struct device *dev, struct rtc_time *timeptr)
 {
 	struct rtc_stm32_data *data = dev->data;

 	uint32_t rtc_date, rtc_time;

 #if HW_SUBSECOND_SUPPORT
 	const struct rtc_stm32_config *cfg = dev->config;
 	uint32_t rtc_subsecond;
 #endif

 	int err = k_mutex_lock(&data->lock, K_NO_WAIT);

 	if (err) {
 		return err;
 	}

 	do {
 		/* read date, time and subseconds and relaunch if a day increment occurred
 		 * while doing so as it will result in an erroneous result otherwise
 		 */
 		rtc_date = LL_RTC_DATE_Get(RTC);
 		do {
 			/* read time and subseconds and relaunch if a second increment occurred
 			 * while doing so as it will result in an erroneous result otherwise
 			 */
 			rtc_time      = LL_RTC_TIME_Get(RTC);
 #if HW_SUBSECOND_SUPPORT
 			rtc_subsecond = LL_RTC_TIME_GetSubSecond(RTC);
 #endif
 		} while (rtc_time != LL_RTC_TIME_Get(RTC));
 	} while (rtc_date != LL_RTC_DATE_Get(RTC));

 	k_mutex_unlock(&data->lock);

 	timeptr->tm_year = bcd2bin(__LL_RTC_GET_YEAR(rtc_date)) + RTC_YEAR_REF - TM_YEAR_REF;
 	/* tm_mon allowed values are 0-11 */
 	timeptr->tm_mon = bcd2bin(__LL_RTC_GET_MONTH(rtc_date)) - 1;
 	timeptr->tm_mday = bcd2bin(__LL_RTC_GET_DAY(rtc_date));

 	int hw_wday = __LL_RTC_GET_WEEKDAY(rtc_date);

 	if (hw_wday == LL_RTC_WEEKDAY_SUNDAY) {
 		/* LL_RTC_WEEKDAY_SUNDAY = 7 but a 0 is expected in tm_wday for sunday */
 		timeptr->tm_wday = 0;
 	} else {
 		/* all other values are consistent between hardware and rtc_time structure */
 		timeptr->tm_wday = hw_wday;
 	}

 	timeptr->tm_hour = bcd2bin(__LL_RTC_GET_HOUR(rtc_time));
 	timeptr->tm_min = bcd2bin(__LL_RTC_GET_MINUTE(rtc_time));
 	timeptr->tm_sec = bcd2bin(__LL_RTC_GET_SECOND(rtc_time));

 #if HW_SUBSECOND_SUPPORT
 	uint64_t temp = ((uint64_t)(cfg->sync_prescaler - rtc_subsecond)) * 1000000000L;

 	timeptr->tm_nsec = DIV_ROUND_CLOSEST(temp, cfg->sync_prescaler + 1);
 #else
 	timeptr->tm_nsec = 0;
 #endif

 	/* unknown values */
 	timeptr->tm_yday  = -1;
 	timeptr->tm_isdst = -1;

 	return 0;
 }

 #ifdef CONFIG_RTC_CALIBRATION
 #if !defined(CONFIG_SOC_SERIES_STM32F2X) && \
 	!(defined(CONFIG_SOC_SERIES_STM32L1X) && !defined(RTC_SMOOTHCALIB_SUPPORT))
 static int rtc_stm32_set_calibration(const struct device *dev, int32_t calibration)
 {
 	ARG_UNUSED(dev);

 	/* Note : calibration is considered here to be ppb value to apply
 	 *        on clock period (not frequency) but with an opposite sign
 	 */

 	if ((calibration > MAX_PPB) || (calibration < MIN_PPB)) {
 		/* out of supported range */
 		return -EINVAL;
 	}

 	int32_t nb_pulses = PPB_TO_NB_PULSES(calibration);

 	/* we tested calibration against supported range
 	 * so theoretically nb_pulses is also within range
 	 */
 	__ASSERT_NO_MSG(nb_pulses <= MAX_CALP);
 	__ASSERT_NO_MSG(nb_pulses >= -MAX_CALM);

 	uint32_t calp, calm;

 	if (nb_pulses > 0) {
 		calp = LL_RTC_CALIB_INSERTPULSE_SET;
 		calm = MAX_CALP - nb_pulses;
 	} else {
 		calp = LL_RTC_CALIB_INSERTPULSE_NONE;
 		calm = -nb_pulses;
 	}

 	/* wait for recalibration to be ok if a previous recalibration occurred */
 	if (!WAIT_FOR(LL_RTC_IsActiveFlag_RECALP(RTC) == 0, 100000, k_msleep(1))) {
 		return -EIO;
 	}

 	LL_RTC_DisableWriteProtection(RTC);

 	MODIFY_REG(RTC->CALR, RTC_CALR_CALP | RTC_CALR_CALM, calp | calm);

 	LL_RTC_EnableWriteProtection(RTC);

 	return 0;
 }

 static int rtc_stm32_get_calibration(const struct device *dev, int32_t *calibration)
 {
 	ARG_UNUSED(dev);

 	uint32_t calr = sys_read32((mem_addr_t) &RTC->CALR);

 	bool calp_enabled = READ_BIT(calr, RTC_CALR_CALP);
 	uint32_t calm = READ_BIT(calr, RTC_CALR_CALM);

 	int32_t nb_pulses = -((int32_t) calm);

 	if (calp_enabled) {
 		nb_pulses += MAX_CALP;
 	}

 	*calibration = NB_PULSES_TO_PPB(nb_pulses);

 	return 0;
 }
 #endif
 #endif /* CONFIG_RTC_CALIBRATION */

 struct rtc_driver_api rtc_stm32_driver_api = {
 	.set_time = rtc_stm32_set_time,
 	.get_time = rtc_stm32_get_time,
 	/* RTC_ALARM not supported */
 	/* RTC_UPDATE not supported */
 #ifdef CONFIG_RTC_CALIBRATION
 #if !defined(CONFIG_SOC_SERIES_STM32F2X) && \
 	!(defined(CONFIG_SOC_SERIES_STM32L1X) && !defined(RTC_SMOOTHCALIB_SUPPORT))
 	.set_calibration = rtc_stm32_set_calibration,
 	.get_calibration = rtc_stm32_get_calibration,
 #else
 #error RTC calibration for devices without smooth calibration feature is not supported yet
 #endif
 #endif /* CONFIG_RTC_CALIBRATION */
 };

 static const struct stm32_pclken rtc_clk[] = STM32_DT_INST_CLOCKS(0);

 BUILD_ASSERT(DT_INST_CLOCKS_HAS_IDX(0, 1), "RTC source clock not defined in the device tree");

 static const struct rtc_stm32_config rtc_config = {
 #if DT_INST_CLOCKS_CELL_BY_IDX(0, 1, bus) == STM32_SRC_LSI
 	/* prescaler values for LSI @ 32 KHz */
 	.async_prescaler = 0x7F,
 	.sync_prescaler = 0x00F9,
 #else /* DT_INST_CLOCKS_CELL_BY_IDX(0, 1, bus) == STM32_SRC_LSE */
 	/* prescaler values for LSE @ 32768 Hz */
 	.async_prescaler = 0x7F,
 	.sync_prescaler = 0x00FF,
 #endif
 	.pclken = rtc_clk,
 };

 static struct rtc_stm32_data rtc_data;

 DEVICE_DT_INST_DEFINE(0, &rtc_stm32_init, NULL, &rtc_data, &rtc_config, PRE_KERNEL_1,
 		      CONFIG_RTC_INIT_PRIORITY, &rtc_stm32_driver_api);
	/*
	* Copyright (c) 2023 Prevas A/S
	* Copyright (c) 2023 Syslinbit
	*
	* SPDX-License-Identifier: Apache-2.0
	*
	*/

	#define DT_DRV_COMPAT st_stm32_rtc

	#include <errno.h>
	#include <zephyr/device.h>
	#include <zephyr/kernel.h>
	#include <zephyr/init.h>
	#include <zephyr/devicetree.h>
	#include <zephyr/drivers/rtc.h>
	#include <zephyr/drivers/clock_control/stm32_clock_control.h>
	#include <zephyr/drivers/clock_control.h>
	#include <zephyr/sys/util.h>
	#include <soc.h>
	#include <stm32_ll_pwr.h>
	#include <stm32_ll_rcc.h>
	#include <stm32_ll_rtc.h>
	#include <stm32_hsem.h>

	#include <zephyr/logging/log.h>

	#include <stdbool.h>

	LOG_MODULE_REGISTER(rtc_stm32, CONFIG_RTC_LOG_LEVEL);

	#if defined(CONFIG_SOC_SERIES_STM32L1X) && !defined(RTC_SUBSECOND_SUPPORT)
	/* subsecond counting is not supported by some STM32L1x MCUs */
	#define HW_SUBSECOND_SUPPORT (0)
	#else
	#define HW_SUBSECOND_SUPPORT (1)
	#endif

	/* RTC start time: 1st, Jan, 2000 */
	#define RTC_YEAR_REF 2000
	/* struct tm start time: 1st, Jan, 1900 */
	#define TM_YEAR_REF 1900

	/* Convert part per billion calibration value to a number of clock pulses added or removed each
	* 2^20 clock cycles so it is suitable for the CALR register fields
	*
	* nb_pulses = ppb * 2^20 / 10^9 = ppb * 2^11 / 5^9 = ppb * 2048 / 1953125
	*/
	#define PPB_TO_NB_PULSES(ppb) DIV_ROUND_CLOSEST((ppb) * 2048, 1953125)

	/* Convert CALR register value (number of clock pulses added or removed each 2^20 clock cycles)
	* to part ber billion calibration value
	*
	* ppb = nb_pulses * 10^9 / 2^20 = nb_pulses * 5^9 / 2^11 = nb_pulses * 1953125 / 2048
	*/
	#define NB_PULSES_TO_PPB(pulses) DIV_ROUND_CLOSEST((pulses) * 1953125, 2048)

	/* CALP field can only be 512 or 0 as in reality CALP is a single bit field representing 512 pulses
	* added every 2^20 clock cycles
	*/
	#define MAX_CALP (512)
	#define MAX_CALM (511)

	#define MAX_PPB NB_PULSES_TO_PPB(MAX_CALP)
	#define MIN_PPB -NB_PULSES_TO_PPB(MAX_CALM)

	/* Timeout in microseconds used to wait for flags */
	#define RTC_TIMEOUT 1000000

	struct rtc_stm32_config {
	uint32_t async_prescaler;
	uint32_t sync_prescaler;
	const struct stm32_pclken *pclken;
	};

	struct rtc_stm32_data {
	struct k_mutex lock;
	};

	static int rtc_stm32_enter_initialization_mode(bool kernel_available)
	{
	if (kernel_available) {
	LL_RTC_EnableInitMode(RTC);
	bool success = WAIT_FOR(LL_RTC_IsActiveFlag_INIT(RTC), RTC_TIMEOUT, k_msleep(1));

	if (!success) {
	return -EIO;
	}
	} else {
	/* kernel is not available so use the blocking but otherwise equivalent function
	* provided by LL
	*/
	ErrorStatus status = LL_RTC_EnterInitMode(RTC);

	if (status != SUCCESS) {
	return -EIO;
	}
	}

	return 0;
	}

	static inline void rtc_stm32_leave_initialization_mode(void)
	{
	LL_RTC_DisableInitMode(RTC);
	}

	static int rtc_stm32_configure(const struct device *dev)
	{
	const struct rtc_stm32_config *cfg = dev->config;

	int err = 0;

	uint32_t hour_format = LL_RTC_GetHourFormat(RTC);
	uint32_t sync_prescaler = LL_RTC_GetSynchPrescaler(RTC);
	uint32_t async_prescaler = LL_RTC_GetAsynchPrescaler(RTC);

	LL_RTC_DisableWriteProtection(RTC);

	/* configuration process requires to stop the RTC counter so do it
	* only if needed to avoid inducing time drift at each reset
	*/
	if ((hour_format != LL_RTC_HOURFORMAT_24HOUR) \|\|
	(sync_prescaler != cfg->sync_prescaler) \|\|
	(async_prescaler != cfg->async_prescaler)) {
	err = rtc_stm32_enter_initialization_mode(false);
	if (err == 0) {
	LL_RTC_SetHourFormat(RTC, LL_RTC_HOURFORMAT_24HOUR);
	LL_RTC_SetSynchPrescaler(RTC, cfg->sync_prescaler);
	LL_RTC_SetAsynchPrescaler(RTC, cfg->async_prescaler);
	}

	rtc_stm32_leave_initialization_mode();
	}

	#ifdef RTC_CR_BYPSHAD
	LL_RTC_EnableShadowRegBypass(RTC);
	#endif /* RTC_CR_BYPSHAD */

	LL_RTC_EnableWriteProtection(RTC);

	return err;
	}

	static int rtc_stm32_init(const struct device *dev)
	{
	const struct device *const clk = DEVICE_DT_GET(STM32_CLOCK_CONTROL_NODE);
	const struct rtc_stm32_config *cfg = dev->config;
	struct rtc_stm32_data *data = dev->data;

	int err = 0;

	if (!device_is_ready(clk)) {
	LOG_ERR("clock control device not ready");
	return -ENODEV;
	}

	/* Enable RTC bus clock */
	if (clock_control_on(clk, (clock_control_subsys_t)&cfg->pclken[0]) != 0) {
	LOG_ERR("clock op failed\n");
	return -EIO;
	}

	k_mutex_init(&data->lock);

	/* Enable Backup access */
	z_stm32_hsem_lock(CFG_HW_RCC_SEMID, HSEM_LOCK_DEFAULT_RETRY);
	#if defined(PWR_CR_DBP) \|\| defined(PWR_CR1_DBP) \|\| defined(PWR_DBPCR_DBP) \|\| defined(PWR_DBPR_DBP)
	LL_PWR_EnableBkUpAccess();
	#endif /* PWR_CR_DBP \|\| PWR_CR1_DBP \|\| PWR_DBPR_DBP */

	/* Enable RTC clock source */
	if (clock_control_configure(clk, (clock_control_subsys_t)&cfg->pclken[1], NULL) != 0) {
	LOG_ERR("clock configure failed\n");
	return -EIO;
	}

	LL_RCC_EnableRTC();

	z_stm32_hsem_unlock(CFG_HW_RCC_SEMID);

	err = rtc_stm32_configure(dev);

	return err;
	}

	static int rtc_stm32_set_time(const struct device dev, const struct rtc_time timeptr)
	{
	struct rtc_stm32_data *data = dev->data;

	uint32_t real_year = timeptr->tm_year + TM_YEAR_REF;

	int err = 0;

	if (real_year < RTC_YEAR_REF) {
	/* RTC does not support years before 2000 */
	return -EINVAL;
	}

	if (timeptr->tm_wday == -1) {
	/* day of the week is expected */
	return -EINVAL;
	}

	err = k_mutex_lock(&data->lock, K_NO_WAIT);
	if (err) {
	return err;
	}

	LOG_INF("Setting clock");
	LL_RTC_DisableWriteProtection(RTC);

	err = rtc_stm32_enter_initialization_mode(true);
	if (err) {
	k_mutex_unlock(&data->lock);
	return err;
	}

	LL_RTC_DATE_SetYear(RTC, bin2bcd(real_year - RTC_YEAR_REF));
	LL_RTC_DATE_SetMonth(RTC, bin2bcd(timeptr->tm_mon + 1));
	LL_RTC_DATE_SetDay(RTC, bin2bcd(timeptr->tm_mday));

	if (timeptr->tm_wday == 0) {
	/* sunday (tm_wday = 0) is not represented by the same value in hardware */
	LL_RTC_DATE_SetWeekDay(RTC, LL_RTC_WEEKDAY_SUNDAY);
	} else {
	/* all the other values are consistent with what is expected by hardware */
	LL_RTC_DATE_SetWeekDay(RTC, timeptr->tm_wday);
	}


	LL_RTC_TIME_SetHour(RTC, bin2bcd(timeptr->tm_hour));
	LL_RTC_TIME_SetMinute(RTC, bin2bcd(timeptr->tm_min));
	LL_RTC_TIME_SetSecond(RTC, bin2bcd(timeptr->tm_sec));

	rtc_stm32_leave_initialization_mode();

	LL_RTC_EnableWriteProtection(RTC);

	k_mutex_unlock(&data->lock);

	return err;
	}

	static int rtc_stm32_get_time(const struct device dev, struct rtc_time timeptr)
	{
	struct rtc_stm32_data *data = dev->data;

	uint32_t rtc_date, rtc_time;

	#if HW_SUBSECOND_SUPPORT
	const struct rtc_stm32_config *cfg = dev->config;
	uint32_t rtc_subsecond;
	#endif

	int err = k_mutex_lock(&data->lock, K_NO_WAIT);

	if (err) {
	return err;
	}

	do {
	/* read date, time and subseconds and relaunch if a day increment occurred
	* while doing so as it will result in an erroneous result otherwise
	*/
	rtc_date = LL_RTC_DATE_Get(RTC);
	do {
	/* read time and subseconds and relaunch if a second increment occurred
	* while doing so as it will result in an erroneous result otherwise
	*/
	rtc_time = LL_RTC_TIME_Get(RTC);
	#if HW_SUBSECOND_SUPPORT
	rtc_subsecond = LL_RTC_TIME_GetSubSecond(RTC);
	#endif
	} while (rtc_time != LL_RTC_TIME_Get(RTC));
	} while (rtc_date != LL_RTC_DATE_Get(RTC));

	k_mutex_unlock(&data->lock);

	timeptr->tm_year = bcd2bin(__LL_RTC_GET_YEAR(rtc_date)) + RTC_YEAR_REF - TM_YEAR_REF;
	/* tm_mon allowed values are 0-11 */
	timeptr->tm_mon = bcd2bin(__LL_RTC_GET_MONTH(rtc_date)) - 1;
	timeptr->tm_mday = bcd2bin(__LL_RTC_GET_DAY(rtc_date));

	int hw_wday = __LL_RTC_GET_WEEKDAY(rtc_date);

	if (hw_wday == LL_RTC_WEEKDAY_SUNDAY) {
	/* LL_RTC_WEEKDAY_SUNDAY = 7 but a 0 is expected in tm_wday for sunday */
	timeptr->tm_wday = 0;
	} else {
	/* all other values are consistent between hardware and rtc_time structure */
	timeptr->tm_wday = hw_wday;
	}

	timeptr->tm_hour = bcd2bin(__LL_RTC_GET_HOUR(rtc_time));
	timeptr->tm_min = bcd2bin(__LL_RTC_GET_MINUTE(rtc_time));
	timeptr->tm_sec = bcd2bin(__LL_RTC_GET_SECOND(rtc_time));

	#if HW_SUBSECOND_SUPPORT
	uint64_t temp = ((uint64_t)(cfg->sync_prescaler - rtc_subsecond)) * 1000000000L;

	timeptr->tm_nsec = DIV_ROUND_CLOSEST(temp, cfg->sync_prescaler + 1);
	#else
	timeptr->tm_nsec = 0;
	#endif

	/* unknown values */
	timeptr->tm_yday = -1;
	timeptr->tm_isdst = -1;

	return 0;
	}

	#ifdef CONFIG_RTC_CALIBRATION
	#if !defined(CONFIG_SOC_SERIES_STM32F2X) && \
	!(defined(CONFIG_SOC_SERIES_STM32L1X) && !defined(RTC_SMOOTHCALIB_SUPPORT))
	static int rtc_stm32_set_calibration(const struct device *dev, int32_t calibration)
	{
	ARG_UNUSED(dev);

	/* Note : calibration is considered here to be ppb value to apply
	* on clock period (not frequency) but with an opposite sign
	*/

	if ((calibration > MAX_PPB) \|\| (calibration < MIN_PPB)) {
	/* out of supported range */
	return -EINVAL;
	}

	int32_t nb_pulses = PPB_TO_NB_PULSES(calibration);

	/* we tested calibration against supported range
	* so theoretically nb_pulses is also within range
	*/
	__ASSERT_NO_MSG(nb_pulses <= MAX_CALP);
	__ASSERT_NO_MSG(nb_pulses >= -MAX_CALM);

	uint32_t calp, calm;

	if (nb_pulses > 0) {
	calp = LL_RTC_CALIB_INSERTPULSE_SET;
	calm = MAX_CALP - nb_pulses;
	} else {
	calp = LL_RTC_CALIB_INSERTPULSE_NONE;
	calm = -nb_pulses;
	}

	/* wait for recalibration to be ok if a previous recalibration occurred */
	if (!WAIT_FOR(LL_RTC_IsActiveFlag_RECALP(RTC) == 0, 100000, k_msleep(1))) {
	return -EIO;
	}

	LL_RTC_DisableWriteProtection(RTC);

	MODIFY_REG(RTC->CALR, RTC_CALR_CALP \| RTC_CALR_CALM, calp \| calm);

	LL_RTC_EnableWriteProtection(RTC);

	return 0;
	}

	static int rtc_stm32_get_calibration(const struct device dev, int32_t calibration)
	{
	ARG_UNUSED(dev);

	uint32_t calr = sys_read32((mem_addr_t) &RTC->CALR);

	bool calp_enabled = READ_BIT(calr, RTC_CALR_CALP);
	uint32_t calm = READ_BIT(calr, RTC_CALR_CALM);

	int32_t nb_pulses = -((int32_t) calm);

	if (calp_enabled) {
	nb_pulses += MAX_CALP;
	}

	*calibration = NB_PULSES_TO_PPB(nb_pulses);

	return 0;
	}
	#endif
	#endif /* CONFIG_RTC_CALIBRATION */

	struct rtc_driver_api rtc_stm32_driver_api = {
	.set_time = rtc_stm32_set_time,
	.get_time = rtc_stm32_get_time,
	/* RTC_ALARM not supported */
	/* RTC_UPDATE not supported */
	#ifdef CONFIG_RTC_CALIBRATION
	#if !defined(CONFIG_SOC_SERIES_STM32F2X) && \
	!(defined(CONFIG_SOC_SERIES_STM32L1X) && !defined(RTC_SMOOTHCALIB_SUPPORT))
	.set_calibration = rtc_stm32_set_calibration,
	.get_calibration = rtc_stm32_get_calibration,
	#else
	#error RTC calibration for devices without smooth calibration feature is not supported yet
	#endif
	#endif /* CONFIG_RTC_CALIBRATION */
	};

	static const struct stm32_pclken rtc_clk[] = STM32_DT_INST_CLOCKS(0);

	BUILD_ASSERT(DT_INST_CLOCKS_HAS_IDX(0, 1), "RTC source clock not defined in the device tree");

	static const struct rtc_stm32_config rtc_config = {
	#if DT_INST_CLOCKS_CELL_BY_IDX(0, 1, bus) == STM32_SRC_LSI
	/* prescaler values for LSI @ 32 KHz */
	.async_prescaler = 0x7F,
	.sync_prescaler = 0x00F9,
	#else /* DT_INST_CLOCKS_CELL_BY_IDX(0, 1, bus) == STM32_SRC_LSE */
	/* prescaler values for LSE @ 32768 Hz */
	.async_prescaler = 0x7F,
	.sync_prescaler = 0x00FF,
	#endif
	.pclken = rtc_clk,
	};

	static struct rtc_stm32_data rtc_data;

	DEVICE_DT_INST_DEFINE(0, &rtc_stm32_init, NULL, &rtc_data, &rtc_config, PRE_KERNEL_1,
	CONFIG_RTC_INIT_PRIORITY, &rtc_stm32_driver_api);