blob: 22aec94f1d87582614a74eed4e1421b83dfb5a2c [file] [log] [blame]
/*
* Copyright (c) 2023 Bjarki Arge Andreasen
*
* SPDX-License-Identifier: Apache-2.0
*/
#define DT_DRV_COMPAT atmel_sam_rtc
#include <zephyr/kernel.h>
#include <zephyr/device.h>
#include <zephyr/irq.h>
#include <zephyr/drivers/rtc.h>
#include <zephyr/sys/util.h>
#include <string.h>
#include <soc.h>
#include "rtc_utils.h"
#define RTC_SAM_REG_GET_FIELD(value, field) \
((RTC_##field##_Msk & value) >> RTC_##field##_Pos)
#define RTC_SAM_WPMR_DISABLE 0x52544300
#define RTC_SAM_WPMR_ENABLE 0x52544301
#define RTC_SAM_CALIBRATE_PPB_MAX (1950000)
#define RTC_SAM_CALIBRATE_PPB_MIN (-1950000)
#define RTC_SAM_CALIBRATE_PPB_QUANTA (1500)
#define RTC_SAM_CALIBRATE_PPB_LOW_SCALE (30500)
#define RTC_SAM_TIME_MASK \
(RTC_ALARM_TIME_MASK_SECOND | RTC_ALARM_TIME_MASK_MINUTE | RTC_ALARM_TIME_MASK_HOUR | \
RTC_ALARM_TIME_MASK_MONTH | RTC_ALARM_TIME_MASK_MONTHDAY | RTC_ALARM_TIME_MASK_YEAR | \
RTC_ALARM_TIME_MASK_WEEKDAY)
typedef void (*rtc_sam_irq_init_fn_ptr)(void);
struct rtc_sam_config {
Rtc *regs;
uint16_t irq_num;
rtc_sam_irq_init_fn_ptr irq_init_fn_ptr;
};
struct rtc_sam_data {
#ifdef CONFIG_RTC_ALARM
rtc_alarm_callback alarm_callback;
void *alarm_user_data;
#endif /* CONFIG_RTC_ALARM */
#ifdef CONFIG_RTC_UPDATE
rtc_update_callback update_callback;
void *update_user_data;
#endif /* CONFIG_RTC_UPDATE */
struct k_spinlock lock;
struct k_sem cr_sec_evt_sem;
struct k_sem cr_upd_ack_sem;
};
static void rtc_sam_disable_wp(void)
{
REG_RTC_WPMR = RTC_SAM_WPMR_DISABLE;
}
static void rtc_sam_enable_wp(void)
{
REG_RTC_WPMR = RTC_SAM_WPMR_ENABLE;
}
static uint32_t rtc_sam_timr_from_tm(const struct rtc_time *timeptr)
{
uint32_t timr;
timr = RTC_TIMR_SEC(bin2bcd(timeptr->tm_sec));
timr |= RTC_TIMR_MIN(bin2bcd(timeptr->tm_min));
timr |= RTC_TIMR_HOUR(bin2bcd(timeptr->tm_hour));
return timr;
}
static uint32_t rtc_sam_calr_from_tm(const struct rtc_time *timeptr)
{
uint32_t calr;
uint8_t centuries;
uint8_t years;
calr = RTC_CALR_DATE(bin2bcd(timeptr->tm_mday));
calr |= RTC_CALR_MONTH(bin2bcd(timeptr->tm_mon + 1));
centuries = (uint8_t)((timeptr->tm_year / 100) + 19);
years = (uint8_t)((timeptr->tm_year % 100));
calr |= RTC_CALR_CENT(bin2bcd(centuries));
calr |= RTC_CALR_YEAR(bin2bcd(years));
calr |= RTC_CALR_DAY(bin2bcd(timeptr->tm_wday + 1));
return calr;
}
static int rtc_sam_set_time(const struct device *dev, const struct rtc_time *timeptr)
{
struct rtc_sam_data *data = dev->data;
const struct rtc_sam_config *config = dev->config;
Rtc *regs = config->regs;
if (rtc_utils_validate_rtc_time(timeptr, RTC_SAM_TIME_MASK) == false) {
return -EINVAL;
}
k_spinlock_key_t key = k_spin_lock(&data->lock);
k_sem_reset(&data->cr_sec_evt_sem);
k_sem_take(&data->cr_sec_evt_sem, K_MSEC(1100));
k_sem_reset(&data->cr_upd_ack_sem);
/* Enable update acknowledge interrupt */
regs->RTC_IER = RTC_IER_ACKEN;
rtc_sam_disable_wp();
/* Request update */
regs->RTC_CR = (RTC_CR_UPDTIM | RTC_CR_UPDCAL);
/* Await update acknowledge */
if (k_sem_take(&data->cr_upd_ack_sem, K_MSEC(1100)) < 0) {
regs->RTC_CR = 0;
rtc_sam_enable_wp();
/* Disable update acknowledge interrupt */
regs->RTC_IDR = RTC_IDR_ACKDIS;
k_spin_unlock(&data->lock, key);
return -EAGAIN;
}
regs->RTC_TIMR = rtc_sam_timr_from_tm(timeptr);
regs->RTC_CALR = rtc_sam_calr_from_tm(timeptr);
regs->RTC_CR = 0;
rtc_sam_enable_wp();
regs->RTC_IDR = RTC_IDR_ACKDIS;
k_spin_unlock(&data->lock, key);
return 0;
}
static int rtc_sam_get_time(const struct device *dev, struct rtc_time *timeptr)
{
const struct rtc_sam_config *config = dev->config;
Rtc *regs = config->regs;
uint32_t timr0;
uint32_t calr0;
uint32_t timr1;
uint32_t calr1;
/* Validate time and date */
if (regs->RTC_VER & (RTC_VER_NVTIM | RTC_VER_NVCAL)) {
return -ENODATA;
}
/* Read until synchronized (registers updated async) */
while (1) {
timr0 = regs->RTC_TIMR;
calr0 = regs->RTC_CALR;
timr1 = regs->RTC_TIMR;
calr1 = regs->RTC_CALR;
if ((timr0 == timr1) && (calr0 == calr1)) {
break;
}
}
timeptr->tm_sec = bcd2bin(RTC_SAM_REG_GET_FIELD(timr0, TIMR_SEC));
timeptr->tm_min = bcd2bin(RTC_SAM_REG_GET_FIELD(timr0, TIMR_MIN));
timeptr->tm_hour = bcd2bin(RTC_SAM_REG_GET_FIELD(timr0, TIMR_HOUR));
timeptr->tm_mday = bcd2bin(RTC_SAM_REG_GET_FIELD(calr0, CALR_DATE));
timeptr->tm_mon = bcd2bin(RTC_SAM_REG_GET_FIELD(calr0, CALR_MONTH)) - 1;
timeptr->tm_year = bcd2bin(RTC_SAM_REG_GET_FIELD(calr0, CALR_YEAR));
timeptr->tm_year += ((int)bcd2bin(RTC_SAM_REG_GET_FIELD(calr0, CALR_CENT))) * 100;
timeptr->tm_year -= 1900;
timeptr->tm_wday = bcd2bin(RTC_SAM_REG_GET_FIELD(calr0, CALR_DAY)) - 1;
timeptr->tm_yday = -1;
timeptr->tm_isdst = -1;
timeptr->tm_nsec = 0;
return 0;
}
static void rtc_sam_isr(const struct device *dev)
{
struct rtc_sam_data *data = dev->data;
const struct rtc_sam_config *config = dev->config;
Rtc *regs = config->regs;
uint32_t sr = regs->RTC_SR;
if (sr & RTC_SR_ACKUPD) {
regs->RTC_SCCR = RTC_SCCR_ACKCLR;
k_sem_give(&data->cr_upd_ack_sem);
}
#ifdef CONFIG_RTC_ALARM
if (sr & RTC_SR_ALARM) {
regs->RTC_SCCR = RTC_SCCR_ALRCLR;
if (data->alarm_callback != NULL) {
data->alarm_callback(dev, 0, data->alarm_user_data);
}
}
#endif /* CONFIG_RTC_ALARM */
#ifdef CONFIG_RTC_UPDATE
if (sr & RTC_SR_SEC) {
regs->RTC_SCCR = RTC_SCCR_SECCLR;
if (data->update_callback != NULL) {
data->update_callback(dev, data->update_user_data);
}
k_sem_give(&data->cr_sec_evt_sem);
}
#endif /* CONFIG_RTC_UPDATE */
}
#ifdef CONFIG_RTC_ALARM
static uint16_t rtc_sam_alarm_get_supported_mask(void)
{
return (RTC_ALARM_TIME_MASK_SECOND
| RTC_ALARM_TIME_MASK_MINUTE
| RTC_ALARM_TIME_MASK_HOUR
| RTC_ALARM_TIME_MASK_MONTHDAY
| RTC_ALARM_TIME_MASK_MONTH);
}
static uint32_t rtc_atmel_timalr_from_tm(const struct rtc_time *timeptr, uint32_t mask)
{
uint32_t timalr = 0;
if (mask & RTC_ALARM_TIME_MASK_SECOND) {
timalr |= RTC_TIMALR_SECEN;
timalr |= RTC_TIMALR_SEC(bin2bcd(timeptr->tm_sec));
}
if (mask & RTC_ALARM_TIME_MASK_MINUTE) {
timalr |= RTC_TIMALR_MINEN;
timalr |= RTC_TIMALR_MIN(bin2bcd(timeptr->tm_min));
}
if (mask & RTC_ALARM_TIME_MASK_HOUR) {
timalr |= RTC_TIMALR_HOUREN;
timalr |= RTC_TIMALR_HOUR(bin2bcd(timeptr->tm_hour));
}
return timalr;
}
static uint32_t rtc_atmel_calalr_from_tm(const struct rtc_time *timeptr, uint32_t mask)
{
uint32_t calalr = RTC_CALALR_MONTH(1) | RTC_CALALR_DATE(1);
if (mask & RTC_ALARM_TIME_MASK_MONTH) {
calalr |= RTC_CALALR_MTHEN;
calalr |= RTC_CALALR_MONTH(bin2bcd(timeptr->tm_mon + 1));
}
if (mask & RTC_ALARM_TIME_MASK_MONTHDAY) {
calalr |= RTC_CALALR_DATEEN;
calalr |= RTC_CALALR_DATE(bin2bcd(timeptr->tm_mday));
}
return calalr;
}
static uint32_t rtc_sam_alarm_mask_from_timalr(uint32_t timalr)
{
uint32_t mask = 0;
if (timalr & RTC_TIMALR_SECEN) {
mask |= RTC_ALARM_TIME_MASK_SECOND;
}
if (timalr & RTC_TIMALR_MINEN) {
mask |= RTC_ALARM_TIME_MASK_MINUTE;
}
if (timalr & RTC_TIMALR_HOUREN) {
mask |= RTC_ALARM_TIME_MASK_HOUR;
}
return mask;
}
static uint32_t rtc_sam_alarm_mask_from_calalr(uint32_t calalr)
{
uint32_t mask = 0;
if (calalr & RTC_CALALR_MTHEN) {
mask |= RTC_ALARM_TIME_MASK_MONTH;
}
if (calalr & RTC_CALALR_DATEEN) {
mask |= RTC_ALARM_TIME_MASK_MONTHDAY;
}
return mask;
}
static void rtc_sam_tm_from_timalr_calalr(struct rtc_time *timeptr, uint32_t mask,
uint32_t timalr, uint32_t calalr)
{
memset(timeptr, 0x00, sizeof(*timeptr));
if (mask & RTC_ALARM_TIME_MASK_SECOND) {
timeptr->tm_sec = bcd2bin(RTC_SAM_REG_GET_FIELD(timalr, TIMALR_SEC));
}
if (mask & RTC_ALARM_TIME_MASK_MINUTE) {
timeptr->tm_min = bcd2bin(RTC_SAM_REG_GET_FIELD(timalr, TIMALR_MIN));
}
if (mask & RTC_ALARM_TIME_MASK_HOUR) {
timeptr->tm_hour = bcd2bin(RTC_SAM_REG_GET_FIELD(timalr, TIMALR_HOUR));
}
if (mask & RTC_ALARM_TIME_MASK_MONTHDAY) {
timeptr->tm_mday = bcd2bin(RTC_SAM_REG_GET_FIELD(calalr, CALALR_DATE));
}
if (mask & RTC_ALARM_TIME_MASK_MONTH) {
timeptr->tm_mon = bcd2bin(RTC_SAM_REG_GET_FIELD(calalr, CALALR_MONTH)) - 1;
}
}
static int rtc_sam_alarm_get_supported_fields(const struct device *dev, uint16_t id,
uint16_t *mask)
{
ARG_UNUSED(dev);
ARG_UNUSED(id);
*mask = rtc_sam_alarm_get_supported_mask();
return 0;
}
static int rtc_sam_alarm_set_time(const struct device *dev, uint16_t id, uint16_t mask,
const struct rtc_time *timeptr)
{
struct rtc_sam_data *data = dev->data;
const struct rtc_sam_config *config = dev->config;
Rtc *regs = config->regs;
uint32_t timalr;
uint32_t calalr;
uint32_t mask_supported;
mask_supported = rtc_sam_alarm_get_supported_mask();
if ((id != 0)) {
return -EINVAL;
}
if ((mask > 0) && (timeptr == NULL)) {
return -EINVAL;
}
if (mask & ~mask_supported) {
return -EINVAL;
}
if (rtc_utils_validate_rtc_time(timeptr, mask) == false) {
return -EINVAL;
}
timalr = rtc_atmel_timalr_from_tm(timeptr, mask);
calalr = rtc_atmel_calalr_from_tm(timeptr, mask);
k_spinlock_key_t key = k_spin_lock(&data->lock);
irq_disable(config->irq_num);
rtc_sam_disable_wp();
/* Set RTC alarm time */
regs->RTC_TIMALR = timalr;
regs->RTC_CALALR = calalr;
rtc_sam_enable_wp();
/* Clear alarm pending status */
regs->RTC_SCCR = RTC_SCCR_ALRCLR;
irq_enable(config->irq_num);
k_spin_unlock(&data->lock, key);
return 0;
}
static int rtc_sam_alarm_get_time(const struct device *dev, uint16_t id, uint16_t *mask,
struct rtc_time *timeptr)
{
struct rtc_sam_data *data = dev->data;
const struct rtc_sam_config *config = dev->config;
Rtc *regs = config->regs;
uint32_t timalr;
uint32_t calalr;
if ((id != 0) || (mask == NULL) || (timeptr == NULL)) {
return -EINVAL;
}
k_spinlock_key_t key = k_spin_lock(&data->lock);
timalr = regs->RTC_TIMALR;
calalr = regs->RTC_CALALR;
k_spin_unlock(&data->lock, key);
*mask = rtc_sam_alarm_mask_from_timalr(timalr);
*mask |= rtc_sam_alarm_mask_from_calalr(calalr);
rtc_sam_tm_from_timalr_calalr(timeptr, *mask, timalr, calalr);
return 0;
}
static int rtc_sam_alarm_is_pending(const struct device *dev, uint16_t id)
{
struct rtc_sam_data *data = dev->data;
const struct rtc_sam_config *config = dev->config;
Rtc *regs = config->regs;
if (id != 0) {
return -EINVAL;
}
k_spinlock_key_t key = k_spin_lock(&data->lock);
if ((regs->RTC_SR & RTC_SR_ALARM) == 0) {
k_spin_unlock(&data->lock, key);
return 0;
}
regs->RTC_SCCR = RTC_SCCR_ALRCLR;
k_spin_unlock(&data->lock, key);
return 1;
}
static int rtc_sam_alarm_set_callback(const struct device *dev, uint16_t id,
rtc_alarm_callback callback, void *user_data)
{
struct rtc_sam_data *data = dev->data;
const struct rtc_sam_config *config = dev->config;
Rtc *regs = config->regs;
if (id != 0) {
return -EINVAL;
}
k_spinlock_key_t key = k_spin_lock(&data->lock);
irq_disable(config->irq_num);
data->alarm_callback = callback;
data->alarm_user_data = user_data;
if (data->alarm_callback) {
regs->RTC_IER = RTC_IER_ALREN;
} else {
regs->RTC_IDR = RTC_IDR_ALRDIS;
}
irq_enable(config->irq_num);
k_spin_unlock(&data->lock, key);
return 0;
}
#endif /* CONFIG_RTC_ALARM */
#ifdef CONFIG_RTC_UPDATE
static int rtc_sam_update_set_callback(const struct device *dev, rtc_update_callback callback,
void *user_data)
{
struct rtc_sam_data *data = dev->data;
const struct rtc_sam_config *config = dev->config;
Rtc *regs = config->regs;
k_spinlock_key_t key = k_spin_lock(&data->lock);
irq_disable(config->irq_num);
data->update_callback = callback;
data->update_user_data = user_data;
if (data->update_callback) {
regs->RTC_IER = RTC_IER_SECEN;
} else {
regs->RTC_IDR = RTC_IDR_SECDIS;
}
irq_enable(config->irq_num);
k_spin_unlock(&data->lock, key);
return 0;
}
#endif /* CONFIG_RTC_UPDATE */
#ifdef CONFIG_RTC_CALIBRATION
static int rtc_sam_set_calibration(const struct device *dev, int32_t calibration)
{
struct rtc_sam_data *data = dev->data;
const struct rtc_sam_config *config = dev->config;
Rtc *regs = config->regs;
bool negative_calibration;
bool high_calibration;
uint32_t slow_clock_calibration;
uint32_t mr;
if ((calibration < RTC_SAM_CALIBRATE_PPB_MIN) ||
(calibration > RTC_SAM_CALIBRATE_PPB_MAX)) {
return -EINVAL;
}
/* The value written to the register is absolute */
if (calibration < 0) {
negative_calibration = true;
calibration = -calibration;
} else {
negative_calibration = false;
}
/*
* Formula adapted from
* Atmel-11157-32-bit-Cortex-M4-Microcontroller-SAM4E16-SAM4E8_Datasheet.pdf
* section 15.6.2
*
* Formula if RTC_MR_HIGHPPM is 0
*
* RTC_MR_CORRECTION = (3906 / (20 * ppm)) - 1
*
* Formula if RTC_MR_HIGHPPM is 1
*
* RTC_MR_CORRECTION = (3906 / ppm) - 1
*
* Since we are working with ppb, we adapt the formula by increasing the
* terms of the fraction by 1000, turning the ppm into ppb
*
* Adapted formula if RTC_MR_HIGHPPM is 0
*
* RTC_MR_CORRECTION = (3906000 / (20 * ppb)) - 1
*
* Adapted formula if RTC_MR_HIGHPPM is 1
*
* RTC_MR_CORRECTION = (3906000 / ppb) - 1
*/
if (calibration < RTC_SAM_CALIBRATE_PPB_QUANTA) {
high_calibration = false;
slow_clock_calibration = 0;
} else if (calibration < RTC_SAM_CALIBRATE_PPB_LOW_SCALE) {
high_calibration = false;
slow_clock_calibration = (uint32_t)((3906000 / (20 * calibration)) - 1);
} else {
high_calibration = true;
slow_clock_calibration = (uint32_t)((3906000 / calibration) - 1);
}
k_spinlock_key_t key = k_spin_lock(&data->lock);
rtc_sam_disable_wp();
mr = regs->RTC_MR;
if (negative_calibration == true) {
mr |= RTC_MR_NEGPPM;
} else {
mr &= ~RTC_MR_NEGPPM;
}
mr &= ~RTC_MR_CORRECTION_Msk;
mr |= RTC_MR_CORRECTION(slow_clock_calibration);
if (high_calibration == true) {
mr |= RTC_MR_HIGHPPM;
} else {
mr &= ~RTC_MR_HIGHPPM;
}
regs->RTC_MR = mr;
rtc_sam_enable_wp();
k_spin_unlock(&data->lock, key);
return 0;
}
static int rtc_sam_get_calibration(const struct device *dev, int32_t *calibration)
{
const struct rtc_sam_config *config = dev->config;
Rtc *regs = config->regs;
uint32_t mr;
int32_t correction;
if (calibration == NULL) {
return -EINVAL;
}
mr = regs->RTC_MR;
correction = (int32_t)RTC_SAM_REG_GET_FIELD(mr, MR_CORRECTION);
/* Formula documented in rtc_sam_set_calibration() */
if (correction == 0) {
*calibration = 0;
} else if (mr & RTC_MR_HIGHPPM) {
*calibration = 3906000 / (correction + 1);
} else {
*calibration = 3906000 / ((correction + 1) * 20);
}
if (mr & RTC_MR_NEGPPM) {
*calibration = -*calibration;
}
return 0;
}
#endif /* CONFIG_RTC_CALIBRATION */
static const struct rtc_driver_api rtc_sam_driver_api = {
.set_time = rtc_sam_set_time,
.get_time = rtc_sam_get_time,
#ifdef CONFIG_RTC_ALARM
.alarm_get_supported_fields = rtc_sam_alarm_get_supported_fields,
.alarm_set_time = rtc_sam_alarm_set_time,
.alarm_get_time = rtc_sam_alarm_get_time,
.alarm_is_pending = rtc_sam_alarm_is_pending,
.alarm_set_callback = rtc_sam_alarm_set_callback,
#endif /* CONFIG_RTC_ALARM */
#ifdef CONFIG_RTC_UPDATE
.update_set_callback = rtc_sam_update_set_callback,
#endif /* CONFIG_RTC_UPDATE */
#ifdef CONFIG_RTC_CALIBRATION
.set_calibration = rtc_sam_set_calibration,
.get_calibration = rtc_sam_get_calibration,
#endif /* CONFIG_RTC_CALIBRATION */
};
static int rtc_sam_init(const struct device *dev)
{
struct rtc_sam_data *data = dev->data;
const struct rtc_sam_config *config = dev->config;
Rtc *regs = config->regs;
rtc_sam_disable_wp();
regs->RTC_MR &= ~(RTC_MR_HRMOD | RTC_MR_PERSIAN);
regs->RTC_CR = 0;
rtc_sam_enable_wp();
regs->RTC_IDR = (RTC_IDR_ACKDIS
| RTC_IDR_ALRDIS
| RTC_IDR_SECDIS
| RTC_IDR_TIMDIS
| RTC_IDR_CALDIS
| RTC_IDR_TDERRDIS);
k_sem_init(&data->cr_sec_evt_sem, 0, 1);
k_sem_init(&data->cr_upd_ack_sem, 0, 1);
config->irq_init_fn_ptr();
irq_enable(config->irq_num);
return 0;
}
#define RTC_SAM_DEVICE(id) \
static void rtc_sam_irq_init_##id(void) \
{ \
IRQ_CONNECT(DT_INST_IRQN(0), DT_INST_IRQ(0, priority), \
rtc_sam_isr, DEVICE_DT_INST_GET(id), 0); \
} \
\
static const struct rtc_sam_config rtc_sam_config_##id = { \
.regs = (Rtc *)DT_INST_REG_ADDR(id), \
.irq_num = DT_INST_IRQN(id), \
.irq_init_fn_ptr = rtc_sam_irq_init_##id, \
}; \
\
static struct rtc_sam_data rtc_sam_data_##id; \
\
DEVICE_DT_INST_DEFINE(id, rtc_sam_init, NULL, \
&rtc_sam_data_##id, \
&rtc_sam_config_##id, POST_KERNEL, \
CONFIG_RTC_INIT_PRIORITY, \
&rtc_sam_driver_api);
DT_INST_FOREACH_STATUS_OKAY(RTC_SAM_DEVICE);