Files
Sensor-Watch/watch-library/hardware/watch/watch_rtc.c
T

305 lines
9.6 KiB
C

/*
* MIT License
*
* Copyright (c) 2020 Joey Castillo
* Copyright (c) 2025 Alessandro Genova
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in all
* copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
* SOFTWARE.
*/
#include <stddef.h>
#include <limits.h>
#include "watch_rtc.h"
#include "watch_private.h"
#include "watch_utility.h"
static const uint32_t RTC_OSC_DIV = 10;
static const uint32_t RTC_OSC_HZ = 1 << RTC_OSC_DIV; // 2^10 = 1024
static const uint32_t RTC_PRESCALER_DIV = 3;
static const uint32_t RTC_CNT_HZ = RTC_OSC_HZ >> RTC_PRESCALER_DIV; // 1024 / 2^3 = 128
static const uint32_t RTC_CNT_DIV = RTC_OSC_DIV - RTC_PRESCALER_DIV; // 7
static const uint32_t RTC_CNT_TICKS_PER_MINUTE = RTC_CNT_HZ * 60;
static const uint32_t RTC_CNT_TICKS_PER_HOUR = RTC_CNT_TICKS_PER_MINUTE * 60;
static const int TB_BKUP_REG = 7;
#define WATCH_RTC_N_COMP_CB 8
typedef struct {
volatile uint32_t counter;
volatile watch_cb_t callback;
volatile bool enabled;
} comp_cb_t;
watch_cb_t tick_callbacks[8];
comp_cb_t comp_callbacks[WATCH_RTC_N_COMP_CB];
watch_cb_t alarm_callback;
watch_cb_t btn_alarm_callback;
watch_cb_t a2_callback;
watch_cb_t a4_callback;
void watch_rtc_callback(uint16_t interrupt_status);
bool _watch_rtc_is_enabled(void) {
return rtc_is_enabled();
}
void _watch_rtc_init(void) {
rtc_init();
#ifdef STATIC_FREQCORR
watch_rtc_freqcorr_write(STATIC_FREQCORR, 0);
#endif
rtc_enable();
rtc_configure_callback(watch_rtc_callback);
for (uint8_t index = 0; index < WATCH_RTC_N_COMP_CB; ++index) {
comp_callbacks[index].counter = 0;
comp_callbacks[index].callback = NULL;
comp_callbacks[index].enabled = false;
}
NVIC_ClearPendingIRQ(RTC_IRQn);
NVIC_EnableIRQ(RTC_IRQn);
}
void watch_rtc_set_date_time(rtc_date_time_t date_time) {
watch_rtc_set_unix_time(watch_utility_date_time_to_unix_time(date_time, 0));
}
rtc_date_time_t watch_rtc_get_date_time(void) {
return watch_utility_date_time_from_unix_time(watch_rtc_get_unix_time(), 0);
}
void watch_rtc_set_unix_time(unix_timestamp_t unix_time) {
// time_backup + counter / RTC_CNT_HZ = unix_time
rtc_counter_t counter = rtc_get_counter();
unix_timestamp_t tb = unix_time - (counter >> RTC_CNT_DIV);
watch_store_backup_data(tb, TB_BKUP_REG);
}
unix_timestamp_t watch_rtc_get_unix_time(void) {
// time_backup + counter / RTC_CNT_HZ = unix_time
rtc_counter_t counter = rtc_get_counter();
unix_timestamp_t tb = watch_get_backup_data(TB_BKUP_REG);
return tb + (counter >> RTC_CNT_DIV);
}
rtc_counter_t watch_rtc_get_counter(void) {
return rtc_get_counter();
}
uint32_t watch_rtc_get_frequency(void) {
return RTC_CNT_HZ;
}
uint32_t watch_rtc_get_ticks_per_minute(void) {
return RTC_CNT_TICKS_PER_MINUTE;
}
rtc_date_time_t watch_get_init_date_time(void) {
rtc_date_time_t date_time;
#ifdef BUILD_YEAR
date_time.unit.year = BUILD_YEAR;
#else
date_time.unit.year = 5;
#endif
#ifdef BUILD_MONTH
date_time.unit.month = BUILD_MONTH;
#else
date_time.unit.month = 1;
#endif
#ifdef BUILD_DAY
date_time.unit.day = BUILD_DAY;
#else
date_time.unit.day = 1;
#endif
#ifdef BUILD_HOUR
date_time.unit.hour = BUILD_HOUR;
#endif
#ifdef BUILD_MINUTE
date_time.unit.minute = BUILD_MINUTE;
#endif
return date_time;
}
void watch_rtc_register_tick_callback(watch_cb_t callback) {
watch_rtc_register_periodic_callback(callback, 1);
}
void watch_rtc_disable_tick_callback(void) {
watch_rtc_disable_periodic_callback(1);
}
void watch_rtc_register_periodic_callback(watch_cb_t callback, uint8_t frequency) {
// we told them, it has to be a power of 2.
if (__builtin_popcount(frequency) != 1) return;
// this left-justifies the period in a 32-bit integer.
uint32_t tmp = (frequency & 0xFF) << 24;
// now we can count the leading zeroes to get the value we need.
// 0x01 (1 Hz) will have 7 leading zeros for PER7. 0x80 (128 Hz) will have no leading zeroes for PER0.
uint8_t per_n = __builtin_clz(tmp);
// this also maps nicely to an index for our list of tick callbacks.
tick_callbacks[per_n] = callback;
// NVIC_ClearPendingIRQ(RTC_IRQn);
// NVIC_EnableIRQ(RTC_IRQn);
RTC->MODE0.INTENSET.reg = 1 << per_n;
}
void watch_rtc_disable_periodic_callback(uint8_t frequency) {
if (__builtin_popcount(frequency) != 1) return;
uint8_t per_n = __builtin_clz((frequency & 0xFF) << 24);
RTC->MODE0.INTENCLR.reg = 1 << per_n;
}
void watch_rtc_disable_matching_periodic_callbacks(uint8_t mask) {
RTC->MODE0.INTENCLR.reg = mask;
}
void watch_rtc_disable_all_periodic_callbacks(void) {
watch_rtc_disable_matching_periodic_callbacks(0xFF);
}
static void _watch_rtc_schedule_next_comp(void) {
rtc_disable_compare_interrupt();
// The soonest we can schedule is the next tick
rtc_counter_t curr_counter = watch_rtc_get_counter() + 1;
bool schedule_any = false;
rtc_counter_t comp_counter;
rtc_counter_t min_diff = UINT_MAX;
for (uint8_t index = 0; index < WATCH_RTC_N_COMP_CB; ++index) {
if (comp_callbacks[index].enabled) {
rtc_counter_t diff = comp_callbacks[index].counter - curr_counter;
if (diff <= min_diff) {
min_diff = diff;
comp_counter = comp_callbacks[index].counter;
schedule_any = true;
}
}
}
if (schedule_any) {
rtc_enable_compare_interrupt(comp_counter);
}
}
void watch_rtc_register_comp_callback(watch_cb_t callback, rtc_counter_t counter, uint8_t index) {
if (index >= WATCH_RTC_N_COMP_CB) {
return;
}
rtc_disable_compare_interrupt();
comp_callbacks[index].counter = counter;
comp_callbacks[index].callback = callback;
comp_callbacks[index].enabled = true;
_watch_rtc_schedule_next_comp();
}
void watch_rtc_disable_comp_callback(uint8_t index) {
if (index >= WATCH_RTC_N_COMP_CB) {
return;
}
rtc_disable_compare_interrupt();
comp_callbacks[index].enabled = false;
_watch_rtc_schedule_next_comp();
}
void watch_rtc_callback(uint16_t interrupt_cause) {
// First read all relevant registers, to ensure no changes occurr during the callbacks
uint16_t interrupt_enabled = RTC->MODE0.INTENSET.reg;
rtc_counter_t comp_counter = RTC->MODE0.COMP[0].reg;
if ((interrupt_cause & interrupt_enabled) & RTC_MODE0_INTFLAG_PER_Msk) {
// handle the tick callback first, it's what we do the most.
// start from PER7, the 1 Hz tick.
for(int8_t i = 7; i >= 0; i--) {
if ((interrupt_cause & interrupt_enabled) & (1 << i)) {
if (tick_callbacks[i] != NULL) {
tick_callbacks[i]();
}
}
}
}
if ((interrupt_cause & interrupt_enabled) & RTC_MODE0_INTFLAG_TAMPER) {
// handle the extwake interrupts next.
uint8_t reason = RTC->MODE0.TAMPID.reg;
if (reason & RTC_TAMPID_TAMPID2) {
if (btn_alarm_callback != NULL) btn_alarm_callback();
} else if (reason & RTC_TAMPID_TAMPID1) {
if (a2_callback != NULL) a2_callback();
} else if (reason & RTC_TAMPID_TAMPID0) {
if (a4_callback != NULL) a4_callback();
}
RTC->MODE0.TAMPID.reg = reason;
}
if ((interrupt_cause & interrupt_enabled) & RTC_MODE0_INTFLAG_CMP0) {
// The comp interrupt is generated one tick after the matched counter
// rtc_counter_t comp_counter = watch_rtc_get_counter() - 1;
for (uint8_t index = 0; index < WATCH_RTC_N_COMP_CB; ++index) {
if (comp_callbacks[index].enabled && comp_counter == comp_callbacks[index].counter) {
comp_callbacks[index].enabled = false;
comp_callbacks[index].callback();
}
}
_watch_rtc_schedule_next_comp();
}
if ((interrupt_cause & interrupt_enabled) & RTC_MODE0_INTFLAG_OVF) {
// Handle the overflow of the counter. All we need to do is reset the reference time.
unix_timestamp_t tb = watch_get_backup_data(TB_BKUP_REG);
watch_store_backup_data(tb + (UINT_MAX >> RTC_CNT_DIV), TB_BKUP_REG);
}
}
void watch_rtc_enable(bool en) {
// Writing it twice - as it's quite dangerous operation.
// If write fails - we might hang with RTC off, which means no recovery possible
while (RTC->MODE0.SYNCBUSY.reg);
RTC->MODE0.CTRLA.bit.ENABLE = en ? 1 : 0;
while (RTC->MODE0.SYNCBUSY.reg);
RTC->MODE0.CTRLA.bit.ENABLE = en ? 1 : 0;
while (RTC->MODE0.SYNCBUSY.reg);
}
void watch_rtc_freqcorr_write(int16_t value, int16_t sign) {
RTC_FREQCORR_Type data;
data.bit.VALUE = value;
data.bit.SIGN = sign;
RTC->MODE0.FREQCORR.reg = data.reg; // Setting correction in single write operation
// We do not sycnronize. We are not in a hurry
}