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/*
* MIT License
*
* Copyright (c) 2022 Andreas Nebinger
*
* 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 <stdlib.h>
#include <string.h>
#include "alarm_face.h"
#include "watch.h"
#include "watch_utility.h"
#include "watch_private_display.h"
typedef enum {
alarm_setting_idx_alarm,
alarm_setting_idx_day,
alarm_setting_idx_hour,
alarm_setting_idx_minute,
alarm_setting_idx_pitch,
alarm_setting_idx_beeps
} alarm_setting_idx_t;
static const char _dow_strings[ALARM_DAY_STATES + 1][2] ={"AL", "MO", "TU", "WE", "TH", "FR", "SA", "SO", "ED", "1t", "MF", "WN"};
static const uint8_t _blink_idx[ALARM_SETTING_STATES] = {2, 0, 4, 6, 8, 9};
static const uint8_t _blink_idx2[ALARM_SETTING_STATES] = {3, 1, 5, 7, 8, 9};
static const BuzzerNote _buzzer_notes[3] = {BUZZER_NOTE_B6, BUZZER_NOTE_C8, BUZZER_NOTE_A8};
static const uint8_t _buzzer_segdata[3][2] = {{0, 3}, {1, 3}, {2, 2}};
static int8_t _wait_ticks;
static uint8_t _get_weekday_idx(watch_date_time date_time) {
date_time.unit.year += 20;
if (date_time.unit.month <= 2) {
date_time.unit.month += 12;
date_time.unit.year--;
}
return (date_time.unit.day + 13 * (date_time.unit.month + 1) / 5 + date_time.unit.year + date_time.unit.year / 4 + 525 - 2) % 7;
}
static void _alarm_set_signal(alarm_state_t *state) {
if (state->alarm[state->alarm_idx].enabled)
watch_set_indicator(WATCH_INDICATOR_SIGNAL);
else
watch_clear_indicator(WATCH_INDICATOR_SIGNAL);
}
static void _alarm_face_draw(movement_settings_t *settings, alarm_state_t *state, uint8_t subsecond) {
char buf[12];
uint8_t i = 0;
if (state->is_setting) {
// display the actual day indicating string for the current alarm
i = state->alarm[state->alarm_idx].day + 1;
}
//handle am/pm for hour display
uint8_t h = state->alarm[state->alarm_idx].hour;
if (!settings->bit.clock_mode_24h) {
if (h >= 12) {
watch_set_indicator(WATCH_INDICATOR_PM);
h %= 12;
} else {
watch_clear_indicator(WATCH_INDICATOR_PM);
}
if (h == 0) h = 12;
}
sprintf(buf, "%c%c%2d%2d%02d ",
_dow_strings[i][0], _dow_strings[i][1],
(state->alarm_idx + 1),
h,
state->alarm[state->alarm_idx].minute);
// blink items if in settings mode
if (state->is_setting && subsecond % 2 && state->setting_state < alarm_setting_idx_pitch && !state->alarm_quick_ticks) {
buf[_blink_idx[state->setting_state]] = buf[_blink_idx2[state->setting_state]] = ' ';
}
watch_display_string(buf, 0);
if (state->is_setting) {
// draw pitch level indicator
if ((subsecond % 2) == 0 || (state->setting_state != alarm_setting_idx_pitch)) {
for (i = 0; i <= state->alarm[state->alarm_idx].pitch && i < 3; i++)
watch_set_pixel(_buzzer_segdata[i][0], _buzzer_segdata[i][1]);
}
// draw beep rounds indicator
if ((subsecond % 2) == 0 || (state->setting_state != alarm_setting_idx_beeps)) {
if (state->alarm[state->alarm_idx].beeps == ALARM_MAX_BEEP_ROUNDS - 1)
watch_display_character('L', _blink_idx[alarm_setting_idx_beeps]);
else {
if (state->alarm[state->alarm_idx].beeps == 0)
watch_display_character('o', _blink_idx[alarm_setting_idx_beeps]);
else
watch_display_character(state->alarm[state->alarm_idx].beeps + 48, _blink_idx[alarm_setting_idx_beeps]);
}
}
}
// set alarm indicator
_alarm_set_signal(state);
}
static void _alarm_initiate_setting(movement_settings_t *settings, alarm_state_t *state, uint8_t subsecond) {
state->is_setting = true;
state->setting_state = 0;
movement_request_tick_frequency(4);
_alarm_face_draw(settings, state, subsecond);
}
static void _alarm_resume_setting(movement_settings_t *settings, alarm_state_t *state, uint8_t subsecond) {
state->is_setting = false;
movement_request_tick_frequency(1);
_alarm_face_draw(settings, state, subsecond);
}
static void _alarm_update_alarm_enabled(movement_settings_t *settings, alarm_state_t *state) {
// save indication for active alarms to movement settings
bool active_alarms = false;
watch_date_time now;
bool now_init = false;
uint8_t weekday_idx;
uint16_t now_minutes_of_day;
uint16_t alarm_minutes_of_day;
for (uint8_t i = 0; i < ALARM_ALARMS; i++) {
if (state->alarm[i].enabled) {
// figure out if alarm is to go off in the next 24 h
if (state->alarm[i].day == ALARM_DAY_EACH_DAY || state->alarm[i].day == ALARM_DAY_ONE_TIME) {
active_alarms = true;
break;
} else {
if (!now_init) {
now = watch_rtc_get_date_time();
now_init = true;
weekday_idx = _get_weekday_idx(now);
now_minutes_of_day = now.unit.hour * 60 + now.unit.minute;
}
alarm_minutes_of_day = state->alarm[i].hour * 60 + state->alarm[i].minute;
// no more shortcuts: check days and times for all possible cases...
if ((state->alarm[i].day == weekday_idx && alarm_minutes_of_day >= now_minutes_of_day)
|| ((weekday_idx + 1) % 7 == state->alarm[i].day && alarm_minutes_of_day <= now_minutes_of_day)
|| (state->alarm[i].day == ALARM_DAY_WORKDAY && (weekday_idx < 4
|| (weekday_idx == 4 && alarm_minutes_of_day >= now_minutes_of_day)
|| (weekday_idx == 6 && alarm_minutes_of_day <= now_minutes_of_day)))
|| (state->alarm[i].day == ALARM_DAY_WEEKEND && (weekday_idx == 5
|| (weekday_idx == 6 && alarm_minutes_of_day >= now_minutes_of_day)
|| (weekday_idx == 4 && alarm_minutes_of_day <= now_minutes_of_day)))) {
active_alarms = true;
break;
}
}
}
}
settings->bit.alarm_enabled = active_alarms;
}
static void _alarm_play_short_beep(uint8_t pitch_idx) {
// play a short double beep
watch_buzzer_play_note(_buzzer_notes[pitch_idx], 50);
watch_buzzer_play_note(BUZZER_NOTE_REST, 50);
watch_buzzer_play_note(_buzzer_notes[pitch_idx], 70);
}
static void _alarm_indicate_beep(alarm_state_t *state) {
// play an example for the current beep setting
if (state->alarm[state->alarm_idx].beeps == 0) {
// short double beep
_alarm_play_short_beep(state->alarm[state->alarm_idx].pitch);
} else {
// regular alarm beep
movement_play_alarm_beeps(1, _buzzer_notes[state->alarm[state->alarm_idx].pitch]);
}
}
static void _abort_quick_ticks(alarm_state_t *state) {
// abort counting quick ticks
if (state->alarm_quick_ticks) {
state->alarm[state->alarm_idx].enabled = true;
state->alarm_quick_ticks = false;
movement_request_tick_frequency(4);
}
}
void alarm_face_setup(movement_settings_t *settings, uint8_t watch_face_index, void **context_ptr) {
(void) settings;
(void) watch_face_index;
if (*context_ptr == NULL) {
*context_ptr = malloc(sizeof(alarm_state_t));
alarm_state_t *state = (alarm_state_t *)*context_ptr;
memset(*context_ptr, 0, sizeof(alarm_state_t));
// initialize the default alarm values
for (uint8_t i = 0; i < ALARM_ALARMS; i++) {
state->alarm[i].day = ALARM_DAY_EACH_DAY;
state->alarm[i].beeps = 5;
state->alarm[i].pitch = 1;
}
state->alarm_handled_minute = -1;
_wait_ticks = -1;
}
}
void alarm_face_activate(movement_settings_t *settings, void *context) {
(void) settings;
(void) context;
watch_set_colon();
}
void alarm_face_resign(movement_settings_t *settings, void *context) {
alarm_state_t *state = (alarm_state_t *)context;
state->is_setting = false;
_alarm_update_alarm_enabled(settings, state);
watch_set_led_off();
state->alarm_quick_ticks = false;
_wait_ticks = -1;
movement_request_tick_frequency(1);
}
bool alarm_face_wants_background_task(movement_settings_t *settings, void *context) {
(void) settings;
alarm_state_t *state = (alarm_state_t *)context;
watch_date_time now = watch_rtc_get_date_time();
// just a failsafe: never fire more than one alarm within a minute
if (state->alarm_handled_minute == now.unit.minute) return false;
state->alarm_handled_minute = now.unit.minute;
// check the rest
for (uint8_t i = 0; i < ALARM_ALARMS; i++) {
if (state->alarm[i].enabled) {
if (state->alarm[i].minute == now.unit.minute) {
if (state->alarm[i].hour == now.unit.hour) {
state->alarm_playing_idx = i;
if (state->alarm[i].day == ALARM_DAY_EACH_DAY || state->alarm[i].day == ALARM_DAY_ONE_TIME) return true;
uint8_t weekday_idx = _get_weekday_idx(now);
if (state->alarm[i].day == weekday_idx) return true;
if (state->alarm[i].day == ALARM_DAY_WORKDAY && weekday_idx < 5) return true;
if (state->alarm[i].day == ALARM_DAY_WEEKEND && weekday_idx >= 5) return true;
}
}
}
}
state->alarm_handled_minute = -1;
// update the movement's alarm indicator five times an hour
if (now.unit.minute % 12 == 0) _alarm_update_alarm_enabled(settings, state);
return false;
}
bool alarm_face_loop(movement_event_t event, movement_settings_t *settings, void *context) {
(void) settings;
alarm_state_t *state = (alarm_state_t *)context;
switch (event.event_type) {
case EVENT_TICK:
if (state->alarm_quick_ticks) {
// we are in fast cycling mode
if (state->setting_state == alarm_setting_idx_hour) {
state->alarm[state->alarm_idx].hour = (state->alarm[state->alarm_idx].hour + 1) % 24;
} else if (state->setting_state == alarm_setting_idx_minute) {
state->alarm[state->alarm_idx].minute = (state->alarm[state->alarm_idx].minute + 1) % 60;
} else _abort_quick_ticks(state);
} else if (!state->is_setting) {
if (_wait_ticks >= 0) _wait_ticks++;
if (_wait_ticks == 2) {
// extra long press of alarm button
_wait_ticks = -1;
if (state->alarm_idx) {
// revert change of enabled flag and show it briefly
state->alarm[state->alarm_idx].enabled ^= 1;
_alarm_set_signal(state);
delay_ms(275);
state->alarm_idx = 0;
}
} else break; // no need to do anything when we are not in settings mode and no quick ticks are running
}
// fall through
case EVENT_ACTIVATE:
_alarm_face_draw(settings, state, event.subsecond);
break;
case EVENT_LIGHT_BUTTON_UP:
if (!state->is_setting) {
movement_illuminate_led();
_alarm_initiate_setting(settings, state, event.subsecond);
break;
}
state->setting_state += 1;
if (state->setting_state >= ALARM_SETTING_STATES) {
// we have done a full settings cycle, so resume to normal
_alarm_resume_setting(settings, state, event.subsecond);
}
break;
case EVENT_LIGHT_LONG_PRESS:
if (state->is_setting) {
_alarm_resume_setting(settings, state, event.subsecond);
} else {
_alarm_initiate_setting(settings, state, event.subsecond);
}
break;
case EVENT_ALARM_BUTTON_UP:
if (!state->is_setting) {
// stop wait ticks counter
_wait_ticks = -1;
// cycle through the alarms
state->alarm_idx = (state->alarm_idx + 1) % (ALARM_ALARMS);
} else {
// handle the settings behaviour
switch (state->setting_state) {
case alarm_setting_idx_alarm:
// alarm selection
state->alarm_idx = (state->alarm_idx + 1) % (ALARM_ALARMS);
break;
case alarm_setting_idx_day:
// day selection
state->alarm[state->alarm_idx].day = (state->alarm[state->alarm_idx].day + 1) % (ALARM_DAY_STATES);
break;
case alarm_setting_idx_hour:
// hour selection
_abort_quick_ticks(state);
state->alarm[state->alarm_idx].hour = (state->alarm[state->alarm_idx].hour + 1) % 24;
break;
case alarm_setting_idx_minute:
// minute selection
_abort_quick_ticks(state);
state->alarm[state->alarm_idx].minute = (state->alarm[state->alarm_idx].minute + 1) % 60;
break;
case alarm_setting_idx_pitch:
// pitch level
state->alarm[state->alarm_idx].pitch = (state->alarm[state->alarm_idx].pitch + 1) % 3;
// play sound to show user what this is for
_alarm_indicate_beep(state);
break;
case alarm_setting_idx_beeps:
// number of beeping rounds selection
state->alarm[state->alarm_idx].beeps = (state->alarm[state->alarm_idx].beeps + 1) % ALARM_MAX_BEEP_ROUNDS;
// play sounds when user reaches 'short' length and also one time on regular beep length
if (state->alarm[state->alarm_idx].beeps <= 1) _alarm_indicate_beep(state);
break;
default:
break;
}
// auto enable an alarm if user sets anything
if (state->setting_state > alarm_setting_idx_alarm) state->alarm[state->alarm_idx].enabled = true;
}
_alarm_face_draw(settings, state, event.subsecond);
break;
case EVENT_ALARM_LONG_PRESS:
if (!state->is_setting) {
// toggle the enabled flag for current alarm
state->alarm[state->alarm_idx].enabled ^= 1;
// start wait ticks counter
_wait_ticks = 0;
} else {
// handle the long press settings behaviour
switch (state->setting_state) {
case alarm_setting_idx_alarm:
// alarm selection
state->alarm_idx = 0;
break;
case alarm_setting_idx_minute:
case alarm_setting_idx_hour:
// initiate fast cycling for hour or minute settings
movement_request_tick_frequency(8);
state->alarm_quick_ticks = true;
break;
default:
break;
}
}
_alarm_face_draw(settings, state, event.subsecond);
break;
case EVENT_ALARM_LONG_UP:
if (state->is_setting) {
if (state->setting_state == alarm_setting_idx_hour || state->setting_state == alarm_setting_idx_minute)
_abort_quick_ticks(state);
} else _wait_ticks = -1;
break;
case EVENT_BACKGROUND_TASK:
// play alarm
if (state->alarm[state->alarm_playing_idx].beeps == 0) {
// short beep
if (watch_is_buzzer_or_led_enabled()) {
_alarm_play_short_beep(state->alarm[state->alarm_playing_idx].pitch);
} else {
// enable, play beep and disable buzzer again
watch_enable_buzzer();
_alarm_play_short_beep(state->alarm[state->alarm_playing_idx].pitch);
watch_disable_buzzer();
}
} else {
// regular alarm beeps
movement_play_alarm_beeps((state->alarm[state->alarm_playing_idx].beeps == (ALARM_MAX_BEEP_ROUNDS - 1) ? 20 : state->alarm[state->alarm_playing_idx].beeps),
_buzzer_notes[state->alarm[state->alarm_playing_idx].pitch]);
}
// one time alarm? -> erase it
if (state->alarm[state->alarm_playing_idx].day == ALARM_DAY_ONE_TIME) {
state->alarm[state->alarm_playing_idx].day = ALARM_DAY_EACH_DAY;
state->alarm[state->alarm_playing_idx].minute = state->alarm[state->alarm_playing_idx].hour = 0;
state->alarm[state->alarm_playing_idx].beeps = 5;
state->alarm[state->alarm_playing_idx].pitch = 1;
state->alarm[state->alarm_playing_idx].enabled = false;
_alarm_update_alarm_enabled(settings, state);
}
break;
case EVENT_TIMEOUT:
movement_move_to_face(0);
break;
case EVENT_LIGHT_BUTTON_DOWN:
// don't light up every time light is hit
break;
default:
movement_default_loop_handler(event, settings);
break;
}
return true;
}
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