stm32f1/application.c

/* This program is free software: you can redistribute it and/or modify
 * it under the terms of the GNU General Public License as published by
 * the Free Software Foundation, either version 3 of the License, or
 * (at your option) any later version.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program.  If not, see <http://www.gnu.org/licenses/>.
 *
 */
/** dachboden front panel access control
 *  @file
 *  @author King Kévin <kingkevin@cuvoodoo.info>
 *  @date 2016-2020
 */

/* standard libraries */
#include <stdint.h> // standard integer types
#include <stdlib.h> // standard utilities
#include <string.h> // string utilities
#include <time.h> // date/time utilities
#include <ctype.h> // utilities to check chars

/* STM32 (including CM3) libraries */
#include <libopencmsis/core_cm3.h> // Cortex M3 utilities
#include <libopencm3/cm3/scb.h> // vector table definition
#include <libopencm3/cm3/nvic.h> // interrupt utilities
#include <libopencm3/stm32/gpio.h> // general purpose input output library
#include <libopencm3/stm32/rcc.h> // real-time control clock library
#include <libopencm3/stm32/exti.h> // external interrupt utilities
#include <libopencm3/stm32/rtc.h> // real time clock utilities
#include <libopencm3/stm32/iwdg.h> // independent watchdog utilities
#include <libopencm3/stm32/dbgmcu.h> // debug utilities
#include <libopencm3/stm32/desig.h> // design utilities
#include <libopencm3/stm32/flash.h> // flash utilities
#include <libopencm3/stm32/f1/bkp.h> // backup domain utilities
#include <libopencm3/stm32/timer.h> // timer utilities

/* own libraries */
#include "global.h" // board definitions
#include "print.h" // printing utilities
#include "uart.h" // USART utilities
#include "usb_cdcacm.h" // USB CDC ACM utilities
#include "terminal.h" // handle the terminal interface
#include "menu.h" // menu utilities
#include "led_ws2812b.h" // WS2812B RGB LED control

/** watchdog period in ms */
#define WATCHDOG_PERIOD 10000

/** set to 0 if the RTC is reset when the board is powered on, only indicates the uptime
 *  set to 1 if VBAT can keep the RTC running when the board is unpowered, indicating the date and time
 */
#define RTC_DATE_TIME 1

/** number of RTC ticks per second
 *  @note use integer divider of oscillator to keep second precision
 */
#define RTC_TICKS_SECOND 1

#if defined(RTC_DATE_TIME) && RTC_DATE_TIME
/** the start time from which to RTC ticks count
 *  @note this allows the 32-bit value to reach further in time, particularly when there are several ticks per second
 */
const time_t rtc_offset = 1577833200; // We 1. Jan 00:00:00 CET 2020
#endif

/** RTC time when device is started */
static time_t time_start = 0;

/** @defgroup main_flags flag set in interrupts to be processed in main task
 *  @{
 */
volatile bool rtc_internal_tick_flag = false; /**< flag set when internal RTC ticked */
/** @} */

/** GPIO pin connected to relay, used to control button connection to panel */
#define RELAY_PANEL_PIN PB6
/** GPIO pin connected to relay, used to simulate button press */
#define RELAY_BUTTON_PIN PB7
/** GPIO for button 1 */
#define BUTTON1_PIN PB9
/** GPIO for button 2 */
#define BUTTON2_PIN PB8

/** which button has been pressed */
volatile uint8_t button_pressed = 0;

/** if we apply the opening policy */
bool opening_apply = false;
uint8_t pattern_length = 0;

static struct opening_settings_t {
	uint8_t days; /**< which days of the week it door access applies (bit 7 = Monday) */
	uint16_t start_time; /**< at which minutes of the day to start */
	uint16_t stop_time; /**< at which minutes of the day to stop */
	uint8_t button_pattern[10]; /**< sequence of buttons to press to open the door */
} opening_settings;

/** timer to generate the ticks for the button LED animations */
#define LED_ANIMATION_TIMER 2

/** number of timer ticks passed, for the LED animation */
static volatile uint8_t led_animation_ticks = 0;

/** the button LED animation for the rust fade (duration in ticks, R, G, B) */
static const uint8_t rust_animation[][4] = {
	{0, 0, 0, 0},
	{1, 0xb7 / 10 * 1, 0x41 / 10 * 1, 0x0e / 10 * 1},
	{1, 0xb7 / 10 * 2, 0x41 / 10 * 2, 0x0e / 10 * 2},
	{1, 0xb7 / 10 * 3, 0x41 / 10 * 3, 0x0e / 10 * 3},
	{1, 0xb7 / 10 * 4, 0x41 / 10 * 4, 0x0e / 10 * 4},
	{1, 0xb7 / 10 * 5, 0x41 / 10 * 5, 0x0e / 10 * 5},
	{1, 0xb7 / 10 * 4, 0x41 / 10 * 4, 0x0e / 10 * 4},
	{1, 0xb7 / 10 * 3, 0x41 / 10 * 3, 0x0e / 10 * 3},
	{1, 0xb7 / 10 * 2, 0x41 / 10 * 2, 0x0e / 10 * 2},
	{1, 0xb7 / 10 * 1, 0x41 / 10 * 1, 0x0e / 10 * 1},
	{0, 0, 0, 0},
};

/** the button LED animation for the strobe (duration in ticks, R, G, B) */
static const uint8_t strobe_animation[][4] = {
	{0, 0, 0, 0},
	{1, 0xff / 2, 0xff / 2, 0xff / 2},
	{2, 0, 0, 0},
	{1, 0xff / 2, 0xff / 2, 0xff / 2},
	{0, 0, 0, 0},
};

/** save current opening_settings into SRAM */
static void save_opening_settings(void)
{
	BKP_DR1 = 0; // invalid saved settings
	BKP_DR2 = opening_settings.days & 0x7f;
	BKP_DR3 = opening_settings.start_time;
	BKP_DR4 = opening_settings.stop_time;
	BKP_DR5 = opening_settings.button_pattern[0];
	BKP_DR6 = opening_settings.button_pattern[1];
	BKP_DR7 = opening_settings.button_pattern[2];
	BKP_DR8 = opening_settings.button_pattern[3];
	BKP_DR9 = opening_settings.button_pattern[4];
	BKP_DR10 = opening_settings.button_pattern[5];
	BKP_DR11 = opening_settings.button_pattern[6];
	BKP_DR12 = opening_settings.button_pattern[7];
	BKP_DR13 = opening_settings.button_pattern[8];
	BKP_DR14 = opening_settings.button_pattern[9];
	BKP_DR1 = 0x4223; //validate saved setting
}

size_t putc(char c)
{
	size_t length = 0; // number of characters printed
	static char last_c = 0; // to remember on which character we last sent
	if ('\n' == c) { // send carriage return (CR) + line feed (LF) newline for each LF
		if ('\r' != last_c) { // CR has not already been sent
#if !defined(STLINKV2)
			uart_putchar_nonblocking('\r'); // send CR over USART
#endif
			usb_cdcacm_putchar('\r'); // send CR over USB
			length++; // remember we printed 1 character
		}
	}
#if !defined(STLINKV2)
	uart_putchar_nonblocking(c); // send byte over USART
#endif
	usb_cdcacm_putchar(c); // send byte over USB
	length++; // remember we printed 1 character
	last_c = c; // remember last character
	return length; // return number of characters printed
}

/** display available commands
 *  @param[in] argument no argument required
 */
static void command_help(void* argument);

/** show software and hardware version
 *  @param[in] argument no argument required
 */
static void command_version(void* argument);

/** show uptime
 *  @param[in] argument no argument required
 */
static void command_uptime(void* argument);

#if RTC_DATE_TIME
/** show date and time
 *  @param[in] argument date and time to set
 */
static void command_datetime(void* argument);
#endif

/** reset board
 *  @param[in] argument no argument required
 */
static void command_reset(void* argument);

/** switch to DFU bootloader
 *  @param[in] argument no argument required
 */
static void command_bootloader_dfu(void* argument);

/** switch to system memory / embedded USART bootloader
 *  @param[in] argument no argument required
 */
static void command_bootloader_embedded(void* argument);

/** show/set on which days the access policy applies
 *  @param[in] argument 7x0/1 to enable day of the week, starting with Monday (optional)
 */
static void command_days(void* argument)
{
	const char* days = (char*)argument; // argument is optional days
	if (NULL != argument) { // days are provided, parse and save them
		bool valid = (7 == strlen(days)); // verify input string
		for (uint8_t day = 0; day < 7 && valid; day++) {
			if (days[day] != '0' && days[day] != '1') {
				valid = false;
			}
		}
		if (valid) { // save provided settings
			// parse new days
			opening_settings.days = 0;
			for (uint8_t day = 0; day < 7; day++) {
				if ('1' == days[day]) {
					opening_settings.days |= (1 << (6 - day));
				}
			}
			save_opening_settings(); // save days
			puts("days saved\n");
		} else {
			puts("provide exactly 7 times 0 (off) or 1 (on). 1st digit for Monday, 7th digit for Sunday\n");
		}
	}
	// display current days
	printf("opening days: %07b\n", opening_settings.days);
	const char* day_names[] = {"Monday", "Tuesday", "Wednesday", "Thursday", "Friday", "Saturday", "Sunday"};
	for (uint8_t day = 0; day < LENGTH(day_names); day++) {
		printf("- %s: %s\n", day_names[day], (opening_settings.days & (1 << (6 - day))) ? "on" : "off");
	}
}

/** show/set on which time the access policy starts applying
 *  @param[in] argument string with time of day, optional
 */
static void command_start(void* argument)
{
	const char* time = (char*)argument; // argument is optional time
	if (NULL != argument) { // days are provided, parse and save them
		bool valid = (5 == strlen(time)); // verify input string
		if (!(valid && isdigit((int8_t)time[0]) && isdigit((int8_t)time[1]) && ':' == time[2] && isdigit((int8_t)time[3]) && isdigit((int8_t)time[4]))) {
			valid = false;
		}
		if (valid) { // save provided settings
			opening_settings.start_time = 0;
			opening_settings.start_time += (time[4] - '0') * 1;
			opening_settings.start_time += (time[3] - '0') * 10;
			opening_settings.start_time += (time[1] - '0') * 60;
			opening_settings.start_time += (time[0] - '0') * 600;
			save_opening_settings(); // save days
			puts("start time saved\n");
		} else {
			puts("provide time in HH:MM format\n");
		}
	}
	printf("start time: %02u:%02u\n", opening_settings.start_time / 60, opening_settings.start_time % 60);
}

/** show/set on which time the access policy stops applying
 *  @param[in] argument string with time of day, optional
 */
static void command_stop(void* argument)
{
	const char* time = (char*)argument; // argument is optional time
	if (NULL != argument) { // days are provided, parse and save them
		bool valid = (5 == strlen(time)); // verify input string
		if (!(valid && isdigit((int8_t)time[0]) && isdigit((int8_t)time[1]) && ':' == time[2] && isdigit((int8_t)time[3]) && isdigit((int8_t)time[4]))) {
			valid = false;
		}
		if (valid) { // save provided settings
			opening_settings.stop_time = 0;
			opening_settings.stop_time += (time[4] - '0') * 1;
			opening_settings.stop_time += (time[3] - '0') * 10;
			opening_settings.stop_time += (time[1] - '0') * 60;
			opening_settings.stop_time += (time[0] - '0') * 600;
			save_opening_settings(); // save days
			puts("stop time saved\n");
		} else {
			puts("provide time in HH:MM format\n");
		}
	}
	printf("stop time: %02u:%02u\n", opening_settings.stop_time / 60, opening_settings.stop_time % 60);
}

/** open door by simulating button press
 *  @param[in] argument not used
 */
static void command_open(void* argument)
{
	(void)argument; // we won't use the argument
	gpio_set(GPIO_PORT(RELAY_PANEL_PIN), GPIO_PIN(RELAY_PANEL_PIN)); // set high to activate relay and take control over the button
	gpio_set(GPIO_PORT(RELAY_BUTTON_PIN), GPIO_PIN(RELAY_BUTTON_PIN)); // set high to activate relay an simulate button press
	sleep_ms(1000); // hold button a bit
	gpio_clear(GPIO_PORT(RELAY_BUTTON_PIN), GPIO_PIN(RELAY_BUTTON_PIN)); // set low to deactivate relay and release button
	if (!opening_apply) {
		gpio_clear(GPIO_PORT(RELAY_PANEL_PIN), GPIO_PIN(RELAY_PANEL_PIN)); // set low to deactivate relay and git control back to button
	}
}

/** show/set button pattern
 *  @param[in] argument sequence of 1/2
 */
static void command_pattern(void* argument)
{
	const char* pattern = (char*)argument; // argument is optional pattern
	if (NULL != argument) { // pattern provided
		bool valid = (LENGTH(opening_settings.button_pattern) >= strlen(pattern)); // verify input string
		for (uint8_t i = 0; i < strlen(pattern) && valid; i++) {
			if ('1' != pattern[i] && '2' != pattern[i]) {
				valid = false;
			}
		}
		if (valid) { // save provided settings
			// reset pattern
			for (uint8_t i = 0; i < LENGTH(opening_settings.button_pattern); i++) {
				opening_settings.button_pattern[i] = 0;
			}
			// save new pattern
			for (uint8_t i = 0; i < strlen(pattern); i++) {
				opening_settings.button_pattern[i] = pattern[i] - '0';
			}
			save_opening_settings(); // save days
			puts("button sequence saved\n");
		} else {
			printf("provide buttons sequence of up to %u 1 or 2\n", LENGTH(opening_settings.button_pattern));
		}
		for (pattern_length = 0; pattern_length < LENGTH(opening_settings.button_pattern) && opening_settings.button_pattern[pattern_length]; pattern_length++);
	}
	if (0 == opening_settings.button_pattern[0]) {
		puts("no button sequence set\n");
	} else {
		puts("button sequence: ");
		for (uint8_t i = 0; i < LENGTH(opening_settings.button_pattern) && opening_settings.button_pattern[i]; i++) {
			putc(opening_settings.button_pattern[i] + '0');
		}
		putc('\n');
	}
}

/** test LEDs
 *  @param[in] argument "on" or "off"
 */
static void command_led(void* argument)
{
	const char* onoff  = (char*)argument; // if it should be switched on or off
	if (NULL == onoff || 0 == strlen(onoff)) {
		puts("say if the LEDs should be switched on or off\n");
	} else if (0 == strcmp(onoff, "on")) {
		for (uint8_t led = 0; led < LED_WS2812B_LEDS; led++) {
			led_ws2812b_set_rgb(led, 0x20, 0x20 , 0x20);
		}
	} else if (0 == strcmp(onoff, "off")) {
		for (uint8_t led = 0; led < LED_WS2812B_LEDS; led++) {
			led_ws2812b_set_rgb(led, 0, 0 , 0);
		}
	} else {
		printf("unknown argument %s\n", onoff);
	}
}

/** list of all supported commands */
static const struct menu_command_t menu_commands[] = {
	{
		.shortcut = 'h',
		.name = "help",
		.command_description = "display help",
		.argument = MENU_ARGUMENT_NONE,
		.argument_description = NULL,
		.command_handler = &command_help,
	},
	{
		.shortcut = 'v',
		.name = "version",
		.command_description = "show software and hardware version",
		.argument = MENU_ARGUMENT_NONE,
		.argument_description = NULL,
		.command_handler = &command_version,
	},
	{
		.shortcut = 'u',
		.name = "uptime",
		.command_description = "show uptime",
		.argument = MENU_ARGUMENT_NONE,
		.argument_description = NULL,
		.command_handler = &command_uptime,
	},
#if RTC_DATE_TIME
	{
		.shortcut = 'D',
		.name = "date",
		.command_description = "show/set date and time",
		.argument = MENU_ARGUMENT_STRING,
		.argument_description = "[YYYY-MM-DD HH:MM:SS]",
		.command_handler = &command_datetime,
	},
#endif
	{
		.shortcut = 'r',
		.name = "reset",
		.command_description = "reset board",
		.argument = MENU_ARGUMENT_NONE,
		.argument_description = NULL,
		.command_handler = &command_reset,
	},
	{
		.shortcut = 'b',
		.name = "bootloader",
		.command_description = "reboot into DFU bootloader",
		.argument = MENU_ARGUMENT_NONE,
		.argument_description = NULL,
		.command_handler = &command_bootloader_dfu,
	},
	{
		.shortcut = 'B',
		.name = "embedded",
		.command_description = "boot embedded USART bootloader",
		.argument = MENU_ARGUMENT_NONE,
		.argument_description = NULL,
		.command_handler = &command_bootloader_embedded,
	},
	{
		.shortcut = 'd',
		.name = "days",
		.command_description = "on which days to apply the access policy",
		.argument = MENU_ARGUMENT_STRING,
		.argument_description = "[0001000, 0/1 for Monday to Sunday]",
		.command_handler = &command_days,
	},
	{
		.shortcut = 's',
		.name = "start",
		.command_description = "on which time to start the access policy",
		.argument = MENU_ARGUMENT_STRING,
		.argument_description = "[HH:MM]",
		.command_handler = &command_start,
	},
	{
		.shortcut = 'S',
		.name = "stop",
		.command_description = "on which time to stop the access policy",
		.argument = MENU_ARGUMENT_STRING,
		.argument_description = "[HH:MM]",
		.command_handler = &command_stop,
	},
	{
		.shortcut = 'o',
		.name = "open",
		.command_description = "open door",
		.argument = MENU_ARGUMENT_NONE,
		.argument_description = NULL,
		.command_handler = &command_open,
	},
	{
		.shortcut = 'l',
		.name = "led",
		.command_description = "test LEDs",
		.argument = MENU_ARGUMENT_STRING,
		.argument_description = "on|off",
		.command_handler = &command_led,
	},
	{
		.shortcut = 'p',
		.name = "password",
		.command_description = "set/show password button sequence",
		.argument = MENU_ARGUMENT_STRING,
		.argument_description = "[sequence of 1/2]",
		.command_handler = &command_pattern,
	},
};

static void command_help(void* argument)
{
	(void)argument; // we won't use the argument
	printf("available commands:\n");
	menu_print_commands(menu_commands, LENGTH(menu_commands)); // print global commands
}

static void command_version(void* argument)
{
	(void)argument; // we won't use the argument
	printf("firmware date: %04u-%02u-%02u\n", BUILD_YEAR, BUILD_MONTH, BUILD_DAY); // show firmware build date
	const uint16_t dev_id = DBGMCU_IDCODE & DBGMCU_IDCODE_DEV_ID_MASK;
	const uint16_t rev_id = DBGMCU_IDCODE >> 16;
	printf("chip: ID=0x%03x, rev=0x%04x\n", dev_id, rev_id);
	// show flash size
	puts("flash size: ");
	if (0xffff == DESIG_FLASH_SIZE) {
		puts("unknown (probably a defective micro-controller\n");
	} else {
		printf("%u KB\n", DESIG_FLASH_SIZE);
	}
	// display device identity
	printf("device id: %08x%08x%04x%04x\n", DESIG_UNIQUE_ID2, DESIG_UNIQUE_ID1, DESIG_UNIQUE_ID0 & 0xffff, DESIG_UNIQUE_ID0 >> 16);
}

static void command_uptime(void* argument)
{
	(void)argument; // we won't use the argument
	uint32_t uptime = (rtc_get_counter_val() - time_start) / RTC_TICKS_SECOND; // get time from internal RTC
	printf("uptime: %u.%02u:%02u:%02u\n", uptime / (24 * 60 * 60), (uptime / (60 * 60)) % 24, (uptime / 60) % 60, uptime % 60);
}

#if RTC_DATE_TIME
static void command_datetime(void* argument)
{
	char* datetime = (char*)argument; // argument is optional date time
	if (NULL == argument) { // no date and time provided, just show the current day and time
		const time_t time_rtc = rtc_get_counter_val() / RTC_TICKS_SECOND + rtc_offset; // get time from internal RTC
		const struct tm* time_tm = localtime(&time_rtc); // convert time
		const char* days[] = { "Su", "Mo", "Tu", "We", "Th", "Fr", "Sa"}; // the days of the week
		printf("date: %s %d-%02d-%02d %02d:%02d:%02d\n", days[time_tm->tm_wday], 1900 + time_tm->tm_year, 1 + time_tm->tm_mon, time_tm->tm_mday, time_tm->tm_hour, time_tm->tm_min, time_tm->tm_sec);
	} else { // date and time provided, set it
		const char* malformed = "date and time malformed, expecting YYYY-MM-DD HH:MM:SS\n";
		struct tm time_tm; // to store the parsed date time
		if (strlen(datetime) != (4 + 1 + 2 + 1 + 2) + 1 + (2 + 1 + 2 + 1 + 2)) { // verify date/time is long enough
			printf(malformed);
			return;
		}
		if (!(isdigit((int8_t)datetime[0]) && isdigit((int8_t)datetime[1]) && isdigit((int8_t)datetime[2]) && isdigit((int8_t)datetime[3]) && '-' == datetime[4] && isdigit((int8_t)datetime[5]) && isdigit((int8_t)datetime[6]) && '-' == datetime[7] && isdigit((int8_t)datetime[8]) && isdigit((int8_t)datetime[9]) && ' ' == datetime[10] && isdigit((int8_t)datetime[11]) && isdigit((int8_t)datetime[12]) && ':' == datetime[13] && isdigit((int8_t)datetime[14]) && isdigit((int8_t)datetime[15]) && ':' == datetime[16] && isdigit((int8_t)datetime[17]) && isdigit((int8_t)datetime[18]))) { // verify format (good enough to not fail parsing)
			printf(malformed);
			return;
		}
		time_tm.tm_year = strtol(&datetime[0], NULL, 10) - 1900; // parse year
		time_tm.tm_mon = strtol(&datetime[5], NULL, 10) - 1; // parse month
		time_tm.tm_mday = strtol(&datetime[8], NULL, 10); // parse day
		time_tm.tm_hour = strtol(&datetime[11], NULL, 10); // parse hour
		time_tm.tm_min = strtol(&datetime[14], NULL, 10); // parse minutes
		time_tm.tm_sec = strtol(&datetime[17], NULL, 10); // parse seconds
		time_t time_rtc = mktime(&time_tm); // get back seconds
		time_rtc -= rtc_offset; // remove start offset
		time_start = time_rtc * RTC_TICKS_SECOND + (rtc_get_counter_val() - time_start); // update uptime with current date
		rtc_set_counter_val(time_rtc * RTC_TICKS_SECOND); // save date/time to internal RTC
		printf("date and time saved: %d-%02d-%02d %02d:%02d:%02d\n", 1900 + time_tm.tm_year, 1 + time_tm.tm_mon, time_tm.tm_mday, time_tm.tm_hour, time_tm.tm_min, time_tm.tm_sec);
	}
}
#endif

static void command_reset(void* argument)
{
	(void)argument; // we won't use the argument
	scb_reset_system(); // reset device
	while (true); // wait for the reset to happen
}

static void command_bootloader_dfu(void* argument)
{
	(void)argument; // we won't use the argument
	// disable relays
	gpio_clear(GPIO_PORT(RELAY_PANEL_PIN), GPIO_PIN(RELAY_PANEL_PIN));
	gpio_clear(GPIO_PORT(RELAY_BUTTON_PIN), GPIO_PIN(RELAY_BUTTON_PIN));
	// set DFU magic to specific RAM location
	__dfu_magic[0] = 'D';
	__dfu_magic[1] = 'F';
	__dfu_magic[2] = 'U';
	__dfu_magic[3] = '!';
	scb_reset_system(); // reset system (core and peripherals)
	while (true); // wait for the reset to happen
}

static void command_bootloader_embedded(void* argument)
{
	(void)argument; // we won't use the argument
	// disable relays
	gpio_clear(GPIO_PORT(RELAY_PANEL_PIN), GPIO_PIN(RELAY_PANEL_PIN));
	gpio_clear(GPIO_PORT(RELAY_BUTTON_PIN), GPIO_PIN(RELAY_BUTTON_PIN));
	// set watchdog to exit system memory after some time
	iwdg_set_period_ms(25000); // set independent watchdog period (26214.4 ms if the max timeout)
	iwdg_start(); // start independent watchdog
	iwdg_reset(); // restart timer
	// start system memory
	const uint32_t address = 0x1FFFF000; // system memory address
	SCB_VTOR = (volatile uint32_t)(address); // set vector table to application vector table (store at the beginning of the application)
	__asm__ volatile ("MSR msp,%0" : :"r"(*(uint32_t*)address)); // set stack pointer to address provided in the beginning of the application (loaded into a register first)
	(*(void(**)(void))((uint32_t)address + 4))(); // start system memory (by jumping to the reset function which address is stored as second entry of the vector table)
	while (true); // this should not be reached
}

/** process user command
 *  @param[in] str user command string (\0 ended)
 */
static void process_command(char* str)
{
	// ensure actions are available
	if (NULL == menu_commands || 0 == LENGTH(menu_commands)) {
		return;
	}
	// don't handle empty lines
	if (!str || 0 == strlen(str)) {
		return;
	}
	bool command_handled = false;
	if (!command_handled) {
		command_handled = menu_handle_command(str, menu_commands, LENGTH(menu_commands)); // try if this is not a global command
	}
	if (!command_handled) {
		printf("command not recognized. enter help to list commands\n");
	}
}

/** program entry point
 *  this is the firmware function started by the micro-controller
 */
void main(void);
void main(void)
{
	rcc_clock_setup_in_hse_8mhz_out_72mhz(); // use 8 MHz high speed external clock to generate 72 MHz internal clock

#if DEBUG
	// enable functionalities for easier debug
	DBGMCU_CR |= DBGMCU_CR_IWDG_STOP; // stop independent watchdog counter when code is halted
	DBGMCU_CR |= DBGMCU_CR_WWDG_STOP; // stop window watchdog counter when code is halted
	DBGMCU_CR |= DBGMCU_CR_STANDBY; // allow debug also in standby mode (keep digital part and clock powered)
	DBGMCU_CR |= DBGMCU_CR_STOP; // allow debug also in stop mode (keep clock powered)
	DBGMCU_CR |= DBGMCU_CR_SLEEP; // allow debug also in sleep mode (keep clock powered)
#else
	// setup watchdog to reset in case we get stuck (i.e. when an error occurred)
	iwdg_set_period_ms(WATCHDOG_PERIOD); // set independent watchdog period
	iwdg_start(); // start independent watchdog
#endif

	board_setup(); // setup board
#if !defined(STLINKV2)
	uart_setup(); // setup USART (for printing)
#endif
	usb_cdcacm_setup(); // setup USB CDC ACM (for printing)
	puts("\nwelcome to the dachboden door panel\n"); // print welcome message

#if DEBUG
	// show reset cause
	if (RCC_CSR & (RCC_CSR_LPWRRSTF | RCC_CSR_WWDGRSTF | RCC_CSR_IWDGRSTF | RCC_CSR_SFTRSTF | RCC_CSR_PORRSTF | RCC_CSR_PINRSTF)) {
		puts("reset cause(s):");
		if (RCC_CSR & RCC_CSR_LPWRRSTF) {
			puts(" low-power");
		}
		if (RCC_CSR & RCC_CSR_WWDGRSTF) {
			puts(" window-watchdog");
		}
		if (RCC_CSR & RCC_CSR_IWDGRSTF) {
			puts(" independent-watchdog");
		}
		if (RCC_CSR & RCC_CSR_SFTRSTF) {
			puts(" software");
		}
		if (RCC_CSR & RCC_CSR_PORRSTF) {
			puts(" POR/PDR");
		}
		if (RCC_CSR & RCC_CSR_PINRSTF) {
			puts(" pin");
		}
		putc('\n');
		RCC_CSR |= RCC_CSR_RMVF; // clear reset flags
	}
#endif
#if !(DEBUG)
	// show watchdog information
	printf("setup watchdog: %.2fs", WATCHDOG_PERIOD / 1000.0);
	if (FLASH_OBR & FLASH_OBR_OPTERR) {
		puts(" (option bytes not set in flash: software wachtdog used, not automatically started at reset)\n");
	} else if (FLASH_OBR & FLASH_OBR_WDG_SW) {
		puts(" (software watchdog used, not automatically started at reset)\n");
	} else {
		puts(" (hardware watchdog used, automatically started at reset)\n");
	}
#endif

	// setup RTC
	puts("setup internal RTC: ");
	// note: the blue pill LSE oscillator is affected when toggling the onboard LED -> DON'T USE THE ONBOARD LED since we want to use the LSE
	rtc_auto_awake(RCC_LSE, 32768 / RTC_TICKS_SECOND - 1); // ensure internal RTC is on, uses the 32.678 kHz LSE, and the prescale is set to our tick speed, else update backup registers accordingly (power off the micro-controller for the change to take effect)
	rtc_interrupt_enable(RTC_SEC); // enable RTC interrupt on "seconds"
	nvic_enable_irq(NVIC_RTC_IRQ); // allow the RTC to interrupt
	time_start = rtc_get_counter_val(); // get start time from internal RTC
	puts("OK\n");

	// setup relays
	puts("setup relays: ");
	rcc_periph_clock_enable(GPIO_RCC(RELAY_PANEL_PIN)); // enable clock for GPIO domain
	gpio_clear(GPIO_PORT(RELAY_PANEL_PIN), GPIO_PIN(RELAY_PANEL_PIN)); // set low to leave per default
	gpio_set_mode(GPIO_PORT(RELAY_PANEL_PIN), GPIO_MODE_OUTPUT_2_MHZ, GPIO_CNF_OUTPUT_PUSHPULL, GPIO_PIN(RELAY_PANEL_PIN)); // set as output to control the transistor controlling the relay
	rcc_periph_clock_enable(GPIO_RCC(RELAY_BUTTON_PIN)); // enable clock for GPIO domain
	gpio_clear(GPIO_PORT(RELAY_BUTTON_PIN), GPIO_PIN(RELAY_BUTTON_PIN)); // set low to leave per default
	gpio_set_mode(GPIO_PORT(RELAY_BUTTON_PIN), GPIO_MODE_OUTPUT_2_MHZ, GPIO_CNF_OUTPUT_PUSHPULL, GPIO_PIN(RELAY_BUTTON_PIN)); // set as output to control the transistor controlling the relay
	puts("OK\n");

	// setup buttons
	puts("setup buttons: ");
	rcc_periph_clock_enable(RCC_AFIO); // enable alternate function clock for external interrupt
	rcc_periph_clock_enable(GPIO_RCC(BUTTON1_PIN)); // enable clock for button
	gpio_set(GPIO_PORT(BUTTON1_PIN), GPIO_PIN(BUTTON1_PIN)); // pull up to be able to detect button push (go low)
	gpio_set_mode(GPIO_PORT(BUTTON1_PIN), GPIO_MODE_INPUT, GPIO_CNF_INPUT_PULL_UPDOWN, GPIO_PIN(BUTTON1_PIN)); // set button pin to input
	exti_select_source(GPIO_EXTI(BUTTON1_PIN), GPIO_PORT(BUTTON1_PIN)); // mask external interrupt of this pin only for this port
	exti_set_trigger(GPIO_EXTI(BUTTON1_PIN), EXTI_TRIGGER_FALLING); // trigger when button is pressed
	exti_enable_request(GPIO_EXTI(BUTTON1_PIN)); // enable external interrupt
	nvic_enable_irq(GPIO_NVIC_EXTI_IRQ(BUTTON1_PIN)); // enable interrupt
	rcc_periph_clock_enable(GPIO_RCC(BUTTON2_PIN)); // enable clock for button
	gpio_set(GPIO_PORT(BUTTON2_PIN), GPIO_PIN(BUTTON2_PIN)); // pull up to be able to detect button push (go low)
	gpio_set_mode(GPIO_PORT(BUTTON2_PIN), GPIO_MODE_INPUT, GPIO_CNF_INPUT_PULL_UPDOWN, GPIO_PIN(BUTTON2_PIN)); // set button pin to input
	exti_select_source(GPIO_EXTI(BUTTON2_PIN), GPIO_PORT(BUTTON2_PIN)); // mask external interrupt of this pin only for this port
	exti_set_trigger(GPIO_EXTI(BUTTON2_PIN), EXTI_TRIGGER_FALLING); // trigger when button is pressed
	exti_enable_request(GPIO_EXTI(BUTTON2_PIN)); // enable external interrupt
	nvic_enable_irq(GPIO_NVIC_EXTI_IRQ(BUTTON2_PIN)); // enable interrupt
	puts("OK\n");

	// read opening settings from SRAM
	puts("reading access settings: ");
	RCC_APB1ENR |= (RCC_APB1ENR_PWREN | RCC_APB1ENR_BKPEN); // enable power
	PWR_CR |= PWR_CR_DBP; // enable access
	if (0x4223 == BKP_DR1) { // the magic header is present
		opening_settings.days = BKP_DR2 & 0x7f;
		opening_settings.start_time = BKP_DR3;
		opening_settings.stop_time = BKP_DR4;
		opening_settings.button_pattern[0] = BKP_DR5;
		opening_settings.button_pattern[1] = BKP_DR6;
		opening_settings.button_pattern[2] = BKP_DR7;
		opening_settings.button_pattern[3] = BKP_DR8;
		opening_settings.button_pattern[4] = BKP_DR9;
		opening_settings.button_pattern[5] = BKP_DR10;
		opening_settings.button_pattern[6] = BKP_DR11;
		opening_settings.button_pattern[7] = BKP_DR12;
		opening_settings.button_pattern[8] = BKP_DR13;
		opening_settings.button_pattern[9] = BKP_DR14;
		puts("loaded\n");
	} else { // there are no settings saved
		memset(&opening_settings, 0, sizeof(struct opening_settings_t)); // clear all values
		puts("default\n");
	}
	// figure out how many button need to be pressed
	for (pattern_length = 0; pattern_length < LENGTH(opening_settings.button_pattern) && opening_settings.button_pattern[pattern_length]; pattern_length++);

	puts("setup bell LEDs: ");
	uint8_t animation_progress = 0; // index of the current animation
	led_ws2812b_setup();
	for (uint8_t led = 0; led < LED_WS2812B_LEDS; led++) {
		led_ws2812b_set_rgb(led, 0x10, 0x10 , 0x10);
	}
	puts("OK\n");

	puts("setup animation timer: ");
	// setup timer to wait for minimal time before next transmission (after previous transmission or reception)
	rcc_periph_clock_enable(RCC_TIM(LED_ANIMATION_TIMER)); // enable clock for timer block
	rcc_periph_reset_pulse(RST_TIM(LED_ANIMATION_TIMER)); // reset timer state
	timer_set_mode(TIM(LED_ANIMATION_TIMER), TIM_CR1_CKD_CK_INT, TIM_CR1_CMS_EDGE, TIM_CR1_DIR_UP); // set timer mode, use undivided timer clock,edge alignment (simple count), and count up
	timer_set_prescaler(TIM(LED_ANIMATION_TIMER), 1099 - 1); // set the prescaler so this 16 bits timer allows to wait for maximum 1s ( 1 / (72E6 / 1099 / (2**16)) = 1.0003s)
	timer_set_period(TIM(LED_ANIMATION_TIMER), 0xffff / 16); // the timing is not defined in the specification. I tested until the communication was reliable (all requests get an response)
	timer_clear_flag(TIM(LED_ANIMATION_TIMER), TIM_SR_UIF); // clear flag
	timer_enable_irq(TIM(LED_ANIMATION_TIMER), TIM_DIER_UIE); // enable update interrupt for timer
	nvic_enable_irq(NVIC_TIM_IRQ(LED_ANIMATION_TIMER)); // catch interrupt in service routine
	puts("OK\n");

	// setup terminal
	terminal_prefix = ""; // set default prefix
	terminal_process = &process_command; // set central function to process commands
	terminal_setup(); // start terminal

	// start main loop
	bool action = false; // if an action has been performed don't go to sleep
	button_flag = false; // reset button flag
	uint32_t last_button_action = 0; // the last time a button has been pressed
	uint8_t button_pattern[LENGTH(opening_settings.button_pattern)]; // to store the input button pattern
	uint8_t button_input = 0; // how many buttons have been pressed
	bool rust_animated = false; // if the rust animation started
	bool strobe_animated = false; // if the strobe animation started
	while (true) { // infinite loop
		iwdg_reset(); // kick the dog
		if (user_input_available) { // user input is available
			action = true; // action has been performed
			led_toggle(); // toggle LED
			char c = user_input_get(); // store receive character
			terminal_send(c); // send received character to terminal
		}
		if (button_flag || button_pressed) { // user pressed button
			action = true; // action has been performed
			sleep_ms(200); // wait a bit to remove noise and double trigger
			if (!gpio_get(GPIO_PORT(BUTTON1_PIN), GPIO_PIN(BUTTON1_PIN))) {
				button_pressed = 1;
			}
			if (!gpio_get(GPIO_PORT(BUTTON2_PIN), GPIO_PIN(BUTTON2_PIN))) {
				button_pressed = 2;
			}
			if (button_pressed) {
				printf("button pressed: %u\n", button_pressed);
				led_toggle(); // toggle LED
				if (pattern_length > 0 && opening_apply) { // only check pattern if there is one to compare to
					// switch off LEDs
					for (uint8_t led = 0; led < LED_WS2812B_LEDS; led++) {
						led_ws2812b_set_rgb(led, 0, 0, 0);
					}
					// start LED animation
					if (1 == button_pressed) {
						rust_animated = true; // remember rust animation started
						led_ws2812b_set_rgb(3, rust_animation[0][1], rust_animation[0][2], rust_animation[0][3]); // start LED animation
						led_ws2812b_set_rgb(4, rust_animation[0][1], rust_animation[0][2], rust_animation[0][3]); // start LED animation
						led_ws2812b_set_rgb(5, rust_animation[0][1], rust_animation[0][2], rust_animation[0][3]); // start LED animation
						strobe_animated = false; // stop strobe animation
						led_ws2812b_set_rgb(0, 0, 0, 0); // switch LED off
						led_ws2812b_set_rgb(1, 0, 0, 0); // switch LED off
						led_ws2812b_set_rgb(2, 0, 0, 0); // switch LED off
					} else if (2 == button_pressed) {
						strobe_animated = true; // remember strobe animation started
						led_ws2812b_set_rgb(0, strobe_animation[0][1], strobe_animation[0][2], strobe_animation[0][3]); // start LED animation
						led_ws2812b_set_rgb(1, strobe_animation[0][1], strobe_animation[0][2], strobe_animation[0][3]); // start LED animation
						led_ws2812b_set_rgb(2, strobe_animation[0][1], strobe_animation[0][2], strobe_animation[0][3]); // start LED animation
						rust_animated = false; // stop rust animation
						led_ws2812b_set_rgb(3, 0, 0, 0); // switch LED off
						led_ws2812b_set_rgb(4, 0, 0, 0); // switch LED off
						led_ws2812b_set_rgb(5, 0, 0, 0); // switch LED off
					}
					led_animation_ticks = 0; // reset timer counter
					animation_progress = 0; // reset animation
					timer_set_counter(TIM(LED_ANIMATION_TIMER), 0); // reset timer counter to get right duration
					timer_enable_counter(TIM(LED_ANIMATION_TIMER)); // start timer
					// store button
					if (button_input < LENGTH(button_pattern)) {
						button_pattern[button_input++] = button_pressed;
						printf("button sequence: %u/%u\n", button_input, pattern_length);
						last_button_action = rtc_get_counter_val(); // remember last button action
					}
					// compare pattern
					if (button_input >= pattern_length) {
						bool pattern_valid = true;
						for (uint8_t i = 0; i < pattern_length; i++) {
							if (button_pattern[i] != opening_settings.button_pattern[i]) {
								pattern_valid = false;
								break;
							}
						}
						// if the correct pattern has been input, press button
						if (pattern_valid) {
							puts("button sequence valid\n");
							gpio_set(GPIO_PORT(RELAY_BUTTON_PIN), GPIO_PIN(RELAY_BUTTON_PIN)); // set high to activate relay an simulate button press
							sleep_ms(1000); // hold button a bit
							gpio_clear(GPIO_PORT(RELAY_BUTTON_PIN), GPIO_PIN(RELAY_BUTTON_PIN)); // set low to deactivate relay and release button
						}
						button_input = 0; // restart from scratch
						last_button_action = 0; // restart sequence
					}
				} else { // ignore all button entry when not within the opening hours
					button_input = 0;
					last_button_action = 0;
				}
				// wait until both buttons are released
				while (!gpio_get(GPIO_PORT(BUTTON1_PIN), GPIO_PIN(BUTTON1_PIN)) || !gpio_get(GPIO_PORT(BUTTON2_PIN), GPIO_PIN(BUTTON2_PIN))) {
					//iwdg_reset(); // kick the dog
					sleep_ms(100);
				}
			} // button_pressed
			button_pressed = 0; // reset button pressed
			button_flag = false; // reset flag
		}
		if (rtc_internal_tick_flag) { // the internal RTC ticked
			rtc_internal_tick_flag = false; // reset flag
			action = true; // action has been performed
			if (0 == (rtc_get_counter_val() % RTC_TICKS_SECOND)) { // one second has passed
				led_toggle(); // toggle LED (good to indicate if main function is stuck)
			}
			if (last_button_action && last_button_action + 5 * RTC_TICKS_SECOND <= rtc_get_counter_val()) { // pattern entry timeout
				puts("button sequence entry timeout\n");
				last_button_action = 0; // reset last button time
				button_input = 0; // reset pattern input
			}
			// always enforce the right state
			gpio_clear(GPIO_PORT(RELAY_BUTTON_PIN), GPIO_PIN(RELAY_BUTTON_PIN)); // set low to not simulate button press
			// verify if day matches
			const time_t time_rtc = rtc_get_counter_val() / RTC_TICKS_SECOND + rtc_offset; // get time from internal RTC
			const struct tm* time_tm = localtime(&time_rtc); // convert time
			const uint16_t current_time = time_tm->tm_hour * 60 + time_tm->tm_min; // get time of day in minutes
			const uint8_t day = 6 - ((time_tm->tm_wday + 6) % 7); // get bit for the current day of week
			if (opening_settings.stop_time > opening_settings.start_time) { // stop time is on same day
				opening_apply = ((opening_settings.days & (1 << day)) && current_time > opening_settings.start_time && current_time < opening_settings.stop_time);
			} else { // stop time is on next day
				opening_apply = ((opening_settings.days & (1 << day)) && current_time > opening_settings.start_time) || (opening_settings.days & (1 << (day + 1 % 7)) && current_time < opening_settings.stop_time);
			}
			if (opening_apply) { // we are in the opening hours
				//puts("apply\n");
				gpio_set(GPIO_PORT(RELAY_PANEL_PIN), GPIO_PIN(RELAY_PANEL_PIN)); // set high to activate relay and disconnect button
			} else {
				gpio_clear(GPIO_PORT(RELAY_PANEL_PIN), GPIO_PIN(RELAY_PANEL_PIN)); // set high to release relay and connect button
			}
		}
		if (led_animation_ticks) { // an LED animation is running
			if (rust_animated) {
				if (animation_progress < LENGTH(rust_animation)) {
					if (led_animation_ticks >= rust_animation[animation_progress][0]) {
						animation_progress++; // got to next animation step
						led_animation_ticks = 0; // reset time ticks
						if (animation_progress < LENGTH(rust_animation)) { // next step of animation reached
							led_ws2812b_set_rgb(3, rust_animation[animation_progress][1], rust_animation[animation_progress][2], rust_animation[animation_progress][3]);
							led_ws2812b_set_rgb(4, rust_animation[animation_progress][1], rust_animation[animation_progress][2], rust_animation[animation_progress][3]);
							led_ws2812b_set_rgb(5, rust_animation[animation_progress][1], rust_animation[animation_progress][2], rust_animation[animation_progress][3]);
						} else { // end of animation reached
							timer_disable_counter(TIM(LED_ANIMATION_TIMER)); // stop timer
							led_ws2812b_set_rgb(3, 0, 0, 0); // switch off LED
							led_ws2812b_set_rgb(4, 0, 0, 0); // switch off LED
							led_ws2812b_set_rgb(5, 0, 0, 0); // switch off LED
						}
					}
				} else { // end of animation reached
					led_animation_ticks = 0; // disable check
					timer_disable_counter(TIM(LED_ANIMATION_TIMER)); // stop timer
				}
			}
			if (strobe_animated) {
				if (animation_progress < LENGTH(strobe_animation)) {
					if (led_animation_ticks >= strobe_animation[animation_progress][0]) {
						animation_progress++; // got to next animation step
						led_animation_ticks = 0; // reset time ticks
						if (animation_progress < LENGTH(strobe_animation)) { // next step of animation reached
							led_ws2812b_set_rgb(0, strobe_animation[animation_progress][1], strobe_animation[animation_progress][2], strobe_animation[animation_progress][3]);
							led_ws2812b_set_rgb(1, strobe_animation[animation_progress][1], strobe_animation[animation_progress][2], strobe_animation[animation_progress][3]);
							led_ws2812b_set_rgb(2, strobe_animation[animation_progress][1], strobe_animation[animation_progress][2], strobe_animation[animation_progress][3]);
						} else { // end of animation reached
							timer_disable_counter(TIM(LED_ANIMATION_TIMER)); // stop timer
							led_ws2812b_set_rgb(3, 0, 0, 0); // switch off LED
							led_ws2812b_set_rgb(4, 0, 0, 0); // switch off LED
							led_ws2812b_set_rgb(5, 0, 0, 0); // switch off LED
						}
					}
				} else { // end of animation reached
					led_animation_ticks = 0; // disable check
					timer_disable_counter(TIM(LED_ANIMATION_TIMER)); // stop timer
				}
			}
		}
		if (action) { // go to sleep if nothing had to be done, else recheck for activity
			action = false;
		} else {
			__WFI(); // go to sleep
		}
	} // main loop
}

/** @brief interrupt service routine called when tick passed on RTC */
void rtc_isr(void)
{
	rtc_clear_flag(RTC_SEC); // clear flag
	rtc_internal_tick_flag = true; // notify to show new time
}

void GPIO_EXTI_ISR(BUTTON1_PIN)(void) // it's the same at BUTTON2_PIN: EXT9_5
{
	if (exti_get_flag_status(GPIO_EXTI(BUTTON1_PIN))) {
		exti_reset_request(GPIO_EXTI(BUTTON1_PIN)); // reset interrupt
	}
	if (exti_get_flag_status(GPIO_EXTI(BUTTON2_PIN))) {
		exti_reset_request(GPIO_EXTI(BUTTON2_PIN)); // reset interrupt
	}
	button_flag = true; // perform button action
}

/** interrupt service routine called on animation tick */
void TIM_ISR(LED_ANIMATION_TIMER)(void)
{
	if (timer_get_flag(TIM(LED_ANIMATION_TIMER), TIM_SR_UIF)) { // update event happened
		timer_clear_flag(TIM(LED_ANIMATION_TIMER), TIM_SR_UIF); // clear flag
		led_animation_ticks++; // remember one tick passed
	}
}