led_clock-old/main.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/>.
 *
 */
/** @file main.c
@author King Kévin <kingkevin@cuvoodoo.info>
@date 2016
@brief show the time on a LED strip

The LED strip consists of 60 WS2812b LEDs.
The time is read from a DS1307 RTC module.
 */

/* standard libraries */
#include <stdint.h> // standard integer types
#include <stdio.h> // standard I/O facilities
#include <stdlib.h> // standard utilities
#include <unistd.h> // standard streams
#include <errno.h> // error number utilities

/* STM32 (including CM3) libraries */
#include <libopencm3/stm32/rcc.h> // real-time control clock library
#include <libopencm3/stm32/gpio.h> // general purpose input output library
#include <libopencm3/cm3/scb.h> // vector table definition
#include <libopencmsis/core_cm3.h> // Cortex M3 utilities
#include <libopencm3/cm3/nvic.h> // interrupt utilities
#include <libopencm3/stm32/exti.h> // external interrupt utilities

/* own libraries */
#include "global.h" // board definitions
#include "usart.h" // USART utilities
#include "usb_cdcacm.h" // USB CDC ACM utilities
#include "led_ws2812b.h" // WS2812b LEDs utilities
#include "rtc_ds1307.h" // Real Time Clock DS1307 utilities

/** @defgroup main_flags flag set in interrupts to be processed in main task
 *  @{
 */
volatile bool button_flag = false; /**< flag set when board user button has been pressed/released */
volatile bool time_flag = false; /**< flag set when time changed */
/** @} */

#define TICKS_PER_SECOND 256 /**< the number of ticks in one second */
#define SQUARE_WAVE_FREQUENCY 4096 /**< square wave output frequency from the RTC IC */
/** @defgroup main_ticks ticks per time units
 *  @note these are derived from TICKS_PER_SECOND
 *  @note I have to use type variables because defines would be stored in signed integers, leading to an overflow it later calculations
 *  @{
 */
/** number of ticks in one second */
const uint32_t ticks_second = TICKS_PER_SECOND;
/** number of ticks in one minute */
const uint32_t ticks_minute = 60*TICKS_PER_SECOND;
/** number of ticks in one hour */
const uint32_t ticks_hour = 60*60*TICKS_PER_SECOND;
/** number of ticks in one midday (12 hours) */
const uint32_t ticks_midday = 12*60*60*TICKS_PER_SECOND;
/** @} */

/** RGB values for the WS2812b clock LEDs */
uint8_t clock_leds[WS2812B_LEDS*3] = {0};
/** current time in tick */
volatile uint32_t current_time = 0;

int _write(int file, char *ptr, int len)
{
	int i;

	if (file == STDOUT_FILENO || file == STDERR_FILENO) {
		for (i = 0; i < len; i++) {
			if (ptr[i] == '\n') { // add carrier return before line feed. this is recommended for most UART terminals
				usart_putchar_nonblocking('\r'); // a second line feed doesn't break the display
				cdcacm_putchar('\r'); // a second line feed doesn't break the display
			}
			usart_putchar_nonblocking(ptr[i]); // send byte over USART
			cdcacm_putchar(ptr[i]); // send byte over USB
		}
		return i;
	}
	errno = EIO;
	return -1;
}

void led_on(void)
{
#if defined(SYSTEM_BOARD) || defined(BLUE_PILL)
	gpio_clear(LED_PORT, LED_PIN);
#elif defined(MAPLE_MINI)
	gpio_set(LED_PORT, LED_PIN);
#endif
}

void led_off(void)
{
#if defined(SYSTEM_BOARD) || defined(BLUE_PILL)
	gpio_set(LED_PORT, LED_PIN);
#elif defined(MAPLE_MINI)
	gpio_clear(LED_PORT, LED_PIN);
#endif
}

void led_toggle(void)
{
	gpio_toggle(LED_PORT, LED_PIN);
}

/** @brief switch off all clock LEDs
 *  @note LEDs need to be set separately
 */
static void clock_clear(void)
{
	// set all colors of all LEDs to 0
	for (uint16_t i=0; i<LENGTH(clock_leds); i++) {
		clock_leds[i] = 0;
	}
}

/** @brief set hours mark on clock LEDs
 *  @note LEDs need to be set separately
 */
static void clock_hours(void)
{
	for (uint8_t hour=0; hour<12; hour++) {
		uint16_t led = WS2812B_LEDS/12*hour;
		clock_leds[led*3+0] = 0xff;
		clock_leds[led*3+1] = 0xff;
		clock_leds[led*3+2] = 0xff;
	}
}

/** @brief show time on LED clock
 *  @param[in] time in ticks to show
 *  @details show hours and minutes progress as full arcs, show second position as marker. the brightness of the LED shows the progress of the unit. hours are blue, minutes green, seconds red
 *  @note LEDs need to be set separately
 */
static void clock_show_time(uint32_t time)
{
	uint32_t led_hour = (WS2812B_LEDS*(255*(uint64_t)(time%ticks_midday)))/ticks_midday; // scale to LED brightnesses for hours
	uint32_t led_minute = (WS2812B_LEDS*(255*(uint64_t)(time%ticks_hour)))/ticks_hour; // scale to LED brightnesses for minutes
	if (led_hour>=WS2812B_LEDS*255 || led_minute>=WS2812B_LEDS*255) { // a calculation error occurred
		return;
	}
	// show hours and minutes on LEDs
	if (led_hour>led_minute) {
		// show hours in blue (and clear other LEDs)
		for (uint16_t led=0; led<WS2812B_LEDS; led++) {
			clock_leds[led*3+0] = 0;
			clock_leds[led*3+1] = 0;
			if (led_hour>=0xff) { // full hours
				clock_leds[led*3+2] = 0xff;
			} else { // running hours
				clock_leds[led*3+2] = led_hour;
			}
			led_hour -= clock_leds[led*3+2];
		}
		// show minutes in green (override hours)
		for (uint16_t led=0; led<WS2812B_LEDS && led_minute>0; led++) {
			clock_leds[led*3+0] = 0;
			if (led_minute>=0xff) { // full minutes
				clock_leds[led*3+1] = 0xff;
			} else { // running minutes
				clock_leds[led*3+1] = led_minute;
			}
			led_minute -= clock_leds[led*3+1];
			clock_leds[led*3+2] = 0;
		}
	} else {
		// show minutes in green (and clear other LEDs)
		for (uint16_t led=0; led<WS2812B_LEDS; led++) {
			clock_leds[led*3+0] = 0;
			if (led_minute>=0xff) { // full minutes
				clock_leds[led*3+1] = 0xff;
			} else { // running minutes
				clock_leds[led*3+1] = led_minute;
			}
			led_minute -= clock_leds[led*3+1];
			clock_leds[led*3+2] = 0;
		}
		// show hours in blue (override minutes)
		for (uint16_t led=0; led<WS2812B_LEDS && led_hour>0; led++) {
			clock_leds[led*3+0] = 0;
			clock_leds[led*3+1] = 0;
			if (led_hour>=0xff) { // full hours
				clock_leds[led*3+2] = 0xff;
			} else { // running hours
				clock_leds[led*3+2] = led_hour;
			}
			led_hour -= clock_leds[led*3+2];
		}
	}
	// don't show seconds on full minute (better for first time setting, barely visible else)
	if (time%ticks_minute==0) {
		return;
	}
	uint16_t led_second = (WS2812B_LEDS*(time%ticks_minute))/ticks_minute; // get LED for seconds
	uint8_t brightness_second = (255*(time%ticks_second))/ticks_second; // get brightness for seconds
	// set second LED
	clock_leds[led_second*3+0] = brightness_second;
	//clock_leds[led_second*3+1] = 0;
	//clock_leds[led_second*3+2] = 0;
	// set previous LED
	led_second = (led_second==0) ? WS2812B_LEDS-1 : led_second-1; // previous LED
	clock_leds[led_second*3+0] = 0xff-brightness_second;
	//clock_leds[led_second*3+1] = 0;
	//clock_leds[led_second*3+2] = 0;
}

/** @brief set the LEDs
 *  @details set the LED colors on WS2812b LEDs
 *  @note WS2812b LED color values need to be transmitted separately
 */
static void leds_set(void)
{
	for (uint16_t i=0; i<LENGTH(clock_leds)/3; i++) {
		ws2812b_set_rgb(i,clock_leds[i*3+0],clock_leds[i*3+1],clock_leds[i*3+2]);
	}
}

/** @brief set the time on the LEDs
 *  @param[in] time time to set
 */
static void clock_set_time(uint32_t time)
{
	clock_show_time(time); // set time
	leds_set(); // set the colors of all LEDs
	ws2812b_transmit(); // transmit set color
}

/** @brief incrementally set the time on the LEDs
 *  @details this will have an animation where time is incremented until it reaches the provided time
 *  @param[in] time time to set
 */
static void clock_animate_time(uint32_t time)
{
	static uint32_t display_time = 0; // the time to display
	while (display_time<time) {
		if (display_time+ticks_hour<=time) { // first set hours
			display_time += ticks_hour; // increment hours
		} else if (display_time+ticks_minute<=time) { // second set minutes
			display_time += ticks_minute; // increment minutes
		} else if (display_time+ticks_second<=time) { // third set seconds
			display_time += ticks_second; // increment seconds
		} else { // finally set time
			display_time = time;
		}
		clock_set_time(display_time); // set time (progress)
		// delay some time for the animation
		for (uint32_t i=0; i<400000; i++) {
			__asm__("nop");
		}
	}
}

/** @brief program entry point
 *  this is the firmware function started by the micro-controller
 */
int main(void)
{	
	SCB_VTOR = (uint32_t) 0x08002000; // relocate vector table because of the bootloader

	rcc_clock_setup_in_hse_8mhz_out_72mhz(); // use 8 MHz high speed external clock to generate 72 MHz internal clock
    usart_setup(); // setup USART (for printing)
    cdcacm_setup(); // setup USB CDC ACM (for printing)
    setbuf(stdout, NULL); // set standard out buffer to NULL to immediately print   
    setbuf(stderr, NULL); // set standard error buffer to NULL to immediately print

	// setup LED
	rcc_periph_clock_enable(LED_RCC); // enable clock for LED
	gpio_set_mode(LED_PORT, GPIO_MODE_OUTPUT_2_MHZ, GPIO_CNF_OUTPUT_PUSHPULL, LED_PIN); // set LED pin to 'output push-pull'
	led_off(); // switch off LED to indicate setup started

	// setup button
#if defined(BUTTON_RCC) && defined(BUTTON_PORT) && defined(BUTTON_PIN) && defined(BUTTON_EXTI) && defined(BUTTON_IRQ)
	rcc_periph_clock_enable(BUTTON_RCC); // enable clock for button
	gpio_set_mode(BUTTON_PORT, GPIO_MODE_INPUT, GPIO_CNF_INPUT_FLOAT, BUTTON_PIN); // set button pin to input
	rcc_periph_clock_enable(RCC_AFIO); // enable alternate function clock for external interrupt
	exti_select_source(BUTTON_EXTI, BUTTON_PORT); // mask external interrupt of this pin only for this port
	exti_set_trigger(BUTTON_EXTI, EXTI_TRIGGER_BOTH); // trigger on both edge
	exti_enable_request(BUTTON_EXTI); // enable external interrupt
	nvic_enable_irq(BUTTON_IRQ); // enable interrupt
#endif

	// setup WS2812b LEDs
	ws2812b_setup(); // setup WS2812b LEDs
	clock_hours(); // show hour markers
	clock_clear(); // clear all LEDs
	leds_set(); // set the colors of all LEDs
	ws2812b_transmit(); // transmit set color

	// setup RTC module
	rtc_setup(); // setup RTC module
	rtc_write_square_wave(SQUARE_WAVE_FREQUENCY); // set square wave output frequency

	printf("welcome to the CuVoodoo LED clock\n"); // print welcome message
	led_on(); // switch on LED to indicate setup completed

	// verify is RTC is running
	if (rtc_oscillator_disabled()) {
		printf("/!\\ RTC oscillator is disabled\n");
	}

	// get date and time
	uint16_t* rtc_time = rtc_read_time(); // get RTC time/date
	printf("current date: %04d-%02d-%02d %02d:%02d:%02d\n", rtc_time[6], rtc_time[5], rtc_time[4], rtc_time[2], rtc_time[1], rtc_time[0]);
	current_time = rtc_time[2]*ticks_hour+rtc_time[1]*ticks_minute+rtc_time[0]*ticks_second; // the current time
	clock_animate_time(current_time); // set time with animation

	//rtc_write_time(0,52,9,4,23,3,2016);
	//rtc_oscillator_enable();

	printf("input commands\n");
	bool action = false; // if an action has been performed don't go to sleep
	button_flag = false; // reset button flag
	char c = ' '; // to store received character
	bool char_flag = false; // a new character has been received
	while (true) { // infinite loop
		while (usart_received) { // data received over UART
			action = true; // action has been performed
			led_toggle(); // toggle LED
			c = usart_getchar(); // store receive character
			char_flag = true; // notify character has been received
		}
		while (cdcacm_received) { // data received over USB
			action = true; // action has been performed
			led_toggle(); // toggle LED
			c = usart_getchar(); // store receive character
			char_flag = true; // notify character has been received
		}
		while (char_flag) { // user data received
			char_flag = false; // reset flag
			action = true; // action has been performed
			printf("%c",c); // echo receive character
		}
		while (button_flag) { // user pressed button
			button_flag = false; // reset flag
			action = true; // action has been performed
			led_toggle(); // toggle LED
		}
		while (time_flag) { // time passed
			time_flag = false; // reset flag
			action = true; // action has been performed
			led_toggle();
			if ((current_time%ticks_minute)==0) { // sync each minute
				rtc_time = rtc_read_time(); // get RTC time/date
				current_time = rtc_time[2]*ticks_hour+rtc_time[1]*ticks_minute+rtc_time[0]*ticks_second; // calculate current time
				printf("it is now %02lu:%02lu:%02lu\n", current_time/ticks_hour, (current_time%ticks_hour)/ticks_minute, (current_time%ticks_minute)/ticks_second); // display time
			}
			clock_set_time(current_time); // set time
			if ((current_time%ticks_second)==0) { // print each second
				//printf("%02lu:%02lu:%02lu\n", current_time/ticks_hour, (current_time%ticks_hour)/ticks_minute, (current_time%ticks_minute)/ticks_second); // display time
			}
		}
		if (action) { // go to sleep if nothing had to be done, else recheck for activity
			action = false;
		} else {
			__WFI(); // go to sleep
		}
	}

	return 0;
}

#if defined(BUTTON_ISR) && defined(BUTTON_EXTI)
void BUTTON_ISR(void)
{
	exti_reset_request(BUTTON_EXTI); // reset interrupt
	button_flag = true; // perform button action
}
#endif

#if defined(SQUARE_WAVE_EXTI) && defined(SQUARE_WAVE_IRQ) && defined(SQUARE_WAVE_ISR) && defined(SQUARE_WAVE_HANDLING) && !SQUARE_WAVE_HANDLING
/** @brief square wave input interrupt */
void SQUARE_WAVE_ISR(void)
{
	static uint16_t square_wave_prescale = 0; /**< prescale the square wave output to generate a tick */

exti_reset_request(SQUARE_WAVE_EXTI); // reset interrupt
	square_wave_prescale = (square_wave_prescale+1)%(SQUARE_WAVE_FREQUENCY/TICKS_PER_SECOND); // increment pre-scale counter
	if (square_wave_prescale==0) { // pre-scale completed
		current_time++; // increment time
		time_flag = true; // update flag
	}
}
#endif