pimoroni-pico/examples/pico_rtc_display/demo.cpp

270 wiersze
8.3 KiB
C++

#include <string.h>
// **************************************************************************
// Demonstrate the Pimoroni RTC module (RV3028)
// Assumes that a Pico Display Pack (a 1.14inch IPS LCD screen with four
// useful buttons) is installed, and that the RV3028 I2C module has
// sda, scl and int on GPIO 20, 21 and 22
// Displays a clock showing date and time (no code yet to set the time,
// so do it on a separate machine), or a countdown timer.
// Button A selects the timer setting function, and runs the timer once set
// Button B selects the clock (the selection on startup)
// Button X increments the timer delay in seconds
// Button Y decrements it
// (There are on-screen reminders of the active buttons)
// **************************************************************************
// To use PicoExplorer rather than PicoDisplay, uncomment the following line
// #define USE_PICO_EXPLORER 1
// This:
// - Includes pico_explorer.hpp rather than pico_display.hpp
// - Replaces all PicoDisplay references with PicoExplorer
// - Leaves out the .set_led() calls in flash_led()
#ifdef USE_PICO_EXPLORER
#include "pico_explorer.hpp"
#else
#include "pico_display.hpp"
#endif
#include "breakout_rtc.hpp"
#define MODE_DISP_CLOCK 0
#define MODE_DISP_TIMER 1
#define MODE_SET_TIMER 2
#define DEFAULT_TIMER_COUNT 5
using namespace pimoroni;
#ifdef USE_PICO_EXPLORER
uint16_t buffer[PicoExplorer::WIDTH * PicoExplorer::HEIGHT];
PicoExplorer pico_display(buffer);
uint16_t screen_width = PicoExplorer::WIDTH;
uint16_t screen_height = PicoExplorer::HEIGHT;
#else
uint16_t buffer[PicoDisplay::WIDTH * PicoDisplay::HEIGHT];
PicoDisplay pico_display(buffer);
uint16_t screen_width = PicoDisplay::WIDTH;
uint16_t screen_height = PicoDisplay::HEIGHT;
#endif
BreakoutRTC rtc;
#define LOW_COUNT_MOD 40
#define HIGH_COUNT_MOD 20
bool repeat_count_reached(uint16_t curr_count) {
// Check whether the current counter means that a key has repeated
if(curr_count <= 10*LOW_COUNT_MOD) {
return (0 == (curr_count % LOW_COUNT_MOD));
}
else {
return (0 == (curr_count % HIGH_COUNT_MOD));
}
}
#define FLASH_MOD 20
void flash_led(uint32_t curr_count) {
// Flash the LED based on the current loop counter
// curr_count=0 will turn LED off
#ifndef USE_PICO_EXPLORER
if((curr_count % FLASH_MOD) < (FLASH_MOD / 2)) {
// value less than half modded number - LED off
pico_display.set_led(0, 0, 0);
}
else {
// value more than half modded number - LED on
pico_display.set_led(128, 128, 128);
}
#endif
}
int main() {
pico_display.init();
rtc.init();
// rtc.setup(false);
// Make sure we have 24-hour time (smaller display!)
if(rtc.is_12_hour())
rtc.set_24_hour();
// Use these variables to make the buttons single-shot
// Counts number of loops pressed, 0 if not pressed
// Only for x and y - a and b are single-shot
uint16_t a_pressed = 0;
uint16_t b_pressed = 0;
uint16_t x_pressed = 0;
uint16_t y_pressed = 0;
struct pt {
float x;
float y;
uint8_t r;
float dx;
float dy;
uint16_t pen;
};
uint32_t i = 0;
char buf[256];
uint8_t display_mode = MODE_DISP_CLOCK;
uint16_t timer_count = DEFAULT_TIMER_COUNT;
while(true) {
if(a_pressed == 0 && pico_display.is_pressed(pico_display.A)) {
a_pressed = 1;
if(display_mode == MODE_DISP_CLOCK) {
// We were displaying clock = set up timer
display_mode = MODE_SET_TIMER;
}
else if(display_mode == MODE_SET_TIMER) {
// We were setting up the timer - run it
rtc.set_timer(false, 1, timer_count, true, true, false);
display_mode = MODE_DISP_TIMER;
}
else if(display_mode == MODE_DISP_TIMER) {
// We were running the timer - go back to setting up
if(0 == (timer_count = rtc.get_timer_count())) {
timer_count = DEFAULT_TIMER_COUNT;
}
rtc.disable_timer_interrupt();
rtc.disable_timer();
rtc.clear_timer_interrupt_flag();
display_mode = MODE_SET_TIMER;
}
}
else if(a_pressed >= 1 && !pico_display.is_pressed(pico_display.A)) {
a_pressed = 0;
}
if(b_pressed == 0 && pico_display.is_pressed(pico_display.B)) {
b_pressed = 1;
if((display_mode == MODE_DISP_TIMER)
|| (display_mode == MODE_SET_TIMER)) {
// We were setting or displaying timer - revert to clock
rtc.disable_timer_interrupt();
rtc.disable_timer();
rtc.clear_timer_interrupt_flag();
display_mode = MODE_DISP_CLOCK;
timer_count = DEFAULT_TIMER_COUNT;
}
}
else if(b_pressed >= 1 && !pico_display.is_pressed(pico_display.B)) {
b_pressed = 0;
}
if(x_pressed == 0 && pico_display.is_pressed(pico_display.X)) {
x_pressed = 1;
if(display_mode == MODE_SET_TIMER) {
// Setting timer - Increment count
timer_count++;
}
}
else if(x_pressed >= 1 && pico_display.is_pressed(pico_display.X)) {
// Button still pressed - check if has reached repeat count
if(repeat_count_reached(x_pressed++)) {
timer_count++;
}
}
else if(x_pressed >= 1 && !pico_display.is_pressed(pico_display.X)) {
x_pressed = 0;
}
if(y_pressed == 0 && pico_display.is_pressed(pico_display.Y)) {
y_pressed = 1;
if(display_mode == MODE_SET_TIMER) {
// Setting timer - Decrement count
if (timer_count >= 1) timer_count--;
}
}
else if(y_pressed >= 1 && pico_display.is_pressed(pico_display.Y)) {
// Button still pressed - check if has reached repeat count
if(repeat_count_reached(y_pressed++)) {
if(timer_count >= 1)
timer_count--;
}
}
else if(y_pressed >= 1 && !pico_display.is_pressed(pico_display.Y)) {
y_pressed = 0;
}
Rect text_box(5, 5, screen_width-10, screen_height-10);
pico_display.set_pen(55, 65, 75);
pico_display.rectangle(text_box);
// text_box.deflate(10);
pico_display.set_clip(text_box);
pico_display.set_pen(255, 255, 255);
switch(display_mode) {
case MODE_DISP_CLOCK:
// Show the clock face
flash_led(0);
if(rtc.update_time()) {
pico_display.text("Set Timer",
Point(text_box.x, text_box.y+2), 230, 1);
pico_display.set_pen(0, 255, 0);
pico_display.text(rtc.string_date(),
Point(text_box.x, text_box.y+20), 230, 4);
pico_display.set_pen(255, 0, 0);
pico_display.text(rtc.string_time(),
Point(text_box.x, text_box.y+60), 230, 6);
pico_display.set_pen(255, 255, 255);
pico_display.text("Clock",
Point(text_box.x, text_box.y+screen_height-20), 230, 1);
}
else {
sprintf(buf, "Time: rtc.updateTime() ret err");
pico_display.text(buf,
Point(text_box.x, text_box.y), 30, 2);
}
break;
case MODE_DISP_TIMER:
pico_display.text("Set Timer",
Point(text_box.x, text_box.y+2), 230, 1);
if(rtc.read_timer_interrupt_flag()) {
// Go periodic time interupt - say loop ended
pico_display.set_pen(255, 0, 0);
sprintf(buf, "%s", "Timer complete");
pico_display.text(buf,
Point(text_box.x, text_box.y+30), 230, 4);
pico_display.set_pen(255, 255, 255);
flash_led(i);
}
else {
sprintf(buf, "%s %d", "Timer running", rtc.get_timer_count());
pico_display.text(buf,
Point(text_box.x, text_box.y+30), 230, 3);
}
pico_display.text("Clock",
Point(text_box.x, text_box.y+screen_height-20), 230, 1);
break;
case MODE_SET_TIMER:
flash_led(0);
pico_display.text("Run Timer",
Point(text_box.x, text_box.y+2), 230, 1);
pico_display.text("+ Time",
Point(text_box.x+screen_width-42, text_box.y+2), 230, 1);
sprintf(buf, "Time %d secs", timer_count);
pico_display.text(buf,
Point(text_box.x, text_box.y+30), 230, 3);
pico_display.text("Clock",
Point(text_box.x, text_box.y+screen_height-20), 230, 1);
pico_display.text("- Time",
Point(text_box.x+screen_width-42,
text_box.y+screen_height-20), 230, 1);
break;
}
pico_display.remove_clip();
// update screen
pico_display.update();
i++;
}
return 0;
}