flipperzero-firmware/applications/examples/strobe.c
DrZlo13 8f9b2513ff
[FL-140] Core api dynamic records (#296)
* SYSTEM: tickless mode with deep sleep.
* Move FreeRTOS ticks to lptim2
* API: move all sumbodules init routines to one place. Timebase: working lptim2 at tick source.
* API Timebase: lp-timer routines, timer access safe zones prediction and synchronization. FreeRTOS: adjust configuration for tickless mode.
* NFC: support for tickless mode.
* API Timebase: improve tick error handling in IRQ. Apploader: use insomnia mode to run applications.
* BLE: prevent sleep while core2 starting
* HAL: nap while in insomnia mode
* init records work
* try to implement record delete
* tests and flapp
* flapp subsystem
* new core functions to get app stat, simplify core code
* fix thread termination
* add strdup to core
* fix tests
* Refactoring: remove all unusued parts, update API usage, aggreagate API sources and headers, new record storage
* Refactoring: update furi record api usage, cleanup code
* Fix broken merge for freertos apps
* Core, Target: fix compilation warnings
* Drop firmware target local
* HAL Timebase, Power, Clock: semaphore guarded access to clock and power modes, better sleep mode.
* SD-Filesystem: wait for all deps to arrive before adding widget. Core, BLE: disable debug dump to serial.
* delete old app example-ipc
* delete old app fatfs list
* fix strobe app, add input header
* delete old display driver
* comment old app qr-code
* fix sd-card test, add forced widget update
* remove unused new core test
* increase heap to 128k
* comment and assert old core tests
* fix syntax

Co-authored-by: Aleksandr Kutuzov <alleteam@gmail.com>
2021-01-20 19:09:26 +03:00

58 lines
1.7 KiB
C

#include <furi.h>
#include <input.h>
static void event_cb(const void* value, void* ctx) {
const InputEvent* event = value;
uint32_t* delay_time = acquire_mutex(ctx, 0);
if(delay_time == NULL) return;
if(event->input == InputUp && *delay_time < 1000) {
*delay_time += 5;
}
if(event->input == InputDown && *delay_time > 10) {
*delay_time -= 5;
}
release_mutex(ctx, delay_time);
}
void application_strobe(void* p) {
// WAT
osDelay(100);
// create pins
GpioPin red = {.pin = LED_RED_Pin, .port = LED_RED_GPIO_Port};
GpioPin green = {.pin = LED_GREEN_Pin, .port = LED_GREEN_GPIO_Port};
GpioPin blue = {.pin = LED_BLUE_Pin, .port = LED_BLUE_GPIO_Port};
GpioPin* red_record = &red;
GpioPin* green_record = &green;
GpioPin* blue_record = &blue;
// configure pins
gpio_init(red_record, GpioModeOutputOpenDrain);
gpio_init(green_record, GpioModeOutputOpenDrain);
gpio_init(blue_record, GpioModeOutputOpenDrain);
uint32_t delay_time_holder = 100;
ValueMutex delay_mutex;
init_mutex(&delay_mutex, &delay_time_holder, sizeof(delay_time_holder));
PubSub* event_record = furi_record_open("input_events");
subscribe_pubsub(event_record, event_cb, &delay_mutex);
while(1) {
uint32_t delay_time = 100;
read_mutex_block(&delay_mutex, &delay_time, sizeof(delay_time));
gpio_write(red_record, false);
gpio_write(green_record, false);
gpio_write(blue_record, false);
osDelay(delay_time / 10);
gpio_write(red_record, true);
gpio_write(green_record, true);
gpio_write(blue_record, true);
osDelay(delay_time);
}
}