mirror of https://github.com/midilab/uClock
remove freertos support(unstable so far) and make interrupted version the default only. update main example
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/* USB MIDI Sync Box - RP2040 example that just blinks LED
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*
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*
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* This example code is in the public domain. |
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*
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*/ |
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//#define LED_BUILTIN PIN_LED_B
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#include "Adafruit_TinyUSB.h" |
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#include <uClock.h> |
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#define ATOMIC(X) { uint32_t __interrupt_mask = save_and_disable_interrupts(); X; restore_interrupts(__interrupt_mask); } |
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uint8_t bpm_blink_timer = 1; |
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void handle_bpm_led(uint32_t tick) |
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{ |
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// BPM led indicator
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if ( !(tick % (96)) || (tick == 1) ) { // first compass step will flash longer
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bpm_blink_timer = 8; |
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digitalWrite(LED_BUILTIN, LOW); |
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} else if ( !(tick % (24)) ) { // each quarter led on
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bpm_blink_timer = 1; |
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digitalWrite(LED_BUILTIN, LOW); |
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} else if ( !(tick % bpm_blink_timer) ) { // get led off
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digitalWrite(LED_BUILTIN, HIGH); |
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} |
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} |
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// Internal clock handlers
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void onSync24Callback(uint32_t tick) { |
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handle_bpm_led(tick); |
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} |
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void onClockStart() { |
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//MIDI_USB.sendRealTime(midi::Start);
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} |
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void onClockStop() { |
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//MIDI_USB.sendRealTime(midi::Stop);
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} |
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void setup() { |
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/*#if defined(ARDUINO_ARCH_MBED) && defined(ARDUINO_ARCH_RP2040)
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// Manual begin() is required on core without built-in support for TinyUSB such as mbed rp2040
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TinyUSB_Device_Init(0); |
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#endif*/ |
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//MIDI_USB.begin(MIDI_CHANNEL_OMNI);
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// A led to count bpms
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pinMode(LED_BUILTIN, OUTPUT); |
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/*digitalWrite(LED_BUILTIN, HIGH);
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delay(500); |
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digitalWrite(LED_BUILTIN, LOW); |
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delay(500); |
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digitalWrite(LED_BUILTIN, HIGH); |
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delay(500); |
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digitalWrite(LED_BUILTIN, LOW); |
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delay(500);*/ |
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Serial.begin(115200); |
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/*while (!Serial)
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delay(1);*/ |
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// Setup our clock system
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// Inits the clock
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uClock.init(); |
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// Set the callback function for the clock output to send MIDI Sync message.
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uClock.setOnSync24(onSync24Callback); |
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// Set the callback function for MIDI Start and Stop messages.
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uClock.setOnClockStart(onClockStart);
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uClock.setOnClockStop(onClockStop); |
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// Set the clock BPM to 126 BPM
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uClock.setTempo(60); |
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// Starts the clock, tick-tac-tick-tac..
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//Serial.println("about to uClock.start()..."); Serial.flush();
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uClock.start(); |
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//Serial.println("uClock.start()ed!"); Serial.flush();
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} |
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uint32_t count = 0; |
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// Do it whatever to interface with Clock.stop(), Clock.start(), Clock.setTempo() and integrate your environment...
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void loop() { |
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//MIDI_USB.read();
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//count++;
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//if (millis()%1000==0)
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// ATOMIC(Serial.println("looped!"));
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} |
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@ -0,0 +1,37 @@ |
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#if defined(WS2812_BUILTIN_LED) |
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#include <Adafruit_NeoPixel.h> |
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#define NUMPIXELS 1 |
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Adafruit_NeoPixel pixels(NUMPIXELS, WS2812_BUILTIN_LED, NEO_GRB + NEO_KHZ800); |
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#endif |
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// check the pinage for BUILTIN LED of your model in case LED_BUILTIN wont ligth up
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// this is valid only if you're not using rgb version ws2812 (WS2812_BUILTIN_LED)
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//#define LED_BUILTIN PIN_LED_B
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void initBlinkLed() { |
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#if defined(WS2812_BUILTIN_LED) |
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// use adafruit neo pixel
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pixels.begin(); |
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#else |
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// normal led pin
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pinMode(LED_BUILTIN, OUTPUT); |
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#endif |
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} |
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void ledOn() { |
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#if defined(WS2812_BUILTIN_LED) |
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pixels.setPixelColor(0, pixels.Color(0, 0, 20)); |
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pixels.show(); // turn the LED on (HIGH is the voltage level)
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#else |
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digitalWrite(LED_BUILTIN, LOW); |
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#endif |
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} |
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void ledOff() { |
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#if defined(WS2812_BUILTIN_LED) |
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pixels.setPixelColor(0, pixels.Color(0, 0, 0)); |
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pixels.show(); |
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#else |
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digitalWrite(LED_BUILTIN, HIGH); |
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#endif |
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} |
@ -1,98 +1,30 @@ |
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#include <Arduino.h> |
#include <Arduino.h> |
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#include "pico/sync.h" |
#include "pico/sync.h" |
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// todo: make this a build flag, so user can choose which method to use?
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// RPi-specific timer
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#define MULTICORE |
struct repeating_timer timer; |
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#ifdef MULTICORE |
#define ATOMIC(X) { uint32_t __interrupt_mask = save_and_disable_interrupts(); X; restore_interrupts(__interrupt_mask); } |
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// use interrupt version -- works for 2 cores ie can run loop1() and loop() simultaneously as well as the clock callback?
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// RPi-specific timer
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// forward declaration of uClockHandler
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struct repeating_timer timer; |
void uClockHandler(); |
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#define ATOMIC(X) { uint32_t __interrupt_mask = save_and_disable_interrupts(); X; restore_interrupts(__interrupt_mask); } |
// ISR handler -- called when tick happens
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bool handlerISR(repeating_timer *timer) |
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// forward declaration of uClockHandler
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{ |
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void uClockHandler(); |
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// ISR handler -- called when tick happens
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bool handlerISR(repeating_timer *timer) |
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{ |
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uClockHandler(); |
uClockHandler(); |
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return true; |
return true; |
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} |
} |
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void initTimer(uint32_t init_clock) { |
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// set up RPi interrupt timer
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// todo: actually should be -init_clock so that timer is set to start init_clock us after last tick, instead of init_clock us after finished processing last tick!
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add_repeating_timer_us(init_clock, &handlerISR, NULL, &timer); |
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} |
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void setTimer(uint32_t us_interval) { |
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cancel_repeating_timer(&timer); |
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// todo: actually should be -us_interval so that timer is set to start init_clock us after last tick, instead of init_clock us after finished processing last tick!
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add_repeating_timer_us(us_interval, &handlerISR, NULL, &timer); |
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} |
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#else |
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// use FreeRTOS scheduling/mutex version -- doesn't work (task starts but does not run) if using loop1() ie core 2
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#include "FreeRTOS.h" |
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#include <task.h> |
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#include <semphr.h> |
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// RPi-specific timer
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struct repeating_timer timer; |
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// FreeRTOS main clock task size in bytes
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#define CLOCK_STACK_SIZE 5*1024 // adjust for your needs, a sequencer with heavy serial handling should be large in size
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TaskHandle_t taskHandle; |
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// mutex to protect the shared resource
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SemaphoreHandle_t _mutex; |
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// mutex control for task
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#define ATOMIC(X) xSemaphoreTake(_mutex, portMAX_DELAY); X; xSemaphoreGive(_mutex); |
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// forward declaration of uClockHandler
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void uClockHandler(); |
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// ISR handler -- called when tick happens
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bool handlerISR(repeating_timer *timer) |
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{ |
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BaseType_t xHigherPriorityTaskWoken = pdFALSE; |
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// Send a notification to task1
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vTaskNotifyGiveFromISR(taskHandle, &xHigherPriorityTaskWoken); |
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portYIELD_FROM_ISR(xHigherPriorityTaskWoken); |
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return true; |
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} |
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// task for user clock process
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void clockTask(void *pvParameters) |
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{ |
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while (1) { |
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// wait for a notification from ISR
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ulTaskNotifyTake(pdTRUE, portMAX_DELAY); |
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uClockHandler(); |
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} |
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} |
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void initTimer(uint32_t init_clock) |
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{ |
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// initialize the mutex for shared resource access
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_mutex = xSemaphoreCreateMutex(); |
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// create the clockTask
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xTaskCreate(clockTask, "clockTask", CLOCK_STACK_SIZE, NULL, 1, &taskHandle); |
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void initTimer(uint32_t init_clock) { |
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// set up RPi interrupt timer
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// set up RPi interrupt timer
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// todo: actually should be -init_clock so that timer is set to start init_clock us after last tick, instead of init_clock us after finished processing last tick!
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// todo: actually should be -init_clock so that timer is set to start init_clock us after last tick, instead of init_clock us after finished processing last tick!
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add_repeating_timer_us(init_clock, &handlerISR, NULL, &timer); |
add_repeating_timer_us(init_clock, &handlerISR, NULL, &timer); |
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} |
} |
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void setTimer(uint32_t us_interval) { |
void setTimer(uint32_t us_interval) { |
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cancel_repeating_timer(&timer); |
cancel_repeating_timer(&timer); |
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// todo: actually should be -us_interval so that timer is set to start init_clock us after last tick, instead of init_clock us after finished processing last tick!
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// todo: actually should be -us_interval so that timer is set to start init_clock us after last tick, instead of init_clock us after finished processing last tick!
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add_repeating_timer_us(us_interval, &handlerISR, NULL, &timer); |
add_repeating_timer_us(us_interval, &handlerISR, NULL, &timer); |
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} |
} |
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#endif |
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