ESPHome: esphome/components/remote_receiver/remote_receiver_libretiny.cpp Source File

#include "remote_receiver.h"

#include "esphome/core/hal.h"

#include "esphome/core/helpers.h"

#include "esphome/core/log.h"


#ifdef USE_LIBRETINY


namespace esphome {

namespace remote_receiver {


static const char *const TAG = "remote_receiver.libretiny";


void IRAM_ATTR HOT RemoteReceiverComponentStore::gpio_intr(RemoteReceiverComponentStore *arg) {

  const uint32_t now = micros();

  // If the lhs is 1 (rising edge) we should write to an uneven index and vice versa

  const uint32_t next = (arg->buffer_write_at + 1) % arg->buffer_size;

  const bool level = arg->pin.digital_read();

  if (level != next % 2)

    return;


  // If next is buffer_read, we have hit an overflow

  if (next == arg->buffer_read_at)

    return;


  const uint32_t last_change = arg->buffer[arg->buffer_write_at];

  const uint32_t time_since_change = now - last_change;

  if (time_since_change <= arg->filter_us)

    return;


  arg->buffer[arg->buffer_write_at = next] = now;

}


void RemoteReceiverComponent::setup() {

  ESP_LOGCONFIG(TAG, "Running setup");

  this->pin_->setup();

  auto &s = this->store_;

  s.filter_us = this->filter_us_;

  s.pin = this->pin_->to_isr();

  s.buffer_size = this->buffer_size_;


  this->high_freq_.start();

  if (s.buffer_size % 2 != 0) {

    // Make sure divisible by two. This way, we know that every 0bxxx0 index is a space and every 0bxxx1 index is a mark

    s.buffer_size++;

  }


  s.buffer = new uint32_t[s.buffer_size];

  void *buf = (void *) s.buffer;

  memset(buf, 0, s.buffer_size * sizeof(uint32_t));


  // First index is a space.

  if (this->pin_->digital_read()) {

    s.buffer_write_at = s.buffer_read_at = 1;

  } else {

    s.buffer_write_at = s.buffer_read_at = 0;

  }

  this->pin_->attach_interrupt(RemoteReceiverComponentStore::gpio_intr, &this->store_, gpio::INTERRUPT_ANY_EDGE);

}

void RemoteReceiverComponent::dump_config() {

  ESP_LOGCONFIG(TAG, "Remote Receiver:");

  LOG_PIN("  Pin: ", this->pin_);

  if (this->pin_->digital_read()) {

    ESP_LOGW(TAG, "Remote Receiver Signal starts with a HIGH value. Usually this means you have to "

                  "invert the signal using 'inverted: True' in the pin schema!");

  }

  ESP_LOGCONFIG(TAG,

                "  Buffer Size: %u\n"

                "  Tolerance: %u%s\n"

                "  Filter out pulses shorter than: %u us\n"

                "  Signal is done after %u us of no changes",

                this->buffer_size_, this->tolerance_,

                (this->tolerance_mode_ == remote_base::TOLERANCE_MODE_TIME) ? " us" : "%", this->filter_us_,

                this->idle_us_);

}


void RemoteReceiverComponent::loop() {

  auto &s = this->store_;


  // copy write at to local variables, as it's volatile

  const uint32_t write_at = s.buffer_write_at;

  const uint32_t dist = (s.buffer_size + write_at - s.buffer_read_at) % s.buffer_size;

  // signals must at least one rising and one leading edge

  if (dist <= 1)

    return;

  const uint32_t now = micros();

  if (now - s.buffer[write_at] < this->idle_us_) {

    // The last change was fewer than the configured idle time ago.

    return;

  }


  ESP_LOGVV(TAG, "read_at=%u write_at=%u dist=%u now=%u end=%u", s.buffer_read_at, write_at, dist, now,

            s.buffer[write_at]);


  // Skip first value, it's from the previous idle level

  s.buffer_read_at = (s.buffer_read_at + 1) % s.buffer_size;

  uint32_t prev = s.buffer_read_at;

  s.buffer_read_at = (s.buffer_read_at + 1) % s.buffer_size;

  const uint32_t reserve_size = 1 + (s.buffer_size + write_at - s.buffer_read_at) % s.buffer_size;

  this->temp_.clear();

  this->temp_.reserve(reserve_size);

  int32_t multiplier = s.buffer_read_at % 2 == 0 ? 1 : -1;


  for (uint32_t i = 0; prev != write_at; i++) {

    int32_t delta = s.buffer[s.buffer_read_at] - s.buffer[prev];

    if (uint32_t(delta) >= this->idle_us_) {

      // already found a space longer than idle. There must have been two pulses

      break;

    }


    ESP_LOGVV(TAG, "  i=%u buffer[%u]=%u - buffer[%u]=%u -> %d", i, s.buffer_read_at, s.buffer[s.buffer_read_at], prev,

              s.buffer[prev], multiplier * delta);

    this->temp_.push_back(multiplier * delta);

    prev = s.buffer_read_at;

    s.buffer_read_at = (s.buffer_read_at + 1) % s.buffer_size;

    multiplier *= -1;

  }

  s.buffer_read_at = (s.buffer_size + s.buffer_read_at - 1) % s.buffer_size;

  this->temp_.push_back(this->idle_us_ * multiplier);


  this->call_listeners_dumpers_();

}


}  // namespace remote_receiver

}  // namespace esphome


#endif

esphome::GPIOPin::setup
virtual void setup()=0

esphome::GPIOPin::digital_read
virtual bool digital_read()=0

esphome::HighFrequencyLoopRequester::start
void start()
Start running the loop continuously.
Definition helpers.cpp:673

esphome::InternalGPIOPin::attach_interrupt
void attach_interrupt(void(*func)(T *), T *arg, gpio::InterruptType type) const
Definition gpio.h:88

esphome::InternalGPIOPin::to_isr
virtual ISRInternalGPIOPin to_isr() const =0

esphome::remote_base::RemoteComponentBase::pin_
InternalGPIOPin * pin_
Definition remote_base.h:109

esphome::remote_base::RemoteReceiverBase::tolerance_mode_
ToleranceMode tolerance_mode_
Definition remote_base.h:228

esphome::remote_base::RemoteReceiverBase::temp_
RawTimings temp_
Definition remote_base.h:226

esphome::remote_base::RemoteReceiverBase::call_listeners_dumpers_
void call_listeners_dumpers_()
Definition remote_base.h:218

esphome::remote_base::RemoteReceiverBase::tolerance_
uint32_t tolerance_
Definition remote_base.h:227

esphome::remote_receiver::RemoteReceiverComponent::setup
void setup() override
Definition remote_receiver_esp8266.cpp:33

esphome::remote_receiver::RemoteReceiverComponent::store_
RemoteReceiverComponentStore store_
Definition remote_receiver.h:98

esphome::remote_receiver::RemoteReceiverComponent::filter_us_
uint32_t filter_us_
Definition remote_receiver.h:103

esphome::remote_receiver::RemoteReceiverComponent::high_freq_
HighFrequencyLoopRequester high_freq_
Definition remote_receiver.h:99

esphome::remote_receiver::RemoteReceiverComponent::idle_us_
uint32_t idle_us_
Definition remote_receiver.h:104

esphome::remote_receiver::RemoteReceiverComponent::dump_config
void dump_config() override
Definition remote_receiver_esp8266.cpp:59

esphome::remote_receiver::RemoteReceiverComponent::loop
void loop() override
Definition remote_receiver_esp8266.cpp:76

esphome::remote_receiver::RemoteReceiverComponent::buffer_size_
uint32_t buffer_size_
Definition remote_receiver.h:102

hal.h

helpers.h

log.h

esphome::gpio::INTERRUPT_ANY_EDGE
@ INTERRUPT_ANY_EDGE
Definition gpio.h:43

esphome::remote_base::TOLERANCE_MODE_TIME
@ TOLERANCE_MODE_TIME
Definition remote_base.h:20

esphome
Providing packet encoding functions for exchanging data with a remote host.
Definition a01nyub.cpp:7

esphome::micros
uint32_t IRAM_ATTR HOT micros()
Definition core.cpp:30

remote_receiver.h

esphome::remote_receiver::RemoteReceiverComponentStore::gpio_intr
static void gpio_intr(RemoteReceiverComponentStore *arg)
Definition remote_receiver_esp8266.cpp:13

esphome::remote_receiver::RemoteReceiverComponentStore::filter_us
uint32_t filter_us
Definition remote_receiver.h:29

esphome::remote_receiver::RemoteReceiverComponentStore::buffer_write_at
volatile uint32_t buffer_write_at
The position last written to.
Definition remote_receiver.h:24