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Refactor pulse_meter
to better handle higher frequencies (#4231)
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parent
40697fea96
commit
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2 changed files with 103 additions and 148 deletions
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@ -1,4 +1,5 @@
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#include "pulse_meter_sensor.h"
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#include <utility>
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#include "esphome/core/log.h"
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namespace esphome {
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@ -9,66 +10,58 @@ static const char *const TAG = "pulse_meter";
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void PulseMeterSensor::setup() {
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this->pin_->setup();
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this->isr_pin_ = pin_->to_isr();
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this->pin_->attach_interrupt(PulseMeterSensor::gpio_intr, this, gpio::INTERRUPT_ANY_EDGE);
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this->last_detected_edge_us_ = 0;
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this->last_valid_edge_us_ = 0;
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this->pulse_width_us_ = 0;
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this->sensor_is_high_ = this->isr_pin_.digital_read();
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this->has_valid_edge_ = false;
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this->pending_state_change_ = NONE;
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if (this->filter_mode_ == FILTER_EDGE) {
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this->pin_->attach_interrupt(PulseMeterSensor::edge_intr, this, gpio::INTERRUPT_RISING_EDGE);
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} else if (this->filter_mode_ == FILTER_PULSE) {
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this->pin_->attach_interrupt(PulseMeterSensor::pulse_intr, this, gpio::INTERRUPT_ANY_EDGE);
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}
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}
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// In PULSE mode we set a flag (pending_state_change_) for every interrupt
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// that constitutes a state change. In the loop() method we check if a time
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// interval greater than the internal_filter time has passed without any
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// interrupts.
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void PulseMeterSensor::loop() {
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// Get a snapshot of the needed volatile sensor values, to make sure they are not
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// modified by the ISR while we are in the loop() method. If they are changed
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// after we the variable "now" has been set, overflow will occur in the
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// subsequent arithmetic
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const bool has_valid_edge = this->has_valid_edge_;
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const uint32_t last_detected_edge_us = this->last_detected_edge_us_;
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const uint32_t last_valid_edge_us = this->last_valid_edge_us_;
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// Get the current time after the snapshot of saved times
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const uint32_t now = micros();
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// Reset the count in get before we pass it back to the ISR as set
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this->get_->count_ = 0;
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this->handle_state_change_(now, last_detected_edge_us, last_valid_edge_us, has_valid_edge);
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// If we've exceeded our timeout interval without receiving any pulses, assume 0 pulses/min until
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// we get at least two valid pulses.
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const uint32_t time_since_valid_edge_us = now - last_detected_edge_us;
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if ((has_valid_edge) && (time_since_valid_edge_us > this->timeout_us_)) {
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ESP_LOGD(TAG, "No pulse detected for %us, assuming 0 pulses/min", time_since_valid_edge_us / 1000000);
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this->last_valid_edge_us_ = 0;
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this->pulse_width_us_ = 0;
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this->has_valid_edge_ = false;
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this->last_detected_edge_us_ = 0;
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}
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// We quantize our pulse widths to 1 ms to avoid unnecessary jitter
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const uint32_t pulse_width_ms = this->pulse_width_us_ / 1000;
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if (this->pulse_width_dedupe_.next(pulse_width_ms)) {
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if (pulse_width_ms == 0) {
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// Treat 0 pulse width as 0 pulses/min (normally because we've not detected any pulses for a while)
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this->publish_state(0);
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} else {
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// Calculate pulses/min from the pulse width in ms
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this->publish_state((60.0f * 1000.0f) / pulse_width_ms);
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}
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}
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// Swap out set and get to get the latest state from the ISR
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// The ISR could interrupt on any of these lines and the results would be consistent
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auto *temp = this->set_;
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this->set_ = this->get_;
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this->get_ = temp;
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// Check if we detected a pulse this loop
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if (this->get_->count_ > 0) {
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// Keep a running total of pulses if a total sensor is configured
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if (this->total_sensor_ != nullptr) {
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this->total_pulses_ += this->get_->count_;
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const uint32_t total = this->total_pulses_;
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if (this->total_dedupe_.next(total)) {
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this->total_sensor_->publish_state(total);
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}
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// We need to detect at least two edges to have a valid pulse width
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if (!this->initialized_) {
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this->initialized_ = true;
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} else {
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uint32_t delta_us = this->get_->last_detected_edge_us_ - this->last_processed_edge_us_;
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float pulse_width_us = delta_us / float(this->get_->count_);
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this->publish_state((60.0f * 1000000.0f) / pulse_width_us);
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}
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this->last_processed_edge_us_ = this->get_->last_detected_edge_us_;
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}
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// No detected edges this loop
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else {
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const uint32_t now = micros();
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const uint32_t time_since_valid_edge_us = now - this->last_processed_edge_us_;
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if (this->initialized_ && time_since_valid_edge_us > this->timeout_us_) {
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ESP_LOGD(TAG, "No pulse detected for %us, assuming 0 pulses/min", time_since_valid_edge_us / 1000000);
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this->initialized_ = false;
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this->publish_state(0.0f);
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}
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}
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}
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void PulseMeterSensor::set_total_pulses(uint32_t pulses) { this->total_pulses_ = pulses; }
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float PulseMeterSensor::get_setup_priority() const { return setup_priority::DATA; }
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void PulseMeterSensor::dump_config() {
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LOG_SENSOR("", "Pulse Meter", this);
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@ -81,96 +74,49 @@ void PulseMeterSensor::dump_config() {
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ESP_LOGCONFIG(TAG, " Assuming 0 pulses/min after not receiving a pulse for %us", this->timeout_us_ / 1000000);
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}
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void IRAM_ATTR PulseMeterSensor::gpio_intr(PulseMeterSensor *sensor) {
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void IRAM_ATTR PulseMeterSensor::edge_intr(PulseMeterSensor *sensor) {
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// This is an interrupt handler - we can't call any virtual method from this method
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// Get the current time before we do anything else so the measurements are consistent
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const uint32_t now = micros();
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if ((now - sensor->last_edge_candidate_us_) >= sensor->filter_us_) {
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sensor->last_edge_candidate_us_ = now;
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sensor->set_->last_detected_edge_us_ = now;
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sensor->set_->count_++;
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}
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}
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void IRAM_ATTR PulseMeterSensor::pulse_intr(PulseMeterSensor *sensor) {
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// This is an interrupt handler - we can't call any virtual method from this method
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// Get the current time before we do anything else so the measurements are consistent
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const uint32_t now = micros();
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const bool pin_val = sensor->isr_pin_.digital_read();
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if (sensor->filter_mode_ == FILTER_EDGE) {
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// We only look at rising edges
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if (!pin_val) {
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return;
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// A pulse occurred faster than we can detect
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if (sensor->last_pin_val_ == pin_val) {
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// If we haven't reached the filter length yet we need to reset our last_intr_ to now
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// otherwise we can consider this noise as the "pulse" was certainly less than filter_us_
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if (now - sensor->last_intr_ < sensor->filter_us_) {
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sensor->last_intr_ = now;
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}
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// Check to see if we should filter this edge out
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if ((now - sensor->last_detected_edge_us_) >= sensor->filter_us_) {
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// Don't measure the first valid pulse (we need at least two pulses to measure the width)
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if (sensor->has_valid_edge_) {
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sensor->pulse_width_us_ = (now - sensor->last_valid_edge_us_);
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}
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sensor->total_pulses_++;
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sensor->last_valid_edge_us_ = now;
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sensor->has_valid_edge_ = true;
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}
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sensor->last_detected_edge_us_ = now;
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} else {
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// Filter Mode is PULSE
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const uint32_t delta_t_us = now - sensor->last_detected_edge_us_;
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// We need to check if we have missed to handle a state change in the
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// loop() function. This can happen when the filter_us value is less than
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// the loop() interval, which is ~50-60ms
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// The section below is essentially a modified repeat of the
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// handle_state_change method. Ideally i would refactor and call the
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// method here as well. However functions called in ISRs need to meet
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// strict criteria and I don't think the methos would meet them.
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if (sensor->pending_state_change_ != NONE && (delta_t_us > sensor->filter_us_)) {
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// We have missed to handle a state change in the loop function.
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sensor->sensor_is_high_ = sensor->pending_state_change_ == TO_HIGH;
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if (sensor->sensor_is_high_) {
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// We need to handle a pulse that would have been missed by the loop function
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sensor->total_pulses_++;
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if (sensor->has_valid_edge_) {
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sensor->pulse_width_us_ = sensor->last_detected_edge_us_ - sensor->last_valid_edge_us_;
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sensor->has_valid_edge_ = true;
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sensor->last_valid_edge_us_ = sensor->last_detected_edge_us_;
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// Check if the last interrupt was long enough in the past
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if (now - sensor->last_intr_ > sensor->filter_us_) {
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// High pulse of filter length now falling (therefore last_intr_ was the rising edge)
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if (!sensor->in_pulse_ && sensor->last_pin_val_) {
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sensor->last_edge_candidate_us_ = sensor->last_intr_;
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sensor->in_pulse_ = true;
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}
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}
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} // End of checking for and handling of change in state
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// Ignore false edges that may be caused by bouncing and exit the ISR ASAP
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if (pin_val == sensor->sensor_is_high_) {
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sensor->pending_state_change_ = NONE;
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return;
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}
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sensor->pending_state_change_ = pin_val ? TO_HIGH : TO_LOW;
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sensor->last_detected_edge_us_ = now;
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// Low pulse of filter length now rising (therefore last_intr_ was the falling edge)
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else if (sensor->in_pulse_ && !sensor->last_pin_val_) {
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sensor->set_->last_detected_edge_us_ = sensor->last_edge_candidate_us_;
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sensor->set_->count_++;
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sensor->in_pulse_ = false;
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}
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}
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void PulseMeterSensor::handle_state_change_(uint32_t now, uint32_t last_detected_edge_us, uint32_t last_valid_edge_us,
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bool has_valid_edge) {
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if (this->pending_state_change_ == NONE) {
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return;
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}
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const bool pin_val = this->isr_pin_.digital_read();
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if (pin_val == this->sensor_is_high_) {
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// Most likely caused by high frequency bouncing. Theoretically we should
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// expect interrupts of alternating state. Here we are registering an
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// interrupt with no change in state. Another interrupt will likely trigger
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// just after this one and have an alternate state.
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this->pending_state_change_ = NONE;
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return;
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}
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if ((now - last_detected_edge_us) > this->filter_us_) {
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this->sensor_is_high_ = pin_val;
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ESP_LOGVV(TAG, "State is now %s", pin_val ? "high" : "low");
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// Increment with valid rising edges only
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if (pin_val) {
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this->total_pulses_++;
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ESP_LOGVV(TAG, "Incremented pulses to %u", this->total_pulses_);
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if (has_valid_edge) {
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this->pulse_width_us_ = last_detected_edge_us - last_valid_edge_us;
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ESP_LOGVV(TAG, "Set pulse width to %u", this->pulse_width_us_);
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}
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this->has_valid_edge_ = true;
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this->last_valid_edge_us_ = last_detected_edge_us;
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ESP_LOGVV(TAG, "last_valid_edge_us_ is now %u", this->last_valid_edge_us_);
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}
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this->pending_state_change_ = NONE;
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sensor->last_intr_ = now;
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sensor->last_pin_val_ = pin_val;
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}
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}
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@ -17,41 +17,50 @@ class PulseMeterSensor : public sensor::Sensor, public Component {
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void set_pin(InternalGPIOPin *pin) { this->pin_ = pin; }
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void set_filter_us(uint32_t filter) { this->filter_us_ = filter; }
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void set_filter_mode(InternalFilterMode mode) { this->filter_mode_ = mode; }
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void set_timeout_us(uint32_t timeout) { this->timeout_us_ = timeout; }
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void set_total_sensor(sensor::Sensor *sensor) { this->total_sensor_ = sensor; }
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void set_total_pulses(uint32_t pulses);
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void set_filter_mode(InternalFilterMode mode) { this->filter_mode_ = mode; }
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void set_total_pulses(uint32_t pulses) { this->total_pulses_ = pulses; }
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void setup() override;
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void loop() override;
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float get_setup_priority() const override { return setup_priority::DATA; }
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float get_setup_priority() const override;
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void dump_config() override;
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protected:
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enum StateChange { TO_LOW = 0, TO_HIGH, NONE };
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static void gpio_intr(PulseMeterSensor *sensor);
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void handle_state_change_(uint32_t now, uint32_t last_detected_edge_us, uint32_t last_valid_edge_us,
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bool has_valid_edge);
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static void edge_intr(PulseMeterSensor *sensor);
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static void pulse_intr(PulseMeterSensor *sensor);
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InternalGPIOPin *pin_{nullptr};
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ISRInternalGPIOPin isr_pin_;
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uint32_t filter_us_ = 0;
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uint32_t timeout_us_ = 1000000UL * 60UL * 5UL;
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sensor::Sensor *total_sensor_{nullptr};
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InternalFilterMode filter_mode_{FILTER_EDGE};
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Deduplicator<uint32_t> pulse_width_dedupe_;
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Deduplicator<uint32_t> total_dedupe_;
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// Variables used in the loop
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bool initialized_ = false;
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uint32_t total_pulses_ = 0;
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uint32_t last_processed_edge_us_ = 0;
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volatile uint32_t last_detected_edge_us_ = 0;
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volatile uint32_t last_valid_edge_us_ = 0;
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volatile uint32_t pulse_width_us_ = 0;
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volatile uint32_t total_pulses_ = 0;
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volatile bool sensor_is_high_ = false;
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volatile bool has_valid_edge_ = false;
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volatile StateChange pending_state_change_{NONE};
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// This struct (and the two pointers) are used to pass data between the ISR and loop.
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// These two pointers are exchanged each loop.
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// Therefore you can't use data in the pointer to loop receives to set values in the pointer to loop sends.
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// As a result it's easiest if you only use these pointers to send data from the ISR to the loop.
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// (except for resetting the values)
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struct State {
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uint32_t last_detected_edge_us_ = 0;
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uint32_t count_ = 0;
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};
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State state_[2];
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volatile State *set_ = state_;
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volatile State *get_ = state_ + 1;
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// Only use these variables in the ISR
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ISRInternalGPIOPin isr_pin_;
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uint32_t last_edge_candidate_us_ = 0;
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uint32_t last_intr_ = 0;
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bool in_pulse_ = false;
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bool last_pin_val_ = false;
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};
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} // namespace pulse_meter
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