mirror of
https://github.com/esphome/esphome.git
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203 lines
9 KiB
C++
203 lines
9 KiB
C++
#include "rotary_encoder.h"
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#include "esphome/core/log.h"
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#include "esphome/core/helpers.h"
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namespace esphome {
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namespace rotary_encoder {
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static const char *TAG = "rotary_encoder";
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// based on https://github.com/jkDesignDE/MechInputs/blob/master/QEIx4.cpp
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static const uint8_t STATE_LUT_MASK = 0x1C; // clears upper counter increment/decrement bits and pin states
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static const uint16_t STATE_PIN_A_HIGH = 0x01;
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static const uint16_t STATE_PIN_B_HIGH = 0x02;
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static const uint16_t STATE_S0 = 0x00;
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static const uint16_t STATE_S1 = 0x04;
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static const uint16_t STATE_S2 = 0x08;
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static const uint16_t STATE_S3 = 0x0C;
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static const uint16_t STATE_CCW = 0x00;
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static const uint16_t STATE_CW = 0x10;
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static const uint16_t STATE_HAS_INCREMENTED = 0x0700;
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static const uint16_t STATE_INCREMENT_COUNTER_4 = 0x0700;
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static const uint16_t STATE_INCREMENT_COUNTER_2 = 0x0300;
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static const uint16_t STATE_INCREMENT_COUNTER_1 = 0x0100;
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static const uint16_t STATE_HAS_DECREMENTED = 0x7000;
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static const uint16_t STATE_DECREMENT_COUNTER_4 = 0x7000;
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static const uint16_t STATE_DECREMENT_COUNTER_2 = 0x3000;
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static const uint16_t STATE_DECREMENT_COUNTER_1 = 0x1000;
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// State explanation: 8-bit uint
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// Bit 0 (0x01) encodes Pin A HIGH/LOW (reset before each read)
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// Bit 1 (0x02) encodes Pin B HIGH/LOW (reset before each read)
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// Bit 2&3 (0x0C) encodes state S0-S3
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// Bit 4 (0x10) encodes clockwise/counter-clockwise rotation
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// Only apply if DRAM_ATTR exists on this platform (exists on ESP32, not on ESP8266)
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#ifndef DRAM_ATTR
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#define DRAM_ATTR
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#endif
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// array needs to be placed in .dram1 for ESP32
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// otherwise it will automatically go into flash, and cause cache disabled issues
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static const uint16_t DRAM_ATTR STATE_LOOKUP_TABLE[32] = {
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// act state S0 in CCW direction
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STATE_CCW | STATE_S0, // 0x00: stay here
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STATE_CW | STATE_S1 | STATE_INCREMENT_COUNTER_1, // 0x01: goto CW+S1 and increment counter (dir change)
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STATE_CCW | STATE_S0, // 0x02: stay here
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STATE_CCW | STATE_S3 | STATE_DECREMENT_COUNTER_4, // 0x03: goto CCW+S3 and decrement counter
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// act state S1 in CCW direction
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STATE_CCW | STATE_S1, // 0x04: stay here
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STATE_CCW | STATE_S1, // 0x05: stay here
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STATE_CCW | STATE_S0 | STATE_DECREMENT_COUNTER_1, // 0x06: goto CCW+S0 and decrement counter
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STATE_CW | STATE_S2 | STATE_INCREMENT_COUNTER_4, // 0x07: goto CW+S2 and increment counter (dir change)
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// act state S2 in CCW direction
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STATE_CCW | STATE_S1 | STATE_DECREMENT_COUNTER_2, // 0x08: goto CCW+S1 and decrement counter
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STATE_CCW | STATE_S2, // 0x09: stay here
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STATE_CW | STATE_S3 | STATE_INCREMENT_COUNTER_1, // 0x0A: goto CW+S3 and increment counter (dir change)
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STATE_CCW | STATE_S2, // 0x0B: stay here
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// act state S3 in CCW direction
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STATE_CW | STATE_S0 | STATE_INCREMENT_COUNTER_2, // 0x0C: goto CW+S0 and increment counter (dir change)
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STATE_CCW | STATE_S2 | STATE_DECREMENT_COUNTER_1, // 0x0D: goto CCW+S2 and decrement counter
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STATE_CCW | STATE_S3, // 0x0E: stay here
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STATE_CCW | STATE_S3, // 0x0F: stay here
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// act state S0 in CW direction
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STATE_CW | STATE_S0, // 0x10: stay here
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STATE_CW | STATE_S1 | STATE_INCREMENT_COUNTER_1, // 0x11: goto CW+S1 and increment counter
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STATE_CW | STATE_S0, // 0x12: stay here
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STATE_CCW | STATE_S3 | STATE_DECREMENT_COUNTER_4, // 0x13: goto CCW+S3 and decrement counter (dir change)
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// act state S1 in CW direction
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STATE_CW | STATE_S1, // 0x14: stay here
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STATE_CW | STATE_S1, // 0x15: stay here
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STATE_CCW | STATE_S0 | STATE_DECREMENT_COUNTER_1, // 0x16: goto CCW+S0 and decrement counter (dir change)
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STATE_CW | STATE_S2 | STATE_INCREMENT_COUNTER_4, // 0x17: goto CW+S2 and increment counter
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// act state S2 in CW direction
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STATE_CCW | STATE_S1 | STATE_DECREMENT_COUNTER_2, // 0x18: goto CCW+S1 and decrement counter (dir change)
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STATE_CW | STATE_S2, // 0x19: stay here
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STATE_CW | STATE_S3 | STATE_INCREMENT_COUNTER_1, // 0x1A: goto CW+S3 and increment counter
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STATE_CW | STATE_S2,
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// act state S3 in CW direction
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STATE_CW | STATE_S0 | STATE_INCREMENT_COUNTER_2, // 0x1C: goto CW+S0 and increment counter
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STATE_CCW | STATE_S2 | STATE_DECREMENT_COUNTER_1, // 0x1D: goto CCW+S2 and decrement counter (dir change)
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STATE_CW | STATE_S3, // 0x1E: stay here
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STATE_CW | STATE_S3 // 0x1F: stay here
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};
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void ICACHE_RAM_ATTR HOT RotaryEncoderSensorStore::gpio_intr(RotaryEncoderSensorStore *arg) {
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// Forget upper bits and add pin states
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uint8_t input_state = arg->state & STATE_LUT_MASK;
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if (arg->pin_a->digital_read())
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input_state |= STATE_PIN_A_HIGH;
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if (arg->pin_b->digital_read())
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input_state |= STATE_PIN_B_HIGH;
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int8_t rotation_dir = 0;
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uint16_t new_state = STATE_LOOKUP_TABLE[input_state];
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if ((new_state & arg->resolution & STATE_HAS_INCREMENTED) != 0) {
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if (arg->counter < arg->max_value)
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arg->counter++;
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rotation_dir = 1;
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}
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if ((new_state & arg->resolution & STATE_HAS_DECREMENTED) != 0) {
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if (arg->counter > arg->min_value)
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arg->counter--;
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rotation_dir = -1;
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}
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if (rotation_dir != 0) {
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auto first_zero = std::find(arg->rotation_events.begin(), arg->rotation_events.end(), 0); // find first zero
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if (first_zero == arg->rotation_events.begin() // are we at the start (first event this loop iteration)
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|| std::signbit(*std::prev(first_zero)) !=
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std::signbit(rotation_dir) // or is the last stored event the wrong direction
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|| *std::prev(first_zero) == std::numeric_limits<int8_t>::lowest() // or the last event slot is full (negative)
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|| *std::prev(first_zero) == std::numeric_limits<int8_t>::max()) { // or the last event slot is full (positive)
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if (first_zero != arg->rotation_events.end()) { // we have a free rotation slot
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*first_zero += rotation_dir; // store the rotation into a new slot
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} else {
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arg->rotation_events_overflow = true;
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}
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} else {
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*std::prev(first_zero) += rotation_dir; // store the rotation into the previous slot
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}
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}
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arg->state = new_state;
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}
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void RotaryEncoderSensor::setup() {
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ESP_LOGCONFIG(TAG, "Setting up Rotary Encoder '%s'...", this->name_.c_str());
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this->pin_a_->setup();
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this->store_.pin_a = this->pin_a_->to_isr();
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this->pin_b_->setup();
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this->store_.pin_b = this->pin_b_->to_isr();
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if (this->pin_i_ != nullptr) {
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this->pin_i_->setup();
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}
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this->pin_a_->attach_interrupt(RotaryEncoderSensorStore::gpio_intr, &this->store_, CHANGE);
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this->pin_b_->attach_interrupt(RotaryEncoderSensorStore::gpio_intr, &this->store_, CHANGE);
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}
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void RotaryEncoderSensor::dump_config() {
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LOG_SENSOR("", "Rotary Encoder", this);
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LOG_PIN(" Pin A: ", this->pin_a_);
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LOG_PIN(" Pin B: ", this->pin_b_);
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LOG_PIN(" Pin I: ", this->pin_i_);
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switch (this->store_.resolution) {
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case ROTARY_ENCODER_1_PULSE_PER_CYCLE:
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ESP_LOGCONFIG(TAG, " Resolution: 1 Pulse Per Cycle");
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break;
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case ROTARY_ENCODER_2_PULSES_PER_CYCLE:
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ESP_LOGCONFIG(TAG, " Resolution: 2 Pulses Per Cycle");
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break;
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case ROTARY_ENCODER_4_PULSES_PER_CYCLE:
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ESP_LOGCONFIG(TAG, " Resolution: 4 Pulse Per Cycle");
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break;
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}
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}
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void RotaryEncoderSensor::loop() {
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std::array<int8_t, 8> rotation_events;
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bool rotation_events_overflow;
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ets_intr_lock();
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rotation_events = this->store_.rotation_events;
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rotation_events_overflow = this->store_.rotation_events_overflow;
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this->store_.rotation_events.fill(0);
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this->store_.rotation_events_overflow = false;
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ets_intr_unlock();
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if (rotation_events_overflow) {
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ESP_LOGW(TAG, "Captured more rotation events than expected");
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}
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for (auto events : rotation_events) {
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if (events == 0) // we are at the end of the recorded events
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break;
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if (events > 0) {
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while (events--) {
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this->on_clockwise_callback_.call();
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}
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} else {
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while (events++) {
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this->on_anticlockwise_callback_.call();
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}
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}
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}
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if (this->pin_i_ != nullptr && this->pin_i_->digital_read()) {
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this->store_.counter = 0;
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}
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int counter = this->store_.counter;
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if (this->store_.last_read != counter) {
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this->store_.last_read = counter;
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this->publish_state(counter);
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}
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}
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float RotaryEncoderSensor::get_setup_priority() const { return setup_priority::DATA; }
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void RotaryEncoderSensor::set_resolution(RotaryEncoderResolution mode) { this->store_.resolution = mode; }
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void RotaryEncoderSensor::set_min_value(int32_t min_value) { this->store_.min_value = min_value; }
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void RotaryEncoderSensor::set_max_value(int32_t max_value) { this->store_.max_value = max_value; }
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} // namespace rotary_encoder
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} // namespace esphome
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