/* * Copyright (c) 2019 David Antliff * Copyright 2011 Ben Buxton * * This file is part of the esp32-rotary-encoder component. * * esp32-rotary-encoder is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * esp32-rotary-encoder is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with esp32-rotary-encoder. If not, see . */ /** * @file rotary_encoder.h * @brief Interface definitions for the ESP32-compatible Incremental Rotary Encoder component. * * This component provides a means to interface with a typical rotary encoder such as the EC11 or LPD3806. * These encoders produce a quadrature signal on two outputs, which can be used to track the position and * direction as movement occurs. * * This component provides functions to initialise the GPIOs and install appropriate interrupt handlers to * track a single device's position. An event queue is used to provide a way for a user task to obtain * position information from the component as it is generated. * * Note that the queue is of length 1, and old values will be overwritten. Using a longer queue is * possible with some minor modifications however newer values are lost if the queue overruns. A circular * buffer where old values are lost would be better (maybe StreamBuffer in FreeRTOS 10.0.0?). */ #ifndef ROTARY_ENCODER_H #define ROTARY_ENCODER_H #include #include #include "freertos/FreeRTOS.h" #include "freertos/queue.h" #include "esp_err.h" #include "driver/gpio.h" #ifdef __cplusplus extern "C" { #endif typedef int32_t rotary_encoder_position_t; /** * @brief Enum representing the direction of rotation. */ typedef enum { ROTARY_ENCODER_DIRECTION_NOT_SET = 0, ///< Direction not yet known (stationary since reset) ROTARY_ENCODER_DIRECTION_CLOCKWISE, ROTARY_ENCODER_DIRECTION_COUNTER_CLOCKWISE, } rotary_encoder_direction_t; // Used internally ///@cond INTERNAL #define TABLE_COLS 4 typedef uint8_t table_row_t[TABLE_COLS]; ///@endcond /** * @brief Struct represents the current state of the device in terms of incremental position and direction of last movement */ typedef struct { rotary_encoder_position_t position; ///< Numerical position since reset. This value increments on clockwise rotation, and decrements on counter-clockewise rotation. Counts full or half steps depending on mode. Set to zero on reset. rotary_encoder_direction_t direction; ///< Direction of last movement. Set to NOT_SET on reset. uint32_t swLastTime; uint8_t swState; bool swDebounce; bool clicked; } rotary_encoder_state_t; /** * @brief Struct carries all the information needed by this driver to manage the rotary encoder device. * The fields of this structure should not be accessed directly. */ typedef struct { gpio_num_t pin_a; ///< GPIO for Signal A from the rotary encoder device gpio_num_t pin_b; ///< GPIO for Signal B from the rotary encoder device gpio_num_t pin_sw; ///< GPIO for Signal C from the rotary encoder device QueueHandle_t queue; ///< Handle for event queue, created by ::rotary_encoder_create_queue const table_row_t * table; ///< Pointer to active state transition table uint8_t table_state; ///< Internal state volatile rotary_encoder_state_t state; ///< Device state } rotary_encoder_info_t; /** * @brief Struct represents a queued event, used to communicate current position to a waiting task */ typedef struct { rotary_encoder_state_t state; ///< The device state corresponding to this event } rotary_encoder_event_t; /** * @brief Initialise the rotary encoder device with the specified GPIO pins and full step increments. * This function will set up the GPIOs as needed, * Note: this function assumes that gpio_install_isr_service(0) has already been called. * @param[in, out] info Pointer to allocated rotary encoder info structure. * @param[in] pin_a GPIO number for rotary encoder output A. * @param[in] pin_b GPIO number for rotary encoder output B. * @return ESP_OK if successful, ESP_FAIL or ESP_ERR_* if an error occurred. */ esp_err_t rotary_encoder_init(rotary_encoder_info_t * info, gpio_num_t pin_a, gpio_num_t pin_b, gpio_num_t pin_c); /** * @brief Enable half-stepping mode. This generates twice as many counted steps per rotation. * @param[in] info Pointer to initialised rotary encoder info structure. * @param[in] enable If true, count half steps. If false, only count full steps. * @return ESP_OK if successful, ESP_FAIL or ESP_ERR_* if an error occurred. */ esp_err_t rotary_encoder_enable_half_steps(rotary_encoder_info_t * info, bool enable); /** * @brief Reverse (flip) the sense of the direction. * Use this if clockwise/counterclockwise are not what you expect. * @param[in] info Pointer to initialised rotary encoder info structure. * @return ESP_OK if successful, ESP_FAIL or ESP_ERR_* if an error occurred. */ esp_err_t rotary_encoder_flip_direction(rotary_encoder_info_t * info); /** * @brief Remove the interrupt handlers installed by ::rotary_encoder_init. * Note: GPIOs will be left in the state they were configured by ::rotary_encoder_init. * @param[in] info Pointer to initialised rotary encoder info structure. * @return ESP_OK if successful, ESP_FAIL or ESP_ERR_* if an error occurred. */ esp_err_t rotary_encoder_uninit(rotary_encoder_info_t * info); /** * @brief Create a queue handle suitable for use as an event queue. * @return A handle to a new queue suitable for use as an event queue. */ QueueHandle_t rotary_encoder_create_queue(void); /** * @brief Set the driver to use the specified queue as an event queue. * It is recommended that a queue constructed by ::rotary_encoder_create_queue is used. * @param[in] info Pointer to initialised rotary encoder info structure. * @param[in] queue Handle to queue suitable for use as an event queue. See ::rotary_encoder_create_queue. * @return ESP_OK if successful, ESP_FAIL or ESP_ERR_* if an error occurred. */ esp_err_t rotary_encoder_set_queue(rotary_encoder_info_t * info, QueueHandle_t queue); /** * @brief Get the current position of the rotary encoder. * @param[in] info Pointer to initialised rotary encoder info structure. * @param[in, out] state Pointer to an allocated rotary_encoder_state_t struct that will * @return ESP_OK if successful, ESP_FAIL or ESP_ERR_* if an error occurred. */ esp_err_t rotary_encoder_get_state(const rotary_encoder_info_t * info, rotary_encoder_state_t * state); /** * @brief Reset the current position of the rotary encoder to zero. * @param[in] info Pointer to initialised rotary encoder info structure. * @return ESP_OK if successful, ESP_FAIL or ESP_ERR_* if an error occurred. */ esp_err_t rotary_encoder_reset(rotary_encoder_info_t * info); #ifdef __cplusplus } #endif #endif // ROTARY_ENCODER_H