components/esp32-rotary-encoder/rotary_encoder.c@8a3696620c0a
components/esp32-rotary-encoder/rotary_encoder.c
Fri, 08 Nov 2019 22:40:15 +0100
- author
- Michiel Broek <mbroek@mbse.eu>
- date
- Fri, 08 Nov 2019 22:40:15 +0100
- changeset 26
- 8a3696620c0a
- parent 0
- 88d965579617
- child 73
- c18d2951e8d7
- permissions
- -rw-r--r--
Increaded stacksize for the user process. Implemented the network update using the proven brewboard code. Reverted the lock release and display sendbuffer lines to the previous code. The networks status screen uses the wifi lock.
/* * 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 <https://www.gnu.org/licenses/>. */ /** * @file rotary_encoder.c * @brief Driver implementation for the ESP32-compatible Incremental Rotary Encoder component. * * Based on https://github.com/buxtronix/arduino/tree/master/libraries/Rotary * Original header follows: * * Rotary encoder handler for arduino. v1.1 * * Copyright 2011 Ben Buxton. Licenced under the GNU GPL Version 3. * Contact: bb@cactii.net * * A typical mechanical rotary encoder emits a two bit gray code * on 3 output pins. Every step in the output (often accompanied * by a physical 'click') generates a specific sequence of output * codes on the pins. * * There are 3 pins used for the rotary encoding - one common and * two 'bit' pins. * * The following is the typical sequence of code on the output when * moving from one step to the next: * * Position Bit1 Bit2 * ---------------------- * Step1 0 0 * 1/4 1 0 * 1/2 1 1 * 3/4 0 1 * Step2 0 0 * * From this table, we can see that when moving from one 'click' to * the next, there are 4 changes in the output code. * * - From an initial 0 - 0, Bit1 goes high, Bit0 stays low. * - Then both bits are high, halfway through the step. * - Then Bit1 goes low, but Bit2 stays high. * - Finally at the end of the step, both bits return to 0. * * Detecting the direction is easy - the table simply goes in the other * direction (read up instead of down). * * To decode this, we use a simple state machine. Every time the output * code changes, it follows state, until finally a full steps worth of * code is received (in the correct order). At the final 0-0, it returns * a value indicating a step in one direction or the other. * * It's also possible to use 'half-step' mode. This just emits an event * at both the 0-0 and 1-1 positions. This might be useful for some * encoders where you want to detect all positions. * * If an invalid state happens (for example we go from '0-1' straight * to '1-0'), the state machine resets to the start until 0-0 and the * next valid codes occur. * * The biggest advantage of using a state machine over other algorithms * is that this has inherent debounce built in. Other algorithms emit spurious * output with switch bounce, but this one will simply flip between * sub-states until the bounce settles, then continue along the state * machine. * A side effect of debounce is that fast rotations can cause steps to * be skipped. By not requiring debounce, fast rotations can be accurately * measured. * Another advantage is the ability to properly handle bad state, such * as due to EMI, etc. * It is also a lot simpler than others - a static state table and less * than 10 lines of logic. */ #include "rotary_encoder.h" #include "esp_log.h" #include "driver/gpio.h" #define TAG "rotary_encoder" //#define ROTARY_ENCODER_DEBUG // Use a single-item queue so that the last value can be easily overwritten by the interrupt handler #define EVENT_QUEUE_LENGTH 1 #define TABLE_ROWS 7 #define DIR_NONE 0x0 // No complete step yet. #define DIR_CW 0x10 // Clockwise step. #define DIR_CCW 0x20 // Anti-clockwise step. // Create the half-step state table (emits a code at 00 and 11) #define R_START 0x0 #define H_CCW_BEGIN 0x1 #define H_CW_BEGIN 0x2 #define H_START_M 0x3 #define H_CW_BEGIN_M 0x4 #define H_CCW_BEGIN_M 0x5 static const uint8_t _ttable_half[TABLE_ROWS][TABLE_COLS] = { // 00 01 10 11 // BA {H_START_M, H_CW_BEGIN, H_CCW_BEGIN, R_START}, // R_START (00) {H_START_M | DIR_CCW, R_START, H_CCW_BEGIN, R_START}, // H_CCW_BEGIN {H_START_M | DIR_CW, H_CW_BEGIN, R_START, R_START}, // H_CW_BEGIN {H_START_M, H_CCW_BEGIN_M, H_CW_BEGIN_M, R_START}, // H_START_M (11) {H_START_M, H_START_M, H_CW_BEGIN_M, R_START | DIR_CW}, // H_CW_BEGIN_M {H_START_M, H_CCW_BEGIN_M, H_START_M, R_START | DIR_CCW}, // H_CCW_BEGIN_M }; // Create the full-step state table (emits a code at 00 only) # define F_CW_FINAL 0x1 # define F_CW_BEGIN 0x2 # define F_CW_NEXT 0x3 # define F_CCW_BEGIN 0x4 # define F_CCW_FINAL 0x5 # define F_CCW_NEXT 0x6 static const uint8_t _ttable_full[TABLE_ROWS][TABLE_COLS] = { // 00 01 10 11 // BA {R_START, F_CW_BEGIN, F_CCW_BEGIN, R_START}, // R_START {F_CW_NEXT, R_START, F_CW_FINAL, R_START | DIR_CW}, // F_CW_FINAL {F_CW_NEXT, F_CW_BEGIN, R_START, R_START}, // F_CW_BEGIN {F_CW_NEXT, F_CW_BEGIN, F_CW_FINAL, R_START}, // F_CW_NEXT {F_CCW_NEXT, R_START, F_CCW_BEGIN, R_START}, // F_CCW_BEGIN {F_CCW_NEXT, F_CCW_FINAL, R_START, R_START | DIR_CCW}, // F_CCW_FINAL {F_CCW_NEXT, F_CCW_FINAL, F_CCW_BEGIN, R_START}, // F_CCW_NEXT }; static uint8_t _process(rotary_encoder_info_t * info) { uint8_t event = 0; if (info != NULL) { // Get state of input pins. uint8_t pin_state = (gpio_get_level(info->pin_b) << 1) | gpio_get_level(info->pin_a); // Determine new state from the pins and state table. #ifdef ROTARY_ENCODER_DEBUG uint8_t old_state = info->table_state; #endif info->table_state = info->table[info->table_state & 0xf][pin_state]; // Return emit bits, i.e. the generated event. event = info->table_state & 0x30; #ifdef ROTARY_ENCODER_DEBUG ESP_EARLY_LOGD(TAG, "BA %d%d, state 0x%02x, new state 0x%02x, event 0x%02x", pin_state >> 1, pin_state & 1, old_state, info->table_state, event); #endif } return event; } static void _isr_rotenc(void * args) { rotary_encoder_info_t * info = (rotary_encoder_info_t *)args; uint8_t event = _process(info); bool send_event = false; switch (event) { case DIR_CW: ++info->state.position; info->state.direction = ROTARY_ENCODER_DIRECTION_CLOCKWISE; send_event = true; break; case DIR_CCW: --info->state.position; info->state.direction = ROTARY_ENCODER_DIRECTION_COUNTER_CLOCKWISE; send_event = true; break; default: break; } if (send_event && info->queue) { rotary_encoder_event_t queue_event = { .state = { .position = info->state.position, .direction = info->state.direction, }, }; BaseType_t task_woken = pdFALSE; xQueueOverwriteFromISR(info->queue, &queue_event, &task_woken); if (task_woken) { portYIELD_FROM_ISR(); } } } esp_err_t rotary_encoder_init(rotary_encoder_info_t * info, gpio_num_t pin_a, gpio_num_t pin_b) { esp_err_t err = ESP_OK; if (info) { info->pin_a = pin_a; info->pin_b = pin_b; info->table = &_ttable_full[0]; //enable_half_step ? &_ttable_half[0] : &_ttable_full[0]; info->table_state = R_START; info->state.position = 0; info->state.direction = ROTARY_ENCODER_DIRECTION_NOT_SET; // configure GPIOs gpio_pad_select_gpio(info->pin_a); gpio_set_pull_mode(info->pin_a, GPIO_PULLUP_ONLY); gpio_set_direction(info->pin_a, GPIO_MODE_INPUT); gpio_set_intr_type(info->pin_a, GPIO_INTR_ANYEDGE); gpio_pad_select_gpio(info->pin_b); gpio_set_pull_mode(info->pin_b, GPIO_PULLUP_ONLY); gpio_set_direction(info->pin_b, GPIO_MODE_INPUT); gpio_set_intr_type(info->pin_b, GPIO_INTR_ANYEDGE); // install interrupt handlers gpio_isr_handler_add(info->pin_a, _isr_rotenc, info); gpio_isr_handler_add(info->pin_b, _isr_rotenc, info); } else { ESP_LOGE(TAG, "info is NULL"); err = ESP_ERR_INVALID_ARG; } return err; } esp_err_t rotary_encoder_enable_half_steps(rotary_encoder_info_t * info, bool enable) { esp_err_t err = ESP_OK; if (info) { info->table = enable ? &_ttable_half[0] : &_ttable_full[0]; info->table_state = R_START; } else { ESP_LOGE(TAG, "info is NULL"); err = ESP_ERR_INVALID_ARG; } return err; } esp_err_t rotary_encoder_flip_direction(rotary_encoder_info_t * info) { esp_err_t err = ESP_OK; if (info) { gpio_num_t temp = info->pin_a; info->pin_a = info->pin_b; info->pin_b = temp; } else { ESP_LOGE(TAG, "info is NULL"); err = ESP_ERR_INVALID_ARG; } return err; } esp_err_t rotary_encoder_uninit(rotary_encoder_info_t * info) { esp_err_t err = ESP_OK; if (info) { gpio_isr_handler_remove(info->pin_a); gpio_isr_handler_remove(info->pin_b); } else { ESP_LOGE(TAG, "info is NULL"); err = ESP_ERR_INVALID_ARG; } return err; } QueueHandle_t rotary_encoder_create_queue(void) { return xQueueCreate(EVENT_QUEUE_LENGTH, sizeof(rotary_encoder_event_t)); } esp_err_t rotary_encoder_set_queue(rotary_encoder_info_t * info, QueueHandle_t queue) { esp_err_t err = ESP_OK; if (info) { info->queue = queue; } else { ESP_LOGE(TAG, "info is NULL"); err = ESP_ERR_INVALID_ARG; } return err; } esp_err_t rotary_encoder_get_state(const rotary_encoder_info_t * info, rotary_encoder_state_t * state) { esp_err_t err = ESP_OK; if (info && state) { // make a snapshot of the state state->position = info->state.position; state->direction = info->state.direction; } else { ESP_LOGE(TAG, "info and/or state is NULL"); err = ESP_ERR_INVALID_ARG; } return err; } esp_err_t rotary_encoder_reset(rotary_encoder_info_t * info) { esp_err_t err = ESP_OK; if (info) { info->state.position = 0; info->state.direction = ROTARY_ENCODER_DIRECTION_NOT_SET; } else { ESP_LOGE(TAG, "info is NULL"); err = ESP_ERR_INVALID_ARG; } return err; }
