// ----------------------------------------------------------------------------- // Event Counter Sensor // Copyright (C) 2017-2018 by Xose PĂ©rez // ----------------------------------------------------------------------------- #if SENSOR_SUPPORT && EVENTS_SUPPORT #pragma once #include "Arduino.h" #include "BaseSensor.h" class EventSensor : public BaseSensor { public: // --------------------------------------------------------------------- // Public // --------------------------------------------------------------------- EventSensor(): BaseSensor() { _count = 1; _sensor_id = SENSOR_EVENTS_ID; } ~EventSensor() { _enableInterrupts(false); } // --------------------------------------------------------------------- void setGPIO(unsigned char gpio) { _gpio = gpio; } void setMode(unsigned char mode) { _mode = mode; } void setInterruptMode(unsigned char mode) { _interrupt_mode = mode; } void setDebounceTime(unsigned long debounce) { _debounce = debounce; } // --------------------------------------------------------------------- unsigned char getGPIO() { return _gpio; } unsigned char getMode() { return _mode; } unsigned char getInterruptMode() { return _interrupt_mode; } unsigned long getDebounceTime() { return _debounce; } // --------------------------------------------------------------------- // Sensors API // --------------------------------------------------------------------- // Initialization method, must be idempotent // Defined outside the class body void begin() { pinMode(_gpio, _mode); _enableInterrupts(true); } // Descriptive name of the sensor String description() { char buffer[20]; snprintf(buffer, sizeof(buffer), "INTERRUPT @ GPIO%d", _gpio); return String(buffer); } // Type for slot # index unsigned char type(unsigned char index) { _error = SENSOR_ERROR_OK; if (index == 0) return MAGNITUDE_EVENTS; _error = SENSOR_ERROR_OUT_OF_RANGE; return MAGNITUDE_NONE; } // Current value for slot # index double value(unsigned char index) { _error = SENSOR_ERROR_OK; if (index == 0) { double value = _events; _events = 0; return value; }; _error = SENSOR_ERROR_OUT_OF_RANGE; return 0; } // Handle interrupt calls void handleInterrupt(unsigned char gpio) { (void) gpio; static unsigned long last = 0; if (millis() - last > _debounce) { _events = _events + 1; last = millis(); } } protected: // --------------------------------------------------------------------- // Interrupt management // --------------------------------------------------------------------- void _attach(EventSensor * instance, unsigned char gpio, unsigned char mode); void _detach(unsigned char gpio); void _enableInterrupts(bool value) { static unsigned char _interrupt_gpio = GPIO_NONE; if (value) { if (_interrupt_gpio != GPIO_NONE) _detach(_interrupt_gpio); _attach(this, _gpio, _interrupt_mode); _interrupt_gpio = _gpio; } else if (_interrupt_gpio != GPIO_NONE) { _detach(_interrupt_gpio); _interrupt_gpio = GPIO_NONE; } } // --------------------------------------------------------------------- // Protected // --------------------------------------------------------------------- volatile unsigned long _events = 0; unsigned long _debounce = EVENTS_DEBOUNCE; unsigned char _gpio; unsigned char _mode; unsigned char _interrupt_mode; }; // ----------------------------------------------------------------------------- // Interrupt helpers // ----------------------------------------------------------------------------- EventSensor * _event_sensor_instance[10] = {NULL}; void ICACHE_RAM_ATTR _event_sensor_isr(unsigned char gpio) { unsigned char index = gpio > 5 ? gpio-6 : gpio; if (_event_sensor_instance[index]) { _event_sensor_instance[index]->handleInterrupt(gpio); } } void ICACHE_RAM_ATTR _event_sensor_isr_0() { _event_sensor_isr(0); } void ICACHE_RAM_ATTR _event_sensor_isr_1() { _event_sensor_isr(1); } void ICACHE_RAM_ATTR _event_sensor_isr_2() { _event_sensor_isr(2); } void ICACHE_RAM_ATTR _event_sensor_isr_3() { _event_sensor_isr(3); } void ICACHE_RAM_ATTR _event_sensor_isr_4() { _event_sensor_isr(4); } void ICACHE_RAM_ATTR _event_sensor_isr_5() { _event_sensor_isr(5); } void ICACHE_RAM_ATTR _event_sensor_isr_12() { _event_sensor_isr(12); } void ICACHE_RAM_ATTR _event_sensor_isr_13() { _event_sensor_isr(13); } void ICACHE_RAM_ATTR _event_sensor_isr_14() { _event_sensor_isr(14); } void ICACHE_RAM_ATTR _event_sensor_isr_15() { _event_sensor_isr(15); } static void (*_event_sensor_isr_list[10])() = { _event_sensor_isr_0, _event_sensor_isr_1, _event_sensor_isr_2, _event_sensor_isr_3, _event_sensor_isr_4, _event_sensor_isr_5, _event_sensor_isr_12, _event_sensor_isr_13, _event_sensor_isr_14, _event_sensor_isr_15 }; void EventSensor::_attach(EventSensor * instance, unsigned char gpio, unsigned char mode) { if (!gpioValid(gpio)) return; _detach(gpio); unsigned char index = gpio > 5 ? gpio-6 : gpio; _event_sensor_instance[index] = instance; attachInterrupt(gpio, _event_sensor_isr_list[index], mode); #if SENSOR_DEBUG DEBUG_MSG_P(PSTR("[SENSOR] GPIO%d interrupt attached to %s\n"), gpio, instance->description().c_str()); #endif } void EventSensor::_detach(unsigned char gpio) { if (!gpioValid(gpio)) return; unsigned char index = gpio > 5 ? gpio-6 : gpio; if (_event_sensor_instance[index]) { detachInterrupt(gpio); #if SENSOR_DEBUG DEBUG_MSG_P(PSTR("[SENSOR] GPIO%d interrupt detached from %s\n"), gpio, _event_sensor_instance[index]->description().c_str()); #endif _event_sensor_instance[index] = NULL; } } #endif // SENSOR_SUPPORT && EVENTS_SUPPORT