/* BUTTON MODULE Copyright (C) 2016-2019 by Xose PĂ©rez */ #if BUTTON_SUPPORT #include #include #include "system.h" #include "relay.h" #include "light.h" #include "button.h" #include "button_config.h" #include "debounce.h" // ----------------------------------------------------------------------------- button_event_delays_t::button_event_delays_t() : debounce(BUTTON_DEBOUNCE_DELAY), dblclick(BUTTON_DBLCLICK_DELAY), lngclick(BUTTON_LNGCLICK_DELAY), lnglngclick(BUTTON_LNGLNGCLICK_DELAY) {} button_event_delays_t::button_event_delays_t(unsigned long debounce, unsigned long dblclick, unsigned long lngclick, unsigned long lnglngclick) : debounce(debounce), dblclick(dblclick), lngclick(lngclick), lnglngclick(lnglngclick) {} button_t::button_t(std::shared_ptr pin, int mode, unsigned long actions, unsigned char relayID, button_event_delays_t delays) : event_handler(new DebounceEvent::DebounceEvent(pin, mode, delays.debounce, delays.dblclick)), event_delays(delays), actions(actions), relayID(relayID) {} bool button_t::state() { return event_handler->pressed(); } std::vector _buttons; // ----------------------------------------------------------------------------- constexpr const uint8_t _buttonMapReleased(uint8_t count, uint8_t length, unsigned long lngclick_delay, unsigned long lnglngclick_delay) { return ( (1 == count) ? ( (length > lnglngclick_delay) ? BUTTON_EVENT_LNGLNGCLICK : (length > lngclick_delay) ? BUTTON_EVENT_LNGCLICK : BUTTON_EVENT_CLICK ) : (2 == count) ? BUTTON_EVENT_DBLCLICK : (3 == count) ? BUTTON_EVENT_TRIPLECLICK : BUTTON_EVENT_NONE ); } const uint8_t _buttonMapEvent(button_t& button, DebounceEvent::Types::event_t event) { using namespace DebounceEvent; switch (event) { case Types::EventPressed: return BUTTON_EVENT_PRESSED; case Types::EventChanged: return BUTTON_EVENT_CLICK; case Types::EventReleased: { return _buttonMapReleased( button.event_handler->getEventCount(), button.event_handler->getEventLength(), button.event_delays.lngclick, button.event_delays.lnglngclick ); } case Types::EventNone: default: return BUTTON_EVENT_NONE; } } unsigned char buttonCount() { return _buttons.size(); } #if MQTT_SUPPORT void buttonMQTT(unsigned char id, uint8_t event) { char payload[4] = {0}; itoa(event, payload, 10); mqttSend(MQTT_TOPIC_BUTTON, id, payload, false, false); // 1st bool = force, 2nd = retain } #endif #if WEB_SUPPORT void _buttonWebSocketOnVisible(JsonObject& root) { if (buttonCount() > 0) { root["btnVisible"] = 1; } } bool _buttonWebSocketOnKeyCheck(const char * key, JsonVariant& value) { return (strncmp(key, "btn", 3) == 0); } #endif bool buttonState(unsigned char id) { if (id >= _buttons.size()) return false; return _buttons[id].state(); } unsigned char buttonAction(unsigned char id, unsigned char event) { if (id >= _buttons.size()) return BUTTON_MODE_NONE; return _buttonDecodeEventAction(_buttons[id].actions, event); } void buttonEvent(unsigned char id, unsigned char event) { DEBUG_MSG_P(PSTR("[BUTTON] Button #%u event %u\n"), id, event); if (event == 0) return; auto& button = _buttons[id]; unsigned char action = _buttonDecodeEventAction(button.actions, event); #if MQTT_SUPPORT if (action != BUTTON_MODE_NONE || BUTTON_MQTT_SEND_ALL_EVENTS) { buttonMQTT(id, event); } #endif if (BUTTON_MODE_TOGGLE == action) { relayToggle(button.relayID); } if (BUTTON_MODE_ON == action) { relayStatus(button.relayID, true); } if (BUTTON_MODE_OFF == action) { relayStatus(button.relayID, false); } if (BUTTON_MODE_AP == action) { if (wifiState() & WIFI_STATE_AP) { wifiStartSTA(); } else { wifiStartAP(); } } if (BUTTON_MODE_RESET == action) { deferredReset(100, CUSTOM_RESET_HARDWARE); } if (BUTTON_MODE_FACTORY == action) { DEBUG_MSG_P(PSTR("\n\nFACTORY RESET\n\n")); resetSettings(); deferredReset(100, CUSTOM_RESET_FACTORY); } #if defined(JUSTWIFI_ENABLE_WPS) if (BUTTON_MODE_WPS == action) { wifiStartWPS(); } #endif // defined(JUSTWIFI_ENABLE_WPS) #if defined(JUSTWIFI_ENABLE_SMARTCONFIG) if (BUTTON_MODE_SMART_CONFIG == action) { wifiStartSmartConfig(); } #endif // defined(JUSTWIFI_ENABLE_SMARTCONFIG) #if LIGHT_PROVIDER != LIGHT_PROVIDER_NONE if (BUTTON_MODE_DIM_UP == action) { lightBrightnessStep(1); lightUpdate(true, true); } if (BUTTON_MODE_DIM_DOWN == action) { lightBrightnessStep(-1); lightUpdate(true, true); } #endif // LIGHT_PROVIDER != LIGHT_PROVIDER_NONE } struct DummyPin : virtual public DebounceEvent::PinBase { DummyPin(unsigned char pin) : DebounceEvent::PinBase(pin) {} void digitalWrite(int8_t val) {} void pinMode(int8_t mode) {} int digitalRead() { return 0; } }; unsigned char buttonAdd(unsigned char pin, unsigned char mode, unsigned long actions, unsigned char relayID) { const unsigned char index = _buttons.size(); button_event_delays_t delays { getSetting({"btnDebDelay", index}, _buttonDebounceDelay(index)), getSetting({"btnDblCDelay", index}, _buttonDoubleClickDelay(index)), getSetting({"btnLngCDelay", index}, _buttonLongClickDelay(index)), getSetting({"btnLngLngCDelay", index}, _buttonLongLongClickDelay(index)) }; _buttons.emplace_back(std::make_shared(GPIO_NONE), BUTTON_PUSHBUTTON, actions, relayID, delays); return _buttons.size() - 1; } void buttonSetup() { // Special hardware cases #if (BUTTON_EVENTS_SOURCE == BUTTON_EVENTS_SOURCE_ITEAD_SONOFF_DUAL) || \ (BUTTON_EVENTS_SOURCE == BUTTON_EVENTS_SOURCE_FOXEL_LIGHTFOX_DUAL) size_t buttons = 0; #if BUTTON1_RELAY != RELAY_NONE ++buttons; #endif #if BUTTON2_RELAY != RELAY_NONE ++buttons; #endif #if BUTTON3_RELAY != RELAY_NONE ++buttons; #endif #if BUTTON4_RELAY != RELAY_NONE ++buttons; #endif _buttons.reserve(buttons); // Ignore default button modes const auto actions = _buttonConstructActions( BUTTON_MODE_NONE, BUTTON_MODE_TOGGLE, BUTTON_MODE_NONE, BUTTON_MODE_NONE, BUTTON_MODE_NONE, BUTTON_MODE_NONE ); for (unsigned char id = 0; id < buttons; ++id) { buttonAdd( GPIO_NONE, BUTTON_PUSHBUTTON, actions, getSetting({"btnRelay", id}, _buttonRelay(id)) ); } // Generic GPIO input handlers #else size_t buttons = 0; // TODO: no real point of doing this when running with dynamic settings // if there is limit like RELAYS_MAX - use that // if not, try to allocate some reasonable amount #if BUTTON1_PIN != GPIO_NONE ++buttons; #endif #if BUTTON2_PIN != GPIO_NONE ++buttons; #endif #if BUTTON3_PIN != GPIO_NONE ++buttons; #endif #if BUTTON4_PIN != GPIO_NONE ++buttons; #endif #if BUTTON5_PIN != GPIO_NONE ++buttons; #endif #if BUTTON6_PIN != GPIO_NONE ++buttons; #endif #if BUTTON7_PIN != GPIO_NONE ++buttons; #endif #if BUTTON8_PIN != GPIO_NONE ++buttons; #endif _buttons.reserve(buttons); for (unsigned char index = 0; index < buttons; ++index) { const auto pin = getSetting({"btnGPIO", index}, _buttonPin(index)); if (!gpioValid(pin)) { break; } button_event_delays_t delays { getSetting({"btnDebDelay", index}, _buttonDebounceDelay(index)), getSetting({"btnDblCDelay", index}, _buttonDoubleClickDelay(index)), getSetting({"btnLngCDelay", index}, _buttonLongClickDelay(index)), getSetting({"btnLngLngCDelay", index}, _buttonLongLongClickDelay(index)) }; // TODO: allow to change DebounceEvent::DigitalPin to something else based on config _buttons.emplace_back( std::make_shared(pin), getSetting({"btnMode", index}, _buttonMode(index)), getSetting({"btnActions", index}, _buttonConstructActions(index)), getSetting({"btnRelay", index}, _buttonRelay(index)), delays ); } #endif DEBUG_MSG_P(PSTR("[BUTTON] Number of buttons: %u\n"), _buttons.size()); // Websocket Callbacks #if WEB_SUPPORT wsRegister() .onVisible(_buttonWebSocketOnVisible) .onKeyCheck(_buttonWebSocketOnKeyCheck); #endif // Register loop espurnaRegisterLoop(buttonLoop); } // Sonoff Dual does not do real GPIO readings and we // depend on the external MCU to send us relay / button events // TODO: move this to a separate 'hardware' setup file? #if BUTTON_EVENTS_SOURCE == BUTTON_EVENTS_SOURCE_ITEAD_SONOFF_DUAL void _buttonLoopSonoffDual() { if (Serial.available() < 4) { return; } unsigned char bytes[4] = {0}; Serial.readBytes(bytes, 4); if ((bytes[0] != 0xA0) || (bytes[1] != 0x04) && (bytes[3] != 0xA1)) { return; } const unsigned char value = bytes[2]; // RELAYs and BUTTONs are synchonized in the SIL F330 // The on-board BUTTON2 should toggle RELAY0 value // Since we are not passing back RELAY2 value // (in the relayStatus method) it will only be present // here if it has actually been pressed if ((value & 4) == 4) { buttonEvent(2, BUTTON_EVENT_CLICK); return; } // Otherwise check if any of the other two BUTTONs // (in the header) has been pressed, but we should // ensure that we only toggle one of them to avoid // the synchronization going mad // This loop is generic for any PSB-04 module for (unsigned int i=0; i 0; // Check if the status for that relay has changed if (relayStatus(i) != status) { buttonEvent(i, BUTTON_EVENT_CLICK); break; } } } #endif // BUTTON_EVENTS_SOURCE_ITEAD_SONOFF_DUAL == 1 // Lightfox uses the same protocol as Dual, but has slightly different actions // TODO: same as above, move from here someplace else #if BUTTON_EVENTS_SOURCE == BUTTON_EVENTS_SOURCE_FOXEL_LIGHTFOX_DUAL void _buttonLoopFoxelLightfox() { if (Serial.available() < 4) { return; } unsigned char bytes[4] = {0}; Serial.readBytes(bytes, 4); if ((bytes[0] != 0xA0) || (bytes[1] != 0x04) && (bytes[3] != 0xA1)) { return; } const unsigned char value = bytes[2]; DEBUG_MSG_P(PSTR("[BUTTON] [LIGHTFOX] Received buttons mask: %u\n"), value); for (unsigned int i=0; i<_buttons.size(); i++) { bool clicked = (value & (1 << i)) > 0; if (clicked) { buttonEvent(i, BUTTON_EVENT_CLICK); } } } #endif // BUTTON_EVENTS_SOURCE_FOXEL_LIGHTFOX_DUAL == 1 void _buttonLoopGeneric() { for (size_t id = 0; id < _buttons.size(); ++id) { auto& button = _buttons[id]; auto event = button.event_handler->loop(); if (event != DebounceEvent::Types::EventNone) { buttonEvent(id, _buttonMapEvent(button, event)); } } } void buttonLoop() { #if BUTTON_EVENTS_SOURCE == BUTTON_EVENTS_SOURCE_GENERIC _buttonLoopGeneric(); #elif BUTTON_EVENTS_SOURCE == BUTTON_EVENTS_SOURCE_ITEAD_SONOFF_DUAL _buttonLoopSonoffDual(); #elif BUTTON_EVENTS_SOURCE == BUTTON_EVENTS_SOURCE_FOXEL_LIGHTFOX_DUAL _buttonLoopFoxelLightfox(); #else #warning "Unknown value for BUTTON_EVENTS_SOURCE" #endif } #endif // BUTTON_SUPPORT