/* * Usermod for detecting people entering/leaving a staircase and switching the * staircase on/off. * * Edit the Animated_Staircase_config.h file to compile this usermod for your * specific configuration. * * See the accompanying README.md file for more info. */ #pragma once #include "wled.h" class Animated_Staircase : public Usermod { private: /* configuration (available in API and stored in flash) */ bool enabled = false; // Enable this usermod unsigned long segment_delay_ms = 150; // Time between switching each segment unsigned long on_time_ms = 30000; // The time for the light to stay on int8_t topPIRorTriggerPin = -1; // disabled int8_t bottomPIRorTriggerPin = -1; // disabled int8_t topEchoPin = -1; // disabled int8_t bottomEchoPin = -1; // disabled bool useUSSensorTop = false; // using PIR or UltraSound sensor? bool useUSSensorBottom = false; // using PIR or UltraSound sensor? unsigned int topMaxDist = 50; // default maximum measured distance in cm, top unsigned int bottomMaxDist = 50; // default maximum measured distance in cm, bottom /* runtime variables */ bool initDone = false; // Time between checking of the sensors const unsigned int scanDelay = 100; // Lights on or off. // Flipping this will start a transition. bool on = false; // Swipe direction for current transition #define SWIPE_UP true #define SWIPE_DOWN false bool swipe = SWIPE_UP; // Indicates which Sensor was seen last (to determine // the direction when swiping off) #define LOWER false #define UPPER true bool lastSensor = LOWER; // Time of the last transition action unsigned long lastTime = 0; // Time of the last sensor check unsigned long lastScanTime = 0; // Last time the lights were switched on or off unsigned long lastSwitchTime = 0; // segment id between onIndex and offIndex are on. // controll the swipe by setting/moving these indices around. // onIndex must be less than or equal to offIndex byte onIndex = 0; byte offIndex = 0; // The maximum number of configured segments. // Dynamically updated based on user configuration. byte maxSegmentId = 1; byte minSegmentId = 0; // These values are used by the API to read the // last sensor state, or trigger a sensor // through the API bool topSensorRead = false; bool topSensorWrite = false; bool bottomSensorRead = false; bool bottomSensorWrite = false; bool topSensorState = false; bool bottomSensorState = false; // strings to reduce flash memory usage (used more than twice) static const char _name[]; static const char _enabled[]; static const char _segmentDelay[]; static const char _onTime[]; static const char _useTopUltrasoundSensor[]; static const char _topPIRorTrigger_pin[]; static const char _topEcho_pin[]; static const char _useBottomUltrasoundSensor[]; static const char _bottomPIRorTrigger_pin[]; static const char _bottomEcho_pin[]; static const char _topEchoCm[]; static const char _bottomEchoCm[]; void publishMqtt(bool bottom, const char* state) { #ifndef WLED_DISABLE_MQTT //Check if MQTT Connected, otherwise it will crash the 8266 if (WLED_MQTT_CONNECTED){ char subuf[64]; sprintf_P(subuf, PSTR("%s/motion/%d"), mqttDeviceTopic, (int)bottom); mqtt->publish(subuf, 0, false, state); } #endif } void updateSegments() { for (int i = minSegmentId; i < maxSegmentId; i++) { Segment &seg = strip.getSegment(i); if (!seg.isActive()) continue; // skip gaps if (i >= onIndex && i < offIndex) { seg.setOption(SEG_OPTION_ON, true); // We may need to copy mode and colors from segment 0 to make sure // changes are propagated even when the config is changed during a wipe // seg.setMode(mainsegment.mode); // seg.setColor(0, mainsegment.colors[0]); } else { seg.setOption(SEG_OPTION_ON, false); } // Always mark segments as "transitional", we are animating the staircase //seg.setOption(SEG_OPTION_TRANSITIONAL, true); // not needed anymore as setOption() does it } strip.trigger(); // force strip refresh stateChanged = true; // inform external devices/UI of change colorUpdated(CALL_MODE_DIRECT_CHANGE); } /* * Detects if an object is within ultrasound range. * signalPin: The pin where the pulse is sent * echoPin: The pin where the echo is received * maxTimeUs: Detection timeout in microseconds. If an echo is * received within this time, an object is detected * and the function will return true. * * The speed of sound is 343 meters per second at 20 degress Celcius. * Since the sound has to travel back and forth, the detection * distance for the sensor in cm is (0.0343 * maxTimeUs) / 2. * * For practical reasons, here are some useful distances: * * Distance = maxtime * 5 cm = 292 uS * 10 cm = 583 uS * 20 cm = 1166 uS * 30 cm = 1749 uS * 50 cm = 2915 uS * 100 cm = 5831 uS */ bool ultrasoundRead(int8_t signalPin, int8_t echoPin, unsigned int maxTimeUs) { if (signalPin<0 || echoPin<0) return false; digitalWrite(signalPin, LOW); delayMicroseconds(2); digitalWrite(signalPin, HIGH); delayMicroseconds(10); digitalWrite(signalPin, LOW); return pulseIn(echoPin, HIGH, maxTimeUs) > 0; } bool checkSensors() { bool sensorChanged = false; if ((millis() - lastScanTime) > scanDelay) { lastScanTime = millis(); bottomSensorRead = bottomSensorWrite || (!useUSSensorBottom ? (bottomPIRorTriggerPin<0 ? false : digitalRead(bottomPIRorTriggerPin)) : ultrasoundRead(bottomPIRorTriggerPin, bottomEchoPin, bottomMaxDist*59) // cm to us ); topSensorRead = topSensorWrite || (!useUSSensorTop ? (topPIRorTriggerPin<0 ? false : digitalRead(topPIRorTriggerPin)) : ultrasoundRead(topPIRorTriggerPin, topEchoPin, topMaxDist*59) // cm to us ); if (bottomSensorRead != bottomSensorState) { bottomSensorState = bottomSensorRead; // change previous state sensorChanged = true; publishMqtt(true, bottomSensorState ? "on" : "off"); DEBUG_PRINTLN(F("Bottom sensor changed.")); } if (topSensorRead != topSensorState) { topSensorState = topSensorRead; // change previous state sensorChanged = true; publishMqtt(false, topSensorState ? "on" : "off"); DEBUG_PRINTLN(F("Top sensor changed.")); } // Values read, reset the flags for next API call topSensorWrite = false; bottomSensorWrite = false; if (topSensorRead != bottomSensorRead) { lastSwitchTime = millis(); if (on) { lastSensor = topSensorRead; } else { // If the bottom sensor triggered, we need to swipe up, ON swipe = bottomSensorRead; DEBUG_PRINT(F("ON -> Swipe ")); DEBUG_PRINTLN(swipe ? F("up.") : F("down.")); if (onIndex == offIndex) { // Position the indices for a correct on-swipe if (swipe == SWIPE_UP) { onIndex = minSegmentId; } else { onIndex = maxSegmentId; } offIndex = onIndex; } on = true; } } } return sensorChanged; } void autoPowerOff() { if ((millis() - lastSwitchTime) > on_time_ms) { // if sensors are still on, do nothing if (bottomSensorState || topSensorState) return; // Swipe OFF in the direction of the last sensor detection swipe = lastSensor; on = false; DEBUG_PRINT(F("OFF -> Swipe ")); DEBUG_PRINTLN(swipe ? F("up.") : F("down.")); } } void updateSwipe() { if ((millis() - lastTime) > segment_delay_ms) { lastTime = millis(); byte oldOn = onIndex; byte oldOff = offIndex; if (on) { // Turn on all segments onIndex = MAX(minSegmentId, onIndex - 1); offIndex = MIN(maxSegmentId, offIndex + 1); } else { if (swipe == SWIPE_UP) { onIndex = MIN(offIndex, onIndex + 1); } else { offIndex = MAX(onIndex, offIndex - 1); } } if (oldOn != onIndex || oldOff != offIndex) updateSegments(); // reduce the number of updates to necessary ones } } // send sesnor values to JSON API void writeSensorsToJson(JsonObject& staircase) { staircase[F("top-sensor")] = topSensorRead; staircase[F("bottom-sensor")] = bottomSensorRead; } // allow overrides from JSON API void readSensorsFromJson(JsonObject& staircase) { bottomSensorWrite = bottomSensorState || (staircase[F("bottom-sensor")].as()); topSensorWrite = topSensorState || (staircase[F("top-sensor")].as()); } void enable(bool enable) { if (enable) { DEBUG_PRINTLN(F("Animated Staircase enabled.")); DEBUG_PRINT(F("Delay between steps: ")); DEBUG_PRINT(segment_delay_ms); DEBUG_PRINT(F(" milliseconds.\nStairs switch off after: ")); DEBUG_PRINT(on_time_ms / 1000); DEBUG_PRINTLN(F(" seconds.")); if (!useUSSensorBottom) pinMode(bottomPIRorTriggerPin, INPUT_PULLUP); else { pinMode(bottomPIRorTriggerPin, OUTPUT); pinMode(bottomEchoPin, INPUT); } if (!useUSSensorTop) pinMode(topPIRorTriggerPin, INPUT_PULLUP); else { pinMode(topPIRorTriggerPin, OUTPUT); pinMode(topEchoPin, INPUT); } onIndex = minSegmentId = strip.getMainSegmentId(); // it may not be the best idea to start with main segment as it may not be the first one offIndex = maxSegmentId = strip.getLastActiveSegmentId() + 1; // shorten the strip transition time to be equal or shorter than segment delay transitionDelayTemp = transitionDelay = segment_delay_ms; strip.setTransition(segment_delay_ms/100); strip.trigger(); } else { // Restore segment options for (int i = 0; i <= strip.getLastActiveSegmentId(); i++) { Segment &seg = strip.getSegment(i); if (!seg.isActive()) continue; // skip vector gaps seg.setOption(SEG_OPTION_ON, true); } strip.trigger(); // force strip update stateChanged = true; // inform external dvices/UI of change colorUpdated(CALL_MODE_DIRECT_CHANGE); DEBUG_PRINTLN(F("Animated Staircase disabled.")); } enabled = enable; } public: void setup() { // standardize invalid pin numbers to -1 if (topPIRorTriggerPin < 0) topPIRorTriggerPin = -1; if (topEchoPin < 0) topEchoPin = -1; if (bottomPIRorTriggerPin < 0) bottomPIRorTriggerPin = -1; if (bottomEchoPin < 0) bottomEchoPin = -1; // allocate pins PinManagerPinType pins[4] = { { topPIRorTriggerPin, useUSSensorTop }, { topEchoPin, false }, { bottomPIRorTriggerPin, useUSSensorBottom }, { bottomEchoPin, false }, }; // NOTE: this *WILL* return TRUE if all the pins are set to -1. // this is *BY DESIGN*. if (!pinManager.allocateMultiplePins(pins, 4, PinOwner::UM_AnimatedStaircase)) { topPIRorTriggerPin = -1; topEchoPin = -1; bottomPIRorTriggerPin = -1; bottomEchoPin = -1; enabled = false; } enable(enabled); initDone = true; } void loop() { if (!enabled || strip.isUpdating()) return; minSegmentId = strip.getMainSegmentId(); // it may not be the best idea to start with main segment as it may not be the first one maxSegmentId = strip.getLastActiveSegmentId() + 1; checkSensors(); if (on) autoPowerOff(); updateSwipe(); } uint16_t getId() { return USERMOD_ID_ANIMATED_STAIRCASE; } #ifndef WLED_DISABLE_MQTT /** * handling of MQTT message * topic only contains stripped topic (part after /wled/MAC) * topic should look like: /swipe with amessage of [up|down] */ bool onMqttMessage(char* topic, char* payload) { if (strlen(topic) == 6 && strncmp_P(topic, PSTR("/swipe"), 6) == 0) { String action = payload; if (action == "up") { bottomSensorWrite = true; return true; } else if (action == "down") { topSensorWrite = true; return true; } else if (action == "on") { enable(true); return true; } else if (action == "off") { enable(false); return true; } } return false; } /** * subscribe to MQTT topic for controlling usermod */ void onMqttConnect(bool sessionPresent) { //(re)subscribe to required topics char subuf[64]; if (mqttDeviceTopic[0] != 0) { strcpy(subuf, mqttDeviceTopic); strcat_P(subuf, PSTR("/swipe")); mqtt->subscribe(subuf, 0); } } #endif void addToJsonState(JsonObject& root) { JsonObject staircase = root[FPSTR(_name)]; if (staircase.isNull()) { staircase = root.createNestedObject(FPSTR(_name)); } writeSensorsToJson(staircase); DEBUG_PRINTLN(F("Staircase sensor state exposed in API.")); } /* * Reads configuration settings from the json API. * See void addToJsonState(JsonObject& root) */ void readFromJsonState(JsonObject& root) { if (!initDone) return; // prevent crash on boot applyPreset() bool en = enabled; JsonObject staircase = root[FPSTR(_name)]; if (!staircase.isNull()) { if (staircase[FPSTR(_enabled)].is()) { en = staircase[FPSTR(_enabled)].as(); } else { String str = staircase[FPSTR(_enabled)]; // checkbox -> off or on en = (bool)(str!="off"); // off is guaranteed to be present } if (en != enabled) enable(en); readSensorsFromJson(staircase); DEBUG_PRINTLN(F("Staircase sensor state read from API.")); } } void appendConfigData() { //oappend(SET_F("dd=addDropdown('staircase','selectfield');")); //oappend(SET_F("addOption(dd,'1st value',0);")); //oappend(SET_F("addOption(dd,'2nd value',1);")); //oappend(SET_F("addInfo('staircase:selectfield',1,'additional info');")); // 0 is field type, 1 is actual field } /* * Writes the configuration to internal flash memory. */ void addToConfig(JsonObject& root) { JsonObject staircase = root[FPSTR(_name)]; if (staircase.isNull()) { staircase = root.createNestedObject(FPSTR(_name)); } staircase[FPSTR(_enabled)] = enabled; staircase[FPSTR(_segmentDelay)] = segment_delay_ms; staircase[FPSTR(_onTime)] = on_time_ms / 1000; staircase[FPSTR(_useTopUltrasoundSensor)] = useUSSensorTop; staircase[FPSTR(_topPIRorTrigger_pin)] = topPIRorTriggerPin; staircase[FPSTR(_topEcho_pin)] = useUSSensorTop ? topEchoPin : -1; staircase[FPSTR(_useBottomUltrasoundSensor)] = useUSSensorBottom; staircase[FPSTR(_bottomPIRorTrigger_pin)] = bottomPIRorTriggerPin; staircase[FPSTR(_bottomEcho_pin)] = useUSSensorBottom ? bottomEchoPin : -1; staircase[FPSTR(_topEchoCm)] = topMaxDist; staircase[FPSTR(_bottomEchoCm)] = bottomMaxDist; DEBUG_PRINTLN(F("Staircase config saved.")); } /* * Reads the configuration to internal flash memory before setup() is called. * * The function should return true if configuration was successfully loaded or false if there was no configuration. */ bool readFromConfig(JsonObject& root) { bool oldUseUSSensorTop = useUSSensorTop; bool oldUseUSSensorBottom = useUSSensorBottom; int8_t oldTopAPin = topPIRorTriggerPin; int8_t oldTopBPin = topEchoPin; int8_t oldBottomAPin = bottomPIRorTriggerPin; int8_t oldBottomBPin = bottomEchoPin; JsonObject top = root[FPSTR(_name)]; if (top.isNull()) { DEBUG_PRINT(FPSTR(_name)); DEBUG_PRINTLN(F(": No config found. (Using defaults.)")); return false; } enabled = top[FPSTR(_enabled)] | enabled; segment_delay_ms = top[FPSTR(_segmentDelay)] | segment_delay_ms; segment_delay_ms = (unsigned long) min((unsigned long)10000,max((unsigned long)10,(unsigned long)segment_delay_ms)); // max delay 10s on_time_ms = top[FPSTR(_onTime)] | on_time_ms/1000; on_time_ms = min(900,max(10,(int)on_time_ms)) * 1000; // min 10s, max 15min useUSSensorTop = top[FPSTR(_useTopUltrasoundSensor)] | useUSSensorTop; topPIRorTriggerPin = top[FPSTR(_topPIRorTrigger_pin)] | topPIRorTriggerPin; topEchoPin = top[FPSTR(_topEcho_pin)] | topEchoPin; useUSSensorBottom = top[FPSTR(_useBottomUltrasoundSensor)] | useUSSensorBottom; bottomPIRorTriggerPin = top[FPSTR(_bottomPIRorTrigger_pin)] | bottomPIRorTriggerPin; bottomEchoPin = top[FPSTR(_bottomEcho_pin)] | bottomEchoPin; topMaxDist = top[FPSTR(_topEchoCm)] | topMaxDist; topMaxDist = min(150,max(30,(int)topMaxDist)); // max distnace ~1.5m (a lag of 9ms may be expected) bottomMaxDist = top[FPSTR(_bottomEchoCm)] | bottomMaxDist; bottomMaxDist = min(150,max(30,(int)bottomMaxDist)); // max distance ~1.5m (a lag of 9ms may be expected) DEBUG_PRINT(FPSTR(_name)); if (!initDone) { // first run: reading from cfg.json DEBUG_PRINTLN(F(" config loaded.")); } else { // changing parameters from settings page DEBUG_PRINTLN(F(" config (re)loaded.")); bool changed = false; if ((oldUseUSSensorTop != useUSSensorTop) || (oldUseUSSensorBottom != useUSSensorBottom) || (oldTopAPin != topPIRorTriggerPin) || (oldTopBPin != topEchoPin) || (oldBottomAPin != bottomPIRorTriggerPin) || (oldBottomBPin != bottomEchoPin)) { changed = true; pinManager.deallocatePin(oldTopAPin, PinOwner::UM_AnimatedStaircase); pinManager.deallocatePin(oldTopBPin, PinOwner::UM_AnimatedStaircase); pinManager.deallocatePin(oldBottomAPin, PinOwner::UM_AnimatedStaircase); pinManager.deallocatePin(oldBottomBPin, PinOwner::UM_AnimatedStaircase); } if (changed) setup(); } // use "return !top["newestParameter"].isNull();" when updating Usermod with new features return true; } /* * Shows the delay between steps and power-off time in the "info" * tab of the web-UI. */ void addToJsonInfo(JsonObject& root) { JsonObject user = root["u"]; if (user.isNull()) { user = root.createNestedObject("u"); } JsonArray infoArr = user.createNestedArray(FPSTR(_name)); // name String uiDomString = F(""); infoArr.add(uiDomString); } }; // strings to reduce flash memory usage (used more than twice) const char Animated_Staircase::_name[] PROGMEM = "staircase"; const char Animated_Staircase::_enabled[] PROGMEM = "enabled"; const char Animated_Staircase::_segmentDelay[] PROGMEM = "segment-delay-ms"; const char Animated_Staircase::_onTime[] PROGMEM = "on-time-s"; const char Animated_Staircase::_useTopUltrasoundSensor[] PROGMEM = "useTopUltrasoundSensor"; const char Animated_Staircase::_topPIRorTrigger_pin[] PROGMEM = "topPIRorTrigger_pin"; const char Animated_Staircase::_topEcho_pin[] PROGMEM = "topEcho_pin"; const char Animated_Staircase::_useBottomUltrasoundSensor[] PROGMEM = "useBottomUltrasoundSensor"; const char Animated_Staircase::_bottomPIRorTrigger_pin[] PROGMEM = "bottomPIRorTrigger_pin"; const char Animated_Staircase::_bottomEcho_pin[] PROGMEM = "bottomEcho_pin"; const char Animated_Staircase::_topEchoCm[] PROGMEM = "top-dist-cm"; const char Animated_Staircase::_bottomEchoCm[] PROGMEM = "bottom-dist-cm";