// STL includes #include #include #include // QT includes #include #include #include #include #include #include #include #include // hyperion include #include #include #include #include // Leddevice includes #include #include #include "MultiColorAdjustment.h" #include "LinearColorSmoothing.h" // effect engine includes #include #define CORE_LOGGER Logger::getInstance("Core") Hyperion* Hyperion::_hyperion = nullptr; Hyperion* Hyperion::initInstance(const QJsonObject& qjsonConfig, const QString configFile) // REMOVE jsonConfig variable when the conversion from jsonCPP to QtJSON is finished { if ( Hyperion::_hyperion != nullptr ) throw std::runtime_error("Hyperion::initInstance can be called only one time"); Hyperion::_hyperion = new Hyperion(qjsonConfig, configFile); return Hyperion::_hyperion; } Hyperion* Hyperion::getInstance() { if ( Hyperion::_hyperion == nullptr ) throw std::runtime_error("Hyperion::getInstance used without call of Hyperion::initInstance before"); return Hyperion::_hyperion; } ColorOrder Hyperion::createColorOrder(const QJsonObject &deviceConfig) { return stringToColorOrder(deviceConfig["colorOrder"].toString("rgb")); } ColorAdjustment * Hyperion::createColorAdjustment(const QJsonObject & adjustmentConfig) { const std::string id = adjustmentConfig["id"].toString("default").toStdString(); RgbChannelAdjustment * blackAdjustment = createRgbChannelAdjustment(adjustmentConfig, "black" , 0, 0, 0); RgbChannelAdjustment * whiteAdjustment = createRgbChannelAdjustment(adjustmentConfig, "white" , 255,255,255); RgbChannelAdjustment * redAdjustment = createRgbChannelAdjustment(adjustmentConfig, "red" , 255, 0, 0); RgbChannelAdjustment * greenAdjustment = createRgbChannelAdjustment(adjustmentConfig, "green" , 0,255, 0); RgbChannelAdjustment * blueAdjustment = createRgbChannelAdjustment(adjustmentConfig, "blue" , 0, 0,255); RgbChannelAdjustment * cyanAdjustment = createRgbChannelAdjustment(adjustmentConfig, "cyan" , 0,255,255); RgbChannelAdjustment * magentaAdjustment = createRgbChannelAdjustment(adjustmentConfig, "magenta", 255, 0,255); RgbChannelAdjustment * yellowAdjustment = createRgbChannelAdjustment(adjustmentConfig, "yellow" , 255,255, 0); RgbTransform * rgbTransform = createRgbTransform(adjustmentConfig); ColorAdjustment * adjustment = new ColorAdjustment(); adjustment->_id = id; adjustment->_rgbBlackAdjustment = *blackAdjustment; adjustment->_rgbWhiteAdjustment = *whiteAdjustment; adjustment->_rgbRedAdjustment = *redAdjustment; adjustment->_rgbGreenAdjustment = *greenAdjustment; adjustment->_rgbBlueAdjustment = *blueAdjustment; adjustment->_rgbCyanAdjustment = *cyanAdjustment; adjustment->_rgbMagentaAdjustment = *magentaAdjustment; adjustment->_rgbYellowAdjustment = *yellowAdjustment; adjustment->_rgbTransform = *rgbTransform; // Cleanup the allocated individual adjustments delete blackAdjustment; delete whiteAdjustment; delete redAdjustment; delete greenAdjustment; delete blueAdjustment; delete cyanAdjustment; delete magentaAdjustment; delete yellowAdjustment; delete rgbTransform; return adjustment; } MultiColorAdjustment * Hyperion::createLedColorsAdjustment(const unsigned ledCnt, const QJsonObject & colorConfig) { // Create the result, the transforms are added to this MultiColorAdjustment * adjustment = new MultiColorAdjustment(ledCnt); const QJsonValue adjustmentConfig = colorConfig["channelAdjustment"]; const QRegExp overallExp("([0-9]+(\\-[0-9]+)?)(,[ ]*([0-9]+(\\-[0-9]+)?))*"); const QJsonArray & adjustmentConfigArray = adjustmentConfig.toArray(); for (signed i = 0; i < adjustmentConfigArray.size(); ++i) { const QJsonObject & config = adjustmentConfigArray.at(i).toObject(); ColorAdjustment * colorAdjustment = createColorAdjustment(config); adjustment->addAdjustment(colorAdjustment); const QString ledIndicesStr = config["leds"].toString("").trimmed(); if (ledIndicesStr.compare("*") == 0) { // Special case for indices '*' => all leds adjustment->setAdjustmentForLed(colorAdjustment->_id, 0, ledCnt-1); Info(CORE_LOGGER, "ColorAdjustment '%s' => [0; %d]", colorAdjustment->_id.c_str(), ledCnt-1); continue; } if (!overallExp.exactMatch(ledIndicesStr)) { Error(CORE_LOGGER, "Given led indices %d not correct format: %s", i, ledIndicesStr.toStdString().c_str()); continue; } std::stringstream ss; const QStringList ledIndexList = ledIndicesStr.split(","); for (int i=0; i 0) { ss << ", "; } if (ledIndexList[i].contains("-")) { QStringList ledIndices = ledIndexList[i].split("-"); int startInd = ledIndices[0].toInt(); int endInd = ledIndices[1].toInt(); adjustment->setAdjustmentForLed(colorAdjustment->_id, startInd, endInd); ss << startInd << "-" << endInd; } else { int index = ledIndexList[i].toInt(); adjustment->setAdjustmentForLed(colorAdjustment->_id, index, index); ss << index; } } Info(CORE_LOGGER, "ColorAdjustment '%s' => [%s]", colorAdjustment->_id.c_str(), ss.str().c_str()); } return adjustment; } RgbTransform* Hyperion::createRgbTransform(const QJsonObject& colorConfig) { const double brightnessMin = colorConfig["brightnessMin"].toDouble(0.0); const double brightness = colorConfig["brightness"].toDouble(0.5); const double gammaR = colorConfig["gammaRed"].toDouble(1.0); const double gammaG = colorConfig["gammaGreen"].toDouble(1.0); const double gammaB = colorConfig["gammaBlue"].toDouble(1.0); RgbTransform* transform = new RgbTransform(gammaR, gammaG, gammaB, brightnessMin, brightness); return transform; } RgbChannelAdjustment* Hyperion::createRgbChannelAdjustment(const QJsonObject& colorConfig, const QString channelName, const int defaultR, const int defaultG, const int defaultB) { const QJsonArray& channelConfig = colorConfig[channelName].toArray(); RgbChannelAdjustment* adjustment = new RgbChannelAdjustment( channelConfig[0].toInt(defaultR), channelConfig[1].toInt(defaultG), channelConfig[2].toInt(defaultB), "ChannelAdjust_"+channelName.toUpper()); return adjustment; } LedString Hyperion::createLedString(const QJsonValue& ledsConfig, const ColorOrder deviceOrder) { LedString ledString; const QString deviceOrderStr = colorOrderToString(deviceOrder); const QJsonArray & ledConfigArray = ledsConfig.toArray(); int maxLedId = ledConfigArray.size(); for (signed i = 0; i < ledConfigArray.size(); ++i) { const QJsonObject& index = ledConfigArray[i].toObject(); Led led; led.index = index["index"].toInt(); led.clone = index["clone"].toInt(-1); if ( led.clone < -1 || led.clone >= maxLedId ) { Warning(CORE_LOGGER, "LED %d: clone index of %d is out of range, clone ignored", led.index, led.clone); led.clone = -1; } if ( led.clone < 0 ) { const QJsonObject& hscanConfig = ledConfigArray[i].toObject()["hscan"].toObject(); const QJsonObject& vscanConfig = ledConfigArray[i].toObject()["vscan"].toObject(); led.minX_frac = std::max(0.0, std::min(1.0, hscanConfig["minimum"].toDouble())); led.maxX_frac = std::max(0.0, std::min(1.0, hscanConfig["maximum"].toDouble())); led.minY_frac = std::max(0.0, std::min(1.0, vscanConfig["minimum"].toDouble())); led.maxY_frac = std::max(0.0, std::min(1.0, vscanConfig["maximum"].toDouble())); // Fix if the user swapped min and max if (led.minX_frac > led.maxX_frac) { std::swap(led.minX_frac, led.maxX_frac); } if (led.minY_frac > led.maxY_frac) { std::swap(led.minY_frac, led.maxY_frac); } // Get the order of the rgb channels for this led (default is device order) led.colorOrder = stringToColorOrder(index["colorOrder"].toString(deviceOrderStr)); ledString.leds().push_back(led); } } // Make sure the leds are sorted (on their indices) std::sort(ledString.leds().begin(), ledString.leds().end(), [](const Led& lhs, const Led& rhs){ return lhs.index < rhs.index; }); return ledString; } LedString Hyperion::createLedStringClone(const QJsonValue& ledsConfig, const ColorOrder deviceOrder) { LedString ledString; const QString deviceOrderStr = colorOrderToString(deviceOrder); const QJsonArray & ledConfigArray = ledsConfig.toArray(); int maxLedId = ledConfigArray.size(); for (signed i = 0; i < ledConfigArray.size(); ++i) { const QJsonObject& index = ledConfigArray[i].toObject(); Led led; led.index = index["index"].toInt(); led.clone = index["clone"].toInt(-1); if ( led.clone < -1 || led.clone >= maxLedId ) { Warning(CORE_LOGGER, "LED %d: clone index of %d is out of range, clone ignored", led.index, led.clone); led.clone = -1; } if ( led.clone >= 0 ) { Debug(CORE_LOGGER, "LED %d: clone from led %d", led.index, led.clone); led.minX_frac = 0; led.maxX_frac = 0; led.minY_frac = 0; led.maxY_frac = 0; // Get the order of the rgb channels for this led (default is device order) led.colorOrder = stringToColorOrder(index["colorOrder"].toString(deviceOrderStr)); ledString.leds().push_back(led); } } // Make sure the leds are sorted (on their indices) std::sort(ledString.leds().begin(), ledString.leds().end(), [](const Led& lhs, const Led& rhs){ return lhs.index < rhs.index; }); return ledString; } QSize Hyperion::getLedLayoutGridSize(const QJsonValue& ledsConfig) { std::vector midPointsX; std::vector midPointsY; const QJsonArray & ledConfigArray = ledsConfig.toArray(); for (signed i = 0; i < ledConfigArray.size(); ++i) { const QJsonObject& index = ledConfigArray[i].toObject(); if (index["clone"].toInt(-1) < 0 ) { const QJsonObject& hscanConfig = ledConfigArray[i].toObject()["hscan"].toObject(); const QJsonObject& vscanConfig = ledConfigArray[i].toObject()["vscan"].toObject(); double minX_frac = std::max(0.0, std::min(1.0, hscanConfig["minimum"].toDouble())); double maxX_frac = std::max(0.0, std::min(1.0, hscanConfig["maximum"].toDouble())); double minY_frac = std::max(0.0, std::min(1.0, vscanConfig["minimum"].toDouble())); double maxY_frac = std::max(0.0, std::min(1.0, vscanConfig["maximum"].toDouble())); // Fix if the user swapped min and max if (minX_frac > maxX_frac) { std::swap(minX_frac, maxX_frac); } if (minY_frac > maxY_frac) { std::swap(minY_frac, maxY_frac); } // calculate mid point and make grid calculation midPointsX.push_back( int(1000.0*(minX_frac + maxX_frac) / 2.0) ); midPointsY.push_back( int(1000.0*(minY_frac + maxY_frac) / 2.0) ); } } // remove duplicates std::sort(midPointsX.begin(), midPointsX.end()); midPointsX.erase(std::unique(midPointsX.begin(), midPointsX.end()), midPointsX.end()); std::sort(midPointsY.begin(), midPointsY.end()); midPointsY.erase(std::unique(midPointsY.begin(), midPointsY.end()), midPointsY.end()); QSize gridSize( midPointsX.size(), midPointsY.size() ); Debug(CORE_LOGGER, "led layout grid: %dx%d", gridSize.width(), gridSize.height()); return gridSize; } LinearColorSmoothing * Hyperion::createColorSmoothing(const QJsonObject & smoothingConfig, LedDevice* leddevice) { std::string type = smoothingConfig["type"].toString("linear").toStdString(); std::transform(type.begin(), type.end(), type.begin(), ::tolower); LinearColorSmoothing * device = nullptr; type = "linear"; // TODO currently hardcoded type, delete it if we have more types if (type == "linear") { Info( CORE_LOGGER, "Creating linear smoothing"); device = new LinearColorSmoothing( leddevice, smoothingConfig["updateFrequency"].toDouble(25.0), smoothingConfig["time_ms"].toInt(200), smoothingConfig["updateDelay"].toInt(0), smoothingConfig["continuousOutput"].toBool(true) ); } else { Error(CORE_LOGGER, "Smoothing disabled, because of unknown type '%s'.", type.c_str()); } device->setEnable(smoothingConfig["enable"].toBool(true)); InfoIf(!device->enabled(), CORE_LOGGER,"Smoothing disabled"); assert(device != nullptr); return device; } MessageForwarder * Hyperion::createMessageForwarder(const QJsonObject & forwarderConfig) { MessageForwarder * forwarder = new MessageForwarder(); if ( !forwarderConfig.isEmpty() && forwarderConfig["enable"].toBool(true) ) { if ( !forwarderConfig["json"].isNull() && forwarderConfig["json"].isArray() ) { const QJsonArray & addr = forwarderConfig["json"].toArray(); for (signed i = 0; i < addr.size(); ++i) { Info(CORE_LOGGER, "Json forward to %s", addr.at(i).toString().toStdString().c_str()); forwarder->addJsonSlave(addr[i].toString().toStdString()); } } if ( !forwarderConfig["proto"].isNull() && forwarderConfig["proto"].isArray() ) { const QJsonArray & addr = forwarderConfig["proto"].toArray(); for (signed i = 0; i < addr.size(); ++i) { Info(CORE_LOGGER, "Proto forward to %s", addr.at(i).toString().toStdString().c_str()); forwarder->addProtoSlave(addr[i].toString().toStdString()); } } } return forwarder; } MessageForwarder * Hyperion::getForwarder() { return _messageForwarder; } Hyperion::Hyperion(const QJsonObject &qjsonConfig, const QString configFile) : _ledString(createLedString(qjsonConfig["leds"], createColorOrder(qjsonConfig["device"].toObject()))) , _ledStringClone(createLedStringClone(qjsonConfig["leds"], createColorOrder(qjsonConfig["device"].toObject()))) , _muxer(_ledString.leds().size()) , _raw2ledAdjustment(createLedColorsAdjustment(_ledString.leds().size(), qjsonConfig["color"].toObject())) , _effectEngine(nullptr) , _messageForwarder(createMessageForwarder(qjsonConfig["forwarder"].toObject())) , _qjsonConfig(qjsonConfig) , _configFile(configFile) , _timer() , _log(CORE_LOGGER) , _hwLedCount(_ledString.leds().size()) , _colorAdjustmentV4Lonly(false) , _sourceAutoSelectEnabled(true) , _configHash() , _ledGridSize(getLedLayoutGridSize(qjsonConfig["leds"])) { registerPriority("Off", PriorityMuxer::LOWEST_PRIORITY); if (!_raw2ledAdjustment->verifyAdjustments()) { throw std::runtime_error("Color adjustment incorrectly set"); } // set color correction activity state const QJsonObject& color = qjsonConfig["color"].toObject(); _adjustmentEnabled = color["channelAdjustment_enable"].toBool(true); _colorAdjustmentV4Lonly = color["channelAdjustment_v4l_only"].toBool(false); InfoIf(!_adjustmentEnabled , _log, "Color adjustment disabled" ); InfoIf(_colorAdjustmentV4Lonly , _log, "Color adjustment for v4l inputs only" ); // initialize the image processor factory _ledMAppingType = ImageProcessor::mappingTypeToInt(color["imageToLedMappingType"].toString()); ImageProcessorFactory::getInstance().init(_ledString, qjsonConfig["blackborderdetector"].toObject(),_ledMAppingType ); getComponentRegister().componentStateChanged(hyperion::COMP_FORWARDER, _messageForwarder->forwardingEnabled()); // initialize leddevices _device = LedDeviceFactory::construct(qjsonConfig["device"].toObject(),_hwLedCount); _deviceSmooth = createColorSmoothing(qjsonConfig["smoothing"].toObject(), _device); getComponentRegister().componentStateChanged(hyperion::COMP_SMOOTHING, _deviceSmooth->componentState()); // setup the timer _timer.setSingleShot(true); QObject::connect(&_timer, SIGNAL(timeout()), this, SLOT(update())); // create the effect engine _effectEngine = new EffectEngine(this,qjsonConfig["effects"].toObject()); const QJsonObject& device = qjsonConfig["device"].toObject(); unsigned int hwLedCount = device["ledCount"].toInt(getLedCount()); _hwLedCount = std::max(hwLedCount, getLedCount()); Debug(_log,"configured leds: %d hw leds: %d", getLedCount(), _hwLedCount); WarningIf(hwLedCount < getLedCount(), _log, "more leds configured than available. check 'ledCount' in 'device' section"); WarningIf(!configWriteable(), _log, "Your config is not writeable - you won't be able to use the web ui for configuration."); // initialize hash of current config configModified(); const QJsonObject & generalConfig = qjsonConfig["general"].toObject(); _configVersionId = generalConfig["configVersion"].toInt(-1); // initialize the leds update(); } void Hyperion::freeObjects() { // switch off all leds clearall(); _device->switchOff(); // delete components on exit of hyperion core delete _effectEngine; delete _device; delete _raw2ledAdjustment; delete _messageForwarder; } Hyperion::~Hyperion() { freeObjects(); } unsigned Hyperion::getLedCount() const { return _ledString.leds().size(); } bool Hyperion::configModified() { bool isModified = false; QFile f(_configFile); if (f.open(QFile::ReadOnly)) { QCryptographicHash hash(QCryptographicHash::Sha1); if (hash.addData(&f)) { if (_configHash.size() == 0) { _configHash = hash.result(); } else { isModified = _configHash != hash.result(); } } } f.close(); return isModified; } bool Hyperion::configWriteable() { QFile file(_configFile); QFileInfo fileInfo(file); return fileInfo.isWritable() && fileInfo.isReadable(); } void Hyperion::registerPriority(const std::string name, const int priority) { Info(_log, "Register new input source named '%s' for priority channel '%d'", name.c_str(), priority ); for(auto const &entry : _priorityRegister) { WarningIf( ( entry.first != name && entry.second == priority), _log, "Input source '%s' uses same priority channel (%d) as '%s'.", name.c_str(), priority, entry.first.c_str()); } _priorityRegister.emplace(name,priority); } void Hyperion::unRegisterPriority(const std::string name) { Info(_log, "Unregister input source named '%s' from priority register", name.c_str()); _priorityRegister.erase(name); } void Hyperion::setSourceAutoSelectEnabled(bool enabled) { _sourceAutoSelectEnabled = enabled; if (! _sourceAutoSelectEnabled) { setCurrentSourcePriority(_muxer.getCurrentPriority()); } update(); DebugIf( !_sourceAutoSelectEnabled, _log, "source auto select is disabled"); InfoIf(_sourceAutoSelectEnabled, _log, "set current input source to auto select"); } bool Hyperion::setCurrentSourcePriority(int priority ) { bool priorityValid = _muxer.hasPriority(priority); if (priorityValid) { DebugIf(_sourceAutoSelectEnabled, _log, "source auto select is disabled"); _sourceAutoSelectEnabled = false; _currentSourcePriority = priority; Info(_log, "set current input source to priority channel %d", _currentSourcePriority); } return priorityValid; } void Hyperion::setComponentState(const hyperion::Components component, const bool state) { if (component == hyperion::COMP_SMOOTHING) { _deviceSmooth->setEnable(state); getComponentRegister().componentStateChanged(hyperion::COMP_SMOOTHING, _deviceSmooth->componentState()); } else { emit componentStateChanged(component, state); } } void Hyperion::setColor(int priority, const ColorRgb &color, const int timeout_ms, bool clearEffects) { // create led output std::vector ledColors(_ledString.leds().size(), color); // set colors setColors(priority, ledColors, timeout_ms, clearEffects, hyperion::COMP_COLOR); } void Hyperion::setColors(int priority, const std::vector& ledColors, const int timeout_ms, bool clearEffects, hyperion::Components component) { // clear effects if this call does not come from an effect if (clearEffects) { _effectEngine->channelCleared(priority); } if (timeout_ms > 0) { const uint64_t timeoutTime = QDateTime::currentMSecsSinceEpoch() + timeout_ms; _muxer.setInput(priority, ledColors, timeoutTime, component); } else { _muxer.setInput(priority, ledColors, -1, component); } if (! _sourceAutoSelectEnabled || priority == _muxer.getCurrentPriority()) { update(); } } void Hyperion::setImage(int priority, const Image & image, int duration_ms) { if (priority == getCurrentPriority()) { emit emitImage(priority, image, duration_ms); } } const std::vector & Hyperion::getAdjustmentIds() const { return _raw2ledAdjustment->getAdjustmentIds(); } ColorAdjustment * Hyperion::getAdjustment(const std::string& id) { return _raw2ledAdjustment->getAdjustment(id); } void Hyperion::adjustmentsUpdated() { update(); } void Hyperion::clear(int priority) { if (_muxer.hasPriority(priority)) { _muxer.clearInput(priority); if (!_sourceAutoSelectEnabled && _currentSourcePriority == priority ) { setSourceAutoSelectEnabled(true); } // update leds if necessary if (priority < _muxer.getCurrentPriority()) { update(); } } // send clear signal to the effect engine // (outside the check so the effect gets cleared even when the effect is not sending colors) _effectEngine->channelCleared(priority); } void Hyperion::clearall() { _muxer.clearAll(); setSourceAutoSelectEnabled(true); // update leds update(); // send clearall signal to the effect engine _effectEngine->allChannelsCleared(); } int Hyperion::getCurrentPriority() const { return _sourceAutoSelectEnabled || !_muxer.hasPriority(_currentSourcePriority) ? _muxer.getCurrentPriority() : _currentSourcePriority; } QList Hyperion::getActivePriorities() const { return _muxer.getPriorities(); } const Hyperion::InputInfo &Hyperion::getPriorityInfo(const int priority) const { return _muxer.getInputInfo(priority); } void Hyperion::reloadEffects() { _effectEngine->readEffects(); } const std::list & Hyperion::getEffects() const { return _effectEngine->getEffects(); } const std::list & Hyperion::getActiveEffects() { return _effectEngine->getActiveEffects(); } const std::list & Hyperion::getEffectSchemas() { return _effectEngine->getEffectSchemas(); } int Hyperion::setEffect(const QString &effectName, int priority, int timeout) { return _effectEngine->runEffect(effectName, priority, timeout); } int Hyperion::setEffect(const QString &effectName, const QJsonObject &args, int priority, int timeout, QString pythonScript) { return _effectEngine->runEffect(effectName, args, priority, timeout, pythonScript); } void Hyperion::setLedMappingType(int mappingType) { _ledMAppingType = mappingType; emit imageToLedsMappingChanged(mappingType); } void Hyperion::update() { // Update the muxer, cleaning obsolete priorities _muxer.setCurrentTime(QDateTime::currentMSecsSinceEpoch()); // Obtain the current priority channel int priority = _sourceAutoSelectEnabled || !_muxer.hasPriority(_currentSourcePriority) ? _muxer.getCurrentPriority() : _currentSourcePriority; const PriorityMuxer::InputInfo & priorityInfo = _muxer.getInputInfo(priority); // copy ledcolors to local buffer _ledBuffer.reserve(_hwLedCount); _ledBuffer = priorityInfo.ledColors; if ( _adjustmentEnabled && priority < PriorityMuxer::LOWEST_PRIORITY && (!_colorAdjustmentV4Lonly || priorityInfo.componentId == hyperion::COMP_V4L) ) { _raw2ledAdjustment->applyAdjustment(_ledBuffer); } // init colororder vector, if empty if (_ledStringColorOrder.empty()) { for (Led& led : _ledString.leds()) { _ledStringColorOrder.push_back(led.colorOrder); } for (Led& led : _ledStringClone.leds()) { _ledStringColorOrder.insert(_ledStringColorOrder.begin() + led.index, led.colorOrder); } } // insert cloned leds into buffer for (Led& led : _ledStringClone.leds()) { _ledBuffer.insert(_ledBuffer.begin() + led.index, _ledBuffer.at(led.clone)); } int i = 0; for (ColorRgb& color : _ledBuffer) { //const ColorOrder ledColorOrder = leds.at(i).colorOrder; // correct the color byte order switch (_ledStringColorOrder.at(i)) { case ORDER_RGB: // leave as it is break; case ORDER_BGR: std::swap(color.red, color.blue); break; case ORDER_RBG: std::swap(color.green, color.blue); break; case ORDER_GRB: std::swap(color.red, color.green); break; case ORDER_GBR: std::swap(color.red, color.green); std::swap(color.green, color.blue); break; case ORDER_BRG: std::swap(color.red, color.blue); std::swap(color.green, color.blue); break; } i++; } if ( _hwLedCount > _ledBuffer.size() ) { _ledBuffer.resize(_hwLedCount, ColorRgb::BLACK); } // Write the data to the device if (_deviceSmooth->enabled()) _deviceSmooth->setLedValues(_ledBuffer); else _device->setLedValues(_ledBuffer); // Start the timeout-timer if (priorityInfo.timeoutTime_ms == -1) { _timer.stop(); } else { int timeout_ms = std::max(0, int(priorityInfo.timeoutTime_ms - QDateTime::currentMSecsSinceEpoch())); _timer.start(timeout_ms); } }