/* KWin - the KDE window manager This file is part of the KDE project. SPDX-FileCopyrightText: 2017 Roman Gilg SPDX-License-Identifier: GPL-2.0-or-later */ #include "nightcolormanager.h" #include "clockskewnotifier.h" #include "nightcolordbusinterface.h" #include "nightcolorlogging.h" #include "nightcolorsettings.h" #include "suncalc.h" #include #include #include #include #include #include #include #include #include #include #include namespace KWin { static const int QUICK_ADJUST_DURATION = 2000; static const int TEMPERATURE_STEP = 50; static NightColorManager *s_instance = nullptr; static bool checkLocation(double lat, double lng) { return -90 <= lat && lat <= 90 && -180 <= lng && lng <= 180; } NightColorManager *NightColorManager::self() { return s_instance; } NightColorManager::NightColorManager(QObject *parent) : Plugin(parent) { s_instance = this; m_iface = new NightColorDBusInterface(this); m_skewNotifier = new ClockSkewNotifier(this); // Display a message when Night Color is (un)inhibited. connect(this, &NightColorManager::inhibitedChanged, this, [this] { // TODO: Maybe use different icons? const QString iconName = isInhibited() ? QStringLiteral("preferences-desktop-display-nightcolor-off") : QStringLiteral("preferences-desktop-display-nightcolor-on"); const QString text = isInhibited() ? i18nc("Night Color was disabled", "Night Color Off") : i18nc("Night Color was enabled", "Night Color On"); QDBusMessage message = QDBusMessage::createMethodCall( QStringLiteral("org.kde.plasmashell"), QStringLiteral("/org/kde/osdService"), QStringLiteral("org.kde.osdService"), QStringLiteral("showText")); message.setArguments({ iconName, text }); QDBusConnection::sessionBus().asyncCall(message); }); if (workspace()) { init(); } else { connect(kwinApp(), &Application::workspaceCreated, this, &NightColorManager::init); } } NightColorManager::~NightColorManager() { s_instance = nullptr; } void NightColorManager::init() { NightColorSettings::instance(kwinApp()->config()); // we may always read in the current config readConfig(); if (!isAvailable()) { return; } // legacy shortcut with localized key (to avoid breaking existing config) if (i18n("Toggle Night Color") != QStringLiteral("Toggle Night Color")) { QAction toggleActionLegacy; toggleActionLegacy.setProperty("componentName", QStringLiteral(KWIN_NAME)); toggleActionLegacy.setObjectName(i18n("Toggle Night Color")); KGlobalAccel::self()->removeAllShortcuts(&toggleActionLegacy); } QAction *toggleAction = new QAction(this); toggleAction->setProperty("componentName", QStringLiteral(KWIN_NAME)); toggleAction->setObjectName(QStringLiteral("Toggle Night Color")); toggleAction->setText(i18n("Toggle Night Color")); KGlobalAccel::setGlobalShortcut(toggleAction, QList()); input()->registerShortcut(QKeySequence(), toggleAction, this, &NightColorManager::toggle); connect(Screens::self(), &Screens::countChanged, this, &NightColorManager::hardReset); connect(LogindIntegration::self(), &LogindIntegration::sessionActiveChanged, this, [this](bool active) { if (active) { hardReset(); } else { cancelAllTimers(); } } ); connect(m_skewNotifier, &ClockSkewNotifier::clockSkewed, this, [this]() { // check if we're resuming from suspend - in this case do a hard reset // Note: We're using the time clock to detect a suspend phase instead of connecting to the // provided logind dbus signal, because this signal would be received way too late. QDBusMessage message = QDBusMessage::createMethodCall("org.freedesktop.login1", "/org/freedesktop/login1", "org.freedesktop.DBus.Properties", QStringLiteral("Get")); message.setArguments(QVariantList({"org.freedesktop.login1.Manager", QStringLiteral("PreparingForSleep")})); QDBusReply reply = QDBusConnection::systemBus().call(message); bool comingFromSuspend; if (reply.isValid()) { comingFromSuspend = reply.value().toBool(); } else { qCDebug(KWIN_NIGHTCOLOR) << "Failed to get PreparingForSleep Property of logind session:" << reply.error().message(); // Always do a hard reset in case we have no further information. comingFromSuspend = true; } if (comingFromSuspend) { hardReset(); } else { resetAllTimers(); } }); hardReset(); } void NightColorManager::hardReset() { cancelAllTimers(); updateTransitionTimings(true); updateTargetTemperature(); if (isAvailable() && isEnabled() && !isInhibited()) { setRunning(true); commitGammaRamps(currentTargetTemp()); } resetAllTimers(); } void NightColorManager::reparseConfigAndReset() { cancelAllTimers(); readConfig(); hardReset(); } void NightColorManager::toggle() { m_isGloballyInhibited = !m_isGloballyInhibited; m_isGloballyInhibited ? inhibit() : uninhibit(); } bool NightColorManager::isInhibited() const { return m_inhibitReferenceCount; } void NightColorManager::inhibit() { m_inhibitReferenceCount++; if (m_inhibitReferenceCount == 1) { resetAllTimers(); emit inhibitedChanged(); } } void NightColorManager::uninhibit() { m_inhibitReferenceCount--; if (!m_inhibitReferenceCount) { resetAllTimers(); emit inhibitedChanged(); } } bool NightColorManager::isEnabled() const { return m_active; } bool NightColorManager::isRunning() const { return m_running; } bool NightColorManager::isAvailable() const { return kwinApp()->platform()->supportsGammaControl(); } int NightColorManager::currentTemperature() const { return m_currentTemp; } int NightColorManager::targetTemperature() const { return m_targetTemperature; } NightColorMode NightColorManager::mode() const { return m_mode; } QDateTime NightColorManager::previousTransitionDateTime() const { return m_prev.first; } qint64 NightColorManager::previousTransitionDuration() const { return m_prev.first.msecsTo(m_prev.second); } QDateTime NightColorManager::scheduledTransitionDateTime() const { return m_next.first; } qint64 NightColorManager::scheduledTransitionDuration() const { return m_next.first.msecsTo(m_next.second); } void NightColorManager::readConfig() { NightColorSettings *s = NightColorSettings::self(); s->load(); setEnabled(s->active()); const NightColorMode mode = s->mode(); switch (s->mode()) { case NightColorMode::Automatic: case NightColorMode::Location: case NightColorMode::Timings: case NightColorMode::Constant: setMode(mode); break; default: // Fallback for invalid setting values. setMode(NightColorMode::Automatic); break; } m_nightTargetTemp = qBound(MIN_TEMPERATURE, s->nightTemperature(), NEUTRAL_TEMPERATURE); double lat, lng; auto correctReadin = [&lat, &lng]() { if (!checkLocation(lat, lng)) { // out of domain lat = 0; lng = 0; } }; // automatic lat = s->latitudeAuto(); lng = s->longitudeAuto(); correctReadin(); m_latAuto = lat; m_lngAuto = lng; // fixed location lat = s->latitudeFixed(); lng = s->longitudeFixed(); correctReadin(); m_latFixed = lat; m_lngFixed = lng; // fixed timings QTime mrB = QTime::fromString(s->morningBeginFixed(), "hhmm"); QTime evB = QTime::fromString(s->eveningBeginFixed(), "hhmm"); int diffME = mrB.msecsTo(evB); if (diffME <= 0) { // morning not strictly before evening - use defaults mrB = QTime(6,0); evB = QTime(18,0); diffME = mrB.msecsTo(evB); } int diffMin = qMin(diffME, MSC_DAY - diffME); int trTime = s->transitionTime() * 1000 * 60; if (trTime < 0 || diffMin <= trTime) { // transition time too long - use defaults mrB = QTime(6,0); evB = QTime(18,0); trTime = FALLBACK_SLOW_UPDATE_TIME; } m_morning = mrB; m_evening = evB; m_trTime = qMax(trTime / 1000 / 60, 1); } void NightColorManager::resetAllTimers() { cancelAllTimers(); if (isAvailable()) { setRunning(isEnabled() && !isInhibited()); // we do this also for active being false in order to reset the temperature back to the day value resetQuickAdjustTimer(); } else { setRunning(false); } } void NightColorManager::cancelAllTimers() { delete m_slowUpdateStartTimer; delete m_slowUpdateTimer; delete m_quickAdjustTimer; m_slowUpdateStartTimer = nullptr; m_slowUpdateTimer = nullptr; m_quickAdjustTimer = nullptr; } void NightColorManager::resetQuickAdjustTimer() { updateTransitionTimings(false); updateTargetTemperature(); int tempDiff = qAbs(currentTargetTemp() - m_currentTemp); // allow tolerance of one TEMPERATURE_STEP to compensate if a slow update is coincidental if (tempDiff > TEMPERATURE_STEP) { cancelAllTimers(); m_quickAdjustTimer = new QTimer(this); m_quickAdjustTimer->setSingleShot(false); connect(m_quickAdjustTimer, &QTimer::timeout, this, &NightColorManager::quickAdjust); int interval = QUICK_ADJUST_DURATION / (tempDiff / TEMPERATURE_STEP); if (interval == 0) { interval = 1; } m_quickAdjustTimer->start(interval); } else { resetSlowUpdateStartTimer(); } } void NightColorManager::quickAdjust() { if (!m_quickAdjustTimer) { return; } int nextTemp; const int targetTemp = currentTargetTemp(); if (m_currentTemp < targetTemp) { nextTemp = qMin(m_currentTemp + TEMPERATURE_STEP, targetTemp); } else { nextTemp = qMax(m_currentTemp - TEMPERATURE_STEP, targetTemp); } commitGammaRamps(nextTemp); if (nextTemp == targetTemp) { // stop timer, we reached the target temp delete m_quickAdjustTimer; m_quickAdjustTimer = nullptr; resetSlowUpdateStartTimer(); } } void NightColorManager::resetSlowUpdateStartTimer() { delete m_slowUpdateStartTimer; m_slowUpdateStartTimer = nullptr; if (!m_running || m_quickAdjustTimer) { // only reenable the slow update start timer when quick adjust is not active anymore return; } // There is no need for starting the slow update timer. Screen color temperature // will be constant all the time now. if (m_mode == NightColorMode::Constant) { return; } // set up the next slow update m_slowUpdateStartTimer = new QTimer(this); m_slowUpdateStartTimer->setSingleShot(true); connect(m_slowUpdateStartTimer, &QTimer::timeout, this, &NightColorManager::resetSlowUpdateStartTimer); updateTransitionTimings(false); updateTargetTemperature(); const int diff = QDateTime::currentDateTime().msecsTo(m_next.first); if (diff <= 0) { qCCritical(KWIN_NIGHTCOLOR) << "Error in time calculation. Deactivating Night Color."; return; } m_slowUpdateStartTimer->start(diff); // start the current slow update resetSlowUpdateTimer(); } void NightColorManager::resetSlowUpdateTimer() { delete m_slowUpdateTimer; m_slowUpdateTimer = nullptr; const QDateTime now = QDateTime::currentDateTime(); const bool isDay = daylight(); const int targetTemp = isDay ? m_dayTargetTemp : m_nightTargetTemp; // We've reached the target color temperature or the transition time is zero. if (m_prev.first == m_prev.second || m_currentTemp == targetTemp) { commitGammaRamps(targetTemp); return; } if (m_prev.first <= now && now <= m_prev.second) { int availTime = now.msecsTo(m_prev.second); m_slowUpdateTimer = new QTimer(this); m_slowUpdateTimer->setSingleShot(false); if (isDay) { connect(m_slowUpdateTimer, &QTimer::timeout, this, [this]() {slowUpdate(m_dayTargetTemp);}); } else { connect(m_slowUpdateTimer, &QTimer::timeout, this, [this]() {slowUpdate(m_nightTargetTemp);}); } // calculate interval such as temperature is changed by TEMPERATURE_STEP K per timer timeout int interval = availTime * TEMPERATURE_STEP / qAbs(targetTemp - m_currentTemp); if (interval == 0) { interval = 1; } m_slowUpdateTimer->start(interval); } } void NightColorManager::slowUpdate(int targetTemp) { if (!m_slowUpdateTimer) { return; } int nextTemp; if (m_currentTemp < targetTemp) { nextTemp = qMin(m_currentTemp + TEMPERATURE_STEP, targetTemp); } else { nextTemp = qMax(m_currentTemp - TEMPERATURE_STEP, targetTemp); } commitGammaRamps(nextTemp); if (nextTemp == targetTemp) { // stop timer, we reached the target temp delete m_slowUpdateTimer; m_slowUpdateTimer = nullptr; } } void NightColorManager::updateTargetTemperature() { const int targetTemperature = mode() != NightColorMode::Constant && daylight() ? m_dayTargetTemp : m_nightTargetTemp; if (m_targetTemperature == targetTemperature) { return; } m_targetTemperature = targetTemperature; emit targetTemperatureChanged(); } void NightColorManager::updateTransitionTimings(bool force) { if (m_mode == NightColorMode::Constant) { m_next = DateTimes(); m_prev = DateTimes(); emit previousTransitionTimingsChanged(); emit scheduledTransitionTimingsChanged(); return; } const QDateTime todayNow = QDateTime::currentDateTime(); if (m_mode == NightColorMode::Timings) { const QDateTime morB = QDateTime(todayNow.date(), m_morning); const QDateTime morE = morB.addSecs(m_trTime * 60); const QDateTime eveB = QDateTime(todayNow.date(), m_evening); const QDateTime eveE = eveB.addSecs(m_trTime * 60); if (morB <= todayNow && todayNow < eveB) { m_next = DateTimes(eveB, eveE); m_prev = DateTimes(morB, morE); } else if (todayNow < morB) { m_next = DateTimes(morB, morE); m_prev = DateTimes(eveB.addDays(-1), eveE.addDays(-1)); } else { m_next = DateTimes(morB.addDays(1), morE.addDays(1)); m_prev = DateTimes(eveB, eveE); } emit previousTransitionTimingsChanged(); emit scheduledTransitionTimingsChanged(); return; } double lat, lng; if (m_mode == NightColorMode::Automatic) { lat = m_latAuto; lng = m_lngAuto; } else { lat = m_latFixed; lng = m_lngFixed; } if (!force) { // first try by only switching the timings if (daylight()) { // next is morning m_prev = m_next; m_next = getSunTimings(todayNow.addDays(1), lat, lng, true); } else { // next is evening m_prev = m_next; m_next = getSunTimings(todayNow, lat, lng, false); } } if (force || !checkAutomaticSunTimings()) { // in case this fails, reset them DateTimes morning = getSunTimings(todayNow, lat, lng, true); if (todayNow < morning.first) { m_prev = getSunTimings(todayNow.addDays(-1), lat, lng, false); m_next = morning; } else { DateTimes evening = getSunTimings(todayNow, lat, lng, false); if (todayNow < evening.first) { m_prev = morning; m_next = evening; } else { m_prev = evening; m_next = getSunTimings(todayNow.addDays(1), lat, lng, true); } } } emit previousTransitionTimingsChanged(); emit scheduledTransitionTimingsChanged(); } DateTimes NightColorManager::getSunTimings(const QDateTime &dateTime, double latitude, double longitude, bool morning) const { DateTimes dateTimes = calculateSunTimings(dateTime, latitude, longitude, morning); // At locations near the poles it is possible, that we can't // calculate some or all sun timings (midnight sun). // In this case try to fallback to sensible default values. const bool beginDefined = !dateTimes.first.isNull(); const bool endDefined = !dateTimes.second.isNull(); if (!beginDefined || !endDefined) { if (beginDefined) { dateTimes.second = dateTimes.first.addMSecs( FALLBACK_SLOW_UPDATE_TIME ); } else if (endDefined) { dateTimes.first = dateTimes.second.addMSecs( - FALLBACK_SLOW_UPDATE_TIME ); } else { // Just use default values for morning and evening, but the user // will probably deactivate Night Color anyway if he is living // in a region without clear sun rise and set. const QTime referenceTime = morning ? QTime(6, 0) : QTime(18, 0); dateTimes.first = QDateTime(dateTime.date(), referenceTime); dateTimes.second = dateTimes.first.addMSecs( FALLBACK_SLOW_UPDATE_TIME ); } } return dateTimes; } bool NightColorManager::checkAutomaticSunTimings() const { if (m_prev.first.isValid() && m_prev.second.isValid() && m_next.first.isValid() && m_next.second.isValid()) { const QDateTime todayNow = QDateTime::currentDateTime(); return m_prev.first <= todayNow && todayNow < m_next.first && m_prev.first.msecsTo(m_next.first) < MSC_DAY * 23./24; } return false; } bool NightColorManager::daylight() const { return m_prev.first.date() == m_next.first.date(); } int NightColorManager::currentTargetTemp() const { if (!m_running) { return NEUTRAL_TEMPERATURE; } if (m_mode == NightColorMode::Constant) { return m_nightTargetTemp; } const QDateTime todayNow = QDateTime::currentDateTime(); auto f = [this, todayNow](int target1, int target2) { if (todayNow <= m_prev.second) { double residueQuota = todayNow.msecsTo(m_prev.second) / (double)m_prev.first.msecsTo(m_prev.second); double ret = (int)((1. - residueQuota) * (double)target2 + residueQuota * (double)target1); // remove single digits ret = ((int)(0.1 * ret)) * 10; return (int)ret; } else { return target2; } }; if (daylight()) { return f(m_nightTargetTemp, m_dayTargetTemp); } else { return f(m_dayTargetTemp, m_nightTargetTemp); } } void NightColorManager::commitGammaRamps(int temperature) { const auto outs = kwinApp()->platform()->outputs(); for (auto *o : outs) { int rampsize = o->gammaRampSize(); GammaRamp ramp(rampsize); /* * The gamma calculation below is based on the Redshift app: * https://github.com/jonls/redshift */ uint16_t *red = ramp.red(); uint16_t *green = ramp.green(); uint16_t *blue = ramp.blue(); // linear default state for (int i = 0; i < rampsize; i++) { uint16_t value = (double)i / rampsize * (UINT16_MAX + 1); red[i] = value; green[i] = value; blue[i] = value; } // approximate white point float whitePoint[3]; float alpha = (temperature % 100) / 100.; int bbCIndex = ((temperature - 1000) / 100) * 3; whitePoint[0] = (1. - alpha) * blackbodyColor[bbCIndex] + alpha * blackbodyColor[bbCIndex + 3]; whitePoint[1] = (1. - alpha) * blackbodyColor[bbCIndex + 1] + alpha * blackbodyColor[bbCIndex + 4]; whitePoint[2] = (1. - alpha) * blackbodyColor[bbCIndex + 2] + alpha * blackbodyColor[bbCIndex + 5]; for (int i = 0; i < rampsize; i++) { red[i] = qreal(red[i]) / (UINT16_MAX+1) * whitePoint[0] * (UINT16_MAX+1); green[i] = qreal(green[i]) / (UINT16_MAX+1) * whitePoint[1] * (UINT16_MAX+1); blue[i] = qreal(blue[i]) / (UINT16_MAX+1) * whitePoint[2] * (UINT16_MAX+1); } if (o->setGammaRamp(ramp)) { setCurrentTemperature(temperature); m_failedCommitAttempts = 0; } else { m_failedCommitAttempts++; if (m_failedCommitAttempts < 10) { qCWarning(KWIN_NIGHTCOLOR).nospace() << "Committing Gamma Ramp failed for output " << o->name() << ". Trying " << (10 - m_failedCommitAttempts) << " times more."; } else { // TODO: On multi monitor setups we could try to rollback earlier changes for already committed outputs qCWarning(KWIN_NIGHTCOLOR) << "Gamma Ramp commit failed too often. Deactivating Night Color for now."; m_failedCommitAttempts = 0; // reset so we can try again later (i.e. after suspend phase or config change) setRunning(false); cancelAllTimers(); } } } } QHash NightColorManager::info() const { return QHash { { QStringLiteral("Available"), isAvailable() }, { QStringLiteral("ActiveEnabled"), true}, { QStringLiteral("Active"), m_active}, { QStringLiteral("ModeEnabled"), true}, { QStringLiteral("Mode"), (int)m_mode}, { QStringLiteral("NightTemperatureEnabled"), true}, { QStringLiteral("NightTemperature"), m_nightTargetTemp}, { QStringLiteral("Running"), m_running}, { QStringLiteral("CurrentColorTemperature"), m_currentTemp}, { QStringLiteral("LatitudeAuto"), m_latAuto}, { QStringLiteral("LongitudeAuto"), m_lngAuto}, { QStringLiteral("LocationEnabled"), true}, { QStringLiteral("LatitudeFixed"), m_latFixed}, { QStringLiteral("LongitudeFixed"), m_lngFixed}, { QStringLiteral("TimingsEnabled"), true}, { QStringLiteral("MorningBeginFixed"), m_morning.toString(Qt::ISODate)}, { QStringLiteral("EveningBeginFixed"), m_evening.toString(Qt::ISODate)}, { QStringLiteral("TransitionTime"), m_trTime}, }; } bool NightColorManager::changeConfiguration(QHash data) { bool activeUpdate, modeUpdate, tempUpdate, locUpdate, timeUpdate; activeUpdate = modeUpdate = tempUpdate = locUpdate = timeUpdate = false; bool active = m_active; NightColorMode mode = m_mode; int nightT = m_nightTargetTemp; double lat = m_latFixed; double lng = m_lngFixed; QTime mor = m_morning; QTime eve = m_evening; int trT = m_trTime; QHash::const_iterator iter1, iter2, iter3; iter1 = data.constFind("Active"); if (iter1 != data.constEnd()) { if (!iter1.value().canConvert()) { return false; } bool act = iter1.value().toBool(); activeUpdate = m_active != act; active = act; } iter1 = data.constFind("Mode"); if (iter1 != data.constEnd()) { if (!iter1.value().canConvert()) { return false; } int mo = iter1.value().toInt(); if (mo < 0 || 3 < mo) { return false; } NightColorMode moM; switch (mo) { case 0: moM = NightColorMode::Automatic; break; case 1: moM = NightColorMode::Location; break; case 2: moM = NightColorMode::Timings; break; case 3: moM = NightColorMode::Constant; break; } modeUpdate = m_mode != moM; mode = moM; } iter1 = data.constFind("NightTemperature"); if (iter1 != data.constEnd()) { if (!iter1.value().canConvert()) { return false; } int nT = iter1.value().toInt(); if (nT < MIN_TEMPERATURE || NEUTRAL_TEMPERATURE < nT) { return false; } tempUpdate = m_nightTargetTemp != nT; nightT = nT; } iter1 = data.constFind("LatitudeFixed"); iter2 = data.constFind("LongitudeFixed"); if (iter1 != data.constEnd() && iter2 != data.constEnd()) { if (!iter1.value().canConvert() || !iter2.value().canConvert()) { return false; } double la = iter1.value().toDouble(); double ln = iter2.value().toDouble(); if (!checkLocation(la, ln)) { return false; } locUpdate = m_latFixed != la || m_lngFixed != ln; lat = la; lng = ln; } iter1 = data.constFind("MorningBeginFixed"); iter2 = data.constFind("EveningBeginFixed"); iter3 = data.constFind("TransitionTime"); if (iter1 != data.constEnd() && iter2 != data.constEnd() && iter3 != data.constEnd()) { if (!iter1.value().canConvert() || !iter2.value().canConvert() || !iter3.value().canConvert()) { return false; } QTime mo = QTime::fromString(iter1.value().toString(), Qt::ISODate); QTime ev = QTime::fromString(iter2.value().toString(), Qt::ISODate); if (!mo.isValid() || !ev.isValid()) { return false; } int tT = iter3.value().toInt(); int diffME = mo.msecsTo(ev); if (diffME <= 0 || qMin(diffME, MSC_DAY - diffME) <= tT * 60 * 1000 || tT < 1) { // morning not strictly before evening, transition time too long or transition time out of bounds return false; } timeUpdate = m_morning != mo || m_evening != ev || m_trTime != tT; mor = mo; eve = ev; trT = tT; } if (!(activeUpdate || modeUpdate || tempUpdate || locUpdate || timeUpdate)) { return true; } bool resetNeeded = activeUpdate || modeUpdate || tempUpdate || (locUpdate && mode == NightColorMode::Location) || (timeUpdate && mode == NightColorMode::Timings); if (resetNeeded) { cancelAllTimers(); } NightColorSettings *s = NightColorSettings::self(); if (activeUpdate) { setEnabled(active); s->setActive(active); } if (modeUpdate) { setMode(mode); s->setMode(mode); } if (tempUpdate) { m_nightTargetTemp = nightT; s->setNightTemperature(nightT); } if (locUpdate) { m_latFixed = lat; m_lngFixed = lng; s->setLatitudeFixed(lat); s->setLongitudeFixed(lng); } if (timeUpdate) { m_morning = mor; m_evening = eve; m_trTime = trT; s->setMorningBeginFixed(mor.toString("hhmm")); s->setEveningBeginFixed(eve.toString("hhmm")); s->setTransitionTime(trT); } s->save(); if (resetNeeded) { resetAllTimers(); } emit configChange(info()); return true; } void NightColorManager::autoLocationUpdate(double latitude, double longitude) { qCDebug(KWIN_NIGHTCOLOR, "Received new location (lat: %f, lng: %f)", latitude, longitude); if (!checkLocation(latitude, longitude)) { return; } // we tolerate small deviations with minimal impact on sun timings if (qAbs(m_latAuto - latitude) < 2 && qAbs(m_lngAuto - longitude) < 1) { return; } cancelAllTimers(); m_latAuto = latitude; m_lngAuto = longitude; NightColorSettings *s = NightColorSettings::self(); s->setLatitudeAuto(latitude); s->setLongitudeAuto(longitude); s->save(); resetAllTimers(); emit configChange(info()); } void NightColorManager::setEnabled(bool enabled) { if (m_active == enabled) { return; } m_active = enabled; m_skewNotifier->setActive(enabled); emit enabledChanged(); } void NightColorManager::setRunning(bool running) { if (m_running == running) { return; } m_running = running; emit runningChanged(); } void NightColorManager::setCurrentTemperature(int temperature) { if (m_currentTemp == temperature) { return; } m_currentTemp = temperature; emit currentTemperatureChanged(); } void NightColorManager::setMode(NightColorMode mode) { if (m_mode == mode) { return; } m_mode = mode; emit modeChanged(); } } // namespace KWin