/* KWin - the KDE window manager This file is part of the KDE project. SPDX-FileCopyrightText: 2015 Martin Gräßlin SPDX-FileCopyrightText: 2019 Vlad Zahorodnii SPDX-License-Identifier: GPL-2.0-or-later */ #include "window.h" #include "effect/globals.h" #include "utils/common.h" #if KWIN_BUILD_ACTIVITIES #include "activities.h" #endif #include "appmenu.h" #include "client_machine.h" #include "compositor.h" #include "core/output.h" #include "decorations/decoratedclient.h" #include "decorations/decorationpalette.h" #include "focuschain.h" #include "input.h" #include "outline.h" #include "placement.h" #include "scene/windowitem.h" #include "scene/workspacescene.h" #include "screenedge.h" #include "shadow.h" #if KWIN_BUILD_TABBOX #include "tabbox/tabbox.h" #endif #include "tiles/tilemanager.h" #include "useractions.h" #include "virtualdesktops.h" #include "wayland/output.h" #include "wayland/plasmawindowmanagement.h" #include "wayland/surface.h" #include "wayland_server.h" #include "workspace.h" #include #include #include #include #include #include #include #include namespace KWin { static inline int sign(int v) { return (v > 0) - (v < 0); } QHash> Window::s_palettes; std::shared_ptr Window::s_defaultPalette; Window::Window() : ready_for_painting(false) , m_internalId(QUuid::createUuid()) , m_clientMachine(new ClientMachine(this)) , m_skipCloseAnimation(false) , m_colorScheme(QStringLiteral("kdeglobals")) { QJSEngine::setObjectOwnership(this, QJSEngine::CppOwnership); connect(this, &Window::bufferGeometryChanged, this, &Window::inputTransformationChanged); connect(this, &Window::interactiveMoveResizeStarted, this, &Window::moveResizedChanged); connect(this, &Window::interactiveMoveResizeFinished, this, &Window::moveResizedChanged); connect(this, &Window::paletteChanged, this, &Window::triggerDecorationRepaint); // If the user manually moved the window, don't restore it after the keyboard closes connect(this, &Window::interactiveMoveResizeFinished, this, [this]() { m_keyboardGeometryRestore = QRectF(); }); connect(this, &Window::maximizedChanged, this, [this]() { m_keyboardGeometryRestore = QRectF(); }); connect(this, &Window::fullScreenChanged, this, [this]() { m_keyboardGeometryRestore = QRectF(); }); // replace on-screen-display on size changes connect(this, &Window::frameGeometryChanged, this, [this](const QRectF &old) { if (isOnScreenDisplay() && !frameGeometry().isEmpty() && old.size() != frameGeometry().size() && isPlaceable()) { workspace()->placement()->place(this, workspace()->clientArea(PlacementArea, this, workspace()->activeOutput())); } }); connect(Workspace::self()->applicationMenu(), &ApplicationMenu::applicationMenuEnabledChanged, this, [this] { Q_EMIT hasApplicationMenuChanged(hasApplicationMenu()); }); connect(&m_offscreenFramecallbackTimer, &QTimer::timeout, this, &Window::maybeSendFrameCallback); } Window::~Window() { Q_ASSERT(!m_tile); } void Window::ref() { ++m_refCount; } void Window::unref() { Q_ASSERT(m_refCount > 0); --m_refCount; if (m_refCount) { return; } if (m_deleted) { workspace()->removeDeleted(this); } delete this; } QDebug operator<<(QDebug debug, const Window *window) { QDebugStateSaver saver(debug); debug.nospace(); if (window) { debug << window->metaObject()->className() << '(' << static_cast(window); if (const SurfaceInterface *surface = window->surface()) { debug << ", surface=" << surface; } if (window->isClient()) { if (!window->isPopupWindow()) { debug << ", caption=" << window->caption(); } if (window->transientFor()) { debug << ", transientFor=" << window->transientFor(); } } if (debug.verbosity() > 2) { debug << ", frameGeometry=" << window->frameGeometry(); debug << ", resourceName=" << window->resourceName(); debug << ", resourceClass=" << window->resourceClass(); } debug << ')'; } else { debug << "Window(0x0)"; } return debug; } QRectF Window::visibleGeometry() const { if (const WindowItem *item = windowItem()) { return item->mapToScene(item->boundingRect()); } return QRectF(); } /** * Returns client machine for this window, * taken either from its window or from the leader window. */ QString Window::wmClientMachine(bool use_localhost) const { if (!m_clientMachine) { // this should never happen return QString(); } if (use_localhost && m_clientMachine->isLocal()) { // special name for the local machine (localhost) return ClientMachine::localhost(); } return m_clientMachine->hostName(); } void Window::setResourceClass(const QString &name, const QString &className) { resource_name = name; resource_class = className; Q_EMIT windowClassChanged(); } qreal Window::opacity() const { return m_opacity; } void Window::setOpacity(qreal opacity) { opacity = std::clamp(opacity, 0.0, 1.0); if (m_opacity == opacity) { return; } const qreal oldOpacity = m_opacity; m_opacity = opacity; Q_EMIT opacityChanged(this, oldOpacity); } bool Window::setupCompositing() { WorkspaceScene *scene = Compositor::self()->scene(); if (!scene) { return false; } m_windowItem = createItem(scene->containerItem()); connect(windowItem(), &WindowItem::positionChanged, this, &Window::visibleGeometryChanged); connect(windowItem(), &WindowItem::boundingRectChanged, this, &Window::visibleGeometryChanged); return true; } void Window::finishCompositing() { m_windowItem.reset(); } void Window::setReadyForPainting() { if (!ready_for_painting) { ready_for_painting = true; Q_EMIT readyForPaintingChanged(); } } Output *Window::output() const { return m_output; } void Window::setOutput(Output *output) { if (m_output != output) { m_output = output; Q_EMIT outputChanged(); } } bool Window::isOnActiveOutput() const { return isOnOutput(workspace()->activeOutput()); } bool Window::isOnOutput(Output *output) const { return output->geometry().intersects(frameGeometry().toRect()); } Shadow *Window::shadow() const { return m_shadow.get(); } void Window::updateShadow() { if (m_shadow) { if (!m_shadow->updateShadow()) { m_shadow.reset(); } Q_EMIT shadowChanged(); } else { m_shadow = Shadow::createShadow(this); if (m_shadow) { Q_EMIT shadowChanged(); } } } EffectWindow *Window::effectWindow() { return m_windowItem ? m_windowItem->effectWindow() : nullptr; } const EffectWindow *Window::effectWindow() const { return m_windowItem ? m_windowItem->effectWindow() : nullptr; } SurfaceItem *Window::surfaceItem() const { if (m_windowItem) { return m_windowItem->surfaceItem(); } return nullptr; } bool Window::wantsShadowToBeRendered() const { return !isFullScreen() && maximizeMode() != MaximizeFull; } bool Window::isClient() const { return false; } bool Window::isUnmanaged() const { return false; } void Window::elevate(bool elevate) { if (m_windowItem) { if (elevate) { m_windowItem->elevate(); } else { m_windowItem->deelevate(); } } } pid_t Window::pid() const { return -1; } bool Window::skipsCloseAnimation() const { return m_skipCloseAnimation; } void Window::setSkipCloseAnimation(bool set) { if (set == m_skipCloseAnimation) { return; } m_skipCloseAnimation = set; Q_EMIT skipCloseAnimationChanged(); } SurfaceInterface *Window::surface() const { return m_surface; } void Window::setSurface(SurfaceInterface *surface) { if (m_surface == surface) { return; } m_surface = surface; Q_EMIT surfaceChanged(); } int Window::stackingOrder() const { return m_stackingOrder; } void Window::setStackingOrder(int order) { if (m_stackingOrder != order) { m_stackingOrder = order; Q_EMIT stackingOrderChanged(); } } QString Window::windowRole() const { return QString(); } QMatrix4x4 Window::inputTransformation() const { QMatrix4x4 m; m.translate(-m_bufferGeometry.x(), -m_bufferGeometry.y()); return m; } bool Window::hitTest(const QPointF &point) const { if (isDecorated()) { if (m_decoration.inputRegion.contains(flooredPoint(mapToFrame(point)))) { return true; } } if (m_surface && m_surface->isMapped()) { return m_surface->inputSurfaceAt(mapToLocal(point)); } return exclusiveContains(m_bufferGeometry, point); } QPointF Window::mapToFrame(const QPointF &point) const { return point - frameGeometry().topLeft(); } QPointF Window::mapToLocal(const QPointF &point) const { return point - bufferGeometry().topLeft(); } QPointF Window::mapFromLocal(const QPointF &point) const { return point + bufferGeometry().topLeft(); } bool Window::isLocalhost() const { if (!m_clientMachine) { return true; } return m_clientMachine->isLocal(); } QMargins Window::frameMargins() const { return QMargins(borderLeft(), borderTop(), borderRight(), borderBottom()); } void Window::updateMouseGrab() { } bool Window::belongToSameApplication(const Window *c1, const Window *c2, SameApplicationChecks checks) { return c1->belongsToSameApplication(c2, checks); } xcb_timestamp_t Window::userTime() const { return XCB_TIME_CURRENT_TIME; } void Window::setSkipSwitcher(bool set) { set = rules()->checkSkipSwitcher(set); if (set == skipSwitcher()) { return; } m_skipSwitcher = set; doSetSkipSwitcher(); updateWindowRules(Rules::SkipSwitcher); Q_EMIT skipSwitcherChanged(); } void Window::setSkipPager(bool b) { b = rules()->checkSkipPager(b); if (b == skipPager()) { return; } m_skipPager = b; doSetSkipPager(); updateWindowRules(Rules::SkipPager); Q_EMIT skipPagerChanged(); } void Window::doSetSkipPager() { } void Window::setSkipTaskbar(bool b) { if (b == skipTaskbar()) { return; } m_skipTaskbar = b; doSetSkipTaskbar(); updateWindowRules(Rules::SkipTaskbar); Q_EMIT skipTaskbarChanged(); } void Window::setOriginalSkipTaskbar(bool b) { m_originalSkipTaskbar = rules()->checkSkipTaskbar(b); setSkipTaskbar(m_originalSkipTaskbar); } void Window::doSetSkipTaskbar() { } void Window::doSetSkipSwitcher() { } void Window::setIcon(const QIcon &icon) { m_icon = icon; Q_EMIT iconChanged(); } void Window::setActive(bool act) { if (isDeleted()) { return; } if (m_active == act) { return; } m_active = act; const int ruledOpacity = m_active ? rules()->checkOpacityActive(qRound(opacity() * 100.0)) : rules()->checkOpacityInactive(qRound(opacity() * 100.0)); setOpacity(ruledOpacity / 100.0); workspace()->setActiveWindow(act ? this : nullptr); if (!m_active) { cancelAutoRaise(); } if (!m_active && shadeMode() == ShadeActivated) { setShade(ShadeNormal); } StackingUpdatesBlocker blocker(workspace()); updateLayer(); // active windows may get different layer auto mainwindows = mainWindows(); for (auto it = mainwindows.constBegin(); it != mainwindows.constEnd(); ++it) { if ((*it)->isFullScreen()) { // fullscreens go high even if their transient is active (*it)->updateLayer(); } } doSetActive(); Q_EMIT activeChanged(); updateMouseGrab(); } void Window::doSetActive() { } bool Window::isDeleted() const { return m_deleted; } void Window::markAsDeleted() { Q_ASSERT(!m_deleted); m_deleted = true; workspace()->addDeleted(this); } Layer Window::layer() const { if (m_layer == UnknownLayer) { const_cast(this)->m_layer = rules()->checkLayer(belongsToLayer()); } return m_layer; } void Window::updateLayer() { if (isDeleted()) { return; } if (layer() == rules()->checkLayer(belongsToLayer())) { return; } StackingUpdatesBlocker blocker(workspace()); m_layer = UnknownLayer; // invalidate, will be updated when doing restacking } Layer Window::belongsToLayer() const { if (isOutline()) { return NormalLayer; } if (isUnmanaged() || isInternal()) { return OverlayLayer; } if (isLockScreen() && !waylandServer()) { return OverlayLayer; } if (isInputMethod()) { return OverlayLayer; } if (isLockScreenOverlay() && waylandServer() && waylandServer()->isScreenLocked()) { return OverlayLayer; } if (isDesktop()) { return DesktopLayer; } if (isSplash()) { // no damn annoying splashscreens return NormalLayer; // getting in the way of everything else } if (isDock() || isAppletPopup()) { return AboveLayer; } if (isPopupWindow()) { return PopupLayer; } if (isOnScreenDisplay()) { return OnScreenDisplayLayer; } if (isNotification()) { return NotificationLayer; } if (isCriticalNotification()) { return CriticalNotificationLayer; } if (keepBelow()) { return BelowLayer; } if (isActiveFullScreen()) { return ActiveLayer; } if (keepAbove()) { return AboveLayer; } return NormalLayer; } bool Window::belongsToDesktop() const { return false; } void Window::setKeepAbove(bool b) { b = rules()->checkKeepAbove(b); if (b && !rules()->checkKeepBelow(false)) { setKeepBelow(false); } if (b == keepAbove()) { return; } m_keepAbove = b; doSetKeepAbove(); updateLayer(); updateWindowRules(Rules::Above); Q_EMIT keepAboveChanged(m_keepAbove); } void Window::doSetKeepAbove() { } void Window::setKeepBelow(bool b) { b = rules()->checkKeepBelow(b); if (b && !rules()->checkKeepAbove(false)) { setKeepAbove(false); } if (b == keepBelow()) { return; } m_keepBelow = b; doSetKeepBelow(); updateLayer(); updateWindowRules(Rules::Below); Q_EMIT keepBelowChanged(m_keepBelow); } void Window::doSetKeepBelow() { } void Window::startAutoRaise() { delete m_autoRaiseTimer; m_autoRaiseTimer = new QTimer(this); connect(m_autoRaiseTimer, &QTimer::timeout, this, &Window::autoRaise); m_autoRaiseTimer->setSingleShot(true); m_autoRaiseTimer->start(options->autoRaiseInterval()); } void Window::cancelAutoRaise() { delete m_autoRaiseTimer; m_autoRaiseTimer = nullptr; } void Window::autoRaise() { workspace()->raiseWindow(this); cancelAutoRaise(); } bool Window::isMostRecentlyRaised() const { // The last window in the unconstrained stacking order is the most recently raised one. return workspace()->topWindowOnDesktop(VirtualDesktopManager::self()->currentDesktop(), nullptr, true, false) == this; } bool Window::wantsTabFocus() const { return (isNormalWindow() || isDialog() || isAppletPopup()) && wantsInput(); } bool Window::isSpecialWindow() const { // TODO return isDesktop() || isDock() || isSplash() || isToolbar() || isNotification() || isOnScreenDisplay() || isCriticalNotification(); } void Window::demandAttention(bool set) { if (isActive()) { set = false; } if (m_demandsAttention == set) { return; } m_demandsAttention = set; doSetDemandsAttention(); workspace()->windowAttentionChanged(this, set); Q_EMIT demandsAttentionChanged(); } void Window::doSetDemandsAttention() { } void Window::setDesktops(QList desktops) { // on x11 we can have only one desktop at a time if (kwinApp()->operationMode() == Application::OperationModeX11 && desktops.size() > 1) { desktops = QList({desktops.last()}); } desktops = rules()->checkDesktops(desktops); if (desktops == m_desktops) { return; } m_desktops = desktops; if (windowManagementInterface()) { if (m_desktops.isEmpty()) { windowManagementInterface()->setOnAllDesktops(true); } else { windowManagementInterface()->setOnAllDesktops(false); auto currentDesktops = windowManagementInterface()->plasmaVirtualDesktops(); for (auto desktop : std::as_const(m_desktops)) { if (!currentDesktops.contains(desktop->id())) { windowManagementInterface()->addPlasmaVirtualDesktop(desktop->id()); } else { currentDesktops.removeOne(desktop->id()); } } for (const auto &desktopId : std::as_const(currentDesktops)) { windowManagementInterface()->removePlasmaVirtualDesktop(desktopId); } } } auto transients_stacking_order = workspace()->ensureStackingOrder(transients()); for (auto it = transients_stacking_order.constBegin(); it != transients_stacking_order.constEnd(); ++it) { (*it)->setDesktops(desktops); } if (isModal()) // if a modal dialog is moved, move the mainwindow with it as otherwise // the (just moved) modal dialog will confusingly return to the mainwindow with // the next desktop change { const auto windows = mainWindows(); for (Window *other : windows) { other->setDesktops(desktops); } } doSetDesktop(); Workspace::self()->focusChain()->update(this, FocusChain::MakeFirst); updateWindowRules(Rules::Desktops); Q_EMIT desktopsChanged(); } void Window::doSetDesktop() { } void Window::enterDesktop(VirtualDesktop *virtualDesktop) { if (m_desktops.contains(virtualDesktop)) { return; } auto desktops = m_desktops; desktops.append(virtualDesktop); setDesktops(desktops); } void Window::leaveDesktop(VirtualDesktop *virtualDesktop) { QList currentDesktops; if (m_desktops.isEmpty()) { currentDesktops = VirtualDesktopManager::self()->desktops(); } else { currentDesktops = m_desktops; } if (!currentDesktops.contains(virtualDesktop)) { return; } auto desktops = currentDesktops; desktops.removeOne(virtualDesktop); setDesktops(desktops); } void Window::setOnAllDesktops(bool b) { if (b == isOnAllDesktops()) { return; } if (b) { setDesktops({}); } else { setDesktops({VirtualDesktopManager::self()->currentDesktop()}); } } QList Window::desktops() const { return m_desktops; } QStringList Window::desktopIds() const { const auto desks = desktops(); QStringList ids; ids.reserve(desks.count()); std::transform(desks.constBegin(), desks.constEnd(), std::back_inserter(ids), [](const VirtualDesktop *vd) { return vd->id(); }); return ids; } bool Window::isOnDesktop(VirtualDesktop *desktop) const { return isOnAllDesktops() || desktops().contains(desktop); } bool Window::isOnCurrentDesktop() const { return isOnDesktop(VirtualDesktopManager::self()->currentDesktop()); } ShadeMode Window::shadeMode() const { return m_shadeMode; } bool Window::isShadeable() const { return false; } void Window::setShade(bool set) { set ? setShade(ShadeNormal) : setShade(ShadeNone); } void Window::setShade(ShadeMode mode) { if (!isShadeable()) { return; } if (mode == ShadeHover && isInteractiveMove()) { return; // causes geometry breaks and is probably nasty } if (isSpecialWindow() || !isDecorated()) { mode = ShadeNone; } mode = rules()->checkShade(mode); if (m_shadeMode == mode) { return; } const bool wasShade = isShade(); const ShadeMode previousShadeMode = shadeMode(); m_shadeMode = mode; if (wasShade == isShade()) { // Decoration may want to update after e.g. hover-shade changes Q_EMIT shadeChanged(); return; // No real change in shaded state } Q_ASSERT(isDecorated()); doSetShade(previousShadeMode); updateWindowRules(Rules::Shade); Q_EMIT shadeChanged(); } void Window::doSetShade(ShadeMode previousShadeMode) { } void Window::shadeHover() { setShade(ShadeHover); cancelShadeHoverTimer(); } void Window::shadeUnhover() { setShade(ShadeNormal); cancelShadeHoverTimer(); } void Window::startShadeHoverTimer() { if (!isShade()) { return; } m_shadeHoverTimer = new QTimer(this); connect(m_shadeHoverTimer, &QTimer::timeout, this, &Window::shadeHover); m_shadeHoverTimer->setSingleShot(true); m_shadeHoverTimer->start(options->shadeHoverInterval()); } void Window::startShadeUnhoverTimer() { if (m_shadeMode == ShadeHover && !isInteractiveMoveResize() && !isInteractiveMoveResizePointerButtonDown()) { m_shadeHoverTimer = new QTimer(this); connect(m_shadeHoverTimer, &QTimer::timeout, this, &Window::shadeUnhover); m_shadeHoverTimer->setSingleShot(true); m_shadeHoverTimer->start(options->shadeHoverInterval()); } } void Window::cancelShadeHoverTimer() { delete m_shadeHoverTimer; m_shadeHoverTimer = nullptr; } void Window::toggleShade() { // If the mode is ShadeHover or ShadeActive, cancel shade too. setShade(shadeMode() == ShadeNone ? ShadeNormal : ShadeNone); } Qt::Edge Window::titlebarPosition() const { // TODO: still needed, remove? return Qt::TopEdge; } bool Window::titlebarPositionUnderMouse() const { if (!isDecorated()) { return false; } const auto sectionUnderMouse = decoration()->sectionUnderMouse(); if (sectionUnderMouse == Qt::TitleBarArea) { return true; } // check other sections based on titlebarPosition switch (titlebarPosition()) { case Qt::TopEdge: return (sectionUnderMouse == Qt::TopLeftSection || sectionUnderMouse == Qt::TopSection || sectionUnderMouse == Qt::TopRightSection); case Qt::LeftEdge: return (sectionUnderMouse == Qt::TopLeftSection || sectionUnderMouse == Qt::LeftSection || sectionUnderMouse == Qt::BottomLeftSection); case Qt::RightEdge: return (sectionUnderMouse == Qt::BottomRightSection || sectionUnderMouse == Qt::RightSection || sectionUnderMouse == Qt::TopRightSection); case Qt::BottomEdge: return (sectionUnderMouse == Qt::BottomLeftSection || sectionUnderMouse == Qt::BottomSection || sectionUnderMouse == Qt::BottomRightSection); default: // nothing return false; } } void Window::setMinimized(bool set) { const bool effectiveSet = rules()->checkMinimize(set); if (m_minimized == effectiveSet) { return; } if (effectiveSet && !isMinimizable()) { return; } m_minimized = effectiveSet; doMinimize(); updateWindowRules(Rules::Minimize); Q_EMIT minimizedChanged(); } void Window::doMinimize() { } QPalette Window::palette() { ensurePalette(); return m_palette->palette(); } const Decoration::DecorationPalette *Window::decorationPalette() { ensurePalette(); return m_palette.get(); } QString Window::preferredColorScheme() const { return rules()->checkDecoColor(QString()); } QString Window::colorScheme() const { return m_colorScheme; } void Window::setColorScheme(const QString &colorScheme) { QString requestedColorScheme = colorScheme; if (requestedColorScheme.isEmpty()) { requestedColorScheme = QStringLiteral("kdeglobals"); } if (m_colorScheme == requestedColorScheme) { return; } m_colorScheme = requestedColorScheme; if (m_palette) { disconnect(m_palette.get(), &Decoration::DecorationPalette::changed, this, &Window::handlePaletteChange); m_palette.reset(); // If there already was a palette, re-create it right away // so the signals for repainting the decoration are emitted. ensurePalette(); } Q_EMIT colorSchemeChanged(); } void Window::updateColorScheme() { setColorScheme(preferredColorScheme()); } void Window::ensurePalette() { if (m_palette) { return; } auto it = s_palettes.find(m_colorScheme); if (it == s_palettes.end() || it->expired()) { m_palette = std::make_shared(m_colorScheme); if (m_palette->isValid()) { s_palettes[m_colorScheme] = m_palette; } else { if (!s_defaultPalette) { s_defaultPalette = std::make_shared(QStringLiteral("kdeglobals")); s_palettes[QStringLiteral("kdeglobals")] = s_defaultPalette; } m_palette = s_defaultPalette; } if (m_colorScheme == QLatin1StringView("kdeglobals")) { s_defaultPalette = m_palette; } } else { m_palette = it->lock(); } connect(m_palette.get(), &Decoration::DecorationPalette::changed, this, &Window::handlePaletteChange); handlePaletteChange(); } void Window::handlePaletteChange() { Q_EMIT paletteChanged(palette()); } QRectF Window::keepInArea(QRectF geometry, QRectF area, bool partial) { if (partial) { // increase the area so that can have only 100 pixels in the area const QRectF geometry = moveResizeGeometry(); area.setLeft(std::min(area.left() - geometry.width() + 100, area.left())); area.setTop(std::min(area.top() - geometry.height() + 100, area.top())); area.setRight(std::max(area.right() + geometry.width() - 100, area.right())); area.setBottom(std::max(area.bottom() + geometry.height() - 100, area.bottom())); } if (!partial) { // resize to fit into area if (area.width() < geometry.width() || area.height() < geometry.height()) { geometry = resizeWithChecks(geometry, geometry.size().boundedTo(area.size())); } } if (geometry.right() > area.right() && geometry.width() <= area.width()) { geometry.moveRight(area.right()); } if (geometry.bottom() > area.bottom() && geometry.height() <= area.height()) { geometry.moveBottom(area.bottom()); } if (geometry.left() < area.left()) { geometry.moveLeft(area.left()); } if (geometry.top() < area.top()) { geometry.moveTop(area.top()); } return geometry; } /** * Returns the maximum client size, not the maximum frame size. */ QSizeF Window::maxSize() const { return rules()->checkMaxSize(QSize(INT_MAX, INT_MAX)); } /** * Returns the minimum client size, not the minimum frame size. */ QSizeF Window::minSize() const { return rules()->checkMinSize(QSize(0, 0)); } void Window::maximize(MaximizeMode mode, const QRectF &restore) { qCWarning(KWIN_CORE, "%s doesn't support setting maximized state", metaObject()->className()); } void Window::setMaximize(bool vertically, bool horizontally, const QRectF &restore) { MaximizeMode mode = MaximizeRestore; if (vertically) { mode = MaximizeMode(mode | MaximizeVertical); } if (horizontally) { mode = MaximizeMode(mode | MaximizeHorizontal); } maximize(mode, restore); } bool Window::startInteractiveMoveResize() { if (isDeleted()) { return false; } Q_ASSERT(!isInteractiveMoveResize()); stopDelayedInteractiveMoveResize(); if (isRequestedFullScreen() && (workspace()->outputs().count() < 2 || !isMovableAcrossScreens())) { return false; } if ((interactiveMoveResizeGravity() == Gravity::None && !isMovableAcrossScreens()) || (interactiveMoveResizeGravity() != Gravity::None && (isShade() || !isResizable()))) { return false; } if (!doStartInteractiveMoveResize()) { return false; } invalidateDecorationDoubleClickTimer(); setInteractiveMoveResize(true); workspace()->setMoveResizeWindow(this); workspace()->raiseWindow(this); m_interactiveMoveResize.initialGeometry = moveResizeGeometry(); m_interactiveMoveResize.startOutput = moveResizeOutput(); m_interactiveMoveResize.initialMaximizeMode = requestedMaximizeMode(); m_interactiveMoveResize.initialQuickTileMode = quickTileMode(); m_interactiveMoveResize.initialGeometryRestore = geometryRestore(); updateElectricGeometryRestore(); checkUnrestrictedInteractiveMoveResize(); Q_EMIT interactiveMoveResizeStarted(); if (workspace()->screenEdges()->isDesktopSwitchingMovingClients()) { workspace()->screenEdges()->reserveDesktopSwitching(true, Qt::Vertical | Qt::Horizontal); } return true; } void Window::finishInteractiveMoveResize(bool cancel) { const bool wasMove = isInteractiveMove(); leaveInteractiveMoveResize(); doFinishInteractiveMoveResize(); if (cancel) { moveResize(initialInteractiveMoveResizeGeometry()); if (m_interactiveMoveResize.initialMaximizeMode != MaximizeMode::MaximizeRestore) { setMaximize(m_interactiveMoveResize.initialMaximizeMode & MaximizeMode::MaximizeVertical, m_interactiveMoveResize.initialMaximizeMode & MaximizeMode::MaximizeHorizontal, m_interactiveMoveResize.initialGeometryRestore); } else if (m_interactiveMoveResize.initialQuickTileMode) { setQuickTileMode(m_interactiveMoveResize.initialQuickTileMode, m_interactiveMoveResize.initialGeometry.center()); setGeometryRestore(m_interactiveMoveResize.initialGeometryRestore); } } else if (moveResizeOutput() != interactiveMoveResizeStartOutput()) { sendToOutput(moveResizeOutput()); // checks rule validity const QRectF oldScreenArea = workspace()->clientArea(MaximizeArea, this, interactiveMoveResizeStartOutput()); const QRectF screenArea = workspace()->clientArea(MaximizeArea, this, moveResizeOutput()); m_electricGeometryRestore = moveToArea(m_electricGeometryRestore, oldScreenArea, screenArea); if (isRequestedFullScreen() || requestedMaximizeMode() != MaximizeRestore) { checkWorkspacePosition(); } } if (isElectricBorderMaximizing()) { if (auto quickTileMode = std::get_if(&m_electricMode.value())) { setQuickTileMode(*quickTileMode, m_interactiveMoveResize.anchor); } else if (auto maximizeMode = std::get_if(&m_electricMode.value())) { maximize(*maximizeMode, m_electricGeometryRestore); } setElectricBorderMaximizing(false); } else if (wasMove && (m_interactiveMoveResize.modifiers & Qt::ShiftModifier)) { setQuickTileMode(QuickTileFlag::Custom, m_interactiveMoveResize.anchor); } setElectricBorderMode(std::nullopt); workspace()->outline()->hide(); m_interactiveMoveResize.counter++; Q_EMIT interactiveMoveResizeFinished(); } // This function checks if it actually makes sense to perform a restricted move/resize. // If e.g. the titlebar is already outside of the workarea, there's no point in performing // a restricted move resize, because then e.g. resize would also move the window (#74555). // NOTE: Most of it is duplicated from handleMoveResize(). void Window::checkUnrestrictedInteractiveMoveResize() { if (isUnrestrictedInteractiveMoveResize()) { return; } const QRectF &moveResizeGeom = moveResizeGeometry(); QRectF desktopArea = workspace()->clientArea(WorkArea, this, moveResizeGeom.center()); int left_marge, right_marge, top_marge, bottom_marge, titlebar_marge; // restricted move/resize - keep at least part of the titlebar always visible // how much must remain visible when moved away in that direction left_marge = std::min(100. + borderRight(), moveResizeGeom.width()); right_marge = std::min(100. + borderLeft(), moveResizeGeom.width()); // width/height change with opaque resizing, use the initial ones titlebar_marge = initialInteractiveMoveResizeGeometry().height(); top_marge = borderBottom(); bottom_marge = borderTop(); if (isInteractiveResize()) { if (moveResizeGeom.bottom() < desktopArea.top() + top_marge) { setUnrestrictedInteractiveMoveResize(true); } if (moveResizeGeom.top() > desktopArea.bottom() - bottom_marge) { setUnrestrictedInteractiveMoveResize(true); } if (moveResizeGeom.right() < desktopArea.left() + left_marge) { setUnrestrictedInteractiveMoveResize(true); } if (moveResizeGeom.left() > desktopArea.right() - right_marge) { setUnrestrictedInteractiveMoveResize(true); } if (!isUnrestrictedInteractiveMoveResize() && moveResizeGeom.top() < desktopArea.top()) { // titlebar mustn't go out setUnrestrictedInteractiveMoveResize(true); } } if (isInteractiveMove()) { if (moveResizeGeom.bottom() < desktopArea.top() + titlebar_marge) { setUnrestrictedInteractiveMoveResize(true); } // no need to check top_marge, titlebar_marge already handles it if (moveResizeGeom.top() > desktopArea.bottom() - bottom_marge) { // titlebar mustn't go out setUnrestrictedInteractiveMoveResize(true); } if (moveResizeGeom.right() < desktopArea.left() + left_marge) { setUnrestrictedInteractiveMoveResize(true); } if (moveResizeGeom.left() > desktopArea.right() - right_marge) { setUnrestrictedInteractiveMoveResize(true); } } } // When the user pressed mouse on the titlebar, don't activate move immediately, // since it may be just a click. Activate instead after a delay. Move used to be // activated only after moving by several pixels, but that looks bad. void Window::startDelayedInteractiveMoveResize() { if (isDeleted()) { return; } Q_ASSERT(!m_interactiveMoveResize.delayedTimer); m_interactiveMoveResize.delayedTimer = new QTimer(this); m_interactiveMoveResize.delayedTimer->setSingleShot(true); connect(m_interactiveMoveResize.delayedTimer, &QTimer::timeout, this, [this]() { Q_ASSERT(isInteractiveMoveResizePointerButtonDown()); if (!startInteractiveMoveResize()) { setInteractiveMoveResizePointerButtonDown(false); } updateCursor(); stopDelayedInteractiveMoveResize(); }); m_interactiveMoveResize.delayedTimer->start(QApplication::startDragTime()); } void Window::stopDelayedInteractiveMoveResize() { delete m_interactiveMoveResize.delayedTimer; m_interactiveMoveResize.delayedTimer = nullptr; } void Window::updateInteractiveMoveResize(const QPointF &global, Qt::KeyboardModifiers modifiers) { setInteractiveMoveResizeAnchor(global); setInteractiveMoveResizeModifiers(modifiers); // ShadeHover or ShadeActive, ShadeNormal was already avoided above const Gravity gravity = interactiveMoveResizeGravity(); if (gravity != Gravity::None && shadeMode() != ShadeNone) { setShade(ShadeNone); } const QRectF currentMoveResizeGeom = moveResizeGeometry(); QRectF nextMoveResizeGeom = currentMoveResizeGeom; if (isInteractiveResize()) { if (isWaitingForInteractiveResizeSync()) { return; // we're still waiting for the client or the timeout } if (m_tile && m_tile->supportsResizeGravity(gravity)) { m_tile->resizeFromGravity(gravity, global.x(), global.y()); return; } nextMoveResizeGeom = nextInteractiveResizeGeometry(global); if (nextMoveResizeGeom != currentMoveResizeGeom) { if (m_tile && !m_tile->supportsResizeGravity(gravity)) { setGeometryRestore(nextMoveResizeGeom); setQuickTileModeAtCurrentPosition(QuickTileFlag::None); return; } if (requestedMaximizeMode() != MaximizeRestore) { switch (interactiveMoveResizeGravity()) { case Gravity::Left: case Gravity::Right: // Quit maximized horizontally state if the window is resized horizontally. if (requestedMaximizeMode() & MaximizeHorizontal) { QRectF originalGeometry = geometryRestore(); originalGeometry.setX(nextMoveResizeGeom.x()); originalGeometry.setWidth(nextMoveResizeGeom.width()); maximize(requestedMaximizeMode() ^ MaximizeHorizontal, originalGeometry); return; } break; case Gravity::Top: case Gravity::Bottom: // Quit maximized vertically state if the window is resized vertically. if (requestedMaximizeMode() & MaximizeVertical) { QRectF originalGeometry = geometryRestore(); originalGeometry.setY(nextMoveResizeGeom.y()); originalGeometry.setHeight(nextMoveResizeGeom.height()); maximize(requestedMaximizeMode() ^ MaximizeVertical, originalGeometry); return; } break; case Gravity::TopLeft: case Gravity::BottomLeft: case Gravity::TopRight: case Gravity::BottomRight: // Quit the maximized mode if the window is resized by dragging one of its corners. maximize(MaximizeRestore, nextMoveResizeGeom); return; default: Q_UNREACHABLE(); } } doInteractiveResizeSync(nextMoveResizeGeom); Q_EMIT interactiveMoveResizeStepped(nextMoveResizeGeom); } } else if (isInteractiveMove()) { if (isRequestedFullScreen()) { nextMoveResizeGeom = workspace()->clientArea(FullScreenArea, this, global); } else { nextMoveResizeGeom = nextInteractiveMoveGeometry(global); } if (nextMoveResizeGeom != currentMoveResizeGeom) { if (!isRequestedFullScreen()) { if (maximizeMode() != MaximizeRestore) { if (maximizeMode() & MaximizeHorizontal) { if (nextMoveResizeGeom.x() != currentMoveResizeGeom.x() || nextMoveResizeGeom.width() != currentMoveResizeGeom.width()) { maximize(MaximizeRestore); return; } } if (maximizeMode() & MaximizeVertical) { if (nextMoveResizeGeom.y() != currentMoveResizeGeom.y() || nextMoveResizeGeom.height() != currentMoveResizeGeom.height()) { maximize(MaximizeRestore); return; } } } else if (quickTileMode() != QuickTileMode(QuickTileFlag::None)) { setQuickTileModeAtCurrentPosition(QuickTileFlag::None); return; } } move(nextMoveResizeGeom.topLeft()); Q_EMIT interactiveMoveResizeStepped(nextMoveResizeGeom); } if (!isRequestedFullScreen()) { if (modifiers & Qt::ShiftModifier) { resetQuickTilingMaximizationZones(); const auto &r = quickTileGeometry(QuickTileFlag::Custom, global); if (r.isEmpty()) { workspace()->outline()->hide(); } else { if (!workspace()->outline()->isActive() || workspace()->outline()->geometry() != r.toRect()) { workspace()->outline()->show(r.toRect(), moveResizeGeometry().toRect()); } } } else { if (quickTileMode() == QuickTileMode(QuickTileFlag::None) && isResizable()) { checkQuickTilingMaximizationZones(global.x(), global.y()); } if (!m_electricMaximizing) { // Only if we are in an electric maximizing gesture we should keep the outline, // otherwise we must make sure it's hidden workspace()->outline()->hide(); } } } } } QRectF Window::titleBarRect(const QRectF &rect, bool &transposed) const { QRectF titleRect = rect; titleRect.moveTopLeft(QPointF(0, 0)); switch (titlebarPosition()) { default: case Qt::TopEdge: titleRect.setHeight(borderTop()); break; case Qt::LeftEdge: titleRect.setWidth(borderLeft()); transposed = true; break; case Qt::BottomEdge: titleRect.setTop(titleRect.bottom() - borderBottom()); break; case Qt::RightEdge: titleRect.setLeft(titleRect.right() - borderRight()); transposed = true; break; } return titleRect; } QRectF Window::nextInteractiveResizeGeometry(const QPointF &global) const { const QRectF currentMoveResizeGeom = moveResizeGeometry(); QRectF nextMoveResizeGeom = moveResizeGeometry(); const Gravity gravity = interactiveMoveResizeGravity(); if (gravity == Gravity::None || isShade() || !isResizable()) { return nextMoveResizeGeom; } // these two points limit the geometry rectangle, i.e. if bottomleft resizing is done, // the bottomleft corner should be at is at (topleft.x(), bottomright().y()) QRectF orig = initialInteractiveMoveResizeGeometry(); QPointF topleft = global - QPointF(interactiveMoveOffset().x() * orig.width(), interactiveMoveOffset().y() * orig.height()); QPointF bottomright = global + QPointF((1.0 - interactiveMoveOffset().x()) * orig.width(), (1.0 - interactiveMoveOffset().y()) * orig.height()); // TODO move whole group when moving its leader or when the leader is not mapped? SizeMode sizeMode = SizeModeAny; auto calculateMoveResizeGeom = [&topleft, &bottomright, &orig, &nextMoveResizeGeom, &sizeMode, &gravity]() { switch (gravity) { case Gravity::TopLeft: nextMoveResizeGeom = QRectF(topleft, orig.bottomRight()); break; case Gravity::BottomRight: nextMoveResizeGeom = QRectF(orig.topLeft(), bottomright); break; case Gravity::BottomLeft: nextMoveResizeGeom = QRectF(QPointF(topleft.x(), orig.y()), QPointF(orig.right(), bottomright.y())); break; case Gravity::TopRight: nextMoveResizeGeom = QRectF(QPointF(orig.x(), topleft.y()), QPointF(bottomright.x(), orig.bottom())); break; case Gravity::Top: nextMoveResizeGeom = QRectF(QPointF(orig.left(), topleft.y()), orig.bottomRight()); sizeMode = SizeModeFixedH; // try not to affect height break; case Gravity::Bottom: nextMoveResizeGeom = QRectF(orig.topLeft(), QPointF(orig.right(), bottomright.y())); sizeMode = SizeModeFixedH; break; case Gravity::Left: nextMoveResizeGeom = QRectF(QPointF(topleft.x(), orig.top()), orig.bottomRight()); sizeMode = SizeModeFixedW; break; case Gravity::Right: nextMoveResizeGeom = QRectF(orig.topLeft(), QPointF(bottomright.x(), orig.bottom())); sizeMode = SizeModeFixedW; break; case Gravity::None: Q_UNREACHABLE(); break; } }; // first resize (without checking constrains), then snap, then check bounds, then check constrains calculateMoveResizeGeom(); // adjust new size to snap to other windows/borders nextMoveResizeGeom = workspace()->adjustWindowSize(this, nextMoveResizeGeom, gravity); if (!isUnrestrictedInteractiveMoveResize()) { // Make sure the titlebar isn't behind a restricted area. We don't need to restrict // the other directions. If not visible enough, move the window to the closest valid // point. We bruteforce this by slowly moving the window back to its previous position const StrutRects strut = workspace()->restrictedMoveArea(VirtualDesktopManager::self()->currentDesktop()); QRegion availableArea(workspace()->clientArea(FullArea, this, workspace()->activeOutput()).toRect()); for (const QRect &rect : strut) { availableArea -= rect; } bool transposed = false; QRectF bTitleRect = titleBarRect(nextMoveResizeGeom, transposed); int lastVisiblePixels = -1; QRectF lastTry = nextMoveResizeGeom; bool titleFailed = false; for (;;) { const QRect titleRect = bTitleRect.translated(nextMoveResizeGeom.topLeft()).toRect(); const int requiredPixels = std::min(100 * (transposed ? titleRect.width() : titleRect.height()), titleRect.width() * titleRect.height()); int visiblePixels = 0; int realVisiblePixels = 0; for (const QRect &rect : availableArea) { const QRect r = rect & titleRect; realVisiblePixels += r.width() * r.height(); if ((transposed && r.width() == titleRect.width()) || // Only the full size regions... (!transposed && r.height() == titleRect.height())) { // ...prevents long slim areas visiblePixels += r.width() * r.height(); } } if (visiblePixels >= requiredPixels) { break; // We have reached a valid position } if (realVisiblePixels <= lastVisiblePixels) { if (titleFailed && realVisiblePixels < lastVisiblePixels) { break; // we won't become better } else { if (!titleFailed) { nextMoveResizeGeom = lastTry; } titleFailed = true; } } lastVisiblePixels = realVisiblePixels; QRectF currentTry = nextMoveResizeGeom; lastTry = currentTry; // Not visible enough, move the window to the closest valid point. We bruteforce // this by slowly moving the window back to its previous position. // The geometry changes at up to two edges, the one with the title (if) shall take // precedence. The opposing edge has no impact on visiblePixels and only one of // the adjacent can alter at a time, ie. it's enough to ignore adjacent edges // if the title edge altered bool leftChanged = !qFuzzyCompare(currentMoveResizeGeom.left(), currentTry.left()); bool rightChanged = !qFuzzyCompare(currentMoveResizeGeom.right(), currentTry.right()); bool topChanged = !qFuzzyCompare(currentMoveResizeGeom.top(), currentTry.top()); bool btmChanged = !qFuzzyCompare(currentMoveResizeGeom.bottom(), currentTry.bottom()); auto fixChangedState = [titleFailed](bool &major, bool &counter, bool &ad1, bool &ad2) { counter = false; if (titleFailed) { major = false; } if (major) { ad1 = ad2 = false; } }; switch (titlebarPosition()) { default: case Qt::TopEdge: fixChangedState(topChanged, btmChanged, leftChanged, rightChanged); break; case Qt::LeftEdge: fixChangedState(leftChanged, rightChanged, topChanged, btmChanged); break; case Qt::BottomEdge: fixChangedState(btmChanged, topChanged, leftChanged, rightChanged); break; case Qt::RightEdge: fixChangedState(rightChanged, leftChanged, topChanged, btmChanged); break; } if (topChanged) { currentTry.setTop(currentTry.y() + qBound(-1.0, currentMoveResizeGeom.y() - currentTry.y(), 1.0)); } else if (leftChanged) { currentTry.setLeft(currentTry.x() + qBound(-1.0, currentMoveResizeGeom.x() - currentTry.x(), 1.0)); } else if (btmChanged) { currentTry.setBottom(currentTry.bottom() + qBound(-1.0, currentMoveResizeGeom.bottom() - currentTry.bottom(), 1.0)); } else if (rightChanged) { currentTry.setRight(currentTry.right() + qBound(-1.0, currentMoveResizeGeom.right() - currentTry.right(), 1.0)); } else { break; // no position changed - that's certainly not good } nextMoveResizeGeom = currentTry; } } // Always obey size hints, even when in "unrestricted" mode QSizeF size = constrainFrameSize(nextMoveResizeGeom.size(), sizeMode); // the new topleft and bottomright corners (after checking size constrains), if they'll be needed topleft = QPointF(nextMoveResizeGeom.right() - size.width(), nextMoveResizeGeom.bottom() - size.height()); bottomright = QPointF(nextMoveResizeGeom.left() + size.width(), nextMoveResizeGeom.top() + size.height()); orig = nextMoveResizeGeom; // if aspect ratios are specified, both dimensions may change. // Therefore grow to the right/bottom if needed. // TODO it should probably obey gravity rather than always using right/bottom ? if (sizeMode == SizeModeFixedH) { orig.setRight(bottomright.x()); } else if (sizeMode == SizeModeFixedW) { orig.setBottom(bottomright.y()); } calculateMoveResizeGeom(); return nextMoveResizeGeom; } QRectF Window::nextInteractiveMoveGeometry(const QPointF &global) const { const QRectF currentMoveResizeGeom = frameGeometry(); if (!isMovable()) { return currentMoveResizeGeom; } QRectF nextMoveResizeGeom = currentMoveResizeGeom; nextMoveResizeGeom.moveTopLeft(QPointF(global.x() - interactiveMoveOffset().x() * currentMoveResizeGeom.width(), global.y() - interactiveMoveOffset().y() * currentMoveResizeGeom.height())); nextMoveResizeGeom.moveTopLeft(workspace()->adjustWindowPosition(this, nextMoveResizeGeom.topLeft(), isUnrestrictedInteractiveMoveResize())); if (!isUnrestrictedInteractiveMoveResize()) { const StrutRects strut = workspace()->restrictedMoveArea(VirtualDesktopManager::self()->currentDesktop()); QRegion availableArea(workspace()->clientArea(FullArea, this, workspace()->activeOutput()).toRect()); for (const QRect &rect : strut) { availableArea -= rect; // Strut areas } bool transposed = false; QRectF bTitleRect = titleBarRect(nextMoveResizeGeom, transposed); for (;;) { QRectF currentTry = nextMoveResizeGeom; const QRect titleRect = bTitleRect.translated(currentTry.topLeft()).toRect(); const int requiredPixels = std::min(100 * (transposed ? titleRect.width() : titleRect.height()), titleRect.width() * titleRect.height()); int visiblePixels = 0; for (const QRect &rect : availableArea) { const QRect r = rect & titleRect; if ((transposed && r.width() == titleRect.width()) || // Only the full size regions... (!transposed && r.height() == titleRect.height())) { // ...prevents long slim areas visiblePixels += r.width() * r.height(); } } if (visiblePixels >= requiredPixels) { break; // We have reached a valid position } // (esp.) if there're more screens with different struts (panels) it the titlebar // will be movable outside the movearea (covering one of the panels) until it // crosses the panel "too much" (not enough visiblePixels) and then stucks because // it's usually only pushed by 1px to either direction // so we first check whether we intersect suc strut and move the window below it // immediately (it's still possible to hit the visiblePixels >= titlebarArea break // by moving the window slightly downwards, but it won't stuck) // see bug #274466 // and bug #301805 for why we can't just match the titlearea against the screen if (workspace()->outputs().count() > 1) { // optimization // TODO: could be useful on partial screen struts (half-width panels etc.) int newTitleTop = -1; for (const QRect ®ion : strut) { QRectF r = region; if (r.top() == 0 && r.width() > r.height() && // "top panel" r.intersects(currentTry) && currentTry.top() < r.bottom()) { newTitleTop = r.bottom(); break; } } if (newTitleTop > -1) { currentTry.moveTop(newTitleTop); // invalid position, possibly on screen change nextMoveResizeGeom = currentTry; break; } } int dx = sign(currentMoveResizeGeom.x() - currentTry.x()), dy = sign(currentMoveResizeGeom.y() - currentTry.y()); if (visiblePixels && dx) { // means there's no full width cap -> favor horizontally dy = 0; } else if (dy) { dx = 0; } // Move it back currentTry.translate(dx, dy); nextMoveResizeGeom = currentTry; // sinces nextMoveResizeGeom is fractional, at best it is within 1 unit of currentMoveResizeGeom if (std::abs(currentMoveResizeGeom.left() - nextMoveResizeGeom.left()) < 1.0 && std::abs(currentMoveResizeGeom.right() - nextMoveResizeGeom.right()) < 1.0 && std::abs(currentMoveResizeGeom.top() - nextMoveResizeGeom.top()) < 1.0 && std::abs(currentMoveResizeGeom.bottom() - nextMoveResizeGeom.bottom()) < 1.0) { break; // Prevent lockup } } } return nextMoveResizeGeom; } StrutRect Window::strutRect(StrutArea area) const { return StrutRect(); } StrutRects Window::strutRects() const { StrutRects region; if (const StrutRect strut = strutRect(StrutAreaTop); strut.isValid()) { region += strut; } if (const StrutRect strut = strutRect(StrutAreaRight); strut.isValid()) { region += strut; } if (const StrutRect strut = strutRect(StrutAreaBottom); strut.isValid()) { region += strut; } if (const StrutRect strut = strutRect(StrutAreaLeft); strut.isValid()) { region += strut; } return region; } bool Window::hasStrut() const { return false; } void Window::setupWindowManagementInterface() { if (m_windowManagementInterface) { // already setup return; } if (!waylandServer() || !waylandServer()->windowManagement()) { return; } auto w = waylandServer()->windowManagement()->createWindow(this, internalId()); w->setTitle(caption()); w->setActive(isActive()); w->setFullscreen(isFullScreen()); w->setKeepAbove(keepAbove()); w->setKeepBelow(keepBelow()); w->setMaximized(maximizeMode() == KWin::MaximizeFull); w->setMinimized(isMinimized()); w->setDemandsAttention(isDemandingAttention()); w->setCloseable(isCloseable()); w->setMaximizeable(isMaximizable()); w->setMinimizeable(isMinimizable()); w->setFullscreenable(isFullScreenable()); w->setApplicationMenuPaths(applicationMenuServiceName(), applicationMenuObjectPath()); w->setIcon(icon()); auto updateAppId = [this, w] { w->setResourceName(resourceName()); w->setAppId(m_desktopFileName.isEmpty() ? resourceClass() : m_desktopFileName); }; updateAppId(); w->setSkipTaskbar(skipTaskbar()); w->setSkipSwitcher(skipSwitcher()); w->setPid(pid()); w->setShadeable(isShadeable()); w->setShaded(isShade()); w->setResizable(isResizable()); w->setMovable(isMovable()); w->setVirtualDesktopChangeable(true); // FIXME Matches X11Window::actionSupported(), but both should be implemented. w->setParentWindow(transientFor() ? transientFor()->windowManagementInterface() : nullptr); w->setGeometry(frameGeometry().toRect()); w->setClientGeometry(clientGeometry().toRect()); connect(this, &Window::skipTaskbarChanged, w, [w, this]() { w->setSkipTaskbar(skipTaskbar()); }); connect(this, &Window::skipSwitcherChanged, w, [w, this]() { w->setSkipSwitcher(skipSwitcher()); }); connect(this, &Window::captionChanged, w, [w, this] { w->setTitle(caption()); }); connect(this, &Window::activeChanged, w, [w, this] { w->setActive(isActive()); }); connect(this, &Window::fullScreenChanged, w, [w, this] { w->setFullscreen(isFullScreen()); }); connect(this, &Window::keepAboveChanged, w, &PlasmaWindowInterface::setKeepAbove); connect(this, &Window::keepBelowChanged, w, &PlasmaWindowInterface::setKeepBelow); connect(this, &Window::minimizedChanged, w, [w, this] { w->setMinimized(isMinimized()); }); connect(this, &Window::maximizedChanged, w, [w, this]() { w->setMaximized(maximizeMode() == MaximizeFull); }); connect(this, &Window::demandsAttentionChanged, w, [w, this] { w->setDemandsAttention(isDemandingAttention()); }); connect(this, &Window::iconChanged, w, [w, this]() { w->setIcon(icon()); }); connect(this, &Window::windowClassChanged, w, updateAppId); connect(this, &Window::desktopFileNameChanged, w, updateAppId); connect(this, &Window::shadeChanged, w, [w, this] { w->setShaded(isShade()); }); connect(this, &Window::transientChanged, w, [w, this]() { w->setParentWindow(transientFor() ? transientFor()->windowManagementInterface() : nullptr); }); connect(this, &Window::frameGeometryChanged, w, [w, this]() { w->setGeometry(frameGeometry().toRect()); }); connect(this, &Window::clientGeometryChanged, w, [w, this]() { w->setClientGeometry(clientGeometry().toRect()); }); connect(this, &Window::applicationMenuChanged, w, [w, this]() { w->setApplicationMenuPaths(applicationMenuServiceName(), applicationMenuObjectPath()); }); connect(w, &PlasmaWindowInterface::closeRequested, this, [this] { closeWindow(); }); connect(w, &PlasmaWindowInterface::moveRequested, this, [this]() { Cursors::self()->mouse()->setPos(frameGeometry().center()); performMousePressCommand(Options::MouseMove, Cursors::self()->mouse()->pos()); }); connect(w, &PlasmaWindowInterface::resizeRequested, this, [this]() { Cursors::self()->mouse()->setPos(frameGeometry().bottomRight()); performMousePressCommand(Options::MouseResize, Cursors::self()->mouse()->pos()); }); connect(w, &PlasmaWindowInterface::fullscreenRequested, this, [this](bool set) { setFullScreen(set); }); connect(w, &PlasmaWindowInterface::minimizedRequested, this, [this](bool set) { setMinimized(set); }); connect(w, &PlasmaWindowInterface::maximizedRequested, this, [this](bool set) { maximize(set ? MaximizeFull : MaximizeRestore); }); connect(w, &PlasmaWindowInterface::keepAboveRequested, this, [this](bool set) { setKeepAbove(set); }); connect(w, &PlasmaWindowInterface::keepBelowRequested, this, [this](bool set) { setKeepBelow(set); }); connect(w, &PlasmaWindowInterface::demandsAttentionRequested, this, [this](bool set) { demandAttention(set); }); connect(w, &PlasmaWindowInterface::activeRequested, this, [this](bool set) { if (set) { workspace()->activateWindow(this, true); } }); connect(w, &PlasmaWindowInterface::shadedRequested, this, [this](bool set) { setShade(set); }); for (const auto vd : std::as_const(m_desktops)) { w->addPlasmaVirtualDesktop(vd->id()); } // We need to set `OnAllDesktops` after the actual VD list has been added. // Otherwise it will unconditionally add the current desktop to the interface // which may not be the case, for example, when using rules w->setOnAllDesktops(isOnAllDesktops()); // Plasma Virtual desktop management // show/hide when the window enters/exits from desktop connect(w, &PlasmaWindowInterface::enterPlasmaVirtualDesktopRequested, this, [this](const QString &desktopId) { VirtualDesktop *vd = VirtualDesktopManager::self()->desktopForId(desktopId); if (vd) { Workspace::self()->addWindowToDesktop(this, vd); } }); connect(w, &PlasmaWindowInterface::enterNewPlasmaVirtualDesktopRequested, this, [this]() { VirtualDesktopManager::self()->setCount(VirtualDesktopManager::self()->count() + 1); auto vd = VirtualDesktopManager::self()->desktops().last(); Workspace::self()->addWindowToDesktop(this, vd); }); connect(w, &PlasmaWindowInterface::leavePlasmaVirtualDesktopRequested, this, [this](const QString &desktopId) { VirtualDesktop *vd = VirtualDesktopManager::self()->desktopForId(desktopId); if (vd) { Workspace::self()->removeWindowFromDesktop(this, vd); } }); for (const auto &activity : std::as_const(m_activityList)) { w->addPlasmaActivity(activity); } connect(this, &Window::activitiesChanged, w, [w, this] { const auto newActivities = QSet(m_activityList.begin(), m_activityList.end()); const auto oldActivitiesList = w->plasmaActivities(); const auto oldActivities = QSet(oldActivitiesList.begin(), oldActivitiesList.end()); const auto activitiesToAdd = newActivities - oldActivities; for (const auto &activity : activitiesToAdd) { w->addPlasmaActivity(activity); } const auto activitiesToRemove = oldActivities - newActivities; for (const auto &activity : activitiesToRemove) { w->removePlasmaActivity(activity); } }); // Plasma Activities management // show/hide when the window enters/exits activity connect(w, &PlasmaWindowInterface::enterPlasmaActivityRequested, this, [this](const QString &activityId) { setOnActivity(activityId, true); }); connect(w, &PlasmaWindowInterface::leavePlasmaActivityRequested, this, [this](const QString &activityId) { setOnActivity(activityId, false); }); connect(w, &PlasmaWindowInterface::sendToOutput, this, [this](OutputInterface *output) { sendToOutput(output->handle()); }); m_windowManagementInterface = w; } void Window::destroyWindowManagementInterface() { delete m_windowManagementInterface; m_windowManagementInterface = nullptr; } std::optional Window::getMousePressCommand(Qt::MouseButton button) const { if (button == Qt::NoButton) { return std::nullopt; } if (isActive()) { if (options->isClickRaise() && !isMostRecentlyRaised()) { return Options::MouseActivateRaiseAndPassClick; } } else { switch (button) { case Qt::LeftButton: return options->commandWindow1(); case Qt::MiddleButton: return options->commandWindow2(); case Qt::RightButton: return options->commandWindow3(); default: // all other buttons pass Activate & Pass Client return Options::MouseActivateAndPassClick; } } return std::nullopt; } std::optional Window::getMouseReleaseCommand(Qt::MouseButton button) const { switch (button) { case Qt::LeftButton: return options->commandWindow1(); case Qt::MiddleButton: return options->commandWindow2(); case Qt::RightButton: return options->commandWindow3(); default: return std::nullopt; } } std::optional Window::getWheelCommand(Qt::Orientation orientation) const { if (orientation != Qt::Vertical || isActive()) { return std::nullopt; } return options->commandWindowWheel(); } bool Window::performMousePressCommand(Options::MouseCommand cmd, const QPointF &globalPos) { if (kwinApp()->operationMode() == Application::OperationModeX11) { // MouseActivateRaiseOnReleaseAndPassClick can't work on X11 if (cmd == Options::MouseActivateRaiseOnReleaseAndPassClick) { cmd = Options::MouseActivateRaiseAndPassClick; } } bool replay = false; switch (cmd) { case Options::MouseRaise: workspace()->raiseWindow(this); break; case Options::MouseLower: { workspace()->lowerWindow(this); // used to be activateNextWindow(this), then topWindowOnDesktop // since this is a mouseOp it's however safe to use the window under the mouse instead if (isActive() && options->focusPolicyIsReasonable()) { Window *next = workspace()->windowUnderMouse(output()); if (next && next != this) { workspace()->requestFocus(next, false); } } break; } case Options::MouseOperationsMenu: if (isActive() && options->isClickRaise()) { autoRaise(); } workspace()->showWindowMenu(QRect(globalPos.toPoint(), globalPos.toPoint()), this); break; case Options::MouseToggleRaiseAndLower: workspace()->raiseOrLowerWindow(this); break; case Options::MouseActivateAndRaise: { replay = isActive(); // for clickraise mode bool mustReplay = !rules()->checkAcceptFocus(acceptsFocus()); if (mustReplay) { auto it = workspace()->stackingOrder().constEnd(), begin = workspace()->stackingOrder().constBegin(); while (mustReplay && --it != begin && *it != this) { auto c = *it; if (!c->isClient() || (c->keepAbove() && !keepAbove()) || (keepBelow() && !c->keepBelow())) { continue; // can never raise above "it" } mustReplay = !(c->isOnCurrentDesktop() && c->isOnCurrentActivity() && c->frameGeometry().intersects(frameGeometry())); } } workspace()->takeActivity(this, Workspace::ActivityFocus | Workspace::ActivityRaise); workspace()->setActiveOutput(globalPos); replay = replay || mustReplay; break; } case Options::MouseActivateAndLower: workspace()->requestFocus(this); workspace()->lowerWindow(this); workspace()->setActiveOutput(globalPos); replay = replay || !rules()->checkAcceptFocus(acceptsFocus()); break; case Options::MouseActivate: replay = isActive(); // for clickraise mode workspace()->takeActivity(this, Workspace::ActivityFocus); workspace()->setActiveOutput(globalPos); replay = replay || !rules()->checkAcceptFocus(acceptsFocus()); break; case Options::MouseActivateRaiseAndPassClick: workspace()->takeActivity(this, Workspace::ActivityFocus | Workspace::ActivityRaise); workspace()->setActiveOutput(globalPos); replay = true; break; case Options::MouseActivateRaiseOnReleaseAndPassClick: workspace()->takeActivity(this, Workspace::ActivityFocus); workspace()->setActiveOutput(globalPos); replay = true; break; case Options::MouseActivateAndPassClick: workspace()->takeActivity(this, Workspace::ActivityFocus); workspace()->setActiveOutput(globalPos); replay = true; break; case Options::MouseMaximize: maximize(MaximizeFull); break; case Options::MouseRestore: maximize(MaximizeRestore); break; case Options::MouseMinimize: setMinimized(true); break; case Options::MouseAbove: { StackingUpdatesBlocker blocker(workspace()); if (keepBelow()) { setKeepBelow(false); } else { setKeepAbove(true); } break; } case Options::MouseBelow: { StackingUpdatesBlocker blocker(workspace()); if (keepAbove()) { setKeepAbove(false); } else { setKeepBelow(true); } break; } case Options::MousePreviousDesktop: workspace()->windowToPreviousDesktop(this); break; case Options::MouseNextDesktop: workspace()->windowToNextDesktop(this); break; case Options::MouseOpacityMore: if (!isDesktop()) { // No point in changing the opacity of the desktop setOpacity(std::min(opacity() + 0.1, 1.0)); } break; case Options::MouseOpacityLess: if (!isDesktop()) { // No point in changing the opacity of the desktop setOpacity(std::max(opacity() - 0.1, 0.1)); } break; case Options::MouseClose: closeWindow(); break; case Options::MouseActivateRaiseAndMove: case Options::MouseActivateRaiseAndUnrestrictedMove: workspace()->raiseWindow(this); workspace()->requestFocus(this); workspace()->setActiveOutput(globalPos); // fallthrough case Options::MouseMove: case Options::MouseUnrestrictedMove: { if (!isMovableAcrossScreens()) { replay = true; break; } if (isInteractiveMoveResize()) { finishInteractiveMoveResize(false); } setInteractiveMoveResizeGravity(Gravity::None); setInteractiveMoveResizePointerButtonDown(true); setInteractiveMoveResizeAnchor(globalPos); setInteractiveMoveResizeModifiers(Qt::KeyboardModifiers()); setInteractiveMoveOffset(QPointF(qreal(globalPos.x() - x()) / width(), qreal(globalPos.y() - y()) / height())); // map from global setUnrestrictedInteractiveMoveResize((cmd == Options::MouseActivateRaiseAndUnrestrictedMove || cmd == Options::MouseUnrestrictedMove)); if (!startInteractiveMoveResize()) { setInteractiveMoveResizePointerButtonDown(false); } updateCursor(); break; } case Options::MouseResize: case Options::MouseUnrestrictedResize: { if (!isResizable() || isShade()) { break; } if (isInteractiveMoveResize()) { finishInteractiveMoveResize(false); } setInteractiveMoveResizePointerButtonDown(true); setInteractiveMoveResizeAnchor(globalPos); setInteractiveMoveResizeModifiers(Qt::KeyboardModifiers()); const QPointF moveOffset = QPointF(globalPos.x() - x(), globalPos.y() - y()); // map from global setInteractiveMoveOffset(QPointF(moveOffset.x() / width(), moveOffset.y() / height())); int x = moveOffset.x(), y = moveOffset.y(); bool left = x < width() / 3; bool right = x >= 2 * width() / 3; bool top = y < height() / 3; bool bot = y >= 2 * height() / 3; Gravity gravity; if (top) { gravity = left ? Gravity::TopLeft : (right ? Gravity::TopRight : Gravity::Top); } else if (bot) { gravity = left ? Gravity::BottomLeft : (right ? Gravity::BottomRight : Gravity::Bottom); } else { gravity = (x < width() / 2) ? Gravity::Left : Gravity::Right; } setInteractiveMoveResizeGravity(gravity); setUnrestrictedInteractiveMoveResize((cmd == Options::MouseUnrestrictedResize)); if (!startInteractiveMoveResize()) { setInteractiveMoveResizePointerButtonDown(false); } updateCursor(); break; } case Options::MouseShade: toggleShade(); cancelShadeHoverTimer(); break; case Options::MouseSetShade: setShade(ShadeNormal); cancelShadeHoverTimer(); break; case Options::MouseUnsetShade: setShade(ShadeNone); cancelShadeHoverTimer(); break; case Options::MouseNothing: default: replay = true; break; } return replay; } bool Window::performMouseReleaseCommand(Options::MouseCommand command, const QPointF &globalPos) { if (kwinApp()->operationMode() == Application::OperationModeX11) { // MouseActivateRaiseOnReleaseAndPassClick can't work on X11 if (command == Options::MouseActivateRaiseOnReleaseAndPassClick) { command = Options::MouseActivateRaiseAndPassClick; } } switch (command) { case Options::MouseActivateRaiseOnReleaseAndPassClick: if (isActive()) { workspace()->takeActivity(this, Workspace::ActivityRaise); } workspace()->setActiveOutput(globalPos); return true; default: return true; } } void Window::setTransientFor(Window *transientFor) { if (transientFor == this) { // cannot be transient for one self return; } if (m_transientFor == transientFor) { return; } m_transientFor = transientFor; Q_EMIT transientChanged(); } const Window *Window::transientFor() const { return m_transientFor; } Window *Window::transientFor() { return m_transientFor; } bool Window::hasTransientPlacementHint() const { return false; } QRectF Window::transientPlacement() const { Q_UNREACHABLE(); return QRectF(); } bool Window::hasTransient(const Window *c, bool indirect) const { return c->transientFor() == this; } QList Window::mainWindows() const { if (const Window *t = transientFor()) { return QList{const_cast(t)}; } return QList(); } QList Window::allMainWindows() const { auto result = mainWindows(); for (const auto *window : result) { result += window->allMainWindows(); } return result; } void Window::setModal(bool m) { // Qt-3.2 can have even modal normal windows :( if (m_modal == m) { return; } m_modal = m; doSetModal(); Q_EMIT modalChanged(); // Changing modality for a mapped window is weird (?) // _NET_WM_STATE_MODAL should possibly rather be _NET_WM_WINDOW_TYPE_MODAL_DIALOG } bool Window::isModal() const { return m_modal; } Window *Window::findModal() const { for (Window *transient : m_transients) { if (transient->isDeleted()) { continue; } if (transient->isModal()) { return transient; } if (Window *modal = transient->findModal()) { return modal; } } return nullptr; } bool Window::isTransient() const { return false; } // check whether a transient should be actually kept above its mainwindow // there may be some special cases where this rule shouldn't be enfored static bool shouldKeepTransientAbove(const Window *parent, const Window *transient) { // #93832 - don't keep splashscreens above dialogs if (transient->isSplash() && parent->isDialog()) { return false; } // This is rather a hack for #76026. Don't keep non-modal dialogs above // the mainwindow, but only if they're group transient (since only such dialogs // have taskbar entry in Kicker). A proper way of doing this (both kwin and kicker) // needs to be found. if (transient->isDialog() && !transient->isModal() && transient->groupTransient()) { return false; } // #63223 - don't keep transients above docks, because the dock is kept high, // and e.g. dialogs for them would be too high too // ignore this if the transient has a placement hint which indicates it should go above it's parent if (parent->isDock() && !transient->hasTransientPlacementHint()) { return false; } return true; } void Window::addTransient(Window *cl) { Q_ASSERT(!m_transients.contains(cl)); Q_ASSERT(cl != this); m_transients.append(cl); if (shouldKeepTransientAbove(this, cl)) { workspace()->constrain(this, cl); } } void Window::removeTransient(Window *cl) { m_transients.removeAll(cl); if (cl->transientFor() == this) { cl->setTransientFor(nullptr); } workspace()->unconstrain(this, cl); } void Window::removeTransientFromList(Window *cl) { m_transients.removeAll(cl); } bool Window::isActiveFullScreen() const { if (!isFullScreen()) { return false; } const auto ac = workspace()->mostRecentlyActivatedWindow(); // instead of activeWindow() - avoids flicker // according to NETWM spec implementation notes suggests // "focused windows having state _NET_WM_STATE_FULLSCREEN" to be on the highest layer. // we'll also take the screen into account return ac && (ac == this || !ac->isOnOutput(output()) || ac->allMainWindows().contains(const_cast(this))); } int Window::borderBottom() const { return isDecorated() ? decoration()->borderBottom() : 0; } int Window::borderLeft() const { return isDecorated() ? decoration()->borderLeft() : 0; } int Window::borderRight() const { return isDecorated() ? decoration()->borderRight() : 0; } int Window::borderTop() const { return isDecorated() ? decoration()->borderTop() : 0; } void Window::updateCursor() { if (isDeleted()) { return; } Gravity gravity = interactiveMoveResizeGravity(); if (!isResizable() || isShade()) { gravity = Gravity::None; } CursorShape c = Qt::ArrowCursor; switch (gravity) { case Gravity::TopLeft: c = KWin::ExtendedCursor::SizeNorthWest; break; case Gravity::BottomRight: c = KWin::ExtendedCursor::SizeSouthEast; break; case Gravity::BottomLeft: c = KWin::ExtendedCursor::SizeSouthWest; break; case Gravity::TopRight: c = KWin::ExtendedCursor::SizeNorthEast; break; case Gravity::Top: c = KWin::ExtendedCursor::SizeNorth; break; case Gravity::Bottom: c = KWin::ExtendedCursor::SizeSouth; break; case Gravity::Left: c = KWin::ExtendedCursor::SizeWest; break; case Gravity::Right: c = KWin::ExtendedCursor::SizeEast; break; default: if (isInteractiveMoveResize()) { c = Qt::ClosedHandCursor; } else { c = Qt::ArrowCursor; } break; } if (c == m_interactiveMoveResize.cursor) { return; } m_interactiveMoveResize.cursor = c; Q_EMIT moveResizeCursorChanged(c); } void Window::leaveInteractiveMoveResize() { workspace()->setMoveResizeWindow(nullptr); setInteractiveMoveResize(false); if (workspace()->screenEdges()->isDesktopSwitchingMovingClients()) { workspace()->screenEdges()->reserveDesktopSwitching(false, Qt::Vertical | Qt::Horizontal); } if (isElectricBorderMaximizing()) { workspace()->outline()->hide(); } } bool Window::doStartInteractiveMoveResize() { return true; } void Window::doFinishInteractiveMoveResize() { } bool Window::isWaitingForInteractiveResizeSync() const { return false; } void Window::doInteractiveResizeSync(const QRectF &) { } void Window::checkQuickTilingMaximizationZones(int xroot, int yroot) { std::optional mode = std::nullopt; bool innerBorder = false; const auto outputs = workspace()->outputs(); for (const Output *output : outputs) { if (!output->geometry().contains(QPoint(xroot, yroot))) { continue; } auto isInScreen = [&output, &outputs](const QPoint &pt) { for (const Output *other : outputs) { if (other == output) { continue; } if (other->geometry().contains(pt)) { return true; } } return false; }; QRectF area = workspace()->clientArea(MaximizeArea, this, QPointF(xroot, yroot)); QuickTileMode tile = QuickTileFlag::None; if (options->electricBorderTiling()) { if (xroot <= area.x() + 20) { tile |= QuickTileFlag::Left; innerBorder = isInScreen(QPoint(area.x() - 1, yroot)); } else if (xroot >= area.x() + area.width() - 20) { tile |= QuickTileFlag::Right; innerBorder = isInScreen(QPoint(area.right() + 1, yroot)); } } if (tile != QuickTileMode(QuickTileFlag::None)) { if (yroot <= area.y() + area.height() * options->electricBorderCornerRatio()) { tile |= QuickTileFlag::Top; } else if (yroot >= area.y() + area.height() - area.height() * options->electricBorderCornerRatio()) { tile |= QuickTileFlag::Bottom; } mode = tile; } else if (options->electricBorderMaximize() && yroot <= area.y() + 5 && isMaximizable()) { mode = MaximizeFull; innerBorder = isInScreen(QPoint(xroot, area.y() - 1)); } break; // no point in checking other screens to contain this... "point"... } if (mode != electricBorderMode()) { setElectricBorderMode(mode); if (innerBorder) { if (!m_electricMaximizingDelay) { m_electricMaximizingDelay = new QTimer(this); m_electricMaximizingDelay->setInterval(250); m_electricMaximizingDelay->setSingleShot(true); connect(m_electricMaximizingDelay, &QTimer::timeout, this, [this]() { if (isInteractiveMove()) { setElectricBorderMaximizing(electricBorderMode().has_value()); } }); } m_electricMaximizingDelay->start(); } else { setElectricBorderMaximizing(mode.has_value()); } } } void Window::resetQuickTilingMaximizationZones() { if (electricBorderMode().has_value()) { if (m_electricMaximizingDelay) { m_electricMaximizingDelay->stop(); } setElectricBorderMaximizing(false); setElectricBorderMode(std::nullopt); } } void Window::keyPressEvent(uint key_code) { if (!isInteractiveMove() && !isInteractiveResize()) { return; } bool is_control = key_code & Qt::CTRL; bool is_alt = key_code & Qt::ALT; key_code = key_code & ~Qt::KeyboardModifierMask; int delta = is_control ? 1 : is_alt ? 32 : 8; QPointF pos = interactiveMoveResizeAnchor(); switch (key_code) { case Qt::Key_Left: pos.rx() -= delta; break; case Qt::Key_Right: pos.rx() += delta; break; case Qt::Key_Up: pos.ry() -= delta; break; case Qt::Key_Down: pos.ry() += delta; break; case Qt::Key_Space: case Qt::Key_Return: case Qt::Key_Enter: setInteractiveMoveResizePointerButtonDown(false); finishInteractiveMoveResize(false); updateCursor(); break; case Qt::Key_Escape: setInteractiveMoveResizePointerButtonDown(false); finishInteractiveMoveResize(true); updateCursor(); break; default: return; } Cursors::self()->mouse()->setPos(pos); } QSizeF Window::resizeIncrements() const { return QSizeF(1, 1); } void Window::dontInteractiveMoveResize() { setInteractiveMoveResizePointerButtonDown(false); stopDelayedInteractiveMoveResize(); if (isInteractiveMoveResize()) { finishInteractiveMoveResize(false); } } Gravity Window::mouseGravity() const { if (isDecorated()) { switch (decoration()->sectionUnderMouse()) { case Qt::BottomLeftSection: return Gravity::BottomLeft; case Qt::BottomRightSection: return Gravity::BottomRight; case Qt::BottomSection: return Gravity::Bottom; case Qt::LeftSection: return Gravity::Left; case Qt::RightSection: return Gravity::Right; case Qt::TopSection: return Gravity::Top; case Qt::TopLeftSection: return Gravity::TopLeft; case Qt::TopRightSection: return Gravity::TopRight; default: return Gravity::None; } } return Gravity::None; } void Window::endInteractiveMoveResize() { setInteractiveMoveResizePointerButtonDown(false); stopDelayedInteractiveMoveResize(); if (isInteractiveMoveResize()) { finishInteractiveMoveResize(false); setInteractiveMoveResizeGravity(mouseGravity()); } updateCursor(); } void Window::cancelInteractiveMoveResize() { setInteractiveMoveResizePointerButtonDown(false); stopDelayedInteractiveMoveResize(); if (isInteractiveMoveResize()) { finishInteractiveMoveResize(true); setInteractiveMoveResizeGravity(mouseGravity()); } updateCursor(); } void Window::setDecoration(std::shared_ptr decoration) { if (m_decoration.decoration == decoration) { return; } if (decoration) { QMetaObject::invokeMethod(decoration.get(), QOverload<>::of(&KDecoration3::Decoration::update), Qt::QueuedConnection); connect(decoration.get(), &KDecoration3::Decoration::shadowChanged, this, [this]() { if (!isDeleted()) { updateShadow(); } }); connect(decoration.get(), &KDecoration3::Decoration::bordersChanged, this, [this]() { if (!isDeleted()) { updateDecorationInputShape(); } }); connect(decoration.get(), &KDecoration3::Decoration::resizeOnlyBordersChanged, this, [this]() { if (!isDeleted()) { updateDecorationInputShape(); } }); connect(decoratedClient()->decoratedClient(), &KDecoration3::DecoratedClient::sizeChanged, this, [this]() { if (!isDeleted()) { updateDecorationInputShape(); } }); } m_decoration.decoration = decoration; updateDecorationInputShape(); Q_EMIT decorationChanged(); } void Window::updateDecorationInputShape() { if (!isDecorated()) { m_decoration.inputRegion = QRegion(); return; } const QMargins borders = decoration()->borders(); const QMargins resizeBorders = decoration()->resizeOnlyBorders(); const QRectF innerRect = QRectF(QPointF(borderLeft(), borderTop()), decoratedClient()->size()); const QRectF outerRect = innerRect + borders + resizeBorders; m_decoration.inputRegion = QRegion(outerRect.toAlignedRect()) - innerRect.toAlignedRect(); } bool Window::decorationHasAlpha() const { if (!isDecorated() || decoration()->isOpaque()) { // either no decoration or decoration has alpha disabled return false; } return true; } void Window::triggerDecorationRepaint() { if (isDecorated()) { decoration()->update(); } } void Window::layoutDecorationRects(QRectF &left, QRectF &top, QRectF &right, QRectF &bottom) const { if (!isDecorated()) { return; } QRectF r = decoration()->rect(); top = QRectF(r.x(), r.y(), r.width(), borderTop()); bottom = QRectF(r.x(), r.y() + r.height() - borderBottom(), r.width(), borderBottom()); left = QRectF(r.x(), r.y() + top.height(), borderLeft(), r.height() - top.height() - bottom.height()); right = QRectF(r.x() + r.width() - borderRight(), r.y() + top.height(), borderRight(), r.height() - top.height() - bottom.height()); } void Window::processDecorationMove(const QPointF &localPos, const QPointF &globalPos) { if (isInteractiveMoveResizePointerButtonDown()) { if (!isInteractiveMoveResize()) { const QPointF offset(interactiveMoveOffset().x() * width(), interactiveMoveOffset().y() * height()); const QPointF delta(localPos - offset); if (delta.manhattanLength() >= QApplication::startDragDistance()) { if (startInteractiveMoveResize()) { updateInteractiveMoveResize(globalPos, input()->keyboardModifiers()); } else { setInteractiveMoveResizePointerButtonDown(false); } updateCursor(); } } return; } // TODO: handle modifiers Gravity newGravity = mouseGravity(); if (newGravity != interactiveMoveResizeGravity()) { setInteractiveMoveResizeGravity(newGravity); updateCursor(); } } bool Window::processDecorationButtonPress(const QPointF &localPos, const QPointF &globalPos, Qt::MouseButton button, bool ignoreMenu) { Options::MouseCommand com = Options::MouseNothing; bool active = isActive(); if (!wantsInput()) { // we cannot be active, use it anyway active = true; } // check whether it is a double click if (button == Qt::LeftButton) { if (m_decoration.doubleClickTimer.isValid()) { const qint64 interval = m_decoration.doubleClickTimer.elapsed(); m_decoration.doubleClickTimer.invalidate(); if (interval > QGuiApplication::styleHints()->mouseDoubleClickInterval()) { m_decoration.doubleClickTimer.start(); // expired -> new first click and pot. init } else { Options::WindowOperation operation; switch (decoration()->sectionUnderMouse()) { case Qt::TitleBarArea: operation = options->operationTitlebarDblClick(); break; case Qt::LeftSection: case Qt::RightSection: operation = Options::HMaximizeOp; break; case Qt::TopSection: case Qt::BottomSection: operation = Options::VMaximizeOp; break; case Qt::TopLeftSection: case Qt::TopRightSection: case Qt::BottomLeftSection: case Qt::BottomRightSection: operation = Options::MaximizeOp; break; default: operation = Options::NoOp; break; } workspace()->performWindowOperation(this, operation); dontInteractiveMoveResize(); return false; } } else { m_decoration.doubleClickTimer.start(); // new first click and pot. init, could be invalidated by release - see below } } if (button == Qt::LeftButton) { com = active ? options->commandActiveTitlebar1() : options->commandInactiveTitlebar1(); } else if (button == Qt::MiddleButton) { com = active ? options->commandActiveTitlebar2() : options->commandInactiveTitlebar2(); } else if (button == Qt::RightButton) { com = active ? options->commandActiveTitlebar3() : options->commandInactiveTitlebar3(); } if (button == Qt::LeftButton && com != Options::MouseOperationsMenu // actions where it's not possible to get the matching && com != Options::MouseMinimize) // mouse release event { setInteractiveMoveResizeGravity(mouseGravity()); setInteractiveMoveResizePointerButtonDown(true); setInteractiveMoveResizeAnchor(globalPos); setInteractiveMoveResizeModifiers(Qt::KeyboardModifiers()); setInteractiveMoveOffset(QPointF(qreal(localPos.x()) / width(), qreal(localPos.y()) / height())); setUnrestrictedInteractiveMoveResize(false); startDelayedInteractiveMoveResize(); updateCursor(); } // In the new API the decoration may process the menu action to display an inactive tab's menu. // If the event is unhandled then the core will create one for the active window in the group. if (!ignoreMenu || com != Options::MouseOperationsMenu) { performMousePressCommand(com, globalPos); } return !( // Return events that should be passed to the decoration in the new API com == Options::MouseRaise || com == Options::MouseOperationsMenu || com == Options::MouseActivateAndRaise || com == Options::MouseActivate || com == Options::MouseActivateRaiseAndPassClick || com == Options::MouseActivateAndPassClick || com == Options::MouseNothing); } void Window::processDecorationButtonRelease(Qt::MouseButton button) { if (button == Qt::LeftButton) { setInteractiveMoveResizePointerButtonDown(false); stopDelayedInteractiveMoveResize(); if (isInteractiveMoveResize()) { finishInteractiveMoveResize(false); setInteractiveMoveResizeGravity(mouseGravity()); } updateCursor(); } } void Window::startDecorationDoubleClickTimer() { m_decoration.doubleClickTimer.start(); } void Window::invalidateDecorationDoubleClickTimer() { m_decoration.doubleClickTimer.invalidate(); } bool Window::providesContextHelp() const { return false; } void Window::showContextHelp() { } Decoration::DecoratedClientImpl *Window::decoratedClient() const { return m_decoration.client; } void Window::setDecoratedClient(Decoration::DecoratedClientImpl *client) { m_decoration.client = client; } void Window::pointerEnterEvent(const QPointF &globalPos) { if (options->isShadeHover()) { cancelShadeHoverTimer(); startShadeHoverTimer(); } if (options->focusPolicy() == Options::ClickToFocus || workspace()->userActionsMenu()->isShown()) { return; } if (options->isAutoRaise() && !isDesktop() && !isDock() && workspace()->focusChangeEnabled() && globalPos != workspace()->focusMousePosition() && workspace()->topWindowOnDesktop(VirtualDesktopManager::self()->currentDesktop(), options->isSeparateScreenFocus() ? output() : nullptr) != this) { startAutoRaise(); } if (isDesktop() || isDock()) { return; } // for FocusFollowsMouse, change focus only if the mouse has actually been moved, not if the focus // change came because of window changes (e.g. closing a window) - #92290 if (options->focusPolicy() != Options::FocusFollowsMouse || globalPos != workspace()->focusMousePosition()) { workspace()->requestDelayFocus(this); } } void Window::pointerLeaveEvent() { cancelAutoRaise(); workspace()->cancelDelayFocus(); cancelShadeHoverTimer(); startShadeUnhoverTimer(); // TODO: send hover leave to deco // TODO: handle Options::FocusStrictlyUnderMouse } QRectF Window::iconGeometry() const { if (!windowManagementInterface() || !waylandServer()) { // window management interface is only available if the surface is mapped return QRectF(); } int minDistance = INT_MAX; Window *candidatePanel = nullptr; QRectF candidateGeom; const auto minGeometries = windowManagementInterface()->minimizedGeometries(); for (auto i = minGeometries.constBegin(), end = minGeometries.constEnd(); i != end; ++i) { Window *panel = waylandServer()->findWindow(i.key()); if (!panel) { continue; } const int distance = QPointF(panel->pos() - pos()).manhattanLength(); if (distance < minDistance) { minDistance = distance; candidatePanel = panel; candidateGeom = i.value(); } } if (!candidatePanel) { // Check all mainwindows of this window. const auto windows = mainWindows(); for (Window *mainWindow : windows) { const auto geom = mainWindow->iconGeometry(); if (geom.isValid()) { return geom; } } return QRectF(); } return candidateGeom.translated(candidatePanel->pos()); } QRectF Window::virtualKeyboardGeometry() const { return m_virtualKeyboardGeometry; } void Window::setVirtualKeyboardGeometry(const QRectF &geo) { // No keyboard anymore if (geo.isEmpty() && !m_keyboardGeometryRestore.isEmpty()) { const QRectF availableArea = workspace()->clientArea(MaximizeArea, this); QRectF newWindowGeometry = (requestedMaximizeMode() & MaximizeHorizontal) ? availableArea : m_keyboardGeometryRestore; moveResize(newWindowGeometry); m_keyboardGeometryRestore = QRectF(); } else if (geo.isEmpty()) { return; // The keyboard has just been opened (rather than resized) save window geometry for a restore } else if (m_keyboardGeometryRestore.isEmpty()) { m_keyboardGeometryRestore = moveResizeGeometry(); } m_virtualKeyboardGeometry = geo; // Don't resize Desktop and fullscreen windows if (isRequestedFullScreen() || isDesktop()) { return; } if (!geo.intersects(m_keyboardGeometryRestore)) { return; } const QRectF availableArea = workspace()->clientArea(MaximizeArea, this); QRectF newWindowGeometry = (requestedMaximizeMode() & MaximizeHorizontal) ? availableArea : m_keyboardGeometryRestore; newWindowGeometry.setHeight(std::min(newWindowGeometry.height(), geo.top() - availableArea.top())); newWindowGeometry.moveTop(std::max(geo.top() - newWindowGeometry.height(), availableArea.top())); newWindowGeometry = newWindowGeometry.intersected(availableArea); moveResize(newWindowGeometry); } QRectF Window::keyboardGeometryRestore() const { return m_keyboardGeometryRestore; } void Window::setKeyboardGeometryRestore(const QRectF &geom) { m_keyboardGeometryRestore = geom; } bool Window::dockWantsInput() const { return false; } void Window::setDesktopFileName(const QString &name) { const QString effectiveName = rules()->checkDesktopFile(name); if (effectiveName == m_desktopFileName) { return; } m_desktopFileName = effectiveName; updateWindowRules(Rules::DesktopFile); Q_EMIT desktopFileNameChanged(); } QString Window::iconFromDesktopFile(const QString &desktopFileName) { const QString absolutePath = findDesktopFile(desktopFileName); if (absolutePath.isEmpty()) { return {}; } KDesktopFile df(absolutePath); return df.readIcon(); } QString Window::iconFromDesktopFile() const { return iconFromDesktopFile(m_desktopFileName); } QString Window::findDesktopFile(const QString &desktopFileName) { if (desktopFileName.isEmpty()) { return {}; } const QLatin1StringView suffix(".desktop"); const QString desktopFileNameWithPrefix = desktopFileName + suffix; if (QDir::isAbsolutePath(desktopFileName)) { if (QFile::exists(desktopFileNameWithPrefix)) { return desktopFileNameWithPrefix; } if (desktopFileName.endsWith(suffix)) { if (QFile::exists(desktopFileName)) { return desktopFileName; } } return QString(); } const QString filePath = QStandardPaths::locate(QStandardPaths::ApplicationsLocation, desktopFileNameWithPrefix); if (!filePath.isEmpty()) { return filePath; } if (desktopFileName.endsWith(suffix)) { return QStandardPaths::locate(QStandardPaths::ApplicationsLocation, desktopFileName); } return QString(); } bool Window::hasApplicationMenu() const { return Workspace::self()->applicationMenu()->applicationMenuEnabled() && !m_applicationMenuServiceName.isEmpty() && !m_applicationMenuObjectPath.isEmpty(); } void Window::updateApplicationMenuServiceName(const QString &serviceName) { const bool old_hasApplicationMenu = hasApplicationMenu(); m_applicationMenuServiceName = serviceName; const bool new_hasApplicationMenu = hasApplicationMenu(); Q_EMIT applicationMenuChanged(); if (old_hasApplicationMenu != new_hasApplicationMenu) { Q_EMIT hasApplicationMenuChanged(new_hasApplicationMenu); } } void Window::updateApplicationMenuObjectPath(const QString &objectPath) { const bool old_hasApplicationMenu = hasApplicationMenu(); m_applicationMenuObjectPath = objectPath; const bool new_hasApplicationMenu = hasApplicationMenu(); Q_EMIT applicationMenuChanged(); if (old_hasApplicationMenu != new_hasApplicationMenu) { Q_EMIT hasApplicationMenuChanged(new_hasApplicationMenu); } } void Window::setApplicationMenuActive(bool applicationMenuActive) { if (m_applicationMenuActive != applicationMenuActive) { m_applicationMenuActive = applicationMenuActive; Q_EMIT applicationMenuActiveChanged(applicationMenuActive); } } void Window::showApplicationMenu(int actionId) { if (isDecorated()) { decoration()->showApplicationMenu(actionId); } else { // we don't know where the application menu button will be, show it in the top left corner instead Workspace::self()->showApplicationMenu(QRect(), this, actionId); } } bool Window::unresponsive() const { return m_unresponsive; } void Window::setUnresponsive(bool unresponsive) { if (m_unresponsive != unresponsive) { m_unresponsive = unresponsive; Q_EMIT unresponsiveChanged(m_unresponsive); Q_EMIT captionChanged(); } } QString Window::shortcutCaptionSuffix() const { if (shortcut().isEmpty()) { return QString(); } return QLatin1String(" {") + shortcut().toString() + QLatin1Char('}'); } QString Window::caption() const { QString cap = captionNormal() + captionSuffix(); if (unresponsive()) { cap += QLatin1String(" "); cap += i18nc("Application is not responding, appended to window title", "(Not Responding)"); } return cap; } /** * Returns the list of activities the window window is on. * if it's on all activities, the list will be empty. * Don't use this, use isOnActivity() and friends (from class Window) */ QStringList Window::activities() const { return m_activityList; } bool Window::isOnCurrentActivity() const { #if KWIN_BUILD_ACTIVITIES if (!Workspace::self()->activities()) { return true; } return isOnActivity(Workspace::self()->activities()->current()); #else return true; #endif } /** * Sets whether the window is on @p activity. * If you remove it from its last activity, then it's on all activities. * * Note: If it was on all activities and you try to remove it from one, nothing will happen; * I don't think that's an important enough use case to handle here. */ void Window::setOnActivity(const QString &activity, bool enable) { #if KWIN_BUILD_ACTIVITIES if (!Workspace::self()->activities()) { return; } QStringList newActivitiesList = activities(); if (newActivitiesList.contains(activity) == enable) { // nothing to do return; } if (enable) { QStringList allActivities = Workspace::self()->activities()->all(); if (!allActivities.contains(activity)) { // bogus ID return; } newActivitiesList.append(activity); } else { newActivitiesList.removeOne(activity); } setOnActivities(newActivitiesList); #endif } /** * set exactly which activities this window is on */ void Window::setOnActivities(const QStringList &newActivitiesList) { #if KWIN_BUILD_ACTIVITIES if (!Workspace::self()->activities()) { return; } if (Workspace::self()->activities()->serviceStatus() != KActivities::Consumer::Running) { return; } const auto allActivities = Workspace::self()->activities()->all(); const auto activityList = [&] { auto result = rules()->checkActivity(newActivitiesList); const auto it = std::remove_if(result.begin(), result.end(), [=](const QString &activity) { return !allActivities.contains(activity); }); result.erase(it, result.end()); return result; }(); const auto allActivityExplicitlyRequested = activityList.isEmpty() || activityList.contains(Activities::nullUuid()); const auto allActivitiesCovered = activityList.size() > 1 && activityList.size() == allActivities.size(); if (allActivityExplicitlyRequested || allActivitiesCovered) { if (!m_activityList.isEmpty()) { m_activityList.clear(); doSetOnActivities(m_activityList); } } else { if (m_activityList != activityList) { m_activityList = activityList; doSetOnActivities(m_activityList); } } updateActivities(false); #endif } void Window::doSetOnActivities(const QStringList &activityList) { } /** * if @p all is true, sets on all activities. * if it's false, sets it to only be on the current activity */ void Window::setOnAllActivities(bool all) { #if KWIN_BUILD_ACTIVITIES if (all == isOnAllActivities()) { return; } if (all) { setOnActivities(QStringList()); } else { setOnActivity(Workspace::self()->activities()->current(), true); } #endif } /** * update after activities changed */ void Window::updateActivities(bool includeTransients) { if (m_activityUpdatesBlocked) { m_blockedActivityUpdatesRequireTransients |= includeTransients; return; } Q_EMIT activitiesChanged(); m_blockedActivityUpdatesRequireTransients = false; // reset Workspace::self()->focusChain()->update(this, FocusChain::MakeFirst); updateWindowRules(Rules::Activity); } void Window::blockActivityUpdates(bool b) { if (b) { ++m_activityUpdatesBlocked; } else { Q_ASSERT(m_activityUpdatesBlocked); --m_activityUpdatesBlocked; if (!m_activityUpdatesBlocked) { updateActivities(m_blockedActivityUpdatesRequireTransients); } } } bool Window::groupTransient() const { return false; } const Group *Window::group() const { return nullptr; } Group *Window::group() { return nullptr; } QPointF Window::framePosToClientPos(const QPointF &point) const { return point + QPointF(borderLeft(), borderTop()); } QPointF Window::clientPosToFramePos(const QPointF &point) const { return point - QPointF(borderLeft(), borderTop()); } QSizeF Window::frameSizeToClientSize(const QSizeF &size) const { const qreal width = size.width() - borderLeft() - borderRight(); const qreal height = size.height() - borderTop() - borderBottom(); return QSizeF(width, height); } QSizeF Window::clientSizeToFrameSize(const QSizeF &size) const { const qreal width = size.width() + borderLeft() + borderRight(); const qreal height = size.height() + borderTop() + borderBottom(); return QSizeF(width, height); } QRectF Window::frameRectToClientRect(const QRectF &rect) const { const QPointF position = framePosToClientPos(rect.topLeft()); const QSizeF size = frameSizeToClientSize(rect.size()); return QRectF(position, size); } QRectF Window::clientRectToFrameRect(const QRectF &rect) const { const QPointF position = clientPosToFramePos(rect.topLeft()); const QSizeF size = clientSizeToFrameSize(rect.size()); return QRectF(position, size); } QRectF Window::moveResizeGeometry() const { return m_moveResizeGeometry; } void Window::setMoveResizeGeometry(const QRectF &geo) { m_moveResizeGeometry = geo; setMoveResizeOutput(workspace()->outputAt(geo.center())); } Output *Window::moveResizeOutput() const { return m_moveResizeOutput; } void Window::setMoveResizeOutput(Output *output) { if (m_moveResizeOutput == output) { return; } if (m_moveResizeOutput) { disconnect(m_moveResizeOutput, &Output::scaleChanged, this, &Window::updatePreferredBufferScale); disconnect(m_moveResizeOutput, &Output::transformChanged, this, &Window::updatePreferredBufferTransform); disconnect(m_moveResizeOutput, &Output::colorDescriptionChanged, this, &Window::updatePreferredColorDescription); } m_moveResizeOutput = output; if (output) { connect(output, &Output::scaleChanged, this, &Window::updatePreferredBufferScale); connect(output, &Output::transformChanged, this, &Window::updatePreferredBufferTransform); connect(output, &Output::colorDescriptionChanged, this, &Window::updatePreferredColorDescription); } updatePreferredBufferScale(); updatePreferredBufferTransform(); updatePreferredColorDescription(); } void Window::move(const QPointF &point) { if (isDeleted()) { return; } const QRectF rect = QRectF(point, m_moveResizeGeometry.size()); setMoveResizeGeometry(rect); moveResizeInternal(rect, MoveResizeMode::Move); } void Window::resize(const QSizeF &size) { if (isDeleted()) { return; } const QRectF rect = QRectF(m_moveResizeGeometry.topLeft(), size); setMoveResizeGeometry(rect); moveResizeInternal(rect, MoveResizeMode::Resize); } void Window::moveResize(const QRectF &rect) { if (isDeleted()) { return; } setMoveResizeGeometry(rect); moveResizeInternal(rect, MoveResizeMode::MoveResize); } void Window::setElectricBorderMode(std::optional mode) { m_electricMode = mode; } void Window::setElectricBorderMaximizing(bool maximizing) { m_electricMaximizing = maximizing; if (maximizing) { if (auto quickTileMode = std::get_if(&m_electricMode.value())) { workspace()->outline()->show(quickTileGeometry(*quickTileMode, interactiveMoveResizeAnchor()).toRect(), moveResizeGeometry().toRect()); } else if (std::get_if(&m_electricMode.value())) { workspace()->outline()->show(workspace()->clientArea(MaximizeArea, this, interactiveMoveResizeAnchor()).toRect(), moveResizeGeometry().toRect()); } } else { workspace()->outline()->hide(); } } QRectF Window::quickTileGeometry(QuickTileMode mode, const QPointF &pos) const { Output *output = workspace()->outputAt(pos); if (mode & QuickTileFlag::Custom) { Tile *tile = workspace()->tileManager(output)->bestTileForPosition(pos); if (tile) { return tile->windowGeometry(); } } Tile *tile = workspace()->tileManager(output)->quickTile(mode); if (tile) { return tile->windowGeometry(); } return workspace()->clientArea(MaximizeArea, this, pos); } void Window::updateQuickTileMode(QuickTileMode newMode) { if ((!m_requestedTile && newMode == QuickTileMode(QuickTileFlag::None)) || m_requestedTile->quickTileMode() == newMode) { return; } m_requestedTile = workspace()->tileManager(output())->quickTile(newMode); doSetQuickTileMode(); } void Window::updateElectricGeometryRestore() { m_electricGeometryRestore = geometryRestore(); if (m_interactiveMoveResize.initialQuickTileMode == QuickTileMode(QuickTileFlag::None)) { if (!(requestedMaximizeMode() & MaximizeHorizontal)) { m_electricGeometryRestore.setX(x()); m_electricGeometryRestore.setWidth(width()); } if (!(requestedMaximizeMode() & MaximizeVertical)) { m_electricGeometryRestore.setY(y()); m_electricGeometryRestore.setHeight(height()); } } } QRectF Window::quickTileGeometryRestore() const { if (quickTileMode() != QuickTileMode(QuickTileFlag::None)) { // If the window is tiled, geometryRestore() already has a good value. return geometryRestore(); } if (isElectricBorderMaximizing()) { return m_electricGeometryRestore; } else { return moveResizeGeometry(); } } void Window::handleQuickTileShortcut(QuickTileMode mode) { // Only allow quick tile on a regular window. if (!isResizable() || isAppletPopup()) { return; } QPointF tileAtPoint = moveResizeGeometry().center(); if (mode != QuickTileFlag::None) { const QuickTileMode oldMode = requestedQuickTileMode(); if (oldMode == QuickTileMode(QuickTileFlag::None) && requestedMaximizeMode() == MaximizeMode::MaximizeRestore) { // Not coming out of an existing tile, not shifting monitors, we're setting a brand new tile. // Store geometry first, so we can go out of this tile later. setGeometryRestore(quickTileGeometryRestore()); } else { QuickTileMode combined = oldMode; if (mode & QuickTileFlag::Left) { if (oldMode & QuickTileFlag::Right) { combined.setFlag(QuickTileFlag::Right, false); } else { combined.setFlag(QuickTileFlag::Left); } } if (mode & QuickTileFlag::Right) { if (oldMode & QuickTileFlag::Left) { combined.setFlag(QuickTileFlag::Left, false); } else { combined.setFlag(QuickTileFlag::Right); } } if (mode & QuickTileFlag::Top) { if (oldMode & QuickTileFlag::Bottom) { combined.setFlag(QuickTileFlag::Bottom, false); } else { combined.setFlag(QuickTileFlag::Top); } } if (mode & QuickTileFlag::Bottom) { if (oldMode & QuickTileFlag::Top) { combined.setFlag(QuickTileFlag::Top, false); } else { combined.setFlag(QuickTileFlag::Bottom); } } // If trying to tile to the side that the window is already tiled to move the window to the next // screen near the tile if it exists and swap the tile side, otherwise toggle the mode (set QuickTileFlag::None) if (combined == oldMode) { Output *currentOutput = moveResizeOutput(); Output *nextOutput = currentOutput; Output *candidateOutput = currentOutput; if ((mode & QuickTileFlag::Horizontal) == QuickTileMode(QuickTileFlag::Left)) { candidateOutput = workspace()->findOutput(nextOutput, Workspace::DirectionWest); } else if ((mode & QuickTileFlag::Horizontal) == QuickTileMode(QuickTileFlag::Right)) { candidateOutput = workspace()->findOutput(nextOutput, Workspace::DirectionEast); } bool shiftHorizontal = candidateOutput != nextOutput; nextOutput = candidateOutput; if ((mode & QuickTileFlag::Vertical) == QuickTileMode(QuickTileFlag::Top)) { candidateOutput = workspace()->findOutput(nextOutput, Workspace::DirectionNorth); } else if ((mode & QuickTileFlag::Vertical) == QuickTileMode(QuickTileFlag::Bottom)) { candidateOutput = workspace()->findOutput(nextOutput, Workspace::DirectionSouth); } bool shiftVertical = candidateOutput != nextOutput; nextOutput = candidateOutput; if (nextOutput == currentOutput) { combined = QuickTileFlag::None; // No other screens in the tile direction, toggle tiling } else { // Move to other screen tileAtPoint = nextOutput->geometry().center(); // Swap sides if (shiftHorizontal) { combined = (~combined & QuickTileFlag::Horizontal) | (combined & QuickTileFlag::Vertical); } if (shiftVertical) { combined = (~combined & QuickTileFlag::Vertical) | (combined & QuickTileFlag::Horizontal); } } } mode = combined; } } setQuickTileMode(mode, tileAtPoint); } void Window::setQuickTileModeAtCurrentPosition(QuickTileMode mode) { setQuickTileMode(mode, m_moveResizeGeometry.center()); } void Window::setQuickTileMode(QuickTileMode mode, const QPointF &tileAtPoint) { // Only allow quick tile on a regular window. if (!isResizable() || isAppletPopup()) { return; } workspace()->updateFocusMousePosition(Cursors::self()->mouse()->pos()); // may cause leave event // sanitize the mode, ie. simplify "invalid" combinations if ((mode & QuickTileFlag::Horizontal) == QuickTileMode(QuickTileFlag::Horizontal)) { mode &= ~QuickTileMode(QuickTileFlag::Horizontal); } if ((mode & QuickTileFlag::Vertical) == QuickTileMode(QuickTileFlag::Vertical)) { mode &= ~QuickTileMode(QuickTileFlag::Vertical); } if (mode == QuickTileMode(QuickTileFlag::Custom)) { requestTile(workspace()->tileManager(workspace()->outputAt(tileAtPoint))->bestTileForPosition(tileAtPoint)); } else { requestTile(workspace()->tileManager(workspace()->outputAt(tileAtPoint))->quickTile(mode)); } } QuickTileMode Window::quickTileMode() const { if (m_tile) { return m_tile->quickTileMode(); } else { return QuickTileFlag::None; } } QuickTileMode Window::requestedQuickTileMode() const { if (m_requestedTile) { return m_requestedTile->quickTileMode(); } return QuickTileFlag::None; } void Window::commitTile(Tile *tile) { if (m_tile == tile) { return; } Tile *oldTile = m_tile; QuickTileMode oldTileMode = quickTileMode(); m_tile = tile; if (m_tile) { Q_ASSERT(!isDeleted()); m_tile->addWindow(this); } if (oldTile) { oldTile->removeWindow(this); } Q_EMIT tileChanged(tile); if (oldTileMode != quickTileMode()) { Q_EMIT quickTileModeChanged(); } } Tile *Window::tile() const { return m_tile; } Tile *Window::requestedTile() const { return m_requestedTile; } void Window::requestTile(Tile *tile) { // Forbid tiling unmanaged windows if (!isClient()) { return; } if (m_requestedTile == tile) { return; } if (tile && requestedMaximizeMode() != MaximizeRestore) { setMaximize(false, false); if (requestedMaximizeMode() != MaximizeRestore) { // window rules may enforce a different maximize mode, we can't do anything here return; } } if (tile && !m_requestedTile && !m_tile) { setGeometryRestore(quickTileGeometryRestore()); } m_requestedTile = tile; if (tile) { moveResize(tile->windowGeometry()); } else { QRectF geometry = moveResizeGeometry(); if (geometryRestore().isValid()) { geometry = geometryRestore(); } if (isInteractiveMove()) { const QPointF anchor = interactiveMoveResizeAnchor(); const QPointF offset = interactiveMoveOffset(); geometry.moveTopLeft(QPointF(anchor.x() - geometry.width() * offset.x(), anchor.y() - geometry.height() * offset.y())); } moveResize(geometry); } doSetQuickTileMode(); } void Window::doSetQuickTileMode() { } void Window::doSetHidden() { } void Window::doSetHiddenByShowDesktop() { } QRectF Window::moveToArea(const QRectF &geometry, const QRectF &oldArea, const QRectF &newArea) { QRectF ret = geometry; // move the window to have the same relative position to the center of the screen // (i.e. one near the middle of the right edge will also end up near the middle of the right edge) QPointF center = geometry.center() - oldArea.center(); center.setX(center.x() * newArea.width() / oldArea.width()); center.setY(center.y() * newArea.height() / oldArea.height()); center += newArea.center(); ret.moveCenter(center); // If the window was inside the old screen area, explicitly make sure its inside also the new screen area if (oldArea.contains(geometry)) { ret = keepInArea(ret, newArea); } return ret; } QRectF Window::ensureSpecialStateGeometry(const QRectF &geometry) { if (isRequestedFullScreen()) { return workspace()->clientArea(FullScreenArea, this, geometry.center()); } else if (requestedMaximizeMode() != MaximizeRestore) { const QRectF maximizeArea = workspace()->clientArea(MaximizeArea, this, geometry.center()); QRectF ret = geometry; if (requestedMaximizeMode() & MaximizeHorizontal) { ret.setX(maximizeArea.x()); ret.setWidth(maximizeArea.width()); } if (requestedMaximizeMode() & MaximizeVertical) { ret.setY(maximizeArea.y()); ret.setHeight(maximizeArea.height()); } return keepInArea(ret, maximizeArea, false); } else if (quickTileMode() != QuickTileMode(QuickTileFlag::None)) { return quickTileGeometry(quickTileMode(), geometry.center()); } else { return geometry; } } void Window::sendToOutput(Output *newOutput) { newOutput = rules()->checkOutput(newOutput); if (isActive()) { workspace()->setActiveOutput(newOutput); // might impact the layer of a fullscreen window const auto windows = workspace()->windows(); for (Window *other : windows) { if (other->isFullScreen() && other->output() == newOutput) { other->updateLayer(); } } } if (moveResizeOutput() == newOutput) { return; } const QRectF oldGeom = moveResizeGeometry(); const QRectF oldScreenArea = workspace()->clientArea(MaximizeArea, this, moveResizeOutput()); const QRectF screenArea = workspace()->clientArea(MaximizeArea, this, newOutput); if (requestedQuickTileMode() == QuickTileMode(QuickTileFlag::Custom)) { requestTile(nullptr); } else { Tile *newTile = workspace()->tileManager(newOutput)->quickTile(requestedQuickTileMode()); requestTile(newTile); } QRectF newGeom = moveToArea(oldGeom, oldScreenArea, screenArea); newGeom = ensureSpecialStateGeometry(newGeom); moveResize(newGeom); // move geometry restores to the new output as well setFullscreenGeometryRestore(moveToArea(m_fullscreenGeometryRestore, oldScreenArea, screenArea)); setGeometryRestore(moveToArea(m_maximizeGeometryRestore, oldScreenArea, screenArea)); auto tso = workspace()->ensureStackingOrder(transients()); for (auto it = tso.constBegin(), end = tso.constEnd(); it != end; ++it) { (*it)->sendToOutput(newOutput); } } void Window::checkWorkspacePosition(QRectF oldGeometry, const VirtualDesktop *oldDesktop) { if (isDeleted()) { qCWarning(KWIN_CORE) << "Window::checkWorkspacePosition: called for a closed window. Consider this a bug"; return; } if (isDock() || isDesktop() || !isPlaceable()) { return; } QRectF newGeom = moveResizeGeometry(); if (!oldGeometry.isValid()) { oldGeometry = newGeom; } VirtualDesktop *desktop = !isOnCurrentDesktop() ? desktops().constLast() : VirtualDesktopManager::self()->currentDesktop(); if (!oldDesktop) { oldDesktop = desktop; } // If the window was touching an edge before but not now move it so it is again. // Old and new maximums have different starting values so windows on the screen // edge will move when a new strut is placed on the edge. QRect oldScreenArea; QRect screenArea; if (workspace()->inRearrange()) { // check if the window is on an about to be destroyed output Output *newOutput = moveResizeOutput(); if (!workspace()->outputs().contains(newOutput)) { newOutput = workspace()->outputAt(newGeom.center()); } // we need to find the screen area as it was before the change oldScreenArea = workspace()->previousScreenSizes().value(moveResizeOutput()); if (oldScreenArea.isNull()) { oldScreenArea = newOutput->geometry(); } screenArea = newOutput->geometry(); newGeom.translate(screenArea.topLeft() - oldScreenArea.topLeft()); } else { oldScreenArea = workspace()->clientArea(ScreenArea, workspace()->outputAt(oldGeometry.center()), oldDesktop).toRect(); screenArea = workspace()->clientArea(ScreenArea, this, newGeom.center()).toRect(); } if (isRequestedFullScreen() || requestedMaximizeMode() != MaximizeRestore || quickTileMode() != QuickTileMode(QuickTileFlag::None)) { moveResize(ensureSpecialStateGeometry(newGeom)); setFullscreenGeometryRestore(moveToArea(m_fullscreenGeometryRestore, oldScreenArea, screenArea)); setGeometryRestore(moveToArea(m_maximizeGeometryRestore, oldScreenArea, screenArea)); return; } const QRect oldGeomTall = QRect(oldGeometry.x(), oldScreenArea.y(), oldGeometry.width(), oldScreenArea.height()); // Full screen height const QRect oldGeomWide = QRect(oldScreenArea.x(), oldGeometry.y(), oldScreenArea.width(), oldGeometry.height()); // Full screen width int oldTopMax = oldScreenArea.y(); int oldRightMax = oldScreenArea.x() + oldScreenArea.width(); int oldBottomMax = oldScreenArea.y() + oldScreenArea.height(); int oldLeftMax = oldScreenArea.x(); int topMax = screenArea.y(); int rightMax = screenArea.x() + screenArea.width(); int bottomMax = screenArea.y() + screenArea.height(); int leftMax = screenArea.x(); const QRect newGeomTall = QRect(newGeom.x(), screenArea.y(), newGeom.width(), screenArea.height()); // Full screen height const QRect newGeomWide = QRect(screenArea.x(), newGeom.y(), screenArea.width(), newGeom.height()); // Full screen width // Get the max strut point for each side where the window is (E.g. Highest point for // the bottom struts bounded by the window's left and right sides). // These 4 compute old bounds ... auto moveAreaFunc = workspace()->inRearrange() ? &Workspace::previousRestrictedMoveArea : //... the restricted areas changed &Workspace::restrictedMoveArea; //... when e.g. active desktop or screen changes for (const QRect &r : (workspace()->*moveAreaFunc)(oldDesktop, StrutAreaTop)) { QRect rect = r & oldGeomTall; if (!rect.isEmpty()) { oldTopMax = std::max(oldTopMax, rect.y() + rect.height()); } } for (const QRect &r : (workspace()->*moveAreaFunc)(oldDesktop, StrutAreaRight)) { QRect rect = r & oldGeomWide; if (!rect.isEmpty()) { oldRightMax = std::min(oldRightMax, rect.x()); } } for (const QRect &r : (workspace()->*moveAreaFunc)(oldDesktop, StrutAreaBottom)) { QRect rect = r & oldGeomTall; if (!rect.isEmpty()) { oldBottomMax = std::min(oldBottomMax, rect.y()); } } for (const QRect &r : (workspace()->*moveAreaFunc)(oldDesktop, StrutAreaLeft)) { QRect rect = r & oldGeomWide; if (!rect.isEmpty()) { oldLeftMax = std::max(oldLeftMax, rect.x() + rect.width()); } } // These 4 compute new bounds for (const QRect &r : workspace()->restrictedMoveArea(desktop, StrutAreaTop)) { QRect rect = r & newGeomTall; if (!rect.isEmpty()) { topMax = std::max(topMax, rect.y() + rect.height()); } } for (const QRect &r : workspace()->restrictedMoveArea(desktop, StrutAreaRight)) { QRect rect = r & newGeomWide; if (!rect.isEmpty()) { rightMax = std::min(rightMax, rect.x()); } } for (const QRect &r : workspace()->restrictedMoveArea(desktop, StrutAreaBottom)) { QRect rect = r & newGeomTall; if (!rect.isEmpty()) { bottomMax = std::min(bottomMax, rect.y()); } } for (const QRect &r : workspace()->restrictedMoveArea(desktop, StrutAreaLeft)) { QRect rect = r & newGeomWide; if (!rect.isEmpty()) { leftMax = std::max(leftMax, rect.x() + rect.width()); } } // Check if the sides were inside or touching but are no longer enum { Left = 0, Top, Right, Bottom, }; bool keep[4] = {false, false, false, false}; bool save[4] = {false, false, false, false}; if (oldGeometry.x() >= oldLeftMax) { save[Left] = newGeom.x() < leftMax; } if (oldGeometry.x() == oldLeftMax) { keep[Left] = newGeom.x() != leftMax; } if (oldGeometry.y() >= oldTopMax) { save[Top] = newGeom.y() < topMax; } if (oldGeometry.y() == oldTopMax) { keep[Top] = newGeom.y() != topMax; } if (oldGeometry.right() <= oldRightMax) { save[Right] = newGeom.right() > rightMax; } if (oldGeometry.right() == oldRightMax) { keep[Right] = newGeom.right() != rightMax; } if (oldGeometry.bottom() <= oldBottomMax) { save[Bottom] = newGeom.bottom() > bottomMax; } if (oldGeometry.bottom() == oldBottomMax) { keep[Bottom] = newGeom.bottom() != bottomMax; } // if randomly touches opposing edges, do not favor either if (keep[Left] && keep[Right]) { keep[Left] = keep[Right] = false; } if (keep[Top] && keep[Bottom]) { keep[Top] = keep[Bottom] = false; } if (save[Left] || keep[Left]) { newGeom.moveLeft(std::max(leftMax, screenArea.x())); } if (save[Top] || keep[Top]) { newGeom.moveTop(std::max(topMax, screenArea.y())); } if (save[Right] || keep[Right]) { newGeom.moveRight(std::min(rightMax, screenArea.right()) + 1); } if (save[Bottom] || keep[Bottom]) { newGeom.moveBottom(std::min(bottomMax, screenArea.bottom()) + 1); } if (oldGeometry.x() >= oldLeftMax && newGeom.x() < leftMax) { newGeom.setLeft(std::max(leftMax, screenArea.x())); } if (oldGeometry.y() >= oldTopMax && newGeom.y() < topMax) { newGeom.setTop(std::max(topMax, screenArea.y())); } checkOffscreenPosition(&newGeom, screenArea); // Obey size hints. TODO: We really should make sure it stays in the right place if (!isShade()) { newGeom.setSize(constrainFrameSize(newGeom.size())); } moveResize(m_rules.checkGeometry(newGeom)); } void Window::checkOffscreenPosition(QRectF *geom, const QRectF &screenArea) { if (geom->left() > screenArea.right()) { geom->moveLeft(screenArea.right() - screenArea.width() / 4); } else if (geom->right() < screenArea.left()) { geom->moveRight(screenArea.left() + screenArea.width() / 4); } if (geom->top() > screenArea.bottom()) { geom->moveTop(screenArea.bottom() - screenArea.height() / 4); } else if (geom->bottom() < screenArea.top()) { geom->moveBottom(screenArea.top() + screenArea.width() / 4); } } /** * Constrains the client size @p size according to a set of the window's size hints. * * Default implementation applies only minimum and maximum size constraints. */ QSizeF Window::constrainClientSize(const QSizeF &size, SizeMode mode) const { qreal width = size.width(); qreal height = size.height(); // When user is resizing the window, the move resize geometry may have negative width or // height. In which case, we need to set negative dimensions to reasonable values. if (width < 1) { width = 1; } if (height < 1) { height = 1; } const QSizeF minimumSize = minSize(); const QSizeF maximumSize = maxSize(); width = std::clamp(width, minimumSize.width(), maximumSize.width()); height = std::clamp(height, minimumSize.height(), maximumSize.height()); return QSizeF(width, height); } /** * Constrains the frame size @p size according to a set of the window's size hints. */ QSizeF Window::constrainFrameSize(const QSizeF &size, SizeMode mode) const { const QSizeF unconstrainedClientSize = frameSizeToClientSize(size); const QSizeF constrainedClientSize = constrainClientSize(unconstrainedClientSize, mode); return clientSizeToFrameSize(constrainedClientSize); } QRectF Window::fullscreenGeometryRestore() const { return m_fullscreenGeometryRestore; } void Window::setFullscreenGeometryRestore(const QRectF &geom) { if (m_fullscreenGeometryRestore != geom) { m_fullscreenGeometryRestore = geom; Q_EMIT fullscreenGeometryRestoreChanged(); } } /** * Returns @c true if the Window can be shown in full screen mode; otherwise @c false. * * Default implementation returns @c false. */ bool Window::isFullScreenable() const { return false; } /** * Returns @c true if the Window is currently being shown in full screen mode; otherwise @c false. * * A window in full screen mode occupies the entire screen with no window frame around it. * * Default implementation returns @c false. */ bool Window::isFullScreen() const { return false; } bool Window::isRequestedFullScreen() const { return isFullScreen(); } /** * Asks the Window to enter or leave full screen mode. * * Default implementation does nothing. * * @param set @c true if the Window has to be shown in full screen mode, otherwise @c false */ void Window::setFullScreen(bool set) { qCWarning(KWIN_CORE, "%s doesn't support setting fullscreen state", metaObject()->className()); } bool Window::wantsAdaptiveSync() const { return rules()->checkAdaptiveSync(isFullScreen()); } bool Window::wantsTearing(bool tearingRequested) const { return rules()->checkTearing(tearingRequested); } /** * Returns @c true if the Window can be minimized; otherwise @c false. * * Default implementation returns @c false. */ bool Window::isMinimizable() const { return false; } /** * Returns @c true if the Window can be maximized; otherwise @c false. * * Default implementation returns @c false. */ bool Window::isMaximizable() const { return false; } /** * Returns the currently applied maximize mode. * * Default implementation returns MaximizeRestore. */ MaximizeMode Window::maximizeMode() const { return MaximizeRestore; } /** * Returns the last requested maximize mode. * * On X11, this method always matches maximizeMode(). On Wayland, it is asynchronous. * * Default implementation matches maximizeMode(). */ MaximizeMode Window::requestedMaximizeMode() const { return maximizeMode(); } /** * Returns the geometry of the Window before it was maximized or quick tiled. */ QRectF Window::geometryRestore() const { return m_maximizeGeometryRestore; } /** * Sets the geometry of the Window before it was maximized or quick tiled to @p rect. */ void Window::setGeometryRestore(const QRectF &rect) { if (m_maximizeGeometryRestore != rect) { m_maximizeGeometryRestore = rect; Q_EMIT maximizeGeometryRestoreChanged(); } } void Window::invalidateDecoration() { } bool Window::noBorder() const { return true; } bool Window::userCanSetNoBorder() const { return false; } void Window::setNoBorder(bool set) { qCWarning(KWIN_CORE, "%s doesn't support setting decorations", metaObject()->className()); } void Window::checkNoBorder() { setNoBorder(false); } void Window::showOnScreenEdge() { qCWarning(KWIN_CORE, "%s doesn't support screen edge activation", metaObject()->className()); } bool Window::isPlaceable() const { return true; } void Window::cleanTabBox() { #if KWIN_BUILD_TABBOX TabBox::TabBox *tabBox = workspace()->tabbox(); if (tabBox && tabBox->isDisplayed() && tabBox->currentClient() == this) { tabBox->nextPrev(true); } #endif } bool Window::supportsWindowRules() const { return false; } void Window::removeRule(Rules *rule) { m_rules.remove(rule); } void Window::evaluateWindowRules() { setupWindowRules(); applyWindowRules(); } void Window::setupWindowRules() { disconnect(this, &Window::captionNormalChanged, this, &Window::evaluateWindowRules); m_rules = workspace()->rulebook()->find(this); // check only after getting the rules, because there may be a rule forcing window type } void Window::updateWindowRules(Rules::Types selection) { if (workspace()->rulebook()->areUpdatesDisabled()) { return; } m_rules.update(this, selection); } void Window::finishWindowRules() { disconnect(this, &Window::captionNormalChanged, this, &Window::evaluateWindowRules); updateWindowRules(Rules::All); m_rules = WindowRules(); } // Applies Force, ForceTemporarily and ApplyNow rules // Used e.g. after the rules have been modified using the kcm. void Window::applyWindowRules() { Q_ASSERT(!isDeleted()); // apply force rules // Placement - does need explicit update, just like some others below // Geometry : setGeometry() doesn't check rules auto client_rules = rules(); const QRectF oldGeometry = moveResizeGeometry(); const QRectF geometry = client_rules->checkGeometrySafe(oldGeometry); if (geometry != oldGeometry) { moveResize(geometry); } // MinSize, MaxSize handled by Geometry // IgnoreGeometry setDesktops(desktops()); sendToOutput(moveResizeOutput()); setOnActivities(activities()); // Type maximize(requestedMaximizeMode()); setMinimized(isMinimized()); setShade(shadeMode()); setOriginalSkipTaskbar(skipTaskbar()); setSkipPager(skipPager()); setSkipSwitcher(skipSwitcher()); setKeepAbove(keepAbove()); setKeepBelow(keepBelow()); setFullScreen(isRequestedFullScreen()); setNoBorder(noBorder()); updateColorScheme(); updateLayer(); // FSP // AcceptFocus : if (workspace()->mostRecentlyActivatedWindow() == this && !client_rules->checkAcceptFocus(true)) { workspace()->activateNextWindow(this); } // Autogrouping : Only checked on window manage // AutogroupInForeground : Only checked on window manage // AutogroupById : Only checked on window manage // StrictGeometry setShortcut(rules()->checkShortcut(shortcut().toString())); // see also X11Window::setActive() if (isActive()) { setOpacity(rules()->checkOpacityActive(qRound(opacity() * 100.0)) / 100.0); workspace()->disableGlobalShortcutsForClient(rules()->checkDisableGlobalShortcuts(false)); } else { setOpacity(rules()->checkOpacityInactive(qRound(opacity() * 100.0)) / 100.0); } setDesktopFileName(rules()->checkDesktopFile(desktopFileName())); } void Window::setLastUsageSerial(quint32 serial) { if (m_lastUsageSerial < serial) { m_lastUsageSerial = serial; } } quint32 Window::lastUsageSerial() const { return m_lastUsageSerial; } uint32_t Window::interactiveMoveResizeCount() const { return m_interactiveMoveResize.counter; } void Window::setLockScreenOverlay(bool allowed) { if (m_lockScreenOverlay == allowed) { return; } m_lockScreenOverlay = allowed; Q_EMIT lockScreenOverlayChanged(); } bool Window::isLockScreenOverlay() const { return m_lockScreenOverlay; } void Window::refOffscreenRendering() { m_offscreenRenderCount++; if (m_offscreenRenderCount == 1) { m_offscreenFramecallbackTimer.start(1'000'000 / output()->refreshRate()); Q_EMIT offscreenRenderingChanged(); } } void Window::unrefOffscreenRendering() { Q_ASSERT(m_offscreenRenderCount); m_offscreenRenderCount--; if (m_offscreenRenderCount == 0) { m_offscreenFramecallbackTimer.stop(); Q_EMIT offscreenRenderingChanged(); } } bool Window::isOffscreenRendering() const { return m_offscreenRenderCount > 0; } void Window::maybeSendFrameCallback() { if (m_surface && !m_windowItem->isVisible()) { const auto timestamp = std::chrono::duration_cast(std::chrono::steady_clock::now().time_since_epoch()).count(); m_surface->traverseTree([this, ×tamp](SurfaceInterface *surface) { surface->frameRendered(timestamp); const auto feedback = surface->takePresentationFeedback(nullptr); if (feedback) { feedback->presented(std::chrono::nanoseconds(1'000'000'000'000 / output()->refreshRate()), std::chrono::steady_clock::now().time_since_epoch(), PresentationMode::VSync); } }); // update refresh rate, it might have changed m_offscreenFramecallbackTimer.start(1'000'000 / output()->refreshRate()); } } bool Window::isShown() const { return !isDeleted() && !isHidden() && !isHiddenByShowDesktop() && !isMinimized(); } bool Window::isHidden() const { return m_hidden; } void Window::setHidden(bool hidden) { if (m_hidden == hidden) { return; } m_hidden = hidden; doSetHidden(); if (hidden) { workspace()->activateNextWindow(this); } Q_EMIT hiddenChanged(); } bool Window::isHiddenByShowDesktop() const { return m_hiddenByShowDesktop; } void Window::setHiddenByShowDesktop(bool hidden) { if (m_hiddenByShowDesktop != hidden) { m_hiddenByShowDesktop = hidden; doSetHiddenByShowDesktop(); Q_EMIT hiddenByShowDesktopChanged(); } } bool Window::isSuspended() const { return m_suspended; } void Window::setSuspended(bool suspended) { if (isDeleted()) { return; } if (m_suspended != suspended) { m_suspended = suspended; doSetSuspended(); } } void Window::doSetSuspended() { } void Window::doSetModal() { } qreal Window::preferredBufferScale() const { return m_preferredBufferScale; } void Window::setPreferredBufferScale(qreal scale) { if (m_preferredBufferScale != scale) { m_preferredBufferScale = scale; doSetPreferredBufferScale(); } } void Window::doSetPreferredBufferScale() { } void Window::updatePreferredBufferScale() { setPreferredBufferScale(m_moveResizeOutput->scale()); } OutputTransform Window::preferredBufferTransform() const { return m_preferredBufferTransform; } void Window::setPreferredBufferTransform(OutputTransform transform) { if (m_preferredBufferTransform != transform) { m_preferredBufferTransform = transform; doSetPreferredBufferTransform(); } } void Window::doSetPreferredBufferTransform() { } void Window::updatePreferredBufferTransform() { setPreferredBufferTransform(m_moveResizeOutput->transform()); } const ColorDescription &Window::preferredColorDescription() const { return m_preferredColorDescription; } void Window::setPreferredColorDescription(const ColorDescription &description) { if (m_preferredColorDescription != description) { m_preferredColorDescription = description; doSetPreferredColorDescription(); } } void Window::doSetPreferredColorDescription() { } void Window::updatePreferredColorDescription() { setPreferredColorDescription(m_moveResizeOutput->colorDescription()); } } // namespace KWin #include "moc_window.cpp"