/******************************************************************** KWin - the KDE window manager This file is part of the KDE project. Copyright (C) 2015 Martin Gräßlin Copyright (C) 2018 David Edmundson This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . *********************************************************************/ #include "shell_client.h" #include "composite.h" #include "cursor.h" #include "deleted.h" #include "placement.h" #include "screenedge.h" #include "screens.h" #ifdef KWIN_BUILD_TABBOX #include "tabbox.h" #endif #include "virtualdesktops.h" #include "wayland_server.h" #include "workspace.h" #include "decorations/decorationbridge.h" #include "decorations/decoratedclient.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include Q_DECLARE_METATYPE(NET::WindowType) using namespace KWayland::Server; namespace KWin { ShellClient::ShellClient(ShellSurfaceInterface *surface) : AbstractClient() , m_shellSurface(surface) , m_xdgShellSurface(nullptr) , m_xdgShellPopup(nullptr) , m_internal(surface->client() == waylandServer()->internalConnection()) { setSurface(surface->surface()); init(); m_isInitialized = true; } ShellClient::ShellClient(XdgShellSurfaceInterface *surface) : AbstractClient() , m_shellSurface(nullptr) , m_xdgShellSurface(surface) , m_xdgShellPopup(nullptr) , m_internal(surface->client() == waylandServer()->internalConnection()) { setSurface(surface->surface()); m_requestGeometryBlockCounter++; init(); connect(surface->surface(), &SurfaceInterface::committed, this, &ShellClient::finishInit); } ShellClient::ShellClient(XdgShellPopupInterface *surface) : AbstractClient() , m_shellSurface(nullptr) , m_xdgShellSurface(nullptr) , m_xdgShellPopup(surface) , m_internal(surface->client() == waylandServer()->internalConnection()) { setSurface(surface->surface()); m_requestGeometryBlockCounter++; init(); connect(surface->surface(), &SurfaceInterface::committed, this, &ShellClient::finishInit); } ShellClient::~ShellClient() = default; template void ShellClient::initSurface(T *shellSurface) { m_caption = shellSurface->title().simplified(); // delay till end of init QTimer::singleShot(0, this, &ShellClient::updateCaption); connect(shellSurface, &T::destroyed, this, &ShellClient::destroyClient); connect(shellSurface, &T::titleChanged, this, [this] (const QString &s) { const auto oldSuffix = m_captionSuffix; m_caption = s.simplified(); updateCaption(); if (m_captionSuffix == oldSuffix) { // don't emit caption change twice // it already got emitted by the changing suffix emit captionChanged(); } } ); connect(shellSurface, &T::moveRequested, this, [this] { // TODO: check the seat and serial performMouseCommand(Options::MouseMove, Cursor::pos()); } ); // determine the resource name, this is inspired from ICCCM 4.1.2.5 // the binary name of the invoked client QFileInfo info{shellSurface->client()->executablePath()}; QByteArray resourceName; if (info.exists()) { resourceName = info.fileName().toUtf8(); } setResourceClass(resourceName, shellSurface->windowClass()); setDesktopFileName(shellSurface->windowClass()); connect(shellSurface, &T::windowClassChanged, this, [this, resourceName] (const QByteArray &windowClass) { setResourceClass(resourceName, windowClass); if (m_isInitialized && supportsWindowRules()) { setupWindowRules(true); applyWindowRules(); } setDesktopFileName(windowClass); } ); connect(shellSurface, &T::resizeRequested, this, [this] (SeatInterface *seat, quint32 serial, Qt::Edges edges) { // TODO: check the seat and serial Q_UNUSED(seat) Q_UNUSED(serial) if (!isResizable() || isShade()) { return; } if (isMoveResize()) { finishMoveResize(false); } setMoveResizePointerButtonDown(true); setMoveOffset(Cursor::pos() - pos()); // map from global setInvertedMoveOffset(rect().bottomRight() - moveOffset()); setUnrestrictedMoveResize(false); auto toPosition = [edges] { Position pos = PositionCenter; if (edges.testFlag(Qt::TopEdge)) { pos = PositionTop; } else if (edges.testFlag(Qt::BottomEdge)) { pos = PositionBottom; } if (edges.testFlag(Qt::LeftEdge)) { pos = Position(pos | PositionLeft); } else if (edges.testFlag(Qt::RightEdge)) { pos = Position(pos | PositionRight); } return pos; }; setMoveResizePointerMode(toPosition()); if (!startMoveResize()) setMoveResizePointerButtonDown(false); updateCursor(); } ); connect(shellSurface, &T::maximizedChanged, this, [this] (bool maximized) { if (m_shellSurface && isFullScreen()) { // ignore for wl_shell - there it is mutual exclusive and messes with the geometry return; } // If the maximized state of the client hasn't been changed due to a window // rule or because the requested state is the same as the current, then the // compositor still has to send a configure event. RequestGeometryBlocker blocker(this); maximize(maximized ? MaximizeFull : MaximizeRestore); } ); // TODO: consider output! connect(shellSurface, &T::fullscreenChanged, this, &ShellClient::clientFullScreenChanged); connect(shellSurface, &T::transientForChanged, this, &ShellClient::setTransient); connect(this, &ShellClient::geometryChanged, this, &ShellClient::updateClientOutputs); connect(screens(), &Screens::changed, this, &ShellClient::updateClientOutputs); } void ShellClient::init() { connect(this, &ShellClient::desktopFileNameChanged, this, &ShellClient::updateIcon); createWindowId(); setupCompositing(); updateIcon(); SurfaceInterface *s = surface(); Q_ASSERT(s); if (s->buffer()) { setReadyForPainting(); if (shouldExposeToWindowManagement()) { setupWindowManagementInterface(); } m_unmapped = false; m_clientSize = s->size(); } else { ready_for_painting = false; } if (!m_internal) { doSetGeometry(QRect(QPoint(0, 0), m_clientSize)); } if (waylandServer()->inputMethodConnection() == s->client()) { m_windowType = NET::OnScreenDisplay; } connect(s, &SurfaceInterface::sizeChanged, this, [this] { m_clientSize = surface()->size(); doSetGeometry(QRect(pos(), m_clientSize + QSize(borderLeft() + borderRight(), borderTop() + borderBottom()))); } ); connect(s, &SurfaceInterface::unmapped, this, &ShellClient::unmap); connect(s, &SurfaceInterface::unbound, this, &ShellClient::destroyClient); connect(s, &SurfaceInterface::destroyed, this, &ShellClient::destroyClient); if (m_shellSurface) { initSurface(m_shellSurface); auto setPopup = [this] { // TODO: verify grab serial m_hasPopupGrab = m_shellSurface->isPopup(); }; connect(m_shellSurface, &ShellSurfaceInterface::popupChanged, this, setPopup); setPopup(); } else if (m_xdgShellSurface) { initSurface(m_xdgShellSurface); auto global = static_cast(m_xdgShellSurface->global()); connect(global, &XdgShellInterface::pingDelayed, this, [this](qint32 serial) { auto it = m_pingSerials.find(serial); if (it != m_pingSerials.end()) { qCDebug(KWIN_CORE) << "First ping timeout:" << caption(); setUnresponsive(true); } }); connect(m_xdgShellSurface, &XdgShellSurfaceInterface::configureAcknowledged, this, [this](int serial) { m_lastAckedConfigureRequest = serial; }); connect(global, &XdgShellInterface::pingTimeout, this, [this](qint32 serial) { auto it = m_pingSerials.find(serial); if (it != m_pingSerials.end()) { if (it.value() == PingReason::CloseWindow) { qCDebug(KWIN_CORE) << "Final ping timeout on a close attempt, asking to kill:" << caption(); //for internal windows, killing the window will delete this QPointer guard(this); killWindow(); if (!guard) { return; } } m_pingSerials.erase(it); } }); connect(global, &XdgShellInterface::pongReceived, this, [this](qint32 serial){ auto it = m_pingSerials.find(serial); if (it != m_pingSerials.end()) { setUnresponsive(false); m_pingSerials.erase(it); } }); connect(m_xdgShellSurface, &XdgShellSurfaceInterface::windowMenuRequested, this, [this] (SeatInterface *seat, quint32 serial, const QPoint &surfacePos) { // TODO: check serial on seat Q_UNUSED(seat) Q_UNUSED(serial) performMouseCommand(Options::MouseOperationsMenu, pos() + surfacePos); } ); connect(m_xdgShellSurface, &XdgShellSurfaceInterface::minimizeRequested, this, [this] { performMouseCommand(Options::MouseMinimize, Cursor::pos()); } ); auto configure = [this] { if (m_closing) { return; } if (m_requestGeometryBlockCounter != 0 || areGeometryUpdatesBlocked()) { return; } m_xdgShellSurface->configure(xdgSurfaceStates(), m_requestedClientSize); }; connect(this, &AbstractClient::activeChanged, this, configure); connect(this, &AbstractClient::clientStartUserMovedResized, this, configure); connect(this, &AbstractClient::clientFinishUserMovedResized, this, configure); } else if (m_xdgShellPopup) { connect(m_xdgShellPopup, &XdgShellPopupInterface::grabRequested, this, [this](SeatInterface *seat, quint32 serial) { Q_UNUSED(seat) Q_UNUSED(serial) //TODO - should check the parent had focus m_hasPopupGrab = true; }); connect(m_xdgShellPopup, &XdgShellPopupInterface::configureAcknowledged, this, [this](int serial) { m_lastAckedConfigureRequest = serial; }); connect(m_xdgShellPopup, &XdgShellPopupInterface::destroyed, this, &ShellClient::destroyClient); } // set initial desktop setDesktop(m_internal ? int(NET::OnAllDesktops) : VirtualDesktopManager::self()->current()); // setup shadow integration getShadow(); connect(s, &SurfaceInterface::shadowChanged, this, &Toplevel::getShadow); connect(waylandServer(), &WaylandServer::foreignTransientChanged, this, [this](KWayland::Server::SurfaceInterface *child) { if (child == surface()) { setTransient(); } }); setTransient(); AbstractClient::updateColorScheme(QString()); } void ShellClient::finishInit() { SurfaceInterface *s = surface(); disconnect(s, &SurfaceInterface::committed, this, &ShellClient::finishInit); updateWindowMargins(); bool needsPlacement = !isInitialPositionSet(); if (supportsWindowRules()) { setupWindowRules(false); const QRect originalGeometry = QRect(pos(), sizeForClientSize(clientSize())); const QRect ruledGeometry = rules()->checkGeometry(originalGeometry, true); if (originalGeometry != ruledGeometry) { setGeometry(ruledGeometry); } maximize(rules()->checkMaximize(maximizeMode(), true)); setDesktop(rules()->checkDesktop(desktop(), true)); setDesktopFileName(rules()->checkDesktopFile(desktopFileName(), true).toUtf8()); if (rules()->checkMinimize(isMinimized(), true)) { minimize(true); // No animation. } setSkipTaskbar(rules()->checkSkipTaskbar(skipTaskbar(), true)); setSkipPager(rules()->checkSkipPager(skipPager(), true)); setSkipSwitcher(rules()->checkSkipSwitcher(skipSwitcher(), true)); setKeepAbove(rules()->checkKeepAbove(keepAbove(), true)); setKeepBelow(rules()->checkKeepBelow(keepBelow(), true)); setShortcut(rules()->checkShortcut(shortcut().toString(), true)); updateColorScheme(); // Don't place the client if its position is set by a rule. if (rules()->checkPosition(invalidPoint, true) != invalidPoint) { needsPlacement = false; } // Don't place the client if the maximize state is set by a rule. if (requestedMaximizeMode() != MaximizeRestore) { needsPlacement = false; } discardTemporaryRules(); RuleBook::self()->discardUsed(this, false); // Remove Apply Now rules. updateWindowRules(Rules::All); } if (needsPlacement) { QRect area = workspace()->clientArea(PlacementArea, Screens::self()->current(), desktop()); placeIn(area); } m_requestGeometryBlockCounter--; if (m_requestGeometryBlockCounter == 0) { requestGeometry(m_blockedRequestGeometry); } m_isInitialized = true; } void ShellClient::destroyClient() { m_closing = true; #ifdef KWIN_BUILD_TABBOX TabBox::TabBox *tabBox = TabBox::TabBox::self(); if (tabBox && tabBox->isDisplayed() && tabBox->currentClient() == this) { tabBox->nextPrev(true); } #endif if (isMoveResize()) { leaveMoveResize(); } Deleted *del = nullptr; if (workspace()) { del = Deleted::create(this); } emit windowClosed(this, del); // Remove Force Temporarily rules. RuleBook::self()->discardUsed(this, true); destroyWindowManagementInterface(); destroyDecoration(); if (workspace()) { StackingUpdatesBlocker blocker(workspace()); if (transientFor()) { transientFor()->removeTransient(this); } for (auto it = transients().constBegin(); it != transients().constEnd();) { if ((*it)->transientFor() == this) { removeTransient(*it); it = transients().constBegin(); // restart, just in case something more has changed with the list } else { ++it; } } } waylandServer()->removeClient(this); if (del) { del->unrefWindow(); } m_shellSurface = nullptr; m_xdgShellSurface = nullptr; m_xdgShellPopup = nullptr; deleteClient(this); } void ShellClient::deleteClient(ShellClient *c) { delete c; } QSize ShellClient::toWindowGeometry(const QSize &size) const { QSize adjustedSize = size - QSize(borderLeft() + borderRight(), borderTop() + borderBottom()); // a client going fullscreen should have the window the contents size of the screen if (!isFullScreen() && requestedMaximizeMode() != MaximizeFull) { adjustedSize -= QSize(m_windowMargins.left() + m_windowMargins.right(), m_windowMargins.top() + m_windowMargins.bottom()); } return adjustedSize; } QStringList ShellClient::activities() const { // TODO: implement return QStringList(); } QPoint ShellClient::clientContentPos() const { return -1 * clientPos(); } QSize ShellClient::clientSize() const { return m_clientSize; } void ShellClient::debug(QDebug &stream) const { stream.nospace(); stream << "\'ShellClient:" << surface() << ";WMCLASS:" << resourceClass() << ":" << resourceName() << ";Caption:" << caption() << "\'"; } bool ShellClient::belongsToDesktop() const { const auto clients = waylandServer()->clients(); return std::any_of(clients.constBegin(), clients.constEnd(), [this](const ShellClient *client) { if (belongsToSameApplication(client, SameApplicationChecks())) { return client->isDesktop(); } return false; } ); } Layer ShellClient::layerForDock() const { if (m_plasmaShellSurface) { switch (m_plasmaShellSurface->panelBehavior()) { case PlasmaShellSurfaceInterface::PanelBehavior::WindowsCanCover: return NormalLayer; case PlasmaShellSurfaceInterface::PanelBehavior::AutoHide: return AboveLayer; case PlasmaShellSurfaceInterface::PanelBehavior::WindowsGoBelow: case PlasmaShellSurfaceInterface::PanelBehavior::AlwaysVisible: return DockLayer; default: Q_UNREACHABLE(); break; } } return AbstractClient::layerForDock(); } QRect ShellClient::transparentRect() const { // TODO: implement return QRect(); } NET::WindowType ShellClient::windowType(bool direct, int supported_types) const { // TODO: implement Q_UNUSED(direct) Q_UNUSED(supported_types) return m_windowType; } double ShellClient::opacity() const { return m_opacity; } void ShellClient::setOpacity(double opacity) { const qreal newOpacity = qBound(0.0, opacity, 1.0); if (newOpacity == m_opacity) { return; } const qreal oldOpacity = m_opacity; m_opacity = newOpacity; addRepaintFull(); emit opacityChanged(this, oldOpacity); } void ShellClient::addDamage(const QRegion &damage) { auto s = surface(); if (s->size().isValid()) { m_clientSize = s->size(); updateWindowMargins(); updatePendingGeometry(); } markAsMapped(); setDepth((s->buffer()->hasAlphaChannel() && !isDesktop()) ? 32 : 24); repaints_region += damage.translated(clientPos()); Toplevel::addDamage(damage); } void ShellClient::markAsMapped() { if (!m_unmapped) { return; } m_unmapped = false; if (!ready_for_painting) { setReadyForPainting(); } else { addRepaintFull(); emit windowShown(this); } if (shouldExposeToWindowManagement()) { setupWindowManagementInterface(); } updateShowOnScreenEdge(); } void ShellClient::createDecoration(const QRect &oldGeom) { KDecoration2::Decoration *decoration = Decoration::DecorationBridge::self()->createDecoration(this); if (decoration) { QMetaObject::invokeMethod(decoration, "update", Qt::QueuedConnection); connect(decoration, &KDecoration2::Decoration::shadowChanged, this, &Toplevel::getShadow); connect(decoration, &KDecoration2::Decoration::bordersChanged, this, [this]() { GeometryUpdatesBlocker blocker(this); RequestGeometryBlocker requestBlocker(this); QRect oldgeom = geometry(); if (!isShade()) checkWorkspacePosition(oldgeom); emit geometryShapeChanged(this, oldgeom); } ); } setDecoration(decoration); // TODO: ensure the new geometry still fits into the client area (e.g. maximized windows) doSetGeometry(QRect(oldGeom.topLeft(), m_clientSize + (decoration ? QSize(decoration->borderLeft() + decoration->borderRight(), decoration->borderBottom() + decoration->borderTop()) : QSize()))); emit geometryShapeChanged(this, oldGeom); } void ShellClient::updateDecoration(bool check_workspace_pos, bool force) { if (!force && ((!isDecorated() && noBorder()) || (isDecorated() && !noBorder()))) return; QRect oldgeom = geometry(); QRect oldClientGeom = oldgeom.adjusted(borderLeft(), borderTop(), -borderRight(), -borderBottom()); blockGeometryUpdates(true); if (force) destroyDecoration(); if (!noBorder()) { createDecoration(oldgeom); } else destroyDecoration(); if (m_serverDecoration && isDecorated()) { m_serverDecoration->setMode(KWayland::Server::ServerSideDecorationManagerInterface::Mode::Server); } if (m_xdgDecoration) { auto mode = isDecorated() || m_userNoBorder ? XdgDecorationInterface::Mode::ServerSide: XdgDecorationInterface::Mode::ClientSide; m_xdgDecoration->configure(mode); if (m_requestGeometryBlockCounter == 0) { m_xdgShellSurface->configure(xdgSurfaceStates(), m_requestedClientSize); } } getShadow(); if (check_workspace_pos) checkWorkspacePosition(oldgeom, -2, oldClientGeom); blockGeometryUpdates(false); } void ShellClient::setGeometry(int x, int y, int w, int h, ForceGeometry_t force) { const QRect newGeometry = rules()->checkGeometry(QRect(x, y, w, h)); if (areGeometryUpdatesBlocked()) { // when the GeometryUpdateBlocker exits the current geom is passed to setGeometry // thus we need to set it here. geom = newGeometry; if (pendingGeometryUpdate() == PendingGeometryForced) {} // maximum, nothing needed else if (force == ForceGeometrySet) setPendingGeometryUpdate(PendingGeometryForced); else setPendingGeometryUpdate(PendingGeometryNormal); return; } if (pendingGeometryUpdate() != PendingGeometryNone) { // reset geometry to the one before blocking, so that we can compare properly geom = geometryBeforeUpdateBlocking(); } const QSize requestedClientSize = newGeometry.size() - QSize(borderLeft() + borderRight(), borderTop() + borderBottom()); const QSize requestedWindowGeometrySize = toWindowGeometry(newGeometry.size()); if (requestedClientSize == m_clientSize && !isWaitingForMoveResizeSync() && (m_requestedClientSize.isEmpty() || requestedWindowGeometrySize == m_requestedClientSize)) { // size didn't change, and we don't need to explicitly request a new size doSetGeometry(newGeometry); updateMaximizeMode(m_requestedMaximizeMode); } else { // size did change, Client needs to provide a new buffer requestGeometry(newGeometry); } } void ShellClient::doSetGeometry(const QRect &rect) { if (geom == rect && pendingGeometryUpdate() == PendingGeometryNone) { return; } if (!m_unmapped) { addWorkspaceRepaint(visibleRect()); } geom = rect; updateWindowRules(Rules::Position | Rules::Size); if (m_unmapped && m_geomMaximizeRestore.isEmpty() && !geom.isEmpty()) { // use first valid geometry as restore geometry m_geomMaximizeRestore = geom; } if (!m_unmapped) { addWorkspaceRepaint(visibleRect()); } if (hasStrut()) { workspace()->updateClientArea(); } const auto old = geometryBeforeUpdateBlocking(); updateGeometryBeforeUpdateBlocking(); emit geometryShapeChanged(this, old); if (isResize()) { performMoveResize(); } } QByteArray ShellClient::windowRole() const { return QByteArray(); } bool ShellClient::belongsToSameApplication(const AbstractClient *other, SameApplicationChecks checks) const { if (checks.testFlag(SameApplicationCheck::AllowCrossProcesses)) { if (other->desktopFileName() == desktopFileName()) { return true; } } if (auto s = other->surface()) { return s->client() == surface()->client(); } return false; } void ShellClient::blockActivityUpdates(bool b) { Q_UNUSED(b) } void ShellClient::updateCaption() { const QString oldSuffix = m_captionSuffix; const auto shortcut = shortcutCaptionSuffix(); m_captionSuffix = shortcut; if ((!isSpecialWindow() || isToolbar()) && findClientWithSameCaption()) { int i = 2; do { m_captionSuffix = shortcut + QLatin1String(" <") + QString::number(i) + QLatin1Char('>'); i++; } while (findClientWithSameCaption()); } if (m_captionSuffix != oldSuffix) { emit captionChanged(); } } void ShellClient::closeWindow() { if (m_xdgShellSurface && isCloseable()) { m_xdgShellSurface->close(); const qint32 pingSerial = static_cast(m_xdgShellSurface->global())->ping(m_xdgShellSurface); m_pingSerials.insert(pingSerial, PingReason::CloseWindow); } } AbstractClient *ShellClient::findModal(bool allow_itself) { Q_UNUSED(allow_itself) return nullptr; } bool ShellClient::isCloseable() const { if (m_windowType == NET::Desktop || m_windowType == NET::Dock) { return false; } if (m_xdgShellSurface) { return true; } return false; } bool ShellClient::isFullScreen() const { return m_fullScreen; } bool ShellClient::isMaximizable() const { if (!isResizable()) { return false; } if (rules()->checkMaximize(MaximizeRestore) != MaximizeRestore || rules()->checkMaximize(MaximizeFull) != MaximizeFull) { return false; } return true; } bool ShellClient::isMinimizable() const { if (!rules()->checkMinimize(true)) { return false; } return (!m_plasmaShellSurface || m_plasmaShellSurface->role() == PlasmaShellSurfaceInterface::Role::Normal); } bool ShellClient::isMovable() const { if (rules()->checkPosition(invalidPoint) != invalidPoint) { return false; } if (m_plasmaShellSurface) { return m_plasmaShellSurface->role() == PlasmaShellSurfaceInterface::Role::Normal; } if (m_xdgShellPopup) { return false; } return true; } bool ShellClient::isMovableAcrossScreens() const { if (rules()->checkPosition(invalidPoint) != invalidPoint) { return false; } if (m_plasmaShellSurface) { return m_plasmaShellSurface->role() == PlasmaShellSurfaceInterface::Role::Normal; } if (m_xdgShellPopup) { return false; } return true; } bool ShellClient::isResizable() const { if (rules()->checkSize(QSize()).isValid()) { return false; } if (m_plasmaShellSurface) { return m_plasmaShellSurface->role() == PlasmaShellSurfaceInterface::Role::Normal; } if (m_xdgShellPopup) { return false; } return true; } bool ShellClient::isShown(bool shaded_is_shown) const { Q_UNUSED(shaded_is_shown) return !m_closing && !m_unmapped && !isMinimized() && !m_hidden; } void ShellClient::hideClient(bool hide) { if (m_hidden == hide) { return; } m_hidden = hide; if (hide) { addWorkspaceRepaint(visibleRect()); workspace()->clientHidden(this); emit windowHidden(this); } else { emit windowShown(this); } } static bool changeMaximizeRecursion = false; void ShellClient::changeMaximize(bool horizontal, bool vertical, bool adjust) { if (changeMaximizeRecursion) { return; } if (!isResizable()) { return; } const QRect clientArea = isElectricBorderMaximizing() ? workspace()->clientArea(MaximizeArea, Cursor::pos(), desktop()) : workspace()->clientArea(MaximizeArea, this); const MaximizeMode oldMode = m_requestedMaximizeMode; const QRect oldGeometry = geometry(); // 'adjust == true' means to update the size only, e.g. after changing workspace size if (!adjust) { if (vertical) m_requestedMaximizeMode = MaximizeMode(m_requestedMaximizeMode ^ MaximizeVertical); if (horizontal) m_requestedMaximizeMode = MaximizeMode(m_requestedMaximizeMode ^ MaximizeHorizontal); } m_requestedMaximizeMode = rules()->checkMaximize(m_requestedMaximizeMode); if (!adjust && m_requestedMaximizeMode == oldMode) { return; } StackingUpdatesBlocker blocker(workspace()); RequestGeometryBlocker geometryBlocker(this); // call into decoration update borders if (isDecorated() && decoration()->client() && !(options->borderlessMaximizedWindows() && m_requestedMaximizeMode == KWin::MaximizeFull)) { changeMaximizeRecursion = true; const auto c = decoration()->client().data(); if ((m_requestedMaximizeMode & MaximizeVertical) != (oldMode & MaximizeVertical)) { emit c->maximizedVerticallyChanged(m_requestedMaximizeMode & MaximizeVertical); } if ((m_requestedMaximizeMode & MaximizeHorizontal) != (oldMode & MaximizeHorizontal)) { emit c->maximizedHorizontallyChanged(m_requestedMaximizeMode & MaximizeHorizontal); } if ((m_requestedMaximizeMode == MaximizeFull) != (oldMode == MaximizeFull)) { emit c->maximizedChanged(m_requestedMaximizeMode & MaximizeFull); } changeMaximizeRecursion = false; } if (options->borderlessMaximizedWindows()) { // triggers a maximize change. // The next setNoBorder interation will exit since there's no change but the first recursion pullutes the restore geometry changeMaximizeRecursion = true; setNoBorder(rules()->checkNoBorder(m_requestedMaximizeMode == MaximizeFull)); changeMaximizeRecursion = false; } // Conditional quick tiling exit points const auto oldQuickTileMode = quickTileMode(); if (quickTileMode() != QuickTileMode(QuickTileFlag::None)) { if (oldMode == MaximizeFull && !clientArea.contains(m_geomMaximizeRestore.center())) { // Not restoring on the same screen // TODO: The following doesn't work for some reason //quick_tile_mode = QuickTileNone; // And exit quick tile mode manually } else if ((oldMode == MaximizeVertical && m_requestedMaximizeMode == MaximizeRestore) || (oldMode == MaximizeFull && m_requestedMaximizeMode == MaximizeHorizontal)) { // Modifying geometry of a tiled window updateQuickTileMode(QuickTileFlag::None); // Exit quick tile mode without restoring geometry } } if (m_requestedMaximizeMode == MaximizeFull) { m_geomMaximizeRestore = oldGeometry; // TODO: Client has more checks if (options->electricBorderMaximize()) { updateQuickTileMode(QuickTileFlag::Maximize); } else { updateQuickTileMode(QuickTileFlag::None); } if (quickTileMode() != oldQuickTileMode) { emit quickTileModeChanged(); } setGeometry(workspace()->clientArea(MaximizeArea, this)); workspace()->raiseClient(this); } else { if (m_requestedMaximizeMode == MaximizeRestore) { updateQuickTileMode(QuickTileFlag::None); } if (quickTileMode() != oldQuickTileMode) { emit quickTileModeChanged(); } if (m_geomMaximizeRestore.isValid()) { setGeometry(m_geomMaximizeRestore); } else { setGeometry(workspace()->clientArea(PlacementArea, this)); } } } MaximizeMode ShellClient::maximizeMode() const { return m_maximizeMode; } MaximizeMode ShellClient::requestedMaximizeMode() const { return m_requestedMaximizeMode; } bool ShellClient::noBorder() const { if (m_serverDecoration) { if (m_serverDecoration->mode() == ServerSideDecorationManagerInterface::Mode::Server) { return m_userNoBorder || isFullScreen(); } } if (m_xdgDecoration && m_xdgDecoration->requestedMode() != XdgDecorationInterface::Mode::ClientSide) { return m_userNoBorder || isFullScreen(); } return true; } bool ShellClient::isFullScreenable() const { if (!rules()->checkFullScreen(true)) { return false; } return !isSpecialWindow(); } void ShellClient::setFullScreen(bool set, bool user) { set = rules()->checkFullScreen(set); const bool wasFullscreen = isFullScreen(); if (wasFullscreen == set) { return; } if (isSpecialWindow()) { return; } if (user && !userCanSetFullScreen()) { return; } if (wasFullscreen) { workspace()->updateFocusMousePosition(Cursor::pos()); // may cause leave event } else { // in shell surface, maximise mode and fullscreen are exclusive // fullscreen->toplevel should restore the state we had before maximising if (m_shellSurface && m_maximizeMode == MaximizeMode::MaximizeFull) { m_geomFsRestore = m_geomMaximizeRestore; } else { m_geomFsRestore = geometry(); } } m_fullScreen = set; if (set) { untab(); workspace()->raiseClient(this); } RequestGeometryBlocker requestBlocker(this); StackingUpdatesBlocker blocker1(workspace()); GeometryUpdatesBlocker blocker2(this); workspace()->updateClientLayer(this); // active fullscreens get different layer updateDecoration(false, false); if (set) { setGeometry(workspace()->clientArea(FullScreenArea, this)); } else { if (m_geomFsRestore.isValid()) { int currentScreen = screen(); setGeometry(QRect(m_geomFsRestore.topLeft(), adjustedSize(m_geomFsRestore.size()))); if( currentScreen != screen()) workspace()->sendClientToScreen( this, currentScreen ); } else { // this can happen when the window was first shown already fullscreen, // so let the client set the size by itself setGeometry(QRect(workspace()->clientArea(PlacementArea, this).topLeft(), QSize(0, 0))); } } updateWindowRules(Rules::Fullscreen|Rules::Position|Rules::Size); emit fullScreenChanged(); } void ShellClient::setNoBorder(bool set) { if (!userCanSetNoBorder()) { return; } set = rules()->checkNoBorder(set); if (m_userNoBorder == set) { return; } m_userNoBorder = set; updateDecoration(true, false); updateWindowRules(Rules::NoBorder); } void ShellClient::setOnAllActivities(bool set) { Q_UNUSED(set) } void ShellClient::takeFocus() { if (rules()->checkAcceptFocus(wantsInput())) { if (m_xdgShellSurface) { const qint32 pingSerial = static_cast(m_xdgShellSurface->global())->ping(m_xdgShellSurface); m_pingSerials.insert(pingSerial, PingReason::FocusWindow); } setActive(true); } if (!keepAbove() && !isOnScreenDisplay() && !belongsToDesktop()) { workspace()->setShowingDesktop(false); } } void ShellClient::doSetActive() { if (!isActive()) { return; } StackingUpdatesBlocker blocker(workspace()); workspace()->focusToNull(); } bool ShellClient::userCanSetFullScreen() const { if (m_xdgShellSurface) { return true; } return false; } bool ShellClient::userCanSetNoBorder() const { if (m_serverDecoration && m_serverDecoration->mode() == ServerSideDecorationManagerInterface::Mode::Server) { return !isFullScreen() && !isShade() && !tabGroup(); } if (m_xdgDecoration && m_xdgDecoration->requestedMode() != XdgDecorationInterface::Mode::ClientSide) { return !isFullScreen() && !isShade() && !tabGroup(); } return false; } bool ShellClient::wantsInput() const { return rules()->checkAcceptFocus(acceptsFocus()); } bool ShellClient::acceptsFocus() const { if (waylandServer()->inputMethodConnection() == surface()->client()) { return false; } if (m_plasmaShellSurface) { if (m_plasmaShellSurface->role() == PlasmaShellSurfaceInterface::Role::OnScreenDisplay || m_plasmaShellSurface->role() == PlasmaShellSurfaceInterface::Role::ToolTip || m_plasmaShellSurface->role() == PlasmaShellSurfaceInterface::Role::Notification || m_plasmaShellSurface->role() == PlasmaShellSurfaceInterface::Role::CriticalNotification) { return false; } } if (m_closing) { // a closing window does not accept focus return false; } if (m_unmapped) { // an unmapped window does not accept focus return false; } if (m_shellSurface) { if (m_shellSurface->isPopup()) { return false; } return m_shellSurface->acceptsKeyboardFocus(); } if (m_xdgShellSurface) { // TODO: proper return true; } return false; } void ShellClient::createWindowId() { if (!m_internal) { m_windowId = waylandServer()->createWindowId(surface()); } } pid_t ShellClient::pid() const { return surface()->client()->processId(); } bool ShellClient::isLockScreen() const { return surface()->client() == waylandServer()->screenLockerClientConnection(); } bool ShellClient::isInputMethod() const { return surface()->client() == waylandServer()->inputMethodConnection(); } bool ShellClient::requestGeometry(const QRect &rect) { if (m_requestGeometryBlockCounter != 0) { m_blockedRequestGeometry = rect; return false; } QSize size; if (rect.isValid()) { size = toWindowGeometry(rect.size()); } else { size = QSize(0, 0); } m_requestedClientSize = size; quint64 serialId = 0; if (m_shellSurface && !size.isEmpty()) { m_shellSurface->requestSize(size); } if (m_xdgShellSurface) { serialId = m_xdgShellSurface->configure(xdgSurfaceStates(), size); } if (m_xdgShellPopup) { auto parent = transientFor(); if (parent) { const QPoint globalClientContentPos = parent->geometry().topLeft() + parent->clientPos(); const QPoint relativeOffset = rect.topLeft() - globalClientContentPos; serialId = m_xdgShellPopup->configure(QRect(relativeOffset, size)); } } if (rect.isValid()) { //if there's no requested size, then there's implicity no positional information worth using PendingConfigureRequest configureRequest; configureRequest.serialId = serialId; configureRequest.positionAfterResize = rect.topLeft(); configureRequest.maximizeMode = m_requestedMaximizeMode; m_pendingConfigureRequests.append(configureRequest); } m_blockedRequestGeometry = QRect(); return true; } void ShellClient::updatePendingGeometry() { QPoint position = pos(); MaximizeMode maximizeMode = m_maximizeMode; for (auto it = m_pendingConfigureRequests.begin(); it != m_pendingConfigureRequests.end(); it++) { if (it->serialId > m_lastAckedConfigureRequest) { //this serial is not acked yet, therefore we know all future serials are not break; } if (it->serialId == m_lastAckedConfigureRequest) { if (position != it->positionAfterResize) { addLayerRepaint(geometry()); } position = it->positionAfterResize; maximizeMode = it->maximizeMode; m_pendingConfigureRequests.erase(m_pendingConfigureRequests.begin(), ++it); break; } //else serialId < m_lastAckedConfigureRequest and the state is now irrelevant and can be ignored } doSetGeometry(QRect(position, m_clientSize + QSize(borderLeft() + borderRight(), borderTop() + borderBottom()))); updateMaximizeMode(maximizeMode); } void ShellClient::clientFullScreenChanged(bool fullScreen) { setFullScreen(fullScreen, false); } void ShellClient::resizeWithChecks(int w, int h, ForceGeometry_t force) { Q_UNUSED(force) QRect area = workspace()->clientArea(WorkArea, this); // don't allow growing larger than workarea if (w > area.width()) { w = area.width(); } if (h > area.height()) { h = area.height(); } if (m_shellSurface) { m_shellSurface->requestSize(QSize(w, h)); } if (m_xdgShellSurface) { m_xdgShellSurface->configure(xdgSurfaceStates(), QSize(w, h)); } } void ShellClient::unmap() { m_unmapped = true; if (isMoveResize()) { leaveMoveResize(); } m_requestedClientSize = QSize(0, 0); destroyWindowManagementInterface(); if (Workspace::self()) { addWorkspaceRepaint(visibleRect()); workspace()->clientHidden(this); } emit windowHidden(this); } void ShellClient::installPlasmaShellSurface(PlasmaShellSurfaceInterface *surface) { m_plasmaShellSurface = surface; auto updatePosition = [this, surface] { QRect rect = QRect(surface->position(), m_clientSize + QSize(borderLeft() + borderRight(), borderTop() + borderBottom())); // Shell surfaces of internal windows are sometimes desync to current value. // Make sure to not set window geometry of internal windows to invalid values (bug 386304). // This is a workaround. if (!m_internal || rect.isValid()) { doSetGeometry(rect); } }; auto updateRole = [this, surface] { NET::WindowType type = NET::Unknown; switch (surface->role()) { case PlasmaShellSurfaceInterface::Role::Desktop: type = NET::Desktop; break; case PlasmaShellSurfaceInterface::Role::Panel: type = NET::Dock; break; case PlasmaShellSurfaceInterface::Role::OnScreenDisplay: type = NET::OnScreenDisplay; break; case PlasmaShellSurfaceInterface::Role::Notification: type = NET::Notification; break; case PlasmaShellSurfaceInterface::Role::ToolTip: type = NET::Tooltip; break; case PlasmaShellSurfaceInterface::Role::CriticalNotification: type = NET::CriticalNotification; break; case PlasmaShellSurfaceInterface::Role::Normal: default: type = NET::Normal; break; } if (type != m_windowType) { m_windowType = type; if (m_windowType == NET::Desktop || type == NET::Dock || type == NET::OnScreenDisplay || type == NET::Notification || type == NET::Tooltip || type == NET::CriticalNotification) { setOnAllDesktops(true); } workspace()->updateClientArea(); } }; connect(surface, &PlasmaShellSurfaceInterface::positionChanged, this, updatePosition); connect(surface, &PlasmaShellSurfaceInterface::roleChanged, this, updateRole); connect(surface, &PlasmaShellSurfaceInterface::panelBehaviorChanged, this, [this] { updateShowOnScreenEdge(); workspace()->updateClientArea(); } ); connect(surface, &PlasmaShellSurfaceInterface::panelAutoHideHideRequested, this, [this] { hideClient(true); m_plasmaShellSurface->hideAutoHidingPanel(); updateShowOnScreenEdge(); } ); connect(surface, &PlasmaShellSurfaceInterface::panelAutoHideShowRequested, this, [this] { hideClient(false); ScreenEdges::self()->reserve(this, ElectricNone); m_plasmaShellSurface->showAutoHidingPanel(); } ); updatePosition(); updateRole(); updateShowOnScreenEdge(); connect(this, &ShellClient::geometryChanged, this, &ShellClient::updateShowOnScreenEdge); setSkipTaskbar(surface->skipTaskbar()); connect(surface, &PlasmaShellSurfaceInterface::skipTaskbarChanged, this, [this] { setSkipTaskbar(m_plasmaShellSurface->skipTaskbar()); }); setSkipSwitcher(surface->skipSwitcher()); connect(surface, &PlasmaShellSurfaceInterface::skipSwitcherChanged, this, [this] { setSkipSwitcher(m_plasmaShellSurface->skipSwitcher()); }); } void ShellClient::updateShowOnScreenEdge() { if (!ScreenEdges::self()) { return; } if (m_unmapped || !m_plasmaShellSurface || m_plasmaShellSurface->role() != PlasmaShellSurfaceInterface::Role::Panel) { ScreenEdges::self()->reserve(this, ElectricNone); return; } if ((m_plasmaShellSurface->panelBehavior() == PlasmaShellSurfaceInterface::PanelBehavior::AutoHide && m_hidden) || m_plasmaShellSurface->panelBehavior() == PlasmaShellSurfaceInterface::PanelBehavior::WindowsCanCover) { // screen edge API requires an edge, thus we need to figure out which edge the window borders const QRect clientGeometry = geometry(); Qt::Edges edges; for (int i = 0; i < screens()->count(); i++) { const QRect screenGeometry = screens()->geometry(i); if (screenGeometry.left() == clientGeometry.left()) { edges |= Qt::LeftEdge; } if (screenGeometry.right() == clientGeometry.right()) { edges |= Qt::RightEdge; } if (screenGeometry.top() == clientGeometry.top()) { edges |= Qt::TopEdge; } if (screenGeometry.bottom() == clientGeometry.bottom()) { edges |= Qt::BottomEdge; } } // a panel might border multiple screen edges. E.g. a horizontal panel at the bottom will // also border the left and right edge // let's remove such cases if (edges.testFlag(Qt::LeftEdge) && edges.testFlag(Qt::RightEdge)) { edges = edges & (~(Qt::LeftEdge | Qt::RightEdge)); } if (edges.testFlag(Qt::TopEdge) && edges.testFlag(Qt::BottomEdge)) { edges = edges & (~(Qt::TopEdge | Qt::BottomEdge)); } // it's still possible that a panel borders two edges, e.g. bottom and left // in that case the one which is sharing more with the edge wins auto check = [clientGeometry](Qt::Edges edges, Qt::Edge horiz, Qt::Edge vert) { if (edges.testFlag(horiz) && edges.testFlag(vert)) { if (clientGeometry.width() >= clientGeometry.height()) { return edges & ~horiz; } else { return edges & ~vert; } } return edges; }; edges = check(edges, Qt::LeftEdge, Qt::TopEdge); edges = check(edges, Qt::LeftEdge, Qt::BottomEdge); edges = check(edges, Qt::RightEdge, Qt::TopEdge); edges = check(edges, Qt::RightEdge, Qt::BottomEdge); ElectricBorder border = ElectricNone; if (edges.testFlag(Qt::LeftEdge)) { border = ElectricLeft; } if (edges.testFlag(Qt::RightEdge)) { border = ElectricRight; } if (edges.testFlag(Qt::TopEdge)) { border = ElectricTop; } if (edges.testFlag(Qt::BottomEdge)) { border = ElectricBottom; } ScreenEdges::self()->reserve(this, border); } else { ScreenEdges::self()->reserve(this, ElectricNone); } } bool ShellClient::isInitialPositionSet() const { if (m_plasmaShellSurface) { return m_plasmaShellSurface->isPositionSet(); } return false; } void ShellClient::installAppMenu(AppMenuInterface *menu) { m_appMenuInterface = menu; auto updateMenu = [this](AppMenuInterface::InterfaceAddress address) { updateApplicationMenuServiceName(address.serviceName); updateApplicationMenuObjectPath(address.objectPath); }; connect(m_appMenuInterface, &AppMenuInterface::addressChanged, this, [=](AppMenuInterface::InterfaceAddress address) { updateMenu(address); }); updateMenu(menu->address()); } void ShellClient::installPalette(ServerSideDecorationPaletteInterface *palette) { m_paletteInterface = palette; auto updatePalette = [this](const QString &palette) { AbstractClient::updateColorScheme(rules()->checkDecoColor(palette)); }; connect(m_paletteInterface, &ServerSideDecorationPaletteInterface::paletteChanged, this, [=](const QString &palette) { updatePalette(palette); }); connect(m_paletteInterface, &QObject::destroyed, this, [=]() { updatePalette(QString()); }); updatePalette(palette->palette()); } void ShellClient::updateColorScheme() { if (m_paletteInterface) { AbstractClient::updateColorScheme(rules()->checkDecoColor(m_paletteInterface->palette())); } else { AbstractClient::updateColorScheme(rules()->checkDecoColor(QString())); } } void ShellClient::updateMaximizeMode(MaximizeMode maximizeMode) { if (maximizeMode == m_maximizeMode) { return; } m_maximizeMode = maximizeMode; updateWindowRules(Rules::MaximizeHoriz | Rules::MaximizeVert | Rules::Position | Rules::Size); emit clientMaximizedStateChanged(this, m_maximizeMode); emit clientMaximizedStateChanged(this, m_maximizeMode & MaximizeHorizontal, m_maximizeMode & MaximizeVertical); } bool ShellClient::hasStrut() const { if (!isShown(true)) { return false; } if (!m_plasmaShellSurface) { return false; } if (m_plasmaShellSurface->role() != PlasmaShellSurfaceInterface::Role::Panel) { return false; } return m_plasmaShellSurface->panelBehavior() == PlasmaShellSurfaceInterface::PanelBehavior::AlwaysVisible; } void ShellClient::updateIcon() { const QString waylandIconName = QStringLiteral("wayland"); const QString dfIconName = iconFromDesktopFile(); const QString iconName = dfIconName.isEmpty() ? waylandIconName : dfIconName; if (iconName == icon().name()) { return; } setIcon(QIcon::fromTheme(iconName)); } bool ShellClient::isTransient() const { return m_transient; } void ShellClient::setTransient() { SurfaceInterface *s = nullptr; if (m_shellSurface) { s = m_shellSurface->transientFor().data(); } if (m_xdgShellSurface) { if (auto transient = m_xdgShellSurface->transientFor().data()) { s = transient->surface(); } } if (m_xdgShellPopup) { s = m_xdgShellPopup->transientFor().data(); } if (!s) { s = waylandServer()->findForeignTransientForSurface(surface()); } auto t = waylandServer()->findClient(s); if (t != transientFor()) { // remove from main client if (transientFor()) transientFor()->removeTransient(this); setTransientFor(t); if (t) { t->addTransient(this); } } m_transient = (s != nullptr); } bool ShellClient::hasTransientPlacementHint() const { return isTransient() && transientFor() != nullptr && (m_shellSurface || m_xdgShellPopup); } QRect ShellClient::transientPlacement(const QRect &bounds) const { QRect anchorRect; Qt::Edges anchorEdge; Qt::Edges gravity; QPoint offset; PositionerConstraints constraintAdjustments; QSize size = geometry().size(); const QPoint parentClientPos = transientFor()->pos() + transientFor()->clientPos(); QRect popupPosition; // returns if a target is within the supplied bounds, optional edges argument states which side to check auto inBounds = [bounds](const QRect &target, Qt::Edges edges = Qt::LeftEdge | Qt::RightEdge | Qt::TopEdge | Qt::BottomEdge) -> bool { if (edges & Qt::LeftEdge && target.left() < bounds.left()) { return false; } if (edges & Qt::TopEdge && target.top() < bounds.top()) { return false; } if (edges & Qt::RightEdge && target.right() > bounds.right()) { //normal QRect::right issue cancels out return false; } if (edges & Qt::BottomEdge && target.bottom() > bounds.bottom()) { return false; } return true; }; if (m_shellSurface) { anchorRect = QRect(m_shellSurface->transientOffset(), QSize(1,1)); anchorEdge = Qt::TopEdge | Qt::LeftEdge; gravity = Qt::BottomEdge | Qt::RightEdge; //our single point represents the top left of the popup constraintAdjustments = (PositionerConstraint::SlideX | PositionerConstraint::SlideY); } else if (m_xdgShellPopup) { anchorRect = m_xdgShellPopup->anchorRect(); anchorEdge = m_xdgShellPopup->anchorEdge(); gravity = m_xdgShellPopup->gravity(); offset = m_xdgShellPopup->anchorOffset(); constraintAdjustments = m_xdgShellPopup->constraintAdjustments(); if (!size.isValid()) { size = m_xdgShellPopup->initialSize(); } } else { Q_UNREACHABLE(); } //initial position popupPosition = QRect(popupOffset(anchorRect, anchorEdge, gravity, size) + offset + parentClientPos, size); //if that fits, we don't need to do anything if (inBounds(popupPosition)) { return popupPosition; } //otherwise apply constraint adjustment per axis in order XDG Shell Popup states if (constraintAdjustments & PositionerConstraint::FlipX) { if (!inBounds(popupPosition, Qt::LeftEdge | Qt::RightEdge)) { //flip both edges (if either bit is set, XOR both) auto flippedAnchorEdge = anchorEdge; if (flippedAnchorEdge & (Qt::LeftEdge | Qt::RightEdge)) { flippedAnchorEdge ^= (Qt::LeftEdge | Qt::RightEdge); } auto flippedGravity = gravity; if (flippedGravity & (Qt::LeftEdge | Qt::RightEdge)) { flippedGravity ^= (Qt::LeftEdge | Qt::RightEdge); } auto flippedPopupPosition = QRect(popupOffset(anchorRect, flippedAnchorEdge, flippedGravity, size) + offset + parentClientPos, size); //if it still doesn't fit we should continue with the unflipped version if (inBounds(flippedPopupPosition, Qt::LeftEdge | Qt::RightEdge)) { popupPosition.moveLeft(flippedPopupPosition.x()); } } } if (constraintAdjustments & PositionerConstraint::SlideX) { if (!inBounds(popupPosition, Qt::LeftEdge)) { popupPosition.moveLeft(bounds.x()); } if (!inBounds(popupPosition, Qt::RightEdge)) { // moveRight suffers from the classic QRect off by one issue popupPosition.moveLeft(bounds.x() + bounds.width() - size.width()); } } if (constraintAdjustments & PositionerConstraint::ResizeX) { //TODO //but we need to sort out when this is run as resize should only happen before first configure } if (constraintAdjustments & PositionerConstraint::FlipY) { if (!inBounds(popupPosition, Qt::TopEdge | Qt::BottomEdge)) { //flip both edges (if either bit is set, XOR both) auto flippedAnchorEdge = anchorEdge; if (flippedAnchorEdge & (Qt::TopEdge | Qt::BottomEdge)) { flippedAnchorEdge ^= (Qt::TopEdge | Qt::BottomEdge); } auto flippedGravity = gravity; if (flippedGravity & (Qt::TopEdge | Qt::BottomEdge)) { flippedGravity ^= (Qt::TopEdge | Qt::BottomEdge); } auto flippedPopupPosition = QRect(popupOffset(anchorRect, flippedAnchorEdge, flippedGravity, size) + offset + parentClientPos, size); //if it still doesn't fit we should continue with the unflipped version if (inBounds(flippedPopupPosition, Qt::TopEdge | Qt::BottomEdge)) { popupPosition.moveTop(flippedPopupPosition.y()); } } } if (constraintAdjustments & PositionerConstraint::SlideY) { if (!inBounds(popupPosition, Qt::TopEdge)) { popupPosition.moveTop(bounds.y()); } if (!inBounds(popupPosition, Qt::BottomEdge)) { popupPosition.moveTop(bounds.y() + bounds.height() - size.height()); } } if (constraintAdjustments & PositionerConstraint::ResizeY) { //TODO } return popupPosition; } QPoint ShellClient::popupOffset(const QRect &anchorRect, const Qt::Edges anchorEdge, const Qt::Edges gravity, const QSize popupSize) const { QPoint anchorPoint; switch (anchorEdge & (Qt::LeftEdge | Qt::RightEdge)) { case Qt::LeftEdge: anchorPoint.setX(anchorRect.x()); break; case Qt::RightEdge: anchorPoint.setX(anchorRect.x() + anchorRect.width()); break; default: anchorPoint.setX(qRound(anchorRect.x() + anchorRect.width() / 2.0)); } switch (anchorEdge & (Qt::TopEdge | Qt::BottomEdge)) { case Qt::TopEdge: anchorPoint.setY(anchorRect.y()); break; case Qt::BottomEdge: anchorPoint.setY(anchorRect.y() + anchorRect.height()); break; default: anchorPoint.setY(qRound(anchorRect.y() + anchorRect.height() / 2.0)); } // calculate where the top left point of the popup will end up with the applied gravity // gravity indicates direction. i.e if gravitating towards the top the popup's bottom edge // will next to the anchor point QPoint popupPosAdjust; switch (gravity & (Qt::LeftEdge | Qt::RightEdge)) { case Qt::LeftEdge: popupPosAdjust.setX(-popupSize.width()); break; case Qt::RightEdge: popupPosAdjust.setX(0); break; default: popupPosAdjust.setX(qRound(-popupSize.width() / 2.0)); } switch (gravity & (Qt::TopEdge | Qt::BottomEdge)) { case Qt::TopEdge: popupPosAdjust.setY(-popupSize.height()); break; case Qt::BottomEdge: popupPosAdjust.setY(0); break; default: popupPosAdjust.setY(qRound(-popupSize.height() / 2.0)); } return anchorPoint + popupPosAdjust; } bool ShellClient::isWaitingForMoveResizeSync() const { if (m_shellSurface) { return !m_pendingConfigureRequests.isEmpty(); } return false; } void ShellClient::doResizeSync() { requestGeometry(moveResizeGeometry()); } QMatrix4x4 ShellClient::inputTransformation() const { QMatrix4x4 m = Toplevel::inputTransformation(); m.translate(-borderLeft(), -borderTop()); return m; } void ShellClient::installServerSideDecoration(KWayland::Server::ServerSideDecorationInterface *deco) { if (m_serverDecoration == deco) { return; } m_serverDecoration = deco; connect(m_serverDecoration, &ServerSideDecorationInterface::destroyed, this, [this] { m_serverDecoration = nullptr; if (m_closing || !Workspace::self()) { return; } if (!m_unmapped) { // maybe delay to next event cycle in case the ShellClient is getting destroyed, too updateDecoration(true); } } ); if (!m_unmapped) { updateDecoration(true); } connect(m_serverDecoration, &ServerSideDecorationInterface::modeRequested, this, [this] (ServerSideDecorationManagerInterface::Mode mode) { const bool changed = mode != m_serverDecoration->mode(); if (changed && !m_unmapped) { updateDecoration(false); } } ); } void ShellClient::installXdgDecoration(XdgDecorationInterface *deco) { Q_ASSERT(m_xdgShellSurface); m_xdgDecoration = deco; connect(m_xdgDecoration, &QObject::destroyed, this, [this] { m_xdgDecoration = nullptr; if (m_closing || !Workspace::self()) { return; } updateDecoration(true); } ); connect(m_xdgDecoration, &XdgDecorationInterface::modeRequested, this, [this] () { //force is true as we must send a new configure response updateDecoration(false, true); }); } bool ShellClient::shouldExposeToWindowManagement() { if (m_internal) { return false; } if (isLockScreen()) { return false; } if (m_xdgShellPopup) { return false; } if (m_shellSurface) { if (m_shellSurface->isTransient() && !m_shellSurface->acceptsKeyboardFocus()) { return false; } } return true; } KWayland::Server::XdgShellSurfaceInterface::States ShellClient::xdgSurfaceStates() const { XdgShellSurfaceInterface::States states; if (isActive()) { states |= XdgShellSurfaceInterface::State::Activated; } if (isFullScreen()) { states |= XdgShellSurfaceInterface::State::Fullscreen; } if (m_requestedMaximizeMode == MaximizeMode::MaximizeFull) { states |= XdgShellSurfaceInterface::State::Maximized; } if (isResize()) { states |= XdgShellSurfaceInterface::State::Resizing; } return states; } void ShellClient::doMinimize() { if (isMinimized()) { workspace()->clientHidden(this); } else { emit windowShown(this); } workspace()->updateMinimizedOfTransients(this); } bool ShellClient::setupCompositing() { if (m_compositingSetup) { return true; } m_compositingSetup = Toplevel::setupCompositing(); return m_compositingSetup; } void ShellClient::finishCompositing(ReleaseReason releaseReason) { m_compositingSetup = false; Toplevel::finishCompositing(releaseReason); } void ShellClient::placeIn(QRect &area) { Placement::self()->place(this, area); setGeometryRestore(geometry()); } void ShellClient::showOnScreenEdge() { if (!m_plasmaShellSurface || m_unmapped) { return; } hideClient(false); workspace()->raiseClient(this); if (m_plasmaShellSurface->panelBehavior() == PlasmaShellSurfaceInterface::PanelBehavior::AutoHide) { m_plasmaShellSurface->showAutoHidingPanel(); } } bool ShellClient::dockWantsInput() const { if (m_plasmaShellSurface) { if (m_plasmaShellSurface->role() == PlasmaShellSurfaceInterface::Role::Panel) { return m_plasmaShellSurface->panelTakesFocus(); } } return false; } void ShellClient::killWindow() { if (!surface()) { return; } auto c = surface()->client(); if (c->processId() == getpid() || c->processId() == 0) { c->destroy(); return; } ::kill(c->processId(), SIGTERM); // give it time to terminate and only if terminate fails, try destroy Wayland connection QTimer::singleShot(5000, c, &ClientConnection::destroy); } bool ShellClient::hasPopupGrab() const { return m_hasPopupGrab; } void ShellClient::popupDone() { if (m_shellSurface) { m_shellSurface->popupDone(); } if (m_xdgShellPopup) { m_xdgShellPopup->popupDone(); } } void ShellClient::updateClientOutputs() { QVector clientOutputs; const auto outputs = waylandServer()->display()->outputs(); for (OutputInterface* output: qAsConst(outputs)) { const QRect outputGeom(output->globalPosition(), output->pixelSize() / output->scale()); if (geometry().intersects(outputGeom)) { clientOutputs << output; } } surface()->setOutputs(clientOutputs); } void ShellClient::updateWindowMargins() { QRect windowGeometry; QSize clientSize = m_clientSize; if (m_xdgShellSurface) { windowGeometry = m_xdgShellSurface->windowGeometry(); } else if (m_xdgShellPopup) { windowGeometry = m_xdgShellPopup->windowGeometry(); if (!clientSize.isValid()) { clientSize = m_xdgShellPopup->initialSize(); } } else { return; } if (windowGeometry.isEmpty() || windowGeometry.width() > clientSize.width() || windowGeometry.height() > clientSize.height()) { m_windowMargins = QMargins(); } else { m_windowMargins = QMargins(windowGeometry.left(), windowGeometry.top(), clientSize.width() - (windowGeometry.right() + 1), clientSize.height() - (windowGeometry.bottom() + 1)); } } bool ShellClient::isPopupWindow() const { if (Toplevel::isPopupWindow()) { return true; } if (m_shellSurface != nullptr) { return m_shellSurface->isPopup(); } if (m_xdgShellPopup != nullptr) { return true; } return false; } QWindow *ShellClient::internalWindow() const { return nullptr; } bool ShellClient::supportsWindowRules() const { if (m_plasmaShellSurface) { return false; } return m_xdgShellSurface; } }