kwin/abstract_client.cpp

3593 lines
122 KiB
C++

/*
KWin - the KDE window manager
This file is part of the KDE project.
SPDX-FileCopyrightText: 2015 Martin Gräßlin <mgraesslin@kde.org>
SPDX-FileCopyrightText: 2019 Vlad Zahorodnii <vlad.zahorodnii@kde.org>
SPDX-License-Identifier: GPL-2.0-or-later
*/
#include "abstract_client.h"
#include "appmenu.h"
#include "decorations/decoratedclient.h"
#include "decorations/decorationpalette.h"
#include "decorations/decorationbridge.h"
#include "effects.h"
#include "focuschain.h"
#include "outline.h"
#include "screens.h"
#ifdef KWIN_BUILD_TABBOX
#include "tabbox.h"
#endif
#include "screenedge.h"
#include "useractions.h"
#include "workspace.h"
#include "wayland_server.h"
#include <KWaylandServer/plasmawindowmanagement_interface.h>
#include <KDecoration2/DecoratedClient>
#include <KDecoration2/Decoration>
#include <KDesktopFile>
#include <QDir>
#include <QMouseEvent>
#include <QStyleHints>
namespace KWin
{
static inline int sign(int v)
{
return (v > 0) - (v < 0);
}
QHash<QString, std::weak_ptr<Decoration::DecorationPalette>> AbstractClient::s_palettes;
std::shared_ptr<Decoration::DecorationPalette> AbstractClient::s_defaultPalette;
AbstractClient::AbstractClient()
: Toplevel()
#ifdef KWIN_BUILD_TABBOX
, m_tabBoxClient(QSharedPointer<TabBox::TabBoxClientImpl>(new TabBox::TabBoxClientImpl(this)))
#endif
, m_colorScheme(QStringLiteral("kdeglobals"))
{
connect(this, &AbstractClient::clientStartUserMovedResized, this, &AbstractClient::moveResizedChanged);
connect(this, &AbstractClient::clientFinishUserMovedResized, this, &AbstractClient::moveResizedChanged);
connect(this, &AbstractClient::clientStartUserMovedResized, this, &AbstractClient::removeCheckScreenConnection);
connect(this, &AbstractClient::clientFinishUserMovedResized, this, &AbstractClient::setupCheckScreenConnection);
connect(this, &AbstractClient::paletteChanged, this, &AbstractClient::triggerDecorationRepaint);
connect(Decoration::DecorationBridge::self(), &QObject::destroyed, this, &AbstractClient::destroyDecoration);
// If the user manually moved the window, don't restore it after the keyboard closes
connect(this, &AbstractClient::clientFinishUserMovedResized, this, [this] () {
m_keyboardGeometryRestore = QRect();
});
connect(this, qOverload<AbstractClient *, bool, bool>(&AbstractClient::clientMaximizedStateChanged), this, [this] () {
m_keyboardGeometryRestore = QRect();
});
connect(this, &AbstractClient::fullScreenChanged, this, [this] () {
m_keyboardGeometryRestore = QRect();
});
// replace on-screen-display on size changes
connect(this, &AbstractClient::frameGeometryChanged, this,
[this] (Toplevel *c, const QRect &old) {
Q_UNUSED(c)
if (isOnScreenDisplay() && !frameGeometry().isEmpty() && old.size() != frameGeometry().size() && isPlaceable()) {
GeometryUpdatesBlocker blocker(this);
const QRect area = workspace()->clientArea(PlacementArea, Screens::self()->current(), desktop());
Placement::self()->place(this, area);
setGeometryRestore(frameGeometry());
}
}
);
connect(this, &AbstractClient::paddingChanged, this, [this]() {
m_visibleRectBeforeGeometryUpdate = visibleRect();
});
connect(ApplicationMenu::self(), &ApplicationMenu::applicationMenuEnabledChanged, this, [this] {
emit hasApplicationMenuChanged(hasApplicationMenu());
});
}
AbstractClient::~AbstractClient()
{
Q_ASSERT(m_blockGeometryUpdates == 0);
Q_ASSERT(m_decoration.decoration == nullptr);
}
void AbstractClient::updateMouseGrab()
{
}
bool AbstractClient::belongToSameApplication(const AbstractClient *c1, const AbstractClient *c2, SameApplicationChecks checks)
{
return c1->belongsToSameApplication(c2, checks);
}
bool AbstractClient::isTransient() const
{
return false;
}
void AbstractClient::setClientShown(bool shown)
{
Q_UNUSED(shown)
}
xcb_timestamp_t AbstractClient::userTime() const
{
return XCB_TIME_CURRENT_TIME;
}
void AbstractClient::setSkipSwitcher(bool set)
{
set = rules()->checkSkipSwitcher(set);
if (set == skipSwitcher())
return;
m_skipSwitcher = set;
doSetSkipSwitcher();
updateWindowRules(Rules::SkipSwitcher);
emit skipSwitcherChanged();
}
void AbstractClient::setSkipPager(bool b)
{
b = rules()->checkSkipPager(b);
if (b == skipPager())
return;
m_skipPager = b;
doSetSkipPager();
updateWindowRules(Rules::SkipPager);
emit skipPagerChanged();
}
void AbstractClient::doSetSkipPager()
{
}
void AbstractClient::setSkipTaskbar(bool b)
{
int was_wants_tab_focus = wantsTabFocus();
if (b == skipTaskbar())
return;
m_skipTaskbar = b;
doSetSkipTaskbar();
updateWindowRules(Rules::SkipTaskbar);
if (was_wants_tab_focus != wantsTabFocus()) {
FocusChain::self()->update(this, isActive() ? FocusChain::MakeFirst : FocusChain::Update);
}
emit skipTaskbarChanged();
}
void AbstractClient::setOriginalSkipTaskbar(bool b)
{
m_originalSkipTaskbar = rules()->checkSkipTaskbar(b);
setSkipTaskbar(m_originalSkipTaskbar);
}
void AbstractClient::doSetSkipTaskbar()
{
}
void AbstractClient::doSetSkipSwitcher()
{
}
void AbstractClient::setIcon(const QIcon &icon)
{
m_icon = icon;
emit iconChanged();
}
void AbstractClient::setActive(bool act)
{
if (isZombie()) {
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()->setActiveClient(act ? this : nullptr);
if (!m_active)
cancelAutoRaise();
if (!m_active && shadeMode() == ShadeActivated)
setShade(ShadeNormal);
StackingUpdatesBlocker blocker(workspace());
workspace()->updateClientLayer(this); // active windows may get different layer
auto mainclients = mainClients();
for (auto it = mainclients.constBegin();
it != mainclients.constEnd();
++it)
if ((*it)->isFullScreen()) // fullscreens go high even if their transient is active
workspace()->updateClientLayer(*it);
doSetActive();
emit activeChanged();
updateMouseGrab();
}
void AbstractClient::doSetActive()
{
}
bool AbstractClient::isZombie() const
{
return m_zombie;
}
void AbstractClient::markAsZombie()
{
Q_ASSERT(!m_zombie);
m_zombie = true;
addWorkspaceRepaint(visibleRect());
}
Layer AbstractClient::layer() const
{
if (m_layer == UnknownLayer)
const_cast< AbstractClient* >(this)->m_layer = belongsToLayer();
return m_layer;
}
void AbstractClient::updateLayer()
{
if (layer() == belongsToLayer())
return;
StackingUpdatesBlocker blocker(workspace());
invalidateLayer(); // invalidate, will be updated when doing restacking
for (auto it = transients().constBegin(),
end = transients().constEnd(); it != end; ++it)
(*it)->updateLayer();
}
void AbstractClient::placeIn(const QRect &area)
{
// TODO: Get rid of this method eventually. We need to call setGeometryRestore() because
// checkWorkspacePosition() operates on geometryRestore() and because of quick tiling.
Placement::self()->place(this, area);
setGeometryRestore(frameGeometry());
}
void AbstractClient::invalidateLayer()
{
m_layer = UnknownLayer;
}
Layer AbstractClient::belongsToLayer() const
{
// NOTICE while showingDesktop, desktops move to the AboveLayer
// (interchangeable w/ eg. yakuake etc. which will at first remain visible)
// and the docks move into the NotificationLayer (which is between Above- and
// ActiveLayer, so that active fullscreen windows will still cover everything)
// Since the desktop is also activated, nothing should be in the ActiveLayer, though
if (isInternal())
return UnmanagedLayer;
if (isLockScreen())
return UnmanagedLayer;
if (isInputMethod())
return UnmanagedLayer;
if (isDesktop())
return workspace()->showingDesktop() ? AboveLayer : DesktopLayer;
if (isSplash()) // no damn annoying splashscreens
return NormalLayer; // getting in the way of everything else
if (isDock()) {
if (workspace()->showingDesktop())
return NotificationLayer;
return layerForDock();
}
if (isOnScreenDisplay())
return OnScreenDisplayLayer;
if (isNotification())
return NotificationLayer;
if (isCriticalNotification())
return CriticalNotificationLayer;
if (workspace()->showingDesktop() && belongsToDesktop()) {
return AboveLayer;
}
if (keepBelow())
return BelowLayer;
if (isActiveFullScreen())
return ActiveLayer;
if (keepAbove())
return AboveLayer;
return NormalLayer;
}
bool AbstractClient::belongsToDesktop() const
{
return false;
}
Layer AbstractClient::layerForDock() const
{
// slight hack for the 'allow window to cover panel' Kicker setting
// don't move keepbelow docks below normal window, but only to the same
// layer, so that both may be raised to cover the other
if (keepBelow())
return NormalLayer;
if (keepAbove()) // slight hack for the autohiding panels
return AboveLayer;
return DockLayer;
}
void AbstractClient::setKeepAbove(bool b)
{
b = rules()->checkKeepAbove(b);
if (b && !rules()->checkKeepBelow(false))
setKeepBelow(false);
if (b == keepAbove()) {
return;
}
m_keepAbove = b;
doSetKeepAbove();
workspace()->updateClientLayer(this);
updateWindowRules(Rules::Above);
emit keepAboveChanged(m_keepAbove);
}
void AbstractClient::doSetKeepAbove()
{
}
void AbstractClient::setKeepBelow(bool b)
{
b = rules()->checkKeepBelow(b);
if (b && !rules()->checkKeepAbove(false))
setKeepAbove(false);
if (b == keepBelow()) {
return;
}
m_keepBelow = b;
doSetKeepBelow();
workspace()->updateClientLayer(this);
updateWindowRules(Rules::Below);
emit keepBelowChanged(m_keepBelow);
}
void AbstractClient::doSetKeepBelow()
{
}
void AbstractClient::startAutoRaise()
{
delete m_autoRaiseTimer;
m_autoRaiseTimer = new QTimer(this);
connect(m_autoRaiseTimer, &QTimer::timeout, this, &AbstractClient::autoRaise);
m_autoRaiseTimer->setSingleShot(true);
m_autoRaiseTimer->start(options->autoRaiseInterval());
}
void AbstractClient::cancelAutoRaise()
{
delete m_autoRaiseTimer;
m_autoRaiseTimer = nullptr;
}
void AbstractClient::autoRaise()
{
workspace()->raiseClient(this);
cancelAutoRaise();
}
bool AbstractClient::isMostRecentlyRaised() const
{
// The last toplevel in the unconstrained stacking order is the most recently raised one.
return workspace()->topClientOnDesktop(VirtualDesktopManager::self()->current(), -1, true, false) == this;
}
bool AbstractClient::wantsTabFocus() const
{
return (isNormalWindow() || isDialog()) && wantsInput();
}
bool AbstractClient::isSpecialWindow() const
{
// TODO
return isDesktop() || isDock() || isSplash() || isToolbar() || isNotification() || isOnScreenDisplay() || isCriticalNotification();
}
void AbstractClient::demandAttention(bool set)
{
if (isActive())
set = false;
if (m_demandsAttention == set)
return;
m_demandsAttention = set;
doSetDemandsAttention();
workspace()->clientAttentionChanged(this, set);
emit demandsAttentionChanged();
}
void AbstractClient::doSetDemandsAttention()
{
}
void AbstractClient::setDesktop(int desktop)
{
const int numberOfDesktops = VirtualDesktopManager::self()->count();
if (desktop != NET::OnAllDesktops) // Do range check
desktop = qMax(1, qMin(numberOfDesktops, desktop));
desktop = qMin(numberOfDesktops, rules()->checkDesktop(desktop));
QVector<VirtualDesktop *> desktops;
if (desktop != NET::OnAllDesktops) {
desktops << VirtualDesktopManager::self()->desktopForX11Id(desktop);
}
setDesktops(desktops);
}
void AbstractClient::setDesktops(QVector<VirtualDesktop*> desktops)
{
//on x11 we can have only one desktop at a time
if (kwinApp()->operationMode() == Application::OperationModeX11 && desktops.size() > 1) {
desktops = QVector<VirtualDesktop*>({desktops.last()});
}
if (desktops == m_desktops) {
return;
}
int was_desk = AbstractClient::desktop();
const bool wasOnCurrentDesktop = isOnCurrentDesktop() && was_desk >= 0;
m_desktops = desktops;
if (windowManagementInterface()) {
if (m_desktops.isEmpty()) {
windowManagementInterface()->setOnAllDesktops(true);
} else {
windowManagementInterface()->setOnAllDesktops(false);
auto currentDesktops = windowManagementInterface()->plasmaVirtualDesktops();
for (auto desktop: m_desktops) {
if (!currentDesktops.contains(desktop->id())) {
windowManagementInterface()->addPlasmaVirtualDesktop(desktop->id());
} else {
currentDesktops.removeOne(desktop->id());
}
}
for (auto desktopId: currentDesktops) {
windowManagementInterface()->removePlasmaVirtualDesktop(desktopId);
}
}
}
if (info) {
info->setDesktop(desktop());
}
if ((was_desk == NET::OnAllDesktops) != (desktop() == NET::OnAllDesktops)) {
// onAllDesktops changed
workspace()->updateOnAllDesktopsOfTransients(this);
}
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
{
foreach (AbstractClient * c2, mainClients())
c2->setDesktops(desktops);
}
doSetDesktop();
FocusChain::self()->update(this, FocusChain::MakeFirst);
updateWindowRules(Rules::Desktop);
emit desktopChanged();
if (wasOnCurrentDesktop != isOnCurrentDesktop())
emit desktopPresenceChanged(this, was_desk);
emit x11DesktopIdsChanged();
}
void AbstractClient::doSetDesktop()
{
}
void AbstractClient::enterDesktop(VirtualDesktop *virtualDesktop)
{
if (m_desktops.contains(virtualDesktop)) {
return;
}
auto desktops = m_desktops;
desktops.append(virtualDesktop);
setDesktops(desktops);
}
void AbstractClient::leaveDesktop(VirtualDesktop *virtualDesktop)
{
QVector<VirtualDesktop*> 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 AbstractClient::setOnAllDesktops(bool b)
{
if ((b && isOnAllDesktops()) ||
(!b && !isOnAllDesktops()))
return;
if (b)
setDesktop(NET::OnAllDesktops);
else
setDesktop(VirtualDesktopManager::self()->current());
}
QVector<uint> AbstractClient::x11DesktopIds() const
{
const auto desks = desktops();
QVector<uint> x11Ids;
x11Ids.reserve(desks.count());
std::transform(desks.constBegin(), desks.constEnd(),
std::back_inserter(x11Ids),
[] (const VirtualDesktop *vd) {
return vd->x11DesktopNumber();
}
);
return x11Ids;
}
ShadeMode AbstractClient::shadeMode() const
{
return m_shadeMode;
}
bool AbstractClient::isShadeable() const
{
return false;
}
void AbstractClient::setShade(bool set)
{
set ? setShade(ShadeNormal) : setShade(ShadeNone);
}
void AbstractClient::setShade(ShadeMode mode)
{
if (!isShadeable())
return;
if (mode == ShadeHover && isMove())
return; // causes geometry breaks and is probably nasty
if (isSpecialWindow() || noBorder())
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
emit shadeChanged();
return; // No real change in shaded state
}
Q_ASSERT(isDecorated());
GeometryUpdatesBlocker blocker(this);
doSetShade(previousShadeMode);
discardWindowPixmap();
updateWindowRules(Rules::Shade);
emit shadeChanged();
}
void AbstractClient::doSetShade(ShadeMode previousShadeMode)
{
Q_UNUSED(previousShadeMode)
}
void AbstractClient::shadeHover()
{
setShade(ShadeHover);
cancelShadeHoverTimer();
}
void AbstractClient::shadeUnhover()
{
setShade(ShadeNormal);
cancelShadeHoverTimer();
}
void AbstractClient::startShadeHoverTimer()
{
if (!isShade())
return;
m_shadeHoverTimer = new QTimer(this);
connect(m_shadeHoverTimer, &QTimer::timeout, this, &AbstractClient::shadeHover);
m_shadeHoverTimer->setSingleShot(true);
m_shadeHoverTimer->start(options->shadeHoverInterval());
}
void AbstractClient::startShadeUnhoverTimer()
{
if (m_shadeMode == ShadeHover && !isMoveResize() && !isMoveResizePointerButtonDown()) {
m_shadeHoverTimer = new QTimer(this);
connect(m_shadeHoverTimer, &QTimer::timeout, this, &AbstractClient::shadeUnhover);
m_shadeHoverTimer->setSingleShot(true);
m_shadeHoverTimer->start(options->shadeHoverInterval());
}
}
void AbstractClient::cancelShadeHoverTimer()
{
delete m_shadeHoverTimer;
m_shadeHoverTimer = nullptr;
}
void AbstractClient::toggleShade()
{
// If the mode is ShadeHover or ShadeActive, cancel shade too.
setShade(shadeMode() == ShadeNone ? ShadeNormal : ShadeNone);
}
AbstractClient::Position AbstractClient::titlebarPosition() const
{
// TODO: still needed, remove?
return PositionTop;
}
bool AbstractClient::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 AbstractClient::PositionTop:
return (sectionUnderMouse == Qt::TopLeftSection || sectionUnderMouse == Qt::TopSection || sectionUnderMouse == Qt::TopRightSection);
case AbstractClient::PositionLeft:
return (sectionUnderMouse == Qt::TopLeftSection || sectionUnderMouse == Qt::LeftSection || sectionUnderMouse == Qt::BottomLeftSection);
case AbstractClient::PositionRight:
return (sectionUnderMouse == Qt::BottomRightSection || sectionUnderMouse == Qt::RightSection || sectionUnderMouse == Qt::TopRightSection);
case AbstractClient::PositionBottom:
return (sectionUnderMouse == Qt::BottomLeftSection || sectionUnderMouse == Qt::BottomSection || sectionUnderMouse == Qt::BottomRightSection);
default:
// nothing
return false;
}
}
void AbstractClient::setMinimized(bool set)
{
set ? minimize() : unminimize();
}
void AbstractClient::minimize(bool avoid_animation)
{
if (!isMinimizable() || isMinimized())
return;
m_minimized = true;
doMinimize();
updateWindowRules(Rules::Minimize);
if (options->moveMinimizedWindowsToEndOfTabBoxFocusChain()) {
FocusChain::self()->update(this, FocusChain::MakeFirstMinimized);
}
// TODO: merge signal with s_minimized
addWorkspaceRepaint(visibleRect());
emit clientMinimized(this, !avoid_animation);
emit minimizedChanged();
}
void AbstractClient::unminimize(bool avoid_animation)
{
if (!isMinimized())
return;
if (rules()->checkMinimize(false)) {
return;
}
m_minimized = false;
doMinimize();
updateWindowRules(Rules::Minimize);
emit clientUnminimized(this, !avoid_animation);
emit minimizedChanged();
}
void AbstractClient::doMinimize()
{
}
QPalette AbstractClient::palette() const
{
if (!m_palette) {
return QPalette();
}
return m_palette->palette();
}
const Decoration::DecorationPalette *AbstractClient::decorationPalette() const
{
return m_palette.get();
}
QString AbstractClient::preferredColorScheme() const
{
return rules()->checkDecoColor(QString());
}
QString AbstractClient::colorScheme() const
{
return m_colorScheme;
}
void AbstractClient::setColorScheme(const QString &colorScheme)
{
QString requestedColorScheme = colorScheme;
if (requestedColorScheme.isEmpty()) {
requestedColorScheme = QStringLiteral("kdeglobals");
}
if (!m_palette || m_colorScheme != requestedColorScheme) {
m_colorScheme = requestedColorScheme;
if (m_palette) {
disconnect(m_palette.get(), &Decoration::DecorationPalette::changed, this, &AbstractClient::handlePaletteChange);
}
auto it = s_palettes.find(m_colorScheme);
if (it == s_palettes.end() || it->expired()) {
m_palette = std::make_shared<Decoration::DecorationPalette>(m_colorScheme);
if (m_palette->isValid()) {
s_palettes[m_colorScheme] = m_palette;
} else {
if (!s_defaultPalette) {
s_defaultPalette = std::make_shared<Decoration::DecorationPalette>(QStringLiteral("kdeglobals"));
s_palettes[QStringLiteral("kdeglobals")] = s_defaultPalette;
}
m_palette = s_defaultPalette;
}
if (m_colorScheme == QStringLiteral("kdeglobals")) {
s_defaultPalette = m_palette;
}
} else {
m_palette = it->lock();
}
connect(m_palette.get(), &Decoration::DecorationPalette::changed, this, &AbstractClient::handlePaletteChange);
emit paletteChanged(palette());
emit colorSchemeChanged();
}
}
void AbstractClient::updateColorScheme()
{
setColorScheme(preferredColorScheme());
}
void AbstractClient::handlePaletteChange()
{
emit paletteChanged(palette());
}
void AbstractClient::keepInArea(QRect area, bool partial)
{
if (partial) {
// increase the area so that can have only 100 pixels in the area
area.setLeft(qMin(area.left() - width() + 100, area.left()));
area.setTop(qMin(area.top() - height() + 100, area.top()));
area.setRight(qMax(area.right() + width() - 100, area.right()));
area.setBottom(qMax(area.bottom() + height() - 100, area.bottom()));
}
if (!partial) {
// resize to fit into area
if (area.width() < width() || area.height() < height())
resizeWithChecks(size().boundedTo(area.size()));
}
int tx = x(), ty = y();
if (frameGeometry().right() > area.right() && width() <= area.width())
tx = area.right() - width() + 1;
if (frameGeometry().bottom() > area.bottom() && height() <= area.height())
ty = area.bottom() - height() + 1;
if (!area.contains(frameGeometry().topLeft())) {
if (tx < area.x())
tx = area.x();
if (ty < area.y())
ty = area.y();
}
if (tx != x() || ty != y())
move(tx, ty);
}
/**
* Returns the maximum client size, not the maximum frame size.
*/
QSize AbstractClient::maxSize() const
{
return rules()->checkMaxSize(QSize(INT_MAX, INT_MAX));
}
/**
* Returns the minimum client size, not the minimum frame size.
*/
QSize AbstractClient::minSize() const
{
return rules()->checkMinSize(QSize(0, 0));
}
void AbstractClient::blockGeometryUpdates(bool block)
{
if (block) {
if (m_blockGeometryUpdates == 0)
m_pendingGeometryUpdate = PendingGeometryNone;
++m_blockGeometryUpdates;
} else {
if (--m_blockGeometryUpdates == 0) {
if (m_pendingGeometryUpdate != PendingGeometryNone) {
if (isShade())
setFrameGeometry(QRect(pos(), adjustedSize()), NormalGeometrySet);
else
setFrameGeometry(frameGeometry(), NormalGeometrySet);
m_pendingGeometryUpdate = PendingGeometryNone;
}
}
}
}
void AbstractClient::maximize(MaximizeMode m)
{
setMaximize(m & MaximizeVertical, m & MaximizeHorizontal);
}
void AbstractClient::setMaximize(bool vertically, bool horizontally)
{
// changeMaximize() flips the state, so change from set->flip
const MaximizeMode oldMode = requestedMaximizeMode();
changeMaximize(
oldMode & MaximizeHorizontal ? !horizontally : horizontally,
oldMode & MaximizeVertical ? !vertically : vertically,
false);
const MaximizeMode newMode = maximizeMode();
if (oldMode != newMode) {
emit clientMaximizedStateChanged(this, newMode);
emit clientMaximizedStateChanged(this, vertically, horizontally);
}
}
void AbstractClient::move(int x, int y, ForceGeometry_t force)
{
// resuming geometry updates is handled only in setGeometry()
Q_ASSERT(pendingGeometryUpdate() == PendingGeometryNone || areGeometryUpdatesBlocked());
QPoint p(x, y);
if (!areGeometryUpdatesBlocked() && p != rules()->checkPosition(p)) {
qCDebug(KWIN_CORE) << "forced position fail:" << p << ":" << rules()->checkPosition(p);
}
if (force == NormalGeometrySet && m_frameGeometry.topLeft() == p)
return;
m_frameGeometry.moveTopLeft(p);
if (areGeometryUpdatesBlocked()) {
if (pendingGeometryUpdate() == PendingGeometryForced)
{} // maximum, nothing needed
else if (force == ForceGeometrySet)
setPendingGeometryUpdate(PendingGeometryForced);
else
setPendingGeometryUpdate(PendingGeometryNormal);
return;
}
const QRect oldBufferGeometry = bufferGeometryBeforeUpdateBlocking();
const QRect oldClientGeometry = clientGeometryBeforeUpdateBlocking();
const QRect oldFrameGeometry = frameGeometryBeforeUpdateBlocking();
doMove(x, y);
updateGeometryBeforeUpdateBlocking();
updateWindowRules(Rules::Position);
screens()->setCurrent(this);
workspace()->updateStackingOrder();
// client itself is not damaged
emit bufferGeometryChanged(this, oldBufferGeometry);
emit clientGeometryChanged(this, oldClientGeometry);
emit frameGeometryChanged(this, oldFrameGeometry);
addRepaintDuringGeometryUpdates();
}
bool AbstractClient::startMoveResize()
{
Q_ASSERT(!isMoveResize());
Q_ASSERT(QWidget::keyboardGrabber() == nullptr);
Q_ASSERT(QWidget::mouseGrabber() == nullptr);
stopDelayedMoveResize();
if (QApplication::activePopupWidget() != nullptr)
return false; // popups have grab
if (isFullScreen() && (screens()->count() < 2 || !isMovableAcrossScreens()))
return false;
if (!doStartMoveResize()) {
return false;
}
invalidateDecorationDoubleClickTimer();
setMoveResize(true);
workspace()->setMoveResizeClient(this);
const Position mode = moveResizePointerMode();
if (mode != PositionCenter) { // means "isResize()" but moveResizeMode = true is set below
if (maximizeMode() == MaximizeFull) { // partial is cond. reset in finishMoveResize
setGeometryRestore(frameGeometry()); // "restore" to current geometry
setMaximize(false, false);
}
}
if (quickTileMode() != QuickTileMode(QuickTileFlag::None) && mode != PositionCenter) { // Cannot use isResize() yet
// Exit quick tile mode when the user attempts to resize a tiled window
updateQuickTileMode(QuickTileFlag::None); // Do so without restoring original geometry
setGeometryRestore(frameGeometry());
doSetQuickTileMode();
emit quickTileModeChanged();
}
updateHaveResizeEffect();
updateInitialMoveResizeGeometry();
checkUnrestrictedMoveResize();
emit clientStartUserMovedResized(this);
if (ScreenEdges::self()->isDesktopSwitchingMovingClients())
ScreenEdges::self()->reserveDesktopSwitching(true, Qt::Vertical|Qt::Horizontal);
return true;
}
void AbstractClient::finishMoveResize(bool cancel)
{
GeometryUpdatesBlocker blocker(this);
const bool wasResize = isResize(); // store across leaveMoveResize
leaveMoveResize();
doFinishMoveResize();
if (cancel)
setFrameGeometry(initialMoveResizeGeometry());
else {
const QRect &moveResizeGeom = moveResizeGeometry();
if (wasResize) {
const bool restoreH = maximizeMode() == MaximizeHorizontal &&
moveResizeGeom.width() != initialMoveResizeGeometry().width();
const bool restoreV = maximizeMode() == MaximizeVertical &&
moveResizeGeom.height() != initialMoveResizeGeometry().height();
if (restoreH || restoreV) {
changeMaximize(restoreH, restoreV, false);
}
}
setFrameGeometry(moveResizeGeom);
}
checkScreen(); // needs to be done because clientFinishUserMovedResized has not yet re-activated online alignment
if (screen() != moveResizeStartScreen()) {
workspace()->sendClientToScreen(this, screen()); // checks rule validity
if (maximizeMode() != MaximizeRestore) {
checkWorkspacePosition();
}
}
if (isElectricBorderMaximizing()) {
setQuickTileMode(electricBorderMode());
setElectricBorderMaximizing(false);
} else if (!cancel && !isFullScreen()) {
QRect geom_restore = geometryRestore();
if (!(maximizeMode() & MaximizeHorizontal)) {
geom_restore.setX(frameGeometry().x());
geom_restore.setWidth(frameGeometry().width());
}
if (!(maximizeMode() & MaximizeVertical)) {
geom_restore.setY(frameGeometry().y());
geom_restore.setHeight(frameGeometry().height());
}
setGeometryRestore(geom_restore);
}
// FRAME update();
emit clientFinishUserMovedResized(this);
}
// 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 AbstractClient::checkUnrestrictedMoveResize()
{
if (isUnrestrictedMoveResize())
return;
const QRect &moveResizeGeom = moveResizeGeometry();
QRect desktopArea = workspace()->clientArea(WorkArea, moveResizeGeom.center(), desktop());
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 = qMin(100 + borderRight(), moveResizeGeom.width());
right_marge = qMin(100 + borderLeft(), moveResizeGeom.width());
// width/height change with opaque resizing, use the initial ones
titlebar_marge = initialMoveResizeGeometry().height();
top_marge = borderBottom();
bottom_marge = borderTop();
if (isResize()) {
if (moveResizeGeom.bottom() < desktopArea.top() + top_marge)
setUnrestrictedMoveResize(true);
if (moveResizeGeom.top() > desktopArea.bottom() - bottom_marge)
setUnrestrictedMoveResize(true);
if (moveResizeGeom.right() < desktopArea.left() + left_marge)
setUnrestrictedMoveResize(true);
if (moveResizeGeom.left() > desktopArea.right() - right_marge)
setUnrestrictedMoveResize(true);
if (!isUnrestrictedMoveResize() && moveResizeGeom.top() < desktopArea.top()) // titlebar mustn't go out
setUnrestrictedMoveResize(true);
}
if (isMove()) {
if (moveResizeGeom.bottom() < desktopArea.top() + titlebar_marge - 1)
setUnrestrictedMoveResize(true);
// no need to check top_marge, titlebar_marge already handles it
if (moveResizeGeom.top() > desktopArea.bottom() - bottom_marge + 1) // titlebar mustn't go out
setUnrestrictedMoveResize(true);
if (moveResizeGeom.right() < desktopArea.left() + left_marge)
setUnrestrictedMoveResize(true);
if (moveResizeGeom.left() > desktopArea.right() - right_marge)
setUnrestrictedMoveResize(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 AbstractClient::startDelayedMoveResize()
{
Q_ASSERT(!m_moveResize.delayedTimer);
m_moveResize.delayedTimer = new QTimer(this);
m_moveResize.delayedTimer->setSingleShot(true);
connect(m_moveResize.delayedTimer, &QTimer::timeout, this,
[this]() {
Q_ASSERT(isMoveResizePointerButtonDown());
if (!startMoveResize()) {
setMoveResizePointerButtonDown(false);
}
updateCursor();
stopDelayedMoveResize();
}
);
m_moveResize.delayedTimer->start(QApplication::startDragTime());
}
void AbstractClient::stopDelayedMoveResize()
{
delete m_moveResize.delayedTimer;
m_moveResize.delayedTimer = nullptr;
}
void AbstractClient::updateMoveResize(const QPointF &currentGlobalCursor)
{
handleMoveResize(pos(), currentGlobalCursor.toPoint());
}
void AbstractClient::handleMoveResize(const QPoint &local, const QPoint &global)
{
const QRect oldGeo = frameGeometry();
handleMoveResize(local.x(), local.y(), global.x(), global.y());
if (!isFullScreen() && isMove()) {
if (quickTileMode() != QuickTileMode(QuickTileFlag::None) && oldGeo != frameGeometry()) {
GeometryUpdatesBlocker blocker(this);
setQuickTileMode(QuickTileFlag::None);
const QRect &geom_restore = geometryRestore();
setMoveOffset(QPoint(double(moveOffset().x()) / double(oldGeo.width()) * double(geom_restore.width()),
double(moveOffset().y()) / double(oldGeo.height()) * double(geom_restore.height())));
if (rules()->checkMaximize(MaximizeRestore) == MaximizeRestore)
setMoveResizeGeometry(geom_restore);
handleMoveResize(local.x(), local.y(), global.x(), global.y()); // fix position
} else if (quickTileMode() == QuickTileMode(QuickTileFlag::None) && isResizable()) {
checkQuickTilingMaximizationZones(global.x(), global.y());
}
}
}
void AbstractClient::handleMoveResize(int x, int y, int x_root, int y_root)
{
if (isWaitingForMoveResizeSync())
return; // we're still waiting for the client or the timeout
const Position mode = moveResizePointerMode();
if ((mode == PositionCenter && !isMovableAcrossScreens())
|| (mode != PositionCenter && (isShade() || !isResizable())))
return;
if (!isMoveResize()) {
QPoint p(QPoint(x/* - padding_left*/, y/* - padding_top*/) - moveOffset());
if (p.manhattanLength() >= QApplication::startDragDistance()) {
if (!startMoveResize()) {
setMoveResizePointerButtonDown(false);
updateCursor();
return;
}
updateCursor();
} else
return;
}
// ShadeHover or ShadeActive, ShadeNormal was already avoided above
if (mode != PositionCenter && shadeMode() != ShadeNone)
setShade(ShadeNone);
QPoint globalPos(x_root, y_root);
// 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())
QPoint topleft = globalPos - moveOffset();
QPoint bottomright = globalPos + invertedMoveOffset();
QRect previousMoveResizeGeom = moveResizeGeometry();
// TODO move whole group when moving its leader or when the leader is not mapped?
auto titleBarRect = [this](bool &transposed, int &requiredPixels) -> QRect {
const QRect &moveResizeGeom = moveResizeGeometry();
QRect r(moveResizeGeom);
r.moveTopLeft(QPoint(0,0));
switch (titlebarPosition()) {
default:
case PositionTop:
r.setHeight(borderTop());
break;
case PositionLeft:
r.setWidth(borderLeft());
transposed = true;
break;
case PositionBottom:
r.setTop(r.bottom() - borderBottom());
break;
case PositionRight:
r.setLeft(r.right() - borderRight());
transposed = true;
break;
}
// When doing a restricted move we must always keep 100px of the titlebar
// visible to allow the user to be able to move it again.
requiredPixels = qMin(100 * (transposed ? r.width() : r.height()),
moveResizeGeom.width() * moveResizeGeom.height());
return r;
};
bool update = false;
if (isResize()) {
QRect orig = initialMoveResizeGeometry();
SizeMode sizeMode = SizeModeAny;
auto calculateMoveResizeGeom = [this, &topleft, &bottomright, &orig, &sizeMode, &mode]() {
switch(mode) {
case PositionTopLeft:
setMoveResizeGeometry(QRect(topleft, orig.bottomRight()));
break;
case PositionBottomRight:
setMoveResizeGeometry(QRect(orig.topLeft(), bottomright));
break;
case PositionBottomLeft:
setMoveResizeGeometry(QRect(QPoint(topleft.x(), orig.y()), QPoint(orig.right(), bottomright.y())));
break;
case PositionTopRight:
setMoveResizeGeometry(QRect(QPoint(orig.x(), topleft.y()), QPoint(bottomright.x(), orig.bottom())));
break;
case PositionTop:
setMoveResizeGeometry(QRect(QPoint(orig.left(), topleft.y()), orig.bottomRight()));
sizeMode = SizeModeFixedH; // try not to affect height
break;
case PositionBottom:
setMoveResizeGeometry(QRect(orig.topLeft(), QPoint(orig.right(), bottomright.y())));
sizeMode = SizeModeFixedH;
break;
case PositionLeft:
setMoveResizeGeometry(QRect(QPoint(topleft.x(), orig.top()), orig.bottomRight()));
sizeMode = SizeModeFixedW;
break;
case PositionRight:
setMoveResizeGeometry(QRect(orig.topLeft(), QPoint(bottomright.x(), orig.bottom())));
sizeMode = SizeModeFixedW;
break;
case PositionCenter:
default:
abort();
break;
}
};
// first resize (without checking constrains), then snap, then check bounds, then check constrains
calculateMoveResizeGeom();
// adjust new size to snap to other windows/borders
setMoveResizeGeometry(workspace()->adjustClientSize(this, moveResizeGeometry(), mode));
if (!isUnrestrictedMoveResize()) {
// 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
QRegion availableArea(workspace()->clientArea(FullArea, -1, 0)); // On the screen
availableArea -= workspace()->restrictedMoveArea(desktop()); // Strut areas
bool transposed = false;
int requiredPixels;
QRect bTitleRect = titleBarRect(transposed, requiredPixels);
int lastVisiblePixels = -1;
QRect lastTry = moveResizeGeometry();
bool titleFailed = false;
for (;;) {
const QRect titleRect(bTitleRect.translated(moveResizeGeometry().topLeft()));
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)
setMoveResizeGeometry(lastTry);
titleFailed = true;
}
}
lastVisiblePixels = realVisiblePixels;
QRect moveResizeGeom = moveResizeGeometry();
lastTry = moveResizeGeom;
// 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 = previousMoveResizeGeom.left() != moveResizeGeom.left();
bool rightChanged = previousMoveResizeGeom.right() != moveResizeGeom.right();
bool topChanged = previousMoveResizeGeom.top() != moveResizeGeom.top();
bool btmChanged = previousMoveResizeGeom.bottom() != moveResizeGeom.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 PositionTop:
fixChangedState(topChanged, btmChanged, leftChanged, rightChanged);
break;
case PositionLeft:
fixChangedState(leftChanged, rightChanged, topChanged, btmChanged);
break;
case PositionBottom:
fixChangedState(btmChanged, topChanged, leftChanged, rightChanged);
break;
case PositionRight:
fixChangedState(rightChanged, leftChanged, topChanged, btmChanged);
break;
}
if (topChanged)
moveResizeGeom.setTop(moveResizeGeom.y() + sign(previousMoveResizeGeom.y() - moveResizeGeom.y()));
else if (leftChanged)
moveResizeGeom.setLeft(moveResizeGeom.x() + sign(previousMoveResizeGeom.x() - moveResizeGeom.x()));
else if (btmChanged)
moveResizeGeom.setBottom(moveResizeGeom.bottom() + sign(previousMoveResizeGeom.bottom() - moveResizeGeom.bottom()));
else if (rightChanged)
moveResizeGeom.setRight(moveResizeGeom.right() + sign(previousMoveResizeGeom.right() - moveResizeGeom.right()));
else
break; // no position changed - that's certainly not good
setMoveResizeGeometry(moveResizeGeom);
}
}
// Always obey size hints, even when in "unrestricted" mode
QSize size = constrainFrameSize(moveResizeGeometry().size(), sizeMode);
// the new topleft and bottomright corners (after checking size constrains), if they'll be needed
topleft = QPoint(moveResizeGeometry().right() - size.width() + 1, moveResizeGeometry().bottom() - size.height() + 1);
bottomright = QPoint(moveResizeGeometry().left() + size.width() - 1, moveResizeGeometry().top() + size.height() - 1);
orig = moveResizeGeometry();
// 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();
if (moveResizeGeometry().size() != previousMoveResizeGeom.size())
update = true;
} else if (isMove()) {
Q_ASSERT(mode == PositionCenter);
if (!isMovable()) { // isMovableAcrossScreens() must have been true to get here
// Special moving of maximized windows on Xinerama screens
int screen = screens()->number(globalPos);
if (isFullScreen())
setMoveResizeGeometry(workspace()->clientArea(FullScreenArea, screen, 0));
else {
QRect moveResizeGeom = workspace()->clientArea(MaximizeArea, screen, 0);
QSize adjSize = constrainFrameSize(moveResizeGeom.size(), SizeModeMax);
if (adjSize != moveResizeGeom.size()) {
QRect r(moveResizeGeom);
moveResizeGeom.setSize(adjSize);
moveResizeGeom.moveCenter(r.center());
}
setMoveResizeGeometry(moveResizeGeom);
}
} else {
// first move, then snap, then check bounds
QRect moveResizeGeom = moveResizeGeometry();
moveResizeGeom.moveTopLeft(topleft);
moveResizeGeom.moveTopLeft(workspace()->adjustClientPosition(this, moveResizeGeom.topLeft(),
isUnrestrictedMoveResize()));
setMoveResizeGeometry(moveResizeGeom);
if (!isUnrestrictedMoveResize()) {
const QRegion strut = workspace()->restrictedMoveArea(desktop()); // Strut areas
QRegion availableArea(workspace()->clientArea(FullArea, -1, 0)); // On the screen
availableArea -= strut; // Strut areas
bool transposed = false;
int requiredPixels;
QRect bTitleRect = titleBarRect(transposed, requiredPixels);
for (;;) {
QRect moveResizeGeom = moveResizeGeometry();
const QRect titleRect(bTitleRect.translated(moveResizeGeom.topLeft()));
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 (screens()->count() > 1) { // optimization
// TODO: could be useful on partial screen struts (half-width panels etc.)
int newTitleTop = -1;
for (const QRect &r : strut) {
if (r.top() == 0 && r.width() > r.height() && // "top panel"
r.intersects(moveResizeGeom) && moveResizeGeom.top() < r.bottom()) {
newTitleTop = r.bottom() + 1;
break;
}
}
if (newTitleTop > -1) {
moveResizeGeom.moveTop(newTitleTop); // invalid position, possibly on screen change
setMoveResizeGeometry(moveResizeGeom);
break;
}
}
int dx = sign(previousMoveResizeGeom.x() - moveResizeGeom.x()),
dy = sign(previousMoveResizeGeom.y() - moveResizeGeom.y());
if (visiblePixels && dx) // means there's no full width cap -> favor horizontally
dy = 0;
else if (dy)
dx = 0;
// Move it back
moveResizeGeom.translate(dx, dy);
setMoveResizeGeometry(moveResizeGeom);
if (moveResizeGeom == previousMoveResizeGeom) {
break; // Prevent lockup
}
}
}
}
if (moveResizeGeometry().topLeft() != previousMoveResizeGeom.topLeft())
update = true;
} else
abort();
if (!update)
return;
if (isResize() && !haveResizeEffect()) {
doResizeSync();
} else
performMoveResize();
if (isMove()) {
ScreenEdges::self()->check(globalPos, QDateTime::fromMSecsSinceEpoch(xTime(), Qt::UTC));
}
}
void AbstractClient::performMoveResize()
{
const QRect &moveResizeGeom = moveResizeGeometry();
if (isMove() || (isResize() && !haveResizeEffect())) {
setFrameGeometry(moveResizeGeom);
}
doPerformMoveResize();
positionGeometryTip();
emit clientStepUserMovedResized(this, moveResizeGeom);
}
StrutRect AbstractClient::strutRect(StrutArea area) const
{
Q_UNUSED(area)
return StrutRect();
}
StrutRects AbstractClient::strutRects() const
{
StrutRects region;
region += strutRect(StrutAreaTop);
region += strutRect(StrutAreaRight);
region += strutRect(StrutAreaBottom);
region += strutRect(StrutAreaLeft);
return region;
}
bool AbstractClient::hasStrut() const
{
return false;
}
void AbstractClient::setupWindowManagementInterface()
{
if (m_windowManagementInterface) {
// already setup
return;
}
if (!waylandServer() || !surface()) {
return;
}
if (!waylandServer()->windowManagement()) {
return;
}
using namespace KWaylandServer;
auto w = waylandServer()->windowManagement()->createWindow(waylandServer()->windowManagement(), internalId());
w->setTitle(caption());
w->setVirtualDesktop(isOnAllDesktops() ? 0 : desktop() - 1);
w->setActive(isActive());
w->setFullscreen(isFullScreen());
w->setKeepAbove(keepAbove());
w->setKeepBelow(keepBelow());
w->setMaximized(maximizeMode() == KWin::MaximizeFull);
w->setMinimized(isMinimized());
w->setOnAllDesktops(isOnAllDesktops());
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->setAppId(QString::fromUtf8(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 X11Client::actionSupported(), but both should be implemented.
w->setParentWindow(transientFor() ? transientFor()->windowManagementInterface() : nullptr);
w->setGeometry(frameGeometry());
connect(this, &AbstractClient::skipTaskbarChanged, w,
[w, this] {
w->setSkipTaskbar(skipTaskbar());
}
);
connect(this, &AbstractClient::skipSwitcherChanged, w,
[w, this] {
w->setSkipSwitcher(skipSwitcher());
}
);
connect(this, &AbstractClient::captionChanged, w, [w, this] { w->setTitle(caption()); });
connect(this, &AbstractClient::activeChanged, w, [w, this] { w->setActive(isActive()); });
connect(this, &AbstractClient::fullScreenChanged, w, [w, this] { w->setFullscreen(isFullScreen()); });
connect(this, &AbstractClient::keepAboveChanged, w, &PlasmaWindowInterface::setKeepAbove);
connect(this, &AbstractClient::keepBelowChanged, w, &PlasmaWindowInterface::setKeepBelow);
connect(this, &AbstractClient::minimizedChanged, w, [w, this] { w->setMinimized(isMinimized()); });
connect(this, static_cast<void (AbstractClient::*)(AbstractClient*,MaximizeMode)>(&AbstractClient::clientMaximizedStateChanged), w,
[w] (KWin::AbstractClient *c, MaximizeMode mode) {
Q_UNUSED(c);
w->setMaximized(mode == KWin::MaximizeFull);
}
);
connect(this, &AbstractClient::demandsAttentionChanged, w, [w, this] { w->setDemandsAttention(isDemandingAttention()); });
connect(this, &AbstractClient::iconChanged, w,
[w, this] {
w->setIcon(icon());
}
);
connect(this, &AbstractClient::windowClassChanged, w, updateAppId);
connect(this, &AbstractClient::desktopFileNameChanged, w, updateAppId);
connect(this, &AbstractClient::shadeChanged, w, [w, this] { w->setShaded(isShade()); });
connect(this, &AbstractClient::transientChanged, w,
[w, this] {
w->setParentWindow(transientFor() ? transientFor()->windowManagementInterface() : nullptr);
}
);
connect(this, &AbstractClient::frameGeometryChanged, w,
[w, this] {
w->setGeometry(frameGeometry());
}
);
connect(this, &AbstractClient::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());
performMouseCommand(Options::MouseMove, Cursors::self()->mouse()->pos());
}
);
connect(w, &PlasmaWindowInterface::resizeRequested, this,
[this] {
Cursors::self()->mouse()->setPos(frameGeometry().bottomRight());
performMouseCommand(Options::MouseResize, Cursors::self()->mouse()->pos());
}
);
connect(w, &PlasmaWindowInterface::virtualDesktopRequested, this,
[this] (quint32 desktop) {
workspace()->sendClientToDesktop(this, desktop + 1, true);
}
);
connect(w, &PlasmaWindowInterface::fullscreenRequested, this,
[this] (bool set) {
setFullScreen(set, false);
}
);
connect(w, &PlasmaWindowInterface::minimizedRequested, this,
[this] (bool set) {
if (set) {
minimize();
} else {
unminimize();
}
}
);
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()->activateClient(this, true);
}
}
);
connect(w, &PlasmaWindowInterface::shadedRequested, this,
[this] (bool set) {
setShade(set);
}
);
for (const auto vd : m_desktops) {
w->addPlasmaVirtualDesktop(vd->id());
}
//this is only for the legacy
connect(this, &AbstractClient::desktopChanged, w,
[w, this] {
if (isOnAllDesktops()) {
w->setOnAllDesktops(true);
return;
}
w->setVirtualDesktop(desktop() - 1);
w->setOnAllDesktops(false);
}
);
//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.toUtf8());
if (vd) {
enterDesktop(vd);
}
}
);
connect(w, &PlasmaWindowInterface::enterNewPlasmaVirtualDesktopRequested, this,
[this] () {
VirtualDesktopManager::self()->setCount(VirtualDesktopManager::self()->count() + 1);
enterDesktop(VirtualDesktopManager::self()->desktops().last());
}
);
connect(w, &PlasmaWindowInterface::leavePlasmaVirtualDesktopRequested, this,
[this] (const QString &desktopId) {
VirtualDesktop *vd = VirtualDesktopManager::self()->desktopForId(desktopId.toUtf8());
if (vd) {
leaveDesktop(vd);
}
}
);
m_windowManagementInterface = w;
}
void AbstractClient::destroyWindowManagementInterface()
{
if (m_windowManagementInterface) {
m_windowManagementInterface->unmap();
m_windowManagementInterface = nullptr;
}
}
Options::MouseCommand AbstractClient::getMouseCommand(Qt::MouseButton button, bool *handled) const
{
*handled = false;
if (button == Qt::NoButton) {
return Options::MouseNothing;
}
if (isActive()) {
if (options->isClickRaise() && !isMostRecentlyRaised()) {
*handled = true;
return Options::MouseActivateRaiseAndPassClick;
}
} else {
*handled = true;
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 Options::MouseNothing;
}
Options::MouseCommand AbstractClient::getWheelCommand(Qt::Orientation orientation, bool *handled) const
{
*handled = false;
if (orientation != Qt::Vertical) {
return Options::MouseNothing;
}
if (!isActive()) {
*handled = true;
return options->commandWindowWheel();
}
return Options::MouseNothing;
}
bool AbstractClient::performMouseCommand(Options::MouseCommand cmd, const QPoint &globalPos)
{
bool replay = false;
switch(cmd) {
case Options::MouseRaise:
workspace()->raiseClient(this);
break;
case Options::MouseLower: {
workspace()->lowerClient(this);
// used to be activateNextClient(this), then topClientOnDesktop
// since this is a mouseOp it's however safe to use the client under the mouse instead
if (isActive() && options->focusPolicyIsReasonable()) {
AbstractClient *next = workspace()->clientUnderMouse(screen());
if (next && next != this)
workspace()->requestFocus(next, false);
}
break;
}
case Options::MouseOperationsMenu:
if (isActive() && options->isClickRaise())
autoRaise();
workspace()->showWindowMenu(QRect(globalPos, globalPos), this);
break;
case Options::MouseToggleRaiseAndLower:
workspace()->raiseOrLowerClient(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) {
AbstractClient *c = qobject_cast<AbstractClient*>(*it);
if (!c || (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);
screens()->setCurrent(globalPos);
replay = replay || mustReplay;
break;
}
case Options::MouseActivateAndLower:
workspace()->requestFocus(this);
workspace()->lowerClient(this);
screens()->setCurrent(globalPos);
replay = replay || !rules()->checkAcceptFocus(acceptsFocus());
break;
case Options::MouseActivate:
replay = isActive(); // for clickraise mode
workspace()->takeActivity(this, Workspace::ActivityFocus);
screens()->setCurrent(globalPos);
replay = replay || !rules()->checkAcceptFocus(acceptsFocus());
break;
case Options::MouseActivateRaiseAndPassClick:
workspace()->takeActivity(this, Workspace::ActivityFocus | Workspace::ActivityRaise);
screens()->setCurrent(globalPos);
replay = true;
break;
case Options::MouseActivateAndPassClick:
workspace()->takeActivity(this, Workspace::ActivityFocus);
screens()->setCurrent(globalPos);
replay = true;
break;
case Options::MouseMaximize:
maximize(MaximizeFull);
break;
case Options::MouseRestore:
maximize(MaximizeRestore);
break;
case Options::MouseMinimize:
minimize();
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(qMin(opacity() + 0.1, 1.0));
break;
case Options::MouseOpacityLess:
if (!isDesktop()) // No point in changing the opacity of the desktop
setOpacity(qMax(opacity() - 0.1, 0.1));
break;
case Options::MouseClose:
closeWindow();
break;
case Options::MouseActivateRaiseAndMove:
case Options::MouseActivateRaiseAndUnrestrictedMove:
workspace()->raiseClient(this);
workspace()->requestFocus(this);
screens()->setCurrent(globalPos);
// fallthrough
case Options::MouseMove:
case Options::MouseUnrestrictedMove: {
if (!isMovableAcrossScreens())
break;
if (isMoveResize())
finishMoveResize(false);
setMoveResizePointerMode(PositionCenter);
setMoveResizePointerButtonDown(true);
setMoveOffset(QPoint(globalPos.x() - x(), globalPos.y() - y())); // map from global
setInvertedMoveOffset(rect().bottomRight() - moveOffset());
setUnrestrictedMoveResize((cmd == Options::MouseActivateRaiseAndUnrestrictedMove
|| cmd == Options::MouseUnrestrictedMove));
if (!startMoveResize())
setMoveResizePointerButtonDown(false);
updateCursor();
break;
}
case Options::MouseResize:
case Options::MouseUnrestrictedResize: {
if (!isResizable() || isShade())
break;
if (isMoveResize())
finishMoveResize(false);
setMoveResizePointerButtonDown(true);
const QPoint moveOffset = QPoint(globalPos.x() - x(), globalPos.y() - y()); // map from global
setMoveOffset(moveOffset);
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;
Position mode;
if (top)
mode = left ? PositionTopLeft : (right ? PositionTopRight : PositionTop);
else if (bot)
mode = left ? PositionBottomLeft : (right ? PositionBottomRight : PositionBottom);
else
mode = (x < width() / 2) ? PositionLeft : PositionRight;
setMoveResizePointerMode(mode);
setInvertedMoveOffset(rect().bottomRight() - moveOffset);
setUnrestrictedMoveResize((cmd == Options::MouseUnrestrictedResize));
if (!startMoveResize())
setMoveResizePointerButtonDown(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;
}
void AbstractClient::setTransientFor(AbstractClient *transientFor)
{
if (transientFor == this) {
// cannot be transient for one self
return;
}
if (m_transientFor == transientFor) {
return;
}
m_transientFor = transientFor;
emit transientChanged();
}
const AbstractClient *AbstractClient::transientFor() const
{
return m_transientFor;
}
AbstractClient *AbstractClient::transientFor()
{
return m_transientFor;
}
bool AbstractClient::hasTransientPlacementHint() const
{
return false;
}
QRect AbstractClient::transientPlacement(const QRect &bounds) const
{
Q_UNUSED(bounds);
Q_UNREACHABLE();
return QRect();
}
bool AbstractClient::hasTransient(const AbstractClient *c, bool indirect) const
{
Q_UNUSED(indirect);
return c->transientFor() == this;
}
QList< AbstractClient* > AbstractClient::mainClients() const
{
if (const AbstractClient *t = transientFor()) {
return QList<AbstractClient*>{const_cast< AbstractClient* >(t)};
}
return QList<AbstractClient*>();
}
QList<AbstractClient*> AbstractClient::allMainClients() const
{
auto result = mainClients();
foreach (const auto *cl, result) {
result += cl->allMainClients();
}
return result;
}
void AbstractClient::setModal(bool m)
{
// Qt-3.2 can have even modal normal windows :(
if (m_modal == m)
return;
m_modal = m;
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 AbstractClient::isModal() const
{
return m_modal;
}
void AbstractClient::addTransient(AbstractClient *cl)
{
Q_ASSERT(!m_transients.contains(cl));
Q_ASSERT(cl != this);
m_transients.append(cl);
}
void AbstractClient::removeTransient(AbstractClient *cl)
{
m_transients.removeAll(cl);
if (cl->transientFor() == this) {
cl->setTransientFor(nullptr);
}
}
void AbstractClient::removeTransientFromList(AbstractClient *cl)
{
m_transients.removeAll(cl);
}
bool AbstractClient::isActiveFullScreen() const
{
if (!isFullScreen())
return false;
const auto ac = workspace()->mostRecentlyActivatedClient(); // instead of activeClient() - 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->screen() != screen()|| ac->allMainClients().contains(const_cast<AbstractClient*>(this)));
}
#define BORDER(which) \
int AbstractClient::border##which() const \
{ \
return isDecorated() ? decoration()->border##which() : 0; \
}
BORDER(Bottom)
BORDER(Left)
BORDER(Right)
BORDER(Top)
#undef BORDER
void AbstractClient::addRepaintDuringGeometryUpdates()
{
const QRect deco_rect = visibleRect();
addLayerRepaint(m_visibleRectBeforeGeometryUpdate);
addLayerRepaint(deco_rect); // trigger repaint of window's new location
m_visibleRectBeforeGeometryUpdate = deco_rect;
}
QRect AbstractClient::bufferGeometryBeforeUpdateBlocking() const
{
return m_bufferGeometryBeforeUpdateBlocking;
}
QRect AbstractClient::frameGeometryBeforeUpdateBlocking() const
{
return m_frameGeometryBeforeUpdateBlocking;
}
QRect AbstractClient::clientGeometryBeforeUpdateBlocking() const
{
return m_clientGeometryBeforeUpdateBlocking;
}
void AbstractClient::updateGeometryBeforeUpdateBlocking()
{
m_bufferGeometryBeforeUpdateBlocking = bufferGeometry();
m_frameGeometryBeforeUpdateBlocking = frameGeometry();
m_clientGeometryBeforeUpdateBlocking = clientGeometry();
}
void AbstractClient::doMove(int, int)
{
}
void AbstractClient::updateInitialMoveResizeGeometry()
{
m_moveResize.initialGeometry = frameGeometry();
m_moveResize.geometry = m_moveResize.initialGeometry;
m_moveResize.startScreen = screen();
}
void AbstractClient::updateCursor()
{
Position m = moveResizePointerMode();
if (!isResizable() || isShade())
m = PositionCenter;
CursorShape c = Qt::ArrowCursor;
switch(m) {
case PositionTopLeft:
c = KWin::ExtendedCursor::SizeNorthWest;
break;
case PositionBottomRight:
c = KWin::ExtendedCursor::SizeSouthEast;
break;
case PositionBottomLeft:
c = KWin::ExtendedCursor::SizeSouthWest;
break;
case PositionTopRight:
c = KWin::ExtendedCursor::SizeNorthEast;
break;
case PositionTop:
c = KWin::ExtendedCursor::SizeNorth;
break;
case PositionBottom:
c = KWin::ExtendedCursor::SizeSouth;
break;
case PositionLeft:
c = KWin::ExtendedCursor::SizeWest;
break;
case PositionRight:
c = KWin::ExtendedCursor::SizeEast;
break;
default:
if (isMoveResize())
c = Qt::SizeAllCursor;
else
c = Qt::ArrowCursor;
break;
}
if (c == m_moveResize.cursor)
return;
m_moveResize.cursor = c;
emit moveResizeCursorChanged(c);
}
void AbstractClient::leaveMoveResize()
{
workspace()->setMoveResizeClient(nullptr);
setMoveResize(false);
if (ScreenEdges::self()->isDesktopSwitchingMovingClients())
ScreenEdges::self()->reserveDesktopSwitching(false, Qt::Vertical|Qt::Horizontal);
if (isElectricBorderMaximizing()) {
outline()->hide();
elevate(false);
}
}
bool AbstractClient::s_haveResizeEffect = false;
void AbstractClient::updateHaveResizeEffect()
{
s_haveResizeEffect = effects && static_cast<EffectsHandlerImpl*>(effects)->provides(Effect::Resize);
}
bool AbstractClient::doStartMoveResize()
{
return true;
}
void AbstractClient::doFinishMoveResize()
{
}
void AbstractClient::positionGeometryTip()
{
}
void AbstractClient::doPerformMoveResize()
{
}
bool AbstractClient::isWaitingForMoveResizeSync() const
{
return false;
}
void AbstractClient::doResizeSync()
{
}
void AbstractClient::checkQuickTilingMaximizationZones(int xroot, int yroot)
{
QuickTileMode mode = QuickTileFlag::None;
bool innerBorder = false;
for (int i=0; i < screens()->count(); ++i) {
if (!screens()->geometry(i).contains(QPoint(xroot, yroot)))
continue;
auto isInScreen = [i](const QPoint &pt) {
for (int j = 0; j < screens()->count(); ++j) {
if (j == i)
continue;
if (screens()->geometry(j).contains(pt)) {
return true;
}
}
return false;
};
QRect area = workspace()->clientArea(MaximizeArea, QPoint(xroot, yroot), desktop());
if (options->electricBorderTiling()) {
if (xroot <= area.x() + 20) {
mode |= QuickTileFlag::Left;
innerBorder = isInScreen(QPoint(area.x() - 1, yroot));
} else if (xroot >= area.x() + area.width() - 20) {
mode |= QuickTileFlag::Right;
innerBorder = isInScreen(QPoint(area.right() + 1, yroot));
}
}
if (mode != QuickTileMode(QuickTileFlag::None)) {
if (yroot <= area.y() + area.height() * options->electricBorderCornerRatio())
mode |= QuickTileFlag::Top;
else if (yroot >= area.y() + area.height() - area.height() * options->electricBorderCornerRatio())
mode |= QuickTileFlag::Bottom;
} else if (options->electricBorderMaximize() && yroot <= area.y() + 5 && isMaximizable()) {
mode = QuickTileFlag::Maximize;
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]() {
if (isMove())
setElectricBorderMaximizing(electricBorderMode() != QuickTileMode(QuickTileFlag::None));
});
}
m_electricMaximizingDelay->start();
} else {
setElectricBorderMaximizing(mode != QuickTileMode(QuickTileFlag::None));
}
}
}
void AbstractClient::keyPressEvent(uint key_code)
{
if (!isMove() && !isResize())
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;
QPoint pos = Cursors::self()->mouse()->pos();
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:
setMoveResizePointerButtonDown(false);
finishMoveResize(false);
updateCursor();
break;
case Qt::Key_Escape:
setMoveResizePointerButtonDown(false);
finishMoveResize(true);
updateCursor();
break;
default:
return;
}
Cursors::self()->mouse()->setPos(pos);
}
QSize AbstractClient::resizeIncrements() const
{
return QSize(1, 1);
}
void AbstractClient::dontMoveResize()
{
setMoveResizePointerButtonDown(false);
stopDelayedMoveResize();
if (isMoveResize())
finishMoveResize(false);
}
AbstractClient::Position AbstractClient::mousePosition() const
{
if (isDecorated()) {
switch (decoration()->sectionUnderMouse()) {
case Qt::BottomLeftSection:
return PositionBottomLeft;
case Qt::BottomRightSection:
return PositionBottomRight;
case Qt::BottomSection:
return PositionBottom;
case Qt::LeftSection:
return PositionLeft;
case Qt::RightSection:
return PositionRight;
case Qt::TopSection:
return PositionTop;
case Qt::TopLeftSection:
return PositionTopLeft;
case Qt::TopRightSection:
return PositionTopRight;
default:
return PositionCenter;
}
}
return PositionCenter;
}
void AbstractClient::endMoveResize()
{
setMoveResizePointerButtonDown(false);
stopDelayedMoveResize();
if (isMoveResize()) {
finishMoveResize(false);
setMoveResizePointerMode(mousePosition());
}
updateCursor();
}
void AbstractClient::createDecoration(const QRect &oldGeometry)
{
KDecoration2::Decoration *decoration = Decoration::DecorationBridge::self()->createDecoration(this);
if (decoration) {
QMetaObject::invokeMethod(decoration, "update", Qt::QueuedConnection);
connect(decoration, &KDecoration2::Decoration::shadowChanged, this, &Toplevel::updateShadow);
connect(decoration, &KDecoration2::Decoration::bordersChanged,
this, &AbstractClient::updateDecorationInputShape);
connect(decoration, &KDecoration2::Decoration::resizeOnlyBordersChanged,
this, &AbstractClient::updateDecorationInputShape);
connect(decoration, &KDecoration2::Decoration::bordersChanged, this, [this]() {
GeometryUpdatesBlocker blocker(this);
const QRect oldGeometry = frameGeometry();
if (!isShade()) {
checkWorkspacePosition(oldGeometry);
}
emit geometryShapeChanged(this, oldGeometry);
});
connect(decoratedClient()->decoratedClient(), &KDecoration2::DecoratedClient::sizeChanged,
this, &AbstractClient::updateDecorationInputShape);
}
setDecoration(decoration);
setFrameGeometry(QRect(oldGeometry.topLeft(), clientSizeToFrameSize(clientSize())));
updateDecorationInputShape();
emit geometryShapeChanged(this, oldGeometry);
}
void AbstractClient::destroyDecoration()
{
delete m_decoration.decoration;
m_decoration.decoration = nullptr;
m_decoration.inputRegion = QRegion();
}
void AbstractClient::updateDecorationInputShape()
{
if (!isDecorated()) {
return;
}
const QMargins borders = decoration()->borders();
const QMargins resizeBorders = decoration()->resizeOnlyBorders();
const QRect innerRect = QRect(QPoint(borderLeft(), borderTop()), decoratedClient()->size());
const QRect outerRect = innerRect + borders + resizeBorders;
m_decoration.inputRegion = QRegion(outerRect) - innerRect;
}
bool AbstractClient::decorationHasAlpha() const
{
if (!isDecorated() || decoration()->isOpaque()) {
// either no decoration or decoration has alpha disabled
return false;
}
return true;
}
void AbstractClient::triggerDecorationRepaint()
{
if (isDecorated()) {
decoration()->update();
}
}
void AbstractClient::layoutDecorationRects(QRect &left, QRect &top, QRect &right, QRect &bottom) const
{
if (!isDecorated()) {
return;
}
QRect r = decoration()->rect();
top = QRect(r.x(), r.y(), r.width(), borderTop());
bottom = QRect(r.x(), r.y() + r.height() - borderBottom(),
r.width(), borderBottom());
left = QRect(r.x(), r.y() + top.height(),
borderLeft(), r.height() - top.height() - bottom.height());
right = QRect(r.x() + r.width() - borderRight(), r.y() + top.height(),
borderRight(), r.height() - top.height() - bottom.height());
}
void AbstractClient::processDecorationMove(const QPoint &localPos, const QPoint &globalPos)
{
if (isMoveResizePointerButtonDown()) {
handleMoveResize(localPos.x(), localPos.y(), globalPos.x(), globalPos.y());
return;
}
// TODO: handle modifiers
Position newmode = mousePosition();
if (newmode != moveResizePointerMode()) {
setMoveResizePointerMode(newmode);
updateCursor();
}
}
bool AbstractClient::processDecorationButtonPress(QMouseEvent *event, 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 (event->button() == Qt::LeftButton && titlebarPositionUnderMouse()) {
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 {
Workspace::self()->performWindowOperation(this, options->operationTitlebarDblClick());
dontMoveResize();
return false;
}
}
else {
m_decoration.doubleClickTimer.start(); // new first click and pot. init, could be invalidated by release - see below
}
}
if (event->button() == Qt::LeftButton)
com = active ? options->commandActiveTitlebar1() : options->commandInactiveTitlebar1();
else if (event->button() == Qt::MiddleButton)
com = active ? options->commandActiveTitlebar2() : options->commandInactiveTitlebar2();
else if (event->button() == Qt::RightButton)
com = active ? options->commandActiveTitlebar3() : options->commandInactiveTitlebar3();
if (event->button() == Qt::LeftButton
&& com != Options::MouseOperationsMenu // actions where it's not possible to get the matching
&& com != Options::MouseMinimize) // mouse release event
{
setMoveResizePointerMode(mousePosition());
setMoveResizePointerButtonDown(true);
setMoveOffset(event->pos());
setInvertedMoveOffset(rect().bottomRight() - moveOffset());
setUnrestrictedMoveResize(false);
startDelayedMoveResize();
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)
performMouseCommand(com, event->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 AbstractClient::processDecorationButtonRelease(QMouseEvent *event)
{
if (isDecorated()) {
if (event->isAccepted() || !titlebarPositionUnderMouse()) {
invalidateDecorationDoubleClickTimer(); // click was for the deco and shall not init a doubleclick
}
}
if (event->buttons() == Qt::NoButton) {
setMoveResizePointerButtonDown(false);
stopDelayedMoveResize();
if (isMoveResize()) {
finishMoveResize(false);
setMoveResizePointerMode(mousePosition());
}
updateCursor();
}
}
void AbstractClient::startDecorationDoubleClickTimer()
{
m_decoration.doubleClickTimer.start();
}
void AbstractClient::invalidateDecorationDoubleClickTimer()
{
m_decoration.doubleClickTimer.invalidate();
}
bool AbstractClient::providesContextHelp() const
{
return false;
}
void AbstractClient::showContextHelp()
{
}
QPointer<Decoration::DecoratedClientImpl> AbstractClient::decoratedClient() const
{
return m_decoration.client;
}
void AbstractClient::setDecoratedClient(QPointer< Decoration::DecoratedClientImpl > client)
{
m_decoration.client = client;
}
void AbstractClient::enterEvent(const QPoint &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()->topClientOnDesktop(VirtualDesktopManager::self()->current(),
options->isSeparateScreenFocus() ? screen() : -1) != 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 AbstractClient::leaveEvent()
{
cancelAutoRaise();
workspace()->cancelDelayFocus();
cancelShadeHoverTimer();
startShadeUnhoverTimer();
// TODO: send hover leave to deco
// TODO: handle Options::FocusStrictlyUnderMouse
}
QRect AbstractClient::iconGeometry() const
{
if (!windowManagementInterface() || !waylandServer()) {
// window management interface is only available if the surface is mapped
return QRect();
}
int minDistance = INT_MAX;
AbstractClient *candidatePanel = nullptr;
QRect candidateGeom;
for (auto i = windowManagementInterface()->minimizedGeometries().constBegin(), end = windowManagementInterface()->minimizedGeometries().constEnd(); i != end; ++i) {
AbstractClient *client = waylandServer()->findClient(i.key());
if (!client) {
continue;
}
const int distance = QPoint(client->pos() - pos()).manhattanLength();
if (distance < minDistance) {
minDistance = distance;
candidatePanel = client;
candidateGeom = i.value();
}
}
if (!candidatePanel) {
return QRect();
}
return candidateGeom.translated(candidatePanel->pos());
}
QRect AbstractClient::inputGeometry() const
{
if (isDecorated()) {
return Toplevel::inputGeometry() + decoration()->resizeOnlyBorders();
}
return Toplevel::inputGeometry();
}
bool AbstractClient::hitTest(const QPoint &point) const
{
if (isDecorated()) {
if (m_decoration.inputRegion.contains(mapToFrame(point))) {
return true;
}
}
return Toplevel::hitTest(point);
}
QRect AbstractClient::virtualKeyboardGeometry() const
{
return m_virtualKeyboardGeometry;
}
void AbstractClient::setVirtualKeyboardGeometry(const QRect &geo)
{
// No keyboard anymore
if (geo.isEmpty() && !m_keyboardGeometryRestore.isEmpty()) {
setFrameGeometry(m_keyboardGeometryRestore);
m_keyboardGeometryRestore = QRect();
} else if (geo.isEmpty()) {
return;
// The keyboard has just been opened (rather than resized) save client geometry for a restore
} else if (m_keyboardGeometryRestore.isEmpty()) {
m_keyboardGeometryRestore = frameGeometry();
}
m_virtualKeyboardGeometry = geo;
// Don't resize Desktop and fullscreen windows
if (isFullScreen() || isDesktop()) {
return;
}
if (!geo.intersects(m_keyboardGeometryRestore)) {
return;
}
const QRect availableArea = workspace()->clientArea(MaximizeArea, this);
QRect newWindowGeometry = m_keyboardGeometryRestore;
newWindowGeometry.moveBottom(geo.top());
newWindowGeometry.setTop(qMax(newWindowGeometry.top(), availableArea.top()));
setFrameGeometry(newWindowGeometry);
}
QRect AbstractClient::keyboardGeometryRestore() const
{
return m_keyboardGeometryRestore;
}
void AbstractClient::setKeyboardGeometryRestore(const QRect &geom)
{
m_keyboardGeometryRestore = geom;
}
bool AbstractClient::dockWantsInput() const
{
return false;
}
void AbstractClient::setDesktopFileName(QByteArray name)
{
name = rules()->checkDesktopFile(name).toUtf8();
if (name == m_desktopFileName) {
return;
}
m_desktopFileName = name;
updateWindowRules(Rules::DesktopFile);
emit desktopFileNameChanged();
}
QString AbstractClient::iconFromDesktopFile() const
{
if (m_desktopFileName.isEmpty()) {
return {};
}
const QString desktopFileName = QString::fromUtf8(m_desktopFileName);
QString desktopFilePath;
if (QDir::isAbsolutePath(desktopFileName)) {
desktopFilePath = desktopFileName;
}
if (desktopFilePath.isEmpty()) {
desktopFilePath = QStandardPaths::locate(QStandardPaths::ApplicationsLocation,
desktopFileName);
}
if (desktopFilePath.isEmpty()) {
desktopFilePath = QStandardPaths::locate(QStandardPaths::ApplicationsLocation,
desktopFileName + QLatin1String(".desktop"));
}
KDesktopFile df(desktopFilePath);
return df.readIcon();
}
bool AbstractClient::hasApplicationMenu() const
{
return ApplicationMenu::self()->applicationMenuEnabled() && !m_applicationMenuServiceName.isEmpty() && !m_applicationMenuObjectPath.isEmpty();
}
void AbstractClient::updateApplicationMenuServiceName(const QString &serviceName)
{
const bool old_hasApplicationMenu = hasApplicationMenu();
m_applicationMenuServiceName = serviceName;
const bool new_hasApplicationMenu = hasApplicationMenu();
emit applicationMenuChanged();
if (old_hasApplicationMenu != new_hasApplicationMenu) {
emit hasApplicationMenuChanged(new_hasApplicationMenu);
}
}
void AbstractClient::updateApplicationMenuObjectPath(const QString &objectPath)
{
const bool old_hasApplicationMenu = hasApplicationMenu();
m_applicationMenuObjectPath = objectPath;
const bool new_hasApplicationMenu = hasApplicationMenu();
emit applicationMenuChanged();
if (old_hasApplicationMenu != new_hasApplicationMenu) {
emit hasApplicationMenuChanged(new_hasApplicationMenu);
}
}
void AbstractClient::setApplicationMenuActive(bool applicationMenuActive)
{
if (m_applicationMenuActive != applicationMenuActive) {
m_applicationMenuActive = applicationMenuActive;
emit applicationMenuActiveChanged(applicationMenuActive);
}
}
void AbstractClient::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 AbstractClient::unresponsive() const
{
return m_unresponsive;
}
void AbstractClient::setUnresponsive(bool unresponsive)
{
if (m_unresponsive != unresponsive) {
m_unresponsive = unresponsive;
emit unresponsiveChanged(m_unresponsive);
emit captionChanged();
}
}
QString AbstractClient::shortcutCaptionSuffix() const
{
if (shortcut().isEmpty()) {
return QString();
}
return QLatin1String(" {") + shortcut().toString() + QLatin1Char('}');
}
AbstractClient *AbstractClient::findClientWithSameCaption() const
{
auto fetchNameInternalPredicate = [this](const AbstractClient *cl) {
return (!cl->isSpecialWindow() || cl->isToolbar()) && cl != this && cl->captionNormal() == captionNormal() && cl->captionSuffix() == captionSuffix();
};
return workspace()->findAbstractClient(fetchNameInternalPredicate);
}
QString AbstractClient::caption() const
{
QString cap = captionNormal() + captionSuffix();
if (unresponsive()) {
cap += QLatin1String(" ");
cap += i18nc("Application is not responding, appended to window title", "(Not Responding)");
}
return cap;
}
void AbstractClient::removeRule(Rules* rule)
{
m_rules.remove(rule);
}
void AbstractClient::discardTemporaryRules()
{
m_rules.discardTemporary();
}
void AbstractClient::evaluateWindowRules()
{
setupWindowRules(true);
applyWindowRules();
}
void AbstractClient::setOnActivities(QStringList newActivitiesList)
{
Q_UNUSED(newActivitiesList)
}
void AbstractClient::checkNoBorder()
{
setNoBorder(false);
}
bool AbstractClient::groupTransient() const
{
return false;
}
const Group *AbstractClient::group() const
{
return nullptr;
}
Group *AbstractClient::group()
{
return nullptr;
}
bool AbstractClient::isInternal() const
{
return false;
}
bool AbstractClient::supportsWindowRules() const
{
return false;
}
QMargins AbstractClient::frameMargins() const
{
return QMargins(borderLeft(), borderTop(), borderRight(), borderBottom());
}
QPoint AbstractClient::framePosToClientPos(const QPoint &point) const
{
return point + QPoint(borderLeft(), borderTop());
}
QPoint AbstractClient::clientPosToFramePos(const QPoint &point) const
{
return point - QPoint(borderLeft(), borderTop());
}
QSize AbstractClient::frameSizeToClientSize(const QSize &size) const
{
const int width = size.width() - borderLeft() - borderRight();
const int height = size.height() - borderTop() - borderBottom();
return QSize(width, height);
}
QSize AbstractClient::clientSizeToFrameSize(const QSize &size) const
{
const int width = size.width() + borderLeft() + borderRight();
const int height = size.height() + borderTop() + borderBottom();
return QSize(width, height);
}
QRect AbstractClient::frameRectToClientRect(const QRect &rect) const
{
const QPoint position = framePosToClientPos(rect.topLeft());
const QSize size = frameSizeToClientSize(rect.size());
return QRect(position, size);
}
QRect AbstractClient::clientRectToFrameRect(const QRect &rect) const
{
const QPoint position = clientPosToFramePos(rect.topLeft());
const QSize size = clientSizeToFrameSize(rect.size());
return QRect(position, size);
}
void AbstractClient::setElectricBorderMode(QuickTileMode mode)
{
if (mode != QuickTileMode(QuickTileFlag::Maximize)) {
// 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);
}
m_electricMode = mode;
}
void AbstractClient::setElectricBorderMaximizing(bool maximizing)
{
m_electricMaximizing = maximizing;
if (maximizing)
outline()->show(electricBorderMaximizeGeometry(Cursors::self()->mouse()->pos(), desktop()), moveResizeGeometry());
else
outline()->hide();
elevate(maximizing);
}
QRect AbstractClient::electricBorderMaximizeGeometry(QPoint pos, int desktop)
{
if (electricBorderMode() == QuickTileMode(QuickTileFlag::Maximize)) {
if (maximizeMode() == MaximizeFull)
return geometryRestore();
else
return workspace()->clientArea(MaximizeArea, pos, desktop);
}
QRect ret = workspace()->clientArea(MaximizeArea, pos, desktop);
if (electricBorderMode() & QuickTileFlag::Left)
ret.setRight(ret.left()+ret.width()/2 - 1);
else if (electricBorderMode() & QuickTileFlag::Right)
ret.setLeft(ret.right()-(ret.width()-ret.width()/2) + 1);
if (electricBorderMode() & QuickTileFlag::Top)
ret.setBottom(ret.top()+ret.height()/2 - 1);
else if (electricBorderMode() & QuickTileFlag::Bottom)
ret.setTop(ret.bottom()-(ret.height()-ret.height()/2) + 1);
return ret;
}
void AbstractClient::setQuickTileMode(QuickTileMode mode, bool keyboard)
{
// Only allow quick tile on a regular window.
if (!isResizable()) {
return;
}
workspace()->updateFocusMousePosition(Cursors::self()->mouse()->pos()); // may cause leave event
GeometryUpdatesBlocker blocker(this);
if (mode == QuickTileMode(QuickTileFlag::Maximize)) {
m_quickTileMode = int(QuickTileFlag::None);
if (maximizeMode() == MaximizeFull) {
setMaximize(false, false);
} else {
QRect prev_geom_restore = geometryRestore(); // setMaximize() would set moveResizeGeom as geom_restore
m_quickTileMode = int(QuickTileFlag::Maximize);
setMaximize(true, true);
QRect clientArea = workspace()->clientArea(MaximizeArea, this);
if (frameGeometry().top() != clientArea.top()) {
QRect r(frameGeometry());
r.moveTop(clientArea.top());
setFrameGeometry(r);
}
setGeometryRestore(prev_geom_restore);
}
doSetQuickTileMode();
emit quickTileModeChanged();
return;
}
// 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);
setElectricBorderMode(mode); // used by ::electricBorderMaximizeGeometry(.)
// restore from maximized so that it is possible to tile maximized windows with one hit or by dragging
if (maximizeMode() != MaximizeRestore) {
if (mode != QuickTileMode(QuickTileFlag::None)) {
// decorations may turn off some borders when tiled
const ForceGeometry_t geom_mode = isDecorated() ? ForceGeometrySet : NormalGeometrySet;
m_quickTileMode = int(QuickTileFlag::None); // Temporary, so the maximize code doesn't get all confused
setMaximize(false, false);
setFrameGeometry(electricBorderMaximizeGeometry(keyboard ? frameGeometry().center() : Cursors::self()->mouse()->pos(), desktop()), geom_mode);
// Store the mode change
m_quickTileMode = mode;
} else {
m_quickTileMode = mode;
setMaximize(false, false);
}
doSetQuickTileMode();
emit quickTileModeChanged();
return;
}
if (mode != QuickTileMode(QuickTileFlag::None)) {
QPoint whichScreen = keyboard ? frameGeometry().center() : Cursors::self()->mouse()->pos();
// If trying to tile to the side that the window is already tiled to move the window to the next
// screen if it exists, otherwise toggle the mode (set QuickTileFlag::None)
if (quickTileMode() == mode) {
const int numScreens = screens()->count();
const int curScreen = screen();
int nextScreen = curScreen;
QVarLengthArray<QRect> screens(numScreens);
for (int i = 0; i < numScreens; ++i) // Cache
screens[i] = Screens::self()->geometry(i);
for (int i = 0; i < numScreens; ++i) {
if (i == curScreen)
continue;
if (screens[i].bottom() <= screens[curScreen].top() || screens[i].top() >= screens[curScreen].bottom())
continue; // not in horizontal line
const int x = screens[i].center().x();
if ((mode & QuickTileFlag::Horizontal) == QuickTileMode(QuickTileFlag::Left)) {
if (x >= screens[curScreen].center().x() || (curScreen != nextScreen && x <= screens[nextScreen].center().x()))
continue; // not left of current or more left then found next
} else if ((mode & QuickTileFlag::Horizontal) == QuickTileMode(QuickTileFlag::Right)) {
if (x <= screens[curScreen].center().x() || (curScreen != nextScreen && x >= screens[nextScreen].center().x()))
continue; // not right of current or more right then found next
}
nextScreen = i;
}
if (nextScreen == curScreen) {
mode = QuickTileFlag::None; // No other screens, toggle tiling
} else {
// Move to other screen
setFrameGeometry(geometryRestore().translated(screens[nextScreen].topLeft() - screens[curScreen].topLeft()));
whichScreen = screens[nextScreen].center();
// Swap sides
if (mode & QuickTileFlag::Horizontal) {
mode = (~mode & QuickTileFlag::Horizontal) | (mode & QuickTileFlag::Vertical);
}
}
setElectricBorderMode(mode); // used by ::electricBorderMaximizeGeometry(.)
} else if (quickTileMode() == QuickTileMode(QuickTileFlag::None)) {
// 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(frameGeometry());
}
if (mode != QuickTileMode(QuickTileFlag::None)) {
m_quickTileMode = mode;
// decorations may turn off some borders when tiled
const ForceGeometry_t geom_mode = isDecorated() ? ForceGeometrySet : NormalGeometrySet;
// Temporary, so the maximize code doesn't get all confused
m_quickTileMode = int(QuickTileFlag::None);
setFrameGeometry(electricBorderMaximizeGeometry(whichScreen, desktop()), geom_mode);
}
// Store the mode change
m_quickTileMode = mode;
}
if (mode == QuickTileMode(QuickTileFlag::None)) {
m_quickTileMode = int(QuickTileFlag::None);
// Untiling, so just restore geometry, and we're done.
if (!geometryRestore().isValid()) // invalid if we started maximized and wait for placement
setGeometryRestore(frameGeometry());
// decorations may turn off some borders when tiled
const ForceGeometry_t geom_mode = isDecorated() ? ForceGeometrySet : NormalGeometrySet;
setFrameGeometry(geometryRestore(), geom_mode);
checkWorkspacePosition(); // Just in case it's a different screen
}
doSetQuickTileMode();
emit quickTileModeChanged();
}
void AbstractClient::doSetQuickTileMode()
{
}
void AbstractClient::sendToScreen(int newScreen)
{
newScreen = rules()->checkScreen(newScreen);
if (isActive()) {
screens()->setCurrent(newScreen);
// might impact the layer of a fullscreen window
foreach (AbstractClient *cc, workspace()->allClientList()) {
if (cc->isFullScreen() && cc->screen() == newScreen) {
cc->updateLayer();
}
}
}
if (screen() == newScreen && !isFullScreen()) // Don't use isOnScreen(), that's true even when only partially
return;
GeometryUpdatesBlocker blocker(this);
// operating on the maximized / quicktiled window would leave the old geom_restore behind,
// so we clear the state first
MaximizeMode maxMode = maximizeMode();
QuickTileMode qtMode = quickTileMode();
if (maxMode != MaximizeRestore)
maximize(MaximizeRestore);
if (qtMode != QuickTileMode(QuickTileFlag::None))
setQuickTileMode(QuickTileFlag::None, true);
QRect oldScreenArea = workspace()->clientArea(MaximizeArea, this);
QRect screenArea = workspace()->clientArea(MaximizeArea, newScreen, desktop());
// the window can have its center so that the position correction moves the new center onto
// the old screen, what will tile it where it is. Ie. the screen is not changed
// this happens esp. with electric border quicktiling
if (qtMode != QuickTileMode(QuickTileFlag::None))
keepInArea(oldScreenArea);
QRect oldGeom = frameGeometry();
QRect newGeom = oldGeom;
// 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)
QPoint center = newGeom.center() - oldScreenArea.center();
center.setX(center.x() * screenArea.width() / oldScreenArea.width());
center.setY(center.y() * screenArea.height() / oldScreenArea.height());
center += screenArea.center();
newGeom.moveCenter(center);
setFrameGeometry(newGeom);
// If the window was inside the old screen area, explicitly make sure its inside also the new screen area.
// Calling checkWorkspacePosition() should ensure that, but when moving to a small screen the window could
// be big enough to overlap outside of the new screen area, making struts from other screens come into effect,
// which could alter the resulting geometry.
if (oldScreenArea.contains(oldGeom)) {
keepInArea(screenArea);
}
if (isFullScreen()) {
QRect newFullScreenGeometryRestore = screenArea;
if (!(maximizeMode() & MaximizeVertical)) {
newFullScreenGeometryRestore.setHeight(geometryRestore().height());
}
if (!(maximizeMode() & MaximizeHorizontal)) {
newFullScreenGeometryRestore.setWidth(geometryRestore().width());
}
newFullScreenGeometryRestore.setSize(newFullScreenGeometryRestore.size().boundedTo(screenArea.size()));
QSize move = (screenArea.size() - newFullScreenGeometryRestore.size()) / 2;
newFullScreenGeometryRestore.translate(move.width(), move.height());
QRect newGeometryRestore = QRect(screenArea.topLeft(), geometryRestore().size().boundedTo(screenArea.size()));
move = (screenArea.size() - newGeometryRestore.size()) / 2;
newGeometryRestore.translate(move.width(), move.height());
setFullscreenGeometryRestore(newFullScreenGeometryRestore);
setGeometryRestore(newGeometryRestore);
checkWorkspacePosition(oldGeom);
} else {
// align geom_restore - checkWorkspacePosition operates on it
setGeometryRestore(frameGeometry());
checkWorkspacePosition(oldGeom);
// re-align geom_restore to constrained geometry
setGeometryRestore(frameGeometry());
}
// finally reset special states
// NOTICE that MaximizeRestore/QuickTileFlag::None checks are required.
// eg. setting QuickTileFlag::None would break maximization
if (maxMode != MaximizeRestore)
maximize(maxMode);
if (qtMode != QuickTileMode(QuickTileFlag::None) && qtMode != quickTileMode())
setQuickTileMode(qtMode, true);
auto tso = workspace()->ensureStackingOrder(transients());
for (auto it = tso.constBegin(), end = tso.constEnd(); it != end; ++it)
(*it)->sendToScreen(newScreen);
}
void AbstractClient::checkWorkspacePosition(QRect oldGeometry, int oldDesktop, QRect oldClientGeometry)
{
if (isDock() || isDesktop() || !isPlaceable()) {
return;
}
enum { Left = 0, Top, Right, Bottom };
const int border[4] = { borderLeft(), borderTop(), borderRight(), borderBottom() };
if( !oldGeometry.isValid())
oldGeometry = frameGeometry();
if( oldDesktop == -2 )
oldDesktop = desktop();
if (!oldClientGeometry.isValid())
oldClientGeometry = oldGeometry.adjusted(border[Left], border[Top], -border[Right], -border[Bottom]);
if (isFullScreen()) {
QRect area = workspace()->clientArea(FullScreenArea, fullscreenGeometryRestore().center(), desktop());
if (frameGeometry() != area)
setFrameGeometry(area);
return;
}
if (maximizeMode() != MaximizeRestore) {
GeometryUpdatesBlocker block(this);
changeMaximize(false, false, true); // adjust size
const QRect screenArea = workspace()->clientArea(ScreenArea, this);
QRect geom = frameGeometry();
checkOffscreenPosition(&geom, screenArea);
setFrameGeometry(geom);
return;
}
if (quickTileMode() != QuickTileMode(QuickTileFlag::None)) {
setFrameGeometry(electricBorderMaximizeGeometry(frameGeometry().center(), desktop()));
return;
}
// this can be true only if this window was mapped before KWin
// was started - in such case, don't adjust position to workarea,
// because the window already had its position, and if a window
// with a strut altering the workarea would be managed in initialization
// after this one, this window would be moved
if (!workspace() || workspace()->initializing())
return;
// 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;
if( workspace()->inUpdateClientArea()) {
// we need to find the screen area as it was before the change
oldScreenArea = QRect( 0, 0, workspace()->oldDisplayWidth(), workspace()->oldDisplayHeight());
int distance = INT_MAX;
foreach(const QRect &r, workspace()->previousScreenSizes()) {
int d = r.contains( oldGeometry.center()) ? 0 : ( r.center() - oldGeometry.center()).manhattanLength();
if( d < distance ) {
distance = d;
oldScreenArea = r;
}
}
} else {
oldScreenArea = workspace()->clientArea(ScreenArea, oldGeometry.center(), oldDesktop);
}
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();
const QRect screenArea = workspace()->clientArea(ScreenArea, geometryRestore().center(), desktop());
int topMax = screenArea.y();
int rightMax = screenArea.x() + screenArea.width();
int bottomMax = screenArea.y() + screenArea.height();
int leftMax = screenArea.x();
QRect newGeom = geometryRestore(); // geometry();
QRect newClientGeom = newGeom.adjusted(border[Left], border[Top], -border[Right], -border[Bottom]);
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()->inUpdateClientArea() ?
&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 = qMax(oldTopMax, rect.y() + rect.height());
}
for (const QRect &r : (workspace()->*moveAreaFunc)(oldDesktop, StrutAreaRight)) {
QRect rect = r & oldGeomWide;
if (!rect.isEmpty())
oldRightMax = qMin(oldRightMax, rect.x());
}
for (const QRect &r : (workspace()->*moveAreaFunc)(oldDesktop, StrutAreaBottom)) {
QRect rect = r & oldGeomTall;
if (!rect.isEmpty())
oldBottomMax = qMin(oldBottomMax, rect.y());
}
for (const QRect &r : (workspace()->*moveAreaFunc)(oldDesktop, StrutAreaLeft)) {
QRect rect = r & oldGeomWide;
if (!rect.isEmpty())
oldLeftMax = qMax(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 = qMax(topMax, rect.y() + rect.height());
}
for (const QRect &r : workspace()->restrictedMoveArea(desktop(), StrutAreaRight)) {
QRect rect = r & newGeomWide;
if (!rect.isEmpty())
rightMax = qMin(rightMax, rect.x());
}
for (const QRect &r : workspace()->restrictedMoveArea(desktop(), StrutAreaBottom)) {
QRect rect = r & newGeomTall;
if (!rect.isEmpty())
bottomMax = qMin(bottomMax, rect.y());
}
for (const QRect &r : workspace()->restrictedMoveArea(desktop(), StrutAreaLeft)) {
QRect rect = r & newGeomWide;
if (!rect.isEmpty())
leftMax = qMax(leftMax, rect.x() + rect.width());
}
// Check if the sides were inside or touching but are no longer
bool keep[4] = {false, false, false, false};
bool save[4] = {false, false, false, false};
int padding[4] = {0, 0, 0, 0};
if (oldGeometry.x() >= oldLeftMax)
save[Left] = newGeom.x() < leftMax;
if (oldGeometry.x() == oldLeftMax)
keep[Left] = newGeom.x() != leftMax;
else if (oldClientGeometry.x() == oldLeftMax && newClientGeom.x() != leftMax) {
padding[0] = border[Left];
keep[Left] = true;
}
if (oldGeometry.y() >= oldTopMax)
save[Top] = newGeom.y() < topMax;
if (oldGeometry.y() == oldTopMax)
keep[Top] = newGeom.y() != topMax;
else if (oldClientGeometry.y() == oldTopMax && newClientGeom.y() != topMax) {
padding[1] = border[Left];
keep[Top] = true;
}
if (oldGeometry.right() <= oldRightMax - 1)
save[Right] = newGeom.right() > rightMax - 1;
if (oldGeometry.right() == oldRightMax - 1)
keep[Right] = newGeom.right() != rightMax - 1;
else if (oldClientGeometry.right() == oldRightMax - 1 && newClientGeom.right() != rightMax - 1) {
padding[2] = border[Right];
keep[Right] = true;
}
if (oldGeometry.bottom() <= oldBottomMax - 1)
save[Bottom] = newGeom.bottom() > bottomMax - 1;
if (oldGeometry.bottom() == oldBottomMax - 1)
keep[Bottom] = newGeom.bottom() != bottomMax - 1;
else if (oldClientGeometry.bottom() == oldBottomMax - 1 && newClientGeom.bottom() != bottomMax - 1) {
padding[3] = border[Bottom];
keep[Bottom] = true;
}
// if randomly touches opposing edges, do not favor either
if (keep[Left] && keep[Right]) {
keep[Left] = keep[Right] = false;
padding[0] = padding[2] = 0;
}
if (keep[Top] && keep[Bottom]) {
keep[Top] = keep[Bottom] = false;
padding[1] = padding[3] = 0;
}
if (save[Left] || keep[Left])
newGeom.moveLeft(qMax(leftMax, screenArea.x()) - padding[0]);
if (padding[0] && screens()->intersecting(newGeom) > 1)
newGeom.moveLeft(newGeom.left() + padding[0]);
if (save[Top] || keep[Top])
newGeom.moveTop(qMax(topMax, screenArea.y()) - padding[1]);
if (padding[1] && screens()->intersecting(newGeom) > 1)
newGeom.moveTop(newGeom.top() + padding[1]);
if (save[Right] || keep[Right])
newGeom.moveRight(qMin(rightMax - 1, screenArea.right()) + padding[2]);
if (padding[2] && screens()->intersecting(newGeom) > 1)
newGeom.moveRight(newGeom.right() - padding[2]);
if (oldGeometry.x() >= oldLeftMax && newGeom.x() < leftMax)
newGeom.setLeft(qMax(leftMax, screenArea.x()));
else if (oldClientGeometry.x() >= oldLeftMax && newGeom.x() + border[Left] < leftMax) {
newGeom.setLeft(qMax(leftMax, screenArea.x()) - border[Left]);
if (screens()->intersecting(newGeom) > 1)
newGeom.setLeft(newGeom.left() + border[Left]);
}
if (save[Bottom] || keep[Bottom])
newGeom.moveBottom(qMin(bottomMax - 1, screenArea.bottom()) + padding[3]);
if (padding[3] && screens()->intersecting(newGeom) > 1)
newGeom.moveBottom(newGeom.bottom() - padding[3]);
if (oldGeometry.y() >= oldTopMax && newGeom.y() < topMax)
newGeom.setTop(qMax(topMax, screenArea.y()));
else if (oldClientGeometry.y() >= oldTopMax && newGeom.y() + border[Top] < topMax) {
newGeom.setTop(qMax(topMax, screenArea.y()) - border[Top]);
if (screens()->intersecting(newGeom) > 1)
newGeom.setTop(newGeom.top() + border[Top]);
}
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()));
if (newGeom != frameGeometry())
setFrameGeometry(newGeom);
}
void AbstractClient::checkOffscreenPosition(QRect* geom, const QRect& 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);
}
}
/**
* Returns the appropriate frame size for the current client size.
*
* This is equivalent to clientSizeToFrameSize(constrainClientSize(clientSize())).
*/
QSize AbstractClient::adjustedSize() const
{
return clientSizeToFrameSize(constrainClientSize(clientSize()));
}
/**
* 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.
*/
QSize AbstractClient::constrainClientSize(const QSize &size, SizeMode mode) const
{
Q_UNUSED(mode)
int width = size.width();
int 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 QSize minimumSize = minSize();
const QSize maximumSize = maxSize();
width = qBound(minimumSize.width(), width, maximumSize.width());
height = qBound(minimumSize.height(), height, maximumSize.height());
return QSize(width, height);
}
/**
* Constrains the frame size @p size according to a set of the window's size hints.
*/
QSize AbstractClient::constrainFrameSize(const QSize &size, SizeMode mode) const
{
const QSize unconstrainedClientSize = frameSizeToClientSize(size);
const QSize constrainedClientSize = constrainClientSize(unconstrainedClientSize, mode);
return clientSizeToFrameSize(constrainedClientSize);
}
/**
* Returns @c true if the AbstractClient can be shown in full screen mode; otherwise @c false.
*
* Default implementation returns @c false.
*/
bool AbstractClient::isFullScreenable() const
{
return false;
}
/**
* Returns @c true if the AbstractClient is currently being shown in full screen mode; otherwise @c false.
*
* A client in full screen mode occupies the entire screen with no window frame around it.
*
* Default implementation returns @c false.
*/
bool AbstractClient::isFullScreen() const
{
return false;
}
/**
* Returns whether requests initiated by the user to enter or leave full screen mode are honored.
*
* Default implementation returns @c false.
*/
bool AbstractClient::userCanSetFullScreen() const
{
return false;
}
/**
* Asks the AbstractClient to enter or leave full screen mode.
*
* Default implementation does nothing.
*
* @param set @c true if the AbstractClient has to be shown in full screen mode, otherwise @c false
* @param user @c true if the request is initiated by the user, otherwise @c false
*/
void AbstractClient::setFullScreen(bool set, bool user)
{
Q_UNUSED(set)
Q_UNUSED(user)
qCWarning(KWIN_CORE, "%s doesn't support setting fullscreen state", metaObject()->className());
}
/**
* Returns @c true if the AbstractClient can be minimized; otherwise @c false.
*
* Default implementation returns @c false.
*/
bool AbstractClient::isMinimizable() const
{
return false;
}
/**
* Returns @c true if the AbstractClient can be maximized; otherwise @c false.
*
* Default implementation returns @c false.
*/
bool AbstractClient::isMaximizable() const
{
return false;
}
/**
* Returns the currently applied maximize mode.
*
* Default implementation returns MaximizeRestore.
*/
MaximizeMode AbstractClient::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 AbstractClient::requestedMaximizeMode() const
{
return maximizeMode();
}
/**
* Returns the geometry of the AbstractClient before it was maximized or quick tiled.
*/
QRect AbstractClient::geometryRestore() const
{
return m_maximizeGeometryRestore;
}
/**
* Sets the geometry of the AbstractClient before it was maximized or quick tiled to @p rect.
*/
void AbstractClient::setGeometryRestore(const QRect &rect)
{
m_maximizeGeometryRestore = rect;
}
/**
* Toggles the maximized state along specified dimensions @p horizontal and @p vertical.
*
* If @p adjust is @c true, only frame geometry will be updated to match requestedMaximizeMode().
*
* Default implementation does nothing.
*/
void AbstractClient::changeMaximize(bool horizontal, bool vertical, bool adjust)
{
Q_UNUSED(horizontal)
Q_UNUSED(vertical)
Q_UNUSED(adjust)
qCWarning(KWIN_CORE, "%s doesn't support setting maximized state", metaObject()->className());
}
void AbstractClient::updateDecoration(bool check_workspace_pos, bool force)
{
Q_UNUSED(check_workspace_pos)
Q_UNUSED(force)
qCWarning(KWIN_CORE, "%s doesn't support server side decorations", metaObject()->className());
}
bool AbstractClient::noBorder() const
{
return true;
}
bool AbstractClient::userCanSetNoBorder() const
{
return false;
}
void AbstractClient::setNoBorder(bool set)
{
Q_UNUSED(set)
qCWarning(KWIN_CORE, "%s doesn't support setting decorations", metaObject()->className());
}
void AbstractClient::showOnScreenEdge()
{
qCWarning(KWIN_CORE, "%s doesn't support screen edge activation", metaObject()->className());
}
bool AbstractClient::isPlaceable() const
{
return true;
}
QRect AbstractClient::fullscreenGeometryRestore() const
{
return m_fullscreenGeometryRestore;
}
void AbstractClient::setFullscreenGeometryRestore(const QRect &geom)
{
m_fullscreenGeometryRestore = geom;
}
}