kwin/abstract_client.cpp
Aleix Pol 6abd23ed02 Make it possible to have a separate cursor for the tablet
Summary:
As is KWin only had 1 Cursor which was a singleton. This made it impossible for
us to properly implement the tablet (as in drawing tablets) support and show where
we're drawing.
This patch makes it possible to have different Cursors in KWin, it makes all the
current code still follow the mouse but the tablet can still render a cursor.

Test Plan: Tests pass, been using it and works as well as before but with beautiful tablet cursors.

Reviewers: #kwin, cblack, davidedmundson

Reviewed By: #kwin, cblack, davidedmundson

Subscribers: davidedmundson, cblack, kwin

Tags: #kwin

Differential Revision: https://phabricator.kde.org/D28155
2020-04-03 01:16:45 +02:00

3302 lines
114 KiB
C++

/********************************************************************
KWin - the KDE window manager
This file is part of the KDE project.
Copyright (C) 2015 Martin Gräßlin <mgraesslin@kde.org>
Copyright (C) 2019 Vlad Zahorodnii <vlad.zahorodnii@kde.org>
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>.
*********************************************************************/
#include "abstract_client.h"
#include "appmenu.h"
#include "decorations/decoratedclient.h"
#include "decorations/decorationpalette.h"
#include "decorations/decorationbridge.h"
#include "cursor.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 <KWayland/Server/plasmawindowmanagement_interface.h>
#include <KDecoration2/Decoration>
#include <KDesktopFile>
#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() && !isInitialPositionSet()) {
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 (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()
{
}
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 (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::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;
}
bool AbstractClient::isShadeable() const
{
return false;
}
void AbstractClient::setShade(bool set)
{
set ? setShade(ShadeNormal) : setShade(ShadeNone);
}
void AbstractClient::setShade(ShadeMode mode)
{
Q_UNUSED(mode)
}
ShadeMode AbstractClient::shadeMode() const
{
return 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);
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();
}
void AbstractClient::updateColorScheme(QString path)
{
if (path.isEmpty()) {
path = QStringLiteral("kdeglobals");
}
if (!m_palette || m_colorScheme != path) {
m_colorScheme = path;
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::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 = maximizeMode();
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;
}
doMove(x, y);
updateWindowRules(Rules::Position);
screens()->setCurrent(this);
workspace()->updateStackingOrder();
// client itself is not damaged
emit frameGeometryChanged(this, frameGeometryBeforeUpdateBlocking());
addRepaintDuringGeometryUpdates();
updateGeometryBeforeUpdateBlocking();
}
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());
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();
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) {
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 immediatelly,
// 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);
}
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 KWayland::Server;
auto w = waylandServer()->windowManagement()->createWindow(waylandServer()->windowManagement());
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()) {
*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::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;
}
void AbstractClient::updateGeometryBeforeUpdateBlocking()
{
m_bufferGeometryBeforeUpdateBlocking = bufferGeometry();
m_frameGeometryBeforeUpdateBlocking = frameGeometry();
}
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::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, [this]() {
GeometryUpdatesBlocker blocker(this);
const QRect oldGeometry = frameGeometry();
if (!isShade()) {
checkWorkspacePosition(oldGeometry);
}
emit geometryShapeChanged(this, oldGeometry);
});
}
setDecoration(decoration);
setFrameGeometry(QRect(oldGeometry.topLeft(), clientSizeToFrameSize(clientSize())));
emit geometryShapeChanged(this, oldGeometry);
}
void AbstractClient::destroyDecoration()
{
delete m_decoration.decoration;
m_decoration.decoration = nullptr;
}
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::MidButton)
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)
{
// TODO: shade hover
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();
// TODO: shade hover
// 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();
}
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);
}
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 QString();
}
QString desktopFile = QString::fromUtf8(m_desktopFileName);
if (!desktopFile.endsWith(QLatin1String(".desktop"))) {
desktopFile.append(QLatin1String(".desktop"));
}
KDesktopFile df(desktopFile);
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 true;
}
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);
}
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);
}
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
}
emit quickTileModeChanged();
}
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) // 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);
}
// 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)
{
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 (isDesktop())
return;
if (isFullScreen()) {
QRect area = workspace()->clientArea(FullScreenArea, this);
if (frameGeometry() != area)
setFrameGeometry(area);
return;
}
if (isDock())
return;
if (maximizeMode() != MaximizeRestore) {
// TODO update geom_restore?
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)
}
/**
* 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)
}
}