kwin/autotests/integration/test_helpers.cpp

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2020-08-02 22:22:19 +00:00
/*
KWin - the KDE window manager
This file is part of the KDE project.
2020-08-02 22:22:19 +00:00
SPDX-FileCopyrightText: 2015 Martin Gräßlin <mgraesslin@kde.org>
2020-08-02 22:22:19 +00:00
SPDX-License-Identifier: GPL-2.0-or-later
*/
#include <config-kwin.h>
#include "kwin_wayland_test.h"
#if KWIN_BUILD_SCREENLOCKER
#include "screenlockerwatcher.h"
#endif
#include "inputmethod.h"
#include "wayland/display.h"
#include "wayland_server.h"
#include "workspace.h"
#include <wayland-zkde-screencast-unstable-v1-client-protocol.h>
#include <KWayland/Client/appmenu.h>
#include <KWayland/Client/compositor.h>
#include <KWayland/Client/connection_thread.h>
#include <KWayland/Client/event_queue.h>
#include <KWayland/Client/output.h>
#include <KWayland/Client/plasmashell.h>
#include <KWayland/Client/plasmawindowmanagement.h>
Implement support for pointer constraints Summary: There are two types of constraints supported: 1. Pointer confinement 2. Pointer locking In the case of confinement the pointer is confined to a given region of the surface. This is comparable to general operation where the pointer is confined to the screen region. In the second case the pointer gets locked. That means it cannot move at all. No further position updates are provided, only relative motion events can go to the application. There is a hint about cursor position update on unlock which is not yet implemented in KWayland::Server, thus also not in this change. The implementation in KWin grants the requests for pointer constraints when the pointer enters the constrained region, either by pointer movement or by e.g. stacking order changes. There is no confirmation from user required to enter that mode. But we want to show an OSD when the pointer gets constrained, this is not yet implemented, though. Breaking an active constraint is relatively easy. E.g. changing the stacking order will break the constraint if another surface is under the cursor. Also (in case of confinement) moving the pointer to an overlapping window breaks the confinement. But as soon as one moves the pointer back to the window a constraint might get honoured again. To properly break there is a dedicated event filter. It listens for a long press of the Escape key. If hold for 3sec the pointer constraint is broken and not activated again till the pointer got moved out of the window. Afterward when moving in the pointer might activate again. The escape filter ensures that the key press is forwarded to the application if it's a short press or if another key gets pressed during the three seconds. If the three seconds way fires, the later escape release is not sent to the application. This basic interaction is also ensured through an added auto test. This change implements T4605. Test Plan: Added auto test and nested KWin Wayland with D3488 Reviewers: #kwin, #plasma_on_wayland Subscribers: plasma-devel, kwin Tags: #plasma_on_wayland, #kwin Differential Revision: https://phabricator.kde.org/D3506
2016-11-25 06:17:43 +00:00
#include <KWayland/Client/pointerconstraints.h>
#include <KWayland/Client/registry.h>
#include <KWayland/Client/seat.h>
#include <KWayland/Client/server_decoration.h>
#include <KWayland/Client/shadow.h>
#include <KWayland/Client/shm_pool.h>
#include <KWayland/Client/subcompositor.h>
#include <KWayland/Client/subsurface.h>
#include <KWayland/Client/surface.h>
#include <KWayland/Client/textinput.h>
// screenlocker
#if KWIN_BUILD_SCREENLOCKER
#include <KScreenLocker/KsldApp>
#endif
#include <QFutureWatcher>
#include <QThread>
#include <QtConcurrent>
// system
#include <sys/socket.h>
#include <sys/types.h>
#include <unistd.h>
#include <xf86drm.h>
namespace KWin
{
namespace Test
{
LayerShellV1::~LayerShellV1()
{
destroy();
}
LayerSurfaceV1::~LayerSurfaceV1()
{
destroy();
}
void LayerSurfaceV1::zwlr_layer_surface_v1_configure(uint32_t serial, uint32_t width, uint32_t height)
{
Q_EMIT configureRequested(serial, QSize(width, height));
}
void LayerSurfaceV1::zwlr_layer_surface_v1_closed()
{
Q_EMIT closeRequested();
}
XdgShell::~XdgShell()
{
destroy();
}
XdgSurface::XdgSurface(XdgShell *shell, KWayland::Client::Surface *surface, QObject *parent)
: QObject(parent)
, QtWayland::xdg_surface(shell->get_xdg_surface(*surface))
, m_surface(surface)
{
}
XdgSurface::~XdgSurface()
{
destroy();
}
KWayland::Client::Surface *XdgSurface::surface() const
{
return m_surface;
}
void XdgSurface::xdg_surface_configure(uint32_t serial)
{
Q_EMIT configureRequested(serial);
}
XdgToplevel::XdgToplevel(XdgSurface *surface, QObject *parent)
: QObject(parent)
, QtWayland::xdg_toplevel(surface->get_toplevel())
, m_xdgSurface(surface)
{
}
XdgToplevel::~XdgToplevel()
{
destroy();
}
XdgSurface *XdgToplevel::xdgSurface() const
{
return m_xdgSurface.get();
}
void XdgToplevel::xdg_toplevel_configure(int32_t width, int32_t height, wl_array *states)
{
States requestedStates;
const uint32_t *stateData = static_cast<const uint32_t *>(states->data);
const size_t stateCount = states->size / sizeof(uint32_t);
for (size_t i = 0; i < stateCount; ++i) {
switch (stateData[i]) {
case QtWayland::xdg_toplevel::state_maximized:
requestedStates |= State::Maximized;
break;
case QtWayland::xdg_toplevel::state_fullscreen:
requestedStates |= State::Fullscreen;
break;
case QtWayland::xdg_toplevel::state_resizing:
requestedStates |= State::Resizing;
break;
case QtWayland::xdg_toplevel::state_activated:
requestedStates |= State::Activated;
break;
}
}
Q_EMIT configureRequested(QSize(width, height), requestedStates);
}
void XdgToplevel::xdg_toplevel_close()
{
Q_EMIT closeRequested();
}
XdgPositioner::XdgPositioner(XdgShell *shell)
: QtWayland::xdg_positioner(shell->create_positioner())
{
}
XdgPositioner::~XdgPositioner()
{
destroy();
}
XdgPopup::XdgPopup(XdgSurface *surface, XdgSurface *parentSurface, XdgPositioner *positioner, QObject *parent)
: QObject(parent)
, QtWayland::xdg_popup(surface->get_popup(parentSurface->object(), positioner->object()))
, m_xdgSurface(surface)
{
}
XdgPopup::~XdgPopup()
{
destroy();
}
XdgSurface *XdgPopup::xdgSurface() const
{
return m_xdgSurface.get();
}
void XdgPopup::xdg_popup_configure(int32_t x, int32_t y, int32_t width, int32_t height)
{
Q_EMIT configureRequested(QRect(x, y, width, height));
}
void XdgPopup::xdg_popup_popup_done()
{
Q_EMIT doneReceived();
}
XdgDecorationManagerV1::~XdgDecorationManagerV1()
{
destroy();
}
XdgToplevelDecorationV1::XdgToplevelDecorationV1(XdgDecorationManagerV1 *manager,
XdgToplevel *toplevel, QObject *parent)
: QObject(parent)
, QtWayland::zxdg_toplevel_decoration_v1(manager->get_toplevel_decoration(toplevel->object()))
{
}
XdgToplevelDecorationV1::~XdgToplevelDecorationV1()
{
destroy();
}
void XdgToplevelDecorationV1::zxdg_toplevel_decoration_v1_configure(uint32_t m)
{
Q_EMIT configureRequested(mode(m));
}
IdleInhibitManagerV1::~IdleInhibitManagerV1()
{
destroy();
}
IdleInhibitorV1::IdleInhibitorV1(IdleInhibitManagerV1 *manager, KWayland::Client::Surface *surface)
: QtWayland::zwp_idle_inhibitor_v1(manager->create_inhibitor(*surface))
{
}
IdleInhibitorV1::~IdleInhibitorV1()
{
destroy();
}
static struct
{
KWayland::Client::ConnectionThread *connection = nullptr;
KWayland::Client::EventQueue *queue = nullptr;
KWayland::Client::Compositor *compositor = nullptr;
KWayland::Client::SubCompositor *subCompositor = nullptr;
KWayland::Client::ServerSideDecorationManager *decoration = nullptr;
KWayland::Client::ShadowManager *shadowManager = nullptr;
XdgShell *xdgShell = nullptr;
KWayland::Client::ShmPool *shm = nullptr;
KWayland::Client::Seat *seat = nullptr;
KWayland::Client::PlasmaShell *plasmaShell = nullptr;
KWayland::Client::PlasmaWindowManagement *windowManagement = nullptr;
KWayland::Client::PointerConstraints *pointerConstraints = nullptr;
KWayland::Client::Registry *registry = nullptr;
WaylandOutputManagementV2 *outputManagementV2 = nullptr;
QThread *thread = nullptr;
QVector<KWayland::Client::Output *> outputs;
QVector<WaylandOutputDeviceV2 *> outputDevicesV2;
IdleInhibitManagerV1 *idleInhibitManagerV1 = nullptr;
KWayland::Client::AppMenuManager *appMenu = nullptr;
XdgDecorationManagerV1 *xdgDecorationManagerV1 = nullptr;
KWayland::Client::TextInputManager *textInputManager = nullptr;
QtWayland::zwp_input_panel_v1 *inputPanelV1 = nullptr;
MockInputMethod *inputMethodV1 = nullptr;
QtWayland::zwp_input_method_context_v1 *inputMethodContextV1 = nullptr;
LayerShellV1 *layerShellV1 = nullptr;
TextInputManagerV3 *textInputManagerV3 = nullptr;
FractionalScaleManagerV1 *fractionalScaleManagerV1 = nullptr;
ScreencastingV1 *screencastingV1 = nullptr;
} s_waylandConnection;
MockInputMethod *inputMethod()
{
return s_waylandConnection.inputMethodV1;
}
KWayland::Client::Surface *inputPanelSurface()
{
return s_waylandConnection.inputMethodV1->inputPanelSurface();
}
MockInputMethod::MockInputMethod(struct wl_registry *registry, int id, int version)
: QtWayland::zwp_input_method_v1(registry, id, version)
{
}
MockInputMethod::~MockInputMethod()
{
}
void MockInputMethod::zwp_input_method_v1_activate(struct ::zwp_input_method_context_v1 *context)
{
if (!m_inputSurface) {
m_inputSurface = Test::createSurface();
m_inputMethodSurface = Test::createInputPanelSurfaceV1(m_inputSurface.get(), s_waylandConnection.outputs.first());
}
m_context = context;
2022-09-22 19:49:53 +00:00
Test::render(m_inputSurface.get(), QSize(1280, 400), Qt::blue);
Q_EMIT activate();
}
void MockInputMethod::zwp_input_method_v1_deactivate(struct ::zwp_input_method_context_v1 *context)
{
QCOMPARE(context, m_context);
zwp_input_method_context_v1_destroy(context);
m_context = nullptr;
if (m_inputSurface) {
m_inputSurface->release();
m_inputSurface->destroy();
m_inputSurface.reset();
delete m_inputMethodSurface;
m_inputMethodSurface = nullptr;
}
}
bool setupWaylandConnection(AdditionalWaylandInterfaces flags)
{
if (s_waylandConnection.connection) {
return false;
}
int sx[2];
if (socketpair(AF_UNIX, SOCK_STREAM | SOCK_CLOEXEC, 0, sx) < 0) {
return false;
}
KWin::waylandServer()->display()->createClient(sx[0]);
// setup connection
s_waylandConnection.connection = new KWayland::Client::ConnectionThread;
QSignalSpy connectedSpy(s_waylandConnection.connection, &KWayland::Client::ConnectionThread::connected);
if (!connectedSpy.isValid()) {
return false;
}
s_waylandConnection.connection->setSocketFd(sx[1]);
s_waylandConnection.thread = new QThread(kwinApp());
s_waylandConnection.connection->moveToThread(s_waylandConnection.thread);
s_waylandConnection.thread->start();
s_waylandConnection.connection->initConnection();
if (!connectedSpy.wait()) {
return false;
}
s_waylandConnection.queue = new KWayland::Client::EventQueue;
s_waylandConnection.queue->setup(s_waylandConnection.connection);
if (!s_waylandConnection.queue->isValid()) {
return false;
}
KWayland::Client::Registry *registry = new KWayland::Client::Registry;
s_waylandConnection.registry = registry;
registry->setEventQueue(s_waylandConnection.queue);
QObject::connect(registry, &KWayland::Client::Registry::outputAnnounced, [=](quint32 name, quint32 version) {
KWayland::Client::Output *output = registry->createOutput(name, version, s_waylandConnection.registry);
s_waylandConnection.outputs << output;
QObject::connect(output, &KWayland::Client::Output::removed, [=]() {
output->deleteLater();
s_waylandConnection.outputs.removeOne(output);
});
QObject::connect(output, &KWayland::Client::Output::destroyed, [=]() {
s_waylandConnection.outputs.removeOne(output);
});
});
QObject::connect(registry, &KWayland::Client::Registry::interfaceAnnounced, [=](const QByteArray &interface, quint32 name, quint32 version) {
if (flags & AdditionalWaylandInterface::InputMethodV1) {
if (interface == QByteArrayLiteral("zwp_input_method_v1")) {
s_waylandConnection.inputMethodV1 = new MockInputMethod(*registry, name, version);
} else if (interface == QByteArrayLiteral("zwp_input_panel_v1")) {
s_waylandConnection.inputPanelV1 = new QtWayland::zwp_input_panel_v1(*registry, name, version);
}
}
if (flags & AdditionalWaylandInterface::LayerShellV1) {
if (interface == QByteArrayLiteral("zwlr_layer_shell_v1")) {
s_waylandConnection.layerShellV1 = new LayerShellV1();
s_waylandConnection.layerShellV1->init(*registry, name, version);
}
}
if (flags & AdditionalWaylandInterface::TextInputManagerV3) {
// do something
if (interface == QByteArrayLiteral("zwp_text_input_manager_v3")) {
s_waylandConnection.textInputManagerV3 = new TextInputManagerV3();
s_waylandConnection.textInputManagerV3->init(*registry, name, version);
}
}
if (interface == QByteArrayLiteral("xdg_wm_base")) {
s_waylandConnection.xdgShell = new XdgShell();
s_waylandConnection.xdgShell->init(*registry, name, version);
}
if (flags & AdditionalWaylandInterface::XdgDecorationV1) {
if (interface == zxdg_decoration_manager_v1_interface.name) {
s_waylandConnection.xdgDecorationManagerV1 = new XdgDecorationManagerV1();
s_waylandConnection.xdgDecorationManagerV1->init(*registry, name, version);
return;
}
}
if (flags & AdditionalWaylandInterface::IdleInhibitV1) {
if (interface == zwp_idle_inhibit_manager_v1_interface.name) {
s_waylandConnection.idleInhibitManagerV1 = new IdleInhibitManagerV1();
s_waylandConnection.idleInhibitManagerV1->init(*registry, name, version);
return;
}
}
if (flags & AdditionalWaylandInterface::OutputDeviceV2) {
if (interface == kde_output_device_v2_interface.name) {
WaylandOutputDeviceV2 *device = new WaylandOutputDeviceV2(name);
device->init(*registry, name, version);
s_waylandConnection.outputDevicesV2 << device;
QObject::connect(device, &WaylandOutputDeviceV2::destroyed, [=]() {
s_waylandConnection.outputDevicesV2.removeOne(device);
device->deleteLater();
});
QObject::connect(registry, &KWayland::Client::Registry::interfaceRemoved, device, [name, device](const quint32 &interfaceName) {
if (name == interfaceName) {
s_waylandConnection.outputDevicesV2.removeOne(device);
device->deleteLater();
}
});
return;
}
}
if (flags & AdditionalWaylandInterface::OutputManagementV2) {
if (interface == kde_output_management_v2_interface.name) {
s_waylandConnection.outputManagementV2 = new WaylandOutputManagementV2(*registry, name, version);
return;
}
}
if (flags & AdditionalWaylandInterface::FractionalScaleManagerV1) {
if (interface == wp_fractional_scale_manager_v1_interface.name) {
s_waylandConnection.fractionalScaleManagerV1 = new FractionalScaleManagerV1();
s_waylandConnection.fractionalScaleManagerV1->init(*registry, name, version);
return;
}
}
if (flags & AdditionalWaylandInterface::ScreencastingV1) {
if (interface == zkde_screencast_unstable_v1_interface.name) {
s_waylandConnection.screencastingV1 = new ScreencastingV1();
s_waylandConnection.screencastingV1->init(*registry, name, version);
return;
}
}
});
QSignalSpy allAnnounced(registry, &KWayland::Client::Registry::interfacesAnnounced);
if (!allAnnounced.isValid()) {
return false;
}
registry->create(s_waylandConnection.connection);
if (!registry->isValid()) {
return false;
}
registry->setup();
if (!allAnnounced.wait()) {
return false;
}
s_waylandConnection.compositor = registry->createCompositor(registry->interface(KWayland::Client::Registry::Interface::Compositor).name, registry->interface(KWayland::Client::Registry::Interface::Compositor).version);
if (!s_waylandConnection.compositor->isValid()) {
return false;
}
s_waylandConnection.subCompositor = registry->createSubCompositor(registry->interface(KWayland::Client::Registry::Interface::SubCompositor).name, registry->interface(KWayland::Client::Registry::Interface::SubCompositor).version);
if (!s_waylandConnection.subCompositor->isValid()) {
return false;
}
s_waylandConnection.shm = registry->createShmPool(registry->interface(KWayland::Client::Registry::Interface::Shm).name, registry->interface(KWayland::Client::Registry::Interface::Shm).version);
if (!s_waylandConnection.shm->isValid()) {
return false;
}
if (flags.testFlag(AdditionalWaylandInterface::Seat)) {
s_waylandConnection.seat = registry->createSeat(registry->interface(KWayland::Client::Registry::Interface::Seat).name, registry->interface(KWayland::Client::Registry::Interface::Seat).version);
if (!s_waylandConnection.seat->isValid()) {
return false;
}
}
if (flags.testFlag(AdditionalWaylandInterface::ShadowManager)) {
s_waylandConnection.shadowManager = registry->createShadowManager(registry->interface(KWayland::Client::Registry::Interface::Shadow).name,
registry->interface(KWayland::Client::Registry::Interface::Shadow).version);
if (!s_waylandConnection.shadowManager->isValid()) {
return false;
}
}
if (flags.testFlag(AdditionalWaylandInterface::Decoration)) {
s_waylandConnection.decoration = registry->createServerSideDecorationManager(registry->interface(KWayland::Client::Registry::Interface::ServerSideDecorationManager).name,
registry->interface(KWayland::Client::Registry::Interface::ServerSideDecorationManager).version);
if (!s_waylandConnection.decoration->isValid()) {
return false;
}
}
if (flags.testFlag(AdditionalWaylandInterface::PlasmaShell)) {
s_waylandConnection.plasmaShell = registry->createPlasmaShell(registry->interface(KWayland::Client::Registry::Interface::PlasmaShell).name,
registry->interface(KWayland::Client::Registry::Interface::PlasmaShell).version);
if (!s_waylandConnection.plasmaShell->isValid()) {
return false;
}
}
if (flags.testFlag(AdditionalWaylandInterface::WindowManagement)) {
s_waylandConnection.windowManagement = registry->createPlasmaWindowManagement(registry->interface(KWayland::Client::Registry::Interface::PlasmaWindowManagement).name,
registry->interface(KWayland::Client::Registry::Interface::PlasmaWindowManagement).version);
if (!s_waylandConnection.windowManagement->isValid()) {
return false;
}
}
Implement support for pointer constraints Summary: There are two types of constraints supported: 1. Pointer confinement 2. Pointer locking In the case of confinement the pointer is confined to a given region of the surface. This is comparable to general operation where the pointer is confined to the screen region. In the second case the pointer gets locked. That means it cannot move at all. No further position updates are provided, only relative motion events can go to the application. There is a hint about cursor position update on unlock which is not yet implemented in KWayland::Server, thus also not in this change. The implementation in KWin grants the requests for pointer constraints when the pointer enters the constrained region, either by pointer movement or by e.g. stacking order changes. There is no confirmation from user required to enter that mode. But we want to show an OSD when the pointer gets constrained, this is not yet implemented, though. Breaking an active constraint is relatively easy. E.g. changing the stacking order will break the constraint if another surface is under the cursor. Also (in case of confinement) moving the pointer to an overlapping window breaks the confinement. But as soon as one moves the pointer back to the window a constraint might get honoured again. To properly break there is a dedicated event filter. It listens for a long press of the Escape key. If hold for 3sec the pointer constraint is broken and not activated again till the pointer got moved out of the window. Afterward when moving in the pointer might activate again. The escape filter ensures that the key press is forwarded to the application if it's a short press or if another key gets pressed during the three seconds. If the three seconds way fires, the later escape release is not sent to the application. This basic interaction is also ensured through an added auto test. This change implements T4605. Test Plan: Added auto test and nested KWin Wayland with D3488 Reviewers: #kwin, #plasma_on_wayland Subscribers: plasma-devel, kwin Tags: #plasma_on_wayland, #kwin Differential Revision: https://phabricator.kde.org/D3506
2016-11-25 06:17:43 +00:00
if (flags.testFlag(AdditionalWaylandInterface::PointerConstraints)) {
s_waylandConnection.pointerConstraints = registry->createPointerConstraints(registry->interface(KWayland::Client::Registry::Interface::PointerConstraintsUnstableV1).name,
registry->interface(KWayland::Client::Registry::Interface::PointerConstraintsUnstableV1).version);
Implement support for pointer constraints Summary: There are two types of constraints supported: 1. Pointer confinement 2. Pointer locking In the case of confinement the pointer is confined to a given region of the surface. This is comparable to general operation where the pointer is confined to the screen region. In the second case the pointer gets locked. That means it cannot move at all. No further position updates are provided, only relative motion events can go to the application. There is a hint about cursor position update on unlock which is not yet implemented in KWayland::Server, thus also not in this change. The implementation in KWin grants the requests for pointer constraints when the pointer enters the constrained region, either by pointer movement or by e.g. stacking order changes. There is no confirmation from user required to enter that mode. But we want to show an OSD when the pointer gets constrained, this is not yet implemented, though. Breaking an active constraint is relatively easy. E.g. changing the stacking order will break the constraint if another surface is under the cursor. Also (in case of confinement) moving the pointer to an overlapping window breaks the confinement. But as soon as one moves the pointer back to the window a constraint might get honoured again. To properly break there is a dedicated event filter. It listens for a long press of the Escape key. If hold for 3sec the pointer constraint is broken and not activated again till the pointer got moved out of the window. Afterward when moving in the pointer might activate again. The escape filter ensures that the key press is forwarded to the application if it's a short press or if another key gets pressed during the three seconds. If the three seconds way fires, the later escape release is not sent to the application. This basic interaction is also ensured through an added auto test. This change implements T4605. Test Plan: Added auto test and nested KWin Wayland with D3488 Reviewers: #kwin, #plasma_on_wayland Subscribers: plasma-devel, kwin Tags: #plasma_on_wayland, #kwin Differential Revision: https://phabricator.kde.org/D3506
2016-11-25 06:17:43 +00:00
if (!s_waylandConnection.pointerConstraints->isValid()) {
return false;
}
}
if (flags.testFlag(AdditionalWaylandInterface::AppMenu)) {
s_waylandConnection.appMenu = registry->createAppMenuManager(registry->interface(KWayland::Client::Registry::Interface::AppMenu).name, registry->interface(KWayland::Client::Registry::Interface::AppMenu).version);
if (!s_waylandConnection.appMenu->isValid()) {
return false;
}
}
if (flags.testFlag(AdditionalWaylandInterface::TextInputManagerV2)) {
s_waylandConnection.textInputManager = registry->createTextInputManager(registry->interface(KWayland::Client::Registry::Interface::TextInputManagerUnstableV2).name, registry->interface(KWayland::Client::Registry::Interface::TextInputManagerUnstableV2).version);
if (!s_waylandConnection.textInputManager->isValid()) {
return false;
}
}
return true;
}
void destroyWaylandConnection()
{
delete s_waylandConnection.compositor;
s_waylandConnection.compositor = nullptr;
delete s_waylandConnection.subCompositor;
s_waylandConnection.subCompositor = nullptr;
delete s_waylandConnection.windowManagement;
s_waylandConnection.windowManagement = nullptr;
delete s_waylandConnection.plasmaShell;
s_waylandConnection.plasmaShell = nullptr;
delete s_waylandConnection.decoration;
s_waylandConnection.decoration = nullptr;
delete s_waylandConnection.decoration;
s_waylandConnection.decoration = nullptr;
delete s_waylandConnection.seat;
s_waylandConnection.seat = nullptr;
Implement support for pointer constraints Summary: There are two types of constraints supported: 1. Pointer confinement 2. Pointer locking In the case of confinement the pointer is confined to a given region of the surface. This is comparable to general operation where the pointer is confined to the screen region. In the second case the pointer gets locked. That means it cannot move at all. No further position updates are provided, only relative motion events can go to the application. There is a hint about cursor position update on unlock which is not yet implemented in KWayland::Server, thus also not in this change. The implementation in KWin grants the requests for pointer constraints when the pointer enters the constrained region, either by pointer movement or by e.g. stacking order changes. There is no confirmation from user required to enter that mode. But we want to show an OSD when the pointer gets constrained, this is not yet implemented, though. Breaking an active constraint is relatively easy. E.g. changing the stacking order will break the constraint if another surface is under the cursor. Also (in case of confinement) moving the pointer to an overlapping window breaks the confinement. But as soon as one moves the pointer back to the window a constraint might get honoured again. To properly break there is a dedicated event filter. It listens for a long press of the Escape key. If hold for 3sec the pointer constraint is broken and not activated again till the pointer got moved out of the window. Afterward when moving in the pointer might activate again. The escape filter ensures that the key press is forwarded to the application if it's a short press or if another key gets pressed during the three seconds. If the three seconds way fires, the later escape release is not sent to the application. This basic interaction is also ensured through an added auto test. This change implements T4605. Test Plan: Added auto test and nested KWin Wayland with D3488 Reviewers: #kwin, #plasma_on_wayland Subscribers: plasma-devel, kwin Tags: #plasma_on_wayland, #kwin Differential Revision: https://phabricator.kde.org/D3506
2016-11-25 06:17:43 +00:00
delete s_waylandConnection.pointerConstraints;
s_waylandConnection.pointerConstraints = nullptr;
delete s_waylandConnection.xdgShell;
s_waylandConnection.xdgShell = nullptr;
delete s_waylandConnection.shadowManager;
s_waylandConnection.shadowManager = nullptr;
delete s_waylandConnection.idleInhibitManagerV1;
s_waylandConnection.idleInhibitManagerV1 = nullptr;
delete s_waylandConnection.shm;
s_waylandConnection.shm = nullptr;
delete s_waylandConnection.registry;
s_waylandConnection.registry = nullptr;
delete s_waylandConnection.appMenu;
s_waylandConnection.appMenu = nullptr;
delete s_waylandConnection.xdgDecorationManagerV1;
s_waylandConnection.xdgDecorationManagerV1 = nullptr;
delete s_waylandConnection.textInputManager;
s_waylandConnection.textInputManager = nullptr;
delete s_waylandConnection.inputPanelV1;
s_waylandConnection.inputPanelV1 = nullptr;
delete s_waylandConnection.layerShellV1;
s_waylandConnection.layerShellV1 = nullptr;
delete s_waylandConnection.outputManagementV2;
s_waylandConnection.outputManagementV2 = nullptr;
delete s_waylandConnection.fractionalScaleManagerV1;
s_waylandConnection.fractionalScaleManagerV1 = nullptr;
delete s_waylandConnection.queue; // Must be destroyed last
s_waylandConnection.queue = nullptr;
if (s_waylandConnection.thread) {
s_waylandConnection.connection->deleteLater();
s_waylandConnection.thread->quit();
s_waylandConnection.thread->wait();
delete s_waylandConnection.thread;
s_waylandConnection.thread = nullptr;
s_waylandConnection.connection = nullptr;
}
s_waylandConnection.outputs.clear();
s_waylandConnection.outputDevicesV2.clear();
}
KWayland::Client::ConnectionThread *waylandConnection()
{
return s_waylandConnection.connection;
}
KWayland::Client::Compositor *waylandCompositor()
{
return s_waylandConnection.compositor;
}
KWayland::Client::SubCompositor *waylandSubCompositor()
{
return s_waylandConnection.subCompositor;
}
KWayland::Client::ShadowManager *waylandShadowManager()
{
return s_waylandConnection.shadowManager;
}
KWayland::Client::ShmPool *waylandShmPool()
{
return s_waylandConnection.shm;
}
KWayland::Client::Seat *waylandSeat()
{
return s_waylandConnection.seat;
}
KWayland::Client::ServerSideDecorationManager *waylandServerSideDecoration()
{
return s_waylandConnection.decoration;
}
KWayland::Client::PlasmaShell *waylandPlasmaShell()
{
return s_waylandConnection.plasmaShell;
}
KWayland::Client::PlasmaWindowManagement *waylandWindowManagement()
{
return s_waylandConnection.windowManagement;
}
KWayland::Client::PointerConstraints *waylandPointerConstraints()
Implement support for pointer constraints Summary: There are two types of constraints supported: 1. Pointer confinement 2. Pointer locking In the case of confinement the pointer is confined to a given region of the surface. This is comparable to general operation where the pointer is confined to the screen region. In the second case the pointer gets locked. That means it cannot move at all. No further position updates are provided, only relative motion events can go to the application. There is a hint about cursor position update on unlock which is not yet implemented in KWayland::Server, thus also not in this change. The implementation in KWin grants the requests for pointer constraints when the pointer enters the constrained region, either by pointer movement or by e.g. stacking order changes. There is no confirmation from user required to enter that mode. But we want to show an OSD when the pointer gets constrained, this is not yet implemented, though. Breaking an active constraint is relatively easy. E.g. changing the stacking order will break the constraint if another surface is under the cursor. Also (in case of confinement) moving the pointer to an overlapping window breaks the confinement. But as soon as one moves the pointer back to the window a constraint might get honoured again. To properly break there is a dedicated event filter. It listens for a long press of the Escape key. If hold for 3sec the pointer constraint is broken and not activated again till the pointer got moved out of the window. Afterward when moving in the pointer might activate again. The escape filter ensures that the key press is forwarded to the application if it's a short press or if another key gets pressed during the three seconds. If the three seconds way fires, the later escape release is not sent to the application. This basic interaction is also ensured through an added auto test. This change implements T4605. Test Plan: Added auto test and nested KWin Wayland with D3488 Reviewers: #kwin, #plasma_on_wayland Subscribers: plasma-devel, kwin Tags: #plasma_on_wayland, #kwin Differential Revision: https://phabricator.kde.org/D3506
2016-11-25 06:17:43 +00:00
{
return s_waylandConnection.pointerConstraints;
}
KWayland::Client::AppMenuManager *waylandAppMenuManager()
{
return s_waylandConnection.appMenu;
}
KWin::Test::WaylandOutputManagementV2 *waylandOutputManagementV2()
{
return s_waylandConnection.outputManagementV2;
}
KWayland::Client::TextInputManager *waylandTextInputManager()
{
return s_waylandConnection.textInputManager;
}
TextInputManagerV3 *waylandTextInputManagerV3()
{
return s_waylandConnection.textInputManagerV3;
}
QVector<KWayland::Client::Output *> waylandOutputs()
{
return s_waylandConnection.outputs;
}
KWayland::Client::Output *waylandOutput(const QString &name)
{
for (KWayland::Client::Output *output : std::as_const(s_waylandConnection.outputs)) {
if (output->name() == name) {
return output;
}
}
return nullptr;
}
ScreencastingV1 *screencasting()
{
return s_waylandConnection.screencastingV1;
}
QVector<KWin::Test::WaylandOutputDeviceV2 *> waylandOutputDevicesV2()
{
return s_waylandConnection.outputDevicesV2;
}
2022-04-23 19:51:16 +00:00
bool waitForWaylandSurface(Window *window)
{
2022-04-23 19:51:16 +00:00
if (window->surface()) {
return true;
}
2022-04-23 19:51:16 +00:00
QSignalSpy surfaceChangedSpy(window, &Window::surfaceChanged);
return surfaceChangedSpy.wait();
}
bool waitForWaylandPointer()
{
if (!s_waylandConnection.seat) {
return false;
}
QSignalSpy hasPointerSpy(s_waylandConnection.seat, &KWayland::Client::Seat::hasPointerChanged);
if (!hasPointerSpy.isValid()) {
return false;
}
return hasPointerSpy.wait();
}
bool waitForWaylandTouch()
{
if (!s_waylandConnection.seat) {
return false;
}
QSignalSpy hasTouchSpy(s_waylandConnection.seat, &KWayland::Client::Seat::hasTouchChanged);
if (!hasTouchSpy.isValid()) {
return false;
}
return hasTouchSpy.wait();
}
bool waitForWaylandKeyboard()
{
if (!s_waylandConnection.seat) {
return false;
}
QSignalSpy hasKeyboardSpy(s_waylandConnection.seat, &KWayland::Client::Seat::hasKeyboardChanged);
if (!hasKeyboardSpy.isValid()) {
return false;
}
return hasKeyboardSpy.wait();
}
void render(KWayland::Client::Surface *surface, const QSize &size, const QColor &color, const QImage::Format &format)
{
QImage img(size, format);
img.fill(color);
render(surface, img);
}
void render(KWayland::Client::Surface *surface, const QImage &img)
{
surface->attachBuffer(s_waylandConnection.shm->createBuffer(img));
surface->damage(QRect(QPoint(0, 0), img.size()));
surface->commit(KWayland::Client::Surface::CommitFlag::None);
}
2022-04-22 17:39:12 +00:00
Window *waitForWaylandWindowShown(int timeout)
{
QSignalSpy windowAddedSpy(workspace(), &Workspace::windowAdded);
if (!windowAddedSpy.isValid()) {
return nullptr;
}
if (!windowAddedSpy.wait(timeout)) {
return nullptr;
}
return windowAddedSpy.first().first().value<Window *>();
}
2022-04-22 17:39:12 +00:00
Window *renderAndWaitForShown(KWayland::Client::Surface *surface, const QSize &size, const QColor &color, const QImage::Format &format, int timeout)
{
QImage img(size, format);
img.fill(color);
return renderAndWaitForShown(surface, img, timeout);
}
Window *renderAndWaitForShown(KWayland::Client::Surface *surface, const QImage &img, int timeout)
{
QSignalSpy windowAddedSpy(workspace(), &Workspace::windowAdded);
if (!windowAddedSpy.isValid()) {
return nullptr;
}
render(surface, img);
flushWaylandConnection();
if (!windowAddedSpy.wait(timeout)) {
return nullptr;
}
return windowAddedSpy.first().first().value<Window *>();
}
void flushWaylandConnection()
{
if (s_waylandConnection.connection) {
s_waylandConnection.connection->flush();
}
}
std::unique_ptr<KWayland::Client::Surface> createSurface()
{
if (!s_waylandConnection.compositor) {
return nullptr;
}
std::unique_ptr<KWayland::Client::Surface> s{s_waylandConnection.compositor->createSurface()};
return s->isValid() ? std::move(s) : nullptr;
}
KWayland::Client::SubSurface *createSubSurface(KWayland::Client::Surface *surface, KWayland::Client::Surface *parentSurface, QObject *parent)
{
if (!s_waylandConnection.subCompositor) {
return nullptr;
}
auto s = s_waylandConnection.subCompositor->createSubSurface(surface, parentSurface, parent);
if (!s->isValid()) {
delete s;
return nullptr;
}
return s;
}
LayerSurfaceV1 *createLayerSurfaceV1(KWayland::Client::Surface *surface, const QString &scope, KWayland::Client::Output *output, LayerShellV1::layer layer)
{
LayerShellV1 *shell = s_waylandConnection.layerShellV1;
if (!shell) {
qWarning() << "Could not create a layer surface because the layer shell global is not bound";
return nullptr;
}
struct ::wl_output *nativeOutput = nullptr;
if (output) {
nativeOutput = *output;
}
LayerSurfaceV1 *shellSurface = new LayerSurfaceV1();
shellSurface->init(shell->get_layer_surface(*surface, nativeOutput, layer, scope));
return shellSurface;
}
QtWayland::zwp_input_panel_surface_v1 *createInputPanelSurfaceV1(KWayland::Client::Surface *surface, KWayland::Client::Output *output)
{
if (!s_waylandConnection.inputPanelV1) {
qWarning() << "Unable to create the input panel surface. The interface input_panel global is not bound";
return nullptr;
}
QtWayland::zwp_input_panel_surface_v1 *s = new QtWayland::zwp_input_panel_surface_v1(s_waylandConnection.inputPanelV1->get_input_panel_surface(*surface));
if (!s->isInitialized()) {
delete s;
return nullptr;
}
s->set_toplevel(output->output(), QtWayland::zwp_input_panel_surface_v1::position_center_bottom);
return s;
}
FractionalScaleV1 *createFractionalScaleV1(KWayland::Client::Surface *surface)
{
if (!s_waylandConnection.fractionalScaleManagerV1) {
qWarning() << "Unable to create fractional scale surface. The global is not bound";
return nullptr;
}
auto scale = new FractionalScaleV1();
scale->init(s_waylandConnection.fractionalScaleManagerV1->get_fractional_scale(*surface));
return scale;
}
static void waitForConfigured(XdgSurface *shellSurface)
{
QSignalSpy surfaceConfigureRequestedSpy(shellSurface, &XdgSurface::configureRequested);
shellSurface->surface()->commit(KWayland::Client::Surface::CommitFlag::None);
QVERIFY(surfaceConfigureRequestedSpy.wait());
shellSurface->ack_configure(surfaceConfigureRequestedSpy.last().first().toUInt());
}
XdgToplevel *createXdgToplevelSurface(KWayland::Client::Surface *surface, QObject *parent)
{
return createXdgToplevelSurface(surface, CreationSetup::CreateAndConfigure, parent);
}
XdgToplevel *createXdgToplevelSurface(KWayland::Client::Surface *surface, CreationSetup configureMode, QObject *parent)
{
XdgShell *shell = s_waylandConnection.xdgShell;
if (!shell) {
qWarning() << "Could not create an xdg_toplevel surface because xdg_wm_base global is not bound";
return nullptr;
}
XdgSurface *xdgSurface = new XdgSurface(shell, surface);
XdgToplevel *xdgToplevel = new XdgToplevel(xdgSurface, parent);
if (configureMode == CreationSetup::CreateAndConfigure) {
waitForConfigured(xdgSurface);
}
return xdgToplevel;
}
XdgPositioner *createXdgPositioner()
{
XdgShell *shell = s_waylandConnection.xdgShell;
if (!shell) {
qWarning() << "Could not create an xdg_positioner object because xdg_wm_base global is not bound";
return nullptr;
}
return new XdgPositioner(shell);
}
XdgPopup *createXdgPopupSurface(KWayland::Client::Surface *surface, XdgSurface *parentSurface, XdgPositioner *positioner,
CreationSetup configureMode, QObject *parent)
{
XdgShell *shell = s_waylandConnection.xdgShell;
if (!shell) {
qWarning() << "Could not create an xdg_popup surface because xdg_wm_base global is not bound";
return nullptr;
}
XdgSurface *xdgSurface = new XdgSurface(shell, surface);
XdgPopup *xdgPopup = new XdgPopup(xdgSurface, parentSurface, positioner, parent);
if (configureMode == CreationSetup::CreateAndConfigure) {
waitForConfigured(xdgSurface);
}
return xdgPopup;
}
XdgToplevelDecorationV1 *createXdgToplevelDecorationV1(XdgToplevel *toplevel, QObject *parent)
{
XdgDecorationManagerV1 *manager = s_waylandConnection.xdgDecorationManagerV1;
if (!manager) {
qWarning() << "Could not create an xdg_toplevel_decoration_v1 because xdg_decoration_manager_v1 global is not bound";
return nullptr;
}
return new XdgToplevelDecorationV1(manager, toplevel, parent);
}
IdleInhibitorV1 *createIdleInhibitorV1(KWayland::Client::Surface *surface)
{
IdleInhibitManagerV1 *manager = s_waylandConnection.idleInhibitManagerV1;
if (!manager) {
qWarning() << "Could not create an idle_inhibitor_v1 because idle_inhibit_manager_v1 global is not bound";
return nullptr;
}
return new IdleInhibitorV1(manager, surface);
}
bool waitForWindowClosed(Window *window)
{
QSignalSpy closedSpy(window, &Window::closed);
if (!closedSpy.isValid()) {
return false;
}
return closedSpy.wait();
}
#if KWIN_BUILD_SCREENLOCKER
bool lockScreen()
{
if (waylandServer()->isScreenLocked()) {
return false;
}
QSignalSpy lockStateChangedSpy(ScreenLocker::KSldApp::self(), &ScreenLocker::KSldApp::lockStateChanged);
if (!lockStateChangedSpy.isValid()) {
return false;
}
ScreenLocker::KSldApp::self()->lock(ScreenLocker::EstablishLock::Immediate);
if (lockStateChangedSpy.count() != 1) {
return false;
}
if (!waylandServer()->isScreenLocked()) {
return false;
}
if (!kwinApp()->screenLockerWatcher()->isLocked()) {
QSignalSpy lockedSpy(kwinApp()->screenLockerWatcher(), &ScreenLockerWatcher::locked);
if (!lockedSpy.isValid()) {
return false;
}
if (!lockedSpy.wait()) {
return false;
}
if (!kwinApp()->screenLockerWatcher()->isLocked()) {
return false;
}
}
return true;
}
bool unlockScreen()
{
QSignalSpy lockStateChangedSpy(ScreenLocker::KSldApp::self(), &ScreenLocker::KSldApp::lockStateChanged);
if (!lockStateChangedSpy.isValid()) {
return false;
}
using namespace ScreenLocker;
const auto children = KSldApp::self()->children();
for (auto it = children.begin(); it != children.end(); ++it) {
if (qstrcmp((*it)->metaObject()->className(), "LogindIntegration") != 0) {
continue;
}
QMetaObject::invokeMethod(*it, "requestUnlock");
break;
}
if (waylandServer()->isScreenLocked()) {
lockStateChangedSpy.wait();
}
if (waylandServer()->isScreenLocked()) {
return true;
}
if (kwinApp()->screenLockerWatcher()->isLocked()) {
QSignalSpy lockedSpy(kwinApp()->screenLockerWatcher(), &ScreenLockerWatcher::locked);
if (!lockedSpy.isValid()) {
return false;
}
if (!lockedSpy.wait()) {
return false;
}
if (kwinApp()->screenLockerWatcher()->isLocked()) {
return false;
}
}
return true;
}
#endif // KWIN_BUILD_LOCKSCREEN
bool renderNodeAvailable()
{
const int deviceCount = drmGetDevices2(0, nullptr, 0);
if (deviceCount <= 0) {
return false;
}
QVector<drmDevice *> devices(deviceCount);
if (drmGetDevices2(0, devices.data(), devices.size()) < 0) {
return false;
}
auto deviceCleanup = qScopeGuard([&devices]() {
drmFreeDevices(devices.data(), devices.size());
});
return std::any_of(devices.constBegin(), devices.constEnd(), [](drmDevice *device) {
return device->available_nodes & (1 << DRM_NODE_RENDER);
});
}
void XcbConnectionDeleter::operator()(xcb_connection_t *pointer)
{
xcb_disconnect(pointer);
};
Test::XcbConnectionPtr createX11Connection()
{
QFutureWatcher<xcb_connection_t *> watcher;
QEventLoop e;
e.connect(&watcher, &QFutureWatcher<xcb_connection_t *>::finished, &e, &QEventLoop::quit);
QFuture<xcb_connection_t *> future = QtConcurrent::run([]() {
return xcb_connect(nullptr, nullptr);
});
watcher.setFuture(future);
e.exec();
return Test::XcbConnectionPtr(future.result());
}
WaylandOutputManagementV2::WaylandOutputManagementV2(struct ::wl_registry *registry, int id, int version)
: QObject()
, QtWayland::kde_output_management_v2()
{
init(registry, id, version);
}
WaylandOutputConfigurationV2 *WaylandOutputManagementV2::createConfiguration()
{
return new WaylandOutputConfigurationV2(create_configuration());
}
WaylandOutputConfigurationV2::WaylandOutputConfigurationV2(struct ::kde_output_configuration_v2 *object)
: QObject()
, QtWayland::kde_output_configuration_v2()
{
init(object);
}
void WaylandOutputConfigurationV2::kde_output_configuration_v2_applied()
{
Q_EMIT applied();
}
void WaylandOutputConfigurationV2::kde_output_configuration_v2_failed()
{
Q_EMIT failed();
}
WaylandOutputDeviceV2Mode::WaylandOutputDeviceV2Mode(struct ::kde_output_device_mode_v2 *object)
: QtWayland::kde_output_device_mode_v2(object)
{
}
WaylandOutputDeviceV2Mode::~WaylandOutputDeviceV2Mode()
{
kde_output_device_mode_v2_destroy(object());
}
void WaylandOutputDeviceV2Mode::kde_output_device_mode_v2_size(int32_t width, int32_t height)
{
m_size = QSize(width, height);
}
void WaylandOutputDeviceV2Mode::kde_output_device_mode_v2_refresh(int32_t refresh)
{
m_refreshRate = refresh;
}
void WaylandOutputDeviceV2Mode::kde_output_device_mode_v2_preferred()
{
m_preferred = true;
}
void WaylandOutputDeviceV2Mode::kde_output_device_mode_v2_removed()
{
Q_EMIT removed();
}
int WaylandOutputDeviceV2Mode::refreshRate() const
{
return m_refreshRate;
}
QSize WaylandOutputDeviceV2Mode::size() const
{
return m_size;
}
bool WaylandOutputDeviceV2Mode::preferred() const
{
return m_preferred;
}
bool WaylandOutputDeviceV2Mode::operator==(const WaylandOutputDeviceV2Mode &other) const
{
return m_size == other.m_size && m_refreshRate == other.m_refreshRate && m_preferred == other.m_preferred;
}
WaylandOutputDeviceV2Mode *WaylandOutputDeviceV2Mode::get(struct ::kde_output_device_mode_v2 *object)
{
auto mode = QtWayland::kde_output_device_mode_v2::fromObject(object);
return static_cast<WaylandOutputDeviceV2Mode *>(mode);
}
WaylandOutputDeviceV2::WaylandOutputDeviceV2(int id)
: QObject()
, kde_output_device_v2()
, m_id(id)
{
}
WaylandOutputDeviceV2::~WaylandOutputDeviceV2()
{
qDeleteAll(m_modes);
kde_output_device_v2_destroy(object());
}
void WaylandOutputDeviceV2::kde_output_device_v2_geometry(int32_t x,
int32_t y,
int32_t physical_width,
int32_t physical_height,
int32_t subpixel,
const QString &make,
const QString &model,
int32_t transform)
{
m_pos = QPoint(x, y);
m_physicalSize = QSize(physical_width, physical_height);
m_subpixel = subpixel;
m_manufacturer = make;
m_model = model;
m_transform = transform;
}
void WaylandOutputDeviceV2::kde_output_device_v2_current_mode(struct ::kde_output_device_mode_v2 *mode)
{
auto m = WaylandOutputDeviceV2Mode::get(mode);
if (*m == *m_mode) {
// unchanged
return;
}
m_mode = m;
}
void WaylandOutputDeviceV2::kde_output_device_v2_mode(struct ::kde_output_device_mode_v2 *mode)
{
WaylandOutputDeviceV2Mode *m = new WaylandOutputDeviceV2Mode(mode);
// last mode sent is the current one
m_mode = m;
m_modes.append(m);
connect(m, &WaylandOutputDeviceV2Mode::removed, this, [this, m]() {
m_modes.removeOne(m);
if (m_mode == m) {
if (!m_modes.isEmpty()) {
m_mode = m_modes.first();
} else {
// was last mode
qFatal("KWaylandBackend: no output modes available anymore, this seems like a compositor bug");
}
}
delete m;
});
}
QString WaylandOutputDeviceV2::modeId() const
{
return QString::number(m_modes.indexOf(m_mode));
}
WaylandOutputDeviceV2Mode *WaylandOutputDeviceV2::deviceModeFromId(const int modeId) const
{
return m_modes.at(modeId);
}
QString WaylandOutputDeviceV2::modeName(const WaylandOutputDeviceV2Mode *m) const
{
return QString::number(m->size().width()) + QLatin1Char('x') + QString::number(m->size().height()) + QLatin1Char('@')
+ QString::number(qRound(m->refreshRate() / 1000.0));
}
QString WaylandOutputDeviceV2::name() const
{
return QStringLiteral("%1 %2").arg(m_manufacturer, m_model);
}
QDebug operator<<(QDebug dbg, const WaylandOutputDeviceV2 *output)
{
dbg << "WaylandOutput(Id:" << output->id() << ", Name:" << QString(output->manufacturer() + QLatin1Char(' ') + output->model()) << ")";
return dbg;
}
void WaylandOutputDeviceV2::kde_output_device_v2_done()
{
Q_EMIT done();
}
void WaylandOutputDeviceV2::kde_output_device_v2_scale(wl_fixed_t factor)
{
m_factor = wl_fixed_to_double(factor);
}
void WaylandOutputDeviceV2::kde_output_device_v2_edid(const QString &edid)
{
m_edid = QByteArray::fromBase64(edid.toUtf8());
}
void WaylandOutputDeviceV2::kde_output_device_v2_enabled(int32_t enabled)
{
if (m_enabled != enabled) {
m_enabled = enabled;
Q_EMIT enabledChanged();
}
}
void WaylandOutputDeviceV2::kde_output_device_v2_uuid(const QString &uuid)
{
m_uuid = uuid;
}
void WaylandOutputDeviceV2::kde_output_device_v2_serial_number(const QString &serialNumber)
{
m_serialNumber = serialNumber;
}
void WaylandOutputDeviceV2::kde_output_device_v2_eisa_id(const QString &eisaId)
{
m_eisaId = eisaId;
}
void WaylandOutputDeviceV2::kde_output_device_v2_capabilities(uint32_t flags)
{
m_flags = flags;
}
void WaylandOutputDeviceV2::kde_output_device_v2_overscan(uint32_t overscan)
{
m_overscan = overscan;
}
void WaylandOutputDeviceV2::kde_output_device_v2_vrr_policy(uint32_t vrr_policy)
{
m_vrr_policy = vrr_policy;
}
void WaylandOutputDeviceV2::kde_output_device_v2_rgb_range(uint32_t rgb_range)
{
m_rgbRange = rgb_range;
}
QByteArray WaylandOutputDeviceV2::edid() const
{
return m_edid;
}
bool WaylandOutputDeviceV2::enabled() const
{
return m_enabled;
}
int WaylandOutputDeviceV2::id() const
{
return m_id;
}
qreal WaylandOutputDeviceV2::scale() const
{
return m_factor;
}
QString WaylandOutputDeviceV2::manufacturer() const
{
return m_manufacturer;
}
QString WaylandOutputDeviceV2::model() const
{
return m_model;
}
QPoint WaylandOutputDeviceV2::globalPosition() const
{
return m_pos;
}
QSize WaylandOutputDeviceV2::pixelSize() const
{
return m_mode->size();
}
int WaylandOutputDeviceV2::refreshRate() const
{
return m_mode->refreshRate();
}
uint32_t WaylandOutputDeviceV2::vrrPolicy() const
{
return m_vrr_policy;
}
uint32_t WaylandOutputDeviceV2::overscan() const
{
return m_overscan;
}
uint32_t WaylandOutputDeviceV2::capabilities() const
{
return m_flags;
}
uint32_t WaylandOutputDeviceV2::rgbRange() const
{
return m_rgbRange;
}
VirtualInputDevice::VirtualInputDevice(QObject *parent)
: InputDevice(parent)
{
}
void VirtualInputDevice::setPointer(bool set)
{
m_pointer = set;
}
void VirtualInputDevice::setKeyboard(bool set)
{
m_keyboard = set;
}
void VirtualInputDevice::setTouch(bool set)
{
m_touch = set;
}
void VirtualInputDevice::setName(const QString &name)
{
m_name = name;
}
QString VirtualInputDevice::sysName() const
{
return QString();
}
QString VirtualInputDevice::name() const
{
return m_name;
}
bool VirtualInputDevice::isEnabled() const
{
return true;
}
void VirtualInputDevice::setEnabled(bool enabled)
{
}
LEDs VirtualInputDevice::leds() const
{
return LEDs();
}
void VirtualInputDevice::setLeds(LEDs leds)
{
}
bool VirtualInputDevice::isKeyboard() const
{
return m_keyboard;
}
bool VirtualInputDevice::isAlphaNumericKeyboard() const
{
return m_keyboard;
}
bool VirtualInputDevice::isPointer() const
{
return m_pointer;
}
bool VirtualInputDevice::isTouchpad() const
{
return false;
}
bool VirtualInputDevice::isTouch() const
{
return m_touch;
}
bool VirtualInputDevice::isTabletTool() const
{
return false;
}
bool VirtualInputDevice::isTabletPad() const
{
return false;
}
bool VirtualInputDevice::isTabletModeSwitch() const
{
return false;
}
bool VirtualInputDevice::isLidSwitch() const
{
return false;
}
void keyboardKeyPressed(quint32 key, quint32 time)
{
auto virtualKeyboard = static_cast<WaylandTestApplication *>(kwinApp())->virtualKeyboard();
Q_EMIT virtualKeyboard->keyChanged(key, InputRedirection::KeyboardKeyState::KeyboardKeyPressed, std::chrono::milliseconds(time), virtualKeyboard);
}
void keyboardKeyReleased(quint32 key, quint32 time)
{
auto virtualKeyboard = static_cast<WaylandTestApplication *>(kwinApp())->virtualKeyboard();
Q_EMIT virtualKeyboard->keyChanged(key, InputRedirection::KeyboardKeyState::KeyboardKeyReleased, std::chrono::milliseconds(time), virtualKeyboard);
}
void pointerAxisHorizontal(qreal delta, quint32 time, qint32 discreteDelta, InputRedirection::PointerAxisSource source)
{
auto virtualPointer = static_cast<WaylandTestApplication *>(kwinApp())->virtualPointer();
Q_EMIT virtualPointer->pointerAxisChanged(InputRedirection::PointerAxis::PointerAxisHorizontal, delta, discreteDelta, source, std::chrono::milliseconds(time), virtualPointer);
}
void pointerAxisVertical(qreal delta, quint32 time, qint32 discreteDelta, InputRedirection::PointerAxisSource source)
{
auto virtualPointer = static_cast<WaylandTestApplication *>(kwinApp())->virtualPointer();
Q_EMIT virtualPointer->pointerAxisChanged(InputRedirection::PointerAxis::PointerAxisVertical, delta, discreteDelta, source, std::chrono::milliseconds(time), virtualPointer);
}
void pointerButtonPressed(quint32 button, quint32 time)
{
auto virtualPointer = static_cast<WaylandTestApplication *>(kwinApp())->virtualPointer();
Q_EMIT virtualPointer->pointerButtonChanged(button, InputRedirection::PointerButtonState::PointerButtonPressed, std::chrono::milliseconds(time), virtualPointer);
}
void pointerButtonReleased(quint32 button, quint32 time)
{
auto virtualPointer = static_cast<WaylandTestApplication *>(kwinApp())->virtualPointer();
Q_EMIT virtualPointer->pointerButtonChanged(button, InputRedirection::PointerButtonState::PointerButtonReleased, std::chrono::milliseconds(time), virtualPointer);
}
void pointerMotion(const QPointF &position, quint32 time)
{
auto virtualPointer = static_cast<WaylandTestApplication *>(kwinApp())->virtualPointer();
Q_EMIT virtualPointer->pointerMotionAbsolute(position, std::chrono::milliseconds(time), virtualPointer);
}
void pointerMotionRelative(const QPointF &delta, quint32 time)
{
auto virtualPointer = static_cast<WaylandTestApplication *>(kwinApp())->virtualPointer();
Q_EMIT virtualPointer->pointerMotion(delta, delta, std::chrono::milliseconds(time), virtualPointer);
}
void touchCancel()
{
auto virtualTouch = static_cast<WaylandTestApplication *>(kwinApp())->virtualTouch();
Q_EMIT virtualTouch->touchCanceled(virtualTouch);
}
void touchDown(qint32 id, const QPointF &pos, quint32 time)
{
auto virtualTouch = static_cast<WaylandTestApplication *>(kwinApp())->virtualTouch();
Q_EMIT virtualTouch->touchDown(id, pos, std::chrono::milliseconds(time), virtualTouch);
}
void touchMotion(qint32 id, const QPointF &pos, quint32 time)
{
auto virtualTouch = static_cast<WaylandTestApplication *>(kwinApp())->virtualTouch();
Q_EMIT virtualTouch->touchMotion(id, pos, std::chrono::milliseconds(time), virtualTouch);
}
void touchUp(qint32 id, quint32 time)
{
auto virtualTouch = static_cast<WaylandTestApplication *>(kwinApp())->virtualTouch();
Q_EMIT virtualTouch->touchUp(id, std::chrono::milliseconds(time), virtualTouch);
}
}
}