kwin/plugins/platforms/drm/drm_output.cpp

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/********************************************************************
KWin - the KDE window manager
This file is part of the KDE project.
Copyright (C) 2015 Martin Gräßlin <mgraesslin@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 "drm_output.h"
#include "drm_backend.h"
#include "drm_object_plane.h"
#include "drm_object_crtc.h"
#include "drm_object_connector.h"
#include <errno.h>
#include "composite.h"
#include "logind.h"
#include "logging.h"
#include "main.h"
#include "orientation_sensor.h"
#include "screens_drm.h"
#include "wayland_server.h"
// KWayland
#include <KWayland/Server/display.h>
#include <KWayland/Server/output_interface.h>
#include <KWayland/Server/outputchangeset.h>
#include <KWayland/Server/outputdevice_interface.h>
#include <KWayland/Server/outputmanagement_interface.h>
#include <KWayland/Server/outputconfiguration_interface.h>
// KF5
#include <KConfigGroup>
#include <KLocalizedString>
#include <KSharedConfig>
// Qt
#include <QMatrix4x4>
#include <QCryptographicHash>
#include <QPainter>
// drm
#include <xf86drm.h>
#include <xf86drmMode.h>
#include <libdrm/drm_mode.h>
namespace KWin
{
DrmOutput::DrmOutput(DrmBackend *backend)
: QObject()
, m_backend(backend)
{
}
DrmOutput::~DrmOutput()
{
hideCursor();
[DRM plugin] Remember static kernel objects, amplify use of DrmCrtc To get an image from KWin to the screen in the DRM pipeline we combine a CRTC, an encoder and a connector. These objects are static in the sense, that they represent real hardware on the graphics card, which doesn't change in a session. See here for more details: https://01.org/linuxgraphics/gfx-docs/drm/gpu/drm-kms.html Until now we used DrmOutput as the main representation for such an active rendering pipeline. I.e. it gets created and destroyed on hot plug events of displays. On the other side we had no fixed representation of the static kernel objects throughout the lifetime of KWin. This has several disadvantages: * We always need to query all available static objects on an hot plug event. * We can't manipulate the frame buffer of a CRTC after an output has been disconnected * Adding functionality for driving multiple displays on a single CRTC (i.e. cloning) would be difficult * We can't destroy the last frame buffer on display disconnect because the CRTC still accesses it and have therefore a memory leak on every display disconnect This patch solves these issues by storing representations of all available CRTC and Connector objects in DrmBackend on init via DrmCrtc and DrmConnector instances. On an hotplug event these vectors are looped for a fitting CRTC and Connector combinations. Buffer handling is moved to the respective CRTC instance. All changes in overview: * Query all available CRTCs and Connectors and save for subsequent hotplug events * Fix logic errors in `queryResources()` * Move framebuffers, buffer flip and blank logic in DrmCrtc * Remove `restoreSaved()`. It isn't necessary and is dangerous if the old framebuffer was deleted in the meantime. Also could reveal sensitive user info from old session. Test Plan: Login, logout, VT switching, connect and disconnect external monitor, energy saving mode. Reviewers: #kwin Subscribers: kwin, #kwin Tags: #kwin Differential Revision: https://phabricator.kde.org/D5118
2017-05-09 18:02:49 +00:00
m_crtc->blank();
if (m_primaryPlane) {
// TODO: when having multiple planes, also clean up these
m_primaryPlane->setOutput(nullptr);
if (m_backend->deleteBufferAfterPageFlip()) {
delete m_primaryPlane->current();
}
m_primaryPlane->setCurrent(nullptr);
}
m_crtc->setOutput(nullptr);
m_conn->setOutput(nullptr);
delete m_waylandOutput.data();
delete m_waylandOutputDevice.data();
delete m_cursor[0];
delete m_cursor[1];
}
[DRM plugin] Remember static kernel objects, amplify use of DrmCrtc To get an image from KWin to the screen in the DRM pipeline we combine a CRTC, an encoder and a connector. These objects are static in the sense, that they represent real hardware on the graphics card, which doesn't change in a session. See here for more details: https://01.org/linuxgraphics/gfx-docs/drm/gpu/drm-kms.html Until now we used DrmOutput as the main representation for such an active rendering pipeline. I.e. it gets created and destroyed on hot plug events of displays. On the other side we had no fixed representation of the static kernel objects throughout the lifetime of KWin. This has several disadvantages: * We always need to query all available static objects on an hot plug event. * We can't manipulate the frame buffer of a CRTC after an output has been disconnected * Adding functionality for driving multiple displays on a single CRTC (i.e. cloning) would be difficult * We can't destroy the last frame buffer on display disconnect because the CRTC still accesses it and have therefore a memory leak on every display disconnect This patch solves these issues by storing representations of all available CRTC and Connector objects in DrmBackend on init via DrmCrtc and DrmConnector instances. On an hotplug event these vectors are looped for a fitting CRTC and Connector combinations. Buffer handling is moved to the respective CRTC instance. All changes in overview: * Query all available CRTCs and Connectors and save for subsequent hotplug events * Fix logic errors in `queryResources()` * Move framebuffers, buffer flip and blank logic in DrmCrtc * Remove `restoreSaved()`. It isn't necessary and is dangerous if the old framebuffer was deleted in the meantime. Also could reveal sensitive user info from old session. Test Plan: Login, logout, VT switching, connect and disconnect external monitor, energy saving mode. Reviewers: #kwin Subscribers: kwin, #kwin Tags: #kwin Differential Revision: https://phabricator.kde.org/D5118
2017-05-09 18:02:49 +00:00
void DrmOutput::releaseGbm()
{
[DRM plugin] Remember static kernel objects, amplify use of DrmCrtc To get an image from KWin to the screen in the DRM pipeline we combine a CRTC, an encoder and a connector. These objects are static in the sense, that they represent real hardware on the graphics card, which doesn't change in a session. See here for more details: https://01.org/linuxgraphics/gfx-docs/drm/gpu/drm-kms.html Until now we used DrmOutput as the main representation for such an active rendering pipeline. I.e. it gets created and destroyed on hot plug events of displays. On the other side we had no fixed representation of the static kernel objects throughout the lifetime of KWin. This has several disadvantages: * We always need to query all available static objects on an hot plug event. * We can't manipulate the frame buffer of a CRTC after an output has been disconnected * Adding functionality for driving multiple displays on a single CRTC (i.e. cloning) would be difficult * We can't destroy the last frame buffer on display disconnect because the CRTC still accesses it and have therefore a memory leak on every display disconnect This patch solves these issues by storing representations of all available CRTC and Connector objects in DrmBackend on init via DrmCrtc and DrmConnector instances. On an hotplug event these vectors are looped for a fitting CRTC and Connector combinations. Buffer handling is moved to the respective CRTC instance. All changes in overview: * Query all available CRTCs and Connectors and save for subsequent hotplug events * Fix logic errors in `queryResources()` * Move framebuffers, buffer flip and blank logic in DrmCrtc * Remove `restoreSaved()`. It isn't necessary and is dangerous if the old framebuffer was deleted in the meantime. Also could reveal sensitive user info from old session. Test Plan: Login, logout, VT switching, connect and disconnect external monitor, energy saving mode. Reviewers: #kwin Subscribers: kwin, #kwin Tags: #kwin Differential Revision: https://phabricator.kde.org/D5118
2017-05-09 18:02:49 +00:00
if (DrmBuffer *b = m_crtc->current()) {
b->releaseGbm();
}
if (m_primaryPlane && m_primaryPlane->current()) {
m_primaryPlane->current()->releaseGbm();
}
}
void DrmOutput::hideCursor()
{
[DRM plugin] Remember static kernel objects, amplify use of DrmCrtc To get an image from KWin to the screen in the DRM pipeline we combine a CRTC, an encoder and a connector. These objects are static in the sense, that they represent real hardware on the graphics card, which doesn't change in a session. See here for more details: https://01.org/linuxgraphics/gfx-docs/drm/gpu/drm-kms.html Until now we used DrmOutput as the main representation for such an active rendering pipeline. I.e. it gets created and destroyed on hot plug events of displays. On the other side we had no fixed representation of the static kernel objects throughout the lifetime of KWin. This has several disadvantages: * We always need to query all available static objects on an hot plug event. * We can't manipulate the frame buffer of a CRTC after an output has been disconnected * Adding functionality for driving multiple displays on a single CRTC (i.e. cloning) would be difficult * We can't destroy the last frame buffer on display disconnect because the CRTC still accesses it and have therefore a memory leak on every display disconnect This patch solves these issues by storing representations of all available CRTC and Connector objects in DrmBackend on init via DrmCrtc and DrmConnector instances. On an hotplug event these vectors are looped for a fitting CRTC and Connector combinations. Buffer handling is moved to the respective CRTC instance. All changes in overview: * Query all available CRTCs and Connectors and save for subsequent hotplug events * Fix logic errors in `queryResources()` * Move framebuffers, buffer flip and blank logic in DrmCrtc * Remove `restoreSaved()`. It isn't necessary and is dangerous if the old framebuffer was deleted in the meantime. Also could reveal sensitive user info from old session. Test Plan: Login, logout, VT switching, connect and disconnect external monitor, energy saving mode. Reviewers: #kwin Subscribers: kwin, #kwin Tags: #kwin Differential Revision: https://phabricator.kde.org/D5118
2017-05-09 18:02:49 +00:00
drmModeSetCursor(m_backend->fd(), m_crtc->id(), 0, 0, 0);
}
void DrmOutput::showCursor(DrmDumbBuffer *c)
{
const QSize &s = c->size();
[DRM plugin] Remember static kernel objects, amplify use of DrmCrtc To get an image from KWin to the screen in the DRM pipeline we combine a CRTC, an encoder and a connector. These objects are static in the sense, that they represent real hardware on the graphics card, which doesn't change in a session. See here for more details: https://01.org/linuxgraphics/gfx-docs/drm/gpu/drm-kms.html Until now we used DrmOutput as the main representation for such an active rendering pipeline. I.e. it gets created and destroyed on hot plug events of displays. On the other side we had no fixed representation of the static kernel objects throughout the lifetime of KWin. This has several disadvantages: * We always need to query all available static objects on an hot plug event. * We can't manipulate the frame buffer of a CRTC after an output has been disconnected * Adding functionality for driving multiple displays on a single CRTC (i.e. cloning) would be difficult * We can't destroy the last frame buffer on display disconnect because the CRTC still accesses it and have therefore a memory leak on every display disconnect This patch solves these issues by storing representations of all available CRTC and Connector objects in DrmBackend on init via DrmCrtc and DrmConnector instances. On an hotplug event these vectors are looped for a fitting CRTC and Connector combinations. Buffer handling is moved to the respective CRTC instance. All changes in overview: * Query all available CRTCs and Connectors and save for subsequent hotplug events * Fix logic errors in `queryResources()` * Move framebuffers, buffer flip and blank logic in DrmCrtc * Remove `restoreSaved()`. It isn't necessary and is dangerous if the old framebuffer was deleted in the meantime. Also could reveal sensitive user info from old session. Test Plan: Login, logout, VT switching, connect and disconnect external monitor, energy saving mode. Reviewers: #kwin Subscribers: kwin, #kwin Tags: #kwin Differential Revision: https://phabricator.kde.org/D5118
2017-05-09 18:02:49 +00:00
drmModeSetCursor(m_backend->fd(), m_crtc->id(), c->handle(), s.width(), s.height());
}
void DrmOutput::showCursor()
{
showCursor(m_cursor[m_cursorIndex]);
if (m_hasNewCursor) {
m_cursorIndex = (m_cursorIndex + 1) % 2;
m_hasNewCursor = false;
}
}
void DrmOutput::updateCursor()
{
QImage cursorImage = m_backend->softwareCursor();
if (cursorImage.isNull()) {
return;
}
m_hasNewCursor = true;
QImage *c = m_cursor[m_cursorIndex]->image();
c->fill(Qt::transparent);
QPainter p;
p.begin(c);
if (m_orientation == Qt::InvertedLandscapeOrientation) {
QMatrix4x4 matrix;
matrix.translate(cursorImage.width() / 2.0, cursorImage.height() / 2.0);
matrix.rotate(180.0f, 0.0f, 0.0f, 1.0f);
matrix.translate(-cursorImage.width() / 2.0, -cursorImage.height() / 2.0);
p.setWorldTransform(matrix.toTransform());
}
p.drawImage(QPoint(0, 0), cursorImage);
p.end();
}
void DrmOutput::moveCursor(const QPoint &globalPos)
{
QMatrix4x4 matrix;
QMatrix4x4 hotspotMatrix;
if (m_orientation == Qt::InvertedLandscapeOrientation) {
matrix.translate(pixelSize().width() /2.0, pixelSize().height() / 2.0);
matrix.rotate(180.0f, 0.0f, 0.0f, 1.0f);
matrix.translate(-pixelSize().width() /2.0, -pixelSize().height() / 2.0);
const auto cursorSize = m_backend->softwareCursor().size();
hotspotMatrix.translate(cursorSize.width()/2.0, cursorSize.height()/2.0);
hotspotMatrix.rotate(180.0f, 0.0f, 0.0f, 1.0f);
hotspotMatrix.translate(-cursorSize.width()/2.0, -cursorSize.height()/2.0);
}
matrix.scale(m_scale);
matrix.translate(-m_globalPos.x(), -m_globalPos.y());
const QPoint p = matrix.map(globalPos) - hotspotMatrix.map(m_backend->softwareCursorHotspot());
[DRM plugin] Remember static kernel objects, amplify use of DrmCrtc To get an image from KWin to the screen in the DRM pipeline we combine a CRTC, an encoder and a connector. These objects are static in the sense, that they represent real hardware on the graphics card, which doesn't change in a session. See here for more details: https://01.org/linuxgraphics/gfx-docs/drm/gpu/drm-kms.html Until now we used DrmOutput as the main representation for such an active rendering pipeline. I.e. it gets created and destroyed on hot plug events of displays. On the other side we had no fixed representation of the static kernel objects throughout the lifetime of KWin. This has several disadvantages: * We always need to query all available static objects on an hot plug event. * We can't manipulate the frame buffer of a CRTC after an output has been disconnected * Adding functionality for driving multiple displays on a single CRTC (i.e. cloning) would be difficult * We can't destroy the last frame buffer on display disconnect because the CRTC still accesses it and have therefore a memory leak on every display disconnect This patch solves these issues by storing representations of all available CRTC and Connector objects in DrmBackend on init via DrmCrtc and DrmConnector instances. On an hotplug event these vectors are looped for a fitting CRTC and Connector combinations. Buffer handling is moved to the respective CRTC instance. All changes in overview: * Query all available CRTCs and Connectors and save for subsequent hotplug events * Fix logic errors in `queryResources()` * Move framebuffers, buffer flip and blank logic in DrmCrtc * Remove `restoreSaved()`. It isn't necessary and is dangerous if the old framebuffer was deleted in the meantime. Also could reveal sensitive user info from old session. Test Plan: Login, logout, VT switching, connect and disconnect external monitor, energy saving mode. Reviewers: #kwin Subscribers: kwin, #kwin Tags: #kwin Differential Revision: https://phabricator.kde.org/D5118
2017-05-09 18:02:49 +00:00
drmModeMoveCursor(m_backend->fd(), m_crtc->id(), p.x(), p.y());
}
QSize DrmOutput::pixelSize() const
{
if (m_orientation == Qt::PortraitOrientation || m_orientation == Qt::InvertedPortraitOrientation) {
return QSize(m_mode.vdisplay, m_mode.hdisplay);
}
return QSize(m_mode.hdisplay, m_mode.vdisplay);
}
QSize DrmOutput::physicalSize() const
{
if (m_orientation == Qt::PortraitOrientation || m_orientation == Qt::InvertedPortraitOrientation) {
return QSize(m_physicalSize.height(), m_physicalSize.width());
}
return m_physicalSize;
}
QRect DrmOutput::geometry() const
{
return QRect(m_globalPos, pixelSize() / scale());
}
qreal DrmOutput::scale() const
{
return m_scale;
}
void DrmOutput::setEnabled(bool enabled)
{
if (enabled == isEnabled()) {
return;
}
if (enabled) {
setDpms(DpmsMode::On);
initOutput();
} else {
setDpms(DpmsMode::Off);
delete m_waylandOutput.data();
}
m_waylandOutputDevice->setEnabled(enabled ?
KWayland::Server::OutputDeviceInterface::Enablement::Enabled : KWayland::Server::OutputDeviceInterface::Enablement::Disabled);
}
bool DrmOutput::isEnabled() const
{
return !m_waylandOutput.isNull();
}
static KWayland::Server::OutputInterface::DpmsMode toWaylandDpmsMode(DrmOutput::DpmsMode mode)
{
using namespace KWayland::Server;
switch (mode) {
case DrmOutput::DpmsMode::On:
return OutputInterface::DpmsMode::On;
case DrmOutput::DpmsMode::Standby:
return OutputInterface::DpmsMode::Standby;
case DrmOutput::DpmsMode::Suspend:
return OutputInterface::DpmsMode::Suspend;
case DrmOutput::DpmsMode::Off:
return OutputInterface::DpmsMode::Off;
default:
Q_UNREACHABLE();
}
}
static DrmOutput::DpmsMode fromWaylandDpmsMode(KWayland::Server::OutputInterface::DpmsMode wlMode)
{
using namespace KWayland::Server;
switch (wlMode) {
case OutputInterface::DpmsMode::On:
return DrmOutput::DpmsMode::On;
case OutputInterface::DpmsMode::Standby:
return DrmOutput::DpmsMode::Standby;
case OutputInterface::DpmsMode::Suspend:
return DrmOutput::DpmsMode::Suspend;
case OutputInterface::DpmsMode::Off:
return DrmOutput::DpmsMode::Off;
default:
Q_UNREACHABLE();
}
}
static QHash<int, QByteArray> s_connectorNames = {
{DRM_MODE_CONNECTOR_Unknown, QByteArrayLiteral("Unknown")},
{DRM_MODE_CONNECTOR_VGA, QByteArrayLiteral("VGA")},
{DRM_MODE_CONNECTOR_DVII, QByteArrayLiteral("DVI-I")},
{DRM_MODE_CONNECTOR_DVID, QByteArrayLiteral("DVI-D")},
{DRM_MODE_CONNECTOR_DVIA, QByteArrayLiteral("DVI-A")},
{DRM_MODE_CONNECTOR_Composite, QByteArrayLiteral("Composite")},
{DRM_MODE_CONNECTOR_SVIDEO, QByteArrayLiteral("SVIDEO")},
{DRM_MODE_CONNECTOR_LVDS, QByteArrayLiteral("LVDS")},
{DRM_MODE_CONNECTOR_Component, QByteArrayLiteral("Component")},
{DRM_MODE_CONNECTOR_9PinDIN, QByteArrayLiteral("DIN")},
{DRM_MODE_CONNECTOR_DisplayPort, QByteArrayLiteral("DP")},
{DRM_MODE_CONNECTOR_HDMIA, QByteArrayLiteral("HDMI-A")},
{DRM_MODE_CONNECTOR_HDMIB, QByteArrayLiteral("HDMI-B")},
{DRM_MODE_CONNECTOR_TV, QByteArrayLiteral("TV")},
{DRM_MODE_CONNECTOR_eDP, QByteArrayLiteral("eDP")},
{DRM_MODE_CONNECTOR_VIRTUAL, QByteArrayLiteral("Virtual")},
{DRM_MODE_CONNECTOR_DSI, QByteArrayLiteral("DSI")}
};
namespace {
quint64 refreshRateForMode(_drmModeModeInfo *m)
{
// Calculate higher precision (mHz) refresh rate
// logic based on Weston, see compositor-drm.c
quint64 refreshRate = (m->clock * 1000000LL / m->htotal + m->vtotal / 2) / m->vtotal;
if (m->flags & DRM_MODE_FLAG_INTERLACE) {
refreshRate *= 2;
}
if (m->flags & DRM_MODE_FLAG_DBLSCAN) {
refreshRate /= 2;
}
if (m->vscan > 1) {
refreshRate /= m->vscan;
}
return refreshRate;
}
}
bool DrmOutput::init(drmModeConnector *connector)
{
initEdid(connector);
initDpms(connector);
initUuid();
if (m_backend->atomicModeSetting()) {
if (!initPrimaryPlane()) {
return false;
}
} else if (!m_crtc->blank()) {
return false;
}
m_internal = connector->connector_type == DRM_MODE_CONNECTOR_LVDS || connector->connector_type == DRM_MODE_CONNECTOR_eDP;
if (m_internal) {
connect(kwinApp(), &Application::screensCreated, this,
[this] {
connect(screens()->orientationSensor(), &OrientationSensor::orientationChanged, this, &DrmOutput::automaticRotation);
}
);
}
QSize physicalSize = !m_edid.physicalSize.isEmpty() ? m_edid.physicalSize : QSize(connector->mmWidth, connector->mmHeight);
// the size might be completely borked. E.g. Samsung SyncMaster 2494HS reports 160x90 while in truth it's 520x292
// as this information is used to calculate DPI info, it's going to result in everything being huge
const QByteArray unknown = QByteArrayLiteral("unkown");
KConfigGroup group = kwinApp()->config()->group("EdidOverwrite").group(m_edid.eisaId.isEmpty() ? unknown : m_edid.eisaId)
.group(m_edid.monitorName.isEmpty() ? unknown : m_edid.monitorName)
.group(m_edid.serialNumber.isEmpty() ? unknown : m_edid.serialNumber);
if (group.hasKey("PhysicalSize")) {
const QSize overwriteSize = group.readEntry("PhysicalSize", physicalSize);
qCWarning(KWIN_DRM) << "Overwriting monitor physical size for" << m_edid.eisaId << "/" << m_edid.monitorName << "/" << m_edid.serialNumber << " from " << physicalSize << "to " << overwriteSize;
physicalSize = overwriteSize;
}
m_physicalSize = physicalSize;
initOutputDevice(connector);
setEnabled(true);
return true;
}
void DrmOutput::initUuid()
{
QCryptographicHash hash(QCryptographicHash::Md5);
hash.addData(QByteArray::number(m_conn->id()));
hash.addData(m_edid.eisaId);
hash.addData(m_edid.monitorName);
hash.addData(m_edid.serialNumber);
m_uuid = hash.result().toHex().left(10);
}
void DrmOutput::initOutput()
{
Q_ASSERT(m_waylandOutputDevice);
if (!m_waylandOutput.isNull()) {
delete m_waylandOutput.data();
m_waylandOutput.clear();
}
m_waylandOutput = waylandServer()->display()->createOutput();
connect(this, &DrmOutput::modeChanged, this,
[this] {
if (m_waylandOutput.isNull()) {
return;
}
m_waylandOutput->setCurrentMode(QSize(m_mode.hdisplay, m_mode.vdisplay), refreshRateForMode(&m_mode));
}
);
m_waylandOutput->setManufacturer(m_waylandOutputDevice->manufacturer());
m_waylandOutput->setModel(m_waylandOutputDevice->model());
m_waylandOutput->setPhysicalSize(m_physicalSize);
// set dpms
if (!m_dpms.isNull()) {
m_waylandOutput->setDpmsSupported(true);
m_waylandOutput->setDpmsMode(toWaylandDpmsMode(m_dpmsMode));
connect(m_waylandOutput.data(), &KWayland::Server::OutputInterface::dpmsModeRequested, this,
[this] (KWayland::Server::OutputInterface::DpmsMode mode) {
setDpms(fromWaylandDpmsMode(mode));
}, Qt::QueuedConnection
);
}
for(const auto &mode: m_waylandOutputDevice->modes()) {
KWayland::Server::OutputInterface::ModeFlags flags;
if (mode.flags & KWayland::Server::OutputDeviceInterface::ModeFlag::Current) {
flags |= KWayland::Server::OutputInterface::ModeFlag::Current;
}
if (mode.flags & KWayland::Server::OutputDeviceInterface::ModeFlag::Preferred) {
flags |= KWayland::Server::OutputInterface::ModeFlag::Preferred;
}
m_waylandOutput->addMode(mode.size, flags, mode.refreshRate);
}
m_waylandOutput->create();
}
void DrmOutput::initOutputDevice(drmModeConnector *connector)
{
if (!m_waylandOutputDevice.isNull()) {
delete m_waylandOutputDevice.data();
m_waylandOutputDevice.clear();
}
m_waylandOutputDevice = waylandServer()->display()->createOutputDevice();
m_waylandOutputDevice->setUuid(m_uuid);
if (!m_edid.eisaId.isEmpty()) {
m_waylandOutputDevice->setManufacturer(QString::fromLatin1(m_edid.eisaId));
} else {
m_waylandOutputDevice->setManufacturer(i18n("unknown"));
}
QString connectorName = s_connectorNames.value(connector->connector_type, QByteArrayLiteral("Unknown"));
QString modelName;
if (!m_edid.monitorName.isEmpty()) {
QString model = QString::fromLatin1(m_edid.monitorName);
if (!m_edid.serialNumber.isEmpty()) {
model.append('/');
model.append(QString::fromLatin1(m_edid.serialNumber));
}
modelName = model;
} else if (!m_edid.serialNumber.isEmpty()) {
modelName = QString::fromLatin1(m_edid.serialNumber);
} else {
modelName = i18n("unknown");
}
m_waylandOutputDevice->setModel(connectorName + QStringLiteral("-") + QString::number(connector->connector_type_id) + QStringLiteral("-") + modelName);
m_waylandOutputDevice->setPhysicalSize(m_physicalSize);
// read in mode information
for (int i = 0; i < connector->count_modes; ++i) {
// TODO: in AMS here we could read and store for later every mode's blob_id
// would simplify isCurrentMode(..) and presentAtomically(..) in case of mode set
auto *m = &connector->modes[i];
KWayland::Server::OutputDeviceInterface::ModeFlags deviceflags;
if (isCurrentMode(m)) {
deviceflags |= KWayland::Server::OutputDeviceInterface::ModeFlag::Current;
}
if (m->type & DRM_MODE_TYPE_PREFERRED) {
deviceflags |= KWayland::Server::OutputDeviceInterface::ModeFlag::Preferred;
}
const auto refreshRate = refreshRateForMode(m);
KWayland::Server::OutputDeviceInterface::Mode mode;
mode.id = i;
mode.size = QSize(m->hdisplay, m->vdisplay);
mode.flags = deviceflags;
mode.refreshRate = refreshRate;
qCDebug(KWIN_DRM) << "Adding mode: " << i << mode.size;
m_waylandOutputDevice->addMode(mode);
}
m_waylandOutputDevice->create();
}
bool DrmOutput::isCurrentMode(const drmModeModeInfo *mode) const
{
return mode->clock == m_mode.clock
&& mode->hdisplay == m_mode.hdisplay
&& mode->hsync_start == m_mode.hsync_start
&& mode->hsync_end == m_mode.hsync_end
&& mode->htotal == m_mode.htotal
&& mode->hskew == m_mode.hskew
&& mode->vdisplay == m_mode.vdisplay
&& mode->vsync_start == m_mode.vsync_start
&& mode->vsync_end == m_mode.vsync_end
&& mode->vtotal == m_mode.vtotal
&& mode->vscan == m_mode.vscan
&& mode->vrefresh == m_mode.vrefresh
&& mode->flags == m_mode.flags
&& mode->type == m_mode.type
&& qstrcmp(mode->name, m_mode.name) == 0;
}
static bool verifyEdidHeader(drmModePropertyBlobPtr edid)
{
const uint8_t *data = reinterpret_cast<uint8_t*>(edid->data);
if (data[0] != 0x00) {
return false;
}
for (int i = 1; i < 7; ++i) {
if (data[i] != 0xFF) {
return false;
}
}
if (data[7] != 0x00) {
return false;
}
return true;
}
static QByteArray extractEisaId(drmModePropertyBlobPtr edid)
{
/*
* From EDID standard section 3.4:
* The ID Manufacturer Name field, shown in Table 3.5, contains a 2-byte representation of the monitor's
* manufacturer. This is the same as the EISA ID. It is based on compressed ASCII, 0001=A ... 11010=Z.
*
* The table:
* | Byte | Bit |
* | | 7 | 6 | 5 | 4 | 3 | 2 | 1 | 0 |
* ----------------------------------------
* | 1 | 0)| (4| 3 | 2 | 1 | 0)| (4| 3 |
* | | * | Character 1 | Char 2|
* ----------------------------------------
* | 2 | 2 | 1 | 0)| (4| 3 | 2 | 1 | 0)|
* | | Character2| Character 3 |
* ----------------------------------------
**/
const uint8_t *data = reinterpret_cast<uint8_t*>(edid->data);
static const uint offset = 0x8;
char id[4];
if (data[offset] >> 7) {
// bit at position 7 is not a 0
return QByteArray();
}
// shift two bits to right, and with 7 right most bits
id[0] = 'A' + ((data[offset] >> 2) & 0x1f) -1;
// for first byte: take last two bits and shift them 3 to left (000xx000)
// for second byte: shift 5 bits to right and take 3 right most bits (00000xxx)
// or both together
id[1] = 'A' + (((data[offset] & 0x3) << 3) | ((data[offset + 1] >> 5) & 0x7)) - 1;
// take five right most bits
id[2] = 'A' + (data[offset + 1] & 0x1f) - 1;
id[3] = '\0';
return QByteArray(id);
}
static void extractMonitorDescriptorDescription(drmModePropertyBlobPtr blob, DrmOutput::Edid &edid)
{
// see section 3.10.3
const uint8_t *data = reinterpret_cast<uint8_t*>(blob->data);
static const uint offset = 0x36;
static const uint blockLength = 18;
for (int i = 0; i < 5; ++i) {
const uint co = offset + i * blockLength;
// Flag = 0000h when block used as descriptor
if (data[co] != 0) {
continue;
}
if (data[co + 1] != 0) {
continue;
}
// Reserved = 00h when block used as descriptor
if (data[co + 2] != 0) {
continue;
}
/*
* FFh: Monitor Serial Number - Stored as ASCII, code page # 437, 13 bytes.
* FEh: ASCII String - Stored as ASCII, code page # 437, 13 bytes.
* FDh: Monitor range limits, binary coded
* FCh: Monitor name, stored as ASCII, code page # 437
* FBh: Descriptor contains additional color point data
* FAh: Descriptor contains additional Standard Timing Identifications
* F9h - 11h: Currently undefined
* 10h: Dummy descriptor, used to indicate that the descriptor space is unused
* 0Fh - 00h: Descriptor defined by manufacturer.
*/
if (data[co + 3] == 0xfc && edid.monitorName.isEmpty()) {
edid.monitorName = QByteArray((const char *)(&data[co + 5]), 12).trimmed();
}
if (data[co + 3] == 0xfe) {
const QByteArray id = QByteArray((const char *)(&data[co + 5]), 12).trimmed();
if (!id.isEmpty()) {
edid.eisaId = id;
}
}
if (data[co + 3] == 0xff) {
edid.serialNumber = QByteArray((const char *)(&data[co + 5]), 12).trimmed();
}
}
}
static QByteArray extractSerialNumber(drmModePropertyBlobPtr edid)
{
// see section 3.4
const uint8_t *data = reinterpret_cast<uint8_t*>(edid->data);
static const uint offset = 0x0C;
/*
* The ID serial number is a 32-bit serial number used to differentiate between individual instances of the same model
* of monitor. Its use is optional. When used, the bit order for this field follows that shown in Table 3.6. The EDID
* structure Version 1 Revision 1 and later offer a way to represent the serial number of the monitor as an ASCII string
* in a separate descriptor block.
*/
uint32_t serialNumber = 0;
serialNumber = (uint32_t) data[offset + 0];
serialNumber |= (uint32_t) data[offset + 1] << 8;
serialNumber |= (uint32_t) data[offset + 2] << 16;
serialNumber |= (uint32_t) data[offset + 3] << 24;
if (serialNumber == 0) {
return QByteArray();
}
return QByteArray::number(serialNumber);
}
static QSize extractPhysicalSize(drmModePropertyBlobPtr edid)
{
const uint8_t *data = reinterpret_cast<uint8_t*>(edid->data);
return QSize(data[0x15], data[0x16]) * 10;
}
void DrmOutput::initEdid(drmModeConnector *connector)
{
ScopedDrmPointer<_drmModePropertyBlob, &drmModeFreePropertyBlob> edid;
for (int i = 0; i < connector->count_props; ++i) {
ScopedDrmPointer<_drmModeProperty, &drmModeFreeProperty> property(drmModeGetProperty(m_backend->fd(), connector->props[i]));
if (!property) {
continue;
}
if ((property->flags & DRM_MODE_PROP_BLOB) && qstrcmp(property->name, "EDID") == 0) {
edid.reset(drmModeGetPropertyBlob(m_backend->fd(), connector->prop_values[i]));
}
}
if (!edid) {
return;
}
// for documentation see: http://read.pudn.com/downloads110/ebook/456020/E-EDID%20Standard.pdf
if (edid->length < 128) {
return;
}
if (!verifyEdidHeader(edid.data())) {
return;
}
m_edid.eisaId = extractEisaId(edid.data());
m_edid.serialNumber = extractSerialNumber(edid.data());
// parse monitor descriptor description
extractMonitorDescriptorDescription(edid.data(), m_edid);
m_edid.physicalSize = extractPhysicalSize(edid.data());
}
bool DrmOutput::initPrimaryPlane()
{
for (int i = 0; i < m_backend->planes().size(); ++i) {
DrmPlane* p = m_backend->planes()[i];
if (!p) {
continue;
}
if (p->type() != DrmPlane::TypeIndex::Primary) {
continue;
}
if (p->output()) { // Plane already has an output
continue;
}
if (m_primaryPlane) { // Output already has a primary plane
continue;
}
if (!p->isCrtcSupported(m_crtc->resIndex())) {
continue;
}
p->setOutput(this);
m_primaryPlane = p;
[DRM plugin] Remember static kernel objects, amplify use of DrmCrtc To get an image from KWin to the screen in the DRM pipeline we combine a CRTC, an encoder and a connector. These objects are static in the sense, that they represent real hardware on the graphics card, which doesn't change in a session. See here for more details: https://01.org/linuxgraphics/gfx-docs/drm/gpu/drm-kms.html Until now we used DrmOutput as the main representation for such an active rendering pipeline. I.e. it gets created and destroyed on hot plug events of displays. On the other side we had no fixed representation of the static kernel objects throughout the lifetime of KWin. This has several disadvantages: * We always need to query all available static objects on an hot plug event. * We can't manipulate the frame buffer of a CRTC after an output has been disconnected * Adding functionality for driving multiple displays on a single CRTC (i.e. cloning) would be difficult * We can't destroy the last frame buffer on display disconnect because the CRTC still accesses it and have therefore a memory leak on every display disconnect This patch solves these issues by storing representations of all available CRTC and Connector objects in DrmBackend on init via DrmCrtc and DrmConnector instances. On an hotplug event these vectors are looped for a fitting CRTC and Connector combinations. Buffer handling is moved to the respective CRTC instance. All changes in overview: * Query all available CRTCs and Connectors and save for subsequent hotplug events * Fix logic errors in `queryResources()` * Move framebuffers, buffer flip and blank logic in DrmCrtc * Remove `restoreSaved()`. It isn't necessary and is dangerous if the old framebuffer was deleted in the meantime. Also could reveal sensitive user info from old session. Test Plan: Login, logout, VT switching, connect and disconnect external monitor, energy saving mode. Reviewers: #kwin Subscribers: kwin, #kwin Tags: #kwin Differential Revision: https://phabricator.kde.org/D5118
2017-05-09 18:02:49 +00:00
qCDebug(KWIN_DRM) << "Initialized primary plane" << p->id() << "on CRTC" << m_crtc->id();
return true;
}
qCCritical(KWIN_DRM) << "Failed to initialize primary plane.";
return false;
}
bool DrmOutput::initCursorPlane() // TODO: Add call in init (but needs layer support in general first)
{
for (int i = 0; i < m_backend->planes().size(); ++i) {
DrmPlane* p = m_backend->planes()[i];
if (!p) {
continue;
}
if (p->type() != DrmPlane::TypeIndex::Cursor) {
continue;
}
if (p->output()) { // Plane already has an output
continue;
}
if (m_cursorPlane) { // Output already has a cursor plane
continue;
}
if (!p->isCrtcSupported(m_crtc->resIndex())) {
continue;
}
p->setOutput(this);
m_cursorPlane = p;
[DRM plugin] Remember static kernel objects, amplify use of DrmCrtc To get an image from KWin to the screen in the DRM pipeline we combine a CRTC, an encoder and a connector. These objects are static in the sense, that they represent real hardware on the graphics card, which doesn't change in a session. See here for more details: https://01.org/linuxgraphics/gfx-docs/drm/gpu/drm-kms.html Until now we used DrmOutput as the main representation for such an active rendering pipeline. I.e. it gets created and destroyed on hot plug events of displays. On the other side we had no fixed representation of the static kernel objects throughout the lifetime of KWin. This has several disadvantages: * We always need to query all available static objects on an hot plug event. * We can't manipulate the frame buffer of a CRTC after an output has been disconnected * Adding functionality for driving multiple displays on a single CRTC (i.e. cloning) would be difficult * We can't destroy the last frame buffer on display disconnect because the CRTC still accesses it and have therefore a memory leak on every display disconnect This patch solves these issues by storing representations of all available CRTC and Connector objects in DrmBackend on init via DrmCrtc and DrmConnector instances. On an hotplug event these vectors are looped for a fitting CRTC and Connector combinations. Buffer handling is moved to the respective CRTC instance. All changes in overview: * Query all available CRTCs and Connectors and save for subsequent hotplug events * Fix logic errors in `queryResources()` * Move framebuffers, buffer flip and blank logic in DrmCrtc * Remove `restoreSaved()`. It isn't necessary and is dangerous if the old framebuffer was deleted in the meantime. Also could reveal sensitive user info from old session. Test Plan: Login, logout, VT switching, connect and disconnect external monitor, energy saving mode. Reviewers: #kwin Subscribers: kwin, #kwin Tags: #kwin Differential Revision: https://phabricator.kde.org/D5118
2017-05-09 18:02:49 +00:00
qCDebug(KWIN_DRM) << "Initialized cursor plane" << p->id() << "on CRTC" << m_crtc->id();
return true;
}
return false;
}
void DrmOutput::initDpms(drmModeConnector *connector)
{
for (int i = 0; i < connector->count_props; ++i) {
ScopedDrmPointer<_drmModeProperty, &drmModeFreeProperty> property(drmModeGetProperty(m_backend->fd(), connector->props[i]));
if (!property) {
continue;
}
if (qstrcmp(property->name, "DPMS") == 0) {
m_dpms.swap(property);
break;
}
}
}
void DrmOutput::setDpms(DrmOutput::DpmsMode mode)
{
if (m_dpms.isNull()) {
return;
}
if (mode == m_dpmsModePending) {
qCDebug(KWIN_DRM) << "New DPMS mode equals old mode. DPMS unchanged.";
return;
}
m_dpmsModePending = mode;
if (m_backend->atomicModeSetting()) {
m_modesetRequested = true;
if (mode == DpmsMode::On) {
if (m_pageFlipPending) {
m_pageFlipPending = false;
Compositor::self()->bufferSwapComplete();
}
dpmsOnHandler();
} else {
m_dpmsAtomicOffPending = true;
if (!m_pageFlipPending) {
dpmsAtomicOff();
}
}
} else {
[DRM plugin] Remember static kernel objects, amplify use of DrmCrtc To get an image from KWin to the screen in the DRM pipeline we combine a CRTC, an encoder and a connector. These objects are static in the sense, that they represent real hardware on the graphics card, which doesn't change in a session. See here for more details: https://01.org/linuxgraphics/gfx-docs/drm/gpu/drm-kms.html Until now we used DrmOutput as the main representation for such an active rendering pipeline. I.e. it gets created and destroyed on hot plug events of displays. On the other side we had no fixed representation of the static kernel objects throughout the lifetime of KWin. This has several disadvantages: * We always need to query all available static objects on an hot plug event. * We can't manipulate the frame buffer of a CRTC after an output has been disconnected * Adding functionality for driving multiple displays on a single CRTC (i.e. cloning) would be difficult * We can't destroy the last frame buffer on display disconnect because the CRTC still accesses it and have therefore a memory leak on every display disconnect This patch solves these issues by storing representations of all available CRTC and Connector objects in DrmBackend on init via DrmCrtc and DrmConnector instances. On an hotplug event these vectors are looped for a fitting CRTC and Connector combinations. Buffer handling is moved to the respective CRTC instance. All changes in overview: * Query all available CRTCs and Connectors and save for subsequent hotplug events * Fix logic errors in `queryResources()` * Move framebuffers, buffer flip and blank logic in DrmCrtc * Remove `restoreSaved()`. It isn't necessary and is dangerous if the old framebuffer was deleted in the meantime. Also could reveal sensitive user info from old session. Test Plan: Login, logout, VT switching, connect and disconnect external monitor, energy saving mode. Reviewers: #kwin Subscribers: kwin, #kwin Tags: #kwin Differential Revision: https://phabricator.kde.org/D5118
2017-05-09 18:02:49 +00:00
if (drmModeConnectorSetProperty(m_backend->fd(), m_conn->id(), m_dpms->prop_id, uint64_t(mode)) < 0) {
m_dpmsModePending = m_dpmsMode;
qCWarning(KWIN_DRM) << "Setting DPMS failed";
return;
}
if (mode == DpmsMode::On) {
dpmsOnHandler();
} else {
dpmsOffHandler();
}
m_dpmsMode = m_dpmsModePending;
}
}
void DrmOutput::dpmsOnHandler()
{
qCDebug(KWIN_DRM) << "DPMS mode set for output" << m_crtc->id() << "to On.";
if (m_waylandOutput) {
m_waylandOutput->setDpmsMode(toWaylandDpmsMode(m_dpmsModePending));
}
emit dpmsChanged();
m_backend->checkOutputsAreOn();
if (!m_backend->atomicModeSetting()) {
[DRM plugin] Remember static kernel objects, amplify use of DrmCrtc To get an image from KWin to the screen in the DRM pipeline we combine a CRTC, an encoder and a connector. These objects are static in the sense, that they represent real hardware on the graphics card, which doesn't change in a session. See here for more details: https://01.org/linuxgraphics/gfx-docs/drm/gpu/drm-kms.html Until now we used DrmOutput as the main representation for such an active rendering pipeline. I.e. it gets created and destroyed on hot plug events of displays. On the other side we had no fixed representation of the static kernel objects throughout the lifetime of KWin. This has several disadvantages: * We always need to query all available static objects on an hot plug event. * We can't manipulate the frame buffer of a CRTC after an output has been disconnected * Adding functionality for driving multiple displays on a single CRTC (i.e. cloning) would be difficult * We can't destroy the last frame buffer on display disconnect because the CRTC still accesses it and have therefore a memory leak on every display disconnect This patch solves these issues by storing representations of all available CRTC and Connector objects in DrmBackend on init via DrmCrtc and DrmConnector instances. On an hotplug event these vectors are looped for a fitting CRTC and Connector combinations. Buffer handling is moved to the respective CRTC instance. All changes in overview: * Query all available CRTCs and Connectors and save for subsequent hotplug events * Fix logic errors in `queryResources()` * Move framebuffers, buffer flip and blank logic in DrmCrtc * Remove `restoreSaved()`. It isn't necessary and is dangerous if the old framebuffer was deleted in the meantime. Also could reveal sensitive user info from old session. Test Plan: Login, logout, VT switching, connect and disconnect external monitor, energy saving mode. Reviewers: #kwin Subscribers: kwin, #kwin Tags: #kwin Differential Revision: https://phabricator.kde.org/D5118
2017-05-09 18:02:49 +00:00
m_crtc->blank();
}
if (Compositor *compositor = Compositor::self()) {
compositor->addRepaintFull();
}
}
void DrmOutput::dpmsOffHandler()
{
qCDebug(KWIN_DRM) << "DPMS mode set for output" << m_crtc->id() << "to Off.";
if (m_waylandOutput) {
m_waylandOutput->setDpmsMode(toWaylandDpmsMode(m_dpmsModePending));
}
emit dpmsChanged();
m_backend->outputWentOff();
}
QString DrmOutput::name() const
{
if (!m_waylandOutput) {
return i18n("unknown");
}
return QStringLiteral("%1 %2").arg(m_waylandOutput->manufacturer()).arg(m_waylandOutput->model());
}
int DrmOutput::currentRefreshRate() const
{
if (!m_waylandOutput) {
return 60000;
}
return m_waylandOutput->refreshRate();
}
void DrmOutput::setGlobalPos(const QPoint &pos)
{
m_globalPos = pos;
if (m_waylandOutput) {
m_waylandOutput->setGlobalPosition(pos);
}
if (m_waylandOutputDevice) {
m_waylandOutputDevice->setGlobalPosition(pos);
}
}
void DrmOutput::setScale(qreal scale)
{
m_scale = scale;
if (m_waylandOutput) {
m_waylandOutput->setScale(scale);
}
if (m_waylandOutputDevice) {
m_waylandOutputDevice->setScale(scale);
}
}
void DrmOutput::setChanges(KWayland::Server::OutputChangeSet *changes)
{
m_changeset = changes;
qCDebug(KWIN_DRM) << "set changes in DrmOutput";
commitChanges();
}
bool DrmOutput::commitChanges()
{
Q_ASSERT(!m_waylandOutputDevice.isNull());
if (m_changeset.isNull()) {
qCDebug(KWIN_DRM) << "no changes";
// No changes to an output is an entirely valid thing
return true;
}
//enabledChanged is handled by drmbackend
if (m_changeset->modeChanged()) {
qCDebug(KWIN_DRM) << "Setting new mode:" << m_changeset->mode();
m_waylandOutputDevice->setCurrentMode(m_changeset->mode());
updateMode(m_changeset->mode());
}
if (m_changeset->transformChanged()) {
qCDebug(KWIN_DRM) << "Server setting transform: " << (int)(m_changeset->transform());
transform(m_changeset->transform());
}
if (m_changeset->positionChanged()) {
qCDebug(KWIN_DRM) << "Server setting position: " << m_changeset->position();
setGlobalPos(m_changeset->position());
// may just work already!
}
if (m_changeset->scaleChanged()) {
qCDebug(KWIN_DRM) << "Setting scale:" << m_changeset->scale();
setScale(m_changeset->scale());
}
return true;
}
void DrmOutput::transform(KWayland::Server::OutputDeviceInterface::Transform transform)
{
m_waylandOutputDevice->setTransform(transform);
using KWayland::Server::OutputDeviceInterface;
using KWayland::Server::OutputInterface;
switch (transform) {
case OutputDeviceInterface::Transform::Normal:
if (m_primaryPlane) {
m_primaryPlane->setTransformation(DrmPlane::Transformation::Rotate0);
}
if (m_waylandOutput) {
m_waylandOutput->setTransform(OutputInterface::Transform::Normal);
}
m_orientation = Qt::PrimaryOrientation;
break;
case OutputDeviceInterface::Transform::Rotated90:
if (m_primaryPlane) {
m_primaryPlane->setTransformation(DrmPlane::Transformation::Rotate90);
}
if (m_waylandOutput) {
m_waylandOutput->setTransform(OutputInterface::Transform::Rotated90);
}
m_orientation = Qt::PortraitOrientation;
break;
case OutputDeviceInterface::Transform::Rotated180:
if (m_primaryPlane) {
m_primaryPlane->setTransformation(DrmPlane::Transformation::Rotate180);
}
if (m_waylandOutput) {
m_waylandOutput->setTransform(OutputInterface::Transform::Rotated180);
}
m_orientation = Qt::InvertedLandscapeOrientation;
break;
case OutputDeviceInterface::Transform::Rotated270:
if (m_primaryPlane) {
m_primaryPlane->setTransformation(DrmPlane::Transformation::Rotate270);
}
if (m_waylandOutput) {
m_waylandOutput->setTransform(OutputInterface::Transform::Rotated270);
}
m_orientation = Qt::InvertedPortraitOrientation;
break;
case OutputDeviceInterface::Transform::Flipped:
// TODO: what is this exactly?
if (m_waylandOutput) {
m_waylandOutput->setTransform(OutputInterface::Transform::Flipped);
}
break;
case OutputDeviceInterface::Transform::Flipped90:
// TODO: what is this exactly?
if (m_waylandOutput) {
m_waylandOutput->setTransform(OutputInterface::Transform::Flipped90);
}
break;
case OutputDeviceInterface::Transform::Flipped180:
// TODO: what is this exactly?
if (m_waylandOutput) {
m_waylandOutput->setTransform(OutputInterface::Transform::Flipped180);
}
break;
case OutputDeviceInterface::Transform::Flipped270:
// TODO: what is this exactly?
if (m_waylandOutput) {
m_waylandOutput->setTransform(OutputInterface::Transform::Flipped270);
}
break;
}
m_modesetRequested = true;
// the cursor might need to get rotated
updateCursor();
showCursor();
emit modeChanged();
}
void DrmOutput::updateMode(int modeIndex)
{
// get all modes on the connector
ScopedDrmPointer<_drmModeConnector, &drmModeFreeConnector> connector(drmModeGetConnector(m_backend->fd(), m_conn->id()));
if (connector->count_modes <= modeIndex) {
// TODO: error?
return;
}
if (isCurrentMode(&connector->modes[modeIndex])) {
// nothing to do
return;
}
m_mode = connector->modes[modeIndex];
m_modesetRequested = true;
emit modeChanged();
}
void DrmOutput::pageFlipped()
{
m_pageFlipPending = false;
[DRM plugin] Remember static kernel objects, amplify use of DrmCrtc To get an image from KWin to the screen in the DRM pipeline we combine a CRTC, an encoder and a connector. These objects are static in the sense, that they represent real hardware on the graphics card, which doesn't change in a session. See here for more details: https://01.org/linuxgraphics/gfx-docs/drm/gpu/drm-kms.html Until now we used DrmOutput as the main representation for such an active rendering pipeline. I.e. it gets created and destroyed on hot plug events of displays. On the other side we had no fixed representation of the static kernel objects throughout the lifetime of KWin. This has several disadvantages: * We always need to query all available static objects on an hot plug event. * We can't manipulate the frame buffer of a CRTC after an output has been disconnected * Adding functionality for driving multiple displays on a single CRTC (i.e. cloning) would be difficult * We can't destroy the last frame buffer on display disconnect because the CRTC still accesses it and have therefore a memory leak on every display disconnect This patch solves these issues by storing representations of all available CRTC and Connector objects in DrmBackend on init via DrmCrtc and DrmConnector instances. On an hotplug event these vectors are looped for a fitting CRTC and Connector combinations. Buffer handling is moved to the respective CRTC instance. All changes in overview: * Query all available CRTCs and Connectors and save for subsequent hotplug events * Fix logic errors in `queryResources()` * Move framebuffers, buffer flip and blank logic in DrmCrtc * Remove `restoreSaved()`. It isn't necessary and is dangerous if the old framebuffer was deleted in the meantime. Also could reveal sensitive user info from old session. Test Plan: Login, logout, VT switching, connect and disconnect external monitor, energy saving mode. Reviewers: #kwin Subscribers: kwin, #kwin Tags: #kwin Differential Revision: https://phabricator.kde.org/D5118
2017-05-09 18:02:49 +00:00
if (!m_crtc) {
return;
}
// Egl based surface buffers get destroyed, QPainter based dumb buffers not
// TODO: split up DrmOutput in two for dumb and egl/gbm surface buffer compatible subclasses completely?
if (m_backend->deleteBufferAfterPageFlip()) {
if (m_backend->atomicModeSetting()) {
if (!m_primaryPlane->next()) {
// on manual vt switch
// TODO: when we later use overlay planes it might happen, that we have a page flip with only
// damage on one of these, and therefore the primary plane has no next buffer
// -> Then we don't want to return here!
if (m_primaryPlane->current()) {
m_primaryPlane->current()->releaseGbm();
}
return;
}
for (DrmPlane *p : m_nextPlanesFlipList) {
p->flipBufferWithDelete();
}
m_nextPlanesFlipList.clear();
} else {
if (!m_crtc->next()) {
// on manual vt switch
if (DrmBuffer *b = m_crtc->current()) {
b->releaseGbm();
}
}
m_crtc->flipBuffer();
}
} else {
if (m_backend->atomicModeSetting()){
for (DrmPlane *p : m_nextPlanesFlipList) {
p->flipBuffer();
}
m_nextPlanesFlipList.clear();
} else {
m_crtc->flipBuffer();
}
[DRM plugin] Remember static kernel objects, amplify use of DrmCrtc To get an image from KWin to the screen in the DRM pipeline we combine a CRTC, an encoder and a connector. These objects are static in the sense, that they represent real hardware on the graphics card, which doesn't change in a session. See here for more details: https://01.org/linuxgraphics/gfx-docs/drm/gpu/drm-kms.html Until now we used DrmOutput as the main representation for such an active rendering pipeline. I.e. it gets created and destroyed on hot plug events of displays. On the other side we had no fixed representation of the static kernel objects throughout the lifetime of KWin. This has several disadvantages: * We always need to query all available static objects on an hot plug event. * We can't manipulate the frame buffer of a CRTC after an output has been disconnected * Adding functionality for driving multiple displays on a single CRTC (i.e. cloning) would be difficult * We can't destroy the last frame buffer on display disconnect because the CRTC still accesses it and have therefore a memory leak on every display disconnect This patch solves these issues by storing representations of all available CRTC and Connector objects in DrmBackend on init via DrmCrtc and DrmConnector instances. On an hotplug event these vectors are looped for a fitting CRTC and Connector combinations. Buffer handling is moved to the respective CRTC instance. All changes in overview: * Query all available CRTCs and Connectors and save for subsequent hotplug events * Fix logic errors in `queryResources()` * Move framebuffers, buffer flip and blank logic in DrmCrtc * Remove `restoreSaved()`. It isn't necessary and is dangerous if the old framebuffer was deleted in the meantime. Also could reveal sensitive user info from old session. Test Plan: Login, logout, VT switching, connect and disconnect external monitor, energy saving mode. Reviewers: #kwin Subscribers: kwin, #kwin Tags: #kwin Differential Revision: https://phabricator.kde.org/D5118
2017-05-09 18:02:49 +00:00
m_crtc->flipBuffer();
}
}
bool DrmOutput::present(DrmBuffer *buffer)
{
if (m_backend->atomicModeSetting()) {
return presentAtomically(buffer);
} else {
return presentLegacy(buffer);
}
}
bool DrmOutput::dpmsAtomicOff()
{
m_dpmsAtomicOffPending = false;
// TODO: With multiple planes: deactivate all of them here
delete m_primaryPlane->next();
m_primaryPlane->setNext(nullptr);
m_nextPlanesFlipList << m_primaryPlane;
if (!doAtomicCommit(AtomicCommitMode::Test)) {
qCDebug(KWIN_DRM) << "Atomic test commit to Dpms Off failed. Aborting.";
return false;
}
if (!doAtomicCommit(AtomicCommitMode::Real)) {
qCDebug(KWIN_DRM) << "Atomic commit to Dpms Off failed. This should have never happened! Aborting.";
return false;
}
m_nextPlanesFlipList.clear();
dpmsOffHandler();
return true;
}
bool DrmOutput::presentAtomically(DrmBuffer *buffer)
{
if (!LogindIntegration::self()->isActiveSession()) {
qCWarning(KWIN_DRM) << "Logind session not active.";
return false;
}
if (m_pageFlipPending) {
qCWarning(KWIN_DRM) << "Page not yet flipped.";
return false;
}
m_primaryPlane->setNext(buffer);
m_nextPlanesFlipList << m_primaryPlane;
if (!doAtomicCommit(AtomicCommitMode::Test)) {
//TODO: When we use planes for layered rendering, fallback to renderer instead. Also for direct scanout?
//TODO: Probably should undo setNext and reset the flip list
qCDebug(KWIN_DRM) << "Atomic test commit failed. Aborting present.";
// go back to previous state
if (m_lastWorkingState.valid) {
m_mode = m_lastWorkingState.mode;
m_orientation = m_lastWorkingState.orientation;
setGlobalPos(m_lastWorkingState.globalPos);
if (m_primaryPlane) {
m_primaryPlane->setTransformation(m_lastWorkingState.planeTransformations);
}
m_modesetRequested = true;
// the cursor might need to get rotated
updateCursor();
showCursor();
// TODO: forward to OutputInterface and OutputDeviceInterface
emit modeChanged();
emit screens()->changed();
}
return false;
}
const bool wasModeset = m_modesetRequested;
if (!doAtomicCommit(AtomicCommitMode::Real)) {
qCDebug(KWIN_DRM) << "Atomic commit failed. This should have never happened! Aborting present.";
//TODO: Probably should undo setNext and reset the flip list
return false;
}
if (wasModeset) {
// store current mode set as new good state
m_lastWorkingState.mode = m_mode;
m_lastWorkingState.orientation = m_orientation;
m_lastWorkingState.globalPos = m_globalPos;
if (m_primaryPlane) {
m_lastWorkingState.planeTransformations = m_primaryPlane->transformation();
}
m_lastWorkingState.valid = true;
}
m_pageFlipPending = true;
return true;
}
bool DrmOutput::presentLegacy(DrmBuffer *buffer)
{
[DRM plugin] Remember static kernel objects, amplify use of DrmCrtc To get an image from KWin to the screen in the DRM pipeline we combine a CRTC, an encoder and a connector. These objects are static in the sense, that they represent real hardware on the graphics card, which doesn't change in a session. See here for more details: https://01.org/linuxgraphics/gfx-docs/drm/gpu/drm-kms.html Until now we used DrmOutput as the main representation for such an active rendering pipeline. I.e. it gets created and destroyed on hot plug events of displays. On the other side we had no fixed representation of the static kernel objects throughout the lifetime of KWin. This has several disadvantages: * We always need to query all available static objects on an hot plug event. * We can't manipulate the frame buffer of a CRTC after an output has been disconnected * Adding functionality for driving multiple displays on a single CRTC (i.e. cloning) would be difficult * We can't destroy the last frame buffer on display disconnect because the CRTC still accesses it and have therefore a memory leak on every display disconnect This patch solves these issues by storing representations of all available CRTC and Connector objects in DrmBackend on init via DrmCrtc and DrmConnector instances. On an hotplug event these vectors are looped for a fitting CRTC and Connector combinations. Buffer handling is moved to the respective CRTC instance. All changes in overview: * Query all available CRTCs and Connectors and save for subsequent hotplug events * Fix logic errors in `queryResources()` * Move framebuffers, buffer flip and blank logic in DrmCrtc * Remove `restoreSaved()`. It isn't necessary and is dangerous if the old framebuffer was deleted in the meantime. Also could reveal sensitive user info from old session. Test Plan: Login, logout, VT switching, connect and disconnect external monitor, energy saving mode. Reviewers: #kwin Subscribers: kwin, #kwin Tags: #kwin Differential Revision: https://phabricator.kde.org/D5118
2017-05-09 18:02:49 +00:00
if (m_crtc->next()) {
return false;
}
if (!LogindIntegration::self()->isActiveSession()) {
[DRM plugin] Remember static kernel objects, amplify use of DrmCrtc To get an image from KWin to the screen in the DRM pipeline we combine a CRTC, an encoder and a connector. These objects are static in the sense, that they represent real hardware on the graphics card, which doesn't change in a session. See here for more details: https://01.org/linuxgraphics/gfx-docs/drm/gpu/drm-kms.html Until now we used DrmOutput as the main representation for such an active rendering pipeline. I.e. it gets created and destroyed on hot plug events of displays. On the other side we had no fixed representation of the static kernel objects throughout the lifetime of KWin. This has several disadvantages: * We always need to query all available static objects on an hot plug event. * We can't manipulate the frame buffer of a CRTC after an output has been disconnected * Adding functionality for driving multiple displays on a single CRTC (i.e. cloning) would be difficult * We can't destroy the last frame buffer on display disconnect because the CRTC still accesses it and have therefore a memory leak on every display disconnect This patch solves these issues by storing representations of all available CRTC and Connector objects in DrmBackend on init via DrmCrtc and DrmConnector instances. On an hotplug event these vectors are looped for a fitting CRTC and Connector combinations. Buffer handling is moved to the respective CRTC instance. All changes in overview: * Query all available CRTCs and Connectors and save for subsequent hotplug events * Fix logic errors in `queryResources()` * Move framebuffers, buffer flip and blank logic in DrmCrtc * Remove `restoreSaved()`. It isn't necessary and is dangerous if the old framebuffer was deleted in the meantime. Also could reveal sensitive user info from old session. Test Plan: Login, logout, VT switching, connect and disconnect external monitor, energy saving mode. Reviewers: #kwin Subscribers: kwin, #kwin Tags: #kwin Differential Revision: https://phabricator.kde.org/D5118
2017-05-09 18:02:49 +00:00
m_crtc->setNext(buffer);
return false;
}
if (m_dpmsMode != DpmsMode::On) {
return false;
}
// Do we need to set a new mode first?
if (!m_crtc->current() || m_crtc->current()->needsModeChange(buffer)) {
if (!setModeLegacy(buffer)) {
return false;
}
}
[DRM plugin] Remember static kernel objects, amplify use of DrmCrtc To get an image from KWin to the screen in the DRM pipeline we combine a CRTC, an encoder and a connector. These objects are static in the sense, that they represent real hardware on the graphics card, which doesn't change in a session. See here for more details: https://01.org/linuxgraphics/gfx-docs/drm/gpu/drm-kms.html Until now we used DrmOutput as the main representation for such an active rendering pipeline. I.e. it gets created and destroyed on hot plug events of displays. On the other side we had no fixed representation of the static kernel objects throughout the lifetime of KWin. This has several disadvantages: * We always need to query all available static objects on an hot plug event. * We can't manipulate the frame buffer of a CRTC after an output has been disconnected * Adding functionality for driving multiple displays on a single CRTC (i.e. cloning) would be difficult * We can't destroy the last frame buffer on display disconnect because the CRTC still accesses it and have therefore a memory leak on every display disconnect This patch solves these issues by storing representations of all available CRTC and Connector objects in DrmBackend on init via DrmCrtc and DrmConnector instances. On an hotplug event these vectors are looped for a fitting CRTC and Connector combinations. Buffer handling is moved to the respective CRTC instance. All changes in overview: * Query all available CRTCs and Connectors and save for subsequent hotplug events * Fix logic errors in `queryResources()` * Move framebuffers, buffer flip and blank logic in DrmCrtc * Remove `restoreSaved()`. It isn't necessary and is dangerous if the old framebuffer was deleted in the meantime. Also could reveal sensitive user info from old session. Test Plan: Login, logout, VT switching, connect and disconnect external monitor, energy saving mode. Reviewers: #kwin Subscribers: kwin, #kwin Tags: #kwin Differential Revision: https://phabricator.kde.org/D5118
2017-05-09 18:02:49 +00:00
const bool ok = drmModePageFlip(m_backend->fd(), m_crtc->id(), buffer->bufferId(), DRM_MODE_PAGE_FLIP_EVENT, this) == 0;
if (ok) {
[DRM plugin] Remember static kernel objects, amplify use of DrmCrtc To get an image from KWin to the screen in the DRM pipeline we combine a CRTC, an encoder and a connector. These objects are static in the sense, that they represent real hardware on the graphics card, which doesn't change in a session. See here for more details: https://01.org/linuxgraphics/gfx-docs/drm/gpu/drm-kms.html Until now we used DrmOutput as the main representation for such an active rendering pipeline. I.e. it gets created and destroyed on hot plug events of displays. On the other side we had no fixed representation of the static kernel objects throughout the lifetime of KWin. This has several disadvantages: * We always need to query all available static objects on an hot plug event. * We can't manipulate the frame buffer of a CRTC after an output has been disconnected * Adding functionality for driving multiple displays on a single CRTC (i.e. cloning) would be difficult * We can't destroy the last frame buffer on display disconnect because the CRTC still accesses it and have therefore a memory leak on every display disconnect This patch solves these issues by storing representations of all available CRTC and Connector objects in DrmBackend on init via DrmCrtc and DrmConnector instances. On an hotplug event these vectors are looped for a fitting CRTC and Connector combinations. Buffer handling is moved to the respective CRTC instance. All changes in overview: * Query all available CRTCs and Connectors and save for subsequent hotplug events * Fix logic errors in `queryResources()` * Move framebuffers, buffer flip and blank logic in DrmCrtc * Remove `restoreSaved()`. It isn't necessary and is dangerous if the old framebuffer was deleted in the meantime. Also could reveal sensitive user info from old session. Test Plan: Login, logout, VT switching, connect and disconnect external monitor, energy saving mode. Reviewers: #kwin Subscribers: kwin, #kwin Tags: #kwin Differential Revision: https://phabricator.kde.org/D5118
2017-05-09 18:02:49 +00:00
m_crtc->setNext(buffer);
} else {
qCWarning(KWIN_DRM) << "Page flip failed:" << strerror(errno);
}
return ok;
}
bool DrmOutput::setModeLegacy(DrmBuffer *buffer)
{
[DRM plugin] Remember static kernel objects, amplify use of DrmCrtc To get an image from KWin to the screen in the DRM pipeline we combine a CRTC, an encoder and a connector. These objects are static in the sense, that they represent real hardware on the graphics card, which doesn't change in a session. See here for more details: https://01.org/linuxgraphics/gfx-docs/drm/gpu/drm-kms.html Until now we used DrmOutput as the main representation for such an active rendering pipeline. I.e. it gets created and destroyed on hot plug events of displays. On the other side we had no fixed representation of the static kernel objects throughout the lifetime of KWin. This has several disadvantages: * We always need to query all available static objects on an hot plug event. * We can't manipulate the frame buffer of a CRTC after an output has been disconnected * Adding functionality for driving multiple displays on a single CRTC (i.e. cloning) would be difficult * We can't destroy the last frame buffer on display disconnect because the CRTC still accesses it and have therefore a memory leak on every display disconnect This patch solves these issues by storing representations of all available CRTC and Connector objects in DrmBackend on init via DrmCrtc and DrmConnector instances. On an hotplug event these vectors are looped for a fitting CRTC and Connector combinations. Buffer handling is moved to the respective CRTC instance. All changes in overview: * Query all available CRTCs and Connectors and save for subsequent hotplug events * Fix logic errors in `queryResources()` * Move framebuffers, buffer flip and blank logic in DrmCrtc * Remove `restoreSaved()`. It isn't necessary and is dangerous if the old framebuffer was deleted in the meantime. Also could reveal sensitive user info from old session. Test Plan: Login, logout, VT switching, connect and disconnect external monitor, energy saving mode. Reviewers: #kwin Subscribers: kwin, #kwin Tags: #kwin Differential Revision: https://phabricator.kde.org/D5118
2017-05-09 18:02:49 +00:00
uint32_t connId = m_conn->id();
if (drmModeSetCrtc(m_backend->fd(), m_crtc->id(), buffer->bufferId(), 0, 0, &connId, 1, &m_mode) == 0) {
return true;
} else {
qCWarning(KWIN_DRM) << "Mode setting failed";
return false;
}
}
bool DrmOutput::doAtomicCommit(AtomicCommitMode mode)
{
drmModeAtomicReq *req = drmModeAtomicAlloc();
auto errorHandler = [this, mode, req] () {
if (mode == AtomicCommitMode::Test) {
// TODO: when we later test overlay planes, make sure we change only the right stuff back
}
if (req) {
drmModeAtomicFree(req);
}
if (m_dpmsMode != m_dpmsModePending) {
qCWarning(KWIN_DRM) << "Setting DPMS failed";
m_dpmsModePending = m_dpmsMode;
if (m_dpmsMode != DpmsMode::On) {
dpmsOffHandler();
}
}
// TODO: see above, rework later for overlay planes!
for (DrmPlane *p : m_nextPlanesFlipList) {
p->setNext(nullptr);
}
m_nextPlanesFlipList.clear();
};
if (!req) {
qCWarning(KWIN_DRM) << "DRM: couldn't allocate atomic request";
errorHandler();
return false;
}
uint32_t flags = 0;
// Do we need to set a new mode?
if (m_modesetRequested) {
if (m_dpmsModePending == DpmsMode::On) {
if (drmModeCreatePropertyBlob(m_backend->fd(), &m_mode, sizeof(m_mode), &m_blobId) != 0) {
qCWarning(KWIN_DRM) << "Failed to create property blob";
errorHandler();
return false;
}
}
if (!atomicReqModesetPopulate(req, m_dpmsModePending == DpmsMode::On)){
qCWarning(KWIN_DRM) << "Failed to populate Atomic Modeset";
errorHandler();
return false;
}
flags |= DRM_MODE_ATOMIC_ALLOW_MODESET;
}
if (mode == AtomicCommitMode::Real) {
if (m_dpmsModePending == DpmsMode::On) {
if (!(flags & DRM_MODE_ATOMIC_ALLOW_MODESET)) {
// TODO: Evaluating this condition should only be necessary, as long as we expect older kernels than 4.10.
flags |= DRM_MODE_ATOMIC_NONBLOCK;
}
flags |= DRM_MODE_PAGE_FLIP_EVENT;
}
} else {
flags |= DRM_MODE_ATOMIC_TEST_ONLY;
}
bool ret = true;
// TODO: Make sure when we use more than one plane at a time, that we go through this list in the right order.
for (int i = m_nextPlanesFlipList.size() - 1; 0 <= i; i-- ) {
DrmPlane *p = m_nextPlanesFlipList[i];
ret &= p->atomicPopulate(req);
}
if (!ret) {
qCWarning(KWIN_DRM) << "Failed to populate atomic planes. Abort atomic commit!";
errorHandler();
return false;
}
if (drmModeAtomicCommit(m_backend->fd(), req, flags, this)) {
qCWarning(KWIN_DRM) << "Atomic request failed to commit:" << strerror(errno);
errorHandler();
return false;
}
if (mode == AtomicCommitMode::Real && (flags & DRM_MODE_ATOMIC_ALLOW_MODESET)) {
qCDebug(KWIN_DRM) << "Atomic Modeset successful.";
m_modesetRequested = false;
m_dpmsMode = m_dpmsModePending;
}
drmModeAtomicFree(req);
return true;
}
bool DrmOutput::atomicReqModesetPopulate(drmModeAtomicReq *req, bool enable)
{
if (enable) {
m_primaryPlane->setValue(int(DrmPlane::PropertyIndex::SrcX), 0);
m_primaryPlane->setValue(int(DrmPlane::PropertyIndex::SrcY), 0);
m_primaryPlane->setValue(int(DrmPlane::PropertyIndex::SrcW), m_mode.hdisplay << 16);
m_primaryPlane->setValue(int(DrmPlane::PropertyIndex::SrcH), m_mode.vdisplay << 16);
m_primaryPlane->setValue(int(DrmPlane::PropertyIndex::CrtcW), m_mode.hdisplay);
m_primaryPlane->setValue(int(DrmPlane::PropertyIndex::CrtcH), m_mode.vdisplay);
m_primaryPlane->setValue(int(DrmPlane::PropertyIndex::CrtcId), m_crtc->id());
} else {
if (m_backend->deleteBufferAfterPageFlip()) {
delete m_primaryPlane->current();
delete m_primaryPlane->next();
}
m_primaryPlane->setCurrent(nullptr);
m_primaryPlane->setNext(nullptr);
m_primaryPlane->setValue(int(DrmPlane::PropertyIndex::SrcX), 0);
m_primaryPlane->setValue(int(DrmPlane::PropertyIndex::SrcY), 0);
m_primaryPlane->setValue(int(DrmPlane::PropertyIndex::SrcW), 0);
m_primaryPlane->setValue(int(DrmPlane::PropertyIndex::SrcH), 0);
m_primaryPlane->setValue(int(DrmPlane::PropertyIndex::CrtcW), 0);
m_primaryPlane->setValue(int(DrmPlane::PropertyIndex::CrtcH), 0);
m_primaryPlane->setValue(int(DrmPlane::PropertyIndex::CrtcId), 0);
}
m_conn->setValue(int(DrmConnector::PropertyIndex::CrtcId), enable ? m_crtc->id() : 0);
m_crtc->setValue(int(DrmCrtc::PropertyIndex::ModeId), enable ? m_blobId : 0);
m_crtc->setValue(int(DrmCrtc::PropertyIndex::Active), enable);
bool ret = true;
ret &= m_conn->atomicPopulate(req);
ret &= m_crtc->atomicPopulate(req);
return ret;
}
bool DrmOutput::initCursor(const QSize &cursorSize)
{
auto createCursor = [this, cursorSize] (int index) {
m_cursor[index] = m_backend->createBuffer(cursorSize);
if (!m_cursor[index]->map(QImage::Format_ARGB32_Premultiplied)) {
return false;
}
return true;
};
if (!createCursor(0) || !createCursor(1)) {
return false;
}
return true;
}
bool DrmOutput::supportsTransformations() const
{
if (!m_primaryPlane) {
return false;
}
const auto transformations = m_primaryPlane->supportedTransformations();
return transformations.testFlag(DrmPlane::Transformation::Rotate90)
|| transformations.testFlag(DrmPlane::Transformation::Rotate180)
|| transformations.testFlag(DrmPlane::Transformation::Rotate270);
}
void DrmOutput::automaticRotation()
{
if (!m_primaryPlane) {
return;
}
const auto supportedTransformations = m_primaryPlane->supportedTransformations();
const auto requestedTransformation = screens()->orientationSensor()->orientation();
using KWayland::Server::OutputDeviceInterface;
OutputDeviceInterface::Transform newTransformation = OutputDeviceInterface::Transform::Normal;
switch (requestedTransformation) {
case OrientationSensor::Orientation::TopUp:
newTransformation = OutputDeviceInterface::Transform::Normal;
break;
case OrientationSensor::Orientation::TopDown:
if (!supportedTransformations.testFlag(DrmPlane::Transformation::Rotate180)) {
return;
}
newTransformation = OutputDeviceInterface::Transform::Rotated180;
break;
case OrientationSensor::Orientation::LeftUp:
if (!supportedTransformations.testFlag(DrmPlane::Transformation::Rotate90)) {
return;
}
newTransformation = OutputDeviceInterface::Transform::Rotated90;
break;
case OrientationSensor::Orientation::RightUp:
if (!supportedTransformations.testFlag(DrmPlane::Transformation::Rotate270)) {
return;
}
newTransformation = OutputDeviceInterface::Transform::Rotated270;
break;
case OrientationSensor::Orientation::FaceUp:
case OrientationSensor::Orientation::FaceDown:
case OrientationSensor::Orientation::Undefined:
// unsupported
return;
}
transform(newTransformation);
emit screens()->changed();
}
}