kwin/backends/drm/drm_backend.cpp
Martin Gräßlin 873b4ed717 Fix build with some compilers
If it's a QPointer the connect needs a .data()
2015-09-11 14:53:34 +02:00

1100 lines
33 KiB
C++

/********************************************************************
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_backend.h"
#include "composite.h"
#include "cursor.h"
#include "input.h"
#include "logging.h"
#include "logind.h"
#include "scene_qpainter_drm_backend.h"
#include "screens_drm.h"
#include "udev.h"
#include "virtual_terminal.h"
#include "wayland_server.h"
#if HAVE_GBM
#include "egl_gbm_backend.h"
#endif
// KWayland
#include <KWayland/Server/display.h>
#include <KWayland/Server/output_interface.h>
// KF5
#include <KConfigGroup>
#include <KLocalizedString>
#include <KSharedConfig>
// Qt
#include <QSocketNotifier>
#include <QPainter>
// system
#include <unistd.h>
#include <sys/mman.h>
// drm
#include <xf86drm.h>
#include <xf86drmMode.h>
#include <libdrm/drm_mode.h>
#if HAVE_GBM
#include <gbm.h>
#endif
#ifndef DRM_CAP_CURSOR_WIDTH
#define DRM_CAP_CURSOR_WIDTH 0x8
#endif
#ifndef DRM_CAP_CURSOR_HEIGHT
#define DRM_CAP_CURSOR_HEIGHT 0x9
#endif
namespace KWin
{
DrmBackend::DrmBackend(QObject *parent)
: AbstractBackend(parent)
, m_udev(new Udev)
, m_udevMonitor(m_udev->monitor())
{
handleOutputs();
m_cursor[0] = nullptr;
m_cursor[1] = nullptr;
}
DrmBackend::~DrmBackend()
{
if (m_fd >= 0) {
// wait for pageflips
while (m_pageFlipsPending != 0) {
QCoreApplication::processEvents(QEventLoop::WaitForMoreEvents);
}
qDeleteAll(m_outputs);
delete m_cursor[0];
delete m_cursor[1];
close(m_fd);
}
}
void DrmBackend::init()
{
LogindIntegration *logind = LogindIntegration::self();
auto takeControl = [logind, this]() {
if (logind->hasSessionControl()) {
openDrm();
} else {
logind->takeControl();
connect(logind, &LogindIntegration::hasSessionControlChanged, this, &DrmBackend::openDrm);
}
};
if (logind->isConnected()) {
takeControl();
} else {
connect(logind, &LogindIntegration::connectedChanged, this, takeControl);
}
auto v = VirtualTerminal::create(this);
connect(v, &VirtualTerminal::activeChanged, this, &DrmBackend::activate);
}
void DrmBackend::activate(bool active)
{
if (active) {
reactivate();
} else {
deactivate();
}
}
void DrmBackend::reactivate()
{
if (m_active) {
return;
}
m_active = true;
DrmBuffer *c = m_cursor[(m_cursorIndex + 1) % 2];
const QPoint cp = Cursor::pos() - softwareCursorHotspot();
for (auto it = m_outputs.constBegin(); it != m_outputs.constEnd(); ++it) {
DrmOutput *o = *it;
o->pageFlipped();
o->blank();
o->showCursor(c);
o->moveCursor(cp);
}
// restart compositor
m_pageFlipsPending = 0;
if (Compositor *compositor = Compositor::self()) {
compositor->bufferSwapComplete();
compositor->addRepaintFull();
}
}
void DrmBackend::deactivate()
{
if (!m_active) {
return;
}
// block compositor
if (m_pageFlipsPending == 0 && Compositor::self()) {
Compositor::self()->aboutToSwapBuffers();
}
// hide cursor and disable
for (auto it = m_outputs.constBegin(); it != m_outputs.constEnd(); ++it) {
DrmOutput *o = *it;
o->hideCursor();
o->restoreSaved();
}
m_active = false;
}
void DrmBackend::pageFlipHandler(int fd, unsigned int frame, unsigned int sec, unsigned int usec, void *data)
{
Q_UNUSED(fd)
Q_UNUSED(frame)
Q_UNUSED(sec)
Q_UNUSED(usec)
auto output = reinterpret_cast<DrmOutput*>(data);
output->pageFlipped();
output->m_backend->m_pageFlipsPending--;
if (output->m_backend->m_pageFlipsPending == 0) {
// TODO: improve, this currently means we wait for all page flips or all outputs.
// It would be better to driver the repaint per output
if (Compositor::self()) {
Compositor::self()->bufferSwapComplete();
}
}
}
void DrmBackend::openDrm()
{
connect(LogindIntegration::self(), &LogindIntegration::sessionActiveChanged, this, &DrmBackend::activate);
VirtualTerminal::self()->init();
UdevDevice::Ptr device = m_udev->primaryGpu();
if (!device) {
qCWarning(KWIN_DRM) << "Did not find a GPU";
return;
}
int fd = LogindIntegration::self()->takeDevice(device->devNode());
if (fd < 0) {
qCWarning(KWIN_DRM) << "failed to open drm device at" << device->devNode();
return;
}
m_fd = fd;
m_active = true;
QSocketNotifier *notifier = new QSocketNotifier(m_fd, QSocketNotifier::Read, this);
connect(notifier, &QSocketNotifier::activated, this,
[this] {
if (!VirtualTerminal::self()->isActive()) {
return;
}
drmEventContext e;
memset(&e, 0, sizeof e);
e.version = DRM_EVENT_CONTEXT_VERSION;
e.page_flip_handler = pageFlipHandler;
drmHandleEvent(m_fd, &e);
}
);
m_drmId = device->sysNum();
queryResources();
// setup udevMonitor
if (m_udevMonitor) {
m_udevMonitor->filterSubsystemDevType("drm");
const int fd = m_udevMonitor->fd();
if (fd != -1) {
QSocketNotifier *notifier = new QSocketNotifier(fd, QSocketNotifier::Read, this);
connect(notifier, &QSocketNotifier::activated, this,
[this] {
auto device = m_udevMonitor->getDevice();
if (!device) {
return;
}
if (device->sysNum() != m_drmId) {
return;
}
if (device->hasProperty("HOTPLUG", "1")) {
qCDebug(KWIN_DRM) << "Received hot plug event for monitored drm device";
queryResources();
m_cursorIndex = (m_cursorIndex + 1) % 2;
updateCursor();
}
}
);
m_udevMonitor->enable();
}
}
setReady(true);
initCursor();
}
void DrmBackend::queryResources()
{
if (m_fd < 0) {
return;
}
ScopedDrmPointer<_drmModeRes, &drmModeFreeResources> resources(drmModeGetResources(m_fd));
if (!resources) {
qCWarning(KWIN_DRM) << "drmModeGetResources failed";
return;
}
QVector<DrmOutput*> connectedOutputs;
for (int i = 0; i < resources->count_connectors; ++i) {
const auto id = resources->connectors[i];
ScopedDrmPointer<_drmModeConnector, &drmModeFreeConnector> connector(drmModeGetConnector(m_fd, id));
if (!connector) {
continue;
}
if (connector->connection != DRM_MODE_CONNECTED) {
continue;
}
if (connector->count_modes == 0) {
continue;
}
if (DrmOutput *o = findOutput(connector->connector_id)) {
connectedOutputs << o;
continue;
}
bool crtcFound = false;
const quint32 crtcId = findCrtc(resources.data(), connector.data(), &crtcFound);
if (!crtcFound) {
continue;
}
ScopedDrmPointer<_drmModeCrtc, &drmModeFreeCrtc> crtc(drmModeGetCrtc(m_fd, crtcId));
if (!crtc) {
continue;
}
DrmOutput *drmOutput = new DrmOutput(this);
connect(drmOutput, &DrmOutput::dpmsChanged, this, &DrmBackend::outputDpmsChanged);
drmOutput->m_crtcId = crtcId;
if (crtc->mode_valid) {
drmOutput->m_mode = crtc->mode;
} else {
drmOutput->m_mode = connector->modes[0];
}
drmOutput->m_connector = connector->connector_id;
drmOutput->init(connector.data());
connectedOutputs << drmOutput;
}
// check for outputs which got removed
auto it = m_outputs.begin();
while (it != m_outputs.end()) {
if (connectedOutputs.contains(*it)) {
it++;
continue;
}
DrmOutput *removed = *it;
it = m_outputs.erase(it);
emit outputRemoved(removed);
delete removed;
}
for (auto it = connectedOutputs.constBegin(); it != connectedOutputs.constEnd(); ++it) {
if (!m_outputs.contains(*it)) {
emit outputAdded(*it);
}
}
m_outputs = connectedOutputs;
emit screensQueried();
// TODO: install global space
}
DrmOutput *DrmBackend::findOutput(quint32 connector)
{
auto it = std::find_if(m_outputs.constBegin(), m_outputs.constEnd(), [connector] (DrmOutput *o) {
return o->m_connector == connector;
});
if (it != m_outputs.constEnd()) {
return *it;
}
return nullptr;
}
quint32 DrmBackend::findCrtc(drmModeRes *res, drmModeConnector *connector, bool *ok)
{
if (ok) {
*ok = false;
}
ScopedDrmPointer<_drmModeEncoder, &drmModeFreeEncoder> encoder(drmModeGetEncoder(m_fd, connector->encoder_id));
if (encoder) {
if (!crtcIsUsed(encoder->crtc_id)) {
if (ok) {
*ok = true;
}
return encoder->crtc_id;
}
}
// let's iterate over all encoders to find a suitable crtc
for (int i = 0; i < connector->count_encoders; ++i) {
ScopedDrmPointer<_drmModeEncoder, &drmModeFreeEncoder> encoder(drmModeGetEncoder(m_fd, connector->encoders[i]));
if (!encoder) {
continue;
}
for (int j = 0; j < res->count_crtcs; ++j) {
if (!(encoder->possible_crtcs & (1 << j))) {
continue;
}
if (!crtcIsUsed(res->crtcs[j])) {
if (ok) {
*ok = true;
}
return res->crtcs[j];
}
}
}
return 0;
}
bool DrmBackend::crtcIsUsed(quint32 crtc)
{
auto it = std::find_if(m_outputs.constBegin(), m_outputs.constEnd(),
[crtc] (DrmOutput *o) {
return o->m_crtcId == crtc;
}
);
return it != m_outputs.constEnd();
}
void DrmBackend::present(DrmBuffer *buffer, DrmOutput *output)
{
if (output->present(buffer)) {
m_pageFlipsPending++;
if (m_pageFlipsPending == 1 && Compositor::self()) {
Compositor::self()->aboutToSwapBuffers();
}
}
}
void DrmBackend::installCursorFromServer()
{
updateCursorFromServer();
}
void DrmBackend::installCursorImage(Qt::CursorShape shape)
{
updateCursorImage(shape);
}
void DrmBackend::initCursor()
{
uint64_t capability = 0;
QSize cursorSize;
if (drmGetCap(m_fd, DRM_CAP_CURSOR_WIDTH, &capability) == 0) {
cursorSize.setWidth(capability);
} else {
cursorSize.setWidth(64);
}
if (drmGetCap(m_fd, DRM_CAP_CURSOR_HEIGHT, &capability) == 0) {
cursorSize.setHeight(capability);
} else {
cursorSize.setHeight(64);
}
m_cursor[0] = createBuffer(cursorSize);
m_cursor[0]->map(QImage::Format_ARGB32_Premultiplied);
m_cursor[0]->image()->fill(Qt::transparent);
m_cursor[1] = createBuffer(cursorSize);
m_cursor[1]->map(QImage::Format_ARGB32_Premultiplied);
m_cursor[0]->image()->fill(Qt::transparent);
// now we have screens and can set cursors, so start tracking
connect(this, &DrmBackend::cursorChanged, this, &DrmBackend::updateCursor);
connect(Cursor::self(), &Cursor::posChanged, this, &DrmBackend::moveCursor);
installCursorImage(Qt::ArrowCursor);
}
void DrmBackend::setCursor()
{
DrmBuffer *c = m_cursor[m_cursorIndex];
m_cursorIndex = (m_cursorIndex + 1) % 2;
for (auto it = m_outputs.constBegin(); it != m_outputs.constEnd(); ++it) {
(*it)->showCursor(c);
}
}
void DrmBackend::updateCursor()
{
const QImage &cursorImage = softwareCursor();
if (cursorImage.isNull()) {
hideCursor();
return;
}
QImage *c = m_cursor[m_cursorIndex]->image();
c->fill(Qt::transparent);
QPainter p;
p.begin(c);
p.drawImage(QPoint(0, 0), cursorImage);
p.end();
setCursor();
moveCursor();
}
void DrmBackend::hideCursor()
{
for (auto it = m_outputs.constBegin(); it != m_outputs.constEnd(); ++it) {
(*it)->hideCursor();
}
}
void DrmBackend::moveCursor()
{
const QPoint p = Cursor::pos() - softwareCursorHotspot();
for (auto it = m_outputs.constBegin(); it != m_outputs.constEnd(); ++it) {
(*it)->moveCursor(p);
}
}
QSize DrmBackend::size() const
{
if (m_outputs.isEmpty()) {
return QSize();
}
return m_outputs.first()->size();
}
Screens *DrmBackend::createScreens(QObject *parent)
{
return new DrmScreens(this, parent);
}
QPainterBackend *DrmBackend::createQPainterBackend()
{
return new DrmQPainterBackend(this);
}
OpenGLBackend *DrmBackend::createOpenGLBackend()
{
#if HAVE_GBM
return new EglGbmBackend(this);
#else
return AbstractBackend::createOpenGLBackend();
#endif
}
DrmBuffer *DrmBackend::createBuffer(const QSize &size)
{
DrmBuffer *b = new DrmBuffer(this, size);
m_buffers << b;
return b;
}
DrmBuffer *DrmBackend::createBuffer(gbm_surface *surface)
{
#if HAVE_GBM
DrmBuffer *b = new DrmBuffer(this, surface);
m_buffers << b;
return b;
#else
return nullptr;
#endif
}
void DrmBackend::bufferDestroyed(DrmBuffer *b)
{
m_buffers.removeAll(b);
}
void DrmBackend::outputDpmsChanged()
{
if (m_outputs.isEmpty()) {
return;
}
bool enabled = false;
for (auto it = m_outputs.constBegin(); it != m_outputs.constEnd(); ++it) {
enabled = enabled || (*it)->isDpmsEnabled();
}
setOutputsEnabled(enabled);
}
DrmOutput::DrmOutput(DrmBackend *backend)
: QObject()
, m_backend(backend)
{
}
DrmOutput::~DrmOutput()
{
hideCursor();
cleanupBlackBuffer();
delete m_waylandOutput.data();
}
void DrmOutput::hideCursor()
{
drmModeSetCursor(m_backend->fd(), m_crtcId, 0, 0, 0);
}
void DrmOutput::restoreSaved()
{
if (!m_savedCrtc.isNull()) {
drmModeSetCrtc(m_backend->fd(), m_savedCrtc->crtc_id, m_savedCrtc->buffer_id,
m_savedCrtc->x, m_savedCrtc->y, &m_connector, 1, &m_savedCrtc->mode);
}
}
void DrmOutput::showCursor(DrmBuffer *c)
{
const QSize &s = c->size();
drmModeSetCursor(m_backend->fd(), m_crtcId, c->handle(), s.width(), s.height());
}
void DrmOutput::moveCursor(const QPoint &globalPos)
{
const QPoint p = globalPos - m_globalPos;
drmModeMoveCursor(m_backend->fd(), m_crtcId, p.x(), p.y());
}
QSize DrmOutput::size() const
{
return QSize(m_mode.hdisplay, m_mode.vdisplay);
}
QRect DrmOutput::geometry() const
{
return QRect(m_globalPos, size());
}
bool DrmOutput::present(DrmBuffer *buffer)
{
if (!buffer || buffer->bufferId() == 0) {
return false;
}
if (!VirtualTerminal::self()->isActive()) {
m_currentBuffer = buffer;
return false;
}
if (m_dpmsMode != DpmsMode::On) {
return false;
}
if (m_currentBuffer) {
return false;
}
if (m_lastStride != buffer->stride()) {
// need to set a new mode first
if (!setMode(buffer)) {
return false;
}
}
const bool ok = drmModePageFlip(m_backend->fd(), m_crtcId, buffer->bufferId(), DRM_MODE_PAGE_FLIP_EVENT, this) == 0;
if (ok) {
m_currentBuffer = buffer;
} else {
qCWarning(KWIN_DRM) << "Page flip failed";
buffer->releaseGbm();
}
return ok;
}
void DrmOutput::pageFlipped()
{
if (!m_currentBuffer) {
return;
}
m_currentBuffer->releaseGbm();
m_currentBuffer = nullptr;
cleanupBlackBuffer();
}
void DrmOutput::cleanupBlackBuffer()
{
if (m_blackBuffer) {
delete m_blackBuffer;
m_blackBuffer = nullptr;
}
}
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();
}
}
void DrmOutput::init(drmModeConnector *connector)
{
initEdid(connector);
initDpms(connector);
m_savedCrtc.reset(drmModeGetCrtc(m_backend->fd(), m_crtcId));
blank();
setDpms(DpmsMode::On);
if (!m_waylandOutput.isNull()) {
delete m_waylandOutput.data();
m_waylandOutput.clear();
}
m_waylandOutput = waylandServer()->display()->createOutput();
if (!m_edid.eisaId.isEmpty()) {
m_waylandOutput->setManufacturer(QString::fromLatin1(m_edid.eisaId));
} else {
m_waylandOutput->setManufacturer(i18n("unknown"));
}
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));
}
m_waylandOutput->setModel(model);
} else if (!m_edid.serialNumber.isEmpty()) {
m_waylandOutput->setModel(QString::fromLatin1(m_edid.serialNumber));
} else {
m_waylandOutput->setModel(i18n("unknown"));
}
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
KSharedConfig::Ptr config = KSharedConfig::openConfig(KWIN_CONFIG);
const QByteArray unknown = QByteArrayLiteral("unkown");
KConfigGroup group = 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_waylandOutput->setPhysicalSize(physicalSize);
// read in mode information
for (int i = 0; i < connector->count_modes; ++i) {
auto *m = &connector->modes[i];
KWayland::Server::OutputInterface::ModeFlags flags;
if (isCurrentMode(m)) {
flags |= KWayland::Server::OutputInterface::ModeFlag::Current;
}
if (m->type & DRM_MODE_TYPE_PREFERRED) {
flags |= KWayland::Server::OutputInterface::ModeFlag::Preferred;
}
// 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;
}
m_waylandOutput->addMode(QSize(m->hdisplay, m->vdisplay), flags, refreshRate);
}
// 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
);
}
m_waylandOutput->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;
}
void DrmOutput::blank()
{
if (!m_blackBuffer) {
m_blackBuffer = m_backend->createBuffer(size());
m_blackBuffer->map();
m_blackBuffer->image()->fill(Qt::black);
}
setMode(m_blackBuffer);
}
bool DrmOutput::setMode(DrmBuffer *buffer)
{
if (drmModeSetCrtc(m_backend->fd(), m_crtcId, buffer->bufferId(), 0, 0, &m_connector, 1, &m_mode) == 0) {
m_lastStride = buffer->stride();
return true;
} else {
qCWarning(KWIN_DRM) << "Mode setting failed";
return false;
}
}
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());
}
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 (drmModeConnectorSetProperty(m_backend->fd(), m_connector, m_dpms->prop_id, uint64_t(mode)) != 0) {
qCWarning(KWIN_DRM) << "Setting DPMS failed";
return;
}
m_dpmsMode = mode;
if (m_waylandOutput) {
m_waylandOutput->setDpmsMode(toWaylandDpmsMode(m_dpmsMode));
}
emit dpmsChanged();
if (m_dpmsMode != DpmsMode::On) {
connect(input(), &InputRedirection::globalPointerChanged, this, &DrmOutput::reenableDpms);
connect(input(), &InputRedirection::pointerButtonStateChanged, this, &DrmOutput::reenableDpms);
connect(input(), &InputRedirection::pointerAxisChanged, this, &DrmOutput::reenableDpms);
connect(input(), &InputRedirection::keyStateChanged, this, &DrmOutput::reenableDpms);
} else {
disconnect(input(), &InputRedirection::globalPointerChanged, this, &DrmOutput::reenableDpms);
disconnect(input(), &InputRedirection::pointerButtonStateChanged, this, &DrmOutput::reenableDpms);
disconnect(input(), &InputRedirection::pointerAxisChanged, this, &DrmOutput::reenableDpms);
disconnect(input(), &InputRedirection::keyStateChanged, this, &DrmOutput::reenableDpms);
blank();
if (Compositor *compositor = Compositor::self()) {
compositor->addRepaintFull();
}
}
}
void DrmOutput::reenableDpms()
{
setDpms(DpmsMode::On);
}
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();
}
DrmBuffer::DrmBuffer(DrmBackend *backend, const QSize &size)
: m_backend(backend)
, m_size(size)
{
drm_mode_create_dumb createArgs;
memset(&createArgs, 0, sizeof createArgs);
createArgs.bpp = 32;
createArgs.width = size.width();
createArgs.height = size.height();
if (drmIoctl(m_backend->fd(), DRM_IOCTL_MODE_CREATE_DUMB, &createArgs) != 0) {
return;
}
m_handle = createArgs.handle;
m_bufferSize = createArgs.size;
m_stride = createArgs.pitch;
drmModeAddFB(m_backend->fd(), size.width(), size.height(), 24, 32,
m_stride, createArgs.handle, &m_bufferId);
}
#if HAVE_GBM
static void gbmCallback(gbm_bo *bo, void *data)
{
DrmBackend *backend = reinterpret_cast<DrmBackend*>(data);
const auto &buffers = backend->buffers();
for (auto buffer: buffers) {
if (buffer->gbm() == bo) {
delete buffer;
return;
}
}
}
#endif
DrmBuffer::DrmBuffer(DrmBackend *backend, gbm_surface *surface)
: m_backend(backend)
, m_surface(surface)
{
#if HAVE_GBM
m_bo = gbm_surface_lock_front_buffer(surface);
if (!m_bo) {
qCWarning(KWIN_DRM) << "Locking front buffer failed";
return;
}
m_size = QSize(gbm_bo_get_width(m_bo), gbm_bo_get_height(m_bo));
m_stride = gbm_bo_get_stride(m_bo);
if (drmModeAddFB(m_backend->fd(), m_size.width(), m_size.height(), 24, 32, m_stride, gbm_bo_get_handle(m_bo).u32, &m_bufferId) != 0) {
qCWarning(KWIN_DRM) << "drmModeAddFB failed";
}
gbm_bo_set_user_data(m_bo, m_backend, gbmCallback);
#endif
}
DrmBuffer::~DrmBuffer()
{
m_backend->bufferDestroyed(this);
delete m_image;
if (m_memory) {
munmap(m_memory, m_bufferSize);
}
if (m_bufferId) {
drmModeRmFB(m_backend->fd(), m_bufferId);
}
if (m_handle) {
drm_mode_destroy_dumb destroyArgs;
destroyArgs.handle = m_handle;
drmIoctl(m_backend->fd(), DRM_IOCTL_MODE_DESTROY_DUMB, &destroyArgs);
}
releaseGbm();
}
bool DrmBuffer::map(QImage::Format format)
{
if (!m_handle || !m_bufferId) {
return false;
}
drm_mode_map_dumb mapArgs;
memset(&mapArgs, 0, sizeof mapArgs);
mapArgs.handle = m_handle;
if (drmIoctl(m_backend->fd(), DRM_IOCTL_MODE_MAP_DUMB, &mapArgs) != 0) {
return false;
}
void *address = mmap(nullptr, m_bufferSize, PROT_WRITE, MAP_SHARED, m_backend->fd(), mapArgs.offset);
if (address == MAP_FAILED) {
return false;
}
m_memory = address;
m_image = new QImage((uchar*)m_memory, m_size.width(), m_size.height(), m_stride, format);
return !m_image->isNull();
}
void DrmBuffer::releaseGbm()
{
#if HAVE_GBM
if (m_bo) {
gbm_surface_release_buffer(m_surface, m_bo);
m_bo = nullptr;
}
#endif
}
}