kwin/src/renderloop.cpp

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/*
SPDX-FileCopyrightText: 2020 Vlad Zahorodnii <vlad.zahorodnii@kde.org>
SPDX-License-Identifier: GPL-2.0-or-later
*/
#include "renderloop.h"
#include "options.h"
#include "renderloop_p.h"
#include "utils.h"
#include "surfaceitem.h"
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namespace KWin
{
template <typename T>
T alignTimestamp(const T &timestamp, const T &alignment)
{
return timestamp + ((alignment - (timestamp % alignment)) % alignment);
}
RenderLoopPrivate *RenderLoopPrivate::get(RenderLoop *loop)
{
return loop->d.data();
}
RenderLoopPrivate::RenderLoopPrivate(RenderLoop *q)
: q(q)
{
compositeTimer.setSingleShot(true);
QObject::connect(&compositeTimer, &QTimer::timeout, q, [this]() { dispatch(); });
}
void RenderLoopPrivate::scheduleRepaint()
{
if (kwinApp()->isTerminating() || compositeTimer.isActive()) {
return;
}
if (vrrPolicy == RenderLoop::VrrPolicy::Always || (vrrPolicy == RenderLoop::VrrPolicy::Automatic && hasFullscreenSurface)) {
presentMode = SyncMode::Adaptive;
} else {
presentMode = SyncMode::Fixed;
}
const std::chrono::nanoseconds vblankInterval(1'000'000'000'000ull / refreshRate);
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const std::chrono::nanoseconds currentTime(std::chrono::steady_clock::now().time_since_epoch());
// Estimate when the next presentation will occur. Note that this is a prediction.
nextPresentationTimestamp = lastPresentationTimestamp + vblankInterval;
if (nextPresentationTimestamp < currentTime && presentMode == SyncMode::Fixed) {
nextPresentationTimestamp = lastPresentationTimestamp
+ alignTimestamp(currentTime - lastPresentationTimestamp, vblankInterval);
}
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// Estimate when it's a good time to perform the next compositing cycle.
const std::chrono::nanoseconds safetyMargin = std::chrono::milliseconds(3);
std::chrono::nanoseconds renderTime;
switch (options->latencyPolicy()) {
case LatencyExteremelyLow:
renderTime = std::chrono::nanoseconds(long(vblankInterval.count() * 0.1));
break;
case LatencyLow:
renderTime = std::chrono::nanoseconds(long(vblankInterval.count() * 0.25));
break;
case LatencyMedium:
renderTime = std::chrono::nanoseconds(long(vblankInterval.count() * 0.5));
break;
case LatencyHigh:
renderTime = std::chrono::nanoseconds(long(vblankInterval.count() * 0.75));
break;
case LatencyExtremelyHigh:
renderTime = std::chrono::nanoseconds(long(vblankInterval.count() * 0.9));
break;
}
switch (options->renderTimeEstimator()) {
case RenderTimeEstimatorMinimum:
renderTime = std::max(renderTime, renderJournal.minimum());
break;
case RenderTimeEstimatorMaximum:
renderTime = std::max(renderTime, renderJournal.maximum());
break;
case RenderTimeEstimatorAverage:
renderTime = std::max(renderTime, renderJournal.average());
break;
}
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std::chrono::nanoseconds nextRenderTimestamp = nextPresentationTimestamp - renderTime - safetyMargin;
// If we can't render the frame before the deadline, start compositing immediately.
if (nextRenderTimestamp < currentTime) {
nextRenderTimestamp = currentTime;
}
const std::chrono::nanoseconds waitInterval = nextRenderTimestamp - currentTime;
compositeTimer.start(std::chrono::duration_cast<std::chrono::milliseconds>(waitInterval));
}
void RenderLoopPrivate::delayScheduleRepaint()
{
pendingReschedule = true;
}
void RenderLoopPrivate::maybeScheduleRepaint()
{
if (pendingReschedule) {
scheduleRepaint();
pendingReschedule = false;
}
}
void RenderLoopPrivate::notifyFrameFailed()
{
Q_ASSERT(pendingFrameCount > 0);
pendingFrameCount--;
if (!inhibitCount) {
maybeScheduleRepaint();
}
}
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void RenderLoopPrivate::notifyFrameCompleted(std::chrono::nanoseconds timestamp)
{
Q_ASSERT(pendingFrameCount > 0);
pendingFrameCount--;
if (lastPresentationTimestamp <= timestamp) {
lastPresentationTimestamp = timestamp;
} else {
qCWarning(KWIN_CORE,
"Got invalid presentation timestamp: %lld (current %lld)",
static_cast<long long>(timestamp.count()),
static_cast<long long>(lastPresentationTimestamp.count()));
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lastPresentationTimestamp = std::chrono::steady_clock::now().time_since_epoch();
}
if (!inhibitCount) {
maybeScheduleRepaint();
}
Q_EMIT q->framePresented(q, timestamp);
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}
void RenderLoopPrivate::dispatch()
{
// On X11, we want to ignore repaints that are scheduled by windows right before
// the Compositor starts repainting.
pendingRepaint = true;
Q_EMIT q->frameRequested(q);
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// The Compositor may decide to not repaint when the frameRequested() signal is
// emitted, in which case the pending repaint flag has to be reset manually.
pendingRepaint = false;
}
void RenderLoopPrivate::invalidate()
{
pendingReschedule = false;
pendingFrameCount = 0;
compositeTimer.stop();
}
RenderLoop::RenderLoop(QObject *parent)
: QObject(parent)
, d(new RenderLoopPrivate(this))
{
}
RenderLoop::~RenderLoop()
{
}
void RenderLoop::inhibit()
{
d->inhibitCount++;
if (d->inhibitCount == 1) {
d->compositeTimer.stop();
}
}
void RenderLoop::uninhibit()
{
Q_ASSERT(d->inhibitCount > 0);
d->inhibitCount--;
if (d->inhibitCount == 0) {
d->maybeScheduleRepaint();
}
}
void RenderLoop::beginFrame()
{
d->pendingRepaint = false;
d->pendingFrameCount++;
d->renderJournal.beginFrame();
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}
void RenderLoop::endFrame()
{
d->renderJournal.endFrame();
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}
int RenderLoop::refreshRate() const
{
return d->refreshRate;
}
void RenderLoop::setRefreshRate(int refreshRate)
{
if (d->refreshRate == refreshRate) {
return;
}
d->refreshRate = refreshRate;
Q_EMIT refreshRateChanged();
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}
void RenderLoop::scheduleRepaint()
{
if (d->pendingRepaint) {
return;
}
if (!d->pendingFrameCount && !d->inhibitCount) {
d->scheduleRepaint();
} else {
d->delayScheduleRepaint();
}
}
std::chrono::nanoseconds RenderLoop::lastPresentationTimestamp() const
{
return d->lastPresentationTimestamp;
}
std::chrono::nanoseconds RenderLoop::nextPresentationTimestamp() const
{
return d->nextPresentationTimestamp;
}
void RenderLoop::setFullscreenSurface(SurfaceItem *surfaceItem)
{
d->hasFullscreenSurface = surfaceItem != nullptr;
}
RenderLoop::VrrPolicy RenderLoop::vrrPolicy() const
{
return d->vrrPolicy;
}
void RenderLoop::setVrrPolicy(VrrPolicy policy)
{
d->vrrPolicy = policy;
}
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} // namespace KWin