kwin/src/colordevice.cpp

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/*
SPDX-FileCopyrightText: 2020 Vlad Zahorodnii <vlad.zahorodnii@kde.org>
SPDX-License-Identifier: GPL-2.0-or-later
*/
#include "colordevice.h"
#include "abstract_output.h"
#include "utils.h"
#include "3rdparty/colortemperature.h"
#include <QTimer>
#include <lcms2.h>
namespace KWin
{
template <typename T>
struct CmsDeleter;
template <typename T>
using CmsScopedPointer = QScopedPointer<T, CmsDeleter<T>>;
template <>
struct CmsDeleter<cmsPipeline>
{
static inline void cleanup(cmsPipeline *pipeline)
{
if (pipeline) {
cmsPipelineFree(pipeline);
}
}
};
template <>
struct CmsDeleter<cmsStage>
{
static inline void cleanup(cmsStage *stage)
{
if (stage) {
cmsStageFree(stage);
}
}
};
template <>
struct CmsDeleter<cmsToneCurve>
{
static inline void cleanup(cmsToneCurve *toneCurve)
{
if (toneCurve) {
cmsFreeToneCurve(toneCurve);
}
}
};
class ColorDevicePrivate
{
public:
enum DirtyToneCurveBit {
DirtyTemperatureToneCurve = 0x1,
DirtyBrightnessToneCurve = 0x2,
DirtyCalibrationToneCurve = 0x4,
};
Q_DECLARE_FLAGS(DirtyToneCurves, DirtyToneCurveBit)
void rebuildPipeline();
void unlinkPipeline();
void updateTemperatureToneCurves();
void updateBrightnessToneCurves();
void updateCalibrationToneCurves();
AbstractOutput *output;
DirtyToneCurves dirtyCurves;
QTimer *updateTimer;
QString profile;
uint brightness = 100;
uint temperature = 6500;
CmsScopedPointer<cmsStage> temperatureStage;
CmsScopedPointer<cmsStage> brightnessStage;
CmsScopedPointer<cmsStage> calibrationStage;
CmsScopedPointer<cmsPipeline> pipeline;
};
void ColorDevicePrivate::rebuildPipeline()
{
if (!pipeline) {
pipeline.reset(cmsPipelineAlloc(nullptr, 3, 3));
}
unlinkPipeline();
if (dirtyCurves & DirtyCalibrationToneCurve) {
updateCalibrationToneCurves();
}
if (dirtyCurves & DirtyBrightnessToneCurve) {
updateBrightnessToneCurves();
}
if (dirtyCurves & DirtyTemperatureToneCurve) {
updateTemperatureToneCurves();
}
dirtyCurves = DirtyToneCurves();
if (calibrationStage) {
if (!cmsPipelineInsertStage(pipeline.data(), cmsAT_END, calibrationStage.data())) {
qCWarning(KWIN_CORE) << "Failed to insert the color calibration pipeline stage";
}
}
if (temperatureStage) {
if (!cmsPipelineInsertStage(pipeline.data(), cmsAT_END, temperatureStage.data())) {
qCWarning(KWIN_CORE) << "Failed to insert the color temperature pipeline stage";
}
}
if (brightnessStage) {
if (!cmsPipelineInsertStage(pipeline.data(), cmsAT_END, brightnessStage.data())) {
qCWarning(KWIN_CORE) << "Failed to insert the color brightness pipeline stage";
}
}
}
void ColorDevicePrivate::unlinkPipeline()
{
while (true) {
cmsStage *last = nullptr;
cmsPipelineUnlinkStage(pipeline.data(), cmsAT_END, &last);
if (!last) {
break;
}
}
}
static qreal interpolate(qreal a, qreal b, qreal blendFactor)
{
return (1 - blendFactor) * a + blendFactor * b;
}
void ColorDevicePrivate::updateTemperatureToneCurves()
{
temperatureStage.reset();
if (temperature == 6500) {
return;
}
// Note that cmsWhitePointFromTemp() returns a slightly green-ish white point.
const int blackBodyColorIndex = ((temperature - 1000) / 100) * 3;
const qreal blendFactor = (temperature % 100) / 100.0;
const qreal xWhitePoint = interpolate(blackbodyColor[blackBodyColorIndex + 0],
blackbodyColor[blackBodyColorIndex + 3],
blendFactor);
const qreal yWhitePoint = interpolate(blackbodyColor[blackBodyColorIndex + 1],
blackbodyColor[blackBodyColorIndex + 4],
blendFactor);
const qreal zWhitePoint = interpolate(blackbodyColor[blackBodyColorIndex + 2],
blackbodyColor[blackBodyColorIndex + 5],
blendFactor);
const double redCurveParams[] = { 1.0, xWhitePoint, 0.0 };
const double greenCurveParams[] = { 1.0, yWhitePoint, 0.0 };
const double blueCurveParams[] = { 1.0, zWhitePoint, 0.0 };
CmsScopedPointer<cmsToneCurve> redCurve(cmsBuildParametricToneCurve(nullptr, 2, redCurveParams));
if (!redCurve) {
qCWarning(KWIN_CORE) << "Failed to build the temperature tone curve for the red channel";
return;
}
CmsScopedPointer<cmsToneCurve> greenCurve(cmsBuildParametricToneCurve(nullptr, 2, greenCurveParams));
if (!greenCurve) {
qCWarning(KWIN_CORE) << "Failed to build the temperature tone curve for the green channel";
return;
}
CmsScopedPointer<cmsToneCurve> blueCurve(cmsBuildParametricToneCurve(nullptr, 2, blueCurveParams));
if (!blueCurve) {
qCWarning(KWIN_CORE) << "Failed to build the temperature tone curve for the blue channel";
return;
}
// The ownership of the tone curves will be moved to the pipeline stage.
cmsToneCurve *toneCurves[] = { redCurve.take(), greenCurve.take(), blueCurve.take() };
temperatureStage.reset(cmsStageAllocToneCurves(nullptr, 3, toneCurves));
if (!temperatureStage) {
qCWarning(KWIN_CORE) << "Failed to create the color temperature pipeline stage";
}
}
void ColorDevicePrivate::updateBrightnessToneCurves()
{
brightnessStage.reset();
if (brightness == 100) {
return;
}
const double curveParams[] = { 1.0, brightness / 100.0, 0.0 };
CmsScopedPointer<cmsToneCurve> redCurve(cmsBuildParametricToneCurve(nullptr, 2, curveParams));
if (!redCurve) {
qCWarning(KWIN_CORE) << "Failed to build the brightness tone curve for the red channel";
return;
}
CmsScopedPointer<cmsToneCurve> greenCurve(cmsBuildParametricToneCurve(nullptr, 2, curveParams));
if (!greenCurve) {
qCWarning(KWIN_CORE) << "Failed to build the brightness tone curve for the green channel";
return;
}
CmsScopedPointer<cmsToneCurve> blueCurve(cmsBuildParametricToneCurve(nullptr, 2, curveParams));
if (!blueCurve) {
qCWarning(KWIN_CORE) << "Failed to build the brightness tone curve for the blue channel";
return;
}
// The ownership of the tone curves will be moved to the pipeline stage.
cmsToneCurve *toneCurves[] = { redCurve.take(), greenCurve.take(), blueCurve.take() };
brightnessStage.reset(cmsStageAllocToneCurves(nullptr, 3, toneCurves));
if (!brightnessStage) {
qCWarning(KWIN_CORE) << "Failed to create the color brightness pipeline stage";
}
}
void ColorDevicePrivate::updateCalibrationToneCurves()
{
calibrationStage.reset();
if (profile.isNull()) {
return;
}
cmsHPROFILE handle = cmsOpenProfileFromFile(profile.toUtf8(), "r");
if (!handle) {
qCWarning(KWIN_CORE) << "Failed to open color profile file:" << profile;
return;
}
cmsToneCurve **vcgt = static_cast<cmsToneCurve **>(cmsReadTag(handle, cmsSigVcgtTag));
if (!vcgt || !vcgt[0]) {
qCWarning(KWIN_CORE) << "Profile" << profile << "has no VCGT tag";
} else {
// Need to duplicate the VCGT tone curves as they are owned by the profile.
cmsToneCurve *toneCurves[] = {
cmsDupToneCurve(vcgt[0]),
cmsDupToneCurve(vcgt[1]),
cmsDupToneCurve(vcgt[2]),
};
calibrationStage.reset(cmsStageAllocToneCurves(nullptr, 3, toneCurves));
if (!calibrationStage) {
qCWarning(KWIN_CORE) << "Failed to create the color calibration pipeline stage";
}
}
cmsCloseProfile(handle);
}
ColorDevice::ColorDevice(AbstractOutput *output, QObject *parent)
: QObject(parent)
, d(new ColorDevicePrivate)
{
d->updateTimer = new QTimer(this);
d->updateTimer->setSingleShot(true);
connect(d->updateTimer, &QTimer::timeout, this, &ColorDevice::update);
d->output = output;
scheduleUpdate();
}
ColorDevice::~ColorDevice()
{
if (d->pipeline) {
d->unlinkPipeline();
}
}
AbstractOutput *ColorDevice::output() const
{
return d->output;
}
uint ColorDevice::brightness() const
{
return d->brightness;
}
void ColorDevice::setBrightness(uint brightness)
{
if (brightness > 100) {
qCWarning(KWIN_CORE) << "Got invalid brightness value:" << brightness;
brightness = 100;
}
if (d->brightness == brightness) {
return;
}
d->brightness = brightness;
d->dirtyCurves |= ColorDevicePrivate::DirtyBrightnessToneCurve;
scheduleUpdate();
Q_EMIT brightnessChanged();
}
uint ColorDevice::temperature() const
{
return d->temperature;
}
void ColorDevice::setTemperature(uint temperature)
{
if (temperature > 6500) {
qCWarning(KWIN_CORE) << "Got invalid temperature value:" << temperature;
temperature = 6500;
}
if (d->temperature == temperature) {
return;
}
d->temperature = temperature;
d->dirtyCurves |= ColorDevicePrivate::DirtyTemperatureToneCurve;
scheduleUpdate();
Q_EMIT temperatureChanged();
}
QString ColorDevice::profile() const
{
return d->profile;
}
void ColorDevice::setProfile(const QString &profile)
{
if (d->profile == profile) {
return;
}
d->profile = profile;
d->dirtyCurves |= ColorDevicePrivate::DirtyCalibrationToneCurve;
scheduleUpdate();
Q_EMIT profileChanged();
}
void ColorDevice::update()
{
d->rebuildPipeline();
GammaRamp gammaRamp(d->output->gammaRampSize());
uint16_t *redChannel = gammaRamp.red();
uint16_t *greenChannel = gammaRamp.green();
uint16_t *blueChannel = gammaRamp.blue();
for (uint32_t i = 0; i < gammaRamp.size(); ++i) {
const uint16_t index = (i * 0xffff) / (gammaRamp.size() - 1);
const uint16_t in[3] = { index, index, index };
uint16_t out[3] = { 0 };
cmsPipelineEval16(in, out, d->pipeline.data());
redChannel[i] = out[0];
greenChannel[i] = out[1];
blueChannel[i] = out[2];
}
if (!d->output->setGammaRamp(gammaRamp)) {
qCWarning(KWIN_CORE) << "Failed to update gamma ramp for output" << d->output;
}
}
void ColorDevice::scheduleUpdate()
{
d->updateTimer->start();
}
} // namespace KWin