kwin/autotests/test_colorspaces.cpp

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/*
SPDX-FileCopyrightText: 2023 Xaver Hugl <xaver.hugl@gmail.com>
SPDX-License-Identifier: LGPL-2.0-or-later
*/
#include <QTest>
#include "core/colorspace.h"
using namespace KWin;
class TestColorspaces : public QObject
{
Q_OBJECT
public:
TestColorspaces() = default;
private Q_SLOTS:
void roundtripConversion_data();
void roundtripConversion();
void nonNormalizedPrimaries();
};
static bool compareVectors(const QVector3D &one, const QVector3D &two, float maxDifference)
{
const bool ret = std::abs(one.x() - two.x()) <= maxDifference
&& std::abs(one.y() - two.y()) <= maxDifference
&& std::abs(one.z() - two.z()) <= maxDifference;
if (!ret) {
qWarning() << one << "!=" << two << "within" << maxDifference;
}
return ret;
}
static const double s_resolution10bit = std::pow(1.0 / 2.0, 10);
void TestColorspaces::roundtripConversion_data()
{
QTest::addColumn<NamedColorimetry>("srcColorimetry");
QTest::addColumn<TransferFunction::Type>("srcTransferFunction");
QTest::addColumn<NamedColorimetry>("dstColorimetry");
QTest::addColumn<TransferFunction::Type>("dstTransferFunction");
QTest::addColumn<double>("requiredAccuracy");
QTest::addRow("BT709 (sRGB) <-> BT2020 (linear)") << NamedColorimetry::BT709 << TransferFunction::sRGB << NamedColorimetry::BT2020 << TransferFunction::linear << s_resolution10bit;
QTest::addRow("BT709 (gamma 2.2) <-> BT2020 (linear)") << NamedColorimetry::BT709 << TransferFunction::gamma22 << NamedColorimetry::BT2020 << TransferFunction::linear << s_resolution10bit;
QTest::addRow("BT709 (scRGB) <-> BT2020 (linear)") << NamedColorimetry::BT709 << TransferFunction::scRGB << NamedColorimetry::BT2020 << TransferFunction::linear << s_resolution10bit;
QTest::addRow("BT709 (linear) <-> BT2020 (linear)") << NamedColorimetry::BT709 << TransferFunction::linear << NamedColorimetry::BT2020 << TransferFunction::linear << s_resolution10bit;
QTest::addRow("BT709 (PQ) <-> BT2020 (linear)") << NamedColorimetry::BT709 << TransferFunction::PerceptualQuantizer << NamedColorimetry::BT2020 << TransferFunction::linear << 3 * s_resolution10bit;
}
void TestColorspaces::roundtripConversion()
{
QFETCH(NamedColorimetry, srcColorimetry);
QFETCH(TransferFunction::Type, srcTransferFunction);
QFETCH(NamedColorimetry, dstColorimetry);
QFETCH(TransferFunction::Type, dstTransferFunction);
QFETCH(double, requiredAccuracy);
const auto src = ColorDescription(srcColorimetry, srcTransferFunction, 100, 0, 100, 100);
const auto dst = ColorDescription(dstColorimetry, dstTransferFunction, 100, 0, 100, 100);
const QVector3D red(1, 0, 0);
const QVector3D green(0, 1, 0);
const QVector3D blue(0, 0, 1);
const QVector3D white(1, 1, 1);
QVERIFY(compareVectors(dst.mapTo(src.mapTo(red, dst), src), red, requiredAccuracy));
QVERIFY(compareVectors(dst.mapTo(src.mapTo(green, dst), src), green, requiredAccuracy));
QVERIFY(compareVectors(dst.mapTo(src.mapTo(blue, dst), src), blue, requiredAccuracy));
QVERIFY(compareVectors(dst.mapTo(src.mapTo(white, dst), src), white, requiredAccuracy));
}
void TestColorspaces::nonNormalizedPrimaries()
{
// this test ensures that non-normalized primaries don't mess up the transformations between color spaces
const auto from = Colorimetry::fromName(NamedColorimetry::BT709);
const auto to = Colorimetry(Colorimetry::xyToXYZ(from.red()) * 2, Colorimetry::xyToXYZ(from.green()) * 2, Colorimetry::xyToXYZ(from.blue()) * 2, Colorimetry::xyToXYZ(from.white()) * 2);
const auto convertedWhite = from.toOther(to) * QVector3D(1, 1, 1);
QCOMPARE_LE(std::abs(1 - convertedWhite.x()), s_resolution10bit);
QCOMPARE_LE(std::abs(1 - convertedWhite.y()), s_resolution10bit);
QCOMPARE_LE(std::abs(1 - convertedWhite.z()), s_resolution10bit);
}
QTEST_MAIN(TestColorspaces)
#include "test_colorspaces.moc"