示例#1
0
void KisPaintDeviceTest::testCreation()
{
    const KoColorSpace * cs = KoColorSpaceRegistry::instance()->rgb8();
    KisPaintDeviceSP dev = new KisPaintDevice(cs);
    QVERIFY(dev->objectName().isEmpty());

    dev = new KisPaintDevice(cs);
    QVERIFY(*dev->colorSpace() == *cs);
    QVERIFY(dev->x() == 0);
    QVERIFY(dev->y() == 0);
    QVERIFY(dev->pixelSize() == cs->pixelSize());
    QVERIFY(dev->channelCount() == cs->channelCount());
    QVERIFY(dev->dataManager() != 0);

    KisImageSP image = new KisImage(0, 1000, 1000, cs, "merge test");
    KisPaintLayerSP layer = new KisPaintLayer(image, "bla", 125);

    dev = new KisPaintDevice(layer.data(), cs);
    QVERIFY(*dev->colorSpace() == *cs);
    QVERIFY(dev->x() == 0);
    QVERIFY(dev->y() == 0);
    QVERIFY(dev->pixelSize() == cs->pixelSize());
    QVERIFY(dev->channelCount() == cs->channelCount());
    QVERIFY(dev->dataManager() != 0);

    // Let the layer go out of scope and see what happens
    {
        KisPaintLayerSP l2 = new KisPaintLayer(image, "blabla", 250);
        dev = new KisPaintDevice(l2.data(), cs);
    }

}
示例#2
0
void KisPaintDeviceTest::testPlanarReadWrite()
{
    const KoColorSpace * cs = KoColorSpaceRegistry::instance()->rgb8();
    KisPaintDeviceSP dev = new KisPaintDevice(cs);

    quint8* pixel = new quint8[cs->pixelSize()];
    cs->fromQColor(QColor(255, 200, 155, 100), pixel);
    dev->fill(0, 0, 5000, 5000, pixel);
    delete[] pixel;

    QColor c1;
    dev->pixel(5, 5, &c1);

    QVector<quint8*> planes = dev->readPlanarBytes(500, 500, 100, 100);
    QVector<quint8*> swappedPlanes;

    QCOMPARE((int)planes.size(), (int)dev->channelCount());

    for (int i = 0; i < 100*100; i++) {
        // BGRA encoded
        QVERIFY(planes.at(2)[i] == 255);
        QVERIFY(planes.at(1)[i] == 200);
        QVERIFY(planes.at(0)[i] == 155);
        QVERIFY(planes.at(3)[i] == 100);
    }

    for (uint i = 1; i < dev->channelCount() + 1; ++i) {
        swappedPlanes.append(planes[dev->channelCount() - i]);
    }

    dev->writePlanarBytes(swappedPlanes, 0, 0, 100, 100);

    dev->convertToQImage(0, 0, 0, 1000, 1000).save("planar.png");

    dev->pixel(5, 5, &c1);

    QVERIFY(c1.red() == 200);
    QVERIFY(c1.green() == 255);
    QVERIFY(c1.blue() == 100);
    QVERIFY(c1.alpha() == 155);

    dev->pixel(75, 50, &c1);

    QVERIFY(c1.red() == 200);
    QVERIFY(c1.green() == 255);
    QVERIFY(c1.blue() == 100);
    QVERIFY(c1.alpha() == 155);

    // check if one of the planes is Null.
    Q_ASSERT(planes.size() == 4);
    delete planes[2];
    planes[2] = 0;
    dev->writePlanarBytes(planes, 0, 0, 100, 100);
    dev->convertToQImage(0, 0, 0, 1000, 1000).save("planar_noR.png");

    dev->pixel(75, 50, &c1);

    QCOMPARE(c1.red(), 200);
    QCOMPARE(c1.green(), 200);
    QCOMPARE(c1.blue(), 155);
    QCOMPARE(c1.alpha(), 100);

    qDeleteAll(planes);
    swappedPlanes.clear();
}
示例#3
0
bool KisTIFFWriterVisitor::saveLayerProjection(KisLayer *layer)
{
    dbgFile << "visiting on layer" << layer->name() << "";
    KisPaintDeviceSP pd = layer->projection();
    // Save depth
    int depth = 8 * pd->pixelSize() / pd->channelCount();
    TIFFSetField(image(), TIFFTAG_BITSPERSAMPLE, depth);
    // Save number of samples
    if (m_options->alpha) {
        TIFFSetField(image(), TIFFTAG_SAMPLESPERPIXEL, pd->channelCount());
        uint16 sampleinfo[1] = { EXTRASAMPLE_UNASSALPHA };
        TIFFSetField(image(), TIFFTAG_EXTRASAMPLES, 1, sampleinfo);
    } else {
        TIFFSetField(image(), TIFFTAG_SAMPLESPERPIXEL, pd->channelCount() - 1);
        TIFFSetField(image(), TIFFTAG_EXTRASAMPLES, 0);
    }
    // Save colorspace information
    uint16 color_type;
    uint16 sample_format = SAMPLEFORMAT_UINT;
    if (!writeColorSpaceInformation(image(), pd->colorSpace(), color_type, sample_format)) { // unsupported colorspace
        return false;
    }
    TIFFSetField(image(), TIFFTAG_PHOTOMETRIC, color_type);
    TIFFSetField(image(), TIFFTAG_SAMPLEFORMAT, sample_format);
    TIFFSetField(image(), TIFFTAG_IMAGEWIDTH, layer->image()->width());
    TIFFSetField(image(), TIFFTAG_IMAGELENGTH, layer->image()->height());

    // Set the compression options
    TIFFSetField(image(), TIFFTAG_COMPRESSION, m_options->compressionType);
    TIFFSetField(image(), TIFFTAG_FAXMODE, m_options->faxMode);
    TIFFSetField(image(), TIFFTAG_JPEGQUALITY, m_options->jpegQuality);
    TIFFSetField(image(), TIFFTAG_ZIPQUALITY, m_options->deflateCompress);
    TIFFSetField(image(), TIFFTAG_PIXARLOGQUALITY, m_options->pixarLogCompress);

    // Set the predictor
    TIFFSetField(image(), TIFFTAG_PREDICTOR, m_options->predictor);

    // Use contiguous configuration
    TIFFSetField(image(), TIFFTAG_PLANARCONFIG, PLANARCONFIG_CONTIG);
    // Use 8 rows per strip
    TIFFSetField(image(), TIFFTAG_ROWSPERSTRIP, 8);

    // Save profile
    if (m_options->saveProfile) {
        const KoColorProfile* profile = pd->colorSpace()->profile();
        if (profile && profile->type() == "icc" && !profile->rawData().isEmpty()) {
            QByteArray ba = profile->rawData();
            TIFFSetField(image(), TIFFTAG_ICCPROFILE, ba.size(), ba.constData());
        }
    }
    tsize_t stripsize = TIFFStripSize(image());
    tdata_t buff = _TIFFmalloc(stripsize);
    qint32 height = layer->image()->height();
    qint32 width = layer->image()->width();
    bool r = true;
    for (int y = 0; y < height; y++) {
        KisHLineConstIteratorSP it = pd->createHLineConstIteratorNG(0, y, width);
        switch (color_type) {
        case PHOTOMETRIC_MINISBLACK: {
            quint8 poses[] = { 0, 1 };
            r = copyDataToStrips(it, buff, depth, sample_format, 1, poses);
        }
        break;
        case PHOTOMETRIC_RGB: {
            quint8 poses[4];
            if (sample_format == SAMPLEFORMAT_IEEEFP) {
                poses[2] = 2;
                poses[1] = 1;
                poses[0] = 0;
                poses[3] = 3;
            } else {
                poses[0] = 2;
                poses[1] = 1;
                poses[2] = 0;
                poses[3] = 3;
            }
            r = copyDataToStrips(it, buff, depth, sample_format, 3, poses);
        }
        break;
        case PHOTOMETRIC_SEPARATED: {
            quint8 poses[] = { 0, 1, 2, 3, 4 };
            r = copyDataToStrips(it, buff, depth, sample_format, 4, poses);
        }
        break;
        case PHOTOMETRIC_ICCLAB: {
            quint8 poses[] = { 0, 1, 2, 3 };
            r = copyDataToStrips(it, buff, depth, sample_format, 3, poses);
        }
        break;
        return false;
        }
        if (!r) return false;
        TIFFWriteScanline(image(), buff, y, (tsample_t) - 1);
    }
    _TIFFfree(buff);
    TIFFWriteDirectory(image());
    return true;
}