void KisFixedPaintDeviceTest::testClear()
{
const KoColorSpace * cs = KoColorSpaceRegistry::instance()->rgb8();
KisFixedPaintDeviceSP dev = new KisFixedPaintDevice(cs);
dev->clear(QRect(0, 0, 100, 100));
QVERIFY(dev->bounds() == QRect(0, 0, 100, 100));
QVERIFY(cs->opacityU8(dev->data() + (50 * 50 * cs->pixelSize())) == OPACITY_TRANSPARENT_U8);
}
void KisAutoBrush::generateMaskAndApplyMaskOrCreateDab(KisFixedPaintDeviceSP dst,
KisBrush::ColoringInformation* coloringInformation,
double scaleX, double scaleY, double angle,
const KisPaintInformation& info,
double subPixelX , double subPixelY, qreal softnessFactor) const
{
Q_UNUSED(info);
// Generate the paint device from the mask
const KoColorSpace* cs = dst->colorSpace();
quint32 pixelSize = cs->pixelSize();
// mask dimension methods already includes KisBrush::angle()
int dstWidth = maskWidth(scaleX, angle, subPixelX, subPixelY, info);
int dstHeight = maskHeight(scaleY, angle, subPixelX, subPixelY, info);
QPointF hotSpot = this->hotSpot(scaleX, scaleY, angle, info);
// mask size and hotSpot function take the KisBrush rotation into account
angle += KisBrush::angle();
// if there's coloring information, we merely change the alpha: in that case,
// the dab should be big enough!
if (coloringInformation) {
// old bounds
QRect oldBounds = dst->bounds();
// new bounds. we don't care if there is some extra memory occcupied.
dst->setRect(QRect(0, 0, dstWidth, dstHeight));
if (dstWidth * dstHeight <= oldBounds.width() * oldBounds.height()) {
// just clear the data in dst,
memset(dst->data(), OPACITY_TRANSPARENT_U8, dstWidth * dstHeight * dst->pixelSize());
} else {
// enlarge the data
dst->initialize();
}
} else {
if (dst->data() == 0 || dst->bounds().isEmpty()) {
qWarning() << "Creating a default black dab: no coloring info and no initialized paint device to mask";
dst->clear(QRect(0, 0, dstWidth, dstHeight));
}
Q_ASSERT(dst->bounds().width() >= dstWidth && dst->bounds().height() >= dstHeight);
}
quint8* dabPointer = dst->data();
quint8* color = 0;
if (coloringInformation) {
if (dynamic_cast<PlainColoringInformation*>(coloringInformation)) {
color = const_cast<quint8*>(coloringInformation->color());
}
}
double invScaleX = 1.0 / scaleX;
double invScaleY = 1.0 / scaleY;
double centerX = hotSpot.x() - 0.5 + subPixelX;
double centerY = hotSpot.y() - 0.5 + subPixelY;
d->shape->setSoftness( softnessFactor );
if (coloringInformation) {
if (color && pixelSize == 4) {
fillPixelOptimized_4bytes(color, dabPointer, dstWidth * dstHeight);
} else if (color) {
fillPixelOptimized_general(color, dabPointer, dstWidth * dstHeight, pixelSize);
} else {
for (int y = 0; y < dstHeight; y++) {
for (int x = 0; x < dstWidth; x++) {
memcpy(dabPointer, coloringInformation->color(), pixelSize);
coloringInformation->nextColumn();
dabPointer += pixelSize;
}
coloringInformation->nextRow();
}
}
}
MaskProcessingData data(dst, cs, d->randomness, d->density,
centerX, centerY,
invScaleX, invScaleY,
angle);
KisBrushMaskApplicatorBase *applicator = d->shape->applicator();
applicator->initializeData(&data);
int jobs = d->idealThreadCountCached;
if(dstHeight > 100 && jobs >= 4) {
int splitter = dstHeight/jobs;
QVector<QRect> rects;
for(int i = 0; i < jobs - 1; i++) {
rects << QRect(0, i*splitter, dstWidth, splitter);
}
rects << QRect(0, (jobs - 1)*splitter, dstWidth, dstHeight - (jobs - 1)*splitter);
OperatorWrapper wrapper(applicator);
QtConcurrent::blockingMap(rects, wrapper);
} else {
QRect rect(0, 0, dstWidth, dstHeight);
applicator->process(rect);
}
}