Exemple #1
0
void KoPathPointInsertCommand::undo()
{
    QUndoCommand::undo();
    for (int i = 0; i < m_pointDataList.size(); ++i) {
        const KoPathPointData &pdBefore = m_pointDataList.at(i);
        KoPathShape * pathShape = pdBefore.pathShape;
        KoPathPointIndex piAfter = pdBefore.pointIndex;
        ++piAfter.second;

        KoPathPoint * before = pathShape->pointByIndex(pdBefore.pointIndex);

        m_points[i] = pathShape->removePoint(piAfter);

        if (m_points[i]->properties() & KoPathPoint::CloseSubpath) {
            piAfter.second = 0;
        }

        KoPathPoint * after = pathShape->pointByIndex(piAfter);

        if (before->activeControlPoint2()) {
            QPointF controlPoint2 = before->controlPoint2();
            qSwap(controlPoint2, m_controlPoints[i].first);
            before->setControlPoint2(controlPoint2);
        }

        if (after->activeControlPoint1()) {
            QPointF controlPoint1 = after->controlPoint1();
            qSwap(controlPoint1, m_controlPoints[i].second);
            after->setControlPoint1(controlPoint1);
        }
        pathShape->update();
    }
    m_deletePoints = true;
}
Exemple #2
0
void KoCreatePathTool::mouseReleaseEvent(KoPointerEvent *event)
{
    Q_D(KoCreatePathTool);

    if (! d->shape || (event->buttons() & Qt::RightButton))
        return;

    d->listeningToModifiers = true; // After the first press-and-release
    d->repaintActivePoint();
    d->pointIsDragged = false;
    KoPathPoint *lastActivePoint = d->activePoint;

    if (!d->finishAfterThisPoint) {
        d->activePoint = d->shape->lineTo(event->point);
        canvas()->snapGuide()->setIgnoredPathPoints((QList<KoPathPoint*>()<<d->activePoint));
    }

    // apply symmetric point property if applicable
    if (lastActivePoint->activeControlPoint1() && lastActivePoint->activeControlPoint2()) {
        QPointF diff1 = lastActivePoint->point() - lastActivePoint->controlPoint1();
        QPointF diff2 = lastActivePoint->controlPoint2() - lastActivePoint->point();
        if (qFuzzyCompare(diff1.x(), diff2.x()) && qFuzzyCompare(diff1.y(), diff2.y()))
            lastActivePoint->setProperty(KoPathPoint::IsSymmetric);
    }

    if (d->finishAfterThisPoint) {

        d->firstPoint->setControlPoint1(d->activePoint->controlPoint1());
        delete d->shape->removePoint(d->shape->pathPointIndex(d->activePoint));
        d->activePoint = d->firstPoint;
        d->shape->closeMerge();

        // we are closing the path, so reset the existing start path point
        d->existingStartPoint = 0;
        // finish path
        endPath();
    }

    if (d->angleSnapStrategy && lastActivePoint->activeControlPoint2()) {
        d->angleSnapStrategy->deactivate();
    }
}
bool KoPathPointTypeCommand::appendPointData(KoPathPointData data)
{
    KoPathPoint *point = data.pathShape->pointByIndex(data.pointIndex);
    if (! point)
        return false;

    PointData pointData(data);
    pointData.m_oldControlPoint1 = data.pathShape->shapeToDocument(point->controlPoint1());
    pointData.m_oldControlPoint2 = data.pathShape->shapeToDocument(point->controlPoint2());
    pointData.m_oldProperties = point->properties();
    pointData.m_hadControlPoint1 = point->activeControlPoint1();
    pointData.m_hadControlPoint2 = point->activeControlPoint2();

    m_additionalPointData.append(pointData);

    return true;
}
void KarbonWhirlPinchCommand::redo()
{
    d->pathShape->update();
    uint subpathCount = d->pathData.count();
    for( uint subpathIndex = 0; subpathIndex < subpathCount; ++subpathIndex )
    {
        uint pointCount = d->pathData[subpathIndex].count();
        for( uint pointIndex = 0; pointIndex < pointCount; ++pointIndex )
        {
            KoPathPoint * p = d->pathShape->pointByIndex( KoPathPointIndex( subpathIndex, pointIndex ) );
            p->setPoint( d->whirlPinch( p->point() ) );
            if( p->activeControlPoint1() )
                p->setControlPoint1( d->whirlPinch( p->controlPoint1() ) );
            if( p->activeControlPoint2() )
                p->setControlPoint2( d->whirlPinch( p->controlPoint2() ) );
        }
    }
    d->pathShape->normalize();
    d->pathShape->update();

    QUndoCommand::redo();
}
KoPathPointTypeCommand::KoPathPointTypeCommand(
    const QList<KoPathPointData> & pointDataList,
    PointType pointType,
    KUndo2Command *parent)
        : KoPathBaseCommand(parent)
        , m_pointType(pointType)
{
    QList<KoPathPointData>::const_iterator it(pointDataList.begin());
    for (; it != pointDataList.end(); ++it) {
        KoPathPoint *point = it->pathShape->pointByIndex(it->pointIndex);
        if (point) {
            PointData pointData(*it);
            pointData.m_oldControlPoint1 = it->pathShape->shapeToDocument(point->controlPoint1());
            pointData.m_oldControlPoint2 = it->pathShape->shapeToDocument(point->controlPoint2());
            pointData.m_oldProperties = point->properties();
            pointData.m_hadControlPoint1 = point->activeControlPoint1();
            pointData.m_hadControlPoint2 = point->activeControlPoint2();
            m_oldPointData.append(pointData);
            m_shapes.insert(it->pathShape);
        }
    }
    setText(QObject::tr("Set point type"));
}
void KoPathPointTypeCommand::redo()
{
    KUndo2Command::redo();
    repaint(false);
    m_additionalPointData.clear();

    QList<PointData>::iterator it(m_oldPointData.begin());
    for (; it != m_oldPointData.end(); ++it) {
        KoPathPoint *point = it->m_pointData.pathShape->pointByIndex(it->m_pointData.pointIndex);
        KoPathPoint::PointProperties properties = point->properties();

        switch (m_pointType) {
        case Line: {
            point->removeControlPoint1();
            point->removeControlPoint2();
            break;
        }
        case Curve: {
            KoPathPointIndex pointIndex = it->m_pointData.pointIndex;
            KoPathPointIndex prevIndex;
            KoPathPointIndex nextIndex;
            KoPathShape * path = it->m_pointData.pathShape;
            // get previous path node
            if (pointIndex.second > 0)
                prevIndex = KoPathPointIndex(pointIndex.first, pointIndex.second - 1);
            else if (pointIndex.second == 0 && path->isClosedSubpath(pointIndex.first))
                prevIndex = KoPathPointIndex(pointIndex.first, path->subpathPointCount(pointIndex.first) - 1);
            // get next node
            if (pointIndex.second < path->subpathPointCount(pointIndex.first) - 1)
                nextIndex = KoPathPointIndex(pointIndex.first, pointIndex.second + 1);
            else if (pointIndex.second < path->subpathPointCount(pointIndex.first) - 1
                     && path->isClosedSubpath(pointIndex.first))
                nextIndex = KoPathPointIndex(pointIndex.first, 0);

            KoPathPoint * prevPoint = path->pointByIndex(prevIndex);
            KoPathPoint * nextPoint = path->pointByIndex(nextIndex);

            if (prevPoint && ! point->activeControlPoint1() && appendPointData(KoPathPointData(path, prevIndex))) {
                KoPathSegment cubic = KoPathSegment(prevPoint, point).toCubic();
                if (prevPoint->activeControlPoint2()) {
                    prevPoint->setControlPoint2(cubic.first()->controlPoint2());
                    point->setControlPoint1(cubic.second()->controlPoint1());
                } else
                    point->setControlPoint1(cubic.second()->controlPoint1());
            }
            if (nextPoint && ! point->activeControlPoint2() && appendPointData(KoPathPointData(path, nextIndex))) {
                KoPathSegment cubic = KoPathSegment(point, nextPoint).toCubic();
                if (nextPoint->activeControlPoint1()) {
                    point->setControlPoint2(cubic.first()->controlPoint2());
                    nextPoint->setControlPoint1(cubic.second()->controlPoint1());
                } else
                    point->setControlPoint2(cubic.first()->controlPoint2());
            }
            break;
        }
        case Symmetric: {
            properties &= ~KoPathPoint::IsSmooth;
            properties |= KoPathPoint::IsSymmetric;

            // calculate vector from node point to first control point and normalize it
            QPointF directionC1 = point->controlPoint1() - point->point();
            qreal dirLengthC1 = sqrt(directionC1.x() * directionC1.x() + directionC1.y() * directionC1.y());
            directionC1 /= dirLengthC1;
            // calculate vector from node point to second control point and normalize it
            QPointF directionC2 = point->controlPoint2() - point->point();
            qreal dirLengthC2 = sqrt(directionC2.x() * directionC2.x() + directionC2.y() * directionC2.y());
            directionC2 /= dirLengthC2;
            // calculate the average distance of the control points to the node point
            qreal averageLength = 0.5 * (dirLengthC1 + dirLengthC2);
            // compute position of the control points so that they lie on a line going through the node point
            // the new distance of the control points is the average distance to the node point
            point->setControlPoint1(point->point() + 0.5 * averageLength * (directionC1 - directionC2));
            point->setControlPoint2(point->point() + 0.5 * averageLength * (directionC2 - directionC1));
        }
        break;
        case Smooth: {
            properties &= ~KoPathPoint::IsSymmetric;
            properties |= KoPathPoint::IsSmooth;

            // calculate vector from node point to first control point and normalize it
            QPointF directionC1 = point->controlPoint1() - point->point();
            qreal dirLengthC1 = sqrt(directionC1.x() * directionC1.x() + directionC1.y() * directionC1.y());
            directionC1 /= dirLengthC1;
            // calculate vector from node point to second control point and normalize it
            QPointF directionC2 = point->controlPoint2() - point->point();
            qreal dirLengthC2 = sqrt(directionC2.x() * directionC2.x() + directionC2.y() * directionC2.y());
            directionC2 /= dirLengthC2;
            // compute position of the control points so that they lie on a line going through the node point
            // the new distance of the control points is the average distance to the node point
            point->setControlPoint1(point->point() + 0.5 * dirLengthC1 * (directionC1 - directionC2));
            point->setControlPoint2(point->point() + 0.5 * dirLengthC2 * (directionC2 - directionC1));
        }
        break;
        case Corner:
        default:
            properties &= ~KoPathPoint::IsSymmetric;
            properties &= ~KoPathPoint::IsSmooth;
            break;
        }
        point->setProperties(properties);
    }
    repaint(true);
}