Exemplo n.º 1
0
void QgsHighlight::paintPolygon( QPainter *p, QgsPolygon polygon )
{
  // OddEven fill rule by default
  QPainterPath path;

  p->setPen( mPen );
  p->setBrush( mBrush );

  for ( int i = 0; i < polygon.size(); i++ )
  {
    if ( polygon[i].empty() ) continue;

    QPolygonF ring;
    ring.reserve( polygon[i].size() + 1 );

    for ( int j = 0; j < polygon[i].size(); j++ )
    {
      //adding point only if it is more than a pixel appart from the previous one
      const QPointF cur = toCanvasCoordinates( polygon[i][j] ) - pos();
      if ( 0 == j || std::abs( ring.back().x() - cur.x() ) > 1 || std::abs( ring.back().y() - cur.y() ) > 1 )
      {
        ring.push_back( cur );
      }
    }

    ring.push_back( ring[ 0 ] );

    path.addPolygon( ring );
  }

  p->drawPath( path );
}
Exemplo n.º 2
0
void NodeBackDrop::resize(int w,int h)
{
    QMutexLocker l(&_imp->bboxMutex);
    QPointF p = pos();
    QPointF thisItemPos = mapFromParent(p);
    
    QRectF textBbox = _imp->name->boundingRect();
    if (w < textBbox.width()) {
        w = textBbox.width();
    }
    
    int minH = (textBbox.height() * 1.5) + 20;
    
    if (h < minH) {
        h = minH;
    }
    
    
    setRect(QRectF(thisItemPos.x(),thisItemPos.y(),w,h));
    
    _imp->header->setRect(QRect(thisItemPos.x(),thisItemPos.y(),w,textBbox.height() * 1.5));
    
    _imp->name->setPos(thisItemPos.x() + w / 2 - textBbox.width() / 2,thisItemPos.y() + 0.25 * textBbox.height());
    _imp->label->setPos(thisItemPos.x(), thisItemPos.y() + textBbox.height() * 1.5 + 10);
    _imp->label->setTextWidth(w);
    
    QPolygonF resizeHandle;
    QPointF bottomRight(thisItemPos.x() + w,thisItemPos.y() + h);
    resizeHandle.push_back(QPointF(bottomRight.x() - 20,bottomRight.y()));
    resizeHandle.push_back(bottomRight);
    resizeHandle.push_back(QPointF(bottomRight.x(), bottomRight.y() - 20));
    _imp->resizeHandle->setPolygon(resizeHandle);
}
Exemplo n.º 3
0
void Triangle::transformerEnPolygone(QPolygonF &polygone , QVector<QPointF>& points)
{
    polygone.clear();
    polygone.push_back(points[this->sommets[0]]);
    polygone.push_back(points[this->sommets[1]]);
    polygone.push_back(points[this->sommets[2]]);

}
Exemplo n.º 4
0
/**
  * whether a given point is within image region
  *@ coord, a point
  *@ returns true, if the point is within borders of image
  */
bool RS_Image::containsPoint(const RS_Vector& coord) const{
    QPolygonF paf;
    RS_VectorSolutions corners =getCorners();
	for(const RS_Vector& vp: corners){
		paf.push_back(QPointF(vp.x, vp.y));
    }
    paf.push_back(paf.at(0));
    return paf.containsPoint(QPointF(coord.x,coord.y),Qt::OddEvenFill);
}
Exemplo n.º 5
0
std::vector<QPolygonF> GraphicsArrowItem::compose() {
	const qreal pi = 3.14;
	QLineF l = QLineF(line());
	double arrowSize = (l.length() < 200.0) ? 10.0 : l.length()/20.0;
	//double arrowSize = 10.0;
	int dx = l.p2().x() - l.p1().x();
	int dy = l.p2().y() - l.p1().y();
	double angle = ::acos(dx/l.length());
	if (dx >= 0 && dy > 0)
		angle = (pi * 2) - angle;
	else if (dx >= 0 && dy <= 0)
		{ }
	else if (dx < 0 && dy > 0)
		angle = (pi * 2) - angle;
	else if (dx < 0 && dy <= 0)
		{ }
	QPointF P1 = l.p1() + QPointF(::sin(angle+pi/3.0)*arrowSize, ::cos(angle+pi/3.0)*arrowSize);
	QPointF P2 = l.p1() + QPointF(::sin(angle+pi-pi/3.0)*arrowSize, ::cos(angle+pi-pi/3.0)*arrowSize);
	QPointF P3 = l.p2() + QPointF(::sin(angle-pi/3.0)*arrowSize, ::cos(angle-pi/3.0)*arrowSize);
	QPointF P4 = l.p2() + QPointF(::sin(angle+pi+pi/3.0)*arrowSize, ::cos(angle+pi+pi/3.0)*arrowSize);

	std::vector<QPolygonF> cont;
	//double off = 0.5*arrowSize*1.732;
	//QPointF offset(off, off);
	if (arrowHead == Start) {
		QPolygonF polybuilder;
		polybuilder.push_back(P1);
		polybuilder.push_back(l.p1());
		polybuilder.push_back(P2);
		polybuilder.push_back(P1);
		cont.push_back(polybuilder);
		//QLineF newline(line());
		//newline.setP1(newline.p1()-offset);
	}
	else if (arrowHead == End) {
		QPolygonF polybuilder;
		polybuilder.push_back(P3);
		polybuilder.push_back(l.p2());
		polybuilder.push_back(P4);
		polybuilder.push_back(P3);
		cont.push_back(polybuilder);
	}
	else if (arrowHead == Both) {
		QPolygonF polybuilder;
		polybuilder.push_back(P1);
		polybuilder.push_back(l.p1());
		polybuilder.push_back(P2);
		polybuilder.push_back(P1);
		QPolygonF polybuilder2;
		polybuilder2.push_back(P3);
		polybuilder2.push_back(l.p2());
		polybuilder2.push_back(P4);
		polybuilder2.push_back(P3);
		cont.push_back(polybuilder);
		cont.push_back(polybuilder2);
	}
	return cont;
}
Exemplo n.º 6
0
void DiveGasPressureItem::modelDataChanged(const QModelIndex &topLeft, const QModelIndex &bottomRight)
{
	// We don't have enougth data to calculate things, quit.
	if (!shouldCalculateStuff(topLeft, bottomRight))
		return;
	int last_index = -1;
	QPolygonF boundingPoly; // This is the "Whole Item", but a pressure can be divided in N Polygons.
	polygons.clear();

	for (int i = 0, count = dataModel->rowCount(); i < count; i++) {
		plot_data *entry = dataModel->data().entry + i;
		int mbar = GET_PRESSURE(entry);

		if (entry->cylinderindex != last_index) {
			polygons.append(QPolygonF()); // this is the polygon that will be actually drawned on screen.
			last_index = entry->cylinderindex;
		}
		if (!mbar) {
			continue;
		}

		QPointF point(hAxis->posAtValue(entry->sec), vAxis->posAtValue(mbar));
		boundingPoly.push_back(point);    // The BoundingRect
		polygons.last().push_back(point); // The polygon thta will be plotted.
	}
	setPolygon(boundingPoly);
	qDeleteAll(texts);
	texts.clear();
	int mbar, cyl;
	int seen_cyl[MAX_CYLINDERS] = { false, };
	int last_pressure[MAX_CYLINDERS] = { 0, };
	int last_time[MAX_CYLINDERS] = { 0, };
	struct plot_data *entry;

	cyl = -1;
	for (int i = 0, count = dataModel->rowCount(); i < count; i++) {
		entry = dataModel->data().entry + i;
		mbar = GET_PRESSURE(entry);

		if (!mbar)
			continue;
		if (cyl != entry->cylinderindex) {
			cyl = entry->cylinderindex;
			if (!seen_cyl[cyl]) {
				plotPressureValue(mbar, entry->sec, Qt::AlignRight | Qt::AlignTop);
				plotGasValue(mbar, entry->sec, Qt::AlignRight | Qt::AlignBottom,
					       displayed_dive.cylinder[cyl].gasmix);
				seen_cyl[cyl] = true;
			}
		}
		last_pressure[cyl] = mbar;
		last_time[cyl] = entry->sec;
	}

	for (cyl = 0; cyl < MAX_CYLINDERS; cyl++) {
		if (last_time[cyl]) {
			plotPressureValue(last_pressure[cyl], last_time[cyl], Qt::AlignLeft | Qt::AlignTop);
		}
	}
}
Exemplo n.º 7
0
void AccumulateEnergy::DrawAccumulateEnergy(QPainter &painter)
{
    float y = draw_area_range.bottom() - dheight_ - 15;
    float x = draw_area_range.left();

    QPolygonF points;

    float accumulateenergydata = 0;
    float maxaccumulateenergy = maxaccumulateenergy_;
    if (maxaccumulateenergy == 0)
    {
       maxaccumulateenergy = 1;
    }

    for(int i = 0;i<datas_.size();i++)
    {
        EnergyData ei = datas_.value(i);
        accumulateenergydata += ei.energy;
        float xt =  x + i* draw_area_range.width() / days_;
        float yt =  y - accumulateenergydata*(uheight_ - 15) / maxaccumulateenergy;
        points.push_back(QPointF(xt,yt));

    }
    painter.save();
    QPen pen;
    pen.setColor(Qt::blue);
    painter.setPen(pen);
    painter.drawPolyline(points);
    painter.restore();
}
Exemplo n.º 8
0
QPolygonF fillLine(const QPointF &first_, const QPointF &second_)
{
    QPolygonF filled;
    
    QPointF first = first_, second = second_;
    
    double m = 0;
    
    double x1 = first.x();
    double y1 = first.y();
    double x2 = second.x();
    double y2 = second.y();
    
    filled << first;
    
    if (x2 == x1)
        return filled;
    
    m = (y2 - y1) / (x2 - x1);
    
    for (double x = x1; x < qMax(first.x(), second.x()); x += 1) {
         QPointF point;
         point.setX(x);
    
         point.setY(y1+m*(x-x1));
        
         if (m < 0)
             filled.push_back(point);
         else if (m > 0)
                  filled << point;
    }
    
    return filled;
}
Exemplo n.º 9
0
void PartialPressureGasItem::modelDataChanged(const QModelIndex& topLeft, const QModelIndex& bottomRight)
{
	//AbstractProfilePolygonItem::modelDataChanged();
	if (!shouldCalculateStuff(topLeft, bottomRight))
		return;

	plot_data *entry = dataModel->data().entry;
	QPolygonF poly;
	alertPoly.clear();
	QSettings s;
	s.beginGroup("TecDetails");
	double threshould = s.value(threshouldKey).toDouble();
	for(int i = 0;  i < dataModel->rowCount(); i++, entry++){
		double value = dataModel->index(i, vDataColumn).data().toDouble();
		int time = dataModel->index(i, hDataColumn).data().toInt();
		QPointF point(hAxis->posAtValue(time), vAxis->posAtValue(value));
		poly.push_back( point );
		if (value >= threshould)
			alertPoly.push_back(point);
	}
	setPolygon(poly);
	/*
	createPPLegend(trUtf8("pN" UTF8_SUBSCRIPT_2),getColor(PN2), legendPos);
	*/
}
Exemplo n.º 10
0
QPolygonF ObstacleBitmap::minusPolygon(const QPolygonF& polygon)const{
	QPolygonF ret;
	for (int i = 0; i < polygon.size(); i++)
	{
		ret.push_back(polygon.at(i) * -1.0);
	}
	return ret;
}
Exemplo n.º 11
0
void get_part_polygon(const PartBBox &part_bbox, QPolygonF &polygon)
{
  polygon.clear();

  boost_math::double_vector t(2);
  t = part_bbox.part_x_axis*part_bbox.min_proj_x + part_bbox.part_y_axis*part_bbox.min_proj_y + part_bbox.part_pos;
  polygon.push_back(QPointF(t(0), t(1)));
    
  t = part_bbox.part_x_axis*part_bbox.max_proj_x + part_bbox.part_y_axis*part_bbox.min_proj_y + part_bbox.part_pos;
  polygon.push_back(QPointF(t(0), t(1)));

  t = part_bbox.part_x_axis*part_bbox.max_proj_x + part_bbox.part_y_axis*part_bbox.max_proj_y + part_bbox.part_pos;
  polygon.push_back(QPointF(t(0), t(1)));

  t = part_bbox.part_x_axis*part_bbox.min_proj_x + part_bbox.part_y_axis*part_bbox.max_proj_y + part_bbox.part_pos;
  polygon.push_back(QPointF(t(0), t(1)));
}
Exemplo n.º 12
0
QPolygonF read_line(uint8_t byte_order, InputIterator& itr, const frame& fr)
{
  const uint32_t count(brig::detail::ogc::read<uint32_t>(byte_order, itr));
  QPolygonF line; line.reserve(count);
  for (uint32_t i(0); i < count; ++i)
    line.push_back( read_point(byte_order, itr, fr) );
  return line;
}
Exemplo n.º 13
0
void FormView::showForm(AbstractForm * form)
{

    QGraphicsScene *s = scene();

    s->clear();
    resetTransform();

    if(form == 0){
        return;
    }
    if(form->get_number_of_points() <= 0) {
        return;
    }

    int factor = 100;

    QPolygonF polygon;
    for(int i=0; i<form->get_number_of_points(); ++i){
        Point point = form->get_point_at_index(i);
        polygon.push_back(QPointF(point.get_x()*factor, point.get_y()*factor));
    }



    s->addPolygon(polygon, QPen(), QBrush(Qt::SolidPattern));

    QRectF bound = polygon.boundingRect();

    s->setSceneRect(bound);



    float realwidth = container->width() - 50;
    float width = bound.width();
    float realheight = container->height() - 50;
    float height = bound.height();

    float relw = 1;
    if(width > 0){
        relw =  realwidth / width;
    }

    float relh = 1;
    if(height > 0){
        relh = realheight / height;
    }

    float rel = relw;
    if(relh < relw){
        rel = relh;
    }

    scale(rel,rel);



}
void KisCategorizedItemDelegate::paintTriangle(QPainter* painter, qint32 x, qint32 y, qint32 size, bool rotate) const
{
    QPolygonF triangle;
    triangle.push_back(QPointF(-0.2,-0.2));
    triangle.push_back(QPointF( 0.2,-0.2));
    triangle.push_back(QPointF( 0.0, 0.2));

    QTransform transform;
    transform.translate(x + size/2, y + size/2);
    transform.scale(size, size);

    if(rotate)
        transform.rotate(-90);

    QPalette palette = QApplication::palette();
    painter->setBrush(palette.buttonText());
    painter->drawPolygon(transform.map(triangle));
}
Exemplo n.º 15
0
static QPolygonF createShape(QSize const& image_size, double radius)
{
	QPointF const center(0.5 * image_size.width(), 0.5 * image_size.height());
	double const PI = 3.14159265;
	double angle = PI / 2.0;
	int const num_steps = 5;
	double const step = PI * 2.0 / num_steps;
	
	QPolygonF poly;
	
	poly.push_back(center + QPointF(cos(angle), sin(angle)) * radius);
	for (int i = 1; i < num_steps; ++i) {
		angle += step * 2;
		poly.push_back(center + QPointF(cos(angle), sin(angle)) * radius);
	}
	
	return poly;
}
Exemplo n.º 16
0
QPolygonF DkRotatingRect::getClosedPoly() {

	if (rect.isEmpty())
		return QPolygonF();

	QPolygonF closedPoly = rect;
	closedPoly.push_back(closedPoly[0]);

	return closedPoly;
}
Exemplo n.º 17
0
QPainterPath ItemPhysEnv::shape() const
{
    QPainterPath path;
    QPolygonF lineBoarder;
    QVector<qreal> points = {0.0,
                             0.0,
                             this->data(ITEM_WIDTH).toReal(),
                             this->data(ITEM_HEIGHT).toReal()};
#define PLEFT   0
#define PTOP    1
#define PRIGHT  2
#define PBOTTOM 3
    lineBoarder.push_back(QPointF(points[PLEFT],     points[PTOP]));
    lineBoarder.push_back(QPointF(points[PRIGHT],    points[PTOP]));
    lineBoarder.push_back(QPointF(points[PRIGHT],    points[PBOTTOM]));
    lineBoarder.push_back(QPointF(points[PLEFT],     points[PBOTTOM]));
    lineBoarder.push_back(QPointF(points[PLEFT],     points[PTOP]));

    lineBoarder.push_back(QPointF(points[PLEFT] + 4, points[PTOP]));
    lineBoarder.push_back(QPointF(points[PLEFT] + 4, points[PBOTTOM] - 4));
    lineBoarder.push_back(QPointF(points[PRIGHT] - 4,points[PBOTTOM] - 4));
    lineBoarder.push_back(QPointF(points[PRIGHT] - 4,points[PTOP] + 4));
    lineBoarder.push_back(QPointF(points[PLEFT],     points[PTOP] + 4));
#undef PLEFT
#undef PTOP
#undef PRIGHT
#undef PBOTTOM

    path.addPolygon(lineBoarder);
    return path;
}
Exemplo n.º 18
0
void fonctionsCommunes::Frame(QGraphicsScene *scene, QVector<Triangle> &triangles, QVector<QPointF> &points)
{
    QPointF p1 = QPointF(240 , 0 ) ;
    QPointF p2 = QPointF(0 , 440 ) ;
    QPointF p3 = QPointF(-240 ,0 ) ;

    //---intiialiser le triangle à dessiner
    QPolygonF P ;
    P.push_back(p1);
    P.push_back(p2);
    P.push_back(p3);

    //---initialiser l'ensemble des points
    points.clear();
    points.push_back(p1);
    points.push_back(p2);
    points.push_back(p3);

    //---initialiser le réseau de triangles
    triangles.clear();
    Triangle T ;
    T.id  = 0 ;
    T.sommets[0] = 0 ;
    T.sommets[1] = 1 ;
    T.sommets[2] = 2 ;
    T.adjacents[0] = -1 ;
    T.adjacents[1] = -1 ;
    T.adjacents[2] = -1 ;
    T.caclulerCentreCirconscrit(points);



    triangles.push_back(T);

    //---initialiser la scène dans le viewer
    scene->clear();
    scene->addPolygon(P , QPen(Qt::red , 1  , Qt::DashLine )) ;


}
Exemplo n.º 19
0
void ViewPort::drawPoligono(QPainter* painter, Poligono* poligono){
	if(!poligono->aberto){
		QPolygonF polygon = QPolygonF(false);
		list<Coordenada*>::iterator it = poligono->getCPPCoordenadas()->begin();
		for (; it!= poligono->getCPPCoordenadas()->end(); it++) {
			calculeCoordenadaVP(*it);
			polygon.push_back(QPointF((*it)->getX(), (*it)->getY()));
		}
		painter->setBrush(QBrush(*poligono->color, Qt::SolidPattern));
		painter->drawPolygon(polygon, Qt::OddEvenFill);
		painter->setBrush(QBrush());
	}
}
Exemplo n.º 20
0
QPolygonF ObstacleBitmap::minkowskiSums(const QPolygonF& polygonV, const QPolygonF& polygonW){
	
	std::vector<QPointF> vertexV = initPolygonVertex(findFirstVertex(polygonV), polygonV);
	std::vector<QPointF> vertexW = initPolygonVertex(findFirstVertex(polygonW), polygonW);

	QPolygonF ret;

	int i = 0;
	int j = 0;

    size_t vSize = vertexV.size();
    size_t wSize = vertexW.size();

	do{
		qreal x = vertexV.at(i%vSize).x() + vertexW.at(j%wSize).x();
		qreal y = vertexV.at(i%vSize).y() + vertexW.at(j%wSize).y();
		ret.push_back(QPointF(x, y));
		QPointF V = vertexV.at((i+1)%vSize) - vertexV.at(i%vSize);
		QPointF W = vertexW.at((j+1)%wSize) - vertexW.at(j%wSize);
		double angle1 = CoordinateTransform::toPositiveDegree(std::atan2(V.y(), V.x()));
		double angle2 = CoordinateTransform::toPositiveDegree(std::atan2(W.y(), W.x()));

		if(i == polygonV.size()){
			//if(angle1 == 0.0){
				angle1 = 360.0;
			//}
		}

		if(j == polygonW.size()){
			//if(angle2 == 0.0){
				angle2 = 360.0;
			//}
		}

		if(angle1 < angle2){
			++i;
		}
		else if(angle1 > angle2){
			++j;
		}
		else{
			++i;
			++j;
		}

	}while((i < polygonV.size()) || (j < polygonW.size()));

	return ret;
}
Exemplo n.º 21
0
// draw an arrowhead
QGraphicsPolygonItem* GAction::makeArrowHead(const GVEdge& e, const QColor& color) {

    // arrow pointing to the right
    QPointF p = e.path.pointAtPercent(1);
    QPointF* q = new QPointF(p.x() - 8, p.y() - 5);
    QPointF* r = new QPointF(p.x() - 8, p.y() + 5);
    QPolygonF polygon;
    polygon.push_back(p);
    polygon.push_back(*q);
    polygon.push_back(*r);

    // rotate arrow
    QMatrix matrix;
    matrix.translate(p.x(), p.y());
    matrix.rotate(-e.path.angleAtPercent(1));
    matrix.translate(-p.x(), -p.y());
    polygon = matrix.map(polygon);

    // turn into QGraphicsPolygonItem
    QGraphicsPolygonItem* res = new QGraphicsPolygonItem (polygon, display);
    res->setPen(QPen(color));
    res->setBrush(QBrush(color));
    return res;
}
Exemplo n.º 22
0
MapEditor::MapEditor(QGraphicsScene* scene)
    : scene_(scene)
{
    copypaste_items_.clear();

    selection_stage_ = 0;

    first_selection_x_ = 0;
    first_selection_y_ = 0;
    second_selection_x_ = 0;
    second_selection_y_ = 0;

    QPolygonF p;
    p.push_back(QPointF(0.0, 0.0));
    p.push_back(QPointF(0.0, 32.0));
    p.push_back(QPointF(32.0, 32.0));
    p.push_back(QPointF(32.0, 0.0));

    QPen pen(QColor(200, 0, 0));
    QBrush brush(QColor(100, 0, 100, 100));

    pointer_.image = scene->addPolygon(p, pen, brush);
    pointer_.image->setZValue(100);

    QPolygonF p2;
    p2.push_back(QPointF(0.0, 0.0));
    p2.push_back(QPointF(0.0, 10 * 32.0));
    p2.push_back(QPointF(10 * 32.0, 10 * 32.0));
    p2.push_back(QPointF(10 * 32.0, 0.0));

    QPen pen2(QColor(0, 100, 200));
    pen2.setWidth(2);

    border_image_ = scene->addPolygon(p2, pen2);
    border_image_->setZValue(99);
}
Exemplo n.º 23
0
QPolygonF
XmlUnmarshaller::polygonF(QDomElement const& el)
{
	QPolygonF poly;
	
	QString const point_tag_name("point");
	QDomNode node(el.firstChild());
	for (; !node.isNull(); node = node.nextSibling()) {
		if (!node.isElement()) {
			continue;
		}
		if (node.nodeName() != point_tag_name) {
			continue;
		}
		poly.push_back(pointF(node.toElement()));
	}
	
	return poly;
}
Exemplo n.º 24
0
void
ComboBox::paintEvent(QPaintEvent* /*e*/)
{
    QStyleOption opt;

    opt.initFrom(this);

    QPainter p(this);
    QRectF bRect = rect();

    {
        ///Now draw the frame

        QColor fillColor;
        if (_clicked || _dirty) {
            fillColor = Qt::black;
        } else {
            double r, g, b;
            switch (_animation) {
            case 0:
            default: {
                appPTR->getCurrentSettings()->getRaisedColor(&r, &g, &b);
                break;
            }
            case 1: {
                appPTR->getCurrentSettings()->getInterpolatedColor(&r, &g, &b);
                break;
            }
            case 2: {
                appPTR->getCurrentSettings()->getKeyframeColor(&r, &g, &b);
                break;
            }
            case 3: {
                appPTR->getCurrentSettings()->getExprColor(&r, &g, &b);
                break;
            }
            }
            fillColor.setRgb( Color::floatToInt<256>(r),
                              Color::floatToInt<256>(g),
                              Color::floatToInt<256>(b) );
        }

        double fw = frameWidth();
        QPen pen;
        if ( !hasFocus() ) {
            pen.setColor(Qt::black);
        } else {
            double r, g, b;
            appPTR->getCurrentSettings()->getSelectionColor(&r, &g, &b);
            QColor c;
            c.setRgb( Color::floatToInt<256>(r),
                      Color::floatToInt<256>(g),
                      Color::floatToInt<256>(b) );
            fw = 2;
        }
        p.setPen(pen);


        QRectF roundedRect = bRect.adjusted(fw / 2., fw / 2., -fw, -fw);
        bRect.adjust(fw, fw, -fw, -fw);
        p.fillRect(bRect, fillColor);
        double roundPixels = 3;
        QPainterPath path;
        path.addRoundedRect(roundedRect, roundPixels, roundPixels);
        p.drawPath(path);
    }
    QColor textColor;
    if (_readOnly) {
        textColor.setRgb(100, 100, 100);
    } else if (_altered) {
        double aR, aG, aB;
        appPTR->getCurrentSettings()->getAltTextColor(&aR, &aG, &aB);
        textColor.setRgbF(aR, aG, aB);
    } else if (!_enabled) {
        textColor = Qt::black;
    } else {
        double r, g, b;
        appPTR->getCurrentSettings()->getTextColor(&r, &g, &b);
        textColor.setRgb( Color::floatToInt<256>(r),
                          Color::floatToInt<256>(g),
                          Color::floatToInt<256>(b) );
    }
    {
        Qt::Alignment align = QStyle::visualAlignment( Qt::LeftToRight, QFlag(_align) );
        int flags = align | Qt::TextForceLeftToRight;

        ///Draw the text
        QPen pen = p.pen();
        if (_currentIndex == -1) {
            QFont f = p.font();
            f.setItalic(true);
            p.setFont(f);
        }
        pen.setColor(textColor);
        p.setPen(pen);

        QRectF lr = layoutRect().toAlignedRect();
        p.drawText(lr.toRect(), flags, _currentText);
    }

    {
        ///Draw the dropdown icon
        QPainterPath path;
        QPolygonF poly;
        poly.push_back( QPointF(bRect.right() - DROP_DOWN_ICON_SIZE * 3. / 2., bRect.height() / 2. - DROP_DOWN_ICON_SIZE / 2.) );
        poly.push_back( QPointF(bRect.right() - DROP_DOWN_ICON_SIZE / 2., bRect.height() / 2. - DROP_DOWN_ICON_SIZE / 2.) );
        poly.push_back( QPointF(bRect.right() - DROP_DOWN_ICON_SIZE, bRect.height() / 2. + DROP_DOWN_ICON_SIZE / 2.) );
        path.addPolygon(poly);
        p.fillPath(path, textColor);
    }
} // ComboBox::paintEvent
// CalculateBoorNet - inserts new control points with de Boor algorithm for
// transformation of B-spline into composite Bezier curve.
void BezierInterpolator::CalculateBoorNet(const QVector<QPointF *> &controlPoints,
    const QVector<qreal> &knotVector,
    QPolygonF &boorNetPoints) const {
  Q_ASSERT(controlPoints.size() > 2);
  Q_ASSERT(knotVector.size() > 4);
  // We draw uniform cubic B-spline that passes through endpoints, so we assume
  // that multiplicity of first and last knot is 4 and 1 for knots between.

  QVector<qreal> newKnotVector = knotVector;
  boorNetPoints.clear();
  for (int counter = 0; counter < controlPoints.size(); ++counter)
    boorNetPoints.push_back(*controlPoints[counter]);

  // Insert every middle knot 2 times to increase its multiplicity from 1 to 3.
  const int curveDegree = 3;
  const int increaseMultiplicity = 2;

  for (int knotCounter = 4; knotCounter < newKnotVector.size() - 4;
       knotCounter += 3) {
    QHash< int, QHash<int, QPointF> > tempPoints;
    for (int counter = knotCounter - curveDegree; counter <= knotCounter;
         ++counter)
      tempPoints[counter][0] = boorNetPoints[counter];

    for (int insertCounter = 1; insertCounter <= increaseMultiplicity;
         ++insertCounter)
      for (int i = knotCounter - curveDegree + insertCounter; i < knotCounter;
           ++i) {
        double coeff = (newKnotVector[knotCounter] - newKnotVector[i]) /
            (newKnotVector[i + curveDegree - insertCounter + 1] - newKnotVector[i]);
        QPointF newPoint = (1.0 - coeff) * tempPoints[i - 1][insertCounter - 1] +
                           coeff * tempPoints[i][insertCounter - 1];
        tempPoints[i][insertCounter] = newPoint;
      }

    for (int counter = 0; counter < increaseMultiplicity; ++counter)
      newKnotVector.insert(knotCounter, newKnotVector[knotCounter]);

    // Fill new control points.
    QPolygonF newBoorNetPoints;
    for (int counter = 0; counter <= knotCounter - curveDegree; ++counter)
      newBoorNetPoints.push_back(boorNetPoints[counter]);

    for (int counter = 1; counter <= increaseMultiplicity; ++counter) {
      QPointF &newP = tempPoints[knotCounter - curveDegree + counter][counter];
      newBoorNetPoints.push_back(newP);
    }

    for (int counter = -curveDegree + increaseMultiplicity + 1; counter <= -1;
         ++counter) {
      QPointF &newP = tempPoints[knotCounter + counter][increaseMultiplicity];
      newBoorNetPoints.push_back(newP);
    }

    for (int counter = increaseMultiplicity - 1; counter >= 1; --counter)
      newBoorNetPoints.push_back(tempPoints[knotCounter - 1][counter]);

    for (int counter = knotCounter - 1; counter < boorNetPoints.size(); ++counter)
      newBoorNetPoints.push_back(boorNetPoints[counter]);

    boorNetPoints = newBoorNetPoints;
  }
}
Exemplo n.º 26
0
void DiveGasPressureItem::modelDataChanged(const QModelIndex &topLeft, const QModelIndex &bottomRight)
{
	// We don't have enougth data to calculate things, quit.
	if (!shouldCalculateStuff(topLeft, bottomRight))
		return;

	int plotted_cyl[MAX_CYLINDERS] = { false, };
	int last_plotted[MAX_CYLINDERS] = { 0, };
	QPolygonF poly[MAX_CYLINDERS];
	QPolygonF boundingPoly;
	polygons.clear();

	for (int i = 0, count = dataModel->rowCount(); i < count; i++) {
		struct plot_data *entry = dataModel->data().entry + i;

		for (int cyl = 0; cyl < MAX_CYLINDERS; cyl++) {
			int mbar = GET_PRESSURE(entry, cyl);
			int time = entry->sec;

			if (!mbar)
				continue;

			QPointF point(hAxis->posAtValue(time), vAxis->posAtValue(mbar));
			boundingPoly.push_back(point);

			if (plotted_cyl[cyl]) {
				/* Have we used this culinder in the last two minutes? Continue */
				if (time - last_plotted[cyl] <= 2*60) {
					poly[cyl].push_back(point);
					last_plotted[cyl] = time;
					continue;
				}

				/* Finish the previous one, start a new one */
				polygons.append(poly[cyl]);
				poly[cyl] = QPolygonF();
			}

			plotted_cyl[cyl] = true;
			last_plotted[cyl] = time;
			poly[cyl].push_back(point);
		}
	}

	for (int cyl = 0; cyl < MAX_CYLINDERS; cyl++) {
		if (!plotted_cyl[cyl])
			continue;
		polygons.append(poly[cyl]);
	}

	setPolygon(boundingPoly);
	qDeleteAll(texts);
	texts.clear();

	int seen_cyl[MAX_CYLINDERS] = { false, };
	int last_pressure[MAX_CYLINDERS] = { 0, };
	int last_time[MAX_CYLINDERS] = { 0, };

	// These are offset values used to print the gas lables and pressures on a
	// dive profile at appropriate Y-coordinates. We alternate aligning the
	// label and the gas pressure above and under the pressure line.
	// The values are historical, and we could try to pick the over/under
	// depending on whether this pressure is higher or lower than the average.
	// Right now it's just strictly alternating when you have multiple gas
	// pressures.

	QFlags<Qt::AlignmentFlag> alignVar = Qt::AlignTop;
	QFlags<Qt::AlignmentFlag> align[MAX_CYLINDERS];

	double axisRange = (vAxis->maximum() - vAxis->minimum())/1000;	// Convert axis pressure range to bar
	double axisLog = log10(log10(axisRange));

	for (int i = 0, count = dataModel->rowCount(); i < count; i++) {
		struct plot_data *entry = dataModel->data().entry + i;

		for (int cyl = 0; cyl < MAX_CYLINDERS; cyl++) {
			int mbar = GET_PRESSURE(entry, cyl);

			if (!mbar)
				continue;

			if (!seen_cyl[cyl]) {
				double value_y_offset, label_y_offset;

				// Magic Y offset depending on whether we're aliging
				// the top of the text or the bottom of the text to
				// the pressure line.
				value_y_offset = -0.5;
				if (alignVar & Qt::AlignTop) {
					label_y_offset = 5 * axisLog;
				} else {
					label_y_offset = -7 * axisLog;
				}
				plotPressureValue(mbar, entry->sec, alignVar, value_y_offset);
				plotGasValue(mbar, entry->sec, displayed_dive.cylinder[cyl].gasmix, alignVar, label_y_offset);
				seen_cyl[cyl] = true;

				/* Alternate alignment as we see cylinder use.. */
				align[cyl] = alignVar;
				alignVar ^= Qt::AlignTop | Qt::AlignBottom;
			}
			last_pressure[cyl] = mbar;
			last_time[cyl] = entry->sec;
		}
	}

	// For each cylinder, on right hand side of profile, write cylinder pressure
	for (int cyl = 0; cyl < MAX_CYLINDERS; cyl++) {
		if (last_time[cyl]) {
			double value_y_offset = -0.5;
			plotPressureValue(last_pressure[cyl], last_time[cyl], align[cyl] | Qt::AlignLeft, value_y_offset);
		}
	}
}
Exemplo n.º 27
0
std::vector<QPolygonF> ObstacleBitmap::drawCSpace(const Robot& robot, const Configuration& config){
	std::vector<QPolygonF> ret;
	for (size_t i = 0; i < obstacles.size(); i++){
		for(size_t j = 0; j < obstacles.at(i).NPolygons(); j++){

			QPolygonF transObstacle(CoordinateTransform::toPlannerPoints(obstacles.at(i).getPolygonF(j), obstacles.at(i).getInitialConfiguration(), Constant::SWP));
			
			for(size_t k = 0; k < robot.NPolygons(); k++){
				QPolygonF transRobot(minusPolygon(QPolygonF(CoordinateTransform::toPlannerPoints(robot.getPolygonF(k), config, Constant::SWP))));
				//qDebug() << "robot: " << transRobot;
				//qDebug() << "Obstacle: " << transObstacle;
				QPolygonF result = minkowskiSums(transObstacle, transRobot);
				//qDebug() << "result: " << result;
				ret.push_back(result);
				drawObstacle(result);
			}
		}
	}

	QPolygonF top;
	top.push_back(QPointF(0, -1));
	top.push_back(QPointF(0, -2));
	top.push_back(QPointF(Constant::BITMAPSIZE, -2));
	top.push_back(QPointF(Constant::BITMAPSIZE, -1));
	QPolygonF bottom;
	bottom.push_back(QPointF(0, Constant::BITMAPSIZE+1));
	bottom.push_back(QPointF(0, Constant::BITMAPSIZE));
	bottom.push_back(QPointF(Constant::BITMAPSIZE, Constant::BITMAPSIZE));
	bottom.push_back(QPointF(Constant::BITMAPSIZE, Constant::BITMAPSIZE+1));
	QPolygonF left;
	left.push_back(QPointF(-2, 0));
	left.push_back(QPointF(-1, 0));
	left.push_back(QPointF(-1, Constant::BITMAPSIZE));
	left.push_back(QPointF(-2, Constant::BITMAPSIZE));
	QPolygonF right;
	right.push_back(QPointF(Constant::BITMAPSIZE, 0));
	right.push_back(QPointF(Constant::BITMAPSIZE+1, 0));
	right.push_back(QPointF(Constant::BITMAPSIZE+1, Constant::BITMAPSIZE));
	right.push_back(QPointF(Constant::BITMAPSIZE, Constant::BITMAPSIZE));

	for(size_t k = 0; k < robot.NPolygons(); k++){
		QPolygonF transRobot(CoordinateTransform::toPlannerPoints(robot.getPolygonF(k), config, Constant::SWP));
		QPolygonF result1 = minkowskiSums(top, transRobot);
		QPolygonF result2 = minkowskiSums(bottom, transRobot);
		QPolygonF result3 = minkowskiSums(left, transRobot);
		QPolygonF result4 = minkowskiSums(right, transRobot);
		ret.push_back(result1);
		drawObstacle(result1);
		ret.push_back(result2);
		drawObstacle(result2);
		ret.push_back(result3);
		drawObstacle(result3);
		ret.push_back(result4);
		drawObstacle(result4);
	}

	return ret;
}
Exemplo n.º 28
0
void FormView::showSetting(Setting setting)
{
    QGraphicsScene *s = scene();

    s->clear();
    resetTransform();


    int scale_fac = 10;
    int spacing = 20;
    int planeWidth = setting.get_problem()->get_plane_width()*scale_fac;
    int planeHeight = setting.get_problem()->get_plane_height()*scale_fac;
    QRectF bound;
    for (int i=0; i<setting.get_number_of_planes(); ++i)
    {
        int x_offset = i*(planeWidth+spacing)+(spacing/2);
        int y_offset = (spacing/2);
        QRectF plane(x_offset,y_offset,planeWidth, planeHeight);
        s->addRect(plane,QPen(), QBrush(QColor(188, 198, 204),Qt::SolidPattern));
        for (int j=0; j<setting.get_plane_at(i)->get_number_of_forms(); ++j)
        {
            QPolygonF polygon;
            Form form;
            setting.get_plane_at(i)->get_form_at(j, form);
            vector<Point>  points_of_current_form = *(form.get_points());
            for (int k=0; k<points_of_current_form.size(); ++k){
                Point point = points_of_current_form[k];
                polygon.push_back(QPointF(point.get_x()*scale_fac, point.get_y()*scale_fac));
            }

            QGraphicsPolygonItem * polyitem = s->addPolygon(polygon, QPen(QColor(Qt::red)), QBrush(Qt::SolidPattern));
            polyitem->setPos(x_offset, y_offset);
            bound = polygon.boundingRect();
        }
    }


    float realwidth = container->width() - 50;
    float width = setting.get_number_of_planes()*(planeWidth+spacing);
    float realheight = container->height() - 50;
    float height = planeHeight+spacing;
    s->setSceneRect(0,0,width,height);

    float relw = 1;
    if(width > 0){
        relw =  realwidth / width;
    }

    float relh = 1;
    if(height > 0){
        relh = realheight / height;
    }

    float rel = relw;
    if(relh < relw){
        rel = relh;
    }

    scale(rel,rel);

}
Exemplo n.º 29
0
void TimelineWidget::paintEvent(QPaintEvent* event)
{
	if (similar(mStart,mStop))
		return;
	QWidget::paintEvent(event);

	QPainter painter(this);
//  QPen pointPen, pointLinePen;
	painter.setRenderHint(QPainter::Antialiasing);
	painter.setPen(Qt::NoPen);

	QColor gray0(240, 240, 240);
	QColor gray01(220, 220, 220);
	QColor gray1(200, 200, 200);
	QColor gray2(170, 170, 170); // darker
	QColor gray3(150, 150, 150); // even darker
	QColor gray4(100, 100, 100); // even darker
	QColor highlight(110, 214, 255); // color around highlighted circle in qslider on KDE.

	// Fill with white background color and grey plot area background color
	QBrush brush(Qt::SolidPattern); // = painter.brush();
	brush.setColor(gray2);
	painter.setBrush(brush);

	painter.drawRoundedRect(this->mFullArea, 4, 4);
//	brush.setColor(gray01);
	brush.setColor(gray1);
	painter.setBrush(brush);
	painter.drawRoundedRect(this->mPlotArea, 4, 4);

	int margin = 1;

	// draw noncompacted interval
	for (unsigned i = 0; i < mNoncompactedIntervals.size(); ++i)
	{
		int start_p = this->mapTime2PlotX(mNoncompactedIntervals[i].mStartTime);
		int stop_p = this->mapTime2PlotX(mNoncompactedIntervals[i].mEndTime);
		QColor color = gray01;
		painter.fillRect(QRect(start_p, mPlotArea.top(), stop_p - start_p, mPlotArea.height()), color);
	}

	// draw all continous events
	for (unsigned i = 0; i < mEvents.size(); ++i)
	{
		if (!mContinousEvents.contains(mEvents[i].mGroup))
			continue;
		int start_p = this->mapTime2PlotX(mEvents[i].mStartTime);
		int stop_p = this->mapTime2PlotX(mEvents[i].mEndTime);
		int level = std::distance(mContinousEvents.begin(),
						std::find(mContinousEvents.begin(), mContinousEvents.end(), mEvents[i].mGroup));
		int level_max = mContinousEvents.size();
		int thisHeight = (mPlotArea.height()) / level_max - margin * (level_max - 1) / level_max;
		int thisTop = mPlotArea.top() + level * thisHeight + level * margin;

//		QColor color = mEventColors[level % mEventColors.size()];
		QColor color = mEvents[i].mColor;

		painter.fillRect(QRect(start_p, thisTop, stop_p - start_p, thisHeight), color);
	}

	// draw all singular events
	for (unsigned i = 0; i < mEvents.size(); ++i)
	{
		if (mContinousEvents.contains(mEvents[i].mGroup))
			continue;

		int start_p = this->mapTime2PlotX(mEvents[i].mStartTime);
//		int stop_p = this->mapTime2PlotX(mEvents[i].mEndTime);

		int glyphWidth = 3;
		QRect rect(start_p - glyphWidth / 2, mPlotArea.top(), glyphWidth, mPlotArea.height());

		brush.setColor(QColor(50, 50, 50));
		painter.setBrush(brush);
		painter.drawRoundedRect(rect, 2, 2);

//		painter.fillRect(rect, gray4);
		if (rect.width() > 2 && rect.height() > 2)
		{
			rect.adjust(1, 1, -1, -1);
			painter.fillRect(rect, gray2);
		}
	}

	int offset_p = this->mapTime2PlotX(mPos);
	QPolygonF glyph;
	int z = 5;
	int h = mPlotArea.height();
	glyph.push_back(QPointF(-z, 0));
	glyph.push_back(QPointF(z, 0));
	glyph.push_back(QPointF(z, 0.7 * h));
	glyph.push_back(QPointF(0, h));
	glyph.push_back(QPointF(-z, 0.7 * h));
	glyph.translate(offset_p, 0);
	if (this->hasFocus() || mCloseToGlyph)
		painter.setPen(highlight);
	else
		painter.setPen(gray4);
//  QBrush brush(Qt::SolidPattern);// = painter.brush();

	QRadialGradient radialGrad(QPointF(offset_p, h / 3), 2 * h / 3);
	radialGrad.setColorAt(0, gray0);
//  radialGrad.setColorAt(0.5, Qt::blue);
	radialGrad.setColorAt(1, gray2);

	brush = QBrush(radialGrad);
//  brush.setColor(gray0);
	painter.setBrush(brush);
	painter.drawPolygon(glyph);
}
void
ZoneDefaultInteraction::onPaint(QPainter& painter, InteractionState const& interaction)
{
	painter.setWorldMatrixEnabled(false);
	painter.setRenderHint(QPainter::Antialiasing);

	QTransform const to_screen(m_rContext.imageView().imageToWidget());

	BOOST_FOREACH(EditableZoneSet::Zone const& zone, m_rContext.zones()) {
		EditableSpline::Ptr const& spline = zone.spline();
		m_visualizer.prepareForSpline(painter, spline);
		QPolygonF points;

		if (!interaction.captured() && interaction.proximityLeader(m_vertexProximity)
				&& spline == m_ptrNearestVertexSpline) {
			SplineVertex::Ptr vertex(m_ptrNearestVertex->next(SplineVertex::LOOP));
			for (; vertex != m_ptrNearestVertex; vertex = vertex->next(SplineVertex::LOOP)) {
				points.push_back(to_screen.map(vertex->point()));
			}
			painter.drawPolyline(points);
		} else if (!interaction.captured() && interaction.proximityLeader(m_segmentProximity)
				&& spline == m_ptrNearestSegmentSpline) {
			SplineVertex::Ptr vertex(m_nearestSegment.prev);
			do {
				vertex = vertex->next(SplineVertex::LOOP);
				points.push_back(to_screen.map(vertex->point()));
			} while (vertex != m_nearestSegment.prev);
			painter.drawPolyline(points);
		} else {
			m_visualizer.drawSpline(painter, to_screen, spline);
		}
	}

	if (interaction.proximityLeader(m_vertexProximity)) {
		// Draw the two adjacent edges in gradient red-to-orange.
		QLinearGradient gradient; // From inactive to active point.
		gradient.setColorAt(0.0, m_visualizer.solidColor());
		gradient.setColorAt(1.0, m_visualizer.highlightDarkColor());

		QPen pen(painter.pen());

		QPointF const prev(to_screen.map(m_ptrNearestVertex->prev(SplineVertex::LOOP)->point()));
		QPointF const pt(to_screen.map(m_ptrNearestVertex->point()));
		QPointF const next(to_screen.map(m_ptrNearestVertex->next(SplineVertex::LOOP)->point()));

		gradient.setStart(prev);
		gradient.setFinalStop(pt);
		pen.setBrush(gradient);
		painter.setPen(pen);
		painter.drawLine(prev, pt);

		gradient.setStart(next);
		pen.setBrush(gradient);
		painter.setPen(pen);
		painter.drawLine(next, pt);

		// Visualize the highlighted vertex.
		QPointF const screen_vertex(to_screen.map(m_ptrNearestVertex->point()));
		m_visualizer.drawVertex(painter, screen_vertex, m_visualizer.highlightBrightColor());
	} else if (interaction.proximityLeader(m_segmentProximity)) {
		QLineF const line(to_screen.map(m_nearestSegment.toLine()));

		// Draw the highglighed edge in orange.
		QPen pen(painter.pen());
		pen.setColor(m_visualizer.highlightDarkColor());
		painter.setPen(pen);
		painter.drawLine(line);

		m_visualizer.drawVertex(painter, m_screenPointOnSegment, m_visualizer.highlightBrightColor());
	} else if (!interaction.captured()) {
		m_visualizer.drawVertex(painter, m_screenMousePos, m_visualizer.solidColor());
	}
}