CircleShape::CircleShape(std::string command, std::string name) 
{
    _type = SimpleShape::CIRCLE;

    BasicShape::setName(name);
    _numFaces = 20;
    
    _vertices = new osg::Vec3Array(_numFaces + 2);
    _colors = new osg::Vec4Array(_numFaces + 2);
    
    setPosition(osg::Vec3(0.0, 0.0, 0.0), 1.0);
    setColor(osg::Vec4(1.0, 0.0, 0.0, 1.0),osg::Vec4(0.0, 1.0, 0.0, 1.0));
    update(command);
    
    setVertexArray(_vertices); 
    setColorArray(_colors); 
    setColorBinding(osg::Geometry::BIND_PER_VERTEX);
    addPrimitiveSet(new osg::DrawArrays(osg::PrimitiveSet::TRIANGLE_FAN,0,_numFaces + 2));

    osg::StateSet* state = getOrCreateStateSet();
    state->setMode(GL_BLEND, osg::StateAttribute::ON);
    state->setMode(GL_LIGHTING, osg::StateAttribute::OFF);
    //osg::Material* mat = new osg::Material();
    //mat->setColorMode(osg::Material::AMBIENT_AND_DIFFUSE);
    //state->setAttributeAndModes(mat, osg::StateAttribute::ON);
}
//==============================================================================
void LineSegmentShapeDrawable::refresh(bool firstTime)
{
  if(mLineSegmentShape->getDataVariance() == dart::dynamics::Shape::STATIC)
    setDataVariance(osg::Object::STATIC);
  else
    setDataVariance(osg::Object::DYNAMIC);

  const std::vector<Eigen::Vector3d>& vertices =
      mLineSegmentShape->getVertices();

  const Eigen::aligned_vector<Eigen::Vector2i>& connections =
      mLineSegmentShape->getConnections();

  if(   mLineSegmentShape->checkDataVariance(dart::dynamics::Shape::DYNAMIC_ELEMENTS)
     || firstTime)
  {
    osg::ref_ptr<osg::DrawElementsUInt> elements =
        new osg::DrawElementsUInt(GL_LINES);
    elements->reserve(2*connections.size());

    for(size_t i=0; i < connections.size(); ++i)
    {
      const Eigen::Vector2i& c = connections[i];
      elements->push_back(c[0]);
      elements->push_back(c[1]);
    }

    addPrimitiveSet(elements);
  }

  if(   mLineSegmentShape->checkDataVariance(dart::dynamics::Shape::DYNAMIC_VERTICES)
     || mLineSegmentShape->checkDataVariance(dart::dynamics::Shape::DYNAMIC_ELEMENTS)
     || firstTime)
  {
    if(mVertices->size() != vertices.size())
      mVertices->resize(vertices.size());

    for(size_t i=0; i<vertices.size(); ++i)
      (*mVertices)[i] = eigToOsgVec3(vertices[i]);

    setVertexArray(mVertices);
  }

  if(   mLineSegmentShape->checkDataVariance(dart::dynamics::Shape::DYNAMIC_COLOR)
     || firstTime)
  {
    if(mColors->size() != 1)
      mColors->resize(1);

    (*mColors)[0] = eigToOsgVec4(mLineSegmentShape->getRGBA());

    setColorArray(mColors, osg::Array::BIND_OVERALL);
  }
}
LaserScanLine::LaserScanLine(URGCPPWrapper &urg)
    : urg(urg), vertices(new osg::Vec3Array(urg.getNumberOfPoints())), color(new osg::Vec4Array(1))
{
    setDataVariance(osg::Object::DYNAMIC);
    getOrCreateStateSet()->setAttribute(new osg::Point(3), osg::StateAttribute::ON);
    addPrimitiveSet(new osg::DrawArrays(osg::PrimitiveSet::POINTS, 0, urg.getNumberOfPoints()));

    setColorBinding(osg::Geometry::BIND_OVERALL);
    (*color)[0] = osg::Vec4(1.0f, 0.0f, 0.0f, 1.0f);
    setColorArray(color);
}
 //! Fills the color array with the given color
 void setColorArray(const fvec4& color)
 {
   u32 vert_count = (u32)(vertexArray() ? vertexArray()->size() : vertexAttribArray(VA_Position) ? vertexAttribArray(VA_Position)->data()->size() : 0);
   VL_CHECK( vert_count )
   ref<ArrayFloat4> color_array = new ArrayFloat4;
   color_array->resize(vert_count);
   for(u32 i=0; i<color_array->size(); ++i)
     color_array->at(i) = color;
   #if defined(VL_OPENGL_ES2)
     setVertexAttribArray(VA_Color, color_array.get());
   #else
     setColorArray(color_array.get());
   #endif
 }
//------------------------------------------------------------------------------
void HudTextureElement::init()
{
    Texture * tex_object = s_texturemanager.getResource(texture_name_);
    if (!tex_object) return;
    
    osg::ref_ptr<osg::Texture2D> tex = tex_object->getOsgTexture();
    osg::ref_ptr<osg::Image> image = tex->getImage();

    aspect_ratio_ = (float)image->s() / image->t();

    tex->setFilter(osg::Texture2D::MIN_FILTER,osg::Texture2D::LINEAR);
    tex->setFilter(osg::Texture2D::MAG_FILTER,osg::Texture2D::LINEAR);

    tex->setBorderColor(osg::Vec4(0,0,0,0));
    tex->setWrap(osg::Texture::WRAP_S, osg::Texture::CLAMP_TO_BORDER);
    tex->setWrap(osg::Texture::WRAP_T, osg::Texture::CLAMP_TO_BORDER);
    
    getOrCreateStateSet()->setTextureAttributeAndModes(0,tex.get(),osg::StateAttribute::ON);

    setUseDisplayList(false);
    setUseVertexBufferObjects(true);

    addPrimitiveSet(new osg::DrawArrays(GL_QUADS,0,4));

    Color color  = s_params.get<Color>   ("hud." + section_ + ".color");
    
    osg::Vec2Array* texcoord = new osg::Vec2Array(4);
    setTexCoordArray(0,texcoord);
        
    osg::Vec4Array * osg_color = new osg::Vec4Array(1);
    (*osg_color)[0].set(color.r_, color.g_, color.b_, color.a_);
    setColorArray(osg_color);
    setColorBinding(osg::Geometry::BIND_OVERALL);

    (*texcoord)[0].set(0,0);
    (*texcoord)[1].set(1,0);
    (*texcoord)[2].set(1,1);
    (*texcoord)[3].set(0,1);


    s_scene_manager.addObserver(ObserverCallbackFun0(this, &HudTextureElement::onResolutionChanged),
                                SOE_RESOLUTION_CHANGED,
                                &fp_group_);    
    onResolutionChanged();
}
Exemple #6
0
Widget::Widget(const std::string& name, point_type w, point_type h):
_parent    (0),
_index     (0),
_layer     (LAYER_LOW),
_padLeft   (0.0f),
_padRight  (0.0f),
_padTop    (0.0f),
_padBottom (0.0f),
_valign    (VA_CENTER),
_halign    (HA_CENTER),
_coordMode (CM_ABSOLUTE),
_canFill   (false),
_canClone  (true),
_isManaged (false),
_isStyled  (false),
_minWidth  (0.0f),
_minHeight (0.0f) {
    _name = name.size() ? name : generateRandomName("Widget");

    if(!_norms.valid()) {
        _norms = new PointArray(1);

        (*_norms)[0].set(0.0f, 0.0f, 1.0f);
        (*_norms)[0].normalize();
    }

    TexCoordArray* texs = new TexCoordArray(4);

    // Fill our texture coordinates with null stuff for now, since we aren't using them
    // until an Image is set at some later point.
    std::fill(texs->begin(), texs->end(), osg::Vec2(0.0f, 0.0f));

    setUseDisplayList(false);
    setDataVariance(osg::Object::DYNAMIC);
    setVertexArray(new PointArray(4));
    setColorArray(new ColorArray(4));
    setNormalArray(_norms.get());
    setTexCoordArray(0, texs);
    setNormalBinding(osg::Geometry::BIND_OVERALL);
    setColorBinding(osg::Geometry::BIND_PER_VERTEX);
    addPrimitiveSet(new osg::DrawArrays(osg::PrimitiveSet::QUADS, 0, 4));

    setDimensions(0.0f, 0.0f, w, h);
    setColor(1.0f, 1.0f, 1.0f, 1.0f);
}
    WidgetBorder::WidgetBorder(const Widget & widget) : widget(widget)
    {
        if (osg::Vec3Array * data = new osg::Vec3Array(4))
        {
            const Rect & rect = widget.getRect();
            const int padding = widget.getBorderPadding();
            const float z = widget.getZ();

            spdlog::get("log")->info("initializing WidgetBorder with rect {}, {}, {}, {}", rect.x1, rect.y1, rect.x2, rect.y2);

            (*data)[0].set(rect.x1 - padding, rect.y2 + padding, z);
            (*data)[1].set(rect.x1 - padding, rect.y1 - padding, z);
            (*data)[2].set(rect.x2 + padding, rect.y1 - padding, z);
            (*data)[3].set(rect.x2 + padding, rect.y2 + padding, z);

            setVertexArray(data);
        }

        if (osg::Vec3Array * data = new osg::Vec3Array(1))
        {
            (*data)[0].set(0.f, 0.f, 1.f);

            setNormalArray(data, osg::Array::BIND_OVERALL);
        }

        if (osg::Vec4Array * data = new osg::Vec4Array(1))
        {
            /*
            const osg::Color & color = widget.getBorderColor();

            (*data)[0].set(widget.getBorderColor().r, widget.getBorderColor().g, widget.getBorderColor().b, widget.getBorderColor().a);
            */

            (*data)[0].set(1.f, 1.f, 1.f, 1.f);

            setColorArray(data, osg::Array::BIND_OVERALL);
        }

        addPrimitiveSet(new osg::DrawArrays(osg::PrimitiveSet::LINE_LOOP, 0, 4));
        // TODO: getOrCreateStateSet()->setAttribute(new osg::LineWidth(widget.getBorderPadding()));
    }
Exemple #8
0
void HeightmapShapeDrawable<S>::refresh(bool /*firstTime*/)
{
  if (mHeightmapShape->getDataVariance() == dynamics::Shape::STATIC)
    setDataVariance(::osg::Object::STATIC);
  else
    setDataVariance(::osg::Object::DYNAMIC);

  // Row major matrix where top left corner is the height at (0, 0), and bottom
  // right corner is the height at (rows, -cols) in (x, y) coordinates.
  const auto& heightmap = mHeightmapShape->getHeightField();

  // This function is called whenever the heightmap version is increased, and
  // the heightmap could be updated in the version up. So we always update the
  // heightmap.
  {
    assert(mElements);
    assert(mNormals);
    setVertices<S>(
        heightmap,
        *mVertices,
        *mElements,
        *mNormals,
        mHeightmapShape->getScale());
    addPrimitiveSet(mElements);

    setVertexArray(mVertices);
    setNormalArray(mNormals, ::osg::Array::BIND_PER_VERTEX);
  }

  // This function is called whenever the heightmap version is increased, and
  // the color could be updated in the version up. So we always update the
  // color.
  {
    if (mColors->size() != 1)
      mColors->resize(1);

    (*mColors)[0] = eigToOsgVec4d(mVisualAspect->getRGBA());

    setColorArray(mColors, ::osg::Array::BIND_OVERALL);
  }
}
    SomePoints()
    {
        osg::Vec4Array* cAry = new osg::Vec4Array;
        setColorArray( cAry, osg::Array::BIND_OVERALL );
        cAry->push_back( osg::Vec4(1,1,1,1) );

        osg::Vec3Array* vAry = new osg::Vec3Array;
        setVertexArray( vAry );
        vAry->push_back( osg::Vec3(0,0,0) );
        vAry->push_back( osg::Vec3(0,1,0) );
        vAry->push_back( osg::Vec3(1,0,0) );
        vAry->push_back( osg::Vec3(1,1,0) );
        vAry->push_back( osg::Vec3(0,0,1) );
        vAry->push_back( osg::Vec3(0,1,1) );
        vAry->push_back( osg::Vec3(1,0,1) );
        vAry->push_back( osg::Vec3(1,1,1) );

        addPrimitiveSet( new osg::DrawArrays( GL_POINTS, 0, vAry->size() ) );

        osg::StateSet* sset = getOrCreateStateSet();
        sset->setMode( GL_LIGHTING, osg::StateAttribute::OFF );

        // if things go wrong, fall back to big points
        osg::Point* p = new osg::Point;
        p->setSize(6);
        sset->setAttribute( p );

#ifdef ENABLE_GLSL
        sset->setAttribute( createShader() );

        // a generic cyclic animation value
        osg::Uniform* u_anim1( new osg::Uniform( "u_anim1", 0.0f ) );
        u_anim1->setUpdateCallback( new SineAnimation( 4, 0.5, 0.5 ) );
        sset->addUniform( u_anim1 );
#endif
    }
void Ellipsoid::subDraw()
{
	computeAssistVar();
	getPrimitiveSetList().clear();

	osg::ref_ptr<osg::Vec3Array> vertexArr = new osg::Vec3Array;
	osg::ref_ptr<osg::Vec3Array> normalArr = new osg::Vec3Array;
	setVertexArray(vertexArr);
	setNormalArray(normalArr, osg::Array::BIND_PER_VERTEX);
	osg::ref_ptr<osg::Vec4Array> colArr = new osg::Vec4Array();
	colArr->push_back(m_color);
	setColorArray(colArr, osg::Array::BIND_OVERALL);

	bool isFull = osg::equivalent(m_angle, 2 * M_PI, GetEpsilon());
	if (isFull)
	{
		m_angle = 2 * M_PI;
	}

	osg::Vec3 bottomNormal = -m_aLen;
	bottomNormal.normalize();
	osg::Quat localToWold;
	localToWold.makeRotate(osg::Z_AXIS, -bottomNormal);
	osg::Vec3 xVec = localToWold * osg::X_AXIS;
	osg::Vec3 yVec = xVec ^ bottomNormal;
	int hCount = m_bDivision;
	double hIncAng = 2 * M_PI / hCount;
	osg::Quat hQuat(hIncAng, bottomNormal);

	int vCount = (int)ceil(m_angle / (2 * M_PI / m_aDivision));
	if (vCount & 1) // 如果是奇数,则变成偶数
		++vCount;
	double vIncAng = m_angle / vCount;

	double currAngle = m_angle / 2.0;
	double b = m_bRadius;
	double a = m_aLen.length();
	osg::Vec3 vec1(b * sin(currAngle), 0, a * cos(currAngle));
	vec1 = localToWold * vec1;
	osg::Vec3 normal1(sin(currAngle) / b, 0, cos(currAngle) / a);
	normal1 = localToWold * normal1;
	normal1.normalize();

	currAngle -= vIncAng;
	osg::Vec3 vec2(b * sin(currAngle), 0, a * cos(currAngle));
	vec2 = localToWold * vec2;
	osg::Vec3 normal2(sin(currAngle) / b, 0, cos(currAngle) / a);
	normal2 = localToWold * normal2;
	normal2.normalize();

	const GLint first = vertexArr->size();
	for (int i = 0; i < vCount / 2; ++i)
	{
		osg::Vec3 hVec1 = vec1;
		osg::Vec3 hVec2 = vec2;
		osg::Vec3 hNormal1 = normal1;
		osg::Vec3 hNormal2 = normal2;
		const size_t hFirst = vertexArr->size();
		for (int j = 0; j < hCount; ++j)
		{
			vertexArr->push_back(m_center + hVec1);
			vertexArr->push_back(m_center + hVec2);
			normalArr->push_back(hNormal1);
			normalArr->push_back(hNormal2);

			hVec1 = hQuat * hVec1;
			hVec2 = hQuat * hVec2;

			hNormal1 = hQuat * hNormal1;
			hNormal2 = hQuat * hNormal2;
		}
		vertexArr->push_back((*vertexArr)[hFirst]);
		vertexArr->push_back((*vertexArr)[hFirst + 1]);
		normalArr->push_back((*normalArr)[hFirst]);
		normalArr->push_back((*normalArr)[hFirst + 1]);

		vec1 = vec2;
		currAngle -= vIncAng;
		vec2.set(b * sin(currAngle), 0, a * cos(currAngle));
		vec2 = localToWold * vec2;

		normal1 = normal2;
		normal2.set(sin(currAngle) / b, 0, cos(currAngle) / a);
		normal2 = localToWold * normal2;
		normal2.normalize();
	}
	addPrimitiveSet(new osg::DrawArrays(osg::PrimitiveSet::QUAD_STRIP, first, vertexArr->size() - first));

	if (!isFull && m_bottomVis)
	{
		const GLint first = vertexArr->size();
		currAngle = m_angle / 2.0;
		osg::Vec3 vec1(b * sin(currAngle), 0, a * cos(currAngle));
		vec1 = localToWold * vec1;
		osg::Vec3 vec2(0, 0, a * cos(currAngle));
		vec2 = localToWold * vec2;

		vertexArr->push_back(m_center + vec2);
		normalArr->push_back(bottomNormal);
		for (int i = 0; i < hCount; ++i)
		{
			vertexArr->push_back(m_center + vec1);
			normalArr->push_back(bottomNormal);
			vec1 = hQuat * vec1;
		}
		vertexArr->push_back((*vertexArr)[first + 1]);
		normalArr->push_back(bottomNormal);
		addPrimitiveSet(new osg::DrawArrays(osg::PrimitiveSet::TRIANGLE_FAN, first, vertexArr->size() - first));
	}
}
void SCylinder::subDraw()
{
    getPrimitiveSetList().clear();
    osg::ref_ptr<osg::Vec3Array> vertexArr = new osg::Vec3Array;
    osg::ref_ptr<osg::Vec3Array> normalArr = new osg::Vec3Array;
    setVertexArray(vertexArr);
    setNormalArray(normalArr, osg::Array::BIND_PER_VERTEX);
    osg::ref_ptr<osg::Vec4Array> colArr = new osg::Vec4Array();
    colArr->push_back(m_color);
    setColorArray(colArr, osg::Array::BIND_OVERALL);

    int count = (int)getDivision();
    double incAng = 2 * M_PI / count;
    osg::Vec3 topNormal = m_height;
    topNormal.normalize();
    double angleCos = m_bottomNormal * (-topNormal) / m_bottomNormal.length() / topNormal.length();
    double angle = acos(angleCos);
    double a = m_radius;
    double b = m_radius / sin(M_PI_2 - angle);
    osg::Vec3 vec = m_bottomNormal ^ topNormal;
    vec.normalize();
    osg::Quat bottomQuat(incAng, m_bottomNormal);
    double currAngle = 0;
    osg::Quat localToWorldQuat;
    localToWorldQuat.makeRotate(osg::Z_AXIS, m_bottomNormal);
    osg::Vec3 yAxis = localToWorldQuat * osg::Y_AXIS;
    osg::Quat localToWorldQuat2;
    localToWorldQuat2.makeRotate(yAxis, vec);
    localToWorldQuat *= localToWorldQuat2;
    osg::Vec3 bottomVec(b * sin(currAngle), a * cos(currAngle), 0);
    bottomVec = localToWorldQuat * bottomVec;
    //bottomVec = localToWorldQuat2 * bottomVec;

    osg::Quat topQuat(incAng, topNormal);
    osg::Vec3 topVec = vec * m_radius;
    osg::Vec3 topCenter = m_org + m_height;
    size_t first = vertexArr->size();
    for (int i = 0; i < count; ++i)
    {
        vertexArr->push_back(topCenter + topVec);
        vertexArr->push_back(m_org + bottomVec);
        normalArr->push_back(topVec);
        normalArr->back().normalize();
        normalArr->push_back(normalArr->back());

        currAngle += incAng;
        bottomVec.set(b * sin(currAngle), a * cos(currAngle), 0);
        bottomVec = localToWorldQuat * bottomVec;
        //bottomVec = localToWorldQuat2 * bottomVec;
        topVec = topQuat * topVec;
    }
    vertexArr->push_back((*vertexArr)[first]);
    vertexArr->push_back((*vertexArr)[first + 1]);
    normalArr->push_back((*normalArr)[first]);
    normalArr->push_back((*normalArr)[first + 1]);
    addPrimitiveSet(new osg::DrawArrays(osg::PrimitiveSet::TRIANGLE_STRIP, first, vertexArr->size() - first));

    if (m_bottomVis)
    {
        first = vertexArr->size();
        vertexArr->push_back(m_org);
        normalArr->push_back(m_bottomNormal);
        for (int i = count; i >= 0; --i)
        {
            vertexArr->push_back((*vertexArr)[i * 2 + 1]);
            normalArr->push_back(m_bottomNormal);
        }
        addPrimitiveSet(new osg::DrawArrays(osg::PrimitiveSet::TRIANGLE_FAN, first, vertexArr->size() - first));
    }

    if (m_topVis)
    {
        first = vertexArr->size();
        vertexArr->push_back(topCenter);
        normalArr->push_back(topNormal);
        for (int i = 0; i < count + 1; ++i)
        {
            vertexArr->push_back((*vertexArr)[i * 2]);
            normalArr->push_back(topNormal);
        }
        addPrimitiveSet(new osg::DrawArrays(osg::PrimitiveSet::TRIANGLE_FAN, first, vertexArr->size() - first));
    }
}
Exemple #12
0
void SuperShape3D::generate(void)
{
    const float lon_step =  2 * osg::PI / _resolution;
    const float lat_step =  osg::PI / _resolution;
    const float epsilon = std::numeric_limits<float>::epsilon();

    osg::Vec3Array* vAry = new osg::Vec3Array;
    vAry->reserve( _resolution * _resolution * 6 );
    setVertexArray( vAry );

    osg::Vec4Array* cAry = new osg::Vec4Array;
    setColorArray( cAry );
    setColorBinding( osg::Geometry::BIND_OVERALL );
    cAry->push_back( osg::Vec4(1,1,1,1) );

    for( int lat_count = 0; lat_count <_resolution; ++lat_count )
    {
        float phi1 = static_cast<float>(lat_count * lat_step - osg::PI_2);
        float phi2 = phi1 + lat_step;

        for( int lon_count = 0; lon_count < _resolution; ++lon_count )
        {
            float theta1 = static_cast<float>(lon_count * lon_step - osg::PI);
            float theta2 = theta1 + lon_step;

            bool tooSmall = false;

            float r1_1 = SS1(theta1);
            if(fabs(r1_1) < epsilon) tooSmall = true;

            float r2_1 = SS2(phi1);
            if(fabs(r2_1) < epsilon) tooSmall = true;

            float r1_2 = SS1(theta2);
            if(fabs(r1_2) < epsilon) tooSmall = true;

            float r2_2 = SS2(phi2);
            if(fabs(r2_2) < epsilon) tooSmall = true;

            if( !tooSmall )
            {
                r1_1 = 1.0f / r1_1;
                r1_2 = 1.0f / r1_2;
                r2_1 = 1.0f / r2_1;
                r2_2 = 1.0f / r2_2;

                osg::Vec3 pa = osg::Vec3(r1_1*cosf(theta1)*r2_1*cosf(phi1), r1_1*sinf(theta1)*r2_1*cosf(phi1), r2_1*sinf(phi1));
                osg::Vec3 pb = osg::Vec3(r1_2*cosf(theta2)*r2_1*cosf(phi1), r1_2*sinf(theta2)*r2_1*cosf(phi1), r2_1*sinf(phi1));
                osg::Vec3 pc = osg::Vec3(r1_2*cosf(theta2)*r2_2*cosf(phi2), r1_2*sinf(theta2)*r2_2*cosf(phi2), r2_2*sinf(phi2));
                osg::Vec3 pd = osg::Vec3(r1_1*cosf(theta1)*r2_2*cosf(phi2), r1_1*sinf(theta1)*r2_2*cosf(phi2), r2_2*sinf(phi2));

                if((pa - pb).length() > epsilon && (pa - pc).length() > epsilon)
                {
                    vAry->push_back( pa );
                    vAry->push_back( pb );
                    vAry->push_back( pc );
                }

                if((pc - pd).length() > epsilon && (pc - pa).length() > epsilon)
                {
                    vAry->push_back( pc );
                    vAry->push_back( pd );
                    vAry->push_back( pa );
                }
            }
        }
    }

    addPrimitiveSet( new osg::DrawArrays( GL_TRIANGLES, 0, vAry->size() ) );
    FacetingVisitor::facet( *this );
}
/*! 
   Draw the Wheel's background gradient

   \param painter Painter
   \param r Bounding rectangle
*/
void QwtWheel::drawWheelBackground(QPainter *painter, const QRect &r )
{
    painter->save();

    //
    // initialize pens
    //
#if QT_VERSION < 0x040000
    const QColor light = colorGroup().light();
    const QColor dark = colorGroup().dark();
#else
    const QColor light = palette().color(QPalette::Light);
    const QColor dark = palette().color(QPalette::Dark);
#endif

    QPen lightPen;
    lightPen.setColor(light);
    lightPen.setWidth(d_data->intBorder);

    QPen darkPen;
    darkPen.setColor(dark);
    darkPen.setWidth(d_data->intBorder);

    setColorArray();

    //
    // initialize auxiliary variables
    //

    const int nFields = NUM_COLORS * 13 / 10;
    const int hiPos = nFields - NUM_COLORS + 1;

    if ( orientation() == Qt::Horizontal )
    {
        const int rx = r.x();
        int ry = r.y() + d_data->intBorder;
        const int rh = r.height() - 2* d_data->intBorder;
        const int rw = r.width();
        //
        //  draw shaded background
        //
        int x1 = rx;
        for (int i = 1; i < nFields; i++ )
        {
            const int x2 = rx + (rw * i) / nFields;
            painter->fillRect(x1, ry, x2-x1 + 1 ,rh, 
                d_data->colors[qwtAbs(i-hiPos)]);
            x1 = x2 + 1;
        }
        painter->fillRect(x1, ry, rw - (x1 - rx), rh, 
            d_data->colors[NUM_COLORS - 1]);

        //
        // draw internal border
        //
        painter->setPen(lightPen);
        ry = r.y() + d_data->intBorder / 2;
        painter->drawLine(r.x(), ry, r.x() + r.width() , ry);

        painter->setPen(darkPen);
        ry = r.y() + r.height() - (d_data->intBorder - d_data->intBorder / 2);
        painter->drawLine(r.x(), ry , r.x() + r.width(), ry);
    }
    else // Qt::Vertical
    {
        int rx = r.x() + d_data->intBorder;
        const int ry = r.y();
        const int rh = r.height();
        const int rw = r.width() - 2 * d_data->intBorder;

        //
        // draw shaded background
        //
        int y1 = ry;
        for ( int i = 1; i < nFields; i++ )
        {
            const int y2 = ry + (rh * i) / nFields;
            painter->fillRect(rx, y1, rw, y2-y1 + 1, 
                d_data->colors[qwtAbs(i-hiPos)]);
            y1 = y2 + 1;
        }
        painter->fillRect(rx, y1, rw, rh - (y1 - ry), 
            d_data->colors[NUM_COLORS - 1]);

        //
        //  draw internal borders
        //
        painter->setPen(lightPen);
        rx = r.x() + d_data->intBorder / 2;
        painter->drawLine(rx, r.y(), rx, r.y() + r.height());

        painter->setPen(darkPen);
        rx = r.x() + r.width() - (d_data->intBorder - d_data->intBorder / 2);
        painter->drawLine(rx, r.y(), rx , r.y() + r.height());
    }

    painter->restore();
}
Exemple #14
0
osgToy::Polyhedron::Polyhedron()
{
    setVertexArray( new osg::Vec3Array );
    setNormalArray( new osg::Vec3Array );
    setColorArray(  new osg::Vec4Array );
}