コード例 #1
0
ファイル: testTextTXFGeo.cpp プロジェクト: mlimper/OpenSG1x
// Create the metrics
NodePtr createMetrics(TextFace *face, Real32 scale, const TextLayoutParam &layoutParam,
                      const TextLayoutResult &layoutResult)
{
    GeometryPtr geoPtr = Geometry::create();
    beginEditCP(geoPtr);
    {
        GeoPTypesUI8Ptr typesPtr = GeoPTypesUI8::create();
        geoPtr->setTypes(typesPtr);

        GeoPLengthsUI32Ptr lensPtr = GeoPLengthsUI32::create();
        geoPtr->setLengths(lensPtr);

        GeoPositions3fPtr posPtr = GeoPositions3f::create();
        geoPtr->setPositions(posPtr);

        GeoColors3fPtr colorsPtr = GeoColors3f::create();
        colorsPtr->push_back(Color3f(0.f, 0.f, 1.f));
        colorsPtr->push_back(Color3f(1.f, 0.f, 0.f));
        colorsPtr->push_back(Color3f(0.f, 1.f, 0.f));
        colorsPtr->push_back(Color3f(1.f, 1.f, 0.f));
        geoPtr->setColors(colorsPtr);

        GeoIndicesUI32Ptr indicesPtr = GeoIndicesUI32::create();
        geoPtr->setIndices(indicesPtr);

        UInt32 i, numGlyphs = layoutResult.getNumGlyphs();
        for (i = 0; i < numGlyphs; ++i)
        {
            const TextGlyph &glyph = face->getGlyph(layoutResult.indices[i]);
            typesPtr->push_back(GL_LINE_LOOP);
            lensPtr->push_back(4);
            const Vec2f &pos = layoutResult.positions[i];
            Real32 left = pos.x() * scale;
            Real32 right = (pos.x() + glyph.getWidth()) * scale;
            Real32 top = pos.y() * scale;
            Real32 bottom = (pos.y() - glyph.getHeight()) * scale;
            UInt32 posOffset = posPtr->size();
            posPtr->push_back(Vec3f(left, bottom, 0.f));
            posPtr->push_back(Vec3f(right, bottom, 0.f));
            posPtr->push_back(Vec3f(right, top, 0.f));
            posPtr->push_back(Vec3f(left, top, 0.f));
            indicesPtr->push_back(posOffset);
            indicesPtr->push_back(0);
            indicesPtr->push_back(posOffset + 1);
            indicesPtr->push_back(0);
            indicesPtr->push_back(posOffset + 2);
            indicesPtr->push_back(0);
            indicesPtr->push_back(posOffset + 3);
            indicesPtr->push_back(0);
        }

        // Bounding box
        Vec2f lowerLeft, upperRight;
        face->calculateBoundingBox(layoutResult, lowerLeft, upperRight);
        typesPtr->push_back(GL_LINE_LOOP);
        lensPtr->push_back(4);
        Real32 left = lowerLeft.x() * scale;
        Real32 right = upperRight.x() * scale;
        Real32 top = upperRight.y() * scale;
        Real32 bottom = lowerLeft.y() * scale;
        UInt32 posOffset = posPtr->size();
        posPtr->push_back(Vec3f(left, bottom, 0.f));
        posPtr->push_back(Vec3f(right, bottom, 0.f));
        posPtr->push_back(Vec3f(right, top, 0.f));
        posPtr->push_back(Vec3f(left, top, 0.f));
        indicesPtr->push_back(posOffset);
        indicesPtr->push_back(1);
        indicesPtr->push_back(posOffset + 1);
        indicesPtr->push_back(1);
        indicesPtr->push_back(posOffset + 2);
        indicesPtr->push_back(1);
        indicesPtr->push_back(posOffset + 3);
        indicesPtr->push_back(1);

        // Text bounds & Line bounds
        Vec2f pos, textPos, offset;
        if (layoutParam.horizontal == true)
        {
            Real32 lineHeight = face->getHoriAscent() - face->getHoriDescent();
            Real32 spacing = layoutParam.spacing * lineHeight;
            if (layoutParam.topToBottom == true)
            {
                switch (layoutParam.minorAlignment)
                {
                    case TextLayoutParam::ALIGN_BEGIN:
                        break;
                    case TextLayoutParam::ALIGN_FIRST:
                        pos[1] = textPos[1] = face->getHoriAscent();
                        break;
                    case TextLayoutParam::ALIGN_MIDDLE:
                        pos[1] = textPos[1] = (spacing * (layoutResult.lineBounds.size() - 1) + lineHeight) / 2.f;
                        break;
                    case TextLayoutParam::ALIGN_END:
                        pos[1] = textPos[1] = spacing * (layoutResult.lineBounds.size() - 1) + lineHeight;
                        break;
                }
                offset.setValues(0.f, -spacing);
            }
            else
            {
                switch (layoutParam.minorAlignment)
                {
                    case TextLayoutParam::ALIGN_BEGIN:
                        pos[1] = lineHeight;
                        textPos[1] = spacing * (layoutResult.lineBounds.size() - 1) + lineHeight;
                        break;
                    case TextLayoutParam::ALIGN_FIRST:
                        pos[1] = face->getHoriAscent();
                        textPos[1] = spacing * (layoutResult.lineBounds.size() - 1) + face->getHoriAscent();
                        break;
                    case TextLayoutParam::ALIGN_MIDDLE:
                        pos[1] = -(spacing * (layoutResult.lineBounds.size() - 1) + lineHeight) / 2.f + lineHeight;
                        textPos[1] = (spacing * (layoutResult.lineBounds.size() - 1) + lineHeight) / 2.f;
                        break;
                    case TextLayoutParam::ALIGN_END:
                        pos[1] = -spacing * (layoutResult.lineBounds.size() - 1);
                        break;
                }
                offset.setValues(0.f, spacing);
            }
        }
        else
        {
            Real32 lineHeight = face->getVertDescent() - face->getVertAscent();
            Real32 spacing = layoutParam.spacing * lineHeight;
            if (layoutParam.leftToRight == true)
            {
                switch (layoutParam.minorAlignment)
                {
                    case TextLayoutParam::ALIGN_BEGIN:
                        break;
                    case TextLayoutParam::ALIGN_FIRST:
                        pos[0] = textPos[0] = face->getVertAscent();
                        break;
                    case TextLayoutParam::ALIGN_MIDDLE:
                        pos[0] = textPos[0] = -(spacing * (layoutResult.lineBounds.size() - 1) + lineHeight) / 2.f;
                        break;
                    case TextLayoutParam::ALIGN_END:
                        pos[0] = textPos[0] = -spacing * (layoutResult.lineBounds.size() - 1) - lineHeight;
                        break;
                }
                offset.setValues(spacing, 0.f);
            }
            else
            {
                switch (layoutParam.minorAlignment)
                {
                    case TextLayoutParam::ALIGN_BEGIN:
                        pos[0] = -lineHeight;
                        textPos[0] = -spacing * (layoutResult.lineBounds.size() - 1) - lineHeight;
                        break;
                    case TextLayoutParam::ALIGN_FIRST:
                        pos[0] = -face->getVertDescent();
                        textPos[0] = -spacing * (layoutResult.lineBounds.size() - 1) -face->getVertDescent();
                        break;
                    case TextLayoutParam::ALIGN_MIDDLE:
                        pos[0] = (spacing * (layoutResult.lineBounds.size() - 1) + lineHeight) / 2.f - lineHeight;
                        textPos[0] = -(spacing * (layoutResult.lineBounds.size() - 1) + lineHeight) / 2.f;
                        break;
                    case TextLayoutParam::ALIGN_END:
                        pos[0] = spacing * (layoutResult.lineBounds.size() - 1);
                        break;
                }
                offset.setValues(-spacing, 0.f);
            }
        }

        typesPtr->push_back(GL_LINE_LOOP);
        lensPtr->push_back(4);
        left = textPos.x();
        top = textPos.y();
        if (layoutParam.horizontal == true)
            if (layoutParam.leftToRight == true)
                switch (layoutParam.majorAlignment)
                {
                    case TextLayoutParam::ALIGN_BEGIN:
                    case TextLayoutParam::ALIGN_FIRST:
                        break;
                    case TextLayoutParam::ALIGN_MIDDLE:
                        left -= layoutResult.textBounds.x() / 2.f;
                        break;
                    case TextLayoutParam::ALIGN_END:
                        left -= layoutResult.textBounds.x();
                        break;
                }
            else
                switch (layoutParam.majorAlignment)
                {
                    case TextLayoutParam::ALIGN_BEGIN:
                    case TextLayoutParam::ALIGN_FIRST:
                        left -= layoutResult.textBounds.x();
                        break;
                    case TextLayoutParam::ALIGN_MIDDLE:
                        left -= layoutResult.textBounds.x() / 2.f;
                        break;
                    case TextLayoutParam::ALIGN_END:
                        break;
                }
        else
            if (layoutParam.topToBottom == true)
                switch (layoutParam.majorAlignment)
                {
                    case TextLayoutParam::ALIGN_BEGIN:
                    case TextLayoutParam::ALIGN_FIRST:
                        break;
                    case TextLayoutParam::ALIGN_MIDDLE:
                        top += layoutResult.textBounds.y() / 2.f;
                        break;
                    case TextLayoutParam::ALIGN_END:
                        top += layoutResult.textBounds.y();
                        break;
                }
            else
                switch (layoutParam.majorAlignment)
                {
                    case TextLayoutParam::ALIGN_BEGIN:
                    case TextLayoutParam::ALIGN_FIRST:
                        top += layoutResult.textBounds.y();
                        break;
                    case TextLayoutParam::ALIGN_MIDDLE:
                        top += layoutResult.textBounds.y() / 2.f;
                        break;
                    case TextLayoutParam::ALIGN_END:
                        break;
                }
        left *= scale;
        right = left + layoutResult.textBounds.x() * scale;
        top *= scale;
        bottom = top - layoutResult.textBounds.y() * scale;
        posOffset = posPtr->size();
        posPtr->push_back(Vec3f(left, bottom, 0.f));
        posPtr->push_back(Vec3f(right, bottom, 0.f));
        posPtr->push_back(Vec3f(right, top, 0.f));
        posPtr->push_back(Vec3f(left, top, 0.f));
        indicesPtr->push_back(posOffset);
        indicesPtr->push_back(3);
        indicesPtr->push_back(posOffset + 1);
        indicesPtr->push_back(3);
        indicesPtr->push_back(posOffset + 2);
        indicesPtr->push_back(3);
        indicesPtr->push_back(posOffset + 3);
        indicesPtr->push_back(3);

        vector<Vec2f>::const_iterator lbIt;
        for (lbIt = layoutResult.lineBounds.begin(); lbIt != layoutResult.lineBounds.end(); ++lbIt)
        {
            typesPtr->push_back(GL_LINE_LOOP);
            lensPtr->push_back(4);
            Real32 left = pos.x();
            Real32 top = pos.y();
            if (layoutParam.horizontal == true)
                if (layoutParam.leftToRight == true)
                    switch (layoutParam.majorAlignment)
                    {
                        case TextLayoutParam::ALIGN_BEGIN:
                        case TextLayoutParam::ALIGN_FIRST:
                            break;
                        case TextLayoutParam::ALIGN_MIDDLE:
                            left -= lbIt->x() / 2.f;
                            break;
                        case TextLayoutParam::ALIGN_END:
                            left -= lbIt->x();
                            break;
                    }
                else
                    switch (layoutParam.majorAlignment)
                    {
                        case TextLayoutParam::ALIGN_BEGIN:
                        case TextLayoutParam::ALIGN_FIRST:
                            left -= lbIt->x();
                            break;
                        case TextLayoutParam::ALIGN_MIDDLE:
                            left -= lbIt->x() / 2.f;
                            break;
                        case TextLayoutParam::ALIGN_END:
                            break;
                    }
            else
                if (layoutParam.topToBottom == true)
                    switch (layoutParam.majorAlignment)
                    {
                        case TextLayoutParam::ALIGN_BEGIN:
                        case TextLayoutParam::ALIGN_FIRST:
                            break;
                        case TextLayoutParam::ALIGN_MIDDLE:
                            top += lbIt->y() / 2.f;
                            break;
                        case TextLayoutParam::ALIGN_END:
                            top += lbIt->y();
                            break;
                    }
                else
                    switch (layoutParam.majorAlignment)
                    {
                        case TextLayoutParam::ALIGN_BEGIN:
                        case TextLayoutParam::ALIGN_FIRST:
                            top += lbIt->y();
                            break;
                        case TextLayoutParam::ALIGN_MIDDLE:
                            top += lbIt->y() / 2.f;
                            break;
                        case TextLayoutParam::ALIGN_END:
                            break;
                    }
            left *= scale;
            Real32 right = left + lbIt->x() * scale;
            top *= scale;
            Real32 bottom = top - lbIt->y() * scale;
            UInt32 posOffset = posPtr->size();
            posPtr->push_back(Vec3f(left, bottom, 0.f));
            posPtr->push_back(Vec3f(right, bottom, 0.f));
            posPtr->push_back(Vec3f(right, top, 0.f));
            posPtr->push_back(Vec3f(left, top, 0.f));
            indicesPtr->push_back(posOffset);
            indicesPtr->push_back(2);
            indicesPtr->push_back(posOffset + 1);
            indicesPtr->push_back(2);
            indicesPtr->push_back(posOffset + 2);
            indicesPtr->push_back(2);
            indicesPtr->push_back(posOffset + 3);
            indicesPtr->push_back(2);

            typesPtr->push_back(GL_LINE_STRIP);
            lensPtr->push_back(2);
            posOffset = posPtr->size();
            if (layoutParam.horizontal == true)
            {
                Real32 base = top - face->getHoriAscent() * scale;
                posPtr->push_back(Vec3f(left, base, 0.f));
                posPtr->push_back(Vec3f(right, base, 0.f));
            }
            else
            {
                Real32 base = left - face->getVertAscent() * scale;
                posPtr->push_back(Vec3f(base, top, 0.f));
                posPtr->push_back(Vec3f(base, bottom, 0.f));
            }
            indicesPtr->push_back(posOffset);
            indicesPtr->push_back(2);
            indicesPtr->push_back(posOffset + 1);
            indicesPtr->push_back(2);
            pos += offset;
        }

        geoPtr->editMFIndexMapping()->clear();
        geoPtr->editMFIndexMapping()->push_back(Geometry::MapPosition);
        geoPtr->editMFIndexMapping()->push_back(Geometry::MapColor);

        SimpleMaterialPtr matPtr = SimpleMaterial::create();
        geoPtr->setMaterial(matPtr);
    }
    endEditCP(geoPtr);

    NodePtr nodePtr = Node::create();
    beginEditCP(nodePtr, Node::CoreFieldMask);
    {
        nodePtr->setCore(geoPtr);
    }
    endEditCP(nodePtr, Node::CoreFieldMask);

    return nodePtr;
}
コード例 #2
0
ファイル: testTextTXFGeo.cpp プロジェクト: mlimper/OpenSG1x
// Create the coordinate cross
NodePtr createCoordinateCross()
{
    GeometryPtr geoPtr = Geometry::create();
    beginEditCP(geoPtr);
    {
        GeoPTypesUI8Ptr typesPtr = GeoPTypesUI8::create();
        typesPtr->push_back(GL_LINES);
        geoPtr->setTypes(typesPtr);

        GeoPLengthsUI32Ptr lensPtr = GeoPLengthsUI32::create();
        lensPtr->push_back(6);
        geoPtr->setLengths(lensPtr);

        GeoPositions3fPtr posPtr = GeoPositions3f::create();
        posPtr->push_back(Vec3f(-0.1f, 0.f, 0.f));
        posPtr->push_back(Vec3f(1.f, 0.f, 0.f));
        posPtr->push_back(Vec3f(0.f, -0.1f, 0.f));
        posPtr->push_back(Vec3f(0.f, 1.f, 0.f));
        posPtr->push_back(Vec3f(0.f, 0.f, -0.1f));
        posPtr->push_back(Vec3f(0.f, 0.f, 1.f));
        geoPtr->setPositions(posPtr);

        GeoColors3fPtr colorsPtr = GeoColors3f::create();
        colorsPtr->push_back(Color3f(1.f, 0.f, 0.f));
        colorsPtr->push_back(Color3f(0.f, 1.f, 0.f));
        colorsPtr->push_back(Color3f(0.f, 0.f, 1.f));
        geoPtr->setColors(colorsPtr);

        GeoIndicesUI32Ptr indicesPtr = GeoIndicesUI32::create();
        // X Axis
        indicesPtr->push_back(0);
        indicesPtr->push_back(0);
        indicesPtr->push_back(1);
        indicesPtr->push_back(0);
        // Y Axis
        indicesPtr->push_back(2);
        indicesPtr->push_back(1);
        indicesPtr->push_back(3);
        indicesPtr->push_back(1);
        // Z Axis
        indicesPtr->push_back(4);
        indicesPtr->push_back(2);
        indicesPtr->push_back(5);
        indicesPtr->push_back(2);
        geoPtr->setIndices(indicesPtr);

        geoPtr->editMFIndexMapping()->clear();
        geoPtr->editMFIndexMapping()->push_back(Geometry::MapPosition);
        geoPtr->editMFIndexMapping()->push_back(Geometry::MapColor);

        SimpleMaterialPtr matPtr = SimpleMaterial::create();
        geoPtr->setMaterial(matPtr);
    }
    endEditCP(geoPtr);

    NodePtr nodePtr = Node::create();
    beginEditCP(nodePtr, Node::CoreFieldMask);
    {
        nodePtr->setCore(geoPtr);
    }
    endEditCP(nodePtr, Node::CoreFieldMask);

    return nodePtr;
}
コード例 #3
0
// Initialize GLUT & OpenSG and set up the scene
int main(int argc, char **argv)
{
    // OSG init
    osgInit(argc,argv);

    // GLUT init
    int winid = setupGLUT(&argc, argv);

    // the connection between GLUT and OpenSG
    GLUTWindowPtr gwin= GLUTWindow::create();
    gwin->setId(winid);
    gwin->init();

    // create the scene
     
    /*
        In the previous example, the colors and positions used the same
        indices. That might not always be the preferred way, and it might not
        make sense for other properties, e.g. normals.
        
        It is possible to assign a different index for every property. See the
        indices section below for details.
    */
    
    /*
        The initial setup is the same as in the single indexed geometry...
    */
    GeoPTypesPtr type = GeoPTypesUI8::create();        
    beginEditCP(type, GeoPTypesUI8::GeoPropDataFieldMask);
    {
        type->push_back(GL_POLYGON  );
        type->push_back(GL_TRIANGLES);
        type->push_back(GL_QUADS    );
    }
    endEditCP  (type, GeoPTypesUI8::GeoPropDataFieldMask);

    GeoPLengthsPtr lens = GeoPLengthsUI32::create();    
    beginEditCP(lens, GeoPLengthsUI32::GeoPropDataFieldMask);
    {
        lens->push_back(4);
        lens->push_back(6);
        lens->push_back(8);
    }
    endEditCP  (lens, GeoPLengthsUI32::GeoPropDataFieldMask);
       
    GeoPositions3fPtr pnts = GeoPositions3f::create();
    beginEditCP(pnts, GeoPositions3f::GeoPropDataFieldMask);
    {
        // the base
        pnts->push_back(Pnt3f(-1, -1, -1));
        pnts->push_back(Pnt3f(-1, -1,  1));
        pnts->push_back(Pnt3f( 1, -1,  1));
        pnts->push_back(Pnt3f( 1, -1, -1));

        // the roof base
        pnts->push_back(Pnt3f(-1,  0, -1));
        pnts->push_back(Pnt3f(-1,  0,  1));
        pnts->push_back(Pnt3f( 1,  0,  1));
        pnts->push_back(Pnt3f( 1,  0, -1));

        // the gable
        pnts->push_back(Pnt3f( 0,  1, -1));
        pnts->push_back(Pnt3f( 0,  1,  1));
    }
    endEditCP  (pnts, GeoPositions3f::GeoPropDataFieldMask);
   
    GeoColors3fPtr colors = GeoColors3f::create();
    beginEditCP(colors, GeoColors3f::GeoPropDataFieldMask);
    {
        colors->push_back(Color3f(1, 1, 0));
        colors->push_back(Color3f(1, 0, 0));
        colors->push_back(Color3f(1, 0, 0));
        colors->push_back(Color3f(1, 1, 0));
        colors->push_back(Color3f(0, 1, 1));
        colors->push_back(Color3f(1, 0, 1));
    }
    endEditCP  (colors, GeoPositions3f::GeoPropDataFieldMask);

    /*
        A new property: normals.
        
        They are used for lighting calculations and have to point away from the
        surface. Normals are standard vectors.
    */
    GeoNormals3fPtr norms = GeoNormals3f::create();
    beginEditCP(norms, GeoNormals3f::GeoPropDataFieldMask);
    {
        norms->push_back(Vec3f(-1,  0,  0));
        norms->push_back(Vec3f( 1,  0,  0));
        norms->push_back(Vec3f( 0, -1,  0));
        norms->push_back(Vec3f( 0,  1,  0));
        norms->push_back(Vec3f( 0,  0, -1));
        norms->push_back(Vec3f( 0,  0,  1));
    }
    endEditCP  (norms, GeoNormals3f::GeoPropDataFieldMask);
    
  
    /*
        To use different indices for different attributes they have to be
        specified. This is done within the single index property, by using more
        than one index per vertex.
        
        In this case every vertex reads multiple indices from the Indices
        property. The meaning of every index is defined by the indexMapping
        given below.
    */
    GeoIndicesUI32Ptr indices = GeoIndicesUI32::create();
    beginEditCP(indices, GeoIndicesUI32::GeoPropDataFieldMask);
    {
        // indices for the polygon
        indices->push_back(0);   // position index
        indices->push_back(3);   // color/normal index
        indices->push_back(1);   // position index
        indices->push_back(3);   // color/normal index
        indices->push_back(2);   // position index
        indices->push_back(3);   // color/normal index
        indices->push_back(3);   // position index
        indices->push_back(3);   // color/normal index
       
        // indices for the triangles
        indices->push_back(7);   // position index
        indices->push_back(4);   // color/normal index
        indices->push_back(4);   // position index
        indices->push_back(4);   // color/normal index
        indices->push_back(8);   // position index
        indices->push_back(4);   // color/normal index

        indices->push_back(5);   // position index
        indices->push_back(5);   // color/normal index
        indices->push_back(6);   // position index
        indices->push_back(5);   // color/normal index
        indices->push_back(9);   // position index
        indices->push_back(5);   // color/normal index
        
        // indices for the quads
        indices->push_back(1);   // position index
        indices->push_back(5);   // color/normal index
        indices->push_back(2);   // position index
        indices->push_back(5);   // color/normal index
        indices->push_back(6);   // position index
        indices->push_back(5);   // color/normal index
        indices->push_back(5);   // position index
        indices->push_back(5);   // color/normal index

        indices->push_back(3);   // position index
        indices->push_back(4);   // color/normal index
        indices->push_back(0);   // position index
        indices->push_back(4);   // color/normal index
        indices->push_back(4);   // position index
        indices->push_back(4);   // color/normal index
        indices->push_back(7);   // position index
        indices->push_back(4);   // color/normal index
    }
    endEditCP  (indices, GeoIndicesUI32::GeoPropDataFieldMask);
    
    /*
       Put it all together into a Geometry NodeCore.
    */
    GeometryPtr geo=Geometry::create();
    beginEditCP(geo, Geometry::TypesFieldMask          |
                     Geometry::LengthsFieldMask        |
                     Geometry::IndicesFieldMask        |
                     Geometry::IndexMappingFieldMask   |
                     Geometry::PositionsFieldMask      |
                     Geometry::NormalsFieldMask        |
                     Geometry::ColorsFieldMask         |
                     Geometry::MaterialFieldMask       );
    {
        geo->setTypes    (type);
        geo->setLengths  (lens);
        geo->setIndices  (indices);
        
        /*
             The meaning of the different indices is given by the indexMapping
             field. 

             If contains an entry that defines which index for a vertex
             selects which attribute. In this example the first index selects
             the positions, the second is used for colors and normals.

             The number of elements in the indexMapping field defines the
             number of indices used for every vertex.
        */
        geo->editMFIndexMapping()->push_back(Geometry::MapPosition   );
        geo->editMFIndexMapping()->push_back(Geometry::MapColor    |
                                             Geometry::MapNormal     );
         
        geo->setPositions(pnts  );
        geo->setColors   (colors);
        geo->setNormals  (norms );
        
        /*
            Use a lit material this time, to show the effect of the normals.
        */
        geo->setMaterial (getDefaultMaterial());   
    }
    endEditCP  (geo, Geometry::TypesFieldMask          |
                     Geometry::LengthsFieldMask        |
                     Geometry::IndicesFieldMask        |
                     Geometry::IndexMappingFieldMask   |
                     Geometry::PositionsFieldMask      |
                     Geometry::NormalsFieldMask        |
                     Geometry::ColorsFieldMask         |
                     Geometry::MaterialFieldMask       );
    
    // put the geometry core into a node
    NodePtr n = Node::create();
    beginEditCP(n, Node::CoreFieldMask);
    {
        n->setCore(geo);
    }
    endEditCP  (n, Node::CoreFieldMask);
    
    // add a transformation to make it move     
    NodePtr scene = Node::create();  
    trans = Transform::create();
    beginEditCP(scene, Node::CoreFieldMask | Node::ChildrenFieldMask  );
    {
        scene->setCore(trans);
        scene->addChild(n);
    }
    endEditCP  (scene, Node::CoreFieldMask | Node::ChildrenFieldMask  );
 

    // create the SimpleSceneManager helper
    mgr = new SimpleSceneManager;

    // tell the manager what to manage
    mgr->setWindow(gwin );
    mgr->setRoot  (scene);

    // show the whole scene
    mgr->showAll();

    // GLUT main loop
    glutMainLoop();

    return 0;
}