Esempio n. 1
0
void
IfWeeder::weedMaterial(SoNode *root, IfWeederMaterialEntry *entry)
{
    // If the material affects no shapes at all, get rid of it. This
    // can happen when vertex property nodes are used.
    if (entry->shapes.getLength() == 0) {
	SoSearchAction sa;
	sa.setNode(entry->material);
	sa.setInterest(SoSearchAction::ALL);
	sa.apply(root);
	for (int i = 0; i < sa.getPaths().getLength(); i++) {
	    SoPath *path = sa.getPaths()[i];
	    SoSeparator *parent = (SoSeparator *) path->getNodeFromTail(1);
	    int index = path->getIndexFromTail(0);
	    ASSERT(parent->isOfType(SoSeparator::getClassTypeId()));
	    ASSERT(parent->getChild(index) == entry->material);
	    parent->removeChild(index);
	}
    }

    // Remove all material values from the material node that are
    // not used by any dependent shapes. Adjust the indices in the
    // dependent shapes accordingly.
    removeDuplicateMaterials(entry);

    // Now remove all material values that are not used by any
    // dependent shapes. Again, adjust the indices in the dependent
    // shapes.
    removeUnusedMaterials(entry);
}
void ViewProviderTransformed::unsetEdit(int ModNum)
{
    ViewProvider::unsetEdit(ModNum);

    while (pcRejectedRoot->getNumChildren() > 7) {
        SoSeparator* sep = static_cast<SoSeparator*>(pcRejectedRoot->getChild(7));
        SoMultipleCopy* rejectedTrfms = static_cast<SoMultipleCopy*>(sep->getChild(2));
        rejectedTrfms   ->removeAllChildren();
        sep->removeChild(1);
        sep->removeChild(0);
        pcRejectedRoot  ->removeChild(7);
    }
    pcRejectedRoot->removeAllChildren();

    pcRoot->removeChild(pcRejectedRoot);

    pcRejectedRoot->unref();
}
void ViewProviderTransformed::recomputeFeature(void)
{
    PartDesign::Transformed* pcTransformed = static_cast<PartDesign::Transformed*>(getObject());
    pcTransformed->getDocument()->recomputeFeature(pcTransformed);
    const std::vector<App::DocumentObjectExecReturn*> log = pcTransformed->getDocument()->getRecomputeLog();
    PartDesign::Transformed::rejectedMap rejected_trsf = pcTransformed->getRejectedTransformations();
    unsigned rejected = 0;
    for (PartDesign::Transformed::rejectedMap::const_iterator r = rejected_trsf.begin(); r != rejected_trsf.end(); r++)
        rejected += r->second.size();
    QString msg = QString::fromLatin1("%1");
    if (rejected > 0) {
        msg = QString::fromLatin1("<font color='orange'>%1<br/></font>\r\n%2");
        if (rejected == 1)
            msg = msg.arg(QObject::tr("One transformed shape does not intersect support"));
        else {
            msg = msg.arg(QObject::tr("%1 transformed shapes do not intersect support"));
            msg = msg.arg(rejected);
        }
    }
    if (log.size() > 0) {
        msg = msg.arg(QString::fromLatin1("<font color='red'>%1<br/></font>"));
        msg = msg.arg(QString::fromStdString(log.back()->Why));
    } else {
        msg = msg.arg(QString::fromLatin1("<font color='green'>%1<br/></font>"));
        msg = msg.arg(QObject::tr("Transformation succeeded"));
    }
    signalDiagnosis(msg);

    // Clear all the rejected stuff
    while (pcRejectedRoot->getNumChildren() > 7) {
        SoSeparator* sep = static_cast<SoSeparator*>(pcRejectedRoot->getChild(7));
        SoMultipleCopy* rejectedTrfms = static_cast<SoMultipleCopy*>(sep->getChild(2));
        rejectedTrfms   ->removeAllChildren();
        sep->removeChild(1);
        sep->removeChild(0);
        pcRejectedRoot  ->removeChild(7);
    }

    for (PartDesign::Transformed::rejectedMap::const_iterator o = rejected_trsf.begin(); o != rejected_trsf.end(); o++) {
        if (o->second.empty()) continue;

        TopoDS_Shape shape;
        if ((o->first)->getTypeId().isDerivedFrom(PartDesign::FeatureAddSub::getClassTypeId())) {
            PartDesign::FeatureAddSub* feature = static_cast<PartDesign::FeatureAddSub*>(o->first);
            shape = feature->AddSubShape.getShape().getShape();
        }

        if (shape.IsNull()) continue;

        // Display the rejected transformations in red
        TopoDS_Shape cShape(shape);

        try {
            // calculating the deflection value
            Standard_Real xMin, yMin, zMin, xMax, yMax, zMax;
            {
                Bnd_Box bounds;
                BRepBndLib::Add(cShape, bounds);
                bounds.SetGap(0.0);
                bounds.Get(xMin, yMin, zMin, xMax, yMax, zMax);
            }
            Standard_Real deflection = ((xMax-xMin)+(yMax-yMin)+(zMax-zMin))/300.0 * Deviation.getValue();

            // create or use the mesh on the data structure
            // Note: This DOES have an effect on cShape
#if OCC_VERSION_HEX >= 0x060600
            Standard_Real AngDeflectionRads = AngularDeflection.getValue() / 180.0 * M_PI;
            BRepMesh_IncrementalMesh(cShape,deflection,Standard_False,
                                        AngDeflectionRads,Standard_True);
#else
            BRepMesh_IncrementalMesh(cShape,deflection);
#endif
            // We must reset the location here because the transformation data
            // are set in the placement property
            TopLoc_Location aLoc;
            cShape.Location(aLoc);

            // count triangles and nodes in the mesh
            int nbrTriangles=0, nbrNodes=0;
            TopExp_Explorer Ex;
            for (Ex.Init(cShape,TopAbs_FACE);Ex.More();Ex.Next()) {
                Handle (Poly_Triangulation) mesh = BRep_Tool::Triangulation(TopoDS::Face(Ex.Current()), aLoc);
                // Note: we must also count empty faces
                if (!mesh.IsNull()) {
                    nbrTriangles += mesh->NbTriangles();
                    nbrNodes     += mesh->NbNodes();
                }
            }

            // create memory for the nodes and indexes
            SoCoordinate3* rejectedCoords = new SoCoordinate3();
            rejectedCoords  ->point      .setNum(nbrNodes);
            SoNormal* rejectedNorms = new SoNormal();
            rejectedNorms   ->vector     .setNum(nbrNodes);
            SoIndexedFaceSet* rejectedFaceSet = new SoIndexedFaceSet();
            rejectedFaceSet ->coordIndex .setNum(nbrTriangles*4);

            // get the raw memory for fast fill up
            SbVec3f* verts = rejectedCoords  ->point      .startEditing();
            SbVec3f* norms = rejectedNorms   ->vector     .startEditing();
            int32_t* index = rejectedFaceSet ->coordIndex .startEditing();

            // preset the normal vector with null vector
            for (int i=0; i < nbrNodes; i++)
                norms[i]= SbVec3f(0.0,0.0,0.0);

            int ii = 0,FaceNodeOffset=0,FaceTriaOffset=0;
            for (Ex.Init(cShape, TopAbs_FACE); Ex.More(); Ex.Next(),ii++) {
                TopLoc_Location aLoc;
                const TopoDS_Face &actFace = TopoDS::Face(Ex.Current());
                // get the mesh of the shape
                Handle (Poly_Triangulation) mesh = BRep_Tool::Triangulation(actFace,aLoc);
                if (mesh.IsNull()) continue;

                // getting the transformation of the shape/face
                gp_Trsf myTransf;
                Standard_Boolean identity = true;
                if (!aLoc.IsIdentity()) {
                    identity = false;
                    myTransf = aLoc.Transformation();
                }

                // getting size of node and triangle array of this face
                int nbNodesInFace = mesh->NbNodes();
                int nbTriInFace   = mesh->NbTriangles();
                // check orientation
                TopAbs_Orientation orient = actFace.Orientation();

                // cycling through the poly mesh
                const Poly_Array1OfTriangle& Triangles = mesh->Triangles();
                const TColgp_Array1OfPnt& Nodes = mesh->Nodes();
                for (int g=1; g <= nbTriInFace; g++) {
                    // Get the triangle
                    Standard_Integer N1,N2,N3;
                    Triangles(g).Get(N1,N2,N3);

                    // change orientation of the triangle if the face is reversed
                    if ( orient != TopAbs_FORWARD ) {
                        Standard_Integer tmp = N1;
                        N1 = N2;
                        N2 = tmp;
                    }

                    // get the 3 points of this triangle
                    gp_Pnt V1(Nodes(N1)), V2(Nodes(N2)), V3(Nodes(N3));

                    // transform the vertices to the place of the face
                    if (!identity) {
                        V1.Transform(myTransf);
                        V2.Transform(myTransf);
                        V3.Transform(myTransf);
                    }

                    // calculating per vertex normals
                    // Calculate triangle normal
                    gp_Vec v1(V1.X(),V1.Y(),V1.Z()),v2(V2.X(),V2.Y(),V2.Z()),v3(V3.X(),V3.Y(),V3.Z());
                    gp_Vec Normal = (v2-v1)^(v3-v1);

                    // add the triangle normal to the vertex normal for all points of this triangle
                    norms[FaceNodeOffset+N1-1] += SbVec3f(Normal.X(),Normal.Y(),Normal.Z());
                    norms[FaceNodeOffset+N2-1] += SbVec3f(Normal.X(),Normal.Y(),Normal.Z());
                    norms[FaceNodeOffset+N3-1] += SbVec3f(Normal.X(),Normal.Y(),Normal.Z());

                    // set the vertices
                    verts[FaceNodeOffset+N1-1].setValue((float)(V1.X()),(float)(V1.Y()),(float)(V1.Z()));
                    verts[FaceNodeOffset+N2-1].setValue((float)(V2.X()),(float)(V2.Y()),(float)(V2.Z()));
                    verts[FaceNodeOffset+N3-1].setValue((float)(V3.X()),(float)(V3.Y()),(float)(V3.Z()));

                    // set the index vector with the 3 point indexes and the end delimiter
                    index[FaceTriaOffset*4+4*(g-1)]   = FaceNodeOffset+N1-1;
                    index[FaceTriaOffset*4+4*(g-1)+1] = FaceNodeOffset+N2-1;
                    index[FaceTriaOffset*4+4*(g-1)+2] = FaceNodeOffset+N3-1;
                    index[FaceTriaOffset*4+4*(g-1)+3] = SO_END_FACE_INDEX;
                }

                // counting up the per Face offsets
                FaceNodeOffset += nbNodesInFace;
                FaceTriaOffset += nbTriInFace;
            }

            // normalize all normals
            for (int i=0; i < nbrNodes; i++)
                norms[i].normalize();

            // end the editing of the nodes
            rejectedCoords  ->point      .finishEditing();
            rejectedNorms   ->vector     .finishEditing();
            rejectedFaceSet ->coordIndex .finishEditing();

            // fill in the transformation matrices
            SoMultipleCopy* rejectedTrfms = new SoMultipleCopy();
            rejectedTrfms->matrix.setNum((o->second).size());
            SbMatrix* mats = rejectedTrfms->matrix.startEditing();

            std::list<gp_Trsf>::const_iterator trsf = (o->second).begin();
            for (unsigned int i=0; i < (o->second).size(); i++,trsf++) {
                Base::Matrix4D mat;
                Part::TopoShape::convertToMatrix(*trsf,mat);
                mats[i] = convert(mat);
            }
            rejectedTrfms->matrix.finishEditing();
            rejectedTrfms->addChild(rejectedFaceSet);
            SoSeparator* sep = new SoSeparator();
            sep->addChild(rejectedCoords);
            sep->addChild(rejectedNorms);
            sep->addChild(rejectedTrfms);
            pcRejectedRoot->addChild(sep);
        }
        catch (...) {
            Base::Console().Error("Cannot compute Inventor representation for the rejected transformations of shape of %s.\n",
                                  pcTransformed->getNameInDocument());
        }
    }

}
Esempio n. 4
0
	IVElement::IVElement(string ivfile, KthReal sc) {
		for(int i=0;i<3;i++){
			position[i]= 0.0f;
			orientation[i]=0.0f;
		}
		orientation[2]=1.0f;
		orientation[3]=0.0f;
		scale=sc;

		trans= new SoTranslation;
		rot = new SoRotation;
		sca = new SoScale();
		color = new SoMaterial;

		posVec = new SoSFVec3f;
		trans->translation.connectFrom(posVec);
		posVec->setValue((float)position[0],(float)position[1],(float)position[2]);

		rotVec = new SoSFRotation;
		rotVec->setValue(SbVec3f((float)orientation[0],(float)orientation[1],
				(float)orientation[2]),(float)orientation[3]);
		rot->rotation.connectFrom(rotVec);

		scaVec= new SoSFVec3f;
		scaVec->setValue((float)scale,(float)scale,(float)scale);
		sca->scaleFactor.connectFrom(scaVec);

		SoInput input;
		ivmodel = new SoSeparator;
		ivmodel->ref();
		ivmodel->addChild(sca);

		if(input.openFile(ivfile.c_str()))
			ivmodel->addChild(SoDB::readAll(&input));
		else
		{
			//ivmodel->addChild(new SoSphere());
			static const char *str[] = { 
				"#VRML V1.0 ascii\n",
				"DEF pointgoal Separator {\n",
				"  Separator {\n",
				"    MaterialBinding { value PER_PART }\n",
				"    Coordinate3 {\n",
				"      point [\n",
				"        0.0 0.0 0.0\n",
				"      ]\n",
				"    }\n",
				"    DrawStyle { pointSize 5 }\n",
				"    PointSet { }\n",
				"   }\n",
				"}\n",
				NULL
			};
			input.setStringArray(str);
			SoSeparator *sep = SoDB::readAll(&input);
			sep->ref();
			while (sep->getNumChildren() > 0)
			{
				ivmodel->addChild(sep->getChild(0));
				sep->removeChild(0);
			}
			sep->unref();
			
		}

		ivmodel->ref();

	}