Example #1
0
/**
 * Computes intesections of coplanars faces from object A with faces from object B.
 * @param mesh mesh that contains the faces, edges and vertices
 * @param facesA set of faces from object A
 * @param facesB set of faces from object B
 */
void BOP_sew(BOP_Mesh *mesh, BOP_Faces *facesA, BOP_Faces *facesB)
{
	for(unsigned int idxFaceB = 0; idxFaceB < facesB->size(); idxFaceB++) {
		BOP_Face *faceB = (*facesB)[idxFaceB];
		MT_Plane3 planeB = faceB->getPlane();
		MT_Point3 p1 = mesh->getVertex(faceB->getVertex(0))->getPoint();
		MT_Point3 p2 = mesh->getVertex(faceB->getVertex(1))->getPoint();
		MT_Point3 p3 = mesh->getVertex(faceB->getVertex(2))->getPoint();
		
		for(unsigned int idxFaceA = 0;
			idxFaceA < facesA->size() &&
			faceB->getTAG() != BROKEN &&
			faceB->getTAG() != PHANTOM;
			idxFaceA++) {
			BOP_Face *faceA = (*facesA)[idxFaceA];
			if ((faceA->getTAG() != BROKEN)&&(faceA->getTAG() != PHANTOM)) {
				MT_Plane3 planeA = faceA->getPlane();
				if (BOP_containsPoint(planeA,p1) && 
					BOP_containsPoint(planeA,p2) && 
					BOP_containsPoint(planeA,p3)) {
					if (BOP_orientation(planeA,planeB) > 0) {
						BOP_intersectCoplanarFaces(mesh,facesA,faceB,faceA,true);
					}
				}
			}
		}
	}
}
Example #2
0
/**
 * Removes faces from facesB that are overlapped with anyone from facesA.
 * @param mesh mesh that contains the faces, edges and vertices
 * @param facesA set of faces from object A
 * @param facesB set of faces from object B
 */
void BOP_removeOverlappedFaces(BOP_Mesh *mesh,  BOP_Faces *facesA,  BOP_Faces *facesB)
{
	for(unsigned int i=0;i<facesA->size();i++) {
		BOP_Face *faceI = (*facesA)[i];       
		if (faceI->getTAG()==BROKEN) continue;
		bool overlapped = false;
		MT_Point3 p1 = mesh->getVertex(faceI->getVertex(0))->getPoint();
		MT_Point3 p2 = mesh->getVertex(faceI->getVertex(1))->getPoint();
		MT_Point3 p3 = mesh->getVertex(faceI->getVertex(2))->getPoint();
		for(unsigned int j=0;j<facesB->size();) {
			BOP_Face *faceJ = (*facesB)[j];
			if (faceJ->getTAG()!=BROKEN) {
			  MT_Plane3 planeJ = faceJ->getPlane();
			  if (BOP_containsPoint(planeJ,p1) && BOP_containsPoint(planeJ,p2) 
			      && BOP_containsPoint(planeJ,p3)) {
			    MT_Point3 q1 = mesh->getVertex(faceJ->getVertex(0))->getPoint();
			    MT_Point3 q2 = mesh->getVertex(faceJ->getVertex(1))->getPoint();
			    MT_Point3 q3 = mesh->getVertex(faceJ->getVertex(2))->getPoint();
			    if (BOP_overlap(MT_Vector3(planeJ.x(),planeJ.y(),planeJ.z()),
					    p1,p2,p3,q1,q2,q3)) {
			      facesB->erase(facesB->begin()+j,facesB->begin()+(j+1));
			      faceJ->setTAG(BROKEN);
			      overlapped = true;
			    }
			    else j++;
			  }
			  else j++;
			}else j++;
		}
		if (overlapped) faceI->setTAG(OVERLAPPED);
	}
}
Example #3
0
/**
 * Creates a list of lists L1, L2, ... LN where
 *   LX = mesh faces with vertex v that come from the same original face
 *        and without any of the vertices that appear before v in vertices
 * @param facesByOriginalFace list of faces lists
 * @param vertices vector with vertices indexs that contains v
 * @param v vertex index
 */
void BOP_Merge2::getFaces(BOP_LFaces &facesByOriginalFace, BOP_Indexs vertices, BOP_Index v)
{
	// Get edges with vertex v
	BOP_Indexs edgeIndexs = m_mesh->getVertex(v)->getEdges();
	const BOP_IT_Indexs edgeEnd = edgeIndexs.end();
	for(BOP_IT_Indexs edgeIndex = edgeIndexs.begin();edgeIndex != edgeEnd;edgeIndex++) {	
		// Foreach edge, add its no broken faces to the output list
		BOP_Edge* edge = m_mesh->getEdge(*edgeIndex);
		BOP_Indexs faceIndexs = edge->getFaces();
		const BOP_IT_Indexs faceEnd = faceIndexs.end();
		for(BOP_IT_Indexs faceIndex=faceIndexs.begin();faceIndex!=faceEnd;faceIndex++) {
			BOP_Face* face = m_mesh->getFace(*faceIndex);
			if (face->getTAG() != BROKEN) {
				// Search if the face contains any of the forbidden vertices
				bool found = false;
				for(BOP_IT_Indexs vertex = vertices.begin();*vertex!= v;vertex++) {
					if (face->containsVertex(*vertex)) {
						// face contains a forbidden vertex!
						found = true;
						break;
				}
			}
			if (!found) {
				// Search if we already have created a list with the 
				// faces that come from the same original face
			  const BOP_IT_LFaces lfEnd = facesByOriginalFace.end();
				for(BOP_IT_LFaces facesByOriginalFaceX=facesByOriginalFace.begin();
					facesByOriginalFaceX!=lfEnd; facesByOriginalFaceX++) {
					if (((*facesByOriginalFaceX)[0])->getOriginalFace() == face->getOriginalFace()) {
						// Search that the face has not been added to the list before
						for(unsigned int i = 0;i<(*facesByOriginalFaceX).size();i++) {
							if ((*facesByOriginalFaceX)[i] == face) {
								found = true;
								break;
							}
						}
						if (!found) {
						  // Add face to the list
						  if (face->getTAG()==OVERLAPPED) facesByOriginalFaceX->insert(facesByOriginalFaceX->begin(),face);
						  else facesByOriginalFaceX->push_back(face);
						  found = true;
						}
						break;
					}
				}
				if (!found) {
					// Create a new list and add the current face
					BOP_Faces facesByOriginalFaceX;
					facesByOriginalFaceX.push_back(face);
					facesByOriginalFace.push_back(facesByOriginalFaceX);
				}
			}
		}
	}
	}
}
Example #4
0
/**
 * testMesh
 */
void BOP_Mesh::testMesh()
{

	BOP_Face* cares[10];
	unsigned int nedges=0,i;
	for(i=0;i<m_edges.size();i++) {
		BOP_Edge *edge = m_edges[i];
		BOP_Indexs faces = edge->getFaces();
		unsigned int count = 0;
		const BOP_IT_Indexs facesEnd = faces.end();
		for(BOP_IT_Indexs it = faces.begin();it!=facesEnd;it++) {
			if (m_faces[*it]->getTAG()!=BROKEN) {
				cares[count] = m_faces[*it];
				count++;
				
			}
		}

		if ((count%2)!=0) nedges++;
	}
	if (nedges)
	  cout << nedges << " wrong edges." << endl;
	else
	  cout << "well edges." << endl;

	unsigned int duplFaces = 0;
	unsigned int wrongFaces = 0;
	for(i=0;i<m_faces.size();i++){
	  BOP_Face *faceI = m_faces[i];
	  if (faceI->getTAG()==BROKEN)
	    continue;

	  if (testFace(faceI)){
	    wrongFaces++;
	    cout << "Wrong Face: " << faceI << endl;
	  }

	  for(unsigned int j=i+1;j<m_faces.size();j++){
	    BOP_Face *faceJ = m_faces[j];

	    if (faceJ->getTAG()==BROKEN)
	      continue;

	    if (testFaces(faceI,faceJ)){
	      duplFaces++;
	      cout << "Duplicate FaceI: " << faceI << endl;
	      cout << "Duplicate FaceJ: " << faceJ << endl;
	    }
	  }
	}

	cout << duplFaces << " duplicate faces." << endl;
	cout << wrongFaces << " wrong faces." << endl;
}
Example #5
0
/**
 * Tests if faces since firstFace have all vertexs non-coincident of colinear, otherwise repairs the mesh.
 * @param mesh mesh that contains the faces, edges and vertices
 * @param firstFace first face index to be tested
 */
void BOP_mergeVertexs(BOP_Mesh *mesh, unsigned int firstFace)
{
	unsigned int numFaces = mesh->getNumFaces();
	for(unsigned int idxFace = firstFace; idxFace < numFaces; idxFace++) {
		BOP_Face *face = mesh->getFace(idxFace);
		if ((face->getTAG() != BROKEN) && (face->getTAG() != PHANTOM)) {
			MT_Point3 vertex1 = mesh->getVertex(face->getVertex(0))->getPoint();
			MT_Point3 vertex2 = mesh->getVertex(face->getVertex(1))->getPoint();
			MT_Point3 vertex3 = mesh->getVertex(face->getVertex(2))->getPoint();
			if (BOP_collinear(vertex1,vertex2,vertex3)) // collinear triangle 
				face->setTAG(PHANTOM);
		}
	}
}
Example #6
0
/**
 * Returns the first face of faces that shares the input edge of face.
 * @param mesh mesh that contains the faces, edges and vertices
 * @param faces set of faces
 * @param face input face
 * @param edge face's edge
 * @return first face that shares the edge of input face
 */
BOP_Face *BOP_getOppositeFace(BOP_Mesh*  mesh, 
							  BOP_Faces* faces, 
							  BOP_Face*  face,
							  BOP_Edge*  edge)
{
	if (edge == NULL)
	  return NULL;
  
	BOP_Indexs auxfaces = edge->getFaces();
	const BOP_IT_Indexs auxfacesEnd = auxfaces.end();
	for(BOP_IT_Indexs it = auxfaces.begin(); it != auxfacesEnd; it++) {
		BOP_Face *auxface = mesh->getFace(*it);
		if ((auxface != face) && (auxface->getTAG()!=BROKEN) && 
			BOP_containsFace(faces,auxface)) {
			return auxface;
		}
	}        
  
	return NULL;
}
Example #7
0
void BOP_Merge2::cleanup( void )
{
	BOP_Edges edges = m_mesh->getEdges();
	for (BOP_IT_Edges edge = edges.begin(); edge != edges.end(); ++edge) {
		BOP_Indexs faces = (*edge)->getFaces();
		for (BOP_IT_Indexs face = faces.begin(); face != faces.end(); ++face) {
			BOP_Face *f = m_mesh->getFace(*face);
			if(f->getTAG()== UNCLASSIFIED) ;
			else (*edge)->removeFace(*face);
		}
		if( (*edge)->getFaces().size() == 0) (*edge)->setUsed(false);
	}

	BOP_Vertexs v = m_mesh->getVertexs();
	for( BOP_IT_Vertexs it = v.begin(); it != v.end(); ++it ) {
		if( (*it)->getTAG() != BROKEN) {
			BOP_Indexs iedges = (*it)->getEdges();
			for(BOP_IT_Indexs i = iedges.begin();i!=iedges.end();i++)
				if( m_mesh->getEdge((*i))->getUsed( ) == false) (*it)->removeEdge( *i );
			if( (*it)->getEdges().size() == 0 ) (*it)->setTAG(BROKEN);
		}
	}
	// clean_nonmanifold( m_mesh );
}
Example #8
0
void dumpmesh ( BOP_Mesh *m, bool force )
{
	unsigned int nonmanifold = 0;
	{
	BOP_Edges edges = m->getEdges();
	int count = 0;
    for (BOP_IT_Edges edge = edges.begin(); edge != edges.end();
		++count, ++edge) {
		if (!(*edge)->getUsed() && (*edge)->getFaces().size() == 0 ) continue;
		BOP_Vertex * v1 = m->getVertex((*edge)->getVertex1());
		BOP_Vertex * v2 = m->getVertex((*edge)->getVertex2());

		if(v1->getTAG()!= BROKEN || v2->getTAG()!= BROKEN ) {
			int fcount = 0;
			BOP_Indexs faces = (*edge)->getFaces();
			for (BOP_IT_Indexs face = faces.begin(); face != faces.end(); face++) {
				BOP_Face *f = m->getFace(*face);
				if(f->getTAG()== UNCLASSIFIED) ++fcount;
			}


			if(fcount !=0 && fcount !=2 ) {
				++nonmanifold;
			}
		}
	}
	if (!force && nonmanifold == 0) return;
	}
	if( nonmanifold )
		cout << nonmanifold << " edges detected" << endl;
#ifdef BOP_DEBUG
	cout << "---------------------------" << endl;

	BOP_Edges edges = m->getEdges();
	int count = 0;
    for (BOP_IT_Edges edge = edges.begin(); edge != edges.end();
		++count, ++edge) {
		BOP_Vertex * v1 = m->getVertex((*edge)->getVertex1());
		BOP_Vertex * v2 = m->getVertex((*edge)->getVertex2());

		if(v1->getTAG()!= BROKEN || v2->getTAG()!= BROKEN ) {
			int fcount = 0;
			BOP_Indexs faces = (*edge)->getFaces();
			cout << count << ", " << (*edge) << ", " << faces.size() << endl;
			for (BOP_IT_Indexs face = faces.begin(); face != faces.end(); face++) {
				BOP_Face *f = m->getFace(*face);
				if(f->getTAG()== UNCLASSIFIED) ++fcount;
				cout << "  face " << f << endl;
			}


			if(fcount !=0 && fcount !=2 )
				cout << "    NON-MANIFOLD" << endl;
		}
	}

	BOP_Faces faces = m->getFaces();
	count = 0;
    for (BOP_IT_Faces face = faces.begin(); face != faces.end(); face++) {
		if( count < 12*2 || (*face)->getTAG() != BROKEN ) {
			cout << count << ", " << *face << endl;
		}
		++count;
	}

	BOP_Vertexs verts = m->getVertexs();
	count = 0;
    for (BOP_IT_Vertexs vert = verts.begin(); vert != verts.end(); vert++) {
		cout << count++ << ", " << *vert << " " << (*vert)->getNumEdges() << endl;
		BOP_Indexs edges = (*vert)->getEdges();
	    for( BOP_IT_Indexs it = edges.begin(); it != edges.end(); ++it) {
			BOP_Edge *edge = m->getEdge(*it);
			cout << "   " << edge << endl;
		}
	}
	cout << "===========================" << endl;
#endif
}
Example #9
0
/**
 * Triangulates faceB using edges of faceA that both are complanars.
 * @param mesh mesh that contains the faces, edges and vertices
 * @param facesB set of faces from object B
 * @param faceA face from object A
 * @param faceB face from object B
 * @param invert indicates if faceA has priority over faceB
 */
void BOP_intersectCoplanarFaces(BOP_Mesh*  mesh,
								BOP_Faces* facesB, 
								BOP_Face*  faceA, 
								BOP_Face*  faceB, 
								bool       invert)
{
	unsigned int oldSize = facesB->size();
	unsigned int originalFaceB = faceB->getOriginalFace();    
	
	MT_Point3 p1 = mesh->getVertex(faceA->getVertex(0))->getPoint();
	MT_Point3 p2 = mesh->getVertex(faceA->getVertex(1))->getPoint();
	MT_Point3 p3 = mesh->getVertex(faceA->getVertex(2))->getPoint();
	
	MT_Vector3 normal(faceA->getPlane().x(),faceA->getPlane().y(),faceA->getPlane().z());
	
	MT_Vector3 p1p2 = p2-p1;
	
	MT_Plane3 plane1((p1p2.cross(normal).normalized()),p1);
	
	BOP_Segment sA;
	sA.m_cfg1 = BOP_Segment::createVertexCfg(1);
	sA.m_v1 = faceA->getVertex(0);
	sA.m_cfg2 = BOP_Segment::createVertexCfg(2);
	sA.m_v2 = faceA->getVertex(1);
	
	BOP_intersectCoplanarFaces(mesh,facesB,faceB,sA,plane1,invert);
	
	MT_Vector3 p2p3 = p3-p2;
	MT_Plane3 plane2((p2p3.cross(normal).normalized()),p2);
	
	sA.m_cfg1 = BOP_Segment::createVertexCfg(2);
	sA.m_v1 = faceA->getVertex(1);
	sA.m_cfg2 = BOP_Segment::createVertexCfg(3);
	sA.m_v2 = faceA->getVertex(2);
  
	if (faceB->getTAG() == BROKEN) {
		for(unsigned int idxFace = oldSize; idxFace < facesB->size(); idxFace++) {
			BOP_Face *face = (*facesB)[idxFace];
			if (face->getTAG() != BROKEN && originalFaceB == face->getOriginalFace())
				BOP_intersectCoplanarFaces(mesh,facesB,face,sA,plane2,invert);
		}
	}
	else {
		BOP_intersectCoplanarFaces(mesh,facesB,faceB,sA,plane2,invert);
	}
  
	MT_Vector3 p3p1 = p1-p3;
	MT_Plane3 plane3((p3p1.cross(normal).safe_normalized()),p3);
	
	sA.m_cfg1 = BOP_Segment::createVertexCfg(3);
	sA.m_v1 = faceA->getVertex(2);
	sA.m_cfg2 = BOP_Segment::createVertexCfg(1);
	sA.m_v2 = faceA->getVertex(0);
  
	if (faceB->getTAG() == BROKEN) {
		for(unsigned int idxFace = oldSize; idxFace < facesB->size(); idxFace++) {
			BOP_Face *face = (*facesB)[idxFace];
			if (face->getTAG() != BROKEN && originalFaceB == face->getOriginalFace())
				BOP_intersectCoplanarFaces(mesh,facesB,face,sA,plane3,invert);
		}
	}
	else {
		BOP_intersectCoplanarFaces(mesh,facesB,faceB,sA,plane3,invert);
	} 
}
Example #10
0
void BOP_Face2Face(BOP_Mesh *mesh, BOP_Faces *facesA, BOP_Faces *facesB)
{
	for(unsigned int idxFaceA=0;idxFaceA<facesA->size();idxFaceA++) {
		BOP_Face *faceA = (*facesA)[idxFaceA];
		MT_Plane3 planeA = faceA->getPlane();
		MT_Point3 p1 = mesh->getVertex(faceA->getVertex(0))->getPoint();
		MT_Point3 p2 = mesh->getVertex(faceA->getVertex(1))->getPoint();
		MT_Point3 p3 = mesh->getVertex(faceA->getVertex(2))->getPoint();

	/* get (or create) bounding box for face A */
		if( faceA->getBBox() == NULL )
        	faceA->setBBox(p1,p2,p3);
		BOP_BBox *boxA = faceA->getBBox();

	/* start checking B faces with the previously stored split index */

		for(unsigned int idxFaceB=faceA->getSplit();
			idxFaceB<facesB->size() && (faceA->getTAG() != BROKEN) && (faceA->getTAG() != PHANTOM);) {
			BOP_Face *faceB = (*facesB)[idxFaceB];
			faceA->setSplit(idxFaceB);
			if ((faceB->getTAG() != BROKEN) && (faceB->getTAG() != PHANTOM)) {

	/* get (or create) bounding box for face B */
				if( faceB->getBBox() == NULL )
        			faceB->setBBox(mesh->getVertex(faceB->getVertex(0))->getPoint(),
                    mesh->getVertex(faceB->getVertex(1))->getPoint(),
                    mesh->getVertex(faceB->getVertex(2))->getPoint());
			  BOP_BBox *boxB = faceB->getBBox();

			  if (boxA->intersect(*boxB)) {
			    MT_Plane3 planeB = faceB->getPlane();
			    if (BOP_containsPoint(planeB,p1) && 
				BOP_containsPoint(planeB,p2) && 
				BOP_containsPoint(planeB,p3)) {
			      if (BOP_orientation(planeB,planeA)>0) {
				    BOP_intersectCoplanarFaces(mesh,facesB,faceA,faceB,false);
			      }
			    }
			    else {
			      BOP_intersectNonCoplanarFaces(mesh,facesA,facesB,faceA,faceB);
			    }
			  }			  
			}
			idxFaceB++;
		}
	}
	
	
	// Clean broken faces from facesA
	BOP_IT_Faces it;
	it = facesA->begin();
	while (it != facesA->end()) {
		BOP_Face *face = *it;
		if (face->getTAG() == BROKEN) it = facesA->erase(it);
		else it++;
	}
	/*
	it = facesB->begin();
	while (it != facesB->end()) {
		BOP_Face *face = *it;
		if (face->getTAG() == BROKEN) it = facesB->erase(it);
		else it++;
	}
	*/
}