예제 #1
0
파일: drawMesh.cpp 프로젝트: cycheung/gmsh
void drawContext::drawMesh()
{
  if(!CTX::instance()->mesh.draw) return;

  // make sure to flag any model-dependent post-processing view as
  // changed if the underlying mesh has, before resetting the changed
  // flag
  if(CTX::instance()->mesh.changed){
    for(unsigned int i = 0; i < GModel::list.size(); i++)
      for(unsigned int j = 0; j < PView::list.size(); j++)
        if(PView::list[j]->getData()->hasModel(GModel::list[i]))
          PView::list[j]->setChanged(true);
  }

  glPointSize((float)CTX::instance()->mesh.pointSize);
  gl2psPointSize((float)(CTX::instance()->mesh.pointSize *
                         CTX::instance()->print.epsPointSizeFactor));

  glLineWidth((float)CTX::instance()->mesh.lineWidth);
  gl2psLineWidth((float)(CTX::instance()->mesh.lineWidth *
                         CTX::instance()->print.epsLineWidthFactor));

  if(CTX::instance()->mesh.lightTwoSide)
    glLightModelf(GL_LIGHT_MODEL_TWO_SIDE, GL_TRUE);
  else
    glLightModelf(GL_LIGHT_MODEL_TWO_SIDE, GL_FALSE);

  if(!CTX::instance()->clipWholeElements){
    for(int i = 0; i < 6; i++)
      if(CTX::instance()->mesh.clip & (1 << i))
        glEnable((GLenum)(GL_CLIP_PLANE0 + i));
      else
        glDisable((GLenum)(GL_CLIP_PLANE0 + i));
  }

  for(unsigned int i = 0; i < GModel::list.size(); i++){
    GModel *m = GModel::list[i];
    m->fillVertexArrays();
    if(m->getVisibility() && isVisible(m)){
      int status = m->getMeshStatus();
      if(status >= 0)
        std::for_each(m->firstVertex(), m->lastVertex(), drawMeshGVertex(this));
      if(status >= 1)
        std::for_each(m->firstEdge(), m->lastEdge(), drawMeshGEdge(this));
      if(status >= 2){
        beginFakeTransparency();
        std::for_each(m->firstFace(), m->lastFace(), drawMeshGFace(this));
        endFakeTransparency();
      }
      if(status >= 3)
        std::for_each(m->firstRegion(), m->lastRegion(), drawMeshGRegion(this));
    }
  }

  CTX::instance()->mesh.changed = 0;

  for(int i = 0; i < 6; i++)
    glDisable((GLenum)(GL_CLIP_PLANE0 + i));
}
예제 #2
0
void collapseSmallEdges(GModel &gm)
{
  return;
  // gm.renumberMeshVertices(true);
  std::list<GFace*> faces;
  for (GModel::fiter fit = gm.firstFace(); fit != gm.lastFace(); fit++){
    faces.push_back(*fit);
  }
  BDS_Mesh *pm = gmsh2BDS(faces);
  outputScalarField(pm->triangles, "all.pos", 0);

  for (GModel::eiter eit = gm.firstEdge(); eit != gm.lastEdge(); eit++){
  }

  delete pm;
}
예제 #3
0
파일: OptHOM.cpp 프로젝트: iyer-arvind/gmsh
bool OptHOM::addBndObjGrad(double factor, double &Obj, alglib::real_1d_array &gradObj)
{
  // set the mesh to its present position
  std::vector<SPoint3> xyz,uvw;
  mesh.getGEntityPositions(xyz,uvw);
  mesh.updateGEntityPositions();

  //could be better (e.g. store the model in the Mesh:: datastrucure)

  GModel *gm = GModel::current();

  // for all model edges, compute the error between the geometry and the mesh

  maxDistCAD = 0.0;
  double distCAD = 0.0;

  for (GModel::eiter it = gm->firstEdge(); it != gm->lastEdge(); ++it){
    // do not do straight lines
    if ((*it)->geomType() == GEntity::Line)continue;
    // look at all mesh lines

    std::vector<bool> doWeCompute((*it)->lines.size());
    for (unsigned int i=0;i<(*it)->lines.size(); i++){
      doWeCompute[i] = false;
      for (unsigned int j=0;j<(*it)->lines[i]->getNumVertices(); j++){
        int index = mesh.getFreeVertexStartIndex((*it)->lines[i]->getVertex(j));
        if (index >=0){
          doWeCompute[i] = true;
          continue;
        }
      }
    }

    std::vector<double> dist((*it)->lines.size());
    for (unsigned int i=0;i<(*it)->lines.size(); i++){
      if (doWeCompute[i]){
        // compute the distance from the geometry to the mesh
        dist[i] = MLineGEdgeDistance ( (*it)->lines[i] , *it );
        maxDistCAD = std::max(maxDistCAD,dist[i]);
        distCAD += dist [i] * factor;
      }
    }
    // be clever to compute the derivative : iterate on all
    // Distance = \sum_{lines} Distance (line, GEdge)
    // For a high order vertex, we compute the derivative only by
    // recomputing the distance to one only line
    const double eps = 1.e-6;
    for (unsigned int i=0;i<(*it)->lines.size(); i++){
      if (doWeCompute[i]){
        for (int j=2 ; j<(*it)->lines[i]->getNumVertices()  ; j++){
          MVertex *v = (*it)->lines[i]->getVertex(j);
          int index = mesh.getFreeVertexStartIndex(v);
          //	printf("%d %d (%d %d)\n",v->getNum(),index,v->onWhat()->tag(),v->onWhat()->dim());
          if (index >= 0){
            double t;
            v->getParameter(0,t);
            SPoint3 pp (v->x(),v->y(),v->z());
            GPoint gp = (*it)->point(t+eps);
            v->setParameter(0,t+eps);
            v->setXYZ(gp.x(),gp.y(),gp.z());
            double dist2 = MLineGEdgeDistance ( (*it)->lines[i] , *it );
            double deriv = (dist2 - dist[i])/eps;
            v->setXYZ(pp.x(),pp.y(),pp.z());
            v->setParameter(0,t);
            //	  printf("%g %g %g\n",dist[i],dist2, MLineGEdgeDistance ( (*it)->lines[i] , *it ));
            // get the index of the vertex
            gradObj[index] += deriv * factor;
          }
        }
      }
      //    printf("done\n");
      // For a low order vertex classified on the GEdge, we recompute
    // two distances for the two MLines connected to the vertex
      for (unsigned int i=0;i<(*it)->lines.size()-1; i++){
        MVertex *v =  (*it)->lines[i]->getVertex(1);
        int index = mesh.getFreeVertexStartIndex(v);
        if (index >= 0){
          double t;
          v->getParameter(0,t);
          SPoint3 pp (v->x(),v->y(),v->z());
          GPoint gp = (*it)->point(t+eps);
          v->setParameter(0,t+eps);
          v->setXYZ(gp.x(),gp.y(),gp.z());
          MLine *l1 = (*it)->lines[i];
          MLine *l2 = (*it)->lines[i+1];
          //	printf("%d %d -- %d %d\n",l1->getVertex(0)->getNum(),l1->getVertex(1)->getNum(),l2->getVertex(0)->getNum(),l2->getVertex(1)->getNum());
          double deriv =
            (MLineGEdgeDistance ( l1 , *it ) - dist[i])  /eps +
            (MLineGEdgeDistance ( l2 , *it ) - dist[i+1])/eps;
          v->setXYZ(pp.x(),pp.y(),pp.z());
          v->setParameter(0,t);
          gradObj[index] += deriv * factor;
        }
      }
    }
  }
  //  printf("computing distance : 1D part %12.5E\n",distCAD);

  // now the 3D part !

  std::vector<std::vector<SVector3> > gsfT;
  computeGradSFAtNodes ( (*gm->firstFace())->triangles[0],gsfT);

  std::map<MVertex*,SVector3> normalsToCAD;


  for(GModel::fiter it = gm->firstFace(); it != gm->lastFace(); ++it){
    // do not do plane surfaces
    if ((*it)->geomType() == GEntity::Plane)continue;
    std::map<MTriangle*,double> dist;

    std::vector<bool> doWeCompute((*it)->triangles.size());
    for (unsigned int i=0;i<(*it)->triangles.size(); i++){
      doWeCompute[i] = false;
      for (unsigned int j=0;j<(*it)->triangles[i]->getNumVertices(); j++){
        int index = mesh.getFreeVertexStartIndex((*it)->triangles[i]->getVertex(j));
        if (index >=0){
          doWeCompute[i] = true;
        }
      }
      if (doWeCompute[i]){
        for (unsigned int j=0;j<(*it)->triangles[i]->getNumVertices(); j++){
          MVertex *v = (*it)->triangles[i]->getVertex(j);
          if (normalsToCAD.find(v) == normalsToCAD.end()){
            SPoint2 p_cad;
            reparamMeshVertexOnFace(v, *it, p_cad);
            SVector3 tg_cad = (*it)->normal(p_cad);
            tg_cad.normalize();
            normalsToCAD[v] = tg_cad;
          }
        }
      }
    }

    for (unsigned int i=0;i<(*it)->triangles.size(); i++){
      // compute the distance from the geometry to the mesh
      if(doWeCompute[i]){
        const double d = MFaceGFaceDistanceOld((*it)->triangles[i], *it, &gsfT, &normalsToCAD);
        dist[(*it)->triangles[i]] = d;
        maxDistCAD = std::max(maxDistCAD,d);
        distCAD += d * factor;
      }
    }

    // be clever again to compute the derivatives
    const double eps = 1.e-6;
    for (unsigned int i=0;i<(*it)->triangles.size(); i++){
      if(doWeCompute[i]){
        for (unsigned int j=0;j<(*it)->triangles[i]->getNumVertices(); j++){
          //    for (; itm !=v2t.end(); ++itm){
          MVertex   *v = (*it)->triangles[i]->getVertex(j);
          if(v->onWhat()->dim() == 1){
            int index = mesh.getFreeVertexStartIndex(v);
            if (index >= 0){
              MTriangle *t = (*it)->triangles[i];
              GEdge *ge = v->onWhat()->cast2Edge();
              double t_;
              v->getParameter(0,t_);
              SPoint3 pp (v->x(),v->y(),v->z());
              GPoint gp = ge->point(t_+eps);
              v->setParameter(0,t_+eps);
              v->setXYZ(gp.x(),gp.y(),gp.z());
              const double distT = dist[t];
              double deriv =  (MFaceGFaceDistanceOld(t, *it, &gsfT, &normalsToCAD) - distT) /eps;
              v->setXYZ(pp.x(),pp.y(),pp.z());
              v->setParameter(0,t_);
              gradObj[index] += deriv * factor;
            }
          }

          if(v->onWhat() == *it){
            int index = mesh.getFreeVertexStartIndex(v);
            if (index >= 0){
              MTriangle *t = (*it)->triangles[i];
              double uu,vv;
              v->getParameter(0,uu);
              v->getParameter(1,vv);
              SPoint3 pp (v->x(),v->y(),v->z());

              const double distT = dist[t];

              GPoint gp = (*it)->point(uu+eps,vv);
              v->setParameter(0,uu+eps);
              v->setXYZ(gp.x(),gp.y(),gp.z());
              double deriv = (MFaceGFaceDistanceOld(t, *it, &gsfT, &normalsToCAD) - distT) /eps;
              v->setXYZ(pp.x(),pp.y(),pp.z());
              v->setParameter(0,uu);
              gradObj[index] += deriv * factor;

              gp = (*it)->point(uu,vv+eps);
              v->setParameter(1,vv+eps);
              v->setXYZ(gp.x(),gp.y(),gp.z());
              deriv = (MFaceGFaceDistanceOld(t, *it, &gsfT, &normalsToCAD) - distT) /eps;
              v->setXYZ(pp.x(),pp.y(),pp.z());
              v->setParameter(1,vv);
              gradObj[index+1] += deriv * factor;
            }
          }
        }
      }
    }
  }
  mesh.updateGEntityPositions(xyz,uvw);
  Obj +=distCAD;
  //  printf("computing distance : 2D part %12.5E\n",distCAD);
  //  printf("%22.15E\n",distCAD);
  return true;
}
예제 #4
0
int main(int argc,char *argv[])
{
  if(argc < 6){
    printf("Usage: %s file lx ly lz rmax [levels=1] [refcs=1]\n", argv[0]);
    printf("where\n");
    printf("  'file' contains a CAD model\n");
    printf("  'lx', 'ly' and 'lz' are the sizes of the elements along the"
           " x-, y- and z-axis at the coarsest level\n");
    printf("  'rmax' is the radius of the largest sphere that can be inscribed"
           " in the structure\n");
    printf("  'levels' sets the number of levels in the grid\n");
    printf("  'refcs' selects if curved surfaces should be refined\n");
    return -1;
  }

  GmshInitialize();
  GmshSetOption("General", "Terminal", 1.);
  GmshMergeFile(argv[1]);
  double lx = atof(argv[2]), ly = atof(argv[3]), lz = atof(argv[4]);
  double rmax = atof(argv[5]);
  int levels = (argc > 6) ? atof(argv[6]) : 1;
  int refineCurvedSurfaces = (argc > 7) ? atof(argv[7]) : 1;

  // minimum distance between points in the cloud at the coarsest
  // level
  double sampling = std::min(rmax, std::min(lx, std::min(ly, lz)));

  // radius of the "tube" created around parts to refine at the
  // coarsest level
  double rtube = std::max(lx, std::max(ly, lz)) * 2.;

  GModel *gm = GModel::current();

  std::vector<SPoint3> points;
  Msg::Info("Filling coarse point cloud on surfaces");
  for (GModel::fiter fit = gm->firstFace(); fit != gm->lastFace(); fit++)
    (*fit)->fillPointCloud(sampling, &points);
  Msg::Info("  %d points in the surface cloud", (int)points.size());

  std::vector<SPoint3> refinePoints;
  if(levels > 1){
    double s = sampling / pow(2., levels - 1);
    Msg::Info("Filling refined point cloud on curves and curved surfaces");
    for (GModel::eiter eit = gm->firstEdge(); eit != gm->lastEdge(); eit++)
      fillPointCloud(*eit, s, refinePoints);

    // FIXME: refine this by computing e.g. "mean" curvature
    if(refineCurvedSurfaces){
      for (GModel::fiter fit = gm->firstFace(); fit != gm->lastFace(); fit++)
        if((*fit)->geomType() != GEntity::Plane)
          (*fit)->fillPointCloud(2 * s, &refinePoints);
    }
    Msg::Info("  %d points in the refined cloud", (int)refinePoints.size());
  }

  SBoundingBox3d bb;
  for(unsigned int i = 0; i < points.size(); i++) bb += points[i];
  for(unsigned int i = 0; i < refinePoints.size(); i++) bb += refinePoints[i];
  bb.scale(1.21, 1.21, 1.21);
  SVector3 range = bb.max() - bb.min();
  int NX = range.x() / lx;
  int NY = range.y() / ly;
  int NZ = range.z() / lz;
  if(NX < 2) NX = 2;
  if(NY < 2) NY = 2;
  if(NZ < 2) NZ = 2;

  Msg::Info("  bounding box min: %g %g %g -- max: %g %g %g",
            bb.min().x(), bb.min().y(), bb.min().z(),
            bb.max().x(), bb.max().y(), bb.max().z());
  Msg::Info("  Nx=%d Ny=%d Nz=%d", NX, NY, NZ);

  cartesianBox<double> box(bb.min().x(), bb.min().y(), bb.min().z(),
                           SVector3(range.x(), 0, 0),
                           SVector3(0, range.y(), 0),
                           SVector3(0, 0, range.z()),
                           NX, NY, NZ, levels);

  Msg::Info("Inserting active cells in the cartesian grid");
  Msg::Info("  level %d", box.getLevel());
  for (unsigned int i = 0; i < points.size(); i++)
    insertActiveCells(points[i].x(), points[i].y(), points[i].z(), rmax, box);

  cartesianBox<double> *parent = &box, *child;
  while((child = parent->getChildBox())){
    Msg::Info("  level %d", child->getLevel());
    for(unsigned int i = 0; i < refinePoints.size(); i++)
      insertActiveCells(refinePoints[i].x(), refinePoints[i].y(), refinePoints[i].z(),
                        rtube / pow(2., (levels - child->getLevel())), *child);
    parent = child;
  }

  // remove child cells that do not entirely fill parent cell or for
  // which there is no parent neighbor; then remove parent cells that
  // have children
  Msg::Info("Removing cells to match X-FEM mesh topology constraints");
  removeBadChildCells(&box);
  removeParentCellsWithChildren(&box);

  // we generate duplicate nodes at this point so we can easily access
  // cell values at each level; we will clean up by renumbering after
  // filtering
  Msg::Info("Initializing nodal values in the cartesian grid");
  box.createNodalValues();

  Msg::Info("Computing levelset on the cartesian grid");
  computeLevelset(gm, box);

  Msg::Info("Removing cells outside the structure");
  removeOutsideCells(&box);

  Msg::Info("Renumbering mesh vertices across levels");
  box.renumberNodes();

  bool decomposeInSimplex = false;
  box.writeMSH("yeah.msh", decomposeInSimplex);

  Msg::Info("Done!");
  GmshFinalize();
}
예제 #5
0
PView *GMSH_BubblesPlugin::execute(PView *v)
{
  double shrink = (double)BubblesOptions_Number[0].def;
  std::string fileName = BubblesOptions_String[0].def;

  FILE *fp = Fopen(fileName.c_str(), "w");
  if(!fp){
    Msg::Error("Could not open output file '%s'", fileName.c_str());
    return v;
  }

  GModel *m = GModel::current();

  int p = m->getMaxElementaryNumber(0) + 1;
  int l = m->getMaxElementaryNumber(1) + 1;
  int s = m->getMaxElementaryNumber(2) + 1;
  int ll = s, ps = 1;

  SBoundingBox3d bbox = m->bounds();
  double lc = norm(SVector3(bbox.max(), bbox.min())) / 100;
  fprintf(fp, "lc = %g;\n", lc);

  for(GModel::viter vit = m->firstVertex(); vit != m->lastVertex(); vit++)
    (*vit)->writeGEO(fp, "lc");

  for(GModel::eiter eit = m->firstEdge(); eit != m->lastEdge(); eit++)
    (*eit)->writeGEO(fp);

  for(GModel::fiter fit = m->firstFace(); fit != m->lastFace(); fit++){
    (*fit)->writeGEO(fp);
    fprintf(fp, "Delete { Surface {%d}; }\n", (*fit)->tag());

    int sbeg = s;
    int llbeg = ll;

    // compute vertex-to-triangle_barycenter map
    std::map<MVertex*, std::vector<SPoint3> > v2t;
    for(unsigned int i = 0; i < (*fit)->triangles.size(); i++)
      for(int j = 0; j < 3; j++)
        v2t[(*fit)->triangles[i]->getVertex(j)].push_back((*fit)->triangles[i]->barycenter());

    // add boundary vertices in map to get cells "closer" to the boundary
    for(std::map<MVertex*, std::vector<SPoint3> >::iterator it = v2t.begin();
        it != v2t.end(); it++){
      MVertex *v = it->first;
      if(v->onWhat() && v->onWhat()->dim() < 2)
        it->second.push_back(SPoint3(it->first->x(), it->first->y(), it->first->z()));
    }

    for(std::map<MVertex*, std::vector<SPoint3> >::iterator it = v2t.begin();
        it != v2t.end(); it++){
      if(it->second.size() > 2){
        // get barycenter of cell boundary points and order them
        SPoint3 bc;
        for(unsigned int i = 0; i < it->second.size(); i++)
          bc += it->second[i];
        bc *= 1. / (double)it->second.size();
        compareAngle comp(bc);
        std::sort(it->second.begin(), it->second.end(), comp);
        // shrink cells
        if(shrink){
          for(unsigned int i = 0; i < it->second.size(); i++){
            double dir[3] = {it->second[i].x() - bc.x(),
                             it->second[i].y() - bc.y(),
                             it->second[i].z() - bc.z()};
            it->second[i][0] -= shrink * dir[0];
            it->second[i][1] -= shrink * dir[1];
            it->second[i][2] -= shrink * dir[2];
          }
        }
        // create b-spline bounded surface for each cell
        int nump = it->second.size();
        for(int i = 0; i < nump; i++){
          SPoint3 &b(it->second[i]);
          fprintf(fp, "Point(%d) = {%.16g, %.16g, %.16g, lc};\n", p++, b.x(), b.y(), b.z());
        }
        fprintf(fp, "BSpline(%d) = {", l++);
        for(int i = nump - 1; i >= 0; i--)
          fprintf(fp, "%d,", p - i - 1);
        fprintf(fp, "%d};\n", p - nump);
        fprintf(fp, "Line Loop(%d) = {%d};\n", ll++, l - 1);
        fprintf(fp, "Plane Surface(%d) = {%d};\n", s++, ll - 1);
      }
    }
    fprintf(fp, "Physical Surface(%d) = {%d:%d};\n", ps++, sbeg, s - 1);

    fprintf(fp, "Plane Surface(%d) = {%d, %d:%d};\n", s++, (*fit)->tag(), llbeg, ll - 1);
    fprintf(fp, "Physical Surface(%d) = {%d};\n", ps++, s - 1);
  }

  fclose(fp);

  return v;
}