Example #1
0
// InsertVertex in the paper
static void insert_cavity_vertex_helper(MutableTriangleTopology& mesh, RawField<const Perturbed2,VertexId> X,
                                        RawField<bool,VertexId> marked, const HalfedgeId vw) {
  // If wv is a boundary edge, or we're already Delaunay and properly oriented, we're done
  const auto wv = mesh.reverse(vw);
  if (mesh.is_boundary(wv))
    return;
  const auto u = mesh.opposite(vw),
             v = mesh.src(vw),
             w = mesh.dst(vw),
             x = mesh.opposite(wv);
  const auto Xu = X[u],
             Xv = X[v],
             Xw = X[w],
             Xx = X[x];
  const bool in = incircle(Xu,Xv,Xw,Xx);
  if (!in && triangle_oriented(Xu,Xv,Xw))
    return;

  // Flip edge and recurse
  const auto xu = mesh.flip_edge(wv);
  assert(mesh.vertices(xu)==vec(x,u));
  const auto vx = mesh.prev(xu),
             xw = mesh.next(mesh.reverse(xu)); // Grab this now before the recursive call changes uvx
  insert_cavity_vertex_helper(mesh,X,marked,vx),
  insert_cavity_vertex_helper(mesh,X,marked,xw);
  if (!in)
    marked[u] = marked[v] = marked[w] = marked[x] = true;
}
Example #2
0
GEODE_NEVER_INLINE static void add_constraint_edges(MutableTriangleTopology& mesh, RawField<const EV,VertexId> X,
                                                    RawArray<const Vector<int,2>> edges, const bool validate) {
  if (!edges.size())
    return;
  IntervalScope scope;
  Hashtable<Vector<VertexId,2>> constrained;
  Array<VertexId> left_cavity, right_cavity; // List of vertices for both cavities
  const auto random = new_<Random>(key+7);
  for (int i=0;i<edges.size();i++) {
    // Randomly choose an edge to ensure optimal time complexity
    const auto edge = edges[int(random_permute(edges.size(),key+5,i))].sorted();
    auto v0 = VertexId(edge.x),
         v1 = VertexId(edge.y);
    const auto vs = vec(v0,v1);
    GEODE_ASSERT(mesh.valid(v0) && mesh.valid(v1));

    {
      // Check if the edge already exists in the triangulation.  To ensure optimal complexity,
      // we loop around both vertices interleaved so that our time is O(min(degree(v0),degree(v1))).
      const auto s0 = mesh.halfedge(v0),
                 s1 = mesh.halfedge(v1);
      {
        auto e0 = s0,
             e1 = s1;
        do {
          if (mesh.dst(e0)==v1 || mesh.dst(e1)==v0)
            goto success; // The edge already exists, so there's nothing to be done.
          e0 = mesh.left(e0);
          e1 = mesh.left(e1);
        } while (e0!=s0 && e1!=s1);
      }

      // Find a triangle touching v0 or v1 containing part of the v0-v1 segment.
      // As above, we loop around both vertices interleaved.
      auto e0 = s0;
      {
        auto e1 = s1;
        if (mesh.is_boundary(e0)) e0 = mesh.left(e0);
        if (mesh.is_boundary(e1)) e1 = mesh.left(e1);
        const auto x0 = Perturbed2(v0.id,X[v0]),
                   x1 = Perturbed2(v1.id,X[v1]);
        const auto e0d = mesh.dst(e0),
                   e1d = mesh.dst(e1);
        bool e0o = triangle_oriented(x0,Perturbed2(e0d.id,X[e0d]),x1),
             e1o = triangle_oriented(x1,Perturbed2(e1d.id,X[e1d]),x0);
        for (;;) { // No need to check for an end condition, since we're guaranteed to terminate
          const auto n0 = mesh.left(e0),
                     n1 = mesh.left(e1);
          const auto n0d = mesh.dst(n0),
                     n1d = mesh.dst(n1);
          const bool n0o = triangle_oriented(x0,Perturbed2(n0d.id,X[n0d]),x1),
                     n1o = triangle_oriented(x1,Perturbed2(n1d.id,X[n1d]),x0);
          if (e0o && !n0o)
            break;
          if (e1o && !n1o) {
            // Swap v0 with v1 and e0 with e1 so that our ray starts at v0
            swap(v0,v1);
            swap(e0,e1);
            break;
          }
          e0 = n0;
          e1 = n1;
          e0o = n0o;
          e1o = n1o;
        }
      }

      // If we only need to walk one step, the retriangulation is a single edge flip
      auto cut = mesh.reverse(mesh.next(e0));
      if (mesh.dst(mesh.next(cut))==v1) {
        if (constrained.contains(vec(mesh.src(cut),mesh.dst(cut)).sorted()))
          throw DelaunayConstraintConflict(vec(v0.id,v1.id),vec(mesh.src(cut).id,mesh.dst(cut).id));
        cut = mesh.flip_edge(cut);
        goto success;
      }

      // Walk from v0 to v1, collecting the two cavities.
      const auto x0 = Perturbed2(v0.id,X[v0]),
                 x1 = Perturbed2(v1.id,X[v1]);
      right_cavity.copy(vec(v0,mesh.dst(cut)));
      left_cavity .copy(vec(v0,mesh.src(cut)));
      mesh.erase(mesh.face(e0));
      for (;;) {
        if (constrained.contains(vec(mesh.src(cut),mesh.dst(cut)).sorted()))
          throw DelaunayConstraintConflict(vec(v0.id,v1.id),vec(mesh.src(cut).id,mesh.dst(cut).id));
        const auto n = mesh.reverse(mesh.next(cut)),
                   p = mesh.reverse(mesh.prev(cut));
        const auto v = mesh.src(n);
        mesh.erase(mesh.face(cut));
        if (v == v1) {
          left_cavity.append(v);
          right_cavity.append(v);
          break;
        } else if (triangle_oriented(x0,x1,Perturbed2(v.id,X[v]))) {
          left_cavity.append(v);
          cut = n;
        } else {
          right_cavity.append(v);
          cut = p;
        }
      }

      // Retriangulate both cavities
      left_cavity.reverse();
      cavity_delaunay(mesh,X,left_cavity,random),
      cavity_delaunay(mesh,X,right_cavity,random);
    }
    success:
    constrained.set(vs);
  }

  // If desired, check that the final mesh is constrained Delaunay
  if (validate)
    assert_delaunay("constrained delaunay validate: ",mesh,X,constrained);
}