Add working version of triangle trimming for hollowed meshes

2021-03-02 18:24:57 +01:00 · 2021-03-02 18:24:57 +01:00 · 1ec154012e
commit 1ec154012e
parent b8c1c13666
1 changed files with 241 additions and 4 deletions
--- a/src/libslic3r/SLA/Hollowing.cpp
+++ b/src/libslic3r/SLA/Hollowing.cpp
@ -29,11 +29,21 @@ inline void _scale(S s, Contour3D &m) { for (auto &p : m.points) p *= s; }
 struct Interior {
    TriangleMesh mesh;
    openvdb::FloatGrid::Ptr gridptr;
    mutable std::optional<openvdb::FloatGrid::ConstAccessor> accessor;
    double closing_distance = 0.;
    double thickness = 0.;
    double voxel_scale = 1.;
-    double nb_in = 3.;
+    double nb_in = 3.;  // narrow band width inwards
-    double nb_out = 3.;
+    double nb_out = 3.; // narrow band width outwards
    // Full narrow band is the sum of the two above values.
    void reset_accessor() const  // This resets the accessor and its cache
    // Not a thread safe call!
    {
        if (gridptr)
            accessor = gridptr->getConstAccessor();
    }
 };
 void InteriorDeleter::operator()(Interior *p)
@ -313,16 +323,243 @@ void hollow_mesh(TriangleMesh &mesh, const Interior &interior, int flags)
 {
    if (mesh.empty() || interior.mesh.empty()) return;
-//    if (flags & hfRemoveInsideTriangles && interior.gridptr)
+    if (flags & hfRemoveInsideTriangles && interior.gridptr)
-//        erase_inside_triangles_2(mesh, interior);
+        remove_inside_triangles(mesh, interior);
    mesh.merge(interior.mesh);
    mesh.require_shared_vertices();
 }
 // Get the distance of p to the interior's zero iso_surface. Interior should
 // have its zero isosurface positioned at offset + closing_distance inwards form
 // the model surface.
 static double get_distance_raw(const Vec3f &p, const Interior &interior)
 {
    assert(interior.gridptr);
    if (!interior.accessor) interior.reset_accessor();
    auto v       = (p * interior.voxel_scale).cast<double>();
    auto grididx = interior.gridptr->transform().worldToIndexCellCentered(
        {v.x(), v.y(), v.z()});
    return interior.accessor->getValue(grididx) ;
 }
 struct TriangleBubble { Vec3f center; double R; };
 // Return the distance of bubble center to the interior boundary or NaN if the
 // triangle is too big to be measured.
 static double get_distance(const TriangleBubble &b, const Interior &interior)
 {
    double R = b.R * interior.voxel_scale;
    double D = get_distance_raw(b.center, interior);
    return (D > 0. && R >= interior.nb_out) ||
           (D < 0. && R >= interior.nb_in)  ||
           ((D - R) < 0. && 2 * R > interior.thickness) ?
                std::nan("") :
                // FIXME: Adding interior.voxel_scale is a compromise supposed
                // to prevent the deletion of the triangles forming the interior
                // itself. This has a side effect that a small portion of the
                // bad triangles will still be visible.
                D - interior.closing_distance /*+ 2 * interior.voxel_scale*/;
 }
 double get_distance(const Vec3f &p, const Interior &interior)
 {
    double d = get_distance_raw(p, interior) - interior.closing_distance;
    return d / interior.voxel_scale;
 }
 // A face that can be divided. Stores the indices into the original mesh if its
 // part of that mesh and the vertices it consists of.
 enum { NEW_FACE = -1};
 struct DivFace {
    Vec3i indx;
    std::array<Vec3f, 3> verts;
    long faceid = NEW_FACE;
    long parent = NEW_FACE;
 };
 // Divide a face recursively and call visitor on all the sub-faces.
 template<class Fn>
 void divide_triangle(const DivFace &face, Fn &&visitor)
 {
    std::array<Vec3f, 3> edges = {(face.verts[0] - face.verts[1]),
                                  (face.verts[1] - face.verts[2]),
                                  (face.verts[2] - face.verts[0])};
    std::array<size_t, 3> edgeidx = {0, 1, 2};
    std::sort(edgeidx.begin(), edgeidx.end(), [&edges](size_t e1, size_t e2) {
        return edges[e1].squaredNorm() > edges[e2].squaredNorm();
    });
    DivFace child1, child2;
    child1.parent   = face.faceid == NEW_FACE ? face.parent : face.faceid;
    child1.indx(0)  = -1;
    child1.indx(1)  = face.indx(edgeidx[1]);
    child1.indx(2)  = face.indx((edgeidx[1] + 1) % 3);
    child1.verts[0] = (face.verts[edgeidx[0]] + face.verts[(edgeidx[0] + 1) % 3]) / 2.;
    child1.verts[1] = face.verts[edgeidx[1]];
    child1.verts[2] = face.verts[(edgeidx[1] + 1) % 3];
    if (visitor(child1))
        divide_triangle(child1, std::forward<Fn>(visitor));
    child2.parent   = face.faceid == NEW_FACE ? face.parent : face.faceid;
    child2.indx(0)  = -1;
    child2.indx(1)  = face.indx(edgeidx[2]);
    child2.indx(2)  = face.indx((edgeidx[2] + 1) % 3);
    child2.verts[0] = child1.verts[0];
    child2.verts[1] = face.verts[edgeidx[2]];
    child2.verts[2] = face.verts[(edgeidx[2] + 1) % 3];
    if (visitor(child2))
        divide_triangle(child2, std::forward<Fn>(visitor));
 }
 void remove_inside_triangles(TriangleMesh &mesh, const Interior &interior)
 {
    enum TrPos { posInside, posTouch, posOutside };
    auto &faces       = mesh.its.indices;
    auto &vertices    = mesh.its.vertices;
    auto bb           = mesh.bounding_box();
    // TODO: Parallel mode not working yet
    using exec_policy = ccr_seq;
    // Info about the needed modifications on the input mesh.
    struct MeshMods {
        // Just a thread safe wrapper for a vector of triangles.
        struct {
            std::vector<std::array<Vec3f, 3>> data;
            exec_policy::SpinningMutex        mutex;
            void emplace_back(const std::array<Vec3f, 3> &pts)
            {
                std::lock_guard lk{mutex};
                data.emplace_back(pts);
            }
            size_t size() const { return data.size(); }
            const std::array<Vec3f, 3>& operator[](size_t idx) const
            {
                return data[idx];
            }
        } new_triangles;
        // A vector of bool for all faces signaling if it needs to be removed
        // or not.
        std::vector<bool> to_remove;
        MeshMods(const TriangleMesh &mesh):
            to_remove(mesh.its.indices.size(), false) {}
        // Number of triangles that need to be removed.
        size_t to_remove_cnt() const
        {
            return std::accumulate(to_remove.begin(), to_remove.end(), size_t(0));
        }
    } mesh_mods{mesh};
    // Must return true if further division of the face is needed.
    auto divfn = [&interior, bb, &mesh_mods](const DivFace &f) {
        BoundingBoxf3 facebb { f.verts.begin(), f.verts.end() };
        // Face is certainly outside the cavity
        if (! facebb.intersects(bb) && f.faceid != NEW_FACE) {
            return false;
        }
        TriangleBubble bubble{facebb.center().cast<float>(), facebb.radius()};
        double D = get_distance(bubble, interior);
        double R = bubble.R * interior.voxel_scale;
        if (std::isnan(D)) // The distance cannot be measured, triangle too big
            return true;
        // Distance of the bubble wall to the interior wall. Negative if the
        // bubble is overlapping with the interior
        double bubble_distance = D - R;
        // The face is crossing the interior or inside, it must be removed and
        // parts of it re-added, that are outside the interior
        if (bubble_distance < 0.) {
            if (f.faceid != NEW_FACE)
                mesh_mods.to_remove[f.faceid] = true;
            if (f.parent != NEW_FACE) // Top parent needs to be removed as well
                mesh_mods.to_remove[f.parent] = true;
            // If the outside part is between the interior end the exterior
            // (inside the wall being invisible), no further division is needed.
            if ((R + D) < interior.thickness)
                return false;
            return true;
        } else if (f.faceid == NEW_FACE) {
            // New face completely outside needs to be re-added.
            mesh_mods.new_triangles.emplace_back(f.verts);
        }
        return false;
    };
    interior.reset_accessor();
    exec_policy::for_each(size_t(0), faces.size(), [&] (size_t face_idx) {
        const Vec3i &face = faces[face_idx];
        std::array<Vec3f, 3> pts =
            { vertices[face(0)], vertices[face(1)], vertices[face(2)] };
        BoundingBoxf3 facebb { pts.begin(), pts.end() };
        // Face is certainly outside the cavity
        if (! facebb.intersects(bb)) return;
        DivFace df{face, pts, long(face_idx)};
        if (divfn(df))
            divide_triangle(df, divfn);
    }, exec_policy::max_concurreny());
    auto new_faces = reserve_vector<Vec3i>(faces.size() +
                                           mesh_mods.new_triangles.size());
    for (size_t face_idx = 0; face_idx < faces.size(); ++face_idx) {
        if (!mesh_mods.to_remove[face_idx])
            new_faces.emplace_back(faces[face_idx]);
    }
    for(size_t i = 0; i < mesh_mods.new_triangles.size(); ++i) {
        size_t o = vertices.size();
        vertices.emplace_back(mesh_mods.new_triangles[i][0]);
        vertices.emplace_back(mesh_mods.new_triangles[i][1]);
        vertices.emplace_back(mesh_mods.new_triangles[i][2]);
        new_faces.emplace_back(int(o), int(o + 1), int(o + 2));
    }
    BOOST_LOG_TRIVIAL(info)
            << "Trimming: " << mesh_mods.to_remove_cnt() << " triangles removed";
    BOOST_LOG_TRIVIAL(info)
            << "Trimming: " << mesh_mods.new_triangles.size() << " triangles added";
    faces.swap(new_faces);
    new_faces = {};
    mesh = TriangleMesh{mesh.its};
    mesh.repaired = true;
    mesh.require_shared_vertices();
 }
 }} // namespace Slic3r::sla