PrusaSlicer-NonPlainar/src/libslic3r/SLA/IndexedMesh.cpp

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#include "IndexedMesh.hpp"
#include "Concurrency.hpp"
#include <libslic3r/AABBTreeIndirect.hpp>
#include <libslic3r/TriangleMesh.hpp>
#include <numeric>
#ifdef SLIC3R_HOLE_RAYCASTER
#include <libslic3r/SLA/Hollowing.hpp>
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#endif
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namespace Slic3r {
namespace sla {
class IndexedMesh::AABBImpl {
private:
AABBTreeIndirect::Tree3f m_tree;
public:
void init(const indexed_triangle_set &its)
{
m_tree = AABBTreeIndirect::build_aabb_tree_over_indexed_triangle_set(
its.vertices, its.indices);
}
void intersect_ray(const indexed_triangle_set &its,
const Vec3d & s,
const Vec3d & dir,
igl::Hit & hit)
{
AABBTreeIndirect::intersect_ray_first_hit(its.vertices, its.indices,
m_tree, s, dir, hit);
}
void intersect_ray(const indexed_triangle_set &its,
const Vec3d & s,
const Vec3d & dir,
std::vector<igl::Hit> & hits)
{
AABBTreeIndirect::intersect_ray_all_hits(its.vertices, its.indices,
m_tree, s, dir, hits);
}
double squared_distance(const indexed_triangle_set & its,
const Vec3d & point,
int & i,
Eigen::Matrix<double, 1, 3> &closest)
{
size_t idx_unsigned = 0;
Vec3d closest_vec3d(closest);
double dist =
AABBTreeIndirect::squared_distance_to_indexed_triangle_set(
its.vertices, its.indices, m_tree, point, idx_unsigned,
closest_vec3d);
i = int(idx_unsigned);
closest = closest_vec3d;
return dist;
}
};
template<class M> void IndexedMesh::init(const M &mesh)
{
BoundingBoxf3 bb = bounding_box(mesh);
m_ground_level += bb.min(Z);
// Build the AABB accelaration tree
m_aabb->init(*m_tm);
}
IndexedMesh::IndexedMesh(const indexed_triangle_set& tmesh)
: m_aabb(new AABBImpl()), m_tm(&tmesh)
{
init(tmesh);
}
IndexedMesh::IndexedMesh(const TriangleMesh &mesh)
: m_aabb(new AABBImpl()), m_tm(&mesh.its)
{
init(mesh);
}
IndexedMesh::~IndexedMesh() {}
IndexedMesh::IndexedMesh(const IndexedMesh &other):
m_tm(other.m_tm), m_ground_level(other.m_ground_level),
m_aabb( new AABBImpl(*other.m_aabb) ) {}
IndexedMesh &IndexedMesh::operator=(const IndexedMesh &other)
{
m_tm = other.m_tm;
m_ground_level = other.m_ground_level;
m_aabb.reset(new AABBImpl(*other.m_aabb)); return *this;
}
IndexedMesh &IndexedMesh::operator=(IndexedMesh &&other) = default;
IndexedMesh::IndexedMesh(IndexedMesh &&other) = default;
const std::vector<Vec3f>& IndexedMesh::vertices() const
{
return m_tm->vertices;
}
const std::vector<Vec3i>& IndexedMesh::indices() const
{
return m_tm->indices;
}
const Vec3f& IndexedMesh::vertices(size_t idx) const
{
return m_tm->vertices[idx];
}
const Vec3i& IndexedMesh::indices(size_t idx) const
{
return m_tm->indices[idx];
}
Vec3d IndexedMesh::normal_by_face_id(int face_id) const {
return its_unnormalized_normal(*m_tm, face_id).cast<double>().normalized();
}
IndexedMesh::hit_result
IndexedMesh::query_ray_hit(const Vec3d &s, const Vec3d &dir) const
{
assert(is_approx(dir.norm(), 1.));
igl::Hit hit{-1, -1, 0.f, 0.f, 0.f};
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hit.t = std::numeric_limits<float>::infinity();
#ifdef SLIC3R_HOLE_RAYCASTER
if (! m_holes.empty()) {
// If there are holes, the hit_results will be made by
// query_ray_hits (object) and filter_hits (holes):
return filter_hits(query_ray_hits(s, dir));
}
#endif
m_aabb->intersect_ray(*m_tm, s, dir, hit);
hit_result ret(*this);
ret.m_t = double(hit.t);
ret.m_dir = dir;
ret.m_source = s;
if(!std::isinf(hit.t) && !std::isnan(hit.t)) {
ret.m_normal = this->normal_by_face_id(hit.id);
ret.m_face_id = hit.id;
}
return ret;
}
std::vector<IndexedMesh::hit_result>
IndexedMesh::query_ray_hits(const Vec3d &s, const Vec3d &dir) const
{
std::vector<IndexedMesh::hit_result> outs;
std::vector<igl::Hit> hits;
m_aabb->intersect_ray(*m_tm, s, dir, hits);
// The sort is necessary, the hits are not always sorted.
std::sort(hits.begin(), hits.end(),
[](const igl::Hit& a, const igl::Hit& b) { return a.t < b.t; });
// Remove duplicates. They sometimes appear, for example when the ray is cast
// along an axis of a cube due to floating-point approximations in igl (?)
hits.erase(std::unique(hits.begin(), hits.end(),
[](const igl::Hit& a, const igl::Hit& b)
{ return a.t == b.t; }),
hits.end());
// Convert the igl::Hit into hit_result
outs.reserve(hits.size());
for (const igl::Hit& hit : hits) {
outs.emplace_back(IndexedMesh::hit_result(*this));
outs.back().m_t = double(hit.t);
outs.back().m_dir = dir;
outs.back().m_source = s;
if(!std::isinf(hit.t) && !std::isnan(hit.t)) {
outs.back().m_normal = this->normal_by_face_id(hit.id);
outs.back().m_face_id = hit.id;
}
}
return outs;
}
#ifdef SLIC3R_HOLE_RAYCASTER
IndexedMesh::hit_result IndexedMesh::filter_hits(
const std::vector<IndexedMesh::hit_result>& object_hits) const
{
assert(! m_holes.empty());
hit_result out(*this);
if (object_hits.empty())
return out;
const Vec3d& s = object_hits.front().source();
const Vec3d& dir = object_hits.front().direction();
// A helper struct to save an intersetion with a hole
struct HoleHit {
HoleHit(float t_p, const Vec3d& normal_p, bool entry_p) :
t(t_p), normal(normal_p), entry(entry_p) {}
float t;
Vec3d normal;
bool entry;
};
std::vector<HoleHit> hole_isects;
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hole_isects.reserve(m_holes.size());
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auto sf = s.cast<float>();
auto dirf = dir.cast<float>();
// Collect hits on all holes, preserve information about entry/exit
for (const sla::DrainHole& hole : m_holes) {
std::array<std::pair<float, Vec3d>, 2> isects;
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if (hole.get_intersections(sf, dirf, isects)) {
// Ignore hole hits behind the source
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if (isects[0].first > 0.f) hole_isects.emplace_back(isects[0].first, isects[0].second, true);
if (isects[1].first > 0.f) hole_isects.emplace_back(isects[1].first, isects[1].second, false);
}
}
// Holes can intersect each other, sort the hits by t
std::sort(hole_isects.begin(), hole_isects.end(),
[](const HoleHit& a, const HoleHit& b) { return a.t < b.t; });
// Now inspect the intersections with object and holes, in the order of
// increasing distance. Keep track how deep are we nested in mesh/holes and
// pick the correct intersection.
// This needs to be done twice - first to find out how deep in the structure
// the source is, then to pick the correct intersection.
int hole_nested = 0;
int object_nested = 0;
for (int dry_run=1; dry_run>=0; --dry_run) {
hole_nested = -hole_nested;
object_nested = -object_nested;
bool is_hole = false;
bool is_entry = false;
const HoleHit* next_hole_hit = hole_isects.empty() ? nullptr : &hole_isects.front();
const hit_result* next_mesh_hit = &object_hits.front();
while (next_hole_hit || next_mesh_hit) {
if (next_hole_hit && next_mesh_hit) // still have hole and obj hits
is_hole = (next_hole_hit->t < next_mesh_hit->m_t);
else
is_hole = next_hole_hit; // one or the other ran out
// Is this entry or exit hit?
is_entry = is_hole ? next_hole_hit->entry : ! next_mesh_hit->is_inside();
if (! dry_run) {
if (! is_hole && hole_nested == 0) {
// This is a valid object hit
return *next_mesh_hit;
}
if (is_hole && ! is_entry && object_nested != 0) {
// This holehit is the one we seek
out.m_t = next_hole_hit->t;
out.m_normal = next_hole_hit->normal;
out.m_source = s;
out.m_dir = dir;
return out;
}
}
// Increase/decrease the counter
(is_hole ? hole_nested : object_nested) += (is_entry ? 1 : -1);
// Advance the respective pointer
if (is_hole && next_hole_hit++ == &hole_isects.back())
next_hole_hit = nullptr;
if (! is_hole && next_mesh_hit++ == &object_hits.back())
next_mesh_hit = nullptr;
}
}
// if we got here, the ray ended up in infinity
return out;
}
#endif
double IndexedMesh::squared_distance(const Vec3d &p, int& i, Vec3d& c) const {
double sqdst = 0;
Eigen::Matrix<double, 1, 3> pp = p;
Eigen::Matrix<double, 1, 3> cc;
sqdst = m_aabb->squared_distance(*m_tm, pp, i, cc);
c = cc;
return sqdst;
}
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static bool point_on_edge(const Vec3d& p, const Vec3d& e1, const Vec3d& e2,
double eps = 0.05)
{
using Line3D = Eigen::ParametrizedLine<double, 3>;
auto line = Line3D::Through(e1, e2);
double d = line.distance(p);
return std::abs(d) < eps;
}
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PointSet normals(const PointSet& points,
const IndexedMesh& mesh,
double eps,
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std::function<void()> thr, // throw on cancel
const std::vector<unsigned>& pt_indices)
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{
if (points.rows() == 0 || mesh.vertices().empty() || mesh.indices().empty())
return {};
std::vector<unsigned> range = pt_indices;
if (range.empty()) {
range.resize(size_t(points.rows()), 0);
std::iota(range.begin(), range.end(), 0);
}
PointSet ret(range.size(), 3);
// for (size_t ridx = 0; ridx < range.size(); ++ridx)
ccr::for_each(size_t(0), range.size(),
[&ret, &mesh, &points, thr, eps, &range](size_t ridx) {
thr();
unsigned el = range[ridx];
auto eidx = Eigen::Index(el);
int faceid = 0;
Vec3d p;
mesh.squared_distance(points.row(eidx), faceid, p);
auto trindex = mesh.indices(faceid);
const Vec3d &p1 = mesh.vertices(trindex(0)).cast<double>();
const Vec3d &p2 = mesh.vertices(trindex(1)).cast<double>();
const Vec3d &p3 = mesh.vertices(trindex(2)).cast<double>();
// We should check if the point lies on an edge of the hosting
// triangle. If it does then all the other triangles using the
// same two points have to be searched and the final normal should
// be some kind of aggregation of the participating triangle
// normals. We should also consider the cases where the support
// point lies right on a vertex of its triangle. The procedure is
// the same, get the neighbor triangles and calculate an average
// normal.
// mark the vertex indices of the edge. ia and ib marks and edge
// ic will mark a single vertex.
int ia = -1, ib = -1, ic = -1;
if (std::abs((p - p1).norm()) < eps) {
ic = trindex(0);
} else if (std::abs((p - p2).norm()) < eps) {
ic = trindex(1);
} else if (std::abs((p - p3).norm()) < eps) {
ic = trindex(2);
} else if (point_on_edge(p, p1, p2, eps)) {
ia = trindex(0);
ib = trindex(1);
} else if (point_on_edge(p, p2, p3, eps)) {
ia = trindex(1);
ib = trindex(2);
} else if (point_on_edge(p, p1, p3, eps)) {
ia = trindex(0);
ib = trindex(2);
}
// vector for the neigboring triangles including the detected one.
std::vector<size_t> neigh;
if (ic >= 0) { // The point is right on a vertex of the triangle
for (size_t n = 0; n < mesh.indices().size(); ++n) {
thr();
Vec3i ni = mesh.indices(n);
if ((ni(X) == ic || ni(Y) == ic || ni(Z) == ic))
neigh.emplace_back(n);
}
} else if (ia >= 0 && ib >= 0) { // the point is on and edge
// now get all the neigboring triangles
for (size_t n = 0; n < mesh.indices().size(); ++n) {
thr();
Vec3i ni = mesh.indices(n);
if ((ni(X) == ia || ni(Y) == ia || ni(Z) == ia) &&
(ni(X) == ib || ni(Y) == ib || ni(Z) == ib))
neigh.emplace_back(n);
}
}
// Calculate the normals for the neighboring triangles
std::vector<Vec3d> neighnorms;
neighnorms.reserve(neigh.size());
for (size_t &tri_id : neigh)
neighnorms.emplace_back(mesh.normal_by_face_id(tri_id));
// Throw out duplicates. They would cause trouble with summing. We
// will use std::unique which works on sorted ranges. We will sort
// by the coefficient-wise sum of the normals. It should force the
// same elements to be consecutive.
std::sort(neighnorms.begin(), neighnorms.end(),
[](const Vec3d &v1, const Vec3d &v2) {
return v1.sum() < v2.sum();
});
auto lend = std::unique(neighnorms.begin(), neighnorms.end(),
[](const Vec3d &n1, const Vec3d &n2) {
// Compare normals for equivalence.
// This is controvers stuff.
auto deq = [](double a, double b) {
return std::abs(a - b) < 1e-3;
};
return deq(n1(X), n2(X)) &&
deq(n1(Y), n2(Y)) &&
deq(n1(Z), n2(Z));
});
if (!neighnorms.empty()) { // there were neighbors to count with
// sum up the normals and then normalize the result again.
// This unification seems to be enough.
Vec3d sumnorm(0, 0, 0);
sumnorm = std::accumulate(neighnorms.begin(), lend, sumnorm);
sumnorm.normalize();
ret.row(long(ridx)) = sumnorm;
} else { // point lies safely within its triangle
Eigen::Vector3d U = p2 - p1;
Eigen::Vector3d V = p3 - p1;
ret.row(long(ridx)) = U.cross(V).normalized();
}
});
return ret;
}
}} // namespace Slic3r::sla