PrusaSlicer-NonPlainar/src/libslic3r/TriangleMesh.hpp

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#ifndef slic3r_TriangleMesh_hpp_
#define slic3r_TriangleMesh_hpp_
#include "libslic3r.h"
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#include <admesh/stl.h>
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#include <functional>
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#include <vector>
#include <boost/thread.hpp>
#include "BoundingBox.hpp"
#include "Line.hpp"
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#include "Point.hpp"
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#include "Polygon.hpp"
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#include "ExPolygon.hpp"
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namespace Slic3r {
class TriangleMesh;
class TriangleMeshSlicer;
typedef std::vector<TriangleMesh*> TriangleMeshPtrs;
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class TriangleMesh
{
public:
TriangleMesh() : repaired(false) { stl_initialize(&this->stl); }
TriangleMesh(const Pointf3s &points, const std::vector<Vec3crd> &facets);
TriangleMesh(const TriangleMesh &other) : repaired(false) { stl_initialize(&this->stl); *this = other; }
TriangleMesh(TriangleMesh &&other) : repaired(false) { stl_initialize(&this->stl); this->swap(other); }
~TriangleMesh() { clear(); }
TriangleMesh& operator=(const TriangleMesh &other);
TriangleMesh& operator=(TriangleMesh &&other) { this->swap(other); return *this; }
void clear() { stl_close(&this->stl); this->repaired = false; }
void swap(TriangleMesh &other) { std::swap(this->stl, other.stl); std::swap(this->repaired, other.repaired); }
void ReadSTLFile(const char* input_file) { stl_open(&stl, input_file); }
void write_ascii(const char* output_file) { stl_write_ascii(&this->stl, output_file, ""); }
void write_binary(const char* output_file) { stl_write_binary(&this->stl, output_file, ""); }
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void repair();
float volume();
void check_topology();
bool is_manifold() const { return this->stl.stats.connected_facets_3_edge == (int)this->stl.stats.number_of_facets; }
void WriteOBJFile(const char* output_file);
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void scale(float factor);
void scale(const Vec3d &versor);
void translate(float x, float y, float z);
void translate(const Vec3f &displacement);
void rotate(float angle, const Axis &axis);
void rotate(float angle, const Vec3d& axis);
void rotate_x(float angle) { this->rotate(angle, X); }
void rotate_y(float angle) { this->rotate(angle, Y); }
void rotate_z(float angle) { this->rotate(angle, Z); }
void mirror(const Axis &axis);
void mirror_x() { this->mirror(X); }
void mirror_y() { this->mirror(Y); }
void mirror_z() { this->mirror(Z); }
void transform(const Transform3d& t, bool fix_left_handed = false);
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void align_to_origin();
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void rotate(double angle, Point* center);
TriangleMeshPtrs split() const;
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void merge(const TriangleMesh &mesh);
ExPolygons horizontal_projection() const;
const float* first_vertex() const { return this->stl.facet_start ? &this->stl.facet_start->vertex[0](0) : nullptr; }
// 2D convex hull of a 3D mesh projected into the Z=0 plane.
Polygon convex_hull();
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BoundingBoxf3 bounding_box() const;
// Returns the bbox of this TriangleMesh transformed by the given transformation
BoundingBoxf3 transformed_bounding_box(const Transform3d &trafo) const;
// Returns the convex hull of this TriangleMesh
TriangleMesh convex_hull_3d() const;
void reset_repair_stats();
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bool needed_repair() const;
size_t facets_count() const { return this->stl.stats.number_of_facets; }
bool empty() const { return this->facets_count() == 0; }
bool is_splittable() const;
stl_file stl;
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bool repaired;
private:
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void require_shared_vertices();
std::deque<uint32_t> find_unvisited_neighbors(std::vector<unsigned char> &facet_visited) const;
friend class TriangleMeshSlicer;
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};
enum FacetEdgeType {
// A general case, the cutting plane intersect a face at two different edges.
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feGeneral,
// Two vertices are aligned with the cutting plane, the third vertex is below the cutting plane.
feTop,
// Two vertices are aligned with the cutting plane, the third vertex is above the cutting plane.
feBottom,
// All three vertices of a face are aligned with the cutting plane.
feHorizontal
};
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class IntersectionReference
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{
public:
IntersectionReference() : point_id(-1), edge_id(-1) {};
IntersectionReference(int point_id, int edge_id) : point_id(point_id), edge_id(edge_id) {}
// Where is this intersection point located? On mesh vertex or mesh edge?
// Only one of the following will be set, the other will remain set to -1.
// Index of the mesh vertex.
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int point_id;
// Index of the mesh edge.
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int edge_id;
};
class IntersectionPoint : public Point, public IntersectionReference
{
public:
IntersectionPoint() {};
IntersectionPoint(int point_id, int edge_id, const Point &pt) : IntersectionReference(point_id, edge_id), Point(pt) {}
IntersectionPoint(const IntersectionReference &ir, const Point &pt) : IntersectionReference(ir), Point(pt) {}
// Inherits coord_t x, y
};
class IntersectionLine : public Line
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{
public:
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IntersectionLine() : a_id(-1), b_id(-1), edge_a_id(-1), edge_b_id(-1), edge_type(feGeneral), flags(0) {}
bool skip() const { return (this->flags & SKIP) != 0; }
void set_skip() { this->flags |= SKIP; }
bool is_seed_candidate() const { return (this->flags & NO_SEED) == 0 && ! this->skip(); }
void set_no_seed(bool set) { if (set) this->flags |= NO_SEED; else this->flags &= ~NO_SEED; }
// Inherits Point a, b
// For each line end point, either {a,b}_id or {a,b}edge_a_id is set, the other is left to -1.
// Vertex indices of the line end points.
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int a_id;
int b_id;
// Source mesh edges of the line end points.
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int edge_a_id;
int edge_b_id;
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// feGeneral, feTop, feBottom, feHorizontal
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FacetEdgeType edge_type;
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// Used by TriangleMeshSlicer::slice() to skip duplicate edges.
enum {
// Triangle edge added, because it has no neighbor.
EDGE0_NO_NEIGHBOR = 0x001,
EDGE1_NO_NEIGHBOR = 0x002,
EDGE2_NO_NEIGHBOR = 0x004,
// Triangle edge added, because it makes a fold with another horizontal edge.
EDGE0_FOLD = 0x010,
EDGE1_FOLD = 0x020,
EDGE2_FOLD = 0x040,
// The edge cannot be a seed of a greedy loop extraction (folds are not safe to become seeds).
NO_SEED = 0x100,
SKIP = 0x200,
};
uint32_t flags;
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};
typedef std::vector<IntersectionLine> IntersectionLines;
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typedef std::vector<IntersectionLine*> IntersectionLinePtrs;
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class TriangleMeshSlicer
{
public:
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typedef std::function<void()> throw_on_cancel_callback_type;
TriangleMeshSlicer() : mesh(nullptr) {}
// Not quite nice, but the constructor and init() methods require non-const mesh pointer to be able to call mesh->require_shared_vertices()
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TriangleMeshSlicer(TriangleMesh* mesh) { this->init(mesh, [](){}); }
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void init(TriangleMesh *mesh, throw_on_cancel_callback_type throw_on_cancel);
void slice(const std::vector<float> &z, std::vector<Polygons>* layers, throw_on_cancel_callback_type throw_on_cancel) const;
void slice(const std::vector<float> &z, const float closing_radius, std::vector<ExPolygons>* layers, throw_on_cancel_callback_type throw_on_cancel) const;
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enum FacetSliceType {
NoSlice = 0,
Slicing = 1,
Cutting = 2
};
FacetSliceType slice_facet(float slice_z, const stl_facet &facet, const int facet_idx,
const float min_z, const float max_z, IntersectionLine *line_out) const;
void cut(float z, TriangleMesh* upper, TriangleMesh* lower) const;
void set_up_direction(const Vec3f& up);
private:
const TriangleMesh *mesh;
// Map from a facet to an edge index.
std::vector<int> facets_edges;
// Scaled copy of this->mesh->stl.v_shared
std::vector<stl_vertex> v_scaled_shared;
// Quaternion that will be used to rotate every facet before the slicing
Eigen::Quaternion<float, Eigen::DontAlign> m_quaternion;
// Whether or not the above quaterion should be used
bool m_use_quaternion = false;
void _slice_do(size_t facet_idx, std::vector<IntersectionLines>* lines, boost::mutex* lines_mutex, const std::vector<float> &z) const;
void make_loops(std::vector<IntersectionLine> &lines, Polygons* loops) const;
void make_expolygons(const Polygons &loops, const float closing_radius, ExPolygons* slices) const;
void make_expolygons_simple(std::vector<IntersectionLine> &lines, ExPolygons* slices) const;
void make_expolygons(std::vector<IntersectionLine> &lines, const float closing_radius, ExPolygons* slices) const;
};
TriangleMesh make_cube(double x, double y, double z);
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// Generate a TriangleMesh of a cylinder
TriangleMesh make_cylinder(double r, double h, double fa=(2*PI/360));
TriangleMesh make_sphere(double rho, double fa=(2*PI/360));
}
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#endif