PrusaSlicer-NonPlainar/src/libslic3r/SLA/SLASupportTree.hpp

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#ifndef SLASUPPORTTREE_HPP
#define SLASUPPORTTREE_HPP
#include <vector>
#include <array>
#include <cstdint>
#include <memory>
#include <Eigen/Geometry>
namespace Slic3r {
// Needed types from Point.hpp
typedef int32_t coord_t;
typedef Eigen::Matrix<double, 3, 1, Eigen::DontAlign> Vec3d;
typedef Eigen::Matrix<float, 3, 1, Eigen::DontAlign> Vec3f;
typedef Eigen::Matrix<coord_t, 3, 1, Eigen::DontAlign> Vec3crd;
typedef std::vector<Vec3d> Pointf3s;
typedef std::vector<Vec3crd> Points3;
class TriangleMesh;
class Model;
class ModelInstance;
class ExPolygon;
using SliceLayer = std::vector<ExPolygon>;
using SlicedSupports = std::vector<SliceLayer>;
namespace sla {
struct SupportConfig {
// Radius in mm of the pointing side of the head.
double head_front_radius_mm = 0.2;
// Radius of the back side of the 3d arrow.
double head_back_radius_mm = 0.5;
// Width in mm from the back sphere center to the front sphere center.
double head_width_mm = 1.0;
// Radius in mm of the support pillars.
// Warning: this value will be at most 65% of head_back_radius_mm
double pillar_radius_mm = 0.8;
// Radius in mm of the pillar base.
double base_radius_mm = 2.0;
// The height of the pillar base cone in mm.
double base_height_mm = 1.0;
// The default angle for connecting support sticks and junctions.
double tilt = M_PI/4;
// The max length of a bridge in mm
double max_bridge_length_mm = 15.0;
};
/// A Control structure for the support calculation. Consists of the status
/// indicator callback and the stop condition predicate.
struct Controller {
std::function<void(unsigned, const std::string&)> statuscb =
[](unsigned, const std::string&){};
std::function<bool(void)> stopcondition = [](){ return false; };
};
/* ************************************************************************** */
/* TODO: May not be needed: */
/* ************************************************************************** */
void create_head(TriangleMesh&, double r1_mm, double r2_mm, double width_mm);
/// Add support volumes to the model directly
void add_sla_supports(Model& model, const SupportConfig& cfg = {},
const Controller& ctl = {});
/* ************************************************************************** */
using PointSet = Eigen::MatrixXd;
struct EigenMesh3D;
/// Just a wrapper to the runtime error to be recognizable in try blocks
class SLASupportsStoppedException: public std::runtime_error {
public:
using std::runtime_error::runtime_error;
SLASupportsStoppedException(): std::runtime_error("") {}
};
/// The class containing mesh data for the generated supports.
class SLASupportTree {
class Impl;
std::unique_ptr<Impl> m_impl;
Impl& get() { return *m_impl; }
const Impl& get() const { return *m_impl; }
friend void add_sla_supports(Model&,
const SupportConfig&,
const Controller&);
/// Generate the 3D supports for a model intended for SLA print.
bool generate(const PointSet& pts,
const EigenMesh3D& mesh,
const SupportConfig& cfg = {},
const Controller& ctl = {});
public:
// Constructors will throw if the stop condition becomes true.
SLASupportTree(const Model& model,
const SupportConfig& cfg = {},
const Controller& ctl = {});
SLASupportTree(const PointSet& pts,
const EigenMesh3D& em,
const SupportConfig& cfg = {},
const Controller& ctl = {});
SLASupportTree(const SLASupportTree&);
SLASupportTree& operator=(const SLASupportTree&);
~SLASupportTree();
/// Get the whole mesh united into the output TriangleMesh
void merged_mesh(TriangleMesh& outmesh) const;
/// Get the sliced 2d layers of the support geometry.
SlicedSupports slice() const;
};
}
}
#endif // SLASUPPORTTREE_HPP