PrusaSlicer-NonPlainar/src/libslic3r/Model.cpp

#include "Model.hpp"
#include "Geometry.hpp"

#include "Format/AMF.hpp"
#include "Format/OBJ.hpp"
#include "Format/PRUS.hpp"
#include "Format/STL.hpp"
#include "Format/3mf.hpp"

#include <float.h>

#include <boost/algorithm/string/predicate.hpp>
#include <boost/filesystem.hpp>
#include <boost/nowide/iostream.hpp>
#include <boost/algorithm/string/replace.hpp>

#include "SVG.hpp"
#include <Eigen/Dense>

namespace Slic3r {

unsigned int Model::s_auto_extruder_id = 1;

ModelID ModelBase::s_last_id = 0;

Model::Model(const Model &rhs)
{
    *this = rhs;
}

Model& Model::operator=(const Model &rhs)
{
    m_id = rhs.m_id;
    // copy materials
    for (const auto &m : rhs.materials)
        this->add_material(m.first, *m.second);
    // copy objects
    this->objects.reserve(rhs.objects.size());
    for (const ModelObject *o : rhs.objects)
        this->add_object(*o, true);
    return *this;
}

Model Model::read_from_file(const std::string &input_file, DynamicPrintConfig *config, bool add_default_instances)
{
    Model model;

    DynamicPrintConfig temp_config;
    if (config == nullptr)
        config = &temp_config;

    bool result = false;
    if (boost::algorithm::iends_with(input_file, ".stl"))
        result = load_stl(input_file.c_str(), &model);
    else if (boost::algorithm::iends_with(input_file, ".obj"))
        result = load_obj(input_file.c_str(), &model);
    else if (!boost::algorithm::iends_with(input_file, ".zip.amf") && (boost::algorithm::iends_with(input_file, ".amf") ||
        boost::algorithm::iends_with(input_file, ".amf.xml")))
        result = load_amf(input_file.c_str(), config, &model);
    else if (boost::algorithm::iends_with(input_file, ".3mf"))
        result = load_3mf(input_file.c_str(), config, &model);
    else if (boost::algorithm::iends_with(input_file, ".prusa"))
        result = load_prus(input_file.c_str(), &model);
    else
        throw std::runtime_error("Unknown file format. Input file must have .stl, .obj, .amf(.xml) or .prusa extension.");

    if (! result)
        throw std::runtime_error("Loading of a model file failed.");

    if (model.objects.empty())
        throw std::runtime_error("The supplied file couldn't be read because it's empty");
    
    for (ModelObject *o : model.objects)
        o->input_file = input_file;
    
    if (add_default_instances)
        model.add_default_instances();

    return model;
}

Model Model::read_from_archive(const std::string &input_file, DynamicPrintConfig *config, bool add_default_instances)
{
    Model model;

    bool result = false;
    if (boost::algorithm::iends_with(input_file, ".3mf"))
        result = load_3mf(input_file.c_str(), config, &model);
    else if (boost::algorithm::iends_with(input_file, ".zip.amf"))
        result = load_amf(input_file.c_str(), config, &model);
    else
        throw std::runtime_error("Unknown file format. Input file must have .3mf or .zip.amf extension.");

    if (!result)
        throw std::runtime_error("Loading of a model file failed.");

    if (model.objects.empty())
        throw std::runtime_error("The supplied file couldn't be read because it's empty");

    for (ModelObject *o : model.objects)
    {
        if (boost::algorithm::iends_with(input_file, ".zip.amf"))
        {
            // we remove the .zip part of the extension to avoid it be added to filenames when exporting
            o->input_file = boost::ireplace_last_copy(input_file, ".zip.", ".");
        }
        else
            o->input_file = input_file;
    }

    if (add_default_instances)
        model.add_default_instances();

    return model;
}

void Model::repair()
{
    for (ModelObject *o : this->objects)
        o->repair();
}

ModelObject* Model::add_object()
{
    this->objects.emplace_back(new ModelObject(this));
    return this->objects.back();
}

ModelObject* Model::add_object(const char *name, const char *path, const TriangleMesh &mesh)
{
    ModelObject* new_object = new ModelObject(this);
    this->objects.push_back(new_object);
    new_object->name = name;
    new_object->input_file = path;
    ModelVolume *new_volume = new_object->add_volume(mesh);
    new_volume->name = name;
    new_object->invalidate_bounding_box();
    return new_object;
}

ModelObject* Model::add_object(const char *name, const char *path, TriangleMesh &&mesh)
{
    ModelObject* new_object = new ModelObject(this);
    this->objects.push_back(new_object);
    new_object->name = name;
    new_object->input_file = path;
    ModelVolume *new_volume = new_object->add_volume(std::move(mesh));
    new_volume->name = name;
    new_object->invalidate_bounding_box();
    return new_object;
}

ModelObject* Model::add_object(const ModelObject &other, bool copy_volumes)
{
    ModelObject* new_object = new ModelObject(this, other, copy_volumes);
    this->objects.push_back(new_object);
    return new_object;
}

void Model::delete_object(size_t idx)
{
    ModelObjectPtrs::iterator i = this->objects.begin() + idx;
    delete *i;
    this->objects.erase(i);
}

void Model::delete_object(ModelObject* object)
{
    if (object == nullptr)
        return;

    for (ModelObjectPtrs::iterator it = objects.begin(); it != objects.end(); ++it)
    {
        ModelObject* obj = *it;
        if (obj == object)
        {
            delete obj;
            objects.erase(it);
            return;
        }
    }
}

void Model::clear_objects()
{
    for (ModelObject *o : this->objects)
        delete o;
    this->objects.clear();
}

void Model::delete_material(t_model_material_id material_id)
{
    ModelMaterialMap::iterator i = this->materials.find(material_id);
    if (i != this->materials.end()) {
        delete i->second;
        this->materials.erase(i);
    }
}

void Model::clear_materials()
{
    for (auto &m : this->materials)
        delete m.second;
    this->materials.clear();
}

ModelMaterial* Model::add_material(t_model_material_id material_id)
{
    ModelMaterial* material = this->get_material(material_id);
    if (material == nullptr)
        material = this->materials[material_id] = new ModelMaterial(this);
    return material;
}

ModelMaterial* Model::add_material(t_model_material_id material_id, const ModelMaterial &other)
{
    // delete existing material if any
    ModelMaterial* material = this->get_material(material_id);
    delete material;
    // set new material
    material = new ModelMaterial(this, other);
    this->materials[material_id] = material;
    return material;
}

// makes sure all objects have at least one instance
bool Model::add_default_instances()
{
    // apply a default position to all objects not having one
    for (ModelObject *o : this->objects)
        if (o->instances.empty())
            o->add_instance();
    return true;
}

// this returns the bounding box of the *transformed* instances
BoundingBoxf3 Model::bounding_box() const
{
    BoundingBoxf3 bb;
    for (ModelObject *o : this->objects)
        bb.merge(o->bounding_box());
    return bb;
}

unsigned int Model::update_print_volume_state(const BoundingBoxf3 &print_volume) 
{
    unsigned int num_printable = 0;
    for (ModelObject *model_object : this->objects)
        num_printable += model_object->check_instances_print_volume_state(print_volume);
    return num_printable;
}

void Model::center_instances_around_point(const Vec2d &point)
{
    BoundingBoxf3 bb;
    for (ModelObject *o : this->objects)
        for (size_t i = 0; i < o->instances.size(); ++ i)
            bb.merge(o->instance_bounding_box(i, false));

    Vec2d shift2 = point - to_2d(bb.center());
    Vec3d shift3 = Vec3d(shift2(0), shift2(1), 0.0);
    for (ModelObject *o : this->objects) {
        for (ModelInstance *i : o->instances)
            i->set_offset(i->get_offset() + shift3);
        o->invalidate_bounding_box();
    }
}

// flattens everything to a single mesh
TriangleMesh Model::mesh() const
{
    TriangleMesh mesh;
    for (const ModelObject *o : this->objects)
        mesh.merge(o->mesh());
    return mesh;
}

static bool _arrange(const Pointfs &sizes, coordf_t dist, const BoundingBoxf* bb, Pointfs &out)
{
    if (sizes.empty())
        // return if the list is empty or the following call to BoundingBoxf constructor will lead to a crash
        return true;

    // we supply unscaled data to arrange()
    bool result = Slic3r::Geometry::arrange(
        sizes.size(),               // number of parts
        BoundingBoxf(sizes).max,    // width and height of a single cell
        dist,                       // distance between cells
        bb,                         // bounding box of the area to fill
        out                         // output positions
    );

    if (!result && bb != nullptr) {
        // Try to arrange again ignoring bb
        result = Slic3r::Geometry::arrange(
            sizes.size(),               // number of parts
            BoundingBoxf(sizes).max,    // width and height of a single cell
            dist,                       // distance between cells
            nullptr,                    // bounding box of the area to fill
            out                         // output positions
        );
    }
    
    return result;
}

/*  arrange objects preserving their instance count
    but altering their instance positions */
bool Model::arrange_objects(coordf_t dist, const BoundingBoxf* bb)
{
    // get the (transformed) size of each instance so that we take
    // into account their different transformations when packing
    Pointfs instance_sizes;
    Pointfs instance_centers;
    for (const ModelObject *o : this->objects)
        for (size_t i = 0; i < o->instances.size(); ++ i) {
            // an accurate snug bounding box around the transformed mesh.
            BoundingBoxf3 bbox(o->instance_bounding_box(i, true));
            instance_sizes.emplace_back(to_2d(bbox.size()));
            instance_centers.emplace_back(to_2d(bbox.center()));
        }

    Pointfs positions;
    if (! _arrange(instance_sizes, dist, bb, positions))
        return false;

    size_t idx = 0;
    for (ModelObject *o : this->objects) {
        for (ModelInstance *i : o->instances) {
            Vec2d offset_xy = positions[idx] - instance_centers[idx];
            i->set_offset(Vec3d(offset_xy(0), offset_xy(1), i->get_offset(Z)));
            ++idx;
        }
        o->invalidate_bounding_box();
    }

    return true;
}

// Duplicate the entire model preserving instance relative positions.
void Model::duplicate(size_t copies_num, coordf_t dist, const BoundingBoxf* bb)
{
    Pointfs model_sizes(copies_num-1, to_2d(this->bounding_box().size()));
    Pointfs positions;
    if (! _arrange(model_sizes, dist, bb, positions))
        throw std::invalid_argument("Cannot duplicate part as the resulting objects would not fit on the print bed.\n");
    
    // note that this will leave the object count unaltered
    
    for (ModelObject *o : this->objects) {
        // make a copy of the pointers in order to avoid recursion when appending their copies
        ModelInstancePtrs instances = o->instances;
        for (const ModelInstance *i : instances) {
            for (const Vec2d &pos : positions) {
                ModelInstance *instance = o->add_instance(*i);
                instance->set_offset(instance->get_offset() + Vec3d(pos(0), pos(1), 0.0));
            }
        }
        o->invalidate_bounding_box();
    }
}

/*  this will append more instances to each object
    and then automatically rearrange everything */
void Model::duplicate_objects(size_t copies_num, coordf_t dist, const BoundingBoxf* bb)
{
    for (ModelObject *o : this->objects) {
        // make a copy of the pointers in order to avoid recursion when appending their copies
        ModelInstancePtrs instances = o->instances;
        for (const ModelInstance *i : instances)
            for (size_t k = 2; k <= copies_num; ++ k)
                o->add_instance(*i);
    }
    
    this->arrange_objects(dist, bb);
}

void Model::duplicate_objects_grid(size_t x, size_t y, coordf_t dist)
{
    if (this->objects.size() > 1) throw "Grid duplication is not supported with multiple objects";
    if (this->objects.empty()) throw "No objects!";

    ModelObject* object = this->objects.front();
    object->clear_instances();

    Vec3d ext_size = object->bounding_box().size() + dist * Vec3d::Ones();

    for (size_t x_copy = 1; x_copy <= x; ++x_copy) {
        for (size_t y_copy = 1; y_copy <= y; ++y_copy) {
            ModelInstance* instance = object->add_instance();
            instance->set_offset(Vec3d(ext_size(0) * (double)(x_copy - 1), ext_size(1) * (double)(y_copy - 1), 0.0));
        }
    }
}

bool Model::looks_like_multipart_object() const
{
    if (this->objects.size() <= 1)
        return false;
    double zmin = std::numeric_limits<double>::max();
    for (const ModelObject *obj : this->objects) {
        if (obj->volumes.size() > 1 || obj->config.keys().size() > 1)
            return false;
        for (const ModelVolume *vol : obj->volumes) {
            double zmin_this = vol->mesh.bounding_box().min(2);
            if (zmin == std::numeric_limits<double>::max())
                zmin = zmin_this;
            else if (std::abs(zmin - zmin_this) > EPSILON)
                // The volumes don't share zmin.
                return true;
        }
    }
    return false;
}

void Model::convert_multipart_object(unsigned int max_extruders)
{
    if (this->objects.empty())
        return;
    
    ModelObject* object = new ModelObject(this);
    object->input_file = this->objects.front()->input_file;
    object->name = this->objects.front()->name;

    reset_auto_extruder_id();

    for (const ModelObject* o : this->objects)
        for (const ModelVolume* v : o->volumes)
        {
            ModelVolume* new_v = object->add_volume(*v);
            if (new_v != nullptr)
            {
                new_v->name = o->name;
                new_v->config.set_deserialize("extruder", get_auto_extruder_id_as_string(max_extruders));
            }
        }

    for (const ModelInstance* i : this->objects.front()->instances)
        object->add_instance(*i);
    
    this->clear_objects();
    this->objects.push_back(object);
}

void Model::adjust_min_z()
{
    if (objects.empty())
        return;

    if (bounding_box().min(2) < 0.0)
    {
        for (ModelObject* obj : objects)
        {
            if (obj != nullptr)
            {
                coordf_t obj_min_z = obj->bounding_box().min(2);
                if (obj_min_z < 0.0)
                    obj->translate(0.0, 0.0, -obj_min_z);
            }
        }
    }
}

unsigned int Model::get_auto_extruder_id(unsigned int max_extruders)
{
    unsigned int id = s_auto_extruder_id;

    if (++s_auto_extruder_id > max_extruders)
        reset_auto_extruder_id();

    return id;
}

std::string Model::get_auto_extruder_id_as_string(unsigned int max_extruders)
{
    char str_extruder[64];
    sprintf(str_extruder, "%ud", get_auto_extruder_id(max_extruders));
    return str_extruder;
}

void Model::reset_auto_extruder_id()
{
    s_auto_extruder_id = 1;
}

ModelObject::ModelObject(Model *model, const ModelObject &rhs, bool copy_volumes) :
    m_model(model)
{
    this->assign(&rhs, copy_volumes);
}

ModelObject::~ModelObject()
{
    this->clear_volumes();
    this->clear_instances();
}

// Clone this ModelObject including its volumes and instances, keep the IDs of the copies equal to the original.
// Called by Print::apply() to clone the Model / ModelObject hierarchy to the back end for background processing.
ModelObject* ModelObject::clone(Model *parent)
{
    return new ModelObject(parent, *this, true);
}

ModelObject& ModelObject::assign(const ModelObject *rhs, bool copy_volumes)
{ 
    m_id                        = rhs->m_id;
    name                        = rhs->name;
    input_file                  = rhs->input_file;
    config                      = rhs->config;
    sla_support_points          = rhs->sla_support_points;
    layer_height_ranges         = rhs->layer_height_ranges;
    layer_height_profile        = rhs->layer_height_profile;
    layer_height_profile_valid  = rhs->layer_height_profile_valid;
    origin_translation          = rhs->origin_translation;
    m_bounding_box              = rhs->m_bounding_box;
    m_bounding_box_valid        = rhs->m_bounding_box_valid;

    volumes.clear();
    instances.clear();
    if (copy_volumes) {
        this->volumes.reserve(rhs->volumes.size());
        for (ModelVolume *model_volume : rhs->volumes)
            this->add_volume(*model_volume);
        this->instances.reserve(rhs->instances.size());
        for (const ModelInstance *model_instance : rhs->instances)
            this->add_instance(*model_instance);
    }

    return *this;
}

ModelVolume* ModelObject::add_volume(const TriangleMesh &mesh)
{
    ModelVolume* v = new ModelVolume(this, mesh);
    this->volumes.push_back(v);
    this->invalidate_bounding_box();
    return v;
}

ModelVolume* ModelObject::add_volume(TriangleMesh &&mesh)
{
    ModelVolume* v = new ModelVolume(this, std::move(mesh));
    this->volumes.push_back(v);
    this->invalidate_bounding_box();
    return v;
}

ModelVolume* ModelObject::add_volume(const ModelVolume &other)
{
    ModelVolume* v = new ModelVolume(this, other);
    this->volumes.push_back(v);
    this->invalidate_bounding_box();
    return v;
}

void ModelObject::delete_volume(size_t idx)
{
    ModelVolumePtrs::iterator i = this->volumes.begin() + idx;
    delete *i;
    this->volumes.erase(i);
    this->invalidate_bounding_box();
}

void ModelObject::clear_volumes()
{
    for (ModelVolume *v : this->volumes)
        delete v;
    this->volumes.clear();
    this->invalidate_bounding_box();
}

ModelInstance* ModelObject::add_instance()
{
    ModelInstance* i = new ModelInstance(this);
    this->instances.push_back(i);
    this->invalidate_bounding_box();
    return i;
}

ModelInstance* ModelObject::add_instance(const ModelInstance &other)
{
    ModelInstance* i = new ModelInstance(this, other);
    this->instances.push_back(i);
    this->invalidate_bounding_box();
    return i;
}

ModelInstance* ModelObject::add_instance(const Vec3d &offset, const Vec3d &scaling_factor, const Vec3d &rotation)
{
    auto *instance = add_instance();
    instance->set_offset(offset);
    instance->set_scaling_factor(scaling_factor);
    instance->set_rotation(rotation);
    return instance;
}

void ModelObject::delete_instance(size_t idx)
{
    ModelInstancePtrs::iterator i = this->instances.begin() + idx;
    delete *i;
    this->instances.erase(i);
    this->invalidate_bounding_box();
}

void ModelObject::delete_last_instance()
{
    this->delete_instance(this->instances.size() - 1);
}

void ModelObject::clear_instances()
{
    for (ModelInstance *i : this->instances)
        delete i;
    this->instances.clear();
    this->invalidate_bounding_box();
}

// Returns the bounding box of the transformed instances.
// This bounding box is approximate and not snug.
const BoundingBoxf3& ModelObject::bounding_box() const
{
    if (! m_bounding_box_valid) {
        BoundingBoxf3 raw_bbox;
        for (const ModelVolume *v : this->volumes)
            if (v->is_model_part())
                // mesh.bounding_box() returns a cached value.
                raw_bbox.merge(v->mesh.bounding_box());
        BoundingBoxf3 bb;
        for (const ModelInstance *i : this->instances)
            bb.merge(i->transform_bounding_box(raw_bbox));
        m_bounding_box = bb;
        m_bounding_box_valid = true;
    }
    return m_bounding_box;
}

// A mesh containing all transformed instances of this object.
TriangleMesh ModelObject::mesh() const
{
    TriangleMesh mesh;
    TriangleMesh raw_mesh = this->raw_mesh();
    for (const ModelInstance *i : this->instances) {
        TriangleMesh m = raw_mesh;
        i->transform_mesh(&m);
        mesh.merge(m);
    }
    return mesh;
}

// Non-transformed (non-rotated, non-scaled, non-translated) sum of non-modifier object volumes.
// Currently used by ModelObject::mesh(), to calculate the 2D envelope for 2D platter
// and to display the object statistics at ModelObject::print_info().
TriangleMesh ModelObject::raw_mesh() const
{
    TriangleMesh mesh;
    for (const ModelVolume *v : this->volumes)
        if (v->is_model_part())
            mesh.merge(v->mesh);
    return mesh;
}

// A transformed snug bounding box around the non-modifier object volumes, without the translation applied.
// This bounding box is only used for the actual slicing.
BoundingBoxf3 ModelObject::raw_bounding_box() const
{
    BoundingBoxf3 bb;
    for (const ModelVolume *v : this->volumes)
        if (v->is_model_part()) {
            if (this->instances.empty())
                throw std::invalid_argument("Can't call raw_bounding_box() with no instances");
            bb.merge(this->instances.front()->transform_mesh_bounding_box(&v->mesh, true));
        }
    return bb;
}

// This returns an accurate snug bounding box of the transformed object instance, without the translation applied.
BoundingBoxf3 ModelObject::instance_bounding_box(size_t instance_idx, bool dont_translate) const
{
    BoundingBoxf3 bb;
    for (ModelVolume *v : this->volumes)
        if (v->is_model_part())
            bb.merge(this->instances[instance_idx]->transform_mesh_bounding_box(&v->mesh, dont_translate));
    return bb;
}

void ModelObject::center_around_origin()
{
    // calculate the displacements needed to 
    // center this object around the origin
	BoundingBoxf3 bb;
	for (ModelVolume *v : this->volumes)
        if (v->is_model_part())
			bb.merge(v->mesh.bounding_box());
    
    // Shift is the vector from the center of the bounding box to the origin
    Vec3d shift = -bb.center();

    this->translate(shift);
    this->origin_translation += shift;

    if (!this->instances.empty()) {
        for (ModelInstance *i : this->instances) {
            i->set_offset(i->get_offset() - shift);
        }
        this->invalidate_bounding_box();
    }
}

void ModelObject::ensure_on_bed()
{
    translate_instances(Vec3d(0.0, 0.0, -get_min_z()));
}

void ModelObject::translate_instances(const Vec3d& vector)
{
    for (size_t i = 0; i < instances.size(); ++i)
    {
        translate_instance(i, vector);
    }
}

void ModelObject::translate_instance(size_t instance_idx, const Vec3d& vector)
{
    ModelInstance* i = instances[instance_idx];
    i->set_offset(i->get_offset() + vector);
    invalidate_bounding_box();
}

void ModelObject::translate(double x, double y, double z)
{
    for (ModelVolume *v : this->volumes)
    {
        v->mesh.translate(float(x), float(y), float(z));
        v->m_convex_hull.translate(float(x), float(y), float(z));
    }

    if (m_bounding_box_valid)
        m_bounding_box.translate(x, y, z);
}

void ModelObject::scale(const Vec3d &versor)
{
    for (ModelVolume *v : this->volumes)
    {
        v->mesh.scale(versor);
        v->m_convex_hull.scale(versor);
    }
    // reset origin translation since it doesn't make sense anymore
    this->origin_translation = Vec3d::Zero();
    this->invalidate_bounding_box();
}

void ModelObject::rotate(float angle, const Axis& axis)
{
    for (ModelVolume *v : this->volumes)
    {
        v->mesh.rotate(angle, axis);
        v->m_convex_hull.rotate(angle, axis);
    }

    center_around_origin();

    this->origin_translation = Vec3d::Zero();
    this->invalidate_bounding_box();
}

void ModelObject::rotate(float angle, const Vec3d& axis)
{
    for (ModelVolume *v : this->volumes)
    {
        v->mesh.rotate(angle, axis);
        v->m_convex_hull.rotate(angle, axis);
    }

    center_around_origin();

    this->origin_translation = Vec3d::Zero();
    this->invalidate_bounding_box();
}

void ModelObject::mirror(const Axis &axis)
{
    for (ModelVolume *v : this->volumes)
    {
        v->mesh.mirror(axis);
        v->m_convex_hull.mirror(axis);
    }

    this->origin_translation = Vec3d::Zero();
    this->invalidate_bounding_box();
}

size_t ModelObject::materials_count() const
{
    std::set<t_model_material_id> material_ids;
    for (const ModelVolume *v : this->volumes)
        material_ids.insert(v->material_id());
    return material_ids.size();
}

size_t ModelObject::facets_count() const
{
    size_t num = 0;
    for (const ModelVolume *v : this->volumes)
        if (v->is_model_part())
            num += v->mesh.stl.stats.number_of_facets;
    return num;
}

bool ModelObject::needed_repair() const
{
    for (const ModelVolume *v : this->volumes)
        if (v->is_model_part() && v->mesh.needed_repair())
            return true;
    return false;
}

void ModelObject::cut(coordf_t z, Model* model) const
{
    // clone this one to duplicate instances, materials etc.
    ModelObject* upper = model->add_object(*this);
    ModelObject* lower = model->add_object(*this);
    upper->sla_support_points.clear();
    lower->sla_support_points.clear();
    upper->clear_volumes();
    lower->clear_volumes();
    upper->input_file = "";
    lower->input_file = "";
    
    for (ModelVolume *volume : this->volumes) {
        if (! volume->is_model_part()) {
            // don't cut modifiers
            upper->add_volume(*volume);
            lower->add_volume(*volume);
        } else {
            TriangleMesh upper_mesh, lower_mesh;
            TriangleMeshSlicer tms(&volume->mesh);
            tms.cut(z, &upper_mesh, &lower_mesh);

            upper_mesh.repair();
            lower_mesh.repair();
            upper_mesh.reset_repair_stats();
            lower_mesh.reset_repair_stats();
            
            if (upper_mesh.facets_count() > 0) {
                ModelVolume* vol    = upper->add_volume(upper_mesh);
                vol->name           = volume->name;
                vol->config         = volume->config;
                vol->set_material(volume->material_id(), *volume->material());
            }
            if (lower_mesh.facets_count() > 0) {
                ModelVolume* vol    = lower->add_volume(lower_mesh);
                vol->name           = volume->name;
                vol->config         = volume->config;
                vol->set_material(volume->material_id(), *volume->material());
            }
        }
    }
}

void ModelObject::split(ModelObjectPtrs* new_objects)
{
    if (this->volumes.size() > 1) {
        // We can't split meshes if there's more than one volume, because
        // we can't group the resulting meshes by object afterwards
        new_objects->push_back(this);
        return;
    }
    
    ModelVolume* volume = this->volumes.front();
    TriangleMeshPtrs meshptrs = volume->mesh.split();
    for (TriangleMesh *mesh : meshptrs) {
        // Snap the mesh to Z=0.
        float z0 = FLT_MAX;
        
        mesh->repair();
        
        ModelObject* new_object = m_model->add_object(*this, false);
        new_object->sla_support_points.clear();
        new_object->input_file  = "";
        ModelVolume* new_volume = new_object->add_volume(*mesh);
        new_volume->name        = volume->name;
        new_volume->config      = volume->config;
        new_volume->set_type(volume->type());
        new_volume->set_material_id(volume->material_id());
        
        new_objects->push_back(new_object);
        delete mesh;
    }
    
    return;
}

void ModelObject::repair()
{
    for (ModelVolume *v : this->volumes)
        v->mesh.repair();
}

double ModelObject::get_min_z() const
{
    if (instances.empty())
        return 0.0;
    else
    {
        double min_z = DBL_MAX;
        for (size_t i = 0; i < instances.size(); ++i)
        {
            min_z = std::min(min_z, get_instance_min_z(i));
        }
        return min_z;
    }
}

double ModelObject::get_instance_min_z(size_t instance_idx) const
{
    double min_z = DBL_MAX;

    ModelInstance* inst = instances[instance_idx];
    const Transform3d& m = inst->get_matrix(true);

    for (ModelVolume *v : volumes)
    {
        for (uint32_t f = 0; f < v->mesh.stl.stats.number_of_facets; ++f)
        {
            const stl_facet* facet = v->mesh.stl.facet_start + f;
            min_z = std::min(min_z, Vec3d::UnitZ().dot(m * facet->vertex[0].cast<double>()));
            min_z = std::min(min_z, Vec3d::UnitZ().dot(m * facet->vertex[1].cast<double>()));
            min_z = std::min(min_z, Vec3d::UnitZ().dot(m * facet->vertex[2].cast<double>()));
        }
    }

    return min_z + inst->get_offset(Z);
}

unsigned int ModelObject::check_instances_print_volume_state(const BoundingBoxf3& print_volume)
{
    unsigned int num_printable = 0;
    enum {
        INSIDE  = 1,
        OUTSIDE = 2
    };
    for (ModelInstance *model_instance : this->instances) {
        unsigned int inside_outside = 0;
        for (const ModelVolume *vol : this->volumes)
            if (vol->is_model_part()) {
                BoundingBoxf3 bb = vol->get_convex_hull().transformed_bounding_box(model_instance->get_matrix());
                if (print_volume.contains(bb))
                    inside_outside |= INSIDE;
                else if (print_volume.intersects(bb))
                    inside_outside |= INSIDE | OUTSIDE;
                else
                    inside_outside |= OUTSIDE;
            }
        model_instance->print_volume_state = 
            (inside_outside == (INSIDE | OUTSIDE)) ? ModelInstance::PVS_Partly_Outside :
            (inside_outside == INSIDE) ? ModelInstance::PVS_Inside : ModelInstance::PVS_Fully_Outside;
        if (inside_outside == INSIDE)
            ++ num_printable;
    }
    return num_printable;
}

void ModelObject::print_info() const
{
    using namespace std;
    cout << fixed;
    boost::nowide::cout << "[" << boost::filesystem::path(this->input_file).filename().string() << "]" << endl;
    
    TriangleMesh mesh = this->raw_mesh();
    mesh.check_topology();
    BoundingBoxf3 bb = mesh.bounding_box();
    Vec3d size = bb.size();
    cout << "size_x = " << size(0) << endl;
    cout << "size_y = " << size(1) << endl;
    cout << "size_z = " << size(2) << endl;
    cout << "min_x = " << bb.min(0) << endl;
    cout << "min_y = " << bb.min(1) << endl;
    cout << "min_z = " << bb.min(2) << endl;
    cout << "max_x = " << bb.max(0) << endl;
    cout << "max_y = " << bb.max(1) << endl;
    cout << "max_z = " << bb.max(2) << endl;
    cout << "number_of_facets = " << mesh.stl.stats.number_of_facets  << endl;
    cout << "manifold = "   << (mesh.is_manifold() ? "yes" : "no") << endl;
    
    mesh.repair();  // this calculates number_of_parts
    if (mesh.needed_repair()) {
        mesh.repair();
        if (mesh.stl.stats.degenerate_facets > 0)
            cout << "degenerate_facets = "  << mesh.stl.stats.degenerate_facets << endl;
        if (mesh.stl.stats.edges_fixed > 0)
            cout << "edges_fixed = "        << mesh.stl.stats.edges_fixed       << endl;
        if (mesh.stl.stats.facets_removed > 0)
            cout << "facets_removed = "     << mesh.stl.stats.facets_removed    << endl;
        if (mesh.stl.stats.facets_added > 0)
            cout << "facets_added = "       << mesh.stl.stats.facets_added      << endl;
        if (mesh.stl.stats.facets_reversed > 0)
            cout << "facets_reversed = "    << mesh.stl.stats.facets_reversed   << endl;
        if (mesh.stl.stats.backwards_edges > 0)
            cout << "backwards_edges = "    << mesh.stl.stats.backwards_edges   << endl;
    }
    cout << "number_of_parts =  " << mesh.stl.stats.number_of_parts << endl;
    cout << "volume = "           << mesh.volume()                  << endl;
}

void ModelVolume::set_material_id(t_model_material_id material_id)
{
    m_material_id = material_id;
    
    // ensure m_material_id references an existing material
    (void)this->object->get_model()->add_material(material_id);
}

ModelMaterial* ModelVolume::material() const
{ 
    return this->object->get_model()->get_material(m_material_id);
}

void ModelVolume::set_material(t_model_material_id material_id, const ModelMaterial &material)
{
    m_material_id = material_id;
    (void)this->object->get_model()->add_material(material_id, material);
}

ModelMaterial* ModelVolume::assign_unique_material()
{
    Model* model = this->get_object()->get_model();
    
    // as material-id "0" is reserved by the AMF spec we start from 1
    m_material_id = 1 + model->materials.size();  // watchout for implicit cast
    return model->add_material(m_material_id);
}

void ModelVolume::calculate_convex_hull()
{
    m_convex_hull = mesh.convex_hull_3d();
}

const TriangleMesh& ModelVolume::get_convex_hull() const
{
    return m_convex_hull;
}

ModelVolume::Type ModelVolume::type_from_string(const std::string &s)
{
    // Legacy support
    if (s == "1")
        return PARAMETER_MODIFIER;
    // New type (supporting the support enforcers & blockers)
    if (s == "ModelPart")
        return MODEL_PART;
    if (s == "ParameterModifier")
        return PARAMETER_MODIFIER;
    if (s == "SupportEnforcer")
        return SUPPORT_ENFORCER;
    if (s == "SupportBlocker")
        return SUPPORT_BLOCKER;
    assert(s == "0");
    // Default value if invalud type string received.
    return MODEL_PART;
}

std::string ModelVolume::type_to_string(const Type t)
{
    switch (t) {
    case MODEL_PART:         return "ModelPart";
    case PARAMETER_MODIFIER: return "ParameterModifier";
    case SUPPORT_ENFORCER:   return "SupportEnforcer";
    case SUPPORT_BLOCKER:    return "SupportBlocker";
    default:
        assert(false);
        return "ModelPart";
    }
}

// Split this volume, append the result to the object owning this volume.
// Return the number of volumes created from this one.
// This is useful to assign different materials to different volumes of an object.
size_t ModelVolume::split(unsigned int max_extruders)
{
    TriangleMeshPtrs meshptrs = this->mesh.split();
    if (meshptrs.size() <= 1) {
        delete meshptrs.front();
        return 1;
    }

    size_t idx = 0;
    size_t ivolume = std::find(this->object->volumes.begin(), this->object->volumes.end(), this) - this->object->volumes.begin();
    std::string name = this->name;

    Model::reset_auto_extruder_id();

    for (TriangleMesh *mesh : meshptrs) {
        mesh->repair();
        if (idx == 0)
            this->mesh = std::move(*mesh);
        else
            this->object->volumes.insert(this->object->volumes.begin() + (++ ivolume), new ModelVolume(object, *this, std::move(*mesh)));
        char str_idx[64];
        sprintf(str_idx, "_%d", idx + 1);
        this->object->volumes[ivolume]->name = name + str_idx;
        this->object->volumes[ivolume]->config.set_deserialize("extruder", Model::get_auto_extruder_id_as_string(max_extruders));
        delete mesh;
        ++ idx;
    }
    
    return idx;
}

void ModelVolume::translate(double x, double y, double z)
{
    translate(Vec3d(x, y, z));
}

void ModelVolume::translate(const Vec3d& displacement)
{
    mesh.translate((float)displacement(0), (float)displacement(1), (float)displacement(2));
    m_convex_hull.translate((float)displacement(0), (float)displacement(1), (float)displacement(2));
}

#if !ENABLE_MODELVOLUME_TRANSFORM
void ModelInstance::set_rotation(const Vec3d& rotation)
{
    set_rotation(X, rotation(0));
    set_rotation(Y, rotation(1));
    set_rotation(Z, rotation(2));
}

void ModelInstance::set_rotation(Axis axis, double rotation)
{
    static const double TWO_PI = 2.0 * (double)PI;
    while (rotation < 0.0)
    {
        rotation += TWO_PI;
    }
    while (TWO_PI < rotation)
    {
        rotation -= TWO_PI;
    }
    m_rotation(axis) = rotation;
}

void ModelInstance::set_scaling_factor(const Vec3d& scaling_factor)
{
    set_scaling_factor(X, scaling_factor(0));
    set_scaling_factor(Y, scaling_factor(1));
    set_scaling_factor(Z, scaling_factor(2));
}

void ModelInstance::set_scaling_factor(Axis axis, double scaling_factor)
{
    m_scaling_factor(axis) = std::abs(scaling_factor);
}

void ModelInstance::set_mirror(const Vec3d& mirror)
{
    set_mirror(X, mirror(0));
    set_mirror(Y, mirror(1));
    set_mirror(Z, mirror(2));
}

void ModelInstance::set_mirror(Axis axis, double mirror)
{
    double abs_mirror = std::abs(mirror);
    if (abs_mirror == 0.0)
        mirror = 1.0;
    else if (abs_mirror != 1.0)
        mirror /= abs_mirror;

    m_mirror(axis) = mirror;
}
#endif // !ENABLE_MODELVOLUME_TRANSFORM

void ModelInstance::transform_mesh(TriangleMesh* mesh, bool dont_translate) const
{
    mesh->transform(get_matrix(dont_translate).cast<float>());
}

BoundingBoxf3 ModelInstance::transform_mesh_bounding_box(const TriangleMesh* mesh, bool dont_translate) const
{
    // Rotate around mesh origin.
    TriangleMesh copy(*mesh);
    copy.transform(get_matrix(true, false, true, true).cast<float>());
    BoundingBoxf3 bbox = copy.bounding_box();

    if (!empty(bbox)) {
        // Scale the bounding box along the three axes.
        for (unsigned int i = 0; i < 3; ++i)
        {
#if ENABLE_MODELVOLUME_TRANSFORM
            if (std::abs(m_transformation.get_scaling_factor((Axis)i)-1.0) > EPSILON)
            {
                bbox.min(i) *= m_transformation.get_scaling_factor((Axis)i);
                bbox.max(i) *= m_transformation.get_scaling_factor((Axis)i);
#else
            if (std::abs(this->m_scaling_factor(i) - 1.0) > EPSILON)
            {
                bbox.min(i) *= this->m_scaling_factor(i);
                bbox.max(i) *= this->m_scaling_factor(i);
#endif // ENABLE_MODELVOLUME_TRANSFORM
            }
        }

        // Translate the bounding box.
        if (! dont_translate) {
#if ENABLE_MODELVOLUME_TRANSFORM
            bbox.min += m_transformation.get_offset();
            bbox.max += m_transformation.get_offset();
#else
            bbox.min += this->m_offset;
            bbox.max += this->m_offset;
#endif // ENABLE_MODELVOLUME_TRANSFORM
        }
    }
    return bbox;
}

BoundingBoxf3 ModelInstance::transform_bounding_box(const BoundingBoxf3 &bbox, bool dont_translate) const
{
    return bbox.transformed(get_matrix(dont_translate));
}

Vec3d ModelInstance::transform_vector(const Vec3d& v, bool dont_translate) const
{
    return get_matrix(dont_translate) * v;
}

void ModelInstance::transform_polygon(Polygon* polygon) const
{
#if ENABLE_MODELVOLUME_TRANSFORM
    // CHECK_ME -> Is the following correct or it should take in account all three rotations ?
    polygon->rotate(m_transformation.get_rotation(Z)); // rotate around polygon origin
    // CHECK_ME -> Is the following correct ?
    polygon->scale(m_transformation.get_scaling_factor(X), m_transformation.get_scaling_factor(Y)); // scale around polygon origin
#else
    // CHECK_ME -> Is the following correct or it should take in account all three rotations ?
    polygon->rotate(this->m_rotation(2));                // rotate around polygon origin
    // CHECK_ME -> Is the following correct ?
    polygon->scale(this->m_scaling_factor(0), this->m_scaling_factor(1));           // scale around polygon origin
#endif // ENABLE_MODELVOLUME_TRANSFORM
}

#if !ENABLE_MODELVOLUME_TRANSFORM
Transform3d ModelInstance::get_matrix(bool dont_translate, bool dont_rotate, bool dont_scale, bool dont_mirror) const
{
    Vec3d translation = dont_translate ? Vec3d::Zero() : m_offset;
    Vec3d rotation = dont_rotate ? Vec3d::Zero() : m_rotation;
    Vec3d scale = dont_scale ? Vec3d::Ones() : m_scaling_factor;
    Vec3d mirror = dont_mirror ? Vec3d::Ones() : m_mirror;
    return Geometry::assemble_transform(translation, rotation, scale, mirror);
}
#endif // !ENABLE_MODELVOLUME_TRANSFORM

}