Refactored Model.cpp/hpp to C++x11 loops,
simplified the mesh / bbox handling.
This commit is contained in:
bubnikv 2017-06-13 11:35:24 +02:00
parent 21ddcb8487
commit 5cae4cc614
13 changed files with 314 additions and 500 deletions

View File

@ -547,7 +547,8 @@ sub mouse_wheel_event {
$zoom /= 10;
$zoom = $self->_zoom / (1-$zoom);
# Don't allow to zoom too far outside the scene.
my $zoom_min = $self->get_zoom_to_bounding_box_factor($self->max_bounding_box) * 0.4;
my $zoom_min = $self->get_zoom_to_bounding_box_factor($self->max_bounding_box);
$zoom_min *= 0.4 if defined $zoom_min;
$zoom = $zoom_min if defined $zoom_min && $zoom < $zoom_min;
$self->_zoom($zoom);

View File

@ -290,7 +290,7 @@ sub _load_stl {
$dialog->Destroy;
my $model = Slic3r::Model->read_from_file($input_file);
my $mesh = $model->raw_mesh;
my $mesh = $model->mesh;
my $expolygons = $mesh->horizontal_projection;
if (@$expolygons == 0) {

View File

@ -707,7 +707,7 @@ sub load_file {
local $SIG{__WARN__} = Slic3r::GUI::warning_catcher($self);
my $model = eval { Slic3r::Model->read_from_file($input_file) };
my $model = eval { Slic3r::Model->read_from_file($input_file, 0) };
Slic3r::GUI::show_error($self, $@) if $@;
my @obj_idx = ();
@ -1007,7 +1007,6 @@ sub rotate {
$self->reset_thumbnail($obj_idx);
}
$model_object->update_bounding_box;
# update print and start background processing
$self->{print}->add_model_object($model_object, $obj_idx);
@ -1032,7 +1031,6 @@ sub mirror {
}
$model_object->mirror($axis);
$model_object->update_bounding_box;
# realign object to Z = 0
$model_object->center_around_origin;
@ -1112,7 +1110,6 @@ sub changescale {
$_->set_scaling_factor($scale) for @{ $model_object->instances };
$object->transform_thumbnail($self->{model}, $obj_idx);
}
$model_object->update_bounding_box;
# update print and start background processing
$self->stop_background_process;
@ -1133,6 +1130,7 @@ sub arrange {
# ignore arrange failures on purpose: user has visual feedback and we don't need to warn him
# when parts don't fit in print bed
# Force auto center of the aligned grid of of objects on the print bed.
$self->update(1);
}
@ -2198,6 +2196,7 @@ sub make_thumbnail {
# make method idempotent
$self->thumbnail->clear;
# raw_mesh is the non-transformed (non-rotated, non-scaled, non-translated) sum of non-modifier object volumes.
my $mesh = $model->objects->[$obj_idx]->raw_mesh;
#FIXME The "correct" variant could be extremely slow.
# if ($mesh->facets_count <= 5000) {

View File

@ -246,7 +246,6 @@ sub mouse_event {
unscale($point->[X] - $self->{drag_start_pos}[X]),
unscale($point->[Y] - $self->{drag_start_pos}[Y]),
));
$model_object->update_bounding_box;
$self->Refresh;
} elsif ($event->Moving) {
my $cursor = wxSTANDARD_CURSOR;

View File

@ -6,8 +6,8 @@ use List::Util qw(first max any);
use Slic3r::Geometry qw(X Y Z move_points);
sub read_from_file {
my $class = shift;
my ($input_file) = @_;
my ($class, $input_file, $add_default_instances) = @_;
$add_default_instances //= 1;
my $model = $input_file =~ /\.stl$/i ? Slic3r::Model->load_stl(Slic3r::encode_path($input_file), basename($input_file))
: $input_file =~ /\.obj$/i ? Slic3r::Model->load_obj(Slic3r::encode_path($input_file), basename($input_file))
@ -19,6 +19,7 @@ sub read_from_file {
if $model->objects_count == 0;
$_->set_input_file($input_file) for @{$model->objects};
$model->add_default_instances if $add_default_instances;
return $model;
}

View File

@ -144,7 +144,6 @@ if (@ARGV) { # slicing from command line
foreach my $file (@ARGV) {
$file = Slic3r::decode_path($file);
my $model = Slic3r::Model->read_from_file($file);
$model->add_default_instances;
my $mesh = $model->mesh;
$mesh->translate(0, 0, -$mesh->bounding_box->z_min);
my $upper = Slic3r::TriangleMesh->new;
@ -164,7 +163,6 @@ if (@ARGV) { # slicing from command line
foreach my $file (@ARGV) {
$file = Slic3r::decode_path($file);
my $model = Slic3r::Model->read_from_file($file);
$model->add_default_instances;
my $mesh = $model->mesh;
$mesh->repair;

View File

@ -28,9 +28,6 @@ my %opt = ();
{
my $model = Slic3r::Model->read_from_file($ARGV[0]);
# make sure all objects have at least one defined instance
$model->add_default_instances;
$_->center_around_origin for @{$model->objects}; # and align to Z = 0
my $app = Slic3r::ViewMesh->new;

View File

@ -38,7 +38,6 @@ my %opt = (
{
# load model
my $model = Slic3r::Model->read_from_file($ARGV[0]);
$model->add_default_instances;
$model->center_instances_around_point(Slic3r::Pointf->new(100,100));
my $mesh = $model->mesh;
$mesh->translate(0, 0, -$mesh->bounding_box->z_min);

View File

@ -3,28 +3,24 @@
namespace Slic3r {
Model::Model() {}
Model::Model(const Model &other)
{
// copy materials
for (ModelMaterialMap::const_iterator i = other.materials.begin(); i != other.materials.end(); ++i)
this->add_material(i->first, *i->second);
for (const auto &m : other.materials)
this->add_material(m.first, *m.second);
// copy objects
this->objects.reserve(other.objects.size());
for (ModelObjectPtrs::const_iterator i = other.objects.begin(); i != other.objects.end(); ++i)
this->add_object(**i, true);
for (const ModelObject *o : other.objects)
this->add_object(*o, true);
}
Model& Model::operator= (Model other)
Model& Model::operator=(Model other)
{
this->swap(other);
return *this;
}
void
Model::swap(Model &other)
void Model::swap(Model &other)
{
std::swap(this->materials, other.materials);
std::swap(this->objects, other.objects);
@ -36,16 +32,13 @@ Model::~Model()
this->clear_materials();
}
ModelObject*
Model::add_object()
ModelObject* Model::add_object()
{
ModelObject* new_object = new ModelObject(this);
this->objects.push_back(new_object);
return new_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* Model::add_object(const char *name, const char *path, const TriangleMesh &mesh)
{
ModelObject* new_object = new ModelObject(this);
this->objects.push_back(new_object);
@ -57,8 +50,7 @@ Model::add_object(const char *name, const char *path, const TriangleMesh &mesh)
return new_object;
}
ModelObject*
Model::add_object(const char *name, const char *path, TriangleMesh &&mesh)
ModelObject* Model::add_object(const char *name, const char *path, TriangleMesh &&mesh)
{
ModelObject* new_object = new ModelObject(this);
this->objects.push_back(new_object);
@ -70,32 +62,28 @@ Model::add_object(const char *name, const char *path, TriangleMesh &&mesh)
return new_object;
}
ModelObject*
Model::add_object(const ModelObject &other, bool copy_volumes)
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)
void Model::delete_object(size_t idx)
{
ModelObjectPtrs::iterator i = this->objects.begin() + idx;
delete *i;
this->objects.erase(i);
}
void
Model::clear_objects()
void Model::clear_objects()
{
// int instead of size_t because it can be -1 when vector is empty
for (int i = this->objects.size()-1; i >= 0; --i)
this->delete_object(i);
for (ModelObject *o : this->objects)
delete o;
this->objects.clear();
}
void
Model::delete_material(t_model_material_id material_id)
void Model::delete_material(t_model_material_id material_id)
{
ModelMaterialMap::iterator i = this->materials.find(material_id);
if (i != this->materials.end()) {
@ -104,145 +92,79 @@ Model::delete_material(t_model_material_id material_id)
}
}
void
Model::clear_materials()
void Model::clear_materials()
{
while (!this->materials.empty())
this->delete_material( this->materials.begin()->first );
for (auto &m : this->materials)
delete m.second;
this->materials.clear();
}
ModelMaterial*
Model::add_material(t_model_material_id material_id)
ModelMaterial* Model::add_material(t_model_material_id material_id)
{
ModelMaterial* material = this->get_material(material_id);
if (material == NULL) {
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)
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);
if (material != NULL) {
delete material;
}
delete material;
// set new material
material = new ModelMaterial(this, other);
this->materials[material_id] = material;
return material;
}
ModelMaterial*
Model::get_material(t_model_material_id material_id)
{
ModelMaterialMap::iterator i = this->materials.find(material_id);
if (i == this->materials.end()) {
return NULL;
} else {
return i->second;
}
}
bool
Model::has_objects_with_no_instances() const
{
for (ModelObjectPtrs::const_iterator i = this->objects.begin();
i != this->objects.end(); ++i)
{
if ((*i)->instances.empty()) {
return true;
}
}
return false;
}
// makes sure all objects have at least one instance
bool
Model::add_default_instances()
bool Model::add_default_instances()
{
// apply a default position to all objects not having one
for (ModelObjectPtrs::const_iterator o = this->objects.begin(); o != this->objects.end(); ++o) {
if ((*o)->instances.empty()) {
(*o)->add_instance();
}
}
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 Model::bounding_box()
{
BoundingBoxf3 bb;
for (ModelObjectPtrs::const_iterator o = this->objects.begin(); o != this->objects.end(); ++o) {
bb.merge((*o)->bounding_box());
}
for (ModelObject *o : this->objects)
bb.merge(o->bounding_box());
return bb;
}
void
Model::center_instances_around_point(const Pointf &point)
void Model::center_instances_around_point(const Pointf &point)
{
BoundingBoxf3 bb = this->bounding_box();
// BoundingBoxf3 bb = this->bounding_box();
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));
Sizef3 size = bb.size();
coordf_t shift_x = -bb.min.x + point.x - size.x/2;
coordf_t shift_y = -bb.min.y + point.y - size.y/2;
for (ModelObjectPtrs::const_iterator o = this->objects.begin(); o != this->objects.end(); ++o) {
for (ModelInstancePtrs::const_iterator i = (*o)->instances.begin(); i != (*o)->instances.end(); ++i) {
(*i)->offset.translate(shift_x, shift_y);
}
(*o)->invalidate_bounding_box();
}
}
void
Model::align_instances_to_origin()
{
BoundingBoxf3 bb = this->bounding_box();
Pointf new_center = (Pointf)bb.size();
new_center.translate(-new_center.x/2, -new_center.y/2);
this->center_instances_around_point(new_center);
}
void
Model::translate(coordf_t x, coordf_t y, coordf_t z)
{
for (ModelObjectPtrs::const_iterator o = this->objects.begin(); o != this->objects.end(); ++o) {
(*o)->translate(x, y, z);
for (ModelObject *o : this->objects) {
for (ModelInstance *i : o->instances)
i->offset.translate(shift_x, shift_y);
o->invalidate_bounding_box();
}
}
// flattens everything to a single mesh
TriangleMesh
Model::mesh() const
TriangleMesh Model::mesh() const
{
TriangleMesh mesh;
for (ModelObjectPtrs::const_iterator o = this->objects.begin(); o != this->objects.end(); ++o) {
mesh.merge((*o)->mesh());
}
for (const ModelObject *o : this->objects)
mesh.merge(o->mesh());
return mesh;
}
// flattens everything to a single mesh
TriangleMesh
Model::raw_mesh() const
{
TriangleMesh mesh;
for (ModelObjectPtrs::const_iterator o = this->objects.begin(); o != this->objects.end(); ++o) {
mesh.merge((*o)->raw_mesh());
}
return mesh;
}
bool
Model::_arrange(const Pointfs &sizes, coordf_t dist, const BoundingBoxf* bb, Pointfs &out) const
static bool _arrange(const Pointfs &sizes, coordf_t dist, const BoundingBoxf* bb, Pointfs &out)
{
// we supply unscaled data to arrange()
return Slic3r::Geometry::arrange(
@ -256,75 +178,74 @@ Model::_arrange(const Pointfs &sizes, coordf_t dist, const BoundingBoxf* bb, Poi
/* arrange objects preserving their instance count
but altering their instance positions */
bool
Model::arrange_objects(coordf_t dist, const BoundingBoxf* bb)
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;
for (ModelObjectPtrs::const_iterator o = this->objects.begin(); o != this->objects.end(); ++o) {
for (size_t i = 0; i < (*o)->instances.size(); ++i) {
instance_sizes.push_back((*o)->instance_bounding_box(i).size());
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.push_back(bbox.size());
instance_centers.push_back(bbox.center());
}
}
Pointfs positions;
if (! this->_arrange(instance_sizes, dist, bb, positions))
if (! _arrange(instance_sizes, dist, bb, positions))
return false;
for (ModelObjectPtrs::const_iterator o = this->objects.begin(); o != this->objects.end(); ++o) {
for (ModelInstancePtrs::const_iterator i = (*o)->instances.begin(); i != (*o)->instances.end(); ++i) {
(*i)->offset = positions.back();
positions.pop_back();
size_t idx = 0;
for (ModelObject *o : this->objects) {
for (ModelInstance *i : o->instances) {
i->offset = positions[idx] - instance_centers[idx];
++ idx;
}
(*o)->invalidate_bounding_box();
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)
// 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, this->bounding_box().size());
Pointfs positions;
if (! this->_arrange(model_sizes, dist, bb, positions))
if (! _arrange(model_sizes, dist, bb, positions))
CONFESS("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 (ModelObjectPtrs::const_iterator o = this->objects.begin(); o != this->objects.end(); ++o) {
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 (ModelInstancePtrs::const_iterator i = instances.begin(); i != instances.end(); ++i) {
for (Pointfs::const_iterator pos = positions.begin(); pos != positions.end(); ++pos) {
ModelInstance* instance = (*o)->add_instance(**i);
instance->offset.translate(*pos);
ModelInstancePtrs instances = o->instances;
for (const ModelInstance *i : instances) {
for (const Pointf &pos : positions) {
ModelInstance *instance = o->add_instance(*i);
instance->offset.translate(pos);
}
}
(*o)->invalidate_bounding_box();
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)
void Model::duplicate_objects(size_t copies_num, coordf_t dist, const BoundingBoxf* bb)
{
for (ModelObjectPtrs::const_iterator o = this->objects.begin(); o != this->objects.end(); ++o) {
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 (ModelInstancePtrs::const_iterator i = instances.begin(); i != instances.end(); ++i) {
for (size_t k = 2; k <= copies_num; ++k)
(*o)->add_instance(**i);
}
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)
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!";
@ -343,26 +264,8 @@ Model::duplicate_objects_grid(size_t x, size_t y, coordf_t dist)
}
}
ModelMaterial::ModelMaterial(Model *model) : model(model) {}
ModelMaterial::ModelMaterial(Model *model, const ModelMaterial &other)
: attributes(other.attributes), config(other.config), model(model)
{}
void
ModelMaterial::apply(const t_model_material_attributes &attributes)
{
this->attributes.insert(attributes.begin(), attributes.end());
}
ModelObject::ModelObject(Model *model) :
model(model),
_bounding_box_valid(false),
layer_height_profile_valid(false)
{}
ModelObject::ModelObject(Model *model, const ModelObject &other, bool copy_volumes)
: name(other.name),
ModelObject::ModelObject(Model *model, const ModelObject &other, bool copy_volumes) :
name(other.name),
input_file(other.input_file),
instances(),
volumes(),
@ -371,9 +274,9 @@ ModelObject::ModelObject(Model *model, const ModelObject &other, bool copy_volum
layer_height_profile(other.layer_height_profile),
layer_height_profile_valid(other.layer_height_profile_valid),
origin_translation(other.origin_translation),
_bounding_box(other._bounding_box),
_bounding_box_valid(other._bounding_box_valid),
model(model)
m_bounding_box(other.m_bounding_box),
m_bounding_box_valid(other.m_bounding_box_valid),
m_model(model)
{
if (copy_volumes) {
this->volumes.reserve(other.volumes.size());
@ -392,8 +295,7 @@ ModelObject& ModelObject::operator=(ModelObject other)
return *this;
}
void
ModelObject::swap(ModelObject &other)
void ModelObject::swap(ModelObject &other)
{
std::swap(this->input_file, other.input_file);
std::swap(this->instances, other.instances);
@ -403,8 +305,8 @@ ModelObject::swap(ModelObject &other)
std::swap(this->layer_height_profile, other.layer_height_profile);
std::swap(this->layer_height_profile_valid, other.layer_height_profile_valid);
std::swap(this->origin_translation, other.origin_translation);
std::swap(this->_bounding_box, other._bounding_box);
std::swap(this->_bounding_box_valid, other._bounding_box_valid);
std::swap(m_bounding_box, other.m_bounding_box);
std::swap(m_bounding_box_valid, other.m_bounding_box_valid);
}
ModelObject::~ModelObject()
@ -413,8 +315,7 @@ ModelObject::~ModelObject()
this->clear_instances();
}
ModelVolume*
ModelObject::add_volume(const TriangleMesh &mesh)
ModelVolume* ModelObject::add_volume(const TriangleMesh &mesh)
{
ModelVolume* v = new ModelVolume(this, mesh);
this->volumes.push_back(v);
@ -422,8 +323,7 @@ ModelObject::add_volume(const TriangleMesh &mesh)
return v;
}
ModelVolume*
ModelObject::add_volume(TriangleMesh &&mesh)
ModelVolume* ModelObject::add_volume(TriangleMesh &&mesh)
{
ModelVolume* v = new ModelVolume(this, std::move(mesh));
this->volumes.push_back(v);
@ -431,8 +331,7 @@ ModelObject::add_volume(TriangleMesh &&mesh)
return v;
}
ModelVolume*
ModelObject::add_volume(const ModelVolume &other)
ModelVolume* ModelObject::add_volume(const ModelVolume &other)
{
ModelVolume* v = new ModelVolume(this, other);
this->volumes.push_back(v);
@ -440,8 +339,7 @@ ModelObject::add_volume(const ModelVolume &other)
return v;
}
void
ModelObject::delete_volume(size_t idx)
void ModelObject::delete_volume(size_t idx)
{
ModelVolumePtrs::iterator i = this->volumes.begin() + idx;
delete *i;
@ -449,16 +347,15 @@ ModelObject::delete_volume(size_t idx)
this->invalidate_bounding_box();
}
void
ModelObject::clear_volumes()
void ModelObject::clear_volumes()
{
// int instead of size_t because it can be -1 when vector is empty
for (int i = this->volumes.size()-1; i >= 0; --i)
this->delete_volume(i);
for (ModelVolume *v : this->volumes)
delete v;
this->volumes.clear();
this->invalidate_bounding_box();
}
ModelInstance*
ModelObject::add_instance()
ModelInstance* ModelObject::add_instance()
{
ModelInstance* i = new ModelInstance(this);
this->instances.push_back(i);
@ -466,8 +363,7 @@ ModelObject::add_instance()
return i;
}
ModelInstance*
ModelObject::add_instance(const ModelInstance &other)
ModelInstance* ModelObject::add_instance(const ModelInstance &other)
{
ModelInstance* i = new ModelInstance(this, other);
this->instances.push_back(i);
@ -475,8 +371,7 @@ ModelObject::add_instance(const ModelInstance &other)
return i;
}
void
ModelObject::delete_instance(size_t idx)
void ModelObject::delete_instance(size_t idx)
{
ModelInstancePtrs::iterator i = this->instances.begin() + idx;
delete *i;
@ -484,108 +379,93 @@ ModelObject::delete_instance(size_t idx)
this->invalidate_bounding_box();
}
void
ModelObject::delete_last_instance()
void ModelObject::delete_last_instance()
{
this->delete_instance(this->instances.size() - 1);
}
void
ModelObject::clear_instances()
void ModelObject::clear_instances()
{
for (size_t i = 0; i < this->instances.size(); ++i)
this->delete_instance(i);
for (ModelInstance *i : this->instances)
delete i;
this->instances.clear();
this->invalidate_bounding_box();
}
// this returns the bounding box of the *transformed* instances
BoundingBoxf3
ModelObject::bounding_box()
// Returns the bounding box of the transformed instances.
// This bounding box is approximate and not snug.
BoundingBoxf3 ModelObject::bounding_box()
{
if (!this->_bounding_box_valid) this->update_bounding_box();
return this->_bounding_box;
}
void
ModelObject::invalidate_bounding_box()
{
this->_bounding_box_valid = false;
}
void
ModelObject::update_bounding_box()
{
// this->_bounding_box = this->mesh().bounding_box();
BoundingBoxf3 raw_bbox;
for (ModelVolumePtrs::const_iterator v = this->volumes.begin(); v != this->volumes.end(); ++v) {
if ((*v)->modifier) continue;
raw_bbox.merge((*v)->mesh.bounding_box());
if (! m_bounding_box_valid) {
BoundingBoxf3 raw_bbox;
for (const ModelVolume *v : this->volumes)
if (! v->modifier)
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;
}
BoundingBoxf3 bb;
for (ModelInstancePtrs::const_iterator i = this->instances.begin(); i != this->instances.end(); ++i)
bb.merge((*i)->transform_bounding_box(raw_bbox));
this->_bounding_box = bb;
this->_bounding_box_valid = true;
return m_bounding_box;
}
// flattens all volumes and instances into a single mesh
TriangleMesh
ModelObject::mesh() const
// A mesh containing all transformed instances of this object.
TriangleMesh ModelObject::mesh() const
{
TriangleMesh mesh;
TriangleMesh raw_mesh = this->raw_mesh();
for (ModelInstancePtrs::const_iterator i = this->instances.begin(); i != this->instances.end(); ++i) {
for (const ModelInstance *i : this->instances) {
TriangleMesh m = raw_mesh;
(*i)->transform_mesh(&m);
i->transform_mesh(&m);
mesh.merge(m);
}
return mesh;
}
TriangleMesh
ModelObject::raw_mesh() const
// 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 (ModelVolumePtrs::const_iterator v = this->volumes.begin(); v != this->volumes.end(); ++v) {
if ((*v)->modifier) continue;
mesh.merge((*v)->mesh);
}
for (const ModelVolume *v : this->volumes)
if (! v->modifier)
mesh.merge(v->mesh);
return mesh;
}
BoundingBoxf3
ModelObject::raw_bounding_box() const
// 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 (ModelVolumePtrs::const_iterator v = this->volumes.begin(); v != this->volumes.end(); ++v) {
if ((*v)->modifier) continue;
if (this->instances.empty()) CONFESS("Can't call raw_bounding_box() with no instances");
bb.merge(this->instances.front()->transform_mesh_bounding_box(&(*v)->mesh, true));
}
for (const ModelVolume *v : this->volumes)
if (! v->modifier) {
if (this->instances.empty()) CONFESS("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 the bounding box of the *transformed* given instance
BoundingBoxf3
ModelObject::instance_bounding_box(size_t instance_idx) const
// 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 (ModelVolumePtrs::const_iterator v = this->volumes.begin(); v != this->volumes.end(); ++v) {
if ((*v)->modifier) continue;
bb.merge(this->instances[instance_idx]->transform_mesh_bounding_box(&(*v)->mesh, true));
}
for (ModelVolume *v : this->volumes)
if (! v->modifier)
bb.merge(this->instances[instance_idx]->transform_mesh_bounding_box(&v->mesh, dont_translate));
return bb;
}
void
ModelObject::center_around_origin()
void ModelObject::center_around_origin()
{
// calculate the displacements needed to
// center this object around the origin
BoundingBoxf3 bb;
for (ModelVolumePtrs::const_iterator v = this->volumes.begin(); v != this->volumes.end(); ++v)
if (! (*v)->modifier)
bb.merge((*v)->mesh.bounding_box());
for (ModelVolume *v : this->volumes)
if (! v->modifier)
bb.merge(v->mesh.bounding_box());
// first align to origin on XYZ
Vectorf3 vector(-bb.min.x, -bb.min.y, -bb.min.z);
@ -599,98 +479,77 @@ ModelObject::center_around_origin()
this->origin_translation.translate(vector);
if (!this->instances.empty()) {
for (ModelInstancePtrs::const_iterator i = this->instances.begin(); i != this->instances.end(); ++i) {
for (ModelInstance *i : this->instances) {
// apply rotation and scaling to vector as well before translating instance,
// in order to leave final position unaltered
Vectorf3 v = vector.negative();
v.rotate((*i)->rotation, (*i)->offset);
v.scale((*i)->scaling_factor);
(*i)->offset.translate(v.x, v.y);
v.rotate(i->rotation, i->offset);
v.scale(i->scaling_factor);
i->offset.translate(v.x, v.y);
}
this->invalidate_bounding_box();
}
}
void
ModelObject::translate(const Vectorf3 &vector)
void ModelObject::translate(coordf_t x, coordf_t y, coordf_t z)
{
this->translate(vector.x, vector.y, vector.z);
for (ModelVolume *v : this->volumes)
v->mesh.translate(float(x), float(y), float(z));
if (m_bounding_box_valid)
m_bounding_box.translate(x, y, z);
}
void
ModelObject::translate(coordf_t x, coordf_t y, coordf_t z)
void ModelObject::scale(const Pointf3 &versor)
{
for (ModelVolumePtrs::const_iterator v = this->volumes.begin(); v != this->volumes.end(); ++v) {
(*v)->mesh.translate(x, y, z);
}
if (this->_bounding_box_valid) this->_bounding_box.translate(x, y, z);
}
void
ModelObject::scale(const Pointf3 &versor)
{
for (ModelVolumePtrs::const_iterator v = this->volumes.begin(); v != this->volumes.end(); ++v) {
(*v)->mesh.scale(versor);
}
for (ModelVolume *v : this->volumes)
v->mesh.scale(versor);
// reset origin translation since it doesn't make sense anymore
this->origin_translation = Pointf3(0,0,0);
this->invalidate_bounding_box();
}
void
ModelObject::rotate(float angle, const Axis &axis)
void ModelObject::rotate(float angle, const Axis &axis)
{
for (ModelVolumePtrs::const_iterator v = this->volumes.begin(); v != this->volumes.end(); ++v) {
(*v)->mesh.rotate(angle, axis);
}
for (ModelVolume *v : this->volumes)
v->mesh.rotate(angle, axis);
this->origin_translation = Pointf3(0,0,0);
this->invalidate_bounding_box();
}
void
ModelObject::mirror(const Axis &axis)
void ModelObject::mirror(const Axis &axis)
{
for (ModelVolumePtrs::const_iterator v = this->volumes.begin(); v != this->volumes.end(); ++v) {
(*v)->mesh.mirror(axis);
}
for (ModelVolume *v : this->volumes)
v->mesh.mirror(axis);
this->origin_translation = Pointf3(0,0,0);
this->invalidate_bounding_box();
}
size_t
ModelObject::materials_count() const
size_t ModelObject::materials_count() const
{
std::set<t_model_material_id> material_ids;
for (ModelVolumePtrs::const_iterator v = this->volumes.begin(); v != this->volumes.end(); ++v) {
material_ids.insert((*v)->material_id());
}
for (const ModelVolume *v : this->volumes)
material_ids.insert(v->material_id());
return material_ids.size();
}
size_t
ModelObject::facets_count() const
size_t ModelObject::facets_count() const
{
size_t num = 0;
for (ModelVolumePtrs::const_iterator v = this->volumes.begin(); v != this->volumes.end(); ++v) {
if ((*v)->modifier) continue;
num += (*v)->mesh.stl.stats.number_of_facets;
}
for (const ModelVolume *v : this->volumes)
if (! v->modifier)
num += v->mesh.stl.stats.number_of_facets;
return num;
}
bool
ModelObject::needed_repair() const
bool ModelObject::needed_repair() const
{
for (ModelVolumePtrs::const_iterator v = this->volumes.begin(); v != this->volumes.end(); ++v) {
if ((*v)->modifier) continue;
if ((*v)->mesh.needed_repair()) return true;
}
for (const ModelVolume *v : this->volumes)
if (! v->modifier && v->mesh.needed_repair())
return true;
return false;
}
void
ModelObject::cut(coordf_t z, Model* model) const
void ModelObject::cut(coordf_t z, Model* model) const
{
// clone this one to duplicate instances, materials etc.
ModelObject* upper = model->add_object(*this);
@ -700,8 +559,7 @@ ModelObject::cut(coordf_t z, Model* model) const
upper->input_file = "";
lower->input_file = "";
for (ModelVolumePtrs::const_iterator v = this->volumes.begin(); v != this->volumes.end(); ++v) {
ModelVolume* volume = *v;
for (ModelVolume *volume : this->volumes) {
if (volume->modifier) {
// don't cut modifiers
upper->add_volume(*volume);
@ -757,8 +615,7 @@ ModelObject::cut(coordf_t z, Model* model) const
}
}
void
ModelObject::split(ModelObjectPtrs* new_objects)
void ModelObject::split(ModelObjectPtrs* new_objects)
{
if (this->volumes.size() > 1) {
// We can't split meshes if there's more than one volume, because
@ -772,7 +629,7 @@ ModelObject::split(ModelObjectPtrs* new_objects)
for (TriangleMeshPtrs::iterator mesh = meshptrs.begin(); mesh != meshptrs.end(); ++mesh) {
(*mesh)->repair();
ModelObject* new_object = this->model->add_object(*this, false);
ModelObject* new_object = m_model->add_object(*this, false);
new_object->input_file = "";
ModelVolume* new_volume = new_object->add_volume(**mesh);
new_volume->name = volume->name;
@ -787,30 +644,7 @@ ModelObject::split(ModelObjectPtrs* new_objects)
return;
}
ModelVolume::ModelVolume(ModelObject* object, const TriangleMesh &mesh)
: mesh(mesh), modifier(false), object(object)
{}
ModelVolume::ModelVolume(ModelObject* object, TriangleMesh &&mesh)
: mesh(std::move(mesh)), modifier(false), object(object)
{}
ModelVolume::ModelVolume(ModelObject* object, const ModelVolume &other)
: name(other.name), mesh(other.mesh), config(other.config),
modifier(other.modifier), object(object)
{
this->material_id(other.material_id());
}
t_model_material_id
ModelVolume::material_id() const
{
return this->_material_id;
}
void
ModelVolume::material_id(t_model_material_id material_id)
void ModelVolume::material_id(t_model_material_id material_id)
{
this->_material_id = material_id;
@ -818,21 +652,18 @@ ModelVolume::material_id(t_model_material_id material_id)
(void)this->object->get_model()->add_material(material_id);
}
ModelMaterial*
ModelVolume::material() const
ModelMaterial* ModelVolume::material() const
{
return this->object->get_model()->get_material(this->_material_id);
}
void
ModelVolume::set_material(t_model_material_id material_id, const ModelMaterial &material)
void ModelVolume::set_material(t_model_material_id material_id, const ModelMaterial &material)
{
this->_material_id = material_id;
(void)this->object->get_model()->add_material(material_id, material);
}
ModelMaterial*
ModelVolume::assign_unique_material()
ModelMaterial* ModelVolume::assign_unique_material()
{
Model* model = this->get_object()->get_model();
@ -841,17 +672,7 @@ ModelVolume::assign_unique_material()
return model->add_material(this->_material_id);
}
ModelInstance::ModelInstance(ModelObject *object)
: rotation(0), scaling_factor(1), object(object)
{}
ModelInstance::ModelInstance(ModelObject *object, const ModelInstance &other)
: rotation(other.rotation), scaling_factor(other.scaling_factor), offset(other.offset), object(object)
{}
void
ModelInstance::transform_mesh(TriangleMesh* mesh, bool dont_translate) const
void ModelInstance::transform_mesh(TriangleMesh* mesh, bool dont_translate) const
{
mesh->rotate_z(this->rotation); // rotate around mesh origin
mesh->scale(this->scaling_factor); // scale around mesh origin
@ -861,7 +682,7 @@ ModelInstance::transform_mesh(TriangleMesh* mesh, bool dont_translate) const
BoundingBoxf3 ModelInstance::transform_mesh_bounding_box(const TriangleMesh* mesh, bool dont_translate) const
{
// rotate around mesh origin
// Rotate around mesh origin.
double c = cos(this->rotation);
double s = sin(this->rotation);
BoundingBoxf3 bbox;
@ -873,16 +694,27 @@ BoundingBoxf3 ModelInstance::transform_mesh_bounding_box(const TriangleMesh* mes
double yold = v.y;
v.x = float(c * xold - s * yold);
v.y = float(s * xold + c * yold);
v.x *= float(this->scaling_factor);
v.y *= float(this->scaling_factor);
v.z *= float(this->scaling_factor);
if (!dont_translate) {
v.x += this->offset.x;
v.y += this->offset.y;
}
bbox.merge(Pointf3(v.x, v.y, v.z));
}
}
if (! empty(bbox)) {
// Scale the bounding box uniformly.
if (std::abs(this->scaling_factor - 1.) > EPSILON) {
bbox.min.x *= float(this->scaling_factor);
bbox.min.y *= float(this->scaling_factor);
bbox.min.z *= float(this->scaling_factor);
bbox.max.x *= float(this->scaling_factor);
bbox.max.y *= float(this->scaling_factor);
bbox.max.z *= float(this->scaling_factor);
}
// Translate the bounding box.
if (! dont_translate) {
bbox.min.x += float(this->offset.x);
bbox.min.y += float(this->offset.y);
bbox.max.x += float(this->offset.x);
bbox.max.y += float(this->offset.y);
}
}
return bbox;
}
@ -907,7 +739,7 @@ BoundingBoxf3 ModelInstance::transform_bounding_box(const BoundingBoxf3 &bbox, b
v.x *= this->scaling_factor;
v.y *= this->scaling_factor;
v.z *= this->scaling_factor;
if (!dont_translate) {
if (! dont_translate) {
v.x += this->offset.x;
v.y += this->offset.y;
}
@ -916,8 +748,7 @@ BoundingBoxf3 ModelInstance::transform_bounding_box(const BoundingBoxf3 &bbox, b
return out;
}
void
ModelInstance::transform_polygon(Polygon* polygon) const
void ModelInstance::transform_polygon(Polygon* polygon) const
{
polygon->rotate(this->rotation); // rotate around polygon origin
polygon->scale(this->scaling_factor); // scale around polygon origin

View File

@ -28,53 +28,6 @@ typedef std::vector<ModelObject*> ModelObjectPtrs;
typedef std::vector<ModelVolume*> ModelVolumePtrs;
typedef std::vector<ModelInstance*> ModelInstancePtrs;
// The print bed content.
// Description of a triangular model with multiple materials, multiple instances with various affine transformations
// and with multiple modifier meshes.
// A model groups multiple objects, each object having possibly multiple instances,
// all objects may share mutliple materials.
class Model
{
public:
// Materials are owned by a model and referenced by objects through t_model_material_id.
// Single material may be shared by multiple models.
ModelMaterialMap materials;
// Objects are owned by a model. Each model may have multiple instances, each instance having its own transformation (shift, scale, rotation).
ModelObjectPtrs objects;
Model();
Model(const Model &other);
Model& operator= (Model other);
void swap(Model &other);
~Model();
ModelObject* add_object();
ModelObject* add_object(const char *name, const char *path, const TriangleMesh &mesh);
ModelObject* add_object(const char *name, const char *path, TriangleMesh &&mesh);
ModelObject* add_object(const ModelObject &other, bool copy_volumes = true);
void delete_object(size_t idx);
void clear_objects();
ModelMaterial* add_material(t_model_material_id material_id);
ModelMaterial* add_material(t_model_material_id material_id, const ModelMaterial &other);
ModelMaterial* get_material(t_model_material_id material_id);
void delete_material(t_model_material_id material_id);
void clear_materials();
bool has_objects_with_no_instances() const;
bool add_default_instances();
BoundingBoxf3 bounding_box() const;
void center_instances_around_point(const Pointf &point);
void align_instances_to_origin();
void translate(coordf_t x, coordf_t y, coordf_t z);
TriangleMesh mesh() const;
TriangleMesh raw_mesh() const;
bool _arrange(const Pointfs &sizes, coordf_t dist, const BoundingBoxf* bb, Pointfs &out) const;
bool arrange_objects(coordf_t dist, const BoundingBoxf* bb = NULL);
// Croaks if the duplicated objects do not fit the print bed.
void duplicate(size_t copies_num, coordf_t dist, const BoundingBoxf* bb = NULL);
void duplicate_objects(size_t copies_num, coordf_t dist, const BoundingBoxf* bb = NULL);
void duplicate_objects_grid(size_t x, size_t y, coordf_t dist);
};
// Material, which may be shared across multiple ModelObjects of a single Model.
class ModelMaterial
{
@ -85,15 +38,16 @@ public:
// Dynamic configuration storage for the object specific configuration values, overriding the global configuration.
DynamicPrintConfig config;
Model* get_model() const { return this->model; };
void apply(const t_model_material_attributes &attributes);
Model* get_model() const { return m_model; };
void apply(const t_model_material_attributes &attributes)
{ this->attributes.insert(attributes.begin(), attributes.end()); }
private:
// Parent, owning this material.
Model* model;
Model *m_model;
ModelMaterial(Model *model);
ModelMaterial(Model *model, const ModelMaterial &other);
ModelMaterial(Model *model) : m_model(model) {}
ModelMaterial(Model *model, const ModelMaterial &other) : attributes(other.attributes), config(other.config), m_model(model) {}
};
// A printable object, possibly having multiple print volumes (each with its own set of parameters and materials),
@ -104,37 +58,33 @@ class ModelObject
{
friend class Model;
public:
std::string name;
std::string input_file;
std::string name;
std::string input_file;
// Instances of this ModelObject. Each instance defines a shift on the print bed, rotation around the Z axis and a uniform scaling.
// Instances are owned by this ModelObject.
ModelInstancePtrs instances;
ModelInstancePtrs instances;
// Printable and modifier volumes, each with its material ID and a set of override parameters.
// ModelVolumes are owned by this ModelObject.
ModelVolumePtrs volumes;
ModelVolumePtrs volumes;
// Configuration parameters specific to a single ModelObject, overriding the global Slic3r settings.
DynamicPrintConfig config;
DynamicPrintConfig config;
// Variation of a layer thickness for spans of Z coordinates.
t_layer_height_ranges layer_height_ranges;
t_layer_height_ranges layer_height_ranges;
// Profile of increasing z to a layer height, to be linearly interpolated when calculating the layers.
// The pairs of <z, layer_height> are packed into a 1D array to simplify handling by the Perl XS.
std::vector<coordf_t> layer_height_profile;
std::vector<coordf_t> layer_height_profile;
// layer_height_profile is initialized when the layer editing mode is entered.
// Only if the user really modified the layer height, layer_height_profile_valid is set
// and used subsequently by the PrintObject.
bool layer_height_profile_valid;
bool layer_height_profile_valid;
/* This vector accumulates the total translation applied to the object by the
center_around_origin() method. Callers might want to apply the same translation
to new volumes before adding them to this object in order to preserve alignment
when user expects that. */
Pointf3 origin_translation;
Pointf3 origin_translation;
// these should be private but we need to expose them via XS until all methods are ported
BoundingBoxf3 _bounding_box;
bool _bounding_box_valid;
Model* get_model() const { return this->model; };
Model* get_model() const { return m_model; };
ModelVolume* add_volume(const TriangleMesh &mesh);
ModelVolume* add_volume(TriangleMesh &&mesh);
@ -148,15 +98,23 @@ public:
void delete_last_instance();
void clear_instances();
// Returns the bounding box of the transformed instances.
// This bounding box is approximate and not snug.
BoundingBoxf3 bounding_box();
void invalidate_bounding_box();
void invalidate_bounding_box() { m_bounding_box_valid = false; }
// A mesh containing all transformed instances of this object.
TriangleMesh mesh() const;
// Non-transformed (non-rotated, non-scaled, non-translated) sum of non-modifier object volumes.
// Currently used by ModelObject::mesh() and to calculate the 2D envelope for 2D platter.
TriangleMesh raw_mesh() const;
// 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 raw_bounding_box() const;
BoundingBoxf3 instance_bounding_box(size_t instance_idx) const;
// A snug bounding box around the transformed non-modifier object volumes.
BoundingBoxf3 instance_bounding_box(size_t instance_idx, bool dont_translate = false) const;
void center_around_origin();
void translate(const Vectorf3 &vector);
void translate(const Vectorf3 &vector) { this->translate(vector.x, vector.y, vector.z); }
void translate(coordf_t x, coordf_t y, coordf_t z);
void scale(const Pointf3 &versor);
void rotate(float angle, const Axis &axis);
@ -166,17 +124,19 @@ public:
bool needed_repair() const;
void cut(coordf_t z, Model* model) const;
void split(ModelObjectPtrs* new_objects);
void update_bounding_box(); // this is a private method but we expose it until we need to expose it via XS
private:
// Parent object, owning this ModelObject.
Model* model;
ModelObject(Model *model);
ModelObject(Model *model) : m_model(model), m_bounding_box_valid(false), layer_height_profile_valid(false) {}
ModelObject(Model *model, const ModelObject &other, bool copy_volumes = true);
ModelObject& operator= (ModelObject other);
void swap(ModelObject &other);
~ModelObject();
// Parent object, owning this ModelObject.
Model *m_model;
// Bounding box, cached.
BoundingBoxf3 m_bounding_box;
bool m_bounding_box_valid;
};
// An object STL, or a modifier volume, over which a different set of parameters shall be applied.
@ -196,7 +156,7 @@ public:
// A parent object owning this modifier volume.
ModelObject* get_object() const { return this->object; };
t_model_material_id material_id() const;
t_model_material_id material_id() const { return this->_material_id; }
void material_id(t_model_material_id material_id);
ModelMaterial* material() const;
void set_material(t_model_material_id material_id, const ModelMaterial &material);
@ -208,9 +168,11 @@ private:
ModelObject* object;
t_model_material_id _material_id;
ModelVolume(ModelObject *object, const TriangleMesh &mesh);
ModelVolume(ModelObject *object, TriangleMesh &&mesh);
ModelVolume(ModelObject *object, const ModelVolume &other);
ModelVolume(ModelObject *object, const TriangleMesh &mesh) : mesh(mesh), modifier(false), object(object) {}
ModelVolume(ModelObject *object, TriangleMesh &&mesh) : mesh(std::move(mesh)), modifier(false), object(object) {}
ModelVolume(ModelObject *object, const ModelVolume &other) :
name(other.name), mesh(other.mesh), config(other.config), modifier(other.modifier), object(object)
{ this->material_id(other.material_id()); }
};
// A single instance of a ModelObject.
@ -238,8 +200,57 @@ private:
// Parent object, owning this instance.
ModelObject* object;
ModelInstance(ModelObject *object);
ModelInstance(ModelObject *object, const ModelInstance &other);
ModelInstance(ModelObject *object) : rotation(0), scaling_factor(1), object(object) {}
ModelInstance(ModelObject *object, const ModelInstance &other) :
rotation(other.rotation), scaling_factor(other.scaling_factor), offset(other.offset), object(object) {}
};
// The print bed content.
// Description of a triangular model with multiple materials, multiple instances with various affine transformations
// and with multiple modifier meshes.
// A model groups multiple objects, each object having possibly multiple instances,
// all objects may share mutliple materials.
class Model
{
public:
// Materials are owned by a model and referenced by objects through t_model_material_id.
// Single material may be shared by multiple models.
ModelMaterialMap materials;
// Objects are owned by a model. Each model may have multiple instances, each instance having its own transformation (shift, scale, rotation).
ModelObjectPtrs objects;
Model() {}
Model(const Model &other);
Model& operator= (Model other);
void swap(Model &other);
~Model();
ModelObject* add_object();
ModelObject* add_object(const char *name, const char *path, const TriangleMesh &mesh);
ModelObject* add_object(const char *name, const char *path, TriangleMesh &&mesh);
ModelObject* add_object(const ModelObject &other, bool copy_volumes = true);
void delete_object(size_t idx);
void clear_objects();
ModelMaterial* add_material(t_model_material_id material_id);
ModelMaterial* add_material(t_model_material_id material_id, const ModelMaterial &other);
ModelMaterial* get_material(t_model_material_id material_id) {
ModelMaterialMap::iterator i = this->materials.find(material_id);
return (i == this->materials.end()) ? nullptr : i->second;
}
void delete_material(t_model_material_id material_id);
void clear_materials();
bool add_default_instances();
BoundingBoxf3 bounding_box();
void center_instances_around_point(const Pointf &point);
void translate(coordf_t x, coordf_t y, coordf_t z) { for (ModelObject *o : this->objects) o->translate(x, y, z); }
TriangleMesh mesh() const;
bool arrange_objects(coordf_t dist, const BoundingBoxf* bb = NULL);
// Croaks if the duplicated objects do not fit the print bed.
void duplicate(size_t copies_num, coordf_t dist, const BoundingBoxf* bb = NULL);
void duplicate_objects(size_t copies_num, coordf_t dist, const BoundingBoxf* bb = NULL);
void duplicate_objects_grid(size_t x, size_t y, coordf_t dist);
};
}

View File

@ -509,9 +509,7 @@ std::string Print::validate() const
{
Polygons convex_hulls_other;
for (PrintObject *object : this->objects) {
// Get convex hull of all meshes assigned to this print object
// (this is the same as model_object()->raw_mesh.convex_hull()
// but probably more efficient.
// Get convex hull of all meshes assigned to this print object.
Polygon convex_hull;
{
Polygons mesh_convex_hulls;

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@ -58,15 +58,12 @@
size_t material_count() const
%code%{ RETVAL = THIS->materials.size(); %};
bool has_objects_with_no_instances();
bool add_default_instances();
Clone<BoundingBoxf3> bounding_box();
void center_instances_around_point(Pointf* point)
%code%{ THIS->center_instances_around_point(*point); %};
void align_instances_to_origin();
void translate(double x, double y, double z);
Clone<TriangleMesh> mesh();
Clone<TriangleMesh> raw_mesh();
ModelObjectPtrs* objects()
%code%{ RETVAL = &THIS->objects; %};
@ -183,25 +180,10 @@ ModelMaterial::attributes()
%code%{ RETVAL = &THIS->instances; %};
void invalidate_bounding_box();
void update_bounding_box();
Clone<TriangleMesh> mesh();
Clone<TriangleMesh> raw_mesh();
Clone<BoundingBoxf3> raw_bounding_box();
Clone<BoundingBoxf3> instance_bounding_box(int idx);
Ref<BoundingBoxf3> _bounding_box(BoundingBoxf3* new_bbox = NULL)
%code{%
if (NULL != new_bbox) {
THIS->_bounding_box = *new_bbox;
THIS->_bounding_box_valid = true;
}
if (!THIS->_bounding_box_valid) {
XSRETURN_UNDEF;
}
RETVAL = &THIS->_bounding_box;
%};
Clone<BoundingBoxf3> instance_bounding_box(int idx)
%code%{ RETVAL = THIS->instance_bounding_box(idx, true); %};
Clone<BoundingBoxf3> bounding_box();
%name{_add_volume} Ref<ModelVolume> add_volume(TriangleMesh* mesh)

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@ -64,8 +64,6 @@ _constant()
Ref<Point3> size()
%code%{ RETVAL = &THIS->size; %};
Clone<BoundingBox> bounding_box();
Ref<Point> _copies_shift()
%code%{ RETVAL = &THIS->_copies_shift; %};
bool typed_slices()
%code%{ RETVAL = THIS->typed_slices; %};