PrusaSlicer-NonPlainar/xs/xsp/Print.xsp

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%module{Slic3r::XS};
%{
#include <xsinit.h>
#include "libslic3r/Print.hpp"
#include "libslic3r/PlaceholderParser.hpp"
%}
%package{Slic3r::Print::State};
%{
IV
_constant()
ALIAS:
STEP_SLICE = posSlice
STEP_PERIMETERS = posPerimeters
STEP_PREPARE_INFILL = posPrepareInfill
STEP_INFILL = posInfill
STEP_SUPPORTMATERIAL = posSupportMaterial
STEP_SKIRT = psSkirt
STEP_BRIM = psBrim
STEP_WIPE_TOWER = psWipeTower
PROTOTYPE:
CODE:
RETVAL = ix;
OUTPUT: RETVAL
%}
%name{Slic3r::Print::Region} class PrintRegion {
// owned by Print, no constructor/destructor
Ref<StaticPrintConfig> config()
%code%{ RETVAL = &THIS->config(); %};
Ref<Print> print();
Clone<Flow> flow(FlowRole role, double layer_height, bool bridge, bool first_layer, double width, PrintObject* object)
%code%{ RETVAL = THIS->flow(role, layer_height, bridge, first_layer, width, *object); %};
};
%name{Slic3r::Print::Object} class PrintObject {
// owned by Print, no constructor/destructor
int region_count()
%code%{ RETVAL = THIS->print()->regions().size(); %};
Ref<Print> print();
Ref<ModelObject> model_object();
Ref<StaticPrintConfig> config()
%code%{ RETVAL = &THIS->config(); %};
Points copies();
t_layer_height_ranges layer_height_ranges()
%code%{ RETVAL = THIS->layer_height_ranges; %};
std::vector<double> layer_height_profile()
%code%{ RETVAL = THIS->layer_height_profile; %};
Clone<BoundingBox> bounding_box();
Points _shifted_copies()
%code%{ RETVAL = THIS->copies(); %};
void set_layer_height_ranges(t_layer_height_ranges layer_height_ranges)
%code%{ THIS->layer_height_ranges = layer_height_ranges; %};
size_t layer_count();
Ref<Layer> get_layer(int idx);
size_t support_layer_count();
Ref<SupportLayer> get_support_layer(int idx);
bool step_done(PrintObjectStep step)
%code%{ RETVAL = THIS->is_step_done(step); %};
void slice();
};
%name{Slic3r::Print} class Print {
Print();
~Print();
Ref<StaticPrintConfig> config()
%code%{ RETVAL = const_cast<GCodeConfig*>(static_cast<const GCodeConfig*>(&THIS->config())); %};
Ref<PlaceholderParser> placeholder_parser()
%code%{ RETVAL = &THIS->placeholder_parser(); %};
Ref<ExtrusionEntityCollection> skirt()
%code%{ RETVAL = const_cast<ExtrusionEntityCollection*>(&THIS->skirt()); %};
Ref<ExtrusionEntityCollection> brim()
%code%{ RETVAL = const_cast<ExtrusionEntityCollection*>(&THIS->brim()); %};
std::string estimated_normal_print_time()
%code%{ RETVAL = THIS->print_statistics().estimated_normal_print_time; %};
std::string estimated_silent_print_time()
%code%{ RETVAL = THIS->print_statistics().estimated_silent_print_time; %};
double total_used_filament()
%code%{ RETVAL = THIS->print_statistics().total_used_filament; %};
double total_extruded_volume()
%code%{ RETVAL = THIS->print_statistics().total_extruded_volume; %};
double total_weight()
%code%{ RETVAL = THIS->print_statistics().total_weight; %};
double total_cost()
%code%{ RETVAL = THIS->print_statistics().total_cost; %};
double total_wipe_tower_cost()
%code%{ RETVAL = THIS->print_statistics().total_wipe_tower_cost; %};
double total_wipe_tower_filament()
%code%{ RETVAL = THIS->print_statistics().total_wipe_tower_filament; %};
int wipe_tower_number_of_toolchanges()
%code%{ RETVAL = THIS->wipe_tower_data().number_of_toolchanges; %};
PrintObjectPtrs* objects()
%code%{ RETVAL = const_cast<PrintObjectPtrs*>(&THIS->objects()); %};
Ref<PrintObject> get_object(int idx)
%code%{ RETVAL = THIS->objects()[idx]; %};
void reload_object(int idx);
size_t object_count()
%code%{ RETVAL = THIS->objects().size(); %};
PrintRegionPtrs* regions()
%code%{ RETVAL = const_cast<PrintRegionPtrs*>(&THIS->regions()); %};
Ref<PrintRegion> get_region(int idx)
%code%{ RETVAL = THIS->regions()[idx]; %};
size_t region_count()
%code%{ RETVAL = THIS->regions().size(); %};
bool step_done(PrintStep step)
%code%{ RETVAL = THIS->is_step_done(step); %};
bool object_step_done(PrintObjectStep step)
%code%{ RETVAL = THIS->is_step_done(step); %};
SV* filament_stats()
%code%{
HV* hv = newHV();
for (std::map<size_t,float>::const_iterator it = THIS->print_statistics().filament_stats.begin(); it != THIS->print_statistics().filament_stats.end(); ++it) {
// stringify extruder_id
std::ostringstream ss;
ss << it->first;
std::string str = ss.str();
(void)hv_store( hv, str.c_str(), str.length(), newSViv(it->second), 0 );
RETVAL = newRV_noinc((SV*)hv);
}
%};
double max_allowed_layer_height() const;
bool has_support_material() const;
void auto_assign_extruders(ModelObject* model_object);
std::string output_filepath(std::string path = "")
%code%{
try {
RETVAL = THIS->output_filepath(path);
} catch (std::exception& e) {
croak("%s\n", e.what());
}
%};
void add_model_object(ModelObject* model_object, int idx = -1);
bool apply_config(DynamicPrintConfig* config)
%code%{ RETVAL = THIS->apply_config(*config); %};
bool has_infinite_skirt();
std::vector<unsigned int> extruders() const;
int validate() %code%{
std::string err = THIS->validate();
if (! err.empty())
croak("Configuration is not valid: %s\n", err.c_str());
RETVAL = 1;
%};
Clone<BoundingBox> bounding_box();
Clone<BoundingBox> total_bounding_box();
Clone<Point> size() %code%{ RETVAL = THIS->bounding_box().size(); %};
void set_callback_event(int evt) %code%{
%};
void set_status_silent();
void set_status(int percent, const char *message);
void process() %code%{
try {
THIS->process();
} catch (std::exception& e) {
croak(e.what());
}
%};
void export_gcode(char *path_template) %code%{
try {
THIS->export_gcode(path_template, nullptr);
} catch (std::exception& e) {
croak(e.what());
}
%};
void export_png(char *path) %code%{
try {
THIS->export_png(path);
} catch (std::exception& e) {
croak(e.what());
}
%};
};