#include "Print.hpp" #include "BoundingBox.hpp" #include "ClipperUtils.hpp" #include "Geometry.hpp" #include namespace Slic3r { template bool PrintState::is_started(StepClass step) const { return this->started.find(step) != this->started.end(); } template bool PrintState::is_done(StepClass step) const { return this->done.find(step) != this->done.end(); } template void PrintState::set_started(StepClass step) { this->started.insert(step); } template void PrintState::set_done(StepClass step) { this->done.insert(step); } template bool PrintState::invalidate(StepClass step) { bool invalidated = this->started.erase(step) > 0; this->done.erase(step); return invalidated; } template class PrintState; template class PrintState; Print::Print() : total_used_filament(0), total_extruded_volume(0) { } Print::~Print() { clear_objects(); clear_regions(); } void Print::clear_objects() { for (int i = this->objects.size()-1; i >= 0; --i) this->delete_object(i); this->clear_regions(); } PrintObject* Print::get_object(size_t idx) { return objects.at(idx); } PrintObject* Print::add_object(ModelObject *model_object, const BoundingBoxf3 &modobj_bbox) { PrintObject *object = new PrintObject(this, model_object, modobj_bbox); objects.push_back(object); // invalidate steps this->invalidate_step(psSkirt); this->invalidate_step(psBrim); return object; } PrintObject* Print::set_new_object(size_t idx, ModelObject *model_object, const BoundingBoxf3 &modobj_bbox) { if (idx >= this->objects.size()) throw "bad idx"; PrintObjectPtrs::iterator old_it = this->objects.begin() + idx; // before deleting object, invalidate all of its steps in order to // invalidate all of the dependent ones in Print (*old_it)->invalidate_all_steps(); delete *old_it; PrintObject *object = new PrintObject(this, model_object, modobj_bbox); this->objects[idx] = object; return object; } void Print::delete_object(size_t idx) { PrintObjectPtrs::iterator i = this->objects.begin() + idx; delete *i; this->objects.erase(i); // TODO: purge unused regions this->state.invalidate(psSkirt); this->state.invalidate(psBrim); } void Print::reload_object(size_t idx) { /* TODO: this method should check whether the per-object config and per-material configs have changed in such a way that regions need to be rearranged or we can just apply the diff and invalidate something. Same logic as apply_config() For now we just re-add all objects since we haven't implemented this incremental logic yet. This should also check whether object volumes (parts) have changed. */ // collect all current model objects ModelObjectPtrs model_objects; FOREACH_OBJECT(this, object) { model_objects.push_back((*object)->model_object()); } // remove our print objects this->clear_objects(); // re-add model objects for (ModelObjectPtrs::iterator it = model_objects.begin(); it != model_objects.end(); ++it) { this->add_model_object(*it); } } void Print::clear_regions() { for (int i = this->regions.size()-1; i >= 0; --i) this->delete_region(i); } PrintRegion* Print::get_region(size_t idx) { return regions.at(idx); } PrintRegion* Print::add_region() { PrintRegion *region = new PrintRegion(this); regions.push_back(region); return region; } void Print::delete_region(size_t idx) { PrintRegionPtrs::iterator i = this->regions.begin() + idx; delete *i; this->regions.erase(i); } bool Print::invalidate_state_by_config_options(const std::vector &opt_keys) { std::set steps; // this method only accepts PrintConfig option keys for (std::vector::const_iterator opt_key = opt_keys.begin(); opt_key != opt_keys.end(); ++opt_key) { if (*opt_key == "skirts" || *opt_key == "skirt_height" || *opt_key == "skirt_distance" || *opt_key == "min_skirt_length") { steps.insert(psSkirt); } else if (*opt_key == "brim_width") { steps.insert(psBrim); steps.insert(psSkirt); } else if (*opt_key == "nozzle_diameter") { steps.insert(psInitExtruders); } else if (*opt_key == "avoid_crossing_perimeters" || *opt_key == "bed_shape" || *opt_key == "bed_temperature" || *opt_key == "bridge_acceleration" || *opt_key == "bridge_fan_speed" || *opt_key == "complete_objects" || *opt_key == "cooling" || *opt_key == "default_acceleration" || *opt_key == "disable_fan_first_layers" || *opt_key == "duplicate_distance" || *opt_key == "end_gcode" || *opt_key == "extruder_clearance_height" || *opt_key == "extruder_clearance_radius" || *opt_key == "extruder_offset" || *opt_key == "extrusion_axis" || *opt_key == "extrusion_multiplier" || *opt_key == "fan_always_on" || *opt_key == "fan_below_layer_time" || *opt_key == "filament_diameter" || *opt_key == "first_layer_acceleration" || *opt_key == "first_layer_bed_temperature" || *opt_key == "first_layer_speed" || *opt_key == "first_layer_temperature" || *opt_key == "gcode_arcs" || *opt_key == "gcode_comments" || *opt_key == "gcode_flavor" || *opt_key == "infill_acceleration" || *opt_key == "infill_first" || *opt_key == "layer_gcode" || *opt_key == "min_fan_speed" || *opt_key == "max_fan_speed" || *opt_key == "min_print_speed" || *opt_key == "notes" || *opt_key == "only_retract_when_crossing_perimeters" || *opt_key == "output_filename_format" || *opt_key == "perimeter_acceleration" || *opt_key == "post_process" || *opt_key == "retract_before_travel" || *opt_key == "retract_layer_change" || *opt_key == "retract_length" || *opt_key == "retract_length_toolchange" || *opt_key == "retract_lift" || *opt_key == "retract_restart_extra" || *opt_key == "retract_restart_extra_toolchange" || *opt_key == "retract_speed" || *opt_key == "slowdown_below_layer_time" || *opt_key == "spiral_vase" || *opt_key == "standby_temperature_delta" || *opt_key == "start_gcode" || *opt_key == "temperature" || *opt_key == "threads" || *opt_key == "toolchange_gcode" || *opt_key == "travel_speed" || *opt_key == "use_firmware_retraction" || *opt_key == "use_relative_e_distances" || *opt_key == "vibration_limit" || *opt_key == "wipe" || *opt_key == "z_offset") { // these options only affect G-code export, so nothing to invalidate } else { // for legacy, if we can't handle this option let's invalidate all steps return this->invalidate_all_steps(); } } bool invalidated = false; for (std::set::const_iterator step = steps.begin(); step != steps.end(); ++step) { if (this->invalidate_step(*step)) invalidated = true; } return invalidated; } bool Print::invalidate_step(PrintStep step) { bool invalidated = this->state.invalidate(step); // propagate to dependent steps if (step == psSkirt) { this->invalidate_step(psBrim); } else if (step == psInitExtruders) { FOREACH_OBJECT(this, object) { (*object)->invalidate_step(posPerimeters); (*object)->invalidate_step(posSupportMaterial); } } return invalidated; } bool Print::invalidate_all_steps() { // make a copy because when invalidating steps the iterators are not working anymore std::set steps = this->state.started; bool invalidated = false; for (std::set::const_iterator step = steps.begin(); step != steps.end(); ++step) { if (this->invalidate_step(*step)) invalidated = true; } return invalidated; } // returns true if an object step is done on all objects // and there's at least one object bool Print::step_done(PrintObjectStep step) const { if (this->objects.empty()) return false; FOREACH_OBJECT(this, object) { if (!(*object)->state.is_done(step)) return false; } return true; } // returns 0-based indices of used extruders std::set Print::extruders() const { std::set extruders; FOREACH_REGION(this, region) { extruders.insert((*region)->config.perimeter_extruder - 1); extruders.insert((*region)->config.infill_extruder - 1); } FOREACH_OBJECT(this, object) { extruders.insert((*object)->config.support_material_extruder - 1); extruders.insert((*object)->config.support_material_interface_extruder - 1); } return extruders; } void Print::_simplify_slices(double distance) { FOREACH_OBJECT(this, object) { FOREACH_LAYER(*object, layer) { (*layer)->slices.simplify(distance); FOREACH_LAYERREGION(*layer, layerm) { (*layerm)->slices.simplify(distance); } } } } double Print::max_allowed_layer_height() const { std::vector nozzle_diameter; std::set extruders = this->extruders(); for (std::set::const_iterator e = extruders.begin(); e != extruders.end(); ++e) { nozzle_diameter.push_back(this->config.nozzle_diameter.get_at(*e)); } return *std::max_element(nozzle_diameter.begin(), nozzle_diameter.end()); } /* Caller is responsible for supplying models whose objects don't collide and have explicit instance positions */ void Print::add_model_object(ModelObject* model_object, int idx) { DynamicPrintConfig object_config = model_object->config; // clone object_config.normalize(); // initialize print object and store it at the given position PrintObject* o; { BoundingBoxf3 bb; model_object->raw_bounding_box(&bb); o = (idx != -1) ? this->set_new_object(idx, model_object, bb) : this->add_object(model_object, bb); } for (ModelVolumePtrs::const_iterator v_i = model_object->volumes.begin(); v_i != model_object->volumes.end(); ++v_i) { size_t volume_id = v_i - model_object->volumes.begin(); ModelVolume* volume = *v_i; // get the config applied to this volume PrintRegionConfig config = this->_region_config_from_model_volume(*volume); // find an existing print region with the same config int region_id = -1; for (PrintRegionPtrs::const_iterator region = this->regions.begin(); region != this->regions.end(); ++region) { if (config.equals((*region)->config)) { region_id = region - this->regions.begin(); break; } } // if no region exists with the same config, create a new one if (region_id == -1) { PrintRegion* r = this->add_region(); r->config.apply(config); region_id = this->regions.size() - 1; } // assign volume to region o->add_region_volume(region_id, volume_id); } // apply config to print object o->config.apply(this->default_object_config); o->config.apply(object_config, true); } bool Print::apply_config(DynamicPrintConfig config) { // we get a copy of the config object so we can modify it safely config.normalize(); // apply variables to placeholder parser this->placeholder_parser.apply_config(config); bool invalidated = false; // handle changes to print config t_config_option_keys print_diff = this->config.diff(config); if (!print_diff.empty()) { this->config.apply(config, true); if (this->invalidate_state_by_config_options(print_diff)) invalidated = true; } // handle changes to object config defaults this->default_object_config.apply(config, true); FOREACH_OBJECT(this, obj_ptr) { // we don't assume that config contains a full ObjectConfig, // so we base it on the current print-wise default PrintObjectConfig new_config = this->default_object_config; new_config.apply(config, true); // we override the new config with object-specific options { DynamicPrintConfig model_object_config = (*obj_ptr)->model_object()->config; model_object_config.normalize(); new_config.apply(model_object_config, true); } // check whether the new config is different from the current one t_config_option_keys diff = (*obj_ptr)->config.diff(new_config); if (!diff.empty()) { (*obj_ptr)->config.apply(new_config, true); if ((*obj_ptr)->invalidate_state_by_config_options(diff)) invalidated = true; } } // handle changes to regions config defaults this->default_region_config.apply(config, true); // All regions now have distinct settings. // Check whether applying the new region config defaults we'd get different regions. bool rearrange_regions = false; std::vector other_region_configs; FOREACH_REGION(this, it_r) { size_t region_id = it_r - this->regions.begin(); PrintRegion* region = *it_r; std::vector this_region_configs; FOREACH_OBJECT(this, it_o) { PrintObject* object = *it_o; std::vector ®ion_volumes = object->region_volumes[region_id]; for (std::vector::const_iterator volume_id = region_volumes.begin(); volume_id != region_volumes.end(); ++volume_id) { ModelVolume* volume = object->model_object()->volumes[*volume_id]; PrintRegionConfig new_config = this->_region_config_from_model_volume(*volume); for (std::vector::iterator it = this_region_configs.begin(); it != this_region_configs.end(); ++it) { // if the new config for this volume differs from the other // volume configs currently associated to this region, it means // the region subdivision does not make sense anymore if (!it->equals(new_config)) { rearrange_regions = true; goto NEXT_REGION; } } this_region_configs.push_back(new_config); for (std::vector::iterator it = other_region_configs.begin(); it != other_region_configs.end(); ++it) { // if the new config for this volume equals any of the other // volume configs that are not currently associated to this // region, it means the region subdivision does not make // sense anymore if (it->equals(new_config)) { rearrange_regions = true; goto NEXT_REGION; } } // if we're here and the new region config is different from the old // one, we need to apply the new config and invalidate all objects // (possible optimization: only invalidate objects using this region) t_config_option_keys region_config_diff = region->config.diff(new_config); if (!region_config_diff.empty()) { region->config.apply(new_config); FOREACH_OBJECT(this, o) { if ((*o)->invalidate_state_by_config_options(region_config_diff)) invalidated = true; } } } } other_region_configs.insert(other_region_configs.end(), this_region_configs.begin(), this_region_configs.end()); NEXT_REGION: continue; } if (rearrange_regions) { // the current subdivision of regions does not make sense anymore. // we need to remove all objects and re-add them ModelObjectPtrs model_objects; FOREACH_OBJECT(this, o) { model_objects.push_back((*o)->model_object()); } this->clear_objects(); for (ModelObjectPtrs::iterator it = model_objects.begin(); it != model_objects.end(); ++it) { this->add_model_object(*it); } invalidated = true; } return invalidated; } void Print::init_extruders() { if (this->state.is_done(psInitExtruders)) return; this->state.set_done(psInitExtruders); // enforce tall skirt if using ooze_prevention // FIXME: this is not idempotent (i.e. switching ooze_prevention off will not revert skirt settings) if (this->config.ooze_prevention && this->extruders().size() > 1) { this->config.skirt_height.value = -1; if (this->config.skirts == 0) this->config.skirts.value = 1; } this->state.set_done(psInitExtruders); } void Print::validate() const { if (this->config.complete_objects) { // check horizontal clearance { Polygons a; FOREACH_OBJECT(this, i_object) { PrintObject* object = *i_object; // get convex hulls of all meshes assigned to this print object Polygons mesh_convex_hulls; for (size_t i = 0; i < this->regions.size(); ++i) { for (std::vector::const_iterator it = object->region_volumes[i].begin(); it != object->region_volumes[i].end(); ++it) { Polygon hull; object->model_object()->volumes[*it]->mesh.convex_hull(&hull); mesh_convex_hulls.push_back(hull); } } // make a single convex hull for all of them Polygon convex_hull; Slic3r::Geometry::convex_hull(mesh_convex_hulls, &convex_hull); // apply the same transformations we apply to the actual meshes when slicing them object->model_object()->instances.front()->transform_polygon(&convex_hull); // align object to Z = 0 and apply XY shift convex_hull.translate(object->_copies_shift); // grow convex hull with the clearance margin { Polygons grown_hull; offset(convex_hull, &grown_hull, scale_(this->config.extruder_clearance_radius.value)/2, 1, jtRound, scale_(0.1)); convex_hull = grown_hull.front(); } // now we check that no instance of convex_hull intersects any of the previously checked object instances for (Points::const_iterator copy = object->_shifted_copies.begin(); copy != object->_shifted_copies.end(); ++copy) { Polygon p = convex_hull; p.translate(*copy); if (intersects(a, p)) throw PrintValidationException("Some objects are too close; your extruder will collide with them."); union_(a, p, &a); } } } // check vertical clearance { std::vector object_height; FOREACH_OBJECT(this, i_object) { PrintObject* object = *i_object; object_height.insert(object_height.end(), object->copies().size(), object->size.z); } std::sort(object_height.begin(), object_height.end()); // ignore the tallest *copy* (this is why we repeat height for all of them): // it will be printed as last one so its height doesn't matter object_height.pop_back(); if (!object_height.empty() && object_height.back() > scale_(this->config.extruder_clearance_height.value)) throw PrintValidationException("Some objects are too tall and cannot be printed without extruder collisions."); } } if (this->config.spiral_vase) { size_t total_copies_count = 0; FOREACH_OBJECT(this, i_object) total_copies_count += (*i_object)->copies().size(); if (total_copies_count > 1) throw PrintValidationException("The Spiral Vase option can only be used when printing a single object."); if (this->regions.size() > 1) throw PrintValidationException("The Spiral Vase option can only be used when printing single material objects."); } { std::vector layer_heights; FOREACH_OBJECT(this, i_object) { PrintObject* object = *i_object; layer_heights.push_back(object->config.layer_height); layer_heights.push_back(object->config.get_abs_value("first_layer_height")); } double max_layer_height = *std::max_element(layer_heights.begin(), layer_heights.end()); std::set extruders = this->extruders(); for (std::set::iterator it = extruders.begin(); it != extruders.end(); ++it) { if (max_layer_height > this->config.nozzle_diameter.get_at(*it)) throw PrintValidationException("Layer height can't be greater than nozzle diameter"); } } } PrintRegionConfig Print::_region_config_from_model_volume(const ModelVolume &volume) { PrintRegionConfig config = this->default_region_config; { DynamicPrintConfig other_config = volume.get_object()->config; other_config.normalize(); config.apply(other_config, true); } { DynamicPrintConfig other_config = volume.config; other_config.normalize(); config.apply(other_config, true); } if (!volume.material_id().empty()) { DynamicPrintConfig material_config = volume.material()->config; material_config.normalize(); config.apply(material_config, true); } return config; } bool Print::has_support_material() const { FOREACH_OBJECT(this, object) { PrintObjectConfig &config = (*object)->config; if (config.support_material || config.raft_layers > 0 || config.support_material_enforce_layers > 0) return true; } return false; } #ifdef SLIC3RXS REGISTER_CLASS(Print, "Print"); #endif }