PrusaSlicer-NonPlainar/xs/src/Print.cpp

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#include "Print.hpp"
#include "BoundingBox.hpp"
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namespace Slic3r {
template <class StepClass>
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bool
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PrintState<StepClass>::is_started(StepClass step) const
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{
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return this->started.find(step) != this->started.end();
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}
template <class StepClass>
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bool
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PrintState<StepClass>::is_done(StepClass step) const
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{
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return this->done.find(step) != this->done.end();
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}
template <class StepClass>
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void
PrintState<StepClass>::set_started(StepClass step)
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{
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this->started.insert(step);
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}
template <class StepClass>
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void
PrintState<StepClass>::set_done(StepClass step)
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{
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this->done.insert(step);
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}
template <class StepClass>
bool
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PrintState<StepClass>::invalidate(StepClass step)
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{
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bool invalidated = this->started.erase(step) > 0;
this->done.erase(step);
return invalidated;
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}
template class PrintState<PrintStep>;
template class PrintState<PrintObjectStep>;
PrintRegion::PrintRegion(Print* print)
: _print(print)
{
}
PrintRegion::~PrintRegion()
{
}
Print*
PrintRegion::print()
{
return this->_print;
}
#ifdef SLIC3RXS
REGISTER_CLASS(PrintRegion, "Print::Region");
#endif
PrintObject::PrintObject(Print* print, ModelObject* model_object, const BoundingBoxf3 &modobj_bbox)
: _print(print),
_model_object(model_object)
{
region_volumes.resize(this->_print->regions.size());
// Compute the translation to be applied to our meshes so that we work with smaller coordinates
{
// Translate meshes so that our toolpath generation algorithms work with smaller
// XY coordinates; this translation is an optimization and not strictly required.
// A cloned mesh will be aligned to 0 before slicing in _slice_region() since we
// don't assume it's already aligned and we don't alter the original position in model.
// We store the XY translation so that we can place copies correctly in the output G-code
// (copies are expressed in G-code coordinates and this translation is not publicly exposed).
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this->_copies_shift = Point(
scale_(modobj_bbox.min.x), scale_(modobj_bbox.min.y));
// TODO: $self->_trigger_copies;
// Scale the object size and store it
Pointf3 size = modobj_bbox.size();
this->size = Point3(scale_(size.x), scale_(size.y), scale_(size.z));
}
}
PrintObject::~PrintObject()
{
}
Print*
PrintObject::print()
{
return this->_print;
}
ModelObject*
PrintObject::model_object()
{
return this->_model_object;
}
void
PrintObject::add_region_volume(int region_id, int volume_id)
{
if (region_id >= region_volumes.size()) {
region_volumes.resize(region_id + 1);
}
region_volumes[region_id].push_back(volume_id);
}
size_t
PrintObject::layer_count()
{
return this->layers.size();
}
void
PrintObject::clear_layers()
{
for (int i = this->layers.size()-1; i >= 0; --i)
this->delete_layer(i);
}
Layer*
PrintObject::get_layer(int idx)
{
return this->layers.at(idx);
}
Layer*
PrintObject::add_layer(int id, coordf_t height, coordf_t print_z, coordf_t slice_z)
{
Layer* layer = new Layer(id, this, height, print_z, slice_z);
layers.push_back(layer);
return layer;
}
void
PrintObject::delete_layer(int idx)
{
LayerPtrs::iterator i = this->layers.begin() + idx;
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delete *i;
this->layers.erase(i);
}
size_t
PrintObject::support_layer_count()
{
return this->support_layers.size();
}
void
PrintObject::clear_support_layers()
{
for (int i = this->support_layers.size()-1; i >= 0; --i)
this->delete_support_layer(i);
}
SupportLayer*
PrintObject::get_support_layer(int idx)
{
return this->support_layers.at(idx);
}
SupportLayer*
PrintObject::add_support_layer(int id, coordf_t height, coordf_t print_z,
coordf_t slice_z)
{
SupportLayer* layer = new SupportLayer(id, this, height, print_z, slice_z);
support_layers.push_back(layer);
return layer;
}
void
PrintObject::delete_support_layer(int idx)
{
SupportLayerPtrs::iterator i = this->support_layers.begin() + idx;
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delete *i;
this->support_layers.erase(i);
}
bool
PrintObject::invalidate_state_by_config_options(const std::vector<t_config_option_key> &opt_keys)
{
std::set<PrintObjectStep> steps;
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// this method only accepts PrintObjectConfig and PrintRegionConfig option keys
for (std::vector<t_config_option_key>::const_iterator opt_key = opt_keys.begin(); opt_key != opt_keys.end(); ++opt_key) {
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if (*opt_key == "perimeters"
|| *opt_key == "extra_perimeters"
|| *opt_key == "gap_fill_speed"
|| *opt_key == "overhangs"
|| *opt_key == "perimeter_extrusion_width"
|| *opt_key == "thin_walls"
|| *opt_key == "external_perimeters_first") {
steps.insert(posPerimeters);
} else if (*opt_key == "resolution"
|| *opt_key == "layer_height"
|| *opt_key == "first_layer_height"
|| *opt_key == "xy_size_compensation"
|| *opt_key == "raft_layers") {
steps.insert(posSlice);
} else if (*opt_key == "support_material"
|| *opt_key == "support_material_angle"
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|| *opt_key == "support_material_extruder"
|| *opt_key == "support_material_extrusion_width"
|| *opt_key == "support_material_interface_layers"
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|| *opt_key == "support_material_interface_extruder"
|| *opt_key == "support_material_interface_spacing"
|| *opt_key == "support_material_interface_speed"
|| *opt_key == "support_material_pattern"
|| *opt_key == "support_material_spacing"
|| *opt_key == "support_material_threshold"
|| *opt_key == "dont_support_bridges") {
steps.insert(posSupportMaterial);
} else if (*opt_key == "interface_shells"
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|| *opt_key == "infill_only_where_needed"
|| *opt_key == "bottom_solid_layers"
|| *opt_key == "top_solid_layers"
|| *opt_key == "infill_extruder"
|| *opt_key == "infill_extrusion_width") {
steps.insert(posPrepareInfill);
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} else if (*opt_key == "fill_angle"
|| *opt_key == "fill_pattern"
|| *opt_key == "solid_fill_pattern"
|| *opt_key == "infill_every_layers"
|| *opt_key == "solid_infill_below_area"
|| *opt_key == "solid_infill_every_layers"
|| *opt_key == "top_infill_extrusion_width") {
steps.insert(posInfill);
} else if (*opt_key == "fill_density"
|| *opt_key == "solid_infill_extrusion_width") {
steps.insert(posPerimeters);
steps.insert(posPrepareInfill);
} else if (*opt_key == "external_perimeter_extrusion_width"
|| *opt_key == "perimeter_extruder") {
steps.insert(posPerimeters);
steps.insert(posSupportMaterial);
} else if (*opt_key == "bridge_flow_ratio") {
steps.insert(posPerimeters);
steps.insert(posInfill);
} else if (*opt_key == "seam_position"
|| *opt_key == "support_material_speed"
|| *opt_key == "bridge_speed"
|| *opt_key == "external_perimeter_speed"
|| *opt_key == "infill_speed"
|| *opt_key == "perimeter_speed"
|| *opt_key == "small_perimeter_speed"
|| *opt_key == "solid_infill_speed"
|| *opt_key == "top_solid_infill_speed") {
// these options only affect G-code export, so nothing to invalidate
} else {
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// for legacy, if we can't handle this option let's invalidate all steps
return this->invalidate_all_steps();
}
}
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bool invalidated = false;
for (std::set<PrintObjectStep>::const_iterator step = steps.begin(); step != steps.end(); ++step) {
if (this->invalidate_step(*step)) invalidated = true;
}
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return invalidated;
}
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bool
PrintObject::invalidate_step(PrintObjectStep step)
{
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bool invalidated = this->state.invalidate(step);
// propagate to dependent steps
if (step == posPerimeters) {
this->invalidate_step(posPrepareInfill);
this->_print->invalidate_step(psSkirt);
this->_print->invalidate_step(psBrim);
} else if (step == posPrepareInfill) {
this->invalidate_step(posInfill);
} else if (step == posInfill) {
this->_print->invalidate_step(psSkirt);
this->_print->invalidate_step(psBrim);
} else if (step == posSlice) {
this->invalidate_step(posPerimeters);
this->invalidate_step(posSupportMaterial);
}
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return invalidated;
}
bool
PrintObject::invalidate_all_steps()
{
// make a copy because when invalidating steps the iterators are not working anymore
std::set<PrintObjectStep> steps = this->state.started;
bool invalidated = false;
for (std::set<PrintObjectStep>::const_iterator step = steps.begin(); step != steps.end(); ++step) {
if (this->invalidate_step(*step)) invalidated = true;
}
return invalidated;
}
#ifdef SLIC3RXS
REGISTER_CLASS(PrintObject, "Print::Object");
#endif
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*
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Print::get_object(size_t idx)
{
return objects.at(idx);
}
PrintObject*
Print::add_object(ModelObject *model_object, const BoundingBoxf3 &modobj_bbox)
{
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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*
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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;
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PrintObject *object = new PrintObject(this, model_object, modobj_bbox);
this->objects[idx] = object;
return object;
}
void
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Print::delete_object(size_t idx)
{
PrintObjectPtrs::iterator i = this->objects.begin() + idx;
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delete *i;
this->objects.erase(i);
// TODO: purge unused regions
this->state.invalidate(psSkirt);
this->state.invalidate(psBrim);
}
void
Print::clear_regions()
{
for (int i = this->regions.size()-1; i >= 0; --i)
this->delete_region(i);
}
PrintRegion*
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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
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Print::delete_region(size_t idx)
{
PrintRegionPtrs::iterator i = this->regions.begin() + idx;
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delete *i;
this->regions.erase(i);
}
bool
Print::invalidate_state_by_config_options(const std::vector<t_config_option_key> &opt_keys)
{
std::set<PrintStep> steps;
// this method only accepts PrintConfig option keys
for (std::vector<t_config_option_key>::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);
} 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 == "g0"
|| *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 {
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// for legacy, if we can't handle this option let's invalidate all steps
return this->invalidate_all_steps();
}
}
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bool invalidated = false;
for (std::set<PrintStep>::const_iterator step = steps.begin(); step != steps.end(); ++step) {
if (this->invalidate_step(*step)) invalidated = true;
}
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return invalidated;
}
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bool
Print::invalidate_step(PrintStep step)
{
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bool invalidated = this->state.invalidate(step);
// propagate to dependent steps
if (step == psSkirt) {
this->invalidate_step(psBrim);
} else if (step == psInitExtruders) {
for (PrintObjectPtrs::iterator object = this->objects.begin(); object != this->objects.end(); ++object) {
(*object)->invalidate_step(posPerimeters);
(*object)->invalidate_step(posSupportMaterial);
}
}
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return invalidated;
}
bool
Print::invalidate_all_steps()
{
// make a copy because when invalidating steps the iterators are not working anymore
std::set<PrintStep> steps = this->state.started;
bool invalidated = false;
for (std::set<PrintStep>::const_iterator step = steps.begin(); step != steps.end(); ++step) {
if (this->invalidate_step(*step)) invalidated = true;
}
return invalidated;
}
#ifdef SLIC3RXS
REGISTER_CLASS(Print, "Print");
#endif
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}