PrusaSlicer-NonPlainar/xs/src/libslic3r/PrintObject.cpp

#include "Print.hpp"
#include "BoundingBox.hpp"

namespace Slic3r {

PrintObject::PrintObject(Print* print, ModelObject* model_object, const BoundingBoxf3 &modobj_bbox)
:   _print(print),
    _model_object(model_object),
    typed_slices(false)
{
    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).
        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;
    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;
    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;
    
    // 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) {
        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"
            || *opt_key == "support_material_extruder"
            || *opt_key == "support_material_extrusion_width"
            || *opt_key == "support_material_interface_layers"
            || *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"
            || *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);
        } 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 {
            // 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<PrintObjectStep>::const_iterator step = steps.begin(); step != steps.end(); ++step) {
        if (this->invalidate_step(*step)) invalidated = true;
    }
    
    return invalidated;
}

bool
PrintObject::invalidate_step(PrintObjectStep step)
{
    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);
    }
    
    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

}
Split Print.cpp and Layer.cpp into multiple compilation units 2014-08-03 17:28:40 +00:00			`#include "Print.hpp"`
			`#include "BoundingBox.hpp"`

			`namespace Slic3r {`

			`PrintObject::PrintObject(Print* print, ModelObject* model_object, const BoundingBoxf3 &modobj_bbox)`
			`: _print(print),`
			`_model_object(model_object),`
			`typed_slices(false)`
			`{`
			`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).`
			`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;`
			`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;`
			`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;`

			`// 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) {`
			`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"`
			`\|\| *opt_key == "support_material_extruder"`
			`\|\| *opt_key == "support_material_extrusion_width"`
			`\|\| *opt_key == "support_material_interface_layers"`
			`\|\| *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"`
			`\|\| *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);`
			`} 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 {`
			`// 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<PrintObjectStep>::const_iterator step = steps.begin(); step != steps.end(); ++step) {`
			`if (this->invalidate_step(*step)) invalidated = true;`
			`}`

			`return invalidated;`
			`}`

			`bool`
			`PrintObject::invalidate_step(PrintObjectStep step)`
			`{`
			`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);`
			`}`

			`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`

			`}`