// Configuration store of Slic3r. // // The configuration store is either static or dynamic. // DynamicPrintConfig is used mainly at the user interface. while the StaticPrintConfig is used // during the slicing and the g-code generation. // // The classes derived from StaticPrintConfig form a following hierarchy. // // FullPrintConfig // PrintObjectConfig // PrintRegionConfig // PrintConfig // GCodeConfig // HostConfig // #ifndef slic3r_PrintConfig_hpp_ #define slic3r_PrintConfig_hpp_ #include "libslic3r.h" #include "Config.hpp" namespace Slic3r { enum GCodeFlavor { gcfRepRap, gcfRepetier, gcfTeacup, gcfMakerWare, gcfMarlin, gcfSailfish, gcfMach3, gcfMachinekit, gcfSmoothie, gcfNoExtrusion, }; enum InfillPattern { ipRectilinear, ipGrid, ipTriangles, ipStars, ipCubic, ipLine, ipConcentric, ipHoneycomb, ip3DHoneycomb, ipGyroid, ipHilbertCurve, ipArchimedeanChords, ipOctagramSpiral, }; enum SupportMaterialPattern { smpRectilinear, smpRectilinearGrid, smpHoneycomb, }; enum SeamPosition { spRandom, spNearest, spAligned, spRear }; enum FilamentType { ftPLA, ftABS, ftPET, ftHIPS, ftFLEX, ftSCAFF, ftEDGE, ftNGEN, ftPVA }; template<> inline t_config_enum_values& ConfigOptionEnum::get_enum_values() { static t_config_enum_values keys_map; if (keys_map.empty()) { keys_map["reprap"] = gcfRepRap; keys_map["repetier"] = gcfRepetier; keys_map["teacup"] = gcfTeacup; keys_map["makerware"] = gcfMakerWare; keys_map["marlin"] = gcfMarlin; keys_map["sailfish"] = gcfSailfish; keys_map["smoothie"] = gcfSmoothie; keys_map["mach3"] = gcfMach3; keys_map["machinekit"] = gcfMachinekit; keys_map["no-extrusion"] = gcfNoExtrusion; } return keys_map; } template<> inline t_config_enum_values& ConfigOptionEnum::get_enum_values() { static t_config_enum_values keys_map; if (keys_map.empty()) { keys_map["rectilinear"] = ipRectilinear; keys_map["grid"] = ipGrid; keys_map["triangles"] = ipTriangles; keys_map["stars"] = ipStars; keys_map["cubic"] = ipCubic; keys_map["line"] = ipLine; keys_map["concentric"] = ipConcentric; keys_map["honeycomb"] = ipHoneycomb; keys_map["3dhoneycomb"] = ip3DHoneycomb; keys_map["gyroid"] = ipGyroid; keys_map["hilbertcurve"] = ipHilbertCurve; keys_map["archimedeanchords"] = ipArchimedeanChords; keys_map["octagramspiral"] = ipOctagramSpiral; } return keys_map; } template<> inline t_config_enum_values& ConfigOptionEnum::get_enum_values() { static t_config_enum_values keys_map; if (keys_map.empty()) { keys_map["rectilinear"] = smpRectilinear; keys_map["rectilinear-grid"] = smpRectilinearGrid; keys_map["honeycomb"] = smpHoneycomb; } return keys_map; } template<> inline t_config_enum_values& ConfigOptionEnum::get_enum_values() { static t_config_enum_values keys_map; if (keys_map.empty()) { keys_map["random"] = spRandom; keys_map["nearest"] = spNearest; keys_map["aligned"] = spAligned; keys_map["rear"] = spRear; } return keys_map; } template<> inline t_config_enum_values& ConfigOptionEnum::get_enum_values() { static t_config_enum_values keys_map; if (keys_map.empty()) { keys_map["PLA"] = ftPLA; keys_map["ABS"] = ftABS; keys_map["PET"] = ftPET; keys_map["HIPS"] = ftHIPS; keys_map["FLEX"] = ftFLEX; keys_map["SCAFF"] = ftSCAFF; keys_map["EDGE"] = ftEDGE; keys_map["NGEN"] = ftNGEN; keys_map["PVA"] = ftPVA; } return keys_map; } // Defines each and every confiuration option of Slic3r, including the properties of the GUI dialogs. // Does not store the actual values, but defines default values. class PrintConfigDef : public ConfigDef { public: PrintConfigDef(); static void handle_legacy(t_config_option_key &opt_key, std::string &value); }; // The one and only global definition of SLic3r configuration options. // This definition is constant. extern PrintConfigDef print_config_def; // Slic3r dynamic configuration, used to override the configuration // per object, per modification volume or per printing material. // The dynamic configuration is also used to store user modifications of the print global parameters, // so the modified configuration values may be diffed against the active configuration // to invalidate the proper slicing resp. g-code generation processing steps. // This object is mapped to Perl as Slic3r::Config. class DynamicPrintConfig : public DynamicConfig { public: DynamicPrintConfig() {} DynamicPrintConfig(const DynamicPrintConfig &other) : DynamicConfig(other) {} static DynamicPrintConfig* new_from_defaults(); static DynamicPrintConfig* new_from_defaults_keys(const std::vector &keys); // Overrides ConfigBase::def(). Static configuration definition. Any value stored into this ConfigBase shall have its definition here. const ConfigDef* def() const override { return &print_config_def; } void normalize(); // Validate the PrintConfig. Returns an empty string on success, otherwise an error message is returned. std::string validate(); // Verify whether the opt_key has not been obsoleted or renamed. // Both opt_key and value may be modified by handle_legacy(). // If the opt_key is no more valid in this version of Slic3r, opt_key is cleared by handle_legacy(). // handle_legacy() is called internally by set_deserialize(). void handle_legacy(t_config_option_key &opt_key, std::string &value) const override { PrintConfigDef::handle_legacy(opt_key, value); } }; template void normalize_and_apply_config(CONFIG &dst, const DynamicPrintConfig &src) { DynamicPrintConfig src_normalized(src); src_normalized.normalize(); dst.apply(src_normalized, true); } class StaticPrintConfig : public StaticConfig { public: StaticPrintConfig() {} // Overrides ConfigBase::def(). Static configuration definition. Any value stored into this ConfigBase shall have its definition here. const ConfigDef* def() const override { return &print_config_def; } protected: // Verify whether the opt_key has not been obsoleted or renamed. // Both opt_key and value may be modified by handle_legacy(). // If the opt_key is no more valid in this version of Slic3r, opt_key is cleared by handle_legacy(). // handle_legacy() is called internally by set_deserialize(). void handle_legacy(t_config_option_key &opt_key, std::string &value) const override { PrintConfigDef::handle_legacy(opt_key, value); } // Internal class for keeping a dynamic map to static options. class StaticCacheBase { public: // To be called during the StaticCache setup. // Add one ConfigOption into m_map_name_to_offset. template void opt_add(const std::string &name, const char *base_ptr, const T &opt) { assert(m_map_name_to_offset.find(name) == m_map_name_to_offset.end()); m_map_name_to_offset[name] = (const char*)&opt - base_ptr; } protected: std::map m_map_name_to_offset; }; // Parametrized by the type of the topmost class owning the options. template class StaticCache : public StaticCacheBase { public: // Calling the constructor of m_defaults with 0 forces m_defaults to not run the initialization. StaticCache() : m_defaults(nullptr) {} ~StaticCache() { delete m_defaults; m_defaults = nullptr; } bool initialized() const { return ! m_keys.empty(); } ConfigOption* optptr(const std::string &name, T *owner) const { const auto it = m_map_name_to_offset.find(name); return (it == m_map_name_to_offset.end()) ? nullptr : reinterpret_cast((char*)owner + it->second); } const ConfigOption* optptr(const std::string &name, const T *owner) const { const auto it = m_map_name_to_offset.find(name); return (it == m_map_name_to_offset.end()) ? nullptr : reinterpret_cast((const char*)owner + it->second); } const std::vector& keys() const { return m_keys; } const T& defaults() const { return *m_defaults; } // To be called during the StaticCache setup. // Collect option keys from m_map_name_to_offset, // assign default values to m_defaults. void finalize(T *defaults, const ConfigDef *defs) { assert(defs != nullptr); m_defaults = defaults; m_keys.clear(); m_keys.reserve(m_map_name_to_offset.size()); for (const auto &kvp : defs->options) { // Find the option given the option name kvp.first by an offset from (char*)m_defaults. ConfigOption *opt = this->optptr(kvp.first, m_defaults); if (opt == nullptr) // This option is not defined by the ConfigBase of type T. continue; m_keys.emplace_back(kvp.first); const ConfigOptionDef *def = defs->get(kvp.first); assert(def != nullptr); if (def->default_value != nullptr) opt->set(def->default_value); } } private: T *m_defaults; std::vector m_keys; }; }; #define STATIC_PRINT_CONFIG_CACHE_BASE(CLASS_NAME) \ public: \ /* Overrides ConfigBase::optptr(). Find ando/or create a ConfigOption instance for a given name. */ \ ConfigOption* optptr(const t_config_option_key &opt_key, bool create = false) override \ { return s_cache_##CLASS_NAME.optptr(opt_key, this); } \ /* Overrides ConfigBase::keys(). Collect names of all configuration values maintained by this configuration store. */ \ t_config_option_keys keys() const override { return s_cache_##CLASS_NAME.keys(); } \ static const CLASS_NAME& defaults() { initialize_cache(); return s_cache_##CLASS_NAME.defaults(); } \ private: \ static void initialize_cache() \ { \ if (! s_cache_##CLASS_NAME.initialized()) { \ CLASS_NAME *inst = new CLASS_NAME(1); \ inst->initialize(s_cache_##CLASS_NAME, (const char*)inst); \ s_cache_##CLASS_NAME.finalize(inst, inst->def()); \ } \ } \ /* Cache object holding a key/option map, a list of option keys and a copy of this static config initialized with the defaults. */ \ static StaticPrintConfig::StaticCache s_cache_##CLASS_NAME; #define STATIC_PRINT_CONFIG_CACHE(CLASS_NAME) \ STATIC_PRINT_CONFIG_CACHE_BASE(CLASS_NAME) \ public: \ /* Public default constructor will initialize the key/option cache and the default object copy if needed. */ \ CLASS_NAME() { initialize_cache(); *this = s_cache_##CLASS_NAME.defaults(); } \ protected: \ /* Protected constructor to be called when compounded. */ \ CLASS_NAME(int) {} #define STATIC_PRINT_CONFIG_CACHE_DERIVED(CLASS_NAME) \ STATIC_PRINT_CONFIG_CACHE_BASE(CLASS_NAME) \ public: \ /* Overrides ConfigBase::def(). Static configuration definition. Any value stored into this ConfigBase shall have its definition here. */ \ const ConfigDef* def() const override { return &print_config_def; } \ /* Handle legacy and obsoleted config keys */ \ void handle_legacy(t_config_option_key &opt_key, std::string &value) const override \ { PrintConfigDef::handle_legacy(opt_key, value); } #define OPT_PTR(KEY) cache.opt_add(#KEY, base_ptr, this->KEY) // This object is mapped to Perl as Slic3r::Config::PrintObject. class PrintObjectConfig : public StaticPrintConfig { STATIC_PRINT_CONFIG_CACHE(PrintObjectConfig) public: ConfigOptionBool clip_multipart_objects; ConfigOptionBool dont_support_bridges; ConfigOptionFloat elefant_foot_compensation; ConfigOptionFloatOrPercent extrusion_width; ConfigOptionFloatOrPercent first_layer_height; ConfigOptionBool infill_only_where_needed; ConfigOptionBool interface_shells; ConfigOptionFloat layer_height; ConfigOptionInt raft_layers; ConfigOptionEnum seam_position; // ConfigOptionFloat seam_preferred_direction; // ConfigOptionFloat seam_preferred_direction_jitter; ConfigOptionBool support_material; ConfigOptionFloat support_material_angle; ConfigOptionBool support_material_buildplate_only; ConfigOptionFloat support_material_contact_distance; ConfigOptionInt support_material_enforce_layers; ConfigOptionInt support_material_extruder; ConfigOptionFloatOrPercent support_material_extrusion_width; ConfigOptionBool support_material_interface_contact_loops; ConfigOptionInt support_material_interface_extruder; ConfigOptionInt support_material_interface_layers; ConfigOptionFloat support_material_interface_spacing; ConfigOptionFloatOrPercent support_material_interface_speed; ConfigOptionEnum support_material_pattern; ConfigOptionFloat support_material_spacing; ConfigOptionFloat support_material_speed; ConfigOptionBool support_material_synchronize_layers; ConfigOptionInt support_material_threshold; ConfigOptionBool support_material_with_sheath; ConfigOptionFloatOrPercent support_material_xy_spacing; ConfigOptionFloat xy_size_compensation; ConfigOptionBool wipe_into_objects; protected: void initialize(StaticCacheBase &cache, const char *base_ptr) { OPT_PTR(clip_multipart_objects); OPT_PTR(dont_support_bridges); OPT_PTR(elefant_foot_compensation); OPT_PTR(extrusion_width); OPT_PTR(first_layer_height); OPT_PTR(infill_only_where_needed); OPT_PTR(interface_shells); OPT_PTR(layer_height); OPT_PTR(raft_layers); OPT_PTR(seam_position); // OPT_PTR(seam_preferred_direction); // OPT_PTR(seam_preferred_direction_jitter); OPT_PTR(support_material); OPT_PTR(support_material_angle); OPT_PTR(support_material_buildplate_only); OPT_PTR(support_material_contact_distance); OPT_PTR(support_material_enforce_layers); OPT_PTR(support_material_interface_contact_loops); OPT_PTR(support_material_extruder); OPT_PTR(support_material_extrusion_width); OPT_PTR(support_material_interface_extruder); OPT_PTR(support_material_interface_layers); OPT_PTR(support_material_interface_spacing); OPT_PTR(support_material_interface_speed); OPT_PTR(support_material_pattern); OPT_PTR(support_material_spacing); OPT_PTR(support_material_speed); OPT_PTR(support_material_synchronize_layers); OPT_PTR(support_material_xy_spacing); OPT_PTR(support_material_threshold); OPT_PTR(support_material_with_sheath); OPT_PTR(xy_size_compensation); OPT_PTR(wipe_into_objects); } }; // This object is mapped to Perl as Slic3r::Config::PrintRegion. class PrintRegionConfig : public StaticPrintConfig { STATIC_PRINT_CONFIG_CACHE(PrintRegionConfig) public: ConfigOptionFloat bridge_angle; ConfigOptionInt bottom_solid_layers; ConfigOptionFloat bridge_flow_ratio; ConfigOptionFloat bridge_speed; ConfigOptionBool ensure_vertical_shell_thickness; ConfigOptionEnum external_fill_pattern; ConfigOptionFloatOrPercent external_perimeter_extrusion_width; ConfigOptionFloatOrPercent external_perimeter_speed; ConfigOptionBool external_perimeters_first; ConfigOptionBool extra_perimeters; ConfigOptionFloat fill_angle; ConfigOptionPercent fill_density; ConfigOptionEnum fill_pattern; ConfigOptionFloat gap_fill_speed; ConfigOptionInt infill_extruder; ConfigOptionFloatOrPercent infill_extrusion_width; ConfigOptionInt infill_every_layers; ConfigOptionFloatOrPercent infill_overlap; ConfigOptionFloat infill_speed; ConfigOptionBool overhangs; ConfigOptionInt perimeter_extruder; ConfigOptionFloatOrPercent perimeter_extrusion_width; ConfigOptionFloat perimeter_speed; ConfigOptionInt perimeters; ConfigOptionFloatOrPercent small_perimeter_speed; ConfigOptionFloat solid_infill_below_area; ConfigOptionInt solid_infill_extruder; ConfigOptionFloatOrPercent solid_infill_extrusion_width; ConfigOptionInt solid_infill_every_layers; ConfigOptionFloatOrPercent solid_infill_speed; ConfigOptionBool thin_walls; ConfigOptionFloatOrPercent top_infill_extrusion_width; ConfigOptionInt top_solid_layers; ConfigOptionFloatOrPercent top_solid_infill_speed; ConfigOptionBool wipe_into_infill; protected: void initialize(StaticCacheBase &cache, const char *base_ptr) { OPT_PTR(bridge_angle); OPT_PTR(bottom_solid_layers); OPT_PTR(bridge_flow_ratio); OPT_PTR(bridge_speed); OPT_PTR(ensure_vertical_shell_thickness); OPT_PTR(external_fill_pattern); OPT_PTR(external_perimeter_extrusion_width); OPT_PTR(external_perimeter_speed); OPT_PTR(external_perimeters_first); OPT_PTR(extra_perimeters); OPT_PTR(fill_angle); OPT_PTR(fill_density); OPT_PTR(fill_pattern); OPT_PTR(gap_fill_speed); OPT_PTR(infill_extruder); OPT_PTR(infill_extrusion_width); OPT_PTR(infill_every_layers); OPT_PTR(infill_overlap); OPT_PTR(infill_speed); OPT_PTR(overhangs); OPT_PTR(perimeter_extruder); OPT_PTR(perimeter_extrusion_width); OPT_PTR(perimeter_speed); OPT_PTR(perimeters); OPT_PTR(small_perimeter_speed); OPT_PTR(solid_infill_below_area); OPT_PTR(solid_infill_extruder); OPT_PTR(solid_infill_extrusion_width); OPT_PTR(solid_infill_every_layers); OPT_PTR(solid_infill_speed); OPT_PTR(thin_walls); OPT_PTR(top_infill_extrusion_width); OPT_PTR(top_solid_infill_speed); OPT_PTR(top_solid_layers); OPT_PTR(wipe_into_infill); } }; class MachineEnvelopeConfig : public StaticPrintConfig { STATIC_PRINT_CONFIG_CACHE(MachineEnvelopeConfig) public: // M201 X... Y... Z... E... [mm/sec^2] ConfigOptionFloats machine_max_acceleration_x; ConfigOptionFloats machine_max_acceleration_y; ConfigOptionFloats machine_max_acceleration_z; ConfigOptionFloats machine_max_acceleration_e; // M203 X... Y... Z... E... [mm/sec] ConfigOptionFloats machine_max_feedrate_x; ConfigOptionFloats machine_max_feedrate_y; ConfigOptionFloats machine_max_feedrate_z; ConfigOptionFloats machine_max_feedrate_e; // M204 S... [mm/sec^2] ConfigOptionFloats machine_max_acceleration_extruding; // M204 T... [mm/sec^2] ConfigOptionFloats machine_max_acceleration_retracting; // M205 X... Y... Z... E... [mm/sec] ConfigOptionFloats machine_max_jerk_x; ConfigOptionFloats machine_max_jerk_y; ConfigOptionFloats machine_max_jerk_z; ConfigOptionFloats machine_max_jerk_e; // M205 T... [mm/sec] ConfigOptionFloats machine_min_travel_rate; // M205 S... [mm/sec] ConfigOptionFloats machine_min_extruding_rate; protected: void initialize(StaticCacheBase &cache, const char *base_ptr) { OPT_PTR(machine_max_acceleration_x); OPT_PTR(machine_max_acceleration_y); OPT_PTR(machine_max_acceleration_z); OPT_PTR(machine_max_acceleration_e); OPT_PTR(machine_max_feedrate_x); OPT_PTR(machine_max_feedrate_y); OPT_PTR(machine_max_feedrate_z); OPT_PTR(machine_max_feedrate_e); OPT_PTR(machine_max_acceleration_extruding); OPT_PTR(machine_max_acceleration_retracting); OPT_PTR(machine_max_jerk_x); OPT_PTR(machine_max_jerk_y); OPT_PTR(machine_max_jerk_z); OPT_PTR(machine_max_jerk_e); OPT_PTR(machine_min_travel_rate); OPT_PTR(machine_min_extruding_rate); } }; // This object is mapped to Perl as Slic3r::Config::GCode. class GCodeConfig : public StaticPrintConfig { STATIC_PRINT_CONFIG_CACHE(GCodeConfig) public: ConfigOptionString before_layer_gcode; ConfigOptionString between_objects_gcode; ConfigOptionFloats deretract_speed; ConfigOptionString end_gcode; ConfigOptionStrings end_filament_gcode; ConfigOptionString extrusion_axis; ConfigOptionFloats extrusion_multiplier; ConfigOptionFloats filament_diameter; ConfigOptionFloats filament_density; ConfigOptionStrings filament_type; ConfigOptionBools filament_soluble; ConfigOptionFloats filament_cost; ConfigOptionFloats filament_max_volumetric_speed; ConfigOptionFloats filament_loading_speed; ConfigOptionFloats filament_load_time; ConfigOptionFloats filament_unloading_speed; ConfigOptionFloats filament_toolchange_delay; ConfigOptionFloats filament_unload_time; ConfigOptionInts filament_cooling_moves; ConfigOptionFloats filament_cooling_initial_speed; ConfigOptionFloats filament_minimal_purge_on_wipe_tower; ConfigOptionFloats filament_cooling_final_speed; ConfigOptionStrings filament_ramming_parameters; ConfigOptionBool gcode_comments; ConfigOptionEnum gcode_flavor; ConfigOptionString layer_gcode; ConfigOptionFloat max_print_speed; ConfigOptionFloat max_volumetric_speed; ConfigOptionFloat max_volumetric_extrusion_rate_slope_positive; ConfigOptionFloat max_volumetric_extrusion_rate_slope_negative; ConfigOptionPercents retract_before_wipe; ConfigOptionFloats retract_length; ConfigOptionFloats retract_length_toolchange; ConfigOptionFloats retract_lift; ConfigOptionFloats retract_lift_above; ConfigOptionFloats retract_lift_below; ConfigOptionFloats retract_restart_extra; ConfigOptionFloats retract_restart_extra_toolchange; ConfigOptionFloats retract_speed; ConfigOptionString start_gcode; ConfigOptionStrings start_filament_gcode; ConfigOptionBool single_extruder_multi_material; ConfigOptionBool single_extruder_multi_material_priming; ConfigOptionString toolchange_gcode; ConfigOptionFloat travel_speed; ConfigOptionBool use_firmware_retraction; ConfigOptionBool use_relative_e_distances; ConfigOptionBool use_volumetric_e; ConfigOptionBool variable_layer_height; ConfigOptionFloat cooling_tube_retraction; ConfigOptionFloat cooling_tube_length; ConfigOptionFloat parking_pos_retraction; ConfigOptionBool remaining_times; ConfigOptionBool silent_mode; ConfigOptionFloat extra_loading_move; std::string get_extrusion_axis() const { return ((this->gcode_flavor.value == gcfMach3) || (this->gcode_flavor.value == gcfMachinekit)) ? "A" : (this->gcode_flavor.value == gcfNoExtrusion) ? "" : this->extrusion_axis.value; } protected: void initialize(StaticCacheBase &cache, const char *base_ptr) { OPT_PTR(before_layer_gcode); OPT_PTR(between_objects_gcode); OPT_PTR(deretract_speed); OPT_PTR(end_gcode); OPT_PTR(end_filament_gcode); OPT_PTR(extrusion_axis); OPT_PTR(extrusion_multiplier); OPT_PTR(filament_diameter); OPT_PTR(filament_density); OPT_PTR(filament_type); OPT_PTR(filament_soluble); OPT_PTR(filament_cost); OPT_PTR(filament_max_volumetric_speed); OPT_PTR(filament_loading_speed); OPT_PTR(filament_load_time); OPT_PTR(filament_unloading_speed); OPT_PTR(filament_unload_time); OPT_PTR(filament_toolchange_delay); OPT_PTR(filament_cooling_moves); OPT_PTR(filament_cooling_initial_speed); OPT_PTR(filament_minimal_purge_on_wipe_tower); OPT_PTR(filament_cooling_final_speed); OPT_PTR(filament_ramming_parameters); OPT_PTR(gcode_comments); OPT_PTR(gcode_flavor); OPT_PTR(layer_gcode); OPT_PTR(max_print_speed); OPT_PTR(max_volumetric_speed); OPT_PTR(max_volumetric_extrusion_rate_slope_positive); OPT_PTR(max_volumetric_extrusion_rate_slope_negative); OPT_PTR(retract_before_wipe); OPT_PTR(retract_length); OPT_PTR(retract_length_toolchange); OPT_PTR(retract_lift); OPT_PTR(retract_lift_above); OPT_PTR(retract_lift_below); OPT_PTR(retract_restart_extra); OPT_PTR(retract_restart_extra_toolchange); OPT_PTR(retract_speed); OPT_PTR(single_extruder_multi_material); OPT_PTR(single_extruder_multi_material_priming); OPT_PTR(start_gcode); OPT_PTR(start_filament_gcode); OPT_PTR(toolchange_gcode); OPT_PTR(travel_speed); OPT_PTR(use_firmware_retraction); OPT_PTR(use_relative_e_distances); OPT_PTR(use_volumetric_e); OPT_PTR(variable_layer_height); OPT_PTR(cooling_tube_retraction); OPT_PTR(cooling_tube_length); OPT_PTR(parking_pos_retraction); OPT_PTR(remaining_times); OPT_PTR(silent_mode); OPT_PTR(extra_loading_move); } }; // This object is mapped to Perl as Slic3r::Config::Print. class PrintConfig : public MachineEnvelopeConfig, public GCodeConfig { STATIC_PRINT_CONFIG_CACHE_DERIVED(PrintConfig) PrintConfig() : GCodeConfig(0) { initialize_cache(); *this = s_cache_PrintConfig.defaults(); } public: double min_object_distance() const; static double min_object_distance(const ConfigBase *config); ConfigOptionBool avoid_crossing_perimeters; ConfigOptionPoints bed_shape; ConfigOptionInts bed_temperature; ConfigOptionFloat bridge_acceleration; ConfigOptionInts bridge_fan_speed; ConfigOptionFloat brim_width; ConfigOptionBool complete_objects; ConfigOptionBools cooling; ConfigOptionFloat default_acceleration; ConfigOptionInts disable_fan_first_layers; ConfigOptionFloat duplicate_distance; ConfigOptionFloat extruder_clearance_height; ConfigOptionFloat extruder_clearance_radius; ConfigOptionStrings extruder_colour; ConfigOptionPoints extruder_offset; ConfigOptionBools fan_always_on; ConfigOptionInts fan_below_layer_time; ConfigOptionStrings filament_colour; ConfigOptionStrings filament_notes; ConfigOptionFloat first_layer_acceleration; ConfigOptionInts first_layer_bed_temperature; ConfigOptionFloatOrPercent first_layer_extrusion_width; ConfigOptionFloatOrPercent first_layer_speed; ConfigOptionInts first_layer_temperature; ConfigOptionFloat infill_acceleration; ConfigOptionBool infill_first; ConfigOptionInts max_fan_speed; ConfigOptionFloats max_layer_height; ConfigOptionInts min_fan_speed; ConfigOptionFloats min_layer_height; ConfigOptionFloat max_print_height; ConfigOptionFloats min_print_speed; ConfigOptionFloat min_skirt_length; ConfigOptionString notes; ConfigOptionFloats nozzle_diameter; ConfigOptionBool only_retract_when_crossing_perimeters; ConfigOptionBool ooze_prevention; ConfigOptionString output_filename_format; ConfigOptionFloat perimeter_acceleration; ConfigOptionStrings post_process; ConfigOptionString printer_model; ConfigOptionString printer_notes; ConfigOptionFloat resolution; ConfigOptionFloats retract_before_travel; ConfigOptionBools retract_layer_change; ConfigOptionFloat skirt_distance; ConfigOptionInt skirt_height; ConfigOptionInt skirts; ConfigOptionInts slowdown_below_layer_time; ConfigOptionBool spiral_vase; ConfigOptionInt standby_temperature_delta; ConfigOptionInts temperature; ConfigOptionInt threads; ConfigOptionBools wipe; ConfigOptionBool wipe_tower; ConfigOptionFloat wipe_tower_x; ConfigOptionFloat wipe_tower_y; ConfigOptionFloat wipe_tower_width; ConfigOptionFloat wipe_tower_per_color_wipe; ConfigOptionFloat wipe_tower_rotation_angle; ConfigOptionFloat wipe_tower_bridging; ConfigOptionFloats wiping_volumes_matrix; ConfigOptionFloats wiping_volumes_extruders; ConfigOptionFloat z_offset; protected: PrintConfig(int) : GCodeConfig(1) {} void initialize(StaticCacheBase &cache, const char *base_ptr) { this->MachineEnvelopeConfig::initialize(cache, base_ptr); this->GCodeConfig::initialize(cache, base_ptr); OPT_PTR(avoid_crossing_perimeters); OPT_PTR(bed_shape); OPT_PTR(bed_temperature); OPT_PTR(bridge_acceleration); OPT_PTR(bridge_fan_speed); OPT_PTR(brim_width); OPT_PTR(complete_objects); OPT_PTR(cooling); OPT_PTR(default_acceleration); OPT_PTR(disable_fan_first_layers); OPT_PTR(duplicate_distance); OPT_PTR(extruder_clearance_height); OPT_PTR(extruder_clearance_radius); OPT_PTR(extruder_colour); OPT_PTR(extruder_offset); OPT_PTR(fan_always_on); OPT_PTR(fan_below_layer_time); OPT_PTR(filament_colour); OPT_PTR(filament_notes); OPT_PTR(first_layer_acceleration); OPT_PTR(first_layer_bed_temperature); OPT_PTR(first_layer_extrusion_width); OPT_PTR(first_layer_speed); OPT_PTR(first_layer_temperature); OPT_PTR(infill_acceleration); OPT_PTR(infill_first); OPT_PTR(max_fan_speed); OPT_PTR(max_layer_height); OPT_PTR(min_fan_speed); OPT_PTR(min_layer_height); OPT_PTR(max_print_height); OPT_PTR(min_print_speed); OPT_PTR(min_skirt_length); OPT_PTR(notes); OPT_PTR(nozzle_diameter); OPT_PTR(only_retract_when_crossing_perimeters); OPT_PTR(ooze_prevention); OPT_PTR(output_filename_format); OPT_PTR(perimeter_acceleration); OPT_PTR(post_process); OPT_PTR(printer_model); OPT_PTR(printer_notes); OPT_PTR(resolution); OPT_PTR(retract_before_travel); OPT_PTR(retract_layer_change); OPT_PTR(skirt_distance); OPT_PTR(skirt_height); OPT_PTR(skirts); OPT_PTR(slowdown_below_layer_time); OPT_PTR(spiral_vase); OPT_PTR(standby_temperature_delta); OPT_PTR(temperature); OPT_PTR(threads); OPT_PTR(wipe); OPT_PTR(wipe_tower); OPT_PTR(wipe_tower_x); OPT_PTR(wipe_tower_y); OPT_PTR(wipe_tower_width); OPT_PTR(wipe_tower_per_color_wipe); OPT_PTR(wipe_tower_rotation_angle); OPT_PTR(wipe_tower_bridging); OPT_PTR(wiping_volumes_matrix); OPT_PTR(wiping_volumes_extruders); OPT_PTR(z_offset); } }; class HostConfig : public StaticPrintConfig { STATIC_PRINT_CONFIG_CACHE(HostConfig) public: ConfigOptionString octoprint_host; ConfigOptionString octoprint_apikey; ConfigOptionString octoprint_cafile; ConfigOptionString serial_port; ConfigOptionInt serial_speed; protected: void initialize(StaticCacheBase &cache, const char *base_ptr) { OPT_PTR(octoprint_host); OPT_PTR(octoprint_apikey); OPT_PTR(octoprint_cafile); OPT_PTR(serial_port); OPT_PTR(serial_speed); } }; // This object is mapped to Perl as Slic3r::Config::Full. class FullPrintConfig : public PrintObjectConfig, public PrintRegionConfig, public PrintConfig, public HostConfig { STATIC_PRINT_CONFIG_CACHE_DERIVED(FullPrintConfig) FullPrintConfig() : PrintObjectConfig(0), PrintRegionConfig(0), PrintConfig(0), HostConfig(0) { initialize_cache(); *this = s_cache_FullPrintConfig.defaults(); } public: // Validate the FullPrintConfig. Returns an empty string on success, otherwise an error message is returned. std::string validate(); protected: // Protected constructor to be called to initialize ConfigCache::m_default. FullPrintConfig(int) : PrintObjectConfig(0), PrintRegionConfig(0), PrintConfig(0), HostConfig(0) {} void initialize(StaticCacheBase &cache, const char *base_ptr) { this->PrintObjectConfig::initialize(cache, base_ptr); this->PrintRegionConfig::initialize(cache, base_ptr); this->PrintConfig ::initialize(cache, base_ptr); this->HostConfig ::initialize(cache, base_ptr); } }; #undef STATIC_PRINT_CONFIG_CACHE #undef STATIC_PRINT_CONFIG_CACHE_BASE #undef STATIC_PRINT_CONFIG_CACHE_DERIVED #undef OPT_PTR } #endif