PrusaSlicer-NonPlainar/src/libslic3r/PrintConfig.hpp

// 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
//

#ifndef slic3r_PrintConfig_hpp_
#define slic3r_PrintConfig_hpp_

#include "libslic3r.h"
#include "Config.hpp"

// #define HAS_PRESSURE_EQUALIZER

namespace Slic3r {

enum GCodeFlavor : unsigned char {
    gcfRepRapSprinter, gcfRepRapFirmware, gcfRepetier, gcfTeacup, gcfMakerWare, gcfMarlin, gcfSailfish, gcfMach3, gcfMachinekit,
    gcfSmoothie, gcfNoExtrusion,
};

enum class MachineLimitsUsage {
	EmitToGCode,
	TimeEstimateOnly,
	Ignore,
	Count,
};

enum PrintHostType {
    htOctoPrint, htDuet, htFlashAir, htAstroBox, htRepetier
};

enum AuthorizationType {
    atKeyPassword, atUserPassword
};

enum class FuzzySkinType {
    None,
    External,
    All,
};

enum InfillPattern : int {
    ipRectilinear, ipMonotonic, ipAlignedRectilinear, ipGrid, ipTriangles, ipStars, ipCubic, ipLine, ipConcentric, ipHoneycomb, ip3DHoneycomb,
    ipGyroid, ipHilbertCurve, ipArchimedeanChords, ipOctagramSpiral, ipAdaptiveCubic, ipSupportCubic, ipCount,
};

enum class IroningType {
	TopSurfaces,
	TopmostOnly,
	AllSolid,
	Count,
};

enum SupportMaterialPattern {
    smpRectilinear, smpRectilinearGrid, smpHoneycomb,
};

enum SeamPosition {
    spRandom, spNearest, spAligned, spRear
};

enum SLAMaterial {
    slamTough,
    slamFlex,
    slamCasting,
    slamDental,
    slamHeatResistant,
};

enum SLADisplayOrientation {
    sladoLandscape,
    sladoPortrait
};

enum SLAPillarConnectionMode {
    slapcmZigZag,
    slapcmCross,
    slapcmDynamic
};

enum BrimType {
    btNoBrim,
    btOuterOnly,
    btInnerOnly,
    btOuterAndInner,
};

template<> inline const t_config_enum_values& ConfigOptionEnum<PrinterTechnology>::get_enum_values() {
    static t_config_enum_values keys_map;
    if (keys_map.empty()) {
        keys_map["FFF"]             = ptFFF;
        keys_map["SLA"]             = ptSLA;
    }
    return keys_map;
}

template<> inline const t_config_enum_values& ConfigOptionEnum<GCodeFlavor>::get_enum_values() {
    static t_config_enum_values keys_map;
    if (keys_map.empty()) {
        keys_map["reprap"]          = gcfRepRapSprinter;
        keys_map["reprapfirmware"]  = gcfRepRapFirmware;
        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 const t_config_enum_values& ConfigOptionEnum<MachineLimitsUsage>::get_enum_values() {
    static t_config_enum_values keys_map;
    if (keys_map.empty()) {
        keys_map["emit_to_gcode"]       = int(MachineLimitsUsage::EmitToGCode);
        keys_map["time_estimate_only"]  = int(MachineLimitsUsage::TimeEstimateOnly);
        keys_map["ignore"]            	= int(MachineLimitsUsage::Ignore);
    }
    return keys_map;
}

template<> inline const t_config_enum_values& ConfigOptionEnum<PrintHostType>::get_enum_values() {
    static t_config_enum_values keys_map;
    if (keys_map.empty()) {
        keys_map["octoprint"]       = htOctoPrint;
        keys_map["duet"]            = htDuet;
        keys_map["flashair"]        = htFlashAir;
        keys_map["astrobox"]        = htAstroBox;
        keys_map["repetier"]        = htRepetier;
    }
    return keys_map;
}

template<> inline const t_config_enum_values& ConfigOptionEnum<AuthorizationType>::get_enum_values() {
    static t_config_enum_values keys_map;
    if (keys_map.empty()) {
        keys_map["key"]             = atKeyPassword;
        keys_map["user"]            = atUserPassword;
    }
    return keys_map;
}

template<> inline const t_config_enum_values& ConfigOptionEnum<FuzzySkinType>::get_enum_values() {
    static t_config_enum_values keys_map;
    if (keys_map.empty()) {
        keys_map["none"]                 = int(FuzzySkinType::None);
        keys_map["external"]             = int(FuzzySkinType::External);
        keys_map["all"]                  = int(FuzzySkinType::All);
    }
    return keys_map;
}

template<> inline const t_config_enum_values& ConfigOptionEnum<InfillPattern>::get_enum_values() {
    static t_config_enum_values keys_map;
    if (keys_map.empty()) {
        keys_map["rectilinear"]         = ipRectilinear;
        keys_map["monotonic"]           = ipMonotonic;
        keys_map["alignedrectilinear"]  = ipAlignedRectilinear;
        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;
        keys_map["adaptivecubic"]       = ipAdaptiveCubic;
        keys_map["supportcubic"]        = ipSupportCubic;
    }
    return keys_map;
}

template<> inline const t_config_enum_values& ConfigOptionEnum<IroningType>::get_enum_values() {
    static t_config_enum_values keys_map;
    if (keys_map.empty()) {
        keys_map["top"]                 = int(IroningType::TopSurfaces);
        keys_map["topmost"]             = int(IroningType::TopmostOnly);
        keys_map["solid"]               = int(IroningType::AllSolid);
    }
    return keys_map;
}

template<> inline const t_config_enum_values& ConfigOptionEnum<SupportMaterialPattern>::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 const t_config_enum_values& ConfigOptionEnum<SeamPosition>::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 const t_config_enum_values& ConfigOptionEnum<SLADisplayOrientation>::get_enum_values() {
    static const t_config_enum_values keys_map = {
        { "landscape", sladoLandscape},
        { "portrait",  sladoPortrait}
    };

    return keys_map;
}

template<> inline const t_config_enum_values& ConfigOptionEnum<SLAPillarConnectionMode>::get_enum_values() {
    static const t_config_enum_values keys_map = {
        {"zigzag", slapcmZigZag},
        {"cross", slapcmCross},
        {"dynamic", slapcmDynamic}
    };

    return keys_map;
}

template<> inline const t_config_enum_values& ConfigOptionEnum<BrimType>::get_enum_values() {
    static const t_config_enum_values keys_map = {
        {"no_brim", btNoBrim},
        {"outer_only", btOuterOnly},
        {"inner_only", btInnerOnly},
        {"outer_and_inner", btOuterAndInner}
    };

    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);

    // Array options growing with the number of extruders
    const std::vector<std::string>& extruder_option_keys() const { return m_extruder_option_keys; }
    // Options defining the extruder retract properties. These keys are sorted lexicographically.
    // The extruder retract keys could be overidden by the same values defined at the Filament level
    // (then the key is further prefixed with the "filament_" prefix).
    const std::vector<std::string>& extruder_retract_keys() const { return m_extruder_retract_keys; }

private:
    void init_common_params();
    void init_fff_params();
    void init_extruder_option_keys();
    void init_sla_params();

    std::vector<std::string> 	m_extruder_option_keys;
    std::vector<std::string> 	m_extruder_retract_keys;
};

// The one and only global definition of SLic3r configuration options.
// This definition is constant.
extern const PrintConfigDef print_config_def;

class StaticPrintConfig;

// Minimum object distance for arrangement, based on printer technology.
double min_object_distance(const ConfigBase &cfg);

// 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 &rhs) : DynamicConfig(rhs) {}
    DynamicPrintConfig(DynamicPrintConfig &&rhs) noexcept : DynamicConfig(std::move(rhs)) {}
    explicit DynamicPrintConfig(const StaticPrintConfig &rhs);
    explicit DynamicPrintConfig(const ConfigBase &rhs) : DynamicConfig(rhs) {}

    DynamicPrintConfig& operator=(const DynamicPrintConfig &rhs) { DynamicConfig::operator=(rhs); return *this; }
    DynamicPrintConfig& operator=(DynamicPrintConfig &&rhs) noexcept { DynamicConfig::operator=(std::move(rhs)); return *this; }

    static DynamicPrintConfig  full_print_config();
    static DynamicPrintConfig* new_from_defaults_keys(const std::vector<std::string> &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_fdm();

    void 				set_num_extruders(unsigned int num_extruders);

    // 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); }
};

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; }
    // Reference to the cached list of keys.
	virtual const t_config_option_keys& keys_ref() const = 0;

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<typename T>
        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<std::string, ptrdiff_t>    m_map_name_to_offset;
    };

    // Parametrized by the type of the topmost class owning the options.
    template<typename T>
    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<ConfigOption*>((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 ConfigOption*>((const char*)owner + it->second);
        }

        const std::vector<std::string>& 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)
                    opt->set(def->default_value.get());
            }
        }

    private:
        T                                  *m_defaults;
        std::vector<std::string>            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. */ \
    const ConfigOption*      optptr(const t_config_option_key &opt_key) const override \
        { return s_cache_##CLASS_NAME.optptr(opt_key, this); } \
    /* 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(); } \
    const t_config_option_keys& keys_ref() 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<CLASS_NAME> 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:
    ConfigOptionFloat               brim_offset;
    ConfigOptionEnum<BrimType>      brim_type;
    ConfigOptionFloat               brim_width;
    ConfigOptionBool                clip_multipart_objects;
    ConfigOptionBool                dont_support_bridges;
    ConfigOptionFloat               elefant_foot_compensation;
    ConfigOptionFloatOrPercent      extrusion_width;
    ConfigOptionFloatOrPercent      first_layer_height;
    ConfigOptionBool                infill_only_where_needed;
    // Force the generation of solid shells between adjacent materials/volumes.
    ConfigOptionBool                interface_shells;
    ConfigOptionFloat               layer_height;
    ConfigOptionInt                 raft_layers;
    ConfigOptionEnum<SeamPosition>  seam_position;
//    ConfigOptionFloat               seam_preferred_direction;
//    ConfigOptionFloat               seam_preferred_direction_jitter;
    ConfigOptionFloat               slice_closing_radius;
    ConfigOptionBool                support_material;
    // Automatic supports (generated based on support_material_threshold).
    ConfigOptionBool                support_material_auto;
    // Direction of the support pattern (in XY plane).
    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;
    // Spacing between interface lines (the hatching distance). Set zero to get a solid interface.
    ConfigOptionFloat               support_material_interface_spacing;
    ConfigOptionFloatOrPercent      support_material_interface_speed;
    ConfigOptionEnum<SupportMaterialPattern> support_material_pattern;
    // Spacing between support material lines (the hatching distance).
    ConfigOptionFloat               support_material_spacing;
    ConfigOptionFloat               support_material_speed;
    ConfigOptionBool                support_material_synchronize_layers;
    // Overhang angle threshold.
    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(brim_offset);
        OPT_PTR(brim_type);
        OPT_PTR(brim_width);
        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(slice_closing_radius);
//        OPT_PTR(seam_preferred_direction);
//        OPT_PTR(seam_preferred_direction_jitter);
        OPT_PTR(support_material);
        OPT_PTR(support_material_auto);
        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               bottom_solid_min_thickness;
    ConfigOptionFloat               bridge_flow_ratio;
    ConfigOptionFloat               bridge_speed;
    ConfigOptionBool                ensure_vertical_shell_thickness;
    ConfigOptionEnum<InfillPattern> top_fill_pattern;
    ConfigOptionEnum<InfillPattern> bottom_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<InfillPattern> fill_pattern;
    ConfigOptionEnum<FuzzySkinType> fuzzy_skin;
    ConfigOptionFloat               fuzzy_skin_thickness;
    ConfigOptionFloat               fuzzy_skin_point_dist;
    ConfigOptionBool                gap_fill_enabled;
    ConfigOptionFloat               gap_fill_speed;
    ConfigOptionFloatOrPercent      infill_anchor;
    ConfigOptionFloatOrPercent      infill_anchor_max;
    ConfigOptionInt                 infill_extruder;
    ConfigOptionFloatOrPercent      infill_extrusion_width;
    ConfigOptionInt                 infill_every_layers;
    ConfigOptionFloatOrPercent      infill_overlap;
    ConfigOptionFloat               infill_speed;
    // Ironing options
    ConfigOptionBool 				ironing;
    ConfigOptionEnum<IroningType> 	ironing_type;
    ConfigOptionPercent 			ironing_flowrate;
    ConfigOptionFloat 				ironing_spacing;
    ConfigOptionFloat 				ironing_speed;
    // Detect bridging perimeters
    ConfigOptionBool                overhangs;
    ConfigOptionInt                 perimeter_extruder;
    ConfigOptionFloatOrPercent      perimeter_extrusion_width;
    ConfigOptionFloat               perimeter_speed;
    // Total number of perimeters.
    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;
    // Detect thin walls.
    ConfigOptionBool                thin_walls;
    ConfigOptionFloatOrPercent      top_infill_extrusion_width;
    ConfigOptionInt                 top_solid_layers;
    ConfigOptionFloat 				top_solid_min_thickness;
    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(bottom_solid_min_thickness);
        OPT_PTR(bridge_flow_ratio);
        OPT_PTR(bridge_speed);
        OPT_PTR(ensure_vertical_shell_thickness);
        OPT_PTR(top_fill_pattern);
        OPT_PTR(bottom_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(fuzzy_skin);
        OPT_PTR(fuzzy_skin_thickness);
        OPT_PTR(fuzzy_skin_point_dist);
        OPT_PTR(gap_fill_enabled);
        OPT_PTR(gap_fill_speed);
        OPT_PTR(infill_anchor);
        OPT_PTR(infill_anchor_max);
        OPT_PTR(infill_extruder);
        OPT_PTR(infill_extrusion_width);
        OPT_PTR(infill_every_layers);
        OPT_PTR(infill_overlap);
        OPT_PTR(infill_speed);
        OPT_PTR(ironing);
        OPT_PTR(ironing_type);
        OPT_PTR(ironing_flowrate);
        OPT_PTR(ironing_spacing);
        OPT_PTR(ironing_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(top_solid_min_thickness);
        OPT_PTR(wipe_into_infill);
    }
};

class MachineEnvelopeConfig : public StaticPrintConfig
{
    STATIC_PRINT_CONFIG_CACHE(MachineEnvelopeConfig)
public:
	// Allowing the machine limits to be completely ignored or used just for time estimator.
    ConfigOptionEnum<MachineLimitsUsage> machine_limits_usage;
    // 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_limits_usage);
        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_spool_weight;
    ConfigOptionFloats              filament_max_volumetric_speed;
    ConfigOptionFloats              filament_loading_speed;
    ConfigOptionFloats              filament_loading_speed_start;
    ConfigOptionFloats              filament_load_time;
    ConfigOptionFloats              filament_unloading_speed;
    ConfigOptionFloats              filament_unloading_speed_start;
    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<GCodeFlavor>   gcode_flavor;
    ConfigOptionBool                gcode_label_objects;
    ConfigOptionString              layer_gcode;
    ConfigOptionFloat               max_print_speed;
    ConfigOptionFloat               max_volumetric_speed;
#ifdef HAS_PRESSURE_EQUALIZER
    ConfigOptionFloat               max_volumetric_extrusion_rate_slope_positive;
    ConfigOptionFloat               max_volumetric_extrusion_rate_slope_negative;
#endif
    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;
    ConfigOptionBool                wipe_tower_no_sparse_layers;
    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;
    ConfigOptionBool                high_current_on_filament_swap;
    ConfigOptionFloat               parking_pos_retraction;
    ConfigOptionBool                remaining_times;
    ConfigOptionBool                silent_mode;
    ConfigOptionFloat               extra_loading_move;
    ConfigOptionString              color_change_gcode;
    ConfigOptionString              pause_print_gcode;
    ConfigOptionString              template_custom_gcode;

    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_spool_weight);
        OPT_PTR(filament_max_volumetric_speed);
        OPT_PTR(filament_loading_speed);
        OPT_PTR(filament_loading_speed_start);
        OPT_PTR(filament_load_time);
        OPT_PTR(filament_unloading_speed);
        OPT_PTR(filament_unloading_speed_start);
        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(gcode_label_objects);
        OPT_PTR(layer_gcode);
        OPT_PTR(max_print_speed);
        OPT_PTR(max_volumetric_speed);
#ifdef HAS_PRESSURE_EQUALIZER
        OPT_PTR(max_volumetric_extrusion_rate_slope_positive);
        OPT_PTR(max_volumetric_extrusion_rate_slope_negative);
#endif /* HAS_PRESSURE_EQUALIZER */
        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(wipe_tower_no_sparse_layers);
        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(high_current_on_filament_swap);
        OPT_PTR(parking_pos_retraction);
        OPT_PTR(remaining_times);
        OPT_PTR(silent_mode);
        OPT_PTR(extra_loading_move);
        OPT_PTR(color_change_gcode);
        OPT_PTR(pause_print_gcode);
        OPT_PTR(template_custom_gcode);
    }
};

// This object is mapped to Perl as Slic3r::Config::Print.
class PrintConfig : public MachineEnvelopeConfig, public GCodeConfig
{
    STATIC_PRINT_CONFIG_CACHE_DERIVED(PrintConfig)
    PrintConfig() : MachineEnvelopeConfig(0), GCodeConfig(0) { initialize_cache(); *this = s_cache_PrintConfig.defaults(); }
public:

    ConfigOptionBool                avoid_crossing_perimeters;
    ConfigOptionFloatOrPercent      avoid_crossing_perimeters_max_detour;
    ConfigOptionPoints              bed_shape;
    ConfigOptionInts                bed_temperature;
    ConfigOptionFloat               bridge_acceleration;
    ConfigOptionInts                bridge_fan_speed;
    ConfigOptionBool                complete_objects;
    ConfigOptionFloats              colorprint_heights;
    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;
    ConfigOptionInts                full_fan_speed_layer;
    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;
    ConfigOptionBool                draft_shield;
    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) : MachineEnvelopeConfig(1), 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(avoid_crossing_perimeters_max_detour);
        OPT_PTR(bed_shape);
        OPT_PTR(bed_temperature);
        OPT_PTR(bridge_acceleration);
        OPT_PTR(bridge_fan_speed);
        OPT_PTR(complete_objects);
        OPT_PTR(colorprint_heights);
        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(full_fan_speed_layer);
        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(draft_shield);
        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);
    }
};

// This object is mapped to Perl as Slic3r::Config::Full.
class FullPrintConfig :
    public PrintObjectConfig,
    public PrintRegionConfig,
    public PrintConfig
{
    STATIC_PRINT_CONFIG_CACHE_DERIVED(FullPrintConfig)
    FullPrintConfig() : PrintObjectConfig(0), PrintRegionConfig(0), PrintConfig(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) {}
    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 object is mapped to Perl as Slic3r::Config::PrintRegion.
class SLAPrintConfig : public StaticPrintConfig
{
    STATIC_PRINT_CONFIG_CACHE(SLAPrintConfig)
public:
    ConfigOptionString     output_filename_format;

protected:
    void initialize(StaticCacheBase &cache, const char *base_ptr)
    {
        OPT_PTR(output_filename_format);
    }
};

class SLAPrintObjectConfig : public StaticPrintConfig
{
    STATIC_PRINT_CONFIG_CACHE(SLAPrintObjectConfig)
public:
    ConfigOptionFloat layer_height;

    //Number of the layers needed for the exposure time fade [3;20]
    ConfigOptionInt  faded_layers /*= 10*/;

    ConfigOptionFloat slice_closing_radius;

    // Enabling or disabling support creation
    ConfigOptionBool  supports_enable;

    // Diameter in mm of the pointing side of the head.
    ConfigOptionFloat support_head_front_diameter /*= 0.2*/;

    // How much the pinhead has to penetrate the model surface
    ConfigOptionFloat support_head_penetration /*= 0.2*/;

    // Width in mm from the back sphere center to the front sphere center.
    ConfigOptionFloat support_head_width /*= 1.0*/;

    // Radius in mm of the support pillars.
    ConfigOptionFloat support_pillar_diameter /*= 0.8*/;

    // The percentage of smaller pillars compared to the normal pillar diameter
    // which are used in problematic areas where a normal pilla cannot fit.
    ConfigOptionPercent support_small_pillar_diameter_percent;
    
    // How much bridge (supporting another pinhead) can be placed on a pillar.
    ConfigOptionInt   support_max_bridges_on_pillar;

    // How the pillars are bridged together
    ConfigOptionEnum<SLAPillarConnectionMode> support_pillar_connection_mode;

    // Generate only ground facing supports
    ConfigOptionBool support_buildplate_only;

    // TODO: unimplemented at the moment. This coefficient will have an impact
    // when bridges and pillars are merged. The resulting pillar should be a bit
    // thicker than the ones merging into it. How much thicker? I don't know
    // but it will be derived from this value.
    ConfigOptionFloat support_pillar_widening_factor;

    // Radius in mm of the pillar base.
    ConfigOptionFloat support_base_diameter /*= 2.0*/;

    // The height of the pillar base cone in mm.
    ConfigOptionFloat support_base_height /*= 1.0*/;

    // The minimum distance of the pillar base from the model in mm.
    ConfigOptionFloat support_base_safety_distance; /*= 1.0*/

    // The default angle for connecting support sticks and junctions.
    ConfigOptionFloat support_critical_angle /*= 45*/;

    // The max length of a bridge in mm
    ConfigOptionFloat support_max_bridge_length /*= 15.0*/;

    // The max distance of two pillars to get cross linked.
    ConfigOptionFloat support_max_pillar_link_distance;

    // The elevation in Z direction upwards. This is the space between the pad
    // and the model object's bounding box bottom. Units in mm.
    ConfigOptionFloat support_object_elevation /*= 5.0*/;

    /////// Following options influence automatic support points placement:
    ConfigOptionInt support_points_density_relative;
    ConfigOptionFloat support_points_minimal_distance;

    // Now for the base pool (pad) /////////////////////////////////////////////

    // Enabling or disabling support creation
    ConfigOptionBool  pad_enable;

    // The thickness of the pad walls
    ConfigOptionFloat pad_wall_thickness /*= 2*/;

    // The height of the pad from the bottom to the top not considering the pit
    ConfigOptionFloat pad_wall_height /*= 5*/;
    
    // How far should the pad extend around the contained geometry
    ConfigOptionFloat pad_brim_size;

    // The greatest distance where two individual pads are merged into one. The
    // distance is measured roughly from the centroids of the pads.
    ConfigOptionFloat pad_max_merge_distance /*= 50*/;

    // The smoothing radius of the pad edges
    // ConfigOptionFloat pad_edge_radius /*= 1*/;

    // The slope of the pad wall...
    ConfigOptionFloat pad_wall_slope;

    // /////////////////////////////////////////////////////////////////////////
    // Zero elevation mode parameters:
    //    - The object pad will be derived from the model geometry.
    //    - There will be a gap between the object pad and the generated pad
    //      according to the support_base_safety_distance parameter.
    //    - The two pads will be connected with tiny connector sticks
    // /////////////////////////////////////////////////////////////////////////

    // Disable the elevation (ignore its value) and use the zero elevation mode
    ConfigOptionBool pad_around_object;
    
    ConfigOptionBool pad_around_object_everywhere;

    // This is the gap between the object bottom and the generated pad
    ConfigOptionFloat pad_object_gap;

    // How far to place the connector sticks on the object pad perimeter
    ConfigOptionFloat pad_object_connector_stride;

    // The width of the connectors sticks
    ConfigOptionFloat pad_object_connector_width;

    // How much should the tiny connectors penetrate into the model body
    ConfigOptionFloat pad_object_connector_penetration;
    
    // /////////////////////////////////////////////////////////////////////////
    // Model hollowing parameters:
    //   - Models can be hollowed out as part of the SLA print process
    //   - Thickness of the hollowed model walls can be adjusted
    //   -
    //   - Additional holes will be drilled into the hollow model to allow for
    //   - resin removal.
    // /////////////////////////////////////////////////////////////////////////
    
    ConfigOptionBool hollowing_enable;
    
    // The minimum thickness of the model walls to maintain. Note that the 
    // resulting walls may be thicker due to smoothing out fine cavities where
    // resin could stuck.
    ConfigOptionFloat hollowing_min_thickness;
    
    // Indirectly controls the voxel size (resolution) used by openvdb
    ConfigOptionFloat hollowing_quality;
   
    // Indirectly controls the minimum size of created cavities.
    ConfigOptionFloat hollowing_closing_distance;

protected:
    void initialize(StaticCacheBase &cache, const char *base_ptr)
    {
        OPT_PTR(layer_height);
        OPT_PTR(faded_layers);
        OPT_PTR(slice_closing_radius);
        OPT_PTR(supports_enable);
        OPT_PTR(support_head_front_diameter);
        OPT_PTR(support_head_penetration);
        OPT_PTR(support_head_width);
        OPT_PTR(support_pillar_diameter);
        OPT_PTR(support_small_pillar_diameter_percent);
        OPT_PTR(support_max_bridges_on_pillar);
        OPT_PTR(support_pillar_connection_mode);
        OPT_PTR(support_buildplate_only);
        OPT_PTR(support_pillar_widening_factor);
        OPT_PTR(support_base_diameter);
        OPT_PTR(support_base_height);
        OPT_PTR(support_base_safety_distance);
        OPT_PTR(support_critical_angle);
        OPT_PTR(support_max_bridge_length);
        OPT_PTR(support_max_pillar_link_distance);
        OPT_PTR(support_points_density_relative);
        OPT_PTR(support_points_minimal_distance);
        OPT_PTR(support_object_elevation);
        OPT_PTR(pad_enable);
        OPT_PTR(pad_wall_thickness);
        OPT_PTR(pad_wall_height);
        OPT_PTR(pad_brim_size);
        OPT_PTR(pad_max_merge_distance);
        // OPT_PTR(pad_edge_radius);
        OPT_PTR(pad_wall_slope);
        OPT_PTR(pad_around_object);
        OPT_PTR(pad_around_object_everywhere);
        OPT_PTR(pad_object_gap);
        OPT_PTR(pad_object_connector_stride);
        OPT_PTR(pad_object_connector_width);
        OPT_PTR(pad_object_connector_penetration);
        OPT_PTR(hollowing_enable);
        OPT_PTR(hollowing_min_thickness);
        OPT_PTR(hollowing_quality);
        OPT_PTR(hollowing_closing_distance);
    }
};

class SLAMaterialConfig : public StaticPrintConfig
{
    STATIC_PRINT_CONFIG_CACHE(SLAMaterialConfig)
public:
    ConfigOptionFloat                       initial_layer_height;
    ConfigOptionFloat                       bottle_cost;
    ConfigOptionFloat                       bottle_volume;
    ConfigOptionFloat                       bottle_weight;
    ConfigOptionFloat                       material_density;
    ConfigOptionFloat                       exposure_time;
    ConfigOptionFloat                       initial_exposure_time;
    ConfigOptionFloats                      material_correction;
protected:
    void initialize(StaticCacheBase &cache, const char *base_ptr)
    {
        OPT_PTR(initial_layer_height);
        OPT_PTR(bottle_cost);
        OPT_PTR(bottle_volume);
        OPT_PTR(bottle_weight);
        OPT_PTR(material_density);
        OPT_PTR(exposure_time);
        OPT_PTR(initial_exposure_time);
        OPT_PTR(material_correction);
    }
};

class SLAPrinterConfig : public StaticPrintConfig
{
    STATIC_PRINT_CONFIG_CACHE(SLAPrinterConfig)
public:
    ConfigOptionEnum<PrinterTechnology>     printer_technology;
    ConfigOptionPoints                      bed_shape;
    ConfigOptionFloat                       max_print_height;
    ConfigOptionFloat                       display_width;
    ConfigOptionFloat                       display_height;
    ConfigOptionInt                         display_pixels_x;
    ConfigOptionInt                         display_pixels_y;
    ConfigOptionEnum<SLADisplayOrientation> display_orientation;
    ConfigOptionBool                        display_mirror_x;
    ConfigOptionBool                        display_mirror_y;
    ConfigOptionFloats                      relative_correction;
    ConfigOptionFloat                       absolute_correction;
    ConfigOptionFloat                       elefant_foot_compensation;
    ConfigOptionFloat                       elefant_foot_min_width;
    ConfigOptionFloat                       gamma_correction;
    ConfigOptionFloat                       fast_tilt_time;
    ConfigOptionFloat                       slow_tilt_time;
    ConfigOptionFloat                       area_fill;
    ConfigOptionFloat                       min_exposure_time;
    ConfigOptionFloat                       max_exposure_time;
    ConfigOptionFloat                       min_initial_exposure_time;
    ConfigOptionFloat                       max_initial_exposure_time;
protected:
    void initialize(StaticCacheBase &cache, const char *base_ptr)
    {
        OPT_PTR(printer_technology);
        OPT_PTR(bed_shape);
        OPT_PTR(max_print_height);
        OPT_PTR(display_width);
        OPT_PTR(display_height);
        OPT_PTR(display_pixels_x);
        OPT_PTR(display_pixels_y);
        OPT_PTR(display_mirror_x);
        OPT_PTR(display_mirror_y);
        OPT_PTR(display_orientation);
        OPT_PTR(relative_correction);
        OPT_PTR(absolute_correction);
        OPT_PTR(elefant_foot_compensation);
        OPT_PTR(elefant_foot_min_width);
        OPT_PTR(gamma_correction);
        OPT_PTR(fast_tilt_time);
        OPT_PTR(slow_tilt_time);
        OPT_PTR(area_fill);
        OPT_PTR(min_exposure_time);
        OPT_PTR(max_exposure_time);
        OPT_PTR(min_initial_exposure_time);
        OPT_PTR(max_initial_exposure_time);
    }
};

class SLAFullPrintConfig : public SLAPrinterConfig, public SLAPrintConfig, public SLAPrintObjectConfig, public SLAMaterialConfig
{
    STATIC_PRINT_CONFIG_CACHE_DERIVED(SLAFullPrintConfig)
    SLAFullPrintConfig() : SLAPrinterConfig(0), SLAPrintConfig(0), SLAPrintObjectConfig(0), SLAMaterialConfig(0) { initialize_cache(); *this = s_cache_SLAFullPrintConfig.defaults(); }

public:
    // Validate the SLAFullPrintConfig. 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.
    SLAFullPrintConfig(int) : SLAPrinterConfig(0), SLAPrintConfig(0), SLAPrintObjectConfig(0), SLAMaterialConfig(0) {}
    void initialize(StaticCacheBase &cache, const char *base_ptr)
    {
        this->SLAPrinterConfig    ::initialize(cache, base_ptr);
        this->SLAPrintConfig      ::initialize(cache, base_ptr);
        this->SLAPrintObjectConfig::initialize(cache, base_ptr);
        this->SLAMaterialConfig   ::initialize(cache, base_ptr);
    }
};

#undef STATIC_PRINT_CONFIG_CACHE
#undef STATIC_PRINT_CONFIG_CACHE_BASE
#undef STATIC_PRINT_CONFIG_CACHE_DERIVED
#undef OPT_PTR

class CLIActionsConfigDef : public ConfigDef
{
public:
    CLIActionsConfigDef();
};

class CLITransformConfigDef : public ConfigDef
{
public:
    CLITransformConfigDef();
};

class CLIMiscConfigDef : public ConfigDef
{
public:
    CLIMiscConfigDef();
};

// This class defines the command line options representing actions.
extern const CLIActionsConfigDef    cli_actions_config_def;

// This class defines the command line options representing transforms.
extern const CLITransformConfigDef  cli_transform_config_def;

// This class defines all command line options that are not actions or transforms.
extern const CLIMiscConfigDef       cli_misc_config_def;

class DynamicPrintAndCLIConfig : public DynamicPrintConfig
{
public:
    DynamicPrintAndCLIConfig() {}
    DynamicPrintAndCLIConfig(const DynamicPrintAndCLIConfig &other) : DynamicPrintConfig(other) {}

    // Overrides ConfigBase::def(). Static configuration definition. Any value stored into this ConfigBase shall have its definition here.
    const ConfigDef*        def() const override { return &s_def; }

    // 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;

private:
    class PrintAndCLIConfigDef : public ConfigDef
    {
    public:
        PrintAndCLIConfigDef() {
            this->options.insert(print_config_def.options.begin(), print_config_def.options.end());
            this->options.insert(cli_actions_config_def.options.begin(), cli_actions_config_def.options.end());
            this->options.insert(cli_transform_config_def.options.begin(), cli_transform_config_def.options.end());
            this->options.insert(cli_misc_config_def.options.begin(), cli_misc_config_def.options.end());
            for (const auto &kvp : this->options)
                this->by_serialization_key_ordinal[kvp.second.serialization_key_ordinal] = &kvp.second;
        }
        // Do not release the default values, they are handled by print_config_def & cli_actions_config_def / cli_transform_config_def / cli_misc_config_def.
        ~PrintAndCLIConfigDef() { this->options.clear(); }
    };
    static PrintAndCLIConfigDef s_def;
};

Points get_bed_shape(const DynamicPrintConfig &cfg);
Points get_bed_shape(const PrintConfig &cfg);
Points get_bed_shape(const SLAPrinterConfig &cfg);

// ModelConfig is a wrapper around DynamicPrintConfig with an addition of a timestamp.
// Each change of ModelConfig is tracked by assigning a new timestamp from a global counter.
// The counter is used for faster synchronization of the background slicing thread
// with the front end by skipping synchronization of equal config dictionaries. 
// The global counter is also used for avoiding unnecessary serialization of config 
// dictionaries when taking an Undo snapshot.
//
// The global counter is NOT thread safe, therefore it is recommended to use ModelConfig from
// the main thread only.
// 
// As there is a global counter and it is being increased with each change to any ModelConfig,
// if two ModelConfig dictionaries differ, they should differ with their timestamp as well.
// Therefore copying the ModelConfig including its timestamp is safe as there is no harm
// in having multiple ModelConfig with equal timestamps as long as their dictionaries are equal.
//
// The timestamp is used by the Undo/Redo stack. As zero timestamp means invalid timestamp
// to the Undo/Redo stack (zero timestamp means the Undo/Redo stack needs to serialize and
// compare serialized data for differences), zero timestamp shall never be used.
// Timestamp==1 shall only be used for empty dictionaries.
class ModelConfig
{
public:
    void         clear() { m_data.clear(); m_timestamp = 1; }

    void         assign_config(const ModelConfig &rhs) {
        if (m_timestamp != rhs.m_timestamp) {
            m_data      = rhs.m_data;
            m_timestamp = rhs.m_timestamp;
        }
    }
    void         assign_config(ModelConfig &&rhs) {
        if (m_timestamp != rhs.m_timestamp) {
            m_data      = std::move(rhs.m_data);
            m_timestamp = rhs.m_timestamp;
            rhs.clear();
        }
    }

    // Modification of the ModelConfig is not thread safe due to the global timestamp counter!
    // Don't call modification methods from the back-end!
    // Assign methods don't assign if src==dst to not having to bump the timestamp in case they are equal.
    void         assign_config(const DynamicPrintConfig &rhs)  { if (m_data != rhs) { m_data = rhs; this->touch(); } }
    void         assign_config(DynamicPrintConfig &&rhs)       { if (m_data != rhs) { m_data = std::move(rhs); this->touch(); } }
    void         apply(const ModelConfig &other, bool ignore_nonexistent = false) { this->apply(other.get(), ignore_nonexistent); }
    void         apply(const ConfigBase &other, bool ignore_nonexistent = false) { m_data.apply_only(other, other.keys(), ignore_nonexistent); this->touch(); }
    void         apply_only(const ModelConfig &other, const t_config_option_keys &keys, bool ignore_nonexistent = false) { this->apply_only(other.get(), keys, ignore_nonexistent); }
    void         apply_only(const ConfigBase &other, const t_config_option_keys &keys, bool ignore_nonexistent = false) { m_data.apply_only(other, keys, ignore_nonexistent); this->touch(); }
    bool         set_key_value(const std::string &opt_key, ConfigOption *opt) { bool out = m_data.set_key_value(opt_key, opt); this->touch(); return out; }
    template<typename T>
    void         set(const std::string &opt_key, T value) { m_data.set(opt_key, value, true); this->touch(); }
    void         set_deserialize(const t_config_option_key &opt_key, const std::string &str, bool append = false)
        { m_data.set_deserialize(opt_key, str, append); this->touch(); }
    bool         erase(const t_config_option_key &opt_key) { bool out = m_data.erase(opt_key); if (out) this->touch(); return out; }

    // Getters are thread safe.
    // The following implicit conversion breaks the Cereal serialization.
//    operator const DynamicPrintConfig&() const throw() { return this->get(); }
    const DynamicPrintConfig&   get() const throw() { return m_data; }
    bool                        empty() const throw() { return m_data.empty(); }
    size_t                      size() const throw() { return m_data.size(); }
    auto                        cbegin() const { return m_data.cbegin(); }
    auto                        cend() const { return m_data.cend(); }
    t_config_option_keys        keys() const { return m_data.keys(); }
    bool                        has(const t_config_option_key &opt_key) const { return m_data.has(opt_key); }
    const ConfigOption*         option(const t_config_option_key &opt_key) const { return m_data.option(opt_key); }
    int                         opt_int(const t_config_option_key &opt_key) const { return m_data.opt_int(opt_key); }
    int                         extruder() const { return opt_int("extruder"); }
    double                      opt_float(const t_config_option_key &opt_key) const { return m_data.opt_float(opt_key); }
    std::string                 opt_serialize(const t_config_option_key &opt_key) const { return m_data.opt_serialize(opt_key); }

    // Return an optional timestamp of this object.
    // If the timestamp returned is non-zero, then the serialization framework will
    // only save this object on the Undo/Redo stack if the timestamp is different
    // from the timestmap of the object at the top of the Undo / Redo stack.
    virtual uint64_t    timestamp() const throw() { return m_timestamp; }
    bool                timestamp_matches(const ModelConfig &rhs) const throw() { return m_timestamp == rhs.m_timestamp; }
    // Not thread safe! Should not be called from other than the main thread!
    void                touch() { m_timestamp = ++ s_last_timestamp; }

private:
    friend class cereal::access;
    template<class Archive> void serialize(Archive& ar) { ar(m_timestamp); ar(m_data); }

    uint64_t                    m_timestamp { 1 };
    DynamicPrintConfig          m_data;

    static uint64_t             s_last_timestamp;
};

} // namespace Slic3r

// Serialization through the Cereal library
namespace cereal {
    // Let cereal know that there are load / save non-member functions declared for DynamicPrintConfig, ignore serialize / load / save from parent class DynamicConfig.
    template <class Archive> struct specialize<Archive, Slic3r::DynamicPrintConfig, cereal::specialization::non_member_load_save> {};

    template<class Archive> void load(Archive& archive, Slic3r::DynamicPrintConfig &config)
    {
        size_t cnt;
        archive(cnt);
        config.clear();
        for (size_t i = 0; i < cnt; ++ i) {
            size_t serialization_key_ordinal;
            archive(serialization_key_ordinal);
            assert(serialization_key_ordinal > 0);
            auto it = Slic3r::print_config_def.by_serialization_key_ordinal.find(serialization_key_ordinal);
            assert(it != Slic3r::print_config_def.by_serialization_key_ordinal.end());
            config.set_key_value(it->second->opt_key, it->second->load_option_from_archive(archive));
        }
    }

    template<class Archive> void save(Archive& archive, const Slic3r::DynamicPrintConfig &config)
    {
        size_t cnt = config.size();
        archive(cnt);
        for (auto it = config.cbegin(); it != config.cend(); ++it) {
            const Slic3r::ConfigOptionDef* optdef = Slic3r::print_config_def.get(it->first);
            assert(optdef != nullptr);
            assert(optdef->serialization_key_ordinal > 0);
            archive(optdef->serialization_key_ordinal);
            optdef->save_option_to_archive(archive, it->second.get());
        }
    }
}

#endif