CoreAPI.h

#pragma once
#include <stdafx.h>
#ifdef PYBIND11_DEF
#include <Python.h>
#include <pybind11/pybind11.h>
#include <pybind11/numpy.h>
#endif
 
 
class ItemsTree;
class ItemsFolder;
class ClusteredMesh;
 
#ifndef PY_PARSER
#ifdef PYBIND11_DEF
 
#define PY_BYTE_ARRAY pybind11::array_t<unsigned char, pybind11::array::c_style>
#define PY_WORD_ARRAY pybind11::array_t<WORD, pybind11::array::c_style>
#define PY_DWORD_ARRAY pybind11::array_t<dword, pybind11::array::c_style>
#define PY_INT_ARRAY pybind11::array_t<int, pybind11::array::c_style>
#define PY_FLOAT_ARRAY pybind11::array_t<float, pybind11::array::c_style>
#define PY_DOUBLE_ARRAY pybind11::array_t<double, pybind11::array::c_style>
 
#endif
#endif
 
#pragma pack(push, 1)
namespace coat {
    class Model;
    class Volume;
    typedef comms::cVec4 vec4;
 
    typedef comms::cVec3 vec3;
 
    typedef comms::cVec3i vec3i;
 
    typedef comms::cVec2 vec2;
 
    typedef comms::cMat4 mat4;
 
    typedef comms::cMat3 mat3;
 
    typedef comms::cMath math;
 
    typedef comms::cStr str;
 
    template <class X> using list = comms::cList<X>;
 
    typedef comms::cRect rect;
 
    typedef comms::cQuat quat;
 
    typedef comms::cRotation rotation;
 
    typedef comms::cAngles angles;
 
    // axis-aligned bound box
    typedef comms::cBounds boundbox;
 
    enum  BoolOpType {
        BOOL_MERGE = -1,
        BOOL_ADD = 0,
        BOOL_SUBTRACT = 1,
        BOOL_INTERSECT = 2,
    };
    class prim;
 
 
    void start_main_menu(const char* id);
 
    void menu_item(const char* id);
    
    bool menu_submenu(const char* id);
 
    void menu_exit();
 
    void menu_separator();
 
    void menu_hotkey(const char* id, int Shift, int Ctrl, int Alt);
 
    bool iconic_submenu(const char* id, int size);
    
    bool is_new_scene();
    
    bool is_steam_app();
    
    bool is_medical();
    
    bool is_ppp();
 
    bool is_proxy();
 
    bool is_multires();
 
    bool is_surface();
 
    bool IsInRoom(const char* name);
 
    bool RoomExists(const char* name);
 
    bool CheckIfExists(const char* path);
 
    
    bool UseRecordScript();
 
 
    bool is_mv();
 
    bool is_ptex();
 
    void show_rmb_panel();
 
    void show_space_panel(const char* Subset, int NumColumns);
 
    bool gltf_support();
 
    int tex_approach();
 
    void menu_insert_extensions(const char* id);
 
    void insert_extensions();
 
    void set_space_panel_columns_count(int num);
 
    void SetAutoSnapDefaults(bool value);
 
    bool menu_property(const char* id);
 
    void tools_section(const char* id);
 
    void tools_item(const char* id);
 
    void page_suffix(const char* suffix);
 
    void default_tool(const char* tool);
 
    bool IsDebug();
 
    void start_rmb_panel();
 
    void menu_sort();
 
    bool IsRecordScript();
 
    bool IsInTool(const char* ToolID);
 
    bool voxtree_item_picked();
 
    bool retopo_object_picked();
 
    bool empty_space_picked();
 
    bool voxtree_object_picked();
 
    int GetCurrentToolSubmode(const char* id);
 
    void tools_comment(const char* id);
 
    bool doc_mode();
 
    void PureIconic();
 
    bool lock_ui_changes();
 
 
    bool ue5_support();
 
    class APICALL Mesh {
    protected:
        friend class Model;
        static std::vector<std::pair<comms::cMeshContainer*, int>> allocated_meshes;
        comms::cMeshContainer* allocate();
        void inc_ref(comms::cMeshContainer* m);
        void dec_ref(comms::cMeshContainer* m);
 
        comms::cMeshContainer* MeshData;
        list<int> raw_start;
        int raw_count;
        void validate_raws();
    public:
        Mesh();
        ~Mesh();
 
        Mesh(const Mesh& m);
        Mesh(const Model& m);
        Mesh& operator = (const Mesh& m);
        Mesh& operator = (const Model& m);
        Mesh MakeCopy();
 
        bool Read(const char* name);
 
        bool Write(const char* name);
 
        bool valid() const;
 
        comms::cMeshContainer* geometry();
 
        comms::cMeshContainer* geometry() const;
 
        void clear();
 
        Mesh& operator +=(const Mesh& m);
 
        Mesh& operator +=(const Model& m);
 
        void addTransformed(const Mesh& m, const mat4& t);
 
        void boolean(const Mesh& m, BoolOpType op);
 
        void transform(const mat4& transform);
 
        void rotateToXYAxis(const vec3& axisX, const vec3& axisY);
 
        void rotateToYZAxis(const vec3& axisY, const vec3& axisZ);
 
        void rotateToZXAxis(const vec3& axisZ, const vec3& axisX);
 
        int vertsCount() const;
 
        int vertsUvCount() const;
 
        int vertsNormalCount() const;
 
        int facesCount();
 
        vec3 getVertex(int idx) const;
 
        void setVertex(int idx, const vec3& v);
 
        int createNewVertex(const vec3& position);
 
        vec2 getVertexUV(int idx) const;
 
        void setVertexUV(int idx, const vec2& v);
 
        int createNewUvVertex(const vec2& uv);
 
        vec3 getVertexNormal(int idx) const ;
 
        void setVertexNormal(int idx, const vec3& v);
 
        void calcNormals();
 
        void calcNormalsIgnoreSharpEdges();
 
        int getFaceVertsCount(int face);
 
        int getFaceUvVertsCount(int face);
 
        int getFaceVertex(int faceIndex, int faceVertexIndex);
 
        std::vector<int> getFaceVerts(int face);
        void getFaceVerts(int face, list<int>& vertices);
 
        void setFaceVerts(int face, const std::vector<int>& vertices);
        void setFaceVerts(int face, const list<int>& vertices);
 
        int getFaceUvVertex(int faceIndex, int faceVertexIndex);
 
         void setFaceUvVertex(int faceIndex, int faceVertexIndex, int uvVertexIndex);
 
        int getFaceNormalVertex(int faceIndex, int faceVertexIndex);
 
        void setFaceNormalVertex(int faceIndex, int faceVertexIndex, int normalVertexIndex);
 
        std::vector<int> getFaceUvVerts(int face);
        void getFaceUvVerts(int face, list<int>& vertices);
 
        int getFaceObject(int faceIndex);
 
        void setFaceObject(int faceIndex, int objectIndex);
 
        int getFaceMaterial(int faceIndex);
 
        void setFaceMaterial(int faceIndex, int materialIndex);
 
        int getObjectsCount();
 
        std::string getObjectName(int idx);
 
        void setObjectName(int idx, const std::string& name);
 
        int addObject(const char* name);
 
        void removeObject(int idx);
 
        void unifyAllObjects(const std::string& name = "");
 
        int getMaterialsCount();
 
        int addMaterial(const char* name);
 
        void removeMaterial(int idx);
 
        std::string getMaterialName(int idx);
 
        void setMaterialName(int idx, const std::string& name);
 
        std::string getMaterialTexture(int idx, int texture_layer);
 
        void setMaterialTexture(int idx, int texture_layer, const std::string& texture_path);
 
        void fromVolume(Volume& v, bool with_subtree = false, bool all_selected = false);
 
        void fromReducedVolume(Volume& v, float reduction_percent, bool with_subtree = false, bool all_selected = false);
 
        void fromVolumeWithMaxPolycount(Volume& v, int max_polycount, bool with_subtree = false, bool all_selected = false);
 
        void toVolume(Volume& v, const mat4& transform = mat4::Identity, BoolOpType op = BOOL_MERGE);
 
        void insertInVolume(Volume& v, const mat4& transform = mat4::Identity);
 
        void addToVolume(Volume& v, const mat4& transform = mat4::Identity);
 
        void subtractFromVolume(Volume& v, const mat4& transform = mat4::Identity);
 
        void intersectWithVolume(Volume& v, const mat4& transform = mat4::Identity);
 
        void fromRetopo();
 
        void fromPaintRoom();
 
        void reduceToPolycount(int destination_triangles_count);
 
        void triangulate();
 
        void booleanOp(Mesh& With, BoolOpType op);
 
        std::vector<vec3> getMeshVertices();
 
        std::vector<vec3> getMeshNormals();
 
        std::vector<vec2> getMeshUVs();
 
        void setMeshVertices(const std::vector<vec3>& positions);
 
        void setMeshNormals(const std::vector<vec3>& normals);
 
        void setMeshUVs(const std::vector<vec2>& uvs);
 
        void setMeshFaces(const std::vector<int>& faces);
 
        void addMeshVertices(const std::vector<vec3>& positions);
 
        void addMeshNormals(const std::vector<vec3>& normals);
 
        void addMeshUVs(const std::vector<vec2>& uvs);
 
        void addMeshFaces(const std::vector<int>& faces);
 
        void clearVerts();
 
        void clearUvVerts();
 
        void clearNormals();
 
        void clearFaces();
 
        void removeFaces(const std::vector<int>& faces);
 
        void clearObject();
 
        void clearMaterials();
 
        void ensureMaterialsAndObjectsExist();
 
        int addObject(const std::string& name);
 
        int addMaterial(const std::string& name);
 
        void removeUnusedObjectsAndMaterials();
 
        void removeUnusedVerts();
 
        void removeUnusedFaces();
 
        void cutByPlane(const vec3& start, const vec3& NormalDirection);
 
        void cutByDistortedPlane(const vec3& start, const vec3& NormalDirection, float noise_degree, float noise_scale, int seed = 0);
 
        void distortByPerlinNoise(float noise_degree, float noise_scale, bool anisotropic = false, int seed = 0);
 
        std::vector<Mesh> splitDisconnectedParts();
 
        void symmetry(const vec3& start, const vec3& NormalDirection, bool resultInQuads);
 
        std::vector<comms::cPlane> autodetectSymmetryPlanes();
 
        void weld(float minimal_relative_distance = 0.0001f);
 
        boundbox getBounds() const;
 
        float getVolume() const;
 
        float getOpenSurfaceVolume(const vec3& start, const vec3& dir) const;
 
        float getSquare() const;
 
        float getFaceSquare(int face);
 
        float getFaceUVSquare(int face);
 
        vec3 getFaceNormal(int face);
 
        void relax(float degree, bool tangent, float crease_angle = 180);
 
        static Mesh box(const vec3& center = vec3::Zero, const vec3& size = vec3::One, const vec3& xAxis =vec3::Zero, const vec3& yAxis = vec3::Zero, const vec3& zAxis = vec3::Zero, float detail_size = 1, float fillet = 0.0f, int nx=0, int ny=0, int nz=0);
 
        static Mesh sphere(const vec3& center = vec3::Zero, float radius = 1.0f, float detail_size = 1);
 
        static Mesh cylinder(const vec3& center = vec3::Zero, float radius = 1, float height = 2, float detail_size = 1, int slices = 0, int caps = 0, int rings = 0, float fillet = 0);
 
        static Mesh cone(const vec3& center = vec3::Zero, float radius = 1, float height = 2, float detail_size = 1, const vec3& topAxis = vec3::AxisY);
 
        static Mesh plane(const vec3& center = vec3::Zero, float sizeX = 2, float sizeY = 2, int divisionsX = 2, int divisionsY = 2, const vec3& xAxis = vec3::AxisX, const vec3& yAxis = vec3::AxisY);
 
        static Mesh hexagonal_plane(const vec3& center = vec3::Zero, float sizeX = 2, float sizeY = 2, int divisionsX = 2, int divisionsY = 2, const vec3& xAxis = vec3::AxisX, const vec3& yAxis = vec3::AxisY);
 
        static Mesh text(const char* string, const char* font = "tahoma", float height = 10.0f, const vec3 & center = vec3::Zero, const vec3& text_direction = vec3::AxisX, const vec3& text_normal = vec3::AxisY, float thickness = 1, int align = 1);
 
        void createVDM(int side, const char* path_to_exr, const vec3& center = vec3::Zero, float radius = 1, const vec3& up = vec3::AxisZ, const vec3& x = vec3::AxisX, const vec3& y = vec3::AxisY);
 
        void shell(float thickness_out, float thickness_in, int divisions = 1);
 
        std::vector<int> extrudeOpenEdges(float distance, vec3 direction = vec3::Zero);
 
        std::vector<int> expandOpenEdges(float distance);
 
        std::vector<int> getOpenEdges();
 
        float getLengthAlongDirection(const vec3& dir) const;
 
        vec3 getCenterMass() const;
 
    
    protected:
        void setMesh(const comms::cMeshContainer& mesh) {
            if (MeshData) {
                MeshData->Clear();
                MeshData->Copy(mesh);
            }
            else {
                MeshData = new comms::cMeshContainer(mesh);
                inc_ref(MeshData);
            }
        }
        friend class prim;
    };
 
    class APICALL Image : public comms::cImage {
    public:
        Image();
        Image(const Image& im);
        bool Read(const char* name);
 
        bool Write(const char* name);
 
        bool FromTexture(int texture_id);
 
        int ToTexture();
#ifdef PYBIND11_DEF
        int Paste(PY_BYTE_ARRAY src_data, int pasteLeft = 0, int pasteTop = 0, int cropLeft = 0, int cropTop = 0, int cropRight = 0, int cropBottom = 0, bool flipY = false);
 
        size_t Pointer();
 
        bool FromArray(PY_BYTE_ARRAY src_data);
        bool FromArray(PY_DWORD_ARRAY src_data);
        bool FromArray(PY_FLOAT_ARRAY src_data);
 
        pybind11::buffer_info _py_buffer_info();
#endif
    };
 
    class Volume;
 
    class APICALL symm {
    public:
        static symm& enable(bool _enable = true);
 
        static bool enabled();
 
        static symm& disable();
 
        static symm& xyz(bool x, bool y, bool z);
 
        static bool is_xyz();
 
        static bool& x();
 
        static bool& y();
 
        static bool& z();
 
        static symm& axial(int n, bool extraMirror = false, bool stepSymmetry = false);
 
        static bool is_axial();
 
        static int& axialOrder();
 
        static bool& extraMirror();
 
        static bool& stepSymmetry();
        static symm& axialMirror(int n, bool extraMirror = false, bool stepSymmetry = false);
 
        static bool isAxialMirror();
 
        static symm& translation(int numX, float stepX, int numY, float stepY, int numZ, float stepZ);
 
        static bool is_translation();
 
        static int& numX();
 
        static float& stepX();
 
        static int& numY();
 
        static float& stepY();
 
        static int& numZ();
 
        static float& stepZ();
 
        static symm& toGlobalSpace();
 
        static symm& toLocalSpace();
 
        static symm& toGeneral();
 
        static symm& set_start(const vec3& pos);
 
        static vec3& start();
 
        static symm& set_end(const vec3& pos);
 
        static vec3& end();
 
        static symm& showSymmetryPlane(bool show = true);
 
        static symm& setCustomSymetryTransforms(list<mat4>& symmetryTransforms);
#ifdef PYBIND11_DEF
        static symm& setCustomSymetryTransforms(pybind11::list& symmetryTransforms);
#endif
 
        static bool isCustomSymmetry();
 
        static symm& getCurrentTransforms(list<mat4>& symmetryTransforms);
 
        static std::vector<mat4> getCurrentTransforms();
 
        static symm& getCurrentPlanes(list<comms::cPlane>& planes);
 
        static std::vector<comms::cPlane> getCurrentPlanes();
    };
    class APICALL SceneElement {
    protected:
        ItemsTree* el;
        VoxTreeBranch* tb() const;
        OneCurveObject* cu() const;
        friend class Scene;
        friend class Curve;
        friend class Volume;
    public:
        SceneElement();     
        SceneElement(VolumeObject* vo);
        SceneElement(ItemsTree* c);
        SceneElement(const SceneElement& other);
 
        ~SceneElement();
 
        const bool operator==(const SceneElement& other) const;
        const bool operator!=(const SceneElement& other) const;
 
        SceneElement parent() const;
 
        int childCount() const;
 
        SceneElement child(int index) const ;
 
        bool isSculptObject() const;
 
        bool isCurve() const;
 
        const SceneElement& setTransform(const mat4& Transform) const ;
 
        const SceneElement& transform(const mat4& Transform) const ;
 
        const SceneElement& density(float density_value) const;
 
        const SceneElement& transform_single(const mat4& Transform) const;
 
        mat4 getTransform() const ;
 
        const SceneElement& clear() const ;
 
        const char* name() const;
 
        const SceneElement& rename(const char* name) const;
 
        SceneElement addChild(const char* name) const;
 
        SceneElement findInSubtree(const char* name) const;
 
        bool iterateSubtree(const std::function<bool(SceneElement)>& fn) const;
#ifdef PYBIND11_DEF
        bool iterateSubtree(const pybind11::object& fn) const;
#endif
 
        bool iterateVisibleSubtree(const std::function<bool(SceneElement)>& fn) const;
#ifdef PYBIND11_DEF
        bool iterateVisibleSubtree(const pybind11::object& fn) const;
#endif
 
        void mergeSubtree(bool booleanMerge = false) const;
 
        void mergeTo(const SceneElement& dest, BoolOpType op);
 
        void copyMergeTo(SceneElement& dest, BoolOpType op);
 
        void removeSubtree() const;
 
        void removeSubtreeItem(int index) const;
 
        void remove() const;
 
        SceneElement duplicate() const;
 
        SceneElement duplicateAsInstance() const;
 
        void changeParent(SceneElement newParent) const;
 
        bool isParentOf(SceneElement child) const;
 
        bool& visible() const;
 
        void setVisibility(bool visible) const;
 
        bool ghost() const;
 
        void setGhost(bool ghost) const;
 
        vec4 getReferenceColor();
 
        void setReferenceColor(const vec4& color);
 
        Volume Volume() const;
 
        void select() const;
 
        void selectOne() const;
 
        void unselectAll() const;
 
        bool selected();
 
        void collectSelected(list<SceneElement>& elemList);
 
        std::vector<SceneElement> collectSelected();
    };
 
    class VolumeCache {
    public:
        VolumeCache();
        tri_DWORD CellID;
        VolumeCell* pCell;
    };
 
    class APICALL Volume {
    protected:
        VoxTreeBranch* tb;
        VolumeObject* Obj;
        friend class SceneElement;
    public:
        Volume();
        Volume(VoxTreeBranch* tb);
        Volume(VolumeObject* vo);
        Volume(const Volume& vol);
        bool valid() const;
 
        bool isSurface() const;
 
        bool isVoxelized() const;
 
        void toSurface();
 
        void toVoxels();
 
        static void enableVoxelsColoring(bool enable = true);
 
        static void color(DWORD CL);
 
        static void color(float r, float g, float b, float a);
 
        static void color(float r, float g, float b);
 
        static void color(const char* colorid);
 
        static void gloss(float value);
 
        static void roughness(float value);
 
        static void metal(float value);
 
        void mergeMesh(Mesh& mesh, const mat4& transform = mat4::Identity, BoolOpType op = BOOL_MERGE);
 
        void insertMesh(Mesh& mesh, const mat4& transform = mat4::Identity);
 
        void addMesh(Mesh& mesh, const mat4& transform = mat4::Identity);
 
        void subtractMesh(Mesh& mesh, const mat4& transform = mat4::Identity);
 
        void intersectWithMesh(Mesh& mesh, const mat4& transform = mat4::Identity);
 
        void mergeMeshWithTexture(Mesh& mesh, const mat4& transform = mat4::Identity, BoolOpType op = BOOL_MERGE);
 
        Volume& makeVoxelFigure(std::function<float(vec3)> densityFunction, const list<vec3>& growCenters, bool Subtract = false, bool useTempLocation = false, bool overHidden = false, bool useColor = false);
 
        float getExactDencity(int x, int y, int z, bool fromBackup, VolumeCache& cache_ref);
 
        float getInterpolatedValue(const vec3& pos, bool fromBackup);
 
        void scanCells(const std::function<void(VolumeCell* vc)>& fn, bool multithreaded = false);
 
        void scanCells(const std::function<void(VolumeCellAttrib* vc)>& fn, bool multithreaded = false);
 
        void scanCells(const std::function<void(VolumeCellAttrib* vc, const tri_DWORD& T)>& fn, bool multithreaded = false);
 
        void scanCells(const std::function<void(VolumeCell* vc, const tri_DWORD& T)>& fn, bool multithreaded = false);
 
        void scanTriangles(const std::function<void(const MCVertex& v1, const MCVertex& v2, const MCVertex& v3)>& fn, bool multithreaded = false);
 
        void scanTriangles(const std::function<void(const Vector3D& v1, const Vector3D& v2, const Vector3D& v3)>& fn, bool multithreaded = false);
 
        int getPolycount();
 
        float getVolume();
 
        float getSquare();
 
        boundbox calcLocalSpaceAABB();
 
        boundbox calcWorldSpaceAABB();
 
        VoxTreeBranch* tree();
 
        VolumeObject* vo();
 
        VolumeCell* cell(int cx, int cy, int cz, bool create, bool backup);
 
        VolumeCellAttrib* attributes(int cx, int cy, int cz, bool create, bool backup);
 
        void dirty(int cx, int cy, int cz);
 
        void setOpacity(float Opacity);
 
        void relaxGpu(const vec3& center, float Radius, float degree);
 
        void relaxVoxels(int count);
 
        void relaxSurface(float degree, bool tangent = false, bool keep_sharp_boolean_edges = false);
 
        void relaxOpenEdges(int nTimes);
 
        SceneElement inScene();
 
        void clear();
 
        void clearNoUndo();
 
        void assignShader(const char* shaderName);
 
        void setBoolShaderProperty(const char* property, bool value);
        void setFloatShaderProperty(const char* property, float value);
        void setColorShaderProperty(const char* property, DWORD value);
 
        void removeFacesByWeight(std::function<float(const vec3&)> weight);
 
        void closeHoles(int maxSize);
 
        static bool checkIfMoldingLicenseAvailable();
 
        static void setMoldingParams(const vec3& direction, float tapering_angle = 0, float undercuts_density = 1.0f, float decimation_limit_millions = 10, bool perform_subtraction = true);
 
        void removeUndercuts();
 
        void basRelief(const vec3& start_point = vec3::Zero);
 
        static void setAutomaticMoldingBox();
 
        static void setMoldingBox(float width, float length, float thickness);
 
        static void setMoldingBorder(float width = 0);
 
        void generateMoldingCurves();
 
        void automaticMolding();
 
        void curveBasedMolding();
 
        void subtractWithoutUndecuts();
 
        SceneElement generateMoldingTest();
 
        SceneElement findMoldingTop();
 
        SceneElement findMoldingBottom();
 
        SceneElement findMoldingTest();
 
        void removeMoldingShapes();
 
        void assignLiveBooleans(int operation);
 
        void collapseBollTree();
    };
 
    inline coat::VolumeCache::VolumeCache() {
        pCell = nullptr;
        CellID.V1 = CellID.V2 = CellID.V3 = 100000;
    }
 
    class APICALL settings {
    public:
        static bool valueExists(const char* ID);
 
        static bool getBool(const char* ID);
 
        static std::string getString(const char* ID);
 
        static float getFloat(const char* ID);
 
        static int getInt(const char* ID);
 
        static bool setBool(const char* ID, bool value);
 
        static bool setString(const char* ID, const char* value);
 
        static bool setFloat(const char* ID, float value);
 
        static bool setInt(const char* ID, int value);
 
        static void saveSettings();
 
        static void resetSettings(bool ResetGeneralSettings = true, bool ResetHiddenSet = true, bool ResetHotkeys = true, bool RestNavigation = true, bool ResetPresets = true, bool ResetTheme = true, bool ResetWindows = true);
 
        static std::vector<std::string> listAllSettings();
 
        static void pressButton(const char* button_name);
    };
 
    class APICALL Scene {
    public:
        static void clearScene(bool askUser = false);
        static SceneElement current();
 
        static SceneElement sculptRoot();
 
        static SceneElement curvesRoot();
 
        static int getLayer(const char* name, bool addIfNotExists = true);
 
        static const char* getLayerName(int LayerID);
 
        static void setLayerName(int LayerID, const char* name);
 
        static int getLayerBlending(int LayerID);
 
        static void setLayerBlending(int LayerID, int mode);
 
        static int getCurrentLayer();
 
        static void setCurrentLayer(int LayerID);
 
        static void mergeVisibleLayers();
 
        static void mergeLayerDown(int LayerID);
 
        static void applyLayerBlending(int LayerID);
        
        static void invalidateLayer(int LayerID);
        
        static void setActiveLayer(int LayerID);
        
        static void removeLayer(int LayerID);
 
        static bool layerVisible(int LayerID);
 
        static void setLayerVisibility(int LayerID, bool Visible);
 
        static void setLayerColorOpacity(int LayerID, float Opacity);
 
        static void setLayerDepthOpacity(int LayerID, float Opacity);
 
        static void setLayerMetalnessOpacity(int LayerID, float Opacity);
 
        static void setLayerGlossOpacity(int LayerID, float Opacity);
 
        static int assignLayerMask(int LayerID);
 
        static void removeLayerMask(int LayerID);
 
        static void extractMaskAsLayer(int LayerID);
 
        static void setMaskForTheLayer(int LayerID, int MaskLayerID);
 
        static void enableLayerMask(int LayerID, bool enable);
 
        static bool isLayerMaskEnabled(int LayerID);
 
        static void invertLayerMask(int LayerID);
 
        static int getLayerMaskLayer(int LayerID);
 
        static void disableLayerMask(int LayerID);
 
        static void enableLayerMask(int LayerID);
 
        static bool maskEnabled(int LayerID);
 
        static void setClippingLayer(int LayerID);
 
        static void disableClippingLayer(int LayerID);
 
 
        static int PaintObjectsCount();
 
        static int PaintMaterialCount();
 
        static int PaintUVSetsCount();
 
        static void RemovePaintObject(int idx);
 
        static void RemovePaintMaterial(int idx);
 
        static void RemoveUVSet(int idx);
 
        static const char* PaintObjectName(int idx);
 
        static const char* PaintMaterialName(int idx);
 
        static const char* PaintUVSetName(int idx);
 
        static SceneElement importMesh(const char* filename, const mat4& transform = mat4::Identity);
 
        static void ScaleSceneVisually(float scale);
 
        static void ScaleSceneUnits(float scale);
 
        static float GetSceneScale();
 
        static const char* GetSceneUnits();
 
        static bool setSceneUnits(const char* units);
 
        static vec3 getSceneShift();
 
        static void setSceneShift(const vec3& shift);
 
        static std::vector<std::string> getAvailableUnits();
 
        static bool convertSceneUnits(const char* destination_unit_name);
    };
 
    class APICALL RenderRoom {
    public:
        static void toRenderRoom();
 
        static void restartRendering();
 
        static void setCustomRenderSize(int width, int height);
 
        static void setRenderResult(const char* filename);
 
        static void renderFrame();
 
        static void enableRealtimeRendering(bool enable);
 
        static bool isRealtimeRenderingEnabled();
 
        static void setExposure(float exposure);
 
        static float getExposure();
 
        static void setEnvironmentLight(float envlight);
 
        static float getEnvironmentLight();
 
        static void setDOFDegree(float degree);
 
        static float getDOFDegree();
 
        static int getLightsCount();
 
        static int addLight();
 
        static void removeLight(int idx);
 
        static void removeAllLights();
 
        static void setLightDirection(int idx, const vec3& dir);
 
        static vec3 getLightDirection(int idx);
 
        static void setLightScattering(int idx, float scattering);
 
        static float getLightScattering(int idx);
 
        static void setLightColor(int idx, const vec3& color = vec3::One);
 
        static vec3 getLightColor(int idx);
 
        static void setLightIntensity(int idx, float intensity);
 
        static float getLightIntensity(int idx);
 
        static void setRaysPerFrame(int count);
 
        static int getRaysPerFrame();
 
        static void setAA(bool AA);
 
        static bool getAA();
        
    };
 
    class APICALL Curve:public SceneElement {
        OneCurveObject* cu;
        bool allocated;
        friend class SceneElement;
        void validate();
    public:
        Curve();
        ~Curve();
 
        Curve(OneCurveObject* ob);
 
        Curve(SceneElement& el);
        Curve& operator = (SceneElement& el);
 
        int pointsCount();
 
        OneSelPoint* point(int idx);
 
        void removePoints(int index, int count);
 
        OneCurveObject* curve();
 
        int renderPointsCount();
 
        OneSelPoint* renderPoint(int idx);
 
        void updatePoints();
 
        bool& closed();
 
        void add(const Vector3D& p, const Vector3D& normal, float Radius);
 
        void addSharp(const Vector3D& p, const Vector3D& normal, float Radius);
 
        void addSmooth(const Vector3D& p, const Vector3D& normal, float Radius);
 
        void add(const Vector3D& p, const Vector3D& normal, const Vector3D& inTangent, const Vector3D& outTangent, float Radius);
 
        void add(const Vector3D& p, const Vector3D& normal, const Vector3D& inOutTangent, float Radius);
 
        void tubeToMesh(Mesh& mesh, bool hemisphere);
 
        void fill(Mesh& mesh, float thickness, float relax_count = 0, float details_level = 1, float extrusion = 0);
    };
 
    class APICALL SphericalCollision {
        list<vec4> spheres;
        uni_hash<int, tri_int> cells;
        float unit;
    public:
        SphericalCollision();
 
        SphericalCollision(float cellsize);
 
        ~SphericalCollision();
 
        void setUnit(float u);
 
        void clear();
 
        int addSphere(const vec3& p, float radius);
 
        vec3 collides(const vec3& p, float radius);
 
        vec4 sphere(int idx);
    };
 
    class APICALL ui {
    public:
        static bool cmd(const char* id, std::function<void()> process_in_modal_dialog = 0);
#ifdef PYBIND11_DEF
        static bool cmd(const char* id, pybind11::object fn = pybind11::none());
#endif
        static bool wait(const char* id, float max_seconds);
 
        static void highlight(const char* id, float milliseconds);
 
        static void enablePenChannel(int i, bool enabled);
 
        static bool isEnabledPenChannel(int i);
 
        static bool setSliderValue(const char* id, float value);
 
        static float getSliderValue(const char* id);
 
        static bool setEditBoxValue(const char* id, const char* value);
 
        static bool setEditBoxValue(const char* id, int value);
 
        static bool setEditBoxValue(const char* id, float value);
 
        static bool getEditBoxValue(const char* id, str& result);
        static const char* getEditBoxValue(const char* id);
 
        static void apply();
 
        static void setFileForFileDialog(const char* filename);
 
        static bool getBoolField(const char* id);
 
        static bool setBoolValue(const char* id, bool value);
 
        static const char* currentRoom();
 
        static bool isInRoom(const char* name);
 
        static void toRoom(const char* name);
 
        static int roomsCount();
 
        static const char* roomName(int index);
 
        static const char* roomID(int index);
 
        static void toolParam(BaseClass* B);
 
        static void removeToolParam(BaseClass* B = nullptr);
 
        static const char* getOption(const char* id);
 
        static bool setOption(const char* id, const char* value);
        static bool setOption(const char* id, bool value);
        static bool setOption(const char* id, float value);
 
        static void hideDontShowAgainMessage(const char* id);
 
        static void showInfoMessage(const char* infoID, int milliseconds);
 
        static void insertInMenu(const char* Menu, const char* ID_in_menu, const char* script_path);
 
        static void insertInToolset(const char* roomID, const char* section, const char* toolID, const char* script_path = "");
 
        static void removeCommandFromMenu(const char* ID_in_menu);
 
        static bool checkIfMenuItemInserted(const char* ID_in_menu);
 
#ifdef PYBIND11_DEF
        static void addExtension(const char* roomID, const char* section, pybind11::object& obj);
#endif
        static bool checkIfExtensionPresent(const char* extension_ID);
 
        static void addTranslation(const char* id, const char* text);
 
        static const std::string getIdTranslation(const char* id);
 
        static const std::string getCurrentLanguage();
 
        static void switchToLanguage(const char* language);
 
        static float scale();
 
        static std::string inputString(const char* text, int min_length = 0);
 
        static int inputInt(int initial_value);
 
        static float inputFloat(float initial_value);
    };
 
    class APICALL Camera
    {
    public:
        static void rotateToGradually(const vec3& destination_dir);
 
        static vec3 getForward();
 
        static vec3 getUp();
 
        static vec3 getRight();
 
        static bool isOrtho();
 
        static void setOrtho(bool ortho);
 
        static vec3 getPivot();
 
        static void setPivot(const vec3& pivot);
 
        static vec3 getPosition();
 
        static vec3 getWorldToScreenSpace(const vec3& world_pos);
 
        static vec3 getScreenToWorldSpace(const vec3& screen_pos);
 
        static void setCamera(const vec3& position, const vec3& lookAt, float fovY, const vec3& up = vec3::Zero);
    };
 
    class APICALL dialog {
#ifndef DOXYGEN_SHOULD_SKIP_THIS
        bool _modal;
        bool _topright;
        str _buttons;
        std::function<void()> _process;
        std::function<void(int)> _press;
        int _width;
        int _icon;
        bool _undoWorks;
        bool _dontshowagain;
        BaseClass* _bc;
        str _text;
        str _caption;
        bool _transparentbg;
        BaseWidget* _widget;
#endif //DOXYGEN_SHOULD_SKIP_THIS
    public:
        dialog();
        dialog& text(const char* id);
 
        dialog& caption(const char* id);
 
        dialog& width(int w);
 
        dialog& modal();
 
        dialog& noModal();
 
        dialog& buttons(const char* list);
 
        dialog& topRight();
 
        dialog& ok();
 
        dialog& cancel();
 
        dialog& yes();
 
        dialog& no();
 
        dialog& warn();
 
        dialog& question();
 
        dialog& undoWorks();
 
        dialog& transparentBackground();
 
        static bool& fadeDialogsBackground();
 
        dialog& dontShowAgainCheckbox();
 
        dialog& params(BaseClass* params);
#ifdef PYBIND11_DEF
        dialog& params(pybind11::object params);
 
        dialog& process(pybind11::object callback);
#endif
        dialog& process(std::function<void()> process);
 
        dialog& onPress(std::function<void(int)> press);
#ifdef PYBIND11_DEF
        dialog& onPress(pybind11::object press);
#endif
 
        int show();
 
        dialog& widget(BaseWidget* w);
    };
 
    class APICALL resource {
        ItemsFolder* folder;
    public:
        resource(const char* id);
 
        static std::vector<std::string> listAllResourcesTypes();
 
        std::vector<std::string> listFolders();
 
        std::string currentFolder();
 
        std::string currentFolderFullPath();
 
        std::string rootPath();
 
        std::vector<std::string> supportedExtensions();
 
        void setCurrentFolder(const char* folder);
 
        void createFolder(const char* folderName);
 
        void removeFolder(const char* folderName);
 
        std::vector<std::string> listCurrentFolderItems();
 
        void addItem(const char* itemPath);
 
        void removeItem(const char* itemName);
 
        void selectItem(const char* itemName);
 
        void moveItemToFolder(const char* itemName, const char* destFolderName);
 
        std::string getCurrentItem();
    };
 
    class APICALL io {
    public:
        static const char* installPath();
 
        static const char* dataPath();
 
        static const char* documents(const char* path);
 
        static bool fileExists(const char* path);
 
        static void copyFile(const char* src, const char* dest);
 
        static void copyFolder(const char* src, const char* dest);
 
        static void removeFile(const char* filename);
 
        static void removeFolder(const char* folder);
 
        static std::string toFullPathInDataFolder(const char* path);
        static void toFullPathInDataFolder(str* path);
 
        static std::string toFullPathInInstallFolder(const char* path);
        static void toFullPathInInstallFolder(str* path);
 
        static std::string convertToWritablePath(const char* path);
        static void convertToWritablePath(str* path);
 
        static std::string convertToWritablePathIfFileExists(const char* path);
        static void convertToWritablePathIfFileExists(str* path);
 
        static std::string getExtension(const char* filepath);
 
        static std::string getFileName(const char* filepath);
 
        static std::string getFilePath(const char* filepath);
 
        static std::string getFileNameWithoutExtension(const char* filepath);
 
        static std::string strFromFile(const char* filename);
 
        static void strToFile(const char* text, const char* filename);
 
        static size_t getFileSize(const char* filename);
 
        static vec2 cursorPos();
 
        static vec2 snappedCursorPos();
 
        static rect wholeScreen();
 
        static rect workArea();
 
        static void progressBar(float stage, float max_stage, const char* message);
 
        static void progressBarInWindowHeader(float stage, float max_stage, const char* message);
 
        static void setWindowTitle(const char* text, float seconds);
 
        static void step(int count = 1);
 
        static void exec(const char* command, const char* arguments = nullptr);
 
        static const char* execAndWait(const char* command, const char* arguments = nullptr);
 
 
        static void updateCoatPyi(const char* folderOrFile);
 
        static void ListFiles(const char* folder, const char* mask, coat::list<coat::str>& result, bool recursive = true);
 
        static std::vector<std::string> ListFiles(const char* folder, const char* mask, bool recursive = true);
 
        static void ListFolders(const char* startFolder, coat::list<coat::str>& result);
 
        static std::vector<std::string> ListFolders(const char* startFolder);
 
        static const char* supportedImagesFormats();
 
        static const char* supportedMeshesFormats();
 
        static bool openFileDialog(const char* extensions, str& fileName);
        static std::string openFileDialog(const char* extensions);
 
        static bool openFilesDialog(const char* extensions, list<str>& fileNames);
 
        static std::vector<std::string> openFilesDialog(const char* extensions);
 
        static bool saveFileDialog(const char* extensions, str& fileName);
        static std::string saveFileDialog(const char* extensions);
 
        static const char* currentSceneFilepath();
 
        static void pipInstall(const char* requirements);
        static void pipUninstall(const char* requirements);
 
        static std::string pythonPath();
 
        static void showPythonConsole();
 
        static void executeScript(const char* path);
 
 
        static void installRequirements(const char* path_to_requirements_txt);
#ifdef PYBIND11_DEF
        static std::string toJson(const pybind11::object& obj, const char* filename = "");
 
        static void fromJsonFile(pybind11::object& obj, const char* filename);
 
        static void restoreObjectFormJsonString(pybind11::object& obj, const char* data);
#endif
 
        static void createRedistributablePackageFromFolder(const char* folder, const char* package_name, const char* excluded_folders_names = "", const char* excluded_extensions = "");
 
        static void download(const char* url, std::function<void(const char*, const char*)> report_success);
 
        static int getDownloadProgress();
 
        static void post_request(const char* url, const char* data, const char* headers, const std::function<void(const char*)>& report_success = nullptr, const std::function<void(const char*)>& report_error = nullptr);
 
        static void get_request(const char* url, const char* headers, const std::function<void(const char*)>& report_success = nullptr, const std::function<void(const char*)>& report_error = nullptr);
 
        static std::vector<std::string> listBlenderInstallFolders();
 
        static void saveScreenshot(const char* filename, int x = 0, int y = 0, int width = 0, int height = 0);
 
        static void removeBackground(const char* image1, const char* image2, const char* result);
    };
 
    class APICALL utils {
    public:
        static vec4 dwordToVec4(unsigned int d);
 
        static unsigned vec4ToDword(const vec4& v);
 
        static void randomize(int seed);
 
        static float random01();
 
        static float random(float min, float max);
 
        static vec3 randomNormal();
 
        static vec3 perlin3d(vec3 p, float seed = 0);
 
        static float perlin(vec3 p, float seed = 0);
 
        static const char* getEnumValueByIndex(const char* enumID, int index);
 
        static int getEnumValue(const char* enumID, const char* key);
 
        static int getEnumValueIndex(const char* enumID, const char* key);
 
        static int getEnumValuesCount(const char* enumID);
 
        static void clearEnum(const char* enumID);
 
        static void addEnumValue(const char* enumID, const char* key, int value = - 1);
 
        static void quit();
 
        static void testSuccessful();
 
        static void testFailed(const char* message);
 
        static void signal(const char* message);
        
        static std::vector<std::string>& last_signals();
 
        static float getFPS();
 
        static float getFrameTimeMs();
 
        static bool inRenderProcess();
 
        static void set(const char* key, const char* value);
 
        static const char* get(const char* key);
    };
 
    class APICALL uv {
    public:
        static int uvSetsCount();
 
        static void setUnwrapIslandsDistance(float distance);
 
        static float getUnwrapIslandsDistance();
 
        static int currentUvSet();
 
        static int islandsCount(int uv_set);
 
        static Mesh islandToMesh(int uv_set, int island_index);
 
        static Mesh islandToMeshInSpace(int uv_set, int island_index);
 
        static std::vector<int> getIslandVertexMapping(int uv_set, int island_index);
 
        static std::vector<int> getIslandBorder(int uv_set, int island_index);
 
        static std::vector<int> getBorderBetweenIslands(int uv_set1, int island_index1, int uv_set2, int island_index2);
 
        static vec2 getIslandVertexUv(int uv_set, int island_index, int vertex_index);
 
        static Mesh flattenSingleIsland(const Mesh& mesh, int method, bool optimize_rotation = true, bool scale_to_geometry = true);
 
        static void meshToIsland(const Mesh& mesh, int uv_set, int island_index);
 
        static void pack(int uv_set, bool rotate, bool shuffle);
 
        static void unwrap(int uv_set);
 
        static void toAbf(int uv_set, int island_index);
 
        static void toLscm(int uv_set, int island_index);
 
        static void toGu(int uv_set, int island_index);
 
        static void toPlanar(int uv_set, int island_index);
 
        static void toStripe(int uv_set, int island_index);
 
        static void toUvSet(int uv_set, int island_index, int destination_uv_set);
 
        static Mesh getWholeMesh();
 
        static Mesh selectedToMesh();
 
        static std::vector<int> getSeams();
 
        static void addSeam(DWORDS2 start_vertex_index, int end_vertex_index);
 
        static void removeSeam(int start_vertex_index, int end_vertex_index);
 
        static std::vector<int> getSharpEdges();
 
        static void addSharpEdge(int start_vertex_index, int end_vertex_index);
 
        static void removeSharpEdge(int start_vertex_index, int end_vertex_index);
 
        static void unwrapUnassigned();
 
        static void applyUVSet();
    };
 
 
    enum ClusterScale
    {
        Uniform_Scaling = 0,
        Axial_Normal = 1,
        Axial_X = 2,
        Axial_Y = 3,
        Axial_Z = 4,
        Radial_Normal = 5,
        Radial_X = 6,
        Radial_Y = 7,
        Radial_Z = 8
    };
    class APICALL Model {
    protected:
        friend class Mesh;
        ClusteredMesh* _mesh;
        bool _from_retopo;
        bool _from_uv;
        ClusteredMesh& _mctx();
        ClusteredMesh* _pmctx() const;
        static void inc_ref(ClusteredMesh* m);
        static void dec_ref(ClusteredMesh* m);
        static bool has_ref(ClusteredMesh* m);
        static ClusteredMesh* allocate();
        static ClusteredMesh* allocate(ClusteredMesh* src);
        static std::vector<std::pair<ClusteredMesh*, int>> allocated_meshes;
    public:
        Model();
 
        Model(const Model& source);
 
        Model(const Mesh& source);
 
        Model & operator=(const Model& source);
 
        Model & operator=(const Mesh& source);
 
        Model & operator += (const Model& source);
 
        Model & operator += (const Mesh& source);
 
        Model& transform(const mat4& m);
 
        Model MakeCopy() const;
 
        ~Model();
 
        static Model fromRetopo();
 
        static Model fromModeling();
 
        static Model fromUv();
 
        void displayOptions(bool showWireframe = true, bool showColored = true, bool showSeams = true, bool showSharpEdges = true, bool smoothView = false);
 
        int getObjectsCount();
 
        int getCurrentObject();
 
        void setCurrentObject(int index);
 
        const char* getObjectName(int group_index);
 
        void removeObject(int group_index);
 
        void setObjectName(int index, const char* name);
 
        void setObjectVisibility(int index, bool visible);
 
        bool getObjectVisibility(int index);
 
        int addObject(const char* name);
 
        int addMaterial(const char* name);
 
        void removeUnusedMaterials();
 
        vec4 getObjectReferenceColor(int group_index);
 
        void setObjectReferenceColor(int group_index, vec4 color);
 
        void selectedToObject(int group_index);
 
        Mesh getWholeMesh();
 
        Mesh selectedToMesh();
 
        Mesh visibleToMesh();
 
        void addTransformed(const Mesh& mesh, const mat4& Transform = mat4::Identity, BoolOpType b = BOOL_MERGE, bool select = false, bool snap_to_existing = false);
 
        Mesh getObjectMesh(int group_index);
 
        void setObjectMesh(int group_index, Mesh& mesh, const mat4& transform = mat4::Identity);
 
        int duplicateObject(int group_index, const char* name = nullptr, const mat4& transform = mat4::Identity, bool select = false);
 
        std::string generateName(const char* base);
 
        void clearObjectMesh(int group_index);
 
        void clear();
 
        void dropUndo();
 
        std::vector<int> getSelectedFaces();
        void getSelectedFaces(list<int>& faces);
 
        void setSelectedFaces(std::vector<int>& faces);
        void setSelectedFaces(list<int>& faces);
 
        void selectFace(int face);
 
        void selectObject(int group_index, bool add_to_selected = true);
 
        std::vector<int> getObjectFaces(int group_index);
        void getObjectFaces(int group_index, list<int>& faces);
 
        bool isFaceSelected(int face);
 
        void unselectAllFaces();
 
        void expandSelection();
 
        void contractSelection();
 
        void selectedToEdges();
 
        void selectedToFaces();
 
        void selectedToVertices();
 
        std::vector<int> getSelectedEdges();
        void getSelectedEdges(list<int>& edges);
 
        void setSelectedEdges(std::vector<int>& edges);
        void setSelectedEdges(list<int>& edges);
 
        void selectEdge(int vertex1, int vertex2);
 
        bool isEdgeSelected(int vertex1, int vertex2);
 
        void unselectAllEdges();
 
        std::vector<int> getSelectedVertices();
        void getSelectedVertices(list<int>& vertices);
 
        std::vector<float> getSelectedVerticesWeights();
 
        void setSelectedVertices(const std::vector<int>& vertices, const std::vector<float>& weights);
        void setSelectedVertices(const list<int>& vertices, const list<float>& weights);
 
        void selectVertex(int vertex, float weight = 1.0f);
 
        bool isVertexSelected(int vertex);
 
        void unselectAllVertices();
 
        int facesCount();
 
        int vertsCount();
 
        int vertsUvCount();
 
        void removeFace(int face);
 
        int createNewFace(int Group, int UVSet);
 
        int getFaceVertsCount(int face);
 
        int getFaceVertex(int face, int vertex_index);
 
        std::vector<int> getFaceVerts(int face);
        void getFaceVerts(int face, list<int>& vertices);
 
        void setFaceVerts(int face, const std::vector<int>& vertices);
        void setFaceVerts(int face, const list<int>& vertices);
 
        bool getFaceVisibility(int face);
 
        void setFaceVisibility(int face, bool visibility);
 
        float getFaceSquare(int face);
 
        float getFaceUVSquare(int face);
 
        vec3 getFaceNormal(int face);
 
        int getFaceObject(int face);
 
        void setFaceObject(int face, int group);
 
        int getFaceMaterial(int face);
 
        void setFaceMaterial(int face, int uv_set);
 
        int getFaceUvVertsCount(int face);
 
        int getFaceUvVertex(int face, int vertex_index);
 
        std::vector<int> getFaceUvVerts(int face);
        void getFaceUvVerts(int face, list<int>& vertices);
 
        void setFaceUvVerts(int face, const std::vector<int>& vertices);
        void setFaceUvVerts(int face, const list<int>& vertices);
 
        vec3 getVertex(int vertex);
 
        void setVertex(int vertex, const vec3& position);
 
        int createNewVertex(const vec3& position);
 
        vec2 getVertexUV(int uv_vertex);
 
        void setVertexUV(int uv_vertex, const vec2& uv);
 
        int createNewUvVertex(const vec2& uv);
 
        vec3 getVertexNormal(int vertex);
 
        void updateNormals(bool for_snapping = true);
 
        void updateTopology();
 
        void cleanup();
 
        std::vector<int> getVertsNearVertex(int vertex);
        void getVertsNearVertex(int vertex, list<int>& vertices);
 
        std::vector<int> getFacesNearVertex(int vertex);
        void getFacesNearVertex(int vertex, list<int>& faces);
 
        std::vector<int> getFaceNeighbors(int face);
        void getFaceNeighbors(int face, list<int>& faces);
 
        std::vector<int> getFacesNearEdge(int vertex1, int vertex2);
        void getFacesNearEdge(int vertex1, int vertex2, list<int>& faces);
 
        bool isOpenEdge(int vertex1, int vertex2);
 
        bool isSharpEdge(int vertex1, int vertex2);
 
        void setEdgeSharpness(int vertex1, int vertex2, bool sharp);
 
        bool isSeam(int vertex1, int vertex2);
 
        void setEdgeSeam(int vertex1, int vertex2, bool seam);
 
        void collapseEdge(int vertex1, int vertex2);
 
        int islandsCount(int uv_set);
 
        Mesh islandToMesh(int uv_set, int island_index);
 
        Mesh islandToMeshInSpace(int uv_set, int island_index);
 
        std::vector<int> getIslandVertexMapping(int uv_set, int island_index);
 
        std::vector<int> getIslandBorder(int uv_set, int island_index);
 
        std::vector<int> getBorderBetweenIslands(int uv_set1, int island_index1, int uv_set2, int island_index2);
 
        vec2 getIslandVertexUv(int uv_set, int island_index, int vertex_index);
 
        static Mesh flattenSingleIsland(const Mesh& mesh, int method, bool optimize_rotation = true, bool scale_to_geometry = true);
 
        void meshToIsland(const Mesh& mesh, int uv_set, int island_index);
 
        void pack(int uv_set, bool rotate, bool shuffle);
 
        void unwrap(int uv_set);
 
        void toAbf(int uv_set, int island_index);
 
        void toLscm(int uv_set, int island_index);
 
        void toGu(int uv_set, int island_index);
 
        void toPlanar(int uv_set, int island_index);
 
        void toStripe(int uv_set, int island_index);
 
        void extrudeSelected();
 
        void moveSelectedFacesAlongFacesNormals(float displacement);
 
        void moveSelectedFacesAlongVertexNormals(float displacement);
 
        void subdivideSelectedFaces(bool apply_catmull_clark = false);
 
        void subdivide(bool apply_catmull_clark = true);
 
        void transformSelected(const mat4& transform, bool apply_symmetry);
 
        void scaleSelectedFacesClusters(float scale, ClusterScale method = Uniform_Scaling);
 
        void bevelOverSelectedVertices(float size);
 
        void bevelOverSelectedEdges(float size, int segments = 1, bool OldVariant = false);
 
        int splitEdge(int vertex1, int vertex2, float position);
 
        bool connect(int vertex1, int vertex2);
 
        bool checkConnectivity(int vertex1, int vertex2);
 
        void connectSelectedVerts();
 
        void invertSelectedFacesTopoplogically();
 
        void inset(float distance);
 
        void shell();
 
        void intrude();
 
        void relaxSelected();
 
        void selectPath(int vertex1, int vertex2);
 
        std::vector<int> getPath(int vertex1, int vertex2);
        
    };
    class APICALL logger {
        FILE* out;
        void* tempTimer;
        str filename;
        str _accum;
        int precission;
        void append(const char*);
        void close();
        
    public:
        logger();
 
        logger(const char* filename);
 
 
        ~logger();
        void open();
 
        void showMessage();
 
        logger& directTo(const char* filename);
 
        str getFullPath();
 
        logger& operator << (const char*);
 
        logger& operator << (str&);
 
        logger& operator << (const wchar_t*);
 
        logger& operator << (int);
 
        logger& operator << (float);
 
        logger& operator << (double);
 
        logger& operator << (const vec2&);
 
        logger& operator << (const vec3&);
 
        logger& operator << (const vec4&);
 
        logger& operator << (BaseClass*);
 
        logger& format(const char* format, ...);
 
        logger& flush();
 
        logger& newline();
 
        logger& timestamp();
 
        logger& startTimer();
 
        logger& endTimer();
 
        logger& floatPrecission(int signs = 2);
    };
}
 
 
#include "CorePrimAPI.h"
#pragma pack(pop)
 
#ifdef COMMS_OPENGL
#include <ui.h>
#include <ui_definition.h>
#define EXPORT(x) \
    static int Main();\
    __defineui(xxx) {\
        ui_element(#x, Main);\
    } static
#define EXPORT_COMMAND(x) \
    static void x();\
    __defineui(x) {\
        ui_element(#x, x);\
    } static void x()
#define EXPORT_EXTENSION(x) __defineui(___##x)
void executeCoreScript(const char* filename, bool build, bool clean);
#endif //COMMS_OPENGL