#ifndef slic3r_GUI_Selection_hpp_ #define slic3r_GUI_Selection_hpp_ #include #include "libslic3r/Geometry.hpp" #include "3DScene.hpp" #if ENABLE_RENDER_SELECTION_CENTER class GLUquadric; typedef class GLUquadric GLUquadricObj; #endif // ENABLE_RENDER_SELECTION_CENTER namespace Slic3r { namespace GUI { class TransformationType { public: enum Enum { // Transforming in a world coordinate system World = 0, // Transforming in a local coordinate system Local = 1, // Absolute transformations, allowed in local coordinate system only. Absolute = 0, // Relative transformations, allowed in both local and world coordinate system. Relative = 2, // For group selection, the transformation is performed as if the group made a single solid body. Joint = 0, // For group selection, the transformation is performed on each object independently. Independent = 4, World_Relative_Joint = World | Relative | Joint, World_Relative_Independent = World | Relative | Independent, Local_Absolute_Joint = Local | Absolute | Joint, Local_Absolute_Independent = Local | Absolute | Independent, Local_Relative_Joint = Local | Relative | Joint, Local_Relative_Independent = Local | Relative | Independent, }; TransformationType() : m_value(World) {} TransformationType(Enum value) : m_value(value) {} TransformationType& operator=(Enum value) { m_value = value; return *this; } Enum operator()() const { return m_value; } bool has(Enum v) const { return ((unsigned int)m_value & (unsigned int)v) != 0; } void set_world() { this->remove(Local); } void set_local() { this->add(Local); } void set_absolute() { this->remove(Relative); } void set_relative() { this->add(Relative); } void set_joint() { this->remove(Independent); } void set_independent() { this->add(Independent); } bool world() const { return !this->has(Local); } bool local() const { return this->has(Local); } bool absolute() const { return !this->has(Relative); } bool relative() const { return this->has(Relative); } bool joint() const { return !this->has(Independent); } bool independent() const { return this->has(Independent); } private: void add(Enum v) { m_value = Enum((unsigned int)m_value | (unsigned int)v); } void remove(Enum v) { m_value = Enum((unsigned int)m_value & (~(unsigned int)v)); } Enum m_value; }; class Selection { public: typedef std::set IndicesList; enum EMode : unsigned char { Volume, Instance }; enum EType : unsigned char { Invalid, Empty, WipeTower, SingleModifier, MultipleModifier, SingleVolume, MultipleVolume, SingleFullObject, MultipleFullObject, SingleFullInstance, MultipleFullInstance, Mixed }; private: struct VolumeCache { private: struct TransformCache { Vec3d position; Vec3d rotation; Vec3d scaling_factor; Vec3d mirror; Transform3d rotation_matrix; Transform3d scale_matrix; Transform3d mirror_matrix; Transform3d full_matrix; TransformCache(); explicit TransformCache(const Geometry::Transformation& transform); }; TransformCache m_volume; TransformCache m_instance; public: VolumeCache() {} VolumeCache(const Geometry::Transformation& volume_transform, const Geometry::Transformation& instance_transform); const Vec3d& get_volume_position() const { return m_volume.position; } const Vec3d& get_volume_rotation() const { return m_volume.rotation; } const Vec3d& get_volume_scaling_factor() const { return m_volume.scaling_factor; } const Vec3d& get_volume_mirror() const { return m_volume.mirror; } const Transform3d& get_volume_rotation_matrix() const { return m_volume.rotation_matrix; } const Transform3d& get_volume_scale_matrix() const { return m_volume.scale_matrix; } const Transform3d& get_volume_mirror_matrix() const { return m_volume.mirror_matrix; } const Transform3d& get_volume_full_matrix() const { return m_volume.full_matrix; } const Vec3d& get_instance_position() const { return m_instance.position; } const Vec3d& get_instance_rotation() const { return m_instance.rotation; } const Vec3d& get_instance_scaling_factor() const { return m_instance.scaling_factor; } const Vec3d& get_instance_mirror() const { return m_instance.mirror; } const Transform3d& get_instance_rotation_matrix() const { return m_instance.rotation_matrix; } const Transform3d& get_instance_scale_matrix() const { return m_instance.scale_matrix; } const Transform3d& get_instance_mirror_matrix() const { return m_instance.mirror_matrix; } const Transform3d& get_instance_full_matrix() const { return m_instance.full_matrix; } }; public: typedef std::map VolumesCache; typedef std::set InstanceIdxsList; typedef std::map ObjectIdxsToInstanceIdxsMap; class Clipboard { Model m_model; Selection::EMode m_mode; public: void reset() { m_model.clear_objects(); } bool is_empty() const { return m_model.objects.empty(); } ModelObject* add_object() { return m_model.add_object(); } ModelObject* get_object(unsigned int id) { return (id < (unsigned int)m_model.objects.size()) ? m_model.objects[id] : nullptr; } const ModelObjectPtrs& get_objects() const { return m_model.objects; } Selection::EMode get_mode() const { return m_mode; } void set_mode(Selection::EMode mode) { m_mode = mode; } }; private: struct Cache { // Cache of GLVolume derived transformation matrices, valid during mouse dragging. VolumesCache volumes_data; // Center of the dragged selection, valid during mouse dragging. Vec3d dragging_center; // Map from indices of ModelObject instances in Model::objects // to a set of indices of ModelVolume instances in ModelObject::instances // Here the index means a position inside the respective std::vector, not ModelID. ObjectIdxsToInstanceIdxsMap content; }; // Volumes owned by GLCanvas3D. GLVolumePtrs* m_volumes; // Model, not owned. Model* m_model; bool m_enabled; bool m_valid; EMode m_mode; EType m_type; // set of indices to m_volumes IndicesList m_list; Cache m_cache; Clipboard m_clipboard; mutable BoundingBoxf3 m_bounding_box; mutable bool m_bounding_box_dirty; // Bounding box of a selection, with no instance scaling applied. This bounding box // is useful for absolute scaling of tilted objects in world coordinate space. mutable BoundingBoxf3 m_unscaled_instance_bounding_box; mutable bool m_unscaled_instance_bounding_box_dirty; mutable BoundingBoxf3 m_scaled_instance_bounding_box; mutable bool m_scaled_instance_bounding_box_dirty; #if ENABLE_RENDER_SELECTION_CENTER GLUquadricObj* m_quadric; #endif // ENABLE_RENDER_SELECTION_CENTER mutable GLArrow m_arrow; mutable GLCurvedArrow m_curved_arrow; mutable float m_scale_factor; public: Selection(); #if ENABLE_RENDER_SELECTION_CENTER ~Selection(); #endif // ENABLE_RENDER_SELECTION_CENTER void set_volumes(GLVolumePtrs* volumes); bool init(bool useVBOs); bool is_enabled() const { return m_enabled; } void set_enabled(bool enable) { m_enabled = enable; } Model* get_model() const { return m_model; } void set_model(Model* model); EMode get_mode() const { return m_mode; } void set_mode(EMode mode) { m_mode = mode; } void add(unsigned int volume_idx, bool as_single_selection = true, bool check_for_already_contained = false); void remove(unsigned int volume_idx); void add_object(unsigned int object_idx, bool as_single_selection = true); void remove_object(unsigned int object_idx); void add_instance(unsigned int object_idx, unsigned int instance_idx, bool as_single_selection = true); void remove_instance(unsigned int object_idx, unsigned int instance_idx); void add_volume(unsigned int object_idx, unsigned int volume_idx, int instance_idx, bool as_single_selection = true); void remove_volume(unsigned int object_idx, unsigned int volume_idx); void add_all(); // Update the selection based on the new instance IDs. void instances_changed(const std::vector &instance_ids_selected); // Update the selection based on the map from old indices to new indices after m_volumes changed. // If the current selection is by instance, this call may select newly added volumes, if they belong to already selected instances. void volumes_changed(const std::vector &map_volume_old_to_new); void clear(); bool is_empty() const { return m_type == Empty; } bool is_wipe_tower() const { return m_type == WipeTower; } bool is_any_modifier() const { return is_single_modifier() || is_multiple_modifier(); } bool is_single_modifier() const { return m_type == SingleModifier; } bool is_multiple_modifier() const { return m_type == MultipleModifier; } bool is_single_full_instance() const; bool is_multiple_full_instance() const { return m_type == MultipleFullInstance; } bool is_single_full_object() const { return m_type == SingleFullObject; } bool is_multiple_full_object() const { return m_type == MultipleFullObject; } bool is_single_volume() const { return m_type == SingleVolume; } bool is_multiple_volume() const { return m_type == MultipleVolume; } bool is_any_volume() const { return is_single_volume() || is_multiple_volume(); } bool is_mixed() const { return m_type == Mixed; } bool is_from_single_instance() const { return get_instance_idx() != -1; } bool is_from_single_object() const; bool contains_volume(unsigned int volume_idx) const { return m_list.find(volume_idx) != m_list.end(); } bool requires_uniform_scale() const; // Returns the the object id if the selection is from a single object, otherwise is -1 int get_object_idx() const; // Returns the instance id if the selection is from a single object and from a single instance, otherwise is -1 int get_instance_idx() const; // Returns the indices of selected instances. // Can only be called if selection is from a single object. const InstanceIdxsList& get_instance_idxs() const; const IndicesList& get_volume_idxs() const { return m_list; } const GLVolume* get_volume(unsigned int volume_idx) const; const ObjectIdxsToInstanceIdxsMap& get_content() const { return m_cache.content; } unsigned int volumes_count() const { return (unsigned int)m_list.size(); } const BoundingBoxf3& get_bounding_box() const; // Bounding box of a selection, with no instance scaling applied. This bounding box // is useful for absolute scaling of tilted objects in world coordinate space. const BoundingBoxf3& get_unscaled_instance_bounding_box() const; const BoundingBoxf3& get_scaled_instance_bounding_box() const; void start_dragging(); void translate(const Vec3d& displacement, bool local = false); void rotate(const Vec3d& rotation, TransformationType transformation_type); void flattening_rotate(const Vec3d& normal); void scale(const Vec3d& scale, TransformationType transformation_type); void scale_to_fit_print_volume(const DynamicPrintConfig& config); void mirror(Axis axis); void translate(unsigned int object_idx, const Vec3d& displacement); void translate(unsigned int object_idx, unsigned int instance_idx, const Vec3d& displacement); void erase(); void render(float scale_factor = 1.0) const; #if ENABLE_RENDER_SELECTION_CENTER void render_center(bool gizmo_is_dragging) const; #endif // ENABLE_RENDER_SELECTION_CENTER void render_sidebar_hints(const std::string& sidebar_field) const; bool requires_local_axes() const; void copy_to_clipboard(); void paste_from_clipboard(); const Clipboard& get_clipboard() const { return m_clipboard; } private: void update_valid(); void update_type(); void set_caches(); void do_add_volume(unsigned int volume_idx); void do_add_instance(unsigned int object_idx, unsigned int instance_idx); void do_add_object(unsigned int object_idx); void do_remove_volume(unsigned int volume_idx); void do_remove_instance(unsigned int object_idx, unsigned int instance_idx); void do_remove_object(unsigned int object_idx); void calc_bounding_box() const; void calc_unscaled_instance_bounding_box() const; void calc_scaled_instance_bounding_box() const; void set_bounding_boxes_dirty() { m_bounding_box_dirty = true; m_unscaled_instance_bounding_box_dirty = true; m_scaled_instance_bounding_box_dirty = true; } void render_selected_volumes() const; void render_synchronized_volumes() const; void render_bounding_box(const BoundingBoxf3& box, float* color) const; void render_sidebar_position_hints(const std::string& sidebar_field) const; void render_sidebar_rotation_hints(const std::string& sidebar_field) const; void render_sidebar_scale_hints(const std::string& sidebar_field) const; void render_sidebar_size_hints(const std::string& sidebar_field) const; void render_sidebar_position_hint(Axis axis) const; void render_sidebar_rotation_hint(Axis axis) const; void render_sidebar_scale_hint(Axis axis) const; void render_sidebar_size_hint(Axis axis, double length) const; public: enum SyncRotationType { // Do not synchronize rotation. Either not rotating at all, or rotating by world Z axis. SYNC_ROTATION_NONE = 0, // Synchronize fully. Used from "place on bed" feature. SYNC_ROTATION_FULL = 1, // Synchronize after rotation by an axis not parallel with Z. SYNC_ROTATION_GENERAL = 2, }; void synchronize_unselected_instances(SyncRotationType sync_rotation_type); void synchronize_unselected_volumes(); private: void ensure_on_bed(); bool is_from_fully_selected_instance(unsigned int volume_idx) const; void paste_volumes_from_clipboard(); void paste_objects_from_clipboard(); }; } // namespace GUI } // namespace Slic3r #endif // slic3r_GUI_Selection_hpp_