/*************************************************************************/
/*  collada.h                                                            */
/*************************************************************************/
/*                       This file is part of:                           */
/*                           GODOT ENGINE                                */
/*                      https://godotengine.org                          */
/*************************************************************************/
/* Copyright (c) 2007-2018 Juan Linietsky, Ariel Manzur.                 */
/* Copyright (c) 2014-2018 Godot Engine contributors (cf. AUTHORS.md)    */
/*                                                                       */
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/* a copy of this software and associated documentation files (the       */
/* "Software"), to deal in the Software without restriction, including   */
/* without limitation the rights to use, copy, modify, merge, publish,   */
/* distribute, sublicense, and/or sell copies of the Software, and to    */
/* permit persons to whom the Software is furnished to do so, subject to */
/* the following conditions:                                             */
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/* The above copyright notice and this permission notice shall be        */
/* included in all copies or substantial portions of the Software.       */
/*                                                                       */
/* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,       */
/* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF    */
/* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.*/
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/*************************************************************************/

#ifdef TOOLS_ENABLED

#ifndef COLLADA_H
#define COLLADA_H

#include "core/io/xml_parser.h"
#include "core/map.h"
#include "core/project_settings.h"
#include "scene/resources/material.h"

class Collada {
public:
	enum ImportFlags {
		IMPORT_FLAG_SCENE = 1,
		IMPORT_FLAG_ANIMATION = 2
	};

	struct Image {

		String path;
	};

	struct Material {

		String name;
		String instance_effect;
	};

	struct Effect {

		String name;
		Map<String, Variant> params;

		struct Channel {

			int uv_idx;
			String texture;
			Color color;
			Channel() { uv_idx = 0; }
		};

		Channel diffuse, specular, emission, bump;
		float shininess;
		bool found_double_sided;
		bool double_sided;
		bool unshaded;

		String get_texture_path(const String &p_source, Collada &state) const;

		Effect() {
			diffuse.color = Color(1, 1, 1, 1);
			double_sided = true;
			found_double_sided = false;
			shininess = 40;
			unshaded = false;
		}
	};

	struct CameraData {

		enum Mode {
			MODE_PERSPECTIVE,
			MODE_ORTHOGONAL
		};

		Mode mode;

		union {
			struct {
				float x_fov;
				float y_fov;
			} perspective;
			struct {
				float x_mag;
				float y_mag;
			} orthogonal;
		};

		float aspect;
		float z_near;
		float z_far;

		CameraData() {

			mode = MODE_PERSPECTIVE;
			perspective.y_fov = 0;
			perspective.x_fov = 0;
			aspect = 1;
			z_near = 0.1;
			z_far = 100;
		}
	};

	struct LightData {

		enum Mode {
			MODE_AMBIENT,
			MODE_DIRECTIONAL,
			MODE_OMNI,
			MODE_SPOT
		};

		Mode mode;

		Color color;

		float constant_att;
		float linear_att;
		float quad_att;

		float spot_angle;
		float spot_exp;

		LightData() {

			mode = MODE_AMBIENT;
			color = Color(1, 1, 1, 1);
			constant_att = 0;
			linear_att = 0;
			quad_att = 0;

			spot_angle = 45;
			spot_exp = 1;
		}
	};

	struct MeshData {

		String name;
		struct Source {

			Vector<float> array;
			int stride;
		};

		Map<String, Source> sources;

		struct Vertices {

			Map<String, String> sources;
		};

		Map<String, Vertices> vertices;

		struct Primitives {

			struct SourceRef {

				String source;
				int offset;
			};

			String material;
			Map<String, SourceRef> sources;
			Vector<float> polygons;
			Vector<float> indices;
			int count;
			int vertex_size;
		};

		Vector<Primitives> primitives;

		bool found_double_sided;
		bool double_sided;

		MeshData() {
			found_double_sided = false;
			double_sided = true;
		}
	};

	struct CurveData {

		String name;
		bool closed;

		struct Source {

			Vector<String> sarray;
			Vector<float> array;
			int stride;
		};

		Map<String, Source> sources;

		Map<String, String> control_vertices;

		CurveData() {

			closed = false;
		}
	};
	struct SkinControllerData {

		String base;
		bool use_idrefs;

		Transform bind_shape;

		struct Source {

			Vector<String> sarray; //maybe for names
			Vector<float> array;
			int stride;
			Source() {
				stride = 1;
			}
		};

		Map<String, Source> sources;

		struct Joints {

			Map<String, String> sources;
		} joints;

		struct Weights {

			struct SourceRef {

				String source;
				int offset;
			};

			String material;
			Map<String, SourceRef> sources;
			Vector<float> sets;
			Vector<float> indices;
			int count;
		} weights;

		Map<String, Transform> bone_rest_map;

		SkinControllerData() { use_idrefs = false; }
	};

	struct MorphControllerData {

		String mesh;
		String mode;

		struct Source {

			int stride;
			Vector<String> sarray; //maybe for names
			Vector<float> array;
			Source() { stride = 1; }
		};

		Map<String, Source> sources;

		Map<String, String> targets;
		MorphControllerData() {}
	};

	struct Vertex {

		int idx;
		Vector3 vertex;
		Vector3 normal;
		Vector3 uv;
		Vector3 uv2;
		Plane tangent;
		Color color;
		int uid;
		struct Weight {
			int bone_idx;
			float weight;
			bool operator<(const Weight w) const { return weight > w.weight; } //heaviest first
		};

		Vector<Weight> weights;

		void fix_weights() {

			weights.sort();
			if (weights.size() > 4) {
				//cap to 4 and make weights add up 1
				weights.resize(4);
				float total = 0;
				for (int i = 0; i < 4; i++)
					total += weights[i].weight;
				if (total)
					for (int i = 0; i < 4; i++)
						weights.write[i].weight /= total;
			}
		}

		void fix_unit_scale(Collada &state);

		bool operator<(const Vertex &p_vert) const {

			if (uid == p_vert.uid) {
				if (vertex == p_vert.vertex) {
					if (normal == p_vert.normal) {
						if (uv == p_vert.uv) {
							if (uv2 == p_vert.uv2) {

								if (!weights.empty() || !p_vert.weights.empty()) {

									if (weights.size() == p_vert.weights.size()) {

										for (int i = 0; i < weights.size(); i++) {
											if (weights[i].bone_idx != p_vert.weights[i].bone_idx)
												return weights[i].bone_idx < p_vert.weights[i].bone_idx;

											if (weights[i].weight != p_vert.weights[i].weight)
												return weights[i].weight < p_vert.weights[i].weight;
										}
									} else {
										return weights.size() < p_vert.weights.size();
									}
								}

								return (color < p_vert.color);
							} else
								return (uv2 < p_vert.uv2);
						} else
							return (uv < p_vert.uv);
					} else
						return (normal < p_vert.normal);
				} else
					return vertex < p_vert.vertex;
			} else
				return uid < p_vert.uid;
		}

		Vertex() {
			uid = 0;
			idx = 0;
		}
	};
	struct Node {

		enum Type {

			TYPE_NODE,
			TYPE_JOINT,
			TYPE_SKELETON, //this bone is not collada, it's added afterwards as optimization
			TYPE_LIGHT,
			TYPE_CAMERA,
			TYPE_GEOMETRY
		};

		struct XForm {

			enum Op {
				OP_ROTATE,
				OP_SCALE,
				OP_TRANSLATE,
				OP_MATRIX,
				OP_VISIBILITY
			};

			String id;
			Op op;
			Vector<float> data;
		};

		Type type;

		String name;
		String id;
		String empty_draw_type;
		bool noname;
		Vector<XForm> xform_list;
		Transform default_transform;
		Transform post_transform;
		Vector<Node *> children;

		Node *parent;

		Transform compute_transform(Collada &state) const;
		Transform get_global_transform() const;
		Transform get_transform() const;

		bool ignore_anim;

		Node() {
			noname = false;
			type = TYPE_NODE;
			parent = NULL;
			ignore_anim = false;
		}
		virtual ~Node() {
			for (int i = 0; i < children.size(); i++)
				memdelete(children[i]);
		};
	};

	struct NodeSkeleton : public Node {

		NodeSkeleton() { type = TYPE_SKELETON; }
	};

	struct NodeJoint : public Node {

		NodeSkeleton *owner;
		String sid;
		NodeJoint() {
			type = TYPE_JOINT;
			owner = NULL;
		}
	};

	struct NodeGeometry : public Node {

		bool controller;
		String source;

		struct Material {
			String target;
		};

		Map<String, Material> material_map;
		Vector<String> skeletons;

		NodeGeometry() { type = TYPE_GEOMETRY; }
	};

	struct NodeCamera : public Node {

		String camera;

		NodeCamera() { type = TYPE_CAMERA; }
	};

	struct NodeLight : public Node {

		String light;

		NodeLight() { type = TYPE_LIGHT; }
	};

	struct VisualScene {

		String name;
		Vector<Node *> root_nodes;

		~VisualScene() {
			for (int i = 0; i < root_nodes.size(); i++)
				memdelete(root_nodes[i]);
		}
	};

	struct AnimationClip {

		String name;
		float begin;
		float end;
		Vector<String> tracks;

		AnimationClip() {
			begin = 0;
			end = 1;
		}
	};

	struct AnimationTrack {

		String id;
		String target;
		String param;
		String component;
		bool property;

		enum InterpolationType {
			INTERP_LINEAR,
			INTERP_BEZIER
		};

		struct Key {

			enum Type {
				TYPE_FLOAT,
				TYPE_MATRIX
			};

			float time;
			Vector<float> data;
			Point2 in_tangent;
			Point2 out_tangent;
			InterpolationType interp_type;

			Key() { interp_type = INTERP_LINEAR; }
		};

		Vector<float> get_value_at_time(float p_time) const;

		Vector<Key> keys;

		AnimationTrack() { property = false; }
	};

	/****************/
	/* IMPORT STATE */
	/****************/

	struct State {

		int import_flags;

		float unit_scale;
		Vector3::Axis up_axis;
		bool z_up;

		struct Version {

			int major, minor, rev;

			bool operator<(const Version &p_ver) const { return (major == p_ver.major) ? ((minor == p_ver.minor) ? (rev < p_ver.rev) : minor < p_ver.minor) : major < p_ver.major; }
			Version(int p_major = 0, int p_minor = 0, int p_rev = 0) {
				major = p_major;
				minor = p_minor;
				rev = p_rev;
			}
		} version;

		Map<String, CameraData> camera_data_map;
		Map<String, MeshData> mesh_data_map;
		Map<String, LightData> light_data_map;
		Map<String, CurveData> curve_data_map;

		Map<String, String> mesh_name_map;
		Map<String, String> morph_name_map;
		Map<String, String> morph_ownership_map;
		Map<String, SkinControllerData> skin_controller_data_map;
		Map<String, MorphControllerData> morph_controller_data_map;

		Map<String, Image> image_map;
		Map<String, Material> material_map;
		Map<String, Effect> effect_map;

		Map<String, VisualScene> visual_scene_map;
		Map<String, Node *> scene_map;
		Set<String> idref_joints;
		Map<String, String> sid_to_node_map;
		//Map<String,NodeJoint*> bone_map;

		Map<String, Transform> bone_rest_map;

		String local_path;
		String root_visual_scene;
		String root_physics_scene;

		Vector<AnimationClip> animation_clips;
		Vector<AnimationTrack> animation_tracks;
		Map<String, Vector<int> > referenced_tracks;
		Map<String, Vector<int> > by_id_tracks;

		float animation_length;

		State() {
			unit_scale = 1.0;
			up_axis = Vector3::AXIS_Y;
			import_flags = 0;
			animation_length = 0;
		}
	} state;

	Error load(const String &p_path, int p_flags = 0);

	Collada();

	Transform fix_transform(const Transform &p_transform);

	Transform get_root_transform() const;

	int get_uv_channel(String p_name);

private: // private stuff
	Map<String, int> channel_map;

	void _parse_asset(XMLParser &parser);
	void _parse_image(XMLParser &parser);
	void _parse_material(XMLParser &parser);
	void _parse_effect_material(XMLParser &parser, Effect &effect, String &id);
	void _parse_effect(XMLParser &parser);
	void _parse_camera(XMLParser &parser);
	void _parse_light(XMLParser &parser);
	void _parse_animation_clip(XMLParser &parser);

	void _parse_mesh_geometry(XMLParser &parser, String p_id, String p_name);
	void _parse_curve_geometry(XMLParser &parser, String p_id, String p_name);

	void _parse_skin_controller(XMLParser &parser, String p_id);
	void _parse_morph_controller(XMLParser &parser, String p_id);
	void _parse_controller(XMLParser &parser);

	Node *_parse_visual_instance_geometry(XMLParser &parser);
	Node *_parse_visual_instance_camera(XMLParser &parser);
	Node *_parse_visual_instance_light(XMLParser &parser);

	Node *_parse_visual_node_instance_data(XMLParser &parser);
	Node *_parse_visual_scene_node(XMLParser &parser);
	void _parse_visual_scene(XMLParser &parser);

	void _parse_animation(XMLParser &parser);
	void _parse_scene(XMLParser &parser);
	void _parse_library(XMLParser &parser);

	Variant _parse_param(XMLParser &parser);
	Vector<float> _read_float_array(XMLParser &parser);
	Vector<String> _read_string_array(XMLParser &parser);
	Transform _read_transform(XMLParser &parser);
	String _read_empty_draw_type(XMLParser &parser);

	void _joint_set_owner(Collada::Node *p_node, NodeSkeleton *p_owner);
	void _create_skeletons(Collada::Node **p_node, NodeSkeleton *p_skeleton = NULL);
	void _find_morph_nodes(VisualScene *p_vscene, Node *p_node);
	bool _remove_node(Node *p_parent, Node *p_node);
	void _remove_node(VisualScene *p_vscene, Node *p_node);
	void _merge_skeletons2(VisualScene *p_vscene);
	void _merge_skeletons(VisualScene *p_vscene, Node *p_node);
	bool _optimize_skeletons(VisualScene *p_vscene, Node *p_node);

	bool _move_geometry_to_skeletons(VisualScene *p_vscene, Node *p_node, List<Node *> *p_mgeom);

	void _optimize();
};

#endif // COLLADA_H

#endif