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source: downloads/OgreMain/include/OgreNode.h @ 1

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1/*
2-----------------------------------------------------------------------------
3This source file is part of OGRE
4    (Object-oriented Graphics Rendering Engine)
5For the latest info, see http://www.ogre3d.org/
6
7Copyright (c) 2000-2006 Torus Knot Software Ltd
8Also see acknowledgements in Readme.html
9
10This program is free software; you can redistribute it and/or modify it under
11the terms of the GNU Lesser General Public License as published by the Free Software
12Foundation; either version 2 of the License, or (at your option) any later
13version.
14
15This program is distributed in the hope that it will be useful, but WITHOUT
16ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
17FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details.
18
19You should have received a copy of the GNU Lesser General Public License along with
20this program; if not, write to the Free Software Foundation, Inc., 59 Temple
21Place - Suite 330, Boston, MA 02111-1307, USA, or go to
22http://www.gnu.org/copyleft/lesser.txt.
23
24You may alternatively use this source under the terms of a specific version of
25the OGRE Unrestricted License provided you have obtained such a license from
26Torus Knot Software Ltd.
27-----------------------------------------------------------------------------
28*/
29#ifndef _Node_H__
30#define _Node_H__
31
32#include "OgrePrerequisites.h"
33
34#include "OgreMatrix3.h"
35#include "OgreMatrix4.h"
36#include "OgreQuaternion.h"
37#include "OgreString.h"
38#include "OgreRenderable.h"
39#include "OgreIteratorWrappers.h"
40
41namespace Ogre {
42
43
44    /** Class representing a general-purpose node an articulated scene graph.
45        @remarks
46            A node in the scene graph is a node in a structured tree. A node contains
47            information about the transformation which will apply to
48            it and all of it's children. Child nodes can have transforms of their own, which
49            are combined with their parent's transformations.
50        @par
51            This is an abstract class - concrete classes are based on this for specific purposes,
52            e.g. SceneNode, Bone
53    */
54    class _OgreExport Node : public Renderable
55    {
56    public:
57        /** Enumeration denoting the spaces which a transform can be relative to.
58        */
59        enum TransformSpace
60        {
61            /// Transform is relative to the local space
62            TS_LOCAL,
63            /// Transform is relative to the space of the parent node
64            TS_PARENT,
65            /// Transform is relative to world space
66            TS_WORLD
67        };
68        typedef HashMap<String, Node*> ChildNodeMap;
69        typedef MapIterator<ChildNodeMap> ChildNodeIterator;
70                typedef ConstMapIterator<ChildNodeMap> ConstChildNodeIterator;
71
72                /** Listener which gets called back on Node events.
73                */
74                class _OgreExport Listener
75                {
76                public:
77                        Listener() {}
78                        virtual ~Listener() {}
79                        /** Called when a node gets updated.
80                        @remarks
81                                Note that this happens when the node's derived update happens,
82                                not every time a method altering it's state occurs. There may
83                                be several state-changing calls but only one of these calls,
84                                when the node graph is fully updated.
85                        */
86                        virtual void nodeUpdated(const Node*) {}
87                        /** Node is being destroyed */
88                        virtual void nodeDestroyed(const Node*) {};
89                        /** Node has been attached to a parent */
90                        virtual void nodeAttached(const Node*) {};
91                        /** Node has been detached from a parent */
92                        virtual void nodeDetached(const Node*) {};
93                };
94
95    protected:
96        /// Pointer to parent node
97        Node* mParent;
98        /// Collection of pointers to direct children; hashmap for efficiency
99        ChildNodeMap mChildren;
100
101                typedef std::set<Node*> ChildUpdateSet;
102        /// List of children which need updating, used if self is not out of date but children are
103        mutable ChildUpdateSet mChildrenToUpdate;
104        /// Flag to indicate own transform from parent is out of date
105        mutable bool mNeedParentUpdate;
106                /// Flag indicating that all children need to be updated
107                mutable bool mNeedChildUpdate;
108                /// Flag indicating that parent has been notified about update request
109            mutable bool mParentNotified ;
110        /// Flag indicating that the node has been queued for update
111        mutable bool mQueuedForUpdate;
112
113        /// Friendly name of this node, can be automatically generated if you don't care
114        String mName;
115
116        /// Incremented count for next name extension
117        static unsigned long msNextGeneratedNameExt;
118
119        /// Stores the orientation of the node relative to it's parent.
120        Quaternion mOrientation;
121
122        /// Stores the position/translation of the node relative to its parent.
123        Vector3 mPosition;
124
125        /// Stores the scaling factor applied to this node
126        Vector3 mScale;
127
128        /// Stores whether this node inherits orientation from it's parent
129        bool mInheritOrientation;
130
131        /// Stores whether this node inherits scale from it's parent
132        bool mInheritScale;
133
134                /// Material pointer should this node be rendered
135                mutable MaterialPtr mpMaterial;
136
137        /// Only available internally - notification of parent.
138        virtual void setParent(Node* parent);
139
140        /** Cached combined orientation.
141            @par
142                This member is the orientation derived by combining the
143                local transformations and those of it's parents.
144                This is updated when _updateFromParent is called by the
145                SceneManager or the nodes parent.
146        */
147        mutable Quaternion mDerivedOrientation;
148
149        /** Cached combined position.
150            @par
151                This member is the position derived by combining the
152                local transformations and those of it's parents.
153                This is updated when _updateFromParent is called by the
154                SceneManager or the nodes parent.
155        */
156        mutable Vector3 mDerivedPosition;
157
158        /** Cached combined scale.
159            @par
160                This member is the position derived by combining the
161                local transformations and those of it's parents.
162                This is updated when _updateFromParent is called by the
163                SceneManager or the nodes parent.
164        */
165        mutable Vector3 mDerivedScale;
166
167        /** Triggers the node to update it's combined transforms.
168            @par
169                This method is called internally by Ogre to ask the node
170                to update it's complete transformation based on it's parents
171                derived transform.
172        */
173        virtual void _updateFromParent(void) const;
174
175                /** Class-specific implementation of _updateFromParent.
176                @remarks
177                        Splitting the implementation of the update away from the update call
178                        itself allows the detail to be overridden without disrupting the
179                        general sequence of updateFromParent (e.g. raising events)
180                */
181                virtual void updateFromParentImpl(void) const;
182
183
184        /** Internal method for creating a new child node - must be overridden per subclass. */
185        virtual Node* createChildImpl(void) = 0;
186
187        /** Internal method for creating a new child node - must be overridden per subclass. */
188        virtual Node* createChildImpl(const String& name) = 0;
189
190        /// The position to use as a base for keyframe animation
191        Vector3 mInitialPosition;
192        /// The orientation to use as a base for keyframe animation
193        Quaternion mInitialOrientation;
194        /// The scale to use as a base for keyframe animation
195        Vector3 mInitialScale;
196
197        /// Cached derived transform as a 4x4 matrix
198        mutable Matrix4 mCachedTransform;
199        mutable bool mCachedTransformOutOfDate;
200
201                /** Node listener - only one allowed (no list) for size & performance reasons. */
202                Listener* mListener;
203
204                typedef std::vector<Node*> QueuedUpdates;
205                static QueuedUpdates msQueuedUpdates;
206
207
208    public:
209        /** Constructor, should only be called by parent, not directly.
210        @remarks
211            Generates a name.
212        */
213        Node();
214        /** Constructor, should only be called by parent, not directly.
215        @remarks
216            Assigned a name.
217        */
218        Node(const String& name);
219
220        virtual ~Node(); 
221
222        /** Returns the name of the node. */
223        const String& getName(void) const;
224
225        /** Gets this node's parent (NULL if this is the root).
226        */
227        virtual Node* getParent(void) const;
228
229        /** Returns a quaternion representing the nodes orientation.
230        */
231        virtual const Quaternion & getOrientation() const;
232
233        /** Sets the orientation of this node via a quaternion.
234        @remarks
235            Orientatings, unlike other transforms, are not always inherited by child nodes.
236            Whether or not orientatings affect the orientation of the child nodes depends on
237            the setInheritOrientation option of the child. In some cases you want a orientating
238            of a parent node to apply to a child node (e.g. where the child node is a part of
239            the same object, so you want it to be the same relative orientation based on the
240            parent's orientation), but not in other cases (e.g. where the child node is just
241            for positioning another object, you want it to maintain it's own orientation).
242            The default is to inherit as with other transforms.
243        @par
244            Note that rotations are oriented around the node's origin.
245        */
246        virtual void setOrientation( const Quaternion& q );
247
248        /** Sets the orientation of this node via quaternion parameters.
249        @remarks
250            Orientatings, unlike other transforms, are not always inherited by child nodes.
251            Whether or not orientatings affect the orientation of the child nodes depends on
252            the setInheritOrientation option of the child. In some cases you want a orientating
253            of a parent node to apply to a child node (e.g. where the child node is a part of
254            the same object, so you want it to be the same relative orientation based on the
255            parent's orientation), but not in other cases (e.g. where the child node is just
256            for positioning another object, you want it to maintain it's own orientation).
257            The default is to inherit as with other transforms.
258        @par
259            Note that rotations are oriented around the node's origin.
260        */
261        virtual void setOrientation( Real w, Real x, Real y, Real z);
262
263        /** Resets the nodes orientation (local axes as world axes, no rotation).
264        @remarks
265            Orientatings, unlike other transforms, are not always inherited by child nodes.
266            Whether or not orientatings affect the orientation of the child nodes depends on
267            the setInheritOrientation option of the child. In some cases you want a orientating
268            of a parent node to apply to a child node (e.g. where the child node is a part of
269            the same object, so you want it to be the same relative orientation based on the
270            parent's orientation), but not in other cases (e.g. where the child node is just
271            for positioning another object, you want it to maintain it's own orientation).
272            The default is to inherit as with other transforms.
273        @par
274            Note that rotations are oriented around the node's origin.
275        */
276        virtual void resetOrientation(void);
277
278        /** Sets the position of the node relative to it's parent.
279        */
280        virtual void setPosition(const Vector3& pos);
281
282        /** Sets the position of the node relative to it's parent.
283        */
284        virtual void setPosition(Real x, Real y, Real z);
285
286        /** Gets the position of the node relative to it's parent.
287        */
288        virtual const Vector3 & getPosition(void) const;
289
290        /** Sets the scaling factor applied to this node.
291        @remarks
292            Scaling factors, unlike other transforms, are not always inherited by child nodes.
293            Whether or not scalings affect the size of the child nodes depends on the setInheritScale
294            option of the child. In some cases you want a scaling factor of a parent node to apply to
295            a child node (e.g. where the child node is a part of the same object, so you want it to be
296            the same relative size based on the parent's size), but not in other cases (e.g. where the
297            child node is just for positioning another object, you want it to maintain it's own size).
298            The default is to inherit as with other transforms.
299        @par
300            Note that like rotations, scalings are oriented around the node's origin.
301        */
302        virtual void setScale(const Vector3& scale);
303
304        /** Sets the scaling factor applied to this node.
305        @remarks
306            Scaling factors, unlike other transforms, are not always inherited by child nodes.
307            Whether or not scalings affect the size of the child nodes depends on the setInheritScale
308            option of the child. In some cases you want a scaling factor of a parent node to apply to
309            a child node (e.g. where the child node is a part of the same object, so you want it to be
310            the same relative size based on the parent's size), but not in other cases (e.g. where the
311            child node is just for positioning another object, you want it to maintain it's own size).
312            The default is to inherit as with other transforms.
313        @par
314            Note that like rotations, scalings are oriented around the node's origin.
315        */
316        virtual void setScale(Real x, Real y, Real z);
317
318        /** Gets the scaling factor of this node.
319        */
320        virtual const Vector3 & getScale(void) const;
321
322        /** Tells the node whether it should inherit orientation from it's parent node.
323        @remarks
324            Orientatings, unlike other transforms, are not always inherited by child nodes.
325            Whether or not orientatings affect the orientation of the child nodes depends on
326            the setInheritOrientation option of the child. In some cases you want a orientating
327            of a parent node to apply to a child node (e.g. where the child node is a part of
328            the same object, so you want it to be the same relative orientation based on the
329            parent's orientation), but not in other cases (e.g. where the child node is just
330            for positioning another object, you want it to maintain it's own orientation).
331            The default is to inherit as with other transforms.
332        @param inherit If true, this node's orientation will be affected by its parent's orientation.
333            If false, it will not be affected.
334        */
335        virtual void setInheritOrientation(bool inherit);
336
337        /** Returns true if this node is affected by orientation applied to the parent node.
338        @remarks
339            Orientatings, unlike other transforms, are not always inherited by child nodes.
340            Whether or not orientatings affect the orientation of the child nodes depends on
341            the setInheritOrientation option of the child. In some cases you want a orientating
342            of a parent node to apply to a child node (e.g. where the child node is a part of
343            the same object, so you want it to be the same relative orientation based on the
344            parent's orientation), but not in other cases (e.g. where the child node is just
345            for positioning another object, you want it to maintain it's own orientation).
346            The default is to inherit as with other transforms.
347        @remarks
348            See setInheritOrientation for more info.
349        */
350        virtual bool getInheritOrientation(void) const;
351
352        /** Tells the node whether it should inherit scaling factors from it's parent node.
353        @remarks
354            Scaling factors, unlike other transforms, are not always inherited by child nodes.
355            Whether or not scalings affect the size of the child nodes depends on the setInheritScale
356            option of the child. In some cases you want a scaling factor of a parent node to apply to
357            a child node (e.g. where the child node is a part of the same object, so you want it to be
358            the same relative size based on the parent's size), but not in other cases (e.g. where the
359            child node is just for positioning another object, you want it to maintain it's own size).
360            The default is to inherit as with other transforms.
361        @param inherit If true, this node's scale will be affected by its parent's scale. If false,
362            it will not be affected.
363        */
364        virtual void setInheritScale(bool inherit);
365
366        /** Returns true if this node is affected by scaling factors applied to the parent node.
367        @remarks
368            See setInheritScale for more info.
369        */
370        virtual bool getInheritScale(void) const;
371
372        /** Scales the node, combining it's current scale with the passed in scaling factor.
373        @remarks
374            This method applies an extra scaling factor to the node's existing scale, (unlike setScale
375            which overwrites it) combining it's current scale with the new one. E.g. calling this
376            method twice with Vector3(2,2,2) would have the same effect as setScale(Vector3(4,4,4)) if
377            the existing scale was 1.
378        @par
379            Note that like rotations, scalings are oriented around the node's origin.
380        */
381        virtual void scale(const Vector3& scale);
382
383        /** Scales the node, combining it's current scale with the passed in scaling factor.
384        @remarks
385            This method applies an extra scaling factor to the node's existing scale, (unlike setScale
386            which overwrites it) combining it's current scale with the new one. E.g. calling this
387            method twice with Vector3(2,2,2) would have the same effect as setScale(Vector3(4,4,4)) if
388            the existing scale was 1.
389        @par
390            Note that like rotations, scalings are oriented around the node's origin.
391        */
392        virtual void scale(Real x, Real y, Real z);
393
394        /** Moves the node along the cartesian axes.
395            @par
396                This method moves the node by the supplied vector along the
397                world cartesian axes, i.e. along world x,y,z
398            @param
399                d Vector with x,y,z values representing the translation.
400            @param
401                relativeTo The space which this transform is relative to.
402        */
403        virtual void translate(const Vector3& d, TransformSpace relativeTo = TS_PARENT);
404        /** Moves the node along the cartesian axes.
405            @par
406                This method moves the node by the supplied vector along the
407                world cartesian axes, i.e. along world x,y,z
408            @param
409                x
410            @param
411                y
412            @param
413                z Real x, y and z values representing the translation.
414            @param
415            relativeTo The space which this transform is relative to.
416        */
417        virtual void translate(Real x, Real y, Real z, TransformSpace relativeTo = TS_PARENT);
418        /** Moves the node along arbitrary axes.
419            @remarks
420                This method translates the node by a vector which is relative to
421                a custom set of axes.
422            @param
423                axes A 3x3 Matrix containg 3 column vectors each representing the
424                axes X, Y and Z respectively. In this format the standard cartesian
425                axes would be expressed as:
426                <pre>
427                1 0 0
428                0 1 0
429                0 0 1
430                </pre>
431                i.e. the identity matrix.
432            @param
433                move Vector relative to the axes above.
434            @param
435            relativeTo The space which this transform is relative to.
436        */
437        virtual void translate(const Matrix3& axes, const Vector3& move, TransformSpace relativeTo = TS_PARENT);
438        /** Moves the node along arbitrary axes.
439            @remarks
440            This method translates the node by a vector which is relative to
441            a custom set of axes.
442            @param
443                axes A 3x3 Matrix containg 3 column vectors each representing the
444                axes X, Y and Z respectively. In this format the standard cartesian
445                axes would be expressed as
446                <pre>
447                1 0 0
448                0 1 0
449                0 0 1
450                </pre>
451                i.e. the identity matrix.
452            @param
453                x,y,z Translation components relative to the axes above.
454            @param
455                relativeTo The space which this transform is relative to.
456        */
457        virtual void translate(const Matrix3& axes, Real x, Real y, Real z, TransformSpace relativeTo = TS_PARENT);
458
459        /** Rotate the node around the Z-axis.
460        */
461        virtual void roll(const Radian& angle, TransformSpace relativeTo = TS_LOCAL);
462#ifndef OGRE_FORCE_ANGLE_TYPES
463        inline void roll(Real degrees, TransformSpace relativeTo = TS_LOCAL) {
464                        roll ( Angle(degrees), relativeTo );
465                }
466#endif//OGRE_FORCE_ANGLE_TYPES
467
468        /** Rotate the node around the X-axis.
469        */
470        virtual void pitch(const Radian& angle, TransformSpace relativeTo = TS_LOCAL);
471#ifndef OGRE_FORCE_ANGLE_TYPES
472        inline void pitch(Real degrees, TransformSpace relativeTo = TS_LOCAL) {
473                        pitch ( Angle(degrees), relativeTo );
474                }
475#endif//OGRE_FORCE_ANGLE_TYPES
476
477        /** Rotate the node around the Y-axis.
478        */
479        virtual void yaw(const Radian& angle, TransformSpace relativeTo = TS_LOCAL);
480#ifndef OGRE_FORCE_ANGLE_TYPES
481        inline void yaw(Real degrees, TransformSpace relativeTo = TS_LOCAL) {
482                        yaw ( Angle(degrees), relativeTo );
483                }
484#endif//OGRE_FORCE_ANGLE_TYPES
485
486        /** Rotate the node around an arbitrary axis.
487        */
488        virtual void rotate(const Vector3& axis, const Radian& angle, TransformSpace relativeTo = TS_LOCAL);
489#ifndef OGRE_FORCE_ANGLE_TYPES
490        inline void rotate(const Vector3& axis, Real degrees, TransformSpace relativeTo = TS_LOCAL) {
491                        rotate ( axis, Angle(degrees), relativeTo );
492                }
493#endif//OGRE_FORCE_ANGLE_TYPES
494
495        /** Rotate the node around an aritrary axis using a Quarternion.
496        */
497        virtual void rotate(const Quaternion& q, TransformSpace relativeTo = TS_LOCAL);
498
499        /** Gets a matrix whose columns are the local axes based on
500            the nodes orientation relative to it's parent. */
501        virtual Matrix3 getLocalAxes(void) const;
502
503        /** Creates an unnamed new Node as a child of this node.
504        @param
505            translate Initial translation offset of child relative to parent
506        @param
507            rotate Initial rotation relative to parent
508        */
509        virtual Node* createChild(
510            const Vector3& translate = Vector3::ZERO, 
511            const Quaternion& rotate = Quaternion::IDENTITY );
512
513        /** Creates a new named Node as a child of this node.
514        @remarks
515            This creates a child node with a given name, which allows you to look the node up from
516            the parent which holds this collection of nodes.
517            @param
518                translate Initial translation offset of child relative to parent
519            @param
520                rotate Initial rotation relative to parent
521        */
522        virtual Node* createChild(const String& name, const Vector3& translate = Vector3::ZERO, const Quaternion& rotate = Quaternion::IDENTITY);
523
524        /** Adds a (precreated) child scene node to this node. If it is attached to another node,
525            it must be detached first.
526        @param child The Node which is to become a child node of this one
527        */
528        virtual void addChild(Node* child);
529
530        /** Reports the number of child nodes under this one.
531        */
532        virtual unsigned short numChildren(void) const;
533
534        /** Gets a pointer to a child node.
535        @remarks
536            There is an alternate getChild method which returns a named child.
537        */
538        virtual Node* getChild(unsigned short index) const;   
539
540        /** Gets a pointer to a named child node.
541        */
542        virtual Node* getChild(const String& name) const;
543
544        /** Retrieves an iterator for efficiently looping through all children of this node.
545        @remarks
546            Using this is faster than repeatedly calling getChild if you want to go through
547            all (or most of) the children of this node.
548            Note that the returned iterator is only valid whilst no children are added or
549            removed from this node. Thus you should not store this returned iterator for
550            later use, nor should you add / remove children whilst iterating through it;
551            store up changes for later. Note that calling methods on returned items in
552            the iterator IS allowed and does not invalidate the iterator.
553        */
554        virtual ChildNodeIterator getChildIterator(void);
555
556        /** Retrieves an iterator for efficiently looping through all children of this node.
557        @remarks
558            Using this is faster than repeatedly calling getChild if you want to go through
559            all (or most of) the children of this node.
560            Note that the returned iterator is only valid whilst no children are added or
561            removed from this node. Thus you should not store this returned iterator for
562            later use, nor should you add / remove children whilst iterating through it;
563            store up changes for later. Note that calling methods on returned items in
564            the iterator IS allowed and does not invalidate the iterator.
565        */
566                virtual ConstChildNodeIterator getChildIterator(void) const;
567
568        /** Drops the specified child from this node.
569        @remarks
570            Does not delete the node, just detaches it from
571            this parent, potentially to be reattached elsewhere.
572            There is also an alternate version which drops a named
573            child from this node.
574        */
575        virtual Node* removeChild(unsigned short index);
576        /** Drops the specified child from this node.
577        @remarks
578        Does not delete the node, just detaches it from
579        this parent, potentially to be reattached elsewhere.
580        There is also an alternate version which drops a named
581        child from this node.
582        */
583        virtual Node* removeChild(Node* child);
584
585        /** Drops the named child from this node.
586        @remarks
587            Does not delete the node, just detaches it from
588            this parent, potentially to be reattached elsewhere.
589        */
590        virtual Node* removeChild(const String& name);
591        /** Removes all child Nodes attached to this node. Does not delete the nodes, just detaches them from
592            this parent, potentially to be reattached elsewhere.
593        */
594        virtual void removeAllChildren(void);
595
596        /** Gets the orientation of the node as derived from all parents.
597        */
598        virtual const Quaternion & _getDerivedOrientation(void) const;
599
600        /** Gets the position of the node as derived from all parents.
601        */
602        virtual const Vector3 & _getDerivedPosition(void) const;
603
604        /** Gets the scaling factor of the node as derived from all parents.
605        */
606        virtual const Vector3 & _getDerivedScale(void) const;
607
608        /** Gets the full transformation matrix for this node.
609            @remarks
610                This method returns the full transformation matrix
611                for this node, including the effect of any parent node
612                transformations, provided they have been updated using the Node::_update method.
613                This should only be called by a SceneManager which knows the
614                derived transforms have been updated before calling this method.
615                Applications using Ogre should just use the relative transforms.
616        */
617        virtual const Matrix4& _getFullTransform(void) const;
618
619        /** Internal method to update the Node.
620            @note
621                Updates this node and any relevant children to incorporate transforms etc.
622                Don't call this yourself unless you are writing a SceneManager implementation.
623            @param
624                updateChildren If true, the update cascades down to all children. Specify false if you wish to
625                update children separately, e.g. because of a more selective SceneManager implementation.
626            @param
627                parentHasChanged This flag indicates that the parent xform has changed,
628                    so the child should retrieve the parent's xform and combine it with its own
629                    even if it hasn't changed itself.
630        */
631        virtual void _update(bool updateChildren, bool parentHasChanged);
632
633        /** Sets a listener for this Node.
634                @remarks
635                        Note for size and performance reasons only one listener per node is
636                        allowed.
637                */
638                virtual void setListener(Listener* listener) { mListener = listener; }
639               
640                /** Gets the current listener for this Node.
641                */
642                virtual Listener* getListener(void) const { return mListener; }
643               
644                /** Overridden from Renderable.
645        @remarks
646            This is only used if the SceneManager chooses to render the node. This option can be set
647            for SceneNodes at SceneManager::setDisplaySceneNodes, and for entities based on skeletal
648            models using Entity::setDisplayBones()
649        */
650        const MaterialPtr& getMaterial(void) const;
651        /** Overridden from Renderable.
652        @remarks
653            This is only used if the SceneManager chooses to render the node. This option can be set
654            for SceneNodes at SceneManager::setDisplaySceneNodes, and for entities based on skeletal
655            models using Entity::setDisplaySkeleton()
656        */
657        void getRenderOperation(RenderOperation& op);
658        /** Overridden from Renderable.
659        @remarks
660            This is only used if the SceneManager chooses to render the node. This option can be set
661            for SceneNodes at SceneManager::setDisplaySceneNodes, and for entities based on skeletal
662            models using Entity::setDisplaySkeleton()
663        */
664        void getWorldTransforms(Matrix4* xform) const;
665        /** @copydoc Renderable::getWorldOrientation */
666        const Quaternion& getWorldOrientation(void) const;
667        /** @copydoc Renderable::getWorldPosition */
668        const Vector3& getWorldPosition(void) const;
669
670        /** Sets the current transform of this node to be the 'initial state' ie that
671            position / orientation / scale to be used as a basis for delta values used
672            in keyframe animation.
673        @remarks
674            You never need to call this method unless you plan to animate this node. If you do
675            plan to animate it, call this method once you've loaded the node with it's base state,
676            ie the state on which all keyframes are based.
677        @par
678            If you never call this method, the initial state is the identity transform, ie do nothing.
679        */
680        virtual void setInitialState(void);
681
682        /** Resets the position / orientation / scale of this node to it's initial state, see setInitialState for more info. */
683        virtual void resetToInitialState(void);
684
685        /** Gets the initial position of this node, see setInitialState for more info.
686        @remarks
687            Also resets the cumulative animation weight used for blending.
688        */
689        virtual const Vector3& getInitialPosition(void) const;
690
691        /** Gets the initial orientation of this node, see setInitialState for more info. */
692        virtual const Quaternion& getInitialOrientation(void) const;
693
694        /** Gets the initial position of this node, see setInitialState for more info. */
695        virtual const Vector3& getInitialScale(void) const;
696
697        /** Overridden, see Renderable */
698        Real getSquaredViewDepth(const Camera* cam) const;
699
700        /** To be called in the event of transform changes to this node that require it's recalculation.
701        @remarks
702            This not only tags the node state as being 'dirty', it also requests it's parent to
703            know about it's dirtiness so it will get an update next time.
704                @param forceParentUpdate Even if the node thinks it has already told it's
705                        parent, tell it anyway
706        */
707        virtual void needUpdate(bool forceParentUpdate = false);
708        /** Called by children to notify their parent that they need an update.
709                @param forceParentUpdate Even if the node thinks it has already told it's
710                        parent, tell it anyway
711                */
712        virtual void requestUpdate(Node* child, bool forceParentUpdate = false);
713        /** Called by children to notify their parent that they no longer need an update. */
714        virtual void cancelUpdate(Node* child);
715
716                /** Queue a 'needUpdate' call to a node safely.
717                @ramarks
718                        You can't call needUpdate() during the scene graph update, e.g. in
719                        response to a Node::Listener hook, because the graph is already being
720                        updated, and update flag changes cannot be made reliably in that context.
721                        Call this method if you need to queue a needUpdate call in this case.
722                */
723                static void queueNeedUpdate(Node* n);
724                /** Process queued 'needUpdate' calls. */
725                static void processQueuedUpdates(void);
726
727        /** @copydoc Renderable::getLights */
728        const LightList& getLights(void) const;
729
730
731
732    };
733
734} //namespace
735
736#endif
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