3ds Max C++ API Reference
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TriObject Class Reference

#include <triobj.h>

+ Inheritance diagram for TriObject:

Public Member Functions

CoreExport TriObject ()
 
CoreExport ~TriObject ()
 
virtual CoreExport bool PrepareDisplay (const MaxSDK::Graphics::UpdateDisplayContext &prepareDisplayContext)
 
virtual CoreExport bool UpdatePerNodeItems (const MaxSDK::Graphics::UpdateDisplayContext &updateDisplayContext, MaxSDK::Graphics::UpdateNodeContext &nodeContext, MaxSDK::Graphics::IRenderItemContainer &targetRenderItemContainer)
 
CoreExport unsigned long GetObjectDisplayRequirement () const
 
virtual CoreExport BaseInterfaceGetInterface (Interface_ID iid)
 
CoreExport voidGetInterface (ULONG id)
 
CoreExport void ReleaseInterface (ULONG id, void *i)
 
CoreExport int HitTest (TimeValue t, INode *inode, int type, int crossing, int flags, IPoint2 *p, ViewExp *vpt)
 This method is called to determine if the specified screen point intersects the item.
 
CoreExport int Display (TimeValue t, INode *inode, ViewExp *vpt, int flags)
 This is called by the system to have the item display itself (perform a quick render in viewport, using the current TM).
 
CoreExport void Snap (TimeValue t, INode *inode, SnapInfo *snap, IPoint2 *p, ViewExp *vpt)
 Checks the point passed for a snap and updates the SnapInfo structure.
 
CoreExport CreateMouseCallBackGetCreateMouseCallBack ()
 This method allows the system to retrieve a callback object used in creating an object in the 3D viewports.
 
CoreExport RefTargetHandle Clone (RemapDir &remap)
 This method is used by 3ds Max to clone an object.
 
CoreExport ObjectState Eval (TimeValue time)
 This method is called to evaluate the object and return the result as an ObjectState.
 
CoreExport Interval ObjectValidity (TimeValue t)
 This method returns the validity interval of the object as a whole at the specified time.
 
CoreExport BOOL HasUVW ()
 Call this method to find out if the object has UVW coordinates.
 
CoreExport BOOL HasUVW (int mapChannel)
 Call this method to find out if the object is has UVW coordinates for the specified mapping channel.
 
CoreExport Interval ChannelValidity (TimeValue t, int nchan)
 Retrieve the current validity interval for the nchan channel of the object.
 
CoreExport void SetChannelValidity (int i, Interval v)
 Sets the validity interval of the specified channel.
 
CoreExport void InvalidateChannels (ChannelMask channels)
 This method invalidates the intervals for the given channel mask.
 
CoreExport Interval ConvertValidity (TimeValue t)
 
int IsDeformable ()
 Indicates whether this object is deformable.
 
int NumPoints ()
 The points of a deformable object are accessed through a virtual array interface.
 
Point3 GetPoint (int i)
 The points of a deformable object are accessed through a virtual array interface.
 
void SetPoint (int i, const Point3 &p)
 The points of a deformable object are accessed through a virtual array interface.
 
CoreExport BOOL IsPointSelected (int i)
 Returns TRUE if the 'i-th' point is selected; otherwise FALSE.
 
CoreExport float PointSelection (int i)
 Returns a floating point weighted point selection if the object supports it.
 
int IsMappable ()
 This method lets you know if the ApplyUVWMap() method is available for this object.
 
int NumMapChannels ()
 Returns the maximum number of channels supported by this type of object.
 
int NumMapsUsed ()
 Returns the number of maps currently used by this object.
 
void ApplyUVWMap (int type, float utile, float vtile, float wtile, int uflip, int vflip, int wflip, int cap, const Matrix3 &tm, int channel=1)
 This method may be called to map the object with UVW mapping coordinates.
 
CoreExport BOOL PolygonCount (TimeValue t, int &numFaces, int &numVerts)
 Retreives the number of faces and vertices of the polyginal mesh representation of this object.
 
void PointsWereChanged ()
 Informs the object that its points have been deformed, so it can invalidate its cache.
 
CoreExport void GetDeformBBox (TimeValue t, Box3 &box, Matrix3 *tm=NULL, BOOL useSel=FALSE)
 This method computes the bounding box in the objects local coordinates or the optional space defined by tm.
 
CoreExport void Deform (Deformer *defProc, int useSel)
 This is the method used to deform the object with a deformer.
 
CoreExport int CanConvertToType (Class_ID obtype)
 Indicates whether the object can be converted to the specified type.
 
CoreExport ObjectConvertToType (TimeValue t, Class_ID obtype)
 This method converts this object to the type specified and returns a pointer it.
 
CoreExport void FreeChannels (ChannelMask chan)
 This method deletes the memory associated with the specified channels and set the intervals associated with the channels to invalid (empty).
 
CoreExport ObjectMakeShallowCopy (ChannelMask channels)
 This method must make a copy of its "shell" and then shallow copy (see below) only the specified channels.
 
CoreExport void ShallowCopy (Object *fromOb, ChannelMask channels)
 This method copies the specified channels from the fromOb to this and copies the validity intervals.
 
CoreExport void NewAndCopyChannels (ChannelMask channels)
 This method replaces the locked channels with newly allocated copies.
 
CoreExport DWORD GetSubselState ()
 For objects that have sub selection levels, this method returns the current selection level of the object.
 
CoreExport void SetSubSelState (DWORD s)
 Implemented by the System.
 
CoreExport BOOL CheckObjectIntegrity ()
 This method is used for debugging only.
 
CoreExport int IntersectRay (TimeValue t, Ray &ray, float &at, Point3 &norm)
 This method is called to compute the intersection point and surface normal at this intersection point of the ray passed and the object.
 
CoreExport void GetWorldBoundBox (TimeValue t, INode *inode, ViewExp *vpt, Box3 &box)
 This method returns the world space bounding box for Objects (see below for the Sub-object gizmo or Modifiers gizmo version).
 
CoreExport void GetLocalBoundBox (TimeValue t, INode *inode, ViewExp *vpt, Box3 &box)
 This is the object space bounding box, the box in the object's local coordinates.
 
CoreExport MeshGetRenderMesh (TimeValue t, INode *inode, View &view, BOOL &needDelete)
 This method should be implemented by all renderable GeomObjects.
 
CoreExport BOOL CanDoDisplacementMapping ()
 Returns TRUE if this object can do displacement mapping; otherwise FALSE.
 
CoreExport TessApproxDisplacmentApprox ()
 
CoreExport bool & DoSubdivisionDisplacment ()
 
CoreExport bool & SplitMeshForDisplacement ()
 
CoreExport void SetDisplacmentApproxToPreset (int preset)
 
CoreExport void DisableDisplacementMapping (BOOL disable)
 
CoreExport void TopologyChanged ()
 Implemented by the System.
 
MeshGetMesh ()
 
CoreExport void DeleteThis ()
 Deletes an instance of this class.
 
void FreeCaches ()
 
Class_ID ClassID ()
 Retrieves a constant that uniquely identifies the plugin class.
 
void GetClassName (MSTR &s, bool localized=true) const override
 Retrieves the name of the plugin class.
 
void NotifyMe (Animatable *subAnim, int message)
 
int IsKeyable ()
 
int Update (TimeValue t)
 
const MCHARGetObjectName (bool) const override
 
CoreExport void RescaleWorldUnits (float f)
 Rescale size of all world units in reference hierarchy.
 
CoreExport IOResult Save (ISave *isave)
 Called for saving data.
 
CoreExport IOResult Save (ISave *isave, ChannelMask channels)
 Access the ReferenceSaveManager of this ReferenceMaker.
 
CoreExport IOResult Load (ILoad *iload)
 Called for loading data.
 
CoreExport IOResult Load (ILoad *iload, ChannelMask channels)
 Access the ReferenceSaveManager of this ReferenceMaker.
 
CoreExport void ReduceDisplayCaches ()
 Should reduce any derived display data to save memory, since the node wont be drawn until the user undhides it.
 
CoreExport bool NeedGWCacheRebuilt (GraphicsWindow *gw, Material *ma, int numMat)
 This returns whether the Graphics Cache for this object needs to be rebuilt.
 
CoreExport void BuildGWCache (GraphicsWindow *gw, Material *ma, int numMat, BOOL threaded)
 This builds the graphics window cached mesh.
 
virtual CoreExport void StartStackEval () override
 This are called right before and after a modifier is applied to an object.
 
virtual CoreExport void EndStackEval () override
 
- Public Member Functions inherited from GeomObject
virtual void InitNodeName (MSTR &s) override
 This is the default name of the node when it is created.
 
SClass_ID SuperClassID () override
 Retrieves a constant representing the type of the plugin.
 
virtual int IsRenderable () override
 Indicates whether the object may be rendered.
 
virtual int IsInstanceDependent ()
 If an object creates different meshes depending on the particular instance (view-dependent) it should return nonzero; otherwise 0.
 
virtual CoreExport MeshGetRenderMesh (TimeValue t, INode *inode, View &view, BOOL &needDelete)
 This method should be implemented by all renderable GeomObjects.
 
virtual int NumberOfRenderMeshes ()
 Objects may supply multiple render meshes ( e.g.
 
virtual MeshGetMultipleRenderMesh (TimeValue t, INode *inode, View &view, BOOL &needDelete, int meshNumber)
 For multiple render meshes, this method must be implemented.
 
virtual void GetMultipleRenderMeshTM (TimeValue t, INode *inode, View &view, int meshNumber, Matrix3 &meshTM, Interval &meshTMValid)
 For multiple render meshes, this method must be implemented.
 
virtual CoreExport PatchMeshGetRenderPatchMesh (TimeValue t, INode *inode, View &view, BOOL &needDelete)
 This method provides a patch mesh representation of the object for use by the renderer.
 
CoreExport Class_ID PreferredCollapseType () override
 This method allows objects to specify the class that is the best class to convert to when the user collapses the stack.
 
virtual BOOL CanDoDisplacementMapping ()
 Returns TRUE if this object can do displacement mapping; otherwise FALSE.
 
- Public Member Functions inherited from Object
CoreExport Object ()
 
CoreExport ~Object ()
 
virtual BOOL CheckObjectIntegrity ()
 This method is used for debugging only.
 
virtual BOOL HasUVW () override
 Call this method to find out if the object has UVW coordinates.
 
virtual BOOL HasUVW (int mapChannel) override
 Call this method to find out if the object is has UVW coordinates for the specified mapping channel.
 
virtual ObjectFindBaseObject ()
 It is called to return a pointer to the base object (an object that is not a derived object).
 
virtual BOOL IsParamSurface ()
 There are several methods used to access a parametric position on the surface of the object.
 
virtual int NumSurfaces (TimeValue t)
 Returns the number of parametric surfaces within the object.
 
virtual Point3 GetSurfacePoint (TimeValue t, float u, float v, Interval &iv)
 This method needs to be implemented if Object::IsParamSurface() returns TRUE.
 
virtual Point3 GetSurfacePoint (TimeValue t, int surface, float u, float v, Interval &iv)
 This method is used to retrieve a point on the specified surface of the object based on two parameters of the surface, u and v.
 
virtual void SurfaceClosed (TimeValue t, int surface, BOOL &uClosed, BOOL &vClosed)
 This method allows the object to return flags that indicate whether the parametric surface is closed in the U and V dimensions.
 
virtual BOOL GetExtendedProperties (TimeValue t, MSTR &prop1Label, MSTR &prop1Data, MSTR &prop2Label, MSTR &prop2Data)
 This method allows an object to return extended Properties fields.
 
CoreExport SvGraphNodeReference SvTraverseAnimGraph (IGraphObjectManager *gom, Animatable *owner, int id, DWORD flags)
 
CoreExport bool SvHandleDoubleClick (IGraphObjectManager *gom, IGraphNode *gNode)
 
CoreExport MSTR SvGetName (IGraphObjectManager *gom, IGraphNode *gNode, bool isBeingEdited)
 
CoreExport COLORREF SvHighlightColor (IGraphObjectManager *gom, IGraphNode *gNode)
 
CoreExport bool SvIsSelected (IGraphObjectManager *gom, IGraphNode *gNode)
 Returns true if the object is selected in its schematic view.
 
CoreExport MultiSelectCallbackSvGetMultiSelectCallback (IGraphObjectManager *gom, IGraphNode *gNode)
 
CoreExport bool SvCanSelect (IGraphObjectManager *gom, IGraphNode *gNode)
 
CoreExport void AddXTCObject (XTCObject *pObj, int priority=0, int branchID=-1)
 This method adds an extension object into the pipeline.
 
CoreExport int NumXTCObjects ()
 Returns the number of extension objects maintained by this Object.
 
CoreExport XTCObjectGetXTCObject (int index)
 Returns a pointer to the specified extension object.
 
CoreExport void RemoveXTCObject (int index)
 Removes the extension object as indicated by the index.
 
CoreExport void SetXTCObjectPriority (int index, int priority)
 Sets the priority for the extension object whose index is passed.
 
CoreExport int GetXTCObjectPriority (int index)
 Returns the integer priority number of the extension object whose index is passed.
 
CoreExport void SetXTCObjectBranchID (int index, int branchID)
 Sets the branch ID of the extension object whose index is passed.
 
CoreExport int GetXTCObjectBranchID (int index)
 Returns the integer branch ID of the extension object whose index is passed.
 
CoreExport void MergeAdditionalChannels (Object *from, int branchID)
 This method has to be called whenever the CompoundObject updates a branch (calling Eval() on it).
 
CoreExport void BranchDeleted (int branchID, bool reorderChannels)
 This method has to be called on the CompoundObject so it can delete the XTCObjects for the specified branch.
 
CoreExport void CopyAdditionalChannels (Object *from, bool deleteOld=true, bool bShallowCopy=false)
 This method copies all extension objects from the "from" object into the current object.
 
CoreExport void DeleteAllAdditionalChannels ()
 Implemented by the System.
 
virtual BOOL UseSelectionBrackets ()
 This method allows an object to choose whether or not it will display selection brackets in shaded viewports.
 
virtual BOOL IsManipulator ()
 
CoreExport voidGetInterface (ULONG id) override
 
CoreExport BaseInterfaceGetInterface (Interface_ID id) override
 
virtual void ReduceDisplayCaches ()
 Should reduce any derived display data to save memory, since the node wont be drawn until the user undhides it.
 
virtual bool NeedGWCacheRebuilt (GraphicsWindow *gw, Material *ma, int numMat)
 This returns whether the Graphics Cache for this object needs to be rebuilt.
 
virtual void BuildGWCache (GraphicsWindow *gw, Material *ma, int numMat, BOOL threaded)
 This builds the graphics window cached mesh.
 
virtual void StartStackEval ()
 This are called right before and after a modifier is applied to an object.
 
virtual void EndStackEval ()
 
virtual int UsesWireColor ()
 This method determines if the object color is used for display.
 
virtual int DoOwnSelectHilite ()
 If an object wants to draw itself in the 3D viewports in its selected state in some custom manner this method should return nonzero.
 
virtual BOOL NormalAlignVector (TimeValue t, Point3 &pt, Point3 &norm)
 Objects that don't support the IntersectRay() method (such as helper objects) can implement this method to provide a default vector for use with the normal align command in 3ds Max.
 
void LockObject ()
 Implemented by the System.
 
void UnlockObject ()
 Implemented by the System.
 
int IsObjectLocked ()
 Implemented by the System.
 
void LockChannels (ChannelMask channels)
 Implemented by the System.
 
void UnlockChannels (ChannelMask channels)
 Implemented by the System.
 
ChannelMask GetChannelLocks ()
 Implemented by the System.
 
void SetChannelLocks (ChannelMask channels)
 Implemented by the System.
 
ChannelMask GetChannelLocks (ChannelMask m)
 Implemented by the System.
 
virtual BOOL CanCacheObject ()
 This method determines if this object can have channels cached.
 
virtual void WSStateInvalidate ()
 This is called by a node when the node's world space state has become invalid.
 
virtual BOOL IsWorldSpaceObject ()
 Returns TRUE if the object as a world space object; otherwise FALSE.
 
CoreExport INodeGetWorldSpaceObjectNode ()
 Implemented by the System.
 
virtual BOOL IsParticleSystem ()
 Implemented by the System.
 
CoreExport void CopyChannelLocks (Object *obj, ChannelMask needChannels)
 Implemented by the System.
 
virtual BOOL HasWeights ()
 Returns TRUE if the object has weights for its points that can be set; otherwise FALSE.
 
virtual double GetWeight (int i)
 Returns the weight of the specified point of the object.
 
virtual void SetWeight (int i, const double w)
 Sets the weight of the specified point.
 
virtual CoreExport void GetCollapseTypes (Tab< Class_ID > &clist, Tab< MSTR * > &nlist)
 When the user clicks on the Edit Stack button in the modify branch a list of 'Convert To:' types is presented.
 
virtual ObjectCollapseObject ()
 This method is called on the world space cache object when the stack gets collapsed, that lets the pipeline object decide, if it wants to return a different object than itself.
 
CoreExport void ReadyChannelsForMod (ChannelMask channels)
 Implemented by the System.
 
virtual CoreExport void MaybeEnlargeViewportRect (GraphicsWindow *gw, Rect &rect)
 This method allows the object to enlarge its viewport rectangle, if it wants to.
 
CoreExport bool IsBaseClassOwnedChannel (int nchan)
 Implemented by the System.
 
CoreExport void UpdateValidity (int nchan, Interval v)
 When a modifier is applied to an object, it needs to include its own validity interval in the interval of the object.
 
Interval GetNoEvalInterval ()
 
void SetNoEvalInterval (Interval iv)
 
virtual CoreExport void ReduceCaches (TimeValue t)
 This method give the object the chance to reduce its caches.
 
virtual int IsConstObject ()
 This is called to determine if this is a construction object or not.
 
virtual int NumPipeBranches (bool selected=true)
 This method returns the number of pipeline branches combined by the object.
 
virtual ObjectGetPipeBranch (int i, bool selected=true)
 Retrieves sub-object branches from an object that supports branching.
 
virtual INodeGetBranchINode (TimeValue t, INode *node, int i, bool selected=true)
 When an object has sub-object branches, it is likely that the sub-objects are transformed relative to the object.
 
virtual int NumberOfContainedShapes ()
 Returns the number of shapes contained inside this object.
 
virtual ShapeObjectGetContainedShape (TimeValue t, int index)
 This method returns the ShapeObject specified by the index passed at the time specified.
 
virtual void GetContainedShapeMatrix (TimeValue t, int index, Matrix3 &mat)
 Returns the matrix associated with the shape whose index is passed.
 
virtual BitArray ContainedShapeSelectionArray ()
 This is used by the lofter.
 
virtual BOOL IsShapeObject ()
 Returns the number of shapes contained inside this object.
 
- Public Member Functions inherited from BaseObject
virtual CoreExport unsigned long GetObjectDisplayRequirement () const
 
virtual CoreExport bool PrepareDisplay (const MaxSDK::Graphics::UpdateDisplayContext &prepareDisplayContext)
 
virtual CoreExport bool UpdatePerNodeItems (const MaxSDK::Graphics::UpdateDisplayContext &updateDisplayContext, MaxSDK::Graphics::UpdateNodeContext &nodeContext, MaxSDK::Graphics::IRenderItemContainer &targetRenderItemContainer)
 
virtual CoreExport bool UpdatePerViewItems (const MaxSDK::Graphics::UpdateDisplayContext &updateDisplayContext, MaxSDK::Graphics::UpdateNodeContext &nodeContext, MaxSDK::Graphics::UpdateViewContext &viewContext, MaxSDK::Graphics::IRenderItemContainer &targetRenderItemContainer)
 
virtual CoreExport const MaxSDK::Graphics::RenderItemHandleArrayGetRenderItems () const
 
virtual CoreExport voidGetInterface (ULONG id) override
 
virtual CoreExport BaseInterfaceGetInterface (Interface_ID id) override
 
CoreExport BaseObject ()
 
virtual CoreExport ~BaseObject ()
 
virtual BOOL HasViewDependentBoundingBox ()
 This method return true if GetWorldBoundBox returns different boxes for different viewports.
 
virtual void SetExtendedDisplay (int flags)
 This method is used for storing mode-dependent display attributes.
 
 __declspec (deprecated) virtual const MCHAR *GetObjectName() MAX_SEALED
 
virtual CoreExport BOOL OKToChangeTopology (MSTR &modName)
 Implemented by the System.
 
virtual BOOL ChangeTopology ()
 This method asks the question of an object or modifier "Do you change topology"? An object or modifier returns TRUE if it is capable of changing topology when its parameters are being edited; otherwise FALSE.
 
virtual void ForceNotify (Interval &i)
 Notifies dependents of a change.
 
virtual IParamArrayGetParamBlock ()
 An object or modifier should implement this method if it wishes to make its parameter block available for other plug-ins to access it.
 
virtual IParamBlock2GetParamBlock (int i) override
 An object or modifier should implement this method if it wishes to make its parameter block available for other plug-ins to access it.
 
virtual int GetParamBlockIndex (int id)
 If a plug-in makes its parameter block available (using GetParamBlock()) then it will need to provide #defines for indices into the parameter block.
 
virtual void Move (TimeValue t, Matrix3 &partm, Matrix3 &tmAxis, Point3 &val, BOOL localOrigin=FALSE)
 When this method is called the plug-in should respond by moving its selected sub-object components.
 
virtual void Rotate (TimeValue t, Matrix3 &partm, Matrix3 &tmAxis, Quat &val, BOOL localOrigin=FALSE)
 When this method is called the plug-in should respond by rotating its selected sub-object components.
 
virtual void Scale (TimeValue t, Matrix3 &partm, Matrix3 &tmAxis, Point3 &val, BOOL localOrigin=FALSE)
 When this method is called the plug-in should respond by scaling its selected sub-object components.
 
virtual void TransformStart (TimeValue t)
 This method is called before the first Move(), Rotate() or Scale() call and before a hold is in effect.
 
virtual void TransformHoldingStart (TimeValue t)
 This method is called before the first Move(), Rotate() or Scale() call and after a hold is in effect.
 
virtual void TransformHoldingFinish (TimeValue t)
 This method is called after the user has completed the Move(), Rotate() or Scale() operation and before the undo object has been accepted.
 
virtual void TransformFinish (TimeValue t)
 This method is called after the user has completed the Move(), Rotate() or Scale() operation and the undo object has been accepted.
 
virtual void TransformCancel (TimeValue t)
 This method is called when the transform operation is canceled by a right-click and the undo has been canceled.
 
virtual int HitTest (TimeValue t, INode *inode, int type, int crossing, int flags, IPoint2 *p, ViewExp *vpt, ModContext *mc)
 This method is used in modifier gizmo hit testing.
 
virtual int Display (TimeValue t, INode *inode, ViewExp *vpt, int flags, ModContext *mc)
 When this method is called the plug-in should respond by performing a quick render of the modifier gizmo in viewport using the current TM.
 
virtual void GetWorldBoundBox (TimeValue t, INode *inode, ViewExp *vpt, Box3 &box, ModContext *mc)
 This method computes the world space bounding box of the modifier gizmo (or any object that when in sub-object mode has a gizmo).
 
virtual void CloneSelSubComponents (TimeValue t)
 This method is called to make a copy of the selected sub-object components of the item.
 
virtual void AcceptCloneSelSubComponents (TimeValue t)
 This method is called when the user mouses up after shift-cloning a sub-object selection.
 
virtual void SelectSubComponent (HitRecord *hitRec, BOOL selected, BOOL all, BOOL invert=FALSE)
 This method is called to change the selection state of the component identified by hitRec.
 
virtual void ClearSelection (int selLevel)
 This method is called to clear the selection for the given sub-object level.
 
virtual void SelectAll (int selLevel)
 This method is called to select every element of the given sub-object level.
 
virtual void InvertSelection (int selLevel)
 This method is called to invert the specified sub-object level.
 
virtual int SubObjectIndex (HitRecord *hitRec)
 Returns the index of the sub-object element identified by the HitRecord hitRec.
 
virtual void ActivateSubobjSel (int level, XFormModes &modes)
 When the user changes the selection of the sub-object drop down, this method is called to notify the plug-in.
 
virtual BOOL SupportsNamedSubSels ()
 An object that supports sub-object selection can choose to support named sub object selection sets.
 
virtual void ActivateSubSelSet (MSTR &setName)
 When the user chooses a name from the drop down list this method is called.
 
virtual void NewSetFromCurSel (MSTR &setName)
 If the user types a new name into the named selection set drop down then this method is called.
 
virtual void RemoveSubSelSet (MSTR &setName)
 If the user selects a set from the drop down and then chooses Remove Named Selections from the Edit menu this method is called.
 
virtual void SetupNamedSelDropDown ()
 To support the Edit Named Selections dialog, plug-ins must implement this method.
 
virtual int NumNamedSelSets ()
 To support the Edit Named Selections dialog, plug-ins must implement this method.
 
virtual MSTR GetNamedSelSetName (int i)
 To support the Edit Named Selections dialog, plug-ins must implement this method.
 
virtual void SetNamedSelSetName (int i, MSTR &newName)
 To support the Edit Named Selections dialog, plug-ins must implement this method.
 
virtual void NewSetByOperator (MSTR &newName, Tab< int > &sets, int op)
 To support the Edit Named Selections dialog, plug-ins must implement this method.
 
virtual void GetSubObjectCenters (SubObjAxisCallback *cb, TimeValue t, INode *node, ModContext *mc)
 When the user is in a sub-object selection level, the system needs to get the reference coordinate system definition from the current modifier being edited so that it can display the axis.
 
virtual void GetSubObjectTMs (SubObjAxisCallback *cb, TimeValue t, INode *node, ModContext *mc)
 When the user is in a sub-object selection level, the system needs to get the reference coordinate system definition from the current modifier being edited so that it can display the axis.
 
virtual void NotifyPreCollapse (INode *node, IDerivedObject *derObj, int index)
 This method is called before a modifier or object is collapsed.
 
virtual void NotifyPostCollapse (INode *node, Object *obj, IDerivedObject *derObj, int index)
 This method is called after a modifier or object is collapsed.
 
virtual int NumSubObjTypes ()
 Objects and modifiers that support subobjects have to overwrite this method - as well as GetSubObjType() - and return a class derived from ISubObjType in GetSubObjType().
 
virtual ISubObjTypeGetSubObjType (int i)
 Returns a pointer to the sub-object type for the sub-object whose index is passed.
 
virtual CoreExport int GetSubObjectLevel ()
 This method returns an integer which indicates the current sub-object level of the modifier or base object.
 
virtual void SetGenUVW (BOOL sw)
 This method is called to change the state of its Generate UVW boolean.
 
virtual void SetGenUVW (int mapChannel, BOOL sw)
 This method is called to change the state of its Generate UVW boolean for the specified mapping channel.
 
virtual void ShowEndResultChanged (BOOL showEndResult)
 This method notifies the BaseObject that the end result display has been switched (the "Show End Result" button has been toggled).
 
- Public Member Functions inherited from ReferenceTarget
CoreExport void GetClassName (MSTR &s, bool localized=true) const override
 Retrieves the name of the plugin class.
 
CoreExport SClass_ID SuperClassID () override
 Retrieves a constant representing the type of the plugin.
 
BOOL IsRefTarget () override
 Checks if this is a ReferenceTarget.
 
CoreExport RefResult TestForLoop (const Interval &refInterval, RefMakerHandle hmaker)
 Tests for a cyclical reference.
 
CoreExport BOOL HasDependents ()
 Checks if a ReferenceTarget has references.
 
CoreExport BOOL HasRealDependents ()
 Checks if this has Real (Strong) Dependents.
 
void BeginDependencyTest ()
 Starts Dependency Test.
 
BOOL EndDependencyTest ()
 Ends Dependency Test.
 
virtual void RefAdded (RefMakerHandle rm)
 Called after a reference is made to a target.
 
virtual void RefAddedUndoRedo (RefMakerHandle rm)
 Called after a reference is made to a target because of undo or redo.
 
 __declspec (deprecated) virtual void RefDeleted() final
 
virtual void RefDeleted (ReferenceMaker *oldOwner)
 Called after a reference to this is deleted.
 
 __declspec (deprecated) virtual void RefDeletedUndoRedo() final
 
virtual void RefDeletedUndoRedo (RefMakerHandle oldOwner)
 Called after a reference to this is deleted because of undo or redo.
 
CoreExport RefResult DeleteAllRefsToMe () override
 Deletes all references to this ReferenceTarget.
 
CoreExport RefResult TransferReferences (RefTargetHandle oldTarget, BOOL delOld=FALSE)
 Transfers all the references from oldTarget to this.
 
CoreExport int DoEnumDependents (DependentEnumProc *dep)
 Begins an enumeration that searches back in the dependency network.
 
virtual CoreExport void BaseClone (ReferenceTarget *from, ReferenceTarget *to, RemapDir &remap)
 This method copies base class data from an object to its clone.
 
CoreExport RefResult NotifyDependents (const Interval &changeInt, PartID partID, RefMessage message, SClass_ID sclass=NOTIFY_ALL, BOOL propagate=TRUE, RefTargetHandle hTarg=nullptr, NotifyDependentsOption notifyDependentsOption=REFNOTIFY_ALLOW_OPTIMIZATIONS) override
 Notify all dependent RefMakers concerned with the message.
 
void FlagDependents (TimeValue t, PartID which=PART_PUT_IN_FG)
 This sends the REFMSG_FLAGDEPENDENTS message up the pipeline.
 
virtual void NotifyForeground (TimeValue t)
 This method is called to flag dependents into the FG.
 
virtual void NotifyTarget (int message, ReferenceMaker *hMaker)
 Sends messages to ReferenceTargets.
 
CoreExport ReferenceTarget ()
 Constructor.
 
virtual CoreExport RefResult AutoDelete ()
 Deletes the object when it has no more real dependents.
 
CoreExport RefResult MaybeAutoDelete ()
 Deletes the object when it has no more real dependents.
 
- Public Member Functions inherited from ReferenceMaker
void GetClassName (MSTR &s, bool localized=true) const override
 Retrieves the name of the plugin class.
 
CoreExport SClass_ID SuperClassID () override
 Retrieves a constant representing the type of the plugin.
 
CoreExport RefResult ReplaceReference (int which, RefTargetHandle newtarg, BOOL delOld=TRUE)
 Used when cloning reference makers.
 
CoreExport RefResult DeleteAllRefsFromMe ()
 Deletes all references from this ReferenceMaker.
 
CoreExport RefResult DeleteAllRefs ()
 Deletes all references both to and from this item.
 
CoreExport RefResult DeleteReference (int i)
 Deletes the specified reference.
 
virtual BOOL CanTransferReference (int i)
 Tells whether this reference can be transfered.
 
CoreExport ReferenceSaveManagerGetReferenceSaveManager ()
 Access the ReferenceSaveManager of this ReferenceMaker.
 
virtual int RemapRefOnLoad (int iref)
 Used to load old files with references.
 
CoreExport void EnumAuxFiles (AssetEnumCallback &assetEnum, DWORD flags) override
 Enumerate auxiliary files (e.g. bitmaps)
 
virtual CoreExport void SaveEnum (SaveEnumProc &sep, BOOL isNodeCall=0)
 The default save enumeration.
 
virtual CoreExport bool SpecifySaveReferences (ReferenceSaveManager &referenceSaveManager)
 Used to specify reference slot remapping during scene file save.
 
CoreExport int DoEnumDependents (DependentEnumProc *dep)
 Begins an enumeration that searches back in the dependency network.
 
CoreExport bool EnumRefHierarchy (RefEnumProc &proc, bool includeCustAttribs=true, bool includeIndirectRefs=true, bool includeNonPersistentRefs=true, bool preventDuplicatesViaFlag=true)
 This method provides a general purpose reference enumerator.
 
CoreExport int FindRef (RefTargetHandle rtarg)
 Get the index of the ReferenceTarget.
 
BOOL IsRefMaker () override
 Tells whether it is a ReferenceMaker.
 
virtual BOOL IsRealDependency (ReferenceTarget *rtarg)
 Returns whether this is a "real" (strong) dependency or not.
 
virtual BOOL ShouldPersistWeakRef (RefTargetHandle rtarg)
 Specifies whether a weak reference is to be persisted on a partial load or save.
 
CoreExport ReferenceMaker ()
 Constructor.
 
CoreExport void DeleteMe ()
 Deletes an instance of this class.
 
virtual CoreExport int NumRefs ()
 Returns the total number of references this ReferenceMaker can hold.
 
virtual CoreExport RefTargetHandle GetReference (int i)
 Returns the 'i-th' reference.
 
- Public Member Functions inherited from Animatable
virtual void FreeCaches ()
 
virtual int NumChildren ()
 
virtual AnimatableChildAnim (int i)
 
virtual CoreExport MSTR NodeName ()
 
virtual void EditTrack ()
 
virtual CoreExport BOOL SubAnimSetKeyBufferPresent (int subNum)
 returns true if the sub-anim has a "Set Key" buffer present
 
virtual BOOL SetKeyBufferPresent ()
 returns true if there is a "Set Key" buffer present
 
virtual CoreExport void SubAnimCommitSetKeyBuffer (TimeValue t, int subNum)
 Commit any "Set Key" buffers on the given sub-anim.
 
virtual void CommitSetKeyBuffer (TimeValue t)
 Commit any "Set Key" buffers.
 
virtual CoreExport void SubAnimRevertSetKeyBuffer (int subNum)
 Revert any "Set Key" buffers on the given sub-anim.
 
virtual void RevertSetKeyBuffer ()
 Revert any "Set Key" buffers.
 
virtual LRESULT CALLBACK TrackViewWinProc (HWND hwnd, UINT message, WPARAM wParam, LPARAM lParam)
 This function is obsolete.
 
virtual BOOL IsRefMaker ()
 Tells whether it is a ReferenceMaker.
 
virtual bool IsParamBlockDesc2Used (ParamBlockDesc2 *desc)
 Returns true if the passed description is being used.
 
virtual bool GetMacroRecorderName (bool used_as_rhs_value, MSTR &objectSpecifiedName)
 This method is called to access the object specified name to use for the Maxscript macrorecorder.
 
CoreExport Animatable ()
 Constructor.
 
MSTR ClassName (bool localized=true) const
 Returns the name of the plugin class.
 
virtual void BeginEditParams (IObjParam *ip, ULONG flags, Animatable *prev=NULL)
 
virtual void EndEditParams (IObjParam *ip, ULONG flags, Animatable *next=NULL)
 
virtual CoreExport int SetProperty (ULONG id, void *data)
 
virtual CoreExport voidGetProperty (ULONG id)
 
CoreExport void AppendProperty (AnimProperty *prop)
 A function to directly add arbitrary properties to this object developers should ensure that the properties ID does not conflict with any Max-specific IDs.
 
CoreExport AnimPropertyFindProperty (DWORD id)
 Find any property.
 
CoreExport void AddAppDataChunk (const Class_ID &cid, SClass_ID sid, DWORD sbid, DWORD len, void *data)
 Adds application/plugin specific (custom) data to an Animatable.
 
CoreExport AppDataChunkGetAppDataChunk (const Class_ID &cid, SClass_ID sid, DWORD sbid)
 Retrieves the application/plugin specific (custom) data stored with an Animatable.
 
CoreExport BOOL RemoveAppDataChunk (const Class_ID &cid, SClass_ID sid, DWORD sbid)
 Deletes the application/plugin specific (custom) data stored with an Animatable.
 
CoreExport void ClearAllAppData ()
 Deletes all application/plugin specific (custom) data stored with an Animatable.
 
virtual int NumSubs ()
 
virtual AnimatableSubAnim (int i)
 
 __declspec (deprecated) virtual MSTR SubAnimName(int i) MAX_SEALED
 
virtual CoreExport MSTR SubAnimName (int i, bool localized)
 
virtual BOOL CanDeleteSubAnim (int i)
 
virtual void DeleteSubAnim (int i)
 
virtual DWORD GetSubAnimCurveColor (int subNum)
 
virtual int SubNumToRefNum (int subNum)
 
virtual BOOL CanCopyAnim ()
 
CoreExport int HasSubElements (int type=0)
 
virtual int GetSubFCurveExtents (int subNum, ParamDimensionBase *dim, float &min, float &max, DWORD flags)
 The values max and min should be initialized before calling this function.
 
virtual ParamDimensionGetParamDimension (int i)
 
virtual BOOL SelectSubAnim (int subNum)
 
virtual BOOL BypassTreeView ()
 
virtual BOOL BypassTrackBar ()
 
virtual BOOL BypassPropertyLevel ()
 
virtual BOOL InvisibleProperty ()
 
virtual int NumKeys ()
 
virtual TimeValue GetKeyTime (int index)
 
virtual int GetKeyIndex (TimeValue t)
 
virtual BOOL GetNextKeyTime (TimeValue t, DWORD flags, TimeValue &nt)
 
virtual void CopyKeysFromTime (TimeValue src, TimeValue dst, DWORD flags)
 
virtual void DeleteKeyAtTime (TimeValue t)
 
virtual BOOL IsKeyAtTime (TimeValue t, DWORD flags)
 
virtual int GetKeyTimes (Tab< TimeValue > &times, Interval range, DWORD flags)
 
virtual int GetKeySelState (BitArray &sel, Interval range, DWORD flags)
 
CoreExport void OpenTreeEntry (int type, DWORD tv)
 
CoreExport void CloseTreeEntry (int type, DWORD tv)
 
CoreExport int IsTreeEntryOpen (int type, DWORD tv)
 
CoreExport BOOL GetSelInTrackView (DWORD tv)
 
CoreExport void SetSelInTrackView (DWORD tv, BOOL sel)
 
CoreExport BOOL InTrackViewSelSet (int which)
 
CoreExport void SetTrackViewSelSet (int which, BOOL inOut)
 
virtual BOOL AssignController (Animatable *control, int subAnim)
 
virtual BOOL CanAssignController (int subAnim)
 Return true if we can reassign the subanim specified.
 
virtual BOOL CanMakeUnique ()
 
CoreExport int EnumAnimTree (AnimEnum *animEnum, Animatable *client, int subNum)
 
virtual int RenderBegin (TimeValue t, ULONG flags=0)
 
virtual int RenderEnd (TimeValue t)
 
virtual CoreExport Interval GetTimeRange (DWORD flags)
 
virtual void EditTimeRange (Interval range, DWORD flags)
 
virtual void DeleteTime (Interval iv, DWORD flags)
 
virtual void ReverseTime (Interval iv, DWORD flags)
 
virtual void ScaleTime (Interval iv, float s)
 
virtual void InsertTime (TimeValue ins, TimeValue amount)
 
virtual BOOL SupportTimeOperations ()
 
virtual CoreExport void MapKeys (TimeMap *map, DWORD flags)
 
virtual void DeleteKeys (DWORD flags)
 
virtual void DeleteKeyByIndex (int index)
 
virtual void SelectKeys (TrackHitTab &sel, DWORD flags)
 
virtual void SelectSubKeys (int subNum, TrackHitTab &sel, DWORD flags)
 
virtual void SelectSubCurve (int subNum, BOOL sel)
 
virtual void SelectKeyByIndex (int i, BOOL sel)
 
virtual BOOL IsKeySelected (int i)
 
virtual void FlagKey (TrackHitRecord hit)
 
virtual int GetFlagKeyIndex ()
 
virtual int NumSelKeys ()
 
virtual void CloneSelectedKeys (BOOL offset=FALSE)
 
virtual void AddNewKey (TimeValue t, DWORD flags)
 
virtual void MoveKeys (ParamDimensionBase *dim, float delta, DWORD flags)
 
virtual void ScaleKeyValues (ParamDimensionBase *dim, float origin, float scale, DWORD flags)
 
virtual void SelectCurve (BOOL sel)
 
virtual BOOL IsCurveSelected ()
 Returns TRUE if the function curve is selected; otherwise returns FALSE.
 
virtual BOOL IsSubCurveSelected (int subNum)
 Returns the selected state of the sub-curve whose index is passed.
 
virtual int GetSelKeyCoords (TimeValue &t, float &val, DWORD flags)
 
virtual void SetSelKeyCoords (TimeValue t, float val, DWORD flags)
 
virtual int SetSelKeyCoordsExpr (ParamDimension *dim, const MCHAR *timeExpr, const MCHAR *valExpr, DWORD flags)
 
virtual void AdjustTangents (TrackHitRecord hit, ParamDimensionBase *dim, Rect &rcGraph, float tzoom, int tscroll, float vzoom, int vscroll, int dx, int dy, DWORD flags)
 
virtual void AdjustTangents (TrackHitRecord hit, ParamDimensionBase *dim, float angle, float length, DWORD flags)
 
virtual CoreExport BOOL IsAnimated ()
 
virtual BOOL CanCopyTrack (Interval iv, DWORD flags)
 
virtual BOOL CanPasteTrack (TrackClipObject *cobj, Interval iv, DWORD flags)
 
virtual TrackClipObjectCopyTrack (Interval iv, DWORD flags)
 
virtual void PasteTrack (TrackClipObject *cobj, Interval iv, DWORD flags)
 
virtual BOOL CanCopySubTrack (int subNum, Interval iv, DWORD flags)
 
virtual BOOL CanPasteSubTrack (int subNum, TrackClipObject *cobj, Interval iv, DWORD flags)
 
virtual TrackClipObjectCopySubTrack (int subNum, Interval iv, DWORD flags)
 
virtual void PasteSubTrack (int subNum, TrackClipObject *cobj, Interval iv, DWORD flags)
 
virtual int GetTrackVSpace (int lineHeight)
 
virtual int HitTestTrack (TrackHitTab &hits, Rect &rcHit, Rect &rcTrack, float zoom, int scroll, DWORD flags)
 
virtual int PaintTrack (ParamDimensionBase *dim, HDC hdc, Rect &rcTrack, Rect &rcPaint, float zoom, int scroll, DWORD flags)
 
virtual int PaintSubTrack (int subNum, ParamDimensionBase *dim, HDC hdc, Rect &rcTrack, Rect &rcPaint, float zoom, int scroll, DWORD flags)
 
virtual int PaintFCurves (ParamDimensionBase *dim, HDC hdc, Rect &rcGraph, Rect &rcPaint, float tzoom, int tscroll, float vzoom, int vscroll, DWORD flags)
 
virtual int HitTestFCurves (ParamDimensionBase *dim, TrackHitTab &hits, Rect &rcHit, Rect &rcGraph, float tzoom, int tscroll, float vzoom, int vscroll, DWORD flags)
 
virtual int PaintSubFCurves (int subNum, ParamDimensionBase *dim, HDC hdc, Rect &rcGraph, Rect &rcPaint, float tzoom, int tscroll, float vzoom, int vscroll, DWORD flags)
 
virtual int HitTestSubFCurves (int subNum, ParamDimensionBase *dim, TrackHitTab &hits, Rect &rcHit, Rect &rcGraph, float tzoom, int tscroll, float vzoom, int vscroll, DWORD flags)
 
virtual void EditTrackParams (TimeValue t, ParamDimensionBase *dim, const MCHAR *pname, HWND hParent, IObjParam *ip, DWORD flags)
 
virtual int TrackParamsType ()
 
virtual int GetFCurveExtents (ParamDimensionBase *dim, float &min, float &max, DWORD flags)
 This method is called to calculate the largest and smallest values of the anim.
 
CoreExport void AddNoteTrack (NoteTrack *note)
 
CoreExport void DeleteNoteTrack (NoteTrack *note, BOOL delNote=TRUE)
 
CoreExport BOOL HasNoteTracks ()
 
CoreExport int NumNoteTracks ()
 
CoreExport NoteTrackGetNoteTrack (int i)
 
virtual void FreeAllBitmaps ()
 
virtual void GetSystemNodes (INodeTab &nodes, SysNodeContext Context)
 
virtual BOOL IsSubClassOf (Class_ID classID)
 returns true if the animatable has sub-classed off the given class
 
virtual CoreExport void MouseCycleCompleted (TimeValue t)
 
virtual CoreExport void MouseCycleStarted (TimeValue t)
 
virtual int NumParamBlocks ()
 
virtual IParamBlock2GetParamBlockByID (short id)
 
CoreExport bool SvSaveData (ISave *isave, USHORT id)
 
CoreExport bool SvLoadData (ILoad *iLoad)
 
CoreExport DWORD SvGetRefIndex ()
 
CoreExport void SvSetRefIndex (DWORD i)
 
CoreExport bool SvDeleteRefIndex ()
 
CoreExport SvGraphNodeReference SvStdTraverseAnimGraph (IGraphObjectManager *gom, Animatable *owner, int id, DWORD flags)
 
virtual CoreExport bool SvCanInitiateLink (IGraphObjectManager *gom, IGraphNode *gNode)
 
virtual CoreExport bool SvCanConcludeLink (IGraphObjectManager *gom, IGraphNode *gNode, IGraphNode *gNodeChild)
 
virtual CoreExport bool SvCanSetName (IGraphObjectManager *gom, IGraphNode *gNode)
 
virtual CoreExport bool SvSetName (IGraphObjectManager *gom, IGraphNode *gNode, const MSTR &name)
 
virtual CoreExport bool SvCanRemoveThis (IGraphObjectManager *gom, IGraphNode *gNode)
 
virtual CoreExport bool SvRemoveThis (IGraphObjectManager *gom, IGraphNode *gNode)
 Called when the user deletes this object in the schematic view...
 
virtual CoreExport bool SvIsHighlighted (IGraphObjectManager *gom, IGraphNode *gNode)
 
virtual CoreExport COLORREF SvGetSwatchColor (IGraphObjectManager *gom, IGraphNode *gNode)
 
virtual CoreExport bool SvIsInactive (IGraphObjectManager *gom, IGraphNode *gNode)
 
virtual CoreExport bool SvLinkChild (IGraphObjectManager *gom, IGraphNode *gNodeThis, IGraphNode *gNodeChild)
 
virtual CoreExport bool SvEditProperties (IGraphObjectManager *gom, IGraphNode *gNode)
 
virtual CoreExport MSTR SvGetTip (IGraphObjectManager *gom, IGraphNode *gNode)
 
virtual CoreExport MSTR SvGetRefTip (IGraphObjectManager *gom, IGraphNode *gNode, IGraphNode *gNodeMaker)
 
virtual CoreExport bool SvCanDetach (IGraphObjectManager *gom, IGraphNode *gNode)
 
virtual CoreExport bool SvDetach (IGraphObjectManager *gom, IGraphNode *gNode)
 
virtual CoreExport MSTR SvGetRelTip (IGraphObjectManager *gom, IGraphNode *gNodeTarget, int id, IGraphNode *gNodeMaker)
 Returns a string to be displayed in the tip window in the schematic view for a relationship from "gNodeMaker" to "gNodeTarget"...
 
virtual CoreExport bool SvCanDetachRel (IGraphObjectManager *gom, IGraphNode *gNodeTarget, int id, IGraphNode *gNodeMaker)
 Returns true if this object can respond to the SvDetachRel(...) method...
 
virtual CoreExport bool SvDetachRel (IGraphObjectManager *gom, IGraphNode *gNodeTarget, int id, IGraphNode *gNodeMaker)
 Detach this relationship.
 
virtual CoreExport bool SvHandleRelDoubleClick (IGraphObjectManager *gom, IGraphNode *gNodeTarget, int id, IGraphNode *gNodeMaker)
 Called when this relationship is double-clicked in the schematic view...
 
CoreExport ICustAttribContainerGetCustAttribContainer ()
 This method returns a pointer to the custom attributes container interface class.
 
CoreExport void AllocCustAttribContainer ()
 This method allocates space for a custom attributes container.
 
CoreExport void DeleteCustAttribContainer ()
 This method deletes space used by a custom attributes container.
 
void SetAFlag (DWORD mask)
 
void ClearAFlag (DWORD mask)
 Clears one or more bits in the Animatable flags.
 
bool TestAFlag (DWORD mask) const
 Tests one or more bits in the Animatable flags.
 
void SetAFlagEx (DWORD mask)
 Sets one or more bits in the Animatable extended flags.
 
void ClearAFlagEx (DWORD mask)
 Clears one or more bits in the Animatable extended flags.
 
bool TestAFlagEx (DWORD mask) const
 Tests one or more bits in the Animatable extended flags.
 
CoreExport bool TestFlagBit (int index)
 Tests the specified flag bit.
 
CoreExport void SetFlagBit (int index, bool newValue=true)
 Sets the specified flag bit.
 
CoreExport void ClearFlagBit (int index)
 Clears the specified flag bit.
 
- Public Member Functions inherited from InterfaceServer
virtual UtilExport ~InterfaceServer ()
 Destructor.
 
virtual UtilExport BaseInterfaceGetInterface (Interface_ID id)
 
template<class InterfaceType >
InterfaceType * GetTypedInterface ()
 

Public Attributes

Mesh mesh
 
TessApprox mDispApprox
 
bool mSubDivideDisplacement
 
bool mDisableDisplacement
 
bool mSplitMesh
 

Protected Member Functions

CoreExport void CopyValidity (TriObject *fromOb, ChannelMask channels)
 
 __declspec (deprecated) static int refCount
 
 __declspec (deprecated) static HANDLE defThread
 
 __declspec (deprecated) static HANDLE defMutex
 
 __declspec (deprecated) static HANDLE defStartEvent
 
 __declspec (deprecated) static HANDLE defEndEvent
 
CoreExport RefResult NotifyRefChanged (const Interval &changeInt, RefTargetHandle hTarget, PartID &partID, RefMessage message, BOOL propagate)
 Receives and responds to messages.
 
void BuildGenerateRenderItemContext (const MaxSDK::Graphics::UpdateDisplayContext &displayContext, MaxSDK::Graphics::GenerateMeshRenderItemsContext &context, bool bNodeSelected)
 
- Protected Member Functions inherited from ReferenceTarget
CoreExport int DoEnumDependentsImpl (DependentEnumProc *dep) override
 Method to perform an enumeration on a ReferenceTarget.
 
virtual CoreExport ~ReferenceTarget ()=0
 Destructor.
 
- Protected Member Functions inherited from ReferenceMaker
virtual CoreExport ~ReferenceMaker ()=0
 Destructor.
 
virtual CoreExport void SetReference (int i, RefTargetHandle rtarg)
 Stores a ReferenceTarget as its 'i-th' reference`.
 
void BlockEval ()
 Validates a given reference link between this reference maker and its reference target.
 
void UnblockEval ()
 Validates a given reference link between this reference maker and its reference target.
 
int Evaluating ()
 Validates a given reference link between this reference maker and its reference target.
 
CoreExport RefResult StdNotifyRefChanged (const Interval &changeInt, RefTargetHandle hTarget, PartID partID, RefMessage message, BOOL propagate, NotifyDependentsOption notifyDependentsOption)
 Validates a given reference link between this reference maker and its reference target.
 
- Protected Member Functions inherited from Animatable
virtual CoreExport ~Animatable ()=0
 Destructor.
 
- Protected Member Functions inherited from Noncopyable
 Noncopyable ()
 
 ~Noncopyable ()
 

Protected Attributes

Interval geomValid
 
Interval topoValid
 
Interval texmapValid
 
Interval selectValid
 
Interval vcolorValid
 
Interval gfxdataValid
 
ChannelMask validBits
 
- Protected Attributes inherited from BaseObject
MaxSDK::Graphics::RenderItemHandleArray mRenderItemHandles
 
- Protected Attributes inherited from Animatable
DWORD aflag
 
AnimPropertyList aprops
 

Additional Inherited Members

- Static Public Member Functions inherited from Animatable
static CoreExport BOOL IsDeleted (Animatable *anim)
 Debug method to determine whether an object has been deleted.
 
static CoreExport AnimHandle GetHandleByAnim (Animatable *anim)
 Get the unique handle for an Animatable object.
 
static CoreExport AnimatableGetAnimByHandle (AnimHandle handle)
 Get an Animatable object from its unique handle.
 
static CoreExport AnimHandle GetNextHandle ()
 Get the unique handle for the next Animatable object to be created.
 
static CoreExport void EnumerateAllAnimatables (EnumAnimList &enumProcObject)
 Enumerator to enumerate across all animatables.
 
static CoreExport bool RegisterAppDataLoadCallback (const Class_ID &cid, SClass_ID sid, APPDATALOADPROC proc)
 Registers a callback proc that is called when an AppDataChunk is read from a scene file.
 
static CoreExport bool UnRegisterAppDataLoadCallback (const Class_ID &cid, SClass_ID sid, APPDATALOADPROC proc)
 Unregisters a callback proc that is called when an AppDataChunk is read from a scene file.
 
static CoreExport bool RegisterAppDataLoadCallback (DWORD sbid, APPDATALOADPROC proc)
 Registers a callback proc that is called when an AppDataChunk is read from a scene file.
 
static CoreExport bool UnRegisterAppDataLoadCallback (DWORD sbid, APPDATALOADPROC proc)
 Unregisters a callback proc that is called when an AppDataChunk is read from a scene file.
 
static CoreExport void ClearAFlagInAllAnimatables (DWORD mask)
 Clears one or more bits in the Animatable flags in all Animatables.
 
static CoreExport void ClearAFlagExInAllAnimatables (DWORD mask)
 Clears one or more bits in the Animatable extended flags in all Animatables.
 
static CoreExport int RequestFlagBit ()
 Requests an unique flag bit index.
 
static CoreExport void ReleaseFlagBit (int index)
 Releases the flag bit index.
 
static CoreExport void ClearFlagBitInAllAnimatables (int index)
 Clears the specified flag bit in all Animatables.
 
- Static Public Member Functions inherited from MaxHeapOperators
static UtilExport voidoperator new (size_t size)
 Standard new operator used to allocate objects If there is insufficient memory, an exception will be thrown.
 
static UtilExport voidoperator new (size_t size, const std::nothrow_t &e)
 Standard new operator used to allocate objects if there is insufficient memory, NULL will be returned.
 
static UtilExport voidoperator new (size_t size, const char *filename, int line)
 New operator used to allocate objects that takes the filename and line number where the new was called If there is insufficient memory, an exception will be thrown.
 
static UtilExport voidoperator new (size_t size, int block_type, const char *filename, int line)
 New operator used to allocate objects that takes the type of memory, filename and line number where the new was called If there is insufficient memory, an exception will be thrown.
 
static UtilExport voidoperator new (size_t size, const std::nothrow_t &e, const char *filename, int line)
 New operator used to allocate objects that takes the filename and line number where the new was called If there is insufficient memory, NULL will be returned.
 
static UtilExport voidoperator new (size_t size, unsigned long flags)
 New operator used to allocate objects that takes extra flags to specify special operations If there is insufficient memory, an exception will be thrown.
 
static UtilExport voidoperator new (size_t size, const std::nothrow_t &e, unsigned long flags)
 New operator used to allocate objects that takes extra flags to specify special operations If there is insufficient memory, NULL will be returned.
 
static UtilExport voidoperator new[] (size_t size)
 New operator used to allocate arrays of objects If there is insufficient memory, an exception will be thrown.
 
static UtilExport voidoperator new[] (size_t size, const std::nothrow_t &e)
 New operator used to allocate arrays of objects If there is insufficient memory, NULL will be returned.
 
static UtilExport voidoperator new[] (size_t size, const char *filename, int line)
 New operator used to allocate arrays of objects If there is insufficient memory, an exception will be thrown.
 
static UtilExport voidoperator new[] (size_t size, int block_type, const char *filename, int line)
 New operator used to allocate arrays of objects.
 
static UtilExport voidoperator new[] (size_t size, const std::nothrow_t &e, const char *filename, int line)
 New operator used to allocate arrays of objects If there is insufficient memory, NULL will be returned.
 
static UtilExport voidoperator new[] (size_t size, unsigned long flags)
 New operator used to allocate arrays of objects If there is insufficient memory, an exception will be thrown.
 
static UtilExport voidoperator new[] (size_t size, const std::nothrow_t &e, unsigned long flags)
 New operator used to allocate arrays of objects If there is insufficient memory, NULL will be returned.
 
static UtilExport void operator delete (void *ptr)
 Standard delete operator used to deallocate an object If the pointer is invalid, an exception will be thrown.
 
static UtilExport void operator delete (void *ptr, const std::nothrow_t &e)
 Standard delete operator used to deallocate an object If the pointer is invalid, nothing will happen.
 
static UtilExport void operator delete (void *ptr, const char *filename, int line)
 Delete operator used to deallocate an object that takes the filename and line number where the delete was called If the pointer is invalid, an exception will be thrown.
 
static UtilExport void operator delete (void *ptr, int block_type, const char *filename, int line)
 Delete operator used to deallocate an object that takes the type of memory, filename and line number where the delete was called If the pointer is invalid, an exception will be thrown.
 
static UtilExport void operator delete (void *ptr, const std::nothrow_t &e, const char *filename, int line)
 Delete operator used to deallocate an object that takes the filename and line number where the delete was called If the pointer is invalid, nothing will happen.
 
static UtilExport void operator delete (void *ptr, unsigned long flags)
 Delete operator used to deallocate an object that takes extra flags to specify special operations If the pointer is invalid, an exception will be thrown.
 
static UtilExport void operator delete (void *ptr, const std::nothrow_t &e, unsigned long flags)
 Delete operator used to deallocate an object that takes extra flags to specify special operations If the pointer is invalid, nothing will happen.
 
static UtilExport void operator delete[] (void *ptr)
 Standard delete operator used to deallocate an array of objects If the pointer is invalid, an exception will be thrown.
 
static UtilExport void operator delete[] (void *ptr, const std::nothrow_t &e)
 Standard delete operator used to deallocate an array of objects If the pointer is invalid, nothing will happen.
 
static UtilExport void operator delete[] (void *ptr, const char *filename, int line)
 Delete operator used to deallocate an array of objects that takes the filename and line number where the delete was called If the pointer is invalid, an exception will be thrown.
 
static UtilExport void operator delete[] (void *ptr, int block_type, const char *filename, int line)
 Delete operator used to deallocate an array of objects that takes the type of memory, filename and line number where the delete was called If the pointer is invalid, an exception will be thrown.
 
static UtilExport void operator delete[] (void *ptr, const std::nothrow_t &e, const char *filename, int line)
 Delete operator used to deallocate an array of objects that takes the filename and line number where the delete was called If the pointer is invalid, nothing will happen.
 
static UtilExport void operator delete[] (void *ptr, unsigned long flags)
 Delete operator used to deallocate an array of objects that takes extra flags to specify special operations If the pointer is invalid, an exception will be thrown.
 
static UtilExport void operator delete[] (void *ptr, const std::nothrow_t &e, unsigned long flags)
 Delete operator used to deallocate an array of objects that takes extra flags to specify special operations If the pointer is invalid, an exception will be thrown.
 
static UtilExport voidoperator new (size_t size, void *placement_ptr)
 Placement new operator.
 
static UtilExport void operator delete (void *ptr, void *placement_ptr)
 Placement delete operator.
 
static UtilExport voidaligned_malloc (size_t size, size_t alignment)
 Allocates memory on a specified alignment boundary.
 
static UtilExport voidaligned_realloc (void *ptr, size_t size, size_t alignment)
 Reallocates memory on a specified alignment boundary.
 
static UtilExport void aligned_free (void *ptr)
 Frees a block of memory that was allocated with aligned_malloc/aligned_realloc.
 
- Static Public Attributes inherited from Animatable
static const AnimHandle kInvalidAnimHandle = 0
 

Detailed Description

See also
Class GeomObject, Class ClassDesc, Class Mesh, Class TessApprox.

Description:
This class represents a renderable, deformable, triangle mesh object. All procedural objects must be able to convert themselves to TriObjects. This class provides implementations of all the required methods of Animatable, ReferenceMaker, ReferenceTarget, BaseObject, Object, and GeomObject. All methods of this class are implemented by the system.
Data Members:
Mesh mesh;

This is the mesh of the TriObject. See Class Mesh for methods to manipulate this mesh.

The following data members are used by the Displacement Mapping mechanism in 3ds Max.

TessApprox mDispApprox;

The object which describes the properties of the tesselation approximation of the mesh.

bool mSubDivideDisplacement;

The subdivision displacement flag. When TRUE, displacement mapping mechanism subdivides mesh faces to accurately displace the map, using the method and settings you specify in the Subdivision Presets and Subdivision Method group boxes. When FALSE, the modifier applies the map by moving vertices in the mesh, the way the Displace modifier does.

bool mDisableDisplacement;

TRUE to disable displacement mapping; FALSE to enable it.

bool mSplitMesh;

The split mesh flag. This flag affects texture mapping as done by the displacement mapping mechanism. When on, the modifier splits the mesh into individual faces before displacing them: this helps preserve texture mapping. When off, the modifier uses an internal method to assign texture mapping. Default=On.

Constructor & Destructor Documentation

◆ TriObject()

◆ ~TriObject()

Member Function Documentation

◆ CopyValidity()

CoreExport void CopyValidity ( TriObject fromOb,
ChannelMask  channels 
)
protected

◆ __declspec() [1/5]

__declspec ( deprecated  )
protected

◆ __declspec() [2/5]

__declspec ( deprecated  )
protected

◆ __declspec() [3/5]

__declspec ( deprecated  )
protected

◆ __declspec() [4/5]

__declspec ( deprecated  )
protected

◆ __declspec() [5/5]

__declspec ( deprecated  )
protected

◆ NotifyRefChanged()

CoreExport RefResult NotifyRefChanged ( const Interval changeInt,
RefTargetHandle  hTarget,
PartID partID,
RefMessage  message,
BOOL  propagate 
)
protectedvirtual

Receives and responds to messages.

A plugin which makes references must implement a method to receive and respond to messages broadcast by its dependents. This is done by implementing NotifyRefChanged(). The plugin developer usually implements this method as a switch statement where each case is one of the messages the plugin needs to respond to. The Method StdNotifyRefChanged calls this, which can change the partID to new value. If it doesn't depend on the particular message& partID, it should return REF_DONTCARE.

  • For developer that need to update a dialog box with data about an object you reference note the following related to this method: This method may be called many times. For instance, say you have a dialog box that displays data about an object you reference. This method will get called many time during the drag operations on that object. If you updated the display every time you'd wind up with a lot of 'flicker' in the dialog box. Rather than updating the dialog box each time, you should just invalidate the window in response to the NotifyRefChanged() call. Then, as the user drags the mouse your window will still receive paint messages. If the scene is complex the user may have to pause (but not let up on the mouse) to allow the paint message to go through since they have a low priority. This is the way many windows in 3ds Max work.
Parameters
changeInt- This is the interval of time over which the message is active. Currently, all plug-ins will receive FOREVER for this interval, with the exception of REFMSG_FLAGDEPENDENTS notifications. In that case, changeInt.Start() is the timepoint to perform the dependency test.
hTarget- This is the handle of the reference target the message was sent by. The reference maker uses this handle to know specifically which reference target sent the message.
partID- This contains information specific to the message passed in. Some messages don't use the partID at all. See the section List of Reference Messages for more information about the meaning of the partID for some common messages.
message- The message parameters passed into this method is the specific message which needs to be handled.
propagate- If called through ReferenceMaker::NotifyDependents(), the value of 'propagate' passed to it. Used if calling NotifyDependents() from within NotifyRefChanged().
Returns
The return value from this method is of type RefResult. This is usually REF_SUCCEED indicating the message was processed. Sometimes, the return value may be REF_STOP. This return value is used to stop the message from being propagated to the dependents of the item.

Implements ReferenceMaker.

◆ BuildGenerateRenderItemContext()

void BuildGenerateRenderItemContext ( const MaxSDK::Graphics::UpdateDisplayContext displayContext,
MaxSDK::Graphics::GenerateMeshRenderItemsContext context,
bool  bNodeSelected 
)
protected

◆ PrepareDisplay()

virtual CoreExport bool PrepareDisplay ( const MaxSDK::Graphics::UpdateDisplayContext prepareDisplayContext)
virtual

Reimplemented from BaseObject.

◆ UpdatePerNodeItems()

virtual CoreExport bool UpdatePerNodeItems ( const MaxSDK::Graphics::UpdateDisplayContext updateDisplayContext,
MaxSDK::Graphics::UpdateNodeContext nodeContext,
MaxSDK::Graphics::IRenderItemContainer targetRenderItemContainer 
)
virtual

Reimplemented from BaseObject.

◆ GetObjectDisplayRequirement()

CoreExport unsigned long GetObjectDisplayRequirement ( ) const
virtual

Reimplemented from BaseObject.

◆ GetInterface() [1/2]

virtual CoreExport BaseInterface * GetInterface ( Interface_ID  id)
virtual
Remarks
Returns a pointer to the Base Interface for the interface ID passed. The default implementation of this method retrieves this information from the ClassDesc for the plug-in.

Any future object-based interfaces should be allocated unique Interface_IDs (you can use Gencid.exe for this) and made available through this call.

The default implementation of GetInterface(Interface_ID) looks up a standalone interface of the given ID on the object's ClassDesc. This gives access to standalone interfaces via any of a plug-in's objects, without having to dig around for the ClassDesc, so you should fall back to calling the default implementation if you don't recognize an ID in your implementation of GetInterface(Interface_ID).
Parameters
idThe unique ID of the interface to get. See Class Interface_ID.

Reimplemented from Object.

◆ GetInterface() [2/2]

CoreExport void * GetInterface ( ULONG  id)
virtual
Remarks
This method provides a mechanism for extending the class in the future. In 3ds Max 4.0 there are new interfaces that are accessed by passing an id to this method and it will respond by returning the corresponding interface pointer.

This method has been used however for a different purpose. It currently is used to determine if an object is of a particular class. With controllers for example, there is one base class Control, however there are many super classes (CTRL_FLOAT_CLASS_ID, CTRL_SCALE_CLASS_ID, etc.). If you wanted to find out if a given Animatable was a controller you would need to compare its SuperClassID to all the known types and only if it wasn't one of the known types could you be sure it wasn't a controller. Having to do this is inconvenient for a developer.

Instead the Control class implements this method. It looks at the id, and if it matches a predefined constant I_CONTROL, it returns its this pointer. In this way, given any Animatable, it is easy to find out if it is a controller by simply asking for the control interface. There is a macro that does this:

#define GetControlInterface(anim)
Definition: control.h:1055
virtual CoreExport BaseInterface * GetInterface(Interface_ID iid)
#define I_CONTROL
An Animatable supporting this interface is a Control.
Definition: AnimatableInterfaceIDs.h:33
A plug-in developer may use this macro as follows:

Control *c = GetControlInterface(anim);

This will either be NULL or a pointer to a valid controller.

Note: Plug-in defined interfaces should be greater than the following value:

#define I_USERINTERFACE 0x0000ffff

If a plug-in implements this method for its own purposes, it would, in general, switch on the id and if it is not aware of the id it would call this method on the base class. Otherwise it could respond to the id as it needed. See the sample code below for the how the Control class implements this method.
Parameters
idThe id of the interface.
Default Implementation:
{ return NULL; }
Sample Code:
The following is the Control class implementation of this method. It looks at the id passed, and if it matches I_CONTROL it returns its this pointer. Otherwise it calls the base class method.

void* Control::GetInterface(ULONG id)
{
if (id==I_CONTROL) {
return this;
}
else {
}
}
virtual CoreExport void * GetInterface(ULONG id)
CoreExport void * GetInterface(ULONG id)

Reimplemented from Object.

◆ ReleaseInterface()

CoreExport void ReleaseInterface ( ULONG  id,
void i 
)
virtual
Remarks
This method is not currently used. It is reserved for future use. Its purpose is for releasing an interface created with GetInterface().

Reimplemented from Animatable.

◆ HitTest()

CoreExport int HitTest ( TimeValue  t,
INode inode,
int  type,
int  crossing,
int  flags,
IPoint2 p,
ViewExp vpt 
)
virtual

This method is called to determine if the specified screen point intersects the item.

The method returns nonzero if the item was hit; otherwise 0.

Parameters
tThe time to perform the hit test.
inodeA pointer to the node to test.
typeThe type of hit testing to perform. See Scene and Node Hit Test Types. for details.
crossingThe state of the crossing setting. If TRUE crossing selection is on.
flagsThe hit test flags. See Scene and Node Hit Testing Flags for details.
pThe screen point to test.
vptAn interface pointer that may be used to call methods associated with the viewports.
Returns
Nonzero if the item was hit; otherwise 0.

Reimplemented from BaseObject.

◆ Display()

CoreExport int Display ( TimeValue  t,
INode inode,
ViewExp vpt,
int  flags 
)
virtual

This is called by the system to have the item display itself (perform a quick render in viewport, using the current TM).

Note: For this method to be called the object's validity interval must be invalid at the specified time t. If the interval is valid, the system may not call this method since it thinks the display is already valid.

Parameters
tThe time to display the object.
inodeThe node to display.
vptAn interface pointer that may be used to call methods associated with the viewports.
flagsSee Display Flags.
Returns
Default return value is -1, means this object doesn't have display function. 0 means it didn't draw anything in current frame. Otherwise return positive values..

Reimplemented from BaseObject.

◆ Snap()

CoreExport void Snap ( TimeValue  t,
INode inode,
SnapInfo snap,
IPoint2 p,
ViewExp vpt 
)
virtual

Checks the point passed for a snap and updates the SnapInfo structure.

Note
Developers wanting to find snap points on an Editable Mesh object should see the method XmeshSnap::Snap() in /MAXSDK/SAMPLES/SNAPS/XMESH/XMESH.CPP.
Parameters
tThe time to check.
inodeThe node to check.
snapThe snap info structure to update.
pThe screen point to check.
vptAn interface pointer that may be used to call methods associated with the viewports.

Reimplemented from BaseObject.

◆ GetCreateMouseCallBack()

CoreExport CreateMouseCallBack * GetCreateMouseCallBack ( )
virtual

This method allows the system to retrieve a callback object used in creating an object in the 3D viewports.

This method returns a pointer to an instance of a class derived from CreateMouseCallBack. This class has a method proc() which is where the programmer defines the user/mouse interaction during the object creation phase.

Returns
A pointer to an instance of a class derived from CreateMouseCallBack.

Implements BaseObject.

◆ Clone()

CoreExport RefTargetHandle Clone ( RemapDir remap)
virtual

This method is used by 3ds Max to clone an object.

See also
CloneRefHierarchy(), class RemapDir This method is called by 3ds Max to have the plugin clone itself. The plug-in's implementation of this method should copy both the data structure and all the data residing in the data structure of this reference target. The plugin should clone all its references as well. Also, the plug-in's implementation of this method must call BaseClone(). In order for classes derived from this class to clone cleanly, the Clone method should just create the new instance, and then call an implementation of BaseClone that clones the references and copies any other necessary data. For example:
class MyDerivedPlugin
: public MyBasePlugin
{
const int MY_REFERENCE = 1;
ReferenceTarget* Clone(RemapDir& remap)
{
ReferenceTarget* result = new MyDerivedPlugin();
BaseClone(this, result, remap);
return result;
}
void BaseClone(ReferenceTarget* from, ReferenceTarget* to, RemapDir& remap)
{
if (!to || !from || from == to)
return;
MyBasePlugin::BaseClone(from, to, remap);
to->ReplaceReference(MY_REFERENCE, remap->CloneRef(from->GetReference(MY_REFERENCE)));
}
};
virtual CoreExport RefTargetHandle GetReference(int i)
Returns the 'i-th' reference.
CoreExport RefResult ReplaceReference(int which, RefTargetHandle newtarg, BOOL delOld=TRUE)
Used when cloning reference makers.
A scene entity that is being owned and listened to by other scene entities.
Definition: ref.h:1849
For remapping references during a Clone.
Definition: ref.h:830
virtual RefTargetHandle CloneRef(RefTargetHandle oldTarg)
Creates a clone of a reference target only if it hasn't been cloned already.

This method should not be directly called by plug-ins. Instead, either RemapDir::CloneRef() or CloneRefHierachy() should be used to perform cloning. These methods ensure that the mapping from the original object to the clone is added to the RemapDir used for cloning, which may be used during backpatch operations

Note
See the remarks in method BaseClone() below.
Parameters
remap- A RemapDir instance used for remapping references during a Clone.
Returns
A pointer to the cloned item.

Reimplemented from ReferenceTarget.

◆ Eval()

CoreExport ObjectState Eval ( TimeValue  t)
virtual

This method is called to evaluate the object and return the result as an ObjectState.

When the system has a pointer to an object it doesn't know if it's a procedural object or a derived object. So it calls Eval() on it and gets back an ObjectState. A derived object managed by the system may have to call Eval() on its input for example. A plug-in (like a procedural object) typically just returns itself. A plug-in that does not just return itself is the Morph Object (/MAXSDK/SAMPLES/OBJECTS/MORPHOBJ.CPP). This object uses a morph controller to compute a new object and fill in an ObjectState which it returns.

Parameters
tSpecifies the time to evaluate the object.
Returns
The result of evaluating the object as an ObjectState.
Sample Code:
Typically this method is implemented as follows:
{ return ObjectState(this); }
The ObjectState is the structure that flows up the geometry pipeline.
Definition: object.h:287

Implements Object.

◆ ObjectValidity()

CoreExport Interval ObjectValidity ( TimeValue  t)
virtual

This method returns the validity interval of the object as a whole at the specified time.

Parameters
tThe time to compute the validity interval.
Returns
The validity interval of the object, including that queried from the base class.

Reimplemented from Object.

◆ HasUVW() [1/2]

CoreExport BOOL HasUVW ( )
virtual

Call this method to find out if the object has UVW coordinates.

This method returns TRUE if the object has UVW coordinates; otherwise FALSE. In 3ds Max 2.0 and later there is code in the renderer that will automatically turn on the UVW coordinates of the base object if UV's are missing (and needed). The base object has to implement two simple methods to make this work: HasUVW() and SetGenUVW(). Developers are encouraged to put these methods in their objects: it makes using the program easier for the user. If they are not implemented, it doesn't cause any real harm: it will just operate as before and put up the missing UVW's message. Here is how the procedural sphere implements these methods:

BOOL SphereObject::GetGenUVW()
{
BOOL genUVs;
pblock->GetValue(PB_GENUVS, 0, genUVs, v);
return genUVs;
}
void SphereObject::SetGenUVW(BOOL sw)
{
if (sw==GetGenUVW()) return;
pblock->SetValue(PB_GENUVS,0, sw);
}
Definition: interval.h:36

Important Note: The pblock->SetValue() will cause a call to NotifyDependents(FOREVER, PART_TEXMAP, REFMSG_CHANGE), which will invalidate the UVW cache. It is essential that this call be made, so if the 'generate UVW' boolean is not handled by a parameter block, then NotifyDependents() needs to be called explicitly. Also Note: For "modifiable objects" that pass up the pipeline getting modified, such as TriObject, EditTriObject, etc., which cannot generate their own UVWs, but can carry them in their data structures, only this HasUVW() method needs to be implemented. For example, here is the implementation for TriObject: BOOL TriObject::HasUVW() { return mesh.tvFace?1:0; }

Reimplemented from Object.

◆ HasUVW() [2/2]

CoreExport BOOL HasUVW ( int  mapChannel)
virtual

Call this method to find out if the object is has UVW coordinates for the specified mapping channel.

This method returns TRUE if the object has UVW coordinates; otherwise FALSE. See the method HasUVW() above for more details.

Parameters
mapChannelSee Mapping Channels.

Reimplemented from Object.

◆ ChannelValidity()

CoreExport Interval ChannelValidity ( TimeValue  t,
int  nchan 
)
virtual

Retrieve the current validity interval for the nchan channel of the object.

Note
Most procedural objects won't implement this method since they don't have individual channels. Developers wanting to get the validity interval for a procedural object should use Object::ObjectValidity() instead.
Parameters
tThe time to retrieve the validity interval of the channel.
nchanSpecifies the channel to return the validity interval of. See
Object Channels.
Returns
The validity interval of the specified channel.

Reimplemented from Object.

◆ SetChannelValidity()

CoreExport void SetChannelValidity ( int  nchan,
Interval  v 
)
virtual

Sets the validity interval of the specified channel.

Parameters
nchanSpecifies the channel. See Object Channels.
vThe validity interval for the channel.

Reimplemented from Object.

◆ InvalidateChannels()

CoreExport void InvalidateChannels ( ChannelMask  channels)
virtual

This method invalidates the intervals for the given channel mask.

This just sets the validity intervals to empty (calling SetEmpty() on the interval).

Parameters
channelsSpecifies the channels to invalidate.

Reimplemented from Object.

◆ ConvertValidity()

CoreExport Interval ConvertValidity ( TimeValue  t)

◆ IsDeformable()

int IsDeformable ( )
inlinevirtual

Indicates whether this object is deformable.

A deformable object is simply an object with points that can be modified. Deformable objects must implement the generic deformable object methods (NumPoints(), GetPoint(i), SetPoint(i), Deform()). A deformable object is simply an object with points that can be modified. These points can be stored in any form the object wants. They are accessed through a virtual array interface with methods to get and set the 'i-th' point. If an object has tangents for instance, it would convert them to and from points as necessary. For example, a simple Bezier spline object that stored its control handles relative to the knot would convert them to be absolute when GetPoint() was called with 'i' specifying one of the control points. When the control point is later set, the object can convert it back to be relative to its knot. At this point it could also apply any constraints that it may have, such as maintaining a degree of continuity. The idea is that the entity calling GetPoint(i) and SetPoint(i) doesn't care what the point represents. It will simply apply some function to the point.

Note
The Deformable object methods only need to be implemented if the object returns TRUE from this method.
Returns
Return nonzero if the object is deformable and implements the generic deformable object methods; otherwise 0.

Reimplemented from Object.

139{ return 1; }

◆ NumPoints()

int NumPoints ( )
inlinevirtual

The points of a deformable object are accessed through a virtual array interface.

This method specifies the number of points in the object. The meaning of 'points' is defined by the object. A TriObject uses the vertices as the points for example. b>

Returns
The number of points in the object.

Reimplemented from Object.

140{ return mesh.getNumVerts(); }
int getNumVerts(void) const
Returns the number of vertices.
Definition: mesh.h:1623
Mesh mesh
Definition: triobj.h:89

◆ GetPoint()

Point3 GetPoint ( int  i)
inlinevirtual

The points of a deformable object are accessed through a virtual array interface.

This method returns the 'i-th' point of the object.

Note
If your plug-in is a modifier and you want to operate on the selected points of the object you are modifying, you can't tell which points are selected unless you know the type of object. If it is a generic deformable object there is no way of knowing since the way the object handles selection is up to it. Therefore, if you want to operate on selected points of a generic deformable object, use a Deformer.
Parameters
iSpecifies which point should be returned.
Returns
The 'i-th' point of the object.

Reimplemented from Object.

141{ return mesh.getVert(i); }
Point3 & getVert(int i)
Returns the 'i-th' vertex.
Definition: mesh.h:1964

◆ SetPoint()

void SetPoint ( int  i,
const Point3 p 
)
inlinevirtual

The points of a deformable object are accessed through a virtual array interface.

This method stores the 'i-th' point of the object.

Parameters
iThe index of the point to store.
pThe point to store.

Reimplemented from Object.

142{ mesh.setVert(i,p); }
void setVert(int i, const Point3 &xyz)
Sets a single vertex in the verts array.
Definition: mesh.h:1949

◆ IsPointSelected()

CoreExport BOOL IsPointSelected ( int  i)
virtual

Returns TRUE if the 'i-th' point is selected; otherwise FALSE.

Parameters
iThe zero based index of the point to check.

Reimplemented from Object.

◆ PointSelection()

CoreExport float PointSelection ( int  i)
virtual

Returns a floating point weighted point selection if the object supports it.

The default implementation just returns 1.0f if selected and 0.0f if not.

Parameters
iThe zero based index of the point to check.

Reimplemented from Object.

◆ IsMappable()

int IsMappable ( )
inlinevirtual

This method lets you know if the ApplyUVWMap() method is available for this object.

This is used by things like the UVW mapping modifier, so that it can determine which objects can have their mapping modified. Returns nonzero if the object is mappable; otherwise zero.

Reimplemented from Object.

148{ return 1; }

◆ NumMapChannels()

int NumMapChannels ( )
inlinevirtual

Returns the maximum number of channels supported by this type of object.

TriObjects for instance return MAX_MESHMAPS which is currently set to 100.

Reimplemented from Object.

149{ return MAX_MESHMAPS; }
#define MAX_MESHMAPS
The higher limit of the mapping channels (map channel can be from 0 to MAX_MESHMAPS - 1)
Definition: mesh.h:427

◆ NumMapsUsed()

int NumMapsUsed ( )
inlinevirtual

Returns the number of maps currently used by this object.

This is at least 1+(highest channel in use). This is used so a plug-in that does something to all map channels doesn't always have to do it to every channel up to MAX_MESHMAPS but rather only to this value.

Reimplemented from Object.

150{ return mesh.getNumMaps(); }
DllExport int getNumMaps() const
Returns the number of mapping channels in use.

◆ ApplyUVWMap()

void ApplyUVWMap ( int  type,
float  utile,
float  vtile,
float  wtile,
int  uflip,
int  vflip,
int  wflip,
int  cap,
const Matrix3 tm,
int  channel = 1 
)
inlinevirtual

This method may be called to map the object with UVW mapping coordinates.

If the object returns nonzero from IsMappable() then this method should be implemented.

Parameters
typeThe mapping type. One of the following values: MAP_PLANAR
MAP_CYLINDRICAL
MAP_SPHERICAL
MAP_BALL
MAP_BOX
utileNumber of tiles in the U direction.
vtileNumber of tiles in the V direction.
wtileNumber of tiles in the W direction.
uflipIf nonzero the U values are mirrored.
vflipIf nonzero the V values are mirrored.
wflipIf nonzero the W values are mirrored.
capThis is used with MAP_CYLINDRICAL. If nonzero, then any face normal that is pointing more vertically than horizontally will be mapped using planar coordinates.
tmThis defines the mapping space. As each point is mapped, it is multiplied by this matrix, and then it is mapped.
channelThis indicates which channel the mapping is applied to. See Mapping Channels .

Reimplemented from Object.

152 {
153 mesh.ApplyUVWMap(type,utile,vtile,wtile,uflip,vflip,wflip,cap,tm,channel); }
DllExport void ApplyUVWMap(int type, float utile, float vtile, float wtile, int uflip, int vflip, int wflip, int cap, const Matrix3 &tm, int channel=1)
This method may be called to map this Mesh with UVW mapping coordinates.

◆ PolygonCount()

CoreExport BOOL PolygonCount ( TimeValue  t,
int numFaces,
int numVerts 
)
virtual

Retreives the number of faces and vertices of the polyginal mesh representation of this object.

If this method returns FALSE then this functionality is not supported. Note: Plug-In developers should use the global function GetPolygonCount(Object*, int&, int&) to retrieve the number f vertices and faces in an arbitrary object.

Parameters
tThe time at which to compute the number of faces and vertices.
numFacesThe number of faces is returned here.
numVertsThe number of vertices is returned here.
Returns
TRUE if the method is fully implemented; otherwise FALSE.

Reimplemented from Object.

◆ PointsWereChanged()

void PointsWereChanged ( )
inlinevirtual

Informs the object that its points have been deformed, so it can invalidate its cache.

A developer who uses the GetPoint() / SetPoint() approach to modifying an object will call PointsWereChanged() to invalidate the object's cache. For example, if a modifier calls SetPoint(), when it is finished it should call this method so the object can invalidate and/or update its bounding box and any other data it might cache.

Reimplemented from Object.

DllExport void InvalidateGeomCache()
Call this method after the geometry of this Mesh has changed.

◆ GetDeformBBox()

CoreExport void GetDeformBBox ( TimeValue  t,
Box3 box,
Matrix3 tm = NULL,
BOOL  useSel = FALSE 
)
virtual

This method computes the bounding box in the objects local coordinates or the optional space defined by tm.

Note: If you are looking for a precise bounding box, use this method and pass in the node's object TM (INode::GetObjectTM()) as the matrix.

Parameters
tThe time to compute the box.
boxA reference to a box the result is stored in.
tmThis is an alternate coordinate system used to compute the box. If the tm is not NULL this matrix should be used in the computation of the result.
useSelIf TRUE, the bounding box of selected sub-elements should be computed; otherwise the entire object should be used.

Reimplemented from Object.

◆ Deform()

CoreExport void Deform ( Deformer defProc,
int  useSel 
)
virtual

This is the method used to deform the object with a deformer.

The developer should loop through the object's points calling the defProc for each point (or each selected point if useSel is nonzero). The Deform() method is mostly a convenience. Modifiers can implement a 'Deformer' callback object which is passed to the Deform() method. The object then iterates through its points calling their deformer's callback for each point. The only difference between using the Deform() method as opposed to iterating through the points is that the Deform() method should respect sub-object selection. For example, the TriObject's implementation of Deform() iterates through its vertices, if the TriObject's selection level is set to vertex then it only calls the Deformer's callback for vertices that are selected. This way modifiers can be written that can be applied only to selection sets without any specific code to check selected points. The default implementation of this method just iterates through all points using GetPoint(i) and SetPoint(i). If an object supports sub-object selection sets then it should override this method.

Parameters
defProcA pointer to an instance of the Deformer class. This is the callback object that actually performs the deformation.
useSelA flag to indicate if the object should use the selected points only. If nonzero the selected points are used; otherwise all the points of the object are used.
Default Implementation:
void Object::Deform(Deformer *defProc,int useSel)
{
int nv = NumPoints();
for (int i=0; i<nv; i++)
SetPoint(i,defProc->Map(i,GetPoint(i)));
}
The callback object used by modifiers to deform "Deformable" objects.
Definition: object.h:1227
virtual CoreExport Point3 Map(int i, Point3 p) const
This is the method that is called to deform or alter a single point.
virtual CoreExport void Deform(Deformer *defProc, int useSel=0)
This is the method used to deform the object with a deformer.
Point3 GetPoint(int i)
The points of a deformable object are accessed through a virtual array interface.
Definition: triobj.h:141
int NumPoints()
The points of a deformable object are accessed through a virtual array interface.
Definition: triobj.h:140
void SetPoint(int i, const Point3 &p)
The points of a deformable object are accessed through a virtual array interface.
Definition: triobj.h:142
void PointsWereChanged()
Informs the object that its points have been deformed, so it can invalidate its cache.
Definition: triobj.h:156
Sample Code:
This code shows the TriObject implementation of this method. Note how it looks at the useSel parameter to only call the selected points if required.
void TriObject::Deform(Deformer *defProc,int useSel)
{
int nv = NumPoints();
int i;
if ( useSel ) {
float *vssel = mesh.getVSelectionWeights ();
if (vssel) {
for (i=0; i<nv; i++) {
if(sel[i]) {
SetPoint(i,defProc->Map(i,GetPoint(i)));
continue;
}
if (vssel[i]==0) continue;
Point3 & A = GetPoint(i);
Point3 dir = defProc->Map(i,A) - A;
SetPoint(i,A+vssel[i]*dir);
}
}
else {
for (i=0; i<nv; i++) if (sel[i])
SetPoint(i,defProc->Map(i,GetPoint(i)));
}
}
else {
for (i=0; i<nv; i++)
SetPoint(i,defProc->Map(i,GetPoint(i)));
}
}
Definition: bitarray.h:59
DllExport BitArray VertexTempSel()
Constructs a vertex selection list based on the current selection level.
float * getVSelectionWeights()
Returns a pointer to the floating point vertex selection weights data.
Definition: mesh.h:1912
Definition: point3.h:54
CoreExport void Deform(Deformer *defProc, int useSel)
This is the method used to deform the object with a deformer.

Reimplemented from Object.

◆ CanConvertToType()

CoreExport int CanConvertToType ( Class_ID  obtype)
virtual

Indicates whether the object can be converted to the specified type.

If the object returns nonzero to indicate it can be converted to the specified type, it must handle converting to and returning an object of that type from ConvertToType(). Note that all overrides of this method should either call _super::CanConvertToType or test to see if obtype == anyObjectClassID. If true, the method should return true.

See also
Class ObjectConverter for additional details on converting objects between types.
Parameters
obtypeThe Class_ID of the type of object to convert to. See Class Class_ID, Class IDs defined in plugapi.h.
Returns
Nonzero if the object can be converted to the specified type; otherwise 0.

Reimplemented from Object.

◆ ConvertToType()

CoreExport Object * ConvertToType ( TimeValue  t,
Class_ID  obtype 
)
virtual

This method converts this object to the type specified and returns a pointer it.

Note that if ConvertToType() returns a new object it should be a completely different object with no ties (pointers or references) to the original. Note that all overrides of this method should either call _super::ConvertToType or test to see if obtype == anyObjectClassID. If true, the object should return itself.

See also
class ObjectConverter for additional details on converting objects between types.
The following is an issue that developers of world space modifiers need to
be aware of if the world space modifier specifies anything but generic deformable objects as its input type. In other words, if a world space modifier, in its implementation of Modifier::InputType(), doesn't specifically return defObjectClassID then the following issue regarding the 3ds Max pipeline needs to be considered. Developers of other plug-ins that don't meet this condition don't need to be concerned with this issue.
World space modifiers that work on anything other than generic deformable
objects are responsible for transforming the points of the object they modify into world space using the ObjectState TM. To understand why this is necessary, consider how 3ds Max applies the node transformation to the object flowing down the pipeline.
In the geometry pipeline architecture, the node in the scene has its
transformation applied to the object in the pipeline at the transition between the last object space modifier and the first world space modifier. The node transformation is what places the object in the scene – thus this is what puts the object in world space. The system does this by transforming the points of the object in the pipeline by the node transformation. This is only possible however for deformable objects. Deformable objects are those that support the Object::IsDeformable(), NumPoints(), GetPoint() and SetPoint() methods. These deformable objects can be deformed by the system using these methods, and thus the system can modify the points to put them in world space itself.
If a world space modifier does not specify that it works on deformable
objects, the system is unable to transform the points of the object into world space. What it does instead is apply the transformation to the ObjectState TM. In this case, a world space modifier is responsible for transforming the points of the object into world space itself, and then setting the ObjectState TM to the identity. There is an example of this in the sample code for the Bomb space warp. The Bomb operates on TriObjects and implements InputType() as { return Class_ID(TRIOBJ_CLASS_ID,0); }. Since it doesn't specifically return defObjectClassID, it is thus responsible for transforming the points of the object into world space itself. It does this in its implementation of ModifyObject() as follows:
if (os->GetTM())
{
Matrix3 tm = *(os->GetTM());
for (int i=0; i<triOb->mesh.getNumVerts(); i++) {
triOb->mesh.verts[i] = triOb->mesh.verts[i] *tm;
}
os->obj->UpdateValidity(GEOM_CHAN_NUM,os->tmValid());
os->SetTM(NULL,FOREVER);
}
#define NULL
Definition: autoptr.h:18
Definition: matrix3.h:99
#define GEOM_CHAN_NUM
The geometry channel number.
Definition: channels.h:112
#define FOREVER
Definition: interval.h:168
As the code above shows, the Bomb checks if the ObjectState TM is non-NULL. If it is, the points of the object are still not in world space and thus must be transformed. It does this by looping through the points of the TriObject and multiplying each point by the ObjectState TM. When it is done, it sets the ObjectState TM to NULL to indicate the points are now in world space. This ensure that any later WSMs will not transform the points with this matrix again.
For the Bomb world space modifier this is not a problem since it specifies
in its implementation of ChannelsChanged() that it will operate on the geometry channel (GEOM_CHANNEL). Certain world space modifiers may not normally specify GEOM_CHANNEL in their implementation of ChannelsChanged(). Consider the camera mapping world space modifier. Its function is to apply mapping coordinates to the object it is applied to. Thus it would normally only specify TEXMAP_CHANNEL for ChannelsChanged(). However, since it operates directly on TriObjects, just like the Bomb, the system cannot transform the points into world space, and therefore the camera mapping modifier must do so in its implementation of ModifyObject(). But since it is actually altering the points of the object by putting them into world space it is altering the geometry channel. Therefore, it should really specify GEOM_CHANNEL | TEXMAP_CHANNEL in its implementation of ChannelsChanged(). If it didn't do this, but went ahead and modified the points of the object anyway, it would be transforming not copies of the points, but the original points stored back in an earlier cache or even the base object.
This is the issue developers need to be aware of. To state this in simple
terms then: Any world space modifier that needs to put the points of the object into world space (since it doesn't implement InputType() as defObjectClassID) needs to specify GEOM_CHANNEL in its implementation of ChannelsChanged().
Parameters
tThe time at which to convert.
obtypeThe Class_ID of the type of object to convert to. See Class Class_ID, Class IDs defined in plugapi.h.
Returns
A pointer to an object of type obtype.
Default Implementation:
{ return NULL; }
Sample Code:
The following code shows how a TriObject can be retrieved from a node. Note on the code that if you call ConvertToType() on an object and it returns a pointer other than itself, you are responsible for deleting that object.
// Retrieve the TriObject from the node
int deleteIt;
TriObject *triObject = GetTriObjectFromNode(ip->GetSelNode(0),deleteIt);
// Use the TriObject if available
if (!triObject) return;
// ...
// Delete it when done...
if (deleteIt) triObject->DeleteMe();
// Return a pointer to a TriObject given an INode or return NULL
// if the node cannot be converted to a TriObject
TriObject *Utility::GetTriObjectFromNode(INode *node, int &deleteIt)
{
deleteIt = FALSE;
Object *obj = node->EvalWorldState(0).obj;
// Note that the TriObject should only be deleted
// if the pointer to it is not equal to the object
// pointer that called ConvertToType()
if (obj != tri)
deleteIt = TRUE;
return tri;
}
else {
return NULL;
}
}
Definition: maxtypes.h:67
Definition: inode.h:55
virtual const ObjectState & EvalWorldState(TimeValue time, BOOL evalHidden=TRUE)=0
The object class is the base class for all objects.
Definition: object.h:1431
virtual CoreExport int CanConvertToType(Class_ID obtype)
Indicates whether the object can be converted to the specified type.
virtual CoreExport Object * ConvertToType(TimeValue t, Class_ID obtype)
This method converts this object to the type specified and returns a pointer it.
Object * obj
Pointer to the object in the pipeline.
Definition: object.h:298
CoreExport void DeleteMe()
Deletes an instance of this class.
Definition: triobj.h:63
#define TRIOBJ_CLASS_ID
TriObject class ID.
Definition: plugapi.h:582

Reimplemented from Object.

◆ FreeChannels()

CoreExport void FreeChannels ( ChannelMask  channels)
virtual

This method deletes the memory associated with the specified channels and set the intervals associated with the channels to invalid (empty).

Parameters
channelsSpecifies the channels to free.

Reimplemented from Object.

◆ MakeShallowCopy()

CoreExport Object * MakeShallowCopy ( ChannelMask  channels)
virtual

This method must make a copy of its "shell" and then shallow copy (see below) only the specified channels.

It must also copy the validity intervals of the copied channels, and invalidate the other intervals.

Parameters
channelsThe channels to copy.
Returns
A pointer to the shallow copy of the object.

Reimplemented from Object.

◆ ShallowCopy()

CoreExport void ShallowCopy ( Object fromOb,
ChannelMask  channels 
)
virtual

This method copies the specified channels from the fromOb to this and copies the validity intervals.

A plug-in needs to copy the specified channels from the specified object fromOb to itself by just copying pointers (not actually copying the data). No new memory is typically allocated, this method is just copying the pointers.

Parameters
fromObObject to copy the channels from.
channelsChannels to copy.

Reimplemented from Object.

◆ NewAndCopyChannels()

CoreExport void NewAndCopyChannels ( ChannelMask  channels)
virtual

This method replaces the locked channels with newly allocated copies.

It will only be called if the channel is locked.

Parameters
channelsThe channels to be allocate and copy.

Reimplemented from Object.

◆ GetSubselState()

CoreExport DWORD GetSubselState ( )
virtual

For objects that have sub selection levels, this method returns the current selection level of the object.

For example, a TriObject has the following selection levels: object, vertex, face, edge. Other object types may have different selection levels. The only standard is that a value of 0 indicates object level. b>

Returns
The current selection level of the object.

Reimplemented from Object.

◆ SetSubSelState()

CoreExport void SetSubSelState ( DWORD  s)
virtual

Implemented by the System.

This method locks the object as a whole. The object defaults to not modifiable.

Reimplemented from Object.

◆ CheckObjectIntegrity()

CoreExport BOOL CheckObjectIntegrity ( )
virtual

This method is used for debugging only.

The TriObject implements this method by making sure its face's vert indices are all valid.

Returns
TRUE if valid; otherwise FALSE.

Reimplemented from Object.

◆ IntersectRay()

CoreExport int IntersectRay ( TimeValue  t,
Ray r,
float &  at,
Point3 norm 
)
virtual

This method is called to compute the intersection point and surface normal at this intersection point of the ray passed and the object.

Parameters
tThe time to compute the intersection.
rRay to intersect. See Class Ray.
atThe point of intersection.
normSurface normal at the point of intersection.
Returns
Nonzero if a point of intersection was found; otherwise 0.
See also
The Mesh class implementation of this method.

Reimplemented from Object.

◆ GetWorldBoundBox()

CoreExport void GetWorldBoundBox ( TimeValue  t,
INode inode,
ViewExp vp,
Box3 box 
)
virtual

This method returns the world space bounding box for Objects (see below for the Sub-object gizmo or Modifiers gizmo version).

The bounding box returned by this method does not need to be precise. It should however be calculated rapidly. The object can handle this by transforming the 8 points of its local bounding box into world space and take the minimums and maximums of the result. Although this isn't necessarily the tightest bounding box of the objects points in world space, it is close enough.

Parameters
tThe time to compute the bounding box.
inodeThe node to calculate the bounding box for.
vpAn interface pointer that can be used to call methods associated with the viewports.
boxContains the returned bounding box.

Reimplemented from BaseObject.

◆ GetLocalBoundBox()

CoreExport void GetLocalBoundBox ( TimeValue  t,
INode inode,
ViewExp vp,
Box3 box 
)
virtual

This is the object space bounding box, the box in the object's local coordinates.

The system expects that requesting the object space bounding box will be fast.

Parameters
tThe time to retrieve the bounding box.
inodeThe node to calculate the bounding box for.
vpAn interface pointer that may be used to call methods associated with the viewports.
boxContains the returned bounding box.

Reimplemented from BaseObject.

◆ GetRenderMesh()

CoreExport Mesh * GetRenderMesh ( TimeValue  t,
INode inode,
View view,
BOOL &  needDelete 
)
virtual

This method should be implemented by all renderable GeomObjects.

It provides a mesh representation of the object for use by the renderer. Primitives that already have a mesh cached can just return a pointer to it (and set needDelete to FALSE). Implementations of this method which take a long time should periodically call View::CheckForRenderAbort() to see if the user has canceled the render. If canceled, the function can either return NULL, or return a non null pointer with the appropriate value for needDelete. (If needDelete is TRUE a non-null mesh will be deleted.)

Parameters
tThe time to get the mesh.
inodeThe node in the scene.
viewIf the renderer calls this method it will pass the view information here. See Class View.
needDeleteSet to TRUE if the renderer should delete the mesh, FALSE otherwise.
Returns
A pointer to the mesh object.

Reimplemented from GeomObject.

◆ CanDoDisplacementMapping()

CoreExport BOOL CanDoDisplacementMapping ( )
virtual

Returns TRUE if this object can do displacement mapping; otherwise FALSE.

Reimplemented from GeomObject.

◆ DisplacmentApprox()

CoreExport TessApprox & DisplacmentApprox ( )
inline
Remarks
This method is available in release 3.0 and later only.

Returns a reference to the mDispApprox data member.
183{ return mDispApprox; }
TessApprox mDispApprox
Definition: triobj.h:90

◆ DoSubdivisionDisplacment()

CoreExport bool & DoSubdivisionDisplacment ( )
inline
Remarks
This method is available in release 3.0 and later only.

Returns a reference to the boolean mSubDivideDisplacement data member.
188{ return mSubDivideDisplacement; }
bool mSubDivideDisplacement
Definition: triobj.h:91

◆ SplitMeshForDisplacement()

CoreExport bool & SplitMeshForDisplacement ( )
inline
Remarks
This method is available in release 3.0 and later only.

Returns a reference to the boolean mSplitMesh data member.
192{ return mSplitMesh; }
bool mSplitMesh
Definition: triobj.h:93

◆ SetDisplacmentApproxToPreset()

CoreExport void SetDisplacmentApproxToPreset ( int  preset)
Remarks
This method is available in release 3.0 and later only.

This method is used internally to set the mDispApprox data member to one of the low/medium/high subdivision presets.

◆ DisableDisplacementMapping()

CoreExport void DisableDisplacementMapping ( BOOL  disable)
Remarks
This method is available in release 3.0 and later only.

Sets the mDisableDisplacement data member to the given state.
Parameters:
BOOL disable

TRUE to disable; FALSE to enable.

◆ TopologyChanged()

CoreExport void TopologyChanged ( )
virtual

Implemented by the System.

This method locks the object as a whole. The object defaults to not modifiable.

Reimplemented from Object.

◆ GetMesh()

Mesh & GetMesh ( )
inline
Remarks
This method is available in release 3.0 and later only.

Returns a reference to the mesh data member of this TriObject.
212{ return mesh; }

◆ DeleteThis()

CoreExport void DeleteThis ( )
virtual

Deletes an instance of this class.

3ds Max calls this method when it needs to delete a plugin object (an instance of a class derived from Animatable). Similarly, plugins that need to delete instances of an Animatable or a class directly derived from it via an Animatable pointer, should call this method instead of calling directly operator delete. Following these rules will ensure that the same memory manager is used to allocate and deallocate the object. The default implementation of this method deletes the object. Plugin instances that never need to be deleted from the heap can overwrite this method to do nothing.

Note
See the method ClassDesc::Create() for details on how Max allocates plugin objects.
See ReferenceMaker::DeleteMe() and ReferenceTarget::MaybeAutoDelete() for information on how plugin instances are deleted by the system.
Remarks
See Memory Management.

See also
Required DLL Functions, Class ClassDesc.

Reimplemented from Animatable.

◆ FreeCaches()

void FreeCaches ( )
inlinevirtual
Remarks
This is called to delete any item that can be rebuilt. For example, the procedural sphere object has a mesh that it caches. It could call Mesh::FreeAll() on the mesh from this method. This will free the vertex/face/uv arrays. If the sphere is ever evaluated again it can just rebuild the mesh. If an object (like a sphere) has modifiers applied to it, and those modifiers are not animated, then the result of the pipeline is cached in the node. So there is no reason for the sphere to also have a cache of its representation. Therefore when this method is called, the sphere can free the data of the mesh.
Default Implementation:
{}

Reimplemented from Animatable.

◆ ClassID()

Class_ID ClassID ( )
inlinevirtual

Retrieves a constant that uniquely identifies the plugin class.

This method must return the unique ID for the plugin class. If two ClassIDs conflict, the system will only load the first conflicting one it finds. A program (gencid.exe) is provided to generate unique class id values.

Returns
A class id that uniquely identifies a plugin class
See also
Class ClassID, class ID definitions in plugapi.h.

Reimplemented from Animatable.

218{ return Class_ID(TRIOBJ_CLASS_ID,0); }

◆ GetClassName()

void GetClassName ( MSTR s,
bool  localized = true 
) const
inlineoverridevirtual

Retrieves the name of the plugin class.

This name is used in 3ds Max's UI and in MAXScript. For Material plug-ins this method is used to put up the material "type" name in the Material Editor.

Parameters
sReference to a string filled in with the name of the plugin class.
localizedIf true, then the class name returned should be localized in the language 3ds Max is currently using. Otherwise it should be the class name in English. If a plugin does not provide localized string resources, it can disregard this parameter and always return the class name in English.

Reimplemented from ReferenceTarget.

219{ UNUSED_PARAM(localized); s = MSTR(_M("TriObject")); }
#define UNUSED_PARAM(x)
Definition: BuildWarnings.h:18
#define _M(x)
Used to wrap string literals.
Definition: strbasic.h:67
WStr MSTR
Definition: strclass.h:1071

◆ NotifyMe()

void NotifyMe ( Animatable subAnim,
int  message 
)
inline
220{ UNUSED_PARAM(subAnim); UNUSED_PARAM(message);}

◆ IsKeyable()

int IsKeyable ( )
inline
221{ return 0;}

◆ Update()

int Update ( TimeValue  t)
inline
222{ UNUSED_PARAM(t); return 0; }

◆ GetObjectName()

const MCHAR * GetObjectName ( bool  localized) const
inlineoverridevirtual
Returns
the name that will appear in the modifier stack.
Parameters
localizedIf true, then the object name returned should be localized in the language 3ds Max is currently using. Otherwise it should be the object name in English. If a plugin does not provide localized string resources, it can disregard this parameter and always return the object name in English.

Reimplemented from BaseObject.

225{ return _M("Mesh"); }

◆ RescaleWorldUnits()

CoreExport void RescaleWorldUnits ( float  f)
virtual

Rescale size of all world units in reference hierarchy.

This method is available in release 2.0 and later only. Must call ClearAFlagInHierarchy(rm, A_WORK1) or ClearAFlagInAllAnimatables(A_WORK1) before doing this on a reference hierarchy. This may be implemented to rescale the size of all world units in a reference hierarchy. Developers must call

return;
void SetAFlag(DWORD mask)
Definition: Animatable.h:325
bool TestAFlag(DWORD mask) const
Tests one or more bits in the Animatable flags.
Definition: Animatable.h:338
#define A_WORK1
Definition: AnimatableFlags.h:216

before doing this on a reference hierarchy.

Parameters
f- The scale factor.

Reimplemented from ReferenceMaker.

◆ Save() [1/2]

CoreExport IOResult Save ( ISave isave)
inlinevirtual

Called for saving data.

Called by the system to allow the plugin to save its data.

Parameters
isave- This pointer may be used to call methods to write data to disk. See the section on Loading and Saving Plug-in Data for an overview of the load/save process.
Returns
The default implementation is return IO_OK.
  • IO_OK means the result was acceptable, with no errors.
  • IO_ERROR This should be returned if an error occurred.

Reimplemented from ReferenceMaker.

230{ return Save(isave, ALL_CHANNELS); }
CoreExport IOResult Save(ISave *isave)
Called for saving data.
Definition: triobj.h:230
const ChannelMask ALL_CHANNELS
All object, transform and global material channels.
Definition: channels.h:99

◆ Save() [2/2]

CoreExport IOResult Save ( ISave isave,
ChannelMask   
)
virtual

Access the ReferenceSaveManager of this ReferenceMaker.

The ReferenceSaveManager is used to specify and enumerate the save reference hierarchy for the ReferenceMaker. If a plugin needed to specify a save reference hierarchy different than its normal reference hierarchy, it would implement SpecifySaveReferences() and specify the save reference hierarchy through the ReferenceSaveManager in that implementation.

Returns
the ReferenceSaveManager for the ReferenceMaker.

Reimplemented from ReferenceMaker.

◆ Load() [1/2]

CoreExport IOResult Load ( ILoad iload)
inlinevirtual

Called for loading data.

Called by the system to allow the plug-in to load its data. See the section on Loading and Saving Plug-in Data for an overview of the load - save process.

Parameters
iload- This interface pointer may be used to call methods to read data from disk.
Returns
The default implementation is return IO_OK.
  • IO_OK means the result was acceptable, with no errors.
  • IO_ERROR This should be returned if an error occurred.

Reimplemented from ReferenceMaker.

232{ return Load(iload, ALL_CHANNELS); }
CoreExport IOResult Load(ILoad *iload)
Called for loading data.
Definition: triobj.h:232

◆ Load() [2/2]

CoreExport IOResult Load ( ILoad iload,
ChannelMask   
)
virtual

Access the ReferenceSaveManager of this ReferenceMaker.

The ReferenceSaveManager is used to specify and enumerate the save reference hierarchy for the ReferenceMaker. If a plugin needed to specify a save reference hierarchy different than its normal reference hierarchy, it would implement SpecifySaveReferences() and specify the save reference hierarchy through the ReferenceSaveManager in that implementation.

Returns
the ReferenceSaveManager for the ReferenceMaker.

Reimplemented from ReferenceMaker.

◆ ReduceDisplayCaches()

CoreExport void ReduceDisplayCaches ( )
virtual

Should reduce any derived display data to save memory, since the node wont be drawn until the user undhides it.

This function should delete any derived data used to display the object such as gfx normals, direct mesh caches etc.
This is typicallly called when the user hides the node or sets it as bounding box

Reimplemented from Object.

◆ NeedGWCacheRebuilt()

CoreExport bool NeedGWCacheRebuilt ( GraphicsWindow gw,
Material ma,
int  numMat 
)
virtual

This returns whether the Graphics Cache for this object needs to be rebuilt.

Parameters:
GraphicsWindow *gw the active graphics window
Material *ma the material aray assigned to the mesh
int numMat the number of materials in the material array

Reimplemented from Object.

◆ BuildGWCache()

CoreExport void BuildGWCache ( GraphicsWindow gw,
Material ma,
int  numMat,
BOOL  threaded 
)
virtual

This builds the graphics window cached mesh.

Parameters:
GraphicsWindow *gw the active graphics window
Material *ma the material aray assigned to the mesh
int numMat the number of materials in the material array
BOOL threaded whether when building the cache it can use additional threads. This is needed since the system may be creating many meshes at the same time

Reimplemented from Object.

◆ StartStackEval()

virtual CoreExport void StartStackEval ( )
overridevirtual

This are called right before and after a modifier is applied to an object.

This allows for certain types of opitimizations to happens since durinng modifier modification the object knows what channels are changing and can do optimizations to speed things up like invalidating specific display channels which it does not know about when say a baseobject is evaluated.

Reimplemented from Object.

◆ EndStackEval()

virtual CoreExport void EndStackEval ( )
overridevirtual

Reimplemented from Object.

Member Data Documentation

◆ geomValid

Interval geomValid
protected

◆ topoValid

Interval topoValid
protected

◆ texmapValid

Interval texmapValid
protected

◆ selectValid

Interval selectValid
protected

◆ vcolorValid

Interval vcolorValid
protected

◆ gfxdataValid

Interval gfxdataValid
protected

◆ validBits

ChannelMask validBits
protected

◆ mesh

Mesh mesh

◆ mDispApprox

TessApprox mDispApprox

◆ mSubDivideDisplacement

bool mSubDivideDisplacement

◆ mDisableDisplacement

bool mDisableDisplacement

◆ mSplitMesh

bool mSplitMesh