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Kitware.VTK.vtkImplicitModeller Class Reference

vtkImplicitModeller - compute distance from input geometry on structured point dataset More...

Inheritance diagram for Kitware.VTK.vtkImplicitModeller:
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Collaboration diagram for Kitware.VTK.vtkImplicitModeller:
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List of all members.

Public Member Functions

 vtkImplicitModeller (IntPtr rawCppThis, bool callDisposalMethod, bool strong)
 Automatically generated constructor - called from generated code. DO NOT call directly.
 vtkImplicitModeller ()
 Construct with sample dimensions=(50,50,50), and so that model bounds are automatically computed from the input. Capping is turned on with CapValue equal to a large positive number.
virtual void AdjustBoundsOff ()
 Control how the model bounds are computed. If the ivar AdjustBounds is set, then the bounds specified (or computed automatically) is modified by the fraction given by AdjustDistance. This means that the model bounds is expanded in each of the x-y-z directions.
virtual void AdjustBoundsOn ()
 Control how the model bounds are computed. If the ivar AdjustBounds is set, then the bounds specified (or computed automatically) is modified by the fraction given by AdjustDistance. This means that the model bounds is expanded in each of the x-y-z directions.
void Append (vtkDataSet input)
 Append a data set to the existing output. To use this function, you'll have to invoke the StartAppend() method before doing successive appends. It's also a good idea to specify the model bounds; otherwise the input model bounds is used. When you've finished appending, use the EndAppend() method.
virtual void CappingOff ()
 The outer boundary of the structured point set can be assigned a particular value. This can be used to close or "cap" all surfaces.
virtual void CappingOn ()
 The outer boundary of the structured point set can be assigned a particular value. This can be used to close or "cap" all surfaces.
double ComputeModelBounds (vtkDataSet input)
 Compute ModelBounds from input geometry. If input is not specified, the input of the filter will be used.
void EndAppend ()
 Method completes the append process.
virtual int GetAdjustBounds ()
 Control how the model bounds are computed. If the ivar AdjustBounds is set, then the bounds specified (or computed automatically) is modified by the fraction given by AdjustDistance. This means that the model bounds is expanded in each of the x-y-z directions.
virtual double GetAdjustDistance ()
 Specify the amount to grow the model bounds (if the ivar AdjustBounds is set). The value is a fraction of the maximum length of the sides of the box specified by the model bounds.
virtual double GetAdjustDistanceMaxValue ()
 Specify the amount to grow the model bounds (if the ivar AdjustBounds is set). The value is a fraction of the maximum length of the sides of the box specified by the model bounds.
virtual double GetAdjustDistanceMinValue ()
 Specify the amount to grow the model bounds (if the ivar AdjustBounds is set). The value is a fraction of the maximum length of the sides of the box specified by the model bounds.
virtual double GetCapValue ()
 Specify the capping value to use. The CapValue is also used as an initial distance value at each point in the dataset.
virtual int GetCapping ()
 The outer boundary of the structured point set can be assigned a particular value. This can be used to close or "cap" all surfaces.
virtual int GetLocatorMaxLevel ()
 Specify the level of the locator to use when using the per voxel process mode.
virtual double GetMaximumDistance ()
 Set / get the distance away from surface of input geometry to sample. Smaller values make large increases in performance.
virtual double GetMaximumDistanceMaxValue ()
 Set / get the distance away from surface of input geometry to sample. Smaller values make large increases in performance.
virtual double GetMaximumDistanceMinValue ()
 Set / get the distance away from surface of input geometry to sample. Smaller values make large increases in performance.
virtual double[] GetModelBounds ()
 Set / get the region in space in which to perform the sampling. If not specified, it will be computed automatically.
virtual void GetModelBounds (IntPtr data)
 Set / get the region in space in which to perform the sampling. If not specified, it will be computed automatically.
virtual int GetNumberOfThreads ()
 Set / Get the number of threads used during Per-Voxel processing mode.
virtual int GetNumberOfThreadsMaxValue ()
 Set / Get the number of threads used during Per-Voxel processing mode.
virtual int GetNumberOfThreadsMinValue ()
 Set / Get the number of threads used during Per-Voxel processing mode.
virtual int GetOutputScalarType ()
 Set the desired output scalar type.
virtual int GetProcessMode ()
 Specify whether to visit each cell once per append or each voxel once per append. Some tests have shown once per voxel to be faster when there are a lot of cells (at least a thousand?); relative performance improvement increases with addition cells. Primitives should not be stripped for best performance of the voxel mode.
string GetProcessModeAsString ()
 Specify whether to visit each cell once per append or each voxel once per append. Some tests have shown once per voxel to be faster when there are a lot of cells (at least a thousand?); relative performance improvement increases with addition cells. Primitives should not be stripped for best performance of the voxel mode.
virtual int GetProcessModeMaxValue ()
 Specify whether to visit each cell once per append or each voxel once per append. Some tests have shown once per voxel to be faster when there are a lot of cells (at least a thousand?); relative performance improvement increases with addition cells. Primitives should not be stripped for best performance of the voxel mode.
virtual int GetProcessModeMinValue ()
 Specify whether to visit each cell once per append or each voxel once per append. Some tests have shown once per voxel to be faster when there are a lot of cells (at least a thousand?); relative performance improvement increases with addition cells. Primitives should not be stripped for best performance of the voxel mode.
virtual int[] GetSampleDimensions ()
 Set/Get the i-j-k dimensions on which to sample distance function.
virtual void GetSampleDimensions (IntPtr data)
 Set/Get the i-j-k dimensions on which to sample distance function.
virtual int GetScaleToMaximumDistance ()
 If a non-floating output type is specified, the output distances can be scaled to use the entire positive scalar range of the output type specified (up to the CapValue which is equal to the max for the type unless modified by the user). For example, if ScaleToMaximumDistance is On and the OutputScalarType is UnsignedChar the distances saved in the output would be linearly scaled between 0 (for distances "very close" to the surface) and 255 (at the specifed maximum distance)... assuming the CapValue is not changed from 255.
override int IsA (string type)
 Undocumented Block.
new vtkImplicitModeller NewInstance ()
 Undocumented Block.
virtual void ScaleToMaximumDistanceOff ()
 If a non-floating output type is specified, the output distances can be scaled to use the entire positive scalar range of the output type specified (up to the CapValue which is equal to the max for the type unless modified by the user). For example, if ScaleToMaximumDistance is On and the OutputScalarType is UnsignedChar the distances saved in the output would be linearly scaled between 0 (for distances "very close" to the surface) and 255 (at the specifed maximum distance)... assuming the CapValue is not changed from 255.
virtual void ScaleToMaximumDistanceOn ()
 If a non-floating output type is specified, the output distances can be scaled to use the entire positive scalar range of the output type specified (up to the CapValue which is equal to the max for the type unless modified by the user). For example, if ScaleToMaximumDistance is On and the OutputScalarType is UnsignedChar the distances saved in the output would be linearly scaled between 0 (for distances "very close" to the surface) and 255 (at the specifed maximum distance)... assuming the CapValue is not changed from 255.
virtual void SetAdjustBounds (int _arg)
 Control how the model bounds are computed. If the ivar AdjustBounds is set, then the bounds specified (or computed automatically) is modified by the fraction given by AdjustDistance. This means that the model bounds is expanded in each of the x-y-z directions.
virtual void SetAdjustDistance (double _arg)
 Specify the amount to grow the model bounds (if the ivar AdjustBounds is set). The value is a fraction of the maximum length of the sides of the box specified by the model bounds.
void SetCapValue (double value)
 Specify the capping value to use. The CapValue is also used as an initial distance value at each point in the dataset.
virtual void SetCapping (int _arg)
 The outer boundary of the structured point set can be assigned a particular value. This can be used to close or "cap" all surfaces.
virtual void SetLocatorMaxLevel (int _arg)
 Specify the level of the locator to use when using the per voxel process mode.
virtual void SetMaximumDistance (double _arg)
 Set / get the distance away from surface of input geometry to sample. Smaller values make large increases in performance.
virtual void SetModelBounds (double _arg1, double _arg2, double _arg3, double _arg4, double _arg5, double _arg6)
 Set / get the region in space in which to perform the sampling. If not specified, it will be computed automatically.
virtual void SetModelBounds (IntPtr _arg)
 Set / get the region in space in which to perform the sampling. If not specified, it will be computed automatically.
virtual void SetNumberOfThreads (int _arg)
 Set / Get the number of threads used during Per-Voxel processing mode.
void SetOutputScalarType (int type)
 Set the desired output scalar type.
void SetOutputScalarTypeToChar ()
 Set the desired output scalar type.
void SetOutputScalarTypeToDouble ()
 Set the desired output scalar type.
void SetOutputScalarTypeToFloat ()
 Set the desired output scalar type.
void SetOutputScalarTypeToInt ()
 Set the desired output scalar type.
void SetOutputScalarTypeToLong ()
 Set the desired output scalar type.
void SetOutputScalarTypeToShort ()
 Set the desired output scalar type.
void SetOutputScalarTypeToUnsignedChar ()
 Set the desired output scalar type.
void SetOutputScalarTypeToUnsignedInt ()
 Set the desired output scalar type.
void SetOutputScalarTypeToUnsignedLong ()
 Set the desired output scalar type.
void SetOutputScalarTypeToUnsignedShort ()
 Set the desired output scalar type.
virtual void SetProcessMode (int _arg)
 Specify whether to visit each cell once per append or each voxel once per append. Some tests have shown once per voxel to be faster when there are a lot of cells (at least a thousand?); relative performance improvement increases with addition cells. Primitives should not be stripped for best performance of the voxel mode.
void SetProcessModeToPerCell ()
 Specify whether to visit each cell once per append or each voxel once per append. Some tests have shown once per voxel to be faster when there are a lot of cells (at least a thousand?); relative performance improvement increases with addition cells. Primitives should not be stripped for best performance of the voxel mode.
void SetProcessModeToPerVoxel ()
 Specify whether to visit each cell once per append or each voxel once per append. Some tests have shown once per voxel to be faster when there are a lot of cells (at least a thousand?); relative performance improvement increases with addition cells. Primitives should not be stripped for best performance of the voxel mode.
void SetSampleDimensions (int i, int j, int k)
 Set/Get the i-j-k dimensions on which to sample distance function.
void SetSampleDimensions (IntPtr dim)
 Set/Get the i-j-k dimensions on which to sample distance function.
virtual void SetScaleToMaximumDistance (int _arg)
 If a non-floating output type is specified, the output distances can be scaled to use the entire positive scalar range of the output type specified (up to the CapValue which is equal to the max for the type unless modified by the user). For example, if ScaleToMaximumDistance is On and the OutputScalarType is UnsignedChar the distances saved in the output would be linearly scaled between 0 (for distances "very close" to the surface) and 255 (at the specifed maximum distance)... assuming the CapValue is not changed from 255.
void StartAppend ()
 Initialize the filter for appending data. You must invoke the StartAppend() method before doing successive Appends(). It's also a good idea to manually specify the model bounds; otherwise the input bounds for the data will be used.

Static Public Member Functions

static new vtkImplicitModeller New ()
 Construct with sample dimensions=(50,50,50), and so that model bounds are automatically computed from the input. Capping is turned on with CapValue equal to a large positive number.
static new int IsTypeOf (string type)
 Undocumented Block.
static new vtkImplicitModeller SafeDownCast (vtkObjectBase o)
 Undocumented Block.

Public Attributes

new const string MRFullTypeName = "Kitware.VTK.vtkImplicitModeller"
 Automatically generated type registration mechanics.

Static Public Attributes

static new readonly string MRClassNameKey = "19vtkImplicitModeller"
 Automatically generated type registration mechanics.

Protected Member Functions

override void Dispose (bool disposing)
 Automatically generated protected Dispose method - called from public Dispose or the C# destructor. DO NOT call directly.

Private Member Functions

static internal IntPtr vtkImplicitModeller_New (ref uint mteStatus, ref uint mteIndex, ref uint rawRefCount)
static internal void vtkImplicitModeller_AdjustBoundsOff_01 (HandleRef pThis)
static internal void vtkImplicitModeller_AdjustBoundsOn_02 (HandleRef pThis)
static internal void vtkImplicitModeller_Append_03 (HandleRef pThis, HandleRef input)
static internal void vtkImplicitModeller_CappingOff_04 (HandleRef pThis)
static internal void vtkImplicitModeller_CappingOn_05 (HandleRef pThis)
static internal double vtkImplicitModeller_ComputeModelBounds_06 (HandleRef pThis, HandleRef input)
static internal void vtkImplicitModeller_EndAppend_07 (HandleRef pThis)
static internal int vtkImplicitModeller_GetAdjustBounds_08 (HandleRef pThis)
static internal double vtkImplicitModeller_GetAdjustDistance_09 (HandleRef pThis)
static internal double vtkImplicitModeller_GetAdjustDistanceMaxValue_10 (HandleRef pThis)
static internal double vtkImplicitModeller_GetAdjustDistanceMinValue_11 (HandleRef pThis)
static internal double vtkImplicitModeller_GetCapValue_12 (HandleRef pThis)
static internal int vtkImplicitModeller_GetCapping_13 (HandleRef pThis)
static internal int vtkImplicitModeller_GetLocatorMaxLevel_14 (HandleRef pThis)
static internal double vtkImplicitModeller_GetMaximumDistance_15 (HandleRef pThis)
static internal double vtkImplicitModeller_GetMaximumDistanceMaxValue_16 (HandleRef pThis)
static internal double vtkImplicitModeller_GetMaximumDistanceMinValue_17 (HandleRef pThis)
static internal IntPtr vtkImplicitModeller_GetModelBounds_18 (HandleRef pThis)
static internal void vtkImplicitModeller_GetModelBounds_19 (HandleRef pThis, IntPtr data)
static internal int vtkImplicitModeller_GetNumberOfThreads_20 (HandleRef pThis)
static internal int vtkImplicitModeller_GetNumberOfThreadsMaxValue_21 (HandleRef pThis)
static internal int vtkImplicitModeller_GetNumberOfThreadsMinValue_22 (HandleRef pThis)
static internal int vtkImplicitModeller_GetOutputScalarType_23 (HandleRef pThis)
static internal int vtkImplicitModeller_GetProcessMode_24 (HandleRef pThis)
static internal IntPtr vtkImplicitModeller_GetProcessModeAsString_25 (HandleRef pThis)
static internal int vtkImplicitModeller_GetProcessModeMaxValue_26 (HandleRef pThis)
static internal int vtkImplicitModeller_GetProcessModeMinValue_27 (HandleRef pThis)
static internal IntPtr vtkImplicitModeller_GetSampleDimensions_28 (HandleRef pThis)
static internal void vtkImplicitModeller_GetSampleDimensions_29 (HandleRef pThis, IntPtr data)
static internal int vtkImplicitModeller_GetScaleToMaximumDistance_30 (HandleRef pThis)
static internal int vtkImplicitModeller_IsA_31 (HandleRef pThis, string type)
static internal int vtkImplicitModeller_IsTypeOf_32 (string type)
static internal IntPtr vtkImplicitModeller_NewInstance_34 (HandleRef pThis, ref uint mteStatus, ref uint mteIndex, ref uint rawRefCount)
static internal IntPtr vtkImplicitModeller_SafeDownCast_35 (HandleRef o, ref uint mteStatus, ref uint mteIndex, ref uint rawRefCount)
static internal void vtkImplicitModeller_ScaleToMaximumDistanceOff_36 (HandleRef pThis)
static internal void vtkImplicitModeller_ScaleToMaximumDistanceOn_37 (HandleRef pThis)
static internal void vtkImplicitModeller_SetAdjustBounds_38 (HandleRef pThis, int _arg)
static internal void vtkImplicitModeller_SetAdjustDistance_39 (HandleRef pThis, double _arg)
static internal void vtkImplicitModeller_SetCapValue_40 (HandleRef pThis, double value)
static internal void vtkImplicitModeller_SetCapping_41 (HandleRef pThis, int _arg)
static internal void vtkImplicitModeller_SetLocatorMaxLevel_42 (HandleRef pThis, int _arg)
static internal void vtkImplicitModeller_SetMaximumDistance_43 (HandleRef pThis, double _arg)
static internal void vtkImplicitModeller_SetModelBounds_44 (HandleRef pThis, double _arg1, double _arg2, double _arg3, double _arg4, double _arg5, double _arg6)
static internal void vtkImplicitModeller_SetModelBounds_45 (HandleRef pThis, IntPtr _arg)
static internal void vtkImplicitModeller_SetNumberOfThreads_46 (HandleRef pThis, int _arg)
static internal void vtkImplicitModeller_SetOutputScalarType_47 (HandleRef pThis, int type)
static internal void vtkImplicitModeller_SetOutputScalarTypeToChar_48 (HandleRef pThis)
static internal void vtkImplicitModeller_SetOutputScalarTypeToDouble_49 (HandleRef pThis)
static internal void vtkImplicitModeller_SetOutputScalarTypeToFloat_50 (HandleRef pThis)
static internal void vtkImplicitModeller_SetOutputScalarTypeToInt_51 (HandleRef pThis)
static internal void vtkImplicitModeller_SetOutputScalarTypeToLong_52 (HandleRef pThis)
static internal void vtkImplicitModeller_SetOutputScalarTypeToShort_53 (HandleRef pThis)
static internal void vtkImplicitModeller_SetOutputScalarTypeToUnsignedChar_54 (HandleRef pThis)
static internal void vtkImplicitModeller_SetOutputScalarTypeToUnsignedInt_55 (HandleRef pThis)
static internal void vtkImplicitModeller_SetOutputScalarTypeToUnsignedLong_56 (HandleRef pThis)
static internal void vtkImplicitModeller_SetOutputScalarTypeToUnsignedShort_57 (HandleRef pThis)
static internal void vtkImplicitModeller_SetProcessMode_58 (HandleRef pThis, int _arg)
static internal void vtkImplicitModeller_SetProcessModeToPerCell_59 (HandleRef pThis)
static internal void vtkImplicitModeller_SetProcessModeToPerVoxel_60 (HandleRef pThis)
static internal void vtkImplicitModeller_SetSampleDimensions_61 (HandleRef pThis, int i, int j, int k)
static internal void vtkImplicitModeller_SetSampleDimensions_62 (HandleRef pThis, IntPtr dim)
static internal void vtkImplicitModeller_SetScaleToMaximumDistance_63 (HandleRef pThis, int _arg)
static internal void vtkImplicitModeller_StartAppend_64 (HandleRef pThis)

Static Private Member Functions

static vtkImplicitModeller ()
 Automatically generated type registration mechanics.

Detailed Description

vtkImplicitModeller - compute distance from input geometry on structured point dataset

Description vtkImplicitModeller is a filter that computes the distance from the input geometry to the points of an output structured point set. This distance function can then be "contoured" to generate new, offset surfaces from the original geometry. An important feature of this object is "capping". If capping is turned on, after the implicit model is created, the values on the boundary of the structured points dataset are set to the cap value. This is used to force closure of the resulting contoured surface. Note, however, that large cap values can generate weird surface normals in those cells adjacent to the boundary of the dataset. Using smaller cap value will reduce this effect. <P> Another important ivar is MaximumDistance. This controls how far into the volume the distance function is computed from the input geometry. Small values give significant increases in performance. However, there can strange sampling effects at the extreme range of the MaximumDistance. <P> In order to properly execute and sample the input data, a rectangular region in space must be defined (this is the ivar ModelBounds). If not explicitly defined, the model bounds will be computed. Note that to avoid boundary effects, it is possible to adjust the model bounds (i.e., using the AdjustBounds and AdjustDistance ivars) to strictly contain the sampled data. <P> This filter has one other unusual capability: it is possible to append data in a sequence of operations to generate a single output. This is useful when you have multiple datasets and want to create a conglomeration of all the data. However, the user must be careful to either specify the ModelBounds or specify the first item such that its bounds completely contain all other items. This is because the rectangular region of the output can not be changed after the 1st Append. <P> The ProcessMode ivar controls the method used within the Append function (where the actual work is done regardless if the Append function is explicitly called) to compute the implicit model. If set to work in voxel mode, each voxel is visited once. If set to cell mode, each cell is visited once. Tests have shown once per voxel to be faster when there are a lot of cells (at least a thousand?); relative performance improvement increases with addition cells. Primitives should not be stripped for best performance of the voxel mode. Also, if explicitly using the Append feature many times, the cell mode will probably be better because each voxel will be visited each Append. Append the data before input if possible when using the voxel mode. Do not switch between voxel and cell mode between execution of StartAppend and EndAppend. <P> Further performance improvement is now possible using the PerVoxel process mode on multi-processor machines (the mode is now multithreaded). Each thread processes a different "slab" of the output. Also, if the input is vtkPolyData, it is appropriately clipped for each thread; that is, each thread only considers the input which could affect its slab of the output. <P> This filter can now produce output of any type supported by vtkImageData. However to support this change, additional sqrts must be executed during the Append step. Previously, the output was initialized to the squared CapValue in StartAppend, the output was updated with squared distance values during the Append, and then the sqrt of the distances was computed in EndAppend. To support different scalar types in the output (largely to reduce memory requirements as an vtkImageShiftScale and/or vtkImageCast could have achieved the same result), we can't "afford" to save squared value in the output, because then we could only represent up to the sqrt of the scalar max for an integer type in the output; 1 (instead of 255) for an unsigned char; 11 for a char (instead of 127). Thus this change may result in a minor performance degradation. Non-float output types can be scaled to the CapValue by turning ScaleToMaximumDistance On.

vtkSampleFunction vtkContourFilter


Constructor & Destructor Documentation

Automatically generated type registration mechanics.

Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller ( IntPtr  rawCppThis,
bool  callDisposalMethod,
bool  strong 
)

Automatically generated constructor - called from generated code. DO NOT call directly.

Construct with sample dimensions=(50,50,50), and so that model bounds are automatically computed from the input. Capping is turned on with CapValue equal to a large positive number.


Member Function Documentation

Control how the model bounds are computed. If the ivar AdjustBounds is set, then the bounds specified (or computed automatically) is modified by the fraction given by AdjustDistance. This means that the model bounds is expanded in each of the x-y-z directions.

Control how the model bounds are computed. If the ivar AdjustBounds is set, then the bounds specified (or computed automatically) is modified by the fraction given by AdjustDistance. This means that the model bounds is expanded in each of the x-y-z directions.

Append a data set to the existing output. To use this function, you'll have to invoke the StartAppend() method before doing successive appends. It's also a good idea to specify the model bounds; otherwise the input model bounds is used. When you've finished appending, use the EndAppend() method.

virtual void Kitware.VTK.vtkImplicitModeller.CappingOff ( ) [virtual]

The outer boundary of the structured point set can be assigned a particular value. This can be used to close or "cap" all surfaces.

virtual void Kitware.VTK.vtkImplicitModeller.CappingOn ( ) [virtual]

The outer boundary of the structured point set can be assigned a particular value. This can be used to close or "cap" all surfaces.

Compute ModelBounds from input geometry. If input is not specified, the input of the filter will be used.

override void Kitware.VTK.vtkImplicitModeller.Dispose ( bool  disposing) [protected]

Automatically generated protected Dispose method - called from public Dispose or the C# destructor. DO NOT call directly.

Reimplemented from Kitware.VTK.vtkImageAlgorithm.

Method completes the append process.

Control how the model bounds are computed. If the ivar AdjustBounds is set, then the bounds specified (or computed automatically) is modified by the fraction given by AdjustDistance. This means that the model bounds is expanded in each of the x-y-z directions.

Specify the amount to grow the model bounds (if the ivar AdjustBounds is set). The value is a fraction of the maximum length of the sides of the box specified by the model bounds.

Specify the amount to grow the model bounds (if the ivar AdjustBounds is set). The value is a fraction of the maximum length of the sides of the box specified by the model bounds.

Specify the amount to grow the model bounds (if the ivar AdjustBounds is set). The value is a fraction of the maximum length of the sides of the box specified by the model bounds.

virtual int Kitware.VTK.vtkImplicitModeller.GetCapping ( ) [virtual]

The outer boundary of the structured point set can be assigned a particular value. This can be used to close or "cap" all surfaces.

virtual double Kitware.VTK.vtkImplicitModeller.GetCapValue ( ) [virtual]

Specify the capping value to use. The CapValue is also used as an initial distance value at each point in the dataset.

Specify the level of the locator to use when using the per voxel process mode.

Set / get the distance away from surface of input geometry to sample. Smaller values make large increases in performance.

Set / get the distance away from surface of input geometry to sample. Smaller values make large increases in performance.

Set / get the distance away from surface of input geometry to sample. Smaller values make large increases in performance.

virtual double [] Kitware.VTK.vtkImplicitModeller.GetModelBounds ( ) [virtual]

Set / get the region in space in which to perform the sampling. If not specified, it will be computed automatically.

virtual void Kitware.VTK.vtkImplicitModeller.GetModelBounds ( IntPtr  data) [virtual]

Set / get the region in space in which to perform the sampling. If not specified, it will be computed automatically.

Set / Get the number of threads used during Per-Voxel processing mode.

Set / Get the number of threads used during Per-Voxel processing mode.

Set / Get the number of threads used during Per-Voxel processing mode.

Set the desired output scalar type.

Specify whether to visit each cell once per append or each voxel once per append. Some tests have shown once per voxel to be faster when there are a lot of cells (at least a thousand?); relative performance improvement increases with addition cells. Primitives should not be stripped for best performance of the voxel mode.

Specify whether to visit each cell once per append or each voxel once per append. Some tests have shown once per voxel to be faster when there are a lot of cells (at least a thousand?); relative performance improvement increases with addition cells. Primitives should not be stripped for best performance of the voxel mode.

Specify whether to visit each cell once per append or each voxel once per append. Some tests have shown once per voxel to be faster when there are a lot of cells (at least a thousand?); relative performance improvement increases with addition cells. Primitives should not be stripped for best performance of the voxel mode.

Specify whether to visit each cell once per append or each voxel once per append. Some tests have shown once per voxel to be faster when there are a lot of cells (at least a thousand?); relative performance improvement increases with addition cells. Primitives should not be stripped for best performance of the voxel mode.

Set/Get the i-j-k dimensions on which to sample distance function.

virtual void Kitware.VTK.vtkImplicitModeller.GetSampleDimensions ( IntPtr  data) [virtual]

Set/Get the i-j-k dimensions on which to sample distance function.

If a non-floating output type is specified, the output distances can be scaled to use the entire positive scalar range of the output type specified (up to the CapValue which is equal to the max for the type unless modified by the user). For example, if ScaleToMaximumDistance is On and the OutputScalarType is UnsignedChar the distances saved in the output would be linearly scaled between 0 (for distances "very close" to the surface) and 255 (at the specifed maximum distance)... assuming the CapValue is not changed from 255.

override int Kitware.VTK.vtkImplicitModeller.IsA ( string  type) [virtual]

Undocumented Block.

Reimplemented from Kitware.VTK.vtkImageAlgorithm.

static new int Kitware.VTK.vtkImplicitModeller.IsTypeOf ( string  type) [static]

Undocumented Block.

Reimplemented from Kitware.VTK.vtkImageAlgorithm.

Construct with sample dimensions=(50,50,50), and so that model bounds are automatically computed from the input. Capping is turned on with CapValue equal to a large positive number.

Reimplemented from Kitware.VTK.vtkAlgorithm.

Undocumented Block.

Reimplemented from Kitware.VTK.vtkImageAlgorithm.

Undocumented Block.

Reimplemented from Kitware.VTK.vtkImageAlgorithm.

Here is the call graph for this function:

If a non-floating output type is specified, the output distances can be scaled to use the entire positive scalar range of the output type specified (up to the CapValue which is equal to the max for the type unless modified by the user). For example, if ScaleToMaximumDistance is On and the OutputScalarType is UnsignedChar the distances saved in the output would be linearly scaled between 0 (for distances "very close" to the surface) and 255 (at the specifed maximum distance)... assuming the CapValue is not changed from 255.

If a non-floating output type is specified, the output distances can be scaled to use the entire positive scalar range of the output type specified (up to the CapValue which is equal to the max for the type unless modified by the user). For example, if ScaleToMaximumDistance is On and the OutputScalarType is UnsignedChar the distances saved in the output would be linearly scaled between 0 (for distances "very close" to the surface) and 255 (at the specifed maximum distance)... assuming the CapValue is not changed from 255.

virtual void Kitware.VTK.vtkImplicitModeller.SetAdjustBounds ( int  _arg) [virtual]

Control how the model bounds are computed. If the ivar AdjustBounds is set, then the bounds specified (or computed automatically) is modified by the fraction given by AdjustDistance. This means that the model bounds is expanded in each of the x-y-z directions.

virtual void Kitware.VTK.vtkImplicitModeller.SetAdjustDistance ( double  _arg) [virtual]

Specify the amount to grow the model bounds (if the ivar AdjustBounds is set). The value is a fraction of the maximum length of the sides of the box specified by the model bounds.

virtual void Kitware.VTK.vtkImplicitModeller.SetCapping ( int  _arg) [virtual]

The outer boundary of the structured point set can be assigned a particular value. This can be used to close or "cap" all surfaces.

Specify the capping value to use. The CapValue is also used as an initial distance value at each point in the dataset.

virtual void Kitware.VTK.vtkImplicitModeller.SetLocatorMaxLevel ( int  _arg) [virtual]

Specify the level of the locator to use when using the per voxel process mode.

virtual void Kitware.VTK.vtkImplicitModeller.SetMaximumDistance ( double  _arg) [virtual]

Set / get the distance away from surface of input geometry to sample. Smaller values make large increases in performance.

virtual void Kitware.VTK.vtkImplicitModeller.SetModelBounds ( double  _arg1,
double  _arg2,
double  _arg3,
double  _arg4,
double  _arg5,
double  _arg6 
) [virtual]

Set / get the region in space in which to perform the sampling. If not specified, it will be computed automatically.

virtual void Kitware.VTK.vtkImplicitModeller.SetModelBounds ( IntPtr  _arg) [virtual]

Set / get the region in space in which to perform the sampling. If not specified, it will be computed automatically.

virtual void Kitware.VTK.vtkImplicitModeller.SetNumberOfThreads ( int  _arg) [virtual]

Set / Get the number of threads used during Per-Voxel processing mode.

Set the desired output scalar type.

Set the desired output scalar type.

Set the desired output scalar type.

Set the desired output scalar type.

Set the desired output scalar type.

Set the desired output scalar type.

Set the desired output scalar type.

Set the desired output scalar type.

Set the desired output scalar type.

Set the desired output scalar type.

Set the desired output scalar type.

virtual void Kitware.VTK.vtkImplicitModeller.SetProcessMode ( int  _arg) [virtual]

Specify whether to visit each cell once per append or each voxel once per append. Some tests have shown once per voxel to be faster when there are a lot of cells (at least a thousand?); relative performance improvement increases with addition cells. Primitives should not be stripped for best performance of the voxel mode.

Specify whether to visit each cell once per append or each voxel once per append. Some tests have shown once per voxel to be faster when there are a lot of cells (at least a thousand?); relative performance improvement increases with addition cells. Primitives should not be stripped for best performance of the voxel mode.

Specify whether to visit each cell once per append or each voxel once per append. Some tests have shown once per voxel to be faster when there are a lot of cells (at least a thousand?); relative performance improvement increases with addition cells. Primitives should not be stripped for best performance of the voxel mode.

void Kitware.VTK.vtkImplicitModeller.SetSampleDimensions ( int  i,
int  j,
int  k 
)

Set/Get the i-j-k dimensions on which to sample distance function.

Set/Get the i-j-k dimensions on which to sample distance function.

virtual void Kitware.VTK.vtkImplicitModeller.SetScaleToMaximumDistance ( int  _arg) [virtual]

If a non-floating output type is specified, the output distances can be scaled to use the entire positive scalar range of the output type specified (up to the CapValue which is equal to the max for the type unless modified by the user). For example, if ScaleToMaximumDistance is On and the OutputScalarType is UnsignedChar the distances saved in the output would be linearly scaled between 0 (for distances "very close" to the surface) and 255 (at the specifed maximum distance)... assuming the CapValue is not changed from 255.

Initialize the filter for appending data. You must invoke the StartAppend() method before doing successive Appends(). It's also a good idea to manually specify the model bounds; otherwise the input bounds for the data will be used.

static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_AdjustBoundsOff_01 ( HandleRef  pThis) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_AdjustBoundsOn_02 ( HandleRef  pThis) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_Append_03 ( HandleRef  pThis,
HandleRef  input 
) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_CappingOff_04 ( HandleRef  pThis) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_CappingOn_05 ( HandleRef  pThis) [private]
static internal double Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_ComputeModelBounds_06 ( HandleRef  pThis,
HandleRef  input 
) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_EndAppend_07 ( HandleRef  pThis) [private]
static internal int Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_GetAdjustBounds_08 ( HandleRef  pThis) [private]
static internal double Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_GetAdjustDistance_09 ( HandleRef  pThis) [private]
static internal double Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_GetAdjustDistanceMaxValue_10 ( HandleRef  pThis) [private]
static internal double Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_GetAdjustDistanceMinValue_11 ( HandleRef  pThis) [private]
static internal int Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_GetCapping_13 ( HandleRef  pThis) [private]
static internal double Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_GetCapValue_12 ( HandleRef  pThis) [private]
static internal int Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_GetLocatorMaxLevel_14 ( HandleRef  pThis) [private]
static internal double Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_GetMaximumDistance_15 ( HandleRef  pThis) [private]
static internal double Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_GetMaximumDistanceMaxValue_16 ( HandleRef  pThis) [private]
static internal double Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_GetMaximumDistanceMinValue_17 ( HandleRef  pThis) [private]
static internal IntPtr Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_GetModelBounds_18 ( HandleRef  pThis) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_GetModelBounds_19 ( HandleRef  pThis,
IntPtr  data 
) [private]
static internal int Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_GetNumberOfThreads_20 ( HandleRef  pThis) [private]
static internal int Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_GetOutputScalarType_23 ( HandleRef  pThis) [private]
static internal int Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_GetProcessMode_24 ( HandleRef  pThis) [private]
static internal IntPtr Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_GetProcessModeAsString_25 ( HandleRef  pThis) [private]
static internal int Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_GetProcessModeMaxValue_26 ( HandleRef  pThis) [private]
static internal int Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_GetProcessModeMinValue_27 ( HandleRef  pThis) [private]
static internal IntPtr Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_GetSampleDimensions_28 ( HandleRef  pThis) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_GetSampleDimensions_29 ( HandleRef  pThis,
IntPtr  data 
) [private]
static internal int Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_IsA_31 ( HandleRef  pThis,
string  type 
) [private]
static internal int Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_IsTypeOf_32 ( string  type) [private]
static internal IntPtr Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_New ( ref uint  mteStatus,
ref uint  mteIndex,
ref uint  rawRefCount 
) [private]
static internal IntPtr Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_NewInstance_34 ( HandleRef  pThis,
ref uint  mteStatus,
ref uint  mteIndex,
ref uint  rawRefCount 
) [private]
static internal IntPtr Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_SafeDownCast_35 ( HandleRef  o,
ref uint  mteStatus,
ref uint  mteIndex,
ref uint  rawRefCount 
) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_ScaleToMaximumDistanceOff_36 ( HandleRef  pThis) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_ScaleToMaximumDistanceOn_37 ( HandleRef  pThis) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_SetAdjustBounds_38 ( HandleRef  pThis,
int  _arg 
) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_SetAdjustDistance_39 ( HandleRef  pThis,
double  _arg 
) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_SetCapping_41 ( HandleRef  pThis,
int  _arg 
) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_SetCapValue_40 ( HandleRef  pThis,
double  value 
) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_SetLocatorMaxLevel_42 ( HandleRef  pThis,
int  _arg 
) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_SetMaximumDistance_43 ( HandleRef  pThis,
double  _arg 
) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_SetModelBounds_44 ( HandleRef  pThis,
double  _arg1,
double  _arg2,
double  _arg3,
double  _arg4,
double  _arg5,
double  _arg6 
) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_SetModelBounds_45 ( HandleRef  pThis,
IntPtr  _arg 
) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_SetNumberOfThreads_46 ( HandleRef  pThis,
int  _arg 
) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_SetOutputScalarType_47 ( HandleRef  pThis,
int  type 
) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_SetOutputScalarTypeToChar_48 ( HandleRef  pThis) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_SetOutputScalarTypeToFloat_50 ( HandleRef  pThis) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_SetOutputScalarTypeToInt_51 ( HandleRef  pThis) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_SetOutputScalarTypeToLong_52 ( HandleRef  pThis) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_SetOutputScalarTypeToShort_53 ( HandleRef  pThis) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_SetProcessMode_58 ( HandleRef  pThis,
int  _arg 
) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_SetProcessModeToPerCell_59 ( HandleRef  pThis) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_SetProcessModeToPerVoxel_60 ( HandleRef  pThis) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_SetSampleDimensions_61 ( HandleRef  pThis,
int  i,
int  j,
int  k 
) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_SetSampleDimensions_62 ( HandleRef  pThis,
IntPtr  dim 
) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_SetScaleToMaximumDistance_63 ( HandleRef  pThis,
int  _arg 
) [private]
static internal void Kitware.VTK.vtkImplicitModeller.vtkImplicitModeller_StartAppend_64 ( HandleRef  pThis) [private]

Member Data Documentation

new readonly string Kitware.VTK.vtkImplicitModeller.MRClassNameKey = "19vtkImplicitModeller" [static]

Automatically generated type registration mechanics.

Reimplemented from Kitware.VTK.vtkImageAlgorithm.

new const string Kitware.VTK.vtkImplicitModeller.MRFullTypeName = "Kitware.VTK.vtkImplicitModeller"

Automatically generated type registration mechanics.

Reimplemented from Kitware.VTK.vtkImageAlgorithm.


The documentation for this class was generated from the following file: