#include <itkFastMarchingExtensionImageFilter.h>
Inheritance diagram for itk::FastMarchingExtensionImageFilter< TLevelSet, TAuxValue, VAuxDimension, TSpeedImage >:
Fast marching can be used to extend auxiliary variables smoothly from the zero level set. Starting from an initial position on the front, this class simultaneously calculate the signed distance and extend a set of auxiliary values.
This class is templated over the level set image type, the auxiliary variable type and the number of auxiliary variables to extended. The initial front is specified by two containers: one containing the known points and one containing the trial points. The auxiliary variables on the front are represented by two auxiliary variable containers: one containing the value of the variables at the know points and on containing the value of the variables at the trail points.
Implemenation of this class is based on Chapter 11 of "Level Set Methods and Fast Marching Methods", J.A. Sethian, Cambridge Press, Second edition, 1999.
Definition at line 58 of file itkFastMarchingExtensionImageFilter.h.
Public Types | |
| typedef AuxVarType::AuxImagePointer | AuxImagePointer |
| typedef AuxVarType::AuxImageType | AuxImageType |
| typedef AuxVarType::AuxValueContainer | AuxValueContainer |
| typedef AuxVarType::AuxValueType | AuxValueType |
| typedef AuxVarType::AuxValueVectorType | AuxValueVectorType |
| typedef SmartPointer< const Self > | ConstPointer |
| typedef DataObject::Pointer | DataObjectPointer |
| typedef std::vector< DataObjectPointer > | DataObjectPointerArray |
| typedef Index< itkGetStaticConstMacro(SetDimension) | IndexType ) |
| typedef InputImageType::ConstPointer | InputImageConstPointer |
| typedef InputImageType::PixelType | InputImagePixelType |
| typedef InputImageType::Pointer | InputImagePointer |
| typedef InputImageType::RegionType | InputImageRegionType |
| typedef TSpeedImage | InputImageType |
| typedef LabelImageType::Pointer | LabelImagePointer |
| typedef Image< unsigned char, itkGetStaticConstMacro(SetDimension) | LabelImageType ) |
| enum | LabelType { FarPoint, AlivePoint, TrialPoint } |
| typedef Superclass::LevelSetImageType | LevelSetImageType |
| typedef LevelSetType::LevelSetPointer | LevelSetPointer |
| typedef Superclass::LevelSetType | LevelSetType |
| typedef LevelSetType::NodeContainer | NodeContainer |
| typedef LevelSetType::NodeContainerPointer | NodeContainerPointer |
| typedef LevelSetType::NodeType | NodeType |
| typedef OutputImageType::PixelType | OutputImagePixelType |
| typedef OutputImageType::Pointer | OutputImagePointer |
| typedef Superclass::OutputImageRegionType | OutputImageRegionType |
| typedef TLevelSet | OutputImageType |
| typedef LevelSetImageType::PointType | OutputPointType |
| typedef LevelSetImageType::RegionType | OutputRegionType |
| typedef LevelSetImageType::SizeType | OutputSizeType |
| typedef LevelSetImageType::SpacingType | OutputSpacingType |
| typedef LevelSetType::PixelType | PixelType |
| typedef SmartPointer< Self > | Pointer |
| typedef FastMarchingExtensionImageFilter | Self |
| typedef SpeedImageType::ConstPointer | SpeedImageConstPointer |
| typedef SpeedImageType::Pointer | SpeedImagePointer |
| typedef Superclass::SpeedImageType | SpeedImageType |
| typedef FastMarchingImageFilter< TLevelSet, TSpeedImage > | Superclass |
Public Member Functions | |
| virtual void | AbortGenerateDataOff () |
| virtual void | AbortGenerateDataOn () |
| virtual void | CollectPointsOff () |
| virtual void | CollectPointsOn () |
| virtual LightObject::Pointer | CreateAnother () const |
| virtual void | DebugOff () const |
| virtual void | DebugOn () const |
| virtual void | Delete () |
| virtual const bool & | GetAbortGenerateData () |
| NodeContainerPointer | GetAlivePoints () |
| AuxValueContainer * | GetAuxiliaryAliveValues (void) |
| AuxImageType * | GetAuxiliaryImage (unsigned int idx) |
| AuxValueContainer::Pointer | GetAuxiliaryTrialValues () |
| Get thConste Collect Points flag *virtual const bool & | GetCollectPoints () |
| Command * | GetCommand (unsigned long tag) |
| bool | GetDebug () const |
| const InputImageType * | GetInput (unsigned int idx) |
| const InputImageType * | GetInput (void) |
| DataObjectPointerArray & | GetInputs () |
| LabelImagePointer | GetLabelImage () const |
| const MetaDataDictionary & | GetMetaDataDictionary (void) const |
| MetaDataDictionary & | GetMetaDataDictionary (void) |
| virtual unsigned long | GetMTime () const |
| MultiThreader * | GetMultiThreader () |
| virtual const char * | GetNameOfClass () const |
| virtual double | GetNormalizationFactor () |
| std::vector< DataObjectPointer >::size_type | GetNumberOfInputs () const |
| std::vector< DataObjectPointer >::size_type | GetNumberOfOutputs () const |
| virtual const int & | GetNumberOfThreads () |
| virtual std::vector< DataObjectPointer >::size_type | GetNumberOfValidRequiredInputs () const |
| OutputImageType * | GetOutput (unsigned int idx) |
| Get the output data of this process object The output of this *function is not valid until an appropriate either explicitly or implicitly Both the filter *itself and the data object have and both *methods update the data Here are three ways to use * | GetOutput () and make sure the data is valid.In these *examples |
| virtual const OutputPointType & | GetOutputOrigin () |
| virtual const OutputRegionType & | GetOutputRegion () |
| Return an array with all the outputs of this process object *This is useful for tracing forward in the pipeline to contruct *graphs etc *DataObjectPointerArray & | GetOutputs () |
| virtual OutputSizeType | GetOutputSize () const |
| virtual const OutputSpacingType & | GetOutputSpacing () |
| virtual const bool & | GetOverrideOutputInformation () |
| NodeContainerPointer | GetProcessedPoints () const |
| virtual const float & | GetProgress () |
| virtual int | GetReferenceCount () const |
| virtual const bool & | GetReleaseDataBeforeUpdateFlag () |
| virtual bool | GetReleaseDataFlag () const |
| virtual const double & | GetSpeedConstant () |
| virtual const double & | GetStoppingValue () |
| NodeContainerPointer | GetTrialPoints () |
| virtual void | GraftNthOutput (unsigned int idx, DataObject *output) |
| virtual void | GraftOutput (DataObject *output) |
| bool | HasObserver (const EventObject &event) const |
| Get the output data of this process object The output of this *function is not valid until an appropriate either explicitly or implicitly Both the filter *itself and the data object have and both *methods update the data Here are three ways to use *a image is a pointer to some Image and the *particular ProcessObjects involved are filters The same *examples apply to non | image (e.g.Mesh) data as well.**\code *anotherFilter->SetInput(someFilter->GetOutput()) |
| void | InvokeEvent (const EventObject &) const |
| void | InvokeEvent (const EventObject &) |
| itkStaticConstMacro (OutputImageDimension, unsigned int, TLevelSet::ImageDimension) | |
| ImageDimension constants * | itkStaticConstMacro (InputImageDimension, unsigned int, TSpeedImage::ImageDimension) |
| itkStaticConstMacro (SpeedImageDimension, unsigned int, SpeedImageType::ImageDimension) | |
| Dimension of the level set and the speed image * | itkStaticConstMacro (SetDimension, unsigned int, LevelSetType::SetDimension) |
| itkStaticConstMacro (AuxDimension, unsigned int, VAuxDimension) | |
| itkStaticConstMacro (SetDimension, unsigned int, Superclass::SetDimension) | |
| virtual DataObjectPointer | MakeOutput (unsigned int idx) |
| virtual void | Modified () const |
| virtual void | OverrideOutputInformationOff () |
| virtual void | OverrideOutputInformationOn () |
| virtual void | PopBackInput () |
| virtual void | PopFrontInput () |
| virtual void | PrepareOutputs () |
| void | Print (std::ostream &os, Indent indent=0) const |
| virtual void | PropagateRequestedRegion (DataObject *output) |
| Push Pop the input of this process object These methods allow a *filter to model its input vector as a queue or stack These *routines may not be appropriate for all especially *filters with different types of inputs These routines follow *the semantics of STL **The routines are useful for applications that need to process *rolling sets of images For if an application has *images and they need to run a filter on then *run the filter on then run the filter on the application can accomplish this by popping *an input off the front of the input list and push a new image *onto the back of input list this only makes sense for *filters that single type of input **Other uses are also possible For a single input pushing *and popping inputs allow the application to temporarily replace *an input to a filter **virtual void | PushBackInput (const InputImageType *image) |
| virtual void | PushFrontInput (const InputImageType *image) |
| virtual void | Register () const |
| virtual void | ReleaseDataBeforeUpdateFlagOff () |
| virtual void | ReleaseDataBeforeUpdateFlagOn () |
| void | ReleaseDataFlagOff () |
| void | ReleaseDataFlagOn () |
| void | RemoveAllObservers () |
| void | RemoveObserver (unsigned long tag) |
| virtual void | ResetPipeline () |
| virtual void | SetAbortGenerateData (bool _arg) |
| Set the container of Alive Points representing the initial front *Alive points are represented as a VectorContainer of LevelSetNodes *void | SetAlivePoints (NodeContainer *points) |
| void | SetAuxiliaryAliveValues (AuxValueContainer *values) |
| void | SetAuxiliaryTrialValues (AuxValueContainer *values) |
| virtual void | SetCollectPoints (bool _arg) |
| void | SetDebug (bool debugFlag) const |
| virtual void | SetInput (unsigned int, const TSpeedImage *image) |
| Set Get the image input of this process object *virtual void | SetInput (const InputImageType *image) |
| void | SetMetaDataDictionary (const MetaDataDictionary &rhs) |
| Set Get the Normalization Factor for the Speed Image The values in the Speed Image is divided by this factor This allows the use of images with integer pixel types to represent the speed *virtual void | SetNormalizationFactor (double _arg) |
| Get Set the number of threads to create when executing *virtual void | SetNumberOfThreads (int _arg) |
| virtual void | SetOutputOrigin (OutputPointType _arg) |
| virtual void | SetOutputRegion (OutputRegionType _arg) |
| virtual void | SetOutputSpacing (OutputSpacingType _arg) |
| virtual void | SetOverrideOutputInformation (bool _arg) |
| virtual void | SetProgress (float _arg) |
| virtual void | SetReferenceCount (int) |
| Turn on off the flags to control whether the bulk data belonging *to the outputs of this ProcessObject are released after being *used by a downstream ProcessObject Default value is off Another *options for controlling memory utilization is the *ReleaseDataBeforeUpdateFlag *virtual void | SetReleaseDataFlag (bool flag) |
| Set the Speed Constant If the Speed Image is *the SpeedConstant value is used for the whole level set *By the SpeedConstant is set to *void | SetSpeedConstant (double value) |
| virtual void | SetStoppingValue (double _arg) |
| Set the container of Trial Points representing the initial front *Trial points are represented as a VectorContainer of LevelSetNodes *void | SetTrialPoints (NodeContainer *points) |
| virtual void | UnRegister () const |
| *endcode *In the above the two lines of code can be in *either order **Note that it may be more efficient to *use a pipeline than to call | Update () once for each filter in *turn.**For an image |
| *endcode *In the above the two lines of code can be in *either order **Note that | Update () is not called automatically except within a *pipeline as in the first example.When\b streaming(using a *StreamingImageFilter) is activated |
| *endcode **code *someFilter | Update () |
| *image | Update () |
| *anotherFilter | Update () |
| Get the output data of this process object The output of this *function is not valid until an appropriate either explicitly or implicitly Both the filter *itself and the data object have | Update () methods |
| Get the output data of this process object The output of this *function is not valid until an appropriate | Update () method has *been called |
| virtual void | UpdateLargestPossibleRegion () |
| virtual void | UpdateOutputData (DataObject *output) |
| virtual void | UpdateOutputInformation () |
| void | UpdateProgress (float amount) |
Static Public Member Functions | |
| static void | BreakOnError () |
| static bool | GetGlobalWarningDisplay () |
| static void | GlobalWarningDisplayOff () |
| static void | GlobalWarningDisplayOn () |
| static Pointer | New () |
| This is a global flag that controls whether any warning *or error messages are displayed *static void | SetGlobalWarningDisplay (bool flag) |
Public Attributes | |
| Allow people to add remove invoke observers(callbacks) to any ITK *object.This is an implementation of the subject/observer design *pattern.An observer is added by specifying an event to respond to *and an itk unsigned lon | AddObserver )(const EventObject &event, Command *) const |
| Push Pop the input of this process object These methods allow a *filter to model its input vector as a queue or stack These *routines may not be appropriate for all especially *filters with different types of inputs These routines follow *the semantics of STL **The routines are useful for applications that need to process *rolling sets of images For if an application has *images and they need to run a filter on then *run the filter on then run the filter on the application can accomplish this by popping *an input off the front of the input list and push a new image *onto the back of input list | Again |
| AuxVarType typedef support *typedef AuxVarTypeDefault< TAuxValue, itkGetStaticConstMacro(AuxDimension), itkGetStaticConstMacro(SetDimension) | AuxVarType ) |
| This is a global flag that controls whether any | debug |
| Set the Speed Constant If the Speed Image is *the SpeedConstant value is used for the whole level set *By | default |
| *endcode *In the above | example |
| Push Pop the input of this process object These methods allow a *filter to model its input vector as a queue or stack These *routines may not be appropriate for all especially *filters with different types of inputs These routines follow *the semantics of STL **The routines are useful for applications that need to process *rolling sets of images For if an application has *images and they need to run a filter on then *run the filter on then run the filter on the application can accomplish this by popping *an input off the front of the input list and push a new image *onto the back of input list this only makes sense for *filters that single type of input **Other uses are also possible For a single input | filter |
| Push Pop the input of this process object These methods allow a *filter to model its input vector as a queue or stack These *routines may not be appropriate for all | filters |
| * | image |
| *endcode **In this a someFilter and a anotherFilter are said *to constitute a b pipeline **code * | image |
| Push Pop the input of this process object These methods allow a *filter to model its input vector as a queue or stack These *routines may not be appropriate for all especially *filters with different types of inputs These routines follow *the semantics of STL **The routines are useful for applications that need to process *rolling sets of images For if an application has *images and they need to run a filter on then *run the filter on then run the filter on * | images |
| Push Pop the input of this process object These methods allow a *filter to model its input vector as a queue or stack These *routines may not be appropriate for all especially *filters with different types of inputs These routines follow *the semantics of STL **The routines are useful for applications that need to process *rolling sets of images For if an application has *images and they need to run a filter on then *run the filter on | images |
| Push Pop the input of this process object These methods allow a *filter to model its input vector as a queue or stack These *routines may not be appropriate for all especially *filters with different types of inputs These routines follow *the semantics of STL **The routines are useful for applications that need to process *rolling sets of images For if an application has *images and they need to run a filter on | images |
| Push Pop the input of this process object These methods allow a *filter to model its input vector as a queue or stack These *routines may not be appropriate for all especially *filters with different types of inputs These routines follow *the semantics of STL **The routines are useful for applications that need to process *rolling sets of images For | instance |
| Set the Speed Constant If the Speed Image is | NULL |
| Get the output data of this process object The output of this *function is not valid until an appropriate either explicitly or implicitly Both the filter *itself and the data object have and both *methods update the data Here are three ways to use *a image is a pointer to some Image | object |
| The output largeset | possible |
| *endcode *In the above the two lines of code can be in *either order **Note that it may be more efficient to *use a pipeline than to call the data generated is for the requested * | Region |
| *endcode **In this | situation |
| The output largeset spacing and origin is computed as follows *If the speed image is NULL or if the OverrideOutputInformation is | true |
Protected Types | |
| typedef ImageToImageFilterDetail::ImageRegionCopier< itkGetStaticConstMacro(OutputImageDimension), itkGetStaticConstMacro(InputImageDimension) | InputToOutputRegionCopierType ) |
| typedef LevelSetImageType::IndexType | LevelSetIndexType |
| typedef ImageToImageFilterDetail::ImageRegionCopier< itkGetStaticConstMacro(InputImageDimension), itkGetStaticConstMacro(OutputImageDimension) | OutputToInputRegionCopierType ) |
Protected Member Functions | |
| virtual void | AddInput (DataObject *input) |
| virtual void | AddOutput (DataObject *output) |
| virtual void | AfterThreadedGenerateData () |
| virtual void | AllocateOutputs () |
| virtual void | BeforeThreadedGenerateData () |
| virtual void | CacheInputReleaseDataFlags () |
| virtual void | CallCopyInputRegionToOutputRegion (OutputImageRegionType &destRegion, const InputImageRegionType &srcRegion) |
| virtual void | CallCopyOutputRegionToInputRegion (InputImageRegionType &destRegion, const OutputImageRegionType &srcRegion) |
| virtual void | EnlargeOutputRequestedRegion (DataObject *output) |
| FastMarchingExtensionImageFilter () | |
| void | GenerateData () |
| virtual void | GenerateInputRequestedRegion () |
| Generate the output image meta information *virtual void | GenerateOutputInformation () |
| virtual void | GenerateOutputRequestedRegion (DataObject *output) |
| const DataObject * | GetInput (unsigned int idx) const |
| virtual const PixelType & | GetLargeValue () |
| virtual const LevelSetIndexType & | GetLastIndex () |
| const AxisNodeType & | GetNodeUsedInCalculation (unsigned int idx) const |
| virtual const unsigned int & | GetNumberOfRequiredInputs () |
| virtual const unsigned int & | GetNumberOfRequiredOutputs () |
| const DataObject * | GetOutput (unsigned int idx) const |
| virtual const LevelSetIndexType & | GetStartIndex () |
| ImageSource () | |
| ImageToImageFilter () | |
| virtual void | Initialize (LevelSetImageType *) |
| bool | PrintObservers (std::ostream &os, Indent indent) const |
| void | PrintSelf (std::ostream &os, Indent indent) const |
| virtual void | PrintTrailer (std::ostream &os, Indent indent) const |
| virtual void | PropagateResetPipeline () |
| **these methods end of hiding the versions from the superclass *ProcessObject whose arguments are DataObjects we re expose *the versions from ProcessObject to avoid warnings about hiding *methods from the superclass *void | PushBackInput (const DataObject *input) |
| * | PushBackInput () |
| * | PushFronInput () in the public section force the *input to be the type expected by an ImageToImageFilter.However |
| void | PushFrontInput (const DataObject *input) |
| virtual void | ReleaseInputs () |
| virtual void | RemoveInput (DataObject *input) |
| virtual void | RemoveOutput (DataObject *output) |
| virtual void | RestoreInputReleaseDataFlags () |
| Protected methods for setting inputs *Subclasses make use of them for setting input *virtual void | SetNthInput (unsigned int num, DataObject *input) |
| Protected methods for setting outputs *Subclasses make use of them for getting output *virtual void | SetNthOutput (unsigned int num, DataObject *output) |
| void | SetNumberOfInputs (unsigned int num) |
| void | SetNumberOfOutputs (unsigned int num) |
| virtual void | SetNumberOfRequiredInputs (unsigned int _arg) |
| virtual void | SetNumberOfRequiredOutputs (unsigned int _arg) |
| virtual int | SplitRequestedRegion (int i, int num, OutputImageRegionType &splitRegion) |
| virtual void | ThreadedGenerateData (const OutputImageRegionType &outputRegionForThread, int threadId) |
| virtual void | UpdateNeighbors (const IndexType &index, const SpeedImageType *, LevelSetImageType *) |
| virtual double | UpdateValue (const IndexType &index, const SpeedImageType *speed, LevelSetImageType *output) |
| ~FastMarchingExtensionImageFilter () | |
Static Protected Member Functions | |
| static ITK_THREAD_RETURN_TYPE | ThreaderCallback (void *arg) |
Protected Attributes | |
| **these methods end of hiding the versions from the superclass *ProcessObject whose arguments are DataObjects | Here |
| OutputRegionType | m_BufferedRegion |
| LevelSetIndexType | m_LastIndex |
| TimeStamp | m_OutputInformationMTime |
| int | m_ReferenceCount |
| SimpleFastMutexLock | m_ReferenceCountLock |
| LevelSetIndexType | m_StartIndex |
| bool | m_Updating |
| Methods invoked by virtual Print() to print information about the object *including superclasses.Typically not called by the user(use Print()*instead) but used in the hierarchical print process to combine the *output of several classes.*/virtual void PrintSelf(std voi | PrintHeader )(std::ostream &os, Indent indent) const |
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Definition at line 93 of file itkFastMarchingExtensionImageFilter.h. |
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Definition at line 92 of file itkFastMarchingExtensionImageFilter.h. |
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Definition at line 91 of file itkFastMarchingExtensionImageFilter.h. |
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Definition at line 89 of file itkFastMarchingExtensionImageFilter.h. |
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Definition at line 90 of file itkFastMarchingExtensionImageFilter.h. |
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Reimplemented from itk::FastMarchingImageFilter< TLevelSet, TSpeedImage >. Definition at line 66 of file itkFastMarchingExtensionImageFilter.h. |
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Smart Pointer type to a DataObject. Reimplemented from itk::ProcessObject. Definition at line 62 of file itkImageSource.h. |
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STL Array of SmartPointers to DataObjects Definition at line 103 of file itkProcessObject.h. |
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Index typedef support. Reimplemented from itk::FastMarchingImageFilter< TLevelSet, TSpeedImage >. Definition at line 97 of file itkFastMarchingExtensionImageFilter.h. |
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Definition at line 83 of file itkImageToImageFilter.h. |
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Definition at line 85 of file itkImageToImageFilter.h. |
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Definition at line 82 of file itkImageToImageFilter.h. |
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Definition at line 84 of file itkImageToImageFilter.h. |
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Some convenient typedefs. Definition at line 81 of file itkImageToImageFilter.h. |
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Typedef for the region copier function object that converts an input region to an output region. Definition at line 163 of file itkImageToImageFilter.h. |
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LabelImagePointer typedef support. Definition at line 165 of file itkFastMarchingImageFilter.h. |
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LabelImage typedef support. Reimplemented in itk::FastMarchingUpwindGradientImageFilter< TLevelSet, TSpeedImage >. Definition at line 162 of file itkFastMarchingImageFilter.h. |
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Reimplemented from itk::FastMarchingImageFilter< TLevelSet, TSpeedImage >. Definition at line 77 of file itkFastMarchingExtensionImageFilter.h. |
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Reimplemented in itk::FastMarchingUpwindGradientImageFilter< TLevelSet, TSpeedImage >. Definition at line 310 of file itkFastMarchingImageFilter.h. |
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Reimplemented in itk::FastMarchingUpwindGradientImageFilter< TLevelSet, TSpeedImage >. Definition at line 117 of file itkFastMarchingImageFilter.h. |
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Inherited typedefs. Reimplemented from itk::FastMarchingImageFilter< TLevelSet, TSpeedImage >. Definition at line 72 of file itkFastMarchingExtensionImageFilter.h. |
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Reimplemented in itk::FastMarchingUpwindGradientImageFilter< TLevelSet, TSpeedImage >. Definition at line 120 of file itkFastMarchingImageFilter.h. |
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Reimplemented in itk::FastMarchingUpwindGradientImageFilter< TLevelSet, TSpeedImage >. Definition at line 121 of file itkFastMarchingImageFilter.h. |
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Reimplemented in itk::FastMarchingUpwindGradientImageFilter< TLevelSet, TSpeedImage >. Definition at line 119 of file itkFastMarchingImageFilter.h. |
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Definition at line 71 of file itkImageSource.h. |
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Definition at line 69 of file itkImageSource.h. |
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Superclass typedefs. Reimplemented from itk::ImageSource< TLevelSet >. Definition at line 75 of file itkImageToImageFilter.h. |
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Some convenient typedefs. Definition at line 65 of file itkImageSource.h. |
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Definition at line 125 of file itkFastMarchingImageFilter.h. |
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Definition at line 123 of file itkFastMarchingImageFilter.h. |
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Definition at line 122 of file itkFastMarchingImageFilter.h. |
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Reimplemented in itk::FastMarchingUpwindGradientImageFilter< TLevelSet, TSpeedImage >. Definition at line 124 of file itkFastMarchingImageFilter.h. |
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Typedef for the region copier function object that converts an output region to an input region. Definition at line 168 of file itkImageToImageFilter.h. |
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Reimplemented in itk::FastMarchingUpwindGradientImageFilter< TLevelSet, TSpeedImage >. Definition at line 118 of file itkFastMarchingImageFilter.h. |
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Reimplemented from itk::FastMarchingImageFilter< TLevelSet, TSpeedImage >. Definition at line 65 of file itkFastMarchingExtensionImageFilter.h. |
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Standard class typdedefs. Reimplemented from itk::FastMarchingImageFilter< TLevelSet, TSpeedImage >. Definition at line 63 of file itkFastMarchingExtensionImageFilter.h. |
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Reimplemented in itk::FastMarchingUpwindGradientImageFilter< TLevelSet, TSpeedImage >. Definition at line 143 of file itkFastMarchingImageFilter.h. |
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SpeedImagePointer typedef support. Definition at line 142 of file itkFastMarchingImageFilter.h. |
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SpeedImage typedef support. Reimplemented from itk::FastMarchingImageFilter< TLevelSet, TSpeedImage >. Definition at line 76 of file itkFastMarchingExtensionImageFilter.h. |
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Reimplemented from itk::FastMarchingImageFilter< TLevelSet, TSpeedImage >. Definition at line 64 of file itkFastMarchingExtensionImageFilter.h. |
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Enum of Fast Marching algorithm point types. FarPoints represent far away points; TrialPoints represent points within a narrowband of the propagating front; and AlivePoints represent points which have already been processed. Definition at line 159 of file itkFastMarchingImageFilter.h. |
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Definition at line 128 of file itkFastMarchingExtensionImageFilter.h. |
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Turn on and off the AbortGenerateData flag. |
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If an imaging filter needs to perform processing after all processing threads have completed, the filter can can provide an implementation for AfterThreadedGenerateData(). The execution flow in the default GenerateData() method will be: 1) Allocate the output buffer 2) Call BeforeThreadedGenerateData() 3) Spawn threads, calling ThreadedGenerateData() in each thread. 4) Call AfterThreadedGenerateData() Note that this flow of control is only available if a filter provides a ThreadedGenerateData() method and NOT a GenerateData() method. Definition at line 254 of file itkImageSource.h. |
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The GenerateData method normally allocates the buffers for all of the outputs of a filter. Some filters may want to override this default behavior. For example, a filter may have multiple outputs with varying resolution. Or a filter may want to process data in place by grafting its input to its output. |
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If an imaging filter needs to perform processing after the buffer has been allocated but before threads are spawned, the filter can can provide an implementation for BeforeThreadedGenerateData(). The execution flow in the default GenerateData() method will be: 1) Allocate the output buffer 2) Call BeforeThreadedGenerateData() 3) Spawn threads, calling ThreadedGenerateData() in each thread. 4) Call AfterThreadedGenerateData() Note that this flow of control is only available if a filter provides a ThreadedGenerateData() method and NOT a GenerateData() method. Definition at line 242 of file itkImageSource.h. |
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This method is called when itkExceptionMacro executes. It allows the debugger to break on error. |
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Cache the state of any ReleaseDataFlag's on the inputs. While the filter is executing, we need to set the ReleaseDataFlag's on the inputs to false in case the current filter is implemented using a mini-pipeline (which will try to release the inputs). After the filter finishes, we restore the state of the ReleaseDataFlag's before the call to ReleaseInputs(). |
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This function calls the actual region copier to do the mapping from input image space to output image space. It uses a Function object used for dispatching to various routines to copy an input region (start index and size) to an output region. For most filters, this is a trivial copy because most filters require the input dimension to match the output dimension. However, some filters like itk::UnaryFunctorImageFilter can support output images of a higher dimension that the input. This function object is used by the default implementation of GenerateOutputInformation(). It can also be used in routines like ThreadedGenerateData() where a filter may need to map an input region to an output region. The default copier uses a "dispatch pattern" to call one of three overloaded functions depending on whether the input and output images are the same dimension, the input is a higher dimension that the output, or the input is of a lower dimension than the output. The use of an overloaded function is required for proper compilation of the various cases. For the latter two cases, trivial implementations are used. If the input image is a higher dimension than the output, the first portion of the input region is copied to the output region. If the input region is a lower dimension than the output, the input region information is copied into the first portion of the output region and the rest of the output region is set to zero. If a filter needs a different default behavior, it can override this method. |
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This function calls the actual region copier to do the mapping from output image space to input image space. It uses a Function object used for dispatching to various routines to copy an output region (start index and size) to an input region. For most filters, this is a trivial copy because most filters require the input dimension to match the output dimension. However, some filters like itk::ExtractImageFilter can support output images of a lower dimension that the input. This function object can be used by GenerateOutputInformation() to copy the input LargestPossibleRegion to the output LargestPossibleRegion and can also be used in GenerateData or ThreadedGenerateData() where a filter may need to map an output region to an input region. The default copier uses a "dispatch pattern" to call one of three overloaded functions depending on whether the input and output images are the same dimension, the input is a higher dimension that the output, or the input is of a lower dimension than the output. The use of an overloaded function is required for proper compilation of the various cases. For the latter two cases, trivial implementations are used. If the input image is a higher dimension than the output, the output region information is copied into the first portion of the input region and the rest of the input region is set to zero. If the input region is a lower dimension than the output, the first portion of the output region is copied to the input region. If a filter needs a different default behavior, it can override this method. The ExtractImageFilter overrides this function object so that if the input image is a higher dimension than the output image, the filter can control "where" in the input image the output subimage is extracted (as opposed to mapping to first few dimensions of the input). |
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Create an object from an instance, potentially deferring to a factory. This method allows you to create an instance of an object that is exactly the same type as the referring object. This is useful in cases where an object has been cast back to a base class. Reimplemented from itk::LightObject. |
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Turn debugging output off. |
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Turn debugging output on. |
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Delete an itk object. This method should always be used to delete an object when the new operator was used to create it. Using the C delete method will not work with reference counting. |
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Give the process object a chance to indictate that it will produce more output than it was requested to produce. For example, many imaging filters must compute the entire output at once or can only produce output in complete slices. Such filters cannot handle smaller requested regions. These filters must provide an implementation of this method, setting the output requested region to the size they will produce. By default, a process object does not modify the size of the output requested region. Reimplemented from itk::FastMarchingImageFilter< TLevelSet, TSpeedImage >. |
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A version of GenerateData() specific for image processing filters. This implementation will split the processing across multiple threads. The buffer is allocated by this method. Then the BeforeThreadedGenerateData() method is called (if provided). Then, a series of threads are spawned each calling ThreadedGenerateData(). After all the threads have completed processing, the AfterThreadedGenerateData() method is called (if provided). If an image processing filter cannot be threaded, the filter should provide an implementation of GenerateData(). That implementation is responsible for allocating the output buffer. If a filter an be threaded, it should NOT provide a GenerateData() method but should provide a ThreadedGenerateData() instead.
Reimplemented from itk::ImageSource< TLevelSet >. Reimplemented in itk::FastMarchingUpwindGradientImageFilter< TLevelSet, TSpeedImage >. |
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What is the input requested region that is required to produce the output requested region? The base assumption for image processing filters is that the input requested region can be set to match the output requested region. If a filter requires more input (for instance a filter that uses neighborhoods needs more input than output to avoid introducing artificial boundary conditions) or less input (for instance a magnify filter) will have to override this method. In doing so, it should call its superclass' implementation as its first step. Note that imaging filters operate differently than the classes to this point in the class hierachy. Up till now, the base assumption has been that the largest possible region will be requested of the input. This implementation of GenerateInputRequestedRegion() only processes the inputs that are a subclass of the ImageBase<InputImageDimension>. If an input is another type of DataObject (including an Image of a different dimension), they are skipped by this method. The subclasses of ImageToImageFilter are responsible for providing an implementation of GenerateInputRequestedRegion() when there are multiple inputs of different types.
Reimplemented from itk::ProcessObject. |
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Generate the information decribing the output data. The default implementation of this method will copy information from the input to the output. A filter may override this method if its output will have different information than its input. For instance, a filter that shrinks an image will need to provide an implementation for this method that changes the spacing of the pixels. Such filters should call their superclass' implementation of this method prior to changing the information values they need (i.e. GenerateOutputInformation() should call Superclass::GenerateOutputInformation() prior to changing the information. Reimplemented from itk::FastMarchingImageFilter< TLevelSet, TSpeedImage >. |
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Given one output whose requested region has been set, how should the requested regions for the remaining outputs of the process object be set? By default, all the outputs are set to the same requested region. If a filter needs to produce different requested regions for each output, for instance an image processing filter producing several outputs at different resolutions, then that filter may override this method and set the requested regions appropriatedly. Note that a filter producing multiple outputs of different types is required to override this method. The default implementation can only correctly handle multiple outputs of the same type. Reimplemented in itk::MultiResolutionPyramidImageFilter< TInputImage, TOutputImage >, itk::RecursiveMultiResolutionPyramidImageFilter< TInputImage, TOutputImage >, itk::watershed::BoundaryResolver< TPixelType, TDimension >, itk::watershed::EquivalenceRelabeler< TScalarType, TImageDimension >, itk::watershed::Relabeler< TScalarType, TImageDimension >, itk::watershed::Segmenter< TInputImage >, itk::watershed::SegmentTreeGenerator< TScalarType >, itk::watershed::Relabeler< ScalarType, itkGetStaticConstMacro(ImageDimension)>, and itk::watershed::SegmentTreeGenerator< ScalarType >. |
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Get the AbortGenerateData flag for the process object. Process objects may handle premature termination of execution in different ways. |
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Get the container of Alive Points representing the initial front. Definition at line 177 of file itkFastMarchingImageFilter.h. |
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Get the container of auxiliary values at the initial alive points. Definition at line 107 of file itkFastMarchingExtensionImageFilter.h. |
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Get one of the extended auxiliary variable image. |
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Get the container of auxiliary values at the initial trial points. Definition at line 115 of file itkFastMarchingExtensionImageFilter.h. |
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Get the command associated with the given tag. NOTE: This returns a pointer to a Command, but it is safe to asign this to a Command::Pointer. Since Command inherits from LightObject, at this point in the code, only a pointer or a reference to the Command can be used. |
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Get the value of the debug flag. |
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Reimplemented from itk::ProcessObject. |
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Return an array with all the inputs of this process object. This is useful for tracing back in the pipeline to construct graphs etc. Definition at line 108 of file itkProcessObject.h. |
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Get the point type label image. Definition at line 194 of file itkFastMarchingImageFilter.h. |
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Get Large Value. This value is used to represent the concept of infinity for the time assigned to pixels that have not been visited. This value is set by default to half the max() of the pixel type used to represent the time-crossing map. |
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Return the multithreader used by this class. Definition at line 281 of file itkProcessObject.h. |
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Run-time type information (and related methods). Reimplemented from itk::FastMarchingImageFilter< TLevelSet, TSpeedImage >. |
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Definition at line 293 of file itkFastMarchingImageFilter.h. |
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Get the size of the input vector. This is merely the size of the input vector, not the number of inputs that have valid DataObject's assigned. Use GetNumberOfValidRequiredInputs() to determine how many inputs are non-null. Definition at line 115 of file itkProcessObject.h. |
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Definition at line 132 of file itkProcessObject.h. |
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Get the number of valid inputs. This is the number of non-null entries in the input vector in the first NumberOfRequiredInputs slots. This method is used to determine whether the necessary required inputs have been set. Subclasses of ProcessObject may override this implementation if the required inputs are not the first slots in input vector. Reimplemented in itk::MultiResolutionPDEDeformableRegistration< TFixedImage, TMovingImage, TDeformationField >, and itk::PDEDeformableRegistrationFilter< TFixedImage, TMovingImage, TDeformationField >. |
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Reimplemented from itk::ProcessObject. |
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Definition at line 130 of file itkProcessObject.h. |
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Definition at line 254 of file itkFastMarchingImageFilter.h. |
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Get the container of Processed Points. If the CollectPoints flag is set, the algorithm collects a container of all processed nodes. This is useful for defining creating Narrowbands for level set algorithms that supports narrow banding. Definition at line 242 of file itkFastMarchingImageFilter.h. |
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Get the execution progress of a process object. The progress is a floating number in [0,1] with 0 meaning no progress and 1 meaning the filter has completed execution. |
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Gets the reference count on this object. Definition at line 98 of file itkLightObject.h. |
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Get the Speed Constant. |
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Get the Fast Marching algorithm Stopping Value. |
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Get the container of Trial Points representing the initial front. Definition at line 190 of file itkFastMarchingImageFilter.h. |
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Definition at line 100 of file itkObject.h. References itk::Object::SetGlobalWarningDisplay(). |
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Definition at line 98 of file itkObject.h. References itk::Object::SetGlobalWarningDisplay(). |
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Graft the specified data object onto this ProcessObject's idx'th output. This is the similar to GraftOutput method except is allows you specify which output is affected. The specified index must be a valid output number (less than ProcessObject::GetNumberOfOutputs()). See the GraftOutput for general usage information. |
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Graft the specified DataObject onto this ProcessObject's output. This method grabs a handle to the specified DataObject's bulk data to used as its output's own bulk data. It also copies the region ivars (RequestedRegion, BufferedRegion, LargestPossibleRegion) and meta-data (Spacing, Origin) from the specified data object into this filter's output data object. Most importantly, however, it leaves the Source ivar untouched so the original pipeline routing is intact. This method is used when a process object is implemented using a mini-pipeline which is defined in its GenerateData() method. The usage is:
// setup the mini-pipeline to process the input to this filter firstFilterInMiniPipeline->SetInput( this->GetInput() ); // setup the mini-pipeline to calculate the correct regions // and write to the appropriate bulk data block lastFilterInMiniPipeline->GraftOutput( this->GetOutput() ); // execute the mini-pipeline lastFilterInMiniPipeline->Update(); // graft the mini-pipeline output back onto this filter's output. // this is needed to get the appropriate regions passed back. this->GraftOutput( lastFilterInMiniPipeline->GetOutput() ); For proper pipeline execution, a filter using a mini-pipeline must implement the GenerateInputRequestedRegion(), GenerateOutputRequestedRegion(), GenerateOutputInformation() and EnlargeOutputRequestedRegion() methods as necessary to reflect how the mini-pipeline will execute (in other words, the outer filter's pipeline mechanism must be consistent with what the mini-pipeline will do). |
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Return true if an observer is registered for this event. |
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Reimplemented from itk::FastMarchingImageFilter< TLevelSet, TSpeedImage >. |
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Call Execute on all the Commands observing this event id. The actions triggered by this call doesn't modify this object. |
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Call Execute on all the Commands observing this event id. |
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Number of auxiliary variables to be extended. |
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The dimension of the level set. |
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Make a DataObject of the correct type to used as the specified output. Every ProcessObject subclass must be able to create a DataObject that can be used as a specified output. This method is automatically called when DataObject::DisconnectPipeline() is called. DataObject::DisconnectPipeline, disconnects a data object from being an output of its current source. When the data object is disconnected, the ProcessObject needs to construct a replacement output data object so that the ProcessObject is in a valid state. So DataObject::DisconnectPipeline eventually calls ProcessObject::MakeOutput. Note that MakeOutput always returns a SmartPointer to a DataObject. If a subclass of ImageSource has multiple outputs of different types, then that class must provide an implementation of MakeOutput(). Reimplemented from itk::ProcessObject. |
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Method for creation through the object factory. Reimplemented from itk::FastMarchingImageFilter< TLevelSet, TSpeedImage >. |
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Reimplemented from itk::ProcessObject. |
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Reimplemented from itk::ProcessObject. |
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An opportunity to deallocate a ProcessObject's bulk data storage. Some filters may wish to reuse existing bulk data storage to avoid unnecessary deallocation/allocation sequences. The default implementation calls Initialize() on each output. DataObject::Initialize() frees its bulk data by default. Reimplemented in itk::WatershedImageFilter< TInputImage >. |
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Cause the object to print itself out. |
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Methods invoked by Print() to print information about the object including superclasses. Typically not called by the user (use Print() instead) but used in the hierarchical print process to combine the output of several classes. Reimplemented from itk::FastMarchingImageFilter< TLevelSet, TSpeedImage >. |
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Send the requested region information back up the pipeline (to the filters that preceed this one). Reimplemented in itk::VTKImageImport< TOutputImage >. |
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Propagate a call to ResetPipeline() up the pipeline. Called only from DataObject. |
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Reimplemented from itk::ProcessObject. Definition at line 250 of file itkImageToImageFilter.h. |
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Reimplemented from itk::ProcessObject. Definition at line 252 of file itkImageToImageFilter.h. |
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Increase the reference count (mark as used by another object). Reimplemented from itk::LightObject. |
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Definition at line 254 of file itkProcessObject.h. |
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Definition at line 253 of file itkProcessObject.h. |
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Remove all observers . |
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Remove the observer with this tag value. |
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Reset the pipeline. If an exception is thrown during an Update(), the pipeline may be in an inconsistent state. This method clears the internal state of the pipeline so Update() can be called. |
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Restore the cached input ReleaseDataFlags. |
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Set the AbortGenerateData flag for the process object. Process objects may handle premature termination of execution in different ways. |
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Definition at line 169 of file itkFastMarchingImageFilter.h. |
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Set the container auxiliary values at the initial alive points. Definition at line 103 of file itkFastMarchingExtensionImageFilter.h. |
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Set the container of auxiliary values at the initial trial points. Definition at line 111 of file itkFastMarchingExtensionImageFilter.h. |
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Set the Collect Points flag. Instrument the algorithm to collect a container of all nodes which it has visited. Useful for creating Narrowbands for level set algorithms that supports narrow banding. |
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Set the value of the debug flag. A non-zero value turns debugging on. |
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Referenced by itk::Object::GlobalWarningDisplayOff(), and itk::Object::GlobalWarningDisplayOn(). |
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Called to allocate the input array. Copies old inputs. |
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Called to allocate the output array. Copies old outputs. |
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Set the execution progress of a process object. The progress is a floating number in [0,1] with 0 meaning no progress and 1 meaning the filter has completed execution. The ProgressEvent is NOT invoked. |
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Sets the reference count (use with care) Reimplemented from itk::LightObject. |
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Definition at line 200 of file itkFastMarchingImageFilter.h. |
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Set the Fast Marching algorithm Stopping Value. The Fast Marching algorithm is terminated when the value of the smallest trial point is greater than the stopping value. |
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Definition at line 182 of file itkFastMarchingImageFilter.h. |
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Split the output's RequestedRegion into "num" pieces, returning region "i" as "splitRegion". This method is called "num" times. The regions must not overlap. The method returns the number of pieces that the routine is capable of splitting the output RequestedRegion, i.e. return value is less than or equal to "num". |
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If an imaging filter can be implemented as a multithreaded algorithm, the filter will provide an implementation of ThreadedGenerateData(). This superclass will automatically split the output image into a number of pieces, spawn multiple threads, and call ThreadedGenerateData() in each thread. Prior to spawning threads, the BeforeThreadedGenerateData() method is called. After all the threads have completed, the AfterThreadedGenerateData() method is called. If an image processing filter cannot support threading, that filter should provide an implementation of the GenerateData() method instead of providing an implementation of ThreadedGenerateData(). If a filter provides a GenerateData() method as its implementation, then the filter is responsible for allocating the output data. If a filter provides a ThreadedGenerateData() method as its implementation, then the output memory will allocated automatically by this superclass. The ThreadedGenerateData() method should only produce the output specified by "outputThreadRegion" parameter. ThreadedGenerateData() cannot write to any other portion of the output image (as this is responsibility of a different thread).
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Static function used as a "callback" by the MultiThreader. The threading library will call this routine for each thread, which will delegate the control to ThreadedGenerateData(). |
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Decrease the reference count (release by another object). Reimplemented from itk::LightObject. |
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Bring this filter up-to-date. Update() checks modified times against last execution times, and re-executes objects if necessary. A side effect of this method is that the whole pipeline may execute in order to bring this filter up-to-date. This method updates the currently prescribed requested region. If no requested region has been set on the output, then the requested region will be set to the largest possible region. Once the requested region is set, Update() will make sure the specified requested region is up-to-date. This is a confusing side effect to users who are just calling Update() on a filter. A first call to Update() will cause the largest possible region to be updated. A second call to Update() will update that same region. If a modification to the upstream pipeline cause a filter to have a different largest possible region, this second call to Update() will not cause the output requested region to be reset to the new largest possible region. Instead, the output requested region will be the same as the last time Update() was called. To have a filter always to produce its largest possible region, users should call UpdateLargestPossibleRegion() instead. Reimplemented from itk::ProcessObject. |
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Bring this filter up-to-date. Update() checks modified times against last execution times, and re-executes objects if necessary. A side effect of this method is that the whole pipeline may execute in order to bring this filter up-to-date. This method updates the currently prescribed requested region. If no requested region has been set on the output, then the requested region will be set to the largest possible region. Once the requested region is set, Update() will make sure the specified requested region is up-to-date. This is a confusing side effect to users who are just calling Update() on a filter. A first call to Update() will cause the largest possible region to be updated. A second call to Update() will update that same region. If a modification to the upstream pipeline cause a filter to have a different largest possible region, this second call to Update() will not cause the output requested region to be reset to the new largest possible region. Instead, the output requested region will be the same as the last time Update() was called. To have a filter always to produce its largest possible region, users should call UpdateLargestPossibleRegion() instead. Reimplemented from itk::ProcessObject. |
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Bring this filter up-to-date. Update() checks modified times against last execution times, and re-executes objects if necessary. A side effect of this method is that the whole pipeline may execute in order to bring this filter up-to-date. This method updates the currently prescribed requested region. If no requested region has been set on the output, then the requested region will be set to the largest possible region. Once the requested region is set, Update() will make sure the specified requested region is up-to-date. This is a confusing side effect to users who are just calling Update() on a filter. A first call to Update() will cause the largest possible region to be updated. A second call to Update() will update that same region. If a modification to the upstream pipeline cause a filter to have a different largest possible region, this second call to Update() will not cause the output requested region to be reset to the new largest possible region. Instead, the output requested region will be the same as the last time Update() was called. To have a filter always to produce its largest possible region, users should call UpdateLargestPossibleRegion() instead. Reimplemented from itk::ProcessObject. |
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Bring this filter up-to-date. Update() checks modified times against last execution times, and re-executes objects if necessary. A side effect of this method is that the whole pipeline may execute in order to bring this filter up-to-date. This method updates the currently prescribed requested region. If no requested region has been set on the output, then the requested region will be set to the largest possible region. Once the requested region is set, Update() will make sure the specified requested region is up-to-date. This is a confusing side effect to users who are just calling Update() on a filter. A first call to Update() will cause the largest possible region to be updated. A second call to Update() will update that same region. If a modification to the upstream pipeline cause a filter to have a different largest possible region, this second call to Update() will not cause the output requested region to be reset to the new largest possible region. Instead, the output requested region will be the same as the last time Update() was called. To have a filter always to produce its largest possible region, users should call UpdateLargestPossibleRegion() instead. Reimplemented from itk::ProcessObject. |
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Bring this filter up-to-date. Update() checks modified times against last execution times, and re-executes objects if necessary. A side effect of this method is that the whole pipeline may execute in order to bring this filter up-to-date. This method updates the currently prescribed requested region. If no requested region has been set on the output, then the requested region will be set to the largest possible region. Once the requested region is set, Update() will make sure the specified requested region is up-to-date. This is a confusing side effect to users who are just calling Update() on a filter. A first call to Update() will cause the largest possible region to be updated. A second call to Update() will update that same region. If a modification to the upstream pipeline cause a filter to have a different largest possible region, this second call to Update() will not cause the output requested region to be reset to the new largest possible region. Instead, the output requested region will be the same as the last time Update() was called. To have a filter always to produce its largest possible region, users should call UpdateLargestPossibleRegion() instead. Reimplemented from itk::ProcessObject. |
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Bring this filter up-to-date. Update() checks modified times against last execution times, and re-executes objects if necessary. A side effect of this method is that the whole pipeline may execute in order to bring this filter up-to-date. This method updates the currently prescribed requested region. If no requested region has been set on the output, then the requested region will be set to the largest possible region. Once the requested region is set, Update() will make sure the specified requested region is up-to-date. This is a confusing side effect to users who are just calling Update() on a filter. A first call to Update() will cause the largest possible region to be updated. A second call to Update() will update that same region. If a modification to the upstream pipeline cause a filter to have a different largest possible region, this second call to Update() will not cause the output requested region to be reset to the new largest possible region. Instead, the output requested region will be the same as the last time Update() was called. To have a filter always to produce its largest possible region, users should call UpdateLargestPossibleRegion() instead. Reimplemented from itk::ProcessObject. |
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Bring this filter up-to-date. Update() checks modified times against last execution times, and re-executes objects if necessary. A side effect of this method is that the whole pipeline may execute in order to bring this filter up-to-date. This method updates the currently prescribed requested region. If no requested region has been set on the output, then the requested region will be set to the largest possible region. Once the requested region is set, Update() will make sure the specified requested region is up-to-date. This is a confusing side effect to users who are just calling Update() on a filter. A first call to Update() will cause the largest possible region to be updated. A second call to Update() will update that same region. If a modification to the upstream pipeline cause a filter to have a different largest possible region, this second call to Update() will not cause the output requested region to be reset to the new largest possible region. Instead, the output requested region will be the same as the last time Update() was called. To have a filter always to produce its largest possible region, users should call UpdateLargestPossibleRegion() instead. Reimplemented from itk::ProcessObject. |
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Like Update(), but sets the output requested region to the largest possible region for the output. This is the method users should call if they want the entire dataset to be processed. If a user wants to update the same output region as a previous call to Update() or a previous call to UpdateLargestPossibleRegion(), then they should call the method Update(). |
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Reimplemented in itk::FastMarchingUpwindGradientImageFilter< TLevelSet, TSpeedImage >. |
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Actually generate new output Reimplemented in itk::StreamingImageFilter< TInputImage, TOutputImage >. |
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Update the information decribing the output data. This method transverses up the pipeline gathering modified time information. On the way back down the pipeline, this method calls GenerateOutputInformation() to set any necessary information about the output data objects. For instance, a filter that shrinks an image will need to provide an implementation for GenerateOutputInformation() that changes the spacing of the pixels. Such filters should call their superclass' implementation of GenerateOutputInformation prior to changing the information values they need (i.e. GenerateOutputInformation() should call Superclass::GenerateOutputInformation() prior to changing the information. Reimplemented in itk::watershed::Segmenter< TInputImage >, and itk::VTKImageImport< TOutputImage >. |
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Update the progress of the process object. Sets the Progress ivar to amount and invokes any observers for the ProgressEvent. The parameter amount should be in [0,1] and is the cumulative (not incremental) progress. |
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Reimplemented from itk::FastMarchingImageFilter< TLevelSet, TSpeedImage >. |
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Definition at line 103 of file itkImageToImageFilter.h. |
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Definition at line 88 of file itkFastMarchingExtensionImageFilter.h. |
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Definition at line 94 of file itkObject.h. |
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Definition at line 195 of file itkFastMarchingImageFilter.h. |
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Definition at line 100 of file itkImageSource.h. |
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Definition at line 103 of file itkImageToImageFilter.h. |
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Reimplemented from itk::ProcessObject. Definition at line 103 of file itkImageToImageFilter.h. |
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Definition at line 246 of file itkImageToImageFilter.h. |
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Definition at line 98 of file itkImageSource.h. |
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Definition at line 92 of file itkImageSource.h. |
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Definition at line 103 of file itkImageToImageFilter.h. |
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Definition at line 103 of file itkImageToImageFilter.h. |
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Definition at line 103 of file itkImageToImageFilter.h. |
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Definition at line 103 of file itkImageToImageFilter.h. |
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Definition at line 307 of file itkFastMarchingImageFilter.h. |
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Definition at line 312 of file itkFastMarchingImageFilter.h. |
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Time when GenerateOutputInformation was last called. Definition at line 428 of file itkProcessObject.h. |
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Number of uses of this object by other objects. Definition at line 119 of file itkLightObject.h. |
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Mutex lock to protect modification to the reference count Definition at line 122 of file itkLightObject.h. |
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Definition at line 311 of file itkFastMarchingImageFilter.h. |
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This flag indicates when the pipeline is executing. It prevents infinite recursion when pipelines have loops. Definition at line 425 of file itkProcessObject.h. |
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Definition at line 195 of file itkFastMarchingImageFilter.h. |
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Definition at line 79 of file itkImageSource.h. |
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Definition at line 246 of file itkFastMarchingImageFilter.h. |
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Definition at line 110 of file itkImageSource.h. |
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Definition at line 88 of file itkImageSource.h. |
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Definition at line 246 of file itkFastMarchingImageFilter.h. |
1.4.2 written by Dimitri van Heesch,
© 1997-2000