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Program: Insight Segmentation & Registration Toolkit
Module: itkDataObject.h
Language: C++
Date: $Date$
Version: $Revision$
Copyright (c) Insight Software Consortium. All rights reserved.
See ITKCopyright.txt or http://www.itk.org/HTML/Copyright.htm for details.
Portions of this code are covered under the VTK copyright.
See VTKCopyright.txt or http://www.kitware.com/VTKCopyright.htm for details.
This software is distributed WITHOUT ANY WARRANTY; without even
the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
PURPOSE. See the above copyright notices for more information.
=========================================================================*/
#ifndef __itkDataObject_h
#define __itkDataObject_h
#include "itkObject.h"
#include "itkSmartPointerForwardReference.h"
#include "itkWeakPointer.h"
#include "itkExceptionObject.h"
namespace itk
{
class ProcessObject;
class DataObject;
/*--------------------Data Object Exceptions---------------------------*/
/** \class DataObjectError
* \brief Exception object for DataObject exceptions */
class ITKCommon_EXPORT DataObjectError : public ExceptionObject
{
public:
/** Default constructor. Needed to ensure the exception object can be
* copied. */
DataObjectError();
/** Destructor. Need to specify empty throw() to avoid warnings. */
virtual ~DataObjectError() throw() {}
/** Constructor. Needed to ensure the exception object can be copied. */
DataObjectError(const char *file, unsigned int lineNumber);
/** Constructor. Needed to ensure the exception object can be copied. */
DataObjectError(const std::string& file, unsigned int lineNumber);
/** Copy constructor. Needed to ensure the exception object can be copied. */
DataObjectError(const DataObjectError &orig);
/** Operator=. Needed to ensure the exception object can be copied. */
DataObjectError& operator=( const DataObjectError& orig);
/** Standard type macro */
itkTypeMacro(DataObjectError, ExceptionObject);
/** Set the data object that is throwing this exception. */
void SetDataObject(DataObject *dobj);
/** Get the data object that is throwing this exception. */
DataObject* GetDataObject();
protected:
/** Print exception information. This method can be overridden by
* specific exception subtypes. The default is to print out the
* location where the exception was first thrown and any description
* provided by the ``thrower''. */
virtual void PrintSelf(std::ostream& os, Indent indent) const;
private:
DataObject *m_DataObject;
};
/** \class InvalidRequestRegionError
* Exception object for invalid requested region
*/
class ITKCommon_EXPORT InvalidRequestedRegionError : public DataObjectError
{
public:
/** Default constructor. Needed to ensure the exception object can be copied. */
InvalidRequestedRegionError();
/** Destructor. Need to specify empty throw() to avoid warnings. */
virtual ~InvalidRequestedRegionError() throw() {}
/** Constructor. Needed to ensure the exception object can be copied. */
InvalidRequestedRegionError(const char *file, unsigned int lineNumber);
/** Constructor. Needed to ensure the exception object can be copied. */
InvalidRequestedRegionError(const std::string& file, unsigned int lineNumber);
/** Copy constructor. Needed to ensure the exception object can be copied. */
InvalidRequestedRegionError(const InvalidRequestedRegionError &orig);
/** Operator=. Needed to ensure the exception object can be copied. */
InvalidRequestedRegionError& operator=( const InvalidRequestedRegionError& orig);
/** Standard type macro */
itkTypeMacro(InvalidRequestedRegionError, DataObjectError);
protected:
/** Print exception information. This method can be overridden by
* specific exception subtypes. The default is to print out the
* location where the exception was first thrown and any description
* provided by the ``thrower''. */
virtual void PrintSelf(std::ostream& os, Indent indent) const;
};
/*----------------------------Data Object--------------------------------*/
/** \class DataObject
* \brief Base class for all data objects in ITK.
*
* This is the base class for all data objects in the Insight data
* processing pipeline. A data object is an object that represents and
* provides access to data. ProcessObjects (i.e., filters) operate on
* input data objects, producing new data objects as output.
* ProcessObject and DataObject are connected together into data flow
* pipelines.
*
* The data flow pipeline architecture requires that DataObjects and
* ProcessObjects negotiate the flow of information. When the tail of
* a pipeline is instructed to Update(), a series of requests are
* propagated up the pipeline (from a ProcessObject to its inputs
* (DataObjects), from these inputs to their sources (ProcessObjects),
* etc.). A call to Update() entails 3 passes up the pipeline (though
* not all passes will traverse the entire pipeline). The first pass
* up the pipeline determines when various components of the pipeline
* were last modified and hence which components will need to be
* updated. As this first pass in unwinding, meta information about
* the DataObjects (for instance image spacing and data size) are
* passed down the pipeline. The second pass up the pipeline
* propagates a request for a specific piece of information (for
* instance a sub-region of an image). A request for a piece of a
* DataObject is propagated to its source, from there to its inputs,
* etc. allowing each ProcessObject to determine whether (1) it can
* already satisfy the request (the requested block of data is already
* available) or (2) the ProcessObject will need to request a new
* block of data on input to satisfy the output request. Finally, a
* pass is made up the pipeline to actually calculate the values for
* the various blocks of data requested (i.e. pixel values are finally
* calculated). This final pass will only traverse up the pipeline as
* far as the first two passes have identified. For instance, to
* satisfy a given request at the tail of a pipeline, only the lower
* few ProcessObjects may have to re-execute.
*
* There are three types of information negotiated by the pipeline
* (prior to actual calculation of the bulk data): modified times,
* meta data, and regions. The modified times keep track of when
* various data objects were last modified and/updated and the when
* the various process objects were modified. The meta data is any
* extra information about the data object that is not part of the
* bulk data. For instance, an Image maintains pixel spacing and
* origin meta data. Finally, the pipeline negotiation process passes
* requests up the pipeline in the form of Regions. A DataObject can
* have as many as three regions (which themselves could be considered
* meta data): LargestPossibleRegion, RequestedRegion, and
* BufferedRegion. The LargestPossibleRegion is the entirety of the
* dataset (for instance how big is the dataset on disk).
* LargestPossibleRegions are negotiated during the first pass of a
* pipeline update (via the method
* ProcessObject::GenerateOutputInformation() which is called from
* ProcessObject::UpdateOutputInformation(). The RequestedRegion is
* the amount of the DataObject that is requested by the user or
* pipeline. RequestedRegions are negotiated during the second pass of
* a pipeline update (via the methods
* ProcessObject::EnlargeOutputRequestedRegion(),
* ProcessObject::GenerateOutputRequestedRegion(),
* ProcessObject::GenerateInputRequestedRegion() which are called from
* ProcessObject::PropagateRequestedRegion()). The BufferedRegion is
* the amount of the DataObject that is currently in memory.
* BufferedRegions are defined during the final pass of a pipeline
* update (when ProcessObjects finally calculate the bulk data via the
* methods ProcessObject::GenerateData() or
* ProcessObject::ThreadedGenerateData() which are called by
* ProcessObject::UpdateOutputData()). These three regions can be
* different but must satisfy the relationship RequestedRegion <=
* BufferedRegion <= LargestPossibleRegion. For instance, an Image
* could be 512x512x200 on disk (LargestPossibleRegion) but the
* application may only have a 256x256x50 section of the dataset in
* memory (BufferedRegion) and the user wants to operate on a
* 100x100x1 section of the buffer (RequestedRegion).
*
* Region negotiation is not applicable for all types of DataObjects.
* For instance, an EquivalencyTable of segmentation labels can be
* passed from ProcessObject to ProcessObject as any other DataObject
* but an EquivalencyTable does not support the concept of a
* sub-region. Therefore, the region negotiations at the DataObject
* (superclass) level are implemented as "abstract" concepts (not to
* be confused with a C++ abstract methods), allowing subclasses to
* provide specialized implementations on an as needed basis. There
* are five methods provided in DataObject that a subclass of
* DataObject may have to override for that particular type of
* DataObject to flow through the pipeline. These methods should only
* have to be specialized for DataObjects that do support
* regions. These methods are:
*
* void UpdateOutputInformation(): This method implements the first
* pass of the pipeline update mechanism outlined above. It is
* responsible for identifying when upstream components of the
* pipeline have been change (ModifiedTimes and Pipeline
* ModifiedTimes) and is responsible for propagating meta data through
* the pipeline. In the simplest case, this method simply calls the
* DataObject's source's UpdateOutputInformation() method (this is the
* default implementation). For DataObjects that support streaming,
* this method also propagates LargestPossibleRegions to downstream
* ProcessObjects.
*
* bool VerifyRequestedRegion(): Verify that the RequestedRegion is
* within the LargestPossibleRegion. For DataObjects that do not
* support Regions, this method always returns true.
*
* bool RequestedRegionIsOutsideOfTheBufferedRegion(): Determine
* whether the RequestedRegion is outside of the current
* BufferedRegion. This method is used by the second pass of a
* pipeline update outlined above. It is used to determine whether a
* filter needs to re-execute in order to satisfy a given request. For
* DataObjects that do not support Regions, this method always returns
* false. By always returning false, these types of DataObjects will
* update solely on the basis of modified times (wherease Images
* update based on either modified times or the RequestedRegion
* needs). If this method always returned true, the DataObject would
* be updated on every single call to Update() (not recommended).
*
* void SetRequestedRegion(DataObject *): Sets the RequestedRegion of
* this DataObject to match the RequestedRegion of the DataObject that
* is passed in as a parameter. This method is used by
* ProcessObject::GenerateOutputRequestedRegion() and by
* ProcessObject::SetNthOutput(). In the former case, it used as an
* abstract API so that a ProcessObject can copy a requested region
* from one output to all its outputs without knowing the particular
* subclass of DataObject. In the latter case, it used when a
* ProcessObject has to create an output object to replace one of its
* outputs (and needs to copy the former object's RequestedRegion). In
* either case, it allows ProcessObject to perform these actions
* without knowing the specifics about the particular subclass of
* DataObject. For DataObjects that do not support Regions, this
* method does nothing.
*
* void SetRequestedRegionToLargestPossibleRegion(): Sets the
* RequestedRegion of this DataObject to match its
* LargestPossibleRegion. This method is used to force a filter to
* produce all of its output on the next call to Update(). For
* DataObjects that do not support Regions, this method does nothing.
*
*
* \sa ProcessObject
* \sa ImageBase
* \sa Mesh
* \ingroup DataRepresentation
* \ingroup ITKSystemObjects
*/
class ITKCommon_EXPORT DataObject : public Object
{
public:
/** Standard class typedefs. */
typedef DataObject Self;
typedef Object Superclass;
typedef SmartPointer<Self> Pointer;
typedef SmartPointer<const Self> ConstPointer;
/** Run-time type information (and related methods). */
itkTypeMacro(DataObject,Object);
/** Separate this data object from the pipeline. This routine disconnects
* a data object from the upstream pipeline. Hence an Update() from
* downstream will not propagate back past this data object. To completely
* isolate this data object from the pipeline, the application must remove
* this data object from any filters which it is connected as the input. */
void DisconnectPipeline();
/** Get the process object that generated this data object.
* If there is no process object, then the data object has
* been disconnected from the pipeline, or the data object
* was created manually. (Note: we cannot use the GetObjectMacro()
* defined in itkMacro because the mutual dependency of
* DataObject and ProcessObject causes compile problems. Also,
* a forward reference smart pointer is returned, not a smart pointer,
* because of the circular dependency between the process and data object.)
*
* GetSource() returns a SmartPointerForwardReference and not a WeakPointer
* because it is assumed the code calling GetSource() wants to hold a
* long term reference to the source. */
SmartPointerForwardReference<ProcessObject> GetSource() const;
/** Which of the source's outputs corresponds to this data object? */
unsigned int GetSourceOutputIndex() const;
/** Restore the data object to its initial state. This means releasing
* memory. */
virtual void Initialize();
/** Turn on/off a flag to control whether this object's data is released
* after being used by a filter. */
void SetReleaseDataFlag(bool flag)
{
m_ReleaseDataFlag = flag;
}
itkGetConstReferenceMacro(ReleaseDataFlag,bool);
itkBooleanMacro(ReleaseDataFlag);
/** Turn on/off a flag to control whether every object releases its data
* after being used by a filter. Being a global flag, it controls the
* behavior of all DataObjects and ProcessObjects. */
static void SetGlobalReleaseDataFlag(bool val);
static bool GetGlobalReleaseDataFlag();
static void GlobalReleaseDataFlagOn()
{Self::SetGlobalReleaseDataFlag(true);}
static void GlobalReleaseDataFlagOff()
{Self::SetGlobalReleaseDataFlag(false);}
/** Release data back to system to conserve memory resource. Used during
* pipeline execution. Releasing this data does not make
* down-stream data invalid, so it does not modify the MTime of this data
* object. */
void ReleaseData();
/** Return flag indicating whether data should be released after use
* by a filter. */
bool ShouldIReleaseData() const;
/** Get the flag indicating the data has been released. */
bool GetDataReleased() const
{return m_DataReleased;}
/** Provides opportunity for the data object to insure internal
* consistency before access. Also causes owning source/filter (if
* any) to update itself. The Update() method is composed of
* UpdateOutputInformation(), PropagateRequestedRegion(), and
* UpdateOutputData(). This method may call methods that throw an
* InvalidRequestedRegionError exception. This exception will leave
* the pipeline in an inconsistent state. You will need to call
* ResetPipeline() on the last ProcessObject in your pipeline in
* order to restore the pipeline to a state where you can call
* Update() again. */
virtual void Update();
/** Update the information for this DataObject so that it can be used
* as an output of a ProcessObject. This method is used in the pipeline
* mechanism to propagate information and initialize the meta data
* associated with a DataObject. Any implementation of this method in
* a derived class is assumed to call its source's
* ProcessObject::UpdateOutputInformation() which determines modified
* times, LargestPossibleRegions, and any extra meta data like spacing,
* origin, etc. Default implementation simply call's it's source's
* UpdateOutputInformation(). */
virtual void UpdateOutputInformation();
/** Methods to update the pipeline. Called internally by the
* pipeline mechanism. */
virtual void PropagateRequestedRegion() throw (InvalidRequestedRegionError);
virtual void UpdateOutputData();
/** 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. */
virtual void ResetPipeline();
/** The maximum MTime of all upstream filters and data objects.
* This does not include the MTime of this data object. */
void SetPipelineMTime(unsigned long time)
{m_PipelineMTime = time;}
itkGetConstReferenceMacro(PipelineMTime,unsigned long);
/** MTime for the last time this DataObject was generated. */
virtual unsigned long GetUpdateMTime() const;
/** Setup a DataObject to receive new data. This method is called
* by the pipeline mechanism on each output of filter that needs
* to execute. The default implementation is to return a DataObject
* to its initial state. This may involve releasing previously
* allocated bulk data. Subclasses of DataObject may want to
* override this method and/or the Initialize() method if they
* want a different default behavior (for instance a DataObject
* might want finer control over its bulk data memory management). */
virtual void PrepareForNewData()
{this->Initialize();}
/** Inform the pipeline mechanism that data has been generated. This
* method is called by ProcessObject::UpdateOutputData() once the
* process object has finished generating its data. This essentially
* marks the DataObject as being updated and ready for use. */
void DataHasBeenGenerated();
/** Set the RequestedRegion to the LargestPossibleRegion. This
* forces a filter to produce all of the output in one execution
* (i.e. not streaming) on the next call to Update(). */
virtual void SetRequestedRegionToLargestPossibleRegion() {};
/** Determine whether the RequestedRegion is outside of the
* BufferedRegion. This method returns true if the RequestedRegion
* is outside the BufferedRegion (true if at least one pixel is
* outside). This is used by the pipeline mechanism to determine
* whether a filter needs to re-execute in order to satisfy the
* current request. If the current RequestedRegion is already
* inside the BufferedRegion from the previous execution (and the
* current filter is up to date), then a given filter does not need
* to re-execute */
virtual bool RequestedRegionIsOutsideOfTheBufferedRegion()
{ return false; }
/** Verify that the RequestedRegion is within the LargestPossibleRegion.
*
* If the RequestedRegion is not within the LargestPossibleRegion,
* then the filter cannot possibly satisfy the request. This method
* returns true if the request can be satisfied (even if it will be
* necessary to process the entire LargestPossibleRegion) and
* returns false otherwise. This method is used by
* PropagateRequestedRegion(). PropagateRequestedRegion() throws a
* InvalidRequestedRegionError exception if the requested region is
* not within the LargestPossibleRegion. Default implementation
* simply returns true in order to support DataObjects that do not
* need regions (for instance itk::EquivalencyTable). */
virtual bool VerifyRequestedRegion() { return true; };
/** Copy information from the specified data set. This method is
* part of the pipeline execution model. By default, a ProcessObject
* will copy meta-data from the first input to all of its
* outputs. See ProcessObject::GenerateOutputInformation(). Each
* subclass of DataObject is responsible for being able to copy
* whatever meta-data it needs from from another DataObject.
* The default implementation of this method is empty. If a subclass
* overrides this method, it should always call its superclass'
* version. */
virtual void CopyInformation(const DataObject*) {};
/** Set the requested region from this data object to match the requested
* region of the data object passed in as a parameter. For
* DataObject's that do not support Regions, this method does
* nothing. Subclasses of DataObject that do support Regions,
* provide an alternative implementation. */
virtual void SetRequestedRegion(DataObject *) {};
/** Method for grafting the content of one data object into another one.
* This method is intended to be overloaded by derived classes. Each one of
* them should use dynamic_casting in order to verify that the grafted
* object is actually of the same type as the class on which the Graft()
* method was invoked. */
virtual void Graft( const DataObject *) {};
protected:
DataObject();
~DataObject();
void PrintSelf(std::ostream& os, Indent indent) const;
/** Propagate a call to ResetPipeline(). Called only from ProcessObject. */
virtual void PropagateResetPipeline();
private:
DataObject(const Self&); //purposely not implemented
void operator=(const Self&); //purposely not implemented
/** Who generated this data? */
mutable WeakPointer<ProcessObject> m_Source;
mutable unsigned int m_SourceOutputIndex;
/** When was this data last generated? */
TimeStamp m_UpdateMTime;
bool m_ReleaseDataFlag; //Data will release after use by a filter if on
bool m_DataReleased; //Keep track of data release during pipeline execution
/** The maximum MTime of all upstream filters and data objects.
* This does not include the MTime of this data object. */
unsigned long m_PipelineMTime;
/** Static member that controls global data release after use by filter. */
static bool m_GlobalReleaseDataFlag;
/** Connect the specified process object to the data object. This
* should only be called from a process object. The second parameter
* indicates which of the source's outputs corresponds to this data
* object. */
bool ConnectSource(ProcessObject *s, unsigned long idx) const;
/** Disconnect the specified process object from the data
* object. This should only be called from a process object. An
* application should call DataObject::DisconnectPipeline() if it
* wants to disconnect a data object from a pipeline. The second
* parameter indicates which of the source's outputs corresponds to
* this data object. If the specified source output index does not
* match the index cached when the data object was connected to the
* pipeline (see ConnectSource), then nothing is done. */
bool DisconnectSource(ProcessObject *s, unsigned long idx) const;
/** Friends of DataObject */
friend class ProcessObject;
friend class DataObjectError;
};
} // end namespace itk
#endif
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