/usr/include/ITK-4.5/itkSpatialObject.hxx is in libinsighttoolkit4-dev 4.5.0-3.
This file is owned by root:root, with mode 0o644.
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*
* Copyright Insight Software Consortium
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0.txt
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*
*=========================================================================*/
#ifndef __itkSpatialObject_hxx
#define __itkSpatialObject_hxx
#include "itkSpatialObject.h"
#include "itkNumericTraits.h"
#include <algorithm>
#include <string>
namespace itk
{
/** Constructor */
template< unsigned int TDimension >
SpatialObject< TDimension >
::SpatialObject(void)
{
m_TypeName = "SpatialObject";
m_Dimension = TDimension;
m_Bounds = BoundingBoxType::New();
m_BoundsMTime = 0;
m_Property = PropertyType::New();
m_TreeNode = NULL;
m_ObjectToWorldTransform = TransformType::New();
m_ObjectToWorldTransform->SetIdentity();
m_ObjectToParentTransform = TransformType::New();
m_ObjectToParentTransform->SetIdentity();
m_IndexToWorldTransform = TransformType::New();
m_IndexToWorldTransform->SetIdentity();
m_BoundingBoxChildrenDepth = MaximumDepth;
m_Id = -1;
m_ParentId = -1;
m_AffineGeometryFrame = AffineGeometryFrameType::New();
m_AffineGeometryFrame->SetIndexToWorldTransform(m_IndexToWorldTransform);
m_TreeNode = SpatialObjectTreeNode< TDimension >::New();
m_TreeNode->Set(this);
m_InternalInverseTransform = TransformType::New();
m_DefaultInsideValue = 1.0;
m_DefaultOutsideValue = 0.0;
}
/** Destructor */
template< unsigned int TDimension >
SpatialObject< TDimension >
::~SpatialObject(void)
{
this->Clear();
}
/** Clear the spatial object by deleting all
* lists of children and subchildren */
template< unsigned int TDimension >
void
SpatialObject< TDimension >
::Clear(void)
{
typename ChildrenListType::iterator pos = m_InternalChildrenList.begin();
typename ChildrenListType::iterator it = m_InternalChildrenList.begin();
while ( it != m_InternalChildrenList.end() )
{
pos = it;
it++;
m_InternalChildrenList.erase(pos);
}
m_InternalChildrenList.clear();
}
/** Return the Derivative at a point given the order of the derivative */
template< unsigned int TDimension >
void
SpatialObject< TDimension >
::DerivativeAt(const PointType & point, short unsigned int order,
OutputVectorType & value, unsigned int depth, char *name)
{
if ( !IsEvaluableAt(point, depth, name) )
{
ExceptionObject e(__FILE__);
e.SetLocation(
"SpatialObject< TDimension >::DerivateAt(\
const PointType, unsigned short, OutputVectorType & )" );
e.SetDescription("This spatial object is not evaluable at the point");
throw e;
}
if ( order == 0 )
{
double r;
ValueAt(point, r, depth, name);
value.Fill(r);
}
else
{
PointType p1, p2;
OutputVectorType v1, v2;
typename OutputVectorType::Iterator it = value.Begin();
typename OutputVectorType::Iterator it_v1 = v1.Begin();
typename OutputVectorType::Iterator it_v2 = v2.Begin();
for ( unsigned short i = 0; i < TDimension; i++, it++, it_v1++, it_v2++ )
{
p1 = point;
p2 = point;
// should get the spacing from the transform
const double *spacing = this->GetModifiableIndexToObjectTransform()->GetScale();
p1[i] -= spacing[i];
p2[i] += spacing[i];
try
{
DerivativeAt(p1, order - 1, v1, depth, name);
DerivativeAt(p2, order - 1, v2, depth, name);
}
catch ( ExceptionObject e )
{
throw e;
}
( *it ) = ( ( *it_v2 ) - ( *it_v1 ) ) / 2;
}
}
}
/** Return if a point is inside the object or its children */
template< unsigned int TDimension >
bool
SpatialObject< TDimension >
::IsInside(const PointType & point, unsigned int depth, char *name) const
{
if ( depth > 0 )
{
typedef typename TreeNodeType::ChildrenListType TreeChildrenListType;
TreeChildrenListType *children = m_TreeNode->GetChildren();
typename TreeChildrenListType::const_iterator it = children->begin();
typename TreeChildrenListType::const_iterator itEnd = children->end();
while ( it != itEnd )
{
if ( ( *it )->Get()->IsInside(point, depth - 1, name) )
{
delete children;
return true;
}
it++;
}
delete children;
}
return false;
}
/** Return if the object is evaluable at a point */
template< unsigned int TDimension >
bool
SpatialObject< TDimension >
::IsEvaluableAt(const PointType & point, unsigned int depth,
char *name) const
{
if ( depth > 0 )
{
typedef typename TreeNodeType::ChildrenListType TreeChildrenListType;
TreeChildrenListType *children = m_TreeNode->GetChildren();
typename TreeChildrenListType::const_iterator it = children->begin();
typename TreeChildrenListType::const_iterator itEnd = children->end();
while ( it != itEnd )
{
if ( ( *it )->Get()->IsEvaluableAt(point, depth - 1, name) )
{
delete children;
return true;
}
it++;
}
delete children;
}
return false;
}
/** Return the value of the object at a point */
template< unsigned int TDimension >
bool
SpatialObject< TDimension >
::ValueAt(const PointType & point, double & value, unsigned int depth,
char *name) const
{
bool evaluable = false;
if ( depth > 0 )
{
typedef typename TreeNodeType::ChildrenListType TreeChildrenListType;
TreeChildrenListType *children = m_TreeNode->GetChildren();
typename TreeChildrenListType::const_iterator it = children->begin();
typename TreeChildrenListType::const_iterator itEnd = children->end();
while ( it != itEnd )
{
if ( ( *it )->Get()->IsEvaluableAt(point, depth - 1, name) )
{
( *it )->Get()->ValueAt(point, value, depth - 1, name);
evaluable = true;
break;
}
it++;
}
delete children;
}
if ( evaluable )
{
return true;
}
return false;
}
/** Print self */
template< unsigned int TDimension >
void
SpatialObject< TDimension >
::PrintSelf(std::ostream & os, Indent indent) const
{
Superclass::PrintSelf(os, indent);
os << "Bounding Box:" << std::endl;
os << indent << m_Bounds << std::endl;
os << "Geometric properties:" << std::endl;
os << indent << "Object to World Transform: " << m_ObjectToWorldTransform
<< std::endl;
os << indent << "Index to World Transform: " << m_IndexToWorldTransform
<< std::endl;
os << std::endl << std::endl;
os << indent << "Bounding Box Children Depth: " << m_BoundingBoxChildrenDepth
<< std::endl;
os << indent << "Bounding Box Children Name: " << m_BoundingBoxChildrenName
<< std::endl;
os << "Object properties: " << std::endl;
os << m_Property << std::endl;
}
/** Get the bounds of the object */
template< unsigned int TDimension >
typename SpatialObject< TDimension >::BoundingBoxType *
SpatialObject< TDimension >
::GetBoundingBox() const
{
return m_Bounds.GetPointer();
}
/** Add a child to the object */
template< unsigned int TDimension >
void
SpatialObject< TDimension >
::AddSpatialObject(Self *pointer)
{
m_TreeNode->AddChild( pointer->GetModifiableTreeNode() );
m_InternalChildrenList.push_back(pointer);
this->Modified();
}
/** Remove a child to the object */
template< unsigned int TDimension >
void
SpatialObject< TDimension >
::RemoveSpatialObject(Self *pointer)
{
if ( m_TreeNode->Remove( pointer->GetModifiableTreeNode() ) )
{
typename ChildrenListType::iterator pos;
pos = std::find(m_InternalChildrenList.begin(),
m_InternalChildrenList.end(), pointer);
if ( pos != m_InternalChildrenList.end() )
{
m_InternalChildrenList.erase(pos);
}
this->Modified();
}
else
{
std::cerr << "Cannot RemoveSpatialObject" << std::endl;
}
}
/** Set the local to global transformation */
template< unsigned int TDimension >
void
SpatialObject< TDimension >
::SetObjectToParentTransform(TransformType *transform)
{
static_cast< TreeNodeType * >(
m_TreeNode.GetPointer() )->SetNodeToParentNodeTransform(transform);
ComputeObjectToWorldTransform();
}
/** Compute the Global Transform */
template< unsigned int TDimension >
void
SpatialObject< TDimension >
::ComputeObjectToWorldTransform()
{
// The ObjectToParentTransform is the combination of the
// ObjectToNodeTransform and the NodeToParentNodeTransform
m_ObjectToParentTransform->SetIdentity();
m_ObjectToParentTransform->SetCenter(
m_AffineGeometryFrame->GetObjectToNodeTransform()->GetCenter() );
m_ObjectToParentTransform->Compose(
m_AffineGeometryFrame->GetObjectToNodeTransform(), false);
m_ObjectToParentTransform->Compose(
static_cast< TreeNodeType * >(
m_TreeNode.GetPointer() )->GetNodeToParentNodeTransform(), false);
m_ObjectToWorldTransform->SetCenter(
m_AffineGeometryFrame->GetObjectToNodeTransform()->GetCenter() );
m_ObjectToWorldTransform->SetMatrix(
m_AffineGeometryFrame->GetObjectToNodeTransform()->GetMatrix() );
m_ObjectToWorldTransform->SetOffset(
m_AffineGeometryFrame->GetObjectToNodeTransform()->GetOffset() );
m_IndexToWorldTransform->SetCenter(
m_AffineGeometryFrame->GetIndexToObjectTransform()->GetCenter() );
m_IndexToWorldTransform->SetMatrix(
m_AffineGeometryFrame->GetIndexToObjectTransform()->GetMatrix() );
m_IndexToWorldTransform->SetOffset(
m_AffineGeometryFrame->GetIndexToObjectTransform()->GetOffset() );
static_cast< TreeNodeType * >( m_TreeNode.GetPointer() )
->ComputeNodeToWorldTransform();
m_ObjectToWorldTransform->Compose(
static_cast< TreeNodeType * >(
m_TreeNode.GetPointer() )->GetNodeToWorldTransform(), false);
m_IndexToWorldTransform->Compose(this->GetObjectToWorldTransform(), false);
// Propagate the changes to the children
typedef typename TreeNodeType::ChildrenListType TreeChildrenListType;
TreeChildrenListType *children = m_TreeNode->GetChildren();
typename TreeChildrenListType::const_iterator it = children->begin();
typename TreeChildrenListType::const_iterator itEnd = children->end();
while ( it != itEnd )
{
( *it )->Get()->ComputeObjectToWorldTransform();
it++;
}
delete children;
}
/** Get the local transformation */
template< unsigned int TDimension >
typename SpatialObject< TDimension >::TransformType *
SpatialObject< TDimension >
::GetObjectToNodeTransform(void)
{
return m_AffineGeometryFrame->GetObjectToNodeTransform();
}
/** Get the local transformation (const) */
template< unsigned int TDimension >
const typename SpatialObject< TDimension >::TransformType *
SpatialObject< TDimension >
::GetObjectToNodeTransform(void) const
{
return m_AffineGeometryFrame->GetObjectToNodeTransform();
}
/** Get the local transformation */
template< unsigned int TDimension >
typename SpatialObject< TDimension >::TransformType *
SpatialObject< TDimension >
::GetObjectToParentTransform(void)
{
return static_cast< TreeNodeType * >(
m_TreeNode.GetPointer() )->GetNodeToParentNodeTransform();
//return m_ObjectToNodeTransform.GetPointer();
}
/** Get the local transformation (const) */
template< unsigned int TDimension >
const typename SpatialObject< TDimension >::TransformType *
SpatialObject< TDimension >
::GetObjectToParentTransform(void) const
{
return static_cast< TreeNodeType * >(
m_TreeNode.GetPointer() )->GetNodeToParentNodeTransform();
}
/** Get the local transformation (const) */
template< unsigned int TDimension >
const typename SpatialObject< TDimension >::TransformType *
SpatialObject< TDimension >
::GetIndexToObjectTransform(void) const
{
return m_AffineGeometryFrame->GetIndexToObjectTransform();
}
/** Set the global to local transformation */
template< unsigned int TDimension >
void
SpatialObject< TDimension >
::SetObjectToWorldTransform(TransformType *transform)
{
m_ObjectToWorldTransform = transform;
ComputeObjectToParentTransform();
}
/** Compute the Transform when the global transform as been set
* This does not change the IndexToObjectMatrix */
template< unsigned int TDimension >
void
SpatialObject< TDimension >
::ComputeObjectToParentTransform()
{
m_ObjectToParentTransform->SetScale( m_ObjectToWorldTransform->GetScale() );
m_ObjectToParentTransform->SetCenter( m_ObjectToWorldTransform->GetCenter() );
m_ObjectToParentTransform->SetMatrix( m_ObjectToWorldTransform->GetMatrix() );
m_ObjectToParentTransform->SetOffset( m_ObjectToWorldTransform->GetOffset() );
if ( m_TreeNode->HasParent() )
{
typename TransformType::Pointer inverse = TransformType::New();
if ( static_cast< TreeNodeType * >( m_TreeNode->GetParent() )
->GetNodeToParentNodeTransform()->GetInverse(inverse) )
{
m_ObjectToParentTransform->Compose(inverse, true);
}
}
m_AffineGeometryFrame->GetModifiableObjectToNodeTransform()->SetIdentity();
static_cast< TreeNodeType * >( m_TreeNode.GetPointer() )
->GetNodeToParentNodeTransform()
->SetCenter( m_ObjectToParentTransform->GetCenter() );
static_cast< TreeNodeType * >( m_TreeNode.GetPointer() )
->GetNodeToParentNodeTransform()
->SetMatrix( m_ObjectToParentTransform->GetMatrix() );
static_cast< TreeNodeType * >( m_TreeNode.GetPointer() )
->GetNodeToParentNodeTransform()
->SetOffset( m_ObjectToParentTransform->GetOffset() );
m_IndexToWorldTransform->SetCenter( m_AffineGeometryFrame
->GetIndexToObjectTransform()
->GetCenter() );
m_IndexToWorldTransform->SetMatrix( m_AffineGeometryFrame
->GetIndexToObjectTransform()
->GetMatrix() );
m_IndexToWorldTransform->SetOffset( m_AffineGeometryFrame
->GetIndexToObjectTransform()
->GetOffset() );
m_IndexToWorldTransform->Compose(m_ObjectToWorldTransform, false);
}
/** Get the modification time */
template< unsigned int TDimension >
ModifiedTimeType
SpatialObject< TDimension >
::GetMTime(void) const
{
ModifiedTimeType latestTime = Object::GetMTime();
if ( latestTime < m_BoundsMTime )
{
latestTime = m_BoundsMTime;
}
typedef typename TreeNodeType::ChildrenListType TreeChildrenListType;
if ( !m_TreeNode )
{
return latestTime;
}
TreeChildrenListType *children = m_TreeNode->GetChildren();
typename TreeChildrenListType::const_iterator it = children->begin();
typename TreeChildrenListType::const_iterator itEnd = children->end();
ModifiedTimeType localTime;
while ( it != itEnd )
{
localTime = ( *it )->Get()->GetMTime();
if ( localTime > latestTime )
{
latestTime = localTime;
}
it++;
}
delete children;
return latestTime;
}
/**
* Compute an axis-aligned bounding box for an object and its selected
* children, down to a specified depth. After computation, the
* resulting bounding box is stored in this->m_Bounds.
*
* By default, the bounding box children depth is maximum, meaning that
* the bounding box for the object and all its recursive children is computed.
* This depth can be set (before calling ComputeBoundingBox) using
* SetBoundingBoxChildrenDepth().
*
* By calling SetBoundingBoxChildrenName(), it is possible to restrict
* the bounding box computation to objects of a specified type or
* family of types. The spatial objects included in the computation
* are those whose typenames share, as their initial substring, the
* string specified via SetBoundingBoxChildrenName(). The root
* spatial object (on which the method is called) is not treated
* specially. If its typename does not match the bounding box
* children name, then it is not included in the bounding box
* computation, but its descendents that match the string are
* included.
*/
template< unsigned int TDimension >
bool
SpatialObject< TDimension >
::ComputeBoundingBox() const
{
itkDebugMacro("Computing Bounding Box");
this->ComputeLocalBoundingBox();
if ( m_BoundingBoxChildrenDepth > 0 && m_TreeNode )
{
typedef typename TreeNodeType::ChildrenListType TreeChildrenListType;
TreeChildrenListType *children = m_TreeNode->GetChildren(0);
typename TreeChildrenListType::const_iterator it = children->begin();
typename TreeChildrenListType::const_iterator itEnd = children->end();
while ( it != itEnd )
{
( *it )->Get()->SetBoundingBoxChildrenDepth(m_BoundingBoxChildrenDepth - 1);
( *it )->Get()->SetBoundingBoxChildrenName(m_BoundingBoxChildrenName);
( *it )->Get()->ComputeBoundingBox();
// If the bounding box is not defined we set the minimum and maximum
bool bbDefined = false;
for ( unsigned int i = 0; i < m_Dimension; i++ )
{
if ( m_Bounds->GetBounds()[2 * i] != 0
|| m_Bounds->GetBounds()[2 * i + 1] != 0 )
{
bbDefined = true;
break;
}
}
if ( !bbDefined )
{
m_Bounds->SetMinimum( ( *it )->Get()->GetBoundingBox()->GetMinimum() );
m_Bounds->SetMaximum( ( *it )->Get()->GetBoundingBox()->GetMaximum() );
}
else
{
m_Bounds->ConsiderPoint( ( *it )->Get()->GetBoundingBox()->GetMinimum() );
m_Bounds->ConsiderPoint( ( *it )->Get()->GetBoundingBox()->GetMaximum() );
}
it++;
}
delete children;
return true;
}
typename BoundingBoxType::PointType pnt;
pnt.Fill(NumericTraits< typename
BoundingBoxType::PointType::ValueType >::Zero);
m_Bounds->SetMinimum(pnt);
m_Bounds->SetMaximum(pnt);
m_BoundsMTime = this->GetMTime();
return false;
}
/** Get the children list.
* User is responsible for freeing the list, but not the elements of
* the list. */
template< unsigned int TDimension >
typename SpatialObject< TDimension >::ChildrenListType *
SpatialObject< TDimension >
::GetChildren(unsigned int depth, char *name) const
{
if ( !m_TreeNode )
{
return 0;
}
typename TreeNodeType::ChildrenListType * children =
m_TreeNode->GetChildren(depth, name);
typename TreeNodeType::ChildrenListType::const_iterator it =
children->begin();
ChildrenListType *childrenSO = new ChildrenListType;
while ( it != children->end() )
{
childrenSO->push_back( ( *it )->Get() );
it++;
}
delete children;
return childrenSO;
}
/** Set children list */
template< unsigned int TDimension >
void
SpatialObject< TDimension >
::SetChildren(ChildrenListType & children)
{
// Add children
typename ChildrenListType::iterator it = children.begin();
typename ChildrenListType::iterator itEnd = children.end();
while ( it != itEnd )
{
static_cast< TreeNodeType * >(
m_TreeNode.GetPointer() )->AddChild( ( *it )->GetModifiableTreeNode() );
it++;
}
}
/** Get the number of children */
template< unsigned int TDimension >
unsigned int
SpatialObject< TDimension >
::GetNumberOfChildren(unsigned int depth, char *name) const
{
return m_TreeNode->GetNumberOfChildren(depth, name);
}
/** Return the Modified time of the LocalToGlobalTransform */
template< unsigned int TDimension >
unsigned long
SpatialObject< TDimension >
::GetTransformMTime(void)
{
return m_ObjectToParentTransform->GetMTime();
}
/** Return the Modified time of the GlobalToLocalTransform */
template< unsigned int TDimension >
unsigned long
SpatialObject< TDimension >
::GetWorldTransformMTime(void)
{
return m_IndexToWorldTransform->GetMTime();
}
/** Get the parent of the spatial object */
template< unsigned int TDimension >
SpatialObject< TDimension > *
SpatialObject< TDimension >
::GetParent(void)
{
if ( m_TreeNode->HasParent() )
{
return m_TreeNode->GetParent()->Get();
}
return NULL;
}
/** Get the parent of the spatial object */
template< unsigned int TDimension >
const SpatialObject< TDimension > *
SpatialObject< TDimension >
::GetParent(void) const
{
if ( m_TreeNode->HasParent() )
{
return m_TreeNode->GetParent()->Get();
}
return NULL;
}
/** Set the parent of the spatial object */
template< unsigned int TDimension >
void
SpatialObject< TDimension >
::SetParent(Self *parent)
{
if ( !parent )
{
m_TreeNode->SetParent(NULL);
}
else
{
m_TreeNode->SetParent( parent->GetTreeNode() );
}
}
/** Return true if the spatial object has a parent */
template< unsigned int TDimension >
bool
SpatialObject< TDimension >
::HasParent(void) const
{
return m_TreeNode->HasParent();
}
/** Set the largest possible region */
template< unsigned int TDimension >
void
SpatialObject< TDimension >
::SetLargestPossibleRegion(const RegionType & region)
{
if ( m_LargestPossibleRegion != region )
{
m_LargestPossibleRegion = region;
this->Modified();
}
}
/** Update the Output information */
template< unsigned int TDimension >
void SpatialObject< TDimension >
::UpdateOutputInformation()
{
if ( this->GetSource() )
{
this->GetSource()->UpdateOutputInformation();
}
// If we don't have a source, then let's make our Image
// span our buffer
else
{
m_LargestPossibleRegion = m_BufferedRegion;
}
// Now we should know what our largest possible region is. If our
// requested region was not set yet, (or has been set to something
// invalid - with no data in it ) then set it to the largest possible
// region.
if ( m_RequestedRegion.GetNumberOfPixels() == 0 )
{
this->SetRequestedRegionToLargestPossibleRegion();
}
}
template< unsigned int TDimension >
void
SpatialObject< TDimension >
::SetRequestedRegionToLargestPossibleRegion()
{
m_RequestedRegion = m_LargestPossibleRegion;
}
template< unsigned int TDimension >
bool
SpatialObject< TDimension >
::RequestedRegionIsOutsideOfTheBufferedRegion()
{
unsigned int i;
const IndexType & requestedRegionIndex = m_RequestedRegion.GetIndex();
const IndexType & bufferedRegionIndex = m_BufferedRegion.GetIndex();
const SizeType & requestedRegionSize = m_RequestedRegion.GetSize();
const SizeType & bufferedRegionSize = m_BufferedRegion.GetSize();
for ( i = 0; i < m_Dimension; i++ )
{
if ( ( requestedRegionIndex[i] < bufferedRegionIndex[i] )
|| ( ( requestedRegionIndex[i] + static_cast< OffsetValueType >( requestedRegionSize[i] ) )
> ( bufferedRegionIndex[i]
+ static_cast< OffsetValueType >( bufferedRegionSize[i] ) ) ) )
{
return true;
}
}
return false;
}
template< unsigned int TDimension >
void
SpatialObject< TDimension >
::SetBufferedRegion(const RegionType & region)
{
if ( m_BufferedRegion != region )
{
m_BufferedRegion = region;
this->ComputeOffsetTable();
this->Modified();
}
}
template< unsigned int TDimension >
bool
SpatialObject< TDimension >
::VerifyRequestedRegion()
{
bool retval = true;
unsigned int i;
// Is the requested region within the LargestPossibleRegion?
// Note that the test is indeed against the largest possible region
// rather than the buffered region; see DataObject::VerifyRequestedRegion.
const IndexType & requestedRegionIndex = m_RequestedRegion.GetIndex();
const IndexType & largestPossibleRegionIndex =
m_LargestPossibleRegion.GetIndex();
const SizeType & requestedRegionSize = m_RequestedRegion.GetSize();
const SizeType & largestPossibleRegionSize = m_LargestPossibleRegion.GetSize();
for ( i = 0; i < m_Dimension; i++ )
{
if ( ( requestedRegionIndex[i] < largestPossibleRegionIndex[i] )
|| ( ( requestedRegionIndex[i] + static_cast< OffsetValueType >( requestedRegionSize[i] ) )
> ( largestPossibleRegionIndex[i]
+ static_cast< OffsetValueType >( largestPossibleRegionSize[i] ) ) ) )
{
retval = false;
}
}
return retval;
}
template< unsigned int TDimension >
void
SpatialObject< TDimension >
::SetRequestedRegion(const RegionType & region)
{
if ( m_RequestedRegion != region )
{
m_RequestedRegion = region;
this->Modified();
}
}
template< unsigned int TDimension >
void
SpatialObject< TDimension >
::SetRequestedRegion(const DataObject *data)
{
const SpatialObject *imgData = dynamic_cast< const SpatialObject * >( data );
if ( imgData )
{
m_RequestedRegion = imgData->GetRequestedRegion();
}
else
{
// pointer could not be cast back down
itkExceptionMacro(
<< "itk::ImageBase::SetRequestedRegion(const DataObject *) cannot cast "
<< typeid( data ).name() << " to " << typeid( SpatialObject * ).name() );
}
}
template< unsigned int TDimension >
void
SpatialObject< TDimension >
::ComputeOffsetTable()
{
OffsetValueType num = 1;
const SizeType & bufferSize = m_BufferedRegion.GetSize();
m_OffsetTable[0] = static_cast< OffsetValueType >( num );
for ( unsigned int i = 0; i < m_Dimension; i++ )
{
num *= bufferSize[i];
m_OffsetTable[i + 1] = static_cast< OffsetValueType >( num );
}
}
template< unsigned int TDimension >
typename SpatialObject< TDimension >::PropertyType *
SpatialObject< TDimension >
::GetProperty(void)
{
return m_Property;
}
template< unsigned int TDimension >
void
SpatialObject< TDimension >
::SetProperty(PropertyType *property)
{
m_Property = property;
}
template< unsigned int TDimension >
void
SpatialObject< TDimension >
::Update(void)
{
Superclass::Update();
/** This is probably not correct and should be removed */
this->Modified();
}
template< unsigned int TDimension >
bool
SpatialObject< TDimension >
::SetInternalInverseTransformToWorldToIndexTransform() const
{
if ( !this->GetIndexToWorldTransform()->GetInverse(
const_cast< TransformType * >( this->GetInternalInverseTransform() ) ) )
{
return false;
}
return true;
}
template< unsigned int TDimension >
void
SpatialObject< TDimension >
::SetNodeToParentNodeTransform(TransformType *transform)
{
if ( !m_TreeNode )
{
static_cast< TreeNodeType * >(
m_TreeNode.GetPointer() )->SetNodeToParentNodeTransform(transform);
}
}
template< unsigned int TDimension >
typename SpatialObject< TDimension >::TransformType *
SpatialObject< TDimension >
::GetNodeToParentNodeTransform(void)
{
if ( m_TreeNode )
{
return static_cast< TreeNodeType * >(
m_TreeNode.GetPointer() )->GetNodeToParentNodeTransform();
}
return NULL;
}
template< unsigned int TDimension >
const typename SpatialObject< TDimension >::TransformType *
SpatialObject< TDimension >
::GetNodeToParentNodeTransform(void) const
{
if ( m_TreeNode )
{
return static_cast< TreeNodeType * >(
m_TreeNode.GetPointer() )->GetNodeToParentNodeTransform();
}
return NULL;
}
/** Return the type of the spatial object as a string
* This is used by the SpatialObjectFactory */
template< unsigned int TDimension >
std::string
SpatialObject< TDimension >::GetSpatialObjectTypeAsString() const
{
std::ostringstream n;
n << GetNameOfClass();
n << "_";
n << TDimension;
return n.str();
}
/** Copy the information from another spatial object */
template< unsigned int TDimension >
void SpatialObject< TDimension >
::CopyInformation(const DataObject *data)
{
// Standard call to the superclass' method
Superclass::CopyInformation(data);
// Attempt to cast data to an ImageBase
const SpatialObject *imgData;
imgData = dynamic_cast< const SpatialObject * >( data );
if ( imgData )
{
// Copy the meta data for this data type
m_LargestPossibleRegion = imgData->GetLargestPossibleRegion();
}
else
{
// pointer could not be cast back down
itkExceptionMacro( << "itk::SpatialObject::CopyInformation() cannot cast "
<< typeid( data ).name() << " to "
<< typeid( SpatialObject * ).name() );
}
// check if we are the same type
const Self *source = dynamic_cast< const Self * >( data );
if ( !source )
{
std::cout << "CopyInformation: objects are not of the same type"
<< std::endl;
return;
}
// copy the properties
this->GetProperty()->SetRed( source->GetProperty()->GetRed() );
this->GetProperty()->SetGreen( source->GetProperty()->GetGreen() );
this->GetProperty()->SetBlue( source->GetProperty()->GetBlue() );
this->GetProperty()->SetAlpha( source->GetProperty()->GetAlpha() );
this->GetProperty()->SetName( source->GetProperty()->GetName().c_str() );
// copy the ivars
this->SetId( source->GetId() );
this->SetParentId( source->GetParentId() );
}
} // end of namespace itk
#endif // __SpatialObject_hxx
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