/usr/include/ITK-4.5/itkTranslationTransform.h is in libinsighttoolkit4-dev 4.5.0-3.
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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 __itkTranslationTransform_h
#define __itkTranslationTransform_h
#include <iostream>
#include "itkTransform.h"
#include "itkMacro.h"
#include "itkMatrix.h"
namespace itk
{
/** \class TranslationTransform
* \brief Translation transformation of a vector space (e.g. space coordinates)
*
* The same functionality could be obtained by using the Affine transform,
* but with a large difference in performace.
*
* \ingroup ITKTransform
*
* \wiki
* \wikiexample{SimpleOperations/TranslationTransform,Translate an image}
* \wikiexample{VectorImages/VectorResampleImageFilter,Translate a vector image}
* \wikiexample{Registration/ImageRegistrationMethod,A basic global registration of two images}
* \wikiexample{Registration/MutualInformation,Mutual Information}
* \endwiki
*/
template <
typename TScalar = double, // Data type for scalars (float or
// double)
unsigned int NDimensions = 3>
// Number of dimensions
class TranslationTransform :
public Transform< TScalar, NDimensions, NDimensions >
{
public:
/** Standard class typedefs. */
typedef TranslationTransform Self;
typedef Transform< TScalar, NDimensions, NDimensions > Superclass;
typedef SmartPointer< Self > Pointer;
typedef SmartPointer< const Self > ConstPointer;
/** New macro for creation of through the object factory. */
itkNewMacro(Self);
/** Run-time type information (and related methods). */
itkTypeMacro(TranslationTransform, Transform);
/** Dimension of the domain space. */
itkStaticConstMacro(SpaceDimension, unsigned int, NDimensions);
itkStaticConstMacro(ParametersDimension, unsigned int, NDimensions);
/** Standard scalar type for this class. */
typedef typename Superclass::ScalarType ScalarType;
/** Standard parameters container. */
typedef typename Superclass::ParametersType ParametersType;
/** Standard Jacobian container. */
typedef typename Superclass::JacobianType JacobianType;
/** The number of parameters defininig this transform. */
typedef typename Superclass::NumberOfParametersType NumberOfParametersType;
/** Standard vector type for this class. */
typedef Vector<TScalar, NDimensions> InputVectorType;
typedef Vector<TScalar, NDimensions> OutputVectorType;
/** Standard covariant vector type for this class. */
typedef CovariantVector<TScalar, NDimensions> InputCovariantVectorType;
typedef CovariantVector<TScalar, NDimensions> OutputCovariantVectorType;
/** Standard vnl_vector type for this class. */
typedef vnl_vector_fixed<TScalar, NDimensions> InputVnlVectorType;
typedef vnl_vector_fixed<TScalar, NDimensions> OutputVnlVectorType;
/** Standard coordinate point type for this class. */
typedef Point<TScalar, NDimensions> InputPointType;
typedef Point<TScalar, NDimensions> OutputPointType;
/** Base inverse transform type. This type should not be changed to the
* concrete inverse transform type or inheritance would be lost.*/
typedef typename Superclass::InverseTransformBaseType InverseTransformBaseType;
typedef typename InverseTransformBaseType::Pointer InverseTransformBasePointer;
/** Transform category type. */
typedef typename Superclass::TransformCategoryType TransformCategoryType;
/** This method returns the value of the offset of the
* TranslationTransform. */
const OutputVectorType & GetOffset(void) const
{
return m_Offset;
}
/** This method sets the parameters for the transform
* value specified by the user. */
void SetParameters(const ParametersType & parameters);
/** Get the Transformation Parameters. */
virtual const ParametersType & GetParameters(void) const;
/** Set offset of an Translation Transform.
* This method sets the offset of an TranslationTransform to a
* value specified by the user. */
void SetOffset(const OutputVectorType & offset)
{
m_Offset = offset; return;
}
/** Compose with another TranslationTransform. */
void Compose(const Self *other, bool pre = 0);
/** Compose affine transformation with a translation.
* This method modifies self to include a translation of the
* origin. The translation is precomposed with self if pre is
* true, and postcomposed otherwise. */
void Translate(const OutputVectorType & offset, bool pre = 0);
/** Transform by an affine transformation.
* This method applies the affine transform given by self to a
* given point or vector, returning the transformed point or
* vector. */
OutputPointType TransformPoint(const InputPointType & point) const;
using Superclass::TransformVector;
OutputVectorType TransformVector(const InputVectorType & vector) const;
OutputVnlVectorType TransformVector(const InputVnlVectorType & vector) const;
using Superclass::TransformCovariantVector;
OutputCovariantVectorType TransformCovariantVector(const InputCovariantVectorType & vector) const;
/** This method finds the point or vector that maps to a given
* point or vector under the affine transformation defined by
* self. If no such point exists, an exception is thrown. */
inline InputPointType BackTransform(const OutputPointType & point) const;
inline InputVectorType BackTransform(const OutputVectorType & vector) const;
inline InputVnlVectorType BackTransform(const OutputVnlVectorType & vector) const;
inline InputCovariantVectorType BackTransform(const OutputCovariantVectorType & vector) const;
/** Find inverse of an affine transformation.
* This method creates and returns a new TranslationTransform object
* which is the inverse of self. If self is not invertible,
* false is returned. */
bool GetInverse(Self *inverse) const;
/** Return an inverse of this transform. */
virtual InverseTransformBasePointer GetInverseTransform() const;
/** Compute the Jacobian Matrix of the transformation at one point */
virtual void ComputeJacobianWithRespectToParameters(const InputPointType & point, JacobianType & j) const;
/** Get the jacobian with respect to position, which simply is an identity
* jacobian because the transform is position-invariant.
* jac will be resized as needed, but it will be more efficient if
* it is already properly sized. */
virtual void ComputeJacobianWithRespectToPosition(const InputPointType & x, JacobianType & jac) const;
/** Set the parameters to the IdentityTransform */
void SetIdentity(void);
/** Return the number of parameters that completely define the Transfom */
virtual NumberOfParametersType GetNumberOfParameters(void) const
{
return NDimensions;
}
/** Indicates that this transform is linear. That is, given two
* points P and Q, and scalar coefficients a and b, then
*
* \f[ T( a*P + b*Q ) = a * T(P) + b * T(Q) \f]
*/
virtual bool IsLinear() const
{
return true;
}
/** Indicates the category transform.
* e.g. an affine transform, or a local one, e.g. a deformation field.
*/
virtual TransformCategoryType GetTransformCategory() const
{
return Self::Linear;
}
/** Set the fixed parameters and update internal transformation.
* The Translation Transform does not require fixed parameters,
* therefore the implementation of this method is a null operation. */
virtual void SetFixedParameters(const ParametersType &)
{
}
/** Get the Fixed Parameters. The TranslationTransform does not
* require Fixed parameters, therefore this method returns an
* parameters array of size zero. */
virtual const ParametersType & GetFixedParameters(void) const
{
this->m_FixedParameters.SetSize(0);
return this->m_FixedParameters;
}
protected:
TranslationTransform();
~TranslationTransform();
/** Print contents of an TranslationTransform. */
void PrintSelf(std::ostream & os, Indent indent) const;
private:
TranslationTransform(const Self &); // purposely not implemented
void operator=(const Self &); // purposely not implemented
JacobianType m_IdentityJacobian;
OutputVectorType m_Offset; // Offset of the transformation
}; // class TranslationTransform
// Back transform a point
template <typename TScalar, unsigned int NDimensions>
inline
typename TranslationTransform<TScalar, NDimensions>::InputPointType
TranslationTransform<TScalar, NDimensions>::BackTransform(const OutputPointType & point) const
{
return point - m_Offset;
}
// Back transform a vector
template <typename TScalar, unsigned int NDimensions>
inline
typename TranslationTransform<TScalar, NDimensions>::InputVectorType
TranslationTransform<TScalar, NDimensions>::BackTransform(const OutputVectorType & vect) const
{
return vect;
}
// Back transform a vnl_vector
template <typename TScalar, unsigned int NDimensions>
inline
typename TranslationTransform<TScalar, NDimensions>::InputVnlVectorType
TranslationTransform<TScalar, NDimensions>::BackTransform(const OutputVnlVectorType & vect) const
{
return vect;
}
// Back Transform a CovariantVector
template <typename TScalar, unsigned int NDimensions>
inline
typename TranslationTransform<TScalar, NDimensions>::InputCovariantVectorType
TranslationTransform<TScalar, NDimensions>::BackTransform(const OutputCovariantVectorType & vect) const
{
return vect;
}
} // namespace itk
#ifndef ITK_MANUAL_INSTANTIATION
#include "itkTranslationTransform.hxx"
#endif
#endif /* __itkTranslationTransform_h */
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