libinsighttoolkit3-dev 3.20.1-1 / usr / include / InsightToolkit / Common / itkMatrixOffsetTransformBase.h

/*=========================================================================

  Program:   Insight Segmentation & Registration Toolkit
  Module:    itkMatrixOffsetTransformBase.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.

     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 __itkMatrixOffsetTransformBase_h
#define __itkMatrixOffsetTransformBase_h

#include <iostream>

#include "itkMatrix.h"
#include "itkTransform.h"
#include "itkExceptionObject.h"
#include "itkMacro.h"

namespace itk
{


/**
 * Matrix and Offset transformation of a vector space (e.g. space coordinates)
 *
 * This class serves as a base class for transforms that can be expressed
 * as a linear transformation plus a constant offset (e.g., affine, similarity
 * and rigid transforms).   This base class also provides the concept of
 * using a center of rotation and a translation instead of an offset.
 *
 * As derived instances of this class are specializations of an affine
 * transform, any two of these transformations may be composed and the result 
 * is an affine transformation.  However, the order is important.
 * Given two affine transformations T1 and T2, we will say that
 * "precomposing T1 with T2" yields the transformation which applies
 * T1 to the source, and then applies T2 to that result to obtain the
 * target.  Conversely, we will say that "postcomposing T1 with T2"
 * yields the transformation which applies T2 to the source, and then
 * applies T1 to that result to obtain the target.  (Whether T1 or T2
 * comes first lexicographically depends on whether you choose to
 * write mappings from right-to-left or vice versa; we avoid the whole
 * problem by referring to the order of application rather than the
 * textual order.)
 *
 * There are three template parameters for this class:
 *
 * ScalarT       The type to be used for scalar numeric values.  Either
 *               float or double.
 *
 * NInputDimensions   The number of dimensions of the input vector space.
 *
 * NOutputDimensions   The number of dimensions of the output vector space.
 *
 * This class provides several methods for setting the matrix and offset
 * defining the transform. To support the registration framework, the 
 * transform parameters can also be set as an Array<double> of size
 * (NInputDimension + 1) * NOutputDimension using method SetParameters(). 
 * The first (NOutputDimension x NInputDimension) parameters defines the
 * matrix in row-major order (where the column index varies the fastest). 
 * The last NOutputDimension parameters defines the translation 
 * in each dimensions.
 *
 * \ingroup Transforms
 *
 */

template <
  class TScalarType=double,         // Data type for scalars 
  unsigned int NInputDimensions=3,  // Number of dimensions in the input space
  unsigned int NOutputDimensions=3> // Number of dimensions in the output space
class MatrixOffsetTransformBase 
  : public Transform< TScalarType, NInputDimensions, NOutputDimensions >
{
public:
  /** Standard typedefs   */
  typedef MatrixOffsetTransformBase             Self;
  typedef Transform< TScalarType,
                     NInputDimensions,
                     NOutputDimensions >        Superclass;
  typedef SmartPointer<Self>                    Pointer;
  typedef SmartPointer<const Self>              ConstPointer;
  
  /** Run-time type information (and related methods).   */
  itkTypeMacro( MatrixOffsetTransformBase, Transform );

  /** New macro for creation of through a Smart Pointer   */
  itkNewMacro( Self );

  /** Dimension of the domain space. */
  itkStaticConstMacro(InputSpaceDimension, unsigned int, NInputDimensions);
  itkStaticConstMacro(OutputSpaceDimension, unsigned int, NOutputDimensions);
  itkStaticConstMacro(ParametersDimension, unsigned int,
                      NOutputDimensions*(NInputDimensions+1));

  
  /** Parameters Type   */
  typedef typename Superclass::ParametersType                  ParametersType;
  typedef typename Superclass::ParametersValueType             ParametersValueType;

  /** Jacobian Type   */
  typedef typename Superclass::JacobianType                    JacobianType;

  /** Standard scalar type for this class */
  typedef typename Superclass::ScalarType                      ScalarType;

  /** Standard vector type for this class   */
  typedef Vector<TScalarType,
                 itkGetStaticConstMacro(InputSpaceDimension)>  InputVectorType;
  typedef Vector<TScalarType,
                 itkGetStaticConstMacro(OutputSpaceDimension)> OutputVectorType;
  typedef typename OutputVectorType::ValueType                 OutputVectorValueType;
  
  /** Standard covariant vector type for this class   */
  typedef CovariantVector<TScalarType,
                          itkGetStaticConstMacro(InputSpaceDimension)>  
                                                    InputCovariantVectorType;
  typedef CovariantVector<TScalarType,
                          itkGetStaticConstMacro(OutputSpaceDimension)>  
                                                    OutputCovariantVectorType;
  
  /** Standard vnl_vector type for this class   */
  typedef vnl_vector_fixed<TScalarType,
                           itkGetStaticConstMacro(InputSpaceDimension)> 
                                                    InputVnlVectorType;
  typedef vnl_vector_fixed<TScalarType,
                           itkGetStaticConstMacro(OutputSpaceDimension)> 
                                                    OutputVnlVectorType;
  
  /** Standard coordinate point type for this class   */
  typedef Point<TScalarType,
                itkGetStaticConstMacro(InputSpaceDimension)>   
                                                    InputPointType;
  typedef typename InputPointType::ValueType        InputPointValueType;
  typedef Point<TScalarType,
                itkGetStaticConstMacro(OutputSpaceDimension)>  
                                                    OutputPointType;
  typedef typename OutputPointType::ValueType       OutputPointValueType;
  
  /** Standard matrix type for this class   */
  typedef Matrix<TScalarType, itkGetStaticConstMacro(OutputSpaceDimension),
                 itkGetStaticConstMacro(InputSpaceDimension)>  
                                                    MatrixType;
  typedef typename MatrixType::ValueType            MatrixValueType;

  /** Standard inverse matrix type for this class   */
  typedef Matrix<TScalarType, itkGetStaticConstMacro(InputSpaceDimension),
                 itkGetStaticConstMacro(OutputSpaceDimension)> 
                                                    InverseMatrixType;

  typedef InputPointType                            CenterType;

  typedef OutputVectorType                          OffsetType;
  typedef typename OffsetType::ValueType            OffsetValueType;

  typedef OutputVectorType                          TranslationType;

  typedef typename TranslationType::ValueType       TranslationValueType;

  /** 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;

  /** Set the transformation to an Identity
   *
   * This sets the matrix to identity and the Offset to null. */
  virtual void SetIdentity( void );

  /** Set matrix of an MatrixOffsetTransformBase
   *
   * This method sets the matrix of an MatrixOffsetTransformBase to a
   * value specified by the user. 
   *
   * This updates the Offset wrt to current translation
   * and center.  See the warning regarding offset-versus-translation
   * in the documentation for SetCenter.
   *
   * To define an affine transform, you must set the matrix,
   * center, and translation OR the matrix and offset */
  virtual void SetMatrix(const MatrixType &matrix)
    {
    m_Matrix = matrix; this->ComputeOffset();
    this->ComputeMatrixParameters();
    m_MatrixMTime.Modified(); this->Modified(); return;
    }

  /** Get matrix of an MatrixOffsetTransformBase
   *
   * This method returns the value of the matrix of the
   * MatrixOffsetTransformBase. 
   * To define an affine transform, you must set the matrix,
   * center, and translation OR the matrix and offset */
  const MatrixType & GetMatrix() const
    { return m_Matrix; }

  /** Set offset (origin) of an MatrixOffset TransformBase.
   *
   * This method sets the offset of an MatrixOffsetTransformBase to a
   * value specified by the user.
   * This updates Translation wrt current center.  See the warning regarding
   * offset-versus-translation in the documentation for SetCenter.
   * To define an affine transform, you must set the matrix,
   * center, and translation OR the matrix and offset */
  void SetOffset(const OutputVectorType &offset)
    {
    m_Offset = offset; this->ComputeTranslation();
    this->Modified(); return;
    }

  /** Get offset of an MatrixOffsetTransformBase
   *
   * This method returns the offset value of the MatrixOffsetTransformBase.
   * To define an affine transform, you must set the matrix,
   * center, and translation OR the matrix and offset */
  const OutputVectorType & GetOffset(void) const
    { return m_Offset; }

  /** Set center of rotation of an MatrixOffsetTransformBase
   *
   * This method sets the center of rotation of an MatrixOffsetTransformBase 
   * to a fixed point - for most transforms derived from this class, 
   * this point is not a "parameter" of the transform - the exception is that
   * "centered" transforms have center as a parameter during optimization.
   *
   * This method updates offset wrt to current translation and matrix.
   * That is, changing the center changes the transform!
   *
   * WARNING: When using the Center, we strongly recommend only changing the
   * matrix and translation to define a transform.   Changing a transform's
   * center, changes the mapping between spaces - specifically, translation is
   * not changed with respect to that new center, and so the offset is updated
   * to * maintain the consistency with translation.   If a center is not used,
   * or is set before the matrix and the offset, then it is safe to change the
   * offset directly.
   *        As a rule of thumb, if you wish to set the center explicitly, set
   * before Offset computations are done.
   *
   * To define an affine transform, you must set the matrix,
   * center, and translation OR the matrix and offset */
  void SetCenter(const InputPointType & center)
    {
    m_Center = center; this->ComputeOffset();
    this->Modified(); return;
    }

  /** Get center of rotation of the MatrixOffsetTransformBase
   *
   * This method returns the point used as the fixed
   * center of rotation for the MatrixOffsetTransformBase. 
   * To define an affine transform, you must set the matrix,
   * center, and translation OR the matrix and offset */
  const InputPointType & GetCenter() const
    { return m_Center; }

  /** Set translation of an MatrixOffsetTransformBase
   *
   * This method sets the translation of an MatrixOffsetTransformBase.
   * This updates Offset to reflect current translation.
   * To define an affine transform, you must set the matrix,
   * center, and translation OR the matrix and offset */
  void SetTranslation(const OutputVectorType & translation)
    {
    m_Translation = translation; this->ComputeOffset();
    this->Modified(); return;
    }

  /** Get translation component of the MatrixOffsetTransformBase
   *
   * This method returns the translation used after rotation
   * about the center point. 
   * To define an affine transform, you must set the matrix,
   * center, and translation OR the matrix and offset */
  const OutputVectorType & GetTranslation(void) const
    {
    return m_Translation;
    }

  /** Set the transformation from a container of parameters.
   * The first (NOutputDimension x NInputDimension) parameters define the
   * matrix and the last NOutputDimension parameters the translation. 
   * Offset is updated based on current center. */
  void SetParameters( const ParametersType & parameters );

  /** Get the Transformation Parameters. */
  const ParametersType& GetParameters(void) const;

  /** Set the fixed parameters and update internal transformation. */
  virtual void SetFixedParameters( const ParametersType & );

  /** Get the Fixed Parameters. */
  virtual const ParametersType& GetFixedParameters(void) const;


  /** Compose with another MatrixOffsetTransformBase
   *
   * This method composes self with another MatrixOffsetTransformBase of the
   * same dimension, modifying self to be the composition of self
   * and other.  If the argument pre is true, then other is
   * precomposed with self; that is, the resulting transformation
   * consists of first applying other to the source, followed by
   * self.  If pre is false or omitted, then other is post-composed
   * with self; that is the resulting transformation consists of
   * first applying self to the source, followed by other. 
   * This updates the Translation based on current center. */
  void Compose(const Self * other, 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.  The TransformPoint method transforms its argument as
   * an affine point, whereas the TransformVector method transforms
   * its argument as a vector. */
  OutputPointType     TransformPoint(const InputPointType & point) const;
  OutputVectorType    TransformVector(const InputVectorType & vector) const;
  OutputVnlVectorType TransformVector(const InputVnlVectorType & vector) const;
  OutputCovariantVectorType TransformCovariantVector(
                                const InputCovariantVectorType &vector) const;
  
  /** Compute the Jacobian of the transformation
   *
   * This method computes the Jacobian matrix of the transformation.
   * given point or vector, returning the transformed point or
   * vector. The rank of the Jacobian will also indicate if the transform
   * is invertible at this point. */
  const JacobianType & GetJacobian(const InputPointType & point ) const;

  /** Create inverse of an affine transformation   
   *   
   * This populates the parameters an affine transform such that
   * the transform is the inverse of self. If self is not invertible,   
   * an exception is thrown.
   * Note that by default the inverese transform is centered at 
   * the origin. If you need to compute the inverse centered at a point, p,
   * 
   * \code
   * transform2->SetCenter( p );
   * transform1->GetInverse( transform2 );
   * \endcode
   *
   * transform2 will now contain the inverse of transform1 and will 
   * with its center set to p. Flipping the two statements will produce an 
   * incorrect transform. 
   *
   */
  bool GetInverse(Self * inverse) const;

  /** Return an inverse of this transform. */
  virtual InverseTransformBasePointer GetInverseTransform() const;

  /** \deprecated Use GetInverse instead.
   *
   * Method will eventually be made a protected member function */ 
  const InverseMatrixType & GetInverseMatrix( void ) const;

  /** Indicates that this transform is linear. That is, given two
   * points P and Q, and scalar coefficients a and b, then
   *
   *           T( a*P + b*Q ) = a * T(P) + b * T(Q)
   */
  virtual bool IsLinear() const { return true; }

protected:
  /** Construct an MatrixOffsetTransformBase object
   *
   * This method constructs a new MatrixOffsetTransformBase object and
   * initializes the matrix and offset parts of the transformation
   * to values specified by the caller.  If the arguments are
   * omitted, then the MatrixOffsetTransformBase is initialized to an identity
   * transformation in the appropriate number of dimensions. */
  MatrixOffsetTransformBase(const MatrixType &matrix,
                            const OutputVectorType &offset);
  MatrixOffsetTransformBase(unsigned int outputDims,
                            unsigned int paramDims);
  MatrixOffsetTransformBase();
  
  /** Destroy an MatrixOffsetTransformBase object */
  virtual ~MatrixOffsetTransformBase();

  /** Print contents of an MatrixOffsetTransformBase */
  void PrintSelf(std::ostream &s, Indent indent) const;

  const InverseMatrixType & GetVarInverseMatrix( void ) const
    { return m_InverseMatrix; }
  void SetVarInverseMatrix(const InverseMatrixType & matrix) const
    { m_InverseMatrix = matrix; m_InverseMatrixMTime.Modified(); }
  bool InverseMatrixIsOld(void) const
    {
    if(m_MatrixMTime != m_InverseMatrixMTime)
      {
      return true;
      }
    else
      {
      return false;
      }
    }

  virtual void ComputeMatrixParameters(void);

  virtual void ComputeMatrix(void);
  void SetVarMatrix(const MatrixType & matrix)
    { m_Matrix = matrix; m_MatrixMTime.Modified(); }

  virtual void ComputeTranslation(void);
  void SetVarTranslation(const OutputVectorType & translation)
    { m_Translation = translation; }

  virtual void ComputeOffset(void);
  void SetVarOffset(const OutputVectorType & offset)
    { m_Offset = offset; }

  void SetVarCenter(const InputPointType & center)
    { m_Center = center; }

private:

  MatrixOffsetTransformBase(const Self & other);
  const Self & operator=( const Self & );

 
  MatrixType                  m_Matrix;         // Matrix of the transformation
  OutputVectorType            m_Offset;         // Offset of the transformation
  mutable InverseMatrixType   m_InverseMatrix;  // Inverse of the matrix
  mutable bool                m_Singular;       // Is m_Inverse singular?

  InputPointType              m_Center;
  OutputVectorType            m_Translation;

  /** To avoid recomputation of the inverse if not needed */
  TimeStamp                   m_MatrixMTime;
  mutable TimeStamp           m_InverseMatrixMTime;

}; //class MatrixOffsetTransformBase

}  // namespace itk

// Define instantiation macro for this template.
#define ITK_TEMPLATE_MatrixOffsetTransformBase(_, EXPORT, x, y) namespace itk { \
  _(3(class EXPORT MatrixOffsetTransformBase< ITK_TEMPLATE_3 x >)) \
  namespace Templates { typedef MatrixOffsetTransformBase< ITK_TEMPLATE_3 x > MatrixOffsetTransformBase##y; } \
  }

#if ITK_TEMPLATE_EXPLICIT
# include "Templates/itkMatrixOffsetTransformBase+-.h"
#endif

#if ITK_TEMPLATE_TXX
# include "itkMatrixOffsetTransformBase.txx"
#endif

#endif /* __itkMatrixOffsetTransformBase_h */