diff --git a/Core/Code/DataManagement/mitkGeometry3D.cpp b/Core/Code/DataManagement/mitkGeometry3D.cpp
index 9097504659..db747c6914 100644
--- a/Core/Code/DataManagement/mitkGeometry3D.cpp
+++ b/Core/Code/DataManagement/mitkGeometry3D.cpp
@@ -1,909 +1,909 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 
 
 #include <sstream>
 #include <iomanip>
 
 #include "mitkGeometry3D.h"
 #include "mitkMatrixConvert.h"
 #include "mitkRotationOperation.h"
 #include "mitkRestorePlanePositionOperation.h"
 #include "mitkPointOperation.h"
 #include "mitkInteractionConst.h"
 
 #include <vtkMatrixToLinearTransform.h>
 #include <vtkMatrix4x4.h>
 
 // Standard constructor for the New() macro. Sets the geometry to 3 dimensions
 mitk::Geometry3D::Geometry3D()
   : m_ParametricBoundingBox(NULL),
     m_ImageGeometry(false), m_Valid(true), m_FrameOfReferenceID(0), m_IndexToWorldTransformLastModified(0)
 {
   FillVector3D(m_FloatSpacing, 1,1,1);
   m_VtkMatrix = vtkMatrix4x4::New();
   m_VtkIndexToWorldTransform = vtkMatrixToLinearTransform::New();
   m_VtkIndexToWorldTransform->SetInput(m_VtkMatrix);
   Initialize();
 }
 mitk::Geometry3D::Geometry3D(const Geometry3D& other) : Superclass(), mitk::OperationActor(), m_ParametricBoundingBox(other.m_ParametricBoundingBox),m_TimeBounds(other.m_TimeBounds),
   m_ImageGeometry(other.m_ImageGeometry), m_Valid(other.m_Valid), m_FrameOfReferenceID(other.m_FrameOfReferenceID), m_IndexToWorldTransformLastModified(other.m_IndexToWorldTransformLastModified), m_RotationQuaternion( other.m_RotationQuaternion ) , m_Origin(other.m_Origin)
 {
   // AffineGeometryFrame
   SetBounds(other.GetBounds());
   //SetIndexToObjectTransform(other.GetIndexToObjectTransform());
   //SetObjectToNodeTransform(other.GetObjectToNodeTransform());
   //SetIndexToWorldTransform(other.GetIndexToWorldTransform());
   // this is not used in AffineGeometryFrame of ITK, thus there are not Get and Set methods
   // m_IndexToNodeTransform = other.m_IndexToNodeTransform;
   // m_InvertedTransform = TransformType::New();
   // m_InvertedTransform = TransformType::New();
   // m_InvertedTransform->DeepCopy(other.m_InvertedTransform);
   m_VtkMatrix = vtkMatrix4x4::New();
   m_VtkMatrix->DeepCopy(other.m_VtkMatrix);
   if (other.m_ParametricBoundingBox.IsNotNull())
   {
     m_ParametricBoundingBox = other.m_ParametricBoundingBox->DeepCopy();
   }
   FillVector3D(m_FloatSpacing,other.m_FloatSpacing[0],other.m_FloatSpacing[1],other.m_FloatSpacing[2]);
   m_VtkIndexToWorldTransform = vtkMatrixToLinearTransform::New();
   m_VtkIndexToWorldTransform->DeepCopy(other.m_VtkIndexToWorldTransform);
   m_VtkIndexToWorldTransform->SetInput(m_VtkMatrix);
   other.InitializeGeometry(this);
 }
 
 mitk::Geometry3D::~Geometry3D()
 {
   m_VtkMatrix->Delete();
   m_VtkIndexToWorldTransform->Delete();
 }
 
 
 static void CopySpacingFromTransform(mitk::AffineTransform3D* transform, mitk::Vector3D& spacing, float floatSpacing[3])
 {
   mitk::AffineTransform3D::MatrixType::InternalMatrixType vnlmatrix;
   vnlmatrix = transform->GetMatrix().GetVnlMatrix();
 
   spacing[0]=vnlmatrix.get_column(0).magnitude();
   spacing[1]=vnlmatrix.get_column(1).magnitude();
   spacing[2]=vnlmatrix.get_column(2).magnitude();
   floatSpacing[0]=spacing[0];
   floatSpacing[1]=spacing[1];
   floatSpacing[2]=spacing[2];
 }
 
 
 void mitk::Geometry3D::Initialize()
 {
   float b[6] = {0,1,0,1,0,1};
   SetFloatBounds(b);
 
   m_IndexToObjectTransform = TransformType::New();
   m_ObjectToNodeTransform = TransformType::New();
 
   if(m_IndexToWorldTransform.IsNull())
     m_IndexToWorldTransform = TransformType::New();
   else
     m_IndexToWorldTransform->SetIdentity();
   CopySpacingFromTransform(m_IndexToWorldTransform, m_Spacing, m_FloatSpacing);
   vtk2itk(m_IndexToWorldTransform->GetOffset(), m_Origin);
 
   m_VtkMatrix->Identity();
 
   m_TimeBounds[0]=ScalarTypeNumericTraits::NonpositiveMin(); m_TimeBounds[1]=ScalarTypeNumericTraits::max();
 
   m_FrameOfReferenceID = 0;
 
   m_ImageGeometry = false;
 }
 
 void mitk::Geometry3D::TransferItkToVtkTransform()
 {
   // copy m_IndexToWorldTransform into m_VtkIndexToWorldTransform
   TransferItkTransformToVtkMatrix(m_IndexToWorldTransform.GetPointer(), m_VtkMatrix);
   m_VtkIndexToWorldTransform->Modified();
 }
 
 void mitk::Geometry3D::TransferVtkToItkTransform()
 {
   TransferVtkMatrixToItkTransform(m_VtkMatrix, m_IndexToWorldTransform.GetPointer());
   CopySpacingFromTransform(m_IndexToWorldTransform, m_Spacing, m_FloatSpacing);
   vtk2itk(m_IndexToWorldTransform->GetOffset(), m_Origin);
 }
 
 void mitk::Geometry3D::SetIndexToWorldTransformByVtkMatrix(vtkMatrix4x4* vtkmatrix)
 {
   m_VtkMatrix->DeepCopy(vtkmatrix);
   TransferVtkToItkTransform();
 }
 
 void mitk::Geometry3D::SetTimeBounds(const TimeBounds& timebounds)
 {
   if(m_TimeBounds != timebounds)
   {
     m_TimeBounds = timebounds;
     Modified();
   }
 }
 
 void mitk::Geometry3D::SetFloatBounds(const float bounds[6])
 {
   mitk::BoundingBox::BoundsArrayType b;
   const float *input = bounds;
   int i=0;
   for(mitk::BoundingBox::BoundsArrayType::Iterator it = b.Begin(); i < 6 ;++i) *it++ = (mitk::ScalarType)*input++;
   SetBoundsArray(b, m_BoundingBox);
 }
 
 void mitk::Geometry3D::SetFloatBounds(const double bounds[6])
 {
   mitk::BoundingBox::BoundsArrayType b;
   const double *input = bounds;
   int i=0;
   for(mitk::BoundingBox::BoundsArrayType::Iterator it = b.Begin(); i < 6 ;++i) *it++ = (mitk::ScalarType)*input++;
   SetBoundsArray(b, m_BoundingBox);
 }
 
 void mitk::Geometry3D::SetParametricBounds(const BoundingBox::BoundsArrayType& bounds)
 {
   SetBoundsArray(bounds, m_ParametricBoundingBox);
 }
 
 void mitk::Geometry3D::WorldToIndex(const mitk::Point3D &pt_mm, mitk::Point3D &pt_units) const
 {
   BackTransform(pt_mm, pt_units);
 }
 
 void mitk::Geometry3D::IndexToWorld(const mitk::Point3D &pt_units, mitk::Point3D &pt_mm) const
 {
   pt_mm = m_IndexToWorldTransform->TransformPoint(pt_units);
 }
 
 void mitk::Geometry3D::WorldToIndex(const mitk::Point3D & /*atPt3d_mm*/, const mitk::Vector3D &vec_mm, mitk::Vector3D &vec_units) const
 {
   MITK_WARN<<"Warning! Call of the deprecated function Geometry3D::WorldToIndex(point, vec, vec). Use Geometry3D::WorldToIndex(vec, vec) instead!";
   //BackTransform(atPt3d_mm, vec_mm, vec_units);
   this->WorldToIndex(vec_mm, vec_units);
 }
 
 void mitk::Geometry3D::WorldToIndex( const mitk::Vector3D &vec_mm, mitk::Vector3D &vec_units) const
 {
   BackTransform( vec_mm, vec_units);
 }
 
 void mitk::Geometry3D::IndexToWorld(const mitk::Point3D &/*atPt3d_units*/, const mitk::Vector3D &vec_units, mitk::Vector3D &vec_mm) const
 {
   MITK_WARN<<"Warning! Call of the deprecated function Geometry3D::IndexToWorld(point, vec, vec). Use Geometry3D::IndexToWorld(vec, vec) instead!";
   //vec_mm = m_IndexToWorldTransform->TransformVector(vec_units);
   this->IndexToWorld(vec_units, vec_mm);
 }
 
 void mitk::Geometry3D::IndexToWorld(const mitk::Vector3D &vec_units, mitk::Vector3D &vec_mm) const
 {
   vec_mm = m_IndexToWorldTransform->TransformVector(vec_units);
 }
 
 void mitk::Geometry3D::SetIndexToWorldTransform(mitk::AffineTransform3D* transform)
 {
   if(m_IndexToWorldTransform.GetPointer() != transform)
   {
     Superclass::SetIndexToWorldTransform(transform);
     CopySpacingFromTransform(m_IndexToWorldTransform, m_Spacing, m_FloatSpacing);
     vtk2itk(m_IndexToWorldTransform->GetOffset(), m_Origin);
     TransferItkToVtkTransform();
     Modified();
   }
 }
 
 itk::LightObject::Pointer mitk::Geometry3D::InternalClone() const
 {
   Self::Pointer newGeometry = new Self(*this);
   newGeometry->UnRegister();
   return newGeometry.GetPointer();
 }
 /*
 void mitk::Geometry3D::InitializeGeometry(Geometry3D * newGeometry) const
 {
   Superclass::InitializeGeometry(newGeometry);
 
   newGeometry->SetTimeBounds(m_TimeBounds);
 
   //newGeometry->GetVtkTransform()->SetMatrix(m_VtkIndexToWorldTransform->GetMatrix()); IW
   //newGeometry->TransferVtkToItkTransform(); //MH
 
   newGeometry->SetFrameOfReferenceID(GetFrameOfReferenceID());
   newGeometry->m_ImageGeometry = m_ImageGeometry;
 }
 */
 void mitk::Geometry3D::SetExtentInMM(int direction, ScalarType extentInMM)
 {
   ScalarType len = GetExtentInMM(direction);
   if(fabs(len - extentInMM)>=mitk::eps)
   {
     AffineTransform3D::MatrixType::InternalMatrixType vnlmatrix;
     vnlmatrix = m_IndexToWorldTransform->GetMatrix().GetVnlMatrix();
     if(len>extentInMM)
       vnlmatrix.set_column(direction, vnlmatrix.get_column(direction)/len*extentInMM);
     else
       vnlmatrix.set_column(direction, vnlmatrix.get_column(direction)*extentInMM/len);
     Matrix3D matrix;
     matrix = vnlmatrix;
     m_IndexToWorldTransform->SetMatrix(matrix);
     Modified();
   }
 }
 
 mitk::BoundingBox::Pointer mitk::Geometry3D::CalculateBoundingBoxRelativeToTransform(const mitk::AffineTransform3D* transform) const
 {
   mitk::BoundingBox::PointsContainer::Pointer pointscontainer=mitk::BoundingBox::PointsContainer::New();
 
   mitk::BoundingBox::PointIdentifier pointid=0;
 
   unsigned char i;
   if(transform!=NULL)
   {
     mitk::AffineTransform3D::Pointer inverse = mitk::AffineTransform3D::New();
     transform->GetInverse(inverse);
     for(i=0; i<8; ++i)
       pointscontainer->InsertElement( pointid++, inverse->TransformPoint( GetCornerPoint(i) ));
   }
   else
   {
     for(i=0; i<8; ++i)
       pointscontainer->InsertElement( pointid++, GetCornerPoint(i) );
   }
 
   mitk::BoundingBox::Pointer result = mitk::BoundingBox::New();
   result->SetPoints(pointscontainer);
   result->ComputeBoundingBox();
 
   return result;
 }
 
 #include <vtkTransform.h>
 void mitk::Geometry3D::ExecuteOperation(Operation* operation)
 {
   vtkTransform *vtktransform = vtkTransform::New();
   vtktransform->SetMatrix(m_VtkMatrix);
   switch (operation->GetOperationType())
   {
   case OpNOTHING:
     break;
   case OpMOVE:
     {
       mitk::PointOperation *pointOp = dynamic_cast<mitk::PointOperation *>(operation);
       if (pointOp == NULL)
       {
         //mitk::StatusBar::GetInstance()->DisplayText("received wrong type of operation!See mitkAffineInteractor.cpp", 10000);
         return;
       }
       mitk::Point3D newPos = pointOp->GetPoint();
       ScalarType data[3];
       vtktransform->GetPosition(data);
       vtktransform->PostMultiply();
       vtktransform->Translate(newPos[0], newPos[1], newPos[2]);
       vtktransform->PreMultiply();
       break;
     }
   case OpSCALE:
     {
       mitk::PointOperation *pointOp = dynamic_cast<mitk::PointOperation *>(operation);
       if (pointOp == NULL)
       {
         //mitk::StatusBar::GetInstance()->DisplayText("received wrong type of operation!See mitkAffineInteractor.cpp", 10000);
         return;
       }
       mitk::Point3D newScale = pointOp->GetPoint();
       ScalarType data[3];
       /* calculate new scale: newscale = oldscale * (oldscale + scaletoadd)/oldscale */
       data[0] = 1 + (newScale[0] / GetMatrixColumn(0).magnitude());
       data[1] = 1 + (newScale[1] / GetMatrixColumn(1).magnitude());
       data[2] = 1 + (newScale[2] / GetMatrixColumn(2).magnitude());
 
       mitk::Point3D center = const_cast<mitk::BoundingBox*>(m_BoundingBox.GetPointer())->GetCenter();
       ScalarType pos[3];
       vtktransform->GetPosition(pos);
       vtktransform->PostMultiply();
       vtktransform->Translate(-pos[0], -pos[1], -pos[2]);
       vtktransform->Translate(-center[0], -center[1], -center[2]);
       vtktransform->PreMultiply();
       vtktransform->Scale(data[0], data[1], data[2]);
       vtktransform->PostMultiply();
       vtktransform->Translate(+center[0], +center[1], +center[2]);
       vtktransform->Translate(pos[0], pos[1], pos[2]);
       vtktransform->PreMultiply();
       break;
     }
   case OpROTATE:
     {
       mitk::RotationOperation *rotateOp = dynamic_cast<mitk::RotationOperation *>(operation);
       if (rotateOp == NULL)
       {
         //mitk::StatusBar::GetInstance()->DisplayText("received wrong type of operation!See mitkAffineInteractor.cpp", 10000);
         return;
       }
       Vector3D rotationVector = rotateOp->GetVectorOfRotation();
       Point3D center = rotateOp->GetCenterOfRotation();
       ScalarType angle = rotateOp->GetAngleOfRotation();
       vtktransform->PostMultiply();
       vtktransform->Translate(-center[0], -center[1], -center[2]);
       vtktransform->RotateWXYZ(angle, rotationVector[0], rotationVector[1], rotationVector[2]);
       vtktransform->Translate(center[0], center[1], center[2]);
       vtktransform->PreMultiply();
       break;
     }
   case OpRESTOREPLANEPOSITION:
   {
       //Copy necessary to avoid vtk warning
       vtkMatrix4x4* matrix = vtkMatrix4x4::New();
       TransferItkTransformToVtkMatrix(dynamic_cast<mitk::RestorePlanePositionOperation*>(operation)->GetTransform().GetPointer(), matrix);
       vtktransform->SetMatrix(matrix);
       break;
   }
 
   default:
     vtktransform->Delete();
     return;
   }
   m_VtkMatrix->DeepCopy(vtktransform->GetMatrix());
   TransferVtkToItkTransform();
   Modified();
   vtktransform->Delete();
 }
 
 void mitk::Geometry3D::BackTransform(const mitk::Point3D &in, mitk::Point3D& out) const
 {
   ScalarType temp[3];
   unsigned int i, j;
   const TransformType::OffsetType& offset = m_IndexToWorldTransform->GetOffset();
 
   // Remove offset
   for (j = 0; j < 3; j++)
   {
     temp[j] = in[j] - offset[j];
   }
 
   // Get WorldToIndex transform
   if (m_IndexToWorldTransformLastModified != m_IndexToWorldTransform->GetMTime())
   {
     m_InvertedTransform = TransformType::New();
     if (!m_IndexToWorldTransform->GetInverse( m_InvertedTransform.GetPointer() ))
     {
       itkExceptionMacro( "Internal ITK matrix inversion error, cannot proceed." );
     }
     m_IndexToWorldTransformLastModified = m_IndexToWorldTransform->GetMTime();
   }
 
   // Check for valid matrix inversion
   const TransformType::MatrixType& inverse = m_InvertedTransform->GetMatrix();
   if(inverse.GetVnlMatrix().has_nans())
   {
     itkExceptionMacro( "Internal ITK matrix inversion error, cannot proceed. Matrix was: " << std::endl
       << m_IndexToWorldTransform->GetMatrix() << "Suggested inverted matrix is:" << std::endl
       << inverse );
   }
 
   // Transform point
   for (i = 0; i < 3; i++)
   {
     out[i] = 0.0;
     for (j = 0; j < 3; j++)
     {
       out[i] += inverse[i][j]*temp[j];
     }
   }
 }
 
 void mitk::Geometry3D::BackTransform(const mitk::Point3D &/*at*/, const mitk::Vector3D &in, mitk::Vector3D& out) const
 {
   MITK_INFO<<"Warning! Call of the deprecated function Geometry3D::BackTransform(point, vec, vec). Use Geometry3D::BackTransform(vec, vec) instead!";
   //// Get WorldToIndex transform
   //if (m_IndexToWorldTransformLastModified != m_IndexToWorldTransform->GetMTime())
   //{
   //  m_InvertedTransform = TransformType::New();
   //  if (!m_IndexToWorldTransform->GetInverse( m_InvertedTransform.GetPointer() ))
   //  {
   //    itkExceptionMacro( "Internal ITK matrix inversion error, cannot proceed." );
   //  }
   //  m_IndexToWorldTransformLastModified = m_IndexToWorldTransform->GetMTime();
   //}
 
   //// Check for valid matrix inversion
   //const TransformType::MatrixType& inverse = m_InvertedTransform->GetMatrix();
   //if(inverse.GetVnlMatrix().has_nans())
   //{
   //  itkExceptionMacro( "Internal ITK matrix inversion error, cannot proceed. Matrix was: " << std::endl
   //    << m_IndexToWorldTransform->GetMatrix() << "Suggested inverted matrix is:" << std::endl
   //    << inverse );
   //}
 
   //// Transform vector
   //for (unsigned int i = 0; i < 3; i++)
   //{
   //  out[i] = 0.0;
   //  for (unsigned int j = 0; j < 3; j++)
   //  {
   //    out[i] += inverse[i][j]*in[j];
   //  }
   //}
   this->BackTransform(in, out);
 }
 
 void mitk::Geometry3D::BackTransform(const mitk::Vector3D& in, mitk::Vector3D& out) const
 {
   // Get WorldToIndex transform
   if (m_IndexToWorldTransformLastModified != m_IndexToWorldTransform->GetMTime())
   {
     m_InvertedTransform = TransformType::New();
     if (!m_IndexToWorldTransform->GetInverse( m_InvertedTransform.GetPointer() ))
     {
       itkExceptionMacro( "Internal ITK matrix inversion error, cannot proceed." );
     }
     m_IndexToWorldTransformLastModified = m_IndexToWorldTransform->GetMTime();
   }
 
   // Check for valid matrix inversion
   const TransformType::MatrixType& inverse = m_InvertedTransform->GetMatrix();
   if(inverse.GetVnlMatrix().has_nans())
   {
     itkExceptionMacro( "Internal ITK matrix inversion error, cannot proceed. Matrix was: " << std::endl
       << m_IndexToWorldTransform->GetMatrix() << "Suggested inverted matrix is:" << std::endl
       << inverse );
   }
 
   // Transform vector
   for (unsigned int i = 0; i < 3; i++)
   {
     out[i] = 0.0;
     for (unsigned int j = 0; j < 3; j++)
     {
       out[i] += inverse[i][j]*in[j];
     }
   }
 }
 
 const float* mitk::Geometry3D::GetFloatSpacing() const
 {
   return m_FloatSpacing;
 }
 
 void mitk::Geometry3D::SetSpacing(const mitk::Vector3D& aSpacing)
 {
   if(mitk::Equal(m_Spacing, aSpacing) == false)
   {
     assert(aSpacing[0]>0 && aSpacing[1]>0 && aSpacing[2]>0);
 
     m_Spacing = aSpacing;
 
     AffineTransform3D::MatrixType::InternalMatrixType vnlmatrix;
 
     vnlmatrix = m_IndexToWorldTransform->GetMatrix().GetVnlMatrix();
 
     mitk::VnlVector col;
     col = vnlmatrix.get_column(0); col.normalize(); col*=aSpacing[0]; vnlmatrix.set_column(0, col);
     col = vnlmatrix.get_column(1); col.normalize(); col*=aSpacing[1]; vnlmatrix.set_column(1, col);
     col = vnlmatrix.get_column(2); col.normalize(); col*=aSpacing[2]; vnlmatrix.set_column(2, col);
 
     Matrix3D matrix;
     matrix = vnlmatrix;
 
     AffineTransform3D::Pointer transform = AffineTransform3D::New();
     transform->SetMatrix(matrix);
     transform->SetOffset(m_IndexToWorldTransform->GetOffset());
 
     SetIndexToWorldTransform(transform.GetPointer());
 
     itk2vtk(m_Spacing, m_FloatSpacing);
   }
 }
 
 void mitk::Geometry3D::SetOrigin(const Point3D & origin)
 {
   if(origin!=GetOrigin())
   {
     m_Origin = origin;
     m_IndexToWorldTransform->SetOffset(m_Origin.GetVectorFromOrigin());
     Modified();
     TransferItkToVtkTransform();
   }
 }
 
 void mitk::Geometry3D::Translate(const Vector3D & vector)
 {
     if((vector[0] != 0) || (vector[1] != 0) || (vector[2] != 0))
     {
         this->SetOrigin(m_Origin + vector);
 //        m_IndexToWorldTransform->SetOffset(m_IndexToWorldTransform->GetOffset()+vector);
 //        TransferItkToVtkTransform();
 //        Modified();
     }
 }
 
 void mitk::Geometry3D::SetIdentity()
 {
   m_IndexToWorldTransform->SetIdentity();
   m_Origin.Fill(0);
   Modified();
   TransferItkToVtkTransform();
 }
 
 void mitk::Geometry3D::Compose( const mitk::AffineGeometryFrame3D::TransformType * other, bool pre )
 {
   m_IndexToWorldTransform->Compose(other, pre);
   CopySpacingFromTransform(m_IndexToWorldTransform, m_Spacing, m_FloatSpacing);
   vtk2itk(m_IndexToWorldTransform->GetOffset(), m_Origin);
   Modified();
   TransferItkToVtkTransform();
 }
 
 void mitk::Geometry3D::Compose( const vtkMatrix4x4 * vtkmatrix, bool pre )
 {
   mitk::AffineGeometryFrame3D::TransformType::Pointer itkTransform = mitk::AffineGeometryFrame3D::TransformType::New();
   TransferVtkMatrixToItkTransform(vtkmatrix, itkTransform.GetPointer());
   Compose(itkTransform, pre);
 }
 
 const std::string mitk::Geometry3D::GetTransformAsString( TransformType* transformType )
 {
   std::ostringstream out;
 
   out << '[';
 
   for( int i=0; i<3; ++i )
   {
     out << '[';
     for( int j=0; j<3; ++j )
       out << transformType->GetMatrix().GetVnlMatrix().get(i, j) << ' ';
     out << ']';
   }
 
   out << "][";
 
   for( int i=0; i<3; ++i )
     out << transformType->GetOffset()[i] << ' ';
 
   out << "]\0";
 
   return out.str();
 }
 
 void mitk::Geometry3D::PrintSelf(std::ostream& os, itk::Indent indent) const
 {
   os << indent << " IndexToWorldTransform: ";
   if(m_IndexToWorldTransform.IsNull())
     os << "NULL" << std::endl;
   else
   {
     // from itk::MatrixOffsetTransformBase
     unsigned int i, j;
     os << std::endl;
     os << indent << "Matrix: " << std::endl;
     for (i = 0; i < 3; i++)
     {
       os << indent.GetNextIndent();
       for (j = 0; j < 3; j++)
       {
         os << m_IndexToWorldTransform->GetMatrix()[i][j] << " ";
       }
       os << std::endl;
     }
 
     os << indent << "Offset: " << m_IndexToWorldTransform->GetOffset() << std::endl;
     os << indent << "Center: " << m_IndexToWorldTransform->GetCenter() << std::endl;
     os << indent << "Translation: " << m_IndexToWorldTransform->GetTranslation() << std::endl;
 
     os << indent << "Inverse: " << std::endl;
     for (i = 0; i < 3; i++)
     {
       os << indent.GetNextIndent();
       for (j = 0; j < 3; j++)
       {
         os << m_IndexToWorldTransform->GetInverseMatrix()[i][j] << " ";
       }
       os << std::endl;
     }
 
     // from itk::ScalableAffineTransform
     os << indent << "Scale : ";
     for (i = 0; i < 3; i++)
     {
       os << m_IndexToWorldTransform->GetScale()[i] << " ";
     }
     os << std::endl;
   }
 
   os << indent << " BoundingBox: ";
   if(m_BoundingBox.IsNull())
     os << "NULL" << std::endl;
   else
   {
     os << indent << "( ";
     for (unsigned int i=0; i<3; i++)
     {
       os << m_BoundingBox->GetBounds()[2*i] << "," << m_BoundingBox->GetBounds()[2*i+1] << " ";
     }
     os << " )" << std::endl;
   }
 
   os << indent << " Origin: " << m_Origin << std::endl;
   os << indent << " ImageGeometry: " << m_ImageGeometry << std::endl;
   os << indent << " Spacing: " << m_Spacing << std::endl;
   os << indent << " TimeBounds: " << m_TimeBounds << std::endl;
 }
 
 mitk::Point3D mitk::Geometry3D::GetCornerPoint(int id) const
 {
   assert(id >= 0);
   assert(m_BoundingBox.IsNotNull());
 
   BoundingBox::BoundsArrayType bounds = m_BoundingBox->GetBounds();
 
   Point3D cornerpoint;
   switch(id)
   {
   case 0: FillVector3D(cornerpoint, bounds[0],bounds[2],bounds[4]); break;
   case 1: FillVector3D(cornerpoint, bounds[0],bounds[2],bounds[5]); break;
   case 2: FillVector3D(cornerpoint, bounds[0],bounds[3],bounds[4]); break;
   case 3: FillVector3D(cornerpoint, bounds[0],bounds[3],bounds[5]); break;
   case 4: FillVector3D(cornerpoint, bounds[1],bounds[2],bounds[4]); break;
   case 5: FillVector3D(cornerpoint, bounds[1],bounds[2],bounds[5]); break;
   case 6: FillVector3D(cornerpoint, bounds[1],bounds[3],bounds[4]); break;
   case 7: FillVector3D(cornerpoint, bounds[1],bounds[3],bounds[5]); break;
   default:
     {
       itkExceptionMacro(<<"A cube only has 8 corners. These are labeled 0-7.");
     }
   }
   if(m_ImageGeometry)
   {
     // Here i have to adjust the 0.5 offset manually, because the cornerpoint is the corner of the
     // bounding box. The bounding box itself is no image, so it is corner-based
     FillVector3D(cornerpoint, cornerpoint[0]-0.5, cornerpoint[1]-0.5, cornerpoint[2]-0.5);
   }
   return m_IndexToWorldTransform->TransformPoint(cornerpoint);
 }
 
 mitk::Point3D mitk::Geometry3D::GetCornerPoint(bool xFront, bool yFront, bool zFront) const
 {
   assert(m_BoundingBox.IsNotNull());
   BoundingBox::BoundsArrayType bounds = m_BoundingBox->GetBounds();
 
   Point3D cornerpoint;
   cornerpoint[0] = (xFront ? bounds[0] : bounds[1]);
   cornerpoint[1] = (yFront ? bounds[2] : bounds[3]);
   cornerpoint[2] = (zFront ? bounds[4] : bounds[5]);
   if(m_ImageGeometry)
   {
     // Here i have to adjust the 0.5 offset manually, because the cornerpoint is the corner of the
     // bounding box. The bounding box itself is no image, so it is corner-based
     FillVector3D(cornerpoint, cornerpoint[0]-0.5, cornerpoint[1]-0.5, cornerpoint[2]-0.5);
   }
 
   return m_IndexToWorldTransform->TransformPoint(cornerpoint);
 }
 
 void
 mitk::Geometry3D::ResetSubTransforms()
 {
 }
 
 void
 mitk::Geometry3D::ChangeImageGeometryConsideringOriginOffset( const bool isAnImageGeometry )
 {
   // If Geometry is switched to ImageGeometry, you have to put an offset to the origin, because
   // imageGeometries origins are pixel-center-based
   // ... and remove the offset, if you switch an imageGeometry back to a normal geometry
   // For more information please see the Geometry documentation page
 
   if(m_ImageGeometry == isAnImageGeometry)
     return;
 
   const BoundingBox::BoundsArrayType& boundsarray =
     this->GetBoundingBox()->GetBounds();
 
   Point3D  originIndex;
   FillVector3D(originIndex,  boundsarray[0], boundsarray[2], boundsarray[4]);
 
   if(isAnImageGeometry == true)
     FillVector3D( originIndex,
       originIndex[0] + 0.5,
       originIndex[1] + 0.5,
       originIndex[2] + 0.5 );
   else
     FillVector3D( originIndex,
       originIndex[0] - 0.5,
       originIndex[1] - 0.5,
       originIndex[2] - 0.5 );
 
   Point3D originWorld;
 
   originWorld = GetIndexToWorldTransform()
     ->TransformPoint( originIndex );
   // instead could as well call  IndexToWorld(originIndex,originWorld);
 
   SetOrigin(originWorld);
 
   this->SetImageGeometry(isAnImageGeometry);
 }
 
 bool mitk::Geometry3D::Is2DConvertable()
 {
    bool isConvertableWithoutLoss = true;
    do
    {
       if (this->GetSpacing()[2] != 1)
       {
          isConvertableWithoutLoss = false;
          break;
       }
       if (this->GetOrigin()[2] != 0)
       {
          isConvertableWithoutLoss = false;
          break;
       }
       mitk::Vector3D col0, col1, col2;
       col0.SetVnlVector(this->GetIndexToWorldTransform()->GetMatrix().GetVnlMatrix().get_column(0));
       col1.SetVnlVector(this->GetIndexToWorldTransform()->GetMatrix().GetVnlMatrix().get_column(1));
       col2.SetVnlVector(this->GetIndexToWorldTransform()->GetMatrix().GetVnlMatrix().get_column(2));
 
       if ((col0[2] != 0) || (col1[2] != 0) || (col2[0] != 0) || (col2[1] != 0) || (col2[2] != 1))
       {
          isConvertableWithoutLoss = false;
          break;
       }
    } while (0);
 
    return isConvertableWithoutLoss;
 }
 
 bool mitk::Equal( const mitk::Geometry3D::BoundingBoxType *rightHandSide, const mitk::Geometry3D::BoundingBoxType *leftHandSide, ScalarType eps, bool verbose )
 {
   bool result = true;
-  if(( rightHandSide == NULL ) )
+  if( rightHandSide == NULL )
   {
     if(verbose)
       MITK_INFO << "[( Geometry3D::BoundingBoxType )] rightHandSide NULL.";
     return false;
   }
-  if(( leftHandSide == NULL ) )
+  if( leftHandSide == NULL )
   {
     if(verbose)
       MITK_INFO << "[( Geometry3D::BoundingBoxType )] leftHandSide NULL.";
     return false;
   }
 
   Geometry3D::BoundsArrayType rightBounds = rightHandSide->GetBounds();
   Geometry3D::BoundsArrayType leftBounds = leftHandSide->GetBounds();
   Geometry3D::BoundsArrayType::Iterator itLeft = leftBounds.Begin();
   for( Geometry3D::BoundsArrayType::Iterator itRight = rightBounds.Begin(); itRight != rightBounds.End(); ++itRight)
   {
     if(( !mitk::Equal( *itRight, *itLeft, eps )) )
     {
       if(verbose)
       {
         MITK_INFO << "[( Geometry3D::BoundingBoxType )] bounds are not equal.";
         MITK_INFO << "rightHandSide is " << setprecision(12) << *itRight << " : leftHandSide is " << *itLeft << " and tolerance is " << eps;
       }
       result = false;
     }
     itLeft++;
   }
   return result;
 }
 
 bool mitk::Equal(const mitk::Geometry3D *rightHandSide, const mitk::Geometry3D *leftHandSide, ScalarType eps, bool verbose)
 {
   bool result = true;
 
-  if(( rightHandSide == NULL ) )
+  if( rightHandSide == NULL )
   {
     if(verbose)
       MITK_INFO << "[( Geometry3D )] rightHandSide NULL.";
     return false;
   }
-  if(( leftHandSide == NULL) )
+  if( leftHandSide == NULL)
   {
     if(verbose)
       MITK_INFO << "[( Geometry3D )] leftHandSide NULL.";
     return false;
   }
 
   //Compare spacings
-  if(( !mitk::Equal( rightHandSide->GetSpacing(), leftHandSide->GetSpacing(), eps )) )
+  if( !mitk::Equal( rightHandSide->GetSpacing(), leftHandSide->GetSpacing(), eps ) )
   {
     if(verbose)
     {
       MITK_INFO << "[( Geometry3D )] Spacing differs.";
       MITK_INFO << "rightHandSide is " << setprecision(12) << rightHandSide->GetSpacing() << " : leftHandSide is " << leftHandSide->GetSpacing() << " and tolerance is " << eps;
     }
     result = false;
   }
 
   //Compare Origins
-  if(( !mitk::Equal( rightHandSide->GetOrigin(), leftHandSide->GetOrigin(), eps )) )
+  if( !mitk::Equal( rightHandSide->GetOrigin(), leftHandSide->GetOrigin(), eps ) )
   {
     if(verbose)
     {
       MITK_INFO << "[( Geometry3D )] Origin differs.";
       MITK_INFO << "rightHandSide is " << setprecision(12) << rightHandSide->GetOrigin() << " : leftHandSide is " << leftHandSide->GetOrigin() << " and tolerance is " << eps;
     }
     result = false;
   }
 
   //Compare Axis and Extents
   for( unsigned int i=0; i<3; ++i)
   {
     if( !mitk::Equal( rightHandSide->GetAxisVector(i), leftHandSide->GetAxisVector(i), eps))
     {
       if(verbose)
       {
         MITK_INFO << "[( Geometry3D )] AxisVector #" << i << " differ";
         MITK_INFO << "rightHandSide is " << setprecision(12) << rightHandSide->GetAxisVector(i) << " : leftHandSide is " << leftHandSide->GetAxisVector(i) << " and tolerance is " << eps;
       }
       result =  false;
     }
 
-    if(( !mitk::Equal( rightHandSide->GetExtent(i), leftHandSide->GetExtent(i), eps) ) )
+    if( !mitk::Equal( rightHandSide->GetExtent(i), leftHandSide->GetExtent(i), eps) )
     {
       if(verbose)
       {
         MITK_INFO << "[( Geometry3D )] Extent #" << i << " differ";
         MITK_INFO << "rightHandSide is " << setprecision(12) << rightHandSide->GetExtent(i) << " : leftHandSide is " << leftHandSide->GetExtent(i) << " and tolerance is " << eps;
       }
       result = false;
     }
   }
 
   //Compare ImageGeometry Flag
-  if(( rightHandSide->GetImageGeometry() != leftHandSide->GetImageGeometry()) )
+  if( rightHandSide->GetImageGeometry() != leftHandSide->GetImageGeometry() )
   {
     if(verbose)
     {
       MITK_INFO << "[( Geometry3D )] GetImageGeometry is different.";
       MITK_INFO << "rightHandSide is " << rightHandSide->GetImageGeometry() << " : leftHandSide is " << leftHandSide->GetImageGeometry();
     }
     result = false;
   }
 
   //Compare BoundingBoxes
-  if(( !mitk::Equal( rightHandSide->GetBoundingBox(), leftHandSide->GetBoundingBox(), eps, verbose)) )
+  if( !mitk::Equal( rightHandSide->GetBoundingBox(), leftHandSide->GetBoundingBox(), eps, verbose) )
   {
     result = false;
   }
 
   //Compare IndexToWorldTransform Matrix
-  if(( !mitk::Equal( rightHandSide->GetIndexToWorldTransform(), rightHandSide->GetIndexToWorldTransform(), eps, verbose)) )
+  if( !mitk::Equal( rightHandSide->GetIndexToWorldTransform(), rightHandSide->GetIndexToWorldTransform(), eps, verbose) )
   {
     result = false;
   }
   return result;
 }
 
 bool mitk::Equal( const Geometry3D::TransformType *rightHandSide, const Geometry3D::TransformType *leftHandSide, ScalarType eps, bool verbose )
 {
   //Compare IndexToWorldTransform Matrix
-  if(( !mitk::MatrixEqualElementWise( rightHandSide->GetMatrix(),
-                                      leftHandSide->GetMatrix()) ) )
+  if( !mitk::MatrixEqualElementWise( rightHandSide->GetMatrix(),
+                                      leftHandSide->GetMatrix()) )
   {
     if(verbose)
     {
       MITK_INFO << "[( Geometry3D::TransformType )] Index to World Transformation matrix differs.";
       MITK_INFO << "rightHandSide is " << setprecision(12) << rightHandSide->GetMatrix() << " : leftHandSide is " << leftHandSide->GetMatrix() << " and tolerance is " << eps;
     }
     return false;
   }
   return true;
 }
diff --git a/Core/Code/DataManagement/mitkImage.cpp b/Core/Code/DataManagement/mitkImage.cpp
index c50ddb9970..6aaf2f67c7 100644
--- a/Core/Code/DataManagement/mitkImage.cpp
+++ b/Core/Code/DataManagement/mitkImage.cpp
@@ -1,1374 +1,1374 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 
 //MITK
 #include "mitkImage.h"
 #include "mitkImageStatisticsHolder.h"
 #include "mitkPixelTypeMultiplex.h"
 #include "mitkCompareImageFilter.h"
 
 //VTK
 #include <vtkImageData.h>
 
 //Other
 #include <cmath>
 
 #define FILL_C_ARRAY( _arr, _size, _value) for(unsigned int i=0u; i<_size; i++) \
 { _arr[i] = _value; }
 
 
 mitk::Image::Image() :
   m_Dimension(0), m_Dimensions(NULL), m_ImageDescriptor(NULL), m_OffsetTable(NULL), m_CompleteData(NULL),
   m_ImageStatistics(NULL)
 {
   m_Dimensions = new unsigned int[MAX_IMAGE_DIMENSIONS];
   FILL_C_ARRAY( m_Dimensions, MAX_IMAGE_DIMENSIONS, 0u);
 
   m_Initialized = false;
 }
 
 mitk::Image::Image(const Image &other) : SlicedData(other), m_Dimension(0), m_Dimensions(NULL),
   m_ImageDescriptor(NULL), m_OffsetTable(NULL), m_CompleteData(NULL), m_ImageStatistics(NULL)
 {
   m_Dimensions = new unsigned int[MAX_IMAGE_DIMENSIONS];
   FILL_C_ARRAY( m_Dimensions, MAX_IMAGE_DIMENSIONS, 0u);
 
   this->Initialize( other.GetPixelType(), other.GetDimension(), other.GetDimensions());
 
   //Since the above called "Initialize" method doesn't take the geometry into account we need to set it
   //here manually
   this->SetGeometry(dynamic_cast<mitk::TimeSlicedGeometry*>(other.GetTimeSlicedGeometry()->Clone().GetPointer()));
 
   if (this->GetDimension() > 3)
   {
     const unsigned int time_steps = this->GetDimension(3);
 
     for (unsigned int i = 0u; i < time_steps; ++i)
     {
       ImageDataItemPointer volume = const_cast<Image&>(other).GetVolumeData(i);
 
       this->SetVolume(volume->GetData(), i);
     }
   }
   else
   {
     ImageDataItemPointer volume = const_cast<Image&>(other).GetVolumeData(0);
 
     this->SetVolume(volume->GetData(), 0);
   }
 }
 
 mitk::Image::~Image()
 {
   Clear();
   m_ReferenceCountLock.Lock();
   m_ReferenceCount = 3;
   m_ReferenceCountLock.Unlock();
   m_ReferenceCountLock.Lock();
   m_ReferenceCount = 0;
   m_ReferenceCountLock.Unlock();
   if(m_OffsetTable != NULL)
     delete [] m_OffsetTable;
 
   if(m_ImageStatistics != NULL)
     delete m_ImageStatistics;
 }
 
 const mitk::PixelType mitk::Image::GetPixelType(int n) const
 {
   return this->m_ImageDescriptor->GetChannelTypeById(n);
 }
 
 unsigned int mitk::Image::GetDimension() const
 {
   return m_Dimension;
 }
 
 unsigned int mitk::Image::GetDimension(int i) const
 {
   if((i>=0) && (i<(int)m_Dimension))
     return m_Dimensions[i];
   return 1;
 }
 
 void* mitk::Image::GetData()
 {
   if(m_Initialized==false)
   {
     if(GetSource().IsNull())
       return NULL;
     if(GetSource()->Updating()==false)
       GetSource()->UpdateOutputInformation();
   }
   m_CompleteData=GetChannelData();
 
   // update channel's data
   // if data was not available at creation point, the m_Data of channel descriptor is NULL
   // if data present, it won't be overwritten
   m_ImageDescriptor->GetChannelDescriptor(0).SetData(m_CompleteData->GetData());
 
   return m_CompleteData->GetData();
 }
 
 
 template <class T>
 void AccessPixel( const mitk::PixelType ptype, void* data, const unsigned int offset, double& value )
 {
   value = 0.0;
   if( data == NULL ) return;
 
   if(ptype.GetBpe() != 24)
   {
     value = (double) (((T*) data)[ offset ]);
   }
   else
   {
     const unsigned int rgboffset = 3 * offset;
 
     double returnvalue = (((T*) data)[rgboffset ]);
     returnvalue += (((T*) data)[rgboffset + 1]);
     returnvalue += (((T*) data)[rgboffset + 2]);
     value = returnvalue;
   }
 
 }
 
 double mitk::Image::GetPixelValueByIndex(const mitk::Index3D &position, unsigned int timestep)
 {
   double value = 0;
   if (this->GetTimeSteps() < timestep)
   {
     timestep = this->GetTimeSteps();
   }
 
   value = 0.0;
 
   const unsigned int* imageDims = this->m_ImageDescriptor->GetDimensions();
   const mitk::PixelType ptype = this->m_ImageDescriptor->GetChannelTypeById(0);
 
   // Comparison ?>=0 not needed since all position[i] and timestep are unsigned int
   // (position[0]>=0 && position[1] >=0 && position[2]>=0 && timestep>=0)
   // bug-11978 : we still need to catch index with negative values
   if ( position[0] < 0 ||
        position[1] < 0 ||
        position[2] < 0 )
   {
     MITK_WARN << "Given position ("<< position << ") is out of image range, returning 0." ;
   }
   // check if the given position is inside the index range of the image, the 3rd dimension needs to be compared only if the dimension is not 0
   else if ( (unsigned int)position[0] >= imageDims[0] ||
             (unsigned int)position[1] >= imageDims[1] ||
             ( imageDims[2] && (unsigned int)position[2] >= imageDims[2] ))
   {
     MITK_WARN << "Given position ("<< position << ") is out of image range, returning 0." ;
   }
   else
   {
     const unsigned int offset = position[0] + position[1]*imageDims[0] + position[2]*imageDims[0]*imageDims[1] + timestep*imageDims[0]*imageDims[1]*imageDims[2];
 
     mitkPixelTypeMultiplex3( AccessPixel, ptype, this->GetData(), offset, value );
   }
 
   return value;
 }
 
 double mitk::Image::GetPixelValueByWorldCoordinate(const mitk::Point3D& position, unsigned int timestep)
 {
   double value = 0.0;
   if (this->GetTimeSteps() < timestep)
   {
     timestep = this->GetTimeSteps();
   }
 
   Index3D itkIndex;
   this->GetGeometry()->WorldToIndex(position, itkIndex);
 
   value = this->GetPixelValueByIndex( itkIndex, timestep);
 
   return value;
 }
 
 mitk::ImageVtkAccessor* mitk::Image::GetVtkImageData(int t, int n)
 {
   if(m_Initialized==false)
   {
     if(GetSource().IsNull())
       return NULL;
     if(GetSource()->Updating()==false)
       GetSource()->UpdateOutputInformation();
   }
   ImageDataItemPointer volume=GetVolumeData(t, n);
   if(volume.GetPointer()==NULL || volume->GetVtkImageData(this) == NULL)
     return NULL;
 
 
   float *fspacing = const_cast<float *>(GetSlicedGeometry(t)->GetFloatSpacing());
   double dspacing[3] = {fspacing[0],fspacing[1],fspacing[2]};
   volume->GetVtkImageData(this)->SetSpacing( dspacing );
 
   return volume->GetVtkImageData(this);
 }
 
 mitk::Image::ImageDataItemPointer mitk::Image::GetSliceData(int s, int t, int n, void *data, ImportMemoryManagementType importMemoryManagement)
 {
   if(IsValidSlice(s,t,n)==false) return NULL;
 
   const size_t ptypeSize = this->m_ImageDescriptor->GetChannelTypeById(n).GetSize();
 
   // slice directly available?
   int pos=GetSliceIndex(s,t,n);
   if(m_Slices[pos].GetPointer()!=NULL)
     return m_Slices[pos];
 
   // is slice available as part of a volume that is available?
   ImageDataItemPointer sl, ch, vol;
   vol=m_Volumes[GetVolumeIndex(t,n)];
   if((vol.GetPointer()!=NULL) && (vol->IsComplete()))
   {
     sl=new ImageDataItem(*vol, m_ImageDescriptor, 2, data, importMemoryManagement == ManageMemory, ((size_t) s)*m_OffsetTable[2]*(ptypeSize));
     sl->SetComplete(true);
     return m_Slices[pos]=sl;
   }
 
   // is slice available as part of a channel that is available?
   ch=m_Channels[n];
   if((ch.GetPointer()!=NULL) && (ch->IsComplete()))
   {
     sl=new ImageDataItem(*ch, m_ImageDescriptor, 2, data, importMemoryManagement == ManageMemory, (((size_t) s)*m_OffsetTable[2]+((size_t) t)*m_OffsetTable[3])*(ptypeSize));
     sl->SetComplete(true);
     return m_Slices[pos]=sl;
   }
 
   // slice is unavailable. Can we calculate it?
   if((GetSource().IsNotNull()) && (GetSource()->Updating()==false))
   {
     // ... wir mussen rechnen!!! ....
     m_RequestedRegion.SetIndex(0, 0);
     m_RequestedRegion.SetIndex(1, 0);
     m_RequestedRegion.SetIndex(2, s);
     m_RequestedRegion.SetIndex(3, t);
     m_RequestedRegion.SetIndex(4, n);
     m_RequestedRegion.SetSize(0, m_Dimensions[0]);
     m_RequestedRegion.SetSize(1, m_Dimensions[1]);
     m_RequestedRegion.SetSize(2, 1);
     m_RequestedRegion.SetSize(3, 1);
     m_RequestedRegion.SetSize(4, 1);
     m_RequestedRegionInitialized=true;
     GetSource()->Update();
     if(IsSliceSet(s,t,n))
       //yes: now we can call ourselves without the risk of a endless loop (see "if" above)
       return GetSliceData(s,t,n,data,importMemoryManagement);
     else
       return NULL;
   }
   else
   {
     ImageDataItemPointer item = AllocateSliceData(s,t,n,data,importMemoryManagement);
     item->SetComplete(true);
     return item;
   }
 }
 
 mitk::Image::ImageDataItemPointer mitk::Image::GetVolumeData(int t, int n, void *data, ImportMemoryManagementType importMemoryManagement)
 {
   if(IsValidVolume(t,n)==false) return NULL;
 
   ImageDataItemPointer ch, vol;
 
   // volume directly available?
   int pos=GetVolumeIndex(t,n);
   vol=m_Volumes[pos];
   if((vol.GetPointer()!=NULL) && (vol->IsComplete()))
     return vol;
 
   const size_t ptypeSize = this->m_ImageDescriptor->GetChannelTypeById(n).GetSize();
 
   // is volume available as part of a channel that is available?
   ch=m_Channels[n];
   if((ch.GetPointer()!=NULL) && (ch->IsComplete()))
   {
     vol=new ImageDataItem(*ch, m_ImageDescriptor, 3, data, importMemoryManagement == ManageMemory, (((size_t) t)*m_OffsetTable[3])*(ptypeSize));
     vol->SetComplete(true);
     return m_Volumes[pos]=vol;
   }
 
   // let's see if all slices of the volume are set, so that we can (could) combine them to a volume
   bool complete=true;
   unsigned int s;
   for(s=0;s<m_Dimensions[2];++s)
   {
     if(m_Slices[GetSliceIndex(s,t,n)].GetPointer()==NULL)
     {
       complete=false;
       break;
     }
   }
   if(complete)
   {
     // if there is only single slice we do not need to combine anything
     if(m_Dimensions[2]<=1)
     {
       ImageDataItemPointer sl;
       sl=GetSliceData(0,t,n,data,importMemoryManagement);
       vol=new ImageDataItem(*sl, m_ImageDescriptor, 3, data, importMemoryManagement == ManageMemory);
       vol->SetComplete(true);
     }
     else
     {
       mitk::PixelType chPixelType = this->m_ImageDescriptor->GetChannelTypeById(n);
 
       vol=m_Volumes[pos];
       // ok, let's combine the slices!
       if(vol.GetPointer()==NULL)
         vol=new ImageDataItem( chPixelType, 3, m_Dimensions, NULL, true);
       vol->SetComplete(true);
       size_t size=m_OffsetTable[2]*(ptypeSize);
       for(s=0;s<m_Dimensions[2];++s)
       {
         int posSl;
         ImageDataItemPointer sl;
         posSl=GetSliceIndex(s,t,n);
 
         sl=m_Slices[posSl];
         if(sl->GetParent()!=vol)
         {
           // copy data of slices in volume
           size_t offset = ((size_t) s)*size;
           std::memcpy(static_cast<char*>(vol->GetData())+offset, sl->GetData(), size);
 
           // FIXME mitkIpPicDescriptor * pic = sl->GetPicDescriptor();
 
           // replace old slice with reference to volume
           sl=new ImageDataItem(*vol, m_ImageDescriptor, 2, data, importMemoryManagement == ManageMemory, ((size_t) s)*size);
           sl->SetComplete(true);
           //mitkIpFuncCopyTags(sl->GetPicDescriptor(), pic);
           m_Slices[posSl]=sl;
         }
       }
       //if(vol->GetPicDescriptor()->info->tags_head==NULL)
       //  mitkIpFuncCopyTags(vol->GetPicDescriptor(), m_Slices[GetSliceIndex(0,t,n)]->GetPicDescriptor());
     }
     return m_Volumes[pos]=vol;
   }
 
   // volume is unavailable. Can we calculate it?
   if((GetSource().IsNotNull()) && (GetSource()->Updating()==false))
   {
     // ... wir muessen rechnen!!! ....
     m_RequestedRegion.SetIndex(0, 0);
     m_RequestedRegion.SetIndex(1, 0);
     m_RequestedRegion.SetIndex(2, 0);
     m_RequestedRegion.SetIndex(3, t);
     m_RequestedRegion.SetIndex(4, n);
     m_RequestedRegion.SetSize(0, m_Dimensions[0]);
     m_RequestedRegion.SetSize(1, m_Dimensions[1]);
     m_RequestedRegion.SetSize(2, m_Dimensions[2]);
     m_RequestedRegion.SetSize(3, 1);
     m_RequestedRegion.SetSize(4, 1);
     m_RequestedRegionInitialized=true;
     GetSource()->Update();
     if(IsVolumeSet(t,n))
       //yes: now we can call ourselves without the risk of a endless loop (see "if" above)
       return GetVolumeData(t,n,data,importMemoryManagement);
     else
       return NULL;
   }
   else
   {
     ImageDataItemPointer item = AllocateVolumeData(t,n,data,importMemoryManagement);
     item->SetComplete(true);
     return item;
   }
 
 }
 
 mitk::Image::ImageDataItemPointer mitk::Image::GetChannelData(int n, void *data, ImportMemoryManagementType importMemoryManagement)
 {
   if(IsValidChannel(n)==false) return NULL;
   ImageDataItemPointer ch, vol;
   ch=m_Channels[n];
   if((ch.GetPointer()!=NULL) && (ch->IsComplete()))
     return ch;
 
   // let's see if all volumes are set, so that we can (could) combine them to a channel
   if(IsChannelSet(n))
   {
     // if there is only one time frame we do not need to combine anything
     if(m_Dimensions[3]<=1)
     {
       vol=GetVolumeData(0,n,data,importMemoryManagement);
       ch=new ImageDataItem(*vol, m_ImageDescriptor, m_ImageDescriptor->GetNumberOfDimensions(), data, importMemoryManagement == ManageMemory);
       ch->SetComplete(true);
     }
     else
     {
       const size_t ptypeSize = this->m_ImageDescriptor->GetChannelTypeById(n).GetSize();
 
       ch=m_Channels[n];
       // ok, let's combine the volumes!
       if(ch.GetPointer()==NULL)
         ch=new ImageDataItem(this->m_ImageDescriptor, NULL, true);
       ch->SetComplete(true);
       size_t size=m_OffsetTable[m_Dimension-1]*(ptypeSize);
       unsigned int t;
       ImageDataItemPointerArray::iterator slicesIt = m_Slices.begin()+n*m_Dimensions[2]*m_Dimensions[3];
       for(t=0;t<m_Dimensions[3];++t)
       {
         int posVol;
         ImageDataItemPointer vol;
 
         posVol=GetVolumeIndex(t,n);
         vol=GetVolumeData(t,n,data,importMemoryManagement);
 
         if(vol->GetParent()!=ch)
         {
           // copy data of volume in channel
           size_t offset = ((size_t) t)*m_OffsetTable[3]*(ptypeSize);
           std::memcpy(static_cast<char*>(ch->GetData())+offset, vol->GetData(), size);
 
           // REVEIW FIX mitkIpPicDescriptor * pic = vol->GetPicDescriptor();
 
           // replace old volume with reference to channel
           vol=new ImageDataItem(*ch, m_ImageDescriptor, 3, data, importMemoryManagement == ManageMemory, offset);
           vol->SetComplete(true);
           //mitkIpFuncCopyTags(vol->GetPicDescriptor(), pic);
 
           m_Volumes[posVol]=vol;
 
           // get rid of slices - they may point to old volume
           ImageDataItemPointer dnull=NULL;
           for(unsigned int i = 0; i < m_Dimensions[2]; ++i, ++slicesIt)
           {
             assert(slicesIt != m_Slices.end());
             *slicesIt = dnull;
           }
         }
       }
       // REVIEW FIX
       //   if(ch->GetPicDescriptor()->info->tags_head==NULL)
       //     mitkIpFuncCopyTags(ch->GetPicDescriptor(), m_Volumes[GetVolumeIndex(0,n)]->GetPicDescriptor());
     }
     return m_Channels[n]=ch;
   }
 
   // channel is unavailable. Can we calculate it?
   if((GetSource().IsNotNull()) && (GetSource()->Updating()==false))
   {
     // ... wir muessen rechnen!!! ....
     m_RequestedRegion.SetIndex(0, 0);
     m_RequestedRegion.SetIndex(1, 0);
     m_RequestedRegion.SetIndex(2, 0);
     m_RequestedRegion.SetIndex(3, 0);
     m_RequestedRegion.SetIndex(4, n);
     m_RequestedRegion.SetSize(0, m_Dimensions[0]);
     m_RequestedRegion.SetSize(1, m_Dimensions[1]);
     m_RequestedRegion.SetSize(2, m_Dimensions[2]);
     m_RequestedRegion.SetSize(3, m_Dimensions[3]);
     m_RequestedRegion.SetSize(4, 1);
     m_RequestedRegionInitialized=true;
     GetSource()->Update();
     // did it work?
     if(IsChannelSet(n))
       //yes: now we can call ourselves without the risk of a endless loop (see "if" above)
       return GetChannelData(n,data,importMemoryManagement);
     else
       return NULL;
   }
   else
   {
     ImageDataItemPointer item = AllocateChannelData(n,data,importMemoryManagement);
     item->SetComplete(true);
     return item;
   }
 }
 
 bool mitk::Image::IsSliceSet(int s, int t, int n) const
 {
   if(IsValidSlice(s,t,n)==false) return false;
 
   if(m_Slices[GetSliceIndex(s,t,n)].GetPointer()!=NULL)
     return true;
 
   ImageDataItemPointer ch, vol;
   vol=m_Volumes[GetVolumeIndex(t,n)];
   if((vol.GetPointer()!=NULL) && (vol->IsComplete()))
     return true;
   ch=m_Channels[n];
   if((ch.GetPointer()!=NULL) && (ch->IsComplete()))
     return true;
   return false;
 }
 
 bool mitk::Image::IsVolumeSet(int t, int n) const
 {
   if(IsValidVolume(t,n)==false) return false;
   ImageDataItemPointer ch, vol;
 
   // volume directly available?
   vol=m_Volumes[GetVolumeIndex(t,n)];
   if((vol.GetPointer()!=NULL) && (vol->IsComplete()))
     return true;
 
   // is volume available as part of a channel that is available?
   ch=m_Channels[n];
   if((ch.GetPointer()!=NULL) && (ch->IsComplete()))
     return true;
 
   // let's see if all slices of the volume are set, so that we can (could) combine them to a volume
   unsigned int s;
   for(s=0;s<m_Dimensions[2];++s)
     if(m_Slices[GetSliceIndex(s,t,n)].GetPointer()==NULL)
       return false;
   return true;
 }
 
 bool mitk::Image::IsChannelSet(int n) const
 {
   if(IsValidChannel(n)==false) return false;
   ImageDataItemPointer ch, vol;
   ch=m_Channels[n];
   if((ch.GetPointer()!=NULL) && (ch->IsComplete()))
 
     return true;
   // let's see if all volumes are set, so that we can (could) combine them to a channel
   unsigned int t;
   for(t=0;t<m_Dimensions[3];++t)
     if(IsVolumeSet(t,n)==false)
       return false;
   return true;
 }
 
 bool mitk::Image::SetSlice(const void *data, int s, int t, int n)
 {
   // const_cast is no risk for ImportMemoryManagementType == CopyMemory
   return SetImportSlice(const_cast<void*>(data), s, t, n, CopyMemory);
 }
 
 bool mitk::Image::SetVolume(const void *data, int t, int n)
 {
   // const_cast is no risk for ImportMemoryManagementType == CopyMemory
   return SetImportVolume(const_cast<void*>(data), t, n, CopyMemory);
 }
 
 bool mitk::Image::SetChannel(const void *data, int n)
 {
   // const_cast is no risk for ImportMemoryManagementType == CopyMemory
   return SetImportChannel(const_cast<void*>(data), n, CopyMemory);
 }
 
 bool mitk::Image::SetImportSlice(void *data, int s, int t, int n, ImportMemoryManagementType importMemoryManagement)
 {
   if(IsValidSlice(s,t,n)==false) return false;
   ImageDataItemPointer sl;
   const size_t ptypeSize = this->m_ImageDescriptor->GetChannelTypeById(n).GetSize();
 
   if(IsSliceSet(s,t,n))
   {
     sl=GetSliceData(s,t,n,data,importMemoryManagement);
     if(sl->GetManageMemory()==false)
     {
       sl=AllocateSliceData(s,t,n,data,importMemoryManagement);
       if(sl.GetPointer()==NULL) return false;
     }
     if ( sl->GetData() != data )
       std::memcpy(sl->GetData(), data, m_OffsetTable[2]*(ptypeSize));
     sl->Modified();
     //we have changed the data: call Modified()!
     Modified();
   }
   else
   {
     sl=AllocateSliceData(s,t,n,data,importMemoryManagement);
     if(sl.GetPointer()==NULL) return false;
     if ( sl->GetData() != data )
       std::memcpy(sl->GetData(), data, m_OffsetTable[2]*(ptypeSize));
     //we just added a missing slice, which is not regarded as modification.
     //Therefore, we do not call Modified()!
   }
   return true;
 }
 
 bool mitk::Image::SetImportVolume(void *data, int t, int n, ImportMemoryManagementType importMemoryManagement)
 {
   if(IsValidVolume(t,n)==false) return false;
 
   const size_t ptypeSize = this->m_ImageDescriptor->GetChannelTypeById(n).GetSize();
   ImageDataItemPointer vol;
   if(IsVolumeSet(t,n))
   {
     vol=GetVolumeData(t,n,data,importMemoryManagement);
     if(vol->GetManageMemory()==false)
     {
       vol=AllocateVolumeData(t,n,data,importMemoryManagement);
       if(vol.GetPointer()==NULL) return false;
     }
     if ( vol->GetData() != data )
       std::memcpy(vol->GetData(), data, m_OffsetTable[3]*(ptypeSize));
     vol->Modified();
     vol->SetComplete(true);
     //we have changed the data: call Modified()!
     Modified();
   }
   else
   {
     vol=AllocateVolumeData(t,n,data,importMemoryManagement);
     if(vol.GetPointer()==NULL) return false;
     if ( vol->GetData() != data )
     {
       std::memcpy(vol->GetData(), data, m_OffsetTable[3]*(ptypeSize));
     }
     vol->SetComplete(true);
     this->m_ImageDescriptor->GetChannelDescriptor(n).SetData( vol->GetData() );
     //we just added a missing Volume, which is not regarded as modification.
     //Therefore, we do not call Modified()!
   }
   return true;
 }
 
 bool mitk::Image::SetImportChannel(void *data, int n, ImportMemoryManagementType importMemoryManagement)
 {
   if(IsValidChannel(n)==false) return false;
 
   // channel descriptor
 
   const size_t ptypeSize = this->m_ImageDescriptor->GetChannelTypeById(n).GetSize();
 
   ImageDataItemPointer ch;
   if(IsChannelSet(n))
   {
     ch=GetChannelData(n,data,importMemoryManagement);
     if(ch->GetManageMemory()==false)
     {
       ch=AllocateChannelData(n,data,importMemoryManagement);
       if(ch.GetPointer()==NULL) return false;
     }
     if ( ch->GetData() != data )
       std::memcpy(ch->GetData(), data, m_OffsetTable[4]*(ptypeSize));
     ch->Modified();
     ch->SetComplete(true);
     //we have changed the data: call Modified()!
     Modified();
   }
   else
   {
     ch=AllocateChannelData(n,data,importMemoryManagement);
     if(ch.GetPointer()==NULL) return false;
     if ( ch->GetData() != data )
       std::memcpy(ch->GetData(), data, m_OffsetTable[4]*(ptypeSize));
     ch->SetComplete(true);
 
     this->m_ImageDescriptor->GetChannelDescriptor(n).SetData( ch->GetData() );
     //we just added a missing Channel, which is not regarded as modification.
     //Therefore, we do not call Modified()!
   }
   return true;
 }
 
 void mitk::Image::Initialize()
 {
   ImageDataItemPointerArray::iterator it, end;
   for( it=m_Slices.begin(), end=m_Slices.end(); it!=end; ++it )
   {
     (*it)=NULL;
   }
   for( it=m_Volumes.begin(), end=m_Volumes.end(); it!=end; ++it )
   {
     (*it)=NULL;
   }
   for( it=m_Channels.begin(), end=m_Channels.end(); it!=end; ++it )
   {
     (*it)=NULL;
   }
   m_CompleteData = NULL;
 
   if( m_ImageStatistics == NULL)
   {
     m_ImageStatistics = new mitk::ImageStatisticsHolder( this );
   }
 
   SetRequestedRegionToLargestPossibleRegion();
 }
 
 void mitk::Image::Initialize(const mitk::ImageDescriptor::Pointer inDesc)
 {
   // store the descriptor
   this->m_ImageDescriptor = inDesc;
 
   // initialize image
   this->Initialize( inDesc->GetChannelDescriptor(0).GetPixelType(), inDesc->GetNumberOfDimensions(), inDesc->GetDimensions(), 1 );
 }
 
 void mitk::Image::Initialize(const mitk::PixelType& type, unsigned int dimension, const unsigned int *dimensions, unsigned int channels)
 {
   Clear();
 
   m_Dimension=dimension;
 
   if(!dimensions)
     itkExceptionMacro(<< "invalid zero dimension image");
 
   unsigned int i;
   for(i=0;i<dimension;++i)
   {
     if(dimensions[i]<1)
       itkExceptionMacro(<< "invalid dimension[" << i << "]: " << dimensions[i]);
   }
 
   // create new array since the old was deleted
   m_Dimensions = new unsigned int[MAX_IMAGE_DIMENSIONS];
 
   // initialize the first four dimensions to 1, the remaining 4 to 0
   FILL_C_ARRAY(m_Dimensions, 4, 1u);
   FILL_C_ARRAY((m_Dimensions+4), 4, 0u);
 
   // copy in the passed dimension information
   std::memcpy(m_Dimensions, dimensions, sizeof(unsigned int)*m_Dimension);
 
   this->m_ImageDescriptor = mitk::ImageDescriptor::New();
   this->m_ImageDescriptor->Initialize( this->m_Dimensions, this->m_Dimension );
 
   for(i=0;i<4;++i)
   {
     m_LargestPossibleRegion.SetIndex(i, 0);
     m_LargestPossibleRegion.SetSize (i, m_Dimensions[i]);
   }
   m_LargestPossibleRegion.SetIndex(i, 0);
   m_LargestPossibleRegion.SetSize(i, channels);
 
   if(m_LargestPossibleRegion.GetNumberOfPixels()==0)
   {
     delete [] m_Dimensions;
     m_Dimensions = NULL;
     return;
   }
 
   for( unsigned int i=0u; i<channels; i++)
   {
     this->m_ImageDescriptor->AddNewChannel( type );
   }
 
   PlaneGeometry::Pointer planegeometry = PlaneGeometry::New();
   planegeometry->InitializeStandardPlane(m_Dimensions[0], m_Dimensions[1]);
 
   SlicedGeometry3D::Pointer slicedGeometry = SlicedGeometry3D::New();
   slicedGeometry->InitializeEvenlySpaced(planegeometry, m_Dimensions[2]);
 
   if(dimension>=4)
   {
     TimeBounds timebounds;
     timebounds[0] = 0.0;
     timebounds[1] = 1.0;
     slicedGeometry->SetTimeBounds(timebounds);
   }
 
   TimeSlicedGeometry::Pointer timeSliceGeometry = TimeSlicedGeometry::New();
   timeSliceGeometry->InitializeEvenlyTimed(slicedGeometry, m_Dimensions[3]);
   timeSliceGeometry->ImageGeometryOn();
 
   SetGeometry(timeSliceGeometry);
 
   ImageDataItemPointer dnull=NULL;
 
   m_Channels.assign(GetNumberOfChannels(), dnull);
 
   m_Volumes.assign(GetNumberOfChannels()*m_Dimensions[3], dnull);
 
   m_Slices.assign(GetNumberOfChannels()*m_Dimensions[3]*m_Dimensions[2], dnull);
 
   ComputeOffsetTable();
 
   Initialize();
 
   m_Initialized = true;
 }
 
 void mitk::Image::Initialize(const mitk::PixelType& type, const mitk::Geometry3D& geometry, unsigned int channels, int tDim )
 {
   unsigned int dimensions[5];
   dimensions[0] = (unsigned int)(geometry.GetExtent(0)+0.5);
   dimensions[1] = (unsigned int)(geometry.GetExtent(1)+0.5);
   dimensions[2] = (unsigned int)(geometry.GetExtent(2)+0.5);
   dimensions[3] = 0;
   dimensions[4] = 0;
 
   unsigned int dimension = 2;
   if ( dimensions[2] > 1 )
     dimension = 3;
 
   if ( tDim > 0)
   {
     dimensions[3] = tDim;
   }
   else
   {
     const mitk::TimeSlicedGeometry* timeGeometry = dynamic_cast<const mitk::TimeSlicedGeometry*>(&geometry);
     if ( timeGeometry != NULL )
     {
       dimensions[3] = timeGeometry->GetTimeSteps();
     }
   }
 
   if ( dimensions[3] > 1 )
     dimension = 4;
 
   Initialize( type, dimension, dimensions, channels );
 
   SetGeometry(static_cast<Geometry3D*>(geometry.Clone().GetPointer()));
 
   mitk::BoundingBox::BoundsArrayType bounds = geometry.GetBoundingBox()->GetBounds();
   if( (bounds[0] != 0.0) || (bounds[2] != 0.0) || (bounds[4] != 0.0) )
   {
     SlicedGeometry3D* slicedGeometry = GetSlicedGeometry(0);
 
     mitk::Point3D origin; origin.Fill(0.0);
     slicedGeometry->IndexToWorld(origin, origin);
 
     bounds[1]-=bounds[0]; bounds[3]-=bounds[2]; bounds[5]-=bounds[4];
     bounds[0] = 0.0;      bounds[2] = 0.0;      bounds[4] = 0.0;
     this->m_ImageDescriptor->Initialize( this->m_Dimensions, this->m_Dimension );
     slicedGeometry->SetBounds(bounds);
     slicedGeometry->GetIndexToWorldTransform()->SetOffset(origin.GetVnlVector().data_block());
 
     GetTimeSlicedGeometry()->InitializeEvenlyTimed(slicedGeometry, m_Dimensions[3]);
   }
 }
 
 void mitk::Image::Initialize(const mitk::PixelType& type, int sDim, const mitk::Geometry2D& geometry2d, bool flipped, unsigned int channels, int tDim )
 {
   SlicedGeometry3D::Pointer slicedGeometry = SlicedGeometry3D::New();
   slicedGeometry->InitializeEvenlySpaced(static_cast<Geometry2D*>(geometry2d.Clone().GetPointer()), sDim, flipped);
   Initialize(type, *slicedGeometry, channels, tDim);
 }
 
 void mitk::Image::Initialize(const mitk::Image* image)
 {
   Initialize(image->GetPixelType(), *image->GetTimeSlicedGeometry());
 }
 
 void mitk::Image::Initialize(vtkImageData* vtkimagedata, int channels, int tDim, int sDim, int pDim)
 {
   if(vtkimagedata==NULL) return;
 
   m_Dimension=vtkimagedata->GetDataDimension();
   unsigned int i, *tmpDimensions=new unsigned int[m_Dimension>4?m_Dimension:4];
   for(i=0;i<m_Dimension;++i) tmpDimensions[i]=vtkimagedata->GetDimensions()[i];
   if(m_Dimension<4)
   {
     unsigned int *p;
     for(i=0,p=tmpDimensions+m_Dimension;i<4-m_Dimension;++i, ++p)
       *p=1;
   }
 
   if(pDim>=0)
   {
     tmpDimensions[1]=pDim;
     if(m_Dimension < 2)
       m_Dimension = 2;
   }
   if(sDim>=0)
   {
     tmpDimensions[2]=sDim;
     if(m_Dimension < 3)
       m_Dimension = 3;
   }
   if(tDim>=0)
   {
     tmpDimensions[3]=tDim;
     if(m_Dimension < 4)
       m_Dimension = 4;
   }
 
 
   switch ( vtkimagedata->GetScalarType() )
   {
   case VTK_BIT:
   case VTK_CHAR:
     //pixelType.Initialize(typeid(char), vtkimagedata->GetNumberOfScalarComponents());
     Initialize(mitk::MakeScalarPixelType<char>(), m_Dimension, tmpDimensions, channels);
     break;
   case VTK_UNSIGNED_CHAR:
     //pixelType.Initialize(typeid(unsigned char), vtkimagedata->GetNumberOfScalarComponents());
     Initialize(mitk::MakeScalarPixelType<unsigned char>(), m_Dimension, tmpDimensions, channels);
     break;
   case VTK_SHORT:
     //pixelType.Initialize(typeid(short), vtkimagedata->GetNumberOfScalarComponents());
     Initialize(mitk::MakeScalarPixelType<short>(), m_Dimension, tmpDimensions, channels);
     break;
   case VTK_UNSIGNED_SHORT:
     //pixelType.Initialize(typeid(unsigned short), vtkimagedata->GetNumberOfScalarComponents());
     Initialize(mitk::MakeScalarPixelType<unsigned short>(), m_Dimension, tmpDimensions, channels);
     break;
   case VTK_INT:
     //pixelType.Initialize(typeid(int), vtkimagedata->GetNumberOfScalarComponents());
     Initialize(mitk::MakeScalarPixelType<int>(), m_Dimension, tmpDimensions, channels);
     break;
   case VTK_UNSIGNED_INT:
     //pixelType.Initialize(typeid(unsigned int), vtkimagedata->GetNumberOfScalarComponents());
     Initialize(mitk::MakeScalarPixelType<unsigned int>(), m_Dimension, tmpDimensions, channels);
     break;
   case VTK_LONG:
     //pixelType.Initialize(typeid(long), vtkimagedata->GetNumberOfScalarComponents());
     Initialize(mitk::MakeScalarPixelType<long>(), m_Dimension, tmpDimensions, channels);
     break;
   case VTK_UNSIGNED_LONG:
     //pixelType.Initialize(typeid(unsigned long), vtkimagedata->GetNumberOfScalarComponents());
     Initialize(mitk::MakeScalarPixelType<unsigned long>(), m_Dimension, tmpDimensions, channels);
     break;
   case VTK_FLOAT:
     //pixelType.Initialize(typeid(float), vtkimagedata->GetNumberOfScalarComponents());
     Initialize(mitk::MakeScalarPixelType<float>(), m_Dimension, tmpDimensions, channels);
     break;
   case VTK_DOUBLE:
     //pixelType.Initialize(typeid(double), vtkimagedata->GetNumberOfScalarComponents());
     Initialize(mitk::MakeScalarPixelType<double>(), m_Dimension, tmpDimensions, channels);
     break;
   default:
     break;
   }
   /*
   Initialize(pixelType,
     m_Dimension,
     tmpDimensions,
     channels);
 */
 
   const double *spacinglist = vtkimagedata->GetSpacing();
   Vector3D spacing;
   FillVector3D(spacing, spacinglist[0], 1.0, 1.0);
   if(m_Dimension>=2)
     spacing[1]=spacinglist[1];
   if(m_Dimension>=3)
     spacing[2]=spacinglist[2];
 
   // access origin of vtkImage
   Point3D origin;
   vtkFloatingPointType vtkorigin[3];
   vtkimagedata->GetOrigin(vtkorigin);
   FillVector3D(origin, vtkorigin[0], 0.0, 0.0);
   if(m_Dimension>=2)
     origin[1]=vtkorigin[1];
   if(m_Dimension>=3)
     origin[2]=vtkorigin[2];
 
   SlicedGeometry3D* slicedGeometry = GetSlicedGeometry(0);
 
   // re-initialize PlaneGeometry with origin and direction
   PlaneGeometry* planeGeometry = static_cast<PlaneGeometry*>(slicedGeometry->GetGeometry2D(0));
   planeGeometry->SetOrigin(origin);
 
   // re-initialize SlicedGeometry3D
   slicedGeometry->SetOrigin(origin);
   slicedGeometry->SetSpacing(spacing);
   GetTimeSlicedGeometry()->InitializeEvenlyTimed(slicedGeometry, m_Dimensions[3]);
 
   delete [] tmpDimensions;
 }
 
 bool mitk::Image::IsValidSlice(int s, int t, int n) const
 {
   if(m_Initialized)
     return ((s>=0) && (s<(int)m_Dimensions[2]) && (t>=0) && (t< (int) m_Dimensions[3]) && (n>=0) && (n< (int)GetNumberOfChannels()));
   else
     return false;
 }
 
 bool mitk::Image::IsValidVolume(int t, int n) const
 {
   if(m_Initialized)
     return IsValidSlice(0, t, n);
   else
     return false;
 }
 
 bool mitk::Image::IsValidChannel(int n) const
 {
   if(m_Initialized)
     return IsValidSlice(0, 0, n);
   else
     return false;
 }
 
 void mitk::Image::ComputeOffsetTable()
 {
   if(m_OffsetTable!=NULL)
     delete [] m_OffsetTable;
 
   m_OffsetTable=new size_t[m_Dimension>4 ? m_Dimension+1 : 4+1];
 
   unsigned int i;
   size_t num=1;
   m_OffsetTable[0] = 1;
   for (i=0; i < m_Dimension; ++i)
   {
     num *= m_Dimensions[i];
     m_OffsetTable[i+1] = num;
   }
   for (;i < 4; ++i)
     m_OffsetTable[i+1] = num;
 }
 
 bool mitk::Image::IsValidTimeStep(int t) const
 {
   return ( ( m_Dimension >= 4 && t <= (int)m_Dimensions[3] && t > 0 ) || (t == 0) );
 }
 
 void mitk::Image::Expand(unsigned int timeSteps)
 {
   if(timeSteps < 1) itkExceptionMacro(<< "Invalid timestep in Image!");
   Superclass::Expand(timeSteps);
 }
 
 int mitk::Image::GetSliceIndex(int s, int t, int n) const
 {
   if(IsValidSlice(s,t,n)==false) return false;
   return ((size_t)s)+((size_t) t)*m_Dimensions[2]+((size_t) n)*m_Dimensions[3]*m_Dimensions[2]; //??
 }
 
 int mitk::Image::GetVolumeIndex(int t, int n) const
 {
   if(IsValidVolume(t,n)==false) return false;
   return ((size_t)t)+((size_t) n)*m_Dimensions[3]; //??
 }
 
 mitk::Image::ImageDataItemPointer mitk::Image::AllocateSliceData(int s, int t, int n, void *data, ImportMemoryManagementType importMemoryManagement)
 {
   int pos;
   pos=GetSliceIndex(s,t,n);
 
   const size_t ptypeSize = this->m_ImageDescriptor->GetChannelTypeById(n).GetSize();
 
   // is slice available as part of a volume that is available?
   ImageDataItemPointer sl, ch, vol;
   vol=m_Volumes[GetVolumeIndex(t,n)];
   if(vol.GetPointer()!=NULL)
   {
     sl=new ImageDataItem(*vol, m_ImageDescriptor, 2, data, importMemoryManagement == ManageMemory, ((size_t) s)*m_OffsetTable[2]*(ptypeSize));
     sl->SetComplete(true);
     return m_Slices[pos]=sl;
   }
 
   // is slice available as part of a channel that is available?
   ch=m_Channels[n];
   if(ch.GetPointer()!=NULL)
   {
     sl=new ImageDataItem(*ch, m_ImageDescriptor, 2, data, importMemoryManagement == ManageMemory, (((size_t) s)*m_OffsetTable[2]+((size_t) t)*m_OffsetTable[3])*(ptypeSize));
     sl->SetComplete(true);
     return m_Slices[pos]=sl;
   }
 
   // allocate new volume (instead of a single slice to keep data together!)
   m_Volumes[GetVolumeIndex(t,n)]=vol=AllocateVolumeData(t,n,NULL,importMemoryManagement);
   sl=new ImageDataItem(*vol, m_ImageDescriptor, 2, data, importMemoryManagement == ManageMemory, ((size_t) s)*m_OffsetTable[2]*(ptypeSize));
   sl->SetComplete(true);
   return m_Slices[pos]=sl;
 
   ////ALTERNATIVE:
   //// allocate new slice
   //sl=new ImageDataItem(*m_PixelType, 2, m_Dimensions);
   //m_Slices[pos]=sl;
   //return vol;
 }
 
 mitk::Image::ImageDataItemPointer mitk::Image::AllocateVolumeData(int t, int n, void *data, ImportMemoryManagementType importMemoryManagement)
 {
   int pos;
   pos=GetVolumeIndex(t,n);
 
   const size_t ptypeSize = this->m_ImageDescriptor->GetChannelTypeById(n).GetSize();
 
   // is volume available as part of a channel that is available?
   ImageDataItemPointer ch, vol;
   ch=m_Channels[n];
   if(ch.GetPointer()!=NULL)
   {
     vol=new ImageDataItem(*ch, m_ImageDescriptor, 3, data,importMemoryManagement == ManageMemory, (((size_t) t)*m_OffsetTable[3])*(ptypeSize));
     return m_Volumes[pos]=vol;
   }
 
   mitk::PixelType chPixelType = this->m_ImageDescriptor->GetChannelTypeById(n);
 
   // allocate new volume
   if(importMemoryManagement == CopyMemory)
   {
     vol=new ImageDataItem( chPixelType, 3, m_Dimensions, NULL, true);
     if(data != NULL)
       std::memcpy(vol->GetData(), data, m_OffsetTable[3]*(ptypeSize));
   }
   else
   {
     vol=new ImageDataItem( chPixelType, 3, m_Dimensions, data, importMemoryManagement == ManageMemory);
   }
   m_Volumes[pos]=vol;
   return vol;
 }
 
 mitk::Image::ImageDataItemPointer mitk::Image::AllocateChannelData(int n, void *data, ImportMemoryManagementType importMemoryManagement)
 {
   ImageDataItemPointer ch;
   // allocate new channel
   if(importMemoryManagement == CopyMemory)
   {
     const size_t ptypeSize = this->m_ImageDescriptor->GetChannelTypeById(n).GetSize();
 
     ch=new ImageDataItem(this->m_ImageDescriptor, NULL, true);
     if(data != NULL)
       std::memcpy(ch->GetData(), data, m_OffsetTable[4]*(ptypeSize));
   }
   else
   {
     ch=new ImageDataItem(this->m_ImageDescriptor, data, importMemoryManagement == ManageMemory);
   }
   m_Channels[n]=ch;
   return ch;
 }
 
 unsigned int* mitk::Image::GetDimensions() const
 {
   return m_Dimensions;
 }
 
 void mitk::Image::Clear()
 {
   Superclass::Clear();
   delete [] m_Dimensions;
   m_Dimensions = NULL;
 }
 
 void mitk::Image::SetGeometry(Geometry3D* aGeometry3D)
 {
   // Please be aware of the 0.5 offset/pixel-center issue! See Geometry documentation for further information
 
   if(aGeometry3D->GetImageGeometry()==false)
   {
     MITK_INFO << "WARNING: Applied a non-image geometry onto an image. Please be SURE that this geometry is pixel-center-based! If it is not, you need to call Geometry3D->ChangeImageGeometryConsideringOriginOffset(true) before calling image->setGeometry(..)\n";
   }
   Superclass::SetGeometry(aGeometry3D);
   GetTimeSlicedGeometry()->ImageGeometryOn();
 }
 
 void mitk::Image::PrintSelf(std::ostream& os, itk::Indent indent) const
 {
   unsigned char i;
   if(m_Initialized)
   {
     os << indent << " Dimension: " << m_Dimension << std::endl;
     os << indent << " Dimensions: ";
     for(i=0; i < m_Dimension; ++i)
       os << GetDimension(i) << " ";
     os << std::endl;
 
     for(unsigned int ch=0; ch < this->m_ImageDescriptor->GetNumberOfChannels(); ch++)
     {
       mitk::PixelType chPixelType = this->m_ImageDescriptor->GetChannelTypeById(ch);
 
       os << indent << " Channel: " << this->m_ImageDescriptor->GetChannelName(ch) << std::endl;
       os << indent << " PixelType: " << chPixelType.GetPixelTypeAsString() << std::endl;
       os << indent << " BytesPerElement: " << chPixelType.GetSize() << std::endl;
       os << indent << " ComponentType: " << chPixelType.GetComponentTypeAsString() << std::endl;
       os << indent << " NumberOfComponents: " << chPixelType.GetNumberOfComponents() << std::endl;
       os << indent << " BitsPerComponent: " << chPixelType.GetBitsPerComponent() << std::endl;
     }
 
   }
   else
   {
     os << indent << " Image not initialized: m_Initialized: false" << std::endl;
   }
 
   Superclass::PrintSelf(os,indent);
 }
 
 bool mitk::Image::IsRotated() const
 {
   const mitk::Geometry3D* geo = this->GetGeometry();
   bool ret = false;
 
   if(geo)
   {
     const vnl_matrix_fixed<float, 3, 3> & mx = geo->GetIndexToWorldTransform()->GetMatrix().GetVnlMatrix();
     float ref = 0;
     for(short k = 0; k < 3; ++k)
       ref += mx[k][k];
     ref/=1000;  // Arbitrary value; if a non-diagonal (nd) element is bigger then this, matrix is considered nd.
 
     for(short i = 0; i < 3; ++i)
     {
       for(short j = 0; j < 3; ++j)
       {
         if(i != j)
         {
           if(std::abs(mx[i][j]) > ref) // matrix is nd
             ret = true;
         }
       }
     }
   }
   return ret;
 }
 
 mitk::ScalarType mitk::Image::GetScalarValueMin(int t) const
 {
   return m_ImageStatistics->GetScalarValueMin(t);
 }
 
 //## \brief Get the maximum for scalar images
 mitk::ScalarType mitk::Image::GetScalarValueMax(int t) const
 {
   return m_ImageStatistics->GetScalarValueMax(t);
 }
 
 //## \brief Get the second smallest value for scalar images
 mitk::ScalarType mitk::Image::GetScalarValue2ndMin(int t) const
 {
   return m_ImageStatistics->GetScalarValue2ndMin(t);
 }
 
 mitk::ScalarType mitk::Image::GetScalarValueMinNoRecompute( unsigned int t ) const
 {
   return m_ImageStatistics->GetScalarValueMinNoRecompute(t);
 }
 
 mitk::ScalarType mitk::Image::GetScalarValue2ndMinNoRecompute( unsigned int t ) const
 {
   return m_ImageStatistics->GetScalarValue2ndMinNoRecompute(t);
 }
 
 mitk::ScalarType mitk::Image::GetScalarValue2ndMax(int t) const
 {
   return m_ImageStatistics->GetScalarValue2ndMax(t);
 }
 
 mitk::ScalarType mitk::Image::GetScalarValueMaxNoRecompute( unsigned int t) const
 {
   return m_ImageStatistics->GetScalarValueMaxNoRecompute(t);
 }
 
 mitk::ScalarType mitk::Image::GetScalarValue2ndMaxNoRecompute( unsigned int t ) const
 {
   return m_ImageStatistics->GetScalarValue2ndMaxNoRecompute(t);
 }
 
 mitk::ScalarType mitk::Image::GetCountOfMinValuedVoxels(int t ) const
 {
   return m_ImageStatistics->GetCountOfMinValuedVoxels(t);
 }
 
 mitk::ScalarType mitk::Image::GetCountOfMaxValuedVoxels(int t) const
 {
   return m_ImageStatistics->GetCountOfMaxValuedVoxels(t);
 }
 
 unsigned int mitk::Image::GetCountOfMaxValuedVoxelsNoRecompute( unsigned int t  ) const
 {
   return m_ImageStatistics->GetCountOfMaxValuedVoxelsNoRecompute(t);
 }
 
 unsigned int mitk::Image::GetCountOfMinValuedVoxelsNoRecompute( unsigned int t ) const
 {
   return m_ImageStatistics->GetCountOfMinValuedVoxelsNoRecompute(t);
 }
 
 bool mitk::Equal(const mitk::Image* rightHandSide, const mitk::Image* leftHandSide, ScalarType eps, bool verbose)
 {
   bool returnValue = true;
-  if(( rightHandSide == NULL ) )
+  if( rightHandSide == NULL )
   {
     if(verbose)
       MITK_INFO << "[( Image )] rightHandSide is NULL.";
     return false;
   }
 
-  if(( leftHandSide == NULL ) )
+  if( leftHandSide == NULL )
   {
     if(verbose)
       MITK_INFO << "[( Image )] leftHandSide is NULL.";
     return false;
   }
 
   // Dimensionality
-  if(( rightHandSide->GetDimension() != leftHandSide->GetDimension() ) )
+  if( rightHandSide->GetDimension() != leftHandSide->GetDimension() )
   {
     if(verbose)
     {
       MITK_INFO << "[( Image )] Dimensionality differs.";
       MITK_INFO << "rightHandSide is " << rightHandSide->GetDimension()
                 << "leftHandSide is " << leftHandSide->GetDimension();
     }
     returnValue = false;
   }
 
   // Pair-wise dimension (size) comparison
   unsigned int minDimensionality = std::min(rightHandSide->GetDimension(),leftHandSide->GetDimension());
   for( unsigned int i=0; i< minDimensionality; ++i)
   {
-    if(( rightHandSide->GetDimension(i) != leftHandSide->GetDimension(i) ) )
+    if( rightHandSide->GetDimension(i) != leftHandSide->GetDimension(i) )
     {
       returnValue = false;
       if(verbose)
       {
         MITK_INFO << "[( Image )] dimension differs.";
         MITK_INFO << "rightHandSide->GetDimension("<<i<<") is " << rightHandSide->GetDimension(i)
                   << "leftHandSide->GetDimension("<<i<<") is " << leftHandSide->GetDimension(i);
       }
     }
   }
 
   // Pixeltype
   mitk::PixelType pixelTypeRightHandSide = rightHandSide->GetPixelType();
   mitk::PixelType pixelTypeLeftHandSide = leftHandSide->GetPixelType();
-  if(( !( pixelTypeRightHandSide == pixelTypeLeftHandSide ) ) )
+  if( !( pixelTypeRightHandSide == pixelTypeLeftHandSide ) )
   {
     if(verbose)
     {
       MITK_INFO << "[( Image )] PixelType differs.";
       MITK_INFO << "rightHandSide is " << pixelTypeRightHandSide.GetTypeAsString()
                 << "leftHandSide is " << pixelTypeLeftHandSide.GetTypeAsString();
     }
     returnValue = false;
   }
 
   // Geometries
-  if(( !mitk::Equal( rightHandSide->GetGeometry(),
-                     leftHandSide->GetGeometry(), eps, verbose) ) )
+  if( !mitk::Equal( rightHandSide->GetGeometry(),
+                     leftHandSide->GetGeometry(), eps, verbose) )
   {
     if(verbose)
     {
       MITK_INFO << "[( Image )] Geometries differ.";
     }
     returnValue = false;
   }
 
   // Pixel values - default mode [ 0 threshold in difference ]
   // compare only if all previous checks were successfull, otherwise the ITK filter will throw an exception
   if( returnValue )
   {
     mitk::CompareImageFilter::Pointer compareFilter = mitk::CompareImageFilter::New();
     compareFilter->SetInput(0, rightHandSide);
     compareFilter->SetInput(1, leftHandSide);
     compareFilter->Update();
 
     if(( !compareFilter->GetResult() ) )
     {
       returnValue = false;
       if(verbose)
       {
         MITK_INFO << "[(Image)] Pixel values differ: ";
       }
       compareFilter->GetCompareResults().PrintSelf();
     }
   }
   return returnValue;
 }
diff --git a/Core/Code/DataManagement/mitkSurface.cpp b/Core/Code/DataManagement/mitkSurface.cpp
index b6b0a69195..5b566b5f05 100644
--- a/Core/Code/DataManagement/mitkSurface.cpp
+++ b/Core/Code/DataManagement/mitkSurface.cpp
@@ -1,540 +1,540 @@
 /*===================================================================
 
 The Medical Imaging Interaction Toolkit (MITK)
 
 Copyright (c) German Cancer Research Center,
 Division of Medical and Biological Informatics.
 All rights reserved.
 
 This software is distributed WITHOUT ANY WARRANTY; without
 even the implied warranty of MERCHANTABILITY or FITNESS FOR
 A PARTICULAR PURPOSE.
 
 See LICENSE.txt or http://www.mitk.org for details.
 
 ===================================================================*/
 
 #include "mitkSurface.h"
 #include "mitkInteractionConst.h"
 #include "mitkSurfaceOperation.h"
 
 #include <algorithm>
 #include <vtkPolyData.h>
 #include <mitkTesting.h>
 
 static vtkPolyData* DeepCopy(vtkPolyData* other)
 {
   if (other == NULL)
     return NULL;
 
   vtkPolyData* copy = vtkPolyData::New();
   copy->DeepCopy(other);
 
   return copy;
 }
 
 static void Delete(vtkPolyData* polyData)
 {
   if (polyData != NULL)
     polyData->Delete();
 }
 
 static void Update(vtkPolyData* polyData)
 {
   if (polyData != NULL)
     polyData->Update();
 }
 
 mitk::Surface::Surface()
   : m_CalculateBoundingBox(false)
 {
   this->InitializeEmpty();
 }
 
 mitk::Surface::Surface(const mitk::Surface& other)
   : BaseData(other),
     m_LargestPossibleRegion(other.m_LargestPossibleRegion),
     m_RequestedRegion(other.m_RequestedRegion),
     m_CalculateBoundingBox(other.m_CalculateBoundingBox)
 {
   if(!other.m_PolyDatas.empty())
   {
     m_PolyDatas.resize(other.m_PolyDatas.size());
     std::transform(other.m_PolyDatas.begin(), other.m_PolyDatas.end(), m_PolyDatas.begin(), DeepCopy);
   }
   else
   {
     this->InitializeEmpty();
   }
 }
 
 void mitk::Surface::Swap(mitk::Surface& other)
 {
   std::swap(m_PolyDatas, other.m_PolyDatas);
   std::swap(m_LargestPossibleRegion, other.m_LargestPossibleRegion);
   std::swap(m_RequestedRegion, other.m_RequestedRegion);
   std::swap(m_CalculateBoundingBox, other.m_CalculateBoundingBox);
 }
 
 mitk::Surface& mitk::Surface::operator=(Surface other)
 {
   this->Swap(other);
   return *this;
 }
 
 mitk::Surface::~Surface()
 {
   this->ClearData();
 }
 
 void mitk::Surface::ClearData()
 {
   using ::Delete;
 
   std::for_each(m_PolyDatas.begin(), m_PolyDatas.end(), Delete);
   m_PolyDatas.clear();
 
   Superclass::ClearData();
 }
 
 const mitk::Surface::RegionType& mitk::Surface::GetLargestPossibleRegion() const
 {
   m_LargestPossibleRegion.SetIndex(3, 0);
   m_LargestPossibleRegion.SetSize(3, GetTimeSlicedGeometry()->GetTimeSteps());
 
   return m_LargestPossibleRegion;
 }
 
 const mitk::Surface::RegionType& mitk::Surface::GetRequestedRegion() const
 {
   return m_RequestedRegion;
 }
 
 void mitk::Surface::InitializeEmpty()
 {
   if (!m_PolyDatas.empty())
     this->ClearData();
 
   Superclass::InitializeTimeSlicedGeometry();
 
   m_PolyDatas.push_back(NULL);
   m_Initialized = true;
 }
 
 void mitk::Surface::SetVtkPolyData(vtkPolyData* polyData, unsigned int t)
 {
   this->Expand(t + 1);
 
   if (m_PolyDatas[t] != NULL)
   {
     if (m_PolyDatas[t] == polyData)
       return;
 
     m_PolyDatas[t]->Delete();
   }
 
   m_PolyDatas[t] = polyData;
 
   if(polyData != NULL)
     polyData->Register(NULL);
 
   m_CalculateBoundingBox = true;
 
   this->Modified();
   this->UpdateOutputInformation();
 }
 
 bool mitk::Surface::IsEmptyTimeStep(unsigned int t) const
 {
   if(!IsInitialized())
     return false;
 
   vtkPolyData* polyData = const_cast<Surface*>(this)->GetVtkPolyData(t);
 
   return polyData == NULL || (
     polyData->GetNumberOfLines() == 0 &&
     polyData->GetNumberOfPolys() == 0 &&
     polyData->GetNumberOfStrips() == 0 &&
     polyData->GetNumberOfVerts() == 0
   );
 }
 
 vtkPolyData* mitk::Surface::GetVtkPolyData(unsigned int t)
 {
   if (t < m_PolyDatas.size())
   {
     if(m_PolyDatas[t] == NULL && this->GetSource().IsNotNull())
     {
       RegionType requestedRegion;
       requestedRegion.SetIndex(3, t);
       requestedRegion.SetSize(3, 1);
 
       this->SetRequestedRegion(&requestedRegion);
       this->GetSource()->Update();
     }
 
     return m_PolyDatas[t];
   }
 
   return NULL;
 }
 
 void mitk::Surface::UpdateOutputInformation()
 {
   if (this->GetSource().IsNotNull())
     this->GetSource()->UpdateOutputInformation();
 
   if (m_CalculateBoundingBox == true && !m_PolyDatas.empty())
     this->CalculateBoundingBox();
   else
     this->GetTimeSlicedGeometry()->UpdateInformation();
 }
 
 void mitk::Surface::CalculateBoundingBox()
 {
   mitk::TimeSlicedGeometry* timeSlicedGeometry = this->GetTimeSlicedGeometry();
 
   if (timeSlicedGeometry->GetTimeSteps() != m_PolyDatas.size())
     mitkThrow() << "Number of geometry time steps is inconsistent with number of poly data pointers.";
 
   for (unsigned int i = 0; i < m_PolyDatas.size(); ++i)
   {
     vtkPolyData* polyData = m_PolyDatas[i];
     vtkFloatingPointType bounds[6] = {0};
 
     if (polyData != NULL && polyData->GetNumberOfPoints() > 0)
     {
       polyData->Update();
       polyData->ComputeBounds();
       polyData->GetBounds(bounds);
     }
 
     mitk::Geometry3D::Pointer geometry = timeSlicedGeometry->GetGeometry3D(i);
 
     if (geometry.IsNull())
       mitkThrow() << "Time-sliced geometry is invalid (equals NULL).";
 
     geometry->SetFloatBounds(bounds);
   }
 
   timeSlicedGeometry->UpdateInformation();
   m_CalculateBoundingBox = false;
 }
 
 void mitk::Surface::SetRequestedRegionToLargestPossibleRegion()
 {
   m_RequestedRegion = GetLargestPossibleRegion();
 }
 
 bool mitk::Surface::RequestedRegionIsOutsideOfTheBufferedRegion()
 {
   RegionType::IndexValueType end = m_RequestedRegion.GetIndex(3) + m_RequestedRegion.GetSize(3);
 
   if(static_cast<RegionType::IndexValueType>(m_PolyDatas.size()) < end)
     return true;
 
   for(RegionType::IndexValueType t = m_RequestedRegion.GetIndex(3); t < end; ++t)
   {
     if(m_PolyDatas[t] == NULL)
       return true;
   }
 
   return false;
 }
 
 bool mitk::Surface::VerifyRequestedRegion()
 {
   if(m_RequestedRegion.GetIndex(3) >= 0 && m_RequestedRegion.GetIndex(3) + m_RequestedRegion.GetSize(3) <= m_PolyDatas.size())
     return true;
 
   return false;
 }
 
 void mitk::Surface::SetRequestedRegion(const itk::DataObject* data )
 {
   const mitk::Surface *surface = dynamic_cast<const mitk::Surface*>(data);
 
   if (surface != NULL)
     m_RequestedRegion = surface->GetRequestedRegion();
   else
     mitkThrow() << "Data object used to get requested region is not a mitk::Surface.";
 }
 
 void mitk::Surface::SetRequestedRegion(Surface::RegionType* region)
 {
   if (region == NULL)
     mitkThrow() << "Requested region is invalid (equals NULL)";
 
   m_RequestedRegion = *region;
 }
 
 void mitk::Surface::CopyInformation(const itk::DataObject* data)
 {
   Superclass::CopyInformation(data);
 
   const mitk::Surface* surface = dynamic_cast<const mitk::Surface*>(data);
 
   if (surface == NULL)
     mitkThrow() << "Data object used to get largest possible region is not a mitk::Surface.";
 
   m_LargestPossibleRegion = surface->GetLargestPossibleRegion();
 }
 
 void mitk::Surface::Update()
 {
   using ::Update;
 
   if (this->GetSource().IsNull())
     std::for_each(m_PolyDatas.begin(), m_PolyDatas.end(), Update);
 
   Superclass::Update();
 }
 
 void mitk::Surface::Expand(unsigned int timeSteps)
 {
   if (timeSteps > m_PolyDatas.size())
   {
     Superclass::Expand(timeSteps);
 
     m_PolyDatas.resize(timeSteps);
     m_CalculateBoundingBox = true;
   }
 }
 
 void mitk::Surface::ExecuteOperation(Operation* operation)
 {
   switch (operation->GetOperationType())
   {
     case OpSURFACECHANGED:
     {
       mitk::SurfaceOperation* surfaceOperation = dynamic_cast<mitk::SurfaceOperation*>(operation);
 
       if(surfaceOperation == NULL)
         break;
 
       unsigned int timeStep = surfaceOperation->GetTimeStep();
 
       if(m_PolyDatas[timeStep] != NULL)
       {
         vtkPolyData* updatedPolyData = surfaceOperation->GetVtkPolyData();
 
         if(updatedPolyData != NULL)
         {
           this->SetVtkPolyData(updatedPolyData, timeStep);
           this->CalculateBoundingBox();
           this->Modified();
         }
       }
 
       break;
     }
 
     default:
       return;
   }
 }
 
 unsigned int mitk::Surface::GetSizeOfPolyDataSeries() const
 {
   return m_PolyDatas.size();
 }
 
 void mitk::Surface::Graft(const DataObject* data)
 {
   const Surface* surface = dynamic_cast<const Surface*>(data);
 
   if(surface == NULL)
     mitkThrow() << "Data object used to graft surface is not a mitk::Surface.";
 
   this->CopyInformation(data);
   m_PolyDatas.clear();
 
   for (unsigned int i = 0; i < surface->GetSizeOfPolyDataSeries(); ++i)
   {
     m_PolyDatas.push_back(vtkPolyData::New());
     m_PolyDatas.back()->DeepCopy(const_cast<mitk::Surface*>(surface)->GetVtkPolyData(i));
   }
 }
 
 void mitk::Surface::PrintSelf(std::ostream& os, itk::Indent indent) const
 {
   Superclass::PrintSelf(os, indent);
 
   os << indent << "\nNumber PolyDatas: " << m_PolyDatas.size() << "\n";
 
   unsigned int count = 0;
 
   for (std::vector<vtkPolyData*>::const_iterator it = m_PolyDatas.begin(); it != m_PolyDatas.end(); ++it)
   {
     os << "\n";
 
     if(*it != NULL)
     {
       os << indent << "PolyData at time step " << count << ":\n";
       os << indent << "Number of cells: " << (*it)->GetNumberOfCells() << "\n";
       os << indent << "Number of points: " << (*it)->GetNumberOfPoints() << "\n\n";
       os << indent << "VTKPolyData:\n";
 
       (*it)->Print(os);
     }
     else
     {
       os << indent << "Empty PolyData at time step " << count << "\n";
     }
 
     ++count;
   }
 }
 
 bool mitk::Equal( vtkPolyData* rightHandSide,  vtkPolyData* leftHandSide, mitk::ScalarType eps, bool verbose )
 {
   bool noDifferenceFound = true;
 
-  if(( rightHandSide == NULL ) )
+  if( rightHandSide == NULL )
   {
     if(verbose)
     {
       MITK_INFO << "[Equal( vtkPolyData*, vtkPolyData* )] rightHandSide NULL.";
     }
     return false;
   }
 
-  if(( leftHandSide == NULL ) )
+  if( leftHandSide == NULL )
   {
     if(verbose)
     {
       MITK_INFO << "[Equal( vtkPolyData*, vtkPolyData* )] leftHandSide NULL.";
     }
     return false;
   }
 
   if( ! mitk::Equal( rightHandSide->GetNumberOfCells(), leftHandSide->GetNumberOfCells(), eps, verbose ) )
   {
     if(verbose)
       MITK_INFO << "[Equal( vtkPolyData*, vtkPolyData* )] Number of cells not equal";
     noDifferenceFound = false;
   }
 
   if( ! mitk::Equal( rightHandSide->GetNumberOfVerts(), leftHandSide->GetNumberOfVerts(), eps, verbose ))
   {
     if(verbose)
       MITK_INFO << "[Equal( vtkPolyData*, vtkPolyData* )] Number of vertices not equal";
     noDifferenceFound = false;
   }
 
   if( ! mitk::Equal( rightHandSide->GetNumberOfLines(), leftHandSide->GetNumberOfLines(), eps, verbose ) )
   {
     if(verbose)
       MITK_INFO << "[Equal( vtkPolyData*, vtkPolyData* )] Number of lines not equal";
     noDifferenceFound = false;
   }
 
   if( ! mitk::Equal( rightHandSide->GetNumberOfPolys(), leftHandSide->GetNumberOfPolys(), eps, verbose ) )
   {
     if(verbose)
       MITK_INFO << "[Equal( vtkPolyData*, vtkPolyData* )] Number of polys not equal";
     noDifferenceFound = false;
   }
 
   if( ! mitk::Equal( rightHandSide->GetNumberOfStrips(), leftHandSide->GetNumberOfStrips(), eps, verbose ) )
   {
     if(verbose)
       MITK_INFO << "[Equal( vtkPolyData*, vtkPolyData* )] Number of strips not equal";
     noDifferenceFound = false;
   }
 
   {
     unsigned int numberOfPointsRight = rightHandSide->GetPoints()->GetNumberOfPoints();
     unsigned int numberOfPointsLeft = leftHandSide->GetPoints()->GetNumberOfPoints();
     if(! mitk::Equal( numberOfPointsRight, numberOfPointsLeft, eps, verbose ))
     {
       if(verbose)
         MITK_INFO << "[Equal( vtkPolyData*, vtkPolyData* )] Number of points not equal";
       noDifferenceFound = false;
     }
     else
     {
       for( unsigned int i( 0 ); i < numberOfPointsRight; i++ )
       {
         bool pointFound = false;
         double pointOne[3];
         rightHandSide->GetPoints()->GetPoint(i, pointOne);
 
         for( unsigned int j( 0 ); j < numberOfPointsLeft; j++ )
         {
           double pointTwo[3];
           leftHandSide->GetPoints()->GetPoint(j, pointTwo);
 
           double x = pointOne[0] - pointTwo[0];
           double y = pointOne[1] - pointTwo[1];
           double z = pointOne[2] - pointTwo[2];
           double distance = x*x + y*y + z*z;
 
           if( distance < eps )
           {
             pointFound = true;
             break;
           }
         }
         if( !pointFound )
         {
           if(verbose)
           {
             MITK_INFO << "[Equal( vtkPolyData*, vtkPolyData* )] Right hand side point with id " << i << " and coordinates ( "
                     << std::setprecision(12)
                     << pointOne[0] << " ; " << pointOne[1] << " ; " << pointOne[2]
                     << " ) could not be found in left hand side with epsilon " << eps << ".";
           }
           noDifferenceFound = false;
           break;
         }
       }
     }
   }
   return noDifferenceFound;
 }
 
 bool mitk::Equal( mitk::Surface* rightHandSide, mitk::Surface* leftHandSide, mitk::ScalarType eps, bool verbose )
 {
   bool noDifferenceFound = true;
 
   if( rightHandSide == NULL )
   {
     if(verbose)
       MITK_INFO << "[Equal( mitk::surface*, mitk::surface* )] rightHandSide NULL.";
     return false;
   }
 
   if( leftHandSide == NULL )
   {
     if(verbose)
       MITK_INFO << "[Equal( mitk::surface*, mitk::surface* )] leftHandSide NULL.";
     return false;
   }
 
   if( ! mitk::Equal( rightHandSide->GetSizeOfPolyDataSeries(), leftHandSide->GetSizeOfPolyDataSeries(), eps, verbose ) )
   {
     if(verbose)
       MITK_INFO << "[Equal( mitk::surface*, mitk::surface* )] Size of PolyData series not equal.";
     noDifferenceFound = false;
   }
 
   if( ! mitk::Equal( rightHandSide->GetTimeSlicedGeometry(), leftHandSide->GetTimeSlicedGeometry(), eps, verbose ) )
   {
     if(verbose)
       MITK_INFO << "[Equal( mitk::surface*, mitk::surface* )] Time sliced geometries not equal";
     noDifferenceFound = false;
   }
 
   for( unsigned int i( 0 ); i < rightHandSide->GetSizeOfPolyDataSeries(); i++ )
   {
     if( ! mitk::Equal( rightHandSide->GetVtkPolyData( i ), leftHandSide->GetVtkPolyData( i ), eps, verbose ) )
     {
       if(verbose)
         MITK_INFO << "[Equal( mitk::surface*, mitk::surface* )] Poly datas not equal.";
       noDifferenceFound = false;
     }
   }
 
   return noDifferenceFound;
 }