diff --git a/Core/Code/DataManagement/mitkGeometry3D.cpp b/Core/Code/DataManagement/mitkGeometry3D.cpp index 1b3ad476e9..0f7609192f 100644 --- a/Core/Code/DataManagement/mitkGeometry3D.cpp +++ b/Core/Code/DataManagement/mitkGeometry3D.cpp @@ -1,822 +1,837 @@ /*=================================================================== 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 #include "mitkGeometry3D.h" #include "mitkMatrixConvert.h" #include "mitkRotationOperation.h" #include "mitkRestorePlanePositionOperation.h" #include "mitkPointOperation.h" #include "mitkInteractionConst.h" //#include "mitkStatusBar.h" #include #include // 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 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(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(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(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(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(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() { } +//Todo List: +//Allow the user to pass eps values for various comparisons: Spacing, Origin, Extent, Axis, Index2WorldTransform, etc. + +//Todo: List of parameters which are copied inside the copy constructor and NOT compared yet +//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_RotationQuaternion( other.m_RotationQuaternion), +//SetBounds(other.GetBounds()); +//m_VtkMatrix = vtkMatrix4x4::New(); + +bool mitk::Geometry3D::AreEqual(const mitk::Geometry3D *rightHandSide, const mitk::Geometry3D *leftHandSide) +{ + // check the validity of input + if( rightHandSide == NULL || leftHandSide == NULL ) + { + MITK_INFO << "[AreEqual( Geometry3D )] Input null."; + return false; + } + + // spacing + if( !mitk::Equal( rightHandSide->GetSpacing(), leftHandSide->GetSpacing() )) + { + MITK_INFO << "[AreEqual( Geometry3D )] Spacing differs."; + MITK_INFO << "rightHandSide is " << rightHandSide->GetSpacing() << " : leftHandSide is " << leftHandSide->GetSpacing(); + return false; + } + + // origin + if( !mitk::Equal( rightHandSide->GetOrigin(), leftHandSide->GetOrigin() )) + { + MITK_INFO << "[AreEqual( Geometry3D )] Origin differs."; + MITK_INFO << "rightHandSide is " << rightHandSide->GetOrigin() << " : leftHandSide is " << leftHandSide->GetOrigin(); + return false; + } + + // compare each view axis and extent + for( unsigned int i=0; i< 3; i++) + { + if( !mitk::Equal( rightHandSide->GetAxisVector(i), leftHandSide->GetAxisVector(i)) ) + { + MITK_INFO << "[AreEqual( Geometry3D )] AxisVector #" << i << " differ"; + MITK_INFO << "rightHandSide is " << rightHandSide->GetAxisVector(i) << " : leftHandSide is " << leftHandSide->GetAxisVector(i); + return false; + } + + if( !mitk::Equal( rightHandSide->GetExtent(i), leftHandSide->GetExtent(i)) ) + { + MITK_INFO << "[AreEqual( Geometry3D )] Extent #" << i << " differ"; + MITK_INFO << "rightHandSide is " << rightHandSide->GetExtent(i) << " : leftHandSide is " << leftHandSide->GetExtent(i); + return false; + } + } + + // index to world transform + if( !mitk::MatrixEqualElementWise( rightHandSide->GetIndexToWorldTransform()->GetMatrix(), + leftHandSide->GetIndexToWorldTransform()->GetMatrix()) ) + { + MITK_INFO << "[AreEqual( Geometry3D )] Index to World Transformation matrix differs."; + MITK_INFO << "rightHandSide is " << rightHandSide->GetIndexToWorldTransform()->GetMatrix() << " : leftHandSide is " << leftHandSide->GetIndexToWorldTransform()->GetMatrix(); + return false; + } + return true; +} + 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::compare::IsEqual(const mitk::Geometry3D *rhs, const mitk::Geometry3D *lhs) -{ - // check the validity of input - if( rhs == NULL || lhs == NULL ) - { - MITK_INFO << "[AreIdentical( Geometry3D )] Input null."; - return false; - } - - // spacing - if( !Equal( rhs->GetSpacing(), lhs->GetSpacing() )) - { - MITK_INFO << "[AreIdentical( Geometry3D )] Spacing differs."; - return false; - } - - // origin - if( !Equal( rhs->GetOrigin(), lhs->GetOrigin() )) - { - MITK_INFO << "[AreIdentical( Geometry3D )] Origin differs."; - return false; - } - - // compare each view axis and extent - bool viewAxisIdentical = true; - bool extentsIdentical = true; - for( unsigned int i=0; i< 3; i++) - { - if( !mitk::Equal( rhs->GetAxisVector(i), lhs->GetAxisVector(i)) ) - viewAxisIdentical = false; - - if( !mitk::Equal( rhs->GetExtent(i), lhs->GetExtent(i)) ) - extentsIdentical = false; - } - if( !viewAxisIdentical || !extentsIdentical ) - { - MITK_INFO << "[AreIdentical( Geometry3D )] Axis AND/OR Extent differ"; - return false; - } - - - // index to world transform - if( !mitk::MatrixEqualElementWise( rhs->GetIndexToWorldTransform()->GetMatrix(), - lhs->GetIndexToWorldTransform()->GetMatrix()) ) - { - MITK_INFO << "[AreIdentical( Geometry3D )] I2W Transformation matrix differs."; - return false; - } - - return true; -} diff --git a/Core/Code/DataManagement/mitkGeometry3D.h b/Core/Code/DataManagement/mitkGeometry3D.h index 5fd42a7506..6efe7459d5 100644 --- a/Core/Code/DataManagement/mitkGeometry3D.h +++ b/Core/Code/DataManagement/mitkGeometry3D.h @@ -1,681 +1,679 @@ /*=================================================================== 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. ===================================================================*/ #ifndef GEOMETRY3D_H_HEADER_INCLUDED_C1EBD0AD #define GEOMETRY3D_H_HEADER_INCLUDED_C1EBD0AD #include #include #include "mitkVector.h" #include "mitkOperationActor.h" #include #include #include #include class vtkLinearTransform; class vtkMatrixToLinearTransform; class vtkMatrix4x4; namespace mitk { //##Documentation //## @brief Standard 3D-BoundingBox typedef //## //## Standard 3D-BoundingBox typedef to get rid of template arguments (3D, type). typedef itk::BoundingBox BoundingBox; //##Documentation //## @brief Standard typedef for time-bounds typedef itk::FixedArray TimeBounds; typedef itk::FixedArray FixedArrayType; typedef itk::AffineGeometryFrame AffineGeometryFrame3D; //##Documentation //## @brief Describes the geometry of a data object //## //## At least, it can return the bounding box of the data object. //## //## The class holds //## \li a bounding box which is axes-parallel in intrinsic coordinates //## (often integer indices of pixels), to be accessed by //## GetBoundingBox() //## \li a transform to convert intrinsic coordinates into a //## world-coordinate system with coordinates in millimeters //## and milliseconds (all are floating point values), to //## be accessed by GetIndexToWorldTransform() //## \li a life span, i.e. a bounding box in time in ms (with //## start and end time), to be accessed by GetTimeBounds(). //## The default is minus infinity to plus infinity. //## //## Geometry3D and its sub-classes allow converting between //## intrinsic coordinates (called index or unit coordinates) //## and world-coordinates (called world or mm coordinates), //## e.g. WorldToIndex. //## In case you need integer index coordinates, provide an //## mitk::Index3D (or itk::Index) as target variable to //## WorldToIndex, otherwise you will get a continuous index //## (floating point values). //## //## An important sub-class is SlicedGeometry3D, which descibes //## data objects consisting of slices, e.g., objects of type Image. //## Conversions between world coordinates (in mm) and unit coordinates //## (e.g., pixels in the case of an Image) can be performed. //## //## For more information on related classes, see \ref Geometry. //## //## Geometry3D instances referring to an Image need a slightly //## different definition of corners, see SetImageGeometry. This //## is usualy automatically called by Image. //## //## Geometry3D have to be initialized in the method GenerateOutputInformation() //## of BaseProcess (or CopyInformation/ UpdateOutputInformation of BaseData, //## if possible, e.g., by analyzing pic tags in Image) subclasses. See also //## itk::ProcessObject::GenerateOutputInformation(), //## itk::DataObject::CopyInformation() and //## itk::DataObject::UpdateOutputInformation(). //## //## Rule: everything is in mm (ms) if not stated otherwise. //## @ingroup Geometry class MITK_CORE_EXPORT Geometry3D : public AffineGeometryFrame3D, public OperationActor { public: mitkClassMacro(Geometry3D, AffineGeometryFrame3D); typedef itk::QuaternionRigidTransform< ScalarType > QuaternionTransformType; typedef QuaternionTransformType::VnlQuaternionType VnlQuaternionType; /** Method for creation through the object factory. */ itkNewMacro(Self); // a bit of a misuse, but we want only doxygen to see the following: #ifdef DOXYGEN_SKIP //##Documentation //## @brief Get the transformation used to convert from index //## to world coordinates itkGetObjectMacro(IndexToWorldTransform, AffineTransform3D); #endif //## @brief Set the transformation used to convert from index //## to world coordinates virtual void SetIndexToWorldTransform(mitk::AffineTransform3D* transform); //##Documentation //## @brief Convenience method for setting the ITK transform //## (m_IndexToWorldTransform) via an vtkMatrix4x4 //## \sa SetIndexToWorldTransform virtual void SetIndexToWorldTransformByVtkMatrix(vtkMatrix4x4* vtkmatrix); #ifdef DOXYGEN_SKIP //##Documentation //## @brief Get bounding box (in index/unit coordinates) itkGetConstObjectMacro(BoundingBox, BoundingBoxType); //##Documentation //## @brief Get bounding box (in index/unit coordinates) as a BoundsArrayType const BoundsArrayType GetBounds() const { assert(m_BoundingBox.IsNotNull()); return m_BoundingBox->GetBounds(); } //##Documentation //## \brief Set the bounding box (in index/unit coordinates) //## //## Only possible via the BoundsArray to make clear that a //## copy of the bounding-box is stored, not a reference to it. virtual void SetBounds(const BoundsArrayType& bounds); #endif //##Documentation //## @brief Set the bounding box (in index/unit coordinates) via a float array virtual void SetFloatBounds(const float bounds[6]); //##Documentation //## @brief Set the bounding box (in index/unit coordinates) via a double array virtual void SetFloatBounds(const double bounds[6]); //##Documentation //## @brief When switching from an Image Geometry to a normal Geometry (and the other way around), you have to change the origin as well (See Geometry Documentation)! This function will change the "isImageGeometry" bool flag and changes the origin respectively. virtual void ChangeImageGeometryConsideringOriginOffset( const bool isAnImageGeometry ); //##Documentation //## @brief Checks, if the given geometry can be converted to 2D without information loss //## e.g. when a 2D image is saved, the matrix is usually cropped to 2x2, and when you load it back to MITK //## it will be filled with standard values. This function checks, if information would be lost during this //## procedure virtual bool Is2DConvertable(); //##Documentation //## @brief Get the time bounds (in ms) itkGetConstReferenceMacro(TimeBounds, TimeBounds); //##Documentation //## @brief Set the time bounds (in ms) virtual void SetTimeBounds(const TimeBounds& timebounds); //##Documentation //## @brief Get the position of the corner number \a id (in world coordinates) //## //## See SetImageGeometry for how a corner is defined on images. Point3D GetCornerPoint(int id) const; //##Documentation //## @brief Get the position of a corner (in world coordinates) //## //## See SetImageGeometry for how a corner is defined on images. Point3D GetCornerPoint(bool xFront=true, bool yFront=true, bool zFront=true) const; //##Documentation //## @brief Get vector along bounding-box in the specified @a direction in mm //## //## The length of the vector is the size of the bounding-box in the //## specified @a direction in mm //## \sa GetMatrixColumn Vector3D GetAxisVector(unsigned int direction) const { Vector3D frontToBack; frontToBack.SetVnlVector(m_IndexToWorldTransform->GetMatrix().GetVnlMatrix().get_column(direction)); frontToBack *= GetExtent(direction); return frontToBack; } //##Documentation //## @brief Get the center of the bounding-box in mm //## Point3D GetCenter() const { assert(m_BoundingBox.IsNotNull()); return m_IndexToWorldTransform->TransformPoint(m_BoundingBox->GetCenter()); } //##Documentation //## @brief Get the squared length of the diagonal of the bounding-box in mm //## double GetDiagonalLength2() const { Vector3D diagonalvector = GetCornerPoint()-GetCornerPoint(false, false, false); return diagonalvector.GetSquaredNorm(); } //##Documentation //## @brief Get the length of the diagonal of the bounding-box in mm //## double GetDiagonalLength() const { return sqrt(GetDiagonalLength2()); } //##Documentation //## @brief Get a VnlVector along bounding-box in the specified //## @a direction, length is spacing //## //## \sa GetAxisVector VnlVector GetMatrixColumn(unsigned int direction) const { return m_IndexToWorldTransform->GetMatrix().GetVnlMatrix().get_column(direction); } #ifdef DOXYGEN_SKIP //##Documentation //## @brief Get the extent of the bounding box (in index/unit coordinates) //## //## To access the extent in mm use GetExtentInMM ScalarType GetExtent(unsigned int direction) const; #endif //##Documentation //## @brief Get the extent of the bounding-box in the specified @a direction in mm //## //## Equals length of GetAxisVector(direction). ScalarType GetExtentInMM(int direction) const { return m_IndexToWorldTransform->GetMatrix().GetVnlMatrix().get_column(direction).magnitude()*GetExtent(direction); } //##Documentation //## @brief Set the extent of the bounding-box in the specified @a direction in mm //## //## @note This changes the matrix in the transform, @a not the bounds, which are given in units! virtual void SetExtentInMM(int direction, ScalarType extentInMM); //##Documentation //## @brief Get the m_IndexToWorldTransform as a vtkLinearTransform vtkLinearTransform* GetVtkTransform() const { return (vtkLinearTransform*)m_VtkIndexToWorldTransform; } //##Documentation //## @brief Set the origin, i.e. the upper-left corner of the plane //## virtual void SetOrigin(const Point3D& origin); //##Documentation //## @brief Translate the origin by a vector //## virtual void Translate(const Vector3D& vector); //##Documentation //## @brief Set the transform to identity //## virtual void SetIdentity(); //##Documentation //## @brief Compose new IndexToWorldTransform with a given transform. //## //## This method composes m_IndexToWorldTransform with another transform, //## 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. virtual void Compose( const AffineGeometryFrame3D::TransformType * other, bool pre = 0 ); //##Documentation //## @brief Compose new IndexToWorldTransform with a given vtkMatrix4x4. //## //## Converts the vtkMatrix4x4 into a itk-transform and calls the previous method. virtual void Compose( const vtkMatrix4x4 * vtkmatrix, bool pre = 0 ); //##Documentation //## @brief Get the origin, e.g. the upper-left corner of the plane const Point3D& GetOrigin() const { return m_Origin; } //##Documentation //## @brief Get the origin as VnlVector //## //## \sa GetOrigin VnlVector GetOriginVnl() const { return const_cast(this)->m_Origin.GetVnlVector(); } //##Documentation //## @brief Convert world coordinates (in mm) of a \em point to (continuous!) index coordinates //## \warning If you need (discrete) integer index coordinates (e.g., for iterating easily over an image), //## use WorldToIndex(const mitk::Point3D& pt_mm, itk::Index &index). //## For further information about coordinates types, please see the Geometry documentation void WorldToIndex(const mitk::Point3D& pt_mm, mitk::Point3D& pt_units) const; //##Documentation //## @brief Convert (continuous or discrete) index coordinates of a \em point to world coordinates (in mm) //## For further information about coordinates types, please see the Geometry documentation void IndexToWorld(const mitk::Point3D& pt_units, mitk::Point3D& pt_mm) const; //##Documentation //## @brief Convert world coordinates (in mm) of a \em vector //## \a vec_mm to (continuous!) index coordinates. //## @deprecated First parameter (Point3D) is not used. If possible, please use void WorldToIndex(const mitk::Vector3D& vec_mm, mitk::Vector3D& vec_units) const. //## For further information about coordinates types, please see the Geometry documentation void WorldToIndex(const mitk::Point3D& atPt3d_mm, const mitk::Vector3D& vec_mm, mitk::Vector3D& vec_units) const; //##Documentation //## @brief Convert world coordinates (in mm) of a \em vector //## \a vec_mm to (continuous!) index coordinates. //## For further information about coordinates types, please see the Geometry documentation void WorldToIndex(const mitk::Vector3D& vec_mm, mitk::Vector3D& vec_units) const; //##Documentation //## @brief Convert (continuous or discrete) index coordinates of a \em vector //## \a vec_units to world coordinates (in mm) //## @deprecated First parameter (Point3D) is not used. If possible, please use void IndexToWorld(const mitk::Vector3D& vec_units, mitk::Vector3D& vec_mm) const. //## For further information about coordinates types, please see the Geometry documentation void IndexToWorld(const mitk::Point3D& atPt3d_units, const mitk::Vector3D& vec_units, mitk::Vector3D& vec_mm) const; //##Documentation //## @brief Convert (continuous or discrete) index coordinates of a \em vector //## \a vec_units to world coordinates (in mm) //## For further information about coordinates types, please see the Geometry documentation void IndexToWorld(const mitk::Vector3D& vec_units, mitk::Vector3D& vec_mm) const; //##Documentation //## @brief Convert world coordinates (in mm) of a \em point to (discrete!) index coordinates. //## This method rounds to integer indices! //## For further information about coordinates types, please see the Geometry documentation template void WorldToIndex(const mitk::Point3D& pt_mm, itk::Index &index) const { typedef itk::Index IndexType; mitk::Point3D pt_units; this->WorldToIndex(pt_mm, pt_units); int i, dim=index.GetIndexDimension(); if(dim>3) { index.Fill(0); dim=3; } for(i=0;i( pt_units[i] ); } } //##Documentation //## @brief Deprecated for use with ITK version 3.10 or newer. //## Convert world coordinates (in mm) of a \em point to //## ITK physical coordinates (in mm, but without a possible rotation) //## //## This method is useful if you have want to access an mitk::Image //## via an itk::Image. ITK v3.8 and older did not support rotated (tilted) //## images, i.e., ITK images are always parallel to the coordinate axes. //## When accessing a (possibly rotated) mitk::Image via an itk::Image //## the rotational part of the transformation in the Geometry3D is //## simply discarded; in other word: only the origin and spacing is //## used by ITK, not the complete matrix available in MITK. //## With WorldToItkPhysicalPoint you can convert an MITK world //## coordinate (including the rotation) into a coordinate that //## can be used with the ITK image as a ITK physical coordinate //## (excluding the rotation). template void WorldToItkPhysicalPoint(const mitk::Point3D& pt_mm, itk::Point& itkPhysicalPoint) const { mitk::vtk2itk(pt_mm, itkPhysicalPoint); } //##Documentation //## @brief Deprecated for use with ITK version 3.10 or newer. //## Convert ITK physical coordinates of a \em point (in mm, //## but without a rotation) into MITK world coordinates (in mm) //## //## For more information, see WorldToItkPhysicalPoint. template void ItkPhysicalPointToWorld(const itk::Point& itkPhysicalPoint, mitk::Point3D& pt_mm) const { mitk::vtk2itk(itkPhysicalPoint, pt_mm); } //##Documentation //## @brief Initialize the Geometry3D virtual void Initialize(); //##Documentation //## @brief Is this an ImageGeometry? //## //## For more information, see SetImageGeometry itkGetConstMacro(ImageGeometry, bool); //##Documentation //## @brief Define that this Geometry3D is refering to an Image //## //## A geometry referring to an Image needs a slightly different //## definition of the position of the corners (see GetCornerPoint). //## The position of a voxel is defined by the position of its center. //## If we would use the origin (position of the (center of) the first //## voxel) as a corner and display this point, it would seem to be //## \em not at the corner but a bit within the image. Even worse for //## the opposite corner of the image: here the corner would appear //## outside the image (by half of the voxel diameter). Thus, we have //## to correct for this and to be able to do that, we need to know //## that the Geometry3D is referring to an Image. itkSetMacro(ImageGeometry, bool); itkBooleanMacro(ImageGeometry); //##Documentation //## @brief Is this Geometry3D in a state that is valid? virtual bool IsValid() const { return m_Valid; } //##Documentation //## @brief Test whether the point \a p (world coordinates in mm) is //## inside the bounding box bool IsInside(const mitk::Point3D& p) const { mitk::Point3D index; WorldToIndex(p, index); return IsIndexInside(index); } //##Documentation //## @brief Test whether the point \a p ((continous!)index coordinates in units) is //## inside the bounding box bool IsIndexInside(const mitk::Point3D& index) const { bool inside = false; //if it is an image geometry, we need to convert the index to discrete values //this is done by applying the rounding function also used in WorldToIndex (see line 323) if (m_ImageGeometry) { mitk::Point3D discretIndex; discretIndex[0]=itk::Math::RoundHalfIntegerUp( index[0] ); discretIndex[1]=itk::Math::RoundHalfIntegerUp( index[1] ); discretIndex[2]=itk::Math::RoundHalfIntegerUp( index[2] ); inside = m_BoundingBox->IsInside(discretIndex); //we have to check if the index is at the upper border of each dimension, // because the boundingbox is not centerbased if (inside) { const BoundingBox::BoundsArrayType& bounds = m_BoundingBox->GetBounds(); if((discretIndex[0] == bounds[1]) || (discretIndex[1] == bounds[3]) || (discretIndex[2] == bounds[5])) inside = false; } } else inside = m_BoundingBox->IsInside(index); return inside; } //##Documentation //## @brief Convenience method for working with ITK indices template bool IsIndexInside(const itk::Index &index) const { int i, dim=index.GetIndexDimension(); Point3D pt_index; pt_index.Fill(0); for ( i = 0; i < dim; ++i ) { pt_index[i] = index[i]; } return IsIndexInside(pt_index); } //##Documentation //## @brief Get the spacing (size of a pixel). //## itkGetConstReferenceMacro(Spacing, mitk::Vector3D); //##Documentation //## @brief Get the spacing as a float[3] array. const float* GetFloatSpacing() const; //##Documentation //## @brief Set the spacing (m_Spacing) virtual void SetSpacing(const mitk::Vector3D& aSpacing); //##Documentation //## @brief Get the DICOM FrameOfReferenceID referring to the //## used world coordinate system itkGetConstMacro(FrameOfReferenceID, unsigned int); //##Documentation //## @brief Set the DICOM FrameOfReferenceID referring to the //## used world coordinate system itkSetMacro(FrameOfReferenceID, unsigned int); //##Documentation //## @brief Copy the ITK transform //## (m_IndexToWorldTransform) to the VTK transform //## \sa SetIndexToWorldTransform void TransferItkToVtkTransform(); //##Documentation //## @brief Copy the VTK transform //## to the ITK transform (m_IndexToWorldTransform) //## \sa SetIndexToWorldTransform void TransferVtkToItkTransform(); //##Documentation //## @brief Get the parametric bounding-box //## //## See AbstractTransformGeometry for an example usage of this. itkGetConstObjectMacro(ParametricBoundingBox, BoundingBox); //##Documentation //## @brief Get the parametric bounds //## //## See AbstractTransformGeometry for an example usage of this. const BoundingBox::BoundsArrayType& GetParametricBounds() const { assert(m_ParametricBoundingBox.IsNotNull()); return m_ParametricBoundingBox->GetBounds(); } //##Documentation //## @brief Get the parametric extent //## //## See AbstractTransformGeometry for an example usage of this. mitk::ScalarType GetParametricExtent(int direction) const { assert(direction>=0 && direction<3); assert(m_ParametricBoundingBox.IsNotNull()); BoundingBoxType::BoundsArrayType bounds = m_ParametricBoundingBox->GetBounds(); return bounds[direction*2+1]-bounds[direction*2]; } //##Documentation //## @brief Get the parametric extent in mm //## //## See AbstractTransformGeometry for an example usage of this. virtual mitk::ScalarType GetParametricExtentInMM(int direction) const { return GetExtentInMM(direction); } //##Documentation //## @brief Get the parametric transform //## //## See AbstractTransformGeometry for an example usage of this. virtual const Transform3D* GetParametricTransform() const { return m_IndexToWorldTransform; } //##Documentation //## @brief Calculates a bounding-box around the geometry relative //## to a coordinate system defined by a transform //## mitk::BoundingBox::Pointer CalculateBoundingBoxRelativeToTransform(const mitk::AffineTransform3D* transform) const; //##Documentation //## @brief clones the geometry //## //## Overwrite in all sub-classes. //## Normally looks like: //## \code //## Self::Pointer newGeometry = new Self(*this); //## newGeometry->UnRegister(); //## return newGeometry.GetPointer(); //## \endcode virtual itk::LightObject::Pointer InternalClone() const; //##Documentation //##@brief executes affine operations (translate, rotate, scale) virtual void ExecuteOperation(Operation* operation); + // + // Static Functions + // + /** + \brief A function comparing two geometries for beeing identical + + The function compares the spacing, origin, axisvectors, extents and the matrix of the + IndexToWorldTransform (elementwise) + */ + static bool MITK_CORE_EXPORT AreEqual(const mitk::Geometry3D* rightHandSide, const mitk::Geometry3D* leftHandSide); + protected: Geometry3D(); Geometry3D(const Geometry3D& other); static const std::string GetTransformAsString( TransformType* transformType ); virtual ~Geometry3D(); virtual void PrintSelf(std::ostream& os, itk::Indent indent) const; virtual void BackTransform(const mitk::Point3D& in, mitk::Point3D& out) const; //##Documentation //## @brief Deprecated virtual void BackTransform(const mitk::Point3D& at, const mitk::Vector3D& in, mitk::Vector3D& out) const; //Without redundant parameter Point3D virtual void BackTransform(const mitk::Vector3D& in, mitk::Vector3D& out) const; //##Documentation //## @brief Set the parametric bounds //## //## Protected in this class, made public in some sub-classes, e.g., //## ExternAbstractTransformGeometry. virtual void SetParametricBounds(const BoundingBox::BoundsArrayType& bounds); /** Resets sub-transforms that compose m_IndexToWorldTransform, by using * the current value of m_IndexToWorldTransform and setting the rotation * component to zero. */ virtual void ResetSubTransforms(); mutable mitk::BoundingBox::Pointer m_ParametricBoundingBox; mutable mitk::TimeBounds m_TimeBounds; vtkMatrix4x4* m_VtkMatrix; bool m_ImageGeometry; //##Documentation //## @brief Spacing of the data. Only significant if the geometry describes //## an Image (m_ImageGeometry==true). mitk::Vector3D m_Spacing; bool m_Valid; unsigned int m_FrameOfReferenceID; static const std::string INDEX_TO_OBJECT_TRANSFORM; static const std::string OBJECT_TO_NODE_TRANSFORM; static const std::string INDEX_TO_NODE_TRANSFORM; static const std::string INDEX_TO_WORLD_TRANSFORM; private: mutable TransformType::Pointer m_InvertedTransform; mutable unsigned long m_IndexToWorldTransformLastModified; VnlQuaternionType m_RotationQuaternion; float m_FloatSpacing[3]; vtkMatrixToLinearTransform* m_VtkIndexToWorldTransform; //##Documentation //## @brief Origin, i.e. upper-left corner of the plane //## Point3D m_Origin; }; - -namespace compare -{ - -/** - \brief A function comparing two geometries for beeing identical - - The function compares the spacing, origin, axisvectors, extents and the matrix of the - IndexToWorldTransform (elementwise) - */ -bool MITK_CORE_EXPORT IsEqual( const mitk::Geometry3D* rhs, const mitk::Geometry3D* lhs); -} - } // namespace mitk #endif /* GEOMETRY3D_H_HEADER_INCLUDED_C1EBD0AD */ diff --git a/Core/Code/DataManagement/mitkImage.cpp b/Core/Code/DataManagement/mitkImage.cpp index e819819739..d5473d5f2f 100644 --- a/Core/Code/DataManagement/mitkImage.cpp +++ b/Core/Code/DataManagement/mitkImage.cpp @@ -1,1335 +1,1335 @@ /*=================================================================== 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 "mitkImage.h" #include "mitkImageStatisticsHolder.h" #include "mitkPixelTypeMultiplex.h" #include #include #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(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(other).GetVolumeData(i); this->SetVolume(volume->GetData(), i); } } else { ImageDataItemPointer volume = const_cast(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 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(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;sSetComplete(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;sGetParent()!=vol) { // copy data of slices in volume size_t offset = ((size_t) s)*size; std::memcpy(static_cast(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;tGetParent()!=ch) { // copy data of volume in channel size_t offset = ((size_t) t)*m_OffsetTable[3]*(ptypeSize); std::memcpy(static_cast(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;sIsComplete())) 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(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(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(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;im_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; im_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(&geometry); if ( timeGeometry != NULL ) { dimensions[3] = timeGeometry->GetTimeSteps(); } } if ( dimensions[3] > 1 ) dimension = 4; Initialize( type, dimension, dimensions, channels ); SetGeometry(static_cast(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.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;iGetDimensions()[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(), m_Dimension, tmpDimensions, channels); break; case VTK_UNSIGNED_CHAR: //pixelType.Initialize(typeid(unsigned char), vtkimagedata->GetNumberOfScalarComponents()); Initialize(mitk::MakeScalarPixelType(), m_Dimension, tmpDimensions, channels); break; case VTK_SHORT: //pixelType.Initialize(typeid(short), vtkimagedata->GetNumberOfScalarComponents()); Initialize(mitk::MakeScalarPixelType(), m_Dimension, tmpDimensions, channels); break; case VTK_UNSIGNED_SHORT: //pixelType.Initialize(typeid(unsigned short), vtkimagedata->GetNumberOfScalarComponents()); Initialize(mitk::MakeScalarPixelType(), m_Dimension, tmpDimensions, channels); break; case VTK_INT: //pixelType.Initialize(typeid(int), vtkimagedata->GetNumberOfScalarComponents()); Initialize(mitk::MakeScalarPixelType(), m_Dimension, tmpDimensions, channels); break; case VTK_UNSIGNED_INT: //pixelType.Initialize(typeid(unsigned int), vtkimagedata->GetNumberOfScalarComponents()); Initialize(mitk::MakeScalarPixelType(), m_Dimension, tmpDimensions, channels); break; case VTK_LONG: //pixelType.Initialize(typeid(long), vtkimagedata->GetNumberOfScalarComponents()); Initialize(mitk::MakeScalarPixelType(), m_Dimension, tmpDimensions, channels); break; case VTK_UNSIGNED_LONG: //pixelType.Initialize(typeid(unsigned long), vtkimagedata->GetNumberOfScalarComponents()); Initialize(mitk::MakeScalarPixelType(), m_Dimension, tmpDimensions, channels); break; case VTK_FLOAT: //pixelType.Initialize(typeid(float), vtkimagedata->GetNumberOfScalarComponents()); Initialize(mitk::MakeScalarPixelType(), m_Dimension, tmpDimensions, channels); break; case VTK_DOUBLE: //pixelType.Initialize(typeid(double), vtkimagedata->GetNumberOfScalarComponents()); Initialize(mitk::MakeScalarPixelType(), 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(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 << " BitsPerElement: " << 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 & 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; } -bool mitk::compare::IsEqual(const mitk::Image* rhs, const mitk::Image* lhs) +bool mitk::Image::AreEqual(const mitk::Image* rightHandSide, const mitk::Image* leftHandSide) { // check the validity of input - if( rhs == NULL || lhs == NULL ) + if( rightHandSide == NULL || leftHandSide == NULL ) { - MITK_INFO << "[AreIdentical( Image )] Input null. "; + MITK_INFO << "[AreEqual( Image )] Input null. "; return false; } // dimensionality - const unsigned int rhsDimension = rhs->GetDimension(); - if( rhsDimension != lhs->GetDimension() ) + const unsigned int rhsDimension = rightHandSide->GetDimension(); + if( rhsDimension != leftHandSide->GetDimension() ) { - MITK_INFO << "[AreIdentical( Image )] Dimensionality differs."; + MITK_INFO << "[AreEqual( Image )] Dimensionality differs."; return false; } // compare each dimension bool dimensionsIdentical = true; for( unsigned int i=0; i< rhsDimension; i++) { - if( rhs->GetDimension(i) != lhs->GetDimension(i) ) + if( rightHandSide->GetDimension(i) != leftHandSide->GetDimension(i) ) dimensionsIdentical = false; } if(!dimensionsIdentical) { - MITK_INFO << "[AreIdentical( Image )] Some dimension differs."; + MITK_INFO << "[AreEqual( Image )] Some dimension differs."; return false; } // compare geometry - if( !IsEqual(rhs->GetGeometry(), lhs->GetGeometry()) ) + if( !mitk::Geometry3D::AreEqual(rightHandSide->GetGeometry(), leftHandSide->GetGeometry()) ) { - MITK_INFO << "[AreIdentical( Image )] --> Geometry3D differs."; + MITK_INFO << "[AreEqual( Image )] --> Geometry3D differs."; return false; } // pixel type - if( !(rhs->GetPixelType() == lhs->GetPixelType()) ) + if( !(rightHandSide->GetPixelType() == leftHandSide->GetPixelType()) ) { - MITK_INFO << "[AreIdentical( Image )] PixelType differs."; + MITK_INFO << "[AreEqual( Image )] PixelType differs."; return false; } // compare pixel values return true; } #include "mitkImageStatisticsHolder.h" //##Documentation mitk::ScalarType mitk::Image::GetScalarValueMin(int t) const { return m_ImageStatistics->GetScalarValueMin(t); } //##Documentation //## \brief Get the maximum for scalar images mitk::ScalarType mitk::Image::GetScalarValueMax(int t) const { return m_ImageStatistics->GetScalarValueMax(t); } //##Documentation //## \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); } diff --git a/Core/Code/DataManagement/mitkImage.h b/Core/Code/DataManagement/mitkImage.h index 77565a3949..31bfe8087a 100644 --- a/Core/Code/DataManagement/mitkImage.h +++ b/Core/Code/DataManagement/mitkImage.h @@ -1,684 +1,680 @@ /*=================================================================== 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. ===================================================================*/ #ifndef MITKIMAGE_H_HEADER_INCLUDED_C1C2FCD2 #define MITKIMAGE_H_HEADER_INCLUDED_C1C2FCD2 #include #include "mitkSlicedData.h" #include "mitkBaseData.h" #include "mitkLevelWindow.h" #include "mitkPlaneGeometry.h" #include "mitkImageDataItem.h" #include "mitkImageDescriptor.h" #include "mitkImageAccessorBase.h" #include "mitkImageVtkAccessor.h" #ifndef __itkHistogram_h #include #endif class vtkImageData; namespace mitk { class SubImageSelector; class ImageTimeSelector; class ImageStatisticsHolder; //##Documentation //## @brief Image class for storing images //## //## Can be asked for header information, the data vector, //## the mitkIpPicDescriptor struct or vtkImageData objects. If not the complete //## data is required, the appropriate SubImageSelector class should be used //## for access. //## Image organizes sets of slices (s x 2D), volumes (t x 3D) and channels (n //## x ND). Channels are for different kind of data, e.g., morphology in //## channel 0, velocities in channel 1. All channels must have the same Geometry! In //## particular, the dimensions of all channels are the same, only the pixel-type //## may differ between channels. //## //## For importing ITK images use of mitk::ITKImageImport is recommended, see //## \ref Adaptor. //## //## For ITK v3.8 and older: Converting coordinates from the ITK physical //## coordinate system (which does not support rotated images) to the MITK world //## coordinate system should be performed via the Geometry3D of the Image, see //## Geometry3D::WorldToItkPhysicalPoint. //## @ingroup Data class MITK_CORE_EXPORT Image : public SlicedData { friend class SubImageSelector; friend class ImageAccessorBase; friend class ImageVtkAccessor; friend class ImageReadAccessor; friend class ImageWriteAccessor; public: mitkClassMacro(Image, SlicedData); itkNewMacro(Self); mitkCloneMacro(Image); /** Smart Pointer type to a ImageDataItem. */ typedef itk::SmartPointer ImageDataItemPointer; typedef itk::Statistics::Histogram HistogramType; typedef mitk::ImageStatisticsHolder* StatisticsHolderPointer; //## @param ImportMemoryManagementType This parameter is evaluated when setting new data to an image. //## The different options are: //## CopyMemory: Data to be set is copied and assigned to a new memory block. Data memory block will be freed on deletion of mitk::Image. //## MamageMemory: Data to be set will be referenced, and Data memory block will be freed on deletion of mitk::Image. //## Reference Memory: Data to be set will be referenced, but Data memory block will not be freed on deletion of mitk::Image. //## DontManageMemory = ReferenceMemory. enum ImportMemoryManagementType { CopyMemory, ManageMemory, ReferenceMemory, DontManageMemory = ReferenceMemory }; //##Documentation //## @brief Vector container of SmartPointers to ImageDataItems; //## Class is only for internal usage to allow convenient access to all slices over iterators; //## See documentation of ImageDataItem for details. typedef std::vector ImageDataItemPointerArray; public: //##Documentation //## @brief Returns the PixelType of channel @a n. const mitk::PixelType GetPixelType(int n = 0) const; //##Documentation //## @brief Get dimension of the image //## unsigned int GetDimension() const; //##Documentation //## @brief Get the size of dimension @a i (e.g., i=0 results in the number of pixels in x-direction). //## //## @sa GetDimensions() unsigned int GetDimension(int i) const; /** @brief Get the data vector of the complete image, i.e., of all channels linked together. If you only want to access a slice, volume at a specific time or single channel use one of the SubImageSelector classes. \deprecatedSince{2012_09} Please use image accessors instead: See Doxygen/Related-Pages/Concepts/Image. This method can be replaced by ImageWriteAccessor::GetData() or ImageReadAccessor::GetData() */ DEPRECATED(virtual void* GetData()); public: /** @brief Get the pixel value at one specific index position. The pixel type is always being converted to double. \deprecatedSince{2012_09} Please use image accessors instead: See Doxygen/Related-Pages/Concepts/Image. This method can be replaced by a method from ImagePixelWriteAccessor or ImagePixelReadAccessor */ DEPRECATED(double GetPixelValueByIndex(const mitk::Index3D& position, unsigned int timestep = 0)); /** @brief Get the pixel value at one specific world position. The pixel type is always being converted to double. \deprecatedSince{2012_09} Please use image accessors instead: See Doxygen/Related-Pages/Concepts/Image. This method can be replaced by a method from ImagePixelWriteAccessor or ImagePixelReadAccessor */ DEPRECATED(double GetPixelValueByWorldCoordinate(const mitk::Point3D& position, unsigned int timestep = 0)); //##Documentation //## @brief Get a volume at a specific time @a t of channel @a n as a vtkImageData. virtual ImageVtkAccessor* GetVtkImageData(int t = 0, int n = 0); //##Documentation //## @brief Get the complete image, i.e., all channels linked together, as a @a mitkIpPicDescriptor. //## //## If you only want to access a slice, volume at a specific time or single channel //## use one of the SubImageSelector classes. //virtual mitkIpPicDescriptor* GetPic(); //##Documentation //## @brief Check whether slice @a s at time @a t in channel @a n is set virtual bool IsSliceSet(int s = 0, int t = 0, int n = 0) const; //##Documentation //## @brief Check whether volume at time @a t in channel @a n is set virtual bool IsVolumeSet(int t = 0, int n = 0) const; //##Documentation //## @brief Check whether the channel @a n is set virtual bool IsChannelSet(int n = 0) const; //##Documentation //## @brief Set @a data as slice @a s at time @a t in channel @a n. It is in //## the responsibility of the caller to ensure that the data vector @a data //## is really a slice (at least is not smaller than a slice), since there is //## no chance to check this. //## //## The data is copied to an array managed by the image. If the image shall //## reference the data, use SetImportSlice with ImportMemoryManagementType //## set to ReferenceMemory. For importing ITK images use of mitk:: //## ITKImageImport is recommended. //## @sa SetPicSlice, SetImportSlice, SetImportVolume virtual bool SetSlice(const void *data, int s = 0, int t = 0, int n = 0); //##Documentation //## @brief Set @a data as volume at time @a t in channel @a n. It is in //## the responsibility of the caller to ensure that the data vector @a data //## is really a volume (at least is not smaller than a volume), since there is //## no chance to check this. //## //## The data is copied to an array managed by the image. If the image shall //## reference the data, use SetImportVolume with ImportMemoryManagementType //## set to ReferenceMemory. For importing ITK images use of mitk:: //## ITKImageImport is recommended. //## @sa SetPicVolume, SetImportVolume virtual bool SetVolume(const void *data, int t = 0, int n = 0); //##Documentation //## @brief Set @a data in channel @a n. It is in //## the responsibility of the caller to ensure that the data vector @a data //## is really a channel (at least is not smaller than a channel), since there is //## no chance to check this. //## //## The data is copied to an array managed by the image. If the image shall //## reference the data, use SetImportChannel with ImportMemoryManagementType //## set to ReferenceMemory. For importing ITK images use of mitk:: //## ITKImageImport is recommended. //## @sa SetPicChannel, SetImportChannel virtual bool SetChannel(const void *data, int n = 0); //##Documentation //## @brief Set @a data as slice @a s at time @a t in channel @a n. It is in //## the responsibility of the caller to ensure that the data vector @a data //## is really a slice (at least is not smaller than a slice), since there is //## no chance to check this. //## //## The data is managed according to the parameter \a importMemoryManagement. //## @sa SetPicSlice virtual bool SetImportSlice(void *data, int s = 0, int t = 0, int n = 0, ImportMemoryManagementType importMemoryManagement = CopyMemory ); //##Documentation //## @brief Set @a data as volume at time @a t in channel @a n. It is in //## the responsibility of the caller to ensure that the data vector @a data //## is really a volume (at least is not smaller than a volume), since there is //## no chance to check this. //## //## The data is managed according to the parameter \a importMemoryManagement. //## @sa SetPicVolume virtual bool SetImportVolume(void *data, int t = 0, int n = 0, ImportMemoryManagementType importMemoryManagement = CopyMemory ); //##Documentation //## @brief Set @a data in channel @a n. It is in //## the responsibility of the caller to ensure that the data vector @a data //## is really a channel (at least is not smaller than a channel), since there is //## no chance to check this. //## //## The data is managed according to the parameter \a importMemoryManagement. //## @sa SetPicChannel virtual bool SetImportChannel(void *data, int n = 0, ImportMemoryManagementType importMemoryManagement = CopyMemory ); //##Documentation //## initialize new (or re-initialize) image information //## @warning Initialize() by pic assumes a plane, evenly spaced geometry starting at (0,0,0). virtual void Initialize(const mitk::PixelType& type, unsigned int dimension, const unsigned int *dimensions, unsigned int channels = 1); //##Documentation //## initialize new (or re-initialize) image information by a Geometry3D //## //## @param tDim override time dimension (@a n[3]) if @a geometry is a TimeSlicedGeometry (if >0) virtual void Initialize(const mitk::PixelType& type, const mitk::Geometry3D& geometry, unsigned int channels = 1, int tDim=-1); //##Documentation //## initialize new (or re-initialize) image information by a Geometry2D and number of slices //## //## Initializes the bounding box according to the width/height of the //## Geometry2D and @a sDim via SlicedGeometry3D::InitializeEvenlySpaced. //## The spacing is calculated from the Geometry2D. //## @param tDim override time dimension (@a n[3]) if @a geometry is a TimeSlicedGeometry (if >0) //## \sa SlicedGeometry3D::InitializeEvenlySpaced virtual void Initialize(const mitk::PixelType& type, int sDim, const mitk::Geometry2D& geometry2d, bool flipped = false, unsigned int channels = 1, int tDim=-1); //##Documentation //## initialize new (or re-initialize) image information by another //## mitk-image. //## Only the header is used, not the data vector! //## virtual void Initialize(const mitk::Image* image); virtual void Initialize(const mitk::ImageDescriptor::Pointer inDesc); //##Documentation //## initialize new (or re-initialize) image information by @a pic. //## Dimensions and @a Geometry3D /@a Geometry2D are set according //## to the tags in @a pic. //## Only the header is used, not the data vector! Use SetPicVolume(pic) //## to set the data vector. //## //## @param tDim override time dimension (@a n[3]) in @a pic (if >0) //## @param sDim override z-space dimension (@a n[2]) in @a pic (if >0) //## @warning Initialize() by pic assumes a plane, evenly spaced geometry starting at (0,0,0). //virtual void Initialize(const mitkIpPicDescriptor* pic, int channels = 1, int tDim = -1, int sDim = -1); //##Documentation //## initialize new (or re-initialize) image information by @a vtkimagedata, //## a vtk-image. //## Only the header is used, not the data vector! Use //## SetVolume(vtkimage->GetScalarPointer()) to set the data vector. //## //## @param tDim override time dimension in @a vtkimagedata (if >0 and <) //## @param sDim override z-space dimension in @a vtkimagedata (if >0 and <) //## @param pDim override y-space dimension in @a vtkimagedata (if >0 and <) virtual void Initialize(vtkImageData* vtkimagedata, int channels = 1, int tDim = -1, int sDim = -1, int pDim = -1); //##Documentation //## initialize new (or re-initialize) image information by @a itkimage, //## a templated itk-image. //## Only the header is used, not the data vector! Use //## SetVolume(itkimage->GetBufferPointer()) to set the data vector. //## //## @param tDim override time dimension in @a itkimage (if >0 and <) //## @param sDim override z-space dimension in @a itkimage (if >0 and <) template void InitializeByItk(const itkImageType* itkimage, int channels = 1, int tDim = -1, int sDim=-1) { if(itkimage==NULL) return; MITK_DEBUG << "Initializing MITK image from ITK image."; // build array with dimensions in each direction with at least 4 entries m_Dimension=itkimage->GetImageDimension(); unsigned int i, *tmpDimensions=new unsigned int[m_Dimension>4?m_Dimension:4]; for(i=0;iGetLargestPossibleRegion().GetSize().GetSize()[i]; if(m_Dimension<4) { unsigned int *p; for(i=0,p=tmpDimensions+m_Dimension;i<4-m_Dimension;++i, ++p) *p=1; } // overwrite number of slices if sDim is set if((m_Dimension>2) && (sDim>=0)) tmpDimensions[2]=sDim; // overwrite number of time points if tDim is set if((m_Dimension>3) && (tDim>=0)) tmpDimensions[3]=tDim; // rough initialization of Image // mitk::PixelType importType = ImportItkPixelType( itkimage::PixelType ); Initialize(MakePixelType(), m_Dimension, tmpDimensions, channels); const typename itkImageType::SpacingType & itkspacing = itkimage->GetSpacing(); MITK_DEBUG << "ITK spacing " << itkspacing; // access spacing of itk::Image Vector3D spacing; FillVector3D(spacing, itkspacing[0], 1.0, 1.0); if(m_Dimension >= 2) spacing[1]=itkspacing[1]; if(m_Dimension >= 3) spacing[2]=itkspacing[2]; // access origin of itk::Image Point3D origin; const typename itkImageType::PointType & itkorigin = itkimage->GetOrigin(); MITK_DEBUG << "ITK origin " << itkorigin; FillVector3D(origin, itkorigin[0], 0.0, 0.0); if(m_Dimension>=2) origin[1]=itkorigin[1]; if(m_Dimension>=3) origin[2]=itkorigin[2]; // access direction of itk::Imagm_PixelType = new mitk::PixelType(type);e and include spacing const typename itkImageType::DirectionType & itkdirection = itkimage->GetDirection(); MITK_DEBUG << "ITK direction " << itkdirection; mitk::Matrix3D matrix; matrix.SetIdentity(); unsigned int j, itkDimMax3 = (m_Dimension >= 3? 3 : m_Dimension); // check if spacing has no zero entry and itkdirection has no zero columns bool itkdirectionOk = true; mitk::ScalarType columnSum; for( j=0; j < itkDimMax3; ++j ) { columnSum = 0.0; for ( i=0; i < itkDimMax3; ++i) { columnSum += fabs(itkdirection[i][j]); } if(columnSum < mitk::eps) { itkdirectionOk = false; } if ( (spacing[j] < - mitk::eps) // (normally sized) negative value && (j==2) && (m_Dimensions[2] == 1) ) { // Negative spacings can occur when reading single DICOM slices with ITK via GDCMIO // In these cases spacing is not determind by ITK correctly (because it distinguishes correctly // between slice thickness and inter slice distance -- slice distance is meaningless for // single slices). // I experienced that ITK produced something meaningful nonetheless because is is // evaluating the tag "(0018,0088) Spacing between slices" as a fallback. This tag is not // reliable (http://www.itk.org/pipermail/insight-users/2005-September/014711.html) // but gives at least a hint. // In real world cases I experienced that this tag contained the correct inter slice distance // with a negative sign, so we just invert such negative spacings. MITK_WARN << "Illegal value of itk::Image::GetSpacing()[" << j <<"]=" << spacing[j] << ". Using inverted value " << -spacing[j]; spacing[j] = -spacing[j]; } else if (spacing[j] < mitk::eps) // value near zero { MITK_ERROR << "Illegal value of itk::Image::GetSpacing()[" << j <<"]=" << spacing[j] << ". Using 1.0 instead."; spacing[j] = 1.0; } } if(itkdirectionOk == false) { MITK_ERROR << "Illegal matrix returned by itk::Image::GetDirection():" << itkdirection << " Using identity instead."; for ( i=0; i < itkDimMax3; ++i) for( j=0; j < itkDimMax3; ++j ) if ( i == j ) matrix[i][j] = spacing[j]; else matrix[i][j] = 0.0; } else { for ( i=0; i < itkDimMax3; ++i) for( j=0; j < itkDimMax3; ++j ) matrix[i][j] = itkdirection[i][j]*spacing[j]; } // re-initialize PlaneGeometry with origin and direction PlaneGeometry* planeGeometry = static_cast(GetSlicedGeometry(0)->GetGeometry2D(0)); planeGeometry->SetOrigin(origin); planeGeometry->GetIndexToWorldTransform()->SetMatrix(matrix); // re-initialize SlicedGeometry3D SlicedGeometry3D* slicedGeometry = GetSlicedGeometry(0); slicedGeometry->InitializeEvenlySpaced(planeGeometry, m_Dimensions[2]); slicedGeometry->SetSpacing(spacing); // re-initialize TimeSlicedGeometry GetTimeSlicedGeometry()->InitializeEvenlyTimed(slicedGeometry, m_Dimensions[3]); // clean-up delete [] tmpDimensions; this->Initialize(); }; //##Documentation //## @brief Check whether slice @a s at time @a t in channel @a n is valid, i.e., //## is (or can be) inside of the image virtual bool IsValidSlice(int s = 0, int t = 0, int n = 0) const; //##Documentation //## @brief Check whether volume at time @a t in channel @a n is valid, i.e., //## is (or can be) inside of the image virtual bool IsValidVolume(int t = 0, int n = 0) const; //##Documentation //## @brief Check whether the channel @a n is valid, i.e., //## is (or can be) inside of the image virtual bool IsValidChannel(int n = 0) const; //##Documentation //## @brief Returns true if an image is rotated, i.e. its geometry's //## transformation matrix has nonzero elements besides the diagonal. //## Non-diagonal elements are checked if larger then 1/1000 of the matrix' trace. bool IsRotated() const; //##Documentation //## @brief Get the sizes of all dimensions as an integer-array. //## //## @sa GetDimension(int i); unsigned int* GetDimensions() const; ImageDescriptor::Pointer GetImageDescriptor() const { return m_ImageDescriptor; } ChannelDescriptor GetChannelDescriptor( int id = 0 ) const { return m_ImageDescriptor->GetChannelDescriptor(id); } /** \brief Sets a geometry to an image. */ virtual void SetGeometry(Geometry3D* aGeometry3D); /** * @warning for internal use only */ virtual ImageDataItemPointer GetSliceData(int s = 0, int t = 0, int n = 0, void *data = NULL, ImportMemoryManagementType importMemoryManagement = CopyMemory); /** * @warning for internal use only */ virtual ImageDataItemPointer GetVolumeData(int t = 0, int n = 0, void *data = NULL, ImportMemoryManagementType importMemoryManagement = CopyMemory); /** * @warning for internal use only */ virtual ImageDataItemPointer GetChannelData(int n = 0, void *data = NULL, ImportMemoryManagementType importMemoryManagement = CopyMemory); /** \brief (DEPRECATED) Get the minimum for scalar images */ DEPRECATED (ScalarType GetScalarValueMin(int t=0) const); /** \brief (DEPRECATED) Get the maximum for scalar images \warning This method is deprecated and will not be available in the future. Use the \a GetStatistics instead */ DEPRECATED (ScalarType GetScalarValueMax(int t=0) const); /** \brief (DEPRECATED) Get the second smallest value for scalar images \warning This method is deprecated and will not be available in the future. Use the \a GetStatistics instead */ DEPRECATED (ScalarType GetScalarValue2ndMin(int t=0) const); /** \brief (DEPRECATED) Get the smallest value for scalar images, but do not recompute it first \warning This method is deprecated and will not be available in the future. Use the \a GetStatistics instead */ DEPRECATED (ScalarType GetScalarValueMinNoRecompute( unsigned int t = 0 ) const); /** \brief (DEPRECATED) Get the second smallest value for scalar images, but do not recompute it first \warning This method is deprecated and will not be available in the future. Use the \a GetStatistics instead */ DEPRECATED (ScalarType GetScalarValue2ndMinNoRecompute( unsigned int t = 0 ) const); /** \brief (DEPRECATED) Get the second largest value for scalar images \warning This method is deprecated and will not be available in the future. Use the \a GetStatistics instead */ DEPRECATED (ScalarType GetScalarValue2ndMax(int t=0) const); /** \brief (DEPRECATED) Get the largest value for scalar images, but do not recompute it first \warning This method is deprecated and will not be available in the future. Use the \a GetStatistics instead */ DEPRECATED (ScalarType GetScalarValueMaxNoRecompute( unsigned int t = 0 ) const ); /** \brief (DEPRECATED) Get the second largest value for scalar images, but do not recompute it first \warning This method is deprecated and will not be available in the future. Use the \a GetStatistics instead */ DEPRECATED (ScalarType GetScalarValue2ndMaxNoRecompute( unsigned int t = 0 ) const); /** \brief (DEPRECATED) Get the count of voxels with the smallest scalar value in the dataset \warning This method is deprecated and will not be available in the future. Use the \a GetStatistics instead */ DEPRECATED (ScalarType GetCountOfMinValuedVoxels(int t = 0) const); /** \brief (DEPRECATED) Get the count of voxels with the largest scalar value in the dataset \warning This method is deprecated and will not be available in the future. Use the \a GetStatistics instead */ DEPRECATED (ScalarType GetCountOfMaxValuedVoxels(int t = 0) const); /** \brief (DEPRECATED) Get the count of voxels with the largest scalar value in the dataset \warning This method is deprecated and will not be available in the future. Use the \a GetStatistics instead */ DEPRECATED (unsigned int GetCountOfMaxValuedVoxelsNoRecompute( unsigned int t = 0 ) const); /** \brief (DEPRECATED) Get the count of voxels with the smallest scalar value in the dataset \warning This method is deprecated and will not be available in the future. Use the \a GetStatistics instead */ DEPRECATED (unsigned int GetCountOfMinValuedVoxelsNoRecompute( unsigned int t = 0 ) const); /** \brief Returns a pointer to the ImageStatisticsHolder object that holds all statistics information for the image. All Get-methods for statistics properties formerly accessible directly from an Image object are now moved to the new \a ImageStatisticsHolder object. */ StatisticsHolderPointer GetStatistics() const { return m_ImageStatistics; } + /** + \brief A function comparing two images for beeing identical + + Identical means same dimensionality, same dimensions and same orientation for the geometry and identical voxel values in case of integral pixel types + and a difference in the voxel values of less then mitk::eps for floating point pixel types. + */ + static bool MITK_CORE_EXPORT AreEqual( const mitk::Image* rightHandSide, const mitk::Image* leftHandSide); + protected: int GetSliceIndex(int s = 0, int t = 0, int n = 0) const; int GetVolumeIndex(int t = 0, int n = 0) const; void ComputeOffsetTable(); virtual bool IsValidTimeStep(int t) const; virtual void Expand( unsigned int timeSteps ); virtual ImageDataItemPointer AllocateSliceData(int s = 0, int t = 0, int n = 0, void *data = NULL, ImportMemoryManagementType importMemoryManagement = CopyMemory); virtual ImageDataItemPointer AllocateVolumeData(int t = 0, int n = 0, void *data = NULL, ImportMemoryManagementType importMemoryManagement = CopyMemory); virtual ImageDataItemPointer AllocateChannelData(int n = 0, void *data = NULL, ImportMemoryManagementType importMemoryManagement = CopyMemory); Image(); Image(const Image &other); virtual ~Image(); virtual void Clear(); //## @warning Has to be called by every Initialize method! virtual void Initialize(); virtual void PrintSelf(std::ostream& os, itk::Indent indent) const; mutable ImageDataItemPointerArray m_Channels; mutable ImageDataItemPointerArray m_Volumes; mutable ImageDataItemPointerArray m_Slices; unsigned int m_Dimension; unsigned int* m_Dimensions; ImageDescriptor::Pointer m_ImageDescriptor; size_t *m_OffsetTable; ImageDataItemPointer m_CompleteData; // Image statistics Holder replaces the former implementation directly inside this class friend class ImageStatisticsHolder; StatisticsHolderPointer m_ImageStatistics; private: /** Stores all existing ImageReadAccessors */ std::vector m_Readers; /** Stores all existing ImageWriteAccessors */ std::vector m_Writers; /** Stores all existing ImageVtkAccessors */ std::vector m_VtkReaders; /** A mutex, which needs to be locked to manage m_Readers and m_Writers */ itk::SimpleFastMutexLock m_ReadWriteLock; /** A mutex, which needs to be locked to manage m_VtkReaders */ itk::SimpleFastMutexLock m_VtkReadersLock; }; -/*! Namespace containing comparison functions for basic data types */ -namespace compare -{ - -/** - \brief A function comparing two images for beeing identical - - Identical means same dimensionality, same dimensions and same orientation for the geometry and identical voxel values in case of integral pixel types - and a difference in the voxel values of less then mitk::eps for floating point pixel types. - */ -bool MITK_CORE_EXPORT IsEqual( const mitk::Image* rhs, const mitk::Image* lhs); - -} +//} //##Documentation //## @brief Cast an itk::Image (with a specific type) to an mitk::Image. //## //## CastToMitkImage does not cast pixel types etc., just image data //## Needs "mitkImage.h" header included. //## If you get a compile error, try image.GetPointer(); //## @ingroup Adaptor //## \sa mitkITKImageImport template void CastToMitkImage(const itk::SmartPointer& itkimage, itk::SmartPointer& mitkoutputimage) { if(mitkoutputimage.IsNull()) { mitkoutputimage = mitk::Image::New(); } mitkoutputimage->InitializeByItk(itkimage.GetPointer()); mitkoutputimage->SetChannel(itkimage->GetBufferPointer()); } //##Documentation //## @brief Cast an itk::Image (with a specific type) to an mitk::Image. //## //## CastToMitkImage does not cast pixel types etc., just image data //## Needs "mitkImage.h" header included. //## If you get a compile error, try image.GetPointer(); //## @ingroup Adaptor //## \sa mitkITKImageImport template void CastToMitkImage(const ItkOutputImageType* itkimage, itk::SmartPointer& mitkoutputimage) { if(mitkoutputimage.IsNull()) { mitkoutputimage = mitk::Image::New(); } mitkoutputimage->InitializeByItk(itkimage); mitkoutputimage->SetChannel(itkimage->GetBufferPointer()); } } // namespace mitk #endif /* MITKIMAGE_H_HEADER_INCLUDED_C1C2FCD2 */ diff --git a/Core/Code/Testing/mitkCompareGeometry3DTest.cpp b/Core/Code/Testing/mitkCompareGeometry3DTest.cpp index 3426919200..c81572bfdd 100644 --- a/Core/Code/Testing/mitkCompareGeometry3DTest.cpp +++ b/Core/Code/Testing/mitkCompareGeometry3DTest.cpp @@ -1,40 +1,47 @@ /*=================================================================== 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 "mitkGeometry3D.h" - #include "mitkTestingMacros.h" + int mitkCompareGeometry3DTest(int /*argc*/, char* /*argv*/[]) { MITK_TEST_BEGIN(mitkCompareGeometry3DTest); - // Build up a new image Geometry mitk::Geometry3D::Pointer geometry3d = mitk::Geometry3D::New(); -// float bounds[ ] = {-10.0, 17.0, -12.0, 188.0, 13.0, 211.0}; + // float bounds[ ] = {-10.0, 17.0, -12.0, 188.0, 13.0, 211.0}; geometry3d->Initialize(); -// geometry3d->SetFloatBounds(bounds); + // geometry3d->SetFloatBounds(bounds); mitk::Geometry3D::Pointer geometry3dTmpCopy = geometry3d->Clone(); - MITK_TEST_CONDITION( mitk::compare::IsEqual( geometry3d, geometry3dTmpCopy), "A clone should be equal to its original."); + MITK_TEST_CONDITION( mitk::Geometry3D::AreEqual( geometry3d, geometry3dTmpCopy), "A clone should be equal to its original."); + + mitk::Point3D origin; + origin[0] = 0.0; + origin[1] = 0.0; + origin[2] = mitk::eps * 1.01; + geometry3dTmpCopy->SetOrigin(origin); + + MITK_TEST_CONDITION( !mitk::Geometry3D::AreEqual( geometry3d, geometry3dTmpCopy), "We modified the origin. It should differ."); MITK_TEST_END(); return EXIT_SUCCESS; } diff --git a/Core/Code/Testing/mitkImageTest.cpp b/Core/Code/Testing/mitkImageTest.cpp index abab296732..16ce97ffc7 100644 --- a/Core/Code/Testing/mitkImageTest.cpp +++ b/Core/Code/Testing/mitkImageTest.cpp @@ -1,472 +1,472 @@ /*=================================================================== 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 includes #include #include #include #include "mitkItkImageFileReader.h" #include #include #include "mitkImageGenerator.h" #include "mitkImageSliceSelector.h" // itk includes #include #include // stl includes #include // vtk includes #include // Checks if reference count is correct after using GetVtkImageData() bool ImageVtkDataReferenceCheck(const char* fname) { const std::string filename = std::string(fname); mitk::ItkImageFileReader::Pointer imageReader = mitk::ItkImageFileReader::New(); try { imageReader->SetFileName(filename); imageReader->Update(); } catch(...) { MITK_TEST_FAILED_MSG(<< "Could not read file for testing: " << filename); return false; } { mitk::Image::Pointer image = imageReader->GetOutput(); vtkImageData* vtk = image->GetVtkImageData(); if(vtk == NULL) return false; } return true; } class mitkImageTestClass { public: void SetClonedGeometry_None_ClonedEqualInput() { mitk::Image::Pointer image = mitk::ImageGenerator::GenerateRandomImage(100, 100, 100, 1, 0.2, 0.3, 0.4); //----------------- // geometry information for image mitk::Point3D origin; mitk::Vector3D right, bottom; mitk::Vector3D spacing; mitk::FillVector3D(origin, 17.0, 19.92, 7.83); mitk::FillVector3D(right, 1.0, 2.0, 3.0); mitk::FillVector3D(bottom, 0.0, -3.0, 2.0); mitk::FillVector3D(spacing, 0.78, 0.91, 2.23); //InitializeStandardPlane(rightVector, downVector, spacing) mitk::PlaneGeometry::Pointer planegeometry = mitk::PlaneGeometry::New(); planegeometry->InitializeStandardPlane(100, 100, right, bottom, &spacing); planegeometry->SetOrigin(origin); planegeometry->ChangeImageGeometryConsideringOriginOffset(true); image->SetClonedGeometry(planegeometry); mitk::Geometry3D::Pointer imageGeometry = image->GetGeometry(); itk::ScalableAffineTransform* frameNew = imageGeometry->GetIndexToWorldTransform(); itk::ScalableAffineTransform* frameOld = planegeometry->GetIndexToWorldTransform(); bool matrixEqual = true; for (int i = 0; i < 16; ++i) { double valueNew = *(frameNew->GetMatrix()[i]); double valueOld = *(frameOld->GetMatrix()[i]); //MITK_INFO << "Index: " << i << " Old: " << valueOld << " New: " << valueNew << " Difference:" << valueOld-valueNew<< std::endl; matrixEqual = matrixEqual && mitk::Equal(valueNew, valueOld, mitk::eps); } // Disabled because this test fails on the dashboard. Does not fail on my machine. // See Bug 6505 // MITK_TEST_CONDITION(matrixEqual, "Matrix elements of cloned matrix equal original matrix"); } }; int mitkImageTest(int argc, char* argv[]) { MITK_TEST_BEGIN(mitkImageTest); mitkImageTestClass tester; tester.SetClonedGeometry_None_ClonedEqualInput(); //Create Image out of nowhere mitk::Image::Pointer imgMem = mitk::Image::New(); mitk::PixelType pt = mitk::MakeScalarPixelType(); unsigned int dim[]={100,100,20}; MITK_TEST_CONDITION_REQUIRED( imgMem.IsNotNull(), "An image was created. "); // Initialize image imgMem->Initialize( pt, 3, dim); MITK_TEST_CONDITION_REQUIRED( imgMem->IsInitialized(), "Image::IsInitialized() ?"); MITK_TEST_CONDITION_REQUIRED( imgMem->GetPixelType() == pt, "PixelType was set correctly."); int *p = (int*)imgMem->GetData(); MITK_TEST_CONDITION( p != NULL, "GetData() returned not-NULL pointer."); // FIXME: this is directly changing the image data // filling image const unsigned int size = dim[0]*dim[1]*dim[2]; for(unsigned int i=0; iGetData(); MITK_TEST_CONDITION( p2 != NULL, "GetData() returned not-NULL pointer."); bool isEqual = true; for(unsigned int i=0; iGetSliceData(dim[2]/2)->GetData(); MITK_TEST_CONDITION_REQUIRED( p2 != NULL, "Valid slice data returned"); unsigned int xy_size = dim[0]*dim[1]; unsigned int start_mid_slice = (dim[2]/2)*xy_size; isEqual = true; for(unsigned int i=0; i(); imgMem->Initialize( pType , 3, dim); MITK_TEST_CONDITION_REQUIRED(imgMem->GetDimension()== 3, "Testing initialization parameter dimension!"); MITK_TEST_CONDITION_REQUIRED(imgMem->GetPixelType() == pType, "Testing initialization parameter pixeltype!"); MITK_TEST_CONDITION_REQUIRED(imgMem->GetDimension(0) == dim[0] && imgMem->GetDimension(1)== dim[1] && imgMem->GetDimension(2)== dim[2], "Testing initialization of dimensions!"); MITK_TEST_CONDITION( imgMem->IsInitialized(), "Image is initialized."); // Setting volume again: imgMem->SetVolume(imgMem->GetData()); //----------------- // geometry information for image mitk::Point3D origin; mitk::Vector3D right, bottom; mitk::Vector3D spacing; mitk::FillVector3D(origin, 17.0, 19.92, 7.83); mitk::FillVector3D(right, 1.0, 2.0, 3.0); mitk::FillVector3D(bottom, 0.0, -3.0, 2.0); mitk::FillVector3D(spacing, 0.78, 0.91, 2.23); //InitializeStandardPlane(rightVector, downVector, spacing) mitk::PlaneGeometry::Pointer planegeometry = mitk::PlaneGeometry::New(); planegeometry->InitializeStandardPlane(100, 100, right, bottom, &spacing); planegeometry->SetOrigin(origin); // Testing Initialize(const mitk::PixelType& type, const mitk::Geometry3D& geometry, unsigned int slices) with PlaneGeometry and GetData(): "; imgMem->Initialize( mitk::MakePixelType(), *planegeometry); MITK_TEST_CONDITION_REQUIRED( imgMem->GetGeometry()->GetOrigin() == static_cast(planegeometry)->GetOrigin(), "Testing correct setting of geometry via initialize!"); p = (int*)imgMem->GetData(); MITK_TEST_CONDITION_REQUIRED( p!=NULL, "GetData() returned valid pointer."); // Testing Initialize(const mitk::PixelType& type, int sDim, const mitk::PlaneGeometry& geometry) and GetData(): "; imgMem->Initialize( mitk::MakePixelType() , 40, *planegeometry); p = (int*)imgMem->GetData(); MITK_TEST_CONDITION_REQUIRED( p!=NULL, "GetData() returned valid pointer."); //----------------- // testing origin information and methods MITK_TEST_CONDITION_REQUIRED( mitk::Equal(imgMem->GetGeometry()->GetOrigin(), origin), "Testing correctness of origin via GetGeometry()->GetOrigin(): "); MITK_TEST_CONDITION_REQUIRED( mitk::Equal(imgMem->GetTimeSlicedGeometry()->GetOrigin(), origin), "Testing correctness of origin via GetTimeSlicedGeometry()->GetOrigin(): "); // Setting origin via SetOrigin(origin): "; mitk::FillVector3D(origin, 37.0, 17.92, 27.83); imgMem->SetOrigin(origin); // Test origin MITK_TEST_CONDITION_REQUIRED( mitk::Equal(imgMem->GetGeometry()->GetOrigin(), origin), "Testing correctness of changed origin via GetGeometry()->GetOrigin(): "); MITK_TEST_CONDITION_REQUIRED( mitk::Equal(imgMem->GetTimeSlicedGeometry()->GetOrigin(), origin), "Testing correctness of changed origin via GetTimeSlicedGeometry()->GetOrigin(): "); MITK_TEST_CONDITION_REQUIRED( mitk::Equal(imgMem->GetSlicedGeometry()->GetGeometry2D(0)->GetOrigin(), origin), "Testing correctness of changed origin via GetSlicedGeometry()->GetGeometry2D(0)->GetOrigin(): "); //----------------- // testing spacing information and methodsunsigned int dim[]={100,100,20}; MITK_TEST_CONDITION_REQUIRED(mitk::Equal(imgMem->GetGeometry()->GetSpacing(), spacing), "Testing correct spacing from Geometry3D!"); MITK_TEST_CONDITION_REQUIRED(mitk::Equal(imgMem->GetTimeSlicedGeometry()->GetSpacing(), spacing), "Testing correctspacing from TimeSlicedGeometry!"); mitk::FillVector3D(spacing, 7.0, 0.92, 1.83); imgMem->SetSpacing(spacing); MITK_TEST_CONDITION_REQUIRED( mitk::Equal(imgMem->GetGeometry()->GetSpacing(), spacing), "Testing correctness of changed spacing via GetGeometry()->GetSpacing(): "); MITK_TEST_CONDITION_REQUIRED( mitk::Equal(imgMem->GetTimeSlicedGeometry()->GetSpacing(), spacing), "Testing correctness of changed spacing via GetTimeSlicedGeometry()->GetSpacing(): "); MITK_TEST_CONDITION_REQUIRED( mitk::Equal(imgMem->GetSlicedGeometry()->GetGeometry2D(0)->GetSpacing(), spacing), "Testing correctness of changed spacing via GetSlicedGeometry()->GetGeometry2D(0)->GetSpacing(): "); mitk::Image::Pointer vecImg = mitk::Image::New(); vecImg->Initialize( imgMem->GetPixelType(), *imgMem->GetGeometry(), 2 /* #channels */, 0 /*tDim*/ ); vecImg->SetImportChannel(imgMem->GetData(), 0, mitk::Image::CopyMemory ); vecImg->SetImportChannel(imgMem->GetData(), 1, mitk::Image::CopyMemory ); MITK_TEST_CONDITION_REQUIRED(vecImg->GetChannelData(0)->GetData() != NULL && vecImg->GetChannelData(1)->GetData() != NULL, "Testing set and return of channel data!"); MITK_TEST_CONDITION_REQUIRED( vecImg->IsValidSlice(0,0,1) , ""); MITK_TEST_OUTPUT(<< " Testing whether CopyMemory worked"); MITK_TEST_CONDITION_REQUIRED(imgMem->GetData() != vecImg->GetData(), ""); MITK_TEST_OUTPUT(<< " Testing destruction after SetImportChannel"); vecImg = NULL; MITK_TEST_CONDITION_REQUIRED(vecImg.IsNull() , "testing destruction!"); //----------------- MITK_TEST_OUTPUT(<< "Testing initialization via vtkImageData"); MITK_TEST_OUTPUT(<< " Setting up vtkImageData"); vtkImageData* vtkimage = vtkImageData::New(); vtkimage->Initialize(); vtkimage->SetDimensions( 2, 3, 4); double vtkorigin[] = {-350,-358.203, -1363.5}; vtkimage->SetOrigin(vtkorigin); mitk::Point3D vtkoriginAsMitkPoint; mitk::vtk2itk(vtkorigin, vtkoriginAsMitkPoint); double vtkspacing[] = {1.367, 1.367, 2}; vtkimage->SetSpacing(vtkspacing); vtkimage->SetScalarType( VTK_SHORT ); vtkimage->AllocateScalars(); std::cout<<"[PASSED]"<Initialize(vtkimage); MITK_TEST_CONDITION_REQUIRED(mitkByVtkImage->IsInitialized(), ""); vtkimage->Delete(); MITK_TEST_OUTPUT(<< " Testing whether spacing has been correctly initialized from vtkImageData"); mitk::Vector3D spacing2 = mitkByVtkImage->GetGeometry()->GetSpacing(); mitk::Vector3D vtkspacingAsMitkVector; mitk::vtk2itk(vtkspacing, vtkspacingAsMitkVector); MITK_TEST_CONDITION_REQUIRED(mitk::Equal(spacing2,vtkspacingAsMitkVector), ""); MITK_TEST_OUTPUT(<< " Testing whether GetSlicedGeometry(0)->GetOrigin() has been correctly initialized from vtkImageData"); mitk::Point3D origin2 = mitkByVtkImage->GetSlicedGeometry(0)->GetOrigin(); MITK_TEST_CONDITION_REQUIRED(mitk::Equal(origin2,vtkoriginAsMitkPoint), ""); MITK_TEST_OUTPUT(<< " Testing whether GetGeometry()->GetOrigin() has been correctly initialized from vtkImageData"); origin2 = mitkByVtkImage->GetGeometry()->GetOrigin(); MITK_TEST_CONDITION_REQUIRED(mitk::Equal(origin2,vtkoriginAsMitkPoint), ""); MITK_TEST_OUTPUT(<< " Testing whether GetTimeSlicedGeometry()->GetOrigin() has been correctly initialized from vtkImageData"); origin2 = mitkByVtkImage->GetTimeSlicedGeometry()->GetOrigin(); MITK_TEST_CONDITION_REQUIRED(mitk::Equal(origin2,vtkoriginAsMitkPoint), ""); // TODO test the following initializers on channel-incorporation // void mitk::Image::Initialize(const mitk::PixelType& type, unsigned int dimension, unsigned int *dimensions, unsigned int channels) // void mitk::Image::Initialize(const mitk::PixelType& type, int sDim, const mitk::Geometry2D& geometry2d, bool flipped, unsigned int channels, int tDim ) // void mitk::Image::Initialize(const mitk::Image* image) // void mitk::Image::Initialize(const mitkIpPicDescriptor* pic, int channels, int tDim, int sDim) //mitk::Image::Pointer vecImg = mitk::Image::New(); //vecImg->Initialize(PixelType(typeid(float), 6, itk::ImageIOBase::SYMMETRICSECONDRANKTENSOR), *imgMem->GetGeometry(), 2 /* #channels */, 0 /*tDim*/, false /*shiftBoundingBoxMinimumToZero*/ ); //vecImg->Initialize(PixelType(typeid(itk::Vector)), *imgMem->GetGeometry(), 2 /* #channels */, 0 /*tDim*/, false /*shiftBoundingBoxMinimumToZero*/ ); // testing access by index coordinates and by world coordinates MITK_TEST_CONDITION_REQUIRED(argc == 2, "Check if test image is accessible!"); const std::string filename = std::string(argv[1]); mitk::ItkImageFileReader::Pointer imageReader = mitk::ItkImageFileReader::New(); try { imageReader->SetFileName(filename); imageReader->Update(); } catch(...) { MITK_TEST_FAILED_MSG(<< "Could not read file for testing: " << filename); return 0; } mitk::Image::Pointer image = imageReader->GetOutput(); // generate a random point in world coordinates mitk::Point3D xMax, yMax, zMax, xMaxIndex, yMaxIndex, zMaxIndex; xMaxIndex.Fill(0.0f); yMaxIndex.Fill(0.0f); zMaxIndex.Fill(0.0f); xMaxIndex[0] = image->GetLargestPossibleRegion().GetSize()[0]; yMaxIndex[1] = image->GetLargestPossibleRegion().GetSize()[1]; zMaxIndex[2] = image->GetLargestPossibleRegion().GetSize()[2]; image->GetGeometry()->IndexToWorld(xMaxIndex, xMax); image->GetGeometry()->IndexToWorld(yMaxIndex, yMax); image->GetGeometry()->IndexToWorld(zMaxIndex, zMax); MITK_INFO << "Origin " << image->GetGeometry()->GetOrigin()[0] << " "<< image->GetGeometry()->GetOrigin()[1] << " "<< image->GetGeometry()->GetOrigin()[2] << ""; MITK_INFO << "MaxExtend " << xMax[0] << " "<< yMax[1] << " "<< zMax[2] << ""; mitk::Point3D point; itk::Statistics::MersenneTwisterRandomVariateGenerator::Pointer randomGenerator = itk::Statistics::MersenneTwisterRandomVariateGenerator::New(); randomGenerator->Initialize( std::rand() ); // initialize with random value, to get sensible random points for the image point[0] = randomGenerator->GetUniformVariate( image->GetGeometry()->GetOrigin()[0], xMax[0]); point[1] = randomGenerator->GetUniformVariate( image->GetGeometry()->GetOrigin()[1], yMax[1]); point[2] = randomGenerator->GetUniformVariate( image->GetGeometry()->GetOrigin()[2], zMax[2]); MITK_INFO << "RandomPoint " << point[0] << " "<< point[1] << " "<< point[2] << ""; // test values and max/min mitk::ScalarType imageMin = image->GetStatistics()->GetScalarValueMin(); mitk::ScalarType imageMax = image->GetStatistics()->GetScalarValueMax(); mitk::ScalarType value = image->GetPixelValueByWorldCoordinate(point); MITK_INFO << imageMin << " "<< imageMax << " "<< value << ""; MITK_TEST_CONDITION( (value >= imageMin && value <= imageMax), "Value returned is between max/min"); // test accessing PixelValue with coordinate leading to a negative index const mitk::Point3D geom_origin = image->GetGeometry()->GetOrigin(); const mitk::Point3D geom_center = image->GetGeometry()->GetCenter(); const unsigned int timestep = 0; // shift position from origin outside of the image ( in the opposite direction to [center-origin] vector which points in the inside) mitk::Point3D position = geom_origin + (geom_origin - geom_center); MITK_TEST_CONDITION_REQUIRED( image->GetPixelValueByWorldCoordinate(position, timestep) == 0, "Test access to the outside of the image") // testing the clone method of mitk::Image mitk::Image::Pointer cloneImage = image->Clone(); MITK_TEST_CONDITION_REQUIRED(cloneImage->GetDimension() == image->GetDimension(), "Clone (testing dimension)"); MITK_TEST_CONDITION_REQUIRED(cloneImage->GetPixelType() == image->GetPixelType(), "Clone (testing pixel type)"); // After cloning an image the geometry of both images should be equal too MITK_TEST_CONDITION_REQUIRED(cloneImage->GetGeometry()->GetOrigin() == image->GetGeometry()->GetOrigin(), "Clone (testing origin)"); MITK_TEST_CONDITION_REQUIRED(cloneImage->GetGeometry()->GetSpacing() == image->GetGeometry()->GetSpacing(), "Clone (testing spacing)"); MITK_TEST_CONDITION_REQUIRED(mitk::MatrixEqualElementWise(cloneImage->GetGeometry()->GetIndexToWorldTransform()->GetMatrix(), image->GetGeometry()->GetIndexToWorldTransform()->GetMatrix()), "Clone (testing transformation matrix)"); MITK_TEST_CONDITION_REQUIRED(mitk::MatrixEqualElementWise(cloneImage->GetTimeSlicedGeometry()->GetGeometry3D(cloneImage->GetDimension(3)-1)->GetIndexToWorldTransform()->GetMatrix(), cloneImage->GetTimeSlicedGeometry()->GetGeometry3D(image->GetDimension(3)-1)->GetIndexToWorldTransform()->GetMatrix()), "Clone(testing time sliced geometry)"); ///////////////////////// // // IsEqual() test // /////////////////////////////// - MITK_TEST_CONDITION( mitk::compare::IsEqual( cloneImage, image ), "Comparing images by IsEqual( cloneImage, image) " ); - MITK_TEST_CONDITION( mitk::compare::IsEqual( cloneImage->GetGeometry(), image->GetGeometry()), "Comparing geometries by IsEqual( geometry )"); + MITK_TEST_CONDITION( mitk::Image::AreEqual( cloneImage, image ), "Comparing images by IsEqual( cloneImage, image) " ); + MITK_TEST_CONDITION( mitk::Geometry3D::AreEqual( cloneImage->GetGeometry(), image->GetGeometry()), "Comparing geometries by IsEqual( geometry )"); // altering origin to test if the IsEqual failes cloneImage->GetGeometry()->SetOrigin(point); - MITK_TEST_CONDITION( !mitk::compare::IsEqual( cloneImage, image ), "Comparing geometries with different origin. " ); + MITK_TEST_CONDITION( !mitk::Image::AreEqual( cloneImage, image ), "Comparing geometries with different origin. " ); // comparing mitk::ImageSliceSelector::Pointer sliceSelector = mitk::ImageSliceSelector::New(); sliceSelector->SetInput( image ); sliceSelector->SetSliceNr( 0 ); mitk::Image::Pointer singleSliceImage = sliceSelector->GetOutput(); - MITK_TEST_CONDITION( !mitk::compare::IsEqual( singleSliceImage, image ), "Comparing 2D and 3D image by IsEqual() "); + MITK_TEST_CONDITION( !mitk::Image::AreEqual( singleSliceImage, image ), "Comparing 2D and 3D image by IsEqual() "); mitk::PixelType fPType = mitk::MakeScalarPixelType(); mitk::PixelType sPType = mitk::MakeScalarPixelType(); mitk::Image::Pointer floatImage = mitk::Image::New(); floatImage->Initialize(fPType, 3, dim); mitk::Image::Pointer shortImage = mitk::Image::New(); shortImage->Initialize(sPType, 3, dim); - MITK_TEST_CONDITION( !mitk::compare::IsEqual( floatImage, shortImage ), "Comparing images with different PixelTypes by IsEqual() "); + MITK_TEST_CONDITION( !mitk::Image::AreEqual( floatImage, shortImage ), "Comparing images with different PixelTypes by IsEqual() "); mitk::Image::Pointer floatImage2 = mitk::Image::New(); unsigned int alteredDim[]={100,100,30}; floatImage2->Initialize(fPType, 3, alteredDim); - MITK_TEST_CONDITION( !mitk::compare::IsEqual( floatImage, floatImage2), "Comparing images with different dimension size by IsEqual() ") + MITK_TEST_CONDITION( !mitk::Image::AreEqual( floatImage, floatImage2), "Comparing images with different dimension size by IsEqual() ") ///////////////////// for (unsigned int i = 0u; i < cloneImage->GetDimension(); ++i) { MITK_TEST_CONDITION_REQUIRED(cloneImage->GetDimension(i) == image->GetDimension(i), "Clone (testing dimension " << i << ")"); } //access via itk if(image->GetDimension()> 3) // CastToItk only works with 3d images so we need to check for 4d images { mitk::ImageTimeSelector::Pointer selector = mitk::ImageTimeSelector::New(); selector->SetTimeNr(0); selector->SetInput(image); selector->Update(); image = selector->GetOutput(); } if(image->GetDimension()==3) { typedef itk::Image ItkFloatImage3D; ItkFloatImage3D::Pointer itkimage; mitk::CastToItkImage(image, itkimage); MITK_TEST_CONDITION_REQUIRED(itkimage.IsNotNull(), "Test conversion to itk::Image!"); mitk::Point3D itkPhysicalPoint; image->GetGeometry()->WorldToItkPhysicalPoint(point, itkPhysicalPoint); MITK_INFO << "ITKPoint " << itkPhysicalPoint[0] << " "<< itkPhysicalPoint[1] << " "<< itkPhysicalPoint[2] << ""; mitk::Point3D backTransformedPoint; image->GetGeometry()->ItkPhysicalPointToWorld(itkPhysicalPoint, backTransformedPoint); MITK_TEST_CONDITION_REQUIRED( mitk::Equal(point,backTransformedPoint), "Testing world->itk-physical->world consistency"); itk::Index<3> idx; bool status = itkimage->TransformPhysicalPointToIndex(itkPhysicalPoint, idx); MITK_INFO << "ITK Index " << idx[0] << " "<< idx[1] << " "<< idx[2] << ""; if(status) { float valByItk = itkimage->GetPixel(idx); MITK_TEST_CONDITION_REQUIRED( mitk::Equal(valByItk, value), "Compare value of pixel returned by mitk in comparison to itk"); } else { MITK_WARN<< "Index is out buffered region!"; } } else { MITK_INFO << "Image does not contain three dimensions, some test cases are skipped!"; } // clone generated 3D image with one slice in z direction (cf. bug 11058) unsigned int* threeDdim = new unsigned int[3]; threeDdim[0] = 100; threeDdim[1] = 200; threeDdim[2] = 1; mitk::Image::Pointer threeDImage = mitk::Image::New(); threeDImage->Initialize(mitk::MakeScalarPixelType(), 3, threeDdim); mitk::Image::Pointer cloneThreeDImage = threeDImage->Clone(); // check that the clone image has the same dimensionality as the source image MITK_TEST_CONDITION_REQUIRED( cloneThreeDImage->GetDimension() == 3, "Testing if the clone image initializes with 3D!"); MITK_TEST_CONDITION_REQUIRED( ImageVtkDataReferenceCheck(argv[1]), "Checking reference count of Image after using GetVtkImageData()"); MITK_TEST_END(); }