/*========================================================================= * * Copyright NumFOCUS * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * https://www.apache.org/licenses/LICENSE-2.0.txt * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * *=========================================================================*/ /*========================================================================= * * Portions of this file are subject to the VTK Toolkit Version 3 copyright. * * Copyright (c) Ken Martin, Will Schroeder, Bill Lorensen * * For complete copyright, license and disclaimer of warranty information * please refer to the NOTICE file at the top of the ITK source tree. * *=========================================================================*/ #ifndef itkImage_hxx #define itkImage_hxx #include "itkProcessObject.h" #include namespace itk { template void Image::Allocate(bool initializePixels) { SizeValueType num; this->ComputeOffsetTable(); num = static_cast(this->GetOffsetTable()[VImageDimension]); m_Buffer->Reserve(num, initializePixels); } template void Image::Initialize() { // // We don't modify ourselves because the "ReleaseData" methods depend upon // no modification when initialized. // // Call the superclass which should initialize the BufferedRegion ivar. Superclass::Initialize(); // Replace the handle to the buffer. This is the safest thing to do, // since the same container can be shared by multiple images (e.g. // Grafted outputs and in place filters). m_Buffer = PixelContainer::New(); } template void Image::FillBuffer(const TPixel & value) { const SizeValueType numberOfPixels = this->GetBufferedRegion().GetNumberOfPixels(); std::fill_n(&(*m_Buffer)[0], numberOfPixels, value); } template void Image::SetPixelContainer(PixelContainer * container) { if (m_Buffer != container) { m_Buffer = container; this->Modified(); } } template void Image::Graft(const Self * image) { // call the superclass' implementation Superclass::Graft(image); if (image) { // Now copy anything remaining that is needed this->SetPixelContainer(const_cast(image->GetPixelContainer())); } } template void Image::Graft(const DataObject * data) { if (data) { // Attempt to cast data to an Image const auto * const imgData = dynamic_cast(data); if (imgData != nullptr) { this->Graft(imgData); } else { // pointer could not be cast back down itkExceptionMacro("itk::Image::Graft() cannot cast " << typeid(data).name() << " to " << typeid(const Self *).name()); } } } template void Image::ComputeIndexToPhysicalPointMatrices() { this->Superclass::ComputeIndexToPhysicalPointMatrices(); } template unsigned int Image::GetNumberOfComponentsPerPixel() const { // use the GetLength() method which works with variable length arrays, // to make it work with as much pixel types as possible return NumericTraits::GetLength({}); } template void Image::PrintSelf(std::ostream & os, Indent indent) const { Superclass::PrintSelf(os, indent); os << indent << "PixelContainer: " << std::endl; m_Buffer->Print(os, indent.GetNextIndent()); // m_Origin and m_Spacing are printed in the Superclass } } // end namespace itk #endif