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/*=========================================================================
*
* 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.
*
*=========================================================================*/
#include "itkCommonEnums.h"
#include "itkLogicOpsFunctors.h"
#include "itkBinaryFunctorImageFilter.h"
#include "itkImageRegionIteratorWithIndex.h"
#include "itkLogicTestSupport.h"
namespace
{
// A bogus class for testing purposes.
class Bogus
{
public:
// using Self = Bogus;
// using Pointer = SmartPointer<Self>;
// itkNewMacro(Self);
// static Bogus* New() { return new Bogus(); };
// void Register() {};
// void UnRegister() {};
float
operator()(double d, double)
{
return static_cast<float>(d);
}
void
Visit(int, Bogus *)
{}
itk::CellGeometryEnum
GetCellTopologyId()
{
return itk::CellGeometryEnum::HEXAHEDRON_CELL;
}
itk::CellGeometryEnum
GetTopologyId()
{
return itk::CellGeometryEnum::HEXAHEDRON_CELL;
}
Bogus() = default;
virtual ~Bogus() = default;
};
} // namespace
int
itkEqualTest(int, char *[])
{
// Define the dimension of the images
constexpr unsigned int myDimension = 3;
// Declare the types of the images
using myImageType1 = itk::Image<float, myDimension>;
using myImageType2 = itk::Image<float, myDimension>;
using myImageType3 = itk::Image<float, myDimension>;
using PixelType = myImageType1::PixelType;
// Declare the type of the index to access images
using myIndexType = itk::Index<myDimension>;
// Declare the type of the size
using mySizeType = itk::Size<myDimension>;
// Declare the type of the Region
using myRegionType = itk::ImageRegion<myDimension>;
using myFilterType = itk::BinaryFunctorImageFilter<
myImageType1,
myImageType2,
myImageType3,
itk::Functor::Equal<myImageType1::PixelType, myImageType2::PixelType, myImageType3::PixelType>>;
// Declare the pointers to images
using myImageType1Pointer = myImageType1::Pointer;
using myImageType2Pointer = myImageType2::Pointer;
using myImageType3Pointer = myImageType3::Pointer;
using myFilterTypePointer = myFilterType::Pointer;
// Create two images
myImageType1Pointer inputImageA = myImageType1::New();
myImageType2Pointer inputImageB = myImageType2::New();
// Define their size, and start index
mySizeType size;
size[0] = 2;
size[1] = 2;
size[2] = 2;
myIndexType start;
start[0] = 0;
start[1] = 0;
start[2] = 0;
myRegionType region{ start, size };
// Initialize Image A
inputImageA->SetRegions(region);
inputImageA->Allocate();
// Initialize Image B
inputImageB->SetRegions(region);
inputImageB->Allocate();
// Declare Iterator types apropriated for each image
using myIteratorType1 = itk::ImageRegionIteratorWithIndex<myImageType1>;
using myIteratorType2 = itk::ImageRegionIteratorWithIndex<myImageType2>;
// Create one iterator for Image A (this is a light object)
myIteratorType1 it1(inputImageA, inputImageA->GetBufferedRegion());
// Initialize the content of Image A
it1.Set(3.0);
++it1;
while (!it1.IsAtEnd())
{
it1.Set(2.0);
++it1;
}
// Create one iterator for Image B (this is a light object)
myIteratorType2 it2(inputImageB, inputImageB->GetBufferedRegion());
// Initialize the content of Image B
while (!it2.IsAtEnd())
{
it2.Set(3.0);
++it2;
}
{
// Create a logic Filter
myFilterTypePointer filter = myFilterType::New();
if (filter.IsNull())
{
return EXIT_FAILURE;
}
// Connect the input images
filter->SetInput1(inputImageA);
filter->SetInput2(inputImageB);
filter->SetFunctor(filter->GetFunctor());
// Get the Smart Pointer to the Filter Output
myImageType3Pointer outputImage = filter->GetOutput();
// Execute the filter
filter->Update();
filter->SetFunctor(filter->GetFunctor());
// check the results
PixelType FG = filter->GetFunctor().GetForegroundValue();
PixelType BG = filter->GetFunctor().GetBackgroundValue();
int status1 = checkImOnImRes<myImageType1, myImageType2, myImageType3, std::equal_to<myImageType1::PixelType>>(
inputImageA, inputImageB, outputImage, FG, BG);
if (status1 == EXIT_FAILURE)
{
return (EXIT_FAILURE);
}
else
{
std::cout << "Step 1 passed" << std::endl;
}
}
{
// Create a logic Filter
myFilterTypePointer filter = myFilterType::New();
// Connect the input images
filter->SetInput1(inputImageA);
filter->SetFunctor(filter->GetFunctor());
// Get the Smart Pointer to the Filter Output
myImageType3Pointer outputImage = filter->GetOutput();
// Now try testing with constant : Im1 == 2
filter->SetConstant(2.0);
filter->Update();
PixelType FG = filter->GetFunctor().GetForegroundValue();
PixelType BG = filter->GetFunctor().GetBackgroundValue();
PixelType C = filter->GetConstant2();
int status2 = checkImOnConstRes<myImageType1, PixelType, myImageType3, std::equal_to<PixelType>>(
inputImageA, C, outputImage, FG, BG);
if (status2 == EXIT_FAILURE)
{
return (EXIT_FAILURE);
}
else
{
std::cout << "Step 2 passed " << std::endl;
}
}
// Now try testing with constant : 3 == Im2
{
// Create a logic Filter
myFilterTypePointer filter = myFilterType::New();
// Connect the input images
filter->SetFunctor(filter->GetFunctor());
// Get the Smart Pointer to the Filter Output
myImageType3Pointer outputImage = filter->GetOutput();
filter->SetConstant1(3.0);
filter->SetInput2(inputImageB);
filter->Update();
PixelType FG = filter->GetFunctor().GetForegroundValue();
PixelType BG = filter->GetFunctor().GetBackgroundValue();
int status3 = checkConstOnImRes<PixelType, myImageType2, myImageType3, std::equal_to<PixelType>>(
filter->GetConstant1(), inputImageB, outputImage, FG, BG);
if (status3 == EXIT_FAILURE)
{
return (EXIT_FAILURE);
}
else
{
std::cout << "Step 3 passed" << std::endl;
}
}
{
// BinaryImageFilter
using iFIB = itk::BinaryFunctorImageFilter<itk::Image<double>, itk::Image<double>, itk::Image<double>, Bogus>;
auto FIB = iFIB::New();
if (FIB.IsNull())
{
return EXIT_FAILURE;
}
}
// All objects should be automatically destroyed at this point
return EXIT_SUCCESS;
}
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