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/*=========================================================================
*
* Copyright Insight Software Consortium
*
* 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
*
* http://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.
*
*=========================================================================*/
#ifndef itkOpenCVImageBridge_hxx
#define itkOpenCVImageBridge_hxx
#include "itkOpenCVImageBridge.h"
#include "itkNumericTraits.h"
namespace itk
{
//
// IplImageToITKImage
//
template<typename TOutputImageType>
typename TOutputImageType::Pointer
OpenCVImageBridge::IplImageToITKImage(const IplImage* in)
{
// Typedefs
typedef TOutputImageType ImageType;
//
// Make sure input isn't null and output type is 2D or 1D
//
if (!in)
{
itkGenericExceptionMacro("Input is ITK_NULLPTR");
}
//
// Do the conversion
//
typename ImageType::Pointer out = ImageType::New();
switch (in->depth)
{
case (IPL_DEPTH_8U):
{
ITKConvertIplImageBuffer< ImageType, unsigned char >( in, out.GetPointer(), IPL_DEPTH_8U );
break;
}
case (IPL_DEPTH_8S):
{
ITKConvertIplImageBuffer< ImageType, char >( in, out.GetPointer(), IPL_DEPTH_8S );
break;
}
case (IPL_DEPTH_16U):
{
ITKConvertIplImageBuffer< ImageType, unsigned short >( in, out.GetPointer(), IPL_DEPTH_16U );
break;
}
case (IPL_DEPTH_16S):
{
ITKConvertIplImageBuffer< ImageType, short >( in, out.GetPointer(), IPL_DEPTH_16S );
break;
}
case (IPL_DEPTH_32F):
{
ITKConvertIplImageBuffer< ImageType, float >( in, out.GetPointer(), IPL_DEPTH_32F );
break;
}
case (IPL_DEPTH_64F):
{
ITKConvertIplImageBuffer< ImageType, double >( in, out.GetPointer(), IPL_DEPTH_64F );
break;
}
default:
{
itkGenericExceptionMacro("Unknown OpenCV type");
}
}
//
// Return the converted image
//
return out;
}
//
// CVMatToITKImage
//
template<typename TOutputImageType>
typename TOutputImageType::Pointer
OpenCVImageBridge::CVMatToITKImage(const cv::Mat & in)
{
const IplImage converted = in;
return IplImageToITKImage<TOutputImageType>(&converted);
}
//
// ITKImageToIplImage
//
template<typename TInputImageType>
IplImage*
OpenCVImageBridge::ITKImageToIplImage(const TInputImageType* in, bool force3Channels)
{
// Typedefs
typedef TInputImageType ImageType;
typedef typename ImageType::PixelType InputPixelType;
typedef typename itk::NumericTraits<InputPixelType>::ValueType ValueType;
//
// Make sure input isn't null, is 2D or 1D, and is scalar or RGB
//
if (!in)
{
itkGenericExceptionMacro("Input is ITK_NULLPTR");
}
typename ImageType::RegionType region = in->GetLargestPossibleRegion();
typename ImageType::SizeType size = region.GetSize();
if (ImageType::ImageDimension > 2)
{
bool IsA2DImage = false;
for( unsigned int dim = 2; ( dim < ImageType::ImageDimension) && !IsA2DImage;dim++ )
{
if( size[dim] != 1 )
{
IsA2DImage= true;
}
}
if( IsA2DImage )
{
itkGenericExceptionMacro("OpenCV only supports 2D and 1D images");
}
}
unsigned int inChannels = itk::NumericTraits<InputPixelType>::MeasurementVectorType::Dimension;
if (inChannels != 1 && inChannels != 3)
{
itkGenericExceptionMacro("OpenCV only supports scalar and 3-channel data");
}
unsigned int outChannels = inChannels;
if (force3Channels)
{
outChannels = 3;
}
//
// Set up the output image
//
IplImage* out;
unsigned int w = static_cast< unsigned int >( size[0] );
unsigned int h = static_cast< unsigned int >( size[1] );
//
// set the depth correctly based on input pixel type
//
unsigned int typeSize = 1;
if (typeid(ValueType) == typeid(unsigned char))
{
out = cvCreateImage(cvSize(w,h), IPL_DEPTH_8U, outChannels);
typeSize = IPL_DEPTH_8U/8;
}
else if (typeid(ValueType) == typeid(char))
{
if (outChannels != 1)
{
itkGenericExceptionMacro("OpenCV does not support color images with pixels of type char");
}
out = cvCreateImage(cvSize(w,h), IPL_DEPTH_8S, outChannels);
typeSize = IPL_DEPTH_8U/8;
}
else if (typeid(ValueType) == typeid(unsigned short))
{
out = cvCreateImage(cvSize(w,h), IPL_DEPTH_16U, outChannels);
typeSize = IPL_DEPTH_16U/8;
}
else if (typeid(ValueType) == typeid(short))
{
if (outChannels != 1)
{
itkGenericExceptionMacro("OpenCV does not support color images with pixels of type short");
}
out = cvCreateImage(cvSize(w,h), IPL_DEPTH_16S, outChannels);
typeSize = IPL_DEPTH_16U/8;
}
else if (typeid(ValueType) == typeid(float))
{
out = cvCreateImage(cvSize(w,h), IPL_DEPTH_32F, outChannels);
typeSize = IPL_DEPTH_32F/8;
}
else if (typeid(ValueType) == typeid(double))
{
if (outChannels != 1)
{
itkGenericExceptionMacro("OpenCV does not support color images with pixels of type double");
}
out = cvCreateImage(cvSize(w,h), IPL_DEPTH_64F, outChannels);
typeSize = IPL_DEPTH_64F/8;
}
else
{
itkGenericExceptionMacro("OpenCV does not support the input pixel type");
}
// Scalar output
if (outChannels == 1)
{
size_t paddedRowBytes = typeSize * out->width;
for (int i=0;i<out->height;i++)
{
memcpy( out->imageData + i*out->widthStep,
in->GetBufferPointer() + i*out->width,
paddedRowBytes);
}
}
// RGB output
else
{
// Set up an IplImage ponting at the input's buffer. It's ok to do the
// const cast because it will only get used to copy pixels
if (inChannels == 3 )
{
IplImage * temp = cvCreateImage(cvSize(w,h),out->depth, inChannels);
HandleRGBPixel< InputPixelType, ImageType::ImageDimension >::Padding( in, temp );
cvCvtColor(temp, out, CV_RGB2BGR);
cvReleaseImage(&temp);
}
// input 1 channel, but forcing 3 channel output
else
{
IplImage* temp = cvCreateImage(cvSize(w,h), out->depth, inChannels);
temp->imageData = reinterpret_cast<char*>(
const_cast<InputPixelType*>(in->GetBufferPointer()));
cvCvtColor(temp, out, CV_GRAY2BGR);
cvReleaseImage(&temp);
}
}
//
// Return the result
//
return out;
}
//
// ITKImageToIplImage
//
template<typename TInputImageType>
cv::Mat
OpenCVImageBridge::ITKImageToCVMat(const TInputImageType* in, bool force3Channels)
{
// Extra copy, but necessary to prevent memory leaks
IplImage* temp = ITKImageToIplImage<TInputImageType>(in, force3Channels);
cv::Mat out = cv::cvarrToMat( temp, true );
cvReleaseImage(&temp);
return out;
}
} // end namespace itk
#endif
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