ExtractROI.cxxΒΆ
Example usage:
./ExtractROI Input/IMAGERY_SSECH.tif Output/ROI_IMAGERY_RGB.png Output/ROI_IMAGERY_MIR.png 0 0 100 100
Example source code (ExtractROI.cxx):
/*
* Copyright (C) 1999-2011 Insight Software Consortium
* Copyright (C) 2005-2020 Centre National d'Etudes Spatiales (CNES)
*
* This file is part of Orfeo Toolbox
*
* https://www.orfeo-toolbox.org/
*
* 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
*
* 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.
*/
// This example shows the use of the
// \doxygen{otb}{MultiChannelExtractROI} and
// \doxygen{otb}{MultiToMonoChannelExtractROI} which allow the
// extraction of ROIs from multiband images stored into
// \doxygen{otb}{VectorImage}s. The first one povides a Vector Image
// as output, while the second one provides a classical
// \doxygen{otb}{Image} with a scalar pixel type. The present example
// shows how to extract a ROI from a 4-band SPOT 5 image and to
// produce a first multi-band 3-channel image and a second
// mono-channel one for the SWIR band.
// We start by including the needed header files.
// \index{otb::ExtractROI!header}
#include "otbImageFileReader.h"
#include "otbImageFileWriter.h"
#include "otbMultiChannelExtractROI.h"
#include "otbMultiToMonoChannelExtractROI.h"
int main(int argc, char* argv[])
{
// R\'ecuperation de arguments
if (argc < 7)
{
std::cerr << "Usage: " << std::endl;
std::cerr << argv[0] << " inputImageFile outputImageFileRGB outputImageFileLastBand startX startY sizeX sizeY" << std::endl;
return EXIT_FAILURE;
}
// The program arguments define the image file names as well as the
// rectangular area to be extracted.
const char* inputFilename = argv[1];
const char* outputFilenameRGB = argv[2];
const char* outputFilenameMIR = argv[3];
unsigned int startX((unsigned int)::atoi(argv[4]));
unsigned int startY((unsigned int)::atoi(argv[5]));
unsigned int sizeX((unsigned int)::atoi(argv[6]));
unsigned int sizeY((unsigned int)::atoi(argv[7]));
// As usual, we define the input and output pixel types.
using InputPixelType = unsigned char;
using OutputPixelType = unsigned char;
// First of all, we extract the multiband part by using the
// \doxygen{otb}{MultiChannelExtractROI} class, which is templated
// over the input and output pixel types. This class in not
// templated over the images types in order to force these images
// to be of \doxygen{otb}{VectorImage} type.
using ExtractROIFilterType = otb::MultiChannelExtractROI<InputPixelType, OutputPixelType>;
// We create the extractor filter by using the \code{New} method of
// the class and we set its parameters.
ExtractROIFilterType::Pointer extractROIFilter = ExtractROIFilterType::New();
extractROIFilter->SetStartX(startX);
extractROIFilter->SetStartY(startY);
extractROIFilter->SetSizeX(sizeX);
extractROIFilter->SetSizeY(sizeY);
// We must tell the filter which are the channels to be used. When
// selecting contiguous bands, we can use the
// \code{SetFirstChannel} and the \code{SetLastChannel}. Otherwise,
// we select individual channels by using the \code{SetChannel} method.
extractROIFilter->SetFirstChannel(1);
extractROIFilter->SetLastChannel(3);
// We will use the OTB readers and writers for file access.
using ReaderType = otb::ImageFileReader<ExtractROIFilterType::InputImageType>;
using WriterType = otb::ImageFileWriter<ExtractROIFilterType::InputImageType>;
ReaderType::Pointer reader = ReaderType::New();
WriterType::Pointer writer = WriterType::New();
// Since the number of bands of the input image is dynamically set
// at runtime, the \code{UpdateOutputInformation} method of the reader must be
// called before using the extractor filter.
reader->SetFileName(inputFilename);
reader->UpdateOutputInformation();
writer->SetFileName(outputFilenameRGB);
// We can then build the pipeline as usual.
extractROIFilter->SetInput(reader->GetOutput());
writer->SetInput(extractROIFilter->GetOutput());
// And execute the pipeline by calling the \code{Update} method of
// the writer.
writer->Update();
// The usage of the \doxygen{otb}{MultiToMonoChannelExtractROI} is
// similar to the one of the \doxygen{otb}{MultiChannelExtractROI}
// described above.
//
// The goal now is to extract an ROI from a multi-band image and
// generate a mono-channel image as output.
//
// We could use the \doxygen{otb}{MultiChannelExtractROI} and
// select a single channel, but using the
// \doxygen{otb}{MultiToMonoChannelExtractROI} we generate a
// \doxygen{otb}{Image} instead of an
// \doxygen{otb}{VectorImage}. This is useful from a computing and
// memory usage point of view.
// This class is also templated over the pixel types.
using ExtractROIMonoFilterType = otb::MultiToMonoChannelExtractROI<InputPixelType, OutputPixelType>;
ExtractROIMonoFilterType::Pointer extractROIMonoFilter = ExtractROIMonoFilterType::New();
extractROIMonoFilter->SetStartX(startX);
extractROIMonoFilter->SetStartY(startY);
extractROIMonoFilter->SetSizeX(sizeX);
extractROIMonoFilter->SetSizeY(sizeY);
// For this filter, only one output channel has to be selected.
extractROIMonoFilter->SetChannel(4);
using monoReaderType = otb::ImageFileReader<ExtractROIMonoFilterType::InputImageType>;
using monoWriterType = otb::ImageFileWriter<ExtractROIMonoFilterType::OutputImageType>;
monoReaderType::Pointer monoReader = monoReaderType::New();
monoWriterType::Pointer monoWriter = monoWriterType::New();
monoReader->SetFileName(inputFilename);
monoReader->Update(); // Needed to know the number of channels in the image
monoWriter->SetFileName(outputFilenameMIR);
extractROIMonoFilter->SetInput(monoReader->GetOutput());
monoWriter->SetInput(extractROIMonoFilter->GetOutput());
monoWriter->Update();
// \begin{figure}
// \center
// \includegraphics[width=0.44\textwidth]{IMAGERY_SSECH.eps}
// \itkcaption[Initial SPOT 5 image]{Quicklook of the original SPOT
// 5 image.}
// \label{fig:IMAGERY_SSECH}
// \end{figure}
//
// \begin{figure}
// \center
// \includegraphics[width=0.44\textwidth]{ROI_IMAGERY_RGB.eps}
// \includegraphics[width=0.44\textwidth]{ROI_IMAGERY_MIR.eps}
// \itkcaption[ROI of a SPOT5 image]{Result of the
// extraction. Left: 3-channel image. Right: mono-band image.}
// \label{fig:ROI_IMAGERY}
// \end{figure}
//
// Figure \ref{fig:ROI_IMAGERY} illustrates the result of the
// application of both extraction filters on the image presented in
// figure \ref{fig:IMAGERY_SSECH}.
return EXIT_SUCCESS;
}