Hu Chunming / vpt_ascend

  /*M///////////////////////////////////////////////////////////////////////////////////////
  //
  //  IMPORTANT: READ BEFORE DOWNLOADING, COPYING, INSTALLING OR USING.
  //
  //  By downloading, copying, installing or using the software you agree to this license.
  //  If you do not agree to this license, do not download, install,
  //  copy or use the software.
  //
  //
  //                        Intel License Agreement
  //                For Open Source Computer Vision Library
  //
  // Copyright (C) 2000, Intel Corporation, all rights reserved.
  // Third party copyrights are property of their respective owners.
  //
  // Redistribution and use in source and binary forms, with or without modification,
  // are permitted provided that the following conditions are met:
  //
  //   * Redistribution's of source code must retain the above copyright notice,
  //     this list of conditions and the following disclaimer.
  //
  //   * Redistribution's in binary form must reproduce the above copyright notice,
  //     this list of conditions and the following disclaimer in the documentation
  //     and/or other materials provided with the distribution.
  //
  //   * The name of Intel Corporation may not be used to endorse or promote products
  //     derived from this software without specific prior written permission.
  //
  // This software is provided by the copyright holders and contributors "as is" and
  // any express or implied warranties, including, but not limited to, the implied
  // warranties of merchantability and fitness for a particular purpose are disclaimed.
  // In no event shall the Intel Corporation or contributors be liable for any direct,
  // indirect, incidental, special, exemplary, or consequential damages
  // (including, but not limited to, procurement of substitute goods or services;
  // loss of use, data, or profits; or business interruption) however caused
  // and on any theory of liability, whether in contract, strict liability,
  // or tort (including negligence or otherwise) arising in any way out of
  // the use of this software, even if advised of the possibility of such damage.
  //
  //M*/
  #include "precomp.hpp"
  
  // GDAL Macros
  #include "cvconfig.h"
  
  #ifdef HAVE_GDAL
  
  // Our Header
  #include "grfmt_gdal.hpp"
  
  
  /// C++ Standard Libraries
  #include <iostream>
  #include <stdexcept>
  #include <string>
  
  
  namespace cv{
  
  
  /**
   * Convert GDAL Palette Interpretation to OpenCV Pixel Type
  */
  int  gdalPaletteInterpretation2OpenCV( GDALPaletteInterp const& paletteInterp, GDALDataType const& gdalType ){
  
      switch( paletteInterp ){
  
          /// GRAYSCALE
          case GPI_Gray:
              if( gdalType == GDT_Byte    ){ return CV_8UC1;  }
              if( gdalType == GDT_UInt16  ){ return CV_16UC1; }
              if( gdalType == GDT_Int16   ){ return CV_16SC1; }
              if( gdalType == GDT_UInt32  ){ return CV_32SC1; }
              if( gdalType == GDT_Int32   ){ return CV_32SC1; }
              if( gdalType == GDT_Float32 ){ return CV_32FC1; }
              if( gdalType == GDT_Float64 ){ return CV_64FC1; }
              return -1;
  
          /// RGB
          case GPI_RGB:
              if( gdalType == GDT_Byte    ){ return CV_8UC3;  }
              if( gdalType == GDT_UInt16  ){ return CV_16UC3; }
              if( gdalType == GDT_Int16   ){ return CV_16SC3; }
              if( gdalType == GDT_UInt32  ){ return CV_32SC3; }
              if( gdalType == GDT_Int32   ){ return CV_32SC3; }
              if( gdalType == GDT_Float32 ){ return CV_32FC3; }
              if( gdalType == GDT_Float64 ){ return CV_64FC3; }
              return -1;
  
  
          /// otherwise
          default:
              return -1;
  
      }
  }
  
  /**
   * Convert gdal type to opencv type
  */
  int gdal2opencv( const GDALDataType& gdalType, const int& channels ){
  
      switch( gdalType ){
  
          /// UInt8
          case GDT_Byte:
              return CV_8UC(channels);
  
          /// UInt16
          case GDT_UInt16:
              return CV_16UC(channels);
  
          /// Int16
          case GDT_Int16:
              return CV_16SC(channels);
  
          /// UInt32
          case GDT_UInt32:
          case GDT_Int32:
              return CV_32SC(channels);
  
          case GDT_Float32:
              return CV_32FC(channels);
  
          case GDT_Float64:
              return CV_64FC(channels);
  
          default:
              std::cout << "Unknown GDAL Data Type" << std::endl;
              std::cout << "Type: " << GDALGetDataTypeName(gdalType) << std::endl;
              return -1;
      }
  }
  
  /**
   * GDAL Decoder Constructor
  */
  GdalDecoder::GdalDecoder(){
  
      // set a dummy signature
      m_signature="0";
      for( size_t i=0; i<160; i++ ){
          m_signature += "0";
      }
  
      /// Register the driver
      GDALAllRegister();
  
      m_driver = NULL;
      m_dataset = NULL;
  }
  
  /**
   * GDAL Decoder Destructor
  */
  GdalDecoder::~GdalDecoder(){
  
      if( m_dataset != NULL ){
         close();
      }
  }
  
  /**
   * Convert data range
  */
  double range_cast( const GDALDataType& gdalType,
                     const int& cvDepth,
                     const double& value )
  {
  
      // uint8 -> uint8
      if( gdalType == GDT_Byte && cvDepth == CV_8U ){
          return value;
      }
      // uint8 -> uint16
      if( gdalType == GDT_Byte && (cvDepth == CV_16U || cvDepth == CV_16S)){
          return (value*256);
      }
  
      // uint8 -> uint32
      if( gdalType == GDT_Byte && (cvDepth == CV_32F || cvDepth == CV_32S)){
          return (value*16777216);
      }
  
      // int16 -> uint8
      if( (gdalType == GDT_UInt16 || gdalType == GDT_Int16) && cvDepth == CV_8U ){
          return std::floor(value/256.0);
      }
  
      // int16 -> int16
      if( (gdalType == GDT_UInt16 || gdalType == GDT_Int16) &&
          ( cvDepth == CV_16U     ||  cvDepth == CV_16S   )){
          return value;
      }
  
      // float32 -> float32
      // float64 -> float64
      if( (gdalType == GDT_Float32 || gdalType == GDT_Float64) &&
          ( cvDepth == CV_32F     ||  cvDepth == CV_64F   )){
          return value;
      }
  
      std::cout << GDALGetDataTypeName( gdalType ) << std::endl;
      std::cout << "warning: unknown range cast requested." << std::endl;
      return (value);
  }
  
  
  /**
   * There are some better mpl techniques for doing this.
  */
  void write_pixel( const double& pixelValue,
                    const GDALDataType& gdalType,
                    const int& gdalChannels,
                    Mat& image,
                    const int& row,
                    const int& col,
                    const int& channel ){
  
      // convert the pixel
      double newValue = range_cast(gdalType, image.depth(), pixelValue );
  
      // input: 1 channel, output: 1 channel
      if( gdalChannels == 1 && image.channels() == 1 ){
          if( image.depth() == CV_8U ){       image.ptr<uchar>(row)[col]          = newValue; }
          else if( image.depth() == CV_16U ){ image.ptr<unsigned short>(row)[col] = newValue; }
          else if( image.depth() == CV_16S ){ image.ptr<short>(row)[col]          = newValue; }
          else if( image.depth() == CV_32S ){ image.ptr<int>(row)[col]            = newValue; }
          else if( image.depth() == CV_32F ){ image.ptr<float>(row)[col]          = newValue; }
          else if( image.depth() == CV_64F ){ image.ptr<double>(row)[col]         = newValue; }
          else{ throw std::runtime_error("Unknown image depth, gdal: 1, img: 1"); }
      }
  
      // input: 1 channel, output: 3 channel
      else if( gdalChannels == 1 && image.channels() == 3 ){
          if( image.depth() == CV_8U ){        image.ptr<Vec3b>(row)[col] = Vec3b(newValue,newValue,newValue); }
          else if( image.depth() == CV_16U ){  image.ptr<Vec3s>(row)[col] = Vec3s(newValue,newValue,newValue); }
          else if( image.depth() == CV_16S ){  image.ptr<Vec3s>(row)[col] = Vec3s(newValue,newValue,newValue); }
          else if( image.depth() == CV_32S ){  image.ptr<Vec3i>(row)[col] = Vec3i(newValue,newValue,newValue); }
          else if( image.depth() == CV_32F ){  image.ptr<Vec3f>(row)[col] = Vec3f(newValue,newValue,newValue); }
          else if( image.depth() == CV_64F ){  image.ptr<Vec3d>(row)[col] = Vec3d(newValue,newValue,newValue); }
          else{                          throw std::runtime_error("Unknown image depth, gdal:1, img: 3"); }
      }
  
      // input: 3 channel, output: 1 channel
      else if( gdalChannels == 3 && image.channels() == 1 ){
          if( image.depth() == CV_8U ){   image.ptr<uchar>(row)[col] += (newValue/3.0); }
          else{ throw std::runtime_error("Unknown image depth, gdal:3, img: 1"); }
      }
  
      // input: 4 channel, output: 1 channel
      else if( gdalChannels == 4 && image.channels() == 1 ){
          if( image.depth() == CV_8U ){   image.ptr<uchar>(row)[col] = newValue;  }
          else{ throw std::runtime_error("Unknown image depth, gdal: 4, image: 1"); }
      }
  
      // input: 3 channel, output: 3 channel
      else if( gdalChannels == 3 && image.channels() == 3 ){
          if( image.depth() == CV_8U ){  (*image.ptr<Vec3b>(row,col))[channel] = newValue;  }
          else if( image.depth() == CV_16U ){  (*image.ptr<Vec3s>(row,col))[channel] = newValue;  }
          else if( image.depth() == CV_16S ){  (*image.ptr<Vec3s>(row,col))[channel] = newValue;  }
          else if( image.depth() == CV_32S ){  (*image.ptr<Vec3i>(row,col))[channel] = newValue;  }
          else if( image.depth() == CV_32F ){  (*image.ptr<Vec3f>(row,col))[channel] = newValue;  }
          else if( image.depth() == CV_64F ){  (*image.ptr<Vec3d>(row,col))[channel] = newValue;  }
          else{ throw std::runtime_error("Unknown image depth, gdal: 3, image: 3"); }
      }
  
      // input: 4 channel, output: 3 channel
      else if( gdalChannels == 4 && image.channels() == 3 ){
          if( channel >= 4 ){ return; }
          else if( image.depth() == CV_8U  && channel < 4 ){  (*image.ptr<Vec3b>(row,col))[channel] = newValue;  }
          else if( image.depth() == CV_16U && channel < 4 ){  (*image.ptr<Vec3s>(row,col))[channel] = newValue;  }
          else if( image.depth() == CV_16S && channel < 4 ){  (*image.ptr<Vec3s>(row,col))[channel] = newValue;  }
          else if( image.depth() == CV_32S && channel < 4 ){  (*image.ptr<Vec3i>(row,col))[channel] = newValue;  }
          else if( image.depth() == CV_32F && channel < 4 ){  (*image.ptr<Vec3f>(row,col))[channel] = newValue;  }
          else if( image.depth() == CV_64F && channel < 4 ){  (*image.ptr<Vec3d>(row,col))[channel] = newValue;  }
          else{ throw std::runtime_error("Unknown image depth, gdal: 4, image: 3"); }
      }
  
      // input: 4 channel, output: 4 channel
      else if( gdalChannels == 4 && image.channels() == 4 ){
          if( image.depth() == CV_8U ){  (*image.ptr<Vec4b>(row,col))[channel] = newValue;  }
          else if( image.depth() == CV_16U ){  (*image.ptr<Vec4s>(row,col))[channel] = newValue;  }
          else if( image.depth() == CV_16S ){  (*image.ptr<Vec4s>(row,col))[channel] = newValue;  }
          else if( image.depth() == CV_32S ){  (*image.ptr<Vec4i>(row,col))[channel] = newValue;  }
          else if( image.depth() == CV_32F ){  (*image.ptr<Vec4f>(row,col))[channel] = newValue;  }
          else if( image.depth() == CV_64F ){  (*image.ptr<Vec4d>(row,col))[channel] = newValue;  }
          else{ throw std::runtime_error("Unknown image depth, gdal: 4, image: 4"); }
      }
  
      // input: > 4 channels, output: > 4 channels
      else if( gdalChannels > 4 && image.channels() > 4 ){
          if( image.depth() == CV_8U ){       image.ptr<uchar>(row,col)[channel]          = newValue; }
          else if( image.depth() == CV_16U ){ image.ptr<unsigned short>(row,col)[channel] = newValue; }
          else if( image.depth() == CV_16S ){ image.ptr<short>(row,col)[channel]          = newValue; }
          else if( image.depth() == CV_32S ){ image.ptr<int>(row,col)[channel]            = newValue; }
          else if( image.depth() == CV_32F ){ image.ptr<float>(row,col)[channel]          = newValue; }
          else if( image.depth() == CV_64F ){ image.ptr<double>(row,col)[channel]         = newValue; }
          else{ throw std::runtime_error("Unknown image depth, gdal: N, img: N"); }
      }
      // otherwise, throw an error
      else{
          throw std::runtime_error("error: can't convert types.");
      }
  
  }
  
  
  void write_ctable_pixel( const double& pixelValue,
                           const GDALDataType& gdalType,
                           GDALColorTable const* gdalColorTable,
                           Mat& image,
                           const int& y,
                           const int& x,
                           const int& c ){
  
      if( gdalColorTable == NULL ){
         write_pixel( pixelValue, gdalType, 1, image, y, x, c );
      }
  
      // if we are Grayscale, then do a straight conversion
      if( gdalColorTable->GetPaletteInterpretation() == GPI_Gray ){
          write_pixel( pixelValue, gdalType, 1, image, y, x, c );
      }
  
      // if we are rgb, then convert here
      else if( gdalColorTable->GetPaletteInterpretation() == GPI_RGB ){
  
          // get the pixel
          short r = gdalColorTable->GetColorEntry( (int)pixelValue )->c1;
          short g = gdalColorTable->GetColorEntry( (int)pixelValue )->c2;
          short b = gdalColorTable->GetColorEntry( (int)pixelValue )->c3;
          short a = gdalColorTable->GetColorEntry( (int)pixelValue )->c4;
  
          write_pixel( r, gdalType, 4, image, y, x, 2 );
          write_pixel( g, gdalType, 4, image, y, x, 1 );
          write_pixel( b, gdalType, 4, image, y, x, 0 );
          if( image.channels() > 3 ){
              write_pixel( a, gdalType, 4, image, y, x, 1 );
          }
      }
  
      // otherwise, set zeros
      else{
          write_pixel( pixelValue, gdalType, 1, image, y, x, c );
      }
  }
  
  
  
  /**
   * read data
  */
  bool GdalDecoder::readData( Mat& img ){
  
  
      // make sure the image is the proper size
      if( img.size() != Size(m_width, m_height) ){
          return false;
      }
  
      // make sure the raster is alive
      if( m_dataset == NULL || m_driver == NULL ){
          return false;
      }
  
      // set the image to zero
      img = 0;
  
      // iterate over each raster band
      // note that OpenCV does bgr rather than rgb
      int nChannels = m_dataset->GetRasterCount();
  
      GDALColorTable* gdalColorTable = NULL;
      if( m_dataset->GetRasterBand(1)->GetColorTable() != NULL ){
          gdalColorTable = m_dataset->GetRasterBand(1)->GetColorTable();
      }
  
      const GDALDataType gdalType = m_dataset->GetRasterBand(1)->GetRasterDataType();
      int nRows, nCols;
  
      if( nChannels > img.channels() ){
          nChannels = img.channels();
      }
  
      for( int c = 0; c<nChannels; c++ ){
  
          // get the GDAL Band
          GDALRasterBand* band = m_dataset->GetRasterBand(c+1);
  
          /* Map palette band and gray band to color index 0 and red, green,
             blue, alpha bands to BGRA indexes. Note: ignoring HSL, CMY,
             CMYK, and YCbCr color spaces, rather than converting them
             to BGR. */
          int color = 0;
          switch (band->GetColorInterpretation()) {
          case GCI_PaletteIndex:
          case GCI_GrayIndex:
          case GCI_BlueBand:
              color = 0;
              break;
          case GCI_GreenBand:
              color = 1;
              break;
          case GCI_RedBand:
              color = 2;
              break;
          case GCI_AlphaBand:
              color = 3;
              break;
          default:
              CV_Error(cv::Error::StsError, "Invalid/unsupported mode");
          }
  
          // make sure the image band has the same dimensions as the image
          if( band->GetXSize() != m_width || band->GetYSize() != m_height ){ return false; }
  
          // grab the raster size
          nRows = band->GetYSize();
          nCols = band->GetXSize();
  
          // create a temporary scanline pointer to store data
          double* scanline = new double[nCols];
  
          // iterate over each row and column
          for( int y=0; y<nRows; y++ ){
  
              // get the entire row
              CPLErr err = band->RasterIO( GF_Read, 0, y, nCols, 1, scanline, nCols, 1, GDT_Float64, 0, 0);
              CV_Assert(err == CE_None);
  
              // set inside the image
              for( int x=0; x<nCols; x++ ){
  
                  // set depending on image types
                  //   given boost, I would use enable_if to speed up.  Avoid for now.
                  if( hasColorTable == false ){
                      write_pixel( scanline[x], gdalType, nChannels, img, y, x, color );
                  }
                  else{
                      write_ctable_pixel( scanline[x], gdalType, gdalColorTable, img, y, x, color );
                  }
              }
          }
  
          // delete our temp pointer
          delete [] scanline;
      }
  
      return true;
  }
  
  
  /**
   * Read image header
  */
  bool GdalDecoder::readHeader(){
  
      // load the dataset
      m_dataset = (GDALDataset*) GDALOpen( m_filename.c_str(), GA_ReadOnly);
  
      // if dataset is null, then there was a problem
      if( m_dataset == NULL ){
          return false;
      }
  
      // make sure we have pixel data inside the raster
      if( m_dataset->GetRasterCount() <= 0 ){
          return false;
      }
  
      //extract the driver information
      m_driver = m_dataset->GetDriver();
  
      // if the driver failed, then exit
      if( m_driver == NULL ){
          return false;
      }
  
  
      // get the image dimensions
      m_width = m_dataset->GetRasterXSize();
      m_height= m_dataset->GetRasterYSize();
  
      // make sure we have at least one band/channel
      if( m_dataset->GetRasterCount() <= 0 ){
          return false;
      }
  
      // check if we have a color palette
      int tempType;
      if( m_dataset->GetRasterBand(1)->GetColorInterpretation() == GCI_PaletteIndex ){
  
          // remember that we have a color palette
          hasColorTable = true;
  
          // if the color tables does not exist, then we failed
          if( m_dataset->GetRasterBand(1)->GetColorTable() == NULL ){
              return false;
          }
  
          // otherwise, get the pixeltype
          else{
              // convert the palette interpretation to opencv type
              tempType = gdalPaletteInterpretation2OpenCV( m_dataset->GetRasterBand(1)->GetColorTable()->GetPaletteInterpretation(),
                                                           m_dataset->GetRasterBand(1)->GetRasterDataType() );
  
              if( tempType == -1 ){
                  return false;
              }
              m_type = tempType;
          }
  
      }
  
      // otherwise, we have standard channels
      else{
  
          // remember that we don't have a color table
          hasColorTable = false;
  
          // convert the datatype to opencv
          tempType = gdal2opencv( m_dataset->GetRasterBand(1)->GetRasterDataType(), m_dataset->GetRasterCount() );
          if( tempType == -1 ){
              return false;
          }
          m_type = tempType;
      }
  
      return true;
  }
  
  /**
   * Close the module
  */
  void GdalDecoder::close(){
  
  
      GDALClose((GDALDatasetH)m_dataset);
      m_dataset = NULL;
      m_driver = NULL;
  }
  
  /**
   * Create a new decoder
  */
  ImageDecoder GdalDecoder::newDecoder()const{
      return makePtr<GdalDecoder>();
  }
  
  /**
   * Test the file signature
  */
  bool GdalDecoder::checkSignature( const String& signature )const{
  
      // look for NITF
      std::string str(signature);
      if( str.substr(0,4).find("NITF") != std::string::npos ){
          return true;
      }
  
      // look for DTED
      if( str.size() > 144 && str.substr(140,4) == "DTED" ){
          return true;
      }
  
      return false;
  }
  
  } /// End of cv Namespace
  
  #endif /**< End  of HAVE_GDAL Definition */