bool QgsImageWarper::openSrcDSAndGetWarpOpt( const QString &input, const ResamplingMethod &resampling,
    const GDALTransformerFunc &pfnTransform,
    GDALDatasetH &hSrcDS, GDALWarpOptions *&psWarpOptions )
{
  // Open input file
  GDALAllRegister();
  hSrcDS = GDALOpen( TO8F( input ), GA_ReadOnly );
  if ( !hSrcDS )
    return false;

  // Setup warp options.
  psWarpOptions = GDALCreateWarpOptions();
  psWarpOptions->hSrcDS = hSrcDS;
  psWarpOptions->nBandCount = GDALGetRasterCount( hSrcDS );
  psWarpOptions->panSrcBands =
    ( int * ) CPLMalloc( sizeof( int ) * psWarpOptions->nBandCount );
  psWarpOptions->panDstBands =
    ( int * ) CPLMalloc( sizeof( int ) * psWarpOptions->nBandCount );
  for ( int i = 0; i < psWarpOptions->nBandCount; ++i )
  {
    psWarpOptions->panSrcBands[i] = i + 1;
    psWarpOptions->panDstBands[i] = i + 1;
  }
  psWarpOptions->pfnProgress = GDALTermProgress;
  psWarpOptions->pfnTransformer = pfnTransform;
  psWarpOptions->eResampleAlg = GDALResampleAlg( resampling );

  return true;
}
Exemplo n.º 2
0
/**
 * GDALReprojectImage() method with a ChunkAndWarpImage replaced with ChunkAndWarpMulti
 */
CPLErr GDALReprojectImageMulti( GDALDatasetH hSrcDS, const char *pszSrcWKT,
                    GDALDatasetH hDstDS, const char *pszDstWKT,
                    GDALResampleAlg eResampleAlg,
                    double dfWarpMemoryLimit,
                    double dfMaxError,
                    GDALProgressFunc pfnProgress, void *pProgressArg,
                    GDALWarpOptions *psOptions )

{
    GDALWarpOptions *psWOptions;

/* -------------------------------------------------------------------- */
/*      Setup a reprojection based transformer.                         */
/* -------------------------------------------------------------------- */
    void *hTransformArg;

    hTransformArg = 
        GDALCreateGenImgProjTransformer( hSrcDS, pszSrcWKT, hDstDS, pszDstWKT, 
                                         TRUE, 1000.0, 0 );

    if( hTransformArg == NULL )
        return CE_Failure;

/* -------------------------------------------------------------------- */
/*      Create a copy of the user provided options, or a defaulted      */
/*      options structure.                                              */
/* -------------------------------------------------------------------- */
    if( psOptions == NULL )
        psWOptions = GDALCreateWarpOptions();
    else
        psWOptions = GDALCloneWarpOptions( psOptions );

    psWOptions->eResampleAlg = eResampleAlg;

/* -------------------------------------------------------------------- */
/*      Set transform.                                                  */
/* -------------------------------------------------------------------- */
    if( dfMaxError > 0.0 )
    {
        psWOptions->pTransformerArg = 
            GDALCreateApproxTransformer( GDALGenImgProjTransform, 
                                         hTransformArg, dfMaxError );

        psWOptions->pfnTransformer = GDALApproxTransform;
    }
    else
    {
        psWOptions->pfnTransformer = GDALGenImgProjTransform;
        psWOptions->pTransformerArg = hTransformArg;
    }

/* -------------------------------------------------------------------- */
/*      Set file and band mapping.                                      */
/* -------------------------------------------------------------------- */
    int  iBand;

    psWOptions->hSrcDS = hSrcDS;
    psWOptions->hDstDS = hDstDS;

    if( psWOptions->nBandCount == 0 )
    {
        psWOptions->nBandCount = MIN(GDALGetRasterCount(hSrcDS),
                                     GDALGetRasterCount(hDstDS));
        
        psWOptions->panSrcBands = (int *) 
            CPLMalloc(sizeof(int) * psWOptions->nBandCount);
        psWOptions->panDstBands = (int *) 
            CPLMalloc(sizeof(int) * psWOptions->nBandCount);

        for( iBand = 0; iBand < psWOptions->nBandCount; iBand++ )
        {
            psWOptions->panSrcBands[iBand] = iBand+1;
            psWOptions->panDstBands[iBand] = iBand+1;
        }
    }

/* -------------------------------------------------------------------- */
/*      Set source nodata values if the source dataset seems to have    */
/*      any. Same for target nodata values                              */
/* -------------------------------------------------------------------- */
    for( iBand = 0; iBand < psWOptions->nBandCount; iBand++ )
    {
        GDALRasterBandH hBand = GDALGetRasterBand( hSrcDS, iBand+1 );
        int             bGotNoData = FALSE;
        double          dfNoDataValue;

        if (GDALGetRasterColorInterpretation(hBand) == GCI_AlphaBand)
        {
            psWOptions->nSrcAlphaBand = iBand + 1;
        }

        dfNoDataValue = GDALGetRasterNoDataValue( hBand, &bGotNoData );
        if( bGotNoData )
        {
            if( psWOptions->padfSrcNoDataReal == NULL )
            {
                int  ii;

                psWOptions->padfSrcNoDataReal = (double *) 
                    CPLMalloc(sizeof(double) * psWOptions->nBandCount);
                psWOptions->padfSrcNoDataImag = (double *) 
                    CPLMalloc(sizeof(double) * psWOptions->nBandCount);

                for( ii = 0; ii < psWOptions->nBandCount; ii++ )
                {
                    psWOptions->padfSrcNoDataReal[ii] = -1.1e20;
                    psWOptions->padfSrcNoDataImag[ii] = 0.0;
                }
            }

            psWOptions->padfSrcNoDataReal[iBand] = dfNoDataValue;
        }

        // Deal with target band
        hBand = GDALGetRasterBand( hDstDS, iBand+1 );
        if (hBand && GDALGetRasterColorInterpretation(hBand) == GCI_AlphaBand)
        {
            psWOptions->nDstAlphaBand = iBand + 1;
        }

        dfNoDataValue = GDALGetRasterNoDataValue( hBand, &bGotNoData );
        if( bGotNoData )
        {
            if( psWOptions->padfDstNoDataReal == NULL )
            {
                int  ii;

                psWOptions->padfDstNoDataReal = (double *) 
                    CPLMalloc(sizeof(double) * psWOptions->nBandCount);
                psWOptions->padfDstNoDataImag = (double *) 
                    CPLMalloc(sizeof(double) * psWOptions->nBandCount);

                for( ii = 0; ii < psWOptions->nBandCount; ii++ )
                {
                    psWOptions->padfDstNoDataReal[ii] = -1.1e20;
                    psWOptions->padfDstNoDataImag[ii] = 0.0;
                }
            }

            psWOptions->padfDstNoDataReal[iBand] = dfNoDataValue;
        }
    }

/* -------------------------------------------------------------------- */
/*      Set the progress function.                                      */
/* -------------------------------------------------------------------- */
    if( pfnProgress != NULL )
    {
        psWOptions->pfnProgress = pfnProgress;
        psWOptions->pProgressArg = pProgressArg;
    }

/* -------------------------------------------------------------------- */
/*      Create a warp options based on the options.                     */
/* -------------------------------------------------------------------- */
    GDALWarpOperation  oWarper;
    CPLErr eErr;

    eErr = oWarper.Initialize( psWOptions );

    if( eErr == CE_None )
        eErr = oWarper.ChunkAndWarpMulti( 0, 0, 
                                          GDALGetRasterXSize(hDstDS),
                                          GDALGetRasterYSize(hDstDS) );

/* -------------------------------------------------------------------- */
/*      Cleanup.                                                        */
/* -------------------------------------------------------------------- */
    GDALDestroyGenImgProjTransformer( hTransformArg );

    if( dfMaxError > 0.0 )
        GDALDestroyApproxTransformer( psWOptions->pTransformerArg );
        
    GDALDestroyWarpOptions( psWOptions );

    return eErr;
}
Exemplo n.º 3
0
int main( int nArgc, char ** papszArgv )
{
    // register drivers
    GDALAllRegister();

    if( nArgc < 2 )
        return EXIT_FAILURE;

    double dfaCornersX[5] = {0};
    double dfaCornersY[5] = {0};
    CPLString sFileName;

    // parse input values
    for( int iArg = 1; iArg < nArgc; iArg++ )
    {
        if( EQUAL(papszArgv[iArg],"-nw"))
        {
            CHECK_HAS_ENOUGH_ADDITIONAL_ARGS(2);
            const char* pszCoord = papszArgv[++iArg];
            dfaCornersY[1] = CPLAtofM(pszCoord);
            pszCoord = papszArgv[++iArg];
            dfaCornersX[1] = CPLAtofM(pszCoord);
        }
        else if( EQUAL(papszArgv[iArg],"-ne"))
        {
            CHECK_HAS_ENOUGH_ADDITIONAL_ARGS(2);
            const char* pszCoord = papszArgv[++iArg];
            dfaCornersY[2] = CPLAtofM(pszCoord);
            pszCoord = papszArgv[++iArg];
            dfaCornersX[2] = CPLAtofM(pszCoord);
        }
        else if( EQUAL(papszArgv[iArg],"-se"))
        {
            CHECK_HAS_ENOUGH_ADDITIONAL_ARGS(2);
            const char* pszCoord = papszArgv[++iArg];
            dfaCornersY[3] = CPLAtofM(pszCoord);
            pszCoord = papszArgv[++iArg];
            dfaCornersX[3] = CPLAtofM(pszCoord);
        }
        else if( EQUAL(papszArgv[iArg],"-sw"))
        {
            CHECK_HAS_ENOUGH_ADDITIONAL_ARGS(2);
            const char* pszCoord = papszArgv[++iArg];
            dfaCornersY[4] = CPLAtofM(pszCoord);
            pszCoord = papszArgv[++iArg];
            dfaCornersX[4] = CPLAtofM(pszCoord);
        }
        else if( EQUAL(papszArgv[iArg],"-c"))
        {
            CHECK_HAS_ENOUGH_ADDITIONAL_ARGS(2);
            const char* pszCoord = papszArgv[++iArg];
            dfaCornersY[0] = CPLAtofM(pszCoord);
            pszCoord = papszArgv[++iArg];
            dfaCornersX[0] = CPLAtofM(pszCoord);
        }
        else if(sFileName.empty())
            sFileName = papszArgv[iArg];
    }

    OGRSpatialReference oOGRSpatialReference(SRS_WKT_WGS84);
    int nZoneNo = ceil( (180.0 + dfaCornersX[0]) / 6.0 );
    OGRSpatialReference oDstSpatialReference(SRS_WKT_WGS84);
    oDstSpatialReference.SetUTM(nZoneNo, dfaCornersY[0] > 0);

    // transform coordinates from WGS84 to UTM
    OGRCoordinateTransformation *poCT = OGRCreateCoordinateTransformation( &oOGRSpatialReference, &oDstSpatialReference);
    if(!poCT)
    {
        Usage("get coordinate transformation failed");
        return EXIT_FAILURE;
    }

    int nResult = poCT->Transform(5, dfaCornersX, dfaCornersY, NULL);
    if(!nResult)
    {
        Usage("transformation failed");
        return EXIT_FAILURE;
    }

    // open input dataset
    GDALDataset *poSrcDataset = (GDALDataset *) GDALOpen( sFileName, GA_ReadOnly ); // GA_Update
    char* pszSpaRefDef = NULL;
    if( oDstSpatialReference.exportToWkt(&pszSpaRefDef) != OGRERR_NONE)
    {
        CPLFree( pszSpaRefDef );
        GDALClose( (GDALDatasetH) poSrcDataset );
        return EXIT_FAILURE;
    }

    // search point along image
    // add GCP to opened raster
    OGRPoint ptCenter(dfaCornersX[0], dfaCornersY[0]);
    OGRPoint pt1(dfaCornersX[1], dfaCornersY[1]); // NW Cormer
    OGRPoint pt2(dfaCornersX[2], dfaCornersY[2]); // NE Corner
    OGRPoint pt3(dfaCornersX[3], dfaCornersY[3]); // SE Corner
    OGRPoint pt4(dfaCornersX[4], dfaCornersY[4]); // SW Corner
    int nGCPCount = 0;
    OGREnvelope DstEnv;
    GDAL_GCP *paGSPs = PrepareGCP(sFileName, &pt1, &pt2, &pt3, &pt4, &ptCenter, oDstSpatialReference, poSrcDataset->GetRasterXSize(), poSrcDataset->GetRasterYSize(), nGCPCount, DstEnv);

    if(poSrcDataset->SetGCPs(nGCPCount, paGSPs, pszSpaRefDef) != CE_None)
    {
        Usage( "Set GCPs failed" );
        return EXIT_FAILURE;
    }

    // create warper
    char **papszTO = NULL;
    papszTO = CSLSetNameValue( papszTO, "METHOD", "GCP_TPS" );
    papszTO = CSLSetNameValue( papszTO, "NUM_THREADS", "4" );
    papszTO = CSLSetNameValue( papszTO, "DST_SRS", pszSpaRefDef );
    papszTO = CSLSetNameValue( papszTO, "SRC_SRS", pszSpaRefDef );
    papszTO = CSLSetNameValue( papszTO, "INSERT_CENTER_LONG", "FALSE" );

    GDALDriver *poOutputDriver = (GDALDriver *) GDALGetDriverByName( "GTiff" );
    CPLSetConfigOption( "CHECK_WITH_INVERT_PROJ", "TRUE" );
    void* hTransformArg = GDALCreateGenImgProjTransformer2( poSrcDataset, NULL, papszTO );
    GDALTransformerInfo* psInfo = (GDALTransformerInfo*)hTransformArg;

    double adfThisGeoTransform[6];
    double adfExtent[4];
    int nThisPixels, nThisLines;

    // suggest the raster output size
    if( GDALSuggestedWarpOutput2( poSrcDataset, psInfo->pfnTransform, hTransformArg, adfThisGeoTransform, &nThisPixels, &nThisLines, adfExtent, 0 ) != CE_None )
    {
        Usage( "Suggest Output failed" );
        return EXIT_FAILURE;
    }

    adfThisGeoTransform[0] = DstEnv.MinX;
    adfThisGeoTransform[3] = DstEnv.MaxY;

    int nPixels = (int) ((DstEnv.MaxX - DstEnv.MinX) / adfThisGeoTransform[1] + 0.5);
    int nLines = (int) ((DstEnv.MaxY - DstEnv.MinY) / -adfThisGeoTransform[5] + 0.5);

    GDALSetGenImgProjTransformerDstGeoTransform( hTransformArg, adfThisGeoTransform);

    // create new raster
    CPLString sOutputRasterPath = CPLResetExtension(sFileName, "tif");
    GDALDataset  *poDstDataset = poOutputDriver->Create(sOutputRasterPath, nPixels, nLines, poSrcDataset->GetRasterCount(), GDT_Byte, NULL );
    if( NULL == poDstDataset )
    {
        Usage( "Create Output failed" );
        return EXIT_FAILURE;
    }
    poDstDataset->SetProjection( pszSpaRefDef );
    poDstDataset->SetGeoTransform( adfThisGeoTransform );

#ifdef APRROX_MAXERROR
    hTransformArg = GDALCreateApproxTransformer( GDALGenImgProjTransform,  hTransformArg, APRROX_MAXERROR);
    GDALTransformerFunc pfnTransformer = GDALApproxTransform;
    GDALApproxTransformerOwnsSubtransformer(hTransformArg, TRUE);
#else
    GDALTransformerFunc pfnTransformer = GDALGenImgProjTransform;
#endif // APRROX_MAXERROR

    // warp
    GDALWarpOptions *psWO = GDALCreateWarpOptions();

    psWO->eWorkingDataType = GDT_Byte;
    psWO->eResampleAlg = GRA_NearestNeighbour;

    psWO->hSrcDS = poSrcDataset;
    psWO->hDstDS = poDstDataset;

    psWO->pfnTransformer = pfnTransformer;
    psWO->pTransformerArg = hTransformArg;

    psWO->pfnProgress = GDALTermProgress;
    psWO->nBandCount = poSrcDataset->GetRasterCount();

    psWO->panSrcBands = (int *) CPLMalloc(psWO->nBandCount*sizeof(int));
    psWO->panDstBands = (int *) CPLMalloc(psWO->nBandCount*sizeof(int));

    for(int i = 0; i < psWO->nBandCount; ++i )
    {
        psWO->panSrcBands[i] = i+1;
        psWO->panDstBands[i] = i+1;
    }

    GDALWarpOperation oWO;
    if( oWO.Initialize( psWO ) == CE_None )
    {
#ifdef MULTI
        if( oWO.ChunkAndWarpMulti( 0, 0, poDstDataset->GetRasterXSize(), poDstDataset->GetRasterYSize() ) != CE_None)
#else //MULTI
        if( oWO.ChunkAndWarpImage( 0, 0, poDstDataset->GetRasterXSize(), poDstDataset->GetRasterYSize() ) != CE_None)
#endif //MULTI
        {
            const char* err = CPLGetLastErrorMsg();
            Usage( CPLSPrintf("Warp failed.%s", err) );
            return EXIT_FAILURE;
        }
    }

    // cleanup
    GDALDestroyWarpOptions( psWO );
    CSLDestroy( papszTO );

    CPLFree( pszSpaRefDef );
    GDALClose( (GDALDatasetH) poSrcDataset );
    GDALClose( (GDALDatasetH) poDstDataset );

    GDALDestroyDriverManager();

    return EXIT_SUCCESS;
}
Exemplo n.º 4
0
bool QgsAlignRaster::createAndWarp( const Item& raster )
{
  GDALDriverH hDriver = GDALGetDriverByName( "GTiff" );
  if ( !hDriver )
  {
    mErrorMessage = QString( "GDALGetDriverByName(GTiff) failed." );
    return false;
  }

  // Open the source file.
  GDALDatasetH hSrcDS = GDALOpen( raster.inputFilename.toLocal8Bit().constData(), GA_ReadOnly );
  if ( !hSrcDS )
  {
    mErrorMessage = QObject::tr( "Unable to open input file: " ) + raster.inputFilename;
    return false;
  }

  // Create output with same datatype as first input band.

  int bandCount = GDALGetRasterCount( hSrcDS );
  GDALDataType eDT = GDALGetRasterDataType( GDALGetRasterBand( hSrcDS, 1 ) );

  // Create the output file.
  GDALDatasetH hDstDS;
  hDstDS = GDALCreate( hDriver, raster.outputFilename.toLocal8Bit().constData(), mXSize, mYSize,
                       bandCount, eDT, NULL );
  if ( !hDstDS )
  {
    GDALClose( hSrcDS );
    mErrorMessage = QObject::tr( "Unable to create output file: " ) + raster.outputFilename;
    return false;
  }

  // Write out the projection definition.
  GDALSetProjection( hDstDS, mCrsWkt.toAscii().constData() );
  GDALSetGeoTransform( hDstDS, ( double* )mGeoTransform );

  // Copy the color table, if required.
  GDALColorTableH hCT = GDALGetRasterColorTable( GDALGetRasterBand( hSrcDS, 1 ) );
  if ( hCT != NULL )
    GDALSetRasterColorTable( GDALGetRasterBand( hDstDS, 1 ), hCT );

  // -----------------------------------------------------------------------

  // Setup warp options.
  GDALWarpOptions* psWarpOptions = GDALCreateWarpOptions();
  psWarpOptions->hSrcDS = hSrcDS;
  psWarpOptions->hDstDS = hDstDS;

  psWarpOptions->nBandCount = GDALGetRasterCount( hSrcDS );
  psWarpOptions->panSrcBands = ( int * ) CPLMalloc( sizeof( int ) * psWarpOptions->nBandCount );
  psWarpOptions->panDstBands = ( int * ) CPLMalloc( sizeof( int ) * psWarpOptions->nBandCount );
  for ( int i = 0; i < psWarpOptions->nBandCount; ++i )
  {
    psWarpOptions->panSrcBands[i] = i + 1;
    psWarpOptions->panDstBands[i] = i + 1;
  }

  psWarpOptions->eResampleAlg = ( GDALResampleAlg ) raster.resampleMethod;

  // our progress function
  psWarpOptions->pfnProgress = _progress;
  psWarpOptions->pProgressArg = this;

  // Establish reprojection transformer.
  psWarpOptions->pTransformerArg =
    GDALCreateGenImgProjTransformer( hSrcDS, GDALGetProjectionRef( hSrcDS ),
                                     hDstDS, GDALGetProjectionRef( hDstDS ),
                                     FALSE, 0.0, 1 );
  psWarpOptions->pfnTransformer = GDALGenImgProjTransform;

  double rescaleArg[2];
  if ( raster.rescaleValues )
  {
    rescaleArg[0] = raster.srcCellSizeInDestCRS; // source cell size
    rescaleArg[1] = mCellSizeX * mCellSizeY;  // destination cell size
    psWarpOptions->pfnPreWarpChunkProcessor = rescalePreWarpChunkProcessor;
    psWarpOptions->pfnPostWarpChunkProcessor = rescalePostWarpChunkProcessor;
    psWarpOptions->pPreWarpProcessorArg = rescaleArg;
    psWarpOptions->pPostWarpProcessorArg = rescaleArg;
    // force use of float32 data type as that is what our pre/post-processor uses
    psWarpOptions->eWorkingDataType = GDT_Float32;
  }

  // Initialize and execute the warp operation.
  GDALWarpOperation oOperation;
  oOperation.Initialize( psWarpOptions );
  oOperation.ChunkAndWarpImage( 0, 0, mXSize, mYSize );

  GDALDestroyGenImgProjTransformer( psWarpOptions->pTransformerArg );
  GDALDestroyWarpOptions( psWarpOptions );

  GDALClose( hDstDS );
  GDALClose( hSrcDS );
  return true;
}
/**
* Sets the surface grids based on a ncepNam (surface only!) forecast.
* @param input The WindNinjaInputs for misc. info.
* @param airGrid The air temperature grid to be filled.
* @param cloudGrid The cloud cover grid to be filled.
* @param uGrid The u velocity grid to be filled.
* @param vGrid The v velocity grid to be filled.
* @param wGrid The w velocity grid to be filled (filled with zeros here?).
*/
void genericSurfInitialization::setSurfaceGrids( WindNinjaInputs &input,
        AsciiGrid<double> &airGrid,
        AsciiGrid<double> &cloudGrid,
        AsciiGrid<double> &uGrid,
        AsciiGrid<double> &vGrid,
        AsciiGrid<double> &wGrid )
{
    int bandNum = -1;

    //get time list
    std::vector<boost::local_time::local_date_time> timeList( getTimeList(input.ninjaTimeZone) );
    //Search time list for our time to identify our band number for cloud/speed/dir
    for(unsigned int i = 0; i < timeList.size(); i++)
    {
        if(input.ninjaTime == timeList[i])
        {
            bandNum = i + 1;
            break;
        }
    }
    if(bandNum < 0)
        throw std::runtime_error("Could not match ninjaTime with a band number in the forecast file.");

    //get some info from the nam file in input

    //Acquire a lock to protect the non-thread safe netCDF library
#ifdef _OPENMP
    omp_guard netCDF_guard(netCDF_lock);
#endif

    GDALDataset* poDS;

    //attempt to grab the projection from the dem?
    //check for member prjString first
    std::string dstWkt;
    dstWkt = input.dem.prjString;
    if ( dstWkt.empty() ) {
        //try to open original
        poDS = (GDALDataset*)GDALOpen( input.dem.fileName.c_str(), GA_ReadOnly );
        if( poDS == NULL ) {
            CPLDebug( "ncepNdfdInitialization::setSurfaceGrids()",
                    "Bad projection reference" );
            //throw();
        }
        dstWkt = poDS->GetProjectionRef();
        if( dstWkt.empty() ) {
            CPLDebug( "ncepNdfdInitialization::setSurfaceGrids()",
                    "Bad projection reference" );
            //throw()
        }
        GDALClose((GDALDatasetH) poDS );
    }

    poDS = (GDALDataset*)GDALOpen( input.forecastFilename.c_str(), GA_ReadOnly );

    if( poDS == NULL ) {
        CPLDebug( "ncepNdfdInitialization::setSurfaceGrids()",
                "Bad forecast file" );
    }
    else
        GDALClose((GDALDatasetH) poDS );

    // open ds one by one and warp, then write to grid
    GDALDataset *srcDS, *wrpDS;
    std::string temp;
    std::string srcWkt;

    std::vector<std::string> varList = getVariableList();

    /*
     * Set the initial values in the warped dataset to no data
     */
    GDALWarpOptions* psWarpOptions;

    for( unsigned int i = 0;i < varList.size();i++ ) {

        temp = "NETCDF:" + input.forecastFilename + ":" + varList[i];

        srcDS = (GDALDataset*)GDALOpenShared( temp.c_str(), GA_ReadOnly );
        if( srcDS == NULL ) {
            CPLDebug( "ncepNdfdInitialization::setSurfaceGrids()",
                    "Bad forecast file" );
        }

        srcWkt = srcDS->GetProjectionRef();

        if( srcWkt.empty() ) {
            CPLDebug( "ncepNdfdInitialization::setSurfaceGrids()",
                    "Bad forecast file" );
            //throw
        }

        /*
         * Grab the first band to get the nodata value for the variable,
         * assume all bands have the same ndv
         */
        GDALRasterBand *poBand = srcDS->GetRasterBand( 1 );
        int pbSuccess;
        double dfNoData = poBand->GetNoDataValue( &pbSuccess );

        psWarpOptions = GDALCreateWarpOptions();

        int nBandCount = srcDS->GetRasterCount();

        psWarpOptions->nBandCount = nBandCount;

        psWarpOptions->padfDstNoDataReal =
            (double*) CPLMalloc( sizeof( double ) * nBandCount );
        psWarpOptions->padfDstNoDataImag =
            (double*) CPLMalloc( sizeof( double ) * nBandCount );

        for( int b = 0;b < srcDS->GetRasterCount();b++ ) {
            psWarpOptions->padfDstNoDataReal[b] = dfNoData;
            psWarpOptions->padfDstNoDataImag[b] = dfNoData;
        }

        if( pbSuccess == false )
            dfNoData = -9999.0;

        psWarpOptions->papszWarpOptions =
            CSLSetNameValue( psWarpOptions->papszWarpOptions,
                            "INIT_DEST", "NO_DATA" );

        wrpDS = (GDALDataset*) GDALAutoCreateWarpedVRT( srcDS, srcWkt.c_str(),
                                                        dstWkt.c_str(),
                                                        GRA_NearestNeighbour,
                                                        1.0, psWarpOptions );

        if( varList[i] == "Temperature_height_above_ground" ) {
            GDAL2AsciiGrid( wrpDS, bandNum, airGrid );
        if( CPLIsNan( dfNoData ) ) {
        airGrid.set_noDataValue(-9999.0);
        airGrid.replaceNan( -9999.0 );
        }
    }
        else if( varList[i] == "V-component_of_wind_height_above_ground" ) {
            GDAL2AsciiGrid( wrpDS, bandNum, vGrid );
        if( CPLIsNan( dfNoData ) ) {
        vGrid.set_noDataValue(-9999.0);
        vGrid.replaceNan( -9999.0 );
        }
    }
        else if( varList[i] == "U-component_of_wind_height_above_ground" ) {
            GDAL2AsciiGrid( wrpDS, bandNum, uGrid );
        if( CPLIsNan( dfNoData ) ) {
        uGrid.set_noDataValue(-9999.0);
        uGrid.replaceNan( -9999.0 );
        }
    }
        else if( varList[i] == "Total_cloud_cover" ) {
            GDAL2AsciiGrid( wrpDS, bandNum, cloudGrid );
        if( CPLIsNan( dfNoData ) ) {
        cloudGrid.set_noDataValue(-9999.0);
        cloudGrid.replaceNan( -9999.0 );
        }
    }

        GDALDestroyWarpOptions( psWarpOptions );
        GDALClose((GDALDatasetH) srcDS );
        GDALClose((GDALDatasetH) wrpDS );
    }
    cloudGrid /= 100.0;

    wGrid.set_headerData( uGrid );
    wGrid = 0.0;
}
Exemplo n.º 6
0
GDALDatasetH CPL_STDCALL 
GDALAutoCreateWarpedVRT( GDALDatasetH hSrcDS, 
                         const char *pszSrcWKT,
                         const char *pszDstWKT,
                         GDALResampleAlg eResampleAlg, 
                         double dfMaxError, 
                         const GDALWarpOptions *psOptionsIn )
    
{
    GDALWarpOptions *psWO;
    int i;

    VALIDATE_POINTER1( hSrcDS, "GDALAutoCreateWarpedVRT", NULL );

/* -------------------------------------------------------------------- */
/*      Populate the warp options.                                      */
/* -------------------------------------------------------------------- */
    if( psOptionsIn != NULL )
        psWO = GDALCloneWarpOptions( psOptionsIn );
    else
        psWO = GDALCreateWarpOptions();

    psWO->eResampleAlg = eResampleAlg;

    psWO->hSrcDS = hSrcDS;

    psWO->nBandCount = GDALGetRasterCount( hSrcDS );
    psWO->panSrcBands = (int *) CPLMalloc(sizeof(int) * psWO->nBandCount);
    psWO->panDstBands = (int *) CPLMalloc(sizeof(int) * psWO->nBandCount);

    for( i = 0; i < psWO->nBandCount; i++ )
    {
        psWO->panSrcBands[i] = i+1;
        psWO->panDstBands[i] = i+1;
    }

    /* TODO: should fill in no data where available */

/* -------------------------------------------------------------------- */
/*      Create the transformer.                                         */
/* -------------------------------------------------------------------- */
    psWO->pfnTransformer = GDALGenImgProjTransform;
    psWO->pTransformerArg = 
        GDALCreateGenImgProjTransformer( psWO->hSrcDS, pszSrcWKT, 
                                         NULL, pszDstWKT,
                                         TRUE, 1.0, 0 );

    if( psWO->pTransformerArg == NULL )
    {
        GDALDestroyWarpOptions( psWO );
        return NULL;
    }

/* -------------------------------------------------------------------- */
/*      Figure out the desired output bounds and resolution.            */
/* -------------------------------------------------------------------- */
    double adfDstGeoTransform[6];
    int    nDstPixels, nDstLines;
    CPLErr eErr;

    eErr = 
        GDALSuggestedWarpOutput( hSrcDS, psWO->pfnTransformer, 
                                 psWO->pTransformerArg, 
                                 adfDstGeoTransform, &nDstPixels, &nDstLines );

/* -------------------------------------------------------------------- */
/*      Update the transformer to include an output geotransform        */
/*      back to pixel/line coordinates.                                 */
/*                                                                      */
/* -------------------------------------------------------------------- */
    GDALSetGenImgProjTransformerDstGeoTransform( 
        psWO->pTransformerArg, adfDstGeoTransform );

/* -------------------------------------------------------------------- */
/*      Do we want to apply an approximating transformation?            */
/* -------------------------------------------------------------------- */
    if( dfMaxError > 0.0 )
    {
        psWO->pTransformerArg = 
            GDALCreateApproxTransformer( psWO->pfnTransformer, 
                                         psWO->pTransformerArg, 
                                         dfMaxError );
        psWO->pfnTransformer = GDALApproxTransform;
    }

/* -------------------------------------------------------------------- */
/*      Create the VRT file.                                            */
/* -------------------------------------------------------------------- */
    GDALDatasetH hDstDS;

    hDstDS = GDALCreateWarpedVRT( hSrcDS, nDstPixels, nDstLines, 
                                  adfDstGeoTransform, psWO );

    GDALDestroyWarpOptions( psWO );

    if( pszDstWKT != NULL )
        GDALSetProjection( hDstDS, pszDstWKT );
    else if( pszSrcWKT != NULL )
        GDALSetProjection( hDstDS, pszDstWKT );
    else if( GDALGetGCPCount( hSrcDS ) > 0 )
        GDALSetProjection( hDstDS, GDALGetGCPProjection( hSrcDS ) );
    else 
        GDALSetProjection( hDstDS, GDALGetProjectionRef( hSrcDS ) );

    return hDstDS;
}
/**
* Sets the surface grids based on a ncep HRRR (surface only!) forecast.
* @param input The WindNinjaInputs for misc. info.
* @param airGrid The air temperature grid to be filled.
* @param cloudGrid The cloud cover grid to be filled.
* @param uGrid The u velocity grid to be filled.
* @param vGrid The v velocity grid to be filled.
* @param wGrid The w velocity grid to be filled (filled with zeros here?).
*/
void ncepHrrrSurfInitialization::setSurfaceGrids( WindNinjaInputs &input,
        AsciiGrid<double> &airGrid,
        AsciiGrid<double> &cloudGrid,
        AsciiGrid<double> &uGrid,
        AsciiGrid<double> &vGrid,
        AsciiGrid<double> &wGrid )
{
    int bandNum = -1;

    GDALDataset *srcDS;
    srcDS = (GDALDataset*)GDALOpenShared( input.forecastFilename.c_str(), GA_ReadOnly );

    if( srcDS == NULL ) {
        CPLDebug( "ncepHRRRSurfaceInitialization::identify()",
                "Bad forecast file" );
    }

    GDALRasterBand *poBand;
    const char *gc;

    //get time list
    std::vector<boost::local_time::local_date_time> timeList( getTimeList( input.ninjaTimeZone ) );

    //Search time list for our time to identify our band number for cloud/speed/dir
    //Right now, just one time step per file
    std::vector<int> bandList;
    for(unsigned int i = 0; i < timeList.size(); i++)
    {
        if(input.ninjaTime == timeList[i])
        {
            for(unsigned int j = 1; j < srcDS->GetRasterCount(); j++)
            { 
                poBand = srcDS->GetRasterBand( j );
                gc = poBand->GetMetadataItem( "GRIB_COMMENT" );
                std::string bandName( gc );

                if( bandName.find( "Temperature [K]" ) != bandName.npos ){
                    gc = poBand->GetMetadataItem( "GRIB_SHORT_NAME" );
                    std::string bandName( gc );
                    if( bandName.find( "2-HTGL" ) != bandName.npos ){
                        bandList.push_back( j );  // 2t 
                        break;
                    }
                }
            }
            for(unsigned int j = 1; j < srcDS->GetRasterCount(); j++)
            { 
                poBand = srcDS->GetRasterBand( j );
                gc = poBand->GetMetadataItem( "GRIB_COMMENT" );
                std::string bandName( gc );

                if( bandName.find( "v-component of wind [m/s]" ) != bandName.npos ){
                    gc = poBand->GetMetadataItem( "GRIB_SHORT_NAME" );
                    std::string bandName( gc );
                    if( bandName.find( "10-HTGL" ) != bandName.npos ){
                        bandList.push_back( j );  // 10v
                        break;
                    }
                }
            }
            for(unsigned int j = 1; j < srcDS->GetRasterCount(); j++)
            { 
                poBand = srcDS->GetRasterBand( j );
                gc = poBand->GetMetadataItem( "GRIB_COMMENT" );
                std::string bandName( gc );

                if( bandName.find( "u-component of wind [m/s]" ) != bandName.npos ){
                    gc = poBand->GetMetadataItem( "GRIB_SHORT_NAME" );
                    std::string bandName( gc );
                    if( bandName.find( "10-HTGL" ) != bandName.npos ){
                        bandList.push_back( j );  // 10u
                        break;
                    }
                }
            }
            for(unsigned int j = 1; j < srcDS->GetRasterCount(); j++)
            { 
                poBand = srcDS->GetRasterBand( j );
                gc = poBand->GetMetadataItem( "GRIB_COMMENT" );
                std::string bandName( gc );

                if( bandName.find( "Total cloud cover [%]" ) != bandName.npos ){
                    gc = poBand->GetMetadataItem( "GRIB_SHORT_NAME" );
                    std::string bandName( gc );
                    if( bandName.find( "0-RESERVED" ) != bandName.npos ){
                        bandList.push_back( j );  // Total cloud cover in % 
                        break;
                    }
                }
            }
        }
    }

    CPLDebug("HRRR", "2t: bandList[0] = %d", bandList[0]);
    CPLDebug("HRRR", "10v: bandList[1] = %d", bandList[1]);
    CPLDebug("HRRR", "10u: bandList[2] = %d", bandList[2]);
    CPLDebug("HRRR", "tcc: bandList[3] = %d", bandList[3]);

    if(bandList.size() < 4)
        throw std::runtime_error("Could not match ninjaTime with a band number in the forecast file.");

    std::string dstWkt;
    dstWkt = input.dem.prjString;

    GDALDataset *wrpDS;
    std::string temp;
    std::string srcWkt;

    GDALWarpOptions* psWarpOptions;

    srcWkt = srcDS->GetProjectionRef();

    poBand = srcDS->GetRasterBand( 9 );
    int pbSuccess;
    double dfNoData = poBand->GetNoDataValue( &pbSuccess );

    psWarpOptions = GDALCreateWarpOptions();

    int nBandCount = bandList.size();

    psWarpOptions->nBandCount = nBandCount;
    psWarpOptions->panSrcBands =
        (int*) CPLMalloc( sizeof( int ) * nBandCount );
    psWarpOptions->panDstBands =
        (int*) CPLMalloc( sizeof( int ) * nBandCount );
    psWarpOptions->padfDstNoDataReal =
        (double*) CPLMalloc( sizeof( double ) * nBandCount );
    psWarpOptions->padfDstNoDataImag =
        (double*) CPLMalloc( sizeof( double ) * nBandCount );


    psWarpOptions->padfDstNoDataReal =
        (double*) CPLMalloc( sizeof( double ) * nBandCount );
    psWarpOptions->padfDstNoDataImag =
        (double*) CPLMalloc( sizeof( double ) * nBandCount );

    if( pbSuccess == false )
        dfNoData = -9999.0;

    psWarpOptions->panSrcBands =
        (int *) CPLMalloc(sizeof(int) * psWarpOptions->nBandCount );
    psWarpOptions->panSrcBands[0] = bandList[0];
    psWarpOptions->panSrcBands[1] = bandList[1];
    psWarpOptions->panSrcBands[2] = bandList[2];
    psWarpOptions->panSrcBands[3] = bandList[3];

    psWarpOptions->panDstBands =
        (int *) CPLMalloc(sizeof(int) * psWarpOptions->nBandCount );
    psWarpOptions->panDstBands[0] = 1;
    psWarpOptions->panDstBands[1] = 2;
    psWarpOptions->panDstBands[2] = 3;
    psWarpOptions->panDstBands[3] = 4;

    wrpDS = (GDALDataset*) GDALAutoCreateWarpedVRT( srcDS, srcWkt.c_str(),
                                                    dstWkt.c_str(),
                                                    GRA_NearestNeighbour,
                                                    1.0, psWarpOptions );
    std::vector<std::string> varList = getVariableList();

    for( unsigned int i = 0; i < varList.size(); i++ ) {
        if( varList[i] == "2t" ) {
            GDAL2AsciiGrid( wrpDS, i+1, airGrid );
            if( CPLIsNan( dfNoData ) ) {
                airGrid.set_noDataValue( -9999.0 );
                airGrid.replaceNan( -9999.0 );
            }
        }
        else if( varList[i] == "10v" ) {
            GDAL2AsciiGrid( wrpDS, i+1, vGrid );
            if( CPLIsNan( dfNoData ) ) {
                vGrid.set_noDataValue( -9999.0 );
                vGrid.replaceNan( -9999.0 );
            }
        }
        else if( varList[i] == "10u" ) {
            GDAL2AsciiGrid( wrpDS, i+1, uGrid );
            if( CPLIsNan( dfNoData ) ) {
                uGrid.set_noDataValue( -9999.0 );
                uGrid.replaceNan( -9999.0 );
            }
        }
        else if( varList[i] == "tcc" ) {
            GDAL2AsciiGrid( wrpDS, i+1, cloudGrid );
            if( CPLIsNan( dfNoData ) ) {
                cloudGrid.set_noDataValue( -9999.0 );
                cloudGrid.replaceNan( -9999.0 );
            }
        }
    }
    //if there are any clouds set cloud fraction to 1, otherwise set to 0.
    for(int i = 0; i < cloudGrid.get_nRows(); i++){
        for(int j = 0; j < cloudGrid.get_nCols(); j++){
            if(cloudGrid(i,j) < 0.0){
                cloudGrid(i,j) = 0.0;
            }
            else{
                cloudGrid(i,j) = 1.0;
            }
        }
    }
    wGrid.set_headerData( uGrid );
    wGrid = 0.0;
    airGrid += 273.15;

    GDALDestroyWarpOptions( psWarpOptions );
    GDALClose((GDALDatasetH) srcDS );
    GDALClose((GDALDatasetH) wrpDS );
}
Exemplo n.º 8
0
void QgsImageWarper::warp( const QString& input, const QString& output,
                           double& xOffset, double& yOffset,
                           ResamplingMethod resampling, bool useZeroAsTrans, const QString& compression )
{
  // Open input file
  GDALAllRegister();
  GDALDatasetH hSrcDS = GDALOpen( QFile::encodeName( input ).constData(), GA_ReadOnly );
  // Setup warp options.
  GDALWarpOptions *psWarpOptions = GDALCreateWarpOptions();
  psWarpOptions->hSrcDS = hSrcDS;
  psWarpOptions->nBandCount = GDALGetRasterCount( hSrcDS );
  psWarpOptions->panSrcBands =
    ( int * ) CPLMalloc( sizeof( int ) * psWarpOptions->nBandCount );
  psWarpOptions->panDstBands =
    ( int * ) CPLMalloc( sizeof( int ) * psWarpOptions->nBandCount );
  for ( int i = 0; i < psWarpOptions->nBandCount; ++i )
  {
    psWarpOptions->panSrcBands[i] = i + 1;
    psWarpOptions->panDstBands[i] = i + 1;
  }
  psWarpOptions->pfnProgress = GDALTermProgress;
  psWarpOptions->pfnTransformer = &QgsImageWarper::transform;
  psWarpOptions->eResampleAlg = GDALResampleAlg( resampling );

  // check the bounds for the warped raster
  // order: upper right, lower right, lower left (y points down)
  double x[] = { GDALGetRasterXSize( hSrcDS ), GDALGetRasterXSize( hSrcDS ), 0 };
  double y[] = { 0, GDALGetRasterYSize( hSrcDS ), GDALGetRasterYSize( hSrcDS ) };
  int s[] = { 0, 0, 0 };
  TransformParameters tParam = { mAngle, 0, 0 };
  transform( &tParam, FALSE, 3, x, y, NULL, s );
  double minX = 0, minY = 0, maxX = 0, maxY = 0;
  for ( int i = 0; i < 3; ++i )
  {
    minX = minX < x[i] ? minX : x[i];
    minY = minY < y[i] ? minY : y[i];
    maxX = maxX > x[i] ? maxX : x[i];
    maxY = maxY > y[i] ? maxY : y[i];
  }
  int newXSize = int( maxX - minX ) + 1;
  int newYSize = int( maxY - minY ) + 1;
  xOffset = -minX;
  yOffset = -minY;
  tParam.x0 = xOffset;
  tParam.y0 = yOffset;
  psWarpOptions->pTransformerArg = &tParam;

  // create the output file
  GDALDriverH driver = GDALGetDriverByName( "GTiff" );
  char **papszOptions = NULL;
  papszOptions = CSLSetNameValue( papszOptions, "INIT_DEST", "NO_DATA" );
  papszOptions = CSLSetNameValue( papszOptions, "COMPRESS", compression.toAscii() );
  GDALDatasetH hDstDS =
    GDALCreate( driver,
                QFile::encodeName( output ).constData(), newXSize, newYSize,
                GDALGetRasterCount( hSrcDS ),
                GDALGetRasterDataType( GDALGetRasterBand( hSrcDS, 1 ) ),
                papszOptions );

  for ( int i = 0; i < GDALGetRasterCount( hSrcDS ); ++i )
  {
    GDALRasterBandH hSrcBand = GDALGetRasterBand( hSrcDS, i + 1 );
    GDALRasterBandH hDstBand = GDALGetRasterBand( hDstDS, i + 1 );
    GDALColorTableH cTable = GDALGetRasterColorTable( hSrcBand );
    GDALSetRasterColorInterpretation( hDstBand, GDALGetRasterColorInterpretation( hSrcBand ) );
    if ( cTable )
    {
      GDALSetRasterColorTable( hDstBand, cTable );
    }

    double noData = GDALGetRasterNoDataValue( hSrcBand, NULL );
    if ( noData == -1e10 && useZeroAsTrans )
    {
      GDALSetRasterNoDataValue( hDstBand, 0 );
    }
    else
    {
      GDALSetRasterNoDataValue( hDstBand, noData );
    }
  }
  psWarpOptions->hDstDS = hDstDS;

  // Initialize and execute the warp operation.
  GDALWarpOperation oOperation;
  oOperation.Initialize( psWarpOptions );
  oOperation.ChunkAndWarpImage( 0, 0, GDALGetRasterXSize( hDstDS ),
                                GDALGetRasterYSize( hDstDS ) );
  GDALDestroyWarpOptions( psWarpOptions );

  GDALClose( hSrcDS );
  GDALClose( hDstDS );
}
Exemplo n.º 9
0
/** Apply a vertical shift grid to a source (DEM typically) dataset.
 * 
 * hGridDataset will typically use WGS84 as horizontal datum (but this is
 * not a requirement) and its values are the values to add to go from geoid
 * elevations to WGS84 ellipsoidal heights.
 * 
 * hGridDataset will be on-the-fly reprojected and resampled to the projection
 * and resolution of hSrcDataset, using bilinear resampling by default.
 * 
 * Both hSrcDataset and hGridDataset must be single band datasets, and have
 * a valid geotransform and projection.
 *
 * On success, a reference will be taken on hSrcDataset and hGridDataset.
 * Reference counting semantics on the source and grid datasets should be
 * honoured. That is, don't just GDALClose() it, unless it was opened with
 * GDALOpenShared(), but rather use GDALReleaseDataset() if wanting to
 * immediately release the reference(s) and make the returned dataset the
 * owner of them.
 *
 * Valid use cases:
 * 
 * \code
 * hSrcDataset = GDALOpen(...)
 * hGridDataset = GDALOpen(...)
 * hDstDataset = GDALApplyVerticalShiftGrid(hSrcDataset, hGridDataset, ...)
 * GDALReleaseDataset(hSrcDataset);
 * GDALReleaseDataset(hGridDataset);
 * if( hDstDataset )
 * {
 *     // Do things with hDstDataset 
 *     GDALClose(hDstDataset) // will close hSrcDataset and hGridDataset
 * }
 * \endcode

 *
 * @param hSrcDataset source (DEM) dataset. Must not be NULL.
 * @param hGridDataset vertical grid shift dataset. Must not be NULL.
 * @param bInverse if set to FALSE, hGridDataset values will be added to
 *                 hSrcDataset. If set to TRUE, they will be subtracted.
 * @param dfSrcUnitToMeter the factor to convert values from hSrcDataset to
 *                         meters (1.0 if source values are in meter).
 * @param dfDstUnitToMeter the factor to convert shifted values from meter
 *                          (1.0 if output values must be in meter).
 * @param papszOptions list of options, or NULL. Supported options are:
 * <ul>
 * <li>RESAMPLING=NEAREST/BILINEAR/CUBIC. Defaults to BILINEAR.</li>
 * <li>MAX_ERROR=val. Maximum error measured in input pixels that is allowed in
 * approximating the transformation (0.0 for exact calculations). Defaults
 * to 0.125</li>
 * <li>DATATYPE=Byte/UInt16/Int16/Float32/Float64. Output data type. If not
 * specified will be the same as the one of hSrcDataset.
 * <li>ERROR_ON_MISSING_VERT_SHIFT=YES/NO. Whether a missing/nodata value in
 * hGridDataset should cause I/O requests to fail. Default is NO (in which case
 * 0 will be used)
 * <li>SRC_SRS=srs_def. Override projection on hSrcDataset;
 * </ul>
 *
 * @return a new dataset corresponding to hSrcDataset adjusted with
 * hGridDataset, or NULL. If not NULL, it must be closed with GDALClose().
 *
 * @since GDAL 2.2
 */
GDALDatasetH GDALApplyVerticalShiftGrid( GDALDatasetH hSrcDataset,
                                         GDALDatasetH hGridDataset,
                                         int bInverse,
                                         double dfSrcUnitToMeter,
                                         double dfDstUnitToMeter,
                                         const char* const* papszOptions )
{
    VALIDATE_POINTER1( hSrcDataset, "GDALApplyVerticalShiftGrid", nullptr );
    VALIDATE_POINTER1( hGridDataset, "GDALApplyVerticalShiftGrid", nullptr );

    double adfSrcGT[6];
    if( GDALGetGeoTransform(hSrcDataset, adfSrcGT) != CE_None )
    {
        CPLError(CE_Failure, CPLE_NotSupported,
                 "Source dataset has no geotransform.");
        return nullptr;
    }
    const char* pszSrcProjection = CSLFetchNameValueDef(papszOptions,
                                            "SRC_SRS",
                                            GDALGetProjectionRef(hSrcDataset));
    if( pszSrcProjection == nullptr || pszSrcProjection[0] == '\0' )
    {
        CPLError(CE_Failure, CPLE_NotSupported,
                 "Source dataset has no projection.");
        return nullptr;
    }
    if(  GDALGetRasterCount(hSrcDataset) != 1 )
    {
        CPLError(CE_Failure, CPLE_NotSupported,
                 "Only single band source dataset is supported.");
        return nullptr;
    }

    double adfGridGT[6];
    if( GDALGetGeoTransform(hGridDataset, adfGridGT) != CE_None )
    {
        CPLError(CE_Failure, CPLE_NotSupported,
                 "Grid dataset has no geotransform.");
        return nullptr;
    }
    const char* pszGridProjection = GDALGetProjectionRef(hGridDataset);
    if( pszGridProjection == nullptr || pszGridProjection[0] == '\0' )
    {
        CPLError(CE_Failure, CPLE_NotSupported,
                 "Grid dataset has no projection.");
        return nullptr;
    }
    if(  GDALGetRasterCount(hGridDataset) != 1 )
    {
        CPLError(CE_Failure, CPLE_NotSupported,
                 "Only single band grid dataset is supported.");
        return nullptr;
    }

    GDALDataType eDT = GDALGetRasterDataType(GDALGetRasterBand(hSrcDataset,1));
    const char* pszDataType = CSLFetchNameValue(papszOptions, "DATATYPE");
    if( pszDataType )
        eDT = GDALGetDataTypeByName(pszDataType);
    if( eDT == GDT_Unknown )
    {
        CPLError(CE_Failure, CPLE_NotSupported,
                 "Invalid DATATYPE=%s", pszDataType);
        return nullptr;
    }

    const int nSrcXSize = GDALGetRasterXSize(hSrcDataset);
    const int nSrcYSize = GDALGetRasterYSize(hSrcDataset);

    OGRSpatialReference oSRS;
    CPLString osSrcProjection(pszSrcProjection);
    oSRS.SetFromUserInput(osSrcProjection);
    if( oSRS.IsCompound() )
    {
        OGR_SRSNode* poNode = oSRS.GetRoot()->GetChild(1);
        if( poNode != nullptr )
        {
            char* pszWKT = nullptr;
            poNode->exportToWkt(&pszWKT);
            osSrcProjection = pszWKT;
            CPLFree(pszWKT);
        }
    }

    void* hTransform = GDALCreateGenImgProjTransformer3( pszGridProjection,
                                                         adfGridGT,
                                                         osSrcProjection,
                                                         adfSrcGT );
    if( hTransform == nullptr )
        return nullptr;
    GDALWarpOptions* psWO = GDALCreateWarpOptions();
    psWO->hSrcDS = hGridDataset;
    psWO->eResampleAlg = GRA_Bilinear;
    const char* pszResampling = CSLFetchNameValue(papszOptions, "RESAMPLING");
    if( pszResampling )
    {
        if( EQUAL(pszResampling, "NEAREST") )
            psWO->eResampleAlg = GRA_NearestNeighbour;
        else if( EQUAL(pszResampling, "BILINEAR") )
            psWO->eResampleAlg = GRA_Bilinear;
        else if( EQUAL(pszResampling, "CUBIC") )
            psWO->eResampleAlg = GRA_Cubic;
    }
    psWO->eWorkingDataType = GDT_Float32;
    int bHasNoData = FALSE;
    const double dfSrcNoData = GDALGetRasterNoDataValue(
        GDALGetRasterBand(hGridDataset, 1), &bHasNoData );
    if( bHasNoData )
    {
        psWO->padfSrcNoDataReal =
                static_cast<double*>(CPLMalloc(sizeof(double)));
        psWO->padfSrcNoDataReal[0] = dfSrcNoData;
    }

    psWO->padfDstNoDataReal = static_cast<double*>(CPLMalloc(sizeof(double)));
    const bool bErrorOnMissingShift = CPLFetchBool( papszOptions,
                                              "ERROR_ON_MISSING_VERT_SHIFT",
                                              false );
    psWO->padfDstNoDataReal[0] = 
        (bErrorOnMissingShift) ? -std::numeric_limits<float>::infinity() : 0.0;
    psWO->papszWarpOptions = CSLSetNameValue(psWO->papszWarpOptions,
                                                 "INIT_DEST",
                                                 "NO_DATA");

    psWO->pfnTransformer = GDALGenImgProjTransform;
    psWO->pTransformerArg = hTransform;
    const double dfMaxError = CPLAtof(CSLFetchNameValueDef(papszOptions,
                                                           "MAX_ERROR",
                                                           "0.125"));
    if( dfMaxError > 0.0 )
    {
        psWO->pTransformerArg =
            GDALCreateApproxTransformer( psWO->pfnTransformer,
                                         psWO->pTransformerArg,
                                         dfMaxError );
        psWO->pfnTransformer = GDALApproxTransform;
        GDALApproxTransformerOwnsSubtransformer(psWO->pTransformerArg, TRUE);
    }
    psWO->nBandCount = 1;
    psWO->panSrcBands = static_cast<int *>(CPLMalloc(sizeof(int)));
    psWO->panSrcBands[0] = 1;
    psWO->panDstBands = static_cast<int *>(CPLMalloc(sizeof(int)));
    psWO->panDstBands[0] = 1;

    VRTWarpedDataset* poReprojectedGrid =
                new VRTWarpedDataset(nSrcXSize, nSrcYSize);
    // This takes a reference on hGridDataset
    CPLErr eErr = poReprojectedGrid->Initialize(psWO);
    CPLAssert(eErr == CE_None);
    CPL_IGNORE_RET_VAL(eErr);
    GDALDestroyWarpOptions(psWO);
    poReprojectedGrid->SetGeoTransform(adfSrcGT);
    poReprojectedGrid->AddBand(GDT_Float32, nullptr);

    GDALApplyVSGDataset* poOutDS = new GDALApplyVSGDataset(
        reinterpret_cast<GDALDataset*>(hSrcDataset),
        poReprojectedGrid,
        eDT,
        CPL_TO_BOOL(bInverse),
        dfSrcUnitToMeter,
        dfDstUnitToMeter,
        // Undocumented option. For testing only
        atoi(CSLFetchNameValueDef(papszOptions, "BLOCKSIZE", "256")) );

    poReprojectedGrid->ReleaseRef();

    if( !poOutDS->IsInitOK() )
    {
        delete poOutDS;
        return nullptr;
    }
    poOutDS->SetDescription( GDALGetDescription( hSrcDataset ) );
    return reinterpret_cast<GDALDatasetH>(poOutDS);
}
Exemplo n.º 10
0
/* Matlab Gateway routine */
void mexFunction(int nlhs, mxArray *plhs[], int nrhs, const mxArray *prhs[]) {
	int	nXYSize;
	double	adfGeoTransform[6] = {0,1,0,0,0,1}, adfDstGeoTransform[6];
	char	*pszSRS_WKT = NULL;
	char	**papszWarpOptions = NULL;
	GDALDatasetH	hSrcDS, hDstDS;
	GDALDriverH	hDriver;
	GDALRasterBandH hBand;
	GDALColorTableH	hColorTable = NULL;
	OGRSpatialReference oSrcSRS, oDstSRS; 
	GDALResampleAlg	interpMethod = GRA_NearestNeighbour;
	GDALTransformerFunc pfnTransformer = NULL;
	CPLErr		eErr;
	GDAL_GCP	*pasGCPs = NULL;
	static int runed_once = FALSE;	/* It will be set to true if reaches end of main */

	const int *dim_array;
	int	nx, ny, i, j, m, n, c, nBands, registration = 1;
	int	n_dims, typeCLASS, nBytes;
	char	*pszSrcSRS = NULL, *pszSrcWKT = NULL;
	char	*pszDstSRS = NULL, *pszDstWKT = NULL;
	void	*in_data;
	mxArray	*mx_ptr;

	unsigned char *tmpByte, *outByte;
	unsigned short int *tmpUI16, *outUI16;
	short int *tmpI16, *outI16;
	int	*tmpI32, *outI32;
	int	nPixels=0, nLines=0, nForceWidth=0, nForceHeight=0;
	int	nGCPCount = 0, nOrder = 0;
	unsigned int *tmpUI32, *outUI32;
	float	*tmpF32, *outF32;
	double	*tmpF64, *outF64, *ptr_d;
	double	dfMinX=0, dfMaxX=0, dfMinY=0, dfMaxY=0, dfResX=0, dfResY=0;
	double	adfExtent[4];
	double	dfXRes=0.0, dfYRes=0.0;
	double	dfWarpMemoryLimit = 0.0;
	double	*pdfDstNodata = NULL; 
	char	**papszMetadataOptions = NULL;
	char	*tmp, *txt;


	if (nrhs == 2 && mxIsStruct(prhs[1])) {
		mx_ptr = mxGetField(prhs[1], 0, "ULx");
		if (mx_ptr == NULL)
			mexErrMsgTxt("GDALWARP 'ULx' field not provided");
		ptr_d = mxGetPr(mx_ptr);
		adfGeoTransform[0] = *ptr_d;

		mx_ptr = mxGetField(prhs[1], 0, "Xinc");
		if (mx_ptr == NULL)
			mexErrMsgTxt("GDALWARP 'Xinc' field not provided");
		ptr_d = mxGetPr(mx_ptr);
		adfGeoTransform[1] = *ptr_d;

		mx_ptr = mxGetField(prhs[1], 0, "ULy");
		if (mx_ptr == NULL)
			mexErrMsgTxt("GDALWARP 'ULy' field not provided");
		ptr_d = mxGetPr(mx_ptr);
		adfGeoTransform[3] = *ptr_d;

		mx_ptr = mxGetField(prhs[1], 0, "Yinc");
		if (mx_ptr == NULL)
			mexErrMsgTxt("GDALWARP 'Yinc' field not provided");
		ptr_d = mxGetPr(mx_ptr);
		adfGeoTransform[5] = -*ptr_d;

		/* -------- See for resolution requests ------------ */
		mx_ptr = mxGetField(prhs[1], 0, "t_size");
		if (mx_ptr != NULL) {
			ptr_d = mxGetPr(mx_ptr);
			if (mxGetN(mx_ptr) == 2) {
				nForceWidth  = (int)ptr_d[0];
				nForceHeight = (int)ptr_d[1];
			}
			else if (mxGetN(mx_ptr) == 1) {	/* pick max(nrow,ncol) */
				if (mxGetM(prhs[0]) > getNK(prhs[0],1))
					nForceHeight = mxGetM(prhs[0]);
				else
					nForceWidth  = getNK(prhs[0], 1);
			}
			else {
				nForceHeight = mxGetM(prhs[0]);
				nForceWidth  = getNK(prhs[0], 1);
			}
		}

		mx_ptr = mxGetField(prhs[1], 0, "t_res");
		if (mx_ptr != NULL) {
			ptr_d = mxGetPr(mx_ptr);
			if (mxGetN(mx_ptr) == 2) {
				dfXRes = ptr_d[0];
				dfYRes = ptr_d[1];
			}
			else if (mxGetN(mx_ptr) == 1) {
				dfXRes = dfYRes = ptr_d[0];
			}
		}
		/* -------------------------------------------------- */

		/* -------- Change Warping cache size?  ------------ */
		mx_ptr = mxGetField(prhs[1], 0, "wm");
		if (mx_ptr != NULL) {
			ptr_d = mxGetPr(mx_ptr);
			dfWarpMemoryLimit = *ptr_d * 1024 * 1024;
		}
		/* -------------------------------------------------- */

		/* -------- Have a nodata value order? -------------- */
		mx_ptr = mxGetField(prhs[1], 0, "nodata");
		if (mx_ptr != NULL) {
			pdfDstNodata = mxGetPr(mx_ptr);
		}
		/* -------------------------------------------------- */

		/* -------- See for projection stuff ---------------- */
		mx_ptr = mxGetField(prhs[1], 0, "SrcProjSRS");
		if (mx_ptr != NULL)
			pszSrcSRS = (char *)mxArrayToString(mx_ptr);

		mx_ptr = mxGetField(prhs[1], 0, "SrcProjWKT");
		if (mx_ptr != NULL)
			pszSrcWKT = (char *)mxArrayToString(mx_ptr);

		mx_ptr = mxGetField(prhs[1], 0, "DstProjSRS");
		if (mx_ptr != NULL)
			pszDstSRS = (char *)mxArrayToString(mx_ptr);

		mx_ptr = mxGetField(prhs[1], 0, "DstProjWKT");
		if (mx_ptr != NULL)
			pszDstWKT = (char *)mxArrayToString(mx_ptr);
		/* -------------------------------------------------- */

		/* -------- Do we have GCPs? ----------------------- */
		mx_ptr = mxGetField(prhs[1], 0, "gcp");
		if (mx_ptr != NULL) {
			nGCPCount = mxGetM(mx_ptr);
			if (mxGetN(mx_ptr) != 4)
				mexErrMsgTxt("GDALWARP: GCPs must be a Mx4 array");
			ptr_d = mxGetPr(mx_ptr);
			pasGCPs = (GDAL_GCP *) mxCalloc( nGCPCount, sizeof(GDAL_GCP) );
			GDALInitGCPs( 1, pasGCPs + nGCPCount - 1 );
			for (i = 0; i < nGCPCount; i++) {
				pasGCPs[i].dfGCPPixel = ptr_d[i];
				pasGCPs[i].dfGCPLine = ptr_d[i+nGCPCount];
				pasGCPs[i].dfGCPX = ptr_d[i+2*nGCPCount];
				pasGCPs[i].dfGCPY = ptr_d[i+3*nGCPCount];
				pasGCPs[i].dfGCPZ = 0;
			}
		}
			/* ---- Have we an order request? --- */
		mx_ptr = mxGetField(prhs[1], 0, "order");
		if (mx_ptr != NULL) {
			ptr_d = mxGetPr(mx_ptr);
			nOrder = (int)*ptr_d;
			if (nOrder != -1 || nOrder != 0 || nOrder != 1 || nOrder != 2 || nOrder != 3)
				nOrder = 0;
		}
		/* -------------------------------------------------- */

		mx_ptr = mxGetField(prhs[1], 0, "ResampleAlg");
		if (mx_ptr != NULL) {
			txt = (char *)mxArrayToString(mx_ptr);
			if (!strcmp(txt,"nearest"))
				interpMethod = GRA_NearestNeighbour;
			else if (!strcmp(txt,"bilinear"))
				interpMethod = GRA_Bilinear;
			else if (!strcmp(txt,"cubic") || !strcmp(txt,"bicubic"))
				interpMethod = GRA_Cubic;
			else if (!strcmp(txt,"spline"))
				interpMethod = GRA_CubicSpline;
		}

		/* If grid limits were in grid registration, convert them to pixel reg */
		mx_ptr = mxGetField(prhs[1], 0, "Reg");
		if (mx_ptr != NULL) {
			ptr_d = mxGetPr(mx_ptr);
			registration = (int)ptr_d[0];
		}

		if (registration == 0) {
			adfGeoTransform[0] -= adfGeoTransform[1]/2.;
			adfGeoTransform[3] -= adfGeoTransform[5]/2.;
		}
	}
	else {
		mexPrintf("Usage: B = gdalwarp_mex(IMG,HDR_STRUCT)\n\n");
		mexPrintf("\tIMG -> is a Mx2 or Mx3 array with an grid/image data to reproject\n");
		mexPrintf("\tHDR_STRUCT -> is a structure with the following fields:\n");
		mexPrintf("\t\t'ULx' X coordinate of the uper left corner\n");
		mexPrintf("\t\t'ULy' Y coordinate of the uper left corner\n");
		mexPrintf("\t\t'Xinc' distance between columns in target grid/image coordinates\n");
		mexPrintf("\t\t'Yinc' distance between rows in target grid/image coordinates\n");
		mexPrintf("\t\t'SrcProjSRS', 'SrcProjWKT' -> Source projection string\n");
		mexPrintf("\t\t'DstProjSRS', 'DstProjWKT' -> Target projection string\n");
		mexPrintf("\t\t\tSRS stands for a string of the type used by proj4\n");
		mexPrintf("\t\t\tWKT stands for a string on the 'Well Known Text' format\n\n");
		mexPrintf("\t\t\tIf one of the Src or Dst fields is absent a GEOGRAPHIC WGS84 is assumed\n");
		mexPrintf("\nOPTIONS\n");
		mexPrintf("\t\t'gcp' a [Mx4] array with Ground Control Points\n");
		mexPrintf("\t\t't_size' a [width height] vector to set output file size in pixels\n");
		mexPrintf("\t\t't_res' a [xres yres] vector to set output file resolution (in target georeferenced units)\n");
		mexPrintf("\t\t'wm' amount of memory (in megabytes) that the warp API is allowed to use for caching\n");
		mexPrintf("\t\t'nodata' Set nodata values for output bands.\n");
		mexPrintf("\t\t'ResampleAlg' To set up the algorithm used during warp operation. Options are: \n");
		mexPrintf("\t\t\t'nearest' Use nearest neighbour resampling (default, fastest algorithm, worst interpolation quality).\n");
		mexPrintf("\t\t\t'bilinear' Use bilinear resampling.\n");
		mexPrintf("\t\t\t'cubic' Use cubic resampling.\n");
		mexPrintf("\t\t\t'spline' Use cubic spline resampling.\n\n");

		if (!runed_once)		/* Do next call only at first time this MEX is loaded */
			GDALAllRegister();

        	mexPrintf( "The following format drivers are configured and support Create() method:\n" );
        	for( i = 0; i < GDALGetDriverCount(); i++ ) {
			hDriver = GDALGetDriver(i);
			if( GDALGetMetadataItem( hDriver, GDAL_DCAP_CREATE, NULL ) != NULL)
				mexPrintf("%s: %s\n", GDALGetDriverShortName(hDriver), 
							GDALGetDriverLongName(hDriver));
		}
		return;
	}

	n_dims = mxGetNumberOfDimensions(prhs[0]);
	dim_array=mxGetDimensions(prhs[0]);
	ny = dim_array[0];
	nx = dim_array[1];
	nBands = dim_array[2];

	if (n_dims == 2)	/* Otherwise it would stay undefined */
		nBands = 1;

	/* Find out in which data type was given the input array */
	if (mxIsUint8(prhs[0])) {
		typeCLASS = GDT_Byte;		nBytes = 1;
		outByte = (unsigned char *)mxMalloc (nx*ny * sizeof(unsigned char));
	}
	else if (mxIsUint16(prhs[0])) {
		typeCLASS = GDT_UInt16;		nBytes = 2;
		outUI16 = (unsigned short int *)mxMalloc (nx*ny * sizeof(short int));
	}
	else if (mxIsInt16(prhs[0])) {
		typeCLASS = GDT_Int16;		nBytes = 2;
		outI16 = (short int *)mxMalloc (nx*ny * sizeof(short int));
	}
	else if (mxIsInt32(prhs[0])) {
		typeCLASS = GDT_Int32;		nBytes = 4;
		outI32 = (int *)mxMalloc (nx*ny * sizeof(int));
	}
	else if (mxIsUint32(prhs[0])) {
		typeCLASS = GDT_UInt32;		nBytes = 4;
		outUI32 = (unsigned int *)mxMalloc (nx*ny * sizeof(int));
	}
	else if (mxIsSingle(prhs[0])) {
		typeCLASS = GDT_Float32;	nBytes = 4;
		outF32 = (float *)mxMalloc (nx*ny * sizeof(float));
	}
	else if (mxIsDouble(prhs[0])) {
		typeCLASS = GDT_Float64;	nBytes = 8;
		outF64 = (double *)mxMalloc (nx*ny * sizeof(double));
	}
	else
		mexErrMsgTxt("GDALWARP Unknown input data class!");


	in_data = (void *)mxGetData(prhs[0]);

	if (!runed_once)		/* Do next call only at first time this MEX is loaded */
		GDALAllRegister();

	hDriver = GDALGetDriverByName( "MEM" ); 

	hSrcDS = GDALCreate( hDriver, "mem", nx, ny, nBands, (GDALDataType)typeCLASS, NULL );
	if (hSrcDS == NULL) {
		mexPrintf ("GDALOpen failed - %d\n%s\n", CPLGetLastErrorNo(), CPLGetLastErrorMsg());
		return;
	}
	GDALSetGeoTransform( hSrcDS, adfGeoTransform ); 

	/* ---------- Set the Source projection ---------------------------- */
	/* If it was not provided assume it is Geog WGS84 */
	if (pszSrcSRS == NULL && pszSrcWKT == NULL)
		oSrcSRS.SetWellKnownGeogCS( "WGS84" ); 
	else if (pszSrcWKT != NULL)
		oSrcSRS.importFromWkt( &pszSrcWKT );

	else {
		if( oSrcSRS.SetFromUserInput( pszSrcSRS ) != OGRERR_NONE )
			mexErrMsgTxt("GDAL_WARP_MEX: Translating source SRS failed.");
	}
	if (pszSrcWKT == NULL)
		oSrcSRS.exportToWkt( &pszSrcWKT );

	GDALSetProjection( hSrcDS, pszSrcWKT );	
	//pszSrcWKT = (char *)GDALGetProjectionRef( hSrcDS );
	CPLAssert( pszSrcWKT != NULL && strlen(pszSrcWKT) > 0 );
	/* ------------------------------------------------------------------ */


	/* -------------- Copy input data into the hSrcDS dataset ----------- */
	for (i = 1; i <= nBands; i++) {
		hBand = GDALGetRasterBand( hSrcDS, i ); 
		nXYSize = (i-1)*nx*ny;
		switch( typeCLASS ) {
			case GDT_Byte:
			 	tmpByte = (unsigned char *)in_data;	
				for (m = ny-1, c = 0; m >= 0; m--) for (n = 0; n < nx; n++)
					outByte[c++] = tmpByte[m + n*ny + nXYSize];
				GDALRasterIO( hBand, GF_Write, 0, 0, nx, ny,outByte, nx, ny, (GDALDataType)typeCLASS, 0, 0 );
				break;
			case GDT_UInt16:
			 	tmpUI16 = (unsigned short int *)in_data;	
				for (m = ny-1, c = 0; m >= 0; m--) for (n = 0; n < nx; n++)
					outUI16[c++] = tmpUI16[m + n*ny + nXYSize];
				GDALRasterIO( hBand, GF_Write, 0, 0, nx, ny,outUI16, nx, ny, (GDALDataType)typeCLASS, 0, 0 );
				break;
			case GDT_Int16:
			 	tmpI16 = (short int *)in_data;	
				for (m = ny-1, c = 0; m >= 0; m--) for (n = 0; n < nx; n++)
					outI16[c++] = tmpI16[m + n*ny + nXYSize];
				GDALRasterIO( hBand, GF_Write, 0, 0, nx, ny,outI16, nx, ny, (GDALDataType)typeCLASS, 0, 0 );
				break;
			case GDT_UInt32:
			 	tmpUI32 = (unsigned int *)in_data;	
				for (m = ny-1, c = 0; m >= 0; m--) for (n = 0; n < nx; n++)
					outUI32[c++] = tmpUI32[m + n*ny + nXYSize];
				GDALRasterIO( hBand, GF_Write, 0, 0, nx, ny,outUI32, nx, ny, (GDALDataType)typeCLASS, 0, 0 );
				break;
			case GDT_Int32:
			 	tmpI32 = (int *)in_data;	
				for (m = ny-1, c = 0; m >= 0; m--) for (n = 0; n < nx; n++)
					outI32[c++] = tmpI32[m + n*ny + nXYSize];
				GDALRasterIO( hBand, GF_Write, 0, 0, nx, ny,outI32, nx, ny, (GDALDataType)typeCLASS, 0, 0 );
				break;
			case GDT_Float32:
			 	tmpF32 = (float *)in_data;	
				for (m = ny-1, c = 0; m >= 0; m--) for (n = 0; n < nx; n++)
					outF32[c++] = tmpF32[m + n*ny + nXYSize];
				GDALRasterIO( hBand, GF_Write, 0, 0, nx, ny,outF32, nx, ny, (GDALDataType)typeCLASS, 0, 0 );
				break;
			case GDT_Float64:
			 	tmpF64 = (double *)in_data;	
				for (m = ny-1, c = 0; m >= 0; m--) for (n = 0; n < nx; n++)
					outF64[c++] = tmpF64[m + n*ny + nXYSize];
				GDALRasterIO( hBand, GF_Write, 0, 0, nx, ny,outF64, nx, ny, (GDALDataType)typeCLASS, 0, 0 );
				break;
		}
	}

	/* ---------- Set up the Target coordinate system ------------------- */
	/* If it was not provided assume it is Geog WGS84 */
	CPLErrorReset();
	if (pszDstSRS == NULL && pszDstWKT == NULL)
		oDstSRS.SetWellKnownGeogCS( "WGS84" ); 
	else if (pszDstWKT != NULL)
		oDstSRS.importFromWkt( &pszDstWKT );
	else {
		if( oDstSRS.SetFromUserInput( pszDstSRS ) != OGRERR_NONE )
			mexErrMsgTxt("GDAL_WARP_MEX: Translating target SRS failed.");
	}
	if (pszDstWKT == NULL)
		oDstSRS.exportToWkt( &pszDstWKT );
	/* ------------------------------------------------------------------ */

	if ( nGCPCount != 0 ) {
		if (GDALSetGCPs(hSrcDS, nGCPCount, pasGCPs, "") != CE_None)
			mexPrintf("GDALWARP WARNING: writing GCPs failed.\n");
	}

	/* Create a transformer that maps from source pixel/line coordinates
	   to destination georeferenced coordinates (not destination pixel line) 
	   We do that by omitting the destination dataset handle (setting it to NULL). */

	void *hTransformArg;

	hTransformArg = GDALCreateGenImgProjTransformer(hSrcDS, pszSrcWKT, NULL, pszDstWKT, 
											nGCPCount == 0 ? FALSE : TRUE, 0, nOrder);
	if( hTransformArg == NULL )
		mexErrMsgTxt("GDALTRANSFORM: Generating transformer failed.");

	GDALTransformerInfo *psInfo = (GDALTransformerInfo*)hTransformArg;

	/* -------------------------------------------------------------------------- */
	/*      Get approximate output georeferenced bounds and resolution for file
	/* -------------------------------------------------------------------------- */
	if (GDALSuggestedWarpOutput2(hSrcDS, GDALGenImgProjTransform, hTransformArg, 
	                             adfDstGeoTransform, &nPixels, &nLines, adfExtent,
	                             0) != CE_None ) {
	    GDALClose(hSrcDS);
		mexErrMsgTxt("GDALWARP: GDALSuggestedWarpOutput2 failed.");
	}

	if (CPLGetConfigOption( "CHECK_WITH_INVERT_PROJ", NULL ) == NULL) {
		double MinX = adfExtent[0];
		double MaxX = adfExtent[2];
		double MaxY = adfExtent[3];
		double MinY = adfExtent[1];
		int bSuccess = TRUE;
            
		/* Check that the the edges of the target image are in the validity area */
		/* of the target projection */
#define N_STEPS 20
		for (i = 0; i <= N_STEPS && bSuccess; i++) {
			for (j = 0; j <= N_STEPS && bSuccess; j++) {
				double dfRatioI = i * 1.0 / N_STEPS;
				double dfRatioJ = j * 1.0 / N_STEPS;
				double expected_x = (1 - dfRatioI) * MinX + dfRatioI * MaxX;
				double expected_y = (1 - dfRatioJ) * MinY + dfRatioJ * MaxY;
				double x = expected_x;
				double y = expected_y;
				double z = 0;
				/* Target SRS coordinates to source image pixel coordinates */
				if (!psInfo->pfnTransform(hTransformArg, TRUE, 1, &x, &y, &z, &bSuccess) || !bSuccess)
					bSuccess = FALSE;
				/* Source image pixel coordinates to target SRS coordinates */
				if (!psInfo->pfnTransform(hTransformArg, FALSE, 1, &x, &y, &z, &bSuccess) || !bSuccess)
					bSuccess = FALSE;
				if (fabs(x - expected_x) > (MaxX - MinX) / nPixels ||
					fabs(y - expected_y) > (MaxY - MinY) / nLines)
					bSuccess = FALSE;
			}
		}
            
		/* If not, retry with CHECK_WITH_INVERT_PROJ=TRUE that forces ogrct.cpp */
		/* to check the consistency of each requested projection result with the */
		/* invert projection */
		if (!bSuccess) {
			CPLSetConfigOption( "CHECK_WITH_INVERT_PROJ", "TRUE" );
			CPLDebug("WARP", "Recompute out extent with CHECK_WITH_INVERT_PROJ=TRUE");

			if (GDALSuggestedWarpOutput2(hSrcDS, GDALGenImgProjTransform, hTransformArg, 
			                             adfDstGeoTransform, &nPixels, &nLines, adfExtent,
			                              0) != CE_None ) {
			    GDALClose(hSrcDS);
				mexErrMsgTxt("GDALWARO: GDALSuggestedWarpOutput2 failed.");
			}
		}
	}

	/* -------------------------------------------------------------------- */
	/*      Expand the working bounds to include this region, ensure the    */
	/*      working resolution is no more than this resolution.             */
	/* -------------------------------------------------------------------- */
	if( dfMaxX == 0.0 && dfMinX == 0.0 ) {
		dfMinX = adfExtent[0];
		dfMaxX = adfExtent[2];
		dfMaxY = adfExtent[3];
		dfMinY = adfExtent[1];
		dfResX = adfDstGeoTransform[1];
		dfResY = ABS(adfDstGeoTransform[5]);
	}
	else {
		dfMinX = MIN(dfMinX,adfExtent[0]);
		dfMaxX = MAX(dfMaxX,adfExtent[2]);
		dfMaxY = MAX(dfMaxY,adfExtent[3]);
		dfMinY = MIN(dfMinY,adfExtent[1]);
		dfResX = MIN(dfResX,adfDstGeoTransform[1]);
		dfResY = MIN(dfResY,ABS(adfDstGeoTransform[5]));
	}

	GDALDestroyGenImgProjTransformer( hTransformArg );

	/* -------------------------------------------------------------------- */
	/*      Turn the suggested region into a geotransform and suggested     */
	/*      number of pixels and lines.                                     */
	/* -------------------------------------------------------------------- */

	adfDstGeoTransform[0] = dfMinX;
	adfDstGeoTransform[1] = dfResX;
	adfDstGeoTransform[2] = 0.0;
	adfDstGeoTransform[3] = dfMaxY;
	adfDstGeoTransform[4] = 0.0;
	adfDstGeoTransform[5] = -1 * dfResY;

	nPixels = (int) ((dfMaxX - dfMinX) / dfResX + 0.5);
	nLines  = (int) ((dfMaxY - dfMinY) / dfResY + 0.5);

	/* -------------------------------------------------------------------- */
	/*      Did the user override some parameters?                          */
	/* -------------------------------------------------------------------- */
	if( dfXRes != 0.0 && dfYRes != 0.0 ) {
		dfMinX = adfDstGeoTransform[0];
		dfMaxX = adfDstGeoTransform[0] + adfDstGeoTransform[1] * nPixels;
		dfMaxY = adfDstGeoTransform[3];
		dfMinY = adfDstGeoTransform[3] + adfDstGeoTransform[5] * nLines;

		nPixels = (int) ((dfMaxX - dfMinX + (dfXRes/2.0)) / dfXRes);
		nLines = (int) ((dfMaxY - dfMinY + (dfYRes/2.0)) / dfYRes);
		adfDstGeoTransform[0] = dfMinX;
		adfDstGeoTransform[3] = dfMaxY;
		adfDstGeoTransform[1] = dfXRes;
		adfDstGeoTransform[5] = -dfYRes;
	}
	else if( nForceWidth != 0 && nForceHeight != 0 ) {
		dfXRes = (dfMaxX - dfMinX) / nForceWidth;
		dfYRes = (dfMaxY - dfMinY) / nForceHeight;

		adfDstGeoTransform[0] = dfMinX;
		adfDstGeoTransform[3] = dfMaxY;
		adfDstGeoTransform[1] = dfXRes;
		adfDstGeoTransform[5] = -dfYRes;

		nPixels = nForceWidth;
		nLines = nForceHeight;
	}
	else if( nForceWidth != 0) {
		dfXRes = (dfMaxX - dfMinX) / nForceWidth;
		dfYRes = dfXRes;

		adfDstGeoTransform[0] = dfMinX;
		adfDstGeoTransform[3] = dfMaxY;
		adfDstGeoTransform[1] = dfXRes;
		adfDstGeoTransform[5] = -dfYRes;

		nPixels = nForceWidth;
		nLines = (int) ((dfMaxY - dfMinY + (dfYRes/2.0)) / dfYRes);
	}
	else if( nForceHeight != 0) {
		dfYRes = (dfMaxY - dfMinY) / nForceHeight;
		dfXRes = dfYRes;

		adfDstGeoTransform[0] = dfMinX;
		adfDstGeoTransform[3] = dfMaxY;
		adfDstGeoTransform[1] = dfXRes;
		adfDstGeoTransform[5] = -dfYRes;

		nPixels = (int) ((dfMaxX - dfMinX + (dfXRes/2.0)) / dfXRes);
		nLines = nForceHeight;
	}

	/* --------------------- Create the output --------------------------- */
	hDstDS = GDALCreate( hDriver, "mem", nPixels, nLines, 
			GDALGetRasterCount(hSrcDS), (GDALDataType)typeCLASS, NULL );
    
	CPLAssert( hDstDS != NULL );

	/* -------------- Write out the projection definition ---------------- */
	GDALSetProjection( hDstDS, pszDstWKT );
	GDALSetGeoTransform( hDstDS, adfDstGeoTransform );

	/* --------------------- Setup warp options -------------------------- */
	GDALWarpOptions *psWO = GDALCreateWarpOptions();

	psWO->hSrcDS = hSrcDS;
	psWO->hDstDS = hDstDS;

	psWO->nBandCount = nBands;
	psWO->panSrcBands = (int *) CPLMalloc(psWO->nBandCount * sizeof(int) );
	psWO->panDstBands = (int *) CPLMalloc(psWO->nBandCount * sizeof(int) );
	for( i = 0; i < nBands; i++ ) {
		psWO->panSrcBands[i] = i+1;
		psWO->panDstBands[i] = i+1;
	}

	if( dfWarpMemoryLimit != 0.0 )
		psWO->dfWarpMemoryLimit = dfWarpMemoryLimit;

	/* --------------------- Setup the Resampling Algo ------------------- */
	psWO->eResampleAlg = interpMethod;


	/* --------------------- Setup NODATA options ------------------------ */
	papszWarpOptions = CSLSetNameValue(papszWarpOptions, "INIT_DEST", "NO_DATA" );

	if ( pdfDstNodata == NULL && (typeCLASS == GDT_Float32 || typeCLASS == GDT_Float64) ) {
		pdfDstNodata = (double *) mxCalloc((size_t)1, sizeof(double));
		*pdfDstNodata = mxGetNaN();
	}
	else if (pdfDstNodata != NULL) {
#define CLAMP(val,type,minval,maxval) \
    do { if (val < minval) { val = minval; } \
    else if (val > maxval) { val = maxval; } \
    else if (val != (type)val) { val = (type)(val + 0.5); } } \
    while(0)
		switch( typeCLASS ) {
			case GDT_Byte:
				CLAMP(pdfDstNodata[0], GByte, 0.0, 255.0);
				break;
			case GDT_UInt16:
				CLAMP(pdfDstNodata[0], GInt16, -32768.0, 32767.0);
				break;
			case GDT_Int16:
				CLAMP(pdfDstNodata[0], GUInt16, 0.0, 65535.0);
				break;
			case GDT_UInt32:
				CLAMP(pdfDstNodata[0], GInt32, -2147483648.0, 2147483647.0);
				break;
			case GDT_Int32:
				CLAMP(pdfDstNodata[0], GUInt32, 0.0, 4294967295.0);
				break;
			default:
				break;
		}
	}

	psWO->papszWarpOptions = CSLDuplicate(papszWarpOptions);

	if (pdfDstNodata != NULL) {
		psWO->padfDstNoDataReal = (double *) CPLMalloc(psWO->nBandCount*sizeof(double));
		psWO->padfDstNoDataImag = (double *) CPLMalloc(psWO->nBandCount*sizeof(double));
		for (i = 0; i < nBands; i++) {
                        psWO->padfDstNoDataReal[i] = pdfDstNodata[0];
                        psWO->padfDstNoDataImag[i] = 0.0;
			GDALSetRasterNoDataValue( GDALGetRasterBand(hDstDS, i+1), pdfDstNodata[0]);
		}
	}

	/* ------------ Establish reprojection transformer ------------------- */
	psWO->pTransformerArg = GDALCreateGenImgProjTransformer( hSrcDS, GDALGetProjectionRef(hSrcDS), 
							hDstDS, GDALGetProjectionRef(hDstDS), 
							nGCPCount == 0 ? FALSE : TRUE, 0.0, nOrder );
	psWO->pfnTransformer = GDALGenImgProjTransform;

	/* ----------- Initialize and execute the warp operation ------------- */
	GDALWarpOperation oOperation;

	oOperation.Initialize( psWO );
	eErr = oOperation.ChunkAndWarpImage( 0, 0, GDALGetRasterXSize( hDstDS ),
						GDALGetRasterYSize( hDstDS ) );
	CPLAssert( eErr == CE_None );

	GDALDestroyGenImgProjTransformer( psWO->pTransformerArg );
	GDALDestroyWarpOptions( psWO );
	GDALClose( hSrcDS );

	/* ------------ Free memory used to fill the hSrcDS dataset ---------- */
	switch( typeCLASS ) {
		case GDT_Byte:		mxFree((void *)outByte);	break;
		case GDT_UInt16:	mxFree((void *)outUI16);	break; 
		case GDT_Int16:		mxFree((void *)outI16);		break; 
		case GDT_UInt32:	mxFree((void *)outUI32);	break; 
		case GDT_Int32:		mxFree((void *)outI32);		break; 
		case GDT_Float32:	mxFree((void *)outF32);		break; 
		case GDT_Float64:	mxFree((void *)outF64);		break; 
	}

	int out_dims[3];
	out_dims[0] = nLines;
	out_dims[1] = nPixels;
	out_dims[2] = nBands;
	plhs[0] = mxCreateNumericArray (n_dims,out_dims,mxGetClassID(prhs[0]), mxREAL);
	tmp = (char *)mxCalloc(nPixels * nLines, nBytes);

	/* ------ Allocate memory to be used in filling the hDstDS dataset ---- */
	switch( typeCLASS ) {
		case GDT_Byte:
			outByte = (unsigned char *)mxGetData(plhs[0]);		break;
		case GDT_UInt16:
			outUI16 = (unsigned short int *)mxGetData(plhs[0]);	break;
		case GDT_Int16:
			outI16 = (short int *)mxGetData(plhs[0]);		break;
		case GDT_UInt32:
			outUI32 = (unsigned int *)mxGetData(plhs[0]);		break;
		case GDT_Int32:
			outI32 = (int *)mxGetData(plhs[0]);			break;
		case GDT_Float32:
			outF32 = (float *)mxGetData(plhs[0]);			break;
		case GDT_Float64:
			outF64 = (double *)mxGetData(plhs[0]);			break;
	}

	/* ----------- Copy the output hSrcDS dataset data into plhs  ---------- */
	for (i = 1; i <= nBands; i++) {
		hBand = GDALGetRasterBand( hDstDS, i ); 
		GDALRasterIO( hBand, GF_Read, 0, 0, nPixels, nLines, tmp, nPixels, nLines,
				(GDALDataType)typeCLASS, 0, 0 );
		nXYSize = (i-1) * nPixels * nLines;
		switch( typeCLASS ) {
			case GDT_Byte:
				for (m = nLines-1, c = 0; m >= 0; m--) for (n = 0; n < nPixels; n++)
					outByte[m + n*nLines + nXYSize] = tmp[c++];
				break;
			case GDT_UInt16:
				tmpUI16 = (GUInt16 *) tmp;
				for (m = nLines-1, c = 0; m >= 0; m--) for (n = 0; n < nPixels; n++)
					outUI16[m + n*nLines + nXYSize] = tmpUI16[c++];
				break;
			case GDT_Int16:
				tmpI16 = (GInt16 *) tmp;
				for (m = nLines-1, c = 0; m >= 0; m--) for (n = 0; n < nPixels; n++)
					outI16[m + n*nLines + nXYSize] = tmpI16[c++];
				break;
			case GDT_UInt32:
				tmpUI32 = (GUInt32 *) tmp;
				for (m = nLines-1, c = 0; m >= 0; m--) for (n = 0; n < nPixels; n++)
					outUI32[m + n*nLines + nXYSize] = tmpUI32[c++];
				break;
			case GDT_Int32:
				tmpI32 = (GInt32 *) tmp;
				for (m = nLines-1, c = 0; m >= 0; m--) for (n = 0; n < nPixels; n++)
					outI32[m + n*nLines + nXYSize] = tmpI32[c++];
				break;
			case GDT_Float32:
				tmpF32 = (float *) tmp;
				for (m = nLines-1, c = 0; m >= 0; m--) for (n = 0; n < nPixels; n++)
					outF32[m + n*nLines + nXYSize] = tmpF32[c++];
				break;
			case GDT_Float64:
				tmpF64 = (double *) tmp;
				for (m = nLines-1, c = 0; m >= 0; m--) for (n = 0; n < nPixels; n++)
					outF64[m + n*nLines + nXYSize] = tmpF64[c++];
				break;
		}
	}

	mxFree(tmp);
	if (nGCPCount) {
		GDALDeinitGCPs( nGCPCount, pasGCPs );	/* makes this mex crash in the next call - Is it still true??? */
		mxFree((void *) pasGCPs );
	}

	if (nlhs == 2)
		plhs[1] = populate_metadata_struct (hDstDS, 1);

	runed_once = TRUE;	/* Signals that next call won't need to call GDALAllRegister() again */

	/*GDALDestroyDriverManager();
	OGRFree(pszDstWKT);*/
	GDALClose( hDstDS );
	CSLDestroy( papszWarpOptions );
	if (pszDstWKT && strlen(pszDstWKT) > 1 ) OGRFree(pszDstWKT);	
	if (pszSrcWKT && strlen(pszSrcWKT) > 1 ) OGRFree(pszSrcWKT);
}
/**
* Sets the surface grids based on a ncep HRRR (surface only!) forecast.
* @param input The WindNinjaInputs for misc. info.
* @param airGrid The air temperature grid to be filled.
* @param cloudGrid The cloud cover grid to be filled.
* @param uGrid The u velocity grid to be filled.
* @param vGrid The v velocity grid to be filled.
* @param wGrid The w velocity grid to be filled (filled with zeros here?).
*/
void ncepHrrrSurfInitialization::setSurfaceGrids( WindNinjaInputs &input,
        AsciiGrid<double> &airGrid,
        AsciiGrid<double> &cloudGrid,
        AsciiGrid<double> &uGrid,
        AsciiGrid<double> &vGrid,
        AsciiGrid<double> &wGrid )
{
    int bandNum = -1;

    GDALDataset *srcDS;
    srcDS = (GDALDataset*)GDALOpenShared( input.forecastFilename.c_str(), GA_ReadOnly );

    if( srcDS == NULL ) {
        CPLDebug( "ncepHRRRSurfaceInitialization::identify()",
                "Bad forecast file" );
    }

    GDALRasterBand *poBand = srcDS->GetRasterBand( 49 );
    const char *gc;
    gc = poBand->GetMetadataItem( "GRIB_COMMENT" );
    std::string bandName( gc );

    //get time list
    std::vector<boost::local_time::local_date_time> timeList( getTimeList( input.ninjaTimeZone ) );

    //Search time list for our time to identify our band number for cloud/speed/dir
    //Right now, just one time step per file
    std::vector<int> bandList;
    for(unsigned int i = 0; i < timeList.size(); i++)
    {
        if(input.ninjaTime == timeList[i])
        {
            //check which HRRR format we have
            if( bandName.find( "u-component of wind [m/s]" ) == bandName.npos ){ //if band 49 isn't u10, it's either 2010 or 2012 format
                GDALRasterBand *poBand = srcDS->GetRasterBand( 50 );
                const char *gc;
                gc = poBand->GetMetadataItem( "GRIB_COMMENT" );
                std::string bandName( gc );
                if( bandName.find( "u-component of wind [m/s]" ) == bandName.npos ){ //if band 50 isn't u10, it's the 2010 format
                    bandList.push_back( 29 ); // 2t
                    bandList.push_back( 34 ); // 10v
                    bandList.push_back( 33 );  // 10u
                    bandList.push_back( 52 ); // geopotential height at cloud top
                }
                else{
                    bandList.push_back( 45 ); // 2t
                    bandList.push_back( 51 ); // 10v
                    bandList.push_back( 50 );  // 10u
                    bandList.push_back( 78 ); // geopotential height at cloud top
                }
            }
            else{ //otherwise, should be 2011 format, but check for u10 band to be sure
                poBand = srcDS->GetRasterBand( 44 );
                gc = poBand->GetMetadataItem( "GRIB_COMMENT" );
                bandName = gc;
                if( bandName.find( "u-component of wind [m/s]" ) == bandName.npos ){
                    CPLDebug( "ncepHRRRSurfaceInitialization::identify()",
                              "Can't find the u-10 band in the forecast file." );
                }
                bandList.push_back( 44 ); // 2t
                bandList.push_back( 50 ); // 10v
                bandList.push_back( 49 );  // 10u
                bandList.push_back( 73 ); // geopotential height at cloud top
            }
            break;
        }
    }

    if(bandList.size() < 4)
        throw std::runtime_error("Could not match ninjaTime with a band number in the forecast file.");

    std::string dstWkt;
    dstWkt = input.dem.prjString;

    GDALDataset *wrpDS;
    std::string temp;
    std::string srcWkt;

    GDALWarpOptions* psWarpOptions;

    srcWkt = srcDS->GetProjectionRef();

    poBand = srcDS->GetRasterBand( 9 );
    int pbSuccess;
    double dfNoData = poBand->GetNoDataValue( &pbSuccess );

    psWarpOptions = GDALCreateWarpOptions();

    int nBandCount = bandList.size();

    psWarpOptions->nBandCount = nBandCount;
    psWarpOptions->panSrcBands =
        (int*) CPLMalloc( sizeof( int ) * nBandCount );
    psWarpOptions->panDstBands =
        (int*) CPLMalloc( sizeof( int ) * nBandCount );
    psWarpOptions->padfDstNoDataReal =
        (double*) CPLMalloc( sizeof( double ) * nBandCount );
    psWarpOptions->padfDstNoDataImag =
        (double*) CPLMalloc( sizeof( double ) * nBandCount );


    psWarpOptions->padfDstNoDataReal =
        (double*) CPLMalloc( sizeof( double ) * nBandCount );
    psWarpOptions->padfDstNoDataImag =
        (double*) CPLMalloc( sizeof( double ) * nBandCount );

    if( pbSuccess == false )
        dfNoData = -9999.0;

    psWarpOptions->panSrcBands =
        (int *) CPLMalloc(sizeof(int) * psWarpOptions->nBandCount );
    psWarpOptions->panSrcBands[0] = bandList[0];
    psWarpOptions->panSrcBands[1] = bandList[1];
    psWarpOptions->panSrcBands[2] = bandList[2];
    psWarpOptions->panSrcBands[3] = bandList[3];

    psWarpOptions->panDstBands =
        (int *) CPLMalloc(sizeof(int) * psWarpOptions->nBandCount );
    psWarpOptions->panDstBands[0] = 1;
    psWarpOptions->panDstBands[1] = 2;
    psWarpOptions->panDstBands[2] = 3;
    psWarpOptions->panDstBands[3] = 4;

    wrpDS = (GDALDataset*) GDALAutoCreateWarpedVRT( srcDS, srcWkt.c_str(),
                                                    dstWkt.c_str(),
                                                    GRA_NearestNeighbour,
                                                    1.0, psWarpOptions );
    std::vector<std::string> varList = getVariableList();

    for( unsigned int i = 0; i < varList.size(); i++ ) {
        if( varList[i] == "2t" ) {
            GDAL2AsciiGrid( wrpDS, i+1, airGrid );
            if( CPLIsNan( dfNoData ) ) {
                airGrid.set_noDataValue( -9999.0 );
                airGrid.replaceNan( -9999.0 );
            }
        }
        else if( varList[i] == "10v" ) {
            GDAL2AsciiGrid( wrpDS, i+1, vGrid );
            if( CPLIsNan( dfNoData ) ) {
                vGrid.set_noDataValue( -9999.0 );
                vGrid.replaceNan( -9999.0 );
            }
        }
        else if( varList[i] == "10u" ) {
            GDAL2AsciiGrid( wrpDS, i+1, uGrid );
            if( CPLIsNan( dfNoData ) ) {
                uGrid.set_noDataValue( -9999.0 );
                uGrid.replaceNan( -9999.0 );
            }
        }
        else if( varList[i] == "gh" ) {
            GDAL2AsciiGrid( wrpDS, i+1, cloudGrid );
            if( CPLIsNan( dfNoData ) ) {
                cloudGrid.set_noDataValue( -9999.0 );
                cloudGrid.replaceNan( -9999.0 );
            }
        }
    }
    //if there are any clouds set cloud fraction to 1, otherwise set to 0.
    for(int i = 0; i < cloudGrid.get_nRows(); i++){
        for(int j = 0; j < cloudGrid.get_nCols(); j++){
            if(cloudGrid(i,j) < 0.0){
                cloudGrid(i,j) = 0.0;
            }
            else{
                cloudGrid(i,j) = 1.0;
            }
        }
    }
    wGrid.set_headerData( uGrid );
    wGrid = 0.0;
    airGrid += 273.15;

    GDALDestroyWarpOptions( psWarpOptions );
    GDALClose((GDALDatasetH) srcDS );
    GDALClose((GDALDatasetH) wrpDS );
}