void CoordinateTransformation::Init(unsigned int nSourceEPSG, unsigned int nDestEPSG) { _nSourceEPSG = nSourceEPSG; _nDestEPSG = nDestEPSG; _bIdentity = false; if (_nSourceEPSG == 0 || _nDestEPSG == 0 || nSourceEPSG == _nDest2) _bIdentity = true; if (_pCT) { OCTDestroyCoordinateTransformation((OGRCoordinateTransformation*) _pCT); _pCT = 0; } if (_pCTBack) { OCTDestroyCoordinateTransformation((OGRCoordinateTransformation*) _pCTBack); _pCTBack = 0; } if (!_bIdentity) { OGRSpatialReference srcref; OGRSpatialReference dstref; OGRErr err; err = srcref.importFromEPSG(_nSourceEPSG); err = dstref.importFromEPSG(_nDestEPSG); _pCT = (void*)OGRCreateCoordinateTransformation(&srcref, &dstref); _pCTBack = (void*)OGRCreateCoordinateTransformation(&dstref, &srcref); } }
CoordinateTransformation::~CoordinateTransformation() { if (_pCT) { OCTDestroyCoordinateTransformation((OGRCoordinateTransformation*) _pCT); _pCT = 0; } if (_pCTBack) { OCTDestroyCoordinateTransformation((OGRCoordinateTransformation*) _pCTBack); _pCTBack = 0; } }
void GDALDestroyRPCTransformer( void *pTransformAlg ) { GDALRPCTransformInfo *psTransform = (GDALRPCTransformInfo *) pTransformAlg; CPLFree( psTransform->pszDEMPath ); if(psTransform->poDS) GDALClose(psTransform->poDS); if(psTransform->poCT) OCTDestroyCoordinateTransformation((OGRCoordinateTransformationH)psTransform->poCT); CPLFree( pTransformAlg ); }
void Convert_Geographic_To_UTM( const int& number_coordinates, const double* latitudes_degrees, const double* longitudes_degrees, const std::string& input_datum, const int& grid_zone, const bool& is_northern, double* eastings_meters, double* northings_meters, const std::string& output_datum ) { // Create the Spatial Reference Objects OGRSpatialReference sourceSRS, targetSRS; sourceSRS.SetWellKnownGeogCS( input_datum.c_str() ); targetSRS.SetWellKnownGeogCS( output_datum.c_str() ); // Configure the Projected Coordinate Components targetSRS.SetUTM( grid_zone, is_northern ); // Build the Transform Engine OGRCoordinateTransformation* transform; transform = OGRCreateCoordinateTransformation( &sourceSRS, &targetSRS ); double* elevations_meters = NULL; memcpy( eastings_meters, longitudes_degrees, sizeof(double)*number_coordinates ); memcpy( northings_meters, latitudes_degrees, sizeof(double)*number_coordinates ); if( !transform->Transform( number_coordinates, eastings_meters, northings_meters, NULL )) { throw std::runtime_error("Transformation Failed."); } // Destroy the Transform OCTDestroyCoordinateTransformation( transform ); }
void Convert_Geographic_To_UTM( const double& latitude_degrees, const double& longitude_degrees, const std::string& input_datum, const int& grid_zone, const bool& is_northern, double& easting_meters, double& northing_meters, const std::string& output_datum ) { // Create the Spatial Reference Objects OGRSpatialReference sourceSRS, targetSRS; sourceSRS.SetWellKnownGeogCS( input_datum.c_str() ); targetSRS.SetWellKnownGeogCS( output_datum.c_str() ); // Configure the Projected Coordinate Components targetSRS.SetUTM( grid_zone, is_northern ); // Build the Transform Engine OGRCoordinateTransformation* transform; transform = OGRCreateCoordinateTransformation( &sourceSRS, &targetSRS ); easting_meters = longitude_degrees; northing_meters = latitude_degrees; double output_elevation_meters = 0; if( !transform->Transform( 1, &easting_meters, &northing_meters, &output_elevation_meters ) ) { throw std::runtime_error("Transformation Failed."); } // Destroy the Transform OCTDestroyCoordinateTransformation( transform ); }
void setSourceSRS(const std::string& sourceURN) { if (m_transformation != nullptr) { OCTDestroyCoordinateTransformation(m_transformation); m_transformation = nullptr; } OGRSpatialReference sourceSRS; OGRErr err = sourceSRS.SetFromUserInput(sourceURN.c_str()); if (err != OGRERR_NONE) { CITYGML_LOG_ERROR(m_logger, "Could not create OGRSpatialReference for source SRS " << sourceURN << ". OGR error code: " << err << "."); return; } m_transformation = OGRCreateCoordinateTransformation(&sourceSRS, &m_destSRS); if (m_transformation == nullptr) { CITYGML_LOG_ERROR(m_logger, "Could not create transformation from source SRS " << sourceURN << " to destination SRS " << m_destSRSURN << "."); return; } m_sourceURN = sourceURN; }
OGREnvelope wxGISRasterRGBRenderer::TransformEnvelope(OGREnvelope* pEnvelope, OGRSpatialReference* pSrsSpatialReference, OGRSpatialReference* pDstSpatialReference) { //get new envelope - it may rotate OGRCoordinateTransformation *poCT = OGRCreateCoordinateTransformation( pSrsSpatialReference, pDstSpatialReference); double pointsx[4]; double pointsy[4]; pointsx[0] = pEnvelope->MaxX; pointsy[0] = pEnvelope->MaxY; pointsx[1] = pEnvelope->MinX; pointsy[1] = pEnvelope->MinY; pointsx[2] = pEnvelope->MaxX; pointsy[2] = pEnvelope->MinY; pointsx[3] = pEnvelope->MinX; pointsy[3] = pEnvelope->MaxY; //get real envelope poCT->Transform(4, pointsx, pointsy); OCTDestroyCoordinateTransformation(poCT); OGREnvelope out; out.MinX = MIN(pointsx[0], MIN(pointsx[1], MIN(pointsx[2], pointsx[3]))); out.MaxX = MAX(pointsx[0], MAX(pointsx[1], MAX(pointsx[2], pointsx[3]))); out.MinY = MIN(pointsy[0], MIN(pointsy[1], MIN(pointsy[2], pointsy[3]))); out.MaxY = MAX(pointsy[0], MAX(pointsy[1], MAX(pointsy[2], pointsy[3]))); return out; }
int main( int argc, char ** argv ) { GDALDatasetH hDataset; GDALRasterBandH hBand; int i, iBand; double adfGeoTransform[6]; GDALDriverH hDriver; char **papszMetadata; int bComputeMinMax = FALSE, bSample = FALSE; int bShowGCPs = TRUE, bShowMetadata = TRUE, bShowRAT=TRUE; int bStats = FALSE, bApproxStats = TRUE, iMDD; int bShowColorTable = TRUE, bComputeChecksum = FALSE; int bReportHistograms = FALSE; const char *pszFilename = NULL; char **papszExtraMDDomains = NULL, **papszFileList; const char *pszProjection = NULL; OGRCoordinateTransformationH hTransform = NULL; /* Check that we are running against at least GDAL 1.5 */ /* Note to developers : if we use newer API, please change the requirement */ if (atoi(GDALVersionInfo("VERSION_NUM")) < 1500) { fprintf(stderr, "At least, GDAL >= 1.5.0 is required for this version of %s, " "which was compiled against GDAL %s\n", argv[0], GDAL_RELEASE_NAME); exit(1); } /* Must process GDAL_SKIP before GDALAllRegister(), but we can't call */ /* GDALGeneralCmdLineProcessor before it needs the drivers to be registered */ /* for the --format or --formats options */ for( i = 1; i < argc; i++ ) { if( EQUAL(argv[i],"--config") && i + 2 < argc && EQUAL(argv[i + 1], "GDAL_SKIP") ) { CPLSetConfigOption( argv[i+1], argv[i+2] ); i += 2; } } GDALAllRegister(); argc = GDALGeneralCmdLineProcessor( argc, &argv, 0 ); if( argc < 1 ) exit( -argc ); /* -------------------------------------------------------------------- */ /* Parse arguments. */ /* -------------------------------------------------------------------- */ for( i = 1; i < argc; i++ ) { if( EQUAL(argv[i], "--utility_version") ) { printf("%s was compiled against GDAL %s and is running against GDAL %s\n", argv[0], GDAL_RELEASE_NAME, GDALVersionInfo("RELEASE_NAME")); return 0; } else if( EQUAL(argv[i], "-mm") ) bComputeMinMax = TRUE; else if( EQUAL(argv[i], "-hist") ) bReportHistograms = TRUE; else if( EQUAL(argv[i], "-stats") ) { bStats = TRUE; bApproxStats = FALSE; } else if( EQUAL(argv[i], "-approx_stats") ) { bStats = TRUE; bApproxStats = TRUE; } else if( EQUAL(argv[i], "-sample") ) bSample = TRUE; else if( EQUAL(argv[i], "-checksum") ) bComputeChecksum = TRUE; else if( EQUAL(argv[i], "-nogcp") ) bShowGCPs = FALSE; else if( EQUAL(argv[i], "-nomd") ) bShowMetadata = FALSE; else if( EQUAL(argv[i], "-norat") ) bShowRAT = FALSE; else if( EQUAL(argv[i], "-noct") ) bShowColorTable = FALSE; else if( EQUAL(argv[i], "-mdd") && i < argc-1 ) papszExtraMDDomains = CSLAddString( papszExtraMDDomains, argv[++i] ); else if( argv[i][0] == '-' ) Usage(); else if( pszFilename == NULL ) pszFilename = argv[i]; else Usage(); } if( pszFilename == NULL ) Usage(); /* -------------------------------------------------------------------- */ /* Open dataset. */ /* -------------------------------------------------------------------- */ hDataset = GDALOpen( pszFilename, GA_ReadOnly ); if( hDataset == NULL ) { fprintf( stderr, "gdalinfo failed - unable to open '%s'.\n", pszFilename ); CSLDestroy( argv ); GDALDumpOpenDatasets( stderr ); GDALDestroyDriverManager(); CPLDumpSharedList( NULL ); exit( 1 ); } /* -------------------------------------------------------------------- */ /* Report general info. */ /* -------------------------------------------------------------------- */ hDriver = GDALGetDatasetDriver( hDataset ); printf( "Driver: %s/%s\n", GDALGetDriverShortName( hDriver ), GDALGetDriverLongName( hDriver ) ); papszFileList = GDALGetFileList( hDataset ); if( CSLCount(papszFileList) == 0 ) { printf( "Files: none associated\n" ); } else { printf( "Files: %s\n", papszFileList[0] ); for( i = 1; papszFileList[i] != NULL; i++ ) printf( " %s\n", papszFileList[i] ); } CSLDestroy( papszFileList ); printf( "Size is %d, %d\n", GDALGetRasterXSize( hDataset ), GDALGetRasterYSize( hDataset ) ); /* -------------------------------------------------------------------- */ /* Report projection. */ /* -------------------------------------------------------------------- */ if( GDALGetProjectionRef( hDataset ) != NULL ) { OGRSpatialReferenceH hSRS; char *pszProjection; pszProjection = (char *) GDALGetProjectionRef( hDataset ); hSRS = OSRNewSpatialReference(NULL); if( OSRImportFromWkt( hSRS, &pszProjection ) == CE_None ) { char *pszPrettyWkt = NULL; OSRExportToPrettyWkt( hSRS, &pszPrettyWkt, FALSE ); printf( "Coordinate System is:\n%s\n", pszPrettyWkt ); CPLFree( pszPrettyWkt ); } else printf( "Coordinate System is `%s'\n", GDALGetProjectionRef( hDataset ) ); OSRDestroySpatialReference( hSRS ); } /* -------------------------------------------------------------------- */ /* Report Geotransform. */ /* -------------------------------------------------------------------- */ if( GDALGetGeoTransform( hDataset, adfGeoTransform ) == CE_None ) { if( adfGeoTransform[2] == 0.0 && adfGeoTransform[4] == 0.0 ) { printf( "Origin = (%.15f,%.15f)\n", adfGeoTransform[0], adfGeoTransform[3] ); printf( "Pixel Size = (%.15f,%.15f)\n", adfGeoTransform[1], adfGeoTransform[5] ); } else printf( "GeoTransform =\n" " %.16g, %.16g, %.16g\n" " %.16g, %.16g, %.16g\n", adfGeoTransform[0], adfGeoTransform[1], adfGeoTransform[2], adfGeoTransform[3], adfGeoTransform[4], adfGeoTransform[5] ); } /* -------------------------------------------------------------------- */ /* Report GCPs. */ /* -------------------------------------------------------------------- */ if( bShowGCPs && GDALGetGCPCount( hDataset ) > 0 ) { if (GDALGetGCPProjection(hDataset) != NULL) { OGRSpatialReferenceH hSRS; char *pszProjection; pszProjection = (char *) GDALGetGCPProjection( hDataset ); hSRS = OSRNewSpatialReference(NULL); if( OSRImportFromWkt( hSRS, &pszProjection ) == CE_None ) { char *pszPrettyWkt = NULL; OSRExportToPrettyWkt( hSRS, &pszPrettyWkt, FALSE ); printf( "GCP Projection = \n%s\n", pszPrettyWkt ); CPLFree( pszPrettyWkt ); } else printf( "GCP Projection = %s\n", GDALGetGCPProjection( hDataset ) ); OSRDestroySpatialReference( hSRS ); } for( i = 0; i < GDALGetGCPCount(hDataset); i++ ) { const GDAL_GCP *psGCP; psGCP = GDALGetGCPs( hDataset ) + i; printf( "GCP[%3d]: Id=%s, Info=%s\n" " (%.15g,%.15g) -> (%.15g,%.15g,%.15g)\n", i, psGCP->pszId, psGCP->pszInfo, psGCP->dfGCPPixel, psGCP->dfGCPLine, psGCP->dfGCPX, psGCP->dfGCPY, psGCP->dfGCPZ ); } } /* -------------------------------------------------------------------- */ /* Report metadata. */ /* -------------------------------------------------------------------- */ papszMetadata = (bShowMetadata) ? GDALGetMetadata( hDataset, NULL ) : NULL; if( bShowMetadata && CSLCount(papszMetadata) > 0 ) { printf( "Metadata:\n" ); for( i = 0; papszMetadata[i] != NULL; i++ ) { printf( " %s\n", papszMetadata[i] ); } } for( iMDD = 0; bShowMetadata && iMDD < CSLCount(papszExtraMDDomains); iMDD++ ) { papszMetadata = GDALGetMetadata( hDataset, papszExtraMDDomains[iMDD] ); if( CSLCount(papszMetadata) > 0 ) { printf( "Metadata (%s):\n", papszExtraMDDomains[iMDD]); for( i = 0; papszMetadata[i] != NULL; i++ ) { printf( " %s\n", papszMetadata[i] ); } } } /* -------------------------------------------------------------------- */ /* Report "IMAGE_STRUCTURE" metadata. */ /* -------------------------------------------------------------------- */ papszMetadata = (bShowMetadata) ? GDALGetMetadata( hDataset, "IMAGE_STRUCTURE" ) : NULL; if( bShowMetadata && CSLCount(papszMetadata) > 0 ) { printf( "Image Structure Metadata:\n" ); for( i = 0; papszMetadata[i] != NULL; i++ ) { printf( " %s\n", papszMetadata[i] ); } } /* -------------------------------------------------------------------- */ /* Report subdatasets. */ /* -------------------------------------------------------------------- */ papszMetadata = GDALGetMetadata( hDataset, "SUBDATASETS" ); if( CSLCount(papszMetadata) > 0 ) { printf( "Subdatasets:\n" ); for( i = 0; papszMetadata[i] != NULL; i++ ) { printf( " %s\n", papszMetadata[i] ); } } /* -------------------------------------------------------------------- */ /* Report geolocation. */ /* -------------------------------------------------------------------- */ papszMetadata = (bShowMetadata) ? GDALGetMetadata( hDataset, "GEOLOCATION" ) : NULL; if( bShowMetadata && CSLCount(papszMetadata) > 0 ) { printf( "Geolocation:\n" ); for( i = 0; papszMetadata[i] != NULL; i++ ) { printf( " %s\n", papszMetadata[i] ); } } /* -------------------------------------------------------------------- */ /* Report RPCs */ /* -------------------------------------------------------------------- */ papszMetadata = (bShowMetadata) ? GDALGetMetadata( hDataset, "RPC" ) : NULL; if( bShowMetadata && CSLCount(papszMetadata) > 0 ) { printf( "RPC Metadata:\n" ); for( i = 0; papszMetadata[i] != NULL; i++ ) { printf( " %s\n", papszMetadata[i] ); } } /* -------------------------------------------------------------------- */ /* Setup projected to lat/long transform if appropriate. */ /* -------------------------------------------------------------------- */ if( GDALGetGeoTransform( hDataset, adfGeoTransform ) == CE_None ) pszProjection = GDALGetProjectionRef(hDataset); if( pszProjection != NULL && strlen(pszProjection) > 0 ) { OGRSpatialReferenceH hProj, hLatLong = NULL; hProj = OSRNewSpatialReference( pszProjection ); if( hProj != NULL ) hLatLong = OSRCloneGeogCS( hProj ); if( hLatLong != NULL ) { CPLPushErrorHandler( CPLQuietErrorHandler ); hTransform = OCTNewCoordinateTransformation( hProj, hLatLong ); CPLPopErrorHandler(); OSRDestroySpatialReference( hLatLong ); } if( hProj != NULL ) OSRDestroySpatialReference( hProj ); } /* -------------------------------------------------------------------- */ /* Report corners. */ /* -------------------------------------------------------------------- */ printf( "Corner Coordinates:\n" ); GDALInfoReportCorner( hDataset, hTransform, "Upper Left", 0.0, 0.0 ); GDALInfoReportCorner( hDataset, hTransform, "Lower Left", 0.0, GDALGetRasterYSize(hDataset)); GDALInfoReportCorner( hDataset, hTransform, "Upper Right", GDALGetRasterXSize(hDataset), 0.0 ); GDALInfoReportCorner( hDataset, hTransform, "Lower Right", GDALGetRasterXSize(hDataset), GDALGetRasterYSize(hDataset) ); GDALInfoReportCorner( hDataset, hTransform, "Center", GDALGetRasterXSize(hDataset)/2.0, GDALGetRasterYSize(hDataset)/2.0 ); if( hTransform != NULL ) { OCTDestroyCoordinateTransformation( hTransform ); hTransform = NULL; } /* ==================================================================== */ /* Loop over bands. */ /* ==================================================================== */ for( iBand = 0; iBand < GDALGetRasterCount( hDataset ); iBand++ ) { double dfMin, dfMax, adfCMinMax[2], dfNoData; int bGotMin, bGotMax, bGotNodata, bSuccess; int nBlockXSize, nBlockYSize, nMaskFlags; double dfMean, dfStdDev; GDALColorTableH hTable; CPLErr eErr; hBand = GDALGetRasterBand( hDataset, iBand+1 ); if( bSample ) { float afSample[10000]; int nCount; nCount = GDALGetRandomRasterSample( hBand, 10000, afSample ); printf( "Got %d samples.\n", nCount ); } GDALGetBlockSize( hBand, &nBlockXSize, &nBlockYSize ); printf( "Band %d Block=%dx%d Type=%s, ColorInterp=%s\n", iBand+1, nBlockXSize, nBlockYSize, GDALGetDataTypeName( GDALGetRasterDataType(hBand)), GDALGetColorInterpretationName( GDALGetRasterColorInterpretation(hBand)) ); if( GDALGetDescription( hBand ) != NULL && strlen(GDALGetDescription( hBand )) > 0 ) printf( " Description = %s\n", GDALGetDescription(hBand) ); dfMin = GDALGetRasterMinimum( hBand, &bGotMin ); dfMax = GDALGetRasterMaximum( hBand, &bGotMax ); if( bGotMin || bGotMax || bComputeMinMax ) { printf( " " ); if( bGotMin ) printf( "Min=%.3f ", dfMin ); if( bGotMax ) printf( "Max=%.3f ", dfMax ); if( bComputeMinMax ) { CPLErrorReset(); GDALComputeRasterMinMax( hBand, FALSE, adfCMinMax ); if (CPLGetLastErrorType() == CE_None) { printf( " Computed Min/Max=%.3f,%.3f", adfCMinMax[0], adfCMinMax[1] ); } } printf( "\n" ); } eErr = GDALGetRasterStatistics( hBand, bApproxStats, bStats, &dfMin, &dfMax, &dfMean, &dfStdDev ); if( eErr == CE_None ) { printf( " Minimum=%.3f, Maximum=%.3f, Mean=%.3f, StdDev=%.3f\n", dfMin, dfMax, dfMean, dfStdDev ); } if( bReportHistograms ) { int nBucketCount, *panHistogram = NULL; eErr = GDALGetDefaultHistogram( hBand, &dfMin, &dfMax, &nBucketCount, &panHistogram, TRUE, GDALTermProgress, NULL ); if( eErr == CE_None ) { int iBucket; printf( " %d buckets from %g to %g:\n ", nBucketCount, dfMin, dfMax ); for( iBucket = 0; iBucket < nBucketCount; iBucket++ ) printf( "%d ", panHistogram[iBucket] ); printf( "\n" ); CPLFree( panHistogram ); } } if ( bComputeChecksum) { printf( " Checksum=%d\n", GDALChecksumImage(hBand, 0, 0, GDALGetRasterXSize(hDataset), GDALGetRasterYSize(hDataset))); } dfNoData = GDALGetRasterNoDataValue( hBand, &bGotNodata ); if( bGotNodata ) { printf( " NoData Value=%.18g\n", dfNoData ); } if( GDALGetOverviewCount(hBand) > 0 ) { int iOverview; printf( " Overviews: " ); for( iOverview = 0; iOverview < GDALGetOverviewCount(hBand); iOverview++ ) { GDALRasterBandH hOverview; const char *pszResampling = NULL; if( iOverview != 0 ) printf( ", " ); hOverview = GDALGetOverview( hBand, iOverview ); printf( "%dx%d", GDALGetRasterBandXSize( hOverview ), GDALGetRasterBandYSize( hOverview ) ); pszResampling = GDALGetMetadataItem( hOverview, "RESAMPLING", "" ); if( pszResampling != NULL && EQUALN(pszResampling,"AVERAGE_BIT2",12) ) printf( "*" ); } printf( "\n" ); if ( bComputeChecksum) { printf( " Overviews checksum: " ); for( iOverview = 0; iOverview < GDALGetOverviewCount(hBand); iOverview++ ) { GDALRasterBandH hOverview; if( iOverview != 0 ) printf( ", " ); hOverview = GDALGetOverview( hBand, iOverview ); printf( "%d", GDALChecksumImage(hOverview, 0, 0, GDALGetRasterBandXSize(hOverview), GDALGetRasterBandYSize(hOverview))); } printf( "\n" ); } } if( GDALHasArbitraryOverviews( hBand ) ) { printf( " Overviews: arbitrary\n" ); } nMaskFlags = GDALGetMaskFlags( hBand ); if( (nMaskFlags & (GMF_NODATA|GMF_ALL_VALID)) == 0 ) { GDALRasterBandH hMaskBand = GDALGetMaskBand(hBand) ; printf( " Mask Flags: " ); if( nMaskFlags & GMF_PER_DATASET ) printf( "PER_DATASET " ); if( nMaskFlags & GMF_ALPHA ) printf( "ALPHA " ); if( nMaskFlags & GMF_NODATA ) printf( "NODATA " ); if( nMaskFlags & GMF_ALL_VALID ) printf( "ALL_VALID " ); printf( "\n" ); if( hMaskBand != NULL && GDALGetOverviewCount(hMaskBand) > 0 ) { int iOverview; printf( " Overviews of mask band: " ); for( iOverview = 0; iOverview < GDALGetOverviewCount(hMaskBand); iOverview++ ) { GDALRasterBandH hOverview; if( iOverview != 0 ) printf( ", " ); hOverview = GDALGetOverview( hMaskBand, iOverview ); printf( "%dx%d", GDALGetRasterBandXSize( hOverview ), GDALGetRasterBandYSize( hOverview ) ); } printf( "\n" ); } } if( strlen(GDALGetRasterUnitType(hBand)) > 0 ) { printf( " Unit Type: %s\n", GDALGetRasterUnitType(hBand) ); } if( GDALGetRasterCategoryNames(hBand) != NULL ) { char **papszCategories = GDALGetRasterCategoryNames(hBand); int i; printf( " Categories:\n" ); for( i = 0; papszCategories[i] != NULL; i++ ) printf( " %3d: %s\n", i, papszCategories[i] ); } if( GDALGetRasterScale( hBand, &bSuccess ) != 1.0 || GDALGetRasterOffset( hBand, &bSuccess ) != 0.0 ) printf( " Offset: %.15g, Scale:%.15g\n", GDALGetRasterOffset( hBand, &bSuccess ), GDALGetRasterScale( hBand, &bSuccess ) ); papszMetadata = (bShowMetadata) ? GDALGetMetadata( hBand, NULL ) : NULL; if( bShowMetadata && CSLCount(papszMetadata) > 0 ) { printf( " Metadata:\n" ); for( i = 0; papszMetadata[i] != NULL; i++ ) { printf( " %s\n", papszMetadata[i] ); } } papszMetadata = (bShowMetadata) ? GDALGetMetadata( hBand, "IMAGE_STRUCTURE" ) : NULL; if( bShowMetadata && CSLCount(papszMetadata) > 0 ) { printf( " Image Structure Metadata:\n" ); for( i = 0; papszMetadata[i] != NULL; i++ ) { printf( " %s\n", papszMetadata[i] ); } } if( GDALGetRasterColorInterpretation(hBand) == GCI_PaletteIndex && (hTable = GDALGetRasterColorTable( hBand )) != NULL ) { int i; printf( " Color Table (%s with %d entries)\n", GDALGetPaletteInterpretationName( GDALGetPaletteInterpretation( hTable )), GDALGetColorEntryCount( hTable ) ); if (bShowColorTable) { for( i = 0; i < GDALGetColorEntryCount( hTable ); i++ ) { GDALColorEntry sEntry; GDALGetColorEntryAsRGB( hTable, i, &sEntry ); printf( " %3d: %d,%d,%d,%d\n", i, sEntry.c1, sEntry.c2, sEntry.c3, sEntry.c4 ); } } } if( bShowRAT && GDALGetDefaultRAT( hBand ) != NULL ) { GDALRasterAttributeTableH hRAT = GDALGetDefaultRAT( hBand ); GDALRATDumpReadable( hRAT, NULL ); } } GDALClose( hDataset ); CSLDestroy( papszExtraMDDomains ); CSLDestroy( argv ); GDALDumpOpenDatasets( stderr ); GDALDestroyDriverManager(); CPLDumpSharedList( NULL ); CPLCleanupTLS(); exit( 0 ); }
CoordinateTransformation::~CoordinateTransformation() { if(nullptr != m_oCT) OCTDestroyCoordinateTransformation( reinterpret_cast<OGRCoordinateTransformationH>(m_oCT)); }
~CDEHandlerPass2() { OGRDataSource::DestroyDataSource(m_data_source); OCTDestroyCoordinateTransformation(m_transformation); OGRCleanupAll(); }
MAIN_START(argc, argv) { // Check that we are running against at least GDAL 1.4. // Note to developers: if we use newer API, please change the requirement. if( atoi(GDALVersionInfo("VERSION_NUM")) < 1400 ) { fprintf(stderr, "At least, GDAL >= 1.4.0 is required for this version of %s, " "which was compiled against GDAL %s\n", argv[0], GDAL_RELEASE_NAME); exit(1); } GDALAllRegister(); OGRRegisterAll(); argc = GDALGeneralCmdLineProcessor( argc, &argv, 0 ); if( argc < 1 ) exit( -argc ); /* -------------------------------------------------------------------- */ /* Get commandline arguments other than the GDAL raster filenames. */ /* -------------------------------------------------------------------- */ const char* pszIndexLayerName = nullptr; const char *index_filename = nullptr; const char *tile_index = "location"; const char* pszDriverName = nullptr; size_t nMaxFieldSize = 254; bool write_absolute_path = false; char* current_path = nullptr; bool skip_different_projection = false; const char *pszTargetSRS = ""; bool bSetTargetSRS = false; const char* pszSrcSRSName = nullptr; int i_SrcSRSName = -1; bool bSrcSRSFormatSpecified = false; SrcSRSFormat eSrcSRSFormat = FORMAT_AUTO; int iArg = 1; // Used after for. for( ; iArg < argc; iArg++ ) { if( EQUAL(argv[iArg], "--utility_version") ) { printf("%s was compiled against GDAL %s and is running against " "GDAL %s\n", argv[0], GDAL_RELEASE_NAME, GDALVersionInfo("RELEASE_NAME")); CSLDestroy( argv ); return 0; } else if( EQUAL(argv[iArg],"--help") ) Usage(nullptr); else if( (strcmp(argv[iArg],"-f") == 0 || strcmp(argv[iArg],"-of") == 0) ) { CHECK_HAS_ENOUGH_ADDITIONAL_ARGS(1); pszDriverName = argv[++iArg]; } else if( strcmp(argv[iArg],"-lyr_name") == 0 ) { CHECK_HAS_ENOUGH_ADDITIONAL_ARGS(1); pszIndexLayerName = argv[++iArg]; } else if( strcmp(argv[iArg],"-tileindex") == 0 ) { CHECK_HAS_ENOUGH_ADDITIONAL_ARGS(1); tile_index = argv[++iArg]; } else if( strcmp(argv[iArg],"-t_srs") == 0 ) { CHECK_HAS_ENOUGH_ADDITIONAL_ARGS(1); pszTargetSRS = argv[++iArg]; bSetTargetSRS = true; } else if ( strcmp(argv[iArg],"-write_absolute_path") == 0 ) { write_absolute_path = true; } else if ( strcmp(argv[iArg],"-skip_different_projection") == 0 ) { skip_different_projection = true; } else if( strcmp(argv[iArg], "-src_srs_name") == 0 ) { CHECK_HAS_ENOUGH_ADDITIONAL_ARGS(1); pszSrcSRSName = argv[++iArg]; } else if( strcmp(argv[iArg], "-src_srs_format") == 0 ) { const char* pszFormat; bSrcSRSFormatSpecified = true; CHECK_HAS_ENOUGH_ADDITIONAL_ARGS(1); pszFormat = argv[++iArg]; if( EQUAL(pszFormat, "AUTO") ) eSrcSRSFormat = FORMAT_AUTO; else if( EQUAL(pszFormat, "WKT") ) eSrcSRSFormat = FORMAT_WKT; else if( EQUAL(pszFormat, "EPSG") ) eSrcSRSFormat = FORMAT_EPSG; else if( EQUAL(pszFormat, "PROJ") ) eSrcSRSFormat = FORMAT_PROJ; } else if( argv[iArg][0] == '-' ) Usage(CPLSPrintf("Unknown option name '%s'", argv[iArg])); else if( index_filename == nullptr ) { index_filename = argv[iArg]; iArg++; break; } } if( index_filename == nullptr ) Usage("No index filename specified."); if( iArg == argc ) Usage("No file to index specified."); if( bSrcSRSFormatSpecified && pszSrcSRSName == nullptr ) Usage("-src_srs_name must be specified when -src_srs_format is " "specified."); /* -------------------------------------------------------------------- */ /* Create and validate target SRS if given. */ /* -------------------------------------------------------------------- */ OGRSpatialReferenceH hTargetSRS = nullptr; if( bSetTargetSRS ) { if( skip_different_projection ) { fprintf( stderr, "Warning : -skip_different_projection does not apply " "when -t_srs is requested.\n" ); } hTargetSRS = OSRNewSpatialReference(""); OSRSetAxisMappingStrategy(hTargetSRS, OAMS_TRADITIONAL_GIS_ORDER); // coverity[tainted_data] if( OSRSetFromUserInput( hTargetSRS, pszTargetSRS ) != CE_None ) { OSRDestroySpatialReference( hTargetSRS ); fprintf( stderr, "Invalid target SRS `%s'.\n", pszTargetSRS ); exit(1); } } /* -------------------------------------------------------------------- */ /* Open or create the target datasource */ /* -------------------------------------------------------------------- */ GDALDatasetH hTileIndexDS = GDALOpenEx( index_filename, GDAL_OF_VECTOR | GDAL_OF_UPDATE, nullptr, nullptr, nullptr ); OGRLayerH hLayer = nullptr; CPLString osFormat; if( hTileIndexDS != nullptr ) { GDALDriverH hDriver = GDALGetDatasetDriver(hTileIndexDS); if( hDriver ) osFormat = GDALGetDriverShortName(hDriver); if( GDALDatasetGetLayerCount(hTileIndexDS) == 1 ) { hLayer = GDALDatasetGetLayer(hTileIndexDS, 0); } else { if( pszIndexLayerName == nullptr ) { printf( "-lyr_name must be specified.\n" ); exit( 1 ); } CPLPushErrorHandler(CPLQuietErrorHandler); hLayer = GDALDatasetGetLayerByName(hTileIndexDS, pszIndexLayerName); CPLPopErrorHandler(); } } else { printf( "Creating new index file...\n" ); if( pszDriverName == nullptr ) { std::vector<CPLString> aoDrivers = GetOutputDriversFor(index_filename, GDAL_OF_VECTOR); if( aoDrivers.empty() ) { CPLError( CE_Failure, CPLE_AppDefined, "Cannot guess driver for %s", index_filename); exit( 10 ); } else { if( aoDrivers.size() > 1 ) { CPLError( CE_Warning, CPLE_AppDefined, "Several drivers matching %s extension. Using %s", CPLGetExtension(index_filename), aoDrivers[0].c_str() ); } osFormat = aoDrivers[0]; } } else { osFormat = pszDriverName; } if( !EQUAL(osFormat, "ESRI Shapefile") ) nMaxFieldSize = 0; GDALDriverH hDriver = GDALGetDriverByName( osFormat.c_str() ); if( hDriver == nullptr ) { printf( "%s driver not available.\n", osFormat.c_str() ); exit( 1 ); } hTileIndexDS = GDALCreate( hDriver, index_filename, 0, 0, 0, GDT_Unknown, nullptr ); } if( hTileIndexDS != nullptr && hLayer == nullptr ) { OGRSpatialReferenceH hSpatialRef = nullptr; char* pszLayerName = nullptr; if( pszIndexLayerName == nullptr ) { VSIStatBuf sStat; if( EQUAL(osFormat, "ESRI Shapefile") || VSIStat(index_filename, &sStat) == 0 ) { pszLayerName = CPLStrdup(CPLGetBasename(index_filename)); } else { printf( "-lyr_name must be specified.\n" ); exit( 1 ); } } else { pszLayerName = CPLStrdup(pszIndexLayerName); } /* get spatial reference for output file from target SRS (if set) */ /* or from first input file */ if( bSetTargetSRS ) { hSpatialRef = OSRClone( hTargetSRS ); } else { GDALDatasetH hDS = GDALOpen( argv[iArg], GA_ReadOnly ); if( hDS ) { const char* pszWKT = GDALGetProjectionRef(hDS); if (pszWKT != nullptr && pszWKT[0] != '\0') { hSpatialRef = OSRNewSpatialReference(pszWKT); OSRSetAxisMappingStrategy(hSpatialRef, OAMS_TRADITIONAL_GIS_ORDER); } GDALClose(hDS); } } hLayer = GDALDatasetCreateLayer( hTileIndexDS, pszLayerName, hSpatialRef, wkbPolygon, nullptr ); CPLFree(pszLayerName); if( hSpatialRef ) OSRRelease(hSpatialRef); if( hLayer ) { OGRFieldDefnH hFieldDefn = OGR_Fld_Create( tile_index, OFTString ); if( nMaxFieldSize ) OGR_Fld_SetWidth( hFieldDefn, static_cast<int>(nMaxFieldSize)); OGR_L_CreateField( hLayer, hFieldDefn, TRUE ); OGR_Fld_Destroy(hFieldDefn); if( pszSrcSRSName != nullptr ) { hFieldDefn = OGR_Fld_Create( pszSrcSRSName, OFTString ); if( nMaxFieldSize ) OGR_Fld_SetWidth(hFieldDefn, static_cast<int>(nMaxFieldSize)); OGR_L_CreateField( hLayer, hFieldDefn, TRUE ); OGR_Fld_Destroy(hFieldDefn); } } } if( hTileIndexDS == nullptr || hLayer == nullptr ) { fprintf( stderr, "Unable to open/create shapefile `%s'.\n", index_filename ); exit(2); } OGRFeatureDefnH hFDefn = OGR_L_GetLayerDefn(hLayer); const int ti_field = OGR_FD_GetFieldIndex( hFDefn, tile_index ); if( ti_field < 0 ) { fprintf( stderr, "Unable to find field `%s' in file `%s'.\n", tile_index, index_filename ); exit(2); } if( pszSrcSRSName != nullptr ) i_SrcSRSName = OGR_FD_GetFieldIndex( hFDefn, pszSrcSRSName ); // Load in memory existing file names in SHP. int nExistingFiles = static_cast<int>(OGR_L_GetFeatureCount(hLayer, FALSE)); if( nExistingFiles < 0) nExistingFiles = 0; char** existingFilesTab = nullptr; bool alreadyExistingProjectionRefValid = false; char* alreadyExistingProjectionRef = nullptr; if( nExistingFiles > 0 ) { OGRFeatureH hFeature = nullptr; existingFilesTab = static_cast<char **>( CPLMalloc(nExistingFiles * sizeof(char*))); for( int i = 0; i < nExistingFiles; i++ ) { hFeature = OGR_L_GetNextFeature(hLayer); existingFilesTab[i] = CPLStrdup(OGR_F_GetFieldAsString( hFeature, ti_field )); if( i == 0 ) { GDALDatasetH hDS = GDALOpen(existingFilesTab[i], GA_ReadOnly ); if( hDS ) { alreadyExistingProjectionRefValid = true; alreadyExistingProjectionRef = CPLStrdup(GDALGetProjectionRef(hDS)); GDALClose(hDS); } } OGR_F_Destroy( hFeature ); } } if( write_absolute_path ) { current_path = CPLGetCurrentDir(); if (current_path == nullptr) { fprintf( stderr, "This system does not support the CPLGetCurrentDir call. " "The option -write_absolute_path will have no effect\n" ); write_absolute_path = FALSE; } } /* -------------------------------------------------------------------- */ /* loop over GDAL files, processing. */ /* -------------------------------------------------------------------- */ for( ; iArg < argc; iArg++ ) { char *fileNameToWrite = nullptr; VSIStatBuf sStatBuf; // Make sure it is a file before building absolute path name. if( write_absolute_path && CPLIsFilenameRelative( argv[iArg] ) && VSIStat( argv[iArg], &sStatBuf ) == 0 ) { fileNameToWrite = CPLStrdup(CPLProjectRelativeFilename(current_path, argv[iArg])); } else { fileNameToWrite = CPLStrdup(argv[iArg]); } // Checks that file is not already in tileindex. { int i = 0; // Used after for. for( ; i < nExistingFiles; i++ ) { if (EQUAL(fileNameToWrite, existingFilesTab[i])) { fprintf(stderr, "File %s is already in tileindex. Skipping it.\n", fileNameToWrite); break; } } if (i != nExistingFiles) { CPLFree(fileNameToWrite); continue; } } GDALDatasetH hDS = GDALOpen( argv[iArg], GA_ReadOnly ); if( hDS == nullptr ) { fprintf( stderr, "Unable to open %s, skipping.\n", argv[iArg] ); CPLFree(fileNameToWrite); continue; } double adfGeoTransform[6] = { 0.0, 0.0, 0.0, 0.0, 0.0, 0.0 }; GDALGetGeoTransform( hDS, adfGeoTransform ); if( adfGeoTransform[0] == 0.0 && adfGeoTransform[1] == 1.0 && adfGeoTransform[3] == 0.0 && std::abs(adfGeoTransform[5]) == 1.0 ) { fprintf( stderr, "It appears no georeferencing is available for\n" "`%s', skipping.\n", argv[iArg] ); GDALClose( hDS ); CPLFree(fileNameToWrite); continue; } const char *projectionRef = GDALGetProjectionRef(hDS); // If not set target srs, test that the current file uses same // projection as others. if( !bSetTargetSRS ) { if( alreadyExistingProjectionRefValid ) { int projectionRefNotNull, alreadyExistingProjectionRefNotNull; projectionRefNotNull = projectionRef && projectionRef[0]; alreadyExistingProjectionRefNotNull = alreadyExistingProjectionRef && alreadyExistingProjectionRef[0]; if ((projectionRefNotNull && alreadyExistingProjectionRefNotNull && EQUAL(projectionRef, alreadyExistingProjectionRef) == 0) || (projectionRefNotNull != alreadyExistingProjectionRefNotNull)) { fprintf( stderr, "Warning : %s is not using the same projection system " "as other files in the tileindex.\n" "This may cause problems when using it in MapServer " "for example.\n" "Use -t_srs option to set target projection system " "(not supported by MapServer).\n" "%s\n", argv[iArg], skip_different_projection ? "Skipping this file." : ""); if( skip_different_projection ) { CPLFree(fileNameToWrite); GDALClose( hDS ); continue; } } } else { alreadyExistingProjectionRefValid = true; alreadyExistingProjectionRef = CPLStrdup(projectionRef); } } const int nXSize = GDALGetRasterXSize( hDS ); const int nYSize = GDALGetRasterYSize( hDS ); double adfX[5] = { 0.0, 0.0, 0.0, 0.0, 0.0 }; double adfY[5] = { 0.0, 0.0, 0.0, 0.0, 0.0 }; adfX[0] = adfGeoTransform[0] + 0 * adfGeoTransform[1] + 0 * adfGeoTransform[2]; adfY[0] = adfGeoTransform[3] + 0 * adfGeoTransform[4] + 0 * adfGeoTransform[5]; adfX[1] = adfGeoTransform[0] + nXSize * adfGeoTransform[1] + 0 * adfGeoTransform[2]; adfY[1] = adfGeoTransform[3] + nXSize * adfGeoTransform[4] + 0 * adfGeoTransform[5]; adfX[2] = adfGeoTransform[0] + nXSize * adfGeoTransform[1] + nYSize * adfGeoTransform[2]; adfY[2] = adfGeoTransform[3] + nXSize * adfGeoTransform[4] + nYSize * adfGeoTransform[5]; adfX[3] = adfGeoTransform[0] + 0 * adfGeoTransform[1] + nYSize * adfGeoTransform[2]; adfY[3] = adfGeoTransform[3] + 0 * adfGeoTransform[4] + nYSize * adfGeoTransform[5]; adfX[4] = adfGeoTransform[0] + 0 * adfGeoTransform[1] + 0 * adfGeoTransform[2]; adfY[4] = adfGeoTransform[3] + 0 * adfGeoTransform[4] + 0 * adfGeoTransform[5]; OGRSpatialReferenceH hSourceSRS = nullptr; if( (bSetTargetSRS || i_SrcSRSName >= 0) && projectionRef != nullptr && projectionRef[0] != '\0' ) { hSourceSRS = OSRNewSpatialReference( projectionRef ); OSRSetAxisMappingStrategy(hSourceSRS, OAMS_TRADITIONAL_GIS_ORDER); } // If set target srs, do the forward transformation of all points. if( bSetTargetSRS && projectionRef != nullptr && projectionRef[0] != '\0' ) { OGRCoordinateTransformationH hCT = nullptr; if( hSourceSRS && !OSRIsSame( hSourceSRS, hTargetSRS ) ) { hCT = OCTNewCoordinateTransformation( hSourceSRS, hTargetSRS ); if( hCT == nullptr || !OCTTransform( hCT, 5, adfX, adfY, nullptr ) ) { fprintf( stderr, "Warning : unable to transform points from source " "SRS `%s' to target SRS `%s'\n" "for file `%s' - file skipped\n", projectionRef, pszTargetSRS, fileNameToWrite ); if( hCT ) OCTDestroyCoordinateTransformation( hCT ); if( hSourceSRS ) OSRDestroySpatialReference( hSourceSRS ); continue; } if( hCT ) OCTDestroyCoordinateTransformation( hCT ); } } OGRFeatureH hFeature = OGR_F_Create( OGR_L_GetLayerDefn( hLayer ) ); OGR_F_SetFieldString( hFeature, ti_field, fileNameToWrite ); if( i_SrcSRSName >= 0 && hSourceSRS != nullptr ) { const char* pszAuthorityCode = OSRGetAuthorityCode(hSourceSRS, nullptr); const char* pszAuthorityName = OSRGetAuthorityName(hSourceSRS, nullptr); if( eSrcSRSFormat == FORMAT_AUTO ) { if( pszAuthorityName != nullptr && pszAuthorityCode != nullptr ) { OGR_F_SetFieldString( hFeature, i_SrcSRSName, CPLSPrintf("%s:%s", pszAuthorityName, pszAuthorityCode) ); } else if( nMaxFieldSize == 0 || strlen(projectionRef) <= nMaxFieldSize ) { OGR_F_SetFieldString(hFeature, i_SrcSRSName, projectionRef); } else { char* pszProj4 = nullptr; if( OSRExportToProj4(hSourceSRS, &pszProj4) == OGRERR_NONE ) { OGR_F_SetFieldString( hFeature, i_SrcSRSName, pszProj4 ); CPLFree(pszProj4); } else { OGR_F_SetFieldString( hFeature, i_SrcSRSName, projectionRef ); } } } else if( eSrcSRSFormat == FORMAT_WKT ) { if( nMaxFieldSize == 0 || strlen(projectionRef) <= nMaxFieldSize ) { OGR_F_SetFieldString( hFeature, i_SrcSRSName, projectionRef ); } else { fprintf(stderr, "Cannot write WKT for file %s as it is too long!\n", fileNameToWrite); } } else if( eSrcSRSFormat == FORMAT_PROJ ) { char* pszProj4 = nullptr; if( OSRExportToProj4(hSourceSRS, &pszProj4) == OGRERR_NONE ) { OGR_F_SetFieldString( hFeature, i_SrcSRSName, pszProj4 ); CPLFree(pszProj4); } } else if( eSrcSRSFormat == FORMAT_EPSG ) { if( pszAuthorityName != nullptr && pszAuthorityCode != nullptr ) OGR_F_SetFieldString( hFeature, i_SrcSRSName, CPLSPrintf("%s:%s", pszAuthorityName, pszAuthorityCode) ); } } if( hSourceSRS ) OSRDestroySpatialReference( hSourceSRS ); OGRGeometryH hPoly = OGR_G_CreateGeometry(wkbPolygon); OGRGeometryH hRing = OGR_G_CreateGeometry(wkbLinearRing); for( int k = 0; k < 5; k++ ) OGR_G_SetPoint_2D(hRing, k, adfX[k], adfY[k]); OGR_G_AddGeometryDirectly( hPoly, hRing ); OGR_F_SetGeometryDirectly( hFeature, hPoly ); if( OGR_L_CreateFeature( hLayer, hFeature ) != OGRERR_NONE ) { printf( "Failed to create feature in shapefile.\n" ); break; } OGR_F_Destroy( hFeature ); CPLFree(fileNameToWrite); GDALClose( hDS ); } CPLFree(current_path); if (nExistingFiles) { for( int i = 0; i < nExistingFiles; i++ ) { CPLFree(existingFilesTab[i]); } CPLFree(existingFilesTab); } CPLFree(alreadyExistingProjectionRef); if ( hTargetSRS ) OSRDestroySpatialReference( hTargetSRS ); GDALClose( hTileIndexDS ); GDALDestroyDriverManager(); OGRCleanupAll(); CSLDestroy(argv); exit( 0 ); }
int main(int argc, char *argv[]) { const char *index_filename = NULL; const char *tile_index = "location"; int i_arg, ti_field; OGRDataSourceH hTileIndexDS; OGRLayerH hLayer = NULL; OGRFeatureDefnH hFDefn; int write_absolute_path = FALSE; char* current_path = NULL; int i; int nExistingFiles; int skip_different_projection = FALSE; char** existingFilesTab = NULL; int alreadyExistingProjectionRefValid = FALSE; char* alreadyExistingProjectionRef = NULL; char* index_filename_mod; int bExists; VSIStatBuf sStatBuf; const char *pszTargetSRS = ""; int bSetTargetSRS = FALSE; OGRSpatialReferenceH hTargetSRS = NULL; /* Check that we are running against at least GDAL 1.4 */ /* Note to developers : if we use newer API, please change the requirement */ if (atoi(GDALVersionInfo("VERSION_NUM")) < 1400) { fprintf(stderr, "At least, GDAL >= 1.4.0 is required for this version of %s, " "which was compiled against GDAL %s\n", argv[0], GDAL_RELEASE_NAME); exit(1); } GDALAllRegister(); OGRRegisterAll(); argc = GDALGeneralCmdLineProcessor( argc, &argv, 0 ); if( argc < 1 ) exit( -argc ); /* -------------------------------------------------------------------- */ /* Get commandline arguments other than the GDAL raster filenames. */ /* -------------------------------------------------------------------- */ for( i_arg = 1; i_arg < argc; i_arg++ ) { if( EQUAL(argv[i_arg], "--utility_version") ) { printf("%s was compiled against GDAL %s and is running against GDAL %s\n", argv[0], GDAL_RELEASE_NAME, GDALVersionInfo("RELEASE_NAME")); return 0; } else if( strcmp(argv[i_arg],"-tileindex") == 0 ) { tile_index = argv[++i_arg]; } else if( strcmp(argv[i_arg],"-t_srs") == 0 ) { pszTargetSRS = argv[++i_arg]; bSetTargetSRS = TRUE; } else if ( strcmp(argv[i_arg],"-write_absolute_path") == 0 ) { write_absolute_path = TRUE; } else if ( strcmp(argv[i_arg],"-skip_different_projection") == 0 ) { skip_different_projection = TRUE; } else if( argv[i_arg][0] == '-' ) Usage(); else if( index_filename == NULL ) { index_filename = argv[i_arg]; i_arg++; break; } } if( index_filename == NULL || i_arg == argc ) Usage(); /* -------------------------------------------------------------------- */ /* Create and validate target SRS if given. */ /* -------------------------------------------------------------------- */ if( bSetTargetSRS ) { if ( skip_different_projection ) { fprintf( stderr, "Warning : -skip_different_projection does not apply " "when -t_srs is requested.\n" ); } hTargetSRS = OSRNewSpatialReference(""); if( OSRSetFromUserInput( hTargetSRS, pszTargetSRS ) != CE_None ) { OSRDestroySpatialReference( hTargetSRS ); fprintf( stderr, "Invalid target SRS `%s'.\n", pszTargetSRS ); exit(1); } } /* -------------------------------------------------------------------- */ /* Open or create the target shapefile and DBF file. */ /* -------------------------------------------------------------------- */ index_filename_mod = CPLStrdup(CPLResetExtension(index_filename, "shp")); bExists = (VSIStat(index_filename_mod, &sStatBuf) == 0); if (!bExists) { CPLFree(index_filename_mod); index_filename_mod = CPLStrdup(CPLResetExtension(index_filename, "SHP")); bExists = (VSIStat(index_filename_mod, &sStatBuf) == 0); } CPLFree(index_filename_mod); if (bExists) { hTileIndexDS = OGROpen( index_filename, TRUE, NULL ); if (hTileIndexDS != NULL) { hLayer = OGR_DS_GetLayer(hTileIndexDS, 0); } } else { OGRSFDriverH hDriver; const char* pszDriverName = "ESRI Shapefile"; printf( "Creating new index file...\n" ); hDriver = OGRGetDriverByName( pszDriverName ); if( hDriver == NULL ) { printf( "%s driver not available.\n", pszDriverName ); exit( 1 ); } hTileIndexDS = OGR_Dr_CreateDataSource( hDriver, index_filename, NULL ); if (hTileIndexDS) { char* pszLayerName = CPLStrdup(CPLGetBasename(index_filename)); /* get spatial reference for output file from target SRS (if set) */ /* or from first input file */ OGRSpatialReferenceH hSpatialRef = NULL; if( bSetTargetSRS ) { hSpatialRef = OSRClone( hTargetSRS ); } else { GDALDatasetH hDS = GDALOpen( argv[i_arg], GA_ReadOnly ); if (hDS) { const char* pszWKT = GDALGetProjectionRef(hDS); if (pszWKT != NULL && pszWKT[0] != '\0') { hSpatialRef = OSRNewSpatialReference(pszWKT); } GDALClose(hDS); } } hLayer = OGR_DS_CreateLayer( hTileIndexDS, pszLayerName, hSpatialRef, wkbPolygon, NULL ); CPLFree(pszLayerName); if (hSpatialRef) OSRRelease(hSpatialRef); if (hLayer) { OGRFieldDefnH hFieldDefn = OGR_Fld_Create( tile_index, OFTString ); OGR_Fld_SetWidth( hFieldDefn, 255); OGR_L_CreateField( hLayer, hFieldDefn, TRUE ); OGR_Fld_Destroy(hFieldDefn); } } } if( hTileIndexDS == NULL || hLayer == NULL ) { fprintf( stderr, "Unable to open/create shapefile `%s'.\n", index_filename ); exit(2); } hFDefn = OGR_L_GetLayerDefn(hLayer); for( ti_field = 0; ti_field < OGR_FD_GetFieldCount(hFDefn); ti_field++ ) { OGRFieldDefnH hFieldDefn = OGR_FD_GetFieldDefn( hFDefn, ti_field ); if( strcmp(OGR_Fld_GetNameRef(hFieldDefn), tile_index) == 0 ) break; } if( ti_field == OGR_FD_GetFieldCount(hFDefn) ) { fprintf( stderr, "Unable to find field `%s' in DBF file `%s'.\n", tile_index, index_filename ); exit(2); } /* Load in memory existing file names in SHP */ nExistingFiles = OGR_L_GetFeatureCount(hLayer, FALSE); if (nExistingFiles) { OGRFeatureH hFeature; existingFilesTab = (char**)CPLMalloc(nExistingFiles * sizeof(char*)); for(i=0;i<nExistingFiles;i++) { hFeature = OGR_L_GetNextFeature(hLayer); existingFilesTab[i] = CPLStrdup(OGR_F_GetFieldAsString( hFeature, ti_field )); if (i == 0) { GDALDatasetH hDS = GDALOpen(existingFilesTab[i], GA_ReadOnly ); if (hDS) { alreadyExistingProjectionRefValid = TRUE; alreadyExistingProjectionRef = CPLStrdup(GDALGetProjectionRef(hDS)); GDALClose(hDS); } } OGR_F_Destroy( hFeature ); } } if (write_absolute_path) { current_path = CPLGetCurrentDir(); if (current_path == NULL) { fprintf( stderr, "This system does not support the CPLGetCurrentDir call. " "The option -write_absolute_path will have no effect\n"); write_absolute_path = FALSE; } } /* -------------------------------------------------------------------- */ /* loop over GDAL files, processing. */ /* -------------------------------------------------------------------- */ for( ; i_arg < argc; i_arg++ ) { GDALDatasetH hDS; double adfGeoTransform[6]; double adfX[5], adfY[5]; int nXSize, nYSize; char* fileNameToWrite; const char* projectionRef; VSIStatBuf sStatBuf; int k; OGRFeatureH hFeature; OGRGeometryH hPoly, hRing; /* Make sure it is a file before building absolute path name */ if (write_absolute_path && CPLIsFilenameRelative( argv[i_arg] ) && VSIStat( argv[i_arg], &sStatBuf ) == 0) { fileNameToWrite = CPLStrdup(CPLProjectRelativeFilename(current_path, argv[i_arg])); } else { fileNameToWrite = CPLStrdup(argv[i_arg]); } /* Checks that file is not already in tileindex */ for(i=0;i<nExistingFiles;i++) { if (EQUAL(fileNameToWrite, existingFilesTab[i])) { fprintf(stderr, "File %s is already in tileindex. Skipping it.\n", fileNameToWrite); break; } } if (i != nExistingFiles) { CPLFree(fileNameToWrite); continue; } hDS = GDALOpen( argv[i_arg], GA_ReadOnly ); if( hDS == NULL ) { fprintf( stderr, "Unable to open %s, skipping.\n", argv[i_arg] ); CPLFree(fileNameToWrite); continue; } GDALGetGeoTransform( hDS, adfGeoTransform ); if( adfGeoTransform[0] == 0.0 && adfGeoTransform[1] == 1.0 && adfGeoTransform[3] == 0.0 && ABS(adfGeoTransform[5]) == 1.0 ) { fprintf( stderr, "It appears no georeferencing is available for\n" "`%s', skipping.\n", argv[i_arg] ); GDALClose( hDS ); CPLFree(fileNameToWrite); continue; } projectionRef = GDALGetProjectionRef(hDS); /* if not set target srs, test that the current file uses same projection as others */ if( !bSetTargetSRS ) { if (alreadyExistingProjectionRefValid) { int projectionRefNotNull, alreadyExistingProjectionRefNotNull; projectionRefNotNull = projectionRef && projectionRef[0]; alreadyExistingProjectionRefNotNull = alreadyExistingProjectionRef && alreadyExistingProjectionRef[0]; if ((projectionRefNotNull && alreadyExistingProjectionRefNotNull && EQUAL(projectionRef, alreadyExistingProjectionRef) == 0) || (projectionRefNotNull != alreadyExistingProjectionRefNotNull)) { fprintf(stderr, "Warning : %s is not using the same projection system as " "other files in the tileindex.\n" "This may cause problems when using it in MapServer for example.\n" "Use -t_srs option to set target projection system (not supported by MapServer).\n" "%s\n", argv[i_arg], (skip_different_projection) ? "Skipping this file." : ""); if (skip_different_projection) { CPLFree(fileNameToWrite); GDALClose( hDS ); continue; } } } else { alreadyExistingProjectionRefValid = TRUE; alreadyExistingProjectionRef = CPLStrdup(projectionRef); } } nXSize = GDALGetRasterXSize( hDS ); nYSize = GDALGetRasterYSize( hDS ); adfX[0] = adfGeoTransform[0] + 0 * adfGeoTransform[1] + 0 * adfGeoTransform[2]; adfY[0] = adfGeoTransform[3] + 0 * adfGeoTransform[4] + 0 * adfGeoTransform[5]; adfX[1] = adfGeoTransform[0] + nXSize * adfGeoTransform[1] + 0 * adfGeoTransform[2]; adfY[1] = adfGeoTransform[3] + nXSize * adfGeoTransform[4] + 0 * adfGeoTransform[5]; adfX[2] = adfGeoTransform[0] + nXSize * adfGeoTransform[1] + nYSize * adfGeoTransform[2]; adfY[2] = adfGeoTransform[3] + nXSize * adfGeoTransform[4] + nYSize * adfGeoTransform[5]; adfX[3] = adfGeoTransform[0] + 0 * adfGeoTransform[1] + nYSize * adfGeoTransform[2]; adfY[3] = adfGeoTransform[3] + 0 * adfGeoTransform[4] + nYSize * adfGeoTransform[5]; adfX[4] = adfGeoTransform[0] + 0 * adfGeoTransform[1] + 0 * adfGeoTransform[2]; adfY[4] = adfGeoTransform[3] + 0 * adfGeoTransform[4] + 0 * adfGeoTransform[5]; /* if set target srs, do the forward transformation of all points */ if( bSetTargetSRS ) { OGRSpatialReferenceH hSourceSRS = NULL; OGRCoordinateTransformationH hCT = NULL; hSourceSRS = OSRNewSpatialReference( projectionRef ); if( hSourceSRS && !OSRIsSame( hSourceSRS, hTargetSRS ) ) { hCT = OCTNewCoordinateTransformation( hSourceSRS, hTargetSRS ); if( hCT == NULL || !OCTTransform( hCT, 5, adfX, adfY, NULL ) ) { fprintf( stderr, "Warning : unable to transform points from source SRS `%s' to target SRS `%s'\n" "for file `%s' - file skipped\n", projectionRef, pszTargetSRS, fileNameToWrite ); if ( hCT ) OCTDestroyCoordinateTransformation( hCT ); if ( hSourceSRS ) OSRDestroySpatialReference( hSourceSRS ); continue; } if ( hCT ) OCTDestroyCoordinateTransformation( hCT ); } if ( hSourceSRS ) OSRDestroySpatialReference( hSourceSRS ); } hFeature = OGR_F_Create( OGR_L_GetLayerDefn( hLayer ) ); OGR_F_SetFieldString( hFeature, ti_field, fileNameToWrite ); hPoly = OGR_G_CreateGeometry(wkbPolygon); hRing = OGR_G_CreateGeometry(wkbLinearRing); for(k=0;k<5;k++) OGR_G_SetPoint_2D(hRing, k, adfX[k], adfY[k]); OGR_G_AddGeometryDirectly( hPoly, hRing ); OGR_F_SetGeometryDirectly( hFeature, hPoly ); if( OGR_L_CreateFeature( hLayer, hFeature ) != OGRERR_NONE ) { printf( "Failed to create feature in shapefile.\n" ); break; } OGR_F_Destroy( hFeature ); CPLFree(fileNameToWrite); GDALClose( hDS ); } CPLFree(current_path); if (nExistingFiles) { for(i=0;i<nExistingFiles;i++) { CPLFree(existingFilesTab[i]); } CPLFree(existingFilesTab); } CPLFree(alreadyExistingProjectionRef); if ( hTargetSRS ) OSRDestroySpatialReference( hTargetSRS ); OGR_DS_Destroy( hTileIndexDS ); GDALDestroyDriverManager(); OGRCleanupAll(); CSLDestroy(argv); exit( 0 ); }
int main( int argc, char ** argv ) { const char *pszLocX = NULL, *pszLocY = NULL; const char *pszSrcFilename = NULL; char *pszSourceSRS = NULL; std::vector<int> anBandList; bool bAsXML = false, bLIFOnly = false; bool bQuiet = false, bValOnly = false; int nOverview = -1; char **papszOpenOptions = NULL; GDALAllRegister(); argc = GDALGeneralCmdLineProcessor( argc, &argv, 0 ); if( argc < 1 ) exit( -argc ); /* -------------------------------------------------------------------- */ /* Parse arguments. */ /* -------------------------------------------------------------------- */ int i; for( i = 1; i < argc; i++ ) { if( EQUAL(argv[i], "--utility_version") ) { printf("%s was compiled against GDAL %s and is running against GDAL %s\n", argv[0], GDAL_RELEASE_NAME, GDALVersionInfo("RELEASE_NAME")); return 0; } else if( EQUAL(argv[i],"-b") && i < argc-1 ) { anBandList.push_back( atoi(argv[++i]) ); } else if( EQUAL(argv[i],"-overview") && i < argc-1 ) { nOverview = atoi(argv[++i]) - 1; } else if( EQUAL(argv[i],"-l_srs") && i < argc-1 ) { CPLFree(pszSourceSRS); pszSourceSRS = SanitizeSRS(argv[++i]); } else if( EQUAL(argv[i],"-geoloc") ) { CPLFree(pszSourceSRS); pszSourceSRS = CPLStrdup("-geoloc"); } else if( EQUAL(argv[i],"-wgs84") ) { CPLFree(pszSourceSRS); pszSourceSRS = SanitizeSRS("WGS84"); } else if( EQUAL(argv[i],"-xml") ) { bAsXML = true; } else if( EQUAL(argv[i],"-lifonly") ) { bLIFOnly = true; bQuiet = true; } else if( EQUAL(argv[i],"-valonly") ) { bValOnly = true; bQuiet = true; } else if( EQUAL(argv[i], "-oo") && i < argc-1 ) { papszOpenOptions = CSLAddString( papszOpenOptions, argv[++i] ); } else if( argv[i][0] == '-' && !isdigit(argv[i][1]) ) Usage(); else if( pszSrcFilename == NULL ) pszSrcFilename = argv[i]; else if( pszLocX == NULL ) pszLocX = argv[i]; else if( pszLocY == NULL ) pszLocY = argv[i]; else Usage(); } if( pszSrcFilename == NULL || (pszLocX != NULL && pszLocY == NULL) ) Usage(); /* -------------------------------------------------------------------- */ /* Open source file. */ /* -------------------------------------------------------------------- */ GDALDatasetH hSrcDS = NULL; hSrcDS = GDALOpenEx( pszSrcFilename, GDAL_OF_RASTER, NULL, (const char* const* )papszOpenOptions, NULL ); if( hSrcDS == NULL ) exit( 1 ); /* -------------------------------------------------------------------- */ /* Setup coordinate transformation, if required */ /* -------------------------------------------------------------------- */ OGRSpatialReferenceH hSrcSRS = NULL, hTrgSRS = NULL; OGRCoordinateTransformationH hCT = NULL; if( pszSourceSRS != NULL && !EQUAL(pszSourceSRS,"-geoloc") ) { hSrcSRS = OSRNewSpatialReference( pszSourceSRS ); hTrgSRS = OSRNewSpatialReference( GDALGetProjectionRef( hSrcDS ) ); hCT = OCTNewCoordinateTransformation( hSrcSRS, hTrgSRS ); if( hCT == NULL ) exit( 1 ); } /* -------------------------------------------------------------------- */ /* If no bands were requested, we will query them all. */ /* -------------------------------------------------------------------- */ if( anBandList.size() == 0 ) { for( i = 0; i < GDALGetRasterCount( hSrcDS ); i++ ) anBandList.push_back( i+1 ); } /* -------------------------------------------------------------------- */ /* Turn the location into a pixel and line location. */ /* -------------------------------------------------------------------- */ int inputAvailable = 1; double dfGeoX; double dfGeoY; CPLString osXML; if( pszLocX == NULL && pszLocY == NULL ) { if (fscanf(stdin, "%lf %lf", &dfGeoX, &dfGeoY) != 2) { inputAvailable = 0; } } else { dfGeoX = CPLAtof(pszLocX); dfGeoY = CPLAtof(pszLocY); } while (inputAvailable) { int iPixel, iLine; if (hCT) { if( !OCTTransform( hCT, 1, &dfGeoX, &dfGeoY, NULL ) ) exit( 1 ); } if( pszSourceSRS != NULL ) { double adfGeoTransform[6], adfInvGeoTransform[6]; if( GDALGetGeoTransform( hSrcDS, adfGeoTransform ) != CE_None ) { CPLError(CE_Failure, CPLE_AppDefined, "Cannot get geotransform"); exit( 1 ); } if( !GDALInvGeoTransform( adfGeoTransform, adfInvGeoTransform ) ) { CPLError(CE_Failure, CPLE_AppDefined, "Cannot invert geotransform"); exit( 1 ); } iPixel = (int) floor( adfInvGeoTransform[0] + adfInvGeoTransform[1] * dfGeoX + adfInvGeoTransform[2] * dfGeoY ); iLine = (int) floor( adfInvGeoTransform[3] + adfInvGeoTransform[4] * dfGeoX + adfInvGeoTransform[5] * dfGeoY ); } else { iPixel = (int) floor(dfGeoX); iLine = (int) floor(dfGeoY); } /* -------------------------------------------------------------------- */ /* Prepare report. */ /* -------------------------------------------------------------------- */ CPLString osLine; if( bAsXML ) { osLine.Printf( "<Report pixel=\"%d\" line=\"%d\">", iPixel, iLine ); osXML += osLine; } else if( !bQuiet ) { printf( "Report:\n" ); printf( " Location: (%dP,%dL)\n", iPixel, iLine ); } int bPixelReport = TRUE; if( iPixel < 0 || iLine < 0 || iPixel >= GDALGetRasterXSize( hSrcDS ) || iLine >= GDALGetRasterYSize( hSrcDS ) ) { if( bAsXML ) osXML += "<Alert>Location is off this file! No further details to report.</Alert>"; else if( bValOnly ) printf("\n"); else if( !bQuiet ) printf( "\nLocation is off this file! No further details to report.\n"); bPixelReport = FALSE; } /* -------------------------------------------------------------------- */ /* Process each band. */ /* -------------------------------------------------------------------- */ for( i = 0; bPixelReport && i < (int) anBandList.size(); i++ ) { GDALRasterBandH hBand = GDALGetRasterBand( hSrcDS, anBandList[i] ); int iPixelToQuery = iPixel; int iLineToQuery = iLine; if (nOverview >= 0 && hBand != NULL) { GDALRasterBandH hOvrBand = GDALGetOverview(hBand, nOverview); if (hOvrBand != NULL) { int nOvrXSize = GDALGetRasterBandXSize(hOvrBand); int nOvrYSize = GDALGetRasterBandYSize(hOvrBand); iPixelToQuery = (int)(0.5 + 1.0 * iPixel / GDALGetRasterXSize( hSrcDS ) * nOvrXSize); iLineToQuery = (int)(0.5 + 1.0 * iLine / GDALGetRasterYSize( hSrcDS ) * nOvrYSize); if (iPixelToQuery >= nOvrXSize) iPixelToQuery = nOvrXSize - 1; if (iLineToQuery >= nOvrYSize) iLineToQuery = nOvrYSize - 1; } else { CPLError(CE_Failure, CPLE_AppDefined, "Cannot get overview %d of band %d", nOverview + 1, anBandList[i] ); } hBand = hOvrBand; } if (hBand == NULL) continue; if( bAsXML ) { osLine.Printf( "<BandReport band=\"%d\">", anBandList[i] ); osXML += osLine; } else if( !bQuiet ) { printf( " Band %d:\n", anBandList[i] ); } /* -------------------------------------------------------------------- */ /* Request location info for this location. It is possible */ /* only the VRT driver actually supports this. */ /* -------------------------------------------------------------------- */ CPLString osItem; osItem.Printf( "Pixel_%d_%d", iPixelToQuery, iLineToQuery ); const char *pszLI = GDALGetMetadataItem( hBand, osItem, "LocationInfo"); if( pszLI != NULL ) { if( bAsXML ) osXML += pszLI; else if( !bQuiet ) printf( " %s\n", pszLI ); else if( bLIFOnly ) { /* Extract all files, if any. */ CPLXMLNode *psRoot = CPLParseXMLString( pszLI ); if( psRoot != NULL && psRoot->psChild != NULL && psRoot->eType == CXT_Element && EQUAL(psRoot->pszValue,"LocationInfo") ) { CPLXMLNode *psNode; for( psNode = psRoot->psChild; psNode != NULL; psNode = psNode->psNext ) { if( psNode->eType == CXT_Element && EQUAL(psNode->pszValue,"File") && psNode->psChild != NULL ) { char* pszUnescaped = CPLUnescapeString( psNode->psChild->pszValue, NULL, CPLES_XML); printf( "%s\n", pszUnescaped ); CPLFree(pszUnescaped); } } } CPLDestroyXMLNode( psRoot ); } } /* -------------------------------------------------------------------- */ /* Report the pixel value of this band. */ /* -------------------------------------------------------------------- */ double adfPixel[2]; if( GDALRasterIO( hBand, GF_Read, iPixelToQuery, iLineToQuery, 1, 1, adfPixel, 1, 1, GDT_CFloat64, 0, 0) == CE_None ) { CPLString osValue; if( GDALDataTypeIsComplex( GDALGetRasterDataType( hBand ) ) ) osValue.Printf( "%.15g+%.15gi", adfPixel[0], adfPixel[1] ); else osValue.Printf( "%.15g", adfPixel[0] ); if( bAsXML ) { osXML += "<Value>"; osXML += osValue; osXML += "</Value>"; } else if( !bQuiet ) printf( " Value: %s\n", osValue.c_str() ); else if( bValOnly ) printf( "%s\n", osValue.c_str() ); // Report unscaled if we have scale/offset values. int bSuccess; double dfOffset = GDALGetRasterOffset( hBand, &bSuccess ); double dfScale = GDALGetRasterScale( hBand, &bSuccess ); if( dfOffset != 0.0 || dfScale != 1.0 ) { adfPixel[0] = adfPixel[0] * dfScale + dfOffset; adfPixel[1] = adfPixel[1] * dfScale + dfOffset; if( GDALDataTypeIsComplex( GDALGetRasterDataType( hBand ) ) ) osValue.Printf( "%.15g+%.15gi", adfPixel[0], adfPixel[1] ); else osValue.Printf( "%.15g", adfPixel[0] ); if( bAsXML ) { osXML += "<DescaledValue>"; osXML += osValue; osXML += "</DescaledValue>"; } else if( !bQuiet ) printf( " Descaled Value: %s\n", osValue.c_str() ); } } if( bAsXML ) osXML += "</BandReport>"; } osXML += "</Report>"; if( (pszLocX != NULL && pszLocY != NULL) || (fscanf(stdin, "%lf %lf", &dfGeoX, &dfGeoY) != 2) ) { inputAvailable = 0; } } /* -------------------------------------------------------------------- */ /* Finalize xml report and print. */ /* -------------------------------------------------------------------- */ if( bAsXML ) { CPLXMLNode *psRoot; char *pszFormattedXML; psRoot = CPLParseXMLString( osXML ); pszFormattedXML = CPLSerializeXMLTree( psRoot ); CPLDestroyXMLNode( psRoot ); printf( "%s", pszFormattedXML ); CPLFree( pszFormattedXML ); } /* -------------------------------------------------------------------- */ /* Cleanup */ /* -------------------------------------------------------------------- */ if (hCT) { OSRDestroySpatialReference( hSrcSRS ); OSRDestroySpatialReference( hTrgSRS ); OCTDestroyCoordinateTransformation( hCT ); } if (hSrcDS) GDALClose(hSrcDS); GDALDumpOpenDatasets( stderr ); GDALDestroyDriverManager(); CPLFree(pszSourceSRS); CSLDestroy(papszOpenOptions); CSLDestroy( argv ); return 0; }
int NBHeightMapper::loadShapeFile(const std::string& file) { #ifdef HAVE_GDAL #if GDAL_VERSION_MAJOR < 2 OGRRegisterAll(); OGRDataSource* ds = OGRSFDriverRegistrar::Open(file.c_str(), FALSE); #else GDALAllRegister(); GDALDataset* ds = (GDALDataset*)GDALOpenEx(file.c_str(), GDAL_OF_VECTOR | GA_ReadOnly, NULL, NULL, NULL); #endif if (ds == NULL) { throw ProcessError("Could not open shape file '" + file + "'."); } // begin file parsing OGRLayer* layer = ds->GetLayer(0); layer->ResetReading(); // triangle coordinates are stored in WGS84 and later matched with network coordinates in WGS84 // build coordinate transformation OGRSpatialReference* sr_src = layer->GetSpatialRef(); OGRSpatialReference sr_dest; sr_dest.SetWellKnownGeogCS("WGS84"); OGRCoordinateTransformation* toWGS84 = OGRCreateCoordinateTransformation(sr_src, &sr_dest); if (toWGS84 == 0) { WRITE_WARNING("Could not create geocoordinates converter; check whether proj.4 is installed."); } int numFeatures = 0; OGRFeature* feature; layer->ResetReading(); while ((feature = layer->GetNextFeature()) != NULL) { OGRGeometry* geom = feature->GetGeometryRef(); assert(geom != 0); // @todo gracefull handling of shapefiles with unexpected contents or any error handling for that matter assert(std::string(geom->getGeometryName()) == std::string("POLYGON")); // try transform to wgs84 geom->transform(toWGS84); OGRLinearRing* cgeom = ((OGRPolygon*) geom)->getExteriorRing(); // assume TIN with with 4 points and point0 == point3 assert(cgeom->getNumPoints() == 4); PositionVector corners; for (int j = 0; j < 3; j++) { Position pos((double) cgeom->getX(j), (double) cgeom->getY(j), (double) cgeom->getZ(j)); corners.push_back(pos); myBoundary.add(pos); } addTriangle(corners); numFeatures++; /* OGRwkbGeometryType gtype = geom->getGeometryType(); switch (gtype) { case wkbPolygon: { break; } case wkbPoint: { WRITE_WARNING("got wkbPoint"); break; } case wkbLineString: { WRITE_WARNING("got wkbLineString"); break; } case wkbMultiPoint: { WRITE_WARNING("got wkbMultiPoint"); break; } case wkbMultiLineString: { WRITE_WARNING("got wkbMultiLineString"); break; } case wkbMultiPolygon: { WRITE_WARNING("got wkbMultiPolygon"); break; } default: WRITE_WARNING("Unsupported shape type occurred"); break; } */ OGRFeature::DestroyFeature(feature); } #if GDAL_VERSION_MAJOR < 2 OGRDataSource::DestroyDataSource(ds); #else GDALClose(ds); #endif OCTDestroyCoordinateTransformation(toWGS84); OGRCleanupAll(); return numFeatures; #else UNUSED_PARAMETER(file); WRITE_ERROR("Cannot load shape file since SUMO was compiled without GDAL support."); return 0; #endif }
~test_osr_ct_data() { OSRDestroySpatialReference(srs_utm_); OSRDestroySpatialReference(srs_ll_); OCTDestroyCoordinateTransformation(ct_); }
static CPLErr ProcessLayer( OGRLayerH hSrcLayer, int bSRSIsSet, GDALDatasetH hDstDS, std::vector<int> anBandList, const std::vector<double> &adfBurnValues, int b3D, int bInverse, const char *pszBurnAttribute, char **papszRasterizeOptions, GDALProgressFunc pfnProgress, void* pProgressData ) { /* -------------------------------------------------------------------- */ /* Checkout that SRS are the same. */ /* If -a_srs is specified, skip the test */ /* -------------------------------------------------------------------- */ OGRCoordinateTransformationH hCT = NULL; if (!bSRSIsSet) { OGRSpatialReferenceH hDstSRS = NULL; if( GDALGetProjectionRef( hDstDS ) != NULL ) { char *pszProjection; pszProjection = (char *) GDALGetProjectionRef( hDstDS ); hDstSRS = OSRNewSpatialReference(NULL); if( OSRImportFromWkt( hDstSRS, &pszProjection ) != OGRERR_NONE ) { OSRDestroySpatialReference(hDstSRS); hDstSRS = NULL; } } OGRSpatialReferenceH hSrcSRS = OGR_L_GetSpatialRef(hSrcLayer); if( hDstSRS != NULL && hSrcSRS != NULL ) { if( OSRIsSame(hSrcSRS, hDstSRS) == FALSE ) { hCT = OCTNewCoordinateTransformation(hSrcSRS, hDstSRS); if( hCT == NULL ) { CPLError(CE_Warning, CPLE_AppDefined, "The output raster dataset and the input vector layer do not have the same SRS.\n" "And reprojection of input data did not work. Results might be incorrect."); } } } else if( hDstSRS != NULL && hSrcSRS == NULL ) { CPLError(CE_Warning, CPLE_AppDefined, "The output raster dataset has a SRS, but the input vector layer SRS is unknown.\n" "Ensure input vector has the same SRS, otherwise results might be incorrect."); } else if( hDstSRS == NULL && hSrcSRS != NULL ) { CPLError(CE_Warning, CPLE_AppDefined, "The input vector layer has a SRS, but the output raster dataset SRS is unknown.\n" "Ensure output raster dataset has the same SRS, otherwise results might be incorrect."); } if( hDstSRS != NULL ) { OSRDestroySpatialReference(hDstSRS); } } /* -------------------------------------------------------------------- */ /* Get field index, and check. */ /* -------------------------------------------------------------------- */ int iBurnField = -1; if( pszBurnAttribute ) { iBurnField = OGR_FD_GetFieldIndex( OGR_L_GetLayerDefn( hSrcLayer ), pszBurnAttribute ); if( iBurnField == -1 ) { CPLError(CE_Failure, CPLE_AppDefined, "Failed to find field %s on layer %s, skipping.", pszBurnAttribute, OGR_FD_GetName( OGR_L_GetLayerDefn( hSrcLayer ) ) ); if( hCT != NULL ) OCTDestroyCoordinateTransformation(hCT); return CE_Failure; } } /* -------------------------------------------------------------------- */ /* Collect the geometries from this layer, and build list of */ /* burn values. */ /* -------------------------------------------------------------------- */ OGRFeatureH hFeat; std::vector<OGRGeometryH> ahGeometries; std::vector<double> adfFullBurnValues; OGR_L_ResetReading( hSrcLayer ); while( (hFeat = OGR_L_GetNextFeature( hSrcLayer )) != NULL ) { OGRGeometryH hGeom; if( OGR_F_GetGeometryRef( hFeat ) == NULL ) { OGR_F_Destroy( hFeat ); continue; } hGeom = OGR_G_Clone( OGR_F_GetGeometryRef( hFeat ) ); if( hCT != NULL ) { if( OGR_G_Transform(hGeom, hCT) != OGRERR_NONE ) { OGR_F_Destroy( hFeat ); OGR_G_DestroyGeometry(hGeom); continue; } } ahGeometries.push_back( hGeom ); for( unsigned int iBand = 0; iBand < anBandList.size(); iBand++ ) { if( adfBurnValues.size() > 0 ) adfFullBurnValues.push_back( adfBurnValues[MIN(iBand,adfBurnValues.size()-1)] ); else if( pszBurnAttribute ) { adfFullBurnValues.push_back( OGR_F_GetFieldAsDouble( hFeat, iBurnField ) ); } /* I have made the 3D option exclusive to other options since it can be used to modify the value from "-burn value" or "-a attribute_name" */ if( b3D ) { // TODO: get geometry "z" value /* Points and Lines will have their "z" values collected at the point and line levels respectively. However filled polygons (GDALdllImageFilledPolygon) can use some help by getting their "z" values here. */ adfFullBurnValues.push_back( 0.0 ); } } OGR_F_Destroy( hFeat ); } if( hCT != NULL ) OCTDestroyCoordinateTransformation(hCT); /* -------------------------------------------------------------------- */ /* If we are in inverse mode, we add one extra ring around the */ /* whole dataset to invert the concept of insideness and then */ /* merge everything into one geometry collection. */ /* -------------------------------------------------------------------- */ if( bInverse ) { if( ahGeometries.size() == 0 ) { for( unsigned int iBand = 0; iBand < anBandList.size(); iBand++ ) { if( adfBurnValues.size() > 0 ) adfFullBurnValues.push_back( adfBurnValues[MIN(iBand,adfBurnValues.size()-1)] ); else /* FIXME? Not sure what to do exactly in the else case, but we must insert a value */ adfFullBurnValues.push_back( 0.0 ); } } InvertGeometries( hDstDS, ahGeometries ); } /* -------------------------------------------------------------------- */ /* Perform the burn. */ /* -------------------------------------------------------------------- */ CPLErr eErr = GDALRasterizeGeometries( hDstDS, static_cast<int>(anBandList.size()), &(anBandList[0]), static_cast<int>(ahGeometries.size()), &(ahGeometries[0]), NULL, NULL, &(adfFullBurnValues[0]), papszRasterizeOptions, pfnProgress, pProgressData ); /* -------------------------------------------------------------------- */ /* Cleanup geometries. */ /* -------------------------------------------------------------------- */ int iGeom; for( iGeom = static_cast<int>(ahGeometries.size())-1; iGeom >= 0; iGeom-- ) OGR_G_DestroyGeometry( ahGeometries[iGeom] ); return eErr; }
~GeoTransform() { if (m_transformation != nullptr) { OCTDestroyCoordinateTransformation(m_transformation); } }
int SpatialReference::computeUTMZone(const BOX3D& box) const { // Nothing we can do if we're an empty SRS if (empty()) return 0; OGRSpatialReferenceH current = OSRNewSpatialReference(getWKT(eHorizontalOnly, false).c_str()); if (! current) throw std::invalid_argument("Could not fetch current SRS"); OGRSpatialReferenceH wgs84 = OSRNewSpatialReference(0); if (OSRSetFromUserInput(wgs84, "EPSG:4326") != OGRERR_NONE) { OSRDestroySpatialReference(current); OSRDestroySpatialReference(wgs84); std::ostringstream msg; msg << "Could not import GDAL input spatial reference for WGS84"; throw std::runtime_error(msg.str()); } void* transform = OCTNewCoordinateTransformation(current, wgs84); if (! transform) { OSRDestroySpatialReference(current); OSRDestroySpatialReference(wgs84); throw std::invalid_argument("could not comput transform from " "coordinate system to WGS84"); } double minx(0.0), miny(0.0), minz(0.0); double maxx(0.0), maxy(0.0), maxz(0.0); // OCTTransform modifies values in-place minx = box.minx; miny = box.miny; minz = box.minz; maxx = box.maxx; maxy = box.maxy; maxz = box.maxz; int ret = OCTTransform(transform, 1, &minx, &miny, &minz); if (ret == 0) { OCTDestroyCoordinateTransformation(transform); OSRDestroySpatialReference(current); OSRDestroySpatialReference(wgs84); std::ostringstream msg; msg << "Could not project minimum point for computeUTMZone::" << CPLGetLastErrorMsg() << ret; throw pdal_error(msg.str()); } ret = OCTTransform(transform, 1, &maxx, &maxy, &maxz); if (ret == 0) { OCTDestroyCoordinateTransformation(transform); OSRDestroySpatialReference(current); OSRDestroySpatialReference(wgs84); std::ostringstream msg; msg << "Could not project maximum point for computeUTMZone::" << CPLGetLastErrorMsg() << ret; throw pdal_error(msg.str()); } int min_zone(0); int max_zone(0); min_zone = calculateZone(minx, miny); max_zone = calculateZone(maxx, maxy); if (min_zone != max_zone) { OCTDestroyCoordinateTransformation(transform); OSRDestroySpatialReference(current); OSRDestroySpatialReference(wgs84); std::ostringstream msg; msg << "Minimum zone is " << min_zone <<"' and maximum zone is '" << max_zone << "'. They do not match because they cross a " "zone boundary"; throw pdal_error(msg.str()); } OCTDestroyCoordinateTransformation(transform); OSRDestroySpatialReference(current); OSRDestroySpatialReference(wgs84); return min_zone; }
static int GDALInfoReportCorner( GDALDatasetH hDataset, const char * corner_name, double x, double y ) { double dfGeoX, dfGeoY; const char *pszProjection; double adfGeoTransform[6]; OGRCoordinateTransformationH hTransform = NULL; printf( "%-11s ", corner_name ); /* -------------------------------------------------------------------- */ /* Transform the point into georeferenced coordinates. */ /* -------------------------------------------------------------------- */ if( GDALGetGeoTransform( hDataset, adfGeoTransform ) == CE_None ) { pszProjection = GDALGetProjectionRef(hDataset); dfGeoX = adfGeoTransform[0] + adfGeoTransform[1] * x + adfGeoTransform[2] * y; dfGeoY = adfGeoTransform[3] + adfGeoTransform[4] * x + adfGeoTransform[5] * y; } else { printf( "(%7.1f,%7.1f)\n", x, y ); return FALSE; } /* -------------------------------------------------------------------- */ /* Report the georeferenced coordinates. */ /* -------------------------------------------------------------------- */ if( fabs(dfGeoX) < 181 && fabs(dfGeoY) < 91 ) { printf( "(%12.7f,%12.7f) ", dfGeoX, dfGeoY ); } else { printf( "(%12.3f,%12.3f) ", dfGeoX, dfGeoY ); } /* -------------------------------------------------------------------- */ /* Setup transformation to lat/long. */ /* -------------------------------------------------------------------- */ if( pszProjection != NULL && strlen(pszProjection) > 0 ) { OGRSpatialReferenceH hProj, hLatLong = NULL; hProj = OSRNewSpatialReference( pszProjection ); if( hProj != NULL ) hLatLong = OSRCloneGeogCS( hProj ); if( hLatLong != NULL ) { hTransform = OCTNewCoordinateTransformation( hProj, hLatLong ); OSRDestroySpatialReference( hLatLong ); } if( hProj != NULL ) OSRDestroySpatialReference( hProj ); } /* -------------------------------------------------------------------- */ /* Transform to latlong and report. */ /* -------------------------------------------------------------------- */ if( hTransform != NULL && OCTTransform(hTransform,1,&dfGeoX,&dfGeoY,NULL) ) { printf( "(%s,", GDALDecToDMS( dfGeoX, "Long", 2 ) ); printf( "%s)", GDALDecToDMS( dfGeoY, "Lat", 2 ) ); } if( hTransform != NULL ) OCTDestroyCoordinateTransformation( hTransform ); printf( "\n" ); return TRUE; }
bool SubrasterByVector(wxGISFeatureDatasetSPtr pSrcFeatureDataSet, wxGISRasterDatasetSPtr pSrcRasterDataSet, CPLString &szDstFolderPath, wxGxRasterFilter* pFilter, GDALDataType eOutputType, int nBandCount, int *panBandList, bool bUseCounter, int nCounterBegin, int nFieldNo, double dfOutResX, double dfOutResY, bool bCopyNodata, bool bSkipSourceMetadata, char** papszOptions, ITrackCancel* pTrackCancel) { //check if openned or/and open dataset if(!pSrcFeatureDataSet->IsOpened()) { if(!pSrcFeatureDataSet->Open(true)) { if(pTrackCancel) pTrackCancel->PutMessage(_("Source vector dataset open failed"), -1, enumGISMessageErr); return false; } } if(!pSrcRasterDataSet->IsOpened()) { if(!pSrcRasterDataSet->Open(true)) { if(pTrackCancel) pTrackCancel->PutMessage(_("Source raster dataset open failed"), -1, enumGISMessageErr); return false; } } const OGRSpatialReferenceSPtr pSrsSRS = pSrcFeatureDataSet->GetSpatialReference(); const OGRSpatialReferenceSPtr pDstSRS = pSrcRasterDataSet->GetSpatialReference(); OGRCoordinateTransformation *poCT(NULL); bool bSame = pSrsSRS == NULL || pDstSRS == NULL || pSrsSRS->IsSame(pDstSRS.get()); if( !bSame ) { poCT = OGRCreateCoordinateTransformation( pSrsSRS.get(), pDstSRS.get() ); if(poCT == NULL) { const char* err = CPLGetLastErrorMsg(); wxString sWarn = wxString::Format(_("Create OGRCreateCoordinateTransformation failed! GDAL error: %s"), wxString(err, wxConvUTF8).c_str()); wxLogWarning(sWarn); if(pTrackCancel) pTrackCancel->PutMessage(sWarn, -1, enumGISMessageWarning); } } IProgressor* pProgressor(NULL); if(pTrackCancel) { pProgressor = pTrackCancel->GetProgressor(); pTrackCancel->PutMessage(wxString::Format(_("Start clip '%s' by geometry from '%s'"), wxString(pSrcRasterDataSet->GetPath(), wxConvUTF8).c_str(), wxString(pSrcFeatureDataSet->GetPath(), wxConvUTF8).c_str()), -1, enumGISMessageNorm); } int nCounter(0); if(pProgressor) pProgressor->SetRange(pSrcFeatureDataSet->GetFeatureCount()); /* -------------------------------------------------------------------- */ /* Build band list to translate */ /* -------------------------------------------------------------------- */ if( nBandCount == 0 ) { nBandCount = pSrcRasterDataSet->GetBandCount(); if( nBandCount == 0 ) { if(pTrackCancel) pTrackCancel->PutMessage(_("Input file has no bands, and so cannot be translated."), -1, enumGISMessageErr); return false; } panBandList = (int *) CPLMalloc(sizeof(int)*nBandCount); for(size_t i = 0; i < nBandCount; ++i ) panBandList[i] = i + 1; } else { for(size_t i = 0; i < nBandCount; ++i ) { if( panBandList[i] > pSrcRasterDataSet->GetBandCount() ) { if(pTrackCancel) pTrackCancel->PutMessage(wxString::Format(_("Band %d requested, but only bands 1 to %d available."), panBandList[i], pSrcRasterDataSet->GetBandCount()), -1, enumGISMessageErr); return false; } } } bool bDefaultfilter(false); if(pFilter == NULL) { pFilter = new wxGxRasterFilter(enumRasterTiff); bDefaultfilter = true; } CPLString szDriver(pFilter->GetDriver().mb_str()); CPLString szExt(pFilter->GetExt().mb_str()); CPLString szBaseName = CPLGetBasename(pSrcRasterDataSet->GetPath()); GDALDriver* pDriver = (GDALDriver*)GDALGetDriverByName( szDriver ); if( pDriver == NULL ) { if(pTrackCancel) pTrackCancel->PutMessage(wxString::Format(_("Output driver '%s' not recognised."), szDriver.c_str()), -1, enumGISMessageErr); if(bDefaultfilter) wxDELETE(pFilter); return false; } pSrcFeatureDataSet->Reset(); OGRFeatureSPtr pFeature; size_t nNameCounter(nCounterBegin); while((pFeature = pSrcFeatureDataSet->Next()) != NULL) { if(pTrackCancel && !pTrackCancel->Continue()) { wxString sErr(_("Interrupted by user")); CPLString sFullErr(sErr.mb_str()); CPLError( CE_Warning, CPLE_AppDefined, sFullErr ); if(pTrackCancel) pTrackCancel->PutMessage(wxString(sFullErr, wxConvLocal), -1, enumGISMessageErr); if(bDefaultfilter) wxDELETE(pFilter); return false; } OGRGeometry *pGeom = pFeature->GetGeometryRef(); if(wkbFlatten(pSrcFeatureDataSet->GetGeometryType()) != wkbUnknown && !pGeom) continue; OGRGeometry *pNewGeom(NULL); if( !bSame && poCT ) { if(pGeom) { pNewGeom = pGeom->clone(); OGRErr eErr = pNewGeom->transform(poCT); if(eErr != OGRERR_NONE) wxDELETE(pNewGeom); } } else pNewGeom = pGeom->clone(); OGREnvelope GeomEnv; pNewGeom->getEnvelope(&GeomEnv); OGREnvelope RasterEnv = pSrcRasterDataSet->GetEnvelope(); GeomEnv.Intersect(RasterEnv); if(GeomEnv.IsInit()) { CPLString szPath; if(bUseCounter) { szPath.Printf("%s_%d", szBaseName.c_str(), nNameCounter++); CPLString sNewName(CheckUniqName(szDstFolderPath, szPath, szExt).mb_str(wxConvUTF8)); szPath = CPLFormFilename(szDstFolderPath, sNewName, szExt); } else { CPLString szName = pFeature->GetFieldAsString(nFieldNo); CPLString sNewName(CheckUniqName(szDstFolderPath, szName, szExt).mb_str(wxConvUTF8)); szPath = CPLFormFilename(szDstFolderPath, sNewName, szExt); } CreateSubRaster(pSrcRasterDataSet, GeomEnv, pNewGeom, pDriver, szPath, eOutputType, nBandCount, panBandList, dfOutResX, dfOutResY, bCopyNodata, bSkipSourceMetadata, papszOptions, pTrackCancel); } nCounter++; if(pProgressor) pProgressor->SetValue(nCounter); } if(poCT) OCTDestroyCoordinateTransformation(poCT); if(bDefaultfilter) wxDELETE(pFilter); return true; }