public override FeatureList process(Feature input, FilterEnv env) { FeatureList output = new FeatureList(); if (transform != null && !transform.Identity()) { foreach (GeoShape shape in input.getShapes()) { XformVisitor visitor = new XformVisitor(); visitor.trans = transform; shape.accept(visitor); } } output.Add(input); return(output); #if TODO // resolve the xlate shortcut Matrix working_matrix = xform_matrix; // TODO: this can go into process(FeatureList) instead of running for every feature.. if (getTranslateScript() != null) { ScriptResult r = env.getScriptEngine().run(getTranslateScript(), input, env); if (r.isValid()) { working_matrix = Matrix.translate(r.asVec3()); } else { env.getReport().error(r.asString()); } } if (working_srs != null || (working_matrix != null && !working_matrix.IsIdentity)) { foreach (GeoShape shape in input.getShapes()) { if (working_matrix != null && !working_matrix.IsIdentity) { XformVisitor visitor; visitor.mat = working_matrix; shape.accept(visitor); } if (working_srs != null && !working_srs.equivalentTo(env.getInputSRS())) { working_srs.transformInPlace(shape); } } } output.Add(input); return(output); #endif throw new NotImplementedException(); }
public override FeatureList process(FeatureList input, FilterEnv env) { FeatureList output = new FeatureList(); //Boolean encontrado = false; SharpMap.Geometries.BoundingBox boundingBox = new SharpMap.Geometries.BoundingBox(longitudeMin, latitudeMin, longitudeMax, latitudeMax); foreach (Feature feature in input) { //if type of features is Point if (feature.row.Geometry is SharpMap.Geometries.Point) { SharpMap.Geometries.Point p = (SharpMap.Geometries.Point)feature.row.Geometry; if (boundingBox.Contains(p.GetBoundingBox())) { output.Add(feature); } } //if type of features is Polygon else if (feature.row.Geometry is SharpMap.Geometries.Polygon) { SharpMap.Geometries.Polygon polygon = (SharpMap.Geometries.Polygon)feature.row.Geometry; if (boundingBox.Contains(polygon.GetBoundingBox())) { output.Add(feature); } } //if type of features is MultiPolygon else if (feature.row.Geometry is SharpMap.Geometries.MultiPolygon) { SharpMap.Geometries.MultiPolygon mp = (SharpMap.Geometries.MultiPolygon)feature.row.Geometry; SharpMap.Geometries.BoundingBox bb = mp.GetBoundingBox(); if (boundingBox.Contains(bb)) { output.Add(feature); } } } if (successor != null) { if (successor is FeatureFilter) { FeatureFilter filter = (FeatureFilter)successor; FeatureList l = filter.process(output, env); } else if (successor is FragmentFilter) { FragmentFilter filter = (FragmentFilter)successor; FragmentList l = filter.process(output, env); } } return(output); }
/** * Processes a single Feature. * * @param input * Individual Feature to process. * @param env * Runtime processing environment. * @return * A collection of Feature instances. The default implementation * of this method just returns the input in a list. */ public virtual FeatureList process(Feature input, FilterEnv env) { FeatureList output = new FeatureList(); output.Add(input); return(output); }
public FeatureList Convert(ResolutionContext context) { List <FeatureDto> list = context.SourceValue as List <FeatureDto>; FeatureList namedlist = new FeatureList(); foreach (FeatureDto v in list) { namedlist.Add(Mapper.Map <Feature> (v)); } return(namedlist); }
public static FeatureList DataTableToList(FeatureDataTable table) { FeatureList list = new FeatureList(); foreach (FeatureDataRow row in table) { Feature f = new Feature(); f.setFeature(row); list.Add(f); } return(list); }
/// <summary> /// 根据ShpReader和DbfReader创建FeatureSet /// </summary> /// <param name="shpReader"></param> /// <param name="dbfReader"></param> /// <param name="recordNum"></param> /// <returns></returns> private static FeatureSet CreateFeatureSet(ShpReader shpReader, DbfReader dbfReader, int recordNum) { GeometryType geometryType = (GeometryType)shpReader.ShpHeader.ShapeType; var featureType = ShpUtil .GeometryType2FeatureType(geometryType); FeatureSet fs = new FeatureSet(featureType); IFeatureList features = new FeatureList(fs); for (int i = 0; i < recordNum; i++) { var spatialBytes = shpReader.GetNextRecord(); dbfReader.GetNextRow(); IGeometry geometry; switch (geometryType) { case GeometryType.Point: geometry = BytesToGeometry.CreatePoint(spatialBytes); break; case GeometryType.MultiPoint: geometry = BytesToGeometry.CreateMultipoint(spatialBytes); break; case GeometryType.PolyLine: geometry = BytesToGeometry.CreatePolyLine(spatialBytes); break; case GeometryType.Polygon: geometry = BytesToGeometry.CreatePolygon(spatialBytes); break; default: geometry = null; break; } IFeature feature = new Feature(geometry); features.Add(feature); } fs.Features.Set(features); fs.AttrTable = dbfReader.DbfTable; var header = shpReader.ShpHeader; //fs.Envelope = new Envelope(header.XMin, header.YMin, // header.XMax, header.YMax, // header.ZMin, header.ZMax); return(fs); }
public override FeatureList process(FeatureList input, FilterEnv env) { FeatureList output = new FeatureList(); foreach (Feature feature in input) { //engine.run(script, feature, null); if (feature.row[attributeName].ToString().ToLowerInvariant() == attributeValue) { output.Add(feature); } } return(output); }
public Main() { _quoteDictionary = new Dictionary <string, Quote>(); FeatureList.Add(FeaturesT.SUPPORTS_REALTIME_OPTIONS_CHAIN); FeatureList.Add(FeaturesT.SUPPORTS_REALTIME_STOCK_QUOTE); FeatureList.Add(FeaturesT.SUPPORTS_STOCK_HISTORICAL_DATA); FeatureList.Add(FeaturesT.SUPPORTS_OPTIONS_HISTORICAL_DATA); FeatureList.Add(FeaturesT.SUPPORTS_HISTORICAL_VOLATILITY); FeatureList.Add(FeaturesT.SUPPORTS_INTEREST_RATE); // update server list ServerList.Add(Name); _B3Poviderconfig = new B3ProviderConfig(); _B3PoviderClient = new B3ProviderClient(_B3Poviderconfig); }
private void LoadFeatureList() { if (FeatureList.Count == 0) { var section = (FeatureListConfigHandler)ConfigurationManager.GetSection("FeatureList"); if (section != null) { foreach (FeatureElement featureItem in section.FeatureItems) { if (!FeatureList.ContainsKey(featureItem.Name)) { FeatureList.Add(featureItem.Name, featureItem.IsEnabled); } } } } }
override public FeatureList process(Feature input, FilterEnv env) { FeatureList output = new FeatureList(); //resolve the xlate shortcut Mogre.Matrix4 workingMatrix = Matrix; //TODO: this can go into process (FeatureList) instead of running for every feature.. if (TranslateScript != null) { ScriptResult r = env.getScriptEngine().run(TranslateScript, input, env); if (r.isValid()) { workingMatrix.MakeTrans(new Mogre.Vector3((float)r.asVec3().x, (float)r.asVec3().y, (float)r.asVec3().z)); } else { env.getReport().error(r.asString()); } } if (workingSrs != null || (workingMatrix != null && workingMatrix != Mogre.Matrix4.IDENTITY)) { //TODO foreach (Geometry shape in input.getGeometry()) //{ // if (workingMatrix != null && !workingMatrix.Equals(Mogre.Matrix4.IDENTITY)) // { // XformVisitor visitor = new XformVisitor(); // visitor.mat = workingMatrix; // shape.accept(visitor); // } // if (workingSrs != null && !(workingSrs.equivalentTo(env.getInputSRS()))) // { // workingSrs.transformInPlace(shape); // } //} if (workingSrs != null && !(workingSrs.equivalentTo(env.getInputSRS()))) { Geometry temp = GeometryTransform.TransformGeometry(input.getGeometry(), ((SharpMapSpatialReference)workingSrs).MathTransform); input.setGeometry(temp); //workingSrs.transformInPlace(input.getGeometry()); } } output.Add(input); return(output); }
public override FeatureList process(FeatureList input, FilterEnv env) { FeatureList output = new FeatureList(); //Boolean encontrado = false; SharpMap.Geometries.BoundingBox boundingBox = new SharpMap.Geometries.BoundingBox(longitudeMin,latitudeMin,longitudeMax,latitudeMax); foreach (Feature feature in input) { //if type of features is Point if (feature.row.Geometry is SharpMap.Geometries.Point) { SharpMap.Geometries.Point p = (SharpMap.Geometries.Point)feature.row.Geometry; if (boundingBox.Contains(p.GetBoundingBox())) { output.Add(feature); } } //if type of features is Polygon else if (feature.row.Geometry is SharpMap.Geometries.Polygon) { SharpMap.Geometries.Polygon polygon = (SharpMap.Geometries.Polygon)feature.row.Geometry; if (boundingBox.Contains(polygon.GetBoundingBox())) { output.Add(feature); } } //if type of features is MultiPolygon else if (feature.row.Geometry is SharpMap.Geometries.MultiPolygon) { SharpMap.Geometries.MultiPolygon mp = (SharpMap.Geometries.MultiPolygon)feature.row.Geometry; SharpMap.Geometries.BoundingBox bb = mp.GetBoundingBox(); if (boundingBox.Contains(bb)) { output.Add(feature); } } } if (successor != null) { if (successor is FeatureFilter) { FeatureFilter filter = (FeatureFilter)successor; FeatureList l = filter.process(output, env); } else if (successor is FragmentFilter) { FragmentFilter filter = (FragmentFilter)successor; FragmentList l = filter.process(output, env); } } return output; }
override public FeatureList process(Feature input, FilterEnv env) { FeatureList output = new FeatureList(); //resolve the xlate shortcut Mogre.Matrix4 workingMatrix = Matrix; //TODO: this can go into process (FeatureList) instead of running for every feature.. if (TranslateScript != null) { ScriptResult r = env.getScriptEngine().run(TranslateScript, input, env); if (r.isValid()) { workingMatrix.MakeTrans(new Mogre.Vector3((float)r.asVec3().x, (float)r.asVec3().y, (float)r.asVec3().z)); } else { env.getReport().error(r.asString()); } } if (workingSrs != null || (workingMatrix != null && workingMatrix != Mogre.Matrix4.IDENTITY)) { //TODO foreach (Geometry shape in input.getGeometry()) //{ // if (workingMatrix != null && !workingMatrix.Equals(Mogre.Matrix4.IDENTITY)) // { // XformVisitor visitor = new XformVisitor(); // visitor.mat = workingMatrix; // shape.accept(visitor); // } // if (workingSrs != null && !(workingSrs.equivalentTo(env.getInputSRS()))) // { // workingSrs.transformInPlace(shape); // } //} if (workingSrs != null && !(workingSrs.equivalentTo(env.getInputSRS()))) { Geometry temp = GeometryTransform.TransformGeometry(input.getGeometry(), ((SharpMapSpatialReference)workingSrs).MathTransform); input.setGeometry(temp); //workingSrs.transformInPlace(input.getGeometry()); } } output.Add(input); return output; }
public void AddFeature(Feature feature) { FeatureList.Add(feature); }
public override FeatureList process(FeatureList input, FilterEnv env) { FeatureList output = new FeatureList(); // HACER ALGO DEL ESTILO: if (transform == null) { //Create zone UTM 32N projection IProjectedCoordinateSystem utmProj = CreateUtmProjection(32); //Create geographic coordinate system (lets just reuse the CS from the projection) IGeographicCoordinateSystem geoCS = utmProj.GeographicCoordinateSystem; //Create transformation CoordinateTransformationFactory ctFac = new CoordinateTransformationFactory(); // TODO DANI Mirar de donde viene este source y target ICoordinateTransformation Coordinatetransform = null;// TODO = ctFac.CreateFromCoordinateSystems(source, target); //cs string wkt = "GEOGCS[\"GCS_WGS_1984\",DATUM[\"D_WGS_1984\",SPHEROID[\"WGS_1984\",6378137,298.257223563]],PRIMEM[\"Greenwich\",0],UNIT[\"Degree\",0.0174532925199433]]"; //ICoordinateSystem cs = SharpMap.Converters.WellKnownText.CoordinateSystemWktReader.Parse(wkt) as ICoordinateSystem; ICoordinateSystem cs = ProjNet.Converters.WellKnownText.CoordinateSystemWktReader.Parse(wkt) as ICoordinateSystem; //wgs84 GeographicCoordinateSystem wgs84 = GeographicCoordinateSystem.WGS84; //gcs CoordinateSystemFactory cFac = new ProjNet.CoordinateSystems.CoordinateSystemFactory(); //CoordinateSystemFactory cFac = new SharpMap.CoordinateSystems.CoordinateSystemFactory(); //Create Bessel 1840 geographic coordinate system IEllipsoid ellipsoid = cFac.CreateFlattenedSphere("Bessel 1840", 6377397.155, 299.15281, LinearUnit.Metre); IHorizontalDatum datum = cFac.CreateHorizontalDatum("Bessel 1840", DatumType.HD_Geocentric, ellipsoid, null); IGeographicCoordinateSystem gcs = cFac.CreateGeographicCoordinateSystem("Bessel 1840", AngularUnit.Degrees, datum, PrimeMeridian.Greenwich, new AxisInfo("Lon", AxisOrientationEnum.East), new AxisInfo("Lat", AxisOrientationEnum.North)); //coordsys //Collection<ProjectionParameter> parameters = new Collection<ProjectionParameter>(5); List <ProjectionParameter> parameters = new List <ProjectionParameter>(); parameters.Add(new ProjectionParameter("latitude_of_origin", 0)); parameters.Add(new ProjectionParameter("central_meridian", 110)); parameters.Add(new ProjectionParameter("scale_factor", 0.997)); parameters.Add(new ProjectionParameter("false_easting", 3900000)); parameters.Add(new ProjectionParameter("false_northing", 900000)); IProjection projection = cFac.CreateProjection("Mercator_1SP", "Mercator_1SP", parameters); IProjectedCoordinateSystem coordsys = cFac.CreateProjectedCoordinateSystem("Makassar / NEIEZ", gcs, projection, LinearUnit.Metre, new AxisInfo("East", AxisOrientationEnum.East), new AxisInfo("North", AxisOrientationEnum.North)); Coordinatetransform = ctFac.CreateFromCoordinateSystems(gcs, coordsys);//gcsWGS84 -> gcenCsWGS84 //Apply transformation transform = Coordinatetransform.MathTransform; } SharpMap.Geometries.Point p = new SharpMap.Geometries.Point(30.0, 20.0); p = GeometryTransform.TransformPoint(p, transform); /*IMPORTANTE * foreach (Feature feature in input) * { * feature.row.Geometry = GeometryTransform.TransformGeometry(feature.row.Geometry, transform); * //feature.row.Geometry = GeometryTransform.TransformMultiPolygon(feature.row.Geometry, transform); * } * IMPORTANTE*/ foreach (Feature f in input) { output.Add(f);//output = input } // Cosas a cambiar: // Primero, la construccion del transform está siguiendo el ejemplo, pero hay que tener en cuenta los datos del xml y construirlo en consecuencia // Segundo, el filtro debe retornar una NUEVA lista, y no modificar la inicial. Ahora modifica los valores de la lista inicial // IMPORTANTE RETORNAR NUEVA LISTA OUTPUT <----------- FALTA POR HACER #if TODO // first time through, establish a working SRS for output data. if (working_srs == null) { // first try to use the terrain SRS if so directed: SpatialReference new_out_srs = getUseTerrainSRS() ? env.getTerrainSRS() : null; if (new_out_srs == null) { // failing that, see if we have an SRS in a resource: if (getSRS() == null && getSRSScript() != null) { ScriptResult r = env.getScriptEngine().run(getSRSScript(), env); if (r.isValid()) { setSRS(env.getSession().getResources().getSRS(r.ToString())); } else { env.getReport().error(r.ToString()); } } new_out_srs = srs; } // set the "working" SRS that will be used for all features passing though this filter: working_srs = new_out_srs != null ? new_out_srs : env.getInputSRS(); // LOCALIZE points around a local origin (the working extent's centroid) if (working_srs != null && getLocalize()) //&& env.getExtent().getArea() > 0.0 ) { if (env.getCellExtent().getSRS().isGeographic() && env.getCellExtent().getWidth() > 179.0) { //NOP - no localization for big geog extent ... needs more thought perhaps } else { GeoPoint centroid0 = new_out_srs != null? new_out_srs.transform(env.getCellExtent().getCentroid()) : env.getCellExtent().getCentroid(); // we do want the localizer point on the surface if possible: GeoPoint centroid = clampToTerrain(centroid0, env); if (centroid == null) { centroid = centroid0; } Matrixd localizer; // For geocentric datasets, we need a special localizer matrix: if (working_srs.isGeocentric()) { localizer = working_srs.getEllipsoid().createGeocentricInvRefFrame(centroid); localizer.invert(localizer); } // For projected datasets, just a simple translation: else { localizer = osg.Matrixd.translate(-centroid); } working_srs = working_srs.cloneWithNewReferenceFrame(localizer); } } } // we have to assign the output SRS on each pass if (working_srs != null) { env.setOutputSRS(working_srs); } return(base.process(input, env)); #endif //throw new NotImplementedException(); if (successor != null) { if (successor is FeatureFilter) { FeatureFilter filter = (FeatureFilter)successor; FeatureList l = filter.process(output, env); } else if (successor is FragmentFilter) { FragmentFilter filter = (FragmentFilter)successor; FragmentList l = filter.process(output, env); } } return(output); }
/** * Processes a single Feature. * * @param input * Individual Feature to process. * @param env * Runtime processing environment. * @return * A collection of Feature instances. The default implementation * of this method just returns the input in a list. */ public virtual FeatureList process(Feature input, FilterEnv env) { FeatureList output = new FeatureList(); output.Add(input); return output; }
public override FeatureList process(FeatureList input, FilterEnv env) { FeatureList output = new FeatureList(); // HACER ALGO DEL ESTILO: if (transform == null) { //Create zone UTM 32N projection IProjectedCoordinateSystem utmProj = CreateUtmProjection(32); //Create geographic coordinate system (lets just reuse the CS from the projection) IGeographicCoordinateSystem geoCS = utmProj.GeographicCoordinateSystem; //Create transformation CoordinateTransformationFactory ctFac = new CoordinateTransformationFactory(); // TODO DANI Mirar de donde viene este source y target ICoordinateTransformation Coordinatetransform = null;// TODO = ctFac.CreateFromCoordinateSystems(source, target); //cs string wkt = "GEOGCS[\"GCS_WGS_1984\",DATUM[\"D_WGS_1984\",SPHEROID[\"WGS_1984\",6378137,298.257223563]],PRIMEM[\"Greenwich\",0],UNIT[\"Degree\",0.0174532925199433]]"; //ICoordinateSystem cs = SharpMap.Converters.WellKnownText.CoordinateSystemWktReader.Parse(wkt) as ICoordinateSystem; ICoordinateSystem cs = ProjNet.Converters.WellKnownText.CoordinateSystemWktReader.Parse(wkt) as ICoordinateSystem; //wgs84 GeographicCoordinateSystem wgs84 = GeographicCoordinateSystem.WGS84; //gcs CoordinateSystemFactory cFac = new ProjNet.CoordinateSystems.CoordinateSystemFactory(); //CoordinateSystemFactory cFac = new SharpMap.CoordinateSystems.CoordinateSystemFactory(); //Create Bessel 1840 geographic coordinate system IEllipsoid ellipsoid = cFac.CreateFlattenedSphere("Bessel 1840", 6377397.155, 299.15281, LinearUnit.Metre); IHorizontalDatum datum = cFac.CreateHorizontalDatum("Bessel 1840", DatumType.HD_Geocentric, ellipsoid, null); IGeographicCoordinateSystem gcs = cFac.CreateGeographicCoordinateSystem("Bessel 1840", AngularUnit.Degrees, datum, PrimeMeridian.Greenwich, new AxisInfo("Lon", AxisOrientationEnum.East), new AxisInfo("Lat", AxisOrientationEnum.North)); //coordsys //Collection<ProjectionParameter> parameters = new Collection<ProjectionParameter>(5); List<ProjectionParameter> parameters = new List<ProjectionParameter>(); parameters.Add(new ProjectionParameter("latitude_of_origin", 0)); parameters.Add(new ProjectionParameter("central_meridian", 110)); parameters.Add(new ProjectionParameter("scale_factor", 0.997)); parameters.Add(new ProjectionParameter("false_easting", 3900000)); parameters.Add(new ProjectionParameter("false_northing", 900000)); IProjection projection = cFac.CreateProjection("Mercator_1SP", "Mercator_1SP", parameters); IProjectedCoordinateSystem coordsys = cFac.CreateProjectedCoordinateSystem("Makassar / NEIEZ", gcs, projection, LinearUnit.Metre, new AxisInfo("East", AxisOrientationEnum.East), new AxisInfo("North", AxisOrientationEnum.North)); Coordinatetransform = ctFac.CreateFromCoordinateSystems(gcs, coordsys);//gcsWGS84 -> gcenCsWGS84 //Apply transformation transform = Coordinatetransform.MathTransform; } SharpMap.Geometries.Point p = new SharpMap.Geometries.Point(30.0, 20.0); p = GeometryTransform.TransformPoint(p,transform); /*IMPORTANTE foreach (Feature feature in input) { feature.row.Geometry = GeometryTransform.TransformGeometry(feature.row.Geometry, transform); //feature.row.Geometry = GeometryTransform.TransformMultiPolygon(feature.row.Geometry, transform); } IMPORTANTE*/ foreach (Feature f in input) { output.Add(f);//output = input } // Cosas a cambiar: // Primero, la construccion del transform está siguiendo el ejemplo, pero hay que tener en cuenta los datos del xml y construirlo en consecuencia // Segundo, el filtro debe retornar una NUEVA lista, y no modificar la inicial. Ahora modifica los valores de la lista inicial // IMPORTANTE RETORNAR NUEVA LISTA OUTPUT <----------- FALTA POR HACER #if TODO // first time through, establish a working SRS for output data. if (working_srs == null) { // first try to use the terrain SRS if so directed: SpatialReference new_out_srs = getUseTerrainSRS() ? env.getTerrainSRS() : null; if (new_out_srs == null) { // failing that, see if we have an SRS in a resource: if (getSRS() == null && getSRSScript() != null) { ScriptResult r = env.getScriptEngine().run(getSRSScript(), env); if (r.isValid()) setSRS(env.getSession().getResources().getSRS(r.ToString())); else env.getReport().error(r.ToString()); } new_out_srs = srs; } // set the "working" SRS that will be used for all features passing though this filter: working_srs = new_out_srs != null ? new_out_srs : env.getInputSRS(); // LOCALIZE points around a local origin (the working extent's centroid) if (working_srs != null && getLocalize()) //&& env.getExtent().getArea() > 0.0 ) { if (env.getCellExtent().getSRS().isGeographic() && env.getCellExtent().getWidth() > 179.0) { //NOP - no localization for big geog extent ... needs more thought perhaps } else { GeoPoint centroid0 = new_out_srs != null ? new_out_srs.transform(env.getCellExtent().getCentroid()) : env.getCellExtent().getCentroid(); // we do want the localizer point on the surface if possible: GeoPoint centroid = clampToTerrain(centroid0, env); if (centroid == null) centroid = centroid0; Matrixd localizer; // For geocentric datasets, we need a special localizer matrix: if (working_srs.isGeocentric()) { localizer = working_srs.getEllipsoid().createGeocentricInvRefFrame(centroid); localizer.invert(localizer); } // For projected datasets, just a simple translation: else { localizer = osg.Matrixd.translate(-centroid); } working_srs = working_srs.cloneWithNewReferenceFrame(localizer); } } } // we have to assign the output SRS on each pass if (working_srs != null) { env.setOutputSRS(working_srs); } return base.process(input, env); #endif //throw new NotImplementedException(); if (successor != null) { if (successor is FeatureFilter) { FeatureFilter filter = (FeatureFilter)successor; FeatureList l = filter.process(output, env); } else if (successor is FragmentFilter) { FragmentFilter filter = (FragmentFilter)successor; FragmentList l = filter.process(output, env); } } return output; }
public override FeatureList process(Feature input, FilterEnv env) { FeatureList output = new FeatureList(); if (transform != null && !transform.Identity()) { foreach (GeoShape shape in input.getShapes()) { XformVisitor visitor = new XformVisitor(); visitor.trans = transform; shape.accept(visitor); } } output.Add(input); return output; #if TODO // resolve the xlate shortcut Matrix working_matrix = xform_matrix; // TODO: this can go into process(FeatureList) instead of running for every feature.. if (getTranslateScript() != null) { ScriptResult r = env.getScriptEngine().run(getTranslateScript(), input, env); if (r.isValid()) working_matrix = Matrix.translate(r.asVec3()); else env.getReport().error(r.asString()); } if (working_srs != null || (working_matrix != null && !working_matrix.IsIdentity)) { foreach (GeoShape shape in input.getShapes()) { if (working_matrix != null && !working_matrix.IsIdentity) { XformVisitor visitor; visitor.mat = working_matrix; shape.accept(visitor); } if (working_srs != null && !working_srs.equivalentTo(env.getInputSRS())) { working_srs.transformInPlace(shape); } } } output.Add(input); return output; #endif throw new NotImplementedException(); }