This document is intended to document the OGR classes. The OGR classes are intended to be generic (not specific to OLE DB or COM or Windows) but are used as a foundation for implementing OLE DB Provider support, as well as client side support for SFCOM. It is intended that these same OGR classes could be used by an implementation of SFCORBA for instance or used directly by C++ programs wanting to use an OpenGIS simple features inspired API.
Because OGR is modeled on the OpenGIS simple features data model, it is very helpful to review the SFCOM, or other simple features interface specifications which can be retrieved from the Open Geospatial Consortium web site. Data types, and method names are modeled on those from the interface specifications.
Geometry (ogr_geometry.h): The geometry classes (OGRGeometry, etc) encapsulate the OpenGIS model vector data as well as providing some geometry operations, and translation to/from well known binary and text format. A geometry includes a spatial reference system (projection).
The geometry classes are represent various kinds of vector geometry. All the geometry classes derived from OGRGeometry which defines the common services of all geometries. Types of geometry include OGRPoint, OGRLineString, OGRPolygon, OGRGeometryCollection, OGRMultiPolygon, OGRMultiPoint, and OGRMultiLineString.
Additional intermediate abstract base classes contain functionality that could eventually be implemented by other geometry types. These include OGRCurve (base class for OGRLineString) and OGRSurface (base class for OGRPolygon). Some intermediate interfaces modeled in the simple features abstract model and SFCOM are not modeled in OGR at this time. In most cases the methods are aggregated into other classes.
The OGRGeometryFactory is used to convert well known text, and well known binary format data into geometries. These are predefined ASCII and binary formats for representing all the types of simple features geometries.
In a manner based on the geometry object in SFCOM, the OGRGeometry includes a reference to an OGRSpatialReference object, defining the spatial reference system of that geometry. This is normally a reference to a shared spatial reference object with reference counting for each of the OGRGeometry objects using it.
Many of the spatial analysis methods (such as computing overlaps and so forth) are not implemented at this time for OGRGeometry.
While it is theoretically possible to derive other or more specific geometry classes from the existing OGRGeometry classes, this isn't an aspect that has been well thought out. In particular, it would be possible to create specialized classes using the OGRGeometryFactory without modifying it.
Generic mechanisms have been introduced so that creating or modifying a feature with a non-linear geometry in a layer of a driver that does not support it will transform that geometry in the closest matching linear geometry.
On the other side, when retrieving data from the OGR C API, the OGRSetNonLinearGeometriesEnabledFlag() function can be used, so that geometries and layer geometry type returned are also converted to their linear approximation if necessary.
The OGRSpatialReference class is intended to store an OpenGIS Spatial Reference System definition. Currently local, geographic and projected coordinate systems are supported. Vertical coordinate systems, geocentric coordinate systems, and compound (horizontal + vertical) coordinate systems are as well supported in recent GDAL versions.
The spatial coordinate system data model is inherited from the OpenGIS Well Known Text format. A simple form of this is defined in the Simple Features specifications. A more sophisticated form is found in the Coordinate Transformation specification. The OGRSpatialReference is built on the features of the Coordinate Transformation specification but is intended to be compatible with the earlier simple features form.
There is also an associated OGRCoordinateTransformation class that encapsulates use of PROJ.4 for converting between different coordinate systems. There is a tutorial available describing how to use the OGRSpatialReference class.
The OGRGeometry captures the geometry of a vector feature ... the spatial position/region of a feature. The OGRFeature contains this geometry, and adds feature attributes, feature id, and a feature class identifier. Starting with OGR 1.11, several geometries can be associated to a OGRFeature.
The set of attributes, their types, names and so forth is represented via the OGRFeatureDefn class. One OGRFeatureDefn normally exists for a layer of features. The same definition is shared in a reference counted manner by the feature of that type (or feature class).
The feature id (FID) of a feature is intended to be a unique identifier for the feature within the layer it is a member of. Freestanding features, or features not yet written to a layer may have a null (OGRNullFID) feature id. The feature ids are modeled in OGR as a 64-bit integer (GDAL 2.0 or later); however, this is not sufficiently expressive to model the natural feature ids in some formats. For instance, the GML feature id is a string.
The feature class also contains an indicator of the types of geometry allowed for that feature class (returned as an OGRwkbGeometryType from OGRFeatureDefn::GetGeomType()). If this is wkbUnknown then any type of geometry is allowed. This implies that features in a given layer can potentially be of different geometry types though they will always share a common attribute schema.
Starting with OGR 1.11, several geometry fields can be associated to a feature class. Each geometry field has its own indicator of geometry type allowed, returned by OGRGeomFieldDefn::GetType(), and its spatial reference system, returned by OGRGeomFieldDefn::GetSpatialRef().
The OGRFeatureDefn also contains a feature class name (normally used as a layer name).
An OGRLayer represents a layer of features within a data source. All features in an OGRLayer share a common schema and are of the same OGRFeatureDefn. An OGRLayer class also contains methods for reading features from the data source. The OGRLayer can be thought of as a gateway for reading and writing features from an underlying data source, normally a file format. In SFCOM and other table based simple features implementation an OGRLayer represents a spatial table.
The OGRLayer includes methods for sequential and random reading and writing. Read access (via the OGRLayer::GetNextFeature() method) normally reads all features, one at a time sequentially; however, it can be limited to return features intersecting a particular geographic region by installing a spatial filter on the OGRLayer (via the OGRLayer::SetSpatialFilter() method).
One flaw in the current OGR architecture is that the spatial filter is set directly on the OGRLayer which is intended to be the only representative of a given layer in a data source. This means it isn't possible to have multiple read operations active at one time with different spatial filters on each. This aspect may be revised in the future to introduce an OGRLayerView class or something similar.
Another question that might arise is why the OGRLayer and OGRFeatureDefn classes are distinct. An OGRLayer always has a one-to-one relationship to an OGRFeatureDefn, so why not amalgamate the classes. There are two reasons:
The SF CORBA model does not have a concept of a layer with a single fixed schema the way that the SFCOM and SFSQL models do. The fact that features belong to a feature collection that is potentially not directly related to their current feature grouping may be important to implementing SFCORBA support using OGR.
The OGRLayer class is an abstract base class. An implementation is expected to be subclassed for each file format driver implemented. OGRLayers are normally owned directly by their GDALDataset, and aren't instantiated or destroyed directly.
A GDALDataset represents a set of OGRLayer objects. This usually represents a single file, set of files, database or gateway. A GDALDataset has a list of OGRLayers which it owns but can return references to.
GDALDataset is an abstract base class. An implementation is expected to be subclassed for each file format driver implemented. GDALDataset objects are not normally instantiated directly but rather with the assistance of an GDALDriver. Deleting an GDALDataset closes access to the underlying persistent data source, but does not normally result in deletion of that file.
The GDALDataset also has support for executing a datasource specific command, normally a form of SQL. This is accomplished via the GDALDataset::ExecuteSQL() method. While some datasources (such as PostGIS and Oracle) pass the SQL through to an underlying database, OGR also includes support for evaluating a subset of the SQL SELECT statement against any datasource.
It is intended that a new GDALDriver object is instantiated and define function pointers for operations like Identify(), Open() for each file format to be supported (along with a file format specific GDALDataset, and OGRLayer classes).
On application startup registration functions are normally called for each desired file format. These functions instantiate the appropriate GDALDriver objects, and register them with the GDALDriverManager. When a dataset is to be opened, the driver manager will normally try each GDALDataset in turn, until one succeeds, returning a GDALDataset object.