============================= Geographic Database Functions ============================= .. module:: django.contrib.gis.db.models.functions :synopsis: Geographic Database Functions The functions documented on this page allow users to access geographic database functions to be used in annotations, aggregations, or filters in Django. Example: .. code-block:: pycon >>> from django.contrib.gis.db.models.functions import Length >>> Track.objects.annotate(length=Length("line")).filter(length__gt=100) Not all backends support all functions, so refer to the documentation of each function to see if your database backend supports the function you want to use. If you call a geographic function on a backend that doesn't support it, you'll get a ``NotImplementedError`` exception. Function's summary: ========================= ======================== ====================== ======================= ================== ================== ====================== Measurement Relationships Operations Editors Input format Output format Miscellaneous ========================= ======================== ====================== ======================= ================== ================== ====================== :class:`Area` :class:`Azimuth` :class:`Difference` :class:`ForcePolygonCW` :class:`AsGeoJSON` :class:`IsEmpty` :class:`Distance` :class:`BoundingCircle` :class:`Intersection` :class:`MakeValid` :class:`AsGML` :class:`IsValid` :class:`GeometryDistance` :class:`Centroid` :class:`SymDifference` :class:`Reverse` :class:`AsKML` :class:`MemSize` :class:`Length` :class:`ClosestPoint` :class:`Union` :class:`Scale` :class:`AsSVG` :class:`NumGeometries` :class:`Perimeter` :class:`Envelope` :class:`SnapToGrid` :class:`FromWKB` :class:`AsWKB` :class:`NumPoints` :class:`LineLocatePoint` :class:`Transform` :class:`FromWKT` :class:`AsWKT` :class:`PointOnSurface` :class:`Translate` :class:`GeoHash` ========================= ======================== ====================== ======================= ================== ================== ====================== ``Area`` ======== .. class:: Area(expression, **extra) *Availability*: MariaDB, `MySQL `_, Oracle, `PostGIS `__, SpatiaLite Accepts a single geographic field or expression and returns the area of the field as an :class:`~django.contrib.gis.measure.Area` measure. MySQL and SpatiaLite without LWGEOM/RTTOPO don't support area calculations on geographic SRSes. ``AsGeoJSON`` ============= .. class:: AsGeoJSON(expression, bbox=False, crs=False, precision=8, **extra) *Availability*: MariaDB, `MySQL `__, Oracle, `PostGIS `__, SpatiaLite Accepts a single geographic field or expression and returns a `GeoJSON `_ representation of the geometry. Note that the result is not a complete GeoJSON structure but only the ``geometry`` key content of a GeoJSON structure. See also :doc:`/ref/contrib/gis/serializers`. Example: .. code-block:: pycon >>> City.objects.annotate(json=AsGeoJSON("point")).get(name="Chicago").json {"type":"Point","coordinates":[-87.65018,41.85039]} ===================== ===================================================== Keyword Argument Description ===================== ===================================================== ``bbox`` Set this to ``True`` if you want the bounding box to be included in the returned GeoJSON. Ignored on Oracle. ``crs`` Set this to ``True`` if you want the coordinate reference system to be included in the returned GeoJSON. Ignored on MySQL and Oracle. ``precision`` It may be used to specify the number of significant digits for the coordinates in the GeoJSON representation -- the default value is 8. Ignored on Oracle. ===================== ===================================================== ``AsGML`` ========= .. class:: AsGML(expression, version=2, precision=8, **extra) *Availability*: Oracle, `PostGIS `__, SpatiaLite Accepts a single geographic field or expression and returns a `Geographic Markup Language (GML)`__ representation of the geometry. Example: .. code-block:: pycon >>> qs = Zipcode.objects.annotate(gml=AsGML("poly")) >>> print(qs[0].gml) -147.78711,70.245363 ... -147.78711,70.245363 ===================== ===================================================== Keyword Argument Description ===================== ===================================================== ``precision`` Specifies the number of significant digits for the coordinates in the GML representation -- the default value is 8. Ignored on Oracle. ``version`` Specifies the GML version to use: 2 (default) or 3. ===================== ===================================================== __ https://en.wikipedia.org/wiki/Geography_Markup_Language ``AsKML`` ========= .. class:: AsKML(expression, precision=8, **extra) *Availability*: `PostGIS `__, SpatiaLite Accepts a single geographic field or expression and returns a `Keyhole Markup Language (KML)`__ representation of the geometry. Example: .. code-block:: pycon >>> qs = Zipcode.objects.annotate(kml=AsKML("poly")) >>> print(qs[0].kml) -103.04135,36.217596,0 ... -103.04135,36.217596,0 ===================== ===================================================== Keyword Argument Description ===================== ===================================================== ``precision`` This keyword may be used to specify the number of significant digits for the coordinates in the KML representation -- the default value is 8. ===================== ===================================================== __ https://developers.google.com/kml/documentation/ ``AsSVG`` ========= .. class:: AsSVG(expression, relative=False, precision=8, **extra) *Availability*: `PostGIS `__, SpatiaLite Accepts a single geographic field or expression and returns a `Scalable Vector Graphics (SVG)`__ representation of the geometry. ===================== ===================================================== Keyword Argument Description ===================== ===================================================== ``relative`` If set to ``True``, the path data will be implemented in terms of relative moves. Defaults to ``False``, meaning that absolute moves are used instead. ``precision`` This keyword may be used to specify the number of significant digits for the coordinates in the SVG representation -- the default value is 8. ===================== ===================================================== __ https://www.w3.org/Graphics/SVG/ ``AsWKB`` ========= .. class:: AsWKB(expression, **extra) *Availability*: MariaDB, `MySQL `__, Oracle, `PostGIS `__, SpatiaLite Accepts a single geographic field or expression and returns a `Well-known binary (WKB)`_ representation of the geometry. Example: .. code-block:: pycon >>> bytes(City.objects.annotate(wkb=AsWKB("point")).get(name="Chelyabinsk").wkb) b'\x01\x01\x00\x00\x00]3\xf9f\x9b\x91K@\x00X\x1d9\xd2\xb9N@' ``AsWKT`` ========= .. class:: AsWKT(expression, **extra) *Availability*: MariaDB, `MySQL `__, Oracle, `PostGIS `__, SpatiaLite Accepts a single geographic field or expression and returns a `Well-known text (WKT)`_ representation of the geometry. Example: .. code-block:: pycon >>> City.objects.annotate(wkt=AsWKT("point")).get(name="Chelyabinsk").wkt 'POINT (55.137555 61.451728)' ``Azimuth`` =========== .. class:: Azimuth(point_a, point_b, **extra) *Availability*: `PostGIS `__, SpatiaLite (LWGEOM/RTTOPO) Returns the azimuth in radians of the segment defined by the given point geometries, or ``None`` if the two points are coincident. The azimuth is angle referenced from north and is positive clockwise: north = ``0``; east = ``π/2``; south = ``π``; west = ``3π/2``. ``BoundingCircle`` ================== .. class:: BoundingCircle(expression, num_seg=48, **extra) *Availability*: `PostGIS `__, `Oracle `_, SpatiaLite 5.1+ Accepts a single geographic field or expression and returns the smallest circle polygon that can fully contain the geometry. The ``num_seg`` parameter is used only on PostGIS. .. versionchanged:: 5.1 SpatiaLite 5.1+ support was added. ``Centroid`` ============ .. class:: Centroid(expression, **extra) *Availability*: MariaDB, `MySQL `__, `PostGIS `__, Oracle, SpatiaLite Accepts a single geographic field or expression and returns the ``centroid`` value of the geometry. ``ClosestPoint`` ================ .. versionadded:: 5.0 .. class:: ClosestPoint(expr1, expr2, **extra) *Availability*: `PostGIS `__, SpatiaLite Accepts two geographic fields or expressions and returns the 2-dimensional point on geometry A that is closest to geometry B. ``Difference`` ============== .. class:: Difference(expr1, expr2, **extra) *Availability*: MariaDB, `MySQL `__, `PostGIS `__, Oracle, SpatiaLite Accepts two geographic fields or expressions and returns the geometric difference, that is the part of geometry A that does not intersect with geometry B. ``Distance`` ============ .. class:: Distance(expr1, expr2, spheroid=None, **extra) *Availability*: MariaDB, `MySQL `__, `PostGIS `__, Oracle, SpatiaLite Accepts two geographic fields or expressions and returns the distance between them, as a :class:`~django.contrib.gis.measure.Distance` object. On MySQL, a raw float value is returned when the coordinates are geodetic. On backends that support distance calculation on geodetic coordinates, the proper backend function is automatically chosen depending on the SRID value of the geometries (e.g. `ST_DistanceSphere `__ on PostGIS). When distances are calculated with geodetic (angular) coordinates, as is the case with the default WGS84 (4326) SRID, you can set the ``spheroid`` keyword argument to decide if the calculation should be based on a simple sphere (less accurate, less resource-intensive) or on a spheroid (more accurate, more resource-intensive). In the following example, the distance from the city of Hobart to every other :class:`~django.contrib.gis.db.models.PointField` in the ``AustraliaCity`` queryset is calculated: .. code-block:: pycon >>> from django.contrib.gis.db.models.functions import Distance >>> pnt = AustraliaCity.objects.get(name="Hobart").point >>> for city in AustraliaCity.objects.annotate(distance=Distance("point", pnt)): ... print(city.name, city.distance) ... Wollongong 990071.220408 m Shellharbour 972804.613941 m Thirroul 1002334.36351 m ... .. note:: Because the ``distance`` attribute is a :class:`~django.contrib.gis.measure.Distance` object, you can easily express the value in the units of your choice. For example, ``city.distance.mi`` is the distance value in miles and ``city.distance.km`` is the distance value in kilometers. See :doc:`measure` for usage details and the list of :ref:`supported_units`. ``Envelope`` ============ .. class:: Envelope(expression, **extra) *Availability*: MariaDB, `MySQL `__, `Oracle `__, `PostGIS `__, SpatiaLite Accepts a single geographic field or expression and returns the geometry representing the bounding box of the geometry. ``ForcePolygonCW`` ================== .. class:: ForcePolygonCW(expression, **extra) *Availability*: `PostGIS `__, SpatiaLite Accepts a single geographic field or expression and returns a modified version of the polygon/multipolygon in which all exterior rings are oriented clockwise and all interior rings are oriented counterclockwise. Non-polygonal geometries are returned unchanged. ``FromWKB`` =========== .. class:: FromWKB(expression, **extra) *Availability*: MariaDB, `MySQL `__, Oracle, `PostGIS `__, SpatiaLite Creates geometry from `Well-known binary (WKB)`_ representation. ``FromWKT`` =========== .. class:: FromWKT(expression, **extra) *Availability*: MariaDB, `MySQL `__, Oracle, `PostGIS `__, SpatiaLite Creates geometry from `Well-known text (WKT)`_ representation. ``GeoHash`` =========== .. class:: GeoHash(expression, precision=None, **extra) *Availability*: `MySQL `__, `PostGIS `__, SpatiaLite (LWGEOM/RTTOPO) Accepts a single geographic field or expression and returns a `GeoHash`__ representation of the geometry. The ``precision`` keyword argument controls the number of characters in the result. __ https://en.wikipedia.org/wiki/Geohash ``GeometryDistance`` ==================== .. class:: GeometryDistance(expr1, expr2, **extra) *Availability*: `PostGIS `__ Accepts two geographic fields or expressions and returns the distance between them. When used in an :meth:`~django.db.models.query.QuerySet.order_by` clause, it provides index-assisted nearest-neighbor result sets. ``Intersection`` ================ .. class:: Intersection(expr1, expr2, **extra) *Availability*: MariaDB, `MySQL `__, `PostGIS `__, Oracle, SpatiaLite Accepts two geographic fields or expressions and returns the geometric intersection between them. ``IsEmpty`` =========== .. class:: IsEmpty(expr) *Availability*: `PostGIS `__ Accepts a geographic field or expression and tests if the value is an empty geometry. Returns ``True`` if its value is empty and ``False`` otherwise. ``IsValid`` =========== .. class:: IsValid(expr) *Availability*: `MySQL `__, `PostGIS `__, Oracle, SpatiaLite Accepts a geographic field or expression and tests if the value is well formed. Returns ``True`` if its value is a valid geometry and ``False`` otherwise. ``Length`` ========== .. class:: Length(expression, spheroid=True, **extra) *Availability*: MariaDB, `MySQL `__, Oracle, `PostGIS `__, SpatiaLite Accepts a single geographic linestring or multilinestring field or expression and returns its length as a :class:`~django.contrib.gis.measure.Distance` measure. On PostGIS and SpatiaLite, when the coordinates are geodetic (angular), you can specify if the calculation should be based on a simple sphere (less accurate, less resource-intensive) or on a spheroid (more accurate, more resource-intensive) with the ``spheroid`` keyword argument. MySQL doesn't support length calculations on geographic SRSes. ``LineLocatePoint`` =================== .. class:: LineLocatePoint(linestring, point, **extra) *Availability*: `PostGIS `__, SpatiaLite Returns a float between 0 and 1 representing the location of the closest point on ``linestring`` to the given ``point``, as a fraction of the 2D line length. ``MakeValid`` ============= .. class:: MakeValid(expr) *Availability*: `PostGIS `__, SpatiaLite (LWGEOM/RTTOPO) Accepts a geographic field or expression and attempts to convert the value into a valid geometry without losing any of the input vertices. Geometries that are already valid are returned without changes. Simple polygons might become a multipolygon and the result might be of lower dimension than the input. ``MemSize`` =========== .. class:: MemSize(expression, **extra) *Availability*: `PostGIS `__ Accepts a single geographic field or expression and returns the memory size (number of bytes) that the geometry field takes. ``NumGeometries`` ================= .. class:: NumGeometries(expression, **extra) *Availability*: MariaDB, `MySQL `__, `PostGIS `__, Oracle, SpatiaLite Accepts a single geographic field or expression and returns the number of geometries if the geometry field is a collection (e.g., a ``GEOMETRYCOLLECTION`` or ``MULTI*`` field). Returns 1 for single geometries. On MySQL, returns ``None`` for single geometries. ``NumPoints`` ============= .. class:: NumPoints(expression, **extra) *Availability*: MariaDB, `MySQL `__, `PostGIS `__, Oracle, SpatiaLite Accepts a single geographic field or expression and returns the number of points in a geometry. On MySQL, returns ``None`` for any non-``LINESTRING`` geometry. ``Perimeter`` ============= .. class:: Perimeter(expression, **extra) *Availability*: `PostGIS `__, Oracle, SpatiaLite Accepts a single geographic field or expression and returns the perimeter of the geometry field as a :class:`~django.contrib.gis.measure.Distance` object. ``PointOnSurface`` ================== .. class:: PointOnSurface(expression, **extra) *Availability*: `PostGIS `__, MariaDB, Oracle, SpatiaLite Accepts a single geographic field or expression and returns a ``Point`` geometry guaranteed to lie on the surface of the field; otherwise returns ``None``. ``Reverse`` =========== .. class:: Reverse(expression, **extra) *Availability*: `PostGIS `__, Oracle, SpatiaLite Accepts a single geographic field or expression and returns a geometry with reversed coordinates. ``Scale`` ========= .. class:: Scale(expression, x, y, z=0.0, **extra) *Availability*: `PostGIS `__, SpatiaLite Accepts a single geographic field or expression and returns a geometry with scaled coordinates by multiplying them with the ``x``, ``y``, and optionally ``z`` parameters. ``SnapToGrid`` ============== .. class:: SnapToGrid(expression, *args, **extra) *Availability*: `PostGIS `__, SpatiaLite Accepts a single geographic field or expression and returns a geometry with all points snapped to the given grid. How the geometry is snapped to the grid depends on how many numeric (either float, integer, or long) arguments are given. =================== ===================================================== Number of Arguments Description =================== ===================================================== 1 A single size to snap both the X and Y grids to. 2 X and Y sizes to snap the grid to. 4 X, Y sizes and the corresponding X, Y origins. =================== ===================================================== ``SymDifference`` ================= .. class:: SymDifference(expr1, expr2, **extra) *Availability*: MariaDB, `MySQL `__, `PostGIS `__, Oracle, SpatiaLite Accepts two geographic fields or expressions and returns the geometric symmetric difference (union without the intersection) between the given parameters. ``Transform`` ============= .. class:: Transform(expression, srid, **extra) *Availability*: `PostGIS `__, Oracle, SpatiaLite Accepts a geographic field or expression and a SRID integer code, and returns the transformed geometry to the spatial reference system specified by the ``srid`` parameter. .. note:: What spatial reference system an integer SRID corresponds to may depend on the spatial database used. In other words, the SRID numbers used for Oracle are not necessarily the same as those used by PostGIS. ``Translate`` ============= .. class:: Translate(expression, x, y, z=0.0, **extra) *Availability*: `PostGIS `__, SpatiaLite Accepts a single geographic field or expression and returns a geometry with its coordinates offset by the ``x``, ``y``, and optionally ``z`` numeric parameters. ``Union`` ========= .. class:: Union(expr1, expr2, **extra) *Availability*: MariaDB, `MySQL `__, `PostGIS `__, Oracle, SpatiaLite Accepts two geographic fields or expressions and returns the union of both geometries. .. _`Well-known binary (WKB)`: https://en.wikipedia.org/wiki/Well-known_text_representation_of_geometry#Well-known_binary .. _`Well-known text (WKT)`: https://en.wikipedia.org/wiki/Well-known_text_representation_of_geometry