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424 lines
21 KiB
Plaintext
======================
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GeoDjango Database API
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======================
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.. _spatial-backends:
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Spatial Backends
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================
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.. module:: django.contrib.gis.db.backends
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:synopsis: GeoDjango's spatial database backends.
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GeoDjango currently provides the following spatial database backends:
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* ``django.contrib.gis.db.backends.postgis``
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* ``django.contrib.gis.db.backends.mysql``
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* ``django.contrib.gis.db.backends.oracle``
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* ``django.contrib.gis.db.backends.spatialite``
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.. _mysql-spatial-limitations:
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MySQL Spatial Limitations
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-------------------------
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Before MySQL 5.6.1, spatial extensions only support bounding box operations
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(what MySQL calls minimum bounding rectangles, or MBR). Specifically, MySQL did
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not conform to the OGC standard. Django supports spatial functions operating on
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real geometries available in modern MySQL versions. However, the spatial
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functions are not as rich as other backends like PostGIS.
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.. warning::
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True spatial indexes (R-trees) are only supported with
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MyISAM tables on MySQL. [#fnmysqlidx]_ In other words, when using
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MySQL spatial extensions you have to choose between fast spatial
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lookups and the integrity of your data -- MyISAM tables do
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not support transactions or foreign key constraints.
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Raster Support
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--------------
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``RasterField`` is currently only implemented for the PostGIS backend. Spatial
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lookups are available for raster fields, but spatial database functions and
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aggregates aren't implemented for raster fields.
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Creating and Saving Models with Geometry Fields
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===============================================
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Here is an example of how to create a geometry object (assuming the ``Zipcode``
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model)::
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>>> from zipcode.models import Zipcode
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>>> z = Zipcode(code=77096, poly='POLYGON(( 10 10, 10 20, 20 20, 20 15, 10 10))')
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>>> z.save()
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:class:`~django.contrib.gis.geos.GEOSGeometry` objects may also be used to save geometric models::
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>>> from django.contrib.gis.geos import GEOSGeometry
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>>> poly = GEOSGeometry('POLYGON(( 10 10, 10 20, 20 20, 20 15, 10 10))')
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>>> z = Zipcode(code=77096, poly=poly)
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>>> z.save()
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Moreover, if the ``GEOSGeometry`` is in a different coordinate system (has a
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different SRID value) than that of the field, then it will be implicitly
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transformed into the SRID of the model's field, using the spatial database's
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transform procedure::
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>>> poly_3084 = GEOSGeometry('POLYGON(( 10 10, 10 20, 20 20, 20 15, 10 10))', srid=3084) # SRID 3084 is 'NAD83(HARN) / Texas Centric Lambert Conformal'
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>>> z = Zipcode(code=78212, poly=poly_3084)
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>>> z.save()
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>>> from django.db import connection
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>>> print(connection.queries[-1]['sql']) # printing the last SQL statement executed (requires DEBUG=True)
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INSERT INTO "geoapp_zipcode" ("code", "poly") VALUES (78212, ST_Transform(ST_GeomFromWKB('\\001 ... ', 3084), 4326))
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Thus, geometry parameters may be passed in using the ``GEOSGeometry`` object, WKT
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(Well Known Text [#fnwkt]_), HEXEWKB (PostGIS specific -- a WKB geometry in
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hexadecimal [#fnewkb]_), and GeoJSON (see :rfc:`7946`). Essentially, if the
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input is not a ``GEOSGeometry`` object, the geometry field will attempt to
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create a ``GEOSGeometry`` instance from the input.
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For more information creating :class:`~django.contrib.gis.geos.GEOSGeometry`
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objects, refer to the :ref:`GEOS tutorial <geos-tutorial>`.
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.. _creating-and-saving-raster-models:
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Creating and Saving Models with Raster Fields
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=============================================
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When creating raster models, the raster field will implicitly convert the input
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into a :class:`~django.contrib.gis.gdal.GDALRaster` using lazy-evaluation.
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The raster field will therefore accept any input that is accepted by the
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:class:`~django.contrib.gis.gdal.GDALRaster` constructor.
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Here is an example of how to create a raster object from a raster file
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``volcano.tif`` (assuming the ``Elevation`` model)::
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>>> from elevation.models import Elevation
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>>> dem = Elevation(name='Volcano', rast='/path/to/raster/volcano.tif')
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>>> dem.save()
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:class:`~django.contrib.gis.gdal.GDALRaster` objects may also be used to save
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raster models::
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>>> from django.contrib.gis.gdal import GDALRaster
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>>> rast = GDALRaster({'width': 10, 'height': 10, 'name': 'Canyon', 'srid': 4326,
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... 'scale': [0.1, -0.1], 'bands': [{"data": range(100)}]})
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>>> dem = Elevation(name='Canyon', rast=rast)
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>>> dem.save()
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Note that this equivalent to::
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>>> dem = Elevation.objects.create(
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... name='Canyon',
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... rast={'width': 10, 'height': 10, 'name': 'Canyon', 'srid': 4326,
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... 'scale': [0.1, -0.1], 'bands': [{"data": range(100)}]},
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... )
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.. _spatial-lookups-intro:
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Spatial Lookups
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===============
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GeoDjango's lookup types may be used with any manager method like
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``filter()``, ``exclude()``, etc. However, the lookup types unique to
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GeoDjango are only available on spatial fields.
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Filters on 'normal' fields (e.g. :class:`~django.db.models.CharField`)
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may be chained with those on geographic fields. Geographic lookups accept
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geometry and raster input on both sides and input types can be mixed freely.
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The general structure of geographic lookups is described below. A complete
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reference can be found in the :ref:`spatial lookup reference<spatial-lookups>`.
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Geometry Lookups
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----------------
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Geographic queries with geometries take the following general form (assuming
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the ``Zipcode`` model used in the :doc:`model-api`)::
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>>> qs = Zipcode.objects.filter(<field>__<lookup_type>=<parameter>)
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>>> qs = Zipcode.objects.exclude(...)
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For example::
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>>> qs = Zipcode.objects.filter(poly__contains=pnt)
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>>> qs = Elevation.objects.filter(poly__contains=rst)
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In this case, ``poly`` is the geographic field, :lookup:`contains <gis-contains>`
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is the spatial lookup type, ``pnt`` is the parameter (which may be a
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:class:`~django.contrib.gis.geos.GEOSGeometry` object or a string of
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GeoJSON , WKT, or HEXEWKB), and ``rst`` is a
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:class:`~django.contrib.gis.gdal.GDALRaster` object.
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.. _spatial-lookup-raster:
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Raster Lookups
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--------------
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The raster lookup syntax is similar to the syntax for geometries. The only
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difference is that a band index can be specified as additional input. If no band
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index is specified, the first band is used by default (index ``0``). In that
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case the syntax is identical to the syntax for geometry lookups.
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To specify the band index, an additional parameter can be specified on both
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sides of the lookup. On the left hand side, the double underscore syntax is
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used to pass a band index. On the right hand side, a tuple of the raster and
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band index can be specified.
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This results in the following general form for lookups involving rasters
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(assuming the ``Elevation`` model used in the :doc:`model-api`)::
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>>> qs = Elevation.objects.filter(<field>__<lookup_type>=<parameter>)
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>>> qs = Elevation.objects.filter(<field>__<band_index>__<lookup_type>=<parameter>)
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>>> qs = Elevation.objects.filter(<field>__<lookup_type>=(<raster_input, <band_index>)
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For example::
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>>> qs = Elevation.objects.filter(rast__contains=geom)
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>>> qs = Elevation.objects.filter(rast__contains=rst)
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>>> qs = Elevation.objects.filter(rast__1__contains=geom)
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>>> qs = Elevation.objects.filter(rast__contains=(rst, 1))
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>>> qs = Elevation.objects.filter(rast__1__contains=(rst, 1))
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On the left hand side of the example, ``rast`` is the geographic raster field
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and :lookup:`contains <gis-contains>` is the spatial lookup type. On the right
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hand side, ``geom`` is a geometry input and ``rst`` is a
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:class:`~django.contrib.gis.gdal.GDALRaster` object. The band index defaults to
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``0`` in the first two queries and is set to ``1`` on the others.
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While all spatial lookups can be used with raster objects on both sides, not all
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underlying operators natively accept raster input. For cases where the operator
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expects geometry input, the raster is automatically converted to a geometry.
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It's important to keep this in mind when interpreting the lookup results.
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The type of raster support is listed for all lookups in the :ref:`compatibility
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table <spatial-lookup-compatibility>`. Lookups involving rasters are currently
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only available for the PostGIS backend.
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.. _distance-queries:
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Distance Queries
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================
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Introduction
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------------
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Distance calculations with spatial data is tricky because, unfortunately,
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the Earth is not flat. Some distance queries with fields in a geographic
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coordinate system may have to be expressed differently because of
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limitations in PostGIS. Please see the :ref:`selecting-an-srid` section
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in the :doc:`model-api` documentation for more details.
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.. _distance-lookups-intro:
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Distance Lookups
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----------------
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*Availability*: PostGIS, MariaDB, MySQL, Oracle, SpatiaLite, PGRaster (Native)
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The following distance lookups are available:
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* :lookup:`distance_lt`
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* :lookup:`distance_lte`
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* :lookup:`distance_gt`
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* :lookup:`distance_gte`
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* :lookup:`dwithin` (except MariaDB and MySQL)
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.. note::
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For *measuring*, rather than querying on distances, use the
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:class:`~django.contrib.gis.db.models.functions.Distance` function.
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Distance lookups take a tuple parameter comprising:
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#. A geometry or raster to base calculations from; and
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#. A number or :class:`~django.contrib.gis.measure.Distance` object containing the distance.
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If a :class:`~django.contrib.gis.measure.Distance` object is used,
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it may be expressed in any units (the SQL generated will use units
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converted to those of the field); otherwise, numeric parameters are assumed
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to be in the units of the field.
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.. note::
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In PostGIS, ``ST_Distance_Sphere`` does *not* limit the geometry types
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geographic distance queries are performed with. [#fndistsphere15]_ However,
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these queries may take a long time, as great-circle distances must be
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calculated on the fly for *every* row in the query. This is because the
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spatial index on traditional geometry fields cannot be used.
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For much better performance on WGS84 distance queries, consider using
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:ref:`geography columns <geography-type>` in your database instead because
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they are able to use their spatial index in distance queries.
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You can tell GeoDjango to use a geography column by setting ``geography=True``
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in your field definition.
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For example, let's say we have a ``SouthTexasCity`` model (from the
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:source:`GeoDjango distance tests <tests/gis_tests/distapp/models.py>` ) on a
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*projected* coordinate system valid for cities in southern Texas::
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from django.contrib.gis.db import models
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class SouthTexasCity(models.Model):
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name = models.CharField(max_length=30)
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# A projected coordinate system (only valid for South Texas!)
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# is used, units are in meters.
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point = models.PointField(srid=32140)
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Then distance queries may be performed as follows::
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>>> from django.contrib.gis.geos import GEOSGeometry
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>>> from django.contrib.gis.measure import D # ``D`` is a shortcut for ``Distance``
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>>> from geoapp.models import SouthTexasCity
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# Distances will be calculated from this point, which does not have to be projected.
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>>> pnt = GEOSGeometry('POINT(-96.876369 29.905320)', srid=4326)
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# If numeric parameter, units of field (meters in this case) are assumed.
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>>> qs = SouthTexasCity.objects.filter(point__distance_lte=(pnt, 7000))
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# Find all Cities within 7 km, > 20 miles away, and > 100 chains away (an obscure unit)
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>>> qs = SouthTexasCity.objects.filter(point__distance_lte=(pnt, D(km=7)))
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>>> qs = SouthTexasCity.objects.filter(point__distance_gte=(pnt, D(mi=20)))
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>>> qs = SouthTexasCity.objects.filter(point__distance_gte=(pnt, D(chain=100)))
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Raster queries work the same way by replacing the geometry field ``point`` with
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a raster field, or the ``pnt`` object with a raster object, or both. To specify
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the band index of a raster input on the right hand side, a 3-tuple can be
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passed to the lookup as follows::
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>>> qs = SouthTexasCity.objects.filter(point__distance_gte=(rst, 2, D(km=7)))
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Where the band with index 2 (the third band) of the raster ``rst`` would be
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used for the lookup.
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.. _compatibility-table:
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Compatibility Tables
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====================
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.. _spatial-lookup-compatibility:
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Spatial Lookups
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---------------
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The following table provides a summary of what spatial lookups are available
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for each spatial database backend. The PostGIS Raster (PGRaster) lookups are
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divided into the three categories described in the :ref:`raster lookup details
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<spatial-lookup-raster>`: native support ``N``, bilateral native support ``B``,
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and geometry conversion support ``C``.
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================================= ========= ======== ========= ============ ========== ========
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Lookup Type PostGIS Oracle MariaDB MySQL [#]_ SpatiaLite PGRaster
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================================= ========= ======== ========= ============ ========== ========
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:lookup:`bbcontains` X X X X N
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:lookup:`bboverlaps` X X X X N
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:lookup:`contained` X X X X N
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:lookup:`contains <gis-contains>` X X X X X B
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:lookup:`contains_properly` X B
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:lookup:`coveredby` X X X B
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:lookup:`covers` X X X B
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:lookup:`crosses` X X X X C
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:lookup:`disjoint` X X X X X B
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:lookup:`distance_gt` X X X X X N
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:lookup:`distance_gte` X X X X X N
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:lookup:`distance_lt` X X X X X N
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:lookup:`distance_lte` X X X X X N
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:lookup:`dwithin` X X X B
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:lookup:`equals` X X X X X C
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:lookup:`exact <same_as>` X X X X X B
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:lookup:`intersects` X X X X X B
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:lookup:`isvalid` X X X (≥ 5.7.5) X (LWGEOM)
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:lookup:`overlaps` X X X X X B
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:lookup:`relate` X X X X C
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:lookup:`same_as` X X X X X B
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:lookup:`touches` X X X X X B
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:lookup:`within` X X X X X B
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:lookup:`left` X C
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:lookup:`right` X C
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:lookup:`overlaps_left` X B
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:lookup:`overlaps_right` X B
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:lookup:`overlaps_above` X C
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:lookup:`overlaps_below` X C
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:lookup:`strictly_above` X C
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:lookup:`strictly_below` X C
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================================= ========= ======== ========= ============ ========== ========
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.. _database-functions-compatibility:
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Database functions
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------------------
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The following table provides a summary of what geography-specific database
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functions are available on each spatial backend.
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.. currentmodule:: django.contrib.gis.db.models.functions
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==================================== ======= ============== ============ =========== ==========
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Function PostGIS Oracle MariaDB MySQL SpatiaLite
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==================================== ======= ============== ============ =========== ==========
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:class:`Area` X X X X X
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:class:`AsGeoJSON` X X X (≥ 10.2.4) X (≥ 5.7.5) X
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:class:`AsGML` X X X
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:class:`AsKML` X X
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:class:`AsSVG` X X
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:class:`AsWKB` X X X X X
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:class:`AsWKT` X X X X X
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:class:`Azimuth` X X (LWGEOM)
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:class:`BoundingCircle` X X
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:class:`Centroid` X X X X X
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:class:`Difference` X X X X X
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:class:`Distance` X X X X X
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:class:`Envelope` X X X X X
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:class:`ForcePolygonCW` X X
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:class:`GeoHash` X X (≥ 5.7.5) X (LWGEOM)
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:class:`Intersection` X X X X X
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:class:`IsValid` X X X (≥ 5.7.5) X (LWGEOM)
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:class:`Length` X X X X X
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:class:`LineLocatePoint` X X
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:class:`MakeValid` X X (LWGEOM)
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:class:`MemSize` X
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:class:`NumGeometries` X X X X X
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:class:`NumPoints` X X X X X
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:class:`Perimeter` X X X
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:class:`PointOnSurface` X X X X
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:class:`Reverse` X X X
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:class:`Scale` X X
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:class:`SnapToGrid` X X
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:class:`SymDifference` X X X X X
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:class:`Transform` X X X
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:class:`Translate` X X
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:class:`Union` X X X X X
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==================================== ======= ============== ============ =========== ==========
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Aggregate Functions
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-------------------
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The following table provides a summary of what GIS-specific aggregate functions
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are available on each spatial backend. Please note that MySQL does not
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support any of these aggregates, and is thus excluded from the table.
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.. currentmodule:: django.contrib.gis.db.models
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======================= ======= ====== ==========
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Aggregate PostGIS Oracle SpatiaLite
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======================= ======= ====== ==========
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:class:`Collect` X X
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:class:`Extent` X X X
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:class:`Extent3D` X
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:class:`MakeLine` X X
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:class:`Union` X X X
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======================= ======= ====== ==========
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.. rubric:: Footnotes
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.. [#fnwkt] *See* Open Geospatial Consortium, Inc., `OpenGIS Simple Feature Specification For SQL <http://www.opengis.org/docs/99-049.pdf>`_, Document 99-049 (May 5, 1999), at Ch. 3.2.5, p. 3-11 (SQL Textual Representation of Geometry).
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.. [#fnewkb] *See* `PostGIS EWKB, EWKT and Canonical Forms <https://postgis.net/docs/using_postgis_dbmanagement.html#EWKB_EWKT>`_, PostGIS documentation at Ch. 4.1.2.
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.. [#fndistsphere15] *See* `PostGIS documentation <https://postgis.net/docs/ST_DistanceSphere.html>`_ on ``ST_DistanceSphere``.
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.. [#fnmysqlidx] *See* `Creating Spatial Indexes <https://dev.mysql.com/doc/refman/en/creating-spatial-indexes.html>`_
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in the MySQL Reference Manual:
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For MyISAM tables, ``SPATIAL INDEX`` creates an R-tree index. For storage
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engines that support nonspatial indexing of spatial columns, the engine
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creates a B-tree index. A B-tree index on spatial values will be useful
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for exact-value lookups, but not for range scans.
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.. [#] Refer :ref:`mysql-spatial-limitations` section for more details.
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