django/django/contrib/gis/tests/relatedapp/tests.py

231 lines
11 KiB
Python
Raw Normal View History

import os, unittest
from django.contrib.gis.geos import *
from django.contrib.gis.db.backend import SpatialBackend
from django.contrib.gis.db.models import F, Extent, Union
from django.contrib.gis.tests.utils import no_mysql, no_oracle, no_spatialite
from django.conf import settings
from models import City, Location, DirectoryEntry, Parcel
cities = (('Aurora', 'TX', -97.516111, 33.058333),
('Roswell', 'NM', -104.528056, 33.387222),
('Kecksburg', 'PA', -79.460734, 40.18476),
)
class RelatedGeoModelTest(unittest.TestCase):
def test01_setup(self):
"Setting up for related model tests."
for name, state, lon, lat in cities:
loc = Location.objects.create(point=Point(lon, lat))
c = City.objects.create(name=name, state=state, location=loc)
@no_oracle # TODO: Fix select_related() problems w/Oracle and pagination.
def test02_select_related(self):
"Testing `select_related` on geographic models (see #7126)."
qs1 = City.objects.all()
qs2 = City.objects.select_related()
qs3 = City.objects.select_related('location')
for qs in (qs1, qs2, qs3):
for ref, c in zip(cities, qs):
nm, st, lon, lat = ref
self.assertEqual(nm, c.name)
self.assertEqual(st, c.state)
self.assertEqual(Point(lon, lat), c.location.point)
@no_mysql
@no_oracle # Pagination problem is implicated in this test as well.
def test03_transform_related(self):
"Testing the `transform` GeoQuerySet method on related geographic models."
# All the transformations are to state plane coordinate systems using
# US Survey Feet (thus a tolerance of 0 implies error w/in 1 survey foot).
if SpatialBackend.postgis:
tol = 3
else:
tol = 0
def check_pnt(ref, pnt):
self.assertAlmostEqual(ref.x, pnt.x, tol)
self.assertAlmostEqual(ref.y, pnt.y, tol)
self.assertEqual(ref.srid, pnt.srid)
# Each city transformed to the SRID of their state plane coordinate system.
transformed = (('Kecksburg', 2272, 'POINT(1490553.98959621 314792.131023984)'),
('Roswell', 2257, 'POINT(481902.189077221 868477.766629735)'),
('Aurora', 2276, 'POINT(2269923.2484839 7069381.28722222)'),
)
for name, srid, wkt in transformed:
# Doing this implicitly sets `select_related` select the location.
# TODO: Fix why this breaks on Oracle.
qs = list(City.objects.filter(name=name).transform(srid, field_name='location__point'))
check_pnt(GEOSGeometry(wkt, srid), qs[0].location.point)
@no_mysql
@no_spatialite
def test04a_related_extent_aggregate(self):
"Testing the `extent` GeoQuerySet aggregates on related geographic models."
# This combines the Extent and Union aggregates into one query
aggs = City.objects.aggregate(Extent('location__point'))
# One for all locations, one that excludes Roswell.
all_extent = (-104.528060913086, 33.0583305358887,-79.4607315063477, 40.1847610473633)
txpa_extent = (-97.51611328125, 33.0583305358887,-79.4607315063477, 40.1847610473633)
e1 = City.objects.extent(field_name='location__point')
e2 = City.objects.exclude(name='Roswell').extent(field_name='location__point')
e3 = aggs['location__point__extent']
# The tolerance value is to four decimal places because of differences
# between the Oracle and PostGIS spatial backends on the extent calculation.
tol = 4
for ref, e in [(all_extent, e1), (txpa_extent, e2), (all_extent, e3)]:
for ref_val, e_val in zip(ref, e): self.assertAlmostEqual(ref_val, e_val, tol)
@no_mysql
def test04b_related_union_aggregate(self):
"Testing the `unionagg` GeoQuerySet aggregates on related geographic models."
# This combines the Extent and Union aggregates into one query
aggs = City.objects.aggregate(Union('location__point'))
# These are the points that are components of the aggregate geographic
# union that is returned.
p1 = Point(-104.528056, 33.387222)
p2 = Point(-97.516111, 33.058333)
p3 = Point(-79.460734, 40.18476)
# Creating the reference union geometry depending on the spatial backend,
# as Oracle will have a different internal ordering of the component
# geometries than PostGIS. The second union aggregate is for a union
# query that includes limiting information in the WHERE clause (in other
# words a `.filter()` precedes the call to `.unionagg()`).
if SpatialBackend.oracle:
ref_u1 = MultiPoint(p3, p1, p2, srid=4326)
ref_u2 = MultiPoint(p3, p2, srid=4326)
else:
ref_u1 = MultiPoint(p1, p2, p3, srid=4326)
ref_u2 = MultiPoint(p2, p3, srid=4326)
u1 = City.objects.unionagg(field_name='location__point')
u2 = City.objects.exclude(name='Roswell').unionagg(field_name='location__point')
u3 = aggs['location__point__union']
self.assertEqual(ref_u1, u1)
self.assertEqual(ref_u2, u2)
self.assertEqual(ref_u1, u3)
def test05_select_related_fk_to_subclass(self):
"Testing that calling select_related on a query over a model with an FK to a model subclass works"
# Regression test for #9752.
l = list(DirectoryEntry.objects.all().select_related())
def test06_f_expressions(self):
"Testing F() expressions on GeometryFields."
# Constructing a dummy parcel border and getting the City instance for
# assigning the FK.
b1 = GEOSGeometry('POLYGON((-97.501205 33.052520,-97.501205 33.052576,-97.501150 33.052576,-97.501150 33.052520,-97.501205 33.052520))', srid=4326)
pcity = City.objects.get(name='Aurora')
# First parcel has incorrect center point that is equal to the City;
# it also has a second border that is different from the first as a
# 100ft buffer around the City.
c1 = pcity.location.point
c2 = c1.transform(2276, clone=True)
b2 = c2.buffer(100)
p1 = Parcel.objects.create(name='P1', city=pcity, center1=c1, center2=c2, border1=b1, border2=b2)
# Now creating a second Parcel where the borders are the same, just
# in different coordinate systems. The center points are also the
# the same (but in different coordinate systems), and this time they
# actually correspond to the centroid of the border.
c1 = b1.centroid
c2 = c1.transform(2276, clone=True)
p2 = Parcel.objects.create(name='P2', city=pcity, center1=c1, center2=c2, border1=b1, border2=b1)
# Should return the second Parcel, which has the center within the
# border.
qs = Parcel.objects.filter(center1__within=F('border1'))
self.assertEqual(1, len(qs))
self.assertEqual('P2', qs[0].name)
if not SpatialBackend.mysql:
# This time center2 is in a different coordinate system and needs
# to be wrapped in transformation SQL.
qs = Parcel.objects.filter(center2__within=F('border1'))
self.assertEqual(1, len(qs))
self.assertEqual('P2', qs[0].name)
# Should return the first Parcel, which has the center point equal
# to the point in the City ForeignKey.
qs = Parcel.objects.filter(center1=F('city__location__point'))
self.assertEqual(1, len(qs))
self.assertEqual('P1', qs[0].name)
if not SpatialBackend.mysql:
# This time the city column should be wrapped in transformation SQL.
qs = Parcel.objects.filter(border2__contains=F('city__location__point'))
self.assertEqual(1, len(qs))
self.assertEqual('P1', qs[0].name)
def test07_values(self):
"Testing values() and values_list() and GeoQuerySets."
# GeoQuerySet and GeoValuesQuerySet, and GeoValuesListQuerySet respectively.
gqs = Location.objects.all()
gvqs = Location.objects.values()
gvlqs = Location.objects.values_list()
# Incrementing through each of the models, dictionaries, and tuples
# returned by the different types of GeoQuerySets.
for m, d, t in zip(gqs, gvqs, gvlqs):
# The values should be Geometry objects and not raw strings returned
# by the spatial database.
self.failUnless(isinstance(d['point'], SpatialBackend.Geometry))
self.failUnless(isinstance(t[1], SpatialBackend.Geometry))
self.assertEqual(m.point, d['point'])
self.assertEqual(m.point, t[1])
def test08_defer_only(self):
"Testing defer() and only() on Geographic models."
qs = Location.objects.all()
def_qs = Location.objects.defer('point')
for loc, def_loc in zip(qs, def_qs):
self.assertEqual(loc.point, def_loc.point)
def test09_pk_relations(self):
"Ensuring correct primary key column is selected across relations. See #10757."
# Adding two more cities, but this time making sure that their location
# ID values do not match their City ID values.
loc1 = Location.objects.create(point='POINT (-95.363151 29.763374)')
loc2 = Location.objects.create(point='POINT (-96.801611 32.782057)')
dallas = City.objects.create(name='Dallas', location=loc2)
houston = City.objects.create(name='Houston', location=loc1)
# The expected ID values -- notice the last two location IDs
# are out of order. We want to make sure that the related
# location ID column is selected instead of ID column for
# the city.
city_ids = (1, 2, 3, 4, 5)
loc_ids = (1, 2, 3, 5, 4)
ids_qs = City.objects.order_by('id').values('id', 'location__id')
for val_dict, c_id, l_id in zip(ids_qs, city_ids, loc_ids):
self.assertEqual(val_dict['id'], c_id)
self.assertEqual(val_dict['location__id'], l_id)
def test10_combine(self):
"Testing the combination of two GeoQuerySets. See #10807."
buf1 = City.objects.get(name='Aurora').location.point.buffer(0.1)
buf2 = City.objects.get(name='Kecksburg').location.point.buffer(0.1)
qs1 = City.objects.filter(location__point__within=buf1)
qs2 = City.objects.filter(location__point__within=buf2)
combined = qs1 | qs2
names = [c.name for c in combined]
self.assertEqual(2, len(names))
self.failUnless('Aurora' in names)
self.failUnless('Kecksburg' in names)
# TODO: Related tests for KML, GML, and distance lookups.
def suite():
s = unittest.TestSuite()
s.addTest(unittest.makeSuite(RelatedGeoModelTest))
return s