def test_set_get_polygon(self):
"""Test setting and getting geometries from a casestudy"""
# create a casestudy
casestudy = self.uic.casestudy
# define the urls
url = reverse('casestudy-detail', kwargs={
'pk': casestudy.pk,
})
# put polygon as geometry
polygon = geos.Polygon([(2.38, 57.322), (23.194, -20.28),
(-120.43, 19.15),
(2.38, 57.322)], [(-5.21, 23.51),
(15.21, -10.81),
(-20.51, 1.51),
(-5.21, 23.51)])
data = {
'geom': polygon.geojson,
}
response = self.patch('casestudy-detail', pk=casestudy.pk, data=data)
self.response_200()
casestudy.refresh_from_db()
# polygon should have been converted to a multipolygon
self.assertJSONEqual(casestudy.geom.json,
geos.MultiPolygon(polygon).json)
# send geom as multipolygon and focusarea as polygon
multipolygon = geos.MultiPolygon(
polygon, geos.Polygon([(3, 3), (4, 4), (5, 3), (3, 3)]))
data = {
'geom': multipolygon.geojson,
'focusarea': polygon.geojson,
}
response = self.patch('casestudy-detail', pk=casestudy.pk, data=data)
assert response.status_code == status.HTTP_200_OK
casestudy.refresh_from_db()
# multipolygon should be a multipolygon
self.assertJSONEqual(casestudy.geom.json, multipolygon.json)
# polygon for focus area should have been converted to multipolygon
self.assertJSONEqual(casestudy.focusarea.json,
geos.MultiPolygon(polygon).json)
# get the response
response = self.get_check_200('casestudy-detail', pk=casestudy.pk)
assert response.data['id'] == casestudy.id
assert response.data['type'] == 'Feature'
self.assertJSONEqual(str(response.data['geometry']), multipolygon.json)
# name and focusarea are stored in as property
assert response.data['properties']['name'] == casestudy.name
self.assertJSONEqual(str(response.data['properties']['focusarea']),
geos.MultiPolygon(polygon).json)
def test_detail_view_without_login_fails(self):
p1 = geos.Polygon(((0, 0), (0, 1), (1, 1), (0, 0)))
p2 = geos.Polygon(((1, 1), (1, 2), (2, 2), (1, 1)))
multi_polygon = geos.MultiPolygon(p1, p2)
clipping_area = ClippingArea.objects.create(
name='test clipping area',
clipping_multi_polygon=multi_polygon,
)
url = reverse('clipping_area-detail', args=[clipping_area.id])
response = self.client.get(url, format='json')
self.assertEqual(response.status_code, status.HTTP_403_FORBIDDEN)
def test_detail_view_with_correct_data_succeeds(self):
p1 = geos.Polygon(((0, 0), (0, 1), (1, 1), (0, 0)))
p2 = geos.Polygon(((1, 1), (1, 2), (2, 2), (1, 1)))
multi_polygon = geos.MultiPolygon(p1, p2)
clipping_area = ClippingArea.objects.create(
name='test clipping area',
clipping_multi_polygon=multi_polygon,
)
url = reverse('clipping_area-detail', args=[clipping_area.id])
self.client.force_authenticate(user=self.user)
response = self.client.get(url, format='json')
self.assertEqual(response.status_code, status.HTTP_200_OK)
self.assertEqual(response.data['name'], "test clipping area")
def test_add_geometry_with_parent_area(self):
"""Test adding/updating features with parent levels"""
polygon1 = geos.Polygon(((0, 0), (0, 10), (10, 10), (0, 10), (0, 0)))
polygon2 = geos.Polygon(((4, 4), (4, 6), (6, 6), (6, 4), (4, 4)))
kreis1 = geojson.Feature(geometry=geojson.loads(polygon1.geojson),
properties={
'name': 'Kreis1',
'code': '01001',
})
kreis2 = geojson.Feature(geometry=geojson.loads(polygon1.geojson),
properties={
'name': 'Kreis2',
'code': '01002',
})
gem1 = geojson.Feature(geometry=geojson.loads(polygon2.geojson),
properties={'name': 'Gemeinde1',
'code': '01002001',
'parent_area_code': \
kreis2['properties']['code'],})
gem2 = geojson.Feature(geometry=geojson.loads(polygon2.geojson),
properties={'name': 'Gemeinde2',
'code': '01001002',
'parent_area_code': \
kreis1['properties']['code'],})
kreise = geojson.FeatureCollection([kreis1, kreis2])
self.post(
'area-list',
casestudy_pk=self.casestudy.pk,
level_pk=self.kreis.pk,
data=kreise,
extra=dict(content_type='application/json'),
)
self.response_201()
gemeinden = geojson.FeatureCollection([gem1, gem2])
gemeinden['parent_level'] = 6
self.post(
'area-list',
casestudy_pk=self.casestudy.pk,
level_pk=self.gemeinde.pk,
data=gemeinden,
extra=dict(content_type='application/json', ),
)
self.response_201()
gem1 = models.Area.objects.get(code='01002001')
assert gem1.parent_area.code == '01002'
gem2 = models.Area.objects.get(code='01001002')
assert gem2.parent_area.code == '01001'
def get_camden_parks():
parks_file = os.path.join(DATA_DIR, 'osm_london', 'natural')
camden = models.Division.objects.get(type='borough', name='Camden').mpoly
sf = shapefile.Reader(parks_file)
recs = sf.records()
shapes = sf.shapes()
# get all parks
park_idx = [i for i, x in enumerate(recs) if x[-1] == 'park']
# park_shapes = [shapes[i] for i in park_idx]
# park_recs = [recs[i] for i in park_idx]
# restrict to camden
camden_parks = {}
for i in park_idx:
ps = shapes[i]
pr = recs[i]
poly = geos.Polygon(np.array(ps.points), srid=4326)
poly.transform(27700)
if camden.intersects(poly):
print "Intersection"
name = pr[1]
if name.strip(' '):
camden_parks[name] = poly
return camden_parks
def create_country(name=None,
fips='TT',
gmi='TT',
iso2='TT',
iso3='TST',
iso_num=0,
border=None,
effective=None):
"""Creates a country data model for unit testing
:returns: The file model
:rtype: :class:`storage.models.CountryData`
"""
if not name:
global COUNTRY_NAME_COUNTER
name = 'test-country-%i' % COUNTRY_NAME_COUNTER
COUNTRY_NAME_COUNTER += 1
if not border:
border = geos.Polygon(((0, 0), (0, 10), (10, 10), (10, 0), (0, 0)))
if not effective:
effective = timezone.now()
return CountryData.objects.create(name=name,
fips=fips,
gmi=gmi,
iso2=iso2,
iso3=iso3,
iso_num=iso_num,
border=border,
effective=effective)
def test_create_polygon(self):
poly = geos.Polygon(
((-13018143.159491, 3811914.6000511), (-12961274.010455,
3792958.217039),
(-13004690.242515, 3778282.3076103), (-13018143.159491,
3811914.6000511)))
Feature.objects.create(geom_multipolygon=poly)
def get_bbox(self, obj):
return geos.Polygon((
(obj.bbox_x0, obj.bbox_y0),
(obj.bbox_x0, obj.bbox_y1),
(obj.bbox_x1, obj.bbox_y1),
(obj.bbox_x1, obj.bbox_y0),
(obj.bbox_x0, obj.bbox_y0),
))
def geodjango_rectangle_from_vertices(xmin, ymin, xmax, ymax):
return geos.Polygon([
(xmin, ymin),
(xmax, ymin),
(xmax, ymax),
(xmin, ymax),
(xmin, ymin),
])
def test_border_update(self):
newborder = geos.Polygon(((0, 0), (42, 0), (42, 42), (0, 42), (0, 0)))
neweffective = datetime.datetime(2010, 4, 5, 18, 26, 0, tzinfo=utc)
CountryData.objects.update_border('Test Country', newborder, neweffective)
tmp = CountryData.objects.filter(name='Test Country', effective=neweffective)
self.assertEqual(tmp[0].border, newborder)
self.assertEqual(tmp[0].effective, neweffective)
self.assertEqual(tmp[0].fips, 'TC')
def test_country_data(self):
'''Tests adding a border and country intersection calculation.'''
testborder = geos.Polygon(((0, 0), (0, 10), (10, 10), (10, 0), (0, 0)))
testborder2 = geos.Polygon(
((11, 0), (11, 8), (19, 8), (19, 0), (11, 0)))
testborder3 = geos.Polygon(
((11, 11), (11, 15), (15, 15), (15, 11), (11, 11)))
testeffective = datetime.datetime(2000, 1, 1, 0, 0, 0, tzinfo=utc)
CountryData.objects.create(name="Test Country",
fips="TC",
gmi="TCY",
iso2="TC",
iso3="TCY",
iso_num=42,
border=testborder,
effective=testeffective)
CountryData.objects.create(name="Test Country 2",
fips="TT",
gmi="TCT",
iso2="TT",
iso3="TCT",
iso_num=43,
border=testborder2,
effective=testeffective)
CountryData.objects.create(name="Test Country 3",
fips="TH",
gmi="TCH",
iso2="TH",
iso3="TCH",
iso_num=44,
border=testborder3,
effective=testeffective)
ws = storage_test_utils.create_workspace(name='test',
base_url='http://localhost')
file = storage_test_utils.create_file(file_name='test.txt',
workspace=ws)
with transaction.atomic():
file.geometry = geos.Polygon(
((5, 5), (5, 10), (12, 10), (12, 5), (5, 5)))
file.set_countries()
file.save()
tmp = [c.iso2 for c in file.countries.all()]
self.assertEqual(len(tmp), 2)
self.assertIn("TC", tmp)
self.assertIn("TT", tmp)
def bounding_box_srid(srid):
'''Return a bounding box for given SRID as a polygon in that SRID. E.g.:
>>> bounding_box_srid(54003).coords
(((240181312.2..., -14671436.0...), (240181312.2..., 14671436.0...), (-240181312.2..., 14671436.03...), (-240181312.2..., -14671436.0...), (240181312.2..., -14671436.0...)),)'''
(xmin, xmax) = lon_bounds_srid(srid)
(ymin, ymax) = lat_bounds_srid(srid)
return geos.Polygon([(xmin, ymin), (xmin, ymax), (xmax, ymax),
(xmax, ymin), (xmin, ymin)],
srid=srid)
def test_polygon_to_coord_string(self):
# Note that the lon,lat order is reversed in the expected string
# (compared to the polygon below).
expected_str = '38.0, -122.2, 38.0, -121.7, 37.5, -121.7, 37.5, -122.2'
polygon = geos.Polygon(
((-122.2, 38.0), (-121.7, 38.0), (-121.7, 37.5),
(-122.2, 37.5), (-122.2, 38.0)))
actual_str = _polygon_to_coord_string(polygon)
self.assertEqual(expected_str, actual_str)
def polygons(self, create, extracted, **kwargs):
if not create:
return # build, can't record many to many relationship
if extracted:
for polygon in extracted:
self.polygons.add(polygon)
else:
geom = geos.Polygon(((0.0, 0.0), (0.0, 50.0), (50.0, 50.0),
(50.0, 0.0), (0.0, 0.0)))
poly = Polygon(geom=geom)
self.polygons.add(poly)
def setUp(self):
django.setup()
self.testborder = geos.Polygon(
((0, 0), (0, 10), (10, 10), (0, 10), (0, 0)))
self.testeffective = datetime.datetime(2000, 1, 1, 0, 0, 0, tzinfo=utc)
CountryData.objects.create(name="Test Country",
fips="TC",
gmi="TCY",
iso2="TC",
iso3="TCY",
iso_num=42,
border=self.testborder,
effective=self.testeffective)
def test_add_geometry(self):
"""Test adding a geometry to an area"""
response = self.get_check_200('area-detail',
casestudy_pk=self.casestudy.pk,
level_pk=self.kreis_pi.adminlevel.pk,
pk=self.kreis_pi.pk)
data = response.data
self.assertEqual(data['type'], 'Feature')
properties = data['properties']
cs_uri = self.reverse('casestudy-detail', pk=self.casestudy.pk)
level_uri = self.reverse('adminlevels-detail',
casestudy_pk=self.casestudy.pk,
pk=self.kreis_pi.adminlevel.pk)
self.assertURLEqual(properties['casestudy'], cs_uri)
self.assertURLEqual(properties['adminlevel'], level_uri)
assert properties['name'] == self.kreis_pi.name
# geometry is None
assert data['geometry'] is None
# add new Polygon as geometry
polygon = geos.Polygon(((0, 0), (0, 10), (10, 10), (0, 10), (0, 0)),
((4, 4), (4, 6), (6, 6), (6, 4), (4, 4)),
srid=4326)
# and change the name
new_name = 'Kreis Pinneberg-Elmshorn'
data = {
'geometry': polygon.geojson,
'properties': {
'name': new_name,
},
}
response = self.patch(
'area-detail',
casestudy_pk=self.casestudy.pk,
level_pk=self.kreis_pi.adminlevel.pk,
pk=self.kreis_pi.pk,
data=json.dumps(data),
extra=dict(content_type='application/json'),
)
self.response_200()
# test if the new geometry is a multipolygon
multipolygon = geos.MultiPolygon(polygon)
self.assertJSONEqual(str(response.data['geometry']),
multipolygon.geojson)
# and that the name has changed
self.assertEqual(response.data['properties']['name'], new_name)
def test_grid_offset(self):
"""
Simple square domain, test with offset coords
"""
domain = geos.Polygon([
(0, 0),
(0, 1),
(1, 1),
(1, 0),
(0, 0),
])
igrid, egrid, fgs = spatial.create_spatial_grid(domain, grid_length=0.1) # no offset
self.assertEqual(len(igrid), 100)
self.assertEqual(len(egrid), 100)
self.assertAlmostEqual(sum([g.area for g in igrid]), 1.0)
for g in igrid:
self.assertAlmostEqual(g.area, 0.01)
self.assertTrue(g.intersects(domain))
for g in egrid:
self.assertAlmostEqual(g[2], g[0] + 0.1)
self.assertAlmostEqual(g[3], g[1] + 0.1)
self.assertTrue(np.all(fgs))
igrid, egrid, fgs = spatial.create_spatial_grid(domain, grid_length=0.1, offset_coords=(0.05, 0.)) # offset
self.assertEqual(len(igrid), 110)
self.assertEqual(len(igrid), 110)
self.assertAlmostEqual(sum([g.area for g in igrid]), 1.0)
self.assertAlmostEqual(igrid[0].area, 0.005)
for g in igrid:
self.assertTrue(g.intersects(domain))
for g in egrid:
self.assertAlmostEqual(g[2], g[0] + 0.1)
self.assertAlmostEqual(g[3], g[1] + 0.1)
# 20 grid squares are not fully within the domain
self.assertEqual(sum(fgs), 90)
igrid, egrid, fgs = spatial.create_spatial_grid(domain, grid_length=0.1, offset_coords=(0., 1.1)) # offset outside of domain
self.assertEqual(len(igrid), 100)
self.assertEqual(len(egrid), 100)
self.assertAlmostEqual(sum([g.area for g in igrid]), 1.0)
for g in igrid:
self.assertAlmostEqual(g.area, 0.01)
self.assertTrue(g.intersects(domain))
for g in egrid:
self.assertAlmostEqual(g[2], g[0] + 0.1)
self.assertAlmostEqual(g[3], g[1] + 0.1)
self.assertTrue(np.all(fgs))
def validate_geometries(self, row, rownum):
try:
geom = fromstr(row['ATTRIBUTEVALUE'])
coord_limit = 1500
bbox = geos.Polygon(settings.DATA_VALIDATION_BBOX)
if geom.num_coords > coord_limit:
self.append_error('ERROR ROW: {0} - {1} has too many coordinates ({2}), Please limit to less then {3} coordinates of 5 digits of precision or less.'.format(rownum, row['ATTRIBUTEVALUE'][:75] + '......', geom.num_coords, coord_limit), 'geometry_errors')
# if fromstr(row['ATTRIBUTEVALUE']).valid == False:
# self.append_error('ERROR ROW: {0} - {1} is an invalid geometry.'.format(rownum, row['ATTRIBUTEVALUE']), 'geometry_errors')
if bbox.contains(geom) == False:
self.append_error('ERROR ROW: {0} - {1} does not fall within the bounding box of the selected coordinate system. Adjust your coordinates or your settings.DATA_EXTENT_VALIDATION property.'.format(rownum, row['ATTRIBUTEVALUE']), 'geometry_errors')
except:
self.append_error('ERROR ROW: {0} - {1} is not a properly formatted geometry.'.format(rownum, row['ATTRIBUTEVALUE']), 'geometry_errors')
def create_grid_centroid_hotspots_shapefile(grid_spacing=25):
grid_spacing = 25 # distance between centroids in metres
res, t0, cid = cad.get_crimes_by_type(nicl_type=range(1, 17))
sk = hotspot.SKernelHistoricVariableBandwidthNn(dt=60, nn=15)
# choose final date 2011/11/1 for training -> 60 days prior ends AFTER crossover to new non-snapped data
days_offset = 245
dt_pred = t0.date() + datetime.timedelta(days=days_offset)
training = res[res[:, 0] <= days_offset]
sk.train(training)
# generate grid
camden = cad.get_camden_region()
# convert to buffered rectangular region
sq_poly = camden.buffer(grid_spacing).envelope
# lock to integer multiples of grid_spacing
c = []
for i in range(len(sq_poly.coords[0])):
a = int(sq_poly.coords[0][i][0] / grid_spacing) * grid_spacing
b = int(sq_poly.coords[0][i][1] / grid_spacing) * grid_spacing
c.append((a, b))
sq_poly = geos.Polygon(geos.LinearRing(c))
r = roc.RocGrid(poly=sq_poly)
print "Setting ROC grid..."
r.set_sample_units(grid_spacing)
print "Done."
# prediction on grid
print "Computing KDE prediction..."
z = sk.predict(r.sample_points)
print "Done."
print "Writing shapefile..."
out_shp = 'risk_surface_%s.shp' % dt_pred.strftime('%Y-%m-%d')
w = shapefile.Writer(shapefile.POINT)
w.field('risk', fieldType='N')
for x, y in zip(r.sample_points, z.flat):
w.point(int(x[0]), int(x[1]))
w.record(risk=y)
w.save(out_shp)
print "Done."
def setUp(self):
self.compiler = ExpressionEvaluator()
poly = geos.Polygon(
((0.0, 0.0), (0.0, 50.0), (50.0, 50.0), (50.0, 0.0), (0.0, 0.0)))
self.context = {
'testint': 1,
'location_1': geos.Point(66, 66),
'location_2': geos.Point(1, 1),
'maincat': 'dieren',
'subcat': 'subcat',
'time': time.strptime("16:00:00", "%H:%M:%S"),
'area': {
'stadsdeel': {
'oost': geos.MultiPolygon(poly)
}
},
'listval': 'geo1',
'list': set(['geo1', 'geo2'])
}
def _cell_to_polygon(center, cell_size):
"""Return the cell with the given mid point and size.
:param center: the center of the risk cell
:type center: a :py:class:`openquake.shapes.Site` instance
:param float cell_size: the configured risk cell size
:return: the risk cell as a :py:class:`django.contrib.gis.geos.Polygon`
"""
clon, clat = center.coords
half_csize = cell_size / 2.0
lon, lat = (clon - half_csize, clat - half_csize)
coos = [
(lon, lat), # lower left
(lon, lat + cell_size), # upper left
(lon + cell_size, lat + cell_size), # upper right
(lon + cell_size, lat), # lower right
(lon, lat)
]
coos = [(round_float(x), round_float(y)) for x, y in coos]
return geos.Polygon(coos)
def setup_classic_job(self, create_job_path=True, upload_id=None):
"""Create a classic job with associated upload and inputs.
:param integer upload_id: if set use upload record with given db key.
:param bool create_job_path: if set the path for the job will be
created and captured in the job record
:returns: a :py:class:`geonode.mtapi.models.OqJob` instance
"""
upload = self.setup_upload(upload_id)
oqp = OqParams()
oqp.job_type = "classical"
oqp.upload = upload
oqp.region_grid_spacing = 0.01
oqp.min_magnitude = 5.0
oqp.investigation_time = 50.0
oqp.component = "gmroti50"
oqp.imt = "pga"
oqp.truncation_type = "twosided"
oqp.truncation_level = 3
oqp.reference_vs30_value = 760
oqp.imls = [
0.005, 0.007, 0.0098, 0.0137, 0.0192, 0.0269, 0.0376, 0.0527,
0.0738, 0.103, 0.145, 0.203, 0.284, 0.397, 0.556, 0.778
]
oqp.poes = [0.01, 0.10]
oqp.realizations = 1
from django.contrib.gis import geos
oqp.region = geos.Polygon(
((-122.2, 38.0), (-121.7, 38.0), (-121.7, 37.5), (-122.2, 37.5),
(-122.2, 38.0)))
oqp.save()
job = OqJob(oq_params=oqp, owner=upload.owner, job_type="classical")
job.save()
if create_job_path:
job.path = os.path.join(upload.path, str(job.id))
os.mkdir(job.path)
os.chmod(job.path, 0777)
job.save()
return job
def get(self, request, **kwargs):
params = request.GET
if params:
print()
self.latitude = round(float(params.get('lat')), 4)
self.longitude = round(float(params.get('lng')), 4)
self.radius = int(params.get('radius'))
self.geometry = self.geodesic_point_buffer(self.latitude,
self.longitude,
self.radius)
geosGeom = geos.Polygon(self.geometry)
self.near_rivers = River.objects.filter(geom__intersects=geosGeom)
self.nearby_rivers = serialize('geojson', self.near_rivers)
self.response['lat'] = self.latitude
self.response['lng'] = self.longitude
self.response['nearby_rivers'] = self.nearby_rivers
self.response['geometry'] = mapping(Polygon(self.geometry))
self.response['flood_prone'] = self.is_flood_prone_area(geosGeom)
#eopatch = self.get_elevation(Polygon(self.geometry).bounds)
#eopatch_sq = eopatch.data_timeless['MAPZEN_DEM'].squeeze()
self.response['mean_slope'] = np.random.rand(
) #self.calclute_slope(eopatch_sq).mean()
self.response['msl'] = np.random.uniform(
low=600, high=4000,
size=None) #self.calculate_mean_sea_level(eopatch_sq)
self.response['rain_prediction'] = self.get_rain_prediction(
self.latitude, self.longitude)
self.response['remarks'] = self.determine_flood_safe()
"""plt.figure(figsize=(10,10))
plt.imshow(eopatch.data_timeless['MAPZEN_DEM'].squeeze())
plt.show()"""
else:
print("No query params")
return Response(self.response)
def _getBusStops(regions: FeatureCollection) -> [Point]:
ret = GeoSampa_BusStops.objects.all()[:0]
for feature in regions['features']:
#This represents a simple exterior linear ring. Interior rings are
#not considered.
geom = geos.Polygon(
feature['geometry']['coordinates'][0],
srid=int(regions['crs']['properties']['name'].split(':')[1]))
partial = GeoSampa_BusStops.objects.filter(mpoint__within=geom)
#TODO: Replace union with Collect
#//https://docs.djangoproject.com/en/2.0/ref/contrib/gis/geoquerysets/#intersects
ret = ret.union(partial)
featuresList = []
for busStop in ret.all():
GeoSampaMiner._reproject(busStop.mpoint)
featuresList.append(
Feature(id=busStop.id,
properties={
'name': busStop.name,
'description': busStop.description,
'address': busStop.address
},
geometry=Point(busStop.mpoint)))
return FeatureCollection(featuresList, crs=GeoSampaMiner._crs)
def import_events(data_from_feed, tolerance=0.0001):
"""
For every shapefile in _merged folder, creates or updates event in Django DB and Geoserver DB.
The geometry inserted in Geoserver DB is the union of all features found in layer.
"""
db = DbUtils()
conn = db.get_db_conn()
curs = conn.cursor()
allowed_extensions = [".shp"]
try:
for root, dirs, files in os.walk(SHAPEFILES_BASE_DIR):
print('shapefiles base dir: {}'.format(SHAPEFILES_BASE_DIR))
for d in dirs:
if d.endswith('_merged'):
print('found merged folder')
for f in os.listdir(os.path.join(SHAPEFILES_BASE_DIR, d)):
if f.endswith(tuple(allowed_extensions)):
print('found shapefiles: {}'.format(f))
'''try:
filepath = os.path.join(SHAPEFILES_BASE_DIR, d, f)
ds = DataSource(filepath)
except GDALException, e:
traceback.print_exc()
break
for layer in ds:
count = 0
polygon_union = None
for feat in layer:
print('processing feature {}'.format(count))
# Simplify the Geometry
geom = geos.fromstr(feat.geom.wkt, srid=4326)
if tolerance > 0:
geom = geom.simplify(tolerance, preserve_topology=True)
# Generalize to 'Multiploygon'
if isinstance(geom, geos.Polygon):
geom = geos.MultiPolygon(geom)
if count == 0:
polygon_union = geom.buffer(0)
else:
polygon_union = polygon_union.union(geom.buffer(0))
count += 1
try:
print('re-extracting geom from union polygon')
polygon_union = geos.fromstr(polygon_union.wkt, srid=4326)
except:
break'''
ems = d.split('_')[0]
select_template = "SELECT ST_AsText(ST_Union(ARRAY(SELECT ST_Buffer(the_geom, 1e-5) FROM {})))".format(
ems)
row = None
try:
curs.execute(select_template)
row = curs.fetchone()
except:
pass
#set default multipolygon
ext_coords = ((0, 0), (0, 1), (1, 1), (1, 0), (0,
0))
int_coords = ((0.4, 0.4), (0.4, 0.6), (0.6, 0.6),
(0.6, 0.4), (0.4, 0.4))
polygon_union = geos.MultiPolygon(geos.Polygon(
ext_coords, int_coords),
srid=4326)
if row:
polygon_union = geos.fromstr(row[0], srid=4326)
# Update event in Django
event_from_feed = get_event_from_feed(
data_from_feed, ems)
new_event = generate_event_from_feed(
event_from_feed, polygon_union)
if new_event:
params = {
'geom': polygon_union,
'event_id': new_event.event_id,
'begin_date': new_event.begin_date,
'end_date': new_event.end_date
}
update_template = """INSERT INTO events (the_geom, event_id, begin_date, end_date)
SELECT
'{geom}', '{event_id}', '{begin_date}', '{end_date}'
ON CONFLICT (event_id)
DO UPDATE SET the_geom = excluded.the_geom;"""
print update_template.format(**params)
curs.execute(update_template.format(**params))
archive_path = os.path.join(SHAPEFILES_BASE_DIR, d,
'archive')
if not os.path.exists(archive_path):
os.makedirs(archive_path)
for f2 in os.listdir(os.path.join(SHAPEFILES_BASE_DIR, d)):
filepath = os.path.join(SHAPEFILES_BASE_DIR, d, f2)
if os.path.isfile(filepath):
print('moving file {} to {}'.format(
f2, archive_path))
os.rename(filepath, os.path.join(archive_path, f2))
conn.commit()
except Exception:
try:
conn.rollback()
except:
pass
traceback.print_exc()
finally:
conn.close()
def test_add_geometries(self):
"""Test adding features as feature collection"""
response = self.get_check_200('area-list',
casestudy_pk=self.casestudy.pk,
level_pk=self.kreis.pk)
num_kreise = len(response.data['results'])
polygon1 = geos.Polygon(((0, 0), (0, 10), (10, 10), (0, 10), (0, 0)))
polygon2 = geos.Polygon(((4, 4), (4, 6), (6, 6), (6, 4), (4, 4)))
kreis1 = geojson.Feature(geometry=geojson.loads(polygon1.geojson),
properties={
'name': 'Kreis1',
'code': '01001'
})
kreis2 = geojson.Feature(geometry=geojson.loads(polygon2.geojson),
properties={
'name': 'Kreis2',
'code': '01002',
'parent_area_code': self.sh.code,
})
kreise = geojson.FeatureCollection([kreis1, kreis2])
kreise['parent_level'] = str(4)
self.post(
'area-list',
casestudy_pk=self.casestudy.pk,
level_pk=self.kreis.pk,
data=kreise,
extra=dict(content_type='application/json'),
)
self.response_201()
k2 = models.Area.objects.get(code='01002')
k1 = models.Area.objects.get(code='01001')
assert k2.name == 'Kreis2'
assert k1.name == 'Kreis1'
k2 = models.Area.objects.get(code='01002')
assert k2.name == 'Kreis2'
assert k2.parent_area == self.sh
response = self.get_check_200('area-list',
casestudy_pk=self.casestudy.pk,
level_pk=self.kreis.pk)
assert len(response.data['results']) == num_kreise + 2
# posting with relating to parents by area code
# should fail, when parent_level is missing
del kreise['parent_level']
self.post(
'area-list',
casestudy_pk=self.casestudy.pk,
level_pk=self.kreis.pk,
data=kreise,
extra=dict(content_type='application/json'),
)
self.response_400()
# relate to parent by id
kreis3 = geojson.Feature(geometry=geojson.loads(polygon2.geojson),
properties={
'name': 'Kreis3',
'code': '01003',
'parent_area': self.sh.id
})
self.post(
'area-list',
casestudy_pk=self.casestudy.pk,
level_pk=self.kreis.pk,
data=kreis3,
extra=dict(content_type='application/json'),
)
self.response_201()
k3 = models.Area.objects.get(code='01003')
assert k3.parent_area == self.sh
# posting with both parent_area_code and parent_area_id should fail
# (only one allowed at a time)
kreis4 = geojson.Feature(geometry=geojson.loads(polygon2.geojson),
properties={
'name': 'Kreis4',
'code': '01004',
'parent_area_code': self.sh.code,
'parent_area': 1
})
kreise = geojson.FeatureCollection([kreis4])
kreise['parent_level'] = str(4)
self.post(
'area-list',
casestudy_pk=self.casestudy.pk,
level_pk=self.kreis.pk,
data=kreise,
extra=dict(content_type='application/json'),
)
self.response_400()
def test_border_update_not_found(self):
newborder = geos.Polygon(((0, 0), (42, 0), (42, 42), (0, 42), (0, 0)))
self.assertRaises(CountryData.DoesNotExist, CountryData.objects.update_border, 'Kerblekistan', newborder)
def is_polygon_equal(self, d):
g = geos.Polygon(d['features'][0]['geometry']['coordinates'][0])
g.srid = self.g.srid
return g.equals_exact(self.g, self.tolerance)
from ConfigParser import ConfigParser
from geonode.mtapi import models as mt_models
from utils.oqrunner import config_writer
from django.contrib.gis import geos
TEST_OWNER_ID = 1
TEST_JOB_PID = 1
TEST_OUTPUT_BASE_PATH = "/tmp/oqserver_tests"
TEST_PARAMS = {
'CALCULATION_MODE':
'classical',
'REGION_VERTEX':
geos.Polygon(((-122.2, 38.0), (-121.7, 38.0), (-121.7, 37.5),
(-122.2, 37.5), (-122.2, 38.0))),
'REGION_GRID_SPACING':
0.01,
'MINIMUM_MAGNITUDE':
5.0,
'INVESTIGATION_TIME':
50.0,
'COMPONENT':
'gmroti50',
'INTENSITY_MEASURE_TYPE':
'pga',
'GMPE_TRUNCATION_TYPE':
'twosided',
'TRUNCATION_LEVEL':
'3',
'REFERENCE_VS30_VALUE':
y = np.random.random(sim_times.size)
out = x > 1.
while np.any(out):
xn = np.random.exponential(scale=2, size=out.sum())
x[out] = xn
out = x > 1.
return CartesianSpaceTimeData.from_args(sim_times, x, y)
if b_sim:
max_t = 0.1
max_d = 0.1
du = 0.01
dv = 0.01
number_nn = [25, 25]
poly = geos.Polygon([(0, 0), (0, 1), (1, 1), (1, 0), (0, 0)])
res_all = simulation()
cid_all = np.arange(res_all.ndata)
else:
max_t = 90
max_d = 500
du = 50
dv = 5
number_nn = [15, 100]
simplification_tol = 20 # for speedup in intersection etc.
full_poly = cad.get_camden_region()
poly = full_poly.simplify(simplification_tol)
bdy = poly.boundary
