def test_project(self):
stub = geometry_grpc.GeometryOperatorsStub(self.channel)
serviceSpatialReference = SpatialReferenceData(wkid=32632)
outputSpatialReference = SpatialReferenceData(wkid=4326)
polyline = LineString([(500000, 0), (400000, 100000),
(600000, -100000)])
a = EnvelopeData(xmin=1, ymin=2, xmax=4, ymax=6)
serviceGeomPolyline = GeometryBagData(
wkt=[polyline.wkt], spatial_reference=serviceSpatialReference)
opRequestProject = OperatorRequest(
left_geometry_bag=serviceGeomPolyline,
operator_type=ServiceOperatorType.Value('Project'),
operation_spatial_reference=outputSpatialReference,
results_encoding_type=GeometryEncodingType.Value('wkt'))
print("make project request")
response2 = stub.ExecuteOperation(opRequestProject)
print("Client received project response:\n", response2)
expected = "MULTILINESTRING ((9 0, 8.101251062924646 0.904618578893133, 9.898748937075354 -0.904618578893133))"
actual = response2.geometry_bag.wkt[0]
opEquals = OperatorRequest(
left_geometry_bag=GeometryBagData(wkt=[expected]),
right_geometry_bag=response2.geometry_bag,
operator_type=ServiceOperatorType.Value("Equals"),
operation_spatial_reference=outputSpatialReference)
response3 = stub.ExecuteOperation(opEquals)
self.assertTrue(response3.spatial_relationship)
def test_buffer(self):
self.assertTrue(True)
polygon = Polygon([(0, 0), (1, 1), (1, 0)])
geometryBagData = GeometryBagData()
geometryBagData.wkb.extend([polygon.wkb])
# geometryBagData.geometry_binaries.extend([polygon.wkb])
# geometryBagData.geometry_encoding_type = GeometryEncodingType.Value('wkb')
buffer_params = BufferParams(distances=[1.2])
opRequest = OperatorRequest(
left_geometry_bag=geometryBagData,
operator_type=ServiceOperatorType.Value('Buffer'),
buffer_params=buffer_params,
results_encoding_type=GeometryEncodingType.Value('wkt'))
print("make stub")
stub = geometry_grpc.GeometryOperatorsStub(self.channel)
print("make wkt request")
response = stub.ExecuteOperation(opRequest)
# print response
print("Client received wkt response:\n", response)
result_buffered = loads(response.geometry_bag.wkt[0])
self.assertTrue(result_buffered.contains(polygon))
shapely_buffer = polygon.buffer(1.2)
self.assertAlmostEqual(shapely_buffer.area, result_buffered.area, 2)
def test_union(self):
# Build patches as in dissolved.py
stub = geometry_grpc.GeometryOperatorsStub(self.channel)
r = partial(random.uniform, -20.0, 20.0)
serviceSpatialReference = SpatialReferenceData(wkid=4326)
points = [Point(r(), r()) for i in range(10000)]
spots = [p.buffer(2.5) for p in points]
service_multipoint = GeometryBagData(
spatial_reference=serviceSpatialReference,
geometry_encoding_type=GeometryEncodingType.Value('wkb'))
shape_start = datetime.datetime.now()
patches = cascaded_union(spots)
# because shapely is non-simple we need to simplify it for this to be a fair comparison
service_multipoint.wkb.extend([patches.wkb])
opRequestOuter = OperatorRequest(
left_geometry_bag=service_multipoint,
operator_type=ServiceOperatorType.Value('Simplify'),
operation_spatial_reference=serviceSpatialReference,
results_encoding_type=GeometryEncodingType.Value('wkb'))
response = stub.ExecuteOperation(opRequestOuter)
patches = wkbloads(response.geometry_bag.wkb[0])
shape_end = datetime.datetime.now()
shape_delta = shape_end - shape_start
shape_microseconds = int(shape_delta.total_seconds() * 1000)
print(shape_microseconds)
print(patches.wkt)
spots_wkb = [s.wkb for s in spots]
geometryBagData = GeometryBagData()
geometryBagData.wkb.extend(spots_wkb)
opRequestUnion = OperatorRequest(
left_geometry_bag=geometryBagData,
operator_type=ServiceOperatorType.Value('Union'))
epl_start = datetime.datetime.now()
response = stub.ExecuteOperation(opRequestUnion)
unioned_result = wkbloads(response.geometry_bag.wkb[0])
epl_end = datetime.datetime.now()
epl_delta = epl_end - epl_start
epl_microseconds = int(epl_delta.total_seconds() * 1000)
# TODO investigate why dev machine is faster for epl and slower for shapely and the alternative is true for test machines (memory limits?)
# self.assertGreater(shape_microseconds, epl_microseconds)
# self.assertGreater(shape_microseconds * 0.75, epl_microseconds)
self.assertAlmostEqual(patches.area, unioned_result.area, 8)
def test_exception(self):
stub = geometry_grpc.GeometryOperatorsStub(self.channel)
serviceSpatialReference = SpatialReferenceData(wkid=32632)
outputSpatialReference = SpatialReferenceData(wkid=4326)
polyline = LineString([(500000, 0), (400000, 100000),
(600000, -100000)])
a = EnvelopeData(xmin=1, ymin=2, xmax=4, ymax=6)
serviceGeomPolyline = GeometryBagData(
wkt=[polyline.wkt], spatial_reference=serviceSpatialReference)
opRequestProject = OperatorRequest(
left_geometry_bag=serviceGeomPolyline,
operator_type=ServiceOperatorType.Value('Project'),
operation_spatial_reference=outputSpatialReference,
results_encoding_type=GeometryEncodingType.Value('wkt'))
print("make project request")
response2 = stub.ExecuteOperation(opRequestProject)
print("Client received project response:\n", response2)
expected = "MULTILINESTRING ((9 0, 8.101251062924646 0.904618578893133, 9.898748937075354 -0.904618578893133))"
actual = response2.geometry_bag.wkt[0]
opEquals = OperatorRequest(
left_geometry_bag=serviceGeomPolyline,
right_geometry_bag=response2.geometry_bag,
operator_type=ServiceOperatorType.Value("Equals"),
operation_spatial_reference=outputSpatialReference)
try:
response3 = stub.ExecuteOperation(opEquals)
self.assertTrue(False)
except grpc.RpcError as e:
self.assertEqual(
'executeOperation error : java.lang.IllegalArgumentException: either both spatial references are local or neither',
e.details())
def test_ETRS(self):
geometry_strings = []
change_interval = 15
start_lon = -180.0
end_lon = 180.0
start_latitude = -90.0
end_latitude = 90.0
m = int(((end_lon - start_lon) / change_interval) *
((end_latitude - start_latitude) / change_interval))
D = 2 # dimensionality
X = np.zeros((m, D)) # data matrix where each row is a single example
idx = 0
original_points = []
for longitude in np.arange(-180.0, 180.0, change_interval):
for latitude in np.arange(-90, 90, change_interval):
X[idx] = (longitude, latitude)
idx += 1
point = Point(longitude, latitude)
original_points.append(point)
geometry_strings.append(point.wkt)
stub = geometry_grpc.GeometryOperatorsStub(self.channel)
serviceSpatialReference = SpatialReferenceData(wkid=4326)
outputSpatialReference = SpatialReferenceData(wkid=3035)
# outputSpatialReference = SpatialReferenceData(wkid=32632)
serviceGeomPolyline = GeometryBagData(
wkt=geometry_strings,
geometry_encoding_type=GeometryEncodingType.Value('wkt'),
spatial_reference=serviceSpatialReference)
opRequestProject = OperatorRequest(
left_geometry_bag=serviceGeomPolyline,
operator_type=ServiceOperatorType.Value('Project'),
operation_spatial_reference=outputSpatialReference)
opRequestOuter = OperatorRequest(
left_geometry_request=opRequestProject,
operator_type=ServiceOperatorType.Value('Project'),
operation_spatial_reference=serviceSpatialReference,
results_encoding_type=GeometryEncodingType.Value('wkt'))
# print("make project request")
response = stub.ExecuteOperation(opRequestOuter)
# print("Client received project response:\n", response)
projected_point_array = [
loads(wkt) for wkt in response.geometry_bag.wkt
]
for index, original in enumerate(original_points):
point_projected = projected_point_array[index]
if point_projected.wkt == 'POINT EMPTY':
continue
if original.x == -180 or original.x == 180:
continue
self.assertAlmostEqual(point_projected.x, original.x, 8)
def test_multipoint(self):
stub = geometry_grpc.GeometryOperatorsStub(self.channel)
serviceSpatialReference = SpatialReferenceData(wkid=4326)
outputSpatialReference = SpatialReferenceData(wkid=3857)
multipoints_array = []
for longitude in range(-180, 180, 10):
for latitude in range(-80, 80, 10):
multipoints_array.append((longitude, latitude))
multipoint = MultiPoint(multipoints_array)
serviceGeomPolyline = GeometryBagData(
wkt=[multipoint.wkt], spatial_reference=serviceSpatialReference)
opRequestProject = OperatorRequest(
left_geometry_bag=serviceGeomPolyline,
operator_type=ServiceOperatorType.Value('Project'),
operation_spatial_reference=outputSpatialReference)
opRequestOuter = OperatorRequest(
left_geometry_request=opRequestProject,
operator_type=ServiceOperatorType.Value('Project'),
operation_spatial_reference=serviceSpatialReference,
results_encoding_type=GeometryEncodingType.Value('wkt'))
print("make project request")
response = stub.ExecuteOperation(opRequestOuter)
print("Client received project response:\n", response)
round_trip_result_wkt = loads(response.geometry_bag.wkt[0])
opRequestOuter = OperatorRequest(
left_geometry_request=opRequestProject,
operator_type=ServiceOperatorType.Value('Project'),
operation_spatial_reference=serviceSpatialReference,
results_encoding_type=GeometryEncodingType.Value('wkb'))
response = stub.ExecuteOperation(opRequestOuter)
round_trip_result = wkbloads(response.geometry_bag.wkb[0])
self.assertIsNotNone(round_trip_result)
max_diff_lat = 0.0
max_diff_lon = 0.0
for index, projected_point in enumerate(round_trip_result):
original_point = multipoint[index]
if math.fabs(original_point.x - projected_point.x) > max_diff_lon:
max_diff_lon = math.fabs(original_point.x - projected_point.x)
if math.fabs(original_point.y - projected_point.y) > max_diff_lat:
max_diff_lat = math.fabs(original_point.y - projected_point.y)
self.assertLess(math.fabs(original_point.x - projected_point.x),
0.0000001)
self.assertLess(math.fabs(original_point.y - projected_point.y),
0.0000001)
for index, projected_point in enumerate(round_trip_result_wkt):
original_point = multipoint[index]
if math.fabs(original_point.x - projected_point.x) > max_diff_lon:
max_diff_lon = math.fabs(original_point.x - projected_point.x)
if math.fabs(original_point.y - projected_point.y) > max_diff_lat:
max_diff_lat = math.fabs(original_point.y - projected_point.y)
self.assertLess(math.fabs(original_point.x - projected_point.x),
0.00000001)
self.assertLess(math.fabs(original_point.y - projected_point.y),
0.00000001)