def test_interpolate_irregular_lat_lon(self):
""" irregular interpolation """
source = np.random.rand(5, 5)
coords_src = Coordinates(
[clinspace(0, 10, 5), clinspace(0, 10, 5)], dims=["lat", "lon"])
coords_dst = Coordinates([[[0, 2, 4, 6, 8, 10], [0, 2, 4, 5, 6, 10]]],
dims=["lat_lon"])
node = MockArrayDataSource(data=source,
coordinates=coords_src,
interpolation={
"method": "nearest",
"interpolators": [ScipyGrid]
})
output = node.eval(coords_dst)
assert isinstance(output, UnitsDataArray)
assert "lat_lon" in output.dims
np.testing.assert_array_equal(output["lat"].values,
coords_dst["lat"].coordinates)
np.testing.assert_array_equal(output["lon"].values,
coords_dst["lon"].coordinates)
assert output.values[0] == source[0, 0]
assert output.values[1] == source[1, 1]
assert output.values[-1] == source[-1, -1]
def test_interpolate_irregular_arbitrary_2dims(self):
""" irregular interpolation """
# Note, this test also tests the looper helper
# try >2 dims
source = np.random.rand(5, 5, 3)
coords_src = Coordinates(
[clinspace(0, 10, 5),
clinspace(0, 10, 5), [2, 3, 5]],
dims=["lat", "lon", "time"])
coords_dst = Coordinates(
[clinspace(1, 11, 5),
clinspace(1, 11, 5), [2, 3, 4]],
dims=["lat", "lon", "time"])
node = MockArrayDataSource(
data=source,
coordinates=coords_src,
interpolation=[{
"method": "nearest",
"interpolators": [ScipyGrid]
}, {
"method": "linear",
"dims": ["time"]
}],
)
output = node.eval(coords_dst)
assert isinstance(output, UnitsDataArray)
assert np.all(output.lat.values == coords_dst["lat"].coordinates)
assert np.all(output.lon.values == coords_dst["lon"].coordinates)
assert np.all(output.time.values == coords_dst["time"].coordinates)
def test_interpolate_irregular_arbitrary_2dims(self):
""" irregular interpolation """
# try >2 dims
source = np.random.rand(5, 5, 3)
coords_src = Coordinates(
[clinspace(0, 10, 5),
clinspace(0, 10, 5), [2, 3, 5]],
dims=['lat', 'lon', 'time'])
coords_dst = Coordinates(
[clinspace(1, 11, 5),
clinspace(1, 11, 5), [2, 3, 5]],
dims=['lat', 'lon', 'time'])
node = MockArrayDataSource(source=source,
native_coordinates=coords_src,
interpolation={
'method': 'nearest',
'interpolators': [ScipyGrid]
})
output = node.eval(coords_dst)
assert isinstance(output, UnitsDataArray)
assert np.all(output.lat.values == coords_dst.coords['lat'])
assert np.all(output.lon.values == coords_dst.coords['lon'])
assert np.all(output.time.values == coords_dst.coords['time'])
def test_time_tolerance(self):
# unstacked 1D
source = np.random.rand(5, 5)
coords_src = Coordinates([
np.linspace(0, 10, 5),
clinspace('2018-01-01', '2018-01-09', 5)
],
dims=['lat', 'time'])
node = MockArrayDataSource(source=source,
native_coordinates=coords_src,
interpolation={
'default': {
'method': 'nearest',
'params': {
'spatial_tolerance':
1.1,
'time_tolerance':
np.timedelta64(1, 'D')
}
}
})
coords_dst = Coordinates(
[[1, 1.2, 1.5, 5, 9],
clinspace('2018-01-01', '2018-01-09', 3)],
dims=['lat', 'time'])
output = node.eval(coords_dst)
assert isinstance(output, UnitsDataArray)
assert np.all(output.lat.values == coords_dst.coords['lat'])
assert output.values[0, 0] == source[0, 0] and output.values[0, 1] == source[0, 2] and \
np.isnan(output.values[1, 0]) and np.isnan(output.values[1, 1]) and \
output.values[2, 0] == source[1, 0] and output.values[2, 1] == source[1, 2]
def test_evaluate_debug_attributes_no_overlap(self):
with podpac.settings:
podpac.settings["DEBUG"] = True
node = MockDataSource()
assert node._evaluated_coordinates is None
assert node._requested_coordinates is None
assert node._requested_source_coordinates is None
assert node._requested_source_coordinates_index is None
assert node._requested_source_boundary is None
assert node._requested_source_data is None
coords = Coordinates(
[clinspace(-55, -45, 20),
clinspace(-55, -45, 20)],
dims=["lat", "lon"])
node.eval(coords)
assert node._evaluated_coordinates is not None
assert node._requested_coordinates is not None
assert node._requested_source_coordinates is not None
assert node._requested_source_coordinates_index is not None
assert node._requested_source_boundary is None # still none in this case
assert node._requested_source_data is None # still none in this case
def test_nearest_selector_negative_time_step(self):
selector = Selector("nearest")
request1 = Coordinates([clinspace("2020-01-01", "2020-01-11", 11)],
["time"])
request2 = Coordinates([clinspace("2020-01-11", "2020-01-01", 11)],
["time"])
source1 = Coordinates(
[clinspace("2020-01-22T00", "2020-01-01T00", 126)], ["time"])
source2 = Coordinates(
[clinspace("2020-01-01T00", "2020-01-22T00", 126)], ["time"])
c11, ci11 = selector.select(source1, request1)
assert len(c11["time"]) == 11
assert len(ci11[0]) == 11
c12, ci12 = selector.select(source1, request2)
assert len(c12["time"]) == 11
assert len(ci12[0]) == 11
c21, ci21 = selector.select(source2, request1)
assert len(c21["time"]) == 11
assert len(ci21[0]) == 11
c22, ci22 = selector.select(source2, request2)
assert len(c22["time"]) == 11
assert len(ci22[0]) == 11
np.testing.assert_equal(ci11[0], ci12[0])
np.testing.assert_equal(ci21[0], ci22[0])
def test_time_tolerance(self):
# unstacked 1D
source = np.random.rand(5, 5)
coords_src = Coordinates(
[np.linspace(0, 10, 5),
clinspace("2018-01-01", "2018-01-09", 5)],
dims=["lat", "time"])
node = MockArrayDataSource(
data=source,
coordinates=coords_src,
interpolation={
"method": "nearest",
"params": {
"spatial_tolerance": 1.1,
"time_tolerance": np.timedelta64(1, "D")
},
},
)
coords_dst = Coordinates([[1, 1.2, 1.5, 5, 9],
clinspace("2018-01-01", "2018-01-09", 3)],
dims=["lat", "time"])
output = node.eval(coords_dst)
assert isinstance(output, UnitsDataArray)
assert np.all(output.lat.values == coords_dst["lat"].coordinates)
assert (output.values[0, 0] == source[0, 0]
and output.values[0, 1] == source[0, 2]
and np.isnan(output.values[1, 0])
and np.isnan(output.values[1, 1])
and output.values[2, 0] == source[1, 0]
and output.values[2, 1] == source[1, 2])
def test_evaluate_no_overlap_with_output(self):
# there is a shortcut if there is no intersect, so we test that here
node = MockDataSource()
coords = Coordinates([clinspace(30, 40, 10), clinspace(30, 40, 10)], dims=["lat", "lon"])
output = UnitsDataArray.create(coords, data=1)
node.eval(coords, output=output)
np.testing.assert_equal(output.data, np.full(output.shape, np.nan))
def setup_method(self, method):
self.coord_src = Coordinates([
clinspace(45, 0, 16),
clinspace(-70., -65., 16),
clinspace(0, 1, 2)
],
dims=['lat', 'lon', 'time'])
LON, LAT, TIME = np.meshgrid(self.coord_src['lon'].coordinates,
self.coord_src['lat'].coordinates,
self.coord_src['time'].coordinates)
self.latSource = LAT
self.lonSource = LON
self.timeSource = TIME
self.nasLat = Array(source=LAT.astype(float),
native_coordinates=self.coord_src,
interpolation='bilinear')
self.nasLon = Array(source=LON.astype(float),
native_coordinates=self.coord_src,
interpolation='bilinear')
self.nasTime = Array(source=TIME.astype(float),
native_coordinates=self.coord_src,
interpolation='bilinear')
def test_evaluate_no_overlap(self):
"""evaluate node with coordinates that do not overlap"""
node = MockDataSource()
coords = Coordinates([clinspace(-55, -45, 20), clinspace(-55, -45, 20)], dims=["lat", "lon"])
output = node.eval(coords)
assert np.all(np.isnan(output))
def test_interpolate_rasterio(self):
""" regular interpolation using rasterio"""
assert rasterio is not None
source = np.arange(0, 15)
source.resize((3, 5))
coords_src = Coordinates(
[clinspace(0, 10, 3), clinspace(0, 10, 5)], dims=["lat", "lon"])
coords_dst = Coordinates(
[clinspace(1, 11, 3), clinspace(1, 11, 5)], dims=["lat", "lon"])
# try one specific rasterio case to measure output
node = MockArrayDataSource(data=source,
coordinates=coords_src,
interpolation={
"method": "min",
"interpolators": [Rasterio]
})
output = node.eval(coords_dst)
assert isinstance(output, UnitsDataArray)
assert np.all(output.lat.values == coords_dst["lat"].coordinates)
assert output.data[0, 3] == 3.0
assert output.data[0, 4] == 4.0
node = MockArrayDataSource(data=source,
coordinates=coords_src,
interpolation={
"method": "max",
"interpolators": [Rasterio]
})
output = node.eval(coords_dst)
assert isinstance(output, UnitsDataArray)
assert np.all(output.lat.values == coords_dst["lat"].coordinates)
assert output.data[0, 3] == 9.0
assert output.data[0, 4] == 9.0
# TODO boundary should be able to use a default
node = MockArrayDataSource(
data=source,
coordinates=coords_src,
interpolation={
"method": "bilinear",
"interpolators": [Rasterio]
},
boundary={
"lat": 2.5,
"lon": 1.25
},
)
output = node.eval(coords_dst)
assert isinstance(output, UnitsDataArray)
assert np.all(output.lat.values == coords_dst["lat"].coordinates)
np.testing.assert_allclose(
output, [[1.4, 2.4, 3.4, 4.4, 5.0], [6.4, 7.4, 8.4, 9.4, 10.0],
[10.4, 11.4, 12.4, 13.4, 14.0]])
class TestArray(object):
"""Test Array datasource class (formerly Array)"""
data = np.random.rand(11, 11)
coordinates = Coordinates([clinspace(-25, 25, 11), clinspace(-25, 25, 11)], dims=['lat', 'lon'])
def test_source_trait(self):
""" must be an ndarray """
node = Array(source=self.data, native_coordinates=self.coordinates)
# list is coercable to array
node = Array(source=[0, 1, 1], native_coordinates=self.coordinates)
# this list is not coercable to array
# Starting with numpy 0.16, this is now allowed!
#with pytest.raises(TraitError):
#node = Array(source=[0, [0, 1]], native_coordinates=self.coordinates)
def test_get_data(self):
""" defined get_data function"""
source = self.data
node = Array(source=source, native_coordinates=self.coordinates)
output = node.eval(self.coordinates)
assert isinstance(output, UnitsDataArray)
assert output.values[0, 0] == source[0, 0]
assert output.values[4, 5] == source[4, 5]
def test_native_coordinates(self):
"""test that native coordinates get defined"""
node = Array(source=self.data)
with pytest.raises(NotImplementedError):
node.get_native_coordinates()
node = Array(source=self.data, native_coordinates=self.coordinates)
assert node.native_coordinates
node = Array(source=self.data, native_coordinates=self.coordinates)
native_coordinates = node.native_coordinates
get_native_coordinates = node.get_native_coordinates()
assert native_coordinates
assert get_native_coordinates
assert native_coordinates == get_native_coordinates
def test_base_definition(self):
node = Array(source=self.data)
d = node.base_definition
source = np.array(d['source'])
np.testing.assert_array_equal(source, self.data)
def test_definition(self):
node = Array(source=self.data)
pipeline = podpac.pipeline.Pipeline(definition=node.definition)
np.testing.assert_array_equal(pipeline.node.source, self.data)
def make_square_array(self, order=1, bands=1):
node = Array(
source=np.arange(8 * bands).reshape(3 - order, 3 + order, bands),
coordinates=Coordinates(
[clinspace(4, 0, 2, "lat"),
clinspace(1, 4, 4, "lon")][::order],
crs="EPSG:4326"),
outputs=[str(s) for s in list(range(bands))],
)
return node
def test_evaluate_with_output_no_intersect(self):
# there is a shortcut if there is no intersect, so we test that here
node = MockDataSource()
coords = Coordinates([clinspace(30, 40, 10),
clinspace(30, 40, 10)],
dims=['lat', 'lon'])
output = UnitsDataArray(np.ones(coords.shape),
coords=coords.coords,
dims=coords.dims)
node.eval(coords, output=output)
np.testing.assert_equal(output.data, np.full(output.shape, np.nan))
def test_set_native_coordinates(self):
nc = Coordinates([clinspace(0, 50, 101),
clinspace(0, 50, 101)],
dims=['lat', 'lon'])
node = DataSource(source='test', native_coordinates=nc)
assert node.native_coordinates is not None
with pytest.raises(tl.TraitError):
DataSource(source='test', native_coordinates='not a coordinate')
with pytest.raises(NotImplementedError):
DataSource(source='test').native_coordinates
def test_interpolate_scipy_grid(self):
source = np.arange(0, 25)
source.resize((5, 5))
coords_src = Coordinates(
[clinspace(0, 10, 5), clinspace(0, 10, 5)], dims=["lat", "lon"])
coords_dst = Coordinates(
[clinspace(1, 11, 5), clinspace(1, 11, 5)], dims=["lat", "lon"])
# try one specific rasterio case to measure output
node = MockArrayDataSource(data=source,
coordinates=coords_src,
interpolation={
"method": "nearest",
"interpolators": [ScipyGrid]
})
output = node.eval(coords_dst)
assert isinstance(output, UnitsDataArray)
assert np.all(output.lat.values == coords_dst["lat"].coordinates)
print(output)
assert output.data[0, 0] == 0.0
assert output.data[0, 3] == 3.0
assert output.data[1, 3] == 8.0
assert np.isnan(output.data[0,
4]) # TODO: how to handle outside bounds
node = MockArrayDataSource(data=source,
coordinates=coords_src,
interpolation={
"method": "cubic_spline",
"interpolators": [ScipyGrid]
})
output = node.eval(coords_dst)
assert isinstance(output, UnitsDataArray)
assert np.all(output.lat.values == coords_dst["lat"].coordinates)
assert int(output.data[0, 0]) == 2
assert int(output.data[2, 4]) == 16
node = MockArrayDataSource(data=source,
coordinates=coords_src,
interpolation={
"method": "bilinear",
"interpolators": [ScipyGrid]
})
output = node.eval(coords_dst)
assert isinstance(output, UnitsDataArray)
assert np.all(output.lat.values == coords_dst["lat"].coordinates)
assert int(output.data[0, 0]) == 2
assert int(output.data[3, 3]) == 20
assert np.isnan(output.data[4,
4]) # TODO: how to handle outside bounds
def test_interpolate_alt(self):
""" for now alt uses nearest neighbor """
source = np.random.rand(5)
coords_src = Coordinates([clinspace(0, 10, 5)], dims=['alt'])
coords_dst = Coordinates([clinspace(1, 11, 5)], dims=['alt'])
node = MockArrayDataSource(source=source,
native_coordinates=coords_src)
output = node.eval(coords_dst)
assert isinstance(output, UnitsDataArray)
assert np.all(output.alt.values == coords_dst.coords['alt'])
def test_evaluate_no_overlap_with_output_extract_output(self):
class MockMultipleDataSource(DataSource):
outputs = ["a", "b", "c"]
coordinates = Coordinates([[0, 1, 2, 3], [10, 11]], dims=["lat", "lon"])
def get_data(self, coordinates, coordinates_index):
return self.create_output_array(coordinates, data=1)
node = MockMultipleDataSource(output="a")
coords = Coordinates([clinspace(-55, -45, 20), clinspace(-55, -45, 20)], dims=["lat", "lon"])
output = node.eval(coords)
assert np.all(np.isnan(output))
def test_interpolate_scipy_grid(self):
source = np.arange(0, 25)
source.resize((5, 5))
coords_src = Coordinates(
[clinspace(0, 10, 5), clinspace(0, 10, 5)],
dims=['lat', 'lon'])
coords_dst = Coordinates(
[clinspace(1, 11, 5), clinspace(1, 11, 5)],
dims=['lat', 'lon'])
# try one specific rasterio case to measure output
node = MockArrayDataSource(source=source,
native_coordinates=coords_src)
node.interpolation = {
'method': 'nearest',
'interpolators': [ScipyGrid]
}
output = node.eval(coords_dst)
assert isinstance(output, UnitsDataArray)
assert np.all(output.lat.values == coords_dst.coords['lat'])
print(output)
assert output.data[0, 0] == 0.
assert output.data[0, 3] == 3.
assert output.data[1, 3] == 8.
assert np.isnan(
output.data[0, 4]) # TODO: how to handle outside bounds
node.interpolation = {
'method': 'cubic_spline',
'interpolators': [ScipyGrid]
}
output = node.eval(coords_dst)
assert isinstance(output, UnitsDataArray)
assert np.all(output.lat.values == coords_dst.coords['lat'])
assert int(output.data[0, 0]) == 2
assert int(output.data[2, 4]) == 16
node.interpolation = {
'method': 'bilinear',
'interpolators': [ScipyGrid]
}
output = node.eval(coords_dst)
assert isinstance(output, UnitsDataArray)
assert np.all(output.lat.values == coords_dst.coords['lat'])
assert int(output.data[0, 0]) == 2
assert int(output.data[3, 3]) == 20
assert np.isnan(
output.data[4, 4]) # TODO: how to handle outside bounds
def test_raster_to_raster(self):
coord_dst = Coordinates(
[clinspace(5., 40., 50),
clinspace(-68., -66., 100)],
dims=['lat', 'lon'])
oLat = self.nasLat.eval(coord_dst)
oLon = self.nasLon.eval(coord_dst)
LON, LAT = np.meshgrid(coord_dst['lon'].coordinates,
coord_dst['lat'].coordinates)
np.testing.assert_array_almost_equal(oLat.data[..., 0], LAT)
np.testing.assert_array_almost_equal(oLon.data[..., 0], LON)
def test_interpolators(self):
node = MockDataSource()
node.eval(node.native_coordinates)
assert isinstance(node.interpolators, OrderedDict)
# when no interpolation happens, this returns as an empty ordered dict
assert not node.interpolators
# when interpolation happens, this is filled
node.eval(
Coordinates([clinspace(-11, 11, 7),
clinspace(-11, 11, 7)],
dims=['lat', 'lon']))
assert 'lat' in list(node.interpolators.keys())[0]
assert 'lon' in list(node.interpolators.keys())[0]
assert isinstance(list(node.interpolators.values())[0], Interpolator)
def test_interpolate_looper_helper(self):
""" irregular interpolation """
# Note, this test also tests the looper helper
# try >2 dims
source = np.random.rand(5, 5, 3, 2)
result = source.copy()
result[:, :, 2, :] = (result[:, :, 1, :] + result[:, :, 2, :]) / 2
result = (result[..., 0:1] + result[..., 1:]) / 2
result = result[[0, 1, 2, 3, 4]]
result = result[:, [0, 1, 2, 3, 4]]
result[-1] = np.nan
result[:, -1] = np.nan
coords_src = Coordinates(
[clinspace(0, 10, 5),
clinspace(0, 10, 5), [2, 3, 5], [0, 2]],
dims=["lat", "lon", "time", "alt"])
coords_dst = Coordinates(
[clinspace(1, 11, 5),
clinspace(1, 11, 5), [2, 3, 4], [1]],
dims=["lat", "lon", "time", "alt"])
node = MockArrayDataSource(
data=source,
coordinates=coords_src,
interpolation=[
{
"method": "nearest",
"interpolators": [ScipyGrid]
},
{
"method": "linear",
"dims": ["time", "alt"]
},
],
)
output = node.eval(coords_dst)
assert isinstance(output, UnitsDataArray)
assert np.all(output.lat.values == coords_dst["lat"].coordinates)
assert np.all(output.lon.values == coords_dst["lon"].coordinates)
assert np.all(output.time.values == coords_dst["time"].coordinates)
assert np.all(output.alt.values == coords_dst["alt"].coordinates)
np.testing.assert_array_almost_equal(result, output.data)
def test_get_native_coordinates(self):
# get_native_coordinates should set the native_coordinates by default
node = MockDataSource()
assert node.native_coordinates is not None
np.testing.assert_equal(node.native_coordinates['lat'].coordinates,
np.linspace(-25, 25, 101))
np.testing.assert_equal(node.native_coordinates['lon'].coordinates,
np.linspace(-25, 25, 101))
# but don't call get_native_coordinates if the native_coordinates are set explicitly
nc = Coordinates([clinspace(0, 50, 101),
clinspace(0, 50, 101)],
dims=['lat', 'lon'])
node = MockDataSource(native_coordinates=nc)
assert node.native_coordinates is not None
np.testing.assert_equal(node.native_coordinates['lat'].coordinates,
nc['lat'].coordinates)
np.testing.assert_equal(node.native_coordinates['lat'].coordinates,
nc['lat'].coordinates)
def test_interpolate_rasterio(self):
""" regular interpolation using rasterio"""
assert rasterio is not None
source = np.arange(0, 15)
source.resize((3, 5))
coords_src = Coordinates(
[clinspace(0, 10, 3), clinspace(0, 10, 5)],
dims=['lat', 'lon'])
coords_dst = Coordinates(
[clinspace(1, 11, 3), clinspace(1, 11, 5)],
dims=['lat', 'lon'])
# try one specific rasterio case to measure output
node = MockArrayDataSource(source=source,
native_coordinates=coords_src)
node.interpolation = {'method': 'min', 'interpolators': [Rasterio]}
output = node.eval(coords_dst)
assert isinstance(output, UnitsDataArray)
assert np.all(output.lat.values == coords_dst.coords['lat'])
assert output.data[0, 3] == 3.
assert output.data[0, 4] == 4.
node.interpolation = {'method': 'max', 'interpolators': [Rasterio]}
output = node.eval(coords_dst)
assert isinstance(output, UnitsDataArray)
assert np.all(output.lat.values == coords_dst.coords['lat'])
assert output.data[0, 3] == 9.
assert output.data[0, 4] == 9.
node.interpolation = {
'method': 'bilinear',
'interpolators': [Rasterio]
}
output = node.eval(coords_dst)
assert isinstance(output, UnitsDataArray)
assert np.all(output.lat.values == coords_dst.coords['lat'])
assert int(output.data[0, 0]) == 1
assert int(output.data[0, 4]) == 5
def test_evaluate_with_output_transpose(self):
# initialize coords with dims=[lon, lat]
lat = clinspace(10, 20, 11)
lon = clinspace(10, 15, 6)
coords = Coordinates([lat, lon], dims=['lat', 'lon'])
# evaluate with dims=[lat, lon], passing in the output
node = MockDataSource()
output = node.create_output_array(coords.transpose('lon', 'lat'))
returned_output = node.eval(coords, output=output)
# returned output sohuld match the requested coordinates
assert returned_output.dims == ('lat', 'lon')
# dims should stay in the order of the output, rather than the order of the requested coordinates
assert output.dims == ('lon', 'lat')
# output data and returned output data should match
np.testing.assert_equal(
output.transpose('lat', 'lon').data, returned_output.data)
def test_interpolate_rasterio_descending(self):
"""should handle descending"""
source = np.random.rand(5, 5)
coords_src = Coordinates(
[clinspace(10, 0, 5), clinspace(0, 10, 5)], dims=["lat", "lon"])
coords_dst = Coordinates(
[clinspace(2, 12, 5), clinspace(2, 12, 5)], dims=["lat", "lon"])
node = MockArrayDataSource(data=source,
coordinates=coords_src,
interpolation={
"method": "nearest",
"interpolators": [Rasterio]
})
output = node.eval(coords_dst)
assert isinstance(output, UnitsDataArray)
assert np.all(output.lat.values == coords_dst["lat"].coordinates)
assert np.all(output.lon.values == coords_dst["lon"].coordinates)
def test_dim_in(self):
interpolator = Interpolator(methods_supported=["test"], method="test")
coords = Coordinates(
[clinspace(0, 10, 5), clinspace(0, 10, 5)], dims=["lat", "lon"])
assert interpolator._dim_in("lat", coords)
assert interpolator._dim_in("lat", coords, unstacked=True)
assert not interpolator._dim_in("time", coords)
coords_two = Coordinates([clinspace(0, 10, 5)], dims=["lat"])
assert interpolator._dim_in("lat", coords, coords_two)
assert not interpolator._dim_in("lon", coords, coords_two)
coords_three = Coordinates(
[(np.linspace(0, 10, 5), np.linspace(0, 10, 5))], dims=["lat_lon"])
assert not interpolator._dim_in("lat", coords, coords_two,
coords_three)
assert interpolator._dim_in("lat",
coords,
coords_two,
coords_three,
unstacked=True)
def test_interpolate_irregular_arbitrary_swap(self):
"""should handle descending"""
source = np.random.rand(5, 5)
coords_src = Coordinates(
[clinspace(0, 10, 5), clinspace(0, 10, 5)], dims=["lat", "lon"])
coords_dst = Coordinates(
[clinspace(2, 12, 5), clinspace(2, 12, 5)], dims=["lat", "lon"])
node = MockArrayDataSource(data=source,
coordinates=coords_src,
interpolation={
"method": "nearest",
"interpolators": [ScipyGrid]
})
output = node.eval(coords_dst)
assert isinstance(output, UnitsDataArray)
np.testing.assert_array_equal(output.lat.values,
coords_dst["lat"].coordinates)
np.testing.assert_array_equal(output.lon.values,
coords_dst["lon"].coordinates)
def test_interpolate_irregular_arbitrary_swap(self):
"""should handle descending"""
source = np.random.rand(5, 5)
coords_src = Coordinates(
[clinspace(0, 10, 5), clinspace(0, 10, 5)],
dims=['lat', 'lon'])
coords_dst = Coordinates(
[clinspace(2, 12, 5), clinspace(2, 12, 5)],
dims=['lat', 'lon'])
node = MockArrayDataSource(source=source,
native_coordinates=coords_src,
interpolation={
'method': 'nearest',
'interpolators': [ScipyGrid]
})
output = node.eval(coords_dst)
assert isinstance(output, UnitsDataArray)
assert np.all(output.lat.values == coords_dst.coords['lat'])
assert np.all(output.lon.values == coords_dst.coords['lon'])
def test_get_data(self):
"""get data from wcs server"""
self.mock_requests()
node = WCS(source=self.source)
lat = node.native_coordinates['lat'].coordinates
lon = node.native_coordinates['lon'].coordinates
time = node.native_coordinates['time'].coordinates
# no time
notime_coordinates = Coordinates([
clinspace(lat[0], lat[-2], 10),
clinspace(lon[0], lon[-2], 10),
'2006-06-14T17:00:00'],
dims=['lat', 'lon', 'time'])
with pytest.raises(ValueError):
output = node.eval(notime_coordinates)
assert isinstance(output, UnitsDataArray)
assert output.native_coordinates['lat'][0] == node.native_coordinates['lat'][0]
# time
time_coordinates = Coordinates([
clinspace(lat[0], lat[-2], 10),
clinspace(lon[0], lon[-2], 10),
clinspace(time[0], time[-1], len(time))],
dims=['lat', 'lon', 'time'])
with pytest.raises(ValueError):
output = node.eval(time_coordinates)
assert isinstance(output, UnitsDataArray)
# requests exceptions
self.mock_requests(data_status_code=400)
with pytest.raises(Exception):
output = node.eval(time_coordinates)
with pytest.raises(Exception):
output = node.eval(time_coordinates)
