def fetch_raster(self, projection, extent, target_resolution):
"""
Fetch SRTM elevation for the given projection and approximate extent.
"""
if not self.validate_projection(projection):
raise ValueError(f'Unsupported projection for the '
f'SRTM{self._resolution} source.')
min_x, max_x, min_y, max_y = extent
min_x, min_y = np.floor([min_x, min_y])
nx = int(np.ceil(max_x) - min_x)
ny = int(np.ceil(max_y) - min_y)
skip = False
if nx > self._max_tiles[0]:
warnings.warn(
f'Required SRTM{self._resolution} tile count ({nx}) exceeds '
f'maximum ({self._max_tiles[0]}). Increase max_nx limit.')
skip = True
if ny > self._max_tiles[1]:
warnings.warn(
f'Required SRTM{self._resolution} tile count ({ny}) exceeds '
f'maximum ({self._max_tiles[1]}). Increase max_ny limit.')
skip = True
if skip:
return []
else:
img, _, extent = self.combined(min_x, min_y, nx, ny)
return [LocatedImage(np.flipud(img), extent)]
def fetch_raster(self, projection, extent, target_resolution):
target_resolution = np.array(target_resolution, dtype=int)
x = np.linspace(extent[0], extent[1], target_resolution[0])
y = np.linspace(extent[2], extent[3], target_resolution[1])
xs, ys = np.meshgrid(x, y)
xyz_sample = self._geocent.transform_points(
projection, xs.flatten(), ys.flatten())
start = time.time()
_, node_indices = self._kd.query(xyz_sample, k=1)
end = time.time()
logging.info('Query of {} points: {}'.format(
np.prod(target_resolution), end - start))
# Clip to valid node indices: can get =N-points for NaN or inf. points.
n_points = self._node_faces.shape[0]
node_indices[(node_indices < 0) | (node_indices >= n_points)] = 0
start = time.time()
face_indices = fmgc.search_faces_for_points(
target_points_xyz=xyz_sample,
i_nodes_nearest=node_indices,
nodes_xyz_array=self._nodes_xyz,
face_nodes_array=self._face_nodes,
node_faces_array=self._node_faces
)
end = time.time()
logging.info('Face search of {} points: {}'.format(
np.prod(target_resolution), end - start))
result = self.img[face_indices].reshape(target_resolution[1],
target_resolution[0])
return [LocatedImage(result, extent)]
def fetch_raster(self, projection, extent, target_resolution):
matrix_set_name = self._matrix_set_name(projection)
wmts_projection = _URN_TO_CRS[
self.wmts.tilematrixsets[matrix_set_name].crs]
if wmts_projection == projection:
wmts_extents = [extent]
else:
# Calculate (possibly multiple) extents in the given projection.
wmts_extents = _target_extents(extent, projection, wmts_projection)
# Bump resolution by a small factor, as a weak alternative to
# delivering a minimum projected resolution.
# Generally, the desired area is smaller than the enclosing extent
# in projection space and may have varying scaling, so the ideal
# solution is a hard problem !
resolution_factor = 1.4
target_resolution = np.array(target_resolution) * resolution_factor
width, height = target_resolution
located_images = []
for wmts_desired_extent in wmts_extents:
# Calculate target resolution for the actual polygon. Note that
# this gives *every* polygon enough pixels for the whole result,
# which is potentially excessive!
min_x, max_x, min_y, max_y = wmts_desired_extent
if wmts_projection == projection:
max_pixel_span = min((max_x - min_x) / width,
(max_y - min_y) / height)
else:
# X/Y orientation is arbitrary, so use a worst-case guess.
max_pixel_span = (min(max_x - min_x, max_y - min_y) /
max(width, height))
# Fetch a suitable image and its actual extent.
wmts_image, wmts_actual_extent = self._wmts_images(
self.wmts,
self.layer,
matrix_set_name,
extent=wmts_desired_extent,
max_pixel_span=max_pixel_span)
# Return each (image, extent) as a LocatedImage.
if wmts_projection == projection:
located_image = LocatedImage(wmts_image, wmts_actual_extent)
else:
# Reproject the image to the desired projection.
located_image = _warped_located_image(
wmts_image,
wmts_projection,
wmts_actual_extent,
output_projection=projection,
output_extent=extent,
target_resolution=target_resolution)
located_images.append(located_image)
return located_images
def fetch_raster(self, projection, extent, target_resolution):
matrix_set_name = self._matrix_set_name(projection)
min_x, max_x, min_y, max_y = extent
width, height = target_resolution
max_pixel_span = min((max_x - min_x) / width, (max_y - min_y) / height)
image, extent = self._wmts_images(self.wmts, self.layer,
matrix_set_name, extent,
max_pixel_span)
return [LocatedImage(image, extent)]
def fill_and_shade(located_elevations):
"""
Given an array of elevations in a LocatedImage, fill any holes in
the data and add a relief (shadows) to give a realistic 3d appearance.
"""
new_elevations = srtm.fill_gaps(located_elevations.image, max_distance=15)
new_img = srtm.add_shading(new_elevations, azimuth=135, altitude=15)
return LocatedImage(new_img, located_elevations.extent)
def shade(located_elevations):
"""
Given an array of elevations in a LocatedImage, add a relief (shadows) to
give a realistic 3d appearance.
"""
new_img = srtm.add_shading(located_elevations.image,
azimuth=135,
altitude=15)
return LocatedImage(new_img, located_elevations.extent)
def _warped_located_image(image, source_projection, source_extent,
output_projection, output_extent, target_resolution):
"""
Reproject an Image from one source-projection and extent to another.
Returns
-------
LocatedImage
A reprojected LocatedImage, the extent of which is >= the requested
'output_extent'.
"""
if source_projection == output_projection:
extent = output_extent
else:
# Convert Image to numpy array (flipping so that origin
# is 'lower').
img, extent = warp_array(np.asanyarray(image)[::-1],
source_proj=source_projection,
source_extent=source_extent,
target_proj=output_projection,
target_res=np.asarray(target_resolution,
dtype=int),
target_extent=output_extent,
mask_extrapolated=True)
# Convert arrays with masked RGB(A) values to non-masked RGBA
# arrays, setting the alpha channel to zero for masked values.
# This avoids unsightly grey boundaries appearing when the
# extent is limited (i.e. not global).
if np.ma.is_masked(img):
if img.shape[2:3] == (3,):
# RGB
old_img = img
img = np.zeros(img.shape[:2] + (4,), dtype=img.dtype)
img[:, :, 0:3] = old_img
img[:, :, 3] = ~ np.any(old_img.mask, axis=2)
if img.dtype.kind == 'u':
img[:, :, 3] *= 255
elif img.shape[2:3] == (4,):
# RGBA
img[:, :, 3] = np.where(np.any(img.mask, axis=2), 0,
img[:, :, 3])
img = img.data
# Convert warped image array back to an Image, undoing the
# earlier flip.
image = Image.fromarray(img[::-1])
return LocatedImage(image, extent)
def _image_and_extent(self, wms_proj, wms_srs, wms_extent, output_proj,
output_extent, target_resolution):
min_x, max_x, min_y, max_y = wms_extent
wms_image = self.service.getmap(layers=self.layers,
srs=wms_srs,
bbox=(min_x, min_y, max_x, max_y),
size=target_resolution,
format='image/png',
**self.getmap_extra_kwargs)
wms_image = Image.open(io.BytesIO(wms_image.read()))
if wms_proj == output_proj:
extent = output_extent
else:
# Convert Image to numpy array (flipping so that origin
# is 'lower').
img, extent = warp_array(np.asanyarray(wms_image)[::-1],
source_proj=wms_proj,
source_extent=wms_extent,
target_proj=output_proj,
target_res=target_resolution,
target_extent=output_extent,
mask_extrapolated=True)
# Convert arrays with masked RGB(A) values to non-masked RGBA
# arrays, setting the alpha channel to zero for masked values.
# This avoids unsightly grey boundaries appearing when the
# extent is limited (i.e. not global).
if np.ma.is_masked(img):
if img.shape[2:3] == (3, ):
# RGB
old_img = img
img = np.zeros(img.shape[:2] + (4, ), dtype=img.dtype)
img[:, :, 0:3] = old_img
img[:, :, 3] = ~np.any(old_img.mask, axis=2)
if img.dtype.kind == 'u':
img[:, :, 3] *= 255
elif img.shape[2:3] == (4, ):
# RGBA
img[:, :, 3] = np.where(np.any(img.mask, axis=2), 0,
img[:, :, 3])
img = img.data
# Convert warped image array back to an Image, undoing the
# earlier flip.
wms_image = Image.fromarray(img[::-1])
return LocatedImage(wms_image, extent)
def fetch_raster(self, projection, extent, target_resolution):
"""
Fetch SRTM3 elevation for the given projection and approximate extent.
"""
if not self.validate_projection(projection):
raise ValueError('Unsupported projection for the SRTM3 source.')
min_x, max_x, min_y, max_y = extent
min_x, min_y = np.floor([min_x, min_y])
nx = int(np.ceil(max_x) - min_x)
ny = int(np.ceil(max_y) - min_y)
if nx > self._max_tiles[0] or ny > self._max_tiles[1]:
return []
else:
img, _, extent = self.combined(min_x, min_y, nx, ny)
return [LocatedImage(np.flipud(img), extent)]
def _warped_located_image(image, source_projection, source_extent,
output_projection, output_extent, target_resolution):
"""
Reproject an Image from one source-projection and extent to another.
Returns
-------
LocatedImage
A reprojected LocatedImage, the extent of which is >= the requested
'output_extent'.
"""
if source_projection == output_projection:
extent = output_extent
else:
# Convert Image to numpy array (flipping so that origin
# is 'lower').
# Convert to RGBA to keep the color palette in the regrid process
# if any
img, extent = warp_array(np.asanyarray(image.convert('RGBA'))[::-1],
source_proj=source_projection,
source_extent=source_extent,
target_proj=output_projection,
target_res=np.asarray(target_resolution,
dtype=int),
target_extent=output_extent,
mask_extrapolated=True)
# Convert arrays with masked RGB(A) values to non-masked RGBA
# arrays, setting the alpha channel to zero for masked values.
# This avoids unsightly grey boundaries appearing when the
# extent is limited (i.e. not global).
if np.ma.is_masked(img):
img[:, :, 3] = np.where(np.any(img.mask, axis=2), 0, img[:, :, 3])
img = img.data
# Convert warped image array back to an Image, undoing the
# earlier flip.
image = Image.fromarray(img[::-1])
return LocatedImage(image, extent)
