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views.py
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views.py
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import io
import json
import os
import re
import uuid
import zipfile
from datetime import datetime
from tempfile import NamedTemporaryFile
import numpy
from PIL import Image
from django.conf import settings
from django.contrib.gis.gdal import GDALRaster
from django.contrib.gis.gdal.raster.const import VSI_FILESYSTEM_BASE_PATH
from django.contrib.gis.geos import Polygon
from django.db.models import Max, Q
from django.http import FileResponse, Http404, HttpResponse
from django.shortcuts import get_object_or_404
from django.template.defaultfilters import slugify
from django.utils.functional import cached_property
from django.views.generic import View
from raster.algebra.const import ALGEBRA_PIXEL_TYPE_GDAL, BAND_INDEX_SEPARATOR
from raster.algebra.parser import RasterAlgebraParser
from raster.const import EXPORT_MAX_PIXELS, IMG_ENHANCEMENTS, IMG_FORMATS, MAX_EXPORT_NAME_LENGTH, README_TEMPLATE
from raster.exceptions import RasterAlgebraException
from raster.models import Legend, RasterLayer, RasterLayerBandMetadata, RasterLayerMetadata
from raster.shortcuts import get_session_colormap
from raster.tiles.const import WEB_MERCATOR_SRID, WEB_MERCATOR_TILESIZE
from raster.tiles.lookup import get_raster_tile
from raster.tiles.utils import tile_bounds, tile_index_range, tile_scale
from raster.utils import band_data_to_image, colormap_to_rgba, pixel_value_from_point
class RasterView(View):
@property
def is_pixel_request(self):
return 'xcoord' in self.kwargs
def get_colormap(self, layer=None):
"""
Returns colormap from request and layer, looking for a colormap in the
request or session, a custom legend name to construct the legend or the
default colormap from the layer legend.
"""
colormap = None
if 'colormap' in self.request.GET:
colormap = colormap_to_rgba(json.loads(self.request.GET['colormap']))
# Ensure colormap range is in float format.
if 'range' in colormap:
colormap['range'] = (float(colormap['range'][0]), float(colormap['range'][1]))
elif 'legend' in self.request.GET:
store = self.request.GET.get('store', 'database')
if store == 'session':
colormap = get_session_colormap(
self.request.session,
self.request.GET['legend']
)
else:
legend_input = self.request.GET['legend']
try:
legend_input = int(legend_input)
except ValueError:
pass
# Try to get legend by id, name or from input layer
if isinstance(legend_input, int):
legend = get_object_or_404(Legend, id=legend_input)
else:
legend = Legend.objects.filter(title__iexact=legend_input).first()
colormap = legend.colormap
elif 'layer' in self.kwargs:
# Get legend for the input layer.
legend = Legend.objects.filter(rasterlayer=self.kwargs.get('layer')).first()
if legend and hasattr(legend, 'colormap'):
colormap = legend.colormap
if not colormap:
# Use a continous grayscale color scheme.
colormap = {
'continuous': True,
'from': (0, 0, 0),
'to': (255, 255, 255),
}
else:
# Add layer level value range to continuous colormaps if it was
# not provided manually.
if 'continuous' in colormap and 'range' not in colormap:
meta = RasterLayerBandMetadata.objects.filter(rasterlayer_id=self.kwargs.get('layer')).first()
if meta:
colormap['range'] = (meta.min, meta.max)
# Filter by custom entries if requested
if colormap and 'entries' in self.request.GET:
entries = self.request.GET['entries'].split(',')
colormap = {k: v for (k, v) in colormap.items() if str(k) in entries}
return colormap
def get_format(self):
"""
Returns image format requested.
"""
return IMG_FORMATS[self.kwargs.get('frmt')]
def enhance(self, img):
for key, enhancer in IMG_ENHANCEMENTS.items():
if key in self.request.GET:
img = enhancer(img).enhance(float(self.request.GET.get(key)))
return img
def write_img_to_response(self, img, stats):
"""
Writes rgba numpy array to http response.
"""
# Get requested format and corresponding content type.
frmt, content_type = self.get_format()
# Enhance image if requested.
img = self.enhance(img)
# Save image to io buffer.
with io.BytesIO() as output:
img.save(output, format=frmt)
# Create response with image content.
response = HttpResponse(
output.getvalue(),
content_type=content_type,
)
# Add aggregation statistics to response headers.
response['aggregation'] = json.dumps(stats)
return response
def get_tile(self, layer_id, zlevel=None):
"""
Returns a tile for rendering. If the tile does not exists, higher
level tiles are searched and warped to lower level if found.
"""
if self.is_pixel_request:
tilez = self.max_zoom
# Derive the tile index from the input coordinates.
xcoord = float(self.kwargs.get('xcoord'))
ycoord = float(self.kwargs.get('ycoord'))
bbox = [xcoord, ycoord, xcoord, ycoord]
indexrange = tile_index_range(bbox, tilez)
tilex = indexrange[0]
tiley = indexrange[1]
else:
# Get tile indices from the request url parameters.
tilez = int(self.kwargs.get('z'))
tilex = int(self.kwargs.get('x'))
tiley = int(self.kwargs.get('y'))
return get_raster_tile(layer_id, tilez, tilex, tiley)
def get_layer(self):
"""
Gets layer from request data trying both name and id.
"""
# Get layer query data from input
if 'layer' in self.kwargs:
data = self.kwargs.get('layer')
elif 'layer' in self.request.GET:
data = self.request.GET.get('layer')
else:
raise Http404
# Determine query paremeter type
try:
data = int(data)
query = Q(id=data)
except ValueError:
query = Q(rasterfile__contains='rasters/' + data)
return get_object_or_404(RasterLayer, query)
@cached_property
def max_zoom(self):
return RasterLayerMetadata.objects.filter(
rasterlayer_id__in=self.get_ids().values()
).aggregate(zlevel=Max('max_zoom'))['zlevel']
class AlgebraView(RasterView):
"""
A view to calculate map algebra on raster layers.
"""
_layer_ids = None
def get_ids(self):
if self._layer_ids is not None:
return self._layer_ids
if 'layer' in self.kwargs:
# For tms requests, construct simple ids dictionary.
data = self.kwargs.get('layer')
# Determine query paremeter type
try:
layer_id = int(data)
except ValueError:
query = Q(rasterfile__contains='rasters/' + data)
layer_id = get_object_or_404(RasterLayer, query).id
# For TMS tile request, get the layer id from the url.
self._layer_ids = {'x': layer_id}
else:
# For algebra requests, get the layer ids from the query parameter.
ids = self.request.GET.get('layers', '').split(',')
# Check if layer parameter is valid
if not len(ids) or not all('=' in idx for idx in ids):
raise RasterAlgebraException('Layer parameter is not valid.')
# Split id/name input pairs
ids = [idx.split('=') for idx in ids]
# Convert ids to integer
try:
ids = {idx[0]: int(idx[1]) for idx in ids}
except ValueError:
raise RasterAlgebraException('Layer parameter is not valid.')
self._layer_ids = ids
return self._layer_ids
def get_formula(self):
if 'layer' in self.kwargs:
# Set the formula to trivial for TMS requests.
return 'x'
else:
return self.request.GET.get('formula', None)
def get(self, request, *args, **kwargs):
# Get layer ids
ids = self.get_ids()
# Prepare unique list of layer ids to be efficient if the same layer
# is used multiple times (for band access for instance).
layerids = set(ids.values())
# Get the tiles for each unique layer.
tiles = {}
for layerid in layerids:
tile = self.get_tile(layerid)
if tile:
tiles[layerid] = tile
else:
# Create empty image if any layer misses the required tile
img = Image.new("RGBA", (WEB_MERCATOR_TILESIZE, WEB_MERCATOR_TILESIZE), (0, 0, 0, 0))
return self.write_img_to_response(img, {})
# Map tiles to a dict with formula names as keys.
data = {}
for name, layerid in ids.items():
data[name] = tiles[layerid]
# Get formula from request
formula = self.get_formula()
# Dispatch by request type. If a formula was provided, use raster
# algebra otherwise look for rgb request.
if formula:
return self.get_algebra(data, formula)
else:
keys = [key.split(BAND_INDEX_SEPARATOR)[0] for key in data.keys()]
if 'r' in keys and 'g' in keys and 'b' in keys:
return self.get_rgb(data)
else:
raise RasterAlgebraException(
'Specify raster algebra formula or provide rgb layer keys.'
)
def get_algebra(self, data, formula):
parser = RasterAlgebraParser()
# Evaluate raster algebra expression, return 400 if not successful
try:
# Evaluate raster algebra expression
result = parser.evaluate_raster_algebra(data, formula)
except:
raise RasterAlgebraException('Failed to evaluate raster algebra.')
# For pixel value requests, return result as json.
if self.is_pixel_request:
xcoord = float(self.kwargs.get('xcoord'))
ycoord = float(self.kwargs.get('ycoord'))
val = pixel_value_from_point(result, [xcoord, ycoord])
return HttpResponse(
json.dumps({'x': xcoord, 'y': ycoord, 'value': val}),
content_type='application/json',
)
# For tif requests, skip colormap and return georeferenced tif file.
if self.kwargs.get('frmt') == 'tif':
vsi_path = os.path.join(VSI_FILESYSTEM_BASE_PATH, str(uuid.uuid4()))
rast = result.warp({
'name': vsi_path,
'driver': 'tif',
'compress': 'DEFLATE',
})
content_type = IMG_FORMATS['tif'][1]
return HttpResponse(rast.vsi_buffer, content_type)
# Get array from algebra result
if result.bands[0].nodata_value is None:
result = result.bands[0].data()
else:
result = numpy.ma.masked_values(
result.bands[0].data(),
result.bands[0].nodata_value,
)
# Get colormap.
colormap = self.get_colormap()
# Render tile using the legend data
img, stats = band_data_to_image(result, colormap)
# Return rendered image
return self.write_img_to_response(img, stats)
def get_rgb_scale(self):
if 'scale' not in self.request.GET:
return
# The scale is either a number or two numbers separated by comma.
scale = self.request.GET.get('scale').split(',')
if len(scale) == 1:
scale_min = 0
scale_max = float(scale[0])
else:
# Get min an max scale from
scale_min = float(scale[0])
scale_max = float(scale[1])
return scale_min, scale_max
def get_alpha(self):
return 'alpha' in self.request.GET
def get_rgb(self, data):
# Get data arrays from tiles, by band if requested.
for key, tile in data.items():
keysplit = key.split(BAND_INDEX_SEPARATOR)
variable = keysplit[0]
if len(keysplit) > 1:
band_index = int(keysplit[1])
else:
band_index = 0
band = tile.bands[band_index]
if variable == 'r':
red = band.data()
red_nodata = band.nodata_value
red_gdal_dtype = band.datatype()
elif variable == 'g':
green = band.data()
green_nodata = band.nodata_value
elif variable == 'b':
blue = band.data()
blue_nodata = band.nodata_value
# For tif requests, skip rgb rendering and return georeferenced tif file.
if self.kwargs.get('frmt') == 'tif':
vsi_path = os.path.join(VSI_FILESYSTEM_BASE_PATH, str(uuid.uuid4()))
# Construct 3 band raster, assuming all
ref = next(iter(data.values()))
result = GDALRaster({
'name': vsi_path,
'driver': 'tif',
'srid': WEB_MERCATOR_SRID,
'datatype': red_gdal_dtype,
'width': ref.width,
'height': ref.height,
'origin': ref.origin,
'scale': ref.scale,
'skew': ref.skew,
'bands': [
{'data': red, 'nodata_value': red_nodata},
{'data': green.astype(red.dtype), 'nodata_value': green_nodata},
{'data': blue.astype(red.dtype), 'nodata_value': blue_nodata},
],
'papsz_options': {
'compress': 'deflate',
},
})
content_type = IMG_FORMATS['tif'][1]
return HttpResponse(result.vsi_buffer, content_type)
# Get scale for the image value range.
scale = self.get_rgb_scale()
if scale is not None:
# Clip the image minimum.
red[red < scale[0]] = scale[0]
green[green < scale[0]] = scale[0]
blue[blue < scale[0]] = scale[0]
# Clip the image maximum.
red[red > scale[1]] = scale[1]
green[green > scale[1]] = scale[1]
blue[blue > scale[1]] = scale[1]
# Scale the image.
red = 255 * (red - scale[0]) / scale[1]
green = 255 * (green - scale[0]) / scale[1]
blue = 255 * (blue - scale[0]) / scale[1]
if self.get_alpha():
mode = 'RGBA'
reshape = 4
# Create the alpha channel.
alpha = 255 * (red > 0) * (blue > 0) * (green > 0)
img_array = numpy.array((red.ravel(), green.ravel(), blue.ravel(), alpha.ravel()))
else:
mode = 'RGB'
reshape = 3
img_array = numpy.array((red.ravel(), green.ravel(), blue.ravel()))
# Reshape array into tile size.
img_array = img_array.T.reshape(WEB_MERCATOR_TILESIZE, WEB_MERCATOR_TILESIZE, reshape).astype('uint8')
# Create image from array
img = Image.fromarray(img_array, mode=mode)
stats = {}
# Return rendered image
return self.write_img_to_response(img, stats)
class LegendView(RasterView):
def get(self, request, legend_id=None):
"""
Returns the legend for this layer as a json string. The legend is a list of
legend entries with the attributes "name", "expression" and "color".
"""
if legend_id:
# Get legend from id
legend = get_object_or_404(Legend, id=legend_id)
else:
# Try to get legend from layer
lyr = self.get_layer()
if not lyr.legend:
raise Http404
legend = lyr.legend
return HttpResponse(legend.json, content_type='application/json')
class ExportView(AlgebraView):
def construct_raster(self, z, xmin, xmax, ymin, ymax):
"""
Create an empty tif raster file on disk using the input tile range. The
new raster aligns with the xyz tile scheme and can be filled
sequentially with raster algebra results.
"""
# Compute bounds and scale to construct raster.
bounds = []
for x in range(xmin, xmax + 1):
for y in range(ymin, ymax + 1):
bounds.append(tile_bounds(x, y, z))
bounds = [
min([bnd[0] for bnd in bounds]),
min([bnd[1] for bnd in bounds]),
max([bnd[2] for bnd in bounds]),
max([bnd[3] for bnd in bounds]),
]
scale = tile_scale(z)
# Create tempfile.
raster_workdir = getattr(settings, 'RASTER_WORKDIR', None)
self.exportfile = NamedTemporaryFile(dir=raster_workdir, suffix='.tif')
# Instantiate raster using the tempfile path.
return GDALRaster({
'srid': WEB_MERCATOR_SRID,
'width': (xmax - xmin + 1) * WEB_MERCATOR_TILESIZE,
'height': (ymax - ymin + 1) * WEB_MERCATOR_TILESIZE,
'scale': (scale, -scale),
'origin': (bounds[0], bounds[3]),
'driver': 'tif',
'bands': [{'data': [0], 'nodata_value': 0}],
'name': self.exportfile.name,
'datatype': ALGEBRA_PIXEL_TYPE_GDAL,
})
def get_tile_range(self):
"""
Compute a xyz tile range from the query parameters. If no bbox
parameter is found, the range defaults to the maximum extent of
all input raster layers.
"""
# Get raster layers
layers = RasterLayer.objects.filter(id__in=self.get_ids().values())
# Establish zoom level
if self.request.GET.get('zoom', None):
zlevel = int(self.request.GET.get('zoom'))
else:
# Get highest zoom level of all input layers
zlevel = self.max_zoom
# Use bounding box to compute tile range
if self.request.GET.get('bbox', None):
bbox = Polygon.from_bbox(self.request.GET.get('bbox').split(','))
bbox.srid = 4326
bbox.transform(WEB_MERCATOR_SRID)
tile_range = tile_index_range(bbox.extent, zlevel)
else:
# Get list of tile ranges
layer_ranges = []
for layer in layers:
layer_ranges.append(tile_index_range(layer.extent(), zlevel))
# Estabish overlap of tile index ranges
tile_range = [
min([rng[0] for rng in layer_ranges]),
min([rng[1] for rng in layer_ranges]),
max([rng[2] for rng in layer_ranges]),
max([rng[3] for rng in layer_ranges]),
]
return [zlevel, ] + tile_range
def write_colormap(self, zfile):
# Try to get colormap
colormap = self.get_colormap()
# Set a simple header for this colormap
colorstr = '# Raster Algebra Colormap\n'
# Check if this is a continuous legend.
colorstr += 'INTERPOLATION: ' + ('CONTINUOUS' if colormap.pop('continuous', None) else 'DISCRETE') + '\n'
# Add expressions and colors of the colormap
for key, val in colormap.items():
colorstr += str(key) + ',' + ','.join((str(x) for x in val)) + ',' + str(key) + '\n'
# Write colormap file
zfile.writestr('COLORMAP.txt', colorstr)
def write_readme(self, zfile):
# Get tile index range
zoom, xmin, ymin, xmax, ymax = self.get_tile_range()
# Construct layer names string
layerstr = ''
for name, layerid in self.get_ids().items():
layer = RasterLayer.objects.get(id=layerid)
layerstr += '{layerid} "{name}" (Formula label: {label})\n'.format(
name=layer.name,
label=name,
layerid=layerid
)
# Get description, append newline if provided
description = self.request.GET.get('description', '')
if description:
description += '\n'
# Initiate metadata object
readmedata = {
'datetime': datetime.now().strftime('%Y-%m-%d at %H:%M'),
'url': self.request.build_absolute_uri(),
'bbox': self.request.GET.get('bbox', 'Minimum bounding-box covering all layers.'),
'formula': self.request.GET.get('formula'),
'zoom': str(zoom),
'xindexrange': '{} - {}'.format(xmin, xmax),
'yindexrange': '{} - {}'.format(ymin, ymax),
'layers': layerstr,
'description': description,
}
# Write readme file
readme = README_TEMPLATE.format(**readmedata)
zfile.writestr('README.txt', readme)
def get(self, request):
# Initiate algebra parser
parser = RasterAlgebraParser()
# Get formula from request
formula = request.GET.get('formula')
# Get id list from request
ids = self.get_ids()
# Compute tile index range
zoom, xmin, ymin, xmax, ymax = self.get_tile_range()
# Check maximum size of target raster in pixels
max_pixels = getattr(settings, 'RASTER_EXPORT_MAX_PIXELS', EXPORT_MAX_PIXELS)
if WEB_MERCATOR_TILESIZE * (xmax - xmin) * WEB_MERCATOR_TILESIZE * (ymax - ymin) > max_pixels:
raise RasterAlgebraException('Export raster too large.')
# Construct an empty raster with the output dimensions
result_raster = self.construct_raster(zoom, xmin, xmax, ymin, ymax)
target = result_raster.bands[0]
# Get raster data as 1D arrays and store in dict that can be used
# for formula evaluation.
for xindex, x in enumerate(range(xmin, xmax + 1)):
for yindex, y in enumerate(range(ymin, ymax + 1)):
data = {}
for name, layerid in ids.items():
tile = get_raster_tile(layerid, zoom, x, y)
if tile:
data[name] = tile
# Ignore this tile if data is not found for all layers
if len(data) != len(ids):
continue
# Evaluate raster algebra expression, return 400 if not successful
try:
# Evaluate raster algebra expression
tile_result = parser.evaluate_raster_algebra(data, formula)
except:
raise RasterAlgebraException('Failed to evaluate raster algebra.')
# Update nodata value on target
target.nodata_value = tile_result.bands[0].nodata_value
# Update results raster with algebra
target.data(
data=tile_result.bands[0].data(),
size=(WEB_MERCATOR_TILESIZE, WEB_MERCATOR_TILESIZE),
offset=(xindex * WEB_MERCATOR_TILESIZE, yindex * WEB_MERCATOR_TILESIZE),
)
# Create filename base with datetime stamp
filename_base = 'algebra_export'
# Add name slug to filename if provided
if request.GET.get('filename', ''):
# Sluggify name
slug = slugify(request.GET.get('filename'))
# Remove all unwanted characters
slug = "".join([c for c in slug if re.match(r'\w|\-', c)])
# Limit length of custom name slug
slug = slug[:MAX_EXPORT_NAME_LENGTH]
# Add name slug to filename base
filename_base += '_' + slug
filename_base += '_{0}'.format(datetime.now().strftime('%Y_%m_%d_%H_%M'))
# Compress resulting raster file into a zip archive
raster_workdir = getattr(settings, 'RASTER_WORKDIR', None)
dest = NamedTemporaryFile(dir=raster_workdir, suffix='.zip')
dest_zip = zipfile.ZipFile(dest.name, 'w', allowZip64=True)
dest_zip.write(
filename=self.exportfile.name,
arcname=filename_base + '.tif',
compress_type=zipfile.ZIP_DEFLATED,
)
# Write README.txt and COLORMAP.txt files to zip file
self.write_readme(dest_zip)
self.write_colormap(dest_zip)
# Close zip file before returning
dest_zip.close()
# Create file based response containing zip file and return for download
response = FileResponse(
open(dest.name, 'rb'),
content_type='application/zip'
)
response['Content-Disposition'] = 'attachment; filename="{0}"'.format(filename_base + '.zip')
return response