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parallel.py
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parallel.py
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"""
* Divide and Conquour script to divide, process in parallel and merge again without having
* to worry about edge effects.
* This version is intended to be used with call gvi.py
"""
from gvi import f
from datetime import datetime
from multiprocessing import Pool
from fiona import open as fi_open
from argparse import ArgumentParser
from subprocess import call, DEVNULL
from rasterio import open as rio_open
from rasterio.transform import rowcol, xy
from rasterio.mask import mask as rio_mask
from rasterio.merge import merge as rio_merge
from shapely.geometry import Polygon, mapping
def coords2Array(a, coords):
"""
* convert between coords and array position
* returns row,col (y,x) as expected by rasterio
"""
x, y = coords
r, c = rowcol(a, x, y)
return int(r), int(c)
def array2Coords(a, index):
"""
* convert between array position and coords
* params are row,col (y,x) as expected by rasterio
* returns coords at the CENTRE of the cell
"""
row, col = index
x, y = xy(a, row, col)
return int(x), int(y)
def extractPolygon(src, poly):
"""
* extract a subset from a raster according to the specified bounds
* returns the dataset (numpy array) and metadata object
"""
# extract the bit of src that intersects poly
out_data, out_transform = rio_mask(src, poly, crop=True, all_touched=True)
# create the metadata for the dataset
out_meta = src.meta
out_meta.update({
"height": out_data.shape[1],
"width": out_data.shape[2],
"transform": out_transform
})
# return the mask and the metadata
return out_data[0], out_meta
def outputFiles(crs, masks):
"""
* Output illustrative GIS (Shapefile and GeoTiff) files of the extracted
* zones and the aoi polygons
"""
# create the file in write mode, with the required CRS (Proj4 string) and an empty schema
with fi_open('./tmp/aoi.shp', 'w',
driver = 'ESRI Shapefile',
crs = crs,
schema = {'geometry': 'Polygon', 'properties': {}}
) as o:
# loop through resulting masks
for m in range(len(masks)):
# write the splitter to shapefile
o.write({'geometry': mapping(masks[m]["aoi"]),'properties': {}})
# create a raster file
with rio_open(f'./tmp/{m}.tif', 'w',
driver = masks[m]["meta"]["driver"],
height = masks[m]["meta"]["height"],
width = masks[m]["meta"]["width"],
count = masks[m]["meta"]["count"],
dtype = masks[m]["meta"]["dtype"],
crs = masks[m]["meta"]["crs"],
transform = masks[m]["meta"]["transform"],
) as dst:
# write the data to the raster
dst.write(masks[m]["dtm"], 1)
# main script
if __name__ == '__main__':
# get settings from args
parser = ArgumentParser(description="Labib's Greenspace Visibility Tool")
parser.add_argument('--dtm', help='DTM layer for analysis', required=True)
parser.add_argument('--dsm', help='DSM layer for analysis', required=True)
parser.add_argument('--green', help='Binary GreenSpace layer for analysis', required=True)
parser.add_argument('--aoi', help='Boundary of Area of Interest', required=True)
parser.add_argument('--padding', help='Required padding for each mask in CRS units (e.g. radius of a viewshed)', required=True)
parser.add_argument('--sections', nargs=2, help='x and y divisions for masking (e.g. 16 divisions would be `4 4`)', required=True)
parser.add_argument('--out', help='Path for result file', required=True)
args = vars(parser.parse_args())
# get args
dtm_path = args['dtm']
dsm_path = args['dsm']
green_path = args['green']
boundary_path = args['aoi']
padding = int(args['padding'])
sections = [ int(x) for x in args['sections'] ]
out_path = args['out']
# log start time and log start
time = datetime.now()
print(f"a {sections[0]}x{sections[1]} grid, {sections[0]*sections[1]} processes, started at {time}.")
# initialise masks array for the results
masks = []
# get aoi bounds from shapefile
with fi_open(boundary_path) as boundary:
bounds = boundary.bounds
# read in raster data
with rio_open(dtm_path) as dtm_input:
with rio_open(dsm_path) as dsm_input:
with rio_open(green_path) as green_input:
# verify raster dimensions and resolution
if (dsm_input.width == dtm_input.width == green_input.width) == False or \
(dsm_input.height == dtm_input.height == green_input.height) == False or \
(dsm_input.res[0] == dtm_input.res[0] == green_input.res[0]) == False:
print("rasters do not match!")
print("width: \t\t", dsm_input.width == dtm_input.width == green_input.width)
print("height: \t", dsm_input.height == dtm_input.height == green_input.height)
print("resolution: \t", dsm_input.res[0] == dtm_input.res[0] == green_input.res[0])
exit()
# store metadata from dtm
meta = dtm_input.meta
# read data bands
dtm_data = dtm_input.read(1)
dsm_data = dsm_input.read(1)
green_data = green_input.read(1)
# adjust bounds to the raster by transforming to image space and back again
minx, miny = array2Coords(dtm_input.transform, coords2Array(dtm_input.transform, [bounds[0], bounds[1]]))
maxx, maxy = array2Coords(dtm_input.transform, coords2Array(dtm_input.transform, [bounds[2] + dtm_input.res[0], bounds[3] + dtm_input.res[0]]))
# get width and height of study area
w, h = (maxx - minx), (maxy - miny)
# get width and height of all aois (absorb offcut into first entry)
aoiWidth = [int(w / sections[0])] * sections[0]
aoiWidth[0] += w - sum(aoiWidth)
aoiHeight = [int(h / sections[1])] * sections[1]
aoiHeight[0] += h - sum(aoiHeight)
# pre-calculate origin location polygon extraction
xOrigin = bounds[0] - padding
yOrigin = bounds[1] - padding
# loop through mask matrix
for x in range(sections[0]):
for y in range(sections[1]):
# construct a Shapely polygon for use in processing
polygon = Polygon([
(bounds[0] + sum(aoiWidth[:x]) - padding, bounds[1] + sum(aoiHeight[:y]) - padding), # bl
(bounds[0] + sum(aoiWidth[:x]) - padding, bounds[1] + sum(aoiHeight[:y+1]) + padding), # tl
(bounds[0] + sum(aoiWidth[:x+2]) + padding, bounds[1] + sum(aoiHeight[:y+1]) + padding), # tr
(bounds[0] + sum(aoiWidth[:x+1]) + padding, bounds[1] + sum(aoiHeight[:y]) - padding) # br
])
# construct a shapely polygon for use in analysis and trimming the results
aoi = Polygon([
(bounds[0] + sum(aoiWidth[:x]), bounds[1] + sum(aoiHeight[:y])), # bl
(bounds[0] + sum(aoiWidth[:x]), bounds[1] + sum(aoiHeight[:y+1])), # tl
(bounds[0] + sum(aoiWidth[:x+1]), bounds[1] + sum(aoiHeight[:y+1])), # tr
(bounds[0] + sum(aoiWidth[:x+1]), bounds[1] + sum(aoiHeight[:y])) # br
])
# extract the polygon and append to masks list
dtm, meta = extractPolygon(dtm_input, [polygon])
dsm, _ = extractPolygon(dsm_input, [polygon])
green, _ = extractPolygon(green_input, [polygon])
# make result object and append to masks list
masks.append({
"dtm": dtm,
"dsm": dsm,
"green": green,
"meta": meta,
"aoi": aoi,
"options": {
"radius": padding, # viewshed radius
"o_height": 1.7, # observer height
"t_height": 0 # target height
}
})
# print(masks[0])
# exit()
# output files for debugging purposes
# outputFiles(dtm_input.crs, masks)
# exit()
# make as many processes as are required and launch them
with Pool(sections[0] * sections[1]) as p:
results = p.map(f, masks)
# open all result files in read mode
files = []
for filepath in results:
files.append(rio_open(filepath, 'r'))
# copy metadata to make a new one
out_meta = files[0].meta.copy()
# merge result files if necessary
if sections[0] > 1 and sections[1] > 1:
# file merge
merged, out_transform = rio_merge(files)
# update metadata
out_meta.update({
"height": merged.shape[1],
"width": merged.shape[2],
"transform": out_transform,
"dtype": 'float64'
})
else:
# otherwise just use it...
merged = files[0]
# create a raster file
with rio_open(out_path, 'w', **out_meta) as dst:
dst.write(merged[0], 1)
# use GDAL binary to calculate histogram and statistics
# call(["gdalinfo", "-stats", out_path], stdout=DEVNULL)
# close all of the files
for file in files:
file.close()
# print how long it took
print(datetime.now() - time)
print("done!")