kopia lustrzana https://github.com/OpenDroneMap/ODM
393 wiersze
16 KiB
Python
Executable File
393 wiersze
16 KiB
Python
Executable File
#!/usr/bin/env python3
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# Author: Piero Toffanin
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# License: AGPLv3
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import os
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import sys
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sys.path.insert(0, os.path.join("..", "..", os.path.dirname(__file__)))
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from math import sqrt
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import rasterio
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import numpy as np
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import numpy.ma as ma
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import multiprocessing
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import argparse
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import functools
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from skimage.draw import line
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from opensfm import dataset
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default_dem_path = "odm_dem/dsm.tif"
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default_outdir = "orthorectified"
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default_image_list = "img_list.txt"
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parser = argparse.ArgumentParser(description='Orthorectification Tool')
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parser.add_argument('dataset',
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type=str,
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help='Path to ODM dataset')
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parser.add_argument('--dem',
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type=str,
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default=default_dem_path,
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help='Absolute path to DEM to use to orthorectify images. Default: %(default)s')
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parser.add_argument('--no-alpha',
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type=bool,
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help="Don't output an alpha channel")
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parser.add_argument('--interpolation',
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type=str,
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choices=('nearest', 'bilinear'),
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default='bilinear',
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help="Type of interpolation to use to sample pixel values.Default: %(default)s")
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parser.add_argument('--outdir',
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type=str,
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default=default_outdir,
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help="Output directory where to store results. Default: %(default)s")
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parser.add_argument('--image-list',
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type=str,
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default=default_image_list,
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help="Path to file that contains the list of image filenames to orthorectify. By default all images in a dataset are processed. Default: %(default)s")
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parser.add_argument('--images',
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type=str,
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default="",
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help="Comma-separated list of filenames to rectify. Use as an alternative to --image-list. Default: process all images.")
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parser.add_argument('--threads',
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type=int,
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default=multiprocessing.cpu_count(),
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help="Number of CPU processes to use. Default: %(default)s")
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parser.add_argument('--skip-visibility-test',
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type=bool,
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help="Skip visibility testing (faster but leaves artifacts due to relief displacement)")
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args = parser.parse_args()
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dataset_path = args.dataset
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dem_path = os.path.join(dataset_path, default_dem_path) if args.dem == default_dem_path else args.dem
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interpolation = args.interpolation
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with_alpha = not args.no_alpha
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image_list = os.path.join(dataset_path, default_image_list) if args.image_list == default_image_list else args.image_list
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cwd_path = os.path.join(dataset_path, default_outdir) if args.outdir == default_outdir else args.outdir
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if not os.path.exists(cwd_path):
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os.makedirs(cwd_path)
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target_images = [] # all
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if args.images:
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target_images = list(map(str.strip, args.images.split(",")))
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print("Processing %s images" % len(target_images))
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elif args.image_list:
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with open(image_list) as f:
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target_images = list(filter(lambda filename: filename != '', map(str.strip, f.read().split("\n"))))
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print("Processing %s images" % len(target_images))
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if not os.path.exists(dem_path):
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print("Whoops! %s does not exist. Provide a path to a valid DEM" % dem_path)
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exit(1)
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def bilinear_interpolate(im, x, y):
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x = np.asarray(x)
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y = np.asarray(y)
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x0 = np.floor(x).astype(int)
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x1 = x0 + 1
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y0 = np.floor(y).astype(int)
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y1 = y0 + 1
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x0 = np.clip(x0, 0, im.shape[1]-1)
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x1 = np.clip(x1, 0, im.shape[1]-1)
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y0 = np.clip(y0, 0, im.shape[0]-1)
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y1 = np.clip(y1, 0, im.shape[0]-1)
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Ia = im[ y0, x0 ]
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Ib = im[ y1, x0 ]
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Ic = im[ y0, x1 ]
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Id = im[ y1, x1 ]
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wa = (x1-x) * (y1-y)
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wb = (x1-x) * (y-y0)
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wc = (x-x0) * (y1-y)
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wd = (x-x0) * (y-y0)
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return wa*Ia + wb*Ib + wc*Ic + wd*Id
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# Read DEM
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print("Reading DEM: %s" % dem_path)
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with rasterio.open(dem_path) as dem_raster:
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dem = dem_raster.read()[0]
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dem_has_nodata = dem_raster.profile.get('nodata') is not None
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if dem_has_nodata:
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m = ma.array(dem, mask=dem==dem_raster.nodata)
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dem_min_value = m.min()
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dem_max_value = m.max()
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else:
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dem_min_value = dem.min()
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dem_max_value = dem.max()
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print("DEM Minimum: %s" % dem_min_value)
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print("DEM Maximum: %s" % dem_max_value)
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h, w = dem.shape
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crs = dem_raster.profile.get('crs')
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dem_offset_x, dem_offset_y = (0, 0)
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if crs:
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print("DEM has a CRS: %s" % str(crs))
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# Read coords.txt
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coords_file = os.path.join(dataset_path, "odm_georeferencing", "coords.txt")
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if not os.path.exists(coords_file):
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print("Whoops! Cannot find %s (we need that!)" % coords_file)
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exit(1)
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with open(coords_file) as f:
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l = f.readline() # discard
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# second line is a northing/easting offset
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l = f.readline().rstrip()
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dem_offset_x, dem_offset_y = map(float, l.split(" "))
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print("DEM offset: (%s, %s)" % (dem_offset_x, dem_offset_y))
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print("DEM dimensions: %sx%s pixels" % (w, h))
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# Read reconstruction
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udata = dataset.UndistortedDataSet(dataset.DataSet(os.path.join(dataset_path, "opensfm")), undistorted_data_path=os.path.join(dataset_path, "opensfm", "undistorted"))
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reconstructions = udata.load_undistorted_reconstruction()
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if len(reconstructions) == 0:
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raise Exception("No reconstructions available")
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max_workers = args.threads
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print("Using %s threads" % max_workers)
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reconstruction = reconstructions[0]
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for shot in reconstruction.shots.values():
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if len(target_images) == 0 or shot.id in target_images:
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print("Processing %s..." % shot.id)
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shot_image = udata.load_undistorted_image(shot.id)
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r = shot.pose.get_rotation_matrix()
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Xs, Ys, Zs = shot.pose.get_origin()
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cam_grid_y, cam_grid_x = dem_raster.index(Xs + dem_offset_x, Ys + dem_offset_y)
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a1 = r[0][0]
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b1 = r[0][1]
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c1 = r[0][2]
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a2 = r[1][0]
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b2 = r[1][1]
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c2 = r[1][2]
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a3 = r[2][0]
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b3 = r[2][1]
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c3 = r[2][2]
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if not args.skip_visibility_test:
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distance_map = np.full((h, w), np.nan)
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for j in range(0, h):
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for i in range(0, w):
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distance_map[j][i] = sqrt((cam_grid_x - i) ** 2 + (cam_grid_y - j) ** 2)
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distance_map[distance_map==0] = 1e-7
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print("Camera pose: (%f, %f, %f)" % (Xs, Ys, Zs))
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img_h, img_w, num_bands = shot_image.shape
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half_img_w = (img_w - 1) / 2.0
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half_img_h = (img_h - 1) / 2.0
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print("Image dimensions: %sx%s pixels" % (img_w, img_h))
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f = shot.camera.focal * max(img_h, img_w)
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has_nodata = dem_raster.profile.get('nodata') is not None
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def process_pixels(step):
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imgout = np.full((num_bands, dem_bbox_h, dem_bbox_w), np.nan)
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minx = dem_bbox_w
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miny = dem_bbox_h
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maxx = 0
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maxy = 0
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for j in range(dem_bbox_miny, dem_bbox_maxy + 1):
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if j % max_workers == step:
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im_j = j - dem_bbox_miny
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for i in range(dem_bbox_minx, dem_bbox_maxx + 1):
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im_i = i - dem_bbox_minx
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# World coordinates
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Za = dem[j][i]
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# Skip nodata
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if has_nodata and Za == dem_raster.nodata:
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continue
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Xa, Ya = dem_raster.xy(j, i)
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# Remove offset (our cameras don't have the geographic offset)
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Xa -= dem_offset_x
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Ya -= dem_offset_y
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# Colinearity function http://web.pdx.edu/~jduh/courses/geog493f14/Week03.pdf
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dx = (Xa - Xs)
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dy = (Ya - Ys)
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dz = (Za - Zs)
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den = a3 * dx + b3 * dy + c3 * dz
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x = half_img_w - (f * (a1 * dx + b1 * dy + c1 * dz) / den)
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y = half_img_h - (f * (a2 * dx + b2 * dy + c2 * dz) / den)
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if x >= 0 and y >= 0 and x <= img_w - 1 and y <= img_h - 1:
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# Visibility test
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if not args.skip_visibility_test:
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check_dem_points = np.column_stack(line(i, j, cam_grid_x, cam_grid_y))
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check_dem_points = check_dem_points[np.all(np.logical_and(np.array([0, 0]) <= check_dem_points, check_dem_points < [w, h]), axis=1)]
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visible = True
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for p in check_dem_points:
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ray_z = Zs + (distance_map[p[1]][p[0]] / distance_map[j][i]) * dz
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if ray_z > dem_max_value:
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break
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if dem[p[1]][p[0]] > ray_z:
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visible = False
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break
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if not visible:
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continue
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if interpolation == 'bilinear':
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xi = img_w - 1 - x
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yi = img_h - 1 - y
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values = bilinear_interpolate(shot_image, xi, yi)
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else:
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# nearest
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xi = img_w - 1 - int(round(x))
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yi = img_h - 1 - int(round(y))
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values = shot_image[yi][xi]
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# We don't consider all zero values (pure black)
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# to be valid sample values. This will sometimes miss
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# valid sample values.
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if not np.all(values == 0):
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minx = min(minx, im_i)
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miny = min(miny, im_j)
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maxx = max(maxx, im_i)
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maxy = max(maxy, im_j)
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for b in range(num_bands):
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imgout[b][im_j][im_i] = values[b]
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# for b in range(num_bands):
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# minx = min(minx, im_i)
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# miny = min(miny, im_j)
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# maxx = max(maxx, im_i)
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# maxy = max(maxy, im_j)
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# imgout[b][im_j][im_i] = 255
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return (imgout, (minx, miny, maxx, maxy))
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# Compute bounding box of image coverage
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# assuming a flat plane at Z = min Z
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# (Otherwise we have to scan the entire DEM)
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# The Xa,Ya equations are just derived from the colinearity equations
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# solving for Xa and Ya instead of x,y
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def dem_coordinates(cpx, cpy):
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"""
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:param cpx principal point X (image coordinates)
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:param cpy principal point Y (image coordinates)
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"""
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Za = dem_min_value
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m = (a3*b1*cpy - a1*b3*cpy - (a3*b2 - a2*b3)*cpx - (a2*b1 - a1*b2)*f)
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Xa = dem_offset_x + (m*Xs + (b3*c1*cpy - b1*c3*cpy - (b3*c2 - b2*c3)*cpx - (b2*c1 - b1*c2)*f)*Za - (b3*c1*cpy - b1*c3*cpy - (b3*c2 - b2*c3)*cpx - (b2*c1 - b1*c2)*f)*Zs)/m
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Ya = dem_offset_y + (m*Ys - (a3*c1*cpy - a1*c3*cpy - (a3*c2 - a2*c3)*cpx - (a2*c1 - a1*c2)*f)*Za + (a3*c1*cpy - a1*c3*cpy - (a3*c2 - a2*c3)*cpx - (a2*c1 - a1*c2)*f)*Zs)/m
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y, x = dem_raster.index(Xa, Ya)
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return (x, y)
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dem_ul = dem_coordinates(-(img_w - 1) / 2.0, -(img_h - 1) / 2.0)
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dem_ur = dem_coordinates((img_w - 1) / 2.0, -(img_h - 1) / 2.0)
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dem_lr = dem_coordinates((img_w - 1) / 2.0, (img_h - 1) / 2.0)
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dem_ll = dem_coordinates(-(img_w - 1) / 2.0, (img_h - 1) / 2.0)
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dem_bbox = [dem_ul, dem_ur, dem_lr, dem_ll]
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dem_bbox_x = np.array(list(map(lambda xy: xy[0], dem_bbox)))
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dem_bbox_y = np.array(list(map(lambda xy: xy[1], dem_bbox)))
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dem_bbox_minx = min(w - 1, max(0, dem_bbox_x.min()))
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dem_bbox_miny = min(h - 1, max(0, dem_bbox_y.min()))
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dem_bbox_maxx = min(w - 1, max(0, dem_bbox_x.max()))
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dem_bbox_maxy = min(h - 1, max(0, dem_bbox_y.max()))
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dem_bbox_w = 1 + dem_bbox_maxx - dem_bbox_minx
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dem_bbox_h = 1 + dem_bbox_maxy - dem_bbox_miny
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print("Iterating over DEM box: [(%s, %s), (%s, %s)] (%sx%s pixels)" % (dem_bbox_minx, dem_bbox_miny, dem_bbox_maxx, dem_bbox_maxy, dem_bbox_w, dem_bbox_h))
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if max_workers > 1:
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with multiprocessing.Pool(max_workers) as p:
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results = p.map(process_pixels, range(max_workers))
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else:
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results = [process_pixels(0)]
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results = list(filter(lambda r: r[1][0] <= r[1][2] and r[1][1] <= r[1][3], results))
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# Merge image
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imgout, _ = results[0]
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for j in range(dem_bbox_miny, dem_bbox_maxy + 1):
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im_j = j - dem_bbox_miny
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resimg, _ = results[j % max_workers]
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for b in range(num_bands):
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imgout[b][im_j] = resimg[b][im_j]
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# Merge bounds
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minx = dem_bbox_w
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miny = dem_bbox_h
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maxx = 0
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maxy = 0
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for _, bounds in results:
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minx = min(bounds[0], minx)
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miny = min(bounds[1], miny)
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maxx = max(bounds[2], maxx)
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maxy = max(bounds[3], maxy)
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print("Output bounds: (%s, %s), (%s, %s) pixels" % (minx, miny, maxx, maxy))
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if minx <= maxx and miny <= maxy:
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imgout = imgout[:,miny:maxy+1,minx:maxx+1]
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if with_alpha:
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alpha = np.zeros((imgout.shape[1], imgout.shape[2]), dtype=np.uint8)
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# Set all not-NaN indices to 255
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alpha[~np.isnan(imgout[0])] = 255
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# Cast
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imgout = imgout.astype(shot_image.dtype)
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dem_transform = dem_raster.profile['transform']
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offset_x, offset_y = dem_raster.xy(dem_bbox_miny + miny, dem_bbox_minx + minx, offset='ul')
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profile = {
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'driver': 'GTiff',
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'width': imgout.shape[2],
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'height': imgout.shape[1],
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'count': num_bands + 1 if with_alpha else num_bands,
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'dtype': imgout.dtype.name,
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'transform': rasterio.transform.Affine(dem_transform[0], dem_transform[1], offset_x,
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dem_transform[3], dem_transform[4], offset_y),
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'nodata': None,
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'crs': crs
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}
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outfile = os.path.join(cwd_path, shot.id)
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if not outfile.endswith(".tif"):
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outfile = outfile + ".tif"
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with rasterio.open(outfile, 'w', **profile) as wout:
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for b in range(num_bands):
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wout.write(imgout[b], b + 1)
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if with_alpha:
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wout.write(alpha, num_bands + 1)
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print("Wrote %s" % outfile)
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else:
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print("Cannot orthorectify image (is the image inside the DEM bounds?)")
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