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parse.py
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parse.py
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import os
import urllib2
import math
import base64
import json
from operator import attrgetter
from sys import maxint as MAX_INT
from multiprocessing.pool import ThreadPool as Pool
def get_length(point1, point2):
return math.sqrt((point1.x - point2.x) ** 2 + (point1.y - point2.y) ** 2)
def get_angle(angle_point, end_point1, end_point2):
side_angle_point1 = get_length(angle_point, end_point1)
side_angle_point2 = get_length(angle_point, end_point2)
side_point1_point2 = get_length(end_point1, end_point2)
if side_angle_point1 == 0 or side_angle_point2 == 0:
return 0
value = (side_angle_point1 ** 2 + side_angle_point2 ** 2 - side_point1_point2 ** 2) /\
(2 * side_angle_point1 * side_angle_point2)
return math.acos(min(max(value, -1), 1))
def get_next_polygon_point(angle_point, first_end_point, points):
next_point = angle_point
next_angle = 0
for point in points:
current_angle = get_angle(angle_point, first_end_point, point)
if (current_angle > next_angle or
current_angle == next_angle and
get_length(angle_point, point) > get_length(angle_point, next_point)):
next_angle = current_angle
next_point = point
return next_point
def get_polar_polygon_from_points(points):
top_point = max(points, key=attrgetter('lng'))
polygon_points = [top_point]
while True:
angle_point = polygon_points[-1]
first_end_point = polygon_points[-2] if len(polygon_points) > 1 else angle_point.clone(delta_lat=1)
next_point = get_next_polygon_point(angle_point, first_end_point, points)
if top_point != next_point:
polygon_points.append(next_point)
else:
break
return polygon_points
def polar_to_int(lat, lng, zoom):
x = int(2 ** zoom * (180 + lng) / 360)
d = min(max(math.sin(lat * math.pi / 180), -0.9999), 0.9999)
y = int(2 ** zoom * (2 * math.pi - math.log((1 + d) / (1 - d))) / (4 * math.pi))
return Tile(x, y, zoom)
def polar_to_int_polygon(polar_polygon, zoom):
return [polar_to_int(point.lat, point.lng, zoom) for point in polar_polygon]
def get_int_polygon_rectangle(int_polygon):
x_top_left = MAX_INT
y_top_left = MAX_INT
x_bottom_right = 0
y_bottom_right = 0
zoom = int_polygon[0].zoom
for point in int_polygon:
x_top_left = min(x_top_left, point.x)
y_top_left = min(y_top_left, point.y)
x_bottom_right = max(x_bottom_right, point.x)
y_bottom_right = max(y_bottom_right, point.y)
return Tile(x_top_left, y_top_left, zoom), Tile(x_bottom_right, y_bottom_right, zoom)
def check_point_in_int_polygon(tile, int_polygon, imprecision=0.1):
for polygon_point in int_polygon:
if polygon_point == tile:
return True
angle_sum = 0
for index, tile1 in enumerate(int_polygon):
tile2 = int_polygon[index + 1] if index + 1 != len(int_polygon) else int_polygon[0]
angle_sum += get_angle(tile, tile1, tile2)
return angle_sum >= 2 * math.pi - imprecision
def create_dirs(save_file_path):
dir_name = os.path.dirname(save_file_path)
if not os.path.exists(dir_name):
os.makedirs(dir_name)
def download_tile(tile, url_template, save_file_path_template):
url = tile.render(url_template)
save_file_path = tile.render(save_file_path_template)
create_dirs(save_file_path)
with open(save_file_path, 'wb') as file:
file.write(urllib2.urlopen(url).read())
def check_and_download_tile(tile, url_template, save_file_path_template, int_polygon):
if not check_point_in_int_polygon(tile, int_polygon):
return
download_tile(tile, url_template, save_file_path_template)
def download_tiles_in_polar_polygon(polar_polygon, zooms, url_template, save_file_path_template, threads_count=10):
for zoom in zooms:
int_polygon = polar_to_int_polygon(polar_polygon, zoom)
point_top_left, point_bottom_right = get_int_polygon_rectangle(int_polygon)
threads_pull = Pool(threads_count)
for x in xrange(point_top_left.x, point_bottom_right.x + 1):
for y in xrange(point_top_left.y, point_bottom_right.y + 1):
threads_pull.apply_async(check_and_download_tile,
[Tile(x, y, zoom), url_template, save_file_path_template, int_polygon])
threads_pull.close()
threads_pull.join()
def get_images_path_list(root_path, from_root_path='', filter=''):
for path, dirs, files in os.walk(root_path):
for file in files:
file_path = os.path.relpath(os.path.join(path, file), from_root_path)
if file_path[-len(filter):] == filter:
yield file_path
def get_zoom_and_coord_from_path(path):
zoom = os.path.basename(os.path.dirname(path))
coord = os.path.basename(path).split('.')[0]
return '%s_%s' % (zoom, coord)
def image_to_base64(path):
with open(path, 'rb') as file:
return base64.b64encode(file.read())
def save_images_path_list(file_list, save_file):
metadata_file_map = dict([(get_zoom_and_coord_from_path(file), file) for file in file_list])
with open(save_file, 'wb') as file:
json.dump(metadata_file_map, file)
def save_images_base64_list(file_list, save_file):
metadata_file_map = dict([(get_zoom_and_coord_from_path(file), image_to_base64(file)) for file in file_list])
with open(save_file, 'wb') as file:
json.dump(metadata_file_map, file)
class Point():
def __init__(self, lat, lng):
self.lat = lat
self.lng = lng
def __eq__(self, other):
return self.lat == other.lat and self.lng == other.lng
def __ne__(self, other):
return not self.__eq__(other)
def __hash__(self):
return hash((self.lat, self.lng))
def __repr__(self):
return '{lat: %(lat)s, lng: %(lng)s}' % {'lat': self.lat, 'lng': self.lng}
def clone(self, delta_lat=0, delta_lng=0):
return Point(self.lat + delta_lat, self.lng + delta_lng)
@property
def x(self):
return self.lng
@property
def y(self):
return self.lat
class Tile():
def __init__(self, x, y, zoom):
self.x = x
self.y = y
self.zoom = zoom
def __eq__(self, other):
return self.x == other.x and self.y == other.y and self.zoom == other.zoom
def __ne__(self, other):
return not self.__eq__(other)
def __hash__(self):
return hash((self.x, self.y, self.zoom))
def __repr__(self):
return self.render('{x: %(x)s, y: %(y)s, zoom: %(zoom)s}')
def render(self, template):
return template % {'x': self.x, 'y': self.y, 'zoom': self.zoom}
if __name__ == '__main__':
from fixtures import all_points
url_template = 'http://mt0.googleapis.com/vt?src=apiv3&x=%(x)s&y=%(y)s&z=%(zoom)s'
project_path = 'site'
save_files_path = project_path + '/cache'
save_file_path_template = save_files_path + '/%(zoom)s/%(x)s_%(y)s.png'
zooms = xrange(15 + 1)
points = [Point(lat, lng) for lat, lng in all_points]
polar_polygon = get_polar_polygon_from_points(points)
download_tiles_in_polar_polygon(polar_polygon, zooms, url_template, save_file_path_template)
images_path_list = save_files_path + '/images.json'
file_list = list(get_images_path_list(save_files_path, project_path, '.png'))
save_images_path_list(file_list, images_path_list)
images_base64_list = save_files_path + '/imagesBase64.json'
file_list = list(get_images_path_list(save_files_path, '', '.png'))
save_images_base64_list(file_list, images_base64_list)