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import argparse
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import concurrent.futures
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import csv
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import itertools
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from concurrent.futures import as_completed
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from functools import lru_cache
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import geonamescache
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import numpy as np
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from geopy.distance import geodesic
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from tqdm import tqdm
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MAX_DISTANCE = 20_037.5
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CACHE = geonamescache.GeonamesCache()
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# Add argparse
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def parse_args():
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parser = argparse.ArgumentParser()
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parser.add_argument(
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"-c", "--country", help="Specify the country code", type=str, default="US"
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)
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parser.add_argument(
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"-w", "--workers", help="Specify the number of workers", type=int, default=1
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)
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parser.add_argument(
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"-s",
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"--chunk-size",
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help="Specify chunk size for batching calculations",
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type=int,
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default=1000,
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)
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parser.add_argument(
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"-o",
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"--output-file",
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help="Specify the name of the output file (file.csv)",
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type=str,
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default="distances.csv",
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)
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parser.add_argument(
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"--shuffle",
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action="store_true",
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help="Option to shuffle combinations list before iterating over it",
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)
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args = parser.parse_args()
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return args
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@lru_cache(maxsize=None)
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def get_coordinates(city_name, country_code="US"):
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"""
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Get the coordinates of a city.
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Parameters
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----------
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city_name : str
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The name of the city.
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country_code : str, optional
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The country code of the city, by default 'US'.
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Returns
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-------
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tuple
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A tuple containing the latitude and longitude of the city,
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or None if the city is not found.
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"""
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city = find_city(city_name, country_code)
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if city is None:
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return None
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return city.get("latitude"), city.get("longitude")
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@lru_cache(maxsize=None)
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def find_city(city_name, country_code="US"):
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"""
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Finds the matching city.
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Parameters
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----------
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city_name : str
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The name of the city.
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country_code : str, optional
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The country code of the city, by default 'US'.
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Returns
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-------
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city
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A dict containing the raw data about the city.
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"""
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search_results = CACHE.get_cities_by_name(city_name)
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# search_results = [
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# list(c.values())[0] for c in search_results
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# ]
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search_results = [inner_dict for d in search_results for inner_dict in d.values()]
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if not search_results: # if not found by name, search alternatenames
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search_results = CACHE.search_cities(
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city_name, attribute="alternatenames", case_sensitive=True
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)
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# filter search results to match requested country
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# and avoid wasted computation if coordinates missing
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search_results = [
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d
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for d in search_results
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if (d.get("countrycode") == country_code) & (d.get("longitude") is not None)
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]
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if not search_results:
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return None
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populations = [city.get("population") for city in search_results]
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city = search_results[np.argmax(populations)]
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return city
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def get_distance(city1, city2, country1="US", country2="US"):
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"""
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Get the distance between two cities in kilometers.
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Parameters
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----------
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city1 : str
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The name of the first city.
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city2 : str
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The name of the second city.
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country1 : str, optional
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The country code of the first city, by default 'US'.
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country2 : str, optional
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The country code of the second city, by default 'US'.
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Returns
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-------
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float
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The distance between the two cities in kilometers,
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or None if one or both city names were not found.
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"""
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city1_coords = get_coordinates(city1, country1)
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city2_coords = get_coordinates(city2, country2)
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if (city1_coords is None) or (city2_coords is None):
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return None
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return geodesic(city1_coords, city2_coords).km
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def calculate_distance(pair):
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city1, city2 = pair
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distance = get_distance(city1, city2)
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return city1, city2, distance
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def main(args):
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output_file = args.output_file
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shuffle = args.shuffle
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country_code = args.country
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chunk_size = args.chunk_size
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max_workers = args.workers
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cities = CACHE.get_cities()
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us_cities = {
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k: c
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for k, c in cities.items()
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if (c.get("countrycode") == country_code) & (c.get("longitude") is not None)
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}
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# & (c.get("population", 0) > 5e4)
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cities = list(us_cities.values())
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unique_names = set([c.get("name") for c in cities])
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unique_names = sorted(list(unique_names))
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# unique_cities = [c for c in cities if c.get("name") in unique_names]
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print(f"Num cities: {len(cities)}, unique names: {len(unique_names)}")
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city_combinations = list(itertools.combinations(unique_names, 2))
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if shuffle:
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np.random.shuffle(city_combinations)
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# chunk size, city_combinations, max_workers, output_file
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num_chunks = len(city_combinations) // chunk_size + 1
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with open(output_file, "w", newline="") as csvfile:
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fieldnames = ["city_from", "city_to", "distance"]
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writer = csv.DictWriter(csvfile, fieldnames=fieldnames)
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writer.writeheader()
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try:
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executor = concurrent.futures.ProcessPoolExecutor(max_workers=max_workers)
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for i in tqdm(
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range(num_chunks),
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total=num_chunks,
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desc="Processing chunks",
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ncols=100,
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bar_format="{l_bar}{bar}{r_bar}",
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):
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chunk = city_combinations[(i * chunk_size) : (i + 1) * chunk_size]
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futures = {
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executor.submit(calculate_distance, pair): pair for pair in chunk
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}
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for future in as_completed(futures):
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city_from, city_to, distance = future.result()
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if distance is not None:
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writer.writerow(
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{
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"city_from": city_from,
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"city_to": city_to,
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"distance": distance,
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}
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)
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csvfile.flush() # write to disk immediately
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except KeyboardInterrupt:
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print("Interrupted. Terminating processes...")
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executor.shutdown(wait=False)
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raise SystemExit("Execution terminated by user.")
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print(f"Wrote {output_file}")
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if __name__ == "__main__":
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# preliminary check
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assert find_city("New York City") is not None
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assert find_city("NYC") is not None
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assert round(get_distance("NYC", "Jamaica"), 2) == 17.11
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args = parse_args()
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main(args)
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# perform check
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print("Performing a quick validation...")
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import pandas as pd
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df = pd.read_csv(args.output_file)
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assert df["distance"].min() > 0
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assert df["distance"].max() < MAX_DISTANCE
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