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* Add doctests in all functions in basic_string.py * Revert back to original basic_string.py * Add doctest in basic_string.py * [pre-commit.ci] auto fixes from pre-commit.com hooks for more information, see https://pre-commit.ci * Update genetic_algorithm/basic_string.py --------- Co-authored-by: pre-commit-ci[bot] <66853113+pre-commit-ci[bot]@users.noreply.github.com> Co-authored-by: Christian Clauss <cclauss@me.com>
209 lines
7.8 KiB
Python
209 lines
7.8 KiB
Python
"""
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Simple multithreaded algorithm to show how the 4 phases of a genetic algorithm works
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(Evaluation, Selection, Crossover and Mutation)
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https://en.wikipedia.org/wiki/Genetic_algorithm
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Author: D4rkia
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"""
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from __future__ import annotations
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import random
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# Maximum size of the population. Bigger could be faster but is more memory expensive.
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N_POPULATION = 200
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# Number of elements selected in every generation of evolution. The selection takes
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# place from best to worst of that generation and must be smaller than N_POPULATION.
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N_SELECTED = 50
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# Probability that an element of a generation can mutate, changing one of its genes.
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# This will guarantee that all genes will be used during evolution.
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MUTATION_PROBABILITY = 0.4
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# Just a seed to improve randomness required by the algorithm.
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random.seed(random.randint(0, 1000))
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def evaluate(item: str, main_target: str) -> tuple[str, float]:
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"""
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Evaluate how similar the item is with the target by just
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counting each char in the right position
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>>> evaluate("Helxo Worlx", "Hello World")
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('Helxo Worlx', 9.0)
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"""
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score = len([g for position, g in enumerate(item) if g == main_target[position]])
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return (item, float(score))
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def crossover(parent_1: str, parent_2: str) -> tuple[str, str]:
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"""
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Slice and combine two strings at a random point.
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>>> random.seed(42)
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>>> crossover("123456", "abcdef")
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('12345f', 'abcde6')
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"""
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random_slice = random.randint(0, len(parent_1) - 1)
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child_1 = parent_1[:random_slice] + parent_2[random_slice:]
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child_2 = parent_2[:random_slice] + parent_1[random_slice:]
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return (child_1, child_2)
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def mutate(child: str, genes: list[str]) -> str:
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"""
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Mutate a random gene of a child with another one from the list.
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>>> random.seed(123)
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>>> mutate("123456", list("ABCDEF"))
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'12345A'
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"""
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child_list = list(child)
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if random.uniform(0, 1) < MUTATION_PROBABILITY:
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child_list[random.randint(0, len(child)) - 1] = random.choice(genes)
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return "".join(child_list)
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# Select, crossover and mutate a new population.
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def select(
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parent_1: tuple[str, float],
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population_score: list[tuple[str, float]],
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genes: list[str],
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) -> list[str]:
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"""
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Select the second parent and generate new population
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>>> random.seed(42)
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>>> parent_1 = ("123456", 8.0)
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>>> population_score = [("abcdef", 4.0), ("ghijkl", 5.0), ("mnopqr", 7.0)]
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>>> genes = list("ABCDEF")
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>>> child_n = int(min(parent_1[1] + 1, 10))
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>>> population = []
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>>> for _ in range(child_n):
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... parent_2 = population_score[random.randrange(len(population_score))][0]
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... child_1, child_2 = crossover(parent_1[0], parent_2)
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... population.extend((mutate(child_1, genes), mutate(child_2, genes)))
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>>> len(population) == (int(parent_1[1]) + 1) * 2
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True
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"""
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pop = []
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# Generate more children proportionally to the fitness score.
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child_n = int(parent_1[1] * 100) + 1
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child_n = 10 if child_n >= 10 else child_n
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for _ in range(child_n):
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parent_2 = population_score[random.randint(0, N_SELECTED)][0]
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child_1, child_2 = crossover(parent_1[0], parent_2)
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# Append new string to the population list.
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pop.append(mutate(child_1, genes))
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pop.append(mutate(child_2, genes))
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return pop
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def basic(target: str, genes: list[str], debug: bool = True) -> tuple[int, int, str]:
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"""
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Verify that the target contains no genes besides the ones inside genes variable.
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>>> from string import ascii_lowercase
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>>> basic("doctest", ascii_lowercase, debug=False)[2]
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'doctest'
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>>> genes = list(ascii_lowercase)
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>>> genes.remove("e")
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>>> basic("test", genes)
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Traceback (most recent call last):
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...
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ValueError: ['e'] is not in genes list, evolution cannot converge
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>>> genes.remove("s")
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>>> basic("test", genes)
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Traceback (most recent call last):
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...
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ValueError: ['e', 's'] is not in genes list, evolution cannot converge
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>>> genes.remove("t")
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>>> basic("test", genes)
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Traceback (most recent call last):
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...
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ValueError: ['e', 's', 't'] is not in genes list, evolution cannot converge
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"""
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# Verify if N_POPULATION is bigger than N_SELECTED
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if N_POPULATION < N_SELECTED:
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msg = f"{N_POPULATION} must be bigger than {N_SELECTED}"
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raise ValueError(msg)
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# Verify that the target contains no genes besides the ones inside genes variable.
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not_in_genes_list = sorted({c for c in target if c not in genes})
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if not_in_genes_list:
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msg = f"{not_in_genes_list} is not in genes list, evolution cannot converge"
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raise ValueError(msg)
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# Generate random starting population.
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population = []
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for _ in range(N_POPULATION):
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population.append("".join([random.choice(genes) for i in range(len(target))]))
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# Just some logs to know what the algorithms is doing.
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generation, total_population = 0, 0
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# This loop will end when we find a perfect match for our target.
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while True:
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generation += 1
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total_population += len(population)
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# Random population created. Now it's time to evaluate.
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# Adding a bit of concurrency can make everything faster,
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#
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# import concurrent.futures
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# population_score: list[tuple[str, float]] = []
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# with concurrent.futures.ThreadPoolExecutor(
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# max_workers=NUM_WORKERS) as executor:
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# futures = {executor.submit(evaluate, item) for item in population}
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# concurrent.futures.wait(futures)
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# population_score = [item.result() for item in futures]
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#
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# but with a simple algorithm like this, it will probably be slower.
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# We just need to call evaluate for every item inside the population.
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population_score = [evaluate(item, target) for item in population]
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# Check if there is a matching evolution.
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population_score = sorted(population_score, key=lambda x: x[1], reverse=True)
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if population_score[0][0] == target:
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return (generation, total_population, population_score[0][0])
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# Print the best result every 10 generation.
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# Just to know that the algorithm is working.
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if debug and generation % 10 == 0:
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print(
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f"\nGeneration: {generation}"
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f"\nTotal Population:{total_population}"
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f"\nBest score: {population_score[0][1]}"
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f"\nBest string: {population_score[0][0]}"
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)
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# Flush the old population, keeping some of the best evolutions.
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# Keeping this avoid regression of evolution.
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population_best = population[: int(N_POPULATION / 3)]
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population.clear()
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population.extend(population_best)
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# Normalize population score to be between 0 and 1.
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population_score = [
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(item, score / len(target)) for item, score in population_score
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]
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# This is selection
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for i in range(N_SELECTED):
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population.extend(select(population_score[int(i)], population_score, genes))
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# Check if the population has already reached the maximum value and if so,
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# break the cycle. If this check is disabled, the algorithm will take
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# forever to compute large strings, but will also calculate small strings in
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# a far fewer generations.
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if len(population) > N_POPULATION:
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break
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if __name__ == "__main__":
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target_str = (
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"This is a genetic algorithm to evaluate, combine, evolve, and mutate a string!"
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)
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genes_list = list(
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" ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklm"
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"nopqrstuvwxyz.,;!?+-*#@^'èéòà€ù=)(&%$£/\\"
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)
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generation, population, target = basic(target_str, genes_list)
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print(
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f"\nGeneration: {generation}\nTotal Population: {population}\nTarget: {target}"
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)
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