Hello
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commit
43951dcdf7
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.gitignore
vendored
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.gitignore
vendored
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/ve
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7
pyproject.toml
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pyproject.toml
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[tool.ruff]
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line-length = 88
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[tool.pylsp]
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line-length = 88
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1
requirements.txt
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requirements.txt
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numpy == 2.*
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167
sim.py
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sim.py
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# This program assumes a tick interval of 1 minute. That is, the events are
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# made to evolve on a one dimensional time grid of 1 minute resolution.
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import os
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import multiprocessing as mp
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import typing as T
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import numpy as np
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DEFAULT_SEED = 1312
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DEFAULT_PARALLELISM = mp.cpu_count()
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DEFAULT_RUNS = 1000
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class Simulation(object):
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def __init__(
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self,
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queue: mp.Queue,
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runs: int,
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generator: np.random.Generator,
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snail_len: float,
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wheel_len: float,
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wheel_dist: float,
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road_len: float,
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snail_speed: float,
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) -> None:
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self.queue = queue
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self.runs = runs
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self.generator = generator
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self.snail_len = snail_len / road_len
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self.wheel_len = wheel_len / road_len
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self.wheel_dist = wheel_dist / road_len
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self.starting_wheel_pos_mul = (road_len - 2 * wheel_len - wheel_dist) / road_len
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self.snail_speed = snail_speed / road_len
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def is_car_passing(self) -> bool:
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"""
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The probability a car is passing every minute is assumed to be
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uniformly distributed in the hour. Having 10 cars/hour, and a tick
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interval of 1 minute we have:
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P_car = 10/60 ~ 0.1666666
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"""
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return self.generator.random() <= 1 / 6
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def is_dead(self, x: float) -> bool:
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"""
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The probability of the car hitting the snail being at x is the
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probability of any of the pieces of the two wheels to be in the
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interval [x-snail_len, x].
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|-------------------------------------------------------| road_len
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|------- x |
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| @@@ |
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|---- x-snail_len |
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|---------- x_wheel_pos |
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| XXXXXXX--(wheel_dist)--XXXXXXX |
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| ------- wheel_len ------- |
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"""
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x_wheel_pos = self.generator.random() * self.starting_wheel_pos_mul
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first_wheel_hit = self.intersect(x, x_wheel_pos)
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second_wheel_hit = self.intersect(x, x_wheel_pos + self.wheel_dist)
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return first_wheel_hit or second_wheel_hit
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def intersect(self, x_snail: float, x_wheel: float) -> bool:
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return (x_wheel > x_snail - self.snail_len) and (x_wheel < x_snail)
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def _run(self) -> bool:
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"""
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This is the entrypoint of the single run of a simulation. The result is
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a boolean indicating whether the snail did survive the road crossing.
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The simulation ends if the snail manages to run all the
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road_len+snail_len distance.
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"""
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win_dist = 1 + self.snail_len
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x = 0
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while x < win_dist:
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if self.is_car_passing() and self.is_dead(x):
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return False
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x += self.snail_speed
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return True
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def run(self) -> None:
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for i in range(self.runs):
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self.queue.put(self._run())
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self.queue.close()
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def clear():
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os.system("cls" if os.name == "nt" else "clear")
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def print_result(runs: int, survived: int) -> None:
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print(f"total runs: {runs}")
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print(f"result: {survived/runs}")
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def gather(q: mp.Queue()) -> None:
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runs = 0
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survived = 0
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while True:
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data = q.get()
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if data is None:
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break
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runs += 1
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if data:
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survived += 1
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print("============= FINAL RESULT ============")
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print_result(runs, survived)
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if __name__ == "__main__":
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seed = int(os.getenv("SEED") or DEFAULT_SEED)
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procs = int(os.getenv("PARALLELISM") or DEFAULT_PARALLELISM)
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runs = int(os.getenv("RUNS") or DEFAULT_RUNS)
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q = mp.Queue()
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seq = np.random.default_rng(int(seed))
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rng_stream = seq.spawn(int(procs))
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snail_len = 5 # 5 cm
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wheel_len = 20 # 20 cm
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wheel_dist = 150 # 1.5 m
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road_len = 500 # 5 m
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snail_speed = 1 # 1 cm/min
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sims = [
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Simulation(
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q,
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runs,
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rng,
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snail_len,
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wheel_len,
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wheel_dist,
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road_len,
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snail_speed,
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)
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for rng in rng_stream
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]
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processes: T.List[mp.Process] = [mp.Process(target=s.run, args=()) for s in sims]
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collector = mp.Process(target=gather, args=(q,))
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collector.start()
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for p in processes:
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p.start()
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for p in processes:
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p.join()
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print(f"process finished: {p}")
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q.put(None)
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collector.join()
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