google-foobar-challenge/extra/bringing-a-gun-to-a-trainer-fight/solution.py

import math

def solution(dimentions, your_position, trainer_position, distance):
    nearest_target = {}
    for position, is_trainer in generate_positions(dimentions, your_position, trainer_position, distance):
        direction = calc_direction(your_position, position)
        if direction in nearest_target:
            prev_position, prev_is_trainer = nearest_target[direction]
            if abs(position[0] - your_position[0]) < abs(prev_position[0] - your_position[0]):
                nearest_target[direction] = (position, is_trainer)
        else:
            nearest_target[direction] = (position, is_trainer)
    return sum(1 for (position, is_trainer) in nearest_target.values() if is_trainer and line_length(your_position, position) <= distance)

def generate_room_id(dimentions, your_position, distance):
    memo = []
    room_width = dimentions[0]
    room_height = dimentions[1]
    x_range = distance / room_width + 1
    y_range = distance / room_height + 1
    for room_x in range(x_range):
        for room_y in range(y_range):
            memo += [(room_x, room_y)]
            yield room_x, room_y
    for room_x, room_y in memo:
        yield - room_x - 1, room_y
        yield room_x, - room_y - 1
        yield - room_x - 1, - room_y - 1

def generate_positions(dimentions, your_position, trainer_position, distance):
    room_width, room_height = dimentions
    for room_x, room_y in generate_room_id(dimentions, your_position, distance):
        x_reflected = room_x % 2 == 1
        y_reflected = room_y % 2 == 1
        x_base = room_x*room_width
        y_base = room_y*room_height
        your_x_offset = your_position[0]
        your_y_offset = your_position[1]
        trainer_x_offset = trainer_position[0]
        trainer_y_offset = trainer_position[1]
        if (x_reflected):
            reflected_your_x_position = x_base + room_width - your_x_offset
            reflected_trainer_x_position = x_base + room_width - trainer_x_offset
        else:
            reflected_your_x_position = x_base + your_x_offset
            reflected_trainer_x_position = x_base + trainer_x_offset
        if (y_reflected):
            reflected_your_y_position = y_base + room_height - your_y_offset
            reflected_trainer_y_position = y_base + room_height - trainer_y_offset
        else:
            reflected_your_y_position = y_base + your_y_offset
            reflected_trainer_y_position = y_base + trainer_y_offset
        yield (reflected_your_x_position, reflected_your_y_position), False
        yield (reflected_trainer_x_position, reflected_trainer_y_position), True

def gcd(m, n):
    while n != 0:
        t = m % n
        m, n = n, t
    return m

def reduce_direction(direction):
    x, y = direction
    if x == 0 and y == 0:
        return 0, 0
    elif x == 0:
        return 0, (1 if y > 0 else -1)
    elif y == 0:
        return (1 if x > 0 else -1), 0
    g = gcd(abs(x), abs(y))
    return x/g, y/g

def calc_direction(origin, target):
    return reduce_direction((target[0] - origin[0], target[1] - origin[1]))

def line_length(origin, target):
    return math.sqrt((target[0] - origin[0])**2 + (target[1] - origin[1])**2)

tests = [
    (([3, 2], [1, 1], [2, 1], 4), 7),
    (([300,275], [150,150], [185,100], 500), 9),
    (([3, 2], [1, 1], [2, 1], 2), 1),
    (([300,275], [150,150], [185,100], 2), 0),
    (([3, 2], [1, 1], [2, 1], 1000), 397845),
    (([30, 20], [10, 10], [20, 10], 10000), 397845),
]

for i, o in tests:
    result = solution(*i)
    print(i, result == o, result, o)