advent-of-code/2023/d24/ex1/ex1.py

#!/usr/bin/env python

import itertools
import sys
from decimal import Decimal
from typing import NamedTuple


class Point(NamedTuple):
    x: int
    y: int
    z: int


class HailStone(NamedTuple):
    pos: Point
    vel: Point


def solve(input: list[str]) -> int:
    def parse_line(line: str) -> HailStone:
        pos, vel = line.split(" @ ")
        return HailStone(
            Point(*map(int, pos.split(", "))), Point(*map(int, vel.split(", ")))
        )

    def parse(input: list[str]) -> list[HailStone]:
        return [parse_line(line) for line in input]

    def intersections(hailstones: list[HailStone], boundaries: tuple[int, int]) -> int:
        def intersects(a: HailStone, b: HailStone) -> bool:
            # According to wikipedia, if:
            # x = a_px + t * a_vx = b_px + u * b_vx
            # y = a_py + t * a_vy = b_py + u * b_vy
            # then:
            # t = ((a_px-b_px)*(-b_vy) - (a_py-b_py)*(-b_vx)) / ((-a_vx)*(-b_vy) - (-a_vy)*(-b_vx))
            # u = ((a_px-b_px)*(-a_vy) - (a_py-b_py)*(-a_vx)) / ((-a_vx)*(-b_vy) - (-a_vy)*(-b_vx))
            (a_px, a_py, _), (a_vx, a_vy, _) = a
            (b_px, b_py, _), (b_vx, b_vy, _) = b

            # Use rationals for extra precision, just in case
            denom = Decimal(a_vx * b_vy - a_vy * b_vx)

            # Parallel lines
            if denom == 0:
                return False

            t = ((a_px - b_px) * (-b_vy) - (a_py - b_py) * (-b_vx)) / denom
            u = ((a_px - b_px) * (-a_vy) - (a_py - b_py) * (-a_vx)) / denom

            # Intersects in the past
            if t < 0 or u < 0:
                return False

            x = a_px + t * a_vx
            y = a_py + t * a_vy

            # Outside our observation area
            if not boundaries[0] <= x <= boundaries[1]:
                return False
            if not boundaries[0] <= y <= boundaries[1]:
                return False

            return True

        return sum(intersects(a, b) for a, b in itertools.combinations(hailstones, 2))

    hailstones = parse(input)
    return intersections(hailstones, (200000000000000, 400000000000000))


def main() -> None:
    input = sys.stdin.read().splitlines()
    print(solve(input))


if __name__ == "__main__":
    main()
2023: d24: ex1: add solution 2023-12-24 13:35:15 +01:00			`#!/usr/bin/env python`

			`import itertools`
			`import sys`
			`from decimal import Decimal`
			`from typing import NamedTuple`


			`class Point(NamedTuple):`
			`x: int`
			`y: int`
			`z: int`


			`class HailStone(NamedTuple):`
			`pos: Point`
			`vel: Point`


			`def solve(input: list[str]) -> int:`
			`def parse_line(line: str) -> HailStone:`
			`pos, vel = line.split(" @ ")`
			`return HailStone(`
			`Point(map(int, pos.split(", "))), Point(map(int, vel.split(", ")))`
			`)`

			`def parse(input: list[str]) -> list[HailStone]:`
			`return [parse_line(line) for line in input]`

			`def intersections(hailstones: list[HailStone], boundaries: tuple[int, int]) -> int:`
			`def intersects(a: HailStone, b: HailStone) -> bool:`
			`# According to wikipedia, if:`
			`# x = a_px + t * a_vx = b_px + u * b_vx`
			`# y = a_py + t * a_vy = b_py + u * b_vy`
			`# then:`
			`# t = ((a_px-b_px)(-b_vy) - (a_py-b_py)(-b_vx)) / ((-a_vx)(-b_vy) - (-a_vy)(-b_vx))`
			`# u = ((a_px-b_px)(-a_vy) - (a_py-b_py)(-a_vx)) / ((-a_vx)(-b_vy) - (-a_vy)(-b_vx))`
			`(a_px, a_py, _), (a_vx, a_vy, _) = a`
			`(b_px, b_py, _), (b_vx, b_vy, _) = b`

			`# Use rationals for extra precision, just in case`
			`denom = Decimal(a_vx * b_vy - a_vy * b_vx)`

			`# Parallel lines`
			`if denom == 0:`
			`return False`

			`t = ((a_px - b_px) * (-b_vy) - (a_py - b_py) * (-b_vx)) / denom`
			`u = ((a_px - b_px) * (-a_vy) - (a_py - b_py) * (-a_vx)) / denom`

			`# Intersects in the past`
			`if t < 0 or u < 0:`
			`return False`

			`x = a_px + t * a_vx`
			`y = a_py + t * a_vy`

			`# Outside our observation area`
			`if not boundaries[0] <= x <= boundaries[1]:`
			`return False`
			`if not boundaries[0] <= y <= boundaries[1]:`
			`return False`

			`return True`

			`return sum(intersects(a, b) for a, b in itertools.combinations(hailstones, 2))`

			`hailstones = parse(input)`
			`return intersections(hailstones, (200000000000000, 400000000000000))`


			`def main() -> None:`
			`input = sys.stdin.read().splitlines()`
			`print(solve(input))`


			`if __name__ == "__main__":`
			`main()`