advent-of-code/2022/d18/ex2/ex2.py

#!/usr/bin/env python

import itertools
import sys
from collections import deque
from collections.abc import Iterator
from typing import NamedTuple


class Point3(NamedTuple):
    x: int
    y: int
    z: int

    @classmethod
    def from_input(cls, input: str) -> "Point3":
        x, y, z = map(int, input.split(","))
        return cls(x, y, z)

    @classmethod
    def neighbours(cls, p: "Point3") -> Iterator["Point3"]:
        for dx, dy, dz in (
            (0, 0, -1),
            (0, 0, 1),
            (0, -1, 0),
            (0, 1, 0),
            (-1, 0, 0),
            (1, 0, 0),
        ):
            yield cls(p.x + dx, p.y + dy, p.z + dz)


def solve(input: list[str]) -> int:
    def compute_unreachable(cubes: set[Point3]) -> set[Point3]:
        def explore(p: Point3, can_reach_out: dict[Point3, bool]) -> bool:
            seen: set[Point3] = set()
            queue: list[Point3] = [p]
            while queue:
                p = queue.pop()
                if p in seen:
                    continue
                if p in can_reach_out:
                    if can_reach_out[p]:
                        return True
                    continue  # Don't go through walls
                seen.add(p)
                queue.extend(Point3.neighbours(p))
            return False

        minx, maxx = min(p.x for p in cubes), max(p.x for p in cubes)
        miny, maxy = min(p.y for p in cubes), max(p.y for p in cubes)
        minz, maxz = min(p.z for p in cubes), max(p.z for p in cubes)

        can_reach_out = {p: False for p in cubes}
        can_reach_out |= {
            Point3(x, y, z): True
            for x, (y, z) in zip(
                itertools.repeat(minx - 1),
                itertools.product(range(miny, maxy + 1), range(minz, maxz + 1)),
            )
        }
        can_reach_out |= {
            Point3(x, y, z): True
            for x, (y, z) in zip(
                itertools.repeat(maxx + 1),
                itertools.product(range(miny, maxy + 1), range(minz, maxz + 1)),
            )
        }
        can_reach_out |= {
            Point3(x, y, z): True
            for y, (x, z) in zip(
                itertools.repeat(miny - 1),
                itertools.product(range(minx, maxx + 1), range(minz, maxz + 1)),
            )
        }
        can_reach_out |= {
            Point3(x, y, z): True
            for y, (x, z) in zip(
                itertools.repeat(maxy + 1),
                itertools.product(range(minx, maxx + 1), range(minz, maxz + 1)),
            )
        }
        can_reach_out |= {
            Point3(x, y, z): True
            for z, (x, y) in zip(
                itertools.repeat(minz - 1),
                itertools.product(range(minx, maxx + 1), range(miny, maxy + 1)),
            )
        }
        can_reach_out |= {
            Point3(x, y, z): True
            for z, (x, y) in zip(
                itertools.repeat(maxz + 1),
                itertools.product(range(minx, maxx + 1), range(miny, maxy + 1)),
            )
        }

        for x, y, z in itertools.product(
            range(minx, maxx + 1),
            range(miny, maxy + 1),
            range(minz, maxz + 1),
        ):
            p = Point3(x, y, z)
            can_reach_out[p] = explore(p, can_reach_out)
        return {p for p, can_reach in can_reach_out.items() if not can_reach}

    cubes = {Point3.from_input(line) for line in input}
    unreachable = compute_unreachable(cubes)

    return sum(1 for p in cubes for n in Point3.neighbours(p) if n not in unreachable)


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


if __name__ == "__main__":
    main()
2022: d18: ex2: add solution 2022-12-18 12:44:49 +01:00			`#!/usr/bin/env python`

			`import itertools`
			`import sys`
			`from collections import deque`
			`from collections.abc import Iterator`
			`from typing import NamedTuple`


			`class Point3(NamedTuple):`
			`x: int`
			`y: int`
			`z: int`

			`@classmethod`
			`def from_input(cls, input: str) -> "Point3":`
			`x, y, z = map(int, input.split(","))`
			`return cls(x, y, z)`

			`@classmethod`
			`def neighbours(cls, p: "Point3") -> Iterator["Point3"]:`
			`for dx, dy, dz in (`
			`(0, 0, -1),`
			`(0, 0, 1),`
			`(0, -1, 0),`
			`(0, 1, 0),`
			`(-1, 0, 0),`
			`(1, 0, 0),`
			`):`
			`yield cls(p.x + dx, p.y + dy, p.z + dz)`


			`def solve(input: list[str]) -> int:`
			`def compute_unreachable(cubes: set[Point3]) -> set[Point3]:`
			`def explore(p: Point3, can_reach_out: dict[Point3, bool]) -> bool:`
			`seen: set[Point3] = set()`
			`queue: list[Point3] = [p]`
			`while queue:`
			`p = queue.pop()`
			`if p in seen:`
			`continue`
			`if p in can_reach_out:`
			`if can_reach_out[p]:`
			`return True`
			`continue # Don't go through walls`
			`seen.add(p)`
			`queue.extend(Point3.neighbours(p))`
			`return False`

			`minx, maxx = min(p.x for p in cubes), max(p.x for p in cubes)`
			`miny, maxy = min(p.y for p in cubes), max(p.y for p in cubes)`
			`minz, maxz = min(p.z for p in cubes), max(p.z for p in cubes)`

			`can_reach_out = {p: False for p in cubes}`
			`can_reach_out \|= {`
			`Point3(x, y, z): True`
			`for x, (y, z) in zip(`
			`itertools.repeat(minx - 1),`
			`itertools.product(range(miny, maxy + 1), range(minz, maxz + 1)),`
			`)`
			`}`
			`can_reach_out \|= {`
			`Point3(x, y, z): True`
			`for x, (y, z) in zip(`
			`itertools.repeat(maxx + 1),`
			`itertools.product(range(miny, maxy + 1), range(minz, maxz + 1)),`
			`)`
			`}`
			`can_reach_out \|= {`
			`Point3(x, y, z): True`
			`for y, (x, z) in zip(`
			`itertools.repeat(miny - 1),`
			`itertools.product(range(minx, maxx + 1), range(minz, maxz + 1)),`
			`)`
			`}`
			`can_reach_out \|= {`
			`Point3(x, y, z): True`
			`for y, (x, z) in zip(`
			`itertools.repeat(maxy + 1),`
			`itertools.product(range(minx, maxx + 1), range(minz, maxz + 1)),`
			`)`
			`}`
			`can_reach_out \|= {`
			`Point3(x, y, z): True`
			`for z, (x, y) in zip(`
			`itertools.repeat(minz - 1),`
			`itertools.product(range(minx, maxx + 1), range(miny, maxy + 1)),`
			`)`
			`}`
			`can_reach_out \|= {`
			`Point3(x, y, z): True`
			`for z, (x, y) in zip(`
			`itertools.repeat(maxz + 1),`
			`itertools.product(range(minx, maxx + 1), range(miny, maxy + 1)),`
			`)`
			`}`

			`for x, y, z in itertools.product(`
			`range(minx, maxx + 1),`
			`range(miny, maxy + 1),`
			`range(minz, maxz + 1),`
			`):`
			`p = Point3(x, y, z)`
			`can_reach_out[p] = explore(p, can_reach_out)`
			`return {p for p, can_reach in can_reach_out.items() if not can_reach}`

			`cubes = {Point3.from_input(line) for line in input}`
			`unreachable = compute_unreachable(cubes)`

			`return sum(1 for p in cubes for n in Point3.neighbours(p) if n not in unreachable)`


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


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