advent-of-code/2020/d20/ex2/ex2.py

#!/usr/bin/env python

import functools
import itertools
import math
import sys
from collections import defaultdict
from copy import deepcopy
from typing import Dict, Iterator, List, Set, Tuple

Tile = List[List[str]]
Tiles = Dict[int, Tile]


def parse(raw: str) -> Tiles:
    def parse_tile(raw: List[str]) -> Tile:
        return [[line[i] for i in range(len(line))] for line in raw]

    res = {}
    for lines in map(lambda s: s.splitlines(), raw.split("\n\n")):
        if len(lines) == 0:
            continue
        nums = int(lines[0][5:-1])
        res[nums] = parse_tile(lines[1:])
    return res


def rotations(tile: Tile) -> Iterator[Tile]:
    yield tile
    for __ in range(3):
        tile = [
            [tile[j][i] for j in range(len(tile))]
            for i in range(len(tile[0]) - 1, -1, -1)
        ]
        yield tile


def flips(tile: Tile) -> Iterator[Tile]:
    yield tile
    yield tile[::-1]
    yield [line[::-1] for line in tile]
    yield [line[::-1] for line in tile[::-1]]


def transforms(tile: Tile) -> List[Tile]:
    # Can't use a set with lists...
    res: List[Tile] = functools.reduce(
        lambda l, it: l + [it] if not any(it == other for other in l) else l,
        itertools.chain.from_iterable(map(rotations, flips(tile))),
        [],
    )
    return res


def borders(tile: Tile) -> Iterator[str]:
    # They should match on same axis (i.e: go clockwise and counter-clockwise)
    return map(
        lambda s: "".join(s),
        [
            tile[0],
            [line[-1] for line in tile],
            tile[-1],
            [line[0] for line in tile],
        ],
    )


Transforms = Dict[int, List[Tile]]
Tiling = List[List[Tuple[int, int]]]  # Which tile, and which transform


def build_tiling(tiles: Tiles) -> Tuple[Transforms, Tiling]:
    transform_mapping = {num: transforms(tile) for num, tile in tiles.items()}
    trans_borders: Dict[int, Dict[int, List[str]]] = defaultdict(dict)
    for num, trans in transform_mapping.items():
        for i, t in enumerate(trans):
            trans_borders[num][i] = list(borders(t))
    length = math.isqrt(len(tiles))
    tiling = [[(-1, -1)] * length for __ in range(length)]

    def rec(x: int = 0, y: int = 0, used: Set[int] = set()) -> bool:
        if x == length:
            return True
        for num, borders in trans_borders.items():
            if num in used:
                continue
            used |= {num}

            for trans, border in borders.items():
                top, __, __, left = border
                if y > 0:
                    nid, ntrans = tiling[x][y - 1]
                    __, right, __, __ = trans_borders[nid][ntrans]
                    if left != right:
                        continue
                if x > 0:
                    nid, ntrans = tiling[x - 1][y]
                    __, __, bottom, __ = trans_borders[nid][ntrans]
                    if top != bottom:
                        continue
                tiling[x][y] = num, trans

                next_x, next_y = (x, y + 1) if y < (length - 1) else (x + 1, 0)
                if rec(next_x, next_y, used):
                    return True

            used -= {num}

        tiling[x][y] = (-1, -1)
        return False

    assert rec()
    return transform_mapping, tiling


def trim(trans: Transforms, tiling: Tiling) -> Tile:
    def trim_tile(tile: Tile) -> Tile:
        return [line[1:-1] for line in tile[1:-1]]

    def tiling_to_tile(tiling: List[List[Tile]]) -> Tile:
        res: Tile = []
        for i in range(len(tiling) * len(tiling[0][0])):
            res.append([])
            tile_line_idx = i % len(tiling[0][0])
            for j in range(len(tiling[0]) * len(tiling[0][0][0])):
                tile = tiling[i // len(tiling[0][0])][j // len(tiling[0][0][0])]
                tile_row_idx = j % len(tiling[0][0][0])
                res[-1].append(tile[tile_line_idx][tile_row_idx])
        return res

    tiles = [[trim_tile(trans[num][id]) for num, id in line] for line in tiling]
    return tiling_to_tile(tiles)


def find_monster(image: Tile, monster: Tile) -> Iterator[Tuple[int, int]]:
    def monster_at(x: int, y: int) -> bool:
        for i in range(len(monster)):
            for j in range(len(monster[0])):
                if monster[i][j] == " ":
                    continue
                if image[x + i][y + j] != "#":
                    return False
        return True

    # Returns upper left corner if found
    for i in range(len(image) - len(monster)):
        for j in range(len(image[0]) - len(monster[0])):
            if monster_at(i, j):
                yield i, j


def remove_monster(image: Tile, monster: Tile, x: int, y: int) -> None:
    for i in range(len(monster)):
        for j in range(len(monster[0])):
            if monster[i][j] == " ":
                continue
            image[x + i][y + j] = " "


def solve(tiles: Tiles) -> int:
    image = trim(*build_tiling(tiles))
    monster = [
        [char for char in line]
        for line in (
            "                  # ",
            "#    ##    ##    ###",
            " #  #  #  #  #  #   ",
        )
    ]
    monsters = transforms(monster)

    for monster in monsters:
        for coords in find_monster(image, monster):
            remove_monster(image, monster, *coords)

    return sum(sum(char == "#" for char in line) for line in image)


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


if __name__ == "__main__":
    main()
2020: d20: ex2: add solution 2020-12-20 14:27:02 +01:00			`#!/usr/bin/env python`

			`import functools`
			`import itertools`
			`import math`
			`import sys`
			`from collections import defaultdict`
			`from copy import deepcopy`
			`from typing import Dict, Iterator, List, Set, Tuple`

			`Tile = List[List[str]]`
			`Tiles = Dict[int, Tile]`


			`def parse(raw: str) -> Tiles:`
			`def parse_tile(raw: List[str]) -> Tile:`
			`return [[line[i] for i in range(len(line))] for line in raw]`

			`res = {}`
			`for lines in map(lambda s: s.splitlines(), raw.split("\n\n")):`
			`if len(lines) == 0:`
			`continue`
			`nums = int(lines[0][5:-1])`
			`res[nums] = parse_tile(lines[1:])`
			`return res`


			`def rotations(tile: Tile) -> Iterator[Tile]:`
			`yield tile`
			`for __ in range(3):`
			`tile = [`
			`[tile[j][i] for j in range(len(tile))]`
			`for i in range(len(tile[0]) - 1, -1, -1)`
			`]`
			`yield tile`


			`def flips(tile: Tile) -> Iterator[Tile]:`
			`yield tile`
			`yield tile[::-1]`
			`yield [line[::-1] for line in tile]`
			`yield [line[::-1] for line in tile[::-1]]`


			`def transforms(tile: Tile) -> List[Tile]:`
			`# Can't use a set with lists...`
			`res: List[Tile] = functools.reduce(`
			`lambda l, it: l + [it] if not any(it == other for other in l) else l,`
			`itertools.chain.from_iterable(map(rotations, flips(tile))),`
			`[],`
			`)`
			`return res`


			`def borders(tile: Tile) -> Iterator[str]:`
			`# They should match on same axis (i.e: go clockwise and counter-clockwise)`
			`return map(`
			`lambda s: "".join(s),`
			`[`
			`tile[0],`
			`[line[-1] for line in tile],`
			`tile[-1],`
			`[line[0] for line in tile],`
			`],`
			`)`


			`Transforms = Dict[int, List[Tile]]`
			`Tiling = List[List[Tuple[int, int]]] # Which tile, and which transform`


			`def build_tiling(tiles: Tiles) -> Tuple[Transforms, Tiling]:`
			`transform_mapping = {num: transforms(tile) for num, tile in tiles.items()}`
			`trans_borders: Dict[int, Dict[int, List[str]]] = defaultdict(dict)`
			`for num, trans in transform_mapping.items():`
			`for i, t in enumerate(trans):`
			`trans_borders[num][i] = list(borders(t))`
			`length = math.isqrt(len(tiles))`
			`tiling = [[(-1, -1)] * length for __ in range(length)]`

			`def rec(x: int = 0, y: int = 0, used: Set[int] = set()) -> bool:`
			`if x == length:`
			`return True`
			`for num, borders in trans_borders.items():`
			`if num in used:`
			`continue`
			`used \|= {num}`

			`for trans, border in borders.items():`
			`top, __, __, left = border`
			`if y > 0:`
			`nid, ntrans = tiling[x][y - 1]`
			`__, right, __, __ = trans_borders[nid][ntrans]`
			`if left != right:`
			`continue`
			`if x > 0:`
			`nid, ntrans = tiling[x - 1][y]`
			`__, __, bottom, __ = trans_borders[nid][ntrans]`
			`if top != bottom:`
			`continue`
			`tiling[x][y] = num, trans`

			`next_x, next_y = (x, y + 1) if y < (length - 1) else (x + 1, 0)`
			`if rec(next_x, next_y, used):`
			`return True`

			`used -= {num}`

			`tiling[x][y] = (-1, -1)`
			`return False`

			`assert rec()`
			`return transform_mapping, tiling`


			`def trim(trans: Transforms, tiling: Tiling) -> Tile:`
			`def trim_tile(tile: Tile) -> Tile:`
			`return [line[1:-1] for line in tile[1:-1]]`

			`def tiling_to_tile(tiling: List[List[Tile]]) -> Tile:`
			`res: Tile = []`
			`for i in range(len(tiling) * len(tiling[0][0])):`
			`res.append([])`
			`tile_line_idx = i % len(tiling[0][0])`
			`for j in range(len(tiling[0]) * len(tiling[0][0][0])):`
			`tile = tiling[i // len(tiling[0][0])][j // len(tiling[0][0][0])]`
			`tile_row_idx = j % len(tiling[0][0][0])`
			`res[-1].append(tile[tile_line_idx][tile_row_idx])`
			`return res`

			`tiles = [[trim_tile(trans[num][id]) for num, id in line] for line in tiling]`
			`return tiling_to_tile(tiles)`


			`def find_monster(image: Tile, monster: Tile) -> Iterator[Tuple[int, int]]:`
			`def monster_at(x: int, y: int) -> bool:`
			`for i in range(len(monster)):`
			`for j in range(len(monster[0])):`
			`if monster[i][j] == " ":`
			`continue`
			`if image[x + i][y + j] != "#":`
			`return False`
			`return True`

			`# Returns upper left corner if found`
			`for i in range(len(image) - len(monster)):`
			`for j in range(len(image[0]) - len(monster[0])):`
			`if monster_at(i, j):`
			`yield i, j`


			`def remove_monster(image: Tile, monster: Tile, x: int, y: int) -> None:`
			`for i in range(len(monster)):`
			`for j in range(len(monster[0])):`
			`if monster[i][j] == " ":`
			`continue`
			`image[x + i][y + j] = " "`


			`def solve(tiles: Tiles) -> int:`
			`image = trim(*build_tiling(tiles))`
			`monster = [`
			`[char for char in line]`
			`for line in (`
			`" # ",`
			`"# ## ## ###",`
			`" # # # # # # ",`
			`)`
			`]`
			`monsters = transforms(monster)`

			`for monster in monsters:`
			`for coords in find_monster(image, monster):`
			`remove_monster(image, monster, *coords)`

			`return sum(sum(char == "#" for char in line) for line in image)`


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


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