python(day20): Optimize and tidy up
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c1c649ed05
commit
6ff43c5335
334
python/day20.py
334
python/day20.py
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@ -2,243 +2,211 @@ import fileinput
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from pprint import pprint
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import itertools
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from copy import deepcopy
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from typing import List, Tuple, Optional, Dict
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N = 10
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SNEK_POSITIONS = (
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(0, 0),
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(1, 1),
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(4, 1),
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(5, 0),
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(6, 0),
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(7, 1),
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(10, 1),
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(11, 0),
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(12, 0),
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(13, 1),
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(16, 1),
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(17, 0),
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(18, 0),
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(18, -1),
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(19, 0),
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)
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#
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# Parse the input
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#
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current_tile = None
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tiles = []
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for line in fileinput.input():
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line = line.strip()
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if not line:
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continue
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if line.startswith("Tile "):
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if current_tile:
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assert len(current_tile) == N
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tiles.append((current_id, current_tile))
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current_id = int(line[5:-1])
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current_tile = []
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else:
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assert len(line) == N
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current_tile.append(list(line))
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assert len(current_tile) == N
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tiles.append((current_id, current_tile))
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Tile = List[List[bool]]
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Position = Tuple[int, int]
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Extremes = Tuple[int, int, int, int]
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def aligns_right(left, right):
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return all(left[y][-1] == right[y][0] for y in range(len(left)))
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def parse() -> List[Tuple[int, Tile]]:
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current_tile = None
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tiles = []
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for line in fileinput.input():
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line = line.strip()
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if not line:
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continue
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if line.startswith("Tile "):
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if current_tile:
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assert len(current_tile) == N
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tiles.append((current_id, current_tile))
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current_id = int(line[5:-1])
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current_tile = []
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else:
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assert len(line) == N
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current_tile.append([c == "#" for c in line])
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assert len(current_tile) == N
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tiles.append((current_id, current_tile))
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return tiles
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def aligns_bottom(top, bottom):
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return all(top[-1][x] == bottom[0][x] for x in range(len(top)))
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def aligns_right(left: Tile, right: Tile) -> bool:
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return all(left_row[-1] == right_row[0] for (left_row, right_row) in zip(left, right))
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def aligns(apos, b):
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ax, ay = apos
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_, a = kek[(ax, ay)]
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if aligns_right(a, b):
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return 1, 0
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if aligns_right(b, a):
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return -1, 0
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def aligns_bottom(top: Tile, bottom: Tile) -> bool:
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return top[-1] == bottom[0]
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def aligns(a: Tile, b: Tile) -> Optional[Position]:
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if aligns_bottom(a, b):
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return 0, 1
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if aligns_bottom(b, a):
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return 0, -1
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if aligns_right(a, b):
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return 1, 0
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if aligns_right(b, a):
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return -1, 0
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return None
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def rotate(a):
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output = deepcopy(a)
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for y in range(len(a)):
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for x in range(len(a)):
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output[-1 - x][y] = a[y][x]
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def rotate(tile: Tile) -> Tile:
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output = list(reversed(tile))
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for y in range(len(tile)):
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for x in range(y):
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output[y][x], output[x][y] = output[x][y], output[y][x]
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return output
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def flip(a):
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output = [None] * len(a)
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for y in range(len(a)):
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output[y] = list(reversed(a[y]))
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return output
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def flip(a: Tile) -> Tile:
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return list(reversed(a))
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def rotate_align(a_pos, b):
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def rotate_align(a: Tile, b: Tile) -> Optional[Tuple[Tile, Position]]:
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"""
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Rotates and flips a and checks if it aligns for every possible orientation.
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"""
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if d := aligns(a_pos, b):
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return b, d
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bf = flip(b)
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if d := aligns(a_pos, bf):
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return bf, d
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for _ in range(4):
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if pos := aligns(a, b):
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return b, pos
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bf = flip(b)
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b = rotate(b)
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if d := aligns(a_pos, b):
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return b, d
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bf = flip(b)
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if d := aligns(a_pos, bf):
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return bf, d
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b = rotate(b)
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if d := aligns(a_pos, b):
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return b, d
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bf = flip(b)
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if d := aligns(a_pos, bf):
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return bf, d
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b = rotate(b)
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if d := aligns(a_pos, b):
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return b, d
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bf = flip(b)
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if d := aligns(a_pos, bf):
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return bf, d
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return None, None
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if pos := aligns(a, bf):
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return bf, pos
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b = rotate(b)
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return None
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positions = {tiles[0][0]: ((0, 0), tiles[0][1])}
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kek = {(0, 0): tiles[0]}
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def part1(
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tiles: List[Tuple[int, Tile]]
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) -> Tuple[Dict[Position, Tuple[int, Tile]], Extremes]:
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tile_positions = {tiles[0][0]: (0, 0)}
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position_tiles = {(0, 0): tiles[0]}
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while len(positions) != len(tiles):
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for a_id, _ in tiles:
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((a_x, a_y), a_tile) = positions.get(a_id, ((None, None), None))
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if not a_tile:
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continue
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for b_id, b_tile in tiles:
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if b_id in positions or a_id == b_id:
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while len(tile_positions) != len(tiles):
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for a_id, _ in tiles:
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try:
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(a_x, a_y) = a_pos = tile_positions[a_id]
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_, a_tile = position_tiles[a_pos]
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except KeyError:
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continue
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transformed, dpos = rotate_align((a_x, a_y), b_tile)
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if dpos is not None:
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dx, dy = dpos
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b_x = a_x + dx
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b_y = a_y + dy
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positions[b_id] = (b_x, b_y), transformed
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kek[(b_x, b_y)] = b_id, transformed
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for b_id, b_tile in tiles:
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if b_id in tile_positions or a_id == b_id:
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continue
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min_y = min(y for ((_, y), _) in positions.values())
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max_y = max(y for ((_, y), _) in positions.values())
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min_x = min(x for ((x, _), _) in positions.values())
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max_x = max(x for ((x, _), _) in positions.values())
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aligned = rotate_align(a_tile, b_tile)
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if aligned is not None:
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transformed, b_pos = aligned
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dx, dy = b_pos
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b_x = a_x + dx
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b_y = a_y + dy
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tile_positions[b_id] = (b_x, b_y)
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position_tiles[(b_x, b_y)] = b_id, transformed
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tilemap = {pos: (id, tile) for id, (pos, tile) in positions.items()}
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bl, _ = tilemap[(min_x, min_y)]
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br, _ = tilemap[(max_x, min_y)]
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tl, _ = tilemap[(min_x, max_y)]
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tr, _ = tilemap[(max_x, max_y)]
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print("Part 1:", tl * tr * bl * br)
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min_y = min(y for (_, y) in tile_positions.values())
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max_y = max(y for (_, y) in tile_positions.values())
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min_x = min(x for (x, _) in tile_positions.values())
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max_x = max(x for (x, _) in tile_positions.values())
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bl, _ = position_tiles[(min_x, min_y)]
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br, _ = position_tiles[(max_x, min_y)]
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tl, _ = position_tiles[(min_x, max_y)]
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tr, _ = position_tiles[(max_x, max_y)]
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print("Part 1:", tl * tr * bl * br)
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return position_tiles, (min_x, max_x, min_y, max_y)
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def is_snek(b, x, y):
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for (x_, y_) in (
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(0, 0),
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(1, 1),
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(4, 1),
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(5, 0),
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(6, 0),
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(7, 1),
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(10, 1),
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(11, 0),
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(12, 0),
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(13, 1),
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(16, 1),
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(17, 0),
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(18, 0),
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(18, -1),
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(19, 0),
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):
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def is_snek(image: Tile, start_x: int, start_y: int) -> bool:
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for (x, y) in SNEK_POSITIONS:
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try:
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if b[y_ + y][x_ + x] == ".":
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if not image[y + start_y][x + start_x]:
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return False
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except:
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return False
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return True
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def find_sneks(b):
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def find_sneks(b: Tile) -> List[Position]:
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sneks = []
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for (x, y) in itertools.product(range(8 * 12), repeat=2):
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if is_snek(b, x, y):
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print(x, y, "is snek")
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sneks.append((x, y))
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return sneks
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def rotate_find_sneks(b):
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if d := find_sneks(b):
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return b, d
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bf = flip(b)
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if d := find_sneks(bf):
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return bf, d
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def rotate_find_sneks(b: Tile) -> Tuple[Tile, List[Position]]:
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for _ in range(4):
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if position := find_sneks(b):
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return b, position
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bf = flip(b)
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b = rotate(b)
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if d := find_sneks(b):
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return b, d
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bf = flip(b)
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if d := find_sneks(bf):
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return bf, d
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b = rotate(b)
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if d := find_sneks(b):
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return b, d
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bf = flip(b)
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if d := find_sneks(bf):
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return bf, d
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b = rotate(b)
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if d := find_sneks(b):
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return b, d
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bf = flip(b)
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if d := find_sneks(bf):
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return bf, d
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if position := find_sneks(bf):
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return bf, position
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b = rotate(b)
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raise RuntimeError("no sneks found")
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def remove_snek(snek):
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def remove_snek(image: Tile, snek_position: Position) -> None:
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# :(
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(x, y) = snek
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for (x_, y_) in (
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(0, 0),
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(1, 1),
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(4, 1),
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(5, 0),
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(6, 0),
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(7, 1),
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(10, 1),
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(11, 0),
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(12, 0),
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(13, 1),
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(16, 1),
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(17, 0),
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(18, 0),
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(18, -1),
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(19, 0),
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):
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big_chungus[y + y_][x + x_] = '.'
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(x, y) = snek_position
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for (x_, y_) in SNEK_POSITIONS:
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image[y + y_][x + x_] = False
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chungus = [["."] * 8 * (max_x - min_x + 1) for _ in range(8 * (max_y - min_y + 1))]
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for (x, y), (id, tile) in tilemap.items():
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x_ = (x - min_x) * 8
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y_ = (y - min_y) * 8
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for i, row in enumerate(tile[1:-1]):
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for j, c in enumerate(row[1:-1]):
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chungus[i + y_][j + x_] = c
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def part2(
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position_tiles: Dict[Position, Tuple[int, Tile]],
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extremes: Tuple[int, int, int, int],
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) -> None:
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min_x, max_x, min_y, max_y = extremes
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image = [[False] * 8 * (max_x - min_x + 1) for _ in range(8 * (max_y - min_y + 1))]
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for (x, y), (_, tile) in position_tiles.items():
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x_ = (x - min_x) * 8
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y_ = (y - min_y) * 8
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for i, row in enumerate(tile[1:-1]):
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for j, c in enumerate(row[1:-1]):
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image[i + y_][j + x_] = c
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# for y, row in enumerate(chungus):
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# print("".join(row))
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rotated_image, snek_positions = rotate_find_sneks(image)
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for snek_position in snek_positions:
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remove_snek(rotated_image, snek_position)
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big_chungus, sneks = rotate_find_sneks(chungus)
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for snek in sneks:
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remove_snek(snek)
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part2 = 0
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for row in rotated_image:
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for c in row:
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if c:
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part2 += 1
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part2 = 0
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for row in big_chungus:
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for c in row:
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if c == "#":
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part2 += 1
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print("Part 2:", part2)
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print("Part 2:", part2)
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def main() -> None:
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tiles = parse()
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position_tiles, extremes = part1(tiles)
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part2(position_tiles, extremes)
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if __name__ == "__main__":
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main()
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