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2017: d14: ex2: add solution

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Bruno BELANYI 2025-05-09 23:38:07 +01:00
parent af8dca3341
commit 711fab975b
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2017/d14/ex2/ex2.py Executable file
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#!/usr/bin/env python
import collections
import functools
import itertools
import operator
import sys
class UnionFind:
_parent: list[int]
_rank: list[int]
def __init__(self, size: int):
# Each node is in its own set, making it its own parent...
self._parent = list(range(size))
# ... And its rank 0
self._rank = [0] * size
def find(self, elem: int) -> int:
while (parent := self._parent[elem]) != elem:
# Replace each parent link by a link to the grand-parent
elem, self._parent[elem] = parent, self._parent[parent]
return elem
def union(self, lhs: int, rhs: int) -> int:
lhs = self.find(lhs)
rhs = self.find(rhs)
# Bail out early if they already belong to the same set
if lhs == rhs:
return lhs
# Always keep `lhs` as the taller tree
if self._rank[lhs] < self._rank[rhs]:
lhs, rhs = rhs, lhs
# Merge the smaller tree into the taller one
self._parent[rhs] = lhs
# Update the rank when merging trees of approximately the same size
if self._rank[lhs] == self._rank[rhs]:
self._rank[lhs] += 1
return lhs
def sets(self) -> dict[int, set[int]]:
res: dict[int, set[int]] = collections.defaultdict(set)
for elem in range(len(self._parent)):
res[self.find(elem)].add(elem)
return dict(res)
def solve(input: str) -> int:
def knot_hash(byte_string: str) -> str:
def compute_sparse_hash(lengths: list[int]) -> list[int]:
circle = list(range(256))
cur_pos, skip_size = 0, 0
for _ in range(64):
for n in lengths:
# Invalid length
assert n < len(circle) # Sanity check
# Reverse
for i, j in zip(
range(cur_pos, cur_pos + n // 2),
# Avoid off-by-one by going further than necessary
range(cur_pos + n - 1, cur_pos, -1),
):
i %= len(circle)
j %= len(circle)
circle[i], circle[j] = circle[j], circle[i]
# Move
cur_pos += n + skip_size
# Increase
skip_size += 1
return circle
def compute_dense_hash(sparse_hash: list[int]) -> list[int]:
assert len(sparse_hash) == 256 # Sanity check
return [
functools.reduce(operator.xor, chunk)
for chunk in itertools.batched(sparse_hash, 16)
]
lengths = [ord(c) for c in byte_string]
lengths += [17, 31, 73, 47, 23] # Additional lengths
sparse_hash = compute_sparse_hash(lengths)
dense_hash = compute_dense_hash(sparse_hash)
return "".join(f"{n:02x}" for n in dense_hash)
def count_regions(hashes: list[int]) -> int:
def occupied(row: int, bit: int) -> bool:
return (hashes[row] & 1 << bit) != 0
def key(row: int, bit: int) -> int:
return row * 128 + bit
def unkey(key: int) -> tuple[int, int]:
return key // 128, key % 128
uf = UnionFind(128 * 128)
for i in range(128):
for bit in range(128):
if not occupied(i, bit):
continue
for ni, nbit in (
(i - 1, bit),
(i, bit - 1),
(i + 1, bit),
(i, bit + 1),
):
if ni < 0 or ni >= 128:
continue
if nbit < 0 or nbit >= 128:
continue
if not occupied(ni, nbit):
continue
uf.union(key(i, bit), key(ni, nbit))
# We created a UnionFind over *all* squares, only count *occupied* squares
return sum(occupied(*unkey(root)) for root in uf.sets())
input = input.strip()
hashes = [int(knot_hash(f"{input}-{i}"), 16) for i in range(128)]
return count_regions(hashes)
def main() -> None:
input = sys.stdin.read()
print(solve(input))
if __name__ == "__main__":
main()