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2022: d17: ex2: add solution

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Bruno BELANYI 2022-12-17 12:52:34 +01:00
parent e509e6fd4b
commit e18d783d39
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2022/d17/ex2/ex2.py Executable file
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#!/usr/bin/env python
import enum
import itertools
import sys
from collections.abc import Iterator
from typing import NamedTuple
class Point(NamedTuple):
x: int
y: int
def __add__(self, other):
if not isinstance(other, Point):
return NotImplemented
return Point(self.x + other.x, self.y + other.y)
def __sub__(self, other):
if not isinstance(other, Point):
return NotImplemented
return Point(self.x - other.x, self.y - other.y)
def translate(points: set[Point], delta: Point) -> set[Point]:
return {p + delta for p in points}
class Rock(str, enum.Enum):
LINE = "####"
PLUS = ".#.\n###\n.#."
CORNER = "..#\n..#\n###"
VERTICAL_LINE = "#\n#\n#\n#"
SQUARE = "##\n##"
@classmethod
def stream(cls) -> Iterator["Rock"]:
yield from itertools.cycle(iter(cls))
def to_points(self) -> set[Point]:
res: set[Point] = set()
for y, line in enumerate(reversed(self.splitlines())):
for x, c in enumerate(line):
if c == ".":
continue
res.add(Point(x, y))
return res
class JetStream(str, enum.Enum):
LEFT = "<"
RIGHT = ">"
@classmethod
def stream(cls, jet_pattern: str) -> Iterator["JetStream"]:
yield from itertools.cycle(map(cls, jet_pattern))
def as_delta(self) -> Point:
if self == self.LEFT:
return Point(-1, 0)
if self == self.RIGHT:
return Point(1, 0)
assert False # Sanity check
def solve(input: list[str]) -> int:
fallen_stack: set[Point] = set()
max_height = 0
LEFT_WALL = -1
RIGHT_WALL = 7
FLOOR = 0
rocks = list(iter(Rock))
jet_stream = [JetStream(c) for c in input[0]]
t = 0
jet_index = 0
rock_index = 0
def step(rock: set[Point], jet: JetStream) -> tuple[set[Point], bool]:
# Check if it can be pushed by the jet, or if it hits an obstacle
pushed_rock = translate(rock, jet.as_delta())
if not (fallen_stack & pushed_rock) and all(
LEFT_WALL < p.x < RIGHT_WALL for p in pushed_rock
):
rock = pushed_rock
# Check if it can go down
fallen_rock = translate(rock, Point(0, -1))
if not (fallen_stack & fallen_rock) and all(p.y > FLOOR for p in fallen_rock):
return fallen_rock, True
return rock, False
def simulate_rock_fall() -> None:
nonlocal max_height
nonlocal jet_index
nonlocal rock_index
rock = rocks[rock_index].to_points()
# Align 2 units away from LEFT_WALL and 3 higher than
# current stack
rock = translate(rock, Point(2, max_height + 3 + 1))
while True:
rock, keep_going = step(rock, jet_stream[jet_index])
jet_index = (jet_index + 1) % len(jet_stream)
if not keep_going:
break
fallen_stack.update(rock)
max_height = max(max_height, max(p.y for p in rock))
rock_index = (rock_index + 1) % len(rocks)
StackStateHash = tuple[int, int, frozenset[Point]]
def stack_state_hash() -> StackStateHash:
top = frozenset(
Point(p.x, p.y - max_height)
for p in fallen_stack
if p.y >= (max_height - 50) # Cut-off point chosen arbitrarily...
)
return rock_index, jet_index, top
assert len(input) == 1 # Sanity check
cache: dict[StackStateHash, tuple[int, int]] = {}
added_height = 0
END_OF_SIMULATION = 1_000_000_000_000
while t < END_OF_SIMULATION:
simulate_rock_fall()
t += 1
stack_hash = stack_state_hash()
if stack_hash in cache:
previous_t, previous_height = cache[stack_hash]
cycle_length = t - previous_t
num_cycles = (END_OF_SIMULATION - t) // cycle_length
added_height += num_cycles * (max_height - previous_height)
t += num_cycles * cycle_length
else:
cache[stack_hash] = t, max_height
return max_height + added_height
def main() -> None:
input = sys.stdin.read().splitlines()
print(solve(input))
if __name__ == "__main__":
main()