Refactor code for API #3
16
poetry.lock
generated
16
poetry.lock
generated
@ -1245,6 +1245,20 @@ files = [
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docs = ["myst-parser", "pydata-sphinx-theme", "sphinx"]
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test = ["argcomplete (>=3.0.3)", "mypy (>=1.7.0)", "pre-commit", "pytest (>=7.0,<8.2)", "pytest-mock", "pytest-mypy-testing"]
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[[package]]
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name = "types-networkx"
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version = "3.4.2.20241115"
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description = "Typing stubs for networkx"
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optional = false
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python-versions = ">=3.8"
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files = [
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{file = "types-networkx-3.4.2.20241115.tar.gz", hash = "sha256:d669b650cf6c6c9ec879a825449eb04a5c10742f3109177e1683f57ee49e0f59"},
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{file = "types_networkx-3.4.2.20241115-py3-none-any.whl", hash = "sha256:f0c382924d6614e06bf0b1ca0b837b8f33faa58982bc086ea762efaf39aa98dd"},
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]
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[package.dependencies]
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numpy = ">=1.20"
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[[package]]
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name = "typing-extensions"
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version = "4.12.2"
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@ -1281,4 +1295,4 @@ files = [
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[metadata]
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lock-version = "2.0"
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python-versions = "^3.10"
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content-hash = "b643261f91a781d77735e05f6d2ac1002867600c2df6393a9d1a15f5e1189109"
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content-hash = "c91bc307ff4a5b3e8cd1976ebea211c9749fe09d563dd80861f70ce26826cda9"
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@ -23,6 +23,7 @@ ruff = "^0.8.1"
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poethepoet = "^0.31.1"
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ipykernel = "^6.29.5"
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networkx-stubs = "^0.0.1"
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types-networkx = "^3.4.2.20241115"
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[tool.poetry.scripts]
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holt59-aoc = "holt59.aoc.__main__:main"
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@ -1,37 +1,38 @@
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import os
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import sys
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from typing import Literal, cast
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from typing import Any, Iterator, Literal, cast
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VERBOSE = os.getenv("AOC_VERBOSE") == "True"
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from ..base import BaseSolver
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Symbol = Literal["|", "-", "L", "J", "7", "F", ".", "S"]
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lines: list[list[Symbol]] = [
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[cast(Symbol, symbol) for symbol in line] for line in sys.stdin.read().splitlines()
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]
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# find starting point
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si, sj = next(
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class Solver(BaseSolver):
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def solve(self, input: str) -> Iterator[Any]:
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lines: list[list[Symbol]] = [
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[cast(Symbol, symbol) for symbol in line] for line in input.splitlines()
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]
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# find starting point
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si, sj = next(
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(i, j)
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for i in range(len(lines))
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for j in range(len(lines[0]))
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if lines[i][j] == "S"
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)
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)
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# find one of the two outputs
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ni, nj = si, sj
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for ni, nj, chars in (
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# find one of the two outputs
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ni, nj = si, sj
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for ni, nj, chars in (
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(si - 1, sj, "|7F"),
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(si + 1, sj, "|LJ"),
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(si, sj - 1, "-LF"),
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(si, sj + 1, "-J7"),
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):
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):
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if lines[ni][nj] in chars:
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break
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# part 1 - find the loop (re-used in part 2)
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loop = [(si, sj), (ni, nj)]
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while True:
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# part 1 - find the loop (re-used in part 2)
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loop = [(si, sj), (ni, nj)]
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while True:
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pi, pj = loop[-2]
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i, j = loop[-1]
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@ -51,30 +52,29 @@ while True:
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loop.append((i, j))
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answer_1 = len(loop) // 2
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print(f"answer 1 is {answer_1}")
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yield len(loop) // 2
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# part 2
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# part 2
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# replace S by an appropriate character for the loop below
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di1, dj1 = loop[1][0] - loop[0][0], loop[1][1] - loop[0][1]
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di2, dj2 = loop[0][0] - loop[-1][0], loop[0][1] - loop[-1][1]
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mapping: dict[tuple[int, int], dict[tuple[int, int], Symbol]] = {
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# replace S by an appropriate character for the loop below
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di1, dj1 = loop[1][0] - loop[0][0], loop[1][1] - loop[0][1]
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di2, dj2 = loop[0][0] - loop[-1][0], loop[0][1] - loop[-1][1]
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mapping: dict[tuple[int, int], dict[tuple[int, int], Symbol]] = {
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(0, 1): {(0, 1): "-", (-1, 0): "F", (1, 0): "L"},
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(0, -1): {(0, -1): "-", (-1, 0): "7", (1, 0): "J"},
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(1, 0): {(1, 0): "|", (0, 1): "7", (0, -1): "F"},
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(-1, 0): {(-1, 0): "|", (0, -1): "L", (0, 1): "J"},
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}
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lines[si][sj] = mapping[di1, dj1][di2, dj2]
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}
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lines[si][sj] = mapping[di1, dj1][di2, dj2]
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# find the points inside the loop using an adaptation of ray casting for a discrete
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# grid (https://stackoverflow.com/a/218081/2666289)
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#
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# use a set for faster '... in loop' check
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#
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loop_s = set(loop)
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inside: set[tuple[int, int]] = set()
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for i in range(len(lines)):
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# find the points inside the loop using an adaptation of ray casting for a discrete
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# grid (https://stackoverflow.com/a/218081/2666289)
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#
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# use a set for faster '... in loop' check
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#
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loop_s = set(loop)
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inside: set[tuple[int, int]] = set()
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for i in range(len(lines)):
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cnt = 0
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for j in range(len(lines[0])):
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if (i, j) not in loop_s and cnt % 2 == 1:
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@ -83,18 +83,18 @@ for i in range(len(lines)):
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if (i, j) in loop_s and lines[i][j] in "|LJ":
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cnt += 1
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if VERBOSE:
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if self.verbose:
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for i in range(len(lines)):
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s = ""
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for j in range(len(lines[0])):
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if (i, j) == (si, sj):
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print("\033[91mS\033[0m", end="")
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s += "\033[91mS\033[0m"
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elif (i, j) in loop:
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print(lines[i][j], end="")
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s += lines[i][j]
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elif (i, j) in inside:
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print("\033[92mI\033[0m", end="")
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s += "\033[92mI\033[0m"
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else:
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print(".", end="")
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print()
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s += "."
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self.logger.info(s)
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answer_2 = len(inside)
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print(f"answer 2 is {answer_2}")
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yield len(inside)
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@ -1,18 +1,22 @@
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import sys
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from typing import Any, Iterator
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import numpy as np
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lines = sys.stdin.read().splitlines()
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data = np.array([[c == "#" for c in line] for line in lines])
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rows = {c for c in range(data.shape[0]) if not data[c, :].any()}
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columns = {c for c in range(data.shape[1]) if not data[:, c].any()}
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galaxies_y, galaxies_x = np.where(data) # type: ignore
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from ..base import BaseSolver
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def compute_total_distance(expansion: int) -> int:
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class Solver(BaseSolver):
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def solve(self, input: str) -> Iterator[Any]:
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lines = input.splitlines()
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data = np.array([[c == "#" for c in line] for line in lines])
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rows = {c for c in range(data.shape[0]) if not data[c, :].any()}
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columns = {c for c in range(data.shape[1]) if not data[:, c].any()}
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galaxies_y, galaxies_x = np.where(data) # type: ignore
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def compute_total_distance(expansion: int) -> int:
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distances: list[int] = []
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for g1 in range(len(galaxies_y)):
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x1, y1 = int(galaxies_x[g1]), int(galaxies_y[g1])
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@ -31,11 +35,8 @@ def compute_total_distance(expansion: int) -> int:
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distances.append(dx + dy)
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return sum(distances)
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# part 1
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yield compute_total_distance(2)
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# part 1
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answer_1 = compute_total_distance(2)
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print(f"answer 1 is {answer_1}")
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# part 2
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answer_2 = compute_total_distance(1000000)
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print(f"answer 2 is {answer_2}")
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# part 2
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yield compute_total_distance(1000000)
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@ -1,9 +1,7 @@
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import os
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import sys
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from functools import lru_cache
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from typing import Iterable
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from typing import Any, Iterable, Iterator
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VERBOSE = os.getenv("AOC_VERBOSE") == "True"
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from ..base import BaseSolver
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@lru_cache
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@ -77,31 +75,29 @@ def compute_possible_arrangements(
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)
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def compute_all_possible_arrangements(lines: Iterable[str], repeat: int) -> int:
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class Solver(BaseSolver):
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def compute_all_possible_arrangements(
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self, lines: Iterable[str], repeat: int
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) -> int:
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count = 0
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if VERBOSE:
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from tqdm import tqdm
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lines = tqdm(lines)
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for line in lines:
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for i_line, line in enumerate(lines):
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self.logger.info(f"processing line {i_line}: {line}...")
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parts = line.split(" ")
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count += compute_possible_arrangements(
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tuple(filter(len, "?".join(parts[0] for _ in range(repeat)).split("."))),
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tuple(
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filter(len, "?".join(parts[0] for _ in range(repeat)).split("."))
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),
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tuple(int(c) for c in parts[1].split(",")) * repeat,
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)
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return count
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def solve(self, input: str) -> Iterator[Any]:
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lines = input.splitlines()
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lines = sys.stdin.read().splitlines()
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# part 1
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yield self.compute_all_possible_arrangements(lines, 1)
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# part 1
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answer_1 = compute_all_possible_arrangements(lines, 1)
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print(f"answer 1 is {answer_1}")
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# part 2
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answer_2 = compute_all_possible_arrangements(lines, 5)
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print(f"answer 2 is {answer_2}")
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# part 2
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yield self.compute_all_possible_arrangements(lines, 5)
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@ -1,5 +1,6 @@
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import sys
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from typing import Callable, Literal
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from typing import Any, Callable, Iterator, Literal
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from ..base import BaseSolver
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def split(block: list[str], axis: Literal[0, 1], count: int) -> int:
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@ -25,19 +26,18 @@ def split(block: list[str], axis: Literal[0, 1], count: int) -> int:
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return 0
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blocks = [block.splitlines() for block in sys.stdin.read().split("\n\n")]
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class Solver(BaseSolver):
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def solve(self, input: str) -> Iterator[Any]:
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blocks = [block.splitlines() for block in input.split("\n\n")]
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# part 1
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answer_1 = sum(
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# part 1
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yield sum(
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split(block, axis=1, count=0) + 100 * split(block, axis=0, count=0)
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for block in blocks
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)
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print(f"answer 1 is {answer_1}")
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)
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# part 2
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answer_2 = sum(
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# part 2
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yield sum(
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split(block, axis=1, count=1) + 100 * split(block, axis=0, count=1)
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for block in blocks
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)
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print(f"answer 2 is {answer_2}")
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)
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@ -1,10 +1,9 @@
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import sys
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from typing import TypeAlias
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from typing import Any, Iterator, TypeAlias
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from ..base import BaseSolver
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RockGrid: TypeAlias = list[list[str]]
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rocks0 = [list(line) for line in sys.stdin.read().splitlines()]
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def slide_rocks_top(rocks: RockGrid) -> RockGrid:
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top = [0 if c == "." else 1 for c in rocks[0]]
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@ -34,21 +33,25 @@ def cycle(rocks: RockGrid) -> RockGrid:
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return rocks
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rocks = slide_rocks_top([[c for c in r] for r in rocks0])
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class Solver(BaseSolver):
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def solve(self, input: str) -> Iterator[Any]:
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rocks0 = [list(line) for line in input.splitlines()]
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# part 1
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answer_1 = sum(
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(len(rocks) - i) * sum(1 for c in row if c == "O") for i, row in enumerate(rocks)
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)
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print(f"answer 1 is {answer_1}")
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rocks = slide_rocks_top([[c for c in r] for r in rocks0])
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# part 2
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rocks = rocks0
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# part 1
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yield sum(
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(len(rocks) - i) * sum(1 for c in row if c == "O")
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for i, row in enumerate(rocks)
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)
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N = 1000000000
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cycles: list[RockGrid] = []
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i_cycle: int = -1
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for i_cycle in range(N):
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# part 2
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rocks = rocks0
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N = 1000000000
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cycles: list[RockGrid] = []
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i_cycle: int = -1
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for i_cycle in range(N):
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rocks = cycle(rocks)
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if any(rocks == c for c in cycles):
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@ -56,13 +59,12 @@ for i_cycle in range(N):
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cycles.append([[c for c in r] for r in rocks])
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cycle_start = next(i for i in range(len(cycles)) if (rocks == cycles[i]))
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cycle_length = i_cycle - cycle_start
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cycle_start = next(i for i in range(len(cycles)) if (rocks == cycles[i]))
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cycle_length = i_cycle - cycle_start
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ci = cycle_start + (N - cycle_start) % cycle_length - 1
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ci = cycle_start + (N - cycle_start) % cycle_length - 1
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answer_2 = sum(
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yield sum(
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(len(rocks) - i) * sum(1 for c in row if c == "O")
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for i, row in enumerate(cycles[ci])
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)
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print(f"answer 2 is {answer_2}")
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)
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|
@ -1,21 +1,24 @@
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import sys
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from functools import reduce
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from typing import Any, Iterator
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steps = sys.stdin.read().strip().split(",")
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from ..base import BaseSolver
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def _hash(s: str) -> int:
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return reduce(lambda v, u: ((v + ord(u)) * 17) % 256, s, 0)
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# part 1
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answer_1 = sum(map(_hash, steps))
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print(f"answer 1 is {answer_1}")
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class Solver(BaseSolver):
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def solve(self, input: str) -> Iterator[Any]:
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steps = input.split(",")
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# part 2
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boxes: list[dict[str, int]] = [{} for _ in range(256)]
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# part 1
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yield sum(map(_hash, steps))
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for step in steps:
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# part 2
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boxes: list[dict[str, int]] = [{} for _ in range(256)]
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for step in steps:
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if (i := step.find("=")) >= 0:
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label, length = step[:i], int(step[i + 1 :])
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boxes[_hash(label)][label] = length
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@ -23,9 +26,8 @@ for step in steps:
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label = step[:-1]
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boxes[_hash(label)].pop(label, None)
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answer_2 = sum(
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yield sum(
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i_box * i_lens * length
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for i_box, box in enumerate(boxes, start=1)
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for i_lens, length in enumerate(box.values(), start=1)
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)
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print(f"answer 2 is {answer_2}")
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)
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|
@ -1,8 +1,6 @@
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import os
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import sys
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from typing import Literal, TypeAlias, cast
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from typing import Any, Iterator, Literal, TypeAlias, cast
|
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VERBOSE = os.getenv("AOC_VERBOSE") == "True"
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from ..base import BaseSolver
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CellType: TypeAlias = Literal[".", "|", "-", "\\", "/"]
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Direction: TypeAlias = Literal["R", "L", "U", "D"]
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@ -78,33 +76,33 @@ def propagate(
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return beams
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layout: list[list[CellType]] = [
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[cast(CellType, col) for col in row] for row in sys.stdin.read().splitlines()
|
||||
]
|
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class Solver(BaseSolver):
|
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def solve(self, input: str) -> Iterator[Any]:
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layout: list[list[CellType]] = [
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[cast(CellType, col) for col in row] for row in input.splitlines()
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]
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beams = propagate(layout, (0, 0), "R")
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beams = propagate(layout, (0, 0), "R")
|
||||
if self.verbose:
|
||||
for row in beams:
|
||||
self.logger.info("".join("#" if col else "." for col in row))
|
||||
|
||||
if VERBOSE:
|
||||
print("\n".join(["".join("#" if col else "." for col in row) for row in beams]))
|
||||
# part 1
|
||||
yield sum(sum(map(bool, row)) for row in beams)
|
||||
|
||||
# part 1
|
||||
answer_1 = sum(sum(map(bool, row)) for row in beams)
|
||||
print(f"answer 1 is {answer_1}")
|
||||
# part 2
|
||||
n_rows, n_cols = len(layout), len(layout[0])
|
||||
cases: list[tuple[tuple[int, int], Direction]] = []
|
||||
|
||||
# part 2
|
||||
n_rows, n_cols = len(layout), len(layout[0])
|
||||
cases: list[tuple[tuple[int, int], Direction]] = []
|
||||
|
||||
for row in range(n_rows):
|
||||
for row in range(n_rows):
|
||||
cases.append(((row, 0), "R"))
|
||||
cases.append(((row, n_cols - 1), "L"))
|
||||
for col in range(n_cols):
|
||||
for col in range(n_cols):
|
||||
cases.append(((0, col), "D"))
|
||||
cases.append(((n_rows - 1, col), "U"))
|
||||
|
||||
answer_2 = max(
|
||||
yield max(
|
||||
sum(sum(map(bool, row)) for row in propagate(layout, start, direction))
|
||||
for start, direction in cases
|
||||
)
|
||||
print(f"answer 2 is {answer_2}")
|
||||
)
|
||||
|
@ -1,13 +1,11 @@
|
||||
from __future__ import annotations
|
||||
|
||||
import heapq
|
||||
import os
|
||||
import sys
|
||||
from collections import defaultdict
|
||||
from dataclasses import dataclass
|
||||
from typing import Literal, TypeAlias
|
||||
from typing import Any, Iterator, Literal, TypeAlias
|
||||
|
||||
VERBOSE = os.getenv("AOC_VERBOSE") == "True"
|
||||
from ..base import BaseSolver
|
||||
|
||||
Direction: TypeAlias = Literal[">", "<", "^", "v"]
|
||||
|
||||
@ -32,11 +30,13 @@ MAPPINGS: dict[Direction, tuple[int, int, Direction]] = {
|
||||
}
|
||||
|
||||
|
||||
def print_shortest_path(
|
||||
class Solver(BaseSolver):
|
||||
def print_shortest_path(
|
||||
self,
|
||||
grid: list[list[int]],
|
||||
target: tuple[int, int],
|
||||
per_cell: dict[tuple[int, int], list[tuple[Label, int]]],
|
||||
):
|
||||
):
|
||||
assert len(per_cell[target]) == 1
|
||||
label = per_cell[target][0][0]
|
||||
|
||||
@ -66,16 +66,18 @@ def print_shortest_path(
|
||||
if (r, c) != (prev_label.row, prev_label.col):
|
||||
p_grid[r][c] = f"\033[93m{grid[r][c]}\033[0m"
|
||||
|
||||
p_grid[label.row][label.col] = f"\033[91m{grid[label.row][label.col]}\033[0m"
|
||||
p_grid[label.row][label.col] = (
|
||||
f"\033[91m{grid[label.row][label.col]}\033[0m"
|
||||
)
|
||||
|
||||
prev_label = label
|
||||
|
||||
p_grid[0][0] = f"\033[92m{grid[0][0]}\033[0m"
|
||||
|
||||
print("\n".join("".join(row) for row in p_grid))
|
||||
for row in p_grid:
|
||||
self.logger.info("".join(row))
|
||||
|
||||
|
||||
def shortest_many_paths(grid: list[list[int]]) -> dict[tuple[int, int], int]:
|
||||
def shortest_many_paths(self, grid: list[list[int]]) -> dict[tuple[int, int], int]:
|
||||
n_rows, n_cols = len(grid), len(grid[0])
|
||||
|
||||
visited: dict[tuple[int, int], tuple[Label, int]] = {}
|
||||
@ -125,13 +127,13 @@ def shortest_many_paths(grid: list[list[int]]) -> dict[tuple[int, int], int]:
|
||||
|
||||
return {(r, c): visited[r, c][1] for r in range(n_rows) for c in range(n_cols)}
|
||||
|
||||
|
||||
def shortest_path(
|
||||
def shortest_path(
|
||||
self,
|
||||
grid: list[list[int]],
|
||||
min_straight: int,
|
||||
max_straight: int,
|
||||
lower_bounds: dict[tuple[int, int], int],
|
||||
) -> int:
|
||||
) -> int:
|
||||
n_rows, n_cols = len(grid), len(grid[0])
|
||||
|
||||
target = (len(grid) - 1, len(grid[0]) - 1)
|
||||
@ -215,19 +217,17 @@ def shortest_path(
|
||||
),
|
||||
)
|
||||
|
||||
if VERBOSE:
|
||||
print_shortest_path(grid, target, per_cell)
|
||||
if self.verbose:
|
||||
self.print_shortest_path(grid, target, per_cell)
|
||||
|
||||
return per_cell[target][0][1]
|
||||
|
||||
def solve(self, input: str) -> Iterator[Any]:
|
||||
data = [[int(c) for c in r] for r in input.splitlines()]
|
||||
estimates = self.shortest_many_paths(data)
|
||||
|
||||
data = [[int(c) for c in r] for r in sys.stdin.read().splitlines()]
|
||||
estimates = shortest_many_paths(data)
|
||||
# part 1
|
||||
yield self.shortest_path(data, 1, 3, lower_bounds=estimates)
|
||||
|
||||
# part 1
|
||||
answer_1 = shortest_path(data, 1, 3, lower_bounds=estimates)
|
||||
print(f"answer 1 is {answer_1}")
|
||||
|
||||
# part 2
|
||||
answer_2 = shortest_path(data, 4, 10, lower_bounds=estimates)
|
||||
print(f"answer 2 is {answer_2}")
|
||||
# part 2
|
||||
yield self.shortest_path(data, 4, 10, lower_bounds=estimates)
|
||||
|
@ -1,5 +1,6 @@
|
||||
import sys
|
||||
from typing import Literal, TypeAlias, cast
|
||||
from typing import Any, Iterator, Literal, TypeAlias, cast
|
||||
|
||||
from ..base import BaseSolver
|
||||
|
||||
Direction: TypeAlias = Literal["R", "L", "U", "D"]
|
||||
|
||||
@ -33,22 +34,23 @@ def polygon(values: list[tuple[Direction, int]]) -> tuple[list[tuple[int, int]],
|
||||
return corners, perimeter
|
||||
|
||||
|
||||
lines = sys.stdin.read().splitlines()
|
||||
class Solver(BaseSolver):
|
||||
def solve(self, input: str) -> Iterator[Any]:
|
||||
lines = input.splitlines()
|
||||
|
||||
# part 1
|
||||
yield area(
|
||||
*polygon(
|
||||
[(cast(Direction, (p := line.split())[0]), int(p[1])) for line in lines]
|
||||
)
|
||||
)
|
||||
|
||||
# part 1
|
||||
answer_1 = area(
|
||||
*polygon([(cast(Direction, (p := line.split())[0]), int(p[1])) for line in lines])
|
||||
)
|
||||
print(f"answer 1 is {answer_1}")
|
||||
|
||||
# part 2
|
||||
answer_2 = area(
|
||||
# part 2
|
||||
yield area(
|
||||
*polygon(
|
||||
[
|
||||
(DIRECTIONS[int((h := line.split()[-1])[-2])], int(h[2:-2], 16))
|
||||
for line in lines
|
||||
]
|
||||
)
|
||||
)
|
||||
print(f"answer 2 is {answer_2}")
|
||||
)
|
||||
|
@ -1,13 +1,8 @@
|
||||
import logging
|
||||
import operator
|
||||
import os
|
||||
import sys
|
||||
from math import prod
|
||||
from typing import Literal, TypeAlias, cast
|
||||
from typing import Any, Iterator, Literal, TypeAlias, cast
|
||||
|
||||
VERBOSE = os.getenv("AOC_VERBOSE") == "True"
|
||||
|
||||
logging.basicConfig(level=logging.INFO if VERBOSE else logging.WARNING)
|
||||
from ..base import BaseSolver
|
||||
|
||||
Category: TypeAlias = Literal["x", "m", "a", "s"]
|
||||
Part: TypeAlias = dict[Category, int]
|
||||
@ -22,7 +17,8 @@ Check: TypeAlias = tuple[Category, Literal["<", ">"], int] | None
|
||||
Workflow: TypeAlias = list[tuple[Check, str]]
|
||||
|
||||
|
||||
def accept(workflows: dict[str, Workflow], part: Part) -> bool:
|
||||
class Solver(BaseSolver):
|
||||
def accept(self, workflows: dict[str, Workflow], part: Part) -> bool:
|
||||
workflow = "in"
|
||||
decision: bool | None = None
|
||||
|
||||
@ -42,8 +38,7 @@ def accept(workflows: dict[str, Workflow], part: Part) -> bool:
|
||||
|
||||
return decision
|
||||
|
||||
|
||||
def propagate(workflows: dict[str, Workflow], start: PartWithBounds) -> int:
|
||||
def propagate(self, workflows: dict[str, Workflow], start: PartWithBounds) -> int:
|
||||
def _fmt(meta: PartWithBounds) -> str:
|
||||
return "{" + ", ".join(f"{k}={v}" for k, v in meta.items()) + "}"
|
||||
|
||||
@ -52,13 +47,13 @@ def propagate(workflows: dict[str, Workflow], start: PartWithBounds) -> int:
|
||||
) -> int:
|
||||
count = 0
|
||||
if target in workflows:
|
||||
logging.info(f" transfer to {target}")
|
||||
self.logger.info(f" transfer to {target}")
|
||||
queue.append((meta, target))
|
||||
elif target == "A":
|
||||
count = prod((high - low + 1) for low, high in meta.values())
|
||||
logging.info(f" accepted ({count})")
|
||||
self.logger.info(f" accepted ({count})")
|
||||
else:
|
||||
logging.info(" rejected")
|
||||
self.logger.info(" rejected")
|
||||
return count
|
||||
|
||||
accepted = 0
|
||||
@ -69,24 +64,26 @@ def propagate(workflows: dict[str, Workflow], start: PartWithBounds) -> int:
|
||||
while queue:
|
||||
n_iterations += 1
|
||||
meta, workflow = queue.pop()
|
||||
logging.info(f"{workflow}: {_fmt(meta)}")
|
||||
self.logger.info(f"{workflow}: {_fmt(meta)}")
|
||||
for check, target in workflows[workflow]:
|
||||
if check is None:
|
||||
logging.info(" end-of-workflow")
|
||||
self.logger.info(" end-of-workflow")
|
||||
accepted += transfer_or_accept(target, meta, queue)
|
||||
continue
|
||||
|
||||
category, sense, value = check
|
||||
bounds, op = meta[category], OPERATORS[sense]
|
||||
|
||||
logging.info(f" checking {_fmt(meta)} against {category} {sense} {value}")
|
||||
self.logger.info(
|
||||
f" checking {_fmt(meta)} against {category} {sense} {value}"
|
||||
)
|
||||
|
||||
if not op(bounds[0], value) and not op(bounds[1], value):
|
||||
logging.info(" reject, always false")
|
||||
self.logger.info(" reject, always false")
|
||||
continue
|
||||
|
||||
if op(meta[category][0], value) and op(meta[category][1], value):
|
||||
logging.info(" accept, always true")
|
||||
self.logger.info(" accept, always true")
|
||||
accepted += transfer_or_accept(target, meta, queue)
|
||||
break
|
||||
|
||||
@ -96,18 +93,18 @@ def propagate(workflows: dict[str, Workflow], start: PartWithBounds) -> int:
|
||||
meta[category], meta2[category] = (value, high), (low, value - 1)
|
||||
else:
|
||||
meta[category], meta2[category] = (low, value), (value + 1, high)
|
||||
logging.info(f" split {_fmt(meta2)} ({target}), {_fmt(meta)}")
|
||||
self.logger.info(f" split {_fmt(meta2)} ({target}), {_fmt(meta)}")
|
||||
|
||||
accepted += transfer_or_accept(target, meta2, queue)
|
||||
|
||||
logging.info(f"run took {n_iterations} iterations")
|
||||
self.logger.info(f"run took {n_iterations} iterations")
|
||||
return accepted
|
||||
|
||||
def solve(self, input: str) -> Iterator[Any]:
|
||||
workflows_s, parts_s = input.split("\n\n")
|
||||
|
||||
workflows_s, parts_s = sys.stdin.read().strip().split("\n\n")
|
||||
|
||||
workflows: dict[str, Workflow] = {}
|
||||
for workflow_s in workflows_s.split("\n"):
|
||||
workflows: dict[str, Workflow] = {}
|
||||
for workflow_s in workflows_s.split("\n"):
|
||||
name, block_s = workflow_s.split("{")
|
||||
workflows[name] = []
|
||||
|
||||
@ -124,17 +121,14 @@ for workflow_s in workflows_s.split("\n"):
|
||||
check, target = None, block
|
||||
workflows[name].append((check, target))
|
||||
|
||||
# part 1
|
||||
parts: list[Part] = [
|
||||
# part 1
|
||||
parts: list[Part] = [
|
||||
{cast(Category, s[0]): int(s[2:]) for s in part_s[1:-1].split(",")}
|
||||
for part_s in parts_s.split("\n")
|
||||
]
|
||||
answer_1 = sum(sum(part.values()) for part in parts if accept(workflows, part))
|
||||
print(f"answer 1 is {answer_1}")
|
||||
]
|
||||
yield sum(sum(part.values()) for part in parts if self.accept(workflows, part))
|
||||
|
||||
|
||||
# part 2
|
||||
answer_2 = propagate(
|
||||
# part 2
|
||||
yield self.propagate(
|
||||
workflows, {cast(Category, c): (1, 4000) for c in ["x", "m", "a", "s"]}
|
||||
)
|
||||
print(f"answer 2 is {answer_2}")
|
||||
)
|
||||
|
@ -1,55 +1,42 @@
|
||||
import logging
|
||||
import os
|
||||
import sys
|
||||
from collections import defaultdict
|
||||
from math import lcm
|
||||
from typing import Literal, TypeAlias
|
||||
|
||||
VERBOSE = os.getenv("AOC_VERBOSE") == "True"
|
||||
logging.basicConfig(level=logging.INFO if VERBOSE else logging.WARNING)
|
||||
from typing import Any, Iterator, Literal, TypeAlias
|
||||
|
||||
from ..base import BaseSolver
|
||||
|
||||
ModuleType: TypeAlias = Literal["broadcaster", "conjunction", "flip-flop"]
|
||||
PulseType: TypeAlias = Literal["high", "low"]
|
||||
|
||||
modules: dict[str, tuple[ModuleType, list[str]]] = {}
|
||||
|
||||
lines = sys.stdin.read().splitlines()
|
||||
class Solver(BaseSolver):
|
||||
_modules: dict[str, tuple[ModuleType, list[str]]]
|
||||
|
||||
for line in lines:
|
||||
name, outputs_s = line.split(" -> ")
|
||||
outputs = outputs_s.split(", ")
|
||||
if name == "broadcaster":
|
||||
modules["broadcaster"] = ("broadcaster", outputs)
|
||||
else:
|
||||
modules[name[1:]] = (
|
||||
"conjunction" if name.startswith("&") else "flip-flop",
|
||||
outputs,
|
||||
)
|
||||
|
||||
|
||||
def process(
|
||||
def _process(
|
||||
self,
|
||||
start: tuple[str, str, PulseType],
|
||||
flip_flop_states: dict[str, Literal["on", "off"]],
|
||||
conjunction_states: dict[str, dict[str, PulseType]],
|
||||
) -> tuple[dict[PulseType, int], dict[str, dict[PulseType, int]]]:
|
||||
) -> tuple[dict[PulseType, int], dict[str, dict[PulseType, int]]]:
|
||||
pulses: list[tuple[str, str, PulseType]] = [start]
|
||||
counts: dict[PulseType, int] = {"low": 0, "high": 0}
|
||||
inputs: dict[str, dict[PulseType, int]] = defaultdict(lambda: {"low": 0, "high": 0})
|
||||
inputs: dict[str, dict[PulseType, int]] = defaultdict(
|
||||
lambda: {"low": 0, "high": 0}
|
||||
)
|
||||
|
||||
logging.info("starting process... ")
|
||||
self.logger.info("starting process... ")
|
||||
|
||||
while pulses:
|
||||
input, name, pulse = pulses.pop(0)
|
||||
logging.info(f"{input} -{pulse}-> {name}")
|
||||
self.logger.info(f"{input} -{pulse}-> {name}")
|
||||
counts[pulse] += 1
|
||||
|
||||
inputs[name][pulse] += 1
|
||||
|
||||
if name not in modules:
|
||||
if name not in self._modules:
|
||||
continue
|
||||
|
||||
type, outputs = modules[name]
|
||||
type, outputs = self._modules[name]
|
||||
|
||||
if type == "broadcaster":
|
||||
...
|
||||
@ -77,11 +64,27 @@ def process(
|
||||
|
||||
return counts, inputs
|
||||
|
||||
def solve(self, input: str) -> Iterator[Any]:
|
||||
self._modules = {}
|
||||
|
||||
with open("./day20.dot", "w") as fp:
|
||||
lines = sys.stdin.read().splitlines()
|
||||
|
||||
for line in lines:
|
||||
name, outputs_s = line.split(" -> ")
|
||||
outputs = outputs_s.split(", ")
|
||||
if name == "broadcaster":
|
||||
self._modules["broadcaster"] = ("broadcaster", outputs)
|
||||
else:
|
||||
self._modules[name[1:]] = (
|
||||
"conjunction" if name.startswith("&") else "flip-flop",
|
||||
outputs,
|
||||
)
|
||||
|
||||
if self.outputs:
|
||||
with open("./day20.dot", "w") as fp:
|
||||
fp.write("digraph G {\n")
|
||||
fp.write("rx [shape=circle, color=red, style=filled];\n")
|
||||
for name, (type, outputs) in modules.items():
|
||||
for name, (type, outputs) in self._modules.items():
|
||||
if type == "conjunction":
|
||||
shape = "diamond"
|
||||
elif type == "flip-flop":
|
||||
@ -89,58 +92,67 @@ with open("./day20.dot", "w") as fp:
|
||||
else:
|
||||
shape = "circle"
|
||||
fp.write(f"{name} [shape={shape}];\n")
|
||||
for name, (type, outputs) in modules.items():
|
||||
for name, (type, outputs) in self._modules.items():
|
||||
for output in outputs:
|
||||
fp.write(f"{name} -> {output};\n")
|
||||
fp.write("}\n")
|
||||
|
||||
# part 1
|
||||
flip_flop_states: dict[str, Literal["on", "off"]] = {
|
||||
name: "off" for name, (type, _) in modules.items() if type == "flip-flop"
|
||||
}
|
||||
conjunction_states: dict[str, dict[str, PulseType]] = {
|
||||
name: {input: "low" for input, (_, outputs) in modules.items() if name in outputs}
|
||||
for name, (type, _) in modules.items()
|
||||
# part 1
|
||||
flip_flop_states: dict[str, Literal["on", "off"]] = {
|
||||
name: "off"
|
||||
for name, (type, _) in self._modules.items()
|
||||
if type == "flip-flop"
|
||||
}
|
||||
conjunction_states: dict[str, dict[str, PulseType]] = {
|
||||
name: {
|
||||
input: "low"
|
||||
for input, (_, outputs) in self._modules.items()
|
||||
if name in outputs
|
||||
}
|
||||
for name, (type, _) in self._modules.items()
|
||||
if type == "conjunction"
|
||||
}
|
||||
counts: dict[PulseType, int] = {"low": 0, "high": 0}
|
||||
for _ in range(1000):
|
||||
result, _ = process(
|
||||
}
|
||||
counts: dict[PulseType, int] = {"low": 0, "high": 0}
|
||||
for _ in range(1000):
|
||||
result, _ = self._process(
|
||||
("button", "broadcaster", "low"), flip_flop_states, conjunction_states
|
||||
)
|
||||
for pulse in ("low", "high"):
|
||||
counts[pulse] += result[pulse]
|
||||
answer_1 = counts["low"] * counts["high"]
|
||||
print(f"answer 1 is {answer_1}")
|
||||
yield counts["low"] * counts["high"]
|
||||
|
||||
# part 2
|
||||
# part 2
|
||||
|
||||
# reset states
|
||||
for name in flip_flop_states:
|
||||
# reset states
|
||||
for name in flip_flop_states:
|
||||
flip_flop_states[name] = "off"
|
||||
|
||||
for name in conjunction_states:
|
||||
for name in conjunction_states:
|
||||
for input in conjunction_states[name]:
|
||||
conjunction_states[name][input] = "low"
|
||||
|
||||
# find the conjunction connected to rx
|
||||
to_rx = [name for name, (_, outputs) in modules.items() if "rx" in outputs]
|
||||
assert len(to_rx) == 1, "cannot handle multiple module inputs for rx"
|
||||
assert (
|
||||
modules[to_rx[0]][0] == "conjunction"
|
||||
), "can only handle conjunction as input to rx"
|
||||
# find the conjunction connected to rx
|
||||
to_rx = [
|
||||
name for name, (_, outputs) in self._modules.items() if "rx" in outputs
|
||||
]
|
||||
assert len(to_rx) == 1, "cannot handle multiple module inputs for rx"
|
||||
assert (
|
||||
self._modules[to_rx[0]][0] == "conjunction"
|
||||
), "can only handle conjunction as input to rx"
|
||||
|
||||
to_rx_inputs = [name for name, (_, outputs) in modules.items() if to_rx[0] in outputs]
|
||||
assert all(
|
||||
modules[i][0] == "conjunction" and len(modules[i][1]) == 1 for i in to_rx_inputs
|
||||
), "can only handle inversion as second-order inputs to rx"
|
||||
to_rx_inputs = [
|
||||
name for name, (_, outputs) in self._modules.items() if to_rx[0] in outputs
|
||||
]
|
||||
assert all(
|
||||
self._modules[i][0] == "conjunction" and len(self._modules[i][1]) == 1
|
||||
for i in to_rx_inputs
|
||||
), "can only handle inversion as second-order inputs to rx"
|
||||
|
||||
|
||||
count = 1
|
||||
cycles: dict[str, int] = {}
|
||||
second: dict[str, int] = {}
|
||||
while len(second) != len(to_rx_inputs):
|
||||
_, inputs = process(
|
||||
count = 1
|
||||
cycles: dict[str, int] = {}
|
||||
second: dict[str, int] = {}
|
||||
while len(second) != len(to_rx_inputs):
|
||||
_, inputs = self._process(
|
||||
("button", "broadcaster", "low"), flip_flop_states, conjunction_states
|
||||
)
|
||||
|
||||
@ -153,9 +165,8 @@ while len(second) != len(to_rx_inputs):
|
||||
|
||||
count += 1
|
||||
|
||||
assert all(
|
||||
assert all(
|
||||
second[k] == cycles[k] * 2 for k in to_rx_inputs
|
||||
), "cannot only handle cycles starting at the beginning"
|
||||
), "cannot only handle cycles starting at the beginning"
|
||||
|
||||
answer_2 = lcm(*cycles.values())
|
||||
print(f"answer 2 is {answer_2}")
|
||||
yield lcm(*cycles.values())
|
||||
|
@ -1,9 +1,6 @@
|
||||
import logging
|
||||
import os
|
||||
import sys
|
||||
from typing import Any, Iterator
|
||||
|
||||
VERBOSE = os.getenv("AOC_VERBOSE") == "True"
|
||||
logging.basicConfig(level=logging.INFO if VERBOSE else logging.WARNING)
|
||||
from ..base import BaseSolver
|
||||
|
||||
|
||||
def reachable(
|
||||
@ -21,35 +18,39 @@ def reachable(
|
||||
return tiles
|
||||
|
||||
|
||||
map = sys.stdin.read().splitlines()
|
||||
start = next(
|
||||
(i, j) for i in range(len(map)) for j in range(len(map[i])) if map[i][j] == "S"
|
||||
)
|
||||
class Solver(BaseSolver):
|
||||
def solve(self, input: str) -> Iterator[Any]:
|
||||
map = input.splitlines()
|
||||
start = next(
|
||||
(i, j)
|
||||
for i in range(len(map))
|
||||
for j in range(len(map[i]))
|
||||
if map[i][j] == "S"
|
||||
)
|
||||
|
||||
# part 1
|
||||
answer_1 = len(reachable(map, {start}, 6 if len(map) < 20 else 64))
|
||||
print(f"answer 1 is {answer_1}")
|
||||
# part 1
|
||||
yield len(reachable(map, {start}, 6 if len(map) < 20 else 64))
|
||||
|
||||
# part 2
|
||||
# part 2
|
||||
|
||||
# the initial map is a square and contains an empty rhombus whose diameter is the size
|
||||
# of the map, and has only empty cells around the middle row and column
|
||||
#
|
||||
# after ~n/2 steps, the first map is filled with a rhombus, after that we get a bigger
|
||||
# rhombus every n steps
|
||||
#
|
||||
# we are going to find the number of cells reached for the initial rhombus, n steps
|
||||
# after and n * 2 steps after
|
||||
#
|
||||
cycle = len(map)
|
||||
rhombus = (len(map) - 3) // 2 + 1
|
||||
# the initial map is a square and contains an empty rhombus whose diameter is
|
||||
# the size of the map, and has only empty cells around the middle row and column
|
||||
#
|
||||
# after ~n/2 steps, the first map is filled with a rhombus, after that we get a
|
||||
# bigger rhombus every n steps
|
||||
#
|
||||
# we are going to find the number of cells reached for the initial rhombus, n
|
||||
# steps after and n * 2 steps after
|
||||
#
|
||||
cycle = len(map)
|
||||
rhombus = (len(map) - 3) // 2 + 1
|
||||
|
||||
values: list[int] = []
|
||||
values.append(len(tiles := reachable(map, {start}, rhombus)))
|
||||
values.append(len(tiles := reachable(map, tiles, cycle)))
|
||||
values.append(len(tiles := reachable(map, tiles, cycle)))
|
||||
values: list[int] = []
|
||||
values.append(len(tiles := reachable(map, {start}, rhombus)))
|
||||
values.append(len(tiles := reachable(map, tiles, cycle)))
|
||||
values.append(len(tiles := reachable(map, tiles, cycle)))
|
||||
|
||||
if logging.root.getEffectiveLevel() == logging.INFO:
|
||||
if self.verbose:
|
||||
n_rows, n_cols = len(map), len(map[0])
|
||||
|
||||
rows = [
|
||||
@ -65,42 +66,42 @@ if logging.root.getEffectiveLevel() == logging.INFO:
|
||||
if (i // cycle) % 2 == (j // cycle) % 2:
|
||||
rows[i][j] = f"\033[91m{rows[i][j]}\033[0m"
|
||||
|
||||
print("\n".join("".join(row) for row in rows))
|
||||
for row in rows:
|
||||
self.logger.info("".join(row))
|
||||
|
||||
self.logger.info(f"values to fit: {values}")
|
||||
|
||||
logging.info(f"values to fit: {values}")
|
||||
# version 1:
|
||||
#
|
||||
# after 3 cycles, the figure looks like the following:
|
||||
#
|
||||
# I M D
|
||||
# I J A K D
|
||||
# H A F A L
|
||||
# C E A K B
|
||||
# C G B
|
||||
#
|
||||
# after 4 cycles, the figure looks like the following:
|
||||
#
|
||||
# I M D
|
||||
# I J A K D
|
||||
# I J A B A K D
|
||||
# H A B A B A L
|
||||
# C E A B A N F
|
||||
# C E A N F
|
||||
# C G F
|
||||
#
|
||||
# the 'radius' of the rhombus is the number of cycles minus 1
|
||||
#
|
||||
# the 4 'corner' (M, H, L, G) are counted once, the blocks with a corner triangle (D, I,
|
||||
# C, B) are each counted radius times, the blocks with everything but one corner (J, K,
|
||||
# E, N) are each counted radius - 1 times
|
||||
#
|
||||
# there are two versions of the whole block, A and B in the above (or odd and even),
|
||||
# depending on the number of cycles, either A or B will be in the center
|
||||
#
|
||||
|
||||
# version 1:
|
||||
#
|
||||
# after 3 cycles, the figure looks like the following:
|
||||
#
|
||||
# I M D
|
||||
# I J A K D
|
||||
# H A F A L
|
||||
# C E A K B
|
||||
# C G B
|
||||
#
|
||||
# after 4 cycles, the figure looks like the following:
|
||||
#
|
||||
# I M D
|
||||
# I J A K D
|
||||
# I J A B A K D
|
||||
# H A B A B A L
|
||||
# C E A B A N F
|
||||
# C E A N F
|
||||
# C G F
|
||||
#
|
||||
# the 'radius' of the rhombus is the number of cycles minus 1
|
||||
#
|
||||
# the 4 'corner' (M, H, L, G) are counted once, the blocks with a corner triangle (D, I,
|
||||
# C, B) are each counted radius times, the blocks with everything but one corner (J, K,
|
||||
# E, N) are each counted radius - 1 times
|
||||
#
|
||||
# there are two versions of the whole block, A and B in the above (or odd and even),
|
||||
# depending on the number of cycles, either A or B will be in the center
|
||||
#
|
||||
|
||||
counts = [
|
||||
counts = [
|
||||
[
|
||||
sum(
|
||||
(i, j) in tiles
|
||||
@ -110,40 +111,40 @@ counts = [
|
||||
for cj in range(-2, 3)
|
||||
]
|
||||
for ci in range(-2, 3)
|
||||
]
|
||||
]
|
||||
|
||||
radius = (26501365 - rhombus) // cycle - 1
|
||||
A = counts[2][2] if radius % 2 == 0 else counts[2][1]
|
||||
B = counts[2][2] if radius % 2 == 1 else counts[2][1]
|
||||
answer_2 = (
|
||||
radius = (26501365 - rhombus) // cycle - 1
|
||||
A = counts[2][2] if radius % 2 == 0 else counts[2][1]
|
||||
B = counts[2][2] if radius % 2 == 1 else counts[2][1]
|
||||
answer_2 = (
|
||||
(radius + 1) * A
|
||||
+ radius * B
|
||||
+ 2 * radius * (radius + 1) // 2 * A
|
||||
+ 2 * radius * (radius - 1) // 2 * B
|
||||
+ sum(counts[i][j] for i, j in ((0, 2), (-1, 2), (2, 0), (2, -1)))
|
||||
+ sum(counts[i][j] for i, j in ((0, 1), (0, 3), (-1, 1), (-1, 3))) * (radius + 1)
|
||||
+ sum(counts[i][j] for i, j in ((0, 1), (0, 3), (-1, 1), (-1, 3)))
|
||||
* (radius + 1)
|
||||
+ sum(counts[i][j] for i, j in ((1, 1), (1, 3), (-2, 1), (-2, 3))) * radius
|
||||
)
|
||||
print(f"answer 2 (v1) is {answer_2}")
|
||||
)
|
||||
print(f"answer 2 (v1) is {answer_2}")
|
||||
|
||||
# version 2: fitting a polynomial
|
||||
#
|
||||
# the value we are interested in (26501365) can be written as R + K * C where R is the
|
||||
# step at which we find the first rhombus, and K the repeat step, so instead of fitting
|
||||
# for X values (R, R + K, R + 2 K), we are going to fit for (0, 1, 2), giving us much
|
||||
# simpler equation for the a, b and c coefficient
|
||||
#
|
||||
# we get:
|
||||
# - (a * 0² + b * 0 + c) = y1 => c = y1
|
||||
# - (a * 1² + b * 1 + c) = y2 => a + b = y2 - y1
|
||||
# => b = y2 - y1 - a
|
||||
# - (a * 2² + b * 2 + c) = y3 => 4a + 2b = y3 - y1
|
||||
# => 4a + 2(y2 - y1 - a) = y3 - y1
|
||||
# => a = (y1 + y3) / 2 - y2
|
||||
#
|
||||
y1, y2, y3 = values
|
||||
a, b, c = (y1 + y3) // 2 - y2, 2 * y2 - (3 * y1 + y3) // 2, y1
|
||||
# version 2: fitting a polynomial
|
||||
#
|
||||
# the value we are interested in (26501365) can be written as R + K * C where R is the
|
||||
# step at which we find the first rhombus, and K the repeat step, so instead of fitting
|
||||
# for X values (R, R + K, R + 2 K), we are going to fit for (0, 1, 2), giving us much
|
||||
# simpler equation for the a, b and c coefficient
|
||||
#
|
||||
# we get:
|
||||
# - (a * 0² + b * 0 + c) = y1 => c = y1
|
||||
# - (a * 1² + b * 1 + c) = y2 => a + b = y2 - y1
|
||||
# => b = y2 - y1 - a
|
||||
# - (a * 2² + b * 2 + c) = y3 => 4a + 2b = y3 - y1
|
||||
# => 4a + 2(y2 - y1 - a) = y3 - y1
|
||||
# => a = (y1 + y3) / 2 - y2
|
||||
#
|
||||
y1, y2, y3 = values
|
||||
a, b, c = (y1 + y3) // 2 - y2, 2 * y2 - (3 * y1 + y3) // 2, y1
|
||||
|
||||
n = (26501365 - rhombus) // cycle
|
||||
answer_2 = a * n * n + b * n + c
|
||||
print(f"answer 2 (v2) is {answer_2}")
|
||||
n = (26501365 - rhombus) // cycle
|
||||
yield a * n * n + b * n + c
|
||||
|
@ -1,26 +1,23 @@
|
||||
import itertools
|
||||
import logging
|
||||
import os
|
||||
import string
|
||||
import sys
|
||||
from collections import defaultdict
|
||||
from typing import Any, Iterator
|
||||
|
||||
VERBOSE = os.getenv("AOC_VERBOSE") == "True"
|
||||
logging.basicConfig(level=logging.INFO if VERBOSE else logging.WARNING)
|
||||
from ..base import BaseSolver
|
||||
|
||||
|
||||
lines = sys.stdin.read().splitlines()
|
||||
class Solver(BaseSolver):
|
||||
def solve(self, input: str) -> Iterator[Any]:
|
||||
lines = input.splitlines()
|
||||
|
||||
|
||||
def _name(i: int) -> str:
|
||||
def _name(i: int) -> str:
|
||||
if len(lines) < 26:
|
||||
return string.ascii_uppercase[i]
|
||||
return f"B{i:04d}"
|
||||
|
||||
|
||||
def build_supports(
|
||||
def build_supports(
|
||||
bricks: list[tuple[tuple[int, int, int], tuple[int, int, int]]],
|
||||
) -> tuple[dict[int, set[int]], dict[int, set[int]]]:
|
||||
) -> tuple[dict[int, set[int]], dict[int, set[int]]]:
|
||||
# 1. compute locations where a brick of sand will land after falling by processing
|
||||
# them in sorted order of bottom z location
|
||||
levels: dict[tuple[int, int, int], int] = defaultdict(lambda: -1)
|
||||
@ -42,7 +39,9 @@ def build_supports(
|
||||
|
||||
# 2. compute the bricks that supports any brick
|
||||
supported_by: dict[int, set[int]] = {}
|
||||
supports: dict[int, set[int]] = {i_brick: set() for i_brick in range(len(bricks))}
|
||||
supports: dict[int, set[int]] = {
|
||||
i_brick: set() for i_brick in range(len(bricks))
|
||||
}
|
||||
for i_brick, ((sx, sy, sz), (ex, ey, ez)) in enumerate(bricks):
|
||||
name = _name(i_brick)
|
||||
|
||||
@ -51,7 +50,7 @@ def build_supports(
|
||||
for x, y in itertools.product(range(sx, ex + 1), range(sy, ey + 1))
|
||||
if (v := levels[x, y, sz - 1]) != -1
|
||||
}
|
||||
logging.info(
|
||||
self.logger.info(
|
||||
f"{name} supported by {', '.join(map(_name, supported_by[i_brick]))}"
|
||||
)
|
||||
|
||||
@ -60,9 +59,8 @@ def build_supports(
|
||||
|
||||
return supported_by, supports
|
||||
|
||||
|
||||
bricks: list[tuple[tuple[int, int, int], tuple[int, int, int]]] = []
|
||||
for line in lines:
|
||||
bricks: list[tuple[tuple[int, int, int], tuple[int, int, int]]] = []
|
||||
for line in lines:
|
||||
bricks.append(
|
||||
(
|
||||
tuple(int(c) for c in line.split("~")[0].split(",")), # type: ignore
|
||||
@ -70,20 +68,19 @@ for line in lines:
|
||||
)
|
||||
)
|
||||
|
||||
# sort bricks by bottom z position to compute supports
|
||||
bricks = sorted(bricks, key=lambda b: b[0][-1])
|
||||
supported_by, supports = build_supports(bricks)
|
||||
# sort bricks by bottom z position to compute supports
|
||||
bricks = sorted(bricks, key=lambda b: b[0][-1])
|
||||
supported_by, supports = build_supports(bricks)
|
||||
|
||||
# part 1
|
||||
answer_1 = len(bricks) - sum(
|
||||
# part 1
|
||||
yield len(bricks) - sum(
|
||||
any(len(supported_by[supported]) == 1 for supported in supports_to)
|
||||
for supports_to in supports.values()
|
||||
)
|
||||
print(f"answer 1 is {answer_1}")
|
||||
)
|
||||
|
||||
# part 2
|
||||
falling_in_chain: dict[int, set[int]] = {}
|
||||
for i_brick in range(len(bricks)):
|
||||
# part 2
|
||||
falling_in_chain: dict[int, set[int]] = {}
|
||||
for i_brick in range(len(bricks)):
|
||||
to_disintegrate: set[int] = {
|
||||
supported
|
||||
for supported in supports[i_brick]
|
||||
@ -100,12 +97,13 @@ for i_brick in range(len(bricks)):
|
||||
|
||||
for d_brick in to_disintegrate:
|
||||
for supported in supports[d_brick]:
|
||||
supported_by_copy[supported] = supported_by_copy[supported] - {d_brick}
|
||||
supported_by_copy[supported] = supported_by_copy[supported] - {
|
||||
d_brick
|
||||
}
|
||||
|
||||
if not supported_by_copy[supported]:
|
||||
to_disintegrate_v.add(supported)
|
||||
|
||||
to_disintegrate = to_disintegrate_v
|
||||
|
||||
answer_2 = sum(len(falling) for falling in falling_in_chain.values())
|
||||
print(f"answer 2 is {answer_2}")
|
||||
yield sum(len(falling) for falling in falling_in_chain.values())
|
||||
|
@ -1,11 +1,7 @@
|
||||
import logging
|
||||
import os
|
||||
import sys
|
||||
from collections import defaultdict
|
||||
from typing import Literal, Sequence, TypeAlias, cast
|
||||
from typing import Any, Iterator, Literal, Sequence, TypeAlias, cast
|
||||
|
||||
VERBOSE = os.getenv("AOC_VERBOSE") == "True"
|
||||
logging.basicConfig(level=logging.INFO if VERBOSE else logging.WARNING)
|
||||
from ..base import BaseSolver
|
||||
|
||||
DirectionType: TypeAlias = Literal[">", "<", "^", "v", ".", "#"]
|
||||
|
||||
@ -35,6 +31,7 @@ def neighbors(
|
||||
Compute neighbors of the given node, ignoring the given set of nodes and considering
|
||||
that you can go uphill on slopes.
|
||||
"""
|
||||
n_rows, n_cols = len(grid), len(grid[0])
|
||||
i, j = node
|
||||
|
||||
for di, dj in Neighbors[grid[i][j]]:
|
||||
@ -103,11 +100,13 @@ def compute_direct_links(
|
||||
return direct
|
||||
|
||||
|
||||
def longest_path_length(
|
||||
class Solver(BaseSolver):
|
||||
def longest_path_length(
|
||||
self,
|
||||
links: dict[tuple[int, int], list[tuple[tuple[int, int], int]]],
|
||||
start: tuple[int, int],
|
||||
target: tuple[int, int],
|
||||
) -> int:
|
||||
) -> int:
|
||||
max_distance: int = -1
|
||||
queue: list[tuple[tuple[int, int], int, frozenset[tuple[int, int]]]] = [
|
||||
(start, 0, frozenset({start}))
|
||||
@ -129,39 +128,38 @@ def longest_path_length(
|
||||
if reach not in path
|
||||
)
|
||||
|
||||
logging.info(f"processed {nodes} nodes")
|
||||
self.logger.info(f"processed {nodes} nodes")
|
||||
|
||||
return max_distance
|
||||
|
||||
def solve(self, input: str) -> Iterator[Any]:
|
||||
lines = cast(list[Sequence[DirectionType]], input.splitlines())
|
||||
|
||||
lines = cast(list[Sequence[DirectionType]], sys.stdin.read().splitlines())
|
||||
n_rows, n_cols = len(lines), len(lines[0])
|
||||
start = (0, 1)
|
||||
target = (len(lines) - 1, len(lines[0]) - 2)
|
||||
start = (0, 1)
|
||||
target = (len(lines) - 1, len(lines[0]) - 2)
|
||||
|
||||
|
||||
direct_links: dict[tuple[int, int], list[tuple[tuple[int, int], int]]] = {
|
||||
direct_links: dict[tuple[int, int], list[tuple[tuple[int, int], int]]] = {
|
||||
start: [reachable(lines, start, target)]
|
||||
}
|
||||
direct_links.update(compute_direct_links(lines, direct_links[start][0][0], target))
|
||||
}
|
||||
direct_links.update(
|
||||
compute_direct_links(lines, direct_links[start][0][0], target)
|
||||
)
|
||||
|
||||
# part 1
|
||||
answer_1 = longest_path_length(direct_links, start, target)
|
||||
print(f"answer 1 is {answer_1}")
|
||||
# part 1
|
||||
yield self.longest_path_length(direct_links, start, target)
|
||||
|
||||
# part 2
|
||||
reverse_links: dict[tuple[int, int], list[tuple[tuple[int, int], int]]] = defaultdict(
|
||||
list
|
||||
)
|
||||
for origin, links in direct_links.items():
|
||||
# part 2
|
||||
reverse_links: dict[tuple[int, int], list[tuple[tuple[int, int], int]]] = (
|
||||
defaultdict(list)
|
||||
)
|
||||
for origin, links in direct_links.items():
|
||||
for destination, distance in links:
|
||||
if origin != start:
|
||||
reverse_links[destination].append((origin, distance))
|
||||
|
||||
links = {
|
||||
links = {
|
||||
k: direct_links.get(k, []) + reverse_links.get(k, [])
|
||||
for k in direct_links.keys() | reverse_links.keys()
|
||||
}
|
||||
}
|
||||
|
||||
answer_2 = longest_path_length(links, start, target)
|
||||
print(f"answer 2 is {answer_2}")
|
||||
yield self.longest_path_length(links, start, target)
|
||||
|
@ -1,22 +1,29 @@
|
||||
import sys
|
||||
from typing import Any, Iterator
|
||||
|
||||
import numpy as np
|
||||
from sympy import solve, symbols
|
||||
|
||||
lines = sys.stdin.read().splitlines()
|
||||
from ..base import BaseSolver
|
||||
|
||||
positions = np.array(
|
||||
|
||||
class Solver(BaseSolver):
|
||||
def solve(self, input: str) -> Iterator[Any]:
|
||||
lines = input.splitlines()
|
||||
|
||||
positions = np.array(
|
||||
[[int(c) for c in line.split("@")[0].strip().split(", ")] for line in lines]
|
||||
)
|
||||
velocities = np.array(
|
||||
)
|
||||
velocities = np.array(
|
||||
[[int(c) for c in line.split("@")[1].strip().split(", ")] for line in lines]
|
||||
)
|
||||
)
|
||||
|
||||
# part 1
|
||||
low, high = [7, 27] if len(positions) <= 10 else [200000000000000, 400000000000000]
|
||||
# part 1
|
||||
low, high = (
|
||||
[7, 27] if len(positions) <= 10 else [200000000000000, 400000000000000]
|
||||
)
|
||||
|
||||
count = 0
|
||||
for i1, (p1, v1) in enumerate(zip(positions, velocities)):
|
||||
count = 0
|
||||
for i1, (p1, v1) in enumerate(zip(positions, velocities)):
|
||||
p, r = p1[:2], v1[:2]
|
||||
|
||||
q, s = positions[i1 + 1 :, :2], velocities[i1 + 1 :, :2]
|
||||
@ -31,33 +38,31 @@ for i1, (p1, v1) in enumerate(zip(positions, velocities)):
|
||||
c = p + np.expand_dims(t, 1) * r
|
||||
count += np.all((low <= c) & (c <= high), axis=1).sum()
|
||||
|
||||
yield count
|
||||
|
||||
answer_1 = count
|
||||
print(f"answer 1 is {answer_1}")
|
||||
# part 2
|
||||
# equation
|
||||
# p1 + t1 * v1 == p0 + t1 * v0
|
||||
# p2 + t2 * v2 == p0 + t2 * v0
|
||||
# p3 + t3 * v3 == p0 + t3 * v0
|
||||
# ...
|
||||
# pn + tn * vn == p0 + tn * v0
|
||||
#
|
||||
|
||||
# part 2
|
||||
# equation
|
||||
# p1 + t1 * v1 == p0 + t1 * v0
|
||||
# p2 + t2 * v2 == p0 + t2 * v0
|
||||
# p3 + t3 * v3 == p0 + t3 * v0
|
||||
# ...
|
||||
# pn + tn * vn == p0 + tn * v0
|
||||
#
|
||||
# we can solve with only 3 lines since each lines contains 3
|
||||
# equations (x / y / z), so 3 lines give 9 equations and 9
|
||||
# variables: position (3), velocities (3) and times (3).
|
||||
n = 3
|
||||
|
||||
# we can solve with only 3 lines since each lines contains 3
|
||||
# equations (x / y / z), so 3 lines give 9 equations and 9
|
||||
# variables: position (3), velocities (3) and times (3).
|
||||
n = 3
|
||||
|
||||
x, y, z, vx, vy, vz, *ts = symbols(
|
||||
x, y, z, vx, vy, vz, *ts = symbols(
|
||||
"x y z vx vy vz " + " ".join(f"t{i}" for i in range(n + 1))
|
||||
)
|
||||
equations = []
|
||||
for i1, ti in zip(range(n), ts):
|
||||
for p, d, pi, di in zip((x, y, z), (vx, vy, vz), positions[i1], velocities[i1]):
|
||||
)
|
||||
equations = []
|
||||
for i1, ti in zip(range(n), ts):
|
||||
for p, d, pi, di in zip(
|
||||
(x, y, z), (vx, vy, vz), positions[i1], velocities[i1]
|
||||
):
|
||||
equations.append(p + ti * d - pi - ti * di)
|
||||
|
||||
r = solve(equations, [x, y, z, vx, vy, vz] + list(ts), dict=True)[0]
|
||||
|
||||
answer_2 = r[x] + r[y] + r[z]
|
||||
print(f"answer 2 is {answer_2}")
|
||||
r = solve(equations, [x, y, z, vx, vy, vz] + list(ts), dict=True)[0]
|
||||
yield r[x] + r[y] + r[z]
|
||||
|
@ -1,25 +1,23 @@
|
||||
import sys
|
||||
from typing import Any, Iterator
|
||||
|
||||
import networkx as nx
|
||||
|
||||
components = {
|
||||
(p := line.split(": "))[0]: p[1].split() for line in sys.stdin.read().splitlines()
|
||||
}
|
||||
from ..base import BaseSolver
|
||||
|
||||
targets = {t for c in components for t in components[c] if t not in components}
|
||||
|
||||
graph = nx.Graph()
|
||||
graph.add_edges_from((u, v) for u, vs in components.items() for v in vs)
|
||||
class Solver(BaseSolver):
|
||||
def solve(self, input: str) -> Iterator[Any]:
|
||||
components = {
|
||||
(p := line.split(": "))[0]: p[1].split() for line in input.splitlines()
|
||||
}
|
||||
|
||||
cut = nx.minimum_edge_cut(graph)
|
||||
graph.remove_edges_from(cut)
|
||||
graph: "nx.Graph[str]" = nx.Graph()
|
||||
graph.add_edges_from((u, v) for u, vs in components.items() for v in vs)
|
||||
|
||||
c1, c2 = nx.connected_components(graph)
|
||||
cut = nx.minimum_edge_cut(graph)
|
||||
graph.remove_edges_from(cut)
|
||||
|
||||
# part 1
|
||||
answer_1 = len(c1) * len(c2)
|
||||
print(f"answer 1 is {answer_1}")
|
||||
c1, c2 = nx.connected_components(graph)
|
||||
|
||||
# part 2
|
||||
answer_2 = ...
|
||||
print(f"answer 2 is {answer_2}")
|
||||
# part 1
|
||||
yield len(c1) * len(c2)
|
||||
|
@ -1,5 +1,7 @@
|
||||
import math
|
||||
import sys
|
||||
from typing import Any, Iterator
|
||||
|
||||
from ..base import BaseSolver
|
||||
|
||||
|
||||
def extreme_times_to_beat(time: int, distance: int) -> tuple[int, int]:
|
||||
@ -25,23 +27,23 @@ def extreme_times_to_beat(time: int, distance: int) -> tuple[int, int]:
|
||||
return t1, t2
|
||||
|
||||
|
||||
lines = sys.stdin.read().splitlines()
|
||||
class Solver(BaseSolver):
|
||||
def solve(self, input: str) -> Iterator[Any]:
|
||||
lines = input.splitlines()
|
||||
|
||||
# part 1
|
||||
times = list(map(int, lines[0].split()[1:]))
|
||||
distances = list(map(int, lines[1].split()[1:]))
|
||||
answer_1 = math.prod(
|
||||
# part 1
|
||||
times = list(map(int, lines[0].split()[1:]))
|
||||
distances = list(map(int, lines[1].split()[1:]))
|
||||
yield math.prod(
|
||||
t2 - t1 + 1
|
||||
for t1, t2 in (
|
||||
extreme_times_to_beat(time, distance)
|
||||
for time, distance in zip(times, distances)
|
||||
)
|
||||
)
|
||||
print(f"answer 1 is {answer_1}")
|
||||
)
|
||||
|
||||
# part 2
|
||||
time = int(lines[0].split(":")[1].strip().replace(" ", ""))
|
||||
distance = int(lines[1].split(":")[1].strip().replace(" ", ""))
|
||||
t1, t2 = extreme_times_to_beat(time, distance)
|
||||
answer_2 = t2 - t1 + 1
|
||||
print(f"answer 2 is {answer_2}")
|
||||
# part 2
|
||||
time = int(lines[0].split(":")[1].strip().replace(" ", ""))
|
||||
distance = int(lines[1].split(":")[1].strip().replace(" ", ""))
|
||||
t1, t2 = extreme_times_to_beat(time, distance)
|
||||
yield t2 - t1 + 1
|
||||
|
@ -1,5 +1,7 @@
|
||||
import sys
|
||||
from collections import Counter, defaultdict
|
||||
from typing import Any, Iterator
|
||||
|
||||
from ..base import BaseSolver
|
||||
|
||||
|
||||
class HandTypes:
|
||||
@ -32,18 +34,17 @@ def extract_key(hand: str, values: dict[str, int], joker: str = "0") -> tuple[in
|
||||
)
|
||||
|
||||
|
||||
lines = sys.stdin.read().splitlines()
|
||||
cards = [(t[0], int(t[1])) for line in lines if (t := line.split())]
|
||||
class Solver(BaseSolver):
|
||||
def solve(self, input: str) -> Iterator[Any]:
|
||||
lines = input.splitlines()
|
||||
cards = [(t[0], int(t[1])) for line in lines if (t := line.split())]
|
||||
|
||||
# part 1
|
||||
values = {card: value for value, card in enumerate("23456789TJQKA")}
|
||||
cards.sort(key=lambda cv: extract_key(cv[0], values=values))
|
||||
yield sum(rank * value for rank, (_, value) in enumerate(cards, start=1))
|
||||
|
||||
# part 1
|
||||
values = {card: value for value, card in enumerate("23456789TJQKA")}
|
||||
cards.sort(key=lambda cv: extract_key(cv[0], values=values))
|
||||
answer_1 = sum(rank * value for rank, (_, value) in enumerate(cards, start=1))
|
||||
print(f"answer 1 is {answer_1}")
|
||||
|
||||
# part 2
|
||||
values = {card: value for value, card in enumerate("J23456789TQKA")}
|
||||
cards.sort(key=lambda cv: extract_key(cv[0], values=values, joker="J"))
|
||||
answer_2 = sum(rank * value for rank, (_, value) in enumerate(cards, start=1))
|
||||
print(f"answer 2 is {answer_2}")
|
||||
# part 2
|
||||
values = {card: value for value, card in enumerate("J23456789TQKA")}
|
||||
cards.sort(key=lambda cv: extract_key(cv[0], values=values, joker="J"))
|
||||
yield sum(rank * value for rank, (_, value) in enumerate(cards, start=1))
|
||||
|
@ -1,29 +1,30 @@
|
||||
import itertools
|
||||
import math
|
||||
import sys
|
||||
from typing import Any, Iterator
|
||||
|
||||
lines = sys.stdin.read().splitlines()
|
||||
from ..base import BaseSolver
|
||||
|
||||
sequence = lines[0]
|
||||
nodes = {
|
||||
|
||||
class Solver(BaseSolver):
|
||||
def solve(self, input: str) -> Iterator[Any]:
|
||||
lines = input.splitlines()
|
||||
|
||||
sequence = lines[0]
|
||||
nodes = {
|
||||
p[0]: {d: n for d, n in zip("LR", p[1].strip("()").split(", "))}
|
||||
for line in lines[2:]
|
||||
if (p := line.split(" = "))
|
||||
}
|
||||
}
|
||||
|
||||
|
||||
def path(start: str):
|
||||
def path(start: str):
|
||||
path = [start]
|
||||
it_seq = iter(itertools.cycle(sequence))
|
||||
while not path[-1].endswith("Z"):
|
||||
path.append(nodes[path[-1]][next(it_seq)])
|
||||
return path
|
||||
|
||||
# part 1
|
||||
yield len(path(next(node for node in nodes if node.endswith("A")))) - 1
|
||||
|
||||
# part 1
|
||||
answer_1 = len(path(next(node for node in nodes if node.endswith("A")))) - 1
|
||||
print(f"answer 1 is {answer_1}")
|
||||
|
||||
# part 2
|
||||
answer_2 = math.lcm(*(len(path(node)) - 1 for node in nodes if node.endswith("A")))
|
||||
print(f"answer 2 is {answer_2}")
|
||||
# part 2
|
||||
yield math.lcm(*(len(path(node)) - 1 for node in nodes if node.endswith("A")))
|
||||
|
@ -1,15 +1,22 @@
|
||||
import sys
|
||||
from typing import Any, Iterator
|
||||
|
||||
lines = sys.stdin.read().splitlines()
|
||||
from ..base import BaseSolver
|
||||
|
||||
data = [[int(c) for c in line.split()] for line in lines]
|
||||
|
||||
right_values: list[int] = []
|
||||
left_values: list[int] = []
|
||||
for values in data:
|
||||
class Solver(BaseSolver):
|
||||
def solve(self, input: str) -> Iterator[Any]:
|
||||
lines = input.splitlines()
|
||||
|
||||
data = [[int(c) for c in line.split()] for line in lines]
|
||||
|
||||
right_values: list[int] = []
|
||||
left_values: list[int] = []
|
||||
for values in data:
|
||||
diffs = [values]
|
||||
while any(d != 0 for d in diffs[-1]):
|
||||
diffs.append([rhs - lhs for lhs, rhs in zip(diffs[-1][:-1], diffs[-1][1:])])
|
||||
diffs.append(
|
||||
[rhs - lhs for lhs, rhs in zip(diffs[-1][:-1], diffs[-1][1:])]
|
||||
)
|
||||
|
||||
rhs: list[int] = [0]
|
||||
lhs: list[int] = [0]
|
||||
@ -20,10 +27,8 @@ for values in data:
|
||||
right_values.append(rhs[-1])
|
||||
left_values.append(lhs[-1])
|
||||
|
||||
# part 1
|
||||
answer_1 = sum(right_values)
|
||||
print(f"answer 1 is {answer_1}")
|
||||
# part 1
|
||||
yield sum(right_values)
|
||||
|
||||
# part 2
|
||||
answer_2 = sum(left_values)
|
||||
print(f"answer 2 is {answer_2}")
|
||||
# part 2
|
||||
yield sum(left_values)
|
||||
|
@ -54,7 +54,7 @@ def main():
|
||||
f".{year}.day{day}", __package__
|
||||
).Solver
|
||||
|
||||
solver = solver_class(logging.getLogger("AOC"), year, day)
|
||||
solver = solver_class(logging.getLogger("AOC"), verbose, year, day)
|
||||
|
||||
data: str
|
||||
if stdin:
|
||||
|
@ -4,10 +4,14 @@ from typing import Any, Final, Iterator
|
||||
|
||||
|
||||
class BaseSolver:
|
||||
def __init__(self, logger: Logger, year: int, day: int):
|
||||
def __init__(
|
||||
self, logger: Logger, verbose: bool, year: int, day: int, outputs: bool = False
|
||||
):
|
||||
self.logger: Final = logger
|
||||
self.verbose: Final = verbose
|
||||
self.year: Final = year
|
||||
self.day: Final = day
|
||||
self.outputs = outputs
|
||||
|
||||
@abstractmethod
|
||||
def solve(self, input: str) -> Iterator[Any]: ...
|
||||
|
Loading…
Reference in New Issue
Block a user