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advent_of_code/2023/day_10/part 1 solution.py
T
Jake Pullen 59bb5f9682 day 10 done
2023-12-11 11:34:40 +00:00

124 lines
3.6 KiB
Python

import numpy as np
from queue import Queue
with open(r'advent_of_code\2023\day_10\input.txt', 'r') as file:
input = file.read()
simple_test_input = '''.....
.S-7.
.|.|.
.L-J.
.....'''
complex_test_input = '''7-F7-
.FJ|7
SJLL7
|F--J
LJ.LJ'''
# print(simple_test_input)
# print(complex_test_input)
#input = simple_test_input.split('\n')
#input = complex_test_input.split('\n')
input = input.split('\n')
#print(input)
NORTH = (-1, 0)
SOUTH = (1, 0)
WEST = (0, -1)
EAST = (0, 1)
pipe_directions = {
'|': (NORTH, SOUTH),
'-': (WEST, EAST),
'L': (NORTH, EAST),
'J': (NORTH, WEST),
'7': (WEST, SOUTH),
'F': (SOUTH, EAST),
'.': (),
}
def performLeeAlgorithm(pipe_map: list[list], distance_map: list[list], start_position: tuple[int]) -> None:
# Initialize a queue and add the start position to it
queue = Queue()
queue.put(start_position)
# Set the distance of the start position to 0
distance_map[start_position[0]][start_position[1]] = 0
# Continue until the queue is empty
while not queue.empty():
# Get the next position from the queue
current_row, current_col = queue.get()
# Iterate over the directions that the pipe at the current position allows
for delta_row, delta_col in pipe_directions[pipe_map[current_row][current_col]]:
# Calculate the next position
next_row, next_col = current_row + delta_row, current_col + delta_col
# If the next position is a pipe and its distance has not been set yet
if pipe_map[next_row][next_col] != '.' and distance_map[next_row][next_col] == -1:
# Set the distance of the next position
distance_map[next_row][next_col] = distance_map[current_row][current_col] + 1
# Add the next position to the queue
queue.put((next_row, next_col))
# Convert each row in the input to a list and store them in a list
pipe_map = [list(row) for row in input]
# Pad the pipe_map with '.' on all sides
pipe_map = np.pad(pipe_map, 1, constant_values='.')
# Create a distance_map with the same shape as pipe_map, filled with -1
distance_map = np.full_like(pipe_map, -1, dtype=np.int32)
# Convert pipe_map and distance_map to lists
pipe_map = pipe_map.tolist()
distance_map = distance_map.tolist()
# find start location
START = None
for i, row in enumerate(pipe_map):
for j, x in enumerate(row):
if x == 'S':
START = (i, j)
break
if START:
break
# Initialize the directions for the start ('S') pipe as an empty list
pipe_directions['S'] = []
# Define the start position
start_row, start_col = START
# Check the pipe in each direction from the start position
# If the pipe in that direction allows movement towards the start position, add the opposite direction to pipe_directions['S']
# Check the pipe to the north
north_pipe = pipe_map[start_row + NORTH[0]][start_col + NORTH[1]]
if SOUTH in pipe_directions[north_pipe]:
pipe_directions['S'].append(NORTH)
# Check the pipe to the south
south_pipe = pipe_map[start_row + SOUTH[0]][start_col + SOUTH[1]]
if NORTH in pipe_directions[south_pipe]:
pipe_directions['S'].append(SOUTH)
# Check the pipe to the east
east_pipe = pipe_map[start_row + EAST[0]][start_col + EAST[1]]
if WEST in pipe_directions[east_pipe]:
pipe_directions['S'].append(EAST)
# Check the pipe to the west
west_pipe = pipe_map[start_row + WEST[0]][start_col + WEST[1]]
if EAST in pipe_directions[west_pipe]:
pipe_directions['S'].append(WEST)
performLeeAlgorithm(pipe_map, distance_map, START)
print(np.max(distance_map))