from helpers import * lines = read_day(24).split('\n')[1:-1] # strip walls sample_lines = ''' #.###### #>>.<^<# #.<..<<# #>v.><># #<^v^^># ######.#'''.strip().split('\n')[1:-1] def sim(lines): height = len(lines) width = len(lines[0]) - 2 blizzards_left = set() blizzards_right = set() blizzards_up = set() blizzards_down = set() for row, line in enumerate(lines): for col, c in enumerate(line[1:-1]): # strip walls if c == '<': blizzards_left.add((col, row)) elif c == '>': blizzards_right.add((col, row)) elif c == '^': blizzards_up.add((col, row)) elif c == 'v': blizzards_down.add((col, row)) def position_free(col: int, row: int, time: int) -> bool: if ((col+time)%width, row) in blizzards_left: return False if ((col-time)%width, row) in blizzards_right: return False if (col, (row+time)%height) in blizzards_up: return False if (col, (row-time)%height) in blizzards_down: return False return True seen_states = set() state_stack = [(0,-1,0)] def try_add_state(col: int, row: int, time: int): if col < 0 or col >= width or row < -1 or row > height: return if row == -1 and col != 0: return if row == height and col != width-1: return if not position_free(col, row, time): return triple = (col, row, time) if triple not in seen_states: seen_states.add(triple) state_stack.append(triple) best_time = 1_000_000 goal = (width-1, height) # End position print('Moving from start to end') while state_stack: col, row, t = state_stack.pop() t1 = t + 1 goal_distance = abs(goal[0]-col) + abs(goal[1]-row) # Manhattan distance if goal_distance == 1: # we're right next to the goal! move there and end this trail best_time = min(best_time, t1) continue if t + goal_distance > best_time: continue try_add_state(col-1, row, t1) try_add_state(col, row-1, t1) try_add_state(col, row, t1) try_add_state(col+1, row, t1) try_add_state(col, row+1, t1) p1 = best_time state_stack = [(width-1, height, best_time)] seen_states.clear() best_time = 1_000_000 goal = (0, -1) # Starting position print('Moving from end to start') while state_stack: col, row, t = state_stack.pop() t1 = t + 1 goal_distance = abs(goal[0]-col) + abs(goal[1]-row) # Manhattan distance if goal_distance == 1: # we're right next to the goal! move there and end this trail best_time = min(best_time, t1) continue if t + goal_distance > best_time: continue try_add_state(col+1, row, t1) try_add_state(col, row+1, t1) try_add_state(col, row, t1) try_add_state(col-1, row, t1) try_add_state(col, row-1, t1) state_stack = [(0,-1,best_time)] seen_states.clear() best_time = 1_000_000 goal = (width-1, height) # End position print('Moving from start to end (2)') while state_stack: col, row, t = state_stack.pop() t1 = t + 1 goal_distance = abs(goal[0]-col) + abs(goal[1]-row) # Manhattan distance if goal_distance == 1: # we're right next to the goal! move there and end this trail best_time = min(best_time, t1) continue if t + goal_distance > best_time: continue try_add_state(col-1, row, t1) try_add_state(col, row-1, t1) try_add_state(col, row, t1) try_add_state(col+1, row, t1) try_add_state(col, row+1, t1) return p1, best_time print(sim(sample_lines)) print(sim(lines))