Day 4: Restroom Redoubt
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Python
I was very confused when I saw the second part. I was like “how the fuck am I supposed now how that shape will exactly look like?” I looked a couple of initial shapes all of which looked sufficiently random. So I constructed x and y marginal distributions of the robots to impose some non-symmetry conditions.
My initial attempt was to just require maximum of x marginal should be at the centre but the sneaky bastards apparently framed the tree and tree was shorter than I expected (realised this only later) so that did not return any hits. I played around a bit and settled for: most of the maximums of x marginal should be near the centre and y marginal should be asymmetric. I still had to play around with the thresholds for these a bit because initially there was a couple of shapes (some repeating every 100 cycles or so) that satisfied my requirements (I had a part which actually outputted found shapes to a text file but then removed that in the final code). So it wasn’t %100 free of manual labour but I can say mostly…
import numpy as np from pathlib import Path from collections import Counter cwd = Path(__file__).parent def parse_input(file_path): with file_path.open("r") as fp: robot_info = fp.readlines() _split = lambda x,p: [int(x.split(' ')[p].split(',')[0].split('=')[-1]), int(x.split(' ')[p].split(',')[-1])] robot_pos = np.array([_split(x, 0) for x in robot_info]) robot_vel = np.array([_split(x, 1) for x in robot_info]) return robot_pos, robot_vel def solve_problem1(file_name, nrows, ncols, nmoves): robot_pos, robot_vel = parse_input(Path(cwd, file_name)) final_pos = robot_pos + nmoves*robot_vel final_pos = [(x[0]%ncols, x[1]%nrows) for x in list(final_pos)] pos_counts = Counter(final_pos) coords = np.array(list(pos_counts.keys()))[:,::-1] #x is cols, y is rows coords = tuple(coords.T) grid = np.zeros((nrows, ncols), dtype=int) grid[coords] += list(pos_counts.values()) counts = [np.sum(grid[:nrows>>1, :ncols>>1]), np.sum(grid[:nrows>>1, -(ncols>>1):]), np.sum(grid[-(nrows>>1):, :ncols>>1]), np.sum(grid[-(nrows>>1):, -(ncols>>1):])] return int(np.prod(counts)) def solve_problem2(file_name, nrows, ncols): robot_pos, robot_vel = parse_input(Path(cwd, file_name)) grid = np.zeros((nrows, ncols), dtype=object) # update all positions in a vectorised manner final_positions = robot_pos[None, :, :] + np.arange(1,10000)[:,None,None]*robot_vel[None,:,:] final_positions[:,:,0] = final_positions[:,:,0]%ncols final_positions[:,:,1] = final_positions[:,:,1]%nrows for s in range(final_positions.shape[0]): grid[:,:] = 0 final_pos = map(tuple, tuple(final_positions[s,:,:])) pos_counts = Counter(final_pos) coords = np.array(list(pos_counts.keys()))[:,::-1] #x is cols, y is rows coords = tuple(coords.T) grid[coords] += list(pos_counts.values()) xmarg = np.sum(grid, axis=0) tops = set(np.argsort(xmarg)[::-1][:10]) p_near_center = len(tops.intersection(set(range((ncols>>1)-5, (ncols>>1) + 6))))/10 ymarg = np.sum(grid, axis=1) ysym = 1 - abs(ymarg[:nrows>>1].sum() - ymarg[nrows>>1:].sum())/ymarg.sum() if p_near_center>0.5 and ysym<0.8: return s+1