89 lines
4.0 KiB
Python
89 lines
4.0 KiB
Python
import numpy as np
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from itertools import cycle
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ex_start = [4,8]
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start = [1,5]
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# Part 1
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def simulate(positions, target_score=1000):
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die = cycle(range(1,101))
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rolls = 0
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scores = np.array([0,0])
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while True:
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for player in range(2):
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move = next(die) + next(die) + next(die)
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rolls += 3
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positions[player] = (positions[player] + move) % 10
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scores[player] += positions[player]+1
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if scores[player] >= target_score:
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return [positions, scores, rolls]
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positions, scores, rolls = simulate(np.array(start)-1)
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print(f'Part 1: Final positions are {positions}, final scores are {scores}, game ended with {rolls} rolls. Answer is thus {min(scores)*rolls}')
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# Part 2
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# Dice probabilities:
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# 3 - 1 1 1 (1) - 1/27
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# 4 - 1 1 2 and permutations (3) - 3/27
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# 5 - 1 1 3 (3), 1 2 2 (3) - 6/27
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# 6 - 2 2 2 (1), 1 2 3 (6) - 7/27
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# 7 - 3 3 1, 3 2 2 and ps - 6/27
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# 8 - 3 3 2 and permutations (3) - 3/27
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# 9 - 3 3 3 (1) - 1/27
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# So our probability curve is:
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# 3 4 5 6 7 8 9
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# . . . . . . .
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# . . . . .
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# . . . . .
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# . . .
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# . . .
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# . . .
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# .
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dirac_rolls = {3:1, 9:1, 4:3, 8:3, 5:6, 7:6, 6:7}
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# A naive assumption is that score per turn is uniformly distributed in [1,10] and thus the expected score per turn is 5.5
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# This may not be true because of the moves but if we move an average of 6 per turn we'll cycle through the possibilities quickly
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# Therefore for a target score of 21 we can expect games to last around 4 turns
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# This means we might actually be able to record all possible moves to reach the target score from a given starting position!
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# The dice rolls are independent events so we can completely ignore switching players for now,
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# and we can determine all of the winning roll sequences for each player individually,
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# and their number of universes (possibility weightings)
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# then we can match up those sequences in PvP with the first turn advantage to player 1 and determine probabilities from that!
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# Our worst case would be something like 1,2,3,4... but this is impossible as our lowest move is 3 and our highest is 9
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# We could instead get something like 4,3,2,1,4,3,2,1,4 which would take 9 moves, and is probably our worst case
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# Our best cases would be 9,8,7 and all of the similar sequences to win in 3 moves
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# Therefore, our move sequences are bounded to be within [3,9] moves for this ruleset
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def simulate_moves_to_win(starting_position=0, score=0, moves=0, target=21, universes=1): # 0 index for my sanity
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moves += 1
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akashic_record = {}
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for roll, subuniverses in dirac_rolls.items():
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new_pos = (starting_position + roll) % 10
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new_score = score + new_pos + 1
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if new_score >= target: # Winning sequence
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akashic_record[(moves, True)] = akashic_record.get((moves, True),0) + universes*subuniverses
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else: # Incomplete sequence
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akashic_record[(moves, False)] = akashic_record.get((moves, False),0) + universes*subuniverses
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subrecord = simulate_moves_to_win(new_pos, new_score, moves, target, universes*subuniverses)
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for k,v in subrecord.items():
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akashic_record[k] = akashic_record.get(k,0) + v
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return akashic_record
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def solve_multiverse(starting_positions=[1,1]): # 1 index to use from input
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p1_moves = simulate_moves_to_win(starting_positions[0]-1)
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p2_moves = simulate_moves_to_win(starting_positions[1]-1)
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p1_winning_universes = 0
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p2_winning_universes = 0
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for (turns,won), universes in p1_moves.items():
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if won:
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p1_winning_universes += universes * p2_moves.get((turns-1, False), 0) # P1 moves before P2 so is always one ahead
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for (turns,won), universes in p2_moves.items():
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if won:
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p2_winning_universes += universes * p1_moves.get((turns, False), 0) # P2 moves after P1 so must check same number of moves
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return p1_winning_universes, p2_winning_universes
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p1w, p2w = solve_multiverse(start)
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print(f'Part 2: Player 1 wins in {p1w} universes, Player 2 wins in {p2w} universes. Answer is most wins: {max(p1w,p2w)}')
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