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train.py
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train.py
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# -*- coding: utf-8 -*-
"""
An implementation of the training pipeline of AlphaZero for Gomoku
@author: Junxiao Song
"""
from __future__ import print_function
import random
import numpy as np
from collections import defaultdict, deque
from game import Board, Game
from mcts_pure import MCTSPlayer as MCTS_Pure
from mcts_alphaZero import MCTSPlayer
from policy_value_net import PolicyValueNet # Theano and Lasagne
# from policy_value_net_pytorch import PolicyValueNet # Pytorch
# from policy_value_net_tensorflow import PolicyValueNet # Tensorflow
# from policy_value_net_keras import PolicyValueNet # Keras
class TrainPipeline():
def __init__(self, init_model=None):
# params of the board and the game
self.board_width = 6
self.board_height = 6
self.n_in_row = 4
self.board = Board(width=self.board_width,
height=self.board_height,
n_in_row=self.n_in_row)
self.game = Game(self.board)
# training params
self.learn_rate = 2e-3
self.lr_multiplier = 1.0 # adaptively adjust the learning rate based on KL
self.temp = 1.0 # the temperature param
self.n_playout = 400 # num of simulations for each move
self.c_puct = 5
self.buffer_size = 10000
self.batch_size = 512 # mini-batch size for training
self.data_buffer = deque(maxlen=self.buffer_size)
self.play_batch_size = 1
self.epochs = 5 # num of train_steps for each update
self.kl_targ = 0.02
self.check_freq = 50
self.game_batch_num = 1500
self.best_win_ratio = 0.0
# num of simulations used for the pure mcts, which is used as
# the opponent to evaluate the trained policy
self.pure_mcts_playout_num = 1000
if init_model:
# start training from an initial policy-value net
self.policy_value_net = PolicyValueNet(self.board_width,
self.board_height,
model_file=init_model)
else:
# start training from a new policy-value net
self.policy_value_net = PolicyValueNet(self.board_width,
self.board_height)
self.mcts_player = MCTSPlayer(self.policy_value_net.policy_value_fn,
c_puct=self.c_puct,
n_playout=self.n_playout,
is_selfplay=1)
def get_equi_data(self, play_data):
"""augment the data set by rotation and flipping
play_data: [(state, mcts_prob, winner_z), ..., ...]
"""
extend_data = []
for state, mcts_prob, winner in play_data:
for i in [1, 2, 3, 4]:
# rotate counterclockwise
equi_state = np.array([np.rot90(s, i) for s in state])
equi_mcts_prob = np.rot90(np.flipud(
mcts_prob.reshape(self.board_height, self.board_width)), i)
extend_data.append((equi_state,
np.flipud(equi_mcts_prob).flatten(),
winner))
# flip horizontally
equi_state = np.array([np.fliplr(s) for s in equi_state])
equi_mcts_prob = np.fliplr(equi_mcts_prob)
extend_data.append((equi_state,
np.flipud(equi_mcts_prob).flatten(),
winner))
return extend_data
def collect_selfplay_data(self, n_games=1):
"""collect self-play data for training"""
for i in range(n_games):
winner, play_data = self.game.start_self_play(self.mcts_player,
temp=self.temp)
play_data = list(play_data)[:]
self.episode_len = len(play_data)
# augment the data
play_data = self.get_equi_data(play_data)
self.data_buffer.extend(play_data)
def policy_update(self):
"""update the policy-value net"""
mini_batch = random.sample(self.data_buffer, self.batch_size)
state_batch = [data[0] for data in mini_batch]
mcts_probs_batch = [data[1] for data in mini_batch]
winner_batch = [data[2] for data in mini_batch]
old_probs, old_v = self.policy_value_net.policy_value(state_batch)
for i in range(self.epochs):
loss, entropy = self.policy_value_net.train_step(
state_batch,
mcts_probs_batch,
winner_batch,
self.learn_rate*self.lr_multiplier)
new_probs, new_v = self.policy_value_net.policy_value(state_batch)
kl = np.mean(np.sum(old_probs * (
np.log(old_probs + 1e-10) - np.log(new_probs + 1e-10)),
axis=1)
)
if kl > self.kl_targ * 4: # early stopping if D_KL diverges badly
break
# adaptively adjust the learning rate
if kl > self.kl_targ * 2 and self.lr_multiplier > 0.1:
self.lr_multiplier /= 1.5
elif kl < self.kl_targ / 2 and self.lr_multiplier < 10:
self.lr_multiplier *= 1.5
explained_var_old = (1 -
np.var(np.array(winner_batch) - old_v.flatten()) /
np.var(np.array(winner_batch)))
explained_var_new = (1 -
np.var(np.array(winner_batch) - new_v.flatten()) /
np.var(np.array(winner_batch)))
print(("kl:{:.5f},"
"lr_multiplier:{:.3f},"
"loss:{},"
"entropy:{},"
"explained_var_old:{:.3f},"
"explained_var_new:{:.3f}"
).format(kl,
self.lr_multiplier,
loss,
entropy,
explained_var_old,
explained_var_new))
return loss, entropy
def policy_evaluate(self, n_games=10):
"""
Evaluate the trained policy by playing against the pure MCTS player
Note: this is only for monitoring the progress of training
"""
current_mcts_player = MCTSPlayer(self.policy_value_net.policy_value_fn,
c_puct=self.c_puct,
n_playout=self.n_playout)
pure_mcts_player = MCTS_Pure(c_puct=5,
n_playout=self.pure_mcts_playout_num)
win_cnt = defaultdict(int)
for i in range(n_games):
winner = self.game.start_play(current_mcts_player,
pure_mcts_player,
start_player=i % 2,
is_shown=0)
win_cnt[winner] += 1
win_ratio = 1.0*(win_cnt[1] + 0.5*win_cnt[-1]) / n_games
print("num_playouts:{}, win: {}, lose: {}, tie:{}".format(
self.pure_mcts_playout_num,
win_cnt[1], win_cnt[2], win_cnt[-1]))
return win_ratio
def run(self):
"""run the training pipeline"""
try:
for i in range(self.game_batch_num):
self.collect_selfplay_data(self.play_batch_size)
print("batch i:{}, episode_len:{}".format(
i+1, self.episode_len))
if len(self.data_buffer) > self.batch_size:
loss, entropy = self.policy_update()
# check the performance of the current model,
# and save the model params
if (i+1) % self.check_freq == 0:
print("current self-play batch: {}".format(i+1))
win_ratio = self.policy_evaluate()
self.policy_value_net.save_model('./current_policy.model')
if win_ratio > self.best_win_ratio:
print("New best policy!!!!!!!!")
self.best_win_ratio = win_ratio
# update the best_policy
self.policy_value_net.save_model('./best_policy.model')
if (self.best_win_ratio == 1.0 and
self.pure_mcts_playout_num < 5000):
self.pure_mcts_playout_num += 1000
self.best_win_ratio = 0.0
except KeyboardInterrupt:
print('\n\rquit')
if __name__ == '__main__':
training_pipeline = TrainPipeline()
training_pipeline.run()