mcts framework

2017-11-16 13:21:27 +08:00 · 2017-11-16 13:21:27 +08:00 · 30427055d1
commit 30427055d1
parent d9368c9a78
7 changed files with 291 additions and 3 deletions
--- a/AlphaGo/Network.py
+++ b/AlphaGo/Network.py
@ -70,7 +70,7 @@ total_loss = value_loss + policy_loss + reg
 update_ops = tf.get_collection(tf.GraphKeys.UPDATE_OPS)
 with tf.control_dependencies(update_ops):
 	train_op = tf.train.RMSPropOptimizer(1e-4).minimize(total_loss)
-var_list = tf.get_collection(tf.GraphKeys.TRAINABLE_VARIABLES)
+var_list = tf.get_collection(tf.GraphKeys.GLOBAL_VARIABLES)
 saver = tf.train.Saver(max_to_keep=10, var_list=var_list)
@ -131,13 +131,21 @@ def train():
 def forward(call_number):
    #checkpoint_path = "/home/yama/rl/tianshou/AlphaGo/checkpoints"
-    checkpoint_path = "/home/yama/rl/tianshou/AlphaGo/checkpoints/jialian"
+    checkpoint_path = "/home/yama/rl/tianshou/AlphaGo/checkpoints"
    board_file = np.genfromtxt("/home/yama/rl/tianshou/leela-zero/src/mcts_nn_files/board_" + call_number, dtype='str');
    human_board = np.zeros((17, 19, 19))
    #TODO : is it ok to ignore the last channel?
    for i in range(17):
        human_board[i] = np.array(list(board_file[i])).reshape(19, 19)
    #print("============================")
    #print("human board sum : " + str(np.sum(human_board[-1])))
    #print("============================")
    #print(human_board)
    #print("============================")
    #rint(human_board)
    feed_board = human_board.transpose(1, 2, 0).reshape(1, 19, 19, 17)
    #print(feed_board[:,:,:,-1])
    #print(feed_board.shape)
    #npz_board = np.load("/home/yama/rl/tianshou/AlphaGo/data/7f83928932f64a79bc1efdea268698ae.npz")
@ -148,7 +156,7 @@ def forward(call_number):
    #print("board shape : ", show_board.shape)
    #print(show_board)
-    itflag = True
+    itflag = False
    with multi_gpu.create_session() as sess:
            sess.run(tf.global_variables_initializer())
            ckpt_file = tf.train.latest_checkpoint(checkpoint_path)
--- a/AlphaGo/Network_ori.py
+++ b/AlphaGo/Network_ori.py
@ -0,0 +1,173 @@
 import os
 import time
 import gc
 import numpy as np
 import tensorflow as tf
 import tensorflow.contrib.layers as layers
 import multi_gpu
 os.environ["CUDA_VISIBLE_DEVICES"] = "1"
 def residual_block(input, is_training):
 	normalizer_params = {'is_training': is_training,
 						 'updates_collections': tf.GraphKeys.UPDATE_OPS}
 	h = layers.conv2d(input, 256, kernel_size=3, stride=1, activation_fn=tf.nn.relu,
 					  normalizer_fn=layers.batch_norm, normalizer_params=normalizer_params,
 					  weights_regularizer=layers.l2_regularizer(1e-4))
 	h = layers.conv2d(h, 256, kernel_size=3, stride=1, activation_fn=tf.identity,
 					  normalizer_fn=layers.batch_norm, normalizer_params=normalizer_params,
 					  weights_regularizer=layers.l2_regularizer(1e-4))
 	h = h + input
 	return tf.nn.relu(h)
 def policy_heads(input, is_training):
 	normalizer_params = {'is_training': is_training,
 						 'updates_collections': tf.GraphKeys.UPDATE_OPS}
 	h = layers.conv2d(input, 2, kernel_size=1, stride=1, activation_fn=tf.nn.relu,
 					  normalizer_fn=layers.batch_norm, normalizer_params=normalizer_params,
 					  weights_regularizer=layers.l2_regularizer(1e-4))
 	h = layers.flatten(h)
 	h = layers.fully_connected(h, 362, activation_fn=tf.identity, weights_regularizer=layers.l2_regularizer(1e-4))
 	return h
 def value_heads(input, is_training):
 	normalizer_params = {'is_training': is_training,
 						 'updates_collections': tf.GraphKeys.UPDATE_OPS}
 	h = layers.conv2d(input, 2, kernel_size=1, stride=1, activation_fn=tf.nn.relu,
 					  normalizer_fn=layers.batch_norm, normalizer_params=normalizer_params,
 					  weights_regularizer=layers.l2_regularizer(1e-4))
 	h = layers.flatten(h)
 	h = layers.fully_connected(h, 256, activation_fn=tf.nn.relu, weights_regularizer=layers.l2_regularizer(1e-4))
 	h = layers.fully_connected(h, 1, activation_fn=tf.nn.tanh, weights_regularizer=layers.l2_regularizer(1e-4))
 	return h
 x = tf.placeholder(tf.float32, shape=[None, 19, 19, 17])
 is_training = tf.placeholder(tf.bool, shape=[])
 z = tf.placeholder(tf.float32, shape=[None, 1])
 pi = tf.placeholder(tf.float32, shape=[None, 362])
 h = layers.conv2d(x, 256, kernel_size=3, stride=1, activation_fn=tf.nn.relu, normalizer_fn=layers.batch_norm,
 				  normalizer_params={'is_training': is_training, 'updates_collections': tf.GraphKeys.UPDATE_OPS},
 				  weights_regularizer=layers.l2_regularizer(1e-4))
 for i in range(19):
 	h = residual_block(h, is_training)
 v = value_heads(h, is_training)
 p = policy_heads(h, is_training)
 # loss = tf.reduce_mean(tf.square(z-v)) - tf.multiply(pi, tf.log(tf.clip_by_value(tf.nn.softmax(p), 1e-8, tf.reduce_max(tf.nn.softmax(p)))))
 value_loss = tf.reduce_mean(tf.square(z - v))
 policy_loss = tf.reduce_mean(tf.nn.softmax_cross_entropy_with_logits(labels=pi, logits=p))
 reg = tf.add_n(tf.get_collection(tf.GraphKeys.REGULARIZATION_LOSSES))
 total_loss = value_loss + policy_loss + reg
 # train_op = tf.train.MomentumOptimizer(1e-4, momentum=0.9, use_nesterov=True).minimize(total_loss)
 update_ops = tf.get_collection(tf.GraphKeys.UPDATE_OPS)
 with tf.control_dependencies(update_ops):
 	train_op = tf.train.RMSPropOptimizer(1e-4).minimize(total_loss)
 var_list = tf.get_collection(tf.GraphKeys.GLOBAL_VARIABLES)
 saver = tf.train.Saver(max_to_keep=10, var_list=var_list)
 def train():
 	data_path = "/home/tongzheng/data/"
 	data_name = os.listdir("/home/tongzheng/data/")
 	epochs = 100
 	batch_size = 128
 	result_path = "./checkpoints/"
 	with multi_gpu.create_session() as sess:
 		sess.run(tf.global_variables_initializer())
 		ckpt_file = tf.train.latest_checkpoint(result_path)
 		if ckpt_file is not None:
 			print('Restoring model from {}...'.format(ckpt_file))
 			saver.restore(sess, ckpt_file)
 		for epoch in range(epochs):
 			for name in data_name:
 				data = np.load(data_path + name)
 				boards = data["boards"]
 				wins = data["wins"]
 				ps = data["ps"]
 				print (boards.shape)
 				print (wins.shape)
 				print (ps.shape)
 				# batch_num = 1
 				batch_num = boards.shape[0] // batch_size
 				index = np.arange(boards.shape[0])
 				np.random.shuffle(index)
 				value_losses = []
 				policy_losses = []
 				regs = []
 				time_train = -time.time()
 				for iter in range(batch_num):
 					lv, lp, r, _ = sess.run([value_loss, policy_loss, reg, train_op],
 														 feed_dict={x: boards[
 															 index[iter * batch_size:(iter + 1) * batch_size]],
 																	z: wins[index[
 																			iter * batch_size:(iter + 1) * batch_size]],
 																	pi: ps[index[
 																		   iter * batch_size:(iter + 1) * batch_size]],
 																	is_training: True})
 					value_losses.append(lv)
 					policy_losses.append(lp)
 					regs.append(r)
 					del lv, lp, r
 					if iter % 1 == 0:
 						print(
 						"Epoch: {}, Part {}, Iteration: {}, Time: {}, Value Loss: {}, Policy Loss: {}, Reg: {}".format(
 							epoch, name, iter, time.time() + time_train, np.mean(np.array(value_losses)),
 							np.mean(np.array(policy_losses)), np.mean(np.array(regs))))
 						del value_losses, policy_losses, regs, time_train
 						time_train = -time.time()
 						value_losses = []
 						policy_losses = []
 						regs = []
 					if iter % 20 == 0:
 						save_path = "Epoch{}.Part{}.Iteration{}.ckpt".format(epoch, name, iter)
 						saver.save(sess, result_path + save_path)
 						del save_path
 				del data, boards, wins, ps, batch_num, index
 				gc.collect()
 def forward(board):
 	result_path = "./checkpoints"
 	itflag = False
 	res = None
 	if board is None:
 		# data = np.load("/home/tongzheng/meta-data/80b7bf21bce14862806d48c3cd760a1b.npz")
 		data = np.load("./data/7f83928932f64a79bc1efdea268698ae.npz")
                board = data["boards"][50].reshape(-1, 19, 19, 17)
                human_board = board[0].transpose(2, 0, 1)
                print("============================")
                print("human board sum : " + str(np.sum(human_board)))
                print("============================")
                print(board[:,:,:,-1])
 		itflag = False
 	with multi_gpu.create_session() as sess:
 		sess.run(tf.global_variables_initializer())
 		ckpt_file = tf.train.latest_checkpoint(result_path)
 		if ckpt_file is not None:
 			print('Restoring model from {}...'.format(ckpt_file))
 			saver.restore(sess, ckpt_file)
 		else:
 			raise ValueError("No model loaded")
 		res = sess.run([tf.nn.softmax(p), v], feed_dict={x: board, is_training: itflag})
 		# res = sess.run([tf.nn.softmax(p),v], feed_dict={x:fix_board["boards"][300].reshape(-1, 19, 19, 17), is_training:False})
 		# res = sess.run([tf.nn.softmax(p),v], feed_dict={x:fix_board["boards"][50].reshape(-1, 19, 19, 17), is_training:True})
 		# print(np.argmax(res[0]))
                print(res)
                print(data["p"][0])
 		print(np.argmax(res[0]))
 		print(np.argmax(data["p"][0]))
 	# print(res[0].tolist()[0])
 	# print(np.argmax(res[0]))
 	return res
 if __name__ == '__main__':
 	# train()
 	# if sys.argv[1] == "test":
 	forward(None)
--- a/tianshou/core/global_config.json
+++ b/tianshou/core/global_config.json
@ -0,0 +1,5 @@
 {
 	"global_description": "read by Environment, Neural Network, and MCTS",
 	"state_space": " ",
 	"action_space": " "
 }
--- a/tianshou/core/mcts.py
+++ b/tianshou/core/mcts.py
@ -0,0 +1,73 @@
 import numpy as np
 import math
 import json
 js = json.load("state_mask.json")
 action_num = 2
 c_puct = 5.
 class MCTSNode:
    def __init__(self, parent, action, state, action_num, prior):
        self.parent = parent
        self.action = action
        self.children = {}
        self.state = state
        self.action_num = action_num
        self.prior = prior
    def select_leaf(self):
        raise NotImplementedError("Need to implement function select_leaf")
    def backup_value(self, action, value):
        raise NotImplementedError("Need to implement function backup_value")
    def expand(self, action):
        raise NotImplementedError("Need to implement function expand")
    def iteration(self):
        raise NotImplementedError("Need to implement function iteration")
 class UCTNode(MCTSNode):
    def __init__(self, parent, action, state, action_num, prior):
        super(UCTNode, self).__init__(parent, action, state, action_num, prior)
        self.Q = np.zeros([action_num])
        self.W = np.zeros([action_num])
        self.N = np.zeros([action_num])
        self.ucb = self.Q + c_puct * self.prior * math.sqrt(np.sum(self.N)) / (self.N + 1)
    def select_leaf(self):
        action = np.argmax(self.ucb)
        if action in self.children.keys():
            self.children[action].select_leaf()
        else:
            # TODO: apply the action and evalate next state
            # state, value = self.env.step_forward(self.state, action)
            # self.children[action] = MCTSNode(self.env, self, action, state, prior)
            # self.backup_value(action, value)
            state, value = self.expand(action)
            self.children[action] = UCTNode(self.env, self, action, state, prior)
    def backup_value(self, action, value):
        self.N[action] += 1
        self.W[action] += 1
        self.Q = self.W / self.N
        self.ucb = self.Q + c_puct * self.prior * math.sqrt(np.sum(self.N)) / (self.N + 1)
        self.parent.backup_value(self.parent.action, value)
 class TSNode(MCTSNode):
    def __init__(self, parent, action, state, action_num, prior, method="Gaussian"):
        super(TSNode, self).__init__(parent, action, state, action_num, prior)
        if method == "Beta":
            self.alpha = np.ones([action_num])
            self.beta = np.ones([action_num])
        if method == "Gaussian":
            self.mu = np.zeros([action_num])
            self.sigma = np.zeros([action_num])
 class ActionNode:
    def __init__(self, parent, action):
        self.parent = parent
        self.action = action
        self.children = {}
--- a/tianshou/core/mcts_test.py
+++ b/tianshou/core/mcts_test.py
@ -0,0 +1,25 @@
 import numpy as np
 class TestEnv:
    def __init__(self, max_step=5):
        self.step = 0
        self.state = 0
        self.max_step = max_step
        self.reward = {i:np.random.uniform() for i in range(2**max_step)}
        self.best = max(self.reward.items(), key=lambda x:x[1])
        print("The best arm is {} with expected reward {}".format(self.best[0],self.best[1]))
    def step_forward(self, action):
        print("Operate action {} at timestep {}".format(action, self.step))
        self.state = self.state + 2**self.step*action
        self.step = self.step + 1
        if self.step == self.max_step:
            reward = int(np.random.uniform() > self.reward[self.state])
            print("Get reward {}".format(reward))
        else:
            reward = 0
        return [self.state, reward]
 if __name__=="__main__":
    env = TestEnv(1)
    env.step_forward(1)
--- a/tianshou/core/policy_value.json
+++ b/tianshou/core/policy_value.json
--- a/tianshou/core/state_mask.json
+++ b/tianshou/core/state_mask.json
@ -0,0 +1,4 @@
 {
 	"state" : "10",
 	"mask"  : "1000"
 }