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04_Dueling_Deep_Q_Network.py
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04_Dueling_Deep_Q_Network.py
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# Import modules
import tensorflow as tf
import pygame
import random
import numpy as np
import matplotlib.pyplot as plt
import datetime
import time
import cv2
import os
# Import game
import sys
sys.path.append("DQN_GAMES/")
import Parameters
game = Parameters.game
class Dueling_DQN:
def __init__(self):
# Game Information
self.algorithm = 'Dueling_DQN'
self.game_name = game.ReturnName()
# Get parameters
self.progress = ''
self.Num_action = game.Return_Num_Action()
# Initial parameters
self.Num_Exploration = Parameters.Num_start_training
self.Num_Training = Parameters.Num_training
self.Num_Testing = Parameters.Num_test
self.learning_rate = Parameters.Learning_rate
self.gamma = Parameters.Gamma
self.first_epsilon = Parameters.Epsilon
self.final_epsilon = Parameters.Final_epsilon
self.epsilon = self.first_epsilon
self.Num_plot_episode = Parameters.Num_plot_episode
self.Is_train = Parameters.Is_train
self.load_path = Parameters.Load_path
self.step = 1
self.score = 0
self.episode = 0
# date - hour - minute - second of training time
self.date_time = str(datetime.date.today()) + '_' + \
str(datetime.datetime.now().hour) + '_' + \
str(datetime.datetime.now().minute) + '_' + \
str(datetime.datetime.now().second)
# parameters for skipping and stacking
self.state_set = []
self.Num_skipping = Parameters.Num_skipFrame
self.Num_stacking = Parameters.Num_stackFrame
# Parameter for Experience Replay
self.Num_replay_memory = Parameters.Num_replay_memory
self.Num_batch = Parameters.Num_batch
self.replay_memory = []
# Parameter for Target Network
self.Num_update_target = Parameters.Num_update
# Parameters for network
self.img_size = 80
self.Num_colorChannel = Parameters.Num_colorChannel
self.first_conv = Parameters.first_conv
self.second_conv = Parameters.second_conv
self.third_conv = Parameters.third_conv
self.first_dense = Parameters.first_dense
self.second_dense_state = [self.first_dense[1], 1]
self.second_dense_action = [self.first_dense[1], self.Num_action]
# Variables for tensorboard
self.loss = 0
self.maxQ = 0
self.score_board = 0
self.maxQ_board = 0
self.loss_board = 0
self.step_old = 0
# Initialize Network
self.input, self.output = self.network('network')
self.input_target, self.output_target = self.network('target')
self.train_step, self.action_target, self.y_target, self.loss_train = self.loss_and_train()
self.sess, self.saver, self.summary_placeholders, self.update_ops, self.summary_op, self.summary_writer = self.init_sess()
def main(self):
# Define game state
game_state = game.GameState()
# Initialization
state = self.initialization(game_state)
stacked_state = self.skip_and_stack_frame(state)
while True:
# Get progress:
self.progress = self.get_progress()
# Select action
action = self.select_action(stacked_state)
# Take action and get info. for update
next_state, reward, terminal = game_state.frame_step(action)
next_state = self.reshape_input(next_state)
stacked_next_state = self.skip_and_stack_frame(next_state)
# Experience Replay
self.experience_replay(stacked_state, action, reward, stacked_next_state, terminal)
# Training!
if self.progress == 'Training':
# Update target network
if self.step % self.Num_update_target == 0:
self.update_target()
# Training
self.train(self.replay_memory)
# Save model
self.save_model()
# Update former info.
stacked_state = stacked_next_state
self.score += reward
self.step += 1
# Plotting
self.plotting(terminal)
# If game is over (terminal)
if terminal:
stacked_state = self.if_terminal(game_state)
# Finished!
if self.progress == 'Finished':
print('Finished!')
break
def init_sess(self):
# Initialize variables
config = tf.ConfigProto()
config.gpu_options.allow_growth = True
sess = tf.InteractiveSession(config=config)
# Make folder for save data
os.makedirs('saved_networks/' + self.game_name + '/' + self.date_time + '_' + self.algorithm)
# Summary for tensorboard
summary_placeholders, update_ops, summary_op = self.setup_summary()
summary_writer = tf.summary.FileWriter('saved_networks/' + self.game_name + '/' + self.date_time + '_' + self.algorithm, sess.graph)
init = tf.global_variables_initializer()
sess.run(init)
# Load the file if the saved file exists
saver = tf.train.Saver()
# check_save = 1
check_save = input('Load Model? (1=yes/2=no): ')
if check_save == 1:
# Restore variables from disk.
saver.restore(sess, self.load_path + "/model.ckpt")
print("Model restored.")
check_train = input('Inference or Training? (1=Inference / 2=Training): ')
if check_train == 1:
self.Num_Exploration = 0
self.Num_Training = 0
return sess, saver, summary_placeholders, update_ops, summary_op, summary_writer
def initialization(self, game_state):
action = np.zeros([self.Num_action])
state, _, _ = game_state.frame_step(action)
state = self.reshape_input(state)
for i in range(self.Num_skipping * self.Num_stacking):
self.state_set.append(state)
return state
def skip_and_stack_frame(self, state):
self.state_set.append(state)
state_in = np.zeros((self.img_size, self.img_size, self.Num_colorChannel * self.Num_stacking))
# Stack the frame according to the number of skipping frame
for stack_frame in range(self.Num_stacking):
state_in[:,:, self.Num_colorChannel * stack_frame : self.Num_colorChannel * (stack_frame+1)] = self.state_set[-1 - (self.Num_skipping * stack_frame)]
del self.state_set[0]
state_in = np.uint8(state_in)
return state_in
def get_progress(self):
progress = ''
if self.step <= self.Num_Exploration:
progress = 'Exploring'
elif self.step <= self.Num_Exploration + self.Num_Training:
progress = 'Training'
elif self.step <= self.Num_Exploration + self.Num_Training + self.Num_Testing:
progress = 'Testing'
else:
progress = 'Finished'
return progress
# Resize and make input as grayscale
def reshape_input(self, state):
state_out = cv2.resize(state, (self.img_size, self.img_size))
if self.Num_colorChannel == 1:
state_out = cv2.cvtColor(state_out, cv2.COLOR_BGR2GRAY)
state_out = np.reshape(state_out, (self.img_size, self.img_size, 1))
state_out = np.uint8(state_out)
return state_out
# Code for tensorboard
def setup_summary(self):
episode_score = tf.Variable(0.)
episode_maxQ = tf.Variable(0.)
episode_loss = tf.Variable(0.)
tf.summary.scalar('Average Score/' + str(self.Num_plot_episode) + ' episodes', episode_score)
tf.summary.scalar('Average MaxQ/' + str(self.Num_plot_episode) + ' episodes', episode_maxQ)
tf.summary.scalar('Average Loss/' + str(self.Num_plot_episode) + ' episodes', episode_loss)
summary_vars = [episode_score, episode_maxQ, episode_loss]
summary_placeholders = [tf.placeholder(tf.float32) for _ in range(len(summary_vars))]
update_ops = [summary_vars[i].assign(summary_placeholders[i]) for i in range(len(summary_vars))]
summary_op = tf.summary.merge_all()
return summary_placeholders, update_ops, summary_op
# Convolution and pooling
def conv2d(self, x, w, stride):
return tf.nn.conv2d(x,w,strides=[1, stride, stride, 1], padding='SAME')
# Get Variables
def conv_weight_variable(self, name, shape):
return tf.get_variable(name, shape = shape, initializer = tf.contrib.layers.xavier_initializer_conv2d())
def weight_variable(self, name, shape):
return tf.get_variable(name, shape = shape, initializer = tf.contrib.layers.xavier_initializer())
def bias_variable(self, name, shape):
return tf.get_variable(name, shape = shape, initializer = tf.contrib.layers.xavier_initializer())
def network(self, network_name):
# Input
x_image = tf.placeholder(tf.float32, shape = [None,
self.img_size,
self.img_size,
self.Num_stacking * self.Num_colorChannel])
x_normalize = (x_image - (255.0/2)) / (255.0/2)
with tf.variable_scope(network_name):
# Convolution variables
w_conv1 = self.conv_weight_variable('_w_conv1', self.first_conv)
b_conv1 = self.bias_variable('_b_conv1',[self.first_conv[3]])
w_conv2 = self.conv_weight_variable('_w_conv2',self.second_conv)
b_conv2 = self.bias_variable('_b_conv2',[self.second_conv[3]])
w_conv3 = self.conv_weight_variable('_w_conv3',self.third_conv)
b_conv3 = self.bias_variable('_b_conv3',[self.third_conv[3]])
# Densely connect layer variables
w_fc1_1 = self.weight_variable('_w_fc1_1',self.first_dense)
b_fc1_1 = self.bias_variable('_b_fc1_1',[self.first_dense[1]])
w_fc1_2 = self.weight_variable('_w_fc1_2',self.first_dense)
b_fc1_2 = self.bias_variable('_b_fc1_2',[self.first_dense[1]])
w_fc2_1 = self.weight_variable('_w_fc2_1',self.second_dense_state)
b_fc2_1 = self.bias_variable('_b_fc2_1',[self.second_dense_state[1]])
w_fc2_2 = self.weight_variable('_w_fc2_2',self.second_dense_action)
b_fc2_2 = self.bias_variable('_b_fc2_2',[self.second_dense_action[1]])
# Network
h_conv1 = tf.nn.relu(self.conv2d(x_normalize, w_conv1, 4) + b_conv1)
h_conv2 = tf.nn.relu(self.conv2d(h_conv1, w_conv2, 2) + b_conv2)
h_conv3 = tf.nn.relu(self.conv2d(h_conv2, w_conv3, 1) + b_conv3)
h_flat = tf.reshape(h_conv3, [-1, self.first_dense[0]])
h_fc1_state = tf.nn.relu(tf.matmul(h_flat, w_fc1_1)+b_fc1_1)
h_fc1_action = tf.nn.relu(tf.matmul(h_flat, w_fc1_2)+b_fc1_2)
h_fc2_state = tf.matmul(h_fc1_state, w_fc2_1)+b_fc2_1
h_fc2_action = tf.matmul(h_fc1_action, w_fc2_2)+b_fc2_2
h_fc2_action_mean = tf.tile(tf.reduce_mean(h_fc2_action, axis=-1, keepdims=True), [1, self.Num_action])
h_fc2_advantage = tf.subtract(h_fc2_action, h_fc2_action_mean)
output = tf.add(h_fc2_state, h_fc2_advantage)
return x_image, output
def loss_and_train(self):
# Loss function and Train
action_target = tf.placeholder(tf.float32, shape = [None, self.Num_action])
y_target = tf.placeholder(tf.float32, shape = [None])
y_prediction = tf.reduce_sum(tf.multiply(self.output, action_target), reduction_indices = 1)
Loss = tf.reduce_mean(tf.square(y_prediction - y_target))
train_step = tf.train.AdamOptimizer(learning_rate = self.learning_rate, epsilon = 1e-02).minimize(Loss)
return train_step, action_target, y_target, Loss
def select_action(self, stacked_state):
action = np.zeros([self.Num_action])
action_index = 0
# Choose action
if self.progress == 'Exploring':
# Choose random action
action_index = random.randint(0, self.Num_action-1)
action[action_index] = 1
elif self.progress == 'Training':
if random.random() < self.epsilon:
# Choose random action
action_index = random.randint(0, self.Num_action-1)
action[action_index] = 1
else:
# Choose greedy action
Q_value = self.output.eval(feed_dict={self.input: [stacked_state]})
action_index = np.argmax(Q_value)
action[action_index] = 1
self.maxQ = np.max(Q_value)
# Decrease epsilon while training
if self.epsilon > self.final_epsilon:
self.epsilon -= self.first_epsilon/self.Num_Training
elif self.progress == 'Testing':
# Choose greedy action
Q_value = self.output.eval(feed_dict={self.input: [stacked_state]})
action_index = np.argmax(Q_value)
action[action_index] = 1
self.maxQ = np.max(Q_value)
self.epsilon = 0
return action
def experience_replay(self, state, action, reward, next_state, terminal):
# If Replay memory is longer than Num_replay_memory, delete the oldest one
if len(self.replay_memory) >= self.Num_replay_memory:
del self.replay_memory[0]
self.replay_memory.append([state, action, reward, next_state, terminal])
def update_target(self):
# Get trainable variables
trainable_variables = tf.trainable_variables()
# network variables
trainable_variables_network = [var for var in trainable_variables if var.name.startswith('network')]
# target variables
trainable_variables_target = [var for var in trainable_variables if var.name.startswith('target')]
for i in range(len(trainable_variables_network)):
self.sess.run(tf.assign(trainable_variables_target[i], trainable_variables_network[i]))
def train(self, replay_memory):
# Select minibatch
minibatch = random.sample(replay_memory, self.Num_batch)
# Save the each batch data
state_batch = [batch[0] for batch in minibatch]
action_batch = [batch[1] for batch in minibatch]
reward_batch = [batch[2] for batch in minibatch]
next_state_batch = [batch[3] for batch in minibatch]
terminal_batch = [batch[4] for batch in minibatch]
# Get y_prediction
y_batch = []
Q_batch = self.output_target.eval(feed_dict = {self.input_target: next_state_batch})
# Get target values
for i in range(len(minibatch)):
if terminal_batch[i] == True:
y_batch.append(reward_batch[i])
else:
y_batch.append(reward_batch[i] + self.gamma * np.max(Q_batch[i]))
_, self.loss = self.sess.run([self.train_step, self.loss_train], feed_dict = {self.action_target: action_batch,
self.y_target: y_batch,
self.input: state_batch})
def save_model(self):
# Save the variables to disk.
if self.step == self.Num_Exploration + self.Num_Training:
save_path = self.saver.save(self.sess, 'saved_networks/' + self.game_name + '/' + self.date_time + '_' + self.algorithm + "/model.ckpt")
print("Model saved in file: %s" % save_path)
def plotting(self, terminal):
if self.progress != 'Exploring':
if terminal:
self.score_board += self.score
self.maxQ_board += self.maxQ
self.loss_board += self.loss
if self.episode % self.Num_plot_episode == 0 and self.episode != 0 and terminal:
diff_step = self.step - self.step_old
tensorboard_info = [self.score_board / self.Num_plot_episode, self.maxQ_board / diff_step, self.loss_board / diff_step]
for i in range(len(tensorboard_info)):
self.sess.run(self.update_ops[i], feed_dict = {self.summary_placeholders[i]: float(tensorboard_info[i])})
summary_str = self.sess.run(self.summary_op)
self.summary_writer.add_summary(summary_str, self.step)
self.score_board = 0
self.maxQ_board = 0
self.loss_board = 0
self.step_old = self.step
else:
self.step_old = self.step
def if_terminal(self, game_state):
# Show Progress
print('Step: ' + str(self.step) + ' / ' +
'Episode: ' + str(self.episode) + ' / ' +
'Progress: ' + self.progress + ' / ' +
'Epsilon: ' + str(self.epsilon) + ' / ' +
'Score: ' + str(self.score))
if self.progress != 'Exploring':
self.episode += 1
self.score = 0
# If game is finished, initialize the state
state = self.initialization(game_state)
stacked_state = self.skip_and_stack_frame(state)
return stacked_state
if __name__ == '__main__':
agent = Dueling_DQN()
agent.main()