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dqn.py
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dqn.py
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import gym
from gym.wrappers import Monitor
import itertools
import numpy as np
import os
import random
import sys
import tensorflow as tf
if "../" not in sys.path:
sys.path.append("../")
from lib import plotting
from collections import deque, namedtuple
env = gym.envs.make("Breakout-v0")
# Atari Actions: 0 (noop), 1 (fire), 2 (left) and 3 (right) are valid actions
VALID_ACTIONS = [0, 1, 2, 3]
class StateProcessor():
"""
Processes a raw Atari images. Resizes it and converts it to grayscale.
"""
def __init__(self):
# Build the Tensorflow graph
with tf.variable_scope("state_processor"):
self.input_state = tf.placeholder(shape=[210, 160, 3], dtype=tf.uint8)
self.output = tf.image.rgb_to_grayscale(self.input_state)
self.output = tf.image.crop_to_bounding_box(self.output, 34, 0, 160, 160)
self.output = tf.image.resize_images(
self.output, [84, 84], method=tf.image.ResizeMethod.NEAREST_NEIGHBOR)
self.output = tf.squeeze(self.output)
def process(self, sess, state):
"""
Args:
sess: A Tensorflow session object
state: A [210, 160, 3] Atari RGB State
Returns:
A processed [84, 84] state representing grayscale values.
"""
return sess.run(self.output, { self.input_state: state })
class Estimator():
"""Q-Value Estimator neural network.
This network is used for both the Q-Network and the Target Network.
"""
def __init__(self, scope="estimator", summaries_dir=None):
self.scope = scope
# Writes Tensorboard summaries to disk
self.summary_writer = None
with tf.variable_scope(scope):
# Build the graph
self._build_model()
if summaries_dir:
summary_dir = os.path.join(summaries_dir, "summaries_{}".format(scope))
if not os.path.exists(summary_dir):
os.makedirs(summary_dir)
self.summary_writer = tf.summary.FileWriter(summary_dir)
def _build_model(self):
"""
Builds the Tensorflow graph.
"""
# Placeholders for our input
# Our input are 4 RGB frames of shape 160, 160 each
self.X_pl = tf.placeholder(shape=[None, 84, 84, 4], dtype=tf.uint8, name="X")
# The TD target value
self.y_pl = tf.placeholder(shape=[None], dtype=tf.float32, name="y")
# Integer id of which action was selected
self.actions_pl = tf.placeholder(shape=[None], dtype=tf.int32, name="actions")
X = tf.to_float(self.X_pl) / 255.0
batch_size = tf.shape(self.X_pl)[0]
# Three convolutional layers
conv1 = tf.contrib.layers.conv2d(
X, 32, 8, 4, activation_fn=tf.nn.relu)
conv2 = tf.contrib.layers.conv2d(
conv1, 64, 4, 2, activation_fn=tf.nn.relu)
conv3 = tf.contrib.layers.conv2d(
conv2, 64, 3, 1, activation_fn=tf.nn.relu)
# Fully connected layers
flattened = tf.contrib.layers.flatten(conv3)
fc1 = tf.contrib.layers.fully_connected(flattened, 512)
self.predictions = tf.contrib.layers.fully_connected(fc1, len(VALID_ACTIONS))
# Get the predictions for the chosen actions only
gather_indices = tf.range(batch_size) * tf.shape(self.predictions)[1] + self.actions_pl
self.action_predictions = tf.gather(tf.reshape(self.predictions, [-1]), gather_indices)
# Calculate the loss
self.losses = tf.squared_difference(self.y_pl, self.action_predictions)
self.loss = tf.reduce_mean(self.losses)
# Optimizer Parameters from original paper
self.optimizer = tf.train.RMSPropOptimizer(0.00025, 0.99, 0.0, 1e-6)
self.train_op = self.optimizer.minimize(self.loss, global_step=tf.contrib.framework.get_global_step())
# Summaries for Tensorboard
self.summaries = tf.summary.merge([
tf.summary.scalar("loss", self.loss),
tf.summary.histogram("loss_hist", self.losses),
tf.summary.histogram("q_values_hist", self.predictions),
tf.summary.scalar("max_q_value", tf.reduce_max(self.predictions))
])
def predict(self, sess, s):
"""
Predicts action values.
Args:
sess: Tensorflow session
s: State input of shape [batch_size, 4, 160, 160, 3]
Returns:
Tensor of shape [batch_size, NUM_VALID_ACTIONS] containing the estimated
action values.
"""
return sess.run(self.predictions, { self.X_pl: s })
def update(self, sess, s, a, y):
"""
Updates the estimator towards the given targets.
Args:
sess: Tensorflow session object
s: State input of shape [batch_size, 4, 160, 160, 3]
a: Chosen actions of shape [batch_size]
y: Targets of shape [batch_size]
Returns:
The calculated loss on the batch.
"""
feed_dict = { self.X_pl: s, self.y_pl: y, self.actions_pl: a }
summaries, global_step, _, loss = sess.run(
[self.summaries, tf.contrib.framework.get_global_step(), self.train_op, self.loss],
feed_dict)
if self.summary_writer:
self.summary_writer.add_summary(summaries, global_step)
return loss
def copy_model_parameters(sess, estimator1, estimator2):
"""
Copies the model parameters of one estimator to another.
Args:
sess: Tensorflow session instance
estimator1: Estimator to copy the paramters from
estimator2: Estimator to copy the parameters to
"""
e1_params = [t for t in tf.trainable_variables() if t.name.startswith(estimator1.scope)]
e1_params = sorted(e1_params, key=lambda v: v.name)
e2_params = [t for t in tf.trainable_variables() if t.name.startswith(estimator2.scope)]
e2_params = sorted(e2_params, key=lambda v: v.name)
update_ops = []
for e1_v, e2_v in zip(e1_params, e2_params):
op = e2_v.assign(e1_v)
update_ops.append(op)
sess.run(update_ops)
def make_epsilon_greedy_policy(estimator, nA):
"""
Creates an epsilon-greedy policy based on a given Q-function approximator and epsilon.
Args:
estimator: An estimator that returns q values for a given state
nA: Number of actions in the environment.
Returns:
A function that takes the (sess, observation, epsilon) as an argument and returns
the probabilities for each action in the form of a numpy array of length nA.
"""
def policy_fn(sess, observation, epsilon):
A = np.ones(nA, dtype=float) * epsilon / nA
q_values = estimator.predict(sess, np.expand_dims(observation, 0))[0]
best_action = np.argmax(q_values)
A[best_action] += (1.0 - epsilon)
return A
return policy_fn
def deep_q_learning(sess,
env,
q_estimator,
target_estimator,
state_processor,
num_episodes,
experiment_dir,
replay_memory_size=500000,
replay_memory_init_size=50000,
update_target_estimator_every=10000,
discount_factor=0.99,
epsilon_start=1.0,
epsilon_end=0.1,
epsilon_decay_steps=500000,
batch_size=32,
record_video_every=50):
"""
Q-Learning algorithm for off-policy TD control using Function Approximation.
Finds the optimal greedy policy while following an epsilon-greedy policy.
Args:
sess: Tensorflow Session object
env: OpenAI environment
q_estimator: Estimator object used for the q values
target_estimator: Estimator object used for the targets
state_processor: A StateProcessor object
num_episodes: Number of episodes to run for
experiment_dir: Directory to save Tensorflow summaries in
replay_memory_size: Size of the replay memory
replay_memory_init_size: Number of random experiences to sampel when initializing
the reply memory.
update_target_estimator_every: Copy parameters from the Q estimator to the
target estimator every N steps
discount_factor: Gamma discount factor
epsilon_start: Chance to sample a random action when taking an action.
Epsilon is decayed over time and this is the start value
epsilon_end: The final minimum value of epsilon after decaying is done
epsilon_decay_steps: Number of steps to decay epsilon over
batch_size: Size of batches to sample from the replay memory
record_video_every: Record a video every N episodes
Returns:
An EpisodeStats object with two numpy arrays for episode_lengths and episode_rewards.
"""
Transition = namedtuple("Transition", ["state", "action", "reward", "next_state", "done"])
# The replay memory
replay_memory = []
# Keeps track of useful statistics
stats = plotting.EpisodeStats(
episode_lengths=np.zeros(num_episodes),
episode_rewards=np.zeros(num_episodes))
# Create directories for checkpoints and summaries
checkpoint_dir = os.path.join(experiment_dir, "checkpoints")
checkpoint_path = os.path.join(checkpoint_dir, "model")
monitor_path = os.path.join(experiment_dir, "monitor")
if not os.path.exists(checkpoint_dir):
os.makedirs(checkpoint_dir)
if not os.path.exists(monitor_path):
os.makedirs(monitor_path)
saver = tf.train.Saver()
# Load a previous checkpoint if we find one
latest_checkpoint = tf.train.latest_checkpoint(checkpoint_dir)
if latest_checkpoint:
print("Loading model checkpoint {}...\n".format(latest_checkpoint))
saver.restore(sess, latest_checkpoint)
total_t = sess.run(tf.contrib.framework.get_global_step())
# The epsilon decay schedule
epsilons = np.linspace(epsilon_start, epsilon_end, epsilon_decay_steps)
# The policy we're following
policy = make_epsilon_greedy_policy(
q_estimator,
len(VALID_ACTIONS))
# Populate the replay memory with initial experience
print("Populating replay memory...")
state = env.reset()
state = state_processor.process(sess, state)
state = np.stack([state] * 4, axis=2)
for i in range(replay_memory_init_size):
action_probs = policy(sess, state, epsilons[min(total_t, epsilon_decay_steps-1)])
action = np.random.choice(np.arange(len(action_probs)), p=action_probs)
next_state, reward, done, _ = env.step(VALID_ACTIONS[action])
next_state = state_processor.process(sess, next_state)
next_state = np.append(state[:,:,1:], np.expand_dims(next_state, 2), axis=2)
replay_memory.append(Transition(state, action, reward, next_state, done))
if done:
state = env.reset()
state = state_processor.process(sess, state)
state = np.stack([state] * 4, axis=2)
else:
state = next_state
# Record videos
# Use the gym env Monitor wrapper
env = Monitor(env,
directory=monitor_path,
resume=True,
video_callable=lambda count: count % record_video_every ==0)
for i_episode in range(num_episodes):
# Save the current checkpoint
saver.save(tf.get_default_session(), checkpoint_path)
# Reset the environment
state = env.reset()
state = state_processor.process(sess, state)
state = np.stack([state] * 4, axis=2)
loss = None
# One step in the environment
for t in itertools.count():
# Epsilon for this time step
epsilon = epsilons[min(total_t, epsilon_decay_steps-1)]
# Add epsilon to Tensorboard
episode_summary = tf.Summary()
episode_summary.value.add(simple_value=epsilon, tag="epsilon")
q_estimator.summary_writer.add_summary(episode_summary, total_t)
# Maybe update the target estimator
if total_t % update_target_estimator_every == 0:
copy_model_parameters(sess, q_estimator, target_estimator)
print("\nCopied model parameters to target network.")
# Print out which step we're on, useful for debugging.
print("\rStep {} ({}) @ Episode {}/{}, loss: {}".format(
t, total_t, i_episode + 1, num_episodes, loss), end="")
sys.stdout.flush()
# Take a step
action_probs = policy(sess, state, epsilon)
action = np.random.choice(np.arange(len(action_probs)), p=action_probs)
next_state, reward, done, _ = env.step(VALID_ACTIONS[action])
next_state = state_processor.process(sess, next_state)
next_state = np.append(state[:,:,1:], np.expand_dims(next_state, 2), axis=2)
# If our replay memory is full, pop the first element
if len(replay_memory) == replay_memory_size:
replay_memory.pop(0)
# Save transition to replay memory
replay_memory.append(Transition(state, action, reward, next_state, done))
# Update statistics
stats.episode_rewards[i_episode] += reward
stats.episode_lengths[i_episode] = t
# Sample a minibatch from the replay memory
samples = random.sample(replay_memory, batch_size)
states_batch, action_batch, reward_batch, next_states_batch, done_batch = map(np.array, zip(*samples))
# Calculate q values and targets (Double DQN)
q_values_next = q_estimator.predict(sess, next_states_batch)
best_actions = np.argmax(q_values_next, axis=1)
q_values_next_target = target_estimator.predict(sess, next_states_batch)
targets_batch = reward_batch + np.invert(done_batch).astype(np.float32) * \
discount_factor * q_values_next_target[np.arange(batch_size), best_actions]
# Perform gradient descent update
states_batch = np.array(states_batch)
loss = q_estimator.update(sess, states_batch, action_batch, targets_batch)
if done:
break
state = next_state
total_t += 1
# Add summaries to tensorboard
episode_summary = tf.Summary()
episode_summary.value.add(simple_value=stats.episode_rewards[i_episode], node_name="episode_reward", tag="episode_reward")
episode_summary.value.add(simple_value=stats.episode_lengths[i_episode], node_name="episode_length", tag="episode_length")
q_estimator.summary_writer.add_summary(episode_summary, total_t)
q_estimator.summary_writer.flush()
yield total_t, plotting.EpisodeStats(
episode_lengths=stats.episode_lengths[:i_episode+1],
episode_rewards=stats.episode_rewards[:i_episode+1])
env.monitor.close()
return stats
tf.reset_default_graph()
# Where we save our checkpoints and graphs
experiment_dir = os.path.abspath("./experiments/{}".format(env.spec.id))
# Create a glboal step variable
global_step = tf.Variable(0, name='global_step', trainable=False)
# Create estimators
q_estimator = Estimator(scope="q", summaries_dir=experiment_dir)
target_estimator = Estimator(scope="target_q")
# State processor
state_processor = StateProcessor()
with tf.Session() as sess:
sess.run(tf.global_variables_initializer())
for t, stats in deep_q_learning(sess,
env,
q_estimator=q_estimator,
target_estimator=target_estimator,
state_processor=state_processor,
experiment_dir=experiment_dir,
num_episodes=10000,
replay_memory_size=500000,
replay_memory_init_size=50000,
update_target_estimator_every=10000,
epsilon_start=1.0,
epsilon_end=0.1,
epsilon_decay_steps=500000,
discount_factor=0.99,
batch_size=32):
print("\nEpisode Reward: {}".format(stats.episode_rewards[-1]))