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worker.py
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worker.py
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import gym
import sys
import os
import itertools
import collections
import numpy as np
import tensorflow as tf
from inspect import getsourcefile
current_path = os.path.dirname(os.path.abspath(getsourcefile(lambda:0)))
import_path = os.path.abspath(os.path.join(current_path, "../.."))
if import_path not in sys.path:
sys.path.append(import_path)
# from lib import plotting
from lib.atari.state_processor import StateProcessor
from lib.atari import helpers as atari_helpers
from estimators import ValueEstimator, PolicyEstimator
Transition = collections.namedtuple("Transition", ["state", "action", "reward", "next_state", "done"])
def make_copy_params_op(v1_list, v2_list):
"""
Creates an operation that copies parameters from variable in v1_list to variables in v2_list.
The ordering of the variables in the lists must be identical.
"""
v1_list = list(sorted(v1_list, key=lambda v: v.name))
v2_list = list(sorted(v2_list, key=lambda v: v.name))
update_ops = []
for v1, v2 in zip(v1_list, v2_list):
op = v2.assign(v1)
update_ops.append(op)
return update_ops
def make_train_op(local_estimator, global_estimator):
"""
Creates an op that applies local estimator gradients
to the global estimator.
"""
local_grads, _ = zip(*local_estimator.grads_and_vars)
# Clip gradients
local_grads, _ = tf.clip_by_global_norm(local_grads, 5.0)
_, global_vars = zip(*global_estimator.grads_and_vars)
local_global_grads_and_vars = list(zip(local_grads, global_vars))
return global_estimator.optimizer.apply_gradients(local_global_grads_and_vars,
global_step=tf.contrib.framework.get_global_step())
class Worker(object):
"""
An A3C worker thread. Runs episodes locally and updates global shared value and policy nets.
Args:
name: A unique name for this worker
env: The Gym environment used by this worker
policy_net: Instance of the globally shared policy net
value_net: Instance of the globally shared value net
global_counter: Iterator that holds the global step
discount_factor: Reward discount factor
summary_writer: A tf.train.SummaryWriter for Tensorboard summaries
max_global_steps: If set, stop coordinator when global_counter > max_global_steps
"""
def __init__(self, name, env, policy_net, value_net, global_counter, discount_factor=0.99, summary_writer=None, max_global_steps=None):
self.name = name
self.discount_factor = discount_factor
self.max_global_steps = max_global_steps
self.global_step = tf.contrib.framework.get_global_step()
self.global_policy_net = policy_net
self.global_value_net = value_net
self.global_counter = global_counter
self.local_counter = itertools.count()
self.sp = StateProcessor()
self.summary_writer = summary_writer
self.env = env
# Create local policy/value nets that are not updated asynchronously
with tf.variable_scope(name):
self.policy_net = PolicyEstimator(policy_net.num_outputs)
self.value_net = ValueEstimator(reuse=True)
# Op to copy params from global policy/valuenets
self.copy_params_op = make_copy_params_op(
tf.contrib.slim.get_variables(scope="global", collection=tf.GraphKeys.TRAINABLE_VARIABLES),
tf.contrib.slim.get_variables(scope=self.name+'/', collection=tf.GraphKeys.TRAINABLE_VARIABLES))
self.vnet_train_op = make_train_op(self.value_net, self.global_value_net)
self.pnet_train_op = make_train_op(self.policy_net, self.global_policy_net)
self.state = None
def run(self, sess, coord, t_max):
with sess.as_default(), sess.graph.as_default():
# Initial state
self.state = atari_helpers.atari_make_initial_state(self.sp.process(self.env.reset()))
try:
while not coord.should_stop():
# Copy Parameters from the global networks
sess.run(self.copy_params_op)
# Collect some experience
transitions, local_t, global_t = self.run_n_steps(t_max, sess)
if self.max_global_steps is not None and global_t >= self.max_global_steps:
tf.logging.info("Reached global step {}. Stopping.".format(global_t))
coord.request_stop()
return
# Update the global networks
self.update(transitions, sess)
except tf.errors.CancelledError:
return
def _policy_net_predict(self, state, sess):
feed_dict = { self.policy_net.states: [state] }
preds = sess.run(self.policy_net.predictions, feed_dict)
return preds["probs"][0]
def _value_net_predict(self, state, sess):
feed_dict = { self.value_net.states: [state] }
preds = sess.run(self.value_net.predictions, feed_dict)
return preds["logits"][0]
def run_n_steps(self, n, sess):
transitions = []
for _ in range(n):
# Take a step
action_probs = self._policy_net_predict(self.state, sess)
action = np.random.choice(np.arange(len(action_probs)), p=action_probs)
next_state, reward, done, _ = self.env.step(action)
next_state = atari_helpers.atari_make_next_state(self.state, self.sp.process(next_state))
# Store transition
transitions.append(Transition(
state=self.state, action=action, reward=reward, next_state=next_state, done=done))
# Increase local and global counters
local_t = next(self.local_counter)
global_t = next(self.global_counter)
if local_t % 100 == 0:
tf.logging.info("{}: local Step {}, global step {}".format(self.name, local_t, global_t))
if done:
self.state = atari_helpers.atari_make_initial_state(self.sp.process(self.env.reset()))
break
else:
self.state = next_state
return transitions, local_t, global_t
def update(self, transitions, sess):
"""
Updates global policy and value networks based on collected experience
Args:
transitions: A list of experience transitions
sess: A Tensorflow session
"""
# If we episode was not done we bootstrap the value from the last state
reward = 0.0
if not transitions[-1].done:
reward = self._value_net_predict(transitions[-1].next_state, sess)
# Accumulate minibatch exmaples
states = []
policy_targets = []
value_targets = []
actions = []
for transition in transitions[::-1]:
reward = transition.reward + self.discount_factor * reward
policy_target = (reward - self._value_net_predict(transition.state, sess))
# Accumulate updates
states.append(transition.state)
actions.append(transition.action)
policy_targets.append(policy_target)
value_targets.append(reward)
feed_dict = {
self.policy_net.states: np.array(states),
self.policy_net.targets: policy_targets,
self.policy_net.actions: actions,
self.value_net.states: np.array(states),
self.value_net.targets: value_targets,
}
# Train the global estimators using local gradients
global_step, pnet_loss, vnet_loss, _, _, pnet_summaries, vnet_summaries = sess.run([
self.global_step,
self.policy_net.loss,
self.value_net.loss,
self.pnet_train_op,
self.vnet_train_op,
self.policy_net.summaries,
self.value_net.summaries
], feed_dict)
# Write summaries
if self.summary_writer is not None:
self.summary_writer.add_summary(pnet_summaries, global_step)
self.summary_writer.add_summary(vnet_summaries, global_step)
self.summary_writer.flush()
return pnet_loss, vnet_loss, pnet_summaries, vnet_summaries