def learn(self, total_timesteps, callback=None, log_interval=100, tb_log_name="A2C",
reset_num_timesteps=True):
new_tb_log = self._init_num_timesteps(reset_num_timesteps)
callback = self._init_callback(callback)
with SetVerbosity(self.verbose), TensorboardWriter(self.graph, self.tensorboard_log, tb_log_name, new_tb_log) \
as writer:
self._setup_learn()
self.learning_rate_schedule = Scheduler(initial_value=self.learning_rate, n_values=total_timesteps,
schedule=self.lr_schedule)
t_start = time.time()
callback.on_training_start(locals(), globals())
for update in range(1, total_timesteps // self.n_batch + 1):
callback.on_rollout_start()
# true_reward is the reward without discount
rollout = self.runner.run(callback)
# unpack
obs, states, rewards, masks, actions, values, ep_infos, true_reward = rollout
callback.update_locals(locals())
callback.on_rollout_end()
# Early stopping due to the callback
if not self.runner.continue_training:
break
self.ep_info_buf.extend(ep_infos)
_, value_loss, policy_entropy = self._train_step(obs, states, rewards, masks, actions, values,
self.num_timesteps // self.n_batch, writer)
n_seconds = time.time() - t_start
fps = int((update * self.n_batch) / n_seconds)
if writer is not None:
total_episode_reward_logger(self.episode_reward,
true_reward.reshape((self.n_envs, self.n_steps)),
masks.reshape((self.n_envs, self.n_steps)),
writer, self.num_timesteps)
if self.verbose >= 1 and (update % log_interval == 0 or update == 1):
explained_var = explained_variance(values, rewards)
logger.record_tabular("nupdates", update)
logger.record_tabular("total_timesteps", self.num_timesteps)
logger.record_tabular("fps", fps)
logger.record_tabular("policy_entropy", float(policy_entropy))
logger.record_tabular("value_loss", float(value_loss))
logger.record_tabular("explained_variance", float(explained_var))
if len(self.ep_info_buf) > 0 and len(self.ep_info_buf[0]) > 0:
logger.logkv('ep_reward_mean', safe_mean([ep_info['r'] for ep_info in self.ep_info_buf]))
logger.logkv('ep_len_mean', safe_mean([ep_info['l'] for ep_info in self.ep_info_buf]))
logger.dump_tabular()
callback.on_training_end()
return self
def learn(self,
total_timesteps,
callback=None,
log_interval=100,
tb_log_name="ACKTR",
reset_num_timesteps=True):
new_tb_log = self._init_num_timesteps(reset_num_timesteps)
callback = self._init_callback(callback)
with SetVerbosity(self.verbose), TensorboardWriter(self.graph, self.tensorboard_log, tb_log_name, new_tb_log) \
as writer:
self._setup_learn()
self.n_batch = self.n_envs * self.n_steps
self.learning_rate_schedule = Scheduler(
initial_value=self.learning_rate,
n_values=total_timesteps,
schedule=self.lr_schedule)
# FIFO queue of the q_runner thread is closed at the end of the learn function.
# As a result, it needs to be redefinied at every call
with self.graph.as_default():
with tf.variable_scope(
"kfac_apply",
reuse=self.trained,
custom_getter=tf_util.outer_scope_getter(
"kfac_apply")):
# Some of the variables are not in a scope when they are create
# so we make a note of any previously uninitialized variables
tf_vars = tf.global_variables()
is_uninitialized = self.sess.run(
[tf.is_variable_initialized(var) for var in tf_vars])
old_uninitialized_vars = [
v for (v, f) in zip(tf_vars, is_uninitialized) if not f
]
self.train_op, self.q_runner = self.optim.apply_gradients(
list(zip(self.grads_check, self.params)))
# then we check for new uninitialized variables and initialize them
tf_vars = tf.global_variables()
is_uninitialized = self.sess.run(
[tf.is_variable_initialized(var) for var in tf_vars])
new_uninitialized_vars = [
v for (v, f) in zip(tf_vars, is_uninitialized)
if not f and v not in old_uninitialized_vars
]
if len(new_uninitialized_vars) != 0:
self.sess.run(
tf.variables_initializer(new_uninitialized_vars))
self.trained = True
t_start = time.time()
coord = tf.train.Coordinator()
if self.q_runner is not None:
enqueue_threads = self.q_runner.create_threads(self.sess,
coord=coord,
start=True)
else:
enqueue_threads = []
callback.on_training_start(locals(), globals())
for update in range(1, total_timesteps // self.n_batch + 1):
callback.on_rollout_start()
# pytype:disable=bad-unpacking
# true_reward is the reward without discount
if isinstance(self.runner, PPO2Runner):
# We are using GAE
rollout = self.runner.run(callback)
obs, returns, masks, actions, values, _, states, ep_infos, true_reward = rollout
else:
rollout = self.runner.run(callback)
obs, states, returns, masks, actions, values, ep_infos, true_reward = rollout
# pytype:enable=bad-unpacking
callback.update_locals(locals())
callback.on_rollout_end()
# Early stopping due to the callback
if not self.runner.continue_training:
break
self.ep_info_buf.extend(ep_infos)
policy_loss, value_loss, policy_entropy = self._train_step(
obs, states, returns, masks, actions, values,
self.num_timesteps // (self.n_batch + 1), writer)
n_seconds = time.time() - t_start
fps = int((update * self.n_batch) / n_seconds)
if writer is not None:
total_episode_reward_logger(
self.episode_reward,
true_reward.reshape((self.n_envs, self.n_steps)),
masks.reshape((self.n_envs, self.n_steps)), writer,
self.num_timesteps)
if self.verbose >= 1 and (update % log_interval == 0
or update == 1):
explained_var = explained_variance(values, returns)
logger.record_tabular("nupdates", update)
logger.record_tabular("total_timesteps",
self.num_timesteps)
logger.record_tabular("fps", fps)
logger.record_tabular("policy_entropy",
float(policy_entropy))
logger.record_tabular("policy_loss", float(policy_loss))
logger.record_tabular("value_loss", float(value_loss))
logger.record_tabular("explained_variance",
float(explained_var))
if len(self.ep_info_buf) > 0 and len(
self.ep_info_buf[0]) > 0:
logger.logkv(
'ep_reward_mean',
safe_mean([
ep_info['r'] for ep_info in self.ep_info_buf
]))
logger.logkv(
'ep_len_mean',
safe_mean([
ep_info['l'] for ep_info in self.ep_info_buf
]))
logger.dump_tabular()
coord.request_stop()
coord.join(enqueue_threads)
callback.on_training_end()
return self
def learn(self,
total_timesteps,
callback=None,
log_interval=1,
tb_log_name="PPO2",
reset_num_timesteps=True):
# Transform to callable if needed
self.learning_rate = get_schedule_fn(self.learning_rate)
self.cliprange = get_schedule_fn(self.cliprange)
cliprange_vf = get_schedule_fn(self.cliprange_vf)
new_tb_log = self._init_num_timesteps(reset_num_timesteps)
callback = self._init_callback(callback)
with SetVerbosity(self.verbose), TensorboardWriter(self.graph, self.tensorboard_log, tb_log_name, new_tb_log) \
as writer:
self._setup_learn()
t_first_start = time.time()
n_updates = total_timesteps // self.n_batch
callback.on_training_start(locals(), globals())
for update in range(1, n_updates + 1):
assert self.n_batch % self.nminibatches == 0, (
"The number of minibatches (`nminibatches`) "
"is not a factor of the total number of samples "
"collected per rollout (`n_batch`), "
"some samples won't be used.")
batch_size = self.n_batch // self.nminibatches
t_start = time.time()
frac = 1.0 - (update - 1.0) / n_updates
lr_now = self.learning_rate(frac)
cliprange_now = self.cliprange(frac)
cliprange_vf_now = cliprange_vf(frac)
callback.on_rollout_start()
# true_reward is the reward without discount
rollout = self.runner.run(callback)
# Unpack
obs, returns, masks, actions, values, neglogpacs, states, ep_infos, true_reward = rollout
callback.on_rollout_end()
# Early stopping due to the callback
if not self.runner.continue_training:
break
self.ep_info_buf.extend(ep_infos)
mb_loss_vals = []
if states is None: # nonrecurrent version
update_fac = max(
self.n_batch // self.nminibatches // self.noptepochs,
1)
inds = np.arange(self.n_batch)
for epoch_num in range(self.noptepochs):
np.random.shuffle(inds)
for start in range(0, self.n_batch, batch_size):
timestep = self.num_timesteps // update_fac + (
(epoch_num * self.n_batch + start) //
batch_size)
end = start + batch_size
mbinds = inds[start:end]
slices = (arr[mbinds]
for arr in (obs, returns, masks, actions,
values, neglogpacs))
mb_loss_vals.append(
self._train_step(
lr_now,
cliprange_now,
*slices,
writer=writer,
update=timestep,
cliprange_vf=cliprange_vf_now))
else: # recurrent version
update_fac = max(
self.n_batch // self.nminibatches // self.noptepochs //
self.n_steps, 1)
assert self.n_envs % self.nminibatches == 0
env_indices = np.arange(self.n_envs)
flat_indices = np.arange(self.n_envs *
self.n_steps).reshape(
self.n_envs, self.n_steps)
envs_per_batch = batch_size // self.n_steps
for epoch_num in range(self.noptepochs):
np.random.shuffle(env_indices)
for start in range(0, self.n_envs, envs_per_batch):
timestep = self.num_timesteps // update_fac + (
(epoch_num * self.n_envs + start) //
envs_per_batch)
end = start + envs_per_batch
mb_env_inds = env_indices[start:end]
mb_flat_inds = flat_indices[mb_env_inds].ravel()
slices = (arr[mb_flat_inds]
for arr in (obs, returns, masks, actions,
values, neglogpacs))
mb_states = states[mb_env_inds]
mb_loss_vals.append(
self._train_step(
lr_now,
cliprange_now,
*slices,
update=timestep,
writer=writer,
states=mb_states,
cliprange_vf=cliprange_vf_now))
loss_vals = np.mean(mb_loss_vals, axis=0)
t_now = time.time()
fps = int(self.n_batch / (t_now - t_start))
if writer is not None:
total_episode_reward_logger(
self.episode_reward,
true_reward.reshape((self.n_envs, self.n_steps)),
masks.reshape((self.n_envs, self.n_steps)), writer,
self.num_timesteps)
if self.verbose >= 1 and (update % log_interval == 0
or update == 1):
explained_var = explained_variance(values, returns)
logger.logkv("serial_timesteps", update * self.n_steps)
logger.logkv("n_updates", update)
logger.logkv("total_timesteps", self.num_timesteps)
logger.logkv("fps", fps)
logger.logkv("explained_variance", float(explained_var))
if len(self.ep_info_buf) > 0 and len(
self.ep_info_buf[0]) > 0:
logger.logkv(
'ep_reward_mean',
safe_mean([
ep_info['r'] for ep_info in self.ep_info_buf
]))
logger.logkv(
'ep_len_mean',
safe_mean([
ep_info['l'] for ep_info in self.ep_info_buf
]))
logger.logkv('time_elapsed', t_start - t_first_start)
for (loss_val, loss_name) in zip(loss_vals,
self.loss_names):
logger.logkv(loss_name, loss_val)
logger.dumpkvs()
callback.on_training_end()
return self