def process_samples(self, itr, paths):
baselines = []
returns = []
if hasattr(self.algo.baseline, 'predict_n'):
all_path_baselines = self.algo.baseline.predict_n(paths)
else:
all_path_baselines = [
self.algo.baseline.predict(path) for path in paths
]
for idx, path in enumerate(paths):
path_baselines = np.append(all_path_baselines[idx], 0)
deltas = path['rewards'] + \
self.algo.discount * path_baselines[1:] - path_baselines[:-1]
path['advantages'] = special.discount_cumsum(
deltas, self.algo.discount * self.algo.gae_lambda)
path['returns'] = special.discount_cumsum(path['rewards'],
self.algo.discount)
baselines.append(path_baselines[:-1])
returns.append(path['returns'])
ev = special.explained_variance_1d(np.concatenate(baselines),
np.concatenate(returns))
if not self.algo.policy.recurrent:
observations = tensor_utils.concat_tensor_list(
[path['observations'] for path in paths])
actions = tensor_utils.concat_tensor_list(
[path['actions'] for path in paths])
rewards = tensor_utils.concat_tensor_list(
[path['rewards'] for path in paths])
returns = tensor_utils.concat_tensor_list(
[path['returns'] for path in paths])
advantages = tensor_utils.concat_tensor_list(
[path['advantages'] for path in paths])
env_infos = tensor_utils.concat_tensor_dict_list(
[path['env_infos'] for path in paths])
agent_infos = tensor_utils.concat_tensor_dict_list(
[path['agent_infos'] for path in paths])
if self.algo.center_adv:
advantages = utils.center_advantages(advantages)
if self.algo.positive_adv:
advantages = utils.shift_advantages_to_positive(advantages)
average_discounted_return = \
np.mean([path['returns'][0] for path in paths])
undiscounted_returns = [sum(path['rewards']) for path in paths]
ent = np.mean(self.algo.policy.distribution.entropy(agent_infos))
samples_data = dict(
observations=observations,
actions=actions,
rewards=rewards,
returns=returns,
advantages=advantages,
env_infos=env_infos,
agent_infos=agent_infos,
paths=paths,
)
else:
max_path_length = max([len(path['advantages']) for path in paths])
# make all paths the same length (pad extra advantages with 0)
obs = [path['observations'] for path in paths]
obs = tensor_utils.pad_tensor_n(obs, max_path_length)
if self.algo.center_adv:
raw_adv = np.concatenate(
[path['advantages'] for path in paths])
adv_mean = np.mean(raw_adv)
adv_std = np.std(raw_adv) + 1e-8
adv = [(path['advantages'] - adv_mean) / adv_std
for path in paths]
else:
adv = [path['advantages'] for path in paths]
adv = np.asarray(
[tensor_utils.pad_tensor(a, max_path_length) for a in adv])
actions = [path['actions'] for path in paths]
actions = tensor_utils.pad_tensor_n(actions, max_path_length)
rewards = [path['rewards'] for path in paths]
rewards = tensor_utils.pad_tensor_n(rewards, max_path_length)
returns = [path['returns'] for path in paths]
returns = tensor_utils.pad_tensor_n(returns, max_path_length)
agent_infos = [path['agent_infos'] for path in paths]
agent_infos = tensor_utils.stack_tensor_dict_list([
tensor_utils.pad_tensor_dict(p, max_path_length)
for p in agent_infos
])
env_infos = [path['env_infos'] for path in paths]
env_infos = tensor_utils.stack_tensor_dict_list([
tensor_utils.pad_tensor_dict(p, max_path_length)
for p in env_infos
])
valids = [np.ones_like(path['returns']) for path in paths]
valids = tensor_utils.pad_tensor_n(valids, max_path_length)
average_discounted_return = \
np.mean([path['returns'][0] for path in paths])
undiscounted_returns = [sum(path['rewards']) for path in paths]
ent = np.sum(
self.algo.policy.distribution.entropy(agent_infos) *
valids) / np.sum(valids)
samples_data = dict(
observations=obs,
actions=actions,
advantages=adv,
rewards=rewards,
returns=returns,
valids=valids,
agent_infos=agent_infos,
env_infos=env_infos,
paths=paths,
)
logger.log('fitting baseline...')
if hasattr(self.algo.baseline, 'fit_with_samples'):
self.algo.baseline.fit_with_samples(paths, samples_data)
else:
self.algo.baseline.fit(paths)
logger.log('fitted')
tabular.record('Iteration', itr)
tabular.record('AverageDiscountedReturn', average_discounted_return)
tabular.record('AverageReturn', np.mean(undiscounted_returns))
tabular.record('ExplainedVariance', ev)
tabular.record('NumTrajs', len(paths))
tabular.record('Entropy', ent)
tabular.record('Perplexity', np.exp(ent))
tabular.record('StdReturn', np.std(undiscounted_returns))
tabular.record('MaxReturn', np.max(undiscounted_returns))
tabular.record('MinReturn', np.min(undiscounted_returns))
return samples_data
def process_samples_discount(self, itr, paths):
baselines = []
returns = []
if hasattr(self.algo.baseline, "predict_n"):
all_path_baselines = self.algo.baseline.predict_n(paths)
else:
all_path_baselines = [
self.algo.baseline.predict(path) for path in paths
]
for idx, path in enumerate(paths):
advantages = []
path_returns = []
'''
path_baselines = all_path_baselines[idx]
return_so_far = 0
for t in range(len(path["rewards"])-1, -1, -1):
return_so_far = path["rewards"][t] + self.algo.discount * return_so_far
path_returns.append(return_so_far)
advantage = return_so_far - path_baselines[t]
advantages.append(advantage)
'''
path_baselines = np.append(all_path_baselines[idx], 0)
deltas = path["rewards"] + \
self.algo.discount * path_baselines[1:] - \
path_baselines[:-1]
advantages = special.discount_cumsum(
deltas, self.algo.discount * self.algo.gae_lambda)
# correction
discount_array = self.algo.discount**np.arange(len(
path["rewards"]))
path['advantages'] = advantages * discount_array
'''
path_returns = special.discount_cumsum(path["rewards"],
self.algo.discount)
path['returns'] = path_returns * discount_array
'''
path['returns'] = special.discount_cumsum(path["rewards"],
self.algo.discount)
baselines.append(path_baselines[:-1])
returns.append(path["returns"])
ev = special.explained_variance_1d(np.concatenate(baselines),
np.concatenate(returns))
observations = tensor_utils.concat_tensor_list(
[path["observations"] for path in paths])
actions = tensor_utils.concat_tensor_list(
[path["actions"] for path in paths])
rewards = tensor_utils.concat_tensor_list(
[path["rewards"] for path in paths])
returns = tensor_utils.concat_tensor_list(
[path["returns"] for path in paths])
advantages = tensor_utils.concat_tensor_list(
[path["advantages"] for path in paths])
env_infos = tensor_utils.concat_tensor_dict_list(
[path["env_infos"] for path in paths])
agent_infos = tensor_utils.concat_tensor_dict_list(
[path["agent_infos"] for path in paths])
if self.algo.center_adv:
advantages = utils.center_advantages(advantages)
if self.algo.positive_adv:
advantages = utils.shift_advantages_to_positive(advantages)
average_discounted_return = \
np.mean([path["returns"][0] for path in paths])
undiscounted_returns = [sum(path["rewards"]) for path in paths]
ent = np.mean(self.algo.policy.distribution.entropy(agent_infos))
samples_data = dict(
observations=observations,
actions=actions,
rewards=rewards,
returns=returns,
advantages=advantages,
env_infos=env_infos,
agent_infos=agent_infos,
paths=paths,
)
logger.log("fitting Exp_paper...")
if hasattr(self.algo.baseline, 'fit_with_samples'):
self.algo.baseline.fit_with_samples(paths, samples_data)
else:
self.algo.baseline.fit(paths)
logger.log("fitted")
logger.record_tabular('Iteration', itr)
logger.record_tabular('AverageDiscountedReturn',
average_discounted_return)
logger.record_tabular('AverageReturn', np.mean(undiscounted_returns))
logger.record_tabular('ExplainedVariance', ev)
logger.record_tabular('NumTrajs', len(paths))
logger.record_tabular('Entropy', ent)
logger.record_tabular('Perplexity', np.exp(ent))
logger.record_tabular('StdReturn', np.std(undiscounted_returns))
logger.record_tabular('MaxReturn', np.max(undiscounted_returns))
logger.record_tabular('MinReturn', np.min(undiscounted_returns))
return samples_data
