class PPOTrainer(BaseRLTrainer):
r"""Trainer class for PPO algorithm
Paper: https://arxiv.org/abs/1707.06347.
"""
supported_tasks = ["Nav-v0"]
def __init__(self, config=None):
super().__init__(config)
self.actor_critic = None
self.agent = None
self.envs = None
if config is not None:
logger.info(f"config: {config}")
self._static_encoder = False
self._encoder = None
def _setup_actor_critic_agent(self, ppo_cfg: Config) -> None:
r"""Sets up actor critic and agent for PPO.
Args:
ppo_cfg: config node with relevant params
Returns:
None
"""
logger.add_filehandler(self.config.LOG_FILE)
self.actor_critic = PointNavBaselinePolicy(
observation_space=self.envs.observation_spaces[0],
action_space=self.envs.action_spaces[0],
hidden_size=ppo_cfg.hidden_size,
goal_sensor_uuid=self.config.TASK_CONFIG.TASK.GOAL_SENSOR_UUID,
)
self.actor_critic.to(self.device)
self.agent = PPO(
actor_critic=self.actor_critic,
clip_param=ppo_cfg.clip_param,
ppo_epoch=ppo_cfg.ppo_epoch,
num_mini_batch=ppo_cfg.num_mini_batch,
value_loss_coef=ppo_cfg.value_loss_coef,
entropy_coef=ppo_cfg.entropy_coef,
lr=ppo_cfg.lr,
eps=ppo_cfg.eps,
max_grad_norm=ppo_cfg.max_grad_norm,
use_normalized_advantage=ppo_cfg.use_normalized_advantage,
)
def save_checkpoint(self,
file_name: str,
extra_state: Optional[Dict] = None) -> None:
r"""Save checkpoint with specified name.
Args:
file_name: file name for checkpoint
Returns:
None
"""
checkpoint = {
"state_dict": self.agent.state_dict(),
"config": self.config,
}
if extra_state is not None:
checkpoint["extra_state"] = extra_state
torch.save(checkpoint,
os.path.join(self.config.CHECKPOINT_FOLDER, file_name))
def load_checkpoint(self, checkpoint_path: str, *args, **kwargs) -> Dict:
r"""Load checkpoint of specified path as a dict.
Args:
checkpoint_path: path of target checkpoint
*args: additional positional args
**kwargs: additional keyword args
Returns:
dict containing checkpoint info
"""
return torch.load(checkpoint_path, *args, **kwargs)
METRICS_BLACKLIST = {"top_down_map", "collisions.is_collision"}
@classmethod
def _extract_scalars_from_info(cls, info: Dict[str,
Any]) -> Dict[str, float]:
result = {}
for k, v in info.items():
if k in cls.METRICS_BLACKLIST:
continue
if isinstance(v, dict):
result.update({
k + "." + subk: subv
for subk, subv in cls._extract_scalars_from_info(
v).items()
if (k + "." + subk) not in cls.METRICS_BLACKLIST
})
# Things that are scalar-like will have an np.size of 1.
# Strings also have an np.size of 1, so explicitly ban those
elif np.size(v) == 1 and not isinstance(v, str):
result[k] = float(v)
return result
@classmethod
def _extract_scalars_from_infos(
cls, infos: List[Dict[str, Any]]) -> Dict[str, List[float]]:
results = defaultdict(list)
for i in range(len(infos)):
for k, v in cls._extract_scalars_from_info(infos[i]).items():
results[k].append(v)
return results
def _collect_rollout_step(self, rollouts, current_episode_reward,
running_episode_stats):
pth_time = 0.0
env_time = 0.0
t_sample_action = time.time()
# sample actions
with torch.no_grad():
step_observation = {
k: v[rollouts.step]
for k, v in rollouts.observations.items()
}
(
values,
actions,
actions_log_probs,
recurrent_hidden_states,
) = self.actor_critic.act(
step_observation,
rollouts.recurrent_hidden_states[rollouts.step],
rollouts.prev_actions[rollouts.step],
rollouts.masks[rollouts.step],
)
pth_time += time.time() - t_sample_action
t_step_env = time.time()
outputs = self.envs.step([a[0].item() for a in actions])
observations, rewards, dones, infos = [list(x) for x in zip(*outputs)]
env_time += time.time() - t_step_env
t_update_stats = time.time()
batch = batch_obs(observations, device=self.device)
rewards = torch.tensor(rewards,
dtype=torch.float,
device=current_episode_reward.device)
rewards = rewards.unsqueeze(1)
masks = torch.tensor(
[[0.0] if done else [1.0] for done in dones],
dtype=torch.float,
device=current_episode_reward.device,
)
current_episode_reward += rewards
running_episode_stats["reward"] += (1 - masks) * current_episode_reward
running_episode_stats["count"] += 1 - masks
for k, v in self._extract_scalars_from_infos(infos).items():
v = torch.tensor(v,
dtype=torch.float,
device=current_episode_reward.device).unsqueeze(1)
if k not in running_episode_stats:
running_episode_stats[k] = torch.zeros_like(
running_episode_stats["count"])
running_episode_stats[k] += (1 - masks) * v
current_episode_reward *= masks
if self._static_encoder:
with torch.no_grad():
batch["prev_visual_features"] = step_observation[
"visual_features"]
batch["visual_features"] = self._encoder(batch)
rollouts.insert(
batch,
recurrent_hidden_states,
actions,
actions_log_probs,
values,
rewards,
masks,
)
pth_time += time.time() - t_update_stats
return pth_time, env_time, self.envs.num_envs
def _update_agent(self, ppo_cfg, rollouts):
t_update_model = time.time()
with torch.no_grad():
last_observation = {
k: v[rollouts.step]
for k, v in rollouts.observations.items()
}
next_value = self.actor_critic.get_value(
last_observation,
rollouts.recurrent_hidden_states[rollouts.step],
rollouts.prev_actions[rollouts.step],
rollouts.masks[rollouts.step],
).detach()
rollouts.compute_returns(next_value, ppo_cfg.use_gae, ppo_cfg.gamma,
ppo_cfg.tau)
value_loss, action_loss, dist_entropy, query_loss = self.agent.update(
rollouts)
rollouts.after_update()
return (
time.time() - t_update_model,
value_loss,
action_loss,
dist_entropy,
query_loss,
)
def train(self) -> None:
r"""Main method for training PPO.
Returns:
None
"""
self.envs = construct_envs(self.config,
get_env_class(self.config.ENV_NAME))
ppo_cfg = self.config.RL.PPO
self.device = (torch.device("cuda", self.config.TORCH_GPU_ID)
if torch.cuda.is_available() else torch.device("cpu"))
if not os.path.isdir(self.config.CHECKPOINT_FOLDER):
os.makedirs(self.config.CHECKPOINT_FOLDER)
self._setup_actor_critic_agent(ppo_cfg)
logger.info("agent number of parameters: {}".format(
sum(param.numel() for param in self.agent.parameters())))
rollouts = RolloutStorage(
ppo_cfg.num_steps,
self.envs.num_envs,
self.envs.observation_spaces[0],
self.envs.action_spaces[0],
ppo_cfg.hidden_size,
)
rollouts.to(self.device)
observations = self.envs.reset()
batch = batch_obs(observations, device=self.device)
for sensor in rollouts.observations:
rollouts.observations[sensor][0].copy_(batch[sensor])
# batch and observations may contain shared PyTorch CUDA
# tensors. We must explicitly clear them here otherwise
# they will be kept in memory for the entire duration of training!
batch = None
observations = None
current_episode_reward = torch.zeros(self.envs.num_envs, 1)
running_episode_stats = dict(
count=torch.zeros(self.envs.num_envs, 1),
reward=torch.zeros(self.envs.num_envs, 1),
)
window_episode_stats = defaultdict(
lambda: deque(maxlen=ppo_cfg.reward_window_size))
t_start = time.time()
env_time = 0
pth_time = 0
count_steps = 0
count_checkpoints = 0
lr_scheduler = LambdaLR(
optimizer=self.agent.optimizer,
lr_lambda=lambda x: linear_decay(x, self.config.NUM_UPDATES),
)
with TensorboardWriter(self.config.TENSORBOARD_DIR,
flush_secs=self.flush_secs) as writer:
for update in range(self.config.NUM_UPDATES):
if ppo_cfg.use_linear_lr_decay:
lr_scheduler.step()
if ppo_cfg.use_linear_clip_decay:
self.agent.clip_param = ppo_cfg.clip_param * linear_decay(
update, self.config.NUM_UPDATES)
for step in range(ppo_cfg.num_steps):
(
delta_pth_time,
delta_env_time,
delta_steps,
) = self._collect_rollout_step(rollouts,
current_episode_reward,
running_episode_stats)
pth_time += delta_pth_time
env_time += delta_env_time
count_steps += delta_steps
(
delta_pth_time,
value_loss,
action_loss,
dist_entropy,
) = self._update_agent(ppo_cfg, rollouts)
pth_time += delta_pth_time
for k, v in running_episode_stats.items():
window_episode_stats[k].append(v.clone())
deltas = {
k:
((v[-1] -
v[0]).sum().item() if len(v) > 1 else v[0].sum().item())
for k, v in window_episode_stats.items()
}
deltas["count"] = max(deltas["count"], 1.0)
writer.add_scalar("reward", deltas["reward"] / deltas["count"],
count_steps)
# Check to see if there are any metrics
# that haven't been logged yet
metrics = {
k: v / deltas["count"]
for k, v in deltas.items() if k not in {"reward", "count"}
}
if len(metrics) > 0:
writer.add_scalars("metrics", metrics, count_steps)
losses = [value_loss, action_loss]
writer.add_scalars(
"losses",
{k: l
for l, k in zip(losses, ["value", "policy"])},
count_steps,
)
# log stats
if update > 0 and update % self.config.LOG_INTERVAL == 0:
logger.info("update: {}\tfps: {:.3f}\t".format(
update, count_steps / (time.time() - t_start)))
logger.info(
"update: {}\tenv-time: {:.3f}s\tpth-time: {:.3f}s\t"
"frames: {}".format(update, env_time, pth_time,
count_steps))
logger.info("Average window size: {} {}".format(
len(window_episode_stats["count"]),
" ".join("{}: {:.3f}".format(k, v / deltas["count"])
for k, v in deltas.items() if k != "count"),
))
# checkpoint model
if update % self.config.CHECKPOINT_INTERVAL == 0:
self.save_checkpoint(f"ckpt.{count_checkpoints}.pth",
dict(step=count_steps))
count_checkpoints += 1
self.envs.close()
def _eval_checkpoint(
self,
checkpoint_path: str,
writer: TensorboardWriter,
checkpoint_index: int = 0,
) -> None:
r"""Evaluates a single checkpoint.
Args:
checkpoint_path: path of checkpoint
writer: tensorboard writer object for logging to tensorboard
checkpoint_index: index of cur checkpoint for logging
Returns:
None
"""
# Map location CPU is almost always better than mapping to a CUDA device.
ckpt_dict = self.load_checkpoint(checkpoint_path, map_location="cpu")
if self.config.EVAL.USE_CKPT_CONFIG:
config = self._setup_eval_config(ckpt_dict["config"])
else:
config = self.config.clone()
ppo_cfg = config.RL.PPO
config.defrost()
config.TASK_CONFIG.DATASET.SPLIT = config.EVAL.SPLIT
config.freeze()
if len(self.config.VIDEO_OPTION) > 0:
config.defrost()
config.TASK_CONFIG.TASK.MEASUREMENTS.append("TOP_DOWN_MAP")
config.TASK_CONFIG.TASK.MEASUREMENTS.append("COLLISIONS")
config.freeze()
logger.info(f"env config: {config}")
self.envs = construct_envs(config, get_env_class(config.ENV_NAME))
self._setup_actor_critic_agent(ppo_cfg)
self.actor_critic.eval()
if self._static_encoder:
self._encoder = self.agent.actor_critic.net.visual_encoder
self.agent.load_state_dict(ckpt_dict["state_dict"])
self.actor_critic = self.agent.actor_critic
observations = self.envs.reset()
batch = batch_obs(observations, device=self.device)
if self._static_encoder:
batch["visual_features"] = self._encoder(batch)
batch["prev_visual_features"] = torch.zeros_like(
batch["visual_features"])
current_episode_reward = torch.zeros(self.envs.num_envs,
1,
device=self.device)
test_recurrent_hidden_states = torch.zeros(
self.actor_critic.net.num_recurrent_layers,
self.config.NUM_PROCESSES,
ppo_cfg.hidden_size,
device=self.device,
)
prev_actions = torch.zeros(self.config.NUM_PROCESSES,
1,
device=self.device,
dtype=torch.long)
not_done_masks = torch.zeros(self.config.NUM_PROCESSES,
1,
device=self.device)
stats_episodes = dict() # dict of dicts that stores stats per episode
rgb_frames = [[] for _ in range(self.config.NUM_PROCESSES)
] # type: List[List[np.ndarray]]
if len(self.config.VIDEO_OPTION) > 0:
os.makedirs(self.config.VIDEO_DIR, exist_ok=True)
number_of_eval_episodes = self.config.TEST_EPISODE_COUNT
if number_of_eval_episodes == -1:
number_of_eval_episodes = sum(self.envs.number_of_episodes)
else:
total_num_eps = sum(self.envs.number_of_episodes)
if total_num_eps < number_of_eval_episodes:
logger.warn(
f"Config specified {number_of_eval_episodes} eval episodes"
", dataset only has {total_num_eps}.")
logger.warn(f"Evaluating with {total_num_eps} instead.")
number_of_eval_episodes = total_num_eps
pbar = tqdm.tqdm(total=number_of_eval_episodes)
self.actor_critic.eval()
while (len(stats_episodes) < number_of_eval_episodes
and self.envs.num_envs > 0):
current_episodes = self.envs.current_episodes()
with torch.no_grad():
step_batch = batch
(
_,
actions,
_,
test_recurrent_hidden_states,
) = self.actor_critic.act(
batch,
test_recurrent_hidden_states,
prev_actions,
not_done_masks,
deterministic=False,
)
prev_actions.copy_(actions)
outputs = self.envs.step([a[0].item() for a in actions])
observations, rewards, dones, infos = [
list(x) for x in zip(*outputs)
]
batch = batch_obs(observations, device=self.device)
if self._static_encoder:
batch["prev_visual_features"] = step_batch["visual_features"]
batch["visual_features"] = self._encoder(batch)
not_done_masks = torch.tensor(
[[0.0] if done else [1.0] for done in dones],
dtype=torch.float,
device=self.device,
)
rewards = torch.tensor(rewards,
dtype=torch.float,
device=self.device).unsqueeze(1)
current_episode_reward += rewards
next_episodes = self.envs.current_episodes()
envs_to_pause = []
n_envs = self.envs.num_envs
for i in range(n_envs):
if (
next_episodes[i].scene_id,
next_episodes[i].episode_id,
) in stats_episodes:
envs_to_pause.append(i)
# episode ended
if not_done_masks[i].item() == 0:
pbar.update()
episode_stats = dict()
episode_stats["reward"] = current_episode_reward[i].item()
episode_stats.update(
self._extract_scalars_from_info(infos[i]))
current_episode_reward[i] = 0
# use scene_id + episode_id as unique id for storing stats
stats_episodes[(
current_episodes[i].scene_id,
current_episodes[i].episode_id,
)] = episode_stats
if len(self.config.VIDEO_OPTION) > 0:
generate_video(
video_option=self.config.VIDEO_OPTION,
video_dir=self.config.VIDEO_DIR,
images=rgb_frames[i],
episode_id=current_episodes[i].episode_id,
checkpoint_idx=checkpoint_index,
metrics=self._extract_scalars_from_info(infos[i]),
tb_writer=writer,
)
rgb_frames[i] = []
# episode continues
elif len(self.config.VIDEO_OPTION) > 0:
frame = observations_to_image(observations[i], infos[i])
rgb_frames[i].append(frame)
(
self.envs,
test_recurrent_hidden_states,
not_done_masks,
current_episode_reward,
prev_actions,
batch,
rgb_frames,
) = self._pause_envs(
envs_to_pause,
self.envs,
test_recurrent_hidden_states,
not_done_masks,
current_episode_reward,
prev_actions,
batch,
rgb_frames,
)
num_episodes = len(stats_episodes)
aggregated_stats = dict()
for stat_key in next(iter(stats_episodes.values())).keys():
aggregated_stats[stat_key] = (
sum([v[stat_key]
for v in stats_episodes.values()]) / num_episodes)
for k, v in aggregated_stats.items():
logger.info(f"Average episode {k}: {v:.4f}")
step_id = checkpoint_index
if "extra_state" in ckpt_dict and "step" in ckpt_dict["extra_state"]:
step_id = ckpt_dict["extra_state"]["step"]
writer.add_scalars(
"eval_reward",
{"average reward": aggregated_stats["reward"]},
step_id,
)
metrics = {k: v for k, v in aggregated_stats.items() if k != "reward"}
if len(metrics) > 0:
writer.add_scalars("eval_metrics", metrics, step_id)
self.envs.close()
class PPOTrainer(BaseRLTrainer):
r"""Trainer class for PPO algorithm
Paper: https://arxiv.org/abs/1707.06347.
"""
supported_tasks = ["Nav-v0"]
def __init__(self, config=None):
super().__init__(config)
self.actor_critic = None
self.agent = None
self.envs = None
if config is not None:
logger.info(f"config: {config}")
def _setup_actor_critic_agent(self, ppo_cfg: Config) -> None:
r"""Sets up actor critic and agent for PPO.
Args:
ppo_cfg: config node with relevant params
Returns:
None
"""
logger.add_filehandler(self.config.LOG_FILE)
self.actor_critic = PointNavBaselinePolicy(
observation_space=self.envs.observation_spaces[0],
action_space=self.envs.action_spaces[0],
hidden_size=ppo_cfg.hidden_size,
goal_sensor_uuid=self.config.TASK_CONFIG.TASK.GOAL_SENSOR_UUID,
)
self.actor_critic.to(self.device)
self.agent = PPO(
actor_critic=self.actor_critic,
clip_param=ppo_cfg.clip_param,
ppo_epoch=ppo_cfg.ppo_epoch,
num_mini_batch=ppo_cfg.num_mini_batch,
value_loss_coef=ppo_cfg.value_loss_coef,
entropy_coef=ppo_cfg.entropy_coef,
lr=ppo_cfg.lr,
eps=ppo_cfg.eps,
max_grad_norm=ppo_cfg.max_grad_norm,
)
def save_checkpoint(self, file_name: str) -> None:
r"""Save checkpoint with specified name.
Args:
file_name: file name for checkpoint
Returns:
None
"""
checkpoint = {
"state_dict": self.agent.state_dict(),
"config": self.config,
}
torch.save(checkpoint,
os.path.join(self.config.CHECKPOINT_FOLDER, file_name))
def load_checkpoint(self, checkpoint_path: str, *args, **kwargs) -> Dict:
r"""Load checkpoint of specified path as a dict.
Args:
checkpoint_path: path of target checkpoint
*args: additional positional args
**kwargs: additional keyword args
Returns:
dict containing checkpoint info
"""
return torch.load(checkpoint_path, map_location=self.device)
def _collect_rollout_step(self, rollouts, current_episode_reward,
episode_rewards, episode_counts):
pth_time = 0.0
env_time = 0.0
t_sample_action = time.time()
# sample actions
with torch.no_grad():
step_observation = {
k: v[rollouts.step]
for k, v in rollouts.observations.items()
}
(
values,
actions,
actions_log_probs,
recurrent_hidden_states,
) = self.actor_critic.act(
step_observation,
rollouts.recurrent_hidden_states[rollouts.step],
rollouts.prev_actions[rollouts.step],
rollouts.masks[rollouts.step],
)
pth_time += time.time() - t_sample_action
t_step_env = time.time()
outputs = self.envs.step([a[0].item() for a in actions])
observations, rewards, dones, infos = [list(x) for x in zip(*outputs)]
env_time += time.time() - t_step_env
t_update_stats = time.time()
batch = batch_obs(observations)
rewards = torch.tensor(rewards, dtype=torch.float)
rewards = rewards.unsqueeze(1)
masks = torch.tensor([[0.0] if done else [1.0] for done in dones],
dtype=torch.float)
current_episode_reward += rewards
episode_rewards += (1 - masks) * current_episode_reward
episode_counts += 1 - masks
current_episode_reward *= masks
rollouts.insert(
batch,
recurrent_hidden_states,
actions,
actions_log_probs,
values,
rewards,
masks,
)
pth_time += time.time() - t_update_stats
return pth_time, env_time, self.envs.num_envs
def _update_agent(self, ppo_cfg, rollouts):
t_update_model = time.time()
with torch.no_grad():
last_observation = {
k: v[-1]
for k, v in rollouts.observations.items()
}
next_value = self.actor_critic.get_value(
last_observation,
rollouts.recurrent_hidden_states[-1],
rollouts.prev_actions[-1],
rollouts.masks[-1],
).detach()
rollouts.compute_returns(next_value, ppo_cfg.use_gae, ppo_cfg.gamma,
ppo_cfg.tau)
value_loss, action_loss, dist_entropy = self.agent.update(rollouts)
rollouts.after_update()
return (
time.time() - t_update_model,
value_loss,
action_loss,
dist_entropy,
)
def train(self) -> None:
r"""Main method for training PPO.
Returns:
None
"""
self.envs = construct_envs(self.config,
get_env_class(self.config.ENV_NAME))
ppo_cfg = self.config.RL.PPO
self.device = torch.device("cuda", self.config.TORCH_GPU_ID)
if not os.path.isdir(self.config.CHECKPOINT_FOLDER):
os.makedirs(self.config.CHECKPOINT_FOLDER)
self._setup_actor_critic_agent(ppo_cfg)
logger.info("agent number of parameters: {}".format(
sum(param.numel() for param in self.agent.parameters())))
observations = self.envs.reset()
batch = batch_obs(observations)
rollouts = RolloutStorage(
ppo_cfg.num_steps,
self.envs.num_envs,
self.envs.observation_spaces[0],
self.envs.action_spaces[0],
ppo_cfg.hidden_size,
)
for sensor in rollouts.observations:
rollouts.observations[sensor][0].copy_(batch[sensor])
rollouts.to(self.device)
episode_rewards = torch.zeros(self.envs.num_envs, 1)
episode_counts = torch.zeros(self.envs.num_envs, 1)
current_episode_reward = torch.zeros(self.envs.num_envs, 1)
window_episode_reward = deque(maxlen=ppo_cfg.reward_window_size)
window_episode_counts = deque(maxlen=ppo_cfg.reward_window_size)
t_start = time.time()
env_time = 0
pth_time = 0
count_steps = 0
count_checkpoints = 0
lr_scheduler = LambdaLR(
optimizer=self.agent.optimizer,
lr_lambda=lambda x: linear_decay(x, self.config.NUM_UPDATES),
)
with TensorboardWriter(self.config.TENSORBOARD_DIR,
flush_secs=self.flush_secs) as writer:
for update in range(self.config.NUM_UPDATES):
if ppo_cfg.use_linear_lr_decay:
lr_scheduler.step()
if ppo_cfg.use_linear_clip_decay:
self.agent.clip_param = ppo_cfg.clip_param * linear_decay(
update, self.config.NUM_UPDATES)
for step in range(ppo_cfg.num_steps):
delta_pth_time, delta_env_time, delta_steps = self._collect_rollout_step(
rollouts,
current_episode_reward,
episode_rewards,
episode_counts,
)
pth_time += delta_pth_time
env_time += delta_env_time
count_steps += delta_steps
delta_pth_time, value_loss, action_loss, dist_entropy = self._update_agent(
ppo_cfg, rollouts)
pth_time += delta_pth_time
window_episode_reward.append(episode_rewards.clone())
window_episode_counts.append(episode_counts.clone())
losses = [value_loss, action_loss]
stats = zip(
["count", "reward"],
[window_episode_counts, window_episode_reward],
)
deltas = {
k:
((v[-1] -
v[0]).sum().item() if len(v) > 1 else v[0].sum().item())
for k, v in stats
}
deltas["count"] = max(deltas["count"], 1.0)
writer.add_scalar("reward", deltas["reward"] / deltas["count"],
count_steps)
writer.add_scalars(
"losses",
{k: l
for l, k in zip(losses, ["value", "policy"])},
count_steps,
)
# log stats
if update > 0 and update % self.config.LOG_INTERVAL == 0:
logger.info("update: {}\tfps: {:.3f}\t".format(
update, count_steps / (time.time() - t_start)))
logger.info(
"update: {}\tenv-time: {:.3f}s\tpth-time: {:.3f}s\t"
"frames: {}".format(update, env_time, pth_time,
count_steps))
window_rewards = (window_episode_reward[-1] -
window_episode_reward[0]).sum()
window_counts = (window_episode_counts[-1] -
window_episode_counts[0]).sum()
if window_counts > 0:
logger.info(
"Average window size {} reward: {:3f}".format(
len(window_episode_reward),
(window_rewards / window_counts).item(),
))
else:
logger.info("No episodes finish in current window")
# checkpoint model
if update % self.config.CHECKPOINT_INTERVAL == 0:
self.save_checkpoint(f"ckpt.{count_checkpoints}.pth")
count_checkpoints += 1
self.envs.close()
def _eval_checkpoint(
self,
checkpoint_path: str,
writer: TensorboardWriter,
checkpoint_index: int = 0,
) -> None:
r"""Evaluates a single checkpoint.
Args:
checkpoint_path: path of checkpoint
writer: tensorboard writer object for logging to tensorboard
checkpoint_index: index of cur checkpoint for logging
Returns:
None
"""
ckpt_dict = self.load_checkpoint(checkpoint_path,
map_location=self.device)
config = self._setup_eval_config(ckpt_dict["config"])
ppo_cfg = config.RL.PPO
if len(self.config.VIDEO_OPTION) > 0:
config.defrost()
config.TASK_CONFIG.TASK.MEASUREMENTS.append("TOP_DOWN_MAP")
config.TASK_CONFIG.TASK.MEASUREMENTS.append("COLLISIONS")
config.freeze()
logger.info(f"env config: {config}")
self.envs = construct_envs(self.config,
get_env_class(self.config.ENV_NAME))
self._setup_actor_critic_agent(ppo_cfg)
self.agent.load_state_dict(ckpt_dict["state_dict"])
self.actor_critic = self.agent.actor_critic
# get name of performance metric, e.g. "spl"
metric_name = self.config.TASK_CONFIG.TASK.MEASUREMENTS[0]
metric_cfg = getattr(self.config.TASK_CONFIG.TASK, metric_name)
measure_type = baseline_registry.get_measure(metric_cfg.TYPE)
assert measure_type is not None, "invalid measurement type {}".format(
metric_cfg.TYPE)
self.metric_uuid = measure_type(None, None)._get_uuid()
observations = self.envs.reset()
batch = batch_obs(observations)
for sensor in batch:
batch[sensor] = batch[sensor].to(self.device)
current_episode_reward = torch.zeros(self.envs.num_envs,
1,
device=self.device)
test_recurrent_hidden_states = torch.zeros(
self.actor_critic.net.num_recurrent_layers,
self.config.NUM_PROCESSES,
ppo_cfg.hidden_size,
device=self.device,
)
prev_actions = torch.zeros(self.config.NUM_PROCESSES,
1,
device=self.device,
dtype=torch.long)
not_done_masks = torch.zeros(self.config.NUM_PROCESSES,
1,
device=self.device)
stats_episodes = dict() # dict of dicts that stores stats per episode
rgb_frames = [
[]
] * self.config.NUM_PROCESSES # type: List[List[np.ndarray]]
if len(self.config.VIDEO_OPTION) > 0:
os.makedirs(self.config.VIDEO_DIR, exist_ok=True)
while (len(stats_episodes) < self.config.TEST_EPISODE_COUNT
and self.envs.num_envs > 0):
current_episodes = self.envs.current_episodes()
with torch.no_grad():
_, actions, _, test_recurrent_hidden_states = self.actor_critic.act(
batch,
test_recurrent_hidden_states,
prev_actions,
not_done_masks,
deterministic=False,
)
prev_actions.copy_(actions)
outputs = self.envs.step([a[0].item() for a in actions])
observations, rewards, dones, infos = [
list(x) for x in zip(*outputs)
]
batch = batch_obs(observations)
for sensor in batch:
batch[sensor] = batch[sensor].to(self.device)
not_done_masks = torch.tensor(
[[0.0] if done else [1.0] for done in dones],
dtype=torch.float,
device=self.device,
)
rewards = torch.tensor(rewards,
dtype=torch.float,
device=self.device).unsqueeze(1)
current_episode_reward += rewards
next_episodes = self.envs.current_episodes()
envs_to_pause = []
n_envs = self.envs.num_envs
for i in range(n_envs):
if (
next_episodes[i].scene_id,
next_episodes[i].episode_id,
) in stats_episodes:
envs_to_pause.append(i)
# episode ended
if not_done_masks[i].item() == 0:
episode_stats = dict()
episode_stats[self.metric_uuid] = infos[i][
self.metric_uuid]
episode_stats["success"] = int(
infos[i][self.metric_uuid] > 0)
episode_stats["reward"] = current_episode_reward[i].item()
current_episode_reward[i] = 0
# use scene_id + episode_id as unique id for storing stats
stats_episodes[(
current_episodes[i].scene_id,
current_episodes[i].episode_id,
)] = episode_stats
if len(self.config.VIDEO_OPTION) > 0:
generate_video(
video_option=self.config.VIDEO_OPTION,
video_dir=self.config.VIDEO_DIR,
images=rgb_frames[i],
episode_id=current_episodes[i].episode_id,
checkpoint_idx=checkpoint_index,
metric_name=self.metric_uuid,
metric_value=infos[i][self.metric_uuid],
tb_writer=writer,
)
rgb_frames[i] = []
# episode continues
elif len(self.config.VIDEO_OPTION) > 0:
frame = observations_to_image(observations[i], infos[i])
rgb_frames[i].append(frame)
# pausing self.envs with no new episode
if len(envs_to_pause) > 0:
state_index = list(range(self.envs.num_envs))
for idx in reversed(envs_to_pause):
state_index.pop(idx)
self.envs.pause_at(idx)
# indexing along the batch dimensions
test_recurrent_hidden_states = test_recurrent_hidden_states[
state_index]
not_done_masks = not_done_masks[state_index]
current_episode_reward = current_episode_reward[state_index]
prev_actions = prev_actions[state_index]
for k, v in batch.items():
batch[k] = v[state_index]
if len(self.config.VIDEO_OPTION) > 0:
rgb_frames = [rgb_frames[i] for i in state_index]
aggregated_stats = dict()
for stat_key in next(iter(stats_episodes.values())).keys():
aggregated_stats[stat_key] = sum(
[v[stat_key] for v in stats_episodes.values()])
num_episodes = len(stats_episodes)
episode_reward_mean = aggregated_stats["reward"] / num_episodes
episode_metric_mean = aggregated_stats[self.metric_uuid] / num_episodes
episode_success_mean = aggregated_stats["success"] / num_episodes
logger.info(f"Average episode reward: {episode_reward_mean:.6f}")
logger.info(f"Average episode success: {episode_success_mean:.6f}")
logger.info(
f"Average episode {self.metric_uuid}: {episode_metric_mean:.6f}")
writer.add_scalars(
"eval_reward",
{"average reward": episode_reward_mean},
checkpoint_index,
)
writer.add_scalars(
f"eval_{self.metric_uuid}",
{f"average {self.metric_uuid}": episode_metric_mean},
checkpoint_index,
)
writer.add_scalars(
"eval_success",
{"average success": episode_success_mean},
checkpoint_index,
)
self.envs.close()