def run_test_replay_buffer(
env: Env__Union,
model: ModelManager__Union,
replay_memory_size: int,
train_every_ts: int,
train_after_ts: int,
num_train_episodes: int,
passing_score_bar: float,
num_eval_episodes: int,
use_gpu: bool,
minibatch_size: Optional[int] = None,
):
"""
Run an online learning test with a replay buffer. The replay buffer is pre-filled, then the training starts.
Each transition is added to the replay buffer immediately after it takes place.
"""
env = env.value
# pyre-fixme[16]: Module `pl` has no attribute `seed_everything`.
pl.seed_everything(SEED)
env.seed(SEED)
env.action_space.seed(SEED)
normalization = build_normalizer(env)
logger.info(f"Normalization is: \n{pprint.pformat(normalization)}")
manager = model.value
trainer = manager.initialize_trainer(
use_gpu=use_gpu,
reward_options=RewardOptions(),
normalization_data_map=normalization,
)
training_policy = manager.create_policy(serving=False)
# pyre-fixme[16]: Module `pl` has no attribute `LightningModule`.
if not isinstance(trainer, pl.LightningModule):
if minibatch_size is None:
minibatch_size = trainer.minibatch_size
assert minibatch_size == trainer.minibatch_size
assert minibatch_size is not None
replay_buffer = ReplayBuffer(replay_capacity=replay_memory_size,
batch_size=minibatch_size)
device = torch.device("cuda") if use_gpu else torch.device("cpu")
# first fill the replay buffer using random policy
train_after_ts = max(train_after_ts, minibatch_size)
fill_replay_buffer(env=env,
replay_buffer=replay_buffer,
desired_size=train_after_ts)
agent = Agent.create_for_env(env, policy=training_policy, device=device)
# TODO: Simplify this setup by creating LightningDataModule
dataset = ReplayBufferDataset.create_for_trainer(
trainer,
env,
agent,
replay_buffer,
batch_size=minibatch_size,
training_frequency=train_every_ts,
num_episodes=num_train_episodes,
max_steps=200,
device=device,
)
data_loader = torch.utils.data.DataLoader(dataset,
collate_fn=identity_collate)
# pyre-fixme[16]: Module `pl` has no attribute `Trainer`.
pl_trainer = pl.Trainer(max_epochs=1, gpus=int(use_gpu))
# Note: the fit() function below also evaluates the agent along the way
# and adds the new transitions to the replay buffer, so it is training
# on incrementally larger and larger buffers.
pl_trainer.fit(trainer, data_loader)
# TODO: Also check train_reward
serving_policy = manager.create_policy(serving=True)
eval_rewards = eval_policy(env,
serving_policy,
num_eval_episodes,
serving=True)
assert (
eval_rewards.mean() >= passing_score_bar
), f"Eval reward is {eval_rewards.mean()}, less than < {passing_score_bar}.\n"
def run_test_online_episode(
env: Env__Union,
model: ModelManager__Union,
num_train_episodes: int,
passing_score_bar: float,
num_eval_episodes: int,
use_gpu: bool,
):
"""
Run an online learning test. At the end of each episode training is run on the trajectory.
"""
env = env.value
# pyre-fixme[16]: Module `pl` has no attribute `seed_everything`.
pl.seed_everything(SEED)
env.seed(SEED)
env.action_space.seed(SEED)
normalization = build_normalizer(env)
logger.info(f"Normalization is: \n{pprint.pformat(normalization)}")
manager = model.value
trainer = manager.initialize_trainer(
use_gpu=use_gpu,
reward_options=RewardOptions(),
normalization_data_map=normalization,
)
policy = manager.create_policy(serving=False)
device = torch.device("cuda") if use_gpu else torch.device("cpu")
agent = Agent.create_for_env(env, policy, device=device)
# pyre-fixme[16]: Module `pl` has no attribute `LightningModule`.
if isinstance(trainer, pl.LightningModule):
# pyre-fixme[16]: Module `pl` has no attribute `Trainer`.
pl_trainer = pl.Trainer(max_epochs=1,
gpus=int(use_gpu),
deterministic=True)
dataset = EpisodicDataset(env=env,
agent=agent,
num_episodes=num_train_episodes,
seed=SEED)
pl_trainer.fit(trainer, dataset)
else:
post_episode_callback = train_post_episode(env, trainer, use_gpu)
_ = train_policy(
env,
policy,
num_train_episodes,
post_step=None,
post_episode=post_episode_callback,
use_gpu=use_gpu,
)
eval_rewards = evaluate_for_n_episodes(
n=num_eval_episodes,
env=env,
agent=agent,
max_steps=env.max_steps,
num_processes=1,
).squeeze(1)
assert (
eval_rewards.mean() >= passing_score_bar
), f"Eval reward is {eval_rewards.mean()}, less than < {passing_score_bar}.\n"
def train_mdnrnn_and_train_on_embedded_env(
env_name: str,
embedding_model: ModelManager__Union,
num_embedding_train_transitions: int,
seq_len: int,
batch_size: int,
num_embedding_train_epochs: int,
train_model: ModelManager__Union,
num_state_embed_transitions: int,
num_agent_train_epochs: int,
num_agent_eval_epochs: int,
use_gpu: bool,
passing_score_bar: float,
# pyre-fixme[9]: saved_mdnrnn_path has type `str`; used as `None`.
saved_mdnrnn_path: str = None,
):
""" Train an agent on embedded states by the MDNRNN. """
env = Gym(env_name=env_name)
env.seed(SEED)
embedding_manager = embedding_model.value
embedding_trainer = embedding_manager.initialize_trainer(
use_gpu=use_gpu,
reward_options=RewardOptions(),
normalization_data_map=build_normalizer(env),
)
device = "cuda" if use_gpu else "cpu"
embedding_trainer_preprocessor = make_replay_buffer_trainer_preprocessor(
embedding_trainer,
# pyre-fixme[6]: Expected `device` for 2nd param but got `str`.
device,
env,
)
if saved_mdnrnn_path is None:
# train from scratch
embedding_trainer = train_mdnrnn(
env=env,
trainer=embedding_trainer,
trainer_preprocessor=embedding_trainer_preprocessor,
num_train_transitions=num_embedding_train_transitions,
seq_len=seq_len,
batch_size=batch_size,
num_train_epochs=num_embedding_train_epochs,
)
else:
# load a pretrained model, and just evaluate it
embedding_trainer.memory_network.mdnrnn.load_state_dict(
torch.load(saved_mdnrnn_path))
# create embedding dataset
embed_rb, state_min, state_max = create_embed_rl_dataset(
env=env,
memory_network=embedding_trainer.memory_network,
num_state_embed_transitions=num_state_embed_transitions,
batch_size=batch_size,
seq_len=seq_len,
hidden_dim=embedding_trainer.params.hidden_size,
use_gpu=use_gpu,
)
embed_env = StateEmbedEnvironment(
gym_env=env,
mdnrnn=embedding_trainer.memory_network,
max_embed_seq_len=seq_len,
state_min_value=state_min,
state_max_value=state_max,
)
agent_manager = train_model.value
agent_trainer = agent_manager.initialize_trainer(
use_gpu=use_gpu,
reward_options=RewardOptions(),
# pyre-fixme[6]: Expected `EnvWrapper` for 1st param but got
# `StateEmbedEnvironment`.
normalization_data_map=build_normalizer(embed_env),
)
device = "cuda" if use_gpu else "cpu"
agent_trainer_preprocessor = make_replay_buffer_trainer_preprocessor(
agent_trainer,
# pyre-fixme[6]: Expected `device` for 2nd param but got `str`.
device,
env,
)
num_batch_per_epoch = embed_rb.size // batch_size
# FIXME: This has to be wrapped in dataloader
for epoch in range(num_agent_train_epochs):
for _ in tqdm(range(num_batch_per_epoch), desc=f"epoch {epoch}"):
batch = embed_rb.sample_transition_batch(batch_size=batch_size)
preprocessed_batch = agent_trainer_preprocessor(batch)
# FIXME: This should be fitted with Lightning's trainer
agent_trainer.train(preprocessed_batch)
# evaluate model
rewards = []
policy = agent_manager.create_policy(serving=False)
# pyre-fixme[6]: Expected `EnvWrapper` for 1st param but got
# `StateEmbedEnvironment`.
agent = Agent.create_for_env(embed_env, policy=policy, device=device)
# num_processes=1 needed to avoid workers from dying on CircleCI tests
rewards = evaluate_for_n_episodes(
n=num_agent_eval_epochs,
# pyre-fixme[6]: Expected `EnvWrapper` for 2nd param but got
# `StateEmbedEnvironment`.
env=embed_env,
agent=agent,
num_processes=1,
)
assert (np.mean(rewards) >= passing_score_bar
), f"average reward doesn't pass our bar {passing_score_bar}"
return rewards
def run_test(
env: Env__Union,
model: ModelManager__Union,
replay_memory_size: int,
train_every_ts: int,
train_after_ts: int,
num_train_episodes: int,
passing_score_bar: float,
num_eval_episodes: int,
use_gpu: bool,
):
env = env.value
env.seed(SEED)
env.action_space.seed(SEED)
normalization = build_normalizer(env)
logger.info(f"Normalization is: \n{pprint.pformat(normalization)}")
manager = model.value
trainer = manager.initialize_trainer(
use_gpu=use_gpu,
reward_options=RewardOptions(),
normalization_data_map=normalization,
)
training_policy = manager.create_policy(serving=False)
replay_buffer = ReplayBuffer(
replay_capacity=replay_memory_size, batch_size=trainer.minibatch_size
)
device = torch.device("cuda") if use_gpu else torch.device("cpu")
# first fill the replay buffer to burn_in
train_after_ts = max(train_after_ts, trainer.minibatch_size)
fill_replay_buffer(
env=env, replay_buffer=replay_buffer, desired_size=train_after_ts
)
post_step = train_with_replay_buffer_post_step(
replay_buffer=replay_buffer,
env=env,
trainer=trainer,
training_freq=train_every_ts,
batch_size=trainer.minibatch_size,
device=device,
)
agent = Agent.create_for_env(
env, policy=training_policy, post_transition_callback=post_step, device=device
)
writer = SummaryWriter()
with summary_writer_context(writer):
train_rewards = []
for i in range(num_train_episodes):
trajectory = run_episode(
env=env, agent=agent, mdp_id=i, max_steps=env.max_steps
)
ep_reward = trajectory.calculate_cumulative_reward()
train_rewards.append(ep_reward)
logger.info(
f"Finished training episode {i} (len {len(trajectory)})"
f" with reward {ep_reward}."
)
logger.info("============Train rewards=============")
logger.info(train_rewards)
logger.info(f"average: {np.mean(train_rewards)};\tmax: {np.max(train_rewards)}")
# Check whether the max score passed the score bar; we explore during training
# the return could be bad (leading to flakiness in C51 and QRDQN).
assert np.max(train_rewards) >= passing_score_bar, (
f"max reward ({np.max(train_rewards)})after training for "
f"{len(train_rewards)} episodes is less than < {passing_score_bar}.\n"
)
serving_policy = manager.create_policy(serving=True)
agent = Agent.create_for_env_with_serving_policy(env, serving_policy)
eval_rewards = evaluate_for_n_episodes(
n=num_eval_episodes, env=env, agent=agent, max_steps=env.max_steps
).squeeze(1)
logger.info("============Eval rewards==============")
logger.info(eval_rewards)
mean_eval = np.mean(eval_rewards)
logger.info(f"average: {mean_eval};\tmax: {np.max(eval_rewards)}")
assert (
mean_eval >= passing_score_bar
), f"Eval reward is {mean_eval}, less than < {passing_score_bar}.\n"
def train_mdnrnn_and_compute_feature_stats(
env_name: str,
model: ModelManager__Union,
num_train_transitions: int,
num_test_transitions: int,
seq_len: int,
batch_size: int,
num_train_epochs: int,
use_gpu: bool,
saved_mdnrnn_path: Optional[str] = None,
):
"""Train MDNRNN Memory Network and compute feature importance/sensitivity."""
env: gym.Env = Gym(env_name=env_name)
env.seed(SEED)
manager = model.value
trainer = manager.build_trainer(
use_gpu=use_gpu,
reward_options=RewardOptions(),
normalization_data_map=build_normalizer(env),
)
device = "cuda" if use_gpu else "cpu"
# pyre-fixme[6]: Expected `device` for 2nd param but got `str`.
trainer_preprocessor = make_replay_buffer_trainer_preprocessor(trainer, device, env)
test_replay_buffer = ReplayBuffer(
replay_capacity=num_test_transitions,
batch_size=batch_size,
stack_size=seq_len,
return_everything_as_stack=True,
)
random_policy = make_random_policy_for_env(env)
agent = Agent.create_for_env(env, policy=random_policy)
fill_replay_buffer(env, test_replay_buffer, num_test_transitions, agent)
if saved_mdnrnn_path is None:
# train from scratch
trainer = train_mdnrnn(
env=env,
trainer=trainer,
trainer_preprocessor=trainer_preprocessor,
num_train_transitions=num_train_transitions,
seq_len=seq_len,
batch_size=batch_size,
num_train_epochs=num_train_epochs,
test_replay_buffer=test_replay_buffer,
)
else:
# load a pretrained model, and just evaluate it
trainer.memory_network.mdnrnn.load_state_dict(torch.load(saved_mdnrnn_path))
with torch.no_grad():
trainer.memory_network.mdnrnn.eval()
test_batch = test_replay_buffer.sample_transition_batch(
batch_size=test_replay_buffer.size
)
preprocessed_test_batch = trainer_preprocessor(test_batch)
feature_importance = calculate_feature_importance(
env=env,
trainer=trainer,
use_gpu=use_gpu,
test_batch=preprocessed_test_batch,
)
feature_sensitivity = calculate_feature_sensitivity(
env=env,
trainer=trainer,
use_gpu=use_gpu,
test_batch=preprocessed_test_batch,
)
trainer.memory_network.mdnrnn.train()
return feature_importance, feature_sensitivity
def run_test_offline(
env_name: str,
model: ModelManager__Union,
replay_memory_size: int,
num_batches_per_epoch: int,
num_train_epochs: int,
passing_score_bar: float,
num_eval_episodes: int,
minibatch_size: int,
use_gpu: bool,
):
env = Gym(env_name=env_name)
env.seed(SEED)
env.action_space.seed(SEED)
normalization = build_normalizer(env)
logger.info(f"Normalization is: \n{pprint.pformat(normalization)}")
manager = model.value
trainer = manager.build_trainer(
use_gpu=use_gpu,
reward_options=RewardOptions(),
normalization_data_map=normalization,
)
# first fill the replay buffer to burn_in
replay_buffer = ReplayBuffer(
replay_capacity=replay_memory_size, batch_size=minibatch_size
)
# always fill full RB
random_policy = make_random_policy_for_env(env)
agent = Agent.create_for_env(env, policy=random_policy)
fill_replay_buffer(
env=env,
replay_buffer=replay_buffer,
desired_size=replay_memory_size,
agent=agent,
)
device = torch.device("cuda") if use_gpu else None
dataset = OfflineReplayBufferDataset.create_for_trainer(
trainer,
env,
replay_buffer,
batch_size=minibatch_size,
num_batches=num_batches_per_epoch,
device=device,
)
data_loader = torch.utils.data.DataLoader(dataset, collate_fn=identity_collate)
pl_trainer = pl.Trainer(
max_epochs=num_train_epochs,
gpus=int(use_gpu),
deterministic=True,
default_root_dir=f"lightning_log_{str(uuid.uuid4())}",
)
pl_trainer.fit(trainer, data_loader)
logger.info(f"Evaluating after training for {num_train_epochs} epochs: ")
eval_rewards = evaluate_cem(env, manager, trainer, num_eval_episodes)
mean_rewards = np.mean(eval_rewards)
assert (
mean_rewards >= passing_score_bar
), f"{mean_rewards} doesn't pass the bar {passing_score_bar}."
def run_test(
env: Env__Union,
model: ModelManager__Union,
replay_memory_size: int,
train_every_ts: int,
train_after_ts: int,
num_train_episodes: int,
passing_score_bar: float,
num_eval_episodes: int,
use_gpu: bool,
minibatch_size: Optional[int] = None,
):
env = env.value
# pyre-fixme[16]: Module `pl` has no attribute `seed_everything`.
pl.seed_everything(SEED)
env.seed(SEED)
env.action_space.seed(SEED)
normalization = build_normalizer(env)
logger.info(f"Normalization is: \n{pprint.pformat(normalization)}")
manager = model.value
trainer = manager.initialize_trainer(
use_gpu=use_gpu,
reward_options=RewardOptions(),
normalization_data_map=normalization,
)
training_policy = manager.create_policy(serving=False)
# pyre-fixme[16]: Module `pl` has no attribute `LightningModule`.
if not isinstance(trainer, pl.LightningModule):
if minibatch_size is None:
minibatch_size = trainer.minibatch_size
assert minibatch_size == trainer.minibatch_size
assert minibatch_size is not None
replay_buffer = ReplayBuffer(replay_capacity=replay_memory_size,
batch_size=minibatch_size)
device = torch.device("cuda") if use_gpu else torch.device("cpu")
# first fill the replay buffer using random policy
train_after_ts = max(train_after_ts, minibatch_size)
fill_replay_buffer(env=env,
replay_buffer=replay_buffer,
desired_size=train_after_ts)
# pyre-fixme[16]: Module `pl` has no attribute `LightningModule`.
if isinstance(trainer, pl.LightningModule):
agent = Agent.create_for_env(env,
policy=training_policy,
device=device)
# TODO: Simplify this setup by creating LightningDataModule
dataset = ReplayBufferDataset.create_for_trainer(
trainer,
env,
agent,
replay_buffer,
batch_size=minibatch_size,
training_frequency=train_every_ts,
num_episodes=num_train_episodes,
max_steps=200,
device=device,
)
data_loader = torch.utils.data.DataLoader(dataset,
collate_fn=identity_collate)
# pyre-fixme[16]: Module `pl` has no attribute `Trainer`.
pl_trainer = pl.Trainer(max_epochs=1, gpus=int(use_gpu))
# Note: the fit() function below also evaluates the agent along the way
# and adds the new transitions to the replay buffer, so it is training
# on incrementally larger and larger buffers.
pl_trainer.fit(trainer, data_loader)
# TODO: Also check train_reward
else:
post_step = train_with_replay_buffer_post_step(
replay_buffer=replay_buffer,
env=env,
trainer=trainer,
training_freq=train_every_ts,
batch_size=trainer.minibatch_size,
device=device,
)
train_rewards = train_policy(
env,
training_policy,
num_train_episodes,
post_step=post_step,
post_episode=None,
use_gpu=use_gpu,
)
# Check whether the max score passed the score bar; we explore during training
# the return could be bad (leading to flakiness in C51 and QRDQN).
assert np.max(train_rewards) >= passing_score_bar, (
f"max reward ({np.max(train_rewards)}) after training for "
f"{len(train_rewards)} episodes is less than < {passing_score_bar}.\n"
)
serving_policy = manager.create_policy(serving=True)
eval_rewards = eval_policy(env,
serving_policy,
num_eval_episodes,
serving=True)
assert (
eval_rewards.mean() >= passing_score_bar
), f"Eval reward is {eval_rewards.mean()}, less than < {passing_score_bar}.\n"
def run_test(
env: str,
model: ModelManager__Union,
replay_memory_size: int,
train_every_ts: int,
train_after_ts: int,
num_train_episodes: int,
max_steps: Optional[int],
passing_score_bar: float,
num_eval_episodes: int,
use_gpu: bool,
):
env = EnvFactory.make(env)
env.seed(SEED)
env.action_space.seed(SEED)
normalization = build_normalizer(env)
logger.info(f"Normalization is {normalization}")
manager = model.value
trainer = manager.initialize_trainer(
use_gpu=use_gpu,
reward_options=RewardOptions(),
normalization_data_map=normalization,
)
replay_buffer = ReplayBuffer.create_from_env(
env=env,
replay_memory_size=replay_memory_size,
batch_size=trainer.minibatch_size,
)
device = torch.device("cuda") if use_gpu else None
post_step = train_with_replay_buffer_post_step(
replay_buffer=replay_buffer,
trainer=trainer,
training_freq=train_every_ts,
batch_size=trainer.minibatch_size,
replay_burnin=train_after_ts,
device=device,
)
training_policy = manager.create_policy(serving=False)
agent = Agent.create_for_env(env,
policy=training_policy,
post_transition_callback=post_step,
device=device)
train_rewards = []
for i in range(num_train_episodes):
ep_reward = run_episode(env=env, agent=agent, max_steps=max_steps)
train_rewards.append(ep_reward)
logger.info(f"Finished training episode {i} with reward {ep_reward}.")
assert train_rewards[-1] >= passing_score_bar, (
f"reward after {len(train_rewards)} episodes is {train_rewards[-1]},"
f"less than < {passing_score_bar}...\n"
f"Full reward history: {train_rewards}")
logger.info("============Train rewards=============")
logger.info(train_rewards)
def gym_to_reagent_serving(
obs: np.array) -> Tuple[torch.Tensor, torch.Tensor]:
obs_tensor = torch.tensor(obs).float().unsqueeze(0)
presence_tensor = torch.ones_like(obs_tensor)
return (obs_tensor, presence_tensor)
serving_policy = manager.create_policy(serving=True)
agent = Agent.create_for_env(env,
policy=serving_policy,
obs_preprocessor=gym_to_reagent_serving)
eval_rewards = []
for i in range(num_eval_episodes):
ep_reward = run_episode(env=env, agent=agent, max_steps=max_steps)
eval_rewards.append(ep_reward)
logger.info(f"Finished eval episode {i} with reward {ep_reward}.")
assert np.mean(eval_rewards) >= passing_score_bar, (
f"Predictor reward is {np.mean(eval_rewards)},"
f"less than < {passing_score_bar}...\n"
f"Full eval rewards: {eval_rewards}.")
logger.info("============Eval rewards==============")
logger.info(eval_rewards)
def create_df_from_replay_buffer(
env,
problem_domain: ProblemDomain,
desired_size: int,
multi_steps: Optional[int],
ds: str,
) -> pd.DataFrame:
# fill the replay buffer
set_seed(env, SEED)
if multi_steps is None:
update_horizon = 1
return_as_timeline_format = False
else:
update_horizon = multi_steps
return_as_timeline_format = True
is_multi_steps = multi_steps is not None
replay_buffer = ReplayBuffer(
replay_capacity=desired_size,
batch_size=1,
update_horizon=update_horizon,
return_as_timeline_format=return_as_timeline_format,
)
random_policy = make_random_policy_for_env(env)
agent = Agent.create_for_env(env, policy=random_policy)
fill_replay_buffer(env, replay_buffer, desired_size, agent)
batch = replay_buffer.sample_all_valid_transitions()
n = batch.state.shape[0]
logger.info(f"Creating df of size {n}.")
def discrete_feat_transform(elem) -> str:
"""query data expects str format"""
return str(elem.item())
def continuous_feat_transform(elem: List[float]) -> Dict[int, float]:
"""query data expects sparse format"""
assert isinstance(elem, torch.Tensor), f"{type(elem)} isn't tensor"
assert len(elem.shape) == 1, f"{elem.shape} isn't 1-dimensional"
return {i: s.item() for i, s in enumerate(elem)}
def make_parametric_feat_transform(one_hot_dim: int):
"""one-hot and then continuous_feat_transform"""
def transform(elem) -> Dict[int, float]:
elem_tensor = torch.tensor(elem.item())
one_hot_feat = F.one_hot(elem_tensor, one_hot_dim).float()
return continuous_feat_transform(one_hot_feat)
return transform
state_features = feature_transform(batch.state, continuous_feat_transform)
next_state_features = feature_transform(
batch.next_state,
continuous_feat_transform,
is_next_with_multi_steps=is_multi_steps,
)
if problem_domain == ProblemDomain.DISCRETE_ACTION:
# discrete action is str
action = feature_transform(batch.action, discrete_feat_transform)
next_action = feature_transform(
batch.next_action,
discrete_feat_transform,
is_next_with_multi_steps=is_multi_steps,
replace_when_terminal="",
terminal=batch.terminal,
)
elif problem_domain == ProblemDomain.PARAMETRIC_ACTION:
# continuous action is Dict[int, double]
assert isinstance(env.action_space, gym.spaces.Discrete)
parametric_feat_transform = make_parametric_feat_transform(env.action_space.n)
action = feature_transform(batch.action, parametric_feat_transform)
next_action = feature_transform(
batch.next_action,
parametric_feat_transform,
is_next_with_multi_steps=is_multi_steps,
replace_when_terminal={},
terminal=batch.terminal,
)
elif problem_domain == ProblemDomain.CONTINUOUS_ACTION:
action = feature_transform(batch.action, continuous_feat_transform)
next_action = feature_transform(
batch.next_action,
continuous_feat_transform,
is_next_with_multi_steps=is_multi_steps,
replace_when_terminal={},
terminal=batch.terminal,
)
elif problem_domain == ProblemDomain.MDN_RNN:
action = feature_transform(batch.action, discrete_feat_transform)
assert multi_steps is not None
next_action = feature_transform(
batch.next_action,
discrete_feat_transform,
is_next_with_multi_steps=True,
replace_when_terminal="",
terminal=batch.terminal,
)
else:
raise NotImplementedError(f"model type: {problem_domain}.")
if multi_steps is None:
time_diff = [1] * n
reward = batch.reward.squeeze(1).tolist()
metrics = [{"reward": r} for r in reward]
else:
time_diff = [[1] * len(ns) for ns in next_state_features]
reward = [reward_list.tolist() for reward_list in batch.reward]
metrics = [
[{"reward": r.item()} for r in reward_list] for reward_list in batch.reward
]
# TODO(T67265031): change this to int
mdp_id = [str(i.item()) for i in batch.mdp_id]
sequence_number = batch.sequence_number.squeeze(1).tolist()
# in the product data, all sequence_number_ordinal start from 1.
# So to be consistent with the product data.
sequence_number_ordinal = (batch.sequence_number.squeeze(1) + 1).tolist()
action_probability = batch.log_prob.exp().squeeze(1).tolist()
df_dict = {
"state_features": state_features,
"next_state_features": next_state_features,
"action": action,
"next_action": next_action,
"reward": reward,
"action_probability": action_probability,
"metrics": metrics,
"time_diff": time_diff,
"mdp_id": mdp_id,
"sequence_number": sequence_number,
"sequence_number_ordinal": sequence_number_ordinal,
"ds": [ds] * n,
}
if problem_domain == ProblemDomain.PARAMETRIC_ACTION:
# Possible actions are List[Dict[int, float]]
assert isinstance(env.action_space, gym.spaces.Discrete)
possible_actions = [{i: 1.0} for i in range(env.action_space.n)]
elif problem_domain == ProblemDomain.DISCRETE_ACTION:
# Possible actions are List[str]
assert isinstance(env.action_space, gym.spaces.Discrete)
possible_actions = [str(i) for i in range(env.action_space.n)]
elif problem_domain == ProblemDomain.MDN_RNN:
# Possible actions are List[str]
assert isinstance(env.action_space, gym.spaces.Discrete)
possible_actions = [str(i) for i in range(env.action_space.n)]
# these are fillers, which should have correct shape
pa_features = range(n)
pna_features = time_diff
if problem_domain in (
ProblemDomain.DISCRETE_ACTION,
ProblemDomain.PARAMETRIC_ACTION,
ProblemDomain.MDN_RNN,
):
def pa_transform(x):
return possible_actions
df_dict["possible_actions"] = feature_transform(pa_features, pa_transform)
df_dict["possible_next_actions"] = feature_transform(
pna_features,
pa_transform,
is_next_with_multi_steps=is_multi_steps,
replace_when_terminal=[],
terminal=batch.terminal,
)
df = pd.DataFrame(df_dict)
# validate df
validate_mdp_ids_seq_nums(df)
# shuffling (sample the whole batch)
df = df.reindex(np.random.permutation(df.index))
return df
