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rebrac.py
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rebrac.py
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# source: https://github.com/tinkoff-ai/ReBRAC
# https://arxiv.org/abs/2305.09836
import os
os.environ["TF_CUDNN_DETERMINISTIC"] = "1" # For reproducibility
import math
import uuid
from copy import deepcopy
from dataclasses import asdict, dataclass
from functools import partial
from typing import Any, Callable, Dict, Sequence, Tuple, Union
import chex
import d4rl # noqa
import flax.linen as nn
import gym
import jax
import jax.numpy as jnp
import numpy as np
import optax
import pyrallis
import wandb
from flax.core import FrozenDict
from flax.training.train_state import TrainState
from tqdm.auto import trange
default_kernel_init = nn.initializers.lecun_normal()
default_bias_init = nn.initializers.zeros
@dataclass
class Config:
# wandb params
project: str = "CORL"
group: str = "rebrac"
name: str = "rebrac"
# model params
actor_learning_rate: float = 1e-3
critic_learning_rate: float = 1e-3
hidden_dim: int = 256
actor_n_hiddens: int = 3
critic_n_hiddens: int = 3
gamma: float = 0.99
tau: float = 5e-3
actor_bc_coef: float = 1.0
critic_bc_coef: float = 1.0
actor_ln: bool = False
critic_ln: bool = True
policy_noise: float = 0.2
noise_clip: float = 0.5
policy_freq: int = 2
normalize_q: bool = True
# training params
dataset_name: str = "halfcheetah-medium-v2"
batch_size: int = 1024
num_epochs: int = 1000
num_updates_on_epoch: int = 1000
normalize_reward: bool = False
normalize_states: bool = False
# evaluation params
eval_episodes: int = 10
eval_every: int = 5
# general params
train_seed: int = 0
eval_seed: int = 42
def __post_init__(self):
self.name = f"{self.name}-{self.dataset_name}-{str(uuid.uuid4())[:8]}"
def pytorch_init(fan_in: float) -> Callable:
"""
Default init for PyTorch Linear layer weights and biases:
https://pytorch.org/docs/stable/generated/torch.nn.Linear.html
"""
bound = math.sqrt(1 / fan_in)
def _init(key: jax.random.PRNGKey, shape: Tuple, dtype: type) -> jax.Array:
return jax.random.uniform(
key, shape=shape, minval=-bound, maxval=bound, dtype=dtype
)
return _init
def uniform_init(bound: float) -> Callable:
def _init(key: jax.random.PRNGKey, shape: Tuple, dtype: type) -> jax.Array:
return jax.random.uniform(
key, shape=shape, minval=-bound, maxval=bound, dtype=dtype
)
return _init
def identity(x: Any) -> Any:
return x
class DetActor(nn.Module):
action_dim: int
hidden_dim: int = 256
layernorm: bool = True
n_hiddens: int = 3
@nn.compact
def __call__(self, state: jax.Array) -> jax.Array:
s_d, h_d = state.shape[-1], self.hidden_dim
# Initialization as in the EDAC paper
layers = [
nn.Dense(
self.hidden_dim,
kernel_init=pytorch_init(s_d),
bias_init=nn.initializers.constant(0.1),
),
nn.relu,
nn.LayerNorm() if self.layernorm else identity,
]
for _ in range(self.n_hiddens - 1):
layers += [
nn.Dense(
self.hidden_dim,
kernel_init=pytorch_init(h_d),
bias_init=nn.initializers.constant(0.1),
),
nn.relu,
nn.LayerNorm() if self.layernorm else identity,
]
layers += [
nn.Dense(
self.action_dim,
kernel_init=uniform_init(1e-3),
bias_init=uniform_init(1e-3),
),
nn.tanh,
]
net = nn.Sequential(layers)
actions = net(state)
return actions
class Critic(nn.Module):
hidden_dim: int = 256
layernorm: bool = True
n_hiddens: int = 3
@nn.compact
def __call__(self, state: jax.Array, action: jax.Array) -> jax.Array:
s_d, a_d, h_d = state.shape[-1], action.shape[-1], self.hidden_dim
# Initialization as in the EDAC paper
layers = [
nn.Dense(
self.hidden_dim,
kernel_init=pytorch_init(s_d + a_d),
bias_init=nn.initializers.constant(0.1),
),
nn.relu,
nn.LayerNorm() if self.layernorm else identity,
]
for _ in range(self.n_hiddens - 1):
layers += [
nn.Dense(
self.hidden_dim,
kernel_init=pytorch_init(h_d),
bias_init=nn.initializers.constant(0.1),
),
nn.relu,
nn.LayerNorm() if self.layernorm else identity,
]
layers += [
nn.Dense(1, kernel_init=uniform_init(3e-3), bias_init=uniform_init(3e-3))
]
network = nn.Sequential(layers)
state_action = jnp.hstack([state, action])
out = network(state_action).squeeze(-1)
return out
class EnsembleCritic(nn.Module):
hidden_dim: int = 256
num_critics: int = 10
layernorm: bool = True
n_hiddens: int = 3
@nn.compact
def __call__(self, state: jax.Array, action: jax.Array) -> jax.Array:
ensemble = nn.vmap(
target=Critic,
in_axes=None,
out_axes=0,
variable_axes={"params": 0},
split_rngs={"params": True},
axis_size=self.num_critics,
)
q_values = ensemble(self.hidden_dim, self.layernorm, self.n_hiddens)(
state, action
)
return q_values
def qlearning_dataset(
env: gym.Env,
dataset: Dict = None,
terminate_on_end: bool = False,
**kwargs,
) -> Dict:
if dataset is None:
dataset = env.get_dataset(**kwargs)
N = dataset["rewards"].shape[0]
obs_ = []
next_obs_ = []
action_ = []
next_action_ = []
reward_ = []
done_ = []
# The newer version of the dataset adds an explicit
# timeouts field. Keep old method for backwards compatability.
use_timeouts = "timeouts" in dataset
episode_step = 0
for i in range(N - 1):
obs = dataset["observations"][i].astype(np.float32)
new_obs = dataset["observations"][i + 1].astype(np.float32)
action = dataset["actions"][i].astype(np.float32)
new_action = dataset["actions"][i + 1].astype(np.float32)
reward = dataset["rewards"][i].astype(np.float32)
done_bool = bool(dataset["terminals"][i])
if use_timeouts:
final_timestep = dataset["timeouts"][i]
else:
final_timestep = episode_step == env._max_episode_steps - 1
if (not terminate_on_end) and final_timestep:
# Skip this transition
episode_step = 0
continue
if done_bool or final_timestep:
episode_step = 0
obs_.append(obs)
next_obs_.append(new_obs)
action_.append(action)
next_action_.append(new_action)
reward_.append(reward)
done_.append(done_bool)
episode_step += 1
return {
"observations": np.array(obs_),
"actions": np.array(action_),
"next_observations": np.array(next_obs_),
"next_actions": np.array(next_action_),
"rewards": np.array(reward_),
"terminals": np.array(done_),
}
def compute_mean_std(states: jax.Array, eps: float) -> Tuple[jax.Array, jax.Array]:
mean = states.mean(0)
std = states.std(0) + eps
return mean, std
def normalize_states(states: jax.Array, mean: jax.Array, std: jax.Array) -> jax.Array:
return (states - mean) / std
@chex.dataclass
class ReplayBuffer:
data: Dict[str, jax.Array] = None
mean: float = 0
std: float = 1
def create_from_d4rl(
self,
dataset_name: str,
normalize_reward: bool = False,
is_normalize: bool = False,
):
d4rl_data = qlearning_dataset(gym.make(dataset_name))
buffer = {
"states": jnp.asarray(d4rl_data["observations"], dtype=jnp.float32),
"actions": jnp.asarray(d4rl_data["actions"], dtype=jnp.float32),
"rewards": jnp.asarray(d4rl_data["rewards"], dtype=jnp.float32),
"next_states": jnp.asarray(
d4rl_data["next_observations"], dtype=jnp.float32
),
"next_actions": jnp.asarray(d4rl_data["next_actions"], dtype=jnp.float32),
"dones": jnp.asarray(d4rl_data["terminals"], dtype=jnp.float32),
}
if is_normalize:
self.mean, self.std = compute_mean_std(buffer["states"], eps=1e-3)
buffer["states"] = normalize_states(buffer["states"], self.mean, self.std)
buffer["next_states"] = normalize_states(
buffer["next_states"], self.mean, self.std
)
if normalize_reward:
buffer["rewards"] = ReplayBuffer.normalize_reward(
dataset_name, buffer["rewards"]
)
self.data = buffer
@property
def size(self) -> int:
# WARN: It will use len of the dataclass, i.e. number of fields.
return self.data["states"].shape[0]
def sample_batch(
self, key: jax.random.PRNGKey, batch_size: int
) -> Dict[str, jax.Array]:
indices = jax.random.randint(
key, shape=(batch_size,), minval=0, maxval=self.size
)
batch = jax.tree_map(lambda arr: arr[indices], self.data)
return batch
def get_moments(self, modality: str) -> Tuple[jax.Array, jax.Array]:
mean = self.data[modality].mean(0)
std = self.data[modality].std(0)
return mean, std
@staticmethod
def normalize_reward(dataset_name: str, rewards: jax.Array) -> jax.Array:
if "antmaze" in dataset_name:
return rewards * 100.0 # like in LAPO
else:
raise NotImplementedError(
"Reward normalization is implemented only for AntMaze yet!"
)
@chex.dataclass(frozen=True)
class Metrics:
accumulators: Dict[str, Tuple[jax.Array, jax.Array]]
@staticmethod
def create(metrics: Sequence[str]) -> "Metrics":
init_metrics = {key: (jnp.array([0.0]), jnp.array([0.0])) for key in metrics}
return Metrics(accumulators=init_metrics)
def update(self, updates: Dict[str, jax.Array]) -> "Metrics":
new_accumulators = deepcopy(self.accumulators)
for key, value in updates.items():
acc, steps = new_accumulators[key]
new_accumulators[key] = (acc + value, steps + 1)
return self.replace(accumulators=new_accumulators)
def compute(self) -> Dict[str, np.ndarray]:
# cumulative_value / total_steps
return {k: np.array(v[0] / v[1]) for k, v in self.accumulators.items()}
def normalize(
arr: jax.Array, mean: jax.Array, std: jax.Array, eps: float = 1e-8
) -> jax.Array:
return (arr - mean) / (std + eps)
def make_env(env_name: str, seed: int) -> gym.Env:
env = gym.make(env_name)
env.seed(seed)
env.action_space.seed(seed)
env.observation_space.seed(seed)
return env
def wrap_env(
env: gym.Env,
state_mean: Union[np.ndarray, float] = 0.0,
state_std: Union[np.ndarray, float] = 1.0,
reward_scale: float = 1.0,
) -> gym.Env:
# PEP 8: E731 do not assign a lambda expression, use a def
def normalize_state(state: np.ndarray) -> np.ndarray:
return (
state - state_mean
) / state_std # epsilon should be already added in std.
def scale_reward(reward: float) -> float:
# Please be careful, here reward is multiplied by scale!
return reward_scale * reward
env = gym.wrappers.TransformObservation(env, normalize_state)
if reward_scale != 1.0:
env = gym.wrappers.TransformReward(env, scale_reward)
return env
def evaluate(
env: gym.Env,
params: jax.Array,
action_fn: Callable,
num_episodes: int,
seed: int,
) -> np.ndarray:
env.seed(seed)
env.action_space.seed(seed)
env.observation_space.seed(seed)
returns = []
for _ in trange(num_episodes, desc="Eval", leave=False):
obs, done = env.reset(), False
total_reward = 0.0
while not done:
action = np.asarray(jax.device_get(action_fn(params, obs)))
obs, reward, done, _ = env.step(action)
total_reward += reward
returns.append(total_reward)
return np.array(returns)
class CriticTrainState(TrainState):
target_params: FrozenDict
class ActorTrainState(TrainState):
target_params: FrozenDict
def update_actor(
key: jax.random.PRNGKey,
actor: TrainState,
critic: TrainState,
batch: Dict[str, jax.Array],
beta: float,
tau: float,
normalize_q: bool,
metrics: Metrics,
) -> Tuple[jax.random.PRNGKey, TrainState, TrainState, Metrics]:
key, random_action_key = jax.random.split(key, 2)
def actor_loss_fn(params: jax.Array) -> Tuple[jax.Array, Metrics]:
actions = actor.apply_fn(params, batch["states"])
bc_penalty = ((actions - batch["actions"]) ** 2).sum(-1)
q_values = critic.apply_fn(critic.params, batch["states"], actions).min(0)
lmbda = 1
if normalize_q:
lmbda = jax.lax.stop_gradient(1 / jax.numpy.abs(q_values).mean())
loss = (beta * bc_penalty - lmbda * q_values).mean()
# logging stuff
random_actions = jax.random.uniform(
random_action_key, shape=batch["actions"].shape, minval=-1.0, maxval=1.0
)
new_metrics = metrics.update(
{
"actor_loss": loss,
"bc_mse_policy": bc_penalty.mean(),
"bc_mse_random": ((random_actions - batch["actions"]) ** 2)
.sum(-1)
.mean(),
"action_mse": ((actions - batch["actions"]) ** 2).mean(),
}
)
return loss, new_metrics
grads, new_metrics = jax.grad(actor_loss_fn, has_aux=True)(actor.params)
new_actor = actor.apply_gradients(grads=grads)
new_actor = new_actor.replace(
target_params=optax.incremental_update(actor.params, actor.target_params, tau)
)
new_critic = critic.replace(
target_params=optax.incremental_update(critic.params, critic.target_params, tau)
)
return key, new_actor, new_critic, new_metrics
def update_critic(
key: jax.random.PRNGKey,
actor: TrainState,
critic: CriticTrainState,
batch: Dict[str, jax.Array],
gamma: float,
beta: float,
tau: float,
policy_noise: float,
noise_clip: float,
metrics: Metrics,
) -> Tuple[jax.random.PRNGKey, TrainState, Metrics]:
key, actions_key = jax.random.split(key)
next_actions = actor.apply_fn(actor.target_params, batch["next_states"])
noise = jax.numpy.clip(
(jax.random.normal(actions_key, next_actions.shape) * policy_noise),
-noise_clip,
noise_clip,
)
next_actions = jax.numpy.clip(next_actions + noise, -1, 1)
bc_penalty = ((next_actions - batch["next_actions"]) ** 2).sum(-1)
next_q = critic.apply_fn(
critic.target_params, batch["next_states"], next_actions
).min(0)
next_q = next_q - beta * bc_penalty
target_q = batch["rewards"] + (1 - batch["dones"]) * gamma * next_q
def critic_loss_fn(critic_params: jax.Array) -> Tuple[jax.Array, jax.Array]:
# [N, batch_size] - [1, batch_size]
q = critic.apply_fn(critic_params, batch["states"], batch["actions"])
q_min = q.min(0).mean()
loss = ((q - target_q[None, ...]) ** 2).mean(1).sum(0)
return loss, q_min
(loss, q_min), grads = jax.value_and_grad(critic_loss_fn, has_aux=True)(
critic.params
)
new_critic = critic.apply_gradients(grads=grads)
new_metrics = metrics.update(
{
"critic_loss": loss,
"q_min": q_min,
}
)
return key, new_critic, new_metrics
def update_td3(
key: jax.random.PRNGKey,
actor: TrainState,
critic: CriticTrainState,
batch: Dict[str, Any],
metrics: Metrics,
gamma: float,
actor_bc_coef: float,
critic_bc_coef: float,
tau: float,
policy_noise: float,
noise_clip: float,
normalize_q: bool,
) -> Tuple[jax.random.PRNGKey, TrainState, TrainState, Metrics]:
key, new_critic, new_metrics = update_critic(
key,
actor,
critic,
batch,
gamma,
critic_bc_coef,
tau,
policy_noise,
noise_clip,
metrics,
)
key, new_actor, new_critic, new_metrics = update_actor(
key, actor, new_critic, batch, actor_bc_coef, tau, normalize_q, new_metrics
)
return key, new_actor, new_critic, new_metrics
def update_td3_no_targets(
key: jax.random.PRNGKey,
actor: TrainState,
critic: CriticTrainState,
batch: Dict[str, Any],
gamma: float,
metrics: Metrics,
actor_bc_coef: float,
critic_bc_coef: float,
tau: float,
policy_noise: float,
noise_clip: float,
) -> Tuple[jax.random.PRNGKey, TrainState, TrainState, Metrics]:
key, new_critic, new_metrics = update_critic(
key,
actor,
critic,
batch,
gamma,
critic_bc_coef,
tau,
policy_noise,
noise_clip,
metrics,
)
return key, actor, new_critic, new_metrics
def action_fn(actor: TrainState) -> Callable:
@jax.jit
def _action_fn(obs: jax.Array) -> jax.Array:
action = actor.apply_fn(actor.params, obs)
return action
return _action_fn
@pyrallis.wrap()
def main(config: Config):
dict_config = asdict(config)
dict_config["mlc_job_name"] = os.environ.get("PLATFORM_JOB_NAME")
wandb.init(
config=dict_config,
project=config.project,
group=config.group,
name=config.name,
id=str(uuid.uuid4()),
)
wandb.mark_preempting()
buffer = ReplayBuffer()
buffer.create_from_d4rl(
config.dataset_name, config.normalize_reward, config.normalize_states
)
key = jax.random.PRNGKey(seed=config.train_seed)
key, actor_key, critic_key = jax.random.split(key, 3)
eval_env = make_env(config.dataset_name, seed=config.eval_seed)
eval_env = wrap_env(eval_env, buffer.mean, buffer.std)
init_state = buffer.data["states"][0][None, ...]
init_action = buffer.data["actions"][0][None, ...]
actor_module = DetActor(
action_dim=init_action.shape[-1],
hidden_dim=config.hidden_dim,
layernorm=config.actor_ln,
n_hiddens=config.actor_n_hiddens,
)
actor = ActorTrainState.create(
apply_fn=actor_module.apply,
params=actor_module.init(actor_key, init_state),
target_params=actor_module.init(actor_key, init_state),
tx=optax.adam(learning_rate=config.actor_learning_rate),
)
critic_module = EnsembleCritic(
hidden_dim=config.hidden_dim,
num_critics=2,
layernorm=config.critic_ln,
n_hiddens=config.critic_n_hiddens,
)
critic = CriticTrainState.create(
apply_fn=critic_module.apply,
params=critic_module.init(critic_key, init_state, init_action),
target_params=critic_module.init(critic_key, init_state, init_action),
tx=optax.adam(learning_rate=config.critic_learning_rate),
)
update_td3_partial = partial(
update_td3,
gamma=config.gamma,
actor_bc_coef=config.actor_bc_coef,
critic_bc_coef=config.critic_bc_coef,
tau=config.tau,
policy_noise=config.policy_noise,
noise_clip=config.noise_clip,
normalize_q=config.normalize_q,
)
update_td3_no_targets_partial = partial(
update_td3_no_targets,
gamma=config.gamma,
actor_bc_coef=config.actor_bc_coef,
critic_bc_coef=config.critic_bc_coef,
tau=config.tau,
policy_noise=config.policy_noise,
noise_clip=config.noise_clip,
)
def td3_loop_update_step(i: int, carry: TrainState):
key, batch_key = jax.random.split(carry["key"])
batch = carry["buffer"].sample_batch(batch_key, batch_size=config.batch_size)
full_update = partial(
update_td3_partial,
key=key,
actor=carry["actor"],
critic=carry["critic"],
batch=batch,
metrics=carry["metrics"],
)
update = partial(
update_td3_no_targets_partial,
key=key,
actor=carry["actor"],
critic=carry["critic"],
batch=batch,
metrics=carry["metrics"],
)
key, new_actor, new_critic, new_metrics = jax.lax.cond(
update_carry["delayed_updates"][i], full_update, update
)
carry.update(key=key, actor=new_actor, critic=new_critic, metrics=new_metrics)
return carry
# metrics
bc_metrics_to_log = [
"critic_loss",
"q_min",
"actor_loss",
"batch_entropy",
"bc_mse_policy",
"bc_mse_random",
"action_mse",
]
# shared carry for update loops
update_carry = {
"key": key,
"actor": actor,
"critic": critic,
"buffer": buffer,
"delayed_updates": jax.numpy.equal(
jax.numpy.arange(config.num_updates_on_epoch) % config.policy_freq, 0
).astype(int),
}
@jax.jit
def actor_action_fn(params: jax.Array, obs: jax.Array):
return actor.apply_fn(params, obs)
for epoch in trange(config.num_epochs, desc="ReBRAC Epochs"):
# metrics for accumulation during epoch and logging to wandb
# we need to reset them every epoch
update_carry["metrics"] = Metrics.create(bc_metrics_to_log)
update_carry = jax.lax.fori_loop(
lower=0,
upper=config.num_updates_on_epoch,
body_fun=td3_loop_update_step,
init_val=update_carry,
)
# log mean over epoch for each metric
mean_metrics = update_carry["metrics"].compute()
wandb.log(
{"epoch": epoch, **{f"ReBRAC/{k}": v for k, v in mean_metrics.items()}}
)
if epoch % config.eval_every == 0 or epoch == config.num_epochs - 1:
eval_returns = evaluate(
eval_env,
update_carry["actor"].params,
actor_action_fn,
config.eval_episodes,
seed=config.eval_seed,
)
normalized_score = eval_env.get_normalized_score(eval_returns) * 100.0
wandb.log(
{
"epoch": epoch,
"eval/return_mean": np.mean(eval_returns),
"eval/return_std": np.std(eval_returns),
"eval/normalized_score_mean": np.mean(normalized_score),
"eval/normalized_score_std": np.std(normalized_score),
}
)
if __name__ == "__main__":
main()