from .base import AlgoBase
from .torch.td3_impl import TD3Impl
from ..optimizers import AdamFactory
from ..argument_utils import check_encoder
from ..argument_utils import check_use_gpu
from ..argument_utils import check_augmentation
from ..argument_utils import check_q_func
[docs]class TD3(AlgoBase):
r""" Twin Delayed Deep Deterministic Policy Gradients algorithm.
TD3 is an improved DDPG-based algorithm.
Major differences from DDPG are as follows.
* TD3 has twin Q functions to reduce overestimation bias at TD learning.
The number of Q functions can be designated by `n_critics`.
* TD3 adds noise to target value estimation to avoid overfitting with the
deterministic policy.
* TD3 updates the policy function after several Q function updates in order
to reduce variance of action-value estimation. The interval of the policy
function update can be designated by `update_actor_interval`.
.. math::
L(\theta_i) = \mathbb{E}_{s_t, a_t, r_{t+1}, s_{t+1} \sim D} [(r_{t+1}
+ \gamma \min_j Q_{\theta_j'}(s_{t+1}, \pi_{\phi'}(s_{t+1}) +
\epsilon) - Q_{\theta_i}(s_t, a_t))^2]
.. math::
J(\phi) = \mathbb{E}_{s_t \sim D}
[\min_i Q_{\theta_i}(s_t, \pi_\phi(s_t))]
where :math:`\epsilon \sim clip (N(0, \sigma), -c, c)`
References:
* `Fujimoto et al., Addressing Function Approximation Error in
Actor-Critic Methods. <https://arxiv.org/abs/1802.09477>`_
Args:
actor_learning_rate (float): learning rate for a policy function.
critic_learning_rate (float): learning rate for Q functions.
actor_optim_factory (d3rlpy.optimizers.OptimizerFactory):
optimizer factory for the actor.
critic_optim_factory (d3rlpy.optimizers.OptimizerFactory):
optimizer factory for the critic.
actor_encoder_factory (d3rlpy.encoders.EncoderFactory or str):
encoder factory for the actor.
critic_encoder_factory (d3rlpy.encoders.EncoderFactory or str):
encoder factory for the critic.
q_func_factory (d3rlpy.q_functions.QFunctionFactory or str):
Q function factory.
batch_size (int): mini-batch size.
n_frames (int): the number of frames to stack for image observation.
n_steps (int): N-step TD calculation.
gamma (float): discount factor.
tau (float): target network synchronization coefficiency.
reguralizing_rate (float): reguralizing term for policy function.
n_critics (int): the number of Q functions for ensemble.
bootstrap (bool): flag to bootstrap Q functions.
share_encoder (bool): flag to share encoder network.
target_smoothing_sigma (float): standard deviation for target noise.
target_smoothing_clip (float): clipping range for target noise.
update_actor_interval (int): interval to update policy function
described as `delayed policy update` in the paper.
use_gpu (bool, int or d3rlpy.gpu.Device):
flag to use GPU, device ID or device.
scaler (d3rlpy.preprocessing.Scaler or str): preprocessor.
The available options are `['pixel', 'min_max', 'standard']`
augmentation (d3rlpy.augmentation.AugmentationPipeline or list(str)):
augmentation pipeline.
dynamics (d3rlpy.dynamics.base.DynamicsBase): dynamics model for data
augmentation.
impl (d3rlpy.algos.torch.td3_impl.TD3Impl): algorithm implementation.
Attributes:
actor_learning_rate (float): learning rate for a policy function.
critic_learning_rate (float): learning rate for Q functions.
actor_optim_factory (d3rlpy.optimizers.OptimizerFactory):
optimizer factory for the actor.
critic_optim_factory (d3rlpy.optimizers.OptimizerFactory):
optimizer factory for the critic.
actor_encoder_factory (d3rlpy.encoders.EncoderFactory):
encoder factory for the actor.
critic_encoder_factory (d3rlpy.encoders.EncoderFactory):
encoder factory for the critic.
q_func_factory (d3rlpy.q_functions.QFunctionFactory):
Q function factory.
batch_size (int): mini-batch size.
n_frames (int): the number of frames to stack for image observation.
n_steps (int): N-step TD calculation.
gamma (float): discount factor.
tau (float): target network synchronization coefficiency.
reguralizing_rate (float): reguralizing term for policy function.
n_critics (int): the number of Q functions for ensemble.
bootstrap (bool): flag to bootstrap Q functions.
share_encoder (bool): flag to share encoder network.
target_smoothing_sigma (float): standard deviation for target noise.
target_smoothing_clip (float): clipping range for target noise.
update_actor_interval (int): interval to update policy function
described as `delayed policy update` in the paper.
use_gpu (d3rlpy.gpu.Device): GPU device.
scaler (d3rlpy.preprocessing.Scaler): preprocessor.
augmentation (d3rlpy.augmentation.AugmentationPipeline):
augmentation pipeline.
dynamics (d3rlpy.dynamics.base.DynamicsBase): dynamics model.
impl (d3rlpy.algos.torch.td3_impl.TD3Impl): algorithm implementation.
eval_results_ (dict): evaluation results.
"""
def __init__(self,
*,
actor_learning_rate=3e-4,
critic_learning_rate=3e-4,
actor_optim_factory=AdamFactory(),
critic_optim_factory=AdamFactory(),
actor_encoder_factory='default',
critic_encoder_factory='default',
q_func_factory='mean',
batch_size=100,
n_frames=1,
n_steps=1,
gamma=0.99,
tau=0.005,
reguralizing_rate=0.0,
n_critics=2,
bootstrap=False,
share_encoder=False,
target_smoothing_sigma=0.2,
target_smoothing_clip=0.5,
update_actor_interval=2,
use_batch_norm=False,
use_gpu=False,
scaler=None,
augmentation=[],
encoder_params={},
dynamics=None,
impl=None,
**kwargs):
super().__init__(batch_size=batch_size,
n_frames=n_frames,
n_steps=n_steps,
gamma=gamma,
scaler=scaler,
dynamics=dynamics)
self.actor_learning_rate = actor_learning_rate
self.critic_learning_rate = critic_learning_rate
self.actor_optim_factory = actor_optim_factory
self.critic_optim_factory = critic_optim_factory
self.actor_encoder_factory = check_encoder(actor_encoder_factory)
self.critic_encoder_factory = check_encoder(critic_encoder_factory)
self.q_func_factory = check_q_func(q_func_factory)
self.tau = tau
self.reguralizing_rate = reguralizing_rate
self.n_critics = n_critics
self.bootstrap = bootstrap
self.share_encoder = share_encoder
self.target_smoothing_sigma = target_smoothing_sigma
self.target_smoothing_clip = target_smoothing_clip
self.update_actor_interval = update_actor_interval
self.use_batch_norm = use_batch_norm
self.augmentation = check_augmentation(augmentation)
self.encoder_params = encoder_params
self.use_gpu = check_use_gpu(use_gpu)
self.impl = impl
[docs] def create_impl(self, observation_shape, action_size):
self.impl = TD3Impl(observation_shape=observation_shape,
action_size=action_size,
actor_learning_rate=self.actor_learning_rate,
critic_learning_rate=self.critic_learning_rate,
actor_optim_factory=self.actor_optim_factory,
critic_optim_factory=self.critic_optim_factory,
actor_encoder_factory=self.actor_encoder_factory,
critic_encoder_factory=self.critic_encoder_factory,
q_func_factory=self.q_func_factory,
gamma=self.gamma,
tau=self.tau,
reguralizing_rate=self.reguralizing_rate,
n_critics=self.n_critics,
bootstrap=self.bootstrap,
share_encoder=self.share_encoder,
target_smoothing_sigma=self.target_smoothing_sigma,
target_smoothing_clip=self.target_smoothing_clip,
use_gpu=self.use_gpu,
scaler=self.scaler,
augmentation=self.augmentation)
self.impl.build()
[docs] def update(self, epoch, total_step, batch):
critic_loss = self.impl.update_critic(batch.observations,
batch.actions,
batch.next_rewards,
batch.next_observations,
batch.terminals, batch.n_steps)
# delayed policy update
if total_step % self.update_actor_interval == 0:
actor_loss = self.impl.update_actor(batch.observations)
self.impl.update_critic_target()
self.impl.update_actor_target()
else:
actor_loss = None
return critic_loss, actor_loss
def _get_loss_labels(self):
return ['critic_loss', 'actor_loss']