a2c-MountainCar-v0 / rl_algo_impls /shared /actor /state_dependent_noise.py

A2C playing MountainCar-v0 from https://github.com/sgoodfriend/rl-algo-impls/tree/0511de345b17175b7cf1ea706c3e05981f11761c

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	from typing import Optional, Tuple, Type, TypeVar, Union

	import torch
	import torch.nn as nn
	from torch.distributions import Distribution, Normal

	from rl_algo_impls.shared.actor.actor import Actor, PiForward
	from rl_algo_impls.shared.module.module import mlp


	class TanhBijector:
	def __init__(self, epsilon: float = 1e-6) -> None:
	self.epsilon = epsilon

	@staticmethod
	def forward(x: torch.Tensor) -> torch.Tensor:
	return torch.tanh(x)

	@staticmethod
	def inverse(y: torch.Tensor) -> torch.Tensor:
	eps = torch.finfo(y.dtype).eps
	clamped_y = y.clamp(min=-1.0 + eps, max=1.0 - eps)
	return torch.atanh(clamped_y)

	def log_prob_correction(self, x: torch.Tensor) -> torch.Tensor:
	return torch.log(1.0 - torch.tanh(x) ** 2 + self.epsilon)


	def sum_independent_dims(tensor: torch.Tensor) -> torch.Tensor:
	if len(tensor.shape) > 1:
	return tensor.sum(dim=1)
	return tensor.sum()


	class StateDependentNoiseDistribution(Normal):
	def __init__(
	self,
	loc,
	scale,
	latent_sde: torch.Tensor,
	exploration_mat: torch.Tensor,
	exploration_matrices: torch.Tensor,
	bijector: Optional[TanhBijector] = None,
	validate_args=None,
	):
	super().__init__(loc, scale, validate_args)
	self.latent_sde = latent_sde
	self.exploration_mat = exploration_mat
	self.exploration_matrices = exploration_matrices
	self.bijector = bijector

	def log_prob(self, a: torch.Tensor) -> torch.Tensor:
	gaussian_a = self.bijector.inverse(a) if self.bijector else a
	log_prob = sum_independent_dims(super().log_prob(gaussian_a))
	if self.bijector:
	log_prob -= torch.sum(self.bijector.log_prob_correction(gaussian_a), dim=1)
	return log_prob

	def sample(self) -> torch.Tensor:
	noise = self._get_noise()
	actions = self.mean + noise
	return self.bijector.forward(actions) if self.bijector else actions

	def _get_noise(self) -> torch.Tensor:
	if len(self.latent_sde) == 1 or len(self.latent_sde) != len(
	self.exploration_matrices
	):
	return torch.mm(self.latent_sde, self.exploration_mat)
	# (batch_size, n_features) -> (batch_size, 1, n_features)
	latent_sde = self.latent_sde.unsqueeze(dim=1)
	# (batch_size, 1, n_actions)
	noise = torch.bmm(latent_sde, self.exploration_matrices)
	return noise.squeeze(dim=1)

	@property
	def mode(self) -> torch.Tensor:
	mean = super().mode
	return self.bijector.forward(mean) if self.bijector else mean


	StateDependentNoiseActorHeadSelf = TypeVar(
	"StateDependentNoiseActorHeadSelf", bound="StateDependentNoiseActorHead"
	)


	class StateDependentNoiseActorHead(Actor):
	def __init__(
	self,
	act_dim: int,
	in_dim: int,
	hidden_sizes: Tuple[int, ...] = (32,),
	activation: Type[nn.Module] = nn.Tanh,
	init_layers_orthogonal: bool = True,
	log_std_init: float = -0.5,
	full_std: bool = True,
	squash_output: bool = False,
	learn_std: bool = False,
	) -> None:
	super().__init__()
	self.act_dim = act_dim
	layer_sizes = (in_dim,) + hidden_sizes + (act_dim,)
	if len(layer_sizes) == 2:
	self.latent_net = nn.Identity()
	elif len(layer_sizes) > 2:
	self.latent_net = mlp(
	layer_sizes[:-1],
	activation,
	output_activation=activation,
	init_layers_orthogonal=init_layers_orthogonal,
	)
	self.mu_net = mlp(
	layer_sizes[-2:],
	activation,
	init_layers_orthogonal=init_layers_orthogonal,
	final_layer_gain=0.01,
	)
	self.full_std = full_std
	std_dim = (layer_sizes[-2], act_dim if self.full_std else 1)
	self.log_std = nn.Parameter(
	torch.ones(std_dim, dtype=torch.float32) * log_std_init
	)
	self.bijector = TanhBijector() if squash_output else None
	self.learn_std = learn_std
	self.device = None

	self.exploration_mat = None
	self.exploration_matrices = None
	self.sample_weights()

	def to(
	self: StateDependentNoiseActorHeadSelf,
	device: Optional[torch.device] = None,
	dtype: Optional[Union[torch.dtype, str]] = None,
	non_blocking: bool = False,
	) -> StateDependentNoiseActorHeadSelf:
	super().to(device, dtype, non_blocking)
	self.device = device
	return self

	def _distribution(self, obs: torch.Tensor) -> Distribution:
	latent = self.latent_net(obs)
	mu = self.mu_net(latent)
	latent_sde = latent if self.learn_std else latent.detach()
	variance = torch.mm(latent_sde2, self._get_std() 2)
	assert self.exploration_mat is not None
	assert self.exploration_matrices is not None
	return StateDependentNoiseDistribution(
	mu,
	torch.sqrt(variance + 1e-6),
	latent_sde,
	self.exploration_mat,
	self.exploration_matrices,
	self.bijector,
	)

	def _get_std(self) -> torch.Tensor:
	std = torch.exp(self.log_std)
	if self.full_std:
	return std
	ones = torch.ones(self.log_std.shape[0], self.act_dim)
	if self.device:
	ones = ones.to(self.device)
	return ones * std

	def forward(
	self,
	obs: torch.Tensor,
	actions: Optional[torch.Tensor] = None,
	action_masks: Optional[torch.Tensor] = None,
	) -> PiForward:
	assert (
	not action_masks
	), f"{self.__class__.__name__} does not support action_masks"
	pi = self._distribution(obs)
	return self.pi_forward(pi, actions)

	def sample_weights(self, batch_size: int = 1) -> None:
	std = self._get_std()
	weights_dist = Normal(torch.zeros_like(std), std)
	# Reparametrization trick to pass gradients
	self.exploration_mat = weights_dist.rsample()
	self.exploration_matrices = weights_dist.rsample(torch.Size((batch_size,)))

	@property
	def action_shape(self) -> Tuple[int, ...]:
	return (self.act_dim,)

	def pi_forward(
	self, distribution: Distribution, actions: Optional[torch.Tensor] = None
	) -> PiForward:
	logp_a = None
	entropy = None
	if actions is not None:
	logp_a = distribution.log_prob(actions)
	entropy = (
	-logp_a
	if self.bijector
	else sum_independent_dims(distribution.entropy())
	)
	return PiForward(distribution, logp_a, entropy)