from itertools import zip_longest from typing import Dict, List, Tuple, Type, Union import gym import torch as th from torch import nn from stable_baselines3.common.preprocessing import get_flattened_obs_dim, is_image_space from stable_baselines3.common.utils import get_device class BaseFeaturesExtractor(nn.Module): """ Base class that represents a features extractor. :param observation_space: :param features_dim: Number of features extracted. """ def __init__(self, observation_space: gym.Space, features_dim: int = 0): super(BaseFeaturesExtractor, self).__init__() assert features_dim > 0 self._observation_space = observation_space self._features_dim = features_dim @property def features_dim(self) -> int: return self._features_dim def forward(self, observations: th.Tensor) -> th.Tensor: raise NotImplementedError() class FlattenExtractor(BaseFeaturesExtractor): """ Feature extract that flatten the input. Used as a placeholder when feature extraction is not needed. :param observation_space: """ def __init__(self, observation_space: gym.Space): super(FlattenExtractor, self).__init__(observation_space, get_flattened_obs_dim(observation_space)) self.flatten = nn.Flatten() def forward(self, observations: th.Tensor) -> th.Tensor: return self.flatten(observations) class NatureCNN(BaseFeaturesExtractor): """ CNN from DQN nature paper: Mnih, Volodymyr, et al. "Human-level control through deep reinforcement learning." Nature 518.7540 (2015): 529-533. :param observation_space: :param features_dim: Number of features extracted. This corresponds to the number of unit for the last layer. """ def __init__(self, observation_space: gym.spaces.Box, features_dim: int = 512): super(NatureCNN, self).__init__(observation_space, features_dim) # We assume CxHxW images (channels first) # Re-ordering will be done by pre-preprocessing or wrapper assert is_image_space(observation_space), ( "You should use NatureCNN " f"only with images not with {observation_space}\n" "(you are probably using `CnnPolicy` instead of `MlpPolicy`)\n" "If you are using a custom environment,\n" "please check it using our env checker:\n" "https://stable-baselines3.readthedocs.io/en/master/common/env_checker.html" ) n_input_channels = observation_space.shape[0] self.cnn = nn.Sequential( nn.Conv2d(n_input_channels, 32, kernel_size=8, stride=4, padding=0), nn.ReLU(), nn.Conv2d(32, 64, kernel_size=4, stride=2, padding=0), nn.ReLU(), nn.Conv2d(64, 64, kernel_size=3, stride=1, padding=0), nn.ReLU(), nn.Flatten(), ) # Compute shape by doing one forward pass with th.no_grad(): n_flatten = self.cnn(th.as_tensor(observation_space.sample()[None]).float()).shape[1] self.linear = nn.Sequential(nn.Linear(n_flatten, features_dim), nn.ReLU()) def forward(self, observations: th.Tensor) -> th.Tensor: return self.linear(self.cnn(observations)) def create_mlp( input_dim: int, output_dim: int, net_arch: List[int], activation_fn: Type[nn.Module] = nn.ReLU, squash_output: bool = False ) -> List[nn.Module]: """ Create a multi layer perceptron (MLP), which is a collection of fully-connected layers each followed by an activation function. :param input_dim: Dimension of the input vector :param output_dim: :param net_arch: Architecture of the neural net It represents the number of units per layer. The length of this list is the number of layers. :param activation_fn: The activation function to use after each layer. :param squash_output: Whether to squash the output using a Tanh activation function :return: """ if len(net_arch) > 0: modules = [nn.Linear(input_dim, net_arch[0]), activation_fn()] else: modules = [] for idx in range(len(net_arch) - 1): modules.append(nn.Linear(net_arch[idx], net_arch[idx + 1])) modules.append(activation_fn()) if output_dim > 0: last_layer_dim = net_arch[-1] if len(net_arch) > 0 else input_dim modules.append(nn.Linear(last_layer_dim, output_dim)) if squash_output: modules.append(nn.Tanh()) return modules class MlpExtractor(nn.Module): """ Constructs an MLP that receives observations as an input and outputs a latent representation for the policy and a value network. The ``net_arch`` parameter allows to specify the amount and size of the hidden layers and how many of them are shared between the policy network and the value network. It is assumed to be a list with the following structure: 1. An arbitrary length (zero allowed) number of integers each specifying the number of units in a shared layer. If the number of ints is zero, there will be no shared layers. 2. An optional dict, to specify the following non-shared layers for the value network and the policy network. It is formatted like ``dict(vf=[], pi=[])``. If it is missing any of the keys (pi or vf), no non-shared layers (empty list) is assumed. For example to construct a network with one shared layer of size 55 followed by two non-shared layers for the value network of size 255 and a single non-shared layer of size 128 for the policy network, the following layers_spec would be used: ``[55, dict(vf=[255, 255], pi=[128])]``. A simple shared network topology with two layers of size 128 would be specified as [128, 128]. Adapted from Stable Baselines. :param feature_dim: Dimension of the feature vector (can be the output of a CNN) :param net_arch: The specification of the policy and value networks. See above for details on its formatting. :param activation_fn: The activation function to use for the networks. :param device: """ def __init__( self, feature_dim: int, net_arch: List[Union[int, Dict[str, List[int]]]], activation_fn: Type[nn.Module], device: Union[th.device, str] = "auto", ): super(MlpExtractor, self).__init__() device = get_device(device) shared_net, policy_net, value_net = [], [], [] policy_only_layers = [] # Layer sizes of the network that only belongs to the policy network value_only_layers = [] # Layer sizes of the network that only belongs to the value network last_layer_dim_shared = feature_dim # Iterate through the shared layers and build the shared parts of the network for idx, layer in enumerate(net_arch): if isinstance(layer, int): # Check that this is a shared layer layer_size = layer # TODO: give layer a meaningful name shared_net.append(nn.Linear(last_layer_dim_shared, layer_size)) shared_net.append(activation_fn()) last_layer_dim_shared = layer_size else: assert isinstance(layer, dict), "Error: the net_arch list can only contain ints and dicts" if "pi" in layer: assert isinstance(layer["pi"], list), "Error: net_arch[-1]['pi'] must contain a list of integers." policy_only_layers = layer["pi"] if "vf" in layer: assert isinstance(layer["vf"], list), "Error: net_arch[-1]['vf'] must contain a list of integers." value_only_layers = layer["vf"] break # From here on the network splits up in policy and value network last_layer_dim_pi = last_layer_dim_shared last_layer_dim_vf = last_layer_dim_shared # Build the non-shared part of the network for idx, (pi_layer_size, vf_layer_size) in enumerate(zip_longest(policy_only_layers, value_only_layers)): if pi_layer_size is not None: assert isinstance(pi_layer_size, int), "Error: net_arch[-1]['pi'] must only contain integers." policy_net.append(nn.Linear(last_layer_dim_pi, pi_layer_size)) policy_net.append(activation_fn()) last_layer_dim_pi = pi_layer_size if vf_layer_size is not None: assert isinstance(vf_layer_size, int), "Error: net_arch[-1]['vf'] must only contain integers." value_net.append(nn.Linear(last_layer_dim_vf, vf_layer_size)) value_net.append(activation_fn()) last_layer_dim_vf = vf_layer_size # Save dim, used to create the distributions self.latent_dim_pi = last_layer_dim_pi self.latent_dim_vf = last_layer_dim_vf # Create networks # If the list of layers is empty, the network will just act as an Identity module self.shared_net = nn.Sequential(*shared_net).to(device) self.policy_net = nn.Sequential(*policy_net).to(device) self.value_net = nn.Sequential(*value_net).to(device) def forward(self, features: th.Tensor) -> Tuple[th.Tensor, th.Tensor]: """ :return: latent_policy, latent_value of the specified network. If all layers are shared, then ``latent_policy == latent_value`` """ shared_latent = self.shared_net(features) return self.policy_net(shared_latent), self.value_net(shared_latent) def get_actor_critic_arch(net_arch: Union[List[int], Dict[str, List[int]]]) -> Tuple[List[int], List[int]]: """ Get the actor and critic network architectures for off-policy actor-critic algorithms (SAC, TD3, DDPG). The ``net_arch`` parameter allows to specify the amount and size of the hidden layers, which can be different for the actor and the critic. It is assumed to be a list of ints or a dict. 1. If it is a list, actor and critic networks will have the same architecture. The architecture is represented by a list of integers (of arbitrary length (zero allowed)) each specifying the number of units per layer. If the number of ints is zero, the network will be linear. 2. If it is a dict, it should have the following structure: ``dict(qf=[], pi=[])``. where the network architecture is a list as described in 1. For example, to have actor and critic that share the same network architecture, you only need to specify ``net_arch=[256, 256]`` (here, two hidden layers of 256 units each). If you want a different architecture for the actor and the critic, then you can specify ``net_arch=dict(qf=[400, 300], pi=[64, 64])``. .. note:: Compared to their on-policy counterparts, no shared layers (other than the features extractor) between the actor and the critic are allowed (to prevent issues with target networks). :param net_arch: The specification of the actor and critic networks. See above for details on its formatting. :return: The network architectures for the actor and the critic """ if isinstance(net_arch, list): actor_arch, critic_arch = net_arch, net_arch else: assert isinstance(net_arch, dict), "Error: the net_arch can only contain be a list of ints or a dict" assert "pi" in net_arch, "Error: no key 'pi' was provided in net_arch for the actor network" assert "qf" in net_arch, "Error: no key 'qf' was provided in net_arch for the critic network" actor_arch, critic_arch = net_arch["pi"], net_arch["qf"] return actor_arch, critic_arch