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from typing import Union, Dict, Optional |
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import torch |
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import torch.nn as nn |
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from ding.utils import SequenceType, squeeze, MODEL_REGISTRY |
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from ..common import ReparameterizationHead, RegressionHead, DiscreteHead |
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@MODEL_REGISTRY.register('mavac') |
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class MAVAC(nn.Module): |
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""" |
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Overview: |
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The neural network and computation graph of algorithms related to (state) Value Actor-Critic (VAC) for \ |
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multi-agent, such as MAPPO(https://arxiv.org/abs/2103.01955). This model now supports discrete and \ |
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continuous action space. The MAVAC is composed of four parts: ``actor_encoder``, ``critic_encoder``, \ |
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``actor_head`` and ``critic_head``. Encoders are used to extract the feature from various observation. \ |
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Heads are used to predict corresponding value or action logit. |
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Interfaces: |
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``__init__``, ``forward``, ``compute_actor``, ``compute_critic``, ``compute_actor_critic``. |
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""" |
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mode = ['compute_actor', 'compute_critic', 'compute_actor_critic'] |
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def __init__( |
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self, |
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agent_obs_shape: Union[int, SequenceType], |
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global_obs_shape: Union[int, SequenceType], |
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action_shape: Union[int, SequenceType], |
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agent_num: int, |
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actor_head_hidden_size: int = 256, |
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actor_head_layer_num: int = 2, |
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critic_head_hidden_size: int = 512, |
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critic_head_layer_num: int = 1, |
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action_space: str = 'discrete', |
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activation: Optional[nn.Module] = nn.ReLU(), |
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norm_type: Optional[str] = None, |
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sigma_type: Optional[str] = 'independent', |
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bound_type: Optional[str] = None, |
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) -> None: |
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""" |
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Overview: |
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Init the MAVAC Model according to arguments. |
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Arguments: |
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- agent_obs_shape (:obj:`Union[int, SequenceType]`): Observation's space for single agent, \ |
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such as 8 or [4, 84, 84]. |
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- global_obs_shape (:obj:`Union[int, SequenceType]`): Global observation's space, such as 8 or [4, 84, 84]. |
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- action_shape (:obj:`Union[int, SequenceType]`): Action space shape for single agent, such as 6 \ |
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or [2, 3, 3]. |
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- agent_num (:obj:`int`): This parameter is temporarily reserved. This parameter may be required for \ |
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subsequent changes to the model |
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- actor_head_hidden_size (:obj:`Optional[int]`): The ``hidden_size`` of ``actor_head`` network, defaults \ |
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to 256, it must match the last element of ``agent_obs_shape``. |
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- actor_head_layer_num (:obj:`int`): The num of layers used in the ``actor_head`` network to compute action. |
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- critic_head_hidden_size (:obj:`Optional[int]`): The ``hidden_size`` of ``critic_head`` network, defaults \ |
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to 512, it must match the last element of ``global_obs_shape``. |
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- critic_head_layer_num (:obj:`int`): The num of layers used in the network to compute Q value output for \ |
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critic's nn. |
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- action_space (:obj:`Union[int, SequenceType]`): The type of different action spaces, including \ |
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['discrete', 'continuous'], then will instantiate corresponding head, including ``DiscreteHead`` \ |
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and ``ReparameterizationHead``. |
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- activation (:obj:`Optional[nn.Module]`): The type of activation function to use in ``MLP`` the after \ |
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``layer_fn``, if ``None`` then default set to ``nn.ReLU()``. |
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- norm_type (:obj:`Optional[str]`): The type of normalization in networks, see \ |
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``ding.torch_utils.fc_block`` for more details. you can choose one of ['BN', 'IN', 'SyncBN', 'LN']. |
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- sigma_type (:obj:`Optional[str]`): The type of sigma in continuous action space, see \ |
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``ding.torch_utils.network.dreamer.ReparameterizationHead`` for more details, in MAPPO, it defaults \ |
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to ``independent``, which means state-independent sigma parameters. |
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- bound_type (:obj:`Optional[str]`): The type of action bound methods in continuous action space, defaults \ |
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to ``None``, which means no bound. |
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""" |
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super(MAVAC, self).__init__() |
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agent_obs_shape: int = squeeze(agent_obs_shape) |
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global_obs_shape: int = squeeze(global_obs_shape) |
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action_shape: int = squeeze(action_shape) |
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self.global_obs_shape, self.agent_obs_shape, self.action_shape = global_obs_shape, agent_obs_shape, action_shape |
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self.action_space = action_space |
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self.actor_encoder = nn.Identity() |
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self.critic_encoder = nn.Identity() |
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self.critic_head = nn.Sequential( |
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nn.Linear(global_obs_shape, critic_head_hidden_size), activation, |
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RegressionHead( |
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critic_head_hidden_size, 1, critic_head_layer_num, activation=activation, norm_type=norm_type |
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) |
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) |
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assert self.action_space in ['discrete', 'continuous'], self.action_space |
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if self.action_space == 'discrete': |
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self.actor_head = nn.Sequential( |
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nn.Linear(agent_obs_shape, actor_head_hidden_size), activation, |
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DiscreteHead( |
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actor_head_hidden_size, |
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action_shape, |
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actor_head_layer_num, |
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activation=activation, |
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norm_type=norm_type |
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) |
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) |
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elif self.action_space == 'continuous': |
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self.actor_head = nn.Sequential( |
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nn.Linear(agent_obs_shape, actor_head_hidden_size), activation, |
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ReparameterizationHead( |
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actor_head_hidden_size, |
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action_shape, |
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actor_head_layer_num, |
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sigma_type=sigma_type, |
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activation=activation, |
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norm_type=norm_type, |
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bound_type=bound_type |
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) |
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) |
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self.actor = [self.actor_encoder, self.actor_head] |
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self.critic = [self.critic_encoder, self.critic_head] |
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self.actor = nn.ModuleList(self.actor) |
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self.critic = nn.ModuleList(self.critic) |
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def forward(self, inputs: Union[torch.Tensor, Dict], mode: str) -> Dict: |
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""" |
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Overview: |
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MAVAC forward computation graph, input observation tensor to predict state value or action logit. \ |
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``mode`` includes ``compute_actor``, ``compute_critic``, ``compute_actor_critic``. |
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Different ``mode`` will forward with different network modules to get different outputs and save \ |
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computation. |
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Arguments: |
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- inputs (:obj:`Dict`): The input dict including observation and related info, \ |
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whose key-values vary from different ``mode``. |
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- mode (:obj:`str`): The forward mode, all the modes are defined in the beginning of this class. |
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Returns: |
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- outputs (:obj:`Dict`): The output dict of MAVAC's forward computation graph, whose key-values vary from \ |
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different ``mode``. |
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Examples (Actor): |
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>>> model = MAVAC(agent_obs_shape=64, global_obs_shape=128, action_shape=14) |
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>>> inputs = { |
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'agent_state': torch.randn(10, 8, 64), |
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'global_state': torch.randn(10, 8, 128), |
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'action_mask': torch.randint(0, 2, size=(10, 8, 14)) |
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} |
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>>> actor_outputs = model(inputs,'compute_actor') |
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>>> assert actor_outputs['logit'].shape == torch.Size([10, 8, 14]) |
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Examples (Critic): |
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>>> model = MAVAC(agent_obs_shape=64, global_obs_shape=128, action_shape=14) |
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>>> inputs = { |
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'agent_state': torch.randn(10, 8, 64), |
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'global_state': torch.randn(10, 8, 128), |
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'action_mask': torch.randint(0, 2, size=(10, 8, 14)) |
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} |
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>>> critic_outputs = model(inputs,'compute_critic') |
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>>> assert actor_outputs['value'].shape == torch.Size([10, 8]) |
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Examples (Actor-Critic): |
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>>> model = MAVAC(64, 64) |
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>>> inputs = { |
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'agent_state': torch.randn(10, 8, 64), |
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'global_state': torch.randn(10, 8, 128), |
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'action_mask': torch.randint(0, 2, size=(10, 8, 14)) |
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} |
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>>> outputs = model(inputs,'compute_actor_critic') |
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>>> assert outputs['value'].shape == torch.Size([10, 8, 14]) |
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>>> assert outputs['logit'].shape == torch.Size([10, 8]) |
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""" |
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assert mode in self.mode, "not support forward mode: {}/{}".format(mode, self.mode) |
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return getattr(self, mode)(inputs) |
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def compute_actor(self, x: Dict) -> Dict: |
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""" |
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Overview: |
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MAVAC forward computation graph for actor part, \ |
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predicting action logit with agent observation tensor in ``x``. |
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Arguments: |
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- x (:obj:`Dict`): Input data dict with keys ['agent_state', 'action_mask'(optional)]. |
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- agent_state: (:obj:`torch.Tensor`): Each agent local state(obs). |
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- action_mask(optional): (:obj:`torch.Tensor`): When ``action_space`` is discrete, action_mask needs \ |
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to be provided to mask illegal actions. |
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Returns: |
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- outputs (:obj:`Dict`): The output dict of the forward computation graph for actor, including ``logit``. |
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ReturnsKeys: |
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- logit (:obj:`torch.Tensor`): The predicted action logit tensor, for discrete action space, it will be \ |
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the same dimension real-value ranged tensor of possible action choices, and for continuous action \ |
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space, it will be the mu and sigma of the Gaussian distribution, and the number of mu and sigma is the \ |
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same as the number of continuous actions. |
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Shapes: |
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- logit (:obj:`torch.FloatTensor`): :math:`(B, M, N)`, where B is batch size and N is ``action_shape`` \ |
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and M is ``agent_num``. |
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Examples: |
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>>> model = MAVAC(agent_obs_shape=64, global_obs_shape=128, action_shape=14) |
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>>> inputs = { |
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'agent_state': torch.randn(10, 8, 64), |
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'global_state': torch.randn(10, 8, 128), |
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'action_mask': torch.randint(0, 2, size=(10, 8, 14)) |
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} |
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>>> actor_outputs = model(inputs,'compute_actor') |
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>>> assert actor_outputs['logit'].shape == torch.Size([10, 8, 14]) |
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""" |
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if self.action_space == 'discrete': |
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action_mask = x['action_mask'] |
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x = x['agent_state'] |
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x = self.actor_encoder(x) |
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x = self.actor_head(x) |
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logit = x['logit'] |
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logit[action_mask == 0.0] = -99999999 |
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elif self.action_space == 'continuous': |
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x = x['agent_state'] |
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x = self.actor_encoder(x) |
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x = self.actor_head(x) |
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logit = x |
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return {'logit': logit} |
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def compute_critic(self, x: Dict) -> Dict: |
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""" |
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Overview: |
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MAVAC forward computation graph for critic part. \ |
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Predict state value with global observation tensor in ``x``. |
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Arguments: |
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- x (:obj:`Dict`): Input data dict with keys ['global_state']. |
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- global_state: (:obj:`torch.Tensor`): Global state(obs). |
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Returns: |
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- outputs (:obj:`Dict`): The output dict of MAVAC's forward computation graph for critic, \ |
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including ``value``. |
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ReturnsKeys: |
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- value (:obj:`torch.Tensor`): The predicted state value tensor. |
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Shapes: |
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- value (:obj:`torch.FloatTensor`): :math:`(B, M)`, where B is batch size and M is ``agent_num``. |
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Examples: |
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>>> model = MAVAC(agent_obs_shape=64, global_obs_shape=128, action_shape=14) |
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>>> inputs = { |
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'agent_state': torch.randn(10, 8, 64), |
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'global_state': torch.randn(10, 8, 128), |
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'action_mask': torch.randint(0, 2, size=(10, 8, 14)) |
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} |
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>>> critic_outputs = model(inputs,'compute_critic') |
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>>> assert critic_outputs['value'].shape == torch.Size([10, 8]) |
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""" |
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x = self.critic_encoder(x['global_state']) |
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x = self.critic_head(x) |
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return {'value': x['pred']} |
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def compute_actor_critic(self, x: Dict) -> Dict: |
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""" |
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Overview: |
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MAVAC forward computation graph for both actor and critic part, input observation to predict action \ |
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logit and state value. |
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Arguments: |
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- x (:obj:`Dict`): The input dict contains ``agent_state``, ``global_state`` and other related info. |
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Returns: |
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- outputs (:obj:`Dict`): The output dict of MAVAC's forward computation graph for both actor and critic, \ |
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including ``logit`` and ``value``. |
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ReturnsKeys: |
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- logit (:obj:`torch.Tensor`): Logit encoding tensor, with same size as input ``x``. |
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- value (:obj:`torch.Tensor`): Q value tensor with same size as batch size. |
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Shapes: |
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- logit (:obj:`torch.FloatTensor`): :math:`(B, M, N)`, where B is batch size and N is ``action_shape`` \ |
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and M is ``agent_num``. |
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- value (:obj:`torch.FloatTensor`): :math:`(B, M)`, where B is batch sizeand M is ``agent_num``. |
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Examples: |
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>>> model = MAVAC(64, 64) |
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>>> inputs = { |
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'agent_state': torch.randn(10, 8, 64), |
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'global_state': torch.randn(10, 8, 128), |
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'action_mask': torch.randint(0, 2, size=(10, 8, 14)) |
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} |
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>>> outputs = model(inputs,'compute_actor_critic') |
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>>> assert outputs['value'].shape == torch.Size([10, 8]) |
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>>> assert outputs['logit'].shape == torch.Size([10, 8, 14]) |
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""" |
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logit = self.compute_actor(x)['logit'] |
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value = self.compute_critic(x)['value'] |
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return {'logit': logit, 'value': value} |
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