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from typing import Union, Dict, Optional
import torch
import torch.nn as nn
from ding.torch_utils import get_lstm
from ding.utils import SequenceType, squeeze, MODEL_REGISTRY
from ding.model.template.q_learning import parallel_wrapper
from ..common import ReparameterizationHead, RegressionHead, DiscreteHead, \
FCEncoder, ConvEncoder
class RNNLayer(nn.Module):
def __init__(self, lstm_type, input_size, hidden_size, res_link: bool = False):
super(RNNLayer, self).__init__()
self.rnn = get_lstm(lstm_type, input_size=input_size, hidden_size=hidden_size)
self.res_link = res_link
def forward(self, x, prev_state, inference: bool = False):
"""
Forward pass of the RNN layer.
If inference is True, sequence length of input is set to 1.
If res_link is True, a residual link is added to the output.
"""
# x: obs_embedding
if self.res_link:
a = x
if inference:
x = x.unsqueeze(0) # for rnn input, put the seq_len of x as 1 instead of none.
# prev_state: DataType: List[Tuple[torch.Tensor]]; Initially, it is a list of None
x, next_state = self.rnn(x, prev_state)
x = x.squeeze(0) # to delete the seq_len dim to match head network input
if self.res_link:
x = x + a
return {'output': x, 'next_state': next_state}
else:
# lstm_embedding stores all hidden_state
lstm_embedding = []
hidden_state_list = []
for t in range(x.shape[0]): # T timesteps
# use x[t:t+1] but not x[t] can keep original dimension
output, prev_state = self.rnn(x[t:t + 1], prev_state) # output: (1,B, head_hidden_size)
lstm_embedding.append(output)
hidden_state = [p['h'] for p in prev_state]
# only keep ht, {list: x.shape[0]{Tensor:(1, batch_size, head_hidden_size)}}
hidden_state_list.append(torch.cat(hidden_state, dim=1))
x = torch.cat(lstm_embedding, 0) # (T, B, head_hidden_size)
if self.res_link:
x = x + a
all_hidden_state = torch.cat(hidden_state_list, dim=0)
return {'output': x, 'next_state': prev_state, 'hidden_state': all_hidden_state}
@MODEL_REGISTRY.register('havac')
class HAVAC(nn.Module):
"""
Overview:
The HAVAC model of each agent for HAPPO.
Interfaces:
``__init__``, ``forward``
"""
mode = ['compute_actor', 'compute_critic', 'compute_actor_critic']
def __init__(
self,
agent_obs_shape: Union[int, SequenceType],
global_obs_shape: Union[int, SequenceType],
action_shape: Union[int, SequenceType],
agent_num: int,
use_lstm: bool = False,
lstm_type: str = 'gru',
encoder_hidden_size_list: SequenceType = [128, 128, 64],
actor_head_hidden_size: int = 64,
actor_head_layer_num: int = 2,
critic_head_hidden_size: int = 64,
critic_head_layer_num: int = 1,
action_space: str = 'discrete',
activation: Optional[nn.Module] = nn.ReLU(),
norm_type: Optional[str] = None,
sigma_type: Optional[str] = 'independent',
bound_type: Optional[str] = None,
res_link: bool = False,
) -> None:
r"""
Overview:
Init the VAC Model for HAPPO according to arguments.
Arguments:
- agent_obs_shape (:obj:`Union[int, SequenceType]`): Observation's space for single agent.
- global_obs_shape (:obj:`Union[int, SequenceType]`): Observation's space for global agent
- action_shape (:obj:`Union[int, SequenceType]`): Action's space.
- agent_num (:obj:`int`): Number of agents.
- lstm_type (:obj:`str`): use lstm or gru, default to gru
- encoder_hidden_size_list (:obj:`SequenceType`): Collection of ``hidden_size`` to pass to ``Encoder``
- actor_head_hidden_size (:obj:`Optional[int]`): The ``hidden_size`` to pass to actor-nn's ``Head``.
- actor_head_layer_num (:obj:`int`):
The num of layers used in the network to compute Q value output for actor's nn.
- critic_head_hidden_size (:obj:`Optional[int]`): The ``hidden_size`` to pass to critic-nn's ``Head``.
- critic_head_layer_num (:obj:`int`):
The num of layers used in the network to compute Q value output for critic's nn.
- activation (:obj:`Optional[nn.Module]`):
The type of activation function to use in ``MLP`` the after ``layer_fn``,
if ``None`` then default set to ``nn.ReLU()``
- norm_type (:obj:`Optional[str]`):
The type of normalization to use, see ``ding.torch_utils.fc_block`` for more details`
- res_link (:obj:`bool`): use the residual link or not, default to False
"""
super(HAVAC, self).__init__()
self.agent_num = agent_num
self.agent_models = nn.ModuleList(
[
HAVACAgent(
agent_obs_shape=agent_obs_shape,
global_obs_shape=global_obs_shape,
action_shape=action_shape,
use_lstm=use_lstm,
action_space=action_space,
) for _ in range(agent_num)
]
)
def forward(self, agent_idx, input_data, mode):
selected_agent_model = self.agent_models[agent_idx]
output = selected_agent_model(input_data, mode)
return output
class HAVACAgent(nn.Module):
"""
Overview:
The HAVAC model of each agent for HAPPO.
Interfaces:
``__init__``, ``forward``, ``compute_actor``, ``compute_critic``, ``compute_actor_critic``
"""
mode = ['compute_actor', 'compute_critic', 'compute_actor_critic']
def __init__(
self,
agent_obs_shape: Union[int, SequenceType],
global_obs_shape: Union[int, SequenceType],
action_shape: Union[int, SequenceType],
use_lstm: bool = False,
lstm_type: str = 'gru',
encoder_hidden_size_list: SequenceType = [128, 128, 64],
actor_head_hidden_size: int = 64,
actor_head_layer_num: int = 2,
critic_head_hidden_size: int = 64,
critic_head_layer_num: int = 1,
action_space: str = 'discrete',
activation: Optional[nn.Module] = nn.ReLU(),
norm_type: Optional[str] = None,
sigma_type: Optional[str] = 'happo',
bound_type: Optional[str] = None,
res_link: bool = False,
) -> None:
r"""
Overview:
Init the VAC Model for HAPPO according to arguments.
Arguments:
- agent_obs_shape (:obj:`Union[int, SequenceType]`): Observation's space for single agent.
- global_obs_shape (:obj:`Union[int, SequenceType]`): Observation's space for global agent
- action_shape (:obj:`Union[int, SequenceType]`): Action's space.
- lstm_type (:obj:`str`): use lstm or gru, default to gru
- encoder_hidden_size_list (:obj:`SequenceType`): Collection of ``hidden_size`` to pass to ``Encoder``
- actor_head_hidden_size (:obj:`Optional[int]`): The ``hidden_size`` to pass to actor-nn's ``Head``.
- actor_head_layer_num (:obj:`int`):
The num of layers used in the network to compute Q value output for actor's nn.
- critic_head_hidden_size (:obj:`Optional[int]`): The ``hidden_size`` to pass to critic-nn's ``Head``.
- critic_head_layer_num (:obj:`int`):
The num of layers used in the network to compute Q value output for critic's nn.
- activation (:obj:`Optional[nn.Module]`):
The type of activation function to use in ``MLP`` the after ``layer_fn``,
if ``None`` then default set to ``nn.ReLU()``
- norm_type (:obj:`Optional[str]`):
The type of normalization to use, see ``ding.torch_utils.fc_block`` for more details`
- res_link (:obj:`bool`): use the residual link or not, default to False
"""
super(HAVACAgent, self).__init__()
agent_obs_shape: int = squeeze(agent_obs_shape)
global_obs_shape: int = squeeze(global_obs_shape)
action_shape: int = squeeze(action_shape)
self.global_obs_shape, self.agent_obs_shape, self.action_shape = global_obs_shape, agent_obs_shape, action_shape
self.action_space = action_space
# Encoder Type
if isinstance(agent_obs_shape, int) or len(agent_obs_shape) == 1:
actor_encoder_cls = FCEncoder
elif len(agent_obs_shape) == 3:
actor_encoder_cls = ConvEncoder
else:
raise RuntimeError(
"not support obs_shape for pre-defined encoder: {}, please customize your own VAC".
format(agent_obs_shape)
)
if isinstance(global_obs_shape, int) or len(global_obs_shape) == 1:
critic_encoder_cls = FCEncoder
elif len(global_obs_shape) == 3:
critic_encoder_cls = ConvEncoder
else:
raise RuntimeError(
"not support obs_shape for pre-defined encoder: {}, please customize your own VAC".
format(global_obs_shape)
)
# We directly connect the Head after a Liner layer instead of using the 3-layer FCEncoder.
# In SMAC task it can obviously improve the performance.
# Users can change the model according to their own needs.
self.actor_encoder = actor_encoder_cls(
obs_shape=agent_obs_shape,
hidden_size_list=encoder_hidden_size_list,
activation=activation,
norm_type=norm_type
)
self.critic_encoder = critic_encoder_cls(
obs_shape=global_obs_shape,
hidden_size_list=encoder_hidden_size_list,
activation=activation,
norm_type=norm_type
)
# RNN part
self.use_lstm = use_lstm
if self.use_lstm:
self.actor_rnn = RNNLayer(
lstm_type,
input_size=encoder_hidden_size_list[-1],
hidden_size=actor_head_hidden_size,
res_link=res_link
)
self.critic_rnn = RNNLayer(
lstm_type,
input_size=encoder_hidden_size_list[-1],
hidden_size=critic_head_hidden_size,
res_link=res_link
)
# Head Type
self.critic_head = RegressionHead(
critic_head_hidden_size, 1, critic_head_layer_num, activation=activation, norm_type=norm_type
)
assert self.action_space in ['discrete', 'continuous'], self.action_space
if self.action_space == 'discrete':
self.actor_head = DiscreteHead(
actor_head_hidden_size, action_shape, actor_head_layer_num, activation=activation, norm_type=norm_type
)
elif self.action_space == 'continuous':
self.actor_head = ReparameterizationHead(
actor_head_hidden_size,
action_shape,
actor_head_layer_num,
sigma_type=sigma_type,
activation=activation,
norm_type=norm_type,
bound_type=bound_type
)
# must use list, not nn.ModuleList
self.actor = [self.actor_encoder, self.actor_rnn, self.actor_head] if self.use_lstm \
else [self.actor_encoder, self.actor_head]
self.critic = [self.critic_encoder, self.critic_rnn, self.critic_head] if self.use_lstm \
else [self.critic_encoder, self.critic_head]
# for convenience of call some apis(such as: self.critic.parameters()), but may cause
# misunderstanding when print(self)
self.actor = nn.ModuleList(self.actor)
self.critic = nn.ModuleList(self.critic)
def forward(self, inputs: Union[torch.Tensor, Dict], mode: str) -> Dict:
r"""
Overview:
Use encoded embedding tensor to predict output.
Parameter updates with VAC's MLPs forward setup.
Arguments:
Forward with ``'compute_actor'`` or ``'compute_critic'``:
- inputs (:obj:`torch.Tensor`):
The encoded embedding tensor, determined with given ``hidden_size``, i.e. ``(B, N=hidden_size)``.
Whether ``actor_head_hidden_size`` or ``critic_head_hidden_size`` depend on ``mode``.
Returns:
- outputs (:obj:`Dict`):
Run with encoder and head.
Forward with ``'compute_actor'``, Necessary Keys:
- logit (:obj:`torch.Tensor`): Logit encoding tensor, with same size as input ``x``.
Forward with ``'compute_critic'``, Necessary Keys:
- value (:obj:`torch.Tensor`): Q value tensor with same size as batch size.
Shapes:
- inputs (:obj:`torch.Tensor`): :math:`(B, N)`, where B is batch size and N corresponding ``hidden_size``
- logit (:obj:`torch.FloatTensor`): :math:`(B, N)`, where B is batch size and N is ``action_shape``
- value (:obj:`torch.FloatTensor`): :math:`(B, )`, where B is batch size.
Actor Examples:
>>> model = VAC(64,128)
>>> inputs = torch.randn(4, 64)
>>> actor_outputs = model(inputs,'compute_actor')
>>> assert actor_outputs['logit'].shape == torch.Size([4, 128])
Critic Examples:
>>> model = VAC(64,64)
>>> inputs = torch.randn(4, 64)
>>> critic_outputs = model(inputs,'compute_critic')
>>> critic_outputs['value']
tensor([0.0252, 0.0235, 0.0201, 0.0072], grad_fn=<SqueezeBackward1>)
Actor-Critic Examples:
>>> model = VAC(64,64)
>>> inputs = torch.randn(4, 64)
>>> outputs = model(inputs,'compute_actor_critic')
>>> outputs['value']
tensor([0.0252, 0.0235, 0.0201, 0.0072], grad_fn=<SqueezeBackward1>)
>>> assert outputs['logit'].shape == torch.Size([4, 64])
"""
assert mode in self.mode, "not support forward mode: {}/{}".format(mode, self.mode)
return getattr(self, mode)(inputs)
def compute_actor(self, inputs: Dict, inference: bool = False) -> Dict:
r"""
Overview:
Execute parameter updates with ``'compute_actor'`` mode
Use encoded embedding tensor to predict output.
Arguments:
- inputs (:obj:`torch.Tensor`):
input data dict with keys ['obs'(with keys ['agent_state', 'global_state', 'action_mask']),
'actor_prev_state']
Returns:
- outputs (:obj:`Dict`):
Run with encoder RNN(optional) and head.
ReturnsKeys:
- logit (:obj:`torch.Tensor`): Logit encoding tensor.
- actor_next_state:
- hidden_state
Shapes:
- logit (:obj:`torch.FloatTensor`): :math:`(B, N)`, where B is batch size and N is ``action_shape``
- actor_next_state: (B,)
- hidden_state:
Examples:
>>> model = HAVAC(
agent_obs_shape=obs_dim,
global_obs_shape=global_obs_dim,
action_shape=action_dim,
use_lstm = True,
)
>>> inputs = {
'obs': {
'agent_state': torch.randn(T, bs, obs_dim),
'global_state': torch.randn(T, bs, global_obs_dim),
'action_mask': torch.randint(0, 2, size=(T, bs, action_dim))
},
'actor_prev_state': [None for _ in range(bs)],
}
>>> actor_outputs = model(inputs,'compute_actor')
>>> assert actor_outputs['logit'].shape == (T, bs, action_dim)
"""
x = inputs['obs']['agent_state']
output = {}
if self.use_lstm:
rnn_actor_prev_state = inputs['actor_prev_state']
if inference:
x = self.actor_encoder(x)
rnn_output = self.actor_rnn(x, rnn_actor_prev_state, inference)
x = rnn_output['output']
x = self.actor_head(x)
output['next_state'] = rnn_output['next_state']
# output: 'logit'/'next_state'
else:
assert len(x.shape) in [3, 5], x.shape
x = parallel_wrapper(self.actor_encoder)(x) # (T, B, N)
rnn_output = self.actor_rnn(x, rnn_actor_prev_state, inference)
x = rnn_output['output']
x = parallel_wrapper(self.actor_head)(x)
output['actor_next_state'] = rnn_output['next_state']
output['actor_hidden_state'] = rnn_output['hidden_state']
# output: 'logit'/'actor_next_state'/'hidden_state'
else:
x = self.actor_encoder(x)
x = self.actor_head(x)
# output: 'logit'
if self.action_space == 'discrete':
action_mask = inputs['obs']['action_mask']
logit = x['logit']
logit[action_mask == 0.0] = -99999999
elif self.action_space == 'continuous':
logit = x
output['logit'] = logit
return output
def compute_critic(self, inputs: Dict, inference: bool = False) -> Dict:
r"""
Overview:
Execute parameter updates with ``'compute_critic'`` mode
Use encoded embedding tensor to predict output.
Arguments:
- inputs (:obj:`Dict`):
input data dict with keys ['obs'(with keys ['agent_state', 'global_state', 'action_mask']),
'critic_prev_state'(when you are using rnn)]
Returns:
- outputs (:obj:`Dict`):
Run with encoder [rnn] and head.
Necessary Keys:
- value (:obj:`torch.Tensor`): Q value tensor with same size as batch size.
- logits
Shapes:
- value (:obj:`torch.FloatTensor`): :math:`(B, )`, where B is batch size.
- logits
Examples:
>>> model = HAVAC(
agent_obs_shape=obs_dim,
global_obs_shape=global_obs_dim,
action_shape=action_dim,
use_lstm = True,
)
>>> inputs = {
'obs': {
'agent_state': torch.randn(T, bs, obs_dim),
'global_state': torch.randn(T, bs, global_obs_dim),
'action_mask': torch.randint(0, 2, size=(T, bs, action_dim))
},
'critic_prev_state': [None for _ in range(bs)],
}
>>> critic_outputs = model(inputs,'compute_critic')
>>> assert critic_outputs['value'].shape == (T, bs))
"""
global_obs = inputs['obs']['global_state']
output = {}
if self.use_lstm:
rnn_critic_prev_state = inputs['critic_prev_state']
if inference:
x = self.critic_encoder(global_obs)
rnn_output = self.critic_rnn(x, rnn_critic_prev_state, inference)
x = rnn_output['output']
x = self.critic_head(x)
output['next_state'] = rnn_output['next_state']
# output: 'value'/'next_state'
else:
assert len(global_obs.shape) in [3, 5], global_obs.shape
x = parallel_wrapper(self.critic_encoder)(global_obs) # (T, B, N)
rnn_output = self.critic_rnn(x, rnn_critic_prev_state, inference)
x = rnn_output['output']
x = parallel_wrapper(self.critic_head)(x)
output['critic_next_state'] = rnn_output['next_state']
output['critic_hidden_state'] = rnn_output['hidden_state']
# output: 'value'/'critic_next_state'/'hidden_state'
else:
x = self.critic_encoder(global_obs)
x = self.critic_head(x)
# output: 'value'
output['value'] = x['pred']
return output
def compute_actor_critic(self, inputs: Dict, inference: bool = False) -> Dict:
r"""
Overview:
Execute parameter updates with ``'compute_actor_critic'`` mode
Use encoded embedding tensor to predict output.
Arguments:
- inputs (:dict): input data dict with keys
['obs'(with keys ['agent_state', 'global_state', 'action_mask']),
'actor_prev_state', 'critic_prev_state'(when you are using rnn)]
Returns:
- outputs (:obj:`Dict`):
Run with encoder and head.
ReturnsKeys:
- logit (:obj:`torch.Tensor`): Logit encoding tensor, with same size as input ``x``.
- value (:obj:`torch.Tensor`): Q value tensor with same size as batch size.
Shapes:
- logit (:obj:`torch.FloatTensor`): :math:`(B, N)`, where B is batch size and N is ``action_shape``
- value (:obj:`torch.FloatTensor`): :math:`(B, )`, where B is batch size.
Examples:
>>> model = VAC(64,64)
>>> inputs = torch.randn(4, 64)
>>> outputs = model(inputs,'compute_actor_critic')
>>> outputs['value']
tensor([0.0252, 0.0235, 0.0201, 0.0072], grad_fn=<SqueezeBackward1>)
>>> assert outputs['logit'].shape == torch.Size([4, 64])
.. note::
``compute_actor_critic`` interface aims to save computation when shares encoder.
Returning the combination dictionry.
"""
actor_output = self.compute_actor(inputs, inference)
critic_output = self.compute_critic(inputs, inference)
if self.use_lstm:
return {
'logit': actor_output['logit'],
'value': critic_output['value'],
'actor_next_state': actor_output['actor_next_state'],
'actor_hidden_state': actor_output['actor_hidden_state'],
'critic_next_state': critic_output['critic_next_state'],
'critic_hidden_state': critic_output['critic_hidden_state'],
}
else:
return {
'logit': actor_output['logit'],
'value': critic_output['value'],
}