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gru.py
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gru.py
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# Copyright (c) Meta Platforms, Inc. and affiliates.
#
# This source code is licensed under the license found in the
# LICENSE file in the root directory of this source tree.
#
from __future__ import annotations
from dataclasses import dataclass, MISSING
from typing import Optional, Sequence, Type
import torch
import torch.nn.functional as F
from tensordict import TensorDict, TensorDictBase
from tensordict.utils import expand_as_right, unravel_key_list
from torch import nn
from torchrl.data.tensor_specs import Composite, Unbounded
from torchrl.modules import GRUCell, MLP, MultiAgentMLP
from benchmarl.models.common import Model, ModelConfig
from benchmarl.utils import DEVICE_TYPING
class GRU(torch.nn.Module):
def __init__(
self,
input_size: int,
hidden_size: int,
device: DEVICE_TYPING,
n_layers: int,
dropout: float,
bias: bool,
time_dim: int = -2,
):
super().__init__()
self.input_size = input_size
self.hidden_size = hidden_size
self.device = device
self.time_dim = time_dim
self.n_layers = n_layers
self.dropout = dropout
self.bias = bias
self.grus = torch.nn.ModuleList(
[
GRUCell(
input_size if i == 0 else hidden_size,
hidden_size,
device=self.device,
bias=self.bias,
)
for i in range(self.n_layers)
]
)
def forward(
self,
input,
is_init,
h,
):
hs = []
h = list(h.unbind(dim=-2))
for in_t, init_t in zip(
input.unbind(self.time_dim), is_init.unbind(self.time_dim)
):
for layer in range(self.n_layers):
h[layer] = torch.where(init_t, 0, h[layer])
h[layer] = self.grus[layer](in_t, h[layer])
if layer < self.n_layers - 1 and self.dropout:
in_t = F.dropout(h[layer], p=self.dropout, training=self.training)
else:
in_t = h[layer]
hs.append(in_t)
h_n = torch.stack(h, dim=-2)
output = torch.stack(hs, self.time_dim)
return output, h_n
def get_net(input_size, hidden_size, n_layers, bias, device, dropout, compile):
gru = GRU(
input_size,
hidden_size,
n_layers=n_layers,
bias=bias,
device=device,
dropout=dropout,
)
if compile:
gru = torch.compile(gru, mode="reduce-overhead")
return gru
class MultiAgentGRU(torch.nn.Module):
def __init__(
self,
input_size: int,
hidden_size: int,
n_agents: int,
device: DEVICE_TYPING,
centralised: bool,
share_params: bool,
n_layers: int,
dropout: float,
bias: bool,
compile: bool,
):
super().__init__()
self.input_size = input_size
self.n_agents = n_agents
self.hidden_size = hidden_size
self.device = device
self.centralised = centralised
self.share_params = share_params
self.n_layers = n_layers
self.bias = bias
self.dropout = dropout
self.compile = compile
if self.centralised:
input_size = input_size * self.n_agents
agent_networks = [
get_net(
input_size=input_size,
hidden_size=self.hidden_size,
n_layers=self.n_layers,
bias=self.bias,
device=self.device,
dropout=self.dropout,
compile=self.compile,
)
for _ in range(self.n_agents if not self.share_params else 1)
]
self._make_params(agent_networks)
with torch.device("meta"):
self._empty_gru = get_net(
input_size=input_size,
hidden_size=self.hidden_size,
n_layers=self.n_layers,
bias=self.bias,
device="meta",
dropout=self.dropout,
compile=self.compile,
)
# Remove all parameters
TensorDict.from_module(self._empty_gru).data.to("meta").to_module(
self._empty_gru
)
def forward(
self,
input,
is_init,
h_0=None,
):
# Input and output always have the multiagent dimension
# Hidden states always have it apart from when it is centralized and share params
# is_init never has it
assert is_init is not None, "We need to pass is_init"
training = h_0 is None
missing_batch = False
if (
not training and len(input.shape) < 3
): # In evaluation the batch might be missing
missing_batch = True
input = input.unsqueeze(0)
h_0 = h_0.unsqueeze(0)
is_init = is_init.unsqueeze(0)
if (
not training
): # In collection we emulate the sequence dimension and we have the hidden state
input = input.unsqueeze(1)
# Check input
batch = input.shape[0]
seq = input.shape[1]
assert input.shape == (batch, seq, self.n_agents, self.input_size)
if h_0 is not None: # Collection
# Set hidden to 0 when is_init
h_0 = torch.where(expand_as_right(is_init, h_0), 0, h_0)
if not training: # If in collection emulate the sequence dimension
is_init = is_init.unsqueeze(1)
assert is_init.shape == (batch, seq, 1)
is_init = is_init.unsqueeze(-2).expand(batch, seq, self.n_agents, 1)
if h_0 is None:
if self.centralised and self.share_params:
shape = (
batch,
self.n_layers,
self.hidden_size,
)
else:
shape = (
batch,
self.n_agents,
self.n_layers,
self.hidden_size,
)
h_0 = torch.zeros(
shape,
device=self.device,
dtype=torch.float,
)
if self.centralised:
input = input.view(batch, seq, self.n_agents * self.input_size)
is_init = is_init[..., 0, :]
output, h_n = self.run_net(input, is_init, h_0)
if self.centralised and self.share_params:
output = output.unsqueeze(-2).expand(
batch, seq, self.n_agents, self.hidden_size
)
if not training:
output = output.squeeze(1)
if missing_batch:
output = output.squeeze(0)
h_n = h_n.squeeze(0)
return output, h_n
def run_net(self, input, is_init, h_0):
if not self.share_params:
if self.centralised:
output, h_n = self.vmap_func_module(
self._empty_gru,
(0, None, None, -3),
(-2, -3),
)(self.params, input, is_init, h_0)
else:
output, h_n = self.vmap_func_module(
self._empty_gru,
(0, -2, -2, -3),
(-2, -3),
)(self.params, input, is_init, h_0)
else:
with self.params.to_module(self._empty_gru):
if self.centralised:
output, h_n = self._empty_gru(input, is_init, h_0)
else:
output, h_n = torch.vmap(
self._empty_gru, in_dims=(-2, -2, -3), out_dims=(-2, -3)
)(input, is_init, h_0)
return output, h_n
def vmap_func_module(self, module, *args, **kwargs):
def exec_module(params, *input):
with params.to_module(module):
return module(*input)
return torch.vmap(exec_module, *args, **kwargs)
def _make_params(self, agent_networks):
if self.share_params:
self.params = TensorDict.from_module(agent_networks[0], as_module=True)
else:
self.params = TensorDict.from_modules(*agent_networks, as_module=True)
class Gru(Model):
r"""A multi-layer Gated Recurrent Unit (GRU) RNN like the one from
`torch <https://pytorch.org/docs/stable/generated/torch.nn.GRU.html>`__ .
The BenchMARL GRU accepts multiple inputs of type array: Tensors of shape ``(*batch,F)``
Where `F` is the number of features. These arrays will be concatenated along the F dimensions,
which will be processed to features of `hidden_size` by the GRU.
Args:
hidden_size (int): The number of features in the hidden state.
num_layers (int): Number of recurrent layers. E.g., setting ``num_layers=2``
would mean stacking two GRUs together to form a `stacked GRU`,
with the second GRU taking in outputs of the first GRU and
computing the final results. Default: 1
bias (bool): If ``False``, then the GRU layers do not use bias.
Default: ``True``
dropout (float): If non-zero, introduces a `Dropout` layer on the outputs of each
GRU layer except the last layer, with dropout probability equal to
:attr:`dropout`. Default: 0
compile (bool): If ``True``, compiles underlying gru model. Default: ``False``
"""
def __init__(
self,
hidden_size: int,
n_layers: int,
bias: bool,
dropout: float,
compile: bool,
**kwargs,
):
super().__init__(
input_spec=kwargs.pop("input_spec"),
output_spec=kwargs.pop("output_spec"),
agent_group=kwargs.pop("agent_group"),
input_has_agent_dim=kwargs.pop("input_has_agent_dim"),
n_agents=kwargs.pop("n_agents"),
centralised=kwargs.pop("centralised"),
share_params=kwargs.pop("share_params"),
device=kwargs.pop("device"),
action_spec=kwargs.pop("action_spec"),
model_index=kwargs.pop("model_index"),
is_critic=kwargs.pop("is_critic"),
)
self.hidden_state_name = (self.agent_group, f"_hidden_gru_{self.model_index}")
self.rnn_keys = unravel_key_list(["is_init", self.hidden_state_name])
self.in_keys += self.rnn_keys
self.hidden_size = hidden_size
self.n_layers = n_layers
self.bias = bias
self.dropout = dropout
self.compile = compile
self.input_features = sum(
[spec.shape[-1] for spec in self.input_spec.values(True, True)]
)
self.output_features = self.output_leaf_spec.shape[-1]
if self.input_has_agent_dim:
self.gru = MultiAgentGRU(
self.input_features,
self.hidden_size,
self.n_agents,
self.device,
bias=self.bias,
n_layers=self.n_layers,
centralised=self.centralised,
share_params=self.share_params,
dropout=self.dropout,
compile=self.compile,
)
else:
self.gru = nn.ModuleList(
[
get_net(
input_size=self.input_features,
hidden_size=self.hidden_size,
n_layers=self.n_layers,
bias=self.bias,
device=self.device,
dropout=self.dropout,
compile=self.compile,
)
for _ in range(self.n_agents if not self.share_params else 1)
]
)
mlp_net_kwargs = {
"_".join(k.split("_")[1:]): v
for k, v in kwargs.items()
if k.startswith("mlp_")
}
if self.output_has_agent_dim:
self.mlp = MultiAgentMLP(
n_agent_inputs=self.hidden_size,
n_agent_outputs=self.output_features,
n_agents=self.n_agents,
centralised=self.centralised,
share_params=self.share_params,
device=self.device,
**mlp_net_kwargs,
)
else:
self.mlp = nn.ModuleList(
[
MLP(
in_features=self.hidden_size,
out_features=self.output_features,
device=self.device,
**mlp_net_kwargs,
)
for _ in range(self.n_agents if not self.share_params else 1)
]
)
def _perform_checks(self):
super()._perform_checks()
input_shape = None
for input_key, input_spec in self.input_spec.items(True, True):
if (self.input_has_agent_dim and len(input_spec.shape) == 2) or (
not self.input_has_agent_dim and len(input_spec.shape) == 1
):
if input_shape is None:
input_shape = input_spec.shape[:-1]
else:
if input_spec.shape[:-1] != input_shape:
raise ValueError(
f"GRU inputs should all have the same shape up to the last dimension, got {self.input_spec}"
)
else:
raise ValueError(
f"GRU input value {input_key} from {self.input_spec} has an invalid shape, maybe you need a CNN?"
)
if self.input_has_agent_dim:
if input_shape[-1] != self.n_agents:
raise ValueError(
"If the GRU input has the agent dimension,"
f" the second to last spec dimension should be the number of agents, got {self.input_spec}"
)
if (
self.output_has_agent_dim
and self.output_leaf_spec.shape[-2] != self.n_agents
):
raise ValueError(
"If the GRU output has the agent dimension,"
" the second to last spec dimension should be the number of agents"
)
def _forward(self, tensordict: TensorDictBase) -> TensorDictBase:
# Gather in_key
input = torch.cat(
[
tensordict.get(in_key)
for in_key in self.in_keys
if in_key not in self.rnn_keys
],
dim=-1,
)
h_0 = tensordict.get(self.hidden_state_name, None)
is_init = tensordict.get("is_init")
training = h_0 is None
# Has multi-agent input dimension
if self.input_has_agent_dim:
output, h_n = self.gru(input, is_init, h_0)
if not self.output_has_agent_dim:
output = output[..., 0, :]
else: # Is a global input, this is a critic
# Check input
batch = input.shape[0]
seq = input.shape[1]
assert input.shape == (batch, seq, self.input_features)
assert is_init.shape == (batch, seq, 1)
h_0 = torch.zeros(
(batch, self.n_layers, self.hidden_size),
device=self.device,
dtype=torch.float,
)
if self.share_params:
output, _ = self.gru[0](input, is_init, h_0)
else:
outputs = []
for net in self.gru:
output, _ = net(input, is_init, h_0)
outputs.append(output)
output = torch.stack(outputs, dim=-2)
# Mlp
if self.output_has_agent_dim:
output = self.mlp.forward(output)
else:
if not self.share_params:
output = torch.stack(
[net(output) for net in self.mlp],
dim=-2,
)
else:
output = self.mlp[0](output)
tensordict.set(self.out_key, output)
if not training:
tensordict.set(("next", *self.hidden_state_name), h_n)
return tensordict
@dataclass
class GruConfig(ModelConfig):
"""Dataclass config for a :class:`~benchmarl.models.Gru`."""
hidden_size: int = MISSING
n_layers: int = MISSING
bias: bool = MISSING
dropout: float = MISSING
compile: bool = MISSING
mlp_num_cells: Sequence[int] = MISSING
mlp_layer_class: Type[nn.Module] = MISSING
mlp_activation_class: Type[nn.Module] = MISSING
mlp_activation_kwargs: Optional[dict] = None
mlp_norm_class: Type[nn.Module] = None
mlp_norm_kwargs: Optional[dict] = None
@staticmethod
def associated_class():
return Gru
@property
def is_rnn(self) -> bool:
return True
def get_model_state_spec(self, model_index: int = 0) -> Composite:
spec = Composite(
{
f"_hidden_gru_{model_index}": Unbounded(
shape=(self.n_layers, self.hidden_size)
)
}
)
return spec