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from typing import Dict, Optional, Union from ray.rllib.algorithms.dqn.dqn_torch_model import DQNTorchModel from ray.rllib.models.torch.fcnet import FullyConnectedNetwork as TorchFC from ray.rllib.models.tf.fcnet import FullyConnectedNetwork from ray.rllib.models.torch.torch_modelv2 import TorchModelV2 from ray.rllib.utils.framework import try_import_tf, try_import_torch from ray.rllib.utils.torch_utils import FLOAT_MIN, FLOAT_MAX
torch, nn = try_import_torch()
class TorchActionMaskModel(TorchModelV2, nn.Module):
def __init__( self, obs_space, action_space, num_outputs, model_config, name, **kwargs, ): orig_space = getattr(obs_space, "original_space", obs_space) TorchModelV2.__init__( self, obs_space, action_space, num_outputs, model_config, name, **kwargs ) nn.Module.__init__(self) self.count = 0
self.internal_model = TorchFC( orig_space["data"], action_space, num_outputs, model_config, name + "_internal", )
def forward(self, input_dict, state, seq_lens): # Extract the available actions tensor from the observation. # Compute the unmasked logits. logits, _ = self.internal_model({"obs": input_dict["obs"]["data"]}) action_mask = input_dict["obs"]["action_mask"]
inf_mask = torch.clamp(torch.log(action_mask), min=FLOAT_MIN) masked_logits = logits + inf_mask
# Return masked logits. return masked_logits, state
def value_function(self): return self.internal_model.value_function()
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