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609 行
23 KiB
609 行
23 KiB
from typing import Any, Dict, List, Optional, Tuple, Callable
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import numpy as np
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from distutils.version import LooseVersion
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from mlagents_envs.timers import timed
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from mlagents.tf_utils import tf
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from mlagents import tf_utils
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from mlagents_envs.exception import UnityException
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from mlagents_envs.base_env import BehaviorSpec
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from mlagents_envs.logging_util import get_logger
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from mlagents.trainers.policy import Policy
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from mlagents.trainers.action_info import ActionInfo
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from mlagents.trainers.trajectory import SplitObservations
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from mlagents.trainers.behavior_id_utils import get_global_agent_id
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from mlagents_envs.base_env import DecisionSteps
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from mlagents.trainers.tf.models import ModelUtils
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from mlagents.trainers.settings import TrainerSettings, EncoderType
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from mlagents.trainers import __version__
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from mlagents.trainers.tf.distributions import (
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GaussianDistribution,
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MultiCategoricalDistribution,
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)
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from mlagents.tf_utils.globals import get_rank
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logger = get_logger(__name__)
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# This is the version number of the inputs and outputs of the model, and
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# determines compatibility with inference in Barracuda.
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MODEL_FORMAT_VERSION = 2
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EPSILON = 1e-6 # Small value to avoid divide by zero
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class UnityPolicyException(UnityException):
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"""
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Related to errors with the Trainer.
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"""
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pass
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class TFPolicy(Policy):
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"""
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Contains a learning model, and the necessary
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functions to save/load models and create the input placeholders.
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"""
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# Callback function used at the start of training to synchronize weights.
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# By default, this nothing.
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# If this needs to be used, it should be done from outside ml-agents.
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broadcast_global_variables: Callable[[int], None] = lambda root_rank: None
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def __init__(
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self,
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seed: int,
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behavior_spec: BehaviorSpec,
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trainer_settings: TrainerSettings,
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tanh_squash: bool = False,
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reparameterize: bool = False,
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condition_sigma_on_obs: bool = True,
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create_tf_graph: bool = True,
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):
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"""
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Initialized the policy.
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:param seed: Random seed to use for TensorFlow.
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:param brain: The corresponding Brain for this policy.
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:param trainer_settings: The trainer parameters.
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"""
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super().__init__(
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seed,
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behavior_spec,
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trainer_settings,
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tanh_squash,
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reparameterize,
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condition_sigma_on_obs,
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)
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# for ghost trainer save/load snapshots
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self.assign_phs: List[tf.Tensor] = []
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self.assign_ops: List[tf.Operation] = []
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self.update_dict: Dict[str, tf.Tensor] = {}
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self.inference_dict: Dict[str, tf.Tensor] = {}
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self.first_normalization_update: bool = False
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self.graph = tf.Graph()
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self.sess = tf.Session(
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config=tf_utils.generate_session_config(), graph=self.graph
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)
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self._initialize_tensorflow_references()
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self.grads = None
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self.update_batch: Optional[tf.Operation] = None
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self.trainable_variables: List[tf.Variable] = []
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self.rank = get_rank()
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if create_tf_graph:
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self.create_tf_graph()
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def get_trainable_variables(self) -> List[tf.Variable]:
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"""
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Returns a List of the trainable variables in this policy. if create_tf_graph hasn't been called,
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returns empty list.
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"""
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return self.trainable_variables
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def create_tf_graph(self) -> None:
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"""
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Builds the tensorflow graph needed for this policy.
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"""
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with self.graph.as_default():
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tf.set_random_seed(self.seed)
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_vars = tf.get_collection(tf.GraphKeys.GLOBAL_VARIABLES)
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if len(_vars) > 0:
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# We assume the first thing created in the graph is the Policy. If
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# already populated, don't create more tensors.
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return
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self.create_input_placeholders()
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encoded = self._create_encoder(
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self.visual_in,
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self.processed_vector_in,
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self.h_size,
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self.num_layers,
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self.vis_encode_type,
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)
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if self.use_continuous_act:
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self._create_cc_actor(
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encoded,
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self.tanh_squash,
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self.reparameterize,
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self.condition_sigma_on_obs,
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)
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else:
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self._create_dc_actor(encoded)
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self.trainable_variables = tf.get_collection(
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tf.GraphKeys.TRAINABLE_VARIABLES, scope="policy"
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)
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self.trainable_variables += tf.get_collection(
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tf.GraphKeys.TRAINABLE_VARIABLES, scope="lstm"
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) # LSTMs need to be root scope for Barracuda export
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self.inference_dict = {
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"action": self.output,
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"log_probs": self.all_log_probs,
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"entropy": self.entropy,
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}
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if self.use_continuous_act:
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self.inference_dict["pre_action"] = self.output_pre
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if self.use_recurrent:
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self.inference_dict["memory_out"] = self.memory_out
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# We do an initialize to make the Policy usable out of the box. If an optimizer is needed,
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# it will re-load the full graph
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self.initialize()
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# Create assignment ops for Ghost Trainer
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self.init_load_weights()
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def _create_encoder(
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self,
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visual_in: List[tf.Tensor],
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vector_in: tf.Tensor,
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h_size: int,
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num_layers: int,
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vis_encode_type: EncoderType,
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) -> tf.Tensor:
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"""
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Creates an encoder for visual and vector observations.
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:param h_size: Size of hidden linear layers.
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:param num_layers: Number of hidden linear layers.
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:param vis_encode_type: Type of visual encoder to use if visual input.
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:return: The hidden layer (tf.Tensor) after the encoder.
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"""
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with tf.variable_scope("policy"):
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encoded = ModelUtils.create_observation_streams(
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self.visual_in,
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self.processed_vector_in,
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1,
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h_size,
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num_layers,
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vis_encode_type,
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)[0]
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return encoded
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@staticmethod
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def _convert_version_string(version_string: str) -> Tuple[int, ...]:
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"""
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Converts the version string into a Tuple of ints (major_ver, minor_ver, patch_ver).
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:param version_string: The semantic-versioned version string (X.Y.Z).
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:return: A Tuple containing (major_ver, minor_ver, patch_ver).
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"""
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ver = LooseVersion(version_string)
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return tuple(map(int, ver.version[0:3]))
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def initialize(self):
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with self.graph.as_default():
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init = tf.global_variables_initializer()
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self.sess.run(init)
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def get_weights(self):
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with self.graph.as_default():
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_vars = tf.get_collection(tf.GraphKeys.GLOBAL_VARIABLES)
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values = [v.eval(session=self.sess) for v in _vars]
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return values
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def init_load_weights(self):
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with self.graph.as_default():
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_vars = tf.get_collection(tf.GraphKeys.GLOBAL_VARIABLES)
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values = [v.eval(session=self.sess) for v in _vars]
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for var, value in zip(_vars, values):
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assign_ph = tf.placeholder(var.dtype, shape=value.shape)
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self.assign_phs.append(assign_ph)
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self.assign_ops.append(tf.assign(var, assign_ph))
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def load_weights(self, values):
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if len(self.assign_ops) == 0:
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logger.warning(
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"Calling load_weights in tf_policy but assign_ops is empty. Did you forget to call init_load_weights?"
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)
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with self.graph.as_default():
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feed_dict = {}
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for assign_ph, value in zip(self.assign_phs, values):
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feed_dict[assign_ph] = value
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self.sess.run(self.assign_ops, feed_dict=feed_dict)
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@timed
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def evaluate(
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self, decision_requests: DecisionSteps, global_agent_ids: List[str]
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) -> Dict[str, Any]:
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"""
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Evaluates policy for the agent experiences provided.
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:param decision_requests: DecisionSteps object containing inputs.
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:param global_agent_ids: The global (with worker ID) agent ids of the data in the batched_step_result.
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:return: Outputs from network as defined by self.inference_dict.
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"""
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feed_dict = {
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self.batch_size_ph: len(decision_requests),
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self.sequence_length_ph: 1,
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}
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if self.use_recurrent:
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if not self.use_continuous_act:
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feed_dict[self.prev_action] = self.retrieve_previous_action(
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global_agent_ids
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)["discrete_action"]
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feed_dict[self.memory_in] = self.retrieve_memories(global_agent_ids)
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feed_dict = self.fill_eval_dict(feed_dict, decision_requests)
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run_out = self._execute_model(feed_dict, self.inference_dict)
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return run_out
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def get_action(
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self, decision_requests: DecisionSteps, worker_id: int = 0
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) -> ActionInfo:
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"""
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Decides actions given observations information, and takes them in environment.
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:param decision_requests: A dictionary of brain names and DecisionSteps from environment.
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:param worker_id: In parallel environment training, the unique id of the environment worker that
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the DecisionSteps came from. Used to construct a globally unique id for each agent.
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:return: an ActionInfo containing action, memories, values and an object
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to be passed to add experiences
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"""
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if len(decision_requests) == 0:
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return ActionInfo.empty()
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global_agent_ids = [
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get_global_agent_id(worker_id, int(agent_id))
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for agent_id in decision_requests.agent_id
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] # For 1-D array, the iterator order is correct.
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run_out = self.evaluate( # pylint: disable=assignment-from-no-return
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decision_requests, global_agent_ids
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)
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self.save_memories(global_agent_ids, run_out.get("memory_out"))
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# For Compatibility with buffer changes for hybrid action support
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if "log_probs" in run_out:
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run_out["log_probs"] = {"action_probs": run_out["log_probs"]}
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if "action" in run_out:
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if self.behavior_spec.action_spec.is_continuous():
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run_out["action"] = {"continuous_action": run_out["action"]}
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else:
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run_out["action"] = {"discrete_action": run_out["action"]}
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return ActionInfo(
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action=run_out.get("action"),
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value=run_out.get("value"),
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outputs=run_out,
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agent_ids=decision_requests.agent_id,
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)
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def update(self, mini_batch, num_sequences):
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"""
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Performs update of the policy.
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:param num_sequences: Number of experience trajectories in batch.
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:param mini_batch: Batch of experiences.
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:return: Results of update.
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"""
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raise UnityPolicyException("The update function was not implemented.")
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def _execute_model(self, feed_dict, out_dict):
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"""
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Executes model.
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:param feed_dict: Input dictionary mapping nodes to input data.
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:param out_dict: Output dictionary mapping names to nodes.
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:return: Dictionary mapping names to input data.
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"""
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network_out = self.sess.run(list(out_dict.values()), feed_dict=feed_dict)
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run_out = dict(zip(list(out_dict.keys()), network_out))
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return run_out
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def fill_eval_dict(self, feed_dict, batched_step_result):
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vec_vis_obs = SplitObservations.from_observations(batched_step_result.obs)
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for i, _ in enumerate(vec_vis_obs.visual_observations):
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feed_dict[self.visual_in[i]] = vec_vis_obs.visual_observations[i]
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if self.use_vec_obs:
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feed_dict[self.vector_in] = vec_vis_obs.vector_observations
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if not self.use_continuous_act:
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mask = np.ones(
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(
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len(batched_step_result),
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sum(self.behavior_spec.action_spec.discrete_branches),
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),
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dtype=np.float32,
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)
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if batched_step_result.action_mask is not None:
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mask = 1 - np.concatenate(batched_step_result.action_mask, axis=1)
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feed_dict[self.action_masks] = mask
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return feed_dict
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def get_current_step(self):
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"""
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Gets current model step.
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:return: current model step.
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"""
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step = self.sess.run(self.global_step)
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return step
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def set_step(self, step: int) -> int:
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"""
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Sets current model step to step without creating additional ops.
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:param step: Step to set the current model step to.
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:return: The step the model was set to.
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"""
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current_step = self.get_current_step()
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# Increment a positive or negative number of steps.
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return self.increment_step(step - current_step)
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def increment_step(self, n_steps):
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"""
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Increments model step.
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"""
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out_dict = {
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"global_step": self.global_step,
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"increment_step": self.increment_step_op,
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}
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feed_dict = {self.steps_to_increment: n_steps}
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return self.sess.run(out_dict, feed_dict=feed_dict)["global_step"]
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def get_inference_vars(self):
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"""
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:return:list of inference var names
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"""
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return list(self.inference_dict.keys())
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def get_update_vars(self):
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"""
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:return:list of update var names
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"""
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return list(self.update_dict.keys())
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def update_normalization(self, vector_obs: np.ndarray) -> None:
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"""
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If this policy normalizes vector observations, this will update the norm values in the graph.
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:param vector_obs: The vector observations to add to the running estimate of the distribution.
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"""
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if self.use_vec_obs and self.normalize:
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if self.first_normalization_update:
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self.sess.run(
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self.init_normalization_op, feed_dict={self.vector_in: vector_obs}
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)
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self.first_normalization_update = False
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else:
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self.sess.run(
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self.update_normalization_op, feed_dict={self.vector_in: vector_obs}
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)
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@property
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def use_vis_obs(self):
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return self.vis_obs_size > 0
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@property
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def use_vec_obs(self):
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return self.vec_obs_size > 0
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def _initialize_tensorflow_references(self):
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self.value_heads: Dict[str, tf.Tensor] = {}
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self.normalization_steps: Optional[tf.Variable] = None
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self.running_mean: Optional[tf.Variable] = None
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self.running_variance: Optional[tf.Variable] = None
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self.init_normalization_op: Optional[tf.Operation] = None
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self.update_normalization_op: Optional[tf.Operation] = None
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self.value: Optional[tf.Tensor] = None
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self.all_log_probs: tf.Tensor = None
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self.total_log_probs: Optional[tf.Tensor] = None
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self.entropy: Optional[tf.Tensor] = None
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self.output_pre: Optional[tf.Tensor] = None
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self.output: Optional[tf.Tensor] = None
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self.selected_actions: tf.Tensor = None
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self.action_masks: Optional[tf.Tensor] = None
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self.prev_action: Optional[tf.Tensor] = None
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self.memory_in: Optional[tf.Tensor] = None
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self.memory_out: Optional[tf.Tensor] = None
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self.version_tensors: Optional[Tuple[tf.Tensor, tf.Tensor, tf.Tensor]] = None
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def create_input_placeholders(self):
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with self.graph.as_default():
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(
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self.global_step,
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self.increment_step_op,
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self.steps_to_increment,
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) = ModelUtils.create_global_steps()
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self.vector_in, self.visual_in = ModelUtils.create_input_placeholders(
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self.behavior_spec.observation_shapes
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)
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if self.normalize:
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self.first_normalization_update = True
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normalization_tensors = ModelUtils.create_normalizer(self.vector_in)
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self.update_normalization_op = normalization_tensors.update_op
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self.init_normalization_op = normalization_tensors.init_op
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self.normalization_steps = normalization_tensors.steps
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self.running_mean = normalization_tensors.running_mean
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self.running_variance = normalization_tensors.running_variance
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self.processed_vector_in = ModelUtils.normalize_vector_obs(
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self.vector_in,
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self.running_mean,
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self.running_variance,
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self.normalization_steps,
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)
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else:
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self.processed_vector_in = self.vector_in
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self.update_normalization_op = None
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self.batch_size_ph = tf.placeholder(
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shape=None, dtype=tf.int32, name="batch_size"
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)
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self.sequence_length_ph = tf.placeholder(
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shape=None, dtype=tf.int32, name="sequence_length"
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)
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self.mask_input = tf.placeholder(
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shape=[None], dtype=tf.float32, name="masks"
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)
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# Only needed for PPO, but needed for BC module
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self.epsilon = tf.placeholder(
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shape=[None, self.act_size[0]], dtype=tf.float32, name="epsilon"
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)
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self.mask = tf.cast(self.mask_input, tf.int32)
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tf.Variable(
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int(self.behavior_spec.action_spec.is_continuous()),
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name="is_continuous_control",
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trainable=False,
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dtype=tf.int32,
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)
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int_version = TFPolicy._convert_version_string(__version__)
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major_ver_t = tf.Variable(
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int_version[0],
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name="trainer_major_version",
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trainable=False,
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dtype=tf.int32,
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)
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minor_ver_t = tf.Variable(
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int_version[1],
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name="trainer_minor_version",
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trainable=False,
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dtype=tf.int32,
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)
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patch_ver_t = tf.Variable(
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int_version[2],
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name="trainer_patch_version",
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trainable=False,
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dtype=tf.int32,
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)
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self.version_tensors = (major_ver_t, minor_ver_t, patch_ver_t)
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tf.Variable(
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MODEL_FORMAT_VERSION,
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name="version_number",
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|
trainable=False,
|
|
dtype=tf.int32,
|
|
)
|
|
tf.Variable(
|
|
self.m_size, name="memory_size", trainable=False, dtype=tf.int32
|
|
)
|
|
if self.behavior_spec.action_spec.is_continuous():
|
|
tf.Variable(
|
|
self.act_size[0],
|
|
name="action_output_shape",
|
|
trainable=False,
|
|
dtype=tf.int32,
|
|
)
|
|
else:
|
|
tf.Variable(
|
|
sum(self.act_size),
|
|
name="action_output_shape",
|
|
trainable=False,
|
|
dtype=tf.int32,
|
|
)
|
|
|
|
def _create_cc_actor(
|
|
self,
|
|
encoded: tf.Tensor,
|
|
tanh_squash: bool = False,
|
|
reparameterize: bool = False,
|
|
condition_sigma_on_obs: bool = True,
|
|
) -> None:
|
|
"""
|
|
Creates Continuous control actor-critic model.
|
|
:param h_size: Size of hidden linear layers.
|
|
:param num_layers: Number of hidden linear layers.
|
|
:param vis_encode_type: Type of visual encoder to use if visual input.
|
|
:param tanh_squash: Whether to use a tanh function, or a clipped output.
|
|
:param reparameterize: Whether we are using the resampling trick to update the policy.
|
|
"""
|
|
if self.use_recurrent:
|
|
self.memory_in = tf.placeholder(
|
|
shape=[None, self.m_size], dtype=tf.float32, name="recurrent_in"
|
|
)
|
|
hidden_policy, memory_policy_out = ModelUtils.create_recurrent_encoder(
|
|
encoded, self.memory_in, self.sequence_length_ph, name="lstm_policy"
|
|
)
|
|
|
|
self.memory_out = tf.identity(memory_policy_out, name="recurrent_out")
|
|
else:
|
|
hidden_policy = encoded
|
|
|
|
with tf.variable_scope("policy"):
|
|
distribution = GaussianDistribution(
|
|
hidden_policy,
|
|
self.act_size,
|
|
reparameterize=reparameterize,
|
|
tanh_squash=tanh_squash,
|
|
condition_sigma=condition_sigma_on_obs,
|
|
)
|
|
|
|
if tanh_squash:
|
|
self.output_pre = distribution.sample
|
|
self.output = tf.identity(self.output_pre, name="action")
|
|
else:
|
|
self.output_pre = distribution.sample
|
|
# Clip and scale output to ensure actions are always within [-1, 1] range.
|
|
output_post = tf.clip_by_value(self.output_pre, -3, 3) / 3
|
|
self.output = tf.identity(output_post, name="action")
|
|
|
|
self.selected_actions = tf.stop_gradient(self.output)
|
|
|
|
self.all_log_probs = tf.identity(distribution.log_probs, name="action_probs")
|
|
self.entropy = distribution.entropy
|
|
|
|
# We keep these tensors the same name, but use new nodes to keep code parallelism with discrete control.
|
|
self.total_log_probs = distribution.total_log_probs
|
|
|
|
def _create_dc_actor(self, encoded: tf.Tensor) -> None:
|
|
"""
|
|
Creates Discrete control actor-critic model.
|
|
:param h_size: Size of hidden linear layers.
|
|
:param num_layers: Number of hidden linear layers.
|
|
:param vis_encode_type: Type of visual encoder to use if visual input.
|
|
"""
|
|
if self.use_recurrent:
|
|
self.prev_action = tf.placeholder(
|
|
shape=[None, len(self.act_size)], dtype=tf.int32, name="prev_action"
|
|
)
|
|
prev_action_oh = tf.concat(
|
|
[
|
|
tf.one_hot(self.prev_action[:, i], self.act_size[i])
|
|
for i in range(len(self.act_size))
|
|
],
|
|
axis=1,
|
|
)
|
|
hidden_policy = tf.concat([encoded, prev_action_oh], axis=1)
|
|
|
|
self.memory_in = tf.placeholder(
|
|
shape=[None, self.m_size], dtype=tf.float32, name="recurrent_in"
|
|
)
|
|
hidden_policy, memory_policy_out = ModelUtils.create_recurrent_encoder(
|
|
hidden_policy,
|
|
self.memory_in,
|
|
self.sequence_length_ph,
|
|
name="lstm_policy",
|
|
)
|
|
|
|
self.memory_out = tf.identity(memory_policy_out, "recurrent_out")
|
|
else:
|
|
hidden_policy = encoded
|
|
|
|
self.action_masks = tf.placeholder(
|
|
shape=[None, sum(self.act_size)], dtype=tf.float32, name="action_masks"
|
|
)
|
|
|
|
with tf.variable_scope("policy"):
|
|
distribution = MultiCategoricalDistribution(
|
|
hidden_policy, self.act_size, self.action_masks
|
|
)
|
|
# It's important that we are able to feed_dict a value into this tensor to get the
|
|
# right one-hot encoding, so we can't do identity on it.
|
|
self.output = distribution.sample
|
|
self.all_log_probs = tf.identity(distribution.log_probs, name="action")
|
|
self.selected_actions = tf.stop_gradient(
|
|
distribution.sample_onehot
|
|
) # In discrete, these are onehot
|
|
self.entropy = distribution.entropy
|
|
self.total_log_probs = distribution.total_log_probs
|