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1076 行
40 KiB
1076 行
40 KiB
import logging
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import numpy as np
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from mlagents.trainers import tf, tf_variance_scaling
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from mlagents.trainers.models import LearningModel, LearningRateSchedule, EncoderType
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LOG_STD_MAX = 2
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LOG_STD_MIN = -20
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EPSILON = 1e-6 # Small value to avoid divide by zero
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DISCRETE_TARGET_ENTROPY_SCALE = 0.2 # Roughly equal to e-greedy 0.05
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CONTINUOUS_TARGET_ENTROPY_SCALE = 1.0 # TODO: Make these an optional hyperparam.
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LOGGER = logging.getLogger("mlagents.trainers")
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POLICY_SCOPE = ""
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TARGET_SCOPE = "target_network"
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class SACNetwork(LearningModel):
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"""
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Base class for an SAC network. Implements methods for creating the actor and critic heads.
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"""
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def __init__(
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self,
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brain,
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m_size=None,
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h_size=128,
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normalize=False,
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use_recurrent=False,
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num_layers=2,
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stream_names=None,
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seed=0,
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vis_encode_type=EncoderType.SIMPLE,
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):
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LearningModel.__init__(
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self, m_size, normalize, use_recurrent, brain, seed, stream_names
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)
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self.normalize = normalize
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self.use_recurrent = use_recurrent
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self.num_layers = num_layers
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self.stream_names = stream_names
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self.h_size = h_size
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self.activ_fn = self.swish
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def get_vars(self, scope):
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return tf.get_collection(tf.GraphKeys.TRAINABLE_VARIABLES, scope=scope)
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def join_scopes(self, scope_1, scope_2):
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"""
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Joins two scopes. Does so safetly (i.e., if one of the two scopes doesn't
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exist, don't add any backslashes)
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"""
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if not scope_1:
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return scope_2
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if not scope_2:
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return scope_1
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else:
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return "/".join(filter(None, [scope_1, scope_2]))
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def create_cc_critic(self, hidden_value, scope, create_qs=True):
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"""
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Creates just the critic network
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"""
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scope = self.join_scopes(scope, "critic")
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self.create_sac_value_head(
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self.stream_names,
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hidden_value,
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self.num_layers,
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self.h_size,
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self.join_scopes(scope, "value"),
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)
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self.value_vars = self.get_vars(self.join_scopes(scope, "value"))
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if create_qs:
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hidden_q = tf.concat([hidden_value, self.external_action_in], axis=-1)
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hidden_qp = tf.concat([hidden_value, self.output], axis=-1)
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self.q1_heads, self.q2_heads, self.q1, self.q2 = self.create_q_heads(
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self.stream_names,
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hidden_q,
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self.num_layers,
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self.h_size,
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self.join_scopes(scope, "q"),
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)
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self.q1_pheads, self.q2_pheads, self.q1_p, self.q2_p = self.create_q_heads(
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self.stream_names,
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hidden_qp,
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self.num_layers,
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self.h_size,
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self.join_scopes(scope, "q"),
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reuse=True,
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)
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self.q_vars = self.get_vars(self.join_scopes(scope, "q"))
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self.critic_vars = self.get_vars(scope)
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def create_dc_critic(self, hidden_value, scope, create_qs=True):
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"""
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Creates just the critic network
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"""
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scope = self.join_scopes(scope, "critic")
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self.create_sac_value_head(
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self.stream_names,
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hidden_value,
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self.num_layers,
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self.h_size,
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self.join_scopes(scope, "value"),
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)
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self.value_vars = self.get_vars("/".join([scope, "value"]))
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if create_qs:
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self.q1_heads, self.q2_heads, self.q1, self.q2 = self.create_q_heads(
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self.stream_names,
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hidden_value,
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self.num_layers,
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self.h_size,
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self.join_scopes(scope, "q"),
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num_outputs=sum(self.act_size),
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)
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self.q1_pheads, self.q2_pheads, self.q1_p, self.q2_p = self.create_q_heads(
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self.stream_names,
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hidden_value,
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self.num_layers,
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self.h_size,
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self.join_scopes(scope, "q"),
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reuse=True,
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num_outputs=sum(self.act_size),
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)
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self.q_vars = self.get_vars(scope)
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self.critic_vars = self.get_vars(scope)
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def create_cc_actor(self, hidden_policy, scope):
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"""
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Creates Continuous control actor for SAC.
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:param hidden_policy: Output of feature extractor (i.e. the input for vector obs, output of CNN for visual obs).
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:param num_layers: TF scope to assign whatever is created in this block.
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"""
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# Create action input (continuous)
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self.action_holder = tf.placeholder(
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shape=[None, self.act_size[0]], dtype=tf.float32, name="action_holder"
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)
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self.external_action_in = self.action_holder
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scope = self.join_scopes(scope, "policy")
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with tf.variable_scope(scope):
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hidden_policy = self.create_vector_observation_encoder(
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hidden_policy,
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self.h_size,
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self.activ_fn,
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self.num_layers,
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"encoder",
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False,
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)
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if self.use_recurrent:
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hidden_policy, memory_out = self.create_recurrent_encoder(
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hidden_policy,
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self.policy_memory_in,
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self.sequence_length,
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name="lstm_policy",
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)
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self.policy_memory_out = memory_out
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with tf.variable_scope(scope):
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mu = tf.layers.dense(
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hidden_policy,
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self.act_size[0],
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activation=None,
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name="mu",
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kernel_initializer=LearningModel.scaled_init(0.01),
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)
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# Policy-dependent log_sigma_sq
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log_sigma_sq = tf.layers.dense(
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hidden_policy,
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self.act_size[0],
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activation=None,
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name="log_std",
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kernel_initializer=LearningModel.scaled_init(0.01),
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)
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self.log_sigma_sq = tf.clip_by_value(log_sigma_sq, LOG_STD_MIN, LOG_STD_MAX)
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sigma_sq = tf.exp(self.log_sigma_sq)
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# Do the reparameterization trick
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policy_ = mu + tf.random_normal(tf.shape(mu)) * sigma_sq
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_gauss_pre = -0.5 * (
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((policy_ - mu) / (tf.exp(self.log_sigma_sq) + EPSILON)) ** 2
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+ 2 * self.log_sigma_sq
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+ np.log(2 * np.pi)
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)
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all_probs = tf.reduce_sum(_gauss_pre, axis=1, keepdims=True)
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self.entropy = tf.reduce_sum(
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self.log_sigma_sq + 0.5 * np.log(2.0 * np.pi * np.e), axis=-1
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)
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# Squash probabilities
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# Keep deterministic around in case we want to use it.
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self.deterministic_output = tf.tanh(mu)
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# Note that this is just for symmetry with PPO.
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self.output_pre = tf.tanh(policy_)
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# Squash correction
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all_probs -= tf.reduce_sum(
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tf.log(1 - self.output_pre ** 2 + EPSILON), axis=1, keepdims=True
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)
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self.all_log_probs = all_probs
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self.selected_actions = tf.stop_gradient(self.output_pre)
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self.action_probs = all_probs
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# Extract output for Barracuda
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self.output = tf.identity(self.output_pre, name="action")
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# Get all policy vars
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self.policy_vars = self.get_vars(scope)
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def create_dc_actor(self, hidden_policy, scope):
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"""
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Creates Discrete control actor for SAC.
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:param hidden_policy: Output of feature extractor (i.e. the input for vector obs, output of CNN for visual obs).
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:param num_layers: TF scope to assign whatever is created in this block.
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"""
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scope = self.join_scopes(scope, "policy")
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# Create inputs outside of the scope
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self.action_masks = tf.placeholder(
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shape=[None, sum(self.act_size)], dtype=tf.float32, name="action_masks"
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)
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if self.use_recurrent:
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self.prev_action = tf.placeholder(
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shape=[None, len(self.act_size)], dtype=tf.int32, name="prev_action"
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)
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with tf.variable_scope(scope):
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hidden_policy = self.create_vector_observation_encoder(
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hidden_policy,
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self.h_size,
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self.activ_fn,
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self.num_layers,
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"encoder",
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False,
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)
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if self.use_recurrent:
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prev_action_oh = tf.concat(
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[
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tf.one_hot(self.prev_action[:, i], self.act_size[i])
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for i in range(len(self.act_size))
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],
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axis=1,
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)
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hidden_policy = tf.concat([hidden_policy, prev_action_oh], axis=1)
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hidden_policy, memory_out = self.create_recurrent_encoder(
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hidden_policy,
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self.policy_memory_in,
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self.sequence_length,
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name="lstm_policy",
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)
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self.policy_memory_out = memory_out
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with tf.variable_scope(scope):
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policy_branches = []
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for size in self.act_size:
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policy_branches.append(
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tf.layers.dense(
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hidden_policy,
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size,
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activation=None,
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use_bias=False,
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kernel_initializer=tf_variance_scaling(0.01),
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)
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)
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all_logits = tf.concat(
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[branch for branch in policy_branches], axis=1, name="action_probs"
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)
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output, normalized_probs, normalized_logprobs = self.create_discrete_action_masking_layer(
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all_logits, self.action_masks, self.act_size
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)
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self.action_probs = normalized_probs
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# Really, this is entropy, but it has an analogous purpose to the log probs in the
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# continuous case.
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self.all_log_probs = self.action_probs * normalized_logprobs
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self.output = output
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# Create action input (discrete)
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self.action_holder = tf.placeholder(
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shape=[None, len(policy_branches)], dtype=tf.int32, name="action_holder"
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)
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self.output_oh = tf.concat(
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[
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tf.one_hot(self.action_holder[:, i], self.act_size[i])
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for i in range(len(self.act_size))
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],
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axis=1,
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)
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# For Curiosity and GAIL to retrieve selected actions. We don't
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# need the mask at this point because it's already stored in the buffer.
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self.selected_actions = tf.stop_gradient(self.output_oh)
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self.external_action_in = tf.concat(
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[
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tf.one_hot(self.action_holder[:, i], self.act_size[i])
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for i in range(len(self.act_size))
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],
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axis=1,
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)
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# This is total entropy over all branches
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self.entropy = -1 * tf.reduce_sum(self.all_log_probs, axis=1)
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# Extract the normalized logprobs for Barracuda
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self.normalized_logprobs = tf.identity(normalized_logprobs, name="action")
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# We kept the LSTMs at a different scope than the rest, so add them if they exist.
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self.policy_vars = self.get_vars(scope)
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if self.use_recurrent:
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self.policy_vars += self.get_vars("lstm")
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def create_sac_value_head(
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self, stream_names, hidden_input, num_layers, h_size, scope
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):
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"""
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Creates one value estimator head for each reward signal in stream_names.
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Also creates the node corresponding to the mean of all the value heads in self.value.
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self.value_head is a dictionary of stream name to node containing the value estimator head for that signal.
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:param stream_names: The list of reward signal names
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:param hidden_input: The last layer of the Critic. The heads will consist of one dense hidden layer on top
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of the hidden input.
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:param num_layers: Number of hidden layers for value network
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:param h_size: size of hidden layers for value network
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:param scope: TF scope for value network.
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"""
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self.value_heads = {}
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with tf.variable_scope(scope):
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value_hidden = self.create_vector_observation_encoder(
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hidden_input, h_size, self.activ_fn, num_layers, "encoder", False
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)
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if self.use_recurrent:
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value_hidden, memory_out = self.create_recurrent_encoder(
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value_hidden,
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self.value_memory_in,
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self.sequence_length,
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name="lstm_value",
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)
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self.value_memory_out = memory_out
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self.create_value_heads(stream_names, value_hidden)
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def create_q_heads(
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self,
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stream_names,
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hidden_input,
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num_layers,
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h_size,
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scope,
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reuse=False,
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num_outputs=1,
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):
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"""
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Creates two q heads for each reward signal in stream_names.
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Also creates the node corresponding to the mean of all the value heads in self.value.
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self.value_head is a dictionary of stream name to node containing the value estimator head for that signal.
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:param stream_names: The list of reward signal names
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:param hidden_input: The last layer of the Critic. The heads will consist of one dense hidden layer on top
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of the hidden input.
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:param num_layers: Number of hidden layers for Q network
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:param h_size: size of hidden layers for Q network
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:param scope: TF scope for Q network.
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:param reuse: Whether or not to reuse variables. Useful for creating Q of policy.
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:param num_outputs: Number of outputs of each Q function. If discrete, equal to number of actions.
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"""
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with tf.variable_scope(self.join_scopes(scope, "q1_encoding"), reuse=reuse):
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q1_hidden = self.create_vector_observation_encoder(
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hidden_input, h_size, self.activ_fn, num_layers, "q1_encoder", reuse
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)
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if self.use_recurrent:
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q1_hidden, memory_out = self.create_recurrent_encoder(
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q1_hidden, self.q1_memory_in, self.sequence_length, name="lstm_q1"
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)
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self.q1_memory_out = memory_out
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q1_heads = {}
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for name in stream_names:
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_q1 = tf.layers.dense(q1_hidden, num_outputs, name="{}_q1".format(name))
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q1_heads[name] = _q1
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q1 = tf.reduce_mean(list(q1_heads.values()), axis=0)
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with tf.variable_scope(self.join_scopes(scope, "q2_encoding"), reuse=reuse):
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q2_hidden = self.create_vector_observation_encoder(
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hidden_input, h_size, self.activ_fn, num_layers, "q2_encoder", reuse
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)
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if self.use_recurrent:
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q2_hidden, memory_out = self.create_recurrent_encoder(
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q2_hidden, self.q2_memory_in, self.sequence_length, name="lstm_q2"
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)
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self.q2_memory_out = memory_out
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q2_heads = {}
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for name in stream_names:
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_q2 = tf.layers.dense(q2_hidden, num_outputs, name="{}_q2".format(name))
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q2_heads[name] = _q2
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q2 = tf.reduce_mean(list(q2_heads.values()), axis=0)
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return q1_heads, q2_heads, q1, q2
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def copy_normalization(self, mean, variance, steps):
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"""
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Copies the mean, variance, and steps into the normalizers of the
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input of this SACNetwork. Used to copy the normalizer from the policy network
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to the target network.
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param mean: Tensor containing the mean.
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param variance: Tensor containing the variance
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param steps: Tensor containing the number of steps.
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"""
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update_mean = tf.assign(self.running_mean, mean)
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update_variance = tf.assign(self.running_variance, variance)
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update_norm_step = tf.assign(self.normalization_steps, steps)
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return tf.group([update_mean, update_variance, update_norm_step])
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|
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class SACTargetNetwork(SACNetwork):
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"""
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Instantiation for the SAC target network. Only contains a single
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value estimator and is updated from the Policy Network.
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"""
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|
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def __init__(
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self,
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brain,
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m_size=None,
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h_size=128,
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normalize=False,
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use_recurrent=False,
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num_layers=2,
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stream_names=None,
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seed=0,
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vis_encode_type=EncoderType.SIMPLE,
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):
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super().__init__(
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brain,
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m_size,
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h_size,
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normalize,
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use_recurrent,
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num_layers,
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stream_names,
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seed,
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vis_encode_type,
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)
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if self.use_recurrent:
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self.memory_in = tf.placeholder(
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shape=[None, self.m_size], dtype=tf.float32, name="recurrent_in"
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)
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self.value_memory_in = self.memory_in
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with tf.variable_scope(TARGET_SCOPE):
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hidden_streams = self.create_observation_streams(
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1,
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self.h_size,
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0,
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vis_encode_type=vis_encode_type,
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stream_scopes=["critic/value/"],
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)
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if brain.vector_action_space_type == "continuous":
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self.create_cc_critic(hidden_streams[0], TARGET_SCOPE, create_qs=False)
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else:
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self.create_dc_critic(hidden_streams[0], TARGET_SCOPE, create_qs=False)
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if self.use_recurrent:
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self.memory_out = tf.concat(
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self.value_memory_out, axis=1
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) # Needed for Barracuda to work
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|
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class SACPolicyNetwork(SACNetwork):
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"""
|
|
Instantiation for SAC policy network. Contains a dual Q estimator,
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a value estimator, and the actual policy network.
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"""
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|
|
def __init__(
|
|
self,
|
|
brain,
|
|
m_size=None,
|
|
h_size=128,
|
|
normalize=False,
|
|
use_recurrent=False,
|
|
num_layers=2,
|
|
stream_names=None,
|
|
seed=0,
|
|
vis_encode_type=EncoderType.SIMPLE,
|
|
):
|
|
super().__init__(
|
|
brain,
|
|
m_size,
|
|
h_size,
|
|
normalize,
|
|
use_recurrent,
|
|
num_layers,
|
|
stream_names,
|
|
seed,
|
|
vis_encode_type,
|
|
)
|
|
self.share_ac_cnn = False
|
|
if self.use_recurrent:
|
|
self.create_memory_ins(self.m_size)
|
|
|
|
hidden_policy, hidden_critic = self.create_observation_ins(
|
|
vis_encode_type, self.share_ac_cnn
|
|
)
|
|
|
|
if brain.vector_action_space_type == "continuous":
|
|
self.create_cc_actor(hidden_policy, POLICY_SCOPE)
|
|
self.create_cc_critic(hidden_critic, POLICY_SCOPE)
|
|
|
|
else:
|
|
self.create_dc_actor(hidden_policy, POLICY_SCOPE)
|
|
self.create_dc_critic(hidden_critic, POLICY_SCOPE)
|
|
|
|
if self.share_ac_cnn:
|
|
# Make sure that the policy also contains the CNN
|
|
self.policy_vars += self.get_vars(
|
|
self.join_scopes(POLICY_SCOPE, "critic/value/main_graph_0_encoder0")
|
|
)
|
|
if self.use_recurrent:
|
|
mem_outs = [
|
|
self.value_memory_out,
|
|
self.q1_memory_out,
|
|
self.q2_memory_out,
|
|
self.policy_memory_out,
|
|
]
|
|
self.memory_out = tf.concat(mem_outs, axis=1)
|
|
|
|
def create_memory_ins(self, m_size):
|
|
"""
|
|
Creates the memory input placeholders for LSTM.
|
|
:param m_size: the total size of the memory.
|
|
"""
|
|
# Create the Policy input separate from the rest
|
|
# This is so in inference we only have to run the Policy network.
|
|
# Barracuda will grab the recurrent_in and recurrent_out named tensors.
|
|
self.inference_memory_in = tf.placeholder(
|
|
shape=[None, m_size // 4], dtype=tf.float32, name="recurrent_in"
|
|
)
|
|
# We assume m_size is divisible by 4
|
|
# Create the non-Policy inputs
|
|
three_fourths_m_size = m_size * 3 // 4
|
|
self.other_memory_in = tf.placeholder(
|
|
shape=[None, three_fourths_m_size],
|
|
dtype=tf.float32,
|
|
name="other_recurrent_in",
|
|
)
|
|
|
|
# Concat and use this as the "placeholder"
|
|
# for training
|
|
self.memory_in = tf.concat(
|
|
[self.other_memory_in, self.inference_memory_in], axis=1
|
|
)
|
|
|
|
# Re-break-up for each network
|
|
num_mems = 4
|
|
mem_ins = []
|
|
for i in range(num_mems):
|
|
_start = m_size // num_mems * i
|
|
_end = m_size // num_mems * (i + 1)
|
|
mem_ins.append(self.memory_in[:, _start:_end])
|
|
self.value_memory_in = mem_ins[0]
|
|
self.q1_memory_in = mem_ins[1]
|
|
self.q2_memory_in = mem_ins[2]
|
|
self.policy_memory_in = mem_ins[3]
|
|
|
|
def create_observation_ins(self, vis_encode_type, share_ac_cnn):
|
|
"""
|
|
Creates the observation inputs, and a CNN if needed,
|
|
:param vis_encode_type: Type of CNN encoder.
|
|
:param share_ac_cnn: Whether or not to share the actor and critic CNNs.
|
|
:return A tuple of (hidden_policy, hidden_critic). We don't save it to self since they're used
|
|
once and thrown away.
|
|
"""
|
|
if share_ac_cnn:
|
|
with tf.variable_scope(POLICY_SCOPE):
|
|
hidden_streams = self.create_observation_streams(
|
|
1,
|
|
self.h_size,
|
|
0,
|
|
vis_encode_type=vis_encode_type,
|
|
stream_scopes=["critic/value/"],
|
|
)
|
|
hidden_policy = hidden_streams[0]
|
|
hidden_critic = hidden_streams[0]
|
|
else:
|
|
with tf.variable_scope(POLICY_SCOPE):
|
|
hidden_streams = self.create_observation_streams(
|
|
2,
|
|
self.h_size,
|
|
0,
|
|
vis_encode_type=vis_encode_type,
|
|
stream_scopes=["policy/", "critic/value/"],
|
|
)
|
|
hidden_policy = hidden_streams[0]
|
|
hidden_critic = hidden_streams[1]
|
|
return hidden_policy, hidden_critic
|
|
|
|
|
|
class SACModel(LearningModel):
|
|
def __init__(
|
|
self,
|
|
brain,
|
|
lr=1e-4,
|
|
lr_schedule=LearningRateSchedule.CONSTANT,
|
|
h_size=128,
|
|
init_entcoef=0.1,
|
|
max_step=5e6,
|
|
normalize=False,
|
|
use_recurrent=False,
|
|
num_layers=2,
|
|
m_size=None,
|
|
seed=0,
|
|
stream_names=None,
|
|
tau=0.005,
|
|
gammas=None,
|
|
vis_encode_type=EncoderType.SIMPLE,
|
|
):
|
|
"""
|
|
Takes a Unity environment and model-specific hyper-parameters and returns the
|
|
appropriate PPO agent model for the environment.
|
|
:param brain: BrainInfo used to generate specific network graph.
|
|
:param lr: Learning rate.
|
|
:param lr_schedule: Learning rate decay schedule.
|
|
:param h_size: Size of hidden layers
|
|
:param init_entcoef: Initial value for entropy coefficient. Set lower to learn faster,
|
|
set higher to explore more.
|
|
:return: a sub-class of PPOAgent tailored to the environment.
|
|
:param max_step: Total number of training steps.
|
|
:param normalize: Whether to normalize vector observation input.
|
|
:param use_recurrent: Whether to use an LSTM layer in the network.
|
|
:param num_layers: Number of hidden layers between encoded input and policy & value layers
|
|
:param tau: Strength of soft-Q update.
|
|
:param m_size: Size of brain memory.
|
|
"""
|
|
self.tau = tau
|
|
self.gammas = gammas
|
|
self.brain = brain
|
|
self.init_entcoef = init_entcoef
|
|
if stream_names is None:
|
|
stream_names = []
|
|
# Use to reduce "survivor bonus" when using Curiosity or GAIL.
|
|
self.use_dones_in_backup = {name: tf.Variable(1.0) for name in stream_names}
|
|
self.disable_use_dones = {
|
|
name: self.use_dones_in_backup[name].assign(0.0) for name in stream_names
|
|
}
|
|
LearningModel.__init__(
|
|
self, m_size, normalize, use_recurrent, brain, seed, stream_names
|
|
)
|
|
if num_layers < 1:
|
|
num_layers = 1
|
|
|
|
self.policy_network = SACPolicyNetwork(
|
|
brain=brain,
|
|
m_size=m_size,
|
|
h_size=h_size,
|
|
normalize=normalize,
|
|
use_recurrent=use_recurrent,
|
|
num_layers=num_layers,
|
|
seed=seed,
|
|
stream_names=stream_names,
|
|
vis_encode_type=vis_encode_type,
|
|
)
|
|
self.target_network = SACTargetNetwork(
|
|
brain=brain,
|
|
m_size=m_size // 4 if m_size else None,
|
|
h_size=h_size,
|
|
normalize=normalize,
|
|
use_recurrent=use_recurrent,
|
|
num_layers=num_layers,
|
|
seed=seed,
|
|
stream_names=stream_names,
|
|
vis_encode_type=vis_encode_type,
|
|
)
|
|
self.create_inputs_and_outputs()
|
|
self.learning_rate = self.create_learning_rate(
|
|
lr_schedule, lr, self.global_step, max_step
|
|
)
|
|
self.create_losses(
|
|
self.policy_network.q1_heads,
|
|
self.policy_network.q2_heads,
|
|
lr,
|
|
max_step,
|
|
stream_names,
|
|
discrete=self.brain.vector_action_space_type == "discrete",
|
|
)
|
|
|
|
self.selected_actions = (
|
|
self.policy_network.selected_actions
|
|
) # For GAIL and other reward signals
|
|
if normalize:
|
|
target_update_norm = self.target_network.copy_normalization(
|
|
self.policy_network.running_mean,
|
|
self.policy_network.running_variance,
|
|
self.policy_network.normalization_steps,
|
|
)
|
|
self.update_normalization = tf.group(
|
|
[self.policy_network.update_normalization, target_update_norm]
|
|
)
|
|
self.running_mean = self.policy_network.running_mean
|
|
self.running_variance = self.policy_network.running_variance
|
|
self.normalization_steps = self.policy_network.normalization_steps
|
|
|
|
def create_inputs_and_outputs(self):
|
|
"""
|
|
Assign the higher-level SACModel's inputs and outputs to those of its policy or
|
|
target network.
|
|
"""
|
|
self.vector_in = self.policy_network.vector_in
|
|
self.visual_in = self.policy_network.visual_in
|
|
self.next_vector_in = self.target_network.vector_in
|
|
self.next_visual_in = self.target_network.visual_in
|
|
self.action_holder = self.policy_network.action_holder
|
|
self.sequence_length = self.policy_network.sequence_length
|
|
self.next_sequence_length = self.target_network.sequence_length
|
|
if self.brain.vector_action_space_type == "discrete":
|
|
self.action_masks = self.policy_network.action_masks
|
|
else:
|
|
self.output_pre = self.policy_network.output_pre
|
|
|
|
self.output = self.policy_network.output
|
|
# Don't use value estimate during inference. TODO: Check why PPO uses value_estimate in inference.
|
|
self.value = tf.identity(
|
|
self.policy_network.value, name="value_estimate_unused"
|
|
)
|
|
self.value_heads = self.policy_network.value_heads
|
|
self.all_log_probs = self.policy_network.all_log_probs
|
|
self.dones_holder = tf.placeholder(
|
|
shape=[None], dtype=tf.float32, name="dones_holder"
|
|
)
|
|
# This is just a dummy to get pretraining to work. PPO has this but SAC doesn't.
|
|
# TODO: Proper input and output specs for models
|
|
self.epsilon = tf.placeholder(
|
|
shape=[None, self.act_size[0]], dtype=tf.float32, name="epsilon"
|
|
)
|
|
if self.use_recurrent:
|
|
self.memory_in = self.policy_network.memory_in
|
|
self.memory_out = self.policy_network.memory_out
|
|
|
|
# For Barracuda
|
|
self.inference_memory_out = tf.identity(
|
|
self.policy_network.policy_memory_out, name="recurrent_out"
|
|
)
|
|
|
|
if self.brain.vector_action_space_type == "discrete":
|
|
self.prev_action = self.policy_network.prev_action
|
|
self.next_memory_in = self.target_network.memory_in
|
|
|
|
def create_losses(
|
|
self, q1_streams, q2_streams, lr, max_step, stream_names, discrete=False
|
|
):
|
|
"""
|
|
Creates training-specific Tensorflow ops for SAC models.
|
|
:param q1_streams: Q1 streams from policy network
|
|
:param q1_streams: Q2 streams from policy network
|
|
:param lr: Learning rate
|
|
:param max_step: Total number of training steps.
|
|
:param stream_names: List of reward stream names.
|
|
:param discrete: Whether or not to use discrete action losses.
|
|
"""
|
|
|
|
if discrete:
|
|
self.target_entropy = [
|
|
DISCRETE_TARGET_ENTROPY_SCALE * np.log(i).astype(np.float32)
|
|
for i in self.act_size
|
|
]
|
|
else:
|
|
self.target_entropy = (
|
|
-1
|
|
* CONTINUOUS_TARGET_ENTROPY_SCALE
|
|
* np.prod(self.act_size[0]).astype(np.float32)
|
|
)
|
|
|
|
self.rewards_holders = {}
|
|
self.min_policy_qs = {}
|
|
|
|
for i, name in enumerate(stream_names):
|
|
if discrete:
|
|
_branched_mpq1 = self.apply_as_branches(
|
|
self.policy_network.q1_pheads[name]
|
|
* self.policy_network.action_probs
|
|
)
|
|
branched_mpq1 = tf.stack(
|
|
[
|
|
tf.reduce_sum(_br, axis=1, keep_dims=True)
|
|
for _br in _branched_mpq1
|
|
]
|
|
)
|
|
_q1_p_mean = tf.reduce_mean(branched_mpq1, axis=0)
|
|
|
|
_branched_mpq2 = self.apply_as_branches(
|
|
self.policy_network.q2_pheads[name]
|
|
* self.policy_network.action_probs
|
|
)
|
|
branched_mpq2 = tf.stack(
|
|
[
|
|
tf.reduce_sum(_br, axis=1, keep_dims=True)
|
|
for _br in _branched_mpq2
|
|
]
|
|
)
|
|
_q2_p_mean = tf.reduce_mean(branched_mpq2, axis=0)
|
|
|
|
self.min_policy_qs[name] = tf.minimum(_q1_p_mean, _q2_p_mean)
|
|
else:
|
|
self.min_policy_qs[name] = tf.minimum(
|
|
self.policy_network.q1_pheads[name],
|
|
self.policy_network.q2_pheads[name],
|
|
)
|
|
|
|
rewards_holder = tf.placeholder(
|
|
shape=[None], dtype=tf.float32, name="{}_rewards".format(name)
|
|
)
|
|
rewards_holder = tf.placeholder(
|
|
shape=[None], dtype=tf.float32, name="{}_rewards".format(name)
|
|
)
|
|
self.rewards_holders[name] = rewards_holder
|
|
|
|
q1_losses = []
|
|
q2_losses = []
|
|
# Multiple q losses per stream
|
|
expanded_dones = tf.expand_dims(self.dones_holder, axis=-1)
|
|
for i, name in enumerate(stream_names):
|
|
_expanded_rewards = tf.expand_dims(self.rewards_holders[name], axis=-1)
|
|
|
|
q_backup = tf.stop_gradient(
|
|
_expanded_rewards
|
|
+ (1.0 - self.use_dones_in_backup[name] * expanded_dones)
|
|
* self.gammas[i]
|
|
* self.target_network.value_heads[name]
|
|
)
|
|
|
|
if discrete:
|
|
# We need to break up the Q functions by branch, and update them individually.
|
|
branched_q1_stream = self.apply_as_branches(
|
|
self.policy_network.external_action_in * q1_streams[name]
|
|
)
|
|
branched_q2_stream = self.apply_as_branches(
|
|
self.policy_network.external_action_in * q2_streams[name]
|
|
)
|
|
|
|
# Reduce each branch into scalar
|
|
branched_q1_stream = [
|
|
tf.reduce_sum(_branch, axis=1, keep_dims=True)
|
|
for _branch in branched_q1_stream
|
|
]
|
|
branched_q2_stream = [
|
|
tf.reduce_sum(_branch, axis=1, keep_dims=True)
|
|
for _branch in branched_q2_stream
|
|
]
|
|
|
|
q1_stream = tf.reduce_mean(branched_q1_stream, axis=0)
|
|
q2_stream = tf.reduce_mean(branched_q2_stream, axis=0)
|
|
|
|
else:
|
|
q1_stream = q1_streams[name]
|
|
q2_stream = q2_streams[name]
|
|
|
|
_q1_loss = 0.5 * tf.reduce_mean(
|
|
tf.to_float(self.mask) * tf.squared_difference(q_backup, q1_stream)
|
|
)
|
|
|
|
_q2_loss = 0.5 * tf.reduce_mean(
|
|
tf.to_float(self.mask) * tf.squared_difference(q_backup, q2_stream)
|
|
)
|
|
|
|
q1_losses.append(_q1_loss)
|
|
q2_losses.append(_q2_loss)
|
|
|
|
self.q1_loss = tf.reduce_mean(q1_losses)
|
|
self.q2_loss = tf.reduce_mean(q2_losses)
|
|
|
|
# Learn entropy coefficient
|
|
if discrete:
|
|
# Create a log_ent_coef for each branch
|
|
self.log_ent_coef = tf.get_variable(
|
|
"log_ent_coef",
|
|
dtype=tf.float32,
|
|
initializer=np.log([self.init_entcoef] * len(self.act_size)).astype(
|
|
np.float32
|
|
),
|
|
trainable=True,
|
|
)
|
|
else:
|
|
self.log_ent_coef = tf.get_variable(
|
|
"log_ent_coef",
|
|
dtype=tf.float32,
|
|
initializer=np.log(self.init_entcoef).astype(np.float32),
|
|
trainable=True,
|
|
)
|
|
|
|
self.ent_coef = tf.exp(self.log_ent_coef)
|
|
if discrete:
|
|
# We also have to do a different entropy and target_entropy per branch.
|
|
branched_log_probs = self.apply_as_branches(
|
|
self.policy_network.all_log_probs
|
|
)
|
|
branched_ent_sums = tf.stack(
|
|
[
|
|
tf.reduce_sum(_lp, axis=1, keep_dims=True) + _te
|
|
for _lp, _te in zip(branched_log_probs, self.target_entropy)
|
|
],
|
|
axis=1,
|
|
)
|
|
self.entropy_loss = -tf.reduce_mean(
|
|
tf.to_float(self.mask)
|
|
* tf.reduce_mean(
|
|
self.log_ent_coef
|
|
* tf.squeeze(tf.stop_gradient(branched_ent_sums), axis=2),
|
|
axis=1,
|
|
)
|
|
)
|
|
|
|
# Same with policy loss, we have to do the loss per branch and average them,
|
|
# so that larger branches don't get more weight.
|
|
# The equivalent KL divergence from Eq 10 of Haarnoja et al. is also pi*log(pi) - Q
|
|
branched_q_term = self.apply_as_branches(
|
|
self.policy_network.action_probs * self.policy_network.q1_p
|
|
)
|
|
|
|
branched_policy_loss = tf.stack(
|
|
[
|
|
tf.reduce_sum(self.ent_coef[i] * _lp - _qt, axis=1, keep_dims=True)
|
|
for i, (_lp, _qt) in enumerate(
|
|
zip(branched_log_probs, branched_q_term)
|
|
)
|
|
]
|
|
)
|
|
self.policy_loss = tf.reduce_mean(
|
|
tf.to_float(self.mask) * tf.squeeze(branched_policy_loss)
|
|
)
|
|
|
|
# Do vbackup entropy bonus per branch as well.
|
|
branched_ent_bonus = tf.stack(
|
|
[
|
|
tf.reduce_sum(self.ent_coef[i] * _lp, axis=1, keep_dims=True)
|
|
for i, _lp in enumerate(branched_log_probs)
|
|
]
|
|
)
|
|
value_losses = []
|
|
for name in stream_names:
|
|
v_backup = tf.stop_gradient(
|
|
self.min_policy_qs[name]
|
|
- tf.reduce_mean(branched_ent_bonus, axis=0)
|
|
)
|
|
value_losses.append(
|
|
0.5
|
|
* tf.reduce_mean(
|
|
tf.to_float(self.mask)
|
|
* tf.squared_difference(
|
|
self.policy_network.value_heads[name], v_backup
|
|
)
|
|
)
|
|
)
|
|
|
|
else:
|
|
self.entropy_loss = -tf.reduce_mean(
|
|
self.log_ent_coef
|
|
* tf.to_float(self.mask)
|
|
* tf.stop_gradient(
|
|
tf.reduce_sum(
|
|
self.policy_network.all_log_probs + self.target_entropy,
|
|
axis=1,
|
|
keep_dims=True,
|
|
)
|
|
)
|
|
)
|
|
batch_policy_loss = tf.reduce_mean(
|
|
self.ent_coef * self.policy_network.all_log_probs
|
|
- self.policy_network.q1_p,
|
|
axis=1,
|
|
)
|
|
self.policy_loss = tf.reduce_mean(
|
|
tf.to_float(self.mask) * batch_policy_loss
|
|
)
|
|
|
|
value_losses = []
|
|
for name in stream_names:
|
|
v_backup = tf.stop_gradient(
|
|
self.min_policy_qs[name]
|
|
- tf.reduce_sum(
|
|
self.ent_coef * self.policy_network.all_log_probs, axis=1
|
|
)
|
|
)
|
|
value_losses.append(
|
|
0.5
|
|
* tf.reduce_mean(
|
|
tf.to_float(self.mask)
|
|
* tf.squared_difference(
|
|
self.policy_network.value_heads[name], v_backup
|
|
)
|
|
)
|
|
)
|
|
self.value_loss = tf.reduce_mean(value_losses)
|
|
|
|
self.total_value_loss = self.q1_loss + self.q2_loss + self.value_loss
|
|
|
|
self.entropy = self.policy_network.entropy
|
|
|
|
def apply_as_branches(self, concat_logits):
|
|
"""
|
|
Takes in a concatenated set of logits and breaks it up into a list of non-concatenated logits, one per
|
|
action branch
|
|
"""
|
|
action_idx = [0] + list(np.cumsum(self.act_size))
|
|
branches_logits = [
|
|
concat_logits[:, action_idx[i] : action_idx[i + 1]]
|
|
for i in range(len(self.act_size))
|
|
]
|
|
return branches_logits
|
|
|
|
def create_sac_optimizers(self):
|
|
"""
|
|
Creates the Adam optimizers and update ops for SAC, including
|
|
the policy, value, and entropy updates, as well as the target network update.
|
|
"""
|
|
policy_optimizer = tf.train.AdamOptimizer(learning_rate=self.learning_rate)
|
|
entropy_optimizer = tf.train.AdamOptimizer(learning_rate=self.learning_rate)
|
|
value_optimizer = tf.train.AdamOptimizer(learning_rate=self.learning_rate)
|
|
|
|
self.target_update_op = [
|
|
tf.assign(target, (1 - self.tau) * target + self.tau * source)
|
|
for target, source in zip(
|
|
self.target_network.value_vars, self.policy_network.value_vars
|
|
)
|
|
]
|
|
LOGGER.debug("value_vars")
|
|
self.print_all_vars(self.policy_network.value_vars)
|
|
LOGGER.debug("targvalue_vars")
|
|
self.print_all_vars(self.target_network.value_vars)
|
|
LOGGER.debug("critic_vars")
|
|
self.print_all_vars(self.policy_network.critic_vars)
|
|
LOGGER.debug("q_vars")
|
|
self.print_all_vars(self.policy_network.q_vars)
|
|
LOGGER.debug("policy_vars")
|
|
self.print_all_vars(self.policy_network.policy_vars)
|
|
|
|
self.target_init_op = [
|
|
tf.assign(target, source)
|
|
for target, source in zip(
|
|
self.target_network.value_vars, self.policy_network.value_vars
|
|
)
|
|
]
|
|
|
|
self.update_batch_policy = policy_optimizer.minimize(
|
|
self.policy_loss, var_list=self.policy_network.policy_vars
|
|
)
|
|
|
|
# Make sure policy is updated first, then value, then entropy.
|
|
with tf.control_dependencies([self.update_batch_policy]):
|
|
self.update_batch_value = value_optimizer.minimize(
|
|
self.total_value_loss, var_list=self.policy_network.critic_vars
|
|
)
|
|
# Add entropy coefficient optimization operation
|
|
with tf.control_dependencies([self.update_batch_value]):
|
|
self.update_batch_entropy = entropy_optimizer.minimize(
|
|
self.entropy_loss, var_list=self.log_ent_coef
|
|
)
|
|
|
|
def print_all_vars(self, variables):
|
|
for _var in variables:
|
|
LOGGER.debug(_var)
|