Python mse Examples

Programming Language: Python

Namespace/Package Name: neorl.rl.baselines.shared.tf_util

Method/Function: mse

Examples at hotexamples.com: 2

Python mse - 2 examples found. These are the top rated real world Python examples of neorl.rl.baselines.shared.tf_util.mse extracted from open source projects. You can rate examples to help us improve the quality of examples.

Example #1

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    def setup_model(self):
        with SetVerbosity(self.verbose):

            assert issubclass(self.policy, ActorCriticPolicy), "Error: the input policy for the A2C model must be an " \
                                                                "instance of common.policies.ActorCriticPolicy."

            self.graph = tf.Graph()
            with self.graph.as_default():
                self.set_random_seed(self.seed)
                self.sess = tf_util.make_session(num_cpu=self.n_cpu_tf_sess,
                                                 graph=self.graph)

                self.n_batch = self.n_envs * self.n_steps

                n_batch_step = None
                n_batch_train = None
                if issubclass(self.policy, RecurrentActorCriticPolicy):
                    n_batch_step = self.n_envs
                    n_batch_train = self.n_envs * self.n_steps

                step_model = self.policy(self.sess,
                                         self.observation_space,
                                         self.action_space,
                                         self.n_envs,
                                         1,
                                         n_batch_step,
                                         reuse=False,
                                         **self.policy_kwargs)

                with tf.variable_scope(
                        "train_model",
                        reuse=True,
                        custom_getter=tf_util.outer_scope_getter(
                            "train_model")):
                    train_model = self.policy(self.sess,
                                              self.observation_space,
                                              self.action_space,
                                              self.n_envs,
                                              self.n_steps,
                                              n_batch_train,
                                              reuse=True,
                                              **self.policy_kwargs)

                with tf.variable_scope("loss", reuse=False):
                    self.actions_ph = train_model.pdtype.sample_placeholder(
                        [None], name="action_ph")
                    self.advs_ph = tf.placeholder(tf.float32, [None],
                                                  name="advs_ph")
                    self.rewards_ph = tf.placeholder(tf.float32, [None],
                                                     name="rewards_ph")
                    self.learning_rate_ph = tf.placeholder(
                        tf.float32, [], name="learning_rate_ph")

                    neglogpac = train_model.proba_distribution.neglogp(
                        self.actions_ph)
                    self.entropy = tf.reduce_mean(
                        train_model.proba_distribution.entropy())
                    self.pg_loss = tf.reduce_mean(self.advs_ph * neglogpac)
                    self.vf_loss = mse(tf.squeeze(train_model.value_flat),
                                       self.rewards_ph)
                    # https://arxiv.org/pdf/1708.04782.pdf#page=9, https://arxiv.org/pdf/1602.01783.pdf#page=4
                    # and https://github.com/dennybritz/reinforcement-learning/issues/34
                    # suggest to add an entropy component in order to improve exploration.
                    loss = self.pg_loss - self.entropy * self.ent_coef + self.vf_loss * self.vf_coef

                    tf.summary.scalar('entropy_loss', self.entropy)
                    tf.summary.scalar('policy_gradient_loss', self.pg_loss)
                    tf.summary.scalar('value_function_loss', self.vf_loss)
                    tf.summary.scalar('loss', loss)

                    self.params = tf_util.get_trainable_vars("model")
                    grads = tf.gradients(loss, self.params)
                    if self.max_grad_norm is not None:
                        grads, _ = tf.clip_by_global_norm(
                            grads, self.max_grad_norm)
                    grads = list(zip(grads, self.params))

                with tf.variable_scope("input_info", reuse=False):
                    tf.summary.scalar('discounted_rewards',
                                      tf.reduce_mean(self.rewards_ph))
                    tf.summary.scalar('learning_rate',
                                      tf.reduce_mean(self.learning_rate_ph))
                    tf.summary.scalar('advantage',
                                      tf.reduce_mean(self.advs_ph))
                    if self.full_tensorboard_log:
                        tf.summary.histogram('discounted_rewards',
                                             self.rewards_ph)
                        tf.summary.histogram('learning_rate',
                                             self.learning_rate_ph)
                        tf.summary.histogram('advantage', self.advs_ph)
                        if tf_util.is_image(self.observation_space):
                            tf.summary.image('observation', train_model.obs_ph)
                        else:
                            tf.summary.histogram('observation',
                                                 train_model.obs_ph)

                trainer = tf.train.RMSPropOptimizer(
                    learning_rate=self.learning_rate_ph,
                    decay=self.alpha,
                    epsilon=self.epsilon,
                    momentum=self.momentum)
                self.apply_backprop = trainer.apply_gradients(grads)

                self.train_model = train_model
                self.step_model = step_model
                self.step = step_model.step
                self.proba_step = step_model.proba_step
                self.value = step_model.value
                self.initial_state = step_model.initial_state
                tf.global_variables_initializer().run(session=self.sess)

                self.summary = tf.summary.merge_all()

Example #2

Show file

File: acktr.py Project: mradaideh/neorl

    def setup_model(self):
        with SetVerbosity(self.verbose):

            assert issubclass(self.policy, ActorCriticPolicy), "Error: the input policy for the ACKTR model must be " \
                                                               "an instance of common.policies.ActorCriticPolicy."

            # Enable continuous actions tricks (normalized advantage)
            self.continuous_actions = isinstance(self.action_space, Box)

            self.graph = tf.Graph()
            with self.graph.as_default():
                self.set_random_seed(self.seed)
                self.sess = tf_util.make_session(num_cpu=self.n_cpu_tf_sess,
                                                 graph=self.graph)

                n_batch_step = None
                n_batch_train = None
                if issubclass(self.policy, RecurrentActorCriticPolicy):
                    n_batch_step = self.n_envs
                    n_batch_train = self.n_envs * self.n_steps

                step_model = self.policy(self.sess,
                                         self.observation_space,
                                         self.action_space,
                                         self.n_envs,
                                         1,
                                         n_batch_step,
                                         reuse=False,
                                         **self.policy_kwargs)

                self.params = params = tf_util.get_trainable_vars("model")

                with tf.variable_scope(
                        "train_model",
                        reuse=True,
                        custom_getter=tf_util.outer_scope_getter(
                            "train_model")):
                    train_model = self.policy(self.sess,
                                              self.observation_space,
                                              self.action_space,
                                              self.n_envs,
                                              self.n_steps,
                                              n_batch_train,
                                              reuse=True,
                                              **self.policy_kwargs)

                with tf.variable_scope(
                        "loss",
                        reuse=False,
                        custom_getter=tf_util.outer_scope_getter("loss")):
                    self.advs_ph = advs_ph = tf.placeholder(tf.float32, [None])
                    self.rewards_ph = rewards_ph = tf.placeholder(
                        tf.float32, [None])
                    self.learning_rate_ph = learning_rate_ph = tf.placeholder(
                        tf.float32, [])
                    self.actions_ph = train_model.pdtype.sample_placeholder(
                        [None])

                    neg_log_prob = train_model.proba_distribution.neglogp(
                        self.actions_ph)

                    # training loss
                    pg_loss = tf.reduce_mean(advs_ph * neg_log_prob)
                    self.entropy = entropy = tf.reduce_mean(
                        train_model.proba_distribution.entropy())
                    self.pg_loss = pg_loss = pg_loss - self.ent_coef * entropy
                    self.vf_loss = vf_loss = mse(
                        tf.squeeze(train_model.value_fn), rewards_ph)
                    train_loss = pg_loss + self.vf_coef * vf_loss

                    # Fisher loss construction
                    self.pg_fisher = pg_fisher_loss = -tf.reduce_mean(
                        neg_log_prob)
                    sample_net = train_model.value_fn + tf.random_normal(
                        tf.shape(train_model.value_fn))
                    self.vf_fisher = vf_fisher_loss = -self.vf_fisher_coef * tf.reduce_mean(
                        tf.pow(
                            train_model.value_fn -
                            tf.stop_gradient(sample_net), 2))
                    self.joint_fisher = pg_fisher_loss + vf_fisher_loss

                    tf.summary.scalar('entropy_loss', self.entropy)
                    tf.summary.scalar('policy_gradient_loss', pg_loss)
                    tf.summary.scalar('policy_gradient_fisher_loss',
                                      pg_fisher_loss)
                    tf.summary.scalar('value_function_loss', self.vf_loss)
                    tf.summary.scalar('value_function_fisher_loss',
                                      vf_fisher_loss)
                    tf.summary.scalar('loss', train_loss)

                    self.grads_check = tf.gradients(train_loss, params)

                with tf.variable_scope("input_info", reuse=False):
                    tf.summary.scalar('discounted_rewards',
                                      tf.reduce_mean(self.rewards_ph))
                    tf.summary.scalar('learning_rate',
                                      tf.reduce_mean(self.learning_rate_ph))
                    tf.summary.scalar('advantage',
                                      tf.reduce_mean(self.advs_ph))

                    if self.full_tensorboard_log:
                        tf.summary.histogram('discounted_rewards',
                                             self.rewards_ph)
                        tf.summary.histogram('learning_rate',
                                             self.learning_rate_ph)
                        tf.summary.histogram('advantage', self.advs_ph)
                        if tf_util.is_image(self.observation_space):
                            tf.summary.image('observation', train_model.obs_ph)
                        else:
                            tf.summary.histogram('observation',
                                                 train_model.obs_ph)

                with tf.variable_scope(
                        "kfac",
                        reuse=False,
                        custom_getter=tf_util.outer_scope_getter("kfac")):
                    with tf.device('/gpu:0'):
                        self.optim = optim = kfac.KfacOptimizer(
                            learning_rate=learning_rate_ph,
                            clip_kl=self.kfac_clip,
                            momentum=0.9,
                            kfac_update=self.kfac_update,
                            epsilon=0.01,
                            stats_decay=0.99,
                            async_eigen_decomp=self.async_eigen_decomp,
                            cold_iter=10,
                            max_grad_norm=self.max_grad_norm,
                            verbose=self.verbose)

                        optim.compute_and_apply_stats(self.joint_fisher,
                                                      var_list=params)

                self.train_model = train_model
                self.step_model = step_model
                self.step = step_model.step
                self.proba_step = step_model.proba_step
                self.value = step_model.value
                self.initial_state = step_model.initial_state
                tf.global_variables_initializer().run(session=self.sess)

                self.summary = tf.summary.merge_all()