Exemplo n.º 1
0
    def construct_from_feed_dict(self, policy_pickle, env_pickle,
                                 baseline_pickle, dynamics_model_pickle,
                                 feed_dict):

        from meta_mb.samplers.sampler import Sampler
        from meta_mb.samplers.mb_sample_processor import ModelSampleProcessor

        env = pickle.loads(env_pickle)
        policy = pickle.loads(policy_pickle)
        baseline = pickle.loads(baseline_pickle)

        self.env = env
        self.env_sampler = Sampler(env=env,
                                   policy=policy,
                                   **feed_dict['env_sampler'])
        self.dynamics_sample_processor = ModelSampleProcessor(
            baseline=baseline, **feed_dict['dynamics_sample_processor'])
Exemplo n.º 2
0
def run_experiment(**kwargs):
    config = tf.ConfigProto()
    config.gpu_options.allow_growth = True
    config.gpu_options.per_process_gpu_memory_fraction = kwargs.get(
        'gpu_frac', 0.95)
    sess = tf.Session(config=config)

    with sess.as_default() as sess:
        exp_dir = os.getcwd() + '/data/' + EXP_NAME + '/' + kwargs.get(
            'exp_name', '')
        logger.configure(dir=exp_dir,
                         format_strs=['stdout', 'log', 'csv'],
                         snapshot_mode='last')
        json.dump(kwargs,
                  open(exp_dir + '/params.json', 'w'),
                  indent=2,
                  sort_keys=True,
                  cls=ClassEncoder)

        # Instantiate classes
        set_seed(kwargs['seed'])

        env = normalize(kwargs['env']())  # Wrappers?

        baseline = NNValueFun(
            'value-function',
            env,
            hidden_nonlinearity=kwargs['vfun_hidden_nonlinearity'],
            hidden_sizes=kwargs['vfun_hidden_sizes'],
            output_nonlinearity=kwargs['vfun_output_nonlinearity'],
            learning_rate=kwargs['vfun_learning_rate'],
            batch_size=kwargs['vfun_batch_size'],
            buffer_size=kwargs['vfun_buffer_size'],
            normalize_input=False,
        )

        policy = GaussianMLPPolicy(
            name="policy",
            obs_dim=np.prod(env.observation_space.shape),
            action_dim=np.prod(env.action_space.shape),
            hidden_sizes=kwargs['policy_hidden_sizes'],
            learn_std=kwargs['policy_learn_std'],
            output_nonlinearity=kwargs['policy_output_nonlinearity'],
        )

        dynamics_model = MLPDynamicsModel(
            'prob-dynamics',
            env=env,
            hidden_nonlinearity=kwargs['dyanmics_hidden_nonlinearity'],
            hidden_sizes=kwargs['dynamics_hidden_sizes'],
            output_nonlinearity=kwargs['dyanmics_output_nonlinearity'],
            learning_rate=kwargs['dynamics_learning_rate'],
            batch_size=kwargs['dynamics_batch_size'],
            buffer_size=kwargs['dynamics_buffer_size'],
            normalize_input=False,
        )

        assert kwargs['num_rollouts'] % kwargs['n_parallel'] == 0

        sampler = Sampler(
            env=env,
            policy=policy,
            num_rollouts=kwargs['num_rollouts'],
            max_path_length=kwargs['max_path_length'],
            n_parallel=kwargs['n_parallel'],
        )

        sample_processor = ModelSampleProcessor(
            baseline=baseline,
            discount=kwargs['discount'],
            gae_lambda=kwargs['gae_lambda'],
            normalize_adv=kwargs['normalize_adv'],
            positive_adv=kwargs['positive_adv'],
        )

        algo = SVG1(
            policy=policy,
            dynamics_model=dynamics_model,
            value_function=baseline,
            tf_reward=env.tf_reward,
            learning_rate=kwargs['svg_learning_rate'],
            num_grad_steps=kwargs['num_rollouts'] *
            kwargs['max_path_length'] // kwargs['svg_batch_size'],
            batch_size=kwargs['svg_batch_size'],
            discount=kwargs['discount'],
            kl_penalty=kwargs['kl_penalty'],
        )

        trainer = Trainer(
            algo=algo,
            policy=policy,
            env=env,
            sampler=sampler,
            sample_processor=sample_processor,
            dynamics_model=dynamics_model,
            value_function=baseline,
            n_itr=kwargs['n_itr'],
            dynamics_model_max_epochs=kwargs['dynamics_max_epochs'],
            vfun_max_epochs=kwargs['vfun_max_epochs'],
            sess=sess,
        )

        trainer.train()
Exemplo n.º 3
0
def run_experiment(**kwargs):
    exp_dir = os.getcwd() + '/data/parallel_mb_ppo/' + EXP_NAME + '/' + kwargs.get('exp_name', '')
    logger.configure(dir=exp_dir, format_strs=['stdout', 'log', 'csv'], snapshot_mode='last')
    json.dump(kwargs, open(exp_dir + '/params.json', 'w'), indent=2, sort_keys=True, cls=ClassEncoder)
    config = tf.ConfigProto()
    config.gpu_options.allow_growth = True
    config.gpu_options.per_process_gpu_memory_fraction = kwargs.get('gpu_frac', 0.95)
    sess = tf.Session(config=config)
    with sess.as_default() as sess:
        # Instantiate classes
        set_seed(kwargs['seed'])

        baseline = kwargs['baseline']()

        env = normalize(kwargs['env']()) # Wrappers?

        policy = GaussianMLPPolicy(
            name="meta-policy",
            obs_dim=np.prod(env.observation_space.shape),
            action_dim=np.prod(env.action_space.shape),
            hidden_sizes=kwargs['policy_hidden_sizes'],
            learn_std=kwargs['policy_learn_std'],
            hidden_nonlinearity=kwargs['policy_hidden_nonlinearity'],
            output_nonlinearity=kwargs['policy_output_nonlinearity'],
        )

        dynamics_model = MLPDynamicsEnsemble('dynamics-ensemble',
                                             env=env,
                                             num_models=kwargs['num_models'],
                                             hidden_nonlinearity=kwargs['dyanmics_hidden_nonlinearity'],
                                             hidden_sizes=kwargs['dynamics_hidden_sizes'],
                                             output_nonlinearity=kwargs['dyanmics_output_nonlinearity'],
                                             learning_rate=kwargs['dynamics_learning_rate'],
                                             batch_size=kwargs['dynamics_batch_size'],
                                             buffer_size=kwargs['dynamics_buffer_size'],
                                             )

        env_sampler = Sampler(
            env=env,
            policy=policy,
            num_rollouts=kwargs['num_rollouts'],
            max_path_length=kwargs['max_path_length'],
            n_parallel=kwargs['n_parallel'],
        )

        model_sampler = METRPOSampler(
            env=env,
            policy=policy,
            num_rollouts=kwargs['imagined_num_rollouts'],
            max_path_length=kwargs['max_path_length'],
            dynamics_model=dynamics_model,
            deterministic=kwargs['deterministic'],
        )

        dynamics_sample_processor = ModelSampleProcessor(
            baseline=baseline,
            discount=kwargs['discount'],
            gae_lambda=kwargs['gae_lambda'],
            normalize_adv=kwargs['normalize_adv'],
            positive_adv=kwargs['positive_adv'],
        )

        model_sample_processor = SampleProcessor(
            baseline=baseline,
            discount=kwargs['discount'],
            gae_lambda=kwargs['gae_lambda'],
            normalize_adv=kwargs['normalize_adv'],
            positive_adv=kwargs['positive_adv'],
        )

        algo = PPO(
            policy=policy,
            learning_rate=kwargs['learning_rate'],
            clip_eps=kwargs['clip_eps'],
            max_epochs=kwargs['num_ppo_steps'],
        )

        trainer = Trainer(
            algo=algo,
            policy=policy,
            env=env,
            model_sampler=model_sampler,
            env_sampler=env_sampler,
            model_sample_processor=model_sample_processor,
            dynamics_sample_processor=dynamics_sample_processor,
            dynamics_model=dynamics_model,
            n_itr=kwargs['n_itr'],
            dynamics_model_max_epochs=kwargs['dynamics_max_epochs'],
            log_real_performance=kwargs['log_real_performance'],
            steps_per_iter=kwargs['steps_per_iter'],
            sample_from_buffer=True,
            sess=sess,
        )

        trainer.train()
Exemplo n.º 4
0
def run_experiment(**kwargs):
    exp_dir = os.getcwd() + '/data/' + EXP_NAME + '/' + kwargs.get(
        'exp_name', '')
    logger.configure(dir=exp_dir,
                     format_strs=['stdout', 'log', 'csv'],
                     snapshot_mode='last')
    json.dump(kwargs,
              open(exp_dir + '/params.json', 'w'),
              indent=2,
              sort_keys=True,
              cls=ClassEncoder)

    config = tf.ConfigProto()
    config.gpu_options.allow_growth = True
    config.gpu_options.per_process_gpu_memory_fraction = kwargs.get(
        'gpu_frac', 0.95)
    sess = tf.Session(config=config)
    with sess.as_default() as sess:

        # Instantiate classes
        set_seed(kwargs['seed'])

        baseline = kwargs['baseline']()

        if not kwargs['use_images']:
            env = normalize(kwargs['env'](policytask=kwargs['task']))
            vae = None

        else:
            vae = VAE(latent_dim=kwargs['latent_dim'],
                      channels=3 * kwargs['time_steps'])
            env = image_wrapper(normalize(kwargs['env']()),
                                latent_dim=kwargs['latent_dim'],
                                time_steps=kwargs['time_steps'])

        policy = NNPolicy(
            name="policy",
            obs_dim=np.prod(env.observation_space.shape),
            action_dim=np.prod(env.action_space.shape),
            hidden_sizes=kwargs['hidden_sizes'],
            normalization=kwargs['normalization'],
        )

        env_sampler = Sampler(
            env=env,
            policy=policy,
            num_rollouts=kwargs['num_rollouts'],
            max_path_length=kwargs['max_path_length'],
            vae=vae,
        )

        model_sampler = ARSSampler(
            env=env,
            policy=policy,
            rollouts_per_policy=kwargs['rollouts_per_policy'],
            max_path_length=kwargs['max_path_length'],
            num_deltas=kwargs['num_deltas'],
            n_parallel=kwargs['num_deltas'],
            vae=vae,
        )

        dynamics_sample_processor = ModelSampleProcessor(
            baseline=baseline,
            discount=kwargs['discount'],
            gae_lambda=kwargs['gae_lambda'],
            normalize_adv=kwargs['normalize_adv'],
            positive_adv=kwargs['positive_adv'],
        )

        ars_sample_processor = ARSSamplerProcessor(
            baseline=baseline,
            discount=kwargs['discount'],
            gae_lambda=kwargs['gae_lambda'],
            normalize_adv=kwargs['normalize_adv'],
            positive_adv=kwargs['positive_adv'],
        )

        algo = RandomSearchOptimizer(policy=policy,
                                     learning_rate=kwargs['learning_rate'],
                                     num_deltas=kwargs['num_deltas'],
                                     percentile=kwargs['percentile'])

        trainer = Trainer(algo=algo,
                          policy=policy,
                          env=env,
                          model_sampler=model_sampler,
                          env_sampler=env_sampler,
                          ars_sample_processor=ars_sample_processor,
                          dynamics_sample_processor=dynamics_sample_processor,
                          num_deltas=kwargs['num_deltas'],
                          n_itr=kwargs['n_itr'],
                          log_real_performance=kwargs['log_real_performance'],
                          steps_per_iter=kwargs['steps_per_iter'],
                          delta_std=kwargs['delta_std'],
                          sess=sess)

        trainer.train()
Exemplo n.º 5
0
def run_experiment(**kwargs):
    exp_dir = os.getcwd() + '/data/' + EXP_NAME
    logger.configure(dir=exp_dir, format_strs=['stdout', 'log', 'csv'], snapshot_mode='last')
    json.dump(kwargs, open(exp_dir + '/params.json', 'w'), indent=2, sort_keys=True, cls=ClassEncoder)
    config = tf.ConfigProto()
    config.gpu_options.allow_growth = True
    config.gpu_options.per_process_gpu_memory_fraction = kwargs.get('gpu_frac', 0.95)
    sess = tf.Session(config=config)
    with sess.as_default() as sess:

        # Instantiate classes
        set_seed(kwargs['seed'])

        baseline = kwargs['baseline']()

        env = normalize(kwargs['env']())

        Qs = [ValueFunction(name="q_fun_%d" % i,
                            obs_dim=int(np.prod(env.observation_space.shape)),
                            action_dim=int(np.prod(env.action_space.shape))
                            ) for i in range(2)]

        Q_targets = [ValueFunction(name="q_fun_target_%d" % i,
                                   obs_dim=int(np.prod(env.observation_space.shape)),
                                   action_dim=int(np.prod(env.action_space.shape))
                                   ) for i in range(2)]

        policy = TanhGaussianMLPPolicy(
            name="policy",
            obs_dim=np.prod(env.observation_space.shape),
            action_dim=np.prod(env.action_space.shape),
            hidden_sizes=kwargs['policy_hidden_sizes'],
            learn_std=kwargs['policy_learn_std'],
            output_nonlinearity=kwargs['policy_output_nonlinearity'],
        )

        sampler = Sampler(
            env=env,
            policy=policy,
            num_rollouts=kwargs['num_rollouts'],
            max_path_length=kwargs['max_path_length'],
            n_parallel=kwargs['n_parallel'],
        )

        sample_processor = ModelSampleProcessor(
            baseline=baseline,
            discount=kwargs['discount'],
            gae_lambda=kwargs['gae_lambda'],
            normalize_adv=kwargs['normalize_adv'],
            positive_adv=kwargs['positive_adv'],
        )

        algo = SAC(
            policy=policy,
            discount=kwargs['discount'],
            learning_rate=kwargs['learning_rate'],
            env=env,
            Qs=Qs,
            Q_targets=Q_targets,
            reward_scale=kwargs['reward_scale']
        )

        trainer = Trainer(
            algo=algo,
            policy=policy,
            env=env,
            sampler=sampler,
            sample_processor=sample_processor,
            n_itr=kwargs['n_itr'],
            sess=sess,
        )

        trainer.train()
    sess.__exit__()
Exemplo n.º 6
0
def run_experiment(**kwargs):
    exp_dir = os.getcwd(
    ) + '/data/parallel_mb_ppo/' + EXP_NAME + '/' + kwargs.get('exp_name', '')
    logger.configure(dir=exp_dir,
                     format_strs=['stdout', 'log', 'csv'],
                     snapshot_mode='last')
    json.dump(kwargs,
              open(exp_dir + '/params.json', 'w'),
              indent=2,
              sort_keys=True,
              cls=ClassEncoder)
    config = tf.ConfigProto()
    config.gpu_options.allow_growth = True
    config.gpu_options.per_process_gpu_memory_fraction = kwargs.get(
        'gpu_frac', 0.95)
    sess = tf.Session(config=config)
    with sess.as_default() as sess:

        # Instantiate classes
        set_seed(kwargs['seed'])

        baseline = kwargs['baseline']()

        env = normalize(kwargs['env']())

        policy = GaussianMLPPolicy(
            name="policy",
            obs_dim=np.prod(env.observation_space.shape),
            action_dim=np.prod(env.action_space.shape),
            hidden_sizes=kwargs['hidden_sizes'],
            learn_std=kwargs['learn_std'],
            hidden_nonlinearity=kwargs['hidden_nonlinearity'],
            output_nonlinearity=kwargs['output_nonlinearity'],
            init_std=kwargs['init_std'],
        )

        # Load policy here

        sampler = Sampler(
            env=env,
            policy=policy,
            num_rollouts=kwargs['num_rollouts'],
            max_path_length=kwargs['max_path_length'],
            n_parallel=kwargs['n_parallel'],
        )

        sample_processor = SingleSampleProcessor(
            baseline=baseline,
            discount=kwargs['discount'],
            gae_lambda=kwargs['gae_lambda'],
            normalize_adv=kwargs['normalize_adv'],
            positive_adv=kwargs['positive_adv'],
        )

        algo = PPO(
            policy=policy,
            learning_rate=kwargs['learning_rate'],
            clip_eps=kwargs['clip_eps'],
            max_epochs=kwargs['num_ppo_steps'],
        )

        trainer = Trainer(
            algo=algo,
            policy=policy,
            env=env,
            sampler=sampler,
            sample_processor=sample_processor,
            n_itr=kwargs['n_itr'],
            sess=sess,
        )

        trainer.train()
Exemplo n.º 7
0
def run_experiment(**config):
    exp_dir = os.getcwd() + '/data/' + EXP_NAME + '/' + config.get('exp_name', '')
    logger.configure(dir=exp_dir, format_strs=['stdout', 'log', 'csv'], snapshot_mode='last')
    json.dump(config, open(exp_dir + '/params.json', 'w'), indent=2, sort_keys=True, cls=ClassEncoder)

    config_sess = tf.ConfigProto()
    config_sess.gpu_options.allow_growth = True
    config_sess.gpu_options.per_process_gpu_memory_fraction = config.get('gpu_frac', 0.95)
    sess = tf.Session(config=config_sess)
    with sess.as_default() as sess:

        env = config['env']()


        if config['recurrent']:
            dynamics_model = RNNDynamicsEnsemble(
                name="dyn_model",
                env=env,
                hidden_sizes=config['hidden_sizes_model'],
                learning_rate=config['learning_rate'],
                backprop_steps=config['backprop_steps'],
                cell_type=config['cell_type'],
                num_models=config['num_models'],
                batch_size=config['batch_size_model'],
                normalize_input=True,
            )

            policy = RNNMPCController(
                name="policy",
                env=env,
                dynamics_model=dynamics_model,
                discount=config['discount'],
                n_candidates=config['n_candidates'],
                horizon=config['horizon'],
                use_cem=config['use_cem'],
                num_cem_iters=config['num_cem_iters'],
                use_reward_model=config['use_reward_model']
            )

        else:
            dynamics_model = MLPDynamicsEnsemble(
                name="dyn_model",
                env=env,
                learning_rate=config['learning_rate'],
                hidden_sizes=config['hidden_sizes_model'],
                weight_normalization=config['weight_normalization_model'],
                num_models=config['num_models'],
                valid_split_ratio=config['valid_split_ratio'],
                rolling_average_persitency=config['rolling_average_persitency'],
                hidden_nonlinearity=config['hidden_nonlinearity_model'],
                batch_size=config['batch_size_model'],
            )

            policy = MPCController(
                name="policy",
                env=env,
                dynamics_model=dynamics_model,
                discount=config['discount'],
                n_candidates=config['n_candidates'],
                horizon=config['horizon'],
                use_cem=config['use_cem'],
                num_cem_iters=config['num_cem_iters'],
            )

        sampler = Sampler(
            env=env,
            policy=policy,
            num_rollouts=config['num_rollouts'],
            max_path_length=config['max_path_length'],
            n_parallel=config['n_parallel'],
        )

        sample_processor = ModelSampleProcessor()

        algo = Trainer(
            env=env,
            policy=policy,
            dynamics_model=dynamics_model,
            sampler=sampler,
            dynamics_sample_processor=sample_processor,
            n_itr=config['n_itr'],
            initial_random_samples=config['initial_random_samples'],
            dynamics_model_max_epochs=config['dynamic_model_epochs'],
            initial_sinusoid_samples=config['initial_sinusoid_samples'],
            sess=sess,
        )
        algo.train()
Exemplo n.º 8
0
def run_experiment(**kwargs):
    exp_dir = os.getcwd() + '/data/' + EXP_NAME + '/' + kwargs.get(
        'exp_name', '')
    logger.configure(dir=exp_dir,
                     format_strs=['stdout', 'log', 'csv'],
                     snapshot_mode='last')
    json.dump(kwargs,
              open(exp_dir + '/params.json', 'w'),
              indent=2,
              sort_keys=True,
              cls=ClassEncoder)

    config = tf.ConfigProto()
    config.gpu_options.allow_growth = True
    config.gpu_options.per_process_gpu_memory_fraction = kwargs.get(
        'gpu_frac', 0.95)
    sess = tf.Session(config=config)
    with sess.as_default() as sess:

        # Instantiate classes
        set_seed(kwargs['seed'])

        baseline = kwargs['baseline']()

        if not kwargs['use_images']:
            env = normalize(kwargs['env']())

        else:
            vae = VAE(latent_dim=8)
            env = image_wrapper(normalize(kwargs['env']()),
                                vae=vae,
                                latent_dim=32)

        policy = NNPolicy(
            name="policy",
            obs_dim=np.prod(env.observation_space.shape),
            action_dim=np.prod(env.action_space.shape),
            hidden_sizes=kwargs['hidden_sizes'],
            normalization=None,
        )

        dynamics_model = MLPDynamicsEnsemble(
            'dynamics-ensemble',
            env=env,
            num_models=kwargs['num_models'],
            hidden_nonlinearity=kwargs['dyanmics_hidden_nonlinearity'],
            hidden_sizes=kwargs['dynamics_hidden_sizes'],
            output_nonlinearity=kwargs['dyanmics_output_nonlinearity'],
            learning_rate=kwargs['dynamics_learning_rate'],
            batch_size=kwargs['dynamics_batch_size'],
            buffer_size=kwargs['dynamics_buffer_size'],
        )

        # dynamics_model = None
        assert kwargs['rollouts_per_policy'] % kwargs['num_models'] == 0

        env_sampler = Sampler(
            env=env,
            policy=policy,
            num_rollouts=kwargs['num_rollouts'],
            max_path_length=kwargs['max_path_length'],
            n_parallel=kwargs['num_rollouts'],
        )

        # TODO: I'm not sure if it works with more than one rollout per model

        model_sampler = ARSSampler(
            env=env,
            policy=policy,
            dynamics_model=dynamics_model,
            rollouts_per_policy=kwargs['rollouts_per_policy'],
            max_path_length=kwargs['horizon'],
            num_deltas=kwargs['num_deltas'],
            n_parallel=1,
        )

        dynamics_sample_processor = ModelSampleProcessor(
            baseline=baseline,
            discount=kwargs['discount'],
            gae_lambda=kwargs['gae_lambda'],
            normalize_adv=kwargs['normalize_adv'],
            positive_adv=kwargs['positive_adv'],
        )

        ars_sample_processor = ARSSamplerProcessor(
            baseline=baseline,
            discount=kwargs['discount'],
            gae_lambda=kwargs['gae_lambda'],
            normalize_adv=kwargs['normalize_adv'],
            positive_adv=kwargs['positive_adv'],
            uncertainty_coeff=kwargs['uncertainty_coeff'])

        algo = RandomSearchOptimizer(policy=policy,
                                     learning_rate=kwargs['learning_rate'],
                                     num_deltas=kwargs['num_deltas'],
                                     percentile=kwargs['percentile'])

        trainer = Trainer(
            algo=algo,
            policy=policy,
            env=env,
            model_sampler=model_sampler,
            env_sampler=env_sampler,
            ars_sample_processor=ars_sample_processor,
            dynamics_sample_processor=dynamics_sample_processor,
            dynamics_model=dynamics_model,
            num_deltas=kwargs['num_deltas'],
            n_itr=kwargs['n_itr'],
            dynamics_model_max_epochs=kwargs['dynamics_max_epochs'],
            log_real_performance=kwargs['log_real_performance'],
            steps_per_iter=kwargs['steps_per_iter'],
            delta_std=kwargs['delta_std'],
            sess=sess,
            initial_random_samples=True,
            sample_from_buffer=kwargs['sample_from_buffer'])

        trainer.train()
Exemplo n.º 9
0
class WorkerData(Worker):
    def __init__(self, simulation_sleep):
        super().__init__()
        self.simulation_sleep = simulation_sleep
        self.env = None
        self.env_sampler = None
        self.dynamics_sample_processor = None
        self.samples_data_arr = []

    def construct_from_feed_dict(
        self,
        policy_pickle,
        env_pickle,
        baseline_pickle,  # UNUSED
        dynamics_model_pickle,
        feed_dict,
    ):

        from meta_mb.samplers.sampler import Sampler
        from meta_mb.samplers.mb_sample_processor import ModelSampleProcessor

        env = pickle.loads(env_pickle)
        policy = pickle.loads(policy_pickle)

        self.env = env
        self.env_sampler = Sampler(env=env,
                                   policy=policy,
                                   **feed_dict['sampler'])
        self.dynamics_sample_processor = ModelSampleProcessor(
            **feed_dict['sample_processor'])

    def prepare_start(self):
        random_sinusoid = self.queue.get()
        self.step(random_sinusoid)
        self.push()

    def step(self, random_sinusoid=(False, False)):
        time_step = time.time()

        if self.itr_counter == 1 and self.env_sampler.policy.dynamics_model.normalization is None:
            if self.verbose:
                logger.log('Data starts first step...')
            self.env_sampler.policy.dynamics_model = pickle.loads(
                self.queue.get())
            if self.verbose:
                logger.log('Data first step done...')
        '''------------- Obtaining samples from the environment -----------'''

        if self.verbose:
            logger.log("Data is obtaining samples...")
        env_paths = self.env_sampler.obtain_samples(
            log=True,
            random=random_sinusoid[0],
            sinusoid=random_sinusoid[1],
            log_prefix='Data-EnvSampler-',
        )
        '''-------------- Processing environment samples -------------------'''

        if self.verbose:
            logger.log("Data is processing samples...")
        samples_data = self.dynamics_sample_processor.process_samples(
            env_paths,
            log=True,
            log_prefix='Data-EnvTrajs-',
        )

        self.samples_data_arr.append(samples_data)
        time_step = time.time() - time_step

        time_sleep = max(self.simulation_sleep - time_step, 0)
        time.sleep(time_sleep)

        logger.logkv('Data-TimeStep', time_step)
        logger.logkv('Data-TimeSleep', time_sleep)

    def _synch(self, dynamics_model_state_pickle):
        time_synch = time.time()
        dynamics_model_state = pickle.loads(dynamics_model_state_pickle)
        assert isinstance(dynamics_model_state, dict)
        self.env_sampler.policy.dynamics_model.set_shared_params(
            dynamics_model_state)
        time_synch = time.time() - time_synch

        logger.logkv('Data-TimeSynch', time_synch)

    def push(self):
        time_push = time.time()
        self.queue_next.put(pickle.dumps(self.samples_data_arr))
        self.samples_data_arr = []
        time_push = time.time() - time_push

        logger.logkv('Data-TimePush', time_push)

    def set_stop_cond(self):
        if self.itr_counter >= self.n_itr:
            self.stop_cond.set()