import logging import numpy as np from typing import List, Type import ray from ray.rllib.agents import with_common_config from ray.rllib.agents.mbmpo.mbmpo_torch_policy import MBMPOTorchPolicy from ray.rllib.agents.mbmpo.model_ensemble import DynamicsEnsembleCustomModel from ray.rllib.agents.mbmpo.utils import calculate_gae_advantages, \ MBMPOExploration from ray.rllib.agents.trainer import Trainer from ray.rllib.env.env_context import EnvContext from ray.rllib.env.wrappers.model_vector_env import model_vector_env from ray.rllib.evaluation.metrics import collect_episodes, collect_metrics, \ get_learner_stats from ray.rllib.evaluation.worker_set import WorkerSet from ray.rllib.execution.common import STEPS_SAMPLED_COUNTER, \ STEPS_TRAINED_COUNTER, STEPS_TRAINED_THIS_ITER_COUNTER, \ _get_shared_metrics from ray.rllib.execution.metric_ops import CollectMetrics from ray.rllib.policy.policy import Policy from ray.rllib.policy.sample_batch import DEFAULT_POLICY_ID, SampleBatch from ray.rllib.utils.annotations import override from ray.rllib.utils.deprecation import DEPRECATED_VALUE from ray.rllib.utils.metrics.learner_info import LEARNER_INFO from ray.rllib.utils.sgd import standardized from ray.rllib.utils.torch_utils import convert_to_torch_tensor from ray.rllib.utils.typing import EnvType, TrainerConfigDict from ray.util.iter import from_actors, LocalIterator logger = logging.getLogger(__name__) # yapf: disable # __sphinx_doc_begin__ # Adds the following updates to the (base) `Trainer` config in # rllib/agents/trainer.py (`COMMON_CONFIG` dict). DEFAULT_CONFIG = with_common_config({ # If true, use the Generalized Advantage Estimator (GAE) # with a value function, see https://arxiv.org/pdf/1506.02438.pdf. "use_gae": True, # GAE(lambda) parameter. "lambda": 1.0, # Initial coefficient for KL divergence. "kl_coeff": 0.0005, # Size of batches collected from each worker. "rollout_fragment_length": 200, # Do create an actual env on the local worker (worker-idx=0). "create_env_on_driver": True, # Step size of SGD. "lr": 1e-3, # Coefficient of the value function loss. "vf_loss_coeff": 0.5, # Coefficient of the entropy regularizer. "entropy_coeff": 0.0, # PPO clip parameter. "clip_param": 0.5, # Clip param for the value function. Note that this is sensitive to the # scale of the rewards. If your expected V is large, increase this. "vf_clip_param": 10.0, # If specified, clip the global norm of gradients by this amount. "grad_clip": None, # Target value for KL divergence. "kl_target": 0.01, # Whether to rollout "complete_episodes" or "truncate_episodes". "batch_mode": "complete_episodes", # Which observation filter to apply to the observation. "observation_filter": "NoFilter", # Number of Inner adaptation steps for the MAML algorithm. "inner_adaptation_steps": 1, # Number of MAML steps per meta-update iteration (PPO steps). "maml_optimizer_steps": 8, # Inner adaptation step size. "inner_lr": 1e-3, # Horizon of the environment (200 in MB-MPO paper). "horizon": 200, # Dynamics ensemble hyperparameters. "dynamics_model": { "custom_model": DynamicsEnsembleCustomModel, # Number of Transition-Dynamics (TD) models in the ensemble. "ensemble_size": 5, # Hidden layers for each model in the TD-model ensemble. "fcnet_hiddens": [512, 512, 512], # Model learning rate. "lr": 1e-3, # Max number of training epochs per MBMPO iter. "train_epochs": 500, # Model batch size. "batch_size": 500, # Training/validation split. "valid_split_ratio": 0.2, # Normalize data (obs, action, and deltas). "normalize_data": True, }, # Exploration for MB-MPO is based on StochasticSampling, but uses 8000 # random timesteps up-front for worker=0. "exploration_config": { "type": MBMPOExploration, "random_timesteps": 8000, }, # Workers sample from dynamics models, not from actual envs. "custom_vector_env": model_vector_env, # How many iterations through MAML per MBMPO iteration. "num_maml_steps": 10, # Deprecated keys: # Share layers for value function. If you set this to True, it's important # to tune vf_loss_coeff. # Use config.model.vf_share_layers instead. "vf_share_layers": DEPRECATED_VALUE, }) # __sphinx_doc_end__ # yapf: enable # Select Metric Keys for MAML Stats Tracing METRICS_KEYS = [ "episode_reward_mean", "episode_reward_min", "episode_reward_max" ] class MetaUpdate: def __init__(self, workers, num_steps, maml_steps, metric_gen): """Computes the MetaUpdate step in MAML. Adapted for MBMPO for multiple MAML Iterations. Args: workers (WorkerSet): Set of Workers num_steps (int): Number of meta-update steps per MAML Iteration maml_steps (int): MAML Iterations per MBMPO Iteration metric_gen (Iterator): Generates metrics dictionary Returns: metrics (dict): MBMPO metrics for logging. """ self.workers = workers self.num_steps = num_steps self.step_counter = 0 self.maml_optimizer_steps = maml_steps self.metric_gen = metric_gen self.metrics = {} def __call__(self, data_tuple): """Args: data_tuple (tuple): 1st element is samples collected from MAML Inner adaptation steps and 2nd element is accumulated metrics """ # Metaupdate Step. print("Meta-Update Step") samples = data_tuple[0] adapt_metrics_dict = data_tuple[1] self.postprocess_metrics( adapt_metrics_dict, prefix="MAMLIter{}".format(self.step_counter)) # MAML Meta-update. fetches = None for i in range(self.maml_optimizer_steps): fetches = self.workers.local_worker().learn_on_batch(samples) learner_stats = get_learner_stats(fetches) # Update KLs. def update(pi, pi_id): assert "inner_kl" not in learner_stats, ( "inner_kl should be nested under policy id key", learner_stats) if pi_id in learner_stats: assert "inner_kl" in learner_stats[pi_id], (learner_stats, pi_id) pi.update_kls(learner_stats[pi_id]["inner_kl"]) else: logger.warning("No data for {}, not updating kl".format(pi_id)) self.workers.local_worker().foreach_trainable_policy(update) # Modify Reporting Metrics. metrics = _get_shared_metrics() metrics.info[LEARNER_INFO] = fetches metrics.counters[STEPS_TRAINED_THIS_ITER_COUNTER] = samples.count metrics.counters[STEPS_TRAINED_COUNTER] += samples.count if self.step_counter == self.num_steps - 1: td_metric = self.workers.local_worker().foreach_policy( fit_dynamics)[0] # Sync workers with meta policy. self.workers.sync_weights() # Sync TD Models with workers. sync_ensemble(self.workers) sync_stats(self.workers) metrics.counters[STEPS_SAMPLED_COUNTER] = td_metric[ STEPS_SAMPLED_COUNTER] # Modify to CollectMetrics. res = self.metric_gen.__call__(None) res.update(self.metrics) self.step_counter = 0 print("MB-MPO Iteration Completed") return [res] else: print("MAML Iteration {} Completed".format(self.step_counter)) self.step_counter += 1 # Sync workers with meta policy print("Syncing Weights with Workers") self.workers.sync_weights() return [] def postprocess_metrics(self, metrics, prefix=""): """Appends prefix to current metrics Args: metrics (dict): Dictionary of current metrics prefix (str): Prefix string to be appended """ for key in metrics.keys(): self.metrics[prefix + "_" + key] = metrics[key] def post_process_metrics(prefix, workers, metrics): """Update current dataset metrics and filter out specific keys. Args: prefix (str): Prefix string to be appended workers (WorkerSet): Set of workers metrics (dict): Current metrics dictionary """ res = collect_metrics(remote_workers=workers.remote_workers()) for key in METRICS_KEYS: metrics[prefix + "_" + key] = res[key] return metrics def inner_adaptation(workers: WorkerSet, samples: List[SampleBatch]): """Performs one gradient descend step on each remote worker. Args: workers (WorkerSet): The WorkerSet of the Trainer. samples (List[SampleBatch]): The list of SampleBatches to perform a training step on (one for each remote worker). """ for i, e in enumerate(workers.remote_workers()): e.learn_on_batch.remote(samples[i]) def fit_dynamics(policy, pid): return policy.dynamics_model.fit() def sync_ensemble(workers: WorkerSet) -> None: """Syncs dynamics ensemble weights from driver (main) to workers. Args: workers (WorkerSet): Set of workers, including driver (main). """ def get_ensemble_weights(worker): policy_map = worker.policy_map policies = policy_map.keys() def policy_ensemble_weights(policy): model = policy.dynamics_model return { k: v.cpu().detach().numpy() for k, v in model.state_dict().items() } return { pid: policy_ensemble_weights(policy) for pid, policy in policy_map.items() if pid in policies } def set_ensemble_weights(policy, pid, weights): weights = weights[pid] weights = convert_to_torch_tensor(weights, device=policy.device) model = policy.dynamics_model model.load_state_dict(weights) if workers.remote_workers(): weights = ray.put(get_ensemble_weights(workers.local_worker())) set_func = ray.put(set_ensemble_weights) for e in workers.remote_workers(): e.foreach_policy.remote(set_func, weights=weights) def sync_stats(workers: WorkerSet) -> None: def get_normalizations(worker): policy = worker.policy_map[DEFAULT_POLICY_ID] return policy.dynamics_model.normalizations def set_normalizations(policy, pid, normalizations): policy.dynamics_model.set_norms(normalizations) if workers.remote_workers(): normalization_dict = ray.put( get_normalizations(workers.local_worker())) set_func = ray.put(set_normalizations) for e in workers.remote_workers(): e.foreach_policy.remote( set_func, normalizations=normalization_dict) def post_process_samples(samples, config: TrainerConfigDict): # Instead of using NN for value function, we use regression split_lst = [] for sample in samples: indexes = np.asarray(sample["dones"]).nonzero()[0] indexes = indexes + 1 reward_list = np.split(sample["rewards"], indexes)[:-1] observation_list = np.split(sample["obs"], indexes)[:-1] paths = [] for i in range(0, len(reward_list)): paths.append({ "rewards": reward_list[i], "observations": observation_list[i] }) paths = calculate_gae_advantages(paths, config["gamma"], config["lambda"]) advantages = np.concatenate([path["advantages"] for path in paths]) sample["advantages"] = standardized(advantages) split_lst.append(sample.count) return samples, split_lst class MBMPOTrainer(Trainer): """Model-Based Meta Policy Optimization (MB-MPO) Trainer. This file defines the distributed Trainer class for model-based meta policy optimization. See `mbmpo_[tf|torch]_policy.py` for the definition of the policy loss. Detailed documentation: https://docs.ray.io/en/master/rllib-algorithms.html#mbmpo """ @classmethod @override(Trainer) def get_default_config(cls) -> TrainerConfigDict: return DEFAULT_CONFIG @override(Trainer) def validate_config(self, config: TrainerConfigDict) -> None: # Call super's validation method. super().validate_config(config) if config["num_gpus"] > 1: raise ValueError("`num_gpus` > 1 not yet supported for MB-MPO!") if config["framework"] != "torch": logger.warning( "MB-MPO only supported in PyTorch so far! Switching to " "`framework=torch`.") config["framework"] = "torch" if config["inner_adaptation_steps"] <= 0: raise ValueError("Inner adaptation steps must be >=1!") if config["maml_optimizer_steps"] <= 0: raise ValueError("PPO steps for meta-update needs to be >=0!") if config["entropy_coeff"] < 0: raise ValueError("`entropy_coeff` must be >=0.0!") if config["batch_mode"] != "complete_episodes": raise ValueError("`batch_mode=truncate_episodes` not supported!") if config["num_workers"] <= 0: raise ValueError("Must have at least 1 worker/task.") if config["create_env_on_driver"] is False: raise ValueError( "Must have an actual Env created on the driver " "(local) worker! Set `create_env_on_driver` to True.") @override(Trainer) def get_default_policy_class(self, config: TrainerConfigDict) -> Type[Policy]: return MBMPOTorchPolicy @staticmethod @override(Trainer) def execution_plan(workers: WorkerSet, config: TrainerConfigDict, **kwargs) -> LocalIterator[dict]: assert len(kwargs) == 0, ( "MBMPO execution_plan does NOT take any additional parameters") # Train TD Models on the driver. workers.local_worker().foreach_policy(fit_dynamics) # Sync driver's policy with workers. workers.sync_weights() # Sync TD Models and normalization stats with workers sync_ensemble(workers) sync_stats(workers) # Dropping metrics from the first iteration _, _ = collect_episodes( workers.local_worker(), workers.remote_workers(), [], timeout_seconds=9999) # Metrics Collector. metric_collect = CollectMetrics( workers, min_history=0, timeout_seconds=config["metrics_episode_collection_timeout_s"]) num_inner_steps = config["inner_adaptation_steps"] def inner_adaptation_steps(itr): buf = [] split = [] metrics = {} for samples in itr: print("Collecting Samples, Inner Adaptation {}".format( len(split))) # Processing Samples (Standardize Advantages) samples, split_lst = post_process_samples(samples, config) buf.extend(samples) split.append(split_lst) adapt_iter = len(split) - 1 prefix = "DynaTrajInner_" + str(adapt_iter) metrics = post_process_metrics(prefix, workers, metrics) if len(split) > num_inner_steps: out = SampleBatch.concat_samples(buf) out["split"] = np.array(split) buf = [] split = [] yield out, metrics metrics = {} else: inner_adaptation(workers, samples) # Iterator for Inner Adaptation Data gathering (from pre->post # adaptation). rollouts = from_actors(workers.remote_workers()) rollouts = rollouts.batch_across_shards() rollouts = rollouts.transform(inner_adaptation_steps) # Meta update step with outer combine loop for multiple MAML # iterations. train_op = rollouts.combine( MetaUpdate(workers, config["num_maml_steps"], config["maml_optimizer_steps"], metric_collect)) return train_op @staticmethod @override(Trainer) def validate_env(env: EnvType, env_context: EnvContext) -> None: """Validates the local_worker's env object (after creation). Args: env: The env object to check (for worker=0 only). env_context: The env context used for the instantiation of the local worker's env (worker=0). Raises: ValueError: In case something is wrong with the config. """ if not hasattr(env, "reward") or not callable(env.reward): raise ValueError( f"Env {env} doest not have a `reward()` method, needed for " "MB-MPO! This `reward()` method should return ")