Source code for ray.rllib.policy.policy

from __future__ import absolute_import
from __future__ import division
from __future__ import print_function

from collections import namedtuple
import numpy as np
import gym

from ray.rllib.utils.annotations import DeveloperAPI

# By convention, metrics from optimizing the loss can be reported in the
# `grad_info` dict returned by learn_on_batch() / compute_grads() via this key.
LEARNER_STATS_KEY = "learner_stats"


class TupleActions(namedtuple("TupleActions", ["batches"])):
    """Used to return tuple actions as a list of batches per tuple element."""

    def __new__(cls, batches):
        return super(TupleActions, cls).__new__(cls, batches)

    def numpy(self):
        return TupleActions([b.numpy() for b in self.batches])


[docs]@DeveloperAPI class Policy(object): """An agent policy and loss, i.e., a TFPolicy or other subclass. This object defines how to act in the environment, and also losses used to improve the policy based on its experiences. Note that both policy and loss are defined together for convenience, though the policy itself is logically separate. All policies can directly extend Policy, however TensorFlow users may find TFPolicy simpler to implement. TFPolicy also enables RLlib to apply TensorFlow-specific optimizations such as fusing multiple policy graphs and multi-GPU support. Attributes: observation_space (gym.Space): Observation space of the policy. action_space (gym.Space): Action space of the policy. """ @DeveloperAPI def __init__(self, observation_space, action_space, config): """Initialize the graph. This is the standard constructor for policies. The policy class you pass into RolloutWorker will be constructed with these arguments. Args: observation_space (gym.Space): Observation space of the policy. action_space (gym.Space): Action space of the policy. config (dict): Policy-specific configuration data. """ self.observation_space = observation_space self.action_space = action_space
[docs] @DeveloperAPI def compute_actions(self, obs_batch, state_batches, prev_action_batch=None, prev_reward_batch=None, info_batch=None, episodes=None, **kwargs): """Compute actions for the current policy. Arguments: obs_batch (np.ndarray): batch of observations state_batches (list): list of RNN state input batches, if any prev_action_batch (np.ndarray): batch of previous action values prev_reward_batch (np.ndarray): batch of previous rewards info_batch (info): batch of info objects episodes (list): MultiAgentEpisode for each obs in obs_batch. This provides access to all of the internal episode state, which may be useful for model-based or multiagent algorithms. kwargs: forward compatibility placeholder Returns: actions (np.ndarray): batch of output actions, with shape like [BATCH_SIZE, ACTION_SHAPE]. state_outs (list): list of RNN state output batches, if any, with shape like [STATE_SIZE, BATCH_SIZE]. info (dict): dictionary of extra feature batches, if any, with shape like {"f1": [BATCH_SIZE, ...], "f2": [BATCH_SIZE, ...]}. """ raise NotImplementedError
[docs] @DeveloperAPI def compute_single_action(self, obs, state, prev_action=None, prev_reward=None, info=None, episode=None, clip_actions=False, **kwargs): """Unbatched version of compute_actions. Arguments: obs (obj): single observation state_batches (list): list of RNN state inputs, if any prev_action (obj): previous action value, if any prev_reward (int): previous reward, if any info (dict): info object, if any episode (MultiAgentEpisode): this provides access to all of the internal episode state, which may be useful for model-based or multi-agent algorithms. clip_actions (bool): should the action be clipped kwargs: forward compatibility placeholder Returns: actions (obj): single action state_outs (list): list of RNN state outputs, if any info (dict): dictionary of extra features, if any """ prev_action_batch = None prev_reward_batch = None info_batch = None episodes = None if prev_action is not None: prev_action_batch = [prev_action] if prev_reward is not None: prev_reward_batch = [prev_reward] if info is not None: info_batch = [info] if episode is not None: episodes = [episode] [action], state_out, info = self.compute_actions( [obs], [[s] for s in state], prev_action_batch=prev_action_batch, prev_reward_batch=prev_reward_batch, info_batch=info_batch, episodes=episodes) if clip_actions: action = clip_action(action, self.action_space) return action, [s[0] for s in state_out], \ {k: v[0] for k, v in info.items()}
[docs] @DeveloperAPI def postprocess_trajectory(self, sample_batch, other_agent_batches=None, episode=None): """Implements algorithm-specific trajectory postprocessing. This will be called on each trajectory fragment computed during policy evaluation. Each fragment is guaranteed to be only from one episode. Arguments: sample_batch (SampleBatch): batch of experiences for the policy, which will contain at most one episode trajectory. other_agent_batches (dict): In a multi-agent env, this contains a mapping of agent ids to (policy, agent_batch) tuples containing the policy and experiences of the other agents. episode (MultiAgentEpisode): this provides access to all of the internal episode state, which may be useful for model-based or multi-agent algorithms. Returns: SampleBatch: postprocessed sample batch. """ return sample_batch
[docs] @DeveloperAPI def learn_on_batch(self, samples): """Fused compute gradients and apply gradients call. Either this or the combination of compute/apply grads must be implemented by subclasses. Returns: grad_info: dictionary of extra metadata from compute_gradients(). Examples: >>> batch = ev.sample() >>> ev.learn_on_batch(samples) """ grads, grad_info = self.compute_gradients(samples) self.apply_gradients(grads) return grad_info
[docs] @DeveloperAPI def compute_gradients(self, postprocessed_batch): """Computes gradients against a batch of experiences. Either this or learn_on_batch() must be implemented by subclasses. Returns: grads (list): List of gradient output values info (dict): Extra policy-specific values """ raise NotImplementedError
[docs] @DeveloperAPI def apply_gradients(self, gradients): """Applies previously computed gradients. Either this or learn_on_batch() must be implemented by subclasses. """ raise NotImplementedError
[docs] @DeveloperAPI def get_weights(self): """Returns model weights. Returns: weights (obj): Serializable copy or view of model weights """ raise NotImplementedError
[docs] @DeveloperAPI def set_weights(self, weights): """Sets model weights. Arguments: weights (obj): Serializable copy or view of model weights """ raise NotImplementedError
[docs] @DeveloperAPI def get_initial_state(self): """Returns initial RNN state for the current policy.""" return []
[docs] @DeveloperAPI def get_state(self): """Saves all local state. Returns: state (obj): Serialized local state. """ return self.get_weights()
[docs] @DeveloperAPI def set_state(self, state): """Restores all local state. Arguments: state (obj): Serialized local state. """ self.set_weights(state)
[docs] @DeveloperAPI def on_global_var_update(self, global_vars): """Called on an update to global vars. Arguments: global_vars (dict): Global variables broadcast from the driver. """ pass
[docs] @DeveloperAPI def export_model(self, export_dir): """Export Policy to local directory for serving. Arguments: export_dir (str): Local writable directory. """ raise NotImplementedError
[docs] @DeveloperAPI def export_checkpoint(self, export_dir): """Export Policy checkpoint to local directory. Argument: export_dir (str): Local writable directory. """ raise NotImplementedError
def clip_action(action, space): """Called to clip actions to the specified range of this policy. Arguments: action: Single action. space: Action space the actions should be present in. Returns: Clipped batch of actions. """ if isinstance(space, gym.spaces.Box): return np.clip(action, space.low, space.high) elif isinstance(space, gym.spaces.Tuple): if type(action) not in (tuple, list): raise ValueError("Expected tuple space for actions {}: {}".format( action, space)) out = [] for a, s in zip(action, space.spaces): out.append(clip_action(a, s)) return out else: return action