Agents

Coach supports many state-of-the-art reinforcement learning algorithms, which are separated into three main classes -value optimization, policy optimization and imitation learning.A detailed description of those algorithms can be found by navigating to each of the algorithm pages.

Agents

• Actor-Critic
• ACER
• Behavioral Cloning
• Bootstrapped DQN
• Categorical DQN
• Conditional Imitation Learning
• Clipped Proximal Policy Optimization
• Deep Deterministic Policy Gradient
• Twin Delayed Deep Deterministic Policy Gradient
• Soft Actor-Critic
• Direct Future Prediction
• Double DQN
• Deep Q Networks
• Dueling DQN
• Mixed Monte Carlo
• N-Step Q Learning
• Normalized Advantage Functions
• Neural Episodic Control
• Persistent Advantage Learning
• Policy Gradient
• Proximal Policy Optimization
• Rainbow

• Quantile Regression DQN

• class rlcoach.base_parameters.AgentParameters(_algorithm: rl_coach.base_parameters.AlgorithmParameters, exploration: ExplorationParameters, memory: MemoryParameters, networks: Dict[str, rl_coach.base_parameters.NetworkParameters], visualization: rl_coach.base_parameters.VisualizationParameters = )[source]

• • Parameters

  • • algorithm – A class inheriting AlgorithmParameters.The parameters used for the specific algorithm used by the agent.These parameters can be later referenced in the agent implementation through self.ap.algorithm.

    • exploration – Either a class inheriting ExplorationParameters or a dictionary mapping between actionspace types and their corresponding ExplorationParameters. If a dictionary was used,when the agent will be instantiated, the correct exploration policy parameters will be usedaccording to the real type of the environment action space.These parameters will be used to instantiate the exporation policy.

    • memory – A class inheriting MemoryParameters. It defines all the parameters used by the memory module.

    • networks – A dictionary mapping between network names and their corresponding network parmeters, definedas a class inheriting NetworkParameters. Each element will be used in order to instantiatea NetworkWrapper class, and all the network wrappers will be stored in the agent underself.network_wrappers. self.network_wrappers is a dict mapping between the network name thatwas given in the networks dict, and the instantiated network wrapper.

    • visualization – A class inheriting VisualizationParameters and defining various parameters that can beused for visualization purposes, such as printing to the screen, rendering, and saving videos.

• class rlcoach.agents.agent.Agent(_agent_parameters: rl_coach.base_parameters.AgentParameters, parent: Union[LevelManager, CompositeAgent] = None)[source]
• • Parameters

  • agent_parameters – A AgentParameters class instance with all the agent parameters

  • act(action: Union[None, int, float, numpy.ndarray, List] = None) → rl_coach.core_types.ActionInfo[source]

  • Given the agents current knowledge, decide on the next action to apply to the environment

    • Parameters

    • action – An action to take, overriding whatever the current policy is

    • Returns

    • An ActionInfo object, which contains the action and any additional info from the action decision process

  • callmemory(_func, args=())[source]

  • This function is a wrapper to allow having the same calls for shared or unshared memories.It should be used instead of calling the memory directly in order to allow different algorithms to workboth with a shared and a local memory.

    • Parameters

    • • func – the name of the memory function to call

      • args – the arguments to supply to the function

    • Returns

    • the return value of the function

  • chooseaction(_curr_state)[source]

  • choose an action to act with in the current episode being played. Different behavior might be exhibited whentraining or testing.

    • Parameters

    • curr_state – the current state to act upon.

    • Returns

    • chosen action, some action value describing the action (q-value, probability, etc)

  • collectsavers(_parent_path_suffix: str) → rl_coach.saver.SaverCollection[source]

  • Collect all of agent’s network savers:param parent_path_suffix: path suffix of the parent of the agent(could be name of level manager or composite agent):return: collection of all agent savers

  • create_networks() → Dict[str, rl_coach.architectures.network_wrapper.NetworkWrapper][source]

  • Create all the networks of the agent.The network creation will be done after setting the environment parameters for the agent, since they are neededfor creating the network.

    • Returns
    • A list containing all the networks

  • freeze_memory()[source]

  • Shuffle episodes in the memory and freeze it to make sure that no extra data is being pushed anymore.:return: None

  • getpredictions(_states: List[Dict[str, numpy.ndarray]], prediction_type: rl_coach.core_types.PredictionType)[source]

  • Get a prediction from the agent with regard to the requested prediction_type.If the agent cannot predict this type of prediction_type, or if there is more than possible way to do so,raise a ValueException.

    • Parameters

    • • states – The states to get a prediction for

      • prediction_type – The type of prediction to get for the states. For example, the state-value prediction.

    • Returns

    • the predicted values

  • getstate_embedding(_state: dict) → numpy.ndarray[source]

  • Given a state, get the corresponding state embedding from the main network

    • Parameters

    • state – a state dict

    • Returns

    • a numpy embedding vector

  • handle_episode_ended() → None[source]

  • Make any changes needed when each episode is ended.This includes incrementing counters, updating full episode dependent values, updating logs, etc.This function is called right after each episode is ended.

    • Returns
    • None

  • init_environment_dependent_modules() → None[source]

  • Initialize any modules that depend on knowing information about the environment such as the action space orthe observation space

    • Returns
    • None

  • initialize_session_dependent_components()[source]

  • Initialize components which require a session as part of their initialization.

    • Returns
    • None

  • learnfrom_batch(_batch) → Tuple[float, List, List][source]

  • Given a batch of transitions, calculates their target values and updates the network.

    • Parameters

    • batch – A list of transitions

    • Returns

    • The total loss of the training, the loss per head and the unclipped gradients

  • load_memory_from_file()[source]

  • Load memory transitions from a file.

    • Returns
    • None

  • log_to_screen() → None[source]

  • Write an episode summary line to the terminal

    • Returns
    • None

  • observe(env_response: rl_coach.core_types.EnvResponse) → bool[source]

  • Given a response from the environment, distill the observation from it and store it for later use.The response should be a dictionary containing the performed action, the new observation and measurements,the reward, a game over flag and any additional information necessary.

    • Parameters

    • env_response – result of call from environment.step(action)

    • Returns

    • a boolean value which determines if the agent has decided to terminate the episode after seeing thegiven observation

  • property parent

  • Get the parent class of the agent

    • Returns
    • the current phase

  • property phase

  • The current running phase of the agent

    • Returns
    • RunPhase

  • post_training_commands() → None[source]

  • A function which allows adding any functionality that is required to run right after the training phase ends.

    • Returns
    • None

  • preparebatch_for_inference(_states: Union[Dict[str, numpy.ndarray], List[Dict[str, numpy.ndarray]]], network_name: str) → Dict[str, numpy.core.multiarray.array][source]

  • Convert curr_state into input tensors tensorflow is expecting. i.e. if we have several inputs states, stack allobservations together, measurements together, etc.

    • Parameters

    • • states – A list of environment states, where each one is a dict mapping from an observation name to itscorresponding observation

      • network_name – The agent network name to prepare the batch for. this is needed in order to extract onlythe observation relevant for the network from the states.

    • Returns

    • A dictionary containing a list of values from all the given states for each of the observations

  • registersignal(_signal_name: str, dump_one_value_per_episode: bool = True, dump_one_value_per_step: bool = False) → rl_coach.utils.Signal[source]

  • Register a signal such that its statistics will be dumped and be viewable through dashboard

    • Parameters

    • • signal_name – the name of the signal as it will appear in dashboard

      • dump_one_value_per_episode – should the signal value be written for each episode?

      • dump_one_value_per_step – should the signal value be written for each step?

    • Returns

    • the created signal

  • resetevaluation_state(_val: rl_coach.core_types.RunPhase) → None[source]

  • Perform accumulators initialization when entering an evaluation phase, and signal dumping when exiting anevaluation phase. Entering or exiting the evaluation phase is determined according to the new phase givenby val, and by the current phase set in self.phase.

    • Parameters

    • val – The new phase to change to

    • Returns

    • None

  • reset_internal_state() → None[source]

  • Reset all the episodic parameters. This function is called right before each episode starts.

    • Returns
    • None

  • restorecheckpoint(_checkpoint_dir: str) → None[source]

  • Allows agents to store additional information when saving checkpoints.

    • Parameters

    • checkpoint_dir – The checkpoint dir to restore from

    • Returns

    • None

  • run_off_policy_evaluation() → None

  • Run off-policy evaluation estimators to evaluate the trained policy performance against a dataset.Should only be implemented for off-policy RL algorithms.

    • Returns
    • None

  • runpre_network_filter_for_inference(_state: Dict[str, numpy.ndarray], update_filter_internal_state: bool = True) → Dict[str, numpy.ndarray][source]

  • Run filters which where defined for being applied right before using the state for inference.

    • Parameters

    • • state – The state to run the filters on

      • update_filter_internal_state – Should update the filter’s internal state - should not update when evaluating

    • Returns

    • The filtered state

  • savecheckpoint(_checkpoint_prefix: str) → None[source]

  • Allows agents to store additional information when saving checkpoints.

    • Parameters

    • checkpoint_prefix – The prefix of the checkpoint file to save

    • Returns

    • None

  • setenvironment_parameters(_spaces: rl_coach.spaces.SpacesDefinition)[source]

  • Sets the parameters that are environment dependent. As a side effect, initializes all the components that aredependent on those values, by calling init_environment_dependent_modules

    • Parameters

    • spaces – the environment spaces definition

    • Returns

    • None

  • setincoming_directive(_action: Union[int, float, numpy.ndarray, List]) → None[source]

  • Allows setting a directive for the agent to follow. This is useful in hierarchy structures, where the agenthas another master agent that is controlling it. In such cases, the master agent can define the goals for theslave agent, define it’s observation, possible actions, etc. The directive type is defined by the agentin-action-space.

    • Parameters

    • action – The action that should be set as the directive

    • Returns

• setsession(_sess) → None[source]

• Set the deep learning framework session for all the agents in the composite agent

  • Returns
  • None

• setup_logger() → None[source]

• Setup the logger for the agent

  • Returns
  • None

• sync() → None[source]

• Sync the global network parameters to local networks

  • Returns
  • None

• train() → float[source]

• Check if a training phase should be done as configured by num_consecutive_playing_steps.If it should, then do several training steps as configured by num_consecutive_training_steps.A single training iteration: Sample a batch, train on it and update target networks.

  • Returns
  • The total training loss during the training iterations.

• update_log() → None[source]

• Updates the episodic log file with all the signal values from the most recent episode.Additional signals for logging can be set by the creating a new signal using self.register_signal,and then updating it with some internal agent values.

  • Returns
  • None

• update_step_in_episode_log() → None[source]

• Updates the in-episode log file with all the signal values from the most recent step.

  • Returns
  • None

• updatetransition_before_adding_to_replay_buffer(_transition: rl_coach.core_types.Transition) → rl_coach.core_types.Transition[source]

• Allows agents to update the transition just before adding it to the replay buffer.Can be useful for agents that want to tweak the reward, termination signal, etc.

  • Parameters

  • transition – the transition to update

  • Returns

  • the updated transition