RLlib: Industry-Grade Reinforcement Learning with TF and Torch ============================================================== **RLlib** is an open-source library for reinforcement learning (RL), offering support for production-level, highly distributed RL workloads, while maintaining unified and simple APIs for a large variety of industry applications. Whether you would like to train your agents in multi-agent setups, purely from offline (historic) datasets, or using externally connected simulators, RLlib offers simple solutions for your decision making needs. You **don't need** to be an **RL expert** to use RLlib, nor do you need to learn Ray or any other of its libraries! If you either have your problem coded (in python) as an `RL environment `_ or own lots of pre-recorded, historic behavioral data to learn from, you will be up and running in only a few days. RLlib is already used in production by industry leaders in many different verticals, such as `climate control `_, `manufacturing and logistics `_, `finance `_, `gaming `_, `automobile `_, `robotics `_, `boat design `_, and many others. Installation and Setup ---------------------- Install RLlib and run your first experiment on your laptop in seconds: **TensorFlow:** .. code-block:: bash $ conda create -n rllib python=3.8 $ conda activate rllib $ pip install "ray[rllib]" tensorflow "gym[atari]" "gym[accept-rom-license]" atari_py $ # Run a test job: $ rllib train --run APPO --env CartPole-v0 **PyTorch:** .. code-block:: bash $ conda create -n rllib python=3.8 $ conda activate rllib $ pip install "ray[rllib]" torch "gym[atari]" "gym[accept-rom-license]" atari_py $ # Run a test job: $ rllib train --run APPO --env CartPole-v0 --torch Quick First Experiment ---------------------- .. code-block:: python import gym from ray.rllib.agents.ppo import PPOTrainer # Define your problem using python and openAI's gym API: class ParrotEnv(gym.Env): """Environment in which an agent must learn to repeat the seen observations. Observations are float numbers indicating the to-be-repeated values, e.g. -1.0, 5.1, or 3.2. The action space is always the same as the observation space. Rewards are r=-abs(observation - action), for all steps. """ def __init__(self, config): # Make the space (for actions and observations) configurable. self.action_space = config.get( "parrot_shriek_range", gym.spaces.Box(-1.0, 1.0, shape=(1, ))) # Since actions should repeat observations, their spaces must be the # same. self.observation_space = self.action_space self.cur_obs = None self.episode_len = 0 def reset(self): """Resets the episode and returns the initial observation of the new one. """ # Reset the episode len. self.episode_len = 0 # Sample a random number from our observation space. self.cur_obs = self.observation_space.sample() # Return initial observation. return self.cur_obs def step(self, action): """Takes a single step in the episode given `action` Returns: New observation, reward, done-flag, info-dict (empty). """ # Set `done` flag after 10 steps. self.episode_len += 1 done = self.episode_len >= 10 # r = -abs(obs - action) reward = -sum(abs(self.cur_obs - action)) # Set a new observation (random sample). self.cur_obs = self.observation_space.sample() return self.cur_obs, reward, done, {} # Create an RLlib Trainer instance to learn how to act in the above # environment. trainer = PPOTrainer( config={ # Env class to use (here: our gym.Env sub-class from above). "env": ParrotEnv, # Config dict to be passed to our custom env's constructor. "env_config": { "parrot_shriek_range": gym.spaces.Box(-5.0, 5.0, (1, )) }, # Parallelize environment rollouts. "num_workers": 3, }) # Train for n iterations and report results (mean episode rewards). # Since we have to guess 10 times and the optimal reward is 0.0 # (exact match between observation and action value), # we can expect to reach an optimal episode reward of 0.0. for i in range(5): results = trainer.train() print(f"Iter: {i}; avg. reward={results['episode_reward_mean']}") After training, you may want to perform action computations (inference) in your environment. Below is a minimal example on how to do this. Also `check out our more detailed examples here `_ (in particular for `normal models `_, `LSTMs `_, and `attention nets `_). .. code-block:: python # Perform inference (action computations) based on given env observations. # Note that we are using a slightly simpler env here (-3.0 to 3.0, instead # of -5.0 to 5.0!), however, this should still work as the agent has # (hopefully) learned to "just always repeat the observation!". env = ParrotEnv({"parrot_shriek_range": gym.spaces.Box(-3.0, 3.0, (1, ))}) # Get the initial observation (some value between -10.0 and 10.0). obs = env.reset() done = False total_reward = 0.0 # Play one episode. while not done: # Compute a single action, given the current observation # from the environment. action = trainer.compute_single_action(obs) # Apply the computed action in the environment. obs, reward, done, info = env.step(action) # Sum up rewards for reporting purposes. total_reward += reward # Report results. print(f"Shreaked for 1 episode; total-reward={total_reward}") For a more detailed `"60 second" example, head to our main documentation `_. Highlighted Features -------------------- The following is a summary of RLlib's most striking features (for an in-depth overview, check out our `documentation `_): The most **popular deep-learning frameworks**: `PyTorch `_ and `TensorFlow (tf1.x/2.x static-graph/eager/traced) `_. **Highly distributed learning**: Our RLlib algorithms (such as our "PPO" or "IMPALA") allow you to set the ``num_workers`` config parameter, such that your workloads can run on 100s of CPUs/nodes thus parallelizing and speeding up learning. **Vectorized (batched) and remote (parallel) environments**: RLlib auto-vectorizes your ``gym.Envs`` via the ``num_envs_per_worker`` config. Environment workers can then batch and thus significantly speedup the action computing forward pass. On top of that, RLlib offers the ``remote_worker_envs`` config to create `single environments (within a vectorized one) as ray Actors `_, thus parallelizing even the env stepping process. | **Multi-agent RL** (MARL): Convert your (custom) ``gym.Envs`` into a multi-agent one via a few simple steps and start training your agents in any of the following fashions: | 1) Cooperative with `shared `_ or `separate `_ policies and/or value functions. | 2) Adversarial scenarios using `self-play `_ and `league-based training `_. | 3) `Independent learning `_ of neutral/co-existing agents. **External simulators**: Don't have your simulation running as a gym.Env in python? No problem! RLlib supports an external environment API and comes with a pluggable, off-the-shelve `client `_/ `server `_ setup that allows you to run 100s of independent simulators on the "outside" (e.g. a Windows cloud) connecting to a central RLlib Policy-Server that learns and serves actions. Alternatively, actions can be computed on the client side to save on network traffic. **Offline RL and imitation learning/behavior cloning**: You don't have a simulator for your particular problem, but tons of historic data recorded by a legacy (maybe non-RL/ML) system? This branch of reinforcement learning is for you! RLlib's comes with several `offline RL `_ algorithms (*CQL*, *MARWIL*, and *DQfD*), allowing you to either purely `behavior-clone `_ your existing system or learn how to further improve over it. In-Depth Documentation ---------------------- For an in-depth overview of RLlib and everything it has to offer, including hand-on tutorials of important industry use cases and workflows, head over to our `documentation pages `_. Cite our Paper -------------- If you've found RLlib useful for your research, please cite our `paper `_ as follows: .. code-block:: @inproceedings{liang2018rllib, Author = {Eric Liang and Richard Liaw and Robert Nishihara and Philipp Moritz and Roy Fox and Ken Goldberg and Joseph E. Gonzalez and Michael I. Jordan and Ion Stoica}, Title = {{RLlib}: Abstractions for Distributed Reinforcement Learning}, Booktitle = {International Conference on Machine Learning ({ICML})}, Year = {2018} }