import logging import itertools import numpy as np from typing import Any, Dict, List, Optional, Tuple, Union import gym from gym import error, spaces from mlagents_envs.environment import UnityEnvironment from mlagents_envs.base_env import BatchedStepResult class UnityGymException(error.Error): """ Any error related to the gym wrapper of ml-agents. """ pass logging.basicConfig(level=logging.INFO) logger = logging.getLogger("gym_unity") GymSingleStepResult = Tuple[np.ndarray, float, bool, Dict] GymMultiStepResult = Tuple[List[np.ndarray], List[float], List[bool], Dict] GymStepResult = Union[GymSingleStepResult, GymMultiStepResult] class UnityEnv(gym.Env): """ Provides Gym wrapper for Unity Learning Environments. Multi-agent environments use lists for object types, as done here: https://github.com/openai/multiagent-particle-envs """ def __init__( self, environment_filename: str, worker_id: int = 0, use_visual: bool = False, uint8_visual: bool = False, multiagent: bool = False, flatten_branched: bool = False, no_graphics: bool = False, allow_multiple_visual_obs: bool = False, ): """ Environment initialization :param environment_filename: The UnityEnvironment path or file to be wrapped in the gym. :param worker_id: Worker number for environment. :param use_visual: Whether to use visual observation or vector observation. :param uint8_visual: Return visual observations as uint8 (0-255) matrices instead of float (0.0-1.0). :param multiagent: Whether to run in multi-agent mode (lists of obs, reward, done). :param flatten_branched: If True, turn branched discrete action spaces into a Discrete space rather than MultiDiscrete. :param no_graphics: Whether to run the Unity simulator in no-graphics mode :param allow_multiple_visual_obs: If True, return a list of visual observations instead of only one. """ self._env = UnityEnvironment( environment_filename, worker_id, no_graphics=no_graphics ) # Take a single step so that the brain information will be sent over if not self._env.get_agent_groups(): self._env.step() self.visual_obs = None self._current_state = None self._n_agents = None self._multiagent = multiagent self._flattener = None # Hidden flag used by Atari environments to determine if the game is over self.game_over = False self._allow_multiple_visual_obs = allow_multiple_visual_obs # Check brain configuration if len(self._env.get_agent_groups()) != 1: raise UnityGymException( "There can only be one brain in a UnityEnvironment " "if it is wrapped in a gym." ) self.brain_name = self._env.get_agent_groups()[0] self.name = self.brain_name self.group_spec = self._env.get_agent_group_spec(self.brain_name) if use_visual and self._get_n_vis_obs() == 0: raise UnityGymException( "`use_visual` was set to True, however there are no" " visual observations as part of this environment." ) self.use_visual = self._get_n_vis_obs() >= 1 and use_visual if not use_visual and uint8_visual: logger.warning( "`uint8_visual was set to true, but visual observations are not in use. " "This setting will not have any effect." ) else: self.uint8_visual = uint8_visual if self._get_n_vis_obs() > 1 and not self._allow_multiple_visual_obs: logger.warning( "The environment contains more than one visual observation. " "You must define allow_multiple_visual_obs=True to received them all. " "Otherwise, please note that only the first will be provided in the observation." ) # Check for number of agents in scene. self._env.reset() step_result = self._env.get_step_result(self.brain_name) self._check_agents(step_result.n_agents()) # Set observation and action spaces if self.group_spec.is_action_discrete(): branches = self.group_spec.discrete_action_branches if self.group_spec.action_shape == 1: self._action_space = spaces.Discrete(branches[0]) else: if flatten_branched: self._flattener = ActionFlattener(branches) self._action_space = self._flattener.action_space else: self._action_space = spaces.MultiDiscrete(branches) else: if flatten_branched: logger.warning( "The environment has a non-discrete action space. It will " "not be flattened." ) high = np.array([1] * self.group_spec.action_shape) self._action_space = spaces.Box(-high, high, dtype=np.float32) high = np.array([np.inf] * self._get_vec_obs_size()) if self.use_visual: shape = self._get_vis_obs_shape() if uint8_visual: self._observation_space = spaces.Box( 0, 255, dtype=np.uint8, shape=shape ) else: self._observation_space = spaces.Box( 0, 1, dtype=np.float32, shape=shape ) else: self._observation_space = spaces.Box(-high, high, dtype=np.float32) def reset(self) -> Union[List[np.ndarray], np.ndarray]: """Resets the state of the environment and returns an initial observation. In the case of multi-agent environments, this is a list. Returns: observation (object/list): the initial observation of the space. """ self._env.reset() info = self._env.get_step_result(self.brain_name) n_agents = info.n_agents() self._check_agents(n_agents) self.game_over = False if not self._multiagent: res: GymStepResult = self._single_step(info) else: res = self._multi_step(info) return res[0] def step(self, action: List[Any]) -> GymStepResult: """Run one timestep of the environment's dynamics. When end of episode is reached, you are responsible for calling `reset()` to reset this environment's state. Accepts an action and returns a tuple (observation, reward, done, info). In the case of multi-agent environments, these are lists. Args: action (object/list): an action provided by the environment Returns: observation (object/list): agent's observation of the current environment reward (float/list) : amount of reward returned after previous action done (boolean/list): whether the episode has ended. info (dict): contains auxiliary diagnostic information, including BatchedStepResult. """ # Use random actions for all other agents in environment. if self._multiagent: if not isinstance(action, list): raise UnityGymException( "The environment was expecting `action` to be a list." ) if len(action) != self._n_agents: raise UnityGymException( "The environment was expecting a list of {} actions.".format( self._n_agents ) ) else: if self._flattener is not None: # Action space is discrete and flattened - we expect a list of scalars action = [self._flattener.lookup_action(_act) for _act in action] action = np.array(action) else: if self._flattener is not None: # Translate action into list action = self._flattener.lookup_action(action) spec = self.group_spec action = np.array(action).reshape((self._n_agents, spec.action_size)) self._env.set_actions(self.brain_name, action) self._env.step() info = self._env.get_step_result(self.brain_name) n_agents = info.n_agents() self._check_agents(n_agents) self._current_state = info if not self._multiagent: single_res = self._single_step(info) self.game_over = single_res[2] return single_res else: multi_res = self._multi_step(info) self.game_over = all(multi_res[2]) return multi_res def _single_step(self, info: BatchedStepResult) -> GymSingleStepResult: if self.use_visual: visual_obs = self._get_vis_obs_list(info) if self._allow_multiple_visual_obs: visual_obs_list = [] for obs in visual_obs: visual_obs_list.append(self._preprocess_single(obs[0])) self.visual_obs = visual_obs_list else: self.visual_obs = self._preprocess_single(visual_obs[0][0]) default_observation = self.visual_obs else: default_observation = self._get_vector_obs(info)[0, :] return ( default_observation, info.reward[0], info.done[0], {"batched_step_result": info}, ) def _preprocess_single(self, single_visual_obs: np.ndarray) -> np.ndarray: if self.uint8_visual: return (255.0 * single_visual_obs).astype(np.uint8) else: return single_visual_obs def _multi_step(self, info: BatchedStepResult) -> GymMultiStepResult: if self.use_visual: self.visual_obs = self._preprocess_multi(self._get_vis_obs_list(info)) default_observation = self.visual_obs else: default_observation = self._get_vector_obs(info) return ( list(default_observation), list(info.reward), list(info.done), {"batched_step_result": info}, ) def _get_n_vis_obs(self) -> int: result = 0 for shape in self.group_spec.observation_shapes: if len(shape) == 3: result += 1 return result def _get_vis_obs_shape(self) -> Optional[Tuple]: for shape in self.group_spec.observation_shapes: if len(shape) == 3: return shape return None def _get_vis_obs_list(self, step_result: BatchedStepResult) -> List[np.ndarray]: result: List[np.ndarray] = [] for obs in step_result.obs: if len(obs.shape) == 4: result.append(obs) return result def _get_vector_obs(self, step_result: BatchedStepResult) -> np.ndarray: result: List[np.ndarray] = [] for obs in step_result.obs: if len(obs.shape) == 2: result.append(obs) return np.concatenate(result, axis=1) def _get_vec_obs_size(self) -> int: result = 0 for shape in self.group_spec.observation_shapes: if len(shape) == 1: result += shape[0] return result def _preprocess_multi( self, multiple_visual_obs: List[np.ndarray] ) -> List[np.ndarray]: if self.uint8_visual: return [ (255.0 * _visual_obs).astype(np.uint8) for _visual_obs in multiple_visual_obs ] else: return multiple_visual_obs def render(self, mode="rgb_array"): return self.visual_obs def close(self) -> None: """Override _close in your subclass to perform any necessary cleanup. Environments will automatically close() themselves when garbage collected or when the program exits. """ self._env.close() def seed(self, seed: Any = None) -> None: """Sets the seed for this env's random number generator(s). Currently not implemented. """ logger.warning("Could not seed environment %s", self.name) return def _check_agents(self, n_agents: int) -> None: if not self._multiagent and n_agents > 1: raise UnityGymException( "The environment was launched as a single-agent environment, however" "there is more than one agent in the scene." ) elif self._multiagent and n_agents <= 1: raise UnityGymException( "The environment was launched as a mutli-agent environment, however" "there is only one agent in the scene." ) if self._n_agents is None: self._n_agents = n_agents logger.info("{} agents within environment.".format(n_agents)) elif self._n_agents != n_agents: raise UnityGymException( "The number of agents in the environment has changed since " "initialization. This is not supported." ) @property def metadata(self): return {"render.modes": ["rgb_array"]} @property def reward_range(self) -> Tuple[float, float]: return -float("inf"), float("inf") @property def spec(self): return None @property def action_space(self): return self._action_space @property def observation_space(self): return self._observation_space @property def number_agents(self): return self._n_agents class ActionFlattener: """ Flattens branched discrete action spaces into single-branch discrete action spaces. """ def __init__(self, branched_action_space): """ Initialize the flattener. :param branched_action_space: A List containing the sizes of each branch of the action space, e.g. [2,3,3] for three branches with size 2, 3, and 3 respectively. """ self._action_shape = branched_action_space self.action_lookup = self._create_lookup(self._action_shape) self.action_space = spaces.Discrete(len(self.action_lookup)) @classmethod def _create_lookup(self, branched_action_space): """ Creates a Dict that maps discrete actions (scalars) to branched actions (lists). Each key in the Dict maps to one unique set of branched actions, and each value contains the List of branched actions. """ possible_vals = [range(_num) for _num in branched_action_space] all_actions = [list(_action) for _action in itertools.product(*possible_vals)] # Dict should be faster than List for large action spaces action_lookup = { _scalar: _action for (_scalar, _action) in enumerate(all_actions) } return action_lookup def lookup_action(self, action): """ Convert a scalar discrete action into a unique set of branched actions. :param: action: A scalar value representing one of the discrete actions. :return: The List containing the branched actions. """ return self.action_lookup[action]