import logging from typing import Any, Dict, List, Optional import numpy as np from mlagents.tf_utils import tf from mlagents.envs.exception import UnityException from mlagents.envs.policy import Policy from mlagents.envs.action_info import ActionInfo from tensorflow.python.platform import gfile from tensorflow.python.framework import graph_util from mlagents.trainers import tensorflow_to_barracuda as tf2bc from mlagents.envs.brain import BrainInfo logger = logging.getLogger("mlagents.trainers") class UnityPolicyException(UnityException): """ Related to errors with the Trainer. """ pass class TFPolicy(Policy): """ Contains a learning model, and the necessary functions to interact with it to perform evaluate and updating. """ possible_output_nodes = [ "action", "value_estimate", "action_probs", "recurrent_out", "memory_size", "version_number", "is_continuous_control", "action_output_shape", ] def __init__(self, seed, brain, trainer_parameters): """ Initialized the policy. :param seed: Random seed to use for TensorFlow. :param brain: The corresponding Brain for this policy. :param trainer_parameters: The trainer parameters. """ self.m_size = None self.model = None self.inference_dict = {} self.update_dict = {} self.sequence_length = 1 self.seed = seed self.brain = brain self.use_recurrent = trainer_parameters["use_recurrent"] self.memory_dict: Dict[int, np.ndarray] = {} self.num_branches = len(self.brain.vector_action_space_size) self.previous_action_dict: Dict[int, np.array] = {} self.normalize = trainer_parameters.get("normalize", False) self.use_continuous_act = brain.vector_action_space_type == "continuous" if self.use_continuous_act: self.num_branches = self.brain.vector_action_space_size[0] self.model_path = trainer_parameters["model_path"] self.keep_checkpoints = trainer_parameters.get("keep_checkpoints", 5) self.graph = tf.Graph() config = tf.ConfigProto() config.gpu_options.allow_growth = True # For multi-GPU training, set allow_soft_placement to True to allow # placing the operation into an alternative device automatically # to prevent from exceptions if the device doesn't suppport the operation # or the device does not exist config.allow_soft_placement = True self.sess = tf.Session(config=config, graph=self.graph) self.saver = None if self.use_recurrent: self.m_size = trainer_parameters["memory_size"] self.sequence_length = trainer_parameters["sequence_length"] if self.m_size == 0: raise UnityPolicyException( "The memory size for brain {0} is 0 even " "though the trainer uses recurrent.".format(brain.brain_name) ) elif self.m_size % 4 != 0: raise UnityPolicyException( "The memory size for brain {0} is {1} " "but it must be divisible by 4.".format( brain.brain_name, self.m_size ) ) def _initialize_graph(self): with self.graph.as_default(): self.saver = tf.train.Saver(max_to_keep=self.keep_checkpoints) init = tf.global_variables_initializer() self.sess.run(init) def _load_graph(self): with self.graph.as_default(): self.saver = tf.train.Saver(max_to_keep=self.keep_checkpoints) logger.info("Loading Model for brain {}".format(self.brain.brain_name)) ckpt = tf.train.get_checkpoint_state(self.model_path) if ckpt is None: logger.info( "The model {0} could not be found. Make " "sure you specified the right " "--run-id".format(self.model_path) ) self.saver.restore(self.sess, ckpt.model_checkpoint_path) def evaluate(self, brain_info: BrainInfo) -> Dict[str, Any]: """ Evaluates policy for the agent experiences provided. :param brain_info: BrainInfo input to network. :return: Output from policy based on self.inference_dict. """ raise UnityPolicyException("The evaluate function was not implemented.") def get_action(self, brain_info: BrainInfo) -> ActionInfo: """ Decides actions given observations information, and takes them in environment. :param brain_info: A dictionary of brain names and BrainInfo from environment. :return: an ActionInfo containing action, memories, values and an object to be passed to add experiences """ if len(brain_info.agents) == 0: return ActionInfo([], [], None) agents_done = [ agent for agent, done in zip(brain_info.agents, brain_info.local_done) if done ] self.remove_memories(agents_done) self.remove_previous_action(agents_done) run_out = self.evaluate(brain_info) # pylint: disable=assignment-from-no-return self.save_memories(brain_info.agents, run_out.get("memory_out")) return ActionInfo( action=run_out.get("action"), value=run_out.get("value"), outputs=run_out ) def update(self, mini_batch, num_sequences): """ Performs update of the policy. :param num_sequences: Number of experience trajectories in batch. :param mini_batch: Batch of experiences. :return: Results of update. """ raise UnityPolicyException("The update function was not implemented.") def _execute_model(self, feed_dict, out_dict): """ Executes model. :param feed_dict: Input dictionary mapping nodes to input data. :param out_dict: Output dictionary mapping names to nodes. :return: Dictionary mapping names to input data. """ network_out = self.sess.run(list(out_dict.values()), feed_dict=feed_dict) run_out = dict(zip(list(out_dict.keys()), network_out)) return run_out def fill_eval_dict(self, feed_dict, brain_info): for i, _ in enumerate(brain_info.visual_observations): feed_dict[self.model.visual_in[i]] = brain_info.visual_observations[i] if self.use_vec_obs: feed_dict[self.model.vector_in] = brain_info.vector_observations if not self.use_continuous_act: feed_dict[self.model.action_masks] = brain_info.action_masks return feed_dict def make_empty_memory(self, num_agents): """ Creates empty memory for use with RNNs :param num_agents: Number of agents. :return: Numpy array of zeros. """ return np.zeros((num_agents, self.m_size), dtype=np.float) def save_memories( self, agent_ids: List[int], memory_matrix: Optional[np.ndarray] ) -> None: if memory_matrix is None: return for index, agent_id in enumerate(agent_ids): self.memory_dict[agent_id] = memory_matrix[index, :] def retrieve_memories(self, agent_ids: List[int]) -> np.ndarray: memory_matrix = np.zeros((len(agent_ids), self.m_size), dtype=np.float) for index, agent_id in enumerate(agent_ids): if agent_id in self.memory_dict: memory_matrix[index, :] = self.memory_dict[agent_id] return memory_matrix def remove_memories(self, agent_ids): for agent_id in agent_ids: if agent_id in self.memory_dict: self.memory_dict.pop(agent_id) def make_empty_previous_action(self, num_agents): """ Creates empty previous action for use with RNNs and discrete control :param num_agents: Number of agents. :return: Numpy array of zeros. """ return np.zeros((num_agents, self.num_branches), dtype=np.int) def save_previous_action( self, agent_ids: List[int], action_matrix: Optional[np.ndarray] ) -> None: if action_matrix is None: return for index, agent_id in enumerate(agent_ids): self.previous_action_dict[agent_id] = action_matrix[index, :] def retrieve_previous_action(self, agent_ids: List[int]) -> np.ndarray: action_matrix = np.zeros((len(agent_ids), self.num_branches), dtype=np.int) for index, agent_id in enumerate(agent_ids): if agent_id in self.previous_action_dict: action_matrix[index, :] = self.previous_action_dict[agent_id] return action_matrix def remove_previous_action(self, agent_ids): for agent_id in agent_ids: if agent_id in self.previous_action_dict: self.previous_action_dict.pop(agent_id) def get_current_step(self): """ Gets current model step. :return: current model step. """ step = self.sess.run(self.model.global_step) return step def increment_step(self, n_steps): """ Increments model step. """ out_dict = { "global_step": self.model.global_step, "increment_step": self.model.increment_step, } feed_dict = {self.model.steps_to_increment: n_steps} return self.sess.run(out_dict, feed_dict=feed_dict)["global_step"] def get_inference_vars(self): """ :return:list of inference var names """ return list(self.inference_dict.keys()) def get_update_vars(self): """ :return:list of update var names """ return list(self.update_dict.keys()) def save_model(self, steps): """ Saves the model :param steps: The number of steps the model was trained for :return: """ with self.graph.as_default(): last_checkpoint = self.model_path + "/model-" + str(steps) + ".cptk" self.saver.save(self.sess, last_checkpoint) tf.train.write_graph( self.graph, self.model_path, "raw_graph_def.pb", as_text=False ) def export_model(self): """ Exports latest saved model to .nn format for Unity embedding. """ with self.graph.as_default(): target_nodes = ",".join(self._process_graph()) graph_def = self.graph.as_graph_def() output_graph_def = graph_util.convert_variables_to_constants( self.sess, graph_def, target_nodes.replace(" ", "").split(",") ) frozen_graph_def_path = self.model_path + "/frozen_graph_def.pb" with gfile.GFile(frozen_graph_def_path, "wb") as f: f.write(output_graph_def.SerializeToString()) tf2bc.convert(frozen_graph_def_path, self.model_path + ".nn") logger.info("Exported " + self.model_path + ".nn file") def _process_graph(self): """ Gets the list of the output nodes present in the graph for inference :return: list of node names """ all_nodes = [x.name for x in self.graph.as_graph_def().node] nodes = [x for x in all_nodes if x in self.possible_output_nodes] logger.info("List of nodes to export for brain :" + self.brain.brain_name) for n in nodes: logger.info("\t" + n) return nodes def update_normalization(self, vector_obs: np.ndarray) -> None: """ If this policy normalizes vector observations, this will update the norm values in the graph. :param vector_obs: The vector observations to add to the running estimate of the distribution. """ if self.use_vec_obs and self.normalize: self.sess.run( self.model.update_normalization, feed_dict={self.model.vector_in: vector_obs}, ) @property def vis_obs_size(self): return self.model.vis_obs_size @property def vec_obs_size(self): return self.model.vec_obs_size @property def use_vis_obs(self): return self.model.vis_obs_size > 0 @property def use_vec_obs(self): return self.model.vec_obs_size > 0