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386 行
19 KiB
386 行
19 KiB
# # Unity ML-Agents Toolkit
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# ## ML-Agent Learning (PPO)
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# Contains an implementation of PPO as described (https://arxiv.org/abs/1707.06347).
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import logging
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import os
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from collections import deque
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import numpy as np
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import tensorflow as tf
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from mlagents.envs import AllBrainInfo, BrainInfo
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from mlagents.trainers.buffer import Buffer
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from mlagents.trainers.ppo.policy import PPOPolicy
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from mlagents.trainers.trainer import Trainer
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logger = logging.getLogger("mlagents.trainers")
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class PPOTrainer(Trainer):
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"""The PPOTrainer is an implementation of the PPO algorithm."""
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def __init__(self, brain, reward_buff_cap, trainer_parameters, training, load, seed, run_id):
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"""
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Responsible for collecting experiences and training PPO model.
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:param trainer_parameters: The parameters for the trainer (dictionary).
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:param training: Whether the trainer is set for training.
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:param load: Whether the model should be loaded.
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:param seed: The seed the model will be initialized with
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:param run_id: The The identifier of the current run
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"""
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super(PPOTrainer, self).__init__(brain, trainer_parameters, training, run_id)
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self.param_keys = ['batch_size', 'beta', 'buffer_size', 'epsilon', 'gamma', 'hidden_units', 'lambd',
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'learning_rate', 'max_steps', 'normalize', 'num_epoch', 'num_layers',
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'time_horizon', 'sequence_length', 'summary_freq', 'use_recurrent',
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'summary_path', 'memory_size', 'use_curiosity', 'curiosity_strength',
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'curiosity_enc_size', 'model_path']
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self.check_param_keys()
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self.use_curiosity = bool(trainer_parameters['use_curiosity'])
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self.step = 0
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self.policy = PPOPolicy(seed, brain, trainer_parameters,
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self.is_training, load)
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stats = {'Environment/Cumulative Reward': [], 'Environment/Episode Length': [],
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'Policy/Value Estimate': [], 'Policy/Entropy': [], 'Losses/Value Loss': [],
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'Losses/Policy Loss': [], 'Policy/Learning Rate': []}
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if self.use_curiosity:
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stats['Losses/Forward Loss'] = []
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stats['Losses/Inverse Loss'] = []
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stats['Policy/Curiosity Reward'] = []
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self.intrinsic_rewards = {}
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self.stats = stats
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self.training_buffer = Buffer()
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self.cumulative_rewards = {}
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self._reward_buffer = deque(maxlen=reward_buff_cap)
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self.episode_steps = {}
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self.summary_path = trainer_parameters['summary_path']
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if not os.path.exists(self.summary_path):
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os.makedirs(self.summary_path)
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self.summary_writer = tf.summary.FileWriter(self.summary_path)
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def __str__(self):
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return '''Hyperparameters for the PPO Trainer of brain {0}: \n{1}'''.format(
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self.brain_name, '\n'.join(['\t{0}:\t{1}'.format(x, self.trainer_parameters[x]) for x in self.param_keys]))
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@property
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def parameters(self):
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"""
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Returns the trainer parameters of the trainer.
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"""
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return self.trainer_parameters
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@property
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def get_max_steps(self):
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"""
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Returns the maximum number of steps. Is used to know when the trainer should be stopped.
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:return: The maximum number of steps of the trainer
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"""
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return float(self.trainer_parameters['max_steps'])
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@property
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def get_step(self):
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"""
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Returns the number of steps the trainer has performed
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:return: the step count of the trainer
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"""
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return self.step
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@property
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def reward_buffer(self):
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"""
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Returns the reward buffer. The reward buffer contains the cumulative
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rewards of the most recent episodes completed by agents using this
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trainer.
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:return: the reward buffer.
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"""
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return self._reward_buffer
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def increment_step_and_update_last_reward(self):
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"""
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Increment the step count of the trainer and Updates the last reward
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"""
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if len(self.stats['Environment/Cumulative Reward']) > 0:
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mean_reward = np.mean(self.stats['Environment/Cumulative Reward'])
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self.policy.update_reward(mean_reward)
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self.policy.increment_step()
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self.step = self.policy.get_current_step()
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def take_action(self, all_brain_info: AllBrainInfo):
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"""
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Decides actions given observations information, and takes them in environment.
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:param all_brain_info: A dictionary of brain names and BrainInfo from environment.
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:return: a tuple containing action, memories, values and an object
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to be passed to add experiences
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"""
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curr_brain_info = all_brain_info[self.brain_name]
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if len(curr_brain_info.agents) == 0:
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return [], [], [], None, None
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run_out = self.policy.evaluate(curr_brain_info)
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self.stats['Policy/Value Estimate'].append(run_out['value'].mean())
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self.stats['Policy/Entropy'].append(run_out['entropy'].mean())
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self.stats['Policy/Learning Rate'].append(run_out['learning_rate'])
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if self.policy.use_recurrent:
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return run_out['action'], run_out['memory_out'], None, \
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run_out['value'], run_out
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else:
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return run_out['action'], None, None, run_out['value'], run_out
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def construct_curr_info(self, next_info: BrainInfo) -> BrainInfo:
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"""
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Constructs a BrainInfo which contains the most recent previous experiences for all agents info
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which correspond to the agents in a provided next_info.
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:BrainInfo next_info: A t+1 BrainInfo.
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:return: curr_info: Reconstructed BrainInfo to match agents of next_info.
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"""
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visual_observations = [[]]
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vector_observations = []
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text_observations = []
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memories = []
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rewards = []
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local_dones = []
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max_reacheds = []
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agents = []
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prev_vector_actions = []
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prev_text_actions = []
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for agent_id in next_info.agents:
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agent_brain_info = self.training_buffer[agent_id].last_brain_info
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if agent_brain_info is None:
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agent_brain_info = next_info
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agent_index = agent_brain_info.agents.index(agent_id)
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for i in range(len(next_info.visual_observations)):
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visual_observations[i].append(agent_brain_info.visual_observations[i][agent_index])
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vector_observations.append(agent_brain_info.vector_observations[agent_index])
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text_observations.append(agent_brain_info.text_observations[agent_index])
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if self.policy.use_recurrent:
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if len(agent_brain_info.memories > 0):
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memories.append(agent_brain_info.memories[agent_index])
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else:
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memories.append(self.policy.make_empty_memory(1))
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rewards.append(agent_brain_info.rewards[agent_index])
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local_dones.append(agent_brain_info.local_done[agent_index])
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max_reacheds.append(agent_brain_info.max_reached[agent_index])
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agents.append(agent_brain_info.agents[agent_index])
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prev_vector_actions.append(agent_brain_info.previous_vector_actions[agent_index])
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prev_text_actions.append(agent_brain_info.previous_text_actions[agent_index])
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if self.policy.use_recurrent:
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memories = np.vstack(memories)
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curr_info = BrainInfo(visual_observations, vector_observations, text_observations,
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memories, rewards, agents, local_dones, prev_vector_actions,
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prev_text_actions, max_reacheds)
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return curr_info
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def add_experiences(self, curr_all_info: AllBrainInfo, next_all_info: AllBrainInfo, take_action_outputs):
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"""
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Adds experiences to each agent's experience history.
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:param curr_all_info: Dictionary of all current brains and corresponding BrainInfo.
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:param next_all_info: Dictionary of all current brains and corresponding BrainInfo.
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:param take_action_outputs: The outputs of the take action method.
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"""
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curr_info = curr_all_info[self.brain_name]
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next_info = next_all_info[self.brain_name]
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for agent_id in curr_info.agents:
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self.training_buffer[agent_id].last_brain_info = curr_info
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self.training_buffer[agent_id].last_take_action_outputs = take_action_outputs
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if curr_info.agents != next_info.agents:
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curr_to_use = self.construct_curr_info(next_info)
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else:
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curr_to_use = curr_info
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intrinsic_rewards = self.policy.get_intrinsic_rewards(curr_to_use, next_info)
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for agent_id in next_info.agents:
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stored_info = self.training_buffer[agent_id].last_brain_info
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stored_take_action_outputs = self.training_buffer[agent_id].last_take_action_outputs
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if stored_info is not None:
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idx = stored_info.agents.index(agent_id)
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next_idx = next_info.agents.index(agent_id)
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if not stored_info.local_done[idx]:
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for i, _ in enumerate(stored_info.visual_observations):
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self.training_buffer[agent_id]['visual_obs%d' % i].append(
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stored_info.visual_observations[i][idx])
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self.training_buffer[agent_id]['next_visual_obs%d' % i].append(
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next_info.visual_observations[i][next_idx])
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if self.policy.use_vec_obs:
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self.training_buffer[agent_id]['vector_obs'].append(stored_info.vector_observations[idx])
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self.training_buffer[agent_id]['next_vector_in'].append(
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next_info.vector_observations[next_idx])
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if self.policy.use_recurrent:
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if stored_info.memories.shape[1] == 0:
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stored_info.memories = np.zeros((len(stored_info.agents), self.policy.m_size))
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self.training_buffer[agent_id]['memory'].append(stored_info.memories[idx])
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actions = stored_take_action_outputs['action']
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if self.policy.use_continuous_act:
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actions_pre = stored_take_action_outputs['pre_action']
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self.training_buffer[agent_id]['actions_pre'].append(actions_pre[idx])
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epsilons = stored_take_action_outputs['random_normal_epsilon']
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self.training_buffer[agent_id]['random_normal_epsilon'].append(
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epsilons[idx])
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else:
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self.training_buffer[agent_id]['action_mask'].append(
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stored_info.action_masks[idx])
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a_dist = stored_take_action_outputs['log_probs']
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value = stored_take_action_outputs['value']
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self.training_buffer[agent_id]['actions'].append(actions[idx])
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self.training_buffer[agent_id]['prev_action'].append(stored_info.previous_vector_actions[idx])
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self.training_buffer[agent_id]['masks'].append(1.0)
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if self.use_curiosity:
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self.training_buffer[agent_id]['rewards'].append(next_info.rewards[next_idx] +
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intrinsic_rewards[next_idx])
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else:
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self.training_buffer[agent_id]['rewards'].append(next_info.rewards[next_idx])
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self.training_buffer[agent_id]['action_probs'].append(a_dist[idx])
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self.training_buffer[agent_id]['value_estimates'].append(value[idx][0])
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if agent_id not in self.cumulative_rewards:
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self.cumulative_rewards[agent_id] = 0
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self.cumulative_rewards[agent_id] += next_info.rewards[next_idx]
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if self.use_curiosity:
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if agent_id not in self.intrinsic_rewards:
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self.intrinsic_rewards[agent_id] = 0
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self.intrinsic_rewards[agent_id] += intrinsic_rewards[next_idx]
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if not next_info.local_done[next_idx]:
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if agent_id not in self.episode_steps:
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self.episode_steps[agent_id] = 0
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self.episode_steps[agent_id] += 1
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def process_experiences(self, current_info: AllBrainInfo, new_info: AllBrainInfo):
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"""
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Checks agent histories for processing condition, and processes them as necessary.
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Processing involves calculating value and advantage targets for model updating step.
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:param current_info: Dictionary of all current brains and corresponding BrainInfo.
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:param new_info: Dictionary of all next brains and corresponding BrainInfo.
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"""
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info = new_info[self.brain_name]
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for l in range(len(info.agents)):
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agent_actions = self.training_buffer[info.agents[l]]['actions']
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if ((info.local_done[l] or len(agent_actions) > self.trainer_parameters['time_horizon'])
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and len(agent_actions) > 0):
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agent_id = info.agents[l]
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if info.local_done[l] and not info.max_reached[l]:
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value_next = 0.0
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else:
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if info.max_reached[l]:
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bootstrapping_info = self.training_buffer[agent_id].last_brain_info
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idx = bootstrapping_info.agents.index(agent_id)
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else:
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bootstrapping_info = info
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idx = l
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value_next = self.policy.get_value_estimate(bootstrapping_info, idx)
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self.training_buffer[agent_id]['advantages'].set(
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get_gae(
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rewards=self.training_buffer[agent_id]['rewards'].get_batch(),
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value_estimates=self.training_buffer[agent_id]['value_estimates'].get_batch(),
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value_next=value_next,
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gamma=self.trainer_parameters['gamma'],
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lambd=self.trainer_parameters['lambd']))
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self.training_buffer[agent_id]['discounted_returns'].set(
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self.training_buffer[agent_id]['advantages'].get_batch()
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+ self.training_buffer[agent_id]['value_estimates'].get_batch())
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self.training_buffer.append_update_buffer(agent_id, batch_size=None,
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training_length=self.policy.sequence_length)
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self.training_buffer[agent_id].reset_agent()
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if info.local_done[l]:
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self.stats['Environment/Cumulative Reward'].append(
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self.cumulative_rewards.get(agent_id, 0))
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self.reward_buffer.appendleft(self.cumulative_rewards.get(agent_id, 0))
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self.stats['Environment/Episode Length'].append(
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self.episode_steps.get(agent_id, 0))
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self.cumulative_rewards[agent_id] = 0
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self.episode_steps[agent_id] = 0
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if self.use_curiosity:
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self.stats['Policy/Curiosity Reward'].append(
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self.intrinsic_rewards.get(agent_id, 0))
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self.intrinsic_rewards[agent_id] = 0
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def end_episode(self):
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"""
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A signal that the Episode has ended. The buffer must be reset.
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Get only called when the academy resets.
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"""
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self.training_buffer.reset_local_buffers()
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for agent_id in self.cumulative_rewards:
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self.cumulative_rewards[agent_id] = 0
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for agent_id in self.episode_steps:
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self.episode_steps[agent_id] = 0
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if self.use_curiosity:
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for agent_id in self.intrinsic_rewards:
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self.intrinsic_rewards[agent_id] = 0
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def is_ready_update(self):
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"""
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Returns whether or not the trainer has enough elements to run update model
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:return: A boolean corresponding to whether or not update_model() can be run
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"""
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size_of_buffer = len(self.training_buffer.update_buffer['actions'])
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return size_of_buffer > max(int(self.trainer_parameters['buffer_size'] / self.policy.sequence_length), 1)
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def update_policy(self):
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"""
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Uses demonstration_buffer to update the policy.
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"""
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n_sequences = max(int(self.trainer_parameters['batch_size'] / self.policy.sequence_length), 1)
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value_total, policy_total, forward_total, inverse_total = [], [], [], []
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advantages = self.training_buffer.update_buffer['advantages'].get_batch()
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self.training_buffer.update_buffer['advantages'].set(
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(advantages - advantages.mean()) / (advantages.std() + 1e-10))
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num_epoch = self.trainer_parameters['num_epoch']
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for k in range(num_epoch):
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self.training_buffer.update_buffer.shuffle()
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buffer = self.training_buffer.update_buffer
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for l in range(len(self.training_buffer.update_buffer['actions']) // n_sequences):
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start = l * n_sequences
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end = (l + 1) * n_sequences
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run_out = self.policy.update(buffer.make_mini_batch(start, end), n_sequences)
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value_total.append(run_out['value_loss'])
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policy_total.append(np.abs(run_out['policy_loss']))
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if self.use_curiosity:
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inverse_total.append(run_out['inverse_loss'])
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forward_total.append(run_out['forward_loss'])
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self.stats['Losses/Value Loss'].append(np.mean(value_total))
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self.stats['Losses/Policy Loss'].append(np.mean(policy_total))
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if self.use_curiosity:
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self.stats['Losses/Forward Loss'].append(np.mean(forward_total))
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self.stats['Losses/Inverse Loss'].append(np.mean(inverse_total))
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self.training_buffer.reset_update_buffer()
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def discount_rewards(r, gamma=0.99, value_next=0.0):
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"""
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Computes discounted sum of future rewards for use in updating value estimate.
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:param r: List of rewards.
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:param gamma: Discount factor.
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:param value_next: T+1 value estimate for returns calculation.
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:return: discounted sum of future rewards as list.
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"""
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discounted_r = np.zeros_like(r)
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running_add = value_next
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for t in reversed(range(0, r.size)):
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running_add = running_add * gamma + r[t]
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discounted_r[t] = running_add
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return discounted_r
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def get_gae(rewards, value_estimates, value_next=0.0, gamma=0.99, lambd=0.95):
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"""
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Computes generalized advantage estimate for use in updating policy.
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:param rewards: list of rewards for time-steps t to T.
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:param value_next: Value estimate for time-step T+1.
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:param value_estimates: list of value estimates for time-steps t to T.
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:param gamma: Discount factor.
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:param lambd: GAE weighing factor.
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:return: list of advantage estimates for time-steps t to T.
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"""
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value_estimates = np.asarray(value_estimates.tolist() + [value_next])
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delta_t = rewards + gamma * value_estimates[1:] - value_estimates[:-1]
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advantage = discount_rewards(r=delta_t, gamma=gamma * lambd)
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return advantage
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