# Copyright (c) 2018 PaddlePaddle Authors. All Rights Reserved. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. import gym import numpy as np import os import queue import time import threading import parl from atari_model import AtariModel from atari_agent import AtariAgent from parl.env.atari_wrappers import wrap_deepmind from parl.utils import logger, tensorboard, get_gpu_count from parl.utils.scheduler import PiecewiseScheduler from parl.utils.time_stat import TimeStat from parl.utils.window_stat import WindowStat from parl.utils import machine_info from actor import Actor class Learner(object): def __init__(self, config): self.config = config self.sample_data_queue = queue.Queue( maxsize=config['sample_queue_max_size']) #=========== Create Agent ========== env = gym.make(config['env_name']) env = wrap_deepmind(env, dim=config['env_dim'], obs_format='NCHW') obs_shape = env.observation_space.shape act_dim = env.action_space.n model = AtariModel(act_dim) algorithm = parl.algorithms.IMPALA( model, sample_batch_steps=self.config['sample_batch_steps'], gamma=self.config['gamma'], vf_loss_coeff=self.config['vf_loss_coeff'], clip_rho_threshold=self.config['clip_rho_threshold'], clip_pg_rho_threshold=self.config['clip_pg_rho_threshold']) self.agent = AtariAgent(algorithm, obs_shape, act_dim, self.learn_data_provider) if machine_info.is_gpu_available(): assert get_gpu_count() == 1, 'Only support training in single GPU,\ Please set environment variable: `export CUDA_VISIBLE_DEVICES=[GPU_ID_TO_USE]` .' self.cache_params = self.agent.get_weights() self.params_lock = threading.Lock() self.params_updated = False self.cache_params_sent_cnt = 0 self.total_params_sync = 0 #========== Learner ========== self.lr, self.entropy_coeff = None, None self.lr_scheduler = PiecewiseScheduler(config['lr_scheduler']) self.entropy_coeff_scheduler = PiecewiseScheduler( config['entropy_coeff_scheduler']) self.total_loss_stat = WindowStat(100) self.pi_loss_stat = WindowStat(100) self.vf_loss_stat = WindowStat(100) self.entropy_stat = WindowStat(100) self.kl_stat = WindowStat(100) self.learn_time_stat = TimeStat(100) self.start_time = None self.learn_thread = threading.Thread(target=self.run_learn) self.learn_thread.setDaemon(True) self.learn_thread.start() #========== Remote Actor =========== self.remote_count = 0 self.batch_buffer = [] self.remote_metrics_queue = queue.Queue() self.sample_total_steps = 0 self.create_actors() def learn_data_provider(self): """ Data generator for fluid.layers.py_reader """ while True: sample_data = self.sample_data_queue.get() self.sample_total_steps += sample_data['obs'].shape[0] self.batch_buffer.append(sample_data) buffer_size = sum( [data['obs'].shape[0] for data in self.batch_buffer]) if buffer_size >= self.config['train_batch_size']: batch = {} for key in self.batch_buffer[0].keys(): batch[key] = np.concatenate( [data[key] for data in self.batch_buffer]) self.batch_buffer = [] obs_np = batch['obs'].astype('float32') actions_np = batch['actions'].astype('int64') behaviour_logits_np = batch['behaviour_logits'].astype( 'float32') rewards_np = batch['rewards'].astype('float32') dones_np = batch['dones'].astype('float32') self.lr = self.lr_scheduler.step() self.entropy_coeff = self.entropy_coeff_scheduler.step() yield [ obs_np, actions_np, behaviour_logits_np, rewards_np, dones_np, np.float32(self.lr), np.float32(self.entropy_coeff) ] def run_learn(self): """ Learn loop """ while True: with self.learn_time_stat: total_loss, pi_loss, vf_loss, entropy, kl = self.agent.learn() self.params_updated = True self.total_loss_stat.add(total_loss) self.pi_loss_stat.add(pi_loss) self.vf_loss_stat.add(vf_loss) self.entropy_stat.add(entropy) self.kl_stat.add(kl) def create_actors(self): """ Connect to the cluster and start sampling of the remote actor. """ parl.connect(self.config['master_address']) logger.info('Waiting for {} remote actors to connect.'.format( self.config['actor_num'])) for i in range(self.config['actor_num']): self.remote_count += 1 logger.info('Remote actor count: {}'.format(self.remote_count)) if self.start_time is None: self.start_time = time.time() remote_thread = threading.Thread(target=self.run_remote_sample) remote_thread.setDaemon(True) remote_thread.start() def run_remote_sample(self): """ Sample data from remote actor and update parameters of remote actor. """ remote_actor = Actor(self.config) cnt = 0 remote_actor.set_weights(self.cache_params) while True: batch = remote_actor.sample() self.sample_data_queue.put(batch) cnt += 1 if cnt % self.config['get_remote_metrics_interval'] == 0: metrics = remote_actor.get_metrics() if metrics: self.remote_metrics_queue.put(metrics) self.params_lock.acquire() if self.params_updated and self.cache_params_sent_cnt >= self.config[ 'params_broadcast_interval']: self.params_updated = False self.cache_params = self.agent.get_weights() self.cache_params_sent_cnt = 0 self.cache_params_sent_cnt += 1 self.total_params_sync += 1 self.params_lock.release() remote_actor.set_weights(self.cache_params) def log_metrics(self): """ Log metrics of learner and actors """ if self.start_time is None: return metrics = [] while True: try: metric = self.remote_metrics_queue.get_nowait() metrics.append(metric) except queue.Empty: break episode_rewards, episode_steps = [], [] for x in metrics: episode_rewards.extend(x['episode_rewards']) episode_steps.extend(x['episode_steps']) max_episode_rewards, mean_episode_rewards, min_episode_rewards, \ max_episode_steps, mean_episode_steps, min_episode_steps =\ None, None, None, None, None, None if episode_rewards: mean_episode_rewards = np.mean(np.array(episode_rewards).flatten()) max_episode_rewards = np.max(np.array(episode_rewards).flatten()) min_episode_rewards = np.min(np.array(episode_rewards).flatten()) mean_episode_steps = np.mean(np.array(episode_steps).flatten()) max_episode_steps = np.max(np.array(episode_steps).flatten()) min_episode_steps = np.min(np.array(episode_steps).flatten()) metric = { 'Sample steps': self.sample_total_steps, 'max_episode_rewards': max_episode_rewards, 'mean_episode_rewards': mean_episode_rewards, 'min_episode_rewards': min_episode_rewards, 'max_episode_steps': max_episode_steps, 'mean_episode_steps': mean_episode_steps, 'min_episode_steps': min_episode_steps, 'sample_queue_size': self.sample_data_queue.qsize(), 'total_params_sync': self.total_params_sync, 'cache_params_sent_cnt': self.cache_params_sent_cnt, 'total_loss': self.total_loss_stat.mean, 'pi_loss': self.pi_loss_stat.mean, 'vf_loss': self.vf_loss_stat.mean, 'entropy': self.entropy_stat.mean, 'kl': self.kl_stat.mean, 'learn_time_s': self.learn_time_stat.mean, 'elapsed_time_s': int(time.time() - self.start_time), 'lr': self.lr, 'entropy_coeff': self.entropy_coeff, } for key, value in metric.items(): if value is not None: tensorboard.add_scalar(key, value, self.sample_total_steps) logger.info(metric) if __name__ == '__main__': from impala_config import config learner = Learner(config) assert config['log_metrics_interval_s'] > 0 while True: time.sleep(config['log_metrics_interval_s']) learner.log_metrics()