hot update Double DQN
This commit is contained in:
johnjim0816
@@ -9,130 +9,122 @@ import torch
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import datetime
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import numpy as np
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import argparse
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from common.utils import save_results,all_seed
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from common.utils import plot_rewards,save_args
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from common.utils import all_seed
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from common.models import MLP
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from common.memories import ReplayBuffer
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from common.launcher import Launcher
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from envs.register import register_env
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from dqn import DQN
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class Main(Launcher):
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def get_args(self):
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""" hyperparameters
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"""
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curr_time = datetime.datetime.now().strftime("%Y%m%d-%H%M%S") # obtain current time
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parser = argparse.ArgumentParser(description="hyperparameters")
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parser.add_argument('--algo_name',default='DQN',type=str,help="name of algorithm")
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parser.add_argument('--env_name',default='CartPole-v0',type=str,help="name of environment")
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parser.add_argument('--train_eps',default=200,type=int,help="episodes of training")
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parser.add_argument('--test_eps',default=20,type=int,help="episodes of testing")
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parser.add_argument('--ep_max_steps',default = 100000,type=int,help="steps per episode, much larger value can simulate infinite steps")
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parser.add_argument('--gamma',default=0.95,type=float,help="discounted factor")
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parser.add_argument('--epsilon_start',default=0.95,type=float,help="initial value of epsilon")
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parser.add_argument('--epsilon_end',default=0.01,type=float,help="final value of epsilon")
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parser.add_argument('--epsilon_decay',default=500,type=int,help="decay rate of epsilon, the higher value, the slower decay")
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parser.add_argument('--lr',default=0.0001,type=float,help="learning rate")
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parser.add_argument('--memory_capacity',default=100000,type=int,help="memory capacity")
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parser.add_argument('--batch_size',default=64,type=int)
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parser.add_argument('--target_update',default=4,type=int)
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parser.add_argument('--hidden_dim',default=256,type=int)
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parser.add_argument('--device',default='cpu',type=str,help="cpu or cuda")
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parser.add_argument('--seed',default=10,type=int,help="seed")
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parser.add_argument('--show_fig',default=False,type=bool,help="if show figure or not")
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parser.add_argument('--save_fig',default=True,type=bool,help="if save figure or not")
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# please manually change the following args in this script if you want
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parser.add_argument('--result_path',default=curr_path + "/outputs/" + parser.parse_args().env_name + \
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'/' + curr_time + '/results' )
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parser.add_argument('--model_path',default=curr_path + "/outputs/" + parser.parse_args().env_name + \
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'/' + curr_time + '/models' )
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args = parser.parse_args()
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args = {**vars(args)} # type(dict)
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return args
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def get_args():
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""" hyperparameters
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"""
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curr_time = datetime.datetime.now().strftime("%Y%m%d-%H%M%S") # obtain current time
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parser = argparse.ArgumentParser(description="hyperparameters")
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parser.add_argument('--algo_name',default='DQN',type=str,help="name of algorithm")
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parser.add_argument('--env_name',default='CartPole-v0',type=str,help="name of environment")
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parser.add_argument('--train_eps',default=200,type=int,help="episodes of training")
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parser.add_argument('--test_eps',default=20,type=int,help="episodes of testing")
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parser.add_argument('--ep_max_steps',default = 100000,type=int,help="steps per episode, much larger value can simulate infinite steps")
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parser.add_argument('--gamma',default=0.95,type=float,help="discounted factor")
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parser.add_argument('--epsilon_start',default=0.95,type=float,help="initial value of epsilon")
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parser.add_argument('--epsilon_end',default=0.01,type=float,help="final value of epsilon")
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parser.add_argument('--epsilon_decay',default=500,type=int,help="decay rate of epsilon, the higher value, the slower decay")
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parser.add_argument('--lr',default=0.0001,type=float,help="learning rate")
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parser.add_argument('--memory_capacity',default=100000,type=int,help="memory capacity")
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parser.add_argument('--batch_size',default=64,type=int)
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parser.add_argument('--target_update',default=4,type=int)
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parser.add_argument('--hidden_dim',default=256,type=int)
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parser.add_argument('--device',default='cpu',type=str,help="cpu or cuda")
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parser.add_argument('--seed',default=10,type=int,help="seed")
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parser.add_argument('--show_fig',default=False,type=bool,help="if show figure or not")
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parser.add_argument('--save_fig',default=True,type=bool,help="if save figure or not")
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# please manually change the following args in this script if you want
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parser.add_argument('--result_path',default=curr_path + "/outputs/" + parser.parse_args().env_name + \
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'/' + curr_time + '/results' )
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parser.add_argument('--model_path',default=curr_path + "/outputs/" + parser.parse_args().env_name + \
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'/' + curr_time + '/models' )
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args = parser.parse_args()
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args = {**vars(args)} # type(dict)
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return args
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def env_agent_config(cfg):
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''' create env and agent
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'''
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register_env(cfg['env_name'])
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env = gym.make(cfg['env_name'])
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if cfg['seed'] !=0: # set random seed
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all_seed(env,seed=cfg["seed"])
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try: # state dimension
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n_states = env.observation_space.n # print(hasattr(env.observation_space, 'n'))
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except AttributeError:
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n_states = env.observation_space.shape[0] # print(hasattr(env.observation_space, 'shape'))
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n_actions = env.action_space.n # action dimension
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print(f"n_states: {n_states}, n_actions: {n_actions}")
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cfg.update({"n_states":n_states,"n_actions":n_actions}) # update to cfg paramters
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model = MLP(n_states,n_actions,hidden_dim=cfg["hidden_dim"])
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memory = ReplayBuffer(cfg["memory_capacity"]) # replay buffer
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agent = DQN(model,memory,cfg) # create agent
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return env, agent
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def env_agent_config(cfg):
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''' create env and agent
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'''
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env = gym.make(cfg['env_name']) # create env
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if cfg['seed'] !=0: # set random seed
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all_seed(env,seed=cfg["seed"])
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n_states = env.observation_space.shape[0] # state dimension
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n_actions = env.action_space.n # action dimension
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print(f"n_states: {n_states}, n_actions: {n_actions}")
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cfg.update({"n_states":n_states,"n_actions":n_actions}) # update to cfg paramters
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model = MLP(n_states,n_actions,hidden_dim=cfg["hidden_dim"])
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memory = ReplayBuffer(cfg["memory_capacity"]) # replay buffer
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agent = DQN(model,memory,cfg) # create agent
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return env, agent
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def train(cfg, env, agent):
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''' 训练
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'''
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print("Start training!")
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print(f"Env: {cfg['env_name']}, Algorithm: {cfg['algo_name']}, Device: {cfg['device']}")
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rewards = [] # record rewards for all episodes
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steps = []
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for i_ep in range(cfg["train_eps"]):
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ep_reward = 0 # reward per episode
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ep_step = 0
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state = env.reset() # reset and obtain initial state
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for _ in range(cfg['ep_max_steps']):
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ep_step += 1
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action = agent.sample_action(state) # sample action
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next_state, reward, done, _ = env.step(action) # update env and return transitions
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agent.memory.push(state, action, reward,
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next_state, done) # save transitions
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state = next_state # update next state for env
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agent.update() # update agent
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ep_reward += reward #
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if done:
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break
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if (i_ep + 1) % cfg["target_update"] == 0: # target net update, target_update means "C" in pseucodes
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agent.target_net.load_state_dict(agent.policy_net.state_dict())
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steps.append(ep_step)
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rewards.append(ep_reward)
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if (i_ep + 1) % 10 == 0:
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print(f'Episode: {i_ep+1}/{cfg["train_eps"]}, Reward: {ep_reward:.2f}: Epislon: {agent.epsilon:.3f}')
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print("Finish training!")
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env.close()
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res_dic = {'episodes':range(len(rewards)),'rewards':rewards,'steps':steps}
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return res_dic
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def train(cfg, env, agent):
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''' 训练
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'''
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print("Start training!")
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print(f"Env: {cfg['env_name']}, Algorithm: {cfg['algo_name']}, Device: {cfg['device']}")
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rewards = [] # record rewards for all episodes
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steps = []
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for i_ep in range(cfg["train_eps"]):
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ep_reward = 0 # reward per episode
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ep_step = 0
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state = env.reset() # reset and obtain initial state
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for _ in range(cfg['ep_max_steps']):
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ep_step += 1
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action = agent.sample_action(state) # sample action
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next_state, reward, done, _ = env.step(action) # update env and return transitions
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agent.memory.push(state, action, reward,
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next_state, done) # save transitions
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state = next_state # update next state for env
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agent.update() # update agent
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ep_reward += reward #
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if done:
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break
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if (i_ep + 1) % cfg["target_update"] == 0: # target net update, target_update means "C" in pseucodes
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agent.target_net.load_state_dict(agent.policy_net.state_dict())
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steps.append(ep_step)
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rewards.append(ep_reward)
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if (i_ep + 1) % 10 == 0:
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print(f'Episode: {i_ep+1}/{cfg["train_eps"]}, Reward: {ep_reward:.2f}: Epislon: {agent.epsilon:.3f}')
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print("Finish training!")
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env.close()
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res_dic = {'episodes':range(len(rewards)),'rewards':rewards,'steps':steps}
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return res_dic
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def test(cfg, env, agent):
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print("Start testing!")
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print(f"Env: {cfg['env_name']}, Algorithm: {cfg['algo_name']}, Device: {cfg['device']}")
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rewards = [] # record rewards for all episodes
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steps = []
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for i_ep in range(cfg['test_eps']):
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ep_reward = 0 # reward per episode
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ep_step = 0
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state = env.reset() # reset and obtain initial state
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for _ in range(cfg['ep_max_steps']):
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ep_step+=1
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action = agent.predict_action(state) # predict action
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next_state, reward, done, _ = env.step(action)
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state = next_state
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ep_reward += reward
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if done:
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break
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steps.append(ep_step)
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rewards.append(ep_reward)
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print(f"Episode: {i_ep+1}/{cfg['test_eps']},Reward: {ep_reward:.2f}")
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print("Finish testing!")
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env.close()
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return {'episodes':range(len(rewards)),'rewards':rewards,'steps':steps}
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def test(cfg, env, agent):
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print("Start testing!")
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print(f"Env: {cfg['env_name']}, Algorithm: {cfg['algo_name']}, Device: {cfg['device']}")
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rewards = [] # record rewards for all episodes
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steps = []
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for i_ep in range(cfg['test_eps']):
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ep_reward = 0 # reward per episode
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ep_step = 0
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state = env.reset() # reset and obtain initial state
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for _ in range(cfg['ep_max_steps']):
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ep_step+=1
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action = agent.predict_action(state) # predict action
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next_state, reward, done, _ = env.step(action)
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state = next_state
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ep_reward += reward
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if done:
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break
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steps.append(ep_step)
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rewards.append(ep_reward)
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print(f"Episode: {i_ep+1}/{cfg['test_eps']},Reward: {ep_reward:.2f}")
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print("Finish testing!")
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env.close()
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return {'episodes':range(len(rewards)),'rewards':rewards,'steps':steps}
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if __name__ == "__main__":
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cfg = get_args()
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# training
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env, agent = env_agent_config(cfg)
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res_dic = train(cfg, env, agent)
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save_args(cfg,path = cfg['result_path']) # save parameters
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agent.save_model(path = cfg['model_path']) # save models
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save_results(res_dic, tag = 'train', path = cfg['result_path']) # save results
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plot_rewards(res_dic['rewards'], cfg, path = cfg['result_path'],tag = "train") # plot results
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# testing
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env, agent = env_agent_config(cfg) # create new env for testing, sometimes can ignore this step
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agent.load_model(path = cfg['model_path']) # load model
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res_dic = test(cfg, env, agent)
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save_results(res_dic, tag='test',
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path = cfg['result_path'])
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plot_rewards(res_dic['rewards'], cfg, path = cfg['result_path'],tag = "test")
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main = Main()
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main.run()
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