def __init__(self, env, args):
self.env = env
# 用来在一个稀疏奖赏的环境上评估算法的好坏,胜利为1,失败为-1,其他普通的一步为0
'''
self.env_evaluate = StarCraft2Env(map_name=args.map,
step_mul=args.step_mul,
difficulty=args.difficulty,
game_version=args.game_version,
seed=args.seed,
replay_dir=args.replay_dir,
reward_sparse=True,
reward_scale=False)
'''
self.env_evaluate = MeetEnv()
if args.alg.find('commnet') > -1 or args.alg.find('g2anet') > -1: # communication agent
self.agents = CommAgents(args)
self.rolloutWorker = CommRolloutWorker(env, self.agents, args)
self.evaluateWorker = CommRolloutWorker(self.env_evaluate, self.agents, args)
else: # no communication agent
self.agents = Agents(args)
self.rolloutWorker = RolloutWorker(env, self.agents, args)
self.evaluateWorker = RolloutWorker(self.env_evaluate, self.agents, args)
if args.alg.find('coma') == -1 and args.alg.find('central_v') == -1 and args.alg.find('reinforce') == -1: # these 3 algorithms are on-poliy
self.buffer = ReplayBuffer(args)
self.args = args
# 用来保存plt和pkl
self.save_path = self.args.result_dir + '/' + args.alg + '/' + args.map
if not os.path.exists(self.save_path):
os.makedirs(self.save_path)
def __init__(self, env, args):
self.env = env
if args.alg.find('commnet') > -1 or args.alg.find(
'g2anet') > -1: # communication agent
self.agents = CommAgents(args)
self.rolloutWorker = CommRolloutWorker(env, self.agents, args)
else: # no communication agent
self.agents = Agents(args)
self.rolloutWorker = RolloutWorker(env, self.agents, args)
if args.learn and args.alg.find('coma') == -1 and args.alg.find(
'central_v') == -1 and args.alg.find(
'reinforce') == -1: # these 3 algorithms are on-poliy
if args.use_per:
self.buffer = PrioritizedReplayBuffer(args)
else:
self.buffer = ReplayBuffer(args)
self.args = args
self.win_rates = []
self.episode_rewards = []
# 用来保存plt和pkl
self.save_path = self.args.result_dir + '/' + args.map + '/'
if not os.path.exists(self.save_path):
os.makedirs(self.save_path)
self.file_name = self.save_path + str(args.env_name) + '_' + str(
args.n_agents) + '_' + str(args.map_size) + '_' + args.name_time
def __init__(self, env, args):
self.env = env
# 用来在一个稀疏奖赏的环境上评估算法的好坏,胜利为1,失败为-1,其他普通的一步为0
self.env_evaluate = StarCraft2Env(map_name=args.map,
step_mul=args.step_mul,
difficulty=args.difficulty,
game_version=args.game_version,
seed=args.seed,
replay_dir=args.replay_dir,
reward_sparse=True,
reward_scale=False)
if args.alg == 'commnet_coma':
self.agents = CommNetAgents(args)
self.rolloutWorker = CommNetRolloutWorker(env, self.agents, args)
self.evaluateWorker = CommNetRolloutWorker(self.env_evaluate,
self.agents, args)
else:
self.agents = Agents(args)
self.rolloutWorker = RolloutWorker(env, self.agents, args)
self.evaluateWorker = RolloutWorker(self.env_evaluate, self.agents,
args)
if args.alg != 'coma' and args.alg != 'commnet_coma':
self.buffer = ReplayBuffer(args)
self.args = args
# 用来保存plt和pkl
self.save_path = self.args.result_dir + '/' + args.alg + '/' + args.map
if not os.path.exists(self.save_path):
os.makedirs(self.save_path)
def __init__(self, curriculum, args, target_env):
self.target_env = target_env
self.curriculum = curriculum
if args.alg.find('commnet') > -1 or args.alg.find(
'g2anet') > -1: # communication agent
self.agents = CommAgents(args)
self.rolloutWorker = CommRolloutWorker(None, self.agents, args)
else: # no communication agent
self.agents = Agents(args)
self.rolloutWorker = RolloutWorker(None, self.agents, args)
if not args.evaluate and args.alg.find('coma') == -1 and args.alg.find(
'central_v') == -1 and args.alg.find(
'reinforce') == -1: # these 3 algorithms are on-poliy
self.buffer = None
self.args = args
self.win_rates = []
self.eval_episode_rewards = []
# 用来保存plt和pkl
self.save_path = args.save_path
if not os.path.exists(self.save_path):
os.makedirs(self.save_path)
self.train_rewards = []
self.ratios = []
self.historical_params = {}
self.switch = True # we will be switching to some task
self.patience = 20
self.writer: SummaryWriter = None
self.eval_envs = None
self.debug = False
def runner(env, args):
model_path = (Path('./models') / args.env_id / args.algo /
('run%i' % args.run_num))
if args.incremental is not None:
model_path = model_path / 'incremental' / ('model_ep%i.pt' %
args.incremental)
else:
model_path = model_path / 'model.pt'
agents = Agents(args)
agents.load(str(model_path))
ifi = 1 / args.fps # inter-frame interval
for ep_i in range(args.n_evaluate_episodes):
print("Episode %i of %i" % (ep_i + 1, args.n_evaluate_episodes))
obs = env.reset()
last_action = np.zeros((args.n_agents, args.n_actions))
agents.policy.init_hidden(1)
epsilon = 0
step = 0
if args.display or args.evaluate:
env.render('human')
while step < args.n_evaluate_steps:
calc_start = time.time()
obs = np.array(obs).reshape((args.n_agents, -1))
actions, actions_onehot = [], []
for agent_num in range(args.n_agents):
action = agents.select_action(obs[agent_num],
last_action[agent_num],
agent_num, epsilon,
args.evaluate)
action_onehot = np.zeros(args.n_actions)
action_onehot[action] = 1
actions.append(action)
actions_onehot.append(action_onehot)
last_action[agent_num] = action_onehot
obs, rewards, terminates, infos = env.step(actions_onehot)
if args.display or args.evaluate:
calc_end = time.time()
elapsed = calc_end - calc_start
if elapsed < ifi:
time.sleep(ifi - elapsed)
env.render('human')
step += 1
env.close()
def __init__(self, env, args):
self.env = env
self.agents = Agents(args)
self.rolloutWorker = RolloutWorker(env, self.agents, args)
if args.learn and args.alg.find('coma') == -1 and args.alg.find(
'central_v') == -1 and args.alg.find(
'reinforce') == -1: # these 3 algorithms are on-poliy
self.buffer = ReplayBuffer(args)
self.args = args
self.win_rates = []
self.episode_rewards = []
# 用来保存plt和pkl
self.save_path = self.args.result_dir + '/' + args.alg + '/' + args.map
if not os.path.exists(self.save_path):
os.makedirs(self.save_path)
def __init__(self, env, args):
self.env = env
self.agents = Agents(args)
self.rolloutWorker = RolloutWorker(env, self.agents, args)
self.buffer = ReplayBuffer(args)
self.args = args
self.epsilon = args.epsilon
# 用来在一个稀疏奖赏的环境上评估算法的好坏,胜利为1,失败为-1,其他普通的一步为0
self.env_evaluate = StarCraft2Env(map_name=args.map,
step_mul=args.step_mul,
difficulty=args.difficulty,
game_version=args.game_version,
seed=args.seed,
replay_dir=args.replay_dir,
reward_sparse=True,
reward_scale=False)
self.evaluateWorker = RolloutWorker(self.env_evaluate, self.agents,
args)
def __init__(self, env, args):
self.env = env
if args.alg.find('commnet') > -1 or args.alg.find(
'g2anet') > -1: # communication agent
self.agents = CommAgents(args)
self.rolloutWorker = CommRolloutWorker(env, self.agents, args)
else: # no communication agent
self.agents = Agents(args)
self.rolloutWorker = RolloutWorker(env, self.agents, args)
if not args.evaluate and args.alg.find('coma') == -1 and args.alg.find(
'central_v') == -1 and args.alg.find(
'reinforce') == -1: # these 3 algorithms are on-poliy
self.buffer = ReplayBuffer(args)
self.args = args
self.win_rates = []
self.episode_rewards = []
# 用来保存plt和pkl
self.save_path = self.args.result_dir + '/' + args.alg + '/' + args.map
if not os.path.exists(self.save_path):
os.makedirs(self.save_path)
class Runner:
def __init__(self, env, args):
self.env = env
# 用来在一个稀疏奖赏的环境上评估算法的好坏,胜利为1,失败为-1,其他普通的一步为0
'''
self.env_evaluate = StarCraft2Env(map_name=args.map,
step_mul=args.step_mul,
difficulty=args.difficulty,
game_version=args.game_version,
seed=args.seed,
replay_dir=args.replay_dir,
reward_sparse=True,
reward_scale=False)
'''
self.env_evaluate = MeetEnv()
if args.alg.find('commnet') > -1 or args.alg.find('g2anet') > -1: # communication agent
self.agents = CommAgents(args)
self.rolloutWorker = CommRolloutWorker(env, self.agents, args)
self.evaluateWorker = CommRolloutWorker(self.env_evaluate, self.agents, args)
else: # no communication agent
self.agents = Agents(args)
self.rolloutWorker = RolloutWorker(env, self.agents, args)
self.evaluateWorker = RolloutWorker(self.env_evaluate, self.agents, args)
if args.alg.find('coma') == -1 and args.alg.find('central_v') == -1 and args.alg.find('reinforce') == -1: # these 3 algorithms are on-poliy
self.buffer = ReplayBuffer(args)
self.args = args
# 用来保存plt和pkl
self.save_path = self.args.result_dir + '/' + args.alg + '/' + args.map
if not os.path.exists(self.save_path):
os.makedirs(self.save_path)
def run(self, num):
plt.figure()
plt.axis([0, self.args.n_epoch, 0, 100])
win_rates = []
episode_rewards = []
train_steps = 0
# print('Run {} start'.format(num))
for epoch in range(self.args.n_epoch):
print('Run {}, train epoch {}'.format(num, epoch))
if epoch % self.args.evaluate_cycle == 0:
win_rate, episode_reward = self.evaluate()
# print('win_rate is ', win_rate)
win_rates.append(win_rate)
episode_rewards.append(episode_reward)
plt.cla()
plt.subplot(2, 1, 1)
plt.plot(range(len(win_rates)), win_rates)
plt.xlabel('epoch*{}'.format(self.args.evaluate_cycle))
plt.ylabel('win_rate')
plt.subplot(2, 1, 2)
plt.plot(range(len(episode_rewards)), episode_rewards)
plt.xlabel('epoch*{}'.format(self.args.evaluate_cycle))
plt.ylabel('episode_rewards')
plt.savefig(self.save_path + '/plt_{}.png'.format(num), format='png')
np.save(self.save_path + '/win_rates_{}'.format(num), win_rates)
np.save(self.save_path + '/episode_rewards_{}'.format(num), episode_rewards)
episodes = []
# 收集self.args.n_episodes个episodes
for episode_idx in range(self.args.n_episodes):
episode, _ = self.rolloutWorker.generate_episode(episode_idx)
episodes.append(episode)
# print(_)
# episode的每一项都是一个(1, episode_len, n_agents, 具体维度)四维数组,下面要把所有episode的的obs拼在一起
episode_batch = episodes[0]
episodes.pop(0)
for episode in episodes:
for key in episode_batch.keys():
episode_batch[key] = np.concatenate((episode_batch[key], episode[key]), axis=0)
if self.args.alg.find('coma') > -1 or self.args.alg.find('central_v') > -1 or self.args.alg.find('reinforce') > -1:
self.agents.train(episode_batch, train_steps, self.rolloutWorker.epsilon)
train_steps += 1
else:
self.buffer.store_episode(episode_batch)
for train_step in range(self.args.train_steps):
mini_batch = self.buffer.sample(min(self.buffer.current_size, self.args.batch_size))
self.agents.train(mini_batch, train_steps)
train_steps += 1
plt.cla()
plt.subplot(2, 1, 1)
plt.plot(range(len(win_rates)), win_rates)
plt.xlabel('epoch*{}'.format(self.args.evaluate_cycle))
plt.ylabel('win_rate')
plt.subplot(2, 1, 2)
plt.plot(range(len(episode_rewards)), episode_rewards)
plt.xlabel('epoch*{}'.format(self.args.evaluate_cycle))
plt.ylabel('episode_rewards')
plt.savefig(self.save_path + '/plt_{}.png'.format(num), format='png')
np.save(self.save_path + '/win_rates_{}'.format(num), win_rates)
np.save(self.save_path + '/episode_rewards_{}'.format(num), episode_rewards)
def evaluate(self):
win_number = 0
episode_rewards = 0
for epoch in range(self.args.evaluate_epoch):
_, episode_reward = self.rolloutWorker.generate_episode(evaluate=True)
episode_rewards += episode_reward
if episode_reward > self.args.threshold:
win_number += 1
return win_number / self.args.evaluate_epoch, episode_rewards / self.args.evaluate_epoch
def evaluate_sparse(self):
win_number = 0
for epoch in range(self.args.evaluate_epoch):
_, episode_reward = self.evaluateWorker.generate_episode(evaluate=True)
result = 'win' if episode_reward > 0 else 'defeat'
print('Epoch {}: {}'.format(epoch, result))
if episode_reward > 0:
win_number += 1
self.env_evaluate.close()
return win_number / self.args.evaluate_epoch
class Runner:
def __init__(self, env, args):
self.env = env
if args.alg.find('commnet') > -1 or args.alg.find(
'g2anet') > -1: # communication agent
self.agents = CommAgents(args)
self.rolloutWorker = CommRolloutWorker(env, self.agents, args)
else: # no communication agent
self.agents = Agents(args)
self.rolloutWorker = RolloutWorker(env, self.agents, args)
if args.learn and args.alg.find('coma') == -1 and args.alg.find(
'central_v') == -1 and args.alg.find(
'reinforce') == -1: # these 3 algorithms are on-poliy
if args.use_per:
self.buffer = PrioritizedReplayBuffer(args)
else:
self.buffer = ReplayBuffer(args)
self.args = args
self.win_rates = []
self.episode_rewards = []
# 用来保存plt和pkl
self.save_path = self.args.result_dir + '/' + args.map + '/'
if not os.path.exists(self.save_path):
os.makedirs(self.save_path)
self.file_name = self.save_path + str(args.env_name) + '_' + str(
args.n_agents) + '_' + str(args.map_size) + '_' + args.name_time
def run(self, num):
train_steps = 0
episode_rewards = 0
fixed_rewards = 0
st = time.time()
plot_rewards = []
# print('Run {} start'.format(num))
for epoch in range(self.args.n_epoch):
# print('Run {}, train epoch {}'.format(num, epoch))
# if epoch % self.args.evaluate_cycle == 0:
# win_rate, episode_reward = self.evaluate()
# # print('win_rate is ', win_rate)
# self.win_rates.append(win_rate)
# self.episode_rewards.append(episode_reward)
# print(episode_reward)
# # self.plt(num)
episodes = []
# 收集self.args.n_episodes个episodes
for episode_idx in range(self.args.n_episodes):
if self.args.use_ja:
if self.args.use_v1:
episode, episode_reward, rate, fixed_reward = self.rolloutWorker.generate_episode_ja_v2(
episode_idx)
else:
episode, episode_reward, rate, fixed_reward = self.rolloutWorker.generate_episode_ja_v3(
episode_idx)
else:
episode, episode_reward, rate, fixed_reward = self.rolloutWorker.generate_episode(
episode_idx)
episodes.append(episode)
episode_rewards += episode_reward
fixed_rewards += fixed_reward
plot_rewards.append(episode_reward)
if epoch % self.args.evaluate_cycle == 0:
t = time.time() - st
st = time.time()
epr = round(episode_rewards / self.args.evaluate_cycle, 2)
fr = round(fixed_rewards / self.args.evaluate_cycle, 2)
print('train epoch {}, reward {}, time {}, rate {}'.format(
epoch, [epr, fr], t, rate))
# wandb.log({"reward": epr, "test_reward": epr})
episode_rewards = 0
fixed_rewards = 0
with open(self.file_name, 'wb') as fp:
pickle.dump(plot_rewards, fp)
# episode的每一项都是一个(1, episode_len, n_agents, 具体维度)四维数组,下面要把所有episode的的obs拼在一起
episode_batch = episodes[0]
episodes.pop(0)
for episode in episodes:
for key in episode_batch.keys():
episode_batch[key] = np.concatenate(
(episode_batch[key], episode[key]), axis=0)
if self.args.alg.find('coma') > -1 or self.args.alg.find(
'central_v') > -1 or self.args.alg.find('reinforce') > -1:
self.agents.train(episode_batch, train_steps,
self.rolloutWorker.epsilon)
train_steps += 1
elif not self.args.load_model:
self.buffer.store_episode(episode_batch)
for train_step in range(self.args.train_steps):
# mini_batch = self.buffer.sample(min(self.buffer.current_size, self.args.batch_size))
# # print(mini_batch['terminated'])
# # print(train_steps)
# dq = self.agents.train(mini_batch, train_steps)
if self.args.use_per:
mini_batch, idxs = self.buffer.sample(
min(self.buffer.current_size,
self.args.batch_size))
dq = self.agents.train(mini_batch, train_steps)
self.buffer.update_priorities(idxs, dq)
else:
mini_batch = self.buffer.sample(
min(self.buffer.current_size,
self.args.batch_size))
dq = self.agents.train(mini_batch, train_steps)
train_steps += 1
# self.plt(num)
def evaluate(self):
win_number = 0
episode_rewards = 0
for epoch in range(self.args.evaluate_epoch):
_, episode_reward, win_tag = self.rolloutWorker.generate_episode(
epoch, evaluate=True)
episode_rewards += episode_reward
if win_tag:
win_number += 1
return win_number / self.args.evaluate_epoch, episode_rewards / self.args.evaluate_epoch
from datetime import datetime
current = datetime.today().strftime('%Y%m%d%H%M%S')
plot_episode_rewards = [] # 이건 에피소드 받은 리워드 ( 에이전트 동안 받은 개별 리워드 다 더한 값)
plot_episode_valid_steps = [] # 에피소드별 action 요청이 하나라도 들어온 step 카운트
plot_episode_count_requested_agent = np.asarray(
[0] * N_AGENTS) # 에이전트별 요청받은 에이전트 대수 기록
plot_episode_requested_agents = np.asarray([0] * N_AGENTS)
plot_count_per_actions = np.asarray([0] * N_ACTION)
args = get_common_args()
args = qmix_args(args)
policy = QMIX(args)
agents = Agents(args, policy)
env = elevator.ElevatorEnv(SCREEN_WIDTH, SCREEN_HEIGHT, False)
worker = RolloutWorker(env, agents, args)
buffer = ReplayBuffer(args)
plt.figure()
plt.axis([0, args.n_epoch, 0, 100])
win_rates = []
episode_rewards = []
train_steps = 0
save_path = args.result_dir + '/' + current
os.makedirs(save_path, exist_ok=True)
for epoch in range(args.n_epoch):
class Runner:
def __init__(self, env, args):
self.env = env
if args.alg.find('commnet') > -1 or args.alg.find(
'g2anet') > -1: # communication agent
self.agents = CommAgents(args)
self.rolloutWorker = CommRolloutWorker(env, self.agents, args)
else: # no communication agent
self.agents = Agents(args)
self.rolloutWorker = RolloutWorker(env, self.agents, args)
if not args.evaluate and args.alg.find('coma') == -1 and args.alg.find(
'central_v') == -1 and args.alg.find(
'reinforce') == -1: # these 3 algorithms are on-poliy
self.buffer = ReplayBuffer(args)
self.args = args
self.win_rates = []
self.episode_rewards = []
# 用来保存plt和pkl
self.save_path = self.args.result_dir + '/' + args.alg + '/' + args.map
if not os.path.exists(self.save_path):
os.makedirs(self.save_path)
def run(self, num):
time_steps, train_steps, evaluate_steps = 0, 0, -1
while time_steps < self.args.n_steps:
print('Run {}, time_steps {}'.format(num, time_steps))
if time_steps // self.args.evaluate_cycle > evaluate_steps:
win_rate, episode_reward = self.evaluate()
# print('win_rate is ', win_rate)
self.win_rates.append(win_rate)
self.episode_rewards.append(episode_reward)
self.plt(num)
evaluate_steps += 1
episodes = []
# 收集self.args.n_episodes个episodes
for episode_idx in range(self.args.n_episodes):
episode, _, _, steps = self.rolloutWorker.generate_episode(
episode_idx)
episodes.append(episode)
time_steps += steps
# print(_)
# episode的每一项都是一个(1, episode_len, n_agents, 具体维度)四维数组,下面要把所有episode的的obs拼在一起
episode_batch = episodes[0]
episodes.pop(0)
for episode in episodes:
for key in episode_batch.keys():
episode_batch[key] = np.concatenate(
(episode_batch[key], episode[key]), axis=0)
if self.args.alg.find('coma') > -1 or self.args.alg.find(
'central_v') > -1 or self.args.alg.find('reinforce') > -1:
self.agents.train(episode_batch, train_steps,
self.rolloutWorker.epsilon)
train_steps += 1
else:
self.buffer.store_episode(episode_batch)
for train_step in range(self.args.train_steps):
mini_batch = self.buffer.sample(
min(self.buffer.current_size, self.args.batch_size))
self.agents.train(mini_batch, train_steps)
train_steps += 1
win_rate, episode_reward = self.evaluate()
print('win_rate is ', win_rate)
self.win_rates.append(win_rate)
self.episode_rewards.append(episode_reward)
self.plt(num)
def evaluate(self):
win_number = 0
episode_rewards = 0
for epoch in range(self.args.evaluate_epoch):
_, episode_reward, win_tag, _ = self.rolloutWorker.generate_episode(
epoch, evaluate=True)
episode_rewards += episode_reward
if win_tag:
win_number += 1
return win_number / self.args.evaluate_epoch, episode_rewards / self.args.evaluate_epoch
def plt(self, num):
plt.figure()
plt.ylim([0, 105])
plt.cla()
plt.subplot(2, 1, 1)
plt.plot(range(len(self.win_rates)), self.win_rates)
plt.xlabel('step*{}'.format(self.args.evaluate_cycle))
plt.ylabel('win_rates')
plt.subplot(2, 1, 2)
plt.plot(range(len(self.episode_rewards)), self.episode_rewards)
plt.xlabel('step*{}'.format(self.args.evaluate_cycle))
plt.ylabel('episode_rewards')
plt.savefig(self.save_path + '/plt_{}.png'.format(num), format='png')
np.save(self.save_path + '/win_rates_{}'.format(num), self.win_rates)
np.save(self.save_path + '/episode_rewards_{}'.format(num),
self.episode_rewards)
plt.close()
class Runner:
def __init__(self, curriculum, args, target_env):
self.target_env = target_env
self.curriculum = curriculum
if args.alg.find('commnet') > -1 or args.alg.find(
'g2anet') > -1: # communication agent
self.agents = CommAgents(args)
self.rolloutWorker = CommRolloutWorker(None, self.agents, args)
else: # no communication agent
self.agents = Agents(args)
self.rolloutWorker = RolloutWorker(None, self.agents, args)
if not args.evaluate and args.alg.find('coma') == -1 and args.alg.find(
'central_v') == -1 and args.alg.find(
'reinforce') == -1: # these 3 algorithms are on-poliy
self.buffer = None
self.args = args
self.win_rates = []
self.eval_episode_rewards = []
# 用来保存plt和pkl
self.save_path = args.save_path
if not os.path.exists(self.save_path):
os.makedirs(self.save_path)
self.train_rewards = []
self.ratios = []
self.historical_params = {}
self.switch = True # we will be switching to some task
self.patience = 20
self.writer: SummaryWriter = None
self.eval_envs = None
self.debug = False
def run(self):
time_steps, train_steps, evaluate_steps = 0, 0, -1
while True:
if time_steps // self.args.evaluate_cycle > evaluate_steps:
win_rate, eval_episode_reward = self.evaluate(
time_steps, self.target_env)
self.win_rates.append(win_rate)
self.eval_episode_rewards.append(eval_episode_reward)
self.plt()
evaluate_steps += 1
performance = int(eval_episode_reward)
self.curriculum.update(performance, self.agents, time_steps,
train_steps)
# eval in other envs
for env in self.eval_envs:
self.evaluate(time_steps, env)
try:
env = self.curriculum.get()
buffer = env.buffer
self.rolloutWorker.env = env
logging.info("Restoring map {}".format(
self.rolloutWorker.env.map_name))
except IndexError: # done
self.agents.policy.save_model(train_step)
self.plt()
break
episodes = []
# 收集self.args.n_episodes个episodes
for episode_idx in range(self.args.n_episodes):
episode, train_episode_reward, _, steps = self.rolloutWorker.generate_episode(
episode_idx)
self.train_rewards.append(train_episode_reward)
episodes.append(episode)
time_steps += steps
logging.info('Time_steps {}, train_episode_reward {}'.format(
time_steps, train_episode_reward))
# print(_)
# episode的每一项都是一个(1, episode_len, n_agents, 具体维度)四维数组,下面要把所有episode的的obs拼在一起
episode_batch = episodes[0]
episodes.pop(0)
for episode in episodes:
for key in episode_batch.keys():
episode_batch[key] = np.concatenate(
(episode_batch[key], episode[key]), axis=0)
if self.args.alg.find('coma') > -1 or self.args.alg.find(
'central_v') > -1 or self.args.alg.find('reinforce') > -1:
self.agents.train(episode_batch, train_steps,
self.rolloutWorker.epsilon)
train_steps += 1
else:
buffer.store_episode(episode_batch)
for train_step in range(self.args.train_steps):
mini_batch = buffer.sample(
min(buffer.current_size, self.args.batch_size))
self.agents.train(mini_batch, train_steps)
train_steps += 1
self.writer.add_scalar(f'Reward/train/',
train_episode_reward,
global_step=time_steps)
self.writer.add_scalar(f'Reward/train/{env.map_name}',
train_episode_reward,
global_step=time_steps)
if self.debug:
for n, p in self.agents.policy.eval_rnn.named_parameters():
self.writer.add_scalar(f'eval_rnn/{n}/norm',
p.norm(),
global_step=time_steps)
self.writer.add_scalar(f'eval_rnn/grad/{n}/norm',
p.grad.norm(),
global_step=time_steps)
self.writer.add_scalar(f'eval_rnn/{n}/norm/{env.map_name}',
p.norm(),
global_step=time_steps)
self.writer.add_scalar(
f'eval_rnn/grad/{n}/norm/{env.map_name}',
p.grad.norm(),
global_step=time_steps)
for n, p in self.agents.policy.eval_qmix_net.named_parameters(
):
self.writer.add_scalar(f'eval_qmix_net/{n}/norm',
p.norm(),
global_step=time_steps)
self.writer.add_scalar(f'eval_qmix_net/grad/{n}/norm',
p.grad.norm(),
global_step=time_steps)
self.writer.add_scalar(
f'eval_qmix_net/{n}/norm/{env.map_name}',
p.norm(),
global_step=time_steps)
self.writer.add_scalar(
f'eval_qmix_net/grad/{n}/norm/{env.map_name}',
p.grad.norm(),
global_step=time_steps)
def evaluate(self, time_steps, env):
win_number = 0
episode_rewards = 0
self.rolloutWorker.env = env
logging.info("Evaluating in map {}".format(
self.rolloutWorker.env.map_name))
for epoch in range(self.args.evaluate_epoch):
_, episode_reward, win_tag, _ = self.rolloutWorker.generate_episode(
epoch, evaluate=True)
logging.info('Eval_epoch {}, eval_episode_reward {}'.format(
epoch, episode_reward))
episode_rewards += episode_reward
self.writer.add_scalar(
f'Reward/eval/{self.rolloutWorker.env.map_name}',
episode_reward, time_steps + epoch)
if win_tag:
win_number += 1
return win_number / self.args.evaluate_epoch, episode_rewards / self.args.evaluate_epoch
def plt(self):
plt.figure().set_size_inches(10, 15)
plt.ylim([0, 105])
plt.cla()
plt.subplot(3, 1, 1)
plt.plot(range(len(self.win_rates)), self.win_rates)
plt.xlabel('step*{}'.format(self.args.evaluate_cycle))
plt.ylabel('win_rates')
plt.subplot(3, 1, 2)
plt.plot(range(len(self.eval_episode_rewards)),
self.eval_episode_rewards)
plt.xlabel('step*{}'.format(self.args.evaluate_cycle))
plt.ylabel('eval_episode_rewards')
plt.subplot(3, 1, 3)
train_rewards = np.array_split(self.train_rewards,
len(self.eval_episode_rewards))
mean_train_rewards = [np.mean(t) for t in train_rewards]
plt.plot(range(len((mean_train_rewards))), mean_train_rewards)
plt.xlabel('step*{}'.format(self.args.evaluate_cycle))
plt.ylabel('train_episode_rewards')
plt.tight_layout()
plt.savefig(self.save_path + '/plt.png', format='png')
np.save(self.save_path + '/win_rates', self.win_rates)
np.save(self.save_path + '/eval_rewards', self.eval_episode_rewards)
np.save(self.save_path + '/train_rewards', self.train_rewards)
plt.close()
class Runner:
def __init__(self, env, args):
self.env = env
if args.alg.find('commnet') > -1 or args.alg.find(
'g2anet') > -1: # communication agent
self.agents = CommAgents(args)
self.rolloutWorker = CommRolloutWorker(env, self.agents, args)
else: # no communication agent
self.agents = Agents(args)
self.rolloutWorker = RolloutWorker(env, self.agents, args)
if args.learn and args.alg.find('coma') == -1 and args.alg.find(
'central_v') == -1 and args.alg.find(
'reinforce') == -1: # these 3 algorithms are on-poliy
self.buffer = ReplayBuffer(args)
self.args = args
self.win_rates = []
self.episode_rewards = []
# 用来保存plt和pkl
self.save_path = self.args.result_dir + '/' + args.alg + '/' + args.map
if not os.path.exists(self.save_path):
os.makedirs(self.save_path)
self.fig = None
def run(self, num):
global EPOCH
train_steps = 0
# print('Run {} start'.format(num))
self.env.reset_callback = reset_callback #TODO
for epoch in range(self.args.n_epoch):
EPOCH = epoch
# print('Run {}, train epoch {}'.format(num, epoch))
if epoch % self.args.evaluate_cycle == 0:
# print('Run {}, train epoch {}, evaluating'.format(num, epoch))
win_rate, episode_reward = self.evaluate()
# print('win_rate is ', win_rate)
self.win_rates.append(self.rolloutWorker.epsilon)
self.episode_rewards.append(episode_reward)
self.plt(num)
episodes = []
# 收集self.args.n_episodes个episodes
for episode_idx in range(self.args.n_episodes):
episode, _, _ = self.rolloutWorker.generate_episode(
episode_idx)
episodes.append(episode)
# print(_)
# episode的每一项都是一个(1, episode_len, n_agents, 具体维度)四维数组,下面要把所有episode的的obs拼在一起
episode_batch = episodes[0]
episodes.pop(0)
for episode in episodes:
for key in episode_batch.keys():
episode_batch[key] = np.concatenate(
(episode_batch[key], episode[key]), axis=0)
if self.args.alg.find('coma') > -1 or self.args.alg.find(
'central_v') > -1 or self.args.alg.find('reinforce') > -1:
self.agents.train(episode_batch, train_steps,
self.rolloutWorker.epsilon)
train_steps += 1
else:
self.buffer.store_episode(episode_batch)
for train_step in range(self.args.train_steps):
mini_batch = self.buffer.sample(
min(self.buffer.current_size, self.args.batch_size))
self.agents.train(mini_batch, train_steps)
train_steps += 1
self.plt(num)
def evaluate(self):
win_number = 0
episode_rewards = 0
for epoch in range(self.args.evaluate_epoch):
_, episode_reward, win_tag = self.rolloutWorker.generate_episode(
epoch, evaluate=True)
episode_rewards += episode_reward
if win_tag:
win_number += 1
return win_number / self.args.evaluate_epoch, episode_rewards / self.args.evaluate_epoch
def plt(self, num):
if self.fig is None:
self.fig = plt.figure()
fig = self.fig
plt.axis([0, self.args.n_epoch, 0, 100])
plt.cla()
plt.subplot(2, 1, 1)
plt.plot(range(len(self.win_rates)), self.win_rates)
plt.xlabel('epoch*{}'.format(self.args.evaluate_cycle))
plt.ylabel('epsilon')
plt.subplot(2, 1, 2)
plt.plot(range(len(self.episode_rewards)), self.episode_rewards)
plt.xlabel('epoch*{}'.format(self.args.evaluate_cycle))
plt.ylabel('episode_rewards')
plt.tight_layout()
plt.savefig(self.save_path + '/plt_{}.png'.format(num), format='png')
np.save(self.save_path + '/win_rates_{}'.format(num), self.win_rates)
np.save(self.save_path + '/episode_rewards_{}'.format(num),
self.episode_rewards)
plt.clf()
def runner(env, args):
model_dir = Path('./models') / args.env_id / args.algo
if not model_dir.exists():
curr_run = 'run1'
else:
exst_run_nums = [
int(str(folder.name).split('run')[1])
for folder in model_dir.iterdir()
if str(folder.name).startswith('run')
]
if len(exst_run_nums) == 0:
curr_run = 'run1'
else:
curr_run = 'run%i' % (max(exst_run_nums) + 1)
run_dir = model_dir / curr_run
log_dir = run_dir / 'logs'
results_dir = run_dir / 'results'
os.makedirs(str(log_dir))
os.makedirs(str(results_dir))
logger = SummaryWriter(str(log_dir))
torch.manual_seed(args.seed)
np.random.seed(args.seed)
if not args.use_cuda:
torch.set_num_threads(args.n_training_threads)
agents = Agents(args)
rolloutWorker = RolloutWorker(env, agents, args)
buffer = ReplayBuffer(args)
train_step = 0
mean_episode_rewards = []
for ep_i in range(0, args.n_episodes, args.n_rollout_threads):
print("Episodes %i-%i of %i" %
(ep_i + 1, ep_i + 1 + args.n_rollout_threads, args.n_episodes))
if args.display:
for env_show in env.envs:
env_show.render('human')
# Using the RolloutWork to interact with the environment (rollout the episodes >= 1)
episodes, rews, mean_rews = [], [], []
for episode_idx in range(args.n_rollouts):
episode, ep_rew, mean_ep_rew = rolloutWorker.generate_episode(
episode_idx)
episodes.append(episode)
rews.append(ep_rew)
mean_rews.append(mean_ep_rew)
episodes_batch = episodes[0]
episodes.pop(0)
for episode in episodes:
for key in episodes_batch.keys():
episodes_batch[key] = np.concatenate(
(episodes_batch[key], episode[key]), axis=0)
buffer.push(episodes_batch)
# Algorithms VDN and QMIX need the buffer but not the epsilon to train agents
if args.algo.find('vdn') > -1 or args.algo.find('qmix') > -1:
for _ in range(args.training_steps):
mini_batch = buffer.sample(
min(buffer.current_size, args.batch_size))
agents.train(mini_batch, train_step)
train_step += 1
# Algorithms COMA, LIIR, MAAC needs the buffer and the epsilon to train agents
else:
for _ in range(args.training_steps):
mini_batch = buffer.sample(
min(buffer.current_size, args.batch_size))
agents.train(mini_batch, train_step, rolloutWorker.epsilon)
train_step += 1
rews = np.mean(rews)
mean_rews = np.mean(mean_rews)
mean_episode_rewards.append(mean_rews)
logger.add_scalar('mean_episode_rewards', mean_rews, ep_i)
print("Episode {} : Total reward {} , Mean reward {}".format(
ep_i + 1, rews, mean_rews))
if ep_i % args.save_cycle < args.n_rollout_threads:
os.makedirs(str(run_dir / 'incremental'), exist_ok=True)
agents.save(
str(run_dir / 'incremental' / ('model_ep%i.pt' % (ep_i + 1))))
agents.save(str(run_dir / 'model.pt'))
agents.save(str(run_dir / 'model.pt'))
env.close()
logger.export_scalars_to_json(str(log_dir / 'summary.json'))
logger.close()
index = list(range(1, len(mean_episode_rewards) + 1))
plt.plot(index, mean_episode_rewards)
plt.ylabel("Mean Episode Rewards")
plt.savefig(str(results_dir) + '/mean_episode_rewards.jpg')
# plt.show()
plt.close()
class Runner:
def __init__(self, env, args):
self.env = env
self.agents = Agents(args)
self.rolloutWorker = RolloutWorker(env, self.agents, args)
self.buffer = ReplayBuffer(args)
self.args = args
self.epsilon = args.epsilon
# 用来在一个稀疏奖赏的环境上评估算法的好坏,胜利为1,失败为-1,其他普通的一步为0
self.env_evaluate = StarCraft2Env(map_name=args.map,
step_mul=args.step_mul,
difficulty=args.difficulty,
game_version=args.game_version,
seed=args.seed,
replay_dir=args.replay_dir,
reward_sparse=True,
reward_scale=False)
self.evaluateWorker = RolloutWorker(self.env_evaluate, self.agents,
args)
def run(self):
plt.figure()
plt.axis([0, self.args.n_epoch, 0, 100])
win_rates = []
episode_rewards = []
train_steps = 0
for epoch in tqdm(range(self.args.n_epoch)):
# print('Train epoch {} start'.format(epoch))
self.epsilon = self.epsilon - 0.0001125 if self.epsilon > 0.05 else self.epsilon
episodes = []
# 收集self.args.n_episodes个episodes
for episode_idx in range(self.args.n_episodes):
episode, _ = self.rolloutWorker.generate_episode(self.epsilon)
episodes.append(episode)
# episode的每一项都是一个(1, episode_len, n_agents, 具体维度)四维数组,下面要把所有episode的的obs拼在一起
episode_batch = episodes[0]
episodes.pop(0)
for episode in episodes:
for key in episode_batch.keys():
episode_batch[key] = np.concatenate(
(episode_batch[key], episode[key]), axis=0)
self.buffer.store_episode(episode_batch)
if self.buffer.current_size > 100:
for train_step in range(self.args.train_steps):
mini_batch = self.buffer.sample(self.args.batch_size)
self.agents.train(mini_batch, train_steps)
train_steps += 1
win_rate, episode_reward = self.evaluate()
# print('win_rate is ', win_rate)
win_rates.append(win_rate)
episode_rewards.append(episode_reward)
# 可视化
if epoch % 100 == 0:
plt.cla()
plt.subplot(2, 1, 1)
plt.plot(range(len(win_rates)), win_rates)
plt.xlabel('epoch')
plt.ylabel('win_rate')
plt.subplot(2, 1, 2)
plt.plot(range(len(episode_rewards)), episode_rewards)
plt.xlabel('epoch')
plt.ylabel('episode_rewards')
plt.savefig(self.args.result_dir + '/plt.png',
format='png')
np.save(self.args.result_dir + '/win_rates', win_rates)
np.save(self.args.result_dir + '/episode_rewards',
episode_rewards)
plt.cla()
plt.subplot(2, 1, 1)
plt.plot(range(len(win_rates)), win_rates)
plt.xlabel('epoch')
plt.ylabel('win_rate')
plt.subplot(2, 1, 2)
plt.plot(range(len(episode_rewards)), episode_rewards)
plt.xlabel('epoch')
plt.ylabel('episode_rewards')
plt.savefig(self.args.result_dir + '/plt.png', format='png')
np.save(self.args.result_dir + '/win_rates', win_rates)
np.save(self.args.result_dir + '/episode_rewards', episode_rewards)
def evaluate(self):
win_number = 0
episode_rewards = 0
for epoch in range(self.args.evaluate_epoch):
_, episode_reward = self.rolloutWorker.generate_episode(0)
episode_rewards += episode_reward
if episode_reward > self.args.threshold:
win_number += 1
return win_number / self.args.evaluate_epoch, episode_rewards / self.args.evaluate_epoch
def evaluate_sparse(self):
win_number = 0
for epoch in range(self.args.evaluate_epoch):
_, episode_reward = self.evaluateWorker.generate_episode(0)
result = 'win' if episode_reward > 0 else 'defeat'
print('Epoch {}: {}'.format(epoch, result))
if episode_reward > 0:
win_number += 1
return win_number / self.args.evaluate_epoch
