def train(rank,
scene_scope,
task_scope,
args,
shared_model,
counter,
lock,
optimizer=None):
torch.manual_seed(args.seed + rank)
#env = create_atari_env(args.env_name)
#env.seed(args.seed + rank)
env = Environment({
'scene_name': scene_scope,
'terminal_state_id': int(task_scope)
})
model = ActorCriticFFNetwork(ACTION_SIZE)
if optimizer is None:
# TODO: Discount learning rate based on episode length
optimizer = my_optim.SharedRMSprop(shared_model.parameters(),
lr=args.lr,
alpha=args.alpha,
eps=args.eps)
optimizer.share_memory()
model.train()
env.reset()
state = torch.from_numpy(env.s_t)
done = True
episode_length = 0
for i in range(int(args.max_episode_length)):
# Sync with the shared model
model.load_state_dict(shared_model.state_dict())
'''
if done:
cx = Variable(torch.zeros(1, 256))
hx = Variable(torch.zeros(1, 256))
else:
cx = Variable(cx.data)
hx = Variable(hx.data)
'''
values = []
log_probs = []
rewards = []
entropies = []
for step in range(args.num_steps):
print('Thread: ', rank, ', step: ', step, 'epochs:', i)
episode_length += 1
logit, value = model(env.s_t, env.target)
prob = F.softmax(logit, dim=1)
log_prob = F.log_softmax(logit, dim=1)
entropy = -(log_prob * prob).sum(1, keepdim=True)
entropies.append(entropy)
action = prob.multinomial(num_samples=1).data
log_prob = log_prob.gather(1, Variable(action))
env.step(action)
#state, reward, done, _ = env.step(action.numpy())
env.update()
state = env.s_t
reward = env.reward
done = env.terminal
done = done or episode_length >= args.max_episode_length
reward = max(min(reward, 1), -1)
with lock:
if counter.value % 1000 == 0:
print('Now saving data. Please wait.')
torch.save(shared_model.state_dict(),
CHECKPOINT_DIR + '/' + 'checkpoint.pth.tar')
counter.value += 1
if done:
episode_length = 0
if env.terminal:
print('Task completed')
counter.value += 1
if done:
episode_length = 0
env.reset()
state = env.s_t
state = torch.from_numpy(state)
values.append(value)
log_probs.append(log_prob)
rewards.append(reward)
if done:
break
R = torch.zeros(1, 1)
if not done:
_, value = model(env.s_t, env.target)
R = value.data
values.append(Variable(R))
policy_loss = 0
value_loss = 0
R = Variable(R)
gae = torch.zeros(1, 1)
for i in reversed(range(len(rewards))):
R = args.gamma * R + rewards[i]
advantage = R - values[i]
value_loss = value_loss + 0.5 * advantage.pow(2)
# Generalized Advantage Estimataion
delta_t = rewards[i] + args.gamma * \
values[i + 1].data - values[i].data
gae = gae * args.gamma * args.tau + delta_t
policy_loss = policy_loss - \
log_probs[i] * Variable(gae) - args.entropy_coef * entropies[i]
optimizer.zero_grad()
(policy_loss + args.value_loss_coef * value_loss).backward()
torch.nn.utils.clip_grad_norm_(model.parameters(), args.max_grad_norm)
ensure_shared_grads(model, shared_model)
optimizer.step()
torch.multiprocessing.set_start_method('spawn')
os.environ['OMP_NUM_THREADS'] = '1'
os.environ['CUDA_VISIBLE_DEVICES'] = ""
list_of_tasks = TASK_LIST
scene_scopes = list_of_tasks.keys()
args = parser.parse_args()
torch.manual_seed(args.seed)
#env = create_atari_env(args.env_name)
shared_model = ActorCriticFFNetwork(ACTION_SIZE)
shared_model.share_memory()
if args.no_shared:
optimizer = None
else:
optimizer = my_optim.SharedRMSprop(shared_model.parameters(),
lr=args.lr,
alpha=args.alpha,
eps=args.eps)
optimizer.share_memory()
processes = []
counter = mp.Value('i', 0)
lock = mp.Lock()
'''
p = mp.Process(target=test, args=(args.num_processes, args, shared_model, counter))
p.start()
processes.append(p)
'''
branches = []
