def test_learning(self):
pol_net = PolNet(self.env.observation_space,
self.env.action_space, h1=32, h2=32)
pol = CategoricalPol(self.env.observation_space,
self.env.action_space, pol_net)
vf_net = VNet(self.env.observation_space, h1=32, h2=32)
vf = DeterministicSVfunc(self.env.observation_space, vf_net)
sampler = EpiSampler(self.env, pol, num_parallel=1)
optim_vf = torch.optim.Adam(vf_net.parameters(), 3e-4)
epis = sampler.sample(pol, max_steps=32)
traj = Traj()
traj.add_epis(epis)
traj = ef.compute_vs(traj, vf)
traj = ef.compute_rets(traj, 0.99)
traj = ef.compute_advs(traj, 0.99, 0.95)
traj = ef.centerize_advs(traj)
traj = ef.compute_h_masks(traj)
traj.register_epis()
result_dict = trpo.train(traj, pol, vf, optim_vf, 1, 24)
del sampler
def test_learning(self):
pol_net = PolNet(self.env.observation_space,
self.env.action_space, h1=32, h2=32)
pol = GaussianPol(self.env.observation_space,
self.env.action_space, pol_net)
vf_net = VNet(self.env.observation_space, h1=32, h2=32)
vf = DeterministicSVfunc(self.env.observation_space, vf_net)
sampler = EpiSampler(self.env, pol, num_parallel=1)
optim_pol = torch.optim.Adam(pol_net.parameters(), 3e-4)
optim_vf = torch.optim.Adam(vf_net.parameters(), 3e-4)
epis = sampler.sample(pol, max_steps=32)
traj = Traj()
traj.add_epis(epis)
traj = ef.compute_vs(traj, vf)
traj = ef.compute_rets(traj, 0.99)
traj = ef.compute_advs(traj, 0.99, 0.95)
traj = ef.centerize_advs(traj)
traj = ef.compute_h_masks(traj)
traj.register_epis()
result_dict = ppo_clip.train(traj=traj, pol=pol, vf=vf, clip_param=0.2,
optim_pol=optim_pol, optim_vf=optim_vf, epoch=1, batch_size=32)
result_dict = ppo_kl.train(traj=traj, pol=pol, vf=vf, kl_beta=0.1, kl_targ=0.2,
optim_pol=optim_pol, optim_vf=optim_vf, epoch=1, batch_size=32, max_grad_norm=10)
del sampler
def test_learning(self):
pol_net = PolNet(self.env.observation_space,
self.env.action_space,
h1=32,
h2=32)
pol = GaussianPol(self.env.observation_space, self.env.action_space,
pol_net)
vf_net = VNet(self.env.observation_space)
vf = DeterministicSVfunc(self.env.observation_space, vf_net)
discrim_net = DiscrimNet(self.env.observation_space,
self.env.action_space,
h1=32,
h2=32)
discrim = DeterministicSAVfunc(self.env.observation_space,
self.env.action_space, discrim_net)
sampler = EpiSampler(self.env, pol, num_parallel=1)
optim_vf = torch.optim.Adam(vf_net.parameters(), 3e-4)
optim_discrim = torch.optim.Adam(discrim_net.parameters(), 3e-4)
with open(os.path.join('data/expert_epis', 'Pendulum-v0_2epis.pkl'),
'rb') as f:
expert_epis = pickle.load(f)
expert_traj = Traj()
expert_traj.add_epis(expert_epis)
expert_traj.register_epis()
epis = sampler.sample(pol, max_steps=32)
agent_traj = Traj()
agent_traj.add_epis(epis)
agent_traj = ef.compute_pseudo_rews(agent_traj, discrim)
agent_traj = ef.compute_vs(agent_traj, vf)
agent_traj = ef.compute_rets(agent_traj, 0.99)
agent_traj = ef.compute_advs(agent_traj, 0.99, 0.95)
agent_traj = ef.centerize_advs(agent_traj)
agent_traj = ef.compute_h_masks(agent_traj)
agent_traj.register_epis()
result_dict = gail.train(agent_traj,
expert_traj,
pol,
vf,
discrim,
optim_vf,
optim_discrim,
rl_type='trpo',
epoch=1,
batch_size=32,
discrim_batch_size=32,
discrim_step=1,
pol_ent_beta=1e-3,
discrim_ent_beta=1e-5)
del sampler
def test_learning(self):
pol_net = PolNet(self.env.ob_space, self.env.ac_space, h1=32, h2=32)
pol = GaussianPol(self.env.ob_space, self.env.ac_space, pol_net)
vf_net = VNet(self.env.ob_space)
vf = DeterministicSVfunc(self.env.ob_space, vf_net)
rewf_net = VNet(self.env.ob_space, h1=32, h2=32)
rewf = DeterministicSVfunc(self.env.ob_space, rewf_net)
shaping_vf_net = VNet(self.env.ob_space, h1=32, h2=32)
shaping_vf = DeterministicSVfunc(self.env.ob_space, shaping_vf_net)
sampler = EpiSampler(self.env, pol, num_parallel=1)
optim_vf = torch.optim.Adam(vf_net.parameters(), 3e-4)
optim_discrim = torch.optim.Adam(
list(rewf_net.parameters()) + list(shaping_vf_net.parameters()), 3e-4)
with open(os.path.join('data/expert_epis', 'Pendulum-v0_2epis.pkl'), 'rb') as f:
expert_epis = pickle.load(f)
expert_traj = Traj()
expert_traj.add_epis(expert_epis)
expert_traj = ef.add_next_obs(expert_traj)
expert_traj.register_epis()
epis = sampler.sample(pol, max_steps=32)
agent_traj = Traj()
agent_traj.add_epis(epis)
agent_traj = ef.add_next_obs(agent_traj)
agent_traj = ef.compute_pseudo_rews(
agent_traj, rew_giver=rewf, state_only=True)
agent_traj = ef.compute_vs(agent_traj, vf)
agent_traj = ef.compute_rets(agent_traj, 0.99)
agent_traj = ef.compute_advs(agent_traj, 0.99, 0.95)
agent_traj = ef.centerize_advs(agent_traj)
agent_traj = ef.compute_h_masks(agent_traj)
agent_traj.register_epis()
result_dict = airl.train(agent_traj, expert_traj, pol, vf, optim_vf, optim_discrim,
rewf=rewf, shaping_vf=shaping_vf,
rl_type='trpo',
epoch=1,
batch_size=32, discrim_batch_size=32,
discrim_step=1,
pol_ent_beta=1e-3, gamma=0.99)
del sampler
def setUpClass(cls):
env = GymEnv('Pendulum-v0')
random_pol = RandomPol(cls.env.observation_space, cls.env.action_space)
sampler = EpiSampler(cls.env, pol, num_parallel=1)
epis = sampler.sample(pol, max_steps=32)
traj = Traj()
traj.add_epis(epis)
traj.register_epis()
cls.num_step = traj.num_step
make_redis('localhost', '6379')
cls.r = get_redis()
cls.r.set('env', env)
cls.r.set('traj', traj)
pol_net = PolNet(env.observation_space, env.action_space)
gpol = GaussianPol(env.observation_space, env.action_space, pol_net)
pol_net = PolNet(env.observation_space,
env.action_space, deterministic=True)
dpol = DeterministicActionNoisePol(
env.observation_space, env.action_space, pol_net)
model_net = ModelNet(env.observation_space, env.action_space)
mpcpol = MPCPol(env.observation_space,
env.action_space, model_net, rew_func)
q_net = QNet(env.observation_space, env.action_space)
qfunc = DeterministicSAVfunc(
env.observation_space, env.action_space, q_net)
aqpol = ArgmaxQfPol(env.observation_space, env.action_space, qfunc)
v_net = VNet(env.observation_space)
vfunc = DeterministicSVfunc(env.observation_space, v_net)
cls.r.set('gpol', cloudpickle.dumps(gpol))
cls.r.set('dpol', cloudpickle.dumps(dpol))
cls.r.set('mpcpol', cloudpickle.dumps(mpcpol))
cls.r.set('qfunc', cloudpickle.dumps(qfunc))
cls.r.set('aqpol', cloudpickle.dumps(aqpol))
cls.r.set('vfunc', cloudpickle.dumps(vfunc))
c2d = C2DEnv(env)
pol_net = PolNet(c2d.observation_space, c2d.action_space)
mcpol = MultiCategoricalPol(
env.observation_space, env.action_space, pol_net)
cls.r.set('mcpol', cloudpickle.dumps(mcpol))
elif isinstance(action_space, gym.spaces.MultiDiscrete):
t_pol = MultiCategoricalPol(
observation_space, action_space, t_pol_net, args.rnn)
s_pol = MultiCategoricalPol(
observation_space, action_space, s_pol_net, args.rnn)
else:
raise ValueError('Only Box, Discrete and Multidiscrete are supported')
if args.teacher_pol:
t_pol.load_state_dict(torch.load(
os.path.join(args.teacher_dir, args.teacher_fname)))
if args.rnn:
s_vf_net = VNetLSTM(observation_space, h_size=256, cell_size=256)
else:
s_vf_net = VNet(observation_space)
if args.sampling_policy == 'teacher':
teacher_sampler = EpiSampler(
env,
t_pol,
num_parallel=args.num_parallel,
seed=args.seed)
student_sampler = EpiSampler(
env,
s_pol,
num_parallel=args.num_parallel,
seed=args.seed)
optim_pol = torch.optim.Adam(s_pol_net.parameters(), args.pol_lr)
t_pol = CategoricalPol(ob_space, ac_space, t_pol_net, args.rnn)
s_pol = CategoricalPol(ob_space, ac_space, s_pol_net, args.rnn)
elif isinstance(ac_space, gym.spaces.MultiDiscrete):
t_pol = MultiCategoricalPol(ob_space, ac_space, t_pol_net, args.rnn)
s_pol = MultiCategoricalPol(ob_space, ac_space, s_pol_net, args.rnn)
else:
raise ValueError('Only Box, Discrete and Multidiscrete are supported')
if args.teacher_pol:
t_pol.load_state_dict(
torch.load(os.path.join(args.teacher_dir, args.teacher_fname)))
if args.rnn:
s_vf_net = VNetLSTM(ob_space, h_size=256, cell_size=256)
else:
s_vf_net = VNet(ob_space)
if args.sampling_policy == 'teacher':
teacher_sampler = EpiSampler(env,
t_pol,
num_parallel=args.num_parallel,
seed=args.seed)
student_sampler = EpiSampler(env,
s_pol,
num_parallel=args.num_parallel,
seed=args.seed)
optim_pol = torch.optim.Adam(s_pol_net.parameters(), args.pol_lr)
total_epi = 0
def main(args):
init_ray(args.num_cpus, args.num_gpus, args.ray_redis_address)
if not os.path.exists(args.log):
os.makedirs(args.log)
if not os.path.exists(os.path.join(args.log, 'models')):
os.mkdir(os.path.join(args.log, 'models'))
score_file = os.path.join(args.log, 'progress.csv')
logger.add_tabular_output(score_file)
logger.add_tensorboard_output(args.log)
with open(os.path.join(args.log, 'args.json'), 'w') as f:
json.dump(vars(args), f)
pprint(vars(args))
# when doing the distributed training, disable video recordings
env = GymEnv(args.env_name)
env.env.seed(args.seed)
if args.c2d:
env = C2DEnv(env)
observation_space = env.observation_space
action_space = env.action_space
pol_net = PolNet(observation_space, action_space)
rnn = False
# pol_net = PolNetLSTM(observation_space, action_space)
# rnn = True
if isinstance(action_space, gym.spaces.Box):
pol = GaussianPol(observation_space, action_space, pol_net, rnn=rnn)
elif isinstance(action_space, gym.spaces.Discrete):
pol = CategoricalPol(observation_space, action_space, pol_net)
elif isinstance(action_space, gym.spaces.MultiDiscrete):
pol = MultiCategoricalPol(observation_space, action_space, pol_net)
else:
raise ValueError('Only Box, Discrete, and MultiDiscrete are supported')
vf_net = VNet(observation_space)
vf = DeterministicSVfunc(observation_space, vf_net)
trainer = TrainManager(Trainer,
args.num_trainer,
args.master_address,
args=args,
vf=vf,
pol=pol)
sampler = EpiSampler(env, pol, args.num_parallel, seed=args.seed)
total_epi = 0
total_step = 0
max_rew = -1e6
start_time = time.time()
while args.max_epis > total_epi:
with measure('sample'):
sampler.set_pol_state(trainer.get_state("pol"))
epis = sampler.sample(max_steps=args.max_steps_per_iter)
with measure('train'):
result_dict = trainer.train(epis=epis)
step = result_dict["traj_num_step"]
total_step += step
total_epi += result_dict["traj_num_epi"]
rewards = [np.sum(epi['rews']) for epi in epis]
mean_rew = np.mean(rewards)
elapsed_time = time.time() - start_time
logger.record_tabular('ElapsedTime', elapsed_time)
logger.record_results(args.log,
result_dict,
score_file,
total_epi,
step,
total_step,
rewards,
plot_title=args.env_name)
with measure('save'):
pol_state = trainer.get_state("pol")
vf_state = trainer.get_state("vf")
optim_pol_state = trainer.get_state("optim_pol")
optim_vf_state = trainer.get_state("optim_vf")
torch.save(pol_state,
os.path.join(args.log, 'models', 'pol_last.pkl'))
torch.save(vf_state, os.path.join(args.log, 'models',
'vf_last.pkl'))
torch.save(optim_pol_state,
os.path.join(args.log, 'models', 'optim_pol_last.pkl'))
torch.save(optim_vf_state,
os.path.join(args.log, 'models', 'optim_vf_last.pkl'))
if mean_rew > max_rew:
torch.save(pol_state,
os.path.join(args.log, 'models', 'pol_max.pkl'))
torch.save(vf_state,
os.path.join(args.log, 'models', 'vf_max.pkl'))
torch.save(
optim_pol_state,
os.path.join(args.log, 'models', 'optim_pol_max.pkl'))
torch.save(
optim_vf_state,
os.path.join(args.log, 'models', 'optim_vf_max.pkl'))
max_rew = mean_rew
del sampler
del trainer
env = C2DEnv(env)
observation_space = env.observation_space
action_space = env.action_space
pol_net = PolNet(observation_space, action_space)
if isinstance(action_space, gym.spaces.Box):
pol = GaussianPol(observation_space, action_space, pol_net)
elif isinstance(action_space, gym.spaces.Discrete):
pol = CategoricalPol(observation_space, action_space, pol_net)
elif isinstance(action_space, gym.spaces.MultiDiscrete):
pol = MultiCategoricalPol(observation_space, action_space, pol_net)
else:
raise ValueError('Only Box, Discrete, and MultiDiscrete are supported')
vf_net = VNet(observation_space)
vf = DeterministicSVfunc(observation_space, vf_net)
if args.rew_type == 'rew':
rewf_net = VNet(observation_space, h1=args.discrim_h1, h2=args.discrim_h2)
rewf = DeterministicSVfunc(observation_space, rewf_net)
shaping_vf_net = VNet(observation_space,
h1=args.discrim_h1,
h2=args.discrim_h2)
shaping_vf = DeterministicSVfunc(observation_space, shaping_vf_net)
optim_discrim = torch.optim.Adam(
list(rewf_net.parameters()) + list(shaping_vf_net.parameters()),
args.discrim_lr)
advf = None
elif args.rew_type == 'adv':
advf_net = DiscrimNet(observation_space,
score_file = os.path.join(args.log, 'progress.csv')
logger.add_tabular_output(score_file)
logger.add_tensorboard_output(args.log)
env = GymEnv(args.env_name,
log_dir=os.path.join(args.log, 'movie'),
record_video=args.record)
env.env.seed(args.seed)
observation_space = env.observation_space
action_space = env.action_space
pol_net = PolNet(observation_space, action_space)
pol = GaussianPol(observation_space, action_space, pol_net)
vf_net = VNet(observation_space)
vf = DeterministicSVfunc(observation_space, vf_net)
qf_net = QNet(observation_space, action_space)
qf = DeterministicSAVfunc(observation_space, action_space, qf_net)
targ_qf_net = QNet(observation_space, action_space)
targ_qf_net.load_state_dict(qf_net.state_dict())
targ_qf = DeterministicSAVfunc(observation_space, action_space, targ_qf_net)
log_alpha = nn.Parameter(torch.zeros((), device=device))
sampler = EpiSampler(env, pol, args.num_parallel, seed=args.seed)
optim_pol = torch.optim.Adam(pol_net.parameters(), args.pol_lr)
optim_vf = torch.optim.Adam(vf_net.parameters(), args.vf_lr)
optim_qf = torch.optim.Adam(qf_net.parameters(), args.qf_lr)
def setup_nets(self):
ob_space = self.env.observation_space
ac_space = self.env.action_space
if self.args.mirror is True:
print("Initiating a symmetric network")
pol_net = SymmetricNet(
*self.env.unwrapped.mirror_sizes,
hidden_size=int(self.args.hidden_size / 4),
num_layers=self.args.num_layers,
varying_std=self.args.varying_std,
tanh_finish=self.args.tanh_finish,
log_std=self.args.log_stdev,
)
elif self.args.rnn:
pol_net = PolNetLSTM(ob_space, ac_space, h_size=256, cell_size=256)
elif self.args.net_version == 1:
pol_net = PolNet(ob_space, ac_space, log_std=self.args.log_stdev)
else:
pol_net = PolNetB(
ob_space,
ac_space,
hidden_size=self.args.hidden_size,
num_layers=self.args.num_layers,
varying_std=self.args.varying_std,
tanh_finish=self.args.tanh_finish,
log_std=self.args.log_stdev,
)
if self.args.mirror == "new":
print("Initiating a new symmetric network")
# TODO: in this case the action_space for the previous pol_net is incorrect, but it isn't easy to fix ...
# we can use this for now which just ignores some of the final indices
pol_net = SymNet(
pol_net,
ob_space.shape[0],
*self.env.unwrapped.sym_act_inds,
varying_std=self.args.varying_std,
log_std=self.args.log_stdev,
deterministic=False,
)
if isinstance(ac_space, gym.spaces.Box):
pol_class = GaussianPol
elif isinstance(ac_space, gym.spaces.Discrete):
pol_class = CategoricalPol
elif isinstance(ac_space, gym.spaces.MultiDiscrete):
pol_class = MultiCategoricalPol
else:
raise ValueError(
"Only Box, Discrete, and MultiDiscrete are supported")
policy = pol_class(
ob_space,
ac_space,
pol_net,
self.args.rnn,
data_parallel=self.args.data_parallel,
parallel_dim=1 if self.args.rnn else 0,
)
if self.args.mirror is True:
vf_net = SymmetricValue(
*self.env.unwrapped.mirror_sizes[:3],
hidden_size=self.args.hidden_size,
num_layers=self.args.num_layers,
)
elif self.args.rnn:
vf_net = VNetLSTM(ob_space, h_size=256, cell_size=256)
elif self.args.net_version == 1:
vf_net = VNet(ob_space)
else:
vf_net = VNetB(
ob_space,
hidden_size=self.args.hidden_size,
num_layers=self.args.num_layers,
)
if self.args.mirror == "new":
print("Initiating a new symmetric value network")
vf_net = SymVNet(vf_net, ob_space.shape[0])
vf = DeterministicSVfunc(
ob_space,
vf_net,
self.args.rnn,
data_parallel=self.args.data_parallel,
parallel_dim=1 if self.args.rnn else 0,
)
self.pol = policy
self.vf = vf