def make_model(self, env):
n_hidden_channels = 50
n_dim_obs = env.observation_space.low.size
v = v_functions.FCVFunction(
n_dim_obs,
n_hidden_layers=2,
n_hidden_channels=n_hidden_channels)
if self.discrete:
n_actions = env.action_space.n
pi = policies.FCSoftmaxPolicy(
n_dim_obs, n_actions,
n_hidden_layers=2,
n_hidden_channels=n_hidden_channels)
else:
n_dim_actions = env.action_space.low.size
pi = policies.FCGaussianPolicy(
n_dim_obs, n_dim_actions,
n_hidden_layers=2,
n_hidden_channels=n_hidden_channels)
return A3CSeparateModel(pi=pi, v=v)
def __init__(self,
env,
feature_transformer,
gamma=0.99,
optimizer='adam',
max_memory=10000):
BaseAgent.__init__(self,
env=env,
feature_transformer=feature_transformer,
gamma=gamma,
optimizer=optimizer)
self.model = agents.pcl.PCLSeparateModel(
pi=policies.FCSoftmaxPolicy(self.n_dims,
self.n_actions,
n_hidden_channels=100,
n_hidden_layers=2),
v=v_functions.FCVFunction(
self.n_dims,
n_hidden_channels=100,
n_hidden_layers=2,
),
)
self.optimizer.setup(self.model)
#self.optimizer.add_hook(chainer.optimizer.GradientClipping(40))
self.replay_buffer = \
chainerrl.replay_buffer.PrioritizedEpisodicReplayBuffer(
capacity=max_memory,
uniform_ratio=0.1,
default_priority_func=exp_return_of_episode,
wait_priority_after_sampling=False,
return_sample_weights=False)
self.agent = agents.pcl.PCL(model=self.model,
optimizer=self.optimizer,
replay_buffer=self.replay_buffer,
t_max=1,
gamma=self.gamma,
tau=1e-2,
phi=phi,
rollout_len=10,
batchsize=1,
disable_online_update=False,
n_times_replay=1,
replay_start_size=1000,
normalize_loss_by_steps=True,
act_deterministically=False,
backprop_future_values=False,
train_async=True)
def make_model(self, env):
n_hidden_channels = 20
n_dim_obs = env.observation_space.low.size
v = v_functions.FCVFunction(
n_dim_obs,
n_hidden_layers=1,
n_hidden_channels=n_hidden_channels,
nonlinearity=F.tanh,
last_wscale=0.01,
)
if self.discrete:
n_actions = env.action_space.n
pi = policies.FCSoftmaxPolicy(
n_dim_obs,
n_actions,
n_hidden_layers=1,
n_hidden_channels=n_hidden_channels,
nonlinearity=F.tanh,
last_wscale=0.01,
)
else:
n_dim_actions = env.action_space.low.size
pi = policies.FCGaussianPolicyWithStateIndependentCovariance(
n_dim_obs,
n_dim_actions,
n_hidden_layers=1,
n_hidden_channels=n_hidden_channels,
nonlinearity=F.tanh,
mean_wscale=0.01,
var_type='diagonal',
)
# Check if KL div supports double-backprop
fake_obs = np.zeros_like(env.observation_space.low, dtype=np.float32)
action_distrib = pi(fake_obs[None])
kl = action_distrib.kl(action_distrib)
old_style_funcs = trpo._find_old_style_function([kl])
if old_style_funcs:
self.skipTest("\
Chainer v{} does not support double backprop of these functions: {}.".format(
chainer.__version__, old_style_funcs))
return pi, v
def make_acer_agent(obs_space_dim, action_space_dim):
def phi(obs):
return obs.astype(np.float32, copy=False)
obs_low = np.array([-1] * obs_space_dim)
obs_high = np.array([1] * obs_space_dim)
ac_low = np.array([-1] * action_space_dim)
ac_high = np.array([1] * action_space_dim)
obs_space = gym.spaces.Box(obs_low, obs_high)
action_space = gym.spaces.Box(ac_low, ac_high)
model = chainerrl.agents.acer.ACERSDNSeparateModel(
pi=policies.FCGaussianPolicy(obs_space.low.size,
action_space.low.size,
n_hidden_channels=50,
n_hidden_layers=2,
bound_mean=True,
min_action=action_space.low,
max_action=action_space.high),
v=v_functions.FCVFunction(obs_space.low.size,
n_hidden_channels=50,
n_hidden_layers=2),
adv=q_functions.FCSAQFunction(obs_space.low.size,
action_space.low.size,
n_hidden_channels=50 // 4,
n_hidden_layers=2),
)
opt = rmsprop_async.RMSpropAsync(lr=7e-4, eps=1e-1, alpha=0.99)
opt.setup(model)
opt.add_hook(chainer.optimizer.GradientClipping(40))
replay_buffer = EpisodicReplayBuffer(10)
agent = chainerrl.agents.acer.ACER(model,
opt,
t_max=5,
gamma=1,
replay_buffer=replay_buffer,
n_times_replay=1,
replay_start_size=50,
disable_online_update=False,
use_trust_region=True,
trust_region_delta=0.1,
truncation_threshold=5,
beta=0.5,
phi=phi)
return agent
def __init__(self, n_dims, n_actions):
self.head = links.Sequence(
L.ConvolutionND(ndim=1,
in_channels=n_dims,
out_channels=100,
ksize=3,
stride=1,
pad=1,
cover_all=True), F.relu)
self.pi = policies.FCSoftmaxPolicy(n_input_channels=100,
n_actions=n_actions,
n_hidden_layers=2,
n_hidden_channels=100)
self.v = v_functions.FCVFunction(n_input_channels=100,
n_hidden_layers=2,
n_hidden_channels=100)
super(A3CFF, self).__init__(self.head, self.pi, self.v)
def main():
import logging
parser = argparse.ArgumentParser()
parser.add_argument('processes', type=int)
parser.add_argument('--env', type=str, default='CartPole-v0')
parser.add_argument('--seed',
type=int,
default=0,
help='Random seed [0, 2 ** 32)')
parser.add_argument('--outdir',
type=str,
default='results',
help='Directory path to save output files.'
' If it does not exist, it will be created.')
parser.add_argument('--t-max', type=int, default=50)
parser.add_argument('--n-times-replay', type=int, default=4)
parser.add_argument('--n-hidden-channels', type=int, default=100)
parser.add_argument('--n-hidden-layers', type=int, default=2)
parser.add_argument('--replay-capacity', type=int, default=5000)
parser.add_argument('--replay-start-size', type=int, default=10**3)
parser.add_argument('--disable-online-update', action='store_true')
parser.add_argument('--beta', type=float, default=1e-2)
parser.add_argument('--profile', action='store_true')
parser.add_argument('--steps', type=int, default=8 * 10**7)
parser.add_argument('--eval-interval', type=int, default=10**5)
parser.add_argument('--eval-n-runs', type=int, default=10)
parser.add_argument('--reward-scale-factor', type=float, default=1e-2)
parser.add_argument('--rmsprop-epsilon', type=float, default=1e-2)
parser.add_argument('--render', action='store_true', default=False)
parser.add_argument('--lr', type=float, default=7e-4)
parser.add_argument('--demo', action='store_true', default=False)
parser.add_argument('--load', type=str, default='')
parser.add_argument('--logger-level', type=int, default=logging.DEBUG)
parser.add_argument('--monitor', action='store_true')
parser.add_argument('--truncation-threshold', type=float, default=5)
parser.add_argument('--trust-region-delta', type=float, default=0.1)
args = parser.parse_args()
logging.basicConfig(level=args.logger_level)
# Set a random seed used in ChainerRL.
# If you use more than one processes, the results will be no longer
# deterministic even with the same random seed.
misc.set_random_seed(args.seed)
# Set different random seeds for different subprocesses.
# If seed=0 and processes=4, subprocess seeds are [0, 1, 2, 3].
# If seed=1 and processes=4, subprocess seeds are [4, 5, 6, 7].
process_seeds = np.arange(args.processes) + args.seed * args.processes
assert process_seeds.max() < 2**32
args.outdir = experiments.prepare_output_dir(args, args.outdir)
def make_env(process_idx, test):
env = gym.make(args.env)
# Use different random seeds for train and test envs
process_seed = int(process_seeds[process_idx])
env_seed = 2**32 - 1 - process_seed if test else process_seed
env.seed(env_seed)
# Cast observations to float32 because our model uses float32
env = chainerrl.wrappers.CastObservationToFloat32(env)
if args.monitor and process_idx == 0:
env = chainerrl.wrappers.Monitor(env, args.outdir)
if not test:
# Scale rewards (and thus returns) to a reasonable range so that
# training is easier
env = chainerrl.wrappers.ScaleReward(env, args.reward_scale_factor)
if args.render and process_idx == 0 and not test:
env = chainerrl.wrappers.Render(env)
return env
sample_env = gym.make(args.env)
timestep_limit = sample_env.spec.tags.get(
'wrapper_config.TimeLimit.max_episode_steps')
obs_space = sample_env.observation_space
action_space = sample_env.action_space
if isinstance(action_space, spaces.Box):
model = acer.ACERSDNSeparateModel(
pi=policies.FCGaussianPolicy(
obs_space.low.size,
action_space.low.size,
n_hidden_channels=args.n_hidden_channels,
n_hidden_layers=args.n_hidden_layers,
bound_mean=True,
min_action=action_space.low,
max_action=action_space.high),
v=v_functions.FCVFunction(obs_space.low.size,
n_hidden_channels=args.n_hidden_channels,
n_hidden_layers=args.n_hidden_layers),
adv=q_functions.FCSAQFunction(
obs_space.low.size,
action_space.low.size,
n_hidden_channels=args.n_hidden_channels // 4,
n_hidden_layers=args.n_hidden_layers),
)
else:
model = acer.ACERSeparateModel(
pi=links.Sequence(
L.Linear(obs_space.low.size, args.n_hidden_channels), F.relu,
L.Linear(args.n_hidden_channels,
action_space.n,
initialW=LeCunNormal(1e-3)), SoftmaxDistribution),
q=links.Sequence(
L.Linear(obs_space.low.size, args.n_hidden_channels), F.relu,
L.Linear(args.n_hidden_channels,
action_space.n,
initialW=LeCunNormal(1e-3)), DiscreteActionValue),
)
opt = rmsprop_async.RMSpropAsync(lr=args.lr,
eps=args.rmsprop_epsilon,
alpha=0.99)
opt.setup(model)
opt.add_hook(chainer.optimizer.GradientClipping(40))
replay_buffer = EpisodicReplayBuffer(args.replay_capacity)
agent = acer.ACER(model,
opt,
t_max=args.t_max,
gamma=0.99,
replay_buffer=replay_buffer,
n_times_replay=args.n_times_replay,
replay_start_size=args.replay_start_size,
disable_online_update=args.disable_online_update,
use_trust_region=True,
trust_region_delta=args.trust_region_delta,
truncation_threshold=args.truncation_threshold,
beta=args.beta)
if args.load:
agent.load(args.load)
if args.demo:
env = make_env(0, True)
eval_stats = experiments.eval_performance(
env=env,
agent=agent,
n_steps=None,
n_episodes=args.eval_n_runs,
max_episode_len=timestep_limit)
print('n_runs: {} mean: {} median: {} stdev {}'.format(
args.eval_n_runs, eval_stats['mean'], eval_stats['median'],
eval_stats['stdev']))
else:
experiments.train_agent_async(agent=agent,
outdir=args.outdir,
processes=args.processes,
make_env=make_env,
profile=args.profile,
steps=args.steps,
eval_n_steps=None,
eval_n_episodes=args.eval_n_runs,
eval_interval=args.eval_interval,
max_episode_len=timestep_limit)
def __init__(self, n_actions):
self.head = links.NIPSDQNHead()
self.pi = policies.FCSoftmaxPolicy(self.head.n_output_channels,
n_actions)
self.v = v_functions.FCVFunction(self.head.n_output_channels)
super().__init__(self.head, self.pi, self.v)
def main():
import logging
parser = argparse.ArgumentParser()
parser.add_argument('processes', type=int)
parser.add_argument('--env', type=str, default='CartPole-v0')
parser.add_argument('--seed', type=int, default=None)
parser.add_argument('--outdir', type=str, default=None)
parser.add_argument('--t-max', type=int, default=50)
parser.add_argument('--n-times-replay', type=int, default=4)
parser.add_argument('--n-hidden-channels', type=int, default=100)
parser.add_argument('--n-hidden-layers', type=int, default=2)
parser.add_argument('--replay-capacity', type=int, default=5000)
parser.add_argument('--replay-start-size', type=int, default=10**3)
parser.add_argument('--disable-online-update', action='store_true')
parser.add_argument('--beta', type=float, default=1e-2)
parser.add_argument('--profile', action='store_true')
parser.add_argument('--steps', type=int, default=8 * 10**7)
parser.add_argument('--eval-interval', type=int, default=10**5)
parser.add_argument('--eval-n-runs', type=int, default=10)
parser.add_argument('--reward-scale-factor', type=float, default=1e-2)
parser.add_argument('--rmsprop-epsilon', type=float, default=1e-2)
parser.add_argument('--render', action='store_true', default=False)
parser.add_argument('--lr', type=float, default=7e-4)
parser.add_argument('--demo', action='store_true', default=False)
parser.add_argument('--load', type=str, default='')
parser.add_argument('--logger-level', type=int, default=logging.DEBUG)
parser.add_argument('--monitor', action='store_true')
parser.add_argument('--truncation-threshold', type=float, default=5)
parser.add_argument('--trust-region-delta', type=float, default=0.1)
args = parser.parse_args()
logging.basicConfig(level=args.logger_level)
if args.seed is not None:
misc.set_random_seed(args.seed)
args.outdir = experiments.prepare_output_dir(args, args.outdir)
def make_env(process_idx, test):
env = gym.make(args.env)
if args.monitor and process_idx == 0:
env = gym.wrappers.Monitor(env, args.outdir)
# Scale rewards observed by agents
if not test:
misc.env_modifiers.make_reward_filtered(
env, lambda x: x * args.reward_scale_factor)
if args.render and process_idx == 0 and not test:
misc.env_modifiers.make_rendered(env)
return env
sample_env = gym.make(args.env)
timestep_limit = sample_env.spec.tags.get(
'wrapper_config.TimeLimit.max_episode_steps')
obs_space = sample_env.observation_space
action_space = sample_env.action_space
if isinstance(action_space, spaces.Box):
model = acer.ACERSDNSeparateModel(
pi=policies.FCGaussianPolicy(
obs_space.low.size,
action_space.low.size,
n_hidden_channels=args.n_hidden_channels,
n_hidden_layers=args.n_hidden_layers,
bound_mean=True,
min_action=action_space.low,
max_action=action_space.high),
v=v_functions.FCVFunction(obs_space.low.size,
n_hidden_channels=args.n_hidden_channels,
n_hidden_layers=args.n_hidden_layers),
adv=q_functions.FCSAQFunction(
obs_space.low.size,
action_space.low.size,
n_hidden_channels=args.n_hidden_channels // 4,
n_hidden_layers=args.n_hidden_layers),
)
else:
model = acer.ACERSeparateModel(
pi=links.Sequence(
L.Linear(obs_space.low.size, args.n_hidden_channels), F.relu,
L.Linear(args.n_hidden_channels,
action_space.n,
initialW=LeCunNormal(1e-3)), SoftmaxDistribution),
q=links.Sequence(
L.Linear(obs_space.low.size, args.n_hidden_channels), F.relu,
L.Linear(args.n_hidden_channels,
action_space.n,
initialW=LeCunNormal(1e-3)), DiscreteActionValue),
)
opt = rmsprop_async.RMSpropAsync(lr=args.lr,
eps=args.rmsprop_epsilon,
alpha=0.99)
opt.setup(model)
opt.add_hook(chainer.optimizer.GradientClipping(40))
replay_buffer = EpisodicReplayBuffer(args.replay_capacity)
agent = acer.ACER(model,
opt,
t_max=args.t_max,
gamma=0.99,
replay_buffer=replay_buffer,
n_times_replay=args.n_times_replay,
replay_start_size=args.replay_start_size,
disable_online_update=args.disable_online_update,
use_trust_region=True,
trust_region_delta=args.trust_region_delta,
truncation_threshold=args.truncation_threshold,
beta=args.beta,
phi=phi)
if args.load:
agent.load(args.load)
if args.demo:
env = make_env(0, True)
eval_stats = experiments.eval_performance(
env=env,
agent=agent,
n_runs=args.eval_n_runs,
max_episode_len=timestep_limit)
print('n_runs: {} mean: {} median: {} stdev {}'.format(
args.eval_n_runs, eval_stats['mean'], eval_stats['median'],
eval_stats['stdev']))
else:
experiments.train_agent_async(agent=agent,
outdir=args.outdir,
processes=args.processes,
make_env=make_env,
profile=args.profile,
steps=args.steps,
eval_n_runs=args.eval_n_runs,
eval_interval=args.eval_interval,
max_episode_len=timestep_limit)
def main(args):
import logging
logging.basicConfig(level=logging.INFO, filename='log')
if (type(args) is list):
args = make_args(args)
if not os.path.exists(args.outdir):
os.makedirs(args.outdir)
# Set a random seed used in ChainerRL.
# If you use more than one processes, the results will be no longer
# deterministic even with the same random seed.
misc.set_random_seed(args.seed)
# Set different random seeds for different subprocesses.
# If seed=0 and processes=4, subprocess seeds are [0, 1, 2, 3].
# If seed=1 and processes=4, subprocess seeds are [4, 5, 6, 7].
process_seeds = np.arange(args.processes) + args.seed * args.processes
assert process_seeds.max() < 2**32
def make_env(process_idx, test):
env = gym.make(args.env)
# Use different random seeds for train and test envs
process_seed = int(process_seeds[process_idx])
env_seed = 2**32 - 1 - process_seed if test else process_seed
env.seed(env_seed)
# Cast observations to float32 because our model uses float32
env = chainerrl.wrappers.CastObservationToFloat32(env)
if args.monitor and process_idx == 0:
env = chainerrl.wrappers.Monitor(env, args.outdir)
if not test:
# Scale rewards (and thus returns) to a reasonable range so that
# training is easier
env = chainerrl.wrappers.ScaleReward(env, args.reward_scale_factor)
if args.render and process_idx == 0 and not test:
env = chainerrl.wrappers.Render(env)
return env
sample_env = gym.make(args.env)
timestep_limit = sample_env.spec.tags.get(
'wrapper_config.TimeLimit.max_episode_steps')
obs_space = sample_env.observation_space
action_space = sample_env.action_space
if isinstance(action_space, spaces.Box):
model = acer.ACERSDNSeparateModel(
pi=policies.FCGaussianPolicy(
obs_space.low.size,
action_space.low.size,
n_hidden_channels=args.n_hidden_channels,
n_hidden_layers=args.n_hidden_layers,
bound_mean=True,
min_action=action_space.low,
max_action=action_space.high),
v=v_functions.FCVFunction(obs_space.low.size,
n_hidden_channels=args.n_hidden_channels,
n_hidden_layers=args.n_hidden_layers),
adv=q_functions.FCSAQFunction(
obs_space.low.size,
action_space.low.size,
n_hidden_channels=args.n_hidden_channels // 4,
n_hidden_layers=args.n_hidden_layers),
)
else:
model = acer.ACERSeparateModel(
pi=links.Sequence(
L.Linear(obs_space.low.size, args.n_hidden_channels), F.relu,
L.Linear(args.n_hidden_channels,
action_space.n,
initialW=LeCunNormal(1e-3)), SoftmaxDistribution),
q=links.Sequence(
L.Linear(obs_space.low.size, args.n_hidden_channels), F.relu,
L.Linear(args.n_hidden_channels,
action_space.n,
initialW=LeCunNormal(1e-3)), DiscreteActionValue),
)
opt = rmsprop_async.RMSpropAsync(lr=args.lr,
eps=args.rmsprop_epsilon,
alpha=0.99)
opt.setup(model)
opt.add_hook(chainer.optimizer.GradientClipping(40))
replay_buffer = EpisodicReplayBuffer(args.replay_capacity)
agent = acer.ACER(model,
opt,
t_max=args.t_max,
gamma=0.99,
replay_buffer=replay_buffer,
n_times_replay=args.n_times_replay,
replay_start_size=args.replay_start_size,
disable_online_update=args.disable_online_update,
use_trust_region=True,
trust_region_delta=args.trust_region_delta,
truncation_threshold=args.truncation_threshold,
beta=args.beta)
if args.load_agent:
agent.load(args.load_agent)
if (args.mode == 'train'):
experiments.train_agent_async(agent=agent,
outdir=args.outdir,
processes=args.processes,
make_env=make_env,
profile=args.profile,
steps=args.steps,
step_offset=args.step_offset,
checkpoint_freq=args.checkpoint_freq,
log_type=args.log_type,
eval_n_steps=None,
eval_n_episodes=args.eval_n_runs,
eval_interval=args.eval_interval,
max_episode_len=timestep_limit)
elif (args.mode == 'check'):
from matplotlib import animation
import matplotlib.pyplot as plt
env = make_env(0, True)
frames = []
for i in range(3):
obs = env.reset()
done = False
R = 0
t = 0
while not done and t < 200:
frames.append(env.render(mode='rgb_array'))
action = agent.act(obs)
obs, r, done, _ = env.step(action)
R += r
t += 1
print('test episode:', i, 'R:', R)
agent.stop_episode()
env.close()
from IPython.display import HTML
plt.figure(figsize=(frames[0].shape[1] / 72.0,
frames[0].shape[0] / 72.0),
dpi=72)
patch = plt.imshow(frames[0])
plt.axis('off')
def animate(i):
patch.set_data(frames[i])
anim = animation.FuncAnimation(plt.gcf(),
animate,
frames=len(frames),
interval=50)
anim.save(args.save_mp4)
return anim
