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train_ppo_gym.py
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train_ppo_gym.py
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"""An example of training PPO against OpenAI Gym Envs.
This script is an example of training a PPO agent against OpenAI Gym envs.
Both discrete and continuous action spaces are supported.
To solve CartPole-v0, run:
python train_ppo_gym.py --env CartPole-v0
"""
import argparse
import chainer
from chainer import functions as F
import gym
import chainerrl
from chainerrl.agents import a3c
from chainerrl.agents import PPO
from chainerrl import experiments
from chainerrl import links
from chainerrl import misc
from chainerrl.optimizers.nonbias_weight_decay import NonbiasWeightDecay
from chainerrl import policies
class A3CFFSoftmax(chainer.ChainList, a3c.A3CModel):
"""An example of A3C feedforward softmax policy."""
def __init__(self, ndim_obs, n_actions, hidden_sizes=(200, 200)):
self.pi = policies.SoftmaxPolicy(
model=links.MLP(ndim_obs, n_actions, hidden_sizes))
self.v = links.MLP(ndim_obs, 1, hidden_sizes=hidden_sizes)
super().__init__(self.pi, self.v)
def pi_and_v(self, state):
return self.pi(state), self.v(state)
class A3CFFMellowmax(chainer.ChainList, a3c.A3CModel):
"""An example of A3C feedforward mellowmax policy."""
def __init__(self, ndim_obs, n_actions, hidden_sizes=(200, 200)):
self.pi = policies.MellowmaxPolicy(
model=links.MLP(ndim_obs, n_actions, hidden_sizes))
self.v = links.MLP(ndim_obs, 1, hidden_sizes=hidden_sizes)
super().__init__(self.pi, self.v)
def pi_and_v(self, state):
return self.pi(state), self.v(state)
class A3CFFGaussian(chainer.Chain, a3c.A3CModel):
"""An example of A3C feedforward Gaussian policy."""
def __init__(self, obs_size, action_space,
n_hidden_layers=2, n_hidden_channels=64,
bound_mean=None):
assert bound_mean in [False, True]
super().__init__()
hidden_sizes = (n_hidden_channels,) * n_hidden_layers
with self.init_scope():
self.pi = policies.FCGaussianPolicyWithStateIndependentCovariance(
obs_size, action_space.low.size,
n_hidden_layers, n_hidden_channels,
var_type='diagonal', nonlinearity=F.tanh,
bound_mean=bound_mean,
min_action=action_space.low, max_action=action_space.high,
mean_wscale=1e-2)
self.v = links.MLP(obs_size, 1, hidden_sizes=hidden_sizes)
def pi_and_v(self, state):
return self.pi(state), self.v(state)
def main():
import logging
parser = argparse.ArgumentParser()
parser.add_argument('--gpu', type=int, default=0)
parser.add_argument('--env', type=str, default='Hopper-v2')
parser.add_argument('--arch', type=str, default='FFGaussian',
choices=('FFSoftmax', 'FFMellowmax',
'FFGaussian'))
parser.add_argument('--bound-mean', action='store_true')
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('--steps', type=int, default=10 ** 6)
parser.add_argument('--eval-interval', type=int, default=10000)
parser.add_argument('--eval-n-runs', type=int, default=10)
parser.add_argument('--reward-scale-factor', type=float, default=1e-2)
parser.add_argument('--standardize-advantages', action='store_true')
parser.add_argument('--render', action='store_true', default=False)
parser.add_argument('--lr', type=float, default=3e-4)
parser.add_argument('--weight-decay', type=float, default=0.0)
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('--update-interval', type=int, default=2048)
parser.add_argument('--batchsize', type=int, default=64)
parser.add_argument('--epochs', type=int, default=10)
parser.add_argument('--entropy-coef', type=float, default=0.0)
args = parser.parse_args()
logging.basicConfig(level=args.logger_level)
# Set a random seed used in ChainerRL
misc.set_random_seed(args.seed, gpus=(args.gpu,))
args.outdir = experiments.prepare_output_dir(args, args.outdir)
def make_env(test):
env = gym.make(args.env)
# Use different random seeds for train and test envs
env_seed = 2 ** 32 - 1 - args.seed if test else args.seed
env.seed(env_seed)
# Cast observations to float32 because our model uses float32
env = chainerrl.wrappers.CastObservationToFloat32(env)
if args.monitor:
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:
env = chainerrl.wrappers.Render(env)
return env
sample_env = gym.make(args.env)
timestep_limit = sample_env.spec.max_episode_steps
obs_space = sample_env.observation_space
action_space = sample_env.action_space
# Normalize observations based on their empirical mean and variance
obs_normalizer = chainerrl.links.EmpiricalNormalization(
obs_space.low.size, clip_threshold=5)
# Switch policy types accordingly to action space types
if args.arch == 'FFSoftmax':
model = A3CFFSoftmax(obs_space.low.size, action_space.n)
elif args.arch == 'FFMellowmax':
model = A3CFFMellowmax(obs_space.low.size, action_space.n)
elif args.arch == 'FFGaussian':
model = A3CFFGaussian(obs_space.low.size, action_space,
bound_mean=args.bound_mean)
opt = chainer.optimizers.Adam(alpha=args.lr, eps=1e-5)
opt.setup(model)
if args.weight_decay > 0:
opt.add_hook(NonbiasWeightDecay(args.weight_decay))
agent = PPO(model, opt,
obs_normalizer=obs_normalizer,
gpu=args.gpu,
update_interval=args.update_interval,
minibatch_size=args.batchsize, epochs=args.epochs,
clip_eps_vf=None, entropy_coef=args.entropy_coef,
standardize_advantages=args.standardize_advantages,
)
if args.load:
agent.load(args.load)
if args.demo:
env = make_env(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:
# Linearly decay the learning rate to zero
def lr_setter(env, agent, value):
agent.optimizer.alpha = value
lr_decay_hook = experiments.LinearInterpolationHook(
args.steps, args.lr, 0, lr_setter)
# Linearly decay the clipping parameter to zero
def clip_eps_setter(env, agent, value):
agent.clip_eps = max(value, 1e-8)
clip_eps_decay_hook = experiments.LinearInterpolationHook(
args.steps, 0.2, 0, clip_eps_setter)
experiments.train_agent_with_evaluation(
agent=agent,
env=make_env(False),
eval_env=make_env(True),
outdir=args.outdir,
steps=args.steps,
eval_n_steps=None,
eval_n_episodes=args.eval_n_runs,
eval_interval=args.eval_interval,
train_max_episode_len=timestep_limit,
save_best_so_far_agent=False,
step_hooks=[
lr_decay_hook,
clip_eps_decay_hook,
],
)
if __name__ == '__main__':
main()