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train_dqn_gym.py
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train_dqn_gym.py
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"""An example of training DQN against OpenAI Gym Envs.
This script is an example of training a DQN agent against OpenAI Gym envs.
Both discrete and continuous action spaces are supported. For continuous action
spaces, A NAF (Normalized Advantage Function) is used to approximate Q-values.
To solve CartPole-v0, run:
python train_dqn_gym.py --env CartPole-v0
To solve Pendulum-v0, run:
python train_dqn_gym.py --env Pendulum-v0
"""
import argparse
import os
import sys
import gym
import numpy as np
import torch.optim as optim
from gym import spaces
import pfrl
from pfrl import experiments, explorers
from pfrl import nn as pnn
from pfrl import q_functions, replay_buffers, utils
from pfrl.agents.dqn import DQN
def main():
import logging
logging.basicConfig(level=logging.INFO)
parser = argparse.ArgumentParser()
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("--env", type=str, default="Pendulum-v0")
parser.add_argument("--seed", type=int, default=0, help="Random seed [0, 2 ** 32)")
parser.add_argument("--gpu", type=int, default=0)
parser.add_argument("--final-exploration-steps", type=int, default=10**4)
parser.add_argument("--start-epsilon", type=float, default=1.0)
parser.add_argument("--end-epsilon", type=float, default=0.1)
parser.add_argument("--noisy-net-sigma", type=float, default=None)
parser.add_argument("--demo", action="store_true", default=False)
parser.add_argument("--load", type=str, default=None)
parser.add_argument("--steps", type=int, default=10**5)
parser.add_argument("--prioritized-replay", action="store_true")
parser.add_argument("--replay-start-size", type=int, default=1000)
parser.add_argument("--target-update-interval", type=int, default=10**2)
parser.add_argument("--target-update-method", type=str, default="hard")
parser.add_argument("--soft-update-tau", type=float, default=1e-2)
parser.add_argument("--update-interval", type=int, default=1)
parser.add_argument("--eval-n-runs", type=int, default=100)
parser.add_argument("--eval-interval", type=int, default=10**4)
parser.add_argument("--n-hidden-channels", type=int, default=100)
parser.add_argument("--n-hidden-layers", type=int, default=2)
parser.add_argument("--gamma", type=float, default=0.99)
parser.add_argument("--minibatch-size", type=int, default=None)
parser.add_argument("--render-train", action="store_true")
parser.add_argument("--render-eval", action="store_true")
parser.add_argument("--monitor", action="store_true")
parser.add_argument("--reward-scale-factor", type=float, default=1e-3)
parser.add_argument(
"--actor-learner",
action="store_true",
help="Enable asynchronous sampling with asynchronous actor(s)",
) # NOQA
parser.add_argument(
"--num-envs",
type=int,
default=1,
help=(
"The number of environments for sampling (only effective with"
" --actor-learner enabled)"
),
) # NOQA
args = parser.parse_args()
# Set a random seed used in PFRL
utils.set_random_seed(args.seed)
args.outdir = experiments.prepare_output_dir(args, args.outdir, argv=sys.argv)
print("Output files are saved in {}".format(args.outdir))
# 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.num_envs) + args.seed * args.num_envs
assert process_seeds.max() < 2**32
def clip_action_filter(a):
return np.clip(a, action_space.low, action_space.high)
def make_env(idx=0, test=False):
env = gym.make(args.env)
# Use different random seeds for train and test envs
process_seed = int(process_seeds[idx])
env_seed = 2**32 - 1 - process_seed if test else process_seed
utils.set_random_seed(env_seed)
# Cast observations to float32 because our model uses float32
env = pfrl.wrappers.CastObservationToFloat32(env)
if args.monitor:
env = pfrl.wrappers.Monitor(env, args.outdir)
if isinstance(env.action_space, spaces.Box):
utils.env_modifiers.make_action_filtered(env, clip_action_filter)
if not test:
# Scale rewards (and thus returns) to a reasonable range so that
# training is easier
env = pfrl.wrappers.ScaleReward(env, args.reward_scale_factor)
if (args.render_eval and test) or (args.render_train and not test):
env = pfrl.wrappers.Render(env)
return env
env = make_env(test=False)
timestep_limit = env.spec.max_episode_steps
obs_space = env.observation_space
obs_size = obs_space.low.size
action_space = env.action_space
if isinstance(action_space, spaces.Box):
action_size = action_space.low.size
# Use NAF to apply DQN to continuous action spaces
q_func = q_functions.FCQuadraticStateQFunction(
obs_size,
action_size,
n_hidden_channels=args.n_hidden_channels,
n_hidden_layers=args.n_hidden_layers,
action_space=action_space,
)
# Use the Ornstein-Uhlenbeck process for exploration
ou_sigma = (action_space.high - action_space.low) * 0.2
explorer = explorers.AdditiveOU(sigma=ou_sigma)
else:
n_actions = action_space.n
q_func = q_functions.FCStateQFunctionWithDiscreteAction(
obs_size,
n_actions,
n_hidden_channels=args.n_hidden_channels,
n_hidden_layers=args.n_hidden_layers,
)
# Use epsilon-greedy for exploration
explorer = explorers.LinearDecayEpsilonGreedy(
args.start_epsilon,
args.end_epsilon,
args.final_exploration_steps,
action_space.sample,
)
if args.noisy_net_sigma is not None:
pnn.to_factorized_noisy(q_func, sigma_scale=args.noisy_net_sigma)
# Turn off explorer
explorer = explorers.Greedy()
opt = optim.Adam(q_func.parameters())
rbuf_capacity = 5 * 10**5
if args.minibatch_size is None:
args.minibatch_size = 32
if args.prioritized_replay:
betasteps = (args.steps - args.replay_start_size) // args.update_interval
rbuf = replay_buffers.PrioritizedReplayBuffer(
rbuf_capacity, betasteps=betasteps
)
else:
rbuf = replay_buffers.ReplayBuffer(rbuf_capacity)
agent = DQN(
q_func,
opt,
rbuf,
gpu=args.gpu,
gamma=args.gamma,
explorer=explorer,
replay_start_size=args.replay_start_size,
target_update_interval=args.target_update_interval,
update_interval=args.update_interval,
minibatch_size=args.minibatch_size,
target_update_method=args.target_update_method,
soft_update_tau=args.soft_update_tau,
)
if args.load:
agent.load(args.load)
eval_env = make_env(test=True)
if args.demo:
eval_stats = experiments.eval_performance(
env=eval_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"],
)
)
elif not args.actor_learner:
print(
"WARNING: Since https://github.com/pfnet/pfrl/pull/112 we have started"
" setting `eval_during_episode=True` in this script, which affects the"
" timings of evaluation phases."
)
experiments.train_agent_with_evaluation(
agent=agent,
env=env,
steps=args.steps,
eval_n_steps=None,
eval_n_episodes=args.eval_n_runs,
eval_interval=args.eval_interval,
outdir=args.outdir,
eval_env=eval_env,
train_max_episode_len=timestep_limit,
eval_during_episode=True,
)
else:
# using impala mode when given num of envs
# When we use multiple envs, it is critical to ensure each env
# can occupy a CPU core to get the best performance.
# Therefore, we need to prevent potential CPU over-provision caused by
# multi-threading in Openmp and Numpy.
# Disable the multi-threading on Openmp and Numpy.
os.environ["OMP_NUM_THREADS"] = "1" # NOQA
(
make_actor,
learner,
poller,
exception_event,
) = agent.setup_actor_learner_training(args.num_envs)
poller.start()
learner.start()
experiments.train_agent_async(
processes=args.num_envs,
make_agent=make_actor,
make_env=make_env,
steps=args.steps,
eval_n_steps=None,
eval_n_episodes=args.eval_n_runs,
eval_interval=args.eval_interval,
outdir=args.outdir,
stop_event=learner.stop_event,
exception_event=exception_event,
)
poller.stop()
learner.stop()
poller.join()
learner.join()
if __name__ == "__main__":
main()