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train_ddpg.py
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train_ddpg.py
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import argparse
import copy
import dataclasses
import datetime
import os
import time
import gym
import numpy as np
import rsoccer_gym
import torch.multiprocessing as mp
import torch.nn.functional as F
import torch.optim as optim
import wandb
from agents.ddpg import (DDPGHP, DDPGActor, DDPGCritic, TargetActor,
TargetCritic, data_func)
from agents.utils import ReplayBuffer, save_checkpoint, unpack_batch, ExperienceFirstLast
import pyvirtualdisplay
if __name__ == "__main__":
# Creates a virtual display for OpenAI gym
pyvirtualdisplay.Display(visible=0, size=(1400, 900)).start()
mp.set_start_method('spawn')
os.environ['OMP_NUM_THREADS'] = "1"
parser = argparse.ArgumentParser()
parser.add_argument("--cuda", default=False,
action="store_true", help="Enable cuda")
parser.add_argument("-n", "--name", required=True,
help="Name of the run")
parser.add_argument("-e", "--env", required=True,
help="Name of the gym environment")
args = parser.parse_args()
device = "cuda" if args.cuda else "cpu"
# Input Experiment Hyperparameters
hp = DDPGHP(
EXP_NAME=args.name,
DEVICE=device,
ENV_NAME=args.env,
N_ROLLOUT_PROCESSES=2,
LEARNING_RATE=0.0001,
EXP_GRAD_RATIO=10,
BATCH_SIZE=256,
GAMMA=0.95,
REWARD_STEPS=3,
NOISE_SIGMA_INITIAL=0.8,
NOISE_THETA=0.15,
NOISE_SIGMA_DECAY=0.99,
NOISE_SIGMA_MIN=0.15,
NOISE_SIGMA_GRAD_STEPS=3000,
REPLAY_SIZE=5000000,
REPLAY_INITIAL=100000,
SAVE_FREQUENCY=100000,
GIF_FREQUENCY=100000,
TOTAL_GRAD_STEPS=2000000
)
wandb.init(project='RoboCIn-RL', name=hp.EXP_NAME, entity='robocin', config=hp.to_dict())
current_time = datetime.datetime.now().strftime('%b-%d_%H-%M-%S')
tb_path = os.path.join('runs', current_time + '_'
+ hp.ENV_NAME + '_' + hp.EXP_NAME)
pi = DDPGActor(hp.N_OBS, hp.N_ACTS).to(device)
Q = DDPGCritic(hp.N_OBS, hp.N_ACTS).to(device)
# Playing
pi.share_memory()
exp_queue = mp.Queue(maxsize=hp.EXP_GRAD_RATIO)
finish_event = mp.Event()
sigma_m = mp.Value('f', hp.NOISE_SIGMA_INITIAL)
gif_req_m = mp.Value('i', -1)
data_proc_list = []
for _ in range(hp.N_ROLLOUT_PROCESSES):
data_proc = mp.Process(
target=data_func,
args=(
pi,
device,
exp_queue,
finish_event,
sigma_m,
gif_req_m,
hp
)
)
data_proc.start()
data_proc_list.append(data_proc)
# Training
tgt_pi = TargetActor(pi)
tgt_Q = TargetCritic(Q)
pi_opt = optim.Adam(pi.parameters(), lr=hp.LEARNING_RATE)
Q_opt = optim.Adam(Q.parameters(), lr=hp.LEARNING_RATE)
buffer = ReplayBuffer(buffer_size=hp.REPLAY_SIZE,
observation_space=hp.observation_space,
action_space=hp.action_space,
device=hp.DEVICE
)
n_grads = 0
n_samples = 0
n_episodes = 0
best_reward = None
last_gif = None
try:
while n_grads < hp.TOTAL_GRAD_STEPS:
metrics = {}
ep_infos = list()
st_time = time.perf_counter()
# Collect EXP_GRAD_RATIO sample for each grad step
new_samples = 0
while new_samples < hp.EXP_GRAD_RATIO:
exp = exp_queue.get()
if exp is None:
raise Exception # got None value in queue
safe_exp = copy.deepcopy(exp)
del(exp)
# Dict is returned with end of episode info
if isinstance(safe_exp, dict):
logs = {"ep_info/"+key: value for key,
value in safe_exp.items() if 'truncated' not in key}
ep_infos.append(logs)
n_episodes += 1
else:
buffer.add(
obs=safe_exp.state,
next_obs=safe_exp.last_state if safe_exp.last_state is not None else safe_exp.state,
action=safe_exp.action,
reward=safe_exp.reward,
done=False if safe_exp.last_state is not None else True
)
new_samples += 1
n_samples += new_samples
sample_time = time.perf_counter()
# Only start training after buffer is larger than initial value
if buffer.size() < hp.REPLAY_INITIAL:
continue
# Sample a batch and load it as a tensor on device
batch = buffer.sample(hp.BATCH_SIZE)
S_v = batch.observations
A_v = batch.actions
r_v = batch.rewards
dones = batch.dones
S_next_v = batch.next_observations
# train critic
Q_opt.zero_grad()
Q_v = Q(S_v, A_v) # expected Q for S,A
A_next_v = tgt_pi(S_next_v) # Get an Bootstrap Action for S_next
Q_next_v = tgt_Q(S_next_v, A_next_v) # Bootstrap Q_next
Q_next_v[dones == 1.] = 0.0 # No bootstrap if transition is terminal
# Calculate a reference Q value using the bootstrap Q
Q_ref_v = r_v + Q_next_v * (hp.GAMMA**hp.REWARD_STEPS)
Q_loss_v = F.mse_loss(Q_v, Q_ref_v.detach())
Q_loss_v.backward()
Q_opt.step()
metrics["train/loss_Q"] = Q_loss_v.cpu().detach().numpy()
# train actor - Maximize Q value received over every S
pi_opt.zero_grad()
A_cur_v = pi(S_v)
pi_loss_v = -Q(S_v, A_cur_v)
pi_loss_v = pi_loss_v.mean()
pi_loss_v.backward()
pi_opt.step()
metrics["train/loss_pi"] = pi_loss_v.cpu().detach().numpy()
# Sync target networks
tgt_pi.sync(alpha=1 - 1e-3)
tgt_Q.sync(alpha=1 - 1e-3)
n_grads += 1
grad_time = time.perf_counter()
metrics['speed/samples'] = new_samples/(sample_time - st_time)
metrics['speed/grad'] = 1/(grad_time - sample_time)
metrics['speed/total'] = 1/(grad_time - st_time)
metrics['counters/samples'] = n_samples
metrics['counters/grads'] = n_grads
metrics['counters/episodes'] = n_episodes
metrics["counters/buffer_len"] = buffer.size()
if ep_infos:
for key in ep_infos[0].keys():
metrics[key] = np.mean([info[key] for info in ep_infos])
# Log metrics
wandb.log(metrics)
if hp.NOISE_SIGMA_DECAY and sigma_m.value > hp.NOISE_SIGMA_MIN \
and n_grads % hp.NOISE_SIGMA_GRAD_STEPS == 0:
# This syntax is needed to be process-safe
# The noise sigma value is accessed by the playing processes
with sigma_m.get_lock():
sigma_m.value *= hp.NOISE_SIGMA_DECAY
if hp.SAVE_FREQUENCY and n_grads % hp.SAVE_FREQUENCY == 0:
save_checkpoint(
hp=hp,
metrics={
'noise_sigma': sigma_m.value,
'n_samples': n_samples,
'n_episodes': n_episodes,
'n_grads': n_grads,
},
pi=pi,
Q=Q,
pi_opt=pi_opt,
Q_opt=Q_opt
)
if hp.GIF_FREQUENCY and n_grads % hp.GIF_FREQUENCY == 0:
gif_req_m.value = n_grads
except KeyboardInterrupt:
print("...Finishing...")
finish_event.set()
finally:
if exp_queue:
while exp_queue.qsize() > 0:
exp_queue.get()
print('queue is empty')
print("Waiting for threads to finish...")
for p in data_proc_list:
p.terminate()
p.join()
del(exp_queue)
del(pi)
finish_event.set()