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acer.py
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acer.py
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import gym
import torch
import torch.nn as nn
import torch.nn.functional as F
import torch.optim as optim
import torch.autograd as autograd
import random
import itertools
import threading as T
from collections import deque
from torch.distributions import Categorical
#Hyperparameters
EPISODES = 10000
learning_rate = 0.0002
discount_factor = 0.98
num_agents = 3
train_interval = 10
replay_iter = 8
buffer_len, start_train = 20000, 500
is_clipping = 1.2
trpo_delta = 1.0
avgnet_ratio = 0.995
class Network(nn.Module):
def __init__(self):
super().__init__()
self.fc1 = nn.Linear(4, 128)
self.fc2 = nn.Linear(128, 128)
self.policy = nn.Linear(128, 2)
self.qval = nn.Linear(128, 2)
def p(self, x):
x = F.relu(self.fc1(x))
self.pi = F.relu(self.fc2(x))
self.pi.retain_grad()
prob = F.softmax(self.policy(self.pi), dim=1)
return prob
def q(self, x):
x = F.relu(self.fc1(x))
x = F.relu(self.fc2(x))
return self.qval(x)
def mini_batch(data):
obs, acts, probs, rewards, next_obs, done = [], [], [], [], [], []
for transition in data:
s, a, p, r, s_, d = transition
obs.append(s); acts.append(a); probs.append(p); rewards.append(r)
next_obs.append(s_), done.append(d)
if d:
break
return torch.tensor(obs).float(), torch.tensor(acts), \
torch.stack(probs, dim=0).float(), torch.tensor(rewards).float(),\
torch.tensor(next_obs).float(), torch.tensor(done)
def train_process(net, global_avgnet, samples, global_optimizer):
obs, acts, old_probs, rewards, next_obs, done = samples
acts, rewards = acts.view(-1, 1), rewards.view(-1, 1)
final_q, final_p = net.q(next_obs[-1].unsqueeze(0)), net.p(next_obs[-1].unsqueeze(0))
final_v = torch.sum(final_q * final_p, dim=1)
qval = net.q(obs)
current_p = net.p(obs)
avg_p = global_avgnet.p(obs)
value = torch.sum(qval*current_p, dim=1, keepdim=True)
act_q = qval.gather(1, acts)
ratio = torch.exp(torch.log(current_p) - torch.log(old_probs))
ret_ratio = torch.min(torch.tensor(1.0), ratio.gather(1, acts))
policy_ratio = torch.min(torch.tensor(is_clipping), ratio.gather(1, acts))
ret_q = []
R = final_v if not done[-1] else torch.tensor([0.0])
for idx, r in enumerate(torch.flip(rewards, [0, 1])):
R = r + discount_factor * R
ret_q.append(R)
R = ret_ratio[-1-idx]*(R - act_q[-1-idx]) + value[-1-idx]
ret_q.reverse()
ret_q = torch.stack(ret_q, dim=0)
p_obj1 = policy_ratio.detach() * torch.log(current_p.gather(1, acts)) * \
(ret_q - value).detach()
p_obj2 = 0
for a in range(2):
coeff = torch.max(torch.tensor(0), 1-is_clipping/ratio[:, a]).view(-1, 1)
a_prob, a_qval = current_p[:, a].view(-1, 1), qval[:, a].view(-1, 1)
p_obj2 += (coeff*a_prob).detach() * torch.log(a_prob) * (a_qval - value).detach()
policy_obj = (p_obj1 + p_obj2).mean()
g = autograd.grad(policy_obj, net.pi, retain_graph=True)[0]
kld = F.kl_div(avg_p.detach(), current_p)
k = autograd.grad(kld, net.pi, retain_graph=True)[0]
#trust-region update
k_norm = torch.linalg.norm(k, dim=1).view(-1, 1, 1)**2
g_, k_ = g.unsqueeze(2), k.unsqueeze(1)
solve = (torch.bmm(k_, g_) - trpo_delta) / k_norm
new_g = g - torch.max(torch.tensor(0), solve.view(-1, 1))*k
q_loss = F.smooth_l1_loss(act_q, ret_q.detach())
global_optimizer.zero_grad()
net.policy.weight._grad = autograd.grad(-policy_obj, net.policy.weight, retain_graph=True)[0]
net.pi.backward(-new_g)
q_loss.backward()
for global_param, local_param in zip(global_net.parameters(), net.parameters()):
global_param._grad = local_param.grad
global_optimizer.step()
def train(net, global_avgnet, online_sample, buffer, global_optimizer):
train_process(net, global_avgnet, mini_batch(online_sample), global_optimizer)
if len(buffer) > start_train:
for _ in range(replay_iter):
key = random.randint(0, len(buffer)-train_interval)
replay_sample = itertools.islice(buffer, key, key+train_interval)
train_process(net, global_avgnet, mini_batch(replay_sample), global_optimizer)
def agent(rank):
env = gym.make('CartPole-v1')
net = Network()
net.load_state_dict(global_net.state_dict())
global_optimizer = optim.Adam(global_net.parameters(), lr=learning_rate)
buffer = deque(maxlen=buffer_len)
samples, score, step = [], 0.0, 0
for ep in range(EPISODES):
obs = env.reset()
done = False
while not done:
prob = net.p(torch.tensor(obs).unsqueeze(0).float())
prob_ = Categorical(prob)
action = prob_.sample().item()
next_obs, reward, done, info = env.step(action)
data = (obs, action, prob[0], reward/100.0, next_obs, done)
samples.append(data)
buffer.append(data)
score += reward
step += 1
obs = next_obs
if step%train_interval==0:
train(net, global_avgnet, samples, buffer, global_optimizer)
for a_param, param in zip(global_avgnet.parameters(), global_net.parameters()):
a_param.data.copy_(a_param.data*avgnet_ratio + param.data*(1-avgnet_ratio))
net.load_state_dict(global_net.state_dict())
samples = []
if ep%10==0 and ep!=0:
print('agent_num:{}, episode:{}, avg_score:{}'.format(rank,ep,score/10.0))
score = 0.0
env.close()
if __name__ == '__main__':
global_net, global_avgnet = Network(), Network()
global_avgnet.load_state_dict(global_net.state_dict())
agents = []
for rank in range(num_agents):
actor = T.Thread(target=agent, args=(rank,))
actor.start()
agents.append(actor)
for t in agents:
t.join()