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import torch
import torch.nn as nn
import torch.nn.functional as F
import math
import utils
import hydra
import os
from agent import Agent
from agent.critic import DoubleQCritic
from agent.actor import DiagGaussianActor
def compute_state_entropy(obs, full_obs, k):
batch_size = 500
with torch.no_grad():
dists = []
for idx in range(len(full_obs) // batch_size + 1):
start = idx * batch_size
end = (idx + 1) * batch_size
dist = torch.norm(
obs[:, None, :] - full_obs[None, start:end, :], dim=-1, p=2
)
dists.append(dist)
dists = torch.cat(dists, dim=1)
knn_dists = torch.kthvalue(dists, k=k + 1, dim=1).values
state_entropy = knn_dists
return state_entropy.unsqueeze(1)
class SACAgent(Agent):
"""SAC algorithm."""
def __init__(self, obs_dim, action_dim, action_range, device, critic_cfg,
actor_cfg, discount, init_temperature, alpha_lr, alpha_betas,
actor_lr, actor_betas, actor_update_frequency, critic_lr,
critic_betas, critic_tau, critic_target_update_frequency,
batch_size, learnable_temperature,
normalize_state_entropy=True):
super().__init__()
self.action_range = action_range
self.device = torch.device(device)
self.discount = discount
self.critic_tau = critic_tau
self.actor_update_frequency = actor_update_frequency
self.critic_target_update_frequency = critic_target_update_frequency
self.batch_size = batch_size
self.learnable_temperature = learnable_temperature
self.critic_cfg = critic_cfg
self.critic_lr = critic_lr
self.critic_betas = critic_betas
self.s_ent_stats = utils.TorchRunningMeanStd(shape=[1], device=device)
self.normalize_state_entropy = normalize_state_entropy
self.init_temperature = init_temperature
self.alpha_lr = alpha_lr
self.alpha_betas = alpha_betas
self.actor_cfg = actor_cfg
self.actor_betas = actor_betas
self.alpha_lr = alpha_lr
self.critic = hydra.utils.instantiate(critic_cfg).to(self.device)
self.critic_target = hydra.utils.instantiate(critic_cfg).to(
self.device)
self.critic_target.load_state_dict(self.critic.state_dict())
self.actor = hydra.utils.instantiate(actor_cfg).to(self.device)
self.log_alpha = torch.tensor(np.log(init_temperature)).to(self.device)
self.log_alpha.requires_grad = True
# set target entropy to -|A|
self.target_entropy = -action_dim
# optimizers
self.actor_optimizer = torch.optim.Adam(
self.actor.parameters(),
lr=actor_lr,
betas=actor_betas)
self.critic_optimizer = torch.optim.Adam(
self.critic.parameters(),
lr=critic_lr,
betas=critic_betas)
self.log_alpha_optimizer = torch.optim.Adam(
[self.log_alpha],
lr=alpha_lr,
betas=alpha_betas)
# change mode
self.train()
self.critic_target.train()
def reset_critic(self):
self.critic = hydra.utils.instantiate(self.critic_cfg).to(self.device)
self.critic_target = hydra.utils.instantiate(self.critic_cfg).to(
self.device)
self.critic_target.load_state_dict(self.critic.state_dict())
self.critic_optimizer = torch.optim.Adam(
self.critic.parameters(),
lr=self.critic_lr,
betas=self.critic_betas)
def reset_actor(self):
# reset log_alpha
self.log_alpha = torch.tensor(np.log(self.init_temperature)).to(self.device)
self.log_alpha.requires_grad = True
self.log_alpha_optimizer = torch.optim.Adam(
[self.log_alpha],
lr=self.alpha_lr,
betas=self.alpha_betas)
# reset actor
self.actor = hydra.utils.instantiate(self.actor_cfg).to(self.device)
self.actor_optimizer = torch.optim.Adam(
self.actor.parameters(),
lr=self.actor_lr,
betas=self.actor_betas)
def train(self, training=True):
self.training = training
self.actor.train(training)
self.critic.train(training)
@property
def alpha(self):
return self.log_alpha.exp()
def act(self, obs, sample=False):
obs = torch.FloatTensor(obs).to(self.device)
obs = obs.unsqueeze(0)
dist = self.actor(obs)
action = dist.sample() if sample else dist.mean
action = action.clamp(*self.action_range)
assert action.ndim == 2 and action.shape[0] == 1
return utils.to_np(action[0])
def update_critic(self, obs, action, reward, next_obs,
not_done, logger, step, print_flag=True):
dist = self.actor(next_obs)
next_action = dist.rsample()
log_prob = dist.log_prob(next_action).sum(-1, keepdim=True)
target_Q1, target_Q2 = self.critic_target(next_obs, next_action)
target_V = torch.min(target_Q1,
target_Q2) - self.alpha.detach() * log_prob
target_Q = reward + (not_done * self.discount * target_V)
target_Q = target_Q.detach()
# get current Q estimates
current_Q1, current_Q2 = self.critic(obs, action)
critic_loss = F.mse_loss(current_Q1, target_Q) + F.mse_loss(
current_Q2, target_Q)
if print_flag:
logger.log('train_critic/loss', critic_loss, step)
# Optimize the critic
self.critic_optimizer.zero_grad()
critic_loss.backward()
self.critic_optimizer.step()
# self.critic.log(logger, step)
def update_critic_state_ent(
self, obs, full_obs, action, next_obs, not_done, logger,
step, K=5, print_flag=True):
dist = self.actor(next_obs)
next_action = dist.rsample()
log_prob = dist.log_prob(next_action).sum(-1, keepdim=True)
target_Q1, target_Q2 = self.critic_target(next_obs, next_action)
target_V = torch.min(target_Q1, target_Q2) - self.alpha.detach() * log_prob
# compute state entropy
state_entropy = compute_state_entropy(obs, full_obs, k=K)
if print_flag:
logger.log("train_critic/entropy", state_entropy.mean(), step)
logger.log("train_critic/entropy_max", state_entropy.max(), step)
logger.log("train_critic/entropy_min", state_entropy.min(), step)
self.s_ent_stats.update(state_entropy)
norm_state_entropy = state_entropy / self.s_ent_stats.std
if print_flag:
logger.log("train_critic/norm_entropy", norm_state_entropy.mean(), step)
logger.log("train_critic/norm_entropy_max", norm_state_entropy.max(), step)
logger.log("train_critic/norm_entropy_min", norm_state_entropy.min(), step)
if self.normalize_state_entropy:
state_entropy = norm_state_entropy
target_Q = state_entropy + (not_done * self.discount * target_V)
target_Q = target_Q.detach()
# get current Q estimates
current_Q1, current_Q2 = self.critic(obs, action)
critic_loss = F.mse_loss(current_Q1, target_Q) + F.mse_loss(
current_Q2, target_Q)
if print_flag:
logger.log('train_critic/loss', critic_loss, step)
# Optimize the critic
self.critic_optimizer.zero_grad()
critic_loss.backward()
self.critic_optimizer.step()
# self.critic.log(logger, step)
def save(self, model_dir, step):
torch.save(
self.actor.state_dict(), '%s/actor_%s.pt' % (model_dir, step)
)
torch.save(
self.critic.state_dict(), '%s/critic_%s.pt' % (model_dir, step)
)
torch.save(
self.critic_target.state_dict(), '%s/critic_target_%s.pt' % (model_dir, step)
)
def load(self, model_dir, step):
file_dir = os.path.dirname(os.path.dirname(os.path.realpath(__file__)))
model_dir = os.path.join(file_dir, model_dir)
self.actor.load_state_dict(
torch.load('%s/actor_%s.pt' % (model_dir, step))
)
self.critic.load_state_dict(
torch.load('%s/critic_%s.pt' % (model_dir, step))
)
self.critic_target.load_state_dict(
torch.load('%s/critic_target_%s.pt' % (model_dir, step))
)
def update_actor_and_alpha(self, obs, logger, step, print_flag=False):
dist = self.actor(obs)
action = dist.rsample()
log_prob = dist.log_prob(action).sum(-1, keepdim=True)
actor_Q1, actor_Q2 = self.critic(obs, action)
actor_Q = torch.min(actor_Q1, actor_Q2)
actor_loss = (self.alpha.detach() * log_prob - actor_Q).mean()
if print_flag:
logger.log('train_actor/loss', actor_loss, step)
logger.log('train_actor/target_entropy', self.target_entropy, step)
logger.log('train_actor/entropy', -log_prob.mean(), step)
# optimize the actor
self.actor_optimizer.zero_grad()
actor_loss.backward()
self.actor_optimizer.step()
# self.actor.log(logger, step)
if self.learnable_temperature:
self.log_alpha_optimizer.zero_grad()
alpha_loss = (self.alpha *
(-log_prob - self.target_entropy).detach()).mean()
if print_flag:
logger.log('train_alpha/loss', alpha_loss, step)
logger.log('train_alpha/value', self.alpha, step)
alpha_loss.backward()
self.log_alpha_optimizer.step()
def update(self, replay_buffer, logger, step, gradient_update=1):
for index in range(gradient_update):
obs, action, reward, next_obs, not_done, not_done_no_max = replay_buffer.sample(
self.batch_size)
print_flag = False
if index == gradient_update -1:
logger.log('train/batch_reward', reward.mean(), step)
print_flag = True
self.update_critic(obs, action, reward, next_obs, not_done_no_max,
logger, step, print_flag)
if step % self.actor_update_frequency == 0:
self.update_actor_and_alpha(obs, logger, step, print_flag)
if step % self.critic_target_update_frequency == 0:
utils.soft_update_params(self.critic, self.critic_target,
self.critic_tau)
def update_after_reset(self, replay_buffer, logger, step, gradient_update=1, policy_update=True):
for index in range(gradient_update):
obs, action, reward, next_obs, not_done, not_done_no_max = replay_buffer.sample(
self.batch_size)
print_flag = False
if index == gradient_update -1:
logger.log('train/batch_reward', reward.mean(), step)
print_flag = True
self.update_critic(obs, action, reward, next_obs, not_done_no_max,
logger, step, print_flag)
if index % self.actor_update_frequency == 0 and policy_update:
self.update_actor_and_alpha(obs, logger, step, print_flag)
if index % self.critic_target_update_frequency == 0:
utils.soft_update_params(self.critic, self.critic_target,
self.critic_tau)
def update_state_ent(self, replay_buffer, logger, step, gradient_update=1, K=5):
for index in range(gradient_update):
obs, full_obs, action, reward, next_obs, not_done, not_done_no_max = replay_buffer.sample_state_ent(
self.batch_size)
print_flag = False
if index == gradient_update -1:
logger.log('train/batch_reward', reward.mean(), step)
print_flag = True
self.update_critic_state_ent(
obs, full_obs, action, next_obs, not_done_no_max,
logger, step, K=K, print_flag=print_flag)
if step % self.actor_update_frequency == 0:
self.update_actor_and_alpha(obs, logger, step, print_flag)
if step % self.critic_target_update_frequency == 0:
utils.soft_update_params(self.critic, self.critic_target,
self.critic_tau) |