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PPO.py
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PPO.py
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import torch
import torch.nn as nn
from torch.distributions import MultivariateNormal
from torch.distributions import Categorical
################################## set device ##################################
print("============================================================================================")
# set device to cpu or cuda
device = torch.device('cpu')
if(torch.cuda.is_available()):
device = torch.device('cuda:4')
torch.cuda.empty_cache()
print("Device set to : " + str(torch.cuda.get_device_name(device)))
else:
print("Device set to : cpu")
print("============================================================================================")
################################## PPO Policy ##################################
class RolloutBuffer:
def __init__(self):
self.actions = []
self.states = []
self.logprobs = []
self.rewards = []
self.state_values = []
self.is_terminals = []
def clear(self):
del self.actions[:]
del self.states[:]
del self.logprobs[:]
del self.rewards[:]
del self.state_values[:]
del self.is_terminals[:]
class Actor(nn.Module):
def __init__(self, state_dim, action_dim):
super(Actor,self).__init__()
self.fc1 = nn.Linear(state_dim, 64)
self.fc2 = nn.Linear(64, 64)
self.fc3 = nn.Linear(64, action_dim)
def forward(self, x):
x=self.fc1(x)
x= torch.tanh(x)
x=self.fc2(x)
x = torch.tanh(x)
x= self.fc3(x)
x = torch.softmax(x, dim=-1)
return x
# class Critic(nn.Module):
# def __init__(self, state_dim):
# super(Critic,self).__init__()
# self.fc1 = nn.Linear(state_dim, 64)
# self.fc2 =
class ActorCritic(nn.Module):
def __init__(self, state_dim, action_dim, has_continuous_action_space, action_std_init):
super(ActorCritic, self).__init__()
self.has_continuous_action_space = has_continuous_action_space
if has_continuous_action_space:
self.action_dim = action_dim
self.action_var = torch.full((action_dim,), action_std_init * action_std_init).to(device)
# actor
if has_continuous_action_space :
self.actor = nn.Sequential(
nn.Linear(state_dim, 64),
nn.Tanh(),
nn.Linear(64, 64),
nn.Tanh(),
nn.Linear(64, action_dim),
nn.Tanh()
)
else:
# self.actor = nn.Sequential(
# nn.Linear(state_dim, 64),
# nn.Tanh(),
# nn.Linear(64, 64),
# nn.Tanh(),
# nn.Linear(64, action_dim),
# nn.Softmax(dim=-1)
# )
self.actor = Actor(state_dim, action_dim).to(device)
# critic
self.critic = nn.Sequential(
nn.Linear(state_dim, 64),
nn.Tanh(),
nn.Linear(64, 64),
nn.Tanh(),
nn.Linear(64, 1)
)
def set_action_std(self, new_action_std):
if self.has_continuous_action_space:
self.action_var = torch.full((self.action_dim,), new_action_std * new_action_std).to(device)
else:
print("--------------------------------------------------------------------------------------------")
print("WARNING : Calling ActorCritic::set_action_std() on discrete action space policy")
print("--------------------------------------------------------------------------------------------")
def forward(self):
raise NotImplementedError
def act(self, state):
if self.has_continuous_action_space:
action_mean = self.actor(state)
cov_mat = torch.diag(self.action_var).unsqueeze(dim=0)
dist = MultivariateNormal(action_mean, cov_mat)
else:
action_probs = self.actor(state)
dist = Categorical(action_probs)
action = dist.sample()
action_logprob = dist.log_prob(action)
state_val = self.critic(state)
return action.detach(), action_logprob.detach(), state_val.detach()
def evaluate(self, state, action):
if self.has_continuous_action_space:
action_mean = self.actor(state)
action_var = self.action_var.expand_as(action_mean)
cov_mat = torch.diag_embed(action_var).to(device)
dist = MultivariateNormal(action_mean, cov_mat)
# For Single Action Environments.
if self.action_dim == 1:
action = action.reshape(-1, self.action_dim)
else:
action_probs = self.actor(state)
dist = Categorical(action_probs)
action_logprobs = dist.log_prob(action)
dist_entropy = dist.entropy()
state_values = self.critic(state)
return action_logprobs, state_values, dist_entropy
class PPO:
def __init__(self, state_dim, action_dim, lr_actor, lr_critic, gamma, K_epochs, eps_clip, has_continuous_action_space, action_std_init=0.6):
self.has_continuous_action_space = has_continuous_action_space
if has_continuous_action_space:
self.action_std = action_std_init
self.gamma = gamma
self.eps_clip = eps_clip
self.K_epochs = K_epochs
self.buffer = RolloutBuffer()
self.policy = ActorCritic(state_dim, action_dim, has_continuous_action_space, action_std_init).to(device)
self.optimizer = torch.optim.Adam([
{'params': self.policy.actor.parameters(), 'lr': lr_actor},
{'params': self.policy.critic.parameters(), 'lr': lr_critic}
])
self.policy_old = ActorCritic(state_dim, action_dim, has_continuous_action_space, action_std_init).to(device)
self.policy_old.load_state_dict(self.policy.state_dict())
self.MseLoss = nn.MSELoss()
def set_action_std(self, new_action_std):
if self.has_continuous_action_space:
self.action_std = new_action_std
self.policy.set_action_std(new_action_std)
self.policy_old.set_action_std(new_action_std)
else:
print("--------------------------------------------------------------------------------------------")
print("WARNING : Calling PPO::set_action_std() on discrete action space policy")
print("--------------------------------------------------------------------------------------------")
def decay_action_std(self, action_std_decay_rate, min_action_std):
print("--------------------------------------------------------------------------------------------")
if self.has_continuous_action_space:
self.action_std = self.action_std - action_std_decay_rate
self.action_std = round(self.action_std, 4)
if (self.action_std <= min_action_std):
self.action_std = min_action_std
print("setting actor output action_std to min_action_std : ", self.action_std)
else:
print("setting actor output action_std to : ", self.action_std)
self.set_action_std(self.action_std)
else:
print("WARNING : Calling PPO::decay_action_std() on discrete action space policy")
print("--------------------------------------------------------------------------------------------")
def select_action(self, state):
if self.has_continuous_action_space:
with torch.no_grad():
state = torch.FloatTensor(state).to(device)
action, action_logprob, state_val = self.policy_old.act(state)
self.buffer.states.append(state)
self.buffer.actions.append(action)
self.buffer.logprobs.append(action_logprob)
self.buffer.state_values.append(state_val)
return action.detach().cpu().numpy().flatten()
else:
with torch.no_grad():
state = torch.tensor(state,dtype=torch.float).to(device) #weight是torch.float类型
state = state.unsqueeze(0) #扩展维度,从0d到1d, (0) -> ([0])
action, action_logprob, state_val = self.policy_old.act(state)
self.buffer.states.append(state)
self.buffer.actions.append(action)
self.buffer.logprobs.append(action_logprob)
self.buffer.state_values.append(state_val)
return action.item()
def update(self):
# Monte Carlo estimate of returns
rewards = []
discounted_reward = 0
for reward, is_terminal in zip(reversed(self.buffer.rewards), reversed(self.buffer.is_terminals)):
if is_terminal:
discounted_reward = 0
discounted_reward = reward + (self.gamma * discounted_reward)
rewards.insert(0, discounted_reward)
# Normalizing the rewards
rewards = torch.tensor(rewards, dtype=torch.float32).to(device)
rewards = (rewards - rewards.mean()) / (rewards.std() + 1e-7)
# convert list to tensor
old_states = torch.stack(self.buffer.states, dim=0).detach().to(device)
old_actions = torch.stack(self.buffer.actions, dim=0).detach().to(device)
old_logprobs = torch.stack(self.buffer.logprobs, dim=0).detach().to(device)
old_state_values =torch.stack(self.buffer.state_values, dim=0).detach().to(device)
# old_actions = old_actions.unsqueeze(1) #[743] ->[743,1]
# old_states = old_states.unsqueeze(1)
# calculate advantages
advantages = rewards.detach() - old_state_values.detach()
# Optimize policy for K epochs
for _ in range(self.K_epochs):
# Evaluating old actions and values
logprobs, state_values, dist_entropy = self.policy.evaluate(old_states, old_actions)
# match state_values tensor dimensions with rewards tensor
state_values = torch.squeeze(state_values)
# Finding the ratio (pi_theta / pi_theta__old)
ratios = torch.exp(logprobs - old_logprobs.detach())
# Finding Surrogate Loss
surr1 = ratios * advantages
surr2 = torch.clamp(ratios, 1-self.eps_clip, 1+self.eps_clip) * advantages
# final loss of clipped objective PPO
loss = -torch.min(surr1, surr2) + 0.5 * self.MseLoss(state_values, rewards) - 0.01 * dist_entropy
# take gradient step
self.optimizer.zero_grad()
loss.mean().backward()
self.optimizer.step()
# Copy new weights into old policy
self.policy_old.load_state_dict(self.policy.state_dict())
# clear buffer
self.buffer.clear()
def save(self, checkpoint_path):
torch.save(self.policy_old.state_dict(), checkpoint_path)
def load(self, checkpoint_path):
self.policy_old.load_state_dict(torch.load(checkpoint_path, map_location=lambda storage, loc: storage))
self.policy.load_state_dict(torch.load(checkpoint_path, map_location=lambda storage, loc: storage))