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vpg.py
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import argparse, random, os
from typing import List, Tuple
import gymnasium as gym
from gymnasium.spaces import Space, Box, Discrete
import numpy as np
import torch
import torch.nn as nn
from torch.optim import Adam
from common.policy import CategoricalPolicy, DiagonalGaussianPolicy
from common.vf import StateValueFunction
from common.utils import set_seed, to_tensor, dim
from common.buffer import RolloutBuffer
import common.mpi_utils as mpi
from common.logger import Logger
class ActorCritic(nn.Module):
def __init__(self,
obs_space: Space,
action_space: Space,
hidden_sizes: List[int]=[64, 64],
activation: nn.Module=nn.Tanh,
device: str='cpu') -> None:
super().__init__()
obs_dim = dim(obs_space)
action_dim = dim(action_space)
# continous action space
if isinstance(action_space, Box):
self.actor = DiagonalGaussianPolicy(obs_dim, action_dim, hidden_sizes, activation).to(device)
# discrete action space
elif isinstance(action_space, Discrete):
self.actor = CategoricalPolicy(obs_dim, action_dim, hidden_sizes, activation).to(device)
self.critic = StateValueFunction(obs_dim, hidden_sizes, activation).to(device)
class VPG:
"""
Vanilla Policy Gradient w/ Generalized Advantage Estimators &
using rewards-to-go as target for the value function, which is chosen as the baseline
:param env: (str) Environment name
:param exp_name: (str) Experiment name
:param cpu: (int) Number of CPUs for parallel computing
:param seed: (int) Seed for RNG
:param hidden_sizes: (List[int]) Sizes of policy & value function networks' hidden layers.
:param pi_lr: (float) Learning rate for policy optimizer
:param v_lr: (float) Learning rate for value function optimizer
:param epochs: (int) Number of epochs
:param steps_per_epoch: (int) Maximum number of steps per epoch
:param train_v_iters: (int) Number of GD-steps to take on value function per epoch
:param max_ep_len: (int) Maximum episode/trajectory length
:param gamma: (float) Discount factor
:param lamb: (float) Lambda for GAE
:param save: (bool) Whether to save the final model.
:param save_every: (int) Model saving frequency.
:param render: (bool) Whether to render the training result.
:param plot: (bool) Whether to plot the statistics.
"""
def __init__(self, args) -> None:
self.env = gym.make(args.env)
set_seed(args.seed + 10 * mpi.proc_rank())
observation_space = self.env.observation_space
action_space = self.env.action_space
self.device = 'cuda:0' if torch.cuda.is_available() and args.cpu == 1 else 'cpu'
self.ac = ActorCritic(observation_space, action_space, args.hidden_sizes, device=self.device)
mpi.sync_params(self.ac)
self.actor_opt = Adam(self.ac.actor.parameters(), lr=args.pi_lr)
self.critic_opt = Adam(self.ac.critic.parameters(), lr=args.v_lr)
self.epochs = args.epochs
self.proc_steps_per_epoch = int(args.steps_per_epoch / mpi.n_procs())
self.steps_per_epoch = args.steps_per_epoch
self.train_v_iters = args.train_v_iters
self.max_ep_len = args.max_ep_len
self.buffer = RolloutBuffer(self.proc_steps_per_epoch, args.gamma, args.lamb)
self.save = args.save
self.save_every = args.save_every
self.render = args.render
self.plot = args.plot
if args.exp_name:
exp_name = args.exp_name
log_dir = os.path.join(os.getcwd(), 'data', exp_name, f'{exp_name}_s{args.seed}')
else:
log_dir = None
config_dict = vars(args)
config_dict['algo'] = 'vpg'
self.logger = Logger(log_dir=log_dir)
self.logger.save_config(config_dict)
self.logger.set_saver(self.ac)
def update_params(self) -> None:
"""Update policy and value networks' parameters"""
def compute_pi_loss(observations, actions, advs):
_, log_prob = self.ac.actor(observations, actions)
loss = -(log_prob * advs).mean()
return loss
def compute_v_loss(observations, rewards_to_go):
values = self.ac.critic(observations)
loss = ((values - rewards_to_go) ** 2).mean()
return loss, values
observations, actions, log_probs, advs, rewards_to_go \
= map(lambda x: x.to(self.device), self.buffer.get())
self.actor_opt.zero_grad()
pi_loss = compute_pi_loss(observations, actions, advs)
pi_loss.backward()
mpi.mpi_avg_grads(self.ac.actor)
self.actor_opt.step()
for _ in range(self.train_v_iters):
self.critic_opt.zero_grad()
v_loss, v_values = compute_v_loss(observations, rewards_to_go)
v_loss.backward()
mpi.mpi_avg_grads(self.ac.critic)
self.critic_opt.step()
self.logger.add({
'pi-loss': pi_loss.item(),
'v-loss': v_loss.item(),
'v-values': v_values.detach().cpu().numpy()
})
def selection_action(self, observation: np.ndarray, action_only: bool=True) -> Tuple[np.ndarray, np.ndarray, np.ndarray]:
observation = to_tensor(observation, device=self.device)
with torch.no_grad():
pi = self.ac.actor._distribution(observation)
action = pi.sample()
if action_only:
return action.cpu().numpy()
log_prob = self.ac.actor._log_prob(pi, action)
value = self.ac.critic(observation)
return action.cpu().numpy(), log_prob.cpu().numpy(), value.cpu().numpy()
def load(self, model_path: str) -> None:
"""Model loading"""
self.ac.load_state_dict(torch.load(model_path))
def train(self) -> None:
for epoch in range(1, self.epochs + 1):
step = 0
while step < self.proc_steps_per_epoch:
observation, _ = self.env.reset()
rewards = []
while True:
action, log_prob, value = self.selection_action(observation, action_only=False)
next_observation, reward, terminated, truncated, _ = self.env.step(action)
self.buffer.add(observation, action, reward, value.item(), log_prob.item())
observation = next_observation
rewards.append(reward)
step += 1
if terminated or truncated or len(rewards) == self.max_ep_len\
or step == self.proc_steps_per_epoch:
if terminated or truncated:
last_value = 0
self.logger.add({
'episode-return': sum(rewards),
'episode-length': len(rewards)
})
else:
_, _, last_value = self.selection_action(observation, action_only=False)
self.buffer.finish_rollout(last_value)
break
self.update_params()
self.logger.log_epoch('epoch', epoch)
self.logger.log_epoch('episode-return', need_optima=True)
self.logger.log_epoch('episode-length', average_only=True)
self.logger.log_epoch('pi-loss', average_only=True)
self.logger.log_epoch('v-loss', average_only=True)
self.logger.log_epoch('v-values', need_optima=True)
self.logger.log_epoch('total-env-interacts', epoch * self.steps_per_epoch)
self.logger.dump_epoch()
if self.save and epoch % self.save_every == 0:
self.logger.save_state()
self.env.close()
if self.render:
self.logger.render(self.selection_action)
if self.plot:
self.logger.plot()
if __name__ == '__main__':
parser = argparse.ArgumentParser(description='Vanilla Policy Gradient')
parser.add_argument('--env', type=str, default='HalfCheetah-v4',
help='Environment ID')
parser.add_argument('--exp-name', type=str, default='vpg',
help='Experiment name')
parser.add_argument('--cpu', type=int, default=4,
help='Number of CPUs for parallel computing')
parser.add_argument('--seed', type=int, default=0,
help='Seed for RNG')
parser.add_argument('--hidden-sizes', nargs='+', type=int, default=[64, 32],
help="Sizes of policy & value function networks' hidden layers")
parser.add_argument('--pi-lr', type=float, default=3e-4,
help='Learning rate for policy optimizer')
parser.add_argument('--v-lr', type=float, default=1e-3,
help='Learning rate for value function optimizer')
parser.add_argument('--epochs', type=int, default=50,
help='Number of epochs')
parser.add_argument('--steps-per-epoch', type=int, default=4000,
help='Maximum number of steps for each epoch')
parser.add_argument('--train-v-iters', type=int, default=80,
help='Number of gradient descent steps to take on value function per epoch')
parser.add_argument('--max-ep-len', type=int, default=1000,
help='Maximum episode/trajectory length')
parser.add_argument('--gamma', type=float, default=0.99,
help='Discount factor')
parser.add_argument('--lamb', type=float, default=0.97,
help='Lambda for Generalized Advantage Estimation')
parser.add_argument('--save', action='store_true',
help='Whether to save the final model')
parser.add_argument('--save-every', type=int, default=1,
help='Model saving frequency')
parser.add_argument('--render', action='store_true',
help='Whether to render the training result')
parser.add_argument('--plot', action='store_true',
help='Whether to plot the training statistics')
args = parser.parse_args()
mpi.mpi_fork(args.cpu)
mpi.setup_pytorch_for_mpi()
agent = VPG(args)
agent.train()