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import numpy as np
import gymnasium as gym
from tqdm import tqdm
import argparse
import wandb
class MonteCarloAgent:
def __init__(self, env_name="CliffWalking-v0", gamma=0.99, epsilon=0.1, **kwargs):
print(f"# MonteCarloAgent - {env_name}")
print(f"- epsilon: {epsilon}")
print(f"- gamma: {gamma}")
self.env = gym.make(env_name, **kwargs)
self.epsilon, self.gamma = epsilon, gamma
self.n_states, self.n_actions = (
self.env.observation_space.n,
self.env.action_space.n,
)
print(f"- n_states: {self.n_states}")
print(f"- n_actions: {self.n_actions}")
self.reset()
def reset(self):
print("Resetting all state variables...")
self.Q = np.zeros((self.n_states, self.n_actions))
self.R = [[[] for _ in range(self.n_actions)] for _ in range(self.n_states)]
# An arbitrary e-greedy policy
self.Pi = np.full(
(self.n_states, self.n_actions), self.epsilon / self.n_actions
)
self.Pi[
np.arange(self.n_states),
np.random.randint(self.n_actions, size=self.n_states),
] = (
1 - self.epsilon + self.epsilon / self.n_actions
)
print("=" * 80)
print("Initial policy:")
print(self.Pi)
print("=" * 80)
def choose_action(self, state):
# Sample an action from the policy
return np.random.choice(self.n_actions, p=self.Pi[state])
def run_episode(self, max_steps=500, **kwargs):
state, _ = self.env.reset()
episode_hist = []
finished = False
# Generate an episode following the current policy
for _ in range(max_steps):
# Sample an action from the policy
action = self.choose_action(state)
# Take the action and observe the reward and next state
next_state, reward, finished, truncated, _ = self.env.step(action)
# Keeping track of the trajectory
episode_hist.append((state, action, reward))
state = next_state
# This is where the agent got to the goal.
# In the case in which agent jumped off the cliff, it is simply respawned at the start position without termination.
if finished or truncated:
break
return episode_hist, finished
def update(self, episode_hist):
G = 0
# For each step of the episode, in reverse order
for t in range(len(episode_hist) - 1, -1, -1):
state, action, reward = episode_hist[t]
# Update the expected return
G = self.gamma * G + reward
# If we haven't already visited this state-action pair up to this point, then we can update the Q-table and policy
# This is the first-visit MC method
if (state, action) not in [(x[0], x[1]) for x in episode_hist[:t]]:
self.R[state][action].append(G)
self.Q[state, action] = np.mean(self.R[state][action])
# Epsilon-greedy policy update
self.Pi[state] = np.full(self.n_actions, self.epsilon / self.n_actions)
# the greedy action is the one with the highest Q-value
self.Pi[state, np.argmax(self.Q[state])] = (
1 - self.epsilon + self.epsilon / self.n_actions
)
def train(self, n_train_episodes=2500, test_every=100, log_wandb=False, **kwargs):
print(f"Training agent for {n_train_episodes} episodes...")
train_running_success_rate, test_success_rate = 0.0, 0.0
stats = {
"train_running_success_rate": train_running_success_rate,
"test_success_rate": test_success_rate,
}
tqrange = tqdm(range(n_train_episodes))
tqrange.set_description("Training")
if log_wandb:
self.wandb_log_img(episode=None)
for e in tqrange:
episode_hist, finished = self.run_episode(**kwargs)
rewards = [x[2] for x in episode_hist]
total_reward, avg_reward = sum(rewards), np.mean(rewards)
train_running_success_rate = (
0.99 * train_running_success_rate + 0.01 * finished
)
self.update(episode_hist)
stats = {
"train_running_success_rate": train_running_success_rate,
"test_success_rate": test_success_rate,
"total_reward": total_reward,
"avg_reward": avg_reward,
}
tqrange.set_postfix(stats)
if e % test_every == 0:
test_success_rate = self.test(verbose=False, **kwargs)
if log_wandb:
self.wandb_log_img(episode=e)
stats["test_success_rate"] = test_success_rate
tqrange.set_postfix(stats)
if log_wandb:
wandb.log(stats)
def test(self, n_test_episodes=50, verbose=True, **kwargs):
if verbose:
print(f"Testing agent for {n_test_episodes} episodes...")
num_successes = 0
for e in range(n_test_episodes):
_, finished = self.run_episode(**kwargs)
num_successes += finished
if verbose:
word = "reached" if finished else "did not reach"
emoji = "🏁" if finished else "🚫"
print(
f"({e + 1:>{len(str(n_test_episodes))}}/{n_test_episodes}) - Agent {word} the goal {emoji}"
)
success_rate = num_successes / n_test_episodes
if verbose:
print(
f"Agent reached the goal in {num_successes}/{n_test_episodes} episodes ({success_rate * 100:.2f}%)"
)
return success_rate
def save_policy(self, fname="policy.npy"):
print(f"Saving policy to {fname}")
np.save(fname, self.Pi)
def load_policy(self, fname="policy.npy"):
print(f"Loading policy from {fname}")
self.Pi = np.load(fname)
def wandb_log_img(self, episode=None, mask=None):
caption_suffix = "Initial" if episode is None else f"After Episode {episode}"
wandb.log(
{
"Q-table": wandb.Image(
self.Q,
caption=f"Q-table - {caption_suffix}",
),
"Policy": wandb.Image(
self.Pi,
caption=f"Policy - {caption_suffix}",
),
}
)
def main():
parser = argparse.ArgumentParser()
### Train/Test parameters
parser.add_argument(
"--train",
action="store_true",
help="Use this flag to train the agent.",
)
parser.add_argument(
"--test",
type=str,
default=None,
help="Use this flag to test the agent. Provide the path to the policy file.",
)
parser.add_argument(
"--n_train_episodes",
type=int,
default=2000,
help="The number of episodes to train for. (default: 2000)",
)
parser.add_argument(
"--n_test_episodes",
type=int,
default=100,
help="The number of episodes to test for. (default: 100)",
)
parser.add_argument(
"--test_every",
type=int,
default=100,
help="During training, test the agent every n episodes. (default: 100)",
)
parser.add_argument(
"--max_steps",
type=int,
default=500,
help="The maximum number of steps per episode before the episode is forced to end. (default: 500)",
)
### Agent parameters
parser.add_argument(
"--gamma",
type=float,
default=0.99,
help="The value for the discount factor to use. (default: 0.99)",
)
parser.add_argument(
"--epsilon",
type=float,
default=0.1,
help="The value for the epsilon-greedy policy to use. (default: 0.1)",
)
### Environment parameters
parser.add_argument(
"--env",
type=str,
default="CliffWalking-v0",
help="The Gymnasium environment to use. (default: CliffWalking-v0)",
)
parser.add_argument(
"--render_mode",
type=str,
default=None,
help="Render mode passed to the gym.make() function. Use 'human' to render the environment. (default: None)",
)
parser.add_argument(
"--wandb_project",
type=str,
default=None,
help="WandB project name for logging. If not provided, no logging is done. (default: None)",
)
parser.add_argument(
"--wandb_group",
type=str,
default="monte-carlo",
help="WandB group name for logging. (default: monte-carlo)",
)
parser.add_argument(
"--wandb_job_type",
type=str,
default="train",
help="WandB job type for logging. (default: train)",
)
args = parser.parse_args()
mca = MonteCarloAgent(
args.env,
gamma=args.gamma,
epsilon=args.epsilon,
render_mode=args.render_mode,
)
run_name = f"mc_{args.env}_e{args.n_train_episodes}_s{args.max_steps}_g{args.gamma}_e{args.epsilon}"
try:
if args.train:
# Log to WandB
if args.wandb_project is not None:
wandb.init(
project=args.wandb_project,
name=run_name,
group=args.wandb_group,
job_type=args.wandb_job_type,
config=dict(args._get_kwargs()),
)
mca.train(
n_train_episodes=args.n_train_episodes,
test_every=args.test_every,
n_test_episodes=args.n_test_episodes,
max_steps=args.max_steps,
log_wandb=args.wandb_project is not None,
)
mca.save_policy(fname=f"policy_{run_name}.npy")
elif args.test is not None:
if not args.test.endswith(".npy"):
args.test += ".npy"
mca.load_policy(args.test)
mca.test(
n_test_episodes=args.n_test_episodes,
max_steps=args.max_steps,
)
else:
print("ERROR: Please provide either --train or --test.")
except KeyboardInterrupt:
print("Exiting...")
if __name__ == "__main__":
main()
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