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# docs and experiment results can be found at https://docs.cleanrl.dev/rl-algorithms/c51/#c51_jaxpy
import argparse
import os
import random
import time
from distutils.util import strtobool
import flax
import flax.linen as nn
import gym
import jax
import jax.numpy as jnp
import numpy as np
import optax
from flax.training.train_state import TrainState
from stable_baselines3.common.buffers import ReplayBuffer
from torch.utils.tensorboard import SummaryWriter
def parse_args():
# fmt: off
parser = argparse.ArgumentParser()
parser.add_argument("--exp-name", type=str, default=os.path.basename(__file__).rstrip(".py"),
help="the name of this experiment")
parser.add_argument("--seed", type=int, default=1,
help="seed of the experiment")
parser.add_argument("--track", type=lambda x: bool(strtobool(x)), default=False, nargs="?", const=True,
help="if toggled, this experiment will be tracked with Weights and Biases")
parser.add_argument("--wandb-project-name", type=str, default="cleanRL",
help="the wandb's project name")
parser.add_argument("--wandb-entity", type=str, default=None,
help="the entity (team) of wandb's project")
parser.add_argument("--capture-video", type=lambda x: bool(strtobool(x)), default=False, nargs="?", const=True,
help="whether to capture videos of the agent performances (check out `videos` folder)")
parser.add_argument("--save-model", type=lambda x: bool(strtobool(x)), default=False, nargs="?", const=True,
help="whether to save model into the `runs/{run_name}` folder")
parser.add_argument("--upload-model", type=lambda x: bool(strtobool(x)), default=False, nargs="?", const=True,
help="whether to upload the saved model to huggingface")
parser.add_argument("--hf-entity", type=str, default="",
help="the user or org name of the model repository from the Hugging Face Hub")
# Algorithm specific arguments
parser.add_argument("--env-id", type=str, default="CartPole-v1",
help="the id of the environment")
parser.add_argument("--total-timesteps", type=int, default=500000,
help="total timesteps of the experiments")
parser.add_argument("--learning-rate", type=float, default=2.5e-4,
help="the learning rate of the optimizer")
parser.add_argument("--n-atoms", type=int, default=101,
help="the number of atoms")
parser.add_argument("--v-min", type=float, default=-100,
help="the number of atoms")
parser.add_argument("--v-max", type=float, default=100,
help="the number of atoms")
parser.add_argument("--buffer-size", type=int, default=10000,
help="the replay memory buffer size")
parser.add_argument("--gamma", type=float, default=0.99,
help="the discount factor gamma")
parser.add_argument("--target-network-frequency", type=int, default=500,
help="the timesteps it takes to update the target network")
parser.add_argument("--batch-size", type=int, default=128,
help="the batch size of sample from the reply memory")
parser.add_argument("--start-e", type=float, default=1,
help="the starting epsilon for exploration")
parser.add_argument("--end-e", type=float, default=0.05,
help="the ending epsilon for exploration")
parser.add_argument("--exploration-fraction", type=float, default=0.5,
help="the fraction of `total-timesteps` it takes from start-e to go end-e")
parser.add_argument("--learning-starts", type=int, default=10000,
help="timestep to start learning")
parser.add_argument("--train-frequency", type=int, default=10,
help="the frequency of training")
args = parser.parse_args()
# fmt: on
return args
def make_env(env_id, seed, idx, capture_video, run_name):
def thunk():
env = gym.make(env_id)
env = gym.wrappers.RecordEpisodeStatistics(env)
if capture_video:
if idx == 0:
env = gym.wrappers.RecordVideo(env, f"videos/{run_name}")
env.seed(seed)
env.action_space.seed(seed)
env.observation_space.seed(seed)
return env
return thunk
# ALGO LOGIC: initialize agent here:
class QNetwork(nn.Module):
action_dim: int
n_atoms: int
@nn.compact
def __call__(self, x):
x = nn.Dense(120)(x)
x = nn.relu(x)
x = nn.Dense(84)(x)
x = nn.relu(x)
x = nn.Dense(self.action_dim * self.n_atoms)(x)
x = x.reshape((x.shape[0], self.action_dim, self.n_atoms))
x = nn.softmax(x, axis=-1) # pmfs
return x
class TrainState(TrainState):
target_params: flax.core.FrozenDict
atoms: jnp.ndarray
def linear_schedule(start_e: float, end_e: float, duration: int, t: int):
slope = (end_e - start_e) / duration
return max(slope * t + start_e, end_e)
if __name__ == "__main__":
args = parse_args()
run_name = f"{args.env_id}__{args.exp_name}__{args.seed}__{int(time.time())}"
if args.track:
import wandb
wandb.init(
project=args.wandb_project_name,
entity=args.wandb_entity,
sync_tensorboard=True,
config=vars(args),
name=run_name,
monitor_gym=True,
save_code=True,
)
writer = SummaryWriter(f"runs/{run_name}")
writer.add_text(
"hyperparameters",
"|param|value|\n|-|-|\n%s" % ("\n".join([f"|{key}|{value}|" for key, value in vars(args).items()])),
)
# TRY NOT TO MODIFY: seeding
random.seed(args.seed)
np.random.seed(args.seed)
key = jax.random.PRNGKey(args.seed)
key, q_key = jax.random.split(key, 2)
# env setup
envs = gym.vector.SyncVectorEnv([make_env(args.env_id, args.seed, 0, args.capture_video, run_name)])
assert isinstance(envs.single_action_space, gym.spaces.Discrete), "only discrete action space is supported"
obs = envs.reset()
q_network = QNetwork(action_dim=envs.single_action_space.n, n_atoms=args.n_atoms)
q_state = TrainState.create(
apply_fn=q_network.apply,
params=q_network.init(q_key, obs),
target_params=q_network.init(q_key, obs),
# directly using jnp.linspace leads to numerical errors
atoms=jnp.asarray(np.linspace(args.v_min, args.v_max, num=args.n_atoms)),
tx=optax.adam(learning_rate=args.learning_rate, eps=0.01 / args.batch_size),
)
q_network.apply = jax.jit(q_network.apply)
# This step is not necessary as init called on same observation and key will always lead to same initializations
q_state = q_state.replace(target_params=optax.incremental_update(q_state.params, q_state.target_params, 1))
rb = ReplayBuffer(
args.buffer_size,
envs.single_observation_space,
envs.single_action_space,
"cpu",
handle_timeout_termination=True,
)
@jax.jit
def update(q_state, observations, actions, next_observations, rewards, dones):
next_pmfs = q_network.apply(q_state.target_params, next_observations) # (batch_size, num_actions, num_atoms)
next_vals = (next_pmfs * q_state.atoms).sum(axis=-1) # (batch_size, num_actions)
next_action = jnp.argmax(next_vals, axis=-1) # (batch_size,)
next_pmfs = next_pmfs[np.arange(next_pmfs.shape[0]), next_action]
next_atoms = rewards + args.gamma * q_state.atoms * (1 - dones)
# projection
delta_z = q_state.atoms[1] - q_state.atoms[0]
tz = jnp.clip(next_atoms, a_min=(args.v_min), a_max=(args.v_max))
b = (tz - args.v_min) / delta_z
l = jnp.clip(jnp.floor(b), a_min=0, a_max=args.n_atoms - 1)
u = jnp.clip(jnp.ceil(b), a_min=0, a_max=args.n_atoms - 1)
# (l == u).astype(jnp.float) handles the case where bj is exactly an integer
# example bj = 1, then the upper ceiling should be uj= 2, and lj= 1
d_m_l = (u + (l == u).astype(jnp.float32) - b) * next_pmfs
d_m_u = (b - l) * next_pmfs
target_pmfs = jnp.zeros_like(next_pmfs)
def project_to_bins(i, val):
val = val.at[i, l[i].astype(jnp.int32)].add(d_m_l[i])
val = val.at[i, u[i].astype(jnp.int32)].add(d_m_u[i])
return val
target_pmfs = jax.lax.fori_loop(0, target_pmfs.shape[0], project_to_bins, target_pmfs)
def loss(q_params, observations, actions, target_pmfs):
pmfs = q_network.apply(q_params, observations)
old_pmfs = pmfs[np.arange(pmfs.shape[0]), actions.squeeze()]
old_pmfs_l = jnp.clip(old_pmfs, a_min=1e-5, a_max=1 - 1e-5)
loss = (-(target_pmfs * jnp.log(old_pmfs_l)).sum(-1)).mean()
return loss, (old_pmfs * q_state.atoms).sum(-1)
(loss_value, old_values), grads = jax.value_and_grad(loss, has_aux=True)(
q_state.params, observations, actions, target_pmfs
)
q_state = q_state.apply_gradients(grads=grads)
return loss_value, old_values, q_state
start_time = time.time()
# TRY NOT TO MODIFY: start the game
obs = envs.reset()
for global_step in range(args.total_timesteps):
# ALGO LOGIC: put action logic here
epsilon = linear_schedule(args.start_e, args.end_e, args.exploration_fraction * args.total_timesteps, global_step)
if random.random() < epsilon:
actions = np.array([envs.single_action_space.sample() for _ in range(envs.num_envs)])
else:
pmfs = q_network.apply(q_state.params, obs)
q_vals = (pmfs * q_state.atoms).sum(axis=-1)
actions = q_vals.argmax(axis=-1)
actions = jax.device_get(actions)
# TRY NOT TO MODIFY: execute the game and log data.
next_obs, rewards, dones, infos = envs.step(actions)
# TRY NOT TO MODIFY: record rewards for plotting purposes
for info in infos:
if "episode" in info.keys():
print(f"global_step={global_step}, episodic_return={info['episode']['r']}")
writer.add_scalar("charts/episodic_return", info["episode"]["r"], global_step)
writer.add_scalar("charts/episodic_length", info["episode"]["l"], global_step)
writer.add_scalar("charts/epsilon", epsilon, global_step)
break
# TRY NOT TO MODIFY: save data to reply buffer; handle `terminal_observation`
real_next_obs = next_obs.copy()
for idx, d in enumerate(dones):
if d:
real_next_obs[idx] = infos[idx]["terminal_observation"]
rb.add(obs, real_next_obs, actions, rewards, dones, infos)
# TRY NOT TO MODIFY: CRUCIAL step easy to overlook
obs = next_obs
# ALGO LOGIC: training.
if global_step > args.learning_starts and global_step % args.train_frequency == 0:
data = rb.sample(args.batch_size)
loss, old_val, q_state = update(
q_state,
data.observations.numpy(),
data.actions.numpy(),
data.next_observations.numpy(),
data.rewards.numpy(),
data.dones.numpy(),
)
if global_step % 100 == 0:
writer.add_scalar("losses/loss", jax.device_get(loss), global_step)
writer.add_scalar("losses/q_values", jax.device_get(old_val.mean()), global_step)
print("SPS:", int(global_step / (time.time() - start_time)))
writer.add_scalar("charts/SPS", int(global_step / (time.time() - start_time)), global_step)
# update the target network
if global_step % args.target_network_frequency == 0:
q_state = q_state.replace(target_params=optax.incremental_update(q_state.params, q_state.target_params, 1))
if args.save_model:
model_path = f"runs/{run_name}/{args.exp_name}.cleanrl_model"
model_data = {
"model_weights": q_state.params,
"args": vars(args),
}
with open(model_path, "wb") as f:
f.write(flax.serialization.to_bytes(model_data))
print(f"model saved to {model_path}")
from cleanrl_utils.evals.c51_jax_eval import evaluate
episodic_returns = evaluate(
model_path,
make_env,
args.env_id,
eval_episodes=10,
run_name=f"{run_name}-eval",
Model=QNetwork,
epsilon=0.05,
)
for idx, episodic_return in enumerate(episodic_returns):
writer.add_scalar("eval/episodic_return", episodic_return, idx)
if args.upload_model:
from cleanrl_utils.huggingface import push_to_hub
repo_name = f"{args.env_id}-{args.exp_name}-seed{args.seed}"
repo_id = f"{args.hf_entity}/{repo_name}" if args.hf_entity else repo_name
push_to_hub(args, episodic_returns, repo_id, "DQN", f"runs/{run_name}", f"videos/{run_name}-eval")
envs.close()
writer.close()