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ff_mappo.py
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# Copyright 2022 InstaDeep Ltd. All rights reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import copy
import time
from typing import Any, Dict, Tuple
import chex
import flax
import hydra
import jax
import jax.numpy as jnp
import optax
from colorama import Fore, Style
from flax.core.frozen_dict import FrozenDict
from jax import tree
from omegaconf import DictConfig, OmegaConf
from rich.pretty import pprint
from mava.evaluator import get_eval_fn, make_ff_eval_act_fn
from mava.networks import FeedForwardActor as Actor
from mava.networks import FeedForwardValueNet as Critic
from mava.systems.ppo.types import LearnerState, OptStates, Params, PPOTransition
from mava.types import ActorApply, CriticApply, ExperimentOutput, LearnerFn, MarlEnv, Metrics
from mava.utils import make_env as environments
from mava.utils.checkpointing import Checkpointer
from mava.utils.config import check_total_timesteps
from mava.utils.jax_utils import merge_leading_dims, unreplicate_batch_dim, unreplicate_n_dims
from mava.utils.logger import LogEvent, MavaLogger
from mava.utils.network_utils import get_action_head
from mava.utils.training import make_learning_rate
from mava.wrappers.episode_metrics import get_final_step_metrics
def get_learner_fn(
env: MarlEnv,
apply_fns: Tuple[ActorApply, CriticApply],
update_fns: Tuple[optax.TransformUpdateFn, optax.TransformUpdateFn],
config: DictConfig,
) -> LearnerFn[LearnerState]:
"""Get the learner function."""
# Unpack apply and update functions.
actor_apply_fn, critic_apply_fn = apply_fns
actor_update_fn, critic_update_fn = update_fns
def _update_step(learner_state: LearnerState, _: Any) -> Tuple[LearnerState, Tuple]:
"""A single update of the network.
This function steps the environment and records the trajectory batch for
training. It then calculates advantages and targets based on the recorded
trajectory and updates the actor and critic networks based on the calculated
losses.
Args:
----
learner_state (NamedTuple):
- params (Params): The current model parameters.
- opt_states (OptStates): The current optimizer states.
- key (PRNGKey): The random number generator state.
- env_state (State): The environment state.
- last_timestep (TimeStep): The last timestep in the current trajectory.
_ (Any): The current metrics info.
"""
def _env_step(
learner_state: LearnerState, _: Any
) -> Tuple[LearnerState, Tuple[PPOTransition, Metrics]]:
"""Step the environment."""
params, opt_states, key, env_state, last_timestep = learner_state
# Select action
key, policy_key = jax.random.split(key)
actor_policy = actor_apply_fn(params.actor_params, last_timestep.observation)
value = critic_apply_fn(params.critic_params, last_timestep.observation)
action = actor_policy.sample(seed=policy_key)
log_prob = actor_policy.log_prob(action)
# Step environment
env_state, timestep = jax.vmap(env.step, in_axes=(0, 0))(env_state, action)
done = timestep.last().repeat(env.num_agents).reshape(config.arch.num_envs, -1)
transition = PPOTransition(
done, action, value, timestep.reward, log_prob, last_timestep.observation
)
learner_state = LearnerState(params, opt_states, key, env_state, timestep)
return learner_state, (transition, timestep.extras["episode_metrics"])
# Step environment for rollout length
learner_state, (traj_batch, episode_metrics) = jax.lax.scan(
_env_step, learner_state, None, config.system.rollout_length
)
# Calculate advantage
params, opt_states, key, env_state, last_timestep = learner_state
last_val = critic_apply_fn(params.critic_params, last_timestep.observation)
def _calculate_gae(
traj_batch: PPOTransition, last_val: chex.Array
) -> Tuple[chex.Array, chex.Array]:
"""Calculate the GAE."""
def _get_advantages(gae_and_next_value: Tuple, transition: PPOTransition) -> Tuple:
"""Calculate the GAE for a single transition."""
gae, next_value = gae_and_next_value
done, value, reward = (
transition.done,
transition.value,
transition.reward,
)
gamma = config.system.gamma
delta = reward + gamma * next_value * (1 - done) - value
gae = delta + gamma * config.system.gae_lambda * (1 - done) * gae
return (gae, value), gae
_, advantages = jax.lax.scan(
_get_advantages,
(jnp.zeros_like(last_val), last_val),
traj_batch,
reverse=True,
unroll=16,
)
return advantages, advantages + traj_batch.value
advantages, targets = _calculate_gae(traj_batch, last_val)
def _update_epoch(update_state: Tuple, _: Any) -> Tuple:
"""Update the network for a single epoch."""
def _update_minibatch(train_state: Tuple, batch_info: Tuple) -> Tuple:
"""Update the network for a single minibatch."""
params, opt_states, key = train_state
traj_batch, advantages, targets = batch_info
def _actor_loss_fn(
actor_params: FrozenDict,
traj_batch: PPOTransition,
gae: chex.Array,
key: chex.PRNGKey,
) -> Tuple:
"""Calculate the actor loss."""
# Rerun network
actor_policy = actor_apply_fn(actor_params, traj_batch.obs)
log_prob = actor_policy.log_prob(traj_batch.action)
# Calculate actor loss
ratio = jnp.exp(log_prob - traj_batch.log_prob)
# Nomalise advantage at minibatch level
gae = (gae - gae.mean()) / (gae.std() + 1e-8)
actor_loss1 = ratio * gae
actor_loss2 = (
jnp.clip(
ratio,
1.0 - config.system.clip_eps,
1.0 + config.system.clip_eps,
)
* gae
)
actor_loss = -jnp.minimum(actor_loss1, actor_loss2)
actor_loss = actor_loss.mean()
# The seed will be used in the TanhTransformedDistribution:
entropy = actor_policy.entropy(seed=key).mean()
total_actor_loss = actor_loss - config.system.ent_coef * entropy
return total_actor_loss, (actor_loss, entropy)
def _critic_loss_fn(
critic_params: FrozenDict,
traj_batch: PPOTransition,
targets: chex.Array,
) -> Tuple:
"""Calculate the critic loss."""
# Rerun network
value = critic_apply_fn(critic_params, traj_batch.obs)
# Clipped MSE loss
value_pred_clipped = traj_batch.value + (value - traj_batch.value).clip(
-config.system.clip_eps, config.system.clip_eps
)
value_losses = jnp.square(value - targets)
value_losses_clipped = jnp.square(value_pred_clipped - targets)
value_loss = 0.5 * jnp.maximum(value_losses, value_losses_clipped).mean()
total_value_loss = config.system.vf_coef * value_loss
return total_value_loss, value_loss
# Calculate actor loss
key, entropy_key = jax.random.split(key)
actor_grad_fn = jax.value_and_grad(_actor_loss_fn, has_aux=True)
actor_loss_info, actor_grads = actor_grad_fn(
params.actor_params,
traj_batch,
advantages,
entropy_key,
)
# Calculate critic loss
critic_grad_fn = jax.value_and_grad(_critic_loss_fn, has_aux=True)
value_loss_info, critic_grads = critic_grad_fn(
params.critic_params, traj_batch, targets
)
# Compute the parallel mean (pmean) over the batch.
# This pmean could be a regular mean as the batch axis is on the same device.
actor_grads, actor_loss_info = jax.lax.pmean(
(actor_grads, actor_loss_info), axis_name="batch"
)
# pmean over devices.
actor_grads, actor_loss_info = jax.lax.pmean(
(actor_grads, actor_loss_info), axis_name="device"
)
critic_grads, value_loss_info = jax.lax.pmean(
(critic_grads, value_loss_info), axis_name="batch"
)
# pmean over devices.
critic_grads, value_loss_info = jax.lax.pmean(
(critic_grads, value_loss_info), axis_name="device"
)
# Update params and optimiser state
actor_updates, actor_new_opt_state = actor_update_fn(
actor_grads, opt_states.actor_opt_state
)
actor_new_params = optax.apply_updates(params.actor_params, actor_updates)
critic_updates, critic_new_opt_state = critic_update_fn(
critic_grads, opt_states.critic_opt_state
)
critic_new_params = optax.apply_updates(params.critic_params, critic_updates)
new_params = Params(actor_new_params, critic_new_params)
new_opt_state = OptStates(actor_new_opt_state, critic_new_opt_state)
actor_loss, (_, entropy) = actor_loss_info
value_loss, unscaled_value_loss = value_loss_info
total_loss = actor_loss + value_loss
loss_info = {
"total_loss": total_loss,
"value_loss": unscaled_value_loss,
"actor_loss": actor_loss,
"entropy": entropy,
}
return (new_params, new_opt_state, entropy_key), loss_info
params, opt_states, traj_batch, advantages, targets, key = update_state
key, shuffle_key, entropy_key = jax.random.split(key, 3)
# Shuffle minibatches
batch_size = config.system.rollout_length * config.arch.num_envs
permutation = jax.random.permutation(shuffle_key, batch_size)
batch = (traj_batch, advantages, targets)
batch = tree.map(lambda x: merge_leading_dims(x, 2), batch)
shuffled_batch = tree.map(lambda x: jnp.take(x, permutation, axis=0), batch)
minibatches = tree.map(
lambda x: jnp.reshape(x, (config.system.num_minibatches, -1, *x.shape[1:])),
shuffled_batch,
)
# Update minibatches
(params, opt_states, entropy_key), loss_info = jax.lax.scan(
_update_minibatch, (params, opt_states, entropy_key), minibatches
)
update_state = (params, opt_states, traj_batch, advantages, targets, key)
return update_state, loss_info
update_state = (params, opt_states, traj_batch, advantages, targets, key)
# Update epochs
update_state, loss_info = jax.lax.scan(
_update_epoch, update_state, None, config.system.ppo_epochs
)
params, opt_states, traj_batch, advantages, targets, key = update_state
learner_state = LearnerState(params, opt_states, key, env_state, last_timestep)
return learner_state, (episode_metrics, loss_info)
def learner_fn(learner_state: LearnerState) -> ExperimentOutput[LearnerState]:
"""Learner function.
This function represents the learner, it updates the network parameters
by iteratively applying the `_update_step` function for a fixed number of
updates. The `_update_step` function is vectorized over a batch of inputs.
Args:
----
learner_state (NamedTuple):
- params (Params): The initial model parameters.
- opt_states (OptStates): The initial optimizer states.
- key (chex.PRNGKey): The random number generator state.
- env_state (LogEnvState): The environment state.
- timesteps (TimeStep): The initial timestep in the initial trajectory.
"""
batched_update_step = jax.vmap(_update_step, in_axes=(0, None), axis_name="batch")
learner_state, (episode_info, loss_info) = jax.lax.scan(
batched_update_step, learner_state, None, config.system.num_updates_per_eval
)
return ExperimentOutput(
learner_state=learner_state,
episode_metrics=episode_info,
train_metrics=loss_info,
)
return learner_fn
def learner_setup(
env: MarlEnv, keys: chex.Array, config: DictConfig
) -> Tuple[LearnerFn[LearnerState], Actor, LearnerState]:
"""Initialise learner_fn, network, optimiser, environment and states."""
# Get available TPU cores.
n_devices = len(jax.devices())
# Get number of agents.
config.system.num_agents = env.num_agents
# PRNG keys.
key, actor_net_key, critic_net_key = keys
# Define network and optimiser.
actor_torso = hydra.utils.instantiate(config.network.actor_network.pre_torso)
action_head, _ = get_action_head(env.action_spec)
actor_action_head = hydra.utils.instantiate(action_head, action_dim=env.action_dim)
critic_torso = hydra.utils.instantiate(config.network.critic_network.pre_torso)
actor_network = Actor(torso=actor_torso, action_head=actor_action_head)
critic_network = Critic(torso=critic_torso, centralised_critic=True)
actor_lr = make_learning_rate(config.system.actor_lr, config)
critic_lr = make_learning_rate(config.system.critic_lr, config)
actor_optim = optax.chain(
optax.clip_by_global_norm(config.system.max_grad_norm),
optax.adam(actor_lr, eps=1e-5),
)
critic_optim = optax.chain(
optax.clip_by_global_norm(config.system.max_grad_norm),
optax.adam(critic_lr, eps=1e-5),
)
# Initialise observation with obs of all agents.
obs = env.observation_spec.generate_value()
init_x = tree.map(lambda x: x[jnp.newaxis, ...], obs)
# Initialise actor params and optimiser state.
actor_params = actor_network.init(actor_net_key, init_x)
actor_opt_state = actor_optim.init(actor_params)
# Initialise critic params and optimiser state.
critic_params = critic_network.init(critic_net_key, init_x)
critic_opt_state = critic_optim.init(critic_params)
# Pack params.
params = Params(actor_params, critic_params)
# Pack apply and update functions.
apply_fns = (actor_network.apply, critic_network.apply)
update_fns = (actor_optim.update, critic_optim.update)
# Get batched iterated update and replicate it to pmap it over cores.
learn = get_learner_fn(env, apply_fns, update_fns, config)
learn = jax.pmap(learn, axis_name="device")
# Initialise environment states and timesteps: across devices and batches.
key, *env_keys = jax.random.split(
key, n_devices * config.system.update_batch_size * config.arch.num_envs + 1
)
env_states, timesteps = jax.vmap(env.reset, in_axes=(0))(
jnp.stack(env_keys),
)
reshape_states = lambda x: x.reshape(
(n_devices, config.system.update_batch_size, config.arch.num_envs) + x.shape[1:]
)
# (devices, update batch size, num_envs, ...)
env_states = tree.map(reshape_states, env_states)
timesteps = tree.map(reshape_states, timesteps)
# Load model from checkpoint if specified.
if config.logger.checkpointing.load_model:
loaded_checkpoint = Checkpointer(
model_name=config.logger.system_name,
**config.logger.checkpointing.load_args, # Other checkpoint args
)
# Restore the learner state from the checkpoint
restored_params, _ = loaded_checkpoint.restore_params(input_params=params)
# Update the params
params = restored_params
# Define params to be replicated across devices and batches.
key, step_keys = jax.random.split(key)
opt_states = OptStates(actor_opt_state, critic_opt_state)
replicate_learner = (params, opt_states, step_keys)
# Duplicate learner for update_batch_size.
broadcast = lambda x: jnp.broadcast_to(x, (config.system.update_batch_size, *x.shape))
replicate_learner = tree.map(broadcast, replicate_learner)
# Duplicate learner across devices.
replicate_learner = flax.jax_utils.replicate(replicate_learner, devices=jax.devices())
# Initialise learner state.
params, opt_states, step_keys = replicate_learner
init_learner_state = LearnerState(params, opt_states, step_keys, env_states, timesteps)
return learn, actor_network, init_learner_state
def run_experiment(_config: DictConfig) -> float:
"""Runs experiment."""
_config.logger.system_name = "ff_mappo"
config = copy.deepcopy(_config)
n_devices = len(jax.devices())
# Create the enviroments for train and eval.
env, eval_env = environments.make(config=config, add_global_state=True)
# PRNG keys.
key, key_e, actor_net_key, critic_net_key = jax.random.split(
jax.random.PRNGKey(config.system.seed), num=4
)
# Setup learner.
learn, actor_network, learner_state = learner_setup(
env, (key, actor_net_key, critic_net_key), config
)
# Setup evaluator.
# One key per device for evaluation.
eval_keys = jax.random.split(key_e, n_devices)
eval_act_fn = make_ff_eval_act_fn(actor_network.apply, config)
evaluator = get_eval_fn(eval_env, eval_act_fn, config, absolute_metric=False)
# Calculate total timesteps.
config = check_total_timesteps(config)
assert (
config.system.num_updates > config.arch.num_evaluation
), "Number of updates per evaluation must be less than total number of updates."
assert (
config.arch.num_envs % config.system.num_minibatches == 0
), "Number of envs must be divisibile by number of minibatches."
# Calculate number of updates per evaluation.
config.system.num_updates_per_eval = config.system.num_updates // config.arch.num_evaluation
steps_per_rollout = (
n_devices
* config.system.num_updates_per_eval
* config.system.rollout_length
* config.system.update_batch_size
* config.arch.num_envs
)
# Logger setup
logger = MavaLogger(config)
cfg: Dict = OmegaConf.to_container(config, resolve=True)
cfg["arch"]["devices"] = jax.devices()
pprint(cfg)
# Set up checkpointer
save_checkpoint = config.logger.checkpointing.save_model
if save_checkpoint:
checkpointer = Checkpointer(
metadata=config, # Save all config as metadata in the checkpoint
model_name=config.logger.system_name,
**config.logger.checkpointing.save_args, # Checkpoint args
)
# Run experiment for a total number of evaluations.
max_episode_return = -jnp.inf
best_params = None
for eval_step in range(config.arch.num_evaluation):
# Train.
start_time = time.time()
learner_output = learn(learner_state)
jax.block_until_ready(learner_output)
# Log the results of the training.
elapsed_time = time.time() - start_time
t = int(steps_per_rollout * (eval_step + 1))
episode_metrics, ep_completed = get_final_step_metrics(learner_output.episode_metrics)
episode_metrics["steps_per_second"] = steps_per_rollout / elapsed_time
# Separately log timesteps, actoring metrics and training metrics.
logger.log({"timestep": t}, t, eval_step, LogEvent.MISC)
if ep_completed: # only log episode metrics if an episode was completed in the rollout.
logger.log(episode_metrics, t, eval_step, LogEvent.ACT)
logger.log(learner_output.train_metrics, t, eval_step, LogEvent.TRAIN)
# Prepare for evaluation.
trained_params = unreplicate_batch_dim(learner_state.params.actor_params)
key_e, *eval_keys = jax.random.split(key_e, n_devices + 1)
eval_keys = jnp.stack(eval_keys)
eval_keys = eval_keys.reshape(n_devices, -1)
# Evaluate.
eval_metrics = evaluator(trained_params, eval_keys, {})
logger.log(eval_metrics, t, eval_step, LogEvent.EVAL)
episode_return = jnp.mean(eval_metrics["episode_return"])
if save_checkpoint:
# Save checkpoint of learner state
checkpointer.save(
timestep=steps_per_rollout * (eval_step + 1),
unreplicated_learner_state=unreplicate_n_dims(learner_output.learner_state),
episode_return=episode_return,
)
if config.arch.absolute_metric and max_episode_return <= episode_return:
best_params = copy.deepcopy(trained_params)
max_episode_return = episode_return
# Update runner state to continue training.
learner_state = learner_output.learner_state
# Record the performance for the final evaluation run.
eval_performance = float(jnp.mean(eval_metrics[config.env.eval_metric]))
# Measure absolute metric.
if config.arch.absolute_metric:
abs_metric_evaluator = get_eval_fn(eval_env, eval_act_fn, config, absolute_metric=True)
eval_keys = jax.random.split(key, n_devices)
eval_metrics = abs_metric_evaluator(best_params, eval_keys, {})
t = int(steps_per_rollout * (eval_step + 1))
logger.log(eval_metrics, t, eval_step, LogEvent.ABSOLUTE)
# Stop the logger.
logger.stop()
return eval_performance
@hydra.main(
config_path="../../../configs/default",
config_name="ff_mappo.yaml",
version_base="1.2",
)
def hydra_entry_point(cfg: DictConfig) -> float:
"""Experiment entry point."""
# Allow dynamic attributes.
OmegaConf.set_struct(cfg, False)
# Run experiment.
eval_performance = run_experiment(cfg)
print(f"{Fore.CYAN}{Style.BRIGHT}MAPPO experiment completed{Style.RESET_ALL}")
return eval_performance
if __name__ == "__main__":
hydra_entry_point()