Unity 机器学习代理工具包 (ML-Agents) 是一个开源项目,它使游戏和模拟能够作为训练智能代理的环境。
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import logging
import tensorflow as tf
from tensorflow.python.client import device_lib
from mlagents.envs.timers import timed
from mlagents.trainers.models import EncoderType, LearningRateSchedule
from mlagents.trainers.ppo.policy import PPOPolicy
from mlagents.trainers.ppo.models import PPOModel
from mlagents.trainers.components.reward_signals.reward_signal_factory import (
create_reward_signal,
)
# Variable scope in which created variables will be placed under
TOWER_SCOPE_NAME = "tower"
logger = logging.getLogger("mlagents.trainers")
class MultiGpuPPOPolicy(PPOPolicy):
def create_model(
self, brain, trainer_params, reward_signal_configs, is_training, load, seed
):
"""
Create PPO models, one on each device
:param brain: Assigned Brain object.
:param trainer_params: Defined training parameters.
:param reward_signal_configs: Reward signal config
:param seed: Random seed.
"""
self.devices = get_devices()
self.towers = []
with self.graph.as_default():
with tf.variable_scope("", reuse=tf.AUTO_REUSE):
for device in self.devices:
with tf.device(device):
self.towers.append(
PPOModel(
brain=brain,
lr=float(trainer_params["learning_rate"]),
lr_schedule=LearningRateSchedule(
trainer_params.get(
"learning_rate_schedule", "linear"
)
),
h_size=int(trainer_params["hidden_units"]),
epsilon=float(trainer_params["epsilon"]),
beta=float(trainer_params["beta"]),
max_step=float(trainer_params["max_steps"]),
normalize=trainer_params["normalize"],
use_recurrent=trainer_params["use_recurrent"],
num_layers=int(trainer_params["num_layers"]),
m_size=self.m_size,
seed=seed,
stream_names=list(reward_signal_configs.keys()),
vis_encode_type=EncoderType(
trainer_params.get("vis_encode_type", "simple")
),
)
)
self.towers[-1].create_ppo_optimizer()
self.model = self.towers[0]
avg_grads = self.average_gradients([t.grads for t in self.towers])
update_batch = self.model.optimizer.apply_gradients(avg_grads)
avg_value_loss = tf.reduce_mean(
tf.stack([model.value_loss for model in self.towers]), 0
)
avg_policy_loss = tf.reduce_mean(
tf.stack([model.policy_loss for model in self.towers]), 0
)
self.inference_dict.update(
{
"action": self.model.output,
"log_probs": self.model.all_log_probs,
"value_heads": self.model.value_heads,
"value": self.model.value,
"entropy": self.model.entropy,
"learning_rate": self.model.learning_rate,
}
)
if self.use_continuous_act:
self.inference_dict["pre_action"] = self.model.output_pre
if self.use_recurrent:
self.inference_dict["memory_out"] = self.model.memory_out
if (
is_training
and self.use_vec_obs
and trainer_params["normalize"]
and not load
):
self.inference_dict["update_mean"] = self.model.update_normalization
self.total_policy_loss = self.model.abs_policy_loss
self.update_dict.update(
{
"value_loss": avg_value_loss,
"policy_loss": avg_policy_loss,
"update_batch": update_batch,
}
)
def create_reward_signals(self, reward_signal_configs):
"""
Create reward signals
:param reward_signal_configs: Reward signal config.
"""
self.reward_signal_towers = []
with self.graph.as_default():
with tf.variable_scope(TOWER_SCOPE_NAME, reuse=tf.AUTO_REUSE):
for device_id, device in enumerate(self.devices):
with tf.device(device):
reward_tower = {}
for reward_signal, config in reward_signal_configs.items():
reward_tower[reward_signal] = create_reward_signal(
self, self.towers[device_id], reward_signal, config
)
for k, v in reward_tower[reward_signal].update_dict.items():
self.update_dict[k + "_" + str(device_id)] = v
self.reward_signal_towers.append(reward_tower)
for _, reward_tower in self.reward_signal_towers[0].items():
for _, update_key in reward_tower.stats_name_to_update_name.items():
all_reward_signal_stats = tf.stack(
[
self.update_dict[update_key + "_" + str(i)]
for i in range(len(self.towers))
]
)
mean_reward_signal_stats = tf.reduce_mean(
all_reward_signal_stats, 0
)
self.update_dict.update({update_key: mean_reward_signal_stats})
self.reward_signals = self.reward_signal_towers[0]
@timed
def update(self, mini_batch, num_sequences):
"""
Updates model using buffer.
:param n_sequences: Number of trajectories in batch.
:param mini_batch: Experience batch.
:return: Output from update process.
"""
feed_dict = {}
stats_needed = self.stats_name_to_update_name
device_batch_size = num_sequences // len(self.devices)
device_batches = []
for i in range(len(self.devices)):
device_batches.append(
{
k: v[
i * device_batch_size : i * device_batch_size
+ device_batch_size
]
for (k, v) in mini_batch.items()
}
)
for batch, tower, reward_tower in zip(
device_batches, self.towers, self.reward_signal_towers
):
feed_dict.update(self.construct_feed_dict(tower, batch, num_sequences))
stats_needed.update(self.stats_name_to_update_name)
for _, reward_signal in reward_tower.items():
feed_dict.update(
reward_signal.prepare_update(tower, batch, num_sequences)
)
stats_needed.update(reward_signal.stats_name_to_update_name)
update_vals = self._execute_model(feed_dict, self.update_dict)
update_stats = {}
for stat_name, update_name in stats_needed.items():
update_stats[stat_name] = update_vals[update_name]
return update_stats
def average_gradients(self, tower_grads):
"""
Average gradients from all towers
:param tower_grads: Gradients from all towers
"""
average_grads = []
for grad_and_vars in zip(*tower_grads):
grads = [g for g, _ in grad_and_vars if g is not None]
if not grads:
continue
avg_grad = tf.reduce_mean(tf.stack(grads), 0)
var = grad_and_vars[0][1]
average_grads.append((avg_grad, var))
return average_grads
def get_devices():
"""
Get all available GPU devices
"""
local_device_protos = device_lib.list_local_devices()
devices = [x.name for x in local_device_protos if x.device_type == "GPU"]
return devices