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replay_buffer.py
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replay_buffer.py
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import copy
import time
import numpy
import ray
import torch
import models
@ray.remote
class ReplayBuffer:
"""
Class which run in a dedicated thread to store played games and generate batch.
"""
def __init__(self, initial_checkpoint, initial_buffer, config):
self.config = config
self.buffer = copy.deepcopy(initial_buffer)
self.num_played_games = initial_checkpoint["num_played_games"]
self.num_played_steps = initial_checkpoint["num_played_steps"]
self.total_samples = sum(
[len(game_history.root_values) for game_history in self.buffer.values()]
)
if self.total_samples != 0:
print(
f"Replay buffer initialized with {self.total_samples} samples ({self.num_played_games} games).\n"
)
# Fix random generator seed
numpy.random.seed(self.config.seed)
def save_game(self, game_history, shared_storage=None):
if self.config.PER:
if game_history.priorities is not None:
# Avoid read only array when loading replay buffer from disk
game_history.priorities = numpy.copy(game_history.priorities)
else:
# Initial priorities for the prioritized replay (See paper appendix Training)
priorities = []
for i, root_value in enumerate(game_history.root_values):
priority = (
numpy.abs(
root_value - self.compute_target_value(game_history, i)
)
** self.config.PER_alpha
)
priorities.append(priority)
game_history.priorities = numpy.array(priorities, dtype="float32")
game_history.game_priority = numpy.max(game_history.priorities)
self.buffer[self.num_played_games] = game_history
self.num_played_games += 1
self.num_played_steps += len(game_history.root_values)
self.total_samples += len(game_history.root_values)
if self.config.replay_buffer_size < len(self.buffer):
del_id = self.num_played_games - len(self.buffer)
self.total_samples -= len(self.buffer[del_id].root_values)
del self.buffer[del_id]
if shared_storage:
shared_storage.set_info.remote("num_played_games", self.num_played_games)
shared_storage.set_info.remote("num_played_steps", self.num_played_steps)
def get_buffer(self):
return self.buffer
def get_batch(self):
(
index_batch,
observation_batch,
action_batch,
reward_batch,
value_batch,
policy_batch,
gradient_scale_batch,
) = ([], [], [], [], [], [], [])
weight_batch = [] if self.config.PER else None
for game_id, game_history, game_prob in self.sample_n_games(
self.config.batch_size
):
game_pos, pos_prob = self.sample_position(game_history)
values, rewards, policies, actions = self.make_target(
game_history, game_pos
)
index_batch.append([game_id, game_pos])
observation_batch.append(
game_history.get_stacked_observations(
game_pos,
self.config.stacked_observations,
len(self.config.action_space),
)
)
action_batch.append(actions)
value_batch.append(values)
reward_batch.append(rewards)
policy_batch.append(policies)
gradient_scale_batch.append(
[
min(
self.config.num_unroll_steps,
len(game_history.action_history) - game_pos,
)
]
* len(actions)
)
if self.config.PER:
weight_batch.append(1 / (self.total_samples * game_prob * pos_prob))
if self.config.PER:
weight_batch = numpy.array(weight_batch, dtype="float32") / max(
weight_batch
)
# observation_batch: batch, channels, height, width
# action_batch: batch, num_unroll_steps+1
# value_batch: batch, num_unroll_steps+1
# reward_batch: batch, num_unroll_steps+1
# policy_batch: batch, num_unroll_steps+1, len(action_space)
# weight_batch: batch
# gradient_scale_batch: batch, num_unroll_steps+1
return (
index_batch,
(
observation_batch,
action_batch,
value_batch,
reward_batch,
policy_batch,
weight_batch,
gradient_scale_batch,
),
)
def sample_game(self, force_uniform=False):
"""
Sample game from buffer either uniformly or according to some priority.
See paper appendix Training.
"""
game_prob = None
if self.config.PER and not force_uniform:
game_probs = numpy.array(
[game_history.game_priority for game_history in self.buffer.values()],
dtype="float32",
)
game_probs /= numpy.sum(game_probs)
game_index = numpy.random.choice(len(self.buffer), p=game_probs)
game_prob = game_probs[game_index]
else:
game_index = numpy.random.choice(len(self.buffer))
game_id = self.num_played_games - len(self.buffer) + game_index
return game_id, self.buffer[game_id], game_prob
def sample_n_games(self, n_games, force_uniform=False):
if self.config.PER and not force_uniform:
game_id_list = []
game_probs = []
for game_id, game_history in self.buffer.items():
game_id_list.append(game_id)
game_probs.append(game_history.game_priority)
game_probs = numpy.array(game_probs, dtype="float32")
game_probs /= numpy.sum(game_probs)
game_prob_dict = dict(
[(game_id, prob) for game_id, prob in zip(game_id_list, game_probs)]
)
selected_games = numpy.random.choice(game_id_list, n_games, p=game_probs)
else:
selected_games = numpy.random.choice(list(self.buffer.keys()), n_games)
game_prob_dict = {}
ret = [
(game_id, self.buffer[game_id], game_prob_dict.get(game_id))
for game_id in selected_games
]
return ret
def sample_position(self, game_history, force_uniform=False):
"""
Sample position from game either uniformly or according to some priority.
See paper appendix Training.
"""
position_prob = None
if self.config.PER and not force_uniform:
position_probs = game_history.priorities / sum(game_history.priorities)
position_index = numpy.random.choice(len(position_probs), p=position_probs)
position_prob = position_probs[position_index]
else:
position_index = numpy.random.choice(len(game_history.root_values))
return position_index, position_prob
def update_game_history(self, game_id, game_history):
# The element could have been removed since its selection and update
if next(iter(self.buffer)) <= game_id:
if self.config.PER:
# Avoid read only array when loading replay buffer from disk
game_history.priorities = numpy.copy(game_history.priorities)
self.buffer[game_id] = game_history
def update_priorities(self, priorities, index_info):
"""
Update game and position priorities with priorities calculated during the training.
See Distributed Prioritized Experience Replay https://arxiv.org/abs/1803.00933
"""
for i in range(len(index_info)):
game_id, game_pos = index_info[i]
# The element could have been removed since its selection and training
if next(iter(self.buffer)) <= game_id:
# Update position priorities
priority = priorities[i, :]
start_index = game_pos
end_index = min(
game_pos + len(priority), len(self.buffer[game_id].priorities)
)
self.buffer[game_id].priorities[start_index:end_index] = priority[
: end_index - start_index
]
# Update game priorities
self.buffer[game_id].game_priority = numpy.max(
self.buffer[game_id].priorities
)
def compute_target_value(self, game_history, index):
# The value target is the discounted root value of the search tree td_steps into the
# future, plus the discounted sum of all rewards until then.
bootstrap_index = index + self.config.td_steps
if bootstrap_index < len(game_history.root_values):
root_values = (
game_history.root_values
if game_history.reanalysed_predicted_root_values is None
else game_history.reanalysed_predicted_root_values
)
last_step_value = (
root_values[bootstrap_index]
if game_history.to_play_history[bootstrap_index]
== game_history.to_play_history[index]
else -root_values[bootstrap_index]
)
value = last_step_value * self.config.discount**self.config.td_steps
else:
value = 0
for i, reward in enumerate(
game_history.reward_history[index + 1 : bootstrap_index + 1]
):
# The value is oriented from the perspective of the current player
value += (
reward
if game_history.to_play_history[index]
== game_history.to_play_history[index + i]
else -reward
) * self.config.discount**i
return value
def make_target(self, game_history, state_index):
"""
Generate targets for every unroll steps.
"""
target_values, target_rewards, target_policies, actions = [], [], [], []
for current_index in range(
state_index, state_index + self.config.num_unroll_steps + 1
):
value = self.compute_target_value(game_history, current_index)
if current_index < len(game_history.root_values):
target_values.append(value)
target_rewards.append(game_history.reward_history[current_index])
target_policies.append(game_history.child_visits[current_index])
actions.append(game_history.action_history[current_index])
elif current_index == len(game_history.root_values):
target_values.append(0)
target_rewards.append(game_history.reward_history[current_index])
# Uniform policy
target_policies.append(
[
1 / len(game_history.child_visits[0])
for _ in range(len(game_history.child_visits[0]))
]
)
actions.append(game_history.action_history[current_index])
else:
# States past the end of games are treated as absorbing states
target_values.append(0)
target_rewards.append(0)
# Uniform policy
target_policies.append(
[
1 / len(game_history.child_visits[0])
for _ in range(len(game_history.child_visits[0]))
]
)
actions.append(numpy.random.choice(self.config.action_space))
return target_values, target_rewards, target_policies, actions
@ray.remote
class Reanalyse:
"""
Class which run in a dedicated thread to update the replay buffer with fresh information.
See paper appendix Reanalyse.
"""
def __init__(self, initial_checkpoint, config):
self.config = config
# Fix random generator seed
numpy.random.seed(self.config.seed)
torch.manual_seed(self.config.seed)
# Initialize the network
self.model = models.MuZeroNetwork(self.config)
self.model.set_weights(initial_checkpoint["weights"])
self.model.to(torch.device("cuda" if self.config.reanalyse_on_gpu else "cpu"))
self.model.eval()
self.num_reanalysed_games = initial_checkpoint["num_reanalysed_games"]
def reanalyse(self, replay_buffer, shared_storage):
while ray.get(shared_storage.get_info.remote("num_played_games")) < 1:
time.sleep(0.1)
while ray.get(
shared_storage.get_info.remote("training_step")
) < self.config.training_steps and not ray.get(
shared_storage.get_info.remote("terminate")
):
self.model.set_weights(ray.get(shared_storage.get_info.remote("weights")))
game_id, game_history, _ = ray.get(
replay_buffer.sample_game.remote(force_uniform=True)
)
# Use the last model to provide a fresher, stable n-step value (See paper appendix Reanalyze)
if self.config.use_last_model_value:
observations = numpy.array(
[
game_history.get_stacked_observations(
i,
self.config.stacked_observations,
len(self.config.action_space),
)
for i in range(len(game_history.root_values))
]
)
observations = (
torch.tensor(observations)
.float()
.to(next(self.model.parameters()).device)
)
values = models.support_to_scalar(
self.model.initial_inference(observations)[0],
self.config.support_size,
)
game_history.reanalysed_predicted_root_values = (
torch.squeeze(values).detach().cpu().numpy()
)
replay_buffer.update_game_history.remote(game_id, game_history)
self.num_reanalysed_games += 1
shared_storage.set_info.remote(
"num_reanalysed_games", self.num_reanalysed_games
)