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self_play.py
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self_play.py
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import math
import time
import numpy
import ray
import torch
import models
@ray.remote
class SelfPlay:
"""
Class which run in a dedicated thread to play games and save them to the replay-buffer.
"""
def __init__(self, initial_checkpoint, Game, config, seed):
self.config = config
self.game = Game(seed)
# Fix random generator seed
numpy.random.seed(seed)
torch.manual_seed(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.selfplay_on_gpu else "cpu"))
self.model.eval()
def continuous_self_play(self, shared_storage, replay_buffer, test_mode=False):
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")))
if not test_mode:
game_history = self.play_game(
self.config.visit_softmax_temperature_fn(
trained_steps=ray.get(
shared_storage.get_info.remote("training_step")
)
),
self.config.temperature_threshold,
False,
"self",
0,
)
replay_buffer.save_game.remote(game_history, shared_storage)
else:
# Take the best action (no exploration) in test mode
game_history = self.play_game(
0,
self.config.temperature_threshold,
False,
"self" if len(self.config.players) == 1 else self.config.opponent,
self.config.muzero_player,
)
# Save to the shared storage
shared_storage.set_info.remote(
{
"episode_length": len(game_history.action_history) - 1,
"total_reward": sum(game_history.reward_history),
"mean_value": numpy.mean(
[value for value in game_history.root_values if value]
),
}
)
if 1 < len(self.config.players):
shared_storage.set_info.remote(
{
"muzero_reward": sum(
reward
for i, reward in enumerate(game_history.reward_history)
if game_history.to_play_history[i - 1]
== self.config.muzero_player
),
"opponent_reward": sum(
reward
for i, reward in enumerate(game_history.reward_history)
if game_history.to_play_history[i - 1]
!= self.config.muzero_player
),
}
)
# Managing the self-play / training ratio
if not test_mode and self.config.self_play_delay:
time.sleep(self.config.self_play_delay)
if not test_mode and self.config.ratio:
while (
ray.get(shared_storage.get_info.remote("training_step"))
/ max(
1, ray.get(shared_storage.get_info.remote("num_played_steps"))
)
< self.config.ratio
and ray.get(shared_storage.get_info.remote("training_step"))
< self.config.training_steps
and not ray.get(shared_storage.get_info.remote("terminate"))
):
time.sleep(0.5)
self.close_game()
def play_game(
self, temperature, temperature_threshold, render, opponent, muzero_player
):
"""
Play one game with actions based on the Monte Carlo tree search at each moves.
"""
game_history = GameHistory()
observation = self.game.reset()
game_history.action_history.append(0)
game_history.observation_history.append(observation)
game_history.reward_history.append(0)
game_history.to_play_history.append(self.game.to_play())
done = False
if render:
self.game.render()
with torch.no_grad():
while (
not done and len(game_history.action_history) <= self.config.max_moves
):
assert (
len(numpy.array(observation).shape) == 3
), f"Observation should be 3 dimensionnal instead of {len(numpy.array(observation).shape)} dimensionnal. Got observation of shape: {numpy.array(observation).shape}"
assert (
numpy.array(observation).shape == self.config.observation_shape
), f"Observation should match the observation_shape defined in MuZeroConfig. Expected {self.config.observation_shape} but got {numpy.array(observation).shape}."
stacked_observations = game_history.get_stacked_observations(
-1, self.config.stacked_observations, len(self.config.action_space)
)
# Choose the action
if opponent == "self" or muzero_player == self.game.to_play():
root, mcts_info = MCTS(self.config).run(
self.model,
stacked_observations,
self.game.legal_actions(),
self.game.to_play(),
True,
)
action = self.select_action(
root,
temperature
if not temperature_threshold
or len(game_history.action_history) < temperature_threshold
else 0,
)
if render:
print(f'Tree depth: {mcts_info["max_tree_depth"]}')
print(
f"Root value for player {self.game.to_play()}: {root.value():.2f}"
)
else:
action, root = self.select_opponent_action(
opponent, stacked_observations
)
observation, reward, done = self.game.step(action)
if render:
print(f"Played action: {self.game.action_to_string(action)}")
self.game.render()
game_history.store_search_statistics(root, self.config.action_space)
# Next batch
game_history.action_history.append(action)
game_history.observation_history.append(observation)
game_history.reward_history.append(reward)
game_history.to_play_history.append(self.game.to_play())
return game_history
def close_game(self):
self.game.close()
def select_opponent_action(self, opponent, stacked_observations):
"""
Select opponent action for evaluating MuZero level.
"""
if opponent == "human":
root, mcts_info = MCTS(self.config).run(
self.model,
stacked_observations,
self.game.legal_actions(),
self.game.to_play(),
True,
)
print(f'Tree depth: {mcts_info["max_tree_depth"]}')
print(f"Root value for player {self.game.to_play()}: {root.value():.2f}")
print(
f"Player {self.game.to_play()} turn. MuZero suggests {self.game.action_to_string(self.select_action(root, 0))}"
)
return self.game.human_to_action(), root
elif opponent == "expert":
return self.game.expert_agent(), None
elif opponent == "random":
assert (
self.game.legal_actions()
), f"Legal actions should not be an empty array. Got {self.game.legal_actions()}."
assert set(self.game.legal_actions()).issubset(
set(self.config.action_space)
), "Legal actions should be a subset of the action space."
return numpy.random.choice(self.game.legal_actions()), None
else:
raise NotImplementedError(
'Wrong argument: "opponent" argument should be "self", "human", "expert" or "random"'
)
@staticmethod
def select_action(node, temperature):
"""
Select action according to the visit count distribution and the temperature.
The temperature is changed dynamically with the visit_softmax_temperature function
in the config.
"""
visit_counts = numpy.array(
[child.visit_count for child in node.children.values()], dtype="int32"
)
actions = [action for action in node.children.keys()]
if temperature == 0:
action = actions[numpy.argmax(visit_counts)]
elif temperature == float("inf"):
action = numpy.random.choice(actions)
else:
# See paper appendix Data Generation
visit_count_distribution = visit_counts ** (1 / temperature)
visit_count_distribution = visit_count_distribution / sum(
visit_count_distribution
)
action = numpy.random.choice(actions, p=visit_count_distribution)
return action
# Game independent
class MCTS:
"""
Core Monte Carlo Tree Search algorithm.
To decide on an action, we run N simulations, always starting at the root of
the search tree and traversing the tree according to the UCB formula until we
reach a leaf node.
"""
def __init__(self, config):
self.config = config
def run(
self,
model,
observation,
legal_actions,
to_play,
add_exploration_noise,
override_root_with=None,
):
"""
At the root of the search tree we use the representation function to obtain a
hidden state given the current observation.
We then run a Monte Carlo Tree Search using only action sequences and the model
learned by the network.
"""
if override_root_with:
root = override_root_with
root_predicted_value = None
else:
root = Node(0)
observation = (
torch.tensor(observation)
.float()
.unsqueeze(0)
.to(next(model.parameters()).device)
)
(
root_predicted_value,
reward,
policy_logits,
hidden_state,
) = model.initial_inference(observation)
root_predicted_value = models.support_to_scalar(
root_predicted_value, self.config.support_size
).item()
reward = models.support_to_scalar(reward, self.config.support_size).item()
assert (
legal_actions
), f"Legal actions should not be an empty array. Got {legal_actions}."
assert set(legal_actions).issubset(
set(self.config.action_space)
), "Legal actions should be a subset of the action space."
root.expand(
legal_actions,
to_play,
reward,
policy_logits,
hidden_state,
)
if add_exploration_noise:
root.add_exploration_noise(
dirichlet_alpha=self.config.root_dirichlet_alpha,
exploration_fraction=self.config.root_exploration_fraction,
)
min_max_stats = MinMaxStats()
max_tree_depth = 0
for _ in range(self.config.num_simulations):
virtual_to_play = to_play
node = root
search_path = [node]
current_tree_depth = 0
while node.expanded():
current_tree_depth += 1
action, node = self.select_child(node, min_max_stats)
search_path.append(node)
# Players play turn by turn
if virtual_to_play + 1 < len(self.config.players):
virtual_to_play = self.config.players[virtual_to_play + 1]
else:
virtual_to_play = self.config.players[0]
# Inside the search tree we use the dynamics function to obtain the next hidden
# state given an action and the previous hidden state
parent = search_path[-2]
value, reward, policy_logits, hidden_state = model.recurrent_inference(
parent.hidden_state,
torch.tensor([[action]]).to(parent.hidden_state.device),
)
value = models.support_to_scalar(value, self.config.support_size).item()
reward = models.support_to_scalar(reward, self.config.support_size).item()
node.expand(
self.config.action_space,
virtual_to_play,
reward,
policy_logits,
hidden_state,
)
self.backpropagate(search_path, value, virtual_to_play, min_max_stats)
max_tree_depth = max(max_tree_depth, current_tree_depth)
extra_info = {
"max_tree_depth": max_tree_depth,
"root_predicted_value": root_predicted_value,
}
return root, extra_info
def select_child(self, node, min_max_stats):
"""
Select the child with the highest UCB score.
"""
max_ucb = max(
self.ucb_score(node, child, min_max_stats)
for action, child in node.children.items()
)
action = numpy.random.choice(
[
action
for action, child in node.children.items()
if self.ucb_score(node, child, min_max_stats) == max_ucb
]
)
return action, node.children[action]
def ucb_score(self, parent, child, min_max_stats):
"""
The score for a node is based on its value, plus an exploration bonus based on the prior.
"""
pb_c = (
math.log(
(parent.visit_count + self.config.pb_c_base + 1) / self.config.pb_c_base
)
+ self.config.pb_c_init
)
pb_c *= math.sqrt(parent.visit_count) / (child.visit_count + 1)
prior_score = pb_c * child.prior
if child.visit_count > 0:
# Mean value Q
value_score = min_max_stats.normalize(
child.reward
+ self.config.discount
* (child.value() if len(self.config.players) == 1 else -child.value())
)
else:
value_score = 0
return prior_score + value_score
def backpropagate(self, search_path, value, to_play, min_max_stats):
"""
At the end of a simulation, we propagate the evaluation all the way up the tree
to the root.
"""
if len(self.config.players) == 1:
for node in reversed(search_path):
node.value_sum += value
node.visit_count += 1
min_max_stats.update(node.reward + self.config.discount * node.value())
value = node.reward + self.config.discount * value
elif len(self.config.players) == 2:
for node in reversed(search_path):
node.value_sum += value if node.to_play == to_play else -value
node.visit_count += 1
min_max_stats.update(node.reward + self.config.discount * -node.value())
value = (
-node.reward if node.to_play == to_play else node.reward
) + self.config.discount * value
else:
raise NotImplementedError("More than two player mode not implemented.")
class Node:
def __init__(self, prior):
self.visit_count = 0
self.to_play = -1
self.prior = prior
self.value_sum = 0
self.children = {}
self.hidden_state = None
self.reward = 0
def expanded(self):
return len(self.children) > 0
def value(self):
if self.visit_count == 0:
return 0
return self.value_sum / self.visit_count
def expand(self, actions, to_play, reward, policy_logits, hidden_state):
"""
We expand a node using the value, reward and policy prediction obtained from the
neural network.
"""
self.to_play = to_play
self.reward = reward
self.hidden_state = hidden_state
policy_values = torch.softmax(
torch.tensor([policy_logits[0][a] for a in actions]), dim=0
).tolist()
policy = {a: policy_values[i] for i, a in enumerate(actions)}
for action, p in policy.items():
self.children[action] = Node(p)
def add_exploration_noise(self, dirichlet_alpha, exploration_fraction):
"""
At the start of each search, we add dirichlet noise to the prior of the root to
encourage the search to explore new actions.
"""
actions = list(self.children.keys())
noise = numpy.random.dirichlet([dirichlet_alpha] * len(actions))
frac = exploration_fraction
for a, n in zip(actions, noise):
self.children[a].prior = self.children[a].prior * (1 - frac) + n * frac
class GameHistory:
"""
Store only usefull information of a self-play game.
"""
def __init__(self):
self.observation_history = []
self.action_history = []
self.reward_history = []
self.to_play_history = []
self.child_visits = []
self.root_values = []
self.reanalysed_predicted_root_values = None
# For PER
self.priorities = None
self.game_priority = None
def store_search_statistics(self, root, action_space):
# Turn visit count from root into a policy
if root is not None:
sum_visits = sum(child.visit_count for child in root.children.values())
self.child_visits.append(
[
root.children[a].visit_count / sum_visits
if a in root.children
else 0
for a in action_space
]
)
self.root_values.append(root.value())
else:
self.root_values.append(None)
def get_stacked_observations(
self, index, num_stacked_observations, action_space_size
):
"""
Generate a new observation with the observation at the index position
and num_stacked_observations past observations and actions stacked.
"""
# Convert to positive index
index = index % len(self.observation_history)
stacked_observations = self.observation_history[index].copy()
for past_observation_index in reversed(
range(index - num_stacked_observations, index)
):
if 0 <= past_observation_index:
previous_observation = numpy.concatenate(
(
self.observation_history[past_observation_index],
[
numpy.ones_like(stacked_observations[0])
* self.action_history[past_observation_index + 1]
/ action_space_size
],
)
)
else:
previous_observation = numpy.concatenate(
(
numpy.zeros_like(self.observation_history[index]),
[numpy.zeros_like(stacked_observations[0])],
)
)
stacked_observations = numpy.concatenate(
(stacked_observations, previous_observation)
)
return stacked_observations
class MinMaxStats:
"""
A class that holds the min-max values of the tree.
"""
def __init__(self):
self.maximum = -float("inf")
self.minimum = float("inf")
def update(self, value):
self.maximum = max(self.maximum, value)
self.minimum = min(self.minimum, value)
def normalize(self, value):
if self.maximum > self.minimum:
# We normalize only when we have set the maximum and minimum values
return (value - self.minimum) / (self.maximum - self.minimum)
return value