# Copyright 2020,2021 Sony Corporation.
# Copyright 2021 Sony Group Corporation.
#
# 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.
from dataclasses import dataclass
from typing import Any, Dict, List, Optional, Union, cast
import gym
import numpy as np
import nnabla as nn
import nnabla.solvers as NS
import nnabla_rl.environment_explorers as EE
import nnabla_rl.model_trainers as MT
from nnabla_rl.algorithm import Algorithm, AlgorithmConfig, eval_api
from nnabla_rl.builders import ExplorerBuilder, ModelBuilder, ReplayBufferBuilder, SolverBuilder
from nnabla_rl.environment_explorer import EnvironmentExplorer
from nnabla_rl.environments.environment_info import EnvironmentInfo
from nnabla_rl.model_trainers.model_trainer import ModelTrainer, TrainingBatch
from nnabla_rl.models import QFunction, SACPolicy, SACQFunction, StochasticPolicy
from nnabla_rl.replay_buffer import ReplayBuffer
from nnabla_rl.utils import context
from nnabla_rl.utils.data import add_batch_dimension, marshal_experiences, set_data_to_variable
from nnabla_rl.utils.misc import create_variable, sync_model
[docs]@dataclass
class SACConfig(AlgorithmConfig):
'''SACConfig
List of configurations for SAC algorithm
Args:
gamma (float): discount factor of rewards. Defaults to 0.99.
learning_rate (float): learning rate which is set to all solvers. \
You can customize/override the learning rate for each solver by implementing the \
(:py:class:`SolverBuilder <nnabla_rl.builders.SolverBuilder>`) by yourself. \
Defaults to 0.0003.
batch_size(int): training batch size. Defaults to 256.
tau (float): target network's parameter update coefficient. Defaults to 0.005.
environment_steps (int): Number of steps to interact with the environment on each iteration. Defaults to 1.
gradient_steps (int): Number of parameter updates to perform on each iteration. Defaults to 1.
target_entropy (float, optional): Target entropy value. Defaults to None.
initial_temperature (float, optional): Initial value of temperature parameter. Defaults to None.
fix_temperature (bool): If true the temperature parameter will not be trained. Defaults to False.
start_timesteps (int): the timestep when training starts.\
The algorithm will collect experiences from the environment by acting randomly until this timestep.\
Defaults to 10000.
replay_buffer_size (int): capacity of the replay buffer. Defaults to 1000000.
'''
gamma: float = 0.99
learning_rate: float = 3.0*1e-4
batch_size: int = 256
tau: float = 0.005
environment_steps: int = 1
gradient_steps: int = 1
target_entropy: Optional[float] = None
initial_temperature: Optional[float] = None
fix_temperature: bool = False
start_timesteps: int = 10000
replay_buffer_size: int = 1000000
def __post_init__(self):
'''__post_init__
Check set values are in valid range.
'''
self._assert_between(self.tau, 0.0, 1.0, 'tau')
self._assert_between(self.gamma, 0.0, 1.0, 'gamma')
self._assert_positive(self.gradient_steps, 'gradient_steps')
self._assert_positive(self.environment_steps, 'environment_steps')
if self.initial_temperature is not None:
self._assert_positive(
self.initial_temperature, 'initial_temperature')
self._assert_positive(self.start_timesteps, 'start_timesteps')
class DefaultQFunctionBuilder(ModelBuilder[QFunction]):
def build_model(self, # type: ignore[override]
scope_name: str,
env_info: EnvironmentInfo,
algorithm_config: SACConfig,
**kwargs) -> QFunction:
return SACQFunction(scope_name)
class DefaultPolicyBuilder(ModelBuilder[StochasticPolicy]):
def build_model(self, # type: ignore[override]
scope_name: str,
env_info: EnvironmentInfo,
algorithm_config: SACConfig,
**kwargs) -> StochasticPolicy:
return SACPolicy(scope_name, env_info.action_dim)
class DefaultSolverBuilder(SolverBuilder):
def build_solver(self, # type: ignore[override]
env_info: EnvironmentInfo,
algorithm_config: SACConfig,
**kwargs) -> nn.solver.Solver:
return NS.Adam(alpha=algorithm_config.learning_rate)
class DefaultReplayBufferBuilder(ReplayBufferBuilder):
def build_replay_buffer(self, # type: ignore[override]
env_info: EnvironmentInfo,
algorithm_config: SACConfig,
**kwargs) -> ReplayBuffer:
return ReplayBuffer(capacity=algorithm_config.replay_buffer_size)
class DefaultExplorerBuilder(ExplorerBuilder):
def build_explorer(self, # type: ignore[override]
env_info: EnvironmentInfo,
algorithm_config: SACConfig,
algorithm: "SAC",
**kwargs) -> EnvironmentExplorer:
explorer_config = EE.RawPolicyExplorerConfig(
warmup_random_steps=algorithm_config.start_timesteps,
initial_step_num=algorithm.iteration_num,
timelimit_as_terminal=False
)
explorer = EE.RawPolicyExplorer(policy_action_selector=algorithm._compute_greedy_action,
env_info=env_info,
config=explorer_config)
return explorer
[docs]class SAC(Algorithm):
'''Soft Actor-Critic (SAC) algorithm implementation.
This class implements the extended version of Soft Actor Critic (SAC) algorithm
proposed by T. Haarnoja, et al. in the paper: "Soft Actor-Critic Algorithms and Applications"
For detail see: https://arxiv.org/abs/1812.05905
This algorithm is slightly differs from the implementation of Soft Actor-Critic algorithm presented
also by T. Haarnoja, et al. in the following paper: https://arxiv.org/abs/1801.01290
The temperature parameter is adjusted automatically instead of providing reward scalar as a
hyper parameter.
Args:
env_or_env_info \
(gym.Env or :py:class:`EnvironmentInfo <nnabla_rl.environments.environment_info.EnvironmentInfo>`):
the environment to train or environment info
config (:py:class:`SACConfig <nnabla_rl.algorithms.sac.ICML2018SACConfig>`): configuration of the SAC algorithm
q_function_builder (:py:class:`ModelBuilder[QFunction] <nnabla_rl.builders.ModelBuilder>`):
builder of q function models
q_solver_builder (:py:class:`SolverBuilder <nnabla_rl.builders.SolverBuilder>`):
builder of q function solvers
policy_builder (:py:class:`ModelBuilder[StochasticPolicy] <nnabla_rl.builders.ModelBuilder>`):
builder of actor models
policy_solver_builder (:py:class:`SolverBuilder <nnabla_rl.builders.SolverBuilder>`):
builder of policy solvers
temperature_solver_builder (:py:class:`SolverBuilder <nnabla_rl.builders.SolverBuilder>`):
builder of temperature solvers
replay_buffer_builder (:py:class:`ReplayBufferBuilder <nnabla_rl.builders.ReplayBufferBuilder>`):
builder of replay_buffer
explorer_builder (:py:class:`ExplorerBuilder <nnabla_rl.builders.ExplorerBuilder>`):
builder of environment explorer
'''
# type declarations to type check with mypy
# NOTE: declared variables are instance variable and NOT class variable, unless it is marked with ClassVar
# See https://mypy.readthedocs.io/en/stable/class_basics.html for details
_config: SACConfig
_q1: QFunction
_q2: QFunction
_train_q_functions: List[QFunction]
_train_q_solvers: Dict[str, nn.solver.Solver]
_target_q_functions: List[QFunction]
_pi: StochasticPolicy
_temperature: MT.policy_trainers.soft_policy_trainer.AdjustableTemperature
_temperature_solver: Optional[nn.solver.Solver]
_replay_buffer: ReplayBuffer
_explorer_builder: ExplorerBuilder
_environment_explorer: EnvironmentExplorer
_policy_trainer: ModelTrainer
_q_function_trainer: ModelTrainer
_eval_state_var: nn.Variable
_eval_deterministic_action: nn.Variable
_eval_probabilistic_action: nn.Variable
_policy_trainer_state: Dict[str, Any]
_q_function_trainer_state: Dict[str, Any]
def __init__(self, env_or_env_info: Union[gym.Env, EnvironmentInfo],
config: SACConfig = SACConfig(),
q_function_builder: ModelBuilder[QFunction] = DefaultQFunctionBuilder(),
q_solver_builder: SolverBuilder = DefaultSolverBuilder(),
policy_builder: ModelBuilder[StochasticPolicy] = DefaultPolicyBuilder(),
policy_solver_builder: SolverBuilder = DefaultSolverBuilder(),
temperature_solver_builder: SolverBuilder = DefaultSolverBuilder(),
replay_buffer_builder: ReplayBufferBuilder = DefaultReplayBufferBuilder(),
explorer_builder: ExplorerBuilder = DefaultExplorerBuilder()):
super(SAC, self).__init__(env_or_env_info, config=config)
self._explorer_builder = explorer_builder
with nn.context_scope(context.get_nnabla_context(self._config.gpu_id)):
self._q1 = q_function_builder(scope_name="q1", env_info=self._env_info, algorithm_config=self._config)
self._q2 = q_function_builder(scope_name="q2", env_info=self._env_info, algorithm_config=self._config)
self._train_q_functions = [self._q1, self._q2]
self._train_q_solvers = {q.scope_name: q_solver_builder(self._env_info, self._config)
for q in self._train_q_functions}
self._target_q_functions = [cast(QFunction, q.deepcopy('target_' + q.scope_name))
for q in self._train_q_functions]
self._pi = policy_builder(scope_name="pi", env_info=self._env_info, algorithm_config=self._config)
self._pi_solver = policy_solver_builder(self._env_info, self._config)
self._temperature = MT.policy_trainers.soft_policy_trainer.AdjustableTemperature(
scope_name='temperature',
initial_value=self._config.initial_temperature)
if not self._config.fix_temperature:
self._temperature_solver = temperature_solver_builder(self._env_info, self._config)
else:
self._temperature_solver = None
self._replay_buffer = replay_buffer_builder(self._env_info, self._config)
@eval_api
def compute_eval_action(self, state):
with nn.context_scope(context.get_nnabla_context(self._config.gpu_id)):
action, _ = self._compute_greedy_action(state, deterministic=True)
return action
def _before_training_start(self, env_or_buffer):
# set context globally to ensure that the training runs on configured gpu
context.set_nnabla_context(self._config.gpu_id)
self._environment_explorer = self._setup_environment_explorer(env_or_buffer)
self._policy_trainer = self._setup_policy_training(env_or_buffer)
self._q_function_trainer = self._setup_q_function_training(
env_or_buffer)
def _setup_environment_explorer(self, env_or_buffer):
return None if self._is_buffer(env_or_buffer) else self._explorer_builder(self._env_info, self._config, self)
def _setup_policy_training(self, env_or_buffer):
policy_trainer_config = MT.policy_trainers.SoftPolicyTrainerConfig(
fixed_temperature=self._config.fix_temperature,
target_entropy=self._config.target_entropy)
policy_trainer = MT.policy_trainers.SoftPolicyTrainer(
models=self._pi,
solvers={self._pi.scope_name: self._pi_solver},
temperature=self._temperature,
temperature_solver=self._temperature_solver,
q_functions=[self._q1, self._q2],
env_info=self._env_info,
config=policy_trainer_config)
return policy_trainer
def _setup_q_function_training(self, env_or_buffer):
# training input/loss variables
q_function_trainer_config = MT.q_value_trainers.SoftQTrainerConfig(
reduction_method='mean',
grad_clip=None)
q_function_trainer = MT.q_value_trainers.SoftQTrainer(
train_functions=self._train_q_functions,
solvers=self._train_q_solvers,
target_functions=self._target_q_functions,
target_policy=self._pi,
temperature=self._policy_trainer.get_temperature(),
env_info=self._env_info,
config=q_function_trainer_config)
for q, target_q in zip(self._train_q_functions, self._target_q_functions):
sync_model(q, target_q)
return q_function_trainer
def _run_online_training_iteration(self, env):
for _ in range(self._config.environment_steps):
self._run_environment_step(env)
for _ in range(self._config.gradient_steps):
self._run_gradient_step(self._replay_buffer)
def _run_offline_training_iteration(self, buffer):
self._sac_training(buffer)
def _run_environment_step(self, env):
experiences = self._environment_explorer.step(env)
self._replay_buffer.append_all(experiences)
def _run_gradient_step(self, replay_buffer):
if self._config.start_timesteps < self.iteration_num:
self._sac_training(replay_buffer)
def _sac_training(self, replay_buffer):
experiences, info = replay_buffer.sample(self._config.batch_size)
(s, a, r, non_terminal, s_next, *_) = marshal_experiences(experiences)
batch = TrainingBatch(batch_size=self._config.batch_size,
s_current=s,
a_current=a,
gamma=self._config.gamma,
reward=r,
non_terminal=non_terminal,
s_next=s_next,
weight=info['weights'])
self._q_function_trainer_state = self._q_function_trainer.train(batch)
for q, target_q in zip(self._train_q_functions, self._target_q_functions):
sync_model(q, target_q, tau=self._config.tau)
self._policy_trainer_state = self._policy_trainer.train(batch)
td_errors = self._q_function_trainer_state['td_errors']
replay_buffer.update_priorities(td_errors)
@eval_api
def _compute_greedy_action(self, s, deterministic=False):
# evaluation input/action variables
s = add_batch_dimension(s)
if not hasattr(self, '_eval_state_var'):
self._eval_state_var = create_variable(1, self._env_info.state_shape)
distribution = self._pi.pi(self._eval_state_var)
self._eval_deterministic_action = distribution.choose_probable()
self._eval_probabilistic_action = distribution.sample()
set_data_to_variable(self._eval_state_var, s)
if deterministic:
self._eval_deterministic_action.forward()
return np.squeeze(self._eval_deterministic_action.d, axis=0), {}
else:
self._eval_probabilistic_action.forward()
return np.squeeze(self._eval_probabilistic_action.d, axis=0), {}
def _models(self):
models = [self._q1, self._q2, self._pi, self._temperature]
return {model.scope_name: model for model in models}
def _solvers(self):
solvers = {}
solvers[self._pi.scope_name] = self._pi_solver
solvers.update(self._train_q_solvers)
if self._temperature_solver is not None:
solvers[self._temperature.scope_name] = self._temperature_solver
return solvers
@classmethod
def is_supported_env(cls, env_or_env_info):
env_info = EnvironmentInfo.from_env(env_or_env_info) if isinstance(env_or_env_info, gym.Env) \
else env_or_env_info
return not env_info.is_discrete_action_env()
@property
def latest_iteration_state(self):
latest_iteration_state = super(SAC, self).latest_iteration_state
if hasattr(self, '_policy_trainer_state'):
latest_iteration_state['scalar'].update({'pi_loss': self._policy_trainer_state['pi_loss']})
if hasattr(self, '_q_function_trainer_state'):
latest_iteration_state['scalar'].update({'q_loss': self._q_function_trainer_state['q_loss']})
latest_iteration_state['histogram'].update(
{'td_errors': self._q_function_trainer_state['td_errors'].flatten()})
return latest_iteration_state