Linear UCB Policy.
Inherits From: LinearBanditPolicy
, TFPolicy
tf_agents.bandits.policies.lin_ucb_policy.LinearUCBPolicy(
action_spec: tf_agents.typing.types.BoundedTensorSpec
,
cov_matrix: Sequence[tf_agents.typing.types.Float
],
data_vector: Sequence[tf_agents.typing.types.Float
],
num_samples: Sequence[tf_agents.typing.types.Int
],
time_step_spec: Optional[tf_agents.typing.types.TimeStep
] = None,
alpha: float = 1.0,
eig_vals: Sequence[tf_agents.typing.types.Float
] = (),
eig_matrix: Sequence[tf_agents.typing.types.Float
] = (),
tikhonov_weight: float = 1.0,
add_bias: bool = False,
emit_policy_info: Sequence[Text] = (),
emit_log_probability: bool = False,
observation_and_action_constraint_splitter: Optional[types.Splitter] = None,
name: Optional[Text] = None
)
Implements the Linear UCB Policy from the following paper:
"A Contextual Bandit Approach to Personalized News Article Recommendation",
Lihong Li, Wei Chu, John Langford, Robert Schapire, WWW 2010.
Args |
action_spec
|
TensorSpec containing action specification.
|
cov_matrix
|
list of the covariance matrices A in the paper. There exists
one A matrix per arm.
|
data_vector
|
list of the b vectors in the paper. The b vector is a
weighted sum of the observations, where the weight is the corresponding
reward. Each arm has its own vector b.
|
num_samples
|
list of number of samples per arm.
|
time_step_spec
|
A TimeStep spec of the expected time_steps.
|
alpha
|
a float value used to scale the confidence intervals.
|
eig_vals
|
list of eigenvalues for each covariance matrix (one per arm).
|
eig_matrix
|
list of eigenvectors for each covariance matrix (one per arm).
|
tikhonov_weight
|
(float) tikhonov regularization term.
|
add_bias
|
If true, a bias term will be added to the linear reward
estimation.
|
emit_policy_info
|
(tuple of strings) what side information we want to get
as part of the policy info. Allowed values can be found in
policy_utilities.PolicyInfo .
|
emit_log_probability
|
Whether to emit log probabilities.
|
observation_and_action_constraint_splitter
|
A function used for masking
valid/invalid actions with each state of the environment. The function
takes in a full observation and returns a tuple consisting of 1) the
part of the observation intended as input to the bandit policy and 2)
the mask. The mask should be a 0-1 Tensor of shape [batch_size,
num_actions] . This function should also work with a TensorSpec as
input, and should output TensorSpec objects for the observation and
mask.
|
name
|
The name of this policy.
|
Attributes |
action_spec
|
Describes the TensorSpecs of the Tensors expected by step(action) .
action can be a single Tensor, or a nested dict, list or tuple of
Tensors.
|
collect_data_spec
|
Describes the Tensors written when using this policy with an environment.
|
emit_log_probability
|
Whether this policy instance emits log probabilities or not.
|
info_spec
|
Describes the Tensors emitted as info by action and distribution .
info can be an empty tuple, a single Tensor, or a nested dict,
list or tuple of Tensors.
|
observation_and_action_constraint_splitter
|
|
policy_state_spec
|
Describes the Tensors expected by step(_, policy_state) .
policy_state can be an empty tuple, a single Tensor, or a nested dict,
list or tuple of Tensors.
|
policy_step_spec
|
Describes the output of action() .
|
time_step_spec
|
Describes the TimeStep tensors returned by step() .
|
trajectory_spec
|
Describes the Tensors written when using this policy with an environment.
|
validate_args
|
Whether action & distribution validate input and output args.
|
Methods
action
View source
action(
time_step: tf_agents.trajectories.TimeStep
,
policy_state: tf_agents.typing.types.NestedTensor
= (),
seed: Optional[types.Seed] = None
) -> tf_agents.trajectories.PolicyStep
Generates next action given the time_step and policy_state.
Args |
time_step
|
A TimeStep tuple corresponding to time_step_spec() .
|
policy_state
|
A Tensor, or a nested dict, list or tuple of Tensors
representing the previous policy_state.
|
seed
|
Seed to use if action performs sampling (optional).
|
Returns |
A PolicyStep named tuple containing:
action : An action Tensor matching the action_spec .
state : A policy state tensor to be fed into the next call to action.
info : Optional side information such as action log probabilities.
|
Raises |
RuntimeError
|
If subclass init didn't call super().init.
ValueError or TypeError: If validate_args is True and inputs or
outputs do not match time_step_spec , policy_state_spec ,
or policy_step_spec .
|
distribution
View source
distribution(
time_step: tf_agents.trajectories.TimeStep
,
policy_state: tf_agents.typing.types.NestedTensor
= ()
) -> tf_agents.trajectories.PolicyStep
Generates the distribution over next actions given the time_step.
Args |
time_step
|
A TimeStep tuple corresponding to time_step_spec() .
|
policy_state
|
A Tensor, or a nested dict, list or tuple of Tensors
representing the previous policy_state.
|
Returns |
A PolicyStep named tuple containing:
action : A tf.distribution capturing the distribution of next actions.
state : A policy state tensor for the next call to distribution.
info : Optional side information such as action log probabilities.
|
Raises |
ValueError or TypeError: If validate_args is True and inputs or
outputs do not match time_step_spec , policy_state_spec ,
or policy_step_spec .
|
get_initial_state
View source
get_initial_state(
batch_size: Optional[types.Int]
) -> tf_agents.typing.types.NestedTensor
Returns an initial state usable by the policy.
Args |
batch_size
|
Tensor or constant: size of the batch dimension. Can be None
in which case no dimensions gets added.
|
Returns |
A nested object of type policy_state containing properly
initialized Tensors.
|
update
View source
update(
policy,
tau: float = 1.0,
tau_non_trainable: Optional[float] = None,
sort_variables_by_name: bool = False
) -> tf.Operation
Update the current policy with another policy.
This would include copying the variables from the other policy.
Args |
policy
|
Another policy it can update from.
|
tau
|
A float scalar in [0, 1]. When tau is 1.0 (the default), we do a hard
update. This is used for trainable variables.
|
tau_non_trainable
|
A float scalar in [0, 1] for non_trainable variables.
If None, will copy from tau.
|
sort_variables_by_name
|
A bool, when True would sort the variables by name
before doing the update.
|
Returns |
An TF op to do the update.
|