garage.tf.baselines.gaussian_cnn_baseline_model
¶
GaussianCNNRegressorModel.
-
class
GaussianCNNBaselineModel
(input_shape, output_dim, filters, strides, padding, hidden_sizes, name='GaussianCNNRegressorModel', hidden_nonlinearity=tf.nn.tanh, hidden_w_init=tf.initializers.glorot_uniform(seed=deterministic.get_tf_seed_stream()), hidden_b_init=tf.zeros_initializer(), output_nonlinearity=None, output_w_init=tf.initializers.glorot_uniform(seed=deterministic.get_tf_seed_stream()), output_b_init=tf.zeros_initializer(), learn_std=True, adaptive_std=False, std_share_network=False, init_std=1.0, min_std=1e-06, max_std=None, std_filters=(), std_strides=(), std_padding='SAME', std_hidden_sizes=(32, 32), std_hidden_nonlinearity=tf.nn.tanh, std_hidden_w_init=tf.initializers.glorot_uniform(seed=deterministic.get_tf_seed_stream()), std_hidden_b_init=tf.zeros_initializer(), std_output_nonlinearity=None, std_output_w_init=tf.initializers.glorot_uniform(seed=deterministic.get_tf_seed_stream()), std_parameterization='exp', layer_normalization=False)¶ Bases:
garage.tf.models.GaussianCNNModel
GaussianCNNBaseline based on garage.tf.models.Model class.
This class can be used to perform regression by fitting a Gaussian distribution to the outputs.
Parameters: - input_shape (tuple[int]) – Input shape of the model (without the batch dimension).
- filters (Tuple[Tuple[int, Tuple[int, int]], ..]) – Number and dimension of filters. For example, ((3, (3, 5)), (32, (3, 3))) means there are two convolutional layers. The filter for the first layer have 3 channels and its shape is (3 x 5), while the filter for the second layer have 32 channels and its shape is (3 x 3).
- strides (tuple[int]) – The stride of the sliding window. For example, (1, 2) means there are two convolutional layers. The stride of the filter for first layer is 1 and that of the second layer is 2.
- padding (str) – The type of padding algorithm to use, either ‘SAME’ or ‘VALID’.
- output_dim (int) – Output dimension of the model.
- name (str) – Model name, also the variable scope.
- hidden_sizes (list[int]) – Output dimension of dense layer(s) for the Convolutional model for mean. For example, (32, 32) means the network consists of two dense layers, each with 32 hidden units.
- hidden_nonlinearity (callable) – Activation function for intermediate dense layer(s). It should return a tf.Tensor. Set it to None to maintain a linear activation.
- hidden_w_init (callable) – Initializer function for the weight of intermediate dense layer(s). The function should return a tf.Tensor.
- hidden_b_init (callable) – Initializer function for the bias of intermediate dense layer(s). The function should return a tf.Tensor.
- output_nonlinearity (callable) – Activation function for output dense layer. It should return a tf.Tensor. Set it to None to maintain a linear activation.
- output_w_init (callable) – Initializer function for the weight of output dense layer(s). The function should return a tf.Tensor.
- output_b_init (callable) – Initializer function for the bias of output dense layer(s). The function should return a tf.Tensor.
- learn_std (bool) – Is std trainable.
- init_std (float) – Initial value for std.
- adaptive_std (bool) – Is std a neural network. If False, it will be a parameter.
- std_share_network (bool) – Boolean for whether mean and std share the same network.
- std_filters (Tuple[Tuple[int, Tuple[int, int]], ..]) – Number and dimension of filters. For example, ((3, (3, 5)), (32, (3, 3))) means there are two convolutional layers. The filter for the first layer have 3 channels and its shape is (3 x 5), while the filter for the second layer have 32 channels and its shape is (3 x 3).
- std_strides (tuple[int]) – The stride of the sliding window. For example, (1, 2) means there are two convolutional layers. The stride of the filter for first layer is 1 and that of the second layer is 2.
- std_padding (str) – The type of padding algorithm to use in std network, either ‘SAME’ or ‘VALID’.
- std_hidden_sizes (list[int]) – Output dimension of dense layer(s) for the Conv for std. For example, (32, 32) means the Conv consists of two hidden layers, each with 32 hidden units.
- min_std (float) – If not None, the std is at least the value of min_std, to avoid numerical issues.
- max_std (float) – If not None, the std is at most the value of max_std, to avoid numerical issues.
- std_hidden_nonlinearity (callable) – Nonlinearity for each hidden layer in the std network.
- std_hidden_w_init (callable) – Initializer function for the weight of intermediate dense layer(s) in the std network.
- std_hidden_b_init (callable) – Initializer function for the bias of intermediate dense layer(s) in the std network.
- std_output_nonlinearity (callable) – Activation function for output dense layer in the std network. It should return a tf.Tensor. Set it to None to maintain a linear activation.
- std_output_w_init (callable) – Initializer function for the weight of output dense layer(s) in the std network.
- std_parameterization (str) –
How the std should be parametrized. There are two options: - exp: the logarithm of the std will be stored, and applied a
exponential transformation- softplus: the std will be computed as log(1+exp(x))
- layer_normalization (bool) – Bool for using layer normalization or not.
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parameters
¶ Parameters of the model.
Returns: Parameters Return type: np.ndarray
-
name
¶ Name (str) of the model.
This is also the variable scope of the model.
Returns: Name of the model. Return type: str
-
input
¶ Default input of the model.
When the model is built the first time, by default it creates the ‘default’ network. This property creates a reference to the input of the network.
Returns: Default input of the model. Return type: tf.Tensor
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output
¶ Default output of the model.
When the model is built the first time, by default it creates the ‘default’ network. This property creates a reference to the output of the network.
Returns: Default output of the model. Return type: tf.Tensor
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inputs
¶ Default inputs of the model.
When the model is built the first time, by default it creates the ‘default’ network. This property creates a reference to the inputs of the network.
Returns: Default inputs of the model. Return type: list[tf.Tensor]
-
outputs
¶ Default outputs of the model.
When the model is built the first time, by default it creates the ‘default’ network. This property creates a reference to the outputs of the network.
Returns: Default outputs of the model. Return type: list[tf.Tensor]
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state_info_specs
¶ State info specification.
Returns: - keys and shapes for the information related to the
- module’s state when taking an action.
Return type: List[str]
-
state_info_keys
¶ State info keys.
Returns: - keys for the information related to the module’s state
- when taking an input.
Return type: List[str]
-
network_output_spec
(self)¶ Network output spec.
Returns: List of key(str) for the network outputs. Return type: list[str]
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build
(self, *inputs, name=None)¶ Build a Network with the given input(s).
* Do not call tf.global_variable_initializers() after building a model as it will reassign random weights to the model. The parameters inside a model will be initialized when calling build(). *
It uses the same, fixed variable scope for all Networks, to ensure parameter sharing. Different Networks must have an unique name.
Parameters: Raises: ValueError
– When a Network with the same name is already built.Returns: - Output tensors of the model with the given
inputs.
Return type: list[tf.Tensor]
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network_input_spec
(self)¶ Network input spec.
Returns: List of key(str) for the network inputs. Return type: list[str]
-
reset
(self, do_resets=None)¶ Reset the module.
This is effective only to recurrent modules. do_resets is effective only to vectoried modules.
For a vectorized modules, do_resets is an array of boolean indicating which internal states to be reset. The length of do_resets should be equal to the length of inputs.
Parameters: do_resets (numpy.ndarray) – Bool array indicating which states to be reset.
-
terminate
(self)¶ Clean up operation.
-
get_trainable_vars
(self)¶ Get trainable variables.
Returns: - A list of trainable variables in the current
- variable scope.
Return type: List[tf.Variable]
-
get_global_vars
(self)¶ Get global variables.
Returns: - A list of global variables in the current
- variable scope.
Return type: List[tf.Variable]
-
get_regularizable_vars
(self)¶ Get all network weight variables in the current scope.
Returns: - A list of network weight variables in the
- current variable scope.
Return type: List[tf.Variable]
-
get_params
(self)¶ Get the trainable variables.
Returns: - A list of trainable variables in the current
- variable scope.
Return type: List[tf.Variable]
-
get_param_shapes
(self)¶ Get parameter shapes.
Returns: A list of variable shapes. Return type: List[tuple]
-
get_param_values
(self)¶ Get param values.
Returns: - Values of the parameters evaluated in
- the current session
Return type: np.ndarray
-
set_param_values
(self, param_values)¶ Set param values.
Parameters: param_values (np.ndarray) – A numpy array of parameter values.
-
flat_to_params
(self, flattened_params)¶ Unflatten tensors according to their respective shapes.
Parameters: flattened_params (np.ndarray) – A numpy array of flattened params. Returns: - A list of parameters reshaped to the
- shapes specified.
Return type: List[np.ndarray]