teras.models.CTGANGenerator#
- class teras.models.CTGANGenerator(data_dim, metadata, hidden_dims=(256, 256), seed=1337, **kwargs)[source]#
CTGANGenerator for CTGAN architecture as proposed by Lei Xu et al. in the paper, “Modeling Tabular data using Conditional GAN”.
- Reference(s):
- Parameters:
data_dim (
int) – int, The dimensionality of the dataset. It will also be the dimensionality of the output produced by the generator. Note the dimensionality must be equal to the dimensionality of dataset that is passed to the fit method and not necessarily the dimensionality of the raw input dataset as sometimes data transformation alters the dimensionality of the dataset.metadata (
dict) – dict, CTGANGenerator applies different activation functions to its outputs depending on the type of features (categorical or continuous). And to determine the feature types and for other computations during the activation step, themetadatacomputed during the data transformation step, is required. It can be accessed through the .metadata property attribute of the CTGANDataTransformer instance which was used to transform the raw input data. Note that, this is NOT the same metadata as features_metadata, which is computed using the get_metadata_for_embedding utility function from teras.utils. You must access it through the .metadata property attribute of the CTGANDataTransformer.hidden_dims (
Union[List[int],Tuple[int]]) – Sequence, A sequence of integers that is used to construct the hidden block. For each value, a CTGANGeneratorLayer of that dimensionality is added. Defaults to [256, 256]
Methods
__init__(data_dim, metadata[, hidden_dims, seed])add_loss(loss)Can be called inside of the call() method to add a scalar loss.
add_metric()add_variable(shape, initializer[, dtype, ...])Add a weight variable to the layer.
add_weight([shape, initializer, dtype, ...])Add a weight variable to the layer.
apply_activations_by_feature_type(...)This function applies activation functions to the interim outputs of the Generator by feature type.
build(input_shape)build_from_config(config)Builds the layer's states with the supplied config dict.
call(inputs)compile([optimizer, loss, loss_weights, ...])Configures the model for training.
compile_from_config(config)Compiles the model with the information given in config.
compiled_loss(y, y_pred[, sample_weight, ...])compute_loss([x, y, y_pred, sample_weight, ...])Compute the total loss, validate it, and return it.
compute_mask(inputs, previous_mask)compute_metrics(x, y, y_pred[, sample_weight])Update metric states and collect all metrics to be returned.
compute_output_shape(input_shape)compute_output_spec(*args, **kwargs)count_params()Count the total number of scalars composing the weights.
evaluate([x, y, batch_size, verbose, ...])Returns the loss value & metrics values for the model in test mode.
export(filepath[, format])Create a TF SavedModel artifact for inference.
fit([x, y, batch_size, epochs, verbose, ...])Trains the model for a fixed number of epochs (dataset iterations).
from_config(config)Creates an operation from its config.
get_build_config()Returns a dictionary with the layer's input shape.
get_compile_config()Returns a serialized config with information for compiling the model.
get_config()Returns the config of the object.
get_layer([name, index])Retrieves a layer based on either its name (unique) or index.
get_metrics_result()Returns the model's metrics values as a dict.
get_weights()Return the values of layer.weights as a list of NumPy arrays.
load_own_variables(store)Loads the state of the layer.
load_weights(filepath[, skip_mismatch])Load weights from a file saved via save_weights().
loss(y, y_pred[, sample_weight])make_predict_function([force])make_test_function([force])make_train_function([force])predict(x[, batch_size, verbose, steps, ...])Generates output predictions for the input samples.
predict_on_batch(x)Returns predictions for a single batch of samples.
predict_step(inputs)quantize(mode)Quantize the weights of the model.
quantized_call(*args, **kwargs)reset_metrics()save(filepath[, overwrite, zipped])Saves a model as a .keras file.
save_own_variables(store)Saves the state of the layer.
save_weights(filepath[, overwrite])Saves all layer weights to a .weights.h5 file.
set_weights(weights)Sets the values of layer.weights from a list of NumPy arrays.
stateless_call(trainable_variables, ...[, ...])Call the layer without any side effects.
stateless_compute_loss(trainable_variables, ...)summary([line_length, positions, print_fn, ...])Prints a string summary of the network.
symbolic_call(*args, **kwargs)test_on_batch(x[, y, sample_weight, return_dict])Test the model on a single batch of samples.
test_step(data)to_json(**kwargs)Returns a JSON string containing the network configuration.
train_on_batch(x[, y, sample_weight, ...])Runs a single gradient update on a single batch of data.
train_step(data)Attributes
compiled_metricscompute_dtypeThe dtype of the computations performed by the layer.
distribute_reduction_methoddistribute_strategydtypeAlias of layer.variable_dtype.
dtype_policyinputRetrieves the input tensor(s) of a symbolic operation.
input_dtypeThe dtype layer inputs should be converted to.
input_specjit_compilelayerslossesList of scalar losses from add_loss, regularizers and sublayers.
metricsList of all metrics.
metrics_namesmetrics_variablesList of all metric variables.
non_trainable_variablesList of all non-trainable layer state.
non_trainable_weightsList of all non-trainable weight variables of the layer.
outputRetrieves the output tensor(s) of a layer.
pathThe path of the layer.
quantization_modeThe quantization mode of this layer, None if not quantized.
run_eagerlysupports_maskingWhether this layer supports computing a mask using compute_mask.
trainableSettable boolean, whether this layer should be trainable or not.
trainable_variablesList of all trainable layer state.
trainable_weightsList of all trainable weight variables of the layer.
variable_dtypeThe dtype of the state (weights) of the layer.
variablesList of all layer state, including random seeds.
weightsList of all weight variables of the layer.