Source code for h2o.estimators.deeplearning

#!/usr/bin/env python
# -*- encoding: utf-8 -*-
#
# This file is auto-generated by h2o-3/h2o-bindings/bin/gen_python.py
# Copyright 2016 H2O.ai;  Apache License Version 2.0 (see LICENSE for details)
#
from __future__ import absolute_import, division, print_function, unicode_literals

from h2o.estimators.estimator_base import H2OEstimator
from h2o.exceptions import H2OValueError
from h2o.frame import H2OFrame
from h2o.utils.typechecks import assert_is_type, Enum, numeric


[docs]class H2ODeepLearningEstimator(H2OEstimator): """ Deep Learning Build a Deep Neural Network model using CPUs Builds a feed-forward multilayer artificial neural network on an H2OFrame Examples -------- >>> import h2o >>> from h2o.estimators.deeplearning import H2ODeepLearningEstimator >>> h2o.connect() >>> rows = [[1,2,3,4,0], [2,1,2,4,1], [2,1,4,2,1], [0,1,2,34,1], [2,3,4,1,0]] * 50 >>> fr = h2o.H2OFrame(rows) >>> fr[4] = fr[4].asfactor() >>> model = H2ODeepLearningEstimator() >>> model.train(x=range(4), y=4, training_frame=fr) """ algo = "deeplearning" def __init__(self, **kwargs): super(H2ODeepLearningEstimator, self).__init__() self._parms = {} names_list = {"model_id", "training_frame", "validation_frame", "nfolds", "keep_cross_validation_predictions", "keep_cross_validation_fold_assignment", "fold_assignment", "fold_column", "response_column", "ignored_columns", "ignore_const_cols", "score_each_iteration", "weights_column", "offset_column", "balance_classes", "class_sampling_factors", "max_after_balance_size", "max_confusion_matrix_size", "max_hit_ratio_k", "checkpoint", "pretrained_autoencoder", "overwrite_with_best_model", "use_all_factor_levels", "standardize", "activation", "hidden", "epochs", "train_samples_per_iteration", "target_ratio_comm_to_comp", "seed", "adaptive_rate", "rho", "epsilon", "rate", "rate_annealing", "rate_decay", "momentum_start", "momentum_ramp", "momentum_stable", "nesterov_accelerated_gradient", "input_dropout_ratio", "hidden_dropout_ratios", "l1", "l2", "max_w2", "initial_weight_distribution", "initial_weight_scale", "initial_weights", "initial_biases", "loss", "distribution", "quantile_alpha", "tweedie_power", "huber_alpha", "score_interval", "score_training_samples", "score_validation_samples", "score_duty_cycle", "classification_stop", "regression_stop", "stopping_rounds", "stopping_metric", "stopping_tolerance", "max_runtime_secs", "score_validation_sampling", "diagnostics", "fast_mode", "force_load_balance", "variable_importances", "replicate_training_data", "single_node_mode", "shuffle_training_data", "missing_values_handling", "quiet_mode", "autoencoder", "sparse", "col_major", "average_activation", "sparsity_beta", "max_categorical_features", "reproducible", "export_weights_and_biases", "mini_batch_size", "categorical_encoding", "elastic_averaging", "elastic_averaging_moving_rate", "elastic_averaging_regularization"} if "Lambda" in kwargs: kwargs["lambda_"] = kwargs.pop("Lambda") for pname, pvalue in kwargs.items(): if pname == 'model_id': self._id = pvalue self._parms["model_id"] = pvalue elif pname in names_list: # Using setattr(...) will invoke type-checking of the arguments setattr(self, pname, pvalue) else: raise H2OValueError("Unknown parameter %s = %r" % (pname, pvalue)) if isinstance(self, H2OAutoEncoderEstimator): self._parms['autoencoder'] = True @property def training_frame(self): """ Id of the training data frame (Not required, to allow initial validation of model parameters). Type: ``H2OFrame``. """ return self._parms.get("training_frame") @training_frame.setter def training_frame(self, training_frame): assert_is_type(training_frame, None, H2OFrame) self._parms["training_frame"] = training_frame @property def validation_frame(self): """ Id of the validation data frame. Type: ``H2OFrame``. """ return self._parms.get("validation_frame") @validation_frame.setter def validation_frame(self, validation_frame): assert_is_type(validation_frame, None, H2OFrame) self._parms["validation_frame"] = validation_frame @property def nfolds(self): """ Number of folds for N-fold cross-validation (0 to disable or >= 2). Type: ``int`` (default: ``0``). """ return self._parms.get("nfolds") @nfolds.setter def nfolds(self, nfolds): assert_is_type(nfolds, None, int) self._parms["nfolds"] = nfolds @property def keep_cross_validation_predictions(self): """ Whether to keep the predictions of the cross-validation models. Type: ``bool`` (default: ``False``). """ return self._parms.get("keep_cross_validation_predictions") @keep_cross_validation_predictions.setter def keep_cross_validation_predictions(self, keep_cross_validation_predictions): assert_is_type(keep_cross_validation_predictions, None, bool) self._parms["keep_cross_validation_predictions"] = keep_cross_validation_predictions @property def keep_cross_validation_fold_assignment(self): """ Whether to keep the cross-validation fold assignment. Type: ``bool`` (default: ``False``). """ return self._parms.get("keep_cross_validation_fold_assignment") @keep_cross_validation_fold_assignment.setter def keep_cross_validation_fold_assignment(self, keep_cross_validation_fold_assignment): assert_is_type(keep_cross_validation_fold_assignment, None, bool) self._parms["keep_cross_validation_fold_assignment"] = keep_cross_validation_fold_assignment @property def fold_assignment(self): """ Cross-validation fold assignment scheme, if fold_column is not specified. The 'Stratified' option will stratify the folds based on the response variable, for classification problems. One of: ``"auto"``, ``"random"``, ``"modulo"``, ``"stratified"`` (default: ``"auto"``). """ return self._parms.get("fold_assignment") @fold_assignment.setter def fold_assignment(self, fold_assignment): assert_is_type(fold_assignment, None, Enum("auto", "random", "modulo", "stratified")) self._parms["fold_assignment"] = fold_assignment @property def fold_column(self): """ Column with cross-validation fold index assignment per observation. Type: ``str``. """ return self._parms.get("fold_column") @fold_column.setter def fold_column(self, fold_column): assert_is_type(fold_column, None, str) self._parms["fold_column"] = fold_column @property def response_column(self): """ Response variable column. Type: ``str``. """ return self._parms.get("response_column") @response_column.setter def response_column(self, response_column): assert_is_type(response_column, None, str) self._parms["response_column"] = response_column @property def ignored_columns(self): """ Names of columns to ignore for training. Type: ``List[str]``. """ return self._parms.get("ignored_columns") @ignored_columns.setter def ignored_columns(self, ignored_columns): assert_is_type(ignored_columns, None, [str]) self._parms["ignored_columns"] = ignored_columns @property def ignore_const_cols(self): """ Ignore constant columns. Type: ``bool`` (default: ``True``). """ return self._parms.get("ignore_const_cols") @ignore_const_cols.setter def ignore_const_cols(self, ignore_const_cols): assert_is_type(ignore_const_cols, None, bool) self._parms["ignore_const_cols"] = ignore_const_cols @property def score_each_iteration(self): """ Whether to score during each iteration of model training. Type: ``bool`` (default: ``False``). """ return self._parms.get("score_each_iteration") @score_each_iteration.setter def score_each_iteration(self, score_each_iteration): assert_is_type(score_each_iteration, None, bool) self._parms["score_each_iteration"] = score_each_iteration @property def weights_column(self): """ Column with observation weights. Giving some observation a weight of zero is equivalent to excluding it from the dataset; giving an observation a relative weight of 2 is equivalent to repeating that row twice. Negative weights are not allowed. Type: ``str``. """ return self._parms.get("weights_column") @weights_column.setter def weights_column(self, weights_column): assert_is_type(weights_column, None, str) self._parms["weights_column"] = weights_column @property def offset_column(self): """ Offset column. This will be added to the combination of columns before applying the link function. Type: ``str``. """ return self._parms.get("offset_column") @offset_column.setter def offset_column(self, offset_column): assert_is_type(offset_column, None, str) self._parms["offset_column"] = offset_column @property def balance_classes(self): """ Balance training data class counts via over/under-sampling (for imbalanced data). Type: ``bool`` (default: ``False``). """ return self._parms.get("balance_classes") @balance_classes.setter def balance_classes(self, balance_classes): assert_is_type(balance_classes, None, bool) self._parms["balance_classes"] = balance_classes @property def class_sampling_factors(self): """ Desired over/under-sampling ratios per class (in lexicographic order). If not specified, sampling factors will be automatically computed to obtain class balance during training. Requires balance_classes. Type: ``List[float]``. """ return self._parms.get("class_sampling_factors") @class_sampling_factors.setter def class_sampling_factors(self, class_sampling_factors): assert_is_type(class_sampling_factors, None, [float]) self._parms["class_sampling_factors"] = class_sampling_factors @property def max_after_balance_size(self): """ Maximum relative size of the training data after balancing class counts (can be less than 1.0). Requires balance_classes. Type: ``float`` (default: ``5``). """ return self._parms.get("max_after_balance_size") @max_after_balance_size.setter def max_after_balance_size(self, max_after_balance_size): assert_is_type(max_after_balance_size, None, float) self._parms["max_after_balance_size"] = max_after_balance_size @property def max_confusion_matrix_size(self): """ [Deprecated] Maximum size (# classes) for confusion matrices to be printed in the Logs. Type: ``int`` (default: ``20``). """ return self._parms.get("max_confusion_matrix_size") @max_confusion_matrix_size.setter def max_confusion_matrix_size(self, max_confusion_matrix_size): assert_is_type(max_confusion_matrix_size, None, int) self._parms["max_confusion_matrix_size"] = max_confusion_matrix_size @property def max_hit_ratio_k(self): """ Max. number (top K) of predictions to use for hit ratio computation (for multi-class only, 0 to disable). Type: ``int`` (default: ``0``). """ return self._parms.get("max_hit_ratio_k") @max_hit_ratio_k.setter def max_hit_ratio_k(self, max_hit_ratio_k): assert_is_type(max_hit_ratio_k, None, int) self._parms["max_hit_ratio_k"] = max_hit_ratio_k @property def checkpoint(self): """ Model checkpoint to resume training with. Type: ``str``. """ return self._parms.get("checkpoint") @checkpoint.setter def checkpoint(self, checkpoint): assert_is_type(checkpoint, None, str, H2OEstimator) self._parms["checkpoint"] = checkpoint @property def pretrained_autoencoder(self): """ Pretrained autoencoder model to initialize this model with. Type: ``str``. """ return self._parms.get("pretrained_autoencoder") @pretrained_autoencoder.setter def pretrained_autoencoder(self, pretrained_autoencoder): assert_is_type(pretrained_autoencoder, None, str, H2OEstimator) self._parms["pretrained_autoencoder"] = pretrained_autoencoder @property def overwrite_with_best_model(self): """ If enabled, override the final model with the best model found during training. Type: ``bool`` (default: ``True``). """ return self._parms.get("overwrite_with_best_model") @overwrite_with_best_model.setter def overwrite_with_best_model(self, overwrite_with_best_model): assert_is_type(overwrite_with_best_model, None, bool) self._parms["overwrite_with_best_model"] = overwrite_with_best_model @property def use_all_factor_levels(self): """ Use all factor levels of categorical variables. Otherwise, the first factor level is omitted (without loss of accuracy). Useful for variable importances and auto-enabled for autoencoder. Type: ``bool`` (default: ``True``). """ return self._parms.get("use_all_factor_levels") @use_all_factor_levels.setter def use_all_factor_levels(self, use_all_factor_levels): assert_is_type(use_all_factor_levels, None, bool) self._parms["use_all_factor_levels"] = use_all_factor_levels @property def standardize(self): """ If enabled, automatically standardize the data. If disabled, the user must provide properly scaled input data. Type: ``bool`` (default: ``True``). """ return self._parms.get("standardize") @standardize.setter def standardize(self, standardize): assert_is_type(standardize, None, bool) self._parms["standardize"] = standardize @property def activation(self): """ Activation function. One of: ``"tanh"``, ``"tanh_with_dropout"``, ``"rectifier"``, ``"rectifier_with_dropout"``, ``"maxout"``, ``"maxout_with_dropout"`` (default: ``"rectifier"``). """ return self._parms.get("activation") @activation.setter def activation(self, activation): assert_is_type(activation, None, Enum("tanh", "tanh_with_dropout", "rectifier", "rectifier_with_dropout", "maxout", "maxout_with_dropout")) self._parms["activation"] = activation @property def hidden(self): """ Hidden layer sizes (e.g. [100, 100]). Type: ``List[int]`` (default: ``[200, 200]``). """ return self._parms.get("hidden") @hidden.setter def hidden(self, hidden): assert_is_type(hidden, None, [int]) self._parms["hidden"] = hidden @property def epochs(self): """ How many times the dataset should be iterated (streamed), can be fractional. Type: ``float`` (default: ``10``). """ return self._parms.get("epochs") @epochs.setter def epochs(self, epochs): assert_is_type(epochs, None, numeric) self._parms["epochs"] = epochs @property def train_samples_per_iteration(self): """ Number of training samples (globally) per MapReduce iteration. Special values are 0: one epoch, -1: all available data (e.g., replicated training data), -2: automatic. Type: ``int`` (default: ``-2``). """ return self._parms.get("train_samples_per_iteration") @train_samples_per_iteration.setter def train_samples_per_iteration(self, train_samples_per_iteration): assert_is_type(train_samples_per_iteration, None, int) self._parms["train_samples_per_iteration"] = train_samples_per_iteration @property def target_ratio_comm_to_comp(self): """ Target ratio of communication overhead to computation. Only for multi-node operation and train_samples_per_iteration = -2 (auto-tuning). Type: ``float`` (default: ``0.05``). """ return self._parms.get("target_ratio_comm_to_comp") @target_ratio_comm_to_comp.setter def target_ratio_comm_to_comp(self, target_ratio_comm_to_comp): assert_is_type(target_ratio_comm_to_comp, None, numeric) self._parms["target_ratio_comm_to_comp"] = target_ratio_comm_to_comp @property def seed(self): """ Seed for random numbers (affects sampling) - Note: only reproducible when running single threaded. Type: ``int`` (default: ``-1``). """ return self._parms.get("seed") @seed.setter def seed(self, seed): assert_is_type(seed, None, int) self._parms["seed"] = seed @property def adaptive_rate(self): """ Adaptive learning rate. Type: ``bool`` (default: ``True``). """ return self._parms.get("adaptive_rate") @adaptive_rate.setter def adaptive_rate(self, adaptive_rate): assert_is_type(adaptive_rate, None, bool) self._parms["adaptive_rate"] = adaptive_rate @property def rho(self): """ Adaptive learning rate time decay factor (similarity to prior updates). Type: ``float`` (default: ``0.99``). """ return self._parms.get("rho") @rho.setter def rho(self, rho): assert_is_type(rho, None, numeric) self._parms["rho"] = rho @property def epsilon(self): """ Adaptive learning rate smoothing factor (to avoid divisions by zero and allow progress). Type: ``float`` (default: ``1e-08``). """ return self._parms.get("epsilon") @epsilon.setter def epsilon(self, epsilon): assert_is_type(epsilon, None, numeric) self._parms["epsilon"] = epsilon @property def rate(self): """ Learning rate (higher => less stable, lower => slower convergence). Type: ``float`` (default: ``0.005``). """ return self._parms.get("rate") @rate.setter def rate(self, rate): assert_is_type(rate, None, numeric) self._parms["rate"] = rate @property def rate_annealing(self): """ Learning rate annealing: rate / (1 + rate_annealing * samples). Type: ``float`` (default: ``1e-06``). """ return self._parms.get("rate_annealing") @rate_annealing.setter def rate_annealing(self, rate_annealing): assert_is_type(rate_annealing, None, numeric) self._parms["rate_annealing"] = rate_annealing @property def rate_decay(self): """ Learning rate decay factor between layers (N-th layer: rate * rate_decay ^ (n - 1). Type: ``float`` (default: ``1``). """ return self._parms.get("rate_decay") @rate_decay.setter def rate_decay(self, rate_decay): assert_is_type(rate_decay, None, numeric) self._parms["rate_decay"] = rate_decay @property def momentum_start(self): """ Initial momentum at the beginning of training (try 0.5). Type: ``float`` (default: ``0``). """ return self._parms.get("momentum_start") @momentum_start.setter def momentum_start(self, momentum_start): assert_is_type(momentum_start, None, numeric) self._parms["momentum_start"] = momentum_start @property def momentum_ramp(self): """ Number of training samples for which momentum increases. Type: ``float`` (default: ``1000000``). """ return self._parms.get("momentum_ramp") @momentum_ramp.setter def momentum_ramp(self, momentum_ramp): assert_is_type(momentum_ramp, None, numeric) self._parms["momentum_ramp"] = momentum_ramp @property def momentum_stable(self): """ Final momentum after the ramp is over (try 0.99). Type: ``float`` (default: ``0``). """ return self._parms.get("momentum_stable") @momentum_stable.setter def momentum_stable(self, momentum_stable): assert_is_type(momentum_stable, None, numeric) self._parms["momentum_stable"] = momentum_stable @property def nesterov_accelerated_gradient(self): """ Use Nesterov accelerated gradient (recommended). Type: ``bool`` (default: ``True``). """ return self._parms.get("nesterov_accelerated_gradient") @nesterov_accelerated_gradient.setter def nesterov_accelerated_gradient(self, nesterov_accelerated_gradient): assert_is_type(nesterov_accelerated_gradient, None, bool) self._parms["nesterov_accelerated_gradient"] = nesterov_accelerated_gradient @property def input_dropout_ratio(self): """ Input layer dropout ratio (can improve generalization, try 0.1 or 0.2). Type: ``float`` (default: ``0``). """ return self._parms.get("input_dropout_ratio") @input_dropout_ratio.setter def input_dropout_ratio(self, input_dropout_ratio): assert_is_type(input_dropout_ratio, None, numeric) self._parms["input_dropout_ratio"] = input_dropout_ratio @property def hidden_dropout_ratios(self): """ Hidden layer dropout ratios (can improve generalization), specify one value per hidden layer, defaults to 0.5. Type: ``List[float]``. """ return self._parms.get("hidden_dropout_ratios") @hidden_dropout_ratios.setter def hidden_dropout_ratios(self, hidden_dropout_ratios): assert_is_type(hidden_dropout_ratios, None, [numeric]) self._parms["hidden_dropout_ratios"] = hidden_dropout_ratios @property def l1(self): """ L1 regularization (can add stability and improve generalization, causes many weights to become 0). Type: ``float`` (default: ``0``). """ return self._parms.get("l1") @l1.setter def l1(self, l1): assert_is_type(l1, None, numeric) self._parms["l1"] = l1 @property def l2(self): """ L2 regularization (can add stability and improve generalization, causes many weights to be small. Type: ``float`` (default: ``0``). """ return self._parms.get("l2") @l2.setter def l2(self, l2): assert_is_type(l2, None, numeric) self._parms["l2"] = l2 @property def max_w2(self): """ Constraint for squared sum of incoming weights per unit (e.g. for Rectifier). Type: ``float`` (default: ``3.4028235e+38``). """ return self._parms.get("max_w2") @max_w2.setter def max_w2(self, max_w2): assert_is_type(max_w2, None, float) self._parms["max_w2"] = max_w2 @property def initial_weight_distribution(self): """ Initial weight distribution. One of: ``"uniform_adaptive"``, ``"uniform"``, ``"normal"`` (default: ``"uniform_adaptive"``). """ return self._parms.get("initial_weight_distribution") @initial_weight_distribution.setter def initial_weight_distribution(self, initial_weight_distribution): assert_is_type(initial_weight_distribution, None, Enum("uniform_adaptive", "uniform", "normal")) self._parms["initial_weight_distribution"] = initial_weight_distribution @property def initial_weight_scale(self): """ Uniform: -value...value, Normal: stddev. Type: ``float`` (default: ``1``). """ return self._parms.get("initial_weight_scale") @initial_weight_scale.setter def initial_weight_scale(self, initial_weight_scale): assert_is_type(initial_weight_scale, None, numeric) self._parms["initial_weight_scale"] = initial_weight_scale @property def initial_weights(self): """ A list of H2OFrame ids to initialize the weight matrices of this model with. Type: ``List[H2OFrame]``. """ return self._parms.get("initial_weights") @initial_weights.setter def initial_weights(self, initial_weights): assert_is_type(initial_weights, None, [H2OFrame, None]) self._parms["initial_weights"] = initial_weights @property def initial_biases(self): """ A list of H2OFrame ids to initialize the bias vectors of this model with. Type: ``List[H2OFrame]``. """ return self._parms.get("initial_biases") @initial_biases.setter def initial_biases(self, initial_biases): assert_is_type(initial_biases, None, [H2OFrame, None]) self._parms["initial_biases"] = initial_biases @property def loss(self): """ Loss function. One of: ``"automatic"``, ``"cross_entropy"``, ``"quadratic"``, ``"huber"``, ``"absolute"``, ``"quantile"`` (default: ``"automatic"``). """ return self._parms.get("loss") @loss.setter def loss(self, loss): assert_is_type(loss, None, Enum("automatic", "cross_entropy", "quadratic", "huber", "absolute", "quantile")) self._parms["loss"] = loss @property def distribution(self): """ Distribution function One of: ``"auto"``, ``"bernoulli"``, ``"multinomial"``, ``"gaussian"``, ``"poisson"``, ``"gamma"``, ``"tweedie"``, ``"laplace"``, ``"quantile"``, ``"huber"`` (default: ``"auto"``). """ return self._parms.get("distribution") @distribution.setter def distribution(self, distribution): assert_is_type(distribution, None, Enum("auto", "bernoulli", "multinomial", "gaussian", "poisson", "gamma", "tweedie", "laplace", "quantile", "huber")) self._parms["distribution"] = distribution @property def quantile_alpha(self): """ Desired quantile for Quantile regression, must be between 0 and 1. Type: ``float`` (default: ``0.5``). """ return self._parms.get("quantile_alpha") @quantile_alpha.setter def quantile_alpha(self, quantile_alpha): assert_is_type(quantile_alpha, None, numeric) self._parms["quantile_alpha"] = quantile_alpha @property def tweedie_power(self): """ Tweedie power for Tweedie regression, must be between 1 and 2. Type: ``float`` (default: ``1.5``). """ return self._parms.get("tweedie_power") @tweedie_power.setter def tweedie_power(self, tweedie_power): assert_is_type(tweedie_power, None, numeric) self._parms["tweedie_power"] = tweedie_power @property def huber_alpha(self): """ Desired quantile for Huber/M-regression (threshold between quadratic and linear loss, must be between 0 and 1). Type: ``float`` (default: ``0.9``). """ return self._parms.get("huber_alpha") @huber_alpha.setter def huber_alpha(self, huber_alpha): assert_is_type(huber_alpha, None, numeric) self._parms["huber_alpha"] = huber_alpha @property def score_interval(self): """ Shortest time interval (in seconds) between model scoring. Type: ``float`` (default: ``5``). """ return self._parms.get("score_interval") @score_interval.setter def score_interval(self, score_interval): assert_is_type(score_interval, None, numeric) self._parms["score_interval"] = score_interval @property def score_training_samples(self): """ Number of training set samples for scoring (0 for all). Type: ``int`` (default: ``10000``). """ return self._parms.get("score_training_samples") @score_training_samples.setter def score_training_samples(self, score_training_samples): assert_is_type(score_training_samples, None, int) self._parms["score_training_samples"] = score_training_samples @property def score_validation_samples(self): """ Number of validation set samples for scoring (0 for all). Type: ``int`` (default: ``0``). """ return self._parms.get("score_validation_samples") @score_validation_samples.setter def score_validation_samples(self, score_validation_samples): assert_is_type(score_validation_samples, None, int) self._parms["score_validation_samples"] = score_validation_samples @property def score_duty_cycle(self): """ Maximum duty cycle fraction for scoring (lower: more training, higher: more scoring). Type: ``float`` (default: ``0.1``). """ return self._parms.get("score_duty_cycle") @score_duty_cycle.setter def score_duty_cycle(self, score_duty_cycle): assert_is_type(score_duty_cycle, None, numeric) self._parms["score_duty_cycle"] = score_duty_cycle @property def classification_stop(self): """ Stopping criterion for classification error fraction on training data (-1 to disable). Type: ``float`` (default: ``0``). """ return self._parms.get("classification_stop") @classification_stop.setter def classification_stop(self, classification_stop): assert_is_type(classification_stop, None, numeric) self._parms["classification_stop"] = classification_stop @property def regression_stop(self): """ Stopping criterion for regression error (MSE) on training data (-1 to disable). Type: ``float`` (default: ``1e-06``). """ return self._parms.get("regression_stop") @regression_stop.setter def regression_stop(self, regression_stop): assert_is_type(regression_stop, None, numeric) self._parms["regression_stop"] = regression_stop @property def stopping_rounds(self): """ Early stopping based on convergence of stopping_metric. Stop if simple moving average of length k of the stopping_metric does not improve for k:=stopping_rounds scoring events (0 to disable) Type: ``int`` (default: ``5``). """ return self._parms.get("stopping_rounds") @stopping_rounds.setter def stopping_rounds(self, stopping_rounds): assert_is_type(stopping_rounds, None, int) self._parms["stopping_rounds"] = stopping_rounds @property def stopping_metric(self): """ Metric to use for early stopping (AUTO: logloss for classification, deviance for regression) One of: ``"auto"``, ``"deviance"``, ``"logloss"``, ``"mse"``, ``"rmse"``, ``"mae"``, ``"rmsle"``, ``"auc"``, ``"lift_top_group"``, ``"misclassification"``, ``"mean_per_class_error"`` (default: ``"auto"``). """ return self._parms.get("stopping_metric") @stopping_metric.setter def stopping_metric(self, stopping_metric): assert_is_type(stopping_metric, None, Enum("auto", "deviance", "logloss", "mse", "rmse", "mae", "rmsle", "auc", "lift_top_group", "misclassification", "mean_per_class_error")) self._parms["stopping_metric"] = stopping_metric @property def stopping_tolerance(self): """ Relative tolerance for metric-based stopping criterion (stop if relative improvement is not at least this much) Type: ``float`` (default: ``0``). """ return self._parms.get("stopping_tolerance") @stopping_tolerance.setter def stopping_tolerance(self, stopping_tolerance): assert_is_type(stopping_tolerance, None, numeric) self._parms["stopping_tolerance"] = stopping_tolerance @property def max_runtime_secs(self): """ Maximum allowed runtime in seconds for model training. Use 0 to disable. Type: ``float`` (default: ``0``). """ return self._parms.get("max_runtime_secs") @max_runtime_secs.setter def max_runtime_secs(self, max_runtime_secs): assert_is_type(max_runtime_secs, None, numeric) self._parms["max_runtime_secs"] = max_runtime_secs @property def score_validation_sampling(self): """ Method used to sample validation dataset for scoring. One of: ``"uniform"``, ``"stratified"`` (default: ``"uniform"``). """ return self._parms.get("score_validation_sampling") @score_validation_sampling.setter def score_validation_sampling(self, score_validation_sampling): assert_is_type(score_validation_sampling, None, Enum("uniform", "stratified")) self._parms["score_validation_sampling"] = score_validation_sampling @property def diagnostics(self): """ Enable diagnostics for hidden layers. Type: ``bool`` (default: ``True``). """ return self._parms.get("diagnostics") @diagnostics.setter def diagnostics(self, diagnostics): assert_is_type(diagnostics, None, bool) self._parms["diagnostics"] = diagnostics @property def fast_mode(self): """ Enable fast mode (minor approximation in back-propagation). Type: ``bool`` (default: ``True``). """ return self._parms.get("fast_mode") @fast_mode.setter def fast_mode(self, fast_mode): assert_is_type(fast_mode, None, bool) self._parms["fast_mode"] = fast_mode @property def force_load_balance(self): """ Force extra load balancing to increase training speed for small datasets (to keep all cores busy). Type: ``bool`` (default: ``True``). """ return self._parms.get("force_load_balance") @force_load_balance.setter def force_load_balance(self, force_load_balance): assert_is_type(force_load_balance, None, bool) self._parms["force_load_balance"] = force_load_balance @property def variable_importances(self): """ Compute variable importances for input features (Gedeon method) - can be slow for large networks. Type: ``bool`` (default: ``False``). """ return self._parms.get("variable_importances") @variable_importances.setter def variable_importances(self, variable_importances): assert_is_type(variable_importances, None, bool) self._parms["variable_importances"] = variable_importances @property def replicate_training_data(self): """ Replicate the entire training dataset onto every node for faster training on small datasets. Type: ``bool`` (default: ``True``). """ return self._parms.get("replicate_training_data") @replicate_training_data.setter def replicate_training_data(self, replicate_training_data): assert_is_type(replicate_training_data, None, bool) self._parms["replicate_training_data"] = replicate_training_data @property def single_node_mode(self): """ Run on a single node for fine-tuning of model parameters. Type: ``bool`` (default: ``False``). """ return self._parms.get("single_node_mode") @single_node_mode.setter def single_node_mode(self, single_node_mode): assert_is_type(single_node_mode, None, bool) self._parms["single_node_mode"] = single_node_mode @property def shuffle_training_data(self): """ Enable shuffling of training data (recommended if training data is replicated and train_samples_per_iteration is close to #nodes x #rows, of if using balance_classes). Type: ``bool`` (default: ``False``). """ return self._parms.get("shuffle_training_data") @shuffle_training_data.setter def shuffle_training_data(self, shuffle_training_data): assert_is_type(shuffle_training_data, None, bool) self._parms["shuffle_training_data"] = shuffle_training_data @property def missing_values_handling(self): """ Handling of missing values. Either MeanImputation or Skip. One of: ``"mean_imputation"``, ``"skip"`` (default: ``"mean_imputation"``). """ return self._parms.get("missing_values_handling") @missing_values_handling.setter def missing_values_handling(self, missing_values_handling): assert_is_type(missing_values_handling, None, Enum("mean_imputation", "skip")) self._parms["missing_values_handling"] = missing_values_handling @property def quiet_mode(self): """ Enable quiet mode for less output to standard output. Type: ``bool`` (default: ``False``). """ return self._parms.get("quiet_mode") @quiet_mode.setter def quiet_mode(self, quiet_mode): assert_is_type(quiet_mode, None, bool) self._parms["quiet_mode"] = quiet_mode @property def autoencoder(self): """ Auto-Encoder. Type: ``bool`` (default: ``False``). """ return self._parms.get("autoencoder") @autoencoder.setter def autoencoder(self, autoencoder): assert_is_type(autoencoder, None, bool) self._parms["autoencoder"] = autoencoder @property def sparse(self): """ Sparse data handling (more efficient for data with lots of 0 values). Type: ``bool`` (default: ``False``). """ return self._parms.get("sparse") @sparse.setter def sparse(self, sparse): assert_is_type(sparse, None, bool) self._parms["sparse"] = sparse @property def col_major(self): """ #DEPRECATED Use a column major weight matrix for input layer. Can speed up forward propagation, but might slow down backpropagation. Type: ``bool`` (default: ``False``). """ return self._parms.get("col_major") @col_major.setter def col_major(self, col_major): assert_is_type(col_major, None, bool) self._parms["col_major"] = col_major @property def average_activation(self): """ Average activation for sparse auto-encoder. #Experimental Type: ``float`` (default: ``0``). """ return self._parms.get("average_activation") @average_activation.setter def average_activation(self, average_activation): assert_is_type(average_activation, None, numeric) self._parms["average_activation"] = average_activation @property def sparsity_beta(self): """ Sparsity regularization. #Experimental Type: ``float`` (default: ``0``). """ return self._parms.get("sparsity_beta") @sparsity_beta.setter def sparsity_beta(self, sparsity_beta): assert_is_type(sparsity_beta, None, numeric) self._parms["sparsity_beta"] = sparsity_beta @property def max_categorical_features(self): """ Max. number of categorical features, enforced via hashing. #Experimental Type: ``int`` (default: ``2147483647``). """ return self._parms.get("max_categorical_features") @max_categorical_features.setter def max_categorical_features(self, max_categorical_features): assert_is_type(max_categorical_features, None, int) self._parms["max_categorical_features"] = max_categorical_features @property def reproducible(self): """ Force reproducibility on small data (will be slow - only uses 1 thread). Type: ``bool`` (default: ``False``). """ return self._parms.get("reproducible") @reproducible.setter def reproducible(self, reproducible): assert_is_type(reproducible, None, bool) self._parms["reproducible"] = reproducible @property def export_weights_and_biases(self): """ Whether to export Neural Network weights and biases to H2O Frames. Type: ``bool`` (default: ``False``). """ return self._parms.get("export_weights_and_biases") @export_weights_and_biases.setter def export_weights_and_biases(self, export_weights_and_biases): assert_is_type(export_weights_and_biases, None, bool) self._parms["export_weights_and_biases"] = export_weights_and_biases @property def mini_batch_size(self): """ Mini-batch size (smaller leads to better fit, larger can speed up and generalize better). Type: ``int`` (default: ``1``). """ return self._parms.get("mini_batch_size") @mini_batch_size.setter def mini_batch_size(self, mini_batch_size): assert_is_type(mini_batch_size, None, int) self._parms["mini_batch_size"] = mini_batch_size @property def categorical_encoding(self): """ Encoding scheme for categorical features One of: ``"auto"``, ``"enum"``, ``"one_hot_internal"``, ``"one_hot_explicit"``, ``"binary"``, ``"eigen"`` (default: ``"auto"``). """ return self._parms.get("categorical_encoding") @categorical_encoding.setter def categorical_encoding(self, categorical_encoding): assert_is_type(categorical_encoding, None, Enum("auto", "enum", "one_hot_internal", "one_hot_explicit", "binary", "eigen")) self._parms["categorical_encoding"] = categorical_encoding @property def elastic_averaging(self): """ Elastic averaging between compute nodes can improve distributed model convergence. #Experimental Type: ``bool`` (default: ``False``). """ return self._parms.get("elastic_averaging") @elastic_averaging.setter def elastic_averaging(self, elastic_averaging): assert_is_type(elastic_averaging, None, bool) self._parms["elastic_averaging"] = elastic_averaging @property def elastic_averaging_moving_rate(self): """ Elastic averaging moving rate (only if elastic averaging is enabled). Type: ``float`` (default: ``0.9``). """ return self._parms.get("elastic_averaging_moving_rate") @elastic_averaging_moving_rate.setter def elastic_averaging_moving_rate(self, elastic_averaging_moving_rate): assert_is_type(elastic_averaging_moving_rate, None, numeric) self._parms["elastic_averaging_moving_rate"] = elastic_averaging_moving_rate @property def elastic_averaging_regularization(self): """ Elastic averaging regularization strength (only if elastic averaging is enabled). Type: ``float`` (default: ``0.001``). """ return self._parms.get("elastic_averaging_regularization") @elastic_averaging_regularization.setter def elastic_averaging_regularization(self, elastic_averaging_regularization): assert_is_type(elastic_averaging_regularization, None, numeric) self._parms["elastic_averaging_regularization"] = elastic_averaging_regularization
[docs]class H2OAutoEncoderEstimator(H2ODeepLearningEstimator): """ Examples -------- >>> import h2o as ml >>> from h2o.estimators.deeplearning import H2OAutoEncoderEstimator >>> ml.init() >>> rows = [[1,2,3,4,0]*50, [2,1,2,4,1]*50, [2,1,4,2,1]*50, [0,1,2,34,1]*50, [2,3,4,1,0]*50] >>> fr = ml.H2OFrame(rows) >>> fr[4] = fr[4].asfactor() >>> model = H2OAutoEncoderEstimator() >>> model.train(x=range(4), training_frame=fr) """ pass