Spark ML – Random Forest

R/ml_classification_random_forest_classifier.R,

ml_random_forest_classifier

Description

Perform classification and regression using random forests.

Usage

 
ml_random_forest_classifier( 
  x, 
  formula = NULL, 
  num_trees = 20, 
  subsampling_rate = 1, 
  max_depth = 5, 
  min_instances_per_node = 1, 
  feature_subset_strategy = "auto", 
  impurity = "gini", 
  min_info_gain = 0, 
  max_bins = 32, 
  seed = NULL, 
  thresholds = NULL, 
  checkpoint_interval = 10, 
  cache_node_ids = FALSE, 
  max_memory_in_mb = 256, 
  features_col = "features", 
  label_col = "label", 
  prediction_col = "prediction", 
  probability_col = "probability", 
  raw_prediction_col = "rawPrediction", 
  uid = random_string("random_forest_classifier_"), 
  ... 
) 
 
ml_random_forest( 
  x, 
  formula = NULL, 
  type = c("auto", "regression", "classification"), 
  features_col = "features", 
  label_col = "label", 
  prediction_col = "prediction", 
  probability_col = "probability", 
  raw_prediction_col = "rawPrediction", 
  feature_subset_strategy = "auto", 
  impurity = "auto", 
  checkpoint_interval = 10, 
  max_bins = 32, 
  max_depth = 5, 
  num_trees = 20, 
  min_info_gain = 0, 
  min_instances_per_node = 1, 
  subsampling_rate = 1, 
  seed = NULL, 
  thresholds = NULL, 
  cache_node_ids = FALSE, 
  max_memory_in_mb = 256, 
  uid = random_string("random_forest_"), 
  response = NULL, 
  features = NULL, 
  ... 
) 
 
ml_random_forest_regressor( 
  x, 
  formula = NULL, 
  num_trees = 20, 
  subsampling_rate = 1, 
  max_depth = 5, 
  min_instances_per_node = 1, 
  feature_subset_strategy = "auto", 
  impurity = "variance", 
  min_info_gain = 0, 
  max_bins = 32, 
  seed = NULL, 
  checkpoint_interval = 10, 
  cache_node_ids = FALSE, 
  max_memory_in_mb = 256, 
  features_col = "features", 
  label_col = "label", 
  prediction_col = "prediction", 
  uid = random_string("random_forest_regressor_"), 
  ... 
) 

Arguments

Arguments Description
x A spark_connection, ml_pipeline, or a tbl_spark.
formula Used when x is a tbl_spark. R formula as a character string or a formula. This is used to transform the input dataframe before fitting, see ft_r_formula for details.
num_trees Number of trees to train (>= 1). If 1, then no bootstrapping is used. If > 1, then bootstrapping is done.
subsampling_rate Fraction of the training data used for learning each decision tree, in range (0, 1]. (default = 1.0)
max_depth Maximum depth of the tree (>= 0); that is, the maximum number of nodes separating any leaves from the root of the tree.
min_instances_per_node Minimum number of instances each child must have after split.
feature_subset_strategy The number of features to consider for splits at each tree node. See details for options.
impurity Criterion used for information gain calculation. Supported: “entropy” and “gini” (default) for classification and “variance” (default) for regression. For ml_decision_tree, setting "auto" will default to the appropriate criterion based on model type.
min_info_gain Minimum information gain for a split to be considered at a tree node. Should be >= 0, defaults to 0.
max_bins The maximum number of bins used for discretizing continuous features and for choosing how to split on features at each node. More bins give higher granularity.
seed Seed for random numbers.
thresholds Thresholds in multi-class classification to adjust the probability of predicting each class. Array must have length equal to the number of classes, with values > 0 excepting that at most one value may be 0. The class with largest value p/t is predicted, where p is the original probability of that class and t is the class’s threshold.
checkpoint_interval Set checkpoint interval (>= 1) or disable checkpoint (-1). E.g. 10 means that the cache will get checkpointed every 10 iterations, defaults to 10.
cache_node_ids If FALSE, the algorithm will pass trees to executors to match instances with nodes. If TRUE, the algorithm will cache node IDs for each instance. Caching can speed up training of deeper trees. Defaults to FALSE.
max_memory_in_mb Maximum memory in MB allocated to histogram aggregation. If too small, then 1 node will be split per iteration, and its aggregates may exceed this size. Defaults to 256.
features_col Features column name, as a length-one character vector. The column should be single vector column of numeric values. Usually this column is output by ft_r_formula.
label_col Label column name. The column should be a numeric column. Usually this column is output by ft_r_formula.
prediction_col Prediction column name.
probability_col Column name for predicted class conditional probabilities.
raw_prediction_col Raw prediction (a.k.a. confidence) column name.
uid A character string used to uniquely identify the ML estimator.
Optional arguments; see Details.
type The type of model to fit. "regression" treats the response as a continuous variable, while "classification" treats the response as a categorical variable. When "auto" is used, the model type is inferred based on the response variable type – if it is a numeric type, then regression is used; classification otherwise.
response (Deprecated) The name of the response column (as a length-one character vector.)
features (Deprecated) The name of features (terms) to use for the model fit.

Details

When x is a tbl_spark and formula (alternatively, response and features) is specified, the function returns a ml_model object wrapping a ml_pipeline_model which contains data pre-processing transformers, the ML predictor, and, for classification models, a post-processing transformer that converts predictions into class labels. For classification, an optional argument predicted_label_col (defaults to "predicted_label") can be used to specify the name of the predicted label column. In addition to the fitted ml_pipeline_model, ml_model objects also contain a ml_pipeline object where the ML predictor stage is an estimator ready to be fit against data. This is utilized by ml_save with type = "pipeline" to faciliate model refresh workflows. The supported options for feature_subset_strategy are

  • "auto": Choose automatically for task: If num_trees == 1, set to "all". If num_trees > 1 (forest), set to "sqrt" for classification and to "onethird" for regression.

  • "all": use all features

  • "onethird": use 1/3 of the features

  • "sqrt": use use sqrt(number of features)

  • "log2": use log2(number of features)

  • "n": when n is in the range (0, 1.0], use n * number of features. When n is in the range (1, number of features), use n features. (default = "auto")

    ml_random_forest is a wrapper around ml_random_forest_regressor.tbl_spark and ml_random_forest_classifier.tbl_spark and calls the appropriate method based on model type.

Value

The object returned depends on the class of x.

  • spark_connection: When x is a spark_connection, the function returns an instance of a ml_estimator object. The object contains a pointer to a Spark Predictor object and can be used to compose Pipeline objects.

  • ml_pipeline: When x is a ml_pipeline, the function returns a ml_pipeline with the predictor appended to the pipeline.

  • tbl_spark: When x is a tbl_spark, a predictor is constructed then immediately fit with the input tbl_spark, returning a prediction model.

  • tbl_spark, with formula: specified When formula is specified, the input tbl_spark is first transformed using a RFormula transformer before being fit by the predictor. The object returned in this case is a ml_model which is a wrapper of a ml_pipeline_model.

Examples

library(sparklyr)
 
sc <- spark_connect(master = "local") 
iris_tbl <- sdf_copy_to(sc, iris, name = "iris_tbl", overwrite = TRUE) 
 
partitions <- iris_tbl %>% 
  sdf_random_split(training = 0.7, test = 0.3, seed = 1111) 
 
iris_training <- partitions$training 
iris_test <- partitions$test 
 
rf_model <- iris_training %>% 
  ml_random_forest(Species ~ ., type = "classification") 
 
pred <- ml_predict(rf_model, iris_test) 
 
ml_multiclass_classification_evaluator(pred) 
#> [1] 0.9695056

See Also

See https://spark.apache.org/docs/latest/ml-classification-regression.html for more information on the set of supervised learning algorithms. Other ml algorithms: ml_aft_survival_regression(), ml_decision_tree_classifier(), ml_gbt_classifier(), ml_generalized_linear_regression(), ml_isotonic_regression(), ml_linear_regression(), ml_linear_svc(), ml_logistic_regression(), ml_multilayer_perceptron_classifier(), ml_naive_bayes(), ml_one_vs_rest()