Class: Rumale::Ensemble::RandomForestRegressor

Inherits:

Object

• Object
• Rumale::Ensemble::RandomForestRegressor

Includes:

Base::BaseEstimator, Base::Regressor

Defined in:

lib/rumale/ensemble/random_forest_regressor.rb

Overview

RandomForestRegressor is a class that implements random forest for regression

Examples:

estimator =
  Rumale::Ensemble::RandomForestRegressor.new(
    n_estimators: 10, criterion: 'mse', max_depth: 3, max_leaf_nodes: 10, min_samples_leaf: 5, random_seed: 1)
estimator.fit(training_samples, traininig_values)
results = estimator.predict(testing_samples)

Direct Known Subclasses

ExtraTreesRegressor

Instance Attribute Summary

• #estimators ⇒ Array<DecisionTreeRegressor> readonly

  Return the set of estimators.

• #feature_importances ⇒ Numo::DFloat readonly

  Return the importance for each feature.

• #rng ⇒ Random readonly

  Return the random generator for random selection of feature index.

Attributes included from Base::BaseEstimator

#params

Instance Method Summary

• #apply(x) ⇒ Numo::Int32

  Return the index of the leaf that each sample reached.

• #fit(x, y) ⇒ RandomForestRegressor

  Fit the model with given training data.

• #initialize(n_estimators: 10, criterion: 'mse', max_depth: nil, max_leaf_nodes: nil, min_samples_leaf: 1, max_features: nil, n_jobs: nil, random_seed: nil) ⇒ RandomForestRegressor constructor

  Create a new regressor with random forest.

• #marshal_dump ⇒ Hash

  Dump marshal data.

• #marshal_load(obj) ⇒ nil

  Load marshal data.

• #predict(x) ⇒ Numo::DFloat

  Predict values for samples.

Methods included from Base::Regressor

#score

Constructor Details

#initialize(n_estimators: 10, criterion: 'mse', max_depth: nil, max_leaf_nodes: nil, min_samples_leaf: 1, max_features: nil, n_jobs: nil, random_seed: nil) ⇒ RandomForestRegressor

Create a new regressor with random forest.

Parameters:

• n_estimators (Integer) (defaults to: 10) —

  The numeber of decision trees for contructing random forest.

• criterion (String) (defaults to: 'mse') —

  The function to evalue spliting point. Supported criteria are ‘gini’ and ‘entropy’.

• max_depth (Integer) (defaults to: nil) —

  The maximum depth of the tree. If nil is given, decision tree grows without concern for depth.

• max_leaf_nodes (Integer) (defaults to: nil) —

  The maximum number of leaves on decision tree. If nil is given, number of leaves is not limited.

• min_samples_leaf (Integer) (defaults to: 1) —

  The minimum number of samples at a leaf node.

• max_features (Integer) (defaults to: nil) —

  The number of features to consider when searching optimal split point. If nil is given, split process considers all features.

• n_jobs (Integer) (defaults to: nil) —

  The number of jobs for running the fit and predict methods in parallel. If nil is given, the methods do not execute in parallel. If zero or less is given, it becomes equal to the number of processors. This parameter is ignored if the Parallel gem is not loaded.

• random_seed (Integer) (defaults to: nil) —

  The seed value using to initialize the random generator. It is used to randomly determine the order of features when deciding spliting point.

# File 'lib/rumale/ensemble/random_forest_regressor.rb', line 52

def initialize(n_estimators: 10,
               criterion: 'mse', max_depth: nil, max_leaf_nodes: nil, min_samples_leaf: 1,
               max_features: nil, n_jobs: nil, random_seed: nil)
  check_params_type_or_nil(Integer, max_depth: max_depth, max_leaf_nodes: max_leaf_nodes,
                                    max_features: max_features, n_jobs: n_jobs, random_seed: random_seed)
  check_params_integer(n_estimators: n_estimators, min_samples_leaf: min_samples_leaf)
  check_params_string(criterion: criterion)
  check_params_positive(n_estimators: n_estimators, max_depth: max_depth,
                        max_leaf_nodes: max_leaf_nodes, min_samples_leaf: min_samples_leaf,
                        max_features: max_features)
  @params = {}
  @params[:n_estimators] = n_estimators
  @params[:criterion] = criterion
  @params[:max_depth] = max_depth
  @params[:max_leaf_nodes] = max_leaf_nodes
  @params[:min_samples_leaf] = min_samples_leaf
  @params[:max_features] = max_features
  @params[:n_jobs] = n_jobs
  @params[:random_seed] = random_seed
  @params[:random_seed] ||= srand
  @estimators = nil
  @feature_importances = nil
  @rng = Random.new(@params[:random_seed])
end

Instance Attribute Details

#estimators ⇒ Array<DecisionTreeRegressor> (readonly)

Return the set of estimators.

Returns:

• (Array<DecisionTreeRegressor>)

# File 'lib/rumale/ensemble/random_forest_regressor.rb', line 25

def estimators
  @estimators
end

#feature_importances ⇒ Numo::DFloat (readonly)

Return the importance for each feature.

Returns:

• (Numo::DFloat) —

  (size: n_features)

# File 'lib/rumale/ensemble/random_forest_regressor.rb', line 29

def feature_importances
  @feature_importances
end

#rng ⇒ Random (readonly)

Return the random generator for random selection of feature index.

Returns:

• (Random)

# File 'lib/rumale/ensemble/random_forest_regressor.rb', line 33

def rng
  @rng
end

Instance Method Details

#apply(x) ⇒ Numo::Int32

Return the index of the leaf that each sample reached.

Parameters:

• x (Numo::DFloat) —

  (shape: [n_samples, n_features]) The samples to assign each leaf.

Returns:

• (Numo::Int32) —

  (shape: [n_samples, n_estimators]) Leaf index for sample.

# File 'lib/rumale/ensemble/random_forest_regressor.rb', line 137

def apply(x)
  check_sample_array(x)
  Numo::Int32[*Array.new(@params[:n_estimators]) { |n| @estimators[n].apply(x) }].transpose
end

#fit(x, y) ⇒ RandomForestRegressor

Fit the model with given training data.

Parameters:

• x (Numo::DFloat) —

  (shape: [n_samples, n_features]) The training data to be used for fitting the model.

• y (Numo::DFloat) —

  (shape: [n_samples, n_outputs]) The target values to be used for fitting the model.

Returns:

• (RandomForestRegressor) —

  The learned regressor itself.

# File 'lib/rumale/ensemble/random_forest_regressor.rb', line 82

def fit(x, y)
  check_sample_array(x)
  check_tvalue_array(y)
  check_sample_tvalue_size(x, y)
  # Initialize some variables.
  n_samples, n_features = x.shape
  @params[:max_features] = Math.sqrt(n_features).to_i unless @params[:max_features].is_a?(Integer)
  @params[:max_features] = [[1, @params[:max_features]].max, n_features].min
  single_target = y.shape[1].nil?
  sub_rng = @rng.dup
  rngs = Array.new(@params[:n_estimators]) { Random.new(sub_rng.rand(Rumale::Values.int_max)) }
  # Construct forest.
  @estimators =
    if enable_parallel?
      # :nocov:
      parallel_map(@params[:n_estimators]) do |n|
        bootstrap_ids = Array.new(n_samples) { rngs[n].rand(0...n_samples) }
        tree = plant_tree(rngs[n].rand(Rumale::Values.int_max))
        tree.fit(x[bootstrap_ids, true], single_target ? y[bootstrap_ids] : y[bootstrap_ids, true])
      end
      # :nocov:
    else
      Array.new(@params[:n_estimators]) do |n|
        bootstrap_ids = Array.new(n_samples) { rngs[n].rand(0...n_samples) }
        tree = plant_tree(rngs[n].rand(Rumale::Values.int_max))
        tree.fit(x[bootstrap_ids, true], single_target ? y[bootstrap_ids] : y[bootstrap_ids, true])
      end
    end
  @feature_importances =
    if enable_parallel?
      parallel_map(@params[:n_estimators]) { |n| @estimators[n].feature_importances }.reduce(&:+)
    else
      @estimators.map(&:feature_importances).reduce(&:+)
    end
  @feature_importances /= @feature_importances.sum
  self
end

#marshal_dump ⇒ Hash

Dump marshal data.

Returns:

• (Hash) —

  The marshal data about RandomForestRegressor.

# File 'lib/rumale/ensemble/random_forest_regressor.rb', line 144

def marshal_dump
  { params: @params,
    estimators: @estimators,
    feature_importances: @feature_importances,
    rng: @rng }
end

#marshal_load(obj) ⇒ nil

Load marshal data.

Returns:

• (nil)

# File 'lib/rumale/ensemble/random_forest_regressor.rb', line 153

def marshal_load(obj)
  @params = obj[:params]
  @estimators = obj[:estimators]
  @feature_importances = obj[:feature_importances]
  @rng = obj[:rng]
  nil
end

#predict(x) ⇒ Numo::DFloat

Predict values for samples.

Parameters:

• x (Numo::DFloat) —

  (shape: [n_samples, n_features]) The samples to predict the values.

Returns:

• (Numo::DFloat) —

  (shape: [n_samples, n_outputs]) Predicted value per sample.

# File 'lib/rumale/ensemble/random_forest_regressor.rb', line 124

def predict(x)
  check_sample_array(x)
  if enable_parallel?
    parallel_map(@params[:n_estimators]) { |n| @estimators[n].predict(x) }.reduce(&:+) / @params[:n_estimators]
  else
    @estimators.map { |tree| tree.predict(x) }.reduce(&:+) / @params[:n_estimators]
  end
end