# frozen_string_literal: true require 'rumale/validation' require 'rumale/base/estimator' require 'rumale/base/regressor' require 'rumale/tree/decision_tree_regressor' require 'rumale/ensemble/value' module Rumale module Ensemble # RandomForestRegressor is a class that implements random forest for regression # # @example # require 'rumale/ensemble/random_forest_regressor' # # 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) # class RandomForestRegressor < ::Rumale::Base::Estimator include ::Rumale::Base::Regressor # Return the set of estimators. # @return [Array] attr_reader :estimators # Return the importance for each feature. # @return [Numo::DFloat] (size: n_features) attr_reader :feature_importances # Return the random generator for random selection of feature index. # @return [Random] attr_reader :rng # Create a new regressor with random forest. # # @param n_estimators [Integer] The numeber of decision trees for contructing random forest. # @param criterion [String] The function to evalue spliting point. Supported criteria are 'gini' and 'entropy'. # @param max_depth [Integer] The maximum depth of the tree. # If nil is given, decision tree grows without concern for depth. # @param max_leaf_nodes [Integer] The maximum number of leaves on decision tree. # If nil is given, number of leaves is not limited. # @param min_samples_leaf [Integer] The minimum number of samples at a leaf node. # @param max_features [Integer] The number of features to consider when searching optimal split point. # If nil is given, split process considers 'Math.sqrt(n_features)' features. # @param n_jobs [Integer] 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. # @param random_seed [Integer] The seed value using to initialize the random generator. # It is used to randomly determine the order of features when deciding spliting point. 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) super() @params = { n_estimators: n_estimators, criterion: criterion, max_depth: max_depth, max_leaf_nodes: max_leaf_nodes, min_samples_leaf: min_samples_leaf, max_features: max_features, n_jobs: n_jobs, random_seed: random_seed || srand } @rng = Random.new(@params[:random_seed]) end # Fit the model with given training data. # # @param x [Numo::DFloat] (shape: [n_samples, n_features]) The training data to be used for fitting the model. # @param y [Numo::DFloat] (shape: [n_samples, n_outputs]) The target values to be used for fitting the model. # @return [RandomForestRegressor] The learned regressor itself. def fit(x, y) x = ::Rumale::Validation.check_convert_sample_array(x) y = ::Rumale::Validation.check_convert_target_value_array(y) ::Rumale::Validation.check_sample_size(x, y) # Initialize some variables. n_samples, n_features = x.shape @params[:max_features] = Math.sqrt(n_features).to_i if @params[:max_features].nil? @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::Ensemble::Value::SEED_BASE)) } # Construct forest. @estimators = if enable_parallel? parallel_map(@params[:n_estimators]) do |n| bootstrap_ids = Array.new(n_samples) { rngs[n].rand(0...n_samples) } plant_tree(rngs[n].seed).fit(x[bootstrap_ids, true], single_target ? y[bootstrap_ids] : y[bootstrap_ids, true]) end else Array.new(@params[:n_estimators]) do |n| bootstrap_ids = Array.new(n_samples) { rngs[n].rand(0...n_samples) } plant_tree(rngs[n].seed).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 }.sum else @estimators.sum(&:feature_importances) end @feature_importances /= @feature_importances.sum self end # Predict values for samples. # # @param x [Numo::DFloat] (shape: [n_samples, n_features]) The samples to predict the values. # @return [Numo::DFloat] (shape: [n_samples, n_outputs]) Predicted value per sample. def predict(x) x = ::Rumale::Validation.check_convert_sample_array(x) if enable_parallel? parallel_map(@params[:n_estimators]) { |n| @estimators[n].predict(x) }.sum / @params[:n_estimators] else @estimators.sum { |tree| tree.predict(x) } / @params[:n_estimators] end end # Return the index of the leaf that each sample reached. # # @param x [Numo::DFloat] (shape: [n_samples, n_features]) The samples to assign each leaf. # @return [Numo::Int32] (shape: [n_samples, n_estimators]) Leaf index for sample. def apply(x) x = ::Rumale::Validation.check_convert_sample_array(x) Numo::Int32[*Array.new(@params[:n_estimators]) { |n| @estimators[n].apply(x) }].transpose.dup end private def plant_tree(rnd_seed) ::Rumale::Tree::DecisionTreeRegressor.new( criterion: @params[:criterion], max_depth: @params[:max_depth], max_leaf_nodes: @params[:max_leaf_nodes], min_samples_leaf: @params[:min_samples_leaf], max_features: @params[:max_features], random_seed: rnd_seed ) end end end end