I'm trying to understand how feature importance is calculated for decision trees in sci-kit learn. This question has been asked before, but I am unable to reproduce the results the algorithm is providing.

For example:

from StringIO import StringIO

from sklearn.datasets import load_iris
from sklearn.tree import DecisionTreeClassifier
from sklearn.tree.export import export_graphviz
from sklearn.feature_selection import mutual_info_classif

X = [[1,0,0], [0,0,0], [0,0,1], [0,1,0]]

y = [1,0,1,1]

clf = DecisionTreeClassifier()
clf.fit(X, y)

feat_importance = clf.tree_.compute_feature_importances(normalize=False)
print("feat importance = " + str(feat_importance))

out = StringIO()
out = export_graphviz(clf, out_file='test/tree.dot')

results in feature importance:

feat importance = [0.25       0.08333333 0.04166667]

and gives the following decision tree:

decision tree

Now, this answer to a similar question suggests the importance is calculated as


Where G is the node impurity, in this case the gini impurity. This is the impurity reduction as far as I understood it. However, for feature 1 this should be:


This answer suggests the importance is weighted by the probability of reaching the node (which is approximated by the proportion of samples reaching that node). Again, for feature 1 this should be:


Both formulas provide the wrong result. How is the feature importance calculated correctly?

  • 3
    The importance is also normalised if you look at the source code. The normalisation is done in such a way that the sum of the output would be equal to 1. You can also see the other details about computation there.
    – error
    Mar 8, 2018 at 10:39
  • Yes, actually my example code was wrong. The calculated feature importance is computed with clf.tree_.compute_feature_importances(normalize=False). I updated my answer. Mar 12, 2018 at 19:37

2 Answers 2


I think feature importance depends on the implementation so we need to look at the documentation of scikit-learn.

The feature importances. The higher, the more important the feature. The importance of a feature is computed as the (normalized) total reduction of the criterion brought by that feature. It is also known as the Gini importance

That reduction or weighted information gain is defined as :

The weighted impurity decrease equation is the following:

N_t / N * (impurity - N_t_R / N_t * right_impurity - N_t_L / N_t * left_impurity)

where N is the total number of samples, N_t is the number of samples at the current node, N_t_L is the number of samples in the left child, and N_t_R is the number of samples in the right child.


Since each feature is used once in your case, feature information must be equal to equation above.

For X[2] :

feature_importance = (4 / 4) * (0.375 - (0.75 * 0.444)) = 0.042

For X[1] :

feature_importance = (3 / 4) * (0.444 - (2/3 * 0.5)) = 0.083

For X[0] :

feature_importance = (2 / 4) * (0.5) = 0.25

  • Great answer!, just X[2] is X[0], and X[0] is X[2] May 15, 2020 at 23:39
  • where are you quoting the formula from?
    – agent18
    Jan 9, 2021 at 16:12
  • @Pulse9 I think what you said is untrue. X[2]'s feature importance is 0.042
    – agent18
    Jan 9, 2021 at 16:23
  • 1
    @agent18, the formula is located under min_impurity_decrease parameter in the given link. Jan 9, 2021 at 19:34

A single feature can be used in the different branches of the tree, feature importance then is it's total contribution in reducing the impurity.

feature_importance += number_of_samples_at_parent_where_feature_is_used\*impurity_at_parent-left_child_samples\*impurity_left-right_child_samples\*impurity_right

impurity is the gini/entropy value

normalized_importance = feature_importance/number_of_samples_root_node(total num of samples)

In the above eg:

feature_2_importance = 0.375*4-0.444*3-0*1 = 0.16799 , 
normalized = 0.16799/4(total_num_of_samples) = 0.04199

If feature_2 was used in other branches calculate the it's importance at each such parent node & sum up the values.

There is a difference in the feature importance calculated & the ones returned by the library as we are using the truncated values seen in the graph.

Instead, we can access all the required data using the 'tree_' attribute of the classifier which can be used to probe the features used, threshold value, impurity, no of samples at each node etc..

eg: clf.tree_.feature gives the list of features used. A negative value indicates it's a leaf node.

Similarly clf.tree_.children_left/right gives the index to the clf.tree_.feature for left & right children

Using the above traverse the tree & use the same indices in clf.tree_.impurity & clf.tree_.weighted_n_node_samples to get the gini/entropy value and number of samples at the each node & at it's children.

def dt_feature_importance(model,normalize=True):

    left_c = model.tree_.children_left
    right_c = model.tree_.children_right

    impurity = model.tree_.impurity    
    node_samples = model.tree_.weighted_n_node_samples 

    # Initialize the feature importance, those not used remain zero
    feature_importance = np.zeros((model.tree_.n_features,))

    for idx,node in enumerate(model.tree_.feature):
        if node >= 0:
            # Accumulate the feature importance over all the nodes where it's used
            feature_importance[node]+=impurity[idx]*node_samples[idx]- \

    # Number of samples at the root node

    if normalize:
        normalizer = feature_importance.sum()
        if normalizer > 0:

    return feature_importance

This function will return the exact same values as returned by clf.tree_.compute_feature_importances(normalize=...)

To sort the features based on their importance

features = clf.tree_.feature[clf.tree_.feature>=0] # Feature number should not be negative, indicates a leaf node
sorted(zip(features,dt_feature_importance(clf,False)[features]),key=lambda x:x[1],reverse=True)

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