I suppose this is possible since in the def of fit function it says:

X : array-like, shape = [n_samples, n_features]

Now I have,

enter image description here

I can certainly generate a string representation of the decision tree then replace X[] with actual feature names. But I wonder if the fit function could directly take feature names as part of inputs? I tried the following format for each sample

  • [1, 2, "feature_1", "feature_2"]

  • [[1, 2], ["feature_1", "feature_2"]]

but neither worked. What does that shape mean? Could you please give me an example?


The fit function itself doesn't support anything like that. However, you can draw the decision tree, including feature labels, with the export_graphviz member function. (Isn't this how you generated the tree above?). Essentially, you'd do something like this:

iris = load_iris()
t = tree.DecisionTreeClassifier()
fitted_tree = t.fit(iris.data, iris.targets)
outfile = tree.export_graphviz(fitted_tree, out_file='filename.dot', feature_names=iris.feature_names)

This will produce a 'dot' file, which graphviz (which must be installed separately) can then "render" into a traditional image format (postscript, png, etc.) For example, to make a png file, you'd run:

dot -Tpng filename.dot > filename.png

The dot file itself is a plain-text format and fairly self-explanatory. If you wanted to tweak the text, a simple find-replace in the text editor of your choice would work. There are also python modules for directly interacting with graphviz and its files. PyDot seems to be pretty popular, but there are others too.

The shape reference in fit's documentation just refers to the layout of X, the training data matrix. Specifically, it expects the first index to vary over training examples, while the 2nd index refers to features. For example, suppose your data's shape is (150, 4), as is the case for iris.data. The fit function will interpret it as containing 150 training examples, each of which consists of four values.


X should be a 2 dimensional numpy ndarray where each row corresponds to a sample and each column represents the values of a feature. That shape refers to the number of rows and columns of the feature data X.

An example of a valid X which contains 3 samples and 2 features:

import numpy as np
X = np.array([[2,2],[2,0],[0,2]])
y = np.array([0,1,1])
print X.shape # Output (2,2)

where the first sample has value 1 and 2 for the first and second feature respectively.

If you have a representation of the feature data in a list of dict (each dict corresponds to a single sample) like so

D = [
 {'feature1': 2, 'feature2': 2},
 {'feature1': 2, 'feature2': 0},
 {'feature1': 0, 'feature2': 2}

then you can use DictVectorizer to produce the matrix X:

from sklearn.feature_extraction import DictVectorizer
v = DictVectorizer(sparse=False)
X = v.fit_transform(D)
  • Thank you. This is really helpful, too. – ShuaiYuan Jan 29 '14 at 14:50

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