.. _preprocessing:

==================
Preprocessing data
==================

.. currentmodule:: sklearn.preprocessing

The ``sklearn.preprocessing`` package provides several common
utility functions and transformer classes to change raw feature vectors
into a representation that is more suitable for the downstream estimators.

In general, learning algorithms benefit from standardization of the data set. If
some outliers are present in the set, robust scalers or transformers are more
appropriate. The behaviors of the different scalers, transformers, and
normalizers on a dataset containing marginal outliers is highlighted in
:ref:`sphx_glr_auto_examples_preprocessing_plot_all_scaling.py`.


.. _preprocessing_scaler:

Standardization, or mean removal and variance scaling
=====================================================

**Standardization** of datasets is a **common requirement for many
machine learning estimators** implemented in scikit-learn; they might behave
badly if the individual features do not more or less look like standard
normally distributed data: Gaussian with **zero mean and unit variance**.

In practice we often ignore the shape of the distribution and just
transform the data to center it by removing the mean value of each
feature, then scale it by dividing non-constant features by their
standard deviation.

For instance, many elements used in the objective function of
a learning algorithm (such as the RBF kernel of Support Vector
Machines or the l1 and l2 regularizers of linear models) assume that
all features are centered around zero and have variance in the same
order. If a feature has a variance that is orders of magnitude larger
than others, it might dominate the objective function and make the
estimator unable to learn from other features correctly as expected.


The function :func:`scale` provides a quick and easy way to perform this
operation on a single array-like dataset::

  >>> from sklearn import preprocessing
  >>> import numpy as np
  >>> X_train = np.array([[ 1., -1.,  2.],
  ...                     [ 2.,  0.,  0.],
  ...                     [ 0.,  1., -1.]])
  >>> X_scaled = preprocessing.scale(X_train)

  >>> X_scaled                                          # doctest: +ELLIPSIS
  array([[ 0.  ..., -1.22...,  1.33...],
         [ 1.22...,  0.  ..., -0.26...],
         [-1.22...,  1.22..., -1.06...]])

..
        >>> import numpy as np
        >>> print_options = np.get_printoptions()
        >>> np.set_printoptions(suppress=True)

Scaled data has zero mean and unit variance::

  >>> X_scaled.mean(axis=0)
  array([0., 0., 0.])

  >>> X_scaled.std(axis=0)
  array([1., 1., 1.])

..    >>> print_options = np.set_printoptions(print_options)

The ``preprocessing`` module further provides a utility class
:class:`StandardScaler` that implements the ``Transformer`` API to compute
the mean and standard deviation on a training set so as to be
able to later reapply the same transformation on the testing set.
This class is hence suitable for use in the early steps of a
:class:`sklearn.pipeline.Pipeline`::

  >>> scaler = preprocessing.StandardScaler().fit(X_train)
  >>> scaler
  StandardScaler(copy=True, with_mean=True, with_std=True)

  >>> scaler.mean_                                      # doctest: +ELLIPSIS
  array([1. ..., 0. ..., 0.33...])

  >>> scaler.scale_                                       # doctest: +ELLIPSIS
  array([0.81..., 0.81..., 1.24...])

  >>> scaler.transform(X_train)                           # doctest: +ELLIPSIS
  array([[ 0.  ..., -1.22...,  1.33...],
         [ 1.22...,  0.  ..., -0.26...],
         [-1.22...,  1.22..., -1.06...]])


The scaler instance can then be used on new data to transform it the
same way it did on the training set::

  >>> X_test = [[-1., 1., 0.]]
  >>> scaler.transform(X_test)                # doctest: +ELLIPSIS
  array([[-2.44...,  1.22..., -0.26...]])

It is possible to disable either centering or scaling by either
passing ``with_mean=False`` or ``with_std=False`` to the constructor
of :class:`StandardScaler`.


Scaling features to a range
---------------------------

An alternative standardization is scaling features to
lie between a given minimum and maximum value, often between zero and one,
or so that the maximum absolute value of each feature is scaled to unit size.
This can be achieved using :class:`MinMaxScaler` or :class:`MaxAbsScaler`,
respectively.

The motivation to use this scaling include robustness to very small
standard deviations of features and preserving zero entries in sparse data.

Here is an example to scale a toy data matrix to the ``[0, 1]`` range::

  >>> X_train = np.array([[ 1., -1.,  2.],
  ...                     [ 2.,  0.,  0.],
  ...                     [ 0.,  1., -1.]])
  ...
  >>> min_max_scaler = preprocessing.MinMaxScaler()
  >>> X_train_minmax = min_max_scaler.fit_transform(X_train)
  >>> X_train_minmax
  array([[0.5       , 0.        , 1.        ],
         [1.        , 0.5       , 0.33333333],
         [0.        , 1.        , 0.        ]])

The same instance of the transformer can then be applied to some new test data
unseen during the fit call: the same scaling and shifting operations will be
applied to be consistent with the transformation performed on the train data::

  >>> X_test = np.array([[-3., -1.,  4.]])
  >>> X_test_minmax = min_max_scaler.transform(X_test)
  >>> X_test_minmax
  array([[-1.5       ,  0.        ,  1.66666667]])

It is possible to introspect the scaler attributes to find about the exact
nature of the transformation learned on the training data::

  >>> min_max_scaler.scale_                             # doctest: +ELLIPSIS
  array([0.5       , 0.5       , 0.33...])

  >>> min_max_scaler.min_                               # doctest: +ELLIPSIS
  array([0.        , 0.5       , 0.33...])

If :class:`MinMaxScaler` is given an explicit ``feature_range=(min, max)`` the
full formula is::

    X_std = (X - X.min(axis=0)) / (X.max(axis=0) - X.min(axis=0))

    X_scaled = X_std * (max - min) + min

:class:`MaxAbsScaler` works in a very similar fashion, but scales in a way
that the training data lies within the range ``[-1, 1]`` by dividing through
the largest maximum value in each feature. It is meant for data
that is already centered at zero or sparse data.

Here is how to use the toy data from the previous example with this scaler::

  >>> X_train = np.array([[ 1., -1.,  2.],
  ...                     [ 2.,  0.,  0.],
  ...                     [ 0.,  1., -1.]])
  ...
  >>> max_abs_scaler = preprocessing.MaxAbsScaler()
  >>> X_train_maxabs = max_abs_scaler.fit_transform(X_train)
  >>> X_train_maxabs                # doctest +NORMALIZE_WHITESPACE^
  array([[ 0.5, -1. ,  1. ],
         [ 1. ,  0. ,  0. ],
         [ 0. ,  1. , -0.5]])
  >>> X_test = np.array([[ -3., -1.,  4.]])
  >>> X_test_maxabs = max_abs_scaler.transform(X_test)
  >>> X_test_maxabs                 # doctest: +NORMALIZE_WHITESPACE
  array([[-1.5, -1. ,  2. ]])
  >>> max_abs_scaler.scale_         # doctest: +ELLIPSIS +NORMALIZE_WHITESPACE
  array([2.,  1.,  2.])


As with :func:`scale`, the module further provides convenience functions
:func:`minmax_scale` and :func:`maxabs_scale` if you don't want to create
an object.


Scaling sparse data
-------------------
Centering sparse data would destroy the sparseness structure in the data, and
thus rarely is a sensible thing to do. However, it can make sense to scale
sparse inputs, especially if features are on different scales.

:class:`MaxAbsScaler`  and :func:`maxabs_scale` were specifically designed
for scaling sparse data, and are the recommended way to go about this.
However, :func:`scale` and :class:`StandardScaler` can accept ``scipy.sparse``
matrices  as input, as long as ``with_mean=False`` is explicitly passed
to the constructor. Otherwise a ``ValueError`` will be raised as
silently centering would break the sparsity and would often crash the
execution by allocating excessive amounts of memory unintentionally.
:class:`RobustScaler` cannot be fitted to sparse inputs, but you can use
the ``transform`` method on sparse inputs.

Note that the scalers accept both Compressed Sparse Rows and Compressed
Sparse Columns format (see ``scipy.sparse.csr_matrix`` and
``scipy.sparse.csc_matrix``). Any other sparse input will be **converted to
the Compressed Sparse Rows representation**.  To avoid unnecessary memory
copies, it is recommended to choose the CSR or CSC representation upstream.

Finally, if the centered data is expected to be small enough, explicitly
converting the input to an array using the ``toarray`` method of sparse matrices
is another option.


Scaling data with outliers
--------------------------

If your data contains many outliers, scaling using the mean and variance
of the data is likely to not work very well. In these cases, you can use
:func:`robust_scale` and :class:`RobustScaler` as drop-in replacements
instead. They use more robust estimates for the center and range of your
data.


.. topic:: References:

  Further discussion on the importance of centering and scaling data is
  available on this FAQ: `Should I normalize/standardize/rescale the data?
  <http://www.faqs.org/faqs/ai-faq/neural-nets/part2/section-16.html>`_

.. topic:: Scaling vs Whitening

  It is sometimes not enough to center and scale the features
  independently, since a downstream model can further make some assumption
  on the linear independence of the features.

  To address this issue you can use :class:`sklearn.decomposition.PCA` with
  ``whiten=True`` to further remove the linear correlation across features.

.. topic:: Scaling a 1D array

   All above functions (i.e. :func:`scale`, :func:`minmax_scale`,
   :func:`maxabs_scale`, and :func:`robust_scale`) accept 1D array which can be
   useful in some specific case.

.. _kernel_centering:

Centering kernel matrices
-------------------------

If you have a kernel matrix of a kernel :math:`K` that computes a dot product
in a feature space defined by function :math:`phi`,
a :class:`KernelCenterer` can transform the kernel matrix
so that it contains inner products in the feature space
defined by :math:`phi` followed by removal of the mean in that space.

.. _preprocessing_transformer:

Non-linear transformation
=========================

Mapping to a Uniform distribution
---------------------------------

Like scalers, :class:`QuantileTransformer` puts all features into the same,
known range or distribution. However, by performing a rank transformation, it
smooths out unusual distributions and is less influenced by outliers than
scaling methods. It does, however, distort correlations and distances within
and across features.

:class:`QuantileTransformer` and :func:`quantile_transform` provide a
non-parametric transformation based on the quantile function to map the data to
a uniform distribution with values between 0 and 1::

  >>> from sklearn.datasets import load_iris
  >>> from sklearn.model_selection import train_test_split
  >>> iris = load_iris()
  >>> X, y = iris.data, iris.target
  >>> X_train, X_test, y_train, y_test = train_test_split(X, y, random_state=0)
  >>> quantile_transformer = preprocessing.QuantileTransformer(random_state=0)
  >>> X_train_trans = quantile_transformer.fit_transform(X_train)
  >>> X_test_trans = quantile_transformer.transform(X_test)
  >>> np.percentile(X_train[:, 0], [0, 25, 50, 75, 100]) # doctest: +SKIP
  array([ 4.3,  5.1,  5.8,  6.5,  7.9])

This feature corresponds to the sepal length in cm. Once the quantile
transformation applied, those landmarks approach closely the percentiles
previously defined::

  >>> np.percentile(X_train_trans[:, 0], [0, 25, 50, 75, 100])
  ... # doctest: +ELLIPSIS +SKIP
  array([ 0.00... ,  0.24...,  0.49...,  0.73...,  0.99... ])

This can be confirmed on a independent testing set with similar remarks::

  >>> np.percentile(X_test[:, 0], [0, 25, 50, 75, 100])
  ... # doctest: +SKIP
  array([ 4.4  ,  5.125,  5.75 ,  6.175,  7.3  ])
  >>> np.percentile(X_test_trans[:, 0], [0, 25, 50, 75, 100])
  ... # doctest: +ELLIPSIS +SKIP
  array([ 0.01...,  0.25...,  0.46...,  0.60... ,  0.94...])

Mapping to a Gaussian distribution
----------------------------------

In many modeling scenarios, normality of the features in a dataset is desirable.
Power transforms are a family of parametric, monotonic transformations that aim
to map data from any distribution to as close to a Gaussian distribution as
possible in order to stabilize variance and minimize skewness.

:class:`PowerTransformer` currently provides one such power transformation,
the Box-Cox transform. The Box-Cox transform is given by:

.. math::
    y_i^{(\lambda)} =
    \begin{cases}
    \dfrac{y_i^\lambda - 1}{\lambda} & \text{if } \lambda \neq 0, \\[8pt]
    \ln{(y_i)} & \text{if } \lambda = 0,
    \end{cases}

Box-Cox can only be applied to strictly positive data. The transformation is
parameterized by :math:`\lambda`, which is determined through maximum likelihood
estimation. Here is an example of using Box-Cox to map samples drawn from a
lognormal distribution to a normal distribution::

  >>> pt = preprocessing.PowerTransformer(method='box-cox', standardize=False)
  >>> X_lognormal = np.random.RandomState(616).lognormal(size=(3, 3))
  >>> X_lognormal                                         # doctest: +ELLIPSIS
  array([[1.28..., 1.18..., 0.84...],
         [0.94..., 1.60..., 0.38...],
         [1.35..., 0.21..., 1.09...]])
  >>> pt.fit_transform(X_lognormal)                   # doctest: +ELLIPSIS
  array([[ 0.49...,  0.17..., -0.15...],
         [-0.05...,  0.58..., -0.57...],
         [ 0.69..., -0.84...,  0.10...]])

While the above example sets the `standardize` option to `False`,
:class:`PowerTransformer` will apply zero-mean, unit-variance normalization
to the transformed output by default.

Below are examples of Box-Cox applied to various probability distributions.
Note that when applied to certain distributions, Box-Cox achieves very
Gaussian-like results, but with others, it is ineffective. This highlights
the importance of visualizing the data before and after transformation.

.. figure:: ../auto_examples/preprocessing/images/sphx_glr_plot_power_transformer_001.png
   :target: ../auto_examples/preprocessing/plot_power_transformer.html
   :align: center
   :scale: 100

It is also possible to map data to a normal distribution using
:class:`QuantileTransformer` by setting ``output_distribution='normal'``.
Using the earlier example with the iris dataset::

  >>> quantile_transformer = preprocessing.QuantileTransformer(
  ...     output_distribution='normal', random_state=0)
  >>> X_trans = quantile_transformer.fit_transform(X)
  >>> quantile_transformer.quantiles_ # doctest: +ELLIPSIS +NORMALIZE_WHITESPACE
  array([[4.3...,   2...,     1...,     0.1...],
         [4.31...,  2.02...,  1.01...,  0.1...],
         [4.32...,  2.05...,  1.02...,  0.1...],
         ...,
         [7.84...,  4.34...,  6.84...,  2.5...],
         [7.87...,  4.37...,  6.87...,  2.5...],
         [7.9...,   4.4...,   6.9...,   2.5...]])

Thus the median of the input becomes the mean of the output, centered at 0. The
normal output is clipped so that the input's minimum and maximum ---
corresponding to the 1e-7 and 1 - 1e-7 quantiles respectively --- do not
become infinite under the transformation.

.. _preprocessing_normalization:

Normalization
=============

**Normalization** is the process of **scaling individual samples to have
unit norm**. This process can be useful if you plan to use a quadratic form
such as the dot-product or any other kernel to quantify the similarity
of any pair of samples.

This assumption is the base of the `Vector Space Model
<https://en.wikipedia.org/wiki/Vector_Space_Model>`_ often used in text
classification and clustering contexts.

The function :func:`normalize` provides a quick and easy way to perform this
operation on a single array-like dataset, either using the ``l1`` or ``l2``
norms::

  >>> X = [[ 1., -1.,  2.],
  ...      [ 2.,  0.,  0.],
  ...      [ 0.,  1., -1.]]
  >>> X_normalized = preprocessing.normalize(X, norm='l2')

  >>> X_normalized                                      # doctest: +ELLIPSIS
  array([[ 0.40..., -0.40...,  0.81...],
         [ 1.  ...,  0.  ...,  0.  ...],
         [ 0.  ...,  0.70..., -0.70...]])

The ``preprocessing`` module further provides a utility class
:class:`Normalizer` that implements the same operation using the
``Transformer`` API (even though the ``fit`` method is useless in this case:
the class is stateless as this operation treats samples independently).

This class is hence suitable for use in the early steps of a
:class:`sklearn.pipeline.Pipeline`::

  >>> normalizer = preprocessing.Normalizer().fit(X)  # fit does nothing
  >>> normalizer
  Normalizer(copy=True, norm='l2')


The normalizer instance can then be used on sample vectors as any transformer::

  >>> normalizer.transform(X)                            # doctest: +ELLIPSIS
  array([[ 0.40..., -0.40...,  0.81...],
         [ 1.  ...,  0.  ...,  0.  ...],
         [ 0.  ...,  0.70..., -0.70...]])

  >>> normalizer.transform([[-1.,  1., 0.]])             # doctest: +ELLIPSIS
  array([[-0.70...,  0.70...,  0.  ...]])


.. topic:: Sparse input

  :func:`normalize` and :class:`Normalizer` accept **both dense array-like
  and sparse matrices from scipy.sparse as input**.

  For sparse input the data is **converted to the Compressed Sparse Rows
  representation** (see ``scipy.sparse.csr_matrix``) before being fed to
  efficient Cython routines. To avoid unnecessary memory copies, it is
  recommended to choose the CSR representation upstream.

.. _preprocessing_categorical_features:

Encoding categorical features
=============================
Often features are not given as continuous values but categorical.
For example a person could have features ``["male", "female"]``,
``["from Europe", "from US", "from Asia"]``,
``["uses Firefox", "uses Chrome", "uses Safari", "uses Internet Explorer"]``.
Such features can be efficiently coded as integers, for instance
``["male", "from US", "uses Internet Explorer"]`` could be expressed as
``[0, 1, 3]`` while ``["female", "from Asia", "uses Chrome"]`` would be
``[1, 2, 1]``.

To convert categorical features to such integer codes, we can use the
:class:`OrdinalEncoder`. This estimator transforms each categorical feature to one
new feature of integers (0 to n_categories - 1)::

    >>> enc = preprocessing.OrdinalEncoder()
    >>> X = [['male', 'from US', 'uses Safari'], ['female', 'from Europe', 'uses Firefox']]
    >>> enc.fit(X)  # doctest: +ELLIPSIS
    OrdinalEncoder(categories='auto', dtype=<... 'numpy.float64'>)
    >>> enc.transform([['female', 'from US', 'uses Safari']])
    array([[0., 1., 1.]])

Such integer representation can, however, not be used directly with all
scikit-learn estimators, as these expect continuous input, and would interpret
the categories as being ordered, which is often not desired (i.e. the set of
browsers was ordered arbitrarily).

Another possibility to convert categorical features to features that can be used
with scikit-learn estimators is to use a one-of-K, also known as one-hot or
dummy encoding.
This type of encoding can be obtained with the :class:`OneHotEncoder`,
which transforms each categorical feature with
``n_categories`` possible values into ``n_categories`` binary features, with
one of them 1, and all others 0.

Continuing the example above::

  >>> enc = preprocessing.OneHotEncoder()
  >>> X = [['male', 'from US', 'uses Safari'], ['female', 'from Europe', 'uses Firefox']]
  >>> enc.fit(X)  # doctest: +ELLIPSIS
  OneHotEncoder(categorical_features=None, categories=None,
         dtype=<... 'numpy.float64'>, handle_unknown='error',
         n_values=None, sparse=True)
  >>> enc.transform([['female', 'from US', 'uses Safari'],
  ...                ['male', 'from Europe', 'uses Safari']]).toarray()
  array([[1., 0., 0., 1., 0., 1.],
         [0., 1., 1., 0., 0., 1.]])

By default, the values each feature can take is inferred automatically
from the dataset and can be found in the ``categories_`` attribute::

    >>> enc.categories_
    [array(['female', 'male'], dtype=object), array(['from Europe', 'from US'], dtype=object), array(['uses Firefox', 'uses Safari'], dtype=object)]

It is possible to specify this explicitly using the parameter ``categories``.
There are two genders, four possible continents and four web browsers in our
dataset::

    >>> genders = ['female', 'male']
    >>> locations = ['from Africa', 'from Asia', 'from Europe', 'from US']
    >>> browsers = ['uses Chrome', 'uses Firefox', 'uses IE', 'uses Safari']
    >>> enc = preprocessing.OneHotEncoder(categories=[genders, locations, browsers])
    >>> # Note that for there are missing categorical values for the 2nd and 3rd
    >>> # feature
    >>> X = [['male', 'from US', 'uses Safari'], ['female', 'from Europe', 'uses Firefox']]
    >>> enc.fit(X) # doctest: +ELLIPSIS
    OneHotEncoder(categorical_features=None,
           categories=[...],
           dtype=<... 'numpy.float64'>, handle_unknown='error',
           n_values=None, sparse=True)
    >>> enc.transform([['female', 'from Asia', 'uses Chrome']]).toarray()
    array([[1., 0., 0., 1., 0., 0., 1., 0., 0., 0.]])

If there is a possibility that the training data might have missing categorical
features, it can often be better to specify ``handle_unknown='ignore'`` instead
of setting the ``categories`` manually as above. When
``handle_unknown='ignore'`` is specified and unknown categories are encountered
during transform, no error will be raised but the resulting one-hot encoded
columns for this feature will be all zeros
(``handle_unknown='ignore'`` is only supported for one-hot encoding)::

    >>> enc = preprocessing.OneHotEncoder(handle_unknown='ignore')
    >>> X = [['male', 'from US', 'uses Safari'], ['female', 'from Europe', 'uses Firefox']]
    >>> enc.fit(X) # doctest: +ELLIPSIS
    OneHotEncoder(categorical_features=None, categories=None,
           dtype=<... 'numpy.float64'>, handle_unknown='ignore',
           n_values=None, sparse=True)
    >>> enc.transform([['female', 'from Asia', 'uses Chrome']]).toarray()
    array([[1., 0., 0., 0., 0., 0.]])


See :ref:`dict_feature_extraction` for categorical features that are represented
as a dict, not as scalars.

.. _preprocessing_discretization:

Discretization
==============

`Discretization <https://en.wikipedia.org/wiki/Discretization_of_continuous_features>`_
(otherwise known as quantization or binning) provides a way to partition continuous
features into discrete values. Certain datasets with continuous features
may benefit from discretization, because discretization can transform the dataset
of continuous attributes to one with only nominal attributes.

K-bins discretization
---------------------

:class:`KBinsDiscretizer` discretizers features into ``k`` equal width bins::

  >>> X = np.array([[ -3., 5., 15 ],
  ...               [  0., 6., 14 ],
  ...               [  6., 3., 11 ]])
  >>> est = preprocessing.KBinsDiscretizer(n_bins=[3, 2, 2], encode='ordinal').fit(X)

By default the output is one-hot encoded into a sparse matrix
(See :ref:`preprocessing_categorical_features`)
and this can be configured with the ``encode`` parameter.
For each feature, the bin edges are computed during ``fit`` and together with
the number of bins, they will define the intervals. Therefore, for the current
example, these intervals are defined as:

 - feature 1: :math:`{[-\infty, -1), [-1, 2), [2, \infty)}`
 - feature 2: :math:`{[-\infty, 5), [5, \infty)}`
 - feature 3: :math:`{[-\infty, 14), [14, \infty)}`

 Based on these bin intervals, ``X`` is transformed as follows::

  >>> est.transform(X)                      # doctest: +SKIP
  array([[ 0., 1., 1.],
         [ 1., 1., 1.],
         [ 2., 0., 0.]])

The resulting dataset contains ordinal attributes which can be further used
in a :class:`sklearn.pipeline.Pipeline`.

Discretization is similar to constructing histograms for continuous data.
However, histograms focus on counting features which fall into particular
bins, whereas discretization focuses on assigning feature values to these bins.

:class:`KBinsDiscretizer` implements different binning strategies, which can be
selected with the ``strategy`` parameter. The 'uniform' strategy uses
constant-width bins. The 'quantile' strategy uses the quantiles values to have
equally populated bins in each feature. The 'kmeans' strategy defines bins based
on a k-means clustering procedure performed on each feature independently.

.. topic:: Examples:

  * :ref:`sphx_glr_auto_examples_preprocessing_plot_discretization.py`
  * :ref:`sphx_glr_auto_examples_preprocessing_plot_discretization_classification.py`
  * :ref:`sphx_glr_auto_examples_preprocessing_plot_discretization_strategies.py`

.. _preprocessing_binarization:

Feature binarization
--------------------

**Feature binarization** is the process of **thresholding numerical
features to get boolean values**. This can be useful for downstream
probabilistic estimators that make assumption that the input data
is distributed according to a multi-variate `Bernoulli distribution
<https://en.wikipedia.org/wiki/Bernoulli_distribution>`_. For instance,
this is the case for the :class:`sklearn.neural_network.BernoulliRBM`.

It is also common among the text processing community to use binary
feature values (probably to simplify the probabilistic reasoning) even
if normalized counts (a.k.a. term frequencies) or TF-IDF valued features
often perform slightly better in practice.

As for the :class:`Normalizer`, the utility class
:class:`Binarizer` is meant to be used in the early stages of
:class:`sklearn.pipeline.Pipeline`. The ``fit`` method does nothing
as each sample is treated independently of others::

  >>> X = [[ 1., -1.,  2.],
  ...      [ 2.,  0.,  0.],
  ...      [ 0.,  1., -1.]]

  >>> binarizer = preprocessing.Binarizer().fit(X)  # fit does nothing
  >>> binarizer
  Binarizer(copy=True, threshold=0.0)

  >>> binarizer.transform(X)
  array([[1., 0., 1.],
         [1., 0., 0.],
         [0., 1., 0.]])

It is possible to adjust the threshold of the binarizer::

  >>> binarizer = preprocessing.Binarizer(threshold=1.1)
  >>> binarizer.transform(X)
  array([[0., 0., 1.],
         [1., 0., 0.],
         [0., 0., 0.]])

As for the :class:`StandardScaler` and :class:`Normalizer` classes, the
preprocessing module provides a companion function :func:`binarize`
to be used when the transformer API is not necessary.

Note that the :class:`Binarizer` is similar to the :class:`KBinsDiscretizer`
when ``k = 2``, and when the bin edge is at the value ``threshold``.

.. topic:: Sparse input

  :func:`binarize` and :class:`Binarizer` accept **both dense array-like
  and sparse matrices from scipy.sparse as input**.

  For sparse input the data is **converted to the Compressed Sparse Rows
  representation** (see ``scipy.sparse.csr_matrix``).
  To avoid unnecessary memory copies, it is recommended to choose the CSR
  representation upstream.

.. _imputation:

Imputation of missing values
============================

Tools for imputing missing values are discussed at :ref:`impute`.

.. _polynomial_features:

Generating polynomial features
==============================

Often it's useful to add complexity to the model by considering nonlinear features of the input data. A simple and common method to use is polynomial features, which can get features' high-order and interaction terms. It is implemented in :class:`PolynomialFeatures`::

    >>> import numpy as np
    >>> from sklearn.preprocessing import PolynomialFeatures
    >>> X = np.arange(6).reshape(3, 2)
    >>> X                                                 # doctest: +ELLIPSIS
    array([[0, 1],
           [2, 3],
           [4, 5]])
    >>> poly = PolynomialFeatures(2)
    >>> poly.fit_transform(X)                             # doctest: +ELLIPSIS
    array([[ 1.,  0.,  1.,  0.,  0.,  1.],
           [ 1.,  2.,  3.,  4.,  6.,  9.],
           [ 1.,  4.,  5., 16., 20., 25.]])

The features of X have been transformed from :math:`(X_1, X_2)` to :math:`(1, X_1, X_2, X_1^2, X_1X_2, X_2^2)`.

In some cases, only interaction terms among features are required, and it can be gotten with the setting ``interaction_only=True``::

    >>> X = np.arange(9).reshape(3, 3)
    >>> X                                                 # doctest: +ELLIPSIS
    array([[0, 1, 2],
           [3, 4, 5],
           [6, 7, 8]])
    >>> poly = PolynomialFeatures(degree=3, interaction_only=True)
    >>> poly.fit_transform(X)                             # doctest: +ELLIPSIS
    array([[  1.,   0.,   1.,   2.,   0.,   0.,   2.,   0.],
           [  1.,   3.,   4.,   5.,  12.,  15.,  20.,  60.],
           [  1.,   6.,   7.,   8.,  42.,  48.,  56., 336.]])

The features of X have been transformed from :math:`(X_1, X_2, X_3)` to :math:`(1, X_1, X_2, X_3, X_1X_2, X_1X_3, X_2X_3, X_1X_2X_3)`.

Note that polynomial features are used implicitly in `kernel methods <https://en.wikipedia.org/wiki/Kernel_method>`_ (e.g., :class:`sklearn.svm.SVC`, :class:`sklearn.decomposition.KernelPCA`) when using polynomial :ref:`svm_kernels`.

See :ref:`sphx_glr_auto_examples_linear_model_plot_polynomial_interpolation.py` for Ridge regression using created polynomial features.

.. _function_transformer:

Custom transformers
===================

Often, you will want to convert an existing Python function into a transformer
to assist in data cleaning or processing. You can implement a transformer from
an arbitrary function with :class:`FunctionTransformer`. For example, to build
a transformer that applies a log transformation in a pipeline, do::

    >>> import numpy as np
    >>> from sklearn.preprocessing import FunctionTransformer
    >>> transformer = FunctionTransformer(np.log1p)
    >>> X = np.array([[0, 1], [2, 3]])
    >>> transformer.transform(X)
    array([[0.        , 0.69314718],
           [1.09861229, 1.38629436]])

You can ensure that ``func`` and ``inverse_func`` are the inverse of each other
by setting ``check_inverse=True`` and calling ``fit`` before
``transform``. Please note that a warning is raised and can be turned into an
error with a ``filterwarnings``::

  >>> import warnings
  >>> warnings.filterwarnings("error", message=".*check_inverse*.",
  ...                         category=UserWarning, append=False)

For a full code example that demonstrates using a :class:`FunctionTransformer`
to do custom feature selection,
see :ref:`sphx_glr_auto_examples_preprocessing_plot_function_transformer.py`
