#!/usr/bin/env python
# coding: utf-8
# Copyright (c) 2015-2017 [Sebastian Raschka](sebastianraschka.com)
#
# https://github.com/rasbt/python-machine-learning-book
#
# [MIT License](https://github.com/rasbt/python-machine-learning-book/blob/master/LICENSE.txt)
# # Python Machine Learning - Code Examples
# # Chapter 4 - Building Good Training Sets – Data Pre-Processing
# Note that the optional watermark extension is a small IPython notebook plugin that I developed to make the code reproducible. You can just skip the following line(s).
# In[1]:
get_ipython().run_line_magic('load_ext', 'watermark')
get_ipython().run_line_magic('watermark', "-a 'Sebastian Raschka' -u -d -p numpy,pandas,matplotlib,sklearn")
# *The use of `watermark` is optional. You can install this IPython extension via "`pip install watermark`". For more information, please see: https://github.com/rasbt/watermark.*
#
#
# ### Overview
# - [Dealing with missing data](#Dealing-with-missing-data)
# - [Eliminating samples or features with missing values](#Eliminating-samples-or-features-with-missing-values)
# - [Imputing missing values](#Imputing-missing-values)
# - [Understanding the scikit-learn estimator API](#Understanding-the-scikit-learn-estimator-API)
# - [Handling categorical data](#Handling-categorical-data)
# - [Mapping ordinal features](#Mapping-ordinal-features)
# - [Encoding class labels](#Encoding-class-labels)
# - [Performing one-hot encoding on nominal features](#Performing-one-hot-encoding-on-nominal-features)
# - [Partitioning a dataset in training and test sets](#Partitioning-a-dataset-in-training-and-test-sets)
# - [Bringing features onto the same scale](#Bringing-features-onto-the-same-scale)
# - [Selecting meaningful features](#Selecting-meaningful-features)
# - [Sparse solutions with L1 regularization](#Sparse-solutions-with-L1-regularization)
# - [Sequential feature selection algorithms](#Sequential-feature-selection-algorithms)
# - [Assessing feature importance with random forests](#Assessing-feature-importance-with-random-forests)
# - [Summary](#Summary)
#
#
# In[2]:
from IPython.display import Image
get_ipython().run_line_magic('matplotlib', 'inline')
# In[3]:
# Added version check for recent scikit-learn 0.18 checks
from distutils.version import LooseVersion as Version
from sklearn import __version__ as sklearn_version
# # Dealing with missing data
# In[4]:
import pandas as pd
from io import StringIO
csv_data = '''A,B,C,D
1.0,2.0,3.0,4.0
5.0,6.0,,8.0
10.0,11.0,12.0,'''
# If you are using Python 2.7, you need
# to convert the string to unicode:
# csv_data = unicode(csv_data)
df = pd.read_csv(StringIO(csv_data))
df
# In[5]:
df.isnull().sum()
#
#
# ## Eliminating samples or features with missing values
# In[6]:
df.dropna()
# In[7]:
df.dropna(axis=1)
# In[8]:
# only drop rows where all columns are NaN
df.dropna(how='all')
# In[9]:
# drop rows that have not at least 4 non-NaN values
df.dropna(thresh=4)
# In[10]:
# only drop rows where NaN appear in specific columns (here: 'C')
df.dropna(subset=['C'])
#
#
# ## Imputing missing values
# In[11]:
from sklearn.preprocessing import Imputer
imr = Imputer(missing_values='NaN', strategy='mean', axis=0)
imr = imr.fit(df)
imputed_data = imr.transform(df.values)
imputed_data
# In[12]:
df.values
#
#
# ## Understanding the scikit-learn estimator API
# In[13]:
Image(filename='./images/04_04.png', width=400)
# In[14]:
Image(filename='./images/04_05.png', width=400)
#
#
# # Handling categorical data
# In[15]:
import pandas as pd
df = pd.DataFrame([['green', 'M', 10.1, 'class1'],
['red', 'L', 13.5, 'class2'],
['blue', 'XL', 15.3, 'class1']])
df.columns = ['color', 'size', 'price', 'classlabel']
df
#
#
# ## Mapping ordinal features
# In[16]:
size_mapping = {'XL': 3,
'L': 2,
'M': 1}
df['size'] = df['size'].map(size_mapping)
df
# In[17]:
inv_size_mapping = {v: k for k, v in size_mapping.items()}
df['size'].map(inv_size_mapping)
#
#
# ## Encoding class labels
# In[18]:
import numpy as np
class_mapping = {label: idx for idx, label in enumerate(np.unique(df['classlabel']))}
class_mapping
# In[19]:
df['classlabel'] = df['classlabel'].map(class_mapping)
df
# In[20]:
inv_class_mapping = {v: k for k, v in class_mapping.items()}
df['classlabel'] = df['classlabel'].map(inv_class_mapping)
df
# In[21]:
from sklearn.preprocessing import LabelEncoder
class_le = LabelEncoder()
y = class_le.fit_transform(df['classlabel'].values)
y
# In[22]:
class_le.inverse_transform(y)
#
#
# ## Performing one-hot encoding on nominal features
# In[23]:
X = df[['color', 'size', 'price']].values
color_le = LabelEncoder()
X[:, 0] = color_le.fit_transform(X[:, 0])
X
# In[24]:
from sklearn.preprocessing import OneHotEncoder
ohe = OneHotEncoder(categorical_features=[0])
ohe.fit_transform(X).toarray()
# In[25]:
pd.get_dummies(df[['price', 'color', 'size']])
#
#
# # Partitioning a dataset in training and test sets
# In[26]:
df_wine = pd.read_csv('https://archive.ics.uci.edu/'
'ml/machine-learning-databases/wine/wine.data',
header=None)
df_wine.columns = ['Class label', 'Alcohol', 'Malic acid', 'Ash',
'Alcalinity of ash', 'Magnesium', 'Total phenols',
'Flavanoids', 'Nonflavanoid phenols', 'Proanthocyanins',
'Color intensity', 'Hue', 'OD280/OD315 of diluted wines',
'Proline']
print('Class labels', np.unique(df_wine['Class label']))
df_wine.head()
#
#
# ### Note:
#
#
# If the link to the Wine dataset provided above does not work for you, you can find a local copy in this repository at [./../datasets/wine/wine.data](./../datasets/wine.data).
#
# Or you could fetch it via
#
# In[27]:
df_wine = pd.read_csv('https://raw.githubusercontent.com/rasbt/python-machine-learning-book/master/code/datasets/wine/wine.data', header=None)
df_wine.columns = ['Class label', 'Alcohol', 'Malic acid', 'Ash',
'Alcalinity of ash', 'Magnesium', 'Total phenols',
'Flavanoids', 'Nonflavanoid phenols', 'Proanthocyanins',
'Color intensity', 'Hue', 'OD280/OD315 of diluted wines', 'Proline']
df_wine.head()
#
# In[28]:
if Version(sklearn_version) < '0.18':
from sklearn.cross_validation import train_test_split
else:
from sklearn.model_selection import train_test_split
X, y = df_wine.iloc[:, 1:].values, df_wine.iloc[:, 0].values
X_train, X_test, y_train, y_test = \
train_test_split(X, y, test_size=0.3, random_state=0)
#
#
# # Bringing features onto the same scale
# In[29]:
from sklearn.preprocessing import MinMaxScaler
mms = MinMaxScaler()
X_train_norm = mms.fit_transform(X_train)
X_test_norm = mms.transform(X_test)
# In[30]:
from sklearn.preprocessing import StandardScaler
stdsc = StandardScaler()
X_train_std = stdsc.fit_transform(X_train)
X_test_std = stdsc.transform(X_test)
# A visual example:
# In[31]:
ex = pd.DataFrame([0, 1, 2, 3, 4, 5])
# standardize
ex[1] = (ex[0] - ex[0].mean()) / ex[0].std(ddof=0)
# Please note that pandas uses ddof=1 (sample standard deviation)
# by default, whereas NumPy's std method and the StandardScaler
# uses ddof=0 (population standard deviation)
# normalize
ex[2] = (ex[0] - ex[0].min()) / (ex[0].max() - ex[0].min())
ex.columns = ['input', 'standardized', 'normalized']
ex
#
#
# # Selecting meaningful features
# ...
# ## Sparse solutions with L1-regularization
# In[32]:
Image(filename='./images/04_12.png', width=500)
# In[33]:
Image(filename='./images/04_13.png', width=500)
# In[34]:
from sklearn.linear_model import LogisticRegression
lr = LogisticRegression(penalty='l1', C=0.1)
lr.fit(X_train_std, y_train)
print('Training accuracy:', lr.score(X_train_std, y_train))
print('Test accuracy:', lr.score(X_test_std, y_test))
# In[35]:
lr.intercept_
# In[36]:
lr.coef_
# In[37]:
import matplotlib.pyplot as plt
fig = plt.figure()
ax = plt.subplot(111)
colors = ['blue', 'green', 'red', 'cyan',
'magenta', 'yellow', 'black',
'pink', 'lightgreen', 'lightblue',
'gray', 'indigo', 'orange']
weights, params = [], []
for c in np.arange(-4., 6.):
lr = LogisticRegression(penalty='l1', C=10.**c, random_state=0)
lr.fit(X_train_std, y_train)
weights.append(lr.coef_[1])
params.append(10.**c)
weights = np.array(weights)
for column, color in zip(range(weights.shape[1]), colors):
plt.plot(params, weights[:, column],
label=df_wine.columns[column + 1],
color=color)
plt.axhline(0, color='black', linestyle='--', linewidth=3)
plt.xlim([10**(-5), 10**5])
plt.ylabel('weight coefficient')
plt.xlabel('C')
plt.xscale('log')
plt.legend(loc='upper left')
ax.legend(loc='upper center',
bbox_to_anchor=(1.38, 1.03),
ncol=1, fancybox=True)
# plt.savefig('./figures/l1_path.png', dpi=300)
plt.show()
#
#
# ## Sequential feature selection algorithms
# In[38]:
from sklearn.base import clone
from itertools import combinations
import numpy as np
from sklearn.metrics import accuracy_score
if Version(sklearn_version) < '0.18':
from sklearn.cross_validation import train_test_split
else:
from sklearn.model_selection import train_test_split
class SBS():
def __init__(self, estimator, k_features, scoring=accuracy_score,
test_size=0.25, random_state=1):
self.scoring = scoring
self.estimator = clone(estimator)
self.k_features = k_features
self.test_size = test_size
self.random_state = random_state
def fit(self, X, y):
X_train, X_test, y_train, y_test = \
train_test_split(X, y, test_size=self.test_size,
random_state=self.random_state)
dim = X_train.shape[1]
self.indices_ = tuple(range(dim))
self.subsets_ = [self.indices_]
score = self._calc_score(X_train, y_train,
X_test, y_test, self.indices_)
self.scores_ = [score]
while dim > self.k_features:
scores = []
subsets = []
for p in combinations(self.indices_, r=dim - 1):
score = self._calc_score(X_train, y_train,
X_test, y_test, p)
scores.append(score)
subsets.append(p)
best = np.argmax(scores)
self.indices_ = subsets[best]
self.subsets_.append(self.indices_)
dim -= 1
self.scores_.append(scores[best])
self.k_score_ = self.scores_[-1]
return self
def transform(self, X):
return X[:, self.indices_]
def _calc_score(self, X_train, y_train, X_test, y_test, indices):
self.estimator.fit(X_train[:, indices], y_train)
y_pred = self.estimator.predict(X_test[:, indices])
score = self.scoring(y_test, y_pred)
return score
# In[39]:
import matplotlib.pyplot as plt
from sklearn.neighbors import KNeighborsClassifier
knn = KNeighborsClassifier(n_neighbors=2)
# selecting features
sbs = SBS(knn, k_features=1)
sbs.fit(X_train_std, y_train)
# plotting performance of feature subsets
k_feat = [len(k) for k in sbs.subsets_]
plt.plot(k_feat, sbs.scores_, marker='o')
plt.ylim([0.7, 1.1])
plt.ylabel('Accuracy')
plt.xlabel('Number of features')
plt.grid()
plt.tight_layout()
# plt.savefig('./sbs.png', dpi=300)
plt.show()
# In[40]:
k5 = list(sbs.subsets_[8])
print(df_wine.columns[1:][k5])
# In[41]:
knn.fit(X_train_std, y_train)
print('Training accuracy:', knn.score(X_train_std, y_train))
print('Test accuracy:', knn.score(X_test_std, y_test))
# In[42]:
knn.fit(X_train_std[:, k5], y_train)
print('Training accuracy:', knn.score(X_train_std[:, k5], y_train))
print('Test accuracy:', knn.score(X_test_std[:, k5], y_test))
#
#
# # Assessing Feature Importances with Random Forests
# In[43]:
from sklearn.ensemble import RandomForestClassifier
feat_labels = df_wine.columns[1:]
forest = RandomForestClassifier(n_estimators=10000,
random_state=0,
n_jobs=-1)
forest.fit(X_train, y_train)
importances = forest.feature_importances_
indices = np.argsort(importances)[::-1]
for f in range(X_train.shape[1]):
print("%2d) %-*s %f" % (f + 1, 30,
feat_labels[indices[f]],
importances[indices[f]]))
plt.title('Feature Importances')
plt.bar(range(X_train.shape[1]),
importances[indices],
color='lightblue',
align='center')
plt.xticks(range(X_train.shape[1]),
feat_labels[indices], rotation=90)
plt.xlim([-1, X_train.shape[1]])
plt.tight_layout()
#plt.savefig('./random_forest.png', dpi=300)
plt.show()
# In[44]:
if Version(sklearn_version) < '0.18':
X_selected = forest.transform(X_train, threshold=0.15)
else:
from sklearn.feature_selection import SelectFromModel
sfm = SelectFromModel(forest, threshold=0.15, prefit=True)
X_selected = sfm.transform(X_train)
X_selected.shape
# Now, let's print the 3 features that met the threshold criterion for feature selection that we set earlier (note that this code snippet does not appear in the actual book but was added to this notebook later for illustrative purposes):
# In[45]:
for f in range(X_selected.shape[1]):
print("%2d) %-*s %f" % (f + 1, 30,
feat_labels[indices[f]],
importances[indices[f]]))
#
#
# # Summary
# ...