Pandas之数据规整化：清理、转换、合并与重塑

数据分析和建模方面大量的工作是用在数据准备上：加载、清理、转换以及重塑。本文主要介绍数据集的合并、重塑和转换。

import numpy as np
import pandas as pd
pd.options.display.max_rows = 20  # 最多显示20行
np.random.seed(12345)
np.set_printoptions(precision=4, suppress=True)  # 精确到4为小数

合并数据集

• pandas.merge可根据一个或多个键将不同DataFrame中的行连接起来。
• pandas.concat可以沿着一条轴将多个对象堆叠到一起
• combine_first可以将重复数据编接在一起，用一个对象中的值填充另一个对象中的缺失值。

数据库风格的DataFrame合并

DataFrame的合并（merge）或连接（join）运算是通过一个或多个键将行链接起来。

s = pd.read_csv('./examples/student.csv')
s

	student_id	student_name	teacher_id
0	1	xiaoming	1
1	2	xiaohua	1
2	3	xiaoli	1
3	4	xiaozhang	2
4	5	xiaosun	3
5	6	xiaohong	5

t = pd.read_csv('./examples/teacher.csv')
t

	teacher_id	teacher_name
0	1	zhangsan
1	2	lisi
2	3	wangwu
3	4	zhaoliu

pd.merge(s,t)  #默认为内连接

	student_id	student_name	teacher_id	teacher_name
0	1	xiaoming	1	zhangsan
1	2	xiaohua	1	zhangsan
2	3	xiaoli	1	zhangsan
3	4	xiaozhang	2	lisi
4	5	xiaosun	3	wangwu

• 如果没有指明用哪个列进行连接，merge会将重叠列的列名当作键。因此，最好显示指定连接键
• 如果两个对象的列名，也可以分别进行指定。
• 默认情况下，merge做的是inner连接连接，返回的是交集。其他方式，还有left,right以及outer。
• left是显示左表中的所有记录，right返回右表中的所有记录，而outer返回的是键的并集，其组合了左连接和右连接的效果。

pd.merge(s,t,on='teacher_id') #明确指定连接键

	student_id	student_name	teacher_id	teacher_name
0	1	xiaoming	1	zhangsan
1	2	xiaohua	1	zhangsan
2	3	xiaoli	1	zhangsan
3	4	xiaozhang	2	lisi
4	5	xiaosun	3	wangwu

s.merge(t, on='teacher_id')

	student_id	student_name	teacher_id	teacher_name
0	1	xiaoming	1	zhangsan
1	2	xiaohua	1	zhangsan
2	3	xiaoli	1	zhangsan
3	4	xiaozhang	2	lisi
4	5	xiaosun	3	wangwu

# 列名不同，需分别进行指定
df3 = pd.DataFrame({'lkey': ['b', 'b', 'a', 'c', 'a', 'a', 'b'],
                    'data1': range(7)})
df4 = pd.DataFrame({'rkey': ['a', 'b', 'd'],
                    'data2': range(3)})

df3

	lkey	data1
0	b	0
1	b	1
2	a	2
3	c	3
4	a	4
5	a	5
6	b	6

df4

	rkey	data2
0	a	0
1	b	1
2	d	2

pd.merge(df3, df4, left_on='lkey', right_on='rkey')

	lkey	data1	rkey	data2
0	b	0	b	1
1	b	1	b	1
2	b	6	b	1
3	a	2	a	0
4	a	4	a	0
5	a	5	a	0

pd.merge(s, t, how='inner')

	student_id	student_name	teacher_id	teacher_name
0	1	xiaoming	1	zhangsan
1	2	xiaohua	1	zhangsan
2	3	xiaoli	1	zhangsan
3	4	xiaozhang	2	lisi
4	5	xiaosun	3	wangwu

pd.merge(s, t, how='left')

	student_id	student_name	teacher_id	teacher_name
0	1	xiaoming	1	zhangsan
1	2	xiaohua	1	zhangsan
2	3	xiaoli	1	zhangsan
3	4	xiaozhang	2	lisi
4	5	xiaosun	3	wangwu
5	6	xiaohong	5	NaN

pd.merge(s, t, how='right')

	student_id	student_name	teacher_id	teacher_name
0	1.0	xiaoming	1	zhangsan
1	2.0	xiaohua	1	zhangsan
2	3.0	xiaoli	1	zhangsan
3	4.0	xiaozhang	2	lisi
4	5.0	xiaosun	3	wangwu
5	NaN	NaN	4	zhaoliu

pd.merge(s, t, how='outer')

	student_id	student_name	teacher_id	teacher_name
0	1.0	xiaoming	1	zhangsan
1	2.0	xiaohua	1	zhangsan
2	3.0	xiaoli	1	zhangsan
3	4.0	xiaozhang	2	lisi
4	5.0	xiaosun	3	wangwu
5	6.0	xiaohong	5	NaN
6	NaN	NaN	4	zhaoliu

• 多对多合并操作，返回的是行的笛卡尔积。
• 连接方式只影响出现在结果中的键。

df1 = pd.DataFrame({'key': ['b', 'b', 'a', 'c', 'a', 'b'],
                    'data1': range(6)})

df1

	key	data1
0	b	0
1	b	1
2	a	2
3	c	3
4	a	4
5	b	5

df2 = pd.DataFrame({'key': ['a', 'b', 'a', 'b', 'd'],
                    'data2': range(5)})
df2

	key	data2
0	a	0
1	b	1
2	a	2
3	b	3
4	d	4

pd.merge(df1, df2, on='key', how='left')

	key	data1	data2
0	b	0	1.0
1	b	0	3.0
2	b	1	1.0
3	b	1	3.0
4	a	2	0.0
5	a	2	2.0
6	c	3	NaN
7	a	4	0.0
8	a	4	2.0
9	b	5	1.0
10	b	5	3.0

pd.merge(df1, df2, how='inner')

	key	data1	data2
0	b	0	1
1	b	0	3
2	b	1	1
3	b	1	3
4	b	5	1
5	b	5	3
6	a	2	0
7	a	2	2
8	a	4	0
9	a	4	2

df1.merge(df2,on=['key'],how='outer')

	key	data1	data2
0	b	0.0	1.0
1	b	0.0	3.0
2	b	1.0	1.0
3	b	1.0	3.0
4	b	5.0	1.0
5	b	5.0	3.0
6	a	2.0	0.0
7	a	2.0	2.0
8	a	4.0	0.0
9	a	4.0	2.0
10	c	3.0	NaN
11	d	NaN	4.0

• 根据多个键进行合并，传入一个由列名组成的列表即可。
• 可以理解为多个键形成一系列元组，并将其当作单个连接键

left = pd.DataFrame({'key1': ['foo', 'foo', 'bar'],
                     'key2': ['one', 'two', 'one'],
                     'lval': [1, 2, 3]})
right = pd.DataFrame({'key1': ['foo', 'foo', 'bar', 'bar'],
                      'key2': ['one', 'one', 'one', 'two'],
                      'rval': [4, 5, 6, 7]})
left
right

	key1	key2	lval
0	foo	one	1
1	foo	two	2
2	bar	one	3

	key1	key2	rval
0	foo	one	4
1	foo	one	5
2	bar	one	6
3	bar	two	7

pd.merge(right,left, on=['key1', 'key2'], how='right')

	key1	key2	rval	lval
0	foo	one	4.0	1
1	foo	one	5.0	1
2	bar	one	6.0	3
3	foo	two	NaN	2

pd.merge(left, right, on=['key1', 'key2'], how='outer')

	key1	key2	lval	rval
0	foo	one	1.0	4.0
1	foo	one	1.0	5.0
2	foo	two	2.0	NaN
3	bar	one	3.0	6.0
4	bar	two	NaN	7.0

• 对于重复列名，可以指定一个suffixes选项，用于附加到重复列名上。

pd.merge(left, right, on='key1')

	key1	key2_x	lval	key2_y	rval
0	foo	one	1	one	4
1	foo	one	1	one	5
2	foo	two	2	one	4
3	foo	two	2	one	5
4	bar	one	3	one	6
5	bar	one	3	two	7

pd.merge(left, right, on='key1', suffixes=('_left', '_right'))

	key1	key2_left	lval	key2_right	rval
0	foo	one	1	one	4
1	foo	one	1	one	5
2	foo	two	2	one	4
3	foo	two	2	one	5
4	bar	one	3	one	6
5	bar	one	3	two	7

merge函数的参数

参数	说明
left	左侧DataFrame
right	右侧DataFrame
how	连接方式，可选为inner、outer、left、right，默认为inner
on	用于连接的列名，必须同时存在于左右两个DataFrame中。如果不指定且其他参数也未指定，则以共同列名合并
left_on	左侧DataFrame中的连接键列
right_on	右侧DataFrame中的连接键列
left_index	TrueorFalse,是否将左侧DataFrame的行索引作为连接键
right_index	TrueorFalse,是否将右侧DataFrame的行索引作为连接键
sort	TrueorFalse，合并后是否对数据进行排序。默认为True,大规模数据时禁用可获得更好的性能
suffixes	字符串元组，用于追加到重叠列名的末尾，默认为(_x, _y)

索引上合并

left1 = pd.DataFrame({'key': ['a', 'b', 'a', 'a', 'b', 'c'],
                      'value': range(6)})
right1 = pd.DataFrame({'group_val': [3.5, 7]}, index=['a', 'b'])
left1
right1

	key	value
0	a	0
1	b	1
2	a	2
3	a	3
4	b	4
5	c	5

	group_val
a	3.5
b	7.0

pd.merge(left1, right1, left_on='key', right_index=True)

	key	value	group_val
0	a	0	3.5
2	a	2	3.5
3	a	3	3.5
1	b	1	7.0
4	b	4	7.0

pd.merge(left1, right1, left_on='key', right_index=True, how='outer')

	key	value	group_val
0	a	0	3.5
2	a	2	3.5
3	a	3	3.5
1	b	1	7.0
4	b	4	7.0
5	c	5	NaN

• 层次化索引

lefth = pd.DataFrame({'key1': ['Ohio', 'Ohio', 'Ohio',
                               'Nevada', 'Nevada'],
                      'key2': [2000, 2001, 2002, 2001, 2002],
                      'data': np.arange(5.)})
righth = pd.DataFrame(np.arange(12).reshape((6, 2)),
                      index=[['Nevada', 'Nevada', 'Ohio', 'Ohio',
                              'Ohio', 'Ohio'],
                             [2001, 2000, 2000, 2000, 2001, 2002]],
                      columns=['event1', 'event2'])
lefth
righth

	key1	key2	data
0	Ohio	2000	0.0
1	Ohio	2001	1.0
2	Ohio	2002	2.0
3	Nevada	2001	3.0
4	Nevada	2002	4.0

		event1	event2
Nevada	2001	0	1
	2000	2	3
Ohio	2000	4	5
	2000	6	7
	2001	8	9
	2002	10	11

pd.merge(lefth, righth, left_on=['key1', 'key2'], right_index=True)

	key1	key2	data	event1	event2
0	Ohio	2000	0.0	4	5
0	Ohio	2000	0.0	6	7
1	Ohio	2001	1.0	8	9
2	Ohio	2002	2.0	10	11
3	Nevada	2001	3.0	0	1

righth.swaplevel(0, 1)

		event1	event2
2001	Nevada	0	1
2000	Nevada	2	3
	Ohio	4	5
	Ohio	6	7
2001	Ohio	8	9
2002	Ohio	10	11

pd.merge(lefth, righth, left_on=['key1', 'key2'], right_index=True)

	key1	key2	data	event1	event2
0	Ohio	2000	0.0	4	5
0	Ohio	2000	0.0	6	7
1	Ohio	2001	1.0	8	9
2	Ohio	2002	2.0	10	11
3	Nevada	2001	3.0	0	1

pd.merge(lefth, righth, left_on=['key1', 'key2'],
         right_index=True, how='outer')

	key1	key2	data	event1	event2
0	Ohio	2000	0.0	4.0	5.0
0	Ohio	2000	0.0	6.0	7.0
1	Ohio	2001	1.0	8.0	9.0
2	Ohio	2002	2.0	10.0	11.0
3	Nevada	2001	3.0	0.0	1.0
4	Nevada	2002	4.0	NaN	NaN
4	Nevada	2000	NaN	2.0	3.0

left2 = pd.DataFrame([[1., 2.], [3., 4.], [5., 6.]],
                     index=['a', 'c', 'e'],
                     columns=['Ohio', 'Nevada'])
right2 = pd.DataFrame([[7., 8.], [9., 10.], [11., 12.], [13, 14]],
                      index=['b', 'c', 'd', 'e'],
                      columns=['Missouri', 'Alabama'])
left2
right2

	Ohio	Nevada
a	1.0	2.0
c	3.0	4.0
e	5.0	6.0

	Missouri	Alabama
b	7.0	8.0
c	9.0	10.0
d	11.0	12.0
e	13.0	14.0

pd.merge(left2, right2, how='outer', left_index=True, right_index=True, 
         sort=False)

	Ohio	Nevada	Missouri	Alabama
a	1.0	2.0	NaN	NaN
b	NaN	NaN	7.0	8.0
c	3.0	4.0	9.0	10.0
d	NaN	NaN	11.0	12.0
e	5.0	6.0	13.0	14.0

left2.merge(right2, how='outer', left_index=True, right_index=True)

	Ohio	Nevada	Missouri	Alabama
a	1.0	2.0	NaN	NaN
b	NaN	NaN	7.0	8.0
c	3.0	4.0	9.0	10.0
d	NaN	NaN	11.0	12.0
e	5.0	6.0	13.0	14.0

• DataFrame还有一个join实例方法，可以更为方便地实现索引合并。可以用于合并多个带有相同或相似索引的DataFrame对象，而不管是否有重叠列。

left2.join(right2, how='outer')

	Ohio	Nevada	Missouri	Alabama
a	1.0	2.0	NaN	NaN
b	NaN	NaN	7.0	8.0
c	3.0	4.0	9.0	10.0
d	NaN	NaN	11.0	12.0
e	5.0	6.0	13.0	14.0

left1.join(right1, on='key')

	key	value	group_val
0	a	0	3.5
1	b	1	7.0
2	a	2	3.5
3	a	3	3.5
4	b	4	7.0
5	c	5	NaN

another = pd.DataFrame([[7., 8.], [9., 10.], [11., 12.], [16., 17.]],
                       index=['a', 'c', 'e', 'f'],
                       columns=['New York', 'Oregon'])
another

	New York	Oregon
a	7.0	8.0
c	9.0	10.0
e	11.0	12.0
f	16.0	17.0

left2.join([right2, another])

	Ohio	Nevada	Missouri	Alabama	New York	Oregon
a	1.0	2.0	NaN	NaN	7.0	8.0
c	3.0	4.0	9.0	10.0	9.0	10.0
e	5.0	6.0	13.0	14.0	11.0	12.0

left2.join([right2, another], how='outer')

	Ohio	Nevada	Missouri	Alabama	New York	Oregon
a	1.0	2.0	NaN	NaN	7.0	8.0
c	3.0	4.0	9.0	10.0	9.0	10.0
e	5.0	6.0	13.0	14.0	11.0	12.0
b	NaN	NaN	7.0	8.0	NaN	NaN
d	NaN	NaN	11.0	12.0	NaN	NaN
f	NaN	NaN	NaN	NaN	16.0	17.0

轴向连接

数组的合并与拆分

• Numpy有一个用于合并原始Numpy数组的concatenate函数，可以按指定轴将一个由数组组成的序列（如元组、列表等）连接到一起。

arr = np.arange(12).reshape((3, 4))
arr

array([[ 0,  1,  2,  3],
       [ 4,  5,  6,  7],
       [ 8,  9, 10, 11]])

np.concatenate([arr, arr], axis=1)

array([[ 0,  1,  2,  3,  0,  1,  2,  3],
       [ 4,  5,  6,  7,  4,  5,  6,  7],
       [ 8,  9, 10, 11,  8,  9, 10, 11]])

np.concatenate([arr, arr], axis=0)

array([[ 0,  1,  2,  3],
       [ 4,  5,  6,  7],
       [ 8,  9, 10, 11],
       [ 0,  1,  2,  3],
       [ 4,  5,  6,  7],
       [ 8,  9, 10, 11]])

a = np.array([[1, 2], [3, 4]])
b = np.array([[5,6]])
a
b

array([[1, 2],
       [3, 4]])

array([[5, 6]])

a.shape
b.shape

(2, 2)

(1, 2)

np.concatenate((a, b), axis=0)

array([[1, 2],
       [3, 4],
       [5, 6]])

np.concatenate((a, b.T), axis=1)

array([[1, 2, 5],
       [3, 4, 6]])

对于常见的连接操作，NumPy提供了比较方便的的方法（如vstack和hstack），因此，上面的操作也可以写为

np.vstack((arr, arr))

array([[ 0,  1,  2,  3],
       [ 4,  5,  6,  7],
       [ 8,  9, 10, 11],
       [ 0,  1,  2,  3],
       [ 4,  5,  6,  7],
       [ 8,  9, 10, 11]])

np.hstack((arr, arr))

array([[ 0,  1,  2,  3,  0,  1,  2,  3],
       [ 4,  5,  6,  7,  4,  5,  6,  7],
       [ 8,  9, 10, 11,  8,  9, 10, 11]])

np.vstack((a, b))

array([[1, 2],
       [3, 4],
       [5, 6]])

np.hstack((a, b.T))

array([[1, 2, 5],
       [3, 4, 6]])

相反的，split用于将一个数组沿指定的轴拆分为多个数组

arr2 = np.random.randn(5, 2)
arr2

array([[ 0.0009,  1.3438],
       [-0.7135, -0.8312],
       [-2.3702, -1.8608],
       [-0.8608,  0.5601],
       [-1.2659,  0.1198]])

first,second,third = np.split(arr2, [1, 3])
first

array([[0.0009, 1.3438]])

second
third

array([[-0.7135, -0.8312],
       [-2.3702, -1.8608]])

array([[-0.8608, 0.5601], [-1.2659, 0.1198]])

Pandas的轴向连接

• 对于pandas对象，带有标签的轴能进一步扩展数组连接运算。pandas有一个concat函数

s1 = pd.Series([0, 1], index=['a', 'b'])
s1

a    0
b    1
dtype: int64

s2 = pd.Series([2, 3, 4], index=['c', 'd', 'e'])
s2

c    2
d    3
e    4
dtype: int64

s3 = pd.Series([5, 6], index=['f', 'g'])
s3

f    5
g    6
dtype: int64

s1.add(s2,fill_value=0)

a    0.0
b    1.0
c    2.0
d    3.0
e    4.0
dtype: float64

pd.concat([s1, s2, s3]) # 默认在axis=0上连接，产生一个新的Series

a    0
b    1
c    2
d    3
e    4
f    5
g    6
dtype: int64

# 如果在axis=1上连接，则产生一个DataFrame，默认为外连接，索引的有序并集
pd.concat([s1, s2, s3], axis=1,sort=False) 

	0	1	2
a	0.0	NaN	NaN
b	1.0	NaN	NaN
c	NaN	2.0	NaN
d	NaN	3.0	NaN
e	NaN	4.0	NaN
f	NaN	NaN	5.0
g	NaN	NaN	6.0

s4 = pd.concat([s1, s3])
s4

a    0
b    1
f    5
g    6
dtype: int64

pd.concat([s1, s4], axis=1)

	0	1
a	0.0	0
b	1.0	1
f	NaN	5
g	NaN	6

# 内连接，返回交集
pd.concat([s1, s4], axis=1, join='inner')

	0	1
a	0	0
b	1	1

• 使用keys可以在想要的连接轴上创建层次化索引

result = pd.concat([s1, s2, s3], keys=['one', 'two', 'three'])
result

one    a    0
       b    1
two    c    2
       d    3
       e    4
three  f    5
       g    6
dtype: int64

result.unstack() # 将数据的行旋转为列

	a	b	c	d	e	f	g
one	0.0	1.0	NaN	NaN	NaN	NaN	NaN
two	NaN	NaN	2.0	3.0	4.0	NaN	NaN
three	NaN	NaN	NaN	NaN	NaN	5.0	6.0

• 如果沿着axis=1对Series进行合并，则keys会成为DataFrame的列标题。

pd.concat([s1, s2, s3], axis=1, keys=['one', 'two', 'three'])

	one	two	three
a	0.0	NaN	NaN
b	1.0	NaN	NaN
c	NaN	2.0	NaN
d	NaN	3.0	NaN
e	NaN	4.0	NaN
f	NaN	NaN	5.0
g	NaN	NaN	6.0

• 上述逻辑同样适合于DataFrame。

df1 = pd.DataFrame(np.arange(6).reshape(3, 2), index=['a', 'b', 'c'],
                   columns=['one', 'two'])
df2 = pd.DataFrame(5 + np.arange(4).reshape(2, 2), index=['a', 'c'],
                   columns=['three', 'four'])

df1

	one	two
a	0	1
b	2	3
c	4	5

df2

	three	four
a	5	6
c	7	8

pd.concat([df1, df2], axis=1)

	one	two	three	four
a	0	1	5.0	6.0
b	2	3	NaN	NaN
c	4	5	7.0	8.0

pd.concat([df1, df2], axis=1, keys=['level1', 'level2'])

	level1		level2
	one	two	three	four
a	0	1	5.0	6.0
b	2	3	NaN	NaN
c	4	5	7.0	8.0

• 如果keys选项传入的不是列表而是字典，则字典的键会被当作keys选项的值。
• ignore_index不保留连接轴上的索引，产生一组新索引。

pd.concat({'level1': df1, 'level2': df2}, axis=1)

	level1		level2
	one	two	three	four
a	0	1	5.0	6.0
b	2	3	NaN	NaN
c	4	5	7.0	8.0

# 创建分层级别的名称
pd.concat([df1, df2], axis=1, keys=['level1', 'level2'],
          names=['upper', 'lower'])

upper	level1		level2
lower	one	two	three	four
a	0	1	5.0	6.0
b	2	3	NaN	NaN
c	4	5	7.0	8.0

df1 = pd.DataFrame(np.random.randn(3, 4), columns=['a', 'b', 'c', 'd'])
df2 = pd.DataFrame(np.random.randn(2, 3), columns=['b', 'd', 'a'])
df1

	a	b	c	d
0	-0.204708	0.478943	-0.519439	-0.555730
1	1.965781	1.393406	0.092908	0.281746
2	0.769023	1.246435	1.007189	-1.296221

df2

	b	d	a
0	0.274992	0.228913	1.352917
1	0.886429	-2.001637	-0.371843

pd.concat([df1,df2])

	a	b	c	d
0	-0.204708	0.478943	-0.519439	-0.555730
1	1.965781	1.393406	0.092908	0.281746
2	0.769023	1.246435	1.007189	-1.296221
0	1.352917	0.274992	NaN	0.228913
1	-0.371843	0.886429	NaN	-2.001637

pd.concat([df1, df2], ignore_index=True)

	a	b	c	d
0	-0.204708	0.478943	-0.519439	-0.555730
1	1.965781	1.393406	0.092908	0.281746
2	0.769023	1.246435	1.007189	-1.296221
3	1.352917	0.274992	NaN	0.228913
4	-0.371843	0.886429	NaN	-2.001637

concat函数的参数

参数	说明
objs	参与连接的pandas对象的列表或字典，必须参数
axis	连接的轴向，默认axis=0
join	连接方式，可选为inner（交集）、outer（并集），默认为join=outer
join_axes	指明用于其他n-1条轴的索引
keys	与连接对象有关的值，用于形成连接轴上的层次化索引。可以是任意的列表或数组、元组数组（如果将level设为多级数组的话）
levels	指定用于层次化索引各级别上的索引
names	创建分层级别的名称
verify_integrity	检查结果对象新轴上的重复情况，如果发现则引发异常。默认为False
ignore_index	不保留连接轴上的索引，产生一组新索引

合并重叠数据

a = pd.Series([np.nan, 2.5, np.nan, 3.5, 4.5, np.nan],
              index=['f', 'e', 'd', 'c', 'b', 'a'])
b = pd.Series(np.arange(len(a), dtype=np.float64),
              index=['f', 'e', 'd', 'c', 'b', 'a'])
b[-1] = np.nan
a
b

f    NaN
e    2.5
d    NaN
c    3.5
b    4.5
a    NaN
dtype: float64

f 0.0 e 1.0 d 2.0 c 3.0 b 4.0 a NaN dtype: float64

np.where(pd.isnull(a), b, a)

array([0. , 2.5, 2. , 3.5, 4.5, nan])

pd.Series(np.where(pd.isnull(a), b, a))

0    0.0
1    2.5
2    2.0
3    3.5
4    4.5
5    NaN
dtype: float64

pd.concat([a, b])

f    NaN
e    2.5
d    NaN
c    3.5
b    4.5
a    NaN
f    0.0
e    1.0
d    2.0
c    3.0
b    4.0
a    NaN
dtype: float64

• combie_first方法，将其NA值用另一个同位置（相同索引）的值代替，会数据自动对齐。
• Combine Series values, choosing the calling Series’s values first. Result index will be the union of the two indexes

a.combine_first(b)

f    0.0
e    2.5
d    2.0
c    3.5
b    4.5
a    NaN
dtype: float64

b.combine_first(a)

f    0.0
e    1.0
d    2.0
c    3.0
b    4.0
a    NaN
dtype: float64

b
b[:-2]

f    0.0
e    1.0
d    2.0
c    3.0
b    4.0
a    NaN
dtype: float64

f 0.0 e 1.0 d 2.0 c 3.0 dtype: float64

a
a[2:]

f    NaN
e    2.5
d    NaN
c    3.5
b    4.5
a    NaN
dtype: float64

d NaN c 3.5 b 4.5 a NaN dtype: float64

b[:-2].combine_first(a[2:])

a    NaN
b    4.5
c    3.0
d    2.0
e    1.0
f    0.0
dtype: float64

• Combine two DataFrame objects and default to non-null values in frame calling the method. Result index columns will be the union of the respective indexes and columns

df1 = pd.DataFrame({'a': [1., np.nan, 5., np.nan],
                    'b': [np.nan, 2., np.nan, 6.],
                    'c': range(2, 18, 4)})
df2 = pd.DataFrame({'a': [5., 4., np.nan, 3., 7.],
                    'b': [np.nan, 3., 4., 6., 8.]})
df1

	a	b	c
0	1.0	NaN	2
1	NaN	2.0	6
2	5.0	NaN	10
3	NaN	6.0	14

df2

	a	b
0	5.0	NaN
1	4.0	3.0
2	NaN	4.0
3	3.0	6.0
4	7.0	8.0

df1.combine_first(df2)

	a	b	c
0	1.0	NaN	2.0
1	4.0	2.0	6.0
2	5.0	4.0	10.0
3	3.0	6.0	14.0
4	7.0	8.0	NaN

重塑（reshape）和透视（pivot）

层次化索引重塑

• stack将数据的列旋转为行。默认dropna=True
• unstack将数的行旋转为列。 默认操作的是最内层，可以传入分层级别的编号或名称，对其他级别进行unstack操作。

data = pd.DataFrame(np.arange(6).reshape((2, 3)),
                    index=pd.Index(['Ohio', 'Colorado'], name='state'),
                    columns=pd.Index(['one', 'two', 'three'],
                    name='number'))
data

number	one	two	three
state
Ohio	0	1	2
Colorado	3	4	5

result = data.stack() # 列旋转为行，得到一个层次化索引的Series
result

state     number
Ohio      one       0
          two       1
          three     2
Colorado  one       3
          two       4
          three     5
dtype: int32

result.unstack() # 行旋转为列，层次化索引的Series得到一个DataFrame

number	one	two	three
state
Ohio	0	1	2
Colorado	3	4	5

result.unstack(0)

state	Ohio	Colorado
number
one	0	3
two	1	4
three	2	5

result.unstack('state')

state	Ohio	Colorado
number
one	0	3
two	1	4
three	2	5

s1 = pd.Series([0, 1, 2, 3], index=['a', 'b', 'c', 'd'])
s2 = pd.Series([4, 5, 6], index=['c', 'd', 'e'])
s1
s2

a    0
b    1
c    2
d    3
dtype: int64

c 4 d 5 e 6 dtype: int64

data2 = pd.concat([s1, s2], keys=['one', 'two'])
data2

one  a    0
     b    1
     c    2
     d    3
two  c    4
     d    5
     e    6
dtype: int64

data2.unstack()

	a	b	c	d	e
one	0.0	1.0	2.0	3.0	NaN
two	NaN	NaN	4.0	5.0	6.0

data2.unstack().stack()

one  a    0.0
     b    1.0
     c    2.0
     d    3.0
two  c    4.0
     d    5.0
     e    6.0
dtype: float64

data2.unstack().stack(dropna=False)

one  a    0.0
     b    1.0
     c    2.0
     d    3.0
     e    NaN
two  a    NaN
     b    NaN
     c    4.0
     d    5.0
     e    6.0
dtype: float64

df = pd.DataFrame({'left': result, 'right': result + 5},
                  columns=pd.Index(['left', 'right'], name='side'))
df

	side	left	right
state	number
Ohio	one	0	5
	two	1	6
	three	2	7
Colorado	one	3	8
	two	4	9
	three	5	10

df.unstack()

side	left			right
number	one	two	three	one	two	three
state
Ohio	0	1	2	5	6	7
Colorado	3	4	5	8	9	10

df.unstack('state')

side	left		right
state	Ohio	Colorado	Ohio	Colorado
number
one	0	3	5	8
two	1	4	6	9
three	2	5	7	10

df
df.unstack('state').stack('side')

	side	left	right
state	number
Ohio	one	0	5
	two	1	6
	three	2	7
Colorado	one	3	8
	two	4	9
	three	5	10

	state	Colorado	Ohio
number	side
one	left	3	0
	right	8	5
two	left	4	1
	right	9	6
three	left	5	2
	right	10	7

透视表 pivot

Return reshaped DataFrame organized by given index / column values.

DataFrame.pivot(self, index=None, columns=None, values=None) → 'DataFrame'

• index str or object, optional Column to use to make new frame’s index. If None, uses existing index.

• columns str or object Column to use to make new frame’s columns.

• values str, object or a list of the previous, optional Column(s) to use for populating new frame’s values. If not specified, all remaining columns will be used and the result will have hierarchically indexed columns.

df = pd.DataFrame({'foo': ['one', 'one', 'one', 'two', 'two',
                           'two'],
                   'bar': ['A', 'B', 'C', 'A', 'B', 'C'],
                   'baz': [1, 2, 3, 4, 5, 6],
                   'zoo': ['x', 'y', 'z', 'q', 'w', 't']})
df

	foo	bar	baz	zoo
0	one	A	1	x
1	one	B	2	y
2	one	C	3	z
3	two	A	4	q
4	two	B	5	w
5	two	C	6	t

df.pivot(index='foo', columns='bar', values='baz')

bar	A	B	C
foo
one	1	2	3
two	4	5	6

df.pivot(index='foo', columns='bar')['baz']

bar	A	B	C
foo
one	1	2	3
two	4	5	6

df.pivot(index='foo', columns='bar', values=['baz', 'zoo'])

	baz			zoo
bar	A	B	C	A	B	C
foo
one	1	2	3	x	y	z
two	4	5	6	q	w	t

• When there are any index, columns combinations with multiple values. DataFrame.pivot_table when you need to aggregate.

透视表pivot_table

pivot_tableCreate a spreadsheet-style pivot table as a DataFrame.

df = pd.DataFrame({"foo": ['one', 'one', 'two', 'two'],
                   "bar": ['A', 'A', 'B', 'C'],
                   "baz": [1, 2, 3, 4]})
df

	foo	bar	baz
0	one	A	1
1	one	A	2
2	two	B	3
3	two	C	4

df.pivot(index='foo', columns='bar', values='bar')

bar	A	B	C
foo
one	1.5	NaN	NaN
two	NaN	3.0	4.0

数据的转换

移除重复数据

data = pd.DataFrame({'k1': ['one', 'two'] * 3 + ['two'],
                     'k2': [1, 1, 2, 3, 3, 4, 4]})
data

	k1	k2
0	one	1
1	two	1
2	one	2
3	two	3
4	one	3
5	two	4
6	two	4

# 判断各行是否重复，返回一个布尔型的Series
data.duplicated()

0    False
1    False
2    False
3    False
4    False
5    False
6     True
dtype: bool

• drop_duplicates方法返回一个移除了重复行的DataFrame
• 默认会判断全部列，也可以指定部分列进行判断
• duplicated和drop_duplicates默认保留的是第一个出现的值组合，传入参数take_last=True则保留最后一个。

data.drop_duplicates()

	k1	k2
0	one	1
1	two	1
2	one	2
3	two	3
4	one	3
5	two	4

data['v1'] = range(7)
data.drop_duplicates(['k1'])

	k1	k2	v1
0	one	1	0
1	two	1	1

data.drop_duplicates(['k1', 'k2'], keep='last')

	k1	k2	v1
0	one	1	0
1	two	1	1
2	one	2	2
3	two	3	3
4	one	3	4
6	two	4	6

利用函数或映射进行数据转换

根据数组、Series或DataFrame列中的值来实现转换工作。

data = pd.DataFrame({'food': ['bacon', 'pulled pork', 'bacon',
                              'Pastrami', 'corned beef', 'Bacon',
                              'pastrami', 'honey ham', 'nova lox'],
                     'ounces': [4, 3, 12, 6, 7.5, 8, 3, 5, 6]})
data

	food	ounces
0	bacon	4.0
1	pulled pork	3.0
2	bacon	12.0
3	Pastrami	6.0
4	corned beef	7.5
5	Bacon	8.0
6	pastrami	3.0
7	honey ham	5.0
8	nova lox	6.0

meat_to_animal = {
  'bacon': 'pig',
  'pulled pork': 'pig',
  'pastrami': 'cow',
  'corned beef': 'cow',
  'honey ham': 'pig',
  'nova lox': 'salmon'
}

lowercased = data['food'].str.lower()
lowercased

0          bacon
1    pulled pork
2          bacon
3       pastrami
4    corned beef
5          bacon
6       pastrami
7      honey ham
8       nova lox
Name: food, dtype: object

• Series的map方法可以接受一个函数或含有映射关系的字典。

data['animal'] = lowercased.map(meat_to_animal)
data

	food	ounces	animal
0	bacon	4.0	pig
1	pulled pork	3.0	pig
2	bacon	12.0	pig
3	Pastrami	6.0	cow
4	corned beef	7.5	cow
5	Bacon	8.0	pig
6	pastrami	3.0	cow
7	honey ham	5.0	pig
8	nova lox	6.0	salmon

data['food'].map(lambda x: meat_to_animal[x.lower()])

0       pig
1       pig
2       pig
3       cow
4       cow
5       pig
6       cow
7       pig
8    salmon
Name: food, dtype: object

部分常用string的函数

方法	功能
isalnum()	如果字符串至少有一个字符并且所有字符都是字母或数字则返 回 True,否则返回 False
isalpha()	如果字符串至少有一个字符并且所有字符都是字母则返回 True, 否则返回 False
isdigit()	如果字符串只包含数字则返回 True 否则返回 False
isnumeric()	如果字符串中只包含数字字符，则返回 True，否则返回 False
isspace()	如果字符串中只包含空白，则返回 True，否则返回 False.
lower()	转换字符串中所有大写字符为小写
islower()	如果字符串中包含至少一个区分大小写的字符，并且所有这些(区分大小写的)字符都是小写，则返回 True，否则返回 False
capitalize()	将字符串的第一个字符转换为大写
isupper()	如果字符串中包含至少一个区分大小写的字符，并且所有这些(区分大小写的)字符都是大写，则返回 Tru
title()	返回"标题化"的字符串,就是说所有单词都是以大写开始，其余字母均为小写
istitle	如果字符串是标题化的(见 title())则返回 True，否则返回 False

替换值

data = pd.Series([1., -999., 2., -999., -1000., 3.])
data

0       1.0
1    -999.0
2       2.0
3    -999.0
4   -1000.0
5       3.0
dtype: float64

data.replace(-999, np.nan)

0       1.0
1       NaN
2       2.0
3       NaN
4   -1000.0
5       3.0
dtype: float64

# 一次性替换多个值
data.replace([-999, -1000], np.nan)

0    1.0
1    NaN
2    2.0
3    NaN
4    NaN
5    3.0
dtype: float64

• 对不同的值进行不同的替换，传入替换关系组成的列表或字典。

data.replace([-999, -1000], [np.nan, 0])

0    1.0
1    NaN
2    2.0
3    NaN
4    0.0
5    3.0
dtype: float64

data.replace({-999: np.nan, -1000: 0})

0    1.0
1    NaN
2    2.0
3    NaN
4    0.0
5    3.0
dtype: float64

重命名轴索引

• 跟Series的值一样，轴标签也可以函数或映射进行转换，从而得到一个新的对象。跟Series一样，轴标签也有一个map函数
• 轴还可以就地修改，而无需新建一个数据结构

data = pd.DataFrame(np.arange(12).reshape((3, 4)),
                    index=['Ohio', 'Colorado', 'New York'],
                    columns=['one', 'two', 'three', 'four'])

transform = lambda x: x[:4].upper()
data.index.map(transform)

Index(['OHIO', 'COLO', 'NEW '], dtype='object')

data.index = data.index.map(transform)
data

	one	two	three	four
OHIO	0	1	2	3
COLO	4	5	6	7
NEW	8	9	10	11

rename创建数据集的转换版，而不是修改原始数据。

data.rename(index=str.title, columns=str.upper)

	ONE	TWO	THREE	FOUR
Ohio	0	1	2	3
Colo	4	5	6	7
New	8	9	10	11

# 部分轴标签的更新
data.rename(index={'OHIO': 'INDIANA'},
            columns={'three': 'peekaboo'})

	one	two	peekaboo	four
INDIANA	0	1	2	3
COLO	4	5	6	7
NEW	8	9	10	11

# 就地修改
data.rename(index={'OHIO': 'INDIANA'}, inplace=True)
data

	one	two	three	four
INDIANA	0	1	2	3
COLO	4	5	6	7
NEW	8	9	10	11