十分钟学会Pandas

这是关于Pandas的简短介绍主要面向新用户。你可以参考Cookbook了解更复杂的使用方法

习惯上,我们这样导入:

In [1]: import pandas as pd

In [2]: import numpy as np

In [3]: import matplotlib.pyplot as plt

创建对象

请参阅数据结构简介部分

通过传递一个列表的值创建一个Series,让Pandas创建一个默认的整数索引:

In [4]: s = pd.Series([1,3,5,np.nan,6,8])

In [5]: s

Out[5]:

0    1.0

1    3.0

2    5.0

3    NaN

4    6.0

5    8.0

dtype: float64

通过传递的numpy数组创建一个DataFrame,并使用DataFrame索引和标记列:

In [6]: dates = pd.date_range('', periods=6)

In [7]: dates

Out[7]:

DatetimeIndex(['2013-01-01', '2013-01-02', '2013-01-03', '2013-01-04',

               '2013-01-05', '2013-01-06'],

              dtype='datetime64[ns]', freq='D')

In [8]: df = pd.DataFrame(np.random.randn(6,4), index=dates, columns=list('ABCD'))

In [9]: df

Out[9]:

                   A         B         C         D

2013-01-01  0.469112 -0.282863 -1.509059 -1.135632

2013-01-02  1.212112 -0.173215  0.119209 -1.044236

2013-01-03 -0.861849 -2.104569 -0.494929  1.071804

2013-01-04  0.721555 -0.706771 -1.039575  0.271860

2013-01-05 -0.424972  0.567020  0.276232 -1.087401

2013-01-06 -0.673690  0.113648 -1.478427  0.524988

通过传递可转换成类似序列结构的字典序列来创建DataFrame。

查看不同列的数据类型

In [12]: df2.dtypes

Out[12]:

A           float64

B    datetime64[ns]

C           float32

D             int32

E          category

F            object

dtype: object

如果你使用的是IPython,可以使用Tab自动补全列名称(以及公共属性)。以下是将要完成的属性的一个子集:

In [13]: df2.<TAB>

df2.A                  df2.bool

df2.abs                df2.boxplot

df2.add                df2.C

df2.add_prefix         df2.clip

df2.add_suffix         df2.clip_lower

df2.align              df2.clip_upper

df2.all                df2.columns

df2.any                df2.combine

df2.append             df2.combine_first

df2.apply              df2.compound

df2.applymap           df2.consolidate

df2.as_blocks          df2.convert_objects

df2.asfreq             df2.copy

df2.as_matrix          df2.corr

df2.astype             df2.corrwith

df2.at                 df2.count

df2.at_time            df2.cov

df2.axes               df2.cummax

df2.B                  df2.cummin

df2.between_time       df2.cumprod

df2.bfill              df2.cumsum

df2.blocks             df2.D

像你见到的那样,A、B、C、D都是使用Tab自动补全的。E也是如此;为了简洁其它的属性被截断了。

查看数据

请参阅基础部分

查看frame中头部和尾部的行

In [14]: df.head()

Out[14]:

                   A         B         C         D

2013-01-01  0.469112 -0.282863 -1.509059 -1.135632

2013-01-02  1.212112 -0.173215  0.119209 -1.044236

2013-01-03 -0.861849 -2.104569 -0.494929  1.071804

2013-01-04  0.721555 -0.706771 -1.039575  0.271860

2013-01-05 -0.424972  0.567020  0.276232 -1.087401

In [15]: df.tail(3)

Out[15]:

                   A         B         C         D

2013-01-04  0.721555 -0.706771 -1.039575  0.271860

2013-01-05 -0.424972  0.567020  0.276232 -1.087401

2013-01-06 -0.673690  0.113648 -1.478427  0.524988

显示索引、行和底层numpy数据

In [16]: df.index

Out[16]:

DatetimeIndex(['2013-01-01', '2013-01-02', '2013-01-03', '2013-01-04',

               '2013-01-05', '2013-01-06'],

              dtype='datetime64[ns]', freq='D')

In [17]: df.columns

Out[17]: Index(['A', 'B', 'C', 'D'], dtype='object')

In [18]: df.values

Out[18]:

array([[ 0.4691, -0.2829, -1.5091, -1.1356],

       [ 1.2121, -0.1732,  0.1192, -1.0442],

       [-0.8618, -2.1046, -0.4949,  1.0718],

       [ 0.7216, -0.7068, -1.0396,  0.2719],

       [-0.425 ,  0.567 ,  0.2762, -1.0874],

       [-0.6737,  0.1136, -1.4784,  0.525 ]])

显示您的数据的快速统计摘要

In [19]: df.describe()

Out[19]:

              A         B         C         D

count  6.000000  6.000000  6.000000  6.000000

mean   0.073711 -0.431125 -0.687758 -0.233103

std    0.843157  0.922818  0.779887  0.973118

min   -0.861849 -2.104569 -1.509059 -1.135632

25%   -0.611510 -0.600794 -1.368714 -1.076610

50%    0.022070 -0.228039 -0.767252 -0.386188

75%    0.658444  0.041933 -0.034326  0.461706

数据转置

In [20]: df.T

Out[20]:

   2013-01-01  2013-01-02  2013-01-03  2013-01-04  2013-01-05  2013-01-06

A    0.469112    1.212112   -0.861849    0.721555   -0.424972   -0.673690

B   -0.282863   -0.173215   -2.104569   -0.706771    0.567020    0.113648

C   -1.509059    0.119209   -0.494929   -1.039575    0.276232   -1.478427

D   -1.135632   -1.044236    1.071804    0.271860   -1.087401    0.524988

按轴排序

In [21]: df.sort_index(axis=1, ascending=False)

Out[21]:

                   D         C         B         A

2013-01-01 -1.135632 -1.509059 -0.282863  0.469112

2013-01-02 -1.044236  0.119209 -0.173215  1.212112

2013-01-03  1.071804 -0.494929 -2.104569 -0.861849

2013-01-04  0.271860 -1.039575 -0.706771  0.721555

2013-01-05 -1.087401  0.276232  0.567020 -0.424972

2013-01-06  0.524988 -1.478427  0.113648 -0.673690

按值排序

In [22]: df.sort_values(by='B')

Out[22]:

                   A         B         C         D

2013-01-03 -0.861849 -2.104569 -0.494929  1.071804

2013-01-04  0.721555 -0.706771 -1.039575  0.271860

2013-01-01  0.469112 -0.282863 -1.509059 -1.135632

2013-01-02  1.212112 -0.173215  0.119209 -1.044236

2013-01-06 -0.673690  0.113648 -1.478427  0.524988

2013-01-05 -0.424972  0.567020  0.276232 -1.087401

选择

请参阅索引文档 索引和选择数据多索引/高级索引

读取

选择一个单独的列,返回一个Series,等同于 df.A

In [23]: df['A']

Out[23]:

2013-01-01    0.469112

2013-01-02    1.212112

2013-01-03   -0.861849

2013-01-04    0.721555

2013-01-05   -0.424972

2013-01-06   -0.673690

Freq: D, Name: A, dtype: float64

使用[]选择,对行进行切片。

In [24]: df[0:3]

Out[24]:

                   A         B         C         D

2013-01-01  0.469112 -0.282863 -1.509059 -1.135632

2013-01-02  1.212112 -0.173215  0.119209 -1.044236

2013-01-03 -0.861849 -2.104569 -0.494929  1.071804

In [25]: df['':'']

Out[25]:

                   A         B         C         D

2013-01-02  1.212112 -0.173215  0.119209 -1.044236

2013-01-03 -0.861849 -2.104569 -0.494929  1.071804

2013-01-04  0.721555 -0.706771 -1.039575  0.271860

通过标签选择

详情参阅标签选择

使用标签获取交叉区域

In [26]: df.loc[dates[0]]

Out[26]:

A    0.469112

B   -0.282863

C   -1.509059

D   -1.135632

Name: 2013-01-01 00:00:00, dtype: float64

通过标签选择多轴

In [27]: df.loc[:,['A','B']]

Out[27]:

                   A         B

2013-01-01  0.469112 -0.282863

2013-01-02  1.212112 -0.173215

2013-01-03 -0.861849 -2.104569

2013-01-04  0.721555 -0.706771

2013-01-05 -0.424972  0.567020

2013-01-06 -0.673690  0.113648

显示标签切片,包含端点

In [28]: df.loc['':'',['A','B']]

Out[28]:

                   A         B

2013-01-02  1.212112 -0.173215

2013-01-03 -0.861849 -2.104569

2013-01-04  0.721555 -0.706771

降低返回对象维度

In [29]: df.loc['',['A','B']]

Out[29]:

A    1.212112

B   -0.173215

Name: 2013-01-02 00:00:00, dtype: float64

获取标量值

In [30]: df.loc[dates[0],'A']

Out[30]: 0.46911229990718628

快速访问标量(同上一方法等价)

In [31]: df.at[dates[0],'A']

Out[31]: 0.46911229990718628

按位置选择

详情参阅按位置选择

通过传递整数选择位置

In [32]: df.iloc[3]

Out[32]:

A    0.721555

B   -0.706771

C   -1.039575

D    0.271860

Name: 2013-01-04 00:00:00, dtype: float64

通过整数切片,类似于numpy/python

In [33]: df.iloc[3:5,0:2]

Out[33]:

                   A         B

2013-01-04  0.721555 -0.706771

2013-01-05 -0.424972  0.567020

通过列表指定位置,类似于numpy/python样式

In [34]: df.iloc[[1,2,4],[0,2]]

Out[34]:

                   A         C

2013-01-02  1.212112  0.119209

2013-01-03 -0.861849 -0.494929

2013-01-05 -0.424972  0.276232

对行切片

In [35]: df.iloc[1:3,:]

Out[35]:

                   A         B         C         D

2013-01-02  1.212112 -0.173215  0.119209 -1.044236

2013-01-03 -0.861849 -2.104569 -0.494929  1.071804

对列切片

In [36]: df.iloc[:,1:3]

Out[36]:

                   B         C

2013-01-01 -0.282863 -1.509059

2013-01-02 -0.173215  0.119209

2013-01-03 -2.104569 -0.494929

2013-01-04 -0.706771 -1.039575

2013-01-05  0.567020  0.276232

2013-01-06  0.113648 -1.478427

获取指定值

In [37]: df.iloc[1,1]

Out[37]: -0.17321464905330858

快速访问标量(同上一方法等价)

In [38]: df.iat[1,1]

Out[38]: -0.17321464905330858

布尔索引

使用单列值选择数据。

In [39]: df[df.A > 0]

Out[39]:

                   A         B         C         D

2013-01-01  0.469112 -0.282863 -1.509059 -1.135632

2013-01-02  1.212112 -0.173215  0.119209 -1.044236

2013-01-04  0.721555 -0.706771 -1.039575  0.271860

从满足布尔条件的DataFrame中选择值。

In [40]: df[df > 0]

Out[40]:

                   A         B         C         D

2013-01-01  0.469112       NaN       NaN       NaN

2013-01-02  1.212112       NaN  0.119209       NaN

2013-01-03       NaN       NaN       NaN  1.071804

2013-01-04  0.721555       NaN       NaN  0.271860

2013-01-05       NaN  0.567020  0.276232       NaN

2013-01-06       NaN  0.113648       NaN  0.524988

使用isin()方法进行过滤

In [41]: df2 = df.copy()

In [42]: df2['E'] = ['one', 'one','two','three','four','three']

In [43]: df2

Out[43]:

                   A         B         C         D      E

2013-01-01  0.469112 -0.282863 -1.509059 -1.135632    one

2013-01-02  1.212112 -0.173215  0.119209 -1.044236    one

2013-01-03 -0.861849 -2.104569 -0.494929  1.071804    two

2013-01-04  0.721555 -0.706771 -1.039575  0.271860  three

2013-01-05 -0.424972  0.567020  0.276232 -1.087401   four

2013-01-06 -0.673690  0.113648 -1.478427  0.524988  three

In [44]: df2[df2['E'].isin(['two','four'])]

Out[44]:

                   A         B         C         D     E

2013-01-03 -0.861849 -2.104569 -0.494929  1.071804   two

2013-01-05 -0.424972  0.567020  0.276232 -1.087401  four

设置

设置一个新列会自动使索引对齐数据

In [45]: s1 = pd.Series([1,2,3,4,5,6], index=pd.date_range('', periods=6))

In [46]: s1

Out[46]:

2013-01-02    1

2013-01-03    2

2013-01-04    3

2013-01-05    4

2013-01-06    5

2013-01-07    6

Freq: D, dtype: int64

In [47]: df['F'] = s1

按标签切片

In [48]: df.at[dates[0],'A'] = 0

按位置设置值

In [49]: df.iat[0,1] = 0

通过numpy数组设置

In [50]: df.loc[:,'D'] = np.array([5] * len(df))

设置结果如下

In [51]: df

Out[51]:

                   A         B         C  D    F

2013-01-01  0.000000  0.000000 -1.509059  5  NaN

2013-01-02  1.212112 -0.173215  0.119209  5  1.0

2013-01-03 -0.861849 -2.104569 -0.494929  5  2.0

2013-01-04  0.721555 -0.706771 -1.039575  5  3.0

2013-01-05 -0.424972  0.567020  0.276232  5  4.0

2013-01-06 -0.673690  0.113648 -1.478427  5  5.0

where操作赋值

In [52]: df2 = df.copy()

In [53]: df2[df2 > 0] = -df2

In [54]: df2

Out[54]:

                   A         B         C  D    F

2013-01-01  0.000000  0.000000 -1.509059 -5  NaN

2013-01-02 -1.212112 -0.173215 -0.119209 -5 -1.0

2013-01-03 -0.861849 -2.104569 -0.494929 -5 -2.0

2013-01-04 -0.721555 -0.706771 -1.039575 -5 -3.0

2013-01-05 -0.424972 -0.567020 -0.276232 -5 -4.0

2013-01-06 -0.673690 -0.113648 -1.478427 -5 -5.0

缺失数据

Pandas主要使用np.nan来表示缺失数据。默认情况下不包括在计算中。请参阅缺失数据部分

重建索引允许修改/添加/删除指定轴的索引,并返回数据副本。

In [55]: df1 = df.reindex(index=dates[0:4], columns=list(df.columns) + ['E'])

In [56]: df1.loc[dates[0]:dates[1],'E'] = 1

In [57]: df1

Out[57]:

                   A         B         C  D    F    E

2013-01-01  0.000000  0.000000 -1.509059  5  NaN  1.0

2013-01-02  1.212112 -0.173215  0.119209  5  1.0  1.0

2013-01-03 -0.861849 -2.104569 -0.494929  5  2.0  NaN

2013-01-04  0.721555 -0.706771 -1.039575  5  3.0  NaN

删除所有缺少数据的行。

In [58]: df1.dropna(how='any')

Out[58]:

                   A         B         C  D    F    E

2013-01-02  1.212112 -0.173215  0.119209  5  1.0  1.0

填写缺失的数据行

In [59]: df1.fillna(value=5)

Out[59]:

                   A         B         C  D    F    E

2013-01-01  0.000000  0.000000 -1.509059  5  5.0  1.0

2013-01-02  1.212112 -0.173215  0.119209  5  1.0  1.0

2013-01-03 -0.861849 -2.104569 -0.494929  5  2.0  5.0

2013-01-04  0.721555 -0.706771 -1.039575  5  3.0  5.0

获取值为nan的布尔值

In [60]: pd.isnull(df1)

Out[60]:

                A      B      C      D      F      E

2013-01-01  False  False  False  False   True  False

2013-01-02  False  False  False  False  False  False

2013-01-03  False  False  False  False  False   True

2013-01-04  False  False  False  False  False   True

运算

请参阅二进制运算的基础部分

统计

运算一般排除丢失的数据。

执行描述性统计

In [61]: df.mean()

Out[61]:

A   -0.004474

B   -0.383981

C   -0.687758

D    5.000000

F    3.000000

dtype: float64

在其他轴上执行相同的运算

In [62]: df.mean(1)

Out[62]:

2013-01-01    0.872735

2013-01-02    1.431621

2013-01-03    0.707731

2013-01-04    1.395042

2013-01-05    1.883656

2013-01-06    1.592306

Freq: D, dtype: float64

运算具有不同维度和需要对齐的对象。此外,Pandas会沿着指定维度运算。

In [63]: s = pd.Series([1,3,5,np.nan,6,8], index=dates).shift(2)

In [64]: s

Out[64]:

2013-01-01    NaN

2013-01-02    NaN

2013-01-03    1.0

2013-01-04    3.0

2013-01-05    5.0

2013-01-06    NaN

Freq: D, dtype: float64

In [65]: df.sub(s, axis='index')

Out[65]:

                   A         B         C    D    F

2013-01-01       NaN       NaN       NaN  NaN  NaN

2013-01-02       NaN       NaN       NaN  NaN  NaN

2013-01-03 -1.861849 -3.104569 -1.494929  4.0  1.0

2013-01-04 -2.278445 -3.706771 -4.039575  2.0  0.0

2013-01-05 -5.424972 -4.432980 -4.723768  0.0 -1.0

2013-01-06       NaN       NaN       NaN  NaN  NaN

应用

将函数应用于数据

In [66]: df.apply(np.cumsum)

Out[66]:

                   A         B         C   D     F

2013-01-01  0.000000  0.000000 -1.509059   5   NaN

2013-01-02  1.212112 -0.173215 -1.389850  10   1.0

2013-01-03  0.350263 -2.277784 -1.884779  15   3.0

2013-01-04  1.071818 -2.984555 -2.924354  20   6.0

2013-01-05  0.646846 -2.417535 -2.648122  25  10.0

2013-01-06 -0.026844 -2.303886 -4.126549  30  15.0

In [67]: df.apply(lambda x: x.max() - x.min())

Out[67]:

A    2.073961

B    2.671590

C    1.785291

D    0.000000

F    4.000000

dtype: float64

直方图

详情请请参阅直方图和离散化

In [68]: s = pd.Series(np.random.randint(0, 7, size=10))

In [69]: s

Out[69]:

0    4

1    2

2    1

3    2

4    6

5    4

6    4

7    6

8    4

9    4

dtype: int64

In [70]: s.value_counts()

Out[70]:

4    5

6    2

2    2

1    1

dtype: int64

字符串方法

Series在字符串中设置了一组字符串处理方法,可以方便地对数组中每个元素进行操作,如下面代码片段所示。请注意,字符串中的模式匹配默认使用正则表达式。(在某些情况下总是使用它们)。详情请参阅矢量字符串方法

In [71]: s = pd.Series(['A', 'B', 'C', 'Aaba', 'Baca', np.nan, 'CABA', 'dog', 'cat'])

In [72]: s.str.lower()

Out[72]:

0       a

1       b

2       c

3    aaba

4    baca

5     NaN

6    caba

7     dog

8     cat

dtype: object

合并

连接

在连接/合并类型操作的情况下,Pandas提供了一些具有用于索引和关系代数的各种函数合并Series、DataFrame和Panel对象的方法

请参阅合并部分

使用concat()把Pandas对象连接:

In [73]: df = pd.DataFrame(np.random.randn(10, 4))

In [74]: df

Out[74]:

          0         1         2         3

0 -0.548702  1.467327 -1.015962 -0.483075

1  1.637550 -1.217659 -0.291519 -1.745505

2 -0.263952  0.991460 -0.919069  0.266046

3 -0.709661  1.669052  1.037882 -1.705775

4 -0.919854 -0.042379  1.247642 -0.009920

5  0.290213  0.495767  0.362949  1.548106

6 -1.131345 -0.089329  0.337863 -0.945867

7 -0.932132  1.956030  0.017587 -0.016692

8 -0.575247  0.254161 -1.143704  0.215897

9  1.193555 -0.077118 -0.408530 -0.862495

# break it into pieces

In [75]: pieces = [df[:3], df[3:7], df[7:]]

In [76]: pd.concat(pieces)

Out[76]:

          0         1         2         3

0 -0.548702  1.467327 -1.015962 -0.483075

1  1.637550 -1.217659 -0.291519 -1.745505

2 -0.263952  0.991460 -0.919069  0.266046

3 -0.709661  1.669052  1.037882 -1.705775

4 -0.919854 -0.042379  1.247642 -0.009920

5  0.290213  0.495767  0.362949  1.548106

6 -1.131345 -0.089329  0.337863 -0.945867

7 -0.932132  1.956030  0.017587 -0.016692

8 -0.575247  0.254161 -1.143704  0.215897

9  1.193555 -0.077118 -0.408530 -0.862495

连接

SQL风格合并。请参阅数据库风格连接

In [77]: left = pd.DataFrame({'key': ['foo', 'foo'], 'lval': [1, 2]})

In [78]: right = pd.DataFrame({'key': ['foo', 'foo'], 'rval': [4, 5]})

In [79]: left

Out[79]:

   key  lval

0  foo     1

1  foo     2

In [80]: right

Out[80]:

   key  rval

0  foo     4

1  foo     5

In [81]: pd.merge(left, right, on='key')

Out[81]:

   key  lval  rval

0  foo     1     4

1  foo     1     5

2  foo     2     4

3  foo     2     5

给出另一个例子:

In [82]: left = pd.DataFrame({'key': ['foo', 'bar'], 'lval': [1, 2]})

In [83]: right = pd.DataFrame({'key': ['foo', 'bar'], 'rval': [4, 5]})

In [84]: left

Out[84]:

   key  lval

0  foo     1

1  bar     2

In [85]: right

Out[85]:

   key  rval

0  foo     4

1  bar     5

In [86]: pd.merge(left, right, on='key')

Out[86]:

   key  lval  rval

0  foo     1     4

1  bar     2     5

追加

添加行到DataFrame。请参阅追加

In [87]: df = pd.DataFrame(np.random.randn(8, 4), columns=['A','B','C','D'])

In [88]: df

Out[88]:

          A         B         C         D

0  1.346061  1.511763  1.627081 -0.990582

1 -0.441652  1.211526  0.268520  0.024580

2 -1.577585  0.396823 -0.105381 -0.532532

3  1.453749  1.208843 -0.080952 -0.264610

4 -0.727965 -0.589346  0.339969 -0.693205

5 -0.339355  0.593616  0.884345  1.591431

6  0.141809  0.220390  0.435589  0.192451

7 -0.096701  0.803351  1.715071 -0.708758

In [89]: s = df.iloc[3]

In [90]: df.append(s, ignore_index=True)

Out[90]:

          A         B         C         D

0  1.346061  1.511763  1.627081 -0.990582

1 -0.441652  1.211526  0.268520  0.024580

2 -1.577585  0.396823 -0.105381 -0.532532

3  1.453749  1.208843 -0.080952 -0.264610

4 -0.727965 -0.589346  0.339969 -0.693205

5 -0.339355  0.593616  0.884345  1.591431

6  0.141809  0.220390  0.435589  0.192451

7 -0.096701  0.803351  1.715071 -0.708758

8  1.453749  1.208843 -0.080952 -0.264610

分组

"分组"我们指的是涉及一个或多个以下步骤的过程

  • Splitting:根据一些标准将数据分组
  • Applying:将功能独立应用于每个组
  • Combining:将结果合并成数据结构

请参阅分组部分

In [91]: df = pd.DataFrame({'A' : ['foo', 'bar', 'foo', 'bar',

   ....:                           'foo', 'bar', 'foo', 'foo'],

   ....:                    'B' : ['one', 'one', 'two', 'three',

   ....:                           'two', 'two', 'one', 'three'],

   ....:                    'C' : np.random.randn(8),

   ....:                    'D' : np.random.randn(8)})

   ....: 

In [92]: df

Out[92]:

     A      B         C         D

0  foo    one -1.202872 -0.055224

1  bar    one -1.814470  2.395985

2  foo    two  1.018601  1.552825

3  bar  three -0.595447  0.166599

4  foo    two  1.395433  0.047609

5  bar    two -0.392670 -0.136473

6  foo    one  0.007207 -0.561757

7  foo  three  1.928123 -1.623033

分组,然后将sum()函数应用于生成的组。

In [93]: df.groupby('A').sum()

Out[93]:

            C        D

A

bar -2.802588  2.42611

foo  3.146492 -0.63958

按多列分组形成层次索引,然后应用该函数。

In [94]: df.groupby(['A','B']).sum()

Out[94]:

                  C         D

A   B

bar one   -1.814470  2.395985

    three -0.595447  0.166599

    two   -0.392670 -0.136473

foo one   -1.195665 -0.616981

    three  1.928123 -1.623033

    two    2.414034  1.600434

重塑

请参阅有关分层索引重塑部分

In [95]: tuples = list(zip(*[['bar', 'bar', 'baz', 'baz',

   ....:                      'foo', 'foo', 'qux', 'qux'],

   ....:                     ['one', 'two', 'one', 'two',

   ....:                      'one', 'two', 'one', 'two']]))

   ....: 

In [96]: index = pd.MultiIndex.from_tuples(tuples, names=['first', 'second'])

In [97]: df = pd.DataFrame(np.random.randn(8, 2), index=index, columns=['A', 'B'])

In [98]: df2 = df[:4]

In [99]: df2

Out[99]:

                     A         B

first second

bar   one     0.029399 -0.542108

      two     0.282696 -0.087302

baz   one    -1.575170  1.771208

      two     0.816482  1.100230

stack()方法将"压缩"DataFrame列中的一个级别。

In [100]: stacked = df2.stack()

In [101]: stacked

Out[101]:

first  second

bar    one     A    0.029399

               B   -0.542108

       two     A    0.282696

               B   -0.087302

baz    one     A   -1.575170

               B    1.771208

       two     A    0.816482

               B    1.100230

dtype: float64

使用"stacked"DataFrame或Series(有一个MultilIndex作为索引)stack()的反向操作是unstack(),它默认情况下解除最后一个级别。

In [102]: stacked.unstack()

Out[102]:

                     A         B

first second

bar   one     0.029399 -0.542108

      two     0.282696 -0.087302

baz   one    -1.575170  1.771208

      two     0.816482  1.100230

In [103]: stacked.unstack(1)

Out[103]:

second        one       two

first

bar   A  0.029399  0.282696

      B -0.542108 -0.087302

baz   A -1.575170  0.816482

      B  1.771208  1.100230

In [104]: stacked.unstack(0)

Out[104]:

first          bar       baz

second

one    A  0.029399 -1.575170

       B -0.542108  1.771208

two    A  0.282696  0.816482

       B -0.087302  1.100230

数据透视表

请参阅数据透视表部分

In [105]: df = pd.DataFrame({'A' : ['one', 'one', 'two', 'three'] * 3,

   .....:                    'B' : ['A', 'B', 'C'] * 4,

   .....:                    'C' : ['foo', 'foo', 'foo', 'bar', 'bar', 'bar'] * 2,

   .....:                    'D' : np.random.randn(12),

   .....:                    'E' : np.random.randn(12)})

   .....: 

In [106]: df

Out[106]:

        A  B    C         D         E

0     one  A  foo  1.418757 -0.179666

1     one  B  foo -1.879024  1.291836

2     two  C  foo  0.536826 -0.009614

3   three  A  bar  1.006160  0.392149

4     one  B  bar -0.029716  0.264599

5     one  C  bar -1.146178 -0.057409

6     two  A  foo  0.100900 -1.425638

7   three  B  foo -1.035018  1.024098

8     one  C  foo  0.314665 -0.106062

9     one  A  bar -0.773723  1.824375

10    two  B  bar -1.170653  0.595974

11  three  C  bar  0.648740  1.167115

我们可以轻松地从这些数据中快速生成数据透视表:

In [107]: pd.pivot_table(df, values='D', index=['A', 'B'], columns=['C'])

Out[107]:

C             bar       foo

A     B

one   A -0.773723  1.418757

      B -0.029716 -1.879024

      C -1.146178  0.314665

three A  1.006160       NaN

      B       NaN -1.035018

      C  0.648740       NaN

two   A       NaN  0.100900

      B -1.170653       NaN

      C       NaN  0.536826

时间序列

Pandas具有简单、强大和高效的功能,用于在变频期间执行重采样操作。这在金融应用中非常常见,但是不限于此。请参阅时间序列部分

In [108]: rng = pd.date_range('1/1/2012', periods=100, freq='S')

In [109]: ts = pd.Series(np.random.randint(0, 500, len(rng)), index=rng)

In [110]: ts.resample('5Min').sum()

Out[110]:

2012-01-01    25083

Freq: 5T, dtype: int64

时区表示

In [111]: rng = pd.date_range('3/6/2012 00:00', periods=5, freq='D')

In [112]: ts = pd.Series(np.random.randn(len(rng)), rng)

In [113]: ts

Out[113]:

2012-03-06    0.464000

2012-03-07    0.227371

2012-03-08   -0.496922

2012-03-09    0.306389

2012-03-10   -2.290613

Freq: D, dtype: float64

In [114]: ts_utc = ts.tz_localize('UTC')

In [115]: ts_utc

Out[115]:

2012-03-06 00:00:00+00:00    0.464000

2012-03-07 00:00:00+00:00    0.227371

2012-03-08 00:00:00+00:00   -0.496922

2012-03-09 00:00:00+00:00    0.306389

2012-03-10 00:00:00+00:00   -2.290613

Freq: D, dtype: float64

转换到另一时区

In [116]: ts_utc.tz_convert('US/Eastern')

Out[116]:

2012-03-05 19:00:00-05:00    0.464000

2012-03-06 19:00:00-05:00    0.227371

2012-03-07 19:00:00-05:00   -0.496922

2012-03-08 19:00:00-05:00    0.306389

2012-03-09 19:00:00-05:00   -2.290613

Freq: D, dtype: float64

在时间跨度之间转换

In [117]: rng = pd.date_range('1/1/2012', periods=5, freq='M')

In [118]: ts = pd.Series(np.random.randn(len(rng)), index=rng)

In [119]: ts

Out[119]:

2012-01-31   -1.134623

2012-02-29   -1.561819

2012-03-31   -0.260838

2012-04-30    0.281957

2012-05-31    1.523962

Freq: M, dtype: float64

In [120]: ps = ts.to_period()

In [121]: ps

Out[121]:

2012-01   -1.134623

2012-02   -1.561819

2012-03   -0.260838

2012-04    0.281957

2012-05    1.523962

Freq: M, dtype: float64

In [122]: ps.to_timestamp()

Out[122]:

2012-01-01   -1.134623

2012-02-01   -1.561819

2012-03-01   -0.260838

2012-04-01    0.281957

2012-05-01    1.523962

Freq: MS, dtype: float64

在时间和时间戳之间转换,可以使用一些方便的算术函数。在下面例子中:

In [123]: prng = pd.period_range('1990Q1', '2000Q4', freq='Q-NOV')

In [124]: ts = pd.Series(np.random.randn(len(prng)), prng)

In [125]: ts.index = (prng.asfreq('M', 'e') + 1).asfreq('H', 's') + 9

In [126]: ts.head()

Out[126]:

1990-03-01 09:00   -0.902937

1990-06-01 09:00    0.068159

1990-09-01 09:00   -0.057873

1990-12-01 09:00   -0.368204

1991-03-01 09:00   -1.144073

Freq: H, dtype: float64

明确的

自0.15版本以来,Pandas可以在DataFrame中包含分类数据。有关完整文档,请参阅分类介绍API文档

In [127]: df = pd.DataFrame({"id":[1,2,3,4,5,6], "raw_grade":['a', 'b', 'b', 'a', 'a', 'e']})

将原始数据转换为分类数据。

In [128]: df["grade"] = df["raw_grade"].astype("category")

In [129]: df["grade"]

Out[129]:

0    a

1    b

2    b

3    a

4    a

5    e

Name: grade, dtype: category

Categories (3, object): [a, b, e]

将类别重命名为更有意义的名称

In [130]: df["grade"].cat.categories = ["very good", "good", "very bad"]

重新排列类别并同时添加丢失的类别(Series.cat下的方法返回一个默认的新Series)。

In [131]: df["grade"] = df["grade"].cat.set_categories(["very bad", "bad", "medium", "good", "very good"])

In [132]: df["grade"]

Out[132]:

0    very good

1         good

2         good

3    very good

4    very good

5     very bad

Name: grade, dtype: category

Categories (5, object): [very bad, bad, medium, good, very good]

排序是按类别中的顺序排序的,而不是词法顺序。

In [133]: df.sort_values(by="grade")

Out[133]:

   id raw_grade      grade

5   6         e   very bad

1   2         b       good

2   3         b       good

0   1         a  very good

3   4         a  very good

4   5         a  very good

按分类列分组还显示空类别。

In [134]: df.groupby("grade").size()

Out[134]:

grade

very bad     1

bad          0

medium       0

good         2

very good    3

dtype: int64

绘图

绘图文档

In [135]: ts = pd.Series(np.random.randn(1000), index=pd.date_range('1/1/2000', periods=1000))

In [136]: ts = ts.cumsum()

In [137]: ts.plot()

Out[137]: <matplotlib.axes._subplots.AxesSubplot at 0x1187d7278>

在DataFrame中,plot()可以方便绘制带标签的所有列。

In [138]: df = pd.DataFrame(np.random.randn(1000, 4), index=ts.index,

   .....:                   columns=['A', 'B', 'C', 'D'])

   .....: 

In [139]: df = df.cumsum()

In [140]: plt.figure(); df.plot(); plt.legend(loc='best')

Out[140]: <matplotlib.legend.Legend at 0x11b5dea20>

获取数据输入/输出

CSV

写入一个csv文件

In [141]: df.to_csv('foo.csv')

从csv文件读取

In [142]: pd.read_csv('foo.csv')

Out[142]:

     Unnamed: 0          A          B         C          D

0    2000-01-01   0.266457  -0.399641 -0.219582   1.186860

1    2000-01-02  -1.170732  -0.345873  1.653061  -0.282953

2    2000-01-03  -1.734933   0.530468  2.060811  -0.515536

3    2000-01-04  -1.555121   1.452620  0.239859  -1.156896

4    2000-01-05   0.578117   0.511371  0.103552  -2.428202

5    2000-01-06   0.478344   0.449933 -0.741620  -1.962409

6    2000-01-07   1.235339  -0.091757 -1.543861  -1.084753

..          ...        ...        ...       ...        ...

993  2002-09-20 -10.628548  -9.153563 -7.883146  28.313940

994  2002-09-21 -10.390377  -8.727491 -6.399645  30.914107

995  2002-09-22  -8.985362  -8.485624 -4.669462  31.367740

996  2002-09-23  -9.558560  -8.781216 -4.499815  30.518439

997  2002-09-24  -9.902058  -9.340490 -4.386639  30.105593

998  2002-09-25 -10.216020  -9.480682 -3.933802  29.758560

999  2002-09-26 -11.856774 -10.671012 -3.216025  29.369368

[1000 rows x 5 columns]

HDF5

读写HDF存储

写入HDF5存储

In [143]: df.to_hdf('foo.h5','df')

从HDF5存储中读取

In [144]: pd.read_hdf('foo.h5','df')

Out[144]:

                    A          B         C          D

2000-01-01   0.266457  -0.399641 -0.219582   1.186860

2000-01-02  -1.170732  -0.345873  1.653061  -0.282953

2000-01-03  -1.734933   0.530468  2.060811  -0.515536

2000-01-04  -1.555121   1.452620  0.239859  -1.156896

2000-01-05   0.578117   0.511371  0.103552  -2.428202

2000-01-06   0.478344   0.449933 -0.741620  -1.962409

2000-01-07   1.235339  -0.091757 -1.543861  -1.084753

...               ...        ...       ...        ...

2002-09-20 -10.628548  -9.153563 -7.883146  28.313940

2002-09-21 -10.390377  -8.727491 -6.399645  30.914107

2002-09-22  -8.985362  -8.485624 -4.669462  31.367740

2002-09-23  -9.558560  -8.781216 -4.499815  30.518439

2002-09-24  -9.902058  -9.340490 -4.386639  30.105593

2002-09-25 -10.216020  -9.480682 -3.933802  29.758560

2002-09-26 -11.856774 -10.671012 -3.216025  29.369368

[1000 rows x 4 columns]

Excel

读写Excel

写入Excel文件

In [145]: df.to_excel('foo.xlsx', sheet_name='Sheet1')

从Excel文件读取

In [146]: pd.read_excel('foo.xlsx', 'Sheet1', index_col=None, na_values=['NA'])

Out[146]:

                    A          B         C          D

2000-01-01   0.266457  -0.399641 -0.219582   1.186860

2000-01-02  -1.170732  -0.345873  1.653061  -0.282953

2000-01-03  -1.734933   0.530468  2.060811  -0.515536

2000-01-04  -1.555121   1.452620  0.239859  -1.156896

2000-01-05   0.578117   0.511371  0.103552  -2.428202

2000-01-06   0.478344   0.449933 -0.741620  -1.962409

2000-01-07   1.235339  -0.091757 -1.543861  -1.084753

...               ...        ...       ...        ...

2002-09-20 -10.628548  -9.153563 -7.883146  28.313940

2002-09-21 -10.390377  -8.727491 -6.399645  30.914107

2002-09-22  -8.985362  -8.485624 -4.669462  31.367740

2002-09-23  -9.558560  -8.781216 -4.499815  30.518439

2002-09-24  -9.902058  -9.340490 -4.386639  30.105593

2002-09-25 -10.216020  -9.480682 -3.933802  29.758560

2002-09-26 -11.856774 -10.671012 -3.216025  29.369368

[1000 rows x 4 columns]

陷阱

如果你尝试以下操作,可以看到如下异常:

>>> if pd.Series([False, True, False]):

    print("I was true")

Traceback

    ...

ValueError: The truth value of an array is ambiguous. Use a.empty, a.any() or a.all().

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