Reshaping and Pivot Tables¶
Reshaping by pivoting DataFrame objects¶
Data is often stored in CSV files or databases in so-called “stacked” or “record” format:
In [1]: df
Out[1]:
date variable value
0 2000-01-03 A 0.469112
1 2000-01-04 A -0.282863
2 2000-01-05 A -1.509059
3 2000-01-03 B -1.135632
4 2000-01-04 B 1.212112
5 2000-01-05 B -0.173215
6 2000-01-03 C 0.119209
7 2000-01-04 C -1.044236
8 2000-01-05 C -0.861849
9 2000-01-03 D -2.104569
10 2000-01-04 D -0.494929
11 2000-01-05 D 1.071804
For the curious here is how the above DataFrame was created:
import pandas.util.testing as tm; tm.N = 3
def unpivot(frame):
N, K = frame.shape
data = {'value' : frame.values.ravel('F'),
'variable' : np.asarray(frame.columns).repeat(N),
'date' : np.tile(np.asarray(frame.index), K)}
return DataFrame(data, columns=['date', 'variable', 'value'])
df = unpivot(tm.makeTimeDataFrame())
To select out everything for variable A we could do:
In [2]: df[df['variable'] == 'A']
Out[2]:
date variable value
0 2000-01-03 A 0.469112
1 2000-01-04 A -0.282863
2 2000-01-05 A -1.509059
But suppose we wish to do time series operations with the variables. A better representation would be where the columns are the unique variables and an index of dates identifies individual observations. To reshape the data into this form, use the pivot function:
In [3]: df.pivot(index='date', columns='variable', values='value')
Out[3]:
variable A B C D
date
2000-01-03 0.469112 -1.135632 0.119209 -2.104569
2000-01-04 -0.282863 1.212112 -1.044236 -0.494929
2000-01-05 -1.509059 -0.173215 -0.861849 1.071804
If the values argument is omitted, and the input DataFrame has more than one column of values which are not used as column or index inputs to pivot, then the resulting “pivoted” DataFrame will have hierarchical columns whose topmost level indicates the respective value column:
In [4]: df['value2'] = df['value'] * 2
In [5]: pivoted = df.pivot('date', 'variable')
In [6]: pivoted
Out[6]:
value value2 \
variable A B C D A B
date
2000-01-03 0.469112 -1.135632 0.119209 -2.104569 0.938225 -2.271265
2000-01-04 -0.282863 1.212112 -1.044236 -0.494929 -0.565727 2.424224
2000-01-05 -1.509059 -0.173215 -0.861849 1.071804 -3.018117 -0.346429
variable C D
date
2000-01-03 0.238417 -4.209138
2000-01-04 -2.088472 -0.989859
2000-01-05 -1.723698 2.143608
You of course can then select subsets from the pivoted DataFrame:
In [7]: pivoted['value2']
Out[7]:
variable A B C D
date
2000-01-03 0.938225 -2.271265 0.238417 -4.209138
2000-01-04 -0.565727 2.424224 -2.088472 -0.989859
2000-01-05 -3.018117 -0.346429 -1.723698 2.143608
Note that this returns a view on the underlying data in the case where the data are homogeneously-typed.
Reshaping by stacking and unstacking¶
Closely related to the pivot function are the related stack and unstack functions currently available on Series and DataFrame. These functions are designed to work together with MultiIndex objects (see the section on hierarchical indexing). Here are essentially what these functions do:
- stack: “pivot” a level of the (possibly hierarchical) column labels, returning a DataFrame with an index with a new inner-most level of row labels.
- unstack: inverse operation from stack: “pivot” a level of the (possibly hierarchical) row index to the column axis, producing a reshaped DataFrame with a new inner-most level of column labels.
The clearest way to explain is by example. Let’s take a prior example data set from the hierarchical indexing section:
In [8]: tuples = list(zip(*[['bar', 'bar', 'baz', 'baz',
...: 'foo', 'foo', 'qux', 'qux'],
...: ['one', 'two', 'one', 'two',
...: 'one', 'two', 'one', 'two']]))
...:
In [9]: index = MultiIndex.from_tuples(tuples, names=['first', 'second'])
In [10]: df = DataFrame(randn(8, 2), index=index, columns=['A', 'B'])
In [11]: df2 = df[:4]
In [12]: df2
Out[12]:
A B
first second
bar one 0.721555 -0.706771
two -1.039575 0.271860
baz one -0.424972 0.567020
two 0.276232 -1.087401
The stack function “compresses” a level in the DataFrame’s columns to produce either:
- A Series, in the case of a simple column Index
- A DataFrame, in the case of a MultiIndex in the columns
If the columns have a MultiIndex, you can choose which level to stack. The stacked level becomes the new lowest level in a MultiIndex on the columns:
In [13]: stacked = df2.stack()
In [14]: stacked
Out[14]:
first second
bar one A 0.721555
B -0.706771
two A -1.039575
B 0.271860
baz one A -0.424972
B 0.567020
two A 0.276232
B -1.087401
dtype: float64
With a “stacked” DataFrame or Series (having a MultiIndex as the index), the inverse operation of stack is unstack, which by default unstacks the last level:
In [15]: stacked.unstack()
Out[15]:
A B
first second
bar one 0.721555 -0.706771
two -1.039575 0.271860
baz one -0.424972 0.567020
two 0.276232 -1.087401
In [16]: stacked.unstack(1)
Out[16]:
second one two
first
bar A 0.721555 -1.039575
B -0.706771 0.271860
baz A -0.424972 0.276232
B 0.567020 -1.087401
In [17]: stacked.unstack(0)
Out[17]:
first bar baz
second
one A 0.721555 -0.424972
B -0.706771 0.567020
two A -1.039575 0.276232
B 0.271860 -1.087401
If the indexes have names, you can use the level names instead of specifying the level numbers:
In [18]: stacked.unstack('second')
Out[18]:
second one two
first
bar A 0.721555 -1.039575
B -0.706771 0.271860
baz A -0.424972 0.276232
B 0.567020 -1.087401
Notice that the stack and unstack methods implicitly sort the index levels involved. Hence a call to stack and then unstack, or viceversa, will result in a sorted copy of the original DataFrame or Series:
In [19]: index = MultiIndex.from_product([[2,1], ['a', 'b']])
In [20]: df = DataFrame(randn(4), index=index, columns=['A'])
In [21]: df
Out[21]:
A
2 a -0.370647
b -1.157892
1 a -1.344312
b 0.844885
In [22]: all(df.unstack().stack() == df.sort())
Out[22]: True
while the above code will raise a TypeError if the call to sort is removed.
Multiple Levels¶
You may also stack or unstack more than one level at a time by passing a list of levels, in which case the end result is as if each level in the list were processed individually.
In [23]: columns = MultiIndex.from_tuples([
....: ('A', 'cat', 'long'), ('B', 'cat', 'long'),
....: ('A', 'dog', 'short'), ('B', 'dog', 'short')
....: ],
....: names=['exp', 'animal', 'hair_length']
....: )
....:
In [24]: df = DataFrame(randn(4, 4), columns=columns)
In [25]: df
Out[25]:
exp A B A B
animal cat cat dog dog
hair_length long long short short
0 1.075770 -0.109050 1.643563 -1.469388
1 0.357021 -0.674600 -1.776904 -0.968914
2 -1.294524 0.413738 0.276662 -0.472035
3 -0.013960 -0.362543 -0.006154 -0.923061
In [26]: df.stack(level=['animal', 'hair_length'])
Out[26]:
exp A B
animal hair_length
0 cat long 1.075770 -0.109050
dog short 1.643563 -1.469388
1 cat long 0.357021 -0.674600
dog short -1.776904 -0.968914
2 cat long -1.294524 0.413738
dog short 0.276662 -0.472035
3 cat long -0.013960 -0.362543
dog short -0.006154 -0.923061
The list of levels can contain either level names or level numbers (but not a mixture of the two).
# df.stack(level=['animal', 'hair_length'])
# from above is equivalent to:
In [27]: df.stack(level=[1, 2])
Out[27]:
exp A B
animal hair_length
0 cat long 1.075770 -0.109050
dog short 1.643563 -1.469388
1 cat long 0.357021 -0.674600
dog short -1.776904 -0.968914
2 cat long -1.294524 0.413738
dog short 0.276662 -0.472035
3 cat long -0.013960 -0.362543
dog short -0.006154 -0.923061
Missing Data¶
These functions are intelligent about handling missing data and do not expect each subgroup within the hierarchical index to have the same set of labels. They also can handle the index being unsorted (but you can make it sorted by calling sortlevel, of course). Here is a more complex example:
In [28]: columns = MultiIndex.from_tuples([('A', 'cat'), ('B', 'dog'),
....: ('B', 'cat'), ('A', 'dog')],
....: names=['exp', 'animal'])
....:
In [29]: index = MultiIndex.from_product([('bar', 'baz', 'foo', 'qux'), ('one', 'two')],
....: names=['first', 'second'])
....:
In [30]: df = DataFrame(randn(8, 4), index=index, columns=columns)
In [31]: df2 = df.ix[[0, 1, 2, 4, 5, 7]]
In [32]: df2
Out[32]:
exp A B A
animal cat dog cat dog
first second
bar one 0.895717 0.805244 -1.206412 2.565646
two 1.431256 1.340309 -1.170299 -0.226169
baz one 0.410835 0.813850 0.132003 -0.827317
foo one -1.413681 1.607920 1.024180 0.569605
two 0.875906 -2.211372 0.974466 -2.006747
qux two -1.226825 0.769804 -1.281247 -0.727707
As mentioned above, stack can be called with a level argument to select which level in the columns to stack:
In [33]: df2.stack('exp')
Out[33]:
animal cat dog
first second exp
bar one A 0.895717 2.565646
B -1.206412 0.805244
two A 1.431256 -0.226169
B -1.170299 1.340309
baz one A 0.410835 -0.827317
B 0.132003 0.813850
foo one A -1.413681 0.569605
B 1.024180 1.607920
two A 0.875906 -2.006747
B 0.974466 -2.211372
qux two A -1.226825 -0.727707
B -1.281247 0.769804
In [34]: df2.stack('animal')
Out[34]:
exp A B
first second animal
bar one cat 0.895717 -1.206412
dog 2.565646 0.805244
two cat 1.431256 -1.170299
dog -0.226169 1.340309
baz one cat 0.410835 0.132003
dog -0.827317 0.813850
foo one cat -1.413681 1.024180
dog 0.569605 1.607920
two cat 0.875906 0.974466
dog -2.006747 -2.211372
qux two cat -1.226825 -1.281247
dog -0.727707 0.769804
With a MultiIndex¶
Unstacking when the columns are a MultiIndex is also careful about doing the right thing:
In [35]: df[:3].unstack(0)
Out[35]:
exp A B A \
animal cat dog cat dog
first bar baz bar baz bar baz bar
second
one 0.895717 0.410835 0.805244 0.81385 -1.206412 0.132003 2.565646
two 1.431256 NaN 1.340309 NaN -1.170299 NaN -0.226169
exp
animal
first baz
second
one -0.827317
two NaN
In [36]: df2.unstack(1)
Out[36]:
exp A B A \
animal cat dog cat dog
second one two one two one two one
first
bar 0.895717 1.431256 0.805244 1.340309 -1.206412 -1.170299 2.565646
baz 0.410835 NaN 0.813850 NaN 0.132003 NaN -0.827317
foo -1.413681 0.875906 1.607920 -2.211372 1.024180 0.974466 0.569605
qux NaN -1.226825 NaN 0.769804 NaN -1.281247 NaN
exp
animal
second two
first
bar -0.226169
baz NaN
foo -2.006747
qux -0.727707
Reshaping by Melt¶
The melt() function is useful to massage a DataFrame into a format where one or more columns are identifier variables, while all other columns, considered measured variables, are “unpivoted” to the row axis, leaving just two non-identifier columns, “variable” and “value”. The names of those columns can be customized by supplying the var_name and value_name parameters.
For instance,
In [37]: cheese = DataFrame({'first' : ['John', 'Mary'],
....: 'last' : ['Doe', 'Bo'],
....: 'height' : [5.5, 6.0],
....: 'weight' : [130, 150]})
....:
In [38]: cheese
Out[38]:
first height last weight
0 John 5.5 Doe 130
1 Mary 6.0 Bo 150
In [39]: melt(cheese, id_vars=['first', 'last'])
Out[39]:
first last variable value
0 John Doe height 5.5
1 Mary Bo height 6.0
2 John Doe weight 130.0
3 Mary Bo weight 150.0
In [40]: melt(cheese, id_vars=['first', 'last'], var_name='quantity')
Out[40]:
first last quantity value
0 John Doe height 5.5
1 Mary Bo height 6.0
2 John Doe weight 130.0
3 Mary Bo weight 150.0
Another way to transform is to use the wide_to_long panel data convenience function.
In [41]: dft = pd.DataFrame({"A1970" : {0 : "a", 1 : "b", 2 : "c"},
....: "A1980" : {0 : "d", 1 : "e", 2 : "f"},
....: "B1970" : {0 : 2.5, 1 : 1.2, 2 : .7},
....: "B1980" : {0 : 3.2, 1 : 1.3, 2 : .1},
....: "X" : dict(zip(range(3), np.random.randn(3)))
....: })
....:
In [42]: dft["id"] = dft.index
In [43]: dft
Out[43]:
A1970 A1980 B1970 B1980 X id
0 a d 2.5 3.2 -0.121306 0
1 b e 1.2 1.3 -0.097883 1
2 c f 0.7 0.1 0.695775 2
In [44]: pd.wide_to_long(dft, ["A", "B"], i="id", j="year")
Out[44]:
X A B
id year
0 1970 -0.121306 a 2.5
1 1970 -0.097883 b 1.2
2 1970 0.695775 c 0.7
0 1980 -0.121306 d 3.2
1 1980 -0.097883 e 1.3
2 1980 0.695775 f 0.1
Combining with stats and GroupBy¶
It should be no shock that combining pivot / stack / unstack with GroupBy and the basic Series and DataFrame statistical functions can produce some very expressive and fast data manipulations.
In [45]: df
Out[45]:
exp A B A
animal cat dog cat dog
first second
bar one 0.895717 0.805244 -1.206412 2.565646
two 1.431256 1.340309 -1.170299 -0.226169
baz one 0.410835 0.813850 0.132003 -0.827317
two -0.076467 -1.187678 1.130127 -1.436737
foo one -1.413681 1.607920 1.024180 0.569605
two 0.875906 -2.211372 0.974466 -2.006747
qux one -0.410001 -0.078638 0.545952 -1.219217
two -1.226825 0.769804 -1.281247 -0.727707
In [46]: df.stack().mean(1).unstack()
Out[46]:
animal cat dog
first second
bar one -0.155347 1.685445
two 0.130479 0.557070
baz one 0.271419 -0.006733
two 0.526830 -1.312207
foo one -0.194750 1.088763
two 0.925186 -2.109060
qux one 0.067976 -0.648927
two -1.254036 0.021048
# same result, another way
In [47]: df.groupby(level=1, axis=1).mean()
Out[47]:
animal cat dog
first second
bar one -0.155347 1.685445
two 0.130479 0.557070
baz one 0.271419 -0.006733
two 0.526830 -1.312207
foo one -0.194750 1.088763
two 0.925186 -2.109060
qux one 0.067976 -0.648927
two -1.254036 0.021048
In [48]: df.stack().groupby(level=1).mean()
Out[48]:
exp A B
second
one 0.071448 0.455513
two -0.424186 -0.204486
In [49]: df.mean().unstack(0)
Out[49]:
exp A B
animal
cat 0.060843 0.018596
dog -0.413580 0.232430
Pivot tables and cross-tabulations¶
The function pandas.pivot_table can be used to create spreadsheet-style pivot tables. See the cookbook for some advanced strategies
It takes a number of arguments
- data: A DataFrame object
- values: a column or a list of columns to aggregate
- index: a column, Grouper, array which has the same length as data, or list of them. Keys to group by on the pivot table index. If an array is passed, it is being used as the same manner as column values.
- columns: a column, Grouper, array which has the same length as data, or list of them. Keys to group by on the pivot table column. If an array is passed, it is being used as the same manner as column values.
- aggfunc: function to use for aggregation, defaulting to numpy.mean
Consider a data set like this:
In [50]: import datetime
In [51]: df = DataFrame({'A' : ['one', 'one', 'two', 'three'] * 6,
....: 'B' : ['A', 'B', 'C'] * 8,
....: 'C' : ['foo', 'foo', 'foo', 'bar', 'bar', 'bar'] * 4,
....: 'D' : np.random.randn(24),
....: 'E' : np.random.randn(24),
....: 'F' : [datetime.datetime(2013, i, 1) for i in range(1, 13)] +
....: [datetime.datetime(2013, i, 15) for i in range(1, 13)]})
....:
In [52]: df
Out[52]:
A B C D E F
0 one A foo 0.341734 -0.317441 2013-01-01
1 one B foo 0.959726 -1.236269 2013-02-01
2 two C foo -1.110336 0.896171 2013-03-01
3 three A bar -0.619976 -0.487602 2013-04-01
4 one B bar 0.149748 -0.082240 2013-05-01
5 one C bar -0.732339 -2.182937 2013-06-01
6 two A foo 0.687738 0.380396 2013-07-01
.. ... .. ... ... ... ...
17 one C bar -0.345352 0.206053 2013-06-15
18 two A foo 1.314232 -0.251905 2013-07-15
19 three B foo 0.690579 -2.213588 2013-08-15
20 one C foo 0.995761 1.063327 2013-09-15
21 one A bar 2.396780 1.266143 2013-10-15
22 two B bar 0.014871 0.299368 2013-11-15
23 three C bar 3.357427 -0.863838 2013-12-15
[24 rows x 6 columns]
We can produce pivot tables from this data very easily:
In [53]: pivot_table(df, values='D', index=['A', 'B'], columns=['C'])
Out[53]:
C bar foo
A B
one A 1.120915 -0.514058
B -0.338421 0.002759
C -0.538846 0.699535
three A -1.181568 NaN
B NaN 0.433512
C 0.588783 NaN
two A NaN 1.000985
B 0.158248 NaN
C NaN 0.176180
In [54]: pivot_table(df, values='D', index=['B'], columns=['A', 'C'], aggfunc=np.sum)
Out[54]:
A one three two
C bar foo bar foo bar foo
B
A 2.241830 -1.028115 -2.363137 NaN NaN 2.001971
B -0.676843 0.005518 NaN 0.867024 0.316495 NaN
C -1.077692 1.399070 1.177566 NaN NaN 0.352360
In [55]: pivot_table(df, values=['D','E'], index=['B'], columns=['A', 'C'], aggfunc=np.sum)
Out[55]:
D E \
A one three two one
C bar foo bar foo bar foo bar
B
A 2.241830 -1.028115 -2.363137 NaN NaN 2.001971 2.786113
B -0.676843 0.005518 NaN 0.867024 0.316495 NaN 1.368280
C -1.077692 1.399070 1.177566 NaN NaN 0.352360 -1.976883
A three two
C foo bar foo bar foo
B
A -0.043211 1.922577 NaN NaN 0.128491
B -1.103384 NaN -2.128743 -0.194294 NaN
C 1.495717 -0.263660 NaN NaN 0.872482
The result object is a DataFrame having potentially hierarchical indexes on the rows and columns. If the values column name is not given, the pivot table will include all of the data that can be aggregated in an additional level of hierarchy in the columns:
In [56]: pivot_table(df, index=['A', 'B'], columns=['C'])
Out[56]:
D E
C bar foo bar foo
A B
one A 1.120915 -0.514058 1.393057 -0.021605
B -0.338421 0.002759 0.684140 -0.551692
C -0.538846 0.699535 -0.988442 0.747859
three A -1.181568 NaN 0.961289 NaN
B NaN 0.433512 NaN -1.064372
C 0.588783 NaN -0.131830 NaN
two A NaN 1.000985 NaN 0.064245
B 0.158248 NaN -0.097147 NaN
C NaN 0.176180 NaN 0.436241
Also, you can use Grouper for index and columns keywords. For detail of Grouper, see Grouping with a Grouper specification.
In [57]: pivot_table(df, values='D', index=Grouper(freq='M', key='F'), columns='C')
Out[57]:
C bar foo
F
2013-01-31 NaN -0.514058
2013-02-28 NaN 0.002759
2013-03-31 NaN 0.176180
2013-04-30 -1.181568 NaN
2013-05-31 -0.338421 NaN
2013-06-30 -0.538846 NaN
2013-07-31 NaN 1.000985
2013-08-31 NaN 0.433512
2013-09-30 NaN 0.699535
2013-10-31 1.120915 NaN
2013-11-30 0.158248 NaN
2013-12-31 0.588783 NaN
You can render a nice output of the table omitting the missing values by calling to_string if you wish:
In [58]: table = pivot_table(df, index=['A', 'B'], columns=['C'])
In [59]: print(table.to_string(na_rep=''))
D E
C bar foo bar foo
A B
one A 1.120915 -0.514058 1.393057 -0.021605
B -0.338421 0.002759 0.684140 -0.551692
C -0.538846 0.699535 -0.988442 0.747859
three A -1.181568 0.961289
B 0.433512 -1.064372
C 0.588783 -0.131830
two A 1.000985 0.064245
B 0.158248 -0.097147
C 0.176180 0.436241
Note that pivot_table is also available as an instance method on DataFrame.
Cross tabulations¶
Use the crosstab function to compute a cross-tabulation of two (or more) factors. By default crosstab computes a frequency table of the factors unless an array of values and an aggregation function are passed.
It takes a number of arguments
- index: array-like, values to group by in the rows
- columns: array-like, values to group by in the columns
- values: array-like, optional, array of values to aggregate according to the factors
- aggfunc: function, optional, If no values array is passed, computes a frequency table
- rownames: sequence, default None, must match number of row arrays passed
- colnames: sequence, default None, if passed, must match number of column arrays passed
- margins: boolean, default False, Add row/column margins (subtotals)
Any Series passed will have their name attributes used unless row or column names for the cross-tabulation are specified
For example:
In [60]: foo, bar, dull, shiny, one, two = 'foo', 'bar', 'dull', 'shiny', 'one', 'two'
In [61]: a = np.array([foo, foo, bar, bar, foo, foo], dtype=object)
In [62]: b = np.array([one, one, two, one, two, one], dtype=object)
In [63]: c = np.array([dull, dull, shiny, dull, dull, shiny], dtype=object)
In [64]: crosstab(a, [b, c], rownames=['a'], colnames=['b', 'c'])
Out[64]:
b one two
c dull shiny dull shiny
a
bar 1 0 0 1
foo 2 1 1 0
Adding margins (partial aggregates)¶
If you pass margins=True to pivot_table, special All columns and rows will be added with partial group aggregates across the categories on the rows and columns:
In [65]: df.pivot_table(index=['A', 'B'], columns='C', margins=True, aggfunc=np.std)
Out[65]:
D E
C bar foo All bar foo All
A B
one A 1.804346 1.210272 1.569879 0.179483 0.418374 0.858005
B 0.690376 1.353355 0.898998 1.083825 0.968138 1.101401
C 0.273641 0.418926 0.771139 1.689271 0.446140 1.422136
three A 0.794212 NaN 0.794212 2.049040 NaN 2.049040
B NaN 0.363548 0.363548 NaN 1.625237 1.625237
C 3.915454 NaN 3.915454 1.035215 NaN 1.035215
two A NaN 0.442998 0.442998 NaN 0.447104 0.447104
B 0.202765 NaN 0.202765 0.560757 NaN 0.560757
C NaN 1.819408 1.819408 NaN 0.650439 0.650439
All 1.556686 0.952552 1.246608 1.250924 0.899904 1.059389
Tiling¶
The cut function computes groupings for the values of the input array and is often used to transform continuous variables to discrete or categorical variables:
In [66]: ages = np.array([10, 15, 13, 12, 23, 25, 28, 59, 60])
In [67]: cut(ages, bins=3)
Out[67]:
[(9.95, 26.667], (9.95, 26.667], (9.95, 26.667], (9.95, 26.667], (9.95, 26.667], (9.95, 26.667], (26.667, 43.333], (43.333, 60], (43.333, 60]]
Categories (3, object): [(9.95, 26.667] < (26.667, 43.333] < (43.333, 60]]
If the bins keyword is an integer, then equal-width bins are formed. Alternatively we can specify custom bin-edges:
In [68]: cut(ages, bins=[0, 18, 35, 70])
Out[68]:
[(0, 18], (0, 18], (0, 18], (0, 18], (18, 35], (18, 35], (18, 35], (35, 70], (35, 70]]
Categories (3, object): [(0, 18] < (18, 35] < (35, 70]]
Computing indicator / dummy variables¶
To convert a categorical variable into a “dummy” or “indicator” DataFrame, for example a column in a DataFrame (a Series) which has k distinct values, can derive a DataFrame containing k columns of 1s and 0s:
In [69]: df = DataFrame({'key': list('bbacab'), 'data1': range(6)})
In [70]: get_dummies(df['key'])
Out[70]:
a b c
0 0 1 0
1 0 1 0
2 1 0 0
3 0 0 1
4 1 0 0
5 0 1 0
Sometimes it’s useful to prefix the column names, for example when merging the result with the original DataFrame:
In [71]: dummies = get_dummies(df['key'], prefix='key')
In [72]: dummies
Out[72]:
key_a key_b key_c
0 0 1 0
1 0 1 0
2 1 0 0
3 0 0 1
4 1 0 0
5 0 1 0
In [73]: df[['data1']].join(dummies)
Out[73]:
data1 key_a key_b key_c
0 0 0 1 0
1 1 0 1 0
2 2 1 0 0
3 3 0 0 1
4 4 1 0 0
5 5 0 1 0
This function is often used along with discretization functions like cut:
In [74]: values = randn(10)
In [75]: values
Out[75]:
array([ 0.4082, -1.0481, -0.0257, -0.9884, 0.0941, 1.2627, 1.29 ,
0.0824, -0.0558, 0.5366])
In [76]: bins = [0, 0.2, 0.4, 0.6, 0.8, 1]
In [77]: get_dummies(cut(values, bins))
Out[77]:
(0, 0.2] (0.2, 0.4] (0.4, 0.6] (0.6, 0.8] (0.8, 1]
0 0 0 1 0 0
1 0 0 0 0 0
2 0 0 0 0 0
3 0 0 0 0 0
4 1 0 0 0 0
5 0 0 0 0 0
6 0 0 0 0 0
7 1 0 0 0 0
8 0 0 0 0 0
9 0 0 1 0 0
See also Series.str.get_dummies.
New in version 0.15.0.
get_dummies() also accepts a DataFrame. By default all categorical variables (categorical in the statistical sense, those with object or categorical dtype) are encoded as dummy variables.
In [78]: df = pd.DataFrame({'A': ['a', 'b', 'a'], 'B': ['c', 'c', 'b'],
....: 'C': [1, 2, 3]})
....:
In [79]: pd.get_dummies(df)
Out[79]:
C A_a A_b B_b B_c
0 1 1 0 0 1
1 2 0 1 0 1
2 3 1 0 1 0
All non-object columns are included untouched in the output.
You can control the columns that are encoded with the columns keyword.
In [80]: pd.get_dummies(df, columns=['A'])
Out[80]:
B C A_a A_b
0 c 1 1 0
1 c 2 0 1
2 b 3 1 0
Notice that the B column is still included in the output, it just hasn’t been encoded. You can drop B before calling get_dummies if you don’t want to include it in the output.
As with the Series version, you can pass values for the prefix and prefix_sep. By default the column name is used as the prefix, and ‘_’ as the prefix separator. You can specify prefix and prefix_sep in 3 ways
- string: Use the same value for prefix or prefix_sep for each column to be encoded
- list: Must be the same length as the number of columns being encoded.
- dict: Mapping column name to prefix
In [81]: simple = pd.get_dummies(df, prefix='new_prefix')
In [82]: simple
Out[82]:
C new_prefix_a new_prefix_b new_prefix_b new_prefix_c
0 1 1 0 0 1
1 2 0 1 0 1
2 3 1 0 1 0
In [83]: from_list = pd.get_dummies(df, prefix=['from_A', 'from_B'])
In [84]: from_list
Out[84]:
C from_A_a from_A_b from_B_b from_B_c
0 1 1 0 0 1
1 2 0 1 0 1
2 3 1 0 1 0
In [85]: from_dict = pd.get_dummies(df, prefix={'B': 'from_B', 'A': 'from_A'})
In [86]: from_dict
Out[86]:
C from_A_a from_A_b from_B_b from_B_c
0 1 1 0 0 1
1 2 0 1 0 1
2 3 1 0 1 0
Factorizing values¶
To encode 1-d values as an enumerated type use factorize:
In [87]: x = pd.Series(['A', 'A', np.nan, 'B', 3.14, np.inf])
In [88]: x
Out[88]:
0 A
1 A
2 NaN
3 B
4 3.14
5 inf
dtype: object
In [89]: labels, uniques = pd.factorize(x)
In [90]: labels
Out[90]: array([ 0, 0, -1, 1, 2, 3])
In [91]: uniques
Out[91]: Index([u'A', u'B', 3.14, inf], dtype='object')
Note that factorize is similar to numpy.unique, but differs in its handling of NaN:
Note
The following numpy.unique will fail under Python 3 with a TypeError because of an ordering bug. See also Here
In [92]: pd.factorize(x, sort=True)
Out[92]:
(array([ 2, 2, -1, 3, 0, 1]),
Index([3.14, inf, u'A', u'B'], dtype='object'))
In [93]: np.unique(x, return_inverse=True)[::-1]
Out[93]: (array([3, 3, 0, 4, 1, 2]), array([nan, 3.14, inf, 'A', 'B'], dtype=object))
Note
If you just want to handle one column as a categorical variable (like R’s factor), you can use df["cat_col"] = pd.Categorical(df["col"]) or df["cat_col"] = df["col"].astype("category"). For full docs on Categorical, see the Categorical introduction and the API documentation. This feature was introduced in version 0.15.