.. currentmodule:: pandas
.. ipython:: python :suppress: import numpy as np from pandas import * randn = np.random.randn np.set_printoptions(precision=4, suppress=True) from pandas.compat import lrange options.display.max_rows=15
Here we discuss a lot of the essential functionality common to the pandas data structures. Here's how to create some of the objects used in the examples from the previous section:
.. ipython:: python
index = date_range('1/1/2000', periods=8)
s = Series(randn(5), index=['a', 'b', 'c', 'd', 'e'])
df = DataFrame(randn(8, 3), index=index,
columns=['A', 'B', 'C'])
wp = Panel(randn(2, 5, 4), items=['Item1', 'Item2'],
major_axis=date_range('1/1/2000', periods=5),
minor_axis=['A', 'B', 'C', 'D'])
To view a small sample of a Series or DataFrame object, use the head and
tail methods. The default number of elements to display is five, but you
may pass a custom number.
.. ipython:: python long_series = Series(randn(1000)) long_series.head() long_series.tail(3)
pandas objects have a number of attributes enabling you to access the metadata
- shape: gives the axis dimensions of the object, consistent with ndarray
- Axis labels
- Series: index (only axis)
- DataFrame: index (rows) and columns
- Panel: items, major_axis, and minor_axis
Note, these attributes can be safely assigned to!
.. ipython:: python df[:2] df.columns = [x.lower() for x in df.columns] df
To get the actual data inside a data structure, one need only access the values property:
.. ipython:: python
s.values
df.values
wp.values
If a DataFrame or Panel contains homogeneously-typed data, the ndarray can actually be modified in-place, and the changes will be reflected in the data structure. For heterogeneous data (e.g. some of the DataFrame's columns are not all the same dtype), this will not be the case. The values attribute itself, unlike the axis labels, cannot be assigned to.
Note
When working with heterogeneous data, the dtype of the resulting ndarray will be chosen to accommodate all of the data involved. For example, if strings are involved, the result will be of object dtype. If there are only floats and integers, the resulting array will be of float dtype.
pandas has support for accelerating certain types of binary numerical and boolean operations using
the numexpr library (starting in 0.11.0) and the bottleneck libraries.
These libraries are especially useful when dealing with large data sets, and provide large
speedups. numexpr uses smart chunking, caching, and multiple cores. bottleneck is
a set of specialized cython routines that are especially fast when dealing with arrays that have
nans.
Here is a sample (using 100 column x 100,000 row DataFrames):
| Operation | 0.11.0 (ms) | Prior Version (ms) | Ratio to Prior |
|---|---|---|---|
df1 > df2 |
13.32 | 125.35 | 0.1063 |
df1 * df2 |
21.71 | 36.63 | 0.5928 |
df1 + df2 |
22.04 | 36.50 | 0.6039 |
You are highly encouraged to install both libraries. See the section :ref:`Recommended Dependencies <install.recommended_dependencies>` for more installation info.
With binary operations between pandas data structures, there are two key points of interest:
- Broadcasting behavior between higher- (e.g. DataFrame) and lower-dimensional (e.g. Series) objects.
- Missing data in computations
We will demonstrate how to manage these issues independently, though they can be handled simultaneously.
DataFrame has the methods add, sub, mul, div and related functions radd, rsub, ... for carrying out binary operations. For broadcasting behavior, Series input is of primary interest. Using these functions, you can use to either match on the index or columns via the axis keyword:
.. ipython:: python
df = DataFrame({'one' : Series(randn(3), index=['a', 'b', 'c']),
'two' : Series(randn(4), index=['a', 'b', 'c', 'd']),
'three' : Series(randn(3), index=['b', 'c', 'd'])})
df
row = df.ix[1]
column = df['two']
df.sub(row, axis='columns')
df.sub(row, axis=1)
df.sub(column, axis='index')
df.sub(column, axis=0)
.. ipython:: python :suppress: df_orig = df
Furthermore you can align a level of a multi-indexed DataFrame with a Series.
.. ipython:: python
dfmi = df.copy()
dfmi.index = MultiIndex.from_tuples([(1,'a'),(1,'b'),(1,'c'),(2,'a')],
names=['first','second'])
dfmi.sub(column, axis=0, level='second')
With Panel, describing the matching behavior is a bit more difficult, so the arithmetic methods instead (and perhaps confusingly?) give you the option to specify the broadcast axis. For example, suppose we wished to demean the data over a particular axis. This can be accomplished by taking the mean over an axis and broadcasting over the same axis:
.. ipython:: python major_mean = wp.mean(axis='major') major_mean wp.sub(major_mean, axis='major')
And similarly for axis="items" and axis="minor".
Note
I could be convinced to make the axis argument in the DataFrame methods match the broadcasting behavior of Panel. Though it would require a transition period so users can change their code...
In Series and DataFrame (though not yet in Panel), the arithmetic functions
have the option of inputting a fill_value, namely a value to substitute when
at most one of the values at a location are missing. For example, when adding
two DataFrame objects, you may wish to treat NaN as 0 unless both DataFrames
are missing that value, in which case the result will be NaN (you can later
replace NaN with some other value using fillna if you wish).
.. ipython:: python :suppress: df2 = df.copy() df2['three']['a'] = 1.
.. ipython:: python df df2 df + df2 df.add(df2, fill_value=0)
Starting in v0.8, pandas introduced binary comparison methods eq, ne, lt, gt, le, and ge to Series and DataFrame whose behavior is analogous to the binary arithmetic operations described above:
.. ipython:: python df.gt(df2) df2.ne(df)
These operations produce a pandas object the same type as the left-hand-side input
that if of dtype bool. These boolean objects can be used in indexing operations,
see :ref:`here<indexing.boolean>`
You can apply the reductions: empty, any(), all(), and bool() to provide a
way to summarize a boolean result.
.. ipython:: python (df>0).all() (df>0).any()
You can reduce to a final boolean value.
.. ipython:: python (df>0).any().any()
You can test if a pandas object is empty, via the empty property.
.. ipython:: python
df.empty
DataFrame(columns=list('ABC')).empty
To evaluate single-element pandas objects in a boolean context, use the method .bool():
.. ipython:: python Series([True]).bool() Series([False]).bool() DataFrame([[True]]).bool() DataFrame([[False]]).bool()
Warning
You might be tempted to do the following:
>>>if df:
...Or
>>> df and df2These both will raise as you are trying to compare multiple values.
ValueError: The truth value of an array is ambiguous. Use a.empty, a.any() or a.all().See :ref:`gotchas<gotchas.truth>` for a more detailed discussion.
Often you may find there is more than one way to compute the same
result. As a simple example, consider df+df and df*2. To test
that these two computations produce the same result, given the tools
shown above, you might imagine using (df+df == df*2).all(). But in
fact, this expression is False:
.. ipython:: python df+df == df*2 (df+df == df*2).all()
Notice that the boolean DataFrame df+df == df*2 contains some False values!
That is because NaNs do not compare as equals:
.. ipython:: python np.nan == np.nan
So, as of v0.13.1, NDFrames (such as Series, DataFrames, and Panels)
have an equals method for testing equality, with NaNs in corresponding
locations treated as equal.
.. ipython:: python (df+df).equals(df*2)
Note that the Series or DataFrame index needs to be in the same order for equality to be True:
.. ipython:: python
df1 = DataFrame({'col':['foo', 0, np.nan]})
df2 = DataFrame({'col':[np.nan, 0, 'foo']}, index=[2,1,0])
df1.equals(df2)
df1.equals(df2.sort())
A problem occasionally arising is the combination of two similar data sets
where values in one are preferred over the other. An example would be two data
series representing a particular economic indicator where one is considered to
be of "higher quality". However, the lower quality series might extend further
back in history or have more complete data coverage. As such, we would like to
combine two DataFrame objects where missing values in one DataFrame are
conditionally filled with like-labeled values from the other DataFrame. The
function implementing this operation is combine_first, which we illustrate:
.. ipython:: python
df1 = DataFrame({'A' : [1., np.nan, 3., 5., np.nan],
'B' : [np.nan, 2., 3., np.nan, 6.]})
df2 = DataFrame({'A' : [5., 2., 4., np.nan, 3., 7.],
'B' : [np.nan, np.nan, 3., 4., 6., 8.]})
df1
df2
df1.combine_first(df2)
The combine_first method above calls the more general DataFrame method
combine. This method takes another DataFrame and a combiner function,
aligns the input DataFrame and then passes the combiner function pairs of
Series (i.e., columns whose names are the same).
So, for instance, to reproduce combine_first as above:
.. ipython:: python combiner = lambda x, y: np.where(isnull(x), y, x) df1.combine(df2, combiner)
A large number of methods for computing descriptive statistics and other related operations on :ref:`Series <api.series.stats>`, :ref:`DataFrame <api.dataframe.stats>`, and :ref:`Panel <api.panel.stats>`. Most of these are aggregations (hence producing a lower-dimensional result) like sum, mean, and quantile, but some of them, like cumsum and cumprod, produce an object of the same size. Generally speaking, these methods take an axis argument, just like ndarray.{sum, std, ...}, but the axis can be specified by name or integer:
- Series: no axis argument needed
- DataFrame: "index" (axis=0, default), "columns" (axis=1)
- Panel: "items" (axis=0), "major" (axis=1, default), "minor" (axis=2)
For example:
.. ipython:: python df df.mean(0) df.mean(1)
All such methods have a skipna option signaling whether to exclude missing
data (True by default):
.. ipython:: python df.sum(0, skipna=False) df.sum(axis=1, skipna=True)
Combined with the broadcasting / arithmetic behavior, one can describe various statistical procedures, like standardization (rendering data zero mean and standard deviation 1), very concisely:
.. ipython:: python ts_stand = (df - df.mean()) / df.std() ts_stand.std() xs_stand = df.sub(df.mean(1), axis=0).div(df.std(1), axis=0) xs_stand.std(1)
Note that methods like cumsum and cumprod preserve the location of NA values:
.. ipython:: python df.cumsum()
Here is a quick reference summary table of common functions. Each also takes an
optional level parameter which applies only if the object has a
:ref:`hierarchical index<advanced.hierarchical>`.
| Function | Description |
|---|---|
count |
Number of non-null observations |
sum |
Sum of values |
mean |
Mean of values |
mad |
Mean absolute deviation |
median |
Arithmetic median of values |
min |
Minimum |
max |
Maximum |
mode |
Mode |
abs |
Absolute Value |
prod |
Product of values |
std |
Unbiased standard deviation |
var |
Unbiased variance |
sem |
Unbiased standard error of the mean |
skew |
Unbiased skewness (3rd moment) |
kurt |
Unbiased kurtosis (4th moment) |
quantile |
Sample quantile (value at %) |
cumsum |
Cumulative sum |
cumprod |
Cumulative product |
cummax |
Cumulative maximum |
cummin |
Cumulative minimum |
Note that by chance some NumPy methods, like mean, std, and sum,
will exclude NAs on Series input by default:
.. ipython:: python np.mean(df['one']) np.mean(df['one'].values)
Series also has a method nunique which will return the number of unique
non-null values:
.. ipython:: python series = Series(randn(500)) series[20:500] = np.nan series[10:20] = 5 series.nunique()
There is a convenient describe function which computes a variety of summary
statistics about a Series or the columns of a DataFrame (excluding NAs of
course):
.. ipython:: python
series = Series(randn(1000))
series[::2] = np.nan
series.describe()
frame = DataFrame(randn(1000, 5), columns=['a', 'b', 'c', 'd', 'e'])
frame.ix[::2] = np.nan
frame.describe()
You can select specific percentiles to include in the output:
.. ipython:: python
series.describe(percentiles=[.05, .25, .75, .95])
By default, the median is always included.
For a non-numerical Series object, describe will give a simple summary of the number of unique values and most frequently occurring values:
.. ipython:: python s = Series(['a', 'a', 'b', 'b', 'a', 'a', np.nan, 'c', 'd', 'a']) s.describe()
Note that on a mixed-type DataFrame object, describe will restrict the summary to include only numerical columns or, if none are, only categorical columns:
.. ipython:: python
frame = DataFrame({'a': ['Yes', 'Yes', 'No', 'No'], 'b': range(4)})
frame.describe()
This behaviour can be controlled by providing a list of types as include/exclude
arguments. The special value all can also be used:
.. ipython:: python
frame.describe(include=['object'])
frame.describe(include=['number'])
frame.describe(include='all')
That feature relies on :ref:`select_dtypes <basics.selectdtypes>`. Refer to there for details about accepted inputs.
The idxmin and idxmax functions on Series and DataFrame compute the
index labels with the minimum and maximum corresponding values:
.. ipython:: python s1 = Series(randn(5)) s1 s1.idxmin(), s1.idxmax() df1 = DataFrame(randn(5,3), columns=['A','B','C']) df1 df1.idxmin(axis=0) df1.idxmax(axis=1)
When there are multiple rows (or columns) matching the minimum or maximum
value, idxmin and idxmax return the first matching index:
.. ipython:: python
df3 = DataFrame([2, 1, 1, 3, np.nan], columns=['A'], index=list('edcba'))
df3
df3['A'].idxmin()
Note
idxmin and idxmax are called argmin and argmax in NumPy.
The value_counts Series method and top-level function computes a histogram
of a 1D array of values. It can also be used as a function on regular arrays:
.. ipython:: python data = np.random.randint(0, 7, size=50) data s = Series(data) s.value_counts() value_counts(data)
Similarly, you can get the most frequently occurring value(s) (the mode) of the values in a Series or DataFrame:
.. ipython:: python
s5 = Series([1, 1, 3, 3, 3, 5, 5, 7, 7, 7])
s5.mode()
df5 = DataFrame({"A": np.random.randint(0, 7, size=50),
"B": np.random.randint(-10, 15, size=50)})
df5.mode()
Continuous values can be discretized using the cut (bins based on values)
and qcut (bins based on sample quantiles) functions:
.. ipython:: python arr = np.random.randn(20) factor = cut(arr, 4) factor factor = cut(arr, [-5, -1, 0, 1, 5]) factor
qcut computes sample quantiles. For example, we could slice up some
normally distributed data into equal-size quartiles like so:
.. ipython:: python arr = np.random.randn(30) factor = qcut(arr, [0, .25, .5, .75, 1]) factor value_counts(factor)
We can also pass infinite values to define the bins:
.. ipython:: python arr = np.random.randn(20) factor = cut(arr, [-np.inf, 0, np.inf]) factor
Arbitrary functions can be applied along the axes of a DataFrame or Panel
using the apply method, which, like the descriptive statistics methods,
take an optional axis argument:
.. ipython:: python df.apply(np.mean) df.apply(np.mean, axis=1) df.apply(lambda x: x.max() - x.min()) df.apply(np.cumsum) df.apply(np.exp)
Depending on the return type of the function passed to apply, the result
will either be of lower dimension or the same dimension.
apply combined with some cleverness can be used to answer many questions
about a data set. For example, suppose we wanted to extract the date where the
maximum value for each column occurred:
.. ipython:: python
tsdf = DataFrame(randn(1000, 3), columns=['A', 'B', 'C'],
index=date_range('1/1/2000', periods=1000))
tsdf.apply(lambda x: x.idxmax())
You may also pass additional arguments and keyword arguments to the apply
method. For instance, consider the following function you would like to apply:
def subtract_and_divide(x, sub, divide=1):
return (x - sub) / divideYou may then apply this function as follows:
df.apply(subtract_and_divide, args=(5,), divide=3)Another useful feature is the ability to pass Series methods to carry out some Series operation on each column or row:
.. ipython:: python
:suppress:
tsdf = DataFrame(randn(10, 3), columns=['A', 'B', 'C'],
index=date_range('1/1/2000', periods=10))
tsdf.values[3:7] = np.nan
.. ipython:: python tsdf tsdf.apply(Series.interpolate)
Finally, apply takes an argument raw which is False by default, which
converts each row or column into a Series before applying the function. When
set to True, the passed function will instead receive an ndarray object, which
has positive performance implications if you do not need the indexing
functionality.
.. seealso:: The section on :ref:`GroupBy <groupby>` demonstrates related, flexible functionality for grouping by some criterion, applying, and combining the results into a Series, DataFrame, etc.
Since not all functions can be vectorized (accept NumPy arrays and return
another array or value), the methods applymap on DataFrame and analogously
map on Series accept any Python function taking a single value and
returning a single value. For example:
.. ipython:: python :suppress: df4 = df_orig.copy()
.. ipython:: python df4 f = lambda x: len(str(x)) df4['one'].map(f) df4.applymap(f)
Series.map has an additional feature which is that it can be used to easily
"link" or "map" values defined by a secondary series. This is closely related
to :ref:`merging/joining functionality <merging>`:
.. ipython:: python
s = Series(['six', 'seven', 'six', 'seven', 'six'],
index=['a', 'b', 'c', 'd', 'e'])
t = Series({'six' : 6., 'seven' : 7.})
s
s.map(t)
Applying with a Panel will pass a Series to the applied function. If the applied
function returns a Series, the result of the application will be a Panel. If the applied function
reduces to a scalar, the result of the application will be a DataFrame.
Note
Prior to 0.13.1 apply on a Panel would only work on ufuncs (e.g. np.sum/np.max).
.. ipython:: python import pandas.util.testing as tm panel = tm.makePanel(5) panel panel['ItemA']
A transformational apply.
.. ipython:: python result = panel.apply(lambda x: x*2, axis='items') result result['ItemA']
A reduction operation.
.. ipython:: python panel.apply(lambda x: x.dtype, axis='items')
A similar reduction type operation
.. ipython:: python panel.apply(lambda x: x.sum(), axis='major_axis')
This last reduction is equivalent to
.. ipython:: python
panel.sum('major_axis')
A transformation operation that returns a Panel, but is computing
the z-score across the major_axis.
.. ipython:: python
result = panel.apply(
lambda x: (x-x.mean())/x.std(),
axis='major_axis')
result
result['ItemA']
Apply can also accept multiple axes in the axis argument. This will pass a
DataFrame of the cross-section to the applied function.
.. ipython:: python f = lambda x: ((x.T-x.mean(1))/x.std(1)).T result = panel.apply(f, axis = ['items','major_axis']) result result.loc[:,:,'ItemA']
This is equivalent to the following
.. ipython:: python
result = Panel(dict([ (ax,f(panel.loc[:,:,ax]))
for ax in panel.minor_axis ]))
result
result.loc[:,:,'ItemA']
reindex is the fundamental data alignment method in pandas. It is used to
implement nearly all other features relying on label-alignment
functionality. To reindex means to conform the data to match a given set of
labels along a particular axis. This accomplishes several things:
- Reorders the existing data to match a new set of labels
- Inserts missing value (NA) markers in label locations where no data for that label existed
- If specified, fill data for missing labels using logic (highly relevant to working with time series data)
Here is a simple example:
.. ipython:: python s = Series(randn(5), index=['a', 'b', 'c', 'd', 'e']) s s.reindex(['e', 'b', 'f', 'd'])
Here, the f label was not contained in the Series and hence appears as
NaN in the result.
With a DataFrame, you can simultaneously reindex the index and columns:
.. ipython:: python df df.reindex(index=['c', 'f', 'b'], columns=['three', 'two', 'one'])
For convenience, you may utilize the reindex_axis method, which takes the
labels and a keyword axis parameter.
Note that the Index objects containing the actual axis labels can be
shared between objects. So if we have a Series and a DataFrame, the
following can be done:
.. ipython:: python rs = s.reindex(df.index) rs rs.index is df.index
This means that the reindexed Series's index is the same Python object as the DataFrame's index.
.. seealso:: :ref:`MultiIndex / Advanced Indexing <advanced>` is an even more concise way of doing reindexing.
Note
When writing performance-sensitive code, there is a good reason to spend
some time becoming a reindexing ninja: many operations are faster on
pre-aligned data. Adding two unaligned DataFrames internally triggers a
reindexing step. For exploratory analysis you will hardly notice the
difference (because reindex has been heavily optimized), but when CPU
cycles matter sprinkling a few explicit reindex calls here and there can
have an impact.
You may wish to take an object and reindex its axes to be labeled the same as
another object. While the syntax for this is straightforward albeit verbose, it
is a common enough operation that the reindex_like method is available to
make this simpler:
.. ipython:: python :suppress: df2 = df.reindex(['a', 'b', 'c'], columns=['one', 'two']) df3 = df2 - df2.mean()
.. ipython:: python df2 df3 df.reindex_like(df2)
The align method is the fastest way to simultaneously align two objects. It
supports a join argument (related to :ref:`joining and merging <merging>`):
join='outer': take the union of the indexes (default)join='left': use the calling object's indexjoin='right': use the passed object's indexjoin='inner': intersect the indexes
It returns a tuple with both of the reindexed Series:
.. ipython:: python s = Series(randn(5), index=['a', 'b', 'c', 'd', 'e']) s1 = s[:4] s2 = s[1:] s1.align(s2) s1.align(s2, join='inner') s1.align(s2, join='left')
For DataFrames, the join method will be applied to both the index and the columns by default:
.. ipython:: python df.align(df2, join='inner')
You can also pass an axis option to only align on the specified axis:
.. ipython:: python df.align(df2, join='inner', axis=0)
If you pass a Series to DataFrame.align, you can choose to align both
objects either on the DataFrame's index or columns using the axis argument:
.. ipython:: python df.align(df2.ix[0], axis=1)
reindex takes an optional parameter method which is a filling method
chosen from the following table:
| Method | Action |
|---|---|
| pad / ffill | Fill values forward |
| bfill / backfill | Fill values backward |
Other fill methods could be added, of course, but these are the two most commonly used for time series data. In a way they only make sense for time series or otherwise ordered data, but you may have an application on non-time series data where this sort of "interpolation" logic is the correct thing to do. More sophisticated interpolation of missing values would be an obvious extension.
We illustrate these fill methods on a simple TimeSeries:
.. ipython:: python
rng = date_range('1/3/2000', periods=8)
ts = Series(randn(8), index=rng)
ts2 = ts[[0, 3, 6]]
ts
ts2
ts2.reindex(ts.index)
ts2.reindex(ts.index, method='ffill')
ts2.reindex(ts.index, method='bfill')
Note these methods require that the indexes are order increasing.
Note the same result could have been achieved using :ref:`fillna <missing_data.fillna>`:
.. ipython:: python ts2.reindex(ts.index).fillna(method='ffill')
Note that reindex will raise a ValueError if the index is not
monotonic. fillna will not make any checks on the order of the index.
A method closely related to reindex is the drop function. It removes a
set of labels from an axis:
.. ipython:: python df df.drop(['a', 'd'], axis=0) df.drop(['one'], axis=1)
Note that the following also works, but is a bit less obvious / clean:
.. ipython:: python df.reindex(df.index - ['a', 'd'])
The rename method allows you to relabel an axis based on some mapping (a
dict or Series) or an arbitrary function.
.. ipython:: python s s.rename(str.upper)
If you pass a function, it must return a value when called with any of the labels (and must produce a set of unique values). But if you pass a dict or Series, it need only contain a subset of the labels as keys:
.. ipython:: python
df.rename(columns={'one' : 'foo', 'two' : 'bar'},
index={'a' : 'apple', 'b' : 'banana', 'd' : 'durian'})
The rename method also provides an inplace named parameter that is by
default False and copies the underlying data. Pass inplace=True to
rename the data in place.
The Panel class has a related rename_axis class which can rename any of
its three axes.
Because Series is array-like, basic iteration produces the values. Other data structures follow the dict-like convention of iterating over the "keys" of the objects. In short:
- Series: values
- DataFrame: column labels
- Panel: item labels
Thus, for example:
.. ipython::
In [0]: for col in df:
...: print(col)
...:
Consistent with the dict-like interface, iteritems iterates through key-value pairs:
- Series: (index, scalar value) pairs
- DataFrame: (column, Series) pairs
- Panel: (item, DataFrame) pairs
For example:
.. ipython::
In [0]: for item, frame in wp.iteritems():
...: print(item)
...: print(frame)
...:
New in v0.7 is the ability to iterate efficiently through rows of a DataFrame. It returns an iterator yielding each index value along with a Series containing the data in each row:
.. ipython::
In [0]: for row_index, row in df2.iterrows():
...: print('%s\n%s' % (row_index, row))
...:
For instance, a contrived way to transpose the DataFrame would be:
.. ipython:: python
df2 = DataFrame({'x': [1, 2, 3], 'y': [4, 5, 6]})
print(df2)
print(df2.T)
df2_t = DataFrame(dict((idx,values) for idx, values in df2.iterrows()))
print(df2_t)
Note
iterrows does not preserve dtypes across the rows (dtypes are
preserved across columns for DataFrames). For example,
.. ipython:: python df_iter = DataFrame([[1, 1.0]], columns=['x', 'y']) row = next(df_iter.iterrows())[1] print(row['x'].dtype) print(df_iter['x'].dtype)
This method will return an iterator yielding a tuple for each row in the DataFrame. The first element of the tuple will be the row's corresponding index value, while the remaining values are the row values proper.
For instance,
.. ipython:: python
for r in df2.itertuples():
print(r)
Series has an accessor to succinctly return datetime like properties for the values of the Series, if its a datetime/period like Series.
This will return a Series, indexed like the existing Series.
.. ipython:: python
# datetime
s = Series(date_range('20130101 09:10:12',periods=4))
s
s.dt.hour
s.dt.second
s.dt.day
This enables nice expressions like this:
.. ipython:: python s[s.dt.day==2]
You can easily produces tz aware transformations:
.. ipython:: python
stz = s.dt.tz_localize('US/Eastern')
stz
stz.dt.tz
You can also chain these types of operations:
.. ipython:: python
s.dt.tz_localize('UTC').dt.tz_convert('US/Eastern')
The .dt accessor works for period and timedelta dtypes.
.. ipython:: python
# period
s = Series(period_range('20130101',periods=4,freq='D'))
s
s.dt.year
s.dt.day
.. ipython:: python
# timedelta
s = Series(timedelta_range('1 day 00:00:05',periods=4,freq='s'))
s
s.dt.days
s.dt.seconds
s.dt.components
Note
Series.dt will raise a TypeError if you access with a non-datetimelike values
Series is equipped with a set of string processing methods that make it easy to
operate on each element of the array. Perhaps most importantly, these methods
exclude missing/NA values automatically. These are accessed via the Series's
str attribute and generally have names matching the equivalent (scalar)
built-in string methods. For example:
.. ipython:: python s = Series(['A', 'B', 'C', 'Aaba', 'Baca', np.nan, 'CABA', 'dog', 'cat']) s.str.lower()
Powerful pattern-matching methods are provided as well, but note that pattern-matching generally uses regular expressions by default (and in some cases always uses them).
Please see :ref:`Vectorized String Methods <text.string_methods>` for a complete description.
There are two obvious kinds of sorting that you may be interested in: sorting
by label and sorting by actual values. The primary method for sorting axis
labels (indexes) across data structures is the sort_index method.
.. ipython:: python
unsorted_df = df.reindex(index=['a', 'd', 'c', 'b'],
columns=['three', 'two', 'one'])
unsorted_df.sort_index()
unsorted_df.sort_index(ascending=False)
unsorted_df.sort_index(axis=1)
DataFrame.sort_index can accept an optional by argument for axis=0
which will use an arbitrary vector or a column name of the DataFrame to
determine the sort order:
.. ipython:: python
df1 = DataFrame({'one':[2,1,1,1],'two':[1,3,2,4],'three':[5,4,3,2]})
df1.sort_index(by='two')
The by argument can take a list of column names, e.g.:
.. ipython:: python df1[['one', 'two', 'three']].sort_index(by=['one','two'])
Series has the method order (analogous to R's order function) which
sorts by value, with special treatment of NA values via the na_position
argument:
.. ipython:: python s[2] = np.nan s.order() s.order(na_position='first')
Note
Series.sort sorts a Series by value in-place. This is to provide
compatibility with NumPy methods which expect the ndarray.sort
behavior. Series.order returns a copy of the sorted data.
Series has the searchsorted method, which works similar to
np.ndarray.searchsorted.
.. ipython:: python ser = Series([1, 2, 3]) ser.searchsorted([0, 3]) ser.searchsorted([0, 4]) ser.searchsorted([1, 3], side='right') ser.searchsorted([1, 3], side='left') ser = Series([3, 1, 2]) ser.searchsorted([0, 3], sorter=np.argsort(ser))
.. versionadded:: 0.14.0
Series has the nsmallest and nlargest methods which return the
smallest or largest n values. For a large Series this can be much
faster than sorting the entire Series and calling head(n) on the result.
.. ipython:: python s = Series(np.random.permutation(10)) s s.order() s.nsmallest(3) s.nlargest(3)
You must be explicit about sorting when the column is a multi-index, and fully specify
all levels to by.
.. ipython:: python
df1.columns = MultiIndex.from_tuples([('a','one'),('a','two'),('b','three')])
df1.sort_index(by=('a','two'))
The copy method on pandas objects copies the underlying data (though not
the axis indexes, since they are immutable) and returns a new object. Note that
it is seldom necessary to copy objects. For example, there are only a
handful of ways to alter a DataFrame in-place:
- Inserting, deleting, or modifying a column
- Assigning to the
indexorcolumnsattributes- For homogeneous data, directly modifying the values via the
valuesattribute or advanced indexing
To be clear, no pandas methods have the side effect of modifying your data; almost all methods return new objects, leaving the original object untouched. If data is modified, it is because you did so explicitly.
The main types stored in pandas objects are float, int, bool, datetime64[ns], timedelta[ns],
and object. In addition these dtypes have item sizes, e.g. int64 and int32. A convenient dtypes
attribute for DataFrames returns a Series with the data type of each column.
.. ipython:: python
dft = DataFrame(dict( A = np.random.rand(3),
B = 1,
C = 'foo',
D = Timestamp('20010102'),
E = Series([1.0]*3).astype('float32'),
F = False,
G = Series([1]*3,dtype='int8')))
dft
dft.dtypes
On a Series use the dtype method.
.. ipython:: python dft['A'].dtype
If a pandas object contains data multiple dtypes IN A SINGLE COLUMN, the dtype of the
column will be chosen to accommodate all of the data types (object is the most
general).
.. ipython:: python # these ints are coerced to floats Series([1, 2, 3, 4, 5, 6.]) # string data forces an ``object`` dtype Series([1, 2, 3, 6., 'foo'])
The method get_dtype_counts will return the number of columns of
each type in a DataFrame:
.. ipython:: python dft.get_dtype_counts()
Numeric dtypes will propagate and can coexist in DataFrames (starting in v0.11.0).
If a dtype is passed (either directly via the dtype keyword, a passed ndarray,
or a passed Series, then it will be preserved in DataFrame operations. Furthermore,
different numeric dtypes will NOT be combined. The following example will give you a taste.
.. ipython:: python
df1 = DataFrame(randn(8, 1), columns = ['A'], dtype = 'float32')
df1
df1.dtypes
df2 = DataFrame(dict( A = Series(randn(8),dtype='float16'),
B = Series(randn(8)),
C = Series(np.array(randn(8),dtype='uint8')) ))
df2
df2.dtypes
By default integer types are int64 and float types are float64,
REGARDLESS of platform (32-bit or 64-bit). The following will all result in int64 dtypes.
.. ipython:: python
DataFrame([1, 2], columns=['a']).dtypes
DataFrame({'a': [1, 2]}).dtypes
DataFrame({'a': 1 }, index=list(range(2))).dtypes
Numpy, however will choose platform-dependent types when creating arrays.
The following WILL result in int32 on 32-bit platform.
.. ipython:: python frame = DataFrame(np.array([1, 2]))
Types can potentially be upcasted when combined with other types, meaning they are promoted
from the current type (say int to float)
.. ipython:: python df3 = df1.reindex_like(df2).fillna(value=0.0) + df2 df3 df3.dtypes
The values attribute on a DataFrame return the lower-common-denominator of the dtypes, meaning
the dtype that can accommodate ALL of the types in the resulting homogeneous dtyped numpy array. This can
force some upcasting.
.. ipython:: python df3.values.dtype
You can use the astype method to explicitly convert dtypes from one to another. These will by default return a copy,
even if the dtype was unchanged (pass copy=False to change this behavior). In addition, they will raise an
exception if the astype operation is invalid.
Upcasting is always according to the numpy rules. If two different dtypes are involved in an operation, then the more general one will be used as the result of the operation.
.. ipython:: python
df3
df3.dtypes
# conversion of dtypes
df3.astype('float32').dtypes
convert_objects is a method to try to force conversion of types from the object dtype to other types.
To force conversion of specific types that are number like, e.g. could be a string that represents a number,
pass convert_numeric=True. This will force strings and numbers alike to be numbers if possible, otherwise
they will be set to np.nan.
.. ipython:: python
df3['D'] = '1.'
df3['E'] = '1'
df3.convert_objects(convert_numeric=True).dtypes
# same, but specific dtype conversion
df3['D'] = df3['D'].astype('float16')
df3['E'] = df3['E'].astype('int32')
df3.dtypes
To force conversion to datetime64[ns], pass convert_dates='coerce'.
This will convert any datetime-like object to dates, forcing other values to NaT.
This might be useful if you are reading in data which is mostly dates,
but occasionally has non-dates intermixed and you want to represent as missing.
.. ipython:: python
s = Series([datetime(2001,1,1,0,0),
'foo', 1.0, 1, Timestamp('20010104'),
'20010105'],dtype='O')
s
s.convert_objects(convert_dates='coerce')
In addition, convert_objects will attempt the soft conversion of any object dtypes, meaning that if all
the objects in a Series are of the same type, the Series will have that dtype.
Performing selection operations on integer type data can easily upcast the data to floating.
The dtype of the input data will be preserved in cases where nans are not introduced (starting in 0.11.0)
See also :ref:`integer na gotchas <gotchas.intna>`
.. ipython:: python
dfi = df3.astype('int32')
dfi['E'] = 1
dfi
dfi.dtypes
casted = dfi[dfi>0]
casted
casted.dtypes
While float dtypes are unchanged.
.. ipython:: python
dfa = df3.copy()
dfa['A'] = dfa['A'].astype('float32')
dfa.dtypes
casted = dfa[df2>0]
casted
casted.dtypes
.. versionadded:: 0.14.1
The :meth:`~pandas.DataFrame.select_dtypes` method implements subsetting of columns
based on their dtype.
First, let's create a :class:`~pandas.DataFrame` with a slew of different dtypes:
.. ipython:: python
df = DataFrame({'string': list('abc'),
'int64': list(range(1, 4)),
'uint8': np.arange(3, 6).astype('u1'),
'float64': np.arange(4.0, 7.0),
'bool1': [True, False, True],
'bool2': [False, True, False],
'dates': pd.date_range('now', periods=3).values,
'category': pd.Categorical(list("ABC"))})
df['tdeltas'] = df.dates.diff()
df['uint64'] = np.arange(3, 6).astype('u8')
df['other_dates'] = pd.date_range('20130101', periods=3).values
df
select_dtypes has two parameters include and exclude that allow you to
say "give me the columns WITH these dtypes" (include) and/or "give the
columns WITHOUT these dtypes" (exclude).
For example, to select bool columns
.. ipython:: python df.select_dtypes(include=[bool])
You can also pass the name of a dtype in the numpy dtype hierarchy:
.. ipython:: python df.select_dtypes(include=['bool'])
:meth:`~pandas.DataFrame.select_dtypes` also works with generic dtypes as well.
For example, to select all numeric and boolean columns while excluding unsigned integers
.. ipython:: python df.select_dtypes(include=['number', 'bool'], exclude=['unsignedinteger'])
To select string columns you must use the object dtype:
.. ipython:: python df.select_dtypes(include=['object'])
To see all the child dtypes of a generic dtype like numpy.number you
can define a function that returns a tree of child dtypes:
.. ipython:: python
def subdtypes(dtype):
subs = dtype.__subclasses__()
if not subs:
return dtype
return [dtype, [subdtypes(dt) for dt in subs]]
All numpy dtypes are subclasses of numpy.generic:
.. ipython:: python
subdtypes(np.generic)
Note
Pandas also defines an additional category dtype, which is not integrated into the normal
numpy hierarchy and wont show up with the above function.
Note
The include and exclude parameters must be non-string sequences.