pycsamt.api.typing#

Shared typing helpers for PyCSAMT.

This module centralizes type aliases used across the v2 codebase. It intentionally keeps the legacy names that appeared in v1 annotations, while mapping them to safer runtime objects. The goal is to let old annotations such as ArrayLike[DType[float]] continue to evaluate, and to provide clearer aliases for new code.

Most aliases in this module are documentation and static-analysis helpers. They should not be used for runtime validation. Use validators from pycsamt.utils.validation or local parsing code when input values must be checked.

Examples

>>> from pycsamt.api.typing import ArrayLike, NDArray, PathLike
>>> def normalize(values: ArrayLike[float]) -> NDArray[float]:
...     ...
>>> def read_any(path: PathLike) -> str:
...     ...

Module Attributes

PathLike

Path accepted by PyCSAMT readers and writers.

Scalar

Common scalar value accepted by lightweight utilities.

Numeric

Python or NumPy numeric scalar.

Array

Concrete NumPy array with arbitrary dtype and shape.

Array1D

One-dimensional NumPy array by convention.

Array2D

Two-dimensional NumPy array by convention.

FloatArray

NumPy array with floating dtype.

IntArray

NumPy array with integer dtype.

IndexLike

Index selector accepted by array utilities.

SeriesLike

Object behaving like a pandas Series.

DataFrameLike

Object behaving like a pandas DataFrame.

Functions

is_path_like(value)

Return whether value can be treated as a path.

Classes

ArrayLike()

Array-like input accepted by NumPy conversion routines.

DType()

Dtype marker kept for legacy annotations.

EDIO()

Electrical Data Interchange object marker.

NDArray()

NumPy array marker kept for legacy annotations.

SP()

Station-position marker for legacy annotations.

Shape()

Shape marker kept for legacy annotations.

Sub()

Subset marker for legacy array annotations.

SupportsArray(*args, **kwargs)

Protocol for objects convertible to NumPy arrays.

ZO()

Impedance tensor object marker.

class pycsamt.api.typing.Any(*args, **kwargs)#

Bases: object

Special type indicating an unconstrained type.

  • Any is compatible with every type.

  • Any assumed to have all methods.

  • All values assumed to be instances of Any.

Note that all the above statements are true from the point of view of static type checkers. At runtime, Any should not be used with instance checks.

pycsamt.api.typing.Array#

Concrete NumPy array with arbitrary dtype and shape.

alias of NDArray[Any]

pycsamt.api.typing.Array1D#

One-dimensional NumPy array by convention.

alias of NDArray[Any]

pycsamt.api.typing.Array2D#

Two-dimensional NumPy array by convention.

alias of NDArray[Any]

class pycsamt.api.typing.ArrayLike[source]#

Bases: _CompatAlias

Array-like input accepted by NumPy conversion routines.

New code may use numpy.typing.ArrayLike directly. This compatibility alias remains subscriptable with one or two arguments for old PyCSAMT annotations.

class pycsamt.api.typing.Callable#

Bases: object

class pycsamt.api.typing.DataFrame(data=None, index=None, columns=None, dtype=None, copy=None)[source]#

Bases: NDFrame, OpsMixin

Two-dimensional, size-mutable, potentially heterogeneous tabular data.

Data structure also contains labeled axes (rows and columns). Arithmetic operations align on both row and column labels. Can be thought of as a dict-like container for Series objects. The primary pandas data structure.

Parameters:
  • data (ndarray (structured or homogeneous), Iterable, dict, or DataFrame) –

    Dict can contain Series, arrays, constants, dataclass or list-like objects. If data is a dict, column order follows insertion-order. If a dict contains Series which have an index defined, it is aligned by its index. This alignment also occurs if data is a Series or a DataFrame itself. Alignment is done on Series/DataFrame inputs.

    If data is a list of dicts, column order follows insertion-order.

  • index (Index or array-like) – Index to use for resulting frame. Will default to RangeIndex if no indexing information part of input data and no index provided.

  • columns (Index or array-like) – Column labels to use for resulting frame when data does not have them, defaulting to RangeIndex(0, 1, 2, …, n). If data contains column labels, will perform column selection instead.

  • dtype (dtype, default None) – Data type to force. Only a single dtype is allowed. If None, infer. If data is DataFrame then is ignored.

  • copy (bool or None, default None) – Copy data from inputs. For dict data, the default of None behaves like copy=True. For DataFrame or 2d ndarray input, the default of None behaves like copy=False. If data is a dict containing one or more Series (possibly of different dtypes), copy=False will ensure that these inputs are not copied.

See also

DataFrame.from_records

Constructor from tuples, also record arrays.

DataFrame.from_dict

From dicts of Series, arrays, or dicts.

read_csv

Read a comma-separated values (csv) file into DataFrame.

read_table

Read general delimited file into DataFrame.

read_clipboard

Read text from clipboard into DataFrame.

Notes

Please reference the User Guide for more information.

Examples

Constructing DataFrame from a dictionary.

>>> d = {"col1": [1, 2], "col2": [3, 4]}
>>> df = pd.DataFrame(data=d)
>>> df
   col1  col2
0     1     3
1     2     4

Notice that the inferred dtype is int64.

>>> df.dtypes
col1    int64
col2    int64
dtype: object

To enforce a single dtype:

>>> df = pd.DataFrame(data=d, dtype=np.int8)
>>> df.dtypes
col1    int8
col2    int8
dtype: object

Constructing DataFrame from a dictionary including Series:

>>> d = {"col1": [0, 1, 2, 3], "col2": pd.Series([2, 3], index=[2, 3])}
>>> pd.DataFrame(data=d, index=[0, 1, 2, 3])
   col1  col2
0     0   NaN
1     1   NaN
2     2   2.0
3     3   3.0

Constructing DataFrame from numpy ndarray:

>>> df2 = pd.DataFrame(
...     np.array([[1, 2, 3], [4, 5, 6], [7, 8, 9]]), columns=["a", "b", "c"]
... )
>>> df2
   a  b  c
0  1  2  3
1  4  5  6
2  7  8  9

Constructing DataFrame from a numpy ndarray that has labeled columns:

>>> data = np.array(
...     [(1, 2, 3), (4, 5, 6), (7, 8, 9)],
...     dtype=[("a", "i4"), ("b", "i4"), ("c", "i4")],
... )
>>> df3 = pd.DataFrame(data, columns=["c", "a"])
>>> df3
   c  a
0  3  1
1  6  4
2  9  7

Constructing DataFrame from dataclass:

>>> from dataclasses import make_dataclass
>>> Point = make_dataclass("Point", [("x", int), ("y", int)])
>>> pd.DataFrame([Point(0, 0), Point(0, 3), Point(2, 3)])
   x  y
0  0  0
1  0  3
2  2  3

Constructing DataFrame from Series/DataFrame:

>>> ser = pd.Series([1, 2, 3], index=["a", "b", "c"])
>>> df = pd.DataFrame(data=ser, index=["a", "c"])
>>> df
   0
a  1
c  3
>>> df1 = pd.DataFrame([1, 2, 3], index=["a", "b", "c"], columns=["x"])
>>> df2 = pd.DataFrame(data=df1, index=["a", "c"])
>>> df2
   x
a  1
c  3
property T: DataFrame#

The transpose of the DataFrame.

Returns:

The transposed DataFrame.

Return type:

DataFrame

See also

DataFrame.transpose

Transpose index and columns.

Examples

>>> df = pd.DataFrame({"col1": [1, 2], "col2": [3, 4]})
>>> df
   col1  col2
0     1     3
1     2     4
>>> df.T
      0  1
col1  1  2
col2  3  4
add(other, axis='columns', level=None, fill_value=None)#

Get Addition of dataframe and other, element-wise (binary operator add).

Equivalent to dataframe + other, but with support to substitute a fill_value for missing data in one of the inputs. With reverse version, radd.

Among flexible wrappers (add, sub, mul, div, floordiv, mod, pow) to arithmetic operators: +, -, *, /, //, %, **.

Parameters:
  • other (scalar, sequence, Series, dict or DataFrame) – Any single or multiple element data structure, or list-like object.

  • axis ({0 or 'index', 1 or 'columns'}) – Whether to compare by the index (0 or ‘index’) or columns. (1 or ‘columns’). For Series input, axis to match Series index on.

  • level (int or label) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (float or None, default None) – Fill existing missing (NaN) values, and any new element needed for successful DataFrame alignment, with this value before computation. If data in both corresponding DataFrame locations is missing the result will be missing.

Returns:

Result of the arithmetic operation.

Return type:

DataFrame

See also

DataFrame.add

Add DataFrames.

DataFrame.sub

Subtract DataFrames.

DataFrame.mul

Multiply DataFrames.

DataFrame.div

Divide DataFrames (float division).

DataFrame.truediv

Divide DataFrames (float division).

DataFrame.floordiv

Divide DataFrames (integer division).

DataFrame.mod

Calculate modulo (remainder after division).

DataFrame.pow

Calculate exponential power.

Notes

Mismatched indices will be unioned together.

Examples

>>> df = pd.DataFrame({'angles': [0, 3, 4],
...                    'degrees': [360, 180, 360]},
...                   index=['circle', 'triangle', 'rectangle'])
>>> df
           angles  degrees
circle          0      360
triangle        3      180
rectangle       4      360

Add a scalar with operator version which return the same results.

>>> df + 1
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361
>>> df.add(1)
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361

Divide by constant with reverse version.

>>> df.div(10)
           angles  degrees
circle        0.0     36.0
triangle      0.3     18.0
rectangle     0.4     36.0
>>> df.rdiv(10)
             angles   degrees
circle          inf  0.027778
triangle   3.333333  0.055556
rectangle  2.500000  0.027778

Subtract a list and Series by axis with operator version.

>>> df - [1, 2]
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub([1, 2], axis='columns')
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub(pd.Series([1, 1, 1], index=['circle', 'triangle', 'rectangle']),
...        axis='index')
           angles  degrees
circle         -1      359
triangle        2      179
rectangle       3      359

Multiply a dictionary by axis.

>>> df.mul({'angles': 0, 'degrees': 2})
            angles  degrees
circle           0      720
triangle         0      360
rectangle        0      720
>>> df.mul({'circle': 0, 'triangle': 2, 'rectangle': 3}, axis='index')
            angles  degrees
circle           0        0
triangle         6      360
rectangle       12     1080

Multiply a DataFrame of different shape with operator version.

>>> other = pd.DataFrame({'angles': [0, 3, 4]},
...                      index=['circle', 'triangle', 'rectangle'])
>>> other
           angles
circle          0
triangle        3
rectangle       4
>>> df * other
           angles  degrees
circle          0      NaN
triangle        9      NaN
rectangle      16      NaN
>>> df.mul(other, fill_value=0)
           angles  degrees
circle          0      0.0
triangle        9      0.0
rectangle      16      0.0

Divide by a MultiIndex by level.

>>> df_multindex = pd.DataFrame({'angles': [0, 3, 4, 4, 5, 6],
...                              'degrees': [360, 180, 360, 360, 540, 720]},
...                             index=[['A', 'A', 'A', 'B', 'B', 'B'],
...                                    ['circle', 'triangle', 'rectangle',
...                                     'square', 'pentagon', 'hexagon']])
>>> df_multindex
             angles  degrees
A circle          0      360
  triangle        3      180
  rectangle       4      360
B square          4      360
  pentagon        5      540
  hexagon         6      720
>>> df.div(df_multindex, level=1, fill_value=0)
             angles  degrees
A circle        NaN      1.0
  triangle      1.0      1.0
  rectangle     1.0      1.0
B square        0.0      0.0
  pentagon      0.0      0.0
  hexagon       0.0      0.0
>>> df_pow = pd.DataFrame({'A': [2, 3, 4, 5],
...                        'B': [6, 7, 8, 9]})
>>> df_pow.pow(2)
    A   B
0   4  36
1   9  49
2  16  64
3  25  81
agg(func=None, axis=0, *args, **kwargs)#

Aggregate using one or more operations over the specified axis.

Parameters:
  • func (function, str, list or dict) –

    Function to use for aggregating the data. If a function, must either work when passed a DataFrame or when passed to DataFrame.apply.

    Accepted combinations are:

    • function

    • string function name

    • list of functions and/or function names, e.g. [np.sum, 'mean']

    • dict of axis labels -> functions, function names or list of such.

  • axis ({0 or 'index', 1 or 'columns'}, default 0) – If 0 or ‘index’: apply function to each column. If 1 or ‘columns’: apply function to each row.

  • *args – Positional arguments to pass to func.

  • **kwargs – Keyword arguments to pass to func.

Returns:

The return can be:

  • scalar : when Series.agg is called with single function

  • Series : when DataFrame.agg is called with a single function

  • DataFrame : when DataFrame.agg is called with several functions

Return type:

scalar, Series or DataFrame

See also

DataFrame.apply

Perform any type of operations.

DataFrame.transform

Perform transformation type operations.

DataFrame.groupby

Perform operations over groups.

DataFrame.resample

Perform operations over resampled bins.

DataFrame.rolling

Perform operations over rolling window.

DataFrame.expanding

Perform operations over expanding window.

core.window.ewm.ExponentialMovingWindow

Perform operation over exponential weighted window.

Notes

The aggregation operations are always performed over an axis, either the index (default) or the column axis. This behavior is different from numpy aggregation functions (mean, median, prod, sum, std, var), where the default is to compute the aggregation of the flattened array, e.g., numpy.mean(arr_2d) as opposed to numpy.mean(arr_2d, axis=0).

agg is an alias for aggregate. Use the alias.

Functions that mutate the passed object can produce unexpected behavior or errors and are not supported. See Mutating with User Defined Function (UDF) methods for more details.

A passed user-defined-function will be passed a Series for evaluation.

If func defines an index relabeling, axis must be 0 or index.

Examples

>>> df = pd.DataFrame(
...     [[1, 2, 3], [4, 5, 6], [7, 8, 9], [np.nan, np.nan, np.nan]],
...     columns=["A", "B", "C"],
... )

Aggregate these functions over the rows.

>>> df.agg(["sum", "min"])
        A     B     C
sum  12.0  15.0  18.0
min   1.0   2.0   3.0

Different aggregations per column.

>>> df.agg({"A": ["sum", "min"], "B": ["min", "max"]})
        A    B
sum  12.0  NaN
min   1.0  2.0
max   NaN  8.0

Aggregate different functions over the columns and rename the index of the resulting DataFrame.

>>> df.agg(x=("A", "max"), y=("B", "min"), z=("C", "mean"))
     A    B    C
x  7.0  NaN  NaN
y  NaN  2.0  NaN
z  NaN  NaN  6.0

Aggregate over the columns.

>>> df.agg("mean", axis="columns")
0    2.0
1    5.0
2    8.0
3    NaN
dtype: float64
aggregate(func=None, axis=0, *args, **kwargs)#

Aggregate using one or more operations over the specified axis.

Parameters:
  • func (function, str, list or dict) –

    Function to use for aggregating the data. If a function, must either work when passed a DataFrame or when passed to DataFrame.apply.

    Accepted combinations are:

    • function

    • string function name

    • list of functions and/or function names, e.g. [np.sum, 'mean']

    • dict of axis labels -> functions, function names or list of such.

  • axis ({0 or 'index', 1 or 'columns'}, default 0) – If 0 or ‘index’: apply function to each column. If 1 or ‘columns’: apply function to each row.

  • *args – Positional arguments to pass to func.

  • **kwargs – Keyword arguments to pass to func.

Returns:

The return can be:

  • scalar : when Series.agg is called with single function

  • Series : when DataFrame.agg is called with a single function

  • DataFrame : when DataFrame.agg is called with several functions

Return type:

scalar, Series or DataFrame

See also

DataFrame.apply

Perform any type of operations.

DataFrame.transform

Perform transformation type operations.

DataFrame.groupby

Perform operations over groups.

DataFrame.resample

Perform operations over resampled bins.

DataFrame.rolling

Perform operations over rolling window.

DataFrame.expanding

Perform operations over expanding window.

core.window.ewm.ExponentialMovingWindow

Perform operation over exponential weighted window.

Notes

The aggregation operations are always performed over an axis, either the index (default) or the column axis. This behavior is different from numpy aggregation functions (mean, median, prod, sum, std, var), where the default is to compute the aggregation of the flattened array, e.g., numpy.mean(arr_2d) as opposed to numpy.mean(arr_2d, axis=0).

agg is an alias for aggregate. Use the alias.

Functions that mutate the passed object can produce unexpected behavior or errors and are not supported. See Mutating with User Defined Function (UDF) methods for more details.

A passed user-defined-function will be passed a Series for evaluation.

If func defines an index relabeling, axis must be 0 or index.

Examples

>>> df = pd.DataFrame(
...     [[1, 2, 3], [4, 5, 6], [7, 8, 9], [np.nan, np.nan, np.nan]],
...     columns=["A", "B", "C"],
... )

Aggregate these functions over the rows.

>>> df.agg(["sum", "min"])
        A     B     C
sum  12.0  15.0  18.0
min   1.0   2.0   3.0

Different aggregations per column.

>>> df.agg({"A": ["sum", "min"], "B": ["min", "max"]})
        A    B
sum  12.0  NaN
min   1.0  2.0
max   NaN  8.0

Aggregate different functions over the columns and rename the index of the resulting DataFrame.

>>> df.agg(x=("A", "max"), y=("B", "min"), z=("C", "mean"))
     A    B    C
x  7.0  NaN  NaN
y  NaN  2.0  NaN
z  NaN  NaN  6.0

Aggregate over the columns.

>>> df.agg("mean", axis="columns")
0    2.0
1    5.0
2    8.0
3    NaN
dtype: float64
all(*, axis: Axis = 0, bool_only: bool = False, skipna: bool = True, **kwargs) Series#
all(*, axis: None, bool_only: bool = False, skipna: bool = True, **kwargs) bool
all(*, axis: Axis | None, bool_only: bool = False, skipna: bool = True, **kwargs) Series | bool

Return whether all elements are True, potentially over an axis.

Returns True unless there at least one element within a series or along a Dataframe axis that is False or equivalent (e.g. zero or empty).

Parameters:
  • axis ({0 or 'index', 1 or 'columns', None}, default 0) –

    Indicate which axis or axes should be reduced. For Series this parameter is unused and defaults to 0.

    • 0 / ‘index’ : reduce the index, return a Series whose index is the original column labels.

    • 1 / ‘columns’ : reduce the columns, return a Series whose index is the original index.

    • None : reduce all axes, return a scalar.

  • bool_only (bool, default False) – Include only boolean columns. Not implemented for Series.

  • skipna (bool, default True) – Exclude NA/null values. If the entire row/column is NA and skipna is True, then the result will be True, as for an empty row/column. If skipna is False, then NA are treated as True, because these are not equal to zero.

  • **kwargs (any, default None) – Additional keywords have no effect but might be accepted for compatibility with NumPy.

Returns:

If axis=None, then a scalar boolean is returned. Otherwise a Series is returned with index matching the index argument.

Return type:

Series or scalar

See also

Series.all

Return True if all elements are True.

DataFrame.any

Return True if one (or more) elements are True.

Examples

Series

>>> pd.Series([True, True]).all()
True
>>> pd.Series([True, False]).all()
False
>>> pd.Series([], dtype="float64").all()
True
>>> pd.Series([np.nan]).all()
True
>>> pd.Series([np.nan]).all(skipna=False)
True

DataFrames

Create a DataFrame from a dictionary.

>>> df = pd.DataFrame({"col1": [True, True], "col2": [True, False]})
>>> df
   col1   col2
0  True   True
1  True  False

Default behaviour checks if values in each column all return True.

>>> df.all()
col1     True
col2    False
dtype: bool

Specify axis='columns' to check if values in each row all return True.

>>> df.all(axis="columns")
0     True
1    False
dtype: bool

Or axis=None for whether every value is True.

>>> df.all(axis=None)
False
any(*, axis: Axis = 0, bool_only: bool = False, skipna: bool = True, **kwargs) Series#
any(*, axis: None, bool_only: bool = False, skipna: bool = True, **kwargs) bool
any(*, axis: Axis | None, bool_only: bool = False, skipna: bool = True, **kwargs) Series | bool

Return whether any element is True, potentially over an axis.

Returns False unless there is at least one element within a series or along a Dataframe axis that is True or equivalent (e.g. non-zero or non-empty).

Parameters:
  • axis ({0 or 'index', 1 or 'columns', None}, default 0) –

    Indicate which axis or axes should be reduced. For Series this parameter is unused and defaults to 0.

    • 0 / ‘index’ : reduce the index, return a Series whose index is the original column labels.

    • 1 / ‘columns’ : reduce the columns, return a Series whose index is the original index.

    • None : reduce all axes, return a scalar.

  • bool_only (bool, default False) – Include only boolean columns. Not implemented for Series.

  • skipna (bool, default True) – Exclude NA/null values. If the entire row/column is NA and skipna is True, then the result will be False, as for an empty row/column. If skipna is False, then NA are treated as True, because these are not equal to zero.

  • **kwargs (any, default None) – Additional keywords have no effect but might be accepted for compatibility with NumPy.

Returns:

If axis=None, then a scalar boolean is returned. Otherwise a Series is returned with index matching the index argument.

Return type:

Series or scalar

See also

numpy.any

Numpy version of this method.

Series.any

Return whether any element is True.

Series.all

Return whether all elements are True.

DataFrame.any

Return whether any element is True over requested axis.

DataFrame.all

Return whether all elements are True over requested axis.

Examples

Series

For Series input, the output is a scalar indicating whether any element is True.

>>> pd.Series([False, False]).any()
False
>>> pd.Series([True, False]).any()
True
>>> pd.Series([], dtype="float64").any()
False
>>> pd.Series([np.nan]).any()
False
>>> pd.Series([np.nan]).any(skipna=False)
True

DataFrame

Whether each column contains at least one True element (the default).

>>> df = pd.DataFrame({"A": [1, 2], "B": [0, 2], "C": [0, 0]})
>>> df
   A  B  C
0  1  0  0
1  2  2  0
>>> df.any()
A     True
B     True
C    False
dtype: bool

Aggregating over the columns.

>>> df = pd.DataFrame({"A": [True, False], "B": [1, 2]})
>>> df
       A  B
0   True  1
1  False  2
>>> df.any(axis="columns")
0    True
1    True
dtype: bool
>>> df = pd.DataFrame({"A": [True, False], "B": [1, 0]})
>>> df
       A  B
0   True  1
1  False  0
>>> df.any(axis="columns")
0    True
1    False
dtype: bool

Aggregating over the entire DataFrame with axis=None.

>>> df.any(axis=None)
True

any for an empty DataFrame is an empty Series.

>>> pd.DataFrame([]).any()
Series([], dtype: bool)
apply(func, axis=0, raw=False, result_type=None, args=(), by_row='compat', engine=None, engine_kwargs=None, **kwargs)#

Apply a function along an axis of the DataFrame.

Objects passed to the function are Series objects whose index is either the DataFrame’s index (axis=0) or the DataFrame’s columns (axis=1). By default (result_type=None), the final return type is inferred from the return type of the applied function. Otherwise, it depends on the result_type argument. The return type of the applied function is inferred based on the first computed result obtained after applying the function to a Series object.

Parameters:
  • func (function) – Function to apply to each column or row.

  • axis ({0 or 'index', 1 or 'columns'}, default 0) –

    Axis along which the function is applied:

    • 0 or ‘index’: apply function to each column.

    • 1 or ‘columns’: apply function to each row.

  • raw (bool, default False) –

    Determines if row or column is passed as a Series or ndarray object:

    • False : passes each row or column as a Series to the function.

    • True : the passed function will receive ndarray objects instead. If you are just applying a NumPy reduction function this will achieve much better performance.

    Note

    When raw=True, the result dtype is inferred from the first returned value.

  • result_type ({'expand', 'reduce', 'broadcast', None}, default None) –

    These only act when axis=1 (columns):

    • ’expand’ : list-like results will be turned into columns.

    • ’reduce’ : returns a Series if possible rather than expanding list-like results. This is the opposite of ‘expand’.

    • ’broadcast’ : results will be broadcast to the original shape of the DataFrame, the original index and columns will be retained.

    The default behaviour (None) depends on the return value of the applied function: list-like results will be returned as a Series of those. However if the apply function returns a Series these are expanded to columns.

  • args (tuple) – Positional arguments to pass to func in addition to the array/series.

  • by_row (False or "compat", default "compat") –

    Only has an effect when func is a listlike or dictlike of funcs and the func isn’t a string. If “compat”, will if possible first translate the func into pandas methods (e.g. Series().apply(np.sum) will be translated to Series().sum()). If that doesn’t work, will try call to apply again with by_row=True and if that fails, will call apply again with by_row=False (backward compatible). If False, the funcs will be passed the whole Series at once.

    Added in version 2.1.0.

  • engine (decorator or {'python', 'numba'}, optional) –

    Choose the execution engine to use. If not provided the function will be executed by the regular Python interpreter.

    Other options include JIT compilers such Numba and Bodo, which in some cases can speed up the execution. To use an executor you can provide the decorators numba.jit, numba.njit or bodo.jit. You can also provide the decorator with parameters, like numba.jit(nogit=True).

    Not all functions can be executed with all execution engines. In general, JIT compilers will require type stability in the function (no variable should change data type during the execution). And not all pandas and NumPy APIs are supported. Check the engine documentation [1] and [2] for limitations.

    Warning

    String parameters will stop being supported in a future pandas version.

    Added in version 2.2.0.

  • engine_kwargs (dict) – Pass keyword arguments to the engine. This is currently only used by the numba engine, see the documentation for the engine argument for more information.

  • **kwargs – Additional keyword arguments to pass as keywords arguments to func.

Returns:

Result of applying func along the given axis of the DataFrame.

Return type:

Series or DataFrame

See also

DataFrame.map

For elementwise operations.

DataFrame.aggregate

Only perform aggregating type operations.

DataFrame.transform

Only perform transforming type operations.

Notes

Functions that mutate the passed object can produce unexpected behavior or errors and are not supported. See Mutating with User Defined Function (UDF) methods for more details.

References

Examples

>>> df = pd.DataFrame([[4, 9]] * 3, columns=["A", "B"])
>>> df
   A  B
0  4  9
1  4  9
2  4  9

Using a numpy universal function (in this case the same as np.sqrt(df)):

>>> df.apply(np.sqrt)
     A    B
0  2.0  3.0
1  2.0  3.0
2  2.0  3.0

Using a reducing function on either axis

>>> df.apply(np.sum, axis=0)
A    12
B    27
dtype: int64
>>> df.apply(np.sum, axis=1)
0    13
1    13
2    13
dtype: int64

Returning a list-like will result in a Series

>>> df.apply(lambda x: [1, 2], axis=1)
0    [1, 2]
1    [1, 2]
2    [1, 2]
dtype: object

Passing result_type='expand' will expand list-like results to columns of a Dataframe

>>> df.apply(lambda x: [1, 2], axis=1, result_type="expand")
   0  1
0  1  2
1  1  2
2  1  2

Returning a Series inside the function is similar to passing result_type='expand'. The resulting column names will be the Series index.

>>> df.apply(lambda x: pd.Series([1, 2], index=["foo", "bar"]), axis=1)
   foo  bar
0    1    2
1    1    2
2    1    2

Passing result_type='broadcast' will ensure the same shape result, whether list-like or scalar is returned by the function, and broadcast it along the axis. The resulting column names will be the originals.

>>> df.apply(lambda x: [1, 2], axis=1, result_type="broadcast")
   A  B
0  1  2
1  1  2
2  1  2

Advanced users can speed up their code by using a Just-in-time (JIT) compiler with apply. The main JIT compilers available for pandas are Numba and Bodo. In general, JIT compilation is only possible when the function passed to apply has type stability (variables in the function do not change their type during the execution).

>>> import bodo
>>> df.apply(lambda x: x.A + x.B, axis=1, engine=bodo.jit)

Note that JIT compilation is only recommended for functions that take a significant amount of time to run. Fast functions are unlikely to run faster with JIT compilation.

assign(**kwargs)#

Assign new columns to a DataFrame.

Returns a new object with all original columns in addition to new ones. Existing columns that are re-assigned will be overwritten.

Parameters:

**kwargs (callable or Series) – The column names are keywords. If the values are callable, they are computed on the DataFrame and assigned to the new columns. The callable must not change input DataFrame (though pandas doesn’t check it). If the values are not callable, (e.g. a Series, scalar, or array), they are simply assigned.

Returns:

A new DataFrame with the new columns in addition to all the existing columns.

Return type:

DataFrame

See also

DataFrame.loc

Select a subset of a DataFrame by labels.

DataFrame.iloc

Select a subset of a DataFrame by positions.

Notes

Assigning multiple columns within the same assign is possible. Later items in ‘**kwargs’ may refer to newly created or modified columns in ‘df’; items are computed and assigned into ‘df’ in order.

Examples

>>> df = pd.DataFrame({"temp_c": [17.0, 25.0]}, index=["Portland", "Berkeley"])
>>> df
          temp_c
Portland    17.0
Berkeley    25.0

Where the value is a callable, evaluated on df:

>>> df.assign(temp_f=lambda x: x.temp_c * 9 / 5 + 32)
          temp_c  temp_f
Portland    17.0    62.6
Berkeley    25.0    77.0

Alternatively, the same behavior can be achieved by directly referencing an existing Series or sequence:

>>> df.assign(temp_f=df["temp_c"] * 9 / 5 + 32)
          temp_c  temp_f
Portland    17.0    62.6
Berkeley    25.0    77.0

or by using pandas.col():

>>> df.assign(temp_f=pd.col("temp_c") * 9 / 5 + 32)
          temp_c  temp_f
Portland    17.0    62.6
Berkeley    25.0    77.0

You can create multiple columns within the same assign where one of the columns depends on another one defined within the same assign:

>>> df.assign(
...     temp_f=lambda x: x["temp_c"] * 9 / 5 + 32,
...     temp_k=lambda x: (x["temp_f"] + 459.67) * 5 / 9,
... )
          temp_c  temp_f  temp_k
Portland    17.0    62.6  290.15
Berkeley    25.0    77.0  298.15
property axes: list[Index]#

Return a list representing the axes of the DataFrame.

It has the row axis labels and column axis labels as the only members. They are returned in that order.

See also

DataFrame.index

The index (row labels) of the DataFrame.

DataFrame.columns

The column labels of the DataFrame.

Examples

>>> df = pd.DataFrame({"col1": [1, 2], "col2": [3, 4]})
>>> df.axes
[RangeIndex(start=0, stop=2, step=1), Index(['col1', 'col2'], dtype='str')]
boxplot(column=None, by=None, ax=None, fontsize=None, rot=0, grid=True, figsize=None, layout=None, return_type=None, backend=None, **kwargs)#

Make a box plot from DataFrame columns.

Make a box-and-whisker plot from DataFrame columns, optionally grouped by some other columns. A box plot is a method for graphically depicting groups of numerical data through their quartiles. The box extends from the Q1 to Q3 quartile values of the data, with a line at the median (Q2). The whiskers extend from the edges of box to show the range of the data. By default, they extend no more than 1.5 * IQR (IQR = Q3 - Q1) from the edges of the box, ending at the farthest data point within that interval. Outliers are plotted as separate dots.

For further details see Wikipedia’s entry for boxplot.

Parameters:
  • column (str or list of str, optional) – Column name or list of names, or vector. Can be any valid input to pandas.DataFrame.groupby().

  • by (str or array-like, optional) – Column in the DataFrame to pandas.DataFrame.groupby(). One box-plot will be done per value of columns in by.

  • ax (object of class matplotlib.axes.Axes, optional) – The matplotlib axes to be used by boxplot.

  • fontsize (float or str) – Tick label font size in points or as a string (e.g., large).

  • rot (float, default 0) – The rotation angle of labels (in degrees) with respect to the screen coordinate system.

  • grid (bool, default True) – Setting this to True will show the grid.

  • figsize (A tuple (width, height) in inches) – The size of the figure to create in matplotlib.

  • layout (tuple (rows, columns), optional) – For example, (3, 5) will display the subplots using 3 rows and 5 columns, starting from the top-left.

  • return_type ({'axes', 'dict', 'both'} or None, default 'axes') –

    The kind of object to return. The default is axes.

    • ’axes’ returns the matplotlib axes the boxplot is drawn on.

    • ’dict’ returns a dictionary whose values are the matplotlib lines of the boxplot.

    • ’both’ returns a namedtuple with the axes and dict.

    • when grouping with by, a Series mapping columns to return_type is returned.

    If return_type is None, a NumPy array of axes with the same shape as layout is returned.

  • backend (str, default None) – Backend to use instead of the backend specified in the option plotting.backend. For instance, ‘matplotlib’. Alternatively, to specify the plotting.backend for the whole session, set pd.options.plotting.backend.

  • **kwargs – All other plotting keyword arguments to be passed to matplotlib.pyplot.boxplot().

  • self (DataFrame)

Returns:

See Notes.

Return type:

result

See also

Series.plot.hist

Make a histogram.

matplotlib.pyplot.boxplot

Matplotlib equivalent plot.

Notes

The return type depends on the return_type parameter:

  • ‘axes’ : object of class matplotlib.axes.Axes

  • ‘dict’ : dict of matplotlib.lines.Line2D objects

  • ‘both’ : a namedtuple with structure (ax, lines)

For data grouped with by, return a Series of the above or a numpy array:

  • Series

  • array (for return_type = None)

Use return_type='dict' when you want to tweak the appearance of the lines after plotting. In this case a dict containing the Lines making up the boxes, caps, fliers, medians, and whiskers is returned.

Examples

Boxplots can be created for every column in the dataframe by df.boxplot() or indicating the columns to be used:

Boxplots of variables distributions grouped by the values of a third variable can be created using the option by. For instance:

A list of strings (i.e. ['X', 'Y']) can be passed to boxplot in order to group the data by combination of the variables in the x-axis:

The layout of boxplot can be adjusted giving a tuple to layout:

Additional formatting can be done to the boxplot, like suppressing the grid (grid=False), rotating the labels in the x-axis (i.e. rot=45) or changing the fontsize (i.e. fontsize=15):

The parameter return_type can be used to select the type of element returned by boxplot. When return_type='axes' is selected, the matplotlib axes on which the boxplot is drawn are returned:

When grouping with by, a Series mapping columns to return_type is returned:

If return_type is None, a NumPy array of axes with the same shape as layout is returned:

columns#

The column labels of the DataFrame.

This property holds the column names as a pandas Index object. It provides an immutable sequence of column labels that can be used for data selection, renaming, and alignment in DataFrame operations.

Returns:

The column labels of the DataFrame.

Return type:

pandas.Index

See also

DataFrame.index

The index (row labels) of the DataFrame.

DataFrame.axes

Return a list representing the axes of the DataFrame.

Examples

>>> df = pd.DataFrame({'A': [1, 2], 'B': [3, 4]})
>>> df
        A  B
0    1  3
1    2  4
>>> df.columns
Index(['A', 'B'], dtype='str')
combine(other, func, fill_value=None, overwrite=True)#

Perform column-wise combine with another DataFrame.

Combines a DataFrame with other DataFrame using func to element-wise combine columns. The row and column indexes of the resulting DataFrame will be the union of the two.

Parameters:
  • other (DataFrame) – The DataFrame to merge column-wise.

  • func (function) – Function that takes two series as inputs and return a Series or a scalar. Used to merge the two dataframes column by columns.

  • fill_value (scalar value, default None) – The value to fill NaNs with prior to passing any column to the merge func.

  • overwrite (bool, default True) – If True, columns in self that do not exist in other will be overwritten with NaNs.

Returns:

Combination of the provided DataFrames.

Return type:

DataFrame

See also

DataFrame.combine_first

Combine two DataFrame objects and default to non-null values in frame calling the method.

Examples

Combine using a simple function that chooses the smaller column.

>>> df1 = pd.DataFrame({"A": [0, 0], "B": [4, 4]})
>>> df2 = pd.DataFrame({"A": [1, 1], "B": [3, 3]})
>>> take_smaller = lambda s1, s2: s1 if s1.sum() < s2.sum() else s2
>>> df1.combine(df2, take_smaller)
   A  B
0  0  3
1  0  3

Example using a true element-wise combine function.

>>> df1 = pd.DataFrame({"A": [5, 0], "B": [2, 4]})
>>> df2 = pd.DataFrame({"A": [1, 1], "B": [3, 3]})
>>> df1.combine(df2, np.minimum)
   A  B
0  1  2
1  0  3

Using fill_value fills Nones prior to passing the column to the merge function.

>>> df1 = pd.DataFrame({"A": [0, 0], "B": [None, 4]})
>>> df2 = pd.DataFrame({"A": [1, 1], "B": [3, 3]})
>>> df1.combine(df2, take_smaller, fill_value=-5)
   A    B
0  0 -5.0
1  0  4.0

Example that demonstrates the use of overwrite and behavior when the axis differ between the dataframes.

>>> df1 = pd.DataFrame({"A": [0, 0], "B": [4, 4]})
>>> df2 = pd.DataFrame(
...     {
...         "B": [3, 3],
...         "C": [-10, 1],
...     },
...     index=[1, 2],
... )
>>> df1.combine(df2, take_smaller)
     A    B     C
0  NaN  NaN   NaN
1  NaN  3.0 -10.0
2  NaN  3.0   1.0
>>> df1.combine(df2, take_smaller, overwrite=False)
     A    B     C
0  0.0  NaN   NaN
1  0.0  3.0 -10.0
2  NaN  3.0   1.0

Demonstrating the preference of the passed in dataframe.

>>> df2 = pd.DataFrame(
...     {
...         "B": [3, 3],
...         "C": [1, 1],
...     },
...     index=[1, 2],
... )
>>> df2.combine(df1, take_smaller)
     B    C   A
0  NaN  NaN 0.0
1  3.0  NaN 0.0
2  3.0  NaN NaN
>>> df2.combine(df1, take_smaller, overwrite=False)
     B    C   A
0  NaN  NaN 0.0
1  3.0  1.0 0.0
2  3.0  1.0 NaN
combine_first(other)#

Update null elements with value in the same location in other.

Combine two DataFrame objects by filling null values in one DataFrame with non-null values from other DataFrame. The row and column indexes of the resulting DataFrame will be the union of the two. The resulting dataframe contains the ‘first’ dataframe values and overrides the second one values where both first.loc[index, col] and second.loc[index, col] are not missing values, upon calling first.combine_first(second).

Parameters:

other (DataFrame) – Provided DataFrame to use to fill null values.

Returns:

The result of combining the provided DataFrame with the other object.

Return type:

DataFrame

See also

DataFrame.combine

Perform series-wise operation on two DataFrames using a given function.

Examples

>>> df1 = pd.DataFrame({"A": [None, 0], "B": [None, 4]})
>>> df2 = pd.DataFrame({"A": [1, 1], "B": [3, 3]})
>>> df1.combine_first(df2)
     A    B
0  1.0  3.0
1  0.0  4.0

Null values still persist if the location of that null value does not exist in other

>>> df1 = pd.DataFrame({"A": [None, 0], "B": [4, None]})
>>> df2 = pd.DataFrame({"B": [3, 3], "C": [1, 1]}, index=[1, 2])
>>> df1.combine_first(df2)
     A    B    C
0  NaN  4.0  NaN
1  0.0  3.0  1.0
2  NaN  3.0  1.0
compare(other, align_axis=1, keep_shape=False, keep_equal=False, result_names=('self', 'other'))#

Compare to another DataFrame and show the differences.

Parameters:
  • other (DataFrame) – Object to compare with.

  • align_axis ({0 or 'index', 1 or 'columns'}, default 1) –

    Determine which axis to align the comparison on.

    • 0, or ‘index’ : Resulting differences are stacked vertically with rows drawn alternately from self and other.

    • 1, or ‘columns’ : Resulting differences are aligned horizontally with columns drawn alternately from self and other.

  • keep_shape (bool, default False) – If true, all rows and columns are kept. Otherwise, only the ones with different values are kept.

  • keep_equal (bool, default False) – If true, the result keeps values that are equal. Otherwise, equal values are shown as NaNs.

  • result_names (tuple, default ('self', 'other')) – Set the dataframes names in the comparison.

Returns:

DataFrame that shows the differences stacked side by side.

The resulting index will be a MultiIndex with ‘self’ and ‘other’ stacked alternately at the inner level.

Return type:

DataFrame

Raises:

ValueError – When the two DataFrames don’t have identical labels or shape.

See also

Series.compare

Compare with another Series and show differences.

DataFrame.equals

Test whether two objects contain the same elements.

Notes

Matching NaNs will not appear as a difference.

Can only compare identically-labeled (i.e. same shape, identical row and column labels) DataFrames

Examples

>>> df = pd.DataFrame(
...     {
...         "col1": ["a", "a", "b", "b", "a"],
...         "col2": [1.0, 2.0, 3.0, np.nan, 5.0],
...         "col3": [1.0, 2.0, 3.0, 4.0, 5.0],
...     },
...     columns=["col1", "col2", "col3"],
... )
>>> df
  col1  col2  col3
0    a   1.0   1.0
1    a   2.0   2.0
2    b   3.0   3.0
3    b   NaN   4.0
4    a   5.0   5.0
>>> df2 = df.copy()
>>> df2.loc[0, "col1"] = "c"
>>> df2.loc[2, "col3"] = 4.0
>>> df2
  col1  col2  col3
0    c   1.0   1.0
1    a   2.0   2.0
2    b   3.0   4.0
3    b   NaN   4.0
4    a   5.0   5.0

Align the differences on columns

>>> df.compare(df2)
  col1       col3
  self other self other
0    a     c  NaN   NaN
2  NaN   NaN  3.0   4.0

Assign result_names

>>> df.compare(df2, result_names=("left", "right"))
  col1       col3
  left right left right
0    a     c  NaN   NaN
2  NaN   NaN  3.0   4.0

Stack the differences on rows

>>> df.compare(df2, align_axis=0)
        col1  col3
0 self     a   NaN
  other    c   NaN
2 self   NaN   3.0
  other  NaN   4.0

Keep the equal values

>>> df.compare(df2, keep_equal=True)
  col1       col3
  self other self other
0    a     c  1.0   1.0
2    b     b  3.0   4.0

Keep all original rows and columns

>>> df.compare(df2, keep_shape=True)
  col1       col2       col3
  self other self other self other
0    a     c  NaN   NaN  NaN   NaN
1  NaN   NaN  NaN   NaN  NaN   NaN
2  NaN   NaN  NaN   NaN  3.0   4.0
3  NaN   NaN  NaN   NaN  NaN   NaN
4  NaN   NaN  NaN   NaN  NaN   NaN

Keep all original rows and columns and also all original values

>>> df.compare(df2, keep_shape=True, keep_equal=True)
  col1       col2       col3
  self other self other self other
0    a     c  1.0   1.0  1.0   1.0
1    a     a  2.0   2.0  2.0   2.0
2    b     b  3.0   3.0  3.0   4.0
3    b     b  NaN   NaN  4.0   4.0
4    a     a  5.0   5.0  5.0   5.0
corr(method='pearson', min_periods=1, numeric_only=False)#

Compute pairwise correlation of columns, excluding NA/null values.

Parameters:
  • method ({'pearson', 'kendall', 'spearman'} or callable) –

    Method of correlation:

    • pearson : standard correlation coefficient

    • kendall : Kendall Tau correlation coefficient

    • spearman : Spearman rank correlation

    • callable: callable with input two 1d ndarrays

      and returning a float. Note that the returned matrix from corr will have 1 along the diagonals and will be symmetric regardless of the callable’s behavior.

  • min_periods (int, optional) – Minimum number of observations required per pair of columns to have a valid result. Currently only available for Pearson and Spearman correlation.

  • numeric_only (bool, default False) –

    Include only float, int or boolean data.

    Changed in version 2.0.0: The default value of numeric_only is now False.

Returns:

Correlation matrix.

Return type:

DataFrame

See also

DataFrame.corrwith

Compute pairwise correlation with another DataFrame or Series.

Series.corr

Compute the correlation between two Series.

Notes

Pearson, Kendall and Spearman correlation are currently computed using pairwise complete observations.

Examples

>>> def histogram_intersection(a, b):
...     v = np.minimum(a, b).sum().round(decimals=1)
...     return v
>>> df = pd.DataFrame(
...     [(0.2, 0.3), (0.0, 0.6), (0.6, 0.0), (0.2, 0.1)],
...     columns=["dogs", "cats"],
... )
>>> df.corr(method=histogram_intersection)
      dogs  cats
dogs   1.0   0.3
cats   0.3   1.0
>>> df = pd.DataFrame(
...     [(1, 1), (2, np.nan), (np.nan, 3), (4, 4)], columns=["dogs", "cats"]
... )
>>> df.corr(min_periods=3)
      dogs  cats
dogs   1.0   NaN
cats   NaN   1.0
corrwith(other, axis=0, drop=False, method='pearson', numeric_only=False, min_periods=None)#

Compute pairwise correlation.

Pairwise correlation is computed between rows or columns of DataFrame with rows or columns of Series or DataFrame. DataFrames are first aligned along both axes before computing the correlations.

Parameters:
  • other (DataFrame, Series) – Object with which to compute correlations.

  • axis ({0 or 'index', 1 or 'columns'}, default 0) – The axis to use. 0 or ‘index’ to compute row-wise, 1 or ‘columns’ for column-wise.

  • drop (bool, default False) – Drop missing indices from result.

  • method ({'pearson', 'kendall', 'spearman'} or callable) –

    Method of correlation:

    • pearson : standard correlation coefficient

    • kendall : Kendall Tau correlation coefficient

    • spearman : Spearman rank correlation

    • callable: callable with input two 1d ndarrays

      and returning a float.

  • numeric_only (bool, default False) – Include only float, int or boolean data.

  • min_periods (int, optional) –

    Minimum number of observations needed to have a valid result.

    Changed in version 2.0.0: The default value of numeric_only is now False.

Returns:

Pairwise correlations.

Return type:

Series

See also

DataFrame.corr

Compute pairwise correlation of columns.

Examples

>>> index = ["a", "b", "c", "d", "e"]
>>> columns = ["one", "two", "three", "four"]
>>> df1 = pd.DataFrame(
...     np.arange(20).reshape(5, 4), index=index, columns=columns
... )
>>> df2 = pd.DataFrame(
...     np.arange(16).reshape(4, 4), index=index[:4], columns=columns
... )
>>> df1.corrwith(df2)
one      1.0
two      1.0
three    1.0
four     1.0
dtype: float64
>>> df2.corrwith(df1, axis=1)
a    1.0
b    1.0
c    1.0
d    1.0
e    NaN
dtype: float64
count(axis=0, numeric_only=False)#

Count non-NA cells for each column or row.

The values None, NaN, NaT, pandas.NA are considered NA.

Parameters:
  • axis ({0 or 'index', 1 or 'columns'}, default 0) – If 0 or ‘index’ counts are generated for each column. If 1 or ‘columns’ counts are generated for each row.

  • numeric_only (bool, default False) – Include only float, int or boolean data.

Returns:

For each column/row the number of non-NA/null entries.

Return type:

Series

See also

Series.count

Number of non-NA elements in a Series.

DataFrame.value_counts

Count unique combinations of columns.

DataFrame.shape

Number of DataFrame rows and columns (including NA elements).

DataFrame.isna

Boolean same-sized DataFrame showing places of NA elements.

Examples

Constructing DataFrame from a dictionary:

>>> df = pd.DataFrame(
...     {
...         "Person": ["John", "Myla", "Lewis", "John", "Myla"],
...         "Age": [24.0, np.nan, 21.0, 33, 26],
...         "Single": [False, True, True, True, False],
...     }
... )
>>> df
   Person   Age  Single
0    John  24.0   False
1    Myla   NaN    True
2   Lewis  21.0    True
3    John  33.0    True
4    Myla  26.0   False

Notice the uncounted NA values:

>>> df.count()
Person    5
Age       4
Single    5
dtype: int64

Counts for each row:

>>> df.count(axis="columns")
0    3
1    2
2    3
3    3
4    3
dtype: int64
cov(min_periods=None, ddof=1, numeric_only=False)#

Compute pairwise covariance of columns, excluding NA/null values.

Compute the pairwise covariance among the series of a DataFrame. The returned data frame is the covariance matrix of the columns of the DataFrame.

Both NA and null values are automatically excluded from the calculation. (See the note below about bias from missing values.) A threshold can be set for the minimum number of observations for each value created. Comparisons with observations below this threshold will be returned as NaN.

This method is generally used for the analysis of time series data to understand the relationship between different measures across time.

Parameters:
  • min_periods (int, optional) – Minimum number of observations required per pair of columns to have a valid result.

  • ddof (int, default 1) – Delta degrees of freedom. The divisor used in calculations is N - ddof, where N represents the number of elements. This argument is applicable only when no nan is in the dataframe.

  • numeric_only (bool, default False) –

    Include only float, int or boolean data.

    Changed in version 2.0.0: The default value of numeric_only is now False.

Returns:

The covariance matrix of the series of the DataFrame.

Return type:

DataFrame

See also

Series.cov

Compute covariance with another Series.

core.window.ewm.ExponentialMovingWindow.cov

Exponential weighted sample covariance.

core.window.expanding.Expanding.cov

Expanding sample covariance.

core.window.rolling.Rolling.cov

Rolling sample covariance.

Notes

Returns the covariance matrix of the DataFrame’s time series. The covariance is normalized by N-ddof.

For DataFrames that have Series that are missing data (assuming that data is missing at random) the returned covariance matrix will be an unbiased estimate of the variance and covariance between the member Series.

However, for many applications this estimate may not be acceptable because the estimate covariance matrix is not guaranteed to be positive semi-definite. This could lead to estimate correlations having absolute values which are greater than one, and/or a non-invertible covariance matrix. See Estimation of covariance matrices for more details.

Examples

>>> df = pd.DataFrame(
...     [(1, 2), (0, 3), (2, 0), (1, 1)], columns=["dogs", "cats"]
... )
>>> df.cov()
          dogs      cats
dogs  0.666667 -1.000000
cats -1.000000  1.666667
>>> np.random.seed(42)
>>> df = pd.DataFrame(
...     np.random.randn(1000, 5), columns=["a", "b", "c", "d", "e"]
... )
>>> df.cov()
          a         b         c         d         e
a  0.998438 -0.020161  0.059277 -0.008943  0.014144
b -0.020161  1.059352 -0.008543 -0.024738  0.009826
c  0.059277 -0.008543  1.010670 -0.001486 -0.000271
d -0.008943 -0.024738 -0.001486  0.921297 -0.013692
e  0.014144  0.009826 -0.000271 -0.013692  0.977795

Minimum number of periods

This method also supports an optional min_periods keyword that specifies the required minimum number of non-NA observations for each column pair in order to have a valid result:

>>> np.random.seed(42)
>>> df = pd.DataFrame(np.random.randn(20, 3), columns=["a", "b", "c"])
>>> df.loc[df.index[:5], "a"] = np.nan
>>> df.loc[df.index[5:10], "b"] = np.nan
>>> df.cov(min_periods=12)
          a         b         c
a  0.316741       NaN -0.150812
b       NaN  1.248003  0.191417
c -0.150812  0.191417  0.895202
cummax(axis=0, skipna=True, numeric_only=False, *args, **kwargs)#

Return cumulative maximum over a DataFrame or Series axis.

Returns a DataFrame or Series of the same size containing the cumulative maximum.

Parameters:
  • axis ({0 or 'index', 1 or 'columns'}, default 0) – The index or the name of the axis. 0 is equivalent to None or ‘index’. For Series this parameter is unused and defaults to 0.

  • skipna (bool, default True) – Exclude NA/null values. If an entire row/column is NA, the result will be NA.

  • numeric_only (bool, default False) – Include only float, int, boolean columns.

  • *args – Additional keywords have no effect but might be accepted for compatibility with NumPy.

  • **kwargs – Additional keywords have no effect but might be accepted for compatibility with NumPy.

Returns:

Return cumulative maximum of Series or DataFrame.

Return type:

Series or DataFrame

See also

core.window.expanding.Expanding.max

Similar functionality but ignores NaN values.

DataFrame.max

Return the maximum over DataFrame axis.

DataFrame.cummax

Return cumulative maximum over DataFrame axis.

DataFrame.cummin

Return cumulative minimum over DataFrame axis.

DataFrame.cumsum

Return cumulative sum over DataFrame axis.

DataFrame.cumprod

Return cumulative product over DataFrame axis.

Examples

Series

>>> s = pd.Series([2, np.nan, 5, -1, 0])
>>> s
0    2.0
1    NaN
2    5.0
3   -1.0
4    0.0
dtype: float64

By default, NA values are ignored.

>>> s.cummax()
0    2.0
1    NaN
2    5.0
3    5.0
4    5.0
dtype: float64

To include NA values in the operation, use skipna=False

>>> s.cummax(skipna=False)
0    2.0
1    NaN
2    NaN
3    NaN
4    NaN
dtype: float64

DataFrame

>>> df = pd.DataFrame(
...     [[2.0, 1.0], [3.0, np.nan], [1.0, 0.0]], columns=list("AB")
... )
>>> df
     A    B
0  2.0  1.0
1  3.0  NaN
2  1.0  0.0

By default, iterates over rows and finds the maximum in each column. This is equivalent to axis=None or axis='index'.

>>> df.cummax()
     A    B
0  2.0  1.0
1  3.0  NaN
2  3.0  1.0

To iterate over columns and find the maximum in each row, use axis=1

>>> df.cummax(axis=1)
     A    B
0  2.0  2.0
1  3.0  NaN
2  1.0  1.0
cummin(axis=0, skipna=True, numeric_only=False, *args, **kwargs)#

Return cumulative minimum over a DataFrame or Series axis.

Returns a DataFrame or Series of the same size containing the cumulative minimum.

Parameters:
  • axis ({0 or 'index', 1 or 'columns'}, default 0) – The index or the name of the axis. 0 is equivalent to None or ‘index’. For Series this parameter is unused and defaults to 0.

  • skipna (bool, default True) – Exclude NA/null values. If an entire row/column is NA, the result will be NA.

  • numeric_only (bool, default False) – Include only float, int, boolean columns.

  • *args – Additional keywords have no effect but might be accepted for compatibility with NumPy.

  • **kwargs – Additional keywords have no effect but might be accepted for compatibility with NumPy.

Returns:

Return cumulative minimum of Series or DataFrame.

Return type:

Series or DataFrame

See also

core.window.expanding.Expanding.min

Similar functionality but ignores NaN values.

DataFrame.min

Return the minimum over DataFrame axis.

DataFrame.cummax

Return cumulative maximum over DataFrame axis.

DataFrame.cummin

Return cumulative minimum over DataFrame axis.

DataFrame.cumsum

Return cumulative sum over DataFrame axis.

DataFrame.cumprod

Return cumulative product over DataFrame axis.

Examples

Series

>>> s = pd.Series([2, np.nan, 5, -1, 0])
>>> s
0    2.0
1    NaN
2    5.0
3   -1.0
4    0.0
dtype: float64

By default, NA values are ignored.

>>> s.cummin()
0    2.0
1    NaN
2    2.0
3   -1.0
4   -1.0
dtype: float64

To include NA values in the operation, use skipna=False

>>> s.cummin(skipna=False)
0    2.0
1    NaN
2    NaN
3    NaN
4    NaN
dtype: float64

DataFrame

>>> df = pd.DataFrame(
...     [[2.0, 1.0], [3.0, np.nan], [1.0, 0.0]], columns=list("AB")
... )
>>> df
     A    B
0  2.0  1.0
1  3.0  NaN
2  1.0  0.0

By default, iterates over rows and finds the minimum in each column. This is equivalent to axis=None or axis='index'.

>>> df.cummin()
     A    B
0  2.0  1.0
1  2.0  NaN
2  1.0  0.0

To iterate over columns and find the minimum in each row, use axis=1

>>> df.cummin(axis=1)
     A    B
0  2.0  1.0
1  3.0  NaN
2  1.0  0.0
cumprod(axis=0, skipna=True, numeric_only=False, *args, **kwargs)#

Return cumulative product over a DataFrame or Series axis.

Returns a DataFrame or Series of the same size containing the cumulative product.

Parameters:
  • axis ({0 or 'index', 1 or 'columns'}, default 0) – The index or the name of the axis. 0 is equivalent to None or ‘index’. For Series this parameter is unused and defaults to 0.

  • skipna (bool, default True) – Exclude NA/null values. If an entire row/column is NA, the result will be NA.

  • numeric_only (bool, default False) – Include only float, int, boolean columns.

  • *args – Additional keywords have no effect but might be accepted for compatibility with NumPy.

  • **kwargs – Additional keywords have no effect but might be accepted for compatibility with NumPy.

Returns:

Return cumulative product of Series or DataFrame.

Return type:

Series or DataFrame

See also

core.window.expanding.Expanding.prod

Similar functionality but ignores NaN values.

DataFrame.prod

Return the product over DataFrame axis.

DataFrame.cummax

Return cumulative maximum over DataFrame axis.

DataFrame.cummin

Return cumulative minimum over DataFrame axis.

DataFrame.cumsum

Return cumulative sum over DataFrame axis.

DataFrame.cumprod

Return cumulative product over DataFrame axis.

Examples

Series

>>> s = pd.Series([2, np.nan, 5, -1, 0])
>>> s
0    2.0
1    NaN
2    5.0
3   -1.0
4    0.0
dtype: float64

By default, NA values are ignored.

>>> s.cumprod()
0     2.0
1     NaN
2    10.0
3   -10.0
4    -0.0
dtype: float64

To include NA values in the operation, use skipna=False

>>> s.cumprod(skipna=False)
0    2.0
1    NaN
2    NaN
3    NaN
4    NaN
dtype: float64

DataFrame

>>> df = pd.DataFrame(
...     [[2.0, 1.0], [3.0, np.nan], [1.0, 0.0]], columns=list("AB")
... )
>>> df
     A    B
0  2.0  1.0
1  3.0  NaN
2  1.0  0.0

By default, iterates over rows and finds the product in each column. This is equivalent to axis=None or axis='index'.

>>> df.cumprod()
     A    B
0  2.0  1.0
1  6.0  NaN
2  6.0  0.0

To iterate over columns and find the product in each row, use axis=1

>>> df.cumprod(axis=1)
     A    B
0  2.0  2.0
1  3.0  NaN
2  1.0  0.0
cumsum(axis=0, skipna=True, numeric_only=False, *args, **kwargs)#

Return cumulative sum over a DataFrame or Series axis.

Returns a DataFrame or Series of the same size containing the cumulative sum.

Parameters:
  • axis ({0 or 'index', 1 or 'columns'}, default 0) – The index or the name of the axis. 0 is equivalent to None or ‘index’. For Series this parameter is unused and defaults to 0.

  • skipna (bool, default True) – Exclude NA/null values. If an entire row/column is NA, the result will be NA.

  • numeric_only (bool, default False) – Include only float, int, boolean columns.

  • *args – Additional keywords have no effect but might be accepted for compatibility with NumPy.

  • **kwargs – Additional keywords have no effect but might be accepted for compatibility with NumPy.

Returns:

Return cumulative sum of Series or DataFrame.

Return type:

Series or DataFrame

See also

core.window.expanding.Expanding.sum

Similar functionality but ignores NaN values.

DataFrame.sum

Return the sum over DataFrame axis.

DataFrame.cummax

Return cumulative maximum over DataFrame axis.

DataFrame.cummin

Return cumulative minimum over DataFrame axis.

DataFrame.cumsum

Return cumulative sum over DataFrame axis.

DataFrame.cumprod

Return cumulative product over DataFrame axis.

Examples

Series

>>> s = pd.Series([2, np.nan, 5, -1, 0])
>>> s
0    2.0
1    NaN
2    5.0
3   -1.0
4    0.0
dtype: float64

By default, NA values are ignored.

>>> s.cumsum()
0    2.0
1    NaN
2    7.0
3    6.0
4    6.0
dtype: float64

To include NA values in the operation, use skipna=False

>>> s.cumsum(skipna=False)
0    2.0
1    NaN
2    NaN
3    NaN
4    NaN
dtype: float64

DataFrame

>>> df = pd.DataFrame(
...     [[2.0, 1.0], [3.0, np.nan], [1.0, 0.0]], columns=list("AB")
... )
>>> df
     A    B
0  2.0  1.0
1  3.0  NaN
2  1.0  0.0

By default, iterates over rows and finds the sum in each column. This is equivalent to axis=None or axis='index'.

>>> df.cumsum()
     A    B
0  2.0  1.0
1  5.0  NaN
2  6.0  1.0

To iterate over columns and find the sum in each row, use axis=1

>>> df.cumsum(axis=1)
     A    B
0  2.0  3.0
1  3.0  NaN
2  1.0  1.0
diff(periods=1, axis=0)#

First discrete difference of element.

Calculates the difference of a DataFrame element compared with another element in the DataFrame (default is element in previous row).

Parameters:
  • periods (int, default 1) – Periods to shift for calculating difference, accepts negative values.

  • axis ({0 or 'index', 1 or 'columns'}, default 0) – Take difference over rows (0) or columns (1).

Returns:

First differences of the Series.

Return type:

DataFrame

See also

DataFrame.pct_change

Percent change over given number of periods.

DataFrame.shift

Shift index by desired number of periods with an optional time freq.

Series.diff

First discrete difference of object.

Notes

For boolean dtypes, this uses operator.xor() rather than operator.sub(). The result is calculated according to current dtype in DataFrame, however dtype of the result is always float64.

Examples

Difference with previous row

>>> df = pd.DataFrame(
...     {
...         "a": [1, 2, 3, 4, 5, 6],
...         "b": [1, 1, 2, 3, 5, 8],
...         "c": [1, 4, 9, 16, 25, 36],
...     }
... )
>>> df
   a  b   c
0  1  1   1
1  2  1   4
2  3  2   9
3  4  3  16
4  5  5  25
5  6  8  36
>>> df.diff()
     a    b     c
0  NaN  NaN   NaN
1  1.0  0.0   3.0
2  1.0  1.0   5.0
3  1.0  1.0   7.0
4  1.0  2.0   9.0
5  1.0  3.0  11.0

Difference with previous column

>>> df.diff(axis=1)
    a  b   c
0 NaN  0   0
1 NaN -1   3
2 NaN -1   7
3 NaN -1  13
4 NaN  0  20
5 NaN  2  28

Difference with 3rd previous row

>>> df.diff(periods=3)
     a    b     c
0  NaN  NaN   NaN
1  NaN  NaN   NaN
2  NaN  NaN   NaN
3  3.0  2.0  15.0
4  3.0  4.0  21.0
5  3.0  6.0  27.0

Difference with following row

>>> df.diff(periods=-1)
     a    b     c
0 -1.0  0.0  -3.0
1 -1.0 -1.0  -5.0
2 -1.0 -1.0  -7.0
3 -1.0 -2.0  -9.0
4 -1.0 -3.0 -11.0
5  NaN  NaN   NaN

Overflow in input dtype

>>> df = pd.DataFrame({"a": [1, 0]}, dtype=np.uint8)
>>> df.diff()
       a
0    NaN
1  255.0
div(other, axis='columns', level=None, fill_value=None)#

Get Floating division of dataframe and other, element-wise (binary operator truediv).

Equivalent to dataframe / other, but with support to substitute a fill_value for missing data in one of the inputs. With reverse version, rtruediv.

Among flexible wrappers (add, sub, mul, div, floordiv, mod, pow) to arithmetic operators: +, -, *, /, //, %, **.

Parameters:
  • other (scalar, sequence, Series, dict or DataFrame) – Any single or multiple element data structure, or list-like object.

  • axis ({0 or 'index', 1 or 'columns'}) – Whether to compare by the index (0 or ‘index’) or columns. (1 or ‘columns’). For Series input, axis to match Series index on.

  • level (int or label) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (float or None, default None) – Fill existing missing (NaN) values, and any new element needed for successful DataFrame alignment, with this value before computation. If data in both corresponding DataFrame locations is missing the result will be missing.

Returns:

Result of the arithmetic operation.

Return type:

DataFrame

See also

DataFrame.add

Add DataFrames.

DataFrame.sub

Subtract DataFrames.

DataFrame.mul

Multiply DataFrames.

DataFrame.div

Divide DataFrames (float division).

DataFrame.truediv

Divide DataFrames (float division).

DataFrame.floordiv

Divide DataFrames (integer division).

DataFrame.mod

Calculate modulo (remainder after division).

DataFrame.pow

Calculate exponential power.

Notes

Mismatched indices will be unioned together.

Examples

>>> df = pd.DataFrame({'angles': [0, 3, 4],
...                    'degrees': [360, 180, 360]},
...                   index=['circle', 'triangle', 'rectangle'])
>>> df
           angles  degrees
circle          0      360
triangle        3      180
rectangle       4      360

Add a scalar with operator version which return the same results.

>>> df + 1
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361
>>> df.add(1)
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361

Divide by constant with reverse version.

>>> df.div(10)
           angles  degrees
circle        0.0     36.0
triangle      0.3     18.0
rectangle     0.4     36.0
>>> df.rdiv(10)
             angles   degrees
circle          inf  0.027778
triangle   3.333333  0.055556
rectangle  2.500000  0.027778

Subtract a list and Series by axis with operator version.

>>> df - [1, 2]
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub([1, 2], axis='columns')
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub(pd.Series([1, 1, 1], index=['circle', 'triangle', 'rectangle']),
...        axis='index')
           angles  degrees
circle         -1      359
triangle        2      179
rectangle       3      359

Multiply a dictionary by axis.

>>> df.mul({'angles': 0, 'degrees': 2})
            angles  degrees
circle           0      720
triangle         0      360
rectangle        0      720
>>> df.mul({'circle': 0, 'triangle': 2, 'rectangle': 3}, axis='index')
            angles  degrees
circle           0        0
triangle         6      360
rectangle       12     1080

Multiply a DataFrame of different shape with operator version.

>>> other = pd.DataFrame({'angles': [0, 3, 4]},
...                      index=['circle', 'triangle', 'rectangle'])
>>> other
           angles
circle          0
triangle        3
rectangle       4
>>> df * other
           angles  degrees
circle          0      NaN
triangle        9      NaN
rectangle      16      NaN
>>> df.mul(other, fill_value=0)
           angles  degrees
circle          0      0.0
triangle        9      0.0
rectangle      16      0.0

Divide by a MultiIndex by level.

>>> df_multindex = pd.DataFrame({'angles': [0, 3, 4, 4, 5, 6],
...                              'degrees': [360, 180, 360, 360, 540, 720]},
...                             index=[['A', 'A', 'A', 'B', 'B', 'B'],
...                                    ['circle', 'triangle', 'rectangle',
...                                     'square', 'pentagon', 'hexagon']])
>>> df_multindex
             angles  degrees
A circle          0      360
  triangle        3      180
  rectangle       4      360
B square          4      360
  pentagon        5      540
  hexagon         6      720
>>> df.div(df_multindex, level=1, fill_value=0)
             angles  degrees
A circle        NaN      1.0
  triangle      1.0      1.0
  rectangle     1.0      1.0
B square        0.0      0.0
  pentagon      0.0      0.0
  hexagon       0.0      0.0
>>> df_pow = pd.DataFrame({'A': [2, 3, 4, 5],
...                        'B': [6, 7, 8, 9]})
>>> df_pow.pow(2)
    A   B
0   4  36
1   9  49
2  16  64
3  25  81
divide(other, axis='columns', level=None, fill_value=None)#

Get Floating division of dataframe and other, element-wise (binary operator truediv).

Equivalent to dataframe / other, but with support to substitute a fill_value for missing data in one of the inputs. With reverse version, rtruediv.

Among flexible wrappers (add, sub, mul, div, floordiv, mod, pow) to arithmetic operators: +, -, *, /, //, %, **.

Parameters:
  • other (scalar, sequence, Series, dict or DataFrame) – Any single or multiple element data structure, or list-like object.

  • axis ({0 or 'index', 1 or 'columns'}) – Whether to compare by the index (0 or ‘index’) or columns. (1 or ‘columns’). For Series input, axis to match Series index on.

  • level (int or label) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (float or None, default None) – Fill existing missing (NaN) values, and any new element needed for successful DataFrame alignment, with this value before computation. If data in both corresponding DataFrame locations is missing the result will be missing.

Returns:

Result of the arithmetic operation.

Return type:

DataFrame

See also

DataFrame.add

Add DataFrames.

DataFrame.sub

Subtract DataFrames.

DataFrame.mul

Multiply DataFrames.

DataFrame.div

Divide DataFrames (float division).

DataFrame.truediv

Divide DataFrames (float division).

DataFrame.floordiv

Divide DataFrames (integer division).

DataFrame.mod

Calculate modulo (remainder after division).

DataFrame.pow

Calculate exponential power.

Notes

Mismatched indices will be unioned together.

Examples

>>> df = pd.DataFrame({'angles': [0, 3, 4],
...                    'degrees': [360, 180, 360]},
...                   index=['circle', 'triangle', 'rectangle'])
>>> df
           angles  degrees
circle          0      360
triangle        3      180
rectangle       4      360

Add a scalar with operator version which return the same results.

>>> df + 1
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361
>>> df.add(1)
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361

Divide by constant with reverse version.

>>> df.div(10)
           angles  degrees
circle        0.0     36.0
triangle      0.3     18.0
rectangle     0.4     36.0
>>> df.rdiv(10)
             angles   degrees
circle          inf  0.027778
triangle   3.333333  0.055556
rectangle  2.500000  0.027778

Subtract a list and Series by axis with operator version.

>>> df - [1, 2]
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub([1, 2], axis='columns')
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub(pd.Series([1, 1, 1], index=['circle', 'triangle', 'rectangle']),
...        axis='index')
           angles  degrees
circle         -1      359
triangle        2      179
rectangle       3      359

Multiply a dictionary by axis.

>>> df.mul({'angles': 0, 'degrees': 2})
            angles  degrees
circle           0      720
triangle         0      360
rectangle        0      720
>>> df.mul({'circle': 0, 'triangle': 2, 'rectangle': 3}, axis='index')
            angles  degrees
circle           0        0
triangle         6      360
rectangle       12     1080

Multiply a DataFrame of different shape with operator version.

>>> other = pd.DataFrame({'angles': [0, 3, 4]},
...                      index=['circle', 'triangle', 'rectangle'])
>>> other
           angles
circle          0
triangle        3
rectangle       4
>>> df * other
           angles  degrees
circle          0      NaN
triangle        9      NaN
rectangle      16      NaN
>>> df.mul(other, fill_value=0)
           angles  degrees
circle          0      0.0
triangle        9      0.0
rectangle      16      0.0

Divide by a MultiIndex by level.

>>> df_multindex = pd.DataFrame({'angles': [0, 3, 4, 4, 5, 6],
...                              'degrees': [360, 180, 360, 360, 540, 720]},
...                             index=[['A', 'A', 'A', 'B', 'B', 'B'],
...                                    ['circle', 'triangle', 'rectangle',
...                                     'square', 'pentagon', 'hexagon']])
>>> df_multindex
             angles  degrees
A circle          0      360
  triangle        3      180
  rectangle       4      360
B square          4      360
  pentagon        5      540
  hexagon         6      720
>>> df.div(df_multindex, level=1, fill_value=0)
             angles  degrees
A circle        NaN      1.0
  triangle      1.0      1.0
  rectangle     1.0      1.0
B square        0.0      0.0
  pentagon      0.0      0.0
  hexagon       0.0      0.0
>>> df_pow = pd.DataFrame({'A': [2, 3, 4, 5],
...                        'B': [6, 7, 8, 9]})
>>> df_pow.pow(2)
    A   B
0   4  36
1   9  49
2  16  64
3  25  81
dot(other: Series) Series#
dot(other: DataFrame | Index | ArrayLike) DataFrame

Compute the matrix multiplication between the DataFrame and other.

This method computes the matrix product between the DataFrame and the values of an other Series, DataFrame or a numpy array.

It can also be called using self @ other.

Parameters:

other (Series, DataFrame or array-like) – The other object to compute the matrix product with.

Returns:

If other is a Series, return the matrix product between self and other as a Series. If other is a DataFrame or a numpy.array, return the matrix product of self and other in a DataFrame of a np.array.

Return type:

Series or DataFrame

See also

Series.dot

Similar method for Series.

Notes

The dimensions of DataFrame and other must be compatible in order to compute the matrix multiplication. In addition, the column names of DataFrame and the index of other must contain the same values, as they will be aligned prior to the multiplication.

The dot method for Series computes the inner product, instead of the matrix product here.

Examples

Here we multiply a DataFrame with a Series.

>>> df = pd.DataFrame([[0, 1, -2, -1], [1, 1, 1, 1]])
>>> s = pd.Series([1, 1, 2, 1])
>>> df.dot(s)
0    -4
1     5
dtype: int64

Here we multiply a DataFrame with another DataFrame.

>>> other = pd.DataFrame([[0, 1], [1, 2], [-1, -1], [2, 0]])
>>> df.dot(other)
    0   1
0   1   4
1   2   2

Note that the dot method give the same result as @

>>> df @ other
    0   1
0   1   4
1   2   2

The dot method works also if other is an np.array.

>>> arr = np.array([[0, 1], [1, 2], [-1, -1], [2, 0]])
>>> df.dot(arr)
    0   1
0   1   4
1   2   2

Note how shuffling of the objects does not change the result.

>>> s2 = s.reindex([1, 0, 2, 3])
>>> df.dot(s2)
0    -4
1     5
dtype: int64
drop(labels: IndexLabel | ListLike = None, *, axis: Axis = 0, index: IndexLabel | ListLike = None, columns: IndexLabel | ListLike = None, level: Level = None, inplace: Literal[True], errors: IgnoreRaise = 'raise') None#
drop(labels: IndexLabel | ListLike = None, *, axis: Axis = 0, index: IndexLabel | ListLike = None, columns: IndexLabel | ListLike = None, level: Level = None, inplace: Literal[False] = False, errors: IgnoreRaise = 'raise') DataFrame
drop(labels: IndexLabel | ListLike = None, *, axis: Axis = 0, index: IndexLabel | ListLike = None, columns: IndexLabel | ListLike = None, level: Level = None, inplace: bool = False, errors: IgnoreRaise = 'raise') DataFrame | None

Drop specified labels from rows or columns.

Remove rows or columns by specifying label names and corresponding axis, or by directly specifying index or column names. When using a multi-index, labels on different levels can be removed by specifying the level. See the user guide for more information about the now unused levels.

Parameters:
  • labels (single label or iterable of labels) – Index or column labels to drop. A tuple will be used as a single label and not treated as an iterable.

  • axis ({0 or 'index', 1 or 'columns'}, default 0) – Whether to drop labels from the index (0 or ‘index’) or columns (1 or ‘columns’).

  • index (single label or iterable of labels) – Alternative to specifying axis (labels, axis=0 is equivalent to index=labels).

  • columns (single label or iterable of labels) – Alternative to specifying axis (labels, axis=1 is equivalent to columns=labels).

  • level (int or level name, optional) – For MultiIndex, level from which the labels will be removed.

  • inplace (bool, default False) – If False, return a copy. Otherwise, do operation in place and return None.

  • errors ({'ignore', 'raise'}, default 'raise') – If ‘ignore’, suppress error and only existing labels are dropped.

Returns:

Returns DataFrame or None DataFrame with the specified index or column labels removed or None if inplace=True.

Return type:

DataFrame or None

Raises:

KeyError – If any of the labels is not found in the selected axis.

See also

DataFrame.loc

Label-location based indexer for selection by label.

DataFrame.dropna

Return DataFrame with labels on given axis omitted where (all or any) data are missing.

DataFrame.drop_duplicates

Return DataFrame with duplicate rows removed, optionally only considering certain columns.

Series.drop

Return Series with specified index labels removed.

Examples

>>> df = pd.DataFrame(np.arange(12).reshape(3, 4), columns=["A", "B", "C", "D"])
>>> df
   A  B   C   D
0  0  1   2   3
1  4  5   6   7
2  8  9  10  11

Drop columns

>>> df.drop(["B", "C"], axis=1)
   A   D
0  0   3
1  4   7
2  8  11
>>> df.drop(columns=["B", "C"])
   A   D
0  0   3
1  4   7
2  8  11

Drop a row by index

>>> df.drop([0, 1])
   A  B   C   D
2  8  9  10  11

Drop columns and/or rows of MultiIndex DataFrame

>>> midx = pd.MultiIndex(
...     levels=[["llama", "cow", "falcon"], ["speed", "weight", "length"]],
...     codes=[[0, 0, 0, 1, 1, 1, 2, 2, 2], [0, 1, 2, 0, 1, 2, 0, 1, 2]],
... )
>>> df = pd.DataFrame(
...     index=midx,
...     columns=["big", "small"],
...     data=[
...         [45, 30],
...         [200, 100],
...         [1.5, 1],
...         [30, 20],
...         [250, 150],
...         [1.5, 0.8],
...         [320, 250],
...         [1, 0.8],
...         [0.3, 0.2],
...     ],
... )
>>> df
                big     small
llama   speed   45.0    30.0
        weight  200.0   100.0
        length  1.5     1.0
cow     speed   30.0    20.0
        weight  250.0   150.0
        length  1.5     0.8
falcon  speed   320.0   250.0
        weight  1.0     0.8
        length  0.3     0.2

Drop a specific index combination from the MultiIndex DataFrame, i.e., drop the combination 'falcon' and 'weight', which deletes only the corresponding row

>>> df.drop(index=("falcon", "weight"))
                big     small
llama   speed   45.0    30.0
        weight  200.0   100.0
        length  1.5     1.0
cow     speed   30.0    20.0
        weight  250.0   150.0
        length  1.5     0.8
falcon  speed   320.0   250.0
        length  0.3     0.2
>>> df.drop(index="cow", columns="small")
                big
llama   speed   45.0
        weight  200.0
        length  1.5
falcon  speed   320.0
        weight  1.0
        length  0.3
>>> df.drop(index="length", level=1)
                big     small
llama   speed   45.0    30.0
        weight  200.0   100.0
cow     speed   30.0    20.0
        weight  250.0   150.0
falcon  speed   320.0   250.0
        weight  1.0     0.8
drop_duplicates(subset: Hashable | Iterable[Hashable] | None = None, *, keep: DropKeep = 'first', inplace: Literal[True], ignore_index: bool = False) None#
drop_duplicates(subset: Hashable | Iterable[Hashable] | None = None, *, keep: DropKeep = 'first', inplace: Literal[False] = False, ignore_index: bool = False) DataFrame
drop_duplicates(subset: Hashable | Iterable[Hashable] | None = None, *, keep: DropKeep = 'first', inplace: bool = False, ignore_index: bool = False) DataFrame | None

Return DataFrame with duplicate rows removed.

Considering certain columns is optional. Indexes, including time indexes are ignored.

Parameters:
  • subset (column label or iterable of labels, optional) – Only consider certain columns for identifying duplicates, by default use all of the columns.

  • keep ({‘first’, ‘last’, False}, default ‘first’) –

    Determines which duplicates (if any) to keep.

    • ’first’ : Drop duplicates except for the first occurrence.

    • ’last’ : Drop duplicates except for the last occurrence.

    • False : Drop all duplicates.

  • inplace (bool, default False) – Whether to modify the DataFrame rather than creating a new one.

  • ignore_index (bool, default False) – If True, the resulting axis will be labeled 0, 1, …, n - 1.

Returns:

DataFrame with duplicates removed or None if inplace=True.

Return type:

DataFrame or None

See also

DataFrame.value_counts

Count unique combinations of columns.

Notes

This method requires columns specified by subset to be of hashable type. Passing unhashable columns will raise a TypeError.

Examples

Consider dataset containing ramen rating.

>>> df = pd.DataFrame(
...     {
...         "brand": ["Yum Yum", "Yum Yum", "Indomie", "Indomie", "Indomie"],
...         "style": ["cup", "cup", "cup", "pack", "pack"],
...         "rating": [4, 4, 3.5, 15, 5],
...     }
... )
>>> df
    brand style  rating
0  Yum Yum   cup     4.0
1  Yum Yum   cup     4.0
2  Indomie   cup     3.5
3  Indomie  pack    15.0
4  Indomie  pack     5.0

By default, it removes duplicate rows based on all columns.

>>> df.drop_duplicates()
    brand style  rating
0  Yum Yum   cup     4.0
2  Indomie   cup     3.5
3  Indomie  pack    15.0
4  Indomie  pack     5.0

To remove duplicates on specific column(s), use subset.

>>> df.drop_duplicates(subset=["brand"])
    brand style  rating
0  Yum Yum   cup     4.0
2  Indomie   cup     3.5

To remove duplicates and keep last occurrences, use keep.

>>> df.drop_duplicates(subset=["brand", "style"], keep="last")
    brand style  rating
1  Yum Yum   cup     4.0
2  Indomie   cup     3.5
4  Indomie  pack     5.0
dropna(*, axis: Axis = 0, how: AnyAll | lib.NoDefault = <no_default>, thresh: int | Literal[_NoDefault.no_default] = <no_default>, subset: IndexLabel = None, inplace: Literal[False] = False, ignore_index: bool = False) DataFrame#
dropna(*, axis: Axis = 0, how: AnyAll | lib.NoDefault = <no_default>, thresh: int | ~pandas.api.typing.Literal[_NoDefault.no_default] = <no_default>, subset: IndexLabel = None, inplace: ~typing.Literal[True], ignore_index: bool = False) None

Remove missing values.

See the User Guide for more on which values are considered missing, and how to work with missing data.

Parameters:
  • axis ({0 or 'index', 1 or 'columns'}, default 0) –

    Determine if rows or columns which contain missing values are removed.

    • 0, or ‘index’ : Drop rows which contain missing values.

    • 1, or ‘columns’ : Drop columns which contain missing value.

    Only a single axis is allowed.

  • how ({'any', 'all'}, default 'any') –

    Determine if row or column is removed from DataFrame, when we have at least one NA or all NA.

    • ’any’ : If any NA values are present, drop that row or column.

    • ’all’ : If all values are NA, drop that row or column.

  • thresh (int, optional) – Require that many non-NA values. Cannot be combined with how.

  • subset (column label or iterable of labels, optional) – Labels along other axis to consider, e.g. if you are dropping rows these would be a list of columns to include.

  • inplace (bool, default False) – Whether to modify the DataFrame rather than creating a new one.

  • ignore_index (bool, default False) –

    If True, the resulting axis will be labeled 0, 1, …, n - 1.

    Added in version 2.0.0.

Returns:

DataFrame with NA entries dropped from it or None if inplace=True.

Return type:

DataFrame or None

See also

DataFrame.isna

Indicate missing values.

DataFrame.notna

Indicate existing (non-missing) values.

DataFrame.fillna

Replace missing values.

Series.dropna

Drop missing values.

Index.dropna

Drop missing indices.

Examples

>>> df = pd.DataFrame(
...     {
...         "name": ["Alfred", "Batman", "Catwoman"],
...         "toy": [np.nan, "Batmobile", "Bullwhip"],
...         "born": [pd.NaT, pd.Timestamp("1940-04-25"), pd.NaT],
...     }
... )
>>> df
       name        toy       born
0    Alfred        NaN        NaT
1    Batman  Batmobile 1940-04-25
2  Catwoman   Bullwhip        NaT

Drop the rows where at least one element is missing.

>>> df.dropna()
     name        toy       born
1  Batman  Batmobile 1940-04-25

Drop the columns where at least one element is missing.

>>> df.dropna(axis="columns")
       name
0    Alfred
1    Batman
2  Catwoman

Drop the rows where all elements are missing.

>>> df.dropna(how="all")
       name        toy       born
0    Alfred        NaN        NaT
1    Batman  Batmobile 1940-04-25
2  Catwoman   Bullwhip        NaT

Keep only the rows with at least 2 non-NA values.

>>> df.dropna(thresh=2)
       name        toy       born
1    Batman  Batmobile 1940-04-25
2  Catwoman   Bullwhip        NaT

Define in which columns to look for missing values.

>>> df.dropna(subset=["name", "toy"])
       name        toy       born
1    Batman  Batmobile 1940-04-25
2  Catwoman   Bullwhip        NaT
duplicated(subset=None, keep='first')#

Return boolean Series denoting duplicate rows.

Considering certain columns is optional.

Parameters:
  • subset (column label or iterable of labels, optional) – Only consider certain columns for identifying duplicates, by default use all of the columns.

  • keep ({'first', 'last', False}, default 'first') –

    Determines which duplicates (if any) to mark.

    • first : Mark duplicates as True except for the first occurrence.

    • last : Mark duplicates as True except for the last occurrence.

    • False : Mark all duplicates as True.

Returns:

Boolean series for each duplicated rows.

Return type:

Series

See also

Index.duplicated

Equivalent method on index.

Series.duplicated

Equivalent method on Series.

Series.drop_duplicates

Remove duplicate values from Series.

DataFrame.drop_duplicates

Remove duplicate values from DataFrame.

Examples

Consider dataset containing ramen rating.

>>> df = pd.DataFrame(
...     {
...         "brand": ["Yum Yum", "Yum Yum", "Indomie", "Indomie", "Indomie"],
...         "style": ["cup", "cup", "cup", "pack", "pack"],
...         "rating": [4, 4, 3.5, 15, 5],
...     }
... )
>>> df
    brand style  rating
0  Yum Yum   cup     4.0
1  Yum Yum   cup     4.0
2  Indomie   cup     3.5
3  Indomie  pack    15.0
4  Indomie  pack     5.0

By default, for each set of duplicated values, the first occurrence is set on False and all others on True.

>>> df.duplicated()
0    False
1     True
2    False
3    False
4    False
dtype: bool

By using ‘last’, the last occurrence of each set of duplicated values is set on False and all others on True.

>>> df.duplicated(keep="last")
0     True
1    False
2    False
3    False
4    False
dtype: bool

By setting keep on False, all duplicates are True.

>>> df.duplicated(keep=False)
0     True
1     True
2    False
3    False
4    False
dtype: bool

To find duplicates on specific column(s), use subset.

>>> df.duplicated(subset=["brand"])
0    False
1     True
2    False
3     True
4     True
dtype: bool
eq(other, axis='columns', level=None)#

Get Not equal to of dataframe and other, element-wise (binary operator eq).

Among flexible wrappers (eq, ne, le, lt, ge, gt) to comparison operators.

Equivalent to ==, !=, <=, <, >=, > with support to choose axis (rows or columns) and level for comparison.

Parameters:
  • other (scalar, sequence, Series, or DataFrame) – Any single or multiple element data structure, or list-like object.

  • axis ({0 or 'index', 1 or 'columns'}, default 'columns') – Whether to compare by the index (0 or ‘index’) or columns (1 or ‘columns’).

  • level (int or label) – Broadcast across a level, matching Index values on the passed MultiIndex level.

Returns:

Result of the comparison.

Return type:

DataFrame of bool

See also

DataFrame.eq

Compare DataFrames for equality elementwise.

DataFrame.ne

Compare DataFrames for inequality elementwise.

DataFrame.le

Compare DataFrames for less than inequality or equality elementwise.

DataFrame.lt

Compare DataFrames for strictly less than inequality elementwise.

DataFrame.ge

Compare DataFrames for greater than inequality or equality elementwise.

DataFrame.gt

Compare DataFrames for strictly greater than inequality elementwise.

Notes

Mismatched indices will be unioned together. NaN values are considered different (i.e. NaN != NaN).

Examples

>>> df = pd.DataFrame(
...     {"cost": [250, 150, 100], "revenue": [100, 250, 300]},
...     index=["A", "B", "C"],
... )
>>> df
   cost  revenue
A   250      100
B   150      250
C   100      300

Comparison with a scalar, using either the operator or method:

>>> df == 100
    cost  revenue
A  False     True
B  False    False
C   True    False
>>> df.eq(100)
    cost  revenue
A  False     True
B  False    False
C   True    False

When other is a Series, the columns of a DataFrame are aligned with the index of other and broadcast:

>>> df != pd.Series([100, 250], index=["cost", "revenue"])
    cost  revenue
A   True     True
B   True    False
C  False     True

Use the method to control the broadcast axis:

>>> df.ne(pd.Series([100, 300], index=["A", "D"]), axis="index")
   cost  revenue
A  True    False
B  True     True
C  True     True
D  True     True

When comparing to an arbitrary sequence, the number of columns must match the number elements in other:

>>> df == [250, 100]
    cost  revenue
A   True     True
B  False    False
C  False    False

Use the method to control the axis:

>>> df.eq([250, 250, 100], axis="index")
    cost  revenue
A   True    False
B  False     True
C   True    False

Compare to a DataFrame of different shape.

>>> other = pd.DataFrame(
...     {"revenue": [300, 250, 100, 150]}, index=["A", "B", "C", "D"]
... )
>>> other
   revenue
A      300
B      250
C      100
D      150
>>> df.gt(other)
    cost  revenue
A  False    False
B  False    False
C  False     True
D  False    False

Compare to a MultiIndex by level.

>>> df_multindex = pd.DataFrame(
...     {
...         "cost": [250, 150, 100, 150, 300, 220],
...         "revenue": [100, 250, 300, 200, 175, 225],
...     },
...     index=[
...         ["Q1", "Q1", "Q1", "Q2", "Q2", "Q2"],
...         ["A", "B", "C", "A", "B", "C"],
...     ],
... )
>>> df_multindex
      cost  revenue
Q1 A   250      100
   B   150      250
   C   100      300
Q2 A   150      200
   B   300      175
   C   220      225
>>> df.le(df_multindex, level=1)
       cost  revenue
Q1 A   True     True
   B   True     True
   C   True     True
Q2 A  False     True
   B   True    False
   C   True    False
eval(expr: str, *, inplace: Literal[False] = False, **kwargs) Any#
eval(expr: str, *, inplace: Literal[True], **kwargs) None

Evaluate a string describing operations on DataFrame columns.

Warning

This method can run arbitrary code which can make you vulnerable to code injection if you pass user input to this function.

Operates on columns only, not specific rows or elements. This allows eval to run arbitrary code, which can make you vulnerable to code injection if you pass user input to this function.

Parameters:
  • expr (str) –

    The expression string to evaluate.

    You can refer to variables in the environment by prefixing them with an ‘@’ character like @a + b.

    You can refer to column names that are not valid Python variable names by surrounding them in backticks. Thus, column names containing spaces or punctuation (besides underscores) or starting with digits must be surrounded by backticks. (For example, a column named “Area (cm^2)” would be referenced as `Area (cm^2)`). Column names which are Python keywords (like “if”, “for”, “import”, etc) cannot be used.

    For example, if one of your columns is called a a and you want to sum it with b, your query should be `a a` + b.

    See the documentation for eval() for full details of supported operations and functions in the expression string.

  • inplace (bool, default False) – If the expression contains an assignment, whether to perform the operation inplace and mutate the existing DataFrame. Otherwise, a new DataFrame is returned.

  • **kwargs – See the documentation for eval() for complete details on the keyword arguments accepted by eval().

Returns:

The result of the evaluation or None if inplace=True.

Return type:

ndarray, scalar, pandas object, or None

See also

DataFrame.query

Evaluates a boolean expression to query the columns of a frame.

DataFrame.assign

Can evaluate an expression or function to create new values for a column.

eval

Evaluate a Python expression as a string using various backends.

Notes

For more details see the API documentation for eval(). For detailed examples see enhancing performance with eval.

Examples

>>> df = pd.DataFrame(
...     {"A": range(1, 6), "B": range(10, 0, -2), "C&C": range(10, 5, -1)}
... )
>>> df
   A   B  C&C
0  1  10   10
1  2   8    9
2  3   6    8
3  4   4    7
4  5   2    6
>>> df.eval("A + B")
0    11
1    10
2     9
3     8
4     7
dtype: int64

Assignment is allowed though by default the original DataFrame is not modified.

>>> df.eval("D = A + B")
   A   B  C&C   D
0  1  10   10  11
1  2   8    9  10
2  3   6    8   9
3  4   4    7   8
4  5   2    6   7
>>> df
   A   B  C&C
0  1  10   10
1  2   8    9
2  3   6    8
3  4   4    7
4  5   2    6

Multiple columns can be assigned to using multi-line expressions:

>>> df.eval(
...     '''
... D = A + B
... E = A - B
... '''
... )
   A   B  C&C   D  E
0  1  10   10  11 -9
1  2   8    9  10 -6
2  3   6    8   9 -3
3  4   4    7   8  0
4  5   2    6   7  3

For columns with spaces or other disallowed characters in their name, you can use backtick quoting.

>>> df.eval("B * `C&C`")
0    100
1     72
2     48
3     28
4     12
dtype: int64

Local variables shall be explicitly referenced using @ character in front of the name:

>>> local_var = 2
>>> df.eval("@local_var * A")
0     2
1     4
2     6
3     8
4    10
Name: A, dtype: int64
explode(column, ignore_index=False)#

Transform each element of a list-like to a row, replicating index values.

Parameters:
  • column (IndexLabel) – Column(s) to explode. For multiple columns, specify a non-empty list with each element be str or tuple, and all specified columns their list-like data on same row of the frame must have matching length.

  • ignore_index (bool, default False) – If True, the resulting index will be labeled 0, 1, …, n - 1.

Returns:

Exploded lists to rows of the subset columns; index will be duplicated for these rows.

Return type:

DataFrame

Raises:

ValueError :

  • If columns of the frame are not unique. * If specified columns to explode is empty list. * If specified columns to explode have not matching count of elements rowwise in the frame.

See also

DataFrame.unstack

Pivot a level of the (necessarily hierarchical) index labels.

DataFrame.melt

Unpivot a DataFrame from wide format to long format.

Series.explode

Explode a DataFrame from list-like columns to long format.

Notes

This routine will explode list-likes including lists, tuples, sets, Series, and np.ndarray. The result dtype of the subset rows will be object. Scalars will be returned unchanged, and empty list-likes will result in a np.nan for that row. In addition, the ordering of rows in the output will be non-deterministic when exploding sets.

Reference the user guide for more examples.

Examples

>>> df = pd.DataFrame(
...     {
...         "A": [[0, 1, 2], "foo", [], [3, 4]],
...         "B": 1,
...         "C": [["a", "b", "c"], np.nan, [], ["d", "e"]],
...     }
... )
>>> df
           A  B          C
0  [0, 1, 2]  1  [a, b, c]
1        foo  1        NaN
2         []  1         []
3     [3, 4]  1     [d, e]

Single-column explode.

>>> df.explode("A")
     A  B          C
0    0  1  [a, b, c]
0    1  1  [a, b, c]
0    2  1  [a, b, c]
1  foo  1        NaN
2  NaN  1         []
3    3  1     [d, e]
3    4  1     [d, e]

Multi-column explode.

>>> df.explode(list("AC"))
     A  B    C
0    0  1    a
0    1  1    b
0    2  1    c
1  foo  1  NaN
2  NaN  1  NaN
3    3  1    d
3    4  1    e
floordiv(other, axis='columns', level=None, fill_value=None)#

Get Integer division of dataframe and other, element-wise (binary operator floordiv).

Equivalent to dataframe // other, but with support to substitute a fill_value for missing data in one of the inputs. With reverse version, rfloordiv.

Among flexible wrappers (add, sub, mul, div, floordiv, mod, pow) to arithmetic operators: +, -, *, /, //, %, **.

Parameters:
  • other (scalar, sequence, Series, dict or DataFrame) – Any single or multiple element data structure, or list-like object.

  • axis ({0 or 'index', 1 or 'columns'}) – Whether to compare by the index (0 or ‘index’) or columns. (1 or ‘columns’). For Series input, axis to match Series index on.

  • level (int or label) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (float or None, default None) – Fill existing missing (NaN) values, and any new element needed for successful DataFrame alignment, with this value before computation. If data in both corresponding DataFrame locations is missing the result will be missing.

Returns:

Result of the arithmetic operation.

Return type:

DataFrame

See also

DataFrame.add

Add DataFrames.

DataFrame.sub

Subtract DataFrames.

DataFrame.mul

Multiply DataFrames.

DataFrame.div

Divide DataFrames (float division).

DataFrame.truediv

Divide DataFrames (float division).

DataFrame.floordiv

Divide DataFrames (integer division).

DataFrame.mod

Calculate modulo (remainder after division).

DataFrame.pow

Calculate exponential power.

Notes

Mismatched indices will be unioned together.

Examples

>>> df = pd.DataFrame({'angles': [0, 3, 4],
...                    'degrees': [360, 180, 360]},
...                   index=['circle', 'triangle', 'rectangle'])
>>> df
           angles  degrees
circle          0      360
triangle        3      180
rectangle       4      360

Add a scalar with operator version which return the same results.

>>> df + 1
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361
>>> df.add(1)
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361

Divide by constant with reverse version.

>>> df.div(10)
           angles  degrees
circle        0.0     36.0
triangle      0.3     18.0
rectangle     0.4     36.0
>>> df.rdiv(10)
             angles   degrees
circle          inf  0.027778
triangle   3.333333  0.055556
rectangle  2.500000  0.027778

Subtract a list and Series by axis with operator version.

>>> df - [1, 2]
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub([1, 2], axis='columns')
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub(pd.Series([1, 1, 1], index=['circle', 'triangle', 'rectangle']),
...        axis='index')
           angles  degrees
circle         -1      359
triangle        2      179
rectangle       3      359

Multiply a dictionary by axis.

>>> df.mul({'angles': 0, 'degrees': 2})
            angles  degrees
circle           0      720
triangle         0      360
rectangle        0      720
>>> df.mul({'circle': 0, 'triangle': 2, 'rectangle': 3}, axis='index')
            angles  degrees
circle           0        0
triangle         6      360
rectangle       12     1080

Multiply a DataFrame of different shape with operator version.

>>> other = pd.DataFrame({'angles': [0, 3, 4]},
...                      index=['circle', 'triangle', 'rectangle'])
>>> other
           angles
circle          0
triangle        3
rectangle       4
>>> df * other
           angles  degrees
circle          0      NaN
triangle        9      NaN
rectangle      16      NaN
>>> df.mul(other, fill_value=0)
           angles  degrees
circle          0      0.0
triangle        9      0.0
rectangle      16      0.0

Divide by a MultiIndex by level.

>>> df_multindex = pd.DataFrame({'angles': [0, 3, 4, 4, 5, 6],
...                              'degrees': [360, 180, 360, 360, 540, 720]},
...                             index=[['A', 'A', 'A', 'B', 'B', 'B'],
...                                    ['circle', 'triangle', 'rectangle',
...                                     'square', 'pentagon', 'hexagon']])
>>> df_multindex
             angles  degrees
A circle          0      360
  triangle        3      180
  rectangle       4      360
B square          4      360
  pentagon        5      540
  hexagon         6      720
>>> df.div(df_multindex, level=1, fill_value=0)
             angles  degrees
A circle        NaN      1.0
  triangle      1.0      1.0
  rectangle     1.0      1.0
B square        0.0      0.0
  pentagon      0.0      0.0
  hexagon       0.0      0.0
>>> df_pow = pd.DataFrame({'A': [2, 3, 4, 5],
...                        'B': [6, 7, 8, 9]})
>>> df_pow.pow(2)
    A   B
0   4  36
1   9  49
2  16  64
3  25  81
classmethod from_arrow(data)#

Construct a DataFrame from a tabular Arrow object.

This function accepts any Arrow-compatible tabular object implementing the Arrow PyCapsule Protocol (i.e. having an __arrow_c_array__ or __arrow_c_stream__ method).

This function currently relies on pyarrow to convert the tabular object in Arrow format to pandas.

Added in version 3.0.

Parameters:

data (pyarrow.Table or Arrow-compatible table) – Any tabular object implementing the Arrow PyCapsule Protocol (i.e. has an __arrow_c_array__ or __arrow_c_stream__ method).

Return type:

DataFrame

See also

Series.from_arrow

Construct a Series from an Arrow object.

Examples

>>> import pyarrow as pa
>>> table = pa.table({"a": [1, 2, 3], "b": ["x", "y", "z"]})
>>> pd.DataFrame.from_arrow(table)
   a  b
0  1  x
1  2  y
2  3  z
classmethod from_dict(data, orient='columns', dtype=None, columns=None)#

Construct DataFrame from dict of array-like or dicts.

Creates DataFrame object from dictionary by columns or by index allowing dtype specification.

Parameters:
  • data (dict) – Of the form {field : array-like} or {field : dict}.

  • orient ({'columns', 'index', 'tight'}, default 'columns') – The “orientation” of the data. If the keys of the passed dict should be the columns of the resulting DataFrame, pass ‘columns’ (default). Otherwise if the keys should be rows, pass ‘index’. If ‘tight’, assume a dict with keys [‘index’, ‘columns’, ‘data’, ‘index_names’, ‘column_names’].

  • dtype (dtype, default None) – Data type to force after DataFrame construction, otherwise infer.

  • columns (list, default None) – Column labels to use when orient='index'. Raises a ValueError if used with orient='columns' or orient='tight'.

Return type:

DataFrame

See also

DataFrame.from_records

DataFrame from structured ndarray, sequence of tuples or dicts, or DataFrame.

DataFrame

DataFrame object creation using constructor.

DataFrame.to_dict

Convert the DataFrame to a dictionary.

Examples

By default the keys of the dict become the DataFrame columns:

>>> data = {"col_1": [3, 2, 1, 0], "col_2": ["a", "b", "c", "d"]}
>>> pd.DataFrame.from_dict(data)
   col_1 col_2
0      3     a
1      2     b
2      1     c
3      0     d

Specify orient='index' to create the DataFrame using dictionary keys as rows:

>>> data = {"row_1": [3, 2, 1, 0], "row_2": ["a", "b", "c", "d"]}
>>> pd.DataFrame.from_dict(data, orient="index")
       0  1  2  3
row_1  3  2  1  0
row_2  a  b  c  d

When using the ‘index’ orientation, the column names can be specified manually:

>>> pd.DataFrame.from_dict(data, orient="index", columns=["A", "B", "C", "D"])
       A  B  C  D
row_1  3  2  1  0
row_2  a  b  c  d

Specify orient='tight' to create the DataFrame using a ‘tight’ format:

>>> data = {
...     "index": [("a", "b"), ("a", "c")],
...     "columns": [("x", 1), ("y", 2)],
...     "data": [[1, 3], [2, 4]],
...     "index_names": ["n1", "n2"],
...     "column_names": ["z1", "z2"],
... }
>>> pd.DataFrame.from_dict(data, orient="tight")
z1     x  y
z2     1  2
n1 n2
a  b   1  3
   c   2  4
classmethod from_records(data, index=None, exclude=None, columns=None, coerce_float=False, nrows=None)#

Convert structured or record ndarray to DataFrame.

Creates a DataFrame object from a structured ndarray, or iterable of tuples or dicts.

Parameters:
  • data (structured ndarray, iterable of tuples or dicts) – Structured input data.

  • index (str, list of fields, array-like) – Field of array to use as the index, alternately a specific set of input labels to use.

  • exclude (sequence, default None) – Columns or fields to exclude.

  • columns (sequence, default None) – Column names to use. If the passed data do not have names associated with them, this argument provides names for the columns. Otherwise, this argument indicates the order of the columns in the result (any names not found in the data will become all-NA columns) and limits the data to these columns if not all column names are provided.

  • coerce_float (bool, default False) – Attempt to convert values of non-string, non-numeric objects (like decimal.Decimal) to floating point, useful for SQL result sets.

  • nrows (int, default None) – Number of rows to read if data is an iterator.

Return type:

DataFrame

See also

DataFrame.from_dict

DataFrame from dict of array-like or dicts.

DataFrame

DataFrame object creation using constructor.

Examples

Data can be provided as a structured ndarray:

>>> data = np.array(
...     [(3, "a"), (2, "b"), (1, "c"), (0, "d")],
...     dtype=[("col_1", "i4"), ("col_2", "U1")],
... )
>>> pd.DataFrame.from_records(data)
   col_1 col_2
0      3     a
1      2     b
2      1     c
3      0     d

Data can be provided as a list of dicts:

>>> data = [
...     {"col_1": 3, "col_2": "a"},
...     {"col_1": 2, "col_2": "b"},
...     {"col_1": 1, "col_2": "c"},
...     {"col_1": 0, "col_2": "d"},
... ]
>>> pd.DataFrame.from_records(data)
   col_1 col_2
0      3     a
1      2     b
2      1     c
3      0     d

Data can be provided as a list of tuples with corresponding columns:

>>> data = [(3, "a"), (2, "b"), (1, "c"), (0, "d")]
>>> pd.DataFrame.from_records(data, columns=["col_1", "col_2"])
   col_1 col_2
0      3     a
1      2     b
2      1     c
3      0     d
ge(other, axis='columns', level=None)#

Get Greater than or equal to of dataframe and other, element-wise (binary operator ge).

Among flexible wrappers (eq, ne, le, lt, ge, gt) to comparison operators.

Equivalent to ==, !=, <=, <, >=, > with support to choose axis (rows or columns) and level for comparison.

Parameters:
  • other (scalar, sequence, Series, or DataFrame) – Any single or multiple element data structure, or list-like object.

  • axis ({0 or 'index', 1 or 'columns'}, default 'columns') – Whether to compare by the index (0 or ‘index’) or columns (1 or ‘columns’).

  • level (int or label) – Broadcast across a level, matching Index values on the passed MultiIndex level.

Returns:

Result of the comparison.

Return type:

DataFrame of bool

See also

DataFrame.eq

Compare DataFrames for equality elementwise.

DataFrame.ne

Compare DataFrames for inequality elementwise.

DataFrame.le

Compare DataFrames for less than inequality or equality elementwise.

DataFrame.lt

Compare DataFrames for strictly less than inequality elementwise.

DataFrame.ge

Compare DataFrames for greater than inequality or equality elementwise.

DataFrame.gt

Compare DataFrames for strictly greater than inequality elementwise.

Notes

Mismatched indices will be unioned together. NaN values are considered different (i.e. NaN != NaN).

Examples

>>> df = pd.DataFrame({'cost': [250, 150, 100],
...                    'revenue': [100, 250, 300]},
...                   index=['A', 'B', 'C'])
>>> df
   cost  revenue
A   250      100
B   150      250
C   100      300

Comparison with a scalar, using either the operator or method:

>>> df == 100
    cost  revenue
A  False     True
B  False    False
C   True    False
>>> df.eq(100)
    cost  revenue
A  False     True
B  False    False
C   True    False

When other is a Series, the columns of a DataFrame are aligned with the index of other and broadcast:

>>> df != pd.Series([100, 250], index=["cost", "revenue"])
    cost  revenue
A   True     True
B   True    False
C  False     True

Use the method to control the broadcast axis:

>>> df.ne(pd.Series([100, 300], index=["A", "D"]), axis='index')
   cost  revenue
A  True    False
B  True     True
C  True     True
D  True     True

When comparing to an arbitrary sequence, the number of columns must match the number elements in other:

>>> df == [250, 100]
    cost  revenue
A   True     True
B  False    False
C  False    False

Use the method to control the axis:

>>> df.eq([250, 250, 100], axis='index')
    cost  revenue
A   True    False
B  False     True
C   True    False

Compare to a DataFrame of different shape.

>>> other = pd.DataFrame({'revenue': [300, 250, 100, 150]},
...                      index=['A', 'B', 'C', 'D'])
>>> other
   revenue
A      300
B      250
C      100
D      150
>>> df.gt(other)
    cost  revenue
A  False    False
B  False    False
C  False     True
D  False    False

Compare to a MultiIndex by level.

>>> df_multindex = pd.DataFrame({'cost': [250, 150, 100, 150, 300, 220],
...                              'revenue': [100, 250, 300, 200, 175, 225]},
...                             index=[['Q1', 'Q1', 'Q1', 'Q2', 'Q2', 'Q2'],
...                                    ['A', 'B', 'C', 'A', 'B', 'C']])
>>> df_multindex
      cost  revenue
Q1 A   250      100
   B   150      250
   C   100      300
Q2 A   150      200
   B   300      175
   C   220      225
>>> df.le(df_multindex, level=1)
       cost  revenue
Q1 A   True     True
   B   True     True
   C   True     True
Q2 A  False     True
   B   True    False
   C   True    False
groupby(by=None, level=None, *, as_index=True, sort=True, group_keys=True, observed=True, dropna=True)#

Group DataFrame using a mapper or by a Series of columns.

A groupby operation involves some combination of splitting the object, applying a function, and combining the results. This can be used to group large amounts of data and compute operations on these groups.

Parameters:
  • by (mapping, function, label, pd.Grouper or list of such) – Used to determine the groups for the groupby. If by is a function, it’s called on each value of the object’s index. If a dict or Series is passed, the Series or dict VALUES will be used to determine the groups (the Series’ values are first aligned; see .align() method). If a list or ndarray of length equal to the number of rows is passed (see the groupby user guide), the values are used as-is to determine the groups. A label or list of labels may be passed to group by the columns in self. Notice that a tuple is interpreted as a (single) key.

  • level (int, level name, or sequence of such, default None) – If the axis is a MultiIndex (hierarchical), group by a particular level or levels. Do not specify both by and level.

  • as_index (bool, default True) – Return object with group labels as the index. Only relevant for DataFrame input. as_index=False is effectively “SQL-style” grouped output. This argument has no effect on filtrations (see the filtrations in the user guide), such as head(), tail(), nth() and in transformations (see the transformations in the user guide).

  • sort (bool, default True) –

    Sort group keys. Get better performance by turning this off. Note this does not influence the order of observations within each group. Groupby preserves the order of rows within each group. If False, the groups will appear in the same order as they did in the original DataFrame. This argument has no effect on filtrations (see the filtrations in the user guide), such as head(), tail(), nth() and in transformations (see the transformations in the user guide).

    Changed in version 2.0.0: Specifying sort=False with an ordered categorical grouper will no longer sort the values.

  • group_keys (bool, default True) –

    When calling apply and the by argument produces a like-indexed (i.e. a transform) result, add group keys to index to identify pieces. By default group keys are not included when the result’s index (and column) labels match the inputs, and are included otherwise.

    Changed in version 2.0.0: group_keys now defaults to True.

  • observed (bool, default True) –

    This only applies if any of the groupers are Categoricals. If True: only show observed values for categorical groupers. If False: show all values for categorical groupers.

    Changed in version 3.0.0: The default value is now True.

  • dropna (bool, default True) – If True, and if group keys contain NA values, NA values together with row/column will be dropped. If False, NA values will also be treated as the key in groups.

Returns:

Returns a groupby object that contains information about the groups.

Return type:

pandas.api.typing.DataFrameGroupBy

See also

resample

Convenience method for frequency conversion and resampling of time series.

Notes

See the user guide for more detailed usage and examples, including splitting an object into groups, iterating through groups, selecting a group, aggregation, and more.

The implementation of groupby is hash-based, meaning in particular that objects that compare as equal will be considered to be in the same group. An exception to this is that pandas has special handling of NA values: any NA values will be collapsed to a single group, regardless of how they compare. See the user guide linked above for more details.

Examples

>>> df = pd.DataFrame(
...     {
...         "Animal": ["Falcon", "Falcon", "Parrot", "Parrot"],
...         "Max Speed": [380.0, 370.0, 24.0, 26.0],
...     }
... )
>>> df
   Animal  Max Speed
0  Falcon      380.0
1  Falcon      370.0
2  Parrot       24.0
3  Parrot       26.0
>>> df.groupby(["Animal"]).mean()
        Max Speed
Animal
Falcon      375.0
Parrot       25.0

Hierarchical Indexes

We can groupby different levels of a hierarchical index using the level parameter:

>>> arrays = [
...     ["Falcon", "Falcon", "Parrot", "Parrot"],
...     ["Captive", "Wild", "Captive", "Wild"],
... ]
>>> index = pd.MultiIndex.from_arrays(arrays, names=("Animal", "Type"))
>>> df = pd.DataFrame({"Max Speed": [390.0, 350.0, 30.0, 20.0]}, index=index)
>>> df
                Max Speed
Animal Type
Falcon Captive      390.0
       Wild         350.0
Parrot Captive       30.0
       Wild          20.0
>>> df.groupby(level=0).mean()
        Max Speed
Animal
Falcon      370.0
Parrot       25.0
>>> df.groupby(level="Type").mean()
         Max Speed
Type
Captive      210.0
Wild         185.0

We can also choose to include NA in group keys or not by setting dropna parameter, the default setting is True.

>>> arr = [[1, 2, 3], [1, None, 4], [2, 1, 3], [1, 2, 2]]
>>> df = pd.DataFrame(arr, columns=["a", "b", "c"])
>>> df.groupby(by=["b"]).sum()
    a   c
b
1.0 2   3
2.0 2   5
>>> df.groupby(by=["b"], dropna=False).sum()
    a   c
b
1.0 2   3
2.0 2   5
NaN 1   4
>>> arr = [["a", 12, 12], [None, 12.3, 33.0], ["b", 12.3, 123], ["a", 1, 1]]
>>> df = pd.DataFrame(arr, columns=["a", "b", "c"])
>>> df.groupby(by="a").sum()
    b     c
a
a   13.0   13.0
b   12.3  123.0
>>> df.groupby(by="a", dropna=False).sum()
    b     c
a
a   13.0   13.0
b   12.3  123.0
NaN 12.3   33.0

When using .apply(), use group_keys to include or exclude the group keys. The group_keys argument defaults to True (include).

>>> df = pd.DataFrame(
...     {
...         "Animal": ["Falcon", "Falcon", "Parrot", "Parrot"],
...         "Max Speed": [380.0, 370.0, 24.0, 26.0],
...     }
... )
>>> df.groupby("Animal", group_keys=True)[["Max Speed"]].apply(lambda x: x)
          Max Speed
Animal
Falcon 0      380.0
       1      370.0
Parrot 2       24.0
       3       26.0
>>> df.groupby("Animal", group_keys=False)[["Max Speed"]].apply(lambda x: x)
   Max Speed
0      380.0
1      370.0
2       24.0
3       26.0
gt(other, axis='columns', level=None)#

Get Greater than of dataframe and other, element-wise (binary operator gt).

Among flexible wrappers (eq, ne, le, lt, ge, gt) to comparison operators.

Equivalent to ==, !=, <=, <, >=, > with support to choose axis (rows or columns) and level for comparison.

Parameters:
  • other (scalar, sequence, Series, or DataFrame) – Any single or multiple element data structure, or list-like object.

  • axis ({0 or 'index', 1 or 'columns'}, default 'columns') – Whether to compare by the index (0 or ‘index’) or columns (1 or ‘columns’).

  • level (int or label) – Broadcast across a level, matching Index values on the passed MultiIndex level.

Returns:

Result of the comparison.

Return type:

DataFrame of bool

See also

DataFrame.eq

Compare DataFrames for equality elementwise.

DataFrame.ne

Compare DataFrames for inequality elementwise.

DataFrame.le

Compare DataFrames for less than inequality or equality elementwise.

DataFrame.lt

Compare DataFrames for strictly less than inequality elementwise.

DataFrame.ge

Compare DataFrames for greater than inequality or equality elementwise.

DataFrame.gt

Compare DataFrames for strictly greater than inequality elementwise.

Notes

Mismatched indices will be unioned together. NaN values are considered different (i.e. NaN != NaN).

Examples

>>> df = pd.DataFrame({'cost': [250, 150, 100],
...                    'revenue': [100, 250, 300]},
...                   index=['A', 'B', 'C'])
>>> df
   cost  revenue
A   250      100
B   150      250
C   100      300

Comparison with a scalar, using either the operator or method:

>>> df == 100
    cost  revenue
A  False     True
B  False    False
C   True    False
>>> df.eq(100)
    cost  revenue
A  False     True
B  False    False
C   True    False

When other is a Series, the columns of a DataFrame are aligned with the index of other and broadcast:

>>> df != pd.Series([100, 250], index=["cost", "revenue"])
    cost  revenue
A   True     True
B   True    False
C  False     True

Use the method to control the broadcast axis:

>>> df.ne(pd.Series([100, 300], index=["A", "D"]), axis='index')
   cost  revenue
A  True    False
B  True     True
C  True     True
D  True     True

When comparing to an arbitrary sequence, the number of columns must match the number elements in other:

>>> df == [250, 100]
    cost  revenue
A   True     True
B  False    False
C  False    False

Use the method to control the axis:

>>> df.eq([250, 250, 100], axis='index')
    cost  revenue
A   True    False
B  False     True
C   True    False

Compare to a DataFrame of different shape.

>>> other = pd.DataFrame({'revenue': [300, 250, 100, 150]},
...                      index=['A', 'B', 'C', 'D'])
>>> other
   revenue
A      300
B      250
C      100
D      150
>>> df.gt(other)
    cost  revenue
A  False    False
B  False    False
C  False     True
D  False    False

Compare to a MultiIndex by level.

>>> df_multindex = pd.DataFrame({'cost': [250, 150, 100, 150, 300, 220],
...                              'revenue': [100, 250, 300, 200, 175, 225]},
...                             index=[['Q1', 'Q1', 'Q1', 'Q2', 'Q2', 'Q2'],
...                                    ['A', 'B', 'C', 'A', 'B', 'C']])
>>> df_multindex
      cost  revenue
Q1 A   250      100
   B   150      250
   C   100      300
Q2 A   150      200
   B   300      175
   C   220      225
>>> df.le(df_multindex, level=1)
       cost  revenue
Q1 A   True     True
   B   True     True
   C   True     True
Q2 A  False     True
   B   True    False
   C   True    False
hist(column=None, by=None, grid=True, xlabelsize=None, xrot=None, ylabelsize=None, yrot=None, ax=None, sharex=False, sharey=False, figsize=None, layout=None, bins=10, backend=None, legend=False, **kwargs)#

Make a histogram of the DataFrame’s columns.

A histogram is a representation of the distribution of data. This function calls matplotlib.pyplot.hist(), on each series in the DataFrame, resulting in one histogram per column.

Parameters:
  • data (DataFrame) – The pandas object holding the data.

  • column (str or sequence, optional) – If passed, will be used to limit data to a subset of columns.

  • by (object, optional) – If passed, then used to form histograms for separate groups.

  • grid (bool, default True) – Whether to show axis grid lines.

  • xlabelsize (int, default None) – If specified changes the x-axis label size.

  • xrot (float, default None) – Rotation of x axis labels. For example, a value of 90 displays the x labels rotated 90 degrees clockwise.

  • ylabelsize (int, default None) – If specified changes the y-axis label size.

  • yrot (float, default None) – Rotation of y axis labels. For example, a value of 90 displays the y labels rotated 90 degrees clockwise.

  • ax (Matplotlib axes object, default None) – The axes to plot the histogram on.

  • sharex (bool, default True if ax is None else False) – In case subplots=True, share x axis and set some x axis labels to invisible; defaults to True if ax is None otherwise False if an ax is passed in. Note that passing in both an ax and sharex=True will alter all x axis labels for all subplots in a figure.

  • sharey (bool, default False) – In case subplots=True, share y axis and set some y axis labels to invisible.

  • figsize (tuple, optional) – The size in inches of the figure to create. Uses the value in matplotlib.rcParams by default.

  • layout (tuple, optional) – Tuple of (rows, columns) for the layout of the histograms.

  • bins (int or sequence, default 10) – Number of histogram bins to be used. If an integer is given, bins + 1 bin edges are calculated and returned. If bins is a sequence, gives bin edges, including left edge of first bin and right edge of last bin. In this case, bins is returned unmodified.

  • backend (str, default None) – Backend to use instead of the backend specified in the option plotting.backend. For instance, ‘matplotlib’. Alternatively, to specify the plotting.backend for the whole session, set pd.options.plotting.backend.

  • legend (bool, default False) – Whether to show the legend.

  • **kwargs – All other plotting keyword arguments to be passed to matplotlib.pyplot.hist().

Returns:

2D NumPy Array of matplotlib.axes.Axes.

Return type:

np.ndarray

See also

matplotlib.pyplot.hist

Plot a histogram using matplotlib.

Examples

This example draws a histogram based on the length and width of some animals, displayed in three bins

idxmax(axis=0, skipna=True, numeric_only=False)#

Return index of first occurrence of maximum over requested axis.

NA/null values are excluded.

Parameters:
  • axis ({0 or 'index', 1 or 'columns'}, default 0) – The axis to use. 0 or ‘index’ for row-wise, 1 or ‘columns’ for column-wise.

  • skipna (bool, default True) – Exclude NA/null values. If the entire DataFrame is NA, or if skipna=False and there is an NA value, this method will raise a ValueError.

  • numeric_only (bool, default False) – Include only float, int or boolean data.

Returns:

Indexes of maxima along the specified axis.

Return type:

Series

Raises:

ValueError

  • If the row/column is empty

See also

Series.idxmax

Return index of the maximum element.

Notes

This method is the DataFrame version of ndarray.argmax.

Examples

Consider a dataset containing food consumption in Argentina.

>>> df = pd.DataFrame(
...     {
...         "consumption": [10.51, 103.11, 55.48],
...         "co2_emissions": [37.2, 19.66, 1712],
...     },
...     index=["Pork", "Wheat Products", "Beef"],
... )
>>> df
                consumption  co2_emissions
Pork                  10.51         37.20
Wheat Products       103.11         19.66
Beef                  55.48       1712.00

By default, it returns the index for the maximum value in each column.

>>> df.idxmax()
consumption      Wheat Products
co2_emissions              Beef
dtype: str

To return the index for the maximum value in each row, use axis="columns".

>>> df.idxmax(axis="columns")
Pork              co2_emissions
Wheat Products     consumption
Beef              co2_emissions
dtype: str
idxmin(axis=0, skipna=True, numeric_only=False)#

Return index of first occurrence of minimum over requested axis.

NA/null values are excluded.

Parameters:
  • axis ({0 or 'index', 1 or 'columns'}, default 0) – The axis to use. 0 or ‘index’ for row-wise, 1 or ‘columns’ for column-wise.

  • skipna (bool, default True) – Exclude NA/null values. If the entire DataFrame is NA, or if skipna=False and there is an NA value, this method will raise a ValueError.

  • numeric_only (bool, default False) – Include only float, int or boolean data.

Returns:

Indexes of minima along the specified axis.

Return type:

Series

Raises:

ValueError

  • If the row/column is empty

See also

Series.idxmin

Return index of the minimum element.

Notes

This method is the DataFrame version of ndarray.argmin.

Examples

Consider a dataset containing food consumption in Argentina.

>>> df = pd.DataFrame(
...     {
...         "consumption": [10.51, 103.11, 55.48],
...         "co2_emissions": [37.2, 19.66, 1712],
...     },
...     index=["Pork", "Wheat Products", "Beef"],
... )
>>> df
                consumption  co2_emissions
Pork                  10.51         37.20
Wheat Products       103.11         19.66
Beef                  55.48       1712.00

By default, it returns the index for the minimum value in each column.

>>> df.idxmin()
consumption                Pork
co2_emissions    Wheat Products
dtype: str

To return the index for the minimum value in each row, use axis="columns".

>>> df.idxmin(axis="columns")
Pork                consumption
Wheat Products    co2_emissions
Beef                consumption
dtype: str
index#

The index (row labels) of the DataFrame.

The index of a DataFrame is a series of labels that identify each row. The labels can be integers, strings, or any other hashable type. The index is used for label-based access and alignment, and can be accessed or modified using this attribute.

Returns:

The index labels of the DataFrame.

Return type:

pandas.Index

See also

DataFrame.columns

The column labels of the DataFrame.

DataFrame.to_numpy

Convert the DataFrame to a NumPy array.

Examples

>>> df = pd.DataFrame({'Name': ['Alice', 'Bob', 'Aritra'],
...                    'Age': [25, 30, 35],
...                    'Location': ['Seattle', 'New York', 'Kona']},
...                   index=([10, 20, 30]))
>>> df.index
Index([10, 20, 30], dtype='int64')

In this example, we create a DataFrame with 3 rows and 3 columns, including Name, Age, and Location information. We set the index labels to be the integers 10, 20, and 30. We then access the index attribute of the DataFrame, which returns an Index object containing the index labels.

>>> df.index = [100, 200, 300]
>>> df
    Name  Age Location
100  Alice   25  Seattle
200    Bob   30 New York
300  Aritra  35    Kona

In this example, we modify the index labels of the DataFrame by assigning a new list of labels to the index attribute. The DataFrame is then updated with the new labels, and the output shows the modified DataFrame.

info(verbose=None, buf=None, max_cols=None, memory_usage=None, show_counts=None)#

Print a concise summary of a DataFrame.

This method prints information about a DataFrame including the index dtype and columns, non-NA values and memory usage.

Parameters:
  • verbose (bool, optional) – Whether to print the full summary. By default, the setting in pandas.options.display.max_info_columns is followed.

  • buf (writable buffer, defaults to sys.stdout) – Where to send the output. By default, the output is printed to sys.stdout. Pass a writable buffer if you need to further process the output.

  • max_cols (int, optional) – When to switch from the verbose to the truncated output. If the DataFrame has more than max_cols columns, the truncated output is used. By default, the setting in pandas.options.display.max_info_columns is used.

  • memory_usage (bool, str, optional) –

    Specifies whether total memory usage of the DataFrame elements (including the index) should be displayed. By default, this follows the pandas.options.display.memory_usage setting.

    True always show memory usage. False never shows memory usage. A value of ‘deep’ is equivalent to “True with deep introspection”. Memory usage is shown in human-readable units (base-2 representation). Without deep introspection a memory estimation is made based in column dtype and number of rows assuming values consume the same memory amount for corresponding dtypes. With deep memory introspection, a real memory usage calculation is performed at the cost of computational resources. See the Frequently Asked Questions for more details.

  • show_counts (bool, optional) – Whether to show the non-null counts. By default, this is shown only if the DataFrame is smaller than pandas.options.display.max_info_rows and pandas.options.display.max_info_columns. A value of True always shows the counts, and False never shows the counts.

Returns:

This method prints a summary of a DataFrame and returns None.

Return type:

None

See also

DataFrame.describe

Generate descriptive statistics of DataFrame columns.

DataFrame.memory_usage

Memory usage of DataFrame columns.

Examples

>>> int_values = [1, 2, 3, 4, 5]
>>> text_values = ["alpha", "beta", "gamma", "delta", "epsilon"]
>>> float_values = [0.0, 0.25, 0.5, 0.75, 1.0]
>>> df = pd.DataFrame(
...     {
...         "int_col": int_values,
...         "text_col": text_values,
...         "float_col": float_values,
...     }
... )
>>> df
    int_col text_col  float_col
0        1    alpha       0.00
1        2     beta       0.25
2        3    gamma       0.50
3        4    delta       0.75
4        5  epsilon       1.00

Prints information of all columns:

>>> df.info(verbose=True)
<class 'pandas.DataFrame'>
RangeIndex: 5 entries, 0 to 4
Data columns (total 3 columns):
 #   Column     Non-Null Count  Dtype
---  ------     --------------  -----
 0   int_col    5 non-null      int64
 1   text_col   5 non-null      str
 2   float_col  5 non-null      float64
dtypes: float64(1), int64(1), str(1)
memory usage: 278.0 bytes

Prints a summary of columns count and its dtypes but not per column information:

>>> df.info(verbose=False)
<class 'pandas.DataFrame'>
RangeIndex: 5 entries, 0 to 4
Columns: 3 entries, int_col to float_col
dtypes: float64(1), int64(1), str(1)
memory usage: 278.0 bytes

Pipe output of DataFrame.info to buffer instead of sys.stdout, get buffer content and writes to a text file:

>>> import io
>>> buffer = io.StringIO()
>>> df.info(buf=buffer)
>>> s = buffer.getvalue()
>>> with open("df_info.txt", "w", encoding="utf-8") as f:
...     f.write(s)
260

The memory_usage parameter allows deep introspection mode, specially useful for big DataFrames and fine-tune memory optimization:

>>> random_strings_array = np.random.choice(["a", "b", "c"], 10**6)
>>> df = pd.DataFrame(
...     {
...         "column_1": np.random.choice(["a", "b", "c"], 10**6),
...         "column_2": np.random.choice(["a", "b", "c"], 10**6),
...         "column_3": np.random.choice(["a", "b", "c"], 10**6),
...     }
... )
>>> df.info()
<class 'pandas.DataFrame'>
RangeIndex: 1000000 entries, 0 to 999999
Data columns (total 3 columns):
 #   Column    Non-Null Count    Dtype
---  ------    --------------    -----
 0   column_1  1000000 non-null  str
 1   column_2  1000000 non-null  str
 2   column_3  1000000 non-null  str
dtypes: str(3)
memory usage: 25.7 MB
>>> df.info(memory_usage="deep")
<class 'pandas.DataFrame'>
RangeIndex: 1000000 entries, 0 to 999999
Data columns (total 3 columns):
 #   Column    Non-Null Count    Dtype
---  ------    --------------    -----
 0   column_1  1000000 non-null  str
 1   column_2  1000000 non-null  str
 2   column_3  1000000 non-null  str
dtypes: str(3)
memory usage: 25.7 MB
insert(loc, column, value, allow_duplicates=<no_default>)#

Insert column into DataFrame at specified location.

Raises a ValueError if column is already contained in the DataFrame, unless allow_duplicates is set to True.

Parameters:
  • loc (int) – Insertion index. Must verify 0 <= loc <= len(columns).

  • column (str, number, or hashable object) – Label of the inserted column.

  • value (Scalar, Series, or array-like) – Content of the inserted column.

  • allow_duplicates (bool, optional, default lib.no_default) – Allow duplicate column labels to be created.

Return type:

None

See also

Index.insert

Insert new item by index.

Examples

>>> df = pd.DataFrame({"col1": [1, 2], "col2": [3, 4]})
>>> df
   col1  col2
0     1     3
1     2     4
>>> df.insert(1, "newcol", [99, 99])
>>> df
   col1  newcol  col2
0     1      99     3
1     2      99     4
>>> df.insert(0, "col1", [100, 100], allow_duplicates=True)
>>> df
   col1  col1  newcol  col2
0   100     1      99     3
1   100     2      99     4

Notice that pandas uses index alignment in case of value from type Series:

>>> df.insert(0, "col0", pd.Series([5, 6], index=[1, 2]))
>>> df
   col0  col1  col1  newcol  col2
0   NaN   100     1      99     3
1   5.0   100     2      99     4
isetitem(loc, value)#

Set the given value in the column with position loc.

This is a positional analogue to __setitem__.

Parameters:
  • loc (int or sequence of ints) – Index position for the column.

  • value (scalar or arraylike) – Value(s) for the column.

Return type:

None

See also

DataFrame.iloc

Purely integer-location based indexing for selection by position.

Notes

frame.isetitem(loc, value) is an in-place method as it will modify the DataFrame in place (not returning a new object). In contrast to frame.iloc[:, i] = value which will try to update the existing values in place, frame.isetitem(loc, value) will not update the values of the column itself in place, it will instead insert a new array.

In cases where frame.columns is unique, this is equivalent to frame[frame.columns[i]] = value.

Examples

>>> df = pd.DataFrame({"A": [1, 2], "B": [3, 4]})
>>> df.isetitem(1, [5, 6])
>>> df
      A  B
0     1  5
1     2  6
isin(values)#

Whether each element in the DataFrame is contained in values.

Parameters:

values (iterable, Series, DataFrame or dict) – The result will only be true at a location if all the labels match. If values is a Series, that’s the index. If values is a dict, the keys must be the column names, which must match. If values is a DataFrame, then both the index and column labels must match.

Returns:

DataFrame of booleans showing whether each element in the DataFrame is contained in values.

Return type:

DataFrame

See also

DataFrame.eq

Equality test for DataFrame.

Series.isin

Equivalent method on Series.

Series.str.contains

Test if pattern or regex is contained within a string of a Series or Index.

Notes

__iter__ is used (and not __contains__) to iterate over values when checking if it contains the elements in DataFrame.

Examples

>>> df = pd.DataFrame(
...     {"num_legs": [2, 4], "num_wings": [2, 0]}, index=["falcon", "dog"]
... )
>>> df
        num_legs  num_wings
falcon         2          2
dog            4          0

When values is a list check whether every value in the DataFrame is present in the list (which animals have 0 or 2 legs or wings)

>>> df.isin([0, 2])
        num_legs  num_wings
falcon      True       True
dog        False       True

To check if values is not in the DataFrame, use the ~ operator:

>>> ~df.isin([0, 2])
        num_legs  num_wings
falcon     False      False
dog         True      False

When values is a dict, we can pass values to check for each column separately:

>>> df.isin({"num_wings": [0, 3]})
        num_legs  num_wings
falcon     False      False
dog        False       True

When values is a Series or DataFrame the index and column must match. Note that ‘falcon’ does not match based on the number of legs in other.

>>> other = pd.DataFrame(
...     {"num_legs": [8, 3], "num_wings": [0, 2]}, index=["spider", "falcon"]
... )
>>> df.isin(other)
        num_legs  num_wings
falcon     False       True
dog        False      False
isna()#

Detect missing values.

Return a boolean same-sized object indicating if the values are NA. NA values, such as None or numpy.NaN, gets mapped to True values. Everything else gets mapped to False values. Characters such as empty strings '' or numpy.inf are not considered NA values.

Returns:

Mask of bool values for each element in Series/DataFrame that indicates whether an element is an NA value.

Return type:

Series/DataFrame

See also

Series.isnull

Alias of isna.

DataFrame.isnull

Alias of isna.

Series.notna

Boolean inverse of isna.

DataFrame.notna

Boolean inverse of isna.

Series.dropna

Omit axes labels with missing values.

DataFrame.dropna

Omit axes labels with missing values.

isna

Top-level isna.

Examples

Show which entries in a DataFrame are NA.

>>> df = pd.DataFrame(
...     dict(
...         age=[5, 6, np.nan],
...         born=[
...             pd.NaT,
...             pd.Timestamp("1939-05-27"),
...             pd.Timestamp("1940-04-25"),
...         ],
...         name=["Alfred", "Batman", ""],
...         toy=[None, "Batmobile", "Joker"],
...     )
... )
>>> df
   age       born    name        toy
0  5.0        NaT  Alfred        NaN
1  6.0 1939-05-27  Batman  Batmobile
2  NaN 1940-04-25              Joker
>>> df.isna()
     age   born   name    toy
0  False   True  False   True
1  False  False  False  False
2   True  False  False  False

Show which entries in a Series are NA.

>>> ser = pd.Series([5, 6, np.nan])
>>> ser
0    5.0
1    6.0
2    NaN
dtype: float64
>>> ser.isna()
0    False
1    False
2     True
dtype: bool
isnull()#

DataFrame.isnull is an alias for DataFrame.isna.

Detect missing values.

Return a boolean same-sized object indicating if the values are NA. NA values, such as None or numpy.NaN, gets mapped to True values. Everything else gets mapped to False values. Characters such as empty strings '' or numpy.inf are not considered NA values.

Returns:

Mask of bool values for each element in Series/DataFrame that indicates whether an element is an NA value.

Return type:

Series/DataFrame

See also

Series.isnull

Alias of isna.

DataFrame.isnull

Alias of isna.

Series.notna

Boolean inverse of isna.

DataFrame.notna

Boolean inverse of isna.

Series.dropna

Omit axes labels with missing values.

DataFrame.dropna

Omit axes labels with missing values.

isna

Top-level isna.

Examples

Show which entries in a DataFrame are NA.

>>> df = pd.DataFrame(
...     dict(
...         age=[5, 6, np.nan],
...         born=[
...             pd.NaT,
...             pd.Timestamp("1939-05-27"),
...             pd.Timestamp("1940-04-25"),
...         ],
...         name=["Alfred", "Batman", ""],
...         toy=[None, "Batmobile", "Joker"],
...     )
... )
>>> df
   age       born    name        toy
0  5.0        NaT  Alfred        NaN
1  6.0 1939-05-27  Batman  Batmobile
2  NaN 1940-04-25              Joker
>>> df.isna()
     age   born   name    toy
0  False   True  False   True
1  False  False  False  False
2   True  False  False  False

Show which entries in a Series are NA.

>>> ser = pd.Series([5, 6, np.nan])
>>> ser
0    5.0
1    6.0
2    NaN
dtype: float64
>>> ser.isna()
0    False
1    False
2     True
dtype: bool
items()#

Iterate over (column name, Series) pairs.

Iterates over the DataFrame columns, returning a tuple with the column name and the content as a Series.

Yields:
  • label (object) – The column names for the DataFrame being iterated over.

  • content (Series) – The column entries belonging to each label, as a Series.

Return type:

Iterable[tuple[Hashable, Series]]

See also

DataFrame.iterrows

Iterate over DataFrame rows as (index, Series) pairs.

DataFrame.itertuples

Iterate over DataFrame rows as namedtuples of the values.

Examples

>>> df = pd.DataFrame(
...     {
...         "species": ["bear", "bear", "marsupial"],
...         "population": [1864, 22000, 80000],
...     },
...     index=["panda", "polar", "koala"],
... )
>>> df
        species   population
panda   bear      1864
polar   bear      22000
koala   marsupial 80000
>>> for label, content in df.items():
...     print(f"label: {label}")
...     print(f"content: {content}", sep="\n")
label: species
content:
panda         bear
polar         bear
koala    marsupial
Name: species, dtype: str
label: population
content:
panda     1864
polar    22000
koala    80000
Name: population, dtype: int64
iterrows()#

Iterate over DataFrame rows as (index, Series) pairs.

Yields:
  • index (label or tuple of label) – The index of the row. A tuple for a MultiIndex.

  • data (Series) – The data of the row as a Series.

Return type:

Iterable[tuple[Hashable, Series]]

See also

DataFrame.itertuples

Iterate over DataFrame rows as namedtuples of the values.

DataFrame.items

Iterate over (column name, Series) pairs.

Notes

  1. Because iterrows returns a Series for each row, it does not preserve dtypes across the rows (dtypes are preserved across columns for DataFrames).

    To preserve dtypes while iterating over the rows, it is better to use itertuples() which returns namedtuples of the values and which is generally faster than iterrows.

  2. You should never modify something you are iterating over. This is not guaranteed to work in all cases. Depending on the data types, the iterator returns a copy and not a view, and writing to it will have no effect.

Examples

>>> df = pd.DataFrame([[1, 1.5]], columns=["int", "float"])
>>> row = next(df.iterrows())[1]
>>> row
int      1.0
float    1.5
Name: 0, dtype: float64
>>> print(row["int"].dtype)
float64
>>> print(df["int"].dtype)
int64
itertuples(index=True, name='Pandas')#

Iterate over DataFrame rows as namedtuples.

Parameters:
  • index (bool, default True) – If True, return the index as the first element of the tuple.

  • name (str or None, default "Pandas") – The name of the returned namedtuples or None to return regular tuples.

Returns:

An object to iterate over namedtuples for each row in the DataFrame with the first field possibly being the index and following fields being the column values.

Return type:

iterator

See also

DataFrame.iterrows

Iterate over DataFrame rows as (index, Series) pairs.

DataFrame.items

Iterate over (column name, Series) pairs.

Notes

The column names will be renamed to positional names if they are invalid Python identifiers, repeated, or start with an underscore.

Examples

>>> df = pd.DataFrame(
...     {"num_legs": [4, 2], "num_wings": [0, 2]}, index=["dog", "hawk"]
... )
>>> df
      num_legs  num_wings
dog          4          0
hawk         2          2
>>> for row in df.itertuples():
...     print(row)
Pandas(Index='dog', num_legs=4, num_wings=0)
Pandas(Index='hawk', num_legs=2, num_wings=2)

By setting the index parameter to False we can remove the index as the first element of the tuple:

>>> for row in df.itertuples(index=False):
...     print(row)
Pandas(num_legs=4, num_wings=0)
Pandas(num_legs=2, num_wings=2)

With the name parameter set we set a custom name for the yielded namedtuples:

>>> for row in df.itertuples(name="Animal"):
...     print(row)
Animal(Index='dog', num_legs=4, num_wings=0)
Animal(Index='hawk', num_legs=2, num_wings=2)
join(other, on=None, how='left', lsuffix='', rsuffix='', sort=False, validate=None)#

Join columns of another DataFrame.

Join columns with other DataFrame either on index or on a key column. Efficiently join multiple DataFrame objects by index at once by passing a list.

Parameters:
  • other (DataFrame, Series, or a list containing any combination of them) – Index should be similar to one of the columns in this one. If a Series is passed, its name attribute must be set, and that will be used as the column name in the resulting joined DataFrame.

  • on (str, list of str, or array-like, optional) – Column or index level name(s) in the caller to join on the index in other, otherwise joins index-on-index. If multiple values given, the other DataFrame must have a MultiIndex. Can pass an array as the join key if it is not already contained in the calling DataFrame. Like an Excel VLOOKUP operation.

  • how ({'left', 'right', 'outer', 'inner', 'cross', 'left_anti', 'right_anti'},) –

    default ‘left’ How to handle the operation of the two objects.

    • left: use calling frame’s index (or column if on is specified)

    • right: use other’s index.

    • outer: form union of calling frame’s index (or column if on is specified) with other’s index, and sort it lexicographically.

    • inner: form intersection of calling frame’s index (or column if on is specified) with other’s index, preserving the order of the calling’s one.

    • cross: creates the cartesian product from both frames, preserves the order of the left keys.

    • left_anti: use set difference of calling frame’s index and other’s index.

    • right_anti: use set difference of other’s index and calling frame’s index.

  • lsuffix (str, default '') – Suffix to use from left frame’s overlapping columns.

  • rsuffix (str, default '') – Suffix to use from right frame’s overlapping columns.

  • sort (bool, default False) – Order result DataFrame lexicographically by the join key. If False, the order of the join key depends on the join type (how keyword).

  • validate (str, optional) –

    If specified, checks if join is of specified type.

    • ”one_to_one” or “1:1”: check if join keys are unique in both left and right datasets.

    • ”one_to_many” or “1:m”: check if join keys are unique in left dataset.

    • ”many_to_one” or “m:1”: check if join keys are unique in right dataset.

    • ”many_to_many” or “m:m”: allowed, but does not result in checks.

Returns:

A dataframe containing columns from both the caller and other.

Return type:

DataFrame

See also

DataFrame.merge

For column(s)-on-column(s) operations.

Notes

Parameters on, lsuffix, and rsuffix are not supported when passing a list of DataFrame objects.

Examples

>>> df = pd.DataFrame(
...     {
...         "key": ["K0", "K1", "K2", "K3", "K4", "K5"],
...         "A": ["A0", "A1", "A2", "A3", "A4", "A5"],
...     }
... )
>>> df
  key   A
0  K0  A0
1  K1  A1
2  K2  A2
3  K3  A3
4  K4  A4
5  K5  A5
>>> other = pd.DataFrame({"key": ["K0", "K1", "K2"], "B": ["B0", "B1", "B2"]})
>>> other
  key   B
0  K0  B0
1  K1  B1
2  K2  B2

Join DataFrames using their indexes.

>>> df.join(other, lsuffix="_caller", rsuffix="_other")
  key_caller   A key_other    B
0         K0  A0        K0   B0
1         K1  A1        K1   B1
2         K2  A2        K2   B2
3         K3  A3       NaN  NaN
4         K4  A4       NaN  NaN
5         K5  A5       NaN  NaN

If we want to join using the key columns, we need to set key to be the index in both df and other. The joined DataFrame will have key as its index.

>>> df.set_index("key").join(other.set_index("key"))
      A    B
key
K0   A0   B0
K1   A1   B1
K2   A2   B2
K3   A3  NaN
K4   A4  NaN
K5   A5  NaN

Another option to join using the key columns is to use the on parameter. DataFrame.join always uses other’s index but we can use any column in df. This method preserves the original DataFrame’s index in the result.

>>> df.join(other.set_index("key"), on="key")
  key   A    B
0  K0  A0   B0
1  K1  A1   B1
2  K2  A2   B2
3  K3  A3  NaN
4  K4  A4  NaN
5  K5  A5  NaN

Using non-unique key values shows how they are matched.

>>> df = pd.DataFrame(
...     {
...         "key": ["K0", "K1", "K1", "K3", "K0", "K1"],
...         "A": ["A0", "A1", "A2", "A3", "A4", "A5"],
...     }
... )
>>> df
  key   A
0  K0  A0
1  K1  A1
2  K1  A2
3  K3  A3
4  K0  A4
5  K1  A5
>>> df.join(other.set_index("key"), on="key", validate="m:1")
  key   A    B
0  K0  A0   B0
1  K1  A1   B1
2  K1  A2   B1
3  K3  A3  NaN
4  K0  A4   B0
5  K1  A5   B1
kurt(*, axis: Axis = 0, skipna: bool = True, numeric_only: bool = False, **kwargs) Series#
kurt(*, axis: None, skipna: bool = True, numeric_only: bool = False, **kwargs) Any
kurt(*, axis: Axis | None, skipna: bool = True, numeric_only: bool = False, **kwargs) Series | Any

Return unbiased kurtosis over requested axis.

Kurtosis obtained using Fisher’s definition of kurtosis (kurtosis of normal == 0.0). Normalized by N-1.

Parameters:
  • axis ({index (0), columns (1)}) –

    Axis for the function to be applied on. For Series this parameter is unused and defaults to 0.

    For DataFrames, specifying axis=None will apply the aggregation across both axes.

    Added in version 2.0.0.

  • skipna (bool, default True) – Exclude NA/null values when computing the result.

  • numeric_only (bool, default False) – Include only float, int, boolean columns.

  • **kwargs – Additional keyword arguments to be passed to the function.

Returns:

Unbiased kurtosis over requested axis.

Return type:

Series or scalar

See also

Dataframe.kurtosis

Returns unbiased kurtosis over requested axis.

Examples

>>> s = pd.Series([1, 2, 2, 3], index=["cat", "dog", "dog", "mouse"])
>>> s
cat    1
dog    2
dog    2
mouse  3
dtype: int64
>>> s.kurt()
1.5

With a DataFrame

>>> df = pd.DataFrame(
...     {"a": [1, 2, 2, 3], "b": [3, 4, 4, 4]},
...     index=["cat", "dog", "dog", "mouse"],
... )
>>> df
       a   b
  cat  1   3
  dog  2   4
  dog  2   4
mouse  3   4
>>> df.kurt()
a   1.5
b   4.0
dtype: float64

With axis=None

>>> df.kurt(axis=None)
-0.9886927196984727

Using axis=1

>>> df = pd.DataFrame(
...     {"a": [1, 2], "b": [3, 4], "c": [3, 4], "d": [1, 2]},
...     index=["cat", "dog"],
... )
>>> df.kurt(axis=1)
cat   -6.0
dog   -6.0
dtype: float64
kurtosis(*, axis=0, skipna=True, numeric_only=False, **kwargs)#

Return unbiased kurtosis over requested axis.

Kurtosis obtained using Fisher’s definition of kurtosis (kurtosis of normal == 0.0). Normalized by N-1.

Parameters:
  • axis ({index (0), columns (1)}) –

    Axis for the function to be applied on. For Series this parameter is unused and defaults to 0.

    For DataFrames, specifying axis=None will apply the aggregation across both axes.

    Added in version 2.0.0.

  • skipna (bool, default True) – Exclude NA/null values when computing the result.

  • numeric_only (bool, default False) – Include only float, int, boolean columns.

  • **kwargs – Additional keyword arguments to be passed to the function.

Returns:

Unbiased kurtosis over requested axis.

Return type:

Series or scalar

See also

Dataframe.kurtosis

Returns unbiased kurtosis over requested axis.

Examples

>>> s = pd.Series([1, 2, 2, 3], index=["cat", "dog", "dog", "mouse"])
>>> s
cat    1
dog    2
dog    2
mouse  3
dtype: int64
>>> s.kurt()
1.5

With a DataFrame

>>> df = pd.DataFrame(
...     {"a": [1, 2, 2, 3], "b": [3, 4, 4, 4]},
...     index=["cat", "dog", "dog", "mouse"],
... )
>>> df
       a   b
  cat  1   3
  dog  2   4
  dog  2   4
mouse  3   4
>>> df.kurt()
a   1.5
b   4.0
dtype: float64

With axis=None

>>> df.kurt(axis=None)
-0.9886927196984727

Using axis=1

>>> df = pd.DataFrame(
...     {"a": [1, 2], "b": [3, 4], "c": [3, 4], "d": [1, 2]},
...     index=["cat", "dog"],
... )
>>> df.kurt(axis=1)
cat   -6.0
dog   -6.0
dtype: float64
le(other, axis='columns', level=None)#

Get Greater than or equal to of dataframe and other, element-wise (binary operator le).

Among flexible wrappers (eq, ne, le, lt, ge, gt) to comparison operators.

Equivalent to ==, !=, <=, <, >=, > with support to choose axis (rows or columns) and level for comparison.

Parameters:
  • other (scalar, sequence, Series, or DataFrame) – Any single or multiple element data structure, or list-like object.

  • axis ({0 or 'index', 1 or 'columns'}, default 'columns') – Whether to compare by the index (0 or ‘index’) or columns (1 or ‘columns’).

  • level (int or label) – Broadcast across a level, matching Index values on the passed MultiIndex level.

Returns:

Result of the comparison.

Return type:

DataFrame of bool

See also

DataFrame.eq

Compare DataFrames for equality elementwise.

DataFrame.ne

Compare DataFrames for inequality elementwise.

DataFrame.le

Compare DataFrames for less than inequality or equality elementwise.

DataFrame.lt

Compare DataFrames for strictly less than inequality elementwise.

DataFrame.ge

Compare DataFrames for greater than inequality or equality elementwise.

DataFrame.gt

Compare DataFrames for strictly greater than inequality elementwise.

Notes

Mismatched indices will be unioned together. NaN values are considered different (i.e. NaN != NaN).

Examples

>>> df = pd.DataFrame({'cost': [250, 150, 100],
...                    'revenue': [100, 250, 300]},
...                   index=['A', 'B', 'C'])
>>> df
   cost  revenue
A   250      100
B   150      250
C   100      300

Comparison with a scalar, using either the operator or method:

>>> df == 100
    cost  revenue
A  False     True
B  False    False
C   True    False
>>> df.eq(100)
    cost  revenue
A  False     True
B  False    False
C   True    False

When other is a Series, the columns of a DataFrame are aligned with the index of other and broadcast:

>>> df != pd.Series([100, 250], index=["cost", "revenue"])
    cost  revenue
A   True     True
B   True    False
C  False     True

Use the method to control the broadcast axis:

>>> df.ne(pd.Series([100, 300], index=["A", "D"]), axis='index')
   cost  revenue
A  True    False
B  True     True
C  True     True
D  True     True

When comparing to an arbitrary sequence, the number of columns must match the number elements in other:

>>> df == [250, 100]
    cost  revenue
A   True     True
B  False    False
C  False    False

Use the method to control the axis:

>>> df.eq([250, 250, 100], axis='index')
    cost  revenue
A   True    False
B  False     True
C   True    False

Compare to a DataFrame of different shape.

>>> other = pd.DataFrame({'revenue': [300, 250, 100, 150]},
...                      index=['A', 'B', 'C', 'D'])
>>> other
   revenue
A      300
B      250
C      100
D      150
>>> df.gt(other)
    cost  revenue
A  False    False
B  False    False
C  False     True
D  False    False

Compare to a MultiIndex by level.

>>> df_multindex = pd.DataFrame({'cost': [250, 150, 100, 150, 300, 220],
...                              'revenue': [100, 250, 300, 200, 175, 225]},
...                             index=[['Q1', 'Q1', 'Q1', 'Q2', 'Q2', 'Q2'],
...                                    ['A', 'B', 'C', 'A', 'B', 'C']])
>>> df_multindex
      cost  revenue
Q1 A   250      100
   B   150      250
   C   100      300
Q2 A   150      200
   B   300      175
   C   220      225
>>> df.le(df_multindex, level=1)
       cost  revenue
Q1 A   True     True
   B   True     True
   C   True     True
Q2 A  False     True
   B   True    False
   C   True    False
lt(other, axis='columns', level=None)#

Get Greater than of dataframe and other, element-wise (binary operator lt).

Among flexible wrappers (eq, ne, le, lt, ge, gt) to comparison operators.

Equivalent to ==, !=, <=, <, >=, > with support to choose axis (rows or columns) and level for comparison.

Parameters:
  • other (scalar, sequence, Series, or DataFrame) – Any single or multiple element data structure, or list-like object.

  • axis ({0 or 'index', 1 or 'columns'}, default 'columns') – Whether to compare by the index (0 or ‘index’) or columns (1 or ‘columns’).

  • level (int or label) – Broadcast across a level, matching Index values on the passed MultiIndex level.

Returns:

Result of the comparison.

Return type:

DataFrame of bool

See also

DataFrame.eq

Compare DataFrames for equality elementwise.

DataFrame.ne

Compare DataFrames for inequality elementwise.

DataFrame.le

Compare DataFrames for less than inequality or equality elementwise.

DataFrame.lt

Compare DataFrames for strictly less than inequality elementwise.

DataFrame.ge

Compare DataFrames for greater than inequality or equality elementwise.

DataFrame.gt

Compare DataFrames for strictly greater than inequality elementwise.

Notes

Mismatched indices will be unioned together. NaN values are considered different (i.e. NaN != NaN).

Examples

>>> df = pd.DataFrame({'cost': [250, 150, 100],
...                    'revenue': [100, 250, 300]},
...                   index=['A', 'B', 'C'])
>>> df
   cost  revenue
A   250      100
B   150      250
C   100      300

Comparison with a scalar, using either the operator or method:

>>> df == 100
    cost  revenue
A  False     True
B  False    False
C   True    False
>>> df.eq(100)
    cost  revenue
A  False     True
B  False    False
C   True    False

When other is a Series, the columns of a DataFrame are aligned with the index of other and broadcast:

>>> df != pd.Series([100, 250], index=["cost", "revenue"])
    cost  revenue
A   True     True
B   True    False
C  False     True

Use the method to control the broadcast axis:

>>> df.ne(pd.Series([100, 300], index=["A", "D"]), axis='index')
   cost  revenue
A  True    False
B  True     True
C  True     True
D  True     True

When comparing to an arbitrary sequence, the number of columns must match the number elements in other:

>>> df == [250, 100]
    cost  revenue
A   True     True
B  False    False
C  False    False

Use the method to control the axis:

>>> df.eq([250, 250, 100], axis='index')
    cost  revenue
A   True    False
B  False     True
C   True    False

Compare to a DataFrame of different shape.

>>> other = pd.DataFrame({'revenue': [300, 250, 100, 150]},
...                      index=['A', 'B', 'C', 'D'])
>>> other
   revenue
A      300
B      250
C      100
D      150
>>> df.gt(other)
    cost  revenue
A  False    False
B  False    False
C  False     True
D  False    False

Compare to a MultiIndex by level.

>>> df_multindex = pd.DataFrame({'cost': [250, 150, 100, 150, 300, 220],
...                              'revenue': [100, 250, 300, 200, 175, 225]},
...                             index=[['Q1', 'Q1', 'Q1', 'Q2', 'Q2', 'Q2'],
...                                    ['A', 'B', 'C', 'A', 'B', 'C']])
>>> df_multindex
      cost  revenue
Q1 A   250      100
   B   150      250
   C   100      300
Q2 A   150      200
   B   300      175
   C   220      225
>>> df.le(df_multindex, level=1)
       cost  revenue
Q1 A   True     True
   B   True     True
   C   True     True
Q2 A  False     True
   B   True    False
   C   True    False
map(func, na_action=None, **kwargs)#

Apply a function to a Dataframe elementwise.

Added in version 2.1.0: DataFrame.applymap was deprecated and renamed to DataFrame.map.

This method applies a function that accepts and returns a scalar to every element of a DataFrame.

Parameters:
  • func (callable) – Python function, returns a single value from a single value.

  • na_action ({None, 'ignore'}, default None) – If ‘ignore’, propagate NaN values, without passing them to func.

  • **kwargs – Additional keyword arguments to pass as keywords arguments to func.

Returns:

Transformed DataFrame.

Return type:

DataFrame

See also

DataFrame.apply

Apply a function along input axis of DataFrame.

DataFrame.replace

Replace values given in to_replace with value.

Series.map

Apply a function elementwise on a Series.

Examples

>>> df = pd.DataFrame([[1, 2.12], [3.356, 4.567]])
>>> df
       0      1
0  1.000  2.120
1  3.356  4.567
>>> df.map(lambda x: len(str(x)))
   0  1
0  3  4
1  5  5

Like Series.map, NA values can be ignored:

>>> df_copy = df.copy()
>>> df_copy.iloc[0, 0] = pd.NA
>>> df_copy.map(lambda x: len(str(x)), na_action="ignore")
     0  1
0  NaN  4
1  5.0  5

It is also possible to use map with functions that are not lambda functions:

>>> df.map(round, ndigits=1)
     0    1
0  1.0  2.1
1  3.4  4.6

Note that a vectorized version of func often exists, which will be much faster. You could square each number elementwise.

>>> df.map(lambda x: x**2)
           0          1
0   1.000000   4.494400
1  11.262736  20.857489

But it’s better to avoid map in that case.

>>> df**2
           0          1
0   1.000000   4.494400
1  11.262736  20.857489
max(*, axis: Axis = 0, skipna: bool = True, numeric_only: bool = False, **kwargs) Series#
max(*, axis: None, skipna: bool = True, numeric_only: bool = False, **kwargs) Any
max(*, axis: Axis | None, skipna: bool = True, numeric_only: bool = False, **kwargs) Series | Any

Return the maximum of the values over the requested axis.

If you want the index of the maximum, use idxmax. This is the equivalent of the numpy.ndarray method argmax.

Parameters:
  • axis ({index (0), columns (1)}) –

    Axis for the function to be applied on. For Series this parameter is unused and defaults to 0.

    For DataFrames, specifying axis=None will apply the aggregation across both axes.

    Added in version 2.0.0.

  • skipna (bool, default True) – Exclude NA/null values when computing the result.

  • numeric_only (bool, default False) – Include only float, int, boolean columns.

  • **kwargs – Additional keyword arguments to be passed to the function.

Returns:

Value containing the calculation referenced in the description.

Return type:

Series or scalar

See also

Series.sum

Return the sum.

Series.min

Return the minimum.

Series.max

Return the maximum.

Series.idxmin

Return the index of the minimum.

Series.idxmax

Return the index of the maximum.

DataFrame.sum

Return the sum over the requested axis.

DataFrame.min

Return the minimum over the requested axis.

DataFrame.max

Return the maximum over the requested axis.

DataFrame.idxmin

Return the index of the minimum over the requested axis.

DataFrame.idxmax

Return the index of the maximum over the requested axis.

Examples

>>> idx = pd.MultiIndex.from_arrays(
...     [["warm", "warm", "cold", "cold"], ["dog", "falcon", "fish", "spider"]],
...     names=["blooded", "animal"],
... )
>>> s = pd.Series([4, 2, 0, 8], name="legs", index=idx)
>>> s
blooded  animal
warm     dog       4
         falcon    2
cold     fish      0
         spider    8
Name: legs, dtype: int64
>>> s.max()
8
mean(*, axis: Axis = 0, skipna: bool = True, numeric_only: bool = False, **kwargs) Series#
mean(*, axis: None, skipna: bool = True, numeric_only: bool = False, **kwargs) Any
mean(*, axis: Axis | None, skipna: bool = True, numeric_only: bool = False, **kwargs) Series | Any

Return the mean of the values over the requested axis.

Parameters:
  • axis ({index (0), columns (1)}) –

    Axis for the function to be applied on. For Series this parameter is unused and defaults to 0.

    For DataFrames, specifying axis=None will apply the aggregation across both axes.

    Added in version 2.0.0.

  • skipna (bool, default True) – Exclude NA/null values when computing the result.

  • numeric_only (bool, default False) – Include only float, int, boolean columns.

  • **kwargs – Additional keyword arguments to be passed to the function.

Returns:

Value containing the calculation referenced in the description.

Return type:

Series or scalar

See also

Series.sum

Return the sum.

Series.min

Return the minimum.

Series.max

Return the maximum.

Series.idxmin

Return the index of the minimum.

Series.idxmax

Return the index of the maximum.

DataFrame.sum

Return the sum over the requested axis.

DataFrame.min

Return the minimum over the requested axis.

DataFrame.max

Return the maximum over the requested axis.

DataFrame.idxmin

Return the index of the minimum over the requested axis.

DataFrame.idxmax

Return the index of the maximum over the requested axis.

Examples

>>> s = pd.Series([1, 2, 3])
>>> s.mean()
2.0

With a DataFrame

>>> df = pd.DataFrame({"a": [1, 2], "b": [2, 3]}, index=["tiger", "zebra"])
>>> df
       a   b
tiger  1   2
zebra  2   3
>>> df.mean()
a   1.5
b   2.5
dtype: float64

Using axis=1

>>> df.mean(axis=1)
tiger   1.5
zebra   2.5
dtype: float64

In this case, numeric_only should be set to True to avoid getting an error.

>>> df = pd.DataFrame({"a": [1, 2], "b": ["T", "Z"]}, index=["tiger", "zebra"])
>>> df.mean(numeric_only=True)
a   1.5
dtype: float64
median(*, axis: Axis = 0, skipna: bool = True, numeric_only: bool = False, **kwargs) Series#
median(*, axis: None, skipna: bool = True, numeric_only: bool = False, **kwargs) Any
median(*, axis: Axis | None, skipna: bool = True, numeric_only: bool = False, **kwargs) Series | Any

Return the median of the values over the requested axis.

Parameters:
  • axis ({index (0), columns (1)}) –

    Axis for the function to be applied on. For Series this parameter is unused and defaults to 0.

    For DataFrames, specifying axis=None will apply the aggregation across both axes.

    Added in version 2.0.0.

  • skipna (bool, default True) – Exclude NA/null values when computing the result.

  • numeric_only (bool, default False) – Include only float, int, boolean columns.

  • **kwargs – Additional keyword arguments to be passed to the function.

Returns:

Value containing the calculation referenced in the description.

Return type:

Series or scalar

See also

Series.sum

Return the sum.

Series.min

Return the minimum.

Series.max

Return the maximum.

Series.idxmin

Return the index of the minimum.

Series.idxmax

Return the index of the maximum.

DataFrame.sum

Return the sum over the requested axis.

DataFrame.min

Return the minimum over the requested axis.

DataFrame.max

Return the maximum over the requested axis.

DataFrame.idxmin

Return the index of the minimum over the requested axis.

DataFrame.idxmax

Return the index of the maximum over the requested axis.

Examples

>>> s = pd.Series([1, 2, 3])
>>> s.median()
2.0

With a DataFrame

>>> df = pd.DataFrame({"a": [1, 2], "b": [2, 3]}, index=["tiger", "zebra"])
>>> df
       a   b
tiger  1   2
zebra  2   3
>>> df.median()
a   1.5
b   2.5
dtype: float64

Using axis=1

>>> df.median(axis=1)
tiger   1.5
zebra   2.5
dtype: float64

In this case, numeric_only should be set to True to avoid getting an error.

>>> df = pd.DataFrame({"a": [1, 2], "b": ["T", "Z"]}, index=["tiger", "zebra"])
>>> df.median(numeric_only=True)
a   1.5
dtype: float64
melt(id_vars=None, value_vars=None, var_name=None, value_name='value', col_level=None, ignore_index=True)#

Unpivot DataFrame from wide to long format, optionally leaving identifiers set.

This function is useful to massage a DataFrame into a format where one or more columns are identifier variables (id_vars), while all other columns, considered measured variables (value_vars), are “unpivoted” to the row axis, leaving just two non-identifier columns, ‘variable’ and ‘value’.

Parameters:
  • id_vars (scalar, tuple, list, or ndarray, optional) – Column(s) to use as identifier variables.

  • value_vars (scalar, tuple, list, or ndarray, optional) – Column(s) to unpivot. If not specified, uses all columns that are not set as id_vars.

  • var_name (scalar, default None) – Name to use for the ‘variable’ column. If None it uses frame.columns.name or ‘variable’.

  • value_name (scalar, default 'value') – Name to use for the ‘value’ column, can’t be an existing column label.

  • col_level (scalar, optional) – If columns are a MultiIndex then use this level to melt.

  • ignore_index (bool, default True) – If True, original index is ignored. If False, original index is retained. Index labels will be repeated as necessary.

Returns:

Unpivoted DataFrame.

Return type:

DataFrame

See also

melt

Identical method.

pivot_table

Create a spreadsheet-style pivot table as a DataFrame.

DataFrame.pivot

Return reshaped DataFrame organized by given index / column values.

DataFrame.explode

Explode a DataFrame from list-like columns to long format.

Notes

Reference the user guide for more examples.

Examples

>>> df = pd.DataFrame(
...     {
...         "A": {0: "a", 1: "b", 2: "c"},
...         "B": {0: 1, 1: 3, 2: 5},
...         "C": {0: 2, 1: 4, 2: 6},
...     }
... )
>>> df
A  B  C
0  a  1  2
1  b  3  4
2  c  5  6
>>> df.melt(id_vars=["A"], value_vars=["B"])
A variable  value
0  a        B      1
1  b        B      3
2  c        B      5
>>> df.melt(id_vars=["A"], value_vars=["B", "C"])
A variable  value
0  a        B      1
1  b        B      3
2  c        B      5
3  a        C      2
4  b        C      4
5  c        C      6

The names of ‘variable’ and ‘value’ columns can be customized:

>>> df.melt(
...     id_vars=["A"],
...     value_vars=["B"],
...     var_name="myVarname",
...     value_name="myValname",
... )
A myVarname  myValname
0  a         B          1
1  b         B          3
2  c         B          5

Original index values can be kept around:

>>> df.melt(id_vars=["A"], value_vars=["B", "C"], ignore_index=False)
A variable  value
0  a        B      1
1  b        B      3
2  c        B      5
0  a        C      2
1  b        C      4
2  c        C      6

If you have multi-index columns:

>>> df.columns = [list("ABC"), list("DEF")]
>>> df
A  B  C
D  E  F
0  a  1  2
1  b  3  4
2  c  5  6
>>> df.melt(col_level=0, id_vars=["A"], value_vars=["B"])
A variable  value
0  a        B      1
1  b        B      3
2  c        B      5
>>> df.melt(id_vars=[("A", "D")], value_vars=[("B", "E")])
(A, D) variable_0 variable_1  value
0      a          B          E      1
1      b          B          E      3
2      c          B          E      5
memory_usage(index=True, deep=False)#

Return the memory usage of each column in bytes.

The memory usage can optionally include the contribution of the index and elements of object dtype.

This value is displayed in DataFrame.info by default. This can be suppressed by setting pandas.options.display.memory_usage to False.

Parameters:
  • index (bool, default True) – Specifies whether to include the memory usage of the DataFrame’s index in returned Series. If index=True, the memory usage of the index is the first item in the output.

  • deep (bool, default False) – If True, introspect the data deeply by interrogating object dtypes for system-level memory consumption, and include it in the returned values.

Returns:

A Series whose index is the original column names and whose values is the memory usage of each column in bytes.

Return type:

Series

See also

numpy.ndarray.nbytes

Total bytes consumed by the elements of an ndarray.

Series.memory_usage

Bytes consumed by a Series.

Categorical

Memory-efficient array for string values with many repeated values.

DataFrame.info

Concise summary of a DataFrame.

Notes

See the Frequently Asked Questions for more details.

Examples

>>> dtypes = ["int64", "float64", "complex128", "object", "bool"]
>>> data = dict([(t, np.ones(shape=5000, dtype=int).astype(t)) for t in dtypes])
>>> df = pd.DataFrame(data)
>>> df.head()
   int64  float64            complex128  object  bool
0      1      1.0              1.0+0.0j       1  True
1      1      1.0              1.0+0.0j       1  True
2      1      1.0              1.0+0.0j       1  True
3      1      1.0              1.0+0.0j       1  True
4      1      1.0              1.0+0.0j       1  True
>>> df.memory_usage()
Index           132
int64         40000
float64       40000
complex128    80000
object        40000
bool           5000
dtype: int64
>>> df.memory_usage(index=False)
int64         40000
float64       40000
complex128    80000
object        40000
bool           5000
dtype: int64

The memory footprint of object dtype columns is ignored by default:

>>> df.memory_usage(deep=True)
Index            132
int64          40000
float64        40000
complex128     80000
object        180000
bool            5000
dtype: int64

Use a Categorical for efficient storage of an object-dtype column with many repeated values.

>>> df["object"].astype("category").memory_usage(deep=True)
5140
merge(right, how='inner', on=None, left_on=None, right_on=None, left_index=False, right_index=False, sort=False, suffixes=('_x', '_y'), copy=<no_default>, indicator=False, validate=None)#

Merge DataFrame or named Series objects with a database-style join.

A named Series object is treated as a DataFrame with a single named column.

The join is done on columns or indexes. If joining columns on columns, the DataFrame indexes will be ignored. Otherwise if joining indexes on indexes or indexes on a column or columns, the index will be passed on. When performing a cross merge, no column specifications to merge on are allowed.

Warning

If both key columns contain rows where the key is a null value, those rows will be matched against each other. This is different from usual SQL join behaviour and can lead to unexpected results.

Parameters:
  • right (DataFrame or named Series) – Object to merge with.

  • how ({'left', 'right', 'outer', 'inner', 'cross', 'left_anti', 'right_anti'},) –

    default ‘inner’ Type of merge to be performed.

    • left: use only keys from left frame, similar to a SQL left outer join; preserve key order.

    • right: use only keys from right frame, similar to a SQL right outer join; preserve key order.

    • outer: use union of keys from both frames, similar to a SQL full outer join; sort keys lexicographically.

    • inner: use intersection of keys from both frames, similar to a SQL inner join; preserve the order of the left keys.

    • cross: creates the cartesian product from both frames, preserves the order of the left keys.

    • left_anti: use only keys from left frame that are not in right frame, similar to SQL left anti join; preserve key order.

      Added in version 3.0.

    • right_anti: use only keys from right frame that are not in left frame, similar to SQL right anti join; preserve key order.

      Added in version 3.0.

  • on (Hashable or a sequence of the previous) – Column or index level names to join on. These must be found in both DataFrames. If on is None and not merging on indexes then this defaults to the intersection of the columns in both DataFrames.

  • left_on (Hashable or a sequence of the previous, or array-like) – Column or index level names to join on in the left DataFrame. Can also be an array or list of arrays of the length of the left DataFrame. These arrays are treated as if they are columns.

  • right_on (Hashable or a sequence of the previous, or array-like) – Column or index level names to join on in the right DataFrame. Can also be an array or list of arrays of the length of the right DataFrame. These arrays are treated as if they are columns.

  • left_index (bool, default False) – Use the index from the left DataFrame as the join key(s). If it is a MultiIndex, the number of keys in the other DataFrame (either the index or a number of columns) must match the number of levels.

  • right_index (bool, default False) – Use the index from the right DataFrame as the join key. Same caveats as left_index.

  • sort (bool, default False) – Sort the join keys lexicographically in the result DataFrame. If False, the order of the join keys depends on the join type (how keyword).

  • suffixes (list-like, default is ("_x", "_y")) – A length-2 sequence where each element is optionally a string indicating the suffix to add to overlapping column names in left and right respectively. Pass a value of None instead of a string to indicate that the column name from left or right should be left as-is, with no suffix. At least one of the values must not be None.

  • copy (bool, default False) –

    This keyword is now ignored; changing its value will have no impact on the method.

    Deprecated since version 3.0.0: This keyword is ignored and will be removed in pandas 4.0. Since pandas 3.0, this method always returns a new object using a lazy copy mechanism that defers copies until necessary (Copy-on-Write). See the user guide on Copy-on-Write for more details.

  • indicator (bool or str, default False) – If True, adds a column to the output DataFrame called “_merge” with information on the source of each row. The column can be given a different name by providing a string argument. The column will have a Categorical type with the value of “left_only” for observations whose merge key only appears in the left DataFrame, “right_only” for observations whose merge key only appears in the right DataFrame, and “both” if the observation’s merge key is found in both DataFrames.

  • validate (str, optional) –

    If specified, checks if merge is of specified type.

    • ”one_to_one” or “1:1”: check if merge keys are unique in both left and right datasets.

    • ”one_to_many” or “1:m”: check if merge keys are unique in left dataset.

    • ”many_to_one” or “m:1”: check if merge keys are unique in right dataset.

    • ”many_to_many” or “m:m”: allowed, but does not result in checks.

Returns:

A DataFrame of the two merged objects.

Return type:

DataFrame

See also

merge_ordered

Merge with optional filling/interpolation.

merge_asof

Merge on nearest keys.

DataFrame.join

Similar method using indices.

Examples

>>> df1 = pd.DataFrame({'lkey': ['foo', 'bar', 'baz', 'foo'],
...                     'value': [1, 2, 3, 5]})
>>> df2 = pd.DataFrame({'rkey': ['foo', 'bar', 'baz', 'foo'],
...                     'value': [5, 6, 7, 8]})
>>> df1
    lkey value
0   foo      1
1   bar      2
2   baz      3
3   foo      5
>>> df2
    rkey value
0   foo      5
1   bar      6
2   baz      7
3   foo      8

Merge df1 and df2 on the lkey and rkey columns. The value columns have the default suffixes, _x and _y, appended.

>>> df1.merge(df2, left_on='lkey', right_on='rkey')
  lkey  value_x rkey  value_y
0  foo        1  foo        5
1  foo        1  foo        8
2  bar        2  bar        6
3  baz        3  baz        7
4  foo        5  foo        5
5  foo        5  foo        8

Merge DataFrames df1 and df2 with specified left and right suffixes appended to any overlapping columns.

>>> df1.merge(df2, left_on='lkey', right_on='rkey',
...           suffixes=('_left', '_right'))
  lkey  value_left rkey  value_right
0  foo           1  foo            5
1  foo           1  foo            8
2  bar           2  bar            6
3  baz           3  baz            7
4  foo           5  foo            5
5  foo           5  foo            8

Merge DataFrames df1 and df2, but raise an exception if the DataFrames have any overlapping columns.

>>> df1.merge(df2, left_on='lkey', right_on='rkey', suffixes=(False, False))
Traceback (most recent call last):
...
ValueError: columns overlap but no suffix specified:
    Index(['value'], dtype='object')
>>> df1 = pd.DataFrame({'a': ['foo', 'bar'], 'b': [1, 2]})
>>> df2 = pd.DataFrame({'a': ['foo', 'baz'], 'c': [3, 4]})
>>> df1
      a  b
0   foo  1
1   bar  2
>>> df2
      a  c
0   foo  3
1   baz  4
>>> df1.merge(df2, how='inner', on='a')
      a  b  c
0   foo  1  3
>>> df1.merge(df2, how='left', on='a')
      a  b  c
0   foo  1  3.0
1   bar  2  NaN
>>> df1 = pd.DataFrame({'left': ['foo', 'bar']})
>>> df2 = pd.DataFrame({'right': [7, 8]})
>>> df1
    left
0   foo
1   bar
>>> df2
    right
0   7
1   8
>>> df1.merge(df2, how='cross')
   left  right
0   foo      7
1   foo      8
2   bar      7
3   bar      8
min(*, axis: Axis = 0, skipna: bool = True, numeric_only: bool = False, **kwargs) Series#
min(*, axis: None, skipna: bool = True, numeric_only: bool = False, **kwargs) Any
min(*, axis: Axis | None, skipna: bool = True, numeric_only: bool = False, **kwargs) Series | Any

Return the minimum of the values over the requested axis.

If you want the index of the minimum, use idxmin. This is the equivalent of the numpy.ndarray method argmin.

Parameters:
  • axis ({index (0), columns (1)}) –

    Axis for the function to be applied on. For Series this parameter is unused and defaults to 0.

    For DataFrames, specifying axis=None will apply the aggregation across both axes.

    Added in version 2.0.0.

  • skipna (bool, default True) – Exclude NA/null values when computing the result.

  • numeric_only (bool, default False) – Include only float, int, boolean columns.

  • **kwargs – Additional keyword arguments to be passed to the function.

Returns:

Value containing the calculation referenced in the description.

Return type:

Series or scalar

See also

Series.sum

Return the sum.

Series.min

Return the minimum.

Series.max

Return the maximum.

Series.idxmin

Return the index of the minimum.

Series.idxmax

Return the index of the maximum.

DataFrame.sum

Return the sum over the requested axis.

DataFrame.min

Return the minimum over the requested axis.

DataFrame.max

Return the maximum over the requested axis.

DataFrame.idxmin

Return the index of the minimum over the requested axis.

DataFrame.idxmax

Return the index of the maximum over the requested axis.

Examples

>>> idx = pd.MultiIndex.from_arrays(
...     [["warm", "warm", "cold", "cold"], ["dog", "falcon", "fish", "spider"]],
...     names=["blooded", "animal"],
... )
>>> s = pd.Series([4, 2, 0, 8], name="legs", index=idx)
>>> s
blooded  animal
warm     dog       4
         falcon    2
cold     fish      0
         spider    8
Name: legs, dtype: int64
>>> s.min()
0
mod(other, axis='columns', level=None, fill_value=None)#

Get Modulo of dataframe and other, element-wise (binary operator mod).

Equivalent to dataframe % other, but with support to substitute a fill_value for missing data in one of the inputs. With reverse version, rmod.

Among flexible wrappers (add, sub, mul, div, floordiv, mod, pow) to arithmetic operators: +, -, *, /, //, %, **.

Parameters:
  • other (scalar, sequence, Series, dict or DataFrame) – Any single or multiple element data structure, or list-like object.

  • axis ({0 or 'index', 1 or 'columns'}) – Whether to compare by the index (0 or ‘index’) or columns. (1 or ‘columns’). For Series input, axis to match Series index on.

  • level (int or label) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (float or None, default None) – Fill existing missing (NaN) values, and any new element needed for successful DataFrame alignment, with this value before computation. If data in both corresponding DataFrame locations is missing the result will be missing.

Returns:

Result of the arithmetic operation.

Return type:

DataFrame

See also

DataFrame.add

Add DataFrames.

DataFrame.sub

Subtract DataFrames.

DataFrame.mul

Multiply DataFrames.

DataFrame.div

Divide DataFrames (float division).

DataFrame.truediv

Divide DataFrames (float division).

DataFrame.floordiv

Divide DataFrames (integer division).

DataFrame.mod

Calculate modulo (remainder after division).

DataFrame.pow

Calculate exponential power.

Notes

Mismatched indices will be unioned together.

Examples

>>> df = pd.DataFrame({'angles': [0, 3, 4],
...                    'degrees': [360, 180, 360]},
...                   index=['circle', 'triangle', 'rectangle'])
>>> df
           angles  degrees
circle          0      360
triangle        3      180
rectangle       4      360

Add a scalar with operator version which return the same results.

>>> df + 1
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361
>>> df.add(1)
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361

Divide by constant with reverse version.

>>> df.div(10)
           angles  degrees
circle        0.0     36.0
triangle      0.3     18.0
rectangle     0.4     36.0
>>> df.rdiv(10)
             angles   degrees
circle          inf  0.027778
triangle   3.333333  0.055556
rectangle  2.500000  0.027778

Subtract a list and Series by axis with operator version.

>>> df - [1, 2]
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub([1, 2], axis='columns')
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub(pd.Series([1, 1, 1], index=['circle', 'triangle', 'rectangle']),
...        axis='index')
           angles  degrees
circle         -1      359
triangle        2      179
rectangle       3      359

Multiply a dictionary by axis.

>>> df.mul({'angles': 0, 'degrees': 2})
            angles  degrees
circle           0      720
triangle         0      360
rectangle        0      720
>>> df.mul({'circle': 0, 'triangle': 2, 'rectangle': 3}, axis='index')
            angles  degrees
circle           0        0
triangle         6      360
rectangle       12     1080

Multiply a DataFrame of different shape with operator version.

>>> other = pd.DataFrame({'angles': [0, 3, 4]},
...                      index=['circle', 'triangle', 'rectangle'])
>>> other
           angles
circle          0
triangle        3
rectangle       4
>>> df * other
           angles  degrees
circle          0      NaN
triangle        9      NaN
rectangle      16      NaN
>>> df.mul(other, fill_value=0)
           angles  degrees
circle          0      0.0
triangle        9      0.0
rectangle      16      0.0

Divide by a MultiIndex by level.

>>> df_multindex = pd.DataFrame({'angles': [0, 3, 4, 4, 5, 6],
...                              'degrees': [360, 180, 360, 360, 540, 720]},
...                             index=[['A', 'A', 'A', 'B', 'B', 'B'],
...                                    ['circle', 'triangle', 'rectangle',
...                                     'square', 'pentagon', 'hexagon']])
>>> df_multindex
             angles  degrees
A circle          0      360
  triangle        3      180
  rectangle       4      360
B square          4      360
  pentagon        5      540
  hexagon         6      720
>>> df.div(df_multindex, level=1, fill_value=0)
             angles  degrees
A circle        NaN      1.0
  triangle      1.0      1.0
  rectangle     1.0      1.0
B square        0.0      0.0
  pentagon      0.0      0.0
  hexagon       0.0      0.0
>>> df_pow = pd.DataFrame({'A': [2, 3, 4, 5],
...                        'B': [6, 7, 8, 9]})
>>> df_pow.pow(2)
    A   B
0   4  36
1   9  49
2  16  64
3  25  81
mode(axis=0, numeric_only=False, dropna=True)#

Get the mode(s) of each element along the selected axis.

The mode of a set of values is the value that appears most often. It can be multiple values.

Parameters:
  • axis ({0 or 'index', 1 or 'columns'}, default 0) –

    The axis to iterate over while searching for the mode:

    • 0 or ‘index’ : get mode of each column

    • 1 or ‘columns’ : get mode of each row.

  • numeric_only (bool, default False) – If True, only apply to numeric columns.

  • dropna (bool, default True) – Don’t consider counts of NaN/NaT.

Returns:

The modes of each column or row.

Return type:

DataFrame

See also

Series.mode

Return the highest frequency value in a Series.

Series.value_counts

Return the counts of values in a Series.

Examples

>>> df = pd.DataFrame(
...     [
...         ("bird", 2, 2),
...         ("mammal", 4, np.nan),
...         ("arthropod", 8, 0),
...         ("bird", 2, np.nan),
...     ],
...     index=("falcon", "horse", "spider", "ostrich"),
...     columns=("species", "legs", "wings"),
... )
>>> df
           species  legs  wings
falcon        bird     2    2.0
horse       mammal     4    NaN
spider   arthropod     8    0.0
ostrich       bird     2    NaN

By default, missing values are not considered, and the mode of wings are both 0 and 2. Because the resulting DataFrame has two rows, the second row of species and legs contains NaN.

>>> df.mode()
  species  legs  wings
0    bird   2.0    0.0
1     NaN   NaN    2.0

Setting dropna=False NaN values are considered and they can be the mode (like for wings).

>>> df.mode(dropna=False)
  species  legs  wings
0    bird     2    NaN

Setting numeric_only=True, only the mode of numeric columns is computed, and columns of other types are ignored.

>>> df.mode(numeric_only=True)
   legs  wings
0   2.0    0.0
1   NaN    2.0

To compute the mode over columns and not rows, use the axis parameter:

>>> df.mode(axis="columns", numeric_only=True)
           0    1
falcon   2.0  NaN
horse    4.0  NaN
spider   0.0  8.0
ostrich  2.0  NaN
mul(other, axis='columns', level=None, fill_value=None)#

Get Multiplication of dataframe and other, element-wise (binary operator mul).

Equivalent to dataframe * other, but with support to substitute a fill_value for missing data in one of the inputs. With reverse version, rmul.

Among flexible wrappers (add, sub, mul, div, floordiv, mod, pow) to arithmetic operators: +, -, *, /, //, %, **.

Parameters:
  • other (scalar, sequence, Series, dict or DataFrame) – Any single or multiple element data structure, or list-like object.

  • axis ({0 or 'index', 1 or 'columns'}) – Whether to compare by the index (0 or ‘index’) or columns. (1 or ‘columns’). For Series input, axis to match Series index on.

  • level (int or label) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (float or None, default None) – Fill existing missing (NaN) values, and any new element needed for successful DataFrame alignment, with this value before computation. If data in both corresponding DataFrame locations is missing the result will be missing.

Returns:

Result of the arithmetic operation.

Return type:

DataFrame

See also

DataFrame.add

Add DataFrames.

DataFrame.sub

Subtract DataFrames.

DataFrame.mul

Multiply DataFrames.

DataFrame.div

Divide DataFrames (float division).

DataFrame.truediv

Divide DataFrames (float division).

DataFrame.floordiv

Divide DataFrames (integer division).

DataFrame.mod

Calculate modulo (remainder after division).

DataFrame.pow

Calculate exponential power.

Notes

Mismatched indices will be unioned together.

Examples

>>> df = pd.DataFrame({'angles': [0, 3, 4],
...                    'degrees': [360, 180, 360]},
...                   index=['circle', 'triangle', 'rectangle'])
>>> df
           angles  degrees
circle          0      360
triangle        3      180
rectangle       4      360

Add a scalar with operator version which return the same results.

>>> df + 1
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361
>>> df.add(1)
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361

Divide by constant with reverse version.

>>> df.div(10)
           angles  degrees
circle        0.0     36.0
triangle      0.3     18.0
rectangle     0.4     36.0
>>> df.rdiv(10)
             angles   degrees
circle          inf  0.027778
triangle   3.333333  0.055556
rectangle  2.500000  0.027778

Subtract a list and Series by axis with operator version.

>>> df - [1, 2]
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub([1, 2], axis='columns')
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub(pd.Series([1, 1, 1], index=['circle', 'triangle', 'rectangle']),
...        axis='index')
           angles  degrees
circle         -1      359
triangle        2      179
rectangle       3      359

Multiply a dictionary by axis.

>>> df.mul({'angles': 0, 'degrees': 2})
            angles  degrees
circle           0      720
triangle         0      360
rectangle        0      720
>>> df.mul({'circle': 0, 'triangle': 2, 'rectangle': 3}, axis='index')
            angles  degrees
circle           0        0
triangle         6      360
rectangle       12     1080

Multiply a DataFrame of different shape with operator version.

>>> other = pd.DataFrame({'angles': [0, 3, 4]},
...                      index=['circle', 'triangle', 'rectangle'])
>>> other
           angles
circle          0
triangle        3
rectangle       4
>>> df * other
           angles  degrees
circle          0      NaN
triangle        9      NaN
rectangle      16      NaN
>>> df.mul(other, fill_value=0)
           angles  degrees
circle          0      0.0
triangle        9      0.0
rectangle      16      0.0

Divide by a MultiIndex by level.

>>> df_multindex = pd.DataFrame({'angles': [0, 3, 4, 4, 5, 6],
...                              'degrees': [360, 180, 360, 360, 540, 720]},
...                             index=[['A', 'A', 'A', 'B', 'B', 'B'],
...                                    ['circle', 'triangle', 'rectangle',
...                                     'square', 'pentagon', 'hexagon']])
>>> df_multindex
             angles  degrees
A circle          0      360
  triangle        3      180
  rectangle       4      360
B square          4      360
  pentagon        5      540
  hexagon         6      720
>>> df.div(df_multindex, level=1, fill_value=0)
             angles  degrees
A circle        NaN      1.0
  triangle      1.0      1.0
  rectangle     1.0      1.0
B square        0.0      0.0
  pentagon      0.0      0.0
  hexagon       0.0      0.0
>>> df_pow = pd.DataFrame({'A': [2, 3, 4, 5],
...                        'B': [6, 7, 8, 9]})
>>> df_pow.pow(2)
    A   B
0   4  36
1   9  49
2  16  64
3  25  81
multiply(other, axis='columns', level=None, fill_value=None)#

Get Multiplication of dataframe and other, element-wise (binary operator mul).

Equivalent to dataframe * other, but with support to substitute a fill_value for missing data in one of the inputs. With reverse version, rmul.

Among flexible wrappers (add, sub, mul, div, floordiv, mod, pow) to arithmetic operators: +, -, *, /, //, %, **.

Parameters:
  • other (scalar, sequence, Series, dict or DataFrame) – Any single or multiple element data structure, or list-like object.

  • axis ({0 or 'index', 1 or 'columns'}) – Whether to compare by the index (0 or ‘index’) or columns. (1 or ‘columns’). For Series input, axis to match Series index on.

  • level (int or label) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (float or None, default None) – Fill existing missing (NaN) values, and any new element needed for successful DataFrame alignment, with this value before computation. If data in both corresponding DataFrame locations is missing the result will be missing.

Returns:

Result of the arithmetic operation.

Return type:

DataFrame

See also

DataFrame.add

Add DataFrames.

DataFrame.sub

Subtract DataFrames.

DataFrame.mul

Multiply DataFrames.

DataFrame.div

Divide DataFrames (float division).

DataFrame.truediv

Divide DataFrames (float division).

DataFrame.floordiv

Divide DataFrames (integer division).

DataFrame.mod

Calculate modulo (remainder after division).

DataFrame.pow

Calculate exponential power.

Notes

Mismatched indices will be unioned together.

Examples

>>> df = pd.DataFrame({'angles': [0, 3, 4],
...                    'degrees': [360, 180, 360]},
...                   index=['circle', 'triangle', 'rectangle'])
>>> df
           angles  degrees
circle          0      360
triangle        3      180
rectangle       4      360

Add a scalar with operator version which return the same results.

>>> df + 1
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361
>>> df.add(1)
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361

Divide by constant with reverse version.

>>> df.div(10)
           angles  degrees
circle        0.0     36.0
triangle      0.3     18.0
rectangle     0.4     36.0
>>> df.rdiv(10)
             angles   degrees
circle          inf  0.027778
triangle   3.333333  0.055556
rectangle  2.500000  0.027778

Subtract a list and Series by axis with operator version.

>>> df - [1, 2]
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub([1, 2], axis='columns')
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub(pd.Series([1, 1, 1], index=['circle', 'triangle', 'rectangle']),
...        axis='index')
           angles  degrees
circle         -1      359
triangle        2      179
rectangle       3      359

Multiply a dictionary by axis.

>>> df.mul({'angles': 0, 'degrees': 2})
            angles  degrees
circle           0      720
triangle         0      360
rectangle        0      720
>>> df.mul({'circle': 0, 'triangle': 2, 'rectangle': 3}, axis='index')
            angles  degrees
circle           0        0
triangle         6      360
rectangle       12     1080

Multiply a DataFrame of different shape with operator version.

>>> other = pd.DataFrame({'angles': [0, 3, 4]},
...                      index=['circle', 'triangle', 'rectangle'])
>>> other
           angles
circle          0
triangle        3
rectangle       4
>>> df * other
           angles  degrees
circle          0      NaN
triangle        9      NaN
rectangle      16      NaN
>>> df.mul(other, fill_value=0)
           angles  degrees
circle          0      0.0
triangle        9      0.0
rectangle      16      0.0

Divide by a MultiIndex by level.

>>> df_multindex = pd.DataFrame({'angles': [0, 3, 4, 4, 5, 6],
...                              'degrees': [360, 180, 360, 360, 540, 720]},
...                             index=[['A', 'A', 'A', 'B', 'B', 'B'],
...                                    ['circle', 'triangle', 'rectangle',
...                                     'square', 'pentagon', 'hexagon']])
>>> df_multindex
             angles  degrees
A circle          0      360
  triangle        3      180
  rectangle       4      360
B square          4      360
  pentagon        5      540
  hexagon         6      720
>>> df.div(df_multindex, level=1, fill_value=0)
             angles  degrees
A circle        NaN      1.0
  triangle      1.0      1.0
  rectangle     1.0      1.0
B square        0.0      0.0
  pentagon      0.0      0.0
  hexagon       0.0      0.0
>>> df_pow = pd.DataFrame({'A': [2, 3, 4, 5],
...                        'B': [6, 7, 8, 9]})
>>> df_pow.pow(2)
    A   B
0   4  36
1   9  49
2  16  64
3  25  81
ne(other, axis='columns', level=None)#

Get Not equal to of dataframe and other, element-wise (binary operator ne).

Among flexible wrappers (eq, ne, le, lt, ge, gt) to comparison operators.

Equivalent to ==, !=, <=, <, >=, > with support to choose axis (rows or columns) and level for comparison.

Parameters:
  • other (scalar, sequence, Series, or DataFrame) – Any single or multiple element data structure, or list-like object.

  • axis ({0 or 'index', 1 or 'columns'}, default 'columns') – Whether to compare by the index (0 or ‘index’) or columns (1 or ‘columns’).

  • level (int or label) – Broadcast across a level, matching Index values on the passed MultiIndex level.

Returns:

Result of the comparison.

Return type:

DataFrame of bool

See also

DataFrame.eq

Compare DataFrames for equality elementwise.

DataFrame.ne

Compare DataFrames for inequality elementwise.

DataFrame.le

Compare DataFrames for less than inequality or equality elementwise.

DataFrame.lt

Compare DataFrames for strictly less than inequality elementwise.

DataFrame.ge

Compare DataFrames for greater than inequality or equality elementwise.

DataFrame.gt

Compare DataFrames for strictly greater than inequality elementwise.

Notes

Mismatched indices will be unioned together. NaN values are considered different (i.e. NaN != NaN).

Examples

>>> df = pd.DataFrame(
...     {"cost": [250, 150, 100], "revenue": [100, 250, 300]},
...     index=["A", "B", "C"],
... )
>>> df
   cost  revenue
A   250      100
B   150      250
C   100      300

Comparison with a scalar, using either the operator or method:

>>> df == 100
    cost  revenue
A  False     True
B  False    False
C   True    False
>>> df.eq(100)
    cost  revenue
A  False     True
B  False    False
C   True    False

When other is a Series, the columns of a DataFrame are aligned with the index of other and broadcast:

>>> df != pd.Series([100, 250], index=["cost", "revenue"])
    cost  revenue
A   True     True
B   True    False
C  False     True

Use the method to control the broadcast axis:

>>> df.ne(pd.Series([100, 300], index=["A", "D"]), axis="index")
   cost  revenue
A  True    False
B  True     True
C  True     True
D  True     True

When comparing to an arbitrary sequence, the number of columns must match the number elements in other:

>>> df == [250, 100]
    cost  revenue
A   True     True
B  False    False
C  False    False

Use the method to control the axis:

>>> df.eq([250, 250, 100], axis="index")
    cost  revenue
A   True    False
B  False     True
C   True    False

Compare to a DataFrame of different shape.

>>> other = pd.DataFrame(
...     {"revenue": [300, 250, 100, 150]}, index=["A", "B", "C", "D"]
... )
>>> other
   revenue
A      300
B      250
C      100
D      150
>>> df.gt(other)
    cost  revenue
A  False    False
B  False    False
C  False     True
D  False    False

Compare to a MultiIndex by level.

>>> df_multindex = pd.DataFrame(
...     {
...         "cost": [250, 150, 100, 150, 300, 220],
...         "revenue": [100, 250, 300, 200, 175, 225],
...     },
...     index=[
...         ["Q1", "Q1", "Q1", "Q2", "Q2", "Q2"],
...         ["A", "B", "C", "A", "B", "C"],
...     ],
... )
>>> df_multindex
      cost  revenue
Q1 A   250      100
   B   150      250
   C   100      300
Q2 A   150      200
   B   300      175
   C   220      225
>>> df.le(df_multindex, level=1)
       cost  revenue
Q1 A   True     True
   B   True     True
   C   True     True
Q2 A  False     True
   B   True    False
   C   True    False
nlargest(n, columns, keep='first')#

Return the first n rows ordered by columns in descending order.

Return the first n rows with the largest values in columns, in descending order. The columns that are not specified are returned as well, but not used for ordering.

This method is equivalent to df.sort_values(columns, ascending=False).head(n), but more performant.

Parameters:
  • n (int) – Number of rows to return.

  • columns (Hashable or a sequence of the previous) – Column label(s) to order by.

  • keep ({'first', 'last', 'all'}, default 'first') –

    Where there are duplicate values:

    • first : prioritize the first occurrence(s)

    • last : prioritize the last occurrence(s)

    • all : keep all the ties of the smallest item even if it means selecting more than n items.

Returns:

The first n rows ordered by the given columns in descending order.

Return type:

DataFrame

See also

DataFrame.nsmallest

Return the first n rows ordered by columns in ascending order.

DataFrame.sort_values

Sort DataFrame by the values.

DataFrame.head

Return the first n rows without re-ordering.

Notes

This function cannot be used with all column types. For example, when specifying columns with object or category dtypes, TypeError is raised.

Examples

>>> df = pd.DataFrame(
...     {
...         "population": [
...             59000000,
...             65000000,
...             434000,
...             434000,
...             434000,
...             337000,
...             11300,
...             11300,
...             11300,
...         ],
...         "GDP": [1937894, 2583560, 12011, 4520, 12128, 17036, 182, 38, 311],
...         "alpha-2": ["IT", "FR", "MT", "MV", "BN", "IS", "NR", "TV", "AI"],
...     },
...     index=[
...         "Italy",
...         "France",
...         "Malta",
...         "Maldives",
...         "Brunei",
...         "Iceland",
...         "Nauru",
...         "Tuvalu",
...         "Anguilla",
...     ],
... )
>>> df
          population      GDP alpha-2
Italy       59000000  1937894      IT
France      65000000  2583560      FR
Malta         434000    12011      MT
Maldives      434000     4520      MV
Brunei        434000    12128      BN
Iceland       337000    17036      IS
Nauru          11300      182      NR
Tuvalu         11300       38      TV
Anguilla       11300      311      AI

In the following example, we will use nlargest to select the three rows having the largest values in column “population”.

>>> df.nlargest(3, "population")
        population      GDP alpha-2
France    65000000  2583560      FR
Italy     59000000  1937894      IT
Malta       434000    12011      MT

When using keep='last', ties are resolved in reverse order:

>>> df.nlargest(3, "population", keep="last")
        population      GDP alpha-2
France    65000000  2583560      FR
Italy     59000000  1937894      IT
Brunei      434000    12128      BN

When using keep='all', the number of element kept can go beyond n if there are duplicate values for the smallest element, all the ties are kept:

>>> df.nlargest(3, "population", keep="all")
          population      GDP alpha-2
France      65000000  2583560      FR
Italy       59000000  1937894      IT
Malta         434000    12011      MT
Maldives      434000     4520      MV
Brunei        434000    12128      BN

However, nlargest does not keep n distinct largest elements:

>>> df.nlargest(5, "population", keep="all")
          population      GDP alpha-2
France      65000000  2583560      FR
Italy       59000000  1937894      IT
Malta         434000    12011      MT
Maldives      434000     4520      MV
Brunei        434000    12128      BN

To order by the largest values in column “population” and then “GDP”, we can specify multiple columns like in the next example.

>>> df.nlargest(3, ["population", "GDP"])
        population      GDP alpha-2
France    65000000  2583560      FR
Italy     59000000  1937894      IT
Brunei      434000    12128      BN
notna()#

Detect existing (non-missing) values.

Return a boolean same-sized object indicating if the values are not NA. Non-missing values get mapped to True. Characters such as empty strings '' or numpy.inf are not considered NA values. NA values, such as None or numpy.NaN, get mapped to False values.

Returns:

Mask of bool values for each element in Series/DataFrame that indicates whether an element is not an NA value.

Return type:

Series/DataFrame

See also

Series.notnull

Alias of notna.

DataFrame.notnull

Alias of notna.

Series.isna

Boolean inverse of notna.

DataFrame.isna

Boolean inverse of notna.

Series.dropna

Omit axes labels with missing values.

DataFrame.dropna

Omit axes labels with missing values.

notna

Top-level notna.

Examples

Show which entries in a DataFrame are not NA.

>>> df = pd.DataFrame(
...     dict(
...         age=[5, 6, np.nan],
...         born=[
...             pd.NaT,
...             pd.Timestamp("1939-05-27"),
...             pd.Timestamp("1940-04-25"),
...         ],
...         name=["Alfred", "Batman", ""],
...         toy=[None, "Batmobile", "Joker"],
...     )
... )
>>> df
   age       born    name        toy
0  5.0        NaT  Alfred        NaN
1  6.0 1939-05-27  Batman  Batmobile
2  NaN 1940-04-25              Joker
>>> df.notna()
     age   born  name    toy
0   True  False  True  False
1   True   True  True   True
2  False   True  True   True

Show which entries in a Series are not NA.

>>> ser = pd.Series([5, 6, np.nan])
>>> ser
0    5.0
1    6.0
2    NaN
dtype: float64
>>> ser.notna()
0     True
1     True
2    False
dtype: bool
notnull()#

DataFrame.notnull is an alias for DataFrame.notna.

Detect existing (non-missing) values.

Return a boolean same-sized object indicating if the values are not NA. Non-missing values get mapped to True. Characters such as empty strings '' or numpy.inf are not considered NA values. NA values, such as None or numpy.NaN, get mapped to False values.

Returns:

Mask of bool values for each element in Series/DataFrame that indicates whether an element is not an NA value.

Return type:

Series/DataFrame

See also

Series.notnull

Alias of notna.

DataFrame.notnull

Alias of notna.

Series.isna

Boolean inverse of notna.

DataFrame.isna

Boolean inverse of notna.

Series.dropna

Omit axes labels with missing values.

DataFrame.dropna

Omit axes labels with missing values.

notna

Top-level notna.

Examples

Show which entries in a DataFrame are not NA.

>>> df = pd.DataFrame(
...     dict(
...         age=[5, 6, np.nan],
...         born=[
...             pd.NaT,
...             pd.Timestamp("1939-05-27"),
...             pd.Timestamp("1940-04-25"),
...         ],
...         name=["Alfred", "Batman", ""],
...         toy=[None, "Batmobile", "Joker"],
...     )
... )
>>> df
   age       born    name        toy
0  5.0        NaT  Alfred        NaN
1  6.0 1939-05-27  Batman  Batmobile
2  NaN 1940-04-25              Joker
>>> df.notnull()
     age   born  name    toy
0   True  False  True  False
1   True   True  True   True
2  False   True  True   True

Show which entries in a Series are not NA.

>>> ser = pd.Series([5, 6, np.nan])
>>> ser
0    5.0
1    6.0
2    NaN
dtype: float64
>>> ser.notnull()
0     True
1     True
2    False
dtype: bool
nsmallest(n, columns, keep='first')#

Return the first n rows ordered by columns in ascending order.

Return the first n rows with the smallest values in columns, in ascending order. The columns that are not specified are returned as well, but not used for ordering.

This method is equivalent to df.sort_values(columns, ascending=True).head(n), but more performant.

Parameters:
  • n (int) – Number of items to retrieve.

  • columns (list or str) – Column name or names to order by.

  • keep ({'first', 'last', 'all'}, default 'first') –

    Where there are duplicate values:

    • first : take the first occurrence.

    • last : take the last occurrence.

    • all : keep all the ties of the largest item even if it means selecting more than n items.

Returns:

DataFrame with the first n rows ordered by columns in ascending order.

Return type:

DataFrame

See also

DataFrame.nlargest

Return the first n rows ordered by columns in descending order.

DataFrame.sort_values

Sort DataFrame by the values.

DataFrame.head

Return the first n rows without re-ordering.

Examples

>>> df = pd.DataFrame(
...     {
...         "population": [
...             59000000,
...             65000000,
...             434000,
...             434000,
...             434000,
...             337000,
...             337000,
...             11300,
...             11300,
...         ],
...         "GDP": [1937894, 2583560, 12011, 4520, 12128, 17036, 182, 38, 311],
...         "alpha-2": ["IT", "FR", "MT", "MV", "BN", "IS", "NR", "TV", "AI"],
...     },
...     index=[
...         "Italy",
...         "France",
...         "Malta",
...         "Maldives",
...         "Brunei",
...         "Iceland",
...         "Nauru",
...         "Tuvalu",
...         "Anguilla",
...     ],
... )
>>> df
          population      GDP alpha-2
Italy       59000000  1937894      IT
France      65000000  2583560      FR
Malta         434000    12011      MT
Maldives      434000     4520      MV
Brunei        434000    12128      BN
Iceland       337000    17036      IS
Nauru         337000      182      NR
Tuvalu         11300       38      TV
Anguilla       11300      311      AI

In the following example, we will use nsmallest to select the three rows having the smallest values in column “population”.

>>> df.nsmallest(3, "population")
          population    GDP alpha-2
Tuvalu         11300     38      TV
Anguilla       11300    311      AI
Iceland       337000  17036      IS

When using keep='last', ties are resolved in reverse order:

>>> df.nsmallest(3, "population", keep="last")
          population  GDP alpha-2
Anguilla       11300  311      AI
Tuvalu         11300   38      TV
Nauru         337000  182      NR

When using keep='all', the number of element kept can go beyond n if there are duplicate values for the largest element, all the ties are kept.

>>> df.nsmallest(3, "population", keep="all")
          population    GDP alpha-2
Tuvalu         11300     38      TV
Anguilla       11300    311      AI
Iceland       337000  17036      IS
Nauru         337000    182      NR

However, nsmallest does not keep n distinct smallest elements:

>>> df.nsmallest(4, "population", keep="all")
          population    GDP alpha-2
Tuvalu         11300     38      TV
Anguilla       11300    311      AI
Iceland       337000  17036      IS
Nauru         337000    182      NR

To order by the smallest values in column “population” and then “GDP”, we can specify multiple columns like in the next example.

>>> df.nsmallest(3, ["population", "GDP"])
          population  GDP alpha-2
Tuvalu         11300   38      TV
Anguilla       11300  311      AI
Nauru         337000  182      NR
nunique(axis=0, dropna=True)#

Count number of distinct elements in specified axis.

Return Series with number of distinct elements. Can ignore NaN values.

Parameters:
  • axis ({0 or 'index', 1 or 'columns'}, default 0) – The axis to use. 0 or ‘index’ for row-wise, 1 or ‘columns’ for column-wise.

  • dropna (bool, default True) – Don’t include NaN in the counts.

Returns:

Series with counts of unique values per row or column, depending on axis.

Return type:

Series

See also

Series.nunique

Method nunique for Series.

DataFrame.count

Count non-NA cells for each column or row.

Examples

>>> df = pd.DataFrame({"A": [4, 5, 6], "B": [4, 1, 1]})
>>> df.nunique()
A    3
B    2
dtype: int64
>>> df.nunique(axis=1)
0    1
1    2
2    2
dtype: int64
pivot(*, columns, index=<no_default>, values=<no_default>)#

Return reshaped DataFrame organized by given index / column values.

Reshape data (produce a “pivot” table) based on column values. Uses unique values from specified index / columns to form axes of the resulting DataFrame. This function does not support data aggregation, multiple values will result in a MultiIndex in the columns. See the User Guide for more on reshaping.

Parameters:
  • columns (Hashable or a sequence of the previous) – Column to use to make new frame’s columns.

  • index (Hashable or a sequence of the previous, optional) – Column to use to make new frame’s index. If not given, uses existing index.

  • values (Hashable or a sequence 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.

Returns:

Returns reshaped DataFrame.

Return type:

DataFrame

Raises:

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

See also

DataFrame.pivot_table

Generalization of pivot that can handle duplicate values for one index/column pair.

DataFrame.unstack

Pivot based on the index values instead of a column.

wide_to_long

Wide panel to long format. Less flexible but more user-friendly than melt.

Notes

For finer-tuned control, see hierarchical indexing documentation along with the related stack/unstack methods.

Reference the user guide for more examples.

Examples

>>> 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

You could also assign a list of column names or a list of index names.

>>> df = pd.DataFrame({
...                   "lev1": [1, 1, 1, 2, 2, 2],
...                   "lev2": [1, 1, 2, 1, 1, 2],
...                   "lev3": [1, 2, 1, 2, 1, 2],
...                   "lev4": [1, 2, 3, 4, 5, 6],
...                   "values": [0, 1, 2, 3, 4, 5]})
>>> df
    lev1 lev2 lev3 lev4 values
0   1    1    1    1    0
1   1    1    2    2    1
2   1    2    1    3    2
3   2    1    2    4    3
4   2    1    1    5    4
5   2    2    2    6    5
>>> df.pivot(index="lev1", columns=["lev2", "lev3"], values="values")
lev2    1         2
lev3    1    2    1    2
lev1
1     0.0  1.0  2.0  NaN
2     4.0  3.0  NaN  5.0
>>> df.pivot(index=["lev1", "lev2"], columns=["lev3"], values="values")
      lev3    1    2
lev1  lev2
   1     1  0.0  1.0
         2  2.0  NaN
   2     1  4.0  3.0
         2  NaN  5.0

A ValueError is raised if there are any duplicates.

>>> 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

Notice that the first two rows are the same for our index and columns arguments.

>>> df.pivot(index='foo', columns='bar', values='baz')
Traceback (most recent call last):
   ...
ValueError: Index contains duplicate entries, cannot reshape
pivot_table(values=None, index=None, columns=None, aggfunc='mean', fill_value=None, margins=False, dropna=True, margins_name='All', observed=True, sort=True, **kwargs)#

Create a spreadsheet-style pivot table as a DataFrame.

The levels in the pivot table will be stored in MultiIndex objects (hierarchical indexes) on the index and columns of the result DataFrame.

Parameters:
  • values (list-like or scalar, optional) – Column or columns to aggregate.

  • index (column, Grouper, array, or sequence of the previous) – Keys to group by on the pivot table index. If a list is passed, it can contain any of the other types (except list). If an array is passed, it must be the same length as the data and will be used in the same manner as column values.

  • columns (column, Grouper, array, or sequence of the previous) – Keys to group by on the pivot table column. If a list is passed, it can contain any of the other types (except list). If an array is passed, it must be the same length as the data and will be used in the same manner as column values.

  • aggfunc (function, list of functions, dict, default "mean") – If a list of functions is passed, the resulting pivot table will have hierarchical columns whose top level are the function names (inferred from the function objects themselves). If a dict is passed, the key is column to aggregate and the value is function or list of functions. If margin=True, aggfunc will be used to calculate the partial aggregates.

  • fill_value (scalar, default None) – Value to replace missing values with (in the resulting pivot table, after aggregation).

  • margins (bool, default False) – If margins=True, special All columns and rows will be added with partial group aggregates across the categories on the rows and columns.

  • dropna (bool, default True) –

    Do not include columns whose entries are all NaN. If True,

    • rows with an NA value in any column will be omitted before computing margins,

    • index/column keys containing NA values will be dropped (see dropna parameter in DataFrame.groupby()).

  • margins_name (str, default 'All') – Name of the row / column that will contain the totals when margins is True.

  • observed (bool, default False) –

    This only applies if any of the groupers are Categoricals. If True: only show observed values for categorical groupers. If False: show all values for categorical groupers.

    Changed in version 3.0.0: The default value is now True.

  • sort (bool, default True) – Specifies if the result should be sorted.

  • **kwargs (dict) – Optional keyword arguments to pass to aggfunc.

Returns:

An Excel style pivot table.

Return type:

DataFrame

See also

DataFrame.pivot

Pivot without aggregation that can handle non-numeric data.

DataFrame.melt

Unpivot a DataFrame from wide to long format, optionally leaving identifiers set.

wide_to_long

Wide panel to long format. Less flexible but more user-friendly than melt.

Notes

Reference the user guide for more examples.

Examples

>>> df = pd.DataFrame({"A": ["foo", "foo", "foo", "foo", "foo",
...                          "bar", "bar", "bar", "bar"],
...                    "B": ["one", "one", "one", "two", "two",
...                          "one", "one", "two", "two"],
...                    "C": ["small", "large", "large", "small",
...                          "small", "large", "small", "small",
...                          "large"],
...                    "D": [1, 2, 2, 3, 3, 4, 5, 6, 7],
...                    "E": [2, 4, 5, 5, 6, 6, 8, 9, 9]})
>>> df
     A    B      C  D  E
0  foo  one  small  1  2
1  foo  one  large  2  4
2  foo  one  large  2  5
3  foo  two  small  3  5
4  foo  two  small  3  6
5  bar  one  large  4  6
6  bar  one  small  5  8
7  bar  two  small  6  9
8  bar  two  large  7  9

This first example aggregates values by taking the sum.

>>> table = pd.pivot_table(df, values='D', index=['A', 'B'],
...                        columns=['C'], aggfunc="sum")
>>> table
C        large  small
A   B
bar one    4.0    5.0
    two    7.0    6.0
foo one    4.0    1.0
    two    NaN    6.0

We can also fill missing values using the fill_value parameter.

>>> table = pd.pivot_table(df, values='D', index=['A', 'B'],
...                        columns=['C'], aggfunc="sum", fill_value=0)
>>> table
C        large  small
A   B
bar one      4      5
    two      7      6
foo one      4      1
    two      0      6

The next example aggregates by taking the mean across multiple columns.

>>> table = pd.pivot_table(df, values=['D', 'E'], index=['A', 'C'],
...                        aggfunc={'D': "mean", 'E': "mean"})
>>> table
                D         E
A   C
bar large  5.500000  7.500000
    small  5.500000  8.500000
foo large  2.000000  4.500000
    small  2.333333  4.333333

We can also calculate multiple types of aggregations for any given value column.

>>> table = pd.pivot_table(df, values=['D', 'E'], index=['A', 'C'],
...                        aggfunc={'D': "mean",
...                                 'E': ["min", "max", "mean"]})
>>> table
                  D   E
               mean max      mean  min
A   C
bar large  5.500000   9  7.500000    6
    small  5.500000   9  8.500000    8
foo large  2.000000   5  4.500000    4
    small  2.333333   6  4.333333    2
plot#

alias of PlotAccessor

pop(item)#

Return item and drop it from DataFrame. Raise KeyError if not found.

Parameters:

item (label) – Label of column to be popped.

Returns:

Series representing the item that is dropped.

Return type:

Series

See also

DataFrame.drop

Drop specified labels from rows or columns.

DataFrame.drop_duplicates

Return DataFrame with duplicate rows removed.

Examples

>>> df = pd.DataFrame(
...     [
...         ("falcon", "bird", 389.0),
...         ("parrot", "bird", 24.0),
...         ("lion", "mammal", 80.5),
...         ("monkey", "mammal", np.nan),
...     ],
...     columns=("name", "class", "max_speed"),
... )
>>> df
     name   class  max_speed
0  falcon    bird      389.0
1  parrot    bird       24.0
2    lion  mammal       80.5
3  monkey  mammal        NaN
>>> df.pop("class")
0      bird
1      bird
2    mammal
3    mammal
Name: class, dtype: str
>>> df
     name  max_speed
0  falcon      389.0
1  parrot       24.0
2    lion       80.5
3  monkey        NaN
pow(other, axis='columns', level=None, fill_value=None)#

Get Exponential power of dataframe and other, element-wise (binary operator pow).

Equivalent to dataframe ** other, but with support to substitute a fill_value for missing data in one of the inputs. With reverse version, rpow.

Among flexible wrappers (add, sub, mul, div, floordiv, mod, pow) to arithmetic operators: +, -, *, /, //, %, **.

Parameters:
  • other (scalar, sequence, Series, dict or DataFrame) – Any single or multiple element data structure, or list-like object.

  • axis ({0 or 'index', 1 or 'columns'}) – Whether to compare by the index (0 or ‘index’) or columns. (1 or ‘columns’). For Series input, axis to match Series index on.

  • level (int or label) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (float or None, default None) – Fill existing missing (NaN) values, and any new element needed for successful DataFrame alignment, with this value before computation. If data in both corresponding DataFrame locations is missing the result will be missing.

Returns:

Result of the arithmetic operation.

Return type:

DataFrame

See also

DataFrame.add

Add DataFrames.

DataFrame.sub

Subtract DataFrames.

DataFrame.mul

Multiply DataFrames.

DataFrame.div

Divide DataFrames (float division).

DataFrame.truediv

Divide DataFrames (float division).

DataFrame.floordiv

Divide DataFrames (integer division).

DataFrame.mod

Calculate modulo (remainder after division).

DataFrame.pow

Calculate exponential power.

Notes

Mismatched indices will be unioned together.

Examples

>>> df = pd.DataFrame({'angles': [0, 3, 4],
...                    'degrees': [360, 180, 360]},
...                   index=['circle', 'triangle', 'rectangle'])
>>> df
           angles  degrees
circle          0      360
triangle        3      180
rectangle       4      360

Add a scalar with operator version which return the same results.

>>> df + 1
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361
>>> df.add(1)
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361

Divide by constant with reverse version.

>>> df.div(10)
           angles  degrees
circle        0.0     36.0
triangle      0.3     18.0
rectangle     0.4     36.0
>>> df.rdiv(10)
             angles   degrees
circle          inf  0.027778
triangle   3.333333  0.055556
rectangle  2.500000  0.027778

Subtract a list and Series by axis with operator version.

>>> df - [1, 2]
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub([1, 2], axis='columns')
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub(pd.Series([1, 1, 1], index=['circle', 'triangle', 'rectangle']),
...        axis='index')
           angles  degrees
circle         -1      359
triangle        2      179
rectangle       3      359

Multiply a dictionary by axis.

>>> df.mul({'angles': 0, 'degrees': 2})
            angles  degrees
circle           0      720
triangle         0      360
rectangle        0      720
>>> df.mul({'circle': 0, 'triangle': 2, 'rectangle': 3}, axis='index')
            angles  degrees
circle           0        0
triangle         6      360
rectangle       12     1080

Multiply a DataFrame of different shape with operator version.

>>> other = pd.DataFrame({'angles': [0, 3, 4]},
...                      index=['circle', 'triangle', 'rectangle'])
>>> other
           angles
circle          0
triangle        3
rectangle       4
>>> df * other
           angles  degrees
circle          0      NaN
triangle        9      NaN
rectangle      16      NaN
>>> df.mul(other, fill_value=0)
           angles  degrees
circle          0      0.0
triangle        9      0.0
rectangle      16      0.0

Divide by a MultiIndex by level.

>>> df_multindex = pd.DataFrame({'angles': [0, 3, 4, 4, 5, 6],
...                              'degrees': [360, 180, 360, 360, 540, 720]},
...                             index=[['A', 'A', 'A', 'B', 'B', 'B'],
...                                    ['circle', 'triangle', 'rectangle',
...                                     'square', 'pentagon', 'hexagon']])
>>> df_multindex
             angles  degrees
A circle          0      360
  triangle        3      180
  rectangle       4      360
B square          4      360
  pentagon        5      540
  hexagon         6      720
>>> df.div(df_multindex, level=1, fill_value=0)
             angles  degrees
A circle        NaN      1.0
  triangle      1.0      1.0
  rectangle     1.0      1.0
B square        0.0      0.0
  pentagon      0.0      0.0
  hexagon       0.0      0.0
>>> df_pow = pd.DataFrame({'A': [2, 3, 4, 5],
...                        'B': [6, 7, 8, 9]})
>>> df_pow.pow(2)
    A   B
0   4  36
1   9  49
2  16  64
3  25  81
prod(*, axis=0, skipna=True, numeric_only=False, min_count=0, **kwargs)#

Return the product of the values over the requested axis.

Parameters:
  • axis ({index (0), columns (1)}) –

    Axis for the function to be applied on. For Series this parameter is unused and defaults to 0.

    Warning

    The behavior of DataFrame.prod with axis=None is deprecated, in a future version this will reduce over both axes and return a scalar To retain the old behavior, pass axis=0 (or do not pass axis).

    Added in version 2.0.0.

  • skipna (bool, default True) – Exclude NA/null values when computing the result.

  • numeric_only (bool, default False) – Include only float, int, boolean columns. Not implemented for Series.

  • min_count (int, default 0) – The required number of valid values to perform the operation. If fewer than min_count non-NA values are present the result will be NA.

  • **kwargs – Additional keyword arguments to be passed to the function.

Returns:

The product of the values over the requested axis.

Return type:

Series or scalar

See also

Series.sum

Return the sum.

Series.min

Return the minimum.

Series.max

Return the maximum.

Series.idxmin

Return the index of the minimum.

Series.idxmax

Return the index of the maximum.

DataFrame.sum

Return the sum over the requested axis.

DataFrame.min

Return the minimum over the requested axis.

DataFrame.max

Return the maximum over the requested axis.

DataFrame.idxmin

Return the index of the minimum over the requested axis.

DataFrame.idxmax

Return the index of the maximum over the requested axis.

Examples

By default, the product of an empty or all-NA Series is 1

>>> pd.Series([], dtype="float64").prod()
1.0

This can be controlled with the min_count parameter

>>> pd.Series([], dtype="float64").prod(min_count=1)
nan

Thanks to the skipna parameter, min_count handles all-NA and empty series identically.

>>> pd.Series([np.nan]).prod()
1.0
>>> pd.Series([np.nan]).prod(min_count=1)
nan
product(*, axis=0, skipna=True, numeric_only=False, min_count=0, **kwargs)#

Return the product of the values over the requested axis.

Parameters:
  • axis ({index (0), columns (1)}) –

    Axis for the function to be applied on. For Series this parameter is unused and defaults to 0.

    Warning

    The behavior of DataFrame.prod with axis=None is deprecated, in a future version this will reduce over both axes and return a scalar To retain the old behavior, pass axis=0 (or do not pass axis).

    Added in version 2.0.0.

  • skipna (bool, default True) – Exclude NA/null values when computing the result.

  • numeric_only (bool, default False) – Include only float, int, boolean columns. Not implemented for Series.

  • min_count (int, default 0) – The required number of valid values to perform the operation. If fewer than min_count non-NA values are present the result will be NA.

  • **kwargs – Additional keyword arguments to be passed to the function.

Returns:

The product of the values over the requested axis.

Return type:

Series or scalar

See also

Series.sum

Return the sum.

Series.min

Return the minimum.

Series.max

Return the maximum.

Series.idxmin

Return the index of the minimum.

Series.idxmax

Return the index of the maximum.

DataFrame.sum

Return the sum over the requested axis.

DataFrame.min

Return the minimum over the requested axis.

DataFrame.max

Return the maximum over the requested axis.

DataFrame.idxmin

Return the index of the minimum over the requested axis.

DataFrame.idxmax

Return the index of the maximum over the requested axis.

Examples

By default, the product of an empty or all-NA Series is 1

>>> pd.Series([], dtype="float64").prod()
1.0

This can be controlled with the min_count parameter

>>> pd.Series([], dtype="float64").prod(min_count=1)
nan

Thanks to the skipna parameter, min_count handles all-NA and empty series identically.

>>> pd.Series([np.nan]).prod()
1.0
>>> pd.Series([np.nan]).prod(min_count=1)
nan
quantile(q: float = 0.5, axis: Axis = 0, numeric_only: bool = False, interpolation: QuantileInterpolation = 'linear', method: Literal['single', 'table'] = 'single') Series#
quantile(q: AnyArrayLike | Sequence[float], axis: Axis = 0, numeric_only: bool = False, interpolation: QuantileInterpolation = 'linear', method: Literal['single', 'table'] = 'single') Series | DataFrame
quantile(q: float | AnyArrayLike | Sequence[float] = 0.5, axis: Axis = 0, numeric_only: bool = False, interpolation: QuantileInterpolation = 'linear', method: Literal['single', 'table'] = 'single') Series | DataFrame

Return values at the given quantile over requested axis.

Parameters:
  • q (float or array-like, default 0.5 (50% quantile)) – Value between 0 <= q <= 1, the quantile(s) to compute.

  • axis ({0 or 'index', 1 or 'columns'}, default 0) – Equals 0 or ‘index’ for row-wise, 1 or ‘columns’ for column-wise.

  • numeric_only (bool, default False) –

    Include only float, int or boolean data.

    Changed in version 2.0.0: The default value of numeric_only is now False.

  • interpolation ({'linear', 'lower', 'higher', 'midpoint', 'nearest'}) –

    This optional parameter specifies the interpolation method to use, when the desired quantile lies between two data points i and j:

    • linear: i + (j - i) * fraction, where fraction is the fractional part of the index surrounded by i and j.

    • lower: i.

    • higher: j.

    • nearest: i or j whichever is nearest.

    • midpoint: (i + j) / 2.

  • method ({'single', 'table'}, default 'single') – Whether to compute quantiles per-column (‘single’) or over all columns (‘table’). When ‘table’, the only allowed interpolation methods are ‘nearest’, ‘lower’, and ‘higher’.

Returns:

If q is an array, a DataFrame will be returned where the

index is q, the columns are the columns of self, and the values are the quantiles.

If q is a float, a Series will be returned where the

index is the columns of self and the values are the quantiles.

Return type:

Series or DataFrame

See also

core.window.rolling.Rolling.quantile

Rolling quantile.

numpy.percentile

Numpy function to compute the percentile.

Examples

>>> df = pd.DataFrame(
...     np.array([[1, 1], [2, 10], [3, 100], [4, 100]]), columns=["a", "b"]
... )
>>> df.quantile(0.1)
a    1.3
b    3.7
Name: 0.1, dtype: float64
>>> df.quantile([0.1, 0.5])
       a     b
0.1  1.3   3.7
0.5  2.5  55.0

Specifying method=’table’ will compute the quantile over all columns.

>>> df.quantile(0.1, method="table", interpolation="nearest")
a    1
b    1
Name: 0.1, dtype: int64
>>> df.quantile([0.1, 0.5], method="table", interpolation="nearest")
     a    b
0.1  1    1
0.5  3  100

Specifying numeric_only=False will compute the quantiles for all columns.

>>> df = pd.DataFrame(
...     {
...         "A": [1, 2],
...         "B": [pd.Timestamp("2010"), pd.Timestamp("2011")],
...         "C": [pd.Timedelta("1 days"), pd.Timedelta("2 days")],
...     }
... )
>>> df.quantile(0.5, numeric_only=False)
A                    1.5
B    2010-07-02 12:00:00
C        1 days 12:00:00
Name: 0.5, dtype: object
query(expr: str, *, parser: Literal['pandas', 'python'] = 'pandas', engine: Literal['python', 'numexpr'] | None = None, local_dict: dict[str, Any] | None = None, global_dict: dict[str, Any] | None = None, resolvers: list[Mapping] | None = None, level: int = 0, inplace: Literal[False] = False) DataFrame#
query(expr: str, *, parser: Literal['pandas', 'python'] = 'pandas', engine: Literal['python', 'numexpr'] | None = None, local_dict: dict[str, Any] | None = None, global_dict: dict[str, Any] | None = None, resolvers: list[Mapping] | None = None, level: int = 0, inplace: Literal[True]) None
query(expr: str, *, parser: Literal['pandas', 'python'] = 'pandas', engine: Literal['python', 'numexpr'] | None = None, local_dict: dict[str, Any] | None = None, global_dict: dict[str, Any] | None = None, resolvers: list[Mapping] | None = None, level: int = 0, inplace: bool = False) DataFrame | None

Query the columns of a DataFrame with a boolean expression.

Warning

This method can run arbitrary code which can make you vulnerable to code injection if you pass user input to this function.

Parameters:
  • expr (str) –

    The query string to evaluate.

    See the documentation for eval() for details of supported operations and functions in the query string.

    See the documentation for DataFrame.eval() for details on referring to column names and variables in the query string.

  • parser ({'pandas', 'python'}, default 'pandas') – The parser to use to construct the syntax tree from the expression. The default of 'pandas' parses code slightly different than standard Python. Alternatively, you can parse an expression using the 'python' parser to retain strict Python semantics. See the enhancing performance documentation for more details.

  • engine ({'python', 'numexpr'}, default 'numexpr') –

    The engine used to evaluate the expression. Supported engines are

    • None : tries to use numexpr, falls back to python

    • 'numexpr' : This default engine evaluates pandas objects using numexpr for large speed ups in complex expressions with large frames.

    • 'python' : Performs operations as if you had eval’d in top level python. This engine is generally not that useful.

    More backends may be available in the future.

  • local_dict (dict or None, optional) – A dictionary of local variables, taken from locals() by default.

  • global_dict (dict or None, optional) – A dictionary of global variables, taken from globals() by default.

  • resolvers (list of dict-like or None, optional) – A list of objects implementing the __getitem__ special method that you can use to inject an additional collection of namespaces to use for variable lookup. For example, this is used in the query() method to inject the DataFrame.index and DataFrame.columns variables that refer to their respective DataFrame instance attributes.

  • level (int, optional) – The number of prior stack frames to traverse and add to the current scope. Most users will not need to change this parameter.

  • inplace (bool) – Whether to modify the DataFrame rather than creating a new one.

Returns:

DataFrame resulting from the provided query expression or None if inplace=True.

Return type:

DataFrame or None

See also

eval

Evaluate a string describing operations on DataFrame columns.

DataFrame.eval

Evaluate a string describing operations on DataFrame columns.

Notes

The result of the evaluation of this expression is first passed to DataFrame.loc and if that fails because of a multidimensional key (e.g., a DataFrame) then the result will be passed to DataFrame.__getitem__().

This method uses the top-level eval() function to evaluate the passed query.

The query() method uses a slightly modified Python syntax by default. For example, the & and | (bitwise) operators have the precedence of their boolean cousins, and and or. This is syntactically valid Python, however the semantics are different.

You can change the semantics of the expression by passing the keyword argument parser='python'. This enforces the same semantics as evaluation in Python space. Likewise, you can pass engine='python' to evaluate an expression using Python itself as a backend. This is not recommended as it is inefficient compared to using numexpr as the engine.

The DataFrame.index and DataFrame.columns attributes of the DataFrame instance are placed in the query namespace by default, which allows you to treat both the index and columns of the frame as a column in the frame. The identifier index is used for the frame index; you can also use the name of the index to identify it in a query. Please note that Python keywords may not be used as identifiers.

For further details and examples see the query documentation in indexing.

Backtick quoted variables

Backtick quoted variables are parsed as literal Python code and are converted internally to a Python valid identifier. This can lead to the following problems.

During parsing a number of disallowed characters inside the backtick quoted string are replaced by strings that are allowed as a Python identifier. These characters include all operators in Python, the space character, the question mark, the exclamation mark, the dollar sign, and the euro sign.

A backtick can be escaped by double backticks.

See also the Python documentation about lexical analysis in combination with the source code in pandas.core.computation.parsing.

Examples

>>> df = pd.DataFrame(
...     {"A": range(1, 6), "B": range(10, 0, -2), "C&C": range(10, 5, -1)}
... )
>>> df
   A   B  C&C
0  1  10   10
1  2   8    9
2  3   6    8
3  4   4    7
4  5   2    6
>>> df.query("A > B")
   A  B  C&C
4  5  2    6

The previous expression is equivalent to

>>> df[df.A > df.B]
   A  B  C&C
4  5  2    6

For columns with spaces in their name, you can use backtick quoting.

>>> df.query("B == `C&C`")
   A   B  C&C
0  1  10   10

The previous expression is equivalent to

>>> df[df.B == df["C&C"]]
   A   B  C&C
0  1  10   10

Using local variable:

>>> local_var = 2
>>> df.query("A <= @local_var")
A   B  C&C
0  1  10   10
1  2   8    9
radd(other, axis='columns', level=None, fill_value=None)#

Get Addition of dataframe and other, element-wise (binary operator radd).

Equivalent to other + dataframe, but with support to substitute a fill_value for missing data in one of the inputs. With reverse version, add.

Among flexible wrappers (add, sub, mul, div, floordiv, mod, pow) to arithmetic operators: +, -, *, /, //, %, **.

Parameters:
  • other (scalar, sequence, Series, dict or DataFrame) – Any single or multiple element data structure, or list-like object.

  • axis ({0 or 'index', 1 or 'columns'}) – Whether to compare by the index (0 or ‘index’) or columns. (1 or ‘columns’). For Series input, axis to match Series index on.

  • level (int or label) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (float or None, default None) – Fill existing missing (NaN) values, and any new element needed for successful DataFrame alignment, with this value before computation. If data in both corresponding DataFrame locations is missing the result will be missing.

Returns:

Result of the arithmetic operation.

Return type:

DataFrame

See also

DataFrame.add

Add DataFrames.

DataFrame.sub

Subtract DataFrames.

DataFrame.mul

Multiply DataFrames.

DataFrame.div

Divide DataFrames (float division).

DataFrame.truediv

Divide DataFrames (float division).

DataFrame.floordiv

Divide DataFrames (integer division).

DataFrame.mod

Calculate modulo (remainder after division).

DataFrame.pow

Calculate exponential power.

Notes

Mismatched indices will be unioned together.

Examples

>>> df = pd.DataFrame({'angles': [0, 3, 4],
...                    'degrees': [360, 180, 360]},
...                   index=['circle', 'triangle', 'rectangle'])
>>> df
           angles  degrees
circle          0      360
triangle        3      180
rectangle       4      360

Add a scalar with operator version which return the same results.

>>> df + 1
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361
>>> df.add(1)
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361

Divide by constant with reverse version.

>>> df.div(10)
           angles  degrees
circle        0.0     36.0
triangle      0.3     18.0
rectangle     0.4     36.0
>>> df.rdiv(10)
             angles   degrees
circle          inf  0.027778
triangle   3.333333  0.055556
rectangle  2.500000  0.027778

Subtract a list and Series by axis with operator version.

>>> df - [1, 2]
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub([1, 2], axis='columns')
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub(pd.Series([1, 1, 1], index=['circle', 'triangle', 'rectangle']),
...        axis='index')
           angles  degrees
circle         -1      359
triangle        2      179
rectangle       3      359

Multiply a dictionary by axis.

>>> df.mul({'angles': 0, 'degrees': 2})
            angles  degrees
circle           0      720
triangle         0      360
rectangle        0      720
>>> df.mul({'circle': 0, 'triangle': 2, 'rectangle': 3}, axis='index')
            angles  degrees
circle           0        0
triangle         6      360
rectangle       12     1080

Multiply a DataFrame of different shape with operator version.

>>> other = pd.DataFrame({'angles': [0, 3, 4]},
...                      index=['circle', 'triangle', 'rectangle'])
>>> other
           angles
circle          0
triangle        3
rectangle       4
>>> df * other
           angles  degrees
circle          0      NaN
triangle        9      NaN
rectangle      16      NaN
>>> df.mul(other, fill_value=0)
           angles  degrees
circle          0      0.0
triangle        9      0.0
rectangle      16      0.0

Divide by a MultiIndex by level.

>>> df_multindex = pd.DataFrame({'angles': [0, 3, 4, 4, 5, 6],
...                              'degrees': [360, 180, 360, 360, 540, 720]},
...                             index=[['A', 'A', 'A', 'B', 'B', 'B'],
...                                    ['circle', 'triangle', 'rectangle',
...                                     'square', 'pentagon', 'hexagon']])
>>> df_multindex
             angles  degrees
A circle          0      360
  triangle        3      180
  rectangle       4      360
B square          4      360
  pentagon        5      540
  hexagon         6      720
>>> df.div(df_multindex, level=1, fill_value=0)
             angles  degrees
A circle        NaN      1.0
  triangle      1.0      1.0
  rectangle     1.0      1.0
B square        0.0      0.0
  pentagon      0.0      0.0
  hexagon       0.0      0.0
>>> df_pow = pd.DataFrame({'A': [2, 3, 4, 5],
...                        'B': [6, 7, 8, 9]})
>>> df_pow.pow(2)
    A   B
0   4  36
1   9  49
2  16  64
3  25  81
rdiv(other, axis='columns', level=None, fill_value=None)#

Get Floating division of dataframe and other, element-wise (binary operator rtruediv).

Equivalent to other / dataframe, but with support to substitute a fill_value for missing data in one of the inputs. With reverse version, truediv.

Among flexible wrappers (add, sub, mul, div, floordiv, mod, pow) to arithmetic operators: +, -, *, /, //, %, **.

Parameters:
  • other (scalar, sequence, Series, dict or DataFrame) – Any single or multiple element data structure, or list-like object.

  • axis ({0 or 'index', 1 or 'columns'}) – Whether to compare by the index (0 or ‘index’) or columns. (1 or ‘columns’). For Series input, axis to match Series index on.

  • level (int or label) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (float or None, default None) – Fill existing missing (NaN) values, and any new element needed for successful DataFrame alignment, with this value before computation. If data in both corresponding DataFrame locations is missing the result will be missing.

Returns:

Result of the arithmetic operation.

Return type:

DataFrame

See also

DataFrame.add

Add DataFrames.

DataFrame.sub

Subtract DataFrames.

DataFrame.mul

Multiply DataFrames.

DataFrame.div

Divide DataFrames (float division).

DataFrame.truediv

Divide DataFrames (float division).

DataFrame.floordiv

Divide DataFrames (integer division).

DataFrame.mod

Calculate modulo (remainder after division).

DataFrame.pow

Calculate exponential power.

Notes

Mismatched indices will be unioned together.

Examples

>>> df = pd.DataFrame({'angles': [0, 3, 4],
...                    'degrees': [360, 180, 360]},
...                   index=['circle', 'triangle', 'rectangle'])
>>> df
           angles  degrees
circle          0      360
triangle        3      180
rectangle       4      360

Add a scalar with operator version which return the same results.

>>> df + 1
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361
>>> df.add(1)
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361

Divide by constant with reverse version.

>>> df.div(10)
           angles  degrees
circle        0.0     36.0
triangle      0.3     18.0
rectangle     0.4     36.0
>>> df.rdiv(10)
             angles   degrees
circle          inf  0.027778
triangle   3.333333  0.055556
rectangle  2.500000  0.027778

Subtract a list and Series by axis with operator version.

>>> df - [1, 2]
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub([1, 2], axis='columns')
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub(pd.Series([1, 1, 1], index=['circle', 'triangle', 'rectangle']),
...        axis='index')
           angles  degrees
circle         -1      359
triangle        2      179
rectangle       3      359

Multiply a dictionary by axis.

>>> df.mul({'angles': 0, 'degrees': 2})
            angles  degrees
circle           0      720
triangle         0      360
rectangle        0      720
>>> df.mul({'circle': 0, 'triangle': 2, 'rectangle': 3}, axis='index')
            angles  degrees
circle           0        0
triangle         6      360
rectangle       12     1080

Multiply a DataFrame of different shape with operator version.

>>> other = pd.DataFrame({'angles': [0, 3, 4]},
...                      index=['circle', 'triangle', 'rectangle'])
>>> other
           angles
circle          0
triangle        3
rectangle       4
>>> df * other
           angles  degrees
circle          0      NaN
triangle        9      NaN
rectangle      16      NaN
>>> df.mul(other, fill_value=0)
           angles  degrees
circle          0      0.0
triangle        9      0.0
rectangle      16      0.0

Divide by a MultiIndex by level.

>>> df_multindex = pd.DataFrame({'angles': [0, 3, 4, 4, 5, 6],
...                              'degrees': [360, 180, 360, 360, 540, 720]},
...                             index=[['A', 'A', 'A', 'B', 'B', 'B'],
...                                    ['circle', 'triangle', 'rectangle',
...                                     'square', 'pentagon', 'hexagon']])
>>> df_multindex
             angles  degrees
A circle          0      360
  triangle        3      180
  rectangle       4      360
B square          4      360
  pentagon        5      540
  hexagon         6      720
>>> df.div(df_multindex, level=1, fill_value=0)
             angles  degrees
A circle        NaN      1.0
  triangle      1.0      1.0
  rectangle     1.0      1.0
B square        0.0      0.0
  pentagon      0.0      0.0
  hexagon       0.0      0.0
>>> df_pow = pd.DataFrame({'A': [2, 3, 4, 5],
...                        'B': [6, 7, 8, 9]})
>>> df_pow.pow(2)
    A   B
0   4  36
1   9  49
2  16  64
3  25  81
reindex(labels=None, *, index=None, columns=None, axis=None, method=None, copy=<no_default>, level=None, fill_value=nan, limit=None, tolerance=None)#

Conform DataFrame to new index with optional filling logic.

Places NA/NaN in locations having no value in the previous index. A new object is produced unless the new index is equivalent to the current one and copy=False.

Parameters:
  • labels (array-like, optional) – New labels / index to conform the axis specified by ‘axis’ to.

  • index (array-like, optional) – New labels for the index. Preferably an Index object to avoid duplicating data.

  • columns (array-like, optional) – New labels for the columns. Preferably an Index object to avoid duplicating data.

  • axis (int or str, optional) – Axis to target. Can be either the axis name (‘index’, ‘columns’) or number (0, 1).

  • method ({None, 'backfill'/'bfill', 'pad'/'ffill', 'nearest'}) –

    Method to use for filling holes in reindexed DataFrame. Please note: this is only applicable to DataFrames/Series with a monotonically increasing/decreasing index.

    • None (default): don’t fill gaps

    • pad / ffill: Propagate last valid observation forward to next valid.

    • backfill / bfill: Use next valid observation to fill gap.

    • nearest: Use nearest valid observations to fill gap.

  • copy (bool, default False) –

    This keyword is now ignored; changing its value will have no impact on the method.

    Deprecated since version 3.0.0: This keyword is ignored and will be removed in pandas 4.0. Since pandas 3.0, this method always returns a new object using a lazy copy mechanism that defers copies until necessary (Copy-on-Write). See the user guide on Copy-on-Write for more details.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (scalar, default np.nan) – Value to use for missing values. Defaults to NaN, but can be any “compatible” value.

  • limit (int, default None) – Maximum number of consecutive elements to forward or backward fill.

  • tolerance (optional) –

    Maximum distance between original and new labels for inexact matches. The values of the index at the matching locations most satisfy the equation abs(index[indexer] - target) <= tolerance.

    Tolerance may be a scalar value, which applies the same tolerance to all values, or list-like, which applies variable tolerance per element. List-like includes list, tuple, array, Series, and must be the same size as the index and its dtype must exactly match the index’s type.

Returns:

DataFrame with changed index.

Return type:

DataFrame

See also

DataFrame.set_index

Set row labels.

DataFrame.reset_index

Remove row labels or move them to new columns.

DataFrame.reindex_like

Change to same indices as other DataFrame.

Examples

DataFrame.reindex supports two calling conventions

  • (index=index_labels, columns=column_labels, ...)

  • (labels, axis={'index', 'columns'}, ...)

We highly recommend using keyword arguments to clarify your intent.

Create a DataFrame with some fictional data.

>>> index = ["Firefox", "Chrome", "Safari", "IE10", "Konqueror"]
>>> columns = ["http_status", "response_time"]
>>> df = pd.DataFrame(
...     [[200, 0.04], [200, 0.02], [404, 0.07], [404, 0.08], [301, 1.0]],
...     columns=columns,
...     index=index,
... )
>>> df
           http_status  response_time
Firefox            200           0.04
Chrome             200           0.02
Safari             404           0.07
IE10               404           0.08
Konqueror          301           1.00

Create a new index and reindex the DataFrame. By default values in the new index that do not have corresponding records in the DataFrame are assigned NaN.

>>> new_index = ["Safari", "Iceweasel", "Comodo Dragon", "IE10", "Chrome"]
>>> df.reindex(new_index)
               http_status  response_time
Safari               404.0           0.07
Iceweasel              NaN            NaN
Comodo Dragon          NaN            NaN
IE10                 404.0           0.08
Chrome               200.0           0.02

We can fill in the missing values by passing a value to the keyword fill_value. Because the index is not monotonically increasing or decreasing, we cannot use arguments to the keyword method to fill the NaN values.

>>> df.reindex(new_index, fill_value=0)
               http_status  response_time
Safari                 404           0.07
Iceweasel                0           0.00
Comodo Dragon            0           0.00
IE10                   404           0.08
Chrome                 200           0.02
>>> df.reindex(new_index, fill_value="missing")
              http_status response_time
Safari                404          0.07
Iceweasel         missing       missing
Comodo Dragon     missing       missing
IE10                  404          0.08
Chrome                200          0.02

We can also reindex the columns.

>>> df.reindex(columns=["http_status", "user_agent"])
           http_status  user_agent
Firefox            200         NaN
Chrome             200         NaN
Safari             404         NaN
IE10               404         NaN
Konqueror          301         NaN

Or we can use “axis-style” keyword arguments

>>> df.reindex(["http_status", "user_agent"], axis="columns")
           http_status  user_agent
Firefox            200         NaN
Chrome             200         NaN
Safari             404         NaN
IE10               404         NaN
Konqueror          301         NaN

To further illustrate the filling functionality in reindex, we will create a DataFrame with a monotonically increasing index (for example, a sequence of dates).

>>> date_index = pd.date_range("1/1/2010", periods=6, freq="D")
>>> df2 = pd.DataFrame(
...     {"prices": [100, 101, np.nan, 100, 89, 88]}, index=date_index
... )
>>> df2
            prices
2010-01-01   100.0
2010-01-02   101.0
2010-01-03     NaN
2010-01-04   100.0
2010-01-05    89.0
2010-01-06    88.0

Suppose we decide to expand the DataFrame to cover a wider date range.

>>> date_index2 = pd.date_range("12/29/2009", periods=10, freq="D")
>>> df2.reindex(date_index2)
            prices
2009-12-29     NaN
2009-12-30     NaN
2009-12-31     NaN
2010-01-01   100.0
2010-01-02   101.0
2010-01-03     NaN
2010-01-04   100.0
2010-01-05    89.0
2010-01-06    88.0
2010-01-07     NaN

The index entries that did not have a value in the original data frame (for example, ‘2009-12-29’) are by default filled with NaN. If desired, we can fill in the missing values using one of several options.

For example, to back-propagate the last valid value to fill the NaN values, pass bfill as an argument to the method keyword.

>>> df2.reindex(date_index2, method="bfill")
            prices
2009-12-29   100.0
2009-12-30   100.0
2009-12-31   100.0
2010-01-01   100.0
2010-01-02   101.0
2010-01-03     NaN
2010-01-04   100.0
2010-01-05    89.0
2010-01-06    88.0
2010-01-07     NaN

Please note that the NaN value present in the original DataFrame (at index value 2010-01-03) will not be filled by any of the value propagation schemes. This is because filling while reindexing does not look at DataFrame values, but only compares the original and desired indexes. If you do want to fill in the NaN values present in the original DataFrame, use the fillna() method.

See the user guide for more.

rename(mapper: Renamer | None = None, *, index: Renamer | None = None, columns: Renamer | None = None, axis: Axis | None = None, copy: bool | Literal[_NoDefault.no_default] = lib.no_default, inplace: Literal[True], level: Level = None, errors: IgnoreRaise = 'ignore') None#
rename(mapper: Renamer | None = None, *, index: Renamer | None = None, columns: Renamer | None = None, axis: Axis | None = None, copy: bool | Literal[_NoDefault.no_default] = lib.no_default, inplace: Literal[False] = False, level: Level = None, errors: IgnoreRaise = 'ignore') DataFrame
rename(mapper: Renamer | None = None, *, index: Renamer | None = None, columns: Renamer | None = None, axis: Axis | None = None, copy: bool | Literal[_NoDefault.no_default] = lib.no_default, inplace: bool = False, level: Level = None, errors: IgnoreRaise = 'ignore') DataFrame | None

Rename columns or index labels.

Function / dict values must be unique (1-to-1). Labels not contained in a dict / Series will be left as-is. Extra labels listed don’t throw an error.

See the user guide for more.

Parameters:
  • mapper (dict-like or function) – Dict-like or function transformations to apply to that axis’ values. Use either mapper and axis to specify the axis to target with mapper, or index and columns.

  • index (dict-like or function) – Alternative to specifying axis (mapper, axis=0 is equivalent to index=mapper).

  • columns (dict-like or function) – Alternative to specifying axis (mapper, axis=1 is equivalent to columns=mapper).

  • axis ({0 or 'index', 1 or 'columns'}, default 0) – Axis to target with mapper. Can be either the axis name (‘index’, ‘columns’) or number (0, 1). The default is ‘index’.

  • copy (bool, default False) –

    This keyword is now ignored; changing its value will have no impact on the method.

    Deprecated since version 3.0.0: This keyword is ignored and will be removed in pandas 4.0. Since pandas 3.0, this method always returns a new object using a lazy copy mechanism that defers copies until necessary (Copy-on-Write). See the user guide on Copy-on-Write for more details.

  • inplace (bool, default False) – Whether to modify the DataFrame rather than creating a new one. If True then value of copy is ignored.

  • level (int or level name, default None) – In case of a MultiIndex, only rename labels in the specified level.

  • errors ({'ignore', 'raise'}, default 'ignore') – If ‘raise’, raise a KeyError when a dict-like mapper, index, or columns contains labels that are not present in the Index being transformed. If ‘ignore’, existing keys will be renamed and extra keys will be ignored.

Returns:

DataFrame with the renamed axis labels or None if inplace=True.

Return type:

DataFrame or None

Raises:

KeyError – If any of the labels is not found in the selected axis and “errors=’raise’”.

See also

DataFrame.rename_axis

Set the name of the axis.

Examples

DataFrame.rename supports two calling conventions

  • (index=index_mapper, columns=columns_mapper, ...)

  • (mapper, axis={'index', 'columns'}, ...)

We highly recommend using keyword arguments to clarify your intent.

Rename columns using a mapping:

>>> df = pd.DataFrame({"A": [1, 2, 3], "B": [4, 5, 6]})
>>> df.rename(columns={"A": "a", "B": "c"})
   a  c
0  1  4
1  2  5
2  3  6

Rename index using a mapping:

>>> df.rename(index={0: "x", 1: "y", 2: "z"})
   A  B
x  1  4
y  2  5
z  3  6

Cast index labels to a different type:

>>> df.index
RangeIndex(start=0, stop=3, step=1)
>>> df.rename(index=str).index
Index(['0', '1', '2'], dtype='str')
>>> df.rename(columns={"A": "a", "B": "b", "C": "c"}, errors="raise")
Traceback (most recent call last):
KeyError: ['C'] not found in axis

Using axis-style parameters:

>>> df.rename(str.lower, axis="columns")
   a  b
0  1  4
1  2  5
2  3  6
>>> df.rename({1: 2, 2: 4}, axis="index")
   A  B
0  1  4
2  2  5
4  3  6
reorder_levels(order, axis=0)#

Rearrange index or column levels using input order.

May not drop or duplicate levels.

Parameters:
  • order (list of int or list of str) – List representing new level order. Reference level by number (position) or by key (label).

  • axis ({0 or 'index', 1 or 'columns'}, default 0) – Where to reorder levels.

Returns:

DataFrame with indices or columns with reordered levels.

Return type:

DataFrame

See also

DataFrame.swaplevel

Swap levels i and j in a MultiIndex.

Examples

>>> data = {
...     "class": ["Mammals", "Mammals", "Reptiles"],
...     "diet": ["Omnivore", "Carnivore", "Carnivore"],
...     "species": ["Humans", "Dogs", "Snakes"],
... }
>>> df = pd.DataFrame(data, columns=["class", "diet", "species"])
>>> df = df.set_index(["class", "diet"])
>>> df
                                  species
class      diet
Mammals    Omnivore                Humans
           Carnivore                 Dogs
Reptiles   Carnivore               Snakes

Let’s reorder the levels of the index:

>>> df.reorder_levels(["diet", "class"])
                                  species
diet      class
Omnivore  Mammals                  Humans
Carnivore Mammals                    Dogs
          Reptiles                 Snakes
reset_index(level: IndexLabel = None, *, drop: bool = False, inplace: Literal[False] = False, col_level: Hashable = 0, col_fill: Hashable = '', allow_duplicates: bool | Literal[_NoDefault.no_default] = <no_default>, names: Hashable | Sequence[Hashable] | None = None) DataFrame#
reset_index(level: IndexLabel = None, *, drop: bool = False, inplace: ~typing.Literal[True], col_level: ~collections.abc.Hashable = 0, col_fill: ~collections.abc.Hashable = '', allow_duplicates: bool | ~pandas.api.typing.Literal[_NoDefault.no_default] = <no_default>, names: ~collections.abc.Hashable | ~collections.abc.Sequence[~collections.abc.Hashable] | None = None) None
reset_index(level: IndexLabel = None, *, drop: bool = False, inplace: bool = False, col_level: Hashable = 0, col_fill: Hashable = '', allow_duplicates: bool | Literal[_NoDefault.no_default] = <no_default>, names: Hashable | Sequence[Hashable] | None = None) DataFrame | None

Reset the index, or a level of it.

Reset the index of the DataFrame, and use the default one instead. If the DataFrame has a MultiIndex, this method can remove one or more levels.

Parameters:
  • level (int, str, tuple, or list, default None) – Only remove the given levels from the index. Removes all levels by default.

  • drop (bool, default False) – Do not try to insert index into dataframe columns. This resets the index to the default integer index.

  • inplace (bool, default False) – Whether to modify the DataFrame rather than creating a new one.

  • col_level (int or str, default 0) – If the columns have multiple levels, determines which level the labels are inserted into. By default it is inserted into the first level.

  • col_fill (object, default '') – If the columns have multiple levels, determines how the other levels are named. If None then the index name is repeated.

  • allow_duplicates (bool, optional, default lib.no_default) – Allow duplicate column labels to be created.

  • names (int, str or 1-dimensional list, default None) – Using the given string, rename the DataFrame column which contains the index data. If the DataFrame has a MultiIndex, this has to be a list with length equal to the number of levels.

Returns:

DataFrame with the new index or None if inplace=True.

Return type:

DataFrame or None

See also

DataFrame.set_index

Opposite of reset_index.

DataFrame.reindex

Change to new indices or expand indices.

DataFrame.reindex_like

Change to same indices as other DataFrame.

Examples

>>> df = pd.DataFrame(
...     [("bird", 389.0), ("bird", 24.0), ("mammal", 80.5), ("mammal", np.nan)],
...     index=["falcon", "parrot", "lion", "monkey"],
...     columns=("class", "max_speed"),
... )
>>> df
         class  max_speed
falcon    bird      389.0
parrot    bird       24.0
lion    mammal       80.5
monkey  mammal        NaN

When we reset the index, the old index is added as a column, and a new sequential index is used:

>>> df.reset_index()
    index   class  max_speed
0  falcon    bird      389.0
1  parrot    bird       24.0
2    lion  mammal       80.5
3  monkey  mammal        NaN

We can use the drop parameter to avoid the old index being added as a column:

>>> df.reset_index(drop=True)
    class  max_speed
0    bird      389.0
1    bird       24.0
2  mammal       80.5
3  mammal        NaN

You can also use reset_index with MultiIndex.

>>> index = pd.MultiIndex.from_tuples(
...     [
...         ("bird", "falcon"),
...         ("bird", "parrot"),
...         ("mammal", "lion"),
...         ("mammal", "monkey"),
...     ],
...     names=["class", "name"],
... )
>>> columns = pd.MultiIndex.from_tuples([("speed", "max"), ("species", "type")])
>>> df = pd.DataFrame(
...     [(389.0, "fly"), (24.0, "fly"), (80.5, "run"), (np.nan, "jump")],
...     index=index,
...     columns=columns,
... )
>>> df
               speed species
                 max    type
class  name
bird   falcon  389.0     fly
       parrot   24.0     fly
mammal lion     80.5     run
       monkey    NaN    jump

Using the names parameter, choose a name for the index column:

>>> df.reset_index(names=["classes", "names"])
  classes   names  speed species
                     max    type
0    bird  falcon  389.0     fly
1    bird  parrot   24.0     fly
2  mammal    lion   80.5     run
3  mammal  monkey    NaN    jump

If the index has multiple levels, we can reset a subset of them:

>>> df.reset_index(level="class")
         class  speed species
                  max    type
name
falcon    bird  389.0     fly
parrot    bird   24.0     fly
lion    mammal   80.5     run
monkey  mammal    NaN    jump

If we are not dropping the index, by default, it is placed in the top level. We can place it in another level:

>>> df.reset_index(level="class", col_level=1)
                speed species
         class    max    type
name
falcon    bird  389.0     fly
parrot    bird   24.0     fly
lion    mammal   80.5     run
monkey  mammal    NaN    jump

When the index is inserted under another level, we can specify under which one with the parameter col_fill:

>>> df.reset_index(level="class", col_level=1, col_fill="species")
              species  speed species
                class    max    type
name
falcon           bird  389.0     fly
parrot           bird   24.0     fly
lion           mammal   80.5     run
monkey         mammal    NaN    jump

If we specify a nonexistent level for col_fill, it is created:

>>> df.reset_index(level="class", col_level=1, col_fill="genus")
                genus  speed species
                class    max    type
name
falcon           bird  389.0     fly
parrot           bird   24.0     fly
lion           mammal   80.5     run
monkey         mammal    NaN    jump
rfloordiv(other, axis='columns', level=None, fill_value=None)#

Get Integer division of dataframe and other, element-wise (binary operator rfloordiv).

Equivalent to other // dataframe, but with support to substitute a fill_value for missing data in one of the inputs. With reverse version, floordiv.

Among flexible wrappers (add, sub, mul, div, floordiv, mod, pow) to arithmetic operators: +, -, *, /, //, %, **.

Parameters:
  • other (scalar, sequence, Series, dict or DataFrame) – Any single or multiple element data structure, or list-like object.

  • axis ({0 or 'index', 1 or 'columns'}) – Whether to compare by the index (0 or ‘index’) or columns. (1 or ‘columns’). For Series input, axis to match Series index on.

  • level (int or label) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (float or None, default None) – Fill existing missing (NaN) values, and any new element needed for successful DataFrame alignment, with this value before computation. If data in both corresponding DataFrame locations is missing the result will be missing.

Returns:

Result of the arithmetic operation.

Return type:

DataFrame

See also

DataFrame.add

Add DataFrames.

DataFrame.sub

Subtract DataFrames.

DataFrame.mul

Multiply DataFrames.

DataFrame.div

Divide DataFrames (float division).

DataFrame.truediv

Divide DataFrames (float division).

DataFrame.floordiv

Divide DataFrames (integer division).

DataFrame.mod

Calculate modulo (remainder after division).

DataFrame.pow

Calculate exponential power.

Notes

Mismatched indices will be unioned together.

Examples

>>> df = pd.DataFrame({'angles': [0, 3, 4],
...                    'degrees': [360, 180, 360]},
...                   index=['circle', 'triangle', 'rectangle'])
>>> df
           angles  degrees
circle          0      360
triangle        3      180
rectangle       4      360

Add a scalar with operator version which return the same results.

>>> df + 1
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361
>>> df.add(1)
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361

Divide by constant with reverse version.

>>> df.div(10)
           angles  degrees
circle        0.0     36.0
triangle      0.3     18.0
rectangle     0.4     36.0
>>> df.rdiv(10)
             angles   degrees
circle          inf  0.027778
triangle   3.333333  0.055556
rectangle  2.500000  0.027778

Subtract a list and Series by axis with operator version.

>>> df - [1, 2]
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub([1, 2], axis='columns')
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub(pd.Series([1, 1, 1], index=['circle', 'triangle', 'rectangle']),
...        axis='index')
           angles  degrees
circle         -1      359
triangle        2      179
rectangle       3      359

Multiply a dictionary by axis.

>>> df.mul({'angles': 0, 'degrees': 2})
            angles  degrees
circle           0      720
triangle         0      360
rectangle        0      720
>>> df.mul({'circle': 0, 'triangle': 2, 'rectangle': 3}, axis='index')
            angles  degrees
circle           0        0
triangle         6      360
rectangle       12     1080

Multiply a DataFrame of different shape with operator version.

>>> other = pd.DataFrame({'angles': [0, 3, 4]},
...                      index=['circle', 'triangle', 'rectangle'])
>>> other
           angles
circle          0
triangle        3
rectangle       4
>>> df * other
           angles  degrees
circle          0      NaN
triangle        9      NaN
rectangle      16      NaN
>>> df.mul(other, fill_value=0)
           angles  degrees
circle          0      0.0
triangle        9      0.0
rectangle      16      0.0

Divide by a MultiIndex by level.

>>> df_multindex = pd.DataFrame({'angles': [0, 3, 4, 4, 5, 6],
...                              'degrees': [360, 180, 360, 360, 540, 720]},
...                             index=[['A', 'A', 'A', 'B', 'B', 'B'],
...                                    ['circle', 'triangle', 'rectangle',
...                                     'square', 'pentagon', 'hexagon']])
>>> df_multindex
             angles  degrees
A circle          0      360
  triangle        3      180
  rectangle       4      360
B square          4      360
  pentagon        5      540
  hexagon         6      720
>>> df.div(df_multindex, level=1, fill_value=0)
             angles  degrees
A circle        NaN      1.0
  triangle      1.0      1.0
  rectangle     1.0      1.0
B square        0.0      0.0
  pentagon      0.0      0.0
  hexagon       0.0      0.0
>>> df_pow = pd.DataFrame({'A': [2, 3, 4, 5],
...                        'B': [6, 7, 8, 9]})
>>> df_pow.pow(2)
    A   B
0   4  36
1   9  49
2  16  64
3  25  81
rmod(other, axis='columns', level=None, fill_value=None)#

Get Modulo of dataframe and other, element-wise (binary operator rmod).

Equivalent to other % dataframe, but with support to substitute a fill_value for missing data in one of the inputs. With reverse version, mod.

Among flexible wrappers (add, sub, mul, div, floordiv, mod, pow) to arithmetic operators: +, -, *, /, //, %, **.

Parameters:
  • other (scalar, sequence, Series, dict or DataFrame) – Any single or multiple element data structure, or list-like object.

  • axis ({0 or 'index', 1 or 'columns'}) – Whether to compare by the index (0 or ‘index’) or columns. (1 or ‘columns’). For Series input, axis to match Series index on.

  • level (int or label) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (float or None, default None) – Fill existing missing (NaN) values, and any new element needed for successful DataFrame alignment, with this value before computation. If data in both corresponding DataFrame locations is missing the result will be missing.

Returns:

Result of the arithmetic operation.

Return type:

DataFrame

See also

DataFrame.add

Add DataFrames.

DataFrame.sub

Subtract DataFrames.

DataFrame.mul

Multiply DataFrames.

DataFrame.div

Divide DataFrames (float division).

DataFrame.truediv

Divide DataFrames (float division).

DataFrame.floordiv

Divide DataFrames (integer division).

DataFrame.mod

Calculate modulo (remainder after division).

DataFrame.pow

Calculate exponential power.

Notes

Mismatched indices will be unioned together.

Examples

>>> df = pd.DataFrame({'angles': [0, 3, 4],
...                    'degrees': [360, 180, 360]},
...                   index=['circle', 'triangle', 'rectangle'])
>>> df
           angles  degrees
circle          0      360
triangle        3      180
rectangle       4      360

Add a scalar with operator version which return the same results.

>>> df + 1
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361
>>> df.add(1)
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361

Divide by constant with reverse version.

>>> df.div(10)
           angles  degrees
circle        0.0     36.0
triangle      0.3     18.0
rectangle     0.4     36.0
>>> df.rdiv(10)
             angles   degrees
circle          inf  0.027778
triangle   3.333333  0.055556
rectangle  2.500000  0.027778

Subtract a list and Series by axis with operator version.

>>> df - [1, 2]
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub([1, 2], axis='columns')
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub(pd.Series([1, 1, 1], index=['circle', 'triangle', 'rectangle']),
...        axis='index')
           angles  degrees
circle         -1      359
triangle        2      179
rectangle       3      359

Multiply a dictionary by axis.

>>> df.mul({'angles': 0, 'degrees': 2})
            angles  degrees
circle           0      720
triangle         0      360
rectangle        0      720
>>> df.mul({'circle': 0, 'triangle': 2, 'rectangle': 3}, axis='index')
            angles  degrees
circle           0        0
triangle         6      360
rectangle       12     1080

Multiply a DataFrame of different shape with operator version.

>>> other = pd.DataFrame({'angles': [0, 3, 4]},
...                      index=['circle', 'triangle', 'rectangle'])
>>> other
           angles
circle          0
triangle        3
rectangle       4
>>> df * other
           angles  degrees
circle          0      NaN
triangle        9      NaN
rectangle      16      NaN
>>> df.mul(other, fill_value=0)
           angles  degrees
circle          0      0.0
triangle        9      0.0
rectangle      16      0.0

Divide by a MultiIndex by level.

>>> df_multindex = pd.DataFrame({'angles': [0, 3, 4, 4, 5, 6],
...                              'degrees': [360, 180, 360, 360, 540, 720]},
...                             index=[['A', 'A', 'A', 'B', 'B', 'B'],
...                                    ['circle', 'triangle', 'rectangle',
...                                     'square', 'pentagon', 'hexagon']])
>>> df_multindex
             angles  degrees
A circle          0      360
  triangle        3      180
  rectangle       4      360
B square          4      360
  pentagon        5      540
  hexagon         6      720
>>> df.div(df_multindex, level=1, fill_value=0)
             angles  degrees
A circle        NaN      1.0
  triangle      1.0      1.0
  rectangle     1.0      1.0
B square        0.0      0.0
  pentagon      0.0      0.0
  hexagon       0.0      0.0
>>> df_pow = pd.DataFrame({'A': [2, 3, 4, 5],
...                        'B': [6, 7, 8, 9]})
>>> df_pow.pow(2)
    A   B
0   4  36
1   9  49
2  16  64
3  25  81
rmul(other, axis='columns', level=None, fill_value=None)#

Get Multiplication of dataframe and other, element-wise (binary operator rmul).

Equivalent to other * dataframe, but with support to substitute a fill_value for missing data in one of the inputs. With reverse version, mul.

Among flexible wrappers (add, sub, mul, div, floordiv, mod, pow) to arithmetic operators: +, -, *, /, //, %, **.

Parameters:
  • other (scalar, sequence, Series, dict or DataFrame) – Any single or multiple element data structure, or list-like object.

  • axis ({0 or 'index', 1 or 'columns'}) – Whether to compare by the index (0 or ‘index’) or columns. (1 or ‘columns’). For Series input, axis to match Series index on.

  • level (int or label) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (float or None, default None) – Fill existing missing (NaN) values, and any new element needed for successful DataFrame alignment, with this value before computation. If data in both corresponding DataFrame locations is missing the result will be missing.

Returns:

Result of the arithmetic operation.

Return type:

DataFrame

See also

DataFrame.add

Add DataFrames.

DataFrame.sub

Subtract DataFrames.

DataFrame.mul

Multiply DataFrames.

DataFrame.div

Divide DataFrames (float division).

DataFrame.truediv

Divide DataFrames (float division).

DataFrame.floordiv

Divide DataFrames (integer division).

DataFrame.mod

Calculate modulo (remainder after division).

DataFrame.pow

Calculate exponential power.

Notes

Mismatched indices will be unioned together.

Examples

>>> df = pd.DataFrame({'angles': [0, 3, 4],
...                    'degrees': [360, 180, 360]},
...                   index=['circle', 'triangle', 'rectangle'])
>>> df
           angles  degrees
circle          0      360
triangle        3      180
rectangle       4      360

Add a scalar with operator version which return the same results.

>>> df + 1
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361
>>> df.add(1)
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361

Divide by constant with reverse version.

>>> df.div(10)
           angles  degrees
circle        0.0     36.0
triangle      0.3     18.0
rectangle     0.4     36.0
>>> df.rdiv(10)
             angles   degrees
circle          inf  0.027778
triangle   3.333333  0.055556
rectangle  2.500000  0.027778

Subtract a list and Series by axis with operator version.

>>> df - [1, 2]
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub([1, 2], axis='columns')
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub(pd.Series([1, 1, 1], index=['circle', 'triangle', 'rectangle']),
...        axis='index')
           angles  degrees
circle         -1      359
triangle        2      179
rectangle       3      359

Multiply a dictionary by axis.

>>> df.mul({'angles': 0, 'degrees': 2})
            angles  degrees
circle           0      720
triangle         0      360
rectangle        0      720
>>> df.mul({'circle': 0, 'triangle': 2, 'rectangle': 3}, axis='index')
            angles  degrees
circle           0        0
triangle         6      360
rectangle       12     1080

Multiply a DataFrame of different shape with operator version.

>>> other = pd.DataFrame({'angles': [0, 3, 4]},
...                      index=['circle', 'triangle', 'rectangle'])
>>> other
           angles
circle          0
triangle        3
rectangle       4
>>> df * other
           angles  degrees
circle          0      NaN
triangle        9      NaN
rectangle      16      NaN
>>> df.mul(other, fill_value=0)
           angles  degrees
circle          0      0.0
triangle        9      0.0
rectangle      16      0.0

Divide by a MultiIndex by level.

>>> df_multindex = pd.DataFrame({'angles': [0, 3, 4, 4, 5, 6],
...                              'degrees': [360, 180, 360, 360, 540, 720]},
...                             index=[['A', 'A', 'A', 'B', 'B', 'B'],
...                                    ['circle', 'triangle', 'rectangle',
...                                     'square', 'pentagon', 'hexagon']])
>>> df_multindex
             angles  degrees
A circle          0      360
  triangle        3      180
  rectangle       4      360
B square          4      360
  pentagon        5      540
  hexagon         6      720
>>> df.div(df_multindex, level=1, fill_value=0)
             angles  degrees
A circle        NaN      1.0
  triangle      1.0      1.0
  rectangle     1.0      1.0
B square        0.0      0.0
  pentagon      0.0      0.0
  hexagon       0.0      0.0
>>> df_pow = pd.DataFrame({'A': [2, 3, 4, 5],
...                        'B': [6, 7, 8, 9]})
>>> df_pow.pow(2)
    A   B
0   4  36
1   9  49
2  16  64
3  25  81
round(decimals=0, *args, **kwargs)#

Round numeric columns in a DataFrame to a variable number of decimal places.

Parameters:
  • decimals (int, dict, Series) – Number of decimal places to round each column to. If an int is given, round each column to the same number of places. Otherwise dict and Series round to variable numbers of places. Column names should be in the keys if decimals is a dict-like, or in the index if decimals is a Series. Any columns not included in decimals will be left as is. Elements of decimals which are not columns of the input will be ignored.

  • *args – Additional keywords have no effect but might be accepted for compatibility with numpy.

  • **kwargs – Additional keywords have no effect but might be accepted for compatibility with numpy.

Returns:

A DataFrame with the affected columns rounded to the specified number of decimal places.

Return type:

DataFrame

See also

numpy.around

Round a numpy array to the given number of decimals.

Series.round

Round a Series to the given number of decimals.

Notes

For values exactly halfway between rounded decimal values, pandas rounds to the nearest even value (e.g. -0.5 and 0.5 round to 0.0, 1.5 and 2.5 round to 2.0, etc.).

Examples

>>> df = pd.DataFrame(
...     [(0.21, 0.32), (0.01, 0.67), (0.66, 0.03), (0.21, 0.18)],
...     columns=["dogs", "cats"],
... )
>>> df
    dogs  cats
0  0.21  0.32
1  0.01  0.67
2  0.66  0.03
3  0.21  0.18

By providing an integer each column is rounded to the same number of decimal places

>>> df.round(1)
    dogs  cats
0   0.2   0.3
1   0.0   0.7
2   0.7   0.0
3   0.2   0.2

With a dict, the number of places for specific columns can be specified with the column names as key and the number of decimal places as value

>>> df.round({"dogs": 1, "cats": 0})
    dogs  cats
0   0.2   0.0
1   0.0   1.0
2   0.7   0.0
3   0.2   0.0

Using a Series, the number of places for specific columns can be specified with the column names as index and the number of decimal places as value

>>> decimals = pd.Series([0, 1], index=["cats", "dogs"])
>>> df.round(decimals)
    dogs  cats
0   0.2   0.0
1   0.0   1.0
2   0.7   0.0
3   0.2   0.0
rpow(other, axis='columns', level=None, fill_value=None)#

Get Exponential power of dataframe and other, element-wise (binary operator rpow).

Equivalent to other ** dataframe, but with support to substitute a fill_value for missing data in one of the inputs. With reverse version, pow.

Among flexible wrappers (add, sub, mul, div, floordiv, mod, pow) to arithmetic operators: +, -, *, /, //, %, **.

Parameters:
  • other (scalar, sequence, Series, dict or DataFrame) – Any single or multiple element data structure, or list-like object.

  • axis ({0 or 'index', 1 or 'columns'}) – Whether to compare by the index (0 or ‘index’) or columns. (1 or ‘columns’). For Series input, axis to match Series index on.

  • level (int or label) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (float or None, default None) – Fill existing missing (NaN) values, and any new element needed for successful DataFrame alignment, with this value before computation. If data in both corresponding DataFrame locations is missing the result will be missing.

Returns:

Result of the arithmetic operation.

Return type:

DataFrame

See also

DataFrame.add

Add DataFrames.

DataFrame.sub

Subtract DataFrames.

DataFrame.mul

Multiply DataFrames.

DataFrame.div

Divide DataFrames (float division).

DataFrame.truediv

Divide DataFrames (float division).

DataFrame.floordiv

Divide DataFrames (integer division).

DataFrame.mod

Calculate modulo (remainder after division).

DataFrame.pow

Calculate exponential power.

Notes

Mismatched indices will be unioned together.

Examples

>>> df = pd.DataFrame({'angles': [0, 3, 4],
...                    'degrees': [360, 180, 360]},
...                   index=['circle', 'triangle', 'rectangle'])
>>> df
           angles  degrees
circle          0      360
triangle        3      180
rectangle       4      360

Add a scalar with operator version which return the same results.

>>> df + 1
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361
>>> df.add(1)
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361

Divide by constant with reverse version.

>>> df.div(10)
           angles  degrees
circle        0.0     36.0
triangle      0.3     18.0
rectangle     0.4     36.0
>>> df.rdiv(10)
             angles   degrees
circle          inf  0.027778
triangle   3.333333  0.055556
rectangle  2.500000  0.027778

Subtract a list and Series by axis with operator version.

>>> df - [1, 2]
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub([1, 2], axis='columns')
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub(pd.Series([1, 1, 1], index=['circle', 'triangle', 'rectangle']),
...        axis='index')
           angles  degrees
circle         -1      359
triangle        2      179
rectangle       3      359

Multiply a dictionary by axis.

>>> df.mul({'angles': 0, 'degrees': 2})
            angles  degrees
circle           0      720
triangle         0      360
rectangle        0      720
>>> df.mul({'circle': 0, 'triangle': 2, 'rectangle': 3}, axis='index')
            angles  degrees
circle           0        0
triangle         6      360
rectangle       12     1080

Multiply a DataFrame of different shape with operator version.

>>> other = pd.DataFrame({'angles': [0, 3, 4]},
...                      index=['circle', 'triangle', 'rectangle'])
>>> other
           angles
circle          0
triangle        3
rectangle       4
>>> df * other
           angles  degrees
circle          0      NaN
triangle        9      NaN
rectangle      16      NaN
>>> df.mul(other, fill_value=0)
           angles  degrees
circle          0      0.0
triangle        9      0.0
rectangle      16      0.0

Divide by a MultiIndex by level.

>>> df_multindex = pd.DataFrame({'angles': [0, 3, 4, 4, 5, 6],
...                              'degrees': [360, 180, 360, 360, 540, 720]},
...                             index=[['A', 'A', 'A', 'B', 'B', 'B'],
...                                    ['circle', 'triangle', 'rectangle',
...                                     'square', 'pentagon', 'hexagon']])
>>> df_multindex
             angles  degrees
A circle          0      360
  triangle        3      180
  rectangle       4      360
B square          4      360
  pentagon        5      540
  hexagon         6      720
>>> df.div(df_multindex, level=1, fill_value=0)
             angles  degrees
A circle        NaN      1.0
  triangle      1.0      1.0
  rectangle     1.0      1.0
B square        0.0      0.0
  pentagon      0.0      0.0
  hexagon       0.0      0.0
>>> df_pow = pd.DataFrame({'A': [2, 3, 4, 5],
...                        'B': [6, 7, 8, 9]})
>>> df_pow.pow(2)
    A   B
0   4  36
1   9  49
2  16  64
3  25  81
rsub(other, axis='columns', level=None, fill_value=None)#

Get Subtraction of dataframe and other, element-wise (binary operator rsub).

Equivalent to other - dataframe, but with support to substitute a fill_value for missing data in one of the inputs. With reverse version, sub.

Among flexible wrappers (add, sub, mul, div, floordiv, mod, pow) to arithmetic operators: +, -, *, /, //, %, **.

Parameters:
  • other (scalar, sequence, Series, dict or DataFrame) – Any single or multiple element data structure, or list-like object.

  • axis ({0 or 'index', 1 or 'columns'}) – Whether to compare by the index (0 or ‘index’) or columns. (1 or ‘columns’). For Series input, axis to match Series index on.

  • level (int or label) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (float or None, default None) – Fill existing missing (NaN) values, and any new element needed for successful DataFrame alignment, with this value before computation. If data in both corresponding DataFrame locations is missing the result will be missing.

Returns:

Result of the arithmetic operation.

Return type:

DataFrame

See also

DataFrame.add

Add DataFrames.

DataFrame.sub

Subtract DataFrames.

DataFrame.mul

Multiply DataFrames.

DataFrame.div

Divide DataFrames (float division).

DataFrame.truediv

Divide DataFrames (float division).

DataFrame.floordiv

Divide DataFrames (integer division).

DataFrame.mod

Calculate modulo (remainder after division).

DataFrame.pow

Calculate exponential power.

Notes

Mismatched indices will be unioned together.

Examples

>>> df = pd.DataFrame({'angles': [0, 3, 4],
...                    'degrees': [360, 180, 360]},
...                   index=['circle', 'triangle', 'rectangle'])
>>> df
           angles  degrees
circle          0      360
triangle        3      180
rectangle       4      360

Add a scalar with operator version which return the same results.

>>> df + 1
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361
>>> df.add(1)
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361

Divide by constant with reverse version.

>>> df.div(10)
           angles  degrees
circle        0.0     36.0
triangle      0.3     18.0
rectangle     0.4     36.0
>>> df.rdiv(10)
             angles   degrees
circle          inf  0.027778
triangle   3.333333  0.055556
rectangle  2.500000  0.027778

Subtract a list and Series by axis with operator version.

>>> df - [1, 2]
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub([1, 2], axis='columns')
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub(pd.Series([1, 1, 1], index=['circle', 'triangle', 'rectangle']),
...        axis='index')
           angles  degrees
circle         -1      359
triangle        2      179
rectangle       3      359

Multiply a dictionary by axis.

>>> df.mul({'angles': 0, 'degrees': 2})
            angles  degrees
circle           0      720
triangle         0      360
rectangle        0      720
>>> df.mul({'circle': 0, 'triangle': 2, 'rectangle': 3}, axis='index')
            angles  degrees
circle           0        0
triangle         6      360
rectangle       12     1080

Multiply a DataFrame of different shape with operator version.

>>> other = pd.DataFrame({'angles': [0, 3, 4]},
...                      index=['circle', 'triangle', 'rectangle'])
>>> other
           angles
circle          0
triangle        3
rectangle       4
>>> df * other
           angles  degrees
circle          0      NaN
triangle        9      NaN
rectangle      16      NaN
>>> df.mul(other, fill_value=0)
           angles  degrees
circle          0      0.0
triangle        9      0.0
rectangle      16      0.0

Divide by a MultiIndex by level.

>>> df_multindex = pd.DataFrame({'angles': [0, 3, 4, 4, 5, 6],
...                              'degrees': [360, 180, 360, 360, 540, 720]},
...                             index=[['A', 'A', 'A', 'B', 'B', 'B'],
...                                    ['circle', 'triangle', 'rectangle',
...                                     'square', 'pentagon', 'hexagon']])
>>> df_multindex
             angles  degrees
A circle          0      360
  triangle        3      180
  rectangle       4      360
B square          4      360
  pentagon        5      540
  hexagon         6      720
>>> df.div(df_multindex, level=1, fill_value=0)
             angles  degrees
A circle        NaN      1.0
  triangle      1.0      1.0
  rectangle     1.0      1.0
B square        0.0      0.0
  pentagon      0.0      0.0
  hexagon       0.0      0.0
>>> df_pow = pd.DataFrame({'A': [2, 3, 4, 5],
...                        'B': [6, 7, 8, 9]})
>>> df_pow.pow(2)
    A   B
0   4  36
1   9  49
2  16  64
3  25  81
rtruediv(other, axis='columns', level=None, fill_value=None)#

Get Floating division of dataframe and other, element-wise (binary operator rtruediv).

Equivalent to other / dataframe, but with support to substitute a fill_value for missing data in one of the inputs. With reverse version, truediv.

Among flexible wrappers (add, sub, mul, div, floordiv, mod, pow) to arithmetic operators: +, -, *, /, //, %, **.

Parameters:
  • other (scalar, sequence, Series, dict or DataFrame) – Any single or multiple element data structure, or list-like object.

  • axis ({0 or 'index', 1 or 'columns'}) – Whether to compare by the index (0 or ‘index’) or columns. (1 or ‘columns’). For Series input, axis to match Series index on.

  • level (int or label) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (float or None, default None) – Fill existing missing (NaN) values, and any new element needed for successful DataFrame alignment, with this value before computation. If data in both corresponding DataFrame locations is missing the result will be missing.

Returns:

Result of the arithmetic operation.

Return type:

DataFrame

See also

DataFrame.add

Add DataFrames.

DataFrame.sub

Subtract DataFrames.

DataFrame.mul

Multiply DataFrames.

DataFrame.div

Divide DataFrames (float division).

DataFrame.truediv

Divide DataFrames (float division).

DataFrame.floordiv

Divide DataFrames (integer division).

DataFrame.mod

Calculate modulo (remainder after division).

DataFrame.pow

Calculate exponential power.

Notes

Mismatched indices will be unioned together.

Examples

>>> df = pd.DataFrame({'angles': [0, 3, 4],
...                    'degrees': [360, 180, 360]},
...                   index=['circle', 'triangle', 'rectangle'])
>>> df
           angles  degrees
circle          0      360
triangle        3      180
rectangle       4      360

Add a scalar with operator version which return the same results.

>>> df + 1
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361
>>> df.add(1)
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361

Divide by constant with reverse version.

>>> df.div(10)
           angles  degrees
circle        0.0     36.0
triangle      0.3     18.0
rectangle     0.4     36.0
>>> df.rdiv(10)
             angles   degrees
circle          inf  0.027778
triangle   3.333333  0.055556
rectangle  2.500000  0.027778

Subtract a list and Series by axis with operator version.

>>> df - [1, 2]
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub([1, 2], axis='columns')
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub(pd.Series([1, 1, 1], index=['circle', 'triangle', 'rectangle']),
...        axis='index')
           angles  degrees
circle         -1      359
triangle        2      179
rectangle       3      359

Multiply a dictionary by axis.

>>> df.mul({'angles': 0, 'degrees': 2})
            angles  degrees
circle           0      720
triangle         0      360
rectangle        0      720
>>> df.mul({'circle': 0, 'triangle': 2, 'rectangle': 3}, axis='index')
            angles  degrees
circle           0        0
triangle         6      360
rectangle       12     1080

Multiply a DataFrame of different shape with operator version.

>>> other = pd.DataFrame({'angles': [0, 3, 4]},
...                      index=['circle', 'triangle', 'rectangle'])
>>> other
           angles
circle          0
triangle        3
rectangle       4
>>> df * other
           angles  degrees
circle          0      NaN
triangle        9      NaN
rectangle      16      NaN
>>> df.mul(other, fill_value=0)
           angles  degrees
circle          0      0.0
triangle        9      0.0
rectangle      16      0.0

Divide by a MultiIndex by level.

>>> df_multindex = pd.DataFrame({'angles': [0, 3, 4, 4, 5, 6],
...                              'degrees': [360, 180, 360, 360, 540, 720]},
...                             index=[['A', 'A', 'A', 'B', 'B', 'B'],
...                                    ['circle', 'triangle', 'rectangle',
...                                     'square', 'pentagon', 'hexagon']])
>>> df_multindex
             angles  degrees
A circle          0      360
  triangle        3      180
  rectangle       4      360
B square          4      360
  pentagon        5      540
  hexagon         6      720
>>> df.div(df_multindex, level=1, fill_value=0)
             angles  degrees
A circle        NaN      1.0
  triangle      1.0      1.0
  rectangle     1.0      1.0
B square        0.0      0.0
  pentagon      0.0      0.0
  hexagon       0.0      0.0
>>> df_pow = pd.DataFrame({'A': [2, 3, 4, 5],
...                        'B': [6, 7, 8, 9]})
>>> df_pow.pow(2)
    A   B
0   4  36
1   9  49
2  16  64
3  25  81
select_dtypes(include=None, exclude=None)#

Return a subset of the DataFrame’s columns based on the column dtypes.

This method allows for filtering columns based on their data types. It is useful when working with heterogeneous DataFrames where operations need to be performed on a specific subset of data types.

Parameters:
  • include (scalar or list-like) – A selection of dtypes or strings to be included/excluded. At least one of these parameters must be supplied.

  • exclude (scalar or list-like) – A selection of dtypes or strings to be included/excluded. At least one of these parameters must be supplied.

Returns:

The subset of the frame including the dtypes in include and excluding the dtypes in exclude.

Return type:

DataFrame

Raises:
  • ValueError

    • If both of include and exclude are empty * If include and exclude have overlapping elements

  • TypeError

    • If any kind of string dtype is passed in.

See also

DataFrame.dtypes

Return Series with the data type of each column.

Notes

  • To select all numeric types, use np.number or 'number'

  • To select strings you must use the object dtype, but note that this will return all object dtype columns. With pd.options.future.infer_string enabled, using "str" will work to select all string columns.

  • See the numpy dtype hierarchy

  • To select datetimes, use np.datetime64, 'datetime' or 'datetime64'

  • To select timedeltas, use np.timedelta64, 'timedelta' or 'timedelta64'

  • To select Pandas categorical dtypes, use 'category'

  • To select Pandas datetimetz dtypes, use 'datetimetz' or 'datetime64[ns, tz]'

Examples

>>> df = pd.DataFrame(
...     {"a": [1, 2] * 3, "b": [True, False] * 3, "c": [1.0, 2.0] * 3}
... )
>>> df
        a      b  c
0       1   True  1.0
1       2  False  2.0
2       1   True  1.0
3       2  False  2.0
4       1   True  1.0
5       2  False  2.0
>>> df.select_dtypes(include="bool")
   b
0  True
1  False
2  True
3  False
4  True
5  False
>>> df.select_dtypes(include=["float64"])
   c
0  1.0
1  2.0
2  1.0
3  2.0
4  1.0
5  2.0
>>> df.select_dtypes(exclude=["int64"])
       b    c
0   True  1.0
1  False  2.0
2   True  1.0
3  False  2.0
4   True  1.0
5  False  2.0
sem(*, axis: Axis = 0, skipna: bool = True, ddof: int = 1, numeric_only: bool = False, **kwargs) Series#
sem(*, axis: None, skipna: bool = True, ddof: int = 1, numeric_only: bool = False, **kwargs) Any
sem(*, axis: Axis | None, skipna: bool = True, ddof: int = 1, numeric_only: bool = False, **kwargs) Series | Any

Return unbiased standard error of the mean over requested axis.

Normalized by N-1 by default. This can be changed using the ddof argument

Parameters:
  • axis ({index (0), columns (1)}) –

    For Series this parameter is unused and defaults to 0.

    Warning

    The behavior of DataFrame.sem with axis=None is deprecated, in a future version this will reduce over both axes and return a scalar To retain the old behavior, pass axis=0 (or do not pass axis).

  • skipna (bool, default True) – Exclude NA/null values. If an entire row/column is NA, the result will be NA.

  • ddof (int, default 1) – Delta Degrees of Freedom. The divisor used in calculations is N - ddof, where N represents the number of elements.

  • numeric_only (bool, default False) – Include only float, int, boolean columns. Not implemented for Series.

  • **kwargs – Additional keywords passed.

Returns:

Unbiased standard error of the mean over requested axis.

Return type:

Series or DataFrame (if level specified)

See also

DataFrame.var

Return unbiased variance over requested axis.

DataFrame.std

Returns sample standard deviation over requested axis.

Examples

>>> s = pd.Series([1, 2, 3])
>>> round(s.sem(), 6)
0.57735

With a DataFrame

>>> df = pd.DataFrame({"a": [1, 2], "b": [2, 3]}, index=["tiger", "zebra"])
>>> df
       a   b
tiger  1   2
zebra  2   3
>>> df.sem()
a   0.5
b   0.5
dtype: float64

Using axis=1

>>> df.sem(axis=1)
tiger   0.5
zebra   0.5
dtype: float64

In this case, numeric_only should be set to True to avoid getting an error.

>>> df = pd.DataFrame({"a": [1, 2], "b": ["T", "Z"]}, index=["tiger", "zebra"])
>>> df.sem(numeric_only=True)
a   0.5
dtype: float64
set_axis(labels, *, axis=0, copy=<no_default>)#

Assign desired index to given axis.

Indexes for column or row labels can be changed by assigning a list-like or Index.

Parameters:
  • labels (list-like, Index) – The values for the new index.

  • axis ({0 or 'index', 1 or 'columns'}, default 0) – The axis to update. The value 0 identifies the rows. For Series this parameter is unused and defaults to 0.

  • copy (bool, default False) –

    This keyword is now ignored; changing its value will have no impact on the method.

    Deprecated since version 3.0.0: This keyword is ignored and will be removed in pandas 4.0. Since pandas 3.0, this method always returns a new object using a lazy copy mechanism that defers copies until necessary (Copy-on-Write). See the user guide on Copy-on-Write for more details.

Returns:

An object of type DataFrame.

Return type:

DataFrame

See also

DataFrame.rename_axis

Alter the name of the index or columns.

Examples

>>> df = pd.DataFrame({"A": [1, 2, 3], "B": [4, 5, 6]})

Change the row labels.

>>> df.set_axis(["a", "b", "c"], axis="index")
    A  B
a  1  4
b  2  5
c  3  6

Change the column labels.

>>> df.set_axis(["I", "II"], axis="columns")
    I  II
0  1   4
1  2   5
2  3   6
set_index(keys, *, drop: bool = True, append: bool = False, inplace: Literal[False] = False, verify_integrity: bool | Literal[_NoDefault.no_default] = <no_default>) DataFrame#
set_index(keys, *, drop: bool = True, append: bool = False, inplace: ~typing.Literal[True], verify_integrity: bool | ~pandas.api.typing.Literal[_NoDefault.no_default] = <no_default>) None

Set the DataFrame index using existing columns.

Set the DataFrame index (row labels) using one or more existing columns or arrays (of the correct length). The index can replace the existing index or expand on it.

Parameters:
  • keys (label or array-like or list of labels/arrays) – This parameter can be either a single column key, a single array of the same length as the calling DataFrame, or a list containing an arbitrary combination of column keys and arrays. Here, “array” encompasses Series, Index, np.ndarray, and instances of Iterator.

  • drop (bool, default True) – Delete columns to be used as the new index.

  • append (bool, default False) – Whether to append columns to existing index. Setting to True will add the new columns to existing index. When set to False, the current index will be dropped from the DataFrame.

  • inplace (bool, default False) – Whether to modify the DataFrame rather than creating a new one.

  • verify_integrity (bool, default False) –

    Check the new index for duplicates. Otherwise defer the check until necessary. Setting to False will improve the performance of this method.

    Deprecated since version 3.0.0.

Returns:

Changed row labels or None if inplace=True.

Return type:

DataFrame or None

See also

DataFrame.reset_index

Opposite of set_index.

DataFrame.reindex

Change to new indices or expand indices.

DataFrame.reindex_like

Change to same indices as other DataFrame.

Examples

>>> df = pd.DataFrame(
...     {
...         "month": [1, 4, 7, 10],
...         "year": [2012, 2014, 2013, 2014],
...         "sale": [55, 40, 84, 31],
...     }
... )
>>> df
   month  year  sale
0      1  2012    55
1      4  2014    40
2      7  2013    84
3     10  2014    31

Set the index to become the ‘month’ column:

>>> df.set_index("month")
       year  sale
month
1      2012    55
4      2014    40
7      2013    84
10     2014    31

Create a MultiIndex using columns ‘year’ and ‘month’:

>>> df.set_index(["year", "month"])
            sale
year  month
2012  1     55
2014  4     40
2013  7     84
2014  10    31

Create a MultiIndex using an Index and a column:

>>> df.set_index([pd.Index([1, 2, 3, 4]), "year"])
         month  sale
   year
1  2012  1      55
2  2014  4      40
3  2013  7      84
4  2014  10     31

Create a MultiIndex using two Series:

>>> s = pd.Series([1, 2, 3, 4])
>>> df.set_index([s, s**2])
      month  year  sale
1 1       1  2012    55
2 4       4  2014    40
3 9       7  2013    84
4 16     10  2014    31

Append a column to the existing index:

>>> df = df.set_index("month")
>>> df.set_index("year", append=True)
              sale
month  year
1      2012    55
4      2014    40
7      2013    84
10     2014    31
>>> df.set_index("year", append=False)
       sale
year
2012    55
2014    40
2013    84
2014    31
property shape: tuple[int, int]#

Return a tuple representing the dimensionality of the DataFrame.

Unlike the len() method, which only returns the number of rows, shape provides both row and column counts, making it a more informative method for understanding dataset size.

See also

numpy.ndarray.shape

Tuple of array dimensions.

Examples

>>> df = pd.DataFrame({"col1": [1, 2], "col2": [3, 4]})
>>> df.shape
(2, 2)
>>> df = pd.DataFrame({"col1": [1, 2], "col2": [3, 4], "col3": [5, 6]})
>>> df.shape
(2, 3)
shift(periods=1, freq=None, axis=0, fill_value=<no_default>, suffix=None)#

Shift index by desired number of periods with an optional time freq.

When freq is not passed, shift the index without realigning the data. If freq is passed (in this case, the index must be date or datetime, or it will raise a NotImplementedError), the index will be increased using the periods and the freq. freq can be inferred when specified as “infer” as long as either freq or inferred_freq attribute is set in the index.

Parameters:
  • periods (int or Sequence) – Number of periods to shift. Can be positive or negative. If an iterable of ints, the data will be shifted once by each int. This is equivalent to shifting by one value at a time and concatenating all resulting frames. The resulting columns will have the shift suffixed to their column names. For multiple periods, axis must not be 1.

  • freq (DateOffset, tseries.offsets, timedelta, or str, optional) – Offset to use from the tseries module or time rule (e.g. ‘EOM’). If freq is specified then the index values are shifted but the data is not realigned. That is, use freq if you would like to extend the index when shifting and preserve the original data. If freq is specified as “infer” then it will be inferred from the freq or inferred_freq attributes of the index. If neither of those attributes exist, a ValueError is thrown.

  • axis ({0 or 'index', 1 or 'columns', None}, default None) – Shift direction. For Series this parameter is unused and defaults to 0.

  • fill_value (object, optional) – The scalar value to use for newly introduced missing values. the default depends on the dtype of self. For Boolean and numeric NumPy data types, np.nan is used. For datetime, timedelta, or period data, etc. NaT is used. For extension dtypes, self.dtype.na_value is used.

  • suffix (str, optional) – If str and periods is an iterable, this is added after the column name and before the shift value for each shifted column name. For Series this parameter is unused and defaults to None.

Returns:

Copy of input object, shifted.

Return type:

DataFrame

See also

Index.shift

Shift values of Index.

DatetimeIndex.shift

Shift values of DatetimeIndex.

PeriodIndex.shift

Shift values of PeriodIndex.

Examples

>>> df = pd.DataFrame(
...     [[10, 13, 17], [20, 23, 27], [15, 18, 22], [30, 33, 37], [45, 48, 52]],
...     columns=["Col1", "Col2", "Col3"],
...     index=pd.date_range("2020-01-01", "2020-01-05"),
... )
>>> df
            Col1  Col2  Col3
2020-01-01    10    13    17
2020-01-02    20    23    27
2020-01-03    15    18    22
2020-01-04    30    33    37
2020-01-05    45    48    52
>>> df.shift(periods=3)
            Col1  Col2  Col3
2020-01-01   NaN   NaN   NaN
2020-01-02   NaN   NaN   NaN
2020-01-03   NaN   NaN   NaN
2020-01-04  10.0  13.0  17.0
2020-01-05  20.0  23.0  27.0
>>> df.shift(periods=1, axis="columns")
            Col1  Col2  Col3
2020-01-01   NaN    10    13
2020-01-02   NaN    20    23
2020-01-03   NaN    15    18
2020-01-04   NaN    30    33
2020-01-05   NaN    45    48
>>> df.shift(periods=3, fill_value=0)
            Col1  Col2  Col3
2020-01-01     0     0     0
2020-01-02     0     0     0
2020-01-03     0     0     0
2020-01-04    10    13    17
2020-01-05    20    23    27
>>> df.shift(periods=3, freq="D")
            Col1  Col2  Col3
2020-01-04    10    13    17
2020-01-05    20    23    27
2020-01-06    15    18    22
2020-01-07    30    33    37
2020-01-08    45    48    52
>>> df.shift(periods=3, freq="infer")
            Col1  Col2  Col3
2020-01-04    10    13    17
2020-01-05    20    23    27
2020-01-06    15    18    22
2020-01-07    30    33    37
2020-01-08    45    48    52
>>> df["Col1"].shift(periods=[0, 1, 2])
            Col1_0  Col1_1  Col1_2
2020-01-01      10     NaN     NaN
2020-01-02      20    10.0     NaN
2020-01-03      15    20.0    10.0
2020-01-04      30    15.0    20.0
2020-01-05      45    30.0    15.0
skew(*, axis: Axis = 0, skipna: bool = True, numeric_only: bool = False, **kwargs) Series#
skew(*, axis: None, skipna: bool = True, numeric_only: bool = False, **kwargs) Any
skew(*, axis: Axis | None, skipna: bool = True, numeric_only: bool = False, **kwargs) Series | Any

Return unbiased skew over requested axis.

Normalized by N-1.

Parameters:
  • axis ({index (0), columns (1)}) –

    Axis for the function to be applied on. For Series this parameter is unused and defaults to 0.

    For DataFrames, specifying axis=None will apply the aggregation across both axes.

    Added in version 2.0.0.

  • skipna (bool, default True) – Exclude NA/null values when computing the result.

  • numeric_only (bool, default False) – Include only float, int, boolean columns.

  • **kwargs – Additional keyword arguments to be passed to the function.

Returns:

Unbiased skew over requested axis.

Return type:

Series or scalar

See also

Dataframe.kurt

Returns unbiased kurtosis over requested axis.

Examples

>>> s = pd.Series([1, 2, 3])
>>> s.skew()
0.0

With a DataFrame

>>> df = pd.DataFrame(
...     {"a": [1, 2, 3], "b": [2, 3, 4], "c": [1, 3, 5]},
...     index=["tiger", "zebra", "cow"],
... )
>>> df
        a   b   c
tiger   1   2   1
zebra   2   3   3
cow     3   4   5
>>> df.skew()
a   0.0
b   0.0
c   0.0
dtype: float64

Using axis=1

>>> df.skew(axis=1)
tiger   1.732051
zebra  -1.732051
cow     0.000000
dtype: float64

In this case, numeric_only should be set to True to avoid getting an error.

>>> df = pd.DataFrame(
...     {"a": [1, 2, 3], "b": ["T", "Z", "X"]}, index=["tiger", "zebra", "cow"]
... )
>>> df.skew(numeric_only=True)
a   0.0
dtype: float64
sort_index(*, axis: Axis = 0, level: IndexLabel = None, ascending: bool | Sequence[bool] = True, inplace: Literal[True], kind: SortKind = 'quicksort', na_position: NaPosition = 'last', sort_remaining: bool = True, ignore_index: bool = False, key: IndexKeyFunc = None) None#
sort_index(*, axis: Axis = 0, level: IndexLabel = None, ascending: bool | Sequence[bool] = True, inplace: Literal[False] = False, kind: SortKind = 'quicksort', na_position: NaPosition = 'last', sort_remaining: bool = True, ignore_index: bool = False, key: IndexKeyFunc = None) DataFrame
sort_index(*, axis: Axis = 0, level: IndexLabel = None, ascending: bool | Sequence[bool] = True, inplace: bool = False, kind: SortKind = 'quicksort', na_position: NaPosition = 'last', sort_remaining: bool = True, ignore_index: bool = False, key: IndexKeyFunc = None) DataFrame | None

Sort object by labels (along an axis).

Returns a new DataFrame sorted by label if inplace argument is False, otherwise updates the original DataFrame and returns None.

Parameters:
  • axis ({0 or 'index', 1 or 'columns'}, default 0) – The axis along which to sort. The value 0 identifies the rows, and 1 identifies the columns.

  • level (int or level name or list of ints or list of level names) – If not None, sort on values in specified index level(s).

  • ascending (bool or list-like of bools, default True) – Sort ascending vs. descending. When the index is a MultiIndex the sort direction can be controlled for each level individually.

  • inplace (bool, default False) – Whether to modify the DataFrame rather than creating a new one.

  • kind ({'quicksort', 'mergesort', 'heapsort', 'stable'}, default 'quicksort') – Choice of sorting algorithm. See also numpy.sort() for more information. mergesort and stable are the only stable algorithms. For DataFrames, this option is only applied when sorting on a single column or label.

  • na_position ({'first', 'last'}, default 'last') – Puts NaNs at the beginning if first; last puts NaNs at the end. Not implemented for MultiIndex.

  • sort_remaining (bool, default True) – If True and sorting by level and index is multilevel, sort by other levels too (in order) after sorting by specified level.

  • ignore_index (bool, default False) – If True, the resulting axis will be labeled 0, 1, …, n - 1.

  • key (callable, optional) – If not None, apply the key function to the index values before sorting. This is similar to the key argument in the builtin sorted() function, with the notable difference that this key function should be vectorized. It should expect an Index and return an Index of the same shape. For MultiIndex inputs, the key is applied per level.

Returns:

The original DataFrame sorted by the labels or None if inplace=True.

Return type:

DataFrame or None

See also

Series.sort_index

Sort Series by the index.

DataFrame.sort_values

Sort DataFrame by the value.

Series.sort_values

Sort Series by the value.

Examples

>>> df = pd.DataFrame(
...     [1, 2, 3, 4, 5], index=[100, 29, 234, 1, 150], columns=["A"]
... )
>>> df.sort_index()
     A
1    4
29   2
100  1
150  5
234  3

By default, it sorts in ascending order, to sort in descending order, use ascending=False

>>> df.sort_index(ascending=False)
     A
234  3
150  5
100  1
29   2
1    4

A key function can be specified which is applied to the index before sorting. For a MultiIndex this is applied to each level separately.

>>> df = pd.DataFrame({"a": [1, 2, 3, 4]}, index=["A", "b", "C", "d"])
>>> df.sort_index(key=lambda x: x.str.lower())
   a
A  1
b  2
C  3
d  4
sort_values(by: IndexLabel, *, axis: Axis = 0, ascending=True, inplace: Literal[False] = False, kind: SortKind = 'quicksort', na_position: NaPosition = 'last', ignore_index: bool = False, key: ValueKeyFunc = None) DataFrame#
sort_values(by: IndexLabel, *, axis: Axis = 0, ascending=True, inplace: Literal[True], kind: SortKind = 'quicksort', na_position: str = 'last', ignore_index: bool = False, key: ValueKeyFunc = None) None

Sort by the values along either axis.

Parameters:
  • by (str or list of str) –

    Name or list of names to sort by.

    • if axis is 0 or ‘index’ then by may contain index levels and/or column labels.

    • if axis is 1 or ‘columns’ then by may contain column levels and/or index labels.

  • axis ("{0 or 'index', 1 or 'columns'}", default 0) – Axis to be sorted.

  • ascending (bool or list of bool, default True) – Sort ascending vs. descending. Specify list for multiple sort orders. If this is a list of bools, must match the length of the by.

  • inplace (bool, default False) – If True, perform operation in-place.

  • kind ({'quicksort', 'mergesort', 'heapsort', 'stable'}, default 'quicksort') – Choice of sorting algorithm. See also numpy.sort() for more information. mergesort and stable are the only stable algorithms. For DataFrames, this option is only applied when sorting on a single column or label.

  • na_position ({'first', 'last'}, default 'last') – Puts NaNs at the beginning if first; last puts NaNs at the end.

  • ignore_index (bool, default False) – If True, the resulting axis will be labeled 0, 1, …, n - 1.

  • key (callable, optional) – Apply the key function to the values before sorting. This is similar to the key argument in the builtin sorted() function, with the notable difference that this key function should be vectorized. It should expect a Series and return a Series with the same shape as the input. It will be applied to each column in by independently. The values in the returned Series will be used as the keys for sorting.

Returns:

DataFrame with sorted values or None if inplace=True.

Return type:

DataFrame or None

See also

DataFrame.sort_index

Sort a DataFrame by the index.

Series.sort_values

Similar method for a Series.

Examples

>>> df = pd.DataFrame(
...     {
...         "col1": ["A", "A", "B", np.nan, "D", "C"],
...         "col2": [2, 1, 9, 8, 7, 4],
...         "col3": [0, 1, 9, 4, 2, 3],
...         "col4": ["a", "B", "c", "D", "e", "F"],
...     }
... )
>>> df
  col1  col2  col3 col4
0    A     2     0    a
1    A     1     1    B
2    B     9     9    c
3  NaN     8     4    D
4    D     7     2    e
5    C     4     3    F

Sort by a single column

In this case, we are sorting the rows according to values in col1:

>>> df.sort_values(by=["col1"])
  col1  col2  col3 col4
0    A     2     0    a
1    A     1     1    B
2    B     9     9    c
5    C     4     3    F
4    D     7     2    e
3  NaN     8     4    D

Sort by multiple columns

You can also provide multiple columns to by argument, as shown below. In this example, the rows are first sorted according to col1, and then the rows that have an identical value in col1 are sorted according to col2.

>>> df.sort_values(by=["col1", "col2"])
  col1  col2  col3 col4
1    A     1     1    B
0    A     2     0    a
2    B     9     9    c
5    C     4     3    F
4    D     7     2    e
3  NaN     8     4    D

Sort in a descending order

The sort order can be reversed using ascending argument, as shown below:

>>> df.sort_values(by="col1", ascending=False)
  col1  col2  col3 col4
4    D     7     2    e
5    C     4     3    F
2    B     9     9    c
0    A     2     0    a
1    A     1     1    B
3  NaN     8     4    D

Placing any NA first

Note that in the above example, the rows that contain an NA value in their col1 are placed at the end of the dataframe. This behavior can be modified via na_position argument, as shown below:

>>> df.sort_values(by="col1", ascending=False, na_position="first")
  col1  col2  col3 col4
3  NaN     8     4    D
4    D     7     2    e
5    C     4     3    F
2    B     9     9    c
0    A     2     0    a
1    A     1     1    B

Customized sort order

The key argument allows for a further customization of sorting behaviour. For example, you may want to ignore the letter’s case when sorting strings:

>>> df.sort_values(by="col4", key=lambda col: col.str.lower())
   col1  col2  col3 col4
0    A     2     0    a
1    A     1     1    B
2    B     9     9    c
3  NaN     8     4    D
4    D     7     2    e
5    C     4     3    F

Another typical example is natural sorting. This can be done using natsort package, which provides a function to generate a key to sort data in their natural order:

>>> df = pd.DataFrame(
...     {
...         "hours": ["0hr", "128hr", "0hr", "64hr", "64hr", "128hr"],
...         "mins": [
...             "10mins",
...             "40mins",
...             "40mins",
...             "40mins",
...             "10mins",
...             "10mins",
...         ],
...         "value": [10, 20, 30, 40, 50, 60],
...     }
... )
>>> df
   hours    mins  value
0    0hr  10mins     10
1  128hr  40mins     20
2    0hr  40mins     30
3   64hr  40mins     40
4   64hr  10mins     50
5  128hr  10mins     60
>>> from natsort import natsort_keygen
>>> df.sort_values(
...     by=["hours", "mins"],
...     key=natsort_keygen(),
... )
   hours    mins  value
0    0hr  10mins     10
2    0hr  40mins     30
4   64hr  10mins     50
3   64hr  40mins     40
5  128hr  10mins     60
1  128hr  40mins     20
sparse#

alias of SparseFrameAccessor

stack(level=-1, dropna=<no_default>, sort=<no_default>, future_stack=True)#

Stack the prescribed level(s) from columns to index.

Return a reshaped DataFrame or Series having a multi-level index with one or more new inner-most levels compared to the current DataFrame. The new inner-most levels are created by pivoting the columns of the current dataframe:

  • if the columns have a single level, the output is a Series;

  • if the columns have multiple levels, the new index level(s) is (are) taken from the prescribed level(s) and the output is a DataFrame.

Parameters:
  • level (int, str, list, default -1) – Level(s) to stack from the column axis onto the index axis, defined as one index or label, or a list of indices or labels.

  • dropna (bool, default True) – Whether to drop rows in the resulting Frame/Series with missing values. Stacking a column level onto the index axis can create combinations of index and column values that are missing from the original dataframe. See Examples section.

  • sort (bool, default True) – Whether to sort the levels of the resulting MultiIndex.

  • future_stack (bool, default True) – Whether to use the new implementation that will replace the current implementation in pandas 3.0. When True, dropna and sort have no impact on the result and must remain unspecified. See pandas 2.1.0 Release notes for more details.

Returns:

Stacked dataframe or series.

Return type:

DataFrame or Series

See also

DataFrame.unstack

Unstack prescribed level(s) from index axis onto column axis.

DataFrame.pivot

Reshape dataframe from long format to wide format.

DataFrame.pivot_table

Create a spreadsheet-style pivot table as a DataFrame.

Notes

The function is named by analogy with a collection of books being reorganized from being side by side on a horizontal position (the columns of the dataframe) to being stacked vertically on top of each other (in the index of the dataframe).

Reference the user guide for more examples.

Examples

Single level columns

>>> df_single_level_cols = pd.DataFrame(
...     [[0, 1], [2, 3]], index=["cat", "dog"], columns=["weight", "height"]
... )

Stacking a dataframe with a single level column axis returns a Series:

>>> df_single_level_cols
     weight height
cat       0      1
dog       2      3
>>> df_single_level_cols.stack()
cat  weight    0
     height    1
dog  weight    2
     height    3
dtype: int64

Multi level columns: simple case

>>> multicol1 = pd.MultiIndex.from_tuples(
...     [("weight", "kg"), ("weight", "pounds")]
... )
>>> df_multi_level_cols1 = pd.DataFrame(
...     [[1, 2], [2, 4]], index=["cat", "dog"], columns=multicol1
... )

Stacking a dataframe with a multi-level column axis:

>>> df_multi_level_cols1
     weight
         kg    pounds
cat       1        2
dog       2        4
>>> df_multi_level_cols1.stack()
            weight
cat kg           1
    pounds       2
dog kg           2
    pounds       4

Missing values

>>> multicol2 = pd.MultiIndex.from_tuples([("weight", "kg"), ("height", "m")])
>>> df_multi_level_cols2 = pd.DataFrame(
...     [[1.0, 2.0], [3.0, 4.0]], index=["cat", "dog"], columns=multicol2
... )

It is common to have missing values when stacking a dataframe with multi-level columns, as the stacked dataframe typically has more values than the original dataframe. Missing values are filled with NaNs:

>>> df_multi_level_cols2
    weight height
        kg      m
cat    1.0    2.0
dog    3.0    4.0
>>> df_multi_level_cols2.stack()
        weight  height
cat kg     1.0     NaN
    m      NaN     2.0
dog kg     3.0     NaN
    m      NaN     4.0

Prescribing the level(s) to be stacked

The first parameter controls which level or levels are stacked:

>>> df_multi_level_cols2.stack(0)
             kg    m
cat weight  1.0  NaN
    height  NaN  2.0
dog weight  3.0  NaN
    height  NaN  4.0
>>> df_multi_level_cols2.stack([0, 1])
cat  weight  kg    1.0
     height  m     2.0
dog  weight  kg    3.0
     height  m     4.0
dtype: float64
std(*, axis: Axis = 0, skipna: bool = True, ddof: int = 1, numeric_only: bool = False, **kwargs) Series#
std(*, axis: None, skipna: bool = True, ddof: int = 1, numeric_only: bool = False, **kwargs) Any
std(*, axis: Axis | None, skipna: bool = True, ddof: int = 1, numeric_only: bool = False, **kwargs) Series | Any

Return sample standard deviation over requested axis.

Normalized by N-1 by default. This can be changed using the ddof argument.

Parameters:
  • axis ({index (0), columns (1)}) –

    For Series this parameter is unused and defaults to 0.

    Warning

    The behavior of DataFrame.std with axis=None is deprecated, in a future version this will reduce over both axes and return a scalar To retain the old behavior, pass axis=0 (or do not pass axis).

  • skipna (bool, default True) – Exclude NA/null values. If an entire row/column is NA, the result will be NA.

  • ddof (int, default 1) – Delta Degrees of Freedom. The divisor used in calculations is N - ddof, where N represents the number of elements.

  • numeric_only (bool, default False) – Include only float, int, boolean columns. Not implemented for Series.

  • **kwargs (dict) – Additional keyword arguments to be passed to the function.

Returns:

Standard deviation over requested axis.

Return type:

Series or scalar

See also

Series.std

Return standard deviation over Series values.

DataFrame.mean

Return the mean of the values over the requested axis.

DataFrame.median

Return the median of the values over the requested axis.

DataFrame.mode

Get the mode(s) of each element along the requested axis.

DataFrame.sum

Return the sum of the values over the requested axis.

Notes

To have the same behaviour as numpy.std, use ddof=0 (instead of the default ddof=1)

Examples

>>> df = pd.DataFrame(
...     {
...         "person_id": [0, 1, 2, 3],
...         "age": [21, 25, 62, 43],
...         "height": [1.61, 1.87, 1.49, 2.01],
...     }
... ).set_index("person_id")
>>> df
           age  height
person_id
0           21    1.61
1           25    1.87
2           62    1.49
3           43    2.01

The standard deviation of the columns can be found as follows:

>>> df.std()
age       18.786076
height     0.237417
dtype: float64

Alternatively, ddof=0 can be set to normalize by N instead of N-1:

>>> df.std(ddof=0)
age       16.269219
height     0.205609
dtype: float64
property style: Styler#

Returns a Styler object.

Contains methods for building a styled HTML representation of the DataFrame.

See also

io.formats.style.Styler

Helps style a DataFrame or Series according to the data with HTML and CSS.

Examples

>>> df = pd.DataFrame({"A": [1, 2, 3]})
>>> df.style

Please see Table Visualization for more examples.

sub(other, axis='columns', level=None, fill_value=None)#

Get Subtraction of dataframe and other, element-wise (binary operator sub).

Equivalent to dataframe - other, but with support to substitute a fill_value for missing data in one of the inputs. With reverse version, rsub.

Among flexible wrappers (add, sub, mul, div, floordiv, mod, pow) to arithmetic operators: +, -, *, /, //, %, **.

Parameters:
  • other (scalar, sequence, Series, dict or DataFrame) – Any single or multiple element data structure, or list-like object.

  • axis ({0 or 'index', 1 or 'columns'}) – Whether to compare by the index (0 or ‘index’) or columns. (1 or ‘columns’). For Series input, axis to match Series index on.

  • level (int or label) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (float or None, default None) – Fill existing missing (NaN) values, and any new element needed for successful DataFrame alignment, with this value before computation. If data in both corresponding DataFrame locations is missing the result will be missing.

Returns:

Result of the arithmetic operation.

Return type:

DataFrame

See also

DataFrame.add

Add DataFrames.

DataFrame.sub

Subtract DataFrames.

DataFrame.mul

Multiply DataFrames.

DataFrame.div

Divide DataFrames (float division).

DataFrame.truediv

Divide DataFrames (float division).

DataFrame.floordiv

Divide DataFrames (integer division).

DataFrame.mod

Calculate modulo (remainder after division).

DataFrame.pow

Calculate exponential power.

Notes

Mismatched indices will be unioned together.

Examples

>>> df = pd.DataFrame({'angles': [0, 3, 4],
...                    'degrees': [360, 180, 360]},
...                   index=['circle', 'triangle', 'rectangle'])
>>> df
           angles  degrees
circle          0      360
triangle        3      180
rectangle       4      360

Add a scalar with operator version which return the same results.

>>> df + 1
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361
>>> df.add(1)
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361

Divide by constant with reverse version.

>>> df.div(10)
           angles  degrees
circle        0.0     36.0
triangle      0.3     18.0
rectangle     0.4     36.0
>>> df.rdiv(10)
             angles   degrees
circle          inf  0.027778
triangle   3.333333  0.055556
rectangle  2.500000  0.027778

Subtract a list and Series by axis with operator version.

>>> df - [1, 2]
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub([1, 2], axis='columns')
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub(pd.Series([1, 1, 1], index=['circle', 'triangle', 'rectangle']),
...        axis='index')
           angles  degrees
circle         -1      359
triangle        2      179
rectangle       3      359

Multiply a dictionary by axis.

>>> df.mul({'angles': 0, 'degrees': 2})
            angles  degrees
circle           0      720
triangle         0      360
rectangle        0      720
>>> df.mul({'circle': 0, 'triangle': 2, 'rectangle': 3}, axis='index')
            angles  degrees
circle           0        0
triangle         6      360
rectangle       12     1080

Multiply a DataFrame of different shape with operator version.

>>> other = pd.DataFrame({'angles': [0, 3, 4]},
...                      index=['circle', 'triangle', 'rectangle'])
>>> other
           angles
circle          0
triangle        3
rectangle       4
>>> df * other
           angles  degrees
circle          0      NaN
triangle        9      NaN
rectangle      16      NaN
>>> df.mul(other, fill_value=0)
           angles  degrees
circle          0      0.0
triangle        9      0.0
rectangle      16      0.0

Divide by a MultiIndex by level.

>>> df_multindex = pd.DataFrame({'angles': [0, 3, 4, 4, 5, 6],
...                              'degrees': [360, 180, 360, 360, 540, 720]},
...                             index=[['A', 'A', 'A', 'B', 'B', 'B'],
...                                    ['circle', 'triangle', 'rectangle',
...                                     'square', 'pentagon', 'hexagon']])
>>> df_multindex
             angles  degrees
A circle          0      360
  triangle        3      180
  rectangle       4      360
B square          4      360
  pentagon        5      540
  hexagon         6      720
>>> df.div(df_multindex, level=1, fill_value=0)
             angles  degrees
A circle        NaN      1.0
  triangle      1.0      1.0
  rectangle     1.0      1.0
B square        0.0      0.0
  pentagon      0.0      0.0
  hexagon       0.0      0.0
>>> df_pow = pd.DataFrame({'A': [2, 3, 4, 5],
...                        'B': [6, 7, 8, 9]})
>>> df_pow.pow(2)
    A   B
0   4  36
1   9  49
2  16  64
3  25  81
subtract(other, axis='columns', level=None, fill_value=None)#

Get Subtraction of dataframe and other, element-wise (binary operator sub).

Equivalent to dataframe - other, but with support to substitute a fill_value for missing data in one of the inputs. With reverse version, rsub.

Among flexible wrappers (add, sub, mul, div, floordiv, mod, pow) to arithmetic operators: +, -, *, /, //, %, **.

Parameters:
  • other (scalar, sequence, Series, dict or DataFrame) – Any single or multiple element data structure, or list-like object.

  • axis ({0 or 'index', 1 or 'columns'}) – Whether to compare by the index (0 or ‘index’) or columns. (1 or ‘columns’). For Series input, axis to match Series index on.

  • level (int or label) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (float or None, default None) – Fill existing missing (NaN) values, and any new element needed for successful DataFrame alignment, with this value before computation. If data in both corresponding DataFrame locations is missing the result will be missing.

Returns:

Result of the arithmetic operation.

Return type:

DataFrame

See also

DataFrame.add

Add DataFrames.

DataFrame.sub

Subtract DataFrames.

DataFrame.mul

Multiply DataFrames.

DataFrame.div

Divide DataFrames (float division).

DataFrame.truediv

Divide DataFrames (float division).

DataFrame.floordiv

Divide DataFrames (integer division).

DataFrame.mod

Calculate modulo (remainder after division).

DataFrame.pow

Calculate exponential power.

Notes

Mismatched indices will be unioned together.

Examples

>>> df = pd.DataFrame({'angles': [0, 3, 4],
...                    'degrees': [360, 180, 360]},
...                   index=['circle', 'triangle', 'rectangle'])
>>> df
           angles  degrees
circle          0      360
triangle        3      180
rectangle       4      360

Add a scalar with operator version which return the same results.

>>> df + 1
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361
>>> df.add(1)
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361

Divide by constant with reverse version.

>>> df.div(10)
           angles  degrees
circle        0.0     36.0
triangle      0.3     18.0
rectangle     0.4     36.0
>>> df.rdiv(10)
             angles   degrees
circle          inf  0.027778
triangle   3.333333  0.055556
rectangle  2.500000  0.027778

Subtract a list and Series by axis with operator version.

>>> df - [1, 2]
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub([1, 2], axis='columns')
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub(pd.Series([1, 1, 1], index=['circle', 'triangle', 'rectangle']),
...        axis='index')
           angles  degrees
circle         -1      359
triangle        2      179
rectangle       3      359

Multiply a dictionary by axis.

>>> df.mul({'angles': 0, 'degrees': 2})
            angles  degrees
circle           0      720
triangle         0      360
rectangle        0      720
>>> df.mul({'circle': 0, 'triangle': 2, 'rectangle': 3}, axis='index')
            angles  degrees
circle           0        0
triangle         6      360
rectangle       12     1080

Multiply a DataFrame of different shape with operator version.

>>> other = pd.DataFrame({'angles': [0, 3, 4]},
...                      index=['circle', 'triangle', 'rectangle'])
>>> other
           angles
circle          0
triangle        3
rectangle       4
>>> df * other
           angles  degrees
circle          0      NaN
triangle        9      NaN
rectangle      16      NaN
>>> df.mul(other, fill_value=0)
           angles  degrees
circle          0      0.0
triangle        9      0.0
rectangle      16      0.0

Divide by a MultiIndex by level.

>>> df_multindex = pd.DataFrame({'angles': [0, 3, 4, 4, 5, 6],
...                              'degrees': [360, 180, 360, 360, 540, 720]},
...                             index=[['A', 'A', 'A', 'B', 'B', 'B'],
...                                    ['circle', 'triangle', 'rectangle',
...                                     'square', 'pentagon', 'hexagon']])
>>> df_multindex
             angles  degrees
A circle          0      360
  triangle        3      180
  rectangle       4      360
B square          4      360
  pentagon        5      540
  hexagon         6      720
>>> df.div(df_multindex, level=1, fill_value=0)
             angles  degrees
A circle        NaN      1.0
  triangle      1.0      1.0
  rectangle     1.0      1.0
B square        0.0      0.0
  pentagon      0.0      0.0
  hexagon       0.0      0.0
>>> df_pow = pd.DataFrame({'A': [2, 3, 4, 5],
...                        'B': [6, 7, 8, 9]})
>>> df_pow.pow(2)
    A   B
0   4  36
1   9  49
2  16  64
3  25  81
sum(*, axis=0, skipna=True, numeric_only=False, min_count=0, **kwargs)#

Return the sum of the values over the requested axis.

This is equivalent to the method numpy.sum.

Parameters:
  • axis ({index (0), columns (1)}) –

    Axis for the function to be applied on. For Series this parameter is unused and defaults to 0.

    Warning

    The behavior of DataFrame.sum with axis=None is deprecated, in a future version this will reduce over both axes and return a scalar To retain the old behavior, pass axis=0 (or do not pass axis).

    Added in version 2.0.0.

  • skipna (bool, default True) – Exclude NA/null values when computing the result.

  • numeric_only (bool, default False) – Include only float, int, boolean columns. Not implemented for Series.

  • min_count (int, default 0) – The required number of valid values to perform the operation. If fewer than min_count non-NA values are present the result will be NA.

  • **kwargs – Additional keyword arguments to be passed to the function.

Returns:

Sum over requested axis.

Return type:

Series or scalar

See also

Series.sum

Return the sum over Series values.

DataFrame.mean

Return the mean of the values over the requested axis.

DataFrame.median

Return the median of the values over the requested axis.

DataFrame.mode

Get the mode(s) of each element along the requested axis.

DataFrame.std

Return the standard deviation of the values over the requested axis.

Examples

>>> idx = pd.MultiIndex.from_arrays(
...     [["warm", "warm", "cold", "cold"], ["dog", "falcon", "fish", "spider"]],
...     names=["blooded", "animal"],
... )
>>> s = pd.Series([4, 2, 0, 8], name="legs", index=idx)
>>> s
blooded  animal
warm     dog       4
         falcon    2
cold     fish      0
         spider    8
Name: legs, dtype: int64
>>> s.sum()
14

By default, the sum of an empty or all-NA Series is 0.

>>> pd.Series([], dtype="float64").sum()  # min_count=0 is the default
0.0

This can be controlled with the min_count parameter. For example, if you’d like the sum of an empty series to be NaN, pass min_count=1.

>>> pd.Series([], dtype="float64").sum(min_count=1)
nan

Thanks to the skipna parameter, min_count handles all-NA and empty series identically.

>>> pd.Series([np.nan]).sum()
0.0
>>> pd.Series([np.nan]).sum(min_count=1)
nan
swaplevel(i=-2, j=-1, axis=0)#

Swap levels i and j in a MultiIndex.

Default is to swap the two innermost levels of the index.

Parameters:
  • i (int or str) – Levels of the indices to be swapped. Can pass level name as string.

  • j (int or str) – Levels of the indices to be swapped. Can pass level name as string.

  • axis ({0 or 'index', 1 or 'columns'}, default 0) – The axis to swap levels on. 0 or ‘index’ for row-wise, 1 or ‘columns’ for column-wise.

Returns:

DataFrame with levels swapped in MultiIndex.

Return type:

DataFrame

See also

DataFrame.reorder_levels

Reorder levels of MultiIndex.

DataFrame.sort_index

Sort MultiIndex.

Examples

>>> df = pd.DataFrame(
...     {"Grade": ["A", "B", "A", "C"]},
...     index=[
...         ["Final exam", "Final exam", "Coursework", "Coursework"],
...         ["History", "Geography", "History", "Geography"],
...         ["January", "February", "March", "April"],
...     ],
... )
>>> df
                                    Grade
Final exam  History     January      A
            Geography   February     B
Coursework  History     March        A
            Geography   April        C

In the following example, we will swap the levels of the indices. Here, we will swap the levels column-wise, but levels can be swapped row-wise in a similar manner. Note that column-wise is the default behaviour. By not supplying any arguments for i and j, we swap the last and second to last indices.

>>> df.swaplevel()
                                    Grade
Final exam  January     History         A
            February    Geography       B
Coursework  March       History         A
            April       Geography       C

By supplying one argument, we can choose which index to swap the last index with. We can for example swap the first index with the last one as follows.

>>> df.swaplevel(0)
                                    Grade
January     History     Final exam      A
February    Geography   Final exam      B
March       History     Coursework      A
April       Geography   Coursework      C

We can also define explicitly which indices we want to swap by supplying values for both i and j. Here, we for example swap the first and second indices.

>>> df.swaplevel(0, 1)
                                    Grade
History     Final exam  January         A
Geography   Final exam  February        B
History     Coursework  March           A
Geography   Coursework  April           C
to_dict(orient: Literal['dict', 'list', 'series', 'split', 'tight', 'index'] = 'dict', *, into: type[MutableMappingT] | MutableMappingT, index: bool = True) MutableMappingT#
to_dict(orient: Literal['records'], *, into: type[MutableMappingT] | MutableMappingT, index: bool = True) list[MutableMappingT]
to_dict(orient: Literal['dict', 'list', 'series', 'split', 'tight', 'index']='dict', *, into: type[dict] = <class 'dict'>, index: bool = True) dict
to_dict(orient: ~typing.Literal['records'], *, into: type[dict] = <class 'dict'>, index: bool = True) list[dict]

Convert the DataFrame to a dictionary.

The type of the key-value pairs can be customized with the parameters (see below).

Parameters:
  • orient (str {'dict', 'list', 'series', 'split', 'tight', 'records', 'index'}) –

    Determines the type of the values of the dictionary.

    • ’dict’ (default) : dict like {column -> {index -> value}}

    • ’list’ : dict like {column -> [values]}

    • ’series’ : dict like {column -> Series(values)}

    • ’split’ : dict like {‘index’ -> [index], ‘columns’ -> [columns], ‘data’ -> [values]}

    • ’tight’ : dict like {‘index’ -> [index], ‘columns’ -> [columns], ‘data’ -> [values], ‘index_names’ -> [index.names], ‘column_names’ -> [column.names]}

    • ’records’ : list like [{column -> value}, … , {column -> value}]

    • ’index’ : dict like {index -> {column -> value}}

  • into (class, default dict) – The collections.abc.MutableMapping subclass used for all Mappings in the return value. Can be the actual class or an empty instance of the mapping type you want. If you want a collections.defaultdict, you must pass it initialized.

  • index (bool, default True) –

    Whether to include the index item (and index_names item if orient is ‘tight’) in the returned dictionary. Can only be False when orient is ‘split’ or ‘tight’. Note that when orient is ‘records’, this parameter does not take effect (index item always not included).

    Added in version 2.0.0.

Returns:

Return a collections.abc.MutableMapping object representing the DataFrame. The resulting transformation depends on the orient parameter.

Return type:

dict, list or collections.abc.MutableMapping

See also

DataFrame.from_dict

Create a DataFrame from a dictionary.

DataFrame.to_json

Convert a DataFrame to JSON format.

Examples

>>> df = pd.DataFrame(
...     {"col1": [1, 2], "col2": [0.5, 0.75]}, index=["row1", "row2"]
... )
>>> df
      col1  col2
row1     1  0.50
row2     2  0.75
>>> df.to_dict()
{'col1': {'row1': 1, 'row2': 2}, 'col2': {'row1': 0.5, 'row2': 0.75}}

You can specify the return orientation.

>>> df.to_dict("series")
{'col1': row1    1
         row2    2
Name: col1, dtype: int64,
'col2': row1    0.50
        row2    0.75
Name: col2, dtype: float64}
>>> df.to_dict("split")
{'index': ['row1', 'row2'], 'columns': ['col1', 'col2'],
 'data': [[1, 0.5], [2, 0.75]]}
>>> df.to_dict("records")
[{'col1': 1, 'col2': 0.5}, {'col1': 2, 'col2': 0.75}]
>>> df.to_dict("index")
{'row1': {'col1': 1, 'col2': 0.5}, 'row2': {'col1': 2, 'col2': 0.75}}
>>> df.to_dict("tight")
{'index': ['row1', 'row2'], 'columns': ['col1', 'col2'],
 'data': [[1, 0.5], [2, 0.75]], 'index_names': [None], 'column_names': [None]}

You can also specify the mapping type.

>>> from collections import OrderedDict, defaultdict
>>> df.to_dict(into=OrderedDict)
OrderedDict([('col1', OrderedDict([('row1', 1), ('row2', 2)])),
             ('col2', OrderedDict([('row1', 0.5), ('row2', 0.75)]))])

If you want a defaultdict, you need to initialize it:

>>> dd = defaultdict(list)
>>> df.to_dict("records", into=dd)
[defaultdict(<class 'list'>, {'col1': 1, 'col2': 0.5}),
 defaultdict(<class 'list'>, {'col1': 2, 'col2': 0.75})]
to_feather(path, **kwargs)#

Write a DataFrame to the binary Feather format.

Parameters:
  • path (str, path object, file-like object) – String, path object (implementing os.PathLike[str]), or file-like object implementing a binary write() function. If a string or a path, it will be used as Root Directory path when writing a partitioned dataset.

  • **kwargs – Additional keywords passed to pyarrow.feather.write_feather(). This includes the compression, compression_level, chunksize and version keywords.

Return type:

None

See also

DataFrame.to_parquet

Write a DataFrame to the binary parquet format.

DataFrame.to_excel

Write object to an Excel sheet.

DataFrame.to_sql

Write to a sql table.

DataFrame.to_csv

Write a csv file.

DataFrame.to_json

Convert the object to a JSON string.

DataFrame.to_html

Render a DataFrame as an HTML table.

DataFrame.to_string

Convert DataFrame to a string.

Notes

This function writes the dataframe as a feather file. Requires a default index. For saving the DataFrame with your custom index use a method that supports custom indices e.g. to_parquet.

Examples

>>> df = pd.DataFrame([[1, 2, 3], [4, 5, 6]])
>>> df.to_feather("file.feather")
to_html(buf: FilePath | WriteBuffer[str], *, columns: Axes | None = None, col_space: ColspaceArgType | None = None, header: bool = True, index: bool = True, na_rep: str = 'NaN', formatters: FormattersType | None = None, float_format: FloatFormatType | None = None, sparsify: bool | None = None, index_names: bool = True, justify: str | None = None, max_rows: int | None = None, max_cols: int | None = None, show_dimensions: bool | str = False, decimal: str = '.', bold_rows: bool = True, classes: str | list | tuple | None = None, escape: bool = True, notebook: bool = False, border: int | bool | None = None, table_id: str | None = None, render_links: bool = False, encoding: str | None = None) None#
to_html(buf: None = None, *, columns: Axes | None = None, col_space: ColspaceArgType | None = None, header: bool = True, index: bool = True, na_rep: str = 'NaN', formatters: FormattersType | None = None, float_format: FloatFormatType | None = None, sparsify: bool | None = None, index_names: bool = True, justify: str | None = None, max_rows: int | None = None, max_cols: int | None = None, show_dimensions: bool | str = False, decimal: str = '.', bold_rows: bool = True, classes: str | list | tuple | None = None, escape: bool = True, notebook: bool = False, border: int | bool | None = None, table_id: str | None = None, render_links: bool = False, encoding: str | None = None) str

Render a DataFrame as an HTML table.

Parameters:
  • buf (str, Path or StringIO-like, optional, default None) – Buffer to write to. If None, the output is returned as a string.

  • columns (array-like, optional, default None) – The subset of columns to write. Writes all columns by default.

  • col_space (str or int, list or dict of int or str, optional) – The minimum width of each column in CSS length units. An int is assumed to be px units.

  • header (bool, optional) – Whether to print column labels, default True.

  • index (bool, optional, default True) – Whether to print index (row) labels.

  • na_rep (str, optional, default 'NaN') – String representation of NaN to use.

  • formatters (list, tuple or dict of one-param. functions, optional) – Formatter functions to apply to columns’ elements by position or name. The result of each function must be a unicode string. List/tuple must be of length equal to the number of columns.

  • float_format (one-parameter function, optional, default None) – Formatter function to apply to columns’ elements if they are floats. This function must return a unicode string and will be applied only to the non-NaN elements, with NaN being handled by na_rep.

  • sparsify (bool, optional, default True) – Set to False for a DataFrame with a hierarchical index to print every multiindex key at each row.

  • index_names (bool, optional, default True) – Prints the names of the indexes.

  • justify (str, default None) –

    How to justify the column labels. If None uses the option from the print configuration (controlled by set_option), ‘right’ out of the box. Valid values are

    • left

    • right

    • center

    • justify

    • justify-all

    • start

    • end

    • inherit

    • match-parent

    • initial

    • unset.

  • max_rows (int, optional) – Maximum number of rows to display in the console.

  • max_cols (int, optional) – Maximum number of columns to display in the console.

  • show_dimensions (bool, default False) – Display DataFrame dimensions (number of rows by number of columns).

  • decimal (str, default '.') – Character recognized as decimal separator, e.g. ‘,’ in Europe.

  • bold_rows (bool, default True) – Make the row labels bold in the output.

  • classes (str or list or tuple, default None) – CSS class(es) to apply to the resulting html table.

  • escape (bool, default True) – Convert the characters <, >, and & to HTML-safe sequences.

  • notebook ({True, False}, default False) – Whether the generated HTML is for IPython Notebook.

  • border (int or bool) – When an integer value is provided, it sets the border attribute in the opening tag, specifying the thickness of the border. If False or 0 is passed, the border attribute will not be present in the <table> tag. The default value for this parameter is governed by pd.options.display.html.border.

  • table_id (str, optional) – A css id is included in the opening <table> tag if specified.

  • render_links (bool, default False) – Convert URLs to HTML links.

  • encoding (str, default "utf-8") – Set character encoding.

Returns:

If buf is None, returns the result as a string. Otherwise returns None.

Return type:

str or None

See also

to_string

Convert DataFrame to a string.

Examples

>>> df = pd.DataFrame(data={"col1": [1, 2], "col2": [4, 3]})
>>> html_string = df.to_html()
>>> print(html_string)
<table border="1" class="dataframe">
  <thead>
    <tr style="text-align: right;">
      <th></th>
      <th>col1</th>
      <th>col2</th>
    </tr>
  </thead>
  <tbody>
    <tr>
      <th>0</th>
      <td>1</td>
      <td>4</td>
    </tr>
    <tr>
      <th>1</th>
      <td>2</td>
      <td>3</td>
    </tr>
  </tbody>
</table>

HTML output

col1

col2

0

1

4

1

2

3

>>> df = pd.DataFrame(data={"col1": [1, 2], "col2": [4, 3]})
>>> html_string = df.to_html(index=False)
>>> print(html_string)
<table border="1" class="dataframe">
  <thead>
    <tr style="text-align: right;">
      <th>col1</th>
      <th>col2</th>
    </tr>
  </thead>
  <tbody>
    <tr>
      <td>1</td>
      <td>4</td>
    </tr>
    <tr>
      <td>2</td>
      <td>3</td>
    </tr>
  </tbody>
</table>

HTML output

col1

col2

1

4

2

3

to_iceberg(table_identifier, catalog_name=None, *, catalog_properties=None, location=None, append=False, snapshot_properties=None)#

Write a DataFrame to an Apache Iceberg table.

Added in version 3.0.0.

Warning

to_iceberg is experimental and may change without warning.

Parameters:
  • table_identifier (str) – Table identifier.

  • catalog_name (str, optional) – The name of the catalog.

  • catalog_properties (dict of {str: str}, optional) – The properties that are used next to the catalog configuration.

  • location (str, optional) – Location for the table.

  • append (bool, default False) – If True, append data to the table, instead of replacing the content.

  • snapshot_properties (dict of {str: str}, optional) – Custom properties to be added to the snapshot summary

Return type:

None

See also

read_iceberg

Read an Apache Iceberg table.

DataFrame.to_parquet

Write a DataFrame in Parquet format.

Examples

>>> df = pd.DataFrame(data={"col1": [1, 2], "col2": [4, 3]})
>>> df.to_iceberg("my_table", catalog_name="my_catalog")
to_markdown(buf: None = None, *, mode: str = 'wt', index: bool = True, storage_options: StorageOptions | None = None, **kwargs) str#
to_markdown(buf: FilePath | WriteBuffer[str], *, mode: str = 'wt', index: bool = True, storage_options: StorageOptions | None = None, **kwargs) None
to_markdown(buf: FilePath | WriteBuffer[str] | None, *, mode: str = 'wt', index: bool = True, storage_options: StorageOptions | None = None, **kwargs) str | None

Print DataFrame in Markdown-friendly format.

Parameters:
  • buf (str, Path or StringIO-like, optional, default None) – Buffer to write to. If None, the output is returned as a string.

  • mode (str, optional) – Mode in which file is opened, “wt” by default.

  • index (bool, optional, default True) – Add index (row) labels.

  • storage_options (dict, optional) – Extra options that make sense for a particular storage connection, e.g. host, port, username, password, etc. For HTTP(S) URLs the key-value pairs are forwarded to urllib.request.Request as header options. For other URLs (e.g. starting with “s3://”, and “gcs://”) the key-value pairs are forwarded to fsspec.open. Please see fsspec and urllib for more details, and for more examples on storage options refer here.

  • **kwargs – These parameters will be passed to tabulate.

Returns:

DataFrame in Markdown-friendly format.

Return type:

str

See also

DataFrame.to_html

Render DataFrame to HTML-formatted table.

DataFrame.to_latex

Render DataFrame to LaTeX-formatted table.

Notes

Requires the tabulate package.

Examples

>>> df = pd.DataFrame(
...     data={"animal_1": ["elk", "pig"], "animal_2": ["dog", "quetzal"]}
... )
>>> print(df.to_markdown())
|    | animal_1   | animal_2   |
|---:|:-----------|:-----------|
|  0 | elk        | dog        |
|  1 | pig        | quetzal    |

Output markdown with a tabulate option.

>>> print(df.to_markdown(tablefmt="grid"))
+----+------------+------------+
|    | animal_1   | animal_2   |
+====+============+============+
|  0 | elk        | dog        |
+----+------------+------------+
|  1 | pig        | quetzal    |
+----+------------+------------+
to_numpy(dtype=None, copy=False, na_value=<no_default>)#

Convert the DataFrame to a NumPy array.

By default, the dtype of the returned array will be the common NumPy dtype of all types in the DataFrame. For example, if the dtypes are float16 and float32, the results dtype will be float32. This may require copying data and coercing values, which may be expensive.

Parameters:
  • dtype (str or numpy.dtype, optional) – The dtype to pass to numpy.asarray().

  • copy (bool, default False) – Whether to ensure that the returned value is not a view on another array. Note that copy=False does not ensure that to_numpy() is no-copy. Rather, copy=True ensure that a copy is made, even if not strictly necessary.

  • na_value (Any, optional) – The value to use for missing values. The default value depends on dtype and the dtypes of the DataFrame columns.

Returns:

The NumPy array representing the values in the DataFrame.

Return type:

numpy.ndarray

See also

Series.to_numpy

Similar method for Series.

Examples

>>> pd.DataFrame({"A": [1, 2], "B": [3, 4]}).to_numpy()
array([[1, 3],
       [2, 4]])

With heterogeneous data, the lowest common type will have to be used.

>>> df = pd.DataFrame({"A": [1, 2], "B": [3.0, 4.5]})
>>> df.to_numpy()
array([[1. , 3. ],
       [2. , 4.5]])

For a mix of numeric and non-numeric types, the output array will have object dtype.

>>> df["C"] = pd.date_range("2000", periods=2)
>>> df.to_numpy()
array([[1, 3.0, Timestamp('2000-01-01 00:00:00')],
       [2, 4.5, Timestamp('2000-01-02 00:00:00')]], dtype=object)
to_orc(path: None = None, *, engine: Literal['pyarrow'] = 'pyarrow', index: bool | None = None, engine_kwargs: dict[str, Any] | None = None) bytes#
to_orc(path: FilePath | WriteBuffer[bytes], *, engine: Literal['pyarrow'] = 'pyarrow', index: bool | None = None, engine_kwargs: dict[str, Any] | None = None) None
to_orc(path: FilePath | WriteBuffer[bytes] | None, *, engine: Literal['pyarrow'] = 'pyarrow', index: bool | None = None, engine_kwargs: dict[str, Any] | None = None) bytes | None

Write a DataFrame to the Optimized Row Columnar (ORC) format.

Parameters:
  • path (str, file-like object or None, default None) – If a string, it will be used as Root Directory path when writing a partitioned dataset. By file-like object, we refer to objects with a write() method, such as a file handle (e.g. via builtin open function). If path is None, a bytes object is returned.

  • engine ({'pyarrow'}, default 'pyarrow') – ORC library to use.

  • index (bool, optional) – If True, include the dataframe’s index(es) in the file output. If False, they will not be written to the file. If None, similar to infer the dataframe’s index(es) will be saved. However, instead of being saved as values, the RangeIndex will be stored as a range in the metadata so it doesn’t require much space and is faster. Other indexes will be included as columns in the file output.

  • engine_kwargs (dict[str, Any] or None, default None) – Additional keyword arguments passed to pyarrow.orc.write_table().

Returns:

Bytes object with DataFrame data if path is not specified else None.

Return type:

bytes if no path argument is provided else None

Raises:
  • NotImplementedError – Dtype of one or more columns is category, unsigned integers, interval, period or sparse.

  • ValueError – engine is not pyarrow.

See also

read_orc

Read a ORC file.

DataFrame.to_parquet

Write a parquet file.

DataFrame.to_csv

Write a csv file.

DataFrame.to_sql

Write to a sql table.

DataFrame.to_hdf

Write to hdf.

Notes

Examples

>>> df = pd.DataFrame(data={"col1": [1, 2], "col2": [4, 3]})
>>> df.to_orc("df.orc")
>>> pd.read_orc("df.orc")
   col1  col2
0     1     4
1     2     3

If you want to get a buffer to the orc content you can write it to io.BytesIO

>>> import io
>>> b = io.BytesIO(df.to_orc())
>>> b.seek(0)
0
>>> content = b.read()
to_parquet(path: None = None, *, engine: Literal['auto', 'pyarrow', 'fastparquet'] = 'auto', compression: ParquetCompressionOptions = 'snappy', index: bool | None = None, partition_cols: list[str] | None = None, storage_options: StorageOptions = None, filesystem: Any = None, **kwargs) bytes#
to_parquet(path: FilePath | WriteBuffer[bytes], *, engine: Literal['auto', 'pyarrow', 'fastparquet'] = 'auto', compression: ParquetCompressionOptions = 'snappy', index: bool | None = None, partition_cols: list[str] | None = None, storage_options: StorageOptions = None, filesystem: Any = None, **kwargs) None

Write a DataFrame to the binary parquet format.

This function writes the dataframe as a parquet file. You can choose different parquet backends, and have the option of compression. See the user guide for more details.

Parameters:
  • path (str, path object, file-like object, or None, default None) – String, path object (implementing os.PathLike[str]), or file-like object implementing a binary write() function. If None, the result is returned as bytes. If a string or path, it will be used as Root Directory path when writing a partitioned dataset.

  • engine ({'auto', 'pyarrow', 'fastparquet'}, default 'auto') – Parquet library to use. If ‘auto’, then the option io.parquet.engine is used. The default io.parquet.engine behavior is to try ‘pyarrow’, falling back to ‘fastparquet’ if ‘pyarrow’ is unavailable.

  • compression (str or None, default 'snappy') – Name of the compression to use. Use None for no compression. Supported options: ‘snappy’, ‘gzip’, ‘brotli’, ‘lz4’, ‘zstd’.

  • index (bool, default None) – If True, include the dataframe’s index(es) in the file output. If False, they will not be written to the file. If None, similar to True the dataframe’s index(es) will be saved. However, instead of being saved as values, the RangeIndex will be stored as a range in the metadata so it doesn’t require much space and is faster. Other indexes will be included as columns in the file output.

  • partition_cols (list, optional, default None) – Column names by which to partition the dataset. Columns are partitioned in the order they are given. Must be None if path is not a string.

  • storage_options (dict, optional) –

    Extra options that make sense for a particular storage connection, e.g. host, port, username, password, etc. For HTTP(S) URLs the key-value pairs are forwarded to urllib.request.Request as header options. For other URLs (e.g. starting with “s3://”, and “gcs://”) the key-value pairs are forwarded to fsspec.open. Please see fsspec and urllib for more details, and for more examples on storage options refer here.

  • filesystem (fsspec or pyarrow filesystem, default None) –

    Filesystem object to use when reading the parquet file. Only implemented for engine="pyarrow".

    Added in version 2.1.0.

  • **kwargs – Additional arguments passed to the parquet library. See pandas io for more details.

Returns:

Returns the DataFrame converted to the binary parquet format as bytes if no path argument. Returns None and writes the DataFrame to the specified location in the Parquet format if the path argument is provided.

Return type:

bytes if no path argument is provided else None

See also

read_parquet

Read a parquet file.

DataFrame.to_orc

Write an orc file.

DataFrame.to_csv

Write a csv file.

DataFrame.to_sql

Write to a sql table.

DataFrame.to_hdf

Write to hdf.

Notes

  • This function requires either the fastparquet or pyarrow library.

  • When saving a DataFrame with categorical columns to parquet, the file size may increase due to the inclusion of all possible categories, not just those present in the data. This behavior is expected and consistent with pandas’ handling of categorical data. To manage file size and ensure a more predictable roundtrip process, consider using Categorical.remove_unused_categories() on the DataFrame before saving.

Examples

>>> df = pd.DataFrame(data={"col1": [1, 2], "col2": [3, 4]})
>>> df.to_parquet("df.parquet.gzip", compression="gzip")
>>> pd.read_parquet("df.parquet.gzip")
   col1  col2
0     1     3
1     2     4

If you want to get a buffer to the parquet content you can use a io.BytesIO object, as long as you don’t use partition_cols, which creates multiple files.

>>> import io
>>> f = io.BytesIO()
>>> df.to_parquet(f)
>>> f.seek(0)
0
>>> content = f.read()
to_period(freq=None, axis=0, copy=<no_default>)#

Convert DataFrame from DatetimeIndex to PeriodIndex.

Convert DataFrame from DatetimeIndex to PeriodIndex with desired frequency (inferred from index if not passed). Either index of columns can be converted, depending on axis argument.

Parameters:
  • freq (str, default) – Frequency of the PeriodIndex.

  • axis ({0 or 'index', 1 or 'columns'}, default 0) – The axis to convert (the index by default).

  • copy (bool, default False) –

    This keyword is now ignored; changing its value will have no impact on the method.

    Deprecated since version 3.0.0: This keyword is ignored and will be removed in pandas 4.0. Since pandas 3.0, this method always returns a new object using a lazy copy mechanism that defers copies until necessary (Copy-on-Write). See the user guide on Copy-on-Write for more details.

Returns:

The DataFrame with the converted PeriodIndex.

Return type:

DataFrame

See also

Series.to_period

Equivalent method for Series.

Series.dt.to_period

Convert DateTime column values.

Examples

>>> idx = pd.to_datetime(
...     [
...         "2001-03-31 00:00:00",
...         "2002-05-31 00:00:00",
...         "2003-08-31 00:00:00",
...     ]
... )
>>> idx
DatetimeIndex(['2001-03-31', '2002-05-31', '2003-08-31'],
              dtype='datetime64[us]', freq=None)
>>> idx.to_period("M")
PeriodIndex(['2001-03', '2002-05', '2003-08'], dtype='period[M]')

For the yearly frequency

>>> idx.to_period("Y")
PeriodIndex(['2001', '2002', '2003'], dtype='period[Y-DEC]')
to_records(index=True, column_dtypes=None, index_dtypes=None)#

Convert DataFrame to a NumPy record array.

Index will be included as the first field of the record array if requested.

Parameters:
  • index (bool, default True) – Include index in resulting record array, stored in ‘index’ field or using the index label, if set.

  • column_dtypes (str, type, dict, default None) – If a string or type, the data type to store all columns. If a dictionary, a mapping of column names and indices (zero-indexed) to specific data types.

  • index_dtypes (str, type, dict, default None) –

    If a string or type, the data type to store all index levels. If a dictionary, a mapping of index level names and indices (zero-indexed) to specific data types.

    This mapping is applied only if index=True.

Returns:

NumPy ndarray with the DataFrame labels as fields and each row of the DataFrame as entries.

Return type:

numpy.rec.recarray

See also

DataFrame.from_records

Convert structured or record ndarray to DataFrame.

numpy.rec.recarray

An ndarray that allows field access using attributes, analogous to typed columns in a spreadsheet.

Examples

>>> df = pd.DataFrame({"A": [1, 2], "B": [0.5, 0.75]}, index=["a", "b"])
>>> df
   A     B
a  1  0.50
b  2  0.75
>>> df.to_records()
rec.array([('a', 1, 0.5 ), ('b', 2, 0.75)],
          dtype=[('index', 'O'), ('A', '<i8'), ('B', '<f8')])

If the DataFrame index has no label then the recarray field name is set to ‘index’. If the index has a label then this is used as the field name:

>>> df.index = df.index.rename("I")
>>> df.to_records()
rec.array([('a', 1, 0.5 ), ('b', 2, 0.75)],
          dtype=[('I', 'O'), ('A', '<i8'), ('B', '<f8')])

The index can be excluded from the record array:

>>> df.to_records(index=False)
rec.array([(1, 0.5 ), (2, 0.75)],
          dtype=[('A', '<i8'), ('B', '<f8')])

Data types can be specified for the columns:

>>> df.to_records(column_dtypes={"A": "int32"})
rec.array([('a', 1, 0.5 ), ('b', 2, 0.75)],
          dtype=[('I', 'O'), ('A', '<i4'), ('B', '<f8')])

As well as for the index:

>>> df.to_records(index_dtypes="<S2")
rec.array([(b'a', 1, 0.5 ), (b'b', 2, 0.75)],
          dtype=[('I', 'S2'), ('A', '<i8'), ('B', '<f8')])
>>> index_dtypes = f"<S{df.index.str.len().max()}"
>>> df.to_records(index_dtypes=index_dtypes)
rec.array([(b'a', 1, 0.5 ), (b'b', 2, 0.75)],
          dtype=[('I', 'S1'), ('A', '<i8'), ('B', '<f8')])
to_stata(path, *, convert_dates=None, write_index=True, byteorder=None, time_stamp=None, data_label=None, variable_labels=None, version=114, convert_strl=None, compression='infer', storage_options=None, value_labels=None)#

Export DataFrame object to Stata dta format.

Writes the DataFrame to a Stata dataset file. “dta” files contain a Stata dataset.

Parameters:
  • path (str, path object, or buffer) – String, path object (implementing os.PathLike[str]), or file-like object implementing a binary write() function.

  • convert_dates (dict) – Dictionary mapping columns containing datetime types to stata internal format to use when writing the dates. Options are ‘tc’, ‘td’, ‘tm’, ‘tw’, ‘th’, ‘tq’, ‘ty’. Column can be either an integer or a name. Datetime columns that do not have a conversion type specified will be converted to ‘tc’. Raises NotImplementedError if a datetime column has timezone information.

  • write_index (bool) – Write the index to Stata dataset.

  • byteorder (str) – Can be “>”, “<”, “little”, or “big”. default is sys.byteorder.

  • time_stamp (datetime) – A datetime to use as file creation date. Default is the current time.

  • data_label (str, optional) – A label for the data set. Must be 80 characters or smaller.

  • variable_labels (dict) – Dictionary containing columns as keys and variable labels as values. Each label must be 80 characters or smaller.

  • version ({114, 117, 118, 119, None}, default 114) –

    Version to use in the output dta file. Set to None to let pandas decide between 118 or 119 formats depending on the number of columns in the frame. Version 114 can be read by Stata 10 and later. Version 117 can be read by Stata 13 or later. Version 118 is supported in Stata 14 and later. Version 119 is supported in Stata 15 and later. Version 114 limits string variables to 244 characters or fewer while versions 117 and later allow strings with lengths up to 2,000,000 characters. Versions 118 and 119 support Unicode characters, and version 119 supports more than 32,767 variables.

    Version 119 should usually only be used when the number of variables exceeds the capacity of dta format 118. Exporting smaller datasets in format 119 may have unintended consequences, and, as of November 2020, Stata SE cannot read version 119 files.

  • convert_strl (list, optional) – List of column names to convert to string columns to Stata StrL format. Only available if version is 117. Storing strings in the StrL format can produce smaller dta files if strings have more than 8 characters and values are repeated.

  • compression (str or dict, default 'infer') – For on-the-fly compression of the output data. If ‘infer’ and ‘path’ is path-like, then detect compression from the following extensions: ‘.gz’, ‘.bz2’, ‘.zip’, ‘.xz’, ‘.zst’, ‘.tar’, ‘.tar.gz’, ‘.tar.xz’ or ‘.tar.bz2’ (otherwise no compression). Set to None for no compression. Can also be a dict with key 'method' set to one of {'zip', 'gzip', 'bz2', 'zstd', 'xz', 'tar'} and other key-value pairs are forwarded to zipfile.ZipFile, gzip.GzipFile, bz2.BZ2File, zstandard.ZstdCompressor, lzma.LZMAFile or tarfile.TarFile, respectively. As an example, the following could be passed for faster compression and to create a reproducible gzip archive: compression={'method': 'gzip', 'compresslevel': 1, 'mtime': 1}.

  • storage_options (dict, optional) –

    Extra options that make sense for a particular storage connection, e.g. host, port, username, password, etc. For HTTP(S) URLs the key-value pairs are forwarded to urllib.request.Request as header options. For other URLs (e.g. starting with “s3://”, and “gcs://”) the key-value pairs are forwarded to fsspec.open. Please see fsspec and urllib for more details, and for more examples on storage options refer here.

  • value_labels (dict of dicts) – Dictionary containing columns as keys and dictionaries of column value to labels as values. Labels for a single variable must be 32,000 characters or smaller.

Raises:
  • NotImplementedError

    • If datetimes contain timezone information * Column dtype is not representable in Stata

  • ValueError

    • Columns listed in convert_dates are neither datetime64[ns] or datetime.datetime * Column listed in convert_dates is not in DataFrame * Categorical label contains more than 32,000 characters

Return type:

None

See also

read_stata

Import Stata data files.

io.stata.StataWriter

Low-level writer for Stata data files.

io.stata.StataWriter117

Low-level writer for version 117 files.

Examples

>>> df = pd.DataFrame(
...     [["falcon", 350], ["parrot", 18]], columns=["animal", "parrot"]
... )
>>> df.to_stata("animals.dta")
to_timestamp(freq=None, how='start', axis=0, copy=<no_default>)#

Cast PeriodIndex to DatetimeIndex of timestamps, at beginning of period.

This can be changed to the end of the period, by specifying how=”e”.

Parameters:
  • freq (str, default frequency of PeriodIndex) – Desired frequency.

  • how ({'s', 'e', 'start', 'end'}) – Convention for converting period to timestamp; start of period vs. end.

  • axis ({0 or 'index', 1 or 'columns'}, default 0) – The axis to convert (the index by default).

  • copy (bool, default False) –

    This keyword is now ignored; changing its value will have no impact on the method.

    Deprecated since version 3.0.0: This keyword is ignored and will be removed in pandas 4.0. Since pandas 3.0, this method always returns a new object using a lazy copy mechanism that defers copies until necessary (Copy-on-Write). See the user guide on Copy-on-Write for more details.

Returns:

DataFrame with the PeriodIndex cast to DatetimeIndex.

Return type:

DataFrame with DatetimeIndex

See also

DataFrame.to_period

Inverse method to cast DatetimeIndex to PeriodIndex.

Series.to_timestamp

Equivalent method for Series.

Examples

>>> idx = pd.PeriodIndex(["2023", "2024"], freq="Y")
>>> d = {"col1": [1, 2], "col2": [3, 4]}
>>> df1 = pd.DataFrame(data=d, index=idx)
>>> df1
      col1   col2
2023     1      3
2024     2      4

The resulting timestamps will be at the beginning of the year in this case

>>> df1 = df1.to_timestamp()
>>> df1
            col1   col2
2023-01-01     1      3
2024-01-01     2      4
>>> df1.index
DatetimeIndex(['2023-01-01', '2024-01-01'], dtype='datetime64[us]', freq=None)

Using freq which is the offset that the Timestamps will have

>>> df2 = pd.DataFrame(data=d, index=idx)
>>> df2 = df2.to_timestamp(freq="M")
>>> df2
            col1   col2
2023-01-31     1      3
2024-01-31     2      4
>>> df2.index
DatetimeIndex(['2023-01-31', '2024-01-31'], dtype='datetime64[us]', freq=None)
to_xml(path_or_buffer: None = None, *, index: bool = True, root_name: str | None = 'data', row_name: str | None = 'row', na_rep: str | None = None, attr_cols: list[str] | None = None, elem_cols: list[str] | None = None, namespaces: dict[str | None, str] | None = None, prefix: str | None = None, encoding: str = 'utf-8', xml_declaration: bool | None = True, pretty_print: bool | None = True, parser: XMLParsers | None = 'lxml', stylesheet: FilePath | ReadBuffer[str] | ReadBuffer[bytes] | None = None, compression: CompressionOptions = 'infer', storage_options: StorageOptions | None = None) str#
to_xml(path_or_buffer: FilePath | WriteBuffer[bytes] | WriteBuffer[str], *, index: bool = True, root_name: str | None = 'data', row_name: str | None = 'row', na_rep: str | None = None, attr_cols: list[str] | None = None, elem_cols: list[str] | None = None, namespaces: dict[str | None, str] | None = None, prefix: str | None = None, encoding: str = 'utf-8', xml_declaration: bool | None = True, pretty_print: bool | None = True, parser: XMLParsers | None = 'lxml', stylesheet: FilePath | ReadBuffer[str] | ReadBuffer[bytes] | None = None, compression: CompressionOptions = 'infer', storage_options: StorageOptions | None = None) None

Render a DataFrame to an XML document.

Parameters:
  • path_or_buffer (str, path object, file-like object, or None, default None) – String, path object (implementing os.PathLike[str]), or file-like object implementing a write() function. If None, the result is returned as a string.

  • index (bool, default True) – Whether to include index in XML document.

  • root_name (str, default 'data') – The name of root element in XML document.

  • row_name (str, default 'row') – The name of row element in XML document.

  • na_rep (str, optional) – Missing data representation.

  • attr_cols (list-like, optional) – List of columns to write as attributes in row element. Hierarchical columns will be flattened with underscore delimiting the different levels.

  • elem_cols (list-like, optional) – List of columns to write as children in row element. By default, all columns output as children of row element. Hierarchical columns will be flattened with underscore delimiting the different levels.

  • namespaces (dict, optional) –

    All namespaces to be defined in root element. Keys of dict should be prefix names and values of dict corresponding URIs. Default namespaces should be given empty string key. For example,

    namespaces = {"": "https://example.com"}
    

  • prefix (str, optional) – Namespace prefix to be used for every element and/or attribute in document. This should be one of the keys in namespaces dict.

  • encoding (str, default 'utf-8') – Encoding of the resulting document.

  • xml_declaration (bool, default True) – Whether to include the XML declaration at start of document.

  • pretty_print (bool, default True) – Whether output should be pretty printed with indentation and line breaks.

  • parser ({'lxml','etree'}, default 'lxml') – Parser module to use for building of tree. Only ‘lxml’ and ‘etree’ are supported. With ‘lxml’, the ability to use XSLT stylesheet is supported.

  • stylesheet (str, path object or file-like object, optional) – A URL, file-like object, or a raw string containing an XSLT script used to transform the raw XML output. Script should use layout of elements and attributes from original output. This argument requires lxml to be installed. Only XSLT 1.0 scripts and not later versions is currently supported.

  • compression (str or dict, default 'infer') – For on-the-fly compression of the output data. If ‘infer’ and ‘path_or_buffer’ is path-like, then detect compression from the following extensions: ‘.gz’, ‘.bz2’, ‘.zip’, ‘.xz’, ‘.zst’, ‘.tar’, ‘.tar.gz’, ‘.tar.xz’ or ‘.tar.bz2’ (otherwise no compression). Set to None for no compression. Can also be a dict with key 'method' set to one of {'zip', 'gzip', 'bz2', 'zstd', 'xz', 'tar'} and other key-value pairs are forwarded to zipfile.ZipFile, gzip.GzipFile, bz2.BZ2File, zstandard.ZstdCompressor, lzma.LZMAFile or tarfile.TarFile, respectively. As an example, the following could be passed for faster compression and to create a reproducible gzip archive: compression={'method': 'gzip', 'compresslevel': 1, 'mtime': 1}.

  • storage_options (dict, optional) –

    Extra options that make sense for a particular storage connection, e.g. host, port, username, password, etc. For HTTP(S) URLs the key-value pairs are forwarded to urllib.request.Request as header options. For other URLs (e.g. starting with “s3://”, and “gcs://”) the key-value pairs are forwarded to fsspec.open. Please see fsspec and urllib for more details, and for more examples on storage options refer here.

Returns:

If io is None, returns the resulting XML format as a string. Otherwise returns None.

Return type:

None or str

See also

to_json

Convert the pandas object to a JSON string.

to_html

Convert DataFrame to a html.

Examples

>>> df = pd.DataFrame(
...     [["square", 360, 4], ["circle", 360, np.nan], ["triangle", 180, 3]],
...     columns=["shape", "degrees", "sides"],
... )
>>> df.to_xml()
<?xml version='1.0' encoding='utf-8'?>
<data>
  <row>
    <index>0</index>
    <shape>square</shape>
    <degrees>360</degrees>
    <sides>4.0</sides>
  </row>
  <row>
    <index>1</index>
    <shape>circle</shape>
    <degrees>360</degrees>
    <sides/>
  </row>
  <row>
    <index>2</index>
    <shape>triangle</shape>
    <degrees>180</degrees>
    <sides>3.0</sides>
  </row>
</data>
>>> df.to_xml(
...     attr_cols=["index", "shape", "degrees", "sides"]
... )
<?xml version='1.0' encoding='utf-8'?>
<data>
  <row index="0" shape="square" degrees="360" sides="4.0"/>
  <row index="1" shape="circle" degrees="360"/>
  <row index="2" shape="triangle" degrees="180" sides="3.0"/>
</data>
>>> df.to_xml(
...     namespaces={"doc": "https://example.com"}, prefix="doc"
... )
<?xml version='1.0' encoding='utf-8'?>
<doc:data xmlns:doc="https://example.com">
  <doc:row>
    <doc:index>0</doc:index>
    <doc:shape>square</doc:shape>
    <doc:degrees>360</doc:degrees>
    <doc:sides>4.0</doc:sides>
  </doc:row>
  <doc:row>
    <doc:index>1</doc:index>
    <doc:shape>circle</doc:shape>
    <doc:degrees>360</doc:degrees>
    <doc:sides/>
  </doc:row>
  <doc:row>
    <doc:index>2</doc:index>
    <doc:shape>triangle</doc:shape>
    <doc:degrees>180</doc:degrees>
    <doc:sides>3.0</doc:sides>
  </doc:row>
</doc:data>
transform(func, axis=0, *args, **kwargs)#

Call func on self producing a DataFrame with the same axis shape as self.

Parameters:
  • func (function, str, list-like or dict-like) –

    Function to use for transforming the data. If a function, must either work when passed a DataFrame or when passed to DataFrame.apply. If func is both list-like and dict-like, dict-like behavior takes precedence.

    Accepted combinations are:

    • function

    • string function name

    • list-like of functions and/or function names, e.g. [np.exp, 'sqrt']

    • dict-like of axis labels -> functions, function names or list-like of such.

  • axis ({0 or 'index', 1 or 'columns'}, default 0) – If 0 or ‘index’: apply function to each column. If 1 or ‘columns’: apply function to each row.

  • *args – Positional arguments to pass to func.

  • **kwargs – Keyword arguments to pass to func.

Returns:

A DataFrame that must have the same length as self.

Return type:

DataFrame

:raises ValueError : If the returned DataFrame has a different length than self.:

See also

DataFrame.agg

Only perform aggregating type operations.

DataFrame.apply

Invoke function on a DataFrame.

Notes

Functions that mutate the passed object can produce unexpected behavior or errors and are not supported. See Mutating with User Defined Function (UDF) methods for more details.

Examples

>>> df = pd.DataFrame({"A": range(3), "B": range(1, 4)})
>>> df
   A  B
0  0  1
1  1  2
2  2  3
>>> df.transform(lambda x: x + 1)
   A  B
0  1  2
1  2  3
2  3  4

Even though the resulting DataFrame must have the same length as the input DataFrame, it is possible to provide several input functions:

>>> s = pd.Series(range(3))
>>> s
0    0
1    1
2    2
dtype: int64
>>> s.transform([np.sqrt, np.exp])
       sqrt        exp
0  0.000000   1.000000
1  1.000000   2.718282
2  1.414214   7.389056

You can call transform on a GroupBy object:

>>> df = pd.DataFrame(
...     {
...         "Date": [
...             "2015-05-08",
...             "2015-05-07",
...             "2015-05-06",
...             "2015-05-05",
...             "2015-05-08",
...             "2015-05-07",
...             "2015-05-06",
...             "2015-05-05",
...         ],
...         "Data": [5, 8, 6, 1, 50, 100, 60, 120],
...     }
... )
>>> df
         Date  Data
0  2015-05-08     5
1  2015-05-07     8
2  2015-05-06     6
3  2015-05-05     1
4  2015-05-08    50
5  2015-05-07   100
6  2015-05-06    60
7  2015-05-05   120
>>> df.groupby("Date")["Data"].transform("sum")
0     55
1    108
2     66
3    121
4     55
5    108
6     66
7    121
Name: Data, dtype: int64
>>> df = pd.DataFrame(
...     {
...         "c": [1, 1, 1, 2, 2, 2, 2],
...         "type": ["m", "n", "o", "m", "m", "n", "n"],
...     }
... )
>>> df
   c type
0  1    m
1  1    n
2  1    o
3  2    m
4  2    m
5  2    n
6  2    n
>>> df["size"] = df.groupby("c")["type"].transform(len)
>>> df
   c type size
0  1    m    3
1  1    n    3
2  1    o    3
3  2    m    4
4  2    m    4
5  2    n    4
6  2    n    4
transpose(*args, copy=<no_default>)#

Transpose index and columns.

Reflect the DataFrame over its main diagonal by writing rows as columns and vice-versa. The property T is an accessor to the method transpose().

Parameters:
  • *args (tuple, optional) – Accepted for compatibility with NumPy.

  • copy (bool, default False) –

    This keyword is now ignored; changing its value will have no impact on the method.

    Note that a copy is always required for mixed dtype DataFrames, or for DataFrames with any extension types.

    Deprecated since version 3.0.0: This keyword is ignored and will be removed in pandas 4.0. Since pandas 3.0, this method always returns a new object using a lazy copy mechanism that defers copies until necessary (Copy-on-Write). See the user guide on Copy-on-Write for more details.

Returns:

The transposed DataFrame.

Return type:

DataFrame

See also

numpy.transpose

Permute the dimensions of a given array.

Notes

Transposing a DataFrame with mixed dtypes will result in a homogeneous DataFrame with the object dtype. In such a case, a copy of the data is always made.

Examples

Square DataFrame with homogeneous dtype

>>> d1 = {"col1": [1, 2], "col2": [3, 4]}
>>> df1 = pd.DataFrame(data=d1)
>>> df1
   col1  col2
0     1     3
1     2     4
>>> df1_transposed = df1.T  # or df1.transpose()
>>> df1_transposed
      0  1
col1  1  2
col2  3  4

When the dtype is homogeneous in the original DataFrame, we get a transposed DataFrame with the same dtype:

>>> df1.dtypes
col1    int64
col2    int64
dtype: object
>>> df1_transposed.dtypes
0    int64
1    int64
dtype: object

Non-square DataFrame with mixed dtypes

>>> d2 = {
...     "name": ["Alice", "Bob"],
...     "score": [9.5, 8],
...     "employed": [False, True],
...     "kids": [0, 0],
... }
>>> df2 = pd.DataFrame(data=d2)
>>> df2
    name  score  employed  kids
0  Alice    9.5     False     0
1    Bob    8.0      True     0
>>> df2_transposed = df2.T  # or df2.transpose()
>>> df2_transposed
              0     1
name      Alice   Bob
score       9.5   8.0
employed  False  True
kids          0     0

When the DataFrame has mixed dtypes, we get a transposed DataFrame with the object dtype:

>>> df2.dtypes
name            str
score       float64
employed       bool
kids          int64
dtype: object
>>> df2_transposed.dtypes
0    object
1    object
dtype: object
truediv(other, axis='columns', level=None, fill_value=None)#

Get Floating division of dataframe and other, element-wise (binary operator truediv).

Equivalent to dataframe / other, but with support to substitute a fill_value for missing data in one of the inputs. With reverse version, rtruediv.

Among flexible wrappers (add, sub, mul, div, floordiv, mod, pow) to arithmetic operators: +, -, *, /, //, %, **.

Parameters:
  • other (scalar, sequence, Series, dict or DataFrame) – Any single or multiple element data structure, or list-like object.

  • axis ({0 or 'index', 1 or 'columns'}) – Whether to compare by the index (0 or ‘index’) or columns. (1 or ‘columns’). For Series input, axis to match Series index on.

  • level (int or label) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (float or None, default None) – Fill existing missing (NaN) values, and any new element needed for successful DataFrame alignment, with this value before computation. If data in both corresponding DataFrame locations is missing the result will be missing.

Returns:

Result of the arithmetic operation.

Return type:

DataFrame

See also

DataFrame.add

Add DataFrames.

DataFrame.sub

Subtract DataFrames.

DataFrame.mul

Multiply DataFrames.

DataFrame.div

Divide DataFrames (float division).

DataFrame.truediv

Divide DataFrames (float division).

DataFrame.floordiv

Divide DataFrames (integer division).

DataFrame.mod

Calculate modulo (remainder after division).

DataFrame.pow

Calculate exponential power.

Notes

Mismatched indices will be unioned together.

Examples

>>> df = pd.DataFrame({'angles': [0, 3, 4],
...                    'degrees': [360, 180, 360]},
...                   index=['circle', 'triangle', 'rectangle'])
>>> df
           angles  degrees
circle          0      360
triangle        3      180
rectangle       4      360

Add a scalar with operator version which return the same results.

>>> df + 1
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361
>>> df.add(1)
           angles  degrees
circle          1      361
triangle        4      181
rectangle       5      361

Divide by constant with reverse version.

>>> df.div(10)
           angles  degrees
circle        0.0     36.0
triangle      0.3     18.0
rectangle     0.4     36.0
>>> df.rdiv(10)
             angles   degrees
circle          inf  0.027778
triangle   3.333333  0.055556
rectangle  2.500000  0.027778

Subtract a list and Series by axis with operator version.

>>> df - [1, 2]
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub([1, 2], axis='columns')
           angles  degrees
circle         -1      358
triangle        2      178
rectangle       3      358
>>> df.sub(pd.Series([1, 1, 1], index=['circle', 'triangle', 'rectangle']),
...        axis='index')
           angles  degrees
circle         -1      359
triangle        2      179
rectangle       3      359

Multiply a dictionary by axis.

>>> df.mul({'angles': 0, 'degrees': 2})
            angles  degrees
circle           0      720
triangle         0      360
rectangle        0      720
>>> df.mul({'circle': 0, 'triangle': 2, 'rectangle': 3}, axis='index')
            angles  degrees
circle           0        0
triangle         6      360
rectangle       12     1080

Multiply a DataFrame of different shape with operator version.

>>> other = pd.DataFrame({'angles': [0, 3, 4]},
...                      index=['circle', 'triangle', 'rectangle'])
>>> other
           angles
circle          0
triangle        3
rectangle       4
>>> df * other
           angles  degrees
circle          0      NaN
triangle        9      NaN
rectangle      16      NaN
>>> df.mul(other, fill_value=0)
           angles  degrees
circle          0      0.0
triangle        9      0.0
rectangle      16      0.0

Divide by a MultiIndex by level.

>>> df_multindex = pd.DataFrame({'angles': [0, 3, 4, 4, 5, 6],
...                              'degrees': [360, 180, 360, 360, 540, 720]},
...                             index=[['A', 'A', 'A', 'B', 'B', 'B'],
...                                    ['circle', 'triangle', 'rectangle',
...                                     'square', 'pentagon', 'hexagon']])
>>> df_multindex
             angles  degrees
A circle          0      360
  triangle        3      180
  rectangle       4      360
B square          4      360
  pentagon        5      540
  hexagon         6      720
>>> df.div(df_multindex, level=1, fill_value=0)
             angles  degrees
A circle        NaN      1.0
  triangle      1.0      1.0
  rectangle     1.0      1.0
B square        0.0      0.0
  pentagon      0.0      0.0
  hexagon       0.0      0.0
>>> df_pow = pd.DataFrame({'A': [2, 3, 4, 5],
...                        'B': [6, 7, 8, 9]})
>>> df_pow.pow(2)
    A   B
0   4  36
1   9  49
2  16  64
3  25  81
unstack(level=-1, fill_value=None, sort=True)#

Pivot a level of the (necessarily hierarchical) index labels.

Returns a DataFrame having a new level of column labels whose inner-most level consists of the pivoted index labels.

If the index is not a MultiIndex, the output will be a Series (the analogue of stack when the columns are not a MultiIndex).

Parameters:
  • level (int, str, or list of these, default -1 (last level)) – Level(s) of index to unstack, can pass level name.

  • fill_value (scalar) – Replace NaN with this value if the unstack produces missing values.

  • sort (bool, default True) – Sort the level(s) in the resulting MultiIndex columns.

Returns:

If index is a MultiIndex: DataFrame with pivoted index labels as new inner-most level column labels, else Series.

Return type:

Series or DataFrame

See also

DataFrame.pivot

Pivot a table based on column values.

DataFrame.stack

Pivot a level of the column labels (inverse operation from unstack).

Notes

Reference the user guide for more examples.

Examples

>>> index = pd.MultiIndex.from_tuples(
...     [("one", "a"), ("one", "b"), ("two", "a"), ("two", "b")]
... )
>>> s = pd.Series(np.arange(1.0, 5.0), index=index)
>>> s
one  a   1.0
     b   2.0
two  a   3.0
     b   4.0
dtype: float64
>>> s.unstack(level=-1)
     a   b
one  1.0  2.0
two  3.0  4.0
>>> s.unstack(level=0)
   one  two
a  1.0   3.0
b  2.0   4.0
>>> df = s.unstack(level=0)
>>> df.unstack()
one  a  1.0
     b  2.0
two  a  3.0
     b  4.0
dtype: float64
update(other, join='left', overwrite=True, filter_func=None, errors='ignore')#

Modify in place using non-NA values from another DataFrame.

Aligns on indices. There is no return value.

Parameters:
  • other (DataFrame, or object coercible into a DataFrame) – Should have at least one matching index/column label with the original DataFrame. If a Series is passed, its name attribute must be set, and that will be used as the column name to align with the original DataFrame.

  • join ({'left'}, default 'left') – Only left join is implemented, keeping the index and columns of the original object.

  • overwrite (bool, default True) –

    How to handle non-NA values for overlapping keys:

    • True: overwrite original DataFrame’s values with values from other.

    • False: only update values that are NA in the original DataFrame.

  • filter_func (callable(1d-array) -> bool 1d-array, optional) – Can choose to replace values other than NA. Return True for values that should be updated.

  • errors ({'raise', 'ignore'}, default 'ignore') – If ‘raise’, will raise a ValueError if the DataFrame and other both contain non-NA data in the same place.

Returns:

This method directly changes calling object.

Return type:

None

Raises:
  • ValueError

    • When errors=’raise’ and there’s overlapping non-NA data. * When errors is not either ‘ignore’ or ‘raise’

  • NotImplementedError

    • If join != ‘left’

See also

dict.update

Similar method for dictionaries.

DataFrame.merge

For column(s)-on-column(s) operations.

Notes

  1. Duplicate indices on other are not supported and raises ValueError.

Examples

>>> df = pd.DataFrame({"A": [1, 2, 3], "B": [400, 500, 600]})
>>> new_df = pd.DataFrame({"B": [4, 5, 6], "C": [7, 8, 9]})
>>> df.update(new_df)
>>> df
   A  B
0  1  4
1  2  5
2  3  6

The DataFrame’s length does not increase as a result of the update, only values at matching index/column labels are updated.

>>> df = pd.DataFrame({"A": ["a", "b", "c"], "B": ["x", "y", "z"]})
>>> new_df = pd.DataFrame({"B": ["d", "e", "f", "g", "h", "i"]})
>>> df.update(new_df)
>>> df
   A  B
0  a  d
1  b  e
2  c  f
>>> df = pd.DataFrame({"A": ["a", "b", "c"], "B": ["x", "y", "z"]})
>>> new_df = pd.DataFrame({"B": ["d", "f"]}, index=[0, 2])
>>> df.update(new_df)
>>> df
   A  B
0  a  d
1  b  y
2  c  f

For Series, its name attribute must be set.

>>> df = pd.DataFrame({"A": ["a", "b", "c"], "B": ["x", "y", "z"]})
>>> new_column = pd.Series(["d", "e", "f"], name="B")
>>> df.update(new_column)
>>> df
   A  B
0  a  d
1  b  e
2  c  f

If other contains NaNs the corresponding values are not updated in the original dataframe.

>>> df = pd.DataFrame({"A": [1, 2, 3], "B": [400.0, 500.0, 600.0]})
>>> new_df = pd.DataFrame({"B": [4, np.nan, 6]})
>>> df.update(new_df)
>>> df
   A      B
0  1    4.0
1  2  500.0
2  3    6.0
value_counts(subset=None, normalize=False, sort=True, ascending=False, dropna=True)#

Return a Series containing the frequency of each distinct row in the DataFrame.

Parameters:
  • subset (Hashable or a sequence of the previous, optional) – Columns to use when counting unique combinations.

  • normalize (bool, default False) – Return proportions rather than frequencies.

  • sort (bool, default True) –

    Stable sort by frequencies when True. Preserve the order of the data when False.

    Changed in version 3.0.0: Prior to 3.0.0, sort=False would sort by the columns values.

    Changed in version 3.0.0: Prior to 3.0.0, the sort was unstable.

  • ascending (bool, default False) – Sort in ascending order.

  • dropna (bool, default True) – Do not include counts of rows that contain NA values.

Returns:

Series containing the frequency of each distinct row in the DataFrame.

Return type:

Series

See also

Series.value_counts

Equivalent method on Series.

Notes

The returned Series will have a MultiIndex with one level per input column but an Index (non-multi) for a single label. By default, rows that contain any NA values are omitted from the result. By default, the resulting Series will be sorted by frequencies in descending order so that the first element is the most frequently-occurring row.

Examples

>>> df = pd.DataFrame(
...     {"num_legs": [2, 4, 4, 6], "num_wings": [2, 0, 0, 0]},
...     index=["falcon", "dog", "cat", "ant"],
... )
>>> df
        num_legs  num_wings
falcon         2          2
dog            4          0
cat            4          0
ant            6          0
>>> df.value_counts()
num_legs  num_wings
4         0            2
2         2            1
6         0            1
Name: count, dtype: int64
>>> df.value_counts(sort=False)
num_legs  num_wings
2         2            1
4         0            2
6         0            1
Name: count, dtype: int64
>>> df.value_counts(ascending=True)
num_legs  num_wings
2         2            1
6         0            1
4         0            2
Name: count, dtype: int64
>>> df.value_counts(normalize=True)
num_legs  num_wings
4         0            0.50
2         2            0.25
6         0            0.25
Name: proportion, dtype: float64

With dropna set to False we can also count rows with NA values.

>>> df = pd.DataFrame(
...     {
...         "first_name": ["John", "Anne", "John", "Beth"],
...         "middle_name": ["Smith", pd.NA, pd.NA, "Louise"],
...     }
... )
>>> df
  first_name middle_name
0       John       Smith
1       Anne         NaN
2       John         NaN
3       Beth      Louise
>>> df.value_counts()
first_name  middle_name
John        Smith          1
Beth        Louise         1
Name: count, dtype: int64
>>> df.value_counts(dropna=False)
first_name  middle_name
John        Smith          1
Anne        NaN            1
John        NaN            1
Beth        Louise         1
Name: count, dtype: int64
>>> df.value_counts("first_name")
first_name
John    2
Anne    1
Beth    1
Name: count, dtype: int64
property values: ndarray#

Return a Numpy representation of the DataFrame.

Warning

We recommend using DataFrame.to_numpy() instead.

Only the values in the DataFrame will be returned, the axes labels will be removed.

Returns:

The values of the DataFrame.

Return type:

numpy.ndarray

See also

DataFrame.to_numpy

Recommended alternative to this method.

DataFrame.index

Retrieve the index labels.

DataFrame.columns

Retrieving the column names.

Notes

The dtype will be a lower-common-denominator dtype (implicit upcasting); that is to say if the dtypes (even of numeric types) are mixed, the one that accommodates all will be chosen. Use this with care if you are not dealing with the blocks.

e.g. If the dtypes are float16 and float32, dtype will be upcast to float32. If dtypes are int32 and uint8, dtype will be upcast to int32. By numpy.find_common_type() convention, mixing int64 and uint64 will result in a float64 dtype.

Examples

A DataFrame where all columns are the same type (e.g., int64) results in an array of the same type.

>>> df = pd.DataFrame(
...     {"age": [3, 29], "height": [94, 170], "weight": [31, 115]}
... )
>>> df
   age  height  weight
0    3      94      31
1   29     170     115
>>> df.dtypes
age       int64
height    int64
weight    int64
dtype: object
>>> df.values
array([[  3,  94,  31],
       [ 29, 170, 115]])

A DataFrame with mixed type columns(e.g., str/object, int64, float32) results in an ndarray of the broadest type that accommodates these mixed types (e.g., object).

>>> df2 = pd.DataFrame(
...     [
...         ("parrot", 24.0, "second"),
...         ("lion", 80.5, 1),
...         ("monkey", np.nan, None),
...     ],
...     columns=("name", "max_speed", "rank"),
... )
>>> df2.dtypes
name             str
max_speed    float64
rank          object
dtype: object
>>> df2.values
array([['parrot', 24.0, 'second'],
       ['lion', 80.5, 1],
       ['monkey', nan, None]], dtype=object)
var(*, axis: Axis = 0, skipna: bool = True, ddof: int = 1, numeric_only: bool = False, **kwargs) Series#
var(*, axis: None, skipna: bool = True, ddof: int = 1, numeric_only: bool = False, **kwargs) Any
var(*, axis: Axis | None, skipna: bool = True, ddof: int = 1, numeric_only: bool = False, **kwargs) Series | Any

Return unbiased variance over requested axis.

Normalized by N-1 by default. This can be changed using the ddof argument.

Parameters:
  • axis ({index (0), columns (1)}) –

    For Series this parameter is unused and defaults to 0.

    Warning

    The behavior of DataFrame.var with axis=None is deprecated, in a future version this will reduce over both axes and return a scalar To retain the old behavior, pass axis=0 (or do not pass axis).

  • skipna (bool, default True) – Exclude NA/null values. If an entire row/column is NA, the result will be NA.

  • ddof (int, default 1) – Delta Degrees of Freedom. The divisor used in calculations is N - ddof, where N represents the number of elements.

  • numeric_only (bool, default False) – Include only float, int, boolean columns. Not implemented for Series.

  • **kwargs – Additional keywords passed.

Returns:

Unbiased variance over requested axis.

Return type:

Series or scalaer

See also

numpy.var

Equivalent function in NumPy.

Series.var

Return unbiased variance over Series values.

Series.std

Return standard deviation over Series values.

DataFrame.std

Return standard deviation of the values over the requested axis.

Examples

>>> df = pd.DataFrame(
...     {
...         "person_id": [0, 1, 2, 3],
...         "age": [21, 25, 62, 43],
...         "height": [1.61, 1.87, 1.49, 2.01],
...     }
... ).set_index("person_id")
>>> df
           age  height
person_id
0           21    1.61
1           25    1.87
2           62    1.49
3           43    2.01
>>> df.var()
age       352.916667
height      0.056367
dtype: float64

Alternatively, ddof=0 can be set to normalize by N instead of N-1:

>>> df.var(ddof=0)
age       264.687500
height      0.042275
dtype: float64
pycsamt.api.typing.DataFrameLike#

Object behaving like a pandas DataFrame.

pycsamt.api.typing.Dict#

alias of dict

class pycsamt.api.typing.DType[source]#

Bases: _CompatAlias

Dtype marker kept for legacy annotations.

New code should prefer numpy.typing.DTypeLike or a concrete NumPy dtype annotation.

type pycsamt.api.typing.DTypeLike = type | str | dtype | _SupportsDType[dtype] | _VoidDTypeLike#
class pycsamt.api.typing.EDIO[source]#

Bases: _CompatAlias

Electrical Data Interchange object marker.

pycsamt.api.typing.FloatArray#

NumPy array with floating dtype.

alias of NDArray[floating[Any]]

class pycsamt.api.typing.Generic#

Bases: object

Abstract base class for generic types.

On Python 3.12 and newer, generic classes implicitly inherit from Generic when they declare a parameter list after the class’s name:

class Mapping[KT, VT]:
    def __getitem__(self, key: KT) -> VT:
        ...
    # Etc.

On older versions of Python, however, generic classes have to explicitly inherit from Generic.

After a class has been declared to be generic, it can then be used as follows:

def lookup_name[KT, VT](mapping: Mapping[KT, VT], key: KT, default: VT) -> VT:
    try:
        return mapping[key]
    except KeyError:
        return default
pycsamt.api.typing.IndexLike#

Index selector accepted by array utilities.

alias of int | slice | Sequence[int] | NDArray[Any]

pycsamt.api.typing.IntArray#

NumPy array with integer dtype.

alias of NDArray[integer[Any]]

class pycsamt.api.typing.Iterable#

Bases: object

class pycsamt.api.typing.Iterator#

Bases: Iterable

pycsamt.api.typing.List#

alias of list

class pycsamt.api.typing.Mapping#

Bases: Collection

A Mapping is a generic container for associating key/value pairs.

This class provides concrete generic implementations of all methods except for __getitem__, __iter__, and __len__.

get(k[, d]) D[k] if k in D, else d.  d defaults to None.#
items() a set-like object providing a view on D's items#
keys() a set-like object providing a view on D's keys#
values() an object providing a view on D's values#
class pycsamt.api.typing.MutableMapping#

Bases: Mapping

A MutableMapping is a generic container for associating key/value pairs.

This class provides concrete generic implementations of all methods except for __getitem__, __setitem__, __delitem__, __iter__, and __len__.

clear() None.  Remove all items from D.#
pop(k[, d]) v, remove specified key and return the corresponding value.#

If key is not found, d is returned if given, otherwise KeyError is raised.

popitem() (k, v), remove and return some (key, value) pair#

as a 2-tuple; but raise KeyError if D is empty.

setdefault(k[, d]) D.get(k,d), also set D[k]=d if k not in D#
update([E, ]**F) None.  Update D from mapping/iterable E and F.#

If E present and has a .keys() method, does: for k in E.keys(): D[k] = E[k] If E present and lacks .keys() method, does: for (k, v) in E: D[k] = v In either case, this is followed by: for k, v in F.items(): D[k] = v

class pycsamt.api.typing.NDArray[source]#

Bases: _CompatAlias

NumPy array marker kept for legacy annotations.

New code may use numpy.typing.NDArray directly for stricter dtype annotations.

type pycsamt.api.typing.NumpyArrayLike = Buffer | _DualArrayLike[dtype, complex | bytes | str]#
type pycsamt.api.typing.NumpyNDArray = ndarray[_AnyShape, dtype]#
pycsamt.api.typing.Numeric#

Python or NumPy numeric scalar.

alias of int | float | complex | number

class pycsamt.api.typing.Path(*args, **kwargs)#

Bases: PurePath

PurePath subclass that can make system calls.

Path represents a filesystem path but unlike PurePath, also offers methods to do system calls on path objects. Depending on your system, instantiating a Path will return either a PosixPath or a WindowsPath object. You can also instantiate a PosixPath or WindowsPath directly, but cannot instantiate a WindowsPath on a POSIX system or vice versa.

stat(*, follow_symlinks=True)#

Return the result of the stat() system call on this path, like os.stat() does.

lstat()#

Like stat(), except if the path points to a symlink, the symlink’s status information is returned, rather than its target’s.

exists(*, follow_symlinks=True)#

Whether this path exists.

This method normally follows symlinks; to check whether a symlink exists, add the argument follow_symlinks=False.

is_dir()#

Whether this path is a directory.

is_file()#

Whether this path is a regular file (also True for symlinks pointing to regular files).

is_mount()#

Check if this path is a mount point

Whether this path is a symbolic link.

is_junction()#

Whether this path is a junction.

is_block_device()#

Whether this path is a block device.

is_char_device()#

Whether this path is a character device.

is_fifo()#

Whether this path is a FIFO.

is_socket()#

Whether this path is a socket.

samefile(other_path)#

Return whether other_path is the same or not as this file (as returned by os.path.samefile()).

open(mode='r', buffering=-1, encoding=None, errors=None, newline=None)#

Open the file pointed to by this path and return a file object, as the built-in open() function does.

read_bytes()#

Open the file in bytes mode, read it, and close the file.

read_text(encoding=None, errors=None)#

Open the file in text mode, read it, and close the file.

write_bytes(data)#

Open the file in bytes mode, write to it, and close the file.

write_text(data, encoding=None, errors=None, newline=None)#

Open the file in text mode, write to it, and close the file.

iterdir()#

Yield path objects of the directory contents.

The children are yielded in arbitrary order, and the special entries ‘.’ and ‘..’ are not included.

glob(pattern, *, case_sensitive=None)#

Iterate over this subtree and yield all existing files (of any kind, including directories) matching the given relative pattern.

rglob(pattern, *, case_sensitive=None)#

Recursively yield all existing files (of any kind, including directories) matching the given relative pattern, anywhere in this subtree.

walk(top_down=True, on_error=None, follow_symlinks=False)#

Walk the directory tree from this directory, similar to os.walk().

classmethod cwd()#

Return a new path pointing to the current working directory.

classmethod home()#

Return a new path pointing to the user’s home directory (as returned by os.path.expanduser(‘~’)).

absolute()#

Return an absolute version of this path by prepending the current working directory. No normalization or symlink resolution is performed.

Use resolve() to get the canonical path to a file.

resolve(strict=False)#

Make the path absolute, resolving all symlinks on the way and also normalizing it.

owner()#

Return the login name of the file owner.

group()#

Return the group name of the file gid.

Return the path to which the symbolic link points.

touch(mode=438, exist_ok=True)#

Create this file with the given access mode, if it doesn’t exist.

mkdir(mode=511, parents=False, exist_ok=False)#

Create a new directory at this given path.

chmod(mode, *, follow_symlinks=True)#

Change the permissions of the path, like os.chmod().

lchmod(mode)#

Like chmod(), except if the path points to a symlink, the symlink’s permissions are changed, rather than its target’s.

Remove this file or link. If the path is a directory, use rmdir() instead.

rmdir()#

Remove this directory. The directory must be empty.

rename(target)#

Rename this path to the target path.

The target path may be absolute or relative. Relative paths are interpreted relative to the current working directory, not the directory of the Path object.

Returns the new Path instance pointing to the target path.

replace(target)#

Rename this path to the target path, overwriting if that path exists.

The target path may be absolute or relative. Relative paths are interpreted relative to the current working directory, not the directory of the Path object.

Returns the new Path instance pointing to the target path.

Make this path a symlink pointing to the target path. Note the order of arguments (link, target) is the reverse of os.symlink.

Make this path a hard link pointing to the same file as target.

Note the order of arguments (self, target) is the reverse of os.link’s.

expanduser()#

Return a new path with expanded ~ and ~user constructs (as returned by os.path.expanduser)

pycsamt.api.typing.PathLike#

Path accepted by PyCSAMT readers and writers.

alias of str | bytes | Path | PathLike[str]

class pycsamt.api.typing.Protocol#

Bases: Generic

Base class for protocol classes.

Protocol classes are defined as:

class Proto(Protocol):
    def meth(self) -> int:
        ...

Such classes are primarily used with static type checkers that recognize structural subtyping (static duck-typing).

For example:

class C:
    def meth(self) -> int:
        return 0

def func(x: Proto) -> int:
    return x.meth()

func(C())  # Passes static type check

See PEP 544 for details. Protocol classes decorated with @typing.runtime_checkable act as simple-minded runtime protocols that check only the presence of given attributes, ignoring their type signatures. Protocol classes can be generic, they are defined as:

class GenProto[T](Protocol):
    def meth(self) -> T:
        ...
class pycsamt.api.typing.SP[source]#

Bases: _CompatAlias

Station-position marker for legacy annotations.

pycsamt.api.typing.Scalar#

Common scalar value accepted by lightweight utilities.

alias of str | bytes | int | float | complex | bool

class pycsamt.api.typing.Sequence#

Bases: Reversible, Collection

All the operations on a read-only sequence.

Concrete subclasses must override __new__ or __init__, __getitem__, and __len__.

count(value) integer -- return number of occurrences of value#
index(value[, start[, stop]]) integer -- return first index of value.#

Raises ValueError if the value is not present.

Supporting start and stop arguments is optional, but recommended.

class pycsamt.api.typing.Series(data=None, index=None, dtype=None, name=None, copy=None)[source]#

Bases: IndexOpsMixin, NDFrame

One-dimensional ndarray with axis labels (including time series).

Labels need not be unique but must be a hashable type. The object supports both integer- and label-based indexing and provides a host of methods for performing operations involving the index. Statistical methods from ndarray have been overridden to automatically exclude missing data (currently represented as NaN).

Operations between Series (+, -, /, *, **) align values based on their associated index values– they need not be the same length. The result index will be the sorted union of the two indexes.

Parameters:
  • data (array-like, Iterable, dict, or scalar value) – Contains data stored in Series. If data is a dict, argument order is maintained. Unordered sets are not supported.

  • index (array-like or Index (1d)) – Values must be hashable and have the same length as data. Non-unique index values are allowed. Will default to RangeIndex (0, 1, 2, …, n) if not provided. If data is dict-like and index is None, then the keys in the data are used as the index. If the index is not None, the resulting Series is reindexed with the index values.

  • dtype (str, numpy.dtype, or ExtensionDtype, optional) – Data type for the output Series. If not specified, this will be inferred from data. See the user guide for more usages.

  • name (Hashable, default None) – The name to give to the Series.

  • copy (bool, default None) – Whether to copy input data, only relevant for array, Series, and Index inputs (for other input, e.g. a list, a new array is created anyway). Defaults to True for array input and False for Index/Series. Even when False for Index/Series, a shallow copy of the data is made. Set to False to avoid copying array input at your own risk (if you know the input data won’t be modified elsewhere). Set to True to force copying Series/Index input up front.

See also

DataFrame

Two-dimensional, size-mutable, potentially heterogeneous tabular data.

Index

Immutable sequence used for indexing and alignment.

Notes

Please reference the User Guide for more information.

Examples

Constructing Series from a dictionary with an Index specified

>>> d = {"a": 1, "b": 2, "c": 3}
>>> ser = pd.Series(data=d, index=["a", "b", "c"])
>>> ser
a   1
b   2
c   3
dtype: int64

The keys of the dictionary match with the Index values, hence the Index values have no effect.

>>> d = {"a": 1, "b": 2, "c": 3}
>>> ser = pd.Series(data=d, index=["x", "y", "z"])
>>> ser
x   NaN
y   NaN
z   NaN
dtype: float64

Note that the Index is first built with the keys from the dictionary. After this the Series is reindexed with the given Index values, hence we get all NaN as a result.

Constructing Series from a list with copy=False.

>>> r = [1, 2]
>>> ser = pd.Series(r, copy=False)
>>> ser.iloc[0] = 999
>>> r
[1, 2]
>>> ser
0    999
1      2
dtype: int64

Due to input data type the Series has a copy of the original data even though copy=False, so the data is unchanged.

Constructing Series from a 1d ndarray with copy=False.

>>> r = np.array([1, 2])
>>> ser = pd.Series(r, copy=False)
>>> ser.iloc[0] = 999
>>> r
array([999,   2])
>>> ser
0    999
1      2
dtype: int64

Due to input data type the Series has a view on the original data, so the data is changed as well.

add(other, level=None, fill_value=None, axis=0)#

Return Addition of series and other, element-wise (binary operator add).

Equivalent to series + other, but with support to substitute a fill_value for missing data in either one of the inputs.

Parameters:
  • other (Series or scalar value) – With which to compute the addition.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (None or float value, default None (NaN)) – Fill existing missing (NaN) values, and any new element needed for successful Series alignment, with this value before computation. If data in both corresponding Series locations is missing the result of filling (at that location) will be missing.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

Returns:

The result of the operation.

Return type:

Series

See also

Series.radd

Reverse of the Addition operator, see Python documentation for more details.

Examples

>>> a = pd.Series([1, 1, 1, np.nan], index=["a", "b", "c", "d"])
>>> a
a    1.0
b    1.0
c    1.0
d    NaN
dtype: float64
>>> b = pd.Series([1, np.nan, 1, np.nan], index=["a", "b", "d", "e"])
>>> b
a    1.0
b    NaN
d    1.0
e    NaN
dtype: float64
>>> a.add(b, fill_value=0)
a    2.0
b    1.0
c    1.0
d    1.0
e    NaN
dtype: float64
agg(func=None, axis=0, *args, **kwargs)#

Aggregate using one or more operations over the specified axis.

Parameters:
  • func (function, str, list or dict) –

    Function to use for aggregating the data. If a function, must either work when passed a Series or when passed to Series.apply.

    Accepted combinations are:

    • function

    • string function name

    • list of functions and/or function names, e.g. [np.sum, 'mean']

    • dict of axis labels -> functions, function names or list of such.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

  • *args – Positional arguments to pass to func.

  • **kwargs – Keyword arguments to pass to func.

Returns:

The return can be:

  • scalar : when Series.agg is called with single function

  • Series : when DataFrame.agg is called with a single function

  • DataFrame : when DataFrame.agg is called with several functions

Return type:

scalar, Series or DataFrame

See also

Series.apply

Invoke function on a Series.

Series.transform

Transform function producing a Series with like indexes.

Notes

The aggregation operations are always performed over an axis, either the index (default) or the column axis. This behavior is different from numpy aggregation functions (mean, median, prod, sum, std, var), where the default is to compute the aggregation of the flattened array, e.g., numpy.mean(arr_2d) as opposed to numpy.mean(arr_2d, axis=0).

agg is an alias for aggregate. Use the alias.

Functions that mutate the passed object can produce unexpected behavior or errors and are not supported. See Mutating with User Defined Function (UDF) methods for more details.

A passed user-defined-function will be passed a Series for evaluation.

If func defines an index relabeling, axis must be 0 or index.

Examples

>>> s = pd.Series([1, 2, 3, 4])
>>> s
0    1
1    2
2    3
3    4
dtype: int64
>>> s.agg("min")
1
>>> s.agg(["min", "max"])
min   1
max   4
dtype: int64
aggregate(func=None, axis=0, *args, **kwargs)#

Aggregate using one or more operations over the specified axis.

Parameters:
  • func (function, str, list or dict) –

    Function to use for aggregating the data. If a function, must either work when passed a Series or when passed to Series.apply.

    Accepted combinations are:

    • function

    • string function name

    • list of functions and/or function names, e.g. [np.sum, 'mean']

    • dict of axis labels -> functions, function names or list of such.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

  • *args – Positional arguments to pass to func.

  • **kwargs – Keyword arguments to pass to func.

Returns:

The return can be:

  • scalar : when Series.agg is called with single function

  • Series : when DataFrame.agg is called with a single function

  • DataFrame : when DataFrame.agg is called with several functions

Return type:

scalar, Series or DataFrame

See also

Series.apply

Invoke function on a Series.

Series.transform

Transform function producing a Series with like indexes.

Notes

The aggregation operations are always performed over an axis, either the index (default) or the column axis. This behavior is different from numpy aggregation functions (mean, median, prod, sum, std, var), where the default is to compute the aggregation of the flattened array, e.g., numpy.mean(arr_2d) as opposed to numpy.mean(arr_2d, axis=0).

agg is an alias for aggregate. Use the alias.

Functions that mutate the passed object can produce unexpected behavior or errors and are not supported. See Mutating with User Defined Function (UDF) methods for more details.

A passed user-defined-function will be passed a Series for evaluation.

If func defines an index relabeling, axis must be 0 or index.

Examples

>>> s = pd.Series([1, 2, 3, 4])
>>> s
0    1
1    2
2    3
3    4
dtype: int64
>>> s.agg("min")
1
>>> s.agg(["min", "max"])
min   1
max   4
dtype: int64
all(*, axis=0, bool_only=False, skipna=True, **kwargs)#

Return whether all elements are True, potentially over an axis.

Returns True unless there at least one element within a series or along a Dataframe axis that is False or equivalent (e.g. zero or empty).

Parameters:
  • axis ({0 or 'index', 1 or 'columns', None}, default 0) –

    Indicate which axis or axes should be reduced. For Series this parameter is unused and defaults to 0.

    • 0 / ‘index’ : reduce the index, return a Series whose index is the original column labels.

    • 1 / ‘columns’ : reduce the columns, return a Series whose index is the original index.

    • None : reduce all axes, return a scalar.

  • bool_only (bool, default False) – Include only boolean columns. Not implemented for Series.

  • skipna (bool, default True) – Exclude NA/null values. If the entire row/column is NA and skipna is True, then the result will be True, as for an empty row/column. If skipna is False, then NA are treated as True, because these are not equal to zero.

  • **kwargs (any, default None) – Additional keywords have no effect but might be accepted for compatibility with NumPy.

Returns:

If axis=None, then a scalar boolean is returned. Otherwise a Series is returned with index matching the index argument.

Return type:

Series or scalar

See also

Series.all

Return True if all elements are True.

DataFrame.any

Return True if one (or more) elements are True.

Examples

Series

>>> pd.Series([True, True]).all()
True
>>> pd.Series([True, False]).all()
False
>>> pd.Series([], dtype="float64").all()
True
>>> pd.Series([np.nan]).all()
True
>>> pd.Series([np.nan]).all(skipna=False)
True

DataFrames

Create a DataFrame from a dictionary.

>>> df = pd.DataFrame({"col1": [True, True], "col2": [True, False]})
>>> df
   col1   col2
0  True   True
1  True  False

Default behaviour checks if values in each column all return True.

>>> df.all()
col1     True
col2    False
dtype: bool

Specify axis='columns' to check if values in each row all return True.

>>> df.all(axis="columns")
0     True
1    False
dtype: bool

Or axis=None for whether every value is True.

>>> df.all(axis=None)
False
any(*, axis=0, bool_only=False, skipna=True, **kwargs)#

Return whether any element is True, potentially over an axis.

Returns False unless there is at least one element within a series or along a Dataframe axis that is True or equivalent (e.g. non-zero or non-empty).

Parameters:
  • axis ({0 or 'index', 1 or 'columns', None}, default 0) –

    Indicate which axis or axes should be reduced. For Series this parameter is unused and defaults to 0.

    • 0 / ‘index’ : reduce the index, return a Series whose index is the original column labels.

    • 1 / ‘columns’ : reduce the columns, return a Series whose index is the original index.

    • None : reduce all axes, return a scalar.

  • bool_only (bool, default False) – Include only boolean columns. Not implemented for Series.

  • skipna (bool, default True) – Exclude NA/null values. If the entire row/column is NA and skipna is True, then the result will be False, as for an empty row/column. If skipna is False, then NA are treated as True, because these are not equal to zero.

  • **kwargs (any, default None) – Additional keywords have no effect but might be accepted for compatibility with NumPy.

Returns:

If axis=None, then a scalar boolean is returned. Otherwise a Series is returned with index matching the index argument.

Return type:

Series or scalar

See also

numpy.any

Numpy version of this method.

Series.any

Return whether any element is True.

Series.all

Return whether all elements are True.

DataFrame.any

Return whether any element is True over requested axis.

DataFrame.all

Return whether all elements are True over requested axis.

Examples

Series

For Series input, the output is a scalar indicating whether any element is True.

>>> pd.Series([False, False]).any()
False
>>> pd.Series([True, False]).any()
True
>>> pd.Series([], dtype="float64").any()
False
>>> pd.Series([np.nan]).any()
False
>>> pd.Series([np.nan]).any(skipna=False)
True

DataFrame

Whether each column contains at least one True element (the default).

>>> df = pd.DataFrame({"A": [1, 2], "B": [0, 2], "C": [0, 0]})
>>> df
   A  B  C
0  1  0  0
1  2  2  0
>>> df.any()
A     True
B     True
C    False
dtype: bool

Aggregating over the columns.

>>> df = pd.DataFrame({"A": [True, False], "B": [1, 2]})
>>> df
       A  B
0   True  1
1  False  2
>>> df.any(axis="columns")
0    True
1    True
dtype: bool
>>> df = pd.DataFrame({"A": [True, False], "B": [1, 0]})
>>> df
       A  B
0   True  1
1  False  0
>>> df.any(axis="columns")
0    True
1    False
dtype: bool

Aggregating over the entire DataFrame with axis=None.

>>> df.any(axis=None)
True

any for an empty DataFrame is an empty Series.

>>> pd.DataFrame([]).any()
Series([], dtype: bool)
apply(func, args=(), *, by_row='compat', **kwargs)#

Invoke function on values of Series.

Can be ufunc (a NumPy function that applies to the entire Series) or a Python function that only works on single values.

Parameters:
  • func (function) – Python function or NumPy ufunc to apply.

  • args (tuple) – Positional arguments passed to func after the series value.

  • by_row (False or "compat", default "compat") –

    If "compat" and func is a callable, func will be passed each element of the Series, like Series.map. If func is a list or dict of callables, will first try to translate each func into pandas methods. If that doesn’t work, will try call to apply again with by_row="compat" and if that fails, will call apply again with by_row=False (backward compatible). If False, the func will be passed the whole Series at once.

    by_row has no effect when func is a string.

    Added in version 2.1.0.

  • **kwargs – Additional keyword arguments passed to func.

Returns:

If func returns a Series object the result will be a DataFrame.

Return type:

Series or DataFrame

See also

Series.map

For element-wise operations.

Series.agg

Only perform aggregating type operations.

Series.transform

Only perform transforming type operations.

Notes

Functions that mutate the passed object can produce unexpected behavior or errors and are not supported. See Mutating with User Defined Function (UDF) methods for more details.

Examples

Create a series with typical summer temperatures for each city.

>>> s = pd.Series([20, 21, 12], index=["London", "New York", "Helsinki"])
>>> s
London      20
New York    21
Helsinki    12
dtype: int64

Square the values by defining a function and passing it as an argument to apply().

>>> def square(x):
...     return x**2
>>> s.apply(square)
London      400
New York    441
Helsinki    144
dtype: int64

Square the values by passing an anonymous function as an argument to apply().

>>> s.apply(lambda x: x**2)
London      400
New York    441
Helsinki    144
dtype: int64

Define a custom function that needs additional positional arguments and pass these additional arguments using the args keyword.

>>> def subtract_custom_value(x, custom_value):
...     return x - custom_value
>>> s.apply(subtract_custom_value, args=(5,))
London      15
New York    16
Helsinki     7
dtype: int64

Define a custom function that takes keyword arguments and pass these arguments to apply.

>>> def add_custom_values(x, **kwargs):
...     for month in kwargs:
...         x += kwargs[month]
...     return x
>>> s.apply(add_custom_values, june=30, july=20, august=25)
London      95
New York    96
Helsinki    87
dtype: int64

Use a function from the Numpy library.

>>> s.apply(np.log)
London      2.995732
New York    3.044522
Helsinki    2.484907
dtype: float64
argsort(axis=0, kind='quicksort', order=None, stable=None)#

Return the integer indices that would sort the Series values.

Override ndarray.argsort. Argsorts the value, omitting NA/null values, and places the result in the same locations as the non-NA values.

Parameters:
  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

  • kind ({'mergesort', 'quicksort', 'heapsort', 'stable'}, default 'quicksort') – Choice of sorting algorithm. See numpy.sort() for more information. ‘mergesort’ and ‘stable’ are the only stable algorithms.

  • order (None) – Has no effect but is accepted for compatibility with numpy.

  • stable (None) – Has no effect but is accepted for compatibility with numpy.

Returns:

Positions of values within the sort order with -1 indicating nan values.

Return type:

Series[np.intp]

See also

numpy.ndarray.argsort

Returns the indices that would sort this array.

Examples

>>> s = pd.Series([3, 2, 1])
>>> s.argsort()
0    2
1    1
2    0
dtype: int64
property array: ExtensionArray#

The ExtensionArray of the data backing this Series or Index.

This property provides direct access to the underlying array data of a Series or Index without requiring conversion to a NumPy array. It returns an ExtensionArray, which is the native storage format for pandas extension dtypes.

Returns:

An ExtensionArray of the values stored within. For extension types, this is the actual array. For NumPy native types, this is a thin (no copy) wrapper around numpy.ndarray.

.array differs from .values, which may require converting the data to a different form.

Return type:

ExtensionArray

See also

Index.to_numpy

Similar method that always returns a NumPy array.

Series.to_numpy

Similar method that always returns a NumPy array.

Notes

This table lays out the different array types for each extension dtype within pandas.

dtype

array type

category

Categorical

period

PeriodArray

interval

IntervalArray

IntegerNA

IntegerArray

string

StringArray

boolean

BooleanArray

datetime64[ns, tz]

DatetimeArray

For any 3rd-party extension types, the array type will be an ExtensionArray.

For all remaining dtypes .array will be a arrays.NumpyExtensionArray wrapping the actual ndarray stored within. If you absolutely need a NumPy array (possibly with copying / coercing data), then use Series.to_numpy() instead.

Examples

For regular NumPy types like int, and float, a NumpyExtensionArray is returned.

>>> pd.Series([1, 2, 3]).array
<NumpyExtensionArray>
[1, 2, 3]
Length: 3, dtype: int64

For extension types, like Categorical, the actual ExtensionArray is returned

>>> ser = pd.Series(pd.Categorical(["a", "b", "a"]))
>>> ser.array
['a', 'b', 'a']
Categories (2, str): ['a', 'b']
autocorr(lag=1)#

Compute the lag-N autocorrelation.

This method computes the Pearson correlation between the Series and its shifted self.

Parameters:

lag (int, default 1) – Number of lags to apply before performing autocorrelation.

Returns:

The Pearson correlation between self and self.shift(lag).

Return type:

float

See also

Series.corr

Compute the correlation between two Series.

Series.shift

Shift index by desired number of periods.

DataFrame.corr

Compute pairwise correlation of columns.

DataFrame.corrwith

Compute pairwise correlation between rows or columns of two DataFrame objects.

Notes

If the Pearson correlation is not well defined return ‘NaN’.

Examples

>>> s = pd.Series([0.25, 0.5, 0.2, -0.05])
>>> s.autocorr()
0.10355...
>>> s.autocorr(lag=2)
-0.99999...

If the Pearson correlation is not well defined, then ‘NaN’ is returned.

>>> s = pd.Series([1, 0, 0, 0])
>>> s.autocorr()
nan
property axes: list[Index]#

Return a list of the row axis labels.

between(left, right, inclusive='both')#

Return boolean Series equivalent to left <= series <= right.

This function returns a boolean vector containing True wherever the corresponding Series element is between the boundary values left and right. NA values are treated as False.

Parameters:
  • left (scalar or list-like) – Left boundary.

  • right (scalar or list-like) – Right boundary.

  • inclusive ({"both", "neither", "left", "right"}) – Include boundaries. Whether to set each bound as closed or open.

Returns:

Series representing whether each element is between left and right (inclusive).

Return type:

Series

See also

Series.gt

Greater than of series and other.

Series.lt

Less than of series and other.

Notes

This function is equivalent to (left <= ser) & (ser <= right)

Examples

>>> s = pd.Series([2, 0, 4, 8, np.nan])

Boundary values are included by default:

>>> s.between(1, 4)
0     True
1    False
2     True
3    False
4    False
dtype: bool

With inclusive set to "neither" boundary values are excluded:

>>> s.between(1, 4, inclusive="neither")
0     True
1    False
2    False
3    False
4    False
dtype: bool

left and right can be any scalar value:

>>> s = pd.Series(["Alice", "Bob", "Carol", "Eve"])
>>> s.between("Anna", "Daniel")
0    False
1     True
2     True
3    False
dtype: bool
case_when(caselist)#

Replace values where the conditions are True.

Added in version 2.2.0.

Parameters:

caselist (A list of tuples of conditions and expected replacements) – Takes the form: (condition0, replacement0), (condition1, replacement1), … . condition should be a 1-D boolean array-like object or a callable. If condition is a callable, it is computed on the Series and should return a boolean Series or array. The callable must not change the input Series (though pandas doesn`t check it). replacement should be a 1-D array-like object, a scalar or a callable. If replacement is a callable, it is computed on the Series and should return a scalar or Series. The callable must not change the input Series (though pandas doesn`t check it).

Returns:

A new Series with values replaced based on the provided conditions.

Return type:

Series

See also

Series.mask

Replace values where the condition is True.

Examples

>>> c = pd.Series([6, 7, 8, 9], name="c")
>>> a = pd.Series([0, 0, 1, 2])
>>> b = pd.Series([0, 3, 4, 5])
>>> c.case_when(
...     caselist=[
...         (a.gt(0), a),  # condition, replacement
...         (b.gt(0), b),
...     ]
... )
0    6
1    3
2    1
3    2
Name: c, dtype: int64
cat#

alias of CategoricalAccessor

combine(other, func, fill_value=None)#

Combine the Series with a Series or scalar according to func.

Combine the Series and other using func to perform elementwise selection for combined Series. fill_value is assumed when value is not present at some index from one of the two Series being combined.

Parameters:
  • other (Series or scalar) – The value(s) to be combined with the Series.

  • func (function) – Function that takes two scalars as inputs and returns an element.

  • fill_value (scalar, optional) – The value to assume when an index is missing from one Series or the other. The default specifies to use the appropriate NaN value for the underlying dtype of the Series.

Returns:

The result of combining the Series with the other object.

Return type:

Series

See also

Series.combine_first

Combine Series values, choosing the calling Series’ values first.

Examples

Consider 2 Datasets s1 and s2 containing highest clocked speeds of different birds.

>>> s1 = pd.Series({"falcon": 330.0, "eagle": 160.0})
>>> s1
falcon    330.0
eagle     160.0
dtype: float64
>>> s2 = pd.Series({"falcon": 345.0, "eagle": 200.0, "duck": 30.0})
>>> s2
falcon    345.0
eagle     200.0
duck       30.0
dtype: float64

Now, to combine the two datasets and view the highest speeds of the birds across the two datasets

>>> s1.combine(s2, max)
duck        NaN
eagle     200.0
falcon    345.0
dtype: float64

In the previous example, the resulting value for duck is missing, because the maximum of a NaN and a float is a NaN. So, in the example, we set fill_value=0, so the maximum value returned will be the value from some dataset.

>>> s1.combine(s2, max, fill_value=0)
duck       30.0
eagle     200.0
falcon    345.0
dtype: float64
combine_first(other)#

Update null elements with value in the same location in ‘other’.

Combine two Series objects by filling null values in one Series with non-null values from the other Series. Result index will be the union of the two indexes.

Parameters:

other (Series) – The value(s) to be used for filling null values.

Returns:

The result of combining the provided Series with the other object.

Return type:

Series

See also

Series.combine

Perform element-wise operation on two Series using a given function.

Examples

>>> s1 = pd.Series([1, np.nan])
>>> s2 = pd.Series([3, 4, 5])
>>> s1.combine_first(s2)
0    1.0
1    4.0
2    5.0
dtype: float64

Null values still persist if the location of that null value does not exist in other

>>> s1 = pd.Series({"falcon": np.nan, "eagle": 160.0})
>>> s2 = pd.Series({"eagle": 200.0, "duck": 30.0})
>>> s1.combine_first(s2)
duck       30.0
eagle     160.0
falcon      NaN
dtype: float64
compare(other, align_axis=1, keep_shape=False, keep_equal=False, result_names=('self', 'other'))#

Compare to another Series and show the differences.

Parameters:
  • other (Series) – Object to compare with.

  • align_axis ({0 or 'index', 1 or 'columns'}, default 1) –

    Determine which axis to align the comparison on.

    • 0, or ‘index’ : Resulting differences are stacked vertically with rows drawn alternately from self and other.

    • 1, or ‘columns’ : Resulting differences are aligned horizontally with columns drawn alternately from self and other.

  • keep_shape (bool, default False) – If true, all rows and columns are kept. Otherwise, only the ones with different values are kept.

  • keep_equal (bool, default False) – If true, the result keeps values that are equal. Otherwise, equal values are shown as NaNs.

  • result_names (tuple, default ('self', 'other')) – Set the dataframes names in the comparison.

Returns:

If axis is 0 or ‘index’ the result will be a Series. The resulting index will be a MultiIndex with ‘self’ and ‘other’ stacked alternately at the inner level.

If axis is 1 or ‘columns’ the result will be a DataFrame. It will have two columns namely ‘self’ and ‘other’.

Return type:

Series or DataFrame

See also

DataFrame.compare

Compare with another DataFrame and show differences.

Notes

Matching NaNs will not appear as a difference.

Examples

>>> s1 = pd.Series(["a", "b", "c", "d", "e"])
>>> s2 = pd.Series(["a", "a", "c", "b", "e"])

Align the differences on columns

>>> s1.compare(s2)
  self other
1    b     a
3    d     b

Stack the differences on indices

>>> s1.compare(s2, align_axis=0)
1  self     b
   other    a
3  self     d
   other    b
dtype: str

Keep all original rows

>>> s1.compare(s2, keep_shape=True)
  self other
0  NaN   NaN
1    b     a
2  NaN   NaN
3    d     b
4  NaN   NaN

Keep all original rows and also all original values

>>> s1.compare(s2, keep_shape=True, keep_equal=True)
  self other
0    a     a
1    b     a
2    c     c
3    d     b
4    e     e
corr(other, method='pearson', min_periods=None)#

Compute correlation with other Series, excluding missing values.

The two Series objects are not required to be the same length and will be aligned internally before the correlation function is applied.

Parameters:
  • other (Series) – Series with which to compute the correlation.

  • method ({'pearson', 'kendall', 'spearman'} or callable) –

    Method used to compute correlation:

    • pearson : Standard correlation coefficient

    • kendall : Kendall Tau correlation coefficient

    • spearman : Spearman rank correlation

    • callable: Callable with input two 1d ndarrays and returning a float.

    Warning

    Note that the returned matrix from corr will have 1 along the diagonals and will be symmetric regardless of the callable’s behavior.

  • min_periods (int, optional) – Minimum number of observations needed to have a valid result.

Returns:

Correlation with other.

Return type:

float

See also

DataFrame.corr

Compute pairwise correlation between columns.

DataFrame.corrwith

Compute pairwise correlation with another DataFrame or Series.

Notes

Pearson, Kendall and Spearman correlation are currently computed using pairwise complete observations.

Automatic data alignment: as with all pandas operations, automatic data alignment is performed for this method. corr() automatically considers values with matching indices.

Examples

>>> def histogram_intersection(a, b):
...     v = np.minimum(a, b).sum().round(decimals=1)
...     return v
>>> s1 = pd.Series([0.2, 0.0, 0.6, 0.2])
>>> s2 = pd.Series([0.3, 0.6, 0.0, 0.1])
>>> s1.corr(s2, method=histogram_intersection)
0.3

Pandas auto-aligns the values with matching indices

>>> s1 = pd.Series([1, 2, 3], index=[0, 1, 2])
>>> s2 = pd.Series([1, 2, 3], index=[2, 1, 0])
>>> s1.corr(s2)
-1.0

If the input is a constant array, the correlation is not defined in this case, and np.nan is returned.

>>> s1 = pd.Series([0.45, 0.45])
>>> s1.corr(s1)
nan
count()#

Return number of non-NA/null observations in the Series.

Returns:

Number of non-null values in the Series.

Return type:

int

See also

DataFrame.count

Count non-NA cells for each column or row.

Examples

>>> s = pd.Series([0.0, 1.0, np.nan])
>>> s.count()
2
cov(other, min_periods=None, ddof=1)#

Compute covariance with Series, excluding missing values.

The two Series objects are not required to be the same length and will be aligned internally before the covariance is calculated.

Parameters:
  • other (Series) – Series with which to compute the covariance.

  • min_periods (int, optional) – Minimum number of observations needed to have a valid result.

  • ddof (int, default 1) – Delta degrees of freedom. The divisor used in calculations is N - ddof, where N represents the number of elements.

Returns:

Covariance between Series and other normalized by N-1 (unbiased estimator).

Return type:

float

See also

DataFrame.cov

Compute pairwise covariance of columns.

Examples

>>> s1 = pd.Series([0.90010907, 0.13484424, 0.62036035])
>>> s2 = pd.Series([0.12528585, 0.26962463, 0.51111198])
>>> s1.cov(s2)
-0.01685762652715874
cummax(axis=0, skipna=True, *args, **kwargs)#

Return cumulative maximum over a Series.

Returns a Series of the same size containing the cumulative maximum.

Parameters:
  • axis ({0 or 'index'}, default 0) – This parameter is unused and defaults to 0.

  • skipna (bool, default True) – Exclude NA/null values. If the series is NA, the result is NA.

  • *args – Additional keywords have no effect but might be accepted for compatibility with NumPy.

  • **kwargs – Additional keywords have no effect but might be accepted for compatibility with NumPy.

Returns:

Return cumulative maximum of Series.

Return type:

Series

See also

core.window.expanding.Expanding.max

Similar functionality but ignores NaN values.

Series.max

Return the maximum over a Series.

Series.cummin

Return cumulative minimum.

Series.cumsum

Return cumulative sum.

Series.cumprod

Return cumulative product.

Examples

>>> s = pd.Series([2, np.nan, 5, -1, 0])
>>> s
0    2.0
1    NaN
2    5.0
3   -1.0
4    0.0
dtype: float64

By default, NA values are ignored.

>>> s.cummax()
0    2.0
1    NaN
2    5.0
3    5.0
4    5.0
dtype: float64

To include NA values in the operation, use skipna=False

>>> s.cummax(skipna=False)
0    2.0
1    NaN
2    NaN
3    NaN
4    NaN
dtype: float64
cummin(axis=0, skipna=True, *args, **kwargs)#

Return cumulative minimum over a Series.

Returns a Series of the same size containing the cumulative minimum.

Parameters:
  • axis ({0 or 'index'}, default 0) – This parameter is unused and defaults to 0.

  • skipna (bool, default True) – If the entire series is NA, the result will be NA.

  • *args – Additional keywords have no effect but might be accepted for compatibility with NumPy.

  • **kwargs – Additional keywords have no effect but might be accepted for compatibility with NumPy.

Returns:

Return cumulative minimum of the Series.

Return type:

Series

See also

core.window.expanding.Expanding.min

Similar functionality but ignores NaN values.

Series.min

Return the minimum value of the Series.

Series.cummax

Return cumulative maximum.

Series.cumsum

Return cumulative sum.

Series.cumprod

Return cumulative product.

Examples

>>> s = pd.Series([2, np.nan, 5, -1, 0])
>>> s
0    2.0
1    NaN
2    5.0
3   -1.0
4    0.0
dtype: float64

By default, NA values are ignored.

>>> s.cummin()
0    2.0
1    NaN
2    2.0
3   -1.0
4   -1.0
dtype: float64

To include NA values in the operation, use skipna=False

>>> s.cummin(skipna=False)
0    2.0
1    NaN
2    NaN
3    NaN
4    NaN
dtype: float64
cumprod(axis=0, skipna=True, *args, **kwargs)#

Return cumulative product over a Series.

Returns a Series of the same size containing the cumulative product.

Parameters:
  • axis ({0 or 'index'}, default 0) – This parameter is unused and defaults to 0.

  • skipna (bool, default True) – Exclude NA/null values. If entire Series is NA, the result will be NA.

  • *args – Additional keywords have no effect but might be accepted for compatibility with NumPy.

  • **kwargs – Additional keywords have no effect but might be accepted for compatibility with NumPy.

Returns:

Return cumulative product of Series.

Return type:

Series

See also

core.window.expanding.Expanding.prod

Similar functionality but ignores NaN values.

Series.prod

Return the product over Series.

Series.cummax

Return cumulative maximum.

Series.cummin

Return cumulative minimum.

Series.cumsum

Return cumulative sum.

Examples

>>> s = pd.Series([2, np.nan, 5, -1, 0])
>>> s
0    2.0
1    NaN
2    5.0
3   -1.0
4    0.0
dtype: float64

By default, NA values are ignored.

>>> s.cumprod()
0     2.0
1     NaN
2    10.0
3   -10.0
4    -0.0
dtype: float64

To include NA values in the operation, use skipna=False

>>> s.cumprod(skipna=False)
0    2.0
1    NaN
2    NaN
3    NaN
4    NaN
dtype: float64
cumsum(axis=0, skipna=True, *args, **kwargs)#

Return cumulative sum over a Series.

Returns a Series of the same size containing the cumulative sum.

Parameters:
  • axis ({0 or 'index'}, default 0) – This parameter is unused and defaults to 0.

  • skipna (bool, default True) – Exclude NA/null values. If entire series is NA, the result will be NA.

  • *args – Additional keywords have no effect but might be accepted for compatibility with NumPy.

  • **kwargs – Additional keywords have no effect but might be accepted for compatibility with NumPy.

Returns:

Return cumulative sum of Series.

Return type:

Series

See also

core.window.expanding.Expanding.sum

Similar functionality but ignores NaN values.

Series.sum

Return the sum over Series.

Series.cummax

Return cumulative maximum.

Series.cummin

Return cumulative minimum.

Series.cumprod

Return cumulative product.

Examples

>>> s = pd.Series([2, np.nan, 5, -1, 0])
>>> s
0    2.0
1    NaN
2    5.0
3   -1.0
4    0.0
dtype: float64

By default, NA values are ignored.

>>> s.cumsum()
0    2.0
1    NaN
2    7.0
3    6.0
4    6.0
dtype: float64

To include NA values in the operation, use skipna=False

>>> s.cumsum(skipna=False)
0    2.0
1    NaN
2    NaN
3    NaN
4    NaN
dtype: float64
diff(periods=1)#

First discrete difference of Series elements.

Calculates the difference of a Series element compared with another element in the Series (default is element in previous row).

Parameters:

periods (int, default 1) – Periods to shift for calculating difference, accepts negative values.

Returns:

First differences of the Series.

Return type:

Series

See also

Series.pct_change

Percent change over given number of periods.

Series.shift

Shift index by desired number of periods with an optional time freq.

DataFrame.diff

First discrete difference of object.

Notes

For boolean dtypes, this uses operator.xor() rather than operator.sub(). The result is calculated according to current dtype in Series, however dtype of the result is always float64.

Examples

Difference with previous row

>>> s = pd.Series([1, 1, 2, 3, 5, 8])
>>> s.diff()
0    NaN
1    0.0
2    1.0
3    1.0
4    2.0
5    3.0
dtype: float64

Difference with 3rd previous row

>>> s.diff(periods=3)
0    NaN
1    NaN
2    NaN
3    2.0
4    4.0
5    6.0
dtype: float64

Difference with following row

>>> s.diff(periods=-1)
0    0.0
1   -1.0
2   -1.0
3   -2.0
4   -3.0
5    NaN
dtype: float64

Overflow in input dtype

>>> s = pd.Series([1, 0], dtype=np.uint8)
>>> s.diff()
0      NaN
1    255.0
dtype: float64
div(other, level=None, fill_value=None, axis=0)#

Return Floating division of series and other, element-wise (binary operator truediv).

Equivalent to series / other, but with support to substitute a fill_value for missing data in either one of the inputs.

Parameters:
  • other (Series or scalar value) – Series with which to compute division.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (None or float value, default None (NaN)) – Fill existing missing (NaN) values, and any new element needed for successful Series alignment, with this value before computation. If data in both corresponding Series locations is missing the result of filling (at that location) will be missing.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

Returns:

The result of the operation.

Return type:

Series

See also

Series.rtruediv

Reverse of the Floating division operator, see Python documentation for more details.

Examples

>>> a = pd.Series([1, 1, 1, np.nan], index=["a", "b", "c", "d"])
>>> a
a    1.0
b    1.0
c    1.0
d    NaN
dtype: float64
>>> b = pd.Series([1, np.nan, 1, np.nan], index=["a", "b", "d", "e"])
>>> b
a    1.0
b    NaN
d    1.0
e    NaN
dtype: float64
>>> a.divide(b, fill_value=0)
a    1.0
b    inf
c    inf
d    0.0
e    NaN
dtype: float64
divide(other, level=None, fill_value=None, axis=0)#

Return Floating division of series and other, element-wise (binary operator truediv).

Equivalent to series / other, but with support to substitute a fill_value for missing data in either one of the inputs.

Parameters:
  • other (Series or scalar value) – Series with which to compute division.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (None or float value, default None (NaN)) – Fill existing missing (NaN) values, and any new element needed for successful Series alignment, with this value before computation. If data in both corresponding Series locations is missing the result of filling (at that location) will be missing.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

Returns:

The result of the operation.

Return type:

Series

See also

Series.rtruediv

Reverse of the Floating division operator, see Python documentation for more details.

Examples

>>> a = pd.Series([1, 1, 1, np.nan], index=["a", "b", "c", "d"])
>>> a
a    1.0
b    1.0
c    1.0
d    NaN
dtype: float64
>>> b = pd.Series([1, np.nan, 1, np.nan], index=["a", "b", "d", "e"])
>>> b
a    1.0
b    NaN
d    1.0
e    NaN
dtype: float64
>>> a.divide(b, fill_value=0)
a    1.0
b    inf
c    inf
d    0.0
e    NaN
dtype: float64
divmod(other, level=None, fill_value=None, axis=0)#

Return Integer division and modulo of series and other, element-wise (binary operator divmod).

Equivalent to divmod(series, other), but with support to substitute a fill_value for missing data in either one of the inputs.

Parameters:
  • other (object) – When a Series is provided, will align on indexes. For all other types, will behave the same as == but with possibly different results due to the other arguments.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (None or float value, default None (NaN)) – Fill existing missing (NaN) values, and any new element needed for successful Series alignment, with this value before computation. If data in both corresponding Series locations is missing the result of filling (at that location) will be missing.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

Returns:

The result of the operation.

Return type:

2-Tuple of Series

See also

Series.rdivmod

Reverse of the Integer division and modulo operator, see Python documentation for more details.

Examples

>>> a = pd.Series([1, 1, 1, np.nan], index=['a', 'b', 'c', 'd'])
>>> a
a    1.0
b    1.0
c    1.0
d    NaN
dtype: float64
>>> b = pd.Series([1, np.nan, 1, np.nan], index=['a', 'b', 'd', 'e'])
>>> b
a    1.0
b    NaN
d    1.0
e    NaN
dtype: float64
>>> a.divmod(b, fill_value=0)
(a    1.0
 b    inf
 c    inf
 d    0.0
 e    NaN
 dtype: float64,
 a    0.0
 b    NaN
 c    NaN
 d    0.0
 e    NaN
 dtype: float64)
dot(other)#

Compute the dot product between the Series and the columns of other.

This method computes the dot product between the Series and another one, or the Series and each columns of a DataFrame, or the Series and each columns of an array.

It can also be called using self @ other.

Parameters:

other (Series, DataFrame or array-like) – The other object to compute the dot product with its columns.

Returns:

Return the dot product of the Series and other if other is a Series, the Series of the dot product of Series and each rows of other if other is a DataFrame or a numpy.ndarray between the Series and each columns of the numpy array.

Return type:

scalar, Series or numpy.ndarray

See also

DataFrame.dot

Compute the matrix product with the DataFrame.

Series.mul

Multiplication of series and other, element-wise.

Notes

The Series and other has to share the same index if other is a Series or a DataFrame.

Examples

>>> s = pd.Series([0, 1, 2, 3])
>>> other = pd.Series([-1, 2, -3, 4])
>>> s.dot(other)
8
>>> s @ other
8
>>> df = pd.DataFrame([[0, 1], [-2, 3], [4, -5], [6, 7]])
>>> s.dot(df)
0    24
1    14
dtype: int64
>>> arr = np.array([[0, 1], [-2, 3], [4, -5], [6, 7]])
>>> s.dot(arr)
array([24, 14])
drop(labels: IndexLabel | ListLike = None, *, axis: Axis = 0, index: IndexLabel | ListLike = None, columns: IndexLabel | ListLike = None, level: Level | None = None, inplace: Literal[True], errors: IgnoreRaise = 'raise') None#
drop(labels: IndexLabel | ListLike = None, *, axis: Axis = 0, index: IndexLabel | ListLike = None, columns: IndexLabel | ListLike = None, level: Level | None = None, inplace: Literal[False] = False, errors: IgnoreRaise = 'raise') Series
drop(labels: IndexLabel | ListLike = None, *, axis: Axis = 0, index: IndexLabel | ListLike = None, columns: IndexLabel | ListLike = None, level: Level | None = None, inplace: bool = False, errors: IgnoreRaise = 'raise') Series | None

Return Series with specified index labels removed.

Remove elements of a Series based on specifying the index labels. When using a multi-index, labels on different levels can be removed by specifying the level.

Parameters:
  • labels (single label or list-like) – Index labels to drop.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

  • index (single label or list-like) – Redundant for application on Series, but ‘index’ can be used instead of ‘labels’.

  • columns (single label or list-like) – No change is made to the Series; use ‘index’ or ‘labels’ instead.

  • level (int or level name, optional) – For MultiIndex, level for which the labels will be removed.

  • inplace (bool, default False) – If True, do operation inplace and return None.

  • errors ({'ignore', 'raise'}, default 'raise') – If ‘ignore’, suppress error and only existing labels are dropped.

Returns:

Series with specified index labels removed or None if inplace=True.

Return type:

Series or None

Raises:

KeyError – If none of the labels are found in the index.

See also

Series.reindex

Return only specified index labels of Series.

Series.dropna

Return series without null values.

Series.drop_duplicates

Return Series with duplicate values removed.

DataFrame.drop

Drop specified labels from rows or columns.

Examples

>>> s = pd.Series(data=np.arange(3), index=["A", "B", "C"])
>>> s
A  0
B  1
C  2
dtype: int64

Drop labels B and C

>>> s.drop(labels=["B", "C"])
A  0
dtype: int64

Drop 2nd level label in MultiIndex Series

>>> midx = pd.MultiIndex(
...     levels=[["llama", "cow", "falcon"], ["speed", "weight", "length"]],
...     codes=[[0, 0, 0, 1, 1, 1, 2, 2, 2], [0, 1, 2, 0, 1, 2, 0, 1, 2]],
... )
>>> s = pd.Series([45, 200, 1.2, 30, 250, 1.5, 320, 1, 0.3], index=midx)
>>> s
llama   speed      45.0
        weight    200.0
        length      1.2
cow     speed      30.0
        weight    250.0
        length      1.5
falcon  speed     320.0
        weight      1.0
        length      0.3
dtype: float64
>>> s.drop(labels="weight", level=1)
llama   speed      45.0
        length      1.2
cow     speed      30.0
        length      1.5
falcon  speed     320.0
        length      0.3
dtype: float64
drop_duplicates(*, keep: DropKeep = 'first', inplace: Literal[False] = False, ignore_index: bool = False) Series#
drop_duplicates(*, keep: DropKeep = 'first', inplace: Literal[True], ignore_index: bool = False) None
drop_duplicates(*, keep: DropKeep = 'first', inplace: bool = False, ignore_index: bool = False) Series | None

Return Series with duplicate values removed.

Parameters:
  • keep ({‘first’, ‘last’, False}, default ‘first’) –

    Method to handle dropping duplicates:

    • ’first’ : Drop duplicates except for the first occurrence.

    • ’last’ : Drop duplicates except for the last occurrence.

    • False : Drop all duplicates.

  • inplace (bool, default False) – If True, performs operation inplace and returns None.

  • ignore_index (bool, default False) –

    If True, the resulting axis will be labeled 0, 1, …, n - 1.

    Added in version 2.0.0.

Returns:

Series with duplicates dropped or None if inplace=True.

Return type:

Series or None

See also

Index.drop_duplicates

Equivalent method on Index.

DataFrame.drop_duplicates

Equivalent method on DataFrame.

Series.duplicated

Related method on Series, indicating duplicate Series values.

Series.unique

Return unique values as an array.

Examples

Generate a Series with duplicated entries.

>>> s = pd.Series(
...     ["llama", "cow", "llama", "beetle", "llama", "hippo"], name="animal"
... )
>>> s
0     llama
1       cow
2     llama
3    beetle
4     llama
5     hippo
Name: animal, dtype: str

With the ‘keep’ parameter, the selection behavior of duplicated values can be changed. The value ‘first’ keeps the first occurrence for each set of duplicated entries. The default value of keep is ‘first’.

>>> s.drop_duplicates()
0     llama
1       cow
3    beetle
5     hippo
Name: animal, dtype: str

The value ‘last’ for parameter ‘keep’ keeps the last occurrence for each set of duplicated entries.

>>> s.drop_duplicates(keep="last")
1       cow
3    beetle
4     llama
5     hippo
Name: animal, dtype: str

The value False for parameter ‘keep’ discards all sets of duplicated entries.

>>> s.drop_duplicates(keep=False)
1       cow
3    beetle
5     hippo
Name: animal, dtype: str
dropna(*, axis: Axis = 0, inplace: Literal[False] = False, how: AnyAll | None = None, ignore_index: bool = False) Series#
dropna(*, axis: Axis = 0, inplace: Literal[True], how: AnyAll | None = None, ignore_index: bool = False) None

Return a new Series with missing values removed.

See the User Guide for more on which values are considered missing, and how to work with missing data.

Parameters:
  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

  • inplace (bool, default False) – If True, do operation inplace and return None.

  • how (str, optional) – Not in use. Kept for compatibility.

  • ignore_index (bool, default False) –

    If True, the resulting axis will be labeled 0, 1, …, n - 1.

    Added in version 2.0.0.

Returns:

Series with NA entries dropped from it or None if inplace=True.

Return type:

Series or None

See also

Series.isna

Indicate missing values.

Series.notna

Indicate existing (non-missing) values.

Series.fillna

Replace missing values.

DataFrame.dropna

Drop rows or columns which contain NA values.

Index.dropna

Drop missing indices.

Examples

>>> ser = pd.Series([1.0, 2.0, np.nan])
>>> ser
0    1.0
1    2.0
2    NaN
dtype: float64

Drop NA values from a Series.

>>> ser.dropna()
0    1.0
1    2.0
dtype: float64

Empty strings are not considered NA values. None is considered an NA value.

>>> ser = pd.Series([np.nan, 2, pd.NaT, "", None, "I stay"])
>>> ser
0       NaN
1         2
2       NaT
3
4      None
5    I stay
dtype: object
>>> ser.dropna()
1         2
3
5    I stay
dtype: object
dt#

alias of CombinedDatetimelikeProperties

property dtype: DtypeObj#

Return the dtype object of the underlying data.

See also

Series.dtypes

Return the dtype object of the underlying data.

Series.astype

Cast a pandas object to a specified dtype dtype.

Series.convert_dtypes

Convert columns to the best possible dtypes using dtypes supporting pd.NA.

Examples

>>> s = pd.Series([1, 2, 3])
>>> s.dtype
dtype('int64')
property dtypes: DtypeObj#

Return the dtype object of the underlying data.

See also

DataFrame.dtypes

Return the dtypes in the DataFrame.

Examples

>>> s = pd.Series([1, 2, 3])
>>> s.dtypes
dtype('int64')
duplicated(keep='first')#

Indicate duplicate Series values.

Duplicated values are indicated as True values in the resulting Series. Either all duplicates, all except the first or all except the last occurrence of duplicates can be indicated.

Parameters:

keep ({'first', 'last', False}, default 'first') –

Method to handle dropping duplicates:

  • ’first’ : Mark duplicates as True except for the first occurrence.

  • ’last’ : Mark duplicates as True except for the last occurrence.

  • False : Mark all duplicates as True.

Returns:

Series indicating whether each value has occurred in the preceding values.

Return type:

Series[bool]

See also

Index.duplicated

Equivalent method on pandas.Index.

DataFrame.duplicated

Equivalent method on pandas.DataFrame.

Series.drop_duplicates

Remove duplicate values from Series.

Examples

By default, for each set of duplicated values, the first occurrence is set on False and all others on True:

>>> animals = pd.Series(["llama", "cow", "llama", "beetle", "llama"])
>>> animals.duplicated()
0    False
1    False
2     True
3    False
4     True
dtype: bool

which is equivalent to

>>> animals.duplicated(keep="first")
0    False
1    False
2     True
3    False
4     True
dtype: bool

By using ‘last’, the last occurrence of each set of duplicated values is set on False and all others on True:

>>> animals.duplicated(keep="last")
0     True
1    False
2     True
3    False
4    False
dtype: bool

By setting keep on False, all duplicates are True:

>>> animals.duplicated(keep=False)
0     True
1    False
2     True
3    False
4     True
dtype: bool
eq(other, level=None, fill_value=None, axis=0)#

Return Equal to of series and other, element-wise (binary operator eq).

Equivalent to series == other, but with support to substitute a fill_value for missing data in either one of the inputs.

Parameters:
  • other (object) – When a Series is provided, will align on indexes. For all other types, will behave the same as == but with possibly different results due to the other arguments.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (None or float value, default None (NaN)) – Fill existing missing (NaN) values, and any new element needed for successful Series alignment, with this value before computation. If data in both corresponding Series locations is missing the result of filling (at that location) will be missing.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

Returns:

The result of the operation.

Return type:

Series

See also

Series.ge

Return elementwise Greater than or equal to of series and other.

Series.le

Return elementwise Less than or equal to of series and other.

Series.gt

Return elementwise Greater than of series and other.

Series.lt

Return elementwise Less than of series and other.

Examples

>>> a = pd.Series([1, 1, 1, np.nan], index=["a", "b", "c", "d"])
>>> a
a    1.0
b    1.0
c    1.0
d    NaN
dtype: float64
>>> b = pd.Series([1, np.nan, 1, np.nan], index=["a", "b", "d", "e"])
>>> b
a    1.0
b    NaN
d    1.0
e    NaN
dtype: float64
>>> a.eq(b, fill_value=0)
a     True
b    False
c    False
d    False
e    False
dtype: bool
explode(ignore_index=False)#

Transform each element of a list-like to a row.

Parameters:

ignore_index (bool, default False) – If True, the resulting index will be labeled 0, 1, …, n - 1.

Returns:

Exploded lists to rows; index will be duplicated for these rows.

Return type:

Series

See also

Series.str.split

Split string values on specified separator.

Series.unstack

Unstack, a.k.a. pivot, Series with MultiIndex to produce DataFrame.

DataFrame.melt

Unpivot a DataFrame from wide format to long format.

DataFrame.explode

Explode a DataFrame from list-like columns to long format.

Notes

This routine will explode list-likes including lists, tuples, sets, Series, and np.ndarray. The result dtype of the subset rows will be object. Scalars will be returned unchanged, and empty list-likes will result in an np.nan for that row. In addition, the ordering of elements in the output will be non-deterministic when exploding sets.

Reference the user guide for more examples.

Examples

>>> s = pd.Series([[1, 2, 3], "foo", [], [3, 4]])
>>> s
0    [1, 2, 3]
1          foo
2           []
3       [3, 4]
dtype: object
>>> s.explode()
0      1
0      2
0      3
1    foo
2    NaN
3      3
3      4
dtype: object
floordiv(other, level=None, fill_value=None, axis=0)#

Return Integer division of series and other, element-wise (binary operator floordiv).

Equivalent to series // other, but with support to substitute a fill_value for missing data in either one of the inputs.

Parameters:
  • other (object) – When a Series is provided, will align on indexes. For all other types, will behave the same as == but with possibly different results due to the other arguments.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (None or float value, default None (NaN)) – Fill existing missing (NaN) values, and any new element needed for successful Series alignment, with this value before computation. If data in both corresponding Series locations is missing the result of filling (at that location) will be missing.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

Returns:

The result of the operation.

Return type:

Series

See also

Series.rfloordiv

Reverse of the Integer division operator, see Python documentation for more details.

Examples

>>> a = pd.Series([1, 1, 1, np.nan], index=['a', 'b', 'c', 'd'])
>>> a
a    1.0
b    1.0
c    1.0
d    NaN
dtype: float64
>>> b = pd.Series([1, np.nan, 1, np.nan], index=['a', 'b', 'd', 'e'])
>>> b
a    1.0
b    NaN
d    1.0
e    NaN
dtype: float64
>>> a.floordiv(b, fill_value=0)
a    1.0
b    inf
c    inf
d    0.0
e    NaN
dtype: float64
classmethod from_arrow(data)#

Construct a Series from an array-like Arrow object.

This function accepts any Arrow-compatible array-like object implementing the Arrow PyCapsule Protocol (i.e. having an __arrow_c_array__ or __arrow_c_stream__ method).

This function currently relies on pyarrow to convert the object in Arrow format to pandas.

Added in version 3.0.

Parameters:

data (pyarrow.Array or Arrow-compatible object) – Any array-like object implementing the Arrow PyCapsule Protocol (i.e. has an __arrow_c_array__ or __arrow_c_stream__ method).

Return type:

Series

See also

DataFrame.from_arrow

Construct a DataFrame from an Arrow object.

Examples

>>> import pyarrow as pa
>>> arrow_array = pa.array([1, 2, 3])
>>> pd.Series.from_arrow(arrow_array)
0    1
1    2
2    3
dtype: int64
ge(other, level=None, fill_value=None, axis=0)#

Return Greater than or equal to of series and other, element-wise (binary operator ge).

Equivalent to series >= other, but with support to substitute a fill_value for missing data in either one of the inputs.

Parameters:
  • other (object) – When a Series is provided, will align on indexes. For all other types, will behave the same as == but with possibly different results due to the other arguments.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (None or float value, default None (NaN)) – Fill existing missing (NaN) values, and any new element needed for successful Series alignment, with this value before computation. If data in both corresponding Series locations is missing the result of filling (at that location) will be missing.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

Returns:

The result of the operation.

Return type:

Series

See also

Series.gt

Greater than comparison, element-wise.

Series.le

Less than or equal to comparison, element-wise.

Series.lt

Less than comparison, element-wise.

Series.eq

Equal to comparison, element-wise.

Series.ne

Not equal to comparison, element-wise.

Examples

>>> a = pd.Series([1, 1, 1, np.nan, 1], index=["a", "b", "c", "d", "e"])
>>> a
a    1.0
b    1.0
c    1.0
d    NaN
e    1.0
dtype: float64
>>> b = pd.Series([0, 1, 2, np.nan, 1], index=["a", "b", "c", "d", "f"])
>>> b
a    0.0
b    1.0
c    2.0
d    NaN
f    1.0
dtype: float64
>>> a.ge(b, fill_value=0)
a     True
b     True
c    False
d    False
e     True
f    False
dtype: bool
groupby(by=None, level=None, *, as_index=True, sort=True, group_keys=True, observed=True, dropna=True)#

Group Series using a mapper or by a Series of columns.

A groupby operation involves some combination of splitting the object, applying a function, and combining the results. This can be used to group large amounts of data and compute operations on these groups.

Parameters:
  • by (mapping, function, label, pd.Grouper or list of such) –

    Used to determine the groups for the groupby. If by is a function, it’s called on each value of the object’s index. If a dict or Series is passed, the Series or dict VALUES will be used to determine the groups (the Series’ values are first aligned; see .align() method). If a list or ndarray of length equal to the selected axis is passed (see the groupby user guide), the values are used as-is to determine the groups. A label or list of labels may be passed to group by the columns in self. Notice that a tuple is interpreted as a (single) key.

  • level (int, level name, or sequence of such, default None) – If the axis is a MultiIndex (hierarchical), group by a particular level or levels. Do not specify both by and level.

  • as_index (bool, default True) –

    Return object with group labels as the index. Only relevant for DataFrame input. as_index=False is effectively “SQL-style” grouped output. This argument has no effect on filtrations (see the filtrations in the user guide), such as head(), tail(), nth() and in transformations (see the transformations in the user guide).

  • sort (bool, default True) –

    Sort group keys. Get better performance by turning this off. Note this does not influence the order of observations within each group. Groupby preserves the order of rows within each group. If False, the groups will appear in the same order as they did in the original DataFrame. This argument has no effect on filtrations (see the filtrations in the user guide), such as head(), tail(), nth() and in transformations (see the transformations in the user guide).

    Changed in version 2.0.0: Specifying sort=False with an ordered categorical grouper will no longer sort the values.

  • group_keys (bool, default True) –

    When calling apply and the by argument produces a like-indexed (i.e. a transform) result, add group keys to index to identify pieces. By default group keys are not included when the result’s index (and column) labels match the inputs, and are included otherwise.

    Changed in version 2.0.0: group_keys now defaults to True.

  • observed (bool, default True) –

    This only applies if any of the groupers are Categoricals. If True: only show observed values for categorical groupers. If False: show all values for categorical groupers.

    Changed in version 3.0.0: The default value is now True.

  • dropna (bool, default True) – If True, and if group keys contain NA values, NA values together with row/column will be dropped. If False, NA values will also be treated as the key in groups.

Returns:

Returns a groupby object that contains information about the groups.

Return type:

pandas.api.typing.SeriesGroupBy

See also

resample

Convenience method for frequency conversion and resampling of time series.

Notes

See the user guide for more detailed usage and examples, including splitting an object into groups, iterating through groups, selecting a group, aggregation, and more.

The implementation of groupby is hash-based, meaning in particular that objects that compare as equal will be considered to be in the same group. An exception to this is that pandas has special handling of NA values: any NA values will be collapsed to a single group, regardless of how they compare. See the user guide linked above for more details.

Examples

>>> ser = pd.Series([390., 350., 30., 20.],
...                 index=['Falcon', 'Falcon', 'Parrot', 'Parrot'],
...                 name="Max Speed")
>>> ser
Falcon    390.0
Falcon    350.0
Parrot     30.0
Parrot     20.0
Name: Max Speed, dtype: float64

We can pass a list of values to group the Series data by custom labels:

>>> ser.groupby(["a", "b", "a", "b"]).mean()
a    210.0
b    185.0
Name: Max Speed, dtype: float64

Grouping by numeric labels yields similar results:

>>> ser.groupby([0, 1, 0, 1]).mean()
0    210.0
1    185.0
Name: Max Speed, dtype: float64

We can group by a level of the index:

>>> ser.groupby(level=0).mean()
Falcon    370.0
Parrot     25.0
Name: Max Speed, dtype: float64

We can group by a condition applied to the Series values:

>>> ser.groupby(ser > 100).mean()
Max Speed
False     25.0
True     370.0
Name: Max Speed, dtype: float64

Grouping by Indexes

We can groupby different levels of a hierarchical index using the level parameter:

>>> arrays = [['Falcon', 'Falcon', 'Parrot', 'Parrot'],
...           ['Captive', 'Wild', 'Captive', 'Wild']]
>>> index = pd.MultiIndex.from_arrays(arrays, names=('Animal', 'Type'))
>>> ser = pd.Series([390., 350., 30., 20.], index=index, name="Max Speed")
>>> ser
Animal  Type
Falcon  Captive    390.0
        Wild       350.0
Parrot  Captive     30.0
        Wild        20.0
Name: Max Speed, dtype: float64
>>> ser.groupby(level=0).mean()
Animal
Falcon    370.0
Parrot     25.0
Name: Max Speed, dtype: float64

We can also group by the ‘Type’ level of the hierarchical index to get the mean speed for each type:

>>> ser.groupby(level="Type").mean()
Type
Captive    210.0
Wild       185.0
Name: Max Speed, dtype: float64

We can also choose to include NA in group keys or not by defining dropna parameter, the default setting is True.

>>> ser = pd.Series([1, 2, 3, 3], index=["a", 'a', 'b', np.nan])
>>> ser.groupby(level=0).sum()
a    3
b    3
dtype: int64

To include NA values in the group keys, set dropna=False:

>>> ser.groupby(level=0, dropna=False).sum()
a    3
b    3
NaN  3
dtype: int64

We can also group by a custom list with NaN values to handle missing group labels:

>>> arrays = ['Falcon', 'Falcon', 'Parrot', 'Parrot']
>>> ser = pd.Series([390., 350., 30., 20.], index=arrays, name="Max Speed")
>>> ser.groupby(["a", "b", "a", np.nan]).mean()
a    210.0
b    350.0
Name: Max Speed, dtype: float64
>>> ser.groupby(["a", "b", "a", np.nan], dropna=False).mean()
a    210.0
b    350.0
NaN   20.0
Name: Max Speed, dtype: float64
gt(other, level=None, fill_value=None, axis=0)#

Return Greater than of series and other, element-wise (binary operator gt).

Equivalent to series > other, but with support to substitute a fill_value for missing data in either one of the inputs.

Parameters:
  • other (object) – When a Series is provided, will align on indexes. For all other types, will behave the same as == but with possibly different results due to the other arguments.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (None or float value, default None (NaN)) – Fill existing missing (NaN) values, and any new element needed for successful Series alignment, with this value before computation. If data in both corresponding Series locations is missing the result of filling (at that location) will be missing.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

Returns:

The result of the operation.

Return type:

Series

See also

Series.lt

Reverse of the Greater than operator, see Python documentation for more details.

Examples

>>> a = pd.Series([1, 1, 1, np.nan, 1], index=['a', 'b', 'c', 'd', 'e'])
>>> a
a    1.0
b    1.0
c    1.0
d    NaN
e    1.0
dtype: float64
>>> b = pd.Series([0, 1, 2, np.nan, 1], index=['a', 'b', 'c', 'd', 'f'])
>>> b
a    0.0
b    1.0
c    2.0
d    NaN
f    1.0
dtype: float64
>>> a.gt(b, fill_value=0)
a     True
b    False
c    False
d    False
e     True
f    False
dtype: bool
property hasnans: bool#

Return True if there are any NaNs.

Enables various performance speedups.

Return type:

bool

See also

Series.isna

Detect missing values.

Series.notna

Detect existing (non-missing) values.

Examples

>>> s = pd.Series([1, 2, 3, None])
>>> s
0    1.0
1    2.0
2    3.0
3    NaN
dtype: float64
>>> s.hasnans
True
hist(by=None, ax=None, grid=True, xlabelsize=None, xrot=None, ylabelsize=None, yrot=None, figsize=None, bins=10, backend=None, legend=False, **kwargs)#

Draw histogram of the input series using matplotlib.

Parameters:
  • by (object, optional) – If passed, then used to form histograms for separate groups.

  • ax (matplotlib axis object) – If not passed, uses gca().

  • grid (bool, default True) – Whether to show axis grid lines.

  • xlabelsize (int, default None) – If specified changes the x-axis label size.

  • xrot (float, default None) – Rotation of x axis labels.

  • ylabelsize (int, default None) – If specified changes the y-axis label size.

  • yrot (float, default None) – Rotation of y axis labels.

  • figsize (tuple, default None) – Figure size in inches by default.

  • bins (int or sequence, default 10) – Number of histogram bins to be used. If an integer is given, bins + 1 bin edges are calculated and returned. If bins is a sequence, gives bin edges, including left edge of first bin and right edge of last bin. In this case, bins is returned unmodified.

  • backend (str, default None) – Backend to use instead of the backend specified in the option plotting.backend. For instance, ‘matplotlib’. Alternatively, to specify the plotting.backend for the whole session, set pd.options.plotting.backend.

  • legend (bool, default False) – Whether to show the legend.

  • **kwargs – To be passed to the actual plotting function.

  • self (Series)

Returns:

A histogram plot.

Return type:

matplotlib.axes.Axes

See also

matplotlib.axes.Axes.hist

Plot a histogram using matplotlib.

Examples

For Series:

For Groupby:

idxmax(axis=0, skipna=True, *args, **kwargs)#

Return the row label of the maximum value.

If multiple values equal the maximum, the first row label with that value is returned.

Parameters:
  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

  • skipna (bool, default True) – Exclude NA/null values. If the entire Series is NA, or if skipna=False and there is an NA value, this method will raise a ValueError.

  • *args – Additional arguments and keywords have no effect but might be accepted for compatibility with NumPy.

  • **kwargs – Additional arguments and keywords have no effect but might be accepted for compatibility with NumPy.

Returns:

Label of the maximum value.

Return type:

Index

Raises:

ValueError – If the Series is empty.

See also

numpy.argmax

Return indices of the maximum values along the given axis.

DataFrame.idxmax

Return index of first occurrence of maximum over requested axis.

Series.idxmin

Return index label of the first occurrence of minimum of values.

Notes

This method is the Series version of ndarray.argmax. This method returns the label of the maximum, while ndarray.argmax returns the position. To get the position, use series.values.argmax().

Examples

>>> s = pd.Series(data=[1, None, 4, 3, 4], index=["A", "B", "C", "D", "E"])
>>> s
A    1.0
B    NaN
C    4.0
D    3.0
E    4.0
dtype: float64
>>> s.idxmax()
'C'
idxmin(axis=0, skipna=True, *args, **kwargs)#

Return the row label of the minimum value.

If multiple values equal the minimum, the first row label with that value is returned.

Parameters:
  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

  • skipna (bool, default True) – Exclude NA/null values. If the entire Series is NA, or if skipna=False and there is an NA value, this method will raise a ValueError.

  • *args – Additional arguments and keywords have no effect but might be accepted for compatibility with NumPy.

  • **kwargs – Additional arguments and keywords have no effect but might be accepted for compatibility with NumPy.

Returns:

Label of the minimum value.

Return type:

Index

Raises:

ValueError – If the Series is empty.

See also

numpy.argmin

Return indices of the minimum values along the given axis.

DataFrame.idxmin

Return index of first occurrence of minimum over requested axis.

Series.idxmax

Return index label of the first occurrence of maximum of values.

Notes

This method is the Series version of ndarray.argmin. This method returns the label of the minimum, while ndarray.argmin returns the position. To get the position, use series.values.argmin().

Examples

>>> s = pd.Series(data=[1, None, 4, 1], index=["A", "B", "C", "D"])
>>> s
A    1.0
B    NaN
C    4.0
D    1.0
dtype: float64
>>> s.idxmin()
'A'
index#

The index (axis labels) of the Series.

The index of a Series is used to label and identify each element of the underlying data. The index can be thought of as an immutable ordered set (technically a multi-set, as it may contain duplicate labels), and is used to index and align data in pandas.

Returns:

The index labels of the Series.

Return type:

Index

See also

Series.reindex

Conform Series to new index.

Index

The base pandas index type.

Notes

For more information on pandas indexing, see the indexing user guide.

Examples

To create a Series with a custom index and view the index labels:

>>> cities = ['Kolkata', 'Chicago', 'Toronto', 'Lisbon']
>>> populations = [14.85, 2.71, 2.93, 0.51]
>>> city_series = pd.Series(populations, index=cities)
>>> city_series.index
Index(['Kolkata', 'Chicago', 'Toronto', 'Lisbon'], dtype='object')

To change the index labels of an existing Series:

>>> city_series.index = ['KOL', 'CHI', 'TOR', 'LIS']
>>> city_series.index
Index(['KOL', 'CHI', 'TOR', 'LIS'], dtype='object')
info(verbose=None, buf=None, max_cols=None, memory_usage=None, show_counts=True)#

Print a concise summary of a Series.

This method prints information about a Series including the index dtype, non-NA values and memory usage.

Parameters:
  • verbose (bool, optional) – Whether to print the full summary. By default, the setting in pandas.options.display.max_info_columns is followed.

  • buf (writable buffer, defaults to sys.stdout) – Where to send the output. By default, the output is printed to sys.stdout. Pass a writable buffer if you need to further process the output.

  • max_cols (int, optional) – Unused, exists only for compatibility with DataFrame.info.

  • memory_usage (bool, str, optional) –

    Specifies whether total memory usage of the Series elements (including the index) should be displayed. By default, this follows the pandas.options.display.memory_usage setting.

    True always show memory usage. False never shows memory usage. A value of ‘deep’ is equivalent to “True with deep introspection”. Memory usage is shown in human-readable units (base-2 representation). Without deep introspection a memory estimation is made based in column dtype and number of rows assuming values consume the same memory amount for corresponding dtypes. With deep memory introspection, a real memory usage calculation is performed at the cost of computational resources. See the Frequently Asked Questions for more details.

  • show_counts (bool, optional) – Whether to show the non-null counts. By default, this is shown only if the DataFrame is smaller than pandas.options.display.max_info_rows and pandas.options.display.max_info_columns. A value of True always shows the counts, and False never shows the counts.

Returns:

This method prints a summary of a Series and returns None.

Return type:

None

See also

Series.describe

Generate descriptive statistics of Series.

Series.memory_usage

Memory usage of Series.

Examples

>>> int_values = [1, 2, 3, 4, 5]
>>> text_values = ["alpha", "beta", "gamma", "delta", "epsilon"]
>>> s = pd.Series(text_values, index=int_values)
>>> s.info()
<class 'pandas.Series'>
Index: 5 entries, 1 to 5
Series name: None
Non-Null Count  Dtype
--------------  -----
5 non-null      str
dtypes: str(1)
memory usage: 106.0 bytes

Prints a summary excluding information about its values:

>>> s.info(verbose=False)
<class 'pandas.Series'>
Index: 5 entries, 1 to 5
dtypes: str(1)
memory usage: 106.0 bytes

Pipe output of Series.info to buffer instead of sys.stdout, get buffer content and writes to a text file:

>>> import io
>>> buffer = io.StringIO()
>>> s.info(buf=buffer)
>>> s = buffer.getvalue()
>>> with open("df_info.txt", "w", encoding="utf-8") as f:
...     f.write(s)
260

The memory_usage parameter allows deep introspection mode, specially useful for big Series and fine-tune memory optimization:

>>> random_strings_array = np.random.choice(["a", "b", "c"], 10**6)
>>> s = pd.Series(np.random.choice(["a", "b", "c"], 10**6))
>>> s.info()
<class 'pandas.Series'>
RangeIndex: 1000000 entries, 0 to 999999
Series name: None
Non-Null Count    Dtype
--------------    -----
1000000 non-null  str
dtypes: str(1)
memory usage: 8.6 MB
>>> s.info(memory_usage="deep")
<class 'pandas.Series'>
RangeIndex: 1000000 entries, 0 to 999999
Series name: None
Non-Null Count    Dtype
--------------    -----
1000000 non-null  str
dtypes: str(1)
memory usage: 8.6 MB
isin(values)#

Whether elements in Series are contained in values.

Return a boolean Series showing whether each element in the Series matches an element in the passed sequence of values exactly.

Parameters:

values (set or list-like) – The sequence of values to test. Passing in a single string will raise a TypeError. Instead, turn a single string into a list of one element.

Returns:

Series of booleans indicating if each element is in values.

Return type:

Series

Raises:

TypeError

  • If values is a string

See also

DataFrame.isin

Equivalent method on DataFrame.

Examples

>>> s = pd.Series(
...     ["llama", "cow", "llama", "beetle", "llama", "hippo"], name="animal"
... )
>>> s.isin(["cow", "llama"])
0     True
1     True
2     True
3    False
4     True
5    False
Name: animal, dtype: bool

To invert the boolean values, use the ~ operator:

>>> ~s.isin(["cow", "llama"])
0    False
1    False
2    False
3     True
4    False
5     True
Name: animal, dtype: bool

Passing a single string as s.isin('llama') will raise an error. Use a list of one element instead:

>>> s.isin(["llama"])
0     True
1    False
2     True
3    False
4     True
5    False
Name: animal, dtype: bool

Strings and integers are distinct and are therefore not comparable:

>>> pd.Series([1]).isin(["1"])
0    False
dtype: bool
>>> pd.Series([1.1]).isin(["1.1"])
0    False
dtype: bool
isna()#

Detect missing values.

Return a boolean same-sized Series indicating if the values are NA. NA values, such as None or numpy.NaN, get mapped to True values. Everything else gets mapped to False values. Characters such as empty strings '' or numpy.inf are not considered NA values.

Returns:

Mask of bool values for each element in Series that indicates whether an element is an NA value.

Return type:

Series

See also

DataFrame.isna

Detect missing values.

DataFrame.isnull

Alias of isna.

Series.notna

Boolean inverse of isna.

DataFrame.notna

Boolean inverse of isna.

Series.notnull

Alias of notna.

DataFrame.notnull

Alias of notna.

Series.dropna

Omit axes labels with missing values.

DataFrame.dropna

Omit axes labels with missing values.

isna

Top-level isna.

Examples

Show which entries in a Series are NA.

>>> ser = pd.Series([5, 6, np.nan])
>>> ser
0    5.0
1    6.0
2    NaN
dtype: float64
>>> ser.isna()
0    False
1    False
2     True
dtype: bool
isnull()#

Series.isnull is an alias for Series.isna.

Detect missing values.

Return a boolean same-sized object indicating if the values are NA. NA values, such as None or numpy.NaN, gets mapped to True values. Everything else gets mapped to False values. Characters such as empty strings '' or numpy.inf are not considered NA values.

Returns:

Mask of bool values for each element in Series/DataFrame that indicates whether an element is an NA value.

Return type:

Series/DataFrame

See also

Series.isnull

Alias of isna.

DataFrame.isnull

Alias of isna.

Series.notna

Boolean inverse of isna.

DataFrame.notna

Boolean inverse of isna.

Series.dropna

Omit axes labels with missing values.

DataFrame.dropna

Omit axes labels with missing values.

isna

Top-level isna.

Examples

Show which entries in a DataFrame are NA.

>>> df = pd.DataFrame(
...     dict(
...         age=[5, 6, np.nan],
...         born=[
...             pd.NaT,
...             pd.Timestamp("1939-05-27"),
...             pd.Timestamp("1940-04-25"),
...         ],
...         name=["Alfred", "Batman", ""],
...         toy=[None, "Batmobile", "Joker"],
...     )
... )
>>> df
   age       born    name        toy
0  5.0        NaT  Alfred        NaN
1  6.0 1939-05-27  Batman  Batmobile
2  NaN 1940-04-25              Joker
>>> df.isna()
     age   born   name    toy
0  False   True  False   True
1  False  False  False  False
2   True  False  False  False

Show which entries in a Series are NA.

>>> ser = pd.Series([5, 6, np.nan])
>>> ser
0    5.0
1    6.0
2    NaN
dtype: float64
>>> ser.isna()
0    False
1    False
2     True
dtype: bool
items()#

Lazily iterate over (index, value) tuples.

This method returns an iterable tuple (index, value). This is convenient if you want to create a lazy iterator.

Returns:

Iterable of tuples containing the (index, value) pairs from a Series.

Return type:

iterable

See also

DataFrame.items

Iterate over (column name, Series) pairs.

DataFrame.iterrows

Iterate over DataFrame rows as (index, Series) pairs.

Examples

>>> s = pd.Series(["A", "B", "C"])
>>> for index, value in s.items():
...     print(f"Index : {index}, Value : {value}")
Index : 0, Value : A
Index : 1, Value : B
Index : 2, Value : C
keys()#

Return alias for index.

Returns:

Index of the Series.

Return type:

Index

See also

Series.index

The index (axis labels) of the Series.

Examples

>>> s = pd.Series([1, 2, 3], index=[0, 1, 2])
>>> s.keys()
Index([0, 1, 2], dtype='int64')
kurt(*, axis=0, skipna=True, numeric_only=False, **kwargs)#

Return unbiased kurtosis over requested axis.

Kurtosis obtained using Fisher’s definition of kurtosis (kurtosis of normal == 0.0). Normalized by N-1.

Parameters:
  • axis ({index (0)}) –

    Axis for the function to be applied on. For Series this parameter is unused and defaults to 0.

    For DataFrames, specifying axis=None will apply the aggregation across both axes.

    Added in version 2.0.0.

  • skipna (bool, default True) – Exclude NA/null values when computing the result.

  • numeric_only (bool, default False) – Include only float, int, boolean columns.

  • **kwargs – Additional keyword arguments to be passed to the function.

Returns:

Unbiased kurtosis.

Return type:

scalar

See also

Series.skew

Return unbiased skew over requested axis.

Series.var

Return unbiased variance over requested axis.

Series.std

Return unbiased standard deviation over requested axis.

Examples

>>> s = pd.Series([1, 2, 2, 3], index=["cat", "dog", "dog", "mouse"])
>>> s
cat    1
dog    2
dog    2
mouse  3
dtype: int64
>>> s.kurt()
1.5
kurtosis(*, axis=0, skipna=True, numeric_only=False, **kwargs)#

Return unbiased kurtosis over requested axis.

Kurtosis obtained using Fisher’s definition of kurtosis (kurtosis of normal == 0.0). Normalized by N-1.

Parameters:
  • axis ({index (0)}) –

    Axis for the function to be applied on. For Series this parameter is unused and defaults to 0.

    For DataFrames, specifying axis=None will apply the aggregation across both axes.

    Added in version 2.0.0.

  • skipna (bool, default True) – Exclude NA/null values when computing the result.

  • numeric_only (bool, default False) – Include only float, int, boolean columns.

  • **kwargs – Additional keyword arguments to be passed to the function.

Returns:

Unbiased kurtosis.

Return type:

scalar

See also

Series.skew

Return unbiased skew over requested axis.

Series.var

Return unbiased variance over requested axis.

Series.std

Return unbiased standard deviation over requested axis.

Examples

>>> s = pd.Series([1, 2, 2, 3], index=["cat", "dog", "dog", "mouse"])
>>> s
cat    1
dog    2
dog    2
mouse  3
dtype: int64
>>> s.kurt()
1.5
le(other, level=None, fill_value=None, axis=0)#

Return Less than or equal to of series and other, element-wise (binary operator le).

Equivalent to series <= other, but with support to substitute a fill_value for missing data in either one of the inputs.

Parameters:
  • other (object) – When a Series is provided, will align on indexes. For all other types, will behave the same as == but with possibly different results due to the other arguments.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (None or float value, default None (NaN)) – Fill existing missing (NaN) values, and any new element needed for successful Series alignment, with this value before computation. If data in both corresponding Series locations is missing the result of filling (at that location) will be missing.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

Returns:

The result of the operation.

Return type:

Series

See also

Series.ge

Return elementwise Greater than or equal to of series and other.

Series.lt

Return elementwise Less than of series and other.

Series.gt

Return elementwise Greater than of series and other.

Series.eq

Return elementwise equal to of series and other.

Examples

>>> a = pd.Series([1, 1, 1, np.nan, 1], index=['a', 'b', 'c', 'd', 'e'])
>>> a
a    1.0
b    1.0
c    1.0
d    NaN
e    1.0
dtype: float64
>>> b = pd.Series([0, 1, 2, np.nan, 1], index=['a', 'b', 'c', 'd', 'f'])
>>> b
a    0.0
b    1.0
c    2.0
d    NaN
f    1.0
dtype: float64
>>> a.le(b, fill_value=0)
a    False
b     True
c     True
d    False
e    False
f     True
dtype: bool
list#

alias of ListAccessor

lt(other, level=None, fill_value=None, axis=0)#

Return Greater than of series and other, element-wise (binary operator lt).

Equivalent to series > other, but with support to substitute a fill_value for missing data in either one of the inputs.

Parameters:
  • other (object) – When a Series is provided, will align on indexes. For all other types, will behave the same as == but with possibly different results due to the other arguments.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (None or float value, default None (NaN)) – Fill existing missing (NaN) values, and any new element needed for successful Series alignment, with this value before computation. If data in both corresponding Series locations is missing the result of filling (at that location) will be missing.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

Returns:

The result of the operation.

Return type:

Series

See also

Series.gt

Element-wise Greater than, see Python documentation for more details.

Examples

>>> a = pd.Series([1, 1, 1, np.nan, 1], index=['a', 'b', 'c', 'd', 'e'])
>>> a
a    1.0
b    1.0
c    1.0
d    NaN
e    1.0
dtype: float64
>>> b = pd.Series([0, 1, 2, np.nan, 1], index=['a', 'b', 'c', 'd', 'f'])
>>> b
a    0.0
b    1.0
c    2.0
d    NaN
f    1.0
dtype: float64
>>> a.gt(b, fill_value=0)
a     True
b    False
c    False
d    False
e     True
f    False
dtype: bool
map(func=None, na_action=None, engine=None, **kwargs)#

Map values of Series according to an input mapping or function.

Used for substituting each value in a Series with another value, that may be derived from a function, a dict or a Series.

Parameters:
  • func (function, collections.abc.Mapping subclass or Series) – Function or mapping correspondence.

  • na_action ({None, 'ignore'}, default None) – If ‘ignore’, propagate NaN values, without passing them to the mapping correspondence.

  • engine (decorator, optional) –

    Choose the execution engine to use to run the function. Only used for functions. If map is called with a mapping or Series, an exception will be raised. If engine is not provided the function will be executed by the regular Python interpreter.

    Options include JIT compilers such as Numba, Bodo or Blosc2, which in some cases can speed up the execution. To use an executor you can provide the decorators numba.jit, numba.njit, bodo.jit or blosc2.jit. You can also provide the decorator with parameters, like numba.jit(nogit=True).

    Not all functions can be executed with all execution engines. In general, JIT compilers will require type stability in the function (no variable should change data type during the execution). And not all pandas and NumPy APIs are supported. Check the engine documentation for limitations.

    Added in version 3.0.0.

  • **kwargs

    Additional keyword arguments to pass as keywords arguments to arg.

    Added in version 3.0.0.

Returns:

Same index as caller.

Return type:

Series

See also

Series.apply

For applying more complex functions on a Series.

Series.replace

Replace values given in to_replace with value.

DataFrame.apply

Apply a function row-/column-wise.

DataFrame.map

Apply a function elementwise on a whole DataFrame.

Notes

When arg is a dictionary, values in Series that are not in the dictionary (as keys) are converted to NaN. However, if the dictionary is a dict subclass that defines __missing__ (i.e. provides a method for default values), then this default is used rather than NaN.

Examples

>>> s = pd.Series(["cat", "dog", np.nan, "rabbit"])
>>> s
0      cat
1      dog
2      NaN
3   rabbit
dtype: str

map accepts a dict or a Series. Values that are not found in the dict are converted to NaN, unless the dict has a default value (e.g. defaultdict):

>>> s.map({"cat": "kitten", "dog": "puppy"})
0   kitten
1    puppy
2      NaN
3      NaN
dtype: str

It also accepts a function:

>>> s.map("I am a {}".format)
0       I am a cat
1       I am a dog
2       I am a nan
3    I am a rabbit
dtype: str

To avoid applying the function to missing values (and keep them as NaN) na_action='ignore' can be used:

>>> s.map("I am a {}".format, na_action="ignore")
0     I am a cat
1     I am a dog
2            NaN
3  I am a rabbit
dtype: str

For categorical data, the function is only applied to the categories:

>>> s = pd.Series(list("cabaa"))
>>> s.map(print)
c
a
b
a
a
0    None
1    None
2    None
3    None
4    None
dtype: object
>>> s_cat = s.astype("category")
>>> s_cat.map(print)  # function called once per unique category
a
b
c
0    None
1    None
2    None
3    None
4    None
dtype: object
max(*, axis=0, skipna=True, numeric_only=False, **kwargs)#

Return the maximum of the values over the requested axis.

If you want the index of the maximum, use idxmax. This is the equivalent of the numpy.ndarray method argmax.

Parameters:
  • axis ({index (0)}) –

    Axis for the function to be applied on. For Series this parameter is unused and defaults to 0.

    For DataFrames, specifying axis=None will apply the aggregation across both axes.

    Added in version 2.0.0.

  • skipna (bool, default True) – Exclude NA/null values when computing the result.

  • numeric_only (bool, default False) – Include only float, int, boolean columns.

  • **kwargs – Additional keyword arguments to be passed to the function.

Returns:

The maximum of the values in the Series.

Return type:

scalar or Series (if level specified)

See also

numpy.max

Equivalent numpy function for arrays.

Series.min

Return the minimum.

Series.max

Return the maximum.

Series.idxmin

Return the index of the minimum.

Series.idxmax

Return the index of the maximum.

DataFrame.min

Return the minimum over the requested axis.

DataFrame.max

Return the maximum over the requested axis.

DataFrame.idxmin

Return the index of the minimum over the requested axis.

DataFrame.idxmax

Return the index of the maximum over the requested axis.

Examples

>>> idx = pd.MultiIndex.from_arrays(
...     [["warm", "warm", "cold", "cold"], ["dog", "falcon", "fish", "spider"]],
...     names=["blooded", "animal"],
... )
>>> s = pd.Series([4, 2, 0, 8], name="legs", index=idx)
>>> s
blooded  animal
warm     dog       4
         falcon    2
cold     fish      0
         spider    8
Name: legs, dtype: int64
>>> s.max()
8
mean(*, axis=0, skipna=True, numeric_only=False, **kwargs)#

Return the mean of the values over the requested axis.

Parameters:
  • axis ({index (0)}) –

    Axis for the function to be applied on. For Series this parameter is unused and defaults to 0.

    For DataFrames, specifying axis=None will apply the aggregation across both axes.

    Added in version 2.0.0.

  • skipna (bool, default True) – Exclude NA/null values when computing the result.

  • numeric_only (bool, default False) – Include only float, int, boolean columns.

  • **kwargs – Additional keyword arguments to be passed to the function.

Returns:

Mean of the values for the requested axis.

Return type:

scalar or Series (if level specified)

See also

numpy.median

Equivalent numpy function for computing median.

Series.sum

Sum of the values.

Series.median

Median of the values.

Series.std

Standard deviation of the values.

Series.var

Variance of the values.

Series.min

Minimum value.

Series.max

Maximum value.

Examples

>>> s = pd.Series([1, 2, 3])
>>> s.mean()
2.0
median(*, axis=0, skipna=True, numeric_only=False, **kwargs)#

Return the median of the values over the requested axis.

Parameters:
  • axis ({index (0)}) –

    Axis for the function to be applied on. For Series this parameter is unused and defaults to 0.

    For DataFrames, specifying axis=None will apply the aggregation across both axes.

    Added in version 2.0.0.

  • skipna (bool, default True) – Exclude NA/null values when computing the result.

  • numeric_only (bool, default False) – Include only float, int, boolean columns.

  • **kwargs – Additional keyword arguments to be passed to the function.

Returns:

Median of the values for the requested axis.

Return type:

scalar or Series (if level specified)

See also

numpy.median

Equivalent numpy function for computing median.

Series.sum

Sum of the values.

Series.median

Median of the values.

Series.std

Standard deviation of the values.

Series.var

Variance of the values.

Series.min

Minimum value.

Series.max

Maximum value.

Examples

>>> s = pd.Series([1, 2, 3])
>>> s.median()
2.0

With a DataFrame

>>> df = pd.DataFrame({"a": [1, 2], "b": [2, 3]}, index=["tiger", "zebra"])
>>> df
       a   b
tiger  1   2
zebra  2   3
>>> df.median()
a   1.5
b   2.5
dtype: float64

Using axis=1

>>> df.median(axis=1)
tiger   1.5
zebra   2.5
dtype: float64

In this case, numeric_only should be set to True to avoid getting an error.

>>> df = pd.DataFrame({"a": [1, 2], "b": ["T", "Z"]}, index=["tiger", "zebra"])
>>> df.median(numeric_only=True)
a   1.5
dtype: float64
memory_usage(index=True, deep=False)#

Return the memory usage of the Series.

The memory usage can optionally include the contribution of the index and of elements of object dtype.

Parameters:
  • index (bool, default True) – Specifies whether to include the memory usage of the Series index.

  • deep (bool, default False) – If True, introspect the data deeply by interrogating object dtypes for system-level memory consumption, and include it in the returned value.

Returns:

Bytes of memory consumed.

Return type:

int

See also

numpy.ndarray.nbytes

Total bytes consumed by the elements of the array.

DataFrame.memory_usage

Bytes consumed by a DataFrame.

Examples

>>> s = pd.Series(range(3))
>>> s.memory_usage()
156

Not including the index gives the size of the rest of the data, which is necessarily smaller:

>>> s.memory_usage(index=False)
24

The memory footprint of object values is ignored by default:

>>> s = pd.Series(["a", "b"])
>>> s.values
<ArrowStringArray>
['a', 'b']
Length: 2, dtype: str
>>> s.memory_usage()
150
>>> s.memory_usage(deep=True)
150
min(*, axis=0, skipna=True, numeric_only=False, **kwargs)#

Return the minimum of the values over the requested axis.

If you want the index of the minimum, use idxmin. This is the equivalent of the numpy.ndarray method argmin.

Parameters:
  • axis ({index (0)}) –

    Axis for the function to be applied on. For Series this parameter is unused and defaults to 0.

    For DataFrames, specifying axis=None will apply the aggregation across both axes.

    Added in version 2.0.0.

  • skipna (bool, default True) – Exclude NA/null values when computing the result.

  • numeric_only (bool, default False) – Include only float, int, boolean columns.

  • **kwargs – Additional keyword arguments to be passed to the function.

Returns:

The minimum of the values in the Series.

Return type:

scalar or Series (if level specified)

See also

numpy.min

Equivalent numpy function for arrays.

Series.min

Return the minimum.

Series.max

Return the maximum.

Series.idxmin

Return the index of the minimum.

Series.idxmax

Return the index of the maximum.

DataFrame.min

Return the minimum over the requested axis.

DataFrame.max

Return the maximum over the requested axis.

DataFrame.idxmin

Return the index of the minimum over the requested axis.

DataFrame.idxmax

Return the index of the maximum over the requested axis.

Examples

>>> idx = pd.MultiIndex.from_arrays(
...     [["warm", "warm", "cold", "cold"], ["dog", "falcon", "fish", "spider"]],
...     names=["blooded", "animal"],
... )
>>> s = pd.Series([4, 2, 0, 8], name="legs", index=idx)
>>> s
blooded  animal
warm     dog       4
         falcon    2
cold     fish      0
         spider    8
Name: legs, dtype: int64
>>> s.min()
0
mod(other, level=None, fill_value=None, axis=0)#

Return Modulo of series and other, element-wise (binary operator mod).

Equivalent to series % other, but with support to substitute a fill_value for missing data in either one of the inputs.

Parameters:
  • other (Series or scalar value) – Series with which to compute modulo.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (None or float value, default None (NaN)) – Fill existing missing (NaN) values, and any new element needed for successful Series alignment, with this value before computation. If data in both corresponding Series locations is missing the result of filling (at that location) will be missing.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

Returns:

The result of the operation.

Return type:

Series

See also

Series.rmod

Reverse of the Modulo operator, see Python documentation for more details.

Examples

>>> a = pd.Series([1, 1, 1, np.nan], index=["a", "b", "c", "d"])
>>> a
a    1.0
b    1.0
c    1.0
d    NaN
dtype: float64
>>> b = pd.Series([1, np.nan, 1, np.nan], index=["a", "b", "d", "e"])
>>> b
a    1.0
b    NaN
d    1.0
e    NaN
dtype: float64
>>> a.mod(b, fill_value=0)
a    0.0
b    NaN
c    NaN
d    0.0
e    NaN
dtype: float64
mode(dropna=True)#

Return the mode(s) of the Series.

The mode is the value that appears most often. There can be multiple modes.

Always returns Series even if only one value is returned.

Parameters:

dropna (bool, default True) – Don’t consider counts of NaN/NaT.

Returns:

Modes of the Series in sorted order.

Return type:

Series

See also

numpy.mode

Equivalent numpy function for computing median.

Series.sum

Sum of the values.

Series.median

Median of the values.

Series.std

Standard deviation of the values.

Series.var

Variance of the values.

Series.min

Minimum value.

Series.max

Maximum value.

Examples

>>> s = pd.Series([2, 4, 2, 2, 4, None])
>>> s.mode()
0    2.0
dtype: float64

More than one mode:

>>> s = pd.Series([2, 4, 8, 2, 4, None])
>>> s.mode()
0    2.0
1    4.0
dtype: float64

With and without considering null value:

>>> s = pd.Series([2, 4, None, None, 4, None])
>>> s.mode(dropna=False)
0   NaN
dtype: float64
>>> s = pd.Series([2, 4, None, None, 4, None])
>>> s.mode()
0    4.0
dtype: float64
mul(other, level=None, fill_value=None, axis=0)#

Return Multiplication of series and other, element-wise (binary operator mul).

Equivalent to series * other, but with support to substitute a fill_value for missing data in either one of the inputs.

Parameters:
  • other (Series or scalar value) – With which to compute the multiplication.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (None or float value, default None (NaN)) – Fill existing missing (NaN) values, and any new element needed for successful Series alignment, with this value before computation. If data in both corresponding Series locations is missing the result of filling (at that location) will be missing.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

Returns:

The result of the operation.

Return type:

Series

See also

Series.rmul

Reverse of the Multiplication operator, see Python documentation for more details.

Examples

>>> a = pd.Series([1, 1, 1, np.nan], index=["a", "b", "c", "d"])
>>> a
a    1.0
b    1.0
c    1.0
d    NaN
dtype: float64
>>> b = pd.Series([1, np.nan, 1, np.nan], index=["a", "b", "d", "e"])
>>> b
a    1.0
b    NaN
d    1.0
e    NaN
dtype: float64
>>> a.multiply(b, fill_value=0)
a    1.0
b    0.0
c    0.0
d    0.0
e    NaN
dtype: float64
>>> a.mul(5, fill_value=0)
a    5.0
b    5.0
c    5.0
d    0.0
dtype: float64
multiply(other, level=None, fill_value=None, axis=0)#

Return Multiplication of series and other, element-wise (binary operator mul).

Equivalent to series * other, but with support to substitute a fill_value for missing data in either one of the inputs.

Parameters:
  • other (Series or scalar value) – With which to compute the multiplication.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (None or float value, default None (NaN)) – Fill existing missing (NaN) values, and any new element needed for successful Series alignment, with this value before computation. If data in both corresponding Series locations is missing the result of filling (at that location) will be missing.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

Returns:

The result of the operation.

Return type:

Series

See also

Series.rmul

Reverse of the Multiplication operator, see Python documentation for more details.

Examples

>>> a = pd.Series([1, 1, 1, np.nan], index=["a", "b", "c", "d"])
>>> a
a    1.0
b    1.0
c    1.0
d    NaN
dtype: float64
>>> b = pd.Series([1, np.nan, 1, np.nan], index=["a", "b", "d", "e"])
>>> b
a    1.0
b    NaN
d    1.0
e    NaN
dtype: float64
>>> a.multiply(b, fill_value=0)
a    1.0
b    0.0
c    0.0
d    0.0
e    NaN
dtype: float64
>>> a.mul(5, fill_value=0)
a    5.0
b    5.0
c    5.0
d    0.0
dtype: float64
property name: Hashable#

Return the name of the Series.

The name of a Series becomes its index or column name if it is used to form a DataFrame. It is also used whenever displaying the Series using the interpreter.

Returns:

The name of the Series, also the column name if part of a DataFrame.

Return type:

label (hashable object)

See also

Series.rename

Sets the Series name when given a scalar input.

Index.name

Corresponding Index property.

Examples

The Series name can be set initially when calling the constructor.

>>> s = pd.Series([1, 2, 3], dtype=np.int64, name="Numbers")
>>> s
0    1
1    2
2    3
Name: Numbers, dtype: int64
>>> s.name = "Integers"
>>> s
0    1
1    2
2    3
Name: Integers, dtype: int64

The name of a Series within a DataFrame is its column name.

>>> df = pd.DataFrame(
...     [[1, 2], [3, 4], [5, 6]], columns=["Odd Numbers", "Even Numbers"]
... )
>>> df
   Odd Numbers  Even Numbers
0            1             2
1            3             4
2            5             6
>>> df["Even Numbers"].name
'Even Numbers'
ne(other, level=None, fill_value=None, axis=0)#

Return Not equal to of series and other, element-wise (binary operator ne).

Equivalent to series != other, but with support to substitute a fill_value for missing data in either one of the inputs.

Parameters:
  • other (object) – When a Series is provided, will align on indexes. For all other types, will behave the same as == but with possibly different results due to the other arguments.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (None or float value, default None (NaN)) – Fill existing missing (NaN) values, and any new element needed for successful Series alignment, with this value before computation. If data in both corresponding Series locations is missing the result of filling (at that location) will be missing.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

Returns:

The result of the operation.

Return type:

Series

See also

Series.eq

Reverse of the Not equal to operator, see Python documentation for more details.

Examples

>>> a = pd.Series([1, 1, 1, np.nan], index=['a', 'b', 'c', 'd'])
>>> a
a    1.0
b    1.0
c    1.0
d    NaN
dtype: float64
>>> b = pd.Series([1, np.nan, 1, np.nan], index=['a', 'b', 'd', 'e'])
>>> b
a    1.0
b    NaN
d    1.0
e    NaN
dtype: float64
>>> a.ne(b, fill_value=0)
a    False
b     True
c     True
d     True
e     True
dtype: bool
nlargest(n=5, keep='first')#

Return the largest n elements.

Parameters:
  • n (int, default 5) – Return this many descending sorted values.

  • keep ({'first', 'last', 'all'}, default 'first') –

    When there are duplicate values that cannot all fit in a Series of n elements:

    • first : return the first n occurrences in order of appearance.

    • last : return the last n occurrences in reverse order of appearance.

    • all : keep all occurrences. This can result in a Series of size larger than n.

Returns:

The n largest values in the Series, sorted in decreasing order.

Return type:

Series

See also

Series.nsmallest

Get the n smallest elements.

Series.sort_values

Sort Series by values.

Series.head

Return the first n rows.

Notes

Faster than .sort_values(ascending=False).head(n) for small n relative to the size of the Series object.

Examples

>>> countries_population = {
...     "Italy": 59000000,
...     "France": 65000000,
...     "Malta": 434000,
...     "Maldives": 434000,
...     "Brunei": 434000,
...     "Iceland": 337000,
...     "Nauru": 11300,
...     "Tuvalu": 11300,
...     "Anguilla": 11300,
...     "Montserrat": 5200,
... }
>>> s = pd.Series(countries_population)
>>> s
Italy       59000000
France      65000000
Malta         434000
Maldives      434000
Brunei        434000
Iceland       337000
Nauru          11300
Tuvalu         11300
Anguilla       11300
Montserrat      5200
dtype: int64

The n largest elements where n=5 by default.

>>> s.nlargest()
France      65000000
Italy       59000000
Malta         434000
Maldives      434000
Brunei        434000
dtype: int64

The n largest elements where n=3. Default keep value is ‘first’ so Malta will be kept.

>>> s.nlargest(3)
France    65000000
Italy     59000000
Malta       434000
dtype: int64

The n largest elements where n=3 and keeping the last duplicates. Brunei will be kept since it is the last with value 434000 based on the index order.

>>> s.nlargest(3, keep="last")
France      65000000
Italy       59000000
Brunei        434000
dtype: int64

The n largest elements where n=3 with all duplicates kept. Note that the returned Series has five elements due to the three duplicates.

>>> s.nlargest(3, keep="all")
France      65000000
Italy       59000000
Malta         434000
Maldives      434000
Brunei        434000
dtype: int64
notna()#

Detect existing (non-missing) values.

Return a boolean same-sized Series indicating if the values are not NA. Non-missing values get mapped to True. Characters such as empty strings '' or numpy.inf are not considered NA values. NA values, such as None or numpy.NaN, get mapped to False values.

Returns:

Mask of bool values for each element in Series that indicates whether an element is not an NA value.

Return type:

Series

See also

Series.isna

Detect missing values.

DataFrame.isna

Detect missing values.

Series.isnull

Alias of isna.

DataFrame.isnull

Alias of isna.

DataFrame.notna

Boolean inverse of isna.

DataFrame.notnull

Alias of notna.

Series.dropna

Omit axes labels with missing values.

DataFrame.dropna

Omit axes labels with missing values.

notna

Top-level notna.

Examples

Show which entries in a Series are not NA.

>>> ser = pd.Series([5, 6, np.nan])
>>> ser
0    5.0
1    6.0
2    NaN
dtype: float64
>>> ser.notna()
0     True
1     True
2    False
dtype: bool
notnull()#

Series.notnull is an alias for Series.notna.

Detect existing (non-missing) values.

Return a boolean same-sized object indicating if the values are not NA. Non-missing values get mapped to True. Characters such as empty strings '' or numpy.inf are not considered NA values. NA values, such as None or numpy.NaN, get mapped to False values.

Returns:

Mask of bool values for each element in Series/DataFrame that indicates whether an element is not an NA value.

Return type:

Series/DataFrame

See also

Series.notnull

Alias of notna.

DataFrame.notnull

Alias of notna.

Series.isna

Boolean inverse of notna.

DataFrame.isna

Boolean inverse of notna.

Series.dropna

Omit axes labels with missing values.

DataFrame.dropna

Omit axes labels with missing values.

notna

Top-level notna.

Examples

Show which entries in a DataFrame are not NA.

>>> df = pd.DataFrame(
...     dict(
...         age=[5, 6, np.nan],
...         born=[
...             pd.NaT,
...             pd.Timestamp("1939-05-27"),
...             pd.Timestamp("1940-04-25"),
...         ],
...         name=["Alfred", "Batman", ""],
...         toy=[None, "Batmobile", "Joker"],
...     )
... )
>>> df
   age       born    name        toy
0  5.0        NaT  Alfred        NaN
1  6.0 1939-05-27  Batman  Batmobile
2  NaN 1940-04-25              Joker
>>> df.notna()
     age   born  name    toy
0   True  False  True  False
1   True   True  True   True
2  False   True  True   True

Show which entries in a Series are not NA.

>>> ser = pd.Series([5, 6, np.nan])
>>> ser
0    5.0
1    6.0
2    NaN
dtype: float64
>>> ser.notna()
0     True
1     True
2    False
dtype: bool
nsmallest(n=5, keep='first')#

Return the smallest n elements.

Parameters:
  • n (int, default 5) – Return this many ascending sorted values.

  • keep ({'first', 'last', 'all'}, default 'first') –

    When there are duplicate values that cannot all fit in a Series of n elements:

    • first : return the first n occurrences in order of appearance.

    • last : return the last n occurrences in reverse order of appearance.

    • all : keep all occurrences. This can result in a Series of size larger than n.

Returns:

The n smallest values in the Series, sorted in increasing order.

Return type:

Series

See also

Series.nlargest

Get the n largest elements.

Series.sort_values

Sort Series by values.

Series.head

Return the first n rows.

Notes

Faster than .sort_values().head(n) for small n relative to the size of the Series object.

Examples

>>> countries_population = {
...     "Italy": 59000000,
...     "France": 65000000,
...     "Brunei": 434000,
...     "Malta": 434000,
...     "Maldives": 434000,
...     "Iceland": 337000,
...     "Nauru": 11300,
...     "Tuvalu": 11300,
...     "Anguilla": 11300,
...     "Montserrat": 5200,
... }
>>> s = pd.Series(countries_population)
>>> s
Italy       59000000
France      65000000
Brunei        434000
Malta         434000
Maldives      434000
Iceland       337000
Nauru          11300
Tuvalu         11300
Anguilla       11300
Montserrat      5200
dtype: int64

The n smallest elements where n=5 by default.

>>> s.nsmallest()
Montserrat    5200
Nauru        11300
Tuvalu       11300
Anguilla     11300
Iceland     337000
dtype: int64

The n smallest elements where n=3. Default keep value is ‘first’ so Nauru and Tuvalu will be kept.

>>> s.nsmallest(3)
Montserrat   5200
Nauru       11300
Tuvalu      11300
dtype: int64

The n smallest elements where n=3 and keeping the last duplicates. Anguilla and Tuvalu will be kept since they are the last with value 11300 based on the index order.

>>> s.nsmallest(3, keep="last")
Montserrat   5200
Anguilla    11300
Tuvalu      11300
dtype: int64

The n smallest elements where n=3 with all duplicates kept. Note that the returned Series has four elements due to the three duplicates.

>>> s.nsmallest(3, keep="all")
Montserrat   5200
Nauru       11300
Tuvalu      11300
Anguilla    11300
dtype: int64
plot#

alias of PlotAccessor

pop(item)#

Return item and drops from series. Raise KeyError if not found.

Parameters:

item (label) – Index of the element that needs to be removed.

Returns:

Value that is popped from series.

Return type:

scalar

See also

Series.drop

Drop specified values from Series.

Series.drop_duplicates

Return Series with duplicate values removed.

Examples

>>> ser = pd.Series([1, 2, 3])
>>> ser.pop(0)
1
>>> ser
1    2
2    3
dtype: int64
pow(other, level=None, fill_value=None, axis=0)#

Return Exponential power of series and other, element-wise (binary operator pow).

Equivalent to series ** other, but with support to substitute a fill_value for missing data in either one of the inputs.

Parameters:
  • other (object) – When a Series is provided, will align on indexes. For all other types, will behave the same as == but with possibly different results due to the other arguments.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (None or float value, default None (NaN)) – Fill existing missing (NaN) values, and any new element needed for successful Series alignment, with this value before computation. If data in both corresponding Series locations is missing the result of filling (at that location) will be missing.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

Returns:

The result of the operation.

Return type:

Series

See also

Series.rpow

Reverse of the Exponential power operator, see Python documentation for more details.

Examples

>>> a = pd.Series([1, 1, 1, np.nan], index=['a', 'b', 'c', 'd'])
>>> a
a    1.0
b    1.0
c    1.0
d    NaN
dtype: float64
>>> b = pd.Series([1, np.nan, 1, np.nan], index=['a', 'b', 'd', 'e'])
>>> b
a    1.0
b    NaN
d    1.0
e    NaN
dtype: float64
>>> a.pow(b, fill_value=0)
a    1.0
b    1.0
c    1.0
d    0.0
e    NaN
dtype: float64
prod(*, axis=None, skipna=True, numeric_only=False, min_count=0, **kwargs)#

Return the product of the values over the requested axis.

By default, missing values are skipped. To include them in the calculation, set skipna parameter to False.

Parameters:
  • axis ({index (0)}) –

    Axis for the function to be applied on. For Series this parameter is unused and defaults to 0.

    Warning

    The behavior of DataFrame.prod with axis=None is deprecated, in a future version this will reduce over both axes and return a scalar To retain the old behavior, pass axis=0 (or do not pass axis).

    Added in version 2.0.0.

  • skipna (bool, default True) – Exclude NA/null values when computing the result.

  • numeric_only (bool, default False) – Include only float, int, boolean columns. Not implemented for Series.

  • min_count (int, default 0) – The required number of valid values to perform the operation. If fewer than min_count non-NA values are present the result will be NA.

  • **kwargs – Additional keyword arguments to be passed to the function.

Returns:

Value containing the calculation referenced in the description.

Return type:

scalar

See also

Series.sum

Return the sum.

Series.min

Return the minimum.

Series.max

Return the maximum.

Series.idxmin

Return the index of the minimum.

Series.idxmax

Return the index of the maximum.

DataFrame.sum

Return the sum over the requested axis.

DataFrame.min

Return the minimum over the requested axis.

DataFrame.max

Return the maximum over the requested axis.

DataFrame.idxmin

Return the index of the minimum over the requested axis.

DataFrame.idxmax

Return the index of the maximum over the requested axis.

Examples

By default, the product of an empty or all-NA Series is 1

>>> pd.Series([], dtype="float64").prod()
1.0

This can be controlled with the min_count parameter

>>> pd.Series([], dtype="float64").prod(min_count=1)
nan

Thanks to the skipna parameter, min_count handles all-NA and empty series identically.

>>> pd.Series([np.nan]).prod()
1.0
>>> pd.Series([np.nan]).prod(min_count=1)
nan
product(*, axis=None, skipna=True, numeric_only=False, min_count=0, **kwargs)#

Return the product of the values over the requested axis.

By default, missing values are skipped. To include them in the calculation, set skipna parameter to False.

Parameters:
  • axis ({index (0)}) –

    Axis for the function to be applied on. For Series this parameter is unused and defaults to 0.

    Warning

    The behavior of DataFrame.prod with axis=None is deprecated, in a future version this will reduce over both axes and return a scalar To retain the old behavior, pass axis=0 (or do not pass axis).

    Added in version 2.0.0.

  • skipna (bool, default True) – Exclude NA/null values when computing the result.

  • numeric_only (bool, default False) – Include only float, int, boolean columns. Not implemented for Series.

  • min_count (int, default 0) – The required number of valid values to perform the operation. If fewer than min_count non-NA values are present the result will be NA.

  • **kwargs – Additional keyword arguments to be passed to the function.

Returns:

Value containing the calculation referenced in the description.

Return type:

scalar

See also

Series.sum

Return the sum.

Series.min

Return the minimum.

Series.max

Return the maximum.

Series.idxmin

Return the index of the minimum.

Series.idxmax

Return the index of the maximum.

DataFrame.sum

Return the sum over the requested axis.

DataFrame.min

Return the minimum over the requested axis.

DataFrame.max

Return the maximum over the requested axis.

DataFrame.idxmin

Return the index of the minimum over the requested axis.

DataFrame.idxmax

Return the index of the maximum over the requested axis.

Examples

By default, the product of an empty or all-NA Series is 1

>>> pd.Series([], dtype="float64").prod()
1.0

This can be controlled with the min_count parameter

>>> pd.Series([], dtype="float64").prod(min_count=1)
nan

Thanks to the skipna parameter, min_count handles all-NA and empty series identically.

>>> pd.Series([np.nan]).prod()
1.0
>>> pd.Series([np.nan]).prod(min_count=1)
nan
quantile(q: float = 0.5, interpolation: QuantileInterpolation = 'linear') float#
quantile(q: Sequence[float] | AnyArrayLike, interpolation: QuantileInterpolation = 'linear') Series
quantile(q: float | Sequence[float] | AnyArrayLike = 0.5, interpolation: QuantileInterpolation = 'linear') float | Series

Return value at the given quantile.

Parameters:
  • q (float or array-like, default 0.5 (50% quantile)) – The quantile(s) to compute, which can lie in range: 0 <= q <= 1.

  • interpolation ({'linear', 'lower', 'higher', 'midpoint', 'nearest'}) –

    This optional parameter specifies the interpolation method to use, when the desired quantile lies between two data points i and j:

    • linear: i + (j - i) * (x-i)/(j-i), where (x-i)/(j-i) is the fractional part of the index surrounded by i > j.

    • lower: i.

    • higher: j.

    • nearest: i or j whichever is nearest.

    • midpoint: (i + j) / 2.

Returns:

If q is an array, a Series will be returned where the index is q and the values are the quantiles, otherwise a float will be returned.

Return type:

float or Series

See also

core.window.Rolling.quantile

Calculate the rolling quantile.

numpy.percentile

Returns the q-th percentile(s) of the array elements.

Examples

>>> s = pd.Series([1, 2, 3, 4])
>>> s.quantile(0.5)
2.5
>>> s.quantile([0.25, 0.5, 0.75])
0.25    1.75
0.50    2.50
0.75    3.25
dtype: float64
radd(other, level=None, fill_value=None, axis=0)#

Return Addition of series and other, element-wise (binary operator radd).

Equivalent to other + series, but with support to substitute a fill_value for missing data in either one of the inputs.

Parameters:
  • other (object) – When a Series is provided, will align on indexes. For all other types, will behave the same as == but with possibly different results due to the other arguments.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (None or float value, default None (NaN)) – Fill existing missing (NaN) values, and any new element needed for successful Series alignment, with this value before computation. If data in both corresponding Series locations is missing the result of filling (at that location) will be missing.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

Returns:

The result of the operation.

Return type:

Series

See also

Series.add

Element-wise Addition, see Python documentation for more details.

Examples

>>> a = pd.Series([1, 1, 1, np.nan], index=['a', 'b', 'c', 'd'])
>>> a
a    1.0
b    1.0
c    1.0
d    NaN
dtype: float64
>>> b = pd.Series([1, np.nan, 1, np.nan], index=['a', 'b', 'd', 'e'])
>>> b
a    1.0
b    NaN
d    1.0
e    NaN
dtype: float64
>>> a.add(b, fill_value=0)
a    2.0
b    1.0
c    1.0
d    1.0
e    NaN
dtype: float64
rdiv(other, level=None, fill_value=None, axis=0)#

Return Floating division of series and other, element-wise (binary operator rtruediv).

Equivalent to other / series, but with support to substitute a fill_value for missing data in either one of the inputs.

Parameters:
  • other (object) – When a Series is provided, will align on indexes. For all other types, will behave the same as == but with possibly different results due to the other arguments.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (None or float value, default None (NaN)) – Fill existing missing (NaN) values, and any new element needed for successful Series alignment, with this value before computation. If data in both corresponding Series locations is missing the result of filling (at that location) will be missing.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

Returns:

The result of the operation.

Return type:

Series

See also

Series.truediv

Element-wise Floating division, see Python documentation for more details.

Examples

>>> a = pd.Series([1, 1, 1, np.nan], index=['a', 'b', 'c', 'd'])
>>> a
a    1.0
b    1.0
c    1.0
d    NaN
dtype: float64
>>> b = pd.Series([1, np.nan, 1, np.nan], index=['a', 'b', 'd', 'e'])
>>> b
a    1.0
b    NaN
d    1.0
e    NaN
dtype: float64
>>> a.divide(b, fill_value=0)
a    1.0
b    inf
c    inf
d    0.0
e    NaN
dtype: float64
rdivmod(other, level=None, fill_value=None, axis=0)#

Return Integer division and modulo of series and other, element-wise (binary operator rdivmod).

Equivalent to other divmod series, but with support to substitute a fill_value for missing data in either one of the inputs.

Parameters:
  • other (object) – When a Series is provided, will align on indexes. For all other types, will behave the same as == but with possibly different results due to the other arguments.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (None or float value, default None (NaN)) – Fill existing missing (NaN) values, and any new element needed for successful Series alignment, with this value before computation. If data in both corresponding Series locations is missing the result of filling (at that location) will be missing.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

Returns:

The result of the operation.

Return type:

2-Tuple of Series

See also

Series.divmod

Element-wise Integer division and modulo, see Python documentation for more details.

Examples

>>> a = pd.Series([1, 1, 1, np.nan], index=['a', 'b', 'c', 'd'])
>>> a
a    1.0
b    1.0
c    1.0
d    NaN
dtype: float64
>>> b = pd.Series([1, np.nan, 1, np.nan], index=['a', 'b', 'd', 'e'])
>>> b
a    1.0
b    NaN
d    1.0
e    NaN
dtype: float64
>>> a.divmod(b, fill_value=0)
(a    1.0
 b    inf
 c    inf
 d    0.0
 e    NaN
 dtype: float64,
 a    0.0
 b    NaN
 c    NaN
 d    0.0
 e    NaN
 dtype: float64)
reindex(index=None, *, axis=None, method=None, copy=<no_default>, level=None, fill_value=None, limit=None, tolerance=None)#

Conform Series to new index with optional filling logic.

Places NA/NaN in locations having no value in the previous index. A new object is produced unless the new index is equivalent to the current one and copy=False.

Parameters:
  • index (scalar, list-like, dict-like or function, optional) – A scalar, list-like, dict-like or functions transformations to apply to that axis’ values.

  • axis ({0 or 'index'}, default 0) – The axis to rename. For Series this parameter is unused and defaults to 0.

  • method ({None, 'backfill'/'bfill', 'pad'/'ffill', 'nearest'}) –

    Method to use for filling holes in reindexed DataFrame. Please note: this is only applicable to DataFrames/Series with a monotonically increasing/decreasing index.

    • None (default): don’t fill gaps

    • pad / ffill: Propagate last valid observation forward to next valid.

    • backfill / bfill: Use next valid observation to fill gap.

    • nearest: Use nearest valid observations to fill gap.

  • copy (bool, default False) –

    This keyword is now ignored; changing its value will have no impact on the method.

    Deprecated since version 3.0.0: This keyword is ignored and will be removed in pandas 4.0. Since pandas 3.0, this method always returns a new object using a lazy copy mechanism that defers copies until necessary (Copy-on-Write). See the user guide on Copy-on-Write for more details.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (scalar, default np.nan) – Value to use for missing values. Defaults to NaN, but can be any “compatible” value.

  • limit (int, default None) – Maximum number of consecutive elements to forward or backward fill.

  • tolerance (optional) –

    Maximum distance between original and new labels for inexact matches. The values of the index at the matching locations most satisfy the equation abs(index[indexer] - target) <= tolerance.

    Tolerance may be a scalar value, which applies the same tolerance to all values, or list-like, which applies variable tolerance per element. List-like includes list, tuple, array, Series, and must be the same size as the index and its dtype must exactly match the index’s type.

Returns:

Series with changed index.

Return type:

Series

See also

DataFrame.set_index

Set row labels.

DataFrame.reset_index

Remove row labels or move them to new columns.

DataFrame.reindex_like

Change to same indices as other DataFrame.

Examples

DataFrame.reindex supports two calling conventions

  • (index=index_labels, columns=column_labels, ...)

  • (labels, axis={'index', 'columns'}, ...)

We highly recommend using keyword arguments to clarify your intent.

Create a DataFrame with some fictional data.

>>> index = ["Firefox", "Chrome", "Safari", "IE10", "Konqueror"]
>>> columns = ["http_status", "response_time"]
>>> df = pd.DataFrame(
...     [[200, 0.04], [200, 0.02], [404, 0.07], [404, 0.08], [301, 1.0]],
...     columns=columns,
...     index=index,
... )
>>> df
           http_status  response_time
Firefox            200           0.04
Chrome             200           0.02
Safari             404           0.07
IE10               404           0.08
Konqueror          301           1.00

Create a new index and reindex the DataFrame. By default values in the new index that do not have corresponding records in the DataFrame are assigned NaN.

>>> new_index = ["Safari", "Iceweasel", "Comodo Dragon", "IE10", "Chrome"]
>>> df.reindex(new_index)
               http_status  response_time
Safari               404.0           0.07
Iceweasel              NaN            NaN
Comodo Dragon          NaN            NaN
IE10                 404.0           0.08
Chrome               200.0           0.02

We can fill in the missing values by passing a value to the keyword fill_value. Because the index is not monotonically increasing or decreasing, we cannot use arguments to the keyword method to fill the NaN values.

>>> df.reindex(new_index, fill_value=0)
               http_status  response_time
Safari                 404           0.07
Iceweasel                0           0.00
Comodo Dragon            0           0.00
IE10                   404           0.08
Chrome                 200           0.02
>>> df.reindex(new_index, fill_value="missing")
              http_status response_time
Safari                404          0.07
Iceweasel         missing       missing
Comodo Dragon     missing       missing
IE10                  404          0.08
Chrome                200          0.02

We can also reindex the columns.

>>> df.reindex(columns=["http_status", "user_agent"])
           http_status  user_agent
Firefox            200         NaN
Chrome             200         NaN
Safari             404         NaN
IE10               404         NaN
Konqueror          301         NaN

Or we can use “axis-style” keyword arguments

>>> df.reindex(["http_status", "user_agent"], axis="columns")
           http_status  user_agent
Firefox            200         NaN
Chrome             200         NaN
Safari             404         NaN
IE10               404         NaN
Konqueror          301         NaN

To further illustrate the filling functionality in reindex, we will create a DataFrame with a monotonically increasing index (for example, a sequence of dates).

>>> date_index = pd.date_range("1/1/2010", periods=6, freq="D")
>>> df2 = pd.DataFrame(
...     {"prices": [100, 101, np.nan, 100, 89, 88]}, index=date_index
... )
>>> df2
            prices
2010-01-01   100.0
2010-01-02   101.0
2010-01-03     NaN
2010-01-04   100.0
2010-01-05    89.0
2010-01-06    88.0

Suppose we decide to expand the DataFrame to cover a wider date range.

>>> date_index2 = pd.date_range("12/29/2009", periods=10, freq="D")
>>> df2.reindex(date_index2)
            prices
2009-12-29     NaN
2009-12-30     NaN
2009-12-31     NaN
2010-01-01   100.0
2010-01-02   101.0
2010-01-03     NaN
2010-01-04   100.0
2010-01-05    89.0
2010-01-06    88.0
2010-01-07     NaN

The index entries that did not have a value in the original data frame (for example, ‘2009-12-29’) are by default filled with NaN. If desired, we can fill in the missing values using one of several options.

For example, to back-propagate the last valid value to fill the NaN values, pass bfill as an argument to the method keyword.

>>> df2.reindex(date_index2, method="bfill")
            prices
2009-12-29   100.0
2009-12-30   100.0
2009-12-31   100.0
2010-01-01   100.0
2010-01-02   101.0
2010-01-03     NaN
2010-01-04   100.0
2010-01-05    89.0
2010-01-06    88.0
2010-01-07     NaN

Please note that the NaN value present in the original DataFrame (at index value 2010-01-03) will not be filled by any of the value propagation schemes. This is because filling while reindexing does not look at DataFrame values, but only compares the original and desired indexes. If you do want to fill in the NaN values present in the original DataFrame, use the fillna() method.

See the user guide for more.

rename(index: Renamer | Hashable | None = None, *, axis: Axis | None = None, copy: bool | ~pandas.api.typing.Literal[_NoDefault.no_default] = <no_default>, inplace: ~typing.Literal[True], level: Level | None = None, errors: IgnoreRaise = 'ignore') Series | None#
rename(index: Renamer | Hashable | None = None, *, axis: Axis | None = None, copy: bool | Literal[_NoDefault.no_default] = <no_default>, inplace: Literal[False] = False, level: Level | None = None, errors: IgnoreRaise = 'ignore') Series

Alter Series index labels or name.

Function / dict values must be unique (1-to-1). Labels not contained in a dict / Series will be left as-is. Extra labels listed don’t throw an error.

Alternatively, change Series.name with a scalar value.

See the user guide for more.

Parameters:
  • index (scalar, hashable sequence, dict-like or function optional) – Functions or dict-like are transformations to apply to the index. Scalar or hashable sequence-like will alter the Series.name attribute.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

  • copy (bool, default False) –

    This keyword is now ignored; changing its value will have no impact on the method.

    Deprecated since version 3.0.0: This keyword is ignored and will be removed in pandas 4.0. Since pandas 3.0, this method always returns a new object using a lazy copy mechanism that defers copies until necessary (Copy-on-Write). See the user guide on Copy-on-Write for more details.

  • inplace (bool, default False) – Whether to return a new Series. If True the value of copy is ignored.

  • level (int or level name, default None) – In case of MultiIndex, only rename labels in the specified level.

  • errors ({'ignore', 'raise'}, default 'ignore') – If ‘raise’, raise KeyError when a dict-like mapper or index contains labels that are not present in the index being transformed. If ‘ignore’, existing keys will be renamed and extra keys will be ignored.

Returns:

A shallow copy with index labels or name altered, or the same object if inplace=True and index is not a dict or callable else None.

Return type:

Series

See also

DataFrame.rename

Corresponding DataFrame method.

Series.rename_axis

Set the name of the axis.

Examples

>>> s = pd.Series([1, 2, 3])
>>> s
0    1
1    2
2    3
dtype: int64
>>> s.rename("my_name")  # scalar, changes Series.name
0    1
1    2
2    3
Name: my_name, dtype: int64
>>> s.rename(lambda x: x**2)  # function, changes labels
0    1
1    2
4    3
dtype: int64
>>> s.rename({1: 3, 2: 5})  # mapping, changes labels
0    1
3    2
5    3
dtype: int64
rename_axis(mapper: IndexLabel | lib.NoDefault = <no_default>, *, index=<no_default>, axis: Axis = 0, copy: bool | ~pandas.api.typing.Literal[_NoDefault.no_default] = <no_default>, inplace: ~typing.Literal[True]) None#
rename_axis(mapper: IndexLabel | lib.NoDefault = <no_default>, *, index=<no_default>, axis: Axis = 0, copy: bool | Literal[_NoDefault.no_default] = <no_default>, inplace: Literal[False] = False) Self
rename_axis(mapper: IndexLabel | lib.NoDefault = <no_default>, *, index=<no_default>, axis: Axis = 0, copy: bool | Literal[_NoDefault.no_default] = <no_default>, inplace: bool = False) Self | None

Set the name of the axis for the index.

Parameters:
  • mapper (scalar, list-like, optional) –

    Value to set the axis name attribute.

    Use either mapper and axis to specify the axis to target with mapper, or index.

  • index (scalar, list-like, dict-like or function, optional) – A scalar, list-like, dict-like or functions transformations to apply to that axis’ values.

  • axis ({0 or 'index'}, default 0) – The axis to rename. For Series this parameter is unused and defaults to 0.

  • copy (bool, default False) –

    This keyword is now ignored; changing its value will have no impact on the method.

    Deprecated since version 3.0.0: This keyword is ignored and will be removed in pandas 4.0. Since pandas 3.0, this method always returns a new object using a lazy copy mechanism that defers copies until necessary (Copy-on-Write). See the user guide on Copy-on-Write for more details.

  • inplace (bool, default False) – Modifies the object directly, instead of creating a new Series or DataFrame.

Returns:

The same type as the caller or None if inplace=True.

Return type:

Series, or None

See also

Series.rename

Alter Series index labels or name.

DataFrame.rename

Alter DataFrame index labels or name.

Index.rename

Set new names on index.

Examples

>>> s = pd.Series(["dog", "cat", "monkey"])
>>> s
0       dog
1       cat
2    monkey
dtype: str
>>> s.rename_axis("animal")
animal
0    dog
1    cat
2    monkey
dtype: str
reorder_levels(order)#

Rearrange index levels using input order.

May not drop or duplicate levels.

Parameters:

order (list of int representing new level order) – Reference level by number or key.

Returns:

Type of caller with index as MultiIndex (new object).

Return type:

Series

See also

DataFrame.reorder_levels

Rearrange index or column levels using input order.

Examples

>>> arrays = [
...     np.array(["dog", "dog", "cat", "cat", "bird", "bird"]),
...     np.array(["white", "black", "white", "black", "white", "black"]),
... ]
>>> s = pd.Series([1, 2, 3, 3, 5, 2], index=arrays)
>>> s
dog   white    1
      black    2
cat   white    3
      black    3
bird  white    5
      black    2
dtype: int64
>>> s.reorder_levels([1, 0])
white  dog     1
black  dog     2
white  cat     3
black  cat     3
white  bird    5
black  bird    2
dtype: int64
repeat(repeats, axis=None)#

Repeat elements of a Series.

Returns a new Series where each element of the current Series is repeated consecutively a given number of times.

Parameters:
  • repeats (int or array of ints) – The number of repetitions for each element. This should be a non-negative integer. Repeating 0 times will return an empty Series.

  • axis (None) – Unused. Parameter needed for compatibility with DataFrame.

Returns:

Newly created Series with repeated elements.

Return type:

Series

See also

Index.repeat

Equivalent function for Index.

numpy.repeat

Similar method for numpy.ndarray.

Examples

>>> s = pd.Series(["a", "b", "c"])
>>> s
0    a
1    b
2    c
dtype: str
>>> s.repeat(2)
0    a
0    a
1    b
1    b
2    c
2    c
dtype: str
>>> s.repeat([1, 2, 3])
0    a
1    b
1    b
2    c
2    c
2    c
dtype: str
reset_index(level: IndexLabel = None, *, drop: Literal[False] = False, name: Level = <no_default>, inplace: Literal[False] = False, allow_duplicates: bool = False) DataFrame#
reset_index(level: IndexLabel = None, *, drop: ~typing.Literal[True], name: Level = <no_default>, inplace: ~typing.Literal[False] = False, allow_duplicates: bool = False) Series
reset_index(level: IndexLabel = None, *, drop: bool = False, name: Level = <no_default>, inplace: ~typing.Literal[True], allow_duplicates: bool = False) None

Generate a new DataFrame or Series with the index reset.

This is useful when the index needs to be treated as a column, or when the index is meaningless and needs to be reset to the default before another operation.

Parameters:
  • level (int, str, tuple, or list, default optional) – For a Series with a MultiIndex, only remove the specified levels from the index. Removes all levels by default.

  • drop (bool, default False) – Just reset the index, without inserting it as a column in the new DataFrame.

  • name (object, optional) – The name to use for the column containing the original Series values. Uses self.name by default. This argument is ignored when drop is True.

  • inplace (bool, default False) – Modify the Series in place (do not create a new object).

  • allow_duplicates (bool, default False) – Allow duplicate column labels to be created.

Returns:

When drop is False (the default), a DataFrame is returned. The newly created columns will come first in the DataFrame, followed by the original Series values. When drop is True, a Series is returned. In either case, if inplace=True, no value is returned.

Return type:

Series or DataFrame or None

See also

DataFrame.reset_index

Analogous function for DataFrame.

Examples

>>> s = pd.Series(
...     [1, 2, 3, 4],
...     name="foo",
...     index=pd.Index(["a", "b", "c", "d"], name="idx"),
... )

Generate a DataFrame with default index.

>>> s.reset_index()
  idx  foo
0   a    1
1   b    2
2   c    3
3   d    4

To specify the name of the new column use name.

>>> s.reset_index(name="values")
  idx  values
0   a       1
1   b       2
2   c       3
3   d       4

To generate a new Series with the default set drop to True.

>>> s.reset_index(drop=True)
0    1
1    2
2    3
3    4
Name: foo, dtype: int64

The level parameter is interesting for Series with a multi-level index.

>>> arrays = [
...     np.array(["bar", "bar", "baz", "baz"]),
...     np.array(["one", "two", "one", "two"]),
... ]
>>> s2 = pd.Series(
...     range(4),
...     name="foo",
...     index=pd.MultiIndex.from_arrays(arrays, names=["a", "b"]),
... )

To remove a specific level from the Index, use level.

>>> s2.reset_index(level="a")
       a  foo
b
one  bar    0
two  bar    1
one  baz    2
two  baz    3

If level is not set, all levels are removed from the Index.

>>> s2.reset_index()
     a    b  foo
0  bar  one    0
1  bar  two    1
2  baz  one    2
3  baz  two    3
rfloordiv(other, level=None, fill_value=None, axis=0)#

Return Integer division of series and other, element-wise (binary operator rfloordiv).

Equivalent to other // series, but with support to substitute a fill_value for missing data in either one of the inputs.

Parameters:
  • other (object) – When a Series is provided, will align on indexes. For all other types, will behave the same as == but with possibly different results due to the other arguments.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (None or float value, default None (NaN)) – Fill existing missing (NaN) values, and any new element needed for successful Series alignment, with this value before computation. If data in both corresponding Series locations is missing the result of filling (at that location) will be missing.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

Returns:

The result of the operation.

Return type:

Series

See also

Series.floordiv

Element-wise Integer division, see Python documentation for more details.

Examples

>>> a = pd.Series([1, 1, 1, np.nan], index=['a', 'b', 'c', 'd'])
>>> a
a    1.0
b    1.0
c    1.0
d    NaN
dtype: float64
>>> b = pd.Series([1, np.nan, 1, np.nan], index=['a', 'b', 'd', 'e'])
>>> b
a    1.0
b    NaN
d    1.0
e    NaN
dtype: float64
>>> a.floordiv(b, fill_value=0)
a    1.0
b    inf
c    inf
d    0.0
e    NaN
dtype: float64
rmod(other, level=None, fill_value=None, axis=0)#

Return Modulo of series and other, element-wise (binary operator rmod).

Equivalent to other % series, but with support to substitute a fill_value for missing data in either one of the inputs.

Parameters:
  • other (object) – When a Series is provided, will align on indexes. For all other types, will behave the same as == but with possibly different results due to the other arguments.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (None or float value, default None (NaN)) – Fill existing missing (NaN) values, and any new element needed for successful Series alignment, with this value before computation. If data in both corresponding Series locations is missing the result of filling (at that location) will be missing.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

Returns:

The result of the operation.

Return type:

Series

See also

Series.mod

Element-wise Modulo, see Python documentation for more details.

Examples

>>> a = pd.Series([1, 1, 1, np.nan], index=['a', 'b', 'c', 'd'])
>>> a
a    1.0
b    1.0
c    1.0
d    NaN
dtype: float64
>>> b = pd.Series([1, np.nan, 1, np.nan], index=['a', 'b', 'd', 'e'])
>>> b
a    1.0
b    NaN
d    1.0
e    NaN
dtype: float64
>>> a.mod(b, fill_value=0)
a    0.0
b    NaN
c    NaN
d    0.0
e    NaN
dtype: float64
rmul(other, level=None, fill_value=None, axis=0)#

Return Multiplication of series and other, element-wise (binary operator rmul).

Equivalent to other * series, but with support to substitute a fill_value for missing data in either one of the inputs.

Parameters:
  • other (object) – When a Series is provided, will align on indexes. For all other types, will behave the same as == but with possibly different results due to the other arguments.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (None or float value, default None (NaN)) – Fill existing missing (NaN) values, and any new element needed for successful Series alignment, with this value before computation. If data in both corresponding Series locations is missing the result of filling (at that location) will be missing.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

Returns:

The result of the operation.

Return type:

Series

See also

Series.mul

Element-wise Multiplication, see Python documentation for more details.

Examples

>>> a = pd.Series([1, 1, 1, np.nan], index=['a', 'b', 'c', 'd'])
>>> a
a    1.0
b    1.0
c    1.0
d    NaN
dtype: float64
>>> b = pd.Series([1, np.nan, 1, np.nan], index=['a', 'b', 'd', 'e'])
>>> b
a    1.0
b    NaN
d    1.0
e    NaN
dtype: float64
>>> a.multiply(b, fill_value=0)
a    1.0
b    0.0
c    0.0
d    0.0
e    NaN
dtype: float64
round(decimals=0, *args, **kwargs)#

Round each value in a Series to the given number of decimals.

Parameters:
  • decimals (int, default 0) – Number of decimal places to round to. If decimals is negative, it specifies the number of positions to the left of the decimal point.

  • *args – Additional arguments and keywords have no effect but might be accepted for compatibility with NumPy.

  • **kwargs – Additional arguments and keywords have no effect but might be accepted for compatibility with NumPy.

Returns:

Rounded values of the Series.

Return type:

Series

See also

numpy.around

Round values of an np.array.

DataFrame.round

Round values of a DataFrame.

Series.dt.round

Round values of data to the specified freq.

Notes

For values exactly halfway between rounded decimal values, pandas rounds to the nearest even value (e.g. -0.5 and 0.5 round to 0.0, 1.5 and 2.5 round to 2.0, etc.).

Examples

>>> s = pd.Series([-0.5, 0.1, 2.5, 1.3, 2.7])
>>> s.round()
0   -0.0
1    0.0
2    2.0
3    1.0
4    3.0
dtype: float64
rpow(other, level=None, fill_value=None, axis=0)#

Return Exponential power of series and other, element-wise (binary operator rpow).

Equivalent to other ** series, but with support to substitute a fill_value for missing data in either one of the inputs.

Parameters:
  • other (object) – When a Series is provided, will align on indexes. For all other types, will behave the same as == but with possibly different results due to the other arguments.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (None or float value, default None (NaN)) – Fill existing missing (NaN) values, and any new element needed for successful Series alignment, with this value before computation. If data in both corresponding Series locations is missing the result of filling (at that location) will be missing.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

Returns:

The result of the operation.

Return type:

Series

See also

Series.pow

Element-wise Exponential power, see Python documentation for more details.

Examples

>>> a = pd.Series([1, 1, 1, np.nan], index=['a', 'b', 'c', 'd'])
>>> a
a    1.0
b    1.0
c    1.0
d    NaN
dtype: float64
>>> b = pd.Series([1, np.nan, 1, np.nan], index=['a', 'b', 'd', 'e'])
>>> b
a    1.0
b    NaN
d    1.0
e    NaN
dtype: float64
>>> a.pow(b, fill_value=0)
a    1.0
b    1.0
c    1.0
d    0.0
e    NaN
dtype: float64
rsub(other, level=None, fill_value=None, axis=0)#

Return Subtraction of series and other, element-wise (binary operator rsub).

Equivalent to other - series, but with support to substitute a fill_value for missing data in either one of the inputs.

Parameters:
  • other (object) – When a Series is provided, will align on indexes. For all other types, will behave the same as == but with possibly different results due to the other arguments.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (None or float value, default None (NaN)) – Fill existing missing (NaN) values, and any new element needed for successful Series alignment, with this value before computation. If data in both corresponding Series locations is missing the result of filling (at that location) will be missing.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

Returns:

The result of the operation.

Return type:

Series

See also

Series.sub

Element-wise Subtraction, see Python documentation for more details.

Examples

>>> a = pd.Series([1, 1, 1, np.nan], index=['a', 'b', 'c', 'd'])
>>> a
a    1.0
b    1.0
c    1.0
d    NaN
dtype: float64
>>> b = pd.Series([1, np.nan, 1, np.nan], index=['a', 'b', 'd', 'e'])
>>> b
a    1.0
b    NaN
d    1.0
e    NaN
dtype: float64
>>> a.subtract(b, fill_value=0)
a    0.0
b    1.0
c    1.0
d   -1.0
e    NaN
dtype: float64
rtruediv(other, level=None, fill_value=None, axis=0)#

Return Floating division of series and other, element-wise (binary operator rtruediv).

Equivalent to other / series, but with support to substitute a fill_value for missing data in either one of the inputs.

Parameters:
  • other (object) – When a Series is provided, will align on indexes. For all other types, will behave the same as == but with possibly different results due to the other arguments.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (None or float value, default None (NaN)) – Fill existing missing (NaN) values, and any new element needed for successful Series alignment, with this value before computation. If data in both corresponding Series locations is missing the result of filling (at that location) will be missing.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

Returns:

The result of the operation.

Return type:

Series

See also

Series.truediv

Element-wise Floating division, see Python documentation for more details.

Examples

>>> a = pd.Series([1, 1, 1, np.nan], index=['a', 'b', 'c', 'd'])
>>> a
a    1.0
b    1.0
c    1.0
d    NaN
dtype: float64
>>> b = pd.Series([1, np.nan, 1, np.nan], index=['a', 'b', 'd', 'e'])
>>> b
a    1.0
b    NaN
d    1.0
e    NaN
dtype: float64
>>> a.divide(b, fill_value=0)
a    1.0
b    inf
c    inf
d    0.0
e    NaN
dtype: float64
searchsorted(value, side='left', sorter=None)#

Find indices where elements should be inserted to maintain order.

Find the indices into a sorted Series self such that, if the corresponding elements in value were inserted before the indices, the order of self would be preserved.

Note

The Series must be monotonically sorted, otherwise wrong locations will likely be returned. Pandas does not check this for you.

Parameters:
  • value (array-like or scalar) – Values to insert into self.

  • side ({'left', 'right'}, optional) – If ‘left’, the index of the first suitable location found is given. If ‘right’, return the last such index. If there is no suitable index, return either 0 or N (where N is the length of self).

  • sorter (1-D array-like, optional) – Optional array of integer indices that sort self into ascending order. They are typically the result of np.argsort.

Returns:

A scalar or array of insertion points with the same shape as value.

Return type:

int or array of int

See also

sort_values

Sort by the values along either axis.

numpy.searchsorted

Similar method from NumPy.

Notes

Binary search is used to find the required insertion points.

Examples

>>> ser = pd.Series([1, 2, 3])
>>> ser
0    1
1    2
2    3
dtype: int64
>>> ser.searchsorted(4)
np.int64(3)
>>> ser.searchsorted([0, 4])
array([0, 3])
>>> ser.searchsorted([1, 3], side="left")
array([0, 2])
>>> ser.searchsorted([1, 3], side="right")
array([1, 3])
>>> ser = pd.Series(pd.to_datetime(["3/11/2000", "3/12/2000", "3/13/2000"]))
>>> ser
0   2000-03-11
1   2000-03-12
2   2000-03-13
dtype: datetime64[us]
>>> ser.searchsorted("3/14/2000")
np.int64(3)
>>> ser = pd.Categorical(
...     ["apple", "bread", "bread", "cheese", "milk"], ordered=True
... )
>>> ser
['apple', 'bread', 'bread', 'cheese', 'milk']
Categories (4, str): ['apple' < 'bread' < 'cheese' < 'milk']
>>> ser.searchsorted("bread")
np.int64(1)
>>> ser.searchsorted(["bread"], side="right")
array([3])

If the values are not monotonically sorted, wrong locations may be returned:

>>> ser = pd.Series([2, 1, 3])
>>> ser
0    2
1    1
2    3
dtype: int64
>>> ser.searchsorted(1)
0  # wrong result, correct would be 1
sem(*, axis=None, skipna=True, ddof=1, numeric_only=False, **kwargs)#

Return unbiased standard error of the mean over requested axis.

Normalized by N-1 by default. This can be changed using the ddof argument

Parameters:
  • axis ({index (0)}) – This parameter is unused and defaults to 0.

  • skipna (bool, default True) – Exclude NA/null values. If an entire row/column is NA, the result will be NA.

  • ddof (int, default 1) – Delta Degrees of Freedom. The divisor used in calculations is N - ddof, where N represents the number of elements.

  • numeric_only (bool, default False) – Include only float, int, boolean columns. Not implemented for Series.

  • **kwargs – Additional keywords have no effect but might be accepted for compatibility with NumPy.

Returns:

Unbiased standard error of the mean over requested axis.

Return type:

scalar or Series (if level specified)

See also

scipy.stats.sem

Compute standard error of the mean.

Series.std

Return sample standard deviation over requested axis.

Series.var

Return unbiased variance over requested axis.

Series.mean

Return the mean of the values over the requested axis.

Series.median

Return the median of the values over the requested axis.

Series.mode

Return the mode(s) of the Series.

Examples

>>> s = pd.Series([1, 2, 3])
>>> round(s.sem(), 6)
0.57735
set_axis(labels, *, axis=0, copy=<no_default>)#

Assign desired index to given axis.

Deprecated since version 3.0.0: This keyword is ignored and will be removed in pandas 4.0. Since pandas 3.0, this method always returns a new object using a lazy copy mechanism that defers copies until necessary (Copy-on-Write). See the user guide on Copy-on-Write for more details.

Indexes for row labels can be changed by assigning a list-like or Index.

Parameters:
  • labels (list-like or Index) – The values for the new index.

  • axis ({0 or 'index'}, default 0) – The axis to update. The value 0 identifies the rows. For Series this parameter is unused and defaults to 0.

  • copy (bool, default False) – This keyword is now ignored; changing its value will have no impact on the method.

Returns:

A shallow copy of the object with axis altered to the given index.

Return type:

Series

See also

Series.rename_axis

Alter the name of the index.

Examples

>>> s = pd.Series([1, 2, 3])
>>> s
0    1
1    2
2    3
dtype: int64
>>> s.set_axis(["a", "b", "c"], axis=0)
a    1
b    2
c    3
dtype: int64
skew(*, axis=0, skipna=True, numeric_only=False, **kwargs)#

Return unbiased skew over requested axis.

Normalized by N-1.

Parameters:
  • axis ({index (0)}) – This parameter is unused and defaults to 0.

  • skipna (bool, default True) – Exclude NA/null values when computing the result.

  • numeric_only (bool, default False) – Unused.

  • **kwargs – Additional keyword arguments to be passed to the function.

Returns:

Unbiased skew of the Series.

Return type:

scalar

See also

Series.var

Return unbiased variance over requested axis.

Series.std

Return unbiased standard deviation over requested axis.

Examples

>>> s = pd.Series([1, 2, 3])
>>> s.skew()
0.0
sort_index(*, axis: Axis = 0, level: IndexLabel = None, ascending: bool | Sequence[bool] = True, inplace: Literal[True], kind: SortKind = 'quicksort', na_position: NaPosition = 'last', sort_remaining: bool = True, ignore_index: bool = False, key: IndexKeyFunc = None) None#
sort_index(*, axis: Axis = 0, level: IndexLabel = None, ascending: bool | Sequence[bool] = True, inplace: Literal[False] = False, kind: SortKind = 'quicksort', na_position: NaPosition = 'last', sort_remaining: bool = True, ignore_index: bool = False, key: IndexKeyFunc = None) Series
sort_index(*, axis: Axis = 0, level: IndexLabel = None, ascending: bool | Sequence[bool] = True, inplace: bool = False, kind: SortKind = 'quicksort', na_position: NaPosition = 'last', sort_remaining: bool = True, ignore_index: bool = False, key: IndexKeyFunc = None) Series | None

Sort Series by index labels.

Returns a new Series sorted by label if inplace argument is False, otherwise updates the original series and returns None.

Parameters:
  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

  • level (int, optional) – If not None, sort on values in specified index level(s).

  • ascending (bool or list-like of bools, default True) – Sort ascending vs. descending. When the index is a MultiIndex the sort direction can be controlled for each level individually.

  • inplace (bool, default False) – If True, perform operation in-place.

  • kind ({'quicksort', 'mergesort', 'heapsort', 'stable'}, default 'quicksort') – Choice of sorting algorithm. See also numpy.sort() for more information. ‘mergesort’ and ‘stable’ are the only stable algorithms. For DataFrames, this option is only applied when sorting on a single column or label.

  • na_position ({'first', 'last'}, default 'last') – If ‘first’ puts NaNs at the beginning, ‘last’ puts NaNs at the end. Not implemented for MultiIndex.

  • sort_remaining (bool, default True) – If True and sorting by level and index is multilevel, sort by other levels too (in order) after sorting by specified level.

  • ignore_index (bool, default False) – If True, the resulting axis will be labeled 0, 1, …, n - 1.

  • key (callable, optional) – If not None, apply the key function to the index values before sorting. This is similar to the key argument in the builtin sorted() function, with the notable difference that this key function should be vectorized. It should expect an Index and return an Index of the same shape.

Returns:

The original Series sorted by the labels or None if inplace=True.

Return type:

Series or None

See also

DataFrame.sort_index

Sort DataFrame by the index.

DataFrame.sort_values

Sort DataFrame by the value.

Series.sort_values

Sort Series by the value.

Examples

>>> s = pd.Series(["a", "b", "c", "d"], index=[3, 2, 1, 4])
>>> s.sort_index()
1    c
2    b
3    a
4    d
dtype: str

Sort Descending

>>> s.sort_index(ascending=False)
4    d
3    a
2    b
1    c
dtype: str

By default NaNs are put at the end, but use na_position to place them at the beginning

>>> s = pd.Series(["a", "b", "c", "d"], index=[3, 2, 1, np.nan])
>>> s.sort_index(na_position="first")
NaN     d
 1.0    c
 2.0    b
 3.0    a
dtype: str

Specify index level to sort

>>> arrays = [
...     np.array(["qux", "qux", "foo", "foo", "baz", "baz", "bar", "bar"]),
...     np.array(["two", "one", "two", "one", "two", "one", "two", "one"]),
... ]
>>> s = pd.Series([1, 2, 3, 4, 5, 6, 7, 8], index=arrays)
>>> s.sort_index(level=1)
bar  one    8
baz  one    6
foo  one    4
qux  one    2
bar  two    7
baz  two    5
foo  two    3
qux  two    1
dtype: int64

Does not sort by remaining levels when sorting by levels

>>> s.sort_index(level=1, sort_remaining=False)
qux  one    2
foo  one    4
baz  one    6
bar  one    8
qux  two    1
foo  two    3
baz  two    5
bar  two    7
dtype: int64

Apply a key function before sorting

>>> s = pd.Series([1, 2, 3, 4], index=["A", "b", "C", "d"])
>>> s.sort_index(key=lambda x: x.str.lower())
A    1
b    2
C    3
d    4
dtype: int64
sort_values(*, axis: Axis = 0, ascending: bool | Sequence[bool] = True, inplace: Literal[False] = False, kind: SortKind = 'quicksort', na_position: NaPosition = 'last', ignore_index: bool = False, key: ValueKeyFunc = None) Series#
sort_values(*, axis: Axis = 0, ascending: bool | Sequence[bool] = True, inplace: Literal[True], kind: SortKind = 'quicksort', na_position: NaPosition = 'last', ignore_index: bool = False, key: ValueKeyFunc = None) None
sort_values(*, axis: Axis = 0, ascending: bool | Sequence[bool] = True, inplace: bool = False, kind: SortKind = 'quicksort', na_position: NaPosition = 'last', ignore_index: bool = False, key: ValueKeyFunc = None) Series | None

Sort by the values.

Sort a Series in ascending or descending order by some criterion.

Parameters:
  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

  • ascending (bool or list of bools, default True) – If True, sort values in ascending order, otherwise descending.

  • inplace (bool, default False) – If True, perform operation in-place.

  • kind ({'quicksort', 'mergesort', 'heapsort', 'stable'}, default 'quicksort') – Choice of sorting algorithm. See also numpy.sort() for more information. ‘mergesort’ and ‘stable’ are the only stable algorithms.

  • na_position ({'first' or 'last'}, default 'last') – Argument ‘first’ puts NaNs at the beginning, ‘last’ puts NaNs at the end.

  • ignore_index (bool, default False) – If True, the resulting axis will be labeled 0, 1, …, n - 1.

  • key (callable, optional) – If not None, apply the key function to the series values before sorting. This is similar to the key argument in the builtin sorted() function, with the notable difference that this key function should be vectorized. It should expect a Series and return an array-like.

Returns:

Series ordered by values or None if inplace=True.

Return type:

Series or None

See also

Series.sort_index

Sort by the Series indices.

DataFrame.sort_values

Sort DataFrame by the values along either axis.

DataFrame.sort_index

Sort DataFrame by indices.

Examples

>>> s = pd.Series([np.nan, 1, 3, 10, 5])
>>> s
0     NaN
1     1.0
2     3.0
3     10.0
4     5.0
dtype: float64

Sort values ascending order (default behavior)

>>> s.sort_values(ascending=True)
1     1.0
2     3.0
4     5.0
3    10.0
0     NaN
dtype: float64

Sort values descending order

>>> s.sort_values(ascending=False)
3    10.0
4     5.0
2     3.0
1     1.0
0     NaN
dtype: float64

Sort values putting NAs first

>>> s.sort_values(na_position="first")
0     NaN
1     1.0
2     3.0
4     5.0
3    10.0
dtype: float64

Sort a series of strings

>>> s = pd.Series(["z", "b", "d", "a", "c"])
>>> s
0    z
1    b
2    d
3    a
4    c
dtype: str
>>> s.sort_values()
3    a
1    b
4    c
2    d
0    z
dtype: str

Sort using a key function. Your key function will be given the Series of values and should return an array-like.

>>> s = pd.Series(["a", "B", "c", "D", "e"])
>>> s.sort_values()
1    B
3    D
0    a
2    c
4    e
dtype: str
>>> s.sort_values(key=lambda x: x.str.lower())
0    a
1    B
2    c
3    D
4    e
dtype: str

NumPy ufuncs work well here. For example, we can sort by the sin of the value

>>> s = pd.Series([-4, -2, 0, 2, 4])
>>> s.sort_values(key=np.sin)
1   -2
4    4
2    0
0   -4
3    2
dtype: int64

More complicated user-defined functions can be used, as long as they expect a Series and return an array-like

>>> s.sort_values(key=lambda x: np.tan(x.cumsum()))
0   -4
3    2
4    4
1   -2
2    0
dtype: int64
sparse#

alias of SparseAccessor

std(*, axis=None, skipna=True, ddof=1, numeric_only=False, **kwargs)#

Return sample standard deviation.

Normalized by N-1 by default. This can be changed using the ddof argument.

Parameters:
  • axis ({index (0)}) – This parameter is unused and defaults to 0.

  • skipna (bool, default True) – Exclude NA/null values. If Series is NA, the result will be NA.

  • ddof (int, default 1) – Delta Degrees of Freedom. The divisor used in calculations is N - ddof, where N represents the number of elements.

  • numeric_only (bool, default False) – Not implemented for Series.

  • **kwargs – Additional keywords have no effect but might be accepted for compatibility with NumPy.

Returns:

Standard deviation over all values in the Series.

Return type:

scalar

See also

numpy.std

Compute the standard deviation along the specified axis.

Series.var

Return unbiased variance over requested axis.

Series.sem

Return unbiased standard error of the mean over requested axis.

Series.mean

Return the mean of the values over the requested axis.

Series.median

Return the median of the values over the requested axis.

Series.mode

Return the mode(s) of the Series.

Examples

>>> s = pd.Series([1, 2, 3])
>>> s.std()
1.0

Alternatively, ddof=0 can be set to normalize by $N$ instead of $N-1$:

>>> s.std(ddof=0)
0.816496580927726
str#

alias of StringMethods

struct#

alias of StructAccessor

sub(other, level=None, fill_value=None, axis=0)#

Return Subtraction of series and other, element-wise (binary operator sub).

Equivalent to series - other, but with support to substitute a fill_value for missing data in either one of the inputs.

Parameters:
  • other (object) – When a Series is provided, will align on indexes. For all other types, will behave the same as == but with possibly different results due to the other arguments.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (None or float value, default None (NaN)) – Fill existing missing (NaN) values, and any new element needed for successful Series alignment, with this value before computation. If data in both corresponding Series locations is missing the result of filling (at that location) will be missing.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

Returns:

The result of the operation.

Return type:

Series

See also

Series.rsub

Reverse of the Subtraction operator, see Python documentation for more details.

Examples

>>> a = pd.Series([1, 1, 1, np.nan], index=['a', 'b', 'c', 'd'])
>>> a
a    1.0
b    1.0
c    1.0
d    NaN
dtype: float64
>>> b = pd.Series([1, np.nan, 1, np.nan], index=['a', 'b', 'd', 'e'])
>>> b
a    1.0
b    NaN
d    1.0
e    NaN
dtype: float64
>>> a.subtract(b, fill_value=0)
a    0.0
b    1.0
c    1.0
d   -1.0
e    NaN
dtype: float64
subtract(other, level=None, fill_value=None, axis=0)#

Return Subtraction of series and other, element-wise (binary operator sub).

Equivalent to series - other, but with support to substitute a fill_value for missing data in either one of the inputs.

Parameters:
  • other (object) – When a Series is provided, will align on indexes. For all other types, will behave the same as == but with possibly different results due to the other arguments.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (None or float value, default None (NaN)) – Fill existing missing (NaN) values, and any new element needed for successful Series alignment, with this value before computation. If data in both corresponding Series locations is missing the result of filling (at that location) will be missing.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

Returns:

The result of the operation.

Return type:

Series

See also

Series.rsub

Reverse of the Subtraction operator, see Python documentation for more details.

Examples

>>> a = pd.Series([1, 1, 1, np.nan], index=['a', 'b', 'c', 'd'])
>>> a
a    1.0
b    1.0
c    1.0
d    NaN
dtype: float64
>>> b = pd.Series([1, np.nan, 1, np.nan], index=['a', 'b', 'd', 'e'])
>>> b
a    1.0
b    NaN
d    1.0
e    NaN
dtype: float64
>>> a.subtract(b, fill_value=0)
a    0.0
b    1.0
c    1.0
d   -1.0
e    NaN
dtype: float64
sum(*, axis=None, skipna=True, numeric_only=False, min_count=0, **kwargs)#

Return the sum of the values over the requested axis.

This is equivalent to the method numpy.sum.

Parameters:
  • axis ({index (0)}) –

    Axis for the function to be applied on. For Series this parameter is unused and defaults to 0.

    Warning

    The behavior of DataFrame.sum with axis=None is deprecated, in a future version this will reduce over both axes and return a scalar To retain the old behavior, pass axis=0 (or do not pass axis).

    Added in version 2.0.0.

  • skipna (bool, default True) – Exclude NA/null values when computing the result.

  • numeric_only (bool, default False) – Include only float, int, boolean columns. Not implemented for Series.

  • min_count (int, default 0) – The required number of valid values to perform the operation. If fewer than min_count non-NA values are present the result will be NA.

  • **kwargs – Additional keyword arguments to be passed to the function.

Returns:

Sum of the values for the requested axis.

Return type:

scalar or Series (if level specified)

See also

numpy.sum

Equivalent numpy function for computing sum.

Series.mean

Mean of the values.

Series.median

Median of the values.

Series.std

Standard deviation of the values.

Series.var

Variance of the values.

Series.min

Minimum value.

Series.max

Maximum value.

Examples

>>> idx = pd.MultiIndex.from_arrays(
...     [["warm", "warm", "cold", "cold"], ["dog", "falcon", "fish", "spider"]],
...     names=["blooded", "animal"],
... )
>>> s = pd.Series([4, 2, 0, 8], name="legs", index=idx)
>>> s
blooded  animal
warm     dog       4
         falcon    2
cold     fish      0
         spider    8
Name: legs, dtype: int64
>>> s.sum()
14

By default, the sum of an empty or all-NA Series is 0.

>>> pd.Series([], dtype="float64").sum()  # min_count=0 is the default
0.0

This can be controlled with the min_count parameter. For example, if you’d like the sum of an empty series to be NaN, pass min_count=1.

>>> pd.Series([], dtype="float64").sum(min_count=1)
nan

Thanks to the skipna parameter, min_count handles all-NA and empty series identically.

>>> pd.Series([np.nan]).sum()
0.0
>>> pd.Series([np.nan]).sum(min_count=1)
nan
swaplevel(i=-2, j=-1, copy=<no_default>)#

Swap levels i and j in a MultiIndex.

Default is to swap the two innermost levels of the index.

Parameters:
  • i (int or str) – Levels of the indices to be swapped. Can pass level name as string.

  • j (int or str) – Levels of the indices to be swapped. Can pass level name as string.

  • copy (bool, default False) –

    This keyword is now ignored; changing its value will have no impact on the method.

    Deprecated since version 3.0.0: This keyword is ignored and will be removed in pandas 4.0. Since pandas 3.0, this method always returns a new object using a lazy copy mechanism that defers copies until necessary (Copy-on-Write). See the user guide on Copy-on-Write for more details.

Returns:

Series with levels swapped in MultiIndex.

Return type:

Series

See also

DataFrame.swaplevel

Swap levels i and j in a DataFrame.

Series.reorder_levels

Rearrange index levels using input order.

MultiIndex.swaplevel

Swap levels i and j in a MultiIndex.

Examples

>>> s = pd.Series(
...     ["A", "B", "A", "C"],
...     index=[
...         ["Final exam", "Final exam", "Coursework", "Coursework"],
...         ["History", "Geography", "History", "Geography"],
...         ["January", "February", "March", "April"],
...     ],
... )
>>> s
Final exam  History    January     A
            Geography  February    B
Coursework  History    March       A
            Geography  April       C
dtype: str

In the following example, we will swap the levels of the indices. Here, we will swap the levels column-wise, but levels can be swapped row-wise in a similar manner. Note that column-wise is the default behavior. By not supplying any arguments for i and j, we swap the last and second to last indices.

>>> s.swaplevel()
Final exam  January   History       A
            February  Geography     B
Coursework  March     History       A
            April     Geography     C
dtype: str

By supplying one argument, we can choose which index to swap the last index with. We can for example swap the first index with the last one as follows.

>>> s.swaplevel(0)
January     History     Final exam      A
February    Geography   Final exam      B
March       History     Coursework      A
April       Geography   Coursework      C
dtype: str

We can also define explicitly which indices we want to swap by supplying values for both i and j. Here, we for example swap the first and second indices.

>>> s.swaplevel(0, 1)
History     Final exam  January         A
Geography   Final exam  February        B
History     Coursework  March           A
Geography   Coursework  April           C
dtype: str
to_dict(*, into: type[MutableMappingT] | MutableMappingT) MutableMappingT#
to_dict(*, into: type[dict] = <class 'dict'>) dict

Convert Series to {label -> value} dict or dict-like object.

Parameters:

into (class, default dict) – The collections.abc.MutableMapping subclass to use as the return object. Can be the actual class or an empty instance of the mapping type you want. If you want a collections.defaultdict, you must pass it initialized.

Returns:

Key-value representation of Series.

Return type:

collections.abc.MutableMapping

See also

Series.to_list

Converts Series to a list of the values.

Series.to_numpy

Converts Series to NumPy ndarray.

Series.array

ExtensionArray of the data backing this Series.

Examples

>>> s = pd.Series([1, 2, 3, 4])
>>> s.to_dict()
{0: 1, 1: 2, 2: 3, 3: 4}
>>> from collections import OrderedDict, defaultdict
>>> s.to_dict(into=OrderedDict)
OrderedDict([(0, 1), (1, 2), (2, 3), (3, 4)])
>>> dd = defaultdict(list)
>>> s.to_dict(into=dd)
defaultdict(<class 'list'>, {0: 1, 1: 2, 2: 3, 3: 4})
to_frame(name=<no_default>)#

Convert Series to DataFrame.

Parameters:

name (object, optional) – The passed name should substitute for the series name (if it has one).

Returns:

DataFrame representation of Series.

Return type:

DataFrame

See also

Series.to_dict

Convert Series to dict object.

Examples

>>> s = pd.Series(["a", "b", "c"], name="vals")
>>> s.to_frame()
  vals
0    a
1    b
2    c
to_markdown(buf: None = None, *, mode: str = 'wt', index: bool = True, storage_options: StorageOptions | None = None, **kwargs) str#
to_markdown(buf: IO[str], *, mode: str = 'wt', index: bool = True, storage_options: StorageOptions | None = None, **kwargs) None
to_markdown(buf: IO[str] | None, *, mode: str = 'wt', index: bool = True, storage_options: StorageOptions | None = None, **kwargs) str | None

Print Series in Markdown-friendly format.

Parameters:
  • buf (str, Path or StringIO-like, optional, default None) – Buffer to write to. If None, the output is returned as a string.

  • mode (str, optional) – Mode in which file is opened, “wt” by default.

  • index (bool, optional, default True) – Add index (row) labels.

  • storage_options (dict, optional) –

    Extra options that make sense for a particular storage connection, e.g. host, port, username, password, etc. For HTTP(S) URLs the key-value pairs are forwarded to urllib.request.Request as header options. For other URLs (e.g. starting with “s3://”, and “gcs://”) the key-value pairs are forwarded to fsspec.open. Please see fsspec and urllib for more details, and for more examples on storage options refer here.

  • **kwargs

    These parameters will be passed to tabulate.

Returns:

Series in Markdown-friendly format.

Return type:

str

See also

Series.to_frame

Rrite a text representation of object to the system clipboard.

Series.to_latex

Render Series to LaTeX-formatted table.

Notes

Requires the tabulate package.

Examples
>>> s = pd.Series(["elk", "pig", "dog", "quetzal"], name="animal")
>>> print(s.to_markdown())
|    | animal   |
|---:|:---------|
|  0 | elk      |
|  1 | pig      |
|  2 | dog      |
|  3 | quetzal  |

Output markdown with a tabulate option.

>>> print(s.to_markdown(tablefmt="grid"))
+----+----------+
|    | animal   |
+====+==========+
|  0 | elk      |
+----+----------+
|  1 | pig      |
+----+----------+
|  2 | dog      |
+----+----------+
|  3 | quetzal  |
+----+----------+
to_period(freq=None, copy=<no_default>)#

Convert Series from DatetimeIndex to PeriodIndex.

Parameters:
  • freq (str, default None) – Frequency associated with the PeriodIndex.

  • copy (bool, default False) –

    This keyword is now ignored; changing its value will have no impact on the method.

    Deprecated since version 3.0.0: This keyword is ignored and will be removed in pandas 4.0. Since pandas 3.0, this method always returns a new object using a lazy copy mechanism that defers copies until necessary (Copy-on-Write). See the user guide on Copy-on-Write for more details.

Returns:

Series with index converted to PeriodIndex.

Return type:

Series

See also

DataFrame.to_period

Equivalent method for DataFrame.

Series.dt.to_period

Convert DateTime column values.

Examples

>>> idx = pd.DatetimeIndex(["2023", "2024", "2025"])
>>> s = pd.Series([1, 2, 3], index=idx)
>>> s = s.to_period()
>>> s
2023    1
2024    2
2025    3
Freq: Y-DEC, dtype: int64

Viewing the index

>>> s.index
PeriodIndex(['2023', '2024', '2025'], dtype='period[Y-DEC]')
to_string(buf: None = None, *, na_rep: str = 'NaN', float_format: str | None = None, header: bool = True, index: bool = True, length: bool = False, dtype=False, name=False, max_rows: int | None = None, min_rows: int | None = None) str#
to_string(buf: FilePath | WriteBuffer[str], *, na_rep: str = 'NaN', float_format: str | None = None, header: bool = True, index: bool = True, length: bool = False, dtype=False, name=False, max_rows: int | None = None, min_rows: int | None = None) None

Render a string representation of the Series.

Parameters:
  • buf (StringIO-like, optional) – Buffer to write to.

  • na_rep (str, optional) – String representation of NaN to use, default ‘NaN’.

  • float_format (one-parameter function, optional) – Formatter function to apply to columns’ elements if they are floats, default None.

  • header (bool, default True) – Add the Series header (index name).

  • index (bool, optional) – Add index (row) labels, default True.

  • length (bool, default False) – Add the Series length.

  • dtype (bool, default False) – Add the Series dtype.

  • name (bool, default False) – Add the Series name if not None.

  • max_rows (int, optional) – Maximum number of rows to show before truncating. If None, show all.

  • min_rows (int, optional) – The number of rows to display in a truncated repr (when number of rows is above max_rows).

Returns:

String representation of Series if buf=None, otherwise None.

Return type:

str or None

See also

Series.to_dict

Convert Series to dict object.

Series.to_frame

Convert Series to DataFrame object.

Series.to_markdown

Print Series in Markdown-friendly format.

Series.to_timestamp

Cast to DatetimeIndex of Timestamps.

Examples

>>> ser = pd.Series([1, 2, 3]).to_string()
>>> ser
'0    1\n1    2\n2    3'
to_timestamp(freq=None, how='start', copy=<no_default>)#

Cast to DatetimeIndex of Timestamps, at beginning of period.

This can be changed to the end of the period, by specifying how=”e”.

Parameters:
  • freq (str, default frequency of PeriodIndex) – Desired frequency.

  • how ({'s', 'e', 'start', 'end'}) – Convention for converting period to timestamp; start of period vs. end.

  • copy (bool, default False) –

    This keyword is now ignored; changing its value will have no impact on the method.

    Deprecated since version 3.0.0: This keyword is ignored and will be removed in pandas 4.0. Since pandas 3.0, this method always returns a new object using a lazy copy mechanism that defers copies until necessary (Copy-on-Write). See the user guide on Copy-on-Write for more details.

Returns:

Series with the PeriodIndex cast to DatetimeIndex.

Return type:

Series with DatetimeIndex

See also

Series.to_period

Inverse method to cast DatetimeIndex to PeriodIndex.

DataFrame.to_timestamp

Equivalent method for DataFrame.

Examples

>>> idx = pd.PeriodIndex(["2023", "2024", "2025"], freq="Y")
>>> s1 = pd.Series([1, 2, 3], index=idx)
>>> s1
2023    1
2024    2
2025    3
Freq: Y-DEC, dtype: int64

The resulting frequency of the Timestamps is YearBegin

>>> s1 = s1.to_timestamp()
>>> s1
2023-01-01    1
2024-01-01    2
2025-01-01    3
Freq: YS-JAN, dtype: int64

Using freq which is the offset that the Timestamps will have

>>> s2 = pd.Series([1, 2, 3], index=idx)
>>> s2 = s2.to_timestamp(freq="M")
>>> s2
2023-01-31    1
2024-01-31    2
2025-01-31    3
Freq: YE-JAN, dtype: int64
transform(func, axis=0, *args, **kwargs)#

Call func on self producing a Series with the same axis shape as self.

Parameters:
  • func (function, str, list-like or dict-like) –

    Function to use for transforming the data. If a function, must either work when passed a Series or when passed to Series.apply. If func is both list-like and dict-like, dict-like behavior takes precedence.

    Accepted combinations are:

    • function

    • string function name

    • list-like of functions and/or function names, e.g. [np.exp, 'sqrt']

    • dict-like of axis labels -> functions, function names or list-like of such

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

  • *args – Positional arguments to pass to func.

  • **kwargs – Keyword arguments to pass to func.

Returns:

A Series that must have the same length as self.

Return type:

Series

:raises ValueError : If the returned Series has a different length than self.:

See also

Series.agg

Only perform aggregating type operations.

Series.apply

Invoke function on a Series.

Notes

Functions that mutate the passed object can produce unexpected behavior or errors and are not supported. See Mutating with User Defined Function (UDF) methods for more details.

Examples

>>> df = pd.DataFrame({"A": range(3), "B": range(1, 4)})
>>> df
A  B
0  0  1
1  1  2
2  2  3
>>> df.transform(lambda x: x + 1)
A  B
0  1  2
1  2  3
2  3  4

Even though the resulting Series must have the same length as the input Series, it is possible to provide several input functions:

>>> s = pd.Series(range(3))
>>> s
0    0
1    1
2    2
dtype: int64
>>> s.transform([np.sqrt, np.exp])
    sqrt        exp
0  0.000000   1.000000
1  1.000000   2.718282
2  1.414214   7.389056

You can call transform on a GroupBy object:

>>> df = pd.DataFrame(
...     {
...         "Date": [
...             "2015-05-08",
...             "2015-05-07",
...             "2015-05-06",
...             "2015-05-05",
...             "2015-05-08",
...             "2015-05-07",
...             "2015-05-06",
...             "2015-05-05",
...         ],
...         "Data": [5, 8, 6, 1, 50, 100, 60, 120],
...     }
... )
>>> df
        Date  Data
0  2015-05-08     5
1  2015-05-07     8
2  2015-05-06     6
3  2015-05-05     1
4  2015-05-08    50
5  2015-05-07   100
6  2015-05-06    60
7  2015-05-05   120
>>> df.groupby("Date")["Data"].transform("sum")
0     55
1    108
2     66
3    121
4     55
5    108
6     66
7    121
Name: Data, dtype: int64
>>> df = pd.DataFrame(
...     {
...         "c": [1, 1, 1, 2, 2, 2, 2],
...         "type": ["m", "n", "o", "m", "m", "n", "n"],
...     }
... )
>>> df
c type
0  1    m
1  1    n
2  1    o
3  2    m
4  2    m
5  2    n
6  2    n
>>> df["size"] = df.groupby("c")["type"].transform(len)
>>> df
c type size
0  1    m    3
1  1    n    3
2  1    o    3
3  2    m    4
4  2    m    4
5  2    n    4
6  2    n    4
truediv(other, level=None, fill_value=None, axis=0)#

Return Floating division of series and other, element-wise (binary operator truediv).

Equivalent to series / other, but with support to substitute a fill_value for missing data in either one of the inputs.

Parameters:
  • other (Series or scalar value) – Series with which to compute division.

  • level (int or name) – Broadcast across a level, matching Index values on the passed MultiIndex level.

  • fill_value (None or float value, default None (NaN)) – Fill existing missing (NaN) values, and any new element needed for successful Series alignment, with this value before computation. If data in both corresponding Series locations is missing the result of filling (at that location) will be missing.

  • axis ({0 or 'index'}) – Unused. Parameter needed for compatibility with DataFrame.

Returns:

The result of the operation.

Return type:

Series

See also

Series.rtruediv

Reverse of the Floating division operator, see Python documentation for more details.

Examples

>>> a = pd.Series([1, 1, 1, np.nan], index=["a", "b", "c", "d"])
>>> a
a    1.0
b    1.0
c    1.0
d    NaN
dtype: float64
>>> b = pd.Series([1, np.nan, 1, np.nan], index=["a", "b", "d", "e"])
>>> b
a    1.0
b    NaN
d    1.0
e    NaN
dtype: float64
>>> a.divide(b, fill_value=0)
a    1.0
b    inf
c    inf
d    0.0
e    NaN
dtype: float64
unique()#

Return unique values of Series object.

Uniques are returned in order of appearance. Hash table-based unique, therefore does NOT sort.

Returns:

The unique values returned as a NumPy array. See Notes.

Return type:

ndarray or ExtensionArray

See also

Series.drop_duplicates

Return Series with duplicate values removed.

unique

Top-level unique method for any 1-d array-like object.

Index.unique

Return Index with unique values from an Index object.

Notes

Returns the unique values as a NumPy array. In case of an extension-array backed Series, a new ExtensionArray of that type with just the unique values is returned. This includes

  • Categorical

  • Period

  • Datetime with Timezone

  • Datetime without Timezone

  • Timedelta

  • Interval

  • Sparse

  • IntegerNA

See Examples section.

Examples

>>> pd.Series([2, 1, 3, 3], name="A").unique()
array([2, 1, 3])
>>> pd.Series([pd.Timestamp("2016-01-01") for _ in range(3)]).unique()
<DatetimeArray>
['2016-01-01 00:00:00']
Length: 1, dtype: datetime64[us]
>>> pd.Series(
...     [pd.Timestamp("2016-01-01", tz="US/Eastern") for _ in range(3)]
... ).unique()
<DatetimeArray>
['2016-01-01 00:00:00-05:00']
Length: 1, dtype: datetime64[us, US/Eastern]

A Categorical will return categories in the order of appearance and with the same dtype.

>>> pd.Series(pd.Categorical(list("baabc"))).unique()
['b', 'a', 'c']
Categories (3, str): ['a', 'b', 'c']
>>> pd.Series(
...     pd.Categorical(list("baabc"), categories=list("abc"), ordered=True)
... ).unique()
['b', 'a', 'c']
Categories (3, str): ['a' < 'b' < 'c']
unstack(level=-1, fill_value=None, sort=True)#

Unstack, also known as pivot, Series with MultiIndex to produce DataFrame.

Parameters:
  • level (int, str, or list of these, default last level) – Level(s) to unstack, can pass level name.

  • fill_value (scalar value, default None) – Value to use when replacing NaN values.

  • sort (bool, default True) – Sort the level(s) in the resulting MultiIndex columns.

Returns:

Unstacked Series.

Return type:

DataFrame

See also

DataFrame.unstack

Pivot the MultiIndex of a DataFrame.

Notes

Reference the user guide for more examples.

Examples

>>> s = pd.Series(
...     [1, 2, 3, 4],
...     index=pd.MultiIndex.from_product([["one", "two"], ["a", "b"]]),
... )
>>> s
one  a    1
     b    2
two  a    3
     b    4
dtype: int64
>>> s.unstack(level=-1)
     a  b
one  1  2
two  3  4
>>> s.unstack(level=0)
   one  two
a    1    3
b    2    4
update(other)#

Modify Series in place using values from passed Series.

Uses non-NA values from passed Series to make updates. Aligns on index.

Parameters:

other (Series, or object coercible into Series) – Other Series that provides values to update the current Series.

Return type:

None

See also

Series.combine

Perform element-wise operation on two Series using a given function.

Series.transform

Modify a Series using a function.

Examples

>>> s = pd.Series([1, 2, 3])
>>> s.update(pd.Series([4, 5, 6]))
>>> s
0    4
1    5
2    6
dtype: int64
>>> s = pd.Series(["a", "b", "c"])
>>> s.update(pd.Series(["d", "e"], index=[0, 2]))
>>> s
0    d
1    b
2    e
dtype: str
>>> s = pd.Series([1, 2, 3])
>>> s.update(pd.Series([4, 5, 6, 7, 8]))
>>> s
0    4
1    5
2    6
dtype: int64

If other contains NaNs the corresponding values are not updated in the original Series.

>>> s = pd.Series([1, 2, 3])
>>> s.update(pd.Series([4, np.nan, 6]))
>>> s
0    4
1    2
2    6
dtype: int64

other can also be a non-Series object type that is coercible into a Series

>>> s = pd.Series([1, 2, 3])
>>> s.update([4, np.nan, 6])
>>> s
0    4
1    2
2    6
dtype: int64
>>> s = pd.Series([1, 2, 3])
>>> s.update({1: 9})
>>> s
0    1
1    9
2    3
dtype: int64
property values#

Return Series as ndarray or ndarray-like depending on the dtype.

Warning

We recommend using Series.array or Series.to_numpy(), depending on whether you need a reference to the underlying data or a NumPy array.

Return type:

numpy.ndarray or ndarray-like

See also

Series.array

Reference to the underlying data.

Series.to_numpy

A NumPy array representing the underlying data.

Examples

>>> pd.Series([1, 2, 3]).values
array([1, 2, 3])
>>> pd.Series(list("aabc")).values
<ArrowStringArray>
['a', 'a', 'b', 'c']
Length: 4, dtype: str
>>> pd.Series(list("aabc")).astype("category").values
['a', 'a', 'b', 'c']
Categories (3, str): ['a', 'b', 'c']

Timezone aware datetime data is converted to UTC:

>>> pd.Series(pd.date_range("20130101", periods=3, tz="US/Eastern")).values
array(['2013-01-01T05:00:00.000000',
       '2013-01-02T05:00:00.000000',
       '2013-01-03T05:00:00.000000'], dtype='datetime64[us]')
var(*, axis=None, skipna=True, ddof=1, numeric_only=False, **kwargs)#

Return unbiased variance over requested axis.

Normalized by N-1 by default. This can be changed using the ddof argument.

Parameters:
  • axis ({index (0)}) –

    For Series this parameter is unused and defaults to 0.

    Warning

    The behavior of DataFrame.var with axis=None is deprecated, in a future version this will reduce over both axes and return a scalar To retain the old behavior, pass axis=0 (or do not pass axis).

  • skipna (bool, default True) – Exclude NA/null values. If an entire row/column is NA, the result will be NA.

  • ddof (int, default 1) – Delta Degrees of Freedom. The divisor used in calculations is N - ddof, where N represents the number of elements.

  • numeric_only (bool, default False) – Include only float, int, boolean columns. Not implemented for Series.

  • **kwargs – Additional keywords passed.

Returns:

Unbiased variance over requested axis.

Return type:

scalar or Series (if level specified)

See also

numpy.var

Equivalent function in NumPy.

Series.std

Returns the standard deviation of the Series.

DataFrame.var

Returns the variance of the DataFrame.

DataFrame.std

Return standard deviation of the values over the requested axis.

Examples

>>> df = pd.DataFrame(
...     {
...         "person_id": [0, 1, 2, 3],
...         "age": [21, 25, 62, 43],
...         "height": [1.61, 1.87, 1.49, 2.01],
...     }
... ).set_index("person_id")
>>> df
           age  height
person_id
0           21    1.61
1           25    1.87
2           62    1.49
3           43    2.01
>>> df.var()
age       352.916667
height      0.056367
dtype: float64

Alternatively, ddof=0 can be set to normalize by N instead of N-1:

>>> df.var(ddof=0)
age       264.687500
height      0.042275
dtype: float64
pycsamt.api.typing.SeriesLike#

Object behaving like a pandas Series.

class pycsamt.api.typing.Shape[source]#

Bases: _CompatAlias

Shape marker kept for legacy annotations.

class pycsamt.api.typing.Sub[source]#

Bases: _CompatAlias

Subset marker for legacy array annotations.

class pycsamt.api.typing.SupportsArray(*args, **kwargs)[source]#

Bases: Protocol

Protocol for objects convertible to NumPy arrays.

class pycsamt.api.typing.SupportsFloat(*args, **kwargs)#

Bases: Protocol

An ABC with one abstract method __float__.

class pycsamt.api.typing.SupportsInt(*args, **kwargs)#

Bases: Protocol

An ABC with one abstract method __int__.

pycsamt.api.typing.Text#

alias of str

pycsamt.api.typing.Type#

alias of type

pycsamt.api.typing.Tuple#

alias of tuple

class pycsamt.api.typing.ZO[source]#

Bases: _CompatAlias

Impedance tensor object marker.

pycsamt.api.typing.overload(func)#

Decorator for overloaded functions/methods.

In a stub file, place two or more stub definitions for the same function in a row, each decorated with @overload.

For example:

@overload
def utf8(value: None) -> None: ...
@overload
def utf8(value: bytes) -> bytes: ...
@overload
def utf8(value: str) -> bytes: ...

In a non-stub file (i.e. a regular .py file), do the same but follow it with an implementation. The implementation should not be decorated with @overload:

@overload
def utf8(value: None) -> None: ...
@overload
def utf8(value: bytes) -> bytes: ...
@overload
def utf8(value: str) -> bytes: ...
def utf8(value):
    ...  # implementation goes here

The overloads for a function can be retrieved at runtime using the get_overloads() function.