.. _indexing: .. currentmodule:: pandas .. ipython:: python :suppress: import numpy as np import random np.random.seed(123456) from pandas import * import pandas as pd randn = np.random.randn randint = np.random.randint np.set_printoptions(precision=4, suppress=True) *************************** Indexing and selecting data *************************** The axis labeling information in pandas objects serves many purposes: - Identifies data (i.e. provides *metadata*) using known indicators, important for for analysis, visualization, and interactive console display - Enables automatic and explicit data alignment - Allows intuitive getting and setting of subsets of the data set In this section / chapter, we will focus on the final point: namely, how to slice, dice, and generally get and set subsets of pandas objects. The primary focus will be on Series and DataFrame as they have received more development attention in this area. Expect more work to be invested higher-dimensional data structures (including Panel) in the future, especially in label-based advanced indexing. .. _indexing.basics: Basics ------ As mentioned when introducing the data structures in the :ref:`last section `, the primary function of indexing with ``[]`` (a.k.a. ``__getitem__`` for those familiar with implementing class behavior in Python) is selecting out lower-dimensional slices. Thus, - **Series**: ``series[label]`` returns a scalar value - **DataFrame**: ``frame[colname]`` returns a Series corresponding to the passed column name - **Panel**: ``panel[itemname]`` returns a DataFrame corresponding to the passed item name Here we construct a simple time series data set to use for illustrating the indexing functionality: .. ipython:: python dates = np.asarray(date_range('1/1/2000', periods=8)) df = DataFrame(randn(8, 4), index=dates, columns=['A', 'B', 'C', 'D']) df panel = Panel({'one' : df, 'two' : df - df.mean()}) panel .. note:: None of the indexing functionality is time series specific unless specifically stated. Thus, as per above, we have the most basic indexing using ``[]``: .. ipython:: python s = df['A'] s[dates[5]] panel['two'] .. _indexing.basics.get_value: Fast scalar value getting and setting ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Since indexing with ``[]`` must handle a lot of cases (single-label access, slicing, boolean indexing, etc.), it has a bit of overhead in order to figure out what you're asking for. If you only want to access a scalar value, the fastest way is to use the ``get_value`` method, which is implemented on all of the data structures: .. ipython:: python s.get_value(dates[5]) df.get_value(dates[5], 'A') There is an analogous ``set_value`` method which has the additional capability of enlarging an object. This method *always* returns a reference to the object it modified, which in the case of enlargement, will be a **new object**: .. ipython:: python df.set_value(dates[5], 'E', 7) Additional Column Access ~~~~~~~~~~~~~~~~~~~~~~~~ .. _indexing.columns.multiple: .. _indexing.df_cols: You may access a column on a dataframe directly as an attribute: .. ipython:: python df.A If you are using the IPython environment, you may also use tab-completion to see the accessible columns of a DataFrame. You can pass a list of columns to ``[]`` to select columns in that order: If a column is not contained in the DataFrame, an exception will be raised. Multiple columns can also be set in this manner: .. ipython:: python df df[['B', 'A']] = df[['A', 'B']] df You may find this useful for applying a transform (in-place) to a subset of the columns. Data slices on other axes ~~~~~~~~~~~~~~~~~~~~~~~~~ It's certainly possible to retrieve data slices along the other axes of a DataFrame or Panel. We tend to refer to these slices as *cross-sections*. DataFrame has the ``xs`` function for retrieving rows as Series and Panel has the analogous ``major_xs`` and ``minor_xs`` functions for retrieving slices as DataFrames for a given ``major_axis`` or ``minor_axis`` label, respectively. .. ipython:: python date = dates[5] df.xs(date) panel.major_xs(date) panel.minor_xs('A') Slicing ranges ~~~~~~~~~~~~~~ The most robust and consistent way of slicing ranges along arbitrary axes is described in the :ref:`Advanced indexing ` section detailing the ``.ix`` method. For now, we explain the semantics of slicing using the ``[]`` operator. With Series, the syntax works exactly as with an ndarray, returning a slice of the values and the corresponding labels: .. ipython:: python s[:5] s[::2] s[::-1] Note that setting works as well: .. ipython:: python s2 = s.copy() s2[:5] = 0 s2 With DataFrame, slicing inside of ``[]`` **slices the rows**. This is provided largely as a convenience since it is such a common operation. .. ipython:: python df[:3] df[::-1] Boolean indexing ~~~~~~~~~~~~~~~~ .. _indexing.boolean: Another common operation is the use of boolean vectors to filter the data. Using a boolean vector to index a Series works exactly as in a numpy ndarray: .. ipython:: python s[s > 0] s[(s < 0) & (s > -0.5)] You may select rows from a DataFrame using a boolean vector the same length as the DataFrame's index (for example, something derived from one of the columns of the DataFrame): .. ipython:: python df[df['A'] > 0] Consider the ``isin`` method of Series, which returns a boolean vector that is true wherever the Series elements exist in the passed list. This allows you to select rows where one or more columns have values you want: .. ipython:: python df2 = DataFrame({'a' : ['one', 'one', 'two', 'three', 'two', 'one', 'six'], 'b' : ['x', 'y', 'y', 'x', 'y', 'x', 'x'], 'c' : randn(7)}) df2[df2['a'].isin(['one', 'two'])] List comprehensions and ``map`` method of Series can also be used to produce more complex criteria: .. ipython:: python # only want 'two' or 'three' criterion = df2['a'].map(lambda x: x.startswith('t')) df2[criterion] # equivalent but slower df2[[x.startswith('t') for x in df2['a']]] # Multiple criteria df2[criterion & (df2['b'] == 'x')] Note, with the :ref:`advanced indexing ` ``ix`` method, you may select along more than one axis using boolean vectors combined with other indexing expressions. Indexing a DataFrame with a boolean DataFrame ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ You may wish to set values on a DataFrame based on some boolean criteria derived from itself or another DataFrame or set of DataFrames. This can be done intuitively like so: .. ipython:: python df2 = df.copy() df2 < 0 df2[df2 < 0] = 0 df2 Note that such an operation requires that the boolean DataFrame is indexed exactly the same. Take Methods ~~~~~~~~~~~~ .. _indexing.take: Similar to numpy ndarrays, pandas Index, Series, and DataFrame also provides the ``take`` method that retrieves elements along a given axis at the given indices. The given indices must be either a list or an ndarray of integer index positions. .. ipython:: python index = Index(randint(0, 1000, 10)) index positions = [0, 9, 3] index[positions] index.take(positions) ser = Series(randn(10)) ser.ix[positions] ser.take(positions) For DataFrames, the given indices should be a 1d list or ndarray that specifies row or column positions. .. ipython:: python frm = DataFrame(randn(5, 3)) frm.take([1, 4, 3]) frm.take([0, 2], axis=1) It is important to note that the ``take`` method on pandas objects are not intended to work on boolean indices and may return unexpected results. .. ipython:: python arr = randn(10) arr.take([False, False, True, True]) arr[[0, 1]] ser = Series(randn(10)) ser.take([False, False, True, True]) ser.ix[[0, 1]] Finally, as a small note on performance, because the ``take`` method handles a narrower range of inputs, it can offer performance that is a good deal faster than fancy indexing. .. ipython:: arr = randn(10000, 5) indexer = np.arange(10000) random.shuffle(indexer) timeit arr[indexer] timeit arr.take(indexer, axis=0) ser = Series(arr[:, 0]) timeit ser.ix[indexer] timeit ser.take(indexer) Duplicate Data ~~~~~~~~~~~~~~ .. _indexing.duplicate: If you want to identify and remove duplicate rows in a DataFrame, there are two methods that will help: ``duplicated`` and ``drop_duplicates``. Each takes as an argument the columns to use to identify duplicated rows. ``duplicated`` returns a boolean vector whose length is the number of rows, and which indicates whether a row is duplicated. ``drop_duplicates`` removes duplicate rows. By default, the first observed row of a duplicate set is considered unique, but each method has a ``take_last`` parameter that indicates the last observed row should be taken instead. .. ipython:: python df2 = DataFrame({'a' : ['one', 'one', 'two', 'three', 'two', 'one', 'six'], 'b' : ['x', 'y', 'y', 'x', 'y', 'x', 'x'], 'c' : np.random.randn(7)}) df2.duplicated(['a','b']) df2.drop_duplicates(['a','b']) df2.drop_duplicates(['a','b'], take_last=True) .. _indexing.dictionarylike: Dictionary-like ``get`` method ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Each of Series, DataFrame, and Panel have a ``get`` method which can return a default value. .. ipython:: python s = Series([1,2,3], index=['a','b','c']) s.get('a') # equivalent to s['a'] s.get('x', default=-1) .. _indexing.advanced: Advanced indexing with labels ----------------------------- We have avoided excessively overloading the ``[]`` / ``__getitem__`` operator to keep the basic functionality of the pandas objects straightforward and simple. However, there are often times when you may wish get a subset (or analogously set a subset) of the data in a way that is not straightforward using the combination of ``reindex`` and ``[]``. Complicated setting operations are actually quite difficult because ``reindex`` usually returns a copy. By *advanced* indexing we are referring to a special ``.ix`` attribute on pandas objects which enable you to do getting/setting operations on a DataFrame, for example, with matrix/ndarray-like semantics. Thus you can combine the following kinds of indexing: - An integer or single label, e.g. ``5`` or ``'a'`` - A list or array of labels ``['a', 'b', 'c']`` or integers ``[4, 3, 0]`` - A slice object with ints ``1:7`` or labels ``'a':'f'`` - A boolean array We'll illustrate all of these methods. First, note that this provides a concise way of reindexing on multiple axes at once: .. ipython:: python subindex = dates[[3,4,5]] df.reindex(index=subindex, columns=['C', 'B']) df.ix[subindex, ['C', 'B']] Assignment / setting values is possible when using ``ix``: .. ipython:: python df2 = df.copy() df2.ix[subindex, ['C', 'B']] = 0 df2 Indexing with an array of integers can also be done: .. ipython:: python df.ix[[4,3,1]] df.ix[dates[[4,3,1]]] **Slicing** has standard Python semantics for integer slices: .. ipython:: python df.ix[1:7, :2] Slicing with labels is semantically slightly different because the slice start and stop are **inclusive** in the label-based case: .. ipython:: python date1, date2 = dates[[2, 4]] print date1, date2 df.ix[date1:date2] df['A'].ix[date1:date2] Getting and setting rows in a DataFrame, especially by their location, is much easier: .. ipython:: python df2 = df[:5].copy() df2.ix[3] df2.ix[3] = np.arange(len(df2.columns)) df2 Column or row selection can be combined as you would expect with arrays of labels or even boolean vectors: .. ipython:: python df.ix[df['A'] > 0, 'B'] df.ix[date1:date2, 'B'] df.ix[date1, 'B'] Slicing with labels is closely related to the ``truncate`` method which does precisely ``.ix[start:stop]`` but returns a copy (for legacy reasons). Returning a view versus a copy ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ The rules about when a view on the data is returned are entirely dependent on NumPy. Whenever an array of labels or a boolean vector are involved in the indexing operation, the result will be a copy. With single label / scalar indexing and slicing, e.g. ``df.ix[3:6]`` or ``df.ix[:, 'A']``, a view will be returned. The ``select`` method ~~~~~~~~~~~~~~~~~~~~~ Another way to extract slices from an object is with the ``select`` method of Series, DataFrame, and Panel. This method should be used only when there is no more direct way. ``select`` takes a function which operates on labels along ``axis`` and returns a boolean. For instance: .. ipython:: python df.select(lambda x: x == 'A', axis=1) The ``lookup`` method ~~~~~~~~~~~~~~~~~~~~~ Sometimes you want to extract a set of values given a sequence of row labels and column labels, and the ``lookup`` method allows for this and returns a numpy array. For instance, .. ipython:: python dflookup = DataFrame(np.random.rand(20,4), columns = ['A','B','C','D']) dflookup.lookup(xrange(0,10,2), ['B','C','A','B','D']) Advanced indexing with integer labels ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Label-based indexing with integer axis labels is a thorny topic. It has been discussed heavily on mailing lists and among various members of the scientific Python community. In pandas, our general viewpoint is that labels matter more than integer locations. Therefore, with an integer axis index *only* label-based indexing is possible with the standard tools like ``.ix``. The following code will generate exceptions: .. code-block:: python s = Series(range(5)) s[-1] df = DataFrame(np.random.randn(5, 4)) df df.ix[-2:] This deliberate decision was made to prevent ambiguities and subtle bugs (many users reported finding bugs when the API change was made to stop "falling back" on position-based indexing). Setting values in mixed-type DataFrame ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ .. _indexing.mixed_type_setting: Setting values on a mixed-type DataFrame or Panel is supported when using scalar values, though setting arbitrary vectors is not yet supported: .. ipython:: python df2 = df[:4] df2['foo'] = 'bar' print df2 df2.ix[2] = np.nan print df2 print df2.dtypes .. _indexing.class: Index objects ------------- The pandas Index class and its subclasses can be viewed as implementing an *ordered set* in addition to providing the support infrastructure necessary for lookups, data alignment, and reindexing. The easiest way to create one directly is to pass a list or other sequence to ``Index``: .. ipython:: python index = Index(['e', 'd', 'a', 'b']) index 'd' in index You can also pass a ``name`` to be stored in the index: .. ipython:: python index = Index(['e', 'd', 'a', 'b'], name='something') index.name Starting with pandas 0.5, the name, if set, will be shown in the console display: .. ipython:: python index = Index(range(5), name='rows') columns = Index(['A', 'B', 'C'], name='cols') df = DataFrame(np.random.randn(5, 3), index=index, columns=columns) df df['A'] Set operations on Index objects ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ .. _indexing.set_ops: The three main operations are ``union (|)``, ``intersection (&)``, and ``diff (-)``. These can be directly called as instance methods or used via overloaded operators: .. ipython:: python a = Index(['c', 'b', 'a']) b = Index(['c', 'e', 'd']) a.union(b) a | b a & b a - b ``isin`` method of Index objects ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ One additional operation is the ``isin`` method that works analogously to the ``Series.isin`` method found :ref:`here `. .. _indexing.hierarchical: Hierarchical indexing (MultiIndex) ---------------------------------- Hierarchical indexing (also referred to as "multi-level" indexing) is brand new in the pandas 0.4 release. It is very exciting as it opens the door to some quite sophisticated data analysis and manipulation, especially for working with higher dimensional data. In essence, it enables you to store and manipulate data with an arbitrary number of dimensions in lower dimensional data structures like Series (1d) and DataFrame (2d). In this section, we will show what exactly we mean by "hierarchical" indexing and how it integrates with the all of the pandas indexing functionality described above and in prior sections. Later, when discussing :ref:`group by ` and :ref:`pivoting and reshaping data `, we'll show non-trivial applications to illustrate how it aids in structuring data for analysis. .. note:: Given that hierarchical indexing is so new to the library, it is definitely "bleeding-edge" functionality but is certainly suitable for production. But, there may inevitably be some minor API changes as more use cases are explored and any weaknesses in the design / implementation are identified. pandas aims to be "eminently usable" so any feedback about new functionality like this is extremely helpful. Creating a MultiIndex (hierarchical index) object ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ The ``MultiIndex`` object is the hierarchical analogue of the standard ``Index`` object which typically stores the axis labels in pandas objects. You can think of ``MultiIndex`` an array of tuples where each tuple is unique. A ``MultiIndex`` can be created from a list of arrays (using ``MultiIndex.from_arrays``) or an array of tuples (using ``MultiIndex.from_tuples``). .. ipython:: python arrays = [['bar', 'bar', 'baz', 'baz', 'foo', 'foo', 'qux', 'qux'], ['one', 'two', 'one', 'two', 'one', 'two', 'one', 'two']] tuples = zip(*arrays) tuples index = MultiIndex.from_tuples(tuples, names=['first', 'second']) s = Series(randn(8), index=index) s As a convenience, you can pass a list of arrays directly into Series or DataFrame to construct a MultiIndex automatically: .. ipython:: python arrays = [np.array(['bar', 'bar', 'baz', 'baz', 'foo', 'foo', 'qux', 'qux']), np.array(['one', 'two', 'one', 'two', 'one', 'two', 'one', 'two'])] s = Series(randn(8), index=arrays) s df = DataFrame(randn(8, 4), index=arrays) df All of the ``MultiIndex`` constructors accept a ``names`` argument which stores string names for the levels themselves. If no names are provided, some arbitrary ones will be assigned: .. ipython:: python index.names This index can back any axis of a pandas object, and the number of **levels** of the index is up to you: .. ipython:: python df = DataFrame(randn(3, 8), index=['A', 'B', 'C'], columns=index) df DataFrame(randn(6, 6), index=index[:6], columns=index[:6]) We've "sparsified" the higher levels of the indexes to make the console output a bit easier on the eyes. It's worth keeping in mind that there's nothing preventing you from using tuples as atomic labels on an axis: .. ipython:: python Series(randn(8), index=tuples) The reason that the ``MultiIndex`` matters is that it can allow you to do grouping, selection, and reshaping operations as we will describe below and in subsequent areas of the documentation. As you will see in later sections, you can find yourself working with hierarchically-indexed data without creating a ``MultiIndex`` explicitly yourself. However, when loading data from a file, you may wish to generate your own ``MultiIndex`` when preparing the data set. Note that how the index is displayed by be controlled using the ``multi_sparse`` option in ``pandas.set_printoptions``: .. ipython:: python pd.set_printoptions(multi_sparse=False) df pd.set_printoptions(multi_sparse=True) Reconstructing the level labels ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ .. _indexing.get_level_values: The method ``get_level_values`` will return a vector of the labels for each location at a particular level: .. ipython:: python index.get_level_values(0) index.get_level_values('second') Basic indexing on axis with MultiIndex ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ One of the important features of hierarchical indexing is that you can select data by a "partial" label identifying a subgroup in the data. **Partial** selection "drops" levels of the hierarchical index in the result in a completely analogous way to selecting a column in a regular DataFrame: .. ipython:: python df['bar'] df['bar', 'one'] df['bar']['one'] s['qux'] Data alignment and using ``reindex`` ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Operations between differently-indexed objects having ``MultiIndex`` on the axes will work as you expect; data alignment will work the same as an Index of tuples: .. ipython:: python s + s[:-2] s + s[::2] ``reindex`` can be called with another ``MultiIndex`` or even a list or array of tuples: .. ipython:: python s.reindex(index[:3]) s.reindex([('foo', 'two'), ('bar', 'one'), ('qux', 'one'), ('baz', 'one')]) Advanced indexing with hierarchical index ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Syntactically integrating ``MultiIndex`` in advanced indexing with ``.ix`` is a bit challenging, but we've made every effort to do so. for example the following works as you would expect: .. ipython:: python df = df.T df df.ix['bar'] df.ix['bar', 'two'] "Partial" slicing also works quite nicely: .. ipython:: python df.ix['baz':'foo'] df.ix[('baz', 'two'):('qux', 'one')] df.ix[('baz', 'two'):'foo'] Passing a list of labels or tuples works similar to reindexing: .. ipython:: python df.ix[[('bar', 'two'), ('qux', 'one')]] The following does not work, and it's not clear if it should or not: :: >>> df.ix[['bar', 'qux']] The code for implementing ``.ix`` makes every attempt to "do the right thing" but as you use it you may uncover corner cases or unintuitive behavior. If you do find something like this, do not hesitate to report the issue or ask on the mailing list. .. _indexing.xs: Cross-section with hierarchical index ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ The ``xs`` method of ``DataFrame`` additionally takes a level argument to make selecting data at a particular level of a MultiIndex easier. .. ipython:: python df.xs('one', level='second') .. _indexing.advanced_reindex: Advanced reindexing and alignment with hierarchical index ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ The parameter ``level`` has been added to the ``reindex`` and ``align`` methods of pandas objects. This is useful to broadcast values across a level. For instance: .. ipython:: python midx = MultiIndex(levels=[['zero', 'one'], ['x','y']], labels=[[1,1,0,0],[1,0,1,0]]) df = DataFrame(randn(4,2), index=midx) print df df2 = df.mean(level=0) print df2 print df2.reindex(df.index, level=0) df_aligned, df2_aligned = df.align(df2, level=0) print df_aligned print df2_aligned The need for sortedness ~~~~~~~~~~~~~~~~~~~~~~~ **Caveat emptor**: the present implementation of ``MultiIndex`` requires that the labels be sorted for some of the slicing / indexing routines to work correctly. You can think about breaking the axis into unique groups, where at the hierarchical level of interest, each distinct group shares a label, but no two have the same label. However, the ``MultiIndex`` does not enforce this: **you are responsible for ensuring that things are properly sorted**. There is an important new method ``sortlevel`` to sort an axis within a ``MultiIndex`` so that its labels are grouped and sorted by the original ordering of the associated factor at that level. Note that this does not necessarily mean the labels will be sorted lexicographically! .. ipython:: python import random; random.shuffle(tuples) s = Series(randn(8), index=MultiIndex.from_tuples(tuples)) s s.sortlevel(0) s.sortlevel(1) .. _indexing.sortlevel_byname: Note, you may also pass a level name to ``sortlevel`` if the MultiIndex levels are named. .. ipython:: python s.index.names = ['L1', 'L2'] s.sortlevel(level='L1') s.sortlevel(level='L2') Some indexing will work even if the data are not sorted, but will be rather inefficient and will also return a copy of the data rather than a view: .. ipython:: python s['qux'] s.sortlevel(1)['qux'] On higher dimensional objects, you can sort any of the other axes by level if they have a MultiIndex: .. ipython:: python df.T.sortlevel(1, axis=1) The ``MultiIndex`` object has code to **explicity check the sort depth**. Thus, if you try to index at a depth at which the index is not sorted, it will raise an exception. Here is a concrete example to illustrate this: .. ipython:: python tuples = [('a', 'a'), ('a', 'b'), ('b', 'a'), ('b', 'b')] idx = MultiIndex.from_tuples(tuples) idx.lexsort_depth reordered = idx[[1, 0, 3, 2]] reordered.lexsort_depth s = Series(randn(4), index=reordered) s.ix['a':'a'] However: :: >>> s.ix[('a', 'b'):('b', 'a')] Exception: MultiIndex lexsort depth 1, key was length 2 Swapping levels with ``swaplevel`` ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ The ``swaplevel`` function can switch the order of two levels: .. ipython:: python df[:5] df[:5].swaplevel(0, 1, axis=0) .. _indexing.reorderlevels: Reordering levels with ``reorder_levels`` ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ The ``reorder_levels`` function generalizes the ``swaplevel`` function, allowing you to permute the hierarchical index levels in one step: .. ipython:: python df[:5].reorder_levels([1,0], axis=0) Some gory internal details ~~~~~~~~~~~~~~~~~~~~~~~~~~ Internally, the ``MultiIndex`` consists of a few things: the **levels**, the integer **labels**, and the level **names**: .. ipython:: python index index.levels index.labels index.names You can probably guess that the labels determine which unique element is identified with that location at each layer of the index. It's important to note that sortedness is determined **solely** from the integer labels and does not check (or care) whether the levels themselves are sorted. Fortunately, the constructors ``from_tuples`` and ``from_arrays`` ensure that this is true, but if you compute the levels and labels yourself, please be careful. Adding an index to an existing DataFrame ---------------------------------------- Occasionally you will load or create a data set into a DataFrame and want to add an index after you've already done so. There are a couple of different ways. Add an index using DataFrame columns ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ .. _indexing.set_index: DataFrame has a ``set_index`` method which takes a column name (for a regular ``Index``) or a list of column names (for a ``MultiIndex``), to create a new, indexed DataFrame: .. ipython:: python :suppress: data = DataFrame({'a' : ['bar', 'bar', 'foo', 'foo'], 'b' : ['one', 'two', 'one', 'two'], 'c' : ['z', 'y', 'x', 'w'], 'd' : [1., 2., 3, 4]}) .. ipython:: python data indexed1 = data.set_index('c') indexed1 indexed2 = data.set_index(['a', 'b']) indexed2 The ``append`` keyword option allow you to keep the existing index and append the given columns to a MultiIndex: .. ipython:: python frame = data.set_index('c', drop=False) frame = frame.set_index(['a', 'b'], append=True) frame Other options in ``set_index`` allow you not drop the index columns or to add the index in-place (without creating a new object): .. ipython:: python data.set_index('c', drop=False) df = data.set_index(['a', 'b'], inplace=True) data Remove / reset the index, ``reset_index`` ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ As a convenience, there is a new function on DataFrame called ``reset_index`` which transfers the index values into the DataFrame's columns and sets a simple integer index. This is the inverse operation to ``set_index`` .. ipython:: python df df.reset_index() The output is more similar to a SQL table or a record array. The names for the columns derived from the index are the ones stored in the ``names`` attribute. You can use the ``level`` keyword to remove only a portion of the index: .. ipython:: python frame frame.reset_index(level=1) ``reset_index`` takes an optional parameter ``drop`` which if true simply discards the index, instead of putting index values in the DataFrame's columns. .. note:: The ``reset_index`` method used to be called ``delevel`` which is now deprecated. Adding an ad hoc index ~~~~~~~~~~~~~~~~~~~~~~ If you create an index yourself, you can just assign it to the ``index`` field: .. code-block:: python df.index = index Indexing internal details ------------------------- .. note:: The following is largely relevant for those actually working on the pandas codebase. And the source code is still the best place to look at the specifics of how things are implemented. In pandas there are a few objects implemented which can serve as valid containers for the axis labels: - ``Index``: the generic "ordered set" object, an ndarray of object dtype assuming nothing about its contents. The labels must be hashable (and likely immutable) and unique. Populates a dict of label to location in Cython to do :math:`O(1)` lookups. - ``Int64Index``: a version of ``Index`` highly optimized for 64-bit integer data, such as time stamps - ``MultiIndex``: the standard hierarchical index object - ``date_range``: fixed frequency date range generated from a time rule or DateOffset. An ndarray of Python datetime objects The motivation for having an ``Index`` class in the first place was to enable different implementations of indexing. This means that it's possible for you, the user, to implement a custom ``Index`` subclass that may be better suited to a particular application than the ones provided in pandas. For example, we plan to add a more efficient datetime index which leverages the new ``numpy.datetime64`` dtype in the relatively near future. From an internal implementation point of view, the relevant methods that an ``Index`` must define are one or more of the following (depending on how incompatible the new object internals are with the ``Index`` functions): - ``get_loc``: returns an "indexer" (an integer, or in some cases a slice object) for a label - ``slice_locs``: returns the "range" to slice between two labels - ``get_indexer``: Computes the indexing vector for reindexing / data alignment purposes. See the source / docstrings for more on this - ``reindex``: Does any pre-conversion of the input index then calls ``get_indexer`` - ``union``, ``intersection``: computes the union or intersection of two Index objects - ``insert``: Inserts a new label into an Index, yielding a new object - ``delete``: Delete a label, yielding a new object - ``drop``: Deletes a set of labels - ``take``: Analogous to ndarray.take