Doc/library/sets.rst - platform/external/python/cpython2 - Gitiles


 :mod:`sets` --- Unordered collections of unique elements
 ========================================================

 .. module:: sets
    :synopsis: Implementation of sets of unique elements.
    :deprecated:
 .. moduleauthor:: Greg V. Wilson <gvwilson@nevex.com>
 .. moduleauthor:: Alex Martelli <aleax@aleax.it>
 .. moduleauthor:: Guido van Rossum <guido@python.org>
 .. sectionauthor:: Raymond D. Hettinger <python@rcn.com>


 .. versionadded:: 2.3

 .. deprecated:: 2.6
    The built-in ``set``/``frozenset`` types replace this module.

 The :mod:`sets` module provides classes for constructing and manipulating
 unordered collections of unique elements.  Common uses include membership
 testing, removing duplicates from a sequence, and computing standard math
 operations on sets such as intersection, union, difference, and symmetric
 difference.

 Like other collections, sets support ``x in set``, ``len(set)``, and ``for x in
 set``.  Being an unordered collection, sets do not record element position or
 order of insertion.  Accordingly, sets do not support indexing, slicing, or
 other sequence-like behavior.

 Most set applications use the :class:`Set` class which provides every set method
 except for :meth:`__hash__`. For advanced applications requiring a hash method,
 the :class:`ImmutableSet` class adds a :meth:`__hash__` method but omits methods
 which alter the contents of the set. Both :class:`Set` and :class:`ImmutableSet`
 derive from :class:`BaseSet`, an abstract class useful for determining whether
 something is a set: ``isinstance(obj, BaseSet)``.

 The set classes are implemented using dictionaries.  Accordingly, the
 requirements for set elements are the same as those for dictionary keys; namely,
 that the element defines both :meth:`__eq__` and :meth:`__hash__`. As a result,
 sets cannot contain mutable elements such as lists or dictionaries. However,
 they can contain immutable collections such as tuples or instances of
 :class:`ImmutableSet`.  For convenience in implementing sets of sets, inner sets
 are automatically converted to immutable form, for example,
 ``Set([Set(['dog'])])`` is transformed to ``Set([ImmutableSet(['dog'])])``.


 .. class:: Set([iterable])

    Constructs a new empty :class:`Set` object.  If the optional *iterable*
    parameter is supplied, updates the set with elements obtained from iteration.
    All of the elements in *iterable* should be immutable or be transformable to an
    immutable using the protocol described in section :ref:`immutable-transforms`.


 .. class:: ImmutableSet([iterable])

    Constructs a new empty :class:`ImmutableSet` object.  If the optional *iterable*
    parameter is supplied, updates the set with elements obtained from iteration.
    All of the elements in *iterable* should be immutable or be transformable to an
    immutable using the protocol described in section :ref:`immutable-transforms`.

    Because :class:`ImmutableSet` objects provide a :meth:`__hash__` method, they
    can be used as set elements or as dictionary keys.  :class:`ImmutableSet`
    objects do not have methods for adding or removing elements, so all of the
    elements must be known when the constructor is called.


 .. _set-objects:

 Set Objects
 -----------

 Instances of :class:`Set` and :class:`ImmutableSet` both provide the following
 operations:

 +-------------------------------+------------+---------------------------------+
 | Operation                     | Equivalent | Result                          |
 +===============================+============+=================================+
 | ``len(s)``                    |            | cardinality of set *s*          |
 +-------------------------------+------------+---------------------------------+
 | ``x in s``                    |            | test *x* for membership in *s*  |
 +-------------------------------+------------+---------------------------------+
 | ``x not in s``                |            | test *x* for non-membership in  |
 |                               |            | *s*                             |
 +-------------------------------+------------+---------------------------------+
 | ``s.issubset(t)``             | ``s <= t`` | test whether every element in   |
 |                               |            | *s* is in *t*                   |
 +-------------------------------+------------+---------------------------------+
 | ``s.issuperset(t)``           | ``s >= t`` | test whether every element in   |
 |                               |            | *t* is in *s*                   |
 +-------------------------------+------------+---------------------------------+
 | ``s.union(t)``                | ``s | t``  | new set with elements from both |
 |                               |            | *s* and *t*                     |
 +-------------------------------+------------+---------------------------------+
 | ``s.intersection(t)``         | ``s & t``  | new set with elements common to |
 |                               |            | *s* and *t*                     |
 +-------------------------------+------------+---------------------------------+
 | ``s.difference(t)``           | ``s - t``  | new set with elements in *s*    |
 |                               |            | but not in *t*                  |
 +-------------------------------+------------+---------------------------------+
 | ``s.symmetric_difference(t)`` | ``s ^ t``  | new set with elements in either |
 |                               |            | *s* or *t* but not both         |
 +-------------------------------+------------+---------------------------------+
 | ``s.copy()``                  |            | new set with a shallow copy of  |
 |                               |            | *s*                             |
 +-------------------------------+------------+---------------------------------+

 Note, the non-operator versions of :meth:`union`, :meth:`intersection`,
 :meth:`difference`, and :meth:`symmetric_difference` will accept any iterable as
 an argument. In contrast, their operator based counterparts require their
 arguments to be sets.  This precludes error-prone constructions like
 ``Set('abc') & 'cbs'`` in favor of the more readable
 ``Set('abc').intersection('cbs')``.

 .. versionchanged:: 2.3.1
    Formerly all arguments were required to be sets.

 In addition, both :class:`Set` and :class:`ImmutableSet` support set to set
 comparisons.  Two sets are equal if and only if every element of each set is
 contained in the other (each is a subset of the other). A set is less than
 another set if and only if the first set is a proper subset of the second set
 (is a subset, but is not equal). A set is greater than another set if and only
 if the first set is a proper superset of the second set (is a superset, but is
 not equal).

 The subset and equality comparisons do not generalize to a complete ordering
 function.  For example, any two disjoint sets are not equal and are not subsets
 of each other, so *all* of the following return ``False``:  ``a<b``, ``a==b``,
 or ``a>b``. Accordingly, sets do not implement the :meth:`__cmp__` method.

 Since sets only define partial ordering (subset relationships), the output of
 the :meth:`list.sort` method is undefined for lists of sets.

 The following table lists operations available in :class:`ImmutableSet` but not
 found in :class:`Set`:

 +-------------+------------------------------+
 | Operation   | Result                       |
 +=============+==============================+
 | ``hash(s)`` | returns a hash value for *s* |
 +-------------+------------------------------+

 The following table lists operations available in :class:`Set` but not found in
 :class:`ImmutableSet`:

 +--------------------------------------+-------------+---------------------------------+
 | Operation                            | Equivalent  | Result                          |
 +======================================+=============+=================================+
 | ``s.update(t)``                      | *s* \|= *t* | return set *s* with elements    |
 |                                      |             | added from *t*                  |
 +--------------------------------------+-------------+---------------------------------+
 | ``s.intersection_update(t)``         | *s* &= *t*  | return set *s* keeping only     |
 |                                      |             | elements also found in *t*      |
 +--------------------------------------+-------------+---------------------------------+
 | ``s.difference_update(t)``           | *s* -= *t*  | return set *s* after removing   |
 |                                      |             | elements found in *t*           |
 +--------------------------------------+-------------+---------------------------------+
 | ``s.symmetric_difference_update(t)`` | *s* ^= *t*  | return set *s* with elements    |
 |                                      |             | from *s* or *t* but not both    |
 +--------------------------------------+-------------+---------------------------------+
 | ``s.add(x)``                         |             | add element *x* to set *s*      |
 +--------------------------------------+-------------+---------------------------------+
 | ``s.remove(x)``                      |             | remove *x* from set *s*; raises |
 |                                      |             | :exc:`KeyError` if not present  |
 +--------------------------------------+-------------+---------------------------------+
 | ``s.discard(x)``                     |             | removes *x* from set *s* if     |
 |                                      |             | present                         |
 +--------------------------------------+-------------+---------------------------------+
 | ``s.pop()``                          |             | remove and return an arbitrary  |
 |                                      |             | element from *s*; raises        |
 |                                      |             | :exc:`KeyError` if empty        |
 +--------------------------------------+-------------+---------------------------------+
 | ``s.clear()``                        |             | remove all elements from set    |
 |                                      |             | *s*                             |
 +--------------------------------------+-------------+---------------------------------+

 Note, the non-operator versions of :meth:`update`, :meth:`intersection_update`,
 :meth:`difference_update`, and :meth:`symmetric_difference_update` will accept
 any iterable as an argument.

 .. versionchanged:: 2.3.1
    Formerly all arguments were required to be sets.

 Also note, the module also includes a :meth:`union_update` method which is an
 alias for :meth:`update`.  The method is included for backwards compatibility.
 Programmers should prefer the :meth:`update` method because it is supported by
 the builtin :class:`set()` and :class:`frozenset()` types.


 .. _set-example:

 Example
 -------

 ::

    >>> from sets import Set
    >>> engineers = Set(['John', 'Jane', 'Jack', 'Janice'])
    >>> programmers = Set(['Jack', 'Sam', 'Susan', 'Janice'])
    >>> managers = Set(['Jane', 'Jack', 'Susan', 'Zack'])
    >>> employees = engineers | programmers | managers           # union
    >>> engineering_management = engineers & managers            # intersection
    >>> fulltime_management = managers - engineers - programmers # difference
    >>> engineers.add('Marvin')                                  # add element
    >>> print engineers
    Set(['Jane', 'Marvin', 'Janice', 'John', 'Jack'])
    >>> employees.issuperset(engineers)     # superset test
    False
    >>> employees.update(engineers)         # update from another set
    >>> employees.issuperset(engineers)
    True
    >>> for group in [engineers, programmers, managers, employees]:
    ...     group.discard('Susan')          # unconditionally remove element
    ...     print group
    ...
    Set(['Jane', 'Marvin', 'Janice', 'John', 'Jack'])
    Set(['Janice', 'Jack', 'Sam'])
    Set(['Jane', 'Zack', 'Jack'])
    Set(['Jack', 'Sam', 'Jane', 'Marvin', 'Janice', 'John', 'Zack'])


 .. _immutable-transforms:

 Protocol for automatic conversion to immutable
 ----------------------------------------------

 Sets can only contain immutable elements.  For convenience, mutable :class:`Set`
 objects are automatically copied to an :class:`ImmutableSet` before being added
 as a set element.

 The mechanism is to always add a :term:`hashable` element, or if it is not
 hashable, the element is checked to see if it has an :meth:`__as_immutable__`
 method which returns an immutable equivalent.

 Since :class:`Set` objects have a :meth:`__as_immutable__` method returning an
 instance of :class:`ImmutableSet`, it is possible to construct sets of sets.

 A similar mechanism is needed by the :meth:`__contains__` and :meth:`remove`
 methods which need to hash an element to check for membership in a set.  Those
 methods check an element for hashability and, if not, check for a
 :meth:`__as_temporarily_immutable__` method which returns the element wrapped by
 a class that provides temporary methods for :meth:`__hash__`, :meth:`__eq__`,
 and :meth:`__ne__`.

 The alternate mechanism spares the need to build a separate copy of the original
 mutable object.

 :class:`Set` objects implement the :meth:`__as_temporarily_immutable__` method
 which returns the :class:`Set` object wrapped by a new class
 :class:`_TemporarilyImmutableSet`.

 The two mechanisms for adding hashability are normally invisible to the user;
 however, a conflict can arise in a multi-threaded environment where one thread
 is updating a set while another has temporarily wrapped it in
 :class:`_TemporarilyImmutableSet`.  In other words, sets of mutable sets are not
 thread-safe.


 .. _comparison-to-builtin-set:

 Comparison to the built-in :class:`set` types
 ---------------------------------------------

 The built-in :class:`set` and :class:`frozenset` types were designed based on
 lessons learned from the :mod:`sets` module.  The key differences are:

 * :class:`Set` and :class:`ImmutableSet` were renamed to :class:`set` and
   :class:`frozenset`.

 * There is no equivalent to :class:`BaseSet`.  Instead, use ``isinstance(x,
   (set, frozenset))``.

 * The hash algorithm for the built-ins performs significantly better (fewer
   collisions) for most datasets.

 * The built-in versions have more space efficient pickles.

 * The built-in versions do not have a :meth:`union_update` method. Instead, use
   the :meth:`update` method which is equivalent.

 * The built-in versions do not have a ``_repr(sorted=True)`` method.
   Instead, use the built-in :func:`repr` and :func:`sorted` functions:
   ``repr(sorted(s))``.

 * The built-in version does not have a protocol for automatic conversion to
   immutable.  Many found this feature to be confusing and no one in the community
   reported having found real uses for it.

	:mod:`sets` --- Unordered collections of unique elements
	========================================================

	.. module:: sets
	:synopsis: Implementation of sets of unique elements.
	:deprecated:
	.. moduleauthor:: Greg V. Wilson <gvwilson@nevex.com>
	.. moduleauthor:: Alex Martelli <aleax@aleax.it>
	.. moduleauthor:: Guido van Rossum <guido@python.org>
	.. sectionauthor:: Raymond D. Hettinger <python@rcn.com>


	.. versionadded:: 2.3

	.. deprecated:: 2.6
	The built-in ``set``/``frozenset`` types replace this module.

	The :mod:`sets` module provides classes for constructing and manipulating
	unordered collections of unique elements. Common uses include membership
	testing, removing duplicates from a sequence, and computing standard math
	operations on sets such as intersection, union, difference, and symmetric
	difference.

	Like other collections, sets support ``x in set``, ``len(set)``, and ``for x in
	set``. Being an unordered collection, sets do not record element position or
	order of insertion. Accordingly, sets do not support indexing, slicing, or
	other sequence-like behavior.

	Most set applications use the :class:`Set` class which provides every set method
	except for :meth:`__hash__`. For advanced applications requiring a hash method,
	the :class:`ImmutableSet` class adds a :meth:`__hash__` method but omits methods
	which alter the contents of the set. Both :class:`Set` and :class:`ImmutableSet`
	derive from :class:`BaseSet`, an abstract class useful for determining whether
	something is a set: ``isinstance(obj, BaseSet)``.

	The set classes are implemented using dictionaries. Accordingly, the
	requirements for set elements are the same as those for dictionary keys; namely,
	that the element defines both :meth:`__eq__` and :meth:`__hash__`. As a result,
	sets cannot contain mutable elements such as lists or dictionaries. However,
	they can contain immutable collections such as tuples or instances of
	:class:`ImmutableSet`. For convenience in implementing sets of sets, inner sets
	are automatically converted to immutable form, for example,
	``Set([Set(['dog'])])`` is transformed to ``Set([ImmutableSet(['dog'])])``.


	.. class:: Set([iterable])

	Constructs a new empty :class:`Set` object. If the optional iterable
	parameter is supplied, updates the set with elements obtained from iteration.
	All of the elements in iterable should be immutable or be transformable to an
	immutable using the protocol described in section :ref:`immutable-transforms`.


	.. class:: ImmutableSet([iterable])

	Constructs a new empty :class:`ImmutableSet` object. If the optional iterable
	parameter is supplied, updates the set with elements obtained from iteration.
	All of the elements in iterable should be immutable or be transformable to an
	immutable using the protocol described in section :ref:`immutable-transforms`.

	Because :class:`ImmutableSet` objects provide a :meth:`__hash__` method, they
	can be used as set elements or as dictionary keys. :class:`ImmutableSet`
	objects do not have methods for adding or removing elements, so all of the
	elements must be known when the constructor is called.


	.. _set-objects:

	Set Objects
	-----------

	Instances of :class:`Set` and :class:`ImmutableSet` both provide the following
	operations:

	+-------------------------------+------------+---------------------------------+
	\| Operation \| Equivalent \| Result \|
	+===============================+============+=================================+
	\| ``len(s)`` \| \| cardinality of set s \|
	+-------------------------------+------------+---------------------------------+
	\| ``x in s`` \| \| test x for membership in s \|
	+-------------------------------+------------+---------------------------------+
	\| ``x not in s`` \| \| test x for non-membership in \|
	\| \| \| s \|
	+-------------------------------+------------+---------------------------------+
	\| ``s.issubset(t)`` \| ``s <= t`` \| test whether every element in \|
	\| \| \| s is in t \|
	+-------------------------------+------------+---------------------------------+
	\| ``s.issuperset(t)`` \| ``s >= t`` \| test whether every element in \|
	\| \| \| t is in s \|
	+-------------------------------+------------+---------------------------------+
	\| ``s.union(t)`` \| ``s \| t`` \| new set with elements from both \|
	\| \| \| s and t \|
	+-------------------------------+------------+---------------------------------+
	\| ``s.intersection(t)`` \| ``s & t`` \| new set with elements common to \|
	\| \| \| s and t \|
	+-------------------------------+------------+---------------------------------+
	\| ``s.difference(t)`` \| ``s - t`` \| new set with elements in s \|
	\| \| \| but not in t \|
	+-------------------------------+------------+---------------------------------+
	\| ``s.symmetric_difference(t)`` \| ``s ^ t`` \| new set with elements in either \|
	\| \| \| s or t but not both \|
	+-------------------------------+------------+---------------------------------+
	\| ``s.copy()`` \| \| new set with a shallow copy of \|
	\| \| \| s \|
	+-------------------------------+------------+---------------------------------+

	Note, the non-operator versions of :meth:`union`, :meth:`intersection`,
	:meth:`difference`, and :meth:`symmetric_difference` will accept any iterable as
	an argument. In contrast, their operator based counterparts require their
	arguments to be sets. This precludes error-prone constructions like
	``Set('abc') & 'cbs'`` in favor of the more readable
	``Set('abc').intersection('cbs')``.

	.. versionchanged:: 2.3.1
	Formerly all arguments were required to be sets.

	In addition, both :class:`Set` and :class:`ImmutableSet` support set to set
	comparisons. Two sets are equal if and only if every element of each set is
	contained in the other (each is a subset of the other). A set is less than
	another set if and only if the first set is a proper subset of the second set
	(is a subset, but is not equal). A set is greater than another set if and only
	if the first set is a proper superset of the second set (is a superset, but is
	not equal).

	The subset and equality comparisons do not generalize to a complete ordering
	function. For example, any two disjoint sets are not equal and are not subsets
	of each other, so all of the following return ``False``: ``a<b``, ``a==b``,
	or ``a>b``. Accordingly, sets do not implement the :meth:`__cmp__` method.

	Since sets only define partial ordering (subset relationships), the output of
	the :meth:`list.sort` method is undefined for lists of sets.

	The following table lists operations available in :class:`ImmutableSet` but not
	found in :class:`Set`:

	+-------------+------------------------------+
	\| Operation \| Result \|
	+=============+==============================+
	\| ``hash(s)`` \| returns a hash value for s \|
	+-------------+------------------------------+

	The following table lists operations available in :class:`Set` but not found in
	:class:`ImmutableSet`:

	+--------------------------------------+-------------+---------------------------------+
	\| Operation \| Equivalent \| Result \|
	+======================================+=============+=================================+
	\| ``s.update(t)`` \| s \\|= t \| return set s with elements \|
	\| \| \| added from t \|
	+--------------------------------------+-------------+---------------------------------+
	\| ``s.intersection_update(t)`` \| s &= t \| return set s keeping only \|
	\| \| \| elements also found in t \|
	+--------------------------------------+-------------+---------------------------------+
	\| ``s.difference_update(t)`` \| s -= t \| return set s after removing \|
	\| \| \| elements found in t \|
	+--------------------------------------+-------------+---------------------------------+
	\| ``s.symmetric_difference_update(t)`` \| s ^= t \| return set s with elements \|
	\| \| \| from s or t but not both \|
	+--------------------------------------+-------------+---------------------------------+
	\| ``s.add(x)`` \| \| add element x to set s \|
	+--------------------------------------+-------------+---------------------------------+
	\| ``s.remove(x)`` \| \| remove x from set s; raises \|
	\| \| \| :exc:`KeyError` if not present \|
	+--------------------------------------+-------------+---------------------------------+
	\| ``s.discard(x)`` \| \| removes x from set s if \|
	\| \| \| present \|
	+--------------------------------------+-------------+---------------------------------+
	\| ``s.pop()`` \| \| remove and return an arbitrary \|
	\| \| \| element from s; raises \|
	\| \| \| :exc:`KeyError` if empty \|
	+--------------------------------------+-------------+---------------------------------+
	\| ``s.clear()`` \| \| remove all elements from set \|
	\| \| \| s \|
	+--------------------------------------+-------------+---------------------------------+

	Note, the non-operator versions of :meth:`update`, :meth:`intersection_update`,
	:meth:`difference_update`, and :meth:`symmetric_difference_update` will accept
	any iterable as an argument.

	.. versionchanged:: 2.3.1
	Formerly all arguments were required to be sets.

	Also note, the module also includes a :meth:`union_update` method which is an
	alias for :meth:`update`. The method is included for backwards compatibility.
	Programmers should prefer the :meth:`update` method because it is supported by
	the builtin :class:`set()` and :class:`frozenset()` types.


	.. _set-example:

	Example
	-------

	::

	>>> from sets import Set
	>>> engineers = Set(['John', 'Jane', 'Jack', 'Janice'])
	>>> programmers = Set(['Jack', 'Sam', 'Susan', 'Janice'])
	>>> managers = Set(['Jane', 'Jack', 'Susan', 'Zack'])
	>>> employees = engineers \| programmers \| managers # union
	>>> engineering_management = engineers & managers # intersection
	>>> fulltime_management = managers - engineers - programmers # difference
	>>> engineers.add('Marvin') # add element
	>>> print engineers
	Set(['Jane', 'Marvin', 'Janice', 'John', 'Jack'])
	>>> employees.issuperset(engineers) # superset test
	False
	>>> employees.update(engineers) # update from another set
	>>> employees.issuperset(engineers)
	True
	>>> for group in [engineers, programmers, managers, employees]:
	... group.discard('Susan') # unconditionally remove element
	... print group
	...
	Set(['Jane', 'Marvin', 'Janice', 'John', 'Jack'])
	Set(['Janice', 'Jack', 'Sam'])
	Set(['Jane', 'Zack', 'Jack'])
	Set(['Jack', 'Sam', 'Jane', 'Marvin', 'Janice', 'John', 'Zack'])


	.. _immutable-transforms:

	Protocol for automatic conversion to immutable
	----------------------------------------------

	Sets can only contain immutable elements. For convenience, mutable :class:`Set`
	objects are automatically copied to an :class:`ImmutableSet` before being added
	as a set element.

	The mechanism is to always add a :term:`hashable` element, or if it is not
	hashable, the element is checked to see if it has an :meth:`__as_immutable__`
	method which returns an immutable equivalent.

	Since :class:`Set` objects have a :meth:`__as_immutable__` method returning an
	instance of :class:`ImmutableSet`, it is possible to construct sets of sets.

	A similar mechanism is needed by the :meth:`__contains__` and :meth:`remove`
	methods which need to hash an element to check for membership in a set. Those
	methods check an element for hashability and, if not, check for a
	:meth:`__as_temporarily_immutable__` method which returns the element wrapped by
	a class that provides temporary methods for :meth:`__hash__`, :meth:`__eq__`,
	and :meth:`__ne__`.

	The alternate mechanism spares the need to build a separate copy of the original
	mutable object.

	:class:`Set` objects implement the :meth:`__as_temporarily_immutable__` method
	which returns the :class:`Set` object wrapped by a new class
	:class:`_TemporarilyImmutableSet`.

	The two mechanisms for adding hashability are normally invisible to the user;
	however, a conflict can arise in a multi-threaded environment where one thread
	is updating a set while another has temporarily wrapped it in
	:class:`_TemporarilyImmutableSet`. In other words, sets of mutable sets are not
	thread-safe.


	.. _comparison-to-builtin-set:

	Comparison to the built-in :class:`set` types
	---------------------------------------------

	The built-in :class:`set` and :class:`frozenset` types were designed based on
	lessons learned from the :mod:`sets` module. The key differences are:

	* :class:`Set` and :class:`ImmutableSet` were renamed to :class:`set` and
	:class:`frozenset`.

	* There is no equivalent to :class:`BaseSet`. Instead, use ``isinstance(x,
	(set, frozenset))``.

	* The hash algorithm for the built-ins performs significantly better (fewer
	collisions) for most datasets.

	* The built-in versions have more space efficient pickles.

	* The built-in versions do not have a :meth:`union_update` method. Instead, use
	the :meth:`update` method which is equivalent.

	* The built-in versions do not have a ``_repr(sorted=True)`` method.
	Instead, use the built-in :func:`repr` and :func:`sorted` functions:
	``repr(sorted(s))``.

	* The built-in version does not have a protocol for automatic conversion to
	immutable. Many found this feature to be confusing and no one in the community
	reported having found real uses for it.