PEP: 218 Title: Adding a Built-In Set Object Type Version: $Revision$ Last-Modified: $Date$ Author: gvwilson@ddj.com (Greg Wilson), python@rcn.com (Raymond Hettinger) Status: Final Type: Standards Track Content-Type: text/x-rst Created: 31-Jul-2000 Python-Version: 2.2 Post-History: Introduction ============ This PEP proposes adding a Set module to the standard Python library, and to then make sets a built-in Python type if that module is widely used. After explaining why sets are desirable, and why the common idiom of using dictionaries in their place is inadequate, we describe how we intend built-in sets to work, and then how the preliminary Set module will behave. The last section discusses the mutability (or otherwise) of sets and set elements, and the solution which the Set module will implement. Rationale ========= Sets are a fundamental mathematical structure, and are very commonly used in algorithm specifications. They are much less frequently used in implementations, even when they are the "right" structure. Programmers frequently use lists instead, even when the ordering information in lists is irrelevant, and by-value lookups are frequent. (Most medium-sized C programs contain a depressing number of start-to-end searches through malloc'd vectors to determine whether particular items are present or not...) Programmers are often told that they can implement sets as dictionaries with "don't care" values. Items can be added to these "sets" by assigning the "don't care" value to them; membership can be tested using "dict.has_key"; and items can be deleted using "del". However, the other main operations on sets (union, intersection, and difference) are not directly supported by this representation, since their meaning is ambiguous for dictionaries containing key/value pairs. Proposal ======== The long-term goal of this PEP is to add a built-in set type to Python. This type will be an unordered collection of unique values, just as a dictionary is an unordered collection of key/value pairs. Iteration and comprehension will be implemented in the obvious ways, so that:: for x in S: will step through the elements of S in arbitrary order, while:: set(x**2 for x in S) will produce a set containing the squares of all elements in S, Membership will be tested using "in" and "not in", and basic set operations will be implemented by a mixture of overloaded operators: ========= ============================= \| union & intersection ^ symmetric difference \- asymmetric difference == != equality and inequality tests < <= >= > subset and superset tests ========= ============================= and methods: ================== ============================================ ``S.add(x)`` Add "x" to the set. ``S.update(s)`` Add all elements of sequence "s" to the set. ``S.remove(x)`` Remove "x" from the set. If "x" is not present, this method raises a ``LookupError`` exception. ``S.discard(x)`` Remove "x" from the set if it is present, or do nothing if it is not. ``S.pop()`` Remove and return an arbitrary element, raising a LookupError if the element is not present. ``S.clear()`` Remove all elements from this set. ``S.copy()`` Make a new set. ``s.issuperset()`` Check for a superset relationship. ``s.issubset()`` Check for a subset relationship. ================== ============================================ and two new built-in conversion functions: ================ =============================================== ``set(x)`` Create a set containing the elements of the collection "x". ``frozenset(x)`` Create an immutable set containing the elements of the collection "x". ================ =============================================== Notes: 1. We propose using the bitwise operators "\|\&" for intersection and union. While "+" for union would be intuitive, "\*" for intersection is not (very few of the people asked guessed what it did correctly). 2. We considered using "+" to add elements to a set, rather than "add". However, Guido van Rossum pointed out that "+" is symmetric for other built-in types (although "\*" is not). Use of "add" will also avoid confusion between that operation and set union. Set Notation ============ The PEP originally proposed {1,2,3} as the set notation and {-} for the empty set. Experience with Python 2.3's sets.py showed that the notation was not necessary. Also, there was some risk of making dictionaries less instantly recognizable. It was also contemplated that the braced notation would support set comprehensions; however, Python 2.4 provided generator expressions which fully met that need and did so it a more general way. (See PEP 289 for details on generator expressions). So, Guido ruled that there would not be a set syntax; however, the issue could be revisited for Python 3000 (see PEP 3000). History ======= To gain experience with sets, a pure python module was introduced in Python 2.3. Based on that implementation, the set and frozenset types were introduced in Python 2.4. The improvements are: * Better hash algorithm for frozensets * More compact pickle format (storing only an element list instead of a dictionary of key:value pairs where the value is always True). * Use a ``__reduce__`` function so that deep copying is automatic. * The BaseSet concept was eliminated. * The ``union_update()`` method became just ``update()``. * Auto-conversion between mutable and immutable sets was dropped. * The ``_repr`` method was dropped (the need is met by the new ``sorted()`` built-in function). Tim Peters believes that the class's constructor should take a single sequence as an argument, and populate the set with that sequence's elements. His argument is that in most cases, programmers will be creating sets from pre-existing sequences, so that this case should be the common one. However, this would require users to remember an extra set of parentheses when initializing a set with known values:: >>> Set((1, 2, 3, 4)) # case 1 On the other hand, feedback from a small number of novice Python users (all of whom were very experienced with other languages) indicates that people will find a "parenthesis-free" syntax more natural:: >>> Set(1, 2, 3, 4) # case 2 Ultimately, we adopted the first strategy in which the initializer takes a single iterable argument. Mutability ========== The most difficult question to resolve in this proposal was whether sets ought to be able to contain mutable elements. A dictionary's keys must be immutable in order to support fast, reliable lookup. While it would be easy to require set elements to be immutable, this would preclude sets of sets (which are widely used in graph algorithms and other applications). Earlier drafts of PEP 218 had only a single set type, but the sets.py implementation in Python 2.3 has two, Set and ImmutableSet. For Python 2.4, the new built-in types were named set and frozenset which are slightly less cumbersome. There are two classes implemented in the "sets" module. Instances of the Set class can be modified by the addition or removal of elements, and the ImmutableSet class is "frozen", with an unchangeable collection of elements. Therefore, an ImmutableSet may be used as a dictionary key or as a set element, but cannot be updated. Both types of set require that their elements are immutable, hashable objects. Parallel comments apply to the "set" and "frozenset" built-in types. Copyright ========= This document has been placed in the Public Domain. .. 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