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Python Enhancement Proposals

PEP 372 – Adding an ordered dictionary to collections

Author:
Armin Ronacher <armin.ronacher at active-4.com>, Raymond Hettinger <python at rcn.com>
Status:
Final
Type:
Standards Track
Created:
15-Jun-2008
Python-Version:
2.7, 3.1
Post-History:


Table of Contents

Abstract

This PEP proposes an ordered dictionary as a new data structure for the collections module, called “OrderedDict” in this PEP. The proposed API incorporates the experiences gained from working with similar implementations that exist in various real-world applications and other programming languages.

Patch

A working Py3.1 patch including tests and documentation is at:

The check-in was in revisions: 70101 and 70102

Rationale

In current Python versions, the widely used built-in dict type does not specify an order for the key/value pairs stored. This makes it hard to use dictionaries as data storage for some specific use cases.

Some dynamic programming languages like PHP and Ruby 1.9 guarantee a certain order on iteration. In those languages, and existing Python ordered-dict implementations, the ordering of items is defined by the time of insertion of the key. New keys are appended at the end, but keys that are overwritten are not moved to the end.

The following example shows the behavior for simple assignments:

>>> d = OrderedDict()
>>> d['parrot'] = 'dead'
>>> d['penguin'] = 'exploded'
>>> d.items()
[('parrot', 'dead'), ('penguin', 'exploded')]

That the ordering is preserved makes an OrderedDict useful for a couple of situations:

  • XML/HTML processing libraries currently drop the ordering of attributes, use a list instead of a dict which makes filtering cumbersome, or implement their own ordered dictionary. This affects ElementTree, html5lib, Genshi and many more libraries.
  • There are many ordered dict implementations in various libraries and applications, most of them subtly incompatible with each other. Furthermore, subclassing dict is a non-trivial task and many implementations don’t override all the methods properly which can lead to unexpected results.

    Additionally, many ordered dicts are implemented in an inefficient way, making many operations more complex then they have to be.

  • PEP 3115 allows metaclasses to change the mapping object used for the class body. An ordered dict could be used to create ordered member declarations similar to C structs. This could be useful, for example, for future ctypes releases as well as ORMs that define database tables as classes, like the one the Django framework ships. Django currently uses an ugly hack to restore the ordering of members in database models.
  • The RawConfigParser class accepts a dict_type argument that allows an application to set the type of dictionary used internally. The motivation for this addition was expressly to allow users to provide an ordered dictionary. [1]
  • Code ported from other programming languages such as PHP often depends on an ordered dict. Having an implementation of an ordering-preserving dictionary in the standard library could ease the transition and improve the compatibility of different libraries.

Ordered Dict API

The ordered dict API would be mostly compatible with dict and existing ordered dicts. Note: this PEP refers to the 2.7 and 3.0 dictionary API as described in collections.Mapping abstract base class.

The constructor and update() both accept iterables of tuples as well as mappings like a dict does. Unlike a regular dictionary, the insertion order is preserved.

>>> d = OrderedDict([('a', 'b'), ('c', 'd')])
>>> d.update({'foo': 'bar'})
>>> d
collections.OrderedDict([('a', 'b'), ('c', 'd'), ('foo', 'bar')])

If ordered dicts are updated from regular dicts, the ordering of new keys is of course undefined.

All iteration methods as well as keys(), values() and items() return the values ordered by the time the key was first inserted:

>>> d['spam'] = 'eggs'
>>> d.keys()
['a', 'c', 'foo', 'spam']
>>> d.values()
['b', 'd', 'bar', 'eggs']
>>> d.items()
[('a', 'b'), ('c', 'd'), ('foo', 'bar'), ('spam', 'eggs')]

New methods not available on dict:

OrderedDict.__reversed__()
Supports reverse iteration by key.

Questions and Answers

What happens if an existing key is reassigned?

The key is not moved but assigned a new value in place. This is consistent with existing implementations.

What happens if keys appear multiple times in the list passed to the constructor?

The same as for regular dicts – the latter item overrides the former. This has the side-effect that the position of the first key is used because only the value is actually overwritten:
>>> OrderedDict([('a', 1), ('b', 2), ('a', 3)])
collections.OrderedDict([('a', 3), ('b', 2)])

This behavior is consistent with existing implementations in Python, the PHP array and the hashmap in Ruby 1.9.

Is the ordered dict a dict subclass? Why?

Yes. Like defaultdict, an ordered dictionary subclasses dict. Being a dict subclass make some of the methods faster (like __getitem__ and __len__). More importantly, being a dict subclass lets ordered dictionaries be usable with tools like json that insist on having dict inputs by testing isinstance(d, dict).

Do any limitations arise from subclassing dict?

Yes. Since the API for dicts is different in Py2.x and Py3.x, the OrderedDict API must also be different. So, the Py2.7 version will need to override iterkeys, itervalues, and iteritems.

Does OrderedDict.popitem() return a particular key/value pair?

Yes. It pops-off the most recently inserted new key and its corresponding value. This corresponds to the usual LIFO behavior exhibited by traditional push/pop pairs. It is semantically equivalent to k=list(od)[-1]; v=od[k]; del od[k]; return (k,v). The actual implementation is more efficient and pops directly from a sorted list of keys.

Does OrderedDict support indexing, slicing, and whatnot?

As a matter of fact, OrderedDict does not implement the Sequence interface. Rather, it is a MutableMapping that remembers the order of key insertion. The only sequence-like addition is support for reversed.

A further advantage of not allowing indexing is that it leaves open the possibility of a fast C implementation using linked lists.

Does OrderedDict support alternate sort orders such as alphabetical?

No. Those wanting different sort orders really need to be using another technique. The OrderedDict is all about recording insertion order. If any other order is of interest, then another structure (like an in-memory dbm) is likely a better fit.

How well does OrderedDict work with the json module, PyYAML, and ConfigParser?

For json, the good news is that json’s encoder respects OrderedDict’s iteration order:
>>> items = [('one', 1), ('two', 2), ('three',3), ('four',4), ('five',5)]
>>> json.dumps(OrderedDict(items))
'{"one": 1, "two": 2, "three": 3, "four": 4, "five": 5}'

In Py2.6, the object_hook for json decoders passes-in an already built dictionary so order is lost before the object hook sees it. This problem is being fixed for Python 2.7/3.1 by adding a new hook that preserves order (see https://github.com/python/cpython/issues/49631 ). With the new hook, order can be preserved:

>>> jtext = '{"one": 1, "two": 2, "three": 3, "four": 4, "five": 5}'
>>> json.loads(jtext, object_pairs_hook=OrderedDict)
OrderedDict({'one': 1, 'two': 2, 'three': 3, 'four': 4, 'five': 5})

For PyYAML, a full round-trip is problem free:

>>> ytext = yaml.dump(OrderedDict(items))
>>> print ytext
!!python/object/apply:collections.OrderedDict
- - [one, 1]
  - [two, 2]
  - [three, 3]
  - [four, 4]
  - [five, 5]

>>> yaml.load(ytext)
OrderedDict({'one': 1, 'two': 2, 'three': 3, 'four': 4, 'five': 5})

For the ConfigParser module, round-tripping is also problem free. Custom dicts were added in Py2.6 specifically to support ordered dictionaries:

>>> config = ConfigParser(dict_type=OrderedDict)
>>> config.read('myconfig.ini')
>>> config.remove_option('Log', 'error')
>>> config.write(open('myconfig.ini', 'w'))

How does OrderedDict handle equality testing?

Comparing two ordered dictionaries implies that the test will be order-sensitive so that list (od1.items())==list(od2.items()).

When ordered dicts are compared with other Mappings, their order insensitive comparison is used. This allows ordered dictionaries to be substituted anywhere regular dictionaries are used.

How __repr__ format will maintain order during a repr/eval round-trip?

OrderedDict([(‘a’, 1), (‘b’, 2)])

What are the trade-offs of the possible underlying data structures?

  • Keeping a sorted list of keys is fast for all operations except __delitem__() which becomes an O(n) exercise. This data structure leads to very simple code and little wasted space.
  • Keeping a separate dictionary to record insertion sequence numbers makes the code a little bit more complex. All of the basic operations are O(1) but the constant factor is increased for __setitem__() and __delitem__() meaning that every use case will have to pay for this speedup (since all buildup go through __setitem__). Also, the first traversal incurs a one-time O(n log n) sorting cost. The storage costs are double that for the sorted-list-of-keys approach.
  • A version written in C could use a linked list. The code would be more complex than the other two approaches but it would conserve space and would keep the same big-oh performance as regular dictionaries. It is the fastest and most space efficient.

Reference Implementation

An implementation with tests and documentation is at:

The proposed version has several merits:

  • Strict compliance with the MutableMapping API and no new methods so that the learning curve is near zero. It is simply a dictionary that remembers insertion order.
  • Generally good performance. The big-oh times are the same as regular dictionaries except that key deletion is O(n).

Other implementations of ordered dicts in various Python projects or standalone libraries, that inspired the API proposed here, are:

Future Directions

With the availability of an ordered dict in the standard library, other libraries may take advantage of that. For example, ElementTree could return odicts in the future that retain the attribute ordering of the source file.

References


Source: https://github.com/python/peps/blob/main/peps/pep-0372.rst

Last modified: 2023-09-09 17:39:29 GMT