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# SOME DESCRIPTIVE TITLE.

# This file is distributed under the same license as the Python package.

# FIRST AUTHOR <EMAIL@ADDRESS>, YEAR.

# Translators:

# python-doc bot, 2025

#, fuzzy

msgid ""

msgstr ""

"Project-Id-Version: Python 3.14\n"

"Report-Msgid-Bugs-To: \n"

"POT-Creation-Date: 2026-03-17 14:51+0000\n"

"PO-Revision-Date: 2025-09-16 00:00+0000\n"

"Last-Translator: python-doc bot, 2025\n"

"Language-Team: Indonesian (https://app.transifex.com/python-doc/teams/5390/"

"id/)\n"

"MIME-Version: 1.0\n"

"Content-Type: text/plain; charset=UTF-8\n"

"Content-Transfer-Encoding: 8bit\n"

"Language: id\n"

"Plural-Forms: nplurals=1; plural=0;\n"

msgid "Sorting Techniques"

msgstr ""

msgid "Author"

msgstr "Penulis"

msgid "Andrew Dalke and Raymond Hettinger"

msgstr "Andrew Dalke dan Raymond Hettinger"

msgid ""

"Python lists have a built-in :meth:`list.sort` method that modifies the list "

"in-place. There is also a :func:`sorted` built-in function that builds a "

"new sorted list from an iterable."

msgstr ""

msgid ""

"In this document, we explore the various techniques for sorting data using "

"Python."

msgstr ""

msgid "Sorting Basics"

msgstr ""

msgid ""

"A simple ascending sort is very easy: just call the :func:`sorted` function. "

"It returns a new sorted list:"

msgstr ""

msgid ""

">>> sorted([5, 2, 3, 1, 4])\n"

"[1, 2, 3, 4, 5]"

msgstr ""

msgid ""

"You can also use the :meth:`list.sort` method. It modifies the list in-place "

"(and returns ``None`` to avoid confusion). Usually it's less convenient "

"than :func:`sorted` - but if you don't need the original list, it's slightly "

"more efficient."

msgstr ""

msgid ""

">>> a = [5, 2, 3, 1, 4]\n"

">>> a.sort()\n"

">>> a\n"

"[1, 2, 3, 4, 5]"

msgstr ""

msgid ""

"Another difference is that the :meth:`list.sort` method is only defined for "

"lists. In contrast, the :func:`sorted` function accepts any iterable."

msgstr ""

msgid ""

">>> sorted({1: 'D', 2: 'B', 3: 'B', 4: 'E', 5: 'A'})\n"

"[1, 2, 3, 4, 5]"

msgstr ""

msgid "Key Functions"

msgstr ""

msgid ""

"The :meth:`list.sort` method and the functions :func:`sorted`, :func:`min`, :"

"func:`max`, :func:`heapq.nsmallest`, and :func:`heapq.nlargest` have a *key* "

"parameter to specify a function (or other callable) to be called on each "

"list element prior to making comparisons."

msgstr ""

msgid ""

"For example, here's a case-insensitive string comparison using :meth:`str."

"casefold`:"

msgstr ""

msgid ""

">>> sorted(\"This is a test string from Andrew\".split(), key=str.casefold)\n"

"['a', 'Andrew', 'from', 'is', 'string', 'test', 'This']"

msgstr ""

msgid ""

"The value of the *key* parameter should be a function (or other callable) "

"that takes a single argument and returns a key to use for sorting purposes. "

"This technique is fast because the key function is called exactly once for "

"each input record."

msgstr ""

msgid ""

"A common pattern is to sort complex objects using some of the object's "

"indices as keys. For example:"

msgstr ""

msgid ""

">>> student_tuples = [\n"

"... ('john', 'A', 15),\n"

"... ('jane', 'B', 12),\n"

"... ('dave', 'B', 10),\n"

"... ]\n"

">>> sorted(student_tuples, key=lambda student: student[2]) # sort by age\n"

"[('dave', 'B', 10), ('jane', 'B', 12), ('john', 'A', 15)]"

msgstr ""

msgid ""

"The same technique works for objects with named attributes. For example:"

msgstr ""

msgid ""

">>> class Student:\n"

"... def __init__(self, name, grade, age):\n"

"... self.name = name\n"

"... self.grade = grade\n"

"... self.age = age\n"

"... def __repr__(self):\n"

"... return repr((self.name, self.grade, self.age))\n"

"\n"

">>> student_objects = [\n"

"... Student('john', 'A', 15),\n"

"... Student('jane', 'B', 12),\n"

"... Student('dave', 'B', 10),\n"

"... ]\n"

">>> sorted(student_objects, key=lambda student: student.age) # sort by "

"age\n"

"[('dave', 'B', 10), ('jane', 'B', 12), ('john', 'A', 15)]"

msgstr ""

msgid ""

"Objects with named attributes can be made by a regular class as shown above, "

"or they can be instances of :class:`~dataclasses.dataclass` or a :term:"

"`named tuple`."

msgstr ""

msgid "Operator Module Functions and Partial Function Evaluation"

msgstr ""

msgid ""

"The :term:`key function` patterns shown above are very common, so Python "

"provides convenience functions to make accessor functions easier and faster. "

"The :mod:`operator` module has :func:`~operator.itemgetter`, :func:"

"`~operator.attrgetter`, and a :func:`~operator.methodcaller` function."

msgstr ""

msgid "Using those functions, the above examples become simpler and faster:"

msgstr ""

msgid ""

">>> from operator import itemgetter, attrgetter\n"

"\n"

">>> sorted(student_tuples, key=itemgetter(2))\n"

"[('dave', 'B', 10), ('jane', 'B', 12), ('john', 'A', 15)]\n"

"\n"

">>> sorted(student_objects, key=attrgetter('age'))\n"

"[('dave', 'B', 10), ('jane', 'B', 12), ('john', 'A', 15)]"

msgstr ""

msgid ""

"The operator module functions allow multiple levels of sorting. For example, "

"to sort by *grade* then by *age*:"

msgstr ""

msgid ""

">>> sorted(student_tuples, key=itemgetter(1,2))\n"

"[('john', 'A', 15), ('dave', 'B', 10), ('jane', 'B', 12)]\n"

"\n"

">>> sorted(student_objects, key=attrgetter('grade', 'age'))\n"

"[('john', 'A', 15), ('dave', 'B', 10), ('jane', 'B', 12)]"

msgstr ""

msgid ""

"The :mod:`functools` module provides another helpful tool for making key-"

"functions. The :func:`~functools.partial` function can reduce the `arity "

"<https://en.wikipedia.org/wiki/Arity>`_ of a multi-argument function making "

"it suitable for use as a key-function."

msgstr ""

msgid ""

">>> from functools import partial\n"

">>> from unicodedata import normalize\n"

"\n"

">>> names = 'Zoë Åbjørn Núñez Élana Zeke Abe Nubia Eloise'.split()\n"

"\n"

">>> sorted(names, key=partial(normalize, 'NFD'))\n"

"['Abe', 'Åbjørn', 'Eloise', 'Élana', 'Nubia', 'Núñez', 'Zeke', 'Zoë']\n"

"\n"

">>> sorted(names, key=partial(normalize, 'NFC'))\n"

"['Abe', 'Eloise', 'Nubia', 'Núñez', 'Zeke', 'Zoë', 'Åbjørn', 'Élana']"

msgstr ""

msgid "Ascending and Descending"

msgstr ""

msgid ""

"Both :meth:`list.sort` and :func:`sorted` accept a *reverse* parameter with "

"a boolean value. This is used to flag descending sorts. For example, to get "

"the student data in reverse *age* order:"

msgstr ""

msgid ""

">>> sorted(student_tuples, key=itemgetter(2), reverse=True)\n"

"[('john', 'A', 15), ('jane', 'B', 12), ('dave', 'B', 10)]\n"

"\n"

">>> sorted(student_objects, key=attrgetter('age'), reverse=True)\n"

"[('john', 'A', 15), ('jane', 'B', 12), ('dave', 'B', 10)]"

msgstr ""

msgid "Sort Stability and Complex Sorts"

msgstr ""

msgid ""

"Sorts are guaranteed to be `stable <https://en.wikipedia.org/wiki/"

"Sorting_algorithm#Stability>`_\\. That means that when multiple records have "

"the same key, their original order is preserved."

msgstr ""

msgid ""

">>> data = [('red', 1), ('blue', 1), ('red', 2), ('blue', 2)]\n"

">>> sorted(data, key=itemgetter(0))\n"

"[('blue', 1), ('blue', 2), ('red', 1), ('red', 2)]"

msgstr ""

msgid ""

"Notice how the two records for *blue* retain their original order so that "

"``('blue', 1)`` is guaranteed to precede ``('blue', 2)``."

msgstr ""

msgid ""

"This wonderful property lets you build complex sorts in a series of sorting "

"steps. For example, to sort the student data by descending *grade* and then "

"ascending *age*, do the *age* sort first and then sort again using *grade*:"

msgstr ""

msgid ""

">>> s = sorted(student_objects, key=attrgetter('age')) # sort on "

"secondary key\n"

">>> sorted(s, key=attrgetter('grade'), reverse=True) # now sort on "

"primary key, descending\n"

"[('dave', 'B', 10), ('jane', 'B', 12), ('john', 'A', 15)]"

msgstr ""

msgid ""

"This can be abstracted out into a wrapper function that can take a list and "

"tuples of field and order to sort them on multiple passes."

msgstr ""

msgid ""

">>> def multisort(xs, specs):\n"

"... for key, reverse in reversed(specs):\n"

"... xs.sort(key=attrgetter(key), reverse=reverse)\n"

"... return xs\n"

"\n"

">>> multisort(list(student_objects), (('grade', True), ('age', False)))\n"

"[('dave', 'B', 10), ('jane', 'B', 12), ('john', 'A', 15)]"

msgstr ""

msgid ""

"The `Timsort <https://en.wikipedia.org/wiki/Timsort>`_ algorithm used in "

"Python does multiple sorts efficiently because it can take advantage of any "

"ordering already present in a dataset."

msgstr ""

msgid "Decorate-Sort-Undecorate"

msgstr ""

msgid "This idiom is called Decorate-Sort-Undecorate after its three steps:"

msgstr ""

msgid ""

"First, the initial list is decorated with new values that control the sort "

"order."

msgstr ""

msgid "Second, the decorated list is sorted."

msgstr ""

msgid ""

"Finally, the decorations are removed, creating a list that contains only the "

"initial values in the new order."

msgstr ""

msgid ""

"For example, to sort the student data by *grade* using the DSU approach:"

msgstr ""

msgid ""

">>> decorated = [(student.grade, i, student) for i, student in "

"enumerate(student_objects)]\n"

">>> decorated.sort()\n"

">>> [student for grade, i, student in decorated] # undecorate\n"

"[('john', 'A', 15), ('jane', 'B', 12), ('dave', 'B', 10)]"

msgstr ""

msgid ""

"This idiom works because tuples are compared lexicographically; the first "

"items are compared; if they are the same then the second items are compared, "

"and so on."

msgstr ""

msgid ""

"It is not strictly necessary in all cases to include the index *i* in the "

"decorated list, but including it gives two benefits:"

msgstr ""

msgid ""

"The sort is stable -- if two items have the same key, their order will be "

"preserved in the sorted list."

msgstr ""

msgid ""

"The original items do not have to be comparable because the ordering of the "

"decorated tuples will be determined by at most the first two items. So for "

"example the original list could contain complex numbers which cannot be "

"sorted directly."

msgstr ""

msgid ""

"Another name for this idiom is `Schwartzian transform <https://en.wikipedia."

"org/wiki/Schwartzian_transform>`_\\, after Randal L. Schwartz, who "

"popularized it among Perl programmers."

msgstr ""

msgid ""

"Now that Python sorting provides key-functions, this technique is not often "

"needed."

msgstr ""

msgid "Comparison Functions"

msgstr ""

msgid ""

"Unlike key functions that return an absolute value for sorting, a comparison "

"function computes the relative ordering for two inputs."

msgstr ""

msgid ""

"For example, a `balance scale <https://upload.wikimedia.org/wikipedia/"

"commons/1/17/Balance_à_tabac_1850.JPG>`_ compares two samples giving a "

"relative ordering: lighter, equal, or heavier. Likewise, a comparison "

"function such as ``cmp(a, b)`` will return a negative value for less-than, "

"zero if the inputs are equal, or a positive value for greater-than."

msgstr ""

msgid ""

"It is common to encounter comparison functions when translating algorithms "

"from other languages. Also, some libraries provide comparison functions as "

"part of their API. For example, :func:`locale.strcoll` is a comparison "

"function."

msgstr ""

msgid ""

"To accommodate those situations, Python provides :class:`functools."

"cmp_to_key` to wrap the comparison function to make it usable as a key "

"function::"

msgstr ""

msgid "sorted(words, key=cmp_to_key(strcoll)) # locale-aware sort order"

msgstr ""

msgid "Strategies For Unorderable Types and Values"

msgstr ""

msgid ""

"A number of type and value issues can arise when sorting. Here are some "

"strategies that can help:"

msgstr ""

msgid "Convert non-comparable input types to strings prior to sorting:"

msgstr ""

msgid ""

">>> data = ['twelve', '11', 10]\n"

">>> sorted(map(str, data))\n"

"['10', '11', 'twelve']"

msgstr ""

msgid ""

"This is needed because most cross-type comparisons raise a :exc:`TypeError`."

msgstr ""

msgid "Remove special values prior to sorting:"

msgstr ""

msgid ""

">>> from math import isnan\n"

">>> from itertools import filterfalse\n"

">>> data = [3.3, float('nan'), 1.1, 2.2]\n"

">>> sorted(filterfalse(isnan, data))\n"

"[1.1, 2.2, 3.3]"

msgstr ""

msgid ""

"This is needed because the `IEEE-754 standard <https://en.wikipedia.org/wiki/"

"IEEE_754>`_ specifies that, \"Every NaN shall compare unordered with "

"everything, including itself.\""

msgstr ""

msgid "Likewise, ``None`` can be stripped from datasets as well:"

msgstr ""

msgid ""

">>> data = [3.3, None, 1.1, 2.2]\n"

">>> sorted(x for x in data if x is not None)\n"

"[1.1, 2.2, 3.3]"

msgstr ""

msgid "This is needed because ``None`` is not comparable to other types."

msgstr ""

msgid "Convert mapping types into sorted item lists before sorting:"

msgstr ""

msgid ""

">>> data = [{'a': 1}, {'b': 2}]\n"

">>> sorted(data, key=lambda d: sorted(d.items()))\n"

"[{'a': 1}, {'b': 2}]"

msgstr ""

msgid ""

"This is needed because dict-to-dict comparisons raise a :exc:`TypeError`."

msgstr ""

msgid "Convert set types into sorted lists before sorting:"

msgstr ""

msgid ""

">>> data = [{'a', 'b', 'c'}, {'b', 'c', 'd'}]\n"

">>> sorted(map(sorted, data))\n"

"[['a', 'b', 'c'], ['b', 'c', 'd']]"

msgstr ""

msgid ""

"This is needed because the elements contained in set types do not have a "

"deterministic order. For example, ``list({'a', 'b'})`` may produce either "

"``['a', 'b']`` or ``['b', 'a']``."

msgstr ""

msgid "Odds and Ends"

msgstr "Barang Sisa *Odds and Ends*"

msgid ""

"For locale aware sorting, use :func:`locale.strxfrm` for a key function or :"

"func:`locale.strcoll` for a comparison function. This is necessary because "

"\"alphabetical\" sort orderings can vary across cultures even if the "

"underlying alphabet is the same."

msgstr ""

msgid ""

"The *reverse* parameter still maintains sort stability (so that records with "

"equal keys retain the original order). Interestingly, that effect can be "

"simulated without the parameter by using the builtin :func:`reversed` "

"function twice:"

msgstr ""

msgid ""

">>> data = [('red', 1), ('blue', 1), ('red', 2), ('blue', 2)]\n"

">>> standard_way = sorted(data, key=itemgetter(0), reverse=True)\n"

">>> double_reversed = list(reversed(sorted(reversed(data), "

"key=itemgetter(0))))\n"

">>> assert standard_way == double_reversed\n"

">>> standard_way\n"

"[('red', 1), ('red', 2), ('blue', 1), ('blue', 2)]"

msgstr ""

msgid ""

"The sort routines use ``<`` when making comparisons between two objects. So, "

"it is easy to add a standard sort order to a class by defining an :meth:"

"`~object.__lt__` method:"

msgstr ""

msgid ""

">>> Student.__lt__ = lambda self, other: self.age < other.age\n"

">>> sorted(student_objects)\n"

"[('dave', 'B', 10), ('jane', 'B', 12), ('john', 'A', 15)]"

msgstr ""

msgid ""

"However, note that ``<`` can fall back to using :meth:`~object.__gt__` if :"

"meth:`~object.__lt__` is not implemented (see :func:`object.__lt__` for "

"details on the mechanics). To avoid surprises, :pep:`8` recommends that all "

"six comparison methods be implemented. The :func:`~functools.total_ordering` "

"decorator is provided to make that task easier."

msgstr ""

msgid ""

"Key functions need not depend directly on the objects being sorted. A key "

"function can also access external resources. For instance, if the student "

"grades are stored in a dictionary, they can be used to sort a separate list "

"of student names:"

msgstr ""

msgid ""

">>> students = ['dave', 'john', 'jane']\n"

">>> newgrades = {'john': 'F', 'jane':'A', 'dave': 'C'}\n"

">>> sorted(students, key=newgrades.__getitem__)\n"

"['jane', 'dave', 'john']"

msgstr ""

msgid "Partial Sorts"

msgstr ""

msgid ""

"Some applications require only some of the data to be ordered. The standard "

"library provides several tools that do less work than a full sort:"

msgstr ""

msgid ""

":func:`min` and :func:`max` return the smallest and largest values, "

"respectively. These functions make a single pass over the input data and "

"require almost no auxiliary memory."

msgstr ""

msgid ""

":func:`heapq.nsmallest` and :func:`heapq.nlargest` return the *n* smallest "

"and largest values, respectively. These functions make a single pass over "

"the data keeping only *n* elements in memory at a time. For values of *n* "

"that are small relative to the number of inputs, these functions make far "

"fewer comparisons than a full sort."

msgstr ""

msgid ""

":func:`heapq.heappush` and :func:`heapq.heappop` create and maintain a "

"partially sorted arrangement of data that keeps the smallest element at "

"position ``0``. These functions are suitable for implementing priority "

"queues which are commonly used for task scheduling."

msgstr ""

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