Doc/library/bisect.rst - platform/external/python/cpython3 - Gitiles

 :mod:`bisect` --- Array bisection algorithm
 ===========================================

 .. module:: bisect
    :synopsis: Array bisection algorithms for binary searching.
 .. sectionauthor:: Fred L. Drake, Jr. <fdrake@acm.org>
 .. sectionauthor:: Raymond Hettinger <python at rcn.com>
 .. example based on the PyModules FAQ entry by Aaron Watters <arw@pythonpros.com>

 **Source code:** :source:`Lib/bisect.py`

 --------------

 This module provides support for maintaining a list in sorted order without
 having to sort the list after each insertion.  For long lists of items with
 expensive comparison operations, this can be an improvement over the more common
 approach.  The module is called :mod:`bisect` because it uses a basic bisection
 algorithm to do its work.  The source code may be most useful as a working
 example of the algorithm (the boundary conditions are already right!).

 The following functions are provided:


 .. function:: bisect_left(a, x, lo=0, hi=len(a))

    Locate the insertion point for *x* in *a* to maintain sorted order.
    The parameters *lo* and *hi* may be used to specify a subset of the list
    which should be considered; by default the entire list is used.  If *x* is
    already present in *a*, the insertion point will be before (to the left of)
    any existing entries.  The return value is suitable for use as the first
    parameter to ``list.insert()`` assuming that *a* is already sorted.

    The returned insertion point *i* partitions the array *a* into two halves so
    that ``all(val < x for val in a[lo:i])`` for the left side and
    ``all(val >= x for val in a[i:hi])`` for the right side.

 .. function:: bisect_right(a, x, lo=0, hi=len(a))
               bisect(a, x, lo=0, hi=len(a))

    Similar to :func:`bisect_left`, but returns an insertion point which comes
    after (to the right of) any existing entries of *x* in *a*.

    The returned insertion point *i* partitions the array *a* into two halves so
    that ``all(val <= x for val in a[lo:i])`` for the left side and
    ``all(val > x for val in a[i:hi])`` for the right side.

 .. function:: insort_left(a, x, lo=0, hi=len(a))

    Insert *x* in *a* in sorted order.  This is equivalent to
    ``a.insert(bisect.bisect_left(a, x, lo, hi), x)`` assuming that *a* is
    already sorted.  Keep in mind that the O(log n) search is dominated by
    the slow O(n) insertion step.

 .. function:: insort_right(a, x, lo=0, hi=len(a))
               insort(a, x, lo=0, hi=len(a))

    Similar to :func:`insort_left`, but inserting *x* in *a* after any existing
    entries of *x*.

 .. seealso::

    `SortedCollection recipe
    <https://code.activestate.com/recipes/577197-sortedcollection/>`_ that uses
    bisect to build a full-featured collection class with straight-forward search
    methods and support for a key-function.  The keys are precomputed to save
    unnecessary calls to the key function during searches.


 Searching Sorted Lists
 ----------------------

 The above :func:`bisect` functions are useful for finding insertion points but
 can be tricky or awkward to use for common searching tasks. The following five
 functions show how to transform them into the standard lookups for sorted
 lists::

     def index(a, x):
         'Locate the leftmost value exactly equal to x'
         i = bisect_left(a, x)
         if i != len(a) and a[i] == x:
             return i
         raise ValueError

     def find_lt(a, x):
         'Find rightmost value less than x'
         i = bisect_left(a, x)
         if i:
             return a[i-1]
         raise ValueError

     def find_le(a, x):
         'Find rightmost value less than or equal to x'
         i = bisect_right(a, x)
         if i:
             return a[i-1]
         raise ValueError

     def find_gt(a, x):
         'Find leftmost value greater than x'
         i = bisect_right(a, x)
         if i != len(a):
             return a[i]
         raise ValueError

     def find_ge(a, x):
         'Find leftmost item greater than or equal to x'
         i = bisect_left(a, x)
         if i != len(a):
             return a[i]
         raise ValueError


 Other Examples
 --------------

 .. _bisect-example:

 The :func:`bisect` function can be useful for numeric table lookups. This
 example uses :func:`bisect` to look up a letter grade for an exam score (say)
 based on a set of ordered numeric breakpoints: 90 and up is an 'A', 80 to 89 is
 a 'B', and so on::

    >>> def grade(score, breakpoints=[60, 70, 80, 90], grades='FDCBA'):
    ...     i = bisect(breakpoints, score)
    ...     return grades[i]
    ...
    >>> [grade(score) for score in [33, 99, 77, 70, 89, 90, 100]]
    ['F', 'A', 'C', 'C', 'B', 'A', 'A']

 Unlike the :func:`sorted` function, it does not make sense for the :func:`bisect`
 functions to have *key* or *reversed* arguments because that would lead to an
 inefficient design (successive calls to bisect functions would not "remember"
 all of the previous key lookups).

 Instead, it is better to search a list of precomputed keys to find the index
 of the record in question::

     >>> data = [('red', 5), ('blue', 1), ('yellow', 8), ('black', 0)]
     >>> data.sort(key=lambda r: r[1])
     >>> keys = [r[1] for r in data]         # precomputed list of keys
     >>> data[bisect_left(keys, 0)]
     ('black', 0)
     >>> data[bisect_left(keys, 1)]
     ('blue', 1)
     >>> data[bisect_left(keys, 5)]
     ('red', 5)
     >>> data[bisect_left(keys, 8)]
     ('yellow', 8)
	:mod:`bisect` --- Array bisection algorithm
	===========================================

	.. module:: bisect
	:synopsis: Array bisection algorithms for binary searching.
	.. sectionauthor:: Fred L. Drake, Jr. <fdrake@acm.org>
	.. sectionauthor:: Raymond Hettinger <python at rcn.com>
	.. example based on the PyModules FAQ entry by Aaron Watters <arw@pythonpros.com>

	Source code: :source:`Lib/bisect.py`

	--------------

	This module provides support for maintaining a list in sorted order without
	having to sort the list after each insertion. For long lists of items with
	expensive comparison operations, this can be an improvement over the more common
	approach. The module is called :mod:`bisect` because it uses a basic bisection
	algorithm to do its work. The source code may be most useful as a working
	example of the algorithm (the boundary conditions are already right!).

	The following functions are provided:


	.. function:: bisect_left(a, x, lo=0, hi=len(a))

	Locate the insertion point for x in a to maintain sorted order.
	The parameters lo and hi may be used to specify a subset of the list
	which should be considered; by default the entire list is used. If x is
	already present in a, the insertion point will be before (to the left of)
	any existing entries. The return value is suitable for use as the first
	parameter to ``list.insert()`` assuming that a is already sorted.

	The returned insertion point i partitions the array a into two halves so
	that ``all(val < x for val in a[lo:i])`` for the left side and
	``all(val >= x for val in a[i:hi])`` for the right side.

	.. function:: bisect_right(a, x, lo=0, hi=len(a))
	bisect(a, x, lo=0, hi=len(a))

	Similar to :func:`bisect_left`, but returns an insertion point which comes
	after (to the right of) any existing entries of x in a.

	The returned insertion point i partitions the array a into two halves so
	that ``all(val <= x for val in a[lo:i])`` for the left side and
	``all(val > x for val in a[i:hi])`` for the right side.

	.. function:: insort_left(a, x, lo=0, hi=len(a))

	Insert x in a in sorted order. This is equivalent to
	``a.insert(bisect.bisect_left(a, x, lo, hi), x)`` assuming that a is
	already sorted. Keep in mind that the O(log n) search is dominated by
	the slow O(n) insertion step.

	.. function:: insort_right(a, x, lo=0, hi=len(a))
	insort(a, x, lo=0, hi=len(a))

	Similar to :func:`insort_left`, but inserting x in a after any existing
	entries of x.

	.. seealso::

	`SortedCollection recipe
	<https://code.activestate.com/recipes/577197-sortedcollection/>`_ that uses
	bisect to build a full-featured collection class with straight-forward search
	methods and support for a key-function. The keys are precomputed to save
	unnecessary calls to the key function during searches.


	Searching Sorted Lists
	----------------------

	The above :func:`bisect` functions are useful for finding insertion points but
	can be tricky or awkward to use for common searching tasks. The following five
	functions show how to transform them into the standard lookups for sorted
	lists::

	def index(a, x):
	'Locate the leftmost value exactly equal to x'
	i = bisect_left(a, x)
	if i != len(a) and a[i] == x:
	return i
	raise ValueError

	def find_lt(a, x):
	'Find rightmost value less than x'
	i = bisect_left(a, x)
	if i:
	return a[i-1]
	raise ValueError

	def find_le(a, x):
	'Find rightmost value less than or equal to x'
	i = bisect_right(a, x)
	if i:
	return a[i-1]
	raise ValueError

	def find_gt(a, x):
	'Find leftmost value greater than x'
	i = bisect_right(a, x)
	if i != len(a):
	return a[i]
	raise ValueError

	def find_ge(a, x):
	'Find leftmost item greater than or equal to x'
	i = bisect_left(a, x)
	if i != len(a):
	return a[i]
	raise ValueError


	Other Examples
	--------------

	.. _bisect-example:

	The :func:`bisect` function can be useful for numeric table lookups. This
	example uses :func:`bisect` to look up a letter grade for an exam score (say)
	based on a set of ordered numeric breakpoints: 90 and up is an 'A', 80 to 89 is
	a 'B', and so on::

	>>> def grade(score, breakpoints=[60, 70, 80, 90], grades='FDCBA'):
	... i = bisect(breakpoints, score)
	... return grades[i]
	...
	>>> [grade(score) for score in [33, 99, 77, 70, 89, 90, 100]]
	['F', 'A', 'C', 'C', 'B', 'A', 'A']

	Unlike the :func:`sorted` function, it does not make sense for the :func:`bisect`
	functions to have key or reversed arguments because that would lead to an
	inefficient design (successive calls to bisect functions would not "remember"
	all of the previous key lookups).

	Instead, it is better to search a list of precomputed keys to find the index
	of the record in question::

	>>> data = [('red', 5), ('blue', 1), ('yellow', 8), ('black', 0)]
	>>> data.sort(key=lambda r: r[1])
	>>> keys = [r[1] for r in data] # precomputed list of keys
	>>> data[bisect_left(keys, 0)]
	('black', 0)
	>>> data[bisect_left(keys, 1)]
	('blue', 1)
	>>> data[bisect_left(keys, 5)]
	('red', 5)
	>>> data[bisect_left(keys, 8)]
	('yellow', 8)