Documentation/core-api/idr.rst - linux - Git at Google

 .. SPDX-License-Identifier: GPL-2.0+

 =============
 ID Allocation
 =============

 :Author: Matthew Wilcox

 Overview
 ========

 A common problem to solve is allocating identifiers (IDs); generally
 small numbers which identify a thing.  Examples include file descriptors,
 process IDs, packet identifiers in networking protocols, SCSI tags
 and device instance numbers.  The IDR and the IDA provide a reasonable
 solution to the problem to avoid everybody inventing their own.  The IDR
 provides the ability to map an ID to a pointer, while the IDA provides
 only ID allocation, and as a result is much more memory-efficient.

 The IDR interface is deprecated; please use the :doc:`XArray <xarray>`
 instead.

 IDR usage
 =========

 Start by initialising an IDR, either with DEFINE_IDR()
 for statically allocated IDRs or idr_init() for dynamically
 allocated IDRs.

 You can call idr_alloc() to allocate an unused ID.  Look up
 the pointer you associated with the ID by calling idr_find()
 and free the ID by calling idr_remove().

 If you need to change the pointer associated with an ID, you can call
 idr_replace().  One common reason to do this is to reserve an
 ID by passing a ``NULL`` pointer to the allocation function; initialise the
 object with the reserved ID and finally insert the initialised object
 into the IDR.

 Some users need to allocate IDs larger than ``INT_MAX``.  So far all of
 these users have been content with a ``UINT_MAX`` limit, and they use
 idr_alloc_u32().  If you need IDs that will not fit in a u32,
 we will work with you to address your needs.

 If you need to allocate IDs sequentially, you can use
 idr_alloc_cyclic().  The IDR becomes less efficient when dealing
 with larger IDs, so using this function comes at a slight cost.

 To perform an action on all pointers used by the IDR, you can
 either use the callback-based idr_for_each() or the
 iterator-style idr_for_each_entry().  You may need to use
 idr_for_each_entry_continue() to continue an iteration.  You can
 also use idr_get_next() if the iterator doesn't fit your needs.

 When you have finished using an IDR, you can call idr_destroy()
 to release the memory used by the IDR.  This will not free the objects
 pointed to from the IDR; if you want to do that, use one of the iterators
 to do it.

 You can use idr_is_empty() to find out whether there are any
 IDs currently allocated.

 If you need to take a lock while allocating a new ID from the IDR,
 you may need to pass a restrictive set of GFP flags, which can lead
 to the IDR being unable to allocate memory.  To work around this,
 you can call idr_preload() before taking the lock, and then
 idr_preload_end() after the allocation.

 .. kernel-doc:: include/linux/idr.h
    :doc: idr sync

 IDA usage
 =========

 .. kernel-doc:: lib/idr.c
    :doc: IDA description

 Functions and structures
 ========================

 .. kernel-doc:: include/linux/idr.h
    :functions:
 .. kernel-doc:: lib/idr.c
    :functions:
	.. SPDX-License-Identifier: GPL-2.0+

	=============
	ID Allocation
	=============

	:Author: Matthew Wilcox

	Overview
	========

	A common problem to solve is allocating identifiers (IDs); generally
	small numbers which identify a thing. Examples include file descriptors,
	process IDs, packet identifiers in networking protocols, SCSI tags
	and device instance numbers. The IDR and the IDA provide a reasonable
	solution to the problem to avoid everybody inventing their own. The IDR
	provides the ability to map an ID to a pointer, while the IDA provides
	only ID allocation, and as a result is much more memory-efficient.

	The IDR interface is deprecated; please use the :doc:`XArray <xarray>`
	instead.

	IDR usage
	=========

	Start by initialising an IDR, either with DEFINE_IDR()
	for statically allocated IDRs or idr_init() for dynamically
	allocated IDRs.

	You can call idr_alloc() to allocate an unused ID. Look up
	the pointer you associated with the ID by calling idr_find()
	and free the ID by calling idr_remove().

	If you need to change the pointer associated with an ID, you can call
	idr_replace(). One common reason to do this is to reserve an
	ID by passing a ``NULL`` pointer to the allocation function; initialise the
	object with the reserved ID and finally insert the initialised object
	into the IDR.

	Some users need to allocate IDs larger than ``INT_MAX``. So far all of
	these users have been content with a ``UINT_MAX`` limit, and they use
	idr_alloc_u32(). If you need IDs that will not fit in a u32,
	we will work with you to address your needs.

	If you need to allocate IDs sequentially, you can use
	idr_alloc_cyclic(). The IDR becomes less efficient when dealing
	with larger IDs, so using this function comes at a slight cost.

	To perform an action on all pointers used by the IDR, you can
	either use the callback-based idr_for_each() or the
	iterator-style idr_for_each_entry(). You may need to use
	idr_for_each_entry_continue() to continue an iteration. You can
	also use idr_get_next() if the iterator doesn't fit your needs.

	When you have finished using an IDR, you can call idr_destroy()
	to release the memory used by the IDR. This will not free the objects
	pointed to from the IDR; if you want to do that, use one of the iterators
	to do it.

	You can use idr_is_empty() to find out whether there are any
	IDs currently allocated.

	If you need to take a lock while allocating a new ID from the IDR,
	you may need to pass a restrictive set of GFP flags, which can lead
	to the IDR being unable to allocate memory. To work around this,
	you can call idr_preload() before taking the lock, and then
	idr_preload_end() after the allocation.

	.. kernel-doc:: include/linux/idr.h
	:doc: idr sync

	IDA usage
	=========

	.. kernel-doc:: lib/idr.c
	:doc: IDA description

	Functions and structures
	========================

	.. kernel-doc:: include/linux/idr.h
	:functions:
	.. kernel-doc:: lib/idr.c
	:functions: