[mirror_ubuntu-bionic-kernel.git] / Documentation / vm / idle_page_tracking.txt

MOTIVATION

The idle page tracking feature allows to track which memory pages are being
accessed by a workload and which are idle. This information can be useful for
estimating the workload's working set size, which, in turn, can be taken into
account when configuring the workload parameters, setting memory cgroup limits,
or deciding where to place the workload within a compute cluster.

It is enabled by CONFIG_IDLE_PAGE_TRACKING=y.

USER API

The idle page tracking API is located at /sys/kernel/mm/page_idle. Currently,
it consists of the only read-write file, /sys/kernel/mm/page_idle/bitmap.

The file implements a bitmap where each bit corresponds to a memory page. The
bitmap is represented by an array of 8-byte integers, and the page at PFN #i is
mapped to bit #i%64 of array element #i/64, byte order is native. When a bit is
set, the corresponding page is idle.

A page is considered idle if it has not been accessed since it was marked idle
(for more details on what "accessed" actually means see the IMPLEMENTATION
DETAILS section). To mark a page idle one has to set the bit corresponding to
the page by writing to the file. A value written to the file is OR-ed with the
current bitmap value.

Only accesses to user memory pages are tracked. These are pages mapped to a
process address space, page cache and buffer pages, swap cache pages. For other
page types (e.g. SLAB pages) an attempt to mark a page idle is silently ignored,
and hence such pages are never reported idle.

For huge pages the idle flag is set only on the head page, so one has to read
/proc/kpageflags in order to correctly count idle huge pages.

Reading from or writing to /sys/kernel/mm/page_idle/bitmap will return
-EINVAL if you are not starting the read/write on an 8-byte boundary, or
if the size of the read/write is not a multiple of 8 bytes. Writing to
this file beyond max PFN will return -ENXIO.

That said, in order to estimate the amount of pages that are not used by a
workload one should:

 1. Mark all the workload's pages as idle by setting corresponding bits in
    /sys/kernel/mm/page_idle/bitmap. The pages can be found by reading
    /proc/pid/pagemap if the workload is represented by a process, or by
    filtering out alien pages using /proc/kpagecgroup in case the workload is
    placed in a memory cgroup.

 2. Wait until the workload accesses its working set.

 3. Read /sys/kernel/mm/page_idle/bitmap and count the number of bits set. If
    one wants to ignore certain types of pages, e.g. mlocked pages since they
    are not reclaimable, he or she can filter them out using /proc/kpageflags.

See Documentation/vm/pagemap.txt for more information about /proc/pid/pagemap,
/proc/kpageflags, and /proc/kpagecgroup.

IMPLEMENTATION DETAILS

The kernel internally keeps track of accesses to user memory pages in order to
reclaim unreferenced pages first on memory shortage conditions. A page is
considered referenced if it has been recently accessed via a process address
space, in which case one or more PTEs it is mapped to will have the Accessed bit
set, or marked accessed explicitly by the kernel (see mark_page_accessed()). The
latter happens when:

 - a userspace process reads or writes a page using a system call (e.g. read(2)
   or write(2))

 - a page that is used for storing filesystem buffers is read or written,
   because a process needs filesystem metadata stored in it (e.g. lists a
   directory tree)

 - a page is accessed by a device driver using get_user_pages()

When a dirty page is written to swap or disk as a result of memory reclaim or
exceeding the dirty memory limit, it is not marked referenced.

The idle memory tracking feature adds a new page flag, the Idle flag. This flag
is set manually, by writing to /sys/kernel/mm/page_idle/bitmap (see the USER API
section), and cleared automatically whenever a page is referenced as defined
above.

When a page is marked idle, the Accessed bit must be cleared in all PTEs it is
mapped to, otherwise we will not be able to detect accesses to the page coming
from a process address space. To avoid interference with the reclaimer, which,
as noted above, uses the Accessed bit to promote actively referenced pages, one
more page flag is introduced, the Young flag. When the PTE Accessed bit is
cleared as a result of setting or updating a page's Idle flag, the Young flag
is set on the page. The reclaimer treats the Young flag as an extra PTE
Accessed bit and therefore will consider such a page as referenced.

Since the idle memory tracking feature is based on the memory reclaimer logic,
it only works with pages that are on an LRU list, other pages are silently
ignored. That means it will ignore a user memory page if it is isolated, but
since there are usually not many of them, it should not affect the overall
result noticeably. In order not to stall scanning of the idle page bitmap,
locked pages may be skipped too.
Commit	Line	Data
33c3fc71 VD	1	MOTIVATION
	2
	3	The idle page tracking feature allows to track which memory pages are being
	4	accessed by a workload and which are idle. This information can be useful for
	5	estimating the workload's working set size, which, in turn, can be taken into
	6	account when configuring the workload parameters, setting memory cgroup limits,
	7	or deciding where to place the workload within a compute cluster.
	8
	9	It is enabled by CONFIG_IDLE_PAGE_TRACKING=y.
	10
	11	USER API
	12
	13	The idle page tracking API is located at /sys/kernel/mm/page_idle. Currently,
	14	it consists of the only read-write file, /sys/kernel/mm/page_idle/bitmap.
	15
	16	The file implements a bitmap where each bit corresponds to a memory page. The
	17	bitmap is represented by an array of 8-byte integers, and the page at PFN #i is
	18	mapped to bit #i%64 of array element #i/64, byte order is native. When a bit is
	19	set, the corresponding page is idle.
	20
	21	A page is considered idle if it has not been accessed since it was marked idle
	22	(for more details on what "accessed" actually means see the IMPLEMENTATION
	23	DETAILS section). To mark a page idle one has to set the bit corresponding to
	24	the page by writing to the file. A value written to the file is OR-ed with the
	25	current bitmap value.
	26
	27	Only accesses to user memory pages are tracked. These are pages mapped to a
	28	process address space, page cache and buffer pages, swap cache pages. For other
	29	page types (e.g. SLAB pages) an attempt to mark a page idle is silently ignored,
	30	and hence such pages are never reported idle.
	31
	32	For huge pages the idle flag is set only on the head page, so one has to read
	33	/proc/kpageflags in order to correctly count idle huge pages.
	34
	35	Reading from or writing to /sys/kernel/mm/page_idle/bitmap will return
	36	-EINVAL if you are not starting the read/write on an 8-byte boundary, or
	37	if the size of the read/write is not a multiple of 8 bytes. Writing to
	38	this file beyond max PFN will return -ENXIO.
	39
	40	That said, in order to estimate the amount of pages that are not used by a
	41	workload one should:
	42
	43	1. Mark all the workload's pages as idle by setting corresponding bits in
	44	/sys/kernel/mm/page_idle/bitmap. The pages can be found by reading
	45	/proc/pid/pagemap if the workload is represented by a process, or by
	46	filtering out alien pages using /proc/kpagecgroup in case the workload is
	47	placed in a memory cgroup.
	48
	49	2. Wait until the workload accesses its working set.
	50
	51	3. Read /sys/kernel/mm/page_idle/bitmap and count the number of bits set. If
	52	one wants to ignore certain types of pages, e.g. mlocked pages since they
	53	are not reclaimable, he or she can filter them out using /proc/kpageflags.
	54
	55	See Documentation/vm/pagemap.txt for more information about /proc/pid/pagemap,
	56	/proc/kpageflags, and /proc/kpagecgroup.
	57
	58	IMPLEMENTATION DETAILS
	59
	60	The kernel internally keeps track of accesses to user memory pages in order to
	61	reclaim unreferenced pages first on memory shortage conditions. A page is
	62	considered referenced if it has been recently accessed via a process address
	63	space, in which case one or more PTEs it is mapped to will have the Accessed bit
	64	set, or marked accessed explicitly by the kernel (see mark_page_accessed()). The
65	latter happens when:
66
67	- a userspace process reads or writes a page using a system call (e.g. read(2)
68	or write(2))
69
70	- a page that is used for storing filesystem buffers is read or written,
71	because a process needs filesystem metadata stored in it (e.g. lists a
72	directory tree)
73
74	- a page is accessed by a device driver using get_user_pages()
75
76	When a dirty page is written to swap or disk as a result of memory reclaim or
77	exceeding the dirty memory limit, it is not marked referenced.
78
79	The idle memory tracking feature adds a new page flag, the Idle flag. This flag
80	is set manually, by writing to /sys/kernel/mm/page_idle/bitmap (see the USER API
81	section), and cleared automatically whenever a page is referenced as defined
82	above.
83
84	When a page is marked idle, the Accessed bit must be cleared in all PTEs it is
85	mapped to, otherwise we will not be able to detect accesses to the page coming
86	from a process address space. To avoid interference with the reclaimer, which,
87	as noted above, uses the Accessed bit to promote actively referenced pages, one
88	more page flag is introduced, the Young flag. When the PTE Accessed bit is
89	cleared as a result of setting or updating a page's Idle flag, the Young flag
90	is set on the page. The reclaimer treats the Young flag as an extra PTE
91	Accessed bit and therefore will consider such a page as referenced.
92
93	Since the idle memory tracking feature is based on the memory reclaimer logic,
94	it only works with pages that are on an LRU list, other pages are silently
95	ignored. That means it will ignore a user memory page if it is isolated, but
96	since there are usually not many of them, it should not affect the overall
97	result noticeably. In order not to stall scanning of the idle page bitmap,
98	locked pages may be skipped too.