提交 24844fd3 编写于 作者: J Jonathan Corbet

Merge branch 'mm-rst' into docs-next

Mike Rapoport says:

  These patches convert files in Documentation/vm to ReST format, add an
  initial index and link it to the top level documentation.

  There are no contents changes in the documentation, except few spelling
  fixes. The relatively large diffstat stems from the indentation and
  paragraph wrapping changes.

  I've tried to keep the formatting as consistent as possible, but I could
  miss some places that needed markup and add some markup where it was not
  necessary.

[jc: significant conflicts in vm/hmm.rst]
......@@ -90,4 +90,4 @@ Date: December 2009
Contact: Lee Schermerhorn <lee.schermerhorn@hp.com>
Description:
The node's huge page size control/query attributes.
See Documentation/vm/hugetlbpage.txt
\ No newline at end of file
See Documentation/vm/hugetlbpage.rst
\ No newline at end of file
......@@ -12,4 +12,4 @@ Description:
free_hugepages
surplus_hugepages
resv_hugepages
See Documentation/vm/hugetlbpage.txt for details.
See Documentation/vm/hugetlbpage.rst for details.
......@@ -40,7 +40,7 @@ Description: Kernel Samepage Merging daemon sysfs interface
sleep_millisecs: how many milliseconds ksm should sleep between
scans.
See Documentation/vm/ksm.txt for more information.
See Documentation/vm/ksm.rst for more information.
What: /sys/kernel/mm/ksm/merge_across_nodes
Date: January 2013
......
......@@ -37,7 +37,7 @@ Description:
The alloc_calls file is read-only and lists the kernel code
locations from which allocations for this cache were performed.
The alloc_calls file only contains information if debugging is
enabled for that cache (see Documentation/vm/slub.txt).
enabled for that cache (see Documentation/vm/slub.rst).
What: /sys/kernel/slab/cache/alloc_fastpath
Date: February 2008
......@@ -219,7 +219,7 @@ Contact: Pekka Enberg <penberg@cs.helsinki.fi>,
Description:
The free_calls file is read-only and lists the locations of
object frees if slab debugging is enabled (see
Documentation/vm/slub.txt).
Documentation/vm/slub.rst).
What: /sys/kernel/slab/cache/free_fastpath
Date: February 2008
......
......@@ -3915,7 +3915,7 @@
cache (risks via metadata attacks are mostly
unchanged). Debug options disable merging on their
own.
For more information see Documentation/vm/slub.txt.
For more information see Documentation/vm/slub.rst.
slab_max_order= [MM, SLAB]
Determines the maximum allowed order for slabs.
......@@ -3929,7 +3929,7 @@
slub_debug can create guard zones around objects and
may poison objects when not in use. Also tracks the
last alloc / free. For more information see
Documentation/vm/slub.txt.
Documentation/vm/slub.rst.
slub_memcg_sysfs= [MM, SLUB]
Determines whether to enable sysfs directories for
......@@ -3943,7 +3943,7 @@
Determines the maximum allowed order for slabs.
A high setting may cause OOMs due to memory
fragmentation. For more information see
Documentation/vm/slub.txt.
Documentation/vm/slub.rst.
slub_min_objects= [MM, SLUB]
The minimum number of objects per slab. SLUB will
......@@ -3952,12 +3952,12 @@
the number of objects indicated. The higher the number
of objects the smaller the overhead of tracking slabs
and the less frequently locks need to be acquired.
For more information see Documentation/vm/slub.txt.
For more information see Documentation/vm/slub.rst.
slub_min_order= [MM, SLUB]
Determines the minimum page order for slabs. Must be
lower than slub_max_order.
For more information see Documentation/vm/slub.txt.
For more information see Documentation/vm/slub.rst.
slub_nomerge [MM, SLUB]
Same with slab_nomerge. This is supported for legacy.
......@@ -4313,7 +4313,7 @@
Format: [always|madvise|never]
Can be used to control the default behavior of the system
with respect to transparent hugepages.
See Documentation/vm/transhuge.txt for more details.
See Documentation/vm/transhuge.rst for more details.
tsc= Disable clocksource stability checks for TSC.
Format: <string>
......
......@@ -120,7 +120,7 @@ A typical out of bounds access report looks like this::
The header of the report discribe what kind of bug happened and what kind of
access caused it. It's followed by the description of the accessed slub object
(see 'SLUB Debug output' section in Documentation/vm/slub.txt for details) and
(see 'SLUB Debug output' section in Documentation/vm/slub.rst for details) and
the description of the accessed memory page.
In the last section the report shows memory state around the accessed address.
......
......@@ -515,7 +515,7 @@ guarantees:
The /proc/PID/clear_refs is used to reset the PG_Referenced and ACCESSED/YOUNG
bits on both physical and virtual pages associated with a process, and the
soft-dirty bit on pte (see Documentation/vm/soft-dirty.txt for details).
soft-dirty bit on pte (see Documentation/vm/soft-dirty.rst for details).
To clear the bits for all the pages associated with the process
> echo 1 > /proc/PID/clear_refs
......@@ -536,7 +536,7 @@ Any other value written to /proc/PID/clear_refs will have no effect.
The /proc/pid/pagemap gives the PFN, which can be used to find the pageflags
using /proc/kpageflags and number of times a page is mapped using
/proc/kpagecount. For detailed explanation, see Documentation/vm/pagemap.txt.
/proc/kpagecount. For detailed explanation, see Documentation/vm/pagemap.rst.
The /proc/pid/numa_maps is an extension based on maps, showing the memory
locality and binding policy, as well as the memory usage (in pages) of
......
......@@ -105,7 +105,7 @@ policy for the file will revert to "default" policy.
NUMA memory allocation policies have optional flags that can be used in
conjunction with their modes. These optional flags can be specified
when tmpfs is mounted by appending them to the mode before the NodeList.
See Documentation/vm/numa_memory_policy.txt for a list of all available
See Documentation/vm/numa_memory_policy.rst for a list of all available
memory allocation policy mode flags and their effect on memory policy.
=static is equivalent to MPOL_F_STATIC_NODES
......
......@@ -45,7 +45,7 @@ the kernel interface as seen by application developers.
.. toctree::
:maxdepth: 2
userspace-api/index
userspace-api/index
Introduction to kernel development
......@@ -89,6 +89,7 @@ needed).
sound/index
crypto/index
filesystems/index
vm/index
Architecture-specific documentation
-----------------------------------
......
......@@ -515,7 +515,7 @@ nr_hugepages
Change the minimum size of the hugepage pool.
See Documentation/vm/hugetlbpage.txt
See Documentation/vm/hugetlbpage.rst
==============================================================
......@@ -524,7 +524,7 @@ nr_overcommit_hugepages
Change the maximum size of the hugepage pool. The maximum is
nr_hugepages + nr_overcommit_hugepages.
See Documentation/vm/hugetlbpage.txt
See Documentation/vm/hugetlbpage.rst
==============================================================
......@@ -667,7 +667,7 @@ and don't use much of it.
The default value is 0.
See Documentation/vm/overcommit-accounting and
See Documentation/vm/overcommit-accounting.rst and
mm/mmap.c::__vm_enough_memory() for more information.
==============================================================
......
00-INDEX
- this file.
active_mm.txt
active_mm.rst
- An explanation from Linus about tsk->active_mm vs tsk->mm.
balance
balance.rst
- various information on memory balancing.
cleancache.txt
cleancache.rst
- Intro to cleancache and page-granularity victim cache.
frontswap.txt
frontswap.rst
- Outline frontswap, part of the transcendent memory frontend.
highmem.txt
highmem.rst
- Outline of highmem and common issues.
hmm.txt
hmm.rst
- Documentation of heterogeneous memory management
hugetlbpage.txt
hugetlbpage.rst
- a brief summary of hugetlbpage support in the Linux kernel.
hugetlbfs_reserv.txt
hugetlbfs_reserv.rst
- A brief overview of hugetlbfs reservation design/implementation.
hwpoison.txt
hwpoison.rst
- explains what hwpoison is
idle_page_tracking.txt
idle_page_tracking.rst
- description of the idle page tracking feature.
ksm.txt
ksm.rst
- how to use the Kernel Samepage Merging feature.
mmu_notifier.txt
mmu_notifier.rst
- a note about clearing pte/pmd and mmu notifications
numa
numa.rst
- information about NUMA specific code in the Linux vm.
numa_memory_policy.txt
numa_memory_policy.rst
- documentation of concepts and APIs of the 2.6 memory policy support.
overcommit-accounting
overcommit-accounting.rst
- description of the Linux kernels overcommit handling modes.
page_frags
page_frags.rst
- description of page fragments allocator
page_migration
page_migration.rst
- description of page migration in NUMA systems.
pagemap.txt
pagemap.rst
- pagemap, from the userspace perspective
page_owner.txt
page_owner.rst
- tracking about who allocated each page
remap_file_pages.txt
remap_file_pages.rst
- a note about remap_file_pages() system call
slub.txt
slub.rst
- a short users guide for SLUB.
soft-dirty.txt
soft-dirty.rst
- short explanation for soft-dirty PTEs
split_page_table_lock
split_page_table_lock.rst
- Separate per-table lock to improve scalability of the old page_table_lock.
swap_numa.txt
swap_numa.rst
- automatic binding of swap device to numa node
transhuge.txt
transhuge.rst
- Transparent Hugepage Support, alternative way of using hugepages.
unevictable-lru.txt
unevictable-lru.rst
- Unevictable LRU infrastructure
userfaultfd.txt
userfaultfd.rst
- description of userfaultfd system call
z3fold.txt
- outline of z3fold allocator for storing compressed pages
zsmalloc.txt
zsmalloc.rst
- outline of zsmalloc allocator for storing compressed pages
zswap.txt
zswap.rst
- Intro to compressed cache for swap pages
.. _active_mm:
=========
Active MM
=========
::
List: linux-kernel
Subject: Re: active_mm
From: Linus Torvalds <torvalds () transmeta ! com>
Date: 1999-07-30 21:36:24
Cc'd to linux-kernel, because I don't write explanations all that often,
and when I do I feel better about more people reading them.
On Fri, 30 Jul 1999, David Mosberger wrote:
>
> Is there a brief description someplace on how "mm" vs. "active_mm" in
> the task_struct are supposed to be used? (My apologies if this was
> discussed on the mailing lists---I just returned from vacation and
> wasn't able to follow linux-kernel for a while).
Basically, the new setup is:
- we have "real address spaces" and "anonymous address spaces". The
difference is that an anonymous address space doesn't care about the
user-level page tables at all, so when we do a context switch into an
anonymous address space we just leave the previous address space
active.
The obvious use for a "anonymous address space" is any thread that
doesn't need any user mappings - all kernel threads basically fall into
this category, but even "real" threads can temporarily say that for
some amount of time they are not going to be interested in user space,
and that the scheduler might as well try to avoid wasting time on
switching the VM state around. Currently only the old-style bdflush
sync does that.
- "tsk->mm" points to the "real address space". For an anonymous process,
tsk->mm will be NULL, for the logical reason that an anonymous process
really doesn't _have_ a real address space at all.
- however, we obviously need to keep track of which address space we
"stole" for such an anonymous user. For that, we have "tsk->active_mm",
which shows what the currently active address space is.
The rule is that for a process with a real address space (ie tsk->mm is
non-NULL) the active_mm obviously always has to be the same as the real
one.
For a anonymous process, tsk->mm == NULL, and tsk->active_mm is the
"borrowed" mm while the anonymous process is running. When the
anonymous process gets scheduled away, the borrowed address space is
returned and cleared.
To support all that, the "struct mm_struct" now has two counters: a
"mm_users" counter that is how many "real address space users" there are,
and a "mm_count" counter that is the number of "lazy" users (ie anonymous
users) plus one if there are any real users.
Usually there is at least one real user, but it could be that the real
user exited on another CPU while a lazy user was still active, so you do
actually get cases where you have a address space that is _only_ used by
lazy users. That is often a short-lived state, because once that thread
gets scheduled away in favour of a real thread, the "zombie" mm gets
released because "mm_users" becomes zero.
Also, a new rule is that _nobody_ ever has "init_mm" as a real MM any
more. "init_mm" should be considered just a "lazy context when no other
context is available", and in fact it is mainly used just at bootup when
no real VM has yet been created. So code that used to check
if (current->mm == &init_mm)
should generally just do
if (!current->mm)
instead (which makes more sense anyway - the test is basically one of "do
we have a user context", and is generally done by the page fault handler
and things like that).
Anyway, I put a pre-patch-2.3.13-1 on ftp.kernel.org just a moment ago,
because it slightly changes the interfaces to accommodate the alpha (who
would have thought it, but the alpha actually ends up having one of the
ugliest context switch codes - unlike the other architectures where the MM
and register state is separate, the alpha PALcode joins the two, and you
need to switch both together).
(From http://marc.info/?l=linux-kernel&m=93337278602211&w=2)
List: linux-kernel
Subject: Re: active_mm
From: Linus Torvalds <torvalds () transmeta ! com>
Date: 1999-07-30 21:36:24
Cc'd to linux-kernel, because I don't write explanations all that often,
and when I do I feel better about more people reading them.
On Fri, 30 Jul 1999, David Mosberger wrote:
>
> Is there a brief description someplace on how "mm" vs. "active_mm" in
> the task_struct are supposed to be used? (My apologies if this was
> discussed on the mailing lists---I just returned from vacation and
> wasn't able to follow linux-kernel for a while).
Basically, the new setup is:
- we have "real address spaces" and "anonymous address spaces". The
difference is that an anonymous address space doesn't care about the
user-level page tables at all, so when we do a context switch into an
anonymous address space we just leave the previous address space
active.
The obvious use for a "anonymous address space" is any thread that
doesn't need any user mappings - all kernel threads basically fall into
this category, but even "real" threads can temporarily say that for
some amount of time they are not going to be interested in user space,
and that the scheduler might as well try to avoid wasting time on
switching the VM state around. Currently only the old-style bdflush
sync does that.
- "tsk->mm" points to the "real address space". For an anonymous process,
tsk->mm will be NULL, for the logical reason that an anonymous process
really doesn't _have_ a real address space at all.
- however, we obviously need to keep track of which address space we
"stole" for such an anonymous user. For that, we have "tsk->active_mm",
which shows what the currently active address space is.
The rule is that for a process with a real address space (ie tsk->mm is
non-NULL) the active_mm obviously always has to be the same as the real
one.
For a anonymous process, tsk->mm == NULL, and tsk->active_mm is the
"borrowed" mm while the anonymous process is running. When the
anonymous process gets scheduled away, the borrowed address space is
returned and cleared.
To support all that, the "struct mm_struct" now has two counters: a
"mm_users" counter that is how many "real address space users" there are,
and a "mm_count" counter that is the number of "lazy" users (ie anonymous
users) plus one if there are any real users.
Usually there is at least one real user, but it could be that the real
user exited on another CPU while a lazy user was still active, so you do
actually get cases where you have a address space that is _only_ used by
lazy users. That is often a short-lived state, because once that thread
gets scheduled away in favour of a real thread, the "zombie" mm gets
released because "mm_users" becomes zero.
Also, a new rule is that _nobody_ ever has "init_mm" as a real MM any
more. "init_mm" should be considered just a "lazy context when no other
context is available", and in fact it is mainly used just at bootup when
no real VM has yet been created. So code that used to check
if (current->mm == &init_mm)
should generally just do
if (!current->mm)
instead (which makes more sense anyway - the test is basically one of "do
we have a user context", and is generally done by the page fault handler
and things like that).
Anyway, I put a pre-patch-2.3.13-1 on ftp.kernel.org just a moment ago,
because it slightly changes the interfaces to accommodate the alpha (who
would have thought it, but the alpha actually ends up having one of the
ugliest context switch codes - unlike the other architectures where the MM
and register state is separate, the alpha PALcode joins the two, and you
need to switch both together).
(From http://marc.info/?l=linux-kernel&m=93337278602211&w=2)
.. _balance:
================
Memory Balancing
================
Started Jan 2000 by Kanoj Sarcar <kanoj@sgi.com>
Memory balancing is needed for !__GFP_ATOMIC and !__GFP_KSWAPD_RECLAIM as
......@@ -62,11 +68,11 @@ for non-sleepable allocations. Second, the HIGHMEM zone is also balanced,
so as to give a fighting chance for replace_with_highmem() to get a
HIGHMEM page, as well as to ensure that HIGHMEM allocations do not
fall back into regular zone. This also makes sure that HIGHMEM pages
are not leaked (for example, in situations where a HIGHMEM page is in
are not leaked (for example, in situations where a HIGHMEM page is in
the swapcache but is not being used by anyone)
kswapd also needs to know about the zones it should balance. kswapd is
primarily needed in a situation where balancing can not be done,
primarily needed in a situation where balancing can not be done,
probably because all allocation requests are coming from intr context
and all process contexts are sleeping. For 2.3, kswapd does not really
need to balance the highmem zone, since intr context does not request
......@@ -89,7 +95,8 @@ pages is below watermark[WMARK_LOW]; in which case zone_wake_kswapd is also set.
(Good) Ideas that I have heard:
1. Dynamic experience should influence balancing: number of failed requests
for a zone can be tracked and fed into the balancing scheme (jalvo@mbay.net)
for a zone can be tracked and fed into the balancing scheme (jalvo@mbay.net)
2. Implement a replace_with_highmem()-like replace_with_regular() to preserve
dma pages. (lkd@tantalophile.demon.co.uk)
dma pages. (lkd@tantalophile.demon.co.uk)
MOTIVATION
.. _cleancache:
==========
Cleancache
==========
Motivation
==========
Cleancache is a new optional feature provided by the VFS layer that
potentially dramatically increases page cache effectiveness for
......@@ -21,9 +28,10 @@ Transcendent memory "drivers" for cleancache are currently implemented
in Xen (using hypervisor memory) and zcache (using in-kernel compressed
memory) and other implementations are in development.
FAQs are included below.
:ref:`FAQs <faq>` are included below.
IMPLEMENTATION OVERVIEW
Implementation Overview
=======================
A cleancache "backend" that provides transcendent memory registers itself
to the kernel's cleancache "frontend" by calling cleancache_register_ops,
......@@ -80,22 +88,33 @@ different Linux threads are simultaneously putting and invalidating a page
with the same handle, the results are indeterminate. Callers must
lock the page to ensure serial behavior.
CLEANCACHE PERFORMANCE METRICS
Cleancache Performance Metrics
==============================
If properly configured, monitoring of cleancache is done via debugfs in
the /sys/kernel/debug/cleancache directory. The effectiveness of cleancache
the `/sys/kernel/debug/cleancache` directory. The effectiveness of cleancache
can be measured (across all filesystems) with:
succ_gets - number of gets that were successful
failed_gets - number of gets that failed
puts - number of puts attempted (all "succeed")
invalidates - number of invalidates attempted
``succ_gets``
number of gets that were successful
``failed_gets``
number of gets that failed
``puts``
number of puts attempted (all "succeed")
``invalidates``
number of invalidates attempted
A backend implementation may provide additional metrics.
.. _faq:
FAQ
===
1) Where's the value? (Andrew Morton)
* Where's the value? (Andrew Morton)
Cleancache provides a significant performance benefit to many workloads
in many environments with negligible overhead by improving the
......@@ -137,8 +156,8 @@ device that stores pages of data in a compressed state. And
the proposed "RAMster" driver shares RAM across multiple physical
systems.
2) Why does cleancache have its sticky fingers so deep inside the
filesystems and VFS? (Andrew Morton and Christoph Hellwig)
* Why does cleancache have its sticky fingers so deep inside the
filesystems and VFS? (Andrew Morton and Christoph Hellwig)
The core hooks for cleancache in VFS are in most cases a single line
and the minimum set are placed precisely where needed to maintain
......@@ -168,9 +187,9 @@ filesystems in the future.
The total impact of the hooks to existing fs and mm files is only
about 40 lines added (not counting comments and blank lines).
3) Why not make cleancache asynchronous and batched so it can
more easily interface with real devices with DMA instead
of copying each individual page? (Minchan Kim)
* Why not make cleancache asynchronous and batched so it can more
easily interface with real devices with DMA instead of copying each
individual page? (Minchan Kim)
The one-page-at-a-time copy semantics simplifies the implementation
on both the frontend and backend and also allows the backend to
......@@ -182,8 +201,8 @@ are avoided. While the interface seems odd for a "real device"
or for real kernel-addressable RAM, it makes perfect sense for
transcendent memory.
4) Why is non-shared cleancache "exclusive"? And where is the
page "invalidated" after a "get"? (Minchan Kim)
* Why is non-shared cleancache "exclusive"? And where is the
page "invalidated" after a "get"? (Minchan Kim)
The main reason is to free up space in transcendent memory and
to avoid unnecessary cleancache_invalidate calls. If you want inclusive,
......@@ -193,7 +212,7 @@ be easily extended to add a "get_no_invalidate" call.
The invalidate is done by the cleancache backend implementation.
5) What's the performance impact?
* What's the performance impact?
Performance analysis has been presented at OLS'09 and LCA'10.
Briefly, performance gains can be significant on most workloads,
......@@ -206,7 +225,7 @@ single-core systems with slow memory-copy speeds, cleancache
has little value, but in newer multicore machines, especially
consolidated/virtualized machines, it has great value.
6) How do I add cleancache support for filesystem X? (Boaz Harrash)
* How do I add cleancache support for filesystem X? (Boaz Harrash)
Filesystems that are well-behaved and conform to certain
restrictions can utilize cleancache simply by making a call to
......@@ -217,26 +236,26 @@ not enable the optional cleancache.
Some points for a filesystem to consider:
- The FS should be block-device-based (e.g. a ram-based FS such
as tmpfs should not enable cleancache)
- To ensure coherency/correctness, the FS must ensure that all
file removal or truncation operations either go through VFS or
add hooks to do the equivalent cleancache "invalidate" operations
- To ensure coherency/correctness, either inode numbers must
be unique across the lifetime of the on-disk file OR the
FS must provide an "encode_fh" function.
- The FS must call the VFS superblock alloc and deactivate routines
or add hooks to do the equivalent cleancache calls done there.
- To maximize performance, all pages fetched from the FS should
go through the do_mpag_readpage routine or the FS should add
hooks to do the equivalent (cf. btrfs)
- Currently, the FS blocksize must be the same as PAGESIZE. This
is not an architectural restriction, but no backends currently
support anything different.
- A clustered FS should invoke the "shared_init_fs" cleancache
hook to get best performance for some backends.
7) Why not use the KVA of the inode as the key? (Christoph Hellwig)
- The FS should be block-device-based (e.g. a ram-based FS such
as tmpfs should not enable cleancache)
- To ensure coherency/correctness, the FS must ensure that all
file removal or truncation operations either go through VFS or
add hooks to do the equivalent cleancache "invalidate" operations
- To ensure coherency/correctness, either inode numbers must
be unique across the lifetime of the on-disk file OR the
FS must provide an "encode_fh" function.
- The FS must call the VFS superblock alloc and deactivate routines
or add hooks to do the equivalent cleancache calls done there.
- To maximize performance, all pages fetched from the FS should
go through the do_mpag_readpage routine or the FS should add
hooks to do the equivalent (cf. btrfs)
- Currently, the FS blocksize must be the same as PAGESIZE. This
is not an architectural restriction, but no backends currently
support anything different.
- A clustered FS should invoke the "shared_init_fs" cleancache
hook to get best performance for some backends.
* Why not use the KVA of the inode as the key? (Christoph Hellwig)
If cleancache would use the inode virtual address instead of
inode/filehandle, the pool id could be eliminated. But, this
......@@ -251,7 +270,7 @@ of cleancache would be lost because the cache of pages in cleanache
is potentially much larger than the kernel pagecache and is most
useful if the pages survive inode cache removal.
8) Why is a global variable required?
* Why is a global variable required?
The cleancache_enabled flag is checked in all of the frequently-used
cleancache hooks. The alternative is a function call to check a static
......@@ -262,14 +281,14 @@ global variable allows cleancache to be enabled by default at compile
time, but have insignificant performance impact when cleancache remains
disabled at runtime.
9) Does cleanache work with KVM?
* Does cleanache work with KVM?
The memory model of KVM is sufficiently different that a cleancache
backend may have less value for KVM. This remains to be tested,
especially in an overcommitted system.
10) Does cleancache work in userspace? It sounds useful for
memory hungry caches like web browsers. (Jamie Lokier)
* Does cleancache work in userspace? It sounds useful for
memory hungry caches like web browsers. (Jamie Lokier)
No plans yet, though we agree it sounds useful, at least for
apps that bypass the page cache (e.g. O_DIRECT).
......
# -*- coding: utf-8; mode: python -*-
project = "Linux Memory Management Documentation"
tags.add("subproject")
latex_documents = [
('index', 'memory-management.tex', project,
'The kernel development community', 'manual'),
]
.. _frontswap:
=========
Frontswap
=========
Frontswap provides a "transcendent memory" interface for swap pages.
In some environments, dramatic performance savings may be obtained because
swapped pages are saved in RAM (or a RAM-like device) instead of a swap disk.
(Note, frontswap -- and cleancache (merged at 3.0) -- are the "frontends"
(Note, frontswap -- and :ref:`cleancache` (merged at 3.0) -- are the "frontends"
and the only necessary changes to the core kernel for transcendent memory;
all other supporting code -- the "backends" -- is implemented as drivers.
See the LWN.net article "Transcendent memory in a nutshell" for a detailed
overview of frontswap and related kernel parts:
https://lwn.net/Articles/454795/ )
See the LWN.net article `Transcendent memory in a nutshell`_
for a detailed overview of frontswap and related kernel parts)
.. _Transcendent memory in a nutshell: https://lwn.net/Articles/454795/
Frontswap is so named because it can be thought of as the opposite of
a "backing" store for a swap device. The storage is assumed to be
......@@ -50,19 +57,27 @@ or the store fails AND the page is invalidated. This ensures stale data may
never be obtained from frontswap.
If properly configured, monitoring of frontswap is done via debugfs in
the /sys/kernel/debug/frontswap directory. The effectiveness of
the `/sys/kernel/debug/frontswap` directory. The effectiveness of
frontswap can be measured (across all swap devices) with:
failed_stores - how many store attempts have failed
loads - how many loads were attempted (all should succeed)
succ_stores - how many store attempts have succeeded
invalidates - how many invalidates were attempted
``failed_stores``
how many store attempts have failed
``loads``
how many loads were attempted (all should succeed)
``succ_stores``
how many store attempts have succeeded
``invalidates``
how many invalidates were attempted
A backend implementation may provide additional metrics.
FAQ
===
1) Where's the value?
* Where's the value?
When a workload starts swapping, performance falls through the floor.
Frontswap significantly increases performance in many such workloads by
......@@ -117,8 +132,8 @@ A KVM implementation is underway and has been RFC'ed to lkml. And,
using frontswap, investigation is also underway on the use of NVM as
a memory extension technology.
2) Sure there may be performance advantages in some situations, but
what's the space/time overhead of frontswap?
* Sure there may be performance advantages in some situations, but
what's the space/time overhead of frontswap?
If CONFIG_FRONTSWAP is disabled, every frontswap hook compiles into
nothingness and the only overhead is a few extra bytes per swapon'ed
......@@ -148,8 +163,8 @@ pressure that can potentially outweigh the other advantages. A
backend, such as zcache, must implement policies to carefully (but
dynamically) manage memory limits to ensure this doesn't happen.
3) OK, how about a quick overview of what this frontswap patch does
in terms that a kernel hacker can grok?
* OK, how about a quick overview of what this frontswap patch does
in terms that a kernel hacker can grok?
Let's assume that a frontswap "backend" has registered during
kernel initialization; this registration indicates that this
......@@ -188,9 +203,9 @@ and (potentially) a swap device write are replaced by a "frontswap backend
store" and (possibly) a "frontswap backend loads", which are presumably much
faster.
4) Can't frontswap be configured as a "special" swap device that is
just higher priority than any real swap device (e.g. like zswap,
or maybe swap-over-nbd/NFS)?
* Can't frontswap be configured as a "special" swap device that is
just higher priority than any real swap device (e.g. like zswap,
or maybe swap-over-nbd/NFS)?
No. First, the existing swap subsystem doesn't allow for any kind of
swap hierarchy. Perhaps it could be rewritten to accommodate a hierarchy,
......@@ -240,9 +255,9 @@ installation, frontswap is useless. Swapless portable devices
can still use frontswap but a backend for such devices must configure
some kind of "ghost" swap device and ensure that it is never used.
5) Why this weird definition about "duplicate stores"? If a page
has been previously successfully stored, can't it always be
successfully overwritten?
* Why this weird definition about "duplicate stores"? If a page
has been previously successfully stored, can't it always be
successfully overwritten?
Nearly always it can, but no, sometimes it cannot. Consider an example
where data is compressed and the original 4K page has been compressed
......@@ -254,7 +269,7 @@ the old data and ensure that it is no longer accessible. Since the
swap subsystem then writes the new data to the read swap device,
this is the correct course of action to ensure coherency.
6) What is frontswap_shrink for?
* What is frontswap_shrink for?
When the (non-frontswap) swap subsystem swaps out a page to a real
swap device, that page is only taking up low-value pre-allocated disk
......@@ -267,7 +282,7 @@ to "repatriate" pages sent to a remote machine back to the local machine;
this is driven using the frontswap_shrink mechanism when memory pressure
subsides.
7) Why does the frontswap patch create the new include file swapfile.h?
* Why does the frontswap patch create the new include file swapfile.h?
The frontswap code depends on some swap-subsystem-internal data
structures that have, over the years, moved back and forth between
......
.. _highmem:
====================
HIGH MEMORY HANDLING
====================
====================
High Memory Handling
====================
By: Peter Zijlstra <a.p.zijlstra@chello.nl>
Contents:
(*) What is high memory?
(*) Temporary virtual mappings.
(*) Using kmap_atomic.
(*) Cost of temporary mappings.
(*) i386 PAE.
.. contents:: :local:
====================
WHAT IS HIGH MEMORY?
What Is High Memory?
====================
High memory (highmem) is used when the size of physical memory approaches or
......@@ -38,7 +27,7 @@ kernel entry/exit. This means the available virtual memory space (4GiB on
i386) has to be divided between user and kernel space.
The traditional split for architectures using this approach is 3:1, 3GiB for
userspace and the top 1GiB for kernel space:
userspace and the top 1GiB for kernel space::
+--------+ 0xffffffff
| Kernel |
......@@ -58,40 +47,38 @@ and user maps. Some hardware (like some ARMs), however, have limited virtual
space when they use mm context tags.
==========================
TEMPORARY VIRTUAL MAPPINGS
Temporary Virtual Mappings
==========================
The kernel contains several ways of creating temporary mappings:
(*) vmap(). This can be used to make a long duration mapping of multiple
physical pages into a contiguous virtual space. It needs global
synchronization to unmap.
* vmap(). This can be used to make a long duration mapping of multiple
physical pages into a contiguous virtual space. It needs global
synchronization to unmap.
(*) kmap(). This permits a short duration mapping of a single page. It needs
global synchronization, but is amortized somewhat. It is also prone to
deadlocks when using in a nested fashion, and so it is not recommended for
new code.
* kmap(). This permits a short duration mapping of a single page. It needs
global synchronization, but is amortized somewhat. It is also prone to
deadlocks when using in a nested fashion, and so it is not recommended for
new code.
(*) kmap_atomic(). This permits a very short duration mapping of a single
page. Since the mapping is restricted to the CPU that issued it, it
performs well, but the issuing task is therefore required to stay on that
CPU until it has finished, lest some other task displace its mappings.
* kmap_atomic(). This permits a very short duration mapping of a single
page. Since the mapping is restricted to the CPU that issued it, it
performs well, but the issuing task is therefore required to stay on that
CPU until it has finished, lest some other task displace its mappings.
kmap_atomic() may also be used by interrupt contexts, since it is does not
sleep and the caller may not sleep until after kunmap_atomic() is called.
kmap_atomic() may also be used by interrupt contexts, since it is does not
sleep and the caller may not sleep until after kunmap_atomic() is called.
It may be assumed that k[un]map_atomic() won't fail.
It may be assumed that k[un]map_atomic() won't fail.
=================
USING KMAP_ATOMIC
Using kmap_atomic
=================
When and where to use kmap_atomic() is straightforward. It is used when code
wants to access the contents of a page that might be allocated from high memory
(see __GFP_HIGHMEM), for example a page in the pagecache. The API has two
functions, and they can be used in a manner similar to the following:
functions, and they can be used in a manner similar to the following::
/* Find the page of interest. */
struct page *page = find_get_page(mapping, offset);
......@@ -109,7 +96,7 @@ Note that the kunmap_atomic() call takes the result of the kmap_atomic() call
not the argument.
If you need to map two pages because you want to copy from one page to
another you need to keep the kmap_atomic calls strictly nested, like:
another you need to keep the kmap_atomic calls strictly nested, like::
vaddr1 = kmap_atomic(page1);
vaddr2 = kmap_atomic(page2);
......@@ -120,8 +107,7 @@ another you need to keep the kmap_atomic calls strictly nested, like:
kunmap_atomic(vaddr1);
==========================
COST OF TEMPORARY MAPPINGS
Cost of Temporary Mappings
==========================
The cost of creating temporary mappings can be quite high. The arch has to
......@@ -136,25 +122,24 @@ If CONFIG_MMU is not set, then there can be no temporary mappings and no
highmem. In such a case, the arithmetic approach will also be used.
========
i386 PAE
========
The i386 arch, under some circumstances, will permit you to stick up to 64GiB
of RAM into your 32-bit machine. This has a number of consequences:
(*) Linux needs a page-frame structure for each page in the system and the
pageframes need to live in the permanent mapping, which means:
* Linux needs a page-frame structure for each page in the system and the
pageframes need to live in the permanent mapping, which means:
(*) you can have 896M/sizeof(struct page) page-frames at most; with struct
page being 32-bytes that would end up being something in the order of 112G
worth of pages; the kernel, however, needs to store more than just
page-frames in that memory...
* you can have 896M/sizeof(struct page) page-frames at most; with struct
page being 32-bytes that would end up being something in the order of 112G
worth of pages; the kernel, however, needs to store more than just
page-frames in that memory...
(*) PAE makes your page tables larger - which slows the system down as more
data has to be accessed to traverse in TLB fills and the like. One
advantage is that PAE has more PTE bits and can provide advanced features
like NX and PAT.
* PAE makes your page tables larger - which slows the system down as more
data has to be accessed to traverse in TLB fills and the like. One
advantage is that PAE has more PTE bits and can provide advanced features
like NX and PAT.
The general recommendation is that you don't use more than 8GiB on a 32-bit
machine - although more might work for you and your workload, you're pretty
......
.. hmm:
=====================================
Heterogeneous Memory Management (HMM)
=====================================
Provide infrastructure and helpers to integrate non-conventional memory (device
memory like GPU on board memory) into regular kernel path, with the cornerstone
......@@ -6,10 +10,10 @@ of this being specialized struct page for such memory (see sections 5 to 7 of
this document).
HMM also provides optional helpers for SVM (Share Virtual Memory), i.e.,
allowing a device to transparently access program address coherently with the
CPU meaning that any valid pointer on the CPU is also a valid pointer for the
device. This is becoming mandatory to simplify the use of advanced hetero-
geneous computing where GPU, DSP, or FPGA are used to perform various
allowing a device to transparently access program address coherently with
the CPU meaning that any valid pointer on the CPU is also a valid pointer
for the device. This is becoming mandatory to simplify the use of advanced
heterogeneous computing where GPU, DSP, or FPGA are used to perform various
computations on behalf of a process.
This document is divided as follows: in the first section I expose the problems
......@@ -21,19 +25,10 @@ fifth section deals with how device memory is represented inside the kernel.
Finally, the last section presents a new migration helper that allows lever-
aging the device DMA engine.
.. contents:: :local:
1) Problems of using a device specific memory allocator:
2) I/O bus, device memory characteristics
3) Shared address space and migration
4) Address space mirroring implementation and API
5) Represent and manage device memory from core kernel point of view
6) Migration to and from device memory
7) Memory cgroup (memcg) and rss accounting
-------------------------------------------------------------------------------
1) Problems of using a device specific memory allocator:
Problems of using a device specific memory allocator
====================================================
Devices with a large amount of on board memory (several gigabytes) like GPUs
have historically managed their memory through dedicated driver specific APIs.
......@@ -77,9 +72,8 @@ are only do-able with a shared address space. It is also more reasonable to use
a shared address space for all other patterns.
-------------------------------------------------------------------------------
2) I/O bus, device memory characteristics
I/O bus, device memory characteristics
======================================
I/O buses cripple shared address spaces due to a few limitations. Most I/O
buses only allow basic memory access from device to main memory; even cache
......@@ -109,9 +103,8 @@ access any memory but we must also permit any memory to be migrated to device
memory while device is using it (blocking CPU access while it happens).
-------------------------------------------------------------------------------
3) Shared address space and migration
Shared address space and migration
==================================
HMM intends to provide two main features. First one is to share the address
space by duplicating the CPU page table in the device page table so the same
......@@ -148,23 +141,23 @@ ages device memory by migrating the part of the data set that is actively being
used by the device.
-------------------------------------------------------------------------------
4) Address space mirroring implementation and API
Address space mirroring implementation and API
==============================================
Address space mirroring's main objective is to allow duplication of a range of
CPU page table into a device page table; HMM helps keep both synchronized. A
device driver that wants to mirror a process address space must start with the
registration of an hmm_mirror struct:
registration of an hmm_mirror struct::
int hmm_mirror_register(struct hmm_mirror *mirror,
struct mm_struct *mm);
int hmm_mirror_register_locked(struct hmm_mirror *mirror,
struct mm_struct *mm);
The locked variant is to be used when the driver is already holding mmap_sem
of the mm in write mode. The mirror struct has a set of callbacks that are used
to propagate CPU page tables:
to propagate CPU page tables::
struct hmm_mirror_ops {
/* sync_cpu_device_pagetables() - synchronize page tables
......@@ -193,10 +186,10 @@ The device driver must perform the update action to the range (mark range
read only, or fully unmap, ...). The device must be done with the update before
the driver callback returns.
When the device driver wants to populate a range of virtual addresses, it can
use either:
int hmm_vma_get_pfns(struct vm_area_struct *vma,
use either::
int hmm_vma_get_pfns(struct vm_area_struct *vma,
struct hmm_range *range,
unsigned long start,
unsigned long end,
......@@ -221,7 +214,7 @@ provides a set of flags to help the driver identify special CPU page table
entries.
Locking with the update() callback is the most important aspect the driver must
respect in order to keep things properly synchronized. The usage pattern is:
respect in order to keep things properly synchronized. The usage pattern is::
int driver_populate_range(...)
{
......@@ -262,9 +255,8 @@ report commands as executed is serialized (there is no point in doing this
concurrently).
-------------------------------------------------------------------------------
5) Represent and manage device memory from core kernel point of view
Represent and manage device memory from core kernel point of view
=================================================================
Several different designs were tried to support device memory. First one used
a device specific data structure to keep information about migrated memory and
......@@ -280,14 +272,14 @@ unaware of the difference. We only need to make sure that no one ever tries to
map those pages from the CPU side.
HMM provides a set of helpers to register and hotplug device memory as a new
region needing a struct page. This is offered through a very simple API:
region needing a struct page. This is offered through a very simple API::
struct hmm_devmem *hmm_devmem_add(const struct hmm_devmem_ops *ops,
struct device *device,
unsigned long size);
void hmm_devmem_remove(struct hmm_devmem *devmem);
The hmm_devmem_ops is where most of the important things are:
The hmm_devmem_ops is where most of the important things are::
struct hmm_devmem_ops {
void (*free)(struct hmm_devmem *devmem, struct page *page);
......@@ -306,13 +298,12 @@ which it cannot do. This second callback must trigger a migration back to
system memory.
-------------------------------------------------------------------------------
6) Migration to and from device memory
Migration to and from device memory
===================================
Because the CPU cannot access device memory, migration must use the device DMA
engine to perform copy from and to device memory. For this we need a new
migration helper:
migration helper::
int migrate_vma(const struct migrate_vma_ops *ops,
struct vm_area_struct *vma,
......@@ -331,7 +322,7 @@ migration might be for a range of addresses the device is actively accessing.
The migrate_vma_ops struct defines two callbacks. First one (alloc_and_copy())
controls destination memory allocation and copy operation. Second one is there
to allow the device driver to perform cleanup operations after migration.
to allow the device driver to perform cleanup operations after migration::
struct migrate_vma_ops {
void (*alloc_and_copy)(struct vm_area_struct *vma,
......@@ -365,9 +356,8 @@ bandwidth but this is considered as a rare event and a price that we are
willing to pay to keep all the code simpler.
-------------------------------------------------------------------------------
7) Memory cgroup (memcg) and rss accounting
Memory cgroup (memcg) and rss accounting
========================================
For now device memory is accounted as any regular page in rss counters (either
anonymous if device page is used for anonymous, file if device page is used for
......
Hugetlbfs Reservation Overview
------------------------------
Huge pages as described at 'Documentation/vm/hugetlbpage.txt' are typically
.. _hugetlbfs_reserve:
=====================
Hugetlbfs Reservation
=====================
Overview
========
Huge pages as described at :ref:`hugetlbpage` are typically
preallocated for application use. These huge pages are instantiated in a
task's address space at page fault time if the VMA indicates huge pages are
to be used. If no huge page exists at page fault time, the task is sent
......@@ -17,47 +24,55 @@ describe how huge page reserve processing is done in the v4.10 kernel.
Audience
--------
========
This description is primarily targeted at kernel developers who are modifying
hugetlbfs code.
The Data Structures
-------------------
===================
resv_huge_pages
This is a global (per-hstate) count of reserved huge pages. Reserved
huge pages are only available to the task which reserved them.
Therefore, the number of huge pages generally available is computed
as (free_huge_pages - resv_huge_pages).
as (``free_huge_pages - resv_huge_pages``).
Reserve Map
A reserve map is described by the structure:
struct resv_map {
struct kref refs;
spinlock_t lock;
struct list_head regions;
long adds_in_progress;
struct list_head region_cache;
long region_cache_count;
};
A reserve map is described by the structure::
struct resv_map {
struct kref refs;
spinlock_t lock;
struct list_head regions;
long adds_in_progress;
struct list_head region_cache;
long region_cache_count;
};
There is one reserve map for each huge page mapping in the system.
The regions list within the resv_map describes the regions within
the mapping. A region is described as:
struct file_region {
struct list_head link;
long from;
long to;
};
the mapping. A region is described as::
struct file_region {
struct list_head link;
long from;
long to;
};
The 'from' and 'to' fields of the file region structure are huge page
indices into the mapping. Depending on the type of mapping, a
region in the reserv_map may indicate reservations exist for the
range, or reservations do not exist.
Flags for MAP_PRIVATE Reservations
These are stored in the bottom bits of the reservation map pointer.
#define HPAGE_RESV_OWNER (1UL << 0) Indicates this task is the
owner of the reservations associated with the mapping.
#define HPAGE_RESV_UNMAPPED (1UL << 1) Indicates task originally
mapping this range (and creating reserves) has unmapped a
page from this task (the child) due to a failed COW.
``#define HPAGE_RESV_OWNER (1UL << 0)``
Indicates this task is the owner of the reservations
associated with the mapping.
``#define HPAGE_RESV_UNMAPPED (1UL << 1)``
Indicates task originally mapping this range (and creating
reserves) has unmapped a page from this task (the child)
due to a failed COW.
Page Flags
The PagePrivate page flag is used to indicate that a huge page
reservation must be restored when the huge page is freed. More
......@@ -65,12 +80,14 @@ Page Flags
Reservation Map Location (Private or Shared)
--------------------------------------------
============================================
A huge page mapping or segment is either private or shared. If private,
it is typically only available to a single address space (task). If shared,
it can be mapped into multiple address spaces (tasks). The location and
semantics of the reservation map is significantly different for two types
of mappings. Location differences are:
- For private mappings, the reservation map hangs off the the VMA structure.
Specifically, vma->vm_private_data. This reserve map is created at the
time the mapping (mmap(MAP_PRIVATE)) is created.
......@@ -82,15 +99,15 @@ of mappings. Location differences are:
Creating Reservations
---------------------
=====================
Reservations are created when a huge page backed shared memory segment is
created (shmget(SHM_HUGETLB)) or a mapping is created via mmap(MAP_HUGETLB).
These operations result in a call to the routine hugetlb_reserve_pages()
These operations result in a call to the routine hugetlb_reserve_pages()::
int hugetlb_reserve_pages(struct inode *inode,
long from, long to,
struct vm_area_struct *vma,
vm_flags_t vm_flags)
int hugetlb_reserve_pages(struct inode *inode,
long from, long to,
struct vm_area_struct *vma,
vm_flags_t vm_flags)
The first thing hugetlb_reserve_pages() does is check for the NORESERVE
flag was specified in either the shmget() or mmap() call. If NORESERVE
......@@ -105,6 +122,7 @@ the 'from' and 'to' arguments have been adjusted by this offset.
One of the big differences between PRIVATE and SHARED mappings is the way
in which reservations are represented in the reservation map.
- For shared mappings, an entry in the reservation map indicates a reservation
exists or did exist for the corresponding page. As reservations are
consumed, the reservation map is not modified.
......@@ -121,12 +139,13 @@ to indicate this VMA owns the reservations.
The reservation map is consulted to determine how many huge page reservations
are needed for the current mapping/segment. For private mappings, this is
always the value (to - from). However, for shared mappings it is possible that some reservations may already exist within the range (to - from). See the
section "Reservation Map Modifications" for details on how this is accomplished.
section :ref:`Reservation Map Modifications <resv_map_modifications>`
for details on how this is accomplished.
The mapping may be associated with a subpool. If so, the subpool is consulted
to ensure there is sufficient space for the mapping. It is possible that the
subpool has set aside reservations that can be used for the mapping. See the
section "Subpool Reservations" for more details.
section :ref:`Subpool Reservations <sub_pool_resv>` for more details.
After consulting the reservation map and subpool, the number of needed new
reservations is known. The routine hugetlb_acct_memory() is called to check
......@@ -135,9 +154,11 @@ calls into routines that potentially allocate and adjust surplus page counts.
However, within those routines the code is simply checking to ensure there
are enough free huge pages to accommodate the reservation. If there are,
the global reservation count resv_huge_pages is adjusted something like the
following.
following::
if (resv_needed <= (resv_huge_pages - free_huge_pages))
resv_huge_pages += resv_needed;
Note that the global lock hugetlb_lock is held when checking and adjusting
these counters.
......@@ -152,14 +173,18 @@ If hugetlb_reserve_pages() was successful, the global reservation count and
reservation map associated with the mapping will be modified as required to
ensure reservations exist for the range 'from' - 'to'.
.. _consume_resv:
Consuming Reservations/Allocating a Huge Page
---------------------------------------------
=============================================
Reservations are consumed when huge pages associated with the reservations
are allocated and instantiated in the corresponding mapping. The allocation
is performed within the routine alloc_huge_page().
struct page *alloc_huge_page(struct vm_area_struct *vma,
unsigned long addr, int avoid_reserve)
is performed within the routine alloc_huge_page()::
struct page *alloc_huge_page(struct vm_area_struct *vma,
unsigned long addr, int avoid_reserve)
alloc_huge_page is passed a VMA pointer and a virtual address, so it can
consult the reservation map to determine if a reservation exists. In addition,
alloc_huge_page takes the argument avoid_reserve which indicates reserves
......@@ -170,8 +195,9 @@ page are being allocated.
The helper routine vma_needs_reservation() is called to determine if a
reservation exists for the address within the mapping(vma). See the section
"Reservation Map Helper Routines" for detailed information on what this
routine does. The value returned from vma_needs_reservation() is generally
:ref:`Reservation Map Helper Routines <resv_map_helpers>` for detailed
information on what this routine does.
The value returned from vma_needs_reservation() is generally
0 or 1. 0 if a reservation exists for the address, 1 if no reservation exists.
If a reservation does not exist, and there is a subpool associated with the
mapping the subpool is consulted to determine if it contains reservations.
......@@ -180,21 +206,25 @@ However, in every case the avoid_reserve argument overrides the use of
a reservation for the allocation. After determining whether a reservation
exists and can be used for the allocation, the routine dequeue_huge_page_vma()
is called. This routine takes two arguments related to reservations:
- avoid_reserve, this is the same value/argument passed to alloc_huge_page()
- chg, even though this argument is of type long only the values 0 or 1 are
passed to dequeue_huge_page_vma. If the value is 0, it indicates a
reservation exists (see the section "Memory Policy and Reservations" for
possible issues). If the value is 1, it indicates a reservation does not
exist and the page must be taken from the global free pool if possible.
The free lists associated with the memory policy of the VMA are searched for
a free page. If a page is found, the value free_huge_pages is decremented
when the page is removed from the free list. If there was a reservation
associated with the page, the following adjustments are made:
associated with the page, the following adjustments are made::
SetPagePrivate(page); /* Indicates allocating this page consumed
* a reservation, and if an error is
* encountered such that the page must be
* freed, the reservation will be restored. */
resv_huge_pages--; /* Decrement the global reservation count */
Note, if no huge page can be found that satisfies the VMA's memory policy
an attempt will be made to allocate one using the buddy allocator. This
brings up the issue of surplus huge pages and overcommit which is beyond
......@@ -222,12 +252,14 @@ mapping. In such cases, the reservation count and subpool free page count
will be off by one. This rare condition can be identified by comparing the
return value from vma_needs_reservation and vma_commit_reservation. If such
a race is detected, the subpool and global reserve counts are adjusted to
compensate. See the section "Reservation Map Helper Routines" for more
compensate. See the section
:ref:`Reservation Map Helper Routines <resv_map_helpers>` for more
information on these routines.
Instantiate Huge Pages
----------------------
======================
After huge page allocation, the page is typically added to the page tables
of the allocating task. Before this, pages in a shared mapping are added
to the page cache and pages in private mappings are added to an anonymous
......@@ -237,7 +269,8 @@ to the global reservation count (resv_huge_pages).
Freeing Huge Pages
------------------
==================
Huge page freeing is performed by the routine free_huge_page(). This routine
is the destructor for hugetlbfs compound pages. As a result, it is only
passed a pointer to the page struct. When a huge page is freed, reservation
......@@ -247,7 +280,8 @@ on an error path where a global reserve count must be restored.
The page->private field points to any subpool associated with the page.
If the PagePrivate flag is set, it indicates the global reserve count should
be adjusted (see the section "Consuming Reservations/Allocating a Huge Page"
be adjusted (see the section
:ref:`Consuming Reservations/Allocating a Huge Page <consume_resv>`
for information on how these are set).
The routine first calls hugepage_subpool_put_pages() for the page. If this
......@@ -259,9 +293,11 @@ Therefore, the global resv_huge_pages counter is incremented in this case.
If the PagePrivate flag was set in the page, the global resv_huge_pages counter
will always be incremented.
.. _sub_pool_resv:
Subpool Reservations
--------------------
====================
There is a struct hstate associated with each huge page size. The hstate
tracks all huge pages of the specified size. A subpool represents a subset
of pages within a hstate that is associated with a mounted hugetlbfs
......@@ -295,7 +331,8 @@ the global pools.
COW and Reservations
--------------------
====================
Since shared mappings all point to and use the same underlying pages, the
biggest reservation concern for COW is private mappings. In this case,
two tasks can be pointing at the same previously allocated page. One task
......@@ -326,30 +363,36 @@ faults on a non-present page. But, the original owner of the
mapping/reservation will behave as expected.
.. _resv_map_modifications:
Reservation Map Modifications
-----------------------------
=============================
The following low level routines are used to make modifications to a
reservation map. Typically, these routines are not called directly. Rather,
a reservation map helper routine is called which calls one of these low level
routines. These low level routines are fairly well documented in the source
code (mm/hugetlb.c). These routines are:
long region_chg(struct resv_map *resv, long f, long t);
long region_add(struct resv_map *resv, long f, long t);
void region_abort(struct resv_map *resv, long f, long t);
long region_count(struct resv_map *resv, long f, long t);
code (mm/hugetlb.c). These routines are::
long region_chg(struct resv_map *resv, long f, long t);
long region_add(struct resv_map *resv, long f, long t);
void region_abort(struct resv_map *resv, long f, long t);
long region_count(struct resv_map *resv, long f, long t);
Operations on the reservation map typically involve two operations:
1) region_chg() is called to examine the reserve map and determine how
many pages in the specified range [f, t) are NOT currently represented.
The calling code performs global checks and allocations to determine if
there are enough huge pages for the operation to succeed.
2a) If the operation can succeed, region_add() is called to actually modify
the reservation map for the same range [f, t) previously passed to
region_chg().
2b) If the operation can not succeed, region_abort is called for the same range
[f, t) to abort the operation.
2)
a) If the operation can succeed, region_add() is called to actually modify
the reservation map for the same range [f, t) previously passed to
region_chg().
b) If the operation can not succeed, region_abort is called for the same
range [f, t) to abort the operation.
Note that this is a two step process where region_add() and region_abort()
are guaranteed to succeed after a prior call to region_chg() for the same
......@@ -371,6 +414,7 @@ and make the appropriate adjustments.
The routine region_del() is called to remove regions from a reservation map.
It is typically called in the following situations:
- When a file in the hugetlbfs filesystem is being removed, the inode will
be released and the reservation map freed. Before freeing the reservation
map, all the individual file_region structures must be freed. In this case
......@@ -384,6 +428,7 @@ It is typically called in the following situations:
removed, region_del() is called to remove the corresponding entry from the
reservation map. In this case, region_del is passed the range
[page_idx, page_idx + 1).
In every case, region_del() will return the number of pages removed from the
reservation map. In VERY rare cases, region_del() can fail. This can only
happen in the hole punch case where it has to split an existing file_region
......@@ -403,9 +448,11 @@ outstanding (outstanding = (end - start) - region_count(resv, start, end)).
Since the mapping is going away, the subpool and global reservation counts
are decremented by the number of outstanding reservations.
.. _resv_map_helpers:
Reservation Map Helper Routines
-------------------------------
===============================
Several helper routines exist to query and modify the reservation maps.
These routines are only interested with reservations for a specific huge
page, so they just pass in an address instead of a range. In addition,
......@@ -414,32 +461,40 @@ or shared) and the location of the reservation map (inode or VMA) can be
determined. These routines simply call the underlying routines described
in the section "Reservation Map Modifications". However, they do take into
account the 'opposite' meaning of reservation map entries for private and
shared mappings and hide this detail from the caller.
shared mappings and hide this detail from the caller::
long vma_needs_reservation(struct hstate *h,
struct vm_area_struct *vma,
unsigned long addr)
long vma_needs_reservation(struct hstate *h,
struct vm_area_struct *vma, unsigned long addr)
This routine calls region_chg() for the specified page. If no reservation
exists, 1 is returned. If a reservation exists, 0 is returned.
exists, 1 is returned. If a reservation exists, 0 is returned::
long vma_commit_reservation(struct hstate *h,
struct vm_area_struct *vma,
unsigned long addr)
long vma_commit_reservation(struct hstate *h,
struct vm_area_struct *vma, unsigned long addr)
This calls region_add() for the specified page. As in the case of region_chg
and region_add, this routine is to be called after a previous call to
vma_needs_reservation. It will add a reservation entry for the page. It
returns 1 if the reservation was added and 0 if not. The return value should
be compared with the return value of the previous call to
vma_needs_reservation. An unexpected difference indicates the reservation
map was modified between calls.
map was modified between calls::
void vma_end_reservation(struct hstate *h,
struct vm_area_struct *vma,
unsigned long addr)
void vma_end_reservation(struct hstate *h,
struct vm_area_struct *vma, unsigned long addr)
This calls region_abort() for the specified page. As in the case of region_chg
and region_abort, this routine is to be called after a previous call to
vma_needs_reservation. It will abort/end the in progress reservation add
operation.
operation::
long vma_add_reservation(struct hstate *h,
struct vm_area_struct *vma,
unsigned long addr)
long vma_add_reservation(struct hstate *h,
struct vm_area_struct *vma, unsigned long addr)
This is a special wrapper routine to help facilitate reservation cleanup
on error paths. It is only called from the routine restore_reserve_on_error().
This routine is used in conjunction with vma_needs_reservation in an attempt
......@@ -453,8 +508,10 @@ be done on error paths.
Reservation Cleanup in Error Paths
----------------------------------
As mentioned in the section "Reservation Map Helper Routines", reservation
==================================
As mentioned in the section
:ref:`Reservation Map Helper Routines <resv_map_helpers>`, reservation
map modifications are performed in two steps. First vma_needs_reservation
is called before a page is allocated. If the allocation is successful,
then vma_commit_reservation is called. If not, vma_end_reservation is called.
......@@ -494,13 +551,14 @@ so that a reservation will not be leaked when the huge page is freed.
Reservations and Memory Policy
------------------------------
==============================
Per-node huge page lists existed in struct hstate when git was first used
to manage Linux code. The concept of reservations was added some time later.
When reservations were added, no attempt was made to take memory policy
into account. While cpusets are not exactly the same as memory policy, this
comment in hugetlb_acct_memory sums up the interaction between reservations
and cpusets/memory policy.
and cpusets/memory policy::
/*
* When cpuset is configured, it breaks the strict hugetlb page
* reservation as the accounting is done on a global variable. Such
......
.. hwpoison:
========
hwpoison
========
What is hwpoison?
=================
Upcoming Intel CPUs have support for recovering from some memory errors
(``MCA recovery''). This requires the OS to declare a page "poisoned",
(``MCA recovery``). This requires the OS to declare a page "poisoned",
kill the processes associated with it and avoid using it in the future.
This patchkit implements the necessary infrastructure in the VM.
......@@ -46,9 +53,10 @@ address. This in theory allows other applications to handle
memory failures too. The expection is that near all applications
won't do that, but some very specialized ones might.
---
Failure recovery modes
======================
There are two (actually three) modi memory failure recovery can be in:
There are two (actually three) modes memory failure recovery can be in:
vm.memory_failure_recovery sysctl set to zero:
All memory failures cause a panic. Do not attempt recovery.
......@@ -67,9 +75,8 @@ late kill
This is best for memory error unaware applications and default
Note some pages are always handled as late kill.
---
User control:
User control
============
vm.memory_failure_recovery
See sysctl.txt
......@@ -79,11 +86,19 @@ vm.memory_failure_early_kill
PR_MCE_KILL
Set early/late kill mode/revert to system default
arg1: PR_MCE_KILL_CLEAR: Revert to system default
arg1: PR_MCE_KILL_SET: arg2 defines thread specific mode
PR_MCE_KILL_EARLY: Early kill
PR_MCE_KILL_LATE: Late kill
PR_MCE_KILL_DEFAULT: Use system global default
arg1: PR_MCE_KILL_CLEAR:
Revert to system default
arg1: PR_MCE_KILL_SET:
arg2 defines thread specific mode
PR_MCE_KILL_EARLY:
Early kill
PR_MCE_KILL_LATE:
Late kill
PR_MCE_KILL_DEFAULT
Use system global default
Note that if you want to have a dedicated thread which handles
the SIGBUS(BUS_MCEERR_AO) on behalf of the process, you should
call prctl(PR_MCE_KILL_EARLY) on the designated thread. Otherwise,
......@@ -92,77 +107,64 @@ PR_MCE_KILL
PR_MCE_KILL_GET
return current mode
Testing
=======
---
Testing:
madvise(MADV_HWPOISON, ....)
(as root)
Poison a page in the process for testing
* madvise(MADV_HWPOISON, ....) (as root) - Poison a page in the
process for testing
hwpoison-inject module through debugfs
* hwpoison-inject module through debugfs ``/sys/kernel/debug/hwpoison/``
/sys/kernel/debug/hwpoison/
corrupt-pfn
Inject hwpoison fault at PFN echoed into this file. This does
some early filtering to avoid corrupted unintended pages in test suites.
corrupt-pfn
unpoison-pfn
Software-unpoison page at PFN echoed into this file. This way
a page can be reused again. This only works for Linux
injected failures, not for real memory failures.
Inject hwpoison fault at PFN echoed into this file. This does
some early filtering to avoid corrupted unintended pages in test suites.
Note these injection interfaces are not stable and might change between
kernel versions
unpoison-pfn
corrupt-filter-dev-major, corrupt-filter-dev-minor
Only handle memory failures to pages associated with the file
system defined by block device major/minor. -1U is the
wildcard value. This should be only used for testing with
artificial injection.
Software-unpoison page at PFN echoed into this file. This
way a page can be reused again.
This only works for Linux injected failures, not for real
memory failures.
corrupt-filter-memcg
Limit injection to pages owned by memgroup. Specified by inode
number of the memcg.
Note these injection interfaces are not stable and might change between
kernel versions
Example::
corrupt-filter-dev-major
corrupt-filter-dev-minor
mkdir /sys/fs/cgroup/mem/hwpoison
Only handle memory failures to pages associated with the file system defined
by block device major/minor. -1U is the wildcard value.
This should be only used for testing with artificial injection.
usemem -m 100 -s 1000 &
echo `jobs -p` > /sys/fs/cgroup/mem/hwpoison/tasks
corrupt-filter-memcg
memcg_ino=$(ls -id /sys/fs/cgroup/mem/hwpoison | cut -f1 -d' ')
echo $memcg_ino > /debug/hwpoison/corrupt-filter-memcg
Limit injection to pages owned by memgroup. Specified by inode number
of the memcg.
page-types -p `pidof init` --hwpoison # shall do nothing
page-types -p `pidof usemem` --hwpoison # poison its pages
Example:
mkdir /sys/fs/cgroup/mem/hwpoison
corrupt-filter-flags-mask, corrupt-filter-flags-value
When specified, only poison pages if ((page_flags & mask) ==
value). This allows stress testing of many kinds of
pages. The page_flags are the same as in /proc/kpageflags. The
flag bits are defined in include/linux/kernel-page-flags.h and
documented in Documentation/vm/pagemap.rst
usemem -m 100 -s 1000 &
echo `jobs -p` > /sys/fs/cgroup/mem/hwpoison/tasks
* Architecture specific MCE injector
memcg_ino=$(ls -id /sys/fs/cgroup/mem/hwpoison | cut -f1 -d' ')
echo $memcg_ino > /debug/hwpoison/corrupt-filter-memcg
x86 has mce-inject, mce-test
page-types -p `pidof init` --hwpoison # shall do nothing
page-types -p `pidof usemem` --hwpoison # poison its pages
Some portable hwpoison test programs in mce-test, see below.
corrupt-filter-flags-mask
corrupt-filter-flags-value
When specified, only poison pages if ((page_flags & mask) == value).
This allows stress testing of many kinds of pages. The page_flags
are the same as in /proc/kpageflags. The flag bits are defined in
include/linux/kernel-page-flags.h and documented in
Documentation/vm/pagemap.txt
Architecture specific MCE injector
x86 has mce-inject, mce-test
Some portable hwpoison test programs in mce-test, see blow.
---
References:
References
==========
http://halobates.de/mce-lc09-2.pdf
Overview presentation from LinuxCon 09
......@@ -174,14 +176,11 @@ git://git.kernel.org/pub/scm/utils/cpu/mce/mce-inject.git
x86 specific injector
---
Limitations:
Limitations
===========
- Not all page types are supported and never will. Most kernel internal
objects cannot be recovered, only LRU pages for now.
objects cannot be recovered, only LRU pages for now.
- Right now hugepage support is missing.
---
Andi Kleen, Oct 2009
MOTIVATION
.. _idle_page_tracking:
==================
Idle Page Tracking
==================
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
......@@ -8,10 +15,14 @@ or deciding where to place the workload within a compute cluster.
It is enabled by CONFIG_IDLE_PAGE_TRACKING=y.
USER API
.. _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.
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
......@@ -19,8 +30,9 @@ 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
(for more details on what "accessed" actually means see the :ref:`Implementation
Details <impl_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.
......@@ -30,9 +42,9 @@ 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.
``/proc/kpageflags`` in order to correctly count idle huge pages.
Reading from or writing to /sys/kernel/mm/page_idle/bitmap will return
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.
......@@ -41,21 +53,25 @@ 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.
``/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.
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.rst for more information about
``/proc/pid/pagemap``, ``/proc/kpageflags``, and ``/proc/kpagecgroup``.
See Documentation/vm/pagemap.txt for more information about /proc/pid/pagemap,
/proc/kpageflags, and /proc/kpagecgroup.
.. _impl_details:
IMPLEMENTATION DETAILS
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
......@@ -77,7 +93,8 @@ 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
is set manually, by writing to ``/sys/kernel/mm/page_idle/bitmap`` (see the
:ref:`User API <user_api>`
section), and cleared automatically whenever a page is referenced as defined
above.
......
=====================================
Linux Memory Management Documentation
=====================================
This is a collection of documents about Linux memory management (mm) subsystem.
User guides for MM features
===========================
The following documents provide guides for controlling and tuning
various features of the Linux memory management
.. toctree::
:maxdepth: 1
hugetlbpage
idle_page_tracking
ksm
numa_memory_policy
pagemap
transhuge
soft-dirty
swap_numa
userfaultfd
zswap
Kernel developers MM documentation
==================================
The below documents describe MM internals with different level of
details ranging from notes and mailing list responses to elaborate
descriptions of data structures and algorithms.
.. toctree::
:maxdepth: 1
active_mm
balance
cleancache
frontswap
highmem
hmm
hwpoison
hugetlbfs_reserv
mmu_notifier
numa
overcommit-accounting
page_migration
page_frags
page_owner
remap_file_pages
slub
split_page_table_lock
unevictable-lru
z3fold
zsmalloc
How to use the Kernel Samepage Merging feature
----------------------------------------------
.. _ksm:
=======================
Kernel Samepage Merging
=======================
KSM is a memory-saving de-duplication feature, enabled by CONFIG_KSM=y,
added to the Linux kernel in 2.6.32. See mm/ksm.c for its implementation,
added to the Linux kernel in 2.6.32. See ``mm/ksm.c`` for its implementation,
and http://lwn.net/Articles/306704/ and http://lwn.net/Articles/330589/
The KSM daemon ksmd periodically scans those areas of user memory which
......@@ -51,110 +54,112 @@ Applications should be considerate in their use of MADV_MERGEABLE,
restricting its use to areas likely to benefit. KSM's scans may use a lot
of processing power: some installations will disable KSM for that reason.
The KSM daemon is controlled by sysfs files in /sys/kernel/mm/ksm/,
The KSM daemon is controlled by sysfs files in ``/sys/kernel/mm/ksm/``,
readable by all but writable only by root:
pages_to_scan - how many present pages to scan before ksmd goes to sleep
e.g. "echo 100 > /sys/kernel/mm/ksm/pages_to_scan"
Default: 100 (chosen for demonstration purposes)
sleep_millisecs - how many milliseconds ksmd should sleep before next scan
e.g. "echo 20 > /sys/kernel/mm/ksm/sleep_millisecs"
Default: 20 (chosen for demonstration purposes)
merge_across_nodes - specifies if pages from different numa nodes can be merged.
When set to 0, ksm merges only pages which physically
reside in the memory area of same NUMA node. That brings
lower latency to access of shared pages. Systems with more
nodes, at significant NUMA distances, are likely to benefit
from the lower latency of setting 0. Smaller systems, which
need to minimize memory usage, are likely to benefit from
the greater sharing of setting 1 (default). You may wish to
compare how your system performs under each setting, before
deciding on which to use. merge_across_nodes setting can be
changed only when there are no ksm shared pages in system:
set run 2 to unmerge pages first, then to 1 after changing
merge_across_nodes, to remerge according to the new setting.
Default: 1 (merging across nodes as in earlier releases)
run - set 0 to stop ksmd from running but keep merged pages,
set 1 to run ksmd e.g. "echo 1 > /sys/kernel/mm/ksm/run",
set 2 to stop ksmd and unmerge all pages currently merged,
but leave mergeable areas registered for next run
Default: 0 (must be changed to 1 to activate KSM,
except if CONFIG_SYSFS is disabled)
use_zero_pages - specifies whether empty pages (i.e. allocated pages
that only contain zeroes) should be treated specially.
When set to 1, empty pages are merged with the kernel
zero page(s) instead of with each other as it would
happen normally. This can improve the performance on
architectures with coloured zero pages, depending on
the workload. Care should be taken when enabling this
setting, as it can potentially degrade the performance
of KSM for some workloads, for example if the checksums
of pages candidate for merging match the checksum of
an empty page. This setting can be changed at any time,
it is only effective for pages merged after the change.
Default: 0 (normal KSM behaviour as in earlier releases)
max_page_sharing - Maximum sharing allowed for each KSM page. This
enforces a deduplication limit to avoid the virtual
memory rmap lists to grow too large. The minimum
value is 2 as a newly created KSM page will have at
least two sharers. The rmap walk has O(N)
complexity where N is the number of rmap_items
(i.e. virtual mappings) that are sharing the page,
which is in turn capped by max_page_sharing. So
this effectively spread the the linear O(N)
computational complexity from rmap walk context
over different KSM pages. The ksmd walk over the
stable_node "chains" is also O(N), but N is the
number of stable_node "dups", not the number of
rmap_items, so it has not a significant impact on
ksmd performance. In practice the best stable_node
"dup" candidate will be kept and found at the head
of the "dups" list. The higher this value the
faster KSM will merge the memory (because there
will be fewer stable_node dups queued into the
stable_node chain->hlist to check for pruning) and
the higher the deduplication factor will be, but
the slowest the worst case rmap walk could be for
any given KSM page. Slowing down the rmap_walk
means there will be higher latency for certain
virtual memory operations happening during
swapping, compaction, NUMA balancing and page
migration, in turn decreasing responsiveness for
the caller of those virtual memory operations. The
scheduler latency of other tasks not involved with
the VM operations doing the rmap walk is not
affected by this parameter as the rmap walks are
always schedule friendly themselves.
stable_node_chains_prune_millisecs - How frequently to walk the whole
list of stable_node "dups" linked in the
stable_node "chains" in order to prune stale
stable_nodes. Smaller milllisecs values will free
up the KSM metadata with lower latency, but they
will make ksmd use more CPU during the scan. This
only applies to the stable_node chains so it's a
noop if not a single KSM page hit the
max_page_sharing yet (there would be no stable_node
chains in such case).
The effectiveness of KSM and MADV_MERGEABLE is shown in /sys/kernel/mm/ksm/:
pages_shared - how many shared pages are being used
pages_sharing - how many more sites are sharing them i.e. how much saved
pages_unshared - how many pages unique but repeatedly checked for merging
pages_volatile - how many pages changing too fast to be placed in a tree
full_scans - how many times all mergeable areas have been scanned
stable_node_chains - number of stable node chains allocated, this is
effectively the number of KSM pages that hit the
max_page_sharing limit
stable_node_dups - number of stable node dups queued into the
stable_node chains
pages_to_scan
how many present pages to scan before ksmd goes to sleep
e.g. ``echo 100 > /sys/kernel/mm/ksm/pages_to_scan`` Default: 100
(chosen for demonstration purposes)
sleep_millisecs
how many milliseconds ksmd should sleep before next scan
e.g. ``echo 20 > /sys/kernel/mm/ksm/sleep_millisecs`` Default: 20
(chosen for demonstration purposes)
merge_across_nodes
specifies if pages from different numa nodes can be merged.
When set to 0, ksm merges only pages which physically reside
in the memory area of same NUMA node. That brings lower
latency to access of shared pages. Systems with more nodes, at
significant NUMA distances, are likely to benefit from the
lower latency of setting 0. Smaller systems, which need to
minimize memory usage, are likely to benefit from the greater
sharing of setting 1 (default). You may wish to compare how
your system performs under each setting, before deciding on
which to use. merge_across_nodes setting can be changed only
when there are no ksm shared pages in system: set run 2 to
unmerge pages first, then to 1 after changing
merge_across_nodes, to remerge according to the new setting.
Default: 1 (merging across nodes as in earlier releases)
run
set 0 to stop ksmd from running but keep merged pages,
set 1 to run ksmd e.g. ``echo 1 > /sys/kernel/mm/ksm/run``,
set 2 to stop ksmd and unmerge all pages currently merged, but
leave mergeable areas registered for next run Default: 0 (must
be changed to 1 to activate KSM, except if CONFIG_SYSFS is
disabled)
use_zero_pages
specifies whether empty pages (i.e. allocated pages that only
contain zeroes) should be treated specially. When set to 1,
empty pages are merged with the kernel zero page(s) instead of
with each other as it would happen normally. This can improve
the performance on architectures with coloured zero pages,
depending on the workload. Care should be taken when enabling
this setting, as it can potentially degrade the performance of
KSM for some workloads, for example if the checksums of pages
candidate for merging match the checksum of an empty
page. This setting can be changed at any time, it is only
effective for pages merged after the change. Default: 0
(normal KSM behaviour as in earlier releases)
max_page_sharing
Maximum sharing allowed for each KSM page. This enforces a
deduplication limit to avoid the virtual memory rmap lists to
grow too large. The minimum value is 2 as a newly created KSM
page will have at least two sharers. The rmap walk has O(N)
complexity where N is the number of rmap_items (i.e. virtual
mappings) that are sharing the page, which is in turn capped
by max_page_sharing. So this effectively spread the the linear
O(N) computational complexity from rmap walk context over
different KSM pages. The ksmd walk over the stable_node
"chains" is also O(N), but N is the number of stable_node
"dups", not the number of rmap_items, so it has not a
significant impact on ksmd performance. In practice the best
stable_node "dup" candidate will be kept and found at the head
of the "dups" list. The higher this value the faster KSM will
merge the memory (because there will be fewer stable_node dups
queued into the stable_node chain->hlist to check for pruning)
and the higher the deduplication factor will be, but the
slowest the worst case rmap walk could be for any given KSM
page. Slowing down the rmap_walk means there will be higher
latency for certain virtual memory operations happening during
swapping, compaction, NUMA balancing and page migration, in
turn decreasing responsiveness for the caller of those virtual
memory operations. The scheduler latency of other tasks not
involved with the VM operations doing the rmap walk is not
affected by this parameter as the rmap walks are always
schedule friendly themselves.
stable_node_chains_prune_millisecs
How frequently to walk the whole list of stable_node "dups"
linked in the stable_node "chains" in order to prune stale
stable_nodes. Smaller milllisecs values will free up the KSM
metadata with lower latency, but they will make ksmd use more
CPU during the scan. This only applies to the stable_node
chains so it's a noop if not a single KSM page hit the
max_page_sharing yet (there would be no stable_node chains in
such case).
The effectiveness of KSM and MADV_MERGEABLE is shown in ``/sys/kernel/mm/ksm/``:
pages_shared
how many shared pages are being used
pages_sharing
how many more sites are sharing them i.e. how much saved
pages_unshared
how many pages unique but repeatedly checked for merging
pages_volatile
how many pages changing too fast to be placed in a tree
full_scans
how many times all mergeable areas have been scanned
stable_node_chains
number of stable node chains allocated, this is effectively
the number of KSM pages that hit the max_page_sharing limit
stable_node_dups
number of stable node dups queued into the stable_node chains
A high ratio of pages_sharing to pages_shared indicates good sharing, but
a high ratio of pages_unshared to pages_sharing indicates wasted effort.
......
.. _mmu_notifier:
When do you need to notify inside page table lock ?
===================================================
When clearing a pte/pmd we are given a choice to notify the event through
(notify version of *_clear_flush call mmu_notifier_invalidate_range) under
(notify version of \*_clear_flush call mmu_notifier_invalidate_range) under
the page table lock. But that notification is not necessary in all cases.
For secondary TLB (non CPU TLB) like IOMMU TLB or device TLB (when device use
......@@ -18,6 +21,7 @@ a page that might now be used by some completely different task.
Case B is more subtle. For correctness it requires the following sequence to
happen:
- take page table lock
- clear page table entry and notify ([pmd/pte]p_huge_clear_flush_notify())
- set page table entry to point to new page
......@@ -28,58 +32,60 @@ the device.
Consider the following scenario (device use a feature similar to ATS/PASID):
Two address addrA and addrB such that |addrA - addrB| >= PAGE_SIZE we assume
Two address addrA and addrB such that \|addrA - addrB\| >= PAGE_SIZE we assume
they are write protected for COW (other case of B apply too).
[Time N] --------------------------------------------------------------------
CPU-thread-0 {try to write to addrA}
CPU-thread-1 {try to write to addrB}
CPU-thread-2 {}
CPU-thread-3 {}
DEV-thread-0 {read addrA and populate device TLB}
DEV-thread-2 {read addrB and populate device TLB}
[Time N+1] ------------------------------------------------------------------
CPU-thread-0 {COW_step0: {mmu_notifier_invalidate_range_start(addrA)}}
CPU-thread-1 {COW_step0: {mmu_notifier_invalidate_range_start(addrB)}}
CPU-thread-2 {}
CPU-thread-3 {}
DEV-thread-0 {}
DEV-thread-2 {}
[Time N+2] ------------------------------------------------------------------
CPU-thread-0 {COW_step1: {update page table to point to new page for addrA}}
CPU-thread-1 {COW_step1: {update page table to point to new page for addrB}}
CPU-thread-2 {}
CPU-thread-3 {}
DEV-thread-0 {}
DEV-thread-2 {}
[Time N+3] ------------------------------------------------------------------
CPU-thread-0 {preempted}
CPU-thread-1 {preempted}
CPU-thread-2 {write to addrA which is a write to new page}
CPU-thread-3 {}
DEV-thread-0 {}
DEV-thread-2 {}
[Time N+3] ------------------------------------------------------------------
CPU-thread-0 {preempted}
CPU-thread-1 {preempted}
CPU-thread-2 {}
CPU-thread-3 {write to addrB which is a write to new page}
DEV-thread-0 {}
DEV-thread-2 {}
[Time N+4] ------------------------------------------------------------------
CPU-thread-0 {preempted}
CPU-thread-1 {COW_step3: {mmu_notifier_invalidate_range_end(addrB)}}
CPU-thread-2 {}
CPU-thread-3 {}
DEV-thread-0 {}
DEV-thread-2 {}
[Time N+5] ------------------------------------------------------------------
CPU-thread-0 {preempted}
CPU-thread-1 {}
CPU-thread-2 {}
CPU-thread-3 {}
DEV-thread-0 {read addrA from old page}
DEV-thread-2 {read addrB from new page}
::
[Time N] --------------------------------------------------------------------
CPU-thread-0 {try to write to addrA}
CPU-thread-1 {try to write to addrB}
CPU-thread-2 {}
CPU-thread-3 {}
DEV-thread-0 {read addrA and populate device TLB}
DEV-thread-2 {read addrB and populate device TLB}
[Time N+1] ------------------------------------------------------------------
CPU-thread-0 {COW_step0: {mmu_notifier_invalidate_range_start(addrA)}}
CPU-thread-1 {COW_step0: {mmu_notifier_invalidate_range_start(addrB)}}
CPU-thread-2 {}
CPU-thread-3 {}
DEV-thread-0 {}
DEV-thread-2 {}
[Time N+2] ------------------------------------------------------------------
CPU-thread-0 {COW_step1: {update page table to point to new page for addrA}}
CPU-thread-1 {COW_step1: {update page table to point to new page for addrB}}
CPU-thread-2 {}
CPU-thread-3 {}
DEV-thread-0 {}
DEV-thread-2 {}
[Time N+3] ------------------------------------------------------------------
CPU-thread-0 {preempted}
CPU-thread-1 {preempted}
CPU-thread-2 {write to addrA which is a write to new page}
CPU-thread-3 {}
DEV-thread-0 {}
DEV-thread-2 {}
[Time N+3] ------------------------------------------------------------------
CPU-thread-0 {preempted}
CPU-thread-1 {preempted}
CPU-thread-2 {}
CPU-thread-3 {write to addrB which is a write to new page}
DEV-thread-0 {}
DEV-thread-2 {}
[Time N+4] ------------------------------------------------------------------
CPU-thread-0 {preempted}
CPU-thread-1 {COW_step3: {mmu_notifier_invalidate_range_end(addrB)}}
CPU-thread-2 {}
CPU-thread-3 {}
DEV-thread-0 {}
DEV-thread-2 {}
[Time N+5] ------------------------------------------------------------------
CPU-thread-0 {preempted}
CPU-thread-1 {}
CPU-thread-2 {}
CPU-thread-3 {}
DEV-thread-0 {read addrA from old page}
DEV-thread-2 {read addrB from new page}
So here because at time N+2 the clear page table entry was not pair with a
notification to invalidate the secondary TLB, the device see the new value for
......
.. _numa:
Started Nov 1999 by Kanoj Sarcar <kanoj@sgi.com>
=============
What is NUMA?
=============
This question can be answered from a couple of perspectives: the
hardware view and the Linux software view.
......@@ -106,7 +110,7 @@ to improve NUMA locality using various CPU affinity command line interfaces,
such as taskset(1) and numactl(1), and program interfaces such as
sched_setaffinity(2). Further, one can modify the kernel's default local
allocation behavior using Linux NUMA memory policy.
[see Documentation/vm/numa_memory_policy.txt.]
[see Documentation/vm/numa_memory_policy.rst.]
System administrators can restrict the CPUs and nodes' memories that a non-
privileged user can specify in the scheduling or NUMA commands and functions
......
The Linux kernel supports the following overcommit handling modes
0 - Heuristic overcommit handling. Obvious overcommits of
address space are refused. Used for a typical system. It
ensures a seriously wild allocation fails while allowing
overcommit to reduce swap usage. root is allowed to
allocate slightly more memory in this mode. This is the
default.
1 - Always overcommit. Appropriate for some scientific
applications. Classic example is code using sparse arrays
and just relying on the virtual memory consisting almost
entirely of zero pages.
2 - Don't overcommit. The total address space commit
for the system is not permitted to exceed swap + a
configurable amount (default is 50%) of physical RAM.
Depending on the amount you use, in most situations
this means a process will not be killed while accessing
pages but will receive errors on memory allocation as
appropriate.
Useful for applications that want to guarantee their
memory allocations will be available in the future
without having to initialize every page.
The overcommit policy is set via the sysctl `vm.overcommit_memory'.
The overcommit amount can be set via `vm.overcommit_ratio' (percentage)
or `vm.overcommit_kbytes' (absolute value).
The current overcommit limit and amount committed are viewable in
/proc/meminfo as CommitLimit and Committed_AS respectively.
Gotchas
-------
The C language stack growth does an implicit mremap. If you want absolute
guarantees and run close to the edge you MUST mmap your stack for the
largest size you think you will need. For typical stack usage this does
not matter much but it's a corner case if you really really care
In mode 2 the MAP_NORESERVE flag is ignored.
How It Works
------------
The overcommit is based on the following rules
For a file backed map
SHARED or READ-only - 0 cost (the file is the map not swap)
PRIVATE WRITABLE - size of mapping per instance
For an anonymous or /dev/zero map
SHARED - size of mapping
PRIVATE READ-only - 0 cost (but of little use)
PRIVATE WRITABLE - size of mapping per instance
Additional accounting
Pages made writable copies by mmap
shmfs memory drawn from the same pool
Status
------
o We account mmap memory mappings
o We account mprotect changes in commit
o We account mremap changes in size
o We account brk
o We account munmap
o We report the commit status in /proc
o Account and check on fork
o Review stack handling/building on exec
o SHMfs accounting
o Implement actual limit enforcement
To Do
-----
o Account ptrace pages (this is hard)
.. _overcommit_accounting:
=====================
Overcommit Accounting
=====================
The Linux kernel supports the following overcommit handling modes
0
Heuristic overcommit handling. Obvious overcommits of address
space are refused. Used for a typical system. It ensures a
seriously wild allocation fails while allowing overcommit to
reduce swap usage. root is allowed to allocate slightly more
memory in this mode. This is the default.
1
Always overcommit. Appropriate for some scientific
applications. Classic example is code using sparse arrays and
just relying on the virtual memory consisting almost entirely
of zero pages.
2
Don't overcommit. The total address space commit for the
system is not permitted to exceed swap + a configurable amount
(default is 50%) of physical RAM. Depending on the amount you
use, in most situations this means a process will not be
killed while accessing pages but will receive errors on memory
allocation as appropriate.
Useful for applications that want to guarantee their memory
allocations will be available in the future without having to
initialize every page.
The overcommit policy is set via the sysctl ``vm.overcommit_memory``.
The overcommit amount can be set via ``vm.overcommit_ratio`` (percentage)
or ``vm.overcommit_kbytes`` (absolute value).
The current overcommit limit and amount committed are viewable in
``/proc/meminfo`` as CommitLimit and Committed_AS respectively.
Gotchas
=======
The C language stack growth does an implicit mremap. If you want absolute
guarantees and run close to the edge you MUST mmap your stack for the
largest size you think you will need. For typical stack usage this does
not matter much but it's a corner case if you really really care
In mode 2 the MAP_NORESERVE flag is ignored.
How It Works
============
The overcommit is based on the following rules
For a file backed map
| SHARED or READ-only - 0 cost (the file is the map not swap)
| PRIVATE WRITABLE - size of mapping per instance
For an anonymous or ``/dev/zero`` map
| SHARED - size of mapping
| PRIVATE READ-only - 0 cost (but of little use)
| PRIVATE WRITABLE - size of mapping per instance
Additional accounting
| Pages made writable copies by mmap
| shmfs memory drawn from the same pool
Status
======
* We account mmap memory mappings
* We account mprotect changes in commit
* We account mremap changes in size
* We account brk
* We account munmap
* We report the commit status in /proc
* Account and check on fork
* Review stack handling/building on exec
* SHMfs accounting
* Implement actual limit enforcement
To Do
=====
* Account ptrace pages (this is hard)
.. _page_frags:
==============
Page fragments
--------------
==============
A page fragment is an arbitrary-length arbitrary-offset area of memory
which resides within a 0 or higher order compound page. Multiple
......
.. _page_migration:
==============
Page migration
--------------
==============
Page migration allows the moving of the physical location of pages between
nodes in a numa system while the process is running. This means that the
......@@ -20,7 +23,7 @@ Page migration functions are provided by the numactl package by Andi Kleen
(a version later than 0.9.3 is required. Get it from
ftp://oss.sgi.com/www/projects/libnuma/download/). numactl provides libnuma
which provides an interface similar to other numa functionality for page
migration. cat /proc/<pid>/numa_maps allows an easy review of where the
migration. cat ``/proc/<pid>/numa_maps`` allows an easy review of where the
pages of a process are located. See also the numa_maps documentation in the
proc(5) man page.
......@@ -56,8 +59,8 @@ description for those trying to use migrate_pages() from the kernel
(for userspace usage see the Andi Kleen's numactl package mentioned above)
and then a low level description of how the low level details work.
A. In kernel use of migrate_pages()
-----------------------------------
In kernel use of migrate_pages()
================================
1. Remove pages from the LRU.
......@@ -78,8 +81,8 @@ A. In kernel use of migrate_pages()
the new page for each page that is considered for
moving.
B. How migrate_pages() works
----------------------------
How migrate_pages() works
=========================
migrate_pages() does several passes over its list of pages. A page is moved
if all references to a page are removable at the time. The page has
......@@ -142,8 +145,8 @@ Steps:
20. The new page is moved to the LRU and can be scanned by the swapper
etc again.
C. Non-LRU page migration
-------------------------
Non-LRU page migration
======================
Although original migration aimed for reducing the latency of memory access
for NUMA, compaction who want to create high-order page is also main customer.
......@@ -164,89 +167,91 @@ migration path.
If a driver want to make own pages movable, it should define three functions
which are function pointers of struct address_space_operations.
1. bool (*isolate_page) (struct page *page, isolate_mode_t mode);
1. ``bool (*isolate_page) (struct page *page, isolate_mode_t mode);``
What VM expects on isolate_page function of driver is to return *true*
if driver isolates page successfully. On returing true, VM marks the page
as PG_isolated so concurrent isolation in several CPUs skip the page
for isolation. If a driver cannot isolate the page, it should return *false*.
What VM expects on isolate_page function of driver is to return *true*
if driver isolates page successfully. On returing true, VM marks the page
as PG_isolated so concurrent isolation in several CPUs skip the page
for isolation. If a driver cannot isolate the page, it should return *false*.
Once page is successfully isolated, VM uses page.lru fields so driver
shouldn't expect to preserve values in that fields.
Once page is successfully isolated, VM uses page.lru fields so driver
shouldn't expect to preserve values in that fields.
2. int (*migratepage) (struct address_space *mapping,
struct page *newpage, struct page *oldpage, enum migrate_mode);
2. ``int (*migratepage) (struct address_space *mapping,``
| ``struct page *newpage, struct page *oldpage, enum migrate_mode);``
After isolation, VM calls migratepage of driver with isolated page.
The function of migratepage is to move content of the old page to new page
and set up fields of struct page newpage. Keep in mind that you should
indicate to the VM the oldpage is no longer movable via __ClearPageMovable()
under page_lock if you migrated the oldpage successfully and returns
MIGRATEPAGE_SUCCESS. If driver cannot migrate the page at the moment, driver
can return -EAGAIN. On -EAGAIN, VM will retry page migration in a short time
because VM interprets -EAGAIN as "temporal migration failure". On returning
any error except -EAGAIN, VM will give up the page migration without retrying
in this time.
After isolation, VM calls migratepage of driver with isolated page.
The function of migratepage is to move content of the old page to new page
and set up fields of struct page newpage. Keep in mind that you should
indicate to the VM the oldpage is no longer movable via __ClearPageMovable()
under page_lock if you migrated the oldpage successfully and returns
MIGRATEPAGE_SUCCESS. If driver cannot migrate the page at the moment, driver
can return -EAGAIN. On -EAGAIN, VM will retry page migration in a short time
because VM interprets -EAGAIN as "temporal migration failure". On returning
any error except -EAGAIN, VM will give up the page migration without retrying
in this time.
Driver shouldn't touch page.lru field VM using in the functions.
Driver shouldn't touch page.lru field VM using in the functions.
3. void (*putback_page)(struct page *);
3. ``void (*putback_page)(struct page *);``
If migration fails on isolated page, VM should return the isolated page
to the driver so VM calls driver's putback_page with migration failed page.
In this function, driver should put the isolated page back to the own data
structure.
If migration fails on isolated page, VM should return the isolated page
to the driver so VM calls driver's putback_page with migration failed page.
In this function, driver should put the isolated page back to the own data
structure.
4. non-lru movable page flags
There are two page flags for supporting non-lru movable page.
There are two page flags for supporting non-lru movable page.
* PG_movable
* PG_movable
Driver should use the below function to make page movable under page_lock.
Driver should use the below function to make page movable under page_lock::
void __SetPageMovable(struct page *page, struct address_space *mapping)
It needs argument of address_space for registering migration family functions
which will be called by VM. Exactly speaking, PG_movable is not a real flag of
struct page. Rather than, VM reuses page->mapping's lower bits to represent it.
It needs argument of address_space for registering migration
family functions which will be called by VM. Exactly speaking,
PG_movable is not a real flag of struct page. Rather than, VM
reuses page->mapping's lower bits to represent it.
::
#define PAGE_MAPPING_MOVABLE 0x2
page->mapping = page->mapping | PAGE_MAPPING_MOVABLE;
so driver shouldn't access page->mapping directly. Instead, driver should
use page_mapping which mask off the low two bits of page->mapping under
page lock so it can get right struct address_space.
For testing of non-lru movable page, VM supports __PageMovable function.
However, it doesn't guarantee to identify non-lru movable page because
page->mapping field is unified with other variables in struct page.
As well, if driver releases the page after isolation by VM, page->mapping
doesn't have stable value although it has PAGE_MAPPING_MOVABLE
(Look at __ClearPageMovable). But __PageMovable is cheap to catch whether
page is LRU or non-lru movable once the page has been isolated. Because
LRU pages never can have PAGE_MAPPING_MOVABLE in page->mapping. It is also
good for just peeking to test non-lru movable pages before more expensive
checking with lock_page in pfn scanning to select victim.
For guaranteeing non-lru movable page, VM provides PageMovable function.
Unlike __PageMovable, PageMovable functions validates page->mapping and
mapping->a_ops->isolate_page under lock_page. The lock_page prevents sudden
destroying of page->mapping.
Driver using __SetPageMovable should clear the flag via __ClearMovablePage
under page_lock before the releasing the page.
* PG_isolated
To prevent concurrent isolation among several CPUs, VM marks isolated page
as PG_isolated under lock_page. So if a CPU encounters PG_isolated non-lru
movable page, it can skip it. Driver doesn't need to manipulate the flag
because VM will set/clear it automatically. Keep in mind that if driver
sees PG_isolated page, it means the page have been isolated by VM so it
shouldn't touch page.lru field.
PG_isolated is alias with PG_reclaim flag so driver shouldn't use the flag
for own purpose.
so driver shouldn't access page->mapping directly. Instead, driver should
use page_mapping which mask off the low two bits of page->mapping under
page lock so it can get right struct address_space.
For testing of non-lru movable page, VM supports __PageMovable function.
However, it doesn't guarantee to identify non-lru movable page because
page->mapping field is unified with other variables in struct page.
As well, if driver releases the page after isolation by VM, page->mapping
doesn't have stable value although it has PAGE_MAPPING_MOVABLE
(Look at __ClearPageMovable). But __PageMovable is cheap to catch whether
page is LRU or non-lru movable once the page has been isolated. Because
LRU pages never can have PAGE_MAPPING_MOVABLE in page->mapping. It is also
good for just peeking to test non-lru movable pages before more expensive
checking with lock_page in pfn scanning to select victim.
For guaranteeing non-lru movable page, VM provides PageMovable function.
Unlike __PageMovable, PageMovable functions validates page->mapping and
mapping->a_ops->isolate_page under lock_page. The lock_page prevents sudden
destroying of page->mapping.
Driver using __SetPageMovable should clear the flag via __ClearMovablePage
under page_lock before the releasing the page.
* PG_isolated
To prevent concurrent isolation among several CPUs, VM marks isolated page
as PG_isolated under lock_page. So if a CPU encounters PG_isolated non-lru
movable page, it can skip it. Driver doesn't need to manipulate the flag
because VM will set/clear it automatically. Keep in mind that if driver
sees PG_isolated page, it means the page have been isolated by VM so it
shouldn't touch page.lru field.
PG_isolated is alias with PG_reclaim flag so driver shouldn't use the flag
for own purpose.
Christoph Lameter, May 8, 2006.
Minchan Kim, Mar 28, 2016.
.. _page_owner:
==================================================
page owner: Tracking about who allocated each page
-----------------------------------------------------------
==================================================
* Introduction
Introduction
============
page owner is for the tracking about who allocated each page.
It can be used to debug memory leak or to find a memory hogger.
......@@ -34,13 +38,15 @@ not affect to allocation performance, especially if the static keys jump
label patching functionality is available. Following is the kernel's code
size change due to this facility.
- Without page owner
- Without page owner::
text data bss dec hex filename
40662 1493 644 42799 a72f mm/page_alloc.o
40662 1493 644 42799 a72f mm/page_alloc.o
- With page owner::
- With page owner
text data bss dec hex filename
40892 1493 644 43029 a815 mm/page_alloc.o
40892 1493 644 43029 a815 mm/page_alloc.o
1427 24 8 1459 5b3 mm/page_ext.o
2722 50 0 2772 ad4 mm/page_owner.o
......@@ -62,21 +68,23 @@ are catched and marked, although they are mostly allocated from struct
page extension feature. Anyway, after that, no page is left in
un-tracking state.
* Usage
Usage
=====
1) Build user-space helper::
1) Build user-space helper
cd tools/vm
make page_owner_sort
2) Enable page owner
Add "page_owner=on" to boot cmdline.
2) Enable page owner: add "page_owner=on" to boot cmdline.
3) Do the job what you want to debug
4) Analyze information from page owner
4) Analyze information from page owner::
cat /sys/kernel/debug/page_owner > page_owner_full.txt
grep -v ^PFN page_owner_full.txt > page_owner.txt
./page_owner_sort page_owner.txt sorted_page_owner.txt
See the result about who allocated each page
in the sorted_page_owner.txt.
See the result about who allocated each page
in the ``sorted_page_owner.txt``.
pagemap, from the userspace perspective
---------------------------------------
.. _pagemap:
======================================
pagemap from the Userspace Perspective
======================================
pagemap is a new (as of 2.6.25) set of interfaces in the kernel that allow
userspace programs to examine the page tables and related information by
reading files in /proc.
reading files in ``/proc``.
There are four components to pagemap:
* /proc/pid/pagemap. This file lets a userspace process find out which
* ``/proc/pid/pagemap``. This file lets a userspace process find out which
physical frame each virtual page is mapped to. It contains one 64-bit
value for each virtual page, containing the following data (from
fs/proc/task_mmu.c, above pagemap_read):
......@@ -15,7 +18,7 @@ There are four components to pagemap:
* Bits 0-54 page frame number (PFN) if present
* Bits 0-4 swap type if swapped
* Bits 5-54 swap offset if swapped
* Bit 55 pte is soft-dirty (see Documentation/vm/soft-dirty.txt)
* Bit 55 pte is soft-dirty (see Documentation/vm/soft-dirty.rst)
* Bit 56 page exclusively mapped (since 4.2)
* Bits 57-60 zero
* Bit 61 page is file-page or shared-anon (since 3.5)
......@@ -37,24 +40,24 @@ There are four components to pagemap:
determine which areas of memory are actually mapped and llseek to
skip over unmapped regions.
* /proc/kpagecount. This file contains a 64-bit count of the number of
* ``/proc/kpagecount``. This file contains a 64-bit count of the number of
times each page is mapped, indexed by PFN.
* /proc/kpageflags. This file contains a 64-bit set of flags for each
* ``/proc/kpageflags``. This file contains a 64-bit set of flags for each
page, indexed by PFN.
The flags are (from fs/proc/page.c, above kpageflags_read):
0. LOCKED
1. ERROR
2. REFERENCED
3. UPTODATE
4. DIRTY
5. LRU
6. ACTIVE
7. SLAB
8. WRITEBACK
9. RECLAIM
The flags are (from ``fs/proc/page.c``, above kpageflags_read):
0. LOCKED
1. ERROR
2. REFERENCED
3. UPTODATE
4. DIRTY
5. LRU
6. ACTIVE
7. SLAB
8. WRITEBACK
9. RECLAIM
10. BUDDY
11. MMAP
12. ANON
......@@ -72,98 +75,108 @@ There are four components to pagemap:
24. ZERO_PAGE
25. IDLE
* /proc/kpagecgroup. This file contains a 64-bit inode number of the
* ``/proc/kpagecgroup``. This file contains a 64-bit inode number of the
memory cgroup each page is charged to, indexed by PFN. Only available when
CONFIG_MEMCG is set.
Short descriptions to the page flags:
0. LOCKED
page is being locked for exclusive access, eg. by undergoing read/write IO
7. SLAB
page is managed by the SLAB/SLOB/SLUB/SLQB kernel memory allocator
When compound page is used, SLUB/SLQB will only set this flag on the head
page; SLOB will not flag it at all.
10. BUDDY
=====================================
0 - LOCKED
page is being locked for exclusive access, eg. by undergoing read/write IO
7 - SLAB
page is managed by the SLAB/SLOB/SLUB/SLQB kernel memory allocator
When compound page is used, SLUB/SLQB will only set this flag on the head
page; SLOB will not flag it at all.
10 - BUDDY
a free memory block managed by the buddy system allocator
The buddy system organizes free memory in blocks of various orders.
An order N block has 2^N physically contiguous pages, with the BUDDY flag
set for and _only_ for the first page.
15. COMPOUND_HEAD
16. COMPOUND_TAIL
15 - COMPOUND_HEAD
A compound page with order N consists of 2^N physically contiguous pages.
A compound page with order 2 takes the form of "HTTT", where H donates its
head page and T donates its tail page(s). The major consumers of compound
pages are hugeTLB pages (Documentation/vm/hugetlbpage.txt), the SLUB etc.
pages are hugeTLB pages (Documentation/vm/hugetlbpage.rst), the SLUB etc.
memory allocators and various device drivers. However in this interface,
only huge/giga pages are made visible to end users.
17. HUGE
16 - COMPOUND_TAIL
A compound page tail (see description above).
17 - HUGE
this is an integral part of a HugeTLB page
19. HWPOISON
19 - HWPOISON
hardware detected memory corruption on this page: don't touch the data!
20. NOPAGE
20 - NOPAGE
no page frame exists at the requested address
21. KSM
21 - KSM
identical memory pages dynamically shared between one or more processes
22. THP
22 - THP
contiguous pages which construct transparent hugepages
23. BALLOON
23 - BALLOON
balloon compaction page
24. ZERO_PAGE
24 - ZERO_PAGE
zero page for pfn_zero or huge_zero page
25. IDLE
25 - IDLE
page has not been accessed since it was marked idle (see
Documentation/vm/idle_page_tracking.txt). Note that this flag may be
Documentation/vm/idle_page_tracking.rst). Note that this flag may be
stale in case the page was accessed via a PTE. To make sure the flag
is up-to-date one has to read /sys/kernel/mm/page_idle/bitmap first.
[IO related page flags]
1. ERROR IO error occurred
3. UPTODATE page has up-to-date data
ie. for file backed page: (in-memory data revision >= on-disk one)
4. DIRTY page has been written to, hence contains new data
ie. for file backed page: (in-memory data revision > on-disk one)
8. WRITEBACK page is being synced to disk
[LRU related page flags]
5. LRU page is in one of the LRU lists
6. ACTIVE page is in the active LRU list
18. UNEVICTABLE page is in the unevictable (non-)LRU list
It is somehow pinned and not a candidate for LRU page reclaims,
eg. ramfs pages, shmctl(SHM_LOCK) and mlock() memory segments
2. REFERENCED page has been referenced since last LRU list enqueue/requeue
9. RECLAIM page will be reclaimed soon after its pageout IO completed
11. MMAP a memory mapped page
12. ANON a memory mapped page that is not part of a file
13. SWAPCACHE page is mapped to swap space, ie. has an associated swap entry
14. SWAPBACKED page is backed by swap/RAM
is up-to-date one has to read ``/sys/kernel/mm/page_idle/bitmap`` first.
IO related page flags
---------------------
1 - ERROR
IO error occurred
3 - UPTODATE
page has up-to-date data
ie. for file backed page: (in-memory data revision >= on-disk one)
4 - DIRTY
page has been written to, hence contains new data
ie. for file backed page: (in-memory data revision > on-disk one)
8 - WRITEBACK
page is being synced to disk
LRU related page flags
----------------------
5 - LRU
page is in one of the LRU lists
6 - ACTIVE
page is in the active LRU list
18 - UNEVICTABLE
page is in the unevictable (non-)LRU list It is somehow pinned and
not a candidate for LRU page reclaims, eg. ramfs pages,
shmctl(SHM_LOCK) and mlock() memory segments
2 - REFERENCED
page has been referenced since last LRU list enqueue/requeue
9 - RECLAIM
page will be reclaimed soon after its pageout IO completed
11 - MMAP
a memory mapped page
12 - ANON
a memory mapped page that is not part of a file
13 - SWAPCACHE
page is mapped to swap space, ie. has an associated swap entry
14 - SWAPBACKED
page is backed by swap/RAM
The page-types tool in the tools/vm directory can be used to query the
above flags.
Using pagemap to do something useful:
Using pagemap to do something useful
====================================
The general procedure for using pagemap to find out about a process' memory
usage goes like this:
1. Read /proc/pid/maps to determine which parts of the memory space are
1. Read ``/proc/pid/maps`` to determine which parts of the memory space are
mapped to what.
2. Select the maps you are interested in -- all of them, or a particular
library, or the stack or the heap, etc.
3. Open /proc/pid/pagemap and seek to the pages you would like to examine.
3. Open ``/proc/pid/pagemap`` and seek to the pages you would like to examine.
4. Read a u64 for each page from pagemap.
5. Open /proc/kpagecount and/or /proc/kpageflags. For each PFN you just
read, seek to that entry in the file, and read the data you want.
5. Open ``/proc/kpagecount`` and/or ``/proc/kpageflags``. For each PFN you
just read, seek to that entry in the file, and read the data you want.
For example, to find the "unique set size" (USS), which is the amount of
memory that a process is using that is not shared with any other process,
......@@ -171,7 +184,8 @@ you can go through every map in the process, find the PFNs, look those up
in kpagecount, and tally up the number of pages that are only referenced
once.
Other notes:
Other notes
===========
Reading from any of the files will return -EINVAL if you are not starting
the read on an 8-byte boundary (e.g., if you sought an odd number of bytes
......
.. _remap_file_pages:
==============================
remap_file_pages() system call
==============================
The remap_file_pages() system call is used to create a nonlinear mapping,
that is, a mapping in which the pages of the file are mapped into a
nonsequential order in memory. The advantage of using remap_file_pages()
......
SOFT-DIRTY PTEs
.. _soft_dirty:
The soft-dirty is a bit on a PTE which helps to track which pages a task
===============
Soft-Dirty PTEs
===============
The soft-dirty is a bit on a PTE which helps to track which pages a task
writes to. In order to do this tracking one should
1. Clear soft-dirty bits from the task's PTEs.
This is done by writing "4" into the /proc/PID/clear_refs file of the
This is done by writing "4" into the ``/proc/PID/clear_refs`` file of the
task in question.
2. Wait some time.
3. Read soft-dirty bits from the PTEs.
This is done by reading from the /proc/PID/pagemap. The bit 55 of the
This is done by reading from the ``/proc/PID/pagemap``. The bit 55 of the
64-bit qword is the soft-dirty one. If set, the respective PTE was
written to since step 1.
Internally, to do this tracking, the writable bit is cleared from PTEs
Internally, to do this tracking, the writable bit is cleared from PTEs
when the soft-dirty bit is cleared. So, after this, when the task tries to
modify a page at some virtual address the #PF occurs and the kernel sets
the soft-dirty bit on the respective PTE.
Note, that although all the task's address space is marked as r/o after the
Note, that although all the task's address space is marked as r/o after the
soft-dirty bits clear, the #PF-s that occur after that are processed fast.
This is so, since the pages are still mapped to physical memory, and thus all
the kernel does is finds this fact out and puts both writable and soft-dirty
bits on the PTE.
While in most cases tracking memory changes by #PF-s is more than enough
While in most cases tracking memory changes by #PF-s is more than enough
there is still a scenario when we can lose soft dirty bits -- a task
unmaps a previously mapped memory region and then maps a new one at exactly
the same place. When unmap is called, the kernel internally clears PTE values
......@@ -36,7 +40,7 @@ including soft dirty bits. To notify user space application about such
memory region renewal the kernel always marks new memory regions (and
expanded regions) as soft dirty.
This feature is actively used by the checkpoint-restore project. You
This feature is actively used by the checkpoint-restore project. You
can find more details about it on http://criu.org
......
.. _split_page_table_lock:
=====================
Split page table lock
=====================
......@@ -11,6 +14,7 @@ access to the table. At the moment we use split lock for PTE and PMD
tables. Access to higher level tables protected by mm->page_table_lock.
There are helpers to lock/unlock a table and other accessor functions:
- pte_offset_map_lock()
maps pte and takes PTE table lock, returns pointer to the taken
lock;
......@@ -34,12 +38,13 @@ Split page table lock for PMD tables is enabled, if it's enabled for PTE
tables and the architecture supports it (see below).
Hugetlb and split page table lock
---------------------------------
=================================
Hugetlb can support several page sizes. We use split lock only for PMD
level, but not for PUD.
Hugetlb-specific helpers:
- huge_pte_lock()
takes pmd split lock for PMD_SIZE page, mm->page_table_lock
otherwise;
......@@ -47,7 +52,7 @@ Hugetlb-specific helpers:
returns pointer to table lock;
Support of split page table lock by an architecture
---------------------------------------------------
===================================================
There's no need in special enabling of PTE split page table lock:
everything required is done by pgtable_page_ctor() and pgtable_page_dtor(),
......@@ -73,7 +78,7 @@ NOTE: pgtable_page_ctor() and pgtable_pmd_page_ctor() can fail -- it must
be handled properly.
page->ptl
---------
=========
page->ptl is used to access split page table lock, where 'page' is struct
page of page containing the table. It shares storage with page->private
......@@ -81,6 +86,7 @@ page of page containing the table. It shares storage with page->private
To avoid increasing size of struct page and have best performance, we use a
trick:
- if spinlock_t fits into long, we use page->ptr as spinlock, so we
can avoid indirect access and save a cache line.
- if size of spinlock_t is bigger then size of long, we use page->ptl as
......
.. _swap_numa:
===========================================
Automatically bind swap device to numa node
-------------------------------------------
===========================================
If the system has more than one swap device and swap device has the node
information, we can make use of this information to decide which swap
......@@ -7,15 +10,16 @@ device to use in get_swap_pages() to get better performance.
How to use this feature
-----------------------
=======================
Swap device has priority and that decides the order of it to be used. To make
use of automatically binding, there is no need to manipulate priority settings
for swap devices. e.g. on a 2 node machine, assume 2 swap devices swapA and
swapB, with swapA attached to node 0 and swapB attached to node 1, are going
to be swapped on. Simply swapping them on by doing:
# swapon /dev/swapA
# swapon /dev/swapB
to be swapped on. Simply swapping them on by doing::
# swapon /dev/swapA
# swapon /dev/swapB
Then node 0 will use the two swap devices in the order of swapA then swapB and
node 1 will use the two swap devices in the order of swapB then swapA. Note
......@@ -24,32 +28,39 @@ that the order of them being swapped on doesn't matter.
A more complex example on a 4 node machine. Assume 6 swap devices are going to
be swapped on: swapA and swapB are attached to node 0, swapC is attached to
node 1, swapD and swapE are attached to node 2 and swapF is attached to node3.
The way to swap them on is the same as above:
# swapon /dev/swapA
# swapon /dev/swapB
# swapon /dev/swapC
# swapon /dev/swapD
# swapon /dev/swapE
# swapon /dev/swapF
Then node 0 will use them in the order of:
swapA/swapB -> swapC -> swapD -> swapE -> swapF
The way to swap them on is the same as above::
# swapon /dev/swapA
# swapon /dev/swapB
# swapon /dev/swapC
# swapon /dev/swapD
# swapon /dev/swapE
# swapon /dev/swapF
Then node 0 will use them in the order of::
swapA/swapB -> swapC -> swapD -> swapE -> swapF
swapA and swapB will be used in a round robin mode before any other swap device.
node 1 will use them in the order of:
swapC -> swapA -> swapB -> swapD -> swapE -> swapF
node 1 will use them in the order of::
swapC -> swapA -> swapB -> swapD -> swapE -> swapF
node 2 will use them in the order of::
swapD/swapE -> swapA -> swapB -> swapC -> swapF
node 2 will use them in the order of:
swapD/swapE -> swapA -> swapB -> swapC -> swapF
Similaly, swapD and swapE will be used in a round robin mode before any
other swap devices.
node 3 will use them in the order of:
swapF -> swapA -> swapB -> swapC -> swapD -> swapE
node 3 will use them in the order of::
swapF -> swapA -> swapB -> swapC -> swapD -> swapE
Implementation details
----------------------
======================
The current code uses a priority based list, swap_avail_list, to decide
which swap device to use and if multiple swap devices share the same
......
==============================
UNEVICTABLE LRU INFRASTRUCTURE
==============================
========
CONTENTS
========
(*) The Unevictable LRU
- The unevictable page list.
- Memory control group interaction.
- Marking address spaces unevictable.
- Detecting Unevictable Pages.
- vmscan's handling of unevictable pages.
(*) mlock()'d pages.
- History.
- Basic management.
- mlock()/mlockall() system call handling.
- Filtering special vmas.
- munlock()/munlockall() system call handling.
- Migrating mlocked pages.
- Compacting mlocked pages.
- mmap(MAP_LOCKED) system call handling.
- munmap()/exit()/exec() system call handling.
- try_to_unmap().
- try_to_munlock() reverse map scan.
- Page reclaim in shrink_*_list().
.. _unevictable_lru:
==============================
Unevictable LRU Infrastructure
==============================
============
INTRODUCTION
.. contents:: :local:
Introduction
============
This document describes the Linux memory manager's "Unevictable LRU"
......@@ -46,8 +22,8 @@ details - the "what does it do?" - by reading the code. One hopes that the
descriptions below add value by provide the answer to "why does it do that?".
===================
THE UNEVICTABLE LRU
The Unevictable LRU
===================
The Unevictable LRU facility adds an additional LRU list to track unevictable
......@@ -66,17 +42,17 @@ completely unresponsive.
The unevictable list addresses the following classes of unevictable pages:
(*) Those owned by ramfs.
* Those owned by ramfs.
(*) Those mapped into SHM_LOCK'd shared memory regions.
* Those mapped into SHM_LOCK'd shared memory regions.
(*) Those mapped into VM_LOCKED [mlock()ed] VMAs.
* Those mapped into VM_LOCKED [mlock()ed] VMAs.
The infrastructure may also be able to handle other conditions that make pages
unevictable, either by definition or by circumstance, in the future.
THE UNEVICTABLE PAGE LIST
The Unevictable Page List
-------------------------
The Unevictable LRU infrastructure consists of an additional, per-zone, LRU list
......@@ -118,7 +94,7 @@ the unevictable list when one task has the page isolated from the LRU and other
tasks are changing the "evictability" state of the page.
MEMORY CONTROL GROUP INTERACTION
Memory Control Group Interaction
--------------------------------
The unevictable LRU facility interacts with the memory control group [aka
......@@ -144,7 +120,9 @@ effects:
the control group to thrash or to OOM-kill tasks.
MARKING ADDRESS SPACES UNEVICTABLE
.. _mark_addr_space_unevict:
Marking Address Spaces Unevictable
----------------------------------
For facilities such as ramfs none of the pages attached to the address space
......@@ -152,15 +130,15 @@ may be evicted. To prevent eviction of any such pages, the AS_UNEVICTABLE
address space flag is provided, and this can be manipulated by a filesystem
using a number of wrapper functions:
(*) void mapping_set_unevictable(struct address_space *mapping);
* ``void mapping_set_unevictable(struct address_space *mapping);``
Mark the address space as being completely unevictable.
(*) void mapping_clear_unevictable(struct address_space *mapping);
* ``void mapping_clear_unevictable(struct address_space *mapping);``
Mark the address space as being evictable.
(*) int mapping_unevictable(struct address_space *mapping);
* ``int mapping_unevictable(struct address_space *mapping);``
Query the address space, and return true if it is completely
unevictable.
......@@ -177,12 +155,13 @@ These are currently used in two places in the kernel:
ensure they're in memory.
DETECTING UNEVICTABLE PAGES
Detecting Unevictable Pages
---------------------------
The function page_evictable() in vmscan.c determines whether a page is
evictable or not using the query function outlined above [see section "Marking
address spaces unevictable"] to check the AS_UNEVICTABLE flag.
evictable or not using the query function outlined above [see section
:ref:`Marking address spaces unevictable <mark_addr_space_unevict>`]
to check the AS_UNEVICTABLE flag.
For address spaces that are so marked after being populated (as SHM regions
might be), the lock action (eg: SHM_LOCK) can be lazy, and need not populate
......@@ -202,7 +181,7 @@ flag, PG_mlocked (as wrapped by PageMlocked()), which is set when a page is
faulted into a VM_LOCKED vma, or found in a vma being VM_LOCKED.
VMSCAN'S HANDLING OF UNEVICTABLE PAGES
Vmscan's Handling of Unevictable Pages
--------------------------------------
If unevictable pages are culled in the fault path, or moved to the unevictable
......@@ -233,8 +212,7 @@ extra evictabilty checks should not occur in the majority of calls to
putback_lru_page().
=============
MLOCKED PAGES
MLOCKED Pages
=============
The unevictable page list is also useful for mlock(), in addition to ramfs and
......@@ -242,7 +220,7 @@ SYSV SHM. Note that mlock() is only available in CONFIG_MMU=y situations; in
NOMMU situations, all mappings are effectively mlocked.
HISTORY
History
-------
The "Unevictable mlocked Pages" infrastructure is based on work originally
......@@ -263,7 +241,7 @@ replaced by walking the reverse map to determine whether any VM_LOCKED VMAs
mapped the page. More on this below.
BASIC MANAGEMENT
Basic Management
----------------
mlocked pages - pages mapped into a VM_LOCKED VMA - are a class of unevictable
......@@ -304,10 +282,10 @@ mlocked pages become unlocked and rescued from the unevictable list when:
(4) before a page is COW'd in a VM_LOCKED VMA.
mlock()/mlockall() SYSTEM CALL HANDLING
mlock()/mlockall() System Call Handling
---------------------------------------
Both [do_]mlock() and [do_]mlockall() system call handlers call mlock_fixup()
Both [do\_]mlock() and [do\_]mlockall() system call handlers call mlock_fixup()
for each VMA in the range specified by the call. In the case of mlockall(),
this is the entire active address space of the task. Note that mlock_fixup()
is used for both mlocking and munlocking a range of memory. A call to mlock()
......@@ -351,7 +329,7 @@ mlock_vma_page() is unable to isolate the page from the LRU, vmscan will handle
it later if and when it attempts to reclaim the page.
FILTERING SPECIAL VMAS
Filtering Special VMAs
----------------------
mlock_fixup() filters several classes of "special" VMAs:
......@@ -379,8 +357,9 @@ VM_LOCKED flag. Therefore, we won't have to deal with them later during
munlock(), munmap() or task exit. Neither does mlock_fixup() account these
VMAs against the task's "locked_vm".
.. _munlock_munlockall_handling:
munlock()/munlockall() SYSTEM CALL HANDLING
munlock()/munlockall() System Call Handling
-------------------------------------------
The munlock() and munlockall() system calls are handled by the same functions -
......@@ -426,7 +405,7 @@ This is fine, because we'll catch it later if and if vmscan tries to reclaim
the page. This should be relatively rare.
MIGRATING MLOCKED PAGES
Migrating MLOCKED Pages
-----------------------
A page that is being migrated has been isolated from the LRU lists and is held
......@@ -451,7 +430,7 @@ list because of a race between munlock and migration, page migration uses the
putback_lru_page() function to add migrated pages back to the LRU.
COMPACTING MLOCKED PAGES
Compacting MLOCKED Pages
------------------------
The unevictable LRU can be scanned for compactable regions and the default
......@@ -461,7 +440,7 @@ unevictable LRU is enabled, the work of compaction is mostly handled by
the page migration code and the same work flow as described in MIGRATING
MLOCKED PAGES will apply.
MLOCKING TRANSPARENT HUGE PAGES
MLOCKING Transparent Huge Pages
-------------------------------
A transparent huge page is represented by a single entry on an LRU list.
......@@ -483,7 +462,7 @@ to unevictable LRU and the rest can be reclaimed.
See also comment in follow_trans_huge_pmd().
mmap(MAP_LOCKED) SYSTEM CALL HANDLING
mmap(MAP_LOCKED) System Call Handling
-------------------------------------
In addition the mlock()/mlockall() system calls, an application can request
......@@ -514,7 +493,7 @@ memory range accounted as locked_vm, as the protections could be changed later
and pages allocated into that region.
munmap()/exit()/exec() SYSTEM CALL HANDLING
munmap()/exit()/exec() System Call Handling
-------------------------------------------
When unmapping an mlocked region of memory, whether by an explicit call to
......@@ -568,16 +547,18 @@ munlock or munmap system calls, mm teardown (munlock_vma_pages_all), reclaim,
holepunching, and truncation of file pages and their anonymous COWed pages.
try_to_munlock() REVERSE MAP SCAN
try_to_munlock() Reverse Map Scan
---------------------------------
[!] TODO/FIXME: a better name might be page_mlocked() - analogous to the
page_referenced() reverse map walker.
.. warning::
[!] TODO/FIXME: a better name might be page_mlocked() - analogous to the
page_referenced() reverse map walker.
When munlock_vma_page() [see section "munlock()/munlockall() System Call
Handling" above] tries to munlock a page, it needs to determine whether or not
the page is mapped by any VM_LOCKED VMA without actually attempting to unmap
all PTEs from the page. For this purpose, the unevictable/mlock infrastructure
When munlock_vma_page() [see section :ref:`munlock()/munlockall() System Call
Handling <munlock_munlockall_handling>` above] tries to munlock a
page, it needs to determine whether or not the page is mapped by any
VM_LOCKED VMA without actually attempting to unmap all PTEs from the
page. For this purpose, the unevictable/mlock infrastructure
introduced a variant of try_to_unmap() called try_to_munlock().
try_to_munlock() calls the same functions as try_to_unmap() for anonymous and
......@@ -595,7 +576,7 @@ large region or tearing down a large address space that has been mlocked via
mlockall(), overall this is a fairly rare event.
PAGE RECLAIM IN shrink_*_list()
Page Reclaim in shrink_*_list()
-------------------------------
shrink_active_list() culls any obviously unevictable pages - i.e.
......
.. _z3fold:
======
z3fold
------
======
z3fold is a special purpose allocator for storing compressed pages.
It is designed to store up to three compressed pages per physical page.
......@@ -7,6 +10,7 @@ It is a zbud derivative which allows for higher compression
ratio keeping the simplicity and determinism of its predecessor.
The main differences between z3fold and zbud are:
* unlike zbud, z3fold allows for up to PAGE_SIZE allocations
* z3fold can hold up to 3 compressed pages in its page
* z3fold doesn't export any API itself and is thus intended to be used
......
......@@ -15621,7 +15621,7 @@ L: linux-mm@kvack.org
S: Maintained
F: mm/zsmalloc.c
F: include/linux/zsmalloc.h
F: Documentation/vm/zsmalloc.txt
F: Documentation/vm/zsmalloc.rst
ZSWAP COMPRESSED SWAP CACHING
M: Seth Jennings <sjenning@redhat.com>
......
......@@ -585,7 +585,7 @@ config ARCH_DISCONTIGMEM_ENABLE
Say Y to support efficient handling of discontiguous physical memory,
for architectures which are either NUMA (Non-Uniform Memory Access)
or have huge holes in the physical address space for other reasons.
See <file:Documentation/vm/numa> for more.
See <file:Documentation/vm/numa.rst> for more.
source "mm/Kconfig"
......
......@@ -397,7 +397,7 @@ config ARCH_DISCONTIGMEM_ENABLE
Say Y to support efficient handling of discontiguous physical memory,
for architectures which are either NUMA (Non-Uniform Memory Access)
or have huge holes in the physical address space for other reasons.
See <file:Documentation/vm/numa> for more.
See <file:Documentation/vm/numa.rst> for more.
config ARCH_FLATMEM_ENABLE
def_bool y
......
......@@ -2556,7 +2556,7 @@ config ARCH_DISCONTIGMEM_ENABLE
Say Y to support efficient handling of discontiguous physical memory,
for architectures which are either NUMA (Non-Uniform Memory Access)
or have huge holes in the physical address space for other reasons.
See <file:Documentation/vm/numa> for more.
See <file:Documentation/vm/numa.rst> for more.
config ARCH_SPARSEMEM_ENABLE
bool
......
......@@ -883,7 +883,7 @@ config PPC_MEM_KEYS
page-based protections, but without requiring modification of the
page tables when an application changes protection domains.
For details, see Documentation/vm/protection-keys.txt
For details, see Documentation/vm/protection-keys.rst
If unsure, say y.
......
......@@ -196,7 +196,7 @@ config HUGETLBFS
help
hugetlbfs is a filesystem backing for HugeTLB pages, based on
ramfs. For architectures that support it, say Y here and read
<file:Documentation/vm/hugetlbpage.txt> for details.
<file:Documentation/vm/hugetlbpage.rst> for details.
If unsure, say N.
......
......@@ -677,7 +677,7 @@ static void dax_mapping_entry_mkclean(struct address_space *mapping,
* downgrading page table protection not changing it to point
* to a new page.
*
* See Documentation/vm/mmu_notifier.txt
* See Documentation/vm/mmu_notifier.rst
*/
if (pmdp) {
#ifdef CONFIG_FS_DAX_PMD
......
此差异已折叠。
......@@ -16,7 +16,7 @@
/*
* Heterogeneous Memory Management (HMM)
*
* See Documentation/vm/hmm.txt for reasons and overview of what HMM is and it
* See Documentation/vm/hmm.rst for reasons and overview of what HMM is and it
* is for. Here we focus on the HMM API description, with some explanation of
* the underlying implementation.
*
......
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