555 lines
26 KiB
ReStructuredText
555 lines
26 KiB
ReStructuredText
.. _unevictable_lru:
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==============================
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Unevictable LRU Infrastructure
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==============================
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.. contents:: :local:
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Introduction
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============
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This document describes the Linux memory manager's "Unevictable LRU"
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infrastructure and the use of this to manage several types of "unevictable"
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pages.
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The document attempts to provide the overall rationale behind this mechanism
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and the rationale for some of the design decisions that drove the
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implementation. The latter design rationale is discussed in the context of an
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implementation description. Admittedly, one can obtain the implementation
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details - the "what does it do?" - by reading the code. One hopes that the
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descriptions below add value by provide the answer to "why does it do that?".
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The Unevictable LRU
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===================
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The Unevictable LRU facility adds an additional LRU list to track unevictable
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pages and to hide these pages from vmscan. This mechanism is based on a patch
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by Larry Woodman of Red Hat to address several scalability problems with page
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reclaim in Linux. The problems have been observed at customer sites on large
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memory x86_64 systems.
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To illustrate this with an example, a non-NUMA x86_64 platform with 128GB of
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main memory will have over 32 million 4k pages in a single node. When a large
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fraction of these pages are not evictable for any reason [see below], vmscan
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will spend a lot of time scanning the LRU lists looking for the small fraction
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of pages that are evictable. This can result in a situation where all CPUs are
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spending 100% of their time in vmscan for hours or days on end, with the system
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completely unresponsive.
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The unevictable list addresses the following classes of unevictable pages:
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* Those owned by ramfs.
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* Those mapped into SHM_LOCK'd shared memory regions.
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* Those mapped into VM_LOCKED [mlock()ed] VMAs.
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The infrastructure may also be able to handle other conditions that make pages
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unevictable, either by definition or by circumstance, in the future.
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The Unevictable LRU Page List
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-----------------------------
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The Unevictable LRU page list is a lie. It was never an LRU-ordered list, but a
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companion to the LRU-ordered anonymous and file, active and inactive page lists;
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and now it is not even a page list. But following familiar convention, here in
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this document and in the source, we often imagine it as a fifth LRU page list.
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The Unevictable LRU infrastructure consists of an additional, per-node, LRU list
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called the "unevictable" list and an associated page flag, PG_unevictable, to
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indicate that the page is being managed on the unevictable list.
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The PG_unevictable flag is analogous to, and mutually exclusive with, the
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PG_active flag in that it indicates on which LRU list a page resides when
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PG_lru is set.
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The Unevictable LRU infrastructure maintains unevictable pages as if they were
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on an additional LRU list for a few reasons:
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(1) We get to "treat unevictable pages just like we treat other pages in the
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system - which means we get to use the same code to manipulate them, the
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same code to isolate them (for migrate, etc.), the same code to keep track
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of the statistics, etc..." [Rik van Riel]
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(2) We want to be able to migrate unevictable pages between nodes for memory
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defragmentation, workload management and memory hotplug. The Linux kernel
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can only migrate pages that it can successfully isolate from the LRU
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lists (or "Movable" pages: outside of consideration here). If we were to
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maintain pages elsewhere than on an LRU-like list, where they can be
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detected by isolate_lru_page(), we would prevent their migration.
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The unevictable list does not differentiate between file-backed and anonymous,
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swap-backed pages. This differentiation is only important while the pages are,
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in fact, evictable.
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The unevictable list benefits from the "arrayification" of the per-node LRU
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lists and statistics originally proposed and posted by Christoph Lameter.
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Memory Control Group Interaction
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--------------------------------
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The unevictable LRU facility interacts with the memory control group [aka
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memory controller; see Documentation/admin-guide/cgroup-v1/memory.rst] by
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extending the lru_list enum.
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The memory controller data structure automatically gets a per-node unevictable
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list as a result of the "arrayification" of the per-node LRU lists (one per
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lru_list enum element). The memory controller tracks the movement of pages to
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and from the unevictable list.
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When a memory control group comes under memory pressure, the controller will
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not attempt to reclaim pages on the unevictable list. This has a couple of
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effects:
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(1) Because the pages are "hidden" from reclaim on the unevictable list, the
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reclaim process can be more efficient, dealing only with pages that have a
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chance of being reclaimed.
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(2) On the other hand, if too many of the pages charged to the control group
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are unevictable, the evictable portion of the working set of the tasks in
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the control group may not fit into the available memory. This can cause
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the control group to thrash or to OOM-kill tasks.
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.. _mark_addr_space_unevict:
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Marking Address Spaces Unevictable
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----------------------------------
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For facilities such as ramfs none of the pages attached to the address space
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may be evicted. To prevent eviction of any such pages, the AS_UNEVICTABLE
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address space flag is provided, and this can be manipulated by a filesystem
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using a number of wrapper functions:
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* ``void mapping_set_unevictable(struct address_space *mapping);``
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Mark the address space as being completely unevictable.
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* ``void mapping_clear_unevictable(struct address_space *mapping);``
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Mark the address space as being evictable.
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* ``int mapping_unevictable(struct address_space *mapping);``
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Query the address space, and return true if it is completely
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unevictable.
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These are currently used in three places in the kernel:
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(1) By ramfs to mark the address spaces of its inodes when they are created,
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and this mark remains for the life of the inode.
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(2) By SYSV SHM to mark SHM_LOCK'd address spaces until SHM_UNLOCK is called.
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Note that SHM_LOCK is not required to page in the locked pages if they're
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swapped out; the application must touch the pages manually if it wants to
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ensure they're in memory.
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(3) By the i915 driver to mark pinned address space until it's unpinned. The
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amount of unevictable memory marked by i915 driver is roughly the bounded
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object size in debugfs/dri/0/i915_gem_objects.
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Detecting Unevictable Pages
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---------------------------
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The function page_evictable() in mm/internal.h determines whether a page is
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evictable or not using the query function outlined above [see section
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:ref:`Marking address spaces unevictable <mark_addr_space_unevict>`]
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to check the AS_UNEVICTABLE flag.
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For address spaces that are so marked after being populated (as SHM regions
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might be), the lock action (e.g. SHM_LOCK) can be lazy, and need not populate
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the page tables for the region as does, for example, mlock(), nor need it make
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any special effort to push any pages in the SHM_LOCK'd area to the unevictable
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list. Instead, vmscan will do this if and when it encounters the pages during
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a reclamation scan.
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On an unlock action (such as SHM_UNLOCK), the unlocker (e.g. shmctl()) must scan
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the pages in the region and "rescue" them from the unevictable list if no other
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condition is keeping them unevictable. If an unevictable region is destroyed,
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the pages are also "rescued" from the unevictable list in the process of
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freeing them.
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page_evictable() also checks for mlocked pages by testing an additional page
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flag, PG_mlocked (as wrapped by PageMlocked()), which is set when a page is
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faulted into a VM_LOCKED VMA, or found in a VMA being VM_LOCKED.
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Vmscan's Handling of Unevictable Pages
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--------------------------------------
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If unevictable pages are culled in the fault path, or moved to the unevictable
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list at mlock() or mmap() time, vmscan will not encounter the pages until they
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have become evictable again (via munlock() for example) and have been "rescued"
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from the unevictable list. However, there may be situations where we decide,
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for the sake of expediency, to leave an unevictable page on one of the regular
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active/inactive LRU lists for vmscan to deal with. vmscan checks for such
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pages in all of the shrink_{active|inactive|page}_list() functions and will
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"cull" such pages that it encounters: that is, it diverts those pages to the
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unevictable list for the memory cgroup and node being scanned.
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There may be situations where a page is mapped into a VM_LOCKED VMA, but the
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page is not marked as PG_mlocked. Such pages will make it all the way to
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shrink_active_list() or shrink_page_list() where they will be detected when
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vmscan walks the reverse map in page_referenced() or try_to_unmap(). The page
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is culled to the unevictable list when it is released by the shrinker.
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To "cull" an unevictable page, vmscan simply puts the page back on the LRU list
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using putback_lru_page() - the inverse operation to isolate_lru_page() - after
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dropping the page lock. Because the condition which makes the page unevictable
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may change once the page is unlocked, __pagevec_lru_add_fn() will recheck the
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unevictable state of a page before placing it on the unevictable list.
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MLOCKED Pages
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=============
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The unevictable page list is also useful for mlock(), in addition to ramfs and
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SYSV SHM. Note that mlock() is only available in CONFIG_MMU=y situations; in
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NOMMU situations, all mappings are effectively mlocked.
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History
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-------
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The "Unevictable mlocked Pages" infrastructure is based on work originally
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posted by Nick Piggin in an RFC patch entitled "mm: mlocked pages off LRU".
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Nick posted his patch as an alternative to a patch posted by Christoph Lameter
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to achieve the same objective: hiding mlocked pages from vmscan.
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In Nick's patch, he used one of the struct page LRU list link fields as a count
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of VM_LOCKED VMAs that map the page (Rik van Riel had the same idea three years
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earlier). But this use of the link field for a count prevented the management
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of the pages on an LRU list, and thus mlocked pages were not migratable as
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isolate_lru_page() could not detect them, and the LRU list link field was not
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available to the migration subsystem.
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Nick resolved this by putting mlocked pages back on the LRU list before
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attempting to isolate them, thus abandoning the count of VM_LOCKED VMAs. When
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Nick's patch was integrated with the Unevictable LRU work, the count was
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replaced by walking the reverse map when munlocking, to determine whether any
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other VM_LOCKED VMAs still mapped the page.
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However, walking the reverse map for each page when munlocking was ugly and
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inefficient, and could lead to catastrophic contention on a file's rmap lock,
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when many processes which had it mlocked were trying to exit. In 5.18, the
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idea of keeping mlock_count in Unevictable LRU list link field was revived and
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put to work, without preventing the migration of mlocked pages. This is why
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the "Unevictable LRU list" cannot be a linked list of pages now; but there was
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no use for that linked list anyway - though its size is maintained for meminfo.
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Basic Management
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----------------
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mlocked pages - pages mapped into a VM_LOCKED VMA - are a class of unevictable
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pages. When such a page has been "noticed" by the memory management subsystem,
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the page is marked with the PG_mlocked flag. This can be manipulated using the
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PageMlocked() functions.
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A PG_mlocked page will be placed on the unevictable list when it is added to
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the LRU. Such pages can be "noticed" by memory management in several places:
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(1) in the mlock()/mlock2()/mlockall() system call handlers;
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(2) in the mmap() system call handler when mmapping a region with the
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MAP_LOCKED flag;
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(3) mmapping a region in a task that has called mlockall() with the MCL_FUTURE
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flag;
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(4) in the fault path and when a VM_LOCKED stack segment is expanded; or
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(5) as mentioned above, in vmscan:shrink_page_list() when attempting to
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reclaim a page in a VM_LOCKED VMA by page_referenced() or try_to_unmap().
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mlocked pages become unlocked and rescued from the unevictable list when:
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(1) mapped in a range unlocked via the munlock()/munlockall() system calls;
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(2) munmap()'d out of the last VM_LOCKED VMA that maps the page, including
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unmapping at task exit;
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(3) when the page is truncated from the last VM_LOCKED VMA of an mmapped file;
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or
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(4) before a page is COW'd in a VM_LOCKED VMA.
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mlock()/mlock2()/mlockall() System Call Handling
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------------------------------------------------
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mlock(), mlock2() and mlockall() system call handlers proceed to mlock_fixup()
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for each VMA in the range specified by the call. In the case of mlockall(),
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this is the entire active address space of the task. Note that mlock_fixup()
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is used for both mlocking and munlocking a range of memory. A call to mlock()
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an already VM_LOCKED VMA, or to munlock() a VMA that is not VM_LOCKED, is
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treated as a no-op and mlock_fixup() simply returns.
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If the VMA passes some filtering as described in "Filtering Special VMAs"
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below, mlock_fixup() will attempt to merge the VMA with its neighbors or split
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off a subset of the VMA if the range does not cover the entire VMA. Any pages
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already present in the VMA are then marked as mlocked by mlock_page() via
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mlock_pte_range() via walk_page_range() via mlock_vma_pages_range().
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Before returning from the system call, do_mlock() or mlockall() will call
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__mm_populate() to fault in the remaining pages via get_user_pages() and to
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mark those pages as mlocked as they are faulted.
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Note that the VMA being mlocked might be mapped with PROT_NONE. In this case,
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get_user_pages() will be unable to fault in the pages. That's okay. If pages
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do end up getting faulted into this VM_LOCKED VMA, they will be handled in the
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fault path - which is also how mlock2()'s MLOCK_ONFAULT areas are handled.
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For each PTE (or PMD) being faulted into a VMA, the page add rmap function
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calls mlock_vma_page(), which calls mlock_page() when the VMA is VM_LOCKED
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(unless it is a PTE mapping of a part of a transparent huge page). Or when
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it is a newly allocated anonymous page, lru_cache_add_inactive_or_unevictable()
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calls mlock_new_page() instead: similar to mlock_page(), but can make better
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judgments, since this page is held exclusively and known not to be on LRU yet.
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mlock_page() sets PageMlocked immediately, then places the page on the CPU's
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mlock pagevec, to batch up the rest of the work to be done under lru_lock by
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__mlock_page(). __mlock_page() sets PageUnevictable, initializes mlock_count
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and moves the page to unevictable state ("the unevictable LRU", but with
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mlock_count in place of LRU threading). Or if the page was already PageLRU
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and PageUnevictable and PageMlocked, it simply increments the mlock_count.
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But in practice that may not work ideally: the page may not yet be on an LRU, or
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it may have been temporarily isolated from LRU. In such cases the mlock_count
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field cannot be touched, but will be set to 0 later when __pagevec_lru_add_fn()
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returns the page to "LRU". Races prohibit mlock_count from being set to 1 then:
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rather than risk stranding a page indefinitely as unevictable, always err with
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mlock_count on the low side, so that when munlocked the page will be rescued to
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an evictable LRU, then perhaps be mlocked again later if vmscan finds it in a
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VM_LOCKED VMA.
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Filtering Special VMAs
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----------------------
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mlock_fixup() filters several classes of "special" VMAs:
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1) VMAs with VM_IO or VM_PFNMAP set are skipped entirely. The pages behind
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these mappings are inherently pinned, so we don't need to mark them as
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mlocked. In any case, most of the pages have no struct page in which to so
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mark the page. Because of this, get_user_pages() will fail for these VMAs,
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so there is no sense in attempting to visit them.
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2) VMAs mapping hugetlbfs page are already effectively pinned into memory. We
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neither need nor want to mlock() these pages. But __mm_populate() includes
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hugetlbfs ranges, allocating the huge pages and populating the PTEs.
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3) VMAs with VM_DONTEXPAND are generally userspace mappings of kernel pages,
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such as the VDSO page, relay channel pages, etc. These pages are inherently
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unevictable and are not managed on the LRU lists. __mm_populate() includes
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these ranges, populating the PTEs if not already populated.
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4) VMAs with VM_MIXEDMAP set are not marked VM_LOCKED, but __mm_populate()
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includes these ranges, populating the PTEs if not already populated.
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Note that for all of these special VMAs, mlock_fixup() does not set the
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VM_LOCKED flag. Therefore, we won't have to deal with them later during
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munlock(), munmap() or task exit. Neither does mlock_fixup() account these
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VMAs against the task's "locked_vm".
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munlock()/munlockall() System Call Handling
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-------------------------------------------
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The munlock() and munlockall() system calls are handled by the same
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mlock_fixup() function as mlock(), mlock2() and mlockall() system calls are.
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If called to munlock an already munlocked VMA, mlock_fixup() simply returns.
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Because of the VMA filtering discussed above, VM_LOCKED will not be set in
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any "special" VMAs. So, those VMAs will be ignored for munlock.
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If the VMA is VM_LOCKED, mlock_fixup() again attempts to merge or split off the
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specified range. All pages in the VMA are then munlocked by munlock_page() via
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mlock_pte_range() via walk_page_range() via mlock_vma_pages_range() - the same
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function used when mlocking a VMA range, with new flags for the VMA indicating
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that it is munlock() being performed.
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munlock_page() uses the mlock pagevec to batch up work to be done under
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lru_lock by __munlock_page(). __munlock_page() decrements the page's
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mlock_count, and when that reaches 0 it clears PageMlocked and clears
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PageUnevictable, moving the page from unevictable state to inactive LRU.
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But in practice that may not work ideally: the page may not yet have reached
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"the unevictable LRU", or it may have been temporarily isolated from it. In
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those cases its mlock_count field is unusable and must be assumed to be 0: so
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that the page will be rescued to an evictable LRU, then perhaps be mlocked
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again later if vmscan finds it in a VM_LOCKED VMA.
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Migrating MLOCKED Pages
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-----------------------
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A page that is being migrated has been isolated from the LRU lists and is held
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locked across unmapping of the page, updating the page's address space entry
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and copying the contents and state, until the page table entry has been
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replaced with an entry that refers to the new page. Linux supports migration
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of mlocked pages and other unevictable pages. PG_mlocked is cleared from the
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the old page when it is unmapped from the last VM_LOCKED VMA, and set when the
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new page is mapped in place of migration entry in a VM_LOCKED VMA. If the page
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was unevictable because mlocked, PG_unevictable follows PG_mlocked; but if the
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page was unevictable for other reasons, PG_unevictable is copied explicitly.
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Note that page migration can race with mlocking or munlocking of the same page.
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There is mostly no problem since page migration requires unmapping all PTEs of
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the old page (including munlock where VM_LOCKED), then mapping in the new page
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(including mlock where VM_LOCKED). The page table locks provide sufficient
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synchronization.
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However, since mlock_vma_pages_range() starts by setting VM_LOCKED on a VMA,
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before mlocking any pages already present, if one of those pages were migrated
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before mlock_pte_range() reached it, it would get counted twice in mlock_count.
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To prevent that, mlock_vma_pages_range() temporarily marks the VMA as VM_IO,
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so that mlock_vma_page() will skip it.
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To complete page migration, we place the old and new pages back onto the LRU
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afterwards. The "unneeded" page - old page on success, new page on failure -
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is freed when the reference count held by the migration process is released.
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Compacting MLOCKED Pages
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------------------------
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The memory map can be scanned for compactable regions and the default behavior
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is to let unevictable pages be moved. /proc/sys/vm/compact_unevictable_allowed
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controls this behavior (see Documentation/admin-guide/sysctl/vm.rst). The work
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of compaction is mostly handled by the page migration code and the same work
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flow as described in Migrating MLOCKED Pages will apply.
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MLOCKING Transparent Huge Pages
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-------------------------------
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A transparent huge page is represented by a single entry on an LRU list.
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Therefore, we can only make unevictable an entire compound page, not
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individual subpages.
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If a user tries to mlock() part of a huge page, and no user mlock()s the
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whole of the huge page, we want the rest of the page to be reclaimable.
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We cannot just split the page on partial mlock() as split_huge_page() can
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fail and a new intermittent failure mode for the syscall is undesirable.
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|
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We handle this by keeping PTE-mlocked huge pages on evictable LRU lists:
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the PMD on the border of a VM_LOCKED VMA will be split into a PTE table.
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This way the huge page is accessible for vmscan. Under memory pressure the
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page will be split, subpages which belong to VM_LOCKED VMAs will be moved
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to the unevictable LRU and the rest can be reclaimed.
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/proc/meminfo's Unevictable and Mlocked amounts do not include those parts
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of a transparent huge page which are mapped only by PTEs in VM_LOCKED VMAs.
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mmap(MAP_LOCKED) System Call Handling
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|
-------------------------------------
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In addition to the mlock(), mlock2() and mlockall() system calls, an application
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can request that a region of memory be mlocked by supplying the MAP_LOCKED flag
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to the mmap() call. There is one important and subtle difference here, though.
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mmap() + mlock() will fail if the range cannot be faulted in (e.g. because
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mm_populate fails) and returns with ENOMEM while mmap(MAP_LOCKED) will not fail.
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The mmaped area will still have properties of the locked area - pages will not
|
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get swapped out - but major page faults to fault memory in might still happen.
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Furthermore, any mmap() call or brk() call that expands the heap by a task
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|
that has previously called mlockall() with the MCL_FUTURE flag will result
|
|
in the newly mapped memory being mlocked. Before the unevictable/mlock
|
|
changes, the kernel simply called make_pages_present() to allocate pages
|
|
and populate the page table.
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|
To mlock a range of memory under the unevictable/mlock infrastructure,
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the mmap() handler and task address space expansion functions call
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populate_vma_page_range() specifying the vma and the address range to mlock.
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munmap()/exit()/exec() System Call Handling
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|
-------------------------------------------
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When unmapping an mlocked region of memory, whether by an explicit call to
|
|
munmap() or via an internal unmap from exit() or exec() processing, we must
|
|
munlock the pages if we're removing the last VM_LOCKED VMA that maps the pages.
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|
Before the unevictable/mlock changes, mlocking did not mark the pages in any
|
|
way, so unmapping them required no processing.
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|
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|
For each PTE (or PMD) being unmapped from a VMA, page_remove_rmap() calls
|
|
munlock_vma_page(), which calls munlock_page() when the VMA is VM_LOCKED
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|
(unless it was a PTE mapping of a part of a transparent huge page).
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|
munlock_page() uses the mlock pagevec to batch up work to be done under
|
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lru_lock by __munlock_page(). __munlock_page() decrements the page's
|
|
mlock_count, and when that reaches 0 it clears PageMlocked and clears
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PageUnevictable, moving the page from unevictable state to inactive LRU.
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|
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|
But in practice that may not work ideally: the page may not yet have reached
|
|
"the unevictable LRU", or it may have been temporarily isolated from it. In
|
|
those cases its mlock_count field is unusable and must be assumed to be 0: so
|
|
that the page will be rescued to an evictable LRU, then perhaps be mlocked
|
|
again later if vmscan finds it in a VM_LOCKED VMA.
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|
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|
Truncating MLOCKED Pages
|
|
------------------------
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|
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|
File truncation or hole punching forcibly unmaps the deleted pages from
|
|
userspace; truncation even unmaps and deletes any private anonymous pages
|
|
which had been Copied-On-Write from the file pages now being truncated.
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|
|
|
Mlocked pages can be munlocked and deleted in this way: like with munmap(),
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|
for each PTE (or PMD) being unmapped from a VMA, page_remove_rmap() calls
|
|
munlock_vma_page(), which calls munlock_page() when the VMA is VM_LOCKED
|
|
(unless it was a PTE mapping of a part of a transparent huge page).
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|
|
|
However, if there is a racing munlock(), since mlock_vma_pages_range() starts
|
|
munlocking by clearing VM_LOCKED from a VMA, before munlocking all the pages
|
|
present, if one of those pages were unmapped by truncation or hole punch before
|
|
mlock_pte_range() reached it, it would not be recognized as mlocked by this VMA,
|
|
and would not be counted out of mlock_count. In this rare case, a page may
|
|
still appear as PageMlocked after it has been fully unmapped: and it is left to
|
|
release_pages() (or __page_cache_release()) to clear it and update statistics
|
|
before freeing (this event is counted in /proc/vmstat unevictable_pgs_cleared,
|
|
which is usually 0).
|
|
|
|
|
|
Page Reclaim in shrink_*_list()
|
|
-------------------------------
|
|
|
|
vmscan's shrink_active_list() culls any obviously unevictable pages -
|
|
i.e. !page_evictable(page) pages - diverting those to the unevictable list.
|
|
However, shrink_active_list() only sees unevictable pages that made it onto the
|
|
active/inactive LRU lists. Note that these pages do not have PageUnevictable
|
|
set - otherwise they would be on the unevictable list and shrink_active_list()
|
|
would never see them.
|
|
|
|
Some examples of these unevictable pages on the LRU lists are:
|
|
|
|
(1) ramfs pages that have been placed on the LRU lists when first allocated.
|
|
|
|
(2) SHM_LOCK'd shared memory pages. shmctl(SHM_LOCK) does not attempt to
|
|
allocate or fault in the pages in the shared memory region. This happens
|
|
when an application accesses the page the first time after SHM_LOCK'ing
|
|
the segment.
|
|
|
|
(3) pages still mapped into VM_LOCKED VMAs, which should be marked mlocked,
|
|
but events left mlock_count too low, so they were munlocked too early.
|
|
|
|
vmscan's shrink_inactive_list() and shrink_page_list() also divert obviously
|
|
unevictable pages found on the inactive lists to the appropriate memory cgroup
|
|
and node unevictable list.
|
|
|
|
rmap's page_referenced_one(), called via vmscan's shrink_active_list() or
|
|
shrink_page_list(), and rmap's try_to_unmap_one() called via shrink_page_list(),
|
|
check for (3) pages still mapped into VM_LOCKED VMAs, and call mlock_vma_page()
|
|
to correct them. Such pages are culled to the unevictable list when released
|
|
by the shrinker.
|