696 lines
28 KiB
ReStructuredText
696 lines
28 KiB
ReStructuredText
==================
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Memory Hot(Un)Plug
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==================
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This document describes generic Linux support for memory hot(un)plug with
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a focus on System RAM, including ZONE_MOVABLE support.
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.. contents:: :local:
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Introduction
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============
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Memory hot(un)plug allows for increasing and decreasing the size of physical
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memory available to a machine at runtime. In the simplest case, it consists of
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physically plugging or unplugging a DIMM at runtime, coordinated with the
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operating system.
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Memory hot(un)plug is used for various purposes:
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- The physical memory available to a machine can be adjusted at runtime, up- or
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downgrading the memory capacity. This dynamic memory resizing, sometimes
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referred to as "capacity on demand", is frequently used with virtual machines
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and logical partitions.
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- Replacing hardware, such as DIMMs or whole NUMA nodes, without downtime. One
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example is replacing failing memory modules.
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- Reducing energy consumption either by physically unplugging memory modules or
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by logically unplugging (parts of) memory modules from Linux.
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Further, the basic memory hot(un)plug infrastructure in Linux is nowadays also
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used to expose persistent memory, other performance-differentiated memory and
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reserved memory regions as ordinary system RAM to Linux.
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Linux only supports memory hot(un)plug on selected 64 bit architectures, such as
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x86_64, arm64, ppc64 and s390x.
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Memory Hot(Un)Plug Granularity
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------------------------------
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Memory hot(un)plug in Linux uses the SPARSEMEM memory model, which divides the
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physical memory address space into chunks of the same size: memory sections. The
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size of a memory section is architecture dependent. For example, x86_64 uses
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128 MiB and ppc64 uses 16 MiB.
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Memory sections are combined into chunks referred to as "memory blocks". The
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size of a memory block is architecture dependent and corresponds to the smallest
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granularity that can be hot(un)plugged. The default size of a memory block is
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the same as memory section size, unless an architecture specifies otherwise.
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All memory blocks have the same size.
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Phases of Memory Hotplug
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------------------------
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Memory hotplug consists of two phases:
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(1) Adding the memory to Linux
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(2) Onlining memory blocks
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In the first phase, metadata, such as the memory map ("memmap") and page tables
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for the direct mapping, is allocated and initialized, and memory blocks are
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created; the latter also creates sysfs files for managing newly created memory
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blocks.
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In the second phase, added memory is exposed to the page allocator. After this
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phase, the memory is visible in memory statistics, such as free and total
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memory, of the system.
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Phases of Memory Hotunplug
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--------------------------
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Memory hotunplug consists of two phases:
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(1) Offlining memory blocks
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(2) Removing the memory from Linux
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In the first phase, memory is "hidden" from the page allocator again, for
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example, by migrating busy memory to other memory locations and removing all
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relevant free pages from the page allocator After this phase, the memory is no
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longer visible in memory statistics of the system.
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In the second phase, the memory blocks are removed and metadata is freed.
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Memory Hotplug Notifications
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============================
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There are various ways how Linux is notified about memory hotplug events such
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that it can start adding hotplugged memory. This description is limited to
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systems that support ACPI; mechanisms specific to other firmware interfaces or
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virtual machines are not described.
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ACPI Notifications
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------------------
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Platforms that support ACPI, such as x86_64, can support memory hotplug
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notifications via ACPI.
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In general, a firmware supporting memory hotplug defines a memory class object
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HID "PNP0C80". When notified about hotplug of a new memory device, the ACPI
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driver will hotplug the memory to Linux.
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If the firmware supports hotplug of NUMA nodes, it defines an object _HID
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"ACPI0004", "PNP0A05", or "PNP0A06". When notified about an hotplug event, all
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assigned memory devices are added to Linux by the ACPI driver.
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Similarly, Linux can be notified about requests to hotunplug a memory device or
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a NUMA node via ACPI. The ACPI driver will try offlining all relevant memory
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blocks, and, if successful, hotunplug the memory from Linux.
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Manual Probing
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--------------
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On some architectures, the firmware may not be able to notify the operating
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system about a memory hotplug event. Instead, the memory has to be manually
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probed from user space.
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The probe interface is located at::
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/sys/devices/system/memory/probe
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Only complete memory blocks can be probed. Individual memory blocks are probed
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by providing the physical start address of the memory block::
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% echo addr > /sys/devices/system/memory/probe
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Which results in a memory block for the range [addr, addr + memory_block_size)
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being created.
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.. note::
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Using the probe interface is discouraged as it is easy to crash the kernel,
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because Linux cannot validate user input; this interface might be removed in
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the future.
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Onlining and Offlining Memory Blocks
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====================================
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After a memory block has been created, Linux has to be instructed to actually
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make use of that memory: the memory block has to be "online".
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Before a memory block can be removed, Linux has to stop using any memory part of
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the memory block: the memory block has to be "offlined".
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The Linux kernel can be configured to automatically online added memory blocks
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and drivers automatically trigger offlining of memory blocks when trying
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hotunplug of memory. Memory blocks can only be removed once offlining succeeded
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and drivers may trigger offlining of memory blocks when attempting hotunplug of
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memory.
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Onlining Memory Blocks Manually
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-------------------------------
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If auto-onlining of memory blocks isn't enabled, user-space has to manually
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trigger onlining of memory blocks. Often, udev rules are used to automate this
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task in user space.
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Onlining of a memory block can be triggered via::
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% echo online > /sys/devices/system/memory/memoryXXX/state
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Or alternatively::
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% echo 1 > /sys/devices/system/memory/memoryXXX/online
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The kernel will select the target zone automatically, depending on the
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configured ``online_policy``.
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One can explicitly request to associate an offline memory block with
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ZONE_MOVABLE by::
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% echo online_movable > /sys/devices/system/memory/memoryXXX/state
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Or one can explicitly request a kernel zone (usually ZONE_NORMAL) by::
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% echo online_kernel > /sys/devices/system/memory/memoryXXX/state
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In any case, if onlining succeeds, the state of the memory block is changed to
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be "online". If it fails, the state of the memory block will remain unchanged
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and the above commands will fail.
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Onlining Memory Blocks Automatically
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------------------------------------
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The kernel can be configured to try auto-onlining of newly added memory blocks.
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If this feature is disabled, the memory blocks will stay offline until
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explicitly onlined from user space.
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The configured auto-online behavior can be observed via::
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% cat /sys/devices/system/memory/auto_online_blocks
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Auto-onlining can be enabled by writing ``online``, ``online_kernel`` or
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``online_movable`` to that file, like::
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% echo online > /sys/devices/system/memory/auto_online_blocks
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Similarly to manual onlining, with ``online`` the kernel will select the
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target zone automatically, depending on the configured ``online_policy``.
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Modifying the auto-online behavior will only affect all subsequently added
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memory blocks only.
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.. note::
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In corner cases, auto-onlining can fail. The kernel won't retry. Note that
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auto-onlining is not expected to fail in default configurations.
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.. note::
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DLPAR on ppc64 ignores the ``offline`` setting and will still online added
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memory blocks; if onlining fails, memory blocks are removed again.
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Offlining Memory Blocks
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-----------------------
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In the current implementation, Linux's memory offlining will try migrating all
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movable pages off the affected memory block. As most kernel allocations, such as
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page tables, are unmovable, page migration can fail and, therefore, inhibit
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memory offlining from succeeding.
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Having the memory provided by memory block managed by ZONE_MOVABLE significantly
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increases memory offlining reliability; still, memory offlining can fail in
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some corner cases.
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Further, memory offlining might retry for a long time (or even forever), until
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aborted by the user.
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Offlining of a memory block can be triggered via::
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% echo offline > /sys/devices/system/memory/memoryXXX/state
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Or alternatively::
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% echo 0 > /sys/devices/system/memory/memoryXXX/online
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If offlining succeeds, the state of the memory block is changed to be "offline".
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If it fails, the state of the memory block will remain unchanged and the above
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commands will fail, for example, via::
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bash: echo: write error: Device or resource busy
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or via::
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bash: echo: write error: Invalid argument
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Observing the State of Memory Blocks
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------------------------------------
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The state (online/offline/going-offline) of a memory block can be observed
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either via::
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% cat /sys/devices/system/memory/memoryXXX/state
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Or alternatively (1/0) via::
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% cat /sys/devices/system/memory/memoryXXX/online
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For an online memory block, the managing zone can be observed via::
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% cat /sys/devices/system/memory/memoryXXX/valid_zones
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Configuring Memory Hot(Un)Plug
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==============================
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There are various ways how system administrators can configure memory
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hot(un)plug and interact with memory blocks, especially, to online them.
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Memory Hot(Un)Plug Configuration via Sysfs
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------------------------------------------
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Some memory hot(un)plug properties can be configured or inspected via sysfs in::
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/sys/devices/system/memory/
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The following files are currently defined:
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====================== =========================================================
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``auto_online_blocks`` read-write: set or get the default state of new memory
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blocks; configure auto-onlining.
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The default value depends on the
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CONFIG_MEMORY_HOTPLUG_DEFAULT_ONLINE kernel configuration
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option.
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See the ``state`` property of memory blocks for details.
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``block_size_bytes`` read-only: the size in bytes of a memory block.
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``probe`` write-only: add (probe) selected memory blocks manually
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from user space by supplying the physical start address.
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Availability depends on the CONFIG_ARCH_MEMORY_PROBE
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kernel configuration option.
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``uevent`` read-write: generic udev file for device subsystems.
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``crash_hotplug`` read-only: when changes to the system memory map
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occur due to hot un/plug of memory, this file contains
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'1' if the kernel updates the kdump capture kernel memory
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map itself (via elfcorehdr), or '0' if userspace must update
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the kdump capture kernel memory map.
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Availability depends on the CONFIG_MEMORY_HOTPLUG kernel
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configuration option.
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====================== =========================================================
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.. note::
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When the CONFIG_MEMORY_FAILURE kernel configuration option is enabled, two
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additional files ``hard_offline_page`` and ``soft_offline_page`` are available
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to trigger hwpoisoning of pages, for example, for testing purposes. Note that
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this functionality is not really related to memory hot(un)plug or actual
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offlining of memory blocks.
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Memory Block Configuration via Sysfs
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------------------------------------
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Each memory block is represented as a memory block device that can be
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onlined or offlined. All memory blocks have their device information located in
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sysfs. Each present memory block is listed under
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``/sys/devices/system/memory`` as::
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/sys/devices/system/memory/memoryXXX
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where XXX is the memory block id; the number of digits is variable.
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A present memory block indicates that some memory in the range is present;
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however, a memory block might span memory holes. A memory block spanning memory
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holes cannot be offlined.
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For example, assume 1 GiB memory block size. A device for a memory starting at
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0x100000000 is ``/sys/devices/system/memory/memory4``::
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(0x100000000 / 1Gib = 4)
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This device covers address range [0x100000000 ... 0x140000000)
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The following files are currently defined:
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=================== ============================================================
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``online`` read-write: simplified interface to trigger onlining /
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offlining and to observe the state of a memory block.
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When onlining, the zone is selected automatically.
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``phys_device`` read-only: legacy interface only ever used on s390x to
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expose the covered storage increment.
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``phys_index`` read-only: the memory block id (XXX).
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``removable`` read-only: legacy interface that indicated whether a memory
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block was likely to be offlineable or not. Nowadays, the
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kernel return ``1`` if and only if it supports memory
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offlining.
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``state`` read-write: advanced interface to trigger onlining /
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offlining and to observe the state of a memory block.
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When writing, ``online``, ``offline``, ``online_kernel`` and
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``online_movable`` are supported.
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``online_movable`` specifies onlining to ZONE_MOVABLE.
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``online_kernel`` specifies onlining to the default kernel
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zone for the memory block, such as ZONE_NORMAL.
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``online`` let's the kernel select the zone automatically.
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When reading, ``online``, ``offline`` and ``going-offline``
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may be returned.
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``uevent`` read-write: generic uevent file for devices.
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``valid_zones`` read-only: when a block is online, shows the zone it
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belongs to; when a block is offline, shows what zone will
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manage it when the block will be onlined.
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For online memory blocks, ``DMA``, ``DMA32``, ``Normal``,
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``Movable`` and ``none`` may be returned. ``none`` indicates
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that memory provided by a memory block is managed by
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multiple zones or spans multiple nodes; such memory blocks
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cannot be offlined. ``Movable`` indicates ZONE_MOVABLE.
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Other values indicate a kernel zone.
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For offline memory blocks, the first column shows the
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zone the kernel would select when onlining the memory block
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right now without further specifying a zone.
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Availability depends on the CONFIG_MEMORY_HOTREMOVE
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kernel configuration option.
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=================== ============================================================
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.. note::
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If the CONFIG_NUMA kernel configuration option is enabled, the memoryXXX/
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directories can also be accessed via symbolic links located in the
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``/sys/devices/system/node/node*`` directories.
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For example::
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/sys/devices/system/node/node0/memory9 -> ../../memory/memory9
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A backlink will also be created::
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/sys/devices/system/memory/memory9/node0 -> ../../node/node0
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Command Line Parameters
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-----------------------
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Some command line parameters affect memory hot(un)plug handling. The following
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command line parameters are relevant:
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======================== =======================================================
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``memhp_default_state`` configure auto-onlining by essentially setting
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``/sys/devices/system/memory/auto_online_blocks``.
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``movable_node`` configure automatic zone selection in the kernel when
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using the ``contig-zones`` online policy. When
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set, the kernel will default to ZONE_MOVABLE when
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onlining a memory block, unless other zones can be kept
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contiguous.
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======================== =======================================================
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See Documentation/admin-guide/kernel-parameters.txt for a more generic
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description of these command line parameters.
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Module Parameters
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------------------
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Instead of additional command line parameters or sysfs files, the
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``memory_hotplug`` subsystem now provides a dedicated namespace for module
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parameters. Module parameters can be set via the command line by predicating
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them with ``memory_hotplug.`` such as::
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memory_hotplug.memmap_on_memory=1
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and they can be observed (and some even modified at runtime) via::
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/sys/module/memory_hotplug/parameters/
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The following module parameters are currently defined:
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================================ ===============================================
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``memmap_on_memory`` read-write: Allocate memory for the memmap from
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the added memory block itself. Even if enabled,
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actual support depends on various other system
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properties and should only be regarded as a
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hint whether the behavior would be desired.
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While allocating the memmap from the memory
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block itself makes memory hotplug less likely
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to fail and keeps the memmap on the same NUMA
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node in any case, it can fragment physical
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memory in a way that huge pages in bigger
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granularity cannot be formed on hotplugged
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memory.
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With value "force" it could result in memory
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wastage due to memmap size limitations. For
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example, if the memmap for a memory block
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requires 1 MiB, but the pageblock size is 2
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MiB, 1 MiB of hotplugged memory will be wasted.
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Note that there are still cases where the
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feature cannot be enforced: for example, if the
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memmap is smaller than a single page, or if the
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architecture does not support the forced mode
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in all configurations.
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``online_policy`` read-write: Set the basic policy used for
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automatic zone selection when onlining memory
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blocks without specifying a target zone.
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``contig-zones`` has been the kernel default
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before this parameter was added. After an
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online policy was configured and memory was
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online, the policy should not be changed
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anymore.
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When set to ``contig-zones``, the kernel will
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try keeping zones contiguous. If a memory block
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intersects multiple zones or no zone, the
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behavior depends on the ``movable_node`` kernel
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command line parameter: default to ZONE_MOVABLE
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if set, default to the applicable kernel zone
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(usually ZONE_NORMAL) if not set.
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When set to ``auto-movable``, the kernel will
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try onlining memory blocks to ZONE_MOVABLE if
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possible according to the configuration and
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memory device details. With this policy, one
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can avoid zone imbalances when eventually
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hotplugging a lot of memory later and still
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wanting to be able to hotunplug as much as
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possible reliably, very desirable in
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virtualized environments. This policy ignores
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the ``movable_node`` kernel command line
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parameter and isn't really applicable in
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environments that require it (e.g., bare metal
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with hotunpluggable nodes) where hotplugged
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memory might be exposed via the
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firmware-provided memory map early during boot
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to the system instead of getting detected,
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added and onlined later during boot (such as
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done by virtio-mem or by some hypervisors
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implementing emulated DIMMs). As one example, a
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hotplugged DIMM will be onlined either
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completely to ZONE_MOVABLE or completely to
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ZONE_NORMAL, not a mixture.
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As another example, as many memory blocks
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belonging to a virtio-mem device will be
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onlined to ZONE_MOVABLE as possible,
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special-casing units of memory blocks that can
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only get hotunplugged together. *This policy
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does not protect from setups that are
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problematic with ZONE_MOVABLE and does not
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change the zone of memory blocks dynamically
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after they were onlined.*
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``auto_movable_ratio`` read-write: Set the maximum MOVABLE:KERNEL
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memory ratio in % for the ``auto-movable``
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online policy. Whether the ratio applies only
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for the system across all NUMA nodes or also
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per NUMA nodes depends on the
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``auto_movable_numa_aware`` configuration.
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All accounting is based on present memory pages
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in the zones combined with accounting per
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memory device. Memory dedicated to the CMA
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allocator is accounted as MOVABLE, although
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residing on one of the kernel zones. The
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possible ratio depends on the actual workload.
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The kernel default is "301" %, for example,
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allowing for hotplugging 24 GiB to a 8 GiB VM
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and automatically onlining all hotplugged
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memory to ZONE_MOVABLE in many setups. The
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additional 1% deals with some pages being not
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present, for example, because of some firmware
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allocations.
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Note that ZONE_NORMAL memory provided by one
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memory device does not allow for more
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ZONE_MOVABLE memory for a different memory
|
|
device. As one example, onlining memory of a
|
|
hotplugged DIMM to ZONE_NORMAL will not allow
|
|
for another hotplugged DIMM to get onlined to
|
|
ZONE_MOVABLE automatically. In contrast, memory
|
|
hotplugged by a virtio-mem device that got
|
|
onlined to ZONE_NORMAL will allow for more
|
|
ZONE_MOVABLE memory within *the same*
|
|
virtio-mem device.
|
|
``auto_movable_numa_aware`` read-write: Configure whether the
|
|
``auto_movable_ratio`` in the ``auto-movable``
|
|
online policy also applies per NUMA
|
|
node in addition to the whole system across all
|
|
NUMA nodes. The kernel default is "Y".
|
|
|
|
Disabling NUMA awareness can be helpful when
|
|
dealing with NUMA nodes that should be
|
|
completely hotunpluggable, onlining the memory
|
|
completely to ZONE_MOVABLE automatically if
|
|
possible.
|
|
|
|
Parameter availability depends on CONFIG_NUMA.
|
|
================================ ===============================================
|
|
|
|
ZONE_MOVABLE
|
|
============
|
|
|
|
ZONE_MOVABLE is an important mechanism for more reliable memory offlining.
|
|
Further, having system RAM managed by ZONE_MOVABLE instead of one of the
|
|
kernel zones can increase the number of possible transparent huge pages and
|
|
dynamically allocated huge pages.
|
|
|
|
Most kernel allocations are unmovable. Important examples include the memory
|
|
map (usually 1/64ths of memory), page tables, and kmalloc(). Such allocations
|
|
can only be served from the kernel zones.
|
|
|
|
Most user space pages, such as anonymous memory, and page cache pages are
|
|
movable. Such allocations can be served from ZONE_MOVABLE and the kernel zones.
|
|
|
|
Only movable allocations are served from ZONE_MOVABLE, resulting in unmovable
|
|
allocations being limited to the kernel zones. Without ZONE_MOVABLE, there is
|
|
absolutely no guarantee whether a memory block can be offlined successfully.
|
|
|
|
Zone Imbalances
|
|
---------------
|
|
|
|
Having too much system RAM managed by ZONE_MOVABLE is called a zone imbalance,
|
|
which can harm the system or degrade performance. As one example, the kernel
|
|
might crash because it runs out of free memory for unmovable allocations,
|
|
although there is still plenty of free memory left in ZONE_MOVABLE.
|
|
|
|
Usually, MOVABLE:KERNEL ratios of up to 3:1 or even 4:1 are fine. Ratios of 63:1
|
|
are definitely impossible due to the overhead for the memory map.
|
|
|
|
Actual safe zone ratios depend on the workload. Extreme cases, like excessive
|
|
long-term pinning of pages, might not be able to deal with ZONE_MOVABLE at all.
|
|
|
|
.. note::
|
|
|
|
CMA memory part of a kernel zone essentially behaves like memory in
|
|
ZONE_MOVABLE and similar considerations apply, especially when combining
|
|
CMA with ZONE_MOVABLE.
|
|
|
|
ZONE_MOVABLE Sizing Considerations
|
|
----------------------------------
|
|
|
|
We usually expect that a large portion of available system RAM will actually
|
|
be consumed by user space, either directly or indirectly via the page cache. In
|
|
the normal case, ZONE_MOVABLE can be used when allocating such pages just fine.
|
|
|
|
With that in mind, it makes sense that we can have a big portion of system RAM
|
|
managed by ZONE_MOVABLE. However, there are some things to consider when using
|
|
ZONE_MOVABLE, especially when fine-tuning zone ratios:
|
|
|
|
- Having a lot of offline memory blocks. Even offline memory blocks consume
|
|
memory for metadata and page tables in the direct map; having a lot of offline
|
|
memory blocks is not a typical case, though.
|
|
|
|
- Memory ballooning without balloon compaction is incompatible with
|
|
ZONE_MOVABLE. Only some implementations, such as virtio-balloon and
|
|
pseries CMM, fully support balloon compaction.
|
|
|
|
Further, the CONFIG_BALLOON_COMPACTION kernel configuration option might be
|
|
disabled. In that case, balloon inflation will only perform unmovable
|
|
allocations and silently create a zone imbalance, usually triggered by
|
|
inflation requests from the hypervisor.
|
|
|
|
- Gigantic pages are unmovable, resulting in user space consuming a
|
|
lot of unmovable memory.
|
|
|
|
- Huge pages are unmovable when an architectures does not support huge
|
|
page migration, resulting in a similar issue as with gigantic pages.
|
|
|
|
- Page tables are unmovable. Excessive swapping, mapping extremely large
|
|
files or ZONE_DEVICE memory can be problematic, although only really relevant
|
|
in corner cases. When we manage a lot of user space memory that has been
|
|
swapped out or is served from a file/persistent memory/... we still need a lot
|
|
of page tables to manage that memory once user space accessed that memory.
|
|
|
|
- In certain DAX configurations the memory map for the device memory will be
|
|
allocated from the kernel zones.
|
|
|
|
- KASAN can have a significant memory overhead, for example, consuming 1/8th of
|
|
the total system memory size as (unmovable) tracking metadata.
|
|
|
|
- Long-term pinning of pages. Techniques that rely on long-term pinnings
|
|
(especially, RDMA and vfio/mdev) are fundamentally problematic with
|
|
ZONE_MOVABLE, and therefore, memory offlining. Pinned pages cannot reside
|
|
on ZONE_MOVABLE as that would turn these pages unmovable. Therefore, they
|
|
have to be migrated off that zone while pinning. Pinning a page can fail
|
|
even if there is plenty of free memory in ZONE_MOVABLE.
|
|
|
|
In addition, using ZONE_MOVABLE might make page pinning more expensive,
|
|
because of the page migration overhead.
|
|
|
|
By default, all the memory configured at boot time is managed by the kernel
|
|
zones and ZONE_MOVABLE is not used.
|
|
|
|
To enable ZONE_MOVABLE to include the memory present at boot and to control the
|
|
ratio between movable and kernel zones there are two command line options:
|
|
``kernelcore=`` and ``movablecore=``. See
|
|
Documentation/admin-guide/kernel-parameters.rst for their description.
|
|
|
|
Memory Offlining and ZONE_MOVABLE
|
|
---------------------------------
|
|
|
|
Even with ZONE_MOVABLE, there are some corner cases where offlining a memory
|
|
block might fail:
|
|
|
|
- Memory blocks with memory holes; this applies to memory blocks present during
|
|
boot and can apply to memory blocks hotplugged via the XEN balloon and the
|
|
Hyper-V balloon.
|
|
|
|
- Mixed NUMA nodes and mixed zones within a single memory block prevent memory
|
|
offlining; this applies to memory blocks present during boot only.
|
|
|
|
- Special memory blocks prevented by the system from getting offlined. Examples
|
|
include any memory available during boot on arm64 or memory blocks spanning
|
|
the crashkernel area on s390x; this usually applies to memory blocks present
|
|
during boot only.
|
|
|
|
- Memory blocks overlapping with CMA areas cannot be offlined, this applies to
|
|
memory blocks present during boot only.
|
|
|
|
- Concurrent activity that operates on the same physical memory area, such as
|
|
allocating gigantic pages, can result in temporary offlining failures.
|
|
|
|
- Out of memory when dissolving huge pages, especially when HugeTLB Vmemmap
|
|
Optimization (HVO) is enabled.
|
|
|
|
Offlining code may be able to migrate huge page contents, but may not be able
|
|
to dissolve the source huge page because it fails allocating (unmovable) pages
|
|
for the vmemmap, because the system might not have free memory in the kernel
|
|
zones left.
|
|
|
|
Users that depend on memory offlining to succeed for movable zones should
|
|
carefully consider whether the memory savings gained from this feature are
|
|
worth the risk of possibly not being able to offline memory in certain
|
|
situations.
|
|
|
|
Further, when running into out of memory situations while migrating pages, or
|
|
when still encountering permanently unmovable pages within ZONE_MOVABLE
|
|
(-> BUG), memory offlining will keep retrying until it eventually succeeds.
|
|
|
|
When offlining is triggered from user space, the offlining context can be
|
|
terminated by sending a signal. A timeout based offlining can easily be
|
|
implemented via::
|
|
|
|
% timeout $TIMEOUT offline_block | failure_handling
|