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it's -> its referenced to by -> referenced by Signed-off-by: Kim Phillips <kim.phillips@amd.com> Reviewed-by: Mike Rapoport (IBM) <rppt@kernel.org> Link: https://lore.kernel.org/r/20230331165254.207526-1-kim.phillips@amd.com Signed-off-by: Jonathan Corbet <corbet@lwn.net>
372 lines
14 KiB
ReStructuredText
372 lines
14 KiB
ReStructuredText
.. SPDX-License-Identifier: GPL-2.0
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===============
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Physical Memory
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===============
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Linux is available for a wide range of architectures so there is a need for an
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architecture-independent abstraction to represent the physical memory. This
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chapter describes the structures used to manage physical memory in a running
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system.
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The first principal concept prevalent in the memory management is
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`Non-Uniform Memory Access (NUMA)
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<https://en.wikipedia.org/wiki/Non-uniform_memory_access>`_.
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With multi-core and multi-socket machines, memory may be arranged into banks
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that incur a different cost to access depending on the “distance” from the
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processor. For example, there might be a bank of memory assigned to each CPU or
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a bank of memory very suitable for DMA near peripheral devices.
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Each bank is called a node and the concept is represented under Linux by a
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``struct pglist_data`` even if the architecture is UMA. This structure is
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always referenced by its typedef ``pg_data_t``. A ``pg_data_t`` structure
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for a particular node can be referenced by ``NODE_DATA(nid)`` macro where
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``nid`` is the ID of that node.
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For NUMA architectures, the node structures are allocated by the architecture
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specific code early during boot. Usually, these structures are allocated
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locally on the memory bank they represent. For UMA architectures, only one
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static ``pg_data_t`` structure called ``contig_page_data`` is used. Nodes will
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be discussed further in Section :ref:`Nodes <nodes>`
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The entire physical address space is partitioned into one or more blocks
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called zones which represent ranges within memory. These ranges are usually
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determined by architectural constraints for accessing the physical memory.
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The memory range within a node that corresponds to a particular zone is
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described by a ``struct zone``, typedeffed to ``zone_t``. Each zone has
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one of the types described below.
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* ``ZONE_DMA`` and ``ZONE_DMA32`` historically represented memory suitable for
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DMA by peripheral devices that cannot access all of the addressable
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memory. For many years there are better more and robust interfaces to get
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memory with DMA specific requirements (Documentation/core-api/dma-api.rst),
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but ``ZONE_DMA`` and ``ZONE_DMA32`` still represent memory ranges that have
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restrictions on how they can be accessed.
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Depending on the architecture, either of these zone types or even they both
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can be disabled at build time using ``CONFIG_ZONE_DMA`` and
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``CONFIG_ZONE_DMA32`` configuration options. Some 64-bit platforms may need
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both zones as they support peripherals with different DMA addressing
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limitations.
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* ``ZONE_NORMAL`` is for normal memory that can be accessed by the kernel all
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the time. DMA operations can be performed on pages in this zone if the DMA
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devices support transfers to all addressable memory. ``ZONE_NORMAL`` is
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always enabled.
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* ``ZONE_HIGHMEM`` is the part of the physical memory that is not covered by a
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permanent mapping in the kernel page tables. The memory in this zone is only
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accessible to the kernel using temporary mappings. This zone is available
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only on some 32-bit architectures and is enabled with ``CONFIG_HIGHMEM``.
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* ``ZONE_MOVABLE`` is for normal accessible memory, just like ``ZONE_NORMAL``.
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The difference is that the contents of most pages in ``ZONE_MOVABLE`` is
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movable. That means that while virtual addresses of these pages do not
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change, their content may move between different physical pages. Often
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``ZONE_MOVABLE`` is populated during memory hotplug, but it may be
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also populated on boot using one of ``kernelcore``, ``movablecore`` and
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``movable_node`` kernel command line parameters. See
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Documentation/mm/page_migration.rst and
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Documentation/admin-guide/mm/memory-hotplug.rst for additional details.
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* ``ZONE_DEVICE`` represents memory residing on devices such as PMEM and GPU.
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It has different characteristics than RAM zone types and it exists to provide
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:ref:`struct page <Pages>` and memory map services for device driver
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identified physical address ranges. ``ZONE_DEVICE`` is enabled with
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configuration option ``CONFIG_ZONE_DEVICE``.
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It is important to note that many kernel operations can only take place using
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``ZONE_NORMAL`` so it is the most performance critical zone. Zones are
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discussed further in Section :ref:`Zones <zones>`.
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The relation between node and zone extents is determined by the physical memory
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map reported by the firmware, architectural constraints for memory addressing
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and certain parameters in the kernel command line.
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For example, with 32-bit kernel on an x86 UMA machine with 2 Gbytes of RAM the
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entire memory will be on node 0 and there will be three zones: ``ZONE_DMA``,
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``ZONE_NORMAL`` and ``ZONE_HIGHMEM``::
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0 2G
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+-------------------------------------------------------------+
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| node 0 |
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+-------------------------------------------------------------+
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0 16M 896M 2G
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+----------+-----------------------+--------------------------+
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| ZONE_DMA | ZONE_NORMAL | ZONE_HIGHMEM |
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+----------+-----------------------+--------------------------+
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With a kernel built with ``ZONE_DMA`` disabled and ``ZONE_DMA32`` enabled and
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booted with ``movablecore=80%`` parameter on an arm64 machine with 16 Gbytes of
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RAM equally split between two nodes, there will be ``ZONE_DMA32``,
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``ZONE_NORMAL`` and ``ZONE_MOVABLE`` on node 0, and ``ZONE_NORMAL`` and
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``ZONE_MOVABLE`` on node 1::
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1G 9G 17G
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+--------------------------------+ +--------------------------+
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| node 0 | | node 1 |
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+--------------------------------+ +--------------------------+
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1G 4G 4200M 9G 9320M 17G
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+---------+----------+-----------+ +------------+-------------+
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| DMA32 | NORMAL | MOVABLE | | NORMAL | MOVABLE |
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+---------+----------+-----------+ +------------+-------------+
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Memory banks may belong to interleaving nodes. In the example below an x86
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machine has 16 Gbytes of RAM in 4 memory banks, even banks belong to node 0
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and odd banks belong to node 1::
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0 4G 8G 12G 16G
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+-------------+ +-------------+ +-------------+ +-------------+
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| node 0 | | node 1 | | node 0 | | node 1 |
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+-------------+ +-------------+ +-------------+ +-------------+
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0 16M 4G
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+-----+-------+ +-------------+ +-------------+ +-------------+
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| DMA | DMA32 | | NORMAL | | NORMAL | | NORMAL |
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+-----+-------+ +-------------+ +-------------+ +-------------+
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In this case node 0 will span from 0 to 12 Gbytes and node 1 will span from
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4 to 16 Gbytes.
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.. _nodes:
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Nodes
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=====
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As we have mentioned, each node in memory is described by a ``pg_data_t`` which
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is a typedef for a ``struct pglist_data``. When allocating a page, by default
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Linux uses a node-local allocation policy to allocate memory from the node
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closest to the running CPU. As processes tend to run on the same CPU, it is
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likely the memory from the current node will be used. The allocation policy can
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be controlled by users as described in
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Documentation/admin-guide/mm/numa_memory_policy.rst.
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Most NUMA architectures maintain an array of pointers to the node
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structures. The actual structures are allocated early during boot when
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architecture specific code parses the physical memory map reported by the
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firmware. The bulk of the node initialization happens slightly later in the
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boot process by free_area_init() function, described later in Section
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:ref:`Initialization <initialization>`.
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Along with the node structures, kernel maintains an array of ``nodemask_t``
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bitmasks called ``node_states``. Each bitmask in this array represents a set of
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nodes with particular properties as defined by ``enum node_states``:
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``N_POSSIBLE``
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The node could become online at some point.
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``N_ONLINE``
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The node is online.
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``N_NORMAL_MEMORY``
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The node has regular memory.
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``N_HIGH_MEMORY``
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The node has regular or high memory. When ``CONFIG_HIGHMEM`` is disabled
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aliased to ``N_NORMAL_MEMORY``.
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``N_MEMORY``
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The node has memory(regular, high, movable)
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``N_CPU``
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The node has one or more CPUs
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For each node that has a property described above, the bit corresponding to the
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node ID in the ``node_states[<property>]`` bitmask is set.
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For example, for node 2 with normal memory and CPUs, bit 2 will be set in ::
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node_states[N_POSSIBLE]
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node_states[N_ONLINE]
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node_states[N_NORMAL_MEMORY]
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node_states[N_HIGH_MEMORY]
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node_states[N_MEMORY]
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node_states[N_CPU]
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For various operations possible with nodemasks please refer to
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``include/linux/nodemask.h``.
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Among other things, nodemasks are used to provide macros for node traversal,
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namely ``for_each_node()`` and ``for_each_online_node()``.
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For instance, to call a function foo() for each online node::
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for_each_online_node(nid) {
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pg_data_t *pgdat = NODE_DATA(nid);
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foo(pgdat);
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}
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Node structure
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--------------
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The nodes structure ``struct pglist_data`` is declared in
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``include/linux/mmzone.h``. Here we briefly describe fields of this
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structure:
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General
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~~~~~~~
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``node_zones``
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The zones for this node. Not all of the zones may be populated, but it is
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the full list. It is referenced by this node's node_zonelists as well as
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other node's node_zonelists.
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``node_zonelists``
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The list of all zones in all nodes. This list defines the order of zones
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that allocations are preferred from. The ``node_zonelists`` is set up by
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``build_zonelists()`` in ``mm/page_alloc.c`` during the initialization of
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core memory management structures.
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``nr_zones``
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Number of populated zones in this node.
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``node_mem_map``
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For UMA systems that use FLATMEM memory model the 0's node
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``node_mem_map`` is array of struct pages representing each physical frame.
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``node_page_ext``
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For UMA systems that use FLATMEM memory model the 0's node
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``node_page_ext`` is array of extensions of struct pages. Available only
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in the kernels built with ``CONFIG_PAGE_EXTENSION`` enabled.
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``node_start_pfn``
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The page frame number of the starting page frame in this node.
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``node_present_pages``
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Total number of physical pages present in this node.
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``node_spanned_pages``
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Total size of physical page range, including holes.
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``node_size_lock``
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A lock that protects the fields defining the node extents. Only defined when
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at least one of ``CONFIG_MEMORY_HOTPLUG`` or
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``CONFIG_DEFERRED_STRUCT_PAGE_INIT`` configuration options are enabled.
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``pgdat_resize_lock()`` and ``pgdat_resize_unlock()`` are provided to
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manipulate ``node_size_lock`` without checking for ``CONFIG_MEMORY_HOTPLUG``
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or ``CONFIG_DEFERRED_STRUCT_PAGE_INIT``.
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``node_id``
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The Node ID (NID) of the node, starts at 0.
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``totalreserve_pages``
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This is a per-node reserve of pages that are not available to userspace
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allocations.
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``first_deferred_pfn``
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If memory initialization on large machines is deferred then this is the first
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PFN that needs to be initialized. Defined only when
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``CONFIG_DEFERRED_STRUCT_PAGE_INIT`` is enabled
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``deferred_split_queue``
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Per-node queue of huge pages that their split was deferred. Defined only when ``CONFIG_TRANSPARENT_HUGEPAGE`` is enabled.
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``__lruvec``
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Per-node lruvec holding LRU lists and related parameters. Used only when
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memory cgroups are disabled. It should not be accessed directly, use
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``mem_cgroup_lruvec()`` to look up lruvecs instead.
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Reclaim control
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~~~~~~~~~~~~~~~
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See also Documentation/mm/page_reclaim.rst.
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``kswapd``
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Per-node instance of kswapd kernel thread.
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``kswapd_wait``, ``pfmemalloc_wait``, ``reclaim_wait``
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Workqueues used to synchronize memory reclaim tasks
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``nr_writeback_throttled``
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Number of tasks that are throttled waiting on dirty pages to clean.
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``nr_reclaim_start``
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Number of pages written while reclaim is throttled waiting for writeback.
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``kswapd_order``
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Controls the order kswapd tries to reclaim
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``kswapd_highest_zoneidx``
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The highest zone index to be reclaimed by kswapd
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``kswapd_failures``
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Number of runs kswapd was unable to reclaim any pages
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``min_unmapped_pages``
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Minimal number of unmapped file backed pages that cannot be reclaimed.
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Determined by ``vm.min_unmapped_ratio`` sysctl. Only defined when
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``CONFIG_NUMA`` is enabled.
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``min_slab_pages``
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Minimal number of SLAB pages that cannot be reclaimed. Determined by
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``vm.min_slab_ratio sysctl``. Only defined when ``CONFIG_NUMA`` is enabled
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``flags``
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Flags controlling reclaim behavior.
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Compaction control
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~~~~~~~~~~~~~~~~~~
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``kcompactd_max_order``
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Page order that kcompactd should try to achieve.
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``kcompactd_highest_zoneidx``
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The highest zone index to be compacted by kcompactd.
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``kcompactd_wait``
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Workqueue used to synchronize memory compaction tasks.
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``kcompactd``
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Per-node instance of kcompactd kernel thread.
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``proactive_compact_trigger``
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Determines if proactive compaction is enabled. Controlled by
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``vm.compaction_proactiveness`` sysctl.
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Statistics
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~~~~~~~~~~
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``per_cpu_nodestats``
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Per-CPU VM statistics for the node
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``vm_stat``
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VM statistics for the node.
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.. _zones:
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Zones
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=====
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.. admonition:: Stub
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This section is incomplete. Please list and describe the appropriate fields.
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.. _pages:
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Pages
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=====
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.. admonition:: Stub
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This section is incomplete. Please list and describe the appropriate fields.
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.. _folios:
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Folios
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======
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.. admonition:: Stub
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This section is incomplete. Please list and describe the appropriate fields.
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.. _initialization:
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Initialization
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==============
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.. admonition:: Stub
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This section is incomplete. Please list and describe the appropriate fields.
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