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Signed-off-by: Mike Rapoport <rppt@linux.ibm.com> Reviewed-by: Randy Dunlap <rdunlap@infradead.org> Signed-off-by: Jonathan Corbet <corbet@lwn.net>
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224 lines
11 KiB
ReStructuredText
.. _mm_concepts:
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=================
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Concepts overview
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=================
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The memory management in Linux is a complex system that evolved over the
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years and included more and more functionality to support a variety of
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systems from MMU-less microcontrollers to supercomputers. The memory
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management for systems without an MMU is called ``nommu`` and it
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definitely deserves a dedicated document, which hopefully will be
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eventually written. Yet, although some of the concepts are the same,
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here we assume that an MMU is available and a CPU can translate a virtual
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address to a physical address.
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.. contents:: :local:
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Virtual Memory Primer
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=====================
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The physical memory in a computer system is a limited resource and
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even for systems that support memory hotplug there is a hard limit on
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the amount of memory that can be installed. The physical memory is not
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necessarily contiguous; it might be accessible as a set of distinct
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address ranges. Besides, different CPU architectures, and even
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different implementations of the same architecture have different views
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of how these address ranges are defined.
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All this makes dealing directly with physical memory quite complex and
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to avoid this complexity a concept of virtual memory was developed.
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The virtual memory abstracts the details of physical memory from the
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application software, allows to keep only needed information in the
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physical memory (demand paging) and provides a mechanism for the
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protection and controlled sharing of data between processes.
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With virtual memory, each and every memory access uses a virtual
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address. When the CPU decodes the an instruction that reads (or
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writes) from (or to) the system memory, it translates the `virtual`
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address encoded in that instruction to a `physical` address that the
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memory controller can understand.
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The physical system memory is divided into page frames, or pages. The
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size of each page is architecture specific. Some architectures allow
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selection of the page size from several supported values; this
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selection is performed at the kernel build time by setting an
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appropriate kernel configuration option.
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Each physical memory page can be mapped as one or more virtual
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pages. These mappings are described by page tables that allow
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translation from a virtual address used by programs to the physical
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memory address. The page tables are organized hierarchically.
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The tables at the lowest level of the hierarchy contain physical
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addresses of actual pages used by the software. The tables at higher
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levels contain physical addresses of the pages belonging to the lower
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levels. The pointer to the top level page table resides in a
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register. When the CPU performs the address translation, it uses this
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register to access the top level page table. The high bits of the
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virtual address are used to index an entry in the top level page
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table. That entry is then used to access the next level in the
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hierarchy with the next bits of the virtual address as the index to
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that level page table. The lowest bits in the virtual address define
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the offset inside the actual page.
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Huge Pages
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==========
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The address translation requires several memory accesses and memory
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accesses are slow relatively to CPU speed. To avoid spending precious
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processor cycles on the address translation, CPUs maintain a cache of
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such translations called Translation Lookaside Buffer (or
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TLB). Usually TLB is pretty scarce resource and applications with
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large memory working set will experience performance hit because of
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TLB misses.
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Many modern CPU architectures allow mapping of the memory pages
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directly by the higher levels in the page table. For instance, on x86,
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it is possible to map 2M and even 1G pages using entries in the second
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and the third level page tables. In Linux such pages are called
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`huge`. Usage of huge pages significantly reduces pressure on TLB,
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improves TLB hit-rate and thus improves overall system performance.
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There are two mechanisms in Linux that enable mapping of the physical
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memory with the huge pages. The first one is `HugeTLB filesystem`, or
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hugetlbfs. It is a pseudo filesystem that uses RAM as its backing
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store. For the files created in this filesystem the data resides in
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the memory and mapped using huge pages. The hugetlbfs is described at
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:ref:`Documentation/admin-guide/mm/hugetlbpage.rst <hugetlbpage>`.
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Another, more recent, mechanism that enables use of the huge pages is
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called `Transparent HugePages`, or THP. Unlike the hugetlbfs that
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requires users and/or system administrators to configure what parts of
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the system memory should and can be mapped by the huge pages, THP
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manages such mappings transparently to the user and hence the
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name. See
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:ref:`Documentation/admin-guide/mm/transhuge.rst <admin_guide_transhuge>`
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for more details about THP.
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Zones
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=====
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Often hardware poses restrictions on how different physical memory
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ranges can be accessed. In some cases, devices cannot perform DMA to
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all the addressable memory. In other cases, the size of the physical
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memory exceeds the maximal addressable size of virtual memory and
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special actions are required to access portions of the memory. Linux
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groups memory pages into `zones` according to their possible
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usage. For example, ZONE_DMA will contain memory that can be used by
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devices for DMA, ZONE_HIGHMEM will contain memory that is not
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permanently mapped into kernel's address space and ZONE_NORMAL will
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contain normally addressed pages.
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The actual layout of the memory zones is hardware dependent as not all
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architectures define all zones, and requirements for DMA are different
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for different platforms.
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Nodes
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=====
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Many multi-processor machines are NUMA - Non-Uniform Memory Access -
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systems. In such systems the memory is arranged into banks that have
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different access latency depending on the "distance" from the
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processor. Each bank is referred to as a `node` and for each node Linux
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constructs an independent memory management subsystem. A node has its
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own set of zones, lists of free and used pages and various statistics
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counters. You can find more details about NUMA in
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:ref:`Documentation/vm/numa.rst <numa>` and in
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:ref:`Documentation/admin-guide/mm/numa_memory_policy.rst <numa_memory_policy>`.
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Page cache
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==========
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The physical memory is volatile and the common case for getting data
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into the memory is to read it from files. Whenever a file is read, the
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data is put into the `page cache` to avoid expensive disk access on
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the subsequent reads. Similarly, when one writes to a file, the data
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is placed in the page cache and eventually gets into the backing
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storage device. The written pages are marked as `dirty` and when Linux
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decides to reuse them for other purposes, it makes sure to synchronize
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the file contents on the device with the updated data.
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Anonymous Memory
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================
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The `anonymous memory` or `anonymous mappings` represent memory that
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is not backed by a filesystem. Such mappings are implicitly created
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for program's stack and heap or by explicit calls to mmap(2) system
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call. Usually, the anonymous mappings only define virtual memory areas
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that the program is allowed to access. The read accesses will result
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in creation of a page table entry that references a special physical
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page filled with zeroes. When the program performs a write, a regular
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physical page will be allocated to hold the written data. The page
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will be marked dirty and if the kernel decides to repurpose it,
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the dirty page will be swapped out.
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Reclaim
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=======
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Throughout the system lifetime, a physical page can be used for storing
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different types of data. It can be kernel internal data structures,
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DMA'able buffers for device drivers use, data read from a filesystem,
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memory allocated by user space processes etc.
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Depending on the page usage it is treated differently by the Linux
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memory management. The pages that can be freed at any time, either
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because they cache the data available elsewhere, for instance, on a
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hard disk, or because they can be swapped out, again, to the hard
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disk, are called `reclaimable`. The most notable categories of the
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reclaimable pages are page cache and anonymous memory.
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In most cases, the pages holding internal kernel data and used as DMA
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buffers cannot be repurposed, and they remain pinned until freed by
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their user. Such pages are called `unreclaimable`. However, in certain
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circumstances, even pages occupied with kernel data structures can be
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reclaimed. For instance, in-memory caches of filesystem metadata can
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be re-read from the storage device and therefore it is possible to
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discard them from the main memory when system is under memory
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pressure.
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The process of freeing the reclaimable physical memory pages and
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repurposing them is called (surprise!) `reclaim`. Linux can reclaim
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pages either asynchronously or synchronously, depending on the state
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of the system. When the system is not loaded, most of the memory is free
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and allocation requests will be satisfied immediately from the free
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pages supply. As the load increases, the amount of the free pages goes
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down and when it reaches a certain threshold (high watermark), an
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allocation request will awaken the ``kswapd`` daemon. It will
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asynchronously scan memory pages and either just free them if the data
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they contain is available elsewhere, or evict to the backing storage
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device (remember those dirty pages?). As memory usage increases even
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more and reaches another threshold - min watermark - an allocation
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will trigger `direct reclaim`. In this case allocation is stalled
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until enough memory pages are reclaimed to satisfy the request.
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Compaction
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==========
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As the system runs, tasks allocate and free the memory and it becomes
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fragmented. Although with virtual memory it is possible to present
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scattered physical pages as virtually contiguous range, sometimes it is
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necessary to allocate large physically contiguous memory areas. Such
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need may arise, for instance, when a device driver requires a large
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buffer for DMA, or when THP allocates a huge page. Memory `compaction`
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addresses the fragmentation issue. This mechanism moves occupied pages
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from the lower part of a memory zone to free pages in the upper part
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of the zone. When a compaction scan is finished free pages are grouped
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together at the beginning of the zone and allocations of large
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physically contiguous areas become possible.
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Like reclaim, the compaction may happen asynchronously in the ``kcompactd``
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daemon or synchronously as a result of a memory allocation request.
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OOM killer
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==========
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It is possible that on a loaded machine memory will be exhausted and the
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kernel will be unable to reclaim enough memory to continue to operate. In
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order to save the rest of the system, it invokes the `OOM killer`.
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The `OOM killer` selects a task to sacrifice for the sake of the overall
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system health. The selected task is killed in a hope that after it exits
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enough memory will be freed to continue normal operation.
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